

Apple II Original ROM Information

Source
http://members.buckeye-express.com/marksm/6502/
27 June 2004

The 6502 Firmware Page


This site is mostly about the firmware -- software in ROM -- that came with the original Apple II, not the II+, IIe, IIc, or IIgs. The original Apple II had 4K of RAM and 8K of ROM. The ROM contains software, such as the Monitor and Integer BASIC, appropriate for a SBC.

Red Book refers to the original Apple II Reference Manual dated 1978.
WOZPAK refers to the WOZPAK II, a publication by Call-A.P.P.L.E., an Apple II user group.
DDJ refers to Dr. Dobbs Journal, a computer magazine.
IA refers to Interface Age, a publication of the SCCS (Southern California Computer Society).
SYM and AIM refer to early 6502 single board computers.

Contents

*	Apple II ROM (12 KB binary) 
*	Memory map of the Apple II ROMs 
*	Summary of Monitor Commands 
*	Red Book Monitor listing 
*	Red Book Sweet-16 listing 
*	WOZPAK Sweet-16 article by Steve Wozniak 
*	WOZPAK Sweet-16 article by Dick Sedgewick 
*	Red Book Mini-Assembler listing 
*	Red Book Floating point listing 
*	WOZPAK Floating point routines description 
*	DDJ Floating point article 
*	IA Floating point article 
*	SYM Monitor listing 
*	AIM Monitor listing 
*	AIM BASIC Language Reference Manual 

------------------------------------------------------------------------

Questions or comments? Email me at 
paulrsm@buckeye-express.com

------------------------------------------------------------------------

Updates

*	2000-09-01 -- Added AIM BASIC Language Reference Manual 

+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Apple II ROM (12 KB binary) 
+------------------------------------------------------------------------

File ............. "a2rom.bin"
Fork ............. DATA
Size (bytes) ..... 12,288 (12KB) / $00003000
Created .......... Sunday, December 8, 2002 -- 8:47:53 PM
Modified ......... Sunday, December 8, 2002 -- 8:47:53 PM

D/000000: A9208D26 03AD57C0 AD53C0AD 50C0A900 [...&..W..S..P...]
D/000010: 851CAD26 03851BA0 00841AA5 1C911A20 [...&............]
D/000020: A2D0C8D0 F6E61BA5 1B291FD0 EE608D22 [.........)...`."]
D/000030: 038E2003 8C210348 29C08526 4A4A0526 [.....!.H)..&JJ.&]
D/000040: 85266885 270A0A0A 26270A26 270A6626 [.&h.'...&'.&'.f&]
D/000050: A527291F 0D260385 278AC000 F005A023 [.')..&..'......#]
D/000060: 6904C8E9 07B0FB8C 2503AABD EAD08530 [i.......%......0]
D/000070: 984AAD24 03851CB0 2960202E D0A51C51 [.J.$....)`.....Q]
D/000080: 26253051 26912660 1024A530 4AB00549 [&%0Q&.&`.$.0J..I]
D/000090: C0853060 881002A0 27A9C085 308C2503 [..0`....'...0.%.]
D/0000A0: A51C0AC9 C01006A5 1C497F85 1C60A530 [.........I...`.0]
D/0000B0: 0A498030 DCA981C8 C02890DF A000B0DB [.I.0.....(......]
D/0000C0: 18A55129 04F027A9 7F253031 26D01BEE [..Q)..'..%01&...]
D/0000D0: 2A03A97F 25301012 18A55129 04F00FB1 [*...%0....Q)....]
D/0000E0: 26451C25 30D003EE 2A035126 9126A551 [&E.%0...*.Q&.&.Q]
D/0000F0: 65532903 C9026AB0 8F303018 A5272CEA [eS)...j..00..',.]
D/000100: D1D02206 26B01A2C F3D0F005 691F38B0 [..".&..,....i.8.]
D/000110: 12692348 A52669B0 B00269F0 852668B0 [.i#H.&i...i..&h.]
D/000120: 02691F66 2669FC85 276018A5 2769042C [.i.f&i..'`..'i.,]
D/000130: EAD1D0F3 06269019 69E0182C 2ED1F013 [.....&..i..,....]
D/000140: A5266950 49F0F002 49F08526 AD260390 [.&iPI...I..&.&..]
D/000150: 0269E066 2690D048 A9008D20 038D2103 [.i.f&..H......!.]
D/000160: 8D220368 4838ED20 03488AED 21038553 [.".hH8...H..!..S]
D/000170: B00A6849 FF690148 A900E553 85518555 [..hI.i.H...S.Q.U]
D/000180: 68855085 54688D20 038E2103 9818ED22 [h.P.Th....!...."]
D/000190: 03900449 FF69FE85 528C2203 665338E5 [...I.i..R.".fS8.]
D/0001A0: 50AAA9FF E551851D AC2503B0 050A2088 [P....Q...%......]
D/0001B0: D038A554 65528554 A555E900 8555B126 [.8.TeR.T.U...U.&]
D/0001C0: 451C2530 51269126 E8D004E6 1DF06BA5 [E.%0Q&.&......k.]
D/0001D0: 53B0DA20 F9D018A5 54655085 54A55565 [S.......TeP.T.Ue]
D/0001E0: 5150D981 82848890 A0C01CFF FEFAF4EC [QP..............]
D/0001F0: E1D4C5B4 A18D7861 493118FF A5260AA5 [......xaI1...&..]
D/000200: 2729032A 05260A0A 0A8D2203 A5274A4A [').*.&...."..'JJ]
D/000210: 29070D22 038D2203 AD25030A 6D25030A [)..".."..%..m%..]
D/000220: AACAA530 297FE84A D0FC8D21 038A186D [...0)..J...!...m]
D/000230: 25039003 EE21038D 20036086 1A841BAA [%....!....`.....]
D/000240: 4A4A4A4A 85538A29 0FAABCEB D1845049 [JJJJ.S.)......PI]
D/000250: 0FAABCEC D1C88452 AC2503A2 008E2A03 [.......R.%....*.]
D/000260: A11A8551 A2808654 8655AE27 03A55438 [...Q...T.U.'..T8]
D/000270: 65508554 900420D8 D018A555 65528555 [eP.T.......UeR.U]
D/000280: 900320D9 D0CAD0E5 A5514A4A 4AD0D3E6 [.........QJJJ...]
D/000290: 1AD002E6 1BA11AD0 C960861A 841BAA4A [.........`.....J]
D/0002A0: 4A4A4A85 538A290F AABCEBD1 8450490F [JJJ.S.)......PI.]
D/0002B0: AABCECD1 C88452AC 2503A200 8E2A03A1 [......R.%....*..]
D/0002C0: 1A8551A2 80865486 55AE2703 A5543865 [..Q...T.U.'..T8e]
D/0002D0: 50855490 0420C0D0 18A55565 52855590 [P.T.......UeR.U.]
D/0002E0: 0320D9D0 CAD0E5A5 514A4A4A D0D3E61A [........QJJJ....]
D/0002F0: D002E61B A11AD0C9 602090D3 8D240320 [........`....$..]
D/000300: AFD34820 9AD36820 2ED0AE23 036020F9 [..H...h....#.`..]
D/000310: D24C7DD0 AD25034A 2090D320 75D0209A [.L}..%.J....u...]
D/000320: D38A4898 AA20AFD3 A8682064 D1AE2303 [..H......h.d..#.]
D/000330: 602090D3 4C10D020 F9D22051 D3203BD2 [`...L......Q..;.]
D/000340: AE230360 20F9D220 51D3209A D2AE2303 [.#.`....Q.....#.]
D/000350: 608E2303 A0322092 D38D2703 A0282092 [`.#..2....'..(..]
D/000360: D348AD28 03851AAD 2903851B A0202092 [.H.(....).......]
D/000370: D3F039A2 00C11AF0 02B0310A 9003E61B [..9.......1.....]
D/000380: 18A8B11A 651AAAC8 B11A6D29 03A86860 [....e.....m)..h`]
D/000390: A016B14A D01688B1 4A608E23 03A005B1 [...J....J`.#....]
D/0003A0: 4AAAC8B1 4AA8E018 E90190ED 4C68EEA0 [J...J.......Lh..]
D/0003B0: 0D2092D3 C9C0B0F4 608E2303 201EF120 [........`.#.....]
D/0003C0: FDFEA900 853C8D28 031865CE A8A90885 [.....<.(..e.....]
D/0003D0: 3D8D2903 65CFB025 C4CA48E5 CB68B01D [=.).e..%..H..h..]
D/0003E0: 843E853F C8D00269 01844A85 4B84CC85 [.>.?...i..J.K...]
D/0003F0: CD20FAFC A9032002 FFAE2303 604C6BE3 [..........#.`Lk.]
D/000400: 2089F6B0 3334F400 2089F618 4C006838 [....34......L.h8]
D/000410: 19CE00C9 3536213B 3CC93739 29D80346 [....56!;<.79)..F]
D/000420: 3A26E0D7 03384AA9 396AD302 2AD40202 [:&...8J.9j..*...]
D/000430: 07307600 A501A600 201BE5A9 AD20EDFD [.0v.............]
D/000440: A9BE20ED FDA517A6 16201BE5 208EFD20 [................]
D/000450: 8CF62B3C A23B0DD1 02C2004C 68EE004C [..+<.;.....Lh..L]
D/000460: 6BE3ECDC 02F419B0 001AC000 27D80363 [k...........'..c]
D/000470: E7673D25 3B211C2C A23C2BB6 03076BBD [.g=%;!.,.<+...k.]
D/000480: 07F5C72C 771B2800 1C67FC08 E547D902 [...,w.(..g...G..]
D/000490: 09DA02F5 F76705FC F747DB06 F71C5D00 [.....g...G....].]
D/0004A0: DC06F108 13FDFD06 0F1D2400 DD0609F0 [..........$.....]
D/0004B0: 06BA1D74 00BD0901 B03C01D1 2089F61C [...t.....<......]
D/0004C0: 4E00CC38 19CA0069 7C0020DF F02089F6 [N..8...i|.......]
D/0004D0: CC287C00 60A9DCA0 D44CB0D5 A434B900 [.(|.`....L...4..]
D/0004E0: 02C9AAD0 0CE634A2 07B53C95 02CA10F9 [......4...<.....]
D/0004F0: 60A002B1 3C990B00 8810F820 8EF8A62F [`...<........../]
D/000500: CAD00CA5 0B290DF0 142908D0 10850D20 [.....)...)......]
D/000510: 89F622D6 020626B1 0202A436 00A200B5 [.."...&....6....]
D/000520: 0B9142E8 20B4FCC6 2F10F490 C460A954 [..B...../....`.T]
D/000530: A0D54CB0 D586D838 A2FFB54D F5CB95CF [..L....8...M....]
D/000540: E8F0F720 1EF12054 D5A20120 2CF12054 [.......T....,..T]
D/000550: D5A6D860 20FAFCA9 1620C9FC 852E20FA [...`............]
D/000560: FCA02420 FDFCB0F9 20FDFCA0 3B20ECFC [..$.........;...]
D/000570: F00E452E 852E20BA FCA03490 F04C26FF [..E.......4..L&.]
D/000580: EAEAEAC1 3CF0EB48 202DFF20 92FDB13C [....<..H.-.....<]
D/000590: 20DAFDA9 A020EDFD A9A820ED FD6820DA [.............h..]
D/0005A0: FDA9A920 EDFDA98D 4CEDFDA9 8D4CEDFD [........L....L..]
D/0005B0: 8DF9038C FA03A94C 8DF80360 A9C3A0D5 [.......L...`....]
D/0005C0: 4CB0D5A9 0020D0D5 A9FF20D0 D54C3AFF [L............L:.]
D/0005D0: 850049FF 8501A53D 85078509 850BA000 [..I....=........]
D/0005E0: 84068408 840AA63E A5009108 C8D0FBE6 [.......>........]
D/0005F0: 09CAD0F6 A63EB106 C500F013 48A50720 [.....>......H...]
D/000600: DAFD9820 8AD6A500 208AD668 2092D6C8 [...........h....]
D/000610: D0E4E607 CAD0DFA6 3EA50191 0A840D84 [........>.......]
D/000620: 0CE60CA5 012045D6 A5002045 D6060C26 [......E....E...&]
D/000630: 0DA50DC5 3E90ECA5 00910AE6 0AD0DAE6 [....>...........]
D/000640: 0BCAD0D5 608502A5 0A450C85 08A50B45 [....`....E.....E]
D/000650: 0D8509A5 029108B1 0AC501F0 E748A50B [.............H..]
D/000660: 20DAFDA5 0A208AD6 A501910A 208AD668 [...............h]
D/000670: 4CCB02A5 0920DAFD A508208A D6A50220 [L...............]
D/000680: 8AD6202D FFA98D4C EDFD20DA FDA9A04C [...-...L.......L]
D/000690: EDFD840F 850E208A D6202DFF A500450E [..........-...E.]
D/0006A0: 850EA007 460E9023 A9A020ED FDA53DC9 [....F..#......=.]
D/0006B0: 50A9C469 0020EDFD A9AD20ED FD98D005 [P..i............]
D/0006C0: A9B120ED FDB9D3D6 20EDFD88 10D6A40F [................]
D/0006D0: 4C85D6B0 B9B8B7B6 B5B4B3B2 B1A00084 [L...............]
D/0006E0: 06840788 98D00EA0 1A200ED7 85068407 [................]
D/0006F0: A021200E D7850884 09A00820 0ED78502 [.!..............]
D/000700: 8403A011 200ED785 0484054C 08D4B14A [...........L...J]
D/000710: 48C8B14A A868604C 4ED7A401 AD30C0E6 [H..J.h`LN....0..]
D/000720: 02D005E6 03D00560 EA4C2CD7 88F0054C [.......`.L,....L]
D/000730: 32D7D0EB A400AD30 C0E602D0 05E603D0 [2......0........]
D/000740: 0560EA4C 46D788F0 D14C4CD7 D0EBADFF [.`.LF....LL.....]
D/000750: 020AA8B9 96D78500 ADFD024A F0044600 [...........J..F.]
D/000760: D0F9B996 D738E500 8501C8B9 96D76500 [.....8........e.]
D/000770: 8500A900 38EDFE02 8503A900 8502A501 [....8...........]
D/000780: D098EAEA 4C87D7E6 02D005E6 03D00560 [....L..........`]
D/000790: EA4C94D7 D0EC0000 F6F6E8E8 DBDBCFCF [.L..............]
D/0007A0: C3C3B8B8 AEAEA4A4 9B9B9292 8A8A8282 [................]
D/0007B0: 7B7B7474 6D6E6768 61625C5C 57575252 [{{ttmnghab\\WWRR]
D/0007C0: 4D4E4949 45454141 3D3E3A3A 36373334 [MNIIEEAA=>::6734]
D/0007D0: 30312E2E 2B2C2929 26272425 22232021 [01..+,))&'$%"#.!]
D/0007E0: 1E1F1D1D 1B1C1A1A 18191717 15161415 [................]
D/0007F0: 13141212 11111010 0F100E0F FFFFFFFF [................]
D/000800: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000810: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000820: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000830: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000840: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000850: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000860: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000870: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000880: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000890: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0008A0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0008B0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0008C0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0008D0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0008E0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0008F0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000900: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000910: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000920: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000930: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000940: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000950: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000960: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000970: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000980: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000990: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0009A0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0009B0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0009C0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0009D0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0009E0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/0009F0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A00: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A10: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A20: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A30: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A40: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A50: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A60: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A70: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A80: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000A90: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000AA0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000AB0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000AC0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000AD0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000AE0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000AF0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B00: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B10: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B20: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B30: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B40: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B50: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B60: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B70: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B80: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000B90: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000BA0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000BB0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000BC0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000BD0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000BE0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000BF0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C00: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C10: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C20: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C30: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C40: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C50: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C60: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C70: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C80: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000C90: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000CA0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000CB0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000CC0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000CD0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000CE0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000CF0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D00: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D10: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D20: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D30: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D40: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D50: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D60: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D70: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D80: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000D90: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000DA0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000DB0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000DC0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000DD0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000DE0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000DF0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E00: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E10: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E20: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E30: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E40: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E50: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E60: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E70: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E80: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000E90: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000EA0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000EB0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000EC0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000ED0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000EE0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000EF0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F00: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F10: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F20: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F30: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F40: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F50: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F60: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F70: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F80: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000F90: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000FA0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000FB0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000FC0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000FD0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000FE0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/000FF0: FFFFFFFF FFFFFFFF FFFFFFFF FFFFFFFF [................]
D/001000: 2000F04C B3E28533 4CEDFD60 8A2920F0 [...L...3L..`.)..]
D/001010: 23A9A085 E44CEDFD A920C524 B00CA98D [#....L.....$....]
D/001020: A00720ED FDA9A088 D0F8A000 B1E2E6E2 [................]
D/001030: D002E6E3 602015E7 2076E5A5 E2C5E6A5 [....`....v......]
D/001040: E3E5E7B0 EF206DE0 4C3BE0A5 CA85E2A5 [......m.L;......]
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D/002C40: D0E9A424 A5254820 24FC209E FCA00068 [...$.%H.$......h]
D/002C50: 6900C523 90F0B0CA A5228525 A0008424 [i..#.....".%...$]
D/002C60: F0E4A900 8524E625 A525C523 90B6C625 [.....$.%.%.#...%]
D/002C70: A5224820 24FCA528 852AA529 852BA421 [."H.$..(.*.).+.!]
D/002C80: 88686901 C523B00D 482024FC B128912A [.hi..#..H.$..(.*]
D/002C90: 8810F930 E1A00020 9EFCB086 A424A9A0 [...0.........$..]
D/002CA0: 9128C8C4 2190F960 3848E901 D0FC68E9 [.(..!..`8H....h.]
D/002CB0: 01D0F660 E642D002 E643A53C C53EA53D [...`.B...C.<.>.=]
D/002CC0: E53FE63C D002E63D 60A04B20 DBFCD0F9 [.?.<...=`.K.....]
D/002CD0: 69FEB0F5 A02120DB FCC8C888 D0FD9005 [i....!..........]
D/002CE0: A03288D0 FDAC20C0 A02CCA60 A2084820 [.2.......,.`..H.]
D/002CF0: FAFC682A A03ACAD0 F56020FD FC88AD60 [..h*.:...`.....`]
D/002D00: C0452F10 F8452F85 2FC08060 A424B128 [.E/..E/./..`.$.(]
D/002D10: 48293F09 40912868 6C3800E6 4ED002E6 [H)?.@.(hl8..N...]
D/002D20: 4F2C00C0 10F59128 AD00C02C 10C06020 [O,.....(...,..`.]
D/002D30: 0CFD202C FC200CFD C99BF0F3 60A53248 [...,........`.2H]
D/002D40: A9FF8532 BD000220 EDFD6885 32BD0002 [...2......h.2...]
D/002D50: C988F01D C998F00A E0F89003 203AFFE8 [.............:..]
D/002D60: D013A9DC 20EDFD20 8EFDA533 20EDFDA2 [...........3....]
D/002D70: 018AF0F3 CA2035FD C995D002 B128C9E0 [......5......(..]
D/002D80: 900229DF 9D0002C9 8DD0B220 9CFCA98D [..).............]
D/002D90: D05BA43D A63C208E FD2040F9 A000A9AD [.[.=.<....@.....]
D/002DA0: 4CEDFDA5 3C090785 3EA53D85 3FA53C29 [L...<...>.=.?.<)]
D/002DB0: 07D00320 92FDA9A0 20EDFDB1 3C20DAFD [............<...]
D/002DC0: 20BAFC90 E8604A90 EA4A4AA5 3E900249 [.....`J..JJ.>..I]
D/002DD0: FF653C48 A9BD20ED FD68484A 4A4A4A20 [.e<H.....hHJJJJ.]
D/002DE0: E5FD6829 0F09B0C9 BA900269 066C3600 [..h).......i.l6.]
D/002DF0: C9A09002 25328435 4820FDFB 68A43560 [....%2.5H...h.5`]
D/002E00: C634F09F CAD016C9 BAD0BB85 31A53E91 [.4..........1.>.]
D/002E10: 40E640D0 02E64160 A434B9FF 01853160 [@.@...A`.4....1`]
D/002E20: A201B53E 95429544 CA10F760 B13C9142 [...>.B.D...`.<.B]
D/002E30: 20B4FC90 F760B13C D142F01C 2092FDB1 [.....`.<.B......]
D/002E40: 3C20DAFD A9A020ED FDA9A820 EDFDB142 [<..............B]
D/002E50: 20DAFDA9 A920EDFD 20B4FC90 D9602075 [.............`.u]
D/002E60: FEA91448 20D0F820 53F9853A 843B6838 [...H....S..:.;h8]
D/002E70: E901D0EF 608AF007 B53C953A CA10F960 [....`....<.:...`]
D/002E80: A03FD002 A0FF8432 60A90085 3EA238A0 [.?.....2`...>.8.]
D/002E90: 1BD008A9 00853EA2 36A0F0A5 3E290FF0 [......>.6...>)..]
D/002EA0: 0609C0A0 00F002A9 FD940095 0160EAEA [.............`..]
D/002EB0: 4C00E04C 03E02075 FE203FFF 6C3A004C [L..L...u..?.l:.L]
D/002EC0: D7FAC634 2075FE4C 43FA4CF8 03A94020 [...4.u.LC.L...@.]
D/002ED0: C9FCA027 A200413C 48A13C20 EDFE20BA [...'..A<H.<.....]
D/002EE0: FCA01D68 90EEA022 20EDFEF0 4DA2100A [...h..."....M...]
D/002EF0: 20D6FCD0 FA602000 FE6868D0 6C20FAFC [.....`...hh.l...]
D/002F00: A91620C9 FC852E20 FAFCA024 20FDFCB0 [...........$....]
D/002F10: F920FDFC A03B20EC FC813C45 2E852E20 [.....;....<E....]
D/002F20: BAFCA035 90F020EC FCC52EF0 0DA9C520 [...5............]
D/002F30: EDFDA9D2 20EDFD20 EDFDA987 4CEDFDA5 [............L...]
D/002F40: 4848A545 A646A447 28608545 86468447 [HH.E.F.G(`.E.F.G]
D/002F50: 08688548 BA8649D8 602084FE 202FFB20 [.h.H..I.`..../..]
D/002F60: 93FE2089 FED8203A FFA9AA85 332067FD [.......:....3.g.]
D/002F70: 20C7FF20 A7FF8434 A0178830 E8D9CCFF [.......4...0....]
D/002F80: D0F820BE FFA4344C 73FFA203 0A0A0A0A [......4Ls.......]
D/002F90: 0A263E26 3FCA10F8 A531D006 B53F953D [.&>&?....1...?.=]
D/002FA0: 9541E8F0 F3D006A2 00863E86 3FB90002 [.A........>.?...]
D/002FB0: C849B0C9 0A90D369 88C9FAB0 CD60A9FE [.I.....i.....`..]
D/002FC0: 48B9E3FF 48A531A0 00843160 BCB2BEED [H...H.1...1`....]
D/002FD0: EFC4ECA9 BBA6A406 95070205 F000EB93 [................]
D/002FE0: A7C699B2 C9BEC135 8CC396AF 17172B1F [.......5......+.]
D/002FF0: 837F5DCC B5FC1717 F503FB03 59FF86FA [..].........Y...]

Brought to you by:

dtcdumpfile 1.0.0 (Apple Macintosh File Hex Dumper) Sunday, July 6, 1997



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Memory map of the Apple II ROMs 
+------------------------------------------------------------------------

Memory map of the Apple II ROMs

*	$F800-$FFFF

Monitor. Handles screen I/O and keyboard input. Also has a disassembler, memory dump, memory move, memory compare, step and trace functions, lo-res graphics routines, multiply and divide routines, and more. This monitor has the cleanest code of all the Apple II monitors. Every one after this had to patch the monitor to add functions while still remaining (mostly) compatible. Complete source code is in the manual. 

* $F689-F7FC

Sweet-16 interpreter. Sweet-16 code has been benchmarked to be about half the size of pure 6502 code but 5-8 times slower. The renumber routine in the Programmer's Aid #1 is written in Sweet-16, where small size was much more important than speed. Complete source code is in the manual.
 
* $F500-F63C and $F666-F668

Mini-assembler. This lets you type in assembly code, one line at a time, and it will assemble the proper bytes. No labels or equates are supported--it is a MINI assembler. Complete source code is in the manual. 

* $F425-F4FB and $F63D-F65D

Floating point routines. Woz's first plans for his 6502 BASIC included floating point, but he abandoned them when he realized he could finish faster by going integer only. He put these routines in the ROMs but they are not called from anywhere. Complete source code is in the manual. 

* $E000-F424

Integer BASIC by Woz (Steve Wozniak, creator of the Apple II). "That BASIC, which we shipped with the first Apple II's, was never assembled--ever. There was one handwritten copy, all handwritten, all hand assembled." Woz, October 1984. 

* $D800-DFFF

Empty ROM socket. There was at least one third party ROM add-on. 

* $D000-D7FF

Programmer's Aid #1--missing from the original Apple II, this is a ROM add-on Apple sold that contains Integer BASIC utilities such as high-resolution graphics support, renumber, append, tape verify, music, and a RAM test. Complete source code is in the manual. 



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Summary of Monitor Commands 
+------------------------------------------------------------------------

Summary of Apple II Monitor Commands

Examining Memory.

*	{adrs}
Examines the value contained in one location. 
*	{adrs1}.{adrs2}
Displays the values contained in all locations between {adrs1} and {adrs2}. 
*	[RETURN]
Displays the values in up to eight locations following the last opened location. 

Changing the Contents of Memory.


*	{adrs}:{val} {val} ...
Stores the values in consecutive memory locations starting at {adrs}. 
*	:{val} {val}
Stores values in memory starting at the next changeable location. 

Moving and Comparing.

*	{dest}<{start}.{end}M
Copies the values in the range {start}.{end} into the range beginning at {dest}. (M=move) 
*	{dest}<{start}.{end}V
Compares the values in the range {start}.{end} to those in the range beginning at {dest}. (V=verify) 

Saving and Loading via Cassette Tape.

*	{start}.{end}W
Writes the values in the memory range {start}.{end} onto tape, preceded by a ten-second leader. 
*	{start}.{end}R
Reads values from tape, storing them in memory beginning at {start} and stopping at {end}. Prints "ERR" if an error occurs. 

Running and Listing Programs.

*	{adrs}G
Transfers control to the machine language program beginning at {adrs}. (G=go) 
*	{adrs}L
Disassembles and displays 20 instructions, starting at {adrs}. Subsequent L's will display 20 more instructions each. (L=list) 

Miscellaneous.

*	{adrs}S
Disassemble, display, and execute the instruction at {adrs}, and display the contents of the 6502's internal registers. Subsequent S's will display and execute successive instructions. (S=step) 
*	{adrs}T
Step infinitely. The TRACE command stops only when it executes a BRK instruction or when you press RESET. (T=trace) 
*	Contrl-E
Displays the contents of the 6502's registers. (E=examine) 
*	I
Set Inverse display mode. 
*	N
Set Normal display mode. Also useful as a delimiter for putting multiple commands on one line. 
*	Control-B
Enter the language currently installed in the Apple's ROM (cold start at $E000). 
*	Control-C
Reenter the language currently installed in the Apple's ROM (warm start at $E003). 
*	{val1}+{val2}
Add the two values and print the result. 
*	{val2}-{val1}
Subtract the second value from the first and print the result. 
*	{slot} Control-P
Divert output to the device whose interface card in in slot number {slot}. If {slot}=0, then route output to the Apple's screen. 
*	{slot} Control-K
Accept input from the device whose interface card is in slot number {slot}. If {slot}=0, then accept input from the Apple's keyboard. 
*	Control-Y
Jump to the machine language subroutine at location $03F8. This lets you add your own commands to the Monitor. 

The Mini-Assembler.

*	F666G
Invoke the Mini-Assembler. 
*	${command}
Execute a Monitor command from the Mini-Assembler. 
*	FF69G
Leave the Mini-Assembler. 



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Red Book Monitor listing 
+------------------------------------------------------------------------

                1    ***************************
                2    *                         *
                3    *        APPLE II         *
                4    *     SYSTEM MONITOR      *
                5    *                         *
                6    *    COPYRIGHT 1977 BY    *
                7    *   APPLE COMPUTER, INC.  *
                8    *                         *
                9    *   ALL RIGHTS RESERVED   *
                10   *                         *
                11   *       S. WOZNIAK        *
                12   *        A. BAUM          *
                13   *                         *
                14   ***************************
                15                             ; TITLE "APPLE II SYSTEM MONITOR"
                16   LOC0     EQU   $00
                17   LOC1     EQU   $01
                18   WNDLFT   EQU   $20
                19   WNDWDTH  EQU   $21
                20   WNDTOP   EQU   $22
                21   WNDBTM   EQU   $23
                22   CH       EQU   $24
                23   CV       EQU   $25
                24   GBASL    EQU   $26
                25   GBASH    EQU   $27
                26   BASL     EQU   $28
                27   BASH     EQU   $29
                28   BAS2L    EQU   $2A
                29   BAS2H    EQU   $2B
                30   H2       EQU   $2C
                31   LMNEM    EQU   $2C
                32   RTNL     EQU   $2C
                33   V2       EQU   $2D
                34   RMNEM    EQU   $2D
                35   RTNH     EQU   $2D
                36   MASK     EQU   $2E
                37   CHKSUM   EQU   $2E
                38   FORMAT   EQU   $2E
                39   LASTIN   EQU   $2F
                40   LENGTH   EQU   $2F
                41   SIGN     EQU   $2F
                42   COLOR    EQU   $30
                43   MODE     EQU   $31
                44   INVFLG   EQU   $32
                45   PROMPT   EQU   $33
                46   YSAV     EQU   $34
                47   YSAV1    EQU   $35
                48   CSWL     EQU   $36
                49   CSWH     EQU   $37
                50   KSWL     EQU   $38
                51   KSWH     EQU   $39
                52   PCL      EQU   $3A
                53   PCH      EQU   $3B
                54   XQT      EQU   $3C
                55   A1L      EQU   $3C
                56   A1H      EQU   $3D
                57   A2L      EQU   $3E
                58   A2H      EQU   $3F
                59   A3L      EQU   $40
                60   A3H      EQU   $41
                61   A4L      EQU   $42
                62   A4H      EQU   $43
                63   A5L      EQU   $44
                64   A5H      EQU   $45
                65   ACC      EQU   $45
                66   XREG     EQU   $46
                67   YREG     EQU   $47
                68   STATUS   EQU   $48
                69   SPNT     EQU   $49
                70   RNDL     EQU   $4E
                71   RNDH     EQU   $4F
                72   ACL      EQU   $50
                73   ACH      EQU   $51
                74   XTNDL    EQU   $52
                75   XTNDH    EQU   $53
                76   AUXL     EQU   $54
                77   AUXH     EQU   $55
                78   PICK     EQU   $95
                79   IN       EQU   $0200
                80   USRADR   EQU   $03F8
                81   NMI      EQU   $03FB
                82   IRQLOC   EQU   $03FE
                83   IOADR    EQU   $C000
                84   KBD      EQU   $C000
                85   KBDSTRB  EQU   $C010
                86   TAPEOUT  EQU   $C020
                87   SPKR     EQU   $C030
                88   TXTCLR   EQU   $C050
                89   TXTSET   EQU   $C051
                90   MIXCLR   EQU   $C052
                91   MIXSET   EQU   $C053
                92   LOWSCR   EQU   $C054
                93   HISCR    EQU   $C055
                94   LORES    EQU   $C056
                95   HIRES    EQU   $C057
                96   TAPEIN   EQU   $C060
                97   PADDL0   EQU   $C064
                98   PTRIG    EQU   $C070
                99   BASIC    EQU   $E000
                100  BASIC2   EQU   $E003
                101           ORG   $F800      ;ROM START ADDRESS
F800: 4A        102  PLOT     LSR              ;Y-COORD/2
F801: 08        103           PHP              ;SAVE LSB IN CARRY
F802: 20 47 F8  104           JSR   GBASCALC   ;CALC BASE ADR IN GBASL,H
F805: 28        105           PLP              ;RESTORE LSB FROM CARRY
F806: A9 0F     106           LDA   #$0F       ;MASK $0F IF EVEN
F808: 90 02     107           BCC   RTMASK
F80A: 69 E0     108           ADC   #$E0       ;MASK $F0 IF ODD
F80C: 85 2E     109  RTMASK   STA   MASK
F80E: B1 26     110  PLOT1    LDA   (GBASL),Y  ;DATA
F810: 45 30     111           EOR   COLOR      ; EOR COLOR
F812: 25 2E     112           AND   MASK       ;  AND MASK
F814: 51 26     113           EOR   (GBASL),Y  ;   EOR DATA
F816: 91 26     114           STA   (GBASL),Y  ;    TO DATA
F818: 60        115           RTS
F819: 20 00 F8  116  HLINE    JSR   PLOT       ;PLOT SQUARE
F81C: C4 2C     117  HLINE1   CPY   H2         ;DONE?
F81E: B0 11     118           BCS   RTS1       ; YES, RETURN
F820: C8        119           INY              ; NO, INC INDEX (X-COORD)
F821: 20 0E F8  120           JSR   PLOT1      ;PLOT NEXT SQUARE
F824: 90 F6     121           BCC   HLINE1     ;ALWAYS TAKEN
F826: 69 01     122  VLINEZ   ADC   #$01       ;NEXT Y-COORD
F828: 48        123  VLINE    PHA              ; SAVE ON STACK
F829: 20 00 F8  124           JSR   PLOT       ; PLOT SQUARE
F82C: 68        125           PLA
F82D: C5 2D     126           CMP   V2         ;DONE?
F82F: 90 F5     127           BCC   VLINEZ     ; NO, LOOP
F831: 60        128  RTS1     RTS
F832: A0 2F     129  CLRSCR   LDY   #$2F       ;MAX Y, FULL SCRN CLR
F834: D0 02     130           BNE   CLRSC2     ;ALWAYS TAKEN
F836: A0 27     131  CLRTOP   LDY   #$27       ;MAX Y, TOP SCREEN CLR
F838: 84 2D     132  CLRSC2   STY   V2         ;STORE AS BOTTOM COORD
                133                            ; FOR VLINE CALLS
F83A: A0 27     134           LDY   #$27       ;RIGHTMOST X-COORD (COLUMN)
F83C: A9 00     135  CLRSC3   LDA   #$00       ;TOP COORD FOR VLINE CALLS
F83E: 85 30     136           STA   COLOR      ;CLEAR COLOR (BLACK)
F840: 20 28 F8  137           JSR   VLINE      ;DRAW VLINE
F843: 88        138           DEY              ;NEXT LEFTMOST X-COORD
F844: 10 F6     139           BPL   CLRSC3     ;LOOP UNTIL DONE
F846: 60        140           RTS
F847: 48        141  GBASCALC PHA              ;FOR INPUT 000DEFGH
F848: 4A        142           LSR
F849: 29 03     143           AND   #$03
F84B: 09 04     144           ORA   #$04       ;  GENERATE GBASH=000001FG
F84D: 85 27     145           STA   GBASH
F84F: 68        146           PLA              ;  AND GBASL=HDEDE000
F850: 29 18     147           AND   #$18
F852: 90 02     148           BCC   GBCALC
F854: 69 7F     149           ADC   #$7F
F856: 85 26     150  GBCALC   STA   GBASL
F858: 0A        151           ASL
F859: 0A        152           ASL
F85A: 05 26     153           ORA   GBASL
F85C: 85 26     154           STA   GBASL
F85E: 60        155           RTS
F85F: A5 30     156  NXTCOL   LDA   COLOR      ;INCREMENT COLOR BY 3
F861: 18        157           CLC
F862: 69 03     158           ADC   #$03
F864: 29 0F     159  SETCOL   AND   #$0F       ;SETS COLOR=17*A MOD 16
F866: 85 30     160           STA   COLOR
F868: 0A        161           ASL              ;BOTH HALF BYTES OF COLOR EQUAL
F869: 0A        162           ASL
F86A: 0A        163           ASL
F86B: 0A        164           ASL
F86C: 05 30     165           ORA   COLOR
F86E: 85 30     166           STA   COLOR
F870: 60        167           RTS
F871: 4A        168  SCRN     LSR              ;READ SCREEN Y-COORD/2
F872: 08        169           PHP              ;SAVE LSB (CARRY)
F873: 20 47 F8  170           JSR   GBASCALC   ;CALC BASE ADDRESS
F876: B1 26     171           LDA   (GBASL),Y  ;GET BYTE
F878: 28        172           PLP              ;RESTORE LSB FROM CARRY
F879: 90 04     173  SCRN2    BCC   RTMSKZ     ;IF EVEN, USE LO H
F87B: 4A        174           LSR
F87C: 4A        175           LSR
F87D: 4A        176           LSR              ;SHIFT HIGH HALF BYTE DOWN
F87E: 4A        177           LSR
F87F: 29 0F     178  RTMSKZ   AND   #$0F       ;MASK 4-BITS
F881: 60        179           RTS
F882: A6 3A     180  INSDS1   LDX   PCL        ;PRINT PCL,H
F884: A4 3B     181           LDY   PCH
F886: 20 96 FD  182           JSR   PRYX2
F889: 20 48 F9  183           JSR   PRBLNK     ;FOLLOWED BY A BLANK
F88C: A1 3A     184           LDA   (PCL,X)    ;GET OP CODE
F88E: A8        185  INSDS2   TAY
F88F: 4A        186           LSR              ;EVEN/ODD TEST
F890: 90 09     187           BCC   IEVEN
F892: 6A        188           ROR              ;BIT 1 TEST
F893: B0 10     189           BCS   ERR        ;XXXXXX11 INVALID OP
F895: C9 A2     190           CMP   #$A2
F897: F0 0C     191           BEQ   ERR        ;OPCODE $89 INVALID
F899: 29 87     192           AND   #$87       ;MASK BITS
F89B: 4A        193  IEVEN    LSR              ;LSB INTO CARRY FOR L/R TEST
F89C: AA        194           TAX
F89D: BD 62 F9  195           LDA   FMT1,X     ;GET FORMAT INDEX BYTE
F8A0: 20 79 F8  196           JSR   SCRN2      ;R/L H-BYTE ON CARRY
F8A3: D0 04     197           BNE   GETFMT
F8A5: A0 80     198  ERR      LDY   #$80       ;SUBSTITUTE $80 FOR INVALID OPS
F8A7: A9 00     199           LDA   #$00       ;SET PRINT FORMAT INDEX TO 0
F8A9: AA        200  GETFMT   TAX
F8AA: BD A6 F9  201           LDA   FMT2,X     ;INDEX INTO PRINT FORMAT TABLE
F8AD: 85 2E     202           STA   FORMAT     ;SAVE FOR ADR FIELD FORMATTING
F8AF: 29 03     203           AND   #$03       ;MASK FOR 2-BIT LENGTH
                204                            ; (P=1 BYTE, 1=2 BYTE, 2=3 BYTE)
F8B1: 85 2F     205           STA   LENGTH
F8B3: 98        206           TYA              ;OPCODE
F8B4: 29 8F     207           AND   #$8F       ;MASK FOR 1XXX1010 TEST
F8B6: AA        208           TAX              ; SAVE IT
F8B7: 98        209           TYA              ;OPCODE TO A AGAIN
F8B8: A0 03     210           LDY   #$03
F8BA: E0 8A     211           CPX   #$8A
F8BC: F0 0B     212           BEQ   MNNDX3
F8BE: 4A        213  MNNDX1   LSR
F8BF: 90 08     214           BCC   MNNDX3     ;FORM INDEX INTO MNEMONIC TABLE
F8C1: 4A        215           LSR
F8C2: 4A        216  MNNDX2   LSR              ;1) 1XXX1010->00101XXX
F8C3: 09 20     217           ORA   #$20       ;2) XXXYYY01->00111XXX
F8C5: 88        218           DEY              ;3) XXXYYY10->00110XXX
F8C6: D0 FA     219           BNE   MNNDX2     ;4) XXXYY100->00100XXX
F8C8: C8        220           INY              ;5) XXXXX000->000XXXXX
F8C9: 88        221  MNNDX3   DEY
F8CA: D0 F2     222           BNE   MNNDX1
F8CC: 60        223           RTS
F8CD: FF FF FF  224           DFB   $FF,$FF,$FF
F8D0: 20 82 F8  225  INSTDSP  JSR   INSDS1     ;GEN FMT, LEN BYTES
F8D3: 48        226           PHA              ;SAVE MNEMONIC TABLE INDEX
F8D4: B1 3A     227  PRNTOP   LDA   (PCL),Y
F8D6: 20 DA FD  228           JSR   PRBYTE
F8D9: A2 01     229           LDX   #$01       ;PRINT 2 BLANKS
F8DB: 20 4A F9  230  PRNTBL   JSR   PRBL2
F8DE: C4 2F     231           CPY   LENGTH     ;PRINT INST (1-3 BYTES)
F8E0: C8        232           INY              ;IN A 12 CHR FIELD
F8E1: 90 F1     233           BCC   PRNTOP
F8E3: A2 03     234           LDX   #$03       ;CHAR COUNT FOR MNEMONIC PRINT
F8E5: C0 04     235           CPY   #$04
F8E7: 90 F2     236           BCC   PRNTBL
F8E9: 68        237           PLA              ;RECOVER MNEMONIC INDEX
F8EA: A8        238           TAY
F8EB: B9 C0 F9  239           LDA   MNEML,Y
F8EE: 85 2C     240           STA   LMNEM      ;FETCH 3-CHAR MNEMONIC
F8F0: B9 00 FA  241           LDA   MNEMR,Y    ;  (PACKED IN 2-BYTES)
F8F3: 85 2D     242           STA   RMNEM
F8F5: A9 00     243  PRMN1    LDA   #$00
F8F7: A0 05     244           LDY   #$05
F8F9: 06 2D     245  PRMN2    ASL   RMNEM      ;SHIFT 5 BITS OF
F8FB: 26 2C     246           ROL   LMNEM      ;  CHARACTER INTO A
F8FD: 2A        247           ROL              ;    (CLEARS CARRY)
F8FE: 88        248           DEY
F8FF: D0 F8     249           BNE   PRMN2
F901: 69 BF     250           ADC   #$BF       ;ADD "?" OFFSET
F903: 20 ED FD  251           JSR   COUT       ;OUTPUT A CHAR OF MNEM
F906: CA        252           DEX
F907: D0 EC     253           BNE   PRMN1
F909: 20 48 F9  254           JSR   PRBLNK     ;OUTPUT 3 BLANKS
F90C: A4 2F     255           LDY   LENGTH
F90E: A2 06     256           LDX   #$06       ;CNT FOR 6 FORMAT BITS
F910: E0 03     257  PRADR1   CPX   #$03
F912: F0 1C     258           BEQ   PRADR5     ;IF X=3 THEN ADDR.
F914: 06 2E     259  PRADR2   ASL   FORMAT
F916: 90 0E     260           BCC   PRADR3
F918: BD B3 F9  261           LDA   CHAR1-1,X
F91B: 20 ED FD  262           JSR   COUT
F91E: BD B9 F9  263           LDA   CHAR2-1,X
F921: F0 03     264           BEQ   PRADR3
F923: 20 ED FD  265           JSR   COUT
F926: CA        266  PRADR3   DEX
F927: D0 E7     267           BNE   PRADR1
F929: 60        268           RTS
F92A: 88        269  PRADR4   DEY
F92B: 30 E7     270           BMI   PRADR2
F92D: 20 DA FD  271           JSR   PRBYTE
F930: A5 2E     272  PRADR5   LDA   FORMAT
F932: C9 E8     273           CMP   #$E8       ;HANDLE REL ADR MODE
F934: B1 3A     274           LDA   (PCL),Y    ;SPECIAL (PRINT TARGET,
F936: 90 F2     275           BCC   PRADR4     ;  NOT OFFSET)
F938: 20 56 F9  276  RELADR   JSR   PCADJ3
F93B: AA        277           TAX              ;PCL,PCH+OFFSET+1 TO A,Y
F93C: E8        278           INX
F93D: D0 01     279           BNE   PRNTYX     ;+1 TO Y,X
F93F: C8        280           INY
F940: 98        281  PRNTYX   TYA
F941: 20 DA FD  282  PRNTAX   JSR   PRBYTE     ;OUTPUT TARGET ADR
F944: 8A        283  PRNTX    TXA              ;  OF BRANCH AND RETURN
F945: 4C DA FD  284           JMP   PRBYTE
F948: A2 03     285  PRBLNK   LDX   #$03       ;BLANK COUNT
F94A: A9 A0     286  PRBL2    LDA   #$A0       ;LOAD A SPACE
F94C: 20 ED FD  287  PRBL3    JSR   COUT       ;OUTPUT A BLANK
F94F: CA        288           DEX
F950: D0 F8     289           BNE   PRBL2      ;LOOP UNTIL COUNT=0
F952: 60        290           RTS
F953: 38        291  PCADJ    SEC              ;0=1-BYTE, 1=2-BYTE
F954: A5 2F     292  PCADJ2   LDA   LENGTH     ;  2=3-BYTE
F956: A4 3B     293  PCADJ3   LDY   PCH
F958: AA        294           TAX              ;TEST DISPLACEMENT SIGN
F959: 10 01     295           BPL   PCADJ4     ;  (FOR REL BRANCH)
F95B: 88        296           DEY              ;EXTEND NEG BY DEC PCH
F95C: 65 3A     297  PCADJ4   ADC   PCL
F95E: 90 01     298           BCC   RTS2       ;PCL+LENGTH(OR DISPL)+1 TO A
F960: C8        299           INY              ;  CARRY INTO Y (PCH)
F961: 60        300  RTS2     RTS
                301  * FMT1 BYTES:    XXXXXXY0 INSTRS
                302  * IF Y=0         THEN LEFT HALF BYTE
                303  * IF Y=1         THEN RIGHT HALF BYTE
                304  *                   (X=INDEX)
F962: 04 20 54  305  FMT1     DFB   $04,$20,$54,$30,$0D
F965: 30 0D
F967: 80 04 90  306           DFB   $80,$04,$90,$03,$22
F96A: 03 22
F96C: 54 33 0D  307           DFB   $54,$33,$0D,$80,$04
F96F: 80 04
F971: 90 04 20  308           DFB   $90,$04,$20,$54,$33
F974: 54 33
F976: 0D 80 04  309           DFB   $0D,$80,$04,$90,$04
F979: 90 04
F97B: 20 54 3B  310           DFB   $20,$54,$3B,$0D,$80
F97E: 0D 80
F980: 04 90 00  311           DFB   $04,$90,$00,$22,$44
F983: 22 44
F985: 33 0D C8  312           DFB   $33,$0D,$C8,$44,$00
F988: 44 00
F98A: 11 22 44  313           DFB   $11,$22,$44,$33,$0D
F98D: 33 0D
F98F: C8 44 A9  314           DFB   $C8,$44,$A9,$01,$22
F992: 01 22
F994: 44 33 0D  315           DFB   $44,$33,$0D,$80,$04
F997: 80 04
F999: 90 01 22  316           DFB   $90,$01,$22,$44,$33
F99C: 44 33
F99E: 0D 80 04  317           DFB   $0D,$80,$04,$90
F9A1: 90
F9A2: 26 31 87  318           DFB   $26,$31,$87,$9A ;$ZZXXXY01 INSTR'S
F9A5: 9A
F9A6: 00        319  FMT2     DFB   $00        ;ERR
F9A7: 21        320           DFB   $21        ;IMM
F9A8: 81        321           DFB   $81        ;Z-PAGE
F9A9: 82        322           DFB   $82        ;ABS
F9AA: 00        323           DFB   $00        ;IMPLIED
F9AB: 00        324           DFB   $00        ;ACCUMULATOR
F9AC: 59        325           DFB   $59        ;(ZPAG,X)
F9AD: 4D        326           DFB   $4D        ;(ZPAG),Y
F9AE: 91        327           DFB   $91        ;ZPAG,X
F9AF: 92        328           DFB   $92        ;ABS,X
F9B0: 86        329           DFB   $86        ;ABS,Y
F9B1: 4A        330           DFB   $4A        ;(ABS)
F9B2: 85        331           DFB   $85        ;ZPAG,Y
F9B3: 9D        332           DFB   $9D        ;RELATIVE
F9B4: AC A9 AC  333  CHAR1    ASC   ",),#($"
F9B7: A3 A8 A4
F9BA: D9 00 D8  334  CHAR2    DFB   $D9,$00,$D8,$A4,$A4,$00
F9BD: A4 A4 00
                335  *CHAR2: "Y",0,"X$$",0
                336  * MNEML IS OF FORM:
                337  *  (A) XXXXX000
                338  *  (B) XXXYY100
                339  *  (C) 1XXX1010
                340  *  (D) XXXYYY10
                341  *  (E) XXXYYY01
                342  *      (X=INDEX)
F9C0: 1C 8A 1C  343  MNEML    DFB   $1C,$8A,$1C,$23,$5D,$8B
F9C3: 23 5D 8B
F9C6: 1B A1 9D  344           DFB   $1B,$A1,$9D,$8A,$1D,$23
F9C9: 8A 1D 23
F9CC: 9D 8B 1D  345           DFB   $9D,$8B,$1D,$A1,$00,$29
F9CF: A1 00 29
F9D2: 19 AE 69  346           DFB   $19,$AE,$69,$A8,$19,$23
F9D5: A8 19 23
F9D8: 24 53 1B  347           DFB   $24,$53,$1B,$23,$24,$53
F9DB: 23 24 53
F9DE: 19 A1     348           DFB   $19,$A1    ;(A) FORMAT ABOVE
F9E0: 00 1A 5B  349           DFB   $00,$1A,$5B,$5B,$A5,$69
F9E3: 5B A5 69
F9E6: 24 24     350           DFB   $24,$24    ;(B) FORMAT
F9E8: AE AE A8  351           DFB   $AE,$AE,$A8,$AD,$29,$00
F9EB: AD 29 00
F9EE: 7C 00     352           DFB   $7C,$00    ;(C) FORMAT
F9F0: 15 9C 6D  353           DFB   $15,$9C,$6D,$9C,$A5,$69
F9F3: 9C A5 69
F9F6: 29 53     354           DFB   $29,$53    ;(D) FORMAT
F9F8: 84 13 34  355           DFB   $84,$13,$34,$11,$A5,$69
F9FB: 11 A5 69
F9FE: 23 A0     356           DFB   $23,$A0    ;(E) FORMAT
FA00: D8 62 5A  357  MNEMR    DFB   $D8,$62,$5A,$48,$26,$62
FA03: 48 26 62
FA06: 94 88 54  358           DFB   $94,$88,$54,$44,$C8,$54
FA09: 44 C8 54
FA0C: 68 44 E8  359           DFB   $68,$44,$E8,$94,$00,$B4
FA0F: 94 00 B4
FA12: 08 84 74  360           DFB   $08,$84,$74,$B4,$28,$6E
FA15: B4 28 6E
FA18: 74 F4 CC  361           DFB   $74,$F4,$CC,$4A,$72,$F2
FA1B: 4A 72 F2
FA1E: A4 8A     362           DFB   $A4,$8A    ;(A) FORMAT
FA20: 00 AA A2  363           DFB   $00,$AA,$A2,$A2,$74,$74
FA23: A2 74 74
FA26: 74 72     364           DFB   $74,$72    ;(B) FORMAT
FA28: 44 68 B2  365           DFB   $44,$68,$B2,$32,$B2,$00
FA2B: 32 B2 00
FA2E: 22 00     366           DFB   $22,$00    ;(C) FORMAT
FA30: 1A 1A 26  367           DFB   $1A,$1A,$26,$26,$72,$72
FA33: 26 72 72
FA36: 88 C8     368           DFB   $88,$C8    ;(D) FORMAT
FA38: C4 CA 26  369           DFB   $C4,$CA,$26,$48,$44,$44
FA3B: 48 44 44
FA3E: A2 C8     370           DFB   $A2,$C8    ;(E) FORMAT
FA40: FF FF FF  371           DFB   $FF,$FF,$FF
FA43: 20 D0 F8  372  STEP     JSR   INSTDSP    ;DISASSEMBLE ONE INST
FA46: 68        373           PLA              ;  AT (PCL,H)
FA47: 85 2C     374           STA   RTNL       ;ADJUST TO USER
FA49: 68        375           PLA              ;  STACK. SAVE
FA4A: 85 2D     376           STA   RTNH       ;  RTN ADR.
FA4C: A2 08     377           LDX   #$08
FA4E: BD 10 FB  378  XQINIT   LDA   INITBL-1,X ;INIT XEQ AREA
FA51: 95 3C     379           STA   XQT,X
FA53: CA        380           DEX
FA54: D0 F8     381           BNE   XQINIT
FA56: A1 3A     382           LDA   (PCL,X)    ;USER OPCODE BYTE
FA58: F0 42     383           BEQ   XBRK       ;SPECIAL IF BREAK
FA5A: A4 2F     384           LDY   LENGTH     ;LEN FROM DISASSEMBLY
FA5C: C9 20     385           CMP   #$20
FA5E: F0 59     386           BEQ   XJSR       ;HANDLE JSR, RTS, JMP,
FA60: C9 60     387           CMP   #$60       ;  JMP (), RTI SPECIAL
FA62: F0 45     388           BEQ   XRTS
FA64: C9 4C     389           CMP   #$4C
FA66: F0 5C     390           BEQ   XJMP
FA68: C9 6C     391           CMP   #$6C
FA6A: F0 59     392           BEQ   XJMPAT
FA6C: C9 40     393           CMP   #$40
FA6E: F0 35     394           BEQ   XRTI
FA70: 29 1F     395           AND   #$1F
FA72: 49 14     396           EOR   #$14
FA74: C9 04     397           CMP   #$04       ;COPY USER INST TO XEQ AREA
FA76: F0 02     398           BEQ   XQ2        ;  WITH TRAILING NOPS
FA78: B1 3A     399  XQ1      LDA   (PCL),Y    ;CHANGE REL BRANCH
FA7A: 99 3C 00  400  XQ2      STA   XQT,Y      ;  DISP TO 4 FOR
FA7D: 88        401           DEY              ;  JMP TO BRANCH OR
FA7E: 10 F8     402           BPL   XQ1        ;  NBRANCH FROM XEQ.
FA80: 20 3F FF  403           JSR   RESTORE    ;RESTORE USER REG CONTENTS.
FA83: 4C 3C 00  404           JMP   XQT        ;XEQ USER OP FROM RAM
FA86: 85 45     405  IRQ      STA   ACC        ;  (RETURN TO NBRANCH)
FA88: 68        406           PLA
FA89: 48        407           PHA              ;**IRQ HANDLER
FA8A: 0A        408           ASL
FA8B: 0A        409           ASL
FA8C: 0A        410           ASL
FA8D: 30 03     411           BMI   BREAK      ;TEST FOR BREAK
FA8F: 6C FE 03  412           JMP   (IRQLOC)   ;USER ROUTINE VECTOR IN RAM
FA92: 28        413  BREAK    PLP
FA93: 20 4C FF  414           JSR   SAV1       ;SAVE REG'S ON BREAK
FA96: 68        415           PLA              ;  INCLUDING PC
FA97: 85 3A     416           STA   PCL
FA99: 68        417           PLA
FA9A: 85 3B     418           STA   PCH
FA9C: 20 82 F8  419  XBRK     JSR   INSDS1     ;PRINT USER PC.
FA9F: 20 DA FA  420           JSR   RGDSP1     ;  AND REG'S
FAA2: 4C 65 FF  421           JMP   MON        ;GO TO MONITOR
FAA5: 18        422  XRTI     CLC
FAA6: 68        423           PLA              ;SIMULATE RTI BY EXPECTING
FAA7: 85 48     424           STA   STATUS     ;  STATUS FROM STACK, THEN RTS
FAA9: 68        425  XRTS     PLA              ;RTS SIMULATION
FAAA: 85 3A     426           STA   PCL        ;  EXTRACT PC FROM STACK
FAAC: 68        427           PLA              ;  AND UPDATE PC BY 1 (LEN=0)
FAAD: 85 3B     428  PCINC2   STA   PCH
FAAF: A5 2F     429  PCINC3   LDA   LENGTH     ;UPDATE PC BY LEN
FAB1: 20 56 F9  430           JSR   PCADJ3
FAB4: 84 3B     431           STY   PCH
FAB6: 18        432           CLC
FAB7: 90 14     433           BCC   NEWPCL
FAB9: 18        434  XJSR     CLC
FABA: 20 54 F9  435           JSR   PCADJ2     ;UPDATE PC AND PUSH
FABD: AA        436           TAX              ;  ONTO STACH FOR
FABE: 98        437           TYA              ;  JSR SIMULATE
FABF: 48        438           PHA
FAC0: 8A        439           TXA
FAC1: 48        440           PHA
FAC2: A0 02     441           LDY   #$02
FAC4: 18        442  XJMP     CLC
FAC5: B1 3A     443  XJMPAT   LDA   (PCL),Y
FAC7: AA        444           TAX              ;LOAD PC FOR JMP,
FAC8: 88        445           DEY              ;  (JMP) SIMULATE.
FAC9: B1 3A     446           LDA   (PCL),Y
FACB: 86 3B     447           STX   PCH
FACD: 85 3A     448  NEWPCL   STA   PCL
FACF: B0 F3     449           BCS   XJMP
FAD1: A5 2D     450  RTNJMP   LDA   RTNH
FAD3: 48        451           PHA
FAD4: A5 2C     452           LDA   RTNL
FAD6: 48        453           PHA
FAD7: 20 8E FD  454  REGDSP   JSR   CROUT      ;DISPLAY USER REG
FADA: A9 45     455  RGDSP1   LDA   #ACC       ;  CONTENTS WITH
FADC: 85 40     456           STA   A3L        ;  LABELS
FADE: A9 00     457           LDA   #ACC/256
FAE0: 85 41     458           STA   A3H
FAE2: A2 FB     459           LDX   #$FB
FAE4: A9 A0     460  RDSP1    LDA   #$A0
FAE6: 20 ED FD  461           JSR   COUT
FAE9: BD 1E FA  462           LDA   RTBL-$FB,X
FAEC: 20 ED FD  463           JSR   COUT
FAEF: A9 BD     464           LDA   #$BD
FAF1: 20 ED FD  465           JSR   COUT
FAF4: B5 4A     466           LDA   ACC+5,X
FAF6: 20 DA FD  467           JSR   PRBYTE
FAF9: E8        468           INX
FAFA: 30 E8     469           BMI   RDSP1
FAFC: 60        470           RTS
FAFD: 18        471  BRANCH   CLC              ;BRANCH TAKEN,
FAFE: A0 01     472           LDY   #$01       ;  ADD LEN+2 TO PC
FB00: B1 3A     473           LDA   (PCL),Y
FB02: 20 56 F9  474           JSR   PCADJ3
FB05: 85 3A     475           STA   PCL
FB07: 98        476           TYA
FB08: 38        477           SEC
FB09: B0 A2     478           BCS   PCINC2
FB0B: 20 4A FF  479  NBRNCH   JSR   SAVE       ;NORMAL RETURN AFTER
FB0E: 38        480           SEC              ;  XEQ USER OF
FB0F: B0 9E     481           BCS   PCINC3     ;GO UPDATE PC
FB11: EA        482  INITBL   NOP
FB12: EA        483           NOP              ;DUMMY FILL FOR
FB13: 4C 0B FB  484           JMP   NBRNCH     ;  XEQ AREA
FB16: 4C FD FA  485           JMP   BRANCH
FB19: C1        486  RTBL     DFB   $C1
FB1A: D8        487           DFB   $D8
FB1B: D9        488           DFB   $D9
FB1C: D0        489           DFB   $D0
FB1D: D3        490           DFB   $D3
FB1E: AD 70 C0  491  PREAD    LDA   PTRIG      ;TRIGGER PADDLES
FB21: A0 00     492           LDY   #$00       ;INIT COUNT
FB23: EA        493           NOP              ;COMPENSATE FOR 1ST COUNT
FB24: EA        494           NOP
FB25: BD 64 C0  495  PREAD2   LDA   PADDL0,X   ;COUNT Y-REG EVERY
FB28: 10 04     496           BPL   RTS2D      ;  12 USEC
FB2A: C8        497           INY
FB2B: D0 F8     498           BNE   PREAD2     ;  EXIT AT 255 MAX
FB2D: 88        499           DEY
FB2E: 60        500  RTS2D    RTS
FB2F: A9 00     501  INIT     LDA   #$00       ;CLR STATUS FOR DEBUG
FB31: 85 48     502           STA   STATUS     ;  SOFTWARE
FB33: AD 56 C0  503           LDA   LORES
FB36: AD 54 C0  504           LDA   LOWSCR     ;INIT VIDEO MODE
FB39: AD 51 C0  505  SETTXT   LDA   TXTSET     ;SET FOR TEXT MODE
FB3C: A9 00     506           LDA   #$00       ;  FULL SCREEN WINDOW
FB3E: F0 0B     507           BEQ   SETWND
FB40: AD 50 C0  508  SETGR    LDA   TXTCLR     ;SET FOR GRAPHICS MODE
FB43: AD 53 C0  509           LDA   MIXSET     ;  LOWER 4 LINES AS
FB46: 20 36 F8  510           JSR   CLRTOP     ;  TEXT WINDOW
FB49: A9 14     511           LDA   #$14
FB4B: 85 22     512  SETWND   STA   WNDTOP     ;SET FOR 40 COL WINDOW
FB4D: A9 00     513           LDA   #$00       ;  TOP IN A-REG,
FB4F: 85 20     514           STA   WNDLFT     ;  BTTM AT LINE 24
FB51: A9 28     515           LDA   #$28
FB53: 85 21     516           STA   WNDWDTH
FB55: A9 18     517           LDA   #$18
FB57: 85 23     518           STA   WNDBTM     ;  VTAB TO ROW 23
FB59: A9 17     519           LDA   #$17
FB5B: 85 25     520  TABV     STA   CV         ;VTABS TO ROW IN A-REG
FB5D: 4C 22 FC  521           JMP   VTAB
FB60: 20 A4 FB  522  MULPM    JSR   MD1        ;ABS VAL OF AC AUX
FB63: A0 10     523  MUL      LDY   #$10       ;INDEX FOR 16 BITS
FB65: A5 50     524  MUL2     LDA   ACL        ;ACX * AUX + XTND
FB67: 4A        525           LSR              ; TO AC, XTND
FB68: 90 0C     526           BCC   MUL4       ;IF NO CARRY,
FB6A: 18        527           CLC              ; NO PARTIAL PROD.
FB6B: A2 FE     528           LDX   #$FE
FB6D: B5 54     529  MUL3     LDA   XTNDL+2,X  ;ADD MPLCND (AUX)
FB6F: 75 56     530           ADC   AUXL+2,X   ; TO PARTIAL PROD
FB71: 95 54     531           STA   XTNDL+2,X  ; (XTND)
FB73: E8        532           INX
FB74: D0 F7     533           BNE   MUL3
FB76: A2 03     534  MUL4     LDX   #$03
FB78: 76        535  MUL5     DFB   $76
FB79: 50        536           DFB   $50
FB7A: CA        537           DEX
FB7B: 10 FB     538           BPL   MUL5
FB7D: 88        539           DEY
FB7E: D0 E5     540           BNE   MUL2
FB80: 60        541           RTS
FB81: 20 A4 FB  542  DIVPM    JSR   MD1        ;ABS VAL OF AC, AUX.
FB84: A0 10     543  DIV      LDY   #$10       ;INDEX FOR 16 BITS
FB86: 06 50     544  DIV2     ASL   ACL
FB88: 26 51     545           ROL   ACH
FB8A: 26 52     546           ROL   XTNDL      ;XTND/AUX
FB8C: 26 53     547           ROL   XTNDH      ;  TO AC.
FB8E: 38        548           SEC
FB8F: A5 52     549           LDA   XTNDL
FB91: E5 54     550           SBC   AUXL       ;MOD TO XTND.
FB93: AA        551           TAX
FB94: A5 53     552           LDA   XTNDH
FB96: E5 55     553           SBC   AUXH
FB98: 90 06     554           BCC   DIV3
FB9A: 86 52     555           STX   XTNDL
FB9C: 85 53     556           STA   XTNDH
FB9E: E6 50     557           INC   ACL
FBA0: 88        558  DIV3     DEY
FBA1: D0 E3     559           BNE   DIV2
FBA3: 60        560           RTS
FBA4: A0 00     561  MD1      LDY   #$00       ;ABS VAL OF AC, AUX
FBA6: 84 2F     562           STY   SIGN       ;  WITH RESULT SIGN
FBA8: A2 54     563           LDX   #AUXL      ;  IN LSB OF SIGN.
FBAA: 20 AF FB  564           JSR   MD3
FBAD: A2 50     565           LDX   #ACL
FBAF: B5 01     566  MD3      LDA   LOC1,X     ;X SPECIFIES AC OR AUX
FBB1: 10 0D     567           BPL   MDRTS
FBB3: 38        568           SEC
FBB4: 98        569           TYA
FBB5: F5 00     570           SBC   LOC0,X     ;COMPL SPECIFIED REG
FBB7: 95 00     571           STA   LOC0,X     ;  IF NEG.
FBB9: 98        572           TYA
FBBA: F5 01     573           SBC   LOC1,X
FBBC: 95 01     574           STA   LOC1,X
FBBE: E6 2F     575           INC   SIGN
FBC0: 60        576  MDRTS    RTS
FBC1: 48        577  BASCALC  PHA              ;CALC BASE ADR IN BASL,H
FBC2: 4A        578           LSR              ;  FOR GIVEN LINE NO
FBC3: 29 03     579           AND   #$03       ;  0<=LINE NO.<=$17
FBC5: 09 04     580           ORA   #$04       ;ARG=000ABCDE, GENERATE
FBC7: 85 29     581           STA   BASH       ;  BASH=000001CD
FBC9: 68        582           PLA              ;  AND
FBCA: 29 18     583           AND   #$18       ;  BASL=EABAB000
FBCC: 90 02     584           BCC   BSCLC2
FBCE: 69 7F     585           ADC   #$7F
FBD0: 85 28     586  BSCLC2   STA   BASL
FBD2: 0A        587           ASL
FBD3: 0A        588           ASL
FBD4: 05 28     589           ORA   BASL
FBD6: 85 28     590           STA   BASL
FBD8: 60        591           RTS
FBD9: C9 87     592  BELL1    CMP   #$87       ;BELL CHAR? (CNTRL-G)
FBDB: D0 12     593           BNE   RTS2B      ;  NO, RETURN
FBDD: A9 40     594           LDA   #$40       ;DELAY .01 SECONDS
FBDF: 20 A8 FC  595           JSR   WAIT
FBE2: A0 C0     596           LDY   #$C0
FBE4: A9 0C     597  BELL2    LDA   #$0C       ;TOGGLE SPEAKER AT
FBE6: 20 A8 FC  598           JSR   WAIT       ;  1 KHZ FOR .1 SEC.
FBE9: AD 30 C0  599           LDA   SPKR
FBEC: 88        600           DEY
FBED: D0 F5     601           BNE   BELL2
FBEF: 60        602  RTS2B    RTS
FBF0: A4 24     603  STOADV   LDY   CH         ;CURSOR H INDEX TO Y-REG
FBF2: 91 28     604           STA   (BASL),Y   ;STORE CHAR IN LINE
FBF4: E6 24     605  ADVANCE  INC   CH         ;INCREMENT CURSOR H INDEX
FBF6: A5 24     606           LDA   CH         ;  (MOVE RIGHT)
FBF8: C5 21     607           CMP   WNDWDTH    ;BEYOND WINDOW WIDTH?
FBFA: B0 66     608           BCS   CR         ;  YES CR TO NEXT LINE
FBFC: 60        609  RTS3     RTS              ;  NO,RETURN
FBFD: C9 A0     610  VIDOUT   CMP   #$A0       ;CONTROL CHAR?
FBFF: B0 EF     611           BCS   STOADV     ;  NO,OUTPUT IT.
FC01: A8        612           TAY              ;INVERSE VIDEO?
FC02: 10 EC     613           BPL   STOADV     ;  YES, OUTPUT IT.
FC04: C9 8D     614           CMP   #$8D       ;CR?
FC06: F0 5A     615           BEQ   CR         ;  YES.
FC08: C9 8A     616           CMP   #$8A       ;LINE FEED?
FC0A: F0 5A     617           BEQ   LF         ;  IF SO, DO IT.
FC0C: C9 88     618           CMP   #$88       ;BACK SPACE? (CNTRL-H)
FC0E: D0 C9     619           BNE   BELL1      ;  NO, CHECK FOR BELL.
FC10: C6 24     620  BS       DEC   CH         ;DECREMENT CURSOR H INDEX
FC12: 10 E8     621           BPL   RTS3       ;IF POS, OK. ELSE MOVE UP
FC14: A5 21     622           LDA   WNDWDTH    ;SET CH TO WNDWDTH-1
FC16: 85 24     623           STA   CH
FC18: C6 24     624           DEC   CH         ;(RIGHTMOST SCREEN POS)
FC1A: A5 22     625  UP       LDA   WNDTOP     ;CURSOR V INDEX
FC1C: C5 25     626           CMP   CV
FC1E: B0 0B     627           BCS   RTS4       ;IF TOP LINE THEN RETURN
FC20: C6 25     628           DEC   CV         ;DEC CURSOR V-INDEX
FC22: A5 25     629  VTAB     LDA   CV         ;GET CURSOR V-INDEX
FC24: 20 C1 FB  630  VTABZ    JSR   BASCALC    ;GENERATE BASE ADR
FC27: 65 20     631           ADC   WNDLFT     ;ADD WINDOW LEFT INDEX
FC29: 85 28     632           STA   BASL       ;TO BASL
FC2B: 60        633  RTS4     RTS
FC2C: 49 C0     634  ESC1     EOR   #$C0       ;ESC?
FC2E: F0 28     635           BEQ   HOME       ;  IF SO, DO HOME AND CLEAR
FC30: 69 FD     636           ADC   #$FD       ;ESC-A OR B CHECK
FC32: 90 C0     637           BCC   ADVANCE    ;  A, ADVANCE
FC34: F0 DA     638           BEQ   BS         ;  B, BACKSPACE
FC36: 69 FD     639           ADC   #$FD       ;ESC-C OR D CHECK
FC38: 90 2C     640           BCC   LF         ;  C, DOWN
FC3A: F0 DE     641           BEQ   UP         ;  D, GO UP
FC3C: 69 FD     642           ADC   #$FD       ;ESC-E OR F CHECK
FC3E: 90 5C     643           BCC   CLREOL     ;  E, CLEAR TO END OF LINE
FC40: D0 E9     644           BNE   RTS4       ;  NOT F, RETURN
FC42: A4 24     645  CLREOP   LDY   CH         ;CURSOR H TO Y INDEX
FC44: A5 25     646           LDA   CV         ;CURSOR V TO A-REGISTER
FC46: 48        647  CLEOP1   PHA              ;SAVE CURRENT LINE ON STK
FC47: 20 24 FC  648           JSR   VTABZ      ;CALC BASE ADDRESS
FC4A: 20 9E FC  649           JSR   CLEOLZ     ;CLEAR TO EOL, SET CARRY
FC4D: A0 00     650           LDY   #$00       ;CLEAR FROM H INDEX=0 FOR REST
FC4F: 68        651           PLA              ;INCREMENT CURRENT LINE
FC50: 69 00     652           ADC   #$00       ;(CARRY IS SET)
FC52: C5 23     653           CMP   WNDBTM     ;DONE TO BOTTOM OF WINDOW?
FC54: 90 F0     654           BCC   CLEOP1     ;  NO, KEEP CLEARING LINES
FC56: B0 CA     655           BCS   VTAB       ;  YES, TAB TO CURRENT LINE
FC58: A5 22     656  HOME     LDA   WNDTOP     ;INIT CURSOR V
FC5A: 85 25     657           STA   CV         ;  AND H-INDICES
FC5C: A0 00     658           LDY   #$00
FC5E: 84 24     659           STY   CH         ;THEN CLEAR TO END OF PAGE
FC60: F0 E4     660           BEQ   CLEOP1
FC62: A9 00     661  CR       LDA   #$00       ;CURSOR TO LEFT OF INDEX
FC64: 85 24     662           STA   CH         ;(RET CURSOR H=0)
FC66: E6 25     663  LF       INC   CV         ;INCR CURSOR V(DOWN 1 LINE)
FC68: A5 25     664           LDA   CV
FC6A: C5 23     665           CMP   WNDBTM     ;OFF SCREEN?
FC6C: 90 B6     666           BCC   VTABZ      ;  NO, SET BASE ADDR
FC6E: C6 25     667           DEC   CV         ;DECR CURSOR V (BACK TO BOTTOM)
FC70: A5 22     668  SCROLL   LDA   WNDTOP     ;START AT TOP OF SCRL WNDW
FC72: 48        669           PHA
FC73: 20 24 FC  670           JSR   VTABZ      ;GENERATE BASE ADR
FC76: A5 28     671  SCRL1    LDA   BASL       ;COPY BASL,H
FC78: 85 2A     672           STA   BAS2L      ;  TO BAS2L,H
FC7A: A5 29     673           LDA   BASH
FC7C: 85 2B     674           STA   BAS2H
FC7E: A4 21     675           LDY   WNDWDTH    ;INIT Y TO RIGHTMOST INDEX
FC80: 88        676           DEY              ;  OF SCROLLING WINDOW
FC81: 68        677           PLA
FC82: 69 01     678           ADC   #$01       ;INCR LINE NUMBER
FC84: C5 23     679           CMP   WNDBTM     ;DONE?
FC86: B0 0D     680           BCS   SCRL3      ;  YES, FINISH
FC88: 48        681           PHA
FC89: 20 24 FC  682           JSR   VTABZ      ;FORM BASL,H (BASE ADDR)
FC8C: B1 28     683  SCRL2    LDA   (BASL),Y   ;MOVE A CHR UP ON LINE
FC8E: 91 2A     684           STA   (BAS2L),Y
FC90: 88        685           DEY              ;NEXT CHAR OF LINE
FC91: 10 F9     686           BPL   SCRL2
FC93: 30 E1     687           BMI   SCRL1      ;NEXT LINE (ALWAYS TAKEN)
FC95: A0 00     688  SCRL3    LDY   #$00       ;CLEAR BOTTOM LINE
FC97: 20 9E FC  689           JSR   CLEOLZ     ;GET BASE ADDR FOR BOTTOM LINE
FC9A: B0 86     690           BCS   VTAB       ;CARRY IS SET
FC9C: A4 24     691  CLREOL   LDY   CH         ;CURSOR H INDEX
FC9E: A9 A0     692  CLEOLZ   LDA   #$A0
FCA0: 91 28     693  CLEOL2   STA   (BASL),Y   ;STORE BLANKS FROM 'HERE'
FCA2: C8        694           INY              ;  TO END OF LINES (WNDWDTH)
FCA3: C4 21     695           CPY   WNDWDTH
FCA5: 90 F9     696           BCC   CLEOL2
FCA7: 60        697           RTS
FCA8: 38        698  WAIT     SEC
FCA9: 48        699  WAIT2    PHA
FCAA: E9 01     700  WAIT3    SBC   #$01
FCAC: D0 FC     701           BNE   WAIT3      ;1.0204 USEC
FCAE: 68        702           PLA              ;(13+27/2*A+5/2*A*A)
FCAF: E9 01     703           SBC   #$01
FCB1: D0 F6     704           BNE   WAIT2
FCB3: 60        705           RTS
FCB4: E6 42     706  NXTA4    INC   A4L        ;INCR 2-BYTE A4
FCB6: D0 02     707           BNE   NXTA1      ;  AND A1
FCB8: E6 43     708           INC   A4H
FCBA: A5 3C     709  NXTA1    LDA   A1L        ;INCR 2-BYTE A1.
FCBC: C5 3E     710           CMP   A2L
FCBE: A5 3D     711           LDA   A1H        ;  AND COMPARE TO A2
FCC0: E5 3F     712           SBC   A2H
FCC2: E6 3C     713           INC   A1L        ;  (CARRY SET IF >=)
FCC4: D0 02     714           BNE   RTS4B
FCC6: E6 3D     715           INC   A1H
FCC8: 60        716  RTS4B    RTS
FCC9: A0 4B     717  HEADR    LDY   #$4B       ;WRITE A*256 'LONG 1'
FCCB: 20 DB FC  718           JSR   ZERDLY     ;  HALF CYCLES
FCCE: D0 F9     719           BNE   HEADR      ;  (650 USEC EACH)
FCD0: 69 FE     720           ADC   #$FE
FCD2: B0 F5     721           BCS   HEADR      ;THEN A 'SHORT 0'
FCD4: A0 21     722           LDY   #$21       ;  (400 USEC)
FCD6: 20 DB FC  723  WRBIT    JSR   ZERDLY     ;WRITE TWO HALF CYCLES
FCD9: C8        724           INY              ;  OF 250 USEC ('0')
FCDA: C8        725           INY              ;  OR 500 USEC ('0')
FCDB: 88        726  ZERDLY   DEY
FCDC: D0 FD     727           BNE   ZERDLY
FCDE: 90 05     728           BCC   WRTAPE     ;Y IS COUNT FOR
FCE0: A0 32     729           LDY   #$32       ;  TIMING LOOP
FCE2: 88        730  ONEDLY   DEY
FCE3: D0 FD     731           BNE   ONEDLY
FCE5: AC 20 C0  732  WRTAPE   LDY   TAPEOUT
FCE8: A0 2C     733           LDY   #$2C
FCEA: CA        734           DEX
FCEB: 60        735           RTS
FCEC: A2 08     736  RDBYTE   LDX   #$08       ;8 BITS TO READ
FCEE: 48        737  RDBYT2   PHA              ;READ TWO TRANSITIONS
FCEF: 20 FA FC  738           JSR   RD2BIT     ;  (FIND EDGE)
FCF2: 68        739           PLA
FCF3: 2A        740           ROL              ;NEXT BIT
FCF4: A0 3A     741           LDY   #$3A       ;COUNT FOR SAMPLES
FCF6: CA        742           DEX
FCF7: D0 F5     743           BNE   RDBYT2
FCF9: 60        744           RTS
FCFA: 20 FD FC  745  RD2BIT   JSR   RDBIT
FCFD: 88        746  RDBIT    DEY              ;DECR Y UNTIL
FCFE: AD 60 C0  747           LDA   TAPEIN     ; TAPE TRANSITION
FD01: 45 2F     748           EOR   LASTIN
FD03: 10 F8     749           BPL   RDBIT
FD05: 45 2F     750           EOR   LASTIN
FD07: 85 2F     751           STA   LASTIN
FD09: C0 80     752           CPY   #$80       ;SET CARRY ON Y
FD0B: 60        753           RTS
FD0C: A4 24     754  RDKEY    LDY   CH
FD0E: B1 28     755           LDA   (BASL),Y   ;SET SCREEN TO FLASH
FD10: 48        756           PHA
FD11: 29 3F     757           AND   #$3F
FD13: 09 40     758           ORA   #$40
FD15: 91 28     759           STA   (BASL),Y
FD17: 68        760           PLA
FD18: 6C 38 00  761           JMP   (KSWL)     ;GO TO USER KEY-IN
FD1B: E6 4E     762  KEYIN    INC   RNDL
FD1D: D0 02     763           BNE   KEYIN2     ;INCR RND NUMBER
FD1F: E6 4F     764           INC   RNDH
FD21: 2C 00 C0  765  KEYIN2   BIT   KBD        ;KEY DOWN?
FD24: 10 F5     766           BPL   KEYIN      ;  LOOP
FD26: 91 28     767           STA   (BASL),Y   ;REPLACE FLASHING SCREEN
FD28: AD 00 C0  768           LDA   KBD        ;GET KEYCODE
FD2B: 2C 10 C0  769           BIT   KBDSTRB    ;CLR KEY STROBE
FD2E: 60        770           RTS
FD2F: 20 0C FD  771  ESC      JSR   RDKEY      ;GET KEYCODE
FD32: 20 2C FC  772           JSR   ESC1       ;  HANDLE ESC FUNC.
FD35: 20 0C FD  773  RDCHAR   JSR   RDKEY      ;READ KEY
FD38: C9 9B     774           CMP   #$9B       ;ESC?
FD3A: F0 F3     775           BEQ   ESC        ;  YES, DON'T RETURN
FD3C: 60        776           RTS
FD3D: A5 32     777  NOTCR    LDA   INVFLG
FD3F: 48        778           PHA
FD40: A9 FF     779           LDA   #$FF
FD42: 85 32     780           STA   INVFLG     ;ECHO USER LINE
FD44: BD 00 02  781           LDA   IN,X       ;  NON INVERSE
FD47: 20 ED FD  782           JSR   COUT
FD4A: 68        783           PLA
FD4B: 85 32     784           STA   INVFLG
FD4D: BD 00 02  785           LDA   IN,X
FD50: C9 88     786           CMP   #$88       ;CHECK FOR EDIT KEYS
FD52: F0 1D     787           BEQ   BCKSPC     ;  BS, CTRL-X
FD54: C9 98     788           CMP   #$98
FD56: F0 0A     789           BEQ   CANCEL
FD58: E0 F8     790           CPX   #$F8       ;MARGIN?
FD5A: 90 03     791           BCC   NOTCR1
FD5C: 20 3A FF  792           JSR   BELL       ;  YES, SOUND BELL
FD5F: E8        793  NOTCR1   INX              ;ADVANCE INPUT INDEX
FD60: D0 13     794           BNE   NXTCHAR
FD62: A9 DC     795  CANCEL   LDA   #$DC       ;BACKSLASH AFTER CANCELLED LINE
FD64: 20 ED FD  796           JSR   COUT
FD67: 20 8E FD  797  GETLNZ   JSR   CROUT      ;OUTPUT CR
FD6A: A5 33     798  GETLN    LDA   PROMPT
FD6C: 20 ED FD  799           JSR   COUT       ;OUTPUT PROMPT CHAR
FD6F: A2 01     800           LDX   #$01       ;INIT INPUT INDEX
FD71: 8A        801  BCKSPC   TXA              ;  WILL BACKSPACE TO 0
FD72: F0 F3     802           BEQ   GETLNZ
FD74: CA        803           DEX
FD75: 20 35 FD  804  NXTCHAR  JSR   RDCHAR
FD78: C9 95     805           CMP   #PICK      ;USE SCREEN CHAR
FD7A: D0 02     806           BNE   CAPTST     ;  FOR CTRL-U
FD7C: B1 28     807           LDA   (BASL),Y
FD7E: C9 E0     808  CAPTST   CMP   #$E0
FD80: 90 02     809           BCC   ADDINP     ;CONVERT TO CAPS
FD82: 29 DF     810           AND   #$DF
FD84: 9D 00 02  811  ADDINP   STA   IN,X       ;ADD TO INPUT BUF
FD87: C9 8D     812           CMP   #$8D
FD89: D0 B2     813           BNE   NOTCR
FD8B: 20 9C FC  814           JSR   CLREOL     ;CLR TO EOL IF CR
FD8E: A9 8D     815  CROUT    LDA   #$8D
FD90: D0 5B     816           BNE   COUT
FD92: A4 3D     817  PRA1     LDY   A1H        ;PRINT CR,A1 IN HEX
FD94: A6 3C     818           LDX   A1L
FD96: 20 8E FD  819  PRYX2    JSR   CROUT
FD99: 20 40 F9  820           JSR   PRNTYX
FD9C: A0 00     821           LDY   #$00
FD9E: A9 AD     822           LDA   #$AD       ;PRINT '-'
FDA0: 4C ED FD  823           JMP   COUT
FDA3: A5 3C     824  XAM8     LDA   A1L
FDA5: 09 07     825           ORA   #$07       ;SET TO FINISH AT
FDA7: 85 3E     826           STA   A2L        ;  MOD 8=7
FDA9: A5 3D     827           LDA   A1H
FDAB: 85 3F     828           STA   A2H
FDAD: A5 3C     829  MODSCHK  LDA   A1L
FDAF: 29 07     830           AND   #$07
FDB1: D0 03     831           BNE   DATAOUT
FDB3: 20 92 FD  832  XAM      JSR   PRA1
FDB6: A9 A0     833  DATAOUT  LDA   #$A0
FDB8: 20 ED FD  834           JSR   COUT       ;OUTPUT BLANK
FDBB: B1 3C     835           LDA   (A1L),Y
FDBD: 20 DA FD  836           JSR   PRBYTE     ;OUTPUT BYTE IN HEX
FDC0: 20 BA FC  837           JSR   NXTA1
FDC3: 90 E8     838           BCC   MODSCHK    ;CHECK IF TIME TO,
FDC5: 60        839  RTS4C    RTS              ;  PRINT ADDR
FDC6: 4A        840  XAMPM    LSR              ;DETERMINE IF MON
FDC7: 90 EA     841           BCC   XAM        ;  MODE IS XAM
FDC9: 4A        842           LSR              ;  ADD, OR SUB
FDCA: 4A        843           LSR
FDCB: A5 3E     844           LDA   A2L
FDCD: 90 02     845           BCC   ADD
FDCF: 49 FF     846           EOR   #$FF       ;SUB: FORM 2'S COMPLEMENT
FDD1: 65 3C     847  ADD      ADC   A1L
FDD3: 48        848           PHA
FDD4: A9 BD     849           LDA   #$BD
FDD6: 20 ED FD  850           JSR   COUT       ;PRINT '=', THEN RESULT
FDD9: 68        851           PLA
FDDA: 48        852  PRBYTE   PHA              ;PRINT BYTE AS 2 HEX
FDDB: 4A        853           LSR              ;  DIGITS, DESTROYS A-REG
FDDC: 4A        854           LSR
FDDD: 4A        855           LSR
FDDE: 4A        856           LSR
FDDF: 20 E5 FD  857           JSR   PRHEXZ
FDE2: 68        858           PLA
FDE3: 29 0F     859  PRHEX    AND   #$0F       ;PRINT HEX DIG IN A-REG
FDE5: 09 B0     860  PRHEXZ   ORA   #$B0       ;  LSB'S
FDE7: C9 BA     861           CMP   #$BA
FDE9: 90 02     862           BCC   COUT
FDEB: 69 06     863           ADC   #$06
FDED: 6C 36 00  864  COUT     JMP   (CSWL)     ;VECTOR TO USER OUTPUT ROUTINE
FDF0: C9 A0     865  COUT1    CMP   #$A0
FDF2: 90 02     866           BCC   COUTZ      ;DON'T OUTPUT CTRL'S INVERSE
FDF4: 25 32     867           AND   INVFLG     ;MASK WITH INVERSE FLAG
FDF6: 84 35     868  COUTZ    STY   YSAV1      ;SAV Y-REG
FDF8: 48        869           PHA              ;SAV A-REG
FDF9: 20 FD FB  870           JSR   VIDOUT     ;OUTPUT A-REG AS ASCII
FDFC: 68        871           PLA              ;RESTORE A-REG
FDFD: A4 35     872           LDY   YSAV1      ;  AND Y-REG
FDFF: 60        873           RTS              ;  THEN RETURN
FE00: C6 34     874  BL1      DEC   YSAV
FE02: F0 9F     875           BEQ   XAM8
FE04: CA        876  BLANK    DEX              ;BLANK TO MON
FE05: D0 16     877           BNE   SETMDZ     ;AFTER BLANK
FE07: C9 BA     878           CMP   #$BA       ;DATA STORE MODE?
FE09: D0 BB     879           BNE   XAMPM      ;  NO, XAM, ADD, OR SUB
FE0B: 85 31     880  STOR     STA   MODE       ;KEEP IN STORE MODE
FE0D: A5 3E     881           LDA   A2L
FE0F: 91 40     882           STA   (A3L),Y    ;STORE AS LOW BYTE AS (A3)
FE11: E6 40     883           INC   A3L
FE13: D0 02     884           BNE   RTS5       ;INCR A3, RETURN
FE15: E6 41     885           INC   A3H
FE17: 60        886  RTS5     RTS
FE18: A4 34     887  SETMODE  LDY   YSAV       ;SAVE CONVERTED ':', '+',
FE1A: B9 FF 01  888           LDA   IN-1,Y     ;  '-', '.' AS MODE.
FE1D: 85 31     889  SETMDZ   STA   MODE
FE1F: 60        890           RTS
FE20: A2 01     891  LT       LDX   #$01
FE22: B5 3E     892  LT2      LDA   A2L,X      ;COPY A2 (2 BYTES) TO
FE24: 95 42     893           STA   A4L,X      ;  A4 AND A5
FE26: 95 44     894           STA   A5L,X
FE28: CA        895           DEX
FE29: 10 F7     896           BPL   LT2
FE2B: 60        897           RTS
FE2C: B1 3C     898  MOVE     LDA   (A1L),Y    ;MOVE (A1 TO A2) TO
FE2E: 91 42     899           STA   (A4L),Y    ;  (A4)
FE30: 20 B4 FC  900           JSR   NXTA4
FE33: 90 F7     901           BCC   MOVE
FE35: 60        902           RTS
FE36: B1 3C     903  VFY      LDA   (A1L),Y    ;VERIFY (A1 TO A2) WITH
FE38: D1 42     904           CMP   (A4L),Y    ;  (A4)
FE3A: F0 1C     905           BEQ   VFYOK
FE3C: 20 92 FD  906           JSR   PRA1
FE3F: B1 3C     907           LDA   (A1L),Y
FE41: 20 DA FD  908           JSR   PRBYTE
FE44: A9 A0     909           LDA   #$A0
FE46: 20 ED FD  910           JSR   COUT
FE49: A9 A8     911           LDA   #$A8
FE4B: 20 ED FD  912           JSR   COUT
FE4E: B1 42     913           LDA   (A4L),Y
FE50: 20 DA FD  914           JSR   PRBYTE
FE53: A9 A9     915           LDA   #$A9
FE55: 20 ED FD  916           JSR   COUT
FE58: 20 B4 FC  917  VFYOK    JSR   NXTA4
FE5B: 90 D9     918           BCC   VFY
FE5D: 60        919           RTS
FE5E: 20 75 FE  920  LIST     JSR   A1PC       ;MOVE A1 (2 BYTES) TO
FE61: A9 14     921           LDA   #$14       ;  PC IF SPEC'D AND
FE63: 48        922  LIST2    PHA              ;  DISEMBLE 20 INSTRS
FE64: 20 D0 F8  923           JSR   INSTDSP
FE67: 20 53 F9  924           JSR   PCADJ      ;ADJUST PC EACH INSTR
FE6A: 85 3A     925           STA   PCL
FE6C: 84 3B     926           STY   PCH
FE6E: 68        927           PLA
FE6F: 38        928           SEC
FE70: E9 01     929           SBC   #$01       ;NEXT OF 20 INSTRS
FE72: D0 EF     930           BNE   LIST2
FE74: 60        931           RTS
FE75: 8A        932  A1PC     TXA              ;IF USER SPEC'D ADR
FE76: F0 07     933           BEQ   A1PCRTS    ;  COPY FROM A1 TO PC
FE78: B5 3C     934  A1PCLP   LDA   A1L,X
FE7A: 95 3A     935           STA   PCL,X
FE7C: CA        936           DEX
FE7D: 10 F9     937           BPL   A1PCLP
FE7F: 60        938  A1PCRTS  RTS
FE80: A0 3F     939  SETINV   LDY   #$3F       ;SET FOR INVERSE VID
FE82: D0 02     940           BNE   SETIFLG    ; VIA COUT1
FE84: A0 FF     941  SETNORM  LDY   #$FF       ;SET FOR NORMAL VID
FE86: 84 32     942  SETIFLG  STY   INVFLG
FE88: 60        943           RTS
FE89: A9 00     944  SETKBD   LDA   #$00       ;SIMULATE PORT #0 INPUT
FE8B: 85 3E     945  INPORT   STA   A2L        ;  SPECIFIED (KEYIN ROUTINE)
FE8D: A2 38     946  INPRT    LDX   #KSWL
FE8F: A0 1B     947           LDY   #KEYIN
FE91: D0 08     948           BNE   IOPRT
FE93: A9 00     949  SETVID   LDA   #$00       ;SIMULATE PORT #0 OUTPUT
FE95: 85 3E     950  OUTPORT  STA   A2L        ;  SPECIFIED (COUT1 ROUTINE)
FE97: A2 36     951  OUTPRT   LDX   #CSWL
FE99: A0 F0     952           LDY   #COUT1
FE9B: A5 3E     953  IOPRT    LDA   A2L        ;SET RAM IN/OUT VECTORS
FE9D: 29 0F     954           AND   #$0F
FE9F: F0 06     955           BEQ   IOPRT1
FEA1: 09 C0     956           ORA   #IOADR/256
FEA3: A0 00     957           LDY   #$00
FEA5: F0 02     958           BEQ   IOPRT2
FEA7: A9 FD     959  IOPRT1   LDA   #COUT1/256
FEA9: 94 00     960  IOPRT2   STY   LOC0,X
FEAB: 95 01     961           STA   LOC1,X
FEAD: 60        962           RTS
FEAE: EA        963           NOP
FEAF: EA        964           NOP
FEB0: 4C 00 E0  965  XBASIC   JMP   BASIC      ;TO BASIC WITH SCRATCH
FEB3: 4C 03 E0  966  BASCONT  JMP   BASIC2     ;CONTINUE BASIC
FEB6: 20 75 FE  967  GO       JSR   A1PC       ;ADR TO PC IF SPEC'D
FEB9: 20 3F FF  968           JSR   RESTORE    ;RESTORE META REGS
FEBC: 6C 3A 00  969           JMP   (PCL)      ;GO TO USER SUBR
FEBF: 4C D7 FA  970  REGZ     JMP   REGDSP     ;TO REG DISPLAY
FEC2: C6 34     971  TRACE    DEC   YSAV
FEC4: 20 75 FE  972  STEPZ    JSR   A1PC       ;ADR TO PC IF SPEC'D
FEC7: 4C 43 FA  973           JMP   STEP       ;TAKE ONE STEP
FECA: 4C F8 03  974  USR      JMP   USRADR     ;TO USR SUBR AT USRADR
FECD: A9 40     975  WRITE    LDA   #$40
FECF: 20 C9 FC  976           JSR   HEADR      ;WRITE 10-SEC HEADER
FED2: A0 27     977           LDY   #$27
FED4: A2 00     978  WR1      LDX   #$00
FED6: 41 3C     979           EOR   (A1L,X)
FED8: 48        980           PHA
FED9: A1 3C     981           LDA   (A1L,X)
FEDB: 20 ED FE  982           JSR   WRBYTE
FEDE: 20 BA FC  983           JSR   NXTA1
FEE1: A0 1D     984           LDY   #$1D
FEE3: 68        985           PLA
FEE4: 90 EE     986           BCC   WR1
FEE6: A0 22     987           LDY   #$22
FEE8: 20 ED FE  988           JSR   WRBYTE
FEEB: F0 4D     989           BEQ   BELL
FEED: A2 10     990  WRBYTE   LDX   #$10
FEEF: 0A        991  WRBYT2   ASL
FEF0: 20 D6 FC  992           JSR   WRBIT
FEF3: D0 FA     993           BNE   WRBYT2
FEF5: 60        994           RTS
FEF6: 20 00 FE  995  CRMON    JSR   BL1        ;HANDLE A CR AS BLANK
FEF9: 68        996           PLA              ;  THEN POP STACK
FEFA: 68        997           PLA              ;  AND RTN TO MON
FEFB: D0 6C     998           BNE   MONZ
FEFD: 20 FA FC  999  READ     JSR   RD2BIT     ;FIND TAPEIN EDGE
FF00: A9 16     1000          LDA   #$16
FF02: 20 C9 FC  1001          JSR   HEADR      ;DELAY 3.5 SECONDS
FF05: 85 2E     1002          STA   CHKSUM     ;INIT CHKSUM=$FF
FF07: 20 FA FC  1003          JSR   RD2BIT     ;FIND TAPEIN EDGE
FF0A: A0 24     1004 RD2      LDY   #$24       ;LOOK FOR SYNC BIT
FF0C: 20 FD FC  1005          JSR   RDBIT      ;  (SHORT 0)
FF0F: B0 F9     1006          BCS   RD2        ;  LOOP UNTIL FOUND
FF11: 20 FD FC  1007          JSR   RDBIT      ;SKIP SECOND SYNC H-CYCLE
FF14: A0 3B     1008          LDY   #$3B       ;INDEX FOR 0/1 TEST
FF16: 20 EC FC  1009 RD3      JSR   RDBYTE     ;READ A BYTE
FF19: 81 3C     1010          STA   (A1L,X)    ;STORE AT (A1)
FF1B: 45 2E     1011          EOR   CHKSUM
FF1D: 85 2E     1012          STA   CHKSUM     ;UPDATE RUNNING CHKSUM
FF1F: 20 BA FC  1013          JSR   NXTA1      ;INC A1, COMPARE TO A2
FF22: A0 35     1014          LDY   #$35       ;COMPENSATE 0/1 INDEX
FF24: 90 F0     1015          BCC   RD3        ;LOOP UNTIL DONE
FF26: 20 EC FC  1016          JSR   RDBYTE     ;READ CHKSUM BYTE
FF29: C5 2E     1017          CMP   CHKSUM
FF2B: F0 0D     1018          BEQ   BELL       ;GOOD, SOUND BELL AND RETURN
FF2D: A9 C5     1019 PRERR    LDA   #$C5
FF2F: 20 ED FD  1020          JSR   COUT       ;PRINT "ERR", THEN BELL
FF32: A9 D2     1021          LDA   #$D2
FF34: 20 ED FD  1022          JSR   COUT
FF37: 20 ED FD  1023          JSR   COUT
FF3A: A9 87     1024 BELL     LDA   #$87       ;OUTPUT BELL AND RETURN
FF3C: 4C ED FD  1025          JMP   COUT
FF3F: A5 48     1026 RESTORE  LDA   STATUS     ;RESTORE 6502 REG CONTENTS
FF41: 48        1027          PHA              ;  USED BY DEBUG SOFTWARE
FF42: A5 45     1028          LDA   ACC
FF44: A6 46     1029 RESTR1   LDX   XREG
FF46: A4 47     1030          LDY   YREG
FF48: 28        1031          PLP
FF49: 60        1032          RTS
FF4A: 85 45     1033 SAVE     STA   ACC        ;SAVE 6502 REG CONTENTS
FF4C: 86 46     1034 SAV1     STX   XREG
FF4E: 84 47     1035          STY   YREG
FF50: 08        1036          PHP
FF51: 68        1037          PLA
FF52: 85 48     1038          STA   STATUS
FF54: BA        1039          TSX
FF55: 86 49     1040          STX   SPNT
FF57: D8        1041          CLD
FF58: 60        1042          RTS
FF59: 20 84 FE  1043 RESET    JSR   SETNORM    ;SET SCREEN MODE
FF5C: 20 2F FB  1044          JSR   INIT       ;  AND INIT KBD/SCREEN
FF5F: 20 93 FE  1045          JSR   SETVID     ;  AS I/O DEV'S
FF62: 20 89 FE  1046          JSR   SETKBD
FF65: D8        1047 MON      CLD              ;MUST SET HEX MODE!
FF66: 20 3A FF  1048          JSR   BELL
FF69: A9 AA     1049 MONZ     LDA   #$AA       ;'*' PROMPT FOR MON
FF6B: 85 33     1050          STA   PROMPT
FF6D: 20 67 FD  1051          JSR   GETLNZ     ;READ A LINE
FF70: 20 C7 FF  1052          JSR   ZMODE      ;CLEAR MON MODE, SCAN IDX
FF73: 20 A7 FF  1053 NXTITM   JSR   GETNUM     ;GET ITEM, NON-HEX
FF76: 84 34     1054          STY   YSAV       ;  CHAR IN A-REG
FF78: A0 17     1055          LDY   #$17       ;  X-REG=0 IF NO HEX INPUT
FF7A: 88        1056 CHRSRCH  DEY
FF7B: 30 E8     1057          BMI   MON        ;NOT FOUND, GO TO MON
FF7D: D9 CC FF  1058          CMP   CHRTBL,Y   ;FIND CMND CHAR IN TEL
FF80: D0 F8     1059          BNE   CHRSRCH
FF82: 20 BE FF  1060          JSR   TOSUB      ;FOUND, CALL CORRESPONDING
FF85: A4 34     1061          LDY   YSAV       ;  SUBROUTINE
FF87: 4C 73 FF  1062          JMP   NXTITM
FF8A: A2 03     1063 DIG      LDX   #$03
FF8C: 0A        1064          ASL
FF8D: 0A        1065          ASL              ;GOT HEX DIG,
FF8E: 0A        1066          ASL              ;  SHIFT INTO A2
FF8F: 0A        1067          ASL
FF90: 0A        1068 NXTBIT   ASL
FF91: 26 3E     1069          ROL   A2L
FF93: 26 3F     1070          ROL   A2H
FF95: CA        1071          DEX              ;LEAVE X=$FF IF DIG
FF96: 10 F8     1072          BPL   NXTBIT
FF98: A5 31     1073 NXTBAS   LDA   MODE
FF9A: D0 06     1074          BNE   NXTBS2     ;IF MODE IS ZERO
FF9C: B5 3F     1075          LDA   A2H,X      ; THEN COPY A2 TO
FF9E: 95 3D     1076          STA   A1H,X      ; A1 AND A3
FFA0: 95 41     1077          STA   A3H,X
FFA2: E8        1078 NXTBS2   INX
FFA3: F0 F3     1079          BEQ   NXTBAS
FFA5: D0 06     1080          BNE   NXTCHR
FFA7: A2 00     1081 GETNUM   LDX   #$00       ;CLEAR A2
FFA9: 86 3E     1082          STX   A2L
FFAB: 86 3F     1083          STX   A2H
FFAD: B9 00 02  1084 NXTCHR   LDA   IN,Y       ;GET CHAR
FFB0: C8        1085          INY
FFB1: 49 B0     1086          EOR   #$B0
FFB3: C9 0A     1087          CMP   #$0A
FFB5: 90 D3     1088          BCC   DIG        ;IF HEX DIG, THEN
FFB7: 69 88     1089          ADC   #$88
FFB9: C9 FA     1090          CMP   #$FA
FFBB: B0 CD     1091          BCS   DIG
FFBD: 60        1092          RTS
FFBE: A9 FE     1093 TOSUB    LDA   #GO/256    ;PUSH HIGH-ORDER
FFC0: 48        1094          PHA              ;  SUBR ADR ON STK
FFC1: B9 E3 FF  1095          LDA   SUBTBL,Y   ;PUSH LOW-ORDER
FFC4: 48        1096          PHA              ;  SUBR ADR ON STK
FFC5: A5 31     1097          LDA   MODE
FFC7: A0 00     1098 ZMODE    LDY   #$00       ;CLR MODE, OLD MODE
FFC9: 84 31     1099          STY   MODE       ;  TO A-REG
FFCB: 60        1100          RTS              ; GO TO SUBR VIA RTS
FFCC: BC        1101 CHRTBL   DFB   $BC        ;F("CTRL-C")
FFCD: B2        1102          DFB   $B2        ;F("CTRL-Y")
FFCE: BE        1103          DFB   $BE        ;F("CTRL-E")
FFCF: ED        1104          DFB   $ED        ;F("T")
FFD0: EF        1105          DFB   $EF        ;F("V")
FFD1: C4        1106          DFB   $C4        ;F("CTRL-K")
FFD2: EC        1107          DFB   $EC        ;F("S")
FFD3: A9        1108          DFB   $A9        ;F("CTRL-P")
FFD4: BB        1109          DFB   $BB        ;F("CTRL-B")
FFD5: A6        1110          DFB   $A6        ;F("-")
FFD6: A4        1111          DFB   $A4        ;F("+")
FFD7: 06        1112          DFB   $06        ;F("M") (F=EX-OR $B0+$89)
FFD8: 95        1113          DFB   $95        ;F("<")
FFD9: 07        1114          DFB   $07        ;F("N")
FFDA: 02        1115          DFB   $02        ;F("I")
FFDB: 05        1116          DFB   $05        ;F("L")
FFDC: F0        1117          DFB   $F0        ;F("W")
FFDD: 00        1118          DFB   $00        ;F("G")
FFDE: EB        1119          DFB   $EB        ;F("R")
FFDF: 93        1120          DFB   $93        ;F(":")
FFE0: A7        1121          DFB   $A7        ;F(".")
FFE1: C6        1122          DFB   $C6        ;F("CR")
FFE2: 99        1123          DFB   $99        ;F(BLANK)
FFE3: B2        1124 SUBTBL   DFB   BASCONT-1
FFE4: C9        1125          DFB   USR-1
FFE5: BE        1126          DFB   REGZ-1
FFE6: C1        1127          DFB   TRACE-1
FFE7: 35        1128          DFB   VFY-1
FFE8: 8C        1129          DFB   INPRT-1
FFE9: C3        1130          DFB   STEPZ-1
FFEA: 96        1131          DFB   OUTPRT-1
FFEB: AF        1132          DFB   XBASIC-1
FFEC: 17        1133          DFB   SETMODE-1
FFED: 17        1134          DFB   SETMODE-1
FFEE: 2B        1135          DFB   MOVE-1
FFEF: 1F        1136          DFB   LT-1
FFF0: 83        1137          DFB   SETNORM-1
FFF1: 7F        1138          DFB   SETINV-1
FFF2: 5D        1139          DFB   LIST-1
FFF3: CC        1140          DFB   WRITE-1
FFF4: B5        1141          DFB   GO-1
FFF5: FC        1142          DFB   READ-1
FFF6: 17        1143          DFB   SETMODE-1
FFF7: 17        1144          DFB   SETMODE-1
FFF8: F5        1145          DFB   CRMON-1
FFF9: 03        1146          DFB   BLANK-1
FFFA: FB        1147          DFB   NMI        ;NMI VECTOR
FFFB: 03        1148          DFB   NMI/256
FFFC: 59        1149          DFB   RESET      ;RESET VECTOR
FFFD: FF        1150          DFB   RESET/256
FFFE: 86        1151          DFB   IRQ        ;IRQ VECTOR
FFFF: FA        1152          DFB   IRQ/256
                1153 XQTNZ    EQU   $3C



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Red Book Sweet-16 listing 
+------------------------------------------------------------------------

                1    ***********************
                2    *                     *
                3    *   APPLE-II PSEUDO   *
                4    * MACHINE INTERPRETER *
                5    *                     *
                6    *   COPYRIGHT 1977    *
                7    * APPLE COMPUTER INC  *
                8    *                     *
                9    * ALL RIGHTS RESERVED *
                10   *     S. WOZNIAK      *
                11   *                     *
                12   ***********************
                13                             ; TITLE "SWEET16 INTERPRETER"
                14   R0L      EQU   $0
                15   R0H      EQU   $1
                16   R14H     EQU   $1D
                17   R15L     EQU   $1E
                18   R15H     EQU   $1F
                19   SW16PAG  EQU   $F7
                20   SAVE     EQU   $FF4A
                21   RESTORE  EQU   $FF3F
                22            ORG   $F689
F689: 20 4A FF  23   SW16     JSR   SAVE       ;PRESERVE 6502 REG CONTENTS
F68C: 68        24            PLA
F68D: 85 1E     25            STA   R15L       ;INIT SWEET16 PC
F68F: 68        26            PLA              ;FROM RETURN
F690: 85 1F     27            STA   R15H       ;  ADDRESS
F692: 20 98 F6  28   SW16B    JSR   SW16C      ;INTERPRET AND EXECUTE
F695: 4C 92 F6  29            JMP   SW16B      ;ONE SWEET16 INSTR.
F698: E6 1E     30   SW16C    INC   R15L
F69A: D0 02     31            BNE   SW16D      ;INCR SWEET16 PC FOR FETCH
F69C: E6 1F     32            INC   R15H
F69E: A9 F7     33   SW16D    LDA   #SW16PAG
F6A0: 48        34            PHA              ;PUSH ON STACK FOR RTS
F6A1: A0 00     35            LDY   #$0
F6A3: B1 1E     36            LDA   (R15L),Y   ;FETCH INSTR
F6A5: 29 0F     37            AND   #$F        ;MASK REG SPECIFICATION
F6A7: 0A        38            ASL              ;DOUBLE FOR TWO BYTE REGISTERS
F6A8: AA        39            TAX              ;TO X REG FOR INDEXING
F6A9: 4A        40            LSR
F6AA: 51 1E     41            EOR   (R15L),Y   ;NOW HAVE OPCODE
F6AC: F0 0B     42            BEQ   TOBR       ;IF ZERO THEN NON-REG OP
F6AE: 86 1D     43            STX   R14H       ;INDICATE'PRIOR RESULT REG'
F6B0: 4A        44            LSR
F6B1: 4A        45            LSR              ;OPCODE*2 TO LSB'S
F6B2: 4A        46            LSR
F6B3: A8        47            TAY              ;TO Y REG FOR INDEXING
F6B4: B9 E1 F6  48            LDA   OPTBL-2,Y  ;LOW ORDER ADR BYTE
F6B7: 48        49            PHA              ;ONTO STACK
F6B8: 60        50            RTS              ;GOTO REG-OP ROUTINE
F6B9: E6 1E     51   TOBR     INC   R15L
F6BB: D0 02     52            BNE   TOBR2      ;INCR PC
F6BD: E6 1F     53            INC   R15H
F6BF: BD E4 F6  54   TOBR2    LDA   BRTBL,X    ;LOW ORDER ADR BYTE
F6C2: 48        55            PHA              ;ONTO STACK FOR NON-REG OP
F6C3: A5 1D     56            LDA   R14H       ;'PRIOR RESULT REG' INDEX
F6C5: 4A        57            LSR              ;PREPARE CARRY FOR BC, BNC.
F6C6: 60        58            RTS              ;GOTO NON-REG OP ROUTINE
F6C7: 68        59   RTNZ     PLA              ;POP RETURN ADDRESS
F6C8: 68        60            PLA
F6C9: 20 3F FF  61            JSR   RESTORE    ;RESTORE 6502 REG CONTENTS
F6CC: 6C 1E 00  62            JMP   (R15L)     ;RETURN TO 6502 CODE VIA PC
F6CF: B1 1E     63   SETZ     LDA   (R15L),Y   ;HIGH-ORDER BYTE OF CONSTANT
F6D1: 95 01     64            STA   R0H,X
F6D3: 88        65            DEY
F6D4: B1 1E     66            LDA   (R15L),Y   ;LOW-ORDER BYTE OF CONSTANT
F6D6: 95 00     67            STA   R0L,X
F6D8: 98        68            TYA              ;Y-REG CONTAINS 1
F6D9: 38        69            SEC
F6DA: 65 1E     70            ADC   R15L       ;ADD 2 TO PC
F6DC: 85 1E     71            STA   R15L
F6DE: 90 02     72            BCC   SET2
F6E0: E6 1F     73            INC   R15H
F6E2: 60        74   SET2     RTS
F6E3: 02        75   OPTBL    DFB   SET-1      ;1X
F6E4: F9        76   BRTBL    DFB   RTN-1      ;0
F6E5: 04        77            DFB   LD-1       ;2X
F6E6: 9D        78            DFB   BR-1       ;1
F6E7: 0D        79            DFB   ST-1       ;3X
F6E8: 9E        80            DFB   BNC-1      ;2
F6E9: 25        81            DFB   LDAT-1     ;4X
F6EA: AF        82            DFB   BC-1       ;3
F6EB: 16        83            DFB   STAT-1     ;5X
F6EC: B2        84            DFB   BP-1       ;4
F6ED: 47        85            DFB   LDDAT-1    ;6X
F6EE: B9        86            DFB   BM-1       ;5
F6EF: 51        87            DFB   STDAT-1    ;7X
F6F0: C0        88            DFB   BZ-1       ;6
F6F1: 2F        89            DFB   POP-1      ;8X
F6F2: C9        90            DFB   BNZ-1      ;7
F6F3: 5B        91            DFB   STPAT-1    ;9X
F6F4: D2        92            DFB   BM1-1      ;8
F6F5: 85        93            DFB   ADD-1      ;AX
F6F6: DD        94            DFB   BNM1-1     ;9
F6F7: 6E        95            DFB   SUB-1      ;BX
F6F8: 05        96            DFB   BK-1       ;A
F6F9: 33        97            DFB   POPD-1     ;CX
F6FA: E8        98            DFB   RS-1       ;B
F6FB: 70        99            DFB   CPR-1      ;DX
F6FC: 93        100           DFB   BS-1       ;C
F6FD: 1E        101           DFB   INR-1      ;EX
F6FE: E7        102           DFB   NUL-1      ;D
F6FF: 65        103           DFB   DCR-1      ;FX
F700: E7        104           DFB   NUL-1      ;E
F701: E7        105           DFB   NUL-1      ;UNUSED
F702: E7        106           DFB   NUL-1      ;F
F703: 10 CA     107  SET      BPL   SETZ       ;ALWAYS TAKEN
F705: B5 00     108  LD       LDA   R0L,X
                109  BK       EQU   *-1
F707: 85 00     110           STA   R0L
F709: B5 01     111           LDA   R0H,X      ;MOVE RX TO R0
F70B: 85 01     112           STA   R0H
F70D: 60        113           RTS
F70E: A5 00     114  ST       LDA   R0L
F710: 95 00     115           STA   R0L,X      ;MOVE R0 TO RX
F712: A5 01     116           LDA   R0H
F714: 95 01     117           STA   R0H,X
F716: 60        118           RTS
F717: A5 00     119  STAT     LDA   R0L
F719: 81 00     120  STAT2    STA   (R0L,X)    ;STORE BYTE INDIRECT
F71B: A0 00     121           LDY   #$0
F71D: 84 1D     122  STAT3    STY   R14H       ;INDICATE R0 IS RESULT NEG
F71F: F6 00     123  INR      INC   R0L,X
F721: D0 02     124           BNE   INR2       ;INCR RX
F723: F6 01     125           INC   R0H,X
F725: 60        126  INR2     RTS
F726: A1 00     127  LDAT     LDA   (R0L,X)    ;LOAD INDIRECT (RX)
F728: 85 00     128           STA   R0L        ;TO R0
F72A: A0 00     129           LDY   #$0
F72C: 84 01     130           STY   R0H        ;ZERO HIGH-ORDER R0 BYTE
F72E: F0 ED     131           BEQ   STAT3      ;ALWAYS TAKEN
F730: A0 00     132  POP      LDY   #$0        ;HIGH ORDER BYTE = 0
F732: F0 06     133           BEQ   POP2       ;ALWAYS TAKEN
F734: 20 66 F7  134  POPD     JSR   DCR        ;DECR RX
F737: A1 00     135           LDA   (R0L,X)    ;POP HIGH ORDER BYTE @RX
F739: A8        136           TAY              ;SAVE IN Y-REG
F73A: 20 66 F7  137  POP2     JSR   DCR        ;DECR RX
F73D: A1 00     138           LDA   (R0L,X)    ;LOW-ORDER BYTE
F73F: 85 00     139           STA   R0L        ;TO R0
F741: 84 01     140           STY   R0H
F743: A0 00     141  POP3     LDY   #$0        ;INDICATE R0 AS LAST RESULT REG
F745: 84 1D     142           STY   R14H
F747: 60        143           RTS
F748: 20 26 F7  144  LDDAT    JSR   LDAT       ;LOW-ORDER BYTE TO R0, INCR RX
F74B: A1 00     145           LDA   (R0L,X)    ;HIGH-ORDER BYTE TO R0
F74D: 85 01     146           STA   R0H
F74F: 4C 1F F7  147           JMP   INR        ;INCR RX
F752: 20 17 F7  148  STDAT    JSR   STAT       ;STORE INDIRECT LOW-ORDER
F755: A5 01     149           LDA   R0H        ;BYTE AND INCR RX.  THEN
F757: 81 00     150           STA   (R0L,X)    ;STORE HIGH-ORDER BYTE.
F759: 4C 1F F7  151           JMP   INR        ;INCR RX AND RETURN
F75C: 20 66 F7  152  STPAT    JSR   DCR        ;DECR RX
F75F: A5 00     153           LDA   R0L
F761: 81 00     154           STA   (R0L,X)    ;STORE R0 LOW BYTE @RX
F763: 4C 43 F7  155           JMP   POP3       ;INDICATE R0 AS LAST RSLT REG
F766: B5 00     156  DCR      LDA   R0L,X
F768: D0 02     157           BNE   DCR2       ;DECR RX
F76A: D6 01     158           DEC   R0H,X
F76C: D6 00     159  DCR2     DEC   R0L,X
F76E: 60        160           RTS
F76F: A0 00     161  SUB      LDY   #$0        ;RESULT TO R0
F771: 38        162  CPR      SEC              ;NOTE Y-REG = 13*2 FOR CPR
F772: A5 00     163           LDA   R0L
F774: F5 00     164           SBC   R0L,X
F776: 99 00 00  165           STA   R0L,Y      ;R0-RX TO RY
F779: A5 01     166           LDA   R0H
F77B: F5 01     167           SBC   R0H,X
F77D: 99 01 00  168  SUB2     STA   R0H,Y
F780: 98        169           TYA              ;LAST RESULT REG*2
F781: 69 00     170           ADC   #$0        ;CARRY TO LSB
F783: 85 1D     171           STA   R14H
F785: 60        172           RTS
F786: A5 00     173  ADD      LDA   R0L
F788: 75 00     174           ADC   R0L,X
F78A: 85 00     175           STA   R0L        ;R0+RX TO R0
F78C: A5 01     176           LDA   R0H
F78E: 75 01     177           ADC   R0H,X
F790: A0 00     178           LDY   #$0        ;R0 FOR RESULT
F792: F0 E9     179           BEQ   SUB2       ;FINISH ADD
F794: A5 1E     180  BS       LDA   R15L       ;NOTE X-REG IS 12*2!
F796: 20 19 F7  181           JSR   STAT2      ;PUSH LOW PC BYTE VIA R12
F799: A5 1F     182           LDA   R15H
F79B: 20 19 F7  183           JSR   STAT2      ;PUSH HIGH-ORDER PC BYTE
F79E: 18        184  BR       CLC
F79F: B0 0E     185  BNC      BCS   BNC2       ;NO CARRY TEST
F7A1: B1 1E     186  BR1      LDA   (R15L),Y   ;DISPLACEMENT BYTE
F7A3: 10 01     187           BPL   BR2
F7A5: 88        188           DEY
F7A6: 65 1E     189  BR2      ADC   R15L       ;ADD TO PC
F7A8: 85 1E     190           STA   R15L
F7AA: 98        191           TYA
F7AB: 65 1F     192           ADC   R15H
F7AD: 85 1F     193           STA   R15H
F7AF: 60        194  BNC2     RTS
F7B0: B0 EC     195  BC       BCS   BR
F7B2: 60        196           RTS
F7B3: 0A        197  BP       ASL              ;DOUBLE RESULT-REG INDEX
F7B4: AA        198           TAX              ;TO X REG FOR INDEXING
F7B5: B5 01     199           LDA   R0H,X      ;TEST FOR PLUS
F7B7: 10 E8     200           BPL   BR1        ;BRANCH IF SO
F7B9: 60        201           RTS
F7BA: 0A        202  BM       ASL              ;DOUBLE RESULT-REG INDEX
F7BB: AA        203           TAX
F7BC: B5 01     204           LDA   R0H,X      ;TEST FOR MINUS
F7BE: 30 E1     205           BMI   BR1
F7C0: 60        206           RTS
F7C1: 0A        207  BZ       ASL              ;DOUBLE RESULT-REG INDEX
F7C2: AA        208           TAX
F7C3: B5 00     209           LDA   R0L,X      ;TEST FOR ZERO
F7C5: 15 01     210           ORA   R0H,X      ;(BOTH BYTES)
F7C7: F0 D8     211           BEQ   BR1        ;BRANCH IF SO
F7C9: 60        212           RTS
F7CA: 0A        213  BNZ      ASL              ;DOUBLE RESULT-REG INDEX
F7CB: AA        214           TAX
F7CC: B5 00     215           LDA   R0L,X      ;TEST FOR NON-ZERO
F7CE: 15 01     216           ORA   R0H,X      ;(BOTH BYTES)
F7D0: D0 CF     217           BNE   BR1        ;BRANCH IF SO
F7D2: 60        218           RTS
F7D3: 0A        219  BM1      ASL              ;DOUBLE RESULT-REG INDEX
F7D4: AA        220           TAX
F7D5: B5 00     221           LDA   R0L,X      ;CHECK BOTH BYTES
F7D7: 35 01     222           AND   R0H,X      ;FOR $FF (MINUS 1)
F7D9: 49 FF     223           EOR   #$FF
F7DB: F0 C4     224           BEQ   BR1        ;BRANCH IF SO
F7DD: 60        225           RTS
F7DE: 0A        226  BNM1     ASL              ;DOUBLE RESULT-REG INDEX
F7DF: AA        227           TAX
F7E0: B5 00     228           LDA   R0L,X
F7E2: 35 01     229           AND   R0H,X      ;CHECK BOTH BYTES FOR NO $FF
F7E4: 49 FF     230           EOR   #$FF
F7E6: D0 B9     231           BNE   BR1        ;BRANCH IF NOT MINUS 1
F7E8: 60        232  NUL      RTS
F7E9: A2 18     233  RS       LDX   #$18       ;12*2 FOR R12 AS STACK POINTER
F7EB: 20 66 F7  234           JSR   DCR        ;DECR STACK POINTER
F7EE: A1 00     235           LDA   (R0L,X)    ;POP HIGH RETURN ADDRESS TO PC
F7F0: 85 1F     236           STA   R15H
F7F2: 20 66 F7  237           JSR   DCR        ;SAME FOR LOW-ORDER BYTE
F7F5: A1 00     238           LDA   (R0L,X)
F7F7: 85 1E     239           STA   R15L
F7F9: 60        240           RTS
F7FA: 4C C7 F6  241  RTN      JMP   RTNZ



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- WOZPAK Sweet-16 article by Steve Wozniak 
+------------------------------------------------------------------------

SWEET 16: A Pseudo 16 Bit Microprocessor

by Steve Wozniak

Description:
------------

While writing APPLE BASIC for a 6502 microprocessor, I repeatedly
encountered a variant of MURPHY'S LAW. Briefly stated, any routine
operating on 16-bit data will require at least twice the code that
it should. Programs making extensive use of 16-bit pointers (such
as compilers, editors, and assemblers) are included in this
category. In my case, even the addition of a few double-byte
instructions to the 6502 would have only slightly alleviated the
problem. What I really needed was a 6502/RCA 1800 hybrid - an
abundance of 16-bit registers and excellent pointer capability.
My solution was to implement a non-existant (meta) 16-bit
processor in software, interpreter style, which I call SWEET 16.

SWEET 16 is based on sixteen 16-bit registers (R0-15), which are
actually 32 memory locations. R0 doubles as the SWEET 16
accumulator (ACC), R15 as the program counter (PC), and R14 as the
status register. R13 holds compare instruction results and R12 is
the subroutine return stack pointer if SWEET 16 subroutines are
used. All other SWEET 16 registers are at the user's unrestricted
disposal.

SWEET 16 instructions fall into register and non-register categories.
The register ops specify one of the sixteen registers to be used as
either a data element or a pointer to data in memory, depending
on the specific instruction. For example INR R5 uses R5 as data
and ST @R7 uses R7 as a pointer to data in memory. Except for the
SET instruction, register ops take one byte of code each. The
non-register ops are primarily 6502 style branches with the second
byte specifying a +/-127 byte displacement relative to the address
of the following instruction. Providing that the prior register op
result meets a specified branch condition, the displacement is
added to the SWEET 16 PC, effecting a branch.

SWEET 16 is intended as a 6502 enhancement package, not a stand
alone processor. A 6502 program switches to SWEET 16 mode with a
subroutine call and subsequent code is interpreted as SWEET 16
instructions. The nonregister op RTN returns the user program to
6502 mode after restoring the internal register contents
(A, X, Y, P, and S). The following example illustrates how to use
SWEET 16.

300  B9 00 02           LDA   IN,Y     ;get a char
303  C9 CD              CMP   #"M"     ;"M" for move
305  D0 09              BNE   NOMOVE   ;No. Skip move
307  20 89 F6           JSR   SW16     ;Yes, call SWEET 16
30A  41         MLOOP   LD    @R1      ;R1 holds source
30B  52                 ST    @R2      ;R2 holds dest. addr.
30C  F3                 DCR   R3       ;Decr. length
30D  07 FB              BNZ   MLOOP    ;Loop until done
30F  00                 RTN            ;Return to 6502 mode.
310  C9 C5      NOMOVE  CMP   #"E"     ;"E" char?
312  D0 13              BEQ   EXIT     ;Yes, exit
314  C8                 INY            ;No, cont.

NOTE:  Registers A, X, Y, P, and S are not disturbed by SWEET 16.

Instruction Descriptions:
-------------------------

The SWEET 16 opcode listing is short and uncomplicated. Excepting
relative branch displacements, hand assembly is trivial. All
register opcodes are formed by combining two Hex digits, one for the
opcode and one to specify a register. For example, opcodes 15 and
45 both specify register R5 while codes 23, 27, and 29 are all ST
ops. Most register ops are assigned in complementary pairs to
facilitate remembering them. Therefore, LD ans ST are opcodes 2N
and 3N respectively, while LD @ and ST @ are codes 4N and 5N.

Opcodes 0 to C (Hex) are assigned to the thirteen non-register ops.
Except for RTN (opcode 0), BK (0A), and RS (0B), the non register
ops are 6502 style branches. The second byte of a branch instruction
contains a +/-127 byte displacement value (in two's complement form)
relative to the address of the instruction immediately following
the branch.

If a specified branch condition is met by the prior register op
result, the displacement is added to the PC effecting a branch.
Except for the BR (Branch always) and BS (Branch to a Subroutine),
the branch opcodes are assigned in complementary pairs, rendering
them easily remembered for hand coding. For example, Branch if Plus
and Branch if Minus are opcodes 4 and 5 while Branch if Zero and
Branch if NonZero are opcodes 6 and 7.

SWEET 16 Opcode Summary:
------------------------

Register OPS-

     1n        SET       Rn     Constant  (Set)
     2n        LD        Rn     (Load)
     3n        ST        Rn     (Store)
     4n        LD        @Rn    (Load Indirect)
     5n        ST        @Rn    (Store Indirect)
     6n        LDD       @Rn    (Load Double Indirect)
     7n        STD       @Rn    (Store Double Indirect)
     8n        POP       @Rn    (Pop Indirect)
     9n        STP       @Rn    (Store POP Indirect)
     An        ADD       Rn     (Add)
     Bn        SUB       Rn     (Sub)
     Cn        POPD      @Rn    (Pop Double Indirect)
     Dn        CPR       Rn     (Compare)
     En        INR       Rn     (Increment)
     Fn        DCR       Rn     (Decrement)

Non-register OPS-

     00        RTN              (Return to 6502 mode)
     01        BR        ea     (Branch always)
     02        BNC       ea     (Branch if No Carry)
     03        BC        ea     (Branch if Carry)
     04        BP        ea     (Branch if Plus)
     05        BM        ea     (Branch if Minus)
     06        BZ        ea     (Branch if Zero)
     07        BNZ       ea     (Branch if NonZero)
     08        BM1       ea     (Branch if Minus 1)
     09        BNM1      ea     (Branch if Not Minus 1)
     0A        BK               (Break)
     0B        RS               (Return from Subroutine)
     0C        BS        ea     (Branch to Subroutine)
     0D                         (Unassigned)
     0E                         (Unassigned)
     0F                         (Unassigned)

Register Instructions:
----------------------

SET:

     SET Rn,Constant     [ 1n Low High ]

     The 2-byte constant is loaded into Rn (n=0 to F, Hex) and
     branch conditions set accordingly. The carry is cleared.

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;R5 now contains $A034

LOAD:

     LD Rn               [ 2n ]

     The ACC (R0) is loaded from Rn and branch conditions set
     according to the data transferred. The carry is cleared and
     contents of Rn are not disturbed.

     EXAMPLE:

     15 34 A0   SET  R5   $A034
     25         LD   R5             ;ACC now contains $A034

STORE:

     ST Rn               [ 3n ]

     The ACC is stored into Rn and branch conditions set according
     to the data transferred. The carry is cleared and the ACC
     contents are not disturbed.

     EXAMPLE:

     25         LD   R5              ;Copy the contents
     36         ST   R6              ;of R5 to R6

LOAD INDIRECT:

     LD @Rn              [ 4n ]

     The low-order ACC byte is loaded from the memory location
     whose address resides in Rn and the high-order ACC byte is
     cleared. Branch conditions reflect the final ACC contents
     which will always be positive and never minus 1. The carry
     is cleared. After the transfer, Rn is incremented by 1.

     EXAMPLE

     15 34 A0   SET  R5   $A034
     45         LD   @R5            ;ACC is loaded from memory
                                    ;location $A034
                                    ;R5 is incr to $A035

STORE INDIRECT:

     ST @Rn              [ 5n ]

     The low-order ACC byte is stored into the memory location
     whose address resides in Rn. Branch conditions reflect the
     2-byte ACC contents. The carry is cleared. After the transfer
     Rn is incremented by 1.

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;Load pointers R5, R6 with
     16 22 90   SET  R6   $9022     ;$A034 and $9022
     45         LD   @R5            ;Move byte from $A034 to $9022
     56         ST   @R6            ;Both ptrs are incremented

LOAD DOUBLE-BYTE INDIRECT:

     LDD @Rn             [ 6n ]

     The low order ACC byte is loaded from memory location whose
     address resides in Rn, and Rn is then incremented by 1. The
     high order ACC byte is loaded from the memory location whose
     address resides in the incremented Rn, and Rn is again
     incremented by 1. Branch conditions reflect the final ACC
     contents. The carry is cleared.

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;The low-order ACC byte is loaded
     65         LDD  @R6            ;from $A034, high-order from
                                    ;$A035, R5 is incr to $A036

STORE DOUBLE-BYTE INDIRECT:

     STD @Rn            [ 7n ]

     The low-order ACC byte is stored into memory location
     whose address resides in Rn, and Rn is the incremented
     by 1. The high-order ACC byte is stored into the memory
     location whose address resides in the incremented Rn, and Rn
     is again incremented by 1. Branch conditions reflect the ACC
     contents which are not disturbed. The carry is cleared.

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;Load pointers R5, R6
     16 22 90   SET  R6   $9022     ;with $A034 and $9022
     65         LDD  @R5            ;Move double byte from
     76         STD  @R6            ;$A034-35 to $9022-23.
                                    ;Both pointers incremented by 2.

POP INDIRECT:

     POP @Rn             [ 8n ]

     The low-order ACC byte is loaded from the memory location
     whose address resides in Rn after Rn is decremented by 1,
     and the high order ACC byte is cleared. Branch conditions
     reflect the final 2-byte ACC contents which will always be
     positive and never minus one. The carry is cleared. Because
     Rn is decremented prior to loading the ACC, single byte
     stacks may be implemented with the ST @Rn and POP @Rn ops
     (Rn is the stack pointer).

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;Init stack pointer
     10 04 00   SET  R0   4         ;Load 4 into ACC
     55         ST   @R5            ;Push 4 onto stack
     10 05 00   SET  R0   5         ;Load 5 into ACC
     55         ST   @R5            ;Push 5 onto stack
     10 06 00   SET  R0   6         ;Load 6 into ACC
     55         ST   @R5            ;Push 6 onto stack
     85         POP  @R5            ;Pop 6 off stack into ACC
     85         POP  @R5            ;Pop 5 off stack
     85         POP  @R5            ;Pop 4 off stack

STORE POP INDIRECT:

     STP @Rn             [ 9n ]

     The low-order ACC byte is stored into the memory location
     whose address resides in Rn after Rn is decremented by 1.
     Branch conditions will reflect the 2-byte ACC contents which
     are not modified. STP @Rn and POP @Rn are used together to
     move data blocks beginning at the greatest address and
     working down. Additionally, single-byte stacks may be
     implemented with the STP @Rn ops.

     EXAMPLE:

     14 34 A0   SET  R4   $A034     ;Init pointers
     15 22 90   SET  R5   $9022
     84         POP  @R4            ;Move byte from
     95         STP  @R5            ;$A033 to $9021
     84         POP  @R4            ;Move byte from
     95         STP  @R5            ;$A032 to $9020

ADD:

     ADD Rn              [ An ]

     The contents of Rn are added to the contents of ACC (R0),
     and the low-order 16 bits of the sum restored in ACC. the
     17th sum bit becomes the carry and the other branch
     conditions reflect the final ACC contents.

     EXAMPLE:

     10 34 76   SET  R0   $7634     ;Init R0 (ACC) and R1
     11 27 42   SET  R1   $4227
     A1         ADD  R1             ;Add R1 (sum=B85B, C clear)
     A0         ADD  R0             ;Double ACC (R0) to $70B6
                                    ;with carry set.

SUBTRACT:

     SUB Rn              [ Bn ]

     The contents of Rn are subtracted from the ACC contents by
     performing a two's complement addition:

     ACC = ACC + Rn + 1

     The low order 16 bits of the subtraction are restored in the
     ACC, the 17th sum bit becomes the carry and other branch
     conditions reflect the final ACC contents. If the 16-bit
     unsigned ACC contents are greater than or equal to the 16-bit
     unsigned Rn contents, then the carry is set, otherwise it is
     cleared. Rn is not disturbed.

     EXAMPLE:

     10 34 76   SET  R0   $7634     ;Init R0 (ACC)
     11 27 42   SET  R1   $4227     ;and R1
     B1         SUB  R1             ;subtract R1
                                    ;(diff=$340D with c set)
     B0         SUB  R0             ;clears ACC. (R0)

POP DOUBLE-BYTE INDIRECT:

     POPD @Rn            [ Cn ]

     Rn is decremented by 1 and the high-order ACC byte is loaded
     from the memory location whose address now resides in Rn. Rn is
     again decremented by 1 and the low-order ACC byte is loaded from
     the corresponding memory location. Branch conditions reflect the
     final ACC contents. The carry is cleared. Because Rn is
     decremented prior to loading each of the ACC halves, double-byte
     stacks may be implemented with the STD @Rn and POPD @Rn ops
     (Rn is the stack pointer).

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;Init stack pointer
     10 12 AA   SET  R0   $AA12     ;Load $AA12 into ACC
     75         STD  @R5            ;Push $AA12 onto stack
     10 34 BB   SET  R0   $BB34     ;Load $BB34 into ACC
     75         STD  @R5            ;Push $BB34 onto stack
     C5         POPD @R5            ;Pop $BB34 off stack
     C5         POPD @R5            ;Pop $AA12 off stack

COMPARE:

     CPR Rn              [ Dn ]

     The ACC (R0) contents are compared to Rn by performing the 16
     bit binary subtraction ACC-Rn and storing the low order 16
     difference bits in R13 for subsequent branch tests. If the 16
     bit unsigned ACC contents are greater than or equal to the 16
     bit unsigned Rn contents, then the carry is set, otherwise it
     is cleared. No other registers, including ACC and Rn, are
     disturbed.

     EXAMPLE:

     15 34 A0           SET  R5   $A034     ;Pointer to memory
     16 BF A0           SET  R6   $A0BF     ;Limit address
     B0         LOOP1   SUB  R0             ;Zero data
     75                 STD  @R5            ;clear 2 locations
                                            ;increment R5 by 2
     25                 LD   R5             ;Compare pointer R5
     D6                 CPR  R6             ;to limit R6
     02 FA              BNC  LOOP1          ;loop if C clear

INCREMENT:

     INR Rn              [ En ]

     The contents of Rn are incremented by 1. The carry is cleared
     and other branch conditions reflect the incremented value.

     EXAMPLE:

     15 34 A0   SET  R5   $A034     ;(Pointer)
     B0         SUB  R0             ;Zero to R0
     55         ST   @R5            ;Clr Location $A034
     E5         INR  R5             ;Incr R5 to $A036
     55         ST   @R5            ;Clrs location $A036
                                    ;(not $A035)

DECREMENT:

     DCR Rn              [ Fn ]

     The contents of Rn are decremented by 1. The carry is cleared
     and other branch conditions reflect the decremented value.

     EXAMPLE:  (Clear 9 bytes beginning at location A034)

     15 34 A0           SET  R5   $A034     ;Init pointer
     14 09 00           SET  R4   9         ;Init counter
     B0                 SUB  R0             ;Zero ACC
     55         LOOP2   ST   @R5            ;Clear a mem byte
     F4                 DCR  R4             ;Decrement count
     07 FC              BNZ  LOOP2          ;Loop until Zero

Non-Register Instructions:
--------------------------

RETURN TO 6502 MODE:

     RTN 00

     Control is returned to the 6502 and program execution continues
     at the location immediately following the RTN instruction. the
     6502 registers and status conditions are restored to their
     original contents (prior to entering SWEET 16 mode).

BRANCH ALWAYS:

     BR ea               [ 01 d ]

     An effective address (ea) is calculated by adding the signed
     displacement byte (d) to the PC. The PC contains the address
     of the instruction immediately following the BR, or the address
     of the BR op plus 2. The displacement is a signed two's
     complement value from -128 to +127. Branch conditions are not
     changed.

     NOTE: The effective address calculation is identical to that
     for 6502 relative branches. The Hex add & Subtract features of
     the APPLE ][ monitor may be used to calculate displacements.

     d = $80  ea = PC + 2 - 128
     d = $81  ea = PC + 2 - 127

     d = $FF  ea = PC + 2 - 1
     d = $00  ea = PC + 2 + 0
     d = $01  ea = PC + 2 + 1

     d = $7E  ea = PC + 2 + 126
     d = $7F  ea = PC + 2 + 127

     EXAMPLE:

     $300:  01 50  BR $352

BRANCH IF NO CARRY:

     BNC ea              [ 02 d ]

     A branch to the effective address is taken only is the carry is
     clear, otherwise execution resumes as normal with the next
     instruction. Branch conditions are not changed.

BRANCH IF CARRY SET:

     BC ea               [ 03 d ]

     A branch is effected only if the carry is set. Branch conditions
     are not changed.

BRANCH IF PLUS:

     BP ea               [ 04 d ]

     A branch is effected only if the prior 'result' (or most
     recently transferred dat) was positive. Branch conditions are
     not changed.

     EXAMPLE: (Clear mem from A034 to A03F)

     15 34 A0           SET  R5   $A034     ;Init pointer
     14 3F A0           SET  R4   $A03F     ;Init limit
     B0         LOOP3   SUB  R0
     55                 ST   @R5            ;Clear mem byte
                                            ;Increment R5
     24                 LD   R4             ;Compare limit
     D5                 CPR  R5             ;to pointer
     04 FA              BP   LOOP3          ;Loop until done

BRANCH IF MINUS:

     BM ea               [ 05 d ]

     A branch is effected only if prior 'result' was minus (negative,
     MSB = 1). Branch conditions are not changed.

BRANCH IF ZERO:

     BZ ea               [ 06 d ]

     A Branch is effected only if the prior 'result' was zero. Branch
     conditions are not changed.

BRANCH IF NONZERO

     BNZ ea              [ 07 d ]

     A branch is effected only if the priot 'result' was non-zero
     Branch conditions are not changed.

BRANCH IF MINUS ONE

     BM1 ea              [ 08 d ]

     A branch is effected only if the prior 'result' was minus one
     ($FFFF Hex). Branch conditions are not changed.

BRANCH IF NOT MINUS ONE

     BNM1 ea             [ 09 d ]

     A branch effected only if the prior 'result' was not minus 1.
     Branch conditions are not changed.

BREAK:

     BK                  [ 0A ]

     A 6502 BRK (break) instruction is executed. SWEET 16 may be
     re-entered non destructively at SW16d after correcting the
     stack pointer to its value prior to executing the BRK.

RETURN FROM SWEET 16 SUBROUTINE:

     RS                  [ 0B ]

     RS terminates execution of a SWEET 16 subroutine and returns to the
     SWEET 16 calling program which resumes execution (in SWEET 16 mode).
     R12, which is the SWEET 16 subroutine return stack pointer, is
     decremented twice. Branch conditions are not changed.

BRANCH TO SWEET 16 SUBROUTINE:

     BS ea               [ 0c d ]

     A branch to the effective address (PC + 2 + d) is taken and
     execution is resumed in SWEET 16 mode. The current PC is pushed
     onto a SWEET 16 subroutine return address stack whose pointer is
     R12, and R12 is incremented by 2. The carry is cleared and branch
     conditions set to indicate the current ACC contents.

     EXAMPLE: (Calling a 'memory move' subroutine to move A034-A03B
              to 3000-3007)

     15 34 A0          SET  R5   $A034     ;Init pointer 1
     14 3B A0          SET  R4   $A03B     ;Init limit 1
     16 00 30          SET  R6   $3000     ;Init pointer 2
     0C 15             BS   MOVE           ;Call move subroutine
     45         MOVE   LD   @R5            ;Move one
     56                ST   @R6            ;byte
     24                LD   R4
     D5                CPR  R5             ;Test if done
     04 FA             BP   MOVE
     0B                RS                  ;Return






Theory of Operation:
--------------------

SWEET 16 execution mode begins with a subroutine call to SW16. All
6502 registers are saved at this time, to be restored when a SWEET
16 RTN instruction returns control to the 6502. If you can tolerate
indefinate 6502 register contents upon exit, approximately 30 usec
may be saved by entering at SW16 + 3. Because this might cause an
inadvertant switch from Hex to Decimal mode, it is advisable to enter
at SW16 the first time through.

After saving the 6502 registers, SWEET 16 initializes its PC (R15)
with the subroutine return address off the 6502 stack. SWEET 16's
PC points to the location preceding the next instruction to be
executed. Following the subroutine call are 1-,2-, and 3-byte
SWEET 16 instructions, stored in ascending memory like 6502
instructions. the main loop at SW16B repeatedly calls the 'execute
instruction' routine to execute it.

Subroutine SW16C increments the PC (R15) and fetches the next opcode,
which is either a register op of the form OP REG with OP between 1
and 15 or a non-register op of the form 0 OP with OP between 0 and 13.
Assuming a register op, the register specification is doubled to
account for the 3 byte SWEET 16 registers and placed in the X-reg
for indexing. Then the instruction type is determined. Register ops
place the doubled register specification in the high order byte of
R14 indicating the 'prior result register' to subsequent branch
instructions. Non-register ops treat the register specifcation
(right-hand half-byte) as their opcode, increment the SWEET 16 PC
to point at the displacement byte of branch instructions, load the
A-reg with the 'prior result register' index for branch condition
testing, and clear the Y-reg.

When is an RTS really a JSR?
----------------------------

Each instruction type has a corresponding subroutine. The subroutine
entry points are stored in a table which is directly indexed into by
the opcode. By assigning all the entries to a common page, only a
single byte to address need be stored per routine. The 6502 indirect
jump might have been used as follows to transfer control to the
appropriate subroutine.

     LDA     #ADRH       ;High-order byte.
     STA     IND+1
     LDA     OPTBL,X     ;Low-order byte.
     STA     IND
     JMP     (IND)

To save code, the subroutine entry address (minus 1) is pushed onto
the stack, high-order byte first. A 6502 RTS (return from subroutine)
is used to pop the address off the stack and into the 6502 PC (after
incrementing by 1). The net result is that the desired subroutine is
reached by executing a subroutine return instruction!

Opcode Subroutines:
-------------------

The register op routines make use of the 6502 'zero page indexed by X'
and 'indexed by X direct' addressing modes to access the specified
registers and indirect data. The 'result' of most register ops is left
in the specified register and can be sensed by subsequent branch
instructions, since the register specification is saved in the high-
order byte of R14. This specification is changed to indicate R0 (ACC)
for ADD and SUB instructions and R13 for the CPR (compare) instruction.

Normally the high-order R14 byte holds the 'prior result register'
index times 2 to account for the 2-byte SWEET 16 registers and the
LSB is zero. If ADD, SUB, or CPR instructions generate carries, then
this index is incremented, setting the LSB.

The SET instruction increments the PC twice, picking up data bytes in
the specified register. In accordance with 6502 convention, the
low-order data byte precedes the high-order byte.

Most SWEET 16 non-register ops are relative branches. The corresponding
subroutines determine whether or not the 'prior result' meets the
specified branch condition and if so, update the SWEET 16 PC by adding
the displacement value (-128 to +127 bytes).

The RTN op restores the 6502 register contents, pops the subroutine
return stack and jumps indirect through the SWEET 16 PC. This transfers
control to the 6502 at the instruction immediately following the
RTN instruction.

The BK op actually executes a 6502 break instruction (BRK), transferring
control to the interrupt handler.

Any number of subroutine levels may be implemented within SWEET 16 code
via the BS (Branch to Subroutine) and RS (Return from Subroutine)
instructions. The user must initialize and otherwise not disturb R12 if
the SWEET 16 subroutine capability is used since it is utilized as the
automatic return stack pointer.

Memory Allocation:
------------------

The only storage that must be allocated for SWEET 16 variables are 32
consecutive locations in page zero for the SWEET 16 registers, four
locations to save the 6502 register contents, and a few levels of the
6502 subroutine return address stack. if you don't need to preserve the
6502 register contents, delete the SAVE and RESTORE subroutines and the
corresponding subroutine calls. This will free the four page zero
locations ASAV, XSAV, YSAV, and PSAV.


User Modifications:
-------------------

You may wish to add some of your own instructions to this implementation of
SWEET 16. If you use the unassigned opcodes $0E and $0F, remember that
SWEET 16 treats these as 2-byte instructions. You may wish to handle the
break instruction as a SWEET 16 call, saving two bytes of code each time
you transfer into SWEET 16 mode. Or you may wish to use the SWEET 16
BK (break) op as a 'CHAROUT' call in the interrupt handler. You can perform
absolute jumps within SWEET 16 by loading the ACC (R0) with the address
you wish to jump to (minus 1) and executing a ST R15 instruction.


+------------------------------------------------------------------------
|  TOPIC -- Apple II -- WOZPAK Sweet-16 article by Dick Sedgewick 
+------------------------------------------------------------------------

SWEET 16 - INTRODUCTION

by Dick Sedgewick

Sweet 16 is probably the least used and least understood seed
in the Apple ][.

In exactly the same sense that Integer and Applesoft Basics
are languages, SWEET 16 is a language. Compared to the
Basics, however, it would be classed as low level with a
strong likeness to conventional 6502 Assembly language.

To use SWEET 16, you must learn the language - and to quote
"WOZ", "The opcode list is short and uncomplicated". "WOZ"
(Steve Wozniak), of course is Mr. Apple, and the creator of
SWEET 16.

SWEET 16 is ROM based in every Apple ][ from $F689 to $F7FC.
It has it's own set of opcodes and instruction sets, and uses
the SAVE and RESTORE routines from the Apple Monitor to
preserve the 6502 registers when in use, allowing SWEET 16 to
be used as a subroutine.

It uses the first 32 locations on zero page to set up its 16
double byte registers, and is therefore not compatible with
Applesoft Basic without some additional efforts.

The original article, "SWEET 16: The 6502 Dream Machine",
first appeared in Byte Magazine, November 1977 and later in
the original "WOZ PAK". The article is included here and
again as test material to help understand the use and
implementation of SWEET 16.

Examples of the use of SWEET 16 are found in the Programmer's
Aid #1, in the Renumber, Append, and Relocate programs. The
Programmer's Aid Operating Manual contains complete source
assembly listings, indexed on page 65.

The demonstration program is written to be introductory and
simple, consisting of three parts:

     1. Integer Basic Program
     2. Machine Language Subroutine
     3. SWEET 16 Subroutine

The task of the program will be to move data. Parameters of
the move will be entered in the Integer Basic Program.

The "CALL 768" ($300) at line 120, enters a 6502 machine
language subroutine having the single purpose of entering
SWEET 16 and subsequently returning to BASIC (addresses $300,
$301, $302, and $312 respectively). The SWEET 16 subroutine
of course performs the move, and is entered at Hex locations
$303 to $311 (see listing Number 3).

After the move, the screen will display three lines of data,
each 8 bytes long, and await entry of a new set of parameters.
The three lines of data displayed on the screen are as
follows:

     Line 1: The first 8 bytes of data starting at $800, which
             is the fixed source data to be moved (in this
             case, the string A$).

     Line 2: The first 8 bytes of data starting at the hex
             address entered as the destination of the
             move (high order byte only).

     Line 3: The first 8 bytes of data starting at $0000 (the
             first four SWEET 16 registers).

The display of 8 bytes of data was chosen to simplify the
illustration of what goes on.

Integer Basic has its own way of recording the string A$.
Because the name chosen for the string "A$" is stored in 2
bytes, a total of five housekeeping bytes precede the data
entered as A$, leaving only three additional bytes available
for display. Integer Basic also adds a housekeeping byte at
the end of a string, known as the "string terminator".

Consequently, for convenience purposes of the display, and to
see the string terminator as the 8th byte, the string data
entered via the keyboard should be limited to two characters,
and will appear as the 6th and 7th bytes. Additionally,
parameters to be entered include the number of bytes to be
moved. A useful range for this demonstration would be 1-8
inclusive, but of course 1-255 will work.

Finally, the starting address of the destination of the move
must be entered. Again, for simplicity, only the high-order
byte is entered, and the program allows a choice between
Decimal 9 and high-order byte of program pointer 1, to avoid
unnecessary problems (in this demonstration enter a decimal
number between 9 and 144 for a 48K APPLE).

The 8 bytes of data displayed starting at $00 will enable one
to observe the condition of the SWEET 16 registers after a
move has been accomplished, and thereby understand how the
SWEET 16 program works.

From the article "SWEET 16: A 6502 Dream Machine", remember
that SWEET 16 can establish 16 double byte registers starting
at $00. This means that SWEET 16 can use the first 32
addresses on zero page.

The "events" occurring in this demonstration program can be
studied in the first four SWEET 16 registers. Therefore, the
8 byte display starting at $0000 is large enough for this
purpose.

These four registers are established as R0, R1, R2, R3:

R0        $0000     &   0001       -SWEET 16 accumulator
R1        $0002     &   0003       -Source address
R2        $0004     &   0005       -Destination address
R3        $0006     &   0007       -Number of bytes to move
 .
 .
 .
R14       $001C     &   001D       -Prior result register
R15       $001E     &   001F       -SWEET 16 Program counter

Additionally, an examination of registers R14 and R15 will
extend and understanding of SWEET 16, as fully explained in
the "WOZ" text. Notice that the high order byte of R14,
(located at $1D) contains $06, and is the doubled register
specification (3X2=$06). R15, the SWEET 16 program counter
contains the address of the next operation as it did for each
step during execution of the program, which was $0312 when
execution ended and the 6502 code resumed.

To try a sample run, enter the Integer Basic program as shown
in Listing #1. Of course, REM statements can be omitted, and
line 10 is only helpful if the machine code is to be stored
on disk. Listing #2 must also be entered starting at $300.

NOTE: A 6502 disassembly does not look like listing #3, but
the SOURCEROR disassembler would create a correct disassembly.

     Enter "RUN" and hit RETURN
     Enter "12" and hit RETURN (A$ - A$ string data)
     Enter "18" and hit RETURN (high-order byte of destination)

The display should appear as follows:

     $0800-C1 40 00 10 08 B1 B2 1E  (SOURCE)
     $0A00-C1 40 00 10 08 B1 B2 1E  (Dest.)
     $0000-1E 00 08 08 08 0A 00 00  (SWEET 16)

NOTE: The 8 bytes stored at $0A00 are identical to the 8
bytes starting at $0800, indicating that an accurate move of 8
bytes length has been made. They are moved one byte at a
time starting with token C1 and ending with token 1E. If
moving less than 8 bytes, the data following the moved data
would be whatever existed at those locations before the move.

The bytes have the following significance:

A Token$

     C1     40   00    10    08     B1     B2        1E
     ---------  ----   --------     ---------        --
         |       |        |          |     |       String
        VN      DSP      NVA       DATA   DATA   Terminator

The SWEET 16 registers are as shown:

     low   high     low   high     low   high     low   high
$0000 1E    00       08    08       08    0A       00    00
     ----------     ----------     ----------     ----------
         |              |              |              |
      register       register       register       register
         R0             R1             R2             R3
       (acc)         (source)        (dest)        (#bytes)

The low order byte of R0, the SWEET 16 accumulator, has $1E
in it, the last byte moved (the 8th).

The low order byte of the source register R1 started as $00
and was incremented eight times, once for each byte of moved
data.

The high order byte of the destination register R2 contains
$0A, which was entered at 10 (the variable) and poked into
the SWEET 16 code. The low-order byte of R2 was incremented
exactly like R1.

Finally, register R3, the register that stores the number of
bytes to be moved, has been poked to 8 (the variable B) and
decremented eight times as each byte got moved, ending up
$0000.

By entering character strings and varying the number of bytes
to be moved, the SWEET 16 registers can be observed and the
contents predicted.

Working with this demonstration program, and study of the
text material will enable you to write SWEET 16 programs that
perform additional 16 bit manipulations. The unassigned
opcodes mentioned in the "WOZ Dream Machine" article should
present a most interesting opportunity to "play".

SWEET 16 as a language - or tool - opens a new direction to
Apple ][ owners without spending a dime, and it's been there
all the time.

"Apple-ites" who desire to learn machine language programming,
can use SWEET 16 as a starting point. With this text
material to use, and less opcodes to learn, a user can
quickly be effective.


Listing #1

>List
     10     PRINT "[D]BLOAD SWEET":  REM CTRL D
     20     CALL - 936: DIM A $ (10)
     30     INPUT "ENTER STRING A $ " , A $
     40     INPUT "ENTER # BYTES " , B
     50     IF NOT B THEN 40 : REM AT LEAST 1
     60     POKE 778 , B : REM POKE LENGTH
     70     INPUT "ENTER DESTINATION " , A
     80     IF A > PEEK (203) - 1 THEN 70
     90     IF A < PEEK (205) + 1 THEN 70
     100    POKE 776 , A : REM POKE DESTINATION
     110    M = 8 : GOSUB 160 : REM DISPLAY
     120    CALL 768 : REM GOTO $0300
     130    M = A : GOSUB 160 : REM DISPLAY
     140    M = O : GOSUB 160 : REM DISPLAY
     150    PRINT : PRINT : GOTO 30
     160    POKE 60 , 0 : POKE 61 , M
     170    CALL -605 : RETURN : REM XAM8 IN MONITOR


Listing #2

     300:20 89 F6 11 00 08 12 00 00 13 00 00 41 52
         F3 07 FB 00 60


Listing #3

SWEET 16

     $300  20  89  F6   JSR    $F689
     $303  11  00  08   SET    R1  source address
     $306  12  00  00   SET    R2  destination address
                         A
     $309  13  00  00   SET    R3  length
                         B
     $30C  41           LD     @R1
     $30D  52           ST     @R2
     $30E  F3           DCR    R3
     $30F  07           BNZ    $30C
     $311  00           RTN
     $312  60           RTS

Data will be poked from the Integer Basic program:

          "A"       from Line 100
          "B"       from Line 60



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Red Book Mini-Assembler listing 
+------------------------------------------------------------------------

                1    ***********************
                2    *                     *
                3    *      APPLE-II       *
                4    *   MINI-ASSEMBLER    *
                5    *                     *
                6    *  COPYRIGHT 1977 BY  *
                7    * APPLE COMPUTER INC. *
                8    *                     *
                9    * ALL RIGHTS RESERVED *
                10   *                     *
                11   *     S. WOZNIAK      *
                12   *      A. BAUM        *
                13   ***********************
                14                             ; TITLE "APPLE-II MINI-ASSEMBLER"
                15   FORMAT   EQU   $2E
                16   LENGTH   EQU   $2F
                17   MODE     EQU   $31
                18   PROMPT   EQU   $33
                19   YSAV     EQU   $34
                20   L        EQU   $35
                21   PCL      EQU   $3A
                22   PCH      EQU   $3B
                23   A1H      EQU   $3D
                24   A2L      EQU   $3E
                25   A2H      EQU   $3F
                26   A4L      EQU   $42
                27   A4H      EQU   $43
                28   FMT      EQU   $44
                29   IN       EQU   $200
                30   INSDS2   EQU   $F88E
                31   INSTDSP  EQU   $F8D0
                32   PRBL2    EQU   $F94A
                33   PCADJ    EQU   $F953
                34   CHAR1    EQU   $F9B4
                35   CHAR2    EQU   $F9BA
                36   MNEML    EQU   $F9C0
                37   MNEMR    EQU   $FA00
                38   CURSUP   EQU   $FC1A
                39   GETLNZ   EQU   $FD67
                40   COUT     EQU   $FDED
                41   BL1      EQU   $FE00
                42   A1PCLP   EQU   $FE78
                43   BELL     EQU   $FF3A
                44   GETNUM   EQU   $FFA7
                45   TOSUB    EQU   $FFBE
                46   ZMODE    EQU   $FFC7
                47   CHRTBL   EQU   $FFCC
                48            ORG   $F500
F500: E9 81     49   REL      SBC   #$81       ;IS FMT COMPATIBLE
F502: 4A        50            LSR              ;WITH RELATIVE MODE?
F503: D0 14     51            BNE   ERR3       ;  NO.
F505: A4 3F     52            LDY   A2H
F507: A6 3E     53            LDX   A2L        ;DOUBLE DECREMENT
F509: D0 01     54            BNE   REL2
F50B: 88        55            DEY
F50C: CA        56   REL2     DEX
F50D: 8A        57            TXA
F50E: 18        58            CLC
F50F: E5 3A     59            SBC   PCL        ;FORM ADDR-PC-2
F511: 85 3E     60            STA   A2L
F513: 10 01     61            BPL   REL3
F515: C8        62            INY
F516: 98        63   REL3     TYA
F517: E5 3B     64            SBC   PCH
F519: D0 6B     65   ERR3     BNE   ERR        ;ERROR IF >1-BYTE BRANCH
F51B: A4 2F     66   FINDOP   LDY   LENGTH
F51D: B9 3D 00  67   FNDOP2   LDA   A1H,Y      ;MOVE INST TO (PC)
F520: 91 3A     68            STA   (PCL),Y
F522: 88        69            DEY
F523: 10 F8     70            BPL   FNDOP2
F525: 20 1A FC  71            JSR   CURSUP
F528: 20 1A FC  72            JSR   CURSUP     ;RESTORE CURSOR
F52B: 20 D0 F8  73            JSR   INSTDSP    ;TYPE FORMATTED LINE
F52E: 20 53 F9  74            JSR   PCADJ      ;UPDATE PC
F531: 84 3B     75            STY   PCH
F533: 85 3A     76            STA   PCL
F535: 4C 95 F5  77            JMP   NXTLINE    ;GET NEXT LINE
F538: 20 BE FF  78   FAKEMON3 JSR   TOSUB      ;GO TO DELIM HANDLER
F53B: A4 34     79            LDY   YSAV       ;RESTORE Y-INDEX
F53D: 20 A7 FF  80   FAKEMON  JSR   GETNUM     ;READ PARAM
F540: 84 34     81            STY   YSAV       ;SAVE Y-INDEX
F542: A0 17     82            LDY   #$17       ;INIT DELIMITER INDEX
F544: 88        83   FAKEMON2 DEY              ;CHECK NEXT DELIM
F545: 30 4B     84            BMI   RESETZ     ;ERR IF UNRECOGNIZED DELIM
F547: D9 CC FF  85            CMP   CHRTBL,Y   ;COMPARE WITH DELIM TABLE
F54A: D0 F8     86            BNE   FAKEMON2   ;NO MATCH
F54C: C0 15     87            CPY   #$15       ;MATCH, IS IT CR?
F54E: D0 E8     88            BNE   FAKEMON3   ;NO, HANDLE IT IN MONITOR
F550: A5 31     89            LDA   MODE
F552: A0 00     90            LDY   #$0
F554: C6 34     91            DEC   YSAV
F556: 20 00 FE  92            JSR   BL1        ;HANDLE CR OUTSIDE MONITOR
F559: 4C 95 F5  93            JMP   NXTLINE
F55C: A5 3D     94   TRYNEXT  LDA   A1H        ;GET TRIAL OPCODE
F55E: 20 8E F8  95            JSR   INSDS2     ;GET FMT+LENGTH FOR OPCODE
F561: AA        96            TAX
F562: BD 00 FA  97            LDA   MNEMR,X    ;GET LOWER MNEMONIC BYTE
F565: C5 42     98            CMP   A4L        ;MATCH?
F567: D0 13     99            BNE   NEXTOP     ;NO, TRY NEXT OPCODE.
F569: BD C0 F9  100           LDA   MNEML,X    ;GET UPPER MNEMONIC BYTE
F56C: C5 43     101           CMP   A4H        ;MATCH?
F56E: D0 0C     102           BNE   NEXTOP     ;NO, TRY NEXT OPCODE
F570: A5 44     103           LDA   FMT
F572: A4 2E     104           LDY   FORMAT     ;GET TRIAL FORMAT
F574: C0 9D     105           CPY   #$9D       ;TRIAL FORMAT RELATIVE?
F576: F0 88     106           BEQ   REL        ;YES.
F578: C5 2E     107  NREL     CMP   FORMAT     ;SAME FORMAT?
F57A: F0 9F     108           BEQ   FINDOP     ;YES.
F57C: C6 3D     109  NEXTOP   DEC   A1H        ;NO, TRY NEXT OPCODE
F57E: D0 DC     110           BNE   TRYNEXT
F580: E6 44     111           INC   FMT        ;NO MORE, TRY WITH LEN=2
F582: C6 35     112           DEC   L          ;WAS L=2 ALREADY?
F584: F0 D6     113           BEQ   TRYNEXT    ;NO.
F586: A4 34     114  ERR      LDY   YSAV       ;YES, UNRECOGNIZED INST.
F588: 98        115  ERR2     TYA
F589: AA        116           TAX
F58A: 20 4A F9  117           JSR   PRBL2      ;PRINT ^ UNDER LAST READ
F58D: A9 DE     118           LDA   #$DE       ;CHAR TO INDICATE ERROR
F58F: 20 ED FD  119           JSR   COUT       ;POSITION.
F592: 20 3A FF  120  RESETZ   JSR   BELL
F595: A9 A1     121  NXTLINE  LDA   #$A1       ;'!'
F597: 85 33     122           STA   PROMPT     ;INITIALIZE PROMPT
F599: 20 67 FD  123           JSR   GETLNZ     ;GET LINE.
F59C: 20 C7 FF  124           JSR   ZMODE      ;INIT SCREEN STUFF
F59F: AD 00 02  125           LDA   IN         ;GET CHAR
F5A2: C9 A0     126           CMP   #$A0       ;ASCII BLANK?
F5A4: F0 13     127           BEQ   SPACE      ;YES
F5A6: C8        128           INY
F5A7: C9 A4     129           CMP   #$A4       ;ASCII '$' IN COL 1?
F5A9: F0 92     130           BEQ   FAKEMON    ;YES, SIMULATE MONITOR
F5AB: 88        131           DEY              ;NO, BACKUP A CHAR
F5AC: 20 A7 FF  132           JSR   GETNUM     ;GET A NUMBER
F5AF: C9 93     133           CMP   #$93       ;':' TERMINATOR?
F5B1: D0 D5     134  ERR4     BNE   ERR2       ;NO, ERR.
F5B3: 8A        135           TXA
F5B4: F0 D2     136           BEQ   ERR2       ;NO ADR PRECEDING COLON.
F5B6: 20 78 FE  137           JSR   A1PCLP     ;MOVE ADR TO PCL, PCH.
F5B9: A9 03     138  SPACE    LDA   #$3        ;COUNT OF CHARS IN MNEMONIC
F5BB: 85 3D     139           STA   A1H
F5BD: 20 34 F6  140  NXTMN    JSR   GETNSP     ;GET FIRST MNEM CHAR.
F5C0: 0A        141  NXTM     ASL
F5C1: E9 BE     142           SBC   #$BE       ;SUBTRACT OFFSET
F5C3: C9 C2     143           CMP   #$C2       ;LEGAL CHAR?
F5C5: 90 C1     144           BCC   ERR2       ;NO.
F5C7: 0A        145           ASL              ;COMPRESS-LEFT JUSTIFY
F5C8: 0A        146           ASL
F5C9: A2 04     147           LDX   #$4
F5CB: 0A        148  NXTM2    ASL              ;DO 5 TRIPLE WORD SHIFTS
F5CC: 26 42     149           ROL   A4L
F5CE: 26 43     150           ROL   A4H
F5D0: CA        151           DEX
F5D1: 10 F8     152           BPL   NXTM2
F5D3: C6 3D     153           DEC   A1H        ;DONE WITH 3 CHARS?
F5D5: F0 F4     154           BEQ   NXTM2      ;YES, BUT DO 1 MORE SHIFT
F5D7: 10 E4     155           BPL   NXTMN      ;NO
F5D9: A2 05     156  FORM1    LDX   #$5        ;5 CHARS IN ADDR MODE
F5DB: 20 34 F6  157  FORM2    JSR   GETNSP     ;GET FIRST CHAR OF ADDR
F5DE: 84 34     158           STY   YSAV
F5E0: DD B4 F9  159           CMP   CHAR1,X    ;FIRST CHAR MATCH PATTERN?
F5E3: D0 13     160           BNE   FORM3      ;NO
F5E5: 20 34 F6  161           JSR   GETNSP     ;YES, GET SECOND CHAR
F5E8: DD BA F9  162           CMP   CHAR2,X    ;MATCHES SECOND HALF?
F5EB: F0 0D     163           BEQ   FORM5      ;YES.
F5ED: BD BA F9  164           LDA   CHAR2,X    ;NO, IS SECOND HALF ZERO?
F5F0: F0 07     165           BEQ   FORM4      ;YES.
F5F2: C9 A4     166           CMP   #$A4       ;NO,SECOND HALF OPTIONAL?
F5F4: F0 03     167           BEQ   FORM4      ;YES.
F5F6: A4 34     168           LDY   YSAV
F5F8: 18        169  FORM3    CLC              ;CLEAR BIT-NO MATCH
F5F9: 88        170  FORM4    DEY              ;BACK UP 1 CHAR
F5FA: 26 44     171  FORM5    ROL   FMT        ;FORM FORMAT BYTE
F5FC: E0 03     172           CPX   #$3        ;TIME TO CHECK FOR ADDR.
F5FE: D0 0D     173           BNE   FORM7      ;NO
F600: 20 A7 FF  174           JSR   GETNUM     ;YES
F603: A5 3F     175           LDA   A2H
F605: F0 01     176           BEQ   FORM6      ;HIGH-ORDER BYTE ZERO
F607: E8        177           INX              ;NO, INCR FOR 2-BYTE
F608: 86 35     178  FORM6    STX   L          ;STORE LENGTH
F60A: A2 03     179           LDX   #$3        ;RELOAD FORMAT INDEX
F60C: 88        180           DEY              ;BACKUP A CHAR
F60D: 86 3D     181  FORM7    STX   A1H        ;SAVE INDEX
F60F: CA        182           DEX              ;DONE WITH FORMAT CHECK?
F610: 10 C9     183           BPL   FORM2      ;NO.
F612: A5 44     184           LDA   FMT        ;YES, PUT LENGTH
F614: 0A        185           ASL              ;IN LOW BITS
F615: 0A        186           ASL
F616: 05 35     187           ORA   L
F618: C9 20     188           CMP   #$20
F61A: B0 06     189           BCS   FORM8      ;ADD "$" IF NONZERO LENGTH
F61C: A6 35     190           LDX   L          ;AND DON'T ALREADY HAVE IT
F61E: F0 02     191           BEQ   FORM8
F620: 09 80     192           ORA   #$80
F622: 85 44     193  FORM8    STA   FMT
F624: 84 34     194           STY   YSAV
F626: B9 00 02  195           LDA   IN,Y       ;GET NEXT NONBLANK
F629: C9 BB     196           CMP   #$BB       ;';' START OF COMMENT?
F62B: F0 04     197           BEQ   FORM9      ;YES
F62D: C9 8D     198           CMP   #$8D       ;CARRIAGE RETURN?
F62F: D0 80     199           BNE   ERR4       ;NO, ERR.
F631: 4C 5C F5  200  FORM9    JMP   TRYNEXT
F634: B9 00 02  201  GETNSP   LDA   IN,Y
F637: C8        202           INY
F638: C9 A0     203           CMP   #$A0       ;GET NEXT NON BLANK CHAR
F63A: F0 F8     204           BEQ   GETNSP
F63C: 60        205           RTS
                206           ORG   $F666
F666: 4C 92 F5  207  MINIASM  JMP   RESETZ



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- Red Book Floating point listing 
+------------------------------------------------------------------------

Apple II Reference Manual (Red Book), January 1978, pages 94-95.

                ***********************
                *                     *
                *  APPLE-II FLOATING  *
                *   POINT ROUTINES    *
                *                     *
                *  COPYRIGHT 1977 BY  *
                * APPLE COMPUTER INC. *
                *                     *
                * ALL RIGHTS RESERVED *
                *                     *
                *     S. WOZNIAK      *
                *                     *
                ***********************
                 TITLE "FLOATING POINT ROUTINES"
                SIGN      EPZ  $F3
                X2        EPZ  $F4
                M2        EPZ  $F5
                X1        EPZ  $F8
                M1        EPZ  $F9
                E         EPZ  $FC
                OVLOC     EQU  $3F5
                          ORG  $F425
F425: 18        ADD       CLC           CLEAR CARRY
F426: A2 02               LDX  #$2      INDEX FOR 3-BYTE ADD.
F428: B5 F9     ADD1      LDA  M1,X
F42A: 75 F5               ADC  M2,X     ADD A BYTE OF MANT2 TO MANT1
F42C: 95 F9               STA  M1,X
F42E: CA                  DEX           INDEX TO NEXT MORE SIGNIF. BYTE.
F42F: 10 F7               BPL  ADD1     LOOP UNTIL DONE.
F431: 60                  RTS           RETURN
F432: 06 F3     MD1       ASL  SIGN     CLEAR LSB OF SIGN.
F434: 20 37 F4            JSR  ABSWAP   ABS VAL OF M1, THEN SWAP WITH M2
F437: 24 F9     ABSWAP    BIT  M1       MANT1 NEGATIVE?
F439: 10 05               BPL  ABSWAP1  NO, SWAP WITH MANT2 AND RETURN.
F43B: 20 A4 F4            JSR  FCOMPL   YES, COMPLEMENT IT.
F43E: E6 F3               INC  SIGN     INCR SIGN, COMPLEMENTING LSB.
F440: 38        ABSWAP1   SEC           SET CARRY FOR RETURN TO MUL/DIV.
F441: A2 04     SWAP      LDX  #$4      INDEX FOR 4 BYTE SWAP.
F443: 94 FB     SWAP1     STY  E-1,X
F445: B5 F7               LDA  X1-1,X   SWAP A BYTE OF EXP/MANT1 WITH
F447: B4 F3               LDY  X2-1,X   EXP/MANT2 AND LEAVE A COPY OF
F449: 94 F7               STY  X1-1,X   MANT1 IN E (3 BYTES).  E+3 USED
F44B: 95 F3               STA  X2-1,X
F44D: CA                  DEX           ADVANCE INDEX TO NEXT BYTE
F44E: D0 F3               BNE  SWAP1    LOOP UNTIL DONE.
F450: 60                  RTS           RETURN
F451: A9 8E     FLOAT     LDA  #$8E     INIT EXP1 TO 14,
F453: 85 F8               STA  X1       THEN NORMALIZE TO FLOAT.
F455: A5 F9     NORM1     LDA  M1       HIGH-ORDER MANT1 BYTE.
F457: C9 C0               CMP  #$C0     UPPER TWO BITS UNEQUAL?
F459: 30 0C               BMI  RTS1     YES, RETURN WITH MANT1 NORMALIZED
F45B: C6 F8               DEC  X1       DECREMENT EXP1.
F45D: 06 FB               ASL  M1+2
F45F: 26 FA               ROL  M1+1     SHIFT MANT1 (3 BYTES) LEFT.
F461: 26 F9               ROL  M1
F463: A5 F8     NORM      LDA  X1       EXP1 ZERO?
F465: D0 EE               BNE  NORM1    NO, CONTINUE NORMALIZING.
F467: 60        RTS1      RTS           RETURN.
F468: 20 A4 F4  FSUB      JSR  FCOMPL   CMPL MANT1,CLEARS CARRY UNLESS 0
F46B: 20 7B F4  SWPALGN   JSR  ALGNSWP  RIGHT SHIFT MANT1 OR SWAP WITH
F46E: A5 F4     FADD      LDA  X2
F470: C5 F8               CMP  X1       COMPARE EXP1 WITH EXP2.
F472: D0 F7               BNE  SWPALGN  IF #,SWAP ADDENDS OR ALIGN MANTS.
F474: 20 25 F4            JSR  ADD      ADD ALIGNED MANTISSAS.
F477: 50 EA     ADDEND    BVC  NORM     NO OVERFLOW, NORMALIZE RESULT.
F479: 70 05               BVS  RTLOG    OV: SHIFT M1 RIGHT, CARRY INTO SIGN
F47B: 90 C4     ALGNSWP   BCC  SWAP     SWAP IF CARRY CLEAR,
                *       ELSE SHIFT RIGHT ARITH.
F47D: A5 F9     RTAR      LDA  M1       SIGN OF MANT1 INTO CARRY FOR
F47F: 0A                  ASL           RIGHT ARITH SHIFT.
F480: E6 F8     RTLOG     INC  X1       INCR X1 TO ADJUST FOR RIGHT SHIFT
F482: F0 75               BEQ  OVFL     EXP1 OUT OF RANGE.
F484: A2 FA     RTLOG1    LDX  #$FA     INDEX FOR 6:BYTE RIGHT SHIFT.
F486: 76 FF     ROR1      ROR  E+3,X
F488: E8                  INX           NEXT BYTE OF SHIFT.
F489: D0 FB               BNE  ROR1     LOOP UNTIL DONE.
F48B: 60                  RTS           RETURN.
F48C: 20 32 F4  FMUL      JSR  MD1      ABS VAL OF MANT1, MANT2
F48F: 65 F8               ADC  X1       ADD EXP1 TO EXP2 FOR PRODUCT EXP
F491: 20 E2 F4            JSR  MD2      CHECK PROD. EXP AND PREP. FOR MUL
F494: 18                  CLC           CLEAR CARRY FOR FIRST BIT.
F495: 20 84 F4  MUL1      JSR  RTLOG1   M1 AND E RIGHT (PROD AND MPLIER)
F498: 90 03               BCC  MUL2     IF CARRY CLEAR, SKIP PARTIAL PROD
F49A: 20 25 F4            JSR  ADD      ADD MULTIPLICAND TO PRODUCT.
F49D: 88        MUL2      DEY           NEXT MUL ITERATION.
F49E: 10 F5               BPL  MUL1     LOOP UNTIL DONE.
F4A0: 46 F3     MDEND     LSR  SIGN     TEST SIGN LSB.
F4A2: 90 BF     NORMX     BCC  NORM     IF EVEN,NORMALIZE PROD,ELSE COMP
F4A4: 38        FCOMPL    SEC           SET CARRY FOR SUBTRACT.
F4A5: A2 03               LDX  #$3      INDEX FOR 3 BYTE SUBTRACT.
F4A7: A9 00     COMPL1    LDA  #$0      CLEAR A.
F4A9: F5 F8               SBC  X1,X     SUBTRACT BYTE OF EXP1.
F4AB: 95 F8               STA  X1,X     RESTORE IT.
F4AD: CA                  DEX           NEXT MORE SIGNIFICANT BYTE.
F4AE: D0 F7               BNE  COMPL1   LOOP UNTIL DONE.
F4B0: F0 C5               BEQ  ADDEND   NORMALIZE (OR SHIFT RT IF OVFL).
F4B2: 20 32 F4  FDIV      JSR  MD1      TAKE ABS VAL OF MANT1, MANT2.
F4B5: E5 F8               SBC  X1       SUBTRACT EXP1 FROM EXP2.
F4B7: 20 E2 F4            JSR  MD2      SAVE AS QUOTIENT EXP.
F4BA: 38        DIV1      SEC           SET CARRY FOR SUBTRACT.
F4BB: A2 02               LDX  #$2      INDEX FOR 3-BYTE SUBTRACTION.
F4BD: B5 F5     DIV2      LDA  M2,X
F4BF: F5 FC               SBC  E,X      SUBTRACT A BYTE OF E FROM MANT2.
F4C1: 48                  PHA           SAVE ON STACK.
F4C2: CA                  DEX           NEXT MORE SIGNIFICANT BYTE.
F4C3: 10 F8               BPL  DIV2     LOOP UNTIL DONE.
F4C5: A2 FD               LDX  #$FD     INDEX FOR 3-BYTE CONDITIONAL MOVE
F4C7: 68        DIV3      PLA           PULL BYTE OF DIFFERENCE OFF STACK
F4C8: 90 02               BCC  DIV4     IF M2<E THEN DON'T RESTORE M2.
F4CA: 95 F8               STA  M2+3,X
F4CC: E8        DIV4      INX           NEXT LESS SIGNIFICANT BYTE.
F4CD: D0 F8               BNE  DIV3     LOOP UNTIL DONE.
F4CF: 26 FB               ROL  M1+2
F4D1: 26 FA               ROL  M1+1     ROLL QUOTIENT LEFT, CARRY INTO LSB
F4D3: 26 F9               ROL  M1
F4D5: 06 F7               ASL  M2+2
F4D7: 26 F6               ROL  M2+1     SHIFT DIVIDEND LEFT
F4D9: 26 F5               ROL  M2
F4DB: B0 1C               BCS  OVFL     OVFL IS DUE TO UNNORMED DIVISOR
F4DD: 88                  DEY           NEXT DIVIDE ITERATION.
F4DE: D0 DA               BNE  DIV1     LOOP UNTIL DONE 23 ITERATIONS.
F4E0: F0 BE               BEQ  MDEND    NORM. QUOTIENT AND CORRECT SIGN.
F4E2: 86 FB     MD2       STX  M1+2
F4E4: 86 FA               STX  M1+1     CLEAR MANT1 (3 BYTES) FOR MUL/DIV.
F4E6: 86 F9               STX  M1
F4E8: B0 0D               BCS  OVCHK    IF CALC. SET CARRY,CHECK FOR OVFL
F4EA: 30 04               BMI  MD3      IF NEG THEN NO UNDERFLOW.
F4EC: 68                  PLA           POP ONE RETURN LEVEL.
F4ED: 68                  PLA
F4EE: 90 B2               BCC  NORMX    CLEAR X1 AND RETURN.
F4F0: 49 80     MD3       EOR  #$80     COMPLEMENT SIGN BIT OF EXPONENT.
F4F2: 85 F8               STA  X1       STORE IT.
F4F4: A0 17               LDY  #$17     COUNT 24 MUL/23 DIV ITERATIONS.
F4F6: 60                  RTS           RETURN.
F4F7: 10 F7     OVCHK     BPL  MD3      IF POSITIVE EXP THEN NO OVFL.
F4F9: 4C F5 03  OVFL      JMP  OVLOC
                          ORG  $F63D
F63D: 20 7D F4  FIX1      JSR  RTAR
F640: A5 F8     FIX       LDA  X1
F642: 10 13               BPL  UNDFL
F644: C9 8E               CMP  #$8E
F646: D0 F5               BNE  FIX1
F648: 24 F9               BIT  M1
F64A: 10 0A               BPL  FIXRTS
F64C: A5 FB               LDA  M1+2
F64E: F0 06               BEQ  FIXRTS
F650: E6 FA               INC  M1+1
F652: D0 02               BNE  FIXRTS
F654: E6 F9               INC  M1
F656: 60        FIXRTS    RTS
F657: A9 00     UNDFL     LDA  #$0
F659: 85 F9               STA  M1
F65B: 85 FA               STA  M1+1
F65D: 60                  RTS



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- WOZPAK Floating point routines description 
+------------------------------------------------------------------------

Wozpak ][, November 1979, pages 109-115.

FLOATING POINT PACKAGE

The mantissa-exponent, or 'floating point' numerical representation is 
widely used by computers to express values with a wide dynamic range.  With 
floating point representation, the number 7.5 x 10^22 requires no more 
memory to store than the number 75 does.  We have allowed for binary 
floating point arithmetic on the APPLE ][ computer by providing a useful 
subroutine package in ROM, which performs the common arithmetic functions.  
Maximum precision is retained by these routines and overflow conditions 
such as 'divide by zero' are trapped for the user.  The 4-byte floating 
point number representation is compatible with future APPLE products such 
as floating point BASIC.

A small amount of memory in Page Zero is dedicated to the floating point 
workspace, including the two floating-point accumulators, FP1 and FP2.  
After placing operands in these accumulators, the user calls subroutines in 
the ROM which perform the desired arithmetic operations, leaving results in 
FP1.  Should an overflow condition occur, a jump to location $3F5 is 
executed, allowing a user routine to take appropriate action.

        FLOATING POINT REPRESENTATION

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
     |     |  | HI  |  |     |  | LOW |
     |_____|  |_____|  |_____|  |_____|

    Exponent       Signed Mantissa

1.  Mantissa

The floating point mantissa is stored in two's complement representation 
with the sign at the most significant bit (MSB) position of the high-order 
mantissa byte.  The mantissa provides 24 bits of precision, including sign, 
and can represent 24-bit integers precisely.  Extending precision is simply 
a matter of adding bytes at the low order end of the mantissa.

Except for magnitudes less than 2^-128 (which lose precision) mantissa are 
normalized by the floating point routines to retain maximum precision.  
That is, the numbers are adjusted so that the upper two high-order mantissa 
bits are unequal.

      HIGH-ORDER MANTISSA BYTE
     01.XXXXXX  Positive mantissa.
     10.XXXXXX  Negative mantissa.
     00.XXXXXX  Unnormalized mantissa.
     11.XXXXXX  Exponent = -128.

2.  Exponent.

The exponent is a binary scaling factor (power of two) which is applied to 
the mantissa.  Ranging from -128 to +127, the exponent is stored in 
standard two's complement representation except for the sign bit which is 
complemented.  This representation allows direct comparison of exponents, 
since they are stored in increasing numerical sequence.  The most negative 
exponent, corresponding to the smallest magnItude, -128, is stored as $00 
($ means hexidecimal) and the most positive, +127, is stored as $FF (all 
ones).

     EXPONENT      STORED AS

      +127      11111111  ($FF)

        +3      10000011  ($83)
        +2      10000010  ($82)
        +1      10000001  ($81)
         0      10000000  ($80)
        -1      01111111  ($7F)
        -2      01111110  ($7E)
        -3      01111101  ($7D)

      -128      00000000  ($00)

The smallest magnitude which can be represented is 2^-150.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
     |  0  |  |  0  |  |  0  |  |  1  |
     |_____|  |_____|  |_____|  |_____|

               HIGH               LOW
       EXP            MANTISSA

The largest positive magnitude which can be represented is +2^128-1.
      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
     | $7F |  | $7F |  | $FF |  | $FF |
     |_____|  |_____|  |_____|  |_____|

       EXP            MANTISSA

 FLOATING POINT REPRESENTATION EXAMPLES

    DECIMAL    HEX        HEX
    NUMBER   EXPONENT   MANTISSA

     + 3        81      60 00 00
     + 4        82      40 00 00
     + 5        82      50 00 00
     + 7        82      70 00 00
     +12        83      60 00 00
     +15        83      78 00 00
     +17        84      44 00 00
     +20        84      50 00 00
     +60        85      78 00 00

     - 3        81      A0 00 00
     - 4        81      80 00 00
     - 5        82      B0 00 00
     - 7        82      90 00 00
     -12        83      A0 00 00
     -15        83      88 00 00
     -17        84      BC 00 00
     -20        84      B0 00 00
     -60        85      88 00 00

FLOATING POINT SUBROUTINE DESCRIPTIONS

FCOMPL subroutine (address $F4A4)

Purpose: FCOMPL is used to negate floating point numbers.

Entry: A normalized or unnormalized value is in FP1 (floating point 
accumulator 1).

Uses: NORM, RTLOG.

Exit: The value in FP1 is negated and then normalized to retain precision.  
The 3-byte FP1 extension, E, may also be altered but FP2 and SIGN are not 
disturbed.  The 6502 A-REG is altered and the X-REG is cleared.  The Y-REG 
is not disturbed.

Caution: Attempting to negate -2^128 will result in an overflow since 
+2^128 is not representable, and a jump to location $3F5 will be executed, 
with the following contents in FP1.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: |  0  |  | $80 |  |  0  |  |  0  |
     |_____|  |_____|  |_____|  |_____|

       X1       M1

Example: Prior to calling FCOMPL, FP1 contains +15.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $78 |  |  0  |  |  0  |   (+15)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

After calling FCOMPL as a subroutine, FP1 contains -15.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $88 |  |  0  |  |  0  |   (+15)
     |_____|  |_____|  |_____|  |_____|

       X1       M1



FADD subroutine (address $F46E)

Purpose: To add two numbers in floating point form.

Entry: The two addends are in FP1 and FP2 respectively.  For maximum 
precision, both should be normalized.

Uses: SWPALGN, ADD, NORM, RTLOG.

Exit: The normalized sum is left in FP1.  FP2 contains the addend of 
greatest magnitude.  E is altered but sign is not.  The A-REG is altered 
and the X-REG is cleared.  The sum mantissa is truncated to 24 bits.

Caution: Overflow may result if the sum is less that -2^128 or greater than 
+2^128-1.  If so, a jump to location $3F5 is executed leaving 0 in X1, and 
twice the proper sum in the mantissa M1.  The sign bit is left in the 
carry, 0 for positive, 1 for negative.

      _____    __________ 
     |     |  |          |
FP1: |  0  |  | X.YYY... |
     |_____|  |__________|

       X1       M1

(For carry=0, true sum=+X.YYY x 2^128)

Example: Prior to calling FADD, FP1 contains +12 and FP2 contains -5.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $60 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP2: | $82 |  | $B0 |  |  0  |  |  0  |   (-5)
     |_____|  |_____|  |_____|  |_____|

       X2       M2

After calling FADD, FP1 contains +7 (FP2 contains +12).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1  | $82 |  | $70 |  |  0  |  |  0  |   (+7)
     |_____|  |_____|  |_____|  |_____|

       X1       M1



FSUB subroutine (address $F468)

Purpose: To subtract two floating point numbers.

Entry: The minuend is in FP1 and the subtrahend is in FP2.  Both should be 
normalized to retain maximum precision prior to calling FSUB.

Uses: FCOMPL, ALGNSWP, FADD, ADD, NORM, RTLOG.

Exit: The normalized difference is in FP1 with the mantissa truncated to 24 
bits.  FP2 holds either the minued or the negated subtrahend, whichever is 
of greater magnitude.  E is altered but SIGN and SCR are not.  the A-REG is 
altered and the X-REG is cleared.  The Y-REG is not disturbed.

Cautions: An exit to location S3F5 is taken if the result is less than 
-2^128 or greater than +2^128-1.  or if the subtrahend is -2^128.

Example: Prior to calling FSUB, FP1 contains +7 (minuend) and FP2 contalns 
-5 (subtrahend).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $82 |  | $70 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP2: | $82 |  | $B0 |  |  0  |  |  0  |   (- 5)
     |_____|  |_____|  |_____|  |_____|

       X2       M2

After calling FSUB, FP1 contains +12 and FP2 contains +7.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $60 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1



FMUL subroutine (address $F48C)

Purpose: To multiply floating point numbers.

Entry: The multiplicand and multiplier must reside in FP1 and FP2 
respectively.  Both should be normalized prior to calling FMUL to retain 
maximum precision.

Uses: MD1, MD2, RTLOG1, ADD, MDEND.

Exit: The signed normalized floating point product is left in FP1.  M1 is 
truncated to contain the 24 most significant mantissa bits (including 
sign).  The absolute value of the multiplier mantissa (M2) is left in FP2.  
E, SIGN, and SCR are altered.  The A- and X-REGs are altered and the Y-REG 
contains $FF upon exit.

Cautions: An exit to location $3F5 is taken if the product is less than 
-2^128 or greater than +2^128-1.

Notes: FMUL will run faster if the absolute value of the multiplier 
mantissa contains fewer '1's than the absolute value of the multiplicand 
mantissa.

Example: Prior to calling FMUL, FP1 contains +12 and FP2 contains -5.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $60 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP2: | $82 |  | $B0 |  |  0  |  |  0  |   (- 5)
     |_____|  |_____|  |_____|  |_____|

       X2       M2

After calling FMUL, FP1 contains -60 and FP2 contains +5.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $85 |  | $88 |  |  0  |  |  0  |   (-60)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP2: | $82 |  | $50 |  |  0  |  |  0  |   (+ 5)
     |_____|  |_____|  |_____|  |_____|

       X2       M2



FDIV subroutine (addr $F4B2)

Purpose: To perform division of floating point numbers.

Entry: The normalized dividend is in FP2 and the normalized divisor is in 
FP1.

Exit: The signed normalized floating point quotient is left in FP1.  The 
mantissa (M1) is truncated to 24 bits.  The 3-bit M1 extension (E) contains 
the absolute value of the divisor mantissa.  MD2, SIGN, and SCR are 
altered.  The A- and X-REGs are altered and the Y-REG is cleared.

Uses: MD1, MD2, MDEND.

Cautions: An exit to location $3F5 is taken if the quotient is less than 
-2^128 or greater than +2^128-1

Notes: MD2 contains the remainder mantissa (equivalent to the MOD 
function).  The remainder exponent is the same as the quotient exponent, or 
1 less if the dividend mantissa magnitude is less than the divisor mantissa 
magnitude.

Example: Prior to calling FDIV, FP1 contains -60 (dividend), and FP2 
contains +12 (divisor).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $85 |  | $80 |  |  0  |  |  0  |   (-60)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP2  | $83 |  | $60 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

After calling FMUL, FP1 contains -5 and M2 contains 0.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $82 |  | $B0 |  |  0  |  |  0  |   (-5)
     |_____|  |_____|  |_____|  |_____|

       X1       M1



FLOAT Subroutine (address $F451)

Purpose: To convert integers to floating point representation.

Entry: A signed (two's complement) 2-byte integer is stored in M1 
(high-order byte) and M1+1 (low-order byte).  M1+2 must be cleared by user 
prior to entry.

Uses: NORM1.

Exit: The normalized floating point equivalent is left in FP1.  E, FP2, 
SIGN, and SCR are not disturbed.  The A-REG contains a copy of the 
high-order mantissa byte upon exit but the X- and Y-REGs are not disturbed.  
The carry is cleared.

Notes: To float a 1-byte integer, place it in M1+1 and clear M1 as well as 
M1+2 prior to calling FLOAT.

FLOAT takes approximately 3 msec. lonqer to convert zero to floating point 
form than other arguments.  The user may check for zero prior to calling 
FLOAT and increase throughput.

           *
           *  LOW-ORDER INT. BYTE IN A-REG
           * HIGH-ORDER BYTE IN Y-REG
           *
85 FA      XFLOAT  STA  M1+1
84 F9              STY  M1    INIT MANT1
A0 00              LDY  #$0
84 FB              STY  M1+2
05 D9              ORA  M1    CHK BOTH
                              BYTES FOR
D0 03              BNE  TOFLOAT  ZERO
85 F8              STA  X1    IF SO CLR X1
60                 RTS        AND RETURN
4C 51 F4  TOFLOAT  JMP  FLOAT ELSE FLOAT
                              INTEGER

Example: Float +274 ($0112 hex)

             CALLING SEQUENCE

A0 01              LDY  #$01  HIGH-ORDER
                              INTEGER BYTE
A9 12              LDA  #$12  LOW-ORDER
                              INTEGER BYTE
84 F9              STY M1
85 FA              STA M1+1
A9 00              LDA #$00
85 F8              STA M1+2
20 51 F4           JSR FLOAT

Upon returning from FLOAT, FP1 contains the floating point representation 
of +274.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1  | $88 |  | $44 |  | $80 |  |  0  |   (+274)
     |_____|  |_____|  |_____|  |_____|

       X1       M1



FIX subroutine (address $F640)

Purpose: To extract the integer portion of a floating point number with 
truncation (ENTIER function).

Entry: A floating point value is in FP1.  It need not be normalized.

Uses: RTAR.

Exit: The two-byte signed two's complement representation of the integer 
portion is left in M1 (high-order byte) and M1+1 (low-order byte).  The 
floating point values +24.63 and -61.2 are converted to the integers +24 
and -61 respectively.  FP1 and E are altered but FP2, E, SIGN, and SCR are 
not.  The A- and X-REGs are altered but the Y-REG is not.

Example: The floating point value +274 is in FP1 prior to calling FIX.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $88 |  | $44 |  | $80 |  |  0  |   (+274)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

After calling FIX, M1 (high-order byte) and M1+1 (low-order byte) contain 
the integer representation of +274 ($0112).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $8E |  | $01 |  | $12 |  |  0  |
     |_____|  |_____|  |_____|  |_____|

       X1       M1

Note: FP1 contains an unnormalized representation of +274 upon exit.



NORM Subroutine (address $F463)

Purpose: To normalize the value in FP1, thus insuring maximum precision.

Entry: A normalized or unnormalized value is in FP1.

Exit: The value in FP1 is normalized.  A zero mantissa will exit with X1=0 
(2 exponent).  If the exponent on exit is -128 (X1=0) then the mantissa 
(M1) is not necessarily normalized (with the two high-order mantissa bits 
unequal).  E, FP2, SIGN, AND SCR are not distubed.  The A-REG is disturbed 
but the X- and Y-REGs are not.  The carry is set.

Example: FP1 contains +12 in unnormalized form (as .0011 x 2 ).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $86 |  | $0C |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       x1       M1

Upon exit from NORM, FP1 contains +12 in normalized form (as 1.1 x 2 ).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $60 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1



NORM1 subroutine (address $F455)

Purpose: To normalize a floating point value in FP1 when it is known the 
exponent is not -128 (X1=0) upon entry.

Entry: An unnormalized number is in FP1.  The exponent byte should not be 0 
for normal use.

Exit: The normalized value is in FP1.  E, FP2, SIGN, and SCR are not not 
disturbed.  The A-REG is altered but the X- and Y-REGs are not.



ADD Subroutine (address $F425)

Purpose: To add the two mantissas (M1 and M2) as 3-byte integers.

Entry: Two mantissas are in M1 (through M1+2) and M2 (through M2+2).  They 
should be aligned, that is with identical exponents, for use in the FADD 
and FSUB subroutines.

Exit: the 24-bit integer sum is in M1 (high-order byte in M1, low-order 
byte in M1+2).  FP2, X1, E, SIGN and SCR are not disturbed.  The A-REG 
contains the high-order byte of the sum, the X-REG contains $FF and the 
Y-REG is not altered.  The carry is the '25th' sum bit.


Example: FP1 contains +5 and FP2 contains +7 prior to calling ADD.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $82 |  | $50 |  |  0  |  |  0  |   (+5)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP2: | $82 |  | $70 |  |  0  |  |  0  |   (+7)
     |_____|  |_____|  |_____|  |_____|

Upon exit, M1 contains the overflow value for +12.  Note that the sign bit 
is incorrect.  This is taken care of with a call to the right shift 
routine.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP:  | $82 |  | $C0 |  |  0  |  |  0  |   (+12)
     |_____|  |_____|  |_____|  |_____|



ABSWAP Subroutine (address $F437)

Purpose: To take the absolute value of FP1 and then swap FP1 with FP2.  
Note that two sequential calls to ABSWAP will take the absolute values of 
both FP1 and FP2 in preparation for a multiply or divide.

Entry: FP1 and FP2 contain floating point values.

Exit: The absolute value of the original FP1 contents are in FP2 and the 
original FP2 contents are in FP1.  The least significant bit of SIGN is 
complemented if a negation takes place (if the original FP1 contents are 
negative) by means of an increment.  SCR and E are used.  The A-REG 
contains a copy of X2, the X-REG is cleared, and the Y-REG is not altered.



RTAR Subroutine (address $F47D)

Purpose: To shift M1 right one bit position while incrementing X1 to 
compensate for scale.  This is roughly the opposite of the NORM subroutine.

Entry: A normalized or unnormalized floating point value is in FP1.

Exit: The 6-byte field MANT1 and E is shifted right one bit arithmetically 
and X1 is incremented by 1 to retain proper scale.  The sign bit of MANT1 
(MSB of M1) is unchanged.  FP2, SIGN, and SCR are not disturbed.  The A-REG 
contains the least significant byte of E (E+2), the X-REG is cleared, and 
the Y-REG is not disturbed.

Caution: If X1 increments of 0 (overflow) then an exit to location $3F5 is 
taken, the A-REG contains the high-order MANT1 byte, M1 and X1 is cleared.  
FP2, SIGN, SCR, and the X- and Y-REGs are not disturbed.

Uses: RTLOG

Example: Prior to calling RTAR, FP1 contains the normalized value -7.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1  | $83 |  | $A0 |  |  0  |  |  0  |   (-7)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

After calling RTAR, FP1 contains the unnormalized value -7 (note that 
precision is lost off the low-order end of M1).

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1  | $84 |  | $D0 |  |  0  |  |  0  |   (-7)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

Note: M1 sign bit is unchanged.



RTLOG subroutine (address $F480)

Purpose: To shift the 6-byte field MANT1 and E one bit to the right (toward 
the least significant bit).  The 6502 carry bit is shifted into the 
high-order M1 bit.  This is useful in correcting binary sum overflows.

Entry: A normalized or unnormalized floating point value is in FP1.  The 
carry must be cleared or set by the user since it is shifted Into the sign 
bit of M1.

Exit: Same as RTAR except that the sign of M1 is not preserved (it is set 
to the value of the carry bit on entry)

Caution: Same as RTAR.

Example: Prior to calling RTLOG, FP1 contains the normalized value -12 and 
the carry is clear.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $83 |  | $A0 |  |  0  |  |  0  |   (-12)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

After calling RTLOG, M1 is shifted one bit to the right and the sign bit is 
clear.  X1 is incremented by 1.

      _____    _____    _____    _____ 
     |     |  |     |  |     |  |     |
FP1: | $84 |  | $50 |  |  0  |  |  0  |   (+20)
     |_____|  |_____|  |_____|  |_____|

       X1       M1

Note: The bit shifted off the end of MANT1 is rotated into the high-order 
bit of the 3-byte extension E.  The 3-byte E field is also shifted one bit 
to the right.



RTLOG1 subroutine (address $F484)

Purpose: To shift MANT1 and E right one bit without adjusting X1.  This is 
used by the multiply loop.  The carry is shifted into the sign bit of 
MANT1.

Entry: M1 and E contain a 6-byte unsigned field.  E is the 3-byte low-order 
extension of MANT1.

Exit: Same as RTLOG except that X1 is not altered and an overflow exit 
cannot occur.



MD2 subroutine (address $F4E2)

Purpose: To clear the 3-byte MANT1 field for FMUL and FDIV, check for 
inital result exponent overflow (and underflow), and initialize the X-REG 
to $17 for loop counting.

Entry: the X-REG is cleared by the user since it is placed in the 3 bytes 
of MANT1.  The A-REG contains the result of an exponent addition (FMUL) or 
subtraction (FDIV).  The carry and sign status bits should be set according 
to this addition or subtraction for overflow and underflow determination.

Exit: The 3 bytes of M1 are cleared (or all set to the contents of the 
X-REG on Entry) and the Y-REG is loaded with $17.  The sign bit of the 
A-REG is complemented and a copy of the A-REG is stored in X1.  FP2, SIGN, 
SCR, and the X-REG are not disturbed.

Uses: NORM.

Caution: Exponent overflow results in an exit to location $3F5.  Exponent 
underflow results in an early return from the calling subroutine (FDIV or 
FMUL) with a floating point zero in FP1.  Because MD2 pops a return address 
off the stack, it may only be called by another subroutine.



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- DDJ Floating point article 
+------------------------------------------------------------------------

Dr. Dobb's Journal, August 1976, pages 17-19.

Floating Point Routines for the 6502

by Roy Rankin, Department of Mechanical Engineering,
   Stanford University, Stanford, CA 94305
   (415) 497-1822

and

   Steve Wozniak, Apple Computer Company
   770 Welch Road, Suite 154
   Palo Alto, CA  94304
   (415) 326-4248

Editor's Note:  Although these routines are for the 6502, it
would appear that one could generate equivalent routines for
most of the "traditional" microprocessors, relatively easily,
by following the flow of the algorithms given in the excellent
comments included in the program listing.  This is particularly
true of the transcendental functions, which were directly modeled
after well-known and proven algorithms, and for which, the
comments are relatively machine independent.

These floating point routines allow 6502 users to perform
most of the more popular and desired floating point and
transcendental functions, namely:

Natural Log - LOG
Common Log - LOG10
Exponential - EXP
Floating Add - FADD
Floating Subtract - FSUB
Floating Multiply - FMUL
Floating Divide - FDIV
Convert Floating to Fixed - FIX
Convert Fixed to Floating - FLOAT

They presume a four-byte floating point operand consisting of
a one-byte exponent ranging from -128 to +127 and a
24-bit two's complement mantissa between 1.0 and 2.0.

The floating point routines were done by Steve Wozniak,
one of the principals in Apple Computer Company.  The
transcendental functions were patterned after those offered by
Hewlett-Packard for their HP2100 minicomputer (with some
modifications), and were done by Roy Rankin, a Ph.D. student
at Stanford University.

There are three error traps; two for overflow, and one for
prohibited logarithm argument.  ERROR (1D06) is the error
exit used in the event of a non-positive log argument.  OVFLW
(1E3B) is the error exit for overflow occuring during calculation
of e to some power.  OVFL (1FE4) is the error exit for
overflow in all of the floating point routines.  There is no
trap for underflow; in such cases, the result is set to 0.0.

All routines are called and exited in a uniform manner:
The arguments(s) are placed in the specified floating point
storage locations (for specifics, see the documentation preceeding
each routine in the listing), then a JSR is used to
enter the desired routine.  Upon normal completion, the
called routine is exited via a subroutine return instruction (RTS).

Note:  The preceeding documentation was written by the Editor, based
on phone conversations with Roy and studying the listing.  There is a
high probability that it is correct.  However, since it was not written
nor reviewed by the authors of these routines, the preceeding 
documentation may contain errors in concept or in detail.
                                                          -- JCW, Jr.


    In the Exponent:
    00 Represents -128
          ...
    7F Represents -1
    80 Represents 0
    81 Represents +1
          ...
    FF Represents +127


  Exponent    Two's Complement Mantissa
  SEEEEEEE  SM.MMMMMM  MMMMMMMM  MMMMMMMM
     n         n+1       n+2       n+3


                *           JULY 5, 1976
                *     BASIC FLOATING POINT ROUTINES
                *       FOR 6502 MICROPROCESSOR
                *       BY R. RANKIN AND S. WOZNIAK
                *
                *     CONSISTING OF:
                *        NATURAL LOG
                *        COMMON LOG
                *        EXPONENTIAL (E**X)
                *        FLOAT      FIX
                *        FADD       FSUB
                *        FMUL       FDIV
                *
                *
                *     FLOATING POINT REPRESENTATION (4-BYTES)
                *                    EXPONENT BYTE 1
                *                    MANTISSA BYTES 2-4
                *
                *     MANTISSA:    TWO'S COMPLIMENT REPRESENTATION WITH SIGN IN
                *       MSB OF HIGH-ORDER BYTE.  MANTISSA IS NORMALIZED WITH AN
                *       ASSUMED DECIMAL POINT BETWEEN BITS 5 AND 6 OF THE HIGH-ORDER
                *       BYTE.  THUS THE MANTISSA IS IN THE RANGE 1. TO 2. EXCEPT
                *       WHEN THE NUMBER IS LESS THAN 2**(-128).
                *
                *     EXPONENT:    THE EXPONENT REPRESENTS POWERS OF TWO.  THE
                *       REPRESENTATION IS 2'S COMPLIMENT EXCEPT THAT THE SIGN
                *       BIT (BIT 7) IS COMPLIMENTED.  THIS ALLOWS DIRECT COMPARISON
                *       OF EXPONENTS FOR SIZE SINCE THEY ARE STORED IN INCREASING
                *       NUMERICAL SEQUENCE RANGING FROM $00 (-128) TO $FF (+127)
                *       ($ MEANS NUMBER IS HEXADECIMAL).
                *
                *     REPRESENTATION OF DECIMAL NUMBERS:    THE PRESENT FLOATING
                *       POINT REPRESENTATION ALLOWS DECIMAL NUMBERS IN THE APPROXIMATE
                *       RANGE OF 10**(-38) THROUGH 10**(38) WITH 6 TO 7 SIGNIFICANT
                *       DIGITS.
                *
                *
0003                   ORG 3       SET BASE PAGE ADRESSES
0003  EA        SIGN   NOP
0004  EA        X2     NOP         EXPONENT 2
0005  00 00 00  M2     BSS 3       MANTISSA 2
0008  EA        X1     NOP         EXPONENT 1
0009  00 00 00  M1     BSS 3       MANTISSA 1
000C            E      BSS 4       SCRATCH
0010            Z      BSS 4
0014            T      BSS 4
0018            SEXP   BSS 4
001C  00        INT    BSS 1
                *
1D00                   ORG $1D00   STARTING LOCATION FOR LOG
                *
                *
                *     NATURAL LOG OF MANT/EXP1 WITH RESULT IN MANT/EXP1
                *
1D00  A5 09     LOG    LDA M1
1D02  F0 02            BEQ ERROR
1D04  10 01            BPL CONT    IF ARG>0 OK
1D06  00        ERROR  BRK         ERROR ARG<=0
                *
1D07  20 1C 1F  CONT   JSR SWAP    MOVE ARG TO EXP/MANT2
1D0A  A5 04            LDA X2      HOLD EXPONENT
1D0C  A0 80            LDY =$80
1D0E  84 04            STY X2      SET EXPONENT 2 TO 0 ($80)
1D10  49 80            EOR =$80    COMPLIMENT SIGN BIT OF ORIGINAL EXPONENT
1D12  85 0A            STA M1+1    SET EXPONENT INTO MANTISSA 1 FOR FLOAT
1D14  A9 00            LDA =0
1D16  85 09            STA M1      CLEAR MSB OF MANTISSA 1
1D18  20 2C 1F         JSR FLOAT   CONVERT TO FLOATING POINT
1D1B  A2 03            LDX =3      4 BYTE TRANSFERS
1D1D  B5 04     SEXP1  LDA X2,X
1D1F  95 10            STA Z,X     COPY MANTISSA TO Z
1D21  B5 08            LDA X1,X
1D23  95 18            STA SEXP,X  SAVE EXPONENT IN SEXP
1D25  BD D1 1D         LDA R22,X   LOAD EXP/MANT1 WITH SQRT(2)
1D28  95 08            STA X1,X
1D2A  CA               DEX
1D2B  10 F0            BPL SEXP1
1D2D  20 4A 1F         JSR FSUB    Z-SQRT(2)
1D30  A2 03            LDX =3      4 BYTE TRANSFER
1D32  B5 08     SAVET  LDA X1,X    SAVE EXP/MANT1 AS T
1D34  95 14            STA T,X
1D36  B5 10            LDA Z,X     LOAD EXP/MANT1 WITH Z
1D38  95 08            STA X1,X
1D3A  BD D1 1D         LDA R22,X   LOAD EXP/MANT2 WITH SQRT(2)
1D3D  95 04            STA X2,X
1D3F  CA               DEX
1D40  10 F0            BPL SAVET
1D42  20 50 1F         JSR FADD    Z+SQRT(2)
1D45  A2 03            LDX =3      4 BYTE TRANSFER
1D47  B5 14     TM2    LDA T,X
1D49  95 04            STA X2,X    LOAD T INTO EXP/MANT2
1D4B  CA               DEX
1D4C  10 F9            BPL TM2
1D4E  20 9D 1F         JSR FDIV    T=(Z-SQRT(2))/(Z+SQRT(2))
1D51  A2 03            LDX =3      4 BYTE TRANSFER
1D53  B5 08     MIT    LDA X1,X
1D55  95 14            STA T,X     COPY EXP/MANT1 TO T AND
1D57  95 04            STA X2,X    LOAD EXP/MANT2 WITH T
1D59  CA               DEX
1D5A  10 F7            BPL MIT
1D5C  20 77 1F         JSR FMUL    T*T
1D5F  20 1C 1F         JSR SWAP    MOVE T*T TO EXP/MANT2
1D62  A2 03            LDX =3      4 BYTE TRANSFER
1D64  BD E1 1D  MIC    LDA C,X
1D67  95 08            STA X1,X    LOAD EXP/MANT1 WITH C
1D69  CA               DEX
1D6A  10 F8            BPL MIC
1D6C  20 4A 1F         JSR FSUB    T*T-C
1D6F  A2 03            LDX =3      4 BYTE TRANSFER
1D71  BD DD 1D  M2MB   LDA MB,X
1D74  95 04            STA X2,X    LOAD EXP/MANT2 WITH MB
1D76  CA               DEX
1D77  10 F8            BPL M2MB
1D79  20 9D 1F         JSR FDIV    MB/(T*T-C)
1D7C  A2 03            LDX =3
1D7E  BD D9 1D  M2A1   LDA A1,X
1D81  95 04            STA X2,X    LOAD EXP/MANT2 WITH A1
1D83  CA               DEX
1D84  10 F8            BPL M2A1
1D86  20 50 1F         JSR FADD    MB/(T*T-C)+A1
1D89  A2 03            LDX =3      4 BYTE TRANSFER
1D8B  B5 14     M2T    LDA T,X
1D8D  95 04            STA X2,X    LOAD EXP/MANT2 WITH T
1D8F  CA               DEX
1D90  10 F9            BPL M2T
1D92  20 77 1F         JSR FMUL    (MB/(T*T-C)+A1)*T
1D95  A2 03            LDX =3      4 BYTE TRANSFER
1D97  BD E5 1D  M2MHL  LDA MHLF,X
1D9A  95 04            STA X2,X    LOAD EXP/MANT2 WITH MHLF (.5)
1D9C  CA               DEX
1D9D  10 F8            BPL M2MHL
1D9F  20 50 1F         JSR FADD    +.5
1DA2  A2 03            LDX =3      4 BYTE TRANSFER
1DA4  B5 18     LDEXP  LDA SEXP,X
1DA6  95 04            STA X2,X    LOAD EXP/MANT2 WITH ORIGINAL EXPONENT
1DA8  CA               DEX
1DA9  10 F9            BPL LDEXP
1DAB  20 50 1F         JSR FADD    +EXPN
1DAE  A2 03            LDX =3      4 BYTE TRANSFER
1DB0  BD D5 1D  MLE2   LDA LE2,X
1DB3  95 04            STA X2,X    LOAD EXP/MANT2 WITH LN(2)
1DB5  CA               DEX
1DB6  10 F8            BPL MLE2
1DB8  20 77 1F         JSR FMUL    *LN(2)
1DBB  60               RTS         RETURN RESULT IN MANT/EXP1
                *
                *     COMMON LOG OF MANT/EXP1 RESULT IN MANT/EXP1
                *
1DBC  20 00 1D  LOG10  JSR LOG     COMPUTE NATURAL LOG
1DBF  A2 03            LDX =3
1DC1  BD CD 1D  L10    LDA LN10,X
1DC4  95 04            STA X2,X    LOAD EXP/MANT2 WITH 1/LN(10)
1DC6  CA               DEX
1DC7  10 F8            BPL L10
1DC9  20 77 1F         JSR FMUL    LOG10(X)=LN(X)/LN(10)
1DCC  60               RTS
                *
1DCD  7E 6F     LN10   DCM 0.4342945
      2D ED
1DD1  80 5A     R22    DCM 1.4142136   SQRT(2)
      02 7A
1DD5  7F 58     LE2    DCM 0.69314718  LOG BASE E OF 2
      B9 0C
1DD9  80 52     A1     DCM 1.2920074
      80 40
1DDD  81 AB     MB     DCM -2.6398577
      86 49
1DE1  80 6A     C      DCM 1.6567626
      08 66
1DE5  7F 40     MHLF   DCM 0.5
      00 00
                *
1E00                   ORG $1E00   STARTING LOCATION FOR EXP
                *
                *     EXP OF MANT/EXP1 RESULT IN MANT/EXP1
                *
1E00  A2 03     EXP    LDX =3      4 BYTE TRANSFER
1E02  BD D8 1E         LDA L2E,X
1E05  95 04            STA X2,X    LOAD EXP/MANT2 WITH LOG BASE 2 OF E
1E07  CA               DEX
1E08  10 F8            BPL EXP+2
1E0A  20 77 1F         JSR FMUL    LOG2(3)*X
1E0D  A2 03            LDX =3      4 BYTE TRANSFER
1E0F  B5 08     FSA    LDA X1,X
1E11  95 10            STA Z,X     STORE EXP/MANT1 IN Z
1E13  CA               DEX
1E14  10 F9            BPL FSA     SAVE Z=LN(2)*X
1E16  20 E8 1F         JSR FIX     CONVERT CONTENTS OF EXP/MANT1 TO AN INTEGER
1E19  A5 0A            LDA M1+1
1E1B  85 1C            STA INT     SAVE RESULT AS INT
1E1D  38               SEC         SET CARRY FOR SUBTRACTION
1E1E  E9 7C            SBC =124    INT-124
1E20  A5 09            LDA M1
1E22  E9 00            SBC =0
1E24  10 15            BPL OVFLW   OVERFLOW INT>=124
1E26  18               CLC         CLEAR CARRY FOR ADD
1E27  A5 0A            LDA M1+1
1E29  69 78            ADC =120    ADD 120 TO INT
1E2B  A5 09            LDA M1
1E2D  69 00            ADC =0
1E2F  10 0B            BPL CONTIN  IF RESULT POSITIVE CONTINUE
1E31  A9 00            LDA =0      INT<-120 SET RESULT TO ZERO AND RETURN
1E33  A2 03            LDX =3      4 BYTE MOVE
1E35  95 08     ZERO   STA X1,X    SET EXP/MANT1 TO ZERO
1E37  CA               DEX
1E38  10 FB            BPL ZERO
1E3A  60               RTS         RETURN
                *
1E3B  00        OVFLW  BRK         OVERFLOW
                *
1E3C  20 2C 1F  CONTIN JSR FLOAT   FLOAT INT
1E3F  A2 03            LDX =3
1E41  B5 10     ENTD   LDA Z,X
1E43  95 04            STA X2,X    LOAD EXP/MANT2 WITH Z
1E45  CA               DEX
1E46  10 F9            BPL ENTD
1E48  20 4A 1F         JSR FSUB    Z*Z-FLOAT(INT)
1E4B  A2 03            LDX =3      4 BYTE MOVE
1E4D  B5 08     ZSAV   LDA X1,X
1E4F  95 10            STA Z,X     SAVE EXP/MANT1 IN Z
1E51  95 04            STA X2,X    COPY EXP/MANT1 TO EXP/MANT2
1E53  CA               DEX
1E54  10 F7            BPL ZSAV
1E56  20 77 1F         JSR FMUL    Z*Z
1E59  A2 03            LDX =3      4 BYTE MOVE
1E5B  BD DC 1E  LA2    LDA A2,X
1E5E  95 04            STA X2,X    LOAD EXP/MANT2 WITH A2
1E60  B5 08            LDA X1,X
1E62  95 18            STA SEXP,X  SAVE EXP/MANT1 AS SEXP
1E64  CA               DEX
1E65  10 F4            BPL LA2
1E67  20 50 1F         JSR FADD    Z*Z+A2
1E6A  A2 03            LDX =3      4 BYTE MOVE
1E6C  BD E0 1E  LB2    LDA B2,X
1E6F  95 04            STA X2,X    LOAD EXP/MANT2 WITH B2
1E71  CA               DEX
1E72  10 F8            BPL LB2
1E74  20 9D 1F         JSR FDIV    T=B/(Z*Z+A2)
1E77  A2 03            LDX =3      4 BYTE MOVE
1E79  B5 08     DLOAD  LDA X1,X
1E7B  95 14            STA T,X     SAVE EXP/MANT1 AS T
1E7D  BD E4 1E         LDA C2,X
1E80  95 08            STA X1,X    LOAD EXP/MANT1 WITH C2
1E82  B5 18            LDA SEXP,X
1E84  95 04            STA X2,X    LOAD EXP/MANT2 WITH SEXP
1E86  CA               DEX
1E87  10 F0            BPL DLOAD
1E89  20 77 1F         JSR FMUL    Z*Z*C2
1E8C  20 1C 1F         JSR SWAP    MOVE EXP/MANT1 TO EXP/MANT2
1E8F  A2 03            LDX =3      4 BYTE TRANSFER
1E91  B5 14     LTMP   LDA T,X
1E93  95 08            STA X1,X    LOAD EXP/MANT1 WITH T
1E95  CA               DEX
1E96  10 F9            BPL LTMP
1E98  20 4A 1F         JSR FSUB    C2*Z*Z-B2/(Z*Z+A2)
1E9B  A2 03            LDX =3      4 BYTE TRANSFER
1E9D  BD E8 1E  LDD    LDA D,X
1EA0  95 04            STA X2,X    LOAD EXP/MANT2 WITH D
1EA2  CA               DEX
1EA3  10 F8            BPL LDD
1EA5  20 50 1F         JSR FADD    D+C2*Z*Z-B2/(Z*Z+A2)
1EA8  20 1C 1F         JSR SWAP    MOVE EXP/MANT1 TO EXP/MANT2
1EAB  A2 03            LDX =3      4 BYTE TRANSFER
1EAD  B5 10     LFA    LDA Z,X
1EAF  95 08            STA X1,X    LOAD EXP/MANT1 WITH Z
1EB1  CA               DEX
1EB2  10 F9            BPL LFA
1EB4  20 4A 1F         JSR FSUB    -Z+D+C2*Z*Z-B2/(Z*Z+A2)
1EB7  A2 03            LDX =3      4 BYTE TRANSFER
1EB9  B5 10     LF3    LDA Z,X
1EBB  95 04            STA X2,X    LOAD EXP/MANT2 WITH Z
1EBD  CA               DEX
1EBE  10 F9            BPL LF3
1EC0  20 9D 1F         JSR FDIV    Z/(**** )
1EC3  A2 03            LDX =3      4 BYTE TRANSFER
1EC5  BD E5 1D  LD12   LDA MHLF,X
1EC8  95 04            STA X2,X    LOAD EXP/MANT2 WITH .5
1ECA  CA               DEX
1ECB  10 F8            BPL LD12
1ECD  20 50 1F         JSR FADD    +Z/(***)+.5
1ED0  38               SEC         ADD INT TO EXPONENT WITH CARRY SET
1ED1  A5 1C            LDA INT     TO MULTIPLY BY
1ED3  65 08            ADC X1      2**(INT+1)
1ED5  85 08            STA X1      RETURN RESULT TO EXPONENT
1ED7  60               RTS         RETURN ANS=(.5+Z/(-Z+D+C2*Z*Z-B2/(Z*Z+A2))*2**(INT+1)
1ED8  80 5C     L2E    DCM 1.4426950409   LOG BASE 2 OF E
      55 1E
1EDC  86 57     A2     DCM 87.417497202
      6A E1
1EE0  89 4D     B2     DCM 617.9722695
      3F 1D
1EE4  7B 46     C2     DCM .03465735903
      FA 70
1EE8  83 4F     D      DCM 9.9545957821
      A3 03
                *
                *
                *     BASIC FLOATING POINT ROUTINES
                *
1F00                   ORG $1F00   START OF BASIC FLOATING POINT ROUTINES
1F00  18        ADD    CLC         CLEAR CARRY
1F01  A2 02            LDX =$02    INDEX FOR 3-BYTE ADD
1F03  B5 09     ADD1   LDA M1,X
1F05  75 05            ADC M2,X    ADD A BYTE OF MANT2 TO MANT1
1F07  95 09            STA M1,X
1F09  CA               DEX         ADVANCE INDEX TO NEXT MORE SIGNIF.BYTE
1F0A  10 F7            BPL ADD1    LOOP UNTIL DONE.
1F0C  60               RTS         RETURN
1F0D  06 03     MD1    ASL SIGN    CLEAR LSB OF SIGN
1F0F  20 12 1F         JSR ABSWAP  ABS VAL OF MANT1, THEN SWAP MANT2
1F12  24 09     ABSWAP BIT M1      MANT1 NEG?
1F14  10 05            BPL ABSWP1  NO,SWAP WITH MANT2 AND RETURN
1F16  20 8F 1F         JSR FCOMPL  YES, COMPLIMENT IT.
1F19  E6 03            INC SIGN    INCR SIGN, COMPLEMENTING LSB
1F1B  38        ABSWP1 SEC         SET CARRY FOR RETURN TO MUL/DIV
                *
                *     SWAP EXP/MANT1 WITH EXP/MANT2
                *
1F1C  A2 04     SWAP   LDX =$04    INDEX FOR 4-BYTE SWAP.
1F1E  94 0B     SWAP1  STY E-1,X
1F20  B5 07            LDA X1-1,X  SWAP A BYTE OF EXP/MANT1 WITH
1F22  B4 03            LDY X2-1,X  EXP/MANT2 AND LEAVEA COPY OF
1F24  94 07            STY X1-1,X  MANT1 IN E(3BYTES). E+3 USED.
1F26  95 03            STA X2-1,X
1F28  CA               DEX         ADVANCE INDEX TO NEXT BYTE
1F29  D0 F3            BNE SWAP1   LOOP UNTIL DONE.
1F2B  60               RTS
                *
                *
                *
                *     CONVERT 16 BIT INTEGER IN M1(HIGH) AND M1+1(LOW) TO F.P.
                *     RESULT IN EXP/MANT1.  EXP/MANT2 UNEFFECTED
                *
                *
1F2C  A9 8E     FLOAT  LDA =$8E
1F2E  85 08            STA X1      SET EXPN TO 14 DEC
1F30  A9 00            LDA =0      CLEAR LOW ORDER BYTE
1F32  85 0B            STA M1+2
1F34  F0 08            BEQ NORM    NORMALIZE RESULT
1F36  C6 08     NORM1  DEC X1      DECREMENT EXP1
1F38  06 0B            ASL M1+2
1F3A  26 0A            ROL M1+1    SHIFT MANT1 (3 BYTES) LEFT
1F3C  26 09            ROL M1
1F3E  A5 09     NORM   LDA M1      HIGH ORDER MANT1 BYTE
1F40  0A               ASL         UPPER TWO BITS UNEQUAL?
1F41  45 09            EOR M1
1F43  30 04            BMI RTS1    YES,RETURN WITH MANT1 NORMALIZED
1F45  A5 08            LDA X1      EXP1 ZERO?
1F47  D0 ED            BNE NORM1   NO, CONTINUE NORMALIZING
1F49  60        RTS1   RTS         RETURN
                *
                *
                *     EXP/MANT2-EXP/MANT1 RESULT IN EXP/MANT1
                *
1F4A  20 8F 1F  FSUB   JSR FCOMPL  CMPL MANT1 CLEARS CARRY UNLESS ZERO
1F4D  20 5D 1F  SWPALG JSR ALGNSW  RIGHT SHIFT MANT1 OR SWAP WITH MANT2 ON CARRY
                *
                *     ADD EXP/MANT1 AND EXP/MANT2 RESULT IN EXP/MANT1
                *
1F50  A5 04     FADD   LDA X2
1F52  C5 08            CMP X1      COMPARE EXP1 WITH EXP2
1F54  D0 F7            BNE SWPALG  IF UNEQUAL, SWAP ADDENDS OR ALIGN MANTISSAS
1F56  20 00 1F         JSR ADD     ADD ALIGNED MANTISSAS
1F59  50 E3     ADDEND BVC NORM    NO OVERFLOW, NORMALIZE RESULTS
1F5B  70 05            BVS RTLOG   OV: SHIFT MANT1 RIGHT. NOTE CARRY IS CORRECT SIGN
1F5D  90 BD     ALGNSW BCC SWAP    SWAP IF CARRY CLEAR, ELSE SHIFT RIGHT ARITH.
1F5F  A5 09     RTAR   LDA M1      SIGN OF MANT1 INTO CARRY FOR
1F61  0A               ASL         RIGHT ARITH SHIFT
1F62  E6 08     RTLOG  INC X1      INCR EXP1 TO COMPENSATE FOR RT SHIFT
1F64  F0 7E            BEQ OVFL    EXP1 OUT OF RANGE.
1F66  A2 FA     RTLOG1 LDX =$FA    INDEX FOR 6 BYTE RIGHT SHIFT
1F68  A9 80     ROR1   LDA =$80
1F6A  B0 01            BCS ROR2
1F6C  0A               ASL
1F6D  56 0F     ROR2   LSR E+3,X   SIMULATE ROR E+3,X
1F6F  15 0F            ORA E+3,X
1F71  95 0F            STA E+3,X
1F73  E8               INX         NEXT BYTE OF SHIFT
1F74  D0 F2            BNE ROR1    LOOP UNTIL DONE
1F76  60               RTS         RETURN
                *
                *
                *     EXP/MANT1 X EXP/MANT2 RESULT IN EXP/MANT1
                *
1F77  20 0D 1F  FMUL   JSR MD1     ABS. VAL OF MANT1, MANT2
1F7A  65 08            ADC X1      ADD EXP1 TO EXP2 FOR PRODUCT EXPONENT
1F7C  20 CD 1F         JSR MD2     CHECK PRODUCT EXP AND PREPARE FOR MUL
1F7F  18               CLC         CLEAR CARRY
1F80  20 66 1F  MUL1   JSR RTLOG1  MANT1 AND E RIGHT.(PRODUCT AND MPLIER)
1F83  90 03            BCC MUL2    IF CARRY CLEAR, SKIP PARTIAL PRODUCT
1F85  20 00 1F         JSR ADD     ADD MULTIPLICAN TO PRODUCT
1F88  88        MUL2   DEY         NEXT MUL ITERATION
1F89  10 F5            BPL MUL1    LOOP UNTIL DONE
1F8B  46 03     MDEND  LSR SIGN    TEST SIGN (EVEN/ODD)
1F8D  90 AF     NORMX  BCC NORM    IF EXEN, NORMALIZE PRODUCT, ELSE COMPLEMENT
1F8F  38        FCOMPL SEC         SET CARRY FOR SUBTRACT
1F90  A2 03            LDX =$03    INDEX FOR 3 BYTE SUBTRACTION
1F92  A9 00     COMPL1 LDA =$00    CLEAR A
1F94  F5 08            SBC X1,X    SUBTRACT BYTE OF EXP1
1F96  95 08            STA X1,X    RESTORE IT
1F98  CA               DEX         NEXT MORE SIGNIFICANT BYTE
1F99  D0 F7            BNE COMPL1  LOOP UNTIL DONE
1F9B  F0 BC            BEQ ADDEND  NORMALIZE (OR SHIFT RIGHT IF OVERFLOW)
                *
                *
                *     EXP/MANT2 / EXP/MANT1 RESULT IN EXP/MANT1
                *
1F9D  20 0D 1F  FDIV   JSR MD1     TAKE ABS VAL OF MANT1, MANT2
1FA0  E5 08            SBC X1      SUBTRACT EXP1 FROM EXP2
1FA2  20 CD 1F         JSR MD2     SAVE AS QUOTIENT EXP
1FA5  38        DIV1   SEC         SET CARRY FOR SUBTRACT
1FA6  A2 02            LDX =$02    INDEX FOR 3-BYTE INSTRUCTION
1FA8  B5 05     DIV2   LDA M2,X
1FAA  F5 0C            SBC E,X     SUBTRACT A BYTE OF E FROM MANT2
1FAC  48               PHA         SAVE ON STACK
1FAD  CA               DEX         NEXT MORE SIGNIF BYTE
1FAE  10 F8            BPL DIV2    LOOP UNTIL DONE
1FB0  A2 FD            LDX =$FD    INDEX FOR 3-BYTE CONDITIONAL MOVE
1FB2  68        DIV3   PLA         PULL A BYTE OF DIFFERENCE OFF STACK
1FB3  90 02            BCC DIV4    IF MANT2<E THEN DONT RESTORE MANT2
1FB5  95 08            STA M2+3,X
1FB7  E8        DIV4   INX         NEXT LESS SIGNIF BYTE
1FB8  D0 F8            BNE DIV3    LOOP UNTIL DONE
1FBA  26 0B            ROL M1+2
1FBC  26 0A            ROL M1+1    ROLL QUOTIENT LEFT, CARRY INTO LSB
1FBE  26 09            ROL M1
1FC0  06 07            ASL M2+2
1FC2  26 06            ROL M2+1    SHIFT DIVIDEND LEFT
1FC4  26 05            ROL M2
1FC6  B0 1C            BCS OVFL    OVERFLOW IS DUE TO UNNORMALIZED DIVISOR
1FC8  88               DEY         NEXT DIVIDE ITERATION
1FC9  D0 DA            BNE DIV1    LOOP UNTIL DONE 23 ITERATIONS
1FCB  F0 BE            BEQ MDEND   NORMALIZE QUOTIENT AND CORRECT SIGN
1FCD  86 0B     MD2    STX M1+2
1FCF  86 0A            STX M1+1    CLR MANT1 (3 BYTES) FOR MUL/DIV
1FD1  86 09            STX M1
1FD3  B0 0D            BCS OVCHK   IF EXP CALC SET CARRY, CHECK FOR OVFL
1FD5  30 04            BMI MD3     IF NEG NO UNDERFLOW
1FD7  68               PLA         POP ONE
1FD8  68               PLA         RETURN LEVEL
1FD9  90 B2            BCC NORMX   CLEAR X1 AND RETURN
1FDB  49 80     MD3    EOR =$80    COMPLIMENT SIGN BIT OF EXP
1FDD  85 08            STA X1      STORE IT
1FDF  A0 17            LDY =$17    COUNT FOR 24 MUL OR 23 DIV ITERATIONS
1FE1  60               RTS         RETURN
1FE2  10 F7     OVCHK  BPL MD3     IF POS EXP THEN NO OVERFLOW
1FE4  00        OVFL   BRK
                *
                *
                *     CONVERT EXP/MANT1 TO INTEGER IN M1 (HIGH) AND M1+1(LOW)
                *      EXP/MANT2 UNEFFECTED
                *
1FE5  20 5F 1F         JSR RTAR    SHIFT MANT1 RT AND INCREMENT EXPNT
1FE8  A5 08     FIX    LDA X1      CHECK EXPONENT
1FEA  C9 8E            CMP =$8E    IS EXPONENT 14?
1FEC  D0 F7            BNE FIX-3   NO, SHIFT
1FEE  60        RTRN   RTS         RETURN
                       END

***************************************************************************
Dr. Dobb's Journal, November/December 1976, page 57.

ERRATA FOR RANKIN'S 6502
FLOATING POINT ROUTINES

Sept. 22, 1976

Dear Jim,

Subsequent to the publication of "Floating Point
Routines for the 6502" (Vol.1, No.7) an error which I made in
the LOG routine came to light which causes improper results
if the argument is less than 1.  The following changes will
correct the error.

1.  After:            CONT JSR SWAP (1D07)
    Add:    A2 00          LDX =0    LOAD X FOR HIGH BYTE OF EXPONENT

2.  After:                 STA M1+1 (1D12)
    Delete:                LDA =0
                           STA M1
    Add:    10 01          BPL *+3   IS EXPONENT NEGATIVE
            CA             DEX       YES, SET X TO $FF
            86 09          STX M1    SET UPPER BYTE OF EXPONENT

3.  Changes 1 and 2 shift the code by 3 bytes so add 3 to the
addresses of the constants LN10 through MHLF whenever
they are referenced.  For example the address of LN10 changes
from 1DCD to 1DD0.  Note also that the entry point for
LOG10 becomes 1DBF.  The routines stays within the page
and hence the following routines (EXP etc.) are not affected.

Yours truly,

Roy Rankin
Dep. of Mech. Eng.
Stanford University



+------------------------------------------------------------------------
|  TOPIC -- Apple II -- IA Floating point article 
+------------------------------------------------------------------------

Interface Age, November 1976, pages 103-111.

Floating Point Routines for the 6502*

    by Roy Rankin
Department of Mechanical Engineering, Stanford University

    and Steve Wozniak
Apple Computer Company

*First appeared in Dr. DOBB's Journal of Computer Calisthenics &
Orthodontia, Box 310, Menlo Park, CA 94025

The following floating point routines represent a joint
effort between Steve Wozniak who wrote the basic float-
ing point routines of FADD, FSUB, FMUL, FDIV and
their support routines and myself, Roy Rankin, who
added FIX, FLOAT, LOG, LOG10, and EXP.  The basic
floating point routines are failry Machine dependent, but
the transcendental programs should be very easy to
transport from one machine to another.  The routines
consist of the following math functions

     * LOG         Natural log
     * LOG10       Base 10 log
     * EXP         Exponential
     * FADD        Floating add
     * FSUB        Floating subtraction
     * FMUL        Floating multiplication
     * FDIV        Floating division
     * FIX         Convert floating to fixed
     * FLOAT       Convert fixed to floating

Two additional routines exchange the contents of
exp/mant1 with exp/mant2 and compliments exp/
mant1.  These routines are

SWAP          Exchange the contents of exp/mant 1 with
              exp/mant 2
FCOMPL        Compliment exp/mant 1

Floating point numbers are represented by 4 bytes as
shown in the following

 +- SIGN BIT     +- SIGN BIT
 |  0 = +        |  0 = +
 |  1 = -        |  1 = -
 v               v
|S|             |S| +- PRESUMED DECIMAL POINT
|B|             |B| v
|_|_ _ _ _ _ _ _|_|_ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _
|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|_|
|7 6 5 4 3 2 1 0|7 6.5 4 3 2 1 0|7 6 5 4 3 2 1 0|7 6 5 4 3 2 1 0|
|               |               |               |               |
|    BYTE N     |   BYTE N+1    |  BYTE N+2     |   BYTE N+3    |
|               |               |               |               |
|               | MOST SIG BYTE |               | LEAST SIG BYTE|
|               | MANTISSA      |               | MANTISSA      |
|               |               |               |               |
|<- EXPONENT  ->|<---          THREE BYTE MANTISSA          --->|
|                       (TWOS COMPLEMENT REPRESENTATION)        |
|<----            FOUR-BYTE FLOATING POINT OPERAND         ---->|

The exponent byte is a binary scaling factor for the
Mantissa.  The exponent is a standard two's comple-
ment representation except that the sign bit is comple-
mented and runs from +128 to +127.  For example:

     $00 is -128
     $01 is -127
         *
         *
     $7F is -1
     $80 is 0
     $81 is -1
         *
         *
     $FF is 127

The mantissa is standard two's complement repre-
sentation with the sign bit in the most significant bit of
the high order byte.  The assumed decimal point is be-
tween bits 6 and 7 of the most significant byte.  Thus the
normalized mantissa ranges in absolute value from 1 to
2.  Except when the exponent has a value of +128 the
mantissa is normalized to retain maximum precision.
The mantissa is normalized if the upper two bits of the
high-order mantissa byte are unequal.  Thus a normal-
ized mantissa is of the following form:

     01.xxxxxx  positive mantissa (high byte)
     10.xxxxxx  negative mantissa (high byte)
        Assumed binary point

Some sample floating point numbers in hex

     83 50 00 00     10.
     80 40 00 00     1.
     7C 66 66 66     .1
     00 00 00 00     0.
     FC 99 99 9A     -.1
     7F 80 00 00     -1.
     83 B0 00 00     -10.

The routines are all entered using a JSR instruction.
Base page locations $004-$007 are referred to as
exp/mant2 while $0008-000b are referred to as exp/
mant1 and act as floating point registers.  On entry to
the subroutines these registers contain the numbers to
be operated upon and contain the result on return,  The
function of the registers is given before each entry point
in the source listing.  There are three error traps which
will cause a software interrupts.  ERROT (1D06) is
encountered if the argument in the log routine is less
than or equal to zero.  OVFLW (1E3B) will be executed if
the argument of EXP is too large.  Overflow detected by
the basic floating point routines will cause OVFL (1FE4)
to be executed.  The routines do not give underflow
errors, but set the number to zero if underflow occurs.

Readers of Dr. Dobbs's journal should note that when
these routines were published in that journal the math
function LOG contained an error which prevented the
correct result from being given if the argument was less
than 1.  This error has been correted in the present list-
ing and marked with "MOD 9/76."


   1                   *           SEPTEMBER 11, 1976
   2                   *     BASIC FLOATING POINT ROUTINES
   3                   *       FOR 6502 MICROPROCESSOR
   4                   *       BY R. RANKIN AND S. WOZNIAK
   5                   *
   6                   *     CONSISTING OF:
   7                   *        NATURAL LOG
   8                   *        COMMON LOG
   9                   *        EXPONENTIAL (E**X)
  10                   *        FLOAT      FIX
  11                   *        FADD       FSUB
  12                   *        FMUL       FDIV
  13                   *
  14                   *
  15                   *     FLOATING POINT REPRESENTATION (4-BYTES)
  16                   *                    EXPONENT BYTE 1
  17                   *                    MANTISSA BYTES 2-4
  18                   *
  19                   *     MANTISSA:    TWO'S COMPLIMENT REPRESENTATION WITH SIGN IN
  20                   *       MSB OF HIGH-ORDER BYTE.  MANTISSA IS NORMALIZED WITH AN
  21                   *       ASSUMED DECIMAL POINT BETWEEN BITS 5 AND 6 OF THE HIGH-ORDER
  22                   *       BYTE.  THUS THE MANTISSA IS IN THE RANGE 1. TO 2. EXCEPT
  23                   *       WHEN THE NUMBER IS LESS THAN 2**(-128).
  24                   *
  25                   *     EXPONENT:    THE EXPONENT REPRESENTS POWERS OF TWO.  THE
  26                   *       REPRESENTATION IS 2'S COMPLIMENT EXCEPT THAT THE SIGN
  27                   *       BIT (BIT 7) IS COMPLIMENTED.  THIS ALLOWS DIRECT COMPARISON
  28                   *       OF EXPONENTS FOR SIZE SINCE THEY ARE STORED IN INCREASING
  29                   *       NUMERICAL SEQUENCE RANGING FROM $00 (-128) TO $FF (+127)
  30                   *       ($ MEANS NUMBER IS HEXADECIMAL).
  31                   *
  32                   *     REPRESENTATION OF DECIMAL NUMBERS:    THE PRESENT FLOATING
  33                   *       POINT REPRESENTATION ALLOWS DECIMAL NUMBERS IN THE APPROXIMATE
  34                   *       RANGE OF 10**(-38) THROUGH 10**(38) WITH 6 TO 7 SIGNIFICANT
  35                   *       DIGITS.
  36                   *
  37                   *
  38  0003                    ORG 3        SET BASE PAGE ADRESSES
  39  0003  EA         SIGN   NOP
  40  0004  EA         X2     NOP          EXPONENT 2
  41  0005  00 00 00   M2     BSS 3        MANTISSA 2
  42  0008  EA         X1     NOP          EXPONENT 1
  43  0009  00 00 00   M1     BSS 3        MANTISSA 1
  44  000C             E      BSS 4        SCRATCH
  45  0010             Z      BSS 4
  46  0014             T      BSS 4
  47  0018             SEXP   BSS 4
  48  001C  00         INT    BSS 1
  49                   *
  50  1D00                    ORG $1D00    STARTING LOCATION FOR LOG
  51                   *
  52                   *     NATURAL LOG OF MANT/EXP1 WITH RESULT IN MANT/EXP1
  53                   *
  54  1D00  A5 09      LOG    LDA M1
  55  1D02  F0 02             BEQ ERROR
  56  1D04  10 01             BPL CONT     IF ARG>0 OK
  57  1D06  00         ERROR  BRK          ERROR ARG<=0
  58                   *
  59  1D07  20 1C 1F   CONT   JSR SWAP     MOVE ARG TO EXP/MANT2
  60  1D0A  A2 00             LDX =0       MOD 9/76: LOAD X FOR LATER
  61  1D0C  A5 04             LDA X2       HOLD EXPONENT
  62  1D0E  A0 80             LDY =$80
  63  1D10  84 04             STY X2       SET EXPONENT 2 TO 0 ($80)
  64  1D12  49 80             EOR =$80     COMPLIMENT SIGN BIT OF ORIGINAL EXPONENT
  65  1D14  85 0A             STA M1+1     SET EXPONENT INTO MANTISSA 1 FOR FLOAT
  66  1D16  10 01             BPL *+3      MOD 9/76: IS EXPONENT ZERO?
  67  1D18  CA                DEX          MOD 9/76: YES SET X TO $FF
  68  1D19  86 09             STX M1       MOD 9/76: SET UPPER BYTE OF EXPONENT
  69  1D1B  20 2C 1F          JSR FLOAT    CONVERT TO FLOATING POINT
  70  1D1E  A2 03             LDX =3       4 BYTE TRANSFERS
  71  1D20  B5 04      SEXP1  LDA X2,X
  72  1D22  95 10             STA Z,X      COPY MANTISSA TO Z
  73  1D24  B5 08             LDA X1,X
  74  1D26  95 18             STA SEXP,X   SAVE EXPONENT IN SEXP
  75  1D28  BD D4 1D          LDA R22,X    LOAD EXP/MANT1 WITH SQRT(2)
  76  1D2B  95 08             STA X1,X
  77  1D2D  CA                DEX
  78  1D2E  10 F0             BPL SEXP1
  79  1D30  20 4A 1F          JSR FSUB     Z-SQRT(2)
  80  1D33  A2 03             LDX =3       4 BYTE TRANSFER
  81  1D35  B5 08      SAVET  LDA X1,X     SAVE EXP/MANT1 AS T
  82  1D37  95 14             STA T,X
  83  1D39  B5 10             LDA Z,X      LOAD EXP/MANT1 WITH Z
  84  1D3B  95 08             STA X1,X
  85  1D3D  BD D4 1D          LDA R22,X    LOAD EXP/MANT2 WITH SQRT(2)
  86  1D40  95 04             STA X2,X
  87  1D42  CA                DEX
  88  1D43  10 F0             BPL SAVET
  89  1D45  20 50 1F          JSR FADD     Z+SQRT(2)
  90  1D48  A2 03             LDX =3       4 BYTE TRANSFER
  91  1D4A  B5 14      TM2    LDA T,X
  92  1D4C  95 04             STA X2,X     LOAD T INTO EXP/MANT2
  93  1D4E  CA                DEX
  94  1D4F  10 F9             BPL TM2
  95  1D51  20 9D 1F          JSR FDIV     T=(Z-SQRT(2))/(Z+SQRT(2))
  96  1D54  A2 03             LDX =3       4 BYTE TRANSFER
  97  1D56  B5 08      MIT    LDA X1,X
  98  1D58  95 14             STA T,X      COPY EXP/MANT1 TO T AND
  99  1D5A  95 04             STA X2,X     LOAD EXP/MANT2 WITH T
 100  1D5C  CA                DEX
 101  1D5D  10 F7             BPL MIT
 102  1D5F  20 77 1F          JSR FMUL     T*T
 103  1D62  20 1C 1F          JSR SWAP     MOVE T*T TO EXP/MANT2
 104  1D65  A2 03             LDX =3       4 BYTE TRANSFER
 105  1D67  BD E4 1D   MIC    LDA C,X
 106  1D6A  95 08             STA X1,X     LOAD EXP/MANT1 WITH C
 107  1D6C  CA                DEX
 108  1D6D  10 F8             BPL MIC
 109  1D6F  20 4A 1F          JSR FSUB     T*T-C
 110  1D72  A2 03             LDX =3       4 BYTE TRANSFER
 111  1D74  BD E0 1D   M2MB   LDA MB,X
 112  1D77  95 04             STA X2,X     LOAD EXP/MANT2 WITH MB
 113  1D79  CA                DEX
 114  1D7A  10 F8             BPL M2MB
 115  1D7C  20 9D 1F          JSR FDIV     MB/(T*T-C)
 116  1D7F  A2 03             LDX =3
 117  1D81  BD DC 1D   M2A1   LDA A1,X
 118  1D84  95 04             STA X2,X     LOAD EXP/MANT2 WITH A1
 119  1D86  CA                DEX
 120  1D87  10 F8             BPL M2A1
 121  1D89  20 50 1F          JSR FADD     MB/(T*T-C)+A1
 122  1D8C  A2 03             LDX =3       4 BYTE TRANSFER
 123  1D8E  B5 14      M2T    LDA T,X
 124  1D90  95 04             STA X2,X     LOAD EXP/MANT2 WITH T
 125  1D92  CA                DEX
 126  1D93  10 F9             BPL M2T
 127  1D95  20 77 1F          JSR FMUL     (MB/(T*T-C)+A1)*T
 128  1D98  A2 03             LDX =3       4 BYTE TRANSFER
 129  1D9A  BD E8 1D   M2MHL  LDA MHLF,X
 130  1D9D  95 04             STA X2,X     LOAD EXP/MANT2 WITH MHLF (.5)
 131  1D9F  CA                DEX
 132  1DA0  10 F8             BPL M2MHL
 133  1DA2  20 50 1F          JSR FADD     +.5
 134  1DA5  A2 03             LDX =3       4 BYTE TRANSFER
 135  1DA7  B5 18      LDEXP  LDA SEXP,X
 136  1DA9  95 04             STA X2,X     LOAD EXP/MANT2 WITH ORIGINAL EXPONENT
 137  1DAB  CA                DEX
 138  1DAC  10 F9             BPL LDEXP
 139  1DAE  20 50 1F          JSR FADD     +EXPN
 140  1DB1  A2 03             LDX =3       4 BYTE TRANSFER
 141  1DB3  BD D8 1D   MLE2   LDA LE2,X
 142  1DB6  95 04             STA X2,X     LOAD EXP/MANT2 WITH LN(2)
 143  1DB8  CA                DEX
 144  1DB9  10 F8             BPL MLE2
 145  1DBB  20 77 1F          JSR FMUL     *LN(2)
 146  1DBE  60                RTS          RETURN RESULT IN MANT/EXP1
 147                   *
 148                   *     COMMON LOG OF MANT/EXP1 RESULT IN MANT/EXP1
 149                   *
 150  1DBF  20 00 1D   LOG10  JSR LOG      COMPUTE NATURAL LOG
 151  1DC2  A2 03             LDX =3
 152  1DC4  BD D0 1D   L10    LDA LN10,X
 153  1DC7  95 04             STA X2,X     LOAD EXP/MANT2 WITH 1/LN(10)
 154  1DC9  CA                DEX
 155  1DCA  10 F8             BPL L10
 156  1DCC  20 77 1F          JSR FMUL     LOG10(X)=LN(X)/LN(10)
 157  1DCF  60                RTS
 158                   *
 159  1DD0  7E 6F      LN10   DCM  0.4342945
            2D ED
 160  1DD4  80 5A      R22    DCM  1.4142136   SQRT(2)
            82 7A
 161  1DD8  7F 58      LE2    DCM  0.69314718  LOG BASE E OF 2
            B9 0C
 162  1DDC  80 52      A1     DCM  1.2920074
            B0 40
 163  1DE0  81 AB      MB     DCM  -2.6398577
            86 49
 164  1DE4  80 6A      C      DCM  1.6567626
            08 66
 165  1DE8  7F 40      MHLF   DCM  0.5
            00 00
 166                   *
 167  1E00                    ORG $1E00    STARTING LOCATION FOR EXP
 168                   *
 169                   *     EXP OF MANT/EXP1 RESULT IN MANT/EXP1
 170                   *
 171  1E00  A2 03      EXP    LDX =3       4 BYTE TRANSFER
 172  1E02  BD D8 1E          LDA L2E,X
 173  1E05  95 04             STA X2,X     LOAD EXP/MANT2 WITH LOG BASE 2 OF E
 174  1E07  CA                DEX
 175  1E08  10 F8             BPL EXP+2
 176  1E0A  20 77 1F          JSR FMUL     LOG2(3)*X
 177  1E0D  A2 03             LDX =3       4 BYTE TRANSFER
 178  1E0F  B5 08      FSA    LDA X1,X
 179  1E11  95 10             STA Z,X      STORE EXP/MANT1 IN Z
 180  1E13  CA                DEX
 181  1E14  10 F9             BPL FSA      SAVE Z=LN(2)*X
 182  1E16  20 E8 1F          JSR FIX      CONVERT CONTENTS OF EXP/MANT1 TO AN INTEGER
 183  1E19  A5 0A             LDA M1+1
 184  1E1B  85 1C             STA INT      SAVE RESULT AS INT
 185  1E1D  38                SEC          SET CARRY FOR SUBTRACTION
 186  1E1E  E9 7C             SBC =124     INT-124
 187  1E20  A5 09             LDA M1
 188  1E22  E9 00             SBC =0
 189  1E24  10 15             BPL OVFLW    OVERFLOW INT>=124
 190  1E26  18                CLC          CLEAR CARRY FOR ADD
 191  1E27  A5 0A             LDA M1+1
 192  1E29  69 78             ADC =120     ADD 120 TO INT
 193  1E2B  A5 09             LDA M1
 194  1E2D  69 00             ADC =0
 195  1E2F  10 0B             BPL CONTIN   IF RESULT POSITIVE CONTINUE
 196  1E31  A9 00             LDA =0       INT<-120 SET RESULT TO ZERO AND RETURN
 197  1E33  A2 03             LDX =3       4 BYTE MOVE
 198  1E35  95 08      ZERO   STA X1,X     SET EXP/MANT1 TO ZERO
 199  1E37  CA                DEX
 200  1E38  10 FB             BPL ZERO
 201  1E3A  60                RTS          RETURN
 202                   *
 203  1E3B  00         OVFLW  BRK          OVERFLOW
 204                   *
 205  1E3C  20 2C 1F   CONTIN JSR FLOAT    FLOAT INT
 206  1E3F  A2 03             LDX =3
 207  1E41  B5 10      ENTD   LDA Z,X
 208  1E43  95 04             STA X2,X     LOAD EXP/MANT2 WITH Z
 209  1E45  CA                DEX
 210  1E46  10 F9             BPL ENTD
 211  1E48  20 4A 1F          JSR FSUB     Z*Z-FLOAT(INT)
 212  1E4B  A2 03             LDX =3       4 BYTE MOVE
 213  1E4D  B5 08      ZSAV   LDA X1,X
 214  1E4F  95 10             STA Z,X      SAVE EXP/MANT1 IN Z
 215  1E51  95 04             STA X2,X     COPY EXP/MANT1 TO EXP/MANT2
 216  1E53  CA                DEX
 217  1E54  10 F7             BPL ZSAV
 218  1E56  20 77 1F          JSR FMUL     Z*Z
 219  1E59  A2 03             LDX =3       4 BYTE MOVE
 220  1E5B  BD DC 1E   LA2    LDA A2,X
 221  1E5E  95 04             STA X2,X     LOAD EXP/MANT2 WITH A2
 222  1E60  B5 08             LDA X1,X
 223  1E62  95 18             STA SEXP,X   SAVE EXP/MANT1 AS SEXP
 224  1E64  CA                DEX
 225  1E65  10 F4             BPL LA2
 226  1E67  20 50 1F          JSR FADD     Z*Z+A2
 227  1E6A  A2 03             LDX =3       4 BYTE MOVE
 228  1E6C  BD E0 1E   LB2    LDA B2,X
 229  1E6F  95 04             STA X2,X     LOAD EXP/MANT2 WITH B2
 230  1E71  CA                DEX
 231  1E72  10 F8             BPL LB2
 232  1E74  20 9D 1F          JSR FDIV     T=B/(Z*Z+A2)
 233  1E77  A2 03             LDX =3       4 BYTE MOVE
 234  1E79  B5 08      DLOAD  LDA X1,X
 235  1E7B  95 14             STA T,X      SAVE EXP/MANT1 AS T
 236  1E7D  BD E4 1E          LDA C2,X
 237  1E80  95 08             STA X1,X     LOAD EXP/MANT1 WITH C2
 238  1E82  B5 18             LDA SEXP,X
 239  1E84  95 04             STA X2,X     LOAD EXP/MANT2 WITH SEXP
 240  1E86  CA                DEX
 241  1E87  10 F0             BPL DLOAD
 242  1E89  20 77 1F          JSR FMUL     Z*Z*C2
 243  1E8C  20 1C 1F          JSR SWAP     MOVE EXP/MANT1 TO EXP/MANT2
 244  1E8F  A2 03             LDX =3       4 BYTE TRANSFER
 245  1E91  B5 14      LTMP   LDA T,X
 246  1E93  95 08             STA X1,X     LOAD EXP/MANT1 WITH T
 247  1E95  CA                DEX
 248  1E96  10 F9             BPL LTMP
 249  1E98  20 4A 1F          JSR FSUB     C2*Z*Z-B2/(Z*Z+A2)
 250  1E9B  A2 03             LDX =3       4 BYTE TRANSFER
 251  1E9D  BD E8 1E   LDD    LDA D,X
 252  1EA0  95 04             STA X2,X     LOAD EXP/MANT2 WITH D
 253  1EA2  CA                DEX
 254  1EA3  10 F8             BPL LDD
 255  1EA5  20 50 1F          JSR FADD     D+C2*Z*Z-B2/(Z*Z+A2)
 256  1EA8  20 1C 1F          JSR SWAP     MOVE EXP/MANT1 TO EXP/MANT2
 257  1EAB  A2 03             LDX =3       4 BYTE TRANSFER
 258  1EAD  B5 10      LFA    LDA Z,X
 259  1EAF  95 08             STA X1,X     LOAD EXP/MANT1 WITH Z
 260  1EB1  CA                DEX
 261  1EB2  10 F9             BPL LFA
 262  1EB4  20 4A 1F          JSR FSUB     -Z+D+C2*Z*Z-B2/(Z*Z+A2)
 263  1EB7  A2 03             LDX =3       4 BYTE TRANSFER
 264  1EB9  B5 10      LF3    LDA Z,X
 265  1EBB  95 04             STA X2,X     LOAD EXP/MANT2 WITH Z
 266  1EBD  CA                DEX
 267  1EBE  10 F9             BPL LF3
 268  1EC0  20 9D 1F          JSR FDIV     Z/(**** )
 269  1EC3  A2 03             LDX =3       4 BYTE TRANSFER
 270  1EC5  BD E8 1D   LD12   LDA MHLF,X
 271  1EC8  95 04             STA X2,X     LOAD EXP/MANT2 WITH .5
 272  1ECA  CA                DEX
 273  1ECB  10 F8             BPL LD12
 274  1ECD  20 50 1F          JSR FADD     +Z/(***)+.5
 275  1ED0  38                SEC          ADD INT TO EXPONENT WITH CARRY SET
 276  1ED1  A5 1C             LDA INT      TO MULTIPLY BY
 277  1ED3  65 08             ADC X1       2**(INT+1)
 278  1ED5  85 08             STA X1       RETURN RESULT TO EXPONENT
 279  1ED7  60                RTS          RETURN ANS=(.5+Z/(-Z+D+C2*Z*Z-B2/(Z*Z+A2))*2**(INT+1)
 280  1ED8  80 5C      L2E    DCM  1.4426950409   LOG BASE 2 OF E
            55 1E
 281  1EDC  86 57      A2     DCM  87.417497202
            6A E1
 282  1EE0  89 4D      B2     DCM  617.9722695
            3F 1D
 283  1EE4  7B 46      C2     DCM  .03465735903
            4A 70
 284  1EE8  83 4F      D      DCM  9.9545957821
            A3 03
 285                   *
 286                   *
 287                   *     BASIC FLOATING POINT ROUTINES
 288                   *
 289  1F00                    ORG $1F00    START OF BASIC FLOATING POINT ROUTINES
 290  1F00  18         ADD    CLC          CLEAR CARRY
 291  1F01  A2 02             LDX =$02     INDEX FOR 3-BYTE ADD
 292  1F03  B5 09      ADD1   LDA M1,X
 293  1F05  75 05             ADC M2,X     ADD A BYTE OF MANT2 TO MANT1
 294  1F07  95 09             STA M1,X
 295  1F09  CA                DEX          ADVANCE INDEX TO NEXT MORE SIGNIF.BYTE
 296  1F0A  10 F7             BPL ADD1     LOOP UNTIL DONE.
 297  1F0C  60                RTS          RETURN
 298  1F0D  06 03      MD1    ASL SIGN     CLEAR LSB OF SIGN
 299  1F0F  20 12 1F          JSR ABSWAP   ABS VAL OF MANT1, THEN SWAP MANT2
 300  1F12  24 09      ABSWAP BIT M1       MANT1 NEG?
 301  1F14  10 05             BPL ABSWP1   NO,SWAP WITH MANT2 AND RETURN
 302  1F16  20 8F 1F          JSR FCOMPL   YES, COMPLIMENT IT.
 303  1F19  E6 03             INC SIGN     INCR SIGN, COMPLEMENTING LSB
 304  1F1B  38         ABSWP1 SEC          SET CARRY FOR RETURN TO MUL/DIV
 305                   *
 306                   *     SWAP EXP/MANT1 WITH EXP/MANT2
 307                   *
 308  1F1C  A2 04      SWAP   LDX =$04     INDEX FOR 4-BYTE SWAP.
 309  1F1E  94 0B      SWAP1  STY E-1,X
 310  1F20  B5 07             LDA X1-1,X   SWAP A BYTE OF EXP/MANT1 WITH
 311  1F22  B4 03             LDY X2-1,X   EXP/MANT2 AND LEAVEA COPY OF
 312  1F24  94 07             STY X1-1,X   MANT1 IN E(3BYTES). E+3 USED.
 313  1F26  95 03             STA X2-1,X
 314  1F28  CA                DEX          ADVANCE INDEX TO NEXT BYTE
 315  1F29  D0 F3             BNE SWAP1    LOOP UNTIL DONE.
 316  1F2B  60                RTS
 317                   *
 318                   *
 319                   *
 320                   *     CONVERT 16 BIT INTEGER IN M1(HIGH) AND M1+1(LOW) TO F.P.
 321                   *     RESULT IN EXP/MANT1.  EXP/MANT2 UNEFFECTED
 322                   *
 323                   *
 324  1F2C  A9 8E      FLOAT  LDA =$8E
 325  1F2E  85 08             STA X1       SET EXPN TO 14 DEC
 326  1F30  A9 00             LDA =0       CLEAR LOW ORDER BYTE
 327  1F32  85 0B             STA M1+2
 328  1F34  F0 08             BEQ NORM     NORMALIZE RESULT
 329  1F36  C6 08      NORM1  DEC X1       DECREMENT EXP1
 330  1F38  06 0B             ASL M1+2
 331  1F3A  26 0A             ROL M1+1     SHIFT MANT1 (3 BYTES) LEFT
 332  1F3C  26 09             ROL M1
 333  1F3E  A5 09      NORM   LDA M1       HIGH ORDER MANT1 BYTE
 334  1F40  0A                ASL          UPPER TWO BITS UNEQUAL?
 335  1F41  45 09             EOR M1
 336  1F43  30 04             BMI RTS1     YES,RETURN WITH MANT1 NORMALIZED
 337  1F45  A5 08             LDA X1       EXP1 ZERO?
 338  1F47  D0 ED             BNE NORM1    NO, CONTINUE NORMALIZING
 339  1F49  60         RTS1   RTS          RETURN
 340                   *
 341                   *
 342                   *     EXP/MANT2-EXP/MANT1 RESULT IN EXP/MANT1
 343                   *
 344  1F4A  20 8F 1F   FSUB   JSR FCOMPL   CMPL MANT1 CLEARS CARRY UNLESS ZERO
 345  1F4D  20 5D 1F   SWPALG JSR ALGNSW   RIGHT SHIFT MANT1 OR SWAP WITH MANT2 ON CARRY
 346                   *
 347                   *     ADD EXP/MANT1 AND EXP/MANT2 RESULT IN EXP/MANT1
 348                   *
 349  1F50  A5 04      FADD   LDA X2
 350  1F52  C5 08             CMP X1       COMPARE EXP1 WITH EXP2
 351  1F54  D0 F7             BNE SWPALG   IF UNEQUAL, SWAP ADDENDS OR ALIGN MANTISSAS
 352  1F56  20 00 1F          JSR ADD      ADD ALIGNED MANTISSAS
 353  1F59  50 E3      ADDEND BVC NORM     NO OVERFLOW, NORMALIZE RESULTS
 354  1F5B  70 05             BVS RTLOG    OV: SHIFT MANT1 RIGHT. NOTE CARRY IS CORRECT SIGN
 355  1F5D  90 BD      ALGNSW BCC SWAP     SWAP IF CARRY CLEAR, ELSE SHIFT RIGHT ARITH.
 356  1F5F  A5 09      RTAR   LDA M1       SIGN OF MANT1 INTO CARRY FOR
 357  1F61  0A                ASL          RIGHT ARITH SHIFT
 358  1F62  E6 08      RTLOG  INC X1       INCR EXP1 TO COMPENSATE FOR RT SHIFT
 359  1F64  F0 7E             BEQ OVFL     EXP1 OUT OF RANGE.
 360  1F66  A2 FA      RTLOG1 LDX =$FA     INDEX FOR 6 BYTE RIGHT SHIFT
 361  1F68  A9 80      ROR1   LDA =$80
 362  1F6A  B0 01             BCS ROR2
 363  1F6C  0A                ASL
 364  1F6D  56 0F      ROR2   LSR E+3,X    SIMULATE ROR E+3,X
 365  1F6F  15 0F             ORA E+3,X
 366  1F71  95 0F             STA E+3,X
 367  1F73  E8                INX          NEXT BYTE OF SHIFT
 368  1F74  D0 F2             BNE ROR1     LOOP UNTIL DONE
 369  1F76  60                RTS          RETURN
 370                   *
 371                   *
 372                   *     EXP/MANT1 X EXP/MANT2 RESULT IN EXP/MANT1
 373                   *
 374  1F77  20 0D 1F   FMUL   JSR MD1      ABS. VAL OF MANT1, MANT2
 375  1F7A  65 08             ADC X1       ADD EXP1 TO EXP2 FOR PRODUCT EXPONENT
 376  1F7C  20 CD 1F          JSR MD2      CHECK PRODUCT EXP AND PREPARE FOR MUL
 377  1F7F  18                CLC          CLEAR CARRY
 378  1F80  20 66 1F   MUL1   JSR RTLOG1   MANT1 AND E RIGHT.(PRODUCT AND MPLIER)
 379  1F83  90 03             BCC MUL2     IF CARRY CLEAR, SKIP PARTIAL PRODUCT
 380  1F85  20 00 1F          JSR ADD      ADD MULTIPLICAN TO PRODUCT
 381  1F88  88         MUL2   DEY          NEXT MUL ITERATION
 382  1F89  10 F5             BPL MUL1     LOOP UNTIL DONE
 383  1F8B  46 03      MDEND  LSR SIGN     TEST SIGN (EVEN/ODD)
 384  1F8D  90 AF      NORMX  BCC NORM     IF EXEN, NORMALIZE PRODUCT, ELSE COMPLEMENT
 385  1F8F  38         FCOMPL SEC          SET CARRY FOR SUBTRACT
 386  1F90  A2 03             LDX =$03     INDEX FOR 3 BYTE SUBTRACTION
 387  1F92  A9 00      COMPL1 LDA =$00     CLEAR A
 388  1F94  F5 08             SBC X1,X     SUBTRACT BYTE OF EXP1
 389  1F96  95 08             STA X1,X     RESTORE IT
 390  1F98  CA                DEX          NEXT MORE SIGNIFICANT BYTE
 391  1F99  D0 F7             BNE COMPL1   LOOP UNTIL DONE
 392  1F9B  F0 BC             BEQ ADDEND   NORMALIZE (OR SHIFT RIGHT IF OVERFLOW)
 393                   *
 394                   *
 395                   *     EXP/MANT2 / EXP/MANT1 RESULT IN EXP/MANT1
 396                   *
 397  1F9D  20 0D 1F   FDIV   JSR MD1      TAKE ABS VAL OF MANT1, MANT2
 398  1FA0  E5 08             SBC X1       SUBTRACT EXP1 FROM EXP2
 399  1FA2  20 CD 1F          JSR MD2      SAVE AS QUOTIENT EXP
 400  1FA5  38         DIV1   SEC          SET CARRY FOR SUBTRACT
 401  1FA6  A2 02             LDX =$02     INDEX FOR 3-BYTE INSTRUCTION
 402  1FA8  B5 05      DIV2   LDA M2,X
 403  1FAA  F5 0C             SBC E,X      SUBTRACT A BYTE OF E FROM MANT2
 404  1FAC  48                PHA          SAVE ON STACK
 405  1FAD  CA                DEX          NEXT MORE SIGNIF BYTE
 406  1FAE  10 F8             BPL DIV2     LOOP UNTIL DONE
 407  1FB0  A2 FD             LDX =$FD     INDEX FOR 3-BYTE CONDITIONAL MOVE
 408  1FB2  68         DIV3   PLA          PULL A BYTE OF DIFFERENCE OFF STACK
 409  1FB3  90 02             BCC DIV4     IF MANT2<E THEN DONT RESTORE MANT2
 410  1FB5  95 08             STA M2+3,X
 411  1FB7  E8         DIV4   INX          NEXT LESS SIGNIF BYTE
 412  1FB8  D0 F8             BNE DIV3     LOOP UNTIL DONE
 413  1FBA  26 0B             ROL M1+2
 414  1FBC  26 0A             ROL M1+1     ROLL QUOTIENT LEFT, CARRY INTO LSB
 415  1FBE  26 09             ROL M1
 416  1FC0  06 07             ASL M2+2
 417  1FC2  26 06             ROL M2+1     SHIFT DIVIDEND LEFT
 418  1FC4  26 05             ROL M2
 419  1FC6  B0 1C             BCS OVFL     OVERFLOW IS DUE TO UNNORMALIZED DIVISOR
 420  1FC8  88                DEY          NEXT DIVIDE ITERATION
 421  1FC9  D0 DA             BNE DIV1     LOOP UNTIL DONE 23 ITERATIONS
 422  1FCB  F0 BE             BEQ MDEND    NORMALIZE QUOTIENT AND CORRECT SIGN
 423  1FCD  86 0B      MD2    STX M1+2
 424  1FCF  86 0A             STX M1+1     CLR MANT1 (3 BYTES) FOR MUL/DIV
 425  1FD1  86 09             STX M1
 426  1FD3  B0 0D             BCS OVCHK    IF EXP CALC SET CARRY, CHECK FOR OVFL
 427  1FD5  30 04             BMI MD3      IF NEG NO UNDERFLOW
 428  1FD7  68                PLA          POP ONE
 429  1FD8  68                PLA          RETURN LEVEL
 430  1FD9  90 B2             BCC NORMX    CLEAR X1 AND RETURN
 431  1FDB  49 80      MD3    EOR =$80     COMPLIMENT SIGN BIT OF EXP
 432  1FDD  85 08             STA X1       STORE IT
 433  1FDF  A0 17             LDY =$17     COUNT FOR 24 MUL OR 23 DIV ITERATIONS
 434  1FE1  60                RTS          RETURN
 435  1FE2  10 F7      OVCHK  BPL MD3      IF POS EXP THEN NO OVERFLOW
 436  1FE4  00         OVFL   BRK
 437                   *
 438                   *
 439                   *     CONVERT EXP/MANT1 TO INTEGER IN M1 (HIGH) AND M1+1(LOW)
 440                   *      EXP/MANT2 UNEFFECTED
 441                   *
 442  1FE5  20 5F 1F          JSR RTAR     SHIFT MANT1 RT AND INCREMENT EXPNT
 443  1FE8  A5 08      FIX    LDA X1       CHECK EXPONENT
 444  1FEA  C9 8E             CMP =$8E     IS EXPONENT 14?
 445  1FEC  D0 F7             BNE FIX-3    NO, SHIFT
 446  1FEE  60         RTRN   RTS          RETURN
 447                          END

OBJECT CODE DUMP

1D00  A5 09 F0 02 10 01 00 20 1C 1F A2 00 A5 04 A0 80
1D10  84 04 49 80 85 0A 10 01 CA 86 09 20 2C 1F A2 03
1D20  B5 04 95 10 B5 08 95 18 BD D4 1D 95 08 CA 10 F0
1D30  20 4A 1F A2 03 B5 08 95 14 B5 10 95 08 BD D4 1D
1D40  95 04 CA 10 F0 20 50 1F A2 03 B5 14 95 04 CA 10
1D50  F9 20 9D 1F A2 03 B5 08 95 14 95 04 CA 10 F7 20
1D60  77 1F 20 1C 1F A2 03 BD E4 1D 95 08 CA 10 F8 20
1D70  4A 1F A2 03 BD E0 1D 95 04 CA 10 F8 20 9D 1F A2
1D80  03 BD DC 1D 95 04 CA 10 F8 20 50 1F A2 03 B5 14
1D90  95 04 CA 10 F9 20 77 1F A2 03 BD E8 1D 95 04 CA
1DA0  10 F8 20 50 1F A2 03 B5 18 95 04 CA 10 F9 20 50
1DB0  1F A2 03 BD D8 1D 95 04 CA 10 F8 20 77 1F 60 20
1DC0  00 1D A2 03 BD D0 1D 95 04 CA 10 F8 20 77 1F 60
1DD0  73 6F 2D ED 80 5A 82 7A 7F 58 B9 0C 80 52 B0 40
1DE0  81 AB 86 49 80 6A 08 66 7F 40 00 00

1E00  A2 03 BD D8 1E 95 04 CA 10 F8 20 77 1F A2 03 B5
1E10  08 95 10 CA 10 F9 20 E8 1F A5 0A 85 1C 38 E9 7C
1E20  A5 09 E9 00 10 15 18 A5 0A 69 78 A5 09 69 00 10
1E30  0B A9 00 A2 03 95 08 CA 10 FB 60 00 20 2C 1F A2
1E40  03 B5 10 95 04 CA 10 F9 20 4A 1F A2 03 B5 08 95
1E50  10 95 04 CA 10 F7 20 77 1F A2 03 BD DC 1E 95 04
1E60  B5 08 95 18 CA 10 F4 20 50 1F A2 03 BD E0 1E 95
1E70  04 CA 10 F8 20 9D 1F A2 03 B5 08 95 14 BD E4 1E
1E80  95 08 B5 18 95 04 CA 10 F0 20 77 1F 20 1C 1F A2
1E90  03 B5 14 95 08 CA 10 F9 20 4A 1F A2 03 BD E8 1E
1EA0  95 04 CA 10 F8 20 50 1F 20 1C 1F A2 03 B5 10 95
1EB0  08 CA 10 F9 20 4A 1F A2 03 B5 10 95 04 CA 10 F9
1EC0  20 9D 1F A2 03 BD E8 1D 95 04 CA 10 F8 20 50 1F
1ED0  38 A5 1C 65 08 85 08 60 80 5C 55 1E 86 57 6A E1
1EE0  89 4D 3F 1D 7B 46 FA 70 83 4F A3 03

1F00  18 A2 02 B5 09 75 05 95 09 CA 10 F7 60 06 03 20
1F10  12 1F 24 09 10 05 20 8F 1F E6 03 38 A2 04 94 0B
1F20  B5 07 B4 03 94 07 95 03 CA D0 F3 60 A9 8E 85 08
1F30  A9 00 85 0B F0 08 C6 08 06 0B 26 0A 26 09 A5 09
1F40  0A 45 09 30 04 A5 08 D0 ED 60 20 8F 1F 20 5D 1F
1F50  A5 04 C5 08 D0 F7 20 00 1F 50 E3 70 05 90 BD A5
1F60  09 0A E6 08 F0 7E A2 FA A9 80 B0 01 0A 56 0F 15
1F70  0F 95 0F E8 D0 F2 60 20 0D 1F 65 08 20 CD 1F 18
1F80  20 66 1F 90 03 20 00 1F 88 10 F5 46 03 90 AF 38
1F90  A2 03 A9 00 F5 08 95 08 CA D0 F7 F0 BC 20 0D 1F
1FA0  E5 08 20 CD 1F 38 A2 02 B5 05 F5 0C 48 CA 10 F8
1FB0  A2 FD 68 90 02 95 08 E8 D0 F8 26 0B 26 0A 26 09
1FC0  06 07 26 06 26 05 B0 1C 88 D0 DA F0 BE 86 0B 86
1FD0  0A 86 09 B0 0D 30 04 68 68 90 B2 49 80 85 08 A0
1FE0  17 60 10 F7 00 20 5F 1F A5 08 C9 8E D0 F7 60



+------------------------------------------------------------------------
|  TOPIC -- SYM Computer -- SYM Monitor listing 
+------------------------------------------------------------------------

SYM-1 SUPERMON AND AUDIO CASSETTE INTERFACE SOURCES
COMBINED AND CONVERTED TO TELEMARK ASSEMBLER (TASM) V3.1

0002   0000             ;
0003   0000             ;*****
0004   0000             ;***** COPYRIGHT 1979 SYNERTEK SYSTEMS CORPORATION
0005   0000             ;***** VERSION 2  4/13/79  "SY1.1"
0006   A600                    *=$A600         ;SYS RAM (ECHOED AT TOP OF MEM)
0007   A600             SCPBUF .BLOCK $20      ;SCOPE BUFFER LAST 32 CHARS
0008   A620             RAM    =*              ;DEFAULT BLK FILLS STARTING HERE
0009   A620             JTABLE .BLOCK $10      ; 8JUMPS - ABS ADDR, LO HI ORDER
0010   A630             TAPDEL .BLOCK 1        ;KH TAPE DELAY
0011   A631             KMBDRY .BLOCK 1        ;KIM TAPE READ BOUNDARY
0012   A632             HSBDRY .BLOCK 1        ;HS TAPE READ BOUNDARY
0013   A633             SCR3   .BLOCK 1        ;RAM SCRATCH LOCS 3-F
0014   A634             SCR4   .BLOCK 1
0015   A635             TAPET1 .BLOCK 1        ;HS TAPE 1/2 BIT TIME
0016   A636             SCR6   .BLOCK 1
0017   A637             SCR7   .BLOCK 1
0018   A638             SCR8   .BLOCK 1
0019   A639             SCR9   .BLOCK 1
0020   A63A             SCRA   .BLOCK 1
0021   A63B             SCRB   .BLOCK 1
0022   A63C             TAPET2 .BLOCK 1        ;HS TAPE 1/2 BIT TIME
0023   A63D             SCRD   .BLOCK 1
0024   A63E             RC     =SCRD
0025   A63E             SCRE   .BLOCK 1
0026   A63F             SCRF   .BLOCK 1
0027   A640             DISBUF .BLOCK 5        ;DISPLAY BUFFER
0028   A645             RDIG   .BLOCK 1        ;RIGHT MOST DIGIT OF DISPLAY
0029   A646                    .BLOCK 3        ;NOT USED
0030   A649             PARNR  .BLOCK 1        ;NUMBER OF PARMS RECEIVED
0031   A64A             ;
0032   A64A             ; 3 16 BIT PARMS, LO HI ORDER
0033   A64A             ; PASSED TO EXECUTE BLOCKS
0034   A64A             ;
0035   A64A             P3L    .BLOCK 1
0036   A64B             P3H    .BLOCK 1
0037   A64C             P2L    .BLOCK 1
0038   A64D             P2H    .BLOCK 1
0039   A64E             P1L    .BLOCK 1
0040   A64F             P1H    .BLOCK 1
0041   A650             PADBIT .BLOCK 1        ;PAD BITS FOR CARRIAGE RETURN
0042   A651             SDBYT  .BLOCK 1        ;SPEED BYTE FOR TERMINAL I/O
0043   A652             ERCNT  .BLOCK 1        ; ERROR COUNT  (MAX $FF)
0044   A653             ; BIT 7 = ECHO /NO ECHO, BIT 6 = CTL O TOGGLE SW
0045   A653             TECHO  .BLOCK 1        ;TERMINAL ECHO LAG
0046   A654             ; BIT7 =CRT IN, 6 =TTY IN, 5 = TTY OUT, 4 = CRT OUT
0047   A654             TOUTFL .BLOCK 1        ;OUTPUT FLAGS
0048   A655             KSHFL  .BLOCK 1        ;KEYBOARD SHIFT FLAG
0049   A656             TV     .BLOCK 1        ;TRACE VELOCITY (0=SINGLE STEP)
0050   A657             LSTCOM .BLOCK 1        ;STORE LAST MONITOR COMMAND
0051   A658             MAXRC  .BLOCK 1        ;MAXIMUM REC LENGTH FOR MEM DUMP
0052   A659             ;
0053   A659             ; USER REG'S FOLLOW
0054   A659             ;
0055   A659             PCLR   .BLOCK 1        ;PROG CTR
0056   A65A             PCHR   .BLOCK 1
0057   A65B             SR     .BLOCK 1        ;STACK
0058   A65C             FR     .BLOCK 1        ;FLAGS
0059   A65D             AR     .BLOCK 1        ;AREG
0060   A65E             XR     .BLOCK 1        ;XREG
0061   A65F             YR     .BLOCK 1        ;YREG
0062   A660             ;
0063   A660             ; I/O VECTORS FOLLOW
0064   A660             ;
0065   A660             INVEC  .BLOCK 3        ;IN CHAR
0066   A663             OUTVEC .BLOCK 3        ;OUT CHAR
0067   A666             INSVEC .BLOCK 3        ;IN STATUS
0068   A669             URSVEC .BLOCK 3        ;UNRECOGNIZED SYNTAX VECTOR
0069   A66C             URCVEC .BLOCK 3        ;UNRECOGNIZED CMD/ERROR VECTOR
0070   A66F             SCNVEC .BLOCK 3        ;SCAN ON-BOARD DISPLAY
0071   A672             ;
0072   A672             ; TRACE, INTERRUPT VECTORS
0073   A672             ;
0074   A672             EXEVEC .BLOCK 2        ; EXEC CMD ALTERNATE INVEC
0075   A674             TRCVEC .BLOCK 2        ;TRACE
0076   A676             UBRKVC .BLOCK 2        ;USER BRK AFTER MONITOR
0077   A678             UBRKV  =UBRKVC
0078   A678             UIRQVC .BLOCK 2        ;USER NON-BRK IRQ AFTER MONITOR
0079   A67A             UIRQV  =UIRQVC
0080   A67A             NMIVEC .BLOCK 2        ;NMI
0081   A67C             RSTVEC .BLOCK 2        ;RESET
0082   A67E             IRQVEC .BLOCK 2        ;IRQ
0083   A680             ;
0084   A680             ;
0085   A680             ;I/O REG DEFINITIONS
0086   A680             PADA   =$A400          ;KEYBOARD/DISPLAY
0087   A680             PBDA   =$A402          ;SERIAL I/O
0088   A680             OR3A   =$AC01          ;WP, DBON, DBOFF
0089   A680             DDR3A  =OR3A+2         ;DATA DIRECTION FOR SAME
0090   A680             OR1B   =$A000
0091   A680             DDR1B  =$A002
0092   A680             PCR1   =$A00C          ; POR/TAPE REMOTE
0093   A680             ;
0094   A680             ; MONITOR MAINLINE
0095   A680             ;
0096   8000                    *=$8000
0097   8000 4C 7C 8B    MONITR JMP MONENT      ;INIT S, CLD, GET ACCESS
0098   8003 20 FF 80    WARM   JSR GETCOM      ;GET COMMAND + PARMS (0-3)
0099   8006 20 4A 81           JSR DISPAT      ;DISPATCH CMD,PARMS TO EXEC BLKS
0100   8009 20 71 81           JSR ERMSG       ;DISP ER MSG IF CARRY SET
0101   800C 4C 03 80           JMP WARM        ;AND CONTINUE
0102   800F             ;
0103   800F             ; TRACE AND INTERRUPT ROUTINES
0104   800F             ;
0105   800F 08          IRQBRK PHP             ;IRQ OR BRK ?
0106   8010 48                 PHA
0107   8011 8A                 TXA
0108   8012 48                 PHA
0109   8013 BA                 TSX
0110   8014 BD 04 01           LDA $0104,X     ;PICK UP FLAGS
0111   8017 29 10              AND #$10
0112   8019 F0 07              BEQ DETIRQ
0113   801B 68                 PLA             ;BRK
0114   801C AA                 TAX
0115   801D 68                 PLA
0116   801E 28                 PLP
0117   801F 6C F6 FF           JMP ($FFF6)
0118   8022 68          DETIRQ PLA             ;IRQ (NON BRK)
0119   8023 AA                 TAX
0120   8024 68                 PLA
0121   8025 28                 PLP
0122   8026 6C F8 FF           JMP ($FFF8)
0123   8029 20 86 8B    SVIRQ  JSR ACCESS      ;SAVE REGS AND DISPLAY CODE
0124   802C 38                 SEC
0125   802D 20 64 80           JSR SAVINT
0126   8030 A9 31              LDA #'1'
0127   8032 4C 53 80           JMP IDISP
0128   8035 08          USRENT PHP             ;USER ENTRY
0129   8036 20 86 8B           JSR ACCESS
0130   8039 38                 SEC
0131   803A 20 64 80           JSR SAVINT
0132   803D EE 59 A6           INC PCLR
0133   8040 D0 03              BNE *+5
0134   8042 EE 5A A6           INC PCHR
0135   8045 A9 33              LDA #'3'
0136   8047 4C 53 80           JMP IDISP
0137   804A 20 86 8B    SVBRK  JSR ACCESS
0138   804D 18                 CLC
0139   804E 20 64 80           JSR SAVINT
0140   8051 A9 30              LDA #'0'
0141   8053             ; INTRPT CODES  0 = BRK
0142   8053             ;               1 = IRQ
0143   8053             ;               2 = NMI
0144   8053             ;               3 = USER ENTRY
0145   8053 48          IDISP  PHA             ;OUT PC, INTRPT CODE (FROM A)
0146   8054 20 D3 80           JSR DBOFF       ;STOP NMI'S
0147   8057 20 4D 83           JSR CRLF
0148   805A 20 37 83           JSR OPCCOM
0149   805D 68                 PLA
0150   805E 20 47 8A           JSR OUTCHR
0151   8061 4C 03 80           JMP WARM
0152   8064 8D 5D A6    SAVINT STA AR          ;SAVE USER REGS AFTER INTRPT
0153   8067 8E 5E A6           STX XR
0154   806A 8C 5F A6           STY YR
0155   806D BA                 TSX
0156   806E D8                 CLD
0157   806F BD 04 01           LDA $104,X
0158   8072 69 FF              ADC #$FF
0159   8074 8D 59 A6           STA PCLR
0160   8077 BD 05 01           LDA $105,X
0161   807A 69 FF              ADC #$FF
0162   807C 8D 5A A6           STA PCHR
0163   807F BD 03 01           LDA $103,X
0164   8082 8D 5C A6           STA FR
0165   8085 BD 02 01           LDA $102,X
0166   8088 9D 05 01           STA $105,X
0167   808B BD 01 01           LDA $101,X
0168   808E 9D 04 01           STA $104,X
0169   8091 E8                 INX
0170   8092 E8                 INX
0171   8093 E8                 INX
0172   8094 9A                 TXS
0173   8095 E8                 INX
0174   8096 E8                 INX
0175   8097 8E 5B A6           STX SR
0176   809A 60                 RTS
0177   809B 20 86 8B    SVNMI  JSR ACCESS      ;TRACE IF TV NE 0
0178   809E 38                 SEC
0179   809F 20 64 80           JSR SAVINT
0180   80A2 20 D3 80           JSR DBOFF       ;STOP NMI'S
0181   80A5 AD 56 A6           LDA TV
0182   80A8 D0 05              BNE TVNZ
0183   80AA A9 32              LDA #'2'
0184   80AC 4C 53 80           JMP IDISP
0185   80AF 20 37 83    TVNZ   JSR OPCCOM      ;TRACE WITH DELAY
0186   80B2 AD 5D A6           LDA AR
0187   80B5 20 4A 83           JSR OBCRLF      ;DISPLAY ACC
0188   80B8 20 5A 83           JSR DELAY
0189   80BB 90 10              BCC TRACON      ;STOP IF KEY ENTERED
0190   80BD 4C 03 80           JMP WARM
0191   80C0 20 86 8B    TRCOFF JSR ACCESS      ;DISABLE NMIS
0192   80C3 38                 SEC
0193   80C4 20 64 80           JSR SAVINT
0194   80C7 20 D3 80           JSR DBOFF
0195   80CA 6C 74 A6           JMP (TRCVEC)    ;AND GO TO SPECIAL TRACE
0196   80CD 20 E4 80    TRACON JSR DBON        ;ENABLE NMI'S
0197   80D0 4C FD 83           JMP GO1ENT+3    ;AND RESUME (NO WRITE PROT)
0198   80D3 AD 01 AC    DBOFF  LDA OR3A        ;PULSE DEBUG OFF
0199   80D6 29 DF              AND #$DF
0200   80D8 09 10              ORA #$10
0201   80DA 8D 01 AC           STA OR3A
0202   80DD AD 03 AC           LDA DDR3A
0203   80E0 09 30              ORA #$30
0204   80E2 D0 0F              BNE DBNEW-3     ;RELEASE FLIP FLOP SO KEY WORKS
0205   80E4 AD 01 AC    DBON   LDA OR3A        ;PULSE DEBUG ON
0206   80E7 29 EF              AND #$EF
0207   80E9 09 20              ORA #$20
0208   80EB 8D 01 AC           STA OR3A
0209   80EE AD 03 AC           LDA DDR3A
0210   80F1 09 30              ORA #$30
0211   80F3 8D 03 AC           STA DDR3A
0212   80F6 AD 03 AC    DBNEW  LDA DDR3A       ;RELEASE FLIP FLOP
0213   80F9 29 CF              AND #$CF
0214   80FB 8D 03 AC           STA DDR3A
0215   80FE 60                 RTS
0216   80FF             ;
0217   80FF             ; GETCOM - GET COMMAND AND 0-3 PARMS
0218   80FF             ;
0219   80FF 20 4D 83    GETCOM JSR CRLF
0220   8102 A9 2E              LDA #'.'        ;PROMPT
0221   8104 20 47 8A           JSR OUTCHR
0222   8107 20 1B 8A    GETC1  JSR INCHR
0223   810A F0 F3              BEQ GETCOM      ;CARRIAGE RETURN?
0224   810C C9 7F              CMP #$7F        ;DELETE?
0225   810E F0 F7              BEQ GETC1
0226   8110 C9 00              CMP #0          ;NULL?
0227   8112 F0 F3              BEQ GETC1
0228   8114             ; L,S,U NEED TO BE HASHED 2 BYTES TO ONE
0229   8114 C9 53              CMP #'S'
0230   8116 F0 1B              BEQ HASHUS
0231   8118 C9 55              CMP #'U'
0232   811A F0 17              BEQ HASHUS
0233   811C C9 4C              CMP #'L'
0234   811E F0 0F              BEQ HASHL
0235   8120 8D 57 A6    STOCOM STA LSTCOM
0236   8123 20 42 83           JSR SPACE
0237   8126 20 08 82           JSR PSHOVE      ;ZERO PARMS
0238   8129 20 08 82           JSR PSHOVE
0239   812C 4C 20 82           JMP PARM        ;AND GO GET PARMS
0240   812F A9 01       HASHL  LDA #$01        ;HASH LOAD CMDS TO ONE BYTE
0241   8131 10 02              BPL HASHUS+2
0242   8133 0A          HASHUS ASL A           ;HASH 'USER' CMDS TO ONE BYTE A
0243   8134 0A                 ASL A           ;U0 = $14 THRU U17 =$1B
0244   8135 8D 57 A6           STA LSTCOM
0245   8138 20 1B 8A           JSR INCHR       ;GET SECOND
0246   813B F0 C2              BEQ GETCOM
0247   813D 18                 CLC
0248   813E 6D 57 A6           ADC LSTCOM
0249   8141 29 0F              AND #$0F
0250   8143 09 10              ORA #$10
0251   8145 10 D9              BPL STOCOM
0252   8147 FF FF FF           .DB $FF,$FF,$FF ;NOT USED
0253   814A             ;
0254   814A             ;DISPATCH TO EXEC BLK 0PARM, 1PARM, 2PARM, OR 3PARM
0255   814A             ;
0256   814A C9 0D       DISPAT CMP #$0D        ;C/R IF OK ELSE URSVEC
0257   814C D0 20              BNE HIPN
0258   814E AD 57 A6           LDA LSTCOM
0259   8151 AE 49 A6           LDX PARNR
0260   8154 D0 03              BNE M12
0261   8156 4C 95 83           JMP BZPARM      ;0 PARM BLOCK
0262   8159 E0 01       M12    CPX #$01
0263   815B D0 03              BNE M13
0264   815D 4C DA 84           JMP B1PARM      ;1 PARM BLOCK
0265   8160 E0 02       M13    CPX #$02
0266   8162 D0 03              BNE M14
0267   8164 4C 19 86           JMP B2PARM      ;2 PARM BLOCK
0268   8167 E0 03       M14    CPX #$03
0269   8169 D0 03              BNE HIPN
0270   816B 4C 14 87           JMP B3PARM      ;3 PARM BLOCK
0271   816E 6C 6A A6    HIPN   JMP (URSVEC+1)  ;ELSE UNREC SYNTAX VECTOR
0272   8171             ;
0273   8171             ; ERMSG - PRINT ACC IN HEX IF CARRY SET
0274   8171             ;
0275   8171 90 44       ERMSG  BCC M15
0276   8173 48                 PHA
0277   8174 20 4D 83           JSR CRLF
0278   8177 A9 45              LDA #'E'
0279   8179 20 47 8A           JSR OUTCHR
0280   817C A9 52              LDA #'R'
0281   817E 20 47 8A           JSR OUTCHR
0282   8181 20 42 83           JSR SPACE
0283   8184 68                 PLA
0284   8185 4C FA 82           JMP OUTBYT
0285   8188             ;
0286   8188             ; SAVER - SAVE ALL REG'S + FLAGS ON STACK
0287   8188             ; RETURN WITH F,A,X,Y UNCHANGED
0288   8188             ; STACK HAS         FLAGS,A,X,Y, PUSHED
0289   8188 08          SAVER  PHP
0290   8189 48                 PHA
0291   818A 48                 PHA
0292   818B 48                 PHA
0293   818C 08                 PHP
0294   818D 48                 PHA
0295   818E 8A                 TXA
0296   818F 48                 PHA
0297   8190 BA                 TSX
0298   8191 BD 09 01           LDA $0109,X
0299   8194 9D 05 01           STA $0105,X
0300   8197 BD 07 01           LDA $0107,X
0301   819A 9D 09 01           STA $0109,X
0302   819D BD 01 01           LDA $0101,X
0303   81A0 9D 07 01           STA $0107,X
0304   81A3 BD 08 01           LDA $0108,X
0305   81A6 9D 04 01           STA $0104,X
0306   81A9 BD 06 01           LDA $0106,X
0307   81AC 9D 08 01           STA $0108,X
0308   81AF 98                 TYA
0309   81B0 9D 06 01           STA $0106,X
0310   81B3 68                 PLA
0311   81B4 AA                 TAX
0312   81B5 68                 PLA
0313   81B6 28                 PLP
0314   81B7 60          M15    RTS
0315   81B8             ; RESTORE EXCEPT A,F
0316   81B8 08          RESXAF PHP
0317   81B9 BA                 TSX
0318   81BA 9D 04 01           STA $0104,X
0319   81BD 28                 PLP
0320   81BE             ; RESTORE EXCEPT F
0321   81BE 08          RESXF  PHP
0322   81BF 68                 PLA
0323   81C0 BA                 TSX
0324   81C1 9D 04 01           STA $0104,X
0325   81C4             ; RESTORE ALL 100%
0326   81C4 68          RESALL PLA
0327   81C5 A8                 TAY
0328   81C6 68                 PLA
0329   81C7 AA                 TAX
0330   81C8 68                 PLA
0331   81C9 28                 PLP
0332   81CA 60                 RTS
0333   81CB             ;
0334   81CB             ; MONITOR UTILITIES
0335   81CB             ;
0336   81CB C9 20       ADVCK  CMP #$20        ;SPACE?
0337   81CD F0 02              BEQ M1
0338   81CF C9 3E              CMP #'>'        ;FWD ARROW?
0339   81D1 38          M1     SEC
0340   81D2 60                 RTS
0341   81D3 20 FA 82    OBCMIN JSR OUTBYT      ;OUT BYTE, OUT COMMA, IN BYTE
0342   81D6 20 3A 83    COMINB JSR COMMA       ;OUT COMMA, IN BYTE
0343   81D9 20 1B 8A    INBYTE JSR INCHR
0344   81DC 20 75 82           JSR ASCNIB
0345   81DF B0 14              BCS OUT4
0346   81E1 0A                 ASL A
0347   81E2 0A                 ASL A
0348   81E3 0A                 ASL A
0349   81E4 0A                 ASL A
0350   81E5 8D 33 A6           STA SCR3
0351   81E8 20 1B 8A           JSR INCHR
0352   81EB 20 75 82           JSR ASCNIB
0353   81EE B0 11              BCS OUT2
0354   81F0 0D 33 A6           ORA SCR3
0355   81F3 18          GOOD   CLC
0356   81F4 60                 RTS
0357   81F5 C9 3A       OUT4   CMP #':'        ;COLON ?
0358   81F7 D0 05              BNE OUT1
0359   81F9 20 1B 8A           JSR INCHR
0360   81FC D0 F5              BNE GOOD        ;CARRIAGE RETURN?
0361   81FE B8          OUT1   CLV
0362   81FF 50 03              BVC CRCHK
0363   8201 2C 04 82    OUT2   BIT CRCHK
0364   8204 C9 0D       CRCHK  CMP #$0D        ;CHECK FOR C/R
0365   8206 38                 SEC
0366   8207 60                 RTS
0367   8208 A2 10       PSHOVE LDX #$10        ;PUSH PARMS DOWN
0368   820A 0E 4A A6    PRM10  ASL P3L
0369   820D 2E 4B A6           ROL P3H
0370   8210 2E 4C A6           ROL P2L
0371   8213 2E 4D A6           ROL P2H
0372   8216 2E 4E A6           ROL P1L
0373   8219 2E 4F A6           ROL P1H
0374   821C CA                 DEX
0375   821D D0 EB              BNE PRM10
0376   821F 60                 RTS
0377   8220 20 88 81    PARM   JSR SAVER       ;GET PARMS - RETURN ON C/R OR ERR
0378   8223 A9 00              LDA #0
0379   8225 8D 49 A6           STA PARNR
0380   8228 8D 33 A6           STA SCR3
0381   822B 20 08 82    PM1    JSR PSHOVE
0382   822E 20 1B 8A    PARFIL JSR INCHR
0383   8231 C9 2C              CMP #','        ;VALID DELIMETERS - ,
0384   8233 F0 04              BEQ M21
0385   8235 C9 2D              CMP #'-'
0386   8237 D0 11              BNE M22
0387   8239 A2 FF       M21    LDX #$FF
0388   823B 8E 33 A6           STX SCR3
0389   823E EE 49 A6           INC PARNR
0390   8241 AE 49 A6           LDX PARNR
0391   8244 E0 03              CPX #$03
0392   8246 D0 E3              BNE PM1
0393   8248 F0 1D              BEQ M24
0394   824A 20 75 82    M22    JSR ASCNIB
0395   824D B0 18              BCS M24
0396   824F A2 04              LDX #4
0397   8251 0E 4A A6    M23    ASL P3L
0398   8254 2E 4B A6           ROL P3H
0399   8257 CA                 DEX
0400   8258 D0 F7              BNE M23
0401   825A 0D 4A A6           ORA P3L
0402   825D 8D 4A A6           STA P3L
0403   8260 A9 FF              LDA #$FF
0404   8262 8D 33 A6           STA SCR3
0405   8265 D0 C7              BNE PARFIL
0406   8267 2C 33 A6    M24    BIT SCR3
0407   826A F0 03              BEQ M25
0408   826C EE 49 A6           INC PARNR
0409   826F C9 0D       M25    CMP #$0D
0410   8271 18                 CLC
0411   8272 4C B8 81           JMP RESXAF
0412   8275 C9 0D       ASCNIB CMP #$0D        ;C/R?
0413   8277 F0 19              BEQ M29
0414   8279 C9 30              CMP #'0'
0415   827B 90 0C              BCC M26
0416   827D C9 47              CMP #'G'
0417   827F B0 08              BCS M26
0418   8281 C9 41              CMP #'A'
0419   8283 B0 08              BCS M27
0420   8285 C9 3A              CMP #':'
0421   8287 90 06              BCC M28
0422   8289 C9 30       M26    CMP #'0'
0423   828B 38                 SEC             ;CARRY SET - NON HEX
0424   828C 60                 RTS
0425   828D E9 37       M27    SBC #$37
0426   828F 29 0F       M28    AND #$0F
0427   8291 18                 CLC
0428   8292 60          M29    RTS
0429   8293 EE 4A A6    INCP3  INC P3L         ;INCREMENT P3 (16 BITS)
0430   8296 D0 03              BNE *+5
0431   8298 EE 4B A6           INC P3H
0432   829B 60                 RTS
0433   829C AE 4D A6    P2SCR  LDX P2H         ;MOVE P2 TO FE,FF
0434   829F 86 FF              STX $FF
0435   82A1 AE 4C A6           LDX P2L
0436   82A4 86 FE              STX $FE
0437   82A6 60                 RTS
0438   82A7 AE 4B A6    P3SCR  LDX P3H         ;MOVE P3 TO FE,FF
0439   82AA 86 FF              STX $FF
0440   82AC AE 4A A6           LDX P3L
0441   82AF 86 FE              STX $FE
0442   82B1 60                 RTS
0443   82B2 E6 FE       INCCMP INC $FE         ;INCREM FE,FF, COMPARE TO P3
0444   82B4 D0 14              BNE COMPAR
0445   82B6 E6 FF              INC $FF
0446   82B8 D0 10       WRAP   BNE COMPAR      ;TEST TO WRAP AROUND
0447   82BA 2C BD 82           BIT EXWRAP
0448   82BD 60          EXWRAP RTS
0449   82BE A5 FE       DECCMP LDA $FE         ;DECREM FE,FF AND COMPARE TO P3
0450   82C0 D0 06              BNE M32
0451   82C2 A5 FF              LDA $FF
0452   82C4 F0 F2              BEQ WRAP
0453   82C6 C6 FF              DEC $FF
0454   82C8 C6 FE       M32    DEC $FE
0455   82CA 20 88 81    COMPAR JSR SAVER       ;COMPARE FE,FF TO P3
0456   82CD A5 FF              LDA $FF
0457   82CF CD 4B A6           CMP P3H
0458   82D2 D0 05              BNE EXITCP
0459   82D4 A5 FE              LDA $FE
0460   82D6 CD 4A A6           CMP P3L
0461   82D9 B8          EXITCP CLV
0462   82DA 4C BE 81           JMP RESXF
0463   82DD 08          CHKSAD PHP             ;16 BIT CKSUM IN SCR6,7
0464   82DE 48                 PHA
0465   82DF 18                 CLC
0466   82E0 6D 36 A6           ADC SCR6
0467   82E3 8D 36 A6           STA SCR6
0468   82E6 90 03              BCC M33
0469   82E8 EE 37 A6           INC SCR7
0470   82EB 68          M33    PLA
0471   82EC 28                 PLP
0472   82ED 60                 RTS
0473   82EE AD 59 A6    OUTPC  LDA PCLR        ;OUTPUT PC
0474   82F1 AE 5A A6           LDX PCHR
0475   82F4 48          OUTXAH PHA
0476   82F5 8A                 TXA
0477   82F6 20 FA 82           JSR OUTBYT
0478   82F9 68                 PLA
0479   82FA 48          OUTBYT PHA             ;OUTPUT 2 HEX DIGS FROM A
0480   82FB 48                 PHA
0481   82FC 4A                 LSR A
0482   82FD 4A                 LSR A
0483   82FE 4A                 LSR A
0484   82FF 4A                 LSR A
0485   8300 20 44 8A           JSR NBASOC
0486   8303 68                 PLA
0487   8304 20 44 8A           JSR NBASOC
0488   8307 68                 PLA
0489   8308 60                 RTS
0490   8309 29 0F       NIBASC AND #$0F        ;NIBBLE IN A TO ASCII IN A
0491   830B C9 0A              CMP #$0A        ;LINE FEED
0492   830D B0 04              BCS NIBALF
0493   830F 69 30              ADC #$30
0494   8311 90 02              BCC EXITNB
0495   8313 69 36       NIBALF ADC #$36
0496   8315 60          EXITNB RTS
0497   8316 20 4D 83    CRLFSZ JSR CRLF        ;PRINT CRLF, FF, FE
0498   8319 A6 FF              LDX $FF
0499   831B A5 FE              LDA $FE
0500   831D 4C F4 82           JMP OUTXAH
0501   8320 A9 3F       OUTQM  LDA #'?'
0502   8322 4C 47 8A           JMP OUTCHR
0503   8325 20 3A 83    OCMCK  JSR COMMA       ;OUT COMMA, CKSUM LO
0504   8328 AD 36 A6           LDA SCR6
0505   832B 4C FA 82           JMP OUTBYT
0506   832E A9 00       ZERCK  LDA #0          ;INIT CHECKSUM
0507   8330 8D 36 A6           STA SCR6
0508   8333 8D 37 A6           STA SCR7
0509   8336 60                 RTS
0510   8337 20 EE 82    OPCCOM JSR OUTPC       ;PC OUT, COMMA OUT
0511   833A 48          COMMA  PHA             ;COMMA OUT
0512   833B A9 2C              LDA #','
0513   833D D0 06              BNE SPCP3
0514   833F 20 42 83    SPC2   JSR SPACE       ;2 SPACES OUT
0515   8342 48          SPACE  PHA             ;1 SPACE OUT
0516   8343 A9 20              LDA #$20        ;SPACE
0517   8345 20 47 8A    SPCP3  JSR OUTCHR
0518   8348 68                 PLA
0519   8349 60                 RTS
0520   834A 20 FA 82    OBCRLF JSR OUTBYT      ;BYTE OUT, CRLF OUT
0521   834D 48          CRLF   PHA
0522   834E A9 0D              LDA #$0D
0523   8350 20 47 8A           JSR OUTCHR
0524   8353 A9 0A              LDA #$0A        ;LINE FEED
0525   8355 20 47 8A           JSR OUTCHR
0526   8358 68                 PLA
0527   8359 60                 RTS
0528   835A AE 56 A6    DELAY  LDX TV          ;DELAY DEPENDS ON TV
0529   835D 20 88 81    DL1    JSR SAVER
0530   8360 A9 FF              LDA #$FF
0531   8362 8D 39 A6           STA SCR9
0532   8365 8D 38 A6           STA SCR8
0533   8368 0E 38 A6    DLY1   ASL SCR8        ;(SCR9,8)=FFFF-2**X
0534   836B 2E 39 A6           ROL SCR9
0535   836E CA                 DEX
0536   836F D0 F7              BNE DLY1
0537   8371 20 03 89    DLY2   JSR IJSCNV      ;SCAN DISPLAY
0538   8374 20 86 83           JSR INSTAT      ;SEE IF KEY DOWN
0539   8377 B0 0A              BCS DLY0
0540   8379 EE 38 A6           INC SCR8        ;SCAN 2**X+1 TIMES
0541   837C D0 03              BNE *+5
0542   837E EE 39 A6           INC SCR9
0543   8381 D0 EE              BNE DLY2
0544   8383 4C BE 81    DLY0   JMP RESXF
0545   8386             ; INSTAT - SEE IF KEY DOWN, RESULT IN CARRY
0546   8386             ; KEYSTAT, TSTAT RETURN IMMEDIATELY W/STATUS
0547   8386             ; INSTAT WAITS FOR RELEASE
0548   8386 20 92 83    INSTAT JSR INJISV
0549   8389 90 06              BCC INST2
0550   838B 20 92 83    INST1  JSR INJISV
0551   838E B0 FB              BCS INST1
0552   8390 38                 SEC
0553   8391 60          INST2  RTS
0554   8392 6C 67 A6    INJISV JMP (INSVEC+1)
0555   8395             ;
0556   8395             ;
0557   8395             ; *** EXECUTE BLOCKS BEGIN HERE
0558   8395             ;
0559   8395             BZPARM =*
0560   8395             ; ZERO PARM COMMANDS
0561   8395             ;
0562   8395 C9 52       REGZ   CMP #'R'        ;DISP REGISTERS
0563   8397 D0 5A              BNE GOZ         ;PC,S,F,A,X,Y
0564   8399 20 4D 83    RGBACK JSR CRLF
0565   839C A9 50              LDA #'P'
0566   839E 20 47 8A           JSR OUTCHR
0567   83A1 20 42 83           JSR SPACE
0568   83A4 20 EE 82           JSR OUTPC
0569   83A7 20 D6 81           JSR COMINB
0570   83AA B0 13              BCS NH3
0571   83AC 8D 34 A6           STA SCR4
0572   83AF 20 D9 81           JSR INBYTE
0573   83B2 B0 0B              BCS NH3
0574   83B4 8D 59 A6           STA PCLR
0575   83B7 AD 34 A6           LDA SCR4
0576   83BA 8D 5A A6           STA PCHR
0577   83BD 90 09              BCC M34
0578   83BF D0 02       NH3    BNE NOTCR
0579   83C1 18          EXITRG CLC
0580   83C2 60          EXRGP1 RTS
0581   83C3 20 CB 81    NOTCR  JSR ADVCK
0582   83C6 D0 FA              BNE EXRGP1
0583   83C8 A0 00       M34    LDY #0
0584   83CA C8          M35    INY
0585   83CB C0 06              CPY #6
0586   83CD F0 CA              BEQ RGBACK
0587   83CF 20 4D 83           JSR CRLF
0588   83D2 B9 99 8F           LDA RGNAM-1,Y   ;GET REG NAME
0589   83D5             ; OUTPUT 3 SPACES TO LINE UP DISPLAY
0590   83D5 20 47 8A           JSR OUTCHR
0591   83D8 20 42 83           JSR SPACE
0592   83DB 20 3F 83           JSR SPC2
0593   83DE B9 5A A6           LDA PCHR,Y
0594   83E1 20 D3 81           JSR OBCMIN
0595   83E4 B0 05              BCS M36
0596   83E6 99 5A A6           STA PCHR,Y
0597   83E9 90 DF              BCC M35
0598   83EB F0 D4       M36    BEQ EXITRG
0599   83ED 20 CB 81           JSR ADVCK
0600   83F0 F0 D8              BEQ M35
0601   83F2 60                 RTS
0602   83F3 C9 47       GOZ    CMP #'G'
0603   83F5 D0 20              BNE LPZB
0604   83F7 20 4D 83           JSR CRLF
0605   83FA 20 9C 8B    GO1ENT JSR NACCES      ;WRITE PROT MONITOR RAM
0606   83FD AE 5B A6           LDX SR          ;RESTORE REGS
0607   8400 9A                 TXS
0608   8401 AD 5A A6           LDA PCHR
0609   8404 48                 PHA
0610   8405 AD 59 A6           LDA PCLR
0611   8408 48          NR10   PHA
0612   8409 AD 5C A6           LDA FR
0613   840C 48                 PHA
0614   840D AC 5F A6           LDY YR
0615   8410 AE 5E A6           LDX XR
0616   8413 AD 5D A6           LDA AR
0617   8416 40                 RTI
0618   8417 C9 11       LPZB   CMP #$11        ;LOAD PAPER TAPE
0619   8419 F0 03              BEQ *+5
0620   841B 4C A7 84           JMP DEPZ
0621   841E 20 88 81           JSR SAVER
0622   8421 20 4D 83           JSR CRLF
0623   8424 A9 00              LDA #0
0624   8426 8D 52 A6           STA ERCNT
0625   8429 20 2E 83    LPZ    JSR ZERCK
0626   842C 20 1B 8A    LP1    JSR INCHR
0627   842F C9 3B              CMP #$3B        ;SEMI COLON
0628   8431 D0 F9              BNE LP1
0629   8433 20 A1 84           JSR LDBYTE
0630   8436 B0 56              BCS TAPERR
0631   8438 D0 09              BNE NUREC
0632   843A AD 52 A6           LDA ERCNT       ;ERRORS ?
0633   843D F0 01              BEQ *+3
0634   843F 38                 SEC
0635   8440 4C B8 81           JMP RESXAF
0636   8443 8D 3D A6    NUREC  STA SCRD
0637   8446 20 A1 84           JSR LDBYTE
0638   8449 B0 43              BCS TAPERR
0639   844B 85 FF              STA $FF
0640   844D 20 A1 84           JSR LDBYTE
0641   8450 B0 D7              BCS LPZ
0642   8452 85 FE              STA $FE
0643   8454 20 A1 84    MORED  JSR LDBYTE
0644   8457 B0 35              BCS TAPERR
0645   8459 A0 00              LDY #0
0646   845B 91 FE              STA ($FE),Y
0647   845D D1 FE              CMP ($FE),Y
0648   845F F0 0C              BEQ LPGD
0649   8461 AD 52 A6           LDA ERCNT
0650   8464 29 0F              AND #$0F
0651   8466 C9 0F              CMP #$0F
0652   8468 F0 03              BEQ *+5
0653   846A EE 52 A6           INC ERCNT
0654   846D 20 B2 82    LPGD   JSR INCCMP
0655   8470 CE 3D A6           DEC SCRD
0656   8473 D0 DF              BNE MORED
0657   8475 20 D9 81           JSR INBYTE
0658   8478 B0 14              BCS TAPERR
0659   847A CD 37 A6           CMP SCR7
0660   847D D0 0C              BNE BADDY
0661   847F 20 D9 81           JSR INBYTE
0662   8482 B0 0A              BCS TAPERR
0663   8484 CD 36 A6           CMP SCR6
0664   8487 F0 A0              BEQ LPZ
0665   8489 D0 03              BNE TAPERR      ;(ALWAYS)
0666   848B 20 D9 81    BADDY  JSR INBYTE
0667   848E AD 52 A6    TAPERR LDA ERCNT
0668   8491 29 F0              AND #$F0
0669   8493 C9 F0              CMP #$F0
0670   8495 F0 92              BEQ LPZ
0671   8497 AD 52 A6           LDA ERCNT
0672   849A 69 10              ADC #$10
0673   849C 8D 52 A6           STA ERCNT
0674   849F D0 88              BNE LPZ
0675   84A1 20 D9 81    LDBYTE JSR INBYTE
0676   84A4 4C DD 82           JMP CHKSAD
0677   84A7 C9 44       DEPZ   CMP #'D'        ;DEPOSIT, 0 PARM - USE (OLD)
0678   84A9 D0 03              BNE MEMZ
0679   84AB 4C E1 84           JMP NEWLN
0680   84AE C9 4D       MEMZ   CMP #'M'        ;MEM, 0 PARM - USE (OLD)
0681   84B0 D0 03              BNE VERZ
0682   84B2 4C 17 85           JMP NEWLOC
0683   84B5 C9 56       VERZ   CMP #'V'        ;VERIFY, 0 PARM - USE (OLD)
0684   84B7 D0 0D              BNE L1ZB        ; ... DO 8 BYTES (LIKE VER 1 PARM)
0685   84B9 A5 FE              LDA $FE
0686   84BB 8D 4A A6           STA P3L
0687   84BE A5 FF              LDA $FF
0688   84C0 8D 4B A6           STA P3H
0689   84C3 4C 9A 85           JMP VER1+4
0690   84C6 C9 12       L1ZB   CMP #$12        ;LOAD KIM, ZERO PARM
0691   84C8 D0 05              BNE L2ZB
0692   84CA A0 00              LDY #0          ;MODE = KIM
0693   84CC 4C 78 8C    L1J    JMP LENTRY      ;GO TO CASSETTE ROUTINE
0694   84CF C9 13       L2ZB   CMP #$13        ;LOAD HS, ZERO PARM
0695   84D1 D0 04              BNE EZPARM
0696   84D3 A0 80              LDY #$80        ;MODE - HS
0697   84D5 D0 F5              BNE L1J         ;(ALWAYS)
0698   84D7 6C 6D A6    EZPARM JMP (URCVEC+1)  ;ELSE UNREC COMMAND
0699   84DA             B1PARM =*
0700   84DA             ;
0701   84DA             ; 1 PARAMETER COMMAND EXEC BLOCKS
0702   84DA             ;
0703   84DA C9 44       DEP1   CMP #'D'        ;DEPOSIT, 1 PARM
0704   84DC D0 32              BNE MEM1
0705   84DE 20 A7 82           JSR P3SCR
0706   84E1 20 16 83    NEWLN  JSR CRLFSZ
0707   84E4 A0 00              LDY #0
0708   84E6 A2 08              LDX #8
0709   84E8 20 42 83    DEPBYT JSR SPACE
0710   84EB 20 D9 81           JSR INBYTE
0711   84EE B0 11              BCS NH41
0712   84F0 91 FE              STA ($FE),Y
0713   84F2 D1 FE              CMP ($FE),Y     ;VERIFY
0714   84F4 F0 03              BEQ DEPN
0715   84F6 20 20 83           JSR OUTQM       ;TYPE "?" IF NG
0716   84F9 20 B2 82    DEPN   JSR INCCMP
0717   84FC CA                 DEX
0718   84FD D0 E9              BNE DEPBYT
0719   84FF F0 E0              BEQ NEWLN
0720   8501 F0 0B       NH41   BEQ DEPEC
0721   8503 C9 20              CMP #$20        ;SPACE = FWD
0722   8505 D0 4C              BNE DEPES
0723   8507 70 F0              BVS DEPN
0724   8509 20 42 83           JSR SPACE
0725   850C 10 EB              BPL DEPN
0726   850E 18          DEPEC  CLC
0727   850F 60                 RTS
0728   8510 C9 4D       MEM1   CMP #'M'        ;MEMORY, 1 PARM
0729   8512 D0 65              BNE GO1
0730   8514 20 A7 82           JSR P3SCR
0731   8517 20 16 83    NEWLOC JSR CRLFSZ
0732   851A 20 3A 83           JSR COMMA
0733   851D A0 00              LDY #0
0734   851F B1 FE              LDA ($FE),Y
0735   8521 20 D3 81           JSR OBCMIN
0736   8524 B0 11              BCS NH42
0737   8526 A0 00              LDY #$00
0738   8528 91 FE              STA ($FE),Y
0739   852A D1 FE              CMP ($FE),Y     ;VERIFY MEM
0740   852C F0 03              BEQ NXTLOC
0741   852E 20 20 83           JSR OUTQM       ;TYPE ? AND CONTINUE
0742   8531 20 B2 82    NXTLOC JSR INCCMP
0743   8534 18                 CLC
0744   8535 90 E0              BCC NEWLOC
0745   8537 F0 3E       NH42   BEQ EXITM1
0746   8539 50 04              BVC *+6
0747   853B C9 3C              CMP #'<'
0748   853D F0 D8              BEQ NEWLOC
0749   853F C9 20              CMP #$20        ;SPACE ?
0750   8541 F0 EE              BEQ NXTLOC
0751   8543 C9 3E              CMP #'>'
0752   8545 F0 EA              BEQ NXTLOC
0753   8547 C9 2B              CMP #'+'
0754   8549 F0 10              BEQ LOCP8
0755   854B C9 3C              CMP #'<'
0756   854D F0 06              BEQ PRVLOC
0757   854F C9 2D              CMP #'-'
0758   8551 F0 16              BEQ LOCM8
0759   8553 38          DEPES  SEC
0760   8554 60                 RTS
0761   8555 20 BE 82    PRVLOC JSR DECCMP      ;BACK ONE BYT
0762   8558 18                 CLC
0763   8559 90 BC              BCC NEWLOC
0764   855B A5 FE       LOCP8  LDA $FE         ;GO FWD 8 BYTES
0765   855D 18                 CLC
0766   855E 69 08              ADC #$08
0767   8560 85 FE              STA $FE
0768   8562 90 02              BCC M42
0769   8564 E6 FF              INC $FF
0770   8566 18          M42    CLC
0771   8567 90 AE              BCC NEWLOC
0772   8569 A5 FE       LOCM8  LDA $FE         ;GO BACKWD 8 BYTES
0773   856B 38                 SEC
0774   856C E9 08              SBC #$08
0775   856E 85 FE              STA $FE
0776   8570 B0 02              BCS M43
0777   8572 C6 FF              DEC $FF
0778   8574 18          M43    CLC
0779   8575 90 A0              BCC NEWLOC
0780   8577 18          EXITM1 CLC
0781   8578 60                 RTS
0782   8579 C9 47       GO1    CMP #'G'        ;GO, 1 PARM (RTRN ADDR ON STK)
0783   857B D0 19              BNE VER1        ; ... PARM IS ADDR TO GO TO
0784   857D 20 4D 83           JSR CRLF
0785   8580 20 9C 8B           JSR NACCES      ;WRITE PROT MONITR RAM
0786   8583 A2 FF              LDX #$FF        ;PUSH RETURN ADDR
0787   8585 9A                 TXS
0788   8586 A9 7F              LDA #$7F
0789   8588 48                 PHA
0790   8589 A9 FF              LDA #$FF
0791   858B 48                 PHA
0792   858C AD 4B A6           LDA P3H
0793   858F 48                 PHA
0794   8590 AD 4A A6           LDA P3L
0795   8593 4C 08 84           JMP NR10
0796   8596 C9 56       VER1   CMP #'V'        ;VERIFY, 1 PARM (8 BYTES, CKSUM)
0797   8598 D0 1A              BNE JUMP1
0798   859A AD 4A A6           LDA P3L
0799   859D 8D 4C A6           STA P2L
0800   85A0 18                 CLC
0801   85A1 69 07              ADC #$07
0802   85A3 8D 4A A6           STA P3L
0803   85A6 AD 4B A6           LDA P3H
0804   85A9 8D 4D A6           STA P2H
0805   85AC 69 00              ADC #0
0806   85AE 8D 4B A6           STA P3H
0807   85B1 4C 40 86           JMP VER2+4
0808   85B4 C9 4A       JUMP1  CMP #'J'        ;JUMP (JUMP TABLE IN SYS RAM)
0809   85B6 D0 1F              BNE L11B
0810   85B8 AD 4A A6           LDA P3L
0811   85BB C9 08              CMP #8          ;0-7 ONLY VALID
0812   85BD B0 26              BCS JUM2
0813   85BF 20 9C 8B           JSR NACCES      ;WRITE PROT SYS RAM
0814   85C2 0A                 ASL A
0815   85C3 A8                 TAY
0816   85C4 A2 FF              LDX #$FF        ;INIT STK PTR
0817   85C6 9A                 TXS
0818   85C7 A9 7F              LDA #$7F        ;PUSH COLD RETURN
0819   85C9 48                 PHA
0820   85CA A9 FF              LDA #$FF
0821   85CC 48                 PHA
0822   85CD B9 21 A6           LDA JTABLE+1,Y  ;GET ADDR FROM TABLE
0823   85D0 48                 PHA             ;PUSH ON STACK
0824   85D1 B9 20 A6           LDA JTABLE,Y
0825   85D4 4C 08 84           JMP NR10        ;LOAD UP USER REG'S AND RTI
0826   85D7 C9 12       L11B   CMP #$12        ;LOAD KIM FMT, 1 PARM
0827   85D9 D0 14              BNE L21B
0828   85DB A0 00              LDY #0          ;MODE = KIM
0829   85DD AD 4A A6    L11C   LDA P3L
0830   85E0 C9 FF              CMP #$FF        ;ID MUST NOT BE FF
0831   85E2 D0 02              BNE *+4
0832   85E4 38                 SEC
0833   85E5 60          JUM2   RTS
0834   85E6 20 08 82           JSR PSHOVE      ;FIX PARM POSITION
0835   85E9 20 08 82    L11D   JSR PSHOVE
0836   85EC 4C 78 8C           JMP LENTRY
0837   85EF C9 13       L21B   CMP #$13        ;LOAD TAPE, HS FMT, 1 PARM
0838   85F1 D0 04              BNE WPR1B
0839   85F3 A0 80              LDY #$80        ;MODE = HS
0840   85F5 D0 E6              BNE L11C
0841   85F7 C9 57       WPR1B  CMP #'W'        ;WRITE PROT USER RAM
0842   85F9 D0 1B              BNE E1PARM
0843   85FB AD 4A A6           LDA P3L         ; FIRST DIG IS 1K ABOVE 0,
0844   85FE 29 11              AND #$11        ; SECOND IS 2K ABOVE 0
0845   8600 C9 08              CMP #8          ; THIRD IS 3K ABOVE 0.
0846   8602 2A                 ROL A
0847   8603 4E 4B A6           LSR P3H
0848   8606 2A                 ROL A
0849   8607 0A                 ASL A
0850   8608 29 0F              AND #$0F
0851   860A 49 0F              EOR #$0F        ;0 IS PROTECT
0852   860C 8D 01 AC           STA OR3A
0853   860F A9 0F              LDA #$0F
0854   8611 8D 03 AC           STA DDR3A
0855   8614 18                 CLC
0856   8615 60                 RTS
0857   8616 4C 27 88    E1PARM JMP CALC3
0858   8619             B2PARM =*
0859   8619             ;
0860   8619             ; 2 PARAMETER EXEC BLOCKS
0861   8619             ;
0862   8619 C9 10       STD2   CMP #$10        ;STORE DOUBLE BYTE
0863   861B D0 12              BNE MEM2
0864   861D 20 A7 82           JSR P3SCR
0865   8620 AD 4D A6           LDA P2H
0866   8623 A0 01              LDY #1
0867   8625 91 FE              STA ($FE),Y
0868   8627 88                 DEY
0869   8628 AD 4C A6           LDA P2L
0870   862B 91 FE              STA ($FE),Y
0871   862D 18                 CLC
0872   862E 60                 RTS
0873   862F C9 4D       MEM2   CMP #'M'        ;CONTINUE MEM SEARCH W/OLD PTR
0874   8631 D0 09              BNE VER2
0875   8633 AD 4C A6           LDA P2L
0876   8636 8D 4E A6           STA P1L
0877   8639 4C 08 88           JMP MEM3C
0878   863C C9 56       VER2   CMP #'V'        ;VERIFY MEM W/CHKSUMS , 2 PARM
0879   863E D0 48              BNE L12B
0880   8640 20 9C 82           JSR P2SCR
0881   8643 20 2E 83           JSR ZERCK
0882   8646 20 16 83    VADDR  JSR CRLFSZ
0883   8649 A2 08              LDX #8
0884   864B 20 42 83    V2     JSR SPACE
0885   864E A0 00              LDY #0
0886   8650 B1 FE              LDA ($FE),Y
0887   8652 20 DD 82           JSR CHKSAD
0888   8655 20 FA 82           JSR OUTBYT
0889   8658 20 B2 82           JSR INCCMP
0890   865B 70 11              BVS V1
0891   865D F0 02              BEQ *+4
0892   865F B0 0D              BCS V1
0893   8661 CA                 DEX
0894   8662 D0 E7              BNE V2
0895   8664 20 25 83           JSR OCMCK
0896   8667 20 86 83           JSR INSTAT
0897   866A 90 DA              BCC VADDR
0898   866C 18                 CLC
0899   866D 60                 RTS
0900   866E 20 BE 82    V1     JSR DECCMP
0901   8671 E0 08              CPX #8
0902   8673 F0 03              BEQ *+5
0903   8675 E8                 INX
0904   8676 10 F6              BPL V1
0905   8678 20 25 83           JSR OCMCK
0906   867B 20 4D 83           JSR CRLF
0907   867E 20 42 83           JSR SPACE
0908   8681 AE 37 A6           LDX SCR7
0909   8684 20 F4 82           JSR OUTXAH
0910   8687 60                 RTS
0911   8688 C9 12       L12B   CMP #$12        ;LOAD KIM FMT TAPE, 2 PARMS
0912   868A D0 0C              BNE SP2B
0913   868C AD 4C A6           LDA P2L
0914   868F C9 FF              CMP #$FF        ;ID MUST BE FF
0915   8691 D0 F4              BNE L12B-1      ;ERR
0916   8693 A0 00              LDY #0          ;MODE = HS
0917   8695 4C E9 85           JMP L11D
0918   8698 C9 1C       SP2B   CMP #$1C        ;SAVE PAPER TAPE, 2 PARMS
0919   869A D0 75              BNE E2PARM
0920   869C 18                 CLC
0921   869D 20 88 81           JSR SAVER
0922   86A0 20 9C 82           JSR P2SCR
0923   86A3 20 FA 86    SP2C   JSR DIFFZ
0924   86A6 B0 03              BCS SP2D
0925   86A8 4C C4 81    SPEXIT JMP RESALL
0926   86AB 20 4D 83    SP2D   JSR CRLF
0927   86AE CD 58 A6           CMP MAXRC
0928   86B1 90 05              BCC SP2E
0929   86B3 AD 58 A6           LDA MAXRC
0930   86B6 B0 02              BCS SP2F
0931   86B8 69 01       SP2E   ADC #1
0932   86BA 8D 3D A6    SP2F   STA RC
0933   86BD A9 3B              LDA #$3B        ;SEMI COLON
0934   86BF 20 47 8A           JSR OUTCHR
0935   86C2 AD 3D A6           LDA RC
0936   86C5 20 F4 86           JSR SVBYTE
0937   86C8 A5 FF              LDA $FF
0938   86CA 20 F4 86           JSR SVBYTE
0939   86CD A5 FE              LDA $FE
0940   86CF 20 F4 86           JSR SVBYTE
0941   86D2 A0 00       MORED2 LDY #$00
0942   86D4 B1 FE              LDA ($FE),Y
0943   86D6 20 F4 86           JSR SVBYTE
0944   86D9 20 86 83           JSR INSTAT      ;STOP IF KEY DEPRESSED
0945   86DC B0 CA              BCS SPEXIT
0946   86DE 20 B2 82           JSR INCCMP
0947   86E1 70 C5              BVS SPEXIT
0948   86E3 CE 3D A6           DEC RC
0949   86E6 D0 EA              BNE MORED2
0950   86E8 AE 37 A6           LDX SCR7
0951   86EB AD 36 A6           LDA SCR6
0952   86EE 20 F4 82           JSR OUTXAH
0953   86F1 18                 CLC
0954   86F2 90 AF              BCC SP2C
0955   86F4 20 DD 82    SVBYTE JSR CHKSAD
0956   86F7 4C FA 82           JMP OUTBYT
0957   86FA 20 2E 83    DIFFZ  JSR ZERCK
0958   86FD AD 4A A6    DIFFL  LDA P3L
0959   8700 38                 SEC
0960   8701 E5 FE              SBC $FE
0961   8703 48                 PHA
0962   8704 AD 4B A6           LDA P3H
0963   8707 E5 FF              SBC $FF
0964   8709 F0 04              BEQ DIFF1
0965   870B 68                 PLA
0966   870C A9 FF              LDA #$FF
0967   870E 60                 RTS
0968   870F 68          DIFF1  PLA
0969   8710 60                 RTS
0970   8711 4C 27 88    E2PARM JMP CALC3       ;MAY BE CALC OR EXEC
0971   8714             B3PARM =*
0972   8714             ;
0973   8714             ; 3 PARAMETER COMMAND EXECUTE BLOCKS
0974   8714             ;
0975   8714 C9 46       FILL3  CMP #'F'        ;FILL MEM
0976   8716 D0 21              BNE BLK3
0977   8718 20 9C 82           JSR P2SCR
0978   871B A9 00              LDA #0
0979   871D 8D 52 A6           STA ERCNT       ;ZERO ERROR COUNT
0980   8720 AD 4E A6           LDA P1L
0981   8723 A0 00       F1     LDY #0
0982   8725 91 FE              STA ($FE),Y
0983   8727 D1 FE              CMP ($FE),Y     ;VERIFY
0984   8729 F0 03              BEQ F3
0985   872B 20 C1 87           JSR BRTT        ;INC ERCNT (UP TO FF)
0986   872E 20 B2 82    F3     JSR INCCMP
0987   8731 70 7C              BVS B1
0988   8733 F0 EE              BEQ F1
0989   8735 90 EC              BCC F1
0990   8737 B0 76       F2     BCS B1          ;(ALWAYS)
0991   8739 C9 42       BLK3   CMP #'B'        ;BLOCK MOVE (OVERLAP OKAY)
0992   873B F0 03              BEQ *+5
0993   873D 4C CD 87           JMP S13B
0994   8740 A9 00              LDA #0
0995   8742 8D 52 A6           STA ERCNT
0996   8745 20 9C 82           JSR P2SCR
0997   8748 AD 4E A6           LDA P1L
0998   874B 85 FC              STA $FC
0999   874D AD 4F A6           LDA P1H
1000   8750 85 FD              STA $FD
1001   8752 C5 FF              CMP $FF         ;WHICH DIRECTION TO MOVE?
1002   8754 D0 06              BNE *+8
1003   8756 A5 FC              LDA $FC
1004   8758 C5 FE              CMP $FE
1005   875A F0 53              BEQ B1          ;16 BITS EQUAL THEN FINISHED
1006   875C B0 14              BCS B2          ;MOVE DEC'NG
1007   875E 20 B7 87    BLP    JSR BMOVE       ;MOVE INC'NG
1008   8761 E6 FC              INC $FC
1009   8763 D0 02              BNE *+4
1010   8765 E6 FD              INC $FD
1011   8767 20 B2 82           JSR INCCMP
1012   876A 70 43              BVS B1
1013   876C F0 F0              BEQ BLP
1014   876E 90 EE              BCC BLP
1015   8770 B0 3D              BCS B1
1016   8772 A5 FC       B2     LDA $FC         ;CALC VALS FOR MOVE DEC'NG
1017   8774 18                 CLC
1018   8775 6D 4A A6           ADC P3L
1019   8778 85 FC              STA $FC
1020   877A A5 FD              LDA $FD
1021   877C 6D 4B A6           ADC P3H
1022   877F 85 FD              STA $FD
1023   8781 38                 SEC
1024   8782 A5 FC              LDA $FC
1025   8784 E5 FE              SBC $FE
1026   8786 85 FC              STA $FC
1027   8788 A5 FD              LDA $FD
1028   878A E5 FF              SBC $FF
1029   878C 85 FD              STA $FD
1030   878E 20 A7 82           JSR P3SCR
1031   8791 AD 4C A6           LDA P2L
1032   8794 8D 4A A6           STA P3L
1033   8797 AD 4D A6           LDA P2H
1034   879A 8D 4B A6           STA P3H
1035   879D 20 B7 87    BLP1   JSR BMOVE       ;MOVE DEC'NG
1036   87A0 A5 FC              LDA $FC
1037   87A2 D0 02              BNE *+4
1038   87A4 C6 FD              DEC $FD
1039   87A6 C6 FC              DEC $FC
1040   87A8 20 BE 82           JSR DECCMP
1041   87AB 70 02              BVS B1
1042   87AD B0 EE              BCS BLP1
1043   87AF AD 52 A6    B1     LDA ERCNT       ;FINISHED, TEST ERCNT
1044   87B2 38                 SEC
1045   87B3 D0 01              BNE *+3
1046   87B5 18                 CLC
1047   87B6 60                 RTS
1048   87B7 A0 00       BMOVE  LDY #0          ;MOVE 1 BYT + VER
1049   87B9 B1 FE              LDA ($FE),Y
1050   87BB 91 FC              STA ($FC),Y
1051   87BD D1 FC              CMP ($FC),Y
1052   87BF F0 0B              BEQ BRT
1053   87C1 AC 52 A6    BRTT   LDY ERCNT       ;INC ERCNT, DONT PASS FF
1054   87C4 C0 FF              CPY #$FF
1055   87C6 F0 04              BEQ *+6
1056   87C8 C8                 INY
1057   87C9 8C 52 A6           STY ERCNT
1058   87CC 60          BRT    RTS
1059   87CD C9 1D       S13B   CMP #$1D        ;SAVE KIM FMT TAPE, 3 PARMS
1060   87CF D0 15              BNE S23B
1061   87D1 A0 00              LDY #$0         ;MODE = KIM
1062   87D3 AD 4E A6    S13C   LDA P1L
1063   87D6 D0 02              BNE *+4         ;ID MUST NOT = 0
1064   87D8 38                 SEC
1065   87D9 60                 RTS
1066   87DA C9 FF              CMP #$FF        ;ID MUST NOT = FF
1067   87DC D0 02              BNE *+4
1068   87DE 38          S1NG   SEC
1069   87DF 60                 RTS
1070   87E0 20 93 82           JSR INCP3       ;USE END ADDR + 1
1071   87E3 4C 87 8E           JMP SENTRY
1072   87E6 C9 1E       S23B   CMP #$1E        ;SAVE HS FMT TAPE, 3 PARMS
1073   87E8 D0 04              BNE L23P
1074   87EA A0 80              LDY #$80        ;MODE = HS
1075   87EC D0 E5              BNE S13C        ;(ALWAYS)
1076   87EE C9 13       L23P   CMP #$13        ;LOAD HS, 3 PARMS
1077   87F0 D0 0F              BNE MEM3
1078   87F2 AD 4E A6           LDA P1L
1079   87F5 C9 FF              CMP #$FF        ;ID MUST BE FF
1080   87F7 D0 E5              BNE S1NG        ;ERROR RETURN
1081   87F9 20 93 82           JSR INCP3       ;USE END ADDR + 1
1082   87FC A0 80              LDY #$80        ;MODE = HS
1083   87FE 4C 78 8C           JMP LENTRY
1084   8801 C9 4D       MEM3   CMP #'M'        ;MEM 3 SEARCH - BYTE
1085   8803 D0 22              BNE CALC3
1086   8805 20 9C 82           JSR P2SCR
1087   8808 AD 4E A6    MEM3C  LDA P1L
1088   880B A0 00              LDY #0
1089   880D D1 FE              CMP ($FE),Y
1090   880F F0 0B              BEQ MEM3E       ;FOUND SEARCH BYTE?
1091   8811 20 B2 82    MEM3D  JSR INCCMP      ;NO, INC BUFFER ADDR
1092   8814 70 04              BVS MEM3EX
1093   8816 F0 F0              BEQ MEM3C
1094   8818 90 EE              BCC MEM3C
1095   881A 18          MEM3EX CLC
1096   881B 60                 RTS             ;SEARCHED TO BOUND
1097   881C 20 17 85    MEM3E  JSR NEWLOC      ;FOUND SEARCH BYTE
1098   881F 90 05              BCC MEM3F
1099   8821 C9 47              CMP #'G'        ;ENTERED G?
1100   8823 F0 EC              BEQ MEM3D
1101   8825 38                 SEC
1102   8826 60          MEM3F  RTS
1103   8827 C9 43       CALC3  CMP #'C'        ;CALCULATE, 1, 2 OR 3 PARMS
1104   8829 D0 26              BNE EXE3        ;RESULT = P1+P2+P3
1105   882B 20 4D 83    C1     JSR CRLF
1106   882E 20 42 83           JSR SPACE
1107   8831 18                 CLC
1108   8832 AD 4E A6           LDA P1L
1109   8835 6D 4C A6           ADC P2L
1110   8838 A8                 TAY
1111   8839 AD 4F A6           LDA P1H
1112   883C 6D 4D A6           ADC P2H
1113   883F AA                 TAX
1114   8840 38                 SEC
1115   8841 98                 TYA
1116   8842 ED 4A A6           SBC P3L
1117   8845 A8                 TAY
1118   8846 8A                 TXA
1119   8847 ED 4B A6           SBC P3H
1120   884A AA                 TAX
1121   884B 98                 TYA
1122   884C 20 F4 82           JSR OUTXAH
1123   884F 18                 CLC
1124   8850 60                 RTS
1125   8851 C9 45       EXE3   CMP #'E'        ;EXECUTE FROM RAM, 1-3 PARMS
1126   8853 D0 57              BNE E3PARM
1127   8855             ; SEE IF VECTOR ALREADY MOVED
1128   8855 AD 62 A6           LDA INVEC+2     ;INVEC MOVED TO SCRA, SCRB
1129   8858             ; HI BYTE OF EXEVEC MUST BE DIFFERENT FROM INVEC
1130   8858 CD 73 A6           CMP EXEVEC+1    ;$FA, $FB USED AS RAM PTR
1131   885B F0 15              BEQ PTRIN
1132   885D 8D 3B A6           STA SCRA+1      ;SAVE INVEC IN SCRA,B
1133   8860 AD 61 A6           LDA INVEC+1
1134   8863 8D 3A A6           STA SCRA
1135   8866 AD 72 A6           LDA EXEVEC      ;PUT ADDR OF RIN IN INVEC
1136   8869 8D 61 A6           STA INVEC+1
1137   886C AD 73 A6           LDA EXEVEC+1
1138   886F 8D 62 A6           STA INVEC+2
1139   8872 AD 4B A6    PTRIN  LDA P3H         ;INIT RAM PTR IN $FA, $FB
1140   8875 85 FB              STA $FB
1141   8877 AD 4A A6           LDA P3L
1142   887A 85 FA              STA $FA
1143   887C 18                 CLC
1144   887D 60                 RTS
1145   887E 20 88 81    RIN    JSR SAVER       ;GET INPUT FROM RAM
1146   8881 A0 00              LDY #$0         ;RAM PTR IN $FA, $FB
1147   8883 B1 FA              LDA ($FA),Y
1148   8885 F0 12              BEQ RESTIV      ;IF 00 BYTE, RESTORE INVEC
1149   8887 E6 FA              INC $FA
1150   8889 D0 02              BNE *+4
1151   888B E6 FB              INC $FB
1152   888D 2C 53 A6           BIT TECHO       ;ECHO CHARS IN ?
1153   8890 10 03              BPL *+5
1154   8892 20 47 8A           JSR OUTCHR
1155   8895 18                 CLC
1156   8896 4C B8 81           JMP RESXAF
1157   8899 AD 3A A6    RESTIV LDA SCRA        ;RESTORE INVEC
1158   889C 8D 61 A6           STA INVEC+1
1159   889F AD 3B A6           LDA SCRA+1
1160   88A2 8D 62 A6           STA INVEC+2
1161   88A5 18                 CLC
1162   88A6 20 1B 8A           JSR INCHR
1163   88A9 4C B8 81           JMP RESXAF
1164   88AC 6C 6D A6    E3PARM JMP (URCVEC+1)  ;... ELSE UNREC CMD
1165   88AF             ; ***
1166   88AF             ; *** HEX KEYBOARD I/O
1167   88AF             ; ***
1168   88AF 20 88 81    GETKEY JSR SAVER       ;FIND KEY
1169   88B2 20 CF 88           JSR GK
1170   88B5 C9 FE              CMP #$FE
1171   88B7 D0 13              BNE EXITGK
1172   88B9 20 CF 88           JSR GK
1173   88BC 8A                 TXA
1174   88BD 0A                 ASL A
1175   88BE 0A                 ASL A
1176   88BF 0A                 ASL A
1177   88C0 0A                 ASL A
1178   88C1 8D 3E A6           STA SCRE
1179   88C4 20 CF 88           JSR GK
1180   88C7 8A                 TXA
1181   88C8 18                 CLC
1182   88C9 6D 3E A6           ADC SCRE
1183   88CC 4C B8 81    EXITGK JMP RESXAF
1184   88CF A9 00       GK     LDA #0
1185   88D1 8D 55 A6           STA KSHFL
1186   88D4 20 03 89    GK1    JSR IJSCNV      ;SCAN KB
1187   88D7 F0 FB              BEQ GK1
1188   88D9 20 2C 89           JSR LRNKEY      ;WHAT KEY IS IT?
1189   88DC F0 F6              BEQ GK1
1190   88DE 48                 PHA
1191   88DF 8A                 TXA
1192   88E0 48                 PHA
1193   88E1 20 72 89           JSR BEEP
1194   88E4 20 23 89    GK2    JSR KEYQ
1195   88E7 D0 FB              BNE GK2         ;Z=1 IF KEY DOWN
1196   88E9 20 9B 89           JSR NOBEEP      ;DELAY (DEBOUNCE) W/O BEEP
1197   88EC 20 23 89           JSR KEYQ
1198   88EF D0 F3              BNE GK2
1199   88F1 68                 PLA
1200   88F2 AA                 TAX
1201   88F3 68                 PLA
1202   88F4 C9 FF              CMP #$FF        ;IF SHIFT, SET FLAG + GET NEXT KEY
1203   88F6 D0 07              BNE EXITG
1204   88F8 A9 19              LDA #$19
1205   88FA 8D 55 A6           STA KSHFL
1206   88FD D0 D5              BNE GK1
1207   88FF 60          EXITG  RTS
1208   8900 20 C1 89    HDOUT  JSR OUTDSP      ;CHAR OUT, SCAN KB
1209   8903 6C 70 A6    IJSCNV JMP (SCNVEC+1)
1210   8906 A9 09       SCAND  LDA #$9         ;SCAN DISPLAY FROM DISBUF
1211   8908 20 A5 89           JSR CONFIG
1212   890B A2 05              LDX #5
1213   890D A0 00       SC1    LDY #0
1214   890F BD 40 A6           LDA DISBUF,X
1215   8912 8C 00 A4           STY PADA
1216   8915 8E 02 A4           STX PBDA
1217   8918 8D 00 A4           STA PADA
1218   891B A0 10              LDY #$10
1219   891D 88          SC2    DEY
1220   891E D0 FD              BNE SC2
1221   8920 CA                 DEX
1222   8921 10 EA              BPL SC1
1223   8923 20 A3 89    KEYQ   JSR KSCONF      ; KEY DOWN ? (YES THEN Z=1)
1224   8926 AD 00 A4    H8926  LDA PADA
1225   8929 49 7F              EOR #$7F
1226   892B 60                 RTS
1227   892C 29 3F       LRNKEY AND #$3F        ;DETERMINE WHAT KEY IS DOWN
1228   892E 8D 3F A6           STA SCRF
1229   8931 A9 05              LDA #$05
1230   8933 20 A5 89           JSR CONFIG
1231   8936 AD 02 A4           LDA PBDA
1232   8939 29 07              AND #$07
1233   893B 49 07              EOR #$07
1234   893D D0 05              BNE LK1
1235   893F 2C 00 A4           BIT PADA
1236   8942 30 1A              BMI NOKEY
1237   8944 C9 04       LK1    CMP #$04
1238   8946 90 02              BCC LK2
1239   8948 A9 03              LDA #$03
1240   894A 0A          LK2    ASL A
1241   894B 0A                 ASL A
1242   894C 0A                 ASL A
1243   894D 0A                 ASL A
1244   894E 0A                 ASL A
1245   894F 0A                 ASL A
1246   8950 18                 CLC
1247   8951 6D 3F A6           ADC SCRF
1248   8954 A2 19              LDX #$19
1249   8956 DD D6 8B    LK3    CMP SYM,X
1250   8959 F0 05              BEQ FOUND
1251   895B CA                 DEX
1252   895C 10 F8              BPL LK3
1253   895E E8          NOKEY  INX
1254   895F 60                 RTS
1255   8960 8A          FOUND  TXA
1256   8961 18                 CLC
1257   8962 6D 55 A6           ADC KSHFL
1258   8965 AA                 TAX
1259   8966 BD EF 8B           LDA ASCII,X
1260   8969 60                 RTS
1261   896A 20 23 89    KYSTAT JSR KEYQ        ;KEY DOWN? RETURN IN CARRY
1262   896D 18                 CLC
1263   896E F0 01              BEQ *+3
1264   8970 38                 SEC
1265   8971 60                 RTS
1266   8972 20 88 81    BEEP   JSR SAVER       ;DELAY (BOUNCE) W/BEEP
1267   8975 A9 0D       BEEPP3 LDA #$0D
1268   8977 20 A5 89    BEEPP5 JSR CONFIG
1269   897A A2 70              LDX #$70        ;DURATION CONSTANT
1270   897C A9 08       BE1    LDA #8
1271   897E 8D 02 A4           STA PBDA
1272   8981 20 95 89           JSR BE2
1273   8984 A9 06              LDA #6
1274   8986 8D 02 A4           STA PBDA
1275   8989 20 95 89           JSR BE2
1276   898C CA                 DEX
1277   898D D0 ED              BNE BE1
1278   898F 20 A3 89           JSR KSCONF
1279   8992 4C C4 81           JMP RESALL
1280   8995 A0 1A       BE2    LDY #$1A
1281   8997 88          BE3    DEY
1282   8998 D0 FD              BNE BE3
1283   899A 60                 RTS
1284   899B 20 88 81    NOBEEP JSR SAVER       ;DELAY W/O BEEP
1285   899E A9 01              LDA #$01
1286   89A0 4C 77 89           JMP BEEPP5      ;(BNE BEEPP5, $FF)
1287   89A3 A9 01       KSCONF LDA #$1         ;CONFIGURE FOR KEYBOARD
1288   89A5 20 88 81    CONFIG JSR SAVER       ;CONFIGURE I/O FROM TABLE VAL
1289   89A8 A0 01              LDY #$01
1290   89AA AA                 TAX
1291   89AB BD C8 8B    CON1   LDA VALSP2,X
1292   89AE 99 02 A4           STA PBDA,Y
1293   89B1 BD C6 8B           LDA VALS,X
1294   89B4 99 00 A4           STA PADA,Y
1295   89B7 CA                 DEX
1296   89B8 88                 DEY
1297   89B9 10 F0              BPL CON1
1298   89BB 4C C4 81           JMP RESALL
1299   89BE 20 AF 88    HKEY   JSR GETKEY      ;GET KEY FROM KB AND ECHO ON KB
1300   89C1 20 88 81    OUTDSP JSR SAVER       ;DISPLAY OUT
1301   89C4 29 7F              AND #$7F
1302   89C6 C9 07              CMP #$07        ;BELL?
1303   89C8 D0 03              BNE NBELL
1304   89CA 4C 75 89           JMP BEEPP3      ;YES - BEEP
1305   89CD 20 06 8A    NBELL  JSR TEXT        ;PUSH INTO SCOPE BUFFER
1306   89D0 C9 2C              CMP #$2C        ;COMMA?
1307   89D2 D0 0A              BNE OUD1
1308   89D4 AD 45 A6           LDA RDIG
1309   89D7 09 80              ORA #$80        ;TURN ON DECIMAL PT
1310   89D9 8D 45 A6           STA RDIG
1311   89DC D0 25              BNE EXITOD
1312   89DE A2 3A       OUD1   LDX #$3A
1313   89E0 DD EE 8B    OUD2   CMP ASCIM1,X
1314   89E3 F0 05              BEQ GETSGS
1315   89E5 CA                 DEX
1316   89E6 D0 F8              BNE OUD2
1317   89E8 F0 19              BEQ EXITOD
1318   89EA BD 28 8C    GETSGS LDA SEGSM1,X    ;GET CORR SEG CODE FROM TABLE
1319   89ED C9 F0              CMP #$F0
1320   89EF F0 12              BEQ EXITOD
1321   89F1 A2 00              LDX #0
1322   89F3 48                 PHA
1323   89F4 BD 41 A6    OUD3   LDA DISBUF+1,X  ;SHOVE DOWN DISPLAY BUFFER
1324   89F7 9D 40 A6           STA DISBUF,X
1325   89FA E8                 INX
1326   89FB E0 05              CPX #5
1327   89FD D0 F5              BNE OUD3
1328   89FF 68                 PLA
1329   8A00 8D 45 A6           STA RDIG
1330   8A03 4C C4 81    EXITOD JMP RESALL
1331   8A06 48          TEXT   PHA             ;UPDATE SCOPE BUFFER
1332   8A07 8A                 TXA             ;SAVE X
1333   8A08 48                 PHA
1334   8A09 A2 1E              LDX #$1E        ;PUSH DOWN 32 CHARS
1335   8A0B BD 00 A6    TXTMOV LDA SCPBUF,X
1336   8A0E 9D 01 A6           STA SCPBUF+1,X
1337   8A11 CA                 DEX
1338   8A12 10 F7              BPL TXTMOV
1339   8A14 68                 PLA             ;RESTORE X
1340   8A15 AA                 TAX
1341   8A16 68                 PLA             ;RESTORE CHR
1342   8A17 8D 00 A6           STA SCPBUF      ;STORE CHR IN EMPTY SLOT
1343   8A1A 60                 RTS
1344   8A1B             ;
1345   8A1B             ;***
1346   8A1B             ;*** TERMINAL I/O
1347   8A1B             ;***
1348   8A1B 20 88 81    INCHR  JSR SAVER       ;INPUT CHAR
1349   8A1E 20 41 8A           JSR INJINV
1350   8A21 29 7F              AND #$7F        ;DROP PARITY
1351   8A23 C9 61              CMP #$61        ;ALPHA?
1352   8A25 90 06              BCC INRT1
1353   8A27 C9 7B              CMP #$7B
1354   8A29 B0 02              BCS INRT1
1355   8A2B 29 DF              AND #$DF        ;CVRT TO UPPER CASE
1356   8A2D C9 0F       INRT1  CMP #$0F        ;CTL O ?
1357   8A2F D0 0B              BNE INRT2
1358   8A31 AD 53 A6           LDA TECHO
1359   8A34 49 40              EOR #$40        ;TOGGLE CTL O BIT
1360   8A36 8D 53 A6           STA TECHO
1361   8A39 18                 CLC
1362   8A3A 90 E2              BCC INCHR+3     ;GET GET ANOTHER CHAR
1363   8A3C C9 0D       INRT2  CMP #$0D        ;CARRIAGE RETURN?
1364   8A3E 4C B8 81           JMP RESXAF
1365   8A41 6C 61 A6    INJINV JMP (INVEC+1)
1366   8A44 20 09 83    NBASOC JSR NIBASC      ;NIBBLE TO ASCII, OUTCHR
1367   8A47 20 88 81    OUTCHR JSR SAVER
1368   8A4A 2C 53 A6           BIT TECHO       ;LOOK AT CTRL O FLAG
1369   8A4D 70 03              BVS *+5
1370   8A4F 20 55 8A           JSR INJOUV
1371   8A52 4C C4 81           JMP RESALL
1372   8A55 6C 64 A6    INJOUV JMP (OUTVEC+1)
1373   8A58 20 88 81    INTCHR JSR SAVER       ;IN TERMINAL CHAR
1374   8A5B A9 00              LDA #0
1375   8A5D 85 F9              STA $F9
1376   8A5F AD 02 A4    LOOK   LDA PBDA        ;FIND LEADING EDGE
1377   8A62 2D 54 A6           AND TOUTFL
1378   8A65 38                 SEC
1379   8A66 E9 40              SBC #$40
1380   8A68 90 F5              BCC LOOK
1381   8A6A 20 E9 8A    TIN    JSR DLYH        ;TERMINAL BIT
1382   8A6D AD 02 A4           LDA PBDA
1383   8A70 2D 54 A6           AND TOUTFL
1384   8A73 38                 SEC
1385   8A74 E9 40              SBC #$40        ;OR BITS 7,7 (TTY,CRT)
1386   8A76 2C 53 A6           BIT TECHO       ;ECHO BIT?
1387   8A79 10 06              BPL DMY1
1388   8A7B 20 D4 8A           JSR OUT
1389   8A7E 4C 87 8A           JMP SAVE
1390   8A81 A0 07       DMY1   LDY #7
1391   8A83 88          TLP1   DEY
1392   8A84 D0 FD              BNE TLP1
1393   8A86 EA                 NOP
1394   8A87 66 F9       SAVE   ROR $F9
1395   8A89 20 E9 8A           JSR DLYH
1396   8A8C 48                 PHA             ;TIMING
1397   8A8D B5 00              LDA 0,X
1398   8A8F 68                 PLA
1399   8A90 90 D8              BCC TIN
1400   8A92 20 E9 8A           JSR DLYH
1401   8A95 18                 CLC
1402   8A96 20 D4 8A           JSR OUT
1403   8A99 A5 F9              LDA $F9
1404   8A9B 49 FF              EOR #$FF
1405   8A9D 4C B8 81           JMP RESXAF
1406   8AA0 85 F9       TOUT   STA $F9         ;TERMINAL CHR OUT
1407   8AA2 20 88 81           JSR SAVER
1408   8AA5 20 E9 8A           JSR DLYH        ;DELAY 1/2 BIT TIME
1409   8AA8 A9 30              LDA #$30        ;SET FOR OUTPUT
1410   8AAA 8D 03 A4           STA PBDA+1      ;DATA DIRECTION
1411   8AAD A5 F9              LDA $F9         ;RECOVER CHR DATA
1412   8AAF A2 0B              LDX #$0B        ;START BIT,8DATA, 3STOPS
1413   8AB1 49 FF              EOR #$FF        ;INVERT DATA
1414   8AB3 38                 SEC             ;START BIT
1415   8AB4 20 D4 8A    OUTC   JSR OUT         ;OUTPUT BIT FROM CARRY
1416   8AB7 20 E6 8A           JSR DLYF        ;WAIT FULL BIT TIME
1417   8ABA A0 06              LDY #$06
1418   8ABC 88          PHAKE  DEY
1419   8ABD D0 FD              BNE PHAKE
1420   8ABF EA                 NOP
1421   8AC0 4A                 LSR A
1422   8AC1 CA                 DEX
1423   8AC2 D0 F0              BNE OUTC
1424   8AC4 A5 F9              LDA $F9
1425   8AC6 C9 0D              CMP #$0D        ;CARRIAGE RETURN?
1426   8AC8 F0 04              BEQ GOPAD       ;YES-PAD IT
1427   8ACA C9 0A              CMP #$0A        ;PAD LINE FEED TOO
1428   8ACC D0 03              BNE LEAVE
1429   8ACE 20 32 8B    GOPAD  JSR PAD
1430   8AD1 4C C4 81    LEAVE  JMP RESALL
1431   8AD4 48          OUT    PHA             ;TERMINAL BIT OUT
1432   8AD5 AD 02 A4           LDA PBDA
1433   8AD8 29 0F              AND #$0F
1434   8ADA 90 02              BCC OUTONE
1435   8ADC 09 30              ORA #$30
1436   8ADE 2D 54 A6    OUTONE AND TOUTFL      ;MASK OUTPUT
1437   8AE1 8D 02 A4           STA PBDA
1438   8AE4 68                 PLA
1439   8AE5 60                 RTS
1440   8AE6             ;
1441   8AE6 20 E9 8A    DLYF   JSR DLYH        ;DELAY FULL
1442   8AE9 08          DLYH   PHP             ;DELAY HALF
1443   8AEA 48                 PHA
1444   8AEB 8A                 TXA
1445   8AEC 48                 PHA
1446   8AED 98                 TYA
1447   8AEE AE 51 A6           LDX SDBYT
1448   8AF1 A0 03       DLYX   LDY #3
1449   8AF3 88          DLYY   DEY
1450   8AF4 D0 FD              BNE DLYY
1451   8AF6 CA                 DEX
1452   8AF7 D0 F8              BNE DLYX
1453   8AF9 A8                 TAY
1454   8AFA 68                 PLA
1455   8AFB AA                 TAX
1456   8AFC 68                 PLA
1457   8AFD 28                 PLP
1458   8AFE 60                 RTS
1459   8AFF A9 00       BAUD   LDA #0          ;DETERMINE BAUD RATE ON PB7
1460   8B01 A8                 TAY
1461   8B02 AD 02 A4    SEEK   LDA PBDA
1462   8B05 0A                 ASL A
1463   8B06 B0 FA              BCS SEEK
1464   8B08 20 27 8B    CLEAR  JSR INK
1465   8B0B 90 FB              BCC CLEAR
1466   8B0D 20 27 8B    SET    JSR INK
1467   8B10 B0 FB              BCS SET
1468   8B12 8C 51 A6           STY SDBYT
1469   8B15 BD 63 8C    DEAF   LDA DECPTS,X
1470   8B18 CD 51 A6           CMP SDBYT
1471   8B1B B0 07              BCS AGAIN
1472   8B1D BD 69 8C           LDA STDVAL,X    ;LOAD CLOSEST STD VALUE
1473   8B20 8D 51 A6           STA SDBYT
1474   8B23 60                 RTS
1475   8B24 E8          AGAIN  INX
1476   8B25 10 EE              BPL DEAF
1477   8B27 C8          INK    INY
1478   8B28 A2 1C              LDX #$1C
1479   8B2A CA          INK1   DEX
1480   8B2B D0 FD              BNE INK1
1481   8B2D AD 02 A4           LDA PBDA
1482   8B30 0A                 ASL A
1483   8B31 60                 RTS
1484   8B32 AE 50 A6    PAD    LDX PADBIT      ;PAD CARRIAGE RETURN OR LF
1485   8B35 20 E6 8A    PAD1   JSR DLYF        ;WITH EXTRA STOP BITS
1486   8B38 CA                 DEX
1487   8B39 D0 FA              BNE PAD1
1488   8B3B 60                 RTS
1489   8B3C 20 A3 89    TSTAT  JSR KSCONF      ;SEE IF BREAK KEY DOWN
1490   8B3F AD 02 A4           LDA PBDA
1491   8B42 2D 54 A6           AND TOUTFL
1492   8B45 38                 SEC
1493   8B46 E9 40              SBC #$40
1494   8B48 60                 RTS
1495   8B49 FF                 .DB $FF         ;NOT USED
1496   8B4A             ; ***
1497   8B4A             ; *** RESET - TURN OFF POR, INIT SYS RAM, ENTER MONITOR
1498   8B4A             ; ***
1499   8B4A             ;
1500   8B4A A2 FF       RESET  LDX #$FF
1501   8B4C 9A                 TXS             ;INIT STACK PTR
1502   8B4D A9 CC              LDA #$CC
1503   8B4F 8D 0C A0           STA PCR1        ;DISABLE POR, TAPE OFF
1504   8B52 A9 04              LDA #4
1505   8B54 48                 PHA
1506   8B55 28                 PLP             ;INIT F, DISABLE IRQ DURING DFTXFR
1507   8B56 20 86 8B           JSR ACCESS      ;UN WRITE PROT SYS RAM
1508   8B59 A2 5F       DFTXFR LDX #$5F        ;INIT SYS RAM (EXCPT SCPBUF)
1509   8B5B BD A0 8F           LDA DFTBLK,X
1510   8B5E 9D 20 A6           STA RAM,X
1511   8B61 CA                 DEX
1512   8B62 10 F7              BPL DFTXFR+2
1513   8B64 A9 07       NEWDEV LDA #7          ;CHANGE DEVC/BAUD RATE
1514   8B66 20 47 8A           JSR OUTCHR      ;BEEP
1515   8B69 20 A3 89    SWITCH JSR KSCONF      ;KEYBOARD OR TERMINAL?
1516   8B6C 20 26 89    SWLP   JSR KEYQ+3
1517   8B6F D0 0B              BNE MONENT
1518   8B71 2C 02 A4           BIT PBDA
1519   8B74 10 F6              BPL SWLP
1520   8B76 20 B7 8B           JSR VECSW       ;SWITCH VECTORS
1521   8B79 20 FF 8A           JSR BAUD
1522   8B7C A2 FF       MONENT LDX #$FF        ;MONITOR ENTRY
1523   8B7E 9A                 TXS
1524   8B7F D8                 CLD
1525   8B80 20 86 8B           JSR ACCESS      ;UNWRITE PROT MONITOR RAM
1526   8B83 4C 03 80           JMP WARM
1527   8B86 20 88 81    ACCESS JSR SAVER       ;UN WRITE PROT SYS RAM
1528   8B89 AD 01 AC           LDA OR3A
1529   8B8C 09 01              ORA #1
1530   8B8E 8D 01 AC    ACC1   STA OR3A
1531   8B91 AD 03 AC           LDA DDR3A
1532   8B94 09 01              ORA #1
1533   8B96 8D 03 AC           STA DDR3A
1534   8B99 4C C4 81           JMP RESALL
1535   8B9C 20 88 81    NACCES JSR SAVER       ;WRITE PROT SYS RAM
1536   8B9F AD 01 AC           LDA OR3A
1537   8BA2 29 FE              AND #$FE
1538   8BA4 18                 CLC
1539   8BA5 90 E7              BCC ACC1
1540   8BA7 20 86 8B    TTY    JSR ACCESS      ;UN WRITE PROT RAM
1541   8BAA A9 D5              LDA #$D5        ;110 BAUD
1542   8BAC 8D 51 A6           STA SDBYT
1543   8BAF AD 54 A6           LDA TOUTFL
1544   8BB2 09 40              ORA #$40
1545   8BB4 8D 54 A6           STA TOUTFL
1546   8BB7 20 86 8B    VECSW  JSR ACCESS      ;UN WRITE PROT RAM
1547   8BBA A2 08              LDX #$8
1548   8BBC BD 6F 8C    SWLP2  LDA TRMTBL,X
1549   8BBF 9D 60 A6           STA INVEC,X
1550   8BC2 CA                 DEX
1551   8BC3 10 F7              BPL SWLP2
1552   8BC5 60                 RTS
1553   8BC6             ;
1554   8BC6             ;***
1555   8BC6             ;*** TABLES (I/O CONFIGURATIONS, KEY CODES, ASCII CODES)
1556   8BC6             ;***
1557   8BC6 00 80 08 37 VALS   .DB $00,$80,$08,$37  ;KB SENSE, A=1
1558   8BCA 00 7F 00 30        .DB $00,$7F,$00,$30  ;KB LRN, A=5
1559   8BCE 00 FF 00 3F        .DB $00,$FF,$00,$3F  ;SCAN DSP, A=9
1560   8BD2 00 00 07 3F        .DB $00,$00,$07,$3F  ;BEEP, A=D
1561   8BD6             VALSP2 =VALS+2
1562   8BD6             SYM    =*              ;KEY CODES RETURNED BY LRNKEY
1563   8BD6             TABLE  =*
1564   8BD6 01                 .DB $01         ;0/U0
1565   8BD7 41                 .DB $41         ;1/U1
1566   8BD8 81                 .DB $81         ;2/U2
1567   8BD9 C1                 .DB $C1         ;3/U3
1568   8BDA 02                 .DB $02         ;4/U4
1569   8BDB 42                 .DB $42         ;5/U5
1570   8BDC 82                 .DB $82         ;6/U6
1571   8BDD C2                 .DB $C2         ;7/U7
1572   8BDE 04                 .DB $04         ;8/JMP
1573   8BDF 44                 .DB $44         ;9/VER
1574   8BE0 84                 .DB $84         ;A/ASCII
1575   8BE1 C4                 .DB $C4         ;B/BLK MOV
1576   8BE2 08                 .DB $08         ;C/CALC
1577   8BE3 48                 .DB $48         ;D/DEP
1578   8BE4 88                 .DB $88         ;E/EXEC
1579   8BE5 C8                 .DB $C8         ;F/FILL
1580   8BE6 10                 .DB $10         ;CR/SD
1581   8BE7 50                 .DB $50         ;-/+
1582   8BE8 90                 .DB $90         ;>/<
1583   8BE9 D0                 .DB $D0         ;SHIFT
1584   8BEA 20                 .DB $20         ;GO/LP
1585   8BEB 60                 .DB $60         ;REG/SP
1586   8BEC A0                 .DB $A0         ;MEM/WP
1587   8BED 00                 .DB $00         ;L2/L1
1588   8BEE 40                 .DB $40         ;S2/S1
1589   8BEF             ASCIM1 =*-1
1590   8BEF             ASCII  =*              ;ASCII CODES AND HASH CODES
1591   8BEF 30                 .DB $30         ;ZERO
1592   8BF0 31                 .DB $31         ;ONE
1593   8BF1 32                 .DB $32         ;TWO
1594   8BF2 33                 .DB $33         ;THREE
1595   8BF3 34                 .DB $34         ;FOUR
1596   8BF4 35                 .DB $35         ;FIVE
1597   8BF5 36                 .DB $36         ;SIX
1598   8BF6 37                 .DB $37         ;SEVEN
1599   8BF7 38                 .DB $38         ;EIGHT
1600   8BF8 39                 .DB $39         ;NINE
1601   8BF9 41                 .DB $41         ;A
1602   8BFA 42                 .DB $42         ;B
1603   8BFB 43                 .DB $43         ;C
1604   8BFC 44                 .DB $44         ;D
1605   8BFD 45                 .DB $45         ;E
1606   8BFE 46                 .DB $46         ;F
1607   8BFF 0D                 .DB $0D         ;CR
1608   8C00 2D                 .DB $2D         ;DASH
1609   8C01 3E                 .DB $3E         ;>
1610   8C02 FF                 .DB $FF         ;SHIFT
1611   8C03 47                 .DB $47         ;G
1612   8C04 52                 .DB $52         ;R
1613   8C05 4D                 .DB $4D         ;M
1614   8C06 13                 .DB $13         ;L2
1615   8C07 1E                 .DB $1E         ;S2
1616   8C08             ; KB UPPER CASE
1617   8C08 14                 .DB $14         ;U0
1618   8C09 15                 .DB $15         ;U1
1619   8C0A 16                 .DB $16         ;U2
1620   8C0B 17                 .DB $17         ;U3
1621   8C0C 18                 .DB $18         ;U4
1622   8C0D 19                 .DB $19         ;U5
1623   8C0E 1A                 .DB $1A         ;U6
1624   8C0F 1B                 .DB $1B         ;U7
1625   8C10 4A                 .DB $4A         ;J
1626   8C11 56                 .DB $56         ;V
1627   8C12 FE                 .DB $FE         ;ASCII
1628   8C13 42                 .DB $42         ;B
1629   8C14 43                 .DB $43         ;C
1630   8C15 44                 .DB $44         ;D
1631   8C16 45                 .DB $45         ;E
1632   8C17 46                 .DB $46         ;F
1633   8C18 10                 .DB $10         ;SD
1634   8C19 2B                 .DB $2B         ;+
1635   8C1A 3C                 .DB $3C         ;<
1636   8C1B 00                 .DB $00         ;SHIFT
1637   8C1C 11                 .DB $11         ;LP
1638   8C1D 1C                 .DB $1C         ;SP
1639   8C1E 57                 .DB $57         ;W
1640   8C1F 12                 .DB $12         ;L1
1641   8C20 1D                 .DB $1D         ;S1
1642   8C21 2E                 .DB $2E         ;.
1643   8C22 20                 .DB $20         ;BLANK
1644   8C23 3F                 .DB $3F         ;?
1645   8C24 50                 .DB $50         ;P
1646   8C25 07                 .DB $07         ;BELL
1647   8C26 53                 .DB $53         ;S
1648   8C27 58                 .DB $58         ;X
1649   8C28 59                 .DB $59         ;Y
1650   8C29             ; SEGMENT CODES FOR ON-BOARD DISPLAY
1651   8C29             SEGSM1 =*-1
1652   8C29 3F                 .DB $3F         ;ZERO
1653   8C2A 06                 .DB $06         ;ONE
1654   8C2B 5B                 .DB $5B         ;TWO
1655   8C2C 4F                 .DB $4F         ;THREE
1656   8C2D 66                 .DB $66         ;FOUR
1657   8C2E 6D                 .DB $6D         ;FIVE
1658   8C2F 7D                 .DB $7D         ;SIX
1659   8C30 07                 .DB $07         ;SEVEN
1660   8C31 7F                 .DB $7F         ;EIGHT
1661   8C32 67                 .DB $67         ;NINE
1662   8C33 77                 .DB $77         ;A
1663   8C34 7C                 .DB $7C         ;B
1664   8C35 39                 .DB $39         ;C
1665   8C36 5E                 .DB $5E         ;D
1666   8C37 79                 .DB $79         ;E
1667   8C38 71                 .DB $71         ;F
1668   8C39 F0                 .DB $F0         ;CR
1669   8C3A 40                 .DB $40         ;DASH
1670   8C3B 70                 .DB $70         ;>
1671   8C3C 00                 .DB $00         ;SHIFT
1672   8C3D 6F                 .DB $6F         ;G
1673   8C3E 50                 .DB $50         ;R
1674   8C3F 54                 .DB $54         ;M
1675   8C40 38                 .DB $38         ;L2
1676   8C41 6D                 .DB $6D         ;S2
1677   8C42 01                 .DB $01         ;U0
1678   8C43 08                 .DB $08         ;U1
1679   8C44 09                 .DB $09         ;U2
1680   8C45 30                 .DB $30         ;U3
1681   8C46 36                 .DB $36         ;U4
1682   8C47 5C                 .DB $5C         ;U5
1683   8C48 63                 .DB $63         ;U6
1684   8C49 03                 .DB $03         ;U7
1685   8C4A 1E                 .DB $1E         ;J
1686   8C4B 72                 .DB $72         ;V
1687   8C4C 77                 .DB $77         ;A
1688   8C4D 7C                 .DB $7C         ;B
1689   8C4E 39                 .DB $39         ;C
1690   8C4F 5E                 .DB $5E         ;D
1691   8C50 79                 .DB $79         ;E
1692   8C51 71                 .DB $71         ;F
1693   8C52 6D                 .DB $6D         ;SD
1694   8C53 76                 .DB $76         ;+
1695   8C54 46                 .DB $46         ;<
1696   8C55 00                 .DB $00         ;SHIFT
1697   8C56 38                 .DB $38         ;LP
1698   8C57 6D                 .DB $6D         ;SP
1699   8C58 1C                 .DB $1C         ;W
1700   8C59 38                 .DB $38         ;L1
1701   8C5A 6D                 .DB $6D         ;S1
1702   8C5B 80                 .DB $80         ;.
1703   8C5C 00                 .DB $00         ;SPACE
1704   8C5D 53                 .DB $53         ;?
1705   8C5E 73                 .DB $73         ;P
1706   8C5F 49                 .DB $49         ;BELL
1707   8C60 6D                 .DB $6D         ;S
1708   8C61 64                 .DB $64         ;X
1709   8C62 6E                 .DB $6E         ;Y
1710   8C63 973D1F100800DECPTS .DB $97,$3D,$1F,$10,$08,$00  ; TO DETERMINE BAUD RATE
1711   8C69                    .MSFIRST
1712   8C69 D54C24100601STDVAL .DW $D54C,$2410,$0601  ;STD VALS FOR BAUD RATES
1713   8C6F                    .LSFIRST
1714   8C6F             ; 110,300,600,1200,2400,4800 BAUD
1715   8C6F 4C 58 8A    TRMTBL JMP INTCHR
1716   8C72 4C A0 8A           JMP TOUT
1717   8C75 4C 3C 8B           JMP TSTAT
1718   8C78             ;
1719   8C78
1720   8C78             ;****** VERSION 2 4/13/79  "SY1.1"
1721   8C78             ;****** COPYRIGHT 1978 SYNERTEK SYSTEMS CORPORATION
1722   8C78             ;******
1723   8C78             BDRY   =$F8            ;0/1 BDRY FOR READ TIMING
1724   8C78             OLD    =$F9            ;HOLD PREV INPUT LEVEL IN GETTR
1725   8C78             CHAR   =$FC            ;CHAR ASSY AND DISASSY
1726   8C78             MODE   =$FD            ;BIT7=1 IS HS, 0 IS KIM
1727   8C78                                    ;... BIT6=1 - IGNORE DATA
1728   8C78             BUFADL =$FE            ;RUNNING BUFFER ADR
1729   8C78             BUFADH =$FF
1730   8C78             ;TAPDEL =$A630         ;HI SPEED TAPE DELAY
1731   8C78             ;KMBDRY =$A631         ;KIM READ BDRY
1732   8C78             ;HSBDRY =$A632         ;HS READ BDRY
1733   8C78             ;TAPET1 =$A635         ;HS FIRST 1/2 BIT
1734   8C78             ;TAPET2 =$A63C         ;HS SECOND 1/2 BIT
1735   8C78             ;SCR6   =$A636         ;SCR6
1736   8C78             ;SCR7   =$8637         ;SCR7
1737   8C78             ;SCR8   =$A638         ;SCR8
1738   8C78             ;SCR9   =$A639         ;SCR9
1739   8C78
1740   A64A                    *=$A64A
1741   A64A             EAL    .BLOCK 1        ;P3L - END ADDR +1 (LO)
1742   A64B             EAH    .BLOCK 1        ;P3H -  (HI)
1743   A64C             SAL    .BLOCK 1        ;P2L - START ADDR  (LO)
1744   A64D             SAH    .BLOCK 1        ;P2H -  (HI)
1745   A64E             ID     .BLOCK 1        ;P1L -  ID
1746   A64F
1747   A64F             EOT    = $04
1748   A64F             SYN    = $16
1749   A64F             TPBIT  =%1000          ;BIT 3 IS ENABLE/DISABLE TO DECODER
1750   A64F             FRAME  =$FF            ;ERROR MSG # FOR FRAME ERROR
1751   A64F             CHECK  =$CC            ;ERROR # FOR CHECKSUM ERROR
1752   A64F             LSTCHR =$2F            ;LAST CHAR NOT '/'
1753   A64F             NONHEX =$FF            ;NON HEX CHAR IN KIM REC
1754   A64F
1755   A64F             ;ACCESS =$8BB6         ;UNRITE PROTECT SYSTEM RAM
1756   A64F             ;P2SCR  =$829C         ;MOVE P2 TO $FF,$FE IN PAGE ZERO
1757   A64F             ;ZERCK  =$832E         ;MOVE ZERO TO CHECK SUM
1758   A64F             ;CONFIG =$89A5         ;CONFIGURE I/O
1759   A64F
1760   A64F             ; I/O - TAPE ON/OFF IS CB2 ON VIA 1 (A000)
1761   A64F             ;       TAPE IN IS PB6 ON VIA 1 (A000)
1762   A64F             ;       TAPE OUT IS CODE 7 TO DISPLAY DECODER, THRU 6532,
1763   A64F             ;             PB0-PB3 (A400)
1764   A64F
1765   A64F             VIAACR =$A00B
1766   A64F             VIAPCR =$A00C          ;CONTROL CB2 TAPE ON/OFF, POR
1767   A64F             TPOUT  =$A402
1768   A64F             TAPOUT =TPOUT
1769   A64F             DDROUT =$A403
1770   A64F             TAPIN  =$A000
1771   A64F             DDRIN  =$A002
1772   A64F             TIMER  =$A406          ;6532 TIMER READ
1773   A64F             TIM8   =$A415          ;6532 TIMER SET (8US)
1774   A64F             DDRDIG =$A401
1775   A64F             DIG    =$A400
1776   A64F
1777   A64F             ; LOADT ENTER W/ID IN PARM 2, MODE IN [Y]
1778   A64F
1779   8C78                    *=$8C78
1780   8C78 20 A9 8D    LOADT  JSR START       ;INITIALIZE
1781   8C7B 20 52 8D    LOADT2 JSR SYNC        ;GET IN SYNC
1782   8C7E 20 E1 8D    LOADT4 JSR RDCHTX
1783   8C81 C9 2A              CMP #'*'        ;START OF DATA?
1784   8C83 F0 06              BEQ LOAD11
1785   8C85 C9 16              CMP #SYN        ;NO - SYN?
1786   8C87 D0 F2              BNE LOADT2      ;IF NOT, RESTART SYNC SEARCH
1787   8C89 F0 F3              BEQ LOADT4      ;IF YES, KEEP LOOKING FOR *
1788   8C8B
1789   8C8B 06 FD       LOAD11 ASL MODE        ;GET MODE IN A, CLEAR BIT6
1790   8C8D 6A                 ROR A
1791   8C8E 85 FD              STA MODE
1792   8C90 20 26 8E           JSR RDBYTX      ;READ ID BYTE ON TAPE
1793   8C93 8D 00 A4           STA DIG         ;DISPLAY ON LED (NOT DECODED)
1794   8C96 CD 4E A6           CMP ID          ;COMPARE WITH REQUESTED ID
1795   8C99 F0 29              BEQ LOADT5      ;LOAD IF EQUAL
1796   8C9B AD 4E A6           LDA ID          ;COMPARE WITH 0
1797   8C9E C9 00              CMP #0
1798   8CA0 F0 22              BEQ LOADT5      ;IF 0, LOAD ANYWAY
1799   8CA2 C9 FF              CMP #$FF        ;COMPARE WITH FF
1800   8CA4 F0 07              BEQ LOADT6      ;IF FF, USE REQUEST SA TO LOAD
1801   8CA6
1802   8CA6 24 FD              BIT MODE        ;UNWANTED RECORD, KIM OR HS?
1803   8CA8 30 16              BMI HWRONG
1804   8CAA 4C 7B 8C           JMP LOADT2      ;IF KIM, RESTART SEARCH
1805   8CAD
1806   8CAD             ; SA (&EA IF USED) COME FROM REQUEST. DISCARD TAPE VALUES
1807   8CAD             ;   (BUFAD ALREADY SET TO SA BY 'START')
1808   8CAD             ;
1809   8CAD 20 74 8E    LOADT6 JSR RDCHK       ;GET SAL FROM TAPE
1810   8CB0 20 74 8E           JSR RDCHK       ;GET SAH FROM TAPE
1811   8CB3 24 FD              BIT MODE        ;HS OR KIM?
1812   8CB5 10 52              BPL LOADT7      ;IF KIM, START READING DATA
1813   8CB7 20 74 8E           JSR RDCHK       ;HS, GET EAH, EAL FROM TAPE
1814   8CBA 20 74 8E           JSR RDCHK       ; ... BUT IGNORE
1815   8CBD 4C DE 8C           JMP LT7H        ;START READING HS DATA
1816   8CC0
1817   8CC0             ; SA ( & EA IF USED) COME FROM TAPE. SA REPLACES BUFAD
1818   8CC0
1819   8CC0 A9 C0       HWRONG LDA #$C0        ;READ THRU TO GE TO NEXT REC
1820   8CC2 85 FD              STA MODE        ;BUT DON'T CHECK CKSUM, NO FRAME ERR
1821   8CC4
1822   8CC4 20 74 8E    LOADT5 JSR RDCHK       ;GET SAL FROM TAPE
1823   8CC7 85 FE              STA BUFADL      ;PUT IN BUF START L
1824   8CC9 20 74 8E           JSR RDCHK       ;SAME FOR SAH
1825   8CCC 85 FF              STA BUFADH
1826   8CCE             ;(SAL - H STILL HAVE REQUEST VALUE)
1827   8CCE 24 FD              BIT MODE        ;HS OR KIM?
1828   8CD0 10 37              BPL LOADT7      ;IF KIM, START READING RECORD
1829   8CD2 20 74 8E           JSR RDCHK       ;HS. GET & SAVE EAL,EAH
1830   8CD5 8D 4A A6           STA EAL
1831   8CD8 20 74 8E           JSR RDCHK
1832   8CDB 8D 4B A6           STA EAH
1833   8CDE
1834   8CDE             ; READ HS DATA
1835   8CDE
1836   8CDE 20 E5 8D    LT7H   JSR RDBYTH      ;GET NEXT BYTE
1837   8CE1 A6 FE              LDX BUFADL      ;CHECK FOR END OF DATA + 1
1838   8CE3 EC 4A A6           CPX EAL
1839   8CE6 D0 07              BNE LT7HA
1840   8CE8 A6 FF              LDX BUFADH
1841   8CEA EC 4B A6           CPX EAH
1842   8CED F0 14              BEQ LT7HB
1843   8CEF 20 77 8E    LT7HA  JSR CHKT        ;NOT END, UPDATE CHECKSUM
1844   8CF2 24 FD              BIT MODE        ;WRONG RECORD?
1845   8CF4 70 04              BVS LT7HC       ;IF SO, DONT STORE BYTE
1846   8CF6 A0 00              LDY #0          ;STORE BYTE
1847   8CF8 91 FE              STA (BUFADL),Y
1848   8CFA E6 FE       LT7HC  INC BUFADL      ;BUMP BUFFER ADDR
1849   8CFC D0 E0              BNE LT7H
1850   8CFE E6 FF              INC BUFADH      ;CARRY
1851   8D00 4C DE 8C           JMP LT7H
1852   8D03
1853   8D03 C9 2F       LT7HB  CMP #'/'        ;EA, MUST BE "/"
1854   8D05 D0 29              BNE LCERR       ;LAST CHAR NOT '/'
1855   8D07 F0 15              BEQ LT8A        ;(ALWAYS)
1856   8D09
1857   8D09             ; READ KIM DATA
1858   8D09
1859   8D09 20 2A 8E    LOADT7 JSR RDBYT
1860   8D0C B0 26              BCS LDT7A       ;NONHEX OR LAST CHAR
1861   8D0E 20 77 8E           JSR CHKT        ;UPDATE CHECKSUM (PACKED BYTE)
1862   8D11 A0 00              LDY #0          ;STORE BYTE
1863   8D13 91 FE              STA (BUFADL),Y
1864   8D15 E6 FE              INC BUFADL      ;BUMP BUFFER ADR
1865   8D17 D0 F0              BNE LOADT7      ;CARRY?
1866   8D19 E6 FF              INC BUFADH
1867   8D1B 4C 09 8D           JMP LOADT7
1868   8D1E
1869   8D1E             ; TEST CHECKSUM & FINISH
1870   8D1E
1871   8D1E             LOADT8 =*
1872   8D1E 20 26 8E    LT8A   JSR RDBYTX      ;CHECK SUM
1873   8D21 CD 36 A6           CMP SCR6
1874   8D24 D0 16              BNE CKERR
1875   8D26 20 26 8E           JSR RDBYTX
1876   8D29 CD 37 A6           CMP SCR7
1877   8D2C D0 0E              BNE CKERR       ;CHECK SUM ERROR
1878   8D2E F0 11              BEQ OKEXIT      ;(ALWAYS)
1879   8D30
1880   8D30 A9 2F       LCERR  LDA #LSTCHR     ;LAST CHAR IS NOT '/'
1881   8D32 D0 0A              BNE NGEXIT      ;(ALWAYS)
1882   8D34
1883   8D34 C9 2F       LDT7A  CMP #'/'        ;LAST OR NONHEX?
1884   8D36 F0 E6              BEQ LOADT8      ;LAST
1885   8D38             FRERR                  ;FRAMING ERROR
1886   8D38 A9 FF       NHERR  LDA #NONHEX     ;KIM ONLY, NON HEX CHAR READ
1887   8D3A D0 02              BNE NGEXIT      ;(ALWAYS)
1888   8D3C
1889   8D3C A9 CC       CKERR  LDA #CHECK      ;CHECKSUM ERROR
1890   8D3E
1891   8D3E 38          NGEXIT SEC             ;ERROR INDICATOR TO MONITOR IS CARRY
1892   8D3F B0 01              BCS EXIT        ;(ALWAYS)
1893   8D41
1894   8D41 18          OKEXIT CLC             ;NO ERROR
1895   8D42
1896   8D42 24 FD       EXIT   BIT MODE
1897   8D44 50 08              BVC EX10        ;READING WRONG REC?
1898   8D46 A0 80              LDY #$80
1899   8D48 4C 78 8C           JMP LOADT       ;RESTART SEARCH
1900   8D4B
1901   8D4B 68          USRREQ PLA             ;USER REQUESTS EXIT
1902   8D4C 68                 PLA
1903   8D4D 38                 SEC
1904   8D4E A2 CC       EX10   LDX #$CC
1905   8D50 D0 69              BNE STCC        ;STOP TAPE, RETURN
1906   8D52 AD 02 A0    SYNC   LDA DDRIN       ;CHANGE DATA DIRECTION
1907   8D55 29 BF              AND #$BF
1908   8D57 8D 02 A0           STA DDRIN
1909   8D5A A9 00              LDA #0
1910   8D5C 8D 0B A0           STA VIAACR
1911   8D5F AD 31 A6           LDA KMBDRY      ;SET UP BOUNDARY
1912   8D62 24 FD              BIT MODE
1913   8D64 10 03              BPL SY100
1914   8D66 AD 32 A6           LDA HSBDRY
1915   8D69 85 F8       SY100  STA BDRY
1916   8D6B A9 6D              LDA #$6D
1917   8D6D 8D 00 A4           STA DIG         ;INDICATE NO SYNC ON LEDS
1918   8D70 A5 FD              LDA MODE        ;TURN ON OUT OF SYNC MODE
1919   8D72 09 40              ORA #$40        ;BIT6
1920   8D74 85 FD              STA MODE
1921   8D76 A9 7F       SYNC5  LDA #$7F        ;TEST FOR CR DOWN ON HKB
1922   8D78 8D 01 A4           STA DDRDIG
1923   8D7B 2C 00 A4           BIT DIG
1924   8D7E 10 CB              BPL USRREQ      ;CR KEY DOWN - EXIT (ERRORS)
1925   8D80 20 9F 8D           JSR SYNBIT
1926   8D83 66 FC              ROR CHAR
1927   8D85 A5 FC              LDA CHAR
1928   8D87 C9 16              CMP #SYN
1929   8D89 D0 EB              BNE SYNC5
1930   8D8B A2 0A       SYNC10 LDX #10         ;NOW MAKE SURE CAN GET 10 SYNS
1931   8D8D 20 E1 8D           JSR RDCHTX
1932   8D90 C9 16              CMP #SYN
1933   8D92 D0 E2              BNE SYNC5
1934   8D94 CA                 DEX
1935   8D95 D0 F6              BNE SYNC10+2
1936   8D97 8E 00 A4           STX DIG         ;TURN OFF DISPLAY
1937   8D9A CA                 DEX             ;X=$FF
1938   8D9B 8E 01 A4           STX DDRDIG
1939   8D9E 60                 RTS
1940   8D9F             ;SYNBIT - GET BIT IN SYN SEARCH. IF HS, ENTER WITH
1941   8D9F             ;  TIMER STARTED BY PREV BIT, BIT RETURNED IN CARRY.
1942   8D9F
1943   8D9F 24 FD       SYNBIT BIT MODE        ;KIM OR HS?
1944   8DA1 10 69              BPL RDBITK      ;KIM
1945   8DA3 20 CA 8D           JSR GETTR       ;HS
1946   8DA6 B0 22              BCS GETTR       ;IF SHORT, GET NEXT TRANS
1947   8DA8 60                 RTS             ;BIT IS ZERO
1948   8DA9
1949   8DA9 84 FD       START  STY MODE        ;MODE PARM PASSED IN [Y]
1950   8DAB 20 86 8B           JSR ACCESS      ;FIX BASIC WARM START BUG
1951   8DAE A9 09              LDA #9
1952   8DB0 20 A5 89           JSR CONFIG      ;PARTIAL I/O CONFIGURATION
1953   8DB3 20 2E 83           JSR ZERCK       ;ZERO THE CHECK SUM
1954   8DB6 20 9C 82           JSR P2SCR       ;MOVE SA TO FE,FF IN PAGE ZERO
1955   8DB9 A2 EC              LDX #$EC
1956   8DBB 8E 0C A0    STCC   STX VIAPCR      ;TAPE ON
1957   8DBE 60                 RTS
1958   8DBF
1959   8DBF             ; GETTR - GET TRANSITION TIME FROM 6532 CLOCK
1960   8DBF             ; DESTROYS A,Y
1961   8DBF
1962   8DBF A9 00       KGETTR LDA #0          ;KIM GETTR - GET FULL CYCLE
1963   8DC1 85 F9              STA OLD         ;FORCE GETTR POLARITY
1964   8DC3 AD 00 A0    KG100  LDA TAPIN       ;WAIT TIL INPUT LO
1965   8DC6 29 40              AND #$40
1966   8DC8 D0 F9              BNE KG100
1967   8DCA
1968   8DCA A0 FF       GETTR  LDY #$FF
1969   8DCC AD 00 A0    NOTR   LDA TAPIN
1970   8DCF 29 40              AND #$40
1971   8DD1 C5 F9              CMP OLD
1972   8DD3 F0 F7              BEQ NOTR        ;NO CHANGE
1973   8DD5 85 F9              STA OLD
1974   8DD7 AD 06 A4           LDA TIMER
1975   8DDA 8C 15 A4           STY TIM8        ;RESTART CLOCK
1976   8DDD 18                 CLC
1977   8DDE 65 F8              ADC BDRY
1978   8DE0 60                 RTS
1979   8DE1
1980   8DE1 24 FD       RDCHTX BIT MODE        ;READ HS OR KIM CHARACTER
1981   8DE3 10 7A              BPL RDCHT       ;KIM
1982   8DE5
1983   8DE5             ; RDBYTH - READ HS BYTE
1984   8DE5             ; Y DESTROYED, BYTE RETURNED IN CHAR AND A
1985   8DE5             ; TIME FROM ONE CALL TO NEXT MUST BE LESS THAN
1986   8DE5             ;    START BIT TIME (TIMER STILL RUNNING)
1987   8DE5
1988   8DE5 8E 38 A6    RDBYTH STX SCR8        ;SAVE X
1989   8DE8 A2 08              LDX #8
1990   8DEA 20 CA 8D           JSR GETTR       ;GET START BIT TIME
1991   8DED B0 14              BCS RDBH90      ;IF NOT 0, FRAMING ERR
1992   8DEF 20 CA 8D    RDBH10 JSR GETTR       ;GET BIT IN CARRY
1993   8DF2 90 04              BCC RDASSY
1994   8DF4 20 CA 8D           JSR GETTR       ;BIT IS ONE, WAIT HALF CYC
1995   8DF7 38                 SEC             ;MAKE SURE "1"
1996   8DF8 66 FC       RDASSY ROR CHAR
1997   8DFA CA                 DEX
1998   8DFB D0 F2              BNE RDBH10
1999   8DFD A5 FC              LDA CHAR        ;GET IN ACC
2000   8DFF AE 38 A6    H8DFF  LDX SCR8        ;RESTORE X
2001   8E02 60                 RTS
2002   8E03 24 FD       RDBH90 BIT MODE        ;NO ERR IF NOT IN SYNC
2003   8E05 70 F8              BVS RDBH90-4    ;OR READING WRONG REC
2004   8E07 68                 PLA             ;FIX STACK
2005   8E08 68                 PLA
2006   8E09 4C 38 8D           JMP FRERR
2007   8E0C
2008   8E0C             ; RDBITK - READ KIM BIT - X,Y,A DESTROYED, BIT RETURNED IN C
2009   8E0C
2010   8E0C 20 BF 8D    RDBITK JSR KGETTR      ;WAIT FOR LF
2011   8E0F B0 FB              BCS RDBITK
2012   8E11 20 BF 8D           JSR KGETTR      ;GET SECOND
2013   8E14 B0 F6              BCS RDBITK
2014   8E16 A2 00              LDX #0
2015   8E18 E8          RDB100 INX             ;COUNT LF FULL CYCLES
2016   8E19 20 BF 8D           JSR KGETTR
2017   8E1C 90 FA              BCC RDB100
2018   8E1E 20 BF 8D           JSR KGETTR      ;GET SECOND
2019   8E21 90 F5              BCC RDB100
2020   8E23 E0 08              CPX #$08        ;GET BIT TO CARRY
2021   8E25 60                 RTS
2022   8E26
2023   8E26 24 FD       RDBYTX BIT MODE        ;READ HS OR KIM BYTE
2024   8E28 30 BB              BMI RDBYTH      ;HS
2025   8E2A
2026   8E2A 20 5F 8E    RDBYT  JSR RDCHT       ;READ KIM BYTE INTO CHAR AND A
2027   8E2D C9 2F              CMP #'/'        ;READ ONE CHAR IF LAST
2028   8E2F F0 2C              BEQ PACKT3      ;SET CARRY AND RETURN
2029   8E31 20 3C 8E           JSR PACKT
2030   8E34 B0 26              BCS RDRTN       ;NON HEX CHAR?
2031   8E36 AA                 TAX             ;SAVE MSD
2032   8E37 20 5F 8E           JSR RDCHT
2033   8E3A 86 FC              STX CHAR        ;MOVE MSD TO CHAR
2034   8E3C             ; AND FALL INTO PACKT AGAIN
2035   8E3C
2036   8E3C             ;PACKT - ASCII HEX TO 4 BITS
2037   8E3C             ;INPUT IN A, OUTPUT IN CHAR AND A, CARRY SET = NON HEX
2038   8E3C
2039   8E3C C9 30       PACKT  CMP #$30        ;LT "0"?
2040   8E3E 90 1D              BCC PACKT3
2041   8E40 C9 47              CMP #$47        ;GT "F" ?
2042   8E42 B0 19              BCS PACKT3
2043   8E44 C9 40              CMP #$40        ;A-F?
2044   8E46 F0 15              BEQ PACKT3      ;40 NOT VALID
2045   8E48 90 03              BCC PACKT1
2046   8E4A 18                 CLC
2047   8E4B 69 09              ADC #9
2048   8E4D 2A          PACKT1 ROL A           ;GET LSD INTO LEFT NIBBLE
2049   8E4E 2A                 ROL A
2050   8E4F 2A                 ROL A
2051   8E50 2A                 ROL A
2052   8E51 A0 04              LDY #4
2053   8E53 2A          RACKT2 ROL A           ;ROTATE 1 BIT AT A TIME INTO CHAR
2054   8E54 26 FC              ROL CHAR
2055   8E56 88                 DEY
2056   8E57 D0 FA              BNE RACKT2
2057   8E59 A5 FC              LDA CHAR        ;GET INTO ACCUM ALSO
2058   8E5B 18                 CLC             ;OK
2059   8E5C 60          RDRTN  RTS
2060   8E5D 38          PACKT3 SEC             ;NOT HEX
2061   8E5E 60                 RTS
2062   8E5F
2063   8E5F             ; RDCHT - READ KIM CHAR
2064   8E5F             ; PRESERVES X, RETURNS CHAR IN CHAR (W/PARITY)
2065   8E5F             ; AND A (W/O PARITY)
2066   8E5F
2067   8E5F 8A          RDCHT  TXA             ;SAVE X
2068   8E60 48                 PHA
2069   8E61 A9 FF              LDA #$FF        ;USE A TO COUNT BITS (BY SHIFTING)
2070   8E63 48          KBITS  PHA             ;SAVE COUNTER
2071   8E64 20 0C 8E           JSR RDBITK
2072   8E67 66 FC              ROR CHAR
2073   8E69 68                 PLA
2074   8E6A 0A                 ASL A
2075   8E6B D0 F6              BNE KBITS       ;DO 8 BITS
2076   8E6D 68                 PLA             ;RESTORE X
2077   8E6E AA                 TAX
2078   8E6F A5 FC              LDA CHAR
2079   8E71 2A                 ROL A
2080   8E72 4A                 LSR A           ;DROP PARITY
2081   8E73 60                 RTS
2082   8E74
2083   8E74             ; RDCHK - READ ONE BYT, INCLUDE IN CKSUM
2084   8E74
2085   8E74 20 26 8E    RDCHK  JSR RDBYTX      ;FALL INTO CHKT
2086   8E77
2087   8E77             ; CHKT - UPDATE CHECK SUM FROM BYTE IN A
2088   8E77             ; DESTROYS Y
2089   8E77
2090   8E77 A8          CHKT   TAY             ;SAVE ACCUM
2091   8E78 18                 CLC
2092   8E79 6D 36 A6           ADC SCR6
2093   8E7C 8D 36 A6           STA SCR6
2094   8E7F 90 03              BCC CHKT10
2095   8E81 EE 37 A6           INC SCR7        ;BUMP HI BYTE
2096   8E84 98          CHKT10 TYA             ;RESTORE A
2097   8E85 60                 RTS
2098   8E86
2099   8E86 FF                 .DB $FF         ;NOT USED
2100   8E87                    *=$8E87         ;KEEP OLD ENTRY POINT
2101   8E87 20 A9 8D    DUMPT  JSR START       ;INIT VIA & CKSUM, SA TO BUFAD & START
2102   8E8A A9 07              LDA #7          ;CODE FOR TAPE OUT
2103   8E8C 8D 02 A4           STA TAPOUT      ;BIT 3 USED FOR HI/LO
2104   8E8F A2 01              LDX #1          ;KIM DELAY CONSTANT (OUTER)
2105   8E91 A4 FD              LDY MODE        ;128 KIM, 0 HS
2106   8E93 10 03              BPL DUMPT1      ;KIM - DO 128 SYNS
2107   8E95 AE 30 A6           LDX TAPDEL      ;HS INITIAL DELAY (OUTER)
2108   8E98 8A          DUMPT1 TXA
2109   8E99 48                 PHA
2110   8E9A A9 16       DMPT1A LDA #SYN
2111   8E9C 20 0A 8F           JSR OUTCTX
2112   8E9F 88                 DEY
2113   8EA0 D0 F8              BNE DMPT1A      ;INNER LOOP (HS OR KIM)
2114   8EA2 68                 PLA
2115   8EA3 AA                 TAX
2116   8EA4 CA                 DEX
2117   8EA5 D0 F1              BNE DUMPT1
2118   8EA7 A9 2A              LDA #'*'        ;WRITE START
2119   8EA9 20 0A 8F           JSR OUTCTX
2120   8EAC
2121   8EAC AD 4E A6           LDA ID          ;WRITE ID
2122   8EAF 20 3F 8F           JSR OUTBTX
2123   8EB2
2124   8EB2 AD 4C A6           LDA SAL         ;WRITE SA
2125   8EB5 20 3C 8F           JSR OUTBCX
2126   8EB8 AD 4D A6           LDA SAH
2127   8EBB 20 3C 8F           JSR OUTBCX
2128   8EBE
2129   8EBE             ;
2130   8EBE 24 FD              BIT MODE        ;KIM OR HS
2131   8EC0 10 0C              BPL DUMPT2
2132   8EC2
2133   8EC2 AD 4A A6           LDA EAL         ;HS, WRITE EA
2134   8EC5 20 3C 8F           JSR OUTBCX
2135   8EC8 AD 4B A6           LDA EAH
2136   8ECB 20 3C 8F           JSR OUTBCX
2137   8ECE
2138   8ECE A5 FE       DUMPT2 LDA BUFADL      ;CHECK FOR LAST BYTE
2139   8ED0 CD 4A A6           CMP EAL
2140   8ED3 D0 25              BNE DUMPT4
2141   8ED5 A5 FF              LDA BUFADH
2142   8ED7 CD 4B A6           CMP EAH
2143   8EDA D0 1E              BNE DUMPT4
2144   8EDC
2145   8EDC A9 2F              LDA #'/'        ;LAST, WRITE "/"
2146   8EDE 20 0A 8F           JSR OUTCTX
2147   8EE1 AD 36 A6           LDA SCR6        ;WRITE CHECK SUM
2148   8EE4 20 3F 8F           JSR OUTBTX
2149   8EE7 AD 37 A6           LDA SCR7
2150   8EEA 20 3F 8F           JSR OUTBTX
2151   8EED
2152   8EED A9 04              LDA #EOT        ;WRITE TWO EOT'S
2153   8EEF 20 3F 8F           JSR OUTBTX
2154   8EF2 A9 04              LDA #EOT
2155   8EF4 20 3F 8F           JSR OUTBTX
2156   8EF7
2157   8EF7             DT3E   =*              ;(SET "OK" MARK)
2158   8EF7 4C 41 8D           JMP OKEXIT
2159   8EFA
2160   8EFA A0 00       DUMPT4 LDY #0          ;GET BYTE
2161   8EFC B1 FE              LDA (BUFADL),Y
2162   8EFE 20 3C 8F           JSR OUTBCX      ;WRITE IT W/CHK SUM
2163   8F01 E6 FE              INC BUFADL      ;BUMP BUFFER ADDR
2164   8F03 D0 C9              BNE DUMPT2
2165   8F05 E6 FF              INC BUFADH      ;CARRY
2166   8F07 4C CE 8E           JMP DUMPT2
2167   8F0A 24 FD       OUTCTX BIT MODE        ;HS OR KIM?
2168   8F0C 10 48              BPL OUTCHT      ;KIM
2169   8F0E
2170   8F0E             ;  OUTBTH - NO CLOCK
2171   8F0E             ; A,X DESTROYED
2172   8F0E             ; MUST RESIDE ON ONE PAGE - TIMING CRITICAL
2173   8F0E A2 09       OUTBTH LDX #9          ;8 BITS + START BIT
2174   8F10 8C 39 A6           STY SCR9
2175   8F13 85 FC              STA CHAR
2176   8F15 AD 02 A4           LDA TAPOUT      ;GET PREV LEVEL
2177   8F18 46 FC       GETBIT LSR CHAR
2178   8F1A 49 08              EOR #TPBIT
2179   8F1C 8D 02 A4           STA TAPOUT      ;INVERT LEVEL
2180   8F1F             ; *** HERE STARTS FIRST HALF CYCLE
2181   8F1F AC 35 A6           LDY TAPET1
2182   8F22 88          A416   DEY             ;TIME FOR THIS LOOP IS 5Y-1
2183   8F23 D0 FD              BNE A416
2184   8F25 90 12              BCC NOFLIP      ;NOFLIP IF BIT ZERO
2185   8F27 49 08              EOR #TPBIT      ;BIT IS ONE - INVERT OUTPUT
2186   8F29 8D 02 A4           STA TAPOUT
2187   8F2C             ; *** END OF FIRST HALF CYCLE
2188   8F2C AC 3C A6    B416   LDY TAPET2
2189   8F2F 88          B416B  DEY             ;LENGTH OF LOOP IS 5Y-1
2190   8F30 D0 FD              BNE B416B
2191   8F32 CA                 DEX
2192   8F33 D0 E3              BNE GETBIT      ;GET NEXT BIT (LAST IS 0 START BIT)
2193   8F35 AC 39 A6           LDY SCR9        ; (BY 9 BIT LSR)
2194   8F38 60                 RTS
2195   8F39 EA          NOFLIP NOP             ;TIMING
2196   8F3A 90 F0              BCC B416        ;(ALWAYS)
2197   8F3C             ;
2198   8F3C 20 77 8E    OUTBCX JSR CHKT        ;WRITE HS OR KIM BYTE & CKSUM
2199   8F3F 24 FD       OUTBTX BIT MODE        ;WRITE HS OR KIM BYTE
2200   8F41 30 CB              BMI OUTBTH      ;HS
2201   8F43
2202   8F43             ;OUTBTC - OUTPUT ONE KIM BYTE
2203   8F43
2204   8F43             OUTBTC =*
2205   8F43 A8          OUTBT  TAY             ;SAVE DATA BYTE
2206   8F44 4A                 LSR A
2207   8F45 4A                 LSR A
2208   8F46 4A                 LSR A
2209   8F47 4A                 LSR A
2210   8F48 20 4B 8F           JSR HEXOUT      ;MORE SIG DIGIT
2211   8F4B             ; FALL INTO HEXOUT
2212   8F4B
2213   8F4B 29 0F       HEXOUT AND #$0F        ;CVT LSD OF [A] TO ASCII, OUTPUT
2214   8F4D C9 0A              CMP #$0A
2215   8F4F 18                 CLC
2216   8F50 30 02              BMI HEX1
2217   8F52 69 07              ADC #$07
2218   8F54 69 30       HEX1   ADC #$30
2219   8F56
2220   8F56             ; OUTCHT - OUTPUT ASCII CHAR (KIM)
2221   8F56             ; CLOCK NOT USED
2222   8F56             ; X,Y PRESERVED
2223   8F56             ; MUST RESIDE ON ONE PAGE - TIMING CRITICAL
2224   8F56
2225   8F56 8E 38 A6    OUTCHT STX SCR8        ;PRESERVE X
2226   8F59 8C 39 A6           STY SCR9        ;DITTO Y
2227   8F5C 85 FC              STA CHAR
2228   8F5E A9 FF              LDA #$FF        ;USE FF W/SHIFTS TO COUNT BITS
2229   8F60 48          KIMBIT PHA             ;SAVE BIT CTR
2230   8F61 AD 02 A4           LDA TPOUT       ;GET CURRENT OUTPUT LEVEL
2231   8F64 46 FC              LSR CHAR        ;GET DATA BIT IN CARRY
2232   8F66 A2 12              LDX #18         ;ASSUME 'ONE'
2233   8F68 B0 02              BCS HF
2234   8F6A A2 24              LDX #36         ;BIT IS ZERO
2235   8F6C A0 19       HF     LDY #25
2236   8F6E 49 08              EOR #TPBIT      ;INVERT OUTPUT
2237   8F70 8D 02 A4           STA TPOUT
2238   8F73 88          HFP1   DEY             ;PAUSE FOR 138 USEC
2239   8F74 D0 FD              BNE HFP1
2240   8F76 CA                 DEX             ;COUNT HALF CYCS OF HF
2241   8F77 D0 F3              BNE HF
2242   8F79 A2 18              LDX #24         ;ASSUME BIT IS ONE
2243   8F7B B0 02              BCS LF20
2244   8F7D A2 0C              LDX #12         ;BIT IS ZERO
2245   8F7F A0 27       LF20   LDY #39
2246   8F81 49 08              EOR #TPBIT      ;INVERT OUTPUT
2247   8F83 8D 02 A4           STA TPOUT
2248   8F86 88          LFP1   DEY             ;PAUSE FOR 208 USEC
2249   8F87 D0 FD              BNE LFP1
2250   8F89 CA                 DEX             ;COUNT HALF CYCS
2251   8F8A D0 F3              BNE LF20
2252   8F8C 68                 PLA             ;RESTORE BIT CTR
2253   8F8D 0A                 ASL A           ;DECREMENT IT
2254   8F8E D0 D0              BNE KIMBIT      ;FF SHIFTED 8X = 0
2255   8F90 AE 38 A6           LDX SCR8
2256   8F93 AC 39 A6           LDY SCR9
2257   8F96 98                 TYA             ;RESTORE DATA BYTE
2258   8F97 60                 RTS
2259   8F98
2260   8F98 FF FF              .DB $FF,$FF     ;NOT USED
2261   8F9A
2262   8F9A             ; REGISTER NAME PATCH
2263   8F9A                    *=$8F9A
2264   8F9A 53                 .DB "S"
2265   8F9B 46                 .DB "F"
2266   8F9C 41                 .DB "A"
2267   8F9D 58                 .DB 'X'
2268   8F9E 59                 .DB "Y"
2269   8F9F 01                 .DB $01
2270   8FA0             ;
2271   8FA0             ;
2272   8FA0             ;***
2273   8FA0             ;*** DEFAULT TABLE
2274   8FA0             ;***
2275   8FA0                    *=$8FA0
2276   8FA0             DFTBLK =*
2277   8FA0 00 C0              .DW $C000       ;BASIC  *** JUMP TABLE
2278   8FA2 A7 8B              .DW TTY
2279   8FA4 64 8B              .DW NEWDEV
2280   8FA6 00 00              .DW $0000       ;PAGE ZERO
2281   8FA8 00 02              .DW $0200
2282   8FAA 00 03              .DW $0300
2283   8FAC 00 C8              .DW $C800
2284   8FAE 00 D0              .DW $D000
2285   8FB0 04                 .DB $04         ;TAPE DELAY (9.0 SEC)
2286   8FB1 2C                 .DB $2C         ;KIM TAPE BOUNDARY
2287   8FB2 46                 .DB $46         ;HS TAPE BOUNDARY
2288   8FB3 00 00              .DB $00,$00     ;SCR3,SCR4
2289   8FB5 33                 .DB $33         ;HS TAPE FIRST 1/2 BIT
2290   8FB6 00 00              .DB $00,$00     ;SCR6,SCR7
2291   8FB8 00 00 00 00        .DB $00,$00,$00,$00 ;SCR8-SCRB
2292   8FBC 5A                 .DB $5A         ;HS TAPE SECOND 1/2 BIT
2293   8FBD 00 00 00           .DB $00,$00,$00 ;SCRD-SCRF
2294   8FC0 00006D6E8606       .DB $00,$00,$6D,$6E,$86,$06 ;DISP BUFFER (SY1.1)
2295   8FC6 00 00 00           .DB $00,$00,$00 ;NOT USED
2296   8FC9 00                 .DB $00         ;PARNR
2297   8FCA 000000000000       .DW $0000,$0000,$0000 ;PARMS
2298   8FD0 01                 .DB $01         ;PADBIT
2299   8FD1 4C                 .DB $4C         ;SDBYT
2300   8FD2 00                 .DB $00         ;ERCNT
2301   8FD3 80                 .DB $80         ;TECHO
2302   8FD4 B0                 .DB $B0         ;TOUTFL
2303   8FD5 00                 .DB $00         ;KSHFL
2304   8FD6 00                 .DB $00         ;TV
2305   8FD7 00                 .DB $00         ;LSTCOM
2306   8FD8 10                 .DB $10         ;MAXRC
2307   8FD9 4A 8B              .DW RESET       ;USER REG'S
2308   8FDB FF                 .DB $FF         ;STACK
2309   8FDC 00                 .DB $00         ;FLAGS
2310   8FDD 00                 .DB $00         ;A
2311   8FDE 00                 .DB $00         ;X
2312   8FDF 00                 .DB $00         ;Y
2313   8FE0             ;VECTORS
2314   8FE0 4C BE 89           JMP HKEY        ;INVEC
2315   8FE3 4C 00 89           JMP HDOUT       ;OUTVEC
2316   8FE6 4C 6A 89           JMP KYSTAT      ;INSVEC
2317   8FE9 4C D1 81           JMP M1          ;UNRECOGNIZED SYNTAX (ERROR)
2318   8FEC 4C D1 81           JMP M1          ;UNRECOGNIZED COMMAND (ERROR)
2319   8FEF 4C 06 89           JMP SCAND       ;SCNVEC
2320   8FF2 7E 88              .DW RIN         ;IN PTR FOR EXEC FROM RAM
2321   8FF4 C0 80              .DW TRCOFF      ;USER TRACE VECTOR
2322   8FF6 4A 80              .DW SVBRK       ;BRK
2323   8FF8 29 80              .DW SVIRQ       ;USER IRQ
2324   8FFA 9B 80              .DW SVNMI       ;NMI
2325   8FFC 4A 8B              .DW RESET       ;RESET
2326   8FFE 0F 80              .DW IRQBRK      ;IRQ
2327   9000
2328   9000             LENTRY =$8C78
2329   9000             SENTRY =$8C78+$20F
2330   9000             RGNAM  =$8F9A          ;REGISTER NAME PATCH
2331   9000
2332   9000                    .END

tasm: Number of errors = 0



+------------------------------------------------------------------------
|  TOPIC -- AIM Computer -- AIM Monitor listing 
+------------------------------------------------------------------------

0001   0000             ;TELEMARK CROSS ASSEMBLER (TASM) http://www.halcyon.com/squakvly/
0002   0000
0003   0000             ;***************************************************
0004   0000             ;***************************************************
0005   0000             ;**                                               **
0006   0000             ;**                               PL-PA00-JOO1A   **
0007   0000             ;**                                               **
0008   0000             ;**     ROCKWELL R6500 MICROCOMPUTER SYSTEM       **
0009   0000             ;**                                               **
0010   0000             ;**               AIM 65 MONITOR                  **
0011   0000             ;**                                               **
0012   0000             ;**              PROGRAM LISTING                  **
0013   0000             ;**                                               **
0014   0000             ;**   REVISION A                   AUG 22, 1978   **
0015   0000             ;**                                               **
0016   0000             ;***************************************************
0017   0000             ;***************************************************
0018   0000
0019   0000             ;ROCKWELL INTERNATIONAL
0020   0000             ;MICROELECTRONIC DEVICES
0021   0000             ;3310 MIRALOMA AVENUE
0022   0000             ;P. O. BOX 3669
0023   0000             ;ANAHEIM CA U.S.A. 92803
0024   0000
0025   0000             ;     **************************************
0026   0000             ;     *  USER 6522 ADDRESSES (A000-A00F)   *
0027   0000             ;     **************************************
0028   A000                    *=$A000
0029   A000             UDRB   .BLOCK 1        ;DATA REG B
0030   A001             UDRAH  .BLOCK 1        ;DATA REG A
0031   A002             UDDRB  .BLOCK 1        ;DATA DIR REG B
0032   A003             UDDRA  .BLOCK 1        ;DATA DIR REG A
0033   A004             UT1L   .BLOCK 1        ;TIMER 1 COUNTER LOW
0034   A005             UT1CH  .BLOCK 1        ;TIMER 1 COUNTER HIGH
0035   A006             UT1LL  .BLOCK 1        ;TIMER 1 LATCH LOW
0036   A007             UT1LH  .BLOCK 1        ;TIMER 1 LATCH HIGH
0037   A008             UT2L   .BLOCK 1        ;TIMER 2 LATCH & COUNTER LOW
0038   A009             UT2H   .BLOCK 1        ;TIMER 2 COUNTER HIGH
0039   A00A             USR    .BLOCK 1        ;SHIFT REGISTER
0040   A00B             UACR   .BLOCK 1        ;AUX CONTROL REGISTER
0041   A00C             UPCR   .BLOCK 1        ;PERIPHERAL CONTROL REGISTER
0042   A00D             UIFR   .BLOCK 1        ;INTERRUPT FLAG REGISTER
0043   A00E             UIER   .BLOCK 1        ;INTERRUPT ENABLE REGISTER
0044   A00F             UDRA   .BLOCK 1        ;DATA REGISTER A
0045   A010
0046   A010             ASSEM  =$D000          ;ASSEMBLER ENTRY
0047   A010             BASIEN =$B000          ;BASIC ENTRY (COLD)
0048   A010             BASIRE =$B003          ;BASIC ENTRY (WARM)
0049   A010
0050   A010             ;      MONITOR RAM
0051   A010             ;TEXT EDITOR EQUATES (PAG 0)
0052   A010             ;OVERLAPS TABUF2+50 (TAPE OUTPUT BUFFER $AD-$FF)
0053   00DF                    *=$00DF
0054   00DF             NOWLN  .BLOCK 2        ;CURRENT LINE
0055   00E1             BOTLN  .BLOCK 2        ;LAST ACTIVE , SO FAR
0056   00E3             TEXT   .BLOCK 2        ;LIMITS OF BUFFER (START)
0057   00E5             END    .BLOCK 2        ;LIMITS OF BUFFER (END)
0058   00E7             SAVE   .BLOCK 2        ;USED BY REPLACE
0059   00E9             OLDLEN .BLOCK 1        ;ORIG LENGTH
0060   00EA             LENGTH .BLOCK 1        ;NEW LENGTH
0061   00EB             STRING .BLOCK 20       ;FIND STRING
0062   00FF
0063   0100                    *=$0100
0064   0100             ;BREAKPOINTS AND USER I/O HANDLERS
0065   0100             BKS    .BLOCK 8        ;BRK LOCATIONS
0066   0108             UIN    .BLOCK 2        ;USER INPUT HANDLER (VECTOR)
0067   010A             UOUT   .BLOCK 2        ;USER OUTPUT HANDLER (VECTOR)
0068   010C
0069   010C             ;UNUSED KEYS TO GO TO USER ROUTINE
0070   010C             KEYF1  .BLOCK 3        ;USER PUTS A JMP INSTRUCTION TO...
0071   010F             KEYF2  .BLOCK 3        ;GO TO HIS ROUTINE ON EITHER KEY..
0072   0112             KEYF3  .BLOCK 3        ;ENTRY
0073   0115
0074   0115             ;EQUATES FOR DISASSEMBLER (PAG 1)
0075   0116                    *=$0116         ;SAME AS TAPE BUFFER I/O (TABUFF)
0076   0116             FORMA  .BLOCK 1
0077   0117             LMNEM  .BLOCK 1
0078   0118             RMNEM  .BLOCK 14
0079   0126
0080   0126             ;EQUATES FOR MNEMONIC ENTRY
0081   0126             MOVAD  .BLOCK 8
0082   012E             TYPE   .BLOCK 2
0083   0130             TMASK1 =MOVAD
0084   0130             TMASK2 =MOVAD+1
0085   0130             CH     .BLOCK 3
0086   0133             ADFLD  .BLOCK 20
0087   0147             HISTM  =$A42E          ;SHARE WITH NAME & HIST
0088   0147             BYTESM =HISTM+1
0089   0147             TEMPX  =HISTM+3
0090   0147             TEMPA  =HISTM+5
0091   0147             OPCODE =HISTM+6
0092   0147             CODFLG =HISTM+9
0093   0147
0094   0147             ;      **********************************
0095   0147             ;      *  6532 ADDRESSES (A400-A7FF)    *
0096   0147             ;      **********************************
0097   A400                    *=$A400
0098   A400             MONRAM *=*
0099   A400             ;JUMP VECTORS
0100   A400             IRQV4  .BLOCK 2        ;IRQ AFTER MONITOR (NO BRK)
0101   A402             NMIV2  .BLOCK 2        ;NMI
0102   A404             IRQV2  .BLOCK 2        ;IRQ
0103   A406
0104   A406             ;I/O DEVICES
0105   A406             DILINK .BLOCK 2        ;DISPL LINKAGE (TO ECHO TO DISP)
0106   A408             TSPEED .BLOCK 1        ;TAPE SPEED (C7,5B,5A)
0107   A409             GAP    .BLOCK 1        ;TIMING GAP BETWEEN BLOCKS
0108   A40A             ;END OF USER ALTERABLE LOCATIONS
0109   A40A             NPUL   .BLOCK 1        ;# OF HALF PULSES...
0110   A40B             TIMG   .BLOCK 3        ;FOR TAPE
0111   A40E             REGF   .BLOCK 1        ;REGS FLG FOR SINGLE STEP MODE
0112   A40F             DISFLG .BLOCK 1        ;DISASSEM FLG FOR SINGLE STEP MODE
0113   A410             BKFLG  .BLOCK 1        ;ENABLE OR DIS BREAKPOINTS
0114   A411             PRIFLG .BLOCK 1        ;ENABLE OR DIS PRINTER
0115   A412             INFLG  .BLOCK 1        ;INPUT DEVICE
0116   A413             OUTFLG .BLOCK 1        ;OUTPUT DEVICE
0117   A414             HISTP  .BLOCK 1        ;HISTORY PTR (SINGLE STEP) (Y)
0118   A415             CURPO2 .BLOCK 1        ;DISPLAY POINTER
0119   A416             CURPOS .BLOCK 1        ;PRINTER POINTER
0120   A417             CNTH30 .BLOCK 1        ;BAUD RATE &...
0121   A418             CNTL30 .BLOCK 1        ;DELAY FOR TTY
0122   A419             COUNT  .BLOCK 1        ;# OF LINES (0-99)
0123   A41A             S1     .BLOCK 2        ;START ADDRESS
0124   A41C             ADDR   .BLOCK 2        ;END ADDRESS
0125   A41E             CKSUM  .BLOCK 2        ;CHECKSUM
0126   A420             S2     =BKS+6          ;VERTICAL COUNT (ONLY ON DUMP)
0127   A420
0128   A420             ;MONITOR REGISTERS
0129   A420             SAVPS  .BLOCK 1        ;STATUS
0130   A421             SAVA   .BLOCK 1        ;ACCUM
0131   A422             SAVX   .BLOCK 1        ;X REG
0132   A423             SAVY   .BLOCK 1        ;Y REG
0133   A424             SAVS   .BLOCK 1        ;STACK POINTER
0134   A425             SAVPC  .BLOCK 2        ;PROGR COUNTER
0135   A427
0136   A427             ;WORK AREAS FOR PAGE ZERO SIMULATION
0137   A427             ;SIMULATE LDA (NNNN),Y ,WHERE NNNN IS ABSOLUTE
0138   A427             STIY   .BLOCK 3        ;STA NM,Y
0139   A42A             CPIY   .BLOCK 3        ;CMP NM,Y   OR  LDA NM,Y
0140   A42D                    .BLOCK 1        ;RTS
0141   A42E             LDIY   =CPIY           ;LDA NM,Y
0142   A42E
0143   A42E             ;VARIABLES FOR TAPE
0144   A42E             NAME   .BLOCK 6        ;FILE NAME
0145   A434             TAPIN  .BLOCK 1        ;IN  FLG (TAPE 1 OR 2)
0146   A435             TAPOUT .BLOCK 1        ;OUT FLG (TAPE 1 OR 2)
0147   A436             TAPTR  .BLOCK 1        ;TAPE BUFF POINTER
0148   A437             TAPTR2 .BLOCK 1        ;TAPE OUTPUT BUFF PTR
0149   A438             HIST   =NAME           ;FOUR LAST ADDR + NEXT (SINGL STEP)`
0150   A438             BLK    =$0115          ;BLOCK COUNT
0151   A438             TABUFF =$0116          ;TAPE BUFFER (I/O)
0152   A438             BLKO   =$0168          ;OUTPUT BLOCK COUNT
0153   A438             TABUF2 =$00AD          ;OUTPUT BUFF WHEN ASSEMB (PAG0)
0154   A438             DIBUFF .BLOCK 40       ;DISPLAY BUFFER
0155   A460
0156   A460             ;VARIABLES USED IN PRINTING
0157   A460             IBUFM  .BLOCK 20       ;PRINTER BUFFER
0158   A474             IDIR   .BLOCK 1        ;DIRECTION == 0=>+ , FF=>-
0159   A475             ICOL   .BLOCK 1        ;COLUMN  LEFTMOST=0,RIGHTMOST=4
0160   A476             IOFFST .BLOCK 1        ;OFFSET  0=LEFT DGT,1=RIGHT DGT
0161   A477             IDOT   .BLOCK 1        ;# OF LAST DOT ENCOUNTERED
0162   A478             IOUTL  .BLOCK 1        ;LOWER 8 OUTPUTS(8 COLS ON RIGHT)
0163   A479             IOUTU  .BLOCK 1        ;UPPER 2 DIGITS
0164   A47A             IBITL  .BLOCK 1        ;1 BIT MSK FOR CURRENT OUTPUT
0165   A47B             IBITU  .BLOCK 1
0166   A47C             IMASK  .BLOCK 1        ;MSK FOR CURRENT ROW
0167   A47D             JUMP   .BLOCK 2        ;INDIR & ADDR OF TABL FOR CURR ROW
0168   A47F
0169   A47F             ;VARIABLES FOR KEYBOARD
0170   A47F             ROLLFL .BLOCK 1        ;SAVE LAST STROBE FOR ROLLOVER
0171   A480             KMASK  =CPIY           ;TO MASK OFF CTRL OR SHIFT
0172   A480             STBKEY =CPIY+1         ;STROBE KEY (1-8 COLUMNS)
0173   A480
0174   A480             ;               I/O ASSIGNMENT
0175   A480                    *=$A480
0176   A480             DRA2   .BLOCK 1        ;DATA REG A
0177   A481             DDRA2  .BLOCK 1        ;DATA DIR REG A
0178   A482             DRB2   .BLOCK 1        ;DATA REG B
0179   A483             DDRB2  .BLOCK 1        ;DATA DIR REG B
0180   A484
0181   A484             ;  WRITE EDGE DETECT CONTROL (NOT USED BECAUSE KB)
0182   A484                    *=$A484
0183   A484             DNPA7  .BLOCK 1        ;DISABLE PA7 INT ,NEG EDGE DET
0184   A485             DPPA7  .BLOCK 1        ;DIS PA7 INT ,POS EDGE DETE
0185   A486             ENPA7  .BLOCK 1        ;ENA PA7 INT ,NEG EDG DET
0186   A487             EPPA7  .BLOCK 1        ;ENA PA7 INT ,POS EDG DET
0187   A488
0188   A488             ;          READ AND CLEAR INTERRUPT
0189   A485                    *=$A485
0190   A485             RINT   .BLOCK 1        ;BIT 7=TIMER FLG , BIT 6=PA7 FLG
0191   A486
0192   A486             ;             TIMER INTERRUPT
0193   A494                    *=$A494
0194   A494             ;WRITE COUNT TO INTERVAL TIMER
0195   A494             ;INTERRUPT DISABLE FOR THESE ADDRS
0196   A494             DIV1   .BLOCK 1        ;DIV BY 1 (DISABLE);ADD 8 TO ENA
0197   A495             DIV8   .BLOCK 1        ;DIV BY 8 (DIS) ; ADD 8 TO ENA
0198   A496             DIV64  .BLOCK 1        ;DIV BY 64 (DIS) ; ADD 8 TO ENA
0199   A497             DI1024 .BLOCK 1        ;DIV BY 1024 (DIS) ; ADD 8 TO ENA
0200   A498
0201   A498             ;     *********************************************
0202   A498             ;     *    6522 ADDRESSES (MONIT) (A800-ABFF)     *
0203   A498             ;     *********************************************
0204   A800                    *=$A800
0205   A800             DRB    .BLOCK 1        ;DATA REG B
0206   A801             DRAH   .BLOCK 1        ;DATA REG A
0207   A802             DDRB   .BLOCK 1        ;DATA DIR REG B
0208   A803             DDRA   .BLOCK 1        ;DATA DIR REG A
0209   A804             T1L    .BLOCK 1        ;TIMER 1 COUNTER LOW
0210   A805             T1CH   .BLOCK 1        ;TIMER 1 COUNTER HIGH
0211   A806             T1LL   .BLOCK 1        ;TIMER 1 LATCH LOW
0212   A807             T1LH   .BLOCK 1        ;TIMER 1 LATCH HIGH
0213   A808             T2L    .BLOCK 1        ;TIMER 2 LATCH & COUNTER LOW
0214   A809             T2H    .BLOCK 1        ;TIMER 2 COUNTER HIGH
0215   A80A             SR     .BLOCK 1        ;SHIFT REGISTER
0216   A80B             ACR    .BLOCK 1        ;AUX CONTROL REGISTER
0217   A80C             PCR    .BLOCK 1        ;PERIPHERAL CONTROL REGISTER
0218   A80D             IFR    .BLOCK 1        ;INTERRUPT FLAG REGISTER
0219   A80E             IER    .BLOCK 1        ;INTERRUPT ENABLE REGISTER
0220   A80F             DRA    .BLOCK 1        ;DATA REGISTER A
0221   A810
0222   A810             ;DEFINE I/O CONTROL FOR PCR (CA1,CA2,CB1,CB2)
0223   A810             DATIN  =$0E            ;DATA IN CA2=1
0224   A810             DATOUT =$0C            ;DATA OUT CA2=0
0225   A810             PRST   =$00            ;PRINT START (CB1) ,NEG DETEC
0226   A810             SP12   =$01            ;STROBE P1,P2  (CA1) ,POS DETEC
0227   A810             MON    =$C0            ;MOTOR ON (CB2=0)
0228   A810             MOFF   =$E0
0229   A810             ;MSKS TO OBTAIN EACH INTERRUPT
0230   A810             MPRST  =$10            ;INT FLG FOR CB1
0231   A810             MSP12  =$02            ;INT FLG FOR CA1
0232   A810             MT2    =$20            ;INT FLG FOR T2
0233   A810
0234   A810             ;DEFINE I/O CONTROL FOR ACR  (TIMERS,SR)
0235   A810             PRTIME =1700           ; PRINTING TIME =1.7M MSEC
0236   A810             DEBTIM =5000           ; DEBOUNCE TIME (5 MSEC)
0237   A810             T2I    =$00            ;T2 AS ONE SHOT (PRI,KB,TTY,TAPE)
0238   A810             T1I    =$00            ;T1 AS ONE SHOT,PB7 DIS (TAPES)
0239   A810             T1FR   =$C0            ;T1 IN FREE RUNNING (TAPE)
0240   A810
0241   A810             ;         ******************************
0242   A810             ;         *    DISPLAY   (AC00-AFFF)   *
0243   A810             ;         ******************************
0244   A810             ; REGISTERS FOR DISPLAY (6520)
0245   AC00                    *=$AC00
0246   AC00             RA     .BLOCK 1        ;REGISTER A
0247   AC01             CRA    .BLOCK 1        ;CONTROL REG A
0248   AC02             RB     .BLOCK 1        ;REG B
0249   AC03             CRB    .BLOCK 1        ;CONTROL REG B
0250   AC04
0251   AC04             ;CHR 00-03 ENA BY $AC04-AC07
0252   AC04             ;CHR 04-07 ENA BY $AC08-AC0B
0253   AC04             ;CHR 08-11 ENA BY $AC10-AC13
0254   AC04             ;CHR 12-15 ENA BY $AC20-AC23
0255   AC04             ;CHR 16-19 ENA BY $AC40-AC43
0256   AC04
0257   AC04             NULLC  =$FF
0258   AC04             CR     =$0D
0259   AC04             LF     =$0A
0260   AC04             ESCAPE =$1B
0261   AC04             RUB    =$08
0262   AC04             EQS    =$BD
0263   AC04             ;.FILE A1
0264   AC04
0265   AC04             ; E=ENTER EDITOR
0266   AC04             ; T=RE-ENTER EDITOR TO RE-EDIT SOURCE
0267   AC04             ; R=SHOW REGISTERS
0268   AC04             ; M=DISPLAY MEMORY
0269   AC04             ;  =SHOW NEXT 4 ADDRESSES
0270   AC04             ; G=GO AT CURRENT P.C. (COUNT)
0271   AC04             ; /=ALTER CURRENT MEMORY
0272   AC04             ; L=LOAD OBJECT
0273   AC04             ; D=DUMP OBJECT
0274   AC04             ; N=ASSEMBLE
0275   AC04             ; *=ALTER P.C.
0276   AC04             ; A=ALTER ACCUMULATOR
0277   AC04             ; X=ALTER X REGISTER
0278   AC04             ; Y=ALTER Y REGISTER
0279   AC04             ; P=ALTER PROCESSOR STATUS
0280   AC04             ; S=ALTER STACK POINTER
0281   AC04             ; B=SET BREAK ADDR
0282   AC04             ; ?=SHOW BREAK ADDRESSES
0283   AC04             ; #=CLEAR BREAK ADDRESSES
0284   AC04             ; H=SHOW TRACE HISTORY STACK
0285   AC04             ; V=TOGGLE REGISTER PRINT WITH DIS.
0286   AC04             ; Z=TOGGLE DISASSEMBLER TRACE
0287   AC04             ; \=TURN ON/OFF PRINTER
0288   AC04             ;  =ADV PAPER
0289   AC04             ; I=MNEMONIC ENTRY
0290   AC04             ; K=DISASSEMBLE MEMORY
0291   AC04             ; 1=TOGGLE TAPE 1 CONTRL (ON OR OFF)
0292   AC04             ; 2=TOGGLE TAPE 2 CONTRL
0293   AC04             ; 3=VERIFY CKSUM FOR TAPES
0294   AC04             ; 4=ENABLE BREAKS
0295   AC04             ; 5=BASIC ENTRY (COLD)
0296   AC04             ; 6=BASIC REENTRY (WARM)
0297   AC04
0298   AC04             ;FOLLOWING KEYS ARE UNUSED BUT 'HOOKS'
0299   AC04             ;ARE PROVIDED IN LOCATIONS 010C-0114
0300   AC04             ;
0301   AC04             ; KEYF1,KEYF2,KEYF3
0302   AC04
0303   E000                    *=$E000
0304   E000             ;ALL MSGS HAVE MSB=1 OF LAST CHAR TO END IT
0305   E000 46524F4DBD  M1     .DB "FROM",EQS
0306   E005 54 4F BD    M3     .DB "TO",EQS
0307   E008 202A2A2A2A20M4     .DB " **** PS AA XX YY S",$D3
0307   E00E 50532041412058582059592053D3
0308   E01C 4D4F5245BF  M5     .DB "MORE",$BF
0309   E021 4F 4E A0    M6     .DB "ON",$A0     ;"ON "
0310   E024 4F 46 C6    M7     .DB "OF",$C6     ;"OFF"
0311   E027 42 52 CB    M8     .DB "BR",$CB     ;"BRK"
0312   E02A 49 4E BD    M9     .DB "IN",EQS
0313   E02D 4F 55 54 BD M10    .DB "OUT",EQS
0314   E031 204D454D2046M11    .DB " MEM FAIL",$A0
0314   E037 41494CA0
0315   E03B 205052494E54M12    .DB " PRINTER DOW",$CE
0315   E041 455220444F57CE
0316   E048 2053524348  TMSG0  .DB " SRCH"
0317   E04D 20 46 BD    TMSG1  .DB " F",EQS
0318   E050 54 BD       TMSG2  .DB "T",EQS
0319   E052 A0 C5 D2 D2 TMSG3  .DB $A0,$C5,$D2,$D2  ;PRINT " ERROR" ,MSB=1
0320   E056 CFD2A0A0A0A0       .DB $CF,$D2,$A0,$A0,$A0,$A0,$A0,$A0,";"
0320   E05C A0A03B
0321   E05F 41 BD       TMSG5  .DB "A",EQS
0322   E061 424C4B3DA0  TMSG6  .DB "BLK=",$A0
0323   E066 A0CCCFC1C43BTMSG7  .DB $A0,$CC,$CF,$C1,$C4,";"
0324   E06C 454449544FD2EMSG1  .DB "EDITO",$D2 ;EDITOR MESSAGES
0325   E072 45 4E C4    EMSG2  .DB "EN",$C4
0326   E075
0327   E075             ;VECTORS COME HERE FIRST AFTER JUMP THRU FFFA-FFFF
0328   E075 6C 02 A4    NMIV1  JMP (NMIV2)     ;NMIV2 IS A VECTOR TO NMIV3
0329   E078 6C 04 A4    IRQV1  JMP (IRQV2)     ;IRQV2 IS A VECTOR TO IRQV3
0330   E07B
0331   E07B             ;SINGLE STEP ENTRY POINT (NMI)
0332   E07B 8D 21 A4    NMIV3  STA SAVA        ;SAVE ACCUM
0333   E07E 68                 PLA
0334   E07F 8D 20 A4           STA SAVPS       ;SAVE PROCESSOR STATUS
0335   E082 D8                 CLD
0336   E083 8E 22 A4           STX SAVX        ;SAVE X
0337   E086 8C 23 A4           STY SAVY
0338   E089 68                 PLA
0339   E08A 8D 25 A4           STA SAVPC       ;PROGRAM COUNTER
0340   E08D 68                 PLA
0341   E08E 8D 26 A4           STA SAVPC+1
0342   E091 BA                 TSX             ;GET STACK PTR & SAVE IT
0343   E092 8E 24 A4           STX SAVS
0344   E095             ;TRACE THE ADDRESS
0345   E095 AC 14 A4           LDY HISTP       ;GET POINTER TO HISTORY STACK
0346   E098 AD 26 A4           LDA SAVPC+1     ;SAVE HALT ADDR IN HISTORY STACK
0347   E09B 99 2E A4           STA HIST,Y
0348   E09E AD 25 A4           LDA SAVPC
0349   E0A1 99 2F A4           STA HIST+1,Y
0350   E0A4 20 88 E6           JSR NHIS        ;UPDATE POINTER
0351   E0A7 AD 10 A4           LDA BKFLG       ;SOFT BREAKS ON?
0352   E0AA F0 08              BEQ NMI5        ;NO ,DONT CHCK BRKPOINT LIST
0353   E0AC 20 6B E7           JSR CKB         ;CHECK BREAKPOINT LIST
0354   E0AF 90 03              BCC NMI5        ;DID NOT HIT BREAKPOINT
0355   E0B1 4C 7F E1    NMI4   JMP IRQ2        ;HIT A BREAK-TRAP TO MONITOR
0356   E0B4 20 90 E7    NMI5   JSR DONE        ;COUNT =0 ?
0357   E0B7 F0 F8              BEQ NMI4        ;YES,TRAP TO MONITOR
0358   E0B9 20 07 E9           JSR RCHEK       ;CHK IF HE WANTS TO INTERR
0359   E0BC 4C 6D E2           JMP GOBK        ;NOT DONE-RESUME EXECUTION
0360   E0BF
0361   E0BF             ;POWER UP AND RESET ENTRY POINT (RST TRANSFERS HERE)
0362   E0BF D8          RSET   CLD             ;CLEAR DEC MODE
0363   E0C0 78                 SEI             ;DISABLE INTERRUPT
0364   E0C1 A2 FF              LDX #$FF        ;INIT STACK PTR
0365   E0C3 9A                 TXS
0366   E0C4 8E 24 A4           STX SAVS        ;ALSO INIT SAVED STACK PTR
0367   E0C7             ;INITIALIZE 6522
0368   E0C7 A2 0E              LDX #14
0369   E0C9 BD 43 E7    RS1    LDA INTAB1,X    ;PB1-PB0,PA7-PA0 FOR PRNTR
0370   E0CC 9D 00 A8           STA DRB,X       ;PB2=TTO,PB6=TTI
0371   E0CF CA                 DEX             ;PB4-PB5=TAPE CONTROL,PB7=DATA
0372   E0D0 10 F7              BPL RS1         ;PB3 =SWITCH KB/TTY
0373   E0D2             ;INITIALIZE 6532
0374   E0D2 A2 03              LDX #3          ;PORTS USED FOR KB
0375   E0D4 BD 52 E7    RS2    LDA INTAB2,X    ;PA0-PA7 AS OUTPUT
0376   E0D7 9D 80 A4           STA DRA2,X      ;PB0-PB7 AS INPUT
0377   E0DA CA                 DEX
0378   E0DB 10 F7              BPL RS2
0379   E0DD             ;INITIALIZE MONITOR RAM (6532)
0380   E0DD AD 56 E7           LDA INTAB3      ;CHECK IF NMIV2 HAS BEEN CHANGED
0381   E0E0 CD 02 A4           CMP NMIV2       ;IF IT HAS THEN ASSUME A COLD
0382   E0E3 D0 0C              BNE RS3A        ;START AND INITIALIZE EVERYTHING
0383   E0E5 AD 57 E7           LDA INTAB3+1
0384   E0E8 CD 03 A4           CMP NMIV2+1
0385   E0EB D0 04              BNE RS3A
0386   E0ED A2 10              LDX #16         ;THEY ARE EQUAL ,IT'S A WARM RESET
0387   E0EF D0 02              BNE RS3
0388   E0F1 A2 00       RS3A   LDX #0          ;INIT EVERYTHING (POWER UP)
0389   E0F3 BD 56 E7    RS3    LDA INTAB3,X
0390   E0F6 9D 02 A4           STA NMIV2,X
0391   E0F9 E8                 INX
0392   E0FA E0 15              CPX #21
0393   E0FC 90 F5              BCC RS3
0394   E0FE             ;INITIALIZE DISPLAY (6520)
0395   E0FE A9 00              LDA #0          ;SET CONTR REG FOR DATA DIR REG
0396   E100 A2 01              LDX #1
0397   E102 20 13 E1           JSR SETREG
0398   E105 A9 FF              LDA #$FF        ;SET DATA DIR REG FOR OUTPUT
0399   E107 CA                 DEX
0400   E108 20 13 E1           JSR SETREG
0401   E10B A9 04              LDA #$04        ;SET CONTR REG FOR PORTS
0402   E10D E8                 INX
0403   E10E 20 13 E1           JSR SETREG
0404   E111 D0 07              BNE RS3B
0405   E113 9D 00 AC    SETREG STA RA,X
0406   E116 9D 02 AC           STA RB,X
0407   E119 60                 RTS
0408   E11A 58          RS3B   CLI             ;CLEAR INTERRUPT
0409   E11B
0410   E11B             ;KB/TTY SWITCH TEST AND BIT RATE MEASUREMENT
0411   E11B A9 08              LDA #$08        ;PB3=SWITCH KB/TTY
0412   E11D 2C 00 A8    RS4    BIT DRB         ;A^M ,PB6-> V (OVERFLOW FLG)
0413   E120 D0 22              BNE RS7         ;BRANCH ON KB
0414   E122 70 F9              BVS RS4         ;START BIT=PB6=0?
0415   E124 A9 FF              LDA #$FF        ;YES ,INITIALIZE TIMER T2
0416   E126 8D 09 A8           STA T2H
0417   E129 2C 00 A8    RS5    BIT DRB         ;END OF START BIT ?
0418   E12C 50 FB              BVC RS5         ;NO ,WAIT UNTIL PB6 BACK TO 1
0419   E12E AD 09 A8           LDA T2H         ;STORE TIMING
0420   E131 49 FF              EOR #$FF        ;COMPLEMENT
0421   E133 8D 17 A4           STA CNTH30
0422   E136 AD 08 A8           LDA T2L
0423   E139 49 FF              EOR #$FF
0424   E13B 20 7C FE           JSR PATCH1      ;ADJUST IT
0425   E13E 20 13 EA    RS6    JSR CRLOW       ;CLEAR DISPLAY
0426   E141 4C 72 FF           JMP PAT21
0427   E144 A2 13       RS7    LDX #19         ;CLEAR HARDWARE CURSORS
0428   E146 8A          RS8    TXA
0429   E147 48                 PHA
0430   E148 A9 00              LDA #0
0431   E14A 20 7B EF           JSR OUTDD1
0432   E14D 68                 PLA
0433   E14E AA                 TAX
0434   E14F CA                 DEX
0435   E150 10 F4              BPL RS8
0436   E152 30 EA              BMI RS6
0437   E154
0438   E154             ;BRK INSTR (00) OR IRQ ENTRY POINT
0439   E154 8D 21 A4    IRQV3  STA SAVA
0440   E157 68                 PLA
0441   E158 48                 PHA             ;GET STATUS
0442   E159 29 10              AND #$10        ;SEE IF 'BRK' , ISOLATE B FLG
0443   E15B D0 06              BNE IRQ1        ;TRAP WAS CAUSED BY "BRK" INSTRUC
0444   E15D AD 21 A4           LDA SAVA        ;TRAP CAUSED BY IRQ SO TRANSFER
0445   E160 6C 00 A4           JMP (MONRAM)    ;CONTROL TO USER THRU VECTOR
0446   E163             ;IS 'BRK' INSTR ,SHOW PC & DATA
0447   E163             ;PC IS OFF BY ONE , SO ADJUST IT
0448   E163 68          IRQ1   PLA
0449   E164 8D 20 A4           STA SAVPS       ;SAVE PROCESSOR STATUS
0450   E167 8E 22 A4           STX SAVX
0451   E16A 8C 23 A4           STY SAVY
0452   E16D D8                 CLD
0453   E16E 68                 PLA             ;PROGR CNTR
0454   E16F 38                 SEC             ;SUBTRACT ONE FROM RETURN ADDR
0455   E170 E9 01              SBC #1
0456   E172 8D 25 A4           STA SAVPC
0457   E175 68                 PLA
0458   E176 E9 00              SBC #0
0459   E178 8D 26 A4           STA SAVPC+1
0460   E17B BA                 TSX             ;GET STACK PTR & SAVE IT
0461   E17C 8E 24 A4           STX SAVS
0462   E17F             ;SHOW PC AND DATA
0463   E17F 20 61 F4    IRQ2   JSR REGQ        ;SHOW NEXT INSTRUCTION & CONTINUE
0464   E182
0465   E182             ;THIS ROUTINE WILL GET A CHR WITH "( )" FROM
0466   E182             ;KB/TTY & THEN WILL GO TO THE RESPECTIVE COMMAND
0467   E182 4C 59 FF    START  JMP PAT19       ;CLEAR DEC MODE & <CR>
0468   E185 A9 BC       STA1   LDA #'<'+$80    ;"<" CHR WITH MSB=1 FOR DISP
0469   E187 20 7A E9           JSR OUTPUT
0470   E18A 20 96 FE           JSR RED1        ;GET CHR & ECHO FROM KB/TTY
0471   E18D 48                 PHA
0472   E18E A9 3E              LDA #'>'
0473   E190 20 7A E9           JSR OUTPUT
0474   E193 68                 PLA             ;SCAN LIST OF CMDS FOR ENTERED CHR
0475   E194 A2 20              LDX #MCNT       ;COUNT OF COMMANDS
0476   E196 DD C4 E1    MCM2   CMP COMB,X      ;CHECK NEXT COMMAND IN LIST
0477   E199 F0 11              BEQ MCM3        ;MATCH , SO PROCESS THIS COMMAND
0478   E19B CA                 DEX
0479   E19C 10 F8              BPL MCM2
0480   E19E             ;IS BAD COMMAND
0481   E19E 20 D4 E7           JSR QM
0482   E1A1 D8          COMIN  CLD
0483   E1A2 20 FE E8           JSR LL
0484   E1A5 AE 24 A4           LDX SAVS
0485   E1A8 9A                 TXS
0486   E1A9 4C 82 E1           JMP START
0487   E1AC             ;HAVE VALID COMMAND
0488   E1AC 8A          MCM3   TXA             ;CONVERT TO WORD (MULT BY 2)
0489   E1AD 0A                 ASL A           ;2 BYTES (ADDR)
0490   E1AE AA                 TAX
0491   E1AF BD E5 E1           LDA MONCOM,X    ;GET ADDRESS OF COMMAND PROCESSOR
0492   E1B2 8D 7D A4           STA JUMP
0493   E1B5 BD E6 E1           LDA MONCOM+1,X
0494   E1B8 8D 7E A4           STA JUMP+1
0495   E1BB 20 C1 E1           JSR JMPR        ;CMD PROCESSORS CAN EXIT WITH 'RTS'
0496   E1BE 4C 82 E1           JMP START
0497   E1C1 6C 7D A4    JMPR   JMP (JUMP)      ;GO TO COMMAND
0498   E1C4
0499   E1C4             ;VALID COMMANDS
0500   E1C4             MCNT   =32             ;COUNT
0501   E1C4 4554524D472FCOMB   .DB "ETRMG/LDN*AXYPS "
0501   E1CA 4C444E2A415859505320
0502   E1D4 423F2348565A       .DB "B?#HVZIK123456[]",$5E
0502   E1DA 494B3132333435365B5D5E
0503   E1E5
0504   E1E5 39F6CFF627E2MONCOM .DW EDIT,REENTR,REG,MEM,GO
0504   E1EB 48E261E2
0505   E1EF A0E2E6E23BE4       .DW CHNGG,LOAD,DUMP,ASSEM,CGPC,CGA
0505   E1F5 00D0D4E5EEE5
0506   E1FB F2E5F6E5EAE5       .DW CGX,CGY,CGPS,CGS,NXT5,BRKA
0506   E201 FAE50DE61BE6
0507   E207 4DE6FEE665E6       .DW SHOW,CLRBK,SHIS,REGT,TRACE
0507   E20D D9E6DDE6
0508   E211 9EFB0AE7BDE6       .DW MNEENT,KDISA,TOGTA1,TOGTA2,VECKSM
0508   E217 CBE694E6
0509   E21B E5E600B003B0       .DW BRKK,BASIEN,BASIRE
0510   E221             ;USER DEFINED FUNCTIONS
0511   E221 0C010F011201       .DW KEYF1,KEYF2,KEYF3
0512   E227
0513   E227             ;***** R COMMAND-DISPLAY REGISTERS *****
0514   E227 20 13 EA    REG    JSR CRLOW       ;CLEAR DISP IF KB
0515   E22A A0 08              LDY #M4-M1      ;MESSAG & <CR>
0516   E22C 20 AF E7           JSR KEP
0517   E22F 20 24 EA           JSR CRCK
0518   E232 20 3E E8    REG1   JSR BLANK
0519   E235 A0 09              LDY #SAVPC-ADDR ;OUTPUT PGR CNTR (SAVEPC+1,SAVEPC)
0520   E237 20 DD E2           JSR WRITAD
0521   E23A A9 20              LDA #SAVPS      ;NOW THE OTHER 5 REGS
0522   E23C 8D 1C A4           STA ADDR
0523   E23F A9 A4              LDA #SAVPS/256
0524   E241 8D 1D A4           STA ADDR+1
0525   E244 A2 05              LDX #5          ;COUNT
0526   E246 D0 07              BNE MEM1        ;SHARE CODE
0527   E248
0528   E248             ;***** M COMMAND-DISPLAY MEMORY *****
0529   E248 20 AE EA    MEM    JSR ADDIN       ;GET START ADDDRESS IN ADDR
0530   E24B B0 13              BCS MEM3
0531   E24D A2 04       MEIN   LDX #4
0532   E24F A0 00       MEM1   LDY #0
0533   E251 20 3E E8    MEM2   JSR BLANK
0534   E254 A9 1C              LDA #ADDR
0535   E256 20 58 EB           JSR LDAY        ;LOAD CONTENTS OF CURR LOCATION
0536   E259 20 46 EA           JSR NUMA        ;AND DISPLAY IT AS 2 HEX DIGITS
0537   E25C C8                 INY
0538   E25D CA                 DEX             ;DECR COUNTER
0539   E25E D0 F1              BNE MEM2
0540   E260 60          MEM3   RTS             ;GET NEXT COMMAND
0541   E261
0542   E261             ;***** G COMMAND-RESTART PROCESSOR *****
0543   E261 20 37 E8    GO     JSR PSL1        ;"/"
0544   E264 20 85 E7           JSR GCNT        ;GET COUNT
0545   E267 20 F0 E9           JSR CRLF
0546   E26A 4C 86 E2           JMP GOBK1       ;RESUME EXECUTION
0547   E26D AD 0E A4    GOBK   LDA REGF        ;DISPLAY REGISTERS ?
0548   E270 F0 06              BEQ GOBK0       ;NO,BRANCH
0549   E272 20 32 E2           JSR REG1        ;SHOW THE SIX REG
0550   E275 20 24 EA           JSR CRCK        ;<CR>
0551   E278 20 07 E9    GOBK0  JSR RCHEK       ;SEE IF HE WANTS TO INTERRUPT
0552   E27B AD 0F A4           LDA DISFLG      ;DISASSEMBLE CURRENT INSTR ?
0553   E27E F0 06              BEQ GOBK1       ;NO,BRANCH
0554   E280 20 6C F4           JSR DISASM      ;DISASM THIS INSTRUCTION
0555   E283 20 13 EA           JSR CRLOW
0556   E286 AE 24 A4    GOBK1  LDX SAVS        ;RESTORE SAVED REGS FOR RTI
0557   E289 9A                 TXS
0558   E28A AC 23 A4           LDY SAVY
0559   E28D AE 22 A4           LDX SAVX
0560   E290 AD 26 A4           LDA SAVPC+1
0561   E293 48                 PHA             ;PUT PC ON STACK
0562   E294 AD 25 A4           LDA SAVPC
0563   E297 48                 PHA
0564   E298 AD 20 A4           LDA SAVPS       ;STATUS ALSO
0565   E29B 48                 PHA
0566   E29C AD 21 A4           LDA SAVA
0567   E29F 40                 RTI             ;AND AWAY WE GO...
0568   E2A0
0569   E2A0             ;***** / COMMAND-ALTER MEMORY *****
0570   E2A0 20 3E E8    CHNGG  JSR BLANK
0571   E2A3 20 DB E2           JSR WRITAZ      ;WRITE ADDR
0572   E2A6 20 3E E8    CHNG1  JSR BLANK
0573   E2A9 20 5D EA           JSR RD2         ;GET VALUE
0574   E2AC 90 0A              BCC CH2         ;ISN'T SKIP OR DONE
0575   E2AE C9 20              CMP #' '
0576   E2B0 D0 13              BNE CH3         ;NOT BLANK SO MUST BE DONE
0577   E2B2             ;SKIP THIS LOCATION
0578   E2B2 20 3E E8           JSR BLANK
0579   E2B5 4C C0 E2           JMP CH4
0580   E2B8             ;IS ALTER
0581   E2B8 20 78 EB    CH2    JSR SADDR       ;STORE ENTERED VALUE INTO MEMORY
0582   E2BB F0 03              BEQ CH4         ;NO ERROR IN STORE
0583   E2BD 4C 33 EB           JMP MEMERR      ;MEMORY WRITE ERROR
0584   E2C0 C8          CH4    INY
0585   E2C1 C0 04              CPY #4
0586   E2C3 D0 E1              BNE CHNG1       ;GO AGAIN
0587   E2C5             ;HAVE DONE LINE OR HAVE <CR>
0588   E2C5 20 CD E2    CH3    JSR NXTADD      ;UPDATE THE ADDRESS
0589   E2C8 A9 0D              LDA #CR         ;CLEAR DISPL
0590   E2CA 4C E9 FE           JMP PATC10      ;ONLY ONE <CR> & BACK TO MONITOR
0591   E2CD
0592   E2CD 98          NXTADD TYA             ;ADD Y TO ADDR+1,ADDR
0593   E2CE 18                 CLC
0594   E2CF 6D 1C A4           ADC ADDR
0595   E2D2 8D 1C A4           STA ADDR
0596   E2D5 90 03              BCC NXTA1
0597   E2D7 EE 1D A4           INC ADDR+1
0598   E2DA 60          NXTA1  RTS
0599   E2DB
0600   E2DB             ;WRITE CURRENT VALUE OF ADDR
0601   E2DB             ;PART OF / & SPACE COMM
0602   E2DB A0 00       WRITAZ LDY #0
0603   E2DD B9 1D A4    WRITAD LDA ADDR+1,Y
0604   E2E0 BE 1C A4           LDX ADDR,Y
0605   E2E3 4C 42 EA           JMP WRAX
0606   E2E6
0607   E2E6             ;***** L COMMAND-GENERAL LOAD *****
0608   E2E6             ;LOAD OBJECT FROM TTY,USER,TYPE OR TAPE IN KIM-1 FORMAT
0609   E2E6 20 48 E8    LOAD   JSR WHEREI      ;WHERE INPUT
0610   E2E9             ;GET ";"  , # OF BYTES AND SA
0611   E2E9 20 93 E9    LOAD1  JSR INALL       ;GET FIRST CHAR
0612   E2EC C9 3B              CMP #SEMICOLON  ;LOOK FOR BEGINNING
0613   E2EE D0 F9              BNE LOAD1       ;IGNORE ALL CHARS BEFORE ";"
0614   E2F0 20 4D EB           JSR CLRCK       ;CLEAR CHECHSUM
0615   E2F3 20 4B E5           JSR CHEKAR      ;READ RECORD LENGTH
0616   E2F6 AA                 TAX             ;SAVE IN X THE # BYTES
0617   E2F7 20 4B E5           JSR CHEKAR      ;READ UPPER HALF OF ADDRESS
0618   E2FA 8D 1D A4           STA ADDR+1
0619   E2FD 20 4B E5           JSR CHEKAR      ;READ LOWER HALF OF ADDRESS
0620   E300 8D 1C A4           STA ADDR
0621   E303 8A                 TXA
0622   E304 F0 1B              BEQ LOAD4       ;LAST RECORD (RECORD LENGTH=0)
0623   E306             ;GET DATA
0624   E306 20 FD E3    LOAD2  JSR RBYTE       ;READ NEXT BYTE OF DATA
0625   E309 20 13 E4           JSR STBYTE      ;STORE AT LOC (ADDR+1,ADDR)
0626   E30C CA                 DEX             ;DECR RECORD LENGTH
0627   E30D D0 F7              BNE LOAD2
0628   E30F             ;COMPARE CKSUM
0629   E30F 20 FD E3           JSR RBYTE       ;READ UPPER HALF OF CHCKSUM
0630   E312 CD 1F A4           CMP CKSUM+1     ;COMPARE TO COMPUTED VALUE
0631   E315 D0 6E              BNE CKERR       ;CKSUM ERROR
0632   E317 20 FD E3           JSR RBYTE       ;READ LOWER HALF OF CHECKSUM
0633   E31A CD 1E A4           CMP CKSUM
0634   E31D D0 66              BNE CKERR
0635   E31F F0 C8              BEQ LOAD1       ;UNTIL LAST RECORD
0636   E321 A2 05       LOAD4  LDX #5          ;READ 4 MORE ZEROS
0637   E323 20 FD E3    LOAD5  JSR RBYTE
0638   E326 CA                 DEX
0639   E327 D0 FA              BNE LOAD5
0640   E329 20 93 E9           JSR INALL       ;READ LAST <CR>
0641   E32C 4C 20 E5           JMP DU13        ;SET DEFAULT DEV & GO BACK
0642   E32F
0643   E32F             ;LOAD ROUTINE FROM TAPE BY BLOCKS
0644   E32F             ;CHECK FOR RIGHT FILE & LOAD FIRST BLOCK
0645   E32F A9 00       LOADTA LDA #$00        ;CLEAR BLOCK COUNT
0646   E331 8D 15 01           STA BLK
0647   E334 20 53 ED           JSR TIBY1       ;LOAD BUFFER WITH A BLOCK
0648   E337 CA                 DEX             ;SET X=0
0649   E338 8E 15 A4           STX CURPO2      ;CLEAR DISPLAY PTR
0650   E33B BD 16 01           LDA TABUFF,X    ;BLK COUNT SHOULD BE ZERO
0651   E33E D0 EF              BNE LOADTA      ;NO, READ ANOTHER BLOCK
0652   E340 E8                 INX
0653   E341             ;AFTER FIRST BLOCK OUTPUT FILE NAME
0654   E341 EE 11 A4           INC PRIFLG      ;SO DO NOT GO TO PRINT.
0655   E344 A0 48              LDY #TMSG0-M1   ;PRINT "F="
0656   E346 20 AF E7           JSR KEP
0657   E349 BD 16 01    LOAD1A LDA TABUFF,X    ;OUTPUT FILE NAME
0658   E34C 20 7A E9           JSR OUTPUT      ;ONLY TO DISPLAY
0659   E34F E8                 INX
0660   E350 E0 06              CPX #6
0661   E352 D0 F5              BNE LOAD1A
0662   E354 20 3E E8           JSR BLANK
0663   E357 A0 61              LDY #TMSG6-M1   ;PRINT "BLK=  "
0664   E359 20 AF E7           JSR KEP
0665   E35C CE 11 A4           DEC PRIFLG      ;RESTORE PRINTR FLG
0666   E35F 20 BD ED           JSR ADDBK1      ;JUST OUTPUT BLK CNT
0667   E362 A2 01              LDX #1          ;RESTORE X
0668   E364             ;CHECK IF FILE IS CORRECT
0669   E364 BD 16 01    LOADT2 LDA TABUFF,X    ;NOW CHCK FILE NAME
0670   E367 DD 2D A4           CMP NAME-1,X
0671   E36A D0 C3              BNE LOADTA      ;IF NO FILENAME GET
0672   E36C E8                 INX             ;ANOTHER BLOCK
0673   E36D E0 06              CPX #6          ;FILENAME=5 CHRS
0674   E36F D0 F3              BNE LOADT2
0675   E371 8E 36 A4           STX TAPTR       ;SAVE TAPE BUFF PTR
0676   E374 EE 11 A4           INC PRIFLG      ;OUTPUT MSG ONLY TO DISPLAY
0677   E377 A9 00              LDA #0          ;CLEAR DISPLAY POINTER
0678   E379 8D 15 A4           STA CURPO2
0679   E37C A0 66              LDY #TMSG7-M1   ;PRINT "LOAD " WITHOUT CLR DISPL
0680   E37E 20 96 E3           JSR CKER1
0681   E381 CE 11 A4           DEC PRIFLG
0682   E384 60                 RTS
0683   E385
0684   E385             ;LINE CKSUM ERROR
0685   E385 20 8E E3    CKERR  JSR CKER0       ;SUBR SO MNEM ENTRY CAN USE IT
0686   E388 20 DB E2           JSR WRITAZ      ;WRITE ADDR
0687   E38B 4C A1 E1           JMP COMIN
0688   E38E 20 FE E8    CKER0  JSR LL          ;SET DEFAULT DEVICES
0689   E391 20 24 EA           JSR CRCK        ;<CR>
0690   E394 A0 52       CKER00 LDY #TMSG3-M1   ;PRINT "ERROR"
0691   E396 B9 00 E0    CKER1  LDA M1,Y        ;DONT CLR DISPLAY TO THE RIGHT
0692   E399 C9 3B              CMP #SEMICOLON
0693   E39B F0 06              BEQ CKER2
0694   E39D 20 7A E9           JSR OUTPUT      ;ONLY TO TERMINAL
0695   E3A0 C8                 INY
0696   E3A1 D0 F3              BNE CKER1
0697   E3A3 60          CKER2  RTS
0698   E3A4
0699   E3A4             ;LOAD ROUTINE FROM TAPE WITH KIM-1 FORMAT
0700   E3A4 20 4D EB    LOADKI JSR CLRCK       ;CLEAR CKSUM
0701   E3A7 20 EA ED    LOADK1 JSR TAISET      ;SET TAPE FOR INPUT
0702   E3AA 20 29 EE    LOADK2 JSR GETTAP      ;READ CHARACTER FROM TAPE
0703   E3AD C9 2A              CMP #'*'        ;BEGINNING OF FILE?
0704   E3AF F0 06              BEQ LOADK3      ;YES,BRNCH
0705   E3B1 C9 16              CMP #$16        ;IF NOT *  SHOULD BE SYN
0706   E3B3 D0 F2              BNE LOADK1
0707   E3B5 F0 F3              BEQ LOADK2
0708   E3B7 20 FD E3    LOADK3 JSR RBYTE       ;READ ID FROM TAPE
0709   E3BA 8D 21 A4           STA SAVA        ;SAVE ID
0710   E3BD             ;NOW GET ADDR TO DISPLAY
0711   E3BD             ;& COMPARE ID AFTERWARDS
0712   E3BD 20 4B E5           JSR CHEKAR      ;GET START ADDR LOW
0713   E3C0 8D 1C A4           STA ADDR
0714   E3C3 20 4B E5           JSR CHEKAR      ;GET START ADDR HIGH
0715   E3C6 8D 1D A4           STA ADDR+1
0716   E3C9 20 25 E4           JSR GETID       ;ID FROM HIM
0717   E3CC CD 21 A4           CMP SAVA        ;DO IDS MATCH?
0718   E3CF D0 D3              BNE LOADKI      ;NO ,GET ANOTHER FILE
0719   E3D1 A2 02       LOADK5 LDX #$02        ;GET 2 CHARS
0720   E3D3 20 29 EE    LOADK6 JSR GETTAP      ;1 CHAR FROM TAPE
0721   E3D6 C9 2F              CMP #'/'        ;LAST CHAR ?
0722   E3D8 F0 0E              BEQ LOADK7      ;YES,BRNCH
0723   E3DA 20 84 EA           JSR PACK        ;CONVERT TO HEX
0724   E3DD B0 A6              BCS CKERR       ;NOT HEX CHAR SO ERROR
0725   E3DF CA                 DEX
0726   E3E0 D0 F1              BNE LOADK6
0727   E3E2 20 13 E4           JSR STBYTE      ;STORE & CHCK MEM FAIL
0728   E3E5 4C D1 E3           JMP LOADK5      ;NEXT
0729   E3E8 20 FD E3    LOADK7 JSR RBYTE       ;END OF DATA CMP CKSUM
0730   E3EB CD 1E A4           CMP CKSUM       ;LOW
0731   E3EE D0 95              BNE CKERR
0732   E3F0 20 FD E3           JSR RBYTE
0733   E3F3 CD 1F A4           CMP CKSUM+1     ;HIGH
0734   E3F6 D0 8D              BNE CKERR
0735   E3F8 68                 PLA             ;CORRECT RTN INSTEAD OF WHEREI
0736   E3F9 68                 PLA
0737   E3FA 4C 20 E5           JMP DU13        ;TELL HIM & GO BACK TO COMMAN
0738   E3FD
0739   E3FD             ;GET 2 ASCII CHRS INTO 1 BYTE
0740   E3FD             ;FOR TAPE (T) GET ONLY ONE HEX CHR
0741   E3FD AD 12 A4    RBYTE  LDA INFLG       ;INPUT DEVICE
0742   E400 C9 54              CMP #'T'
0743   E402 D0 03              BNE RBYT1
0744   E404 4C 93 E9           JMP INALL       ;ONLY ONE BYTE FOR T (INPUT DEV)
0745   E407 20 93 E9    RBYT1  JSR INALL
0746   E40A 20 84 EA           JSR PACK
0747   E40D 20 93 E9           JSR INALL
0748   E410 4C 84 EA           JMP PACK
0749   E413
0750   E413             ;STORE AND CHECK MEMORY FAIL
0751   E413 20 4E E5    STBYTE JSR CHEKA       ;ADD TO CKSUM
0752   E416 A0 00              LDY #0
0753   E418 20 78 EB           JSR SADDR       ;STORE AND CHCK
0754   E41B F0 03              BEQ *+5
0755   E41D 4C 33 EB           JMP MEMERR      ;MEMORY WRITE ERROR
0756   E420 A0 01              LDY #1          ;INC ADDR+1,ADDR BY 1
0757   E422 4C CD E2           JMP NXTADD
0758   E425
0759   E425             ;GET ID FROM LAST 2 CHR OF FILENAM
0760   E425 A2 04       GETID  LDX #4          ;SEE WHAT HE GAVE US
0761   E427 BD 2E A4    GID1   LDA NAME,X      ;GET LAST 2 CHARS
0762   E42A CA                 DEX
0763   E42B C9 20              CMP #' '        ;<SPACE> ?
0764   E42D F0 F8              BEQ GID1
0765   E42F BD 2E A4           LDA NAME,X      ;CONVERT TO BINARY
0766   E432 20 84 EA           JSR PACK
0767   E435 BD 2F A4           LDA NAME+1,X
0768   E438 4C 84 EA           JMP PACK        ;ID IS IN STIY
0769   E43B
0770   E43B             ;***** D COMMAND-GENERAL DUMP *****
0771   E43B             ;TO TTY,PRINTR,USER,X ,TAPE,TAKIM-1
0772   E43B AD 10 A4    DUMP   LDA BKFLG       ;SAVE IT TO USE IT
0773   E43E 48                 PHA
0774   E43F A9 00              LDA #00
0775   E441 8D 10 A4           STA BKFLG
0776   E444 20 24 EA    DU1    JSR CRCK        ;<CR>
0777   E447 20 A3 E7    DU0    JSR FROM        ;GET START ADDR
0778   E44A B0 FB              BCS DU0         ;IN CASE OF ERROR DO IT AGAIN
0779   E44C 20 3E E8           JSR BLANK
0780   E44F 20 10 F9           JSR ADDRS1      ;TRANSFER ADDR TO S1
0781   E452 20 A7 E7    DU1B   JSR TO          ;GET END ADDR
0782   E455 B0 FB              BCS DU1B
0783   E457 20 13 EA           JSR CRLOW
0784   E45A AD 10 A4           LDA BKFLG       ;EXECUTE WHEREO ONLY ONCE
0785   E45D D0 0E              BNE DU1A
0786   E45F 20 71 E8           JSR WHEREO      ;WHICH DEV (OUTFLG)
0787   E462 A9 00              LDA #0
0788   E464 8D 06 01           STA S2          ;CLEAR RECORD COUNT
0789   E467 8D 07 01           STA S2+1
0790   E46A EE 10 A4           INC BKFLG       ;SET FLG
0791   E46D             ;CHCK OUTPUT DEV
0792   E46D AD 13 A4    DU1A   LDA OUTFLG
0793   E470 C9 4B              CMP #'K'        ;TAPE FOR KIM?
0794   E472 D0 04              BNE *+6
0795   E474 68                 PLA             ;PULL FLG
0796   E475 4C 87 E5           JMP DUMPKI      ;YES, GO OUTPUT WHOLE FILE
0797   E478 A0 01              LDY #1          ;OUTPUT ONE MORE BYTE
0798   E47A 20 CD E2           JSR NXTADD
0799   E47D 20 F0 E9    DU2    JSR CRLF
0800   E480 20 07 E9           JSR RCHEK       ;SEE IF HE WANTS TO INTERRUPT
0801   E483             ;CALCULATE # OF BYTES YET TO BE DUMPED
0802   E483 20 4D EB           JSR CLRCK       ;CLEAR CKSUM
0803   E486 AD 1C A4           LDA ADDR        ;END ADDRESS-CURRENT ADDRESS
0804   E489 38                 SEC
0805   E48A ED 1A A4           SBC S1
0806   E48D 48                 PHA             ;# OF BYTES LOW
0807   E48E AD 1D A4           LDA ADDR+1
0808   E491 ED 1B A4           SBC S1+1
0809   E494 D0 09              BNE DU6         ;# OF BYTES HIGH
0810   E496             ;SEE IF 24 OR MORE BYTES TO GO
0811   E496 68                 PLA             ;# BYTES HIGH WAS ZERO
0812   E497 F0 42              BEQ DU10        ;ARE DONE
0813   E499 C9 18              CMP #24         ;# BYTES > 24 ?
0814   E49B 90 05              BCC DU8         ;NO ,ONLY OUTPUT REMAINING BYTES
0815   E49D B0 01              BCS DU7         ;YES ,24 BYTES IN NEXT RECORD
0816   E49F 68          DU6    PLA
0817   E4A0 A9 18       DU7    LDA #24
0818   E4A2             ;OUTPUT ";" ,# OF BYTES AND SA
0819   E4A2 48          DU8    PHA
0820   E4A3 20 BA E9           JSR SEMI        ;SEMICOLON
0821   E4A6 68                 PLA
0822   E4A7 8D 19 A4           STA COUNT       ;SAVE # OF BYTES
0823   E4AA 20 38 E5           JSR OUTCK       ;OUTPUT # OF BYTES
0824   E4AD AD 1B A4           LDA S1+1        ;OUTPUT ADDRESS
0825   E4B0 20 38 E5           JSR OUTCK
0826   E4B3 AD 1A A4           LDA S1
0827   E4B6 20 38 E5           JSR OUTCK
0828   E4B9             ;OUTPUT DATA
0829   E4B9 20 31 E5    DU9    JSR OUTCKS      ;GET CHAR SPEC BY S1 (NO PAG 0)
0830   E4BC A9 00              LDA #0          ;CLEAR DISP PTR
0831   E4BE 8D 15 A4           STA CURPO2
0832   E4C1 20 5D E5           JSR ADDS1       ;INCR S1+1,S1
0833   E4C4 CE 19 A4           DEC COUNT       ;DECREMENT BYTE COUNT
0834   E4C7 D0 F0              BNE DU9         ;NOT DONE WITH THIS RECORD
0835   E4C9             ;OUTPUT CKSUM
0836   E4C9 AD 1F A4           LDA CKSUM+1
0837   E4CC 20 3B E5           JSR OUTCK1      ;WITHOUT CHEKA
0838   E4CF AD 1E A4           LDA CKSUM
0839   E4D2 20 3B E5           JSR OUTCK1
0840   E4D5 20 66 E5           JSR INCS2       ;INC VERTICAL COUNT
0841   E4D8 4C 7D E4           JMP DU2         ;NEXT RECORD
0842   E4DB             ;ALL DONE
0843   E4DB A0 1C       DU10   LDY #M5-M1      ;PRINT "MORE ?#
0844   E4DD 20 70 E9           JSR KEPR        ;OUTPUT MSG AND GET AN ANSWER
0845   E4E0 C9 59              CMP #'Y'
0846   E4E2 D0 03              BNE *+5
0847   E4E4 4C 44 E4           JMP DU1         ;DUMP MORE DATA
0848   E4E7 68                 PLA             ;RESTORE FLG
0849   E4E8 8D 10 A4           STA BKFLG
0850   E4EB             ;OUTPUT LAST RECORD
0851   E4EB 20 66 E5           JSR INCS2
0852   E4EE 20 BA E9           JSR SEMI        ;OUTPUT ';'
0853   E4F1 A2 02              LDX #2
0854   E4F3 A9 00              LDA #0          ;OUTPUT # OF BYTES (0-LAST RECORD)
0855   E4F5 20 3B E5           JSR OUTCK1
0856   E4F8 AD 07 01    DU10A  LDA S2+1        ;OUTPUT RECORD COUNT
0857   E4FB 20 3B E5           JSR OUTCK1      ;CHECKCUM IS THE SAME
0858   E4FE AD 06 01           LDA S2
0859   E501 20 3B E5           JSR OUTCK1
0860   E504 CA                 DEX
0861   E505 D0 F1              BNE DU10A
0862   E507 20 F0 E9           JSR CRLF
0863   E50A             ;CLOSE TAPE BLOCK IF ACTIVE
0864   E50A AD 13 A4    DU11   LDA OUTFLG
0865   E50D C9 54              CMP #'T'
0866   E50F D0 0F              BNE DU13        ;NO ,BRANCH
0867   E511 AD 37 A4    DU12   LDA TAPTR2      ;TAP OUTPUT BUFF PTR
0868   E514 C9 01              CMP #1          ;BECAUSE FIRST ONE IS BLK CNT
0869   E516 F0 08              BEQ DU13        ;NO DATA TO WRITE
0870   E518 A9 00              LDA #0          ;FILL REST BUFF ZEROS
0871   E51A 20 8B F1           JSR TOBYTE      ;OUTPUT TO BUFF
0872   E51D 4C 11 E5           JMP DU12        ;FINISH THIS BLOCK
0873   E520 20 13 EA    DU13   JSR CRLOW
0874   E523 18                 CLC             ;ENABLE INTERR
0875   E524 A9 00              LDA #T1I        ;T1 FROM FREE RUNNING TO 1 SHOT
0876   E526 8D 0B A8           STA ACR
0877   E529 A9 34       DU14   LDA #$34        ;SET BOTH TAPES ON
0878   E52B 8D 00 A8           STA DRB
0879   E52E 4C FE E8           JMP LL
0880   E531
0881   E531             ;GET CHAR SPECIFIED BY START ADDR (S1)
0882   E531 A9 1A       OUTCKS LDA #S1
0883   E533 A0 00              LDY #0
0884   E535 20 58 EB           JSR LDAY
0885   E538
0886   E538             ;ADD TO CHECKSUM AND PRINT
0887   E538 20 4E E5    OUTCK  JSR CHEKA       ;CHCKSUM
0888   E53B 48          OUTCK1 PHA
0889   E53C AD 13 A4           LDA OUTFLG      ;IF TAPE DO NOT CNVRT
0890   E53F C9 54              CMP #'T'        ;TO TWO ASCII CHRS
0891   E541 D0 04              BNE OUTCK2
0892   E543 68                 PLA
0893   E544 4C 8B F1           JMP TOBYTE      ;OUTPUT TO TAP BUFF
0894   E547 68          OUTCK2 PLA
0895   E548 4C 46 EA           JMP NUMA        ;TWO ASCII REPRE
0896   E54B
0897   E54B 20 FD E3    CHEKAR JSR RBYTE       ;TWO ASCII CHR---> 1 BYTE
0898   E54E 48          CHEKA  PHA             ;ADD TO CHECKSUM
0899   E54F 18                 CLC
0900   E550 6D 1E A4           ADC CKSUM
0901   E553 8D 1E A4           STA CKSUM
0902   E556 90 03              BCC *+5
0903   E558 EE 1F A4           INC CKSUM+1
0904   E55B 68                 PLA
0905   E55C 60                 RTS
0906   E55D
0907   E55D             ;ADD ONE TO START ADDR (S1)
0908   E55D EE 1A A4    ADDS1  INC S1
0909   E560 D0 03              BNE ADD1
0910   E562 EE 1B A4           INC S1+1
0911   E565 60          ADD1   RTS
0912   E566
0913   E566 EE 06 01    INCS2  INC S2          ;INCR VERTICAL COUNT
0914   E569 D0 03              BNE *+5
0915   E56B EE 07 01           INC S2+1
0916   E56E 60                 RTS
0917   E56F
0918   E56F             ;OPEN A FILE FOR OUTPUT TO TAPE BY BLOCKS
0919   E56F             ;OUTPUT FILENAME GIVEN BY JSR WHEREO TO TAPE BUFF
0920   E56F A2 00       DUMPTA LDX #0          ;INITIALIZE TAPTR
0921   E571 8A                 TXA             ;TO OUTPUT
0922   E572 8E 68 01           STX BLKO        ;BLOCK COUNTER
0923   E575 8E 37 A4           STX TAPTR2      ;TAP OUTPUT BUFF PTR
0924   E578 20 8B F1           JSR TOBYTE      ;TWO START OF FILE CHRS
0925   E57B BD 2E A4    DUMPT1 LDA NAME,X      ;OUTPUT FILENAME
0926   E57E 20 8B F1           JSR TOBYTE
0927   E581 E8                 INX
0928   E582 E0 05              CPX #5
0929   E584 D0 F5              BNE DUMPT1      ;5 FILENAME CHRS ?
0930   E586 60                 RTS
0931   E587
0932   E587             ;DUMP ROUTINE TO TAPE WITH KIM-1 FORMAT
0933   E587 20 1D F2    DUMPKI JSR TAOSET      ;SET TAPE FOR OUTPUT
0934   E58A A9 2A              LDA #'*'        ;TO EITHER 1 OR 2
0935   E58C 20 4A F2           JSR OUTTAP      ;DIRECTLY TO TAPE
0936   E58F             ;ID FROM LAST 2 CHRS OF FILENAME
0937   E58F 20 25 E4           JSR GETID
0938   E592 20 3B E5           JSR OUTCK1
0939   E595 20 4D EB           JSR CLRCK
0940   E598             ;STARTING ADDR
0941   E598 AD 1A A4           LDA S1
0942   E59B 20 38 E5           JSR OUTCK       ;WITH CHCKSUM
0943   E59E AD 1B A4           LDA S1+1
0944   E5A1 20 38 E5           JSR OUTCK
0945   E5A4             ;OUTPUT DATA
0946   E5A4 20 31 E5    DUK2   JSR OUTCKS      ;OUTPUT CHR SPECIFIED BY S1+1,S1
0947   E5A7 20 5D E5           JSR ADDS1       ;INCREM S1+1,S1
0948   E5AA AD 1A A4           LDA S1          ;CHCK FOR LAST BYTE
0949   E5AD CD 1C A4           CMP ADDR        ;LSB OF END ADDR
0950   E5B0 AD 1B A4           LDA S1+1
0951   E5B3 ED 1D A4           SBC ADDR+1
0952   E5B6 90 EC              BCC DUK2        ;NEXT CHR
0953   E5B8             ;NOW SEND END CHR "/"
0954   E5B8 A9 2F              LDA #'/'
0955   E5BA 20 4A F2           JSR OUTTAP      ;DIRECTLY TO TAPE
0956   E5BD             ;CHECKSUM
0957   E5BD AD 1E A4           LDA CKSUM
0958   E5C0 20 46 EA           JSR NUMA        ;ASCII REPRES
0959   E5C3 AD 1F A4           LDA CKSUM+1
0960   E5C6 20 46 EA           JSR NUMA
0961   E5C9             ;TWO EOT CHRS
0962   E5C9 A9 04              LDA #$04
0963   E5CB 20 4A F2           JSR OUTTAP
0964   E5CE 20 4A F2           JSR OUTTAP
0965   E5D1             ;TURN TAPES ON
0966   E5D1 4C 20 E5           JMP DU13
0967   E5D4
0968   E5D4             ;***** * COMMAND-ALTER PROGRAM COUNTER *****
0969   E5D4 20 AE EA    CGPC   JSR ADDIN       ;ADDR <=ADDRESS ENTERED FROM KB
0970   E5D7 20 DD E5    CGPC0  JSR CGPC1       ;TRANSFER ADDR TO SAVPC
0971   E5DA 4C 13 EA           JMP CRLOW
0972   E5DD AD 1D A4    CGPC1  LDA ADDR+1      ;THIS WAY MNEMONICS CAN USE IT
0973   E5E0 8D 26 A4           STA SAVPC+1
0974   E5E3 AD 1C A4           LDA ADDR
0975   E5E6 8D 25 A4           STA SAVPC
0976   E5E9 60                 RTS
0977   E5EA
0978   E5EA             ;***** P COMMAND-ALTER PROCESSOR STATUS *****
0979   E5EA A2 00       CGPS   LDX #0
0980   E5EC F0 0E              BEQ CGALL
0981   E5EE
0982   E5EE             ;***** A COMMAND-ALTER ACCUMULATOR *****
0983   E5EE A2 01       CGA    LDX #1
0984   E5F0 D0 0A              BNE CGALL
0985   E5F2
0986   E5F2             ;***** X COMMAND-ALTER X REGISTER *****
0987   E5F2 A2 02       CGX    LDX #2
0988   E5F4 D0 06              BNE CGALL
0989   E5F6
0990   E5F6             ;***** Y COMMAND-ALTER Y REGISTER *****
0991   E5F6 A2 03       CGY    LDX #3
0992   E5F8 D0 02              BNE CGALL
0993   E5FA
0994   E5FA             ;***** S COMMAND-ALTER STACK POINTER *****
0995   E5FA A2 04       CGS    LDX #4
0996   E5FC 20 D8 E7    CGALL  JSR EQUAL       ;PRINT PROMPT
0997   E5FF 20 5D EA           JSR RD2         ;GET VALUE FROM KEYBOARD
0998   E602 B0 04              BCS GOERR
0999   E604 9D 20 A4           STA SAVPS,X
1000   E607 60                 RTS
1001   E608 20 D4 E7    GOERR  JSR QM
1002   E60B D0 EF              BNE CGALL
1003   E60D
1004   E60D             ;***** <SPACE> COMMAND-SHOW NEXT 5 MEMORY LOC *****
1005   E60D 20 3E E8    NXT5   JSR BLANK
1006   E610 A0 04              LDY #4          ;UPDATE ADDR FROM
1007   E612 20 CD E2           JSR NXTADD      ;<M>=XXXX
1008   E615 20 DB E2           JSR WRITAZ      ;OUTPUT ADDRESS
1009   E618 4C 4D E2           JMP MEIN        ;DISPLAY CONTENTS OF NEXT 4 LOCS
1010   E61B
1011   E61B             ;***** B COMMAND-SET BREAKPOINT ADDR *****
1012   E61B A0 27       BRKA   LDY #M8-M1      ;PRINT "BRK"
1013   E61D 20 AF E7           JSR KEP
1014   E620 20 37 E8    BRK1   JSR PSL1        ;PRINT "/"
1015   E623 20 73 E9           JSR REDOUT      ;GET BREAK NUMBER
1016   E626 38                 SEC
1017   E627 E9 30              SBC #'0'        ;0 THRU 3
1018   E629 30 04              BMI BKERR       ;CHARACTER < '0' -ILLEGAL
1019   E62B C9 04              CMP #4          ;FOUR BRK POINTS
1020   E62D 30 05              BMI BKOK        ;0 < CHARACTER < 4 -OK
1021   E62F 20 D4 E7    BKERR  JSR QM          ;ERROR
1022   E632 D0 EC              BNE BRK1        ;ALLOW REENTRY OF BREAK NUMBER
1023   E634 0A          BKOK   ASL A           ;*2 TO FORM WORD OFFSET
1024   E635 48                 PHA             ;SAVE IT
1025   E636 20 AE EA           JSR ADDIN       ;GET ADDRESS FOR BREAKPOINT
1026   E639 68                 PLA
1027   E63A B0 10              BCS BKO2        ;BAD ADDRESS ENTERED
1028   E63C 20 3D FF           JSR PATC18      ;<CR> & CLR BUFFERS
1029   E63F AA                 TAX             ;# OF BRK
1030   E640 AD 1C A4           LDA ADDR        ;STORE ENTERED ADDR IN BRKPT LIST
1031   E643 9D 00 01           STA BKS,X
1032   E646 AD 1D A4           LDA ADDR+1
1033   E649 9D 01 01           STA BKS+1,X
1034   E64C 60          BKO2   RTS             ;ALL DONE
1035   E64D
1036   E64D             ;***** ? COMMAND-SHOW CURRENT BREAKPOINTS *****
1037   E64D A0 00       SHOW   LDY #0
1038   E64F 20 13 EA           JSR CRLOW
1039   E652 20 3E E8    SH1    JSR BLANK
1040   E655 BE 00 01           LDX BKS,Y       ;ADDRESS OF NEXT BREAKPOINT
1041   E658 B9 01 01           LDA BKS+1,Y
1042   E65B 20 42 EA           JSR WRAX        ;SHOW BREAKPOINT ADDRESS
1043   E65E C8                 INY
1044   E65F C8                 INY
1045   E660 C0 08              CPY #8
1046   E662 D0 EE              BNE SH1
1047   E664 60                 RTS
1048   E665
1049   E665             ;***** H COMMAND-SHOW TRACE STACK HISTORY *****
1050   E665             ;LAST FIVE INSTR ADDRS
1051   E665 A2 05       SHIS   LDX #5          ;NUMBER OF ENTRIES
1052   E667 8E 29 A4           STX STIY+2
1053   E66A AC 14 A4    SH11   LDY HISTP       ;POINTER TO LATEST ENTRY
1054   E66D 20 13 EA           JSR CRLOW
1055   E670 20 3E E8           JSR BLANK
1056   E673 B9 2E A4           LDA HIST,Y      ;OUTPUT ADDRESS OF ENTRY
1057   E676 20 46 EA           JSR NUMA
1058   E679 B9 2F A4           LDA HIST+1,Y
1059   E67C 20 46 EA           JSR NUMA
1060   E67F 20 88 E6           JSR NHIS        ;UPDATE POINTER
1061   E682 CE 29 A4           DEC STIY+2
1062   E685 D0 E3              BNE SH11
1063   E687 60                 RTS
1064   E688
1065   E688             ;UPDATE HISTORY POINTER (PART OF H)
1066   E688 C8          NHIS   INY
1067   E689 C8                 INY
1068   E68A C0 0A              CPY #10
1069   E68C D0 02              BNE NH1
1070   E68E A0 00              LDY #0          ;WRAPAROUND AT 10
1071   E690 8C 14 A4    NH1    STY HISTP
1072   E693 60                 RTS
1073   E694
1074   E694             ;***** 3 COMMAND-VERIFY TAPES *****
1075   E694             ;VERIFY CKSUM OF BLOCKS
1076   E694 20 48 E8    VECKSM JSR WHEREI      ;GET THE FILE
1077   E697 20 93 E9           JSR INALL       ;CHCK OBJ OR SOURCE
1078   E69A C9 0D              CMP #CR         ;FIRST CHR IS <CR> IF OBJ
1079   E69C D0 0E              BNE VECK2       ;ASSUME SOURCE CODE
1080   E69E 20 93 E9    VECK1  JSR INALL       ;OBJECT FILE
1081   E6A1 C9 3B              CMP #SEMICOLON
1082   E6A3 D0 F9              BNE VECK1       ;IGNORE ALL CHARS BEFORE ';'
1083   E6A5 20 93 E9           JSR INALL
1084   E6A8 4C 60 FF           JMP PAT20
1085   E6AB EA                 NOP
1086   E6AC 20 93 E9    VECK2  JSR INALL       ;IT IS TEXT
1087   E6AF C9 0D              CMP #CR
1088   E6B1 D0 F9              BNE VECK2
1089   E6B3 20 93 E9           JSR INALL       ;NEED TO <CR> TO FINISH
1090   E6B6 C9 0D              CMP #CR
1091   E6B8 D0 F2              BNE VECK2
1092   E6BA 4C 20 E5           JMP DU13        ;CLOSE FILE, IT IS OKAY
1093   E6BD
1094   E6BD             ;***** 1 COMMAND-TOGGLE TAPE 1 CONTROL *****
1095   E6BD AD 00 A8    TOGTA1 LDA DRB
1096   E6C0 49 10              EOR #$10        ;INVERT PB4
1097   E6C2 8D 00 A8           STA DRB
1098   E6C5 29 10              AND #$10
1099   E6C7 F0 28              BEQ BRK3        ;IF 0 TAPE CNTRL IS ON
1100   E6C9 D0 2F              BNE BRK4        ;IF $10 TAPE CNTRL IS OFF
1101   E6CB
1102   E6CB             ;***** 2 COMMAND-TOGGLE TAPE 2 CONTROL *****
1103   E6CB AD 00 A8    TOGTA2 LDA DRB
1104   E6CE 49 20              EOR #$20        ;INVERT PB5
1105   E6D0 8D 00 A8           STA DRB
1106   E6D3 29 20              AND #$20
1107   E6D5 F0 1A              BEQ BRK3
1108   E6D7 D0 21              BNE BRK4
1109   E6D9
1110   E6D9             ;***** V COMMAND-TOGGLE REGISTER DISP FLG *****
1111   E6D9             ;DISPLAY REGIST BEFORE EXEC
1112   E6D9 A2 0E       REGT   LDX #REGF
1113   E6DB D0 0A              BNE TOGL
1114   E6DD
1115   E6DD             ;****** Z COMMAND-TOGGLE DIS TRACE FLG *****
1116   E6DD             ;DISPL NEXT INSTR BEFORE EXEC
1117   E6DD A2 0F       TRACE  LDX #DISFLG
1118   E6DF D0 06              BNE TOGL
1119   E6E1
1120   E6E1             ;***** \ COMMAND-TOGGLE PRINTER FLAG *****
1121   E6E1 A2 11       PRITR  LDX #PRIFLG
1122   E6E3 D0 02              BNE TOGL
1123   E6E5
1124   E6E5             ;***** 4 COMMAND-TOGGLE SOFT BRK ENABL FLG *****
1125   E6E5 A2 10       BRKK   LDX #BKFLG
1126   E6E7
1127   E6E7 BD 00 A4    TOGL   LDA MONRAM,X    ;LOAD FLAG
1128   E6EA F0 0A              BEQ TOGL1       ;FLAG IS OFF ,SO TURN ON
1129   E6EC A9 00              LDA #0          ;FLAG IS ON ,SO TURN OFF
1130   E6EE 9D 00 A4           STA MONRAM,X
1131   E6F1 A0 24       BRK3   LDY #M7-M1      ;PRINT "OFF"
1132   E6F3 4C AF E7    BRK2   JMP KEP
1133   E6F6 38          TOGL1  SEC             ;TURN FLAG ON BY SETTING NON-ZERO
1134   E6F7 7E 00 A4           ROR MONRAM,X    ;FLAG IS ON MSB
1135   E6FA A0 21       BRK4   LDY #M6-M1      ;PRINT "ON"
1136   E6FC D0 F5              BNE BRK2
1137   E6FE
1138   E6FE             ;***** # COMMAND-CLEAR ALL BREAKS *****
1139   E6FE A9 00       CLRBK  LDA #0          ;STORE ZEROS INTO BRKPT LIST
1140   E700 A2 07              LDX #7
1141   E702 9D 00 01    RS20   STA BKS,X
1142   E705 CA                 DEX
1143   E706 10 FA              BPL RS20
1144   E708 30 E7              BMI BRK3        ;PRINT "OFF"
1145   E70A
1146   E70A             ;***** K COMMAND-DISASSEMBLE MEMORY *****
1147   E70A A9 2A       KDISA  LDA #'*'        ;GET START ADDRESS
1148   E70C 20 7A E9           JSR OUTPUT
1149   E70F 20 AE EA           JSR ADDIN
1150   E712 B0 F6              BCS KDISA       ;IF ERROR DO IT AGAIN
1151   E714 20 D7 E5           JSR CGPC0       ;GET IT INTO PROG CNTR
1152   E717 20 37 E8           JSR PSL1        ;PRINT "/"
1153   E71A 20 85 E7           JSR GCNT        ;GET COUNT
1154   E71D 20 24 EA           JSR CRCK
1155   E720 4C 2B E7           JMP JD2
1156   E723 20 07 E9    JD1    JSR RCHEK       ;SEE IF HE WANTS TO INTERRUPT
1157   E726 20 90 E7           JSR DONE
1158   E729 F0 17              BEQ JD4
1159   E72B 20 6C F4    JD2    JSR DISASM      ;GO TO DISASSEMBLER
1160   E72E AD 25 A4           LDA SAVPC       ;POINT TO NEXT INSTRUC LOCAT
1161   E731 38                 SEC             ;ONE MORE TO PROG CNTR
1162   E732 65 EA              ADC LENGTH
1163   E734 8D 25 A4           STA SAVPC
1164   E737 90 03              BCC JD3
1165   E739 EE 26 A4           INC SAVPC+1
1166   E73C 20 24 EA    JD3    JSR CRCK        ;<CR>
1167   E73F 4C 23 E7           JMP JD1
1168   E742 60          JD4    RTS
1169   E743
1170   E743             ;INITIALIZATION TABLE FOR 6522
1171   E743 340037FF25FFINTAB1 .DB $34,$00,$37,$FF,$25,$FF,$25,$FF
1171   E749 25FF
1172   E74B FF FF 00 00        .DB $FF,$FF,$00,T1I+T2I
1173   E74F E1 FF 7F           .DB MOFF+PRST+SP12,$FF,$7F
1174   E752             ;INITIALIZATION TABLE FOR 6532
1175   E752 FF FF 00 00 INTAB2 .DB $FF,$FF,$00,$00
1176   E756             ;INITIALIZATION TABLE FOR MONITOR RAM
1177   E756 7BE054E105EFINTAB3 .DW NMIV3,IRQV3,OUTDIS
1178   E75C C70802CA0380       .DB $C7,$08,$02,$CA,$03,$80,$00,$00
1178   E762 0000
1179   E764 00800D0D0000       .DB $00,$80,$0D,$0D,$00,$00,$00
1179   E76A 00
1180   E76B             ;SEE IF WE HIT A SOFT BREAKPOINT (PART OF NMV3)
1181   E76B A2 07       CKB    LDX #7          ;COMPARE BRKPT LIST TO TRAP ADDR
1182   E76D BD 00 01    CKB2   LDA BKS,X       ;GET ADDRESS OF NEXT BREAKPOINT
1183   E770 CA                 DEX
1184   E771 CD 26 A4           CMP SAVPC+1     ;COMPARE TO SAVED PROGRAM COUNTER
1185   E774 D0 0A              BNE CKB1
1186   E776 BD 00 01           LDA BKS,X
1187   E779 CD 25 A4           CMP SAVPC
1188   E77C D0 02              BNE CKB1        ;NO MATCH SO TRY NEXT BREAKPOINT
1189   E77E 38                 SEC             ;MATCH-SET MATCH FLAG
1190   E77F 60                 RTS
1191   E780 CA          CKB1   DEX
1192   E781 10 EA              BPL CKB2        ;MORE TO GO
1193   E783 18                 CLC             ;NO MATCH -RESET MATCH FLAG
1194   E784 60                 RTS
1195   E785
1196   E785             ;GET # OF LINES COUNT FOR GO-COMMAND,LIST-COMM
1197   E785 20 5D EA    GCNT   JSR RD2
1198   E788 90 02              BCC GCN1
1199   E78A 49 0C              EOR #$0C        ;<SPACE>---> $2C ,<CR>---> $01
1200   E78C 8D 19 A4    GCN1   STA COUNT
1201   E78F 60                 RTS
1202   E790
1203   E790             ;CHECK IF COUNT HAS REACHED ZERO
1204   E790             ;COUNT=$2C MEANS FOREVER
1205   E790 AD 19 A4    DONE   LDA COUNT       ;IF COUNT=0 WE ARE DONE
1206   E793 C9 2C              CMP #$2C        ;THIS MEANS FOR EVER
1207   E795 F0 09              BEQ DON1        ;SET ACC DIFF FROM ZERO
1208   E797 F8                 SED             ;DECREMENT COUNT IN DECIMAL
1209   E798 38                 SEC
1210   E799 E9 01              SBC #1
1211   E79B D8                 CLD
1212   E79C 8D 19 A4           STA COUNT
1213   E79F 60                 RTS
1214   E7A0 A9 2C       DON1   LDA #$2C
1215   E7A2 60                 RTS
1216   E7A3
1217   E7A3 A0 00       FROM   LDY #0          ;PRINT "FR="
1218   E7A5 F0 02              BEQ TO1
1219   E7A7
1220   E7A7 A0 05       TO     LDY #M3-M1      ;PRINT "TO="
1221   E7A9 20 AF E7    TO1    JSR KEP
1222   E7AC 4C B1 EA           JMP ADDNE       ;GET ADDRESS
1223   E7AF
1224   E7AF             ;PRINT MSG POINTED TO BY Y REG
1225   E7AF B9 00 E0    KEP    LDA M1,Y
1226   E7B2 48                 PHA
1227   E7B3 29 7F              AND #$7F        ;STRIP OFF MSB
1228   E7B5 20 7A E9           JSR OUTPUT
1229   E7B8 C8                 INY
1230   E7B9 68                 PLA
1231   E7BA 10 F3              BPL KEP         ;MSB =1 ?
1232   E7BC 60                 RTS
1233   E7BD
1234   E7BD             ;PRINT "*" ,BUT NOT TO TAPE RECORDER, NOR LOADING....
1235   E7BD             ;PAPER TAPE OR TO DISPLAY
1236   E7BD AD 12 A4    PROMPT LDA INFLG       ;WHICH DEV (FOR EDITOR)
1237   E7C0 C9 54              CMP #'T'        ;NO PROMPT IF "T" OR "L"
1238   E7C2 4C EF FE           JMP PATC11
1239   E7C5 20 42 E8    PROMP1 JSR TTYTST      ;PROMPT ONLY TO TTY
1240   E7C8 D0 05              BNE PR2         ;BRANCH ON KB
1241   E7CA A9 2A              LDA #'*'
1242   E7CC 4C 7A E9    PR1    JMP OUTPUT      ;ONLY TO TERMIN
1243   E7CF A9 0D       PR2    LDA #CR         ;CLR DISP
1244   E7D1 4C 05 EF           JMP OUTDIS
1245   E7D4
1246   E7D4 A9 3F       QM     LDA #'?'        ;PRINT "?"
1247   E7D6 D0 F4              BNE PR1
1248   E7D8
1249   E7D8 A9 3D       EQUAL  LDA #'='        ;PRINT "="
1250   E7DA D0 F0              BNE PR1
1251   E7DC
1252   E7DC             ;ON DELETE KEY OUTPUT SLASH IF TTY & ....
1253   E7DC             ;BACK UP CURSOR IF KB (MAY NEED SCROLLING)
1254   E7DC 20 42 E8    PSLS   JSR TTYTST      ;TTY OR KB ?
1255   E7DF F0 56              BEQ PSL1        ;BRANCH ON TTY
1256   E7E1 20 9E EB           JSR PHXY        ;SAVE X,Y
1257   E7E4 CE 15 A4           DEC CURPO2      ;DECR DISP PNTR
1258   E7E7 AE 15 A4           LDX CURPO2
1259   E7EA E0 14              CPX #20         ;IF MORE THAN 20 JUST SCROLL THEM
1260   E7EC B0 0D              BCS PSL0
1261   E7EE A9 20              LDA #' '        ;< 20 ,SO CLR CUR
1262   E7F0 20 02 EF           JSR OUTDP1
1263   E7F3 CE 15 A4           DEC CURPO2
1264   E7F6 4C 02 E8           JMP PSL00
1265   E7F9 EA                 NOP
1266   E7FA EA                 NOP
1267   E7FB 20 F8 FE    PSL0   JSR PATC12      ;CLR PRIFLG
1268   E7FE CA                 DEX             ;ONE CHR LESS
1269   E7FF 20 2F EF           JSR OUTD2A      ;SCROLL THEM
1270   E802 AD 15 A4    PSL00  LDA CURPO2      ;DISBUF---> PRIBUFF
1271   E805 C9 15              CMP #21
1272   E807 90 13              BCC PSL0B
1273   E809 C9 29              CMP #41
1274   E80B 90 07              BCC PSL0A
1275   E80D A0 28              LDY #40         ;CHR 40-59
1276   E80F E9 28              SBC #40
1277   E811 4C 1E E8           JMP PSL0C
1278   E814 A0 14       PSL0A  LDY #20         ;CHR 20-39
1279   E816 38                 SEC
1280   E817 E9 14              SBC #20
1281   E819 4C 1E E8           JMP PSL0C
1282   E81C A0 00       PSL0B  LDY #0          ;CHR 00-19
1283   E81E 8D 16 A4    PSL0C  STA CURPOS
1284   E821 A2 00              LDX #0
1285   E823 B9 38 A4    PSL0D  LDA DIBUFF,Y    ;TRANSFER THEM
1286   E826 9D 60 A4           STA IBUFM,X
1287   E829 E8                 INX
1288   E82A C8                 INY
1289   E82B EC 16 A4           CPX CURPOS      ;PRI PNTR
1290   E82E 90 F3              BCC PSL0D
1291   E830 20 38 F0           JSR OUTPR       ;CLR PRI BUFF TO THE RIGHT
1292   E833 20 AC EB           JSR PLXY        ;RESTORE X,Y
1293   E836 60                 RTS
1294   E837 A9 2F       PSL1   LDA #'/'        ;PRINT "/"
1295   E839 D0 91              BNE PR1
1296   E83B
1297   E83B 20 3E E8    BLANK2 JSR BLANK       ;TWO SPACES
1298   E83E A9 20       BLANK  LDA #' '
1299   E840 D0 8A              BNE PR1
1300   E842
1301   E842             ;CHECK TTY/KBD SWITCH (Z=1 FOR TTY)
1302   E842 A9 08       TTYTST LDA #$08        ;CHECK IF TTY OR KB
1303   E844 2C 00 A8           BIT DRB         ;TTY OR KB SWICTH =PB3
1304   E847 60                 RTS
1305   E848
1306   E848             ;WHERE IS INPUT COMING FROM?
1307   E848             ;SET UP FOR INPUT ACTIVE DEVICE
1308   E848 A0 2A       WHEREI LDY #M9-M1      ;PRINT "IN"
1309   E84A 20 70 E9           JSR KEPR        ;OUTPUT MSG AND INPUT CHR
1310   E84D 8D 12 A4           STA INFLG
1311   E850 C9 54              CMP #'T'
1312   E852 D0 08              BNE WHE1
1313   E854 A2 00              LDX #0          ;FOR INPUT FILE FLG
1314   E856 20 A2 E8           JSR FNAM        ;OPEN FILE FOR TAPE (1 OR 2)
1315   E859 4C 2F E3           JMP LOADTA      ;GET FILE
1316   E85C C9 4B       WHE1   CMP #'K'        ;TAPE WITH KIM FORMAT
1317   E85E D0 08              BNE WHE2
1318   E860 A2 00              LDX #0          ;FOR INPUT FILE FLG
1319   E862 20 A2 E8           JSR FNAM        ;OPEN FILE FOR TAP (1 OR 2)
1320   E865 4C A4 E3           JMP LOADKI      ;THE WHOLE FILE
1321   E868 C9 55       WHE2   CMP #'U'        ;USER RTN?
1322   E86A D0 04              BNE WHE3
1323   E86C 18                 CLC             ;SET FLG FOR INITIALIZATION
1324   E86D 6C 08 01           JMP (UIN)       ;USER INPUT SETUP
1325   E870 60          WHE3   RTS
1326   E871
1327   E871             ;WHERE IS OUTPUT GOING TO?
1328   E871             ;SET UP FOR OUTPUT ACTIVE DEVICE
1329   E871 A0 2D       WHEREO LDY #M10-M1     ;PRINT "OUT"
1330   E873 20 70 E9           JSR KEPR        ;OUTPUT MSG & INPUT CHR
1331   E876 8D 13 A4           STA OUTFLG      ;DEVICE FLG
1332   E879             ;TAPES
1333   E879 C9 54              CMP #'T'
1334   E87B D0 08              BNE WHRO1
1335   E87D A2 01              LDX #1          ;FOR OUTPUT FILE FLG
1336   E87F 20 A2 E8           JSR FNAM        ;FILENAME & TAPE (1 OR 2)
1337   E882 4C 6F E5           JMP DUMPTA      ;INITIALIZE FILE
1338   E885 C9 4B       WHRO1  CMP #'K'        ;TAPE WITH KIM FORMAT
1339   E887 D0 05              BNE WHRO2
1340   E889 A2 01              LDX #1          ;FOR OUTPUT FILE FLG
1341   E88B 4C A2 E8           JMP FNAM
1342   E88E             ;PRINTER
1343   E88E C9 50       WHRO2  CMP #'P'        ;PRINTER?
1344   E890 D0 05              BNE WHRO3
1345   E892 A9 0D              LDA #CR         ;OUTPUT LAST LINE IF ON
1346   E894 4C 00 F0           JMP OUTPRI      ;& CLEAR PRINTER PTR
1347   E897             ;USER SET UP
1348   E897 C9 55       WHRO3  CMP #'U'        ;USR RTN?
1349   E899 D0 04              BNE WHRO4
1350   E89B 18                 CLC             ;CLR FLG FOR INITIALIZATION
1351   E89C 6C 0A 01           JMP (UOUT)      ;USER OUTPUT SETUP
1352   E89F             ;ANY OTHER
1353   E89F 4C 13 EA    WHRO4  JMP CRLOW
1354   E8A2
1355   E8A2             ;GET FILE NAME & TAPE UNIT
1356   E8A2 20 9E EB    FNAM   JSR PHXY        ;SAVE IN/OUT FLG (X)
1357   E8A5 20 CF E8           JSR NAMO        ;GET NAME
1358   E8A8 A0 50       WHICHT LDY #TMSG2-M1   ;PRINT "T="
1359   E8AA 20 70 E9           JSR KEPR        ;OUTPUT MSG & INPUT CHR
1360   E8AD C9 0D              CMP #CR
1361   E8AF D0 02              BNE TAP1
1362   E8B1 A9 31              LDA #'1'        ;<CR> ==> TAPE 1
1363   E8B3 38          TAP1   SEC
1364   E8B4 E9 31              SBC #'1'        ;SUBTRACT 31
1365   E8B6 30 04              BMI TAP2        ;ONLY 1,2 OK
1366   E8B8 C9 02              CMP #2
1367   E8BA 30 06              BMI TAP3        ;OK
1368   E8BC 20 D4 E7    TAP2   JSR QM          ;ERROR
1369   E8BF 4C A8 E8           JMP WHICHT
1370   E8C2 20 AC EB    TAP3   JSR PLXY        ;IN/OUT FLG
1371   E8C5 9D 34 A4           STA TAPIN,X     ;IF X=0 --> TAPIN (TAPE 1 OR 2)
1372   E8C8 20 83 FE           JSR CUREAD      ;GET ANYTHING
1373   E8CB 20 24 EA           JSR CRCK        ;<CR>
1374   E8CE 60                 RTS             ;IF X=1 --> TAPOUT (TAPE 1 OR 2)
1375   E8CF
1376   E8CF             ;GET FILE NAME
1377   E8CF A0 4D       NAMO   LDY #TMSG1-M1   ;PRINT "F="
1378   E8D1 20 AF E7           JSR KEP         ;NO CRLF
1379   E8D4 A0 00              LDY #0
1380   E8D6 20 5F E9    NAMO1  JSR RDRUP       ;GET CHAR
1381   E8D9 C9 0D              CMP #CR         ;DONE?
1382   E8DB F0 0C              BEQ NAMO2
1383   E8DD C9 20              CMP #' '
1384   E8DF F0 08              BEQ NAMO2
1385   E8E1 99 2E A4           STA NAME,Y      ;STORE
1386   E8E4 C8                 INY
1387   E8E5 C0 05              CPY #5
1388   E8E7 D0 ED              BNE NAMO1
1389   E8E9             ;BLANK REST OF NAME
1390   E8E9 A9 20       NAMO2  LDA #' '
1391   E8EB C0 05       NAMO3  CPY #5
1392   E8ED F0 06              BEQ NAMO4
1393   E8EF 99 2E A4           STA NAME,Y
1394   E8F2 C8                 INY
1395   E8F3 D0 F6              BNE NAMO3
1396   E8F5 4C 3E E8    NAMO4  JMP BLANK
1397   E8F8
1398   E8F8             ;SET INPUT FROM TERMINAL (KB OR TTY)
1399   E8F8 A9 0D       INLOW  LDA #CR
1400   E8FA 8D 12 A4           STA INFLG
1401   E8FD 60                 RTS
1402   E8FE
1403   E8FE             ;SET I/O  TO TERMINAL (KB & D/P ,OR TTY)
1404   E8FE 20 F8 E8    LL     JSR INLOW
1405   E901
1406   E901             ;SET OUTPUT TO TERMINAL (D/P OR TTY)
1407   E901 A9 0D       OUTLOW LDA #CR
1408   E903 8D 13 A4           STA OUTFLG
1409   E906 60          OUTL1  RTS
1410   E907
1411   E907             ;ON <ESCAPE> STOPS EXECUTION & BACK TO MONITOR
1412   E907             ;ON <SPACE> STOPS EXECUTION & CONTINUE ON ANY OTHER KEY
1413   E907 20 42 E8    RCHEK  JSR TTYTST      ;TTY OR KB ?
1414   E90A F0 1A              BEQ RCHTTY
1415   E90C 20 EF EC           JSR ROONEK      ;CLR MSK & GET A KEY
1416   E90F 88                 DEY
1417   E910 30 13              BMI RCH3        ;RTN ON NO KEY
1418   E912 A2 00              LDX #0
1419   E914 20 82 EC           JSR GETK2       ;GET THE KEY
1420   E917 C9 1B              CMP #ESCAPE
1421   E919 F0 3B              BEQ REA1        ;TO COMMAN & SET I/O TO TERMINAL
1422   E91B C9 20              CMP #' '        ;WAIT KEY
1423   E91D D0 06              BNE RCH3        ;RTN, IGNORE OTHER KEYS
1424   E91F 20 EF EC    RCH2   JSR ROONEK      ;WAIT TILL HE RELEASE IT &
1425   E922 88                 DEY             ;QUIT WAITING ON NEXT KEY
1426   E923 30 FA              BMI RCH2
1427   E925 60          RCH3   RTS
1428   E926 70 13       RCHTTY BVS RCHT1       ;TTI=PB6 ---> V (OVERFL FLG)
1429   E928 2C 00 A8    RCHT2  BIT DRB         ;WAIT TILL HE RELEASE IT
1430   E92B 50 FB              BVC RCHT2
1431   E92D 20 0F EC           JSR DELAY
1432   E930 20 DB EB           JSR GETTTY      ;GET A CHAR
1433   E933 C9 1B              CMP #ESCAPE
1434   E935 F0 1F              BEQ REA1        ;TO COMMAN
1435   E937 C9 20              CMP #' '
1436   E939 D0 ED              BNE RCHT2
1437   E93B 60          RCHT1  RTS             ;QUIT WAITING ON ANY KEY
1438   E93C
1439   E93C             ;READ ONE CHAR FROM KB/TTY & PRESERVE X,Y
1440   E93C 20 9E EB    READ   JSR PHXY        ;PUSH X & Y
1441   E93F 20 42 E8           JSR TTYTST      ;TTY OR KB ?
1442   E942 D0 06              BNE READ1
1443   E944 20 DB EB           JSR GETTTY
1444   E947 4C 4D E9           JMP READ2
1445   E94A 20 40 EC    READ1  JSR GETKEY
1446   E94D 20 AC EB    READ2  JSR PLXY        ;PULL X & Y
1447   E950 29 7F              AND #$7F        ;STRIP PARITY
1448   E952 C9 1B              CMP #ESCAPE
1449   E954 D0 E5              BNE RCHT1       ;RTN
1450   E956 20 3D FF    REA1   JSR PATC18      ;<CR> & CLR BUFFERS
1451   E959 4C A1 E1           JMP COMIN       ;BOTH I/O TO TERMINAL
1452   E95C
1453   E95C             ;READ WITH RUBOUT OR DELETE POSSIBLE
1454   E95C 20 DC E7    RB2    JSR PSLS        ;SLASH OR BACK SPACE
1455   E95F 20 83 FE    RDRUP  JSR CUREAD
1456   E962 C9 08              CMP #RUB        ;RUBOUT
1457   E964 F0 04              BEQ RDR1
1458   E966 C9 7F              CMP #$7F        ;ALSO DELETE
1459   E968 D0 0C              BNE RED2        ;ECHO IF NOT <CR>
1460   E96A             ;RUBOUT TO DELETE CHAR
1461   E96A 88          RDR1   DEY
1462   E96B 10 EF              BPL RB2
1463   E96D C8                 INY
1464   E96E F0 EF              BEQ RDRUP
1465   E970
1466   E970             ;OUTPUT MESSAGE THEN INPUT CHR
1467   E970 20 AF E7    KEPR   JSR KEP
1468   E973
1469   E973             ;READ AND ECHO A CHAR FROM KB OR TTY
1470   E973 20 83 FE    REDOUT JSR CUREAD
1471   E976 C9 0D       RED2   CMP #CR
1472   E978 F0 C1              BEQ RCHT1       ;DO NOT ECHO <CR>
1473   E97A
1474   E97A             ;OUTPUTS A CHAR TO EITHER TTY OR D/P
1475   E97A 48          OUTPUT PHA             ;SAVE IT
1476   E97B AD 11 A4    OUT1   LDA PRIFLG      ;IF LSB=1 OUTPUT ONLY TO DISP
1477   E97E 29 01              AND #$01
1478   E980 F0 04              BEQ OUT1A
1479   E982 68                 PLA
1480   E983 4C 02 EF           JMP OUTDP1      ;ONLY TO DISPL
1481   E986 20 42 E8    OUT1A  JSR TTYTST      ;TTY OR KB ?
1482   E989 D0 04              BNE OUT2
1483   E98B 68                 PLA
1484   E98C 4C A8 EE           JMP OUTTTY      ;TO TTY
1485   E98F 68          OUT2   PLA
1486   E990 4C FC EE           JMP OUTDP       ;TO DISP & PRINTR
1487   E993
1488   E993             ;GET A CHR FROM CURRENT INPUT DEVICE (SET ON INFLG)
1489   E993 AD 12 A4    INALL  LDA INFLG
1490   E996 C9 54              CMP #'T'
1491   E998 D0 03              BNE *+5
1492   E99A 4C 3B ED           JMP TIBYTE      ;CHAR FROM BUFFER
1493   E99D C9 4B              CMP #'K'        ;WITH KIM FORMAT
1494   E99F D0 03              BNE *+5
1495   E9A1 4C 29 EE           JMP GETTAP      ;DIRECTLY FROM TAPE
1496   E9A4 C9 4D              CMP #'M'        ;MEMORY FOR ASM?
1497   E9A6 D0 03              BNE *+5
1498   E9A8 4C D0 FA           JMP MREAD
1499   E9AB C9 55              CMP #'U'        ;USER ROUTINE?
1500   E9AD D0 04              BNE *+6
1501   E9AF 38                 SEC             ;SET FLG FOR NORMAL INPUT
1502   E9B0 6C 08 01           JMP (UIN)
1503   E9B3 C9 4C              CMP #'L'        ;TO LOAD PPR TAPE
1504   E9B5 D0 A8              BNE RDRUP
1505   E9B7 4C DB EB           JMP GETTTY      ; FROM TTY
1506   E9BA
1507   E9BA             ;.FILE A2
1508   E9BA A9 3B       SEMI   LDA #SEMICOLON  ;OUTPUT A ";"
1509   E9BC             ;WRITE A CHR TO OUTPUT DEVICE (SET ON OUTFLG)
1510   E9BC 48          OUTALL PHA
1511   E9BD AD 13 A4           LDA OUTFLG
1512   E9C0             ;TAPE BY BLOCKS
1513   E9C0 C9 54              CMP #'T'        ;TAPES ?
1514   E9C2 D0 04              BNE OUTA1
1515   E9C4 68                 PLA
1516   E9C5 4C 8B F1           JMP TOBYTE      ;OUTPUT ONE CHAR TO TAPE BUFFER
1517   E9C8             ;TAPE KIM FORMAT
1518   E9C8 C9 4B       OUTA1  CMP #'K'        ;KIM-1 ?
1519   E9CA D0 04              BNE OUTA2
1520   E9CC 68                 PLA
1521   E9CD 4C 4A F2           JMP OUTTAP
1522   E9D0             ;PRINTER
1523   E9D0 C9 50       OUTA2  CMP #'P'        ;PRINTER ?
1524   E9D2 D0 0E              BNE OUTA3
1525   E9D4 38                 SEC             ;TURN PRINTER ON
1526   E9D5 6E 11 A4           ROR PRIFLG
1527   E9D8 68                 PLA
1528   E9D9 08                 PHP
1529   E9DA 20 00 F0           JSR OUTPRI
1530   E9DD 28                 PLP
1531   E9DE 2E 11 A4           ROL PRIFLG      ;RESTORE FLG
1532   E9E1 60                 RTS
1533   E9E2             ;USER DEFINED
1534   E9E2 C9 55       OUTA3  CMP #'U'        ;USER ROUTINE?
1535   E9E4 D0 04              BNE OUTA4
1536   E9E6 38                 SEC             ;SET FLG FOR NORMAL OUTPUT
1537   E9E7 6C 0A 01           JMP (UOUT)      ;YES
1538   E9EA             ;NOWHERE OR TO TTY ,D/P
1539   E9EA C9 58       OUTA4  CMP #'X'        ;EAT IT?
1540   E9EC D0 8D              BNE OUT1        ;OUTPUT TO TTY OR D/P
1541   E9EE 68                 PLA
1542   E9EF 60                 RTS
1543   E9F0
1544   E9F0             ;THIS ROUTINE OUTPUTS A CRLF TO ANY OUTPUT DEV
1545   E9F0             ;LF AND NULL IS SENT ONLY TO TTY
1546   E9F0 A9 0D       CRLF   LDA #CR
1547   E9F2 20 BC E9           JSR OUTALL
1548   E9F5 20 42 E8           JSR TTYTST      ;TTY OR KB ?
1549   E9F8 D0 29              BNE CR2J
1550   E9FA AD 13 A4           LDA OUTFLG      ;LF ONLY TO TTY
1551   E9FD C9 54              CMP #'T'
1552   E9FF F0 22              BEQ CR2J
1553   EA01 C9 4B              CMP #'K'
1554   EA03 F0 1E              BEQ CR2J
1555   EA05 C9 50              CMP #'P'
1556   EA07 F0 1A              BEQ CR2J
1557   EA09 A9 0A              LDA #LF
1558   EA0B 20 BC E9           JSR OUTALL
1559   EA0E A9 FF              LDA #NULLC
1560   EA10 4C BC E9           JMP OUTALL
1561   EA13
1562   EA13             ;CRLF TO TERMINAL (TTY OR D/P) ONLY
1563   EA13 48          CRLOW  PHA             ;SAVE A
1564   EA14 AD 13 A4           LDA OUTFLG
1565   EA17 48                 PHA
1566   EA18 20 01 E9           JSR OUTLOW
1567   EA1B 20 F0 E9           JSR CRLF
1568   EA1E 68                 PLA
1569   EA1F 8D 13 A4           STA OUTFLG
1570   EA22 68                 PLA
1571   EA23 60          CR2J   RTS
1572   EA24
1573   EA24             ;OUTPUT <CR> TO TTY IF SWITCH ON TTY & INFLG NOT L
1574   EA24             ;DONT CLR DISPLAY BUT CLEARS PNTRS FOR NEXT LINE
1575   EA24             ;IF PRNTR HAS PRINTED ON 21RST CHR DONT OUTPUT <CR>
1576   EA24 AD 12 A4    CRCK   LDA INFLG       ;NO <CR> IF "L"
1577   EA27 C9 4C              CMP #'L'
1578   EA29 D0 01              BNE CRCK1
1579   EA2B 60                 RTS
1580   EA2C 20 42 E8    CRCK1  JSR TTYTST      ;CHECK IF TTY OR KB
1581   EA2F F0 E2              BEQ CRLOW       ;BRNCH IF TTY
1582   EA31             ;IF PRINTR PTR=0 ,DO NOT CLR PRI
1583   EA31 AD 16 A4           LDA CURPOS
1584   EA34 F0 05              BEQ CRCK2       ;IF PTR=0 ,NO <CR>
1585   EA36 A9 0D              LDA #CR
1586   EA38 20 00 F0           JSR OUTPRI
1587   EA3B A9 8D       CRCK2  LDA #CR+$80     ;<CR> ONLY FOR TV
1588   EA3D 4C 02 EF           JMP OUTDP1
1589   EA40 EA                 NOP
1590   EA41 EA                 NOP
1591   EA42
1592   EA42             ;WRITE A THEN X IN ASCII TO THE OUTPUT DEV
1593   EA42 20 46 EA    WRAX   JSR NUMA
1594   EA45 8A                 TXA
1595   EA46
1596   EA46             ;PRINT ONE BYTE=TWO ASCII CHARS TO OUTPUT DEVICE
1597   EA46 48          NUMA   PHA
1598   EA47 4A                 LSR A
1599   EA48 4A                 LSR A
1600   EA49 4A                 LSR A
1601   EA4A 4A                 LSR A
1602   EA4B 20 51 EA           JSR NOUT
1603   EA4E 68                 PLA
1604   EA4F 29 0F              AND #$F
1605   EA51 18          NOUT   CLC
1606   EA52 69 30              ADC #'0'
1607   EA54 C9 3A              CMP #'9'+1
1608   EA56 90 02              BCC LT10
1609   EA58 69 06              ADC #6          ;CARRY IS SET
1610   EA5A 4C BC E9    LT10   JMP OUTALL
1611   EA5D
1612   EA5D             ;READ TWO CHR & PACK THEM INTO ONE BYTE
1613   EA5D             ;PART OF ALTER MEMORY , / COMM
1614   EA5D 20 73 E9    RD2    JSR REDOUT
1615   EA60 C9 0D              CMP #CR         ;<CR>?
1616   EA62 F0 17              BEQ RSPAC
1617   EA64 C9 20              CMP #' '        ;FOR MEMORY ALTER
1618   EA66 F0 13              BEQ RSPAC
1619   EA68 C9 2E              CMP #'.'        ;TREAT "." AS <SPACE>
1620   EA6A D0 04              BNE RD1
1621   EA6C A9 20              LDA #' '
1622   EA6E D0 0B              BNE RSPAC
1623   EA70 20 84 EA    RD1    JSR PACK
1624   EA73 B0 06              BCS RSPAC
1625   EA75 20 73 E9           JSR REDOUT
1626   EA78 4C 84 EA           JMP PACK
1627   EA7B             ;WAS SPACE OR <CR>
1628   EA7B 38          RSPAC  SEC
1629   EA7C 60                 RTS
1630   EA7D
1631   EA7D             ;CONVERT ACC IN ASCII TO ACC IN HEX (4 MSB=0)
1632   EA7D 48          HEX    PHA             ;SAVE A
1633   EA7E A9 00              LDA #0          ;CLEAR STIY IF HEX
1634   EA80 8D 29 A4           STA STIY+2      ;BECAUSE ONLY ONCE
1635   EA83 68                 PLA
1636   EA84             ;PACK TWO ASCII INTO ONE HEX (CALL SUBR TWO TIMES)
1637   EA84             ;RESULT IS GIVEN ON ACC WITH FIRST CHR INTO 4 MSB
1638   EA84 C9 30       PACK   CMP #'0'        ;< 30 ?
1639   EA86 90 F3              BCC RSPAC
1640   EA88 C9 47              CMP #'F'+1      ; > 47 ?
1641   EA8A B0 EF              BCS RSPAC
1642   EA8C C9 3A              CMP #'9'+1      ; < $10
1643   EA8E 90 06              BCC PAK1
1644   EA90 C9 40              CMP #'A'-1      ; > $10 ?
1645   EA92 90 E7              BCC RSPAC
1646   EA94 69 08              ADC #8          ;ADD 9 IF LETTER (C IS SET)
1647   EA96 2A          PAK1   ROL A           ;SHIFT A 4 TIMES
1648   EA97 2A                 ROL A
1649   EA98 2A                 ROL A
1650   EA99 2A                 ROL A
1651   EA9A 8E 2D A4           STX CPIY+3      ;SAVE X
1652   EA9D A2 04              LDX #4
1653   EA9F 2A          PAK2   ROL A           ;TRANSFER A TO STIY
1654   EAA0 2E 29 A4           ROL STIY+2      ; THRU CARRY
1655   EAA3 CA                 DEX
1656   EAA4 D0 F9              BNE PAK2
1657   EAA6 AE 2D A4           LDX CPIY+3      ;REST X
1658   EAA9 AD 29 A4           LDA STIY+2
1659   EAAC 18                 CLC
1660   EAAD 60                 RTS
1661   EAAE
1662   EAAE             ;GET FOUR BYTE ADDR ,TAKE LAST FOUR CHR TO...
1663   EAAE             ;CALCULATE ADDR .ALLOW DELETE ALSO
1664   EAAE 20 D8 E7    ADDIN  JSR EQUAL
1665   EAB1 AD 15 A4    ADDNE  LDA CURPO2      ;SAVE POSITION
1666   EAB4 48                 PHA
1667   EAB5 A0 00              LDY #0
1668   EAB7 20 5F E9    ADDN1  JSR RDRUP
1669   EABA C9 0D              CMP #CR
1670   EABC F0 09              BEQ ADDN2
1671   EABE C9 20              CMP #' '
1672   EAC0 F0 05              BEQ ADDN2
1673   EAC2 C8                 INY
1674   EAC3 C0 0B              CPY #11         ;ALLOW 10
1675   EAC5 90 F0              BCC ADDN1
1676   EAC7 68          ADDN2  PLA
1677   EAC8 8D 2D A4           STA CPIY+3      ;SAVE
1678   EACB C0 00              CPY #0          ;IF FIRST CHR PUT DEFAULT VALUES
1679   EACD D0 0D              BNE ADDN3
1680   EACF A9 02              LDA #$02
1681   EAD1 8D 1D A4           STA ADDR+1      ;DEFAULT OF 0200
1682   EAD4 8D 1E A4           STA CKSUM       ;DEFAULT
1683   EAD7 8C 1C A4           STY ADDR
1684   EADA 18                 CLC
1685   EADB 60                 RTS
1686   EADC A2 00       ADDN3  LDX #0
1687   EADE 88                 DEY             ;Y-4
1688   EADF 88                 DEY
1689   EAE0 88                 DEY
1690   EAE1 88                 DEY
1691   EAE2 10 13              BPL ADDN5       ;BRANCH IF > 4 CHR
1692   EAE4 98                 TYA
1693   EAE5 49 FF              EOR #$FF
1694   EAE7 A8                 TAY             ;# OF LEADING 0
1695   EAE8 A9 30       ADDN4  LDA #$30
1696   EAEA 9D 1C A4           STA ADDR,X
1697   EAED E8                 INX
1698   EAEE 88                 DEY
1699   EAEF 10 F7              BPL ADDN4
1700   EAF1 AC 2D A4           LDY CPIY+3      ;NOW THE CHR
1701   EAF4 4C FD EA           JMP ADDN6
1702   EAF7 98          ADDN5  TYA             ;PUT CHR
1703   EAF8 18                 CLC
1704   EAF9 6D 2D A4           ADC CPIY+3
1705   EAFC A8                 TAY
1706   EAFD B9 38 A4    ADDN6  LDA DIBUFF,Y    ;FROM DISP BUFF
1707   EB00 9D 1C A4           STA ADDR,X
1708   EB03 C8                 INY
1709   EB04 E8                 INX
1710   EB05 E0 04              CPX #4
1711   EB07 D0 F4              BNE ADDN6
1712   EB09 A2 01              LDX #1
1713   EB0B A0 00              LDY #0          ;CNVRT CHR TO HEX
1714   EB0D B9 1C A4    ADDN7  LDA ADDR,Y
1715   EB10 20 7D EA           JSR HEX
1716   EB13 B0 16              BCS ADDN8
1717   EB15 C8                 INY
1718   EB16 B9 1C A4           LDA ADDR,Y
1719   EB19 C8                 INY
1720   EB1A 20 84 EA           JSR PACK        ;PACK TWO CHRS INTO 1 BYTE
1721   EB1D B0 0C              BCS ADDN8       ;BRCNH IF ERROR
1722   EB1F 9D 1C A4           STA ADDR,X
1723   EB22 CA                 DEX
1724   EB23 10 E8              BPL ADDN7
1725   EB25 E8                 INX             ;X=0
1726   EB26 8E 1E A4           STX CKSUM       ;TO INDICATE WE GOT AN ADDR
1727   EB29 18                 CLC             ;NO INVALID CHARS
1728   EB2A 60                 RTS
1729   EB2B 20 94 E3    ADDN8  JSR CKER00      ;OUTPUT ERROR MSG
1730   EB2E 20 24 EA           JSR CRCK        ;<CR>
1731   EB31 38                 SEC             ;SET CARRY FOR INVALID CHR
1732   EB32 60                 RTS
1733   EB33
1734   EB33             ;MEMORY FAIL TO WRITE MSG & SPECIFIC ADDRESS
1735   EB33 20 24 EA    MEMERR JSR CRCK
1736   EB36 20 CD E2           JSR NXTADD      ;ADD Y TO ADDR+1,ADDR
1737   EB39 A0 31              LDY #M11-M1     ;PRINT "MEM FAIL"
1738   EB3B 20 AF E7           JSR KEP         ;FAIL MSG
1739   EB3E 20 DB E2           JSR WRITAZ      ;PRINT ADDR+1 , ADDR
1740   EB41 4C A1 E1           JMP COMIN
1741   EB44
1742   EB44             ;CLEAR DISPLAY & PRINTER POINTERS
1743   EB44 A9 00       CLR    LDA #0
1744   EB46 8D 15 A4           STA CURPO2      ;DISP PNTR
1745   EB49 8D 16 A4           STA CURPOS      ;PRINTR PNTR
1746   EB4C 60                 RTS
1747   EB4D
1748   EB4D             ;CLEAR CKSUM
1749   EB4D A9 00       CLRCK  LDA #0
1750   EB4F 8D 1F A4           STA CKSUM+1
1751   EB52 8D 1E A4           STA CKSUM
1752   EB55 60                 RTS
1753   EB56
1754   EB56             ;CODE FOR PAGE ZERO SIMULATION
1755   EB56             ;SUBR LDAY-SIMULATES LDA (N),Y INSTR WITHOUT PAG 0
1756   EB56             ;BY PUTTING INDIR ADDR INTO RAM & THEN EXEC LDA NM,Y
1757   EB56 A9 25       PCLLD  LDA #SAVPC      ;FOR DISASSEMBLER
1758   EB58 8C 2D A4    LDAY   STY CPIY+3      ;SAVE Y
1759   EB5B A8                 TAY
1760   EB5C B9 00 A4           LDA MONRAM,Y    ;MONRAM=MONITOR RAM
1761   EB5F 8D 2B A4           STA LDIY+1
1762   EB62 B9 01 A4           LDA MONRAM+1,Y
1763   EB65 8D 2C A4           STA LDIY+2
1764   EB68 AC 2D A4           LDY CPIY+3      ;REST Y
1765   EB6B A9 B9              LDA #$B9        ;INST FOR LDA NM,Y
1766   EB6D 8D 2A A4           STA LDIY
1767   EB70 A9 60              LDA #$60        ;RTS
1768   EB72 8D 2D A4           STA LDIY+3
1769   EB75 4C 2A A4           JMP LDIY        ;START EXECUTING LDA (),Y
1770   EB78
1771   EB78             ;SUBR STORE AT ADDR & CMP WITHOUT PAG 0
1772   EB78             ;REPLACES STA (ADDR),Y  &  CMP (ADDR),Y
1773   EB78             ;LOOK THAT ADDR & ADDR+1 ARE NOT ON PAG 0
1774   EB78 48          SADDR  PHA
1775   EB79 AD 1C A4           LDA ADDR
1776   EB7C 8D 28 A4           STA STIY+1
1777   EB7F 8D 2B A4           STA CPIY+1
1778   EB82 AD 1D A4           LDA ADDR+1
1779   EB85 8D 29 A4           STA STIY+2
1780   EB88 8D 2C A4           STA CPIY+2
1781   EB8B A9 99              LDA #$99        ;STA INSTR
1782   EB8D 8D 27 A4           STA STIY
1783   EB90 A9 D9              LDA #$D9        ;CMP INSTR
1784   EB92 8D 2A A4           STA CPIY
1785   EB95 A9 60              LDA #$60        ;RTS
1786   EB97 8D 2D A4           STA LDIY+3
1787   EB9A 68                 PLA
1788   EB9B 4C 27 A4           JMP STIY        ;START EXECUTING STA (),Y
1789   EB9E
1790   EB9E             ;PUSH X & Y WITHOUT CHANGING THE REGS
1791   EB9E 8D 2D A4    PHXY   STA CPIY+3      ;SAVE ACC
1792   EBA1 98                 TYA
1793   EBA2 48                 PHA             ;PUSH Y
1794   EBA3 8A                 TXA
1795   EBA4 48                 PHA             ;PUSH X
1796   EBA5 20 BA EB           JSR SWSTAK      ;SWAP X , Y WITH RTRN ADDR FROM S`
1797   EBA8 AD 2D A4           LDA CPIY+3
1798   EBAB 60                 RTS
1799   EBAC
1800   EBAC             ;PULL X & Y WITHOUT CHANGING ACC
1801   EBAC             ;IT HAS TO BE CALLED BY JSR & NOT BY JMP INSTR
1802   EBAC             ;SINCE IT SWAPS THE STACK
1803   EBAC 8D 2D A4    PLXY   STA CPIY+3
1804   EBAF 20 BA EB           JSR SWSTAK      ;SWAP X , Y WITH RTRN ADDR FROM`
1805   EBB2 68                 PLA
1806   EBB3 AA                 TAX             ;PULL X
1807   EBB4 68                 PLA
1808   EBB5 A8                 TAY             ;PULL Y
1809   EBB6 AD 2D A4           LDA CPIY+3
1810   EBB9 60                 RTS
1811   EBBA
1812   EBBA             ;SWAP STACK
1813   EBBA BA          SWSTAK TSX
1814   EBBB A9 02              LDA #2
1815   EBBD 48          SWST1  PHA
1816   EBBE BD 06 01           LDA $0106,X     ;GET PCH OR PCL
1817   EBC1 BC 04 01           LDY $0104,X     ;GET Y OR X REGS
1818   EBC4 9D 04 01           STA $0104,X
1819   EBC7 98                 TYA
1820   EBC8 9D 06 01           STA $0106,X
1821   EBCB CA                 DEX
1822   EBCC 68                 PLA
1823   EBCD 38                 SEC
1824   EBCE E9 01              SBC #1
1825   EBD0 D0 EB              BNE SWST1
1826   EBD2 BD 08 01           LDA $0108,X     ;RESTORE Y & X FROM STACK
1827   EBD5 A8                 TAY
1828   EBD6 BD 07 01           LDA $0107,X
1829   EBD9 AA                 TAX
1830   EBDA 60                 RTS
1831   EBDB
1832   EBDB             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1833   EBDB             ;GET A CHAR FROM TTY SUBR INTO ACC ,SAVES X
1834   EBDB 8A          GETTTY TXA             ;SAVE X
1835   EBDC 48                 PHA
1836   EBDD A2 07              LDX #$07        ;SET UP FOR 8 BIT CNT
1837   EBDF 8E 2A A4           STX CPIY        ;CLR MSB
1838   EBE2 2C 00 A8    GET1   BIT DRB         ;A^M ,  PB6->V
1839   EBE5 70 FB              BVS GET1        ;WAIT FOR START BIT
1840   EBE7 20 0F EC           JSR DELAY       ;DELAY 1 BIT
1841   EBEA 20 23 EC           JSR DEHALF      ;DELAY 1/2 BIT TIME
1842   EBED AD 00 A8    GET3   LDA DRB         ;GET 8 BITS
1843   EBF0 29 40              AND #$40        ;MASK OFF OTHER BITS,ONLY PB6
1844   EBF2 4E 2A A4           LSR CPIY        ;SHIFT RIGHT CHARACTER
1845   EBF5 0D 2A A4           ORA CPIY
1846   EBF8 8D 2A A4           STA CPIY
1847   EBFB 20 0F EC           JSR DELAY       ;DELAY 1 BIT TIME
1848   EBFE CA                 DEX
1849   EBFF D0 EC              BNE GET3        ;GET NEXT BIT
1850   EC01 20 0F EC           JSR DELAY       ;DO NOT CARE FOR PARITY BIT
1851   EC04 20 23 EC           JSR DEHALF      ;UNTIL WE GET BACK TO ONE AGAIN
1852   EC07 68                 PLA             ;RESTORE X
1853   EC08 AA                 TAX
1854   EC09 AD 2A A4           LDA CPIY
1855   EC0C 29 7F              AND #$7F        ;CLEAR PARITY BIT
1856   EC0E 60                 RTS
1857   EC0F
1858   EC0F             ;DELAY 1 BIT TIME AS GIVEN BY BAUD RATE
1859   EC0F AD 18 A4    DELAY  LDA CNTL30      ;START TIMER T2
1860   EC12 8D 08 A8           STA T2L
1861   EC15 AD 17 A4           LDA CNTH30
1862   EC18 8D 09 A8    DE1    STA T2H
1863   EC1B AD 0D A8    DE2    LDA IFR         ;GET INT FLG FOR T2
1864   EC1E 29 20              AND #MT2
1865   EC20 F0 F9              BEQ DE2         ;TIME OUT ?
1866   EC22 60                 RTS
1867   EC23
1868   EC23             ;DELAY HALF BIT TIME
1869   EC23             ;TOTAL TIME DIVIDED BY 2
1870   EC23 AD 17 A4    DEHALF LDA CNTH30
1871   EC26 4A                 LSR A           ;LSB TO CARRY
1872   EC27 AD 18 A4           LDA CNTL30
1873   EC2A 6A                 ROR A           ;SHIFT WITH CARRY
1874   EC2B 8D 08 A8           STA T2L
1875   EC2E AD 17 A4           LDA CNTH30
1876   EC31 4A                 LSR A
1877   EC32 8D 09 A8           STA T2H
1878   EC35 4C 1B EC           JMP DE2
1879   EC38
1880   EC38             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
1881   EC38 A9 00       GETKD0 LDA #0
1882   EC3A 8D 77 A4           STA IDOT        ;GO ANOTHER 90 DOTS
1883   EC3D 20 50 F0           JSR IPO0        ;OUTPUT 90 DOTS TO PRI (ZEROS)
1884   EC40
1885   EC40             ;GET A CHAR FROM KB SUBROUTINE
1886   EC40             ;FROM KB Y=ROW ,STBKEY=COLUMNS (STROBE)
1887   EC40             ;X=CTRL OR SHIFT ,OTHERWISE X=0
1888   EC40 20 EF EC    GETKEY JSR ROONEK      ;WAIT IF LAST KEY STILL DOWN
1889   EC43 20 2A ED    GETKY  JSR DEBKEY      ;DEBOUNCE KEY (5 MSEC)
1890   EC46             ;CTRL OR SHIFT ?
1891   EC46 A9 8F              LDA #$8F        ;CHCK CLMN 5,6,7
1892   EC48 8D 80 A4           STA DRA2
1893   EC4B AD 82 A4           LDA DRB2        ;CHCK ROW 1
1894   EC4E 4A                 LSR A
1895   EC4F B0 20              BCS GETK1       ;IF=1 ,NO CTRL OR SHIFT
1896   EC51 A2 03              LDX #3          ;CLMN 5,6,7 (CNTRL,SHIFTL,SHIFTR)
1897   EC53 A9 7F              LDA #$7F        ;CTRL OR SHIFT ,SO WHICH ONE?
1898   EC55 38          GETK0  SEC
1899   EC56 6A                 ROR A
1900   EC57 48                 PHA
1901   EC58 20 0B ED           JSR ONEK2       ;LETS GET CTRL OR SHIFT INTO X
1902   EC5B AD 82 A4           LDA DRB2
1903   EC5E 4A                 LSR A           ;ONLY ROW 1
1904   EC5F 90 06              BCC GETK00      ;GOT YOU
1905   EC61 68                 PLA
1906   EC62 CA                 DEX
1907   EC63 D0 F0              BNE GETK0
1908   EC65 F0 DC              BEQ GETKY       ;THERE IS A MISTAKE CHECK AGAIN
1909   EC67 68          GETK00 PLA             ;NOW GET STBKEY INTO X
1910   EC68 AD 2B A4           LDA STBKEY      ;CLMN INTO X
1911   EC6B 49 FF              EOR #$FF        ;COMPLEMENT BECAUSE STRBS ARE 0
1912   EC6D AA                 TAX             ;CTRL OR SHIFT TO X
1913   EC6E EE 2A A4           INC KMASK       ;SET MSK=$01
1914   EC71             ;NOW GET ANY KEY
1915   EC71 20 05 ED    GETK1  JSR ONEKEY      ;GET A KEY
1916   EC74 88                 DEY             ;CHK THE ROW (1-8)
1917   EC75 D0 09              BNE GETK1B      ;CHK IF CTRL OR SHIFT
1918   EC77 AD 2B A4           LDA STBKEY      ;WERE ENTERED AT THE LAST MOMENT
1919   EC7A C9 F7              CMP #$F7        ;IF CLMN 5,6,7,8 TO IT AGAIN
1920   EC7C B0 04              BCS GETK2
1921   EC7E 90 C3              BCC GETKY       ;SEND IT TO GET CTRL OR SHIFT
1922   EC80 30 C1       GETK1B BMI GETKY       ;NO KEY ,CLEAR MSK
1923   EC82             ;WE HAVE A KEY ,DECODE IT
1924   EC82 20 2C ED    GETK2  JSR DEBK1       ;DEBOUNCE KEY (5 MSEC)
1925   EC85 98                 TYA             ;MULT BY 8
1926   EC86 0A                 ASL A
1927   EC87 0A                 ASL A
1928   EC88 0A                 ASL A
1929   EC89 A8                 TAY             ;NOW Y HAS ROW ADDR FROM ROW 1
1930   EC8A AD 2B A4           LDA STBKEY      ;ADD COLUMN TO Y
1931   EC8D 4A          GETK3  LSR A
1932   EC8E 90 03              BCC GETK4
1933   EC90 C8                 INY
1934   EC91 D0 FA              BNE GETK3
1935   EC93 B9 21 F4    GETK4  LDA ROW1,Y      ;GET THE CHR
1936   EC96 48                 PHA
1937   EC97 8A                 TXA             ;SEE IF CTRL OR SHIFT WAS USED
1938   EC98 F0 24              BEQ GETK7       ;BRCH IF NO CTRL OR SHIFT
1939   EC9A 29 10              AND #$10        ;CTRL ?
1940   EC9C F0 06              BEQ GETK5       ;NO ,GO GETKS
1941   EC9E 68                 PLA
1942   EC9F 29 3F              AND #$3F        ;MSK OFF 2 MSB FOR CONTROL
1943   ECA1 4C BF EC           JMP GETK8       ;EXIT
1944   ECA4 68          GETK5  PLA
1945   ECA5 48                 PHA             ;SAVE IT
1946   ECA6 29 40              AND #$40        ;IF ALPHA CHARS DO NOT SHIFT
1947   ECA8 D0 14              BNE GETK7
1948   ECAA 68                 PLA
1949   ECAB 48                 PHA
1950   ECAC 29 0F              AND #$0F        ;ONLY LSB
1951   ECAE F0 0E              BEQ GETK7       ;DO NOT INTERCHANGE <SPACE> OR 0
1952   ECB0 C9 0C              CMP #$0C        ;ACC>=$0C ?
1953   ECB2 B0 05              BCS GETK6       ;YES ACC>=$0C
1954   ECB4 68                 PLA             ;NO, ACC<$0C
1955   ECB5 29 EF              AND #$EF        ;STRIP OFF BIT 4
1956   ECB7 D0 06              BNE GETK8       ;EXIT
1957   ECB9 68          GETK6  PLA             ;ACC>=$0C
1958   ECBA 09 10              ORA #$10        ;BIT 4= 1
1959   ECBC D0 01              BNE GETK8       ;EXIT
1960   ECBE 68          GETK7  PLA
1961   ECBF             ;CHECK FOR "ADV PAP","PRI LINE", OR "TOGL PRIFLG"
1962   ECBF             ;IN THIS WAY WE DONT HAVE TO CHCK FOR THIS COMM
1963   ECBF C9 60       GETK8  CMP #$60        ;ADV PAPER COMM
1964   ECC1 D0 06              BNE GETK11
1965   ECC3 E0 00              CPX #0          ;IF SHIFT IS NOT ADV PAPER
1966   ECC5 F0 25              BEQ GETK10      ;NO SHIFT ,SO ADVPAPER
1967   ECC7 29 4F              AND #$4F        ;CONVRT TO "@"
1968   ECC9 C9 1C       GETK11 CMP #$1C        ;SEE IF TOGGL PRIFLG (CONTRL PRI)
1969   ECCB D0 14              BNE GETK13
1970   ECCD 20 E1 E6           JSR PRITR       ;GO TOGGLE FLG
1971   ECD0 A0 01              LDY #1          ;GET THE PTRS BACK 3 SPACES
1972   ECD2 B9 15 A4    GETK12 LDA CURPO2,Y
1973   ECD5 38                 SEC
1974   ECD6 E9 03              SBC #3          ;BECAUSE "ON ,OFF" MSGS
1975   ECD8 99 15 A4           STA CURPO2,Y
1976   ECDB 88                 DEY
1977   ECDC 10 F4              BPL GETK12
1978   ECDE 4C 40 EC           JMP GETKEY
1979   ECE1 C9 5C       GETK13 CMP #BACKSLASH  ;PRINT LINE COMMAND
1980   ECE3 D0 06              BNE GETK14
1981   ECE5 20 4A F0           JSR IPS0        ;PRINT WHATEVER IS IN BUFFER
1982   ECE8 4C 40 EC           JMP GETKEY
1983   ECEB 60          GETK14 RTS
1984   ECEC 4C 38 EC    GETK10 JMP GETKD0
1985   ECEF
1986   ECEF             ;WAIT IF LAST KEY STILL DOWN  (ROLLOVER)
1987   ECEF AD 82 A4    ROONEK LDA DRB2        ;SEE IF KEY STILL DOWN
1988   ECF2 C9 FF              CMP #$FF
1989   ECF4 F0 0A              BEQ ROO1        ;NO KEY AT ALL, CLR ROLLFL
1990   ECF6 0D 7F A4           ORA ROLLFL      ;ACCEPT ONLY LAST KEY
1991   ECF9 49 FF              EOR #$FF        ;STRBS ARE ZEROS TO INVER
1992   ECFB D0 F2              BNE ROONEK
1993   ECFD 20 2A ED           JSR DEBKEY      ;CLR KMASK & DEBOUNCE RELEASE
1994   ED00 A9 00       ROO1   LDA #0          ;CLR KMASK
1995   ED02 8D 2A A4           STA KMASK
1996   ED05             ;GO THRU KB ONCE AND RTN ,IF ANY
1997   ED05             ;KEY Y=ROW (1-8) & STBKEY=CLMN
1998   ED05             ;IF NO KEY Y=0 ,STBKEY=$FF
1999   ED05 A9 7F       ONEKEY LDA #$7F        ;FIRST STROBE TO MSB
2000   ED07 D0 02              BNE ONEK2       ;START AT ONEK2
2001   ED09 38          ONEK1  SEC             ;ONLY ONE PULSE (ZERO)
2002   ED0A 6A                 ROR A           ;SHIFT TO RIGHT
2003   ED0B 8D 80 A4    ONEK2  STA DRA2        ;OUTPUT CLMN STROBE
2004   ED0E 8D 2B A4           STA STBKEY      ;SAVE IT
2005   ED11 A0 08              LDY #8          ;CHECK 8 ROWS
2006   ED13 AD 82 A4           LDA DRB2        ;ANY KEY ?
2007   ED16 0D 2A A4           ORA KMASK       ;DISABLE ROW 1 IF CTRL OR SHIFT
2008   ED19 8D 7F A4           STA ROLLFL      ;SAVE WHICH KEY IT WAS
2009   ED1C 0A          ONEK3  ASL A
2010   ED1D 90 0A              BCC ONEK4       ;JUMP IF KEY (ZERO)
2011   ED1F 88                 DEY
2012   ED20 D0 FA              BNE ONEK3
2013   ED22 AD 2B A4           LDA STBKEY
2014   ED25 C9 FF              CMP #$FF        ;LAST CLMN ?
2015   ED27 D0 E0              BNE ONEK1       ;NO ,DO NEXT CLMN
2016   ED29 60          ONEK4  RTS
2017   ED2A
2018   ED2A A2 00       DEBKEY LDX #0          ;CLEAR CNTRL OR SHIFT
2019   ED2C A9 00       DEBK1  LDA #0          ;CLR KMASK
2020   ED2E 8D 2A A4           STA KMASK
2021   ED31 A9 88              LDA #DEBTIM     ;DEBOUNCE TIME FOR KEYBOARD
2022   ED33 8D 08 A8           STA T2L
2023   ED36 A9 13              LDA #DEBTIM/256
2024   ED38 4C 18 EC           JMP DE1         ;WAIT FOR 5 MSEC
2025   ED3B
2026   ED3B             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2027   ED3B             ;GET A CHAR FROM TAPE SUBROUTINE
2028   ED3B             ;A BUFFER IS USED TO GET BLOCKS OF DATA
2029   ED3B             ;FROM TAPE ,EXCEPT WHEN FORMAT EQUAL TO
2030   ED3B             ;KIM-1 (THE WHOLE FILE IS LOADED AT ONE TIME)
2031   ED3B 20 9E EB    TIBYTE JSR PHXY        ;PUSH X
2032   ED3E AE 36 A4           LDX TAPTR       ;POINTER FOR BUFFER
2033   ED41 E0 50              CPX #80         ;IS BUFFER EMPTY ?
2034   ED43 D0 03              BNE TIB1
2035   ED45 20 53 ED           JSR TIBY1       ;LOAD ANOTHER BLOCK
2036   ED48 BD 16 01    TIB1   LDA TABUFF,X
2037   ED4B E8                 INX
2038   ED4C 8E 36 A4           STX TAPTR
2039   ED4F 20 AC EB           JSR PLXY        ;PULL X
2040   ED52 60                 RTS
2041   ED53             ;LOAD A BLOCK FROM TAPE INTO BUFFER
2042   ED53 20 EA ED    TIBY1  JSR TAISET      ;SET TAPE FOR INPUT
2043   ED56 20 29 EE    TIBY3  JSR GETTAP      ;GET A CHAR FROM TAPE
2044   ED59 C9 23              CMP #'#'        ;CHECK FIRST CHR FOR
2045   ED5B F0 06              BEQ TIBY4       ;START OF BLOCK
2046   ED5D C9 16              CMP #$16        ;IF NOT # SHOULD BE SYN
2047   ED5F D0 F2              BNE TIBY1
2048   ED61 F0 F3              BEQ TIBY3
2049   ED63 A2 00       TIBY4  LDX #0
2050   ED65 20 29 EE    TIBY5  JSR GETTAP      ;NOW LOAD INTO BUFFER
2051   ED68 9D 16 01           STA TABUFF,X
2052   ED6B E8                 INX
2053   ED6C E0 52              CPX #82
2054   ED6E D0 F5              BNE TIBY5
2055   ED70 AD 00 A8           LDA DRB
2056   ED73 29 CF              AND #$CF
2057   ED75 8D 00 A8           STA DRB         ;TURN OFF TAPES
2058   ED78 58                 CLI             ;ENABL INTERR
2059   ED79 20 BD ED           JSR ADDBK1      ;DISPLAY BLK COUNT
2060   ED7C A2 00              LDX #0          ;TO CLEAR PTR IN TIBYTE
2061   ED7E AD 15 01           LDA BLK         ;CHECK THE BLOCK COUNT
2062   ED81 F0 05              BEQ TIBY5A      ;IF FIRST BLK ,DO NOT CMP
2063   ED83 DD 16 01           CMP TABUFF,X
2064   ED86 D0 28              BNE TIBY7       ;BRANCH IF WE MISSED ONE BLOCK
2065   ED88 E8          TIBY5A INX
2066   ED89 8E 36 A4           STX TAPTR
2067   ED8C EE 15 01           INC BLK         ;INCR BLK CONT
2068   ED8F AD 67 01           LDA TABUFF+81   ;STORE THIS BLK CKSUM
2069   ED92 48                 PHA
2070   ED93 AD 66 01           LDA TABUFF+80
2071   ED96 48                 PHA
2072   ED97 CE 12 A4           DEC INFLG       ;SET INFLG DIFF FROM OUTFLG
2073   ED9A 20 E7 F1           JSR BKCKSM      ;COMPUT BLK CKSUM FOR THIS BLK
2074   ED9D 68                 PLA
2075   ED9E CD 66 01           CMP TABUFF+80   ;DO THEY AGREE ?
2076   EDA1 D0 0C              BNE TIBY6
2077   EDA3 68                 PLA
2078   EDA4 CD 67 01           CMP TABUFF+81
2079   EDA7 D0 07              BNE TIBY7
2080   EDA9 EE 12 A4           INC INFLG       ;RESTORE INPUT DEVICE
2081   EDAC A2 01              LDX #1          ;TO GET FIRST CHR IN TIBYTE
2082   EDAE 60                 RTS
2083   EDAF 68          TIBY6  PLA             ;RESTORE STACK PTR
2084   EDB0 68          TIBY7  PLA
2085   EDB1 68                 PLA
2086   EDB2 68                 PLA
2087   EDB3 68                 PLA
2088   EDB4 20 8E E3           JSR CKER0
2089   EDB7 4C A1 E1           JMP COMIN
2090   EDBA
2091   EDBA             ;ADD 1 TO BLK COUNT AND OUTPUT IT
2092   EDBA EE 15 01    ADDBLK INC BLK         ;INCR BLK CNT
2093   EDBD EE 11 A4    ADDBK1 INC PRIFLG      ;SO DONT OUTPUT TO PRINTR
2094   EDC0 A9 12              LDA #18         ;ONLY OUTPUT IN THIS POSITION
2095   EDC2 8D 15 A4           STA CURPO2
2096   EDC5 AD 4A A4           LDA DIBUFF+18   ;SAVE DISBUF (FOR EDIT)
2097   EDC8 48                 PHA
2098   EDC9 AD 4B A4           LDA DIBUFF+19
2099   EDCC 48                 PHA
2100   EDCD AE 13 A4           LDX OUTFLG      ;SAVE OUTFLG
2101   EDD0 A9 0D              LDA #CR
2102   EDD2 8D 13 A4           STA OUTFLG      ;TO OUTPUT TO TERMINAL
2103   EDD5 AD 16 01           LDA BLK+1       ;BLK CNT COMING FROM TAPE
2104   EDD8 20 46 EA           JSR NUMA        ;OUTPUT IN ASCII
2105   EDDB 8E 13 A4           STX OUTFLG      ;RESTORE OUTFLG
2106   EDDE 68                 PLA
2107   EDDF 8D 4B A4           STA DIBUFF+19
2108   EDE2 68                 PLA
2109   EDE3 8D 4A A4           STA DIBUFF+18
2110   EDE6 CE 11 A4           DEC PRIFLG      ;RESTORE PRI FLG
2111   EDE9 60                 RTS
2112   EDEA
2113   EDEA             ;SET TAPE (1 OR 2) FOR INPUT
2114   EDEA A9 37       TAISET LDA #$37        ;SET PB7 FOR INPUT
2115   EDEC 8D 02 A8           STA DDRB
2116   EDEF AD 34 A4           LDA TAPIN       ;INPUT FLG (TAP 1=2 OR TAP 2=1)
2117   EDF2 20 1C EE           JSR TIOSET      ;RESET PB4 OR PB5
2118   EDF5 A9 EE              LDA #MOFF+DATIN ;SET CA2=1 (DATA IN)
2119   EDF7 8D 0C A8           STA PCR
2120   EDFA A9 FF              LDA #$FF        ;PREPARE T2
2121   EDFC 8D 08 A8           STA T2L         ;LACTH
2122   EDFF             ;CHCK BIT BY BIT UNTIL $16
2123   EDFF 20 3B EE    SYNC   JSR RDBIT       ;GET A BIT IN MSB
2124   EE02 4E 2A A4           LSR CPIY        ;MAKE ROOM FOR BIT
2125   EE05 0D 2A A4           ORA CPIY        ;PUT BIT INTO MSB
2126   EE08 8D 2A A4           STA CPIY
2127   EE0B C9 16              CMP #$16        ;SYN CHAR ?
2128   EE0D D0 F0              BNE SYNC
2129   EE0F A2 05              LDX #$05        ;TEST FOR 5 SYN CHARS
2130   EE11 20 29 EE    SYNC1  JSR GETTAP
2131   EE14 C9 16              CMP #$16
2132   EE16 D0 E7              BNE SYNC        ;IF NOT 2 CHAR RE-SYNC
2133   EE18 CA                 DEX
2134   EE19 D0 F6              BNE SYNC1
2135   EE1B 60                 RTS
2136   EE1C
2137   EE1C             ;SET PB4 OR PB5 OFF
2138   EE1C             ;USED BY IN/OUT SET UPS
2139   EE1C D0 04       TIOSET BNE TIOS1       ;BRCH IF TAP1
2140   EE1E A9 14              LDA #$14        ;SET TAP 2 OFF (PB5=0)
2141   EE20 D0 02              BNE TIOS2
2142   EE22 A9 24       TIOS1  LDA #$24        ;SET TAP 1 OFF (PB4=0)
2143   EE24 8D 00 A8    TIOS2  STA DRB
2144   EE27 78                 SEI             ;DISABLE INTERR WHILE TAP
2145   EE28 60                 RTS
2146   EE29
2147   EE29             ;GET 1 CHAR FROM TAPE AND RETURN
2148   EE29             ;WITH CHR IN ACC, USE CPIY TO ASM CHR ,USES Y
2149   EE29 A0 08       GETTAP LDY #$08        ;READ 8 BITS
2150   EE2B 20 3B EE    GETA1  JSR RDBIT       ;GET NEXT DATA BIT
2151   EE2E 4E 2A A4           LSR CPIY        ;MAKE ROOM FOR MSB
2152   EE31 0D 2A A4           ORA CPIY        ;OR IN SIGN BIT
2153   EE34 8D 2A A4           STA CPIY        ;REPLACE CHAR
2154   EE37 88                 DEY
2155   EE38 D0 F1              BNE GETA1
2156   EE3A 60                 RTS
2157   EE3B             ;GET ONE BIT FROM TAPE AND
2158   EE3B             ;RETURN IT IN SIGN OF A (MSB)
2159   EE3B AD 08 A4    RDBIT  LDA TSPEED      ;ARE WE IN C7 OR 5B,5A FREQUENC`
2160   EE3E 30 27              BMI RDBIT4      ;JUMP TO C7 FREQ FORMAT
2161   EE40 20 75 EE           JSR CKFREQ      ;START BIT IN HIGH FREQ
2162   EE43 20 75 EE    RDBIT1 JSR CKFREQ      ;HIGH TO LOW FREQ TRANS
2163   EE46 B0 FB              BCS RDBIT1
2164   EE48 AD 96 A4           LDA DIV64       ;GET HIGH FREQ TIMING
2165   EE4B 48                 PHA
2166   EE4C A9 FF              LDA #$FF        ;SET UP TIMER
2167   EE4E 8D 96 A4           STA DIV64
2168   EE51 20 75 EE    RDBIT2 JSR CKFREQ      ;LOW TO HIGH FREQ TRANS
2169   EE54 90 FB              BCC RDBIT2      ;WAIT TILL FREQ IS HIGH
2170   EE56 68                 PLA
2171   EE57 38                 SEC
2172   EE58 ED 96 A4           SBC DIV64       ;(256-T1) - (256-T2) =T2-T1
2173   EE5B 48                 PHA             ;LOW FREQ TIME-HIGH FREQ TIME
2174   EE5C A9 FF              LDA #$FF
2175   EE5E 8D 96 A4           STA DIV64       ;SET UP TIMER
2176   EE61 68                 PLA
2177   EE62 49 FF              EOR #$FF
2178   EE64 29 80              AND #$80
2179   EE66 60                 RTS
2180   EE67             ;EACH BIT STARTS WITH HALF PULSE OF 2400 & THEN
2181   EE67             ;3 HALF PULSES OF 1200 HZ FOR 0 ,3 PUSLES OF 2400 FOR 1
2182   EE67             ;THE READING IS MADE ON THE FOURTH 1/2 PULSE ,WHERE
2183   EE67             ;THE SIGNAL HAS STABILIZED
2184   EE67 20 75 EE    RDBIT4 JSR CKFREQ      ;SEE WHICH FREQ
2185   EE6A 90 FB              BCC RDBIT4
2186   EE6C 20 75 EE           JSR CKFREQ
2187   EE6F 20 75 EE           JSR CKFREQ
2188   EE72 4C B5 FF           JMP PATC24      ;NOW READ THE BIT
2189   EE75
2190   EE75 2C 00 A8    CKFREQ BIT DRB         ;ARE WE HIGH OR LOW ?
2191   EE78 30 27              BMI CKF4
2192   EE7A 2C 00 A8    CKF1   BIT DRB         ;WAIT TILL HIGH
2193   EE7D 10 FB              BPL CKF1
2194   EE7F 65 00              ADC $00         ;EQUALIZER
2195   EE81 AD 09 A8    CKF2   LDA T2H         ;SAVE CNTR
2196   EE84 48                 PHA
2197   EE85 AD 08 A8           LDA T2L
2198   EE88 48                 PHA
2199   EE89 A9 FF              LDA #$FF
2200   EE8B 8D 09 A8           STA T2H         ;START CNTR
2201   EE8E AD 08 A4           LDA TSPEED
2202   EE91 30 06              BMI CKF3        ;SUPER SPEED ?
2203   EE93 68                 PLA
2204   EE94 CD 08 A4           CMP TSPEED      ;HIGH OR LOW FREC
2205   EE97 68                 PLA             ;C=1 IF HIGH ,C=0 IF LOW
2206   EE98 60                 RTS
2207   EE99 68          CKF3   PLA
2208   EE9A CD 08 A4           CMP TSPEED      ;CENTER FREQ
2209   EE9D 68          CKF3A  PLA
2210   EE9E E9 FE              SBC #$FE
2211   EEA0 60                 RTS
2212   EEA1 2C 00 A8    CKF4   BIT DRB         ;WAIT TILL LOW
2213   EEA4 30 FB              BMI CKF4
2214   EEA6 10 D9              BPL CKF2        ;GO GET TIMING
2215   EEA8
2216   EEA8             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2217   EEA8             ;OUTPUT ACC TO TTY SUBROUTINE
2218   EEA8             ;X,Y ARE PRESERVED
2219   EEA8 48          OUTTTY PHA             ;SAVE A
2220   EEA9 20 9E EB           JSR PHXY        ;PUSH X
2221   EEAC 8D 27 A4           STA STIY        ;PUT CHAR HERE
2222   EEAF 20 0F EC           JSR DELAY       ;STOP BIT FROM LAST CHAR
2223   EEB2 AD 00 A8           LDA DRB
2224   EEB5 29 FB              AND #$FB        ;START BIT PB2=0
2225   EEB7 8D 00 A8           STA DRB         ;TTO=PB2
2226   EEBA 8D 28 A4           STA STIY+1      ;SAVE THIS PATTERN
2227   EEBD 20 0F EC           JSR DELAY
2228   EEC0 A2 08              LDX #$08        ;8 BITS
2229   EEC2 2E 27 A4           ROL STIY        ;GET FIRST LSB INTO BIT 2
2230   EEC5 2E 27 A4           ROL STIY
2231   EEC8 2E 27 A4           ROL STIY
2232   EECB 6E 27 A4    OUTT1  ROR STIY
2233   EECE AD 27 A4           LDA STIY
2234   EED1 29 04              AND #$04        ;GET ONLY BIT 2 FOR PB2
2235   EED3 0D 28 A4           ORA STIY+1      ;PUT BIT INTO PATTERN
2236   EED6 8D 00 A8           STA DRB         ;NOW TO TTY
2237   EED9 08                 PHP             ;PRESERVE CARRY FOR ROTATE
2238   EEDA 20 0F EC           JSR DELAY
2239   EEDD 28                 PLP
2240   EEDE CA                 DEX
2241   EEDF D0 EA              BNE OUTT1
2242   EEE1 A9 04              LDA #$04        ;STOP BIT
2243   EEE3 0D 28 A4           ORA STIY+1
2244   EEE6 8D 00 A8           STA DRB
2245   EEE9 20 0F EC           JSR DELAY       ;STOP BIT
2246   EEEC 20 AC EB           JSR PLXY        ;PULL X
2247   EEEF 68                 PLA
2248   EEF0 C9 0A              CMP #LF
2249   EEF2 F0 07              BEQ OUTT2
2250   EEF4 C9 FF              CMP #NULLC
2251   EEF6 F0 03              BEQ OUTT2
2252   EEF8 4C 05 EF           JMP OUTDIS      ;USE THAT BUFF
2253   EEFB 60          OUTT2  RTS
2254   EEFC
2255   EEFC             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2256   EEFC             ;OUTPUT A CHR TO D/P SUBR (SINGLE ENTRY FOR BOTH SUBR)
2257   EEFC             ;IF CHAR=<CR> CLEAR DISPLAY & PRINTER
2258   EEFC 20 00 F0    OUTDP  JSR OUTPRI      ;FIRST TO PRI THEN TO DISP
2259   EEFF EA                 NOP
2260   EF00 EA                 NOP
2261   EF01 EA                 NOP
2262   EF02 6C 06 A4    OUTDP1 JMP (DILINK)    ;HERE HE COULD ECHO SOMEWHERE ELSE`
2263   EF05
2264   EF05             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2265   EF05             ;OUTPUT ACC TO DISPLAY SUBROUTINE
2266   EF05             ;IF SIGN BIT (MSB)=1 DISP DO NOT CLR TO THE RIGHT
2267   EF05 48          OUTDIS PHA             ;SAVE A
2268   EF06 20 9E EB           JSR PHXY        ;PUSH X
2269   EF09 C9 0D              CMP #CR         ;<CR> ?
2270   EF0B D0 07              BNE OUTD1
2271   EF0D A2 00              LDX #0          ;YES
2272   EF0F 8E 15 A4           STX CURPO2      ;CLEAR DISP POINTER
2273   EF12 F0 42              BEQ OUTD5       ;GO CLEAR DISP
2274   EF14 4C 9C FE    OUTD1  JMP PATCH4
2275   EF17 E0 3C       OUTD1A CPX #60         ;LAST CHAR FOR DISP?
2276   EF19 90 05              BCC OUTD2
2277   EF1B 20 AC EB           JSR PLXY        ;GO BACK
2278   EF1E 68                 PLA             ;DO NOT STORE
2279   EF1F 60                 RTS
2280   EF20 9D 38 A4    OUTD2  STA DIBUFF,X    ;PUT CHAR IN BUFF
2281   EF23 EE 15 A4           INC CURPO2      ;INC POINTER
2282   EF26 E0 14              CPX #20         ;DISPLAY FULL?
2283   EF28 90 1E              BCC OUTD4
2284   EF2A 20 2F EF           JSR OUTD2A      ;THIS WAY SCROLL IS A SUBR
2285   EF2D 30 47              BMI OUTD7       ;EXIT DISP
2286   EF2F             ;YES, SCROLL CHARS TO THE LEFT
2287   EF2F 8A          OUTD2A TXA             ;X---> Y
2288   EF30 A8                 TAY
2289   EF31 A2 13              LDX #19         ;ADDR FOR DISP DO NOT
2290   EF33 8E 27 A4    OUTD3  STX STIY        ;DECREM IN BINARY
2291   EF36 B9 38 A4           LDA DIBUFF,Y    ;FROM BUFFER TO DISP
2292   EF39 09 80              ORA #$80        ;NO CURSOR
2293   EF3B 20 7B EF           JSR OUTDD1      ;CONVERT X INTO REAL ADDR
2294   EF3E 88                 DEY
2295   EF3F CE 27 A4           DEC STIY
2296   EF42 AE 27 A4           LDX STIY
2297   EF45 10 EC              BPL OUTD3       ;AGAIN UNTIL WHOLE DISP
2298   EF47 60                 RTS
2299   EF48 48          OUTD4  PHA
2300   EF49 09 80              ORA #$80        ;NO CURSOR
2301   EF4B 20 7B EF           JSR OUTDD1      ;X=<$19 ,CONVRT TO REAL ADDR
2302   EF4E 68                 PLA
2303   EF4F 29 80              AND #$80        ;IF MSB=0 CLEAR REST OF DISPLAY
2304   EF51 D0 23              BNE OUTD7
2305   EF53 AE 15 A4           LDX CURPO2
2306   EF56             ;CLEAR DISP TO THE RIGHT
2307   EF56 E0 14       OUTD5  CPX #20
2308   EF58 B0 1C              BCS OUTD7
2309   EF5A 8E 27 A4           STX STIY
2310   EF5D A9 A0              LDA #' '+$80    ;<SPACE>
2311   EF5F 20 7B EF           JSR OUTDD1      ;CONVRT TO REAL ADDR
2312   EF62 EE 27 A4           INC STIY
2313   EF65 AE 27 A4           LDX STIY
2314   EF68 D0 EC              BNE OUTD5       ;GO NEXT
2315   EF6A 4C 76 EF           JMP OUTD7
2316   EF6D EA                 NOP
2317   EF6E EA                 NOP
2318   EF6F EA                 NOP
2319   EF70 EA                 NOP
2320   EF71 EA                 NOP
2321   EF72 EA                 NOP
2322   EF73 EA                 NOP
2323   EF74 EA                 NOP
2324   EF75 EA                 NOP
2325   EF76 20 AC EB    OUTD7  JSR PLXY        ;REST ,SO PRINTR INDEPEN
2326   EF79 68                 PLA
2327   EF7A 60                 RTS
2328   EF7B
2329   EF7B             ;CONVERT X INTO REAL ADDR FOR DISPLAY
2330   EF7B             ;AND OUTPUT IT  PB=DATA ; PA=W,CE ,A0 A1 (6520)
2331   EF7B 48          OUTDD1 PHA             ;SAVE DATA
2332   EF7C 8A                 TXA
2333   EF7D 48                 PHA             ;SAVE X
2334   EF7E 4A                 LSR A           ;DIVIDE X BY 4
2335   EF7F 4A                 LSR A           ;TO GET CHIP SELECT
2336   EF80 AA                 TAX             ;BACK TO X
2337   EF81 A9 04              LDA #4          ;FIRST CHIP SELECT
2338   EF83 E0 00              CPX #0          ;FIRST CHIP ?
2339   EF85 F0 04              BEQ OUTDD3
2340   EF87 0A          OUTDD2 ASL A
2341   EF88 CA                 DEX
2342   EF89 D0 FC              BNE OUTDD2      ;BACK TILL RIGH CS
2343   EF8B 8D 28 A4    OUTDD3 STA STIY+1      ;SAVE CS TEMPORARILY
2344   EF8E 68                 PLA             ;GET X AGAIN FOR CHAR
2345   EF8F 29 03              AND #$03        ;IN THAT CHIP
2346   EF91 0D 28 A4           ORA STIY+1      ;OR IN CS AND CHAR
2347   EF94             ;STORE ADDR AND DATA INTO DISPL
2348   EF94 49 FF              EOR #$FF        ;W=1 , CE=0 & A1,A0
2349   EF96 8D 00 AC           STA RA
2350   EF99 AA                 TAX             ;SAVE A IN X
2351   EF9A 68                 PLA             ;GET DATA
2352   EF9B 48                 PHA
2353   EF9C 8D 02 AC           STA RB
2354   EF9F 8A                 TXA
2355   EFA0 49 80              EOR #$80        ;SET W=0
2356   EFA2 8D 00 AC           STA RA
2357   EFA5 EA                 NOP
2358   EFA6 09 7C              ORA #$7C        ;SET CE=1
2359   EFA8 8D 00 AC           STA RA
2360   EFAB A9 FF              LDA #$FF        ;SET W=1
2361   EFAD 8D 00 AC           STA RA
2362   EFB0 68                 PLA             ;RETURN DATA
2363   EFB1 60                 RTS
2364   EFB2
2365   EFF9                    *=$EFF9
2366   EFF9 EA                 .DB $EA
2367   F000                    *=$F000
2368   F000             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2369   F000             ;OUTPUT ACC TO PRINTER SUBROUTINE
2370   F000             ;PRINTS ON 21RST CHAR OR WHEN <CR>
2371   F000             ;IT WILL PUT IT ON BUBFFER BUT WONT PRINT IF
2372   F000             ;PRIFLG=0
2373   F000 48          OUTPRI PHA             ;SAVE CHR TO BE OUTPUT
2374   F001 20 9E EB           JSR PHXY        ;SAVE X
2375   F004 C9 0D              CMP #CR         ;SEE IF CR
2376   F006 F0 07              BEQ OUT01       ;YES SO PRINT THE BUFF
2377   F008 AE 16 A4           LDX CURPOS      ;PTR TO NEXT POS IN BUFF
2378   F00B E0 14              CPX #20         ;SEE IF BUFF FULL
2379   F00D D0 16              BNE OUT04       ;NOT FULL SO RETURN
2380   F00F             ;<CR> SO FILL REST OF BUFFER WITH BLANKS
2381   F00F 48          OUT01  PHA
2382   F010 A9 00              LDA #0          ;CURPOS = 0
2383   F012 AE 16 A4           LDX CURPOS      ;SEE IF ANYTHING IN BUFFER
2384   F015 8D 16 A4           STA CURPOS
2385   F018 20 38 F0           JSR OUTPR       ;CLEAR PRIBUF TO THE RIGHT
2386   F01B             ;BUFFER FILLED SO PRINT IT
2387   F01B 20 45 F0           JSR IPST        ;START THE PRINT
2388   F01E A2 00              LDX #0          ;STORE CHR IN BUFF (FIRST LOC)
2389   F020 68                 PLA             ;GET IT
2390   F021 C9 0D              CMP #CR         ;DONT STORE IF <CR>
2391   F023 F0 0E              BEQ OUT05
2392   F025 9D 60 A4    OUT04  STA IBUFM,X     ;STORE CHR IN BUFF
2393   F028 EE 16 A4           INC CURPOS      ;INCR BUFF PNTR
2394   F02B E8                 INX
2395   F02C 29 80              AND #$80
2396   F02E D0 03              BNE OUT05       ;DONT CLR IF MSB=1
2397   F030 20 38 F0           JSR OUTPR       ;CLEAR PRIBUFF TO THE RIGHT
2398   F033 20 AC EB    OUT05  JSR PLXY        ;RESTORE REGS
2399   F036 68                 PLA
2400   F037 60                 RTS
2401   F038 A9 20       OUTPR  LDA #' '        ;FILL REST OF BUFF WITH BLANKS
2402   F03A E0 14       OUTPR1 CPX #20         ;SEE IF END OF BUFF
2403   F03C F0 06              BEQ OUTPR2
2404   F03E 9D 60 A4           STA IBUFM,X     ;NO SO STORE BLANK
2405   F041 E8                 INX             ;INCR BUFF PNTR
2406   F042 10 F6              BPL OUTPR1
2407   F044 60          OUTPR2 RTS
2408   F045
2409   F045             ;SUB TO OUTPUT BUFFER, 70 DOTS (10 DOTS AT
2410   F045             ;A TIME BY 7 ROWS) FOR EACH LINE OF PRINTING
2411   F045 2C 11 A4    IPST   BIT PRIFLG      ;PRINT FLG ON ?
2412   F048 10 2E              BPL IPO4
2413   F04A 20 CB F0    IPS0   JSR PINT        ;INITIALIZE VALUES
2414   F04D 20 E3 F0           JSR IPSU        ;SET UP FIRS OUTPUT PATTERN
2415   F050 A9 C1       IPO0   LDA #PRST+SP12+MON ;TURN MOTOR ON
2416   F052 8D 0C A8           STA PCR
2417   F055 20 A0 FF           JSR PAT23       ;TIME OUT ?
2418   F058 D0 0C              BNE IPO2        ;NO, START SIGNAL RECEIVED
2419   F05A 20 A0 FF           JSR PAT23       ;YES, TRY AGAIN
2420   F05D D0 07              BNE IPO2        ;OK
2421   F05F 4C 79 F0           JMP PRIERR      ;TWO TIME OUTS - ERROR
2422   F062 EA                 NOP
2423   F063 EA                 NOP
2424   F064 EA                 NOP
2425   F065 EA                 NOP
2426   F066 20 87 F0    IPO2   JSR PRNDOT      ;STRB P1=1 PRINT DOTS (1.7MSEC)
2427   F069 20 87 F0           JSR PRNDOT      ;STRB P2=1 PRINT DOTS (1.7MSEC)
2428   F06C             ;CHECK FOR 90, WHEN 70 PRNDOT WILL OUTPUT ZEROS
2429   F06C AD 77 A4           LDA IDOT
2430   F06F C9 5A              CMP #90
2431   F071 90 F3              BCC IPO2        ;L.T. 90 THEN GO STROB P1
2432   F073 A9 E1       IPO3   LDA #PRST+SP12+MOFF ;TURN MOTOR OFF
2433   F075 8D 0C A8           STA PCR
2434   F078 60          IPO4   RTS
2435   F079
2436   F079 20 44 EB    PRIERR JSR CLR         ;CLEAR PRI PNTR
2437   F07C 20 B1 FE           JSR PATCH5      ;TURN PRI OFF
2438   F07F A0 3B              LDY #M12-M1
2439   F081 20 AF E7           JSR KEP
2440   F084 4C A1 E1           JMP COMIN       ;BACK WHERE SUBR WAS CALLED
2441   F087
2442   F087             ;SUBR TO INCR DOT COUNTER,WHEN
2443   F087             ;NEG TRANS OUTPUT CHR FOR 1.7 MSEC
2444   F087             ;CLEAR & SET UP NEXT PATTERN
2445   F087 A9 00       PRNDOT LDA #0          ;CLR INTERRPTS
2446   F089 8D 01 A8           STA DRAH
2447   F08C AD 0D A8    PRDOT0 LDA IFR
2448   F08F 29 02              AND #MSP12      ;ANY STROBES ?
2449   F091 F0 F9              BEQ PRDOT0
2450   F093 AD 0C A8           LDA PCR
2451   F096 49 01              EOR #$01
2452   F098 8D 0C A8           STA PCR
2453   F09B EE 77 A4           INC IDOT
2454   F09E AD 79 A4           LDA IOUTU       ;2 LEFT ELEM
2455   F0A1 0D 00 A8           ORA DRB         ;DO NOT TURN TTY OUTPUT OFF
2456   F0A4 8D 00 A8           STA DRB
2457   F0A7 AD 78 A4           LDA IOUTL       ;7 RIGHT ELEM, CLR CA1 INTER FLG
2458   F0AA 8D 01 A8           STA DRAH
2459   F0AD A9 A4              LDA #PRTIME
2460   F0AF 8D 08 A8           STA T2L
2461   F0B2 A9 06              LDA #PRTIME/256 ;START T2 FOR 1.7 MSEC
2462   F0B4 8D 09 A8           STA T2H
2463   F0B7 20 E3 F0           JSR IPSU        ;SET NEXT PATTERN WHILE WAITING
2464   F0BA 20 1B EC           JSR DE2         ;WAIT TILL TIME OUT
2465   F0BD A9 00              LDA #0          ;THERMAL ELEM OFF
2466   F0BF 8D 01 A8           STA DRAH
2467   F0C2 AD 00 A8           LDA DRB         ;BUT DONT CHANGE TAPE CONTROLS
2468   F0C5 29 FC              AND #$FC
2469   F0C7 8D 00 A8           STA DRB
2470   F0CA 60                 RTS
2471   F0CB
2472   F0CB             ; SUBROUTINE PINT -- INIT VARS FOR PRINTER
2473   F0CB A9 FF       PINT   LDA #$FF
2474   F0CD 8D 74 A4           STA IDIR        ;DIRECTION <= -
2475   F0D0 A9 05              LDA #5
2476   F0D2 8D 75 A4           STA ICOL        ;COLUMN <= LEFTMOST +1
2477   F0D5 A9 01              LDA #1
2478   F0D7 8D 76 A4           STA IOFFST      ;OFFSET <= LEFT CHARACTER
2479   F0DA 8D 7C A4           STA IMASK
2480   F0DD A9 00              LDA #0
2481   F0DF 8D 77 A4           STA IDOT        ;DOT COUNTER <= 0
2482   F0E2 60                 RTS
2483   F0E3
2484   F0E3             ;THE VARIABLES FOR THE PRINTER ARE AS FOLLOWS:
2485   F0E3             ;
2486   F0E3             ;IDIR   DIRECT HEAD IS CURRENTLY MOVING (0=+, $FF=-)
2487   F0E3             ;ICOL   CLMN TO BE PRNTED NEXT (LEFTMOST=0,RIGHTMOST=4)
2488   F0E3             ;IOFFST OFFSET N PRINT BUFF (0=LEFT CHR, 1=RIGHT CHR)
2489   F0E3             ;IDOT   COUNT OF NUMBER OF DOTS PRINTED THUS FAR
2490   F0E3             ;IOUTL  SOLENOID PATTERN (8 CHRS ON RIGHT)
2491   F0E3             ;IOUTU  SOLENOID PATTERN (2 CHRS ON LEFT)
2492   F0E3             ;IBITL  1 BIT MSK USED IN SETTING NEXT SOLENOID VALUE
2493   F0E3             ;IBITU  UPPER PART OF MASK
2494   F0E3             ;IBUFM  START OF PRINT BUFFER (LEFTMOST CHR FIRST)
2495   F0E3             ;IMASK  MASK FOR CURRENT ROW BEING PRINTED
2496   F0E3             ;JUMP   ADDRESS OF TABLE FOR CURRENT COLUMN
2497   F0E3             ;
2498   F0E3             ;   THE DOT PATTERNS FOR THE CHRS ARE STORED SO THAT...
2499   F0E3             ;EACH BYTE CONTAINS THE DOTS FOR ONE COLUMN OF ONE...
2500   F0E3             ;CHR. SINCE EACH COLUMN CONTAINS SEVEN DOTS ,
2501   F0E3             ;THIS MEANS THAT ONE BIT PER BYTE IS UNUSED.
2502   F0E3             ;    THE PATTERNS ARE ORGANIZED INTO 5 TABLES OF 64...
2503   F0E3             ;BYTES WHERE EACH TABLE CONTAINS ALL THE DOT...
2504   F0E3             ;PATTERNS FOR A PARTICULAR COLUMN. THE BYTES IN EACH...
2505   F0E3             ;TABLE ARE ORDERED ACCORDING TO THE CHR CODE OF...
2506   F0E3             ;THE CHR BEING REFERENCED. THE CHR CODE CAN...
2507   F0E3             ;THUS BE USED TO DIRECTLY INDEX INTO THE TABLE.
2508   F0E3
2509   F0E3             ;SUBROUTINE IPSU -- SET UP OUTPUT PATTERN FOR PRINTER
2510   F0E3             ;   THIS ROUTINE IS CALLED IN ORDER TO
2511   F0E3             ;SET UP THE NEXT GROUP OF SOLENOIDS TO
2512   F0E3             ;BE OUTPUT TO THE PRINTER.
2513   F0E3             ;   ON ENTRY THE CONTENTS OF ALL REGISTERS
2514   F0E3             ;ARE ARBITRARY
2515   F0E3             ;   ON EXIT THE CONTENTS OF A,X,Y ARE UNDEFINED
2516   F0E3 A2 00       IPSU   LDX #0          ;X POINTS TO VAR BLOCK FOR PRNTR
2517   F0E5 20 21 F1           JSR INCP        ;ADVANCE PTRS TO NXT DOT POSITION
2518   F0E8             ;X NOW CONTAINS INDEX INTO PRINT BUFFER
2519   F0E8 BD 60 A4    IPS1   LDA IBUFM,X     ;LOAD NEXT CHAR FROM BUFFER
2520   F0EB 29 3F              AND #$3F
2521   F0ED A8                 TAY
2522   F0EE A9 7D              LDA #JUMP       ;A<= DOT PATTERN FOR CHAR & COL
2523   F0F0 20 58 EB           JSR LDAY
2524   F0F3 2C 7C A4           BIT IMASK       ;SEE IF DOT IS SET
2525   F0F6 F0 16              BEQ IPS2        ;NO SO GO ON TO NEXT CHAR
2526   F0F8 AD 7A A4           LDA IBITL       ;DOT ON SO SET THE CURR SOLENOID
2527   F0FB F0 08              BEQ IPS3        ;LSB OF SOL MASK IS 0 , DO MSB
2528   F0FD 0D 78 A4           ORA IOUTL       ;SET THE SOLENOID IN THE PATTERN
2529   F100 8D 78 A4           STA IOUTL
2530   F103 D0 09              BNE IPS2        ;BRANCH ALWAYS
2531   F105 AD 7B A4    IPS3   LDA IBITU       ;SOLENOID IS ONE OF THE 2 MSD
2532   F108 0D 79 A4           ORA IOUTU       ;SET THE BIT IN THE PATTERN
2533   F10B 8D 79 A4           STA IOUTU
2534   F10E 0E 7A A4    IPS2   ASL IBITL       ;SHIFT MSK TO NXT CHR POSITION
2535   F111 2E 7B A4           ROL IBITU
2536   F114 CA                 DEX             ;DECR PTR INTO BUFFER
2537   F115 CA                 DEX
2538   F116 10 D0              BPL IPS1        ;NOT END YET
2539   F118             ;SOLENOID PATTERN IS SET UP IN IOUTU,IOUTL
2540   F118 AD 79 A4           LDA IOUTU       ;LEFTMOST 2
2541   F11B 29 03              AND #$03        ;DISABLE FOR SEGMENTS
2542   F11D 8D 79 A4           STA IOUTU
2543   F120 60                 RTS
2544   F121
2545   F121             ; SUBROUTINE INCP
2546   F121             ;THIS SUBROUTINE IS USED TO UPDATE THE PRINTER VARIABLES
2547   F121             ;TO POINT TO THE NEXT DOT POSITION TO BE PRINTED
2548   F121             ;X REG IS USED TO POINT TO THE VARIABLE BLOCK OF
2549   F121             ;BEING UPDATED
2550   F121             ;ON EXIT X CONTAINS THE POINTER TO THE LAST CHARACTER IN
2551   F121             ;THE PRINT BUFFER
2552   F121             ;CONTENTS OF A,Y ON EXIT ARE ARBITRARY
2553   F121 BD 74 A4    INCP   LDA IDIR,X      ;EXAMINE DIRECTION(+ OR -)
2554   F124 10 1E              BPL OP03        ;DIRECTION = +
2555   F126             ;*DIRECTION = -
2556   F126 BD 75 A4           LDA ICOL,X      ;SEE WHAT THE COLUMN IS
2557   F129 F0 05              BEQ OP04        ;COLUMN = 0 SO END OF DIGIT
2558   F12B             ;**COLUMN # 0 SO JUST DECREMENT COLUMN
2559   F12B DE 75 A4           DEC ICOL,X
2560   F12E 10 33              BPL NEWCOL      ;BRANCH ALWAYS
2561   F130             ;**COLUMN = 0 SO SEE IF EVEN OR ODD DIGIT
2562   F130 BD 76 A4    OP04   LDA IOFFST,X
2563   F133 F0 0A              BEQ OP07        ;OFFSET = 0 SO DIRECTION CHANGE
2564   F135             ;***OFFSET = 1 SO MOVE TO RIGHT DIGIT
2565   F135 DE 76 A4           DEC IOFFST,X    ;OFFSET <= 0 (LEFT CHARACTER)
2566   F138 A9 04              LDA #4          ;COLUMN <= 4
2567   F13A 9D 75 A4           STA ICOL,X
2568   F13D 10 24              BPL NEWCOL      ;BRANCH ALWAYS
2569   F13F             ;***OFFSET = 0 SO CHANGE DIRECTION TO +
2570   F13F FE 74 A4    OP07   INC IDIR,X      ;DIRECTION <= $00 (+)
2571   F142 10 1C              BPL NEWROW      ;BRANCH ALWAYS
2572   F144             ;*DIRECTION = +
2573   F144 BD 75 A4    OP03   LDA ICOL,X      ;SEE IF LAST COLUMN IN DIGIT
2574   F147 C9 04              CMP #4
2575   F149 F0 05              BEQ OP05        ;COLUMN = 4 SO GO TO NEXT DIGIT
2576   F14B FE 75 A4           INC ICOL,X      ;JUST INCR COLUMN-NOT END OF DIGIT
2577   F14E 10 13              BPL NEWCOL      ;BRANCH ALWAYS
2578   F150             ;**AT COLUMN 4 -- SEE IF LEFT OR RIGHT DIGIT
2579   F150 BD 76 A4    OP05   LDA IOFFST,X
2580   F153 D0 08              BNE OP06        ;OFFSET # 0 SO RIGHT DIGIT
2581   F155 9D 75 A4           STA ICOL,X      ;COLUMN <= 0
2582   F158 FE 76 A4           INC IOFFST,X    ;OFFSET <= 1 (RIGHT CHARACTER)
2583   F15B 10 06              BPL NEWCOL      ;BRANCH ALWAYS
2584   F15D             ;***OFFSET = 1 SO DIRECTION CHANGE
2585   F15D DE 74 A4    OP06   DEC IDIR,X      ;DIRECTION <= $FF (-)
2586   F160
2587   F160             ;START OF NEW PRINT ROW
2588   F160 1E 7C A4    NEWROW ASL IMASK,X     ;UPDATE ROW MASK FOR DOT PATTERNS
2589   F163             ;START OF NEW PRINT COLUMN
2590   F163 A9 00       NEWCOL LDA #0          ;CLEAR OUTPUT PATTERN
2591   F165 9D 78 A4           STA IOUTL,X     ;PATTERN FOR 8 RIGHT CHRS
2592   F168 9D 79 A4           STA IOUTU,X     ;PATTERN FOR 2 LEFT SOLEN
2593   F16B 9D 7B A4           STA IBITU,X     ;OUTPUT MSK FOR LEFTMOST SOLEN
2594   F16E A9 01              LDA #1
2595   F170 9D 7A A4           STA IBITL,X     ;OUTPUT MSK FOR RIGHTMOST SOLEN
2596   F173             ;GET ADDRESS OF DOT PATTERN TABLE FOR NEXT COLUMN
2597   F173 BD 75 A4           LDA ICOL,X      ;GET COLUMN NUMBER (0-4)
2598   F176 0A                 ASL A           ;*2 ,INDEX INTO TBL OF TBL ADDRS
2599   F177 A8                 TAY
2600   F178 B9 D7 F2           LDA MTBL,Y      ;LSB OF ADDR OF TABLE
2601   F17B 9D 7D A4           STA JUMP,X      ;PTR TO TBL WITH DOT PATTERNS
2602   F17E B9 D8 F2           LDA MTBL+1,Y    ;MSB OF TABLE ADDRESS
2603   F181 9D 7E A4           STA JUMP+1,X
2604   F184 A9 12              LDA #18         ;COMPUTE INDEX INTO PRNTR BUFFER
2605   F186 1D 76 A4           ORA IOFFST,X    ;+1 IF RIGHT CHR
2606   F189 AA                 TAX
2607   F18A 60                 RTS
2608   F18B
2609   F18B             ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
2610   F18B             ;OUTPUT ACC TO TAPE BUFFER SUBROUTINE
2611   F18B             ; & WHEN FULL OUTPUT BUFF TO TAPE.
2612   F18B             ; IF INFLG=OUTFLG= T USE TWO BUFFERS
2613   F18B             ;OTHERWISE USE SAME BUFFER FOR INPUT
2614   F18B             ;AND OUTPUT (MONIT BUFFER)
2615   F18B 20 9E EB    TOBYTE JSR PHXY        ;SAVE X
2616   F18E AE 37 A4           LDX TAPTR2      ;TAPE BUFFER POINTER FOR OUTPUT
2617   F191 20 0F F2           JSR BKCK2       ;STORE IN BUFFER
2618   F194 E8                 INX
2619   F195 8E 37 A4           STX TAPTR2      ;FOR NEXT
2620   F198 E0 50              CPX #80         ;BUFFER FULL?
2621   F19A D0 32              BNE TABY3       ;NO , GO BACK
2622   F19C             ;OUTPUT A BLOCK FROM BUFFER TO TAPE
2623   F19C 20 E7 F1           JSR BKCKSM      ;COMPUT BLOCK CHECKSUM
2624   F19F 20 1D F2           JSR TAOSET      ;SET TAPE FOR OUTPUT
2625   F1A2 A9 23              LDA #'#'        ;CHAR FOR BEGINNING
2626   F1A4 20 4A F2           JSR OUTTAP      ;OF BLOCK
2627   F1A7             ;OUTPUT CHRS FROM ACTIVE BUFFER
2628   F1A7 20 D2 F1    TABY2  JSR CKBUFF      ;LOAD CHR FROM ACTIVE BUFFER
2629   F1AA 20 4A F2           JSR OUTTAP      ; FROM BUFFER
2630   F1AD E8                 INX
2631   F1AE E0 53              CPX #83         ;2 BLOCK CKSUM CHR + 1 EXTRA CHR..
2632   F1B0 D0 F5              BNE TABY2       ;OTHERWISE ERROR
2633   F1B2 AD 00 A8           LDA DRB
2634   F1B5 29 CF              AND #$CF        ;TURN TAPES OFF PB5,PB4
2635   F1B7 8D 00 A8           STA DRB
2636   F1BA 58                 CLI             ;ENABLE INTERRUPT
2637   F1BB A9 00              LDA #0
2638   F1BD 8D 37 A4           STA TAPTR2      ;CLR TAPE BUFF PTR
2639   F1C0 A9 00              LDA #T1I        ;RESET FREE RUNNING TO 1 SHOT
2640   F1C2 8D 0B A8           STA ACR
2641   F1C5 20 9A FF           JSR PAT22       ;ADD 1 TO BLK COUNT & OUTPUT
2642   F1C8 AD 68 01           LDA BLKO        ;PUT BLK CNT IN FIRST LOC (TABUFF)
2643   F1CB 20 8B F1           JSR TOBYTE
2644   F1CE 20 AC EB    TABY3  JSR PLXY
2645   F1D1 60                 RTS
2646   F1D2
2647   F1D2             ;CHCK ACTIVE BUFFER AND LOAD A CHR
2648   F1D2             ;CARRY=0 IF ONLY 1 BUFFER ,C=1 IF 2 BUFFERS
2649   F1D2 AD 12 A4    CKBUFF LDA INFLG
2650   F1D5 CD 13 A4           CMP OUTFLG
2651   F1D8 D0 08              BNE CBUFF1
2652   F1DA C9 54              CMP #'T'        ;SEE IF INFLG=OUTFLG = T
2653   F1DC D0 04              BNE CBUFF1
2654   F1DE 38                 SEC             ;USE PAGE 1 FOR OUTPUT BUFFER
2655   F1DF B5 AD              LDA TABUF2,X
2656   F1E1 60                 RTS
2657   F1E2 18          CBUFF1 CLC             ;USE SAME BUFFER FOR I/O
2658   F1E3 BD 16 01           LDA TABUFF,X
2659   F1E6 60                 RTS
2660   F1E7
2661   F1E7             ;COMPUTE BLOCK CHECKSUM & PUT IT
2662   F1E7             ;AT THE END OF ACTIVE BUFFER
2663   F1E7 A9 00       BKCKSM LDA #0          ;CLEAR BLK CKSUM LOCAT
2664   F1E9 8D 66 01           STA TABUFF+80
2665   F1EC 8D 67 01           STA TABUFF+81
2666   F1EF A2 4F              LDX #79
2667   F1F1 20 D2 F1    BKCK1  JSR CKBUFF      ;GET CHR FROM EITHER BUFFER
2668   F1F4 18                 CLC
2669   F1F5 6D 66 01           ADC TABUFF+80   ;ADD TO CKSUM
2670   F1F8 8D 66 01           STA TABUFF+80
2671   F1FB 90 03              BCC *+5
2672   F1FD EE 67 01           INC TABUFF+81
2673   F200 CA                 DEX
2674   F201 10 EE              BPL BKCK1       ;DO THE WHOLE BUFFER
2675   F203 A2 50              LDX #80
2676   F205 AD 66 01           LDA TABUFF+80   ;PUT CKSUM INTO RIGHT BUFFER
2677   F208 20 0F F2           JSR BKCK2
2678   F20B E8                 INX
2679   F20C AD 67 01           LDA TABUFF+81
2680   F20F 48          BKCK2  PHA             ;OUTPUT A CHAR TO RIGHT BUFFER
2681   F210 20 D2 F1           JSR CKBUFF      ;GET WHICH BUFFER
2682   F213 68                 PLA
2683   F214 B0 04              BCS BKCK3       ;BRNCH TO SECOND BUFFER
2684   F216 9D 16 01           STA TABUFF,X
2685   F219 60                 RTS
2686   F21A 95 AD       BKCK3  STA TABUF2,X    ;TO PAG 1
2687   F21C 60                 RTS
2688   F21D
2689   F21D             ;SET TAPE (1 OR 2) FOR OUTPUT
2690   F21D 20 C0 F2    TAOSET JSR SETSPD      ;SET UP SPEED (# OF HALF PULSES)
2691   F220 AD 35 A4           LDA TAPOUT      ;OUTPUT FLG (TAPE 1 OR 2)
2692   F223 20 1C EE           JSR TIOSET      ;SET PB4 OR PB5 TO ZERO
2693   F226 A9 EC              LDA #DATOUT+MOFF ;SET CA2=0 (DATA OUT)
2694   F228 8D 0C A8           STA PCR
2695   F22B A9 C0              LDA #T1FR       ;SET TIMER IN FREE RUNNING
2696   F22D 8D 0B A8           STA ACR
2697   F230 A9 00              LDA #00
2698   F232 8D 05 A8           STA T1CH        ;START TIMER T1
2699   F235 AE 09 A4           LDX GAP         ;OUTPUT 4*GAP SYN BYTES
2700   F238 A9 16       TAOS1  LDA #$16        ;SYN CHAR
2701   F23A 20 4A F2           JSR OUTTAP      ;TO TAPE
2702   F23D 20 4A F2           JSR OUTTAP
2703   F240 20 4A F2           JSR OUTTAP
2704   F243 20 4A F2           JSR OUTTAP
2705   F246 CA                 DEX
2706   F247 D0 EF              BNE TAOS1
2707   F249 60                 RTS
2708   F24A
2709   F24A             ;OUTPUT ACC TO TAPE
2710   F24A 8E 2D A4    OUTTAP STX CPIY+3      ;SAVE X
2711   F24D A0 07              LDY #$07        ;FOR THE 8 BITS
2712   F24F 8C 27 A4           STY STIY
2713   F252 AE 08 A4           LDX TSPEED
2714   F255 30 39              BMI OUTTA1      ;IF ONE IS SUPER HIPER
2715   F257 48                 PHA
2716   F258 A0 02       TRY    LDY #2          ;SEND 3 UNITS
2717   F25A 8C 28 A4           STY STIY+1      ;STARTING AT 3700 HZ
2718   F25D BE 0A A4    ZON    LDX NPUL,Y      ;#OF HALF CYCLES
2719   F260 48                 PHA
2720   F261 B9 0B A4    ZON1   LDA TIMG,Y      ;SET UP LACTH FOR NEXT
2721   F264 8D 06 A8           STA T1LL        ;PULSE (80 OR CA) (FREC)
2722   F267 A9 00              LDA #0
2723   F269 8D 07 A8           STA T1LH
2724   F26C 2C 0D A8    ZON2   BIT IFR         ;WAIT FOR PREVIOUS
2725   F26F 50 FB              BVC ZON2        ;CYCLE (T1 INT FLG)
2726   F271 AD 04 A8           LDA T1L         ;CLR INTERR FLG
2727   F274 CA                 DEX
2728   F275 D0 EA              BNE ZON1        ;SEND ALL CYCLES
2729   F277 68                 PLA
2730   F278 CE 28 A4           DEC STIY+1
2731   F27B F0 05              BEQ SETZ        ;BRCH IF LAST ONE
2732   F27D 30 07              BMI ROUT        ;BRCH IF NO MORE
2733   F27F 4A                 LSR A           ;TAKE NEXT BIT
2734   F280 90 DB              BCC ZON         ;...IF IT'S A ONE...
2735   F282 A0 00       SETZ   LDY #0          ;SWITCH TO 2400 HZ
2736   F284 F0 D7              BEQ ZON         ;UNCONDITIONAL BRCH
2737   F286 CE 27 A4    ROUT   DEC STIY        ;ONE LESS BIT
2738   F289 10 CD              BPL TRY         ;ANY MORE? GO BACK
2739   F28B 68          ROUT1  PLA             ;RECOVER CHR
2740   F28C AE 2D A4           LDX CPIY+3      ;RESTORE X
2741   F28F 60                 RTS
2742   F290
2743   F290             ;OUTPUT HALF PULSE FOR 0 (1200 HZ) &
2744   F290             ;TWO HALF PULSES FOR 1 (2400 HZ)  (00 TSPEED)
2745   F290 48          OUTTA1 PHA
2746   F291 8D 28 A4           STA STIY+1      ;STORE ACC
2747   F294 A2 02       OUTTA2 LDX #2          ;# OF HALF PULSES
2748   F296 A9 D0              LDA #$D0        ;1/2 PULSE OF 2400
2749   F298 8D 06 A8           STA T1LL
2750   F29B A9 00              LDA #00
2751   F29D 8D 07 A8           STA T1LH
2752   F2A0 20 BC FF           JSR PATC25      ;WAIT TILL COMPLETED
2753   F2A3 4E 28 A4           LSR STIY+1      ;GET BITS FROM CHR
2754   F2A6 B0 0A              BCS OUTTA3
2755   F2A8 A9 A0              LDA #$A0        ;BIT=0 ,OUTPUT 1200 HZ
2756   F2AA 8D 06 A8           STA T1LL
2757   F2AD A9 01              LDA #$01
2758   F2AF 8D 07 A8           STA T1LH
2759   F2B2 20 BC FF    OUTTA3 JSR PATC25
2760   F2B5 CA                 DEX
2761   F2B6 10 FA              BPL OUTTA3      ;OUTPUT 3 HALF PULSES
2762   F2B8 88                 DEY
2763   F2B9 10 D9              BPL OUTTA2      ;ALL BITS ?
2764   F2BB 4C 8B F2           JMP ROUT1       ;RESTORE REGS
2765   F2BE EA                 NOP
2766   F2BF EA                 NOP
2767   F2C0
2768   F2C0             ;SET SPEED FROM NORMAL TO 3 TIMES NORMAL
2769   F2C0 AD 08 A4    SETSPD LDA TSPEED      ;SPEED FLG
2770   F2C3 6A                 ROR A           ;NORMAL OR 3* NORM
2771   F2C4 A9 0C              LDA #12
2772   F2C6 90 02              BCC SETSP1
2773   F2C8 A9 04              LDA #4
2774   F2CA 8D 0A A4    SETSP1 STA NPUL
2775   F2CD A9 12              LDA #18
2776   F2CF 90 02              BCC SETSP2
2777   F2D1 A9 06              LDA #6
2778   F2D3 8D 0C A4    SETSP2 STA TIMG+1
2779   F2D6 60                 RTS
2780   F2D7             ;.FILE A3/2
2781   F2D7
2782   F2D7             ; ADDRESS TABLE FOR EACH PRINT COLUMN
2783   F2D7             ; EACH TBL CONTAINS DOT PATTERNS FOR 1 OF THE 5 COLUMNS.
2784   F2D7             ;   DATA ARE STORED WITH EACH BYTE DEFINING ONE COLUMN...
2785   F2D7             ; OF A CHARACTER, WITH THE TOP DOT CORRESPONDING TO THE..
2786   F2D7             ; LSB IN THE BYTE
2787   F2D7 E1F221F361F3MTBL   .DW COL0,COL1,COL2,COL3,COL4
2787   F2DD A1F3E1F3
2788   F2E1
2789   F2E1             ;DOT PATTERNS FOR COLUMN ZERO (LEFTMOST COLUMN)
2790   F2E1 3E7E7F3E7F7FCOL0   .DB $3E,$7E,$7F,$3E,$7F,$7F,$7F,$3E  ;@ -- G
2790   F2E7 7F3E
2791   F2E9 7F00207F7F7F       .DB $7F,$00,$20,$7F,$7F,$7F,$7F,$3E  ;H -- O
2791   F2EF 7F3E
2792   F2F1 7F3E7F46013F       .DB $7F,$3E,$7F,$46,$01,$3F,$07,$7F  ;P -- W
2792   F2F7 077F
2793   F2F9 6307617F0300       .DB $63,$07,$61,$7F,$03,$00,$02,$40  ;X -- (
2793   F2FF 0240
2794   F301 000000142463       .DB $00,$00,$00,$14,$24,$63,$60,$00  ;  -- '
2794   F307 6000
2795   F309 000014084008       .DB $00,$00,$14,$08,$40,$08,$40,$60  ;( -- /
2795   F30F 4060
2796   F311 3E4462411827       .DB $3E,$44,$62,$41,$18,$27,$3C,$01  ;0 -- 7
2796   F317 3C01
2797   F319 364600400814       .DB $36,$46,$00,$40,$08,$14,$41,$02  ;8 -- ?
2797   F31F 4102
2798   F321
2799   F321             ;DOT PATTERNS FOR COLUMN 1
2800   F321 410949414149COL1   .DB $41,$09,$49,$41,$41,$49,$09,$41  ;@ -- G
2800   F327 0941
2801   F329 084140084002       .DB $08,$41,$40,$08,$40,$02,$06,$41  ;H -- O
2801   F32F 0641
2802   F331 094109490140       .DB $09,$41,$09,$49,$01,$40,$18,$20  ;P -- W
2802   F337 1820
2803   F339 140851410400       .DB $14,$08,$51,$41,$04,$00,$01,$40  ;X -- (
2803   F33F 0140
2804   F341 0000077F2A13       .DB $00,$00,$07,$7F,$2A,$13,$4E,$04  ;  -- '
2804   F347 4E04
2805   F349 1C4108083008       .DB $1C,$41,$08,$08,$30,$08,$00,$10  ;( -- /
2805   F34F 0010
2806   F351 514251411445       .DB $51,$42,$51,$41,$14,$45,$4A,$71  ;0 -- 7
2806   F357 4A71
2807   F359 494900341414       .DB $49,$49,$00,$34,$14,$14,$41,$01  ;8 -- ?
2807   F35F 4101
2808   F361
2809   F361             ;DOT PATTERNS FOR COLUMN 2
2810   F361 5D0949414149COL2   .DB $5D,$09,$49,$41,$41,$49,$09,$41  ;@ -- G
2810   F367 0941
2811   F369 087F4114400C       .DB $08,$7F,$41,$14,$40,$0C,$08,$41  ;H -- O
2811   F36F 0841
2812   F371 095119497F40       .DB $09,$51,$19,$49,$7F,$40,$60,$18  ;P -- W
2812   F377 6018
2813   F379 087849410841       .DB $08,$78,$49,$41,$08,$41,$01,$40  ;X -- (
2813   F37F 0140
2814   F381 004F00147F08       .DB $00,$4F,$00,$14,$7F,$08,$59,$02  ;  -- '
2814   F387 5902
2815   F389 22223E3E0008       .DB $22,$22,$3E,$3E,$00,$08,$00,$08  ;( -- /
2815   F38F 0008
2816   F391 497F51491245       .DB $49,$7F,$51,$49,$12,$45,$49,$09  ;0 -- 7
2816   F397 4909
2817   F399 494944002214       .DB $49,$49,$44,$00,$22,$14,$22,$51  ;8 -- ?
2817   F39F 2251
2818   F3A1
2819   F3A1             ;DOT PATTERNS FOR COLUMN 3
2820   F3A1 550949412249COL3   .DB $55,$09,$49,$41,$22,$49,$09,$49  ;@ -- G
2820   F3A7 0949
2821   F3A9 08413F224002       .DB $08,$41,$3F,$22,$40,$02,$30,$41  ;H -- O
2821   F3AF 3041
2822   F3B1 092129490140       .DB $09,$21,$29,$49,$01,$40,$18,$20  ;P -- W
2822   F3B7 1820
2823   F3B9 140845001041       .DB $14,$08,$45,$00,$10,$41,$01,$40  ;X -- (
2823   F3BF 0140
2824   F3C1 0000077F2A64       .DB $00,$00,$07,$7F,$2A,$64,$26,$01  ;  -- '
2824   F3C7 2601
2825   F3C9 411C08080008       .DB $41,$1C,$08,$08,$00,$08,$00,$04  ;( -- /
2825   F3CF 0004
2826   F3D1 454049557F45       .DB $45,$40,$49,$55,$7F,$45,$49,$05  ;0 -- 7
2826   F3D7 4905
2827   F3D9 492900004114       .DB $49,$29,$00,$00,$41,$14,$14,$09  ;8 -- ?
2827   F3DF 1409
2828   F3E1             ;DOT PATTERNS FOR COLUMN 4
2829   F3E1 1E7E36221C41COL4   .DB $1E,$7E,$36,$22,$1C,$41,$01,$7A  ;@ -- G
2829   F3E7 017A
2830   F3E9 7F000141407F       .DB $7F,$00,$01,$41,$40,$7F,$7F,$3E  ;H -- O
2830   F3EF 7F3E
2831   F3F1 065E4631013F       .DB $06,$5E,$46,$31,$01,$3F,$07,$7F  ;P -- W
2831   F3F7 077F
2832   F3F9 63074300607F       .DB $63,$07,$43,$00,$60,$7F,$02,$40  ;X -- (
2832   F3FF 0240
2833   F401 000000141263       .DB $00,$00,$00,$14,$12,$63,$50,$00  ;  -- '
2833   F407 5000
2834   F409 000014080008       .DB $00,$00,$14,$08,$00,$08,$00,$03  ;( -- /
2834   F40F 0003
2835   F411 3E4046221039       .DB $3E,$40,$46,$22,$10,$39,$31,$03  ;0 -- 7
2835   F417 3103
2836   F419 361E00004114       .DB $36,$1E,$00,$00,$41,$14,$08,$06  ;8 -- ?
2836   F41F 0806
2837   F421
2838   F421             ;ASCII CHARACTERS FOR KB
2839   F421 2008000D0000ROW1   .DB $20,$08,$00,$0D,$00,$00,$00,$00
2839   F427 0000
2840   F429 00605C000000ROW2   .DB $00,$60,'\',$00,$00,$00,$7F,$00
2840   F42F 7F00
2841   F431 2E4C502D3A30ROW3   .DB ".LP-:0;/"
2841   F437 3B2F
2842   F439 4D4A494F3938ROW4   .DB "MJIO98K,"
2842   F43F 4B2C
2843   F441 424759553736ROW5   .DB "BGYU76HN"
2843   F447 484E
2844   F449 434452543534ROW6   .DB "CDRT54FV"
2844   F44F 4656
2845   F451 5A4157453332ROW7   .DB "ZAWE32SX"
2845   F457 5358
2846   F459 00001B51315EROW8   .DB $00,$00,$1B,"Q1",$5E,"]["
2846   F45F 5D5B
2847   F461
2848   F461             ;DISASSEMBLE INSTRUCTIONS AND SHOW REGS IS REGF SET
2849   F461 AD 0E A4    REGQ   LDA REGF        ;GET FLAG
2850   F464 F0 06              BEQ DISASM
2851   F466 20 32 E2           JSR REG1        ;SHOW THE SIX REGS
2852   F469 20 24 EA           JSR CRCK        ;<CR>
2853   F46C
2854   F46C 20 45 F5    DISASM JSR PRBL2
2855   F46F 20 3C F5           JSR PRPC        ;OUTPUT PROG COUNTR
2856   F472 A0 00              LDY #0
2857   F474 20 56 EB           JSR PCLLD
2858   F477 A8                 TAY
2859   F478 4A                 LSR A
2860   F479 90 0B              BCC IEVEN
2861   F47B 4A                 LSR A
2862   F47C B0 17              BCS ERR
2863   F47E C9 22              CMP #$22
2864   F480 F0 13              BEQ ERR
2865   F482 29 07              AND #7
2866   F484 09 80              ORA #$80
2867   F486 4A          IEVEN  LSR A
2868   F487 AA                 TAX
2869   F488 BD 5B F5           LDA MODE,X
2870   F48B B0 04              BCS RTMODE
2871   F48D 4A                 LSR A
2872   F48E 4A                 LSR A
2873   F48F 4A                 LSR A
2874   F490 4A                 LSR A
2875   F491 29 0F       RTMODE AND #$F
2876   F493 D0 04              BNE GETFMT
2877   F495 A0 80       ERR    LDY #$80
2878   F497 A9 00              LDA #0
2879   F499 AA          GETFMT TAX
2880   F49A BD 9F F5           LDA MODE2,X
2881   F49D 8D 16 01           STA FORMA
2882   F4A0 29 03              AND #3
2883   F4A2 85 EA              STA LENGTH
2884   F4A4 98                 TYA             ;OPCODE
2885   F4A5 29 8F              AND #$8F
2886   F4A7 AA                 TAX
2887   F4A8 98                 TYA             ;OPCODE IN A AGAIN
2888   F4A9 A0 03              LDY #3
2889   F4AB E0 8A              CPX #$8A
2890   F4AD F0 0B              BEQ MNNDX3
2891   F4AF 4A          MNNDX1 LSR A
2892   F4B0 90 08              BCC MNNDX3
2893   F4B2 4A                 LSR A
2894   F4B3 4A          MNNDX2 LSR A
2895   F4B4 09 20              ORA #$20
2896   F4B6 88                 DEY
2897   F4B7 D0 FA              BNE MNNDX2
2898   F4B9 C8                 INY
2899   F4BA 88          MNNDX3 DEY
2900   F4BB D0 F2              BNE MNNDX1
2901   F4BD 48                 PHA             ;SAVE MNEMONIC TABLE INDEX
2902   F4BE 20 56 EB           JSR PCLLD
2903   F4C1 20 46 EA           JSR NUMA
2904   F4C4 20 45 F5           JSR PRBL2       ;PRINT LAST BLANK
2905   F4C7 68                 PLA
2906   F4C8 A8                 TAY
2907   F4C9 B9 B9 F5           LDA MNEML,Y
2908   F4CC 8D 17 01           STA LMNEM
2909   F4CF B9 F9 F5           LDA MNEMR,Y
2910   F4D2 8D 18 01           STA RMNEM
2911   F4D5 A2 03              LDX #3          ;MUST BE
2912   F4D7 A9 00       PRMN1  LDA #0
2913   F4D9 A0 05              LDY #5
2914   F4DB 0E 18 01    PRMN2  ASL RMNEM
2915   F4DE 2E 17 01           ROL LMNEM
2916   F4E1 2A                 ROL A
2917   F4E2 88                 DEY
2918   F4E3 D0 F6              BNE PRMN2
2919   F4E5 69 BF              ADC #'?'+$80    ;ADD "?" OFFSET
2920   F4E7 20 BC E9           JSR OUTALL
2921   F4EA CA                 DEX
2922   F4EB D0 EA              BNE PRMN1
2923   F4ED 20 45 F5           JSR PRBL2
2924   F4F0 A2 06              LDX #6
2925   F4F2 A9 00              LDA #0
2926   F4F4 8D 29 A4           STA STIY+2      ;FLAG
2927   F4F7 E0 03       PRADR1 CPX #3
2928   F4F9 D0 1E              BNE PRADR3      ;IF X=3 PRINT ADDR VALUE
2929   F4FB A4 EA              LDY LENGTH
2930   F4FD F0 1A              BEQ PRADR3      ;1 BYTE INSTR
2931   F4FF AD 16 01    PRADR2 LDA FORMA
2932   F502 C9 E8              CMP #$E8        ;RELATIVE ADDRESSING
2933   F504 20 56 EB           JSR PCLLD
2934   F507 B0 27              BCS RELADR
2935   F509             ;SE IF SYMBOL
2936   F509 48                 PHA
2937   F50A AD 29 A4           LDA STIY+2
2938   F50D D0 03              BNE MR11A
2939   F50F EE 29 A4           INC STIY+2      ;SHOW WE WERE HERE
2940   F512
2941   F512 68          MR11A  PLA
2942   F513 20 46 EA           JSR NUMA
2943   F516 88                 DEY
2944   F517 D0 E6              BNE PRADR2
2945   F519 0E 16 01    PRADR3 ASL FORMA
2946   F51C 90 0E              BCC PRADR4
2947   F51E BD AC F5           LDA CHAR1-1,X
2948   F521 20 BC E9           JSR OUTALL
2949   F524 BD B2 F5           LDA CHAR2-1,X
2950   F527 F0 03              BEQ PRADR4
2951   F529 20 BC E9           JSR OUTALL
2952   F52C CA          PRADR4 DEX
2953   F52D D0 C8              BNE PRADR1
2954   F52F 60                 RTS
2955   F530 20 4D F5    RELADR JSR PCADJ3
2956   F533 AA                 TAX
2957   F534 E8                 INX
2958   F535 D0 01              BNE PRNTXY
2959   F537 C8                 INY
2960   F538 98          PRNTXY TYA
2961   F539 4C 42 EA           JMP WRAX        ;PRINT A &X
2962   F53C AD 26 A4    PRPC   LDA SAVPC+1     ;PRINT PC
2963   F53F AE 25 A4           LDX SAVPC
2964   F542 20 42 EA           JSR WRAX
2965   F545 A9 20       PRBL2  LDA #' '
2966   F547 4C BC E9           JMP OUTALL
2967   F54A A5 EA              LDA LENGTH
2968   F54C 38                 SEC
2969   F54D AC 26 A4    PCADJ3 LDY SAVPC+1     ;PRG CNTR HIGH
2970   F550 AA                 TAX
2971   F551 10 01              BPL PCADJ4
2972   F553 88                 DEY
2973   F554 6D 25 A4    PCADJ4 ADC SAVPC       ;PROG CNTR LOW
2974   F557 90 01              BCC RTS1
2975   F559 C8                 INY
2976   F55A 60          RTS1   RTS
2977   F55B
2978   F55B 40024503D008MODE   .DB $40,2,$45,3,$D0,8,$40,9
2978   F561 4009
2979   F563 30224533D008       .DB $30,$22,$45,$33,$D0,8,$40,9
2979   F569 4009
2980   F56B 40024533D008       .DB $40,2,$45,$33,$D0,8,$40,9
2980   F571 4009
2981   F573 400245B3D008       .DB $40,2,$45,$B3,$D0,8,$40,9
2981   F579 4009
2982   F57B 00224433D08C       .DB 0,$22,$44,$33,$D0,$8C,$44,0
2982   F581 4400
2983   F583 11224433D08C       .DB $11,$22,$44,$33,$D0,$8C,$44,$9A
2983   F589 449A
2984   F58B 10 22 44 33        .DB $10,$22,$44,$33
2985   F58F D0 08 40 09        .DB $D0,8,$40,9
2986   F593 10224433D008       .DB $10,$22,$44,$33,$D0,8,$40,9
2986   F599 4009
2987   F59B 62 13 78 A9        .DB $62,$13,$78,$A9
2988   F59F
2989   F59F 002101020080MODE2  .DB 0,$21,1,2,0,$80,$59,$4D
2989   F5A5 594D
2990   F5A7 1112064A051D       .DB $11,$12,6,$4A,5,$1D
2991   F5AD
2992   F5AD 2C292C23282ECHAR1  .DB ",",$29,",#(","."
2993   F5B3 590058000041CHAR2  .DB "Y",0,"X",0,0,"A"
2994   F5B9
2995   F5B9 1C8A1C235D8BMNEML  .DB $1C,$8A,$1C,$23,$5D,$8B,$1B
2995   F5BF 1B
2996   F5C0 A1                 .DB $A1
2997   F5C1 9D8A1D239D8B       .DB $9D,$8A,$1D,$23,$9D,$8B,$1D,$A1
2997   F5C7 1DA1
2998   F5C9 002919AE69A8       .DB 0,$29,$19,$AE,$69,$A8,$19,$23
2998   F5CF 1923
2999   F5D1 24531B232453       .DB $24,$53,$1B,$23,$24,$53,$19,$A1
2999   F5D7 19A1
3000   F5D9 001A5B5BA569       .DB 0,$1A,$5B,$5B,$A5,$69,$24,$24
3000   F5DF 2424
3001   F5E1 AEAEA8AD2900       .DB $AE,$AE,$A8,$AD,$29,0,$7C,0
3001   F5E7 7C00
3002   F5E9 159C6D9CA569       .DB $15,$9C,$6D,$9C,$A5,$69,$29,$53
3002   F5EF 2953
3003   F5F1 84133411A569       .DB $84,$13,$34,$11,$A5,$69,$23,$A0
3003   F5F7 23A0
3004   F5F9
3005   F5F9 D8625A482662MNEMR  .DB $D8,$62,$5A,$48,$26,$62,$94
3005   F5FF 94
3006   F600 88                 .DB $88
3007   F601 5444C8546844       .DB $54,$44,$C8,$54,$68,$44,$E8,$94
3007   F607 E894
3008   F609 00B4088474B4       .DB 0,$B4,8,$84,$74,$B4,$28,$6E
3008   F60F 286E
3009   F611 74F4CC4A72F2       .DB $74,$F4,$CC,$4A,$72,$F2,$A4,$8A
3009   F617 A48A
3010   F619 00AAA2A27474       .DB 0,$AA,$A2,$A2,$74,$74,$74,$72
3010   F61F 7472
3011   F621 4468B232B200       .DB $44,$68,$B2,$32,$B2,0,$22,0
3011   F627 2200
3012   F629 1A1A26267272       .DB $1A,$1A,$26,$26,$72,$72,$88,$C8
3012   F62F 88C8
3013   F631 C4CA26484444       .DB $C4,$CA,$26,$48,$44,$44,$A2,$C8
3013   F637 A2C8
3014   F639
3015   F639             ;*******************************
3016   F639             ;***    AIM TEXT EDITOR      ***
3017   F639             ;***      05/01/78           ***
3018   F639             ;*******************************
3019   F639
3020   F639             ; R=READ FROM ANY INPUT DEVICE
3021   F639             ; I=INSERT A LINE FROM INPUT DEV
3022   F639             ; K=DELETE A LINE
3023   F639             ; U-GO UP ONE LINE
3024   F639             ; D=GO DOWN ONE LINE
3025   F639             ; L=LIST LINES TO OUTPUT DEV
3026   F639             ; T=GO TO TOP OF TEXT
3027   F639             ; B=GO TO BOTTOM OF TEXT
3028   F639             ; F=FIND STRING
3029   F639             ; C=CHANGE STRING TO NEW STRING
3030   F639             ; Q=QUIT EDITOR
3031   F639             ; <SPACE>=DISPLAY CURRENT LINE
3032   F639
3033   F639             ;***** E COMMAND-EDITOR ENTRY (FROM MONITOR) *****
3034   F639 20 13 EA    EDIT   JSR CRLOW
3035   F63C A0 6C              LDY #EMSG1-M1
3036   F63E 20 AF E7           JSR KEP         ;START UP MSG
3037   F641 20 13 EA           JSR CRLOW
3038   F644 20 A3 E7    EDI0   JSR FROM
3039   F647 B0 FB              BCS EDI0
3040   F649 AD 1E A4           LDA CKSUM       ;IS CLR IF ADDR WAS INPUTTED
3041   F64C F0 03              BEQ *+5
3042   F64E 20 DB E2           JSR WRITAZ      ;OUTPUT DEFAULT ADDR (0200)
3043   F651 A2 01              LDX #1
3044   F653 BD 1C A4    EDI1   LDA ADDR,X
3045   F656 95 E3              STA TEXT,X
3046   F658 95 E1              STA BOTLN,X
3047   F65A 9D 1A A4           STA S1,X        ;FOR MEMORY TEST
3048   F65D CA                 DEX
3049   F65E 10 F3              BPL EDI1
3050   F660 20 3B E8           JSR BLANK2
3051   F663 20 A7 E7    EDI2   JSR TO          ;END
3052   F666 B0 FB              BCS EDI2
3053   F668 20 BC F8           JSR TOPNO       ;TRANSF TEXT TO ADDR FOR RAM CHECK
3054   F66B AD 1E A4           LDA CKSUM       ;IS CLR IF ADDR WAS INPUTTED
3055   F66E F0 10              BEQ EDI4        ;BRNCH IF NOT DEFAULT VALUE
3056   F670 20 34 F9           JSR SAVNOW
3057   F673 20 B6 F6    EDI3   JSR EDI         ;CARRY IS SET IF NO RAM THERE
3058   F676 90 FB              BCC EDI3
3059   F678 A9 00              LDA #0          ;SET UPPER LIMIT TO BEGINNING...
3060   F67A 8D 1C A4           STA ADDR        ;OF PAGE
3061   F67D 20 DB E2           JSR WRITAZ      ;OUTPUT DEFAULT VALUE ,UPPER LIMIT
3062   F680 AD 1C A4    EDI4   LDA ADDR
3063   F683 85 E5              STA END
3064   F685 AD 1D A4           LDA ADDR+1
3065   F688 85 E6              STA END+1
3066   F68A 20 34 F9           JSR SAVNOW
3067   F68D             ;NOW SEE IF MEMORY IS THERE
3068   F68D 20 B6 F6    EDI5   JSR EDI
3069   F690 90 FB              BCC EDI5
3070   F692 A5 E6              LDA END+1       ;CMP WITH END
3071   F694 CD 1D A4           CMP ADDR+1
3072   F697 F0 11              BEQ EDI7
3073   F699 B0 13              BCS EDI8
3074   F69B 20 BC F8    EDI6   JSR TOPNO       ;RESTORE NOWLN
3075   F69E A9 00              LDA #0
3076   F6A0 91 DF              STA (NOWLN),Y   ;END OF TEXT MARKER
3077   F6A2 20 13 EA           JSR CRLOW
3078   F6A5 A9 52              LDA #'R'        ;FORCE READ COMMAND
3079   F6A7 4C 8D FA           JMP ENTRY
3080   F6AA A5 E5       EDI7   LDA END         ;IF ZERO MEM IS OKAY
3081   F6AC F0 ED              BEQ EDI6
3082   F6AE A9 00       EDI8   LDA #0
3083   F6B0 8D 1C A4           STA ADDR
3084   F6B3 4C 33 EB           JMP MEMERR      ;NO MEMORY FOR THOSE LIMITS
3085   F6B6
3086   F6B6 A0 00       EDI    LDY #0          ;CHCK IF MEMORY WRITES
3087   F6B8 20 B7 FE           JSR PATCH6      ;GET BYTE ADDR BY ADDR,ADDR+1
3088   F6BB 48                 PHA             ;SAVE IT
3089   F6BC A9 AA              LDA #$AA        ;SET THIS PATTERN
3090   F6BE 20 78 EB           JSR SADDR       ;CHCK IT
3091   F6C1 D0 09              BNE EDI2B
3092   F6C3 68                 PLA
3093   F6C4 20 78 EB           JSR SADDR       ;RESTORE CHR
3094   F6C7 EE 1D A4           INC ADDR+1      ;NEXT PAG
3095   F6CA 18                 CLC             ;IT WROTE
3096   F6CB 60                 RTS
3097   F6CC 38          EDI2B  SEC             ;DIDNT WRITE
3098   F6CD 68                 PLA
3099   F6CE 60                 RTS
3100   F6CF
3101   F6CF             ;***** T COMMAND-REENTRY EDITOR *****
3102   F6CF             ;RE-ENTRY POINT,TEXT ALREADY THERE
3103   F6CF 20 24 EA    REENTR JSR CRCK        ;<CR> IF PRI ON
3104   F6D2 20 BC F8    TP     JSR TOPNO       ;GO TO TOP
3105   F6D5 4C B9 F7           JMP IN03A       ;DISPLAY LINE
3106   F6D8
3107   F6D8             ;***** U COMMAND-UP LINE *****
3108   F6D8             ;GO UP ONE LINE BUT...
3109   F6D8             ;DOWN IN ADDRESSING MEMORY
3110   F6D8 20 DB F8    DNNO   JSR ATTOP       ;THIS RTN DOESNT PRINT
3111   F6DB 90 06              BCC DOW1        ;NOT TOP
3112   F6DD 20 27 F7           JSR PLNE        ;ARE AT TOP
3113   F6E0 4C 78 FA           JMP ERR0
3114   F6E3 A0 00       DOW1   LDY #0
3115   F6E5 20 1D F9           JSR SUB         ;DECREMENT NOWLN PAST <CR>
3116   F6E8 20 1D F9    DOW2   JSR SUB
3117   F6EB 20 DB F8           JSR ATTOP
3118   F6EE B0 30              BCS UP4
3119   F6F0 B1 DF              LDA (NOWLN),Y
3120   F6F2 C9 0D              CMP #CR
3121   F6F4 D0 F2              BNE DOW2
3122   F6F6 4C 28 F9           JMP AD1
3123   F6F9
3124   F6F9             ;***** D COMMAND-DOWN LINE *****
3125   F6F9             ;GO DOWN ONE LINE BUT...
3126   F6F9             ;UP IN ADDRESSING MEMORY
3127   F6F9 20 09 F7    UP     JSR UPNO
3128   F6FC 20 27 F7           JSR PLNE        ;DISPLAY LINE & CHCK BOTTOM
3129   F6FF 20 E9 F8           JSR ATBOT
3130   F702 90 1C              BCC UP4
3131   F704 A0 72              LDY #EMSG2-M1   ;PRINT "END"
3132   F706 4C AF E7           JMP KEP
3133   F709 A0 00       UPNO   LDY #0
3134   F70B 20 E9 F8           JSR ATBOT
3135   F70E 90 03              BCC UP1
3136   F710 4C 5C FA           JMP ENDERR
3137   F713 B1 DF       UP1    LDA (NOWLN),Y
3138   F715 F0 09              BEQ UP4
3139   F717 C8                 INY
3140   F718 C9 0D              CMP #CR
3141   F71A D0 F7              BNE UP1
3142   F71C 98                 TYA
3143   F71D 20 2A F9           JSR ADDA        ;ADD LENGTH TO CURRENT LINE
3144   F720 60          UP4    RTS
3145   F721
3146   F721             ;***** B COMMAND-GO TO BOTTOM *****
3147   F721 20 C5 F8    BT     JSR SETBOT
3148   F724             ;START U-COMMAND HERE
3149   F724 20 D8 F6    DOWN   JSR DNNO        ;U COMMAND
3150   F727
3151   F727             ;***** <SPACE> COMMAND-DISPLAY CURRENT LINE *****
3152   F727 A0 00       PLNE   LDY #0          ;PRINT CURRENT LINE
3153   F729 B1 DF       P02    LDA (NOWLN),Y
3154   F72B F0 0E              BEQ P01         ;PAST END ?
3155   F72D C9 0D              CMP #CR         ;DONE?
3156   F72F F0 0A              BEQ P01
3157   F731 20 BC E9           JSR OUTALL      ;PUT IT SOMEWHERE
3158   F734 99 38 A4           STA DIBUFF,Y
3159   F737 C8                 INY
3160   F738 4C 29 F7           JMP P02
3161   F73B 84 EA       P01    STY LENGTH
3162   F73D 84 E9              STY OLDLEN
3163   F73F AC 13 A4    P03    LDY OUTFLG      ;ONE MORE <CR> FOR TAPE
3164   F742 C0 0D              CPY #CR
3165   F744 F0 03              BEQ P00
3166   F746 4C F0 E9           JMP CRLF        ;TO OUTPUT DEV
3167   F749 4C 24 EA    P00    JMP CRCK        ;<CR>, & DONT CLR DISPL
3168   F74C
3169   F74C             ;***** K COMMAND-KILL LINE *****
3170   F74C             ;DELETE CURRENT LINE
3171   F74C 20 B6 F8    DLNE   JSR KIFLG       ;CLR K OR I COMM FLG
3172   F74F EA                 NOP
3173   F750 EA                 NOP
3174   F751 EA                 NOP
3175   F752 20 27 F7           JSR PLNE
3176   F755 20 E9 F8           JSR ATBOT
3177   F758 B0 CD              BCS PLNE        ;AT END OF TEXT
3178   F75A A0 00              LDY #0
3179   F75C 84 EA              STY LENGTH
3180   F75E 20 3F F9           JSR REPLAC      ;KILL LINE
3181   F761 4C 27 F7           JMP PLNE
3182   F764
3183   F764             ;***** I COMMAND-INSERT LINE *****
3184   F764 20 6D F7    IN     JSR INL
3185   F767 20 F9 F6           JSR UP          ;DISPLAY NEXT LINE DOWN
3186   F76A 4C 78 FA           JMP ERR0        ;IF AT BOTTOM PRINT "END"
3187   F76D 20 B6 F8    INL    JSR KIFLG       ;CLR K OR I COMM FLG
3188   F770 A0 00              LDY #0          ;GET LINE INTO DIBUFF
3189   F772 84 E9              STY OLDLEN
3190   F774 20 BD E7           JSR PROMPT
3191   F777 20 44 EB           JSR CLR
3192   F77A 20 93 E9    IN02   JSR INALL
3193   F77D 20 F8 FE           JSR PATC12      ;CLR, SO WE CAN OUTPUT TO PRI
3194   F780 C9 7F              CMP #$7F        ;RUB
3195   F782 4C 2A FF           JMP PATC17      ;NO ZEROS IN CASE OF PAPER TAPE
3196   F785 C9 0A       IN02A  CMP #LF
3197   F787 F0 F1              BEQ IN02
3198   F789 C9 0D              CMP #CR
3199   F78B F0 1B              BEQ IN03
3200   F78D C0 3C              CPY #60         ;DO NOT INCR Y IF 60
3201   F78F B0 08              BCS IN03B
3202   F791 99 38 A4           STA DIBUFF,Y
3203   F794 C8                 INY
3204   F795 C0 3C              CPY #60
3205   F797 D0 E1              BNE IN02        ;CONTIN , DISP WONT ALLOW > 60 CHR`
3206   F799 A0 3C       IN03B  LDY #60         ;SET Y TO MAX OF 60
3207   F79B A9 01              LDA #$01
3208   F79D 0D 11 A4           ORA PRIFLG      ;DO NOT OUTPUT TO PRI ANY MORE
3209   F7A0 8D 11 A4           STA PRIFLG      ;OTHERWISE CLOBBERS THE BUFFER
3210   F7A3 8C 15 A4           STY CURPO2
3211   F7A6 D0 D2              BNE IN02        ;GO BACK
3212   F7A8 84 EA       IN03   STY LENGTH
3213   F7AA C0 00              CPY #0          ;FIRST CHAR?
3214   F7AC D0 17              BNE IN05
3215   F7AE AD 19 A4           LDA COUNT       ;K OR I COMM FLG ?
3216   F7B1 D0 12              BNE IN05        ;BRANCH IF C COMMAND
3217   F7B3 20 24 EA           JSR CRCK        ;<CR> IF PRI PNTR DIFF FROM 0
3218   F7B6 20 03 FF           JSR PATC13      ;TURN ON TAPES & SET DEFAULT DEV
3219   F7B9 20 27 F7    IN03A  JSR PLNE        ;DISPLAY NEXT LINE DOWN
3220   F7BC 20 09 F7           JSR UPNO        ;PRINT "END" IF BOTTOM
3221   F7BF 20 D8 F6           JSR DNNO
3222   F7C2 4C 78 FA           JMP ERR0
3223   F7C5 20 3F F9    IN05   JSR REPLAC      ;INSERT THE LINE
3224   F7C8 4C 24 EA           JMP CRCK        ;<CR> IF PRI PTR NOT 0
3225   F7CB
3226   F7CB             ;***** R COMMAND-READ LINE *****
3227   F7CB             ;READ TEXT FROM ANY INPUT DEVICE UNTIL
3228   F7CB             ;TWO CONSECUTIVE <CR> ARE ENCOUNTER.
3229   F7CB 20 48 E8    INPU   JSR WHEREI
3230   F7CE AC 12 A4           LDY INFLG       ;IF TAPE DO NOT ERRASE BUFFER
3231   F7D1 C0 54              CPY #'T'
3232   F7D3 F0 03              BEQ INPU1
3233   F7D5 20 13 EA           JSR CRLOW
3234   F7D8 20 6D F7    INPU1  JSR INL
3235   F7DB 20 09 F7           JSR UPNO        ;NEXT LINE
3236   F7DE 4C D8 F7           JMP INPU1
3237   F7E1
3238   F7E1             ;***** L COMMAND-LIST LINES *****
3239   F7E1             ;PRINT FROM HERE N LINES TO ACTIVE OUTPUT DEV
3240   F7E1 20 37 E8    LST    JSR PSL1        ;PRINT "/"
3241   F7E4 20 85 E7           JSR GCNT        ;GET LINES COUNT
3242   F7E7 20 13 EA           JSR CRLOW
3243   F7EA 20 71 E8           JSR WHEREO      ;WHERE TO
3244   F7ED 4C F8 F7           JMP LST02       ;ONE MORE LINE
3245   F7F0 20 07 E9    LST01  JSR RCHEK
3246   F7F3 20 90 E7           JSR DONE
3247   F7F6 F0 0B              BEQ LST3
3248   F7F8 20 27 F7    LST02  JSR PLNE
3249   F7FB 20 09 F7           JSR UPNO        ;NEXT LINE
3250   F7FE 20 E9 F8           JSR ATBOT
3251   F801 90 ED              BCC LST01       ;NO
3252   F803 20 3F F7    LST3   JSR P03         ;ONE MORE CRLF FOR TAPE
3253   F806 20 0D FF           JSR PATC14      ;CLOSE TAPE IF NEEDED
3254   F809 4C 5C FA           JMP ENDERR
3255   F80C
3256   F80C             ;***** F COMMAND-FIND STRING *****
3257   F80C             ;FIND STRING AND PRINT LINE TO TERMINAL
3258   F80C 20 1E F8    FCHAR  JSR FCH
3259   F80F AD 15 A4    FCHA1  LDA CURPO2      ;SAVE BUFFER PNTR
3260   F812 48                 PHA
3261   F813 20 44 EB           JSR CLR         ;CLEAR DISP PNTR
3262   F816 20 27 F7           JSR PLNE
3263   F819 68                 PLA
3264   F81A 8D 15 A4           STA CURPO2
3265   F81D 60                 RTS
3266   F81E             ;FIND A CHARACTER STRING
3267   F81E A0 00       FCH    LDY #0
3268   F820 20 BD E7           JSR PROMPT
3269   F823 20 5F E9    FC1    JSR RDRUP       ;GET THE CHARACTER
3270   F826 C9 0D              CMP #CR         ;REUSE OLD ARGUMENT??
3271   F828 D0 0A              BNE FC3
3272   F82A C0 00              CPY #0          ;FIRST CHAR?
3273   F82C D0 06              BNE FC3
3274   F82E 20 09 F7    FC2    JSR UPNO        ;NEXT LINE DOWN
3275   F831 4C 49 F8           JMP FC5
3276   F834 C9 0D       FC3    CMP #CR         ;DONE
3277   F836 F0 0B              BEQ FC4
3278   F838 99 EB 00           STA STRING,Y
3279   F83B C8                 INY
3280   F83C C0 14              CPY #20         ;MAX LENGTH
3281   F83E D0 E3              BNE FC1
3282   F840 4C 72 FA           JMP ERROR
3283   F843 20 24 EA    FC4    JSR CRCK        ;CLEAR DISPLAY
3284   F846 8C 29 A4           STY STIY+2      ;COUNT OF CHARACTERS
3285   F849 A0 00       FC5    LDY #0
3286   F84B 8C 15 A4           STY CURPO2      ;START AT BEGINNING OF LINENTR IS
3287   F84E AC 15 A4    FC6    LDY CURPO2      ;CLOBBER
3288   F851 A2 00              LDX #0
3289   F853 B1 DF       FC7    LDA (NOWLN),Y   ;GET THE CHARACTER
3290   F855 D0 03              BNE FC8         ;NOT AT END
3291   F857 4C 5C FA           JMP ENDERR
3292   F85A C9 0D       FC8    CMP #CR         ;END OF LINE
3293   F85C F0 D0              BEQ FC2
3294   F85E D5 EB              CMP STRING,X
3295   F860 F0 06              BEQ FC9
3296   F862 EE 15 A4           INC CURPO2
3297   F865 4C 4E F8           JMP FC6
3298   F868 C8          FC9    INY
3299   F869 E8                 INX
3300   F86A EC 29 A4           CPX STIY+2      ;DONE?
3301   F86D D0 E4              BNE FC7
3302   F86F 60                 RTS
3303   F870
3304   F870             ;***** Q COMMAND-EXIT EDITOR *****
3305   F870             ; EXIT THE TEXT EDITOR NEATLY
3306   F870 20 13 EA    STOP   JSR CRLOW
3307   F873 4C A1 E1           JMP COMIN
3308   F876
3309   F876             ;***** C COMMAND-CHANGE STRING *****
3310   F876             ;CHANGE STRING TO ANOTHER STRING IN A LINE
3311   F876 20 B2 F8    CHNG   JSR CFLG        ;SET C COMMAND FLG
3312   F879 20 0C F8           JSR FCHAR       ;FIND CORRECT LINE
3313   F87C 20 3C E9    CHN1   JSR READ        ;IS <CR> IF OK
3314   F87F C9 0D              CMP #CR
3315   F881 F0 09              BEQ CHN2
3316   F883 20 2E F8           JSR FC2         ;TRY NEXT ONE
3317   F886 20 0F F8           JSR FCHA1       ; SHOW LINE
3318   F889 4C 7C F8           JMP CHN1
3319   F88C AD 29 A4    CHN2   LDA STIY+2      ;GET CHAR COUNT
3320   F88F 85 E9              STA OLDLEN      ;GET READY FOR REPLAC
3321   F891 AD 15 A4           LDA CURPO2      ;PNTR TO BEGINNING OF STRING
3322   F894 48                 PHA             ;SAVE IT
3323   F895 20 2A F9           JSR ADDA        ;ADD TO NOWLN (LINE PNTR)
3324   F898 20 44 EB           JSR CLR         ;CLEAR DISP
3325   F89B A0 05              LDY #M3-M1      ;PRINT "TO"
3326   F89D 20 AF E7           JSR KEP
3327   F8A0 A0 00              LDY #0
3328   F8A2 20 7A F7           JSR IN02        ;GET NEW STRING & REPLAC
3329   F8A5 68                 PLA
3330   F8A6 AA                 TAX
3331   F8A7 F0 06              BEQ CHN4
3332   F8A9 20 1D F9    CHN3   JSR SUB         ;RESTORE NOWLN WHERE IT WAS
3333   F8AC CA                 DEX
3334   F8AD D0 FA              BNE CHN3
3335   F8AF 4C 27 F7    CHN4   JMP PLNE        ;DISPLAY THE CHANGED LINE
3336   F8B2
3337   F8B2             ;THE FOLLOWING ARE SUBROUTINES USED BY COMMANDS
3338   F8B2 A9 01       CFLG   LDA #1          ;SET FLG FOR C COMMAND
3339   F8B4 D0 02              BNE KI2
3340   F8B6 A9 00       KIFLG  LDA #0          ;CLR K OR I COMMAND FLG
3341   F8B8 8D 19 A4    KI2    STA COUNT
3342   F8BB 60                 RTS
3343   F8BC
3344   F8BC A5 E3       TOPNO  LDA TEXT        ;SET CURRENT LINE TO TOP
3345   F8BE A6 E4              LDX TEXT+1
3346   F8C0 85 DF       TPO1   STA NOWLN
3347   F8C2 86 E0              STX NOWLN+1
3348   F8C4 60                 RTS
3349   F8C5
3350   F8C5 A5 E1       SETBOT LDA BOTLN       ;SET CURRENT LINE TO BOTTOM
3351   F8C7 A6 E2              LDX BOTLN+1
3352   F8C9 85 E7              STA SAVE
3353   F8CB 86 E8              STX SAVE+1
3354   F8CD 4C C0 F8           JMP TPO1
3355   F8D0
3356   F8D0 AD 1C A4    RESNOW LDA ADDR        ;RESTORE CURRENT LINE ADDRESS
3357   F8D3 85 DF              STA NOWLN
3358   F8D5 AD 1D A4           LDA ADDR+1
3359   F8D8 85 E0              STA NOWLN+1
3360   F8DA 60                 RTS
3361   F8DB
3362   F8DB             ; SEE IF CURRENT LINE AT TOP (C SET IF SO)
3363   F8DB A5 DF       ATTOP  LDA NOWLN
3364   F8DD C5 E3              CMP TEXT
3365   F8DF D0 16              BNE AT01
3366   F8E1 A5 E0              LDA NOWLN+1
3367   F8E3 C5 E4              CMP TEXT+1
3368   F8E5 D0 10              BNE AT01
3369   F8E7 38                 SEC
3370   F8E8 60                 RTS
3371   F8E9
3372   F8E9             ; SEE IF CURRENT LINE AT BOTTOM (C SET IF SO)
3373   F8E9 A5 DF       ATBOT  LDA NOWLN
3374   F8EB A6 E0              LDX NOWLN+1
3375   F8ED C5 E1              CMP BOTLN
3376   F8EF D0 06              BNE AT01
3377   F8F1 E4 E2              CPX BOTLN+1
3378   F8F3 D0 02              BNE AT01
3379   F8F5 38          AT02   SEC
3380   F8F6 60                 RTS
3381   F8F7 18          AT01   CLC
3382   F8F8 60                 RTS
3383   F8F9
3384   F8F9             ;SEE IF WE RAN PAST END OF BUFFER LIMIT
3385   F8F9 A5 E1       ATEND  LDA BOTLN
3386   F8FB A6 E2              LDX BOTLN+1
3387   F8FD E4 E6              CPX END+1       ;HIGH BYTE > OR = ?
3388   F8FF 90 F6              BCC AT01
3389   F901 D0 F2              BNE AT02
3390   F903 C5 E5              CMP END         ;LOW BYTE > OR = ?
3391   F905 90 F0              BCC AT01
3392   F907 B0 EC              BCS AT02
3393   F909
3394   F909             ; SAVE CURRENT LINE (NEWLN) IN S1
3395   F909 A5 DF       NOWS1  LDA NOWLN
3396   F90B A6 E0              LDX NOWLN+1
3397   F90D 4C 16 F9           JMP ADDS1A
3398   F910
3399   F910             ; MOVE ADDR INTO S1
3400   F910 AD 1C A4    ADDRS1 LDA ADDR
3401   F913 AE 1D A4           LDX ADDR+1
3402   F916 8D 1A A4    ADDS1A STA S1
3403   F919 8E 1B A4           STX S1+1
3404   F91C 60                 RTS
3405   F91D
3406   F91D             ; SUBTRACT ONE FROM CURRENT LINE (NOWLN)
3407   F91D C6 DF       SUB    DEC NOWLN
3408   F91F A5 DF              LDA NOWLN
3409   F921 C9 FF              CMP #$FF
3410   F923 D0 02              BNE SUB1
3411   F925 C6 E0              DEC NOWLN+1
3412   F927 60          SUB1   RTS
3413   F928
3414   F928             ; ADD ACC TO CURRENT LINE (NOWLN)
3415   F928 A9 01       AD1    LDA #1
3416   F92A 18          ADDA   CLC
3417   F92B 65 DF              ADC NOWLN
3418   F92D 85 DF              STA NOWLN
3419   F92F 90 02              BCC ADDA1
3420   F931 E6 E0              INC NOWLN+1
3421   F933 60          ADDA1  RTS
3422   F934
3423   F934 A5 DF       SAVNOW LDA NOWLN       ;SAVE CURRENT LINE INTO ADDR
3424   F936 8D 1C A4           STA ADDR
3425   F939 A5 E0              LDA NOWLN+1
3426   F93B 8D 1D A4           STA ADDR+1
3427   F93E 60          REP2   RTS
3428   F93F
3429   F93F             ;MOVE CURRENT TEXT AROUND TO HAVE
3430   F93F             ;SPACE TO PUT IN THE NEW BUFFER
3431   F93F A4 EA       REPLAC LDY LENGTH
3432   F941 C4 E9              CPY OLDLEN      ;COMPARE OLD AND NEW LENGTHS
3433   F943 D0 1A              BNE R2W         ;BRANCH IF DIFF
3434   F945 F0 07              BEQ R87         ;LENGTHS ARE EQUAL. JUST REPLACE
3435   F947 A9 0D       R8     LDA #CR
3436   F949 91 DF              STA (NOWLN),Y
3437   F94B 20 4A FA           JSR GOGO
3438   F94E
3439   F94E             ;LENGTH = OLDLEN
3440   F94E 88          R87    DEY
3441   F94F C0 FF              CPY #$FF
3442   F951 F0 EB              BEQ REP2
3443   F953 B9 38 A4    R88    LDA DIBUFF,Y
3444   F956 91 DF              STA (NOWLN),Y
3445   F958 20 4A FA           JSR GOGO
3446   F95B 88                 DEY
3447   F95C 10 F5              BPL R88
3448   F95E 60                 RTS
3449   F95F B0 6E       R2W    BCS R100        ;LENGTH > OLDLEN
3450   F961
3451   F961             ;LENGTH < OLDLEN
3452   F961 20 34 F9           JSR SAVNOW      ;PUT NOWLN INTO ADDR
3453   F964 20 10 F9           JSR ADDRS1      ;PUT IT IN S1 ALSO
3454   F967 A5 E9              LDA OLDLEN
3455   F969 38                 SEC
3456   F96A E5 EA              SBC LENGTH      ;GET DIFFERENCE IN LENGTHS
3457   F96C A4 EA              LDY LENGTH
3458   F96E D0 07              BNE RQP
3459   F970 AE 19 A4           LDX COUNT       ;C-COMM ?
3460   F973 D0 02              BNE RQP         ;YES, JUMP
3461   F975 69 00              ADC #0          ;INCLUDE <CR>
3462   F977 48          RQP    PHA
3463   F978 18                 CLC
3464   F979 6D 1A A4           ADC S1
3465   F97C 8D 1A A4           STA S1
3466   F97F 90 03              BCC R6
3467   F981 EE 1B A4           INC S1+1
3468   F984 A9 1A       R6     LDA #S1
3469   F986 20 58 EB           JSR LDAY
3470   F989 91 DF              STA (NOWLN),Y   ;...AND NOVE IT UP (DOWN IN ADDR)
3471   F98B 20 4A FA           JSR GOGO
3472   F98E AA                 TAX
3473   F98F AD 1A A4           LDA S1
3474   F992 C5 E1              CMP BOTLN       ;DONE ??
3475   F994 D0 07              BNE R5
3476   F996 AD 1B A4           LDA S1+1
3477   F999 C5 E2              CMP BOTLN+1
3478   F99B F0 0E              BEQ R7
3479   F99D 20 28 F9    R5     JSR AD1
3480   F9A0 EE 1A A4           INC S1
3481   F9A3 D0 03              BNE R55
3482   F9A5 EE 1B A4           INC S1+1
3483   F9A8 4C 84 F9    R55    JMP R6
3484   F9AB 20 D0 F8    R7     JSR RESNOW      ;RESTORE NOWLN
3485   F9AE 68                 PLA             ;RESTORE DIFFERENCE
3486   F9AF 8D 2A A4           STA CPIY        ;SAVE IT
3487   F9B2 A5 E1              LDA BOTLN
3488   F9B4 38                 SEC
3489   F9B5 ED 2A A4           SBC CPIY        ;AND SUBTRACT IT FROM BOTTOM
3490   F9B8 85 E1              STA BOTLN
3491   F9BA B0 02              BCS R9
3492   F9BC C6 E2              DEC BOTLN+1
3493   F9BE AD 19 A4    R9     LDA COUNT       ;C COMM OR K ,I COMM ?
3494   F9C1 D0 04              BNE R10
3495   F9C3 A4 EA              LDY LENGTH
3496   F9C5 D0 05              BNE R11
3497   F9C7 A4 EA       R10    LDY LENGTH
3498   F9C9 D0 83              BNE R87
3499   F9CB 60                 RTS
3500   F9CC 4C 47 F9    R11    JMP R8
3501   F9CF
3502   F9CF             ;LENGTH > OLDLEN
3503   F9CF A5 EA       R100   LDA LENGTH      ;NEW LINE IS LONGER
3504   F9D1 38                 SEC
3505   F9D2 E5 E9              SBC OLDLEN
3506   F9D4 A4 E9              LDY OLDLEN
3507   F9D6 D0 02              BNE R101        ;ALREADY HAVE ROOM FOR CR
3508   F9D8 69 00              ADC #0          ;ADD ONE TO DIFFERENCE
3509   F9DA 48          R101   PHA
3510   F9DB 20 34 F9           JSR SAVNOW      ;NOWLN INTO S1
3511   F9DE 20 C5 F8           JSR SETBOT
3512   F9E1 A0 00              LDY #0
3513   F9E3 B1 DF       R102   LDA (NOWLN),Y
3514   F9E5 C9 00              CMP #0
3515   F9E7 F0 06              BEQ R108
3516   F9E9 20 28 F9           JSR AD1
3517   F9EC 4C E3 F9           JMP R102
3518   F9EF 68          R108   PLA
3519   F9F0 48                 PHA
3520   F9F1 18                 CLC
3521   F9F2 65 E1              ADC BOTLN       ;ADD DIFFERENCE TO END
3522   F9F4 85 E1              STA BOTLN       ;STORE NEW END
3523   F9F6 90 02              BCC R103
3524   F9F8 E6 E2              INC BOTLN+1
3525   F9FA 20 F9 F8    R103   JSR ATEND
3526   F9FD 90 0B              BCC R107
3527   F9FF A5 E7              LDA SAVE        ;RESTORE OLD BOTTOM
3528   FA01 85 E1              STA BOTLN
3529   FA03 A5 E8              LDA SAVE+1
3530   FA05 85 E2              STA BOTLN+1
3531   FA07 4C 5C FA           JMP ENDERR      ;RAN PAST BUFFER END
3532   FA0A 20 09 F9    R107   JSR NOWS1       ;SAVE CURRENT END
3533   FA0D 68                 PLA
3534   FA0E 18                 CLC
3535   FA0F 65 DF              ADC NOWLN
3536   FA11 85 DF              STA NOWLN
3537   FA13 90 02              BCC R104
3538   FA15 E6 E0              INC NOWLN+1
3539   FA17 A9 1A       R104   LDA #S1
3540   FA19 20 58 EB           JSR LDAY
3541   FA1C 91 DF              STA (NOWLN),Y
3542   FA1E 20 4A FA           JSR GOGO
3543   FA21 AD 1A A4           LDA S1
3544   FA24 CD 1C A4           CMP ADDR
3545   FA27 D0 08              BNE R105
3546   FA29 AD 1B A4           LDA S1+1
3547   FA2C CD 1D A4           CMP ADDR+1      ;BACK WHERE WE STARTED ??
3548   FA2F F0 13              BEQ R106        ;BRANCH IF DONE
3549   FA31 20 1D F9    R105   JSR SUB
3550   FA34 CE 1A A4           DEC S1
3551   FA37 AD 1A A4           LDA S1
3552   FA3A C9 FF              CMP #$FF
3553   FA3C D0 03              BNE R1051
3554   FA3E CE 1B A4           DEC S1+1
3555   FA41 4C 17 FA    R1051  JMP R104
3556   FA44 20 D0 F8    R106   JSR RESNOW
3557   FA47 4C BE F9           JMP R9
3558   FA4A
3559   FA4A             ;SEE IF IT WROTE INTO MEMORY
3560   FA4A D1 DF       GOGO   CMP (NOWLN),Y
3561   FA4C F0 0D              BEQ GOGO1
3562   FA4E             ;MOVE ADDRESS
3563   FA4E A5 DF              LDA NOWLN
3564   FA50 8D 1C A4           STA ADDR
3565   FA53 A5 E0              LDA NOWLN+1
3566   FA55 8D 1D A4           STA ADDR+1
3567   FA58 4C 33 EB           JMP MEMERR
3568   FA5B 60          GOGO1  RTS             ;OK
3569   FA5C
3570   FA5C 20 44 EB    ENDERR JSR CLR         ;CLEAR PNTR
3571   FA5F A0 72              LDY #EMSG2-M1   ;PRINT "END"
3572   FA61 20 AF E7           JSR KEP
3573   FA64 20 D8 F6           JSR DNNO        ;BACK UP TO LAST LINE
3574   FA67 20 42 E8           JSR TTYTST      ;IF TTY <CR>
3575   FA6A D0 03              BNE ENDE2
3576   FA6C 20 13 EA           JSR CRLOW
3577   FA6F 4C 78 FA    ENDE2  JMP ERR0
3578   FA72 20 FE E8    ERROR  JSR LL
3579   FA75 20 D4 E7           JSR QM
3580   FA78 20 44 EB    ERR0   JSR CLR
3581   FA7B A2 FF              LDX #$FF
3582   FA7D             COM    =ERR0
3583   FA7D 9A                 TXS
3584   FA7E 20 FE E8           JSR LL          ;I/O TO TERMINAL (KB,D/P OR TTY)
3585   FA81 D8                 CLD
3586   FA82 20 88 FA           JSR COMM
3587   FA85 4C 78 FA           JMP ERR0
3588   FA88
3589   FA88             ;GET EDITOR COMMANDS & DECODE
3590   FA88 A2 00       COMM   LDX #0
3591   FA8A 20 BC FE           JSR PATCH8      ;READ A CHAR WITH "=< >"
3592   FA8D A2 0B       ENTRY  LDX #COMCN1
3593   FA8F DD AC FA    CD02   CMP COMTBL,X    ;COMPARE WITH ALLOWABLE COMMANDS
3594   FA92 F0 0C              BEQ CFND1       ;MATCH ,SO PROCESS COMMAND
3595   FA94 CA                 DEX
3596   FA95 10 F8              BPL CD02
3597   FA97 20 D4 E7           JSR QM          ;NOT IN LIST ,SO NOT LEGAL COMMAND
3598   FA9A 20 24 EA           JSR CRCK
3599   FA9D 4C 78 FA           JMP ERR0
3600   FAA0 20 17 FF    CFND1  JSR PATC15      ;<CR> & START DECODING COMMAND
3601   FAA3 BD B9 FA           LDA JTBL+1,X
3602   FAA6 8D 1B A4           STA S1+1
3603   FAA9 6C 1A A4           JMP (S1)
3604   FAAC
3605   FAAC             COMCN1 =11
3606   FAAC             ;COMMAND TABLE
3607   FAAC 4B2052495544COMTBL .DB "K RIUDLTBFQC"
3607   FAB2 4C5442465143
3608   FAB8 4CF727F7CBF7JTBL   .DW DLNE,PLNE,INPU,IN,DOWN,UP
3608   FABE 64F724F7F9F6
3609   FAC4 E1F7D2F621F7       .DW LST,TP,BT,FCHAR,STOP,CHNG
3609   FACA 0CF870F876F8
3610   FAD0
3611   FAD0             ;READ FROM MEMORY FOR ASSEMBLER
3612   FAD0 98          MREAD  TYA
3613   FAD1 48                 PHA
3614   FAD2 A0 00              LDY #0
3615   FAD4 B1 DF              LDA (NOWLN),Y
3616   FAD6 8D 2A A4           STA CPIY
3617   FAD9 20 28 F9           JSR AD1
3618   FADC 68                 PLA
3619   FADD A8                 TAY
3620   FADE AD 2A A4           LDA CPIY
3621   FAE1 60                 RTS
3622   FAE2
3623   FAE2             ;THIS PROGRAM CONVERS MNEMONIC INSTRUCTIONS INTO MACHINE
3624   FAE2             ;CODE AND STORES IT IN THE DESIGNATED MEMORY AREA
3625   FAE2
3626   FAE2             ;ROM TABLE LOCATIONS:
3627   FAE2 00020008F2FFTYPTR1 .DB 00,02,00,08,$F2,$FF,$80,01
3627   FAE8 8001
3628   FAEA C0E2C0C0FF00       .DB $C0,$E2,$C0,$C0,$FF,00,00
3628   FAF0 00
3629   FAF1 0800108040C0TYPTR2 .DB 08,00,$10,$80,$40,$C0,00,$C0
3629   FAF7 00C0
3630   FAF9 00400000E420       .DB $00,$40,00,00,$E4,$20,$80
3630   FAFF 80
3631   FB00 00FC000808F8CORR   .DB 00,$FC,00,08,08,$F8,$FC,$F4
3631   FB06 FCF4
3632   FB08 0C1004F40020       .DB $0C,$10,04,$F4,00,$20,$10
3632   FB0E 10
3633   FB0F 00000F010101SIZEM  .DB 00,00,$0F,01,01,01,$11,$11
3633   FB15 1111
3634   FB17 020211110212       .DB 02,02,$11,$11,02,$12,00
3634   FB1D 00
3635   FB1E
3636   FB1E 000810182028STCODE .DB $00,$08,$10,$18,$20,$28,$30,$38
3636   FB24 3038
3637   FB26 404850586068       .DB $40,$48,$50,$58,$60,$68,$70,$78
3637   FB2C 7078
3638   FB2E 80889098ACA8       .DB $80,$88,$90,$98,$AC,$A8,$B0,$B8
3638   FB34 B0B8
3639   FB36 CCC8D0D8ECE8       .DB $CC,$C8,$D0,$D8,$EC,$E8,$F0,$F8
3639   FB3C F0F8
3640   FB3E 0C2C4C4C8CAC       .DB $0C,$2C,$4C,$4C,$8C,$AC,$CC,$EC
3640   FB44 CCEC
3641   FB46 8A9AAABACADA       .DB $8A,$9A,$AA,$BA,$CA,$DA,$EA,$FA
3641   FB4C EAFA
3642   FB4E 0E2E4E6E8EAE       .DB $0E,$2E,$4E,$6E,$8E,$AE,$CE,$EE
3642   FB54 CEEE
3643   FB56 0D2D4D6D8DAD       .DB $0D,$2D,$4D,$6D,$8D,$AD,$CD,$ED
3643   FB5C CDED
3644   FB5E 0D0D0C0D0E0DTYPTB  .DB 13,13,12,13,14,13,12,13
3644   FB64 0C0D
3645   FB66 0D0D0C0D0D0D       .DB 13,13,12,13,13,13,12,13
3645   FB6C 0C0D
3646   FB6E 0F0D0C0D090D       .DB 15,13,12,13,9,13,12,13
3646   FB74 0C0D
3647   FB76 080D0C0D080D       .DB 8,13,12,13,8,13,12,13
3647   FB7C 0C0D
3648   FB7E 0F060B0B040A       .DB 15,6,11,11,4,10,8,8
3648   FB84 0808
3649   FB86 0D0D0D0D0D0F       .DB 13,13,13,13,13,15,13,15
3649   FB8C 0D0F
3650   FB8E 070707070509       .DB 7,7,7,7,5,9,3,3
3650   FB94 0303
3651   FB96 010101010201       .DB 1,1,1,1,2,1,1,1
3651   FB9C 0101
3652   FB9E
3653   FB9E             ;PROGRAM STARTS HERE
3654   FB9E AD 25 A4    MNEENT LDA SAVPC       ;TRANSF PC TO ADDR
3655   FBA1 8D 1C A4           STA ADDR
3656   FBA4 AD 26 A4           LDA SAVPC+1
3657   FBA7 8D 1D A4           STA ADDR+1
3658   FBAA 20 24 EA    STARTM JSR CRCK        ;<CR> IF PRI PTR DIFF FROM 0
3659   FBAD A9 00              LDA #0
3660   FBAF 8D 37 A4           STA CODFLG
3661   FBB2 20 3E E8           JSR BLANK
3662   FBB5 20 DB E2           JSR WRITAZ      ;WRITE ADDRESS
3663   FBB8 20 3B E8           JSR BLANK2
3664   FBBB 20 3B E8           JSR BLANK2
3665   FBBE 4C 06 FE           JMP MNEM        ;JUMP TO INPUT MNEMONIC OPCODE
3666   FBC1 A9 00       MODEM  LDA #00         ;SET UP TO FORM MODE MATCH
3667   FBC3 8D 26 01           STA TMASK1
3668   FBC6 8D 27 01           STA TMASK2
3669   FBC9 20 3E E8           JSR BLANK
3670   FBCC AC 2E 01           LDY TYPE
3671   FBCF 38                 SEC
3672   FBD0 6E 26 01    PNTLUP ROR TMASK1      ;SHIFT POINTER TO INSTRUCTION TYPE
3673   FBD3 6E 27 01           ROR TMASK2
3674   FBD6 88                 DEY
3675   FBD7 D0 F7              BNE PNTLUP
3676   FBD9
3677   FBD9             ;TEST FOR ONE BYTE INSTRUCTION
3678   FBD9 AC 2E 01           LDY TYPE
3679   FBDC C0 0D              CPY #$0D
3680   FBDE D0 05              BNE RDADDR
3681   FBE0 A2 00              LDX #00
3682   FBE2
3683   FBE2             ;INPUT ADRESS FIELD
3684   FBE2 4C CB FC           JMP OPCOMP
3685   FBE5 A0 06       RDADDR LDY #06         ;CLEAR ADDRESS FIELD (NON HEX)
3686   FBE7 A9 51              LDA #'Q'
3687   FBE9 99 32 01    CLRLUP STA ADFLD-1,Y
3688   FBEC 88                 DEY
3689   FBED D0 FA              BNE CLRLUP      ;(LEAVES Y = 0 FOR NEXT PHASE)
3690   FBEF 20 5F E9           JSR RDRUP       ;WITH RUBOUT
3691   FBF2 C9 20              CMP #' '        ;IGNORE SPACE CHARACTERS
3692   FBF4 F0 EF              BEQ RDADDR
3693   FBF6 99 33 01    STORCH STA ADFLD,Y     ;STORE ADDRESS CHARACTER
3694   FBF9 C8                 INY
3695   FBFA C0 07              CPY #07
3696   FBFC B0 5C              BCS TRY56
3697   FBFE 20 5F E9           JSR RDRUP       ;READ REMAINDER OF ADDRESS CHARS
3698   FC01 C9 20              CMP #' '        ;THRU WHEN <SPACE> OR <CR>
3699   FC03 D0 05              BNE STOR1
3700   FC05 EE 37 A4           INC CODFLG      ;SET CODE FLG
3701   FC08 D0 04              BNE EVAL
3702   FC0A C9 0D       STOR1  CMP #CR         ;CHECK FOR <CR>
3703   FC0C D0 E8              BNE STORCH
3704   FC0E
3705   FC0E             ;SEPARATE ADDRESS MODE FROM ADDRESS FIELD
3706   FC0E 8C 31 A4    EVAL   STY TEMPX       ;TEMPX NOW HAS NUMBER OF CHAR
3707   FC11 AD 33 01           LDA ADFLD       ;CHECK FIRST CHAR FOR # OR (
3708   FC14 C9 23              CMP #'#'
3709   FC16 F0 25              BEQ HATCJ
3710   FC18 C9 28              CMP #'('
3711   FC1A F0 5A              BEQ PAREN
3712   FC1C AD 31 A4           LDA TEMPX       ;CHECK FOR ACCUMULATOR MODE
3713   FC1F C9 01              CMP #01
3714   FC21 D0 05              BNE TRYZP
3715   FC23 A2 01       ACCUM  LDX #01
3716   FC25 4C CB FC           JMP OPCOMP
3717   FC28 C9 02       TRYZP  CMP #02         ;CHECK FOR ZERO PAGE MODE
3718   FC2A D0 14              BNE TRY34
3719   FC2C AD 2E 01           LDA TYPE        ;CHCK FOR BRNCH WITH RELATIVE ADDR`
3720   FC2F C9 0C              CMP #$0C
3721   FC31 D0 05              BNE ZPAGE
3722   FC33 A2 02              LDX #02
3723   FC35 4C CB FC           JMP OPCOMP
3724   FC38 A2 05       ZPAGE  LDX #05
3725   FC3A 4C CB FC           JMP OPCOMP
3726   FC3D 4C B6 FC    HATCJ  JMP HATCH
3727   FC40 A9 04       TRY34  LDA #04         ;CHECK FOR ABSOLUTE OR ZP,X ORZP,`
3728   FC42 CD 31 A4           CMP TEMPX
3729   FC45 90 15              BCC ABSIND
3730   FC47 A2 02              LDX #02
3731   FC49 20 F1 FD           JSR XORYZ       ;CC = X, CS = Y, NE = ABSOLUTE
3732   FC4C D0 58              BNE ABSOL
3733   FC4E 90 05              BCC ZPX
3734   FC50 A2 03       ZPY    LDX #03         ;CARRY SET SO ZP,Y MODE
3735   FC52 4C CB FC           JMP OPCOMP
3736   FC55 A2 04       ZPX    LDX #04         ;CARRY CLEAR SO ZP,X MODE
3737   FC57 4C CB FC           JMP OPCOMP
3738   FC5A B0 69       TRY56  BCS ERRORM
3739   FC5C 20 EF FD    ABSIND JSR XORY        ;CC=ABS,X   CS=ABS,Y  NE=ERROR
3740   FC5F D0 64              BNE ERRORM
3741   FC61 90 0F              BCC ABSX
3742   FC63 A9 09       ABSY   LDA #09
3743   FC65 CD 2E 01           CMP TYPE
3744   FC68 D0 04              BNE ABSY1
3745   FC6A A2 0E              LDX #$0E
3746   FC6C D0 5D              BNE OPCOMP
3747   FC6E A2 08       ABSY1  LDX #$08
3748   FC70 D0 59              BNE OPCOMP
3749   FC72 A2 09       ABSX   LDX #09         ;CARRY CLEAR SO ABS,X MODE
3750   FC74 D0 55              BNE OPCOMP
3751   FC76 AD 36 01    PAREN  LDA ADFLD+3     ;SEE IF (HH,X),(HH)Y OR (HHHH)
3752   FC79 C9 2C              CMP #','        ;(HHX) (HH),Y  ARE OK TOO
3753   FC7B F0 04              BEQ INDX        ;COMMA IN 4TH POSITION = (HH,X)
3754   FC7D C9 58              CMP #'X'        ;X IN 4TH POSITION = (HHX)
3755   FC7F D0 04              BNE TRYINY
3756   FC81 A2 0B       INDX   LDX #$0B
3757   FC83 D0 46              BNE OPCOMP
3758   FC85 C9 29       TRYINY CMP #')'        ;")" IN 4TH POS = (HH)Y OR (HH),Y
3759   FC87 D0 0B              BNE TRYJMP
3760   FC89 20 EF FD           JSR XORY        ;CHCK TO SEE IF Y INDEX REG DESIRE
3761   FC8C D0 37              BNE ERRORM
3762   FC8E 90 35              BCC ERRORM
3763   FC90 A2 0A              LDX #$0A
3764   FC92 D0 37              BNE OPCOMP
3765   FC94 AD 38 01    TRYJMP LDA ADFLD+5     ;CHECK FOR FINAL PAREN
3766   FC97 C9 29              CMP #')'
3767   FC99 D0 2A              BNE ERRORM
3768   FC9B AD 2E 01           LDA TYPE        ;CONFIRM CORRECT ADDRESS TYPE
3769   FC9E C9 0B              CMP #$0B
3770   FCA0 D0 23              BNE ERRORM
3771   FCA2 A2 0D              LDX #$0D        ;OK, FORM IS JMP (HHHH)
3772   FCA4 D0 25              BNE OPCOMP
3773   FCA6 AD 2E 01    ABSOL  LDA TYPE        ;CHECK FOR BRANCH TO ABSOLUTE LOC
3774   FCA9 C9 0C              CMP #$0C
3775   FCAB D0 05              BNE ABSOL1
3776   FCAD A2 02              LDX #02
3777   FCAF 4C CB FC           JMP OPCOMP
3778   FCB2 A2 0C       ABSOL1 LDX #$0C
3779   FCB4 D0 15              BNE OPCOMP
3780   FCB6             ;SELECT IMMEDIATE ADDRESSING TYPE
3781   FCB6 AD 2E 01    HATCH  LDA TYPE
3782   FCB9 C9 01              CMP #01
3783   FCBB F0 04              BEQ IMMED1
3784   FCBD A2 07              LDX #07
3785   FCBF D0 0A              BNE OPCOMP
3786   FCC1 A2 06       IMMED1 LDX #06
3787   FCC3 D0 06              BNE OPCOMP
3788   FCC5 20 94 E3    ERRORM JSR CKER00      ;OUTPUT ERROR MESSAGE
3789   FCC8 4C AA FB           JMP STARTM
3790   FCCB
3791   FCCB             ;COMPUTE FINAL OP CODE FOR DEFINED ADDRESING MODE
3792   FCCB BD E2 FA    OPCOMP LDA TYPTR1,X    ;MATCH TYPE MASK WITH VALID MODE
3793   FCCE F0 05              BEQ OPCMP1      ;PATTERNS & SKIP 1ST WORD TEST IF
3794   FCD0 2D 26 01           AND TMASK1      ;ALREADY ZERO
3795   FCD3 D0 08              BNE VALID
3796   FCD5 BD F1 FA    OPCMP1 LDA TYPTR2,X    ;TEST 2ND PART
3797   FCD8 2D 27 01           AND TMASK2      ;INST DOES NOT HAVE SPECIFIED MODE
3798   FCDB F0 E8              BEQ ERRORM
3799   FCDD 18          VALID  CLC             ;FORM FINAL OP CODE
3800   FCDE BD 00 FB           LDA CORR,X
3801   FCE1 6D 34 A4           ADC OPCODE
3802   FCE4 8D 34 A4           STA OPCODE
3803   FCE7
3804   FCE7             ;PROCESS ADRESSES TO FINAL FORMAT
3805   FCE7 BD 0F FB           LDA SIZEM,X     ;OBTAIN ADDRESS FORMAT FROM TABLE
3806   FCEA C9 00              CMP #00
3807   FCEC F0 50              BEQ ONEBYT
3808   FCEE C9 0F              CMP #$0F        ;NEED BRANCH COMPUTATION?
3809   FCF0 F0 1D              BEQ BRNCHC
3810   FCF2 8D 33 A4           STA TEMPA       ;SAVE START POINT & CHAR COUNT
3811   FCF5 29 0F              AND #$0F        ;SEPARATE CHARACTER COUNT
3812   FCF7 A8                 TAY             ;LOAD ADDR BYTES INTO Y (0,1,OR 2)
3813   FCF8 8D 2F A4           STA BYTESM      ;SAVE IN BYTES
3814   FCFB EE 2F A4           INC BYTESM      ;TO INSTR LENGTH (1,2,OR 3 BYTES)
3815   FCFE AD 33 A4           LDA TEMPA       ;SEPARATE STARTING POINT
3816   FD01 29 F0              AND #$F0
3817   FD03 4A                 LSR A
3818   FD04 4A                 LSR A
3819   FD05 4A                 LSR A
3820   FD06 4A                 LSR A
3821   FD07 AA                 TAX             ;AND PUT IT IN X
3822   FD08 20 12 FD           JSR CONVRT      ;CONVERT ASCII ADDRESS TO HEX
3823   FD0B B0 B8              BCS ERRORM      ;SKIP OUT IF ERROR IN INPUT
3824   FD0D 90 1D              BCC STASH
3825   FD0F 4C 86 FD    BRNCHC JMP BRCOMP
3826   FD12
3827   FD12             ;############ SUBROUTINE ###############
3828   FD12             ;CONVERT FORMATTED ADDRESS INTO PROPER HEX ADDRESS
3829   FD12 BD 33 01    CONVRT LDA ADFLD,X     ;PICK UP 1ST ADDRES CHARACTER
3830   FD15 20 7D EA           JSR HEX         ;CONVERT TO MOST SIG HEX
3831   FD18 B0 11              BCS ERRFLG
3832   FD1A E8                 INX             ;GET NEXT ASCII CHARACTER
3833   FD1B BD 33 01           LDA ADFLD,X
3834   FD1E E8                 INX             ;POINT TO NEXT CHARACTER, IF ANY
3835   FD1F 20 84 EA           JSR PACK
3836   FD22 B0 07              BCS ERRFLG
3837   FD24 99 34 A4           STA OPCODE,Y    ;SAVE IN MOST SIG. BYTE LOCATION
3838   FD27 88                 DEY             ;SET UP FOR NEXT ADDR BYTE, IF ANY
3839   FD28 D0 E8              BNE CONVRT      ;IF NECESSARY, FORM NEXT ADDR BYTE
3840   FD2A 18                 CLC
3841   FD2B 60          ERRFLG RTS             ;NON HEX CLEARED CARRY
3842   FD2C             ;#############
3843   FD2C
3844   FD2C AC 2F A4    STASH  LDY BYTESM      ;SET UP TO STORE COMMAND
3845   FD2F 88                 DEY
3846   FD30 B9 34 A4    STSHLP LDA OPCODE,Y
3847   FD33 20 78 EB           JSR SADDR       ;STORE ONE BYTE OF COMMAND
3848   FD36 C0 00              CPY #00
3849   FD38 F0 0B              BEQ FORMDS
3850   FD3A 88                 DEY
3851   FD3B B8                 CLV
3852   FD3C 50 F2              BVC STSHLP      ;REPEAT TILL THRU
3853   FD3E
3854   FD3E A9 01       ONEBYT LDA #01         ;SET BYTES = 1
3855   FD40 8D 2F A4           STA BYTESM
3856   FD43 D0 E7              BNE STASH
3857   FD45
3858   FD45             ;FORMAT FOR SYSTEM 65 DISPLAY (REFORMAT FOR AIM)
3859   FD45 20 44 EB    FORMDS JSR CLR
3860   FD48 20 DD E5           JSR CGPC1       ;ADDR TO SAVPC FOR  DISASSEMBLY
3861   FD4B 20 42 E8           JSR TTYTST      ;IF TTY DO NOT GO TO DISASS
3862   FD4E D0 08              BNE FORMD1
3863   FD50 20 3B E8           JSR BLANK2      ;IT IS TTY
3864   FD53 20 3B E8           JSR BLANK2
3865   FD56 D0 11              BNE FORMD2      ;OUTPUT OPCODE
3866   FD58 20 6C F4    FORMD1 JSR DISASM
3867   FD5B 20 24 EA           JSR CRCK        ;<CR> IF PRI PTR DIFF FROM 0
3868   FD5E AD 37 A4           LDA CODFLG      ;SEE IF HE WANTS CODE ALSO
3869   FD61 F0 1A              BEQ FORM1
3870   FD63 20 3E E8           JSR BLANK
3871   FD66 20 3C F5           JSR PRPC        ;PROG CNTR
3872   FD69             ;OUTPUT OPCODE
3873   FD69 AE 2F A4    FORMD2 LDX BYTESM
3874   FD6C A0 00              LDY #00
3875   FD6E A9 1C       DISPLY LDA #ADDR       ;DO LDA (ADDR),Y ,WHITOUT PAG 0
3876   FD70 20 58 EB           JSR LDAY
3877   FD73 20 46 EA           JSR NUMA
3878   FD76 20 3E E8           JSR BLANK
3879   FD79 C8                 INY
3880   FD7A CA                 DEX
3881   FD7B D0 F1              BNE DISPLY
3882   FD7D
3883   FD7D             ;POINT TO NEXT INSTRUCTION LOCATION
3884   FD7D AC 2F A4    FORM1  LDY BYTESM      ;ADD BYTESM TO ADDR
3885   FD80 20 CD E2           JSR NXTADD
3886   FD83 4C 24 FF           JMP PATC16      ;UPDATE PC
3887   FD86
3888   FD86             ;RELATIVE BRANCH ADDRESS COMPUTATION
3889   FD86 AD 31 A4    BRCOMP LDA TEMPX
3890   FD89 C9 02              CMP #02         ;IF REL BRANCH INPUT, USE IT
3891   FD8B D0 11              BNE COMPBR
3892   FD8D A2 00              LDX #00
3893   FD8F A0 01              LDY #01
3894   FD91 20 12 FD           JSR CONVRT
3895   FD94 B0 40              BCS ERRJMP
3896   FD96 A9 02              LDA #02
3897   FD98 8D 2F A4           STA BYTESM      ;SET PROPER BYTES
3898   FD9B 4C 2C FD           JMP STASH
3899   FD9E A2 00       COMPBR LDX #00
3900   FDA0 A0 02              LDY #02
3901   FDA2 20 12 FD           JSR CONVRT
3902   FDA5 B0 2F              BCS ERRJMP
3903   FDA7 AD 1D A4           LDA ADDR+1      ;ADD BRANCH OFFSET
3904   FDAA 8D 27 01           STA MOVAD+1
3905   FDAD AD 1C A4           LDA ADDR
3906   FDB0 18                 CLC
3907   FDB1 69 02              ADC #02
3908   FDB3 8D 26 01           STA MOVAD
3909   FDB6 90 03              BCC CMPBR1
3910   FDB8 EE 27 01           INC MOVAD+1
3911   FDBB 38          CMPBR1 SEC             ;COMPUTE BRANCH RELATIVE ADDRESS
3912   FDBC AD 35 A4           LDA OPCODE+1
3913   FDBF ED 26 01           SBC MOVAD
3914   FDC2 8D 35 A4           STA OPCODE+1
3915   FDC5 AD 36 A4           LDA OPCODE+2
3916   FDC8 ED 27 01           SBC MOVAD+1
3917   FDCB 8D 36 A4           STA OPCODE+2
3918   FDCE C9 00              CMP #00
3919   FDD0 F0 0E              BEQ FORWRD
3920   FDD2 C9 FF              CMP #$FF
3921   FDD4 F0 03              BEQ BACKWD
3922   FDD6 4C C5 FC    ERRJMP JMP ERRORM
3923   FDD9 AD 35 A4    BACKWD LDA OPCODE+1    ;CHECK IN RANGE
3924   FDDC 30 09              BMI OK
3925   FDDE 10 F6              BPL ERRJMP
3926   FDE0 AD 35 A4    FORWRD LDA OPCODE+1
3927   FDE3 10 02              BPL OK
3928   FDE5 30 EF              BMI ERRJMP
3929   FDE7 A9 02       OK     LDA #02         ;SET UP FOR STASH
3930   FDE9 8D 2F A4           STA BYTESM
3931   FDEC 4C 2C FD           JMP STASH
3932   FDEF
3933   FDEF             ;###### SUBROUTINE ########
3934   FDEF             ;SUBROUTINE FOR DETERMINING X OR Y OR NEITHER
3935   FDEF A2 04       XORY   LDX #04
3936   FDF1 BD 33 01    XORYZ  LDA ADFLD,X
3937   FDF4 C9 2C              CMP #','
3938   FDF6 D0 04              BNE XORY1
3939   FDF8 E8                 INX
3940   FDF9 BD 33 01           LDA ADFLD,X
3941   FDFC C9 58       XORY1  CMP #'X'
3942   FDFE F0 03              BEQ ISX
3943   FE00 C9 59              CMP #'Y'
3944   FE02             XORYRT
3945   FE02 60                 RTS             ;NOT ZERO IS NOT X OR NOT Y
3946   FE03 18          ISX    CLC             ;CARRY SET IS Y
3947   FE04 90 FC              BCC XORYRT      ; CARRY CLEAR IS X
3948   FE06             ;####### END OF SUB ########
3949   FE06
3950   FE06             ; INPUT FOR MNEMONIC CODE
3951   FE06 A0 00       MNEM   LDY #00
3952   FE08 8C 34 A4           STY OPCODE
3953   FE0B 8C 35 A4           STY OPCODE+1
3954   FE0E 8C 36 A4           STY OPCODE+2    ;CLEARS OPCODE FOR NEW INPUT
3955   FE11 8C 26 01           STY MOVAD       ;CLEARS UNUSED BIT IN FINAL FORMAT
3956   FE14 20 5F E9    RDLUP  JSR RDRUP
3957   FE17 C9 2A              CMP #'*'        ;COMMAND TO LOAD POINTER
3958   FE19 F0 58              BEQ STLOAD      ;GO TO SET CURRENT ADDRESS POINTER
3959   FE1B C9 20              CMP #' '        ;IGNORE SPACE BAR INPUT
3960   FE1D F0 F5              BEQ RDLUP
3961   FE1F 29 1F              AND #$1F        ;MASK OFF UPPER 3 BITS
3962   FE21 99 30 01           STA CH,Y
3963   FE24 98                 TYA
3964   FE25 AA                 TAX             ;Y----> X
3965   FE26 FE 30 01           INC CH,X        ;FORMAT TO MATCH DISASSEMBLER TBL
3966   FE29 C8                 INY
3967   FE2A C0 03              CPY #03         ;REPEAT FOR EACH OF 3 CHARACTERS
3968   FE2C D0 E6              BNE RDLUP
3969   FE2E
3970   FE2E             ;COMPRESS 3 FORMATED CHARACTERS TO MOVAD & MOVAD+1
3971   FE2E A0 03              LDY #03         ;SET UP OUTER LOOP
3972   FE30 B9 2F 01    OUTLUP LDA CH-1,Y      ;COMPRESS 3 CHARACTERS
3973   FE33 A2 05              LDX #05         ;SET UP INNER LOOP
3974   FE35 4A          INLUP  LSR A           ;SHIFT 5 BITS ACC TO MOVAD,MOVAD+1
3975   FE36 6E 26 01           ROR MOVAD
3976   FE39 6E 27 01           ROR MOVAD+1
3977   FE3C CA                 DEX
3978   FE3D D0 F6              BNE INLUP
3979   FE3F 88                 DEY
3980   FE40 D0 EE              BNE OUTLUP
3981   FE42
3982   FE42             ;SEARCH FOR MATCHING COMPRESSED CODE
3983   FE42 A2 40              LDX #$40
3984   FE44 AD 26 01    SRCHLP LDA MOVAD
3985   FE47 DD B8 F5    SRCHM  CMP MNEML-1,X   ;MATCH LEFT HALF
3986   FE4A F0 05              BEQ MATCH
3987   FE4C CA                 DEX
3988   FE4D D0 F8              BNE SRCHM       ;IF NO - TRY AGAIN
3989   FE4F F0 0B              BEQ MATCH1
3990   FE51 AD 27 01    MATCH  LDA MOVAD+1     ;ALSO MATCH RIGHT HALF
3991   FE54 DD F8 F5           CMP MNEMR-1,X
3992   FE57 F0 06              BEQ GOTIT
3993   FE59 CA                 DEX
3994   FE5A D0 E8              BNE SRCHLP
3995   FE5C 4C C5 FC    MATCH1 JMP ERRORM
3996   FE5F
3997   FE5F             ;GET INSTRUCTION TYPE FROM TYPE TABLE
3998   FE5F BD 5D FB    GOTIT  LDA TYPTB-1,X
3999   FE62 8D 2E 01           STA TYPE
4000   FE65
4001   FE65             ;GET OPCODE FROM OP CODE UE
4002   FE65 BD 1D FB           LDA STCODE-1,X
4003   FE68 8D 34 A4           STA OPCODE
4004   FE6B 4C C1 FB           JMP MODEM
4005   FE6E
4006   FE6E             ;THIS SECTION SETS THE CURRENT ADDRESS POINTER
4007   FE6E A9 2A       STLO   LDA #'*'
4008   FE70 20 7A E9           JSR OUTPUT
4009   FE73 20 AE EA    STLOAD JSR ADDIN       ;GET ADDR
4010   FE76 B0 F6              BCS STLO        ;IN CASE OF ERROR
4011   FE78 4C 24 FF           JMP PATC16      ;ADDR TO PC THEN TO STARTM
4012   FE7B
4013   FE7B             ;PATCHES TO CORRECT PROBLEMS WITHOUT
4014   FE7B             ;CHANGING ENTRY POINTS TO THE ROUTINES
4015   FE7B 41                 .DB "A"
4016   FE7C 38          PATCH1 SEC             ;ADJUST BAUD
4017   FE7D E9 2C              SBC #44
4018   FE7F 8D 18 A4           STA CNTL30
4019   FE82 60                 RTS
4020   FE83
4021   FE83 8A          CUREAD TXA             ;SAVE X  , OUTPUT CUR
4022   FE84 48                 PHA
4023   FE85 AE 15 A4           LDX CURPO2
4024   FE88 E0 14              CPX #20         ;ONLY IF < 20
4025   FE8A B0 05              BCS PAT2A
4026   FE8C A9 DE              LDA #$DE
4027   FE8E 20 7B EF           JSR OUTDD1
4028   FE91 68          PAT2A  PLA
4029   FE92 AA                 TAX
4030   FE93 4C 3C E9           JMP READ        ;CONTINUE
4031   FE96
4032   FE96 20 3C E9    RED1   JSR READ        ;READ & ECHO WITHOUT CURSOR
4033   FE99 4C 76 E9           JMP RED2
4034   FE9C
4035   FE9C AE 15 A4    PATCH4 LDX CURPO2      ;DONT DO ANYTHING IF "8D"
4036   FE9F C9 8D              CMP #CR+$80     ;SO <CR> FOR TV & NOT FOR DISP
4037   FEA1 D0 0B              BNE PAT4A
4038   FEA3 A9 A0              LDA #' '+$80    ;CLR CURSOR
4039   FEA5 20 7B EF           JSR OUTDD1
4040   FEA8 20 44 EB           JSR CLR         ;CLR PNTRS
4041   FEAB 4C 76 EF           JMP OUTD7       ;EXIT
4042   FEAE 4C 17 EF    PAT4A  JMP OUTD1A      ;CONTINUE
4043   FEB1
4044   FEB1 8D 11 A4    PATCH5 STA PRIFLG      ;TURN PRI OFF
4045   FEB4 4C 73 F0           JMP IPO3
4046   FEB7
4047   FEB7 A9 1C       PATCH6 LDA #ADDR       ;SIMULATE LDA (ADDR),Y
4048   FEB9 4C 58 EB           JMP LDAY
4049   FEBC
4050   FEBC 20 3C E9    PATCH8 JSR READ        ;READ & ECHO WITH CARROTS
4051   FEBF 48                 PHA
4052   FEC0 20 D8 E7           JSR EQUAL
4053   FEC3 A9 3C              LDA #'<'
4054   FEC5 20 7A E9           JSR OUTPUT
4055   FEC8 68                 PLA
4056   FEC9 48                 PHA
4057   FECA C9 0D              CMP #CR
4058   FECC F0 03              BEQ PATC8C
4059   FECE 20 7A E9           JSR OUTPUT
4060   FED1 A9 3E       PATC8C LDA #'>'
4061   FED3 20 7A E9           JSR OUTPUT
4062   FED6 68                 PLA
4063   FED7 60                 RTS
4064   FED8
4065   FED8 C9 F7       PATCH9 CMP #$F7        ;CHCK LOWER TRANSITION OF TIMER
4066   FEDA B0 06              BCS PAT9A
4067   FEDC CD 08 A4           CMP TSPEED
4068   FEDF 4C 9D EE           JMP CKF3A
4069   FEE2 CD 08 A4    PAT9A  CMP TSPEED
4070   FEE5 68                 PLA
4071   FEE6 C9 FF              CMP #$FF
4072   FEE8 60          PAT9B  RTS
4073   FEE9
4074   FEE9 20 F0 E9    PATC10 JSR CRLF        ;CLR DISP (ONLY 1 <CR>)
4075   FEEC 4C 85 E1           JMP STA1
4076   FEEF
4077   FEEF F0 F7       PATC11 BEQ PAT9B       ;GO OUTPUT PROMPT
4078   FEF1 C9 4C              CMP #'L'        ;NO PROMPT FOR "T" OR "L"
4079   FEF3 F0 F3              BEQ PAT9B
4080   FEF5 4C C5 E7           JMP PROMP1
4081   FEF8
4082   FEF8 48          PATC12 PHA             ;CLEAR PRIFLG SO WE CAN OUTPUT
4083   FEF9 AD 11 A4           LDA PRIFLG      ;TO PRINTER IF FLG WAS ON (MSB)
4084   FEFC 29 F0              AND #$F0
4085   FEFE 8D 11 A4           STA PRIFLG
4086   FF01 68                 PLA
4087   FF02 60                 RTS
4088   FF03
4089   FF03 AD 12 A4    PATC13 LDA INFLG       ;TURN TAPES ON ONLY IF TAPES
4090   FF06 C9 54              CMP #'T'
4091   FF08 D0 DE              BNE PAT9B
4092   FF0A 4C 29 E5           JMP DU14        ;TURN ON TAPES & SET DEF DEV
4093   FF0D
4094   FF0D AD 13 A4    PATC14 LDA OUTFLG      ;TURN ON TAPES ONLY IF TAPES
4095   FF10 C9 54              CMP #'T'
4096   FF12 D0 D4              BNE PAT9B
4097   FF14 4C 0A E5           JMP DU11
4098   FF17
4099   FF17 20 F0 E9    PATC15 JSR CRLF        ;DECODE COMMAND
4100   FF1A 8A                 TXA             ;SAVE INDEX
4101   FF1B 0A                 ASL A
4102   FF1C AA                 TAX
4103   FF1D BD B8 FA           LDA JTBL,X      ;PART OF ENTRY
4104   FF20 8D 1A A4           STA S1
4105   FF23 60                 RTS
4106   FF24
4107   FF24 20 DD E5    PATC16 JSR CGPC1       ;ADDR TO PC
4108   FF27 4C AA FB           JMP STARTM      ;BACK TO MNEMONIC START
4109   FF2A
4110   FF2A F0 0E       PATC17 BEQ PAT17B      ;RUB, SO READ ANOTHER
4111   FF2C C9 00              CMP #0
4112   FF2E F0 03              BEQ PAT17A
4113   FF30 4C 85 F7           JMP IN02A       ;NEITHER ,CONTINUE
4114   FF33 20 93 E9    PAT17A JSR INALL       ;SKIP ON ZEROS
4115   FF36 C9 7F              CMP #$7F        ;UNTILL RUB
4116   FF38 D0 F9              BNE PAT17A
4117   FF3A 4C 7A F7    PAT17B JMP IN02        ;GO BACK
4118   FF3D
4119   FF3D 20 F8 FE    PATC18 JSR PATC12      ;RESET PRIFLG
4120   FF40 48                 PHA
4121   FF41 20 42 E8           JSR TTYTST      ;IF TTY JUST RTN
4122   FF44 D0 02              BNE PAT18A
4123   FF46 68                 PLA
4124   FF47 60                 RTS
4125   FF48 20 FE E8    PAT18A JSR LL          ;SET TO LOW SPEED
4126   FF4B 20 45 F0           JSR IPST        ;PRINT WHAT IS IN BUFFER
4127   FF4E 20 44 EB           JSR CLR         ;CLR PRINTER BUFFER BY OUTPUTTING
4128   FF51 20 3E E8           JSR BLANK       ;AN SPACE
4129   FF54 20 44 EB           JSR CLR
4130   FF57 68                 PLA             ;RTN ACC
4131   FF58 60                 RTS
4132   FF59
4133   FF59 D8          PAT19  CLD
4134   FF5A 20 24 EA           JSR CRCK
4135   FF5D 4C 85 E1           JMP STA1
4136   FF60
4137   FF60 F0 0D       PAT20  BEQ VECK4       ;END (DATA BYTES=0)
4138   FF62 18                 CLC
4139   FF63 69 04              ADC #4
4140   FF65 AA                 TAX
4141   FF66 20 93 E9    VECK5  JSR INALL       ;SKIP OVER DATA
4142   FF69 CA                 DEX
4143   FF6A D0 FA              BNE VECK5
4144   FF6C 4C 9E E6           JMP VECK1       ;PROCESS NEXT RCD
4145   FF6F 4C 20 E5    VECK4  JMP DU13
4146   FF72
4147   FF72 A0 00       PAT21  LDY #0
4148   FF74 B9 88 FF    PAT21A LDA POMSG,Y     ;RESET MSG
4149   FF77 F0 06              BEQ PAT21B
4150   FF79 20 7A E9           JSR OUTPUT
4151   FF7C C8                 INY
4152   FF7D D0 F5              BNE PAT21A
4153   FF7F 20 F0 E9    PAT21B JSR CRLF
4154   FF82 20 F0 E9           JSR CRLF
4155   FF85 4C 82 E1           JMP START
4156   FF88
4157   FF88 2020524F434BPOMSG  .DB "  ROCKWELL AIM 65"
4157   FF8E 57454C4C2041494D203635
4158   FF99 00                 .DB 0
4159   FF9A
4160   FF9A EE 68 01    PAT22  INC BLKO
4161   FF9D 4C BD ED           JMP ADDBK1
4162   FFA0
4163   FFA0 A9 FF       PAT23  LDA #$FF        ;START TIMER
4164   FFA2 8D 97 A4           STA DI1024
4165   FFA5 AD 85 A4    PAT23A LDA RINT        ;TIME OUT?
4166   FFA8 30 08              BMI PAT23B      ;YES
4167   FFAA AD 0D A8           LDA IFR         ;START SIGNAL?
4168   FFAD 29 10              AND #MPRST
4169   FFAF F0 F4              BEQ PAT23A      ;NO
4170   FFB1 60                 RTS             ;YES
4171   FFB2 A9 00       PAT23B LDA #0          ;TIME OUT RETURN
4172   FFB4 60                 RTS
4173   FFB5
4174   FFB5 20 75 EE    PATC24 JSR CKFREQ      ;READ BIT FROM FOURTH HALF PULSE
4175   FFB8 6A                 ROR A
4176   FFB9 29 80              AND #$80
4177   FFBB 60                 RTS
4178   FFBC
4179   FFBC 2C 0D A8    PATC25 BIT IFR         ;WAIT TILL TIMES OUT
4180   FFBF 50 FB              BVC PATC25
4181   FFC1 AD 04 A8           LDA T1L         ;CLR INTERRUPT FLG
4182   FFC4 60                 RTS
4183   FFC5
4184   FFF9                    *=$FFF9
4185   FFF9             ;INTERRUPT VECTORS
4186   FFF9 FA                 .DB $FA
4187   FFFA 75E0BFE078E0       .DW NMIV1,RSET,IRQV1    ;SET UP VECTORS
4188   10000             ;.END A0/1
4189   10000             SEMICOLON =$3B
4190   10000             BACKSLASH =$5C
4191   10000                    .END M1



Label        Value      Label        Value      Label        Value
------------------      ------------------      ------------------
ASSEM         D000      ADFLD         0133      ADDR          A41C
ACR           A80B      ADDS1         E55D      ADD1          E565
ADDIN         EAAE      ADDNE         EAB1      ADDN1         EAB7
ADDN2         EAC7      ADDN3         EADC      ADDN4         EAE8
ADDN5         EAF7      ADDN6         EAFD      ADDN7         EB0D
ADDN8         EB2B      ADDBLK        EDBA      ADDBK1        EDBD
ATTOP         F8DB      ATBOT         F8E9      AT02          F8F5
AT01          F8F7      ATEND         F8F9      ADDRS1        F910
ADDS1A        F916      AD1           F928      ADDA          F92A
ADDA1         F933      ACCUM         FC23      ABSIND        FC5C
ABSY          FC63      ABSY1         FC6E      ABSX          FC72
ABSOL         FCA6      ABSOL1        FCB2      BASIEN        B000
BASIRE        B003      BOTLN         00E1      BKS           0100
BYTESM        A42F      BKFLG         A410      BLK           0115
BLKO          0168      BRKA          E61B      BRK1          E620
BKERR         E62F      BKOK          E634      BKO2          E64C
BRKK          E6E5      BRK3          E6F1      BRK2          E6F3
BRK4          E6FA      BLANK2        E83B      BLANK         E83E
BKCKSM        F1E7      BKCK1         F1F1      BKCK2         F20F
BKCK3         F21A      BT            F721      BRNCHC        FD0F
BRCOMP        FD86      BACKWD        FDD9      BACKSLASH     005C
CH            0130      CODFLG        A437      CURPO2        A415
CURPOS        A416      CNTH30        A417      CNTL30        A418
COUNT         A419      CKSUM         A41E      CPIY          A42A
CRA           AC01      CRB           AC03      CR            000D
COMIN         E1A1      COMB          E1C4      CHNGG         E2A0
CHNG1         E2A6      CH2           E2B8      CH4           E2C0
CH3           E2C5      CKERR         E385      CKER0         E38E
CKER00        E394      CKER1         E396      CKER2         E3A3
CHEKAR        E54B      CHEKA         E54E      CGPC          E5D4
CGPC0         E5D7      CGPC1         E5DD      CGPS          E5EA
CGA           E5EE      CGX           E5F2      CGY           E5F6
CGS           E5FA      CGALL         E5FC      CLRBK         E6FE
CKB           E76B      CKB2          E76D      CKB1          E780
CRLF          E9F0      CRLOW         EA13      CR2J          EA23
CRCK          EA24      CRCK1         EA2C      CRCK2         EA3B
CLR           EB44      CLRCK         EB4D      CKFREQ        EE75
CKF1          EE7A      CKF2          EE81      CKF3          EE99
CKF3A         EE9D      CKF4          EEA1      CKBUFF        F1D2
CBUFF1        F1E2      COL0          F2E1      COL1          F321
COL2          F361      COL3          F3A1      COL4          F3E1
CHAR1         F5AD      CHAR2         F5B3      CHNG          F876
CHN1          F87C      CHN2          F88C      CHN3          F8A9
CHN4          F8AF      CFLG          F8B2      COM           FA78
COMM          FA88      CD02          FA8F      CFND1         FAA0
COMCN1        000B      COMTBL        FAAC      CORR          FB00
CLRLUP        FBE9      CONVRT        FD12      COMPBR        FD9E
CMPBR1        FDBB      CUREAD        FE83      DILINK        A406
DISFLG        A40F      DIBUFF        A438      DRA2          A480
DDRA2         A481      DRB2          A482      DDRB2         A483
DNPA7         A484      DPPA7         A485      DIV1          A494
DIV8          A495      DIV64         A496      DI1024        A497
DRB           A800      DRAH          A801      DDRB          A802
DDRA          A803      DRA           A80F      DATIN         000E
DATOUT        000C      DEBTIM        1388      DUMP          E43B
DU1           E444      DU0           E447      DU1B          E452
DU1A          E46D      DU2           E47D      DU6           E49F
DU7           E4A0      DU8           E4A2      DU9           E4B9
DU10          E4DB      DU10A         E4F8      DU11          E50A
DU12          E511      DU13          E520      DU14          E529
DUMPTA        E56F      DUMPT1        E57B      DUMPKI        E587
DUK2          E5A4      DONE          E790      DON1          E7A0
DELAY         EC0F      DE1           EC18      DE2           EC1B
DEHALF        EC23      DEBKEY        ED2A      DEBK1         ED2C
DISASM        F46C      DNNO          F6D8      DOW1          F6E3
DOW2          F6E8      DOWN          F724      DLNE          F74C
DISPLY        FD6E      END           00E5      ENPA7         A486
EPPA7         A487      ESCAPE        001B      EQS           00BD
EMSG1         E06C      EMSG2         E072      EQUAL         E7D8
ERR           F495      EDIT          F639      EDI0          F644
EDI1          F653      EDI2          F663      EDI3          F673
EDI4          F680      EDI5          F68D      EDI6          F69B
EDI7          F6AA      EDI8          F6AE      EDI           F6B6
EDI2B         F6CC      ENDERR        FA5C      ENDE2         FA6F
ERROR         FA72      ERR0          FA78      ENTRY         FA8D
EVAL          FC0E      ERRORM        FCC5      ERRFLG        FD2B
ERRJMP        FDD6      FORMA         0116      FROM          E7A3
FNAM          E8A2      FCHAR         F80C      FCHA1         F80F
FCH           F81E      FC1           F823      FC2           F82E
FC3           F834      FC4           F843      FC5           F849
FC6           F84E      FC7           F853      FC8           F85A
FC9           F868      FORMDS        FD45      FORMD1        FD58
FORMD2        FD69      FORM1         FD7D      FORWRD        FDE0
GAP           A409      GO            E261      GOBK          E26D
GOBK0         E278      GOBK1         E286      GETID         E425
GID1          E427      GOERR         E608      GCNT          E785
GCN1          E78C      GETTTY        EBDB      GET1          EBE2
GET3          EBED      GETKD0        EC38      GETKEY        EC40
GETKY         EC43      GETK0         EC55      GETK00        EC67
GETK1         EC71      GETK1B        EC80      GETK2         EC82
GETK3         EC8D      GETK4         EC93      GETK5         ECA4
GETK6         ECB9      GETK7         ECBE      GETK8         ECBF
GETK11        ECC9      GETK12        ECD2      GETK13        ECE1
GETK14        ECEB      GETK10        ECEC      GETTAP        EE29
GETA1         EE2B      GETFMT        F499      GOGO          FA4A
GOGO1         FA5B      GOTIT         FE5F      HISTM         A42E
HISTP         A414      HIST          A42E      HEX           EA7D
HATCJ         FC3D      HATCH         FCB6      IRQV4         A400
IRQV2         A404      INFLG         A412      IBUFM         A460
IDIR          A474      ICOL          A475      IOFFST        A476
IDOT          A477      IOUTL         A478      IOUTU         A479
IBITL         A47A      IBITU         A47B      IMASK         A47C
IFR           A80D      IER           A80E      IRQV1         E078
IRQV3         E154      IRQ1          E163      IRQ2          E17F
INCS2         E566      INTAB1        E743      INTAB2        E752
INTAB3        E756      INLOW         E8F8      INALL         E993
IPST          F045      IPS0          F04A      IPO0          F050
IPO2          F066      IPO3          F073      IPO4          F078
IPSU          F0E3      IPS1          F0E8      IPS3          F105
IPS2          F10E      INCP          F121      IEVEN         F486
IN            F764      INL           F76D      IN02          F77A
IN02A         F785      IN03B         F799      IN03          F7A8
IN03A         F7B9      IN05          F7C5      INPU          F7CB
INPU1         F7D8      INDX          FC81      IMMED1        FCC1
ISX           FE03      INLUP         FE35      JUMP          A47D
JMPR          E1C1      JD1           E723      JD2           E72B
JD3           E73C      JD4           E742      JTBL          FAB8
KEYF1         010C      KEYF2         010F      KEYF3         0112
KMASK         A42A      KDISA         E70A      KEP           E7AF
KEPR          E970      KIFLG         F8B6      KI2           F8B8
LENGTH        00EA      LMNEM         0117      LDIY          A42A
LF            000A      LOAD          E2E6      LOAD1         E2E9
LOAD2         E306      LOAD4         E321      LOAD5         E323
LOADTA        E32F      LOAD1A        E349      LOADT2        E364
LOADKI        E3A4      LOADK1        E3A7      LOADK2        E3AA
LOADK3        E3B7      LOADK5        E3D1      LOADK6        E3D3
LOADK7        E3E8      LL            E8FE      LT10          EA5A
LDAY          EB58      LST           F7E1      LST01         F7F0
LST02         F7F8      LST3          F803      MOVAD         0126
MONRAM        A400      MON           00C0      MOFF          00E0
MPRST         0010      MSP12         0002      MT2           0020
M1            E000      M3            E005      M4            E008
M5            E01C      M6            E021      M7            E024
M8            E027      M9            E02A      M10           E02D
M11           E031      M12           E03B      MCM2          E196
MCM3          E1AC      MCNT          0020      MONCOM        E1E5
MEM           E248      MEIN          E24D      MEM1          E24F
MEM2          E251      MEM3          E260      MEMERR        EB33
MTBL          F2D7      MNNDX1        F4AF      MNNDX2        F4B3
MNNDX3        F4BA      MR11A         F512      MODE          F55B
MODE2         F59F      MNEML         F5B9      MNEMR         F5F9
MREAD         FAD0      MNEENT        FB9E      MODEM         FBC1
MNEM          FE06      MATCH         FE51      MATCH1        FE5C
NOWLN         00DF      NMIV2         A402      NPUL          A40A
NAME          A42E      NULLC         00FF      NMIV1         E075
NMIV3         E07B      NMI4          E0B1      NMI5          E0B4
NXTADD        E2CD      NXTA1         E2DA      NXT5          E60D
NHIS          E688      NH1           E690      NAMO          E8CF
NAMO1         E8D6      NAMO2         E8E9      NAMO3         E8EB
NAMO4         E8F5      NUMA          EA46      NOUT          EA51
NEWROW        F160      NEWCOL        F163      NOWS1         F909
OLDLEN        00E9      OPCODE        A434      OUTFLG        A413
OUTCKS        E531      OUTCK         E538      OUTCK1        E53B
OUTCK2        E547      OUTLOW        E901      OUTL1         E906
OUTPUT        E97A      OUT1          E97B      OUT1A         E986
OUT2          E98F      OUTALL        E9BC      OUTA1         E9C8
OUTA2         E9D0      OUTA3         E9E2      OUTA4         E9EA
ONEKEY        ED05      ONEK1         ED09      ONEK2         ED0B
ONEK3         ED1C      ONEK4         ED29      OUTTTY        EEA8
OUTT1         EECB      OUTT2         EEFB      OUTDP         EEFC
OUTDP1        EF02      OUTDIS        EF05      OUTD1         EF14
OUTD1A        EF17      OUTD2         EF20      OUTD2A        EF2F
OUTD3         EF33      OUTD4         EF48      OUTD5         EF56
OUTD7         EF76      OUTDD1        EF7B      OUTDD2        EF87
OUTDD3        EF8B      OUTPRI        F000      OUT01         F00F
OUT04         F025      OUT05         F033      OUTPR         F038
OUTPR1        F03A      OUTPR2        F044      OP04          F130
OP07          F13F      OP03          F144      OP05          F150
OP06          F15D      OUTTAP        F24A      OUTTA1        F290
OUTTA2        F294      OUTTA3        F2B2      OPCOMP        FCCB
OPCMP1        FCD5      ONEBYT        FD3E      OK            FDE7
OUTLUP        FE30      PRIFLG        A411      PCR           A80C
PRST          0000      PRTIME        06A4      PRITR         E6E1
PROMPT        E7BD      PROMP1        E7C5      PR1           E7CC
PR2           E7CF      PSLS          E7DC      PSL0          E7FB
PSL00         E802      PSL0A         E814      PSL0B         E81C
PSL0C         E81E      PSL0D         E823      PSL1          E837
PACK          EA84      PAK1          EA96      PAK2          EA9F
PCLLD         EB56      PHXY          EB9E      PLXY          EBAC
PRIERR        F079      PRNDOT        F087      PRDOT0        F08C
PINT          F0CB      PRMN1         F4D7      PRMN2         F4DB
PRADR1        F4F7      PRADR2        F4FF      PRADR3        F519
PRADR4        F52C      PRNTXY        F538      PRPC          F53C
PRBL2         F545      PCADJ3        F54D      PCADJ4        F554
PLNE          F727      P02           F729      P01           F73B
P03           F73F      P00           F749      PNTLUP        FBD0
PAREN         FC76      PATCH1        FE7C      PAT2A         FE91
PATCH4        FE9C      PAT4A         FEAE      PATCH5        FEB1
PATCH6        FEB7      PATCH8        FEBC      PATC8C        FED1
PATCH9        FED8      PAT9A         FEE2      PAT9B         FEE8
PATC10        FEE9      PATC11        FEEF      PATC12        FEF8
PATC13        FF03      PATC14        FF0D      PATC15        FF17
PATC16        FF24      PATC17        FF2A      PAT17A        FF33
PAT17B        FF3A      PATC18        FF3D      PAT18A        FF48
PAT19         FF59      PAT20         FF60      PAT21         FF72
PAT21A        FF74      PAT21B        FF7F      POMSG         FF88
PAT22         FF9A      PAT23         FFA0      PAT23A        FFA5
PAT23B        FFB2      PATC24        FFB5      PATC25        FFBC
QM            E7D4      RMNEM         0118      REGF          A40E
ROLLFL        A47F      RINT          A485      RA            AC00
RB            AC02      RUB           0008      RSET          E0BF
RS1           E0C9      RS2           E0D4      RS3A          E0F1
RS3           E0F3      RS3B          E11A      RS4           E11D
RS5           E129      RS6           E13E      RS7           E144
RS8           E146      REG           E227      REG1          E232
RBYTE         E3FD      RBYT1         E407      REGT          E6D9
RS20          E702      RCHEK         E907      RCH2          E91F
RCH3          E925      RCHTTY        E926      RCHT2         E928
RCHT1         E93B      READ          E93C      READ1         E94A
READ2         E94D      REA1          E956      RB2           E95C
RDRUP         E95F      RDR1          E96A      REDOUT        E973
RED2          E976      RD2           EA5D      RD1           EA70
RSPAC         EA7B      ROONEK        ECEF      ROO1          ED00
RDBIT         EE3B      RDBIT1        EE43      RDBIT2        EE51
RDBIT4        EE67      ROUT          F286      ROUT1         F28B
ROW1          F421      ROW2          F429      ROW3          F431
ROW4          F439      ROW5          F441      ROW6          F449
ROW7          F451      ROW8          F459      REGQ          F461
RTMODE        F491      RELADR        F530      RTS1          F55A
REENTR        F6CF      RESNOW        F8D0      REP2          F93E
REPLAC        F93F      R8            F947      R87           F94E
R88           F953      R2W           F95F      RQP           F977
R6            F984      R5            F99D      R55           F9A8
R7            F9AB      R9            F9BE      R10           F9C7
R11           F9CC      R100          F9CF      R101          F9DA
R102          F9E3      R108          F9EF      R103          F9FA
R107          FA0A      R104          FA17      R105          FA31
R1051         FA41      R106          FA44      RDADDR        FBE5
RDLUP         FE14      RED1          FE96      SAVE          00E7
STRING        00EB      S1            A41A      S2            0106
SAVPS         A420      SAVA          A421      SAVX          A422
SAVY          A423      SAVS          A424      SAVPC         A425
STIY          A427      STBKEY        A42B      SR            A80A
SP12          0001      SETREG        E113      START         E182
STA1          E185      STBYTE        E413      SHOW          E64D
SH1           E652      SHIS          E665      SH11          E66A
SEMI          E9BA      SADDR         EB78      SWSTAK        EBBA
SWST1         EBBD      SYNC          EDFF      SYNC1         EE11
SETZ          F282      SETSPD        F2C0      SETSP1        F2CA
SETSP2        F2D3      STOP          F870      SETBOT        F8C5
SUB           F91D      SUB1          F927      SAVNOW        F934
SIZEM         FB0F      STCODE        FB1E      STARTM        FBAA
STORCH        FBF6      STOR1         FC0A      STASH         FD2C
STSHLP        FD30      SRCHLP        FE44      SRCHM         FE47
STLO          FE6E      STLOAD        FE73      SEMICOLON     003B
TEXT          00E3      TYPE          012E      TMASK1        0126
TMASK2        0127      TEMPX         A431      TEMPA         A433
TSPEED        A408      TIMG          A40B      TAPIN         A434
TAPOUT        A435      TAPTR         A436      TAPTR2        A437
TABUFF        0116      TABUF2        00AD      T1L           A804
T1CH          A805      T1LL          A806      T1LH          A807
T2L           A808      T2H           A809      T2I           0000
T1I           0000      T1FR          00C0      TMSG0         E048
TMSG1         E04D      TMSG2         E050      TMSG3         E052
TMSG5         E05F      TMSG6         E061      TMSG7         E066
TOGTA1        E6BD      TOGTA2        E6CB      TRACE         E6DD
TOGL          E6E7      TOGL1         E6F6      TO            E7A7
TO1           E7A9      TTYTST        E842      TAP1          E8B3
TAP2          E8BC      TAP3          E8C2      TIBYTE        ED3B
TIB1          ED48      TIBY1         ED53      TIBY3         ED56
TIBY4         ED63      TIBY5         ED65      TIBY5A        ED88
TIBY6         EDAF      TIBY7         EDB0      TAISET        EDEA
TIOSET        EE1C      TIOS1         EE22      TIOS2         EE24
TOBYTE        F18B      TABY2         F1A7      TABY3         F1CE
TAOSET        F21D      TAOS1         F238      TRY           F258
TP            F6D2      TOPNO         F8BC      TPO1          F8C0
TYPTR1        FAE2      TYPTR2        FAF1      TYPTB         FB5E
TRYZP         FC28      TRY34         FC40      TRY56         FC5A
TRYINY        FC85      TRYJMP        FC94      UDRB          A000
UDRAH         A001      UDDRB         A002      UDDRA         A003
UT1L          A004      UT1CH         A005      UT1LL         A006
UT1LH         A007      UT2L          A008      UT2H          A009
USR           A00A      UACR          A00B      UPCR          A00C
UIFR          A00D      UIER          A00E      UDRA          A00F
UIN           0108      UOUT          010A      UP            F6F9
UPNO          F709      UP1           F713      UP4           F720
VECKSM        E694      VECK1         E69E      VECK2         E6AC
VALID         FCDD      VECK5         FF66      VECK4         FF6F
WRITAZ        E2DB      WRITAD        E2DD      WHEREI        E848
WHE1          E85C      WHE2          E868      WHE3          E870
WHEREO        E871      WHRO1         E885      WHRO2         E88E
WHRO3         E897      WHRO4         E89F      WHICHT        E8A8
WRAX          EA42      XORY          FDEF      XORYZ         FDF1
XORY1         FDFC      XORYRT        FE02      ZON           F25D
ZON1          F261      ZON2          F26C      ZPAGE         FC38
ZPY           FC50      ZPX           FC55

tasm: Number of errors = 0


AIM 65 MICROCOMPUTER MONITOR PROGRAM LISTING
Rockwell International
Document No. 29650 N36L
Rev. 1, April 1979

I used the Telemark Cross Assembler v3.1 (TASM) to re-create the source code.
See http://www.halcyon.com/squakvly/

I tried to exactly duplicate the original source but some errors may exist. 
The exceptions are when the original had a hexadecimal constant instead
of an ASCII constant or ASCII equate (especially CR) in some immediate
mode instructions; I changed them to ASCII constants or an equate.

For example, line 468 in the printed listing is:
0468  E185  A9 BC       STA1   LDA #$BC        ;"<" CHR WITH MSB=1 FOR DISP

My version is:
0468   E185 A9 BC       STA1   LDA #'<'+$80    ;"<" CHR WITH MSB=1 FOR DISP

The TASM assembler is not the same one that Rockwell used to write the
code, so some assembler directives and opcode formats are different. 
However, the ASM file uses the same line numbering as the printed listing. 
That is, line 1000 in the printed listing corresponds to line 1000 in the
ASM file and line 1000 in the LST file.

I could not fully read eight lines in the program listing because I was
looking at a scanned copy, not the original.  The rightmost characters
were lost in the binding.  These are the lines:

0149  HIST   =NAME           ;FOUR LAST ADDR + NEXT (SINGL STEP)
1796         JSR SWSTAK      ;SWAP X , Y WITH RTRN ADDR FROM S
1804         JSR SWSTAK      ;SWAP X , Y WITH RTRN ADDR FROM
2159  RDBIT  LDA TSPEED      ;ARE WE IN C7 OR 5B,5A FREQUENC
2262  OUTDP1 JMP (DILINK)    ;HERE HE COULD ECHO SOMEWHERE ELSE
3205         BNE IN02        ;CONTIN , DISP WONT ALLOW > 60 CHR
3719         LDA TYPE        ;CHCK FOR BRNCH WITH RELATIVE ADDR
3727  TRY34  LDA #04         ;CHECK FOR ABSOLUTE OR ZP,X ORZP,

NOTE: I have since been told that the cut-off lines above exist in the
original manual.



+------------------------------------------------------------------------
|  TOPIC -- AIM Computer -- AIM BASIC Language Reference Manual 
+------------------------------------------------------------------------

AIM 65 MICROCOMPUTER BASIC LANGUAGE REFERENCE MANUAL

Rockwell International Corporation
Document No 29650 N49
March 1979

    TABLE OF CONTENTS

100 Installing BASIC in the AIM 65

200 Getting Started With Basic
    201       BASIC Command Set
    202       Direct and Indirect Commands
    203       Operating on Programs and Lines
    204       Printing Data
    205       Number Format
    206       Variables
    207       Relational Tests
    208       Looping
    209       Matrix Operations
    210       Subroutines
    211       Entering Data
    212       Strings

300 Statement Definitions
    301       Special Characters
    302       Operators
    303       Commands
    304       Program Statements
    305       Input/Output Statements
    306       String Functions
    307       Arithmetic Functions

A   Error Messages
B   Space Hints
C   Speed Hints
D   Converting BASIC Programs not Written for AIM 65 BASIC
E   ASCII Character Codes
F   Assembly Language Subroutines
G   Storing AIM 65 BASIC Programs on Cassette
H   ATN Implementation

INTRODUCTION

Before a computer can perform any useful function, it must be "told" what to do.  Unfortunately,
at this time, computers are not capable of understanding English or any other "human" language.
This is primarily because our languages are rich with ambiguities and implied meanings.  The
computer must be told precise instructions and the exact sequence of operations to be performed
in order so accomplish any specific task.  Therefore, in order to facilitate human communication
with a computer, programming languages have been developed.

Rockwell AIM 65 8K BASIC by Microsoft is a programming language both easily understood and
simple to use.  It serves as an excellent "tool" for applications in areas such as business, science,
and education.  After only a few hours of using BASIC, you will find that you can already write
programs with an ease that few other computer languages can duplicate.

Originally developed at Dartmouth University, the BASIC language has found wide acceptance in
the computer field.  Although it is one of the simplest computer languages to use, it is very powerful.
BASIC uses a small set of common English words as its "comnmands."  Designed specifically as an
"interactive" language, you can give a command such as "PRINT 2 + 2," and BASIC will immediately
reply with "4."  It is not necessary to submit a card deck wish your program on it and then wait
hours for the results.  Instead, the full power of the computer is "at your fingertips."

We hope that you enjoy BASIC, and are successful in using it to solve all of your programming
problems.

100 INSTALLING BASIC IN THE AIM 65

ROM INSTALLATION PROCEDURE

Before handling the BASIC ROM circuits, be sure to observe the precautions outlined in Section 1.4
of the AIM 65 User's Guide.

To install the ROMs, turn off power to the AIM 65.  Inspect the pins on the two BASIC ROMs to
ensure that they are straight and free of foreign material.  While supporting the AIM 65 Master
Module beneath the ROM socket, insert ROM number R3225 into Socket Z25, being careful to
observe the device orientation.  Now insert ROM number R3226 into Socket Z26.  Be certain that
both ROM's are completely inserted into their sockets, then turn on power to the AIM 65.

ENTERING BASIC

To enter and initialize BASIC, type 5 after the monitor prompt is displayed.  AIM 65 will respond
with:

    <5>

    MEMORY SIZE? ^

Type the highest address in memory that is to be allocated to the BASIC program, in decimal.  End
the entry by typing RETURN.  BASIC will allocate memory from 530 (212 in hex) through the
entered address.  If BASIC is to use all available memory, type RETURN without entering an
address.  The highest address is 1024 (400 hex) in the 1K RAM version of AIM 65, and 4096
(1000 hex) in the 4K RAM version.

BASIC will then ask:

    WIDTH? ^

Type in the output line width of the printer (or any other output device that is being used) and end the
input with RETURN.

The entered number may vary from 1 to 255, depending on the output device.  If RETURN is typed
without entering a number, the output line width is set to a default value of 20, which is the column
width of the AIM 65 printer.

BASIC will respond with:

    XXXX BYTES FREE

where XXXX is the number of bytes available for BASIC program, variables, matrix storage, and
string space.  If all available memory was allocated, BASIC will reply with:

    494 BYTES FREE (for 1K RAM; i.e., 1024-530)

or

    3566 BYTES FREE (for 4K RAM; i.e., 4096-530)

BASIC will display:

    ^ AIM 65 BASIC Vn.n

where n.n is the version number.

BASIC is now in the command entry mode as indicated by the BASIC prompt (^) in the display
column 1.  Subject 201 gets you started into the BASIC commands.

Read the following paragraphs first, however, so understand how to exit and reenter the BASIC
and how the BASIC cursor prompt operates.

              CAUTION

    Entering BASIC with the 5 key causes the allocated
    memory to be initialized with AA (hex) in all bytes,
    starting with address 532.  This, of course, destroys
    any previous BASIC programs, data in the AIM 65
    Editor Text Buffer, or machine level routines that
    may have been stored in this portion of memory.
    Be sure to save any desired data or programs that
    may exist in this area before entering BASIC with
    the 5 key.

    Note that text in the Text Buffer or machine level
    routine may co-exist in memory with BASIC by
    locating such text or routines in upper memory
    and entering the highest BASIC address with a
    value lower than the starting address of such text
    or routines.

EXITING BASIC

To escape from BASIC and return to the AIM 65 Monitor, type ESC any time the BASIC command
cursor is displayed.  You can also escape BASIC while a program is running, by pressing the F1 key
(see Subject 301).

Pressing RESET will also cause the AIM 65 Monitor to be entered as well as performing a hardware
reset of AIM 65.

REENTERING BASIC

BASIC may be reentered by typing 6 whenever the AIM 65 Monitor prompt is displayed.  In this
case, however, any existing BASIC program is retained in memory.  AIM 65 will respond to a
Key 6 entry with:

    <6>

    ^6>

BASIC CURSOR

The BASIC cursor (^), displayed in column 1 whenever BASIC is in the command entry mode,
indicates that a BASIC command can be entered.  The last displayed data resulting from the previous
command is retained except for column 1 to provide information continuity with the previous
command or displayed output data.  This is especially helpful when the printer control is turned off
to preserve printer paper.

When the first character of the next command is typed, the display will blank except for the newly
typed character.  The cursor then advances across the display in accordance with typed characters
to indicate the character input position.

The displayed cursor does not appear on the printer output, thus any data printed in column 1 will
be retained.

              CAUTION

    The minus sign associated with any negative values
    that are displayed starting in column 1 will be
    replaced with the cursor in the BASIC command
    entry mode.  In the case of direct commands, the
    minus sign will only flash before the cursor is
    displayed if the printer control is on or may not
    appear at all if the printer control is off.  In order
    to retain the minus sign, a leading blank should
    be displayed before the value is displayed (see
    Subject 204).

PRINTER CONTROL

While in the BASIC command entry mode, the printer may be turned on or off by typing PRINT
while CNTL is pressed (CNTL PRINT).  The on/off state of the printer is displayed after typing
PRINT.

If the printer is turned off, statements in the BASIC command entry mode and data output from
PRINT commands will be directed to the display only.  If the printer is turned on, all commands
and data from PRINT commands will be directed to both the printer and display.  With the printer
off, data can still be directed to the printer by using the PRINT) command (see Subject 305).

Similarly, INPUT statements will output data to the printer in response to the printer control state.
An INPUT! statement will output data to the printer even if the printer control is off (see
Subject 305).

200  GETTING STARTED WITH BASIC

201  BASIC COMMAND SET

This section is not intended to be a detailed course in BASIC programming.  It will, however, serve
as an excellent introduction for those of you unfamiliar with the language.

We recommend that you try each example in this section as it is presented.  This will enhance your
"feel" for BASIC and how it is used.  Table 201-1 lists all the AIM 65 BASIC commands.

              NOTE

    Any time the cursor (^) is displayed in column 1
    a BASIC command may be typed in.  End all
    commands to BASIC by typing RETURN.  The
    RETURN tells BASIC that you have finished
    typing the command.  If you make an error, type
    a DEL (RUBOUT on a TTY) to eliminate the
    last character.  Repeated use of DEL will
    eliminate previous characters.  An @ symbol
    will eliminate that entire line being typed.

    Table 201.1.  AIM 65 BASIC Commands

    Commands                      Input/Output
    --------                      ------------
    CLEAR                         DATA
    CONT                          GET
    FRE                           INPUT
    LIST                          POS
    LOAD                          PRINT
    NEW                           READ
    PEEK                          SPC
    POKE                          TAB
    RUN
    SAVE
                                  String Functions
                                  ----------------
    Program Statements            ASC
    ------------------            CHR$
    DEF FN                        LEFT$
    DIM                           LEN
    END                           MID$
    FOR                           RIGHT$
    GOSUB                         STR$
    GOTO                          VAL
    IF...GOTO
    IF...THEN
    LET                           Arithmetic Functions
    NEXT                          --------------------
    ON...GOSUB                    ABS
    ON...GOTO                     ATN*
    REM                           COS
    RESTORE                       EXP
    RETURN                        INT
    STOP                          LOG
    USR                           RND
    WAIT                          SIN
                                  SGN
                                  SQR
                                  TAN

* Although the ATN function is not included in AIM 65 BASIC,
  the ATN command is recognized (see Appendix H).

202  DIRECT AND INDIRECT COMMANDS

DIRECT COMMANDS

Try typing in the following:

    PRINT 10-4 (end with RETURN)

BASIC will immediately print:

    6

The print statement you typed in was executed as soon as you hit the RETURN key.  This is called
a direct command.  BASIC evaluated the formula after the "PRINT" and then typed out its value,
in this case "6".

Now try typing in this:

    PRINT 1/2,3*10          ("*" means multiply, "/" means divide)

BASIC will print:

    .5        30

As you can see, BASIC can do division and multiplication as well as subtraction.  Note how a ","
(comma) was used in the print command to print two values instead of just one.  The command
divides a line into 10-character-wide columns.  The comma causes BASIC to skip to the next
10-column field on the terminal, where the value 30 is printed.

INDIRECT COMMANDS

There is another type of command called an Indirect Command.  Every Indirect command begins
with a Line Number.  A Line Number is any integer from 0 to 63999.

Try typing in these lines:

    10 PRINT 2+3
    20 PRINT 2-3

A sequence of Indirect Commands is called a "Program."  Instead of executing indirect statements
immediately, BASIC saves Indirect Commands in memory.  When you type in RUN, BASIC will
execute the lowest numbered indirect statement that has been typed in first, then the next higher,
etc., for as many as were typed in.

In the example above, we typed in line 10 first and line 20 second.  However, it makes no difference
in what order you type in indirect statements.  BASIC always puts them into correct numerical order
according to the Line Number.

Suppose we type in

RUN

BASIC will print:

    5
    -1

203  OPERATING ON PROGRAMS AND LINES

In Subject 202, we typed a two-line program into memory.  Now let's see how BASIC can be used
to operate on either or both lines.

LISTING A PROGRAM

If we want a listing of the complete program currently in memory, we type in

    LIST

BASIC will reply with:

    10 PRINT 2+3
    20 PRINT 2-3

DELETING A LINE

Sometimes it is desirable to delete a line of a program altogether.  This is accomplished by typing
the Line Number of the line so be deleted, followed by a carriage return.

Type in the following:

    10
    LIST

BASIC will reply with:

    20 PRINT 2-3

We have now deleted line 10 from the program.

REPLACING A LINE

You can replace line 10, rather than just deleting it, by typing the new line 10 and hitting
RETURN.

Type in the following:

    10 PRINT 3-3
    LIST

BASIC will reply with:

    10 PRINT 3-3
    20 PRINT 2-3

It is not recommended that lines be numbered consecutively.  It may become necessary to insert a
new line between two existing lines.  An increment of 10 between line numbers is generally sufficient.

DELETING A PROGRAM

If you want to delete the complete program currently stored in memory, type in "NEW."  If you
are finished running one program and are about to read in a new one, be sure to type in "NEW"
first.

Type in the following:

    NEW

Now type in:

    LIST

204  PRINTING DATA

If is often desirable to include explanatory text along with answers that are printed out.

Type in the following:

    PRINT "ONE HALF EQUALS", 1/2

BASIC will reply with:

    ONE THIRD EOUALS
    .5

As explained in Subject 202, including a "," in a PRINT statement causes it to space over to the
next 10-column field before the value following the "," is printed.

If we use a ";" instead of a comma, the next value will be printed immediately following the
previous value.

              NOTE

    Numbers are always printed with at least one
    trailing space.  Any text to be printed must
    always be enclosed in double quotes.

Try the following examples:

1.  PRINT "ONE HALF EQUALS"; 1/2
    ONE HALF EQUALS .5

2.  PRINT 1,2,3
    1         2
    3
    ...

3.  PRINT 1;2;3
    1 2 3

4.  PRINT -1;2;-3
    -1 2 -3

205  NUMBER FORMAT

We will digress for a moment to explain the format of numbers in BASIC.  Numbers are stored
internally to over nine digits of accuracy.  When a number is printed, only nine digits are shown.
Every number may also have an exponent (a power of ten scaling factor).

The largest number that may be presented in AIM 65 BASIC is 1.70141183*10^38, while the
smallest positive number is 2.93873588*10^-39.

When a number is printed, the following rules define the format:

1.  If the number is negative, a minus sign (-) is printed.  If the number is positive, a space is
    printed.

2.  If the absolute value of the number is an integer in the range 0 to 999999999, it is
    printed as an integer.

3.  If the absolute value of the number is greater than or equal to 0.01 and less than or equal
    to 999999999, it is printed in fixed point notation, with no exponent.

4.  If the number does not fall under categories 2 or 3, scientific notation is used.

Scientific notation is formatted as follows:  SX.XXXXXXXXESTT.  (Each X is some integer,
0 to 9.)

The leading "S" is the sign of the number:  a space for a positive number and a "-" for
for a negative one.  One non-zero digit is printed before the decimal point.  This it
followed by the decimal point and then the other eight digits of the mantissa.  An
"E" is then printed (for exponent), followed by the sign (S) of the exponent; then
the two digits (TT) of the exponent itself.  Leading zeroes are never printed; i.e.,
the digit before the decimal is never zero.  Trailing zeroes are never printed.  If there
is only one digit to print after all trailing zeroes are suppressed, no decimal point is
printed.  The exponent sign will be "+" for positive and "-" for negative.  Two
digits of the exponent are always printed; that is, zeroes are not suppressed in the
exponent field.  The value of any number expressed thus is the number so the left
of the "E" times 10 raised to the power of the number to the right of the "E".

Regardless of what format is used, a space is always printed following a number.  BASIC checks
to see if the entire number will fit on the current line.  If it cannot, a carriage return/line feed is
executed before printing the number.

Following are examples of various numbers and the output format in which BASIC will output them:

    NUMBER              OUTPUT FORMAT
    -------------       -------------
    +1                   1
    -1                  -1
     6523                6523
    -23.460             -23.46
     1E20                1E+20
    -12.3456E-7         -1.23456E-06
     1.234567E-10        1.23457E-10
     1000000000          1E+09
     999999999           999999999
    .1                  .1
    .01                 .01
    .000123              1.23 E-04

A number input from the keyboard or a numeric constant used in a BASIC program may have as
many digits as desired, up to the maximum length of a line (72 characters) or maximum numeric
value.  However, only the first 10 digits are significant, and tenth digit is rounded up.

    PRINT 1.23456789876543210
    1.2345679

206  VARIABLES

ASSIGNING VARIABLES WITH AN INPUT STATEMENT

Following is an example of a program that reads a value from the keyboard and uses that value to
calculate and print a result:

    10 INPUT R
    20 PRINT 3.14159*R*R
    RUN
    ?10
    314.159

Here's what's happening:  When BASIC encounters the input statement, it outputs a question mark
(?) on the display and then waits for you to type in a number.  When you do (in the above example,
10 was typed), execution continues with the next statement in the program after the variable (R)
has been set (in this case to 10).  In the above example, line 20 would now be executed.  When the
formula after the PRINT statement is evaluated, the value 10 is substituted for the variable R each
time R appears in the formula.  Therefore, the formula becomes 3.14159*10*10, or 314.159.

If we wanted so calculate the area of various circles, we could rerun the program for each successive
circle.  But, there's an easier way to do it simply by adding another line to the program, as follows:

    30 GOTO 10
    RUN
    ?10
    314.159
    ?3
    28.27431
    ?4.7
    69.3977231
    ?

By putting a "GOTO" statement on the end of our program, we have caused it to go back to line 10
after it prints each answer for the successive circles.  This could have gone on indefinitely, but we
decided to stop after calculating the area for three circles.  This was accomplished by typing a
carriage return to the input statement (thus a blank line).

VARIABLE NAMES

The letter "R" in the program above is a "variable."  A variable name can be any alphabetic
character and may be followed by any alphanumeric character (letters A to Z, numbers 0 to 9).

Any alphanumeric characters after the first two are ignored.

Here are some examples of legal and illegal variable names:

    Legal     Illegal

    A         % (first character must be alphabetic)
    Z1        ZIABCD (variable name too long)

    TP        TO (variable names cannot be reserved words)
    PSTG$     RGOTO (variable names cannot contain reserved words)
    COUNT

ASSIGNING VARIABLES WITH A LET OR ASSIGNMENT STATEMENT

Besides having values assigned to variables with an input statement, you can also set the value of a
variable with a LET or assignment statement.

Try the following examples:

    A=5

    PRINT A, A*2
    5         10

    LET Z=7

    PRINT Z, Z-A
    7         2

As you will notice from the examples, the "LET" is optional in an assignment statement.

BASIC "remembers" the values that have been assigned to variables using this type of statement.
This "remembering" process uses space in the memory to store the data.

The values of variables are discarded (and the space in memory used to store them is released) when
one of four conditions occur:

*   A new line is typed into the program or an old line is deleted

*   A CLEAR command is typed in

*   A RUN command is typed in

*   NEW is typed in

Another important fact is that if a variable is encountered in a formula before it is assigned a value,
it is automatically assigned the value zero.  Zero is then substituted as the value of the variable in the
particular formula.  Try the example below:

    PRINT Q;Q+2;Q*2
    0 2 0

RESERVED WORDS

The words used as BASIC statements are "reserved" for this specific purpose.  You cannot use these
words as variable names or inside of any variable name.  For instance, "FEND" would be illegal
because "END" is a reserved word.

Table 206-1 is a list of the reserved words in BASIC.

    Table 206-1.  AIM 65 BASIC Reserved Words

    ABS       FN        LIST      PRINT     SPC
    AND       FOR       LOAD      POS       SQR
    ASC       FRE       LOG       READ      STEP
    ATN       GET       MID$      REM       STOP
    CHR$      GOSUB     NEW       RESTORE   STR$
    CLEAR     GOTO      NEXT      RETURN    TAB
    CONT      IF        NOT       RIGHT$    TAN
    COS       INPUT     NULL      RND       THEN
    DATA      INT       ON        RUN       TO
    DEF       LEFT$     OR        SAVE      USR
    DIM       LEN       PEEK      SGN       VAL
    END       LET       POKE      SIN       WAIT
    EXP

REMARKS

The REM (short for "remark") statement is used to insert comments or notes into a program.  When
BASIC encounters a REM statement, the rest of the line is ignored.

This serves mainly as an aid for the programmer and serves no useful function as far as the operation
of the program in solving a particular problem.

207  RELATIONAL TESTS

Suppose we wanted to write a program to check whether a number is zero.  With the statements
we've gone over so far, this could not be done.  What is needed is a statement which can be used
to conditionally branch to another statement.  The "IF-THEN" statement does just that.

Type in the following program:  (remember, type NEW first)

    10 INPUT B
    20 IF B=0 THEN 55
    30 PRINT "NON-ZERO"
    40 GOTO 10
    50 PRINT "ZERO"
    60 GOTO 10

When this program is typed and run, it will ask for a value for B.  Type in any value you wish.
The AIM 65 will then come to the "IF" statement.  Between the "IF" and the "THEN" portion
of the statement there are two expressions separated by a "relation."

A relation is one of the following six symbols:

    RELATION            MEANING
    --------            ------------------------
    =                   EQUAL TO
    >                   GREATER THAN
    <                   LESS THAN
    <>                  NOT EQUAL TO
    <= or =<            LESS THAN OR EQUAL TO
    => or >=            GREATER THAN OR EQUAL TO

The IF statement is either true or false, depending upon whether the two expressions satisfy the
relation.  For example, in the program we just did, if 0 was typed in for B the IF statement would
be true because 0=0.  In this case, since the number after the THEN is 50, execution of the program
would continue at line 50.  Therefore, "ZERO" would be printed and then the program would
jump back to line 10 (because of the GOTO statement in line 60).

Suppose a 1 was typed in for B.  Since 1=0 is false, the IF statement would be false and the program
would continue execution with the next line.  Therefore, "NON-ZERO" would be printed and the
GOTO in line 40 would send the program back to line 10.

A PROGRAM USING RELATIONS

Now try the following program for comparing two numbers:

    10 INPUT A,B
    20 IF A<=B THEN 50
    30 PRINT "A IS BIGGER"
    40 GOTO 10
    50 IF A<B THEN 80
    60 PRINT "THEY ARE THE SAME"
    70 GOTO 10
    80 PRINT "B IS BIGGER"
    90 GOTO 10

When this program is run, line 10 will input two numbers from the keyboard.  At line 20, if A is
greater than B, A<=B will be false.  This will cause the next statement to be executed, printing
"A IS BIGGER" and then line 40 sends the computer back to line 10 to begin again.

At line 20, if A has the same value as B, A<=B is true so we go to line 50.  At line 50, since A has
the same value as B, A<B is false; therefore, we go to the following statement and print "THEY
ARE THE SAME." Then line 70 sends us back to the beginning again.

At line 20, if A is smaller than B, A<=B is true so we goto line 50.  At line 50, A<B will be true
so we then go to line 80.  "B IS BIGGER" is then printed and again we go back to the beginning.

Try running the last two programs several times.  It may be easier to understand if you try writing
your own program at this time using the IF-THEN statement.  Actually trying programs of your
own is the quickest and easiest way to understand how BASIC works.  Remember, to stop these
programs just give a RETURN to the input statement.

208  LOOPING

One advantage of computers is their ability to perform repetitive tasks.  Let's take a closer look and
see how this works.

A SQUARE ROOT PROGRAM

Suppose we want a table of square roots from 1 to 9.  The BASIC function for square root is "SQR";
the form being SORIX), X being the number whose square root is to be calculated.  We could write
the program as follows:

    10 PRINT 1,SQR(1)
    20 PRINT 2,SQR(2)
    30 PRINT 3,SQR(3)
    40 PRINT 4,SQR(4)
    50 PRINT 5,SQR(5)
    60 PRINT 6,SQR(6)
    70 PRINT 7,SQR(7)
    80 PRINT 8,SQR(8)
    90 PRINT 9,SQR(9)

AN IMPROVED SQUARE ROOT PROGRAM

This program will do the job, but is terribly inefficient.  We can improve the program considerably
by using the IF statement just introduced as follows:

    10 N=1
    20 PRINT N;SQR(N)
    3D N=N+1
    40 IF N<=9 THEN 20

When this program is run, its output will look exactly like that of the 9 statement program above
it.  Let's look at how it works:

At line 10 we have a LET statement which sets the value of the variable N equal to 1.  At line 20
we print N and the square root of N using its current value.  It thus becomes 20 PRINT 1;SQR(1),
and this calculation is printed out.

At line 30 we use what will appear at first to be a rather unusual LET statement.  Mathematically,
the statement N=N+1 is nonsense.  However, the important thing to remember is that in a LET
statement, the symbol "=" does not signify equality.  In this case, "=" means "to be replaced
with."  All the statement does is to take the current value of N and add 1 to it.  Thus, after the
first time through line 30, N becomes 2.

At line 40, since N now equals 2, N<=9 is true so the THEN portion branches us back to line 20,
with N now at a value of 2.

The overall result is that lines 20 through 40 are repeated, each time adding 1 to the value of N.
When N finally equals 9 at line 20, the next line will increment it to 11.  This results in a false
statement at line 40, and since there are no further statements to the program it stops.

BASIC STATEMENTS FOR LOOPING

This technique is referred to as "looping" or "iteration."  Since it is used quite extensively in
programming, there are special BASIC statements for using it.  We can show these with the
following program:

    10 FOR N=1 TO 9
    20 PRINT N;SQR(N)
    30 NEXT N

The output of the program listed above will be exactly the same as the previous two programs.

At line 10, N is set to equal 1.  Line 20 causes the value of N and the square root of N so be printed.
At line 30 we sees new type of statement.  The "NEXT N" statement causes one to be added to N,
and then if N<=9 we go back to the statement following the "FOR" statement.  The overall
operation then is the same as with the previous program.

Notice that the variable following the "FOR" is exactly the same as the variable after the "NEXT."
There is nothing special about the N in this case.  Any variable could be used, as long as it is the
same in both the "FOR" and the "NEXT" statements.  For instance, "Z1" could be substituted
everywhere there is an "N" in the above program and it would function exactly the same.

ANOTHER SQUARE ROOT PROGRAM

Suppose we want to print a table of square roots of each even number from 10 to 20.  The
following program performs this task:

    10 N=10
    20 PRINT N;SQR(N)
    30 N=N+2
    40 IF N<=20 THEN 20

Note the similarity between this program and our "improved" square root program.  This program
can also be written using the "FOR" loop just introduced.

    10 FOR N=10 TO 20 STEP 2
    20 PRINT N;SQR(N)
    30 NEXT N

Notice that the only major difference between this program and the previous one using "FOR"
loops is the addition of the "STEP 2" clause.

This tells BASIC to add 2 to N each time, instead of 1 as in the previous program.  If no "STEP"
is given in a "FOR" statement, BASIC assumes that 1 is to be added each time.  The "STEP" can
be followed by any expression.

A COUNT-BACKWARD PROGRAM

Suppose we wanted to count backward from 10 to 1.  A program for doing this would be as
follows:

    10 I=10
    20 PRINT I
    30 I=I-1
    40 IF I>=1 THEN 20

Notice that we are now checking to see that I is greater than or equal to the final value.  The reason
is that we are now counting by a negative number.  In the previous examples it was the opposite, so
we were checking for a variable less than or equal to the final value.

SOME OTHER LOOPING OPERATIONS

The "STEP" statement previously shown can also be used with negative numbers to accomplish this
same result.  This can be done using the same format as in the other program:

    10 FOR I=10 TO 1 STEP -1
    20 PRINT I
    30 NEXT I

"FOR" loops can also be "nested."  For example:

    10 FOR I=1 TO 5
    20 FOR J=1 TO 3
    30 PRINT I,J
    40 NEXT J
    50 NEXT I

Notice that "NEXT J" precedes "NEXT I."  This is because the J-Ioop is inside the I-loop.  The
following program is incorrect; run it and see what happens:

    10 FOR I=1 TO 5
    20 FOR J=1 TO 3
    30 PRINT I,J
    40 NEXT I
    50 NEXT J

It does not work because when the "NEXT I" is encountered, all knowledge of the J-loop is lost.
This happens because the J-loop is "inside" the I-loop.

209  MATRIX OPERATIONS

It is often convenient to be able to select any element in a table of numbers.  BASIC allows this to
be done through the use of matrices.

A matrix is a table of numbers.  The name of this table (the matrix name) is any legal variable name,
"A" for example.  The matrix name "A" is distinct and separate from the simple variable "A," and
you could use both in the same program.

To select an element of the table, we subscript "A":  that is, to select the I'th element, we enclose I
in parentheses "(I)" and then follow "A" by this subscript.  Therefore, "A(I)" is the I'th element in
the matrix "A."

"A(1)" is only one element of matrix A, and BASIC must be told how much space so allocate for
the entire matrix.  This is done with a "DIM" statement, using the format "DIM A(15)."  In this
case, we have reserved space for the matrix index "I" to go from 0 to 15.  Matrix subscripts always
start as 0; therefore, in the above example, we have allowed for 16 numbers in matrix A.

If "A(1)" is used in a program before is has been dimensioned, BASIC reserves space for 11 elements
(0 through 10).

A SORT PROGRAM

As an example of how matrices are used, try the following program so sort a list of 8 numbers, in
which you pick the numbers to be sorted:

     10 DIM A(8)                            110 A(I)=A(I+1)
     20 FOR I=1 TO 8                        120 A(I+1)=T
     30 INPUT A(I)                          130 F=1
     50 NEXT I                              140 NEXT I
     70 F=0                                 150 IF F=1 THEN 70
     80 FOR I=1 TO 7                        160 FOR I=1 TO 8
     90 IF A(I)<=A(I+1) THEN 140            170 PRINT A(I)
    100 T=A(I)                              180 NEXT I

When line 10 is executed, BASIC sets aside space for 9 numeric values, A(0) through A(8).
Lines 20 through 50 get the unsorted list from the user.  The sorting itself is done by going through
the list of numbers and switching any two that are not in order.  "F" is used to indicate if any
switches were made; if any were made, line 150 tells BASIC to go back and check some more.

If we did not switch any numbers, or after they are all in order, lines 160 through 180 will print
out the sorted list.  Note that a subscript can be any expression.

210  SUBROUTINES

If you have a program that performs the same action in several different places, you could duplicate
the same statements for the action in each place within the program.

The "GOSUB" and "RETURN" statements can be used to avoid this duplication.  When a "GOSUB"
is encountered, BASIC branches to the line whose number follows the "GOSUB."  However, BASIC
remembers where it was in the program before it branches.  When the "RETURN" statement is
encountered, BASIC goes back to the first statement following the last "GOSUB" that was
executed.  Observe the following program:

     10 PRINT "WHAT IS THE NUMBER";
     30 GOSUB 100
     40 T=N
     50 PRINT "SECOND NUMBER";
     70 GOSUB 100
     80 PRINT "THE SUM IS"; T+N
     90 STOP
    100 INPUT N
    110 IF N=INT(N) THEN 140
    120 PRINT "MUST BE INTEGER."
    130 GOTO 100
    140 RETURN

This program asks for two numbers (which must be integers), and then prints their sum.  The
subroutine in this program is lines 100 to 140.  The subroutine asks for a number, and if it is not
an integer, asks for a new number.  It will continue to ask until an integer value is typed in.

The main program prints "WHAT IS THE NUMBER," and then calls the subroutine so get the value
of the number into N.  When the subroutine returns (to line 40), the value input is saved in the
variable T.  This is done so that when the subroutine is called a second time, the value of the first
number will not be lost.

"SECOND NUMBER" is then printed, and the second value is entered when the subroutine is
again called.

When the subroutine returns the second time, "THE SUM IS" is printed, followed by the sum.
T contains the value of the first number that was entered and N contains the value of the second
number.


STOPPING A PROGRAM

The next statement in the program is a "STOP" statement.  This causes the program to stop
execution at line 90.  If the "STOP" statement was excluded from the program, we would "fall
into" the subroutine at line 100.  This is undesirable because we would be asked to input another
number.  If we did, the subroutine would try to return; and since there was no "GOSUB" which
called the subroutine, an RG error would occur.  Each "GOSUB" executed in a program should
have a matching "RETURN" executed later.  The opposite also applies:  a "RETURN" should be
encountered only if it is part of a subroutine which has been called by a "GOSUB."

Either "STOP" or "END" can be used to separate a program from its subroutines.  "STOP" will
print a message saying at what line the "STOP" was encountered.

211  ENTERING DATA

Suppose you had to enter numbers to your program that did not change each time the program was
run, but you would like it to be easy to change them if necessary.  BASIC contains special state-
ments, "READ" and "DATA," for this purpose.

Consider the following program:

     10 PRINT "GUESS A NUMBER";
     20 INPUT G
     30 READ D
     40 IF D = -999999 THEN 90
     50 IF D<>G THEN 30
     60 PRINT "YOU ARE CORRECT"
     70 END
     90 PRINT "BAD GUESS, TRY AGAIN."
     95 RESTORE
    100 GOTO 10
    110 DATA 1,393,-39,28,391,-8,0,3.14,90
    120 DATA 89,5,10,15,-34,-999999

When the "READ" statement is encountered, the effect is the same as an INPUT statement.  But,
instead of getting a number from the keyboard, a number is read from the "DATA" statements.

The first time a number is needed for a READ, the first number in the first DATA statement is
read.  The second time one is needed, the second number in the first DATA statement is read.
When the all numbers of the first DATA statement have been read in this manner, the second
DATA statement will be used.  DATA is always read sequentially in this manner, and there may
be any number of DATA statements in your program.

The purpose of this program is to play a little game in which you try to guess one of the numbers
contained in the DATA statements.  For each guess that is typed in, we read through all of the
numbers in the DATA statements until we find one that matches the guess.

If more values are read than there are numbers in the DATA statements, an out of data (OD) error
occurs.  That is why in line 40 we check to see if -999999 was read.  This is not one of the numbers
to be matched, but is used as a flag to indicate that all of the data (possible correct guesses) has
been read.  Therefore, if -999999 was read, we know that the guess was incorrect.

Before going back to line 10 for another guess, we need to make the READ's begin with the first
piece of data again.  This is the function of the "RESTORE." After the RESTORE is encountered,
the next piece of data read will be the first number in the first DATA statement again.

DATA statements may be placed anywhere within the program.  Only READ statements make use
of the DATA statements in a program, and any other time they are encountered during program
execution they will be ignored.

212  STRINGS

A list of characters is referred to as a "String." Rockwell, R6500, and THIS IS A TEST are all
strings.  Like numeric variables, string variables can be assigned specific values.  String variables are
distinguished from numeric variables by a "$" after the variable name.

For example, try the following:

    A$="ROCKWELL R6500"
    PRINT A$
    ROCKWELL R6500

In this example, we set the string variable A$ to the string value "ROCKWELL R6500."  Note that
we also enclosed the character string so be assigned to A$ in quotes.

LEN FUNCTION

Now that we have set A$ to a string value, we can find out what the length of this value is (the
number of characters it contains).  We do this as follows:

    PRINT LEN(A$),LEN("MICROCOMPUTER")
    14        13

The "LEN" function returns an integer equal to the number of characters in a string.

A string expression may contain from 0 to 255 characters.  A string containing 0 characters is called
the "null" string.  Before a string variable is set to a value in the program, it is initialized to the null
string.  Printing a null string on the terminal will cause no characters to be printed, and the printer
or cursor will not be advanced to the next column.  Try the following:

    PRINT LEN(Q$);Q$;3
    0 3

Another way to create the null string is:  Q$=""

Setting a string variable to the null string can be used to free up the string space used by a non-null
string variable.

LEFT$ FUNCTION

It is often desirable to access parts of a string and manipulate them.  Now that we have set A$ to
"ROCKWELL R6500," we might want to print out only the first eight characters of A$.  We would
do so like this:

    PRINT LEFT$(A$,8)
    ROCKWELL

"LEFT$" is a string function which returns a string composed of the leftmost N characters of its
string argument.  Here is another example:

    FOR N=1 TO LEN(A$):PRINT LEFT$(A$,N):NEXT N
    R
    RO
    ROC
    ROCK
    ROCKW
    ROCKWE
    ROCKWEL
    ROCKWELL
    ROCKWELL R
    ROCKWELL R6
    ROCKWELL R65
    ROCKWELL R650
    ROCKWELL R6500

Since A$ has 14 characters this loop will be executed with N=1,2,3,...,13,14.  The first time
through only the first character will be printed, the second time the first two characters will be
printed, etc.

RIGHT$ FUNCTION

Another string function, called "RIGHT$," returns the right N characters from a string expression.
Try substituting "RIGHT$" for "LEFT$" in the previous example and see what happens.

MID$ FUNCTION

There is also a string function which allows us to take characters from the middle of a string.  Try
the following:

    FOR N=1 TO LEN(A$):PRINT MID$(A$,N):NEXT N
    ROCKWELL R6500
    OCKWELL R6500
    CKWELL R6500
    KWELL R6500
    WELL R6500
    ELL R6500
    LL R6500
    L R6500
     R6500
    R6500
    6500
    500
    00
    0

"MID$" returns a string starting at the Nth position of A$ so the end (last character) of A$.  The
first position of the string is position 1 and the last possible position of a string is position 255.

Very often it is desirable to extract only the Nth character from a string.  This can be done by
calling MID$ with three arguments.  The third argument specifies the number of characters to
return.

For example:

    FOR N=1 TO LEN(A$):PRINT MID$(A$,N,1),MID$(A$,N,2):NEXT N
    R         RO
    O         OC
    C         CK
    K         KW
    W         WE
    E         EL
    L         LL
    L         L
               R
    R         R6
    6         65
    5         50
    0         00
    0         0

CONCATENATION-JOINING STRINGS

Strings may also be concatenated (put or joined together) through the use of the "+" operator.
Try the following:

    B$="BASIC FOR"+" "+A$
    PRINT B$
    BASIC FOR ROCKWELL R6500

Concatenation is especially useful if you wish to take a string apart and then put it back together
with slight modifications.  For instance:

    C$=LEFT$(B$,9)+"-"+MID$(B$,11,8)+"-"+RIGHT$(B$,5)
    PRINT C$
    BASIC FOR-ROCKWELL-R6500

VAL AND STRS FUNCTIONS

Sometimes it is desirable to convert a number to its string representation, and vice-versa.  "VAL"
and "STR$" perform these functions.

Try the following:

    STRING$="567.8"
    PRINT VAL(STRING$)
    567.8
    STRING$=STR$(3.1415)
    PRINT STRINGS$,LEFT$(STRING$,5)
    3.1415    3.14

"STR$" can be used to perform formatted I/O on numbers.  You can convert a number to a string
and then use LEFT$, RIGHT$, MID$ and concatenation to reformat the number as desired.

"STR$" can also be used to conveniently find out how many print columns a number will take.
For example:

    PRINT LEN(STR$(3.157))
    6

If you have an application in which a user is typing in a question such as "WHAT IS THE VOLUME
OF A CYLINDER OF RADIUS 5.36 FEET, OF HEIGHT 5.1 FEET?" you can use "VAL" to
extract the numeric values 5.36 and 5.1 from the question.

CHR$ FUNCTION

CHR$ is a string function which returns a one character string which contains the alphanumeric
equivalent of the argument, according so the conversion table in Appendix E.  ASC takes the first
character of a string and converts it to its ASCII decimal value.

One of the most common uses of CHR$ is to send a special character to a terminal.

    100 DIM A$(15)
    110 FOR I=1 TO 15
    120 READ A$(I)
    130 NEXT I
    120 F=0:I=1
    130 IF A$(I)<=A$(I+1) THEN 180
    140 T$=A$(I+1)
    150 A$(I+1)=A$(I)
    160 A$(I)=T$
    170 F=1
    180 I=I+1
    185 IF I<15 THEN 130
    190 IF F THEN 120
    200 FOR I=1 TO 15
    202 PRINT A$(I)
    204 NEXT I
    220 DATA AIM 65,DOG
    230 DATA CAT,R6500
    240 DATA ROCKWELL,RANDOM
    250 DATA SATURDAY,"***ANSWER***"
    260 DATA MICRO,FOO
    270 DATA COMPUTER,MED
    280 DATA NEWPORT BE-ACH,DALLAS,ANAHEIM

ADDITIONAL STRING CONSIDERATIONS

1.  A string may contain from 0 to 255 characters.  All string variable names end in a dollar
    sign ($); for example, A$, B9$, K$, HELLO$.

2.  String matrices may be dimensioned exactly like numeric matrices.  For instance,
    DIM A$(10,10) creates a string matrix of 121 elements, eleven rows by elevon columns
    (rows 0 to 10 and columns 0 to 10).  Each string matrix element is a complete string,
    which can be up to 255 characters in length.

    NAME            EXAMPLE                 PURPOSE/USE
    ----            -------                 -----------

    DIM             25 DIM A$(10,10)        Allocates space for a pointer and length for
                                            each element of a string matrix.  No string
                                            space is allocated.

    LET             27 LET A$="FOO"+V$      Assigns the value of a string expression to
                                            a string variable.  LET is optional.

    =                                       String comparison operators.  Comparison
    >                                       is made on the basis of ASCII codes, a
    <                                       character at a time until a difference is
    <= or =<                                found.  If during the comparison of two
    >= or =>                                strings, the end of one is reached, the
    <>                                      shorter string is considered smaller.
                                            Note that "A " is greater than "A" since
                                            trailing spaces are significant.

    +               30 LET Z$=R$+Q$         String concatenation.  The resulting string
                                            must be less than 256 characters in length
                                            or an LS error will occur.

    INPUT           40 INPUT X$             Reads a string from the keyboard.  String
                                            does not have to be quoted; but if not,
                                            leading blanks will be ignored and the
                                            string will be terminated on a "," or ":"
                                            character.

    READ            50 READ X$              Reads a string from DATA statements
                                            within the program.  Strings do not have
                                            to be quoted; but if they are not, they
                                            are terminated on a "," or ":" character
                                            and leading spaces are ignored.  See
                                            DATA for the format of string data.

    PRINT           60 PRINT X$             Prints the string expression on the
                    70 PRINT "FOO"+A$       display/printer.

300  STATEMENT DEFINITIONS

301  SPECIAL CHARACTERS

    CHARACTER       USE
    ---------       ---

    @               Erases current line being typed, and types a carriage return/line
                    feed.

    DEL             Erases last character typed.  If no more characters are left on
                    the line, types a carriage return/line feed.

    RETURN          A RETURN must end every line typed in.  Returns cursor to
                    the first position (leftmost) on line, and prints the line if the
                    printer is on.

    F1              Interrupts execution of a program or a list command.  F1 has
                    effect when a statement finishes execution, or in the case of
                    interrupting a LIST command, when a complete line has
                    finished printing.  In both cases a return is made to BASIC's
                    command level and OK is typed.

                    Prints "BREAK IN LINE XXXX," where XXXX is the line
                    number of the next statement to be executed.

                    There is no F1 key on a TTY.  However, when TTY is being
                    used, the AIM 65's F1 key is operational and can be used.

    : (colon)       A colon is used to separate statements on a line.  Colons may
                    be used in direct and indirect statements.  The only limit on
                    the number of statements per line is the line length.  It is not
                    possible to GOTO or GOSUB to the middle of a line.

    ?               Question marks are equivalent to PRINT.  For instance, ? 2+2
                    is equivalent to PRINT 2+2.  Question marks can also be used
                    in indirect statements.  10 ? X, when listed, will be typed as
                    10 PRINT X.

    $               A dollar sign ($) suffix on a variable name establishes the
                    variable as a character string.

    %               A percent sign (%) suffix on a variable name establishes the
                    variable as an integer

    !               An exclamation sign (!) suffix on an INPUT, PRINT, or ?
                    command causes the input or output to be printed even
                    though the printer is turned off.

    ESC             Returns control to the Monitor.

    CNTL PRINT      Turns the AIM 65 printer on if it is off, and off if it is on.

302  OPERATORS

    SYMBOL          SAMPLE STATEMENT        PURPOSE/USE
    ------          ----------------        -----------

    =               A=100                   Assigns a value to a variable

                    LET Z=2.5               The LET is optional

    -               B=-A                    Negation.  Note that 0-A is subtraction,
                                            while -A is negation.

    ^ (F3 key)      130 PRINT X^3           Exponentiation (equal to X*X*X in
                                            in the sample statement)

                                            0^0=1    0 to any other power = 0

                                            A^B, with A negative and B not an
                                            integer gives an FC error.

    *               140 X=R*(B*D)           Multiplication.

    /               150 PRINT X/1.3         Division.

    +               160 Z=R+T+Q             Addition

    -               170 J=100-I             Subtraction

RULES FOR EVALUATING EXPRESSIONS:

1)  Operations of higher precedence are performed before operations of lower precedence.
    This means the multiplication and divisions are performed before additions and subtractions.
    As an example, 2+10/5 equals 4, not 2.4.  When operations of equal precedence are found
    in a formula, the left hand one is executed first:  6-3+5=8, not -2.

2)  The order in which operations are performed can always be specified explicitly through the
    use of parentheses.  For instance, to add 5 to 3 and then divided that by 4, we would use
    (5+3)/4, which equals 2.  If instead we had used 5+3/4, we would get 5.75 as a result
    (5 plus 3/4).

The precedence of operators used in evaluating expressions is as follows, in order beginning with the
highest precedence :

                NOTE

        Operators listed on the same line have the same
        precedence.

1)  Expressions in parentheses are always evaluated first

2)  ^ (F3 KEY)                  ExponentiatiOn

3)  NEGATION                    -X where X may be a formula

4)  * and /                     Multiplication and Division

5)  + and -                     Addition and Subtraction

6)  RELATIONAL OPERATORS:               =               Equal
    (equal precedence for all six)      <>              Not Equal
                                        <               Less Than
                                        >               Greater Than
                                        =< or <=        Less Than or Equal
                                        => or >=        Greater Than or Equal

                                (These three below are Logical Operators)

7)  NOT                         Logical and bitwise "NOT" like
                                negation, not takes only the formula
                                to its right as an argument

8)  AND                         Logical and bitwise "AND"

9)  OR                          Logical and bitwise "OR"

A relational expression can be used as part of any expression.

Relational Operator expressions will always have a value of True (-1) or a value of False (0).
Therefore, (5=4)=0, (5=5)=-1, (4>5)=0, (4<5)=-1, etc.

The THEN clause of an IF statement is executed whenever the formula after the IF is not equal to 0.
That is to say, IF X THEN ... is equivalent to IF X<>0 THEN ....

    SYMBOL          SAMPLE STATEMENT                PURPOSE/USE
    ------          ----------------                -----------

    -               10 IF A=15 THEN 40              Expression Equals Expression

    <>              70 IF A<>0 THEN 5               Expression Does Not Equal Expression

    >               30 IF B>100 THEN 8              Expression Greater Than Expression

    <               160 IF B<2 THEN 10              Expression Less Than Expression

    <=,=<           180 IF 100<=B+C THEN 10         Expression Less Than or Equal To
                                                    Expression

    >=,=>           190 IF Q=>R THEN 50             Expression Greater Than Or Equal To
                                                    Expression

    AND             2 IF A<5 AND B<2 THEN 7         If expression 1 (A<5) AND expression 2
                                                    (B<2) are both true, then branch to
                                                    line 7

    OR              IF A<1 OR B<2 THEN 2            If either expression 1 (A<1) OR
                                                    expression 2 (B<2) is true, then branch
                                                    to line 2

    NOT             IF NOT Q3 THEN 4                If expression "NOT Q3" is true (Because
                                                    Q3 is false), then branch to line 4

                                                    Note:  NOT -1=0 (NOT true=false)

AND, OR, and NOT can be used for bit manipulation, and for performing boolean operations.

These three operators convert their arguments to sixteen bit, signed two's-complement integers in
the range -32768 to +32767.  They then perform the specified logical operation on them and return
a result within the same range.  If the arguments are not in this range, an "FC" error results.

The operations are performed in bitwise fashion, this means that each bit of the result is obtained
by examining the bit in the same position for each argument.

The following truth table shows the logical relationship between bits:

    OPERATOR      ARGUMENT 1      ARGUMENT 2      RESULT
    --------      ----------      ----------      ------

      AND             1               1              1
                      0               1              0
                      1               0              0
                      0               0              0

      OR              1               1              1
                      1               0              1
                      0               1              1
                      0               0              0

      NOT             1               -              0
                      0               -              1

EXAMPLES:  (In all of the examples below, leading zeroes on binary numbers are not shown.)

63 AND 16=16    Since 63 equals binary 111111 and 16 equals binary 10000, the result
                of the AND is binary 10000 or 16.

15 AND 14=14    15 equals binary 1111 and 14 equals binary 1110, so 15 AND 14
                equals binary 1110 or 14.

-1 AND 8=8      -1 equals binary 1111111111111111 and 8 equals binary 1000, so
                the result is binary 1000 or 8 decimal.

4 AND 2=0       4 equals binary 100 and 2 equals binary 10, so the result is binary 0
                because nons of the bits in either argument match to give a 1 bit in
                the result.

4 OR 2=6        Binary 100 OR'd with binary 10 equals binary 110, or 6 decimal.

10 OR 10=10     Binary 1010 OR'd with binary 1010 equals binary 1010, or 10 decimal.

-1 OR -2=-1     Binary 1111111111111111 (-1) OR'd with binary 1111111111111110
                (-2) equals binary 1111111111111111, or -1.

NOT 0=-1        The bit complement of binary 0 to 16 places is sixteen ones
                (1111111111111111) or -1.  Also NOT -1=0.

NOT X           NOT X is equal to -(X+1).  This is because to form the sixteen bit
                two's complement of the number, you take the bit (one's)
                complement and add one.

NOT 1=-2        The sixteen bit complement of 1 is 1111111111111110, which is
                equal to -(1+1) or -2.

A typical use of the bitwise operators is to test bits set in the computer's locations which reflect the
state of some external device.

Bit position 7 is the most significant bit of a byte, while position 0 is the least significant.

For instance, suppose bit 1 of location 40963 is 0 when the door to Room X is closed, and 1 if the
door is open.  The following program will print "Intruder Alert" if the door is opened:

    10 IF NOT (PEEK(40963) AND 2) THEN 10       This line will execute over and over until
                                                bit 1 (masked or selected by the 2)
                                                becomes a 1.  When that happens, we go
                                                to line 20.

    20 PRINT "INTRUDER ALERT"                   Line 20 will output "INTRUDER
                                                ALERT."

However, we can replace statement 10 with a "WAIT" statement, which has exactly the same effect.

    10 WAIT 40963,2                             This line delays the execution of the
                                                next statement in the program until
                                                bit 1 of location A003 becomes 1.  The
                                                WAIT is much faster than the equivalent
                                                IF statement and also takes less bytes
                                                of program storage.

The following is another useful way of using relational operators:

    125 A=-(B>C)*B-(B<=C)*C                     This statement will set the variable A
                                                to MAX(B,C) = the larger of the two
                                                variables B and C.

303  COMMANDS

A BASIC command may be entered when the cursor is displayed.  This is called the "Command Level."
Commands may be used as program statements.  Certain commands, such as LIST, NEW, and LOAD
will terminate program execution when they finish.  Each command may require one or more
arguments in addition to the command statement, as defined in the syntax/function description.  An
argument without parenthesis is required to be entered without parenthesis.  Arguments contained
within parenthesis are required to be entered with the shown parenthesis.  Arguments within brackets
are optional.  Optional arguments, if included, must be entered with or without accompanying
parenthesis, however shown.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

CLEAR           CLEAR                                                   CLEAR
                Clears all program variables, resets "FOR"
                and "GOSUB" state, and restores data.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

CONT            CONT                                                    CONT
                Continues program execution after the F1
                key or a STOP or INPUT statement termi-
                nates execution.  You cannot continue after
                any error, after modifying your program, or
                before your program has been run.  One of
                the main purposes of CONT is debugging.
                Suppose at some point after running your
                program, nothing is printed.  This may be
                because your program is performing some
                time consuming calculation, but it may be
                because you have fallen into an "infinite
                loop."  An infinite loop is a series of BASIC
                statements from which there is no excape.
                BASIC will keep executing the series of
                statements over and over; until you inter-
                vene or until power to the AIM 65 is
                turned off.  If you suspect your program
                is in an infinite loop, press F1 until the
                BREAK message is displayed.  The line
                number of the statement BASIC was
                executing will be displayed.  After BASIC
                has displayed the cursor, you can use
                PRINT to type out some of the values of
                your variables.  After examining these
                values you may become satisfied that your
                program is functioning correctly.  You
                should then type in CONT to Continue
                executing your program where it left off, or
                type a direct GOTO statement to resume
                execution of the program at a different line.
                You could also use assignment statements
                to set some of your variables to different
                values.  Remember, if you interrupt a
                program with the F1 key and expect to
                continue it later, you must not get any
                errors or type in any new program lines.
                If you do, you won't be able to continue
                and will get a "CN" (continue not) error.
                It is impossible to continue a direct
                command.  CONT always resumes
                execution at the next statement to be
                executed in your program when F1 was
                typed.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

FRE             FRE (expression)                                        270 PRINT FRE(0)
                Gives the number of memory bytes
                currently unused by BASIC.  A dummy
                operand--0 or 1--must be used.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

LIST            LIST [[start line] [-[end line]]]
                Lists current program optionally starting at
                specified line.  List can be interrupted with
                the F1 key.  (BASIC will finish listing the
                current line.)

                Lists entire program                                    LIST

                Lists just line 100.                                    LIST 100

                Lists lines 100 to 1000.                                LIST 100-1000

                Lists from current line to line 1000.                   LIST -1000

                Lists from line 100 to end of program.                  LIST 100-

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

LOAD            LOAD                                                    LOAD
                Loads a BASIC program from the cassette
                tape.  When done, the LOAD will display
                the cursor.  See Appendix G for more
                information.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

NEW             NEW                                                     NEW
                Deletes current program and all variables.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

PEEK            PEEK (address)                                          356 PRINT PEEK(I)
                The PEEK function returns the contents of
                memory address I in decimal.  The value
                returned will be =>0 and <=255.  If I is
                >65535 or <0, an FC error will occur.
                An attempt to read a non-existent memory
                address will return an unknown value.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

POKE            POKE location, byte                                     357 POKE I,J
                The POKE statement stores the byte
                specified by its second argument (J) into
                the location given by its first argument (I).
                The byte to be stored must be =>0 and
                <=255, or an FC error will occur.  The
                address (I) must be =>0 and <=65535, or
                an FC error result.  Caution:  Careless use
                of the POKE statement may cause your
                program, BASIC, or the Monitor functions
                to operate incorrectly, to hang up, and/or
                cause loss of your program.  Note that
                Pages 0 and 1 in memory are reserved for
                use by BASIC and should not be used for
                user program variable storage.  A POKE to
                a non-existent memory location is harmless.
                One of the main uses of POKE is to pass
                arguments to machine language subroutines.
                (See Appendix F.)  You could also use
                PEEK and POKE to write a memory
                diagnostic or an assembler in BASIC.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

RUN             RUN line number                                         RUN 200
                Starts execution of the program currently in
                memory at the specified line number.  RUN
                deletes all variables [does a CLEAR) and
                restores DATA.  If you have stopped your
                program and wish to continue execution at
                some point in the program, use a direct
                GOTO statement to start execution of your
                program at the desired line, or CONT to
                continue after a break.

                Start program execution at the lowest                   RUN
                numbered statement.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

SAVE            SAVE                                                    SAVE
                Saves the current program in the AIM 65
                memory on cassette tape.  The program in
                memory is left unchanged.  More than one
                program may be stored on cassette using
                this command.

                See Appendix G for more information.

304  PROGRAM STATEMENTS

In the following description of statements, an argument of B, C, V or W denotes a numeric variable,
X denotes a numeric expression, X$ denotes a string expression and an I or J denotes an expression
that is truncated to an integer before the statement is executed.  Truncation means that any
fractional part of the number is lost, e.g., 3.9 becomes 3, 4.01 becomes 4.

An expression is a series of variables, operators, function calls and constants which after the
operations and function calls are performed using the precedence rules, evaluates to a numeric
or string value.

A constant is either a number (3.14) or a string literal ("FOO").

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

DEF             DEF FNx [(argument list)] = expression                  100 DEF FNA(V)=V/B+C
                The user can define functions like the built-
                in functions (SQR, SGN, ABS, etc.) through
                the use of the DEF statement.  The name
                of the function is "FN" followed by any
                legal variable name, for example:  FNX,
                FNJ7, FNKO, FNR2.  User defined func-
                tions are restricted to one line.  A function
                may be defined to be any expression, but
                may only have one argument.  In the
                example, B and C are variables that are used
                in the program.  Executing the DEF state-
                ment defines the function.  User defined
                functions can be redefined by executing
                another DEF statement for the same
                function.  "V" is called the dummy variable.

                Execution of this statement following the               100 Z=FNA(3)
                above would cause Z to be set to 3/B+C,
                but the value of V would be unchanged.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

DIM             DIM variable (size 1, [size 2...])                      113 DIM A(3),B(10)
                Allocates space for matrices.  All matrix
                elements are set to zero by the DIM
                statement.

                Matrices can have from one to 255                       114 DIM R3(5,5),
                dimensions.                                             D$(2,2,2)

                Matrices can be dimensioned dynamically                 115 DIM Q1(N),Z(2*I)
                during program execution.  If a matrix is
                not explicitly dimensioned with a DIM
                statement, it is assumed to be a single
                dimensioned matrix of whose single
                subscript may range 0 to 10 (eleven
                elements).

                If this statement was encountered before a              117 A(8)=4
                DIM statement for A was found in the
                program, it would be as if a DIM A(10)
                had been executed previous to the execu-
                tion of line 117.  All subscripts start at
                zero (0), which means that DIM X(100)
                really allocates 101 matrix elements.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

END             END                                                     999 END
                Terminates program execution without
                printing a BREAK message.  (See STOP.)
                CONT after an END statement causes
                execution to resume at the statement after
                the END Statement.  END can be used
                anywhere in the program, and is optional.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

FOR             FOR variable = expression to expression                 300 FOR V=1 TO 9.3
                [STEP expression]  (See NEXT statement)                 STEP .6
                V is set equal to the value of the expression
                following the equal sign, in this case 1.  This
                value is called the initial value.  Then the
                statements between FOR and NEXT are
                executed.  The final value is the value of the
                expression following the TO.  The step is
                the value of the expression following STEP.
                When the NEXT statement is encountered,
                the step is added to the variable.

                If no STEP was specified, it is assumed to              310 FOR V=1 TO 9.3
                be one.  If the step is positive and the new
                value of the variable is <= the final value
                (9.3 in this example), or the step value is
                negative and the new value of the variable
                is => the final value, then the first state-
                ment following the FOR statement is
                executed.  Otherwise, the statement
                following the NEXT statement is executed.
                All FOR loops execute the statements
                between the FOR and the NEXT at least
                once, even in cases like FOR V=1 TO 0.

                Note that expressions (formulas) may be                 315 FOR V=10*N TO
                used for the initial, final and step values             3.4/Q STEP SQR(R)
                in a FOR loop.  The values of the expres-
                sions are computed only once, before the
                body of the FOR...NEXT loop is
                executed.

                When the statement after the NEXT is                    320 FOR V=9 TO 1
                executed, the loop variable is never equal              STEP -1
                to the final value, but is equal to whatever
                value caused the FOR...NEXT loop to
                terminate.  The statements between the
                FOR and its corresponding NEXT in both
                examples above (310 and 320) would be
                executed nine times.

                Error:  do not use nested FOR...NEXT                    330 FOR W=1 TO 10:
                loops with the same index variable.                     FOR W=1 TO 5:NEXT
                                                                        W:NEXT W
                FOR loop nesting is limited only by the
                available memory.  (See Appendix C.)

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

GOSUB           GOSUB line number                                       10 GOSUB 910
                Branches to the specified statement (910)
                until a RETURN is encountered; when a
                branch is then made to the statement after
                the GOSUB.  GOSUB nesting is limited
                only by the available memory.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

GOTO            GOTO line number                                        50 GOTO 100
                Branches to the statement specified.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

IF...GOTO       IF expression GOTO line number ...                      32 IF X<=Y+23.4
                Equivalent to IF...THEN, except that                    GOTO 92
                IF...GOTO must be followed by a line
                number, while IF...THEN can be
                followed by either a line number or
                another statement.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

IF...THEN       IF expression THEN line number ...                      IF X<10 THEN 5

                Branches to specified statement if the
                relation is True.

                Executes all of the statements on the                   20 IF X<0 THEN PRINT
                remainder of the THEN if the relation                   "X LESS THAN 0"
                is True.

                WARNING:  The "Z=A" will never be                       25 IF X=5 THEN 50:Z=A
                executed because if the relation is true,
                BASIC will branch to line 50.  If the
                relation is false BASIC will proceed to
                to the line following line 25.

                In this example, if X is less than 0, the               26 IF X<0 THEN PRINT
                PRINT statement will be executed and                    "ERROR, X NEGATIVE":
                then the GOTO statement will branch to                  GOTO 350
                line 350.  If the X was 0 or positive,
                BASIC will proceed to execute the lines
                after line 26.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

LET             [LET] variable = expression                             300 LET W=X
                Assigns a value to a variable,

                "LET" is optional.                                      310 V=5.1

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

NEXT            NEXT [variable] [,variable] ...                         340 NEXT V
                Marks the end of a FOR loop.

                If no variable is given, matches the most               345 NEXT
                recent FOR loop,

                A single NEXT may be used to match                      350 NEXT V,W
                multiple FOR statements.  Equivalent
                to NEXT V:NEXT W.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

ON...GOSUB      ON expression GOSUB line [,line] ...                    110 ON I GOSUB 50,60
                Identical to "ON...GOTO," except that
                a subroutine call (GOSUB) is executed
                instead of a GOTO.  RETURN from the
                GOSUB branches to the statement after
                the ON...GOSUB.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

ON...GOTO       ON expression GOTO line [, line] ...                    100 ON I GOTO 10,20,
                Branches to the line indicated by the                   30,40
                I'th number after the GOTO.  That is:

                IF I=1, THEN GOTO LINE 10
                IF I=2, THEN GOTO LINE 20
                IF I=3, THEN GOTO LINE 30
                IF I=4, THEN GOTO LINE 40.

                If I=0, or I attempts to select a nonexistent
                line (>=5 in this case), the statement after
                the ON statement is executed.  However, if
                I is >255 or <0, an FC error message will
                result.  As many line numbers as will fit on
                a line can follow an ON...GOTO.

                This statement will branch to line 40 if the            105 ON SGN(X)+2
                expression X is less than zero, to line 50 if           GOTO 40,50,60
                it equals zero, and to line 60 if it is greater
                than zero.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

REM             REM any text                                            500 REM NOW SET
                Allows the programmer to put comments                   V=0
                in his program.  REM statements are not
                executed, but can be branched to.  A REM
                statement is terminated by end of line, but
                not by a ":".

                In this case the V=0 will never be executed             505 REM SET V=0:
                by BASIC.                                               V=0

                In this case V=0 will be executed,                      505 V=0: REM SET
                                                                        V=0

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

RESTORE         RESTORE                                                 510 RESTORE
                Allows the re-reading of DATA statements,
                After a RESTORE, the next piece of data
                read will be the first piece listed in the first
                DATA statement of the program.  The
                second piece of data read will be the second
                piece listed in the first DATA statement,
                and so on as in a normal READ operation.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

RETURN          RETURN                                                  50 RETURN
                Causes a subroutine to return to the state-
                ment after the most recently executed
                GOSUB.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

STOP            STOP                                                    900 STOP
                Causes a program to stop execution and to
                enter command mode.

                Prints BREAK IN LINE 900.  (As per this
                example.)  CONT after a STOP branches
                to the statement following the STOP.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

USR             USR (argument)                                          200 V=USR(W)
                Calls the user's machine language subroutine
                with the argument.  See PEEK and POKE in
                Subject 303, and Appendix F.

SYMBOL          SYNTAX/FUNCTION                                         EXAMPLE

WAIT            WAIT (address, mask [, select] )                        805 WAIT I,J,K
                This statement reads the contents of the                806 WAIT I,J
                addressed location, does an Exclusive-OR
                with the select value, and then ANDs the
                result with the mask.  This sequence is
                repeated until a non-zero result is obtained,
                at which time execution continues at the
                statement that follows WAIT.  If the WAIT
                statement has no select argument, the
                select value is assumed to be zero.  If you
                are waiting for a bit to become zero, there
                should be a "one" in the corresponding
                bit position of the select value.  The select
                value (K) and the mask value (J) can range
                from 0 to 255.  The address (I) can range
                from 0 to 65535.

305  INPUT/OUTPUT STATEMENTS

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

DATA            DATA item [, item...]                                   10 DATA 1,3,-1E3,.04
                Specifies data, read from left to right.
                Information appears in data statements in
                the same order as it will be read in the
                program.

                Strings may be read from DATA state-                    20 DATA "FOO",Z1
                ments.  If you want the string to contain
                leading spaces (blanks), colons (:) or
                commas (,), you must enclose the string
                in double quotes.  It is illegal so have a
                double quote within string data or a
                string literal.  (""BASIC"" is illegal.)

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

INPUT           INPUT [!] ["prompt string literal";]                    3 INPUT V,W,W2
                variable [, variable] ...
                Requests data from the keyboard (to be
                typed in).  Each value must be separated
                from the preceeding value by a comma (,).
                The last value typed should be followed by
                a carriage return.  A "?" is displayed as a
                prompt character.  Only constants may be
                typed in as a response to an INPUT state-
                ment, such as 4.5E-3 or "CAT."  If more
                data was requested in an INPUT statement
                than was typed in, a "??" is printed and
                the rest of the data should be typed in.  If
                more data was typed in than was requested,
                the warning "EXTRA IGNORED" will be
                displayed.  Strings must be input in the
                same format as they are specified in DATA
                statements.

                Optionally displays a prompt string                     5 INPUT "VALUE";V
                ("VALUE") before requesting data from
                the keyboard.  If RETURN is typed to an
                input statement, BASIC returns to com-
                command mode.  Typing CONT after an
                INPUT command has been interrupted
                will cause execution to resume at the
                INPUT statement.

                If the optional character ! is included                 15 INPUT! "VALUE";V
                following INPUT, then the prompts from
                the INPUT statement and the user's entries
                will be printed (even if the printer is
                turned off) and displayed.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

POS             POS (expression)                                        260 PRINT POS(I)
                Gives the current position of the cursor on
                the display.  The leftmost character position
                on the display is position zero.  A dummy
                operand--0 or 1--must be used.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

PRINT           PRINT [!] expression [, expression]                     360 PRINT X,Y;Z
                Prints the value of expressions on the                  370 PRINT " "
                display/printer.  If the list of values to be           380 PRINT X,Y;
                printed out does not end with a comma                   390 PRINT "VALUE IS";A
                (,) or a semicolon (;), then a carriage                 400 PRINT A2,B,
                return/line feed is executed after all the
                values have been printed.  Strings enclosed
                in quotes (") may also be printed.  If a
                semicolon separates two expressions in
                the list, their values are printed next to
                each other.  If a comma appears after an
                expression in the list, and the print head
                is at print position 11 or more, then a
                carriage return/line feed is executed.  If
                the print head is before print position 11,
                then spaces are printed until the carriage
                is at the beginning of the next 10 column
                field.  If there is a blank string enclosed in
                quotes, as in line 370 of the examples,
                then a carriage return/line feed is
                executed.

                "VALUE IS" will be displayed and printed.               410 PRINT ! "VALUE
                                                                        IS";A

                String expressions may be printed.                      420 PRINT MID$(A$,2);

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

READ            READ variable [, variable]                              490 READ V,W
                Read data into specified variables from a
                DATA statement.  The first piece of data
                read will be the first piece of data listed in
                the first DATA statement of the program.
                The second piece of data read will be the
                second piece listed in the first DATA
                statement, and so on.  When all of the data
                have been read from the first DATA state-
                ment, the next piece of data to be read will
                be the first piece listed in the second DATA
                statement of the program.  Attempting to
                read more data than there is in all the
                DATA statements in a program will cause
                an OD (out of data) error.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

SPC             SPC (expression)                                        250 PRINT SPC(I)
                Prints I space [or blank) characters on the
                terminal.  May be used only in a PRINT
                statement.  I must be =>0 and <=255 or
                an FC error will result.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

TAB             TAB (expression)                                        240 PRINT TAB(I)
                Spaces to the specified print position
                (column) on the printer.  May be used
                only in PRINT statements.  Zero is the
                leftmost column on the termainl, 19 the
                rightmost.  If the carriage is beyond pos
                position I, then no printing is done.  I must
                be =>0 and <=255.

                If I is greater than 19, the printer will skip
                the required number of lines to arrive at
                the specified position.

306  STRING FUNCTIONS

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

ASC             ASC (string expression)                                 300 PRINT ASC(X$)
                Returns the ASCII numeric value of the
                first character of the string expression X$.
                See Appendix E for an ASCII/number
                conversion table.  An FC error will occur
                if X$ is the null string.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

CHR$            CHR$ (expression)                                       275 PRINT CHR$(I)
                Returns one character, the ASCII equiva-
                lent of the argument (I) which must be a
                number between 0 and 255.  See Appendix E.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

GET             GET string variable                                     10 GET A$
                Inputs a single character from the keyboard.
                If data is at the keyboard, it is put in the
                variable specified in the GET statement.
                If no data is available, the BASIC program
                will continue execution.

                GET can only be used as an indirect
                command.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

LEFT$           LEFT$ (string expression, length)                       310 PRINT LEFT$(X$,I)
                Gives the leftmost I characters of the string
                expression X$.  If I<=0 or >255 an FC
                error occurs.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

LEN             LEN (string expression)                                 220 PRINT LEN(X$)
                Gives the length of the string expression X$
                in characters (bytes).  Non-printing charac-
                ters and blanks are counted as part of the
                length.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

MID$            MID$ [string expression, start [, length])              330 PRINT MID$(X$,I)
                MID$ called with two arguments returns
                characters from the string expression X$
                starting at character position I.  If
                I>LEN(X$), then MID$ returns a null
                (zero length) string.  If I<=0 or >255,
                an FC error occurs,

                MID$ called with three arguments returns                340 PRINT MID$(X$,
                a string expression composed of the                     I,J)
                characters of the string expression X$
                starting at the Ith character for J characters.
                If I>LEN(X$), MID$ returns a null string.
                If I or J <=0 or >255, an FC error occurs.
                If J specifies more characters than are left
                in the string, all characters from the Ith on
                are returned.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

RIGHT$          RIGHT$ (string expression, length)                      320 PRINT RIGHT$
                Gives the rightmost I characters of the                 (X$,I)
                string expression X$.  When I<=0 or
                >255 an FC error will occur.  If
                I>=LEN(X$) then RIGHT$ returns all
                of X$.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

STR$            STR$ (expression)                                       290 PRINT STR$(X)
                Gives a string which is the character repre-
                sentation of the numeric expression X.
                For instance, STR$(3.1)="3.1."

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

VAL             VAL (string expression)                                 280 PRINT VAL(X$)
                Returns the string expression X$ converted
                to a number.  For instance.
                VAL("3.1")=3.1.  If the first non-space
                character of the string is not a plus (+) or
                minus (-) sign; a digit or a decimal point (.)
                then zero will be returned.

307  ARITHMETIC FUNCTIONS

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

ABS             ABS (expression)                                        120 PRINT ABS(X)
                Gives the absolute value of the expression
                X.  ABS returns X if X>=0, -X otherwise.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

ATN             ATN (expression)                                        210 PRINT ATN(X)
                Gives the arcTangent of the expression X.
                The result is returned in radians and ranges
                from -PI/2 to PI/2 (PI/2=1.5708).  If you
                want to use this function, you must provide
                the code in memory.  See Appendix H for
                implementation details.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

COS             COS (expression)                                        200 PRINT COS(X)
                Gives the cosine of the expression X.  X is
                interpreted as being in radians.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

EXP             EXP (expression)                                        150 PRINT EXP(X)
                Gives the constant "E" (2.71828) raised so
                the power X (E^X).  The maximum argu-
                ment that can be passed to EXP without
                overflow occurring is 88.0296.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

INT             INT (expression)                                        140 PRINT INT(X)
                Returns the largest integer less than or
                equal to its expression X.  For example:
                INT(.23)=0, INT(7)=7, INT(-.1)=-1,
                INT(-2)=-2, INT(1.1)=1.

                The following would round X to 0 decimal
                places:

                     INT(X*10^D+.5)/10^D

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

LOG             LOG (expression)                                        160 PRINT LOG(X)
                Gives the natural (Base E) logarithm of its
                expression X.  To obtain the Base Y
                logarithm of X use the formula LOG(X)/
                LOG(Y).  Example:  The base 10 (com-
                mon) log of 7 = LOG(7)/LOG(10).

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

RND             RND (parameter)                                         170 PRINT RND(X)
                Generates a random number between 0
                and 1.  The parameter X controls the
                generation of random numbers as follows:

                X<0 starts a new sequence of random
                numbers using X.  Calling RND with the
                same X starts the same random number
                sequence.  X=0 gives the last random
                number generated.  Repeated calls to
                RND(0) will always return the same
                random number.  X>0 generates a new
                random number between 0 and 1.

                Note that (B-A)*RND(1)+A will
                generate a random number between
                A and B.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

SGN             SGN (expression)                                        230 PRINT SGN(X)
                Gives 1.  If X>0, 0 if X=0, and -1 if
                X<0.

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

SIN             SIN (expression)                                        190 PRINT SIN(X)
                Gives the sine of the expression X.  X is
                interpreted as being in radians.  Note:
                COS(X) =SIN(X+3.14159/2) and that
                1 Radian = 180/PI degrees = 57.2958
                degrees; so that the sine of X degrees=
                SIN(X/57.2958).

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

SQR             SQR (expression)                                        180 PRINT SQR(X)
                Gives the square root of the expression X.
                An FC error will occur if X is less than zero,

STATEMENT       SYNTAX/FUNCTION                                         EXAMPLE

TAN             TAN (expression)                                        200 PRINT TAN(X)
                Gives the tangent of the expression X.  X is
                interpreted as being in radians.

DERIVED FUNCTIONS

The following functions, while not intrinsic to BASIC, can be calculated using the existing BASIC
functions:

FUNCTION                 FUNCTION EXPRESSED IN TERMS OF BASIC FUNCTIONS

SECANT                   SEC(X) = 1/COS(X)

COSECANT                 CSC(X) = 1/SIN(X)

COTANGENT                COT(X) = 1/TAN(X)

INVERSE SINE*            ARCSIN(X) = ATN(X/SQR(-X*X+1))

INVERSE COSINE*          ARCCOS(X) = -ATN(X/SQR(-X*X+1))+1.5708

INVERSE SECANT*          ARCSEC(X) = ATN(SQR(X*X-1))+(SGN(X)-1)*1.5708

INVERSE COSECANT*        ARCCSC(X) = ATN(1/SQR(X*X-1))+(SGN(X)-1)*1.5708

INVERSE COTANGENT*       ARCCOT(X) = -ATN(X)+1.5708

HYPERBOLIC SINE          SINH(X) = (EXP(X)-EXP(-X))/2

HYPERBOLIC COSINE        COSH(X) = (EXP(X)+EXP(-X))/2

HYPERBOLIC TANGENT       TANH(X) = -EXP(-X)/(EXP(X)+EXP(-X))*2+1

HYPERBOLIC SECANT        SECH(X) = 2/(EXP(X)+EXP(-X))

HYPERBOLIC COSECANT      CSCH(X) = 2/(EXP(X)-EXP(-X))

HYPERBOLIC
COTANGENT                COTH(X) = EXP(-X)/(EXP(X)-EXP(-X))*2+1

*These functions require the user-defined ATN function.  See Appendix H for details.

FUNCTION                 FUNCTION EXPRESSED IN TERMS OF BASIC FUNCTIONS

INVERSE HYPERBOLIC
SINE                     ARGSINH(X) = LOG(X+SQR(X*X+1))

INVERSE HYPERBOLIC
COSINE                   ARGCOSH(X) = LOG(X+SQR(X*X-1))

INVERSE HYPERBOLIC
TANGENT                  ARGTANH(X) = LOG((1+X)/(1-X))/2

INVERSE HYPERBOLIC
SECANT                   ARGSECH(X) = LOG((XQR(-X*X+1)+1)/X

INVERSE HYPERBOLIC
COSECANT                 ARGCSCH(X) = LOG((SGN(X)*SQR(X*X+1)+1)/X)

INVERSE HYPERBOLIC
COTANGENT                ARGCOTH(X) = LOG((X+1)/(X-1))/2

A  ERROR MESSAGES

If an error occurs, BASIC outputs an error message, returns to command level and displays the
cursor.  Variable values and the program text remain intact, but the program can not be continued
and all GOSUB and FOR context is lost.

When an error occurs in a direct statement, no line number is printed.

Format of error messages:

     Direct Statement         ?XX ERROR

     Indirect Statement       ?XX ERROR IN YYYYY

In both of the above examples, "XX" will be the error code.  The "YYYYY" will be the line
number where the error occured for the indirect statement.

The following are the possible error codes and their meanings:

ERROR CODE     MEANING

    BS         Bad Subscript.  An attempt was made to reference a matrix element
               which is outside the dimensions of the matrix.  This error can occur
               if the wrong number of dimensions are used in a matrix reference;
               for instance, LET A(1,1,1)=Z when A has been dimensioned DIM
               A(2,2).

    CN         Continue error, Attempt to continue a program when none exists, an
               error occured, or after a new line was typed into the program.

    DD         Double Dimension.  After a matrix was dimensioned, another DIM
               statement for the same matrix was encountered.  This error often
               occurs if a matrix has been given the default dimension 10 because
               a statement like A(I)=3 is encountered and then later in the program
               a DIM A(100) is found,

    FC         Function Call error, The parameter passed to a math or string func-
               tion was out of range.  FC errors can occur due to:

                   1.  A negative matrix subscript (LET A(-1)=0)

                   2.  An unreasonably large matrix subscript (>32767)

                   3.  LOG-negative or zero argument

                   4.  SQR-negative argument

                   5.  A^B with A negative and B not an integer

                   6.  A call to USR before the address of the machine language
                       subroutine has been patched in

                   7.  Calls to MID$, LEFT$, RIGHT$, WAIT, PEEK, POKE,
                       TAB, SPC or ON...GOTO with an improper argument.

    ID         Illegal Direct.  You cannot use an INPUT, DEF or GET statement as
               a direct command.

    LS         Long String.  Attempt was made by use of the concantenation operator
               to create a string more than 255 characters long.

    NF         NEXT without FOR.  The variable in a NEXT statement corresponds
               to no previously executed FOR statement.

    OD         Out of Data.  A READ statement was executed but all of the DATA
               statements in the program have already been read.  The program tried
               to read too much data or insufficient data was included in the
               program.

    OM         Out of Memory.  Program too large, too many variables, too many
               FOR loops, too many GOSUB's, too complicated an expression, or
               any combination of the above.  (see Appendix B)

    OV         Overflow.  The result of a calculation was too large to be represented
               in BASIC's number format.  If an underflow (too small result) occurs,
               zero is given as the result and execution continues without any error
               message being printed.

    RG         RETURN without GOSUB.  A RETURN statement was encountered
               without a previous GOSUB statement being executed,

    SN         Syntax error.  Missing parenthesis in an expression, illegal character in
               a line, incorrect punctuation, etc.

    ST         String Temporaries.  A string expression was too complex.  Break it
               into two or more shorter expressions.

    TM         Type Mismatch.  The left side of an assignment statement was a
               numeric variable and the right side was a string, or vice versa; or, a
               function which expected a string argument was given a numeric
               one or vice versa.

    UF         Undefined Function.  Reference was made to a user function which
               has never been defined.

    US         Undefined Statement.  An attempt was made to GOTO, GOSUB or
               THEN to a statement which does not exist.

    /0         Division by Zero

B  SPACE HINTS

In order to make your program smaller and save space, the following hints may be useful.

    1.  Use multiple statements per line.  There is a five-byte of overhead associated with each
        line in the program.  Two of these five bytes contain the line number of the line in binary.
        This means that no matter how many digits you have in your line number (minimum line
        number is 0, maximum is 63999), it takes the same number of bytes.  Putting as many
        statements as possible on a line will cut down on the number of bytes used by your
        program.

    2.  Delete all unnecessary spaces from your program.  For instance:

            10 PRINT X, Y, Z

        uses three more bytes than

            10 PRINTX,Y,Z

        Note:  All spaces between the line number and the first non-blank character are ignored.

    3.  Delete all REM statements.  Each REM statement uses at least one byte plus the number
        in the comment text.  For instance, the statement 130 REM THIS IS A COMMENT uses
        24 bytes of memory.

        In the statement 140 X=X+Y: REM UPDATE SUM, the REM uses 14 bytes of memory
        including the colon before the REM.

    4.  Use variables instead of constants.  Suppose you use the constant 3.14159 ten times in
        your program.  If you insert a statement

            10 P=3.1.4159

        in the program, and use P instead of 3.14159 each time it is needed, you will save 40
        bytes.  This will also result in a speed improvement.

    5.  A program need not end with an END, so an END statement at the end of a program
        may be deleted.

    6.  Reuse variables.  If you have a variable T which is used so hold a temporary result in one
        part of the program and you need a temporary variable later in your program, use it
        again.  Or, if you are asking the terminal user to give a YES or NO answer to two differ-
        ent questions at two different times during the execution of the program, use the same
        temporary variable A$ to store the reply.

    7.  Use GOSUB's to execute sections of program statements that perform identical actions.

    8.  Use the zero elements of matrices; for instance, A(0), B(0,X).

STORAGE ALLOCATION INFORMATION

Simple (non-matrix) numeric and strong variables like V use 7 bytes; 2 for the variable name, and
5 for the value.  Simple non-matrix string variables also use 7 bytes; 2 for the variable name, 1 for the
length, 2 for a pointer, and 2 are unused.

Matrix variables require 7 bytes to hold the header, plus additional bytes to hold each matrix element.
Each element that is an integer variable requires 2 bytes.  Elements that are string variables or floating
point variables require 3 bytes or 5 bytes, respectively.

String variables also use one byte of string space for each character in the string.  This is true
whether the string variable is a simple string variable like A$, or an element of a string matrix
such as Q1$(5,2).

When a new function is defined by a DEF statement, 7 bytes are used to store the definition.

Reserved words such as FOR, GOTO or NOT, and the names of the intrinsic functions such as
COS, INT and STR$ take up only one byte of program storage.  All other characters in programs
use one byte of program storage each.

When a program is being executed, space is dynamically allocated on the stack as follows:

    1.  Each active FOR...NEXT loop uses 22 bytes.

    2.  Each active GOSUB (one that has not returned yet) uses 6 bytes.

    3.  Each parenthesis encountered in an expression uses 4 bytes and each temporary result
        calculated in an expression uses 12 bytes.

C  SPEED HINTS

The hints below should improve the execution time of your BASIC program.  Note that some of
these hints are the same as those used to decrease the space used by your programs.  This means
that in many cases you can increase the efficiency of both the speed and size of your programs at
the same time.

    1.  Delete all unnecessary spaces and REM's from the program.  This may cause a small
        decrease in execution time because BASIC would otherwise have to ignore or skip
        over spaces and REM statements.

    2.  THIS IS PROBABLY THE MOST IMPORTANT SPEED HINT.

        Use variables instead of constants.  It takes more time to convert a constant to its
        floating point representation than it does to fetch the value of a simple or matrix
        variable.  This is especially important within FOR...NEXT loops or other code that
        is executed repeatedly.

    3.  Variables which are encountered first during the execution of a BASIC program are
        allocated at the start of the variable table.  This means that a statement such as
        5 A=0:B=A:C=A, will place A first, B second, and C third in the symbol table
        (assuming line 5 is the first statement executed in the program).  Later in the program,
        when BASIC finds a reference to the variable A, it will search only one entry in the
        symbol table to find A, two entries to find B and three entries to find C, etc.

    4.  Use NEXT statements without the index variable.  NEXT is somewhat faster than
        NEXT I because no check is made to see whether the variable specified in the NEXT
        is the same as the variable in the most recent FOR statement.

D  CONVERTING BASIC PROGRAMS NOT WRITTEN FOR AIM 65 BASIC

Though implementations of BASIC on different computers are in many ways similar, there are some
incompatibilities which you should watch for if you are planning to convert some BASIC programs
that were not written in AIM 65 BASIC.

    1.  Matrix subscripts.  Some BASICs use "[" and "]" to denote matrix subscripts.  AIM 65
        BASIC uses "(" and ")".

    2.  Strings.  A number of BASICs force you to dimension (declare) the length of strings
        before you use them.  You should remove all dimension statements of this type from
        the program.  In some of these BASICs, a declaration of the form DIM A$(I,J) declares
        a string matrix of J elements each of which has a length I.  Convert DIM statements of
        this type to equivalent ones in AIM 65 BASIC:  DIM A$(J).

        AIM 65 BASIC uses "+" for string concatenation, not "," or "&".

        AIM 65 BASIC uses LEFT$, RIGHT$ and MID$ to take substrings of strings.  Other
        BASICs uses A$(I) to access the Ith character of the string A$, and A$(I,J) to take a
        substring of A$ from character position I to character position J.  Convert as follows:

            OLD                 AIM 65

            A$(I)               MID$(A$,I,1)

            A$(I,J)             MID$(A$,I,J-I+1)

        This assumes that the reference to a substring of A$ is in an expression or is on the
        right side of an assignment.  If the reference to A$ is on the left hand side of an
        assignment, and X$ is the string expression used to replace characters in A$, convert
        as follows:

            OLD                 AIM 65

            A$(I)=X$            A$=LEFT$(A$,I-1)+X$+MID$(A$,I+1)

            A$(I,J)=X$          A$=LEFT$(A$,I-1)+X$+MID$(A$,J+1)

    3.  Multiple assignments.  Some BASICs allow statements of the form:  500 LET B=C=0.
        This statement would set the variables B & C to zero.

        In AIM 65 BASIC this has an entirely different effect.  All the "='s" to the right of the
        first one would be interpreted as logical comparison operators.  This would set the
        variable B to -1 if C equaled 0.  If C did not equal 0, B would be set to 0.  The easiest
        way to convert statements like this one is to rewrite them as follows:

            500 C=0:B=C

    4.  Some BASICs use "/" instead of ":" to delimit multiple statements per line.  Change all
        occurrences of "/" to ":" in the program.

    5.  Programs which use the MAT functions available in some BASICs will have to be
        re-written using FOR...NEXT loops to perform the appropriate operations.

    6.  A PRINT statement with no arguments will not cause a paper feed on the printer.  To
        generate a paper feed (blank line), use PRINT "space"

E  ASCII CHARACTER CODES

DECIMAL     CHAR.       DECIMAL     CHAR.       DECIMAL     CHAR.
-------     ----        -------     ----        -------     ----
000         NUL         043         +           086         V
001         SOH         044         ,           087         W
002         STX         045         -           088         X
003         ETX         046         .           089         Y
004         EOT         047         /           090         Z
005         ENQ         048         0           091         [
006         ACK         049         1.          092         /
007         BEL         050         2           093         ]
008         BS          051         3           094         ^
009         HT          052         4           095         _
010         LF          053         5           096         `
011         VT          054         6           097         a
012         FF          055         7           098         b
013         CR          056         8           099         c
014         SO          057         9           100         d
015         SI          058         :           101         e
016         DLE         059         ;           102         f
017         DC1         060         <           103         g
018         DC2         061         =           104         h
019         DC3         062         >           105         i
020         DC4         063         ?           106         j
021         NAK         064         @           107         k
022         SYN         065         A           108         l
023         ETB         066         B           109         m
024         CAN         067         C           110         n
025         EM          068         D           111         o
026         SUB         069         E           112         p
027         ESCAPE      070         F           113         q
028         FS          071         G           114         r
029         GS          072         H           115         s
030         RS          073         I           116         t
031         US          074         J           117         u
032         SPACE       075         K           118         v
033         !           076         L           119         w
034         "           077         M           120         x
035         #           078         N           121         y
036         $           079         O           122         z
037         %           080         P           123         {
038         &           081         Q           124         |
039         '           082         R           125         }
040         (           083         S           126         ~
041         )           084         T           127         DEL
042         *           085         U

LF=Line Feed     FF=Form Feed     CR=Carriage Return     DEL=Rubout on TTY

F  ASSEMBLY LANGUAGE SUBROUTINES

AIM 65 BASIC allows a user to link to assembly language subroutines, via the USR(W) function.
This function allows one parameter to be passed between BASIC and a subroutine.

The first step is to allocate sufficient memory for the subroutine.  AIM 65 BASIC always uses all
RAM memory locations, beginning at decimal location 530 (hex location 212), unless limited by
the user.  You can limit BASIC's memory useage by answering the prompt MEMORY SIZE? (see
Subject 100) with some number less than 4096, assuming a 4K system.  This will leave sufficient
space for the subroutine as the top of RAM.

For example, if your response to MEMORY SIZE? is "2048", 1518 bytes at the top of RAM
will be free for assembly language subroutines.

Parameter (W), passed to a subroutine by USR(W), will be converted to floating-point accumulator
located at $A9.  The floating-point accumulator has the following format:

        ADDRESS         CONTENT

        $A9             Exponent + $81 ($80 if mantissa = 00)

        $AA-$AD         Mantissa, normalized so that Bit 7 of MSB is set.
                        $AA is MSB, $AD is LSB.

        $AE             Sign of mantissa

A parameter passed to an assembly language subroutine from BASIC can be truncated by the sub-
routine to a 2-byte integer and deposited in $AC (MSB) and $AD (LSB).  If the parameter is
greater than 32767 or less than -32768, an FC error will result.  The address of the subroutine
that converts a floating-point number to an integer is located in $B006, $B007.

A parameter passed to BASIC from an assembly language subroutine will be converted to floating-
point.  The address of the subroutine that performs this conversion is in $B008, $B009.  The
integer MSB ($AC) must be in the accumulator; the integer LSB ($AD) must be in the Y register.

Prior to executing USR, the starting address of the assembly language subroutine must be stored
in locations $04 (LSB) and $05 (MSB).  This is generally performed using the POKE command.
Note that more than one assembly language subroutine may be called from a BASIC program,
by changing the starting address in $04 and $05.

Figure F-1 is the listing for a BASIC program that calls an assembly language subroutine located at
$A00.  Here's what the BASIC program does:

    *   Line 10 - Stores the starting address of the assembly language subroutine ($A00) into
        locations $04 and $05, using POKE.

    *   Line 20 - Asks for a number "N".

    *   Line 30 - Calls the subroutine, with N as the parameter.

    *   Line 40 - Upon return from the subroutine, the BASIC program prints X, the parameter
        passed from the subroutine to the BASIC program.

    *   Line 50 - Loops back to get a new N

                ROCKWELL AIM 65

                <5>
                MEMORY SIZE? 2048
                WIDTH?
                 1518 BYTES FREE
                AIM 65 BASIC V1.1
                OK
                10 POKE 04,0: POKE 05
                ,10
                20 INPUT"NUMBER";N
                30 X=USR(N)
                40 PRINTX
                50 GOTO 20

Figure F-1.  BASIC Program That Calls Assembly Language Subroutine

The assembly language subroutine (Figure F-2) performs these operations:

    *   Prints the floating-point accumulator ($A9-$AE), using Monitor subroutines NUMA
        ($EA46), BLANK ($E83E) and CRLF ($E9F0),

    *   Converts the floating-point accumulator to an integer, using the subroutine at $BF00.
        The address $BF00 was found in locations $B006, $B007.  (Address $BF00 may vary
        with different versions of BASIC.  Be sure to check locations $B006 and $B007 for the
        correct address.)

    *   After conversion, the program again prints the floating point accumulator,

    *   The program then swaps the bytes of the integer.

    *   Finally, the program converts the result to floating point and returns to BASIC (JMP
        C0D3).  Address $C0D3 was found in locations $B008, $B009.  (Address $C0D3 may
        vary with different versions of BASIC.  Be sure to check locations $B008 and $B009
        for the correct address.

               <1>
                0A26    *=A00
                0A00 A0 LDY #00
                0A02 A2 LDX #00
                0A04 B5 LDA A9,X
                0A06 20 JSR EA46
                0A09 20 JSR E83E
                0A0C E8 INX
                0A0D E0 CPX #06
                0A0F D0 BNE 0A04
                0A11 20 JSR E9F0
                0A14 C0 CPY #00
                0A16 F0 BEQ 0A1F
                0A13 A5 LDA AD
                0A18 A4 LDY AC
                0A1C 4C JMP C0D3
                0A1F 20 JSR BF00
                0A22 C8 INY
                0A23 D0 BNE 0A02
                0A25 00 BRK
                0A26

Figure F-2 Assembly Language Subroutine

Figure F-3 shows the print-out for various values of "N".

                <6>
                OK
                RUN
                NUMBER? 128
                88 80 00 00 00 00
                88 00 00 00 80 00
                -32768

                NUMBER? 1
                81 80 00 00 00 00
                81 00 00 00 01 00
                 256

                NUMBER? 4097
                8D 80 06 00 00 00
                8D 00 00 10 01 00
                 272

                NUMBER? 256
                89 80 00 00 00 00
                89 00 00 01 00 00
                 1

Figure F-3.  Output for Example

G  STORING AIM 65 BASIC PROGRAMS ON CASSETTE

AIM 65 BASIC Programs can be stored on cassette tape by using BASIC's SAVE and LOAD
commands, or by using the AIM 65 Editor.  Before employing either procedure be sure to care-
fully observe the recorder installation and operation procedures given in Section 9 of the
AIM 65 User's Guide.

RECORDING ON CASSETTE USING THE BASIC SAVE COMMAND

The procedure to store a BASIC program is:

    1.  Install a cassette in the recorder, and manually position the tape to the program record
        position.  Be sure to initialise the counter at the start of the tape.

        Note:  Since remote control must be used to retrieve a BASIC program, observe the
        tape gap CAUTION in Section 9.1.5 (Step 1) of the AIM 65 User's Guide.

    2.  While in BASIC, type in SAVE.  BASIC will respond with:

            OUT=

    3.  Enter a T (for "Tape").  BASIC will display:

            OUT=T F=

    4.  Enter the file name (up to five characters).  If the file name is FNAME, BASIC will
        display:

            OUT=T F=FNAME T=

    5.  Put the recorder into Record mode.

    6.  Enter the recorder number (1 or 2) and type RETURN.

    7.  If remote control is being used, observe the procedures outlined in Section 9.1.5 of
        the AIM 65 User's Guide.

    8.  When recording has been completed, BASIC will display the cursor.

    9.  Switch the recorder out of record mode.


RETRIEVING A PROGRAM FROM CASSETTE USING THE BASIC LOAD COMMAND

The procedure to retrieve a BASIC program is:

    1.  Install the cassette in the recorder., and manually position the tape to about five counts
        before the beginning of the desired file.

        Note:  Remote control must be used when retrieving a file via BASIC.

    2.  While in BASIC, type in LOAD.  BASIC will respond with:

            IN=

    3.  Enter a T (for "Tape").  BASIC will display:

            IN=T F=

    4.  Enter the file name.  If the file name is FNAME, BASIC will display:

            IN=T F=FNAME T=

    5.  Enter the recorder number (1 or 2) and type RETURN.

    6.  Put the recorder into play mode.  Be sure to observe the procedures outlined in
        Section 9.1.6 of the AIM 65 User's Guide.

        While the file is being read, each line will be displayed (and printed, if the printer is on).
        If the printer is on, the tape gap ($A409) will probably have to be increased.

        The file being loaded will not overlay any BASIC statements already entered unless
        the statement numbers are the same.

    7.  When loading has been completed.  BASIC will display the cursor.

    8.  Switch the recorder out of play mode.

CASSETTE OPERATIONS USING THE AIM 65 EDITOR

AIM 65 BASIC programs can also be stored and retrieved from cassette using the AIM 65 Editor.
However, if the program is to be retrieved by BASIC at some future time, one rule must be
observed:

    When BASIC stores a program on cassette, it inserts a CTRL/Z after the last line.  The
    AIM 65 Editor will strip off the CTRL/Z when it retrieves the program.  Therefore,
    before storing a BASIC program from the Editor, the user must insert a CTRL/Z
    following the last line of the program.

H  ATN IMPLEMENTATION

The ATN function (see Subject 307) can be programmed in RAM using the AIM 65 Mnemonic
Entry (I) and Alter Memory Locations (/) commands, as shown below.  The program is written
for the AIM 65 with 4K bytes of RAM.  The ATN function can be relocated elsewhere in memory
by changing the starting addresses of the instructions and constants, the conditional branch
addresses, the vector to the constants start address and the vector to the ATN function starT
address.

ATN FUNCTION CONSTANTS ENTERED BY ALTER MEMORY <M>

<M> = 0F80  XX  XX  XX  XX    Constants Starting Address = 0F80
</> = 0F80  0B  76  83  83                                     8
</>   0F84  BD  D3  79  1E
</>   0F88  F4  A6  F5  7B
</>   0F8C  83  FC  B0  10
</>   0F90  7C  0C  1F  67
</>   0F94  CA  7C  DE  53
</>   0F98  CB  C1  7D  14
</>   OF9C  64  70  4C  7D
</>   0FA0  B7  EA  51. 7A
</>   0FA4  7D  63  30  88
</>   0FA8  7E  7E  92  44
</>   0FAC  99  3A  7E  4C
</>   0FR0  CC  91  C7  7F
</>   0FB4  AA  AA  AA  13
</>   0FR8  81  00  00  00
</>   0FBC  00

ATN FUNCTION INSTRUCTIONS STORED BY MNEMONIC ENTRY (I)

<I>
XXXX *=0FBD                   Instructions Starting Address = 0F8D
0FBD A5 LDA AE
0FBF 48 PHA
0FC0 10 BPL 0FC5
0FC2 20 JSR CCB8
0FC5 AS LDA A9
0FC7 48 PHA
0FC8 C9 CMP #81
0FCA 90 BCC 0FD3
0FCC A9 LDA #FB
0FCE A0 LDY #C6
0FD0 20 JSR C84E
0FD3 A9 LDA #80 \             Starting Address of Constants = 0F80
0FD5 A0 LDY #0F /
0FD7 20 JSR CD44
0FDA 68 PLA
0FDB C9 CMP #81
0FDD 90 BCC 0FE6
0FDF A9 LDA #4E
0FE1 A0 LDY #CE
0FE3 20 JSR C58F
0FE6 68 PLA
0FE7 10 BPL 0FEC
0FE9 4C JMP CCB8
0FEC 60 RTS
0FEC

BASIC INITIALIZATION FOR ATN FUNCTION

BASIC memory must be initialized below the memory allocated to the ATN function.  The ATN
vector in RAM must also be changed from the address of the FC error message to the starting
address of the ATN function instructions.  This can be done using BASIC initialization, as follows:

<5>
MEMORY SIZE? 3968               Limit BASIC to F80
WIDTH?                                            16
 3438 BYTES FREE
  AIM 65 BASIC V1.1
POKE 188,189                    Change ATN function vector low to $BD
POKE 189,15                     Change ATN function vector high to $0F
?ATN (TAN(.5))                  Test case to verify proper ATN function program
 .5                             Expected answer = .5

SAVING ATN OBJECT CODE ON CASSETTE

The object code for the ATN function can be saved on cassette by dumping addresses $00BB
through $00BD (Jump instruction to ATN) and $0F80 through $0FEC (constants and instructions)
after the function is initially loaded and verified.

The ATN function can then be loaded from cassette by executing the Monitor L command after
BASIC has been initialized via the 5 command.  After the ATN function has been loaded, reenter
BASIC with the 6 command.


###
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Apple II Original ROM Information
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