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SUBTTL DIAGNOSTIC SECTION
START: SETZM USER# ;CLEAR USER CONTROL WORD
JSP 0,.+1 ;GET FLAGS
TLNE USERF ;IN USER MODE?
SETOM USER ;YES, SET USER CONTROL WORD
SKIPN MONFLG ;SPECIAL USER MODE?
SETZM USER ;YES, CLEAR USER CONTROL WORD
SKIPN USER
JRST STARTA
SKIPL MONCTL
TTCALL 3,PGMNAM
JRST STARTA
PGMNAM: ASCIZ/
DECSYSTEM-2020 BASIC INSTRUCTION DIAGNOSTIC (1) [DSKAA]
/
;BASIC INSTRUCTION TEST (1)
;THE TEST IS DESIGNED FOR INITIAL DEBUGGING OF
;PROCESSOR HARDWARE AND TO DETECT (SOLID) FAILURES
;IN THE FIELD.
STARTA: JRST .+1
SUBTTL TEST OF JUMP, JUMPA AND SKIPX INSTRUCTIONS
;NOTE: AN "*" IN THE COMMENT FIELD OF AN INSTRUCTION INDICATES THAT IT IS THE TESTED
;INSTRUCTION.
;**********
;THIS TEST VERIFIES THAT SKIPA ALWAYS SKIPS THE NEXT INSTRUCTION
A00=.
A12500: SKIPA ;*SKIPA SHOULD ALWAYS SKIP THE NEXT INSTRUCTION
HALT ;IF PROGRAM HALTS, SKIPA DID NOT SKIP
;IF PROGRAM HANGS UP ON SKIPA INSTRUCTION, CHECK AB PC EN [ABC], AB PC F/F [ABC],
;AB PC B [ABC OR AB], AB PC (FETCH) EN [ABC], IR SKIPS [IR3], IR SKIPX [IR1],
;IR 3XX [IR1], IR BITS 00 - 08 [IR1], F CYC ACT EN C [FI], FT6 F/F [F2],
;PC CLOCK EN [PCC], ET2 J F/F [E], PC CLK (ET2) EN [PCC], ADZ COND P [ADZ] AND
;ADZ COND R [ADZ], PC CLOCK A [PCC], PC CLOCK B [PCC]
;IF PROGRAM HALTED ON HALT INSTRUCTION, CHECK ST1 COND [ST2]
;**********
;THIS TEST VERIFIES THAT JUMP NEVER JUMPS
A15000: JUMP .+1 ;*JUMP SHOULD NEVER JUMP
SKIPA ;SKIP HALT INSTRUCTION IF JUMP IS SUCCESSFUL
HALT ;HALT IF JUMP FAILS
;IF PROGRAM HANGS UP ON JUMP .+1 INSTRUCTION, THE JUMP INSTRUCTION
;MAY HAVE FAILED. CHECK ST1 COND [ST2], ST INST FET ST1 EN [ST2], ET2 D F/F [E],
;IR JUMPS [IR1], IR JUMPX [IR1]
;**********
;THIS TEST VERIFIES THAT JUMP NEVER JUMPS
A15100: JUMP .+2 ;*JUMP SHOULD NEVER JUMP
SKIPA ;SKIP HALT INSTRUCTION IF JUMP IS SUCCESSFUL
HALT ;HALT IF JUMP FAILS
;AB PC EN [ABC]
;**********
;THIS TEST VERIFIES THAT JUMPA .+1 ALWAYS JUMPS TO THE NEXT INSTRUCTION
A12700: JUMPA .+1 ;*JUMPA .+1 SHOULD NEVER JUMP
SKIPA ;SKIP HALT INSTRUCTION IF JUMPA IS SUCCESSFUL
HALT ;HALT IF JUMPA .+1 FAILED
;**********
;THIS TEST VERIFIES THAT JUMPA JUMPS TO THE LOCATION SPECIFIED BY E WHEN E=.+2
A12600: JUMPA .+2 ;*JUMPA .+2 SHOULD ALWAYS SKIP THE NEXT INSTRUCTION
HALT ;PROGRAM HALTS HERE IF JUMPA .+2 FAILS
;ST1 COND [ST2]
;**********
;THIS TEST VERIFIES THAT SKIPA IS DATA INDEPENDENT. HENCE, IT ALWAYS SKIPS THE NEXT
;INSTRUCTION.
;THE MOVE [0] INSTRUCTION IS USED TO TEST THE DATA INDEPENDENCE OF SKIPA.
A100: MOVE [0] ;PRESET LOCATION 0 TO ALL ZEROS
SKIPA ;*SKIPA SHOULD ALWAYS SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST INSURES THAT SKIPA IS DATA INDEPENDENT. HENCE, IT ALWAYS SKIPS THE NEXT
;INSTRUCTION.
;THE MOVE [-1] INSTRUCTION IS USED TO TEST THE DATA INDEPENDENCE OF SKIPA.
A200: MOVE [-1] ;PRESET LOCATION 0 TO ALL ONES
SKIPA ;*SKIPA SKOULD ALWAYS SKIP THE NEXT INSTRUCTION
STOP
;COND P [ADZ]
;**********
;THIS TEST VERIFIES THAT SKIPGE SKIPS THE NEXT INSTRUCTION WHEN C(E)
;IS ALL ZEROS. THE MOVE INSTRUCTION IS USED TO LOAD E WITH ALL ZEROS.
A300: MOVE [0] ;PRESET E TO ALL ZEROS
SKIPGE ;*SKIPGE SHOULD SKIP THE NEXT INSTRUCTION
STOP
;COND R [ADZ], AD00 S-A-1, AD AR + EN [ADAP], AD LT AR + EN [ADAP],
;AD RT AR + EN [ADAP], AD AR + EN C [ADAP], F CYC ACT EN A [F1]
;**********
;THIS TEST VERIFIES THAT SKIP IS DATA INDEPENDENT. HENCE, SKIP NEVER SKIPS. IT ALWAYS
;CONTINUES ON TO THE NEXT INSTRUCTION.
A400: MOVE [-1] ;PRESET E TO ALL ONES
SKIP ;*SKIP SHOULD NEVER SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;PC CHANGE [PCC], PC CHANGE A [PCC], SEE MEMORY CONTROL DWGS [MC1-4]
;**********
;THIS TEST VERIFIES THAT SKIPGE WILL NOT SKIP THE NEXT INSTRUCTION WHEN C(E) IS
;NEGATIVE. THE MOVE INSTRUCTION LOADS E WITH -1, A NEGATIVE NUMBER.
A500: MOVE [-1] ;PRESET E WITH ALL ONES, A NEGATIVE NUMBER
SKIPGE ;*SKIPGE SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;IF MOVE INSTRUCTION FAILED, CHECK MOVX-: FCE [F1], -IR XXXI [IR1], -IR XXXM [IR1],
;IR HWTFWT [IR3], IR FWT [IR2], IR2XX [IR1]
;IF SKIPGE FAILED, CHECK SKIPX: FCE [F1]
;**********
;THIS TEST VERIFIES THAT SKIPN WILL NOT SKIP THE NEXT INSTRUCTION WHEN
;C(E) IS ZERO. THE MOVE INSTRUCTION LOADS E WITH ALL ZEROS.
A600: MOVE [0] ;PRESET E WITH ALL ZEROS
SKIPN ;*SKIPN SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;**********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT SHOULD SKIP
;THE NEXT INSTRUCTION WHEN C(E) IS NON-ZERO. THE MOVE INSTRUCTION LOADS
;E WITH -1, A NON-ZERO NUMBER.
A700: MOVE [-1] ;PRESET E WITH ALL ONES, A NON-ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPE IS DATA DEPENDENT. HENCE, IT SHOULD NOT
;SKIP THE NEXT INSTRUCTION WHEN C(E) IS NON-ZERO. THE MOVE INSTRUCTION LOADS E
;WITH -1, A NON-ZERO NUMBER.
A1000: MOVE [-1] ;PRESET E WITH ALL ONES, A NON-ZERO NUMBER
SKIPE ;*SKIPE SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;**********
;THIS TEST VERIFIES THAT SKIPE IS DATA DEPENDENT. HENCE, IT SHOULD SKIP
;THE NEXT INSTRUCTION WHEN C(E) IS ZERO. THE MOVE INSTRUCTION LOADS ALL
;ZEROS INTO E.
A1100: MOVE [0] ;PRESET E TO ALL ZEROS
SKIPE ;*SKIPE SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIP IS DATA INDEPENDENT. HENCE, IT NEVER SKIPS. IT ALWAYS
;CONTINUES ON TO THE NEXT INSTRUCTION.
A1200: MOVE [0] ;PRESET E TO ALL ZEROS
SKIP ;*SKIP SHOULD NEVER SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;**********
;THIS TEST VERIFIES THAT SKIPL IS DATA DEPENDENT. HENCE, IT WILL NOT SKIP THE NEXT
;INSTRUCTION WHEN C(E) IS NOT NEGATIVE. THE MOVE INSTRUCTION IS USED TO LOAD
;E WITH ALL ZEROS, A NON-NEGATIVE NUMBER.
A1300: MOVE [0] ;PRESET E T0 ZERO, A NON-NEGATIVE NUMBER
SKIPL ;*SKIPL SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;**********
;THIS TEST VERIFIES THAT SKIPL IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN C(E) IS NEGATIVE. THE MOVE INSTRUCTION IS USED TO LOAD E WITH -1,
;A NEGATIVE NUMBER.
A1400: MOVE [-1] ;PRESET E TO -1, A NEGATIVE NUMBER
SKIPL ;*SKIPL SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPG IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN C(E) IS GREATER THAN ZERO. THE MOVE INSTRUCTION IS USED TO LOAD
;E WITH A NON-ZERO POSITIVE NUMBER.
A1500: MOVE [XWD 377777,-1] ;PRESET E TO 377777777777, A NON-ZERO POSITIVE NUMBER
SKIPG ;*SKIPG SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPG IS DATA DEPENDENT. HENCE, IT WILL NOT SKIP THE NEXT
;INSTRUCTION WHEN C(E) IS NOT GREATER THAN ZERO. THE MOVE INSTRUCTION IS USED TO
;LOAD E WITH -1, A NUMBER NOT GREATER THAN ZERO.
A1600: MOVE [-1] ;PRESET E TO -1, A NEGATIVE NUMBER
SKIPG ;*SKIPG SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;**********
;THIS TEST VERIFIES THAT SKIPL IS DATA DEPENDENT. HENCE, IT WILL NOT SKIP THE NEXT
;INSTRUCTION WHEN C(E) IS NON-NEGATIVE. THE MOVE INSTRUCTION IS USED TO LOAD E WITH
;377777777777, A NON-NEGATIVE NUMBER.
A1700: MOVE [XWD 377777,-1] ;PRESET E TO 377777777777, A NON-NEGATIVE NUMBER
SKIPL ;*SKIPL SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;**********
;THIS TEST VERIFIES THAT SKIPLE IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN C(E) IS ZERO. THE MOVE INSTRUCTION LOADS E WITH ALL ZEROS.
A2000: MOVE [0] ;PRESET E TO ALL ZEROS
SKIPLE ;*SKIPLE SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPLE IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A NEGATIVE NUMBER. THE MOVE INSTRUCTION IS USED TO LOAD
;E WITH 400000000000, A NEGATIVE NUMBER.
A2100: MOVE [XWD 400000,0] ;PRESET E TO 400000000000, A NEGATIVE NUMBER.
SKIPLE ;*SKIPLE SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPLE IS DATA DEPENDENT. HENCE, IT WILL NOT SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A POSITIVE NUMBER. THE MOVE INSTRUCTION LOADS
;E WITH 377777777777, A POSITIVE NUMBER.
A2200: MOVE [XWD 377777,-1] ;PRESET E TO 377777777777, A POSITIVE NUMBER
SKIPLE ;*SKIPLE SHOULD NOT SKIP THE NEXT INSTRUCTION
SKIPA ;SKIP HALT INSTRUCTION IF TEST PASSES
STOP
;*********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION ;WHEN E CONTAINS A NON-ZERO NUMBER. THE MOVE INSTRUCTION IS USED TO
;LOAD 777000000000, A NON-ZERO NUMBER INTO E.
A2300: MOVE [XWD 777000,0] ;PRESET E WITH 777000000000, A NON-ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A NON-ZERO NUMBER. THE MOVE INSTRUCTION IS USED TO
;LOAD A NON-ZERO NUMBER, 377000000 INTO E.
A2400: MOVE [XWD 377,0] ;PRESET E TO 377000000, A NON ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A NON-ZERO NUMBER. THE MOVE INSTRUCTION IS USED TO
;LOAD E WITH A NON-ZERO NUMBER, 177000.
A2500: MOVE [177000] ;PRESET E WITH 177000, A NON ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A NON-ZERO NUMBER. THE MOVE INSTRUCTION IS USED TO
;LOAD 777, A NON-ZERO NUMBER INTO E.
A2600: MOVE [777] ;PRESET E WITH 777, A NON-ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A NON-ZERO NUMBER. THE MOVE INSTRUCTION IS USED TO
;LOAD E WITH 600000, A NON-ZERO NUMBER.
A2700: MOVE [600000] ;PRESET E WITK 600000, A NON-ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
;THIS TEST VERIFIES THAT SKIPN IS DATA DEPENDENT. HENCE, IT WILL SKIP THE NEXT
;INSTRUCTION WHEN E CONTAINS A NON-ZERO NUMBER. THE MOVE INSTRUCTION IS USED TO
;LOAD E WITH 400000000, A NON-ZERO NUMBER.
A3000: MOVE [XWD 400,000] ;PRESET E WITH 400000000, A NON-ZERO NUMBER
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
SN=3100
ZZ=0
A3100: REPEAT ^D36,
<;THIS TEST VERIFIES THAT SKIPN IS SENSITIVE TO A ONE IN EVERY BIT POSITION. THIS TEST
;IS REPEATED 36 TIMES. EACH TIME A WORD OF ALL ZEROS EXCEPT FOR A ONE IN ONE
;BIT POSITION IS MOVED INTO E. THEN SKIPN IS EXECUTED. THIS TEST ALSO
;CHECKS ADDER GATING. IF THIS TEST FAILS, CHECK C(E).
;IF C(E)=0, MOVE FAILED; OTHERWISE SKIPN FAILED.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [ZZ] ;MOVE THE CURRENT VALUE OF ZZ INTO E. ZZ IS NON-ZERO
SKIPN ;*SKIPN SHOULD SKIP THE NEXT INSTRUCTION
STOP
;**********
>
SUBTTL TEST OF MOVE, SKIP AND COMPARE INSTRUCTIONS
;THIS TEST VERIFIES THAT MOVEI LOADS E INTO THE AC. SKIPG IS USED TO CHECK THAT
;THE AC WAS INDEED MODIFIED BY MOVEI.
A3200: MOVEI [-1] ;*MOVEI SHOULD LOAD A POSITIVE NUMBER INTO AC0
SKIPG ;SKIP HALT INSTRUCTION IF MOVEI LOADED AC CORRECTLY
STOP
;IF PROGRAM HANGS UP ON MOVEI INSTRUCTION, CHECK AD FM +EN [ADFP], AD FM + EN A [ADFP],
;AD FM + F/F [ADFP], F CYC ACT EN C [F1]
;**********
;THIS TEST VERIFIES THAT SKIPL IS SENSITIVE TO THE DATA IN E AND NOT SENSITIVE TO
;THE DATA IN THE AC. HENCE, SKIPL WILL SKIP THE NEXT INSTRUCTION ONLY IF
;C(E) IS LESS THAN ZERO. E IS SET TO -1, A NEGATIVE NUMBER; AND
;THE AC IS SET TO 0 IN THIS TEST. THEREFORE SKIPL SHOULD SKIP.
A3300: MOVE [0] ;SET THE AC TO ALL ZEROS
SKIPL [-1] ;*SKIPL SHOULD SKIP BECAUSE C(E) IS NEGATIVE
STOP
;**********
;THIS TEST VERIFIES THAT SKIPL IS SENSITIVE TO THE SIGN BIT IN E. SKIPL SHOULD
;SKIP THE NEXT INSTRUCTION WHEN AND ONLY WHEN THE SIGN BIT IS SET. IN THIS
;TEST, C(AC) IS PRESET TO ALL ZEROS, THEN SKIPL IS EXECUTED WITH C(E)=400000,,0.
;A FAILURE UCCURS IF SKIPL DOES NOT SKIP.
A13100: MOVE [0] ;SET THE AC TO ALL ZEROS
SKIPL [400000,,0] ;*SKIPL SHOULD SKIP BECAUSE C(E) IS NEGATIVE
STOP
;**********
;THIS TEST VERIFIES THAT THE CAM INSTRUCTION DOES NOT MODIFY C(AC). THE AC IS
;INITIALLY LOADED WITH ALL ZEROS; THEN CAM IS EXECUTED WITH C(E) NON-ZERO.
;THE AC IS THEN CHECKED FOR ALL ZEROS. THIS TEST FAILS IF THE AC WAS MODIFIED BY CAM.
A3400: MOVE [0] ;PRESET THE AC TO ALL ZEROS
CAM [1234] ;*CAM SHOULD NOT MODIFY THE AC
MOVE ;MOVE C(0) INTO 0 (THIS INSTRUCTION SERVES AS A NO-OP.
;IT IS A PROGRAM FILLER IN CASE CAM SKIPS.)
SKIPE ;SKIP HALT INSTRUCTION IF AC WAS NOT MODIFIED BY CAM
STOP
;IF TEST HANGS ON CAM INSTRUCTION, AB PC EN [ABC], AB PC (FETCH) EN [ABC],
;IR CAXX [IR3]
;IF TEST LOOPS ON CAM INSTRUCTION, MC INSTR FETCH EN [MC1], MC INST FET ET2 EN [MC1],
;ET2 J F/F [E], IR CAXX [IR3]
;IF TEST HALTS AT HALT INSTRUCTION, SAC INH [ST2], IR CAXX [IR3], IR CAMX [IR1]
;**********
;THIS TEST VERIFIES THAT THE CAI INSTRUCTION DOES NOT MODIFY C(AC). THE AC IS
;INITIALLY LOADED WITH ALL ZEROS; THEN CAI IS EXECUTED WITH E NON-ZERO. THE AC IS
;THEN CHECKED FOR ALL ZEROS. THIS TEST FAILS IF THE AC WAS MODIFIED BY CAM.
A3500: MOVE [0] ;PRESET THE AC TO ALL ZEROS
CAI [1234] ;*CAI SHOULD NOT MODIFY THE AC
MOVE ;MOVE C(0) INTO 0 (THIS INSTRUCTION IS A PROGRAM FILLER
;IN CASE CAI MODIFIES THE AC. IT SERVES AS A NO-OP)
SKIPE ;SKIP HALT INSTRUCTION IF CAI DID NOT MODIFY THE AC
STOP
;**********
;THIS TEST VERIFIES THAT CAI DOES NOT MODIFY C(AC0) WHEN AN AC OTHER THAN AC0 IS
;SPECIFIED BY THE CAI INSTRUCTION.
;THIS IS THE FIRST TEST THAT USES AN AC OTHER THAN AC0.
;FIRST, AC0 IS LOADED WITH ALL ZEROS; THEN, THE CAI INSTRUCTION IS EXECUTED WITH
;A NON-ZERO E. AC 0 IS THEN TESTED F0R ALL ZEROS.
A3600: MOVE [0] ;LOAD AC0 WITH ALL ZEROS
CAI 17,[1234] ;*CAI SHOULD NOT MODIFY AC0
MOVE ;MOVE C(0) INTO 0 (THIS INSTRUCTION IS A FILLER IN CASE
;CAI SKIPS THE NEXT INSTRUCTION. IT ACTS AS A NO-OP)
SKIPE ;SKIP HALT INSTRUCTION IF C(AC0) WAS NOT MODIFIED
STOP
;**********
;THIS TEST VERIFIES THAT CAM DOES NOT MODIFY C(AC0) WHEN AN AC OTHER THAN AC0 IS
;SPECIFIED BY THE CAM INSTRUCTION.
;FIRST, AC0 IS LOADED WITH ALL ZEROS; THEN, THE CAM INSTRUCTION IS EXECUTED WITH
;A NON-ZERO E. AC 0 IS THEN TESTED F0R ALL ZEROS.
A3700: MOVE [0] ;PRESET C(AC0) TO ALL ZEROS
CAM 17,[1234] ;*CAM SHOULD NOT MODIFY AC0
MOVE ;MOVE C(0) INTO 0 (THIS INSTRUCTION IS A FILLER IN CASE
;CAM SKIPS THE NEXT INSTRUCTION. IT SERVES AS A NO-OP)
SKIPE ;SKIP HALT INSTRUCTION IF AC0 WAS NOT MODIFIED BY CAM
STOP
;**********
;THIS TEST VERIFIES THAT MOVE WILL PLACE C(E) INTO THE AC. AC, E AND C(E) ARE NON-ZERO
;IN THIS TEST. THIS TEST PASSES IF FINAL C(AC) OF THE MOVE INSTRUCTION IS NON-ZERO.
A4500: MOVE 1,[0] ;LOAD THE AC WITH ALL ZEROS
MOVE 1,[-1] ;*MOVE SHOULD PLACE ALL ONES IN THE AC
SKIPN 1 ;SKIP HALT INSTRUCTION IF MOVE MODIFIED THE AC
STOP
;**********
;THIS TEST VERIFIES THAT THE MOVE INSTRUCTION WILL PLACE C(E) INTO THE AC.
;AC, E ARE NON-ZERO AND C(E)=0.
;THIS TEST FAILS IF THE FINAL C(AC) IS NOT EQUAL TO ZERO, THE ORIGINAL C(E)
A4600: MOVE 1,[0] ;*PLACE ALL ZEROS INTO THE AC
SKIPE 1 ;SKIP HALT INSTRUCTION IF MOVE PLACED ALL ZEROS INTO AC
STOP
;IF JUMP .+1 OF PREVIOUS TEST FAILED, CHECK JUMPS: AD FM + EN [ADFP], IR JUMPS [IR1],
;IR JUMPX [IR1], AR AD EN [ARMA], AR AD EN A [ARMA], AR LT AD EN A [ARMA],
;AR LT ADD EN B [ARMA], AR RT AD EN A [ARMA],
;AR RT AD EN B [ARMA], AR A CLK INPUT [ARMA],
;ET2 C F/F [E], AR AD ET2 EN [ARMA], AR AD BR (ET2) B [ARMA]
;**********
;THIS TEST VERIFIES THAT SOS DOES NOT MODIFY C(AC) WHEN THE AC IS AC0.
;FIRST, AC0 IS LOADED WITH ALL ZEROS AND E IS LOADED WITH A POSITIVE NUMBER;
;THEN, SOS IS EXECUTED. SOS SHOULD SUBTRACT ONE FROM C((E)
;AND EXECUTE THE NEXT INSTRUCTION. IT SHOULD NOT MODIFY AC0.
;THE TEST PASSES IF AC0 WAS NOT MODIFIED.
A4000: MOVE [0] ;PRESET AC0 TO ALL ZEROS
MOVE 7,[1234] ;PRESET E WITH A POSITIVE NUMBER
SOS 7 ;*SOS SHOULD NOT MODIFY C(AC0)
MOVE ;MOVE C(0) INTO 0 (THIS INSTRUCTION IS A FILLER IN CASE
;SOS SKIPS THE NEXT INSTRUCTION. IT SERVES AS A NO-OP)
SKIPE ;SKIP THE HALT INSTRUCTION IF C(AC0) WAS NOT MODIFIED
STOP
;**********
SN=4100
AC=0
A4100: REPEAT 4,
<;THIS TEST VERIFIES THAT THE SKIP INSTRUCTION WILL PLACE THE CONTENTS OF E INTO THE AC
;WHEN THE AC IS NOT AC0. THIS TEST IS PERFORMED FOR AC1, AC2, AC4 AND AC10.
;FIRST, THE AC IS LOADED WITH ALL ZEROS; THEN, THE SKIP INSTRUCTION IS EXECUTED
;WITH AC1, AC2, AC4 OR AC10. C(E) IS EQUAL TO -1. THE SKIP INSTRUCTION SHOULD CAUSE
;THE AC TO CONTAIN -1. THE AC IS THEN CHECKED FOR
;NON-ZERO CONTENTS. THE TEST FAILS IF C(AC)=0.
;THIS TEST ALSO VERIFIES THAT 'SKIP AC,[-1]' DOES NOT CLOBBER AC0.
SN=SN+1
AC=AC+AC
IFE AC,<AC=1>
MOVE 0,[0] ;PRESET AC0 TO ALL ZEROS
MOVE AC,[0] ;PRESET THE AC TO ALL ZEROS
SKIP AC,[-1] ;*SKIP SHOULD PLACE -1 INTO THE AC
SKIPN AC ;SKIP THE HALT INSTRUCTION IF THE AC IS NON-ZERO
STOP
SKIPE 0 ;VERIFY THAT AC0 DID NOT GET CLOBBERED BY SKIP
STOP
;**********
>
SUBTTL TEST OF SKIP, FULL WORD TRANSFER AND HALF WORD TRANSFER INSTRUCTIONS
;THIS TEST VERIFIES THAT THE SKIP INSTRUCTION WILL NOT MODIFY THE CONTENTS OF AC0.
;FIRST, AC0 IS LOADED WITH ALL ZEROS; THEN,
;THE SKIP INSTRUCTION IS EXECUTED WITH C(E)=-1 AND AC0. AC0 IS THEN TESTED FOR ALL
;ZEROS. THE TEST FAILS IF AC0 WAS MODIFIED BY THE SKIP INSTRUCTION.
A4200: MOVE [0] ;PRESET AC0 TO ALL ZEROS
SKIP [-1] ;*SKIP SHOULD NOT MODIFY AC0
SKIPE ;SKIP HALT INSTRUCTION IF AC0 WAS NOT MODIFIED BY SKIP
STOP
;AC=0: SAC INH, IR BIT 9, 10, 11 OR 12 S-A-1
;**********
;THIS TEST VERIFIES THAT MOVSS DOES NOT MODIFY C(AC0) WHEN AC0 IS SPECIFIED AS THE AC.
;FIRST, E IS LOADED WITH ALL ONES AND THE AC (AC0)
;IS LOADED WITH ALL ZEROS; THEN, MOVSS IS EXECUTED. MOVSS SHOULD NOT MODIFY AC0.
;AC0 IS THEN CHECKED TO INSURE THAT IT WAS NOT MODIFIED BY MOVSS.
A4300: MOVE 7,[-1] ;LOAD E OF THE MOVSS INSTRUCTION WITH ALL ONES
MOVE [0] ;PRESET AC0 TO ALL ZEROS
MOVSS 7 ;*MOVSS SHOULD NOT MODIFY AC0
SKIPE ;SKIP HALT INSTRUCTION IF AC0 WAS INTACT
STOP
;MOVX & AC=0: SAC INH [ST2], IR XXXS [IR1]
;**********
;THIS TEST VERIFIES THAT HRRS DOES NOT MODIFY C(AC0) WHEN AC0 IS THE SPECIFIED AC.
;FIRST, E IS LOADED WITH ALL ONES AND AC0 IS LOADED WITH ALL ZEROS;
;THEN, HRRS IS EXECUTED WITH AC=AC0. AC0 IS THEN CHECKED FOR ALL ZEROS.
;IF AC0 WAS MODIFIED BY THE HRRS INSTRUCTION, THE TEST FAIL.
A4400: MOVE 7,[-1] ;PRESET E OF THE HRRS INSTRUCTION TO ALL ONES
MOVE [0] ;PRESET AC0 TO ALL ZEROS
HRRS 7 ;*HRRS SHOULD NOT MODIFY THE AC WHEN THE AC IS AC0
SKIPE ;SKIP THE HALT INSTRUCTION IF AC0 WAS INTACT
STOP
;(HXXXS&AC=0): SAC INH [ST2], IR HWTFWT [IR3], IR XXXS [IR1], IR HWT [IR1],
;IR BITS S-A-1
;**********
;THIS TEST VERIFIES THAT THE JUMP INSTRUCTION DOES NOT MODIFY C(AC).
;THE AC IS FIRST LOADED WITH ALL ZEROS;
;THEN JUMP .+1 IS EXECUTED. THE AC IS THEN CHECKED TO INSURE THAT IT WAS NOT MODIFIED
;BY JUMP. THE TEST FAILS IF THE AC WAS MODIFIED
A4700: MOVE [0] ; PRESET THE AC TO ALL ZEROS
JUMP .+1 ;*JUMP SHOULD NOT MODIFY THE AC
SKIPE ;SKIP HALT INSTRUCTION IF AC WAS INTACT
STOP
;**********
;THIS TEST VERIFIES THAT MOVS WILL NOT PICK UP ANY ONES WHEN SWAPPING A WORD
;OF ALL ZEROS. FIRST, E IS LOADED WITH A WORD OF ALL ZEROS;
;THEN, MOVS IS EXECUTED. THE AC IS THEN CHECKED TO INSURE THAT THE RESULT DOES NOT
;CONTAIN ANY ONES.
A5000: MOVE [0] ;PRESET E WITH ALL ZEROS
MOVS ;*MOVS SHOULD RESULT WITH AN AC 0F ALL ZEROS
SKIPE ;SKIP HALT INSTRUCTION IF C(AC)=0
STOP
;**********
;THIS TEST VERIFIES THAT A MOVS EXECUTED ON AN E CONTAINING A NON-ZERO NUMBER
;RESULTS IN A NON-ZERO NUMBER IN THE AC. FIRST A NON-ZERO WORD
;IS LOADED INTO E; THEN, MOVS IS EXECUTED. THE AC IS CHECKED FOR A NON-ZERO RESULT.
;IF C(AC)=0, THE TEST FAILS.
A5100: MOVE [XWD 0,-1] ;LOAD E WITH A NON-ZERO VALUE
MOVS ;*MOVS SHOULD RESULT IN C(AC) NON-ZERO
SKIPN ;SKIP HALT INSTRUCTION IF C(AC) OF MOVS IS NON-ZERO
STOP
;**********
;THIS TEST VERIFIES THAT A MOVS EXECUTED ON AN E CONTAINING A NON-ZERO NUMBER
;RESULTS IN A NON-ZERO NUMBER IN THE AC. FIRST A NON-ZERO WORD
;IS LOADED INTO E; THEN, MOVS IS EXECUTED. THE AC IS CHECKED FOR A NON-ZERO
;RESULT. IF C(AC)=0, THE TEST FAILS.
A5200: MOVE [XWD -1,0] ;LOAD E OF MOVS WITH A NON-ZERO NUMBER
MOVS ;*MOVS SHOULD RESULT WITH C(AC) NON-ZERO
SKIPN ;SKIP HALT INSTRUCTION IF C(AC) OF MOVS IS NON-ZERO
STOP
;**********
;THIS TEST VERIFIES THAT THE MOVS INSTRUCTION SWAPS BITS 0 AND 188 OF E
;AND STORES THEM IN THE AC UNLESS AR BIT 0 IS S-A-0. FIRST, A WORD
;WITH BIT 0 SET TO A ONE AND BIT 18 CLEARED IS LOADED INTO E. THEN, MOVS
;IS EXECUTED. THE AC IS THEN CHECKED FOR A 0 IN BIT 0, WHICH IS THE
;CORRECT RESULT.
A5300: MOVE [XWD -1,0] ;LOAD E OF MOVS WITH 777777000000
MOVS ;*MOVS SHOULD RESULT WITH AC BIT 0 EQUAL TO 0
SKIPG ;SKIP HALT INSTRUCTION IF BIT 0 OF AC IS 0
STOP
;MOVSX: AR SWAP [ARMB], AR LT AR RT A [ARMB], AR LT AR RT B [ARMB],
;AR RT AR LT A [ARMB], AR RT AR LT B [ARMB], ET2 A F/F [E], IR MOVSX [IR1],
;IR MOV(E,S)X [IR1]
;**********
;THIS TEST VERIFIES THAT THE MOVS INSTRUCTION SWAPS BITS 0 AND 18 OF E AND
;STORES THEM IN THE AC UNLESS AR BIT 0 IS S-A-1. FIRST, A WORD WITH BIT 0
;SET TO A ONE AND BIT 18 CLEARED IS LOADED INTO E. THEN, MOVS IS EXECUTED.
;THE AC IS CHECKED FOR A ZERO IN BIT ZERO, WHICH IS THE CORRECT RESULT.
A5400: MOVE [XWD 0,-1] ;LOAD E OF MOVS WITH 777777
MOVS ;*MOVS SHOULD RESULT WITH BIT 0 OF THE AC SET
SKIPL ;PASS IF AC BIT 0 IS SET
STOP
;**********
SN=5500
ZZ=0
A5500: REPEAT ^D18,
<;THIS TEST VERIFIES THAT AR LT INPUT IS FUNCTIONING. A WORD OF ALL ZER0S,
;EXCEPT FOR ONE ONE IN THE RIGHT HALF IS SWAPPED.
;THE AC IS CHECKED FOR ITS CONTENTS NON-ZERO. THE TEST PASSES
;IF C(AC) IS NON-ZERO. THIS TEST IS REPEATED 18 TIMES SO THAT EACH BIT
;OF THE LEFT HALF OF THE AC IS TESTED WITH A 1.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [0] ;CLEAR AC
MOVS [ZZ] ;*MOVS SHOULD RESULT WITH A NON-ZERO WORD IN THE AC
SKIPN ;SKIP HALT INSTRUCTION IF SET BIT IS NOT LOST IN SWAP.
STOP
;**********
>
SN=5600
A5600: REPEAT ^D18,
<;THIS TEST VERIFIES THAT AR RT INPUT IS FUNCTIONING. A WORD OF ALL
;ZEROS, EXCEPT FOR ONE ONE IN THE LEFT HALF IS SWAPPED. THE AC IS
;CHECKED FOR ITS CONTENTS NON-ZERO. THE TEST PASSES IF C(AC) IS
;NON-ZERO. THIS TEST IS REPEATED 18 TIMES SO THAT EACH BIT OF THE RIGHT
;HALF OF THE AC IS TESTED WITH A 1.
SN=SN+1
ZZ=ZZ+ZZ
MOVE [0] ;CLEAR AC
MOVS [ZZ] ;*MOVS SHOULD RESULT WITH A NON-ZERO WORD IN THE AC
SKIPN ;SKIP HALT INSTRUCTION IF SET BIT IS NOT LOST IN SWAP.
STOP
;**********
>
SUBTTL TEST OF BOOLEAN INSTRUCTIONS (SETM, SETZ, AND, XOR, EQV)
;THIS TEST VERIFIES THAT SETM LOADS AC FROM E. THE AC IS FIRST SET
;TO ZERO; THEN, SETM IS EXECUTED WITH ALL ONES IN E. BIT 0 OF THE AC
;IS THEN CHECKED FOR A 1.
A5700: MOVE [0] ;PRELOAD AC WITH ALL ZEROS
SETM [-1] ;*SETM SHOULD LOAD AC WITH ALL ONES
SKIPL ;PASS TEST IF AC BIT 0 IS A ONE
STOP
;FCE [F1], IR BOOLE [IR1], IRXX(0,5,12,17) [IR2]
;**********
;THIS TEST VERIFIES THAT SETM LOADS AC FROM E. THE AC IS FIRST SET TO
;ALL ONES; THEN, SETM IS EXECUTED WITH ALL ZEROS IN E. THE AC IS CHECKED
;FOR ALL ZEROS
A6000: MOVE [-1] ;PRESET AC TO ALL ONES
SETM [0] ;*SETM SHOULD LOAD AC WITH ALL ONES
SKIPE ;PASSES TEST IF C(AC) = 0
STOP
;AD AR + EN [ADAP], AD AR + EN C[ADAP],
;F CYC ACT EN A[F1], IR BOOLE AD A +F[IR2],
;IR BOOLE [IR1], IRXX(1-3,6,11,15,16) [IR2]
;**********
;THIS TEST VERIFIES THAT SETZ LOADS TH AC WITH ALL ZEROS. FIRST, A WORD
;OF ALL ZEROS IS LOADED INTO THE AC VIA A MOVE INSTC. THEN, SETZ IS
;EXECUTED. THE AC IS CHECKED FOR ALL ZEROS.
;IF ANY BITS IN THE AC ARE SET, THE TEST FAILS.
A6100: MOVE [0] ;RESET AC TO ALL ZEROS
SETZ ;*SETZ SHOULD CLEAR THE AC
SKIPE ;PASS TEST IF C(AC) = 0
STOP
;AD MASK GEN EN [ADC1], AD MASK GEN F/F'S [ADC1]
;AD MASK EN B; F CYC ACT EN B[F1]; IRXX00 [IR1];
;IR BOOLE [IR1]
;**********
;THIS TEST VERIFIES THAT SETZ LOADS THE AC WITH ALL ZEROS. FIRST,
;THE AC IS SET TO ALL ONES; THEN, SETZ IS EXECUTED. THE AC IS THEN
;CHECKED FOR ALL ZEROS. IF ANY BITS IN THE AC ARE SET, THE TEST FAILS.
A6200: MOVE [-1] ;PRESET AC TO ALL ONES
SETZ . ;*SETZ SHOULD CLEAR THE AC
SKIPE ;PASS TEST IF C(AC) = 0
STOP
;AR AD EN [ARMA], AR AD ET2 EN [ARMA], IR BOOLE [IR]
;**********
;THIS TEST VERIFIES THAT THE AND INSTRUCTION OPERATING ON AN AC
;CONTAINING ALL ZEROS AND AN E CONTAINING ALL ZEROS RESULTS IN AN AC
;OF ALL ZEROS. THE AC AND E ARE THE SAME IN THIS TEST.
;AC, E ARE LOADED WITH ZEROS; THEN, AND IS EXECUTED. THE AC IS THEN
;CHECKED FOR ALL ZEROS. IF ANY BITS IN THE AC ARE SET BY THE AND INSTRUCTION,
;THE TEST FAILS.
A6300: MOVE [0] ;PRESET AC, E TO ALL ZEROS
AND ;*AND SHOULD RESULT IN C(AC) = 0
SKIPE ;PASS TEST IF C(AC) = 0
STOP
;**********
SN=6400
ZZ=0
A6400: REPEAT ^D36,
<;THIS TEST VERIFIES THAT IF ONE OF THE OPERANDS OF THE AND INSTRUCTION
;IS ZERO, THE RESULT WILL BE ZERO. THIS TEST IS REPEATED 36 TIMES WITH
;ALL ZEROS IN THE AC EXCEPT FOR ONE ONE IN BIT X
;WHERE X TAKES ON INTEGER VALUES 0 THRU 35. E CONTAINS ALL ZEROS.
;THE RESULT SHOULD BE ALL ZEROS IN THE AC. IF C(AC) IS NON-ZERO,
;'AND' FAILED. C(0) IS ALSO CHECKED FOR ALL ZEROS. IF C(0) IS
;NON-ZERO, AC0 WAS CLOBBERED BY 'AND'.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
SETZ ;PRESET E TO ALL ZEROS
MOVE 1,[ZZ] ;LOAD AC WITH ALL ZEROS EXCEPT FOR A ONE IN BIT X
;WHERE X VARIES FROM 0 THRU 35
AND 1,0 ;*AND SHOULD RESULT IN C(AC) = 0
SKIPE 1 ;FAIL IF C(AC) NON-ZERO
STOP
SKIPE 0 ;FAIL IF C(0) IS NON-ZERO
STOP
;**********
>
SN=6500
ZZ=0
A6500: REPEAT ^D36,
<;THIS TEST VERIFIES THAT THE RESULT OF A WORD ANDED WITH ITSELF
;SHOULD BE THAT SAME WORD. A WORD CONTAINING ALL ZEROS EXCEPT FOR A ONE
;IN ONLY ONE BIT IS ANDED WITH ITSELF. THE AC IS THEN CHECKED FOR ITS
;CONTENTS NONZERO. IF C(AC)=0, THE 'AND' INSTRUCTION FAILED. THIS TEST IS REPEATED
;36 TIMES TO CHECK EACH BIT INDIVIDUALLY.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [ZZ] ;LOAD AC WITH ALL ZEROS EXCEPT FOR A ONE IN ONE BIT
AND ;*AND OF WORD CONTAINING A ONE IN ONE BIT
;POSITION WITH ITSELF SHOULD RESULT WITH
;C(AC) NONZERO
SKIPN ;PASS TEST IF C(AC) NONZERO
STOP
;**********
>
;THIS TEST VERIFIES THAT THE RESULT OF THE AND INSTRUCTION WHERE
;C(AC)=0 AND C(E)=0 AND E OUTSIDE OF THE AC RANGE IS ALL ZEROS IN THE AC.
;FIRST, THE AC IS CLEARED; THEN, THE C(AC) IS ANDED WITH C(E) WHEN
;E GREATER THAN 20 AND C(E)=0. THE RESULT SHOULD BE C(AC)=0.
;IF C(AC) IS NON-ZERO, 'AND' FAILED WITH THE MEMORY OPERAND.
A6600: MOVE [0] ;PRESET AC TO ALL ZEROS
AND [0] ;*AND OF TWO WORDS OF ALL ZEROS
;SHOULD RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
;THIS TEST VERIFIES THAT THE RESULT OF THE AND INSTRUCTION WHERE C(AC)=0
;AND C(E) IS ALL ONES IS AN AC CONTAINING ALL ZEROS. FIRST, THE AC IS
;CLEARED; THEN THE C(AC) IS ANDED WITH AN E CONTAINING ALL ONES, WHERE
;E IS BEYOND THE AC RANGE. THE RESULT SHOULD BE C(AC)=0.
;IF C(AC) IS NON-ZERO, 'AND' FAILED WITH THE MEMORY OPERAND.
A6700: MOVE [0] ;PRESET AC TO ALL ZEROS
AND [-1] ;*AND OF TWO WORDS WHERE C(AC)=0 SHOULD RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;AD FM+EN [ADFP],AD FM+EN A [ADFP],
;F CYC ACT EN C [F1],IR BOOLE AD FM+F [IR2],
;IR BOOLE [IR1],IRXX(1,4,5,11,13,16) [IR2]
;**********
;THIS TEST VERIFIES THAT THE RESULT OF THE AND INSTRUCTION WHERE C(E)=0
;AND C(AC) IS ALL ONES IS AN AC CONTAINING ALL ZEROS. FIRST, THE
;AC IS SET TO ALL ONES; THEN, THE AC IS ANDED WITH AN E CONTAINING ALL
;ZEROS, WHERE E IS BEYOND THE AC RANGE. THE RESULT SHOULD BE C(AC)=0.
;IF C(AC) IS NON-ZERO, 'AND' FAILED WITH THE MEMORY OPERAND.
A7000: MOVE [-1] ;PRESET AC TO ALL ONES
AND [0] ;*AND OF TWO WORDS WHERE C(E)=0 SHOULD RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
;THIS TEST VERIFIES THAT THE RESULT OF THE AND INSTRUCTION WHERE C(E) IS
;ALL ONES AND C(AC) IS ALL ONES IS AN AC CONTAINING ALL ONES. FIRST, THE
;AC IS SET TO ALL ONES; THEN, C(AC) IS ANDED WITH AN E CONTAINING ALL
;ONES. THE AC IS THEN CHECKED FOR A NON-ZERO RESULT.
;IF C(AC) IS ZERO, 'AND' FAILED WITH THE MEMORY OPERAND.
A7100: MOVE [-1] ;PRELOAD AC WITH ALL ONES
AND [-1] ;*AND OF TWO WORDS OF ALL ONES SHOULD
;RESULT IN C(AC)=ALL ONES
SKIPN ;PASS TEST IF C(AC) IS NON ZERO
STOP
;**********
;THIS TEST VERIFIES THAT THE RESULT OF THE XOR INSTRUCTION WHERE
;C(AC)=0 AND C(E) IS NON-ZERO IS AN AC WHERE CONTENTS IS NON-ZERO.
;FIRST, THE AC IS CLEARED, THEN, XOR IS EXECUTED WHERE C(E) IS NON-ZERO.
;THE AC IS THEN CHECKED FOR NON-ZERO CONTENTS.
A7200: MOVE [0] ;CLEAR AC
XOR [707070707070] ;*XOR WITH C(AC)=0 AND C(E)=7070707070 SHOULD
;RESTULT IN C(AC)=707070707070
SKIPN ;PASS TEST IF C(AC) NON-ZERO
STOP
;**********
SN=7300
ZZ=0
A7300: REPEAT ^D36,
<;THIS TEST VERIFIES THAT THE RESULT OF THE XOR INSTRUCTION WHERE
;C(AC)=0 AND C(E) IS NON-ZERO IS AN AC WHOSE CONTENTS IS NON-ZERO. THIS
;TEST IS REPEATED 36 TIMES. EACH TIME THE AC IS CLEARED AND XOR IS EXECUTED
;WITH ALL BITS OF E CLEAR EXCEPT FOR ONE FLOATING BIT WHICH IS SET TO A ONE.
;THE AC IS THEN CHECKED FOR A NON-ZERO RESULT.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [0] ;CLEAR AC
XOR [ZZ] ;*XOR WITH C(AC)=0 AND ONE BIT OF C(E) SET SHOULD
;RESULT IN C(AC) NONZERO
SKIPN ;PASS TEST IF C(AC) NON-ZERO
STOP
;**********
>
SN=7400
ZZ=0
A7400: REPEAT ^D36,
<;THIS TEST VERIFIES THAT THE RESULT OF THE XOR INSTRUCTION WHERE
;C(E)=0 AND C(AC) IS NON-ZERO IS AN AC WHOSE CONTENTS IS NON-ZERO. THIS
;TEST IS REPEATED 36 TIMES. EACH TIME THE AC IS INITIALIZED SO THAT ONE
;AND ONLY ONE FLOATING BIT IS SET TO ONE AND XOR IS EXECUTED WITH E
;CONTAINING ALL ZEROS. THE AC IS THEN CHECKED FOR A NON-ZERO RESULT.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [ZZ] ;PRELOAD AC WITH ONE FLOATING BIT SET
XOR [0] ;*XOR WITH C(E)=0 AND ONE BIT OF C(AC) SET SHOULD
;RESULT IN C(AC) NON-ZERO
SKIPN ;PASS TEST IF C(AC) NON-ZERO
STOP
;AD FM- EN [ADFM], AD FM- F/F'S[ADFM],F CYC ACT EN D[R1],
;IR BOOLE AD FM- F [IR2],IR BOOLE[IR1],IR XX (2,6,7,10,12,15)[IR2],
;AD EQV[ADCR],AD EQV F/F[ADC2],FCYC ACT EN A[F1],
;IR BOOLE (6,11)[IR2],IR BOOLE[IR1],IRXX(6,11)[IR2]
;**********
>
SN=7500
ZZ=0
A7500: REPEAT ^D36,
<;THIS TEST VERIFIES THAT THE RESULT OF AN XOR INSTRUCTION
;WHERE C(AC) = C(E) IS AN AC CONTAINING ALL ZEROS. FIRST,
;THE AC IS INITIALIZED WITH A WORD CONTAINING ALL ZEROS EXCEPT
;FOR ONE FLOATING ONE; THEN, XOR IS EXECUTED WITH E CONTAINING THE SAME
;NUMBER. THE RESULT SHOULD BE AN AC CONTAINING ALL ZEROS. THIS TEST
;IS REPEATED 36 TIMES. IF ANY BIT IN THE RESULT IS NON-ZERO, IT MAY
;INDICATE AN ILLEGAL CARRY GENERATION.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [ZZ] ;INITIALIZE AC WITH ONE FLOATING BIT SET
XOR [ZZ] ;*XOR WITH C(AC)=C(E) SHOULD RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
>
;THIS TEST VERIFIES THAT THE RESULT OF AN XOR INSTRUCTION WHERE
;C(AC)=C(E)=0 IS AN AC CONTAINING ALL ZEROS; FIRST THE AC IS CLEARED; THEN
;XOR IS EXECUTED WITH C(E)=0. THE RESULT IN THE AC IS CHECKED FOR ALL ZEROS
A7600: MOVE [0] ;INITIALIZE AC TO ALL ZEROS
XOR [0] ;*XOR WITH C(AC)=C(E)=0 SHOULD RESULT INC(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
;THIS TEST VERIFIES THAT THE RESULT OF AN EQV INSTRUCTION WHERE
;C(AC)=0 AND C(E) ALL ONES IS AN AC CONTAINING ALL ZEROS SINCE
;THE EQUIVALENCE FUNCTION SHOULD SET ONLY LIKE BITS. FIRST, THE AC
;SHOULD BE CLEARED; THEN, EQV IS EXECUTED WITH E CONTAINING ALL ONES.
;THE AC IS THEN CHECKED FOR ALL ZEROS
A7700: MOVE [0] ;CLEAR THE AC
EQV [-1] ;*EQV WITH C(AC)=0 AND C(E) ALL ONES SHOULD
;RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
SN=10000
ZZ=0
A10000: REPEAT ^D18,
<;THIS TEST VERIFIES THAT THE RESULT OF AN EQV INSTRUCTION WHERE
;C(AC)=0 AND C(E) IS ALL ONES EXCEPT FOR A ZERO IN ONLY ONE BIT IS AN
;AC WHOSE CONTENTS IS NON-ZERO (A ONE RESULTS IN THE BIT WHERE
;E CONTAINS A ZERO). THIS TEST IS REPEATED 36 TIMES SO THAT EACH BIT
;OF THE RESULT IS A ONE ONCE AND ONLY ONCE. FIRST, THE AC IS
;CLEARED; THEN,EQV IS EXECUTED WITH ONE BIT OF E EQUAL TO ZERO. THE
;RESULT IN THE AC IS THEN CHECKED FOR ITS CONTENTS NON-ZERO
SN=SN+1
ZZ=ZZ+ZZ+1
IFE <ZZ-1>,<ZZ=-2>
MOVE [0] ;PRESET AC TO ALL ZEROS
EQV [XWD -1,ZZ] ;*EQV WITH C(AC)=0 AND ONE BIT OF C(E)=0 SHOULD
;RESULT IN C(AC) NON-ZERO
SKIPN ;PASS TEST IF C(AC) NON-ZERO
STOP
;**********
>
SN=10100
ZZ=0
A10100: REPEAT ^D18,
<;THIS TEST VERIFIES THAT THE RESULT OF AN EQV INSTRUCTION WHERE
;C(AC)=0 AND C(E) IS ALL ONES EXCEPT FOR A ZERO IN ONLY ONE BIT IS AN
;AC WHOSE CONTENTS IS NON-ZERO (A ONE RESULTS IN THE BIT WHERE
;E CONTAINS A ZERO). THIS TEST IS REPEATED 36 TIMES SO THAT EACH BIT
;OF THE RESULT IS A ONE ONCE AND ONLY ONCE. FIRST, THE AC IS
;CLEARED; THEN,EQV IS EXECUTED WITH ONE BIT OF E EQUAL TO ZERO. THE
;RESULT IN THE AC IS THEN CHECKED FOR ITS CONTENTS NON-ZERO
SN=SN+1
ZZ=ZZ+ZZ+1
IFE <ZZ-1>,<ZZ=-2>
MOVE [0] ;PRESET AC TO ALL ZEROS
EQV [XWD ZZ,-1] ;*EQV WITH C(AC)=0 AND ONE BIT OF C(E)=0 SHOULD
;RESULT IN C(AC) NON-ZERO
SKIPN ;PASS TEST IF C(AC) NON-ZERO
STOP
;**********
>
;THIS TEST VERIFIES THAT THE RESULT OF AN AC CONTAINING ALL ZEROS
;EQUIVALENCED WITH AN E CONTAINING ALL ZEROS IS AN AC CONTAINING ALL
;ONES; AND FUTHERMORE, IF THIS AC CONTAINING ALL ONES IS EQUIVALANCED
;WITH AN E CONTAINING ALL ZEROS, THE FINAL RESULT IN THE AC
;SHOULD BE ALL ZEROS. FIRST, THE AC IS INITIALIZED TO ALL ZEROS, THEN,
;THIS AC IS EQUIVALENCED TWICE WITH AN E CONTAINING ALL ZEROS. THE AC IS
;THEN CHECKED FOR ALL ZEROS
A10200: MOVE [0] ;CLEAR THE AC
EQV [0] ;*EQV SHOULD RESULT IN C(AC)=ALL ONES
EQV [0] ;*EQV SHOULD RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
;THIS TEST VERIFIES THAT THE RESULT OF AN AC CONTAINING ALL ONES
;EQUIVALENCED WITH AN E CONTAINING ALL ONES IS AN AC CONTAINING ALL ONES;
;AND FUTHERMORE, IF THIS AC CONTAINING ALL ONES ISEQUIVALENCED WITH AN E
;CONTAINING ALL ZEROS, THE FINAL RESULT IN THE AC SHOULD BE ALL ZEROS.
;FIRST, THE AC IS INITIALIZED TO ALL ONES; THEN, THIS AC IS
;EQUIVALENCED WITH AN E OF ALL ONES. NEXT, THIS SAME AC IS EQUIVALENCED
;WITH AN E OF ALL ZEROS. THE AC IS THEN CHECKED FOR ALL ZEROS.
A10300: MOVE [-1] ;SET C(AC) TO ALL ONES
EQV [-1] ;*EQV SHOULD RESULT IN C(AC) OF ALL ONES
EQV [0] ;*EQV SHOULD RESULT IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
SN=13000
ZZ=0
A13000: REPEAT ^D36,
<;THIS TEST CHECKS THE 'AND' INSTRUCTION AND THE ADDER ON A ONE-BIT-AT-A-TIME BASIS.
;THE AC IS LOADED WITH ALL ZEROS EXCEPT FOR ONE BIT EQUAL TO ONE; THE AC IS THEN
;ANDED WITH C(E) WHERE C(E)=C(AC). THE NET RESULT SHOULD BE NO CHANGE TO C(AC).
;NEXT, THE AC IS EQUIVALENCED WITH C(E) WHERE C(E)=C(AC). THIS RESULT SHOULD
;BE ALL ONES IN THE AC. THE AC IS THEN EQUIVALENCED WITH A WORD OF ALL ZEROS,
;WHICH SHOULD RESULT IN C(AC)=0. THE AC IS CHECKED FOR ALL ZEROS.
;IF C(AC) IS NON-ZERO, THE TEST FAILS. THIS TEST IS REPEATED 36 TIMES TO
;RIPPLE A ONE THROUGH EVERY BIT OF THE AC.
SN=SN+1
ZZ=ZZ+ZZ
IFE ZZ,<ZZ=1>
MOVE [ZZ] ;SETUP AC WITH A ONE IN ONLY ONE BIT
AND [ZZ] ;*AND FLOATING ONE WITH ITSELF SHOULD NOT CHANGE C(AC)
EQV [ZZ] ;RESULTS IN C(AC)=ALL ONES
EQV [0] ;RESULTS IN C(AC)=0
SKIPE ;PASS TEST IF C(AC)=0
STOP
;**********
>
ENDIT: SETZM TNUMB#
JRST BEGEND
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