Trying to build a forth runtime in C
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
forth/testfiles/combinedtest.f

1849 lines
55 KiB

\ From: John Hayes S1I
\ Subject: tester.fr
\ Date: Mon, 27 Nov 95 13:10:09 PST
\ (C) 1995 JOHNS HOPKINS UNIVERSITY / APPLIED PHYSICS LABORATORY
\ MAY BE DISTRIBUTED FREELY AS LONG AS THIS COPYRIGHT NOTICE REMAINS.
\ VERSION 1.2
\ 24/11/2015 Replaced Core Ext word <> with = 0=
\ 31/3/2015 Variable #ERRORS added and incremented for each error reported.
\ 22/1/09 The words { and } have been changed to T{ and }T respectively to
\ agree with the Forth 200X file ttester.fs. This avoids clashes with
\ locals using { ... } and the FSL use of }
HEX
\ SET THE FOLLOWING FLAG TO TRUE FOR MORE VERBOSE OUTPUT; THIS MAY
\ ALLOW YOU TO TELL WHICH TEST CAUSED YOUR SYSTEM TO HANG.
VARIABLE VERBOSE
\ FALSE VERBOSE !
TRUE VERBOSE !
: EMPTY-STACK \ ( ... -- ) EMPTY STACK: HANDLES UNDERFLOWED STACK TOO.
DEPTH ?DUP IF DUP 0< IF NEGATE 0 DO 0 LOOP ELSE 0 DO DROP LOOP THEN THEN ;
VARIABLE #ERRORS 0 #ERRORS !
: ERROR \ ( C-ADDR U -- ) DISPLAY AN ERROR MESSAGE FOLLOWED BY
\ THE LINE THAT HAD THE ERROR.
CR TYPE SOURCE TYPE \ DISPLAY LINE CORRESPONDING TO ERROR
EMPTY-STACK \ THROW AWAY EVERY THING ELSE
#ERRORS @ 1 + #ERRORS !
\ QUIT \ *** Uncomment this line to QUIT on an error
;
VARIABLE ACTUAL-DEPTH \ STACK RECORD
CREATE ACTUAL-RESULTS 20 CELLS ALLOT
: T{ \ ( -- ) SYNTACTIC SUGAR.
;
: -> \ ( ... -- ) RECORD DEPTH AND CONTENT OF STACK.
DEPTH DUP ACTUAL-DEPTH ! \ RECORD DEPTH
?DUP IF \ IF THERE IS SOMETHING ON STACK
0 DO ACTUAL-RESULTS I CELLS + ! LOOP \ SAVE THEM
THEN ;
: }T \ ( ... -- ) COMPARE STACK (EXPECTED) CONTENTS WITH SAVED
\ (ACTUAL) CONTENTS.
DEPTH ACTUAL-DEPTH @ = IF \ IF DEPTHS MATCH
DEPTH ?DUP IF \ IF THERE IS SOMETHING ON THE STACK
0 DO \ FOR EACH STACK ITEM
ACTUAL-RESULTS I CELLS + @ \ COMPARE ACTUAL WITH EXPECTED
= 0= IF S" INCORRECT RESULT: " ERROR LEAVE THEN
LOOP
THEN
ELSE \ DEPTH MISMATCH
S" WRONG NUMBER OF RESULTS: " ERROR
THEN ;
: TESTING \ ( -- ) TALKING COMMENT.
SOURCE VERBOSE @
IF DUP >R TYPE CR R> >IN !
ELSE >IN ! DROP [CHAR] * EMIT
THEN ;
\ From: John Hayes S1I
\ Subject: core.fr
\ Date: Mon, 27 Nov 95 13:10
\ (C) 1995 JOHNS HOPKINS UNIVERSITY / APPLIED PHYSICS LABORATORY
\ MAY BE DISTRIBUTED FREELY AS LONG AS THIS COPYRIGHT NOTICE REMAINS.
\ VERSION 1.2
\ THIS PROGRAM TESTS THE CORE WORDS OF AN ANS FORTH SYSTEM.
\ THE PROGRAM ASSUMES A TWO'S COMPLEMENT IMPLEMENTATION WHERE
\ THE RANGE OF SIGNED NUMBERS IS -2^(N-1) ... 2^(N-1)-1 AND
\ THE RANGE OF UNSIGNED NUMBERS IS 0 ... 2^(N)-1.
\ I HAVEN'T FIGURED OUT HOW TO TEST KEY, QUIT, ABORT, OR ABORT"...
\ I ALSO HAVEN'T THOUGHT OF A WAY TO TEST ENVIRONMENT?...
CR
TESTING CORE WORDS
HEX
\ ------------------------------------------------------------------------
TESTING BASIC ASSUMPTIONS
T{ -> }T \ START WITH CLEAN SLATE
( TEST IF ANY BITS ARE SET; ANSWER IN BASE 1 )
T{ : BITSSET? IF 0 0 ELSE 0 THEN ; -> }T
T{ 0 BITSSET? -> 0 }T ( ZERO IS ALL BITS CLEAR )
T{ 1 BITSSET? -> 0 0 }T ( OTHER NUMBER HAVE AT LEAST ONE BIT )
T{ -1 BITSSET? -> 0 0 }T
\ ------------------------------------------------------------------------
TESTING BOOLEANS: INVERT AND OR XOR
T{ 0 0 AND -> 0 }T
T{ 0 1 AND -> 0 }T
T{ 1 0 AND -> 0 }T
T{ 1 1 AND -> 1 }T
T{ 0 INVERT 1 AND -> 1 }T
T{ 1 INVERT 1 AND -> 0 }T
0 CONSTANT 0S
0 INVERT CONSTANT 1S
T{ 0S INVERT -> 1S }T
T{ 1S INVERT -> 0S }T
T{ 0S 0S AND -> 0S }T
T{ 0S 1S AND -> 0S }T
T{ 1S 0S AND -> 0S }T
T{ 1S 1S AND -> 1S }T
T{ 0S 0S OR -> 0S }T
T{ 0S 1S OR -> 1S }T
T{ 1S 0S OR -> 1S }T
T{ 1S 1S OR -> 1S }T
T{ 0S 0S XOR -> 0S }T
T{ 0S 1S XOR -> 1S }T
T{ 1S 0S XOR -> 1S }T
T{ 1S 1S XOR -> 0S }T
\ ------------------------------------------------------------------------
TESTING 2* 2/ LSHIFT RSHIFT
( WE TRUST 1S, INVERT, AND BITSSET?; WE WILL CONFIRM RSHIFT LATER )
1S 1 RSHIFT INVERT CONSTANT MSB
T{ MSB BITSSET? -> 0 0 }T
T{ 0S 2* -> 0S }T
T{ 1 2* -> 2 }T
T{ 4000 2* -> 8000 }T
T{ 1S 2* 1 XOR -> 1S }T
T{ MSB 2* -> 0S }T
T{ 0S 2/ -> 0S }T
T{ 1 2/ -> 0 }T
T{ 4000 2/ -> 2000 }T
T{ 1S 2/ -> 1S }T \ MSB PROPOGATED
T{ 1S 1 XOR 2/ -> 1S }T
T{ MSB 2/ MSB AND -> MSB }T
T{ 1 0 LSHIFT -> 1 }T
T{ 1 1 LSHIFT -> 2 }T
T{ 1 2 LSHIFT -> 4 }T
T{ 1 F LSHIFT -> 8000 }T \ BIGGEST GUARANTEED SHIFT
T{ 1S 1 LSHIFT 1 XOR -> 1S }T
T{ MSB 1 LSHIFT -> 0 }T
T{ 1 0 RSHIFT -> 1 }T
T{ 1 1 RSHIFT -> 0 }T
T{ 2 1 RSHIFT -> 1 }T
T{ 4 2 RSHIFT -> 1 }T
T{ 8000 F RSHIFT -> 1 }T \ BIGGEST
T{ MSB 1 RSHIFT MSB AND -> 0 }T \ RSHIFT ZERO FILLS MSBS
T{ MSB 1 RSHIFT 2* -> MSB }T
\ ------------------------------------------------------------------------
TESTING COMPARISONS: 0= = 0< < > U< MIN MAX
0 INVERT CONSTANT MAX-UINT
0 INVERT 1 RSHIFT CONSTANT MAX-INT
0 INVERT 1 RSHIFT INVERT CONSTANT MIN-INT
0 INVERT 1 RSHIFT CONSTANT MID-UINT
0 INVERT 1 RSHIFT INVERT CONSTANT MID-UINT+1
0S CONSTANT <FALSE>
1S CONSTANT <TRUE>
T{ 0 0= -> <TRUE> }T
T{ 1 0= -> <FALSE> }T
T{ 2 0= -> <FALSE> }T
T{ -1 0= -> <FALSE> }T
T{ MAX-UINT 0= -> <FALSE> }T
T{ MIN-INT 0= -> <FALSE> }T
T{ MAX-INT 0= -> <FALSE> }T
T{ 0 0 = -> <TRUE> }T
T{ 1 1 = -> <TRUE> }T
T{ -1 -1 = -> <TRUE> }T
T{ 1 0 = -> <FALSE> }T
T{ -1 0 = -> <FALSE> }T
T{ 0 1 = -> <FALSE> }T
T{ 0 -1 = -> <FALSE> }T
T{ 0 0< -> <FALSE> }T
T{ -1 0< -> <TRUE> }T
T{ MIN-INT 0< -> <TRUE> }T
T{ 1 0< -> <FALSE> }T
T{ MAX-INT 0< -> <FALSE> }T
T{ 0 1 < -> <TRUE> }T
T{ 1 2 < -> <TRUE> }T
T{ -1 0 < -> <TRUE> }T
T{ -1 1 < -> <TRUE> }T
T{ MIN-INT 0 < -> <TRUE> }T
T{ MIN-INT MAX-INT < -> <TRUE> }T
T{ 0 MAX-INT < -> <TRUE> }T
T{ 0 0 < -> <FALSE> }T
T{ 1 1 < -> <FALSE> }T
T{ 1 0 < -> <FALSE> }T
T{ 2 1 < -> <FALSE> }T
T{ 0 -1 < -> <FALSE> }T
T{ 1 -1 < -> <FALSE> }T
T{ 0 MIN-INT < -> <FALSE> }T
T{ MAX-INT MIN-INT < -> <FALSE> }T
T{ MAX-INT 0 < -> <FALSE> }T
T{ 0 1 > -> <FALSE> }T
T{ 1 2 > -> <FALSE> }T
T{ -1 0 > -> <FALSE> }T
T{ -1 1 > -> <FALSE> }T
T{ MIN-INT 0 > -> <FALSE> }T
T{ MIN-INT MAX-INT > -> <FALSE> }T
T{ 0 MAX-INT > -> <FALSE> }T
T{ 0 0 > -> <FALSE> }T
T{ 1 1 > -> <FALSE> }T
T{ 1 0 > -> <TRUE> }T
T{ 2 1 > -> <TRUE> }T
T{ 0 -1 > -> <TRUE> }T
T{ 1 -1 > -> <TRUE> }T
T{ 0 MIN-INT > -> <TRUE> }T
T{ MAX-INT MIN-INT > -> <TRUE> }T
T{ MAX-INT 0 > -> <TRUE> }T
T{ 0 1 U< -> <TRUE> }T
T{ 1 2 U< -> <TRUE> }T
T{ 0 MID-UINT U< -> <TRUE> }T
T{ 0 MAX-UINT U< -> <TRUE> }T
T{ MID-UINT MAX-UINT U< -> <TRUE> }T
T{ 0 0 U< -> <FALSE> }T
T{ 1 1 U< -> <FALSE> }T
T{ 1 0 U< -> <FALSE> }T
T{ 2 1 U< -> <FALSE> }T
T{ MID-UINT 0 U< -> <FALSE> }T
T{ MAX-UINT 0 U< -> <FALSE> }T
T{ MAX-UINT MID-UINT U< -> <FALSE> }T
T{ 0 1 MIN -> 0 }T
T{ 1 2 MIN -> 1 }T
T{ -1 0 MIN -> -1 }T
T{ -1 1 MIN -> -1 }T
T{ MIN-INT 0 MIN -> MIN-INT }T
T{ MIN-INT MAX-INT MIN -> MIN-INT }T
T{ 0 MAX-INT MIN -> 0 }T
T{ 0 0 MIN -> 0 }T
T{ 1 1 MIN -> 1 }T
T{ 1 0 MIN -> 0 }T
T{ 2 1 MIN -> 1 }T
T{ 0 -1 MIN -> -1 }T
T{ 1 -1 MIN -> -1 }T
T{ 0 MIN-INT MIN -> MIN-INT }T
T{ MAX-INT MIN-INT MIN -> MIN-INT }T
T{ MAX-INT 0 MIN -> 0 }T
T{ 0 1 MAX -> 1 }T
T{ 1 2 MAX -> 2 }T
T{ -1 0 MAX -> 0 }T
T{ -1 1 MAX -> 1 }T
T{ MIN-INT 0 MAX -> 0 }T
T{ MIN-INT MAX-INT MAX -> MAX-INT }T
T{ 0 MAX-INT MAX -> MAX-INT }T
T{ 0 0 MAX -> 0 }T
T{ 1 1 MAX -> 1 }T
T{ 1 0 MAX -> 1 }T
T{ 2 1 MAX -> 2 }T
T{ 0 -1 MAX -> 0 }T
T{ 1 -1 MAX -> 1 }T
T{ 0 MIN-INT MAX -> 0 }T
T{ MAX-INT MIN-INT MAX -> MAX-INT }T
T{ MAX-INT 0 MAX -> MAX-INT }T
\ ------------------------------------------------------------------------
TESTING STACK OPS: 2DROP 2DUP 2OVER 2SWAP ?DUP DEPTH DROP DUP OVER ROT SWAP
T{ 1 2 2DROP -> }T
T{ 1 2 2DUP -> 1 2 1 2 }T
T{ 1 2 3 4 2OVER -> 1 2 3 4 1 2 }T
T{ 1 2 3 4 2SWAP -> 3 4 1 2 }T
T{ 0 ?DUP -> 0 }T
T{ 1 ?DUP -> 1 1 }T
T{ -1 ?DUP -> -1 -1 }T
T{ DEPTH -> 0 }T
T{ 0 DEPTH -> 0 1 }T
T{ 0 1 DEPTH -> 0 1 2 }T
T{ 0 DROP -> }T
T{ 1 2 DROP -> 1 }T
T{ 1 DUP -> 1 1 }T
T{ 1 2 OVER -> 1 2 1 }T
T{ 1 2 3 ROT -> 2 3 1 }T
T{ 1 2 SWAP -> 2 1 }T
\ ------------------------------------------------------------------------
TESTING >R R> R@
T{ : GR1 >R R> ; -> }T
T{ : GR2 >R R@ R> DROP ; -> }T
T{ 123 GR1 -> 123 }T
T{ 123 GR2 -> 123 }T
T{ 1S GR1 -> 1S }T ( RETURN STACK HOLDS CELLS )
\ ------------------------------------------------------------------------
TESTING ADD/SUBTRACT: + - 1+ 1- ABS NEGATE
T{ 0 5 + -> 5 }T
T{ 5 0 + -> 5 }T
T{ 0 -5 + -> -5 }T
T{ -5 0 + -> -5 }T
T{ 1 2 + -> 3 }T
T{ 1 -2 + -> -1 }T
T{ -1 2 + -> 1 }T
T{ -1 -2 + -> -3 }T
T{ -1 1 + -> 0 }T
T{ MID-UINT 1 + -> MID-UINT+1 }T
T{ 0 5 - -> -5 }T
T{ 5 0 - -> 5 }T
T{ 0 -5 - -> 5 }T
T{ -5 0 - -> -5 }T
T{ 1 2 - -> -1 }T
T{ 1 -2 - -> 3 }T
T{ -1 2 - -> -3 }T
T{ -1 -2 - -> 1 }T
T{ 0 1 - -> -1 }T
T{ MID-UINT+1 1 - -> MID-UINT }T
T{ 0 1+ -> 1 }T
T{ -1 1+ -> 0 }T
T{ 1 1+ -> 2 }T
T{ MID-UINT 1+ -> MID-UINT+1 }T
T{ 2 1- -> 1 }T
T{ 1 1- -> 0 }T
T{ 0 1- -> -1 }T
T{ MID-UINT+1 1- -> MID-UINT }T
T{ 0 NEGATE -> 0 }T
T{ 1 NEGATE -> -1 }T
T{ -1 NEGATE -> 1 }T
T{ 2 NEGATE -> -2 }T
T{ -2 NEGATE -> 2 }T
T{ 0 ABS -> 0 }T
T{ 1 ABS -> 1 }T
T{ -1 ABS -> 1 }T
T{ MIN-INT ABS -> MID-UINT+1 }T
\ ------------------------------------------------------------------------
TESTING MULTIPLY: S>D * M* UM*
T{ 0 S>D -> 0 0 }T
T{ 1 S>D -> 1 0 }T
T{ 2 S>D -> 2 0 }T
T{ -1 S>D -> -1 -1 }T
T{ -2 S>D -> -2 -1 }T
T{ MIN-INT S>D -> MIN-INT -1 }T
T{ MAX-INT S>D -> MAX-INT 0 }T
T{ 0 0 M* -> 0 S>D }T
T{ 0 1 M* -> 0 S>D }T
T{ 1 0 M* -> 0 S>D }T
T{ 1 2 M* -> 2 S>D }T
T{ 2 1 M* -> 2 S>D }T
T{ 3 3 M* -> 9 S>D }T
T{ -3 3 M* -> -9 S>D }T
T{ 3 -3 M* -> -9 S>D }T
T{ -3 -3 M* -> 9 S>D }T
T{ 0 MIN-INT M* -> 0 S>D }T
T{ 1 MIN-INT M* -> MIN-INT S>D }T
T{ 2 MIN-INT M* -> 0 1S }T
T{ 0 MAX-INT M* -> 0 S>D }T
T{ 1 MAX-INT M* -> MAX-INT S>D }T
T{ 2 MAX-INT M* -> MAX-INT 1 LSHIFT 0 }T
T{ MIN-INT MIN-INT M* -> 0 MSB 1 RSHIFT }T
T{ MAX-INT MIN-INT M* -> MSB MSB 2/ }T
T{ MAX-INT MAX-INT M* -> 1 MSB 2/ INVERT }T
T{ 0 0 * -> 0 }T \ TEST IDENTITIES
T{ 0 1 * -> 0 }T
T{ 1 0 * -> 0 }T
T{ 1 2 * -> 2 }T
T{ 2 1 * -> 2 }T
T{ 3 3 * -> 9 }T
T{ -3 3 * -> -9 }T
T{ 3 -3 * -> -9 }T
T{ -3 -3 * -> 9 }T
T{ MID-UINT+1 1 RSHIFT 2 * -> MID-UINT+1 }T
T{ MID-UINT+1 2 RSHIFT 4 * -> MID-UINT+1 }T
T{ MID-UINT+1 1 RSHIFT MID-UINT+1 OR 2 * -> MID-UINT+1 }T
T{ 0 0 UM* -> 0 0 }T
T{ 0 1 UM* -> 0 0 }T
T{ 1 0 UM* -> 0 0 }T
T{ 1 2 UM* -> 2 0 }T
T{ 2 1 UM* -> 2 0 }T
T{ 3 3 UM* -> 9 0 }T
T{ MID-UINT+1 1 RSHIFT 2 UM* -> MID-UINT+1 0 }T
T{ MID-UINT+1 2 UM* -> 0 1 }T
T{ MID-UINT+1 4 UM* -> 0 2 }T
T{ 1S 2 UM* -> 1S 1 LSHIFT 1 }T
T{ MAX-UINT MAX-UINT UM* -> 1 1 INVERT }T
\ ------------------------------------------------------------------------
TESTING DIVIDE: FM/MOD SM/REM UM/MOD */ */MOD / /MOD MOD
T{ 0 S>D 1 FM/MOD -> 0 0 }T
T{ 1 S>D 1 FM/MOD -> 0 1 }T
T{ 2 S>D 1 FM/MOD -> 0 2 }T
T{ -1 S>D 1 FM/MOD -> 0 -1 }T
T{ -2 S>D 1 FM/MOD -> 0 -2 }T
T{ 0 S>D -1 FM/MOD -> 0 0 }T
T{ 1 S>D -1 FM/MOD -> 0 -1 }T
T{ 2 S>D -1 FM/MOD -> 0 -2 }T
T{ -1 S>D -1 FM/MOD -> 0 1 }T
T{ -2 S>D -1 FM/MOD -> 0 2 }T
T{ 2 S>D 2 FM/MOD -> 0 1 }T
T{ -1 S>D -1 FM/MOD -> 0 1 }T
T{ -2 S>D -2 FM/MOD -> 0 1 }T
T{ 7 S>D 3 FM/MOD -> 1 2 }T
T{ 7 S>D -3 FM/MOD -> -2 -3 }T
T{ -7 S>D 3 FM/MOD -> 2 -3 }T
T{ -7 S>D -3 FM/MOD -> -1 2 }T
T{ MAX-INT S>D 1 FM/MOD -> 0 MAX-INT }T
T{ MIN-INT S>D 1 FM/MOD -> 0 MIN-INT }T
T{ MAX-INT S>D MAX-INT FM/MOD -> 0 1 }T
T{ MIN-INT S>D MIN-INT FM/MOD -> 0 1 }T
T{ 1S 1 4 FM/MOD -> 3 MAX-INT }T
T{ 1 MIN-INT M* 1 FM/MOD -> 0 MIN-INT }T
T{ 1 MIN-INT M* MIN-INT FM/MOD -> 0 1 }T
T{ 2 MIN-INT M* 2 FM/MOD -> 0 MIN-INT }T
T{ 2 MIN-INT M* MIN-INT FM/MOD -> 0 2 }T
T{ 1 MAX-INT M* 1 FM/MOD -> 0 MAX-INT }T
T{ 1 MAX-INT M* MAX-INT FM/MOD -> 0 1 }T
T{ 2 MAX-INT M* 2 FM/MOD -> 0 MAX-INT }T
T{ 2 MAX-INT M* MAX-INT FM/MOD -> 0 2 }T
T{ MIN-INT MIN-INT M* MIN-INT FM/MOD -> 0 MIN-INT }T
T{ MIN-INT MAX-INT M* MIN-INT FM/MOD -> 0 MAX-INT }T
T{ MIN-INT MAX-INT M* MAX-INT FM/MOD -> 0 MIN-INT }T
T{ MAX-INT MAX-INT M* MAX-INT FM/MOD -> 0 MAX-INT }T
T{ 0 S>D 1 SM/REM -> 0 0 }T
T{ 1 S>D 1 SM/REM -> 0 1 }T
T{ 2 S>D 1 SM/REM -> 0 2 }T
T{ -1 S>D 1 SM/REM -> 0 -1 }T
T{ -2 S>D 1 SM/REM -> 0 -2 }T
T{ 0 S>D -1 SM/REM -> 0 0 }T
T{ 1 S>D -1 SM/REM -> 0 -1 }T
T{ 2 S>D -1 SM/REM -> 0 -2 }T
T{ -1 S>D -1 SM/REM -> 0 1 }T
T{ -2 S>D -1 SM/REM -> 0 2 }T
T{ 2 S>D 2 SM/REM -> 0 1 }T
T{ -1 S>D -1 SM/REM -> 0 1 }T
T{ -2 S>D -2 SM/REM -> 0 1 }T
T{ 7 S>D 3 SM/REM -> 1 2 }T
T{ 7 S>D -3 SM/REM -> 1 -2 }T
T{ -7 S>D 3 SM/REM -> -1 -2 }T
T{ -7 S>D -3 SM/REM -> -1 2 }T
T{ MAX-INT S>D 1 SM/REM -> 0 MAX-INT }T
T{ MIN-INT S>D 1 SM/REM -> 0 MIN-INT }T
T{ MAX-INT S>D MAX-INT SM/REM -> 0 1 }T
T{ MIN-INT S>D MIN-INT SM/REM -> 0 1 }T
T{ 1S 1 4 SM/REM -> 3 MAX-INT }T
T{ 2 MIN-INT M* 2 SM/REM -> 0 MIN-INT }T
T{ 2 MIN-INT M* MIN-INT SM/REM -> 0 2 }T
T{ 2 MAX-INT M* 2 SM/REM -> 0 MAX-INT }T
T{ 2 MAX-INT M* MAX-INT SM/REM -> 0 2 }T
T{ MIN-INT MIN-INT M* MIN-INT SM/REM -> 0 MIN-INT }T
T{ MIN-INT MAX-INT M* MIN-INT SM/REM -> 0 MAX-INT }T
T{ MIN-INT MAX-INT M* MAX-INT SM/REM -> 0 MIN-INT }T
T{ MAX-INT MAX-INT M* MAX-INT SM/REM -> 0 MAX-INT }T
T{ 0 0 1 UM/MOD -> 0 0 }T
T{ 1 0 1 UM/MOD -> 0 1 }T
T{ 1 0 2 UM/MOD -> 1 0 }T
T{ 3 0 2 UM/MOD -> 1 1 }T
T{ MAX-UINT 2 UM* 2 UM/MOD -> 0 MAX-UINT }T
T{ MAX-UINT 2 UM* MAX-UINT UM/MOD -> 0 2 }T
T{ MAX-UINT MAX-UINT UM* MAX-UINT UM/MOD -> 0 MAX-UINT }T
: IFFLOORED
[ -3 2 / -2 = INVERT ] LITERAL IF POSTPONE \ THEN ;
: IFSYM
[ -3 2 / -1 = INVERT ] LITERAL IF POSTPONE \ THEN ;
\ THE SYSTEM MIGHT DO EITHER FLOORED OR SYMMETRIC DIVISION.
\ SINCE WE HAVE ALREADY TESTED M*, FM/MOD, AND SM/REM WE CAN USE THEM IN TEST.
IFFLOORED : T/MOD >R S>D R> FM/MOD ;
IFFLOORED : T/ T/MOD SWAP DROP ;
IFFLOORED : TMOD T/MOD DROP ;
IFFLOORED : T*/MOD >R M* R> FM/MOD ;
IFFLOORED : T*/ T*/MOD SWAP DROP ;
IFSYM : T/MOD >R S>D R> SM/REM ;
IFSYM : T/ T/MOD SWAP DROP ;
IFSYM : TMOD T/MOD DROP ;
IFSYM : T*/MOD >R M* R> SM/REM ;
IFSYM : T*/ T*/MOD SWAP DROP ;
T{ 0 1 /MOD -> 0 1 T/MOD }T
T{ 1 1 /MOD -> 1 1 T/MOD }T
T{ 2 1 /MOD -> 2 1 T/MOD }T
T{ -1 1 /MOD -> -1 1 T/MOD }T
T{ -2 1 /MOD -> -2 1 T/MOD }T
T{ 0 -1 /MOD -> 0 -1 T/MOD }T
T{ 1 -1 /MOD -> 1 -1 T/MOD }T
T{ 2 -1 /MOD -> 2 -1 T/MOD }T
T{ -1 -1 /MOD -> -1 -1 T/MOD }T
T{ -2 -1 /MOD -> -2 -1 T/MOD }T
T{ 2 2 /MOD -> 2 2 T/MOD }T
T{ -1 -1 /MOD -> -1 -1 T/MOD }T
T{ -2 -2 /MOD -> -2 -2 T/MOD }T
T{ 7 3 /MOD -> 7 3 T/MOD }T
T{ 7 -3 /MOD -> 7 -3 T/MOD }T
T{ -7 3 /MOD -> -7 3 T/MOD }T
T{ -7 -3 /MOD -> -7 -3 T/MOD }T
T{ MAX-INT 1 /MOD -> MAX-INT 1 T/MOD }T
T{ MIN-INT 1 /MOD -> MIN-INT 1 T/MOD }T
T{ MAX-INT MAX-INT /MOD -> MAX-INT MAX-INT T/MOD }T
T{ MIN-INT MIN-INT /MOD -> MIN-INT MIN-INT T/MOD }T
T{ 0 1 / -> 0 1 T/ }T
T{ 1 1 / -> 1 1 T/ }T
T{ 2 1 / -> 2 1 T/ }T
T{ -1 1 / -> -1 1 T/ }T
T{ -2 1 / -> -2 1 T/ }T
T{ 0 -1 / -> 0 -1 T/ }T
T{ 1 -1 / -> 1 -1 T/ }T
T{ 2 -1 / -> 2 -1 T/ }T
T{ -1 -1 / -> -1 -1 T/ }T
T{ -2 -1 / -> -2 -1 T/ }T
T{ 2 2 / -> 2 2 T/ }T
T{ -1 -1 / -> -1 -1 T/ }T
T{ -2 -2 / -> -2 -2 T/ }T
T{ 7 3 / -> 7 3 T/ }T
T{ 7 -3 / -> 7 -3 T/ }T
T{ -7 3 / -> -7 3 T/ }T
T{ -7 -3 / -> -7 -3 T/ }T
T{ MAX-INT 1 / -> MAX-INT 1 T/ }T
T{ MIN-INT 1 / -> MIN-INT 1 T/ }T
T{ MAX-INT MAX-INT / -> MAX-INT MAX-INT T/ }T
T{ MIN-INT MIN-INT / -> MIN-INT MIN-INT T/ }T
T{ 0 1 MOD -> 0 1 TMOD }T
T{ 1 1 MOD -> 1 1 TMOD }T
T{ 2 1 MOD -> 2 1 TMOD }T
T{ -1 1 MOD -> -1 1 TMOD }T
T{ -2 1 MOD -> -2 1 TMOD }T
T{ 0 -1 MOD -> 0 -1 TMOD }T
T{ 1 -1 MOD -> 1 -1 TMOD }T
T{ 2 -1 MOD -> 2 -1 TMOD }T
T{ -1 -1 MOD -> -1 -1 TMOD }T
T{ -2 -1 MOD -> -2 -1 TMOD }T
T{ 2 2 MOD -> 2 2 TMOD }T
T{ -1 -1 MOD -> -1 -1 TMOD }T
T{ -2 -2 MOD -> -2 -2 TMOD }T
T{ 7 3 MOD -> 7 3 TMOD }T
T{ 7 -3 MOD -> 7 -3 TMOD }T
T{ -7 3 MOD -> -7 3 TMOD }T
T{ -7 -3 MOD -> -7 -3 TMOD }T
T{ MAX-INT 1 MOD -> MAX-INT 1 TMOD }T
T{ MIN-INT 1 MOD -> MIN-INT 1 TMOD }T
T{ MAX-INT MAX-INT MOD -> MAX-INT MAX-INT TMOD }T
T{ MIN-INT MIN-INT MOD -> MIN-INT MIN-INT TMOD }T
T{ 0 2 1 */ -> 0 2 1 T*/ }T
T{ 1 2 1 */ -> 1 2 1 T*/ }T
T{ 2 2 1 */ -> 2 2 1 T*/ }T
T{ -1 2 1 */ -> -1 2 1 T*/ }T
T{ -2 2 1 */ -> -2 2 1 T*/ }T
T{ 0 2 -1 */ -> 0 2 -1 T*/ }T
T{ 1 2 -1 */ -> 1 2 -1 T*/ }T
T{ 2 2 -1 */ -> 2 2 -1 T*/ }T
T{ -1 2 -1 */ -> -1 2 -1 T*/ }T
T{ -2 2 -1 */ -> -2 2 -1 T*/ }T
T{ 2 2 2 */ -> 2 2 2 T*/ }T
T{ -1 2 -1 */ -> -1 2 -1 T*/ }T
T{ -2 2 -2 */ -> -2 2 -2 T*/ }T
T{ 7 2 3 */ -> 7 2 3 T*/ }T
T{ 7 2 -3 */ -> 7 2 -3 T*/ }T
T{ -7 2 3 */ -> -7 2 3 T*/ }T
T{ -7 2 -3 */ -> -7 2 -3 T*/ }T
T{ MAX-INT 2 MAX-INT */ -> MAX-INT 2 MAX-INT T*/ }T
T{ MIN-INT 2 MIN-INT */ -> MIN-INT 2 MIN-INT T*/ }T
T{ 0 2 1 */MOD -> 0 2 1 T*/MOD }T
T{ 1 2 1 */MOD -> 1 2 1 T*/MOD }T
T{ 2 2 1 */MOD -> 2 2 1 T*/MOD }T
T{ -1 2 1 */MOD -> -1 2 1 T*/MOD }T
T{ -2 2 1 */MOD -> -2 2 1 T*/MOD }T
T{ 0 2 -1 */MOD -> 0 2 -1 T*/MOD }T
T{ 1 2 -1 */MOD -> 1 2 -1 T*/MOD }T
T{ 2 2 -1 */MOD -> 2 2 -1 T*/MOD }T
T{ -1 2 -1 */MOD -> -1 2 -1 T*/MOD }T
T{ -2 2 -1 */MOD -> -2 2 -1 T*/MOD }T
T{ 2 2 2 */MOD -> 2 2 2 T*/MOD }T
T{ -1 2 -1 */MOD -> -1 2 -1 T*/MOD }T
T{ -2 2 -2 */MOD -> -2 2 -2 T*/MOD }T
T{ 7 2 3 */MOD -> 7 2 3 T*/MOD }T
T{ 7 2 -3 */MOD -> 7 2 -3 T*/MOD }T
T{ -7 2 3 */MOD -> -7 2 3 T*/MOD }T
T{ -7 2 -3 */MOD -> -7 2 -3 T*/MOD }T
T{ MAX-INT 2 MAX-INT */MOD -> MAX-INT 2 MAX-INT T*/MOD }T
T{ MIN-INT 2 MIN-INT */MOD -> MIN-INT 2 MIN-INT T*/MOD }T
\ ------------------------------------------------------------------------
TESTING HERE , @ ! CELL+ CELLS C, C@ C! CHARS 2@ 2! ALIGN ALIGNED +! ALLOT
HERE 1 ALLOT
HERE
CONSTANT 2NDA
CONSTANT 1STA
T{ 1STA 2NDA U< -> <TRUE> }T \ HERE MUST GROW WITH ALLOT
T{ 1STA 1+ -> 2NDA }T \ ... BY ONE ADDRESS UNIT
( MISSING TEST: NEGATIVE ALLOT )
\ Added by GWJ so that ALIGN can be used before , (comma) is tested
1 ALIGNED CONSTANT ALMNT \ -- 1|2|4|8 for 8|16|32|64 bit alignment
ALIGN
T{ HERE 1 ALLOT ALIGN HERE SWAP - ALMNT = -> <TRUE> }T
\ End of extra test
HERE 1 ,
HERE 2 ,
CONSTANT 2ND
CONSTANT 1ST
T{ 1ST 2ND U< -> <TRUE> }T \ HERE MUST GROW WITH ALLOT
T{ 1ST CELL+ -> 2ND }T \ ... BY ONE CELL
T{ 1ST 1 CELLS + -> 2ND }T
T{ 1ST @ 2ND @ -> 1 2 }T
T{ 5 1ST ! -> }T
T{ 1ST @ 2ND @ -> 5 2 }T
T{ 6 2ND ! -> }T
T{ 1ST @ 2ND @ -> 5 6 }T
T{ 1ST 2@ -> 6 5 }T
T{ 2 1 1ST 2! -> }T
T{ 1ST 2@ -> 2 1 }T
T{ 1S 1ST ! 1ST @ -> 1S }T \ CAN STORE CELL-WIDE VALUE
HERE 1 C,
HERE 2 C,
CONSTANT 2NDC
CONSTANT 1STC
T{ 1STC 2NDC U< -> <TRUE> }T \ HERE MUST GROW WITH ALLOT
T{ 1STC CHAR+ -> 2NDC }T \ ... BY ONE CHAR
T{ 1STC 1 CHARS + -> 2NDC }T
T{ 1STC C@ 2NDC C@ -> 1 2 }T
T{ 3 1STC C! -> }T
T{ 1STC C@ 2NDC C@ -> 3 2 }T
T{ 4 2NDC C! -> }T
T{ 1STC C@ 2NDC C@ -> 3 4 }T
ALIGN 1 ALLOT HERE ALIGN HERE 3 CELLS ALLOT
CONSTANT A-ADDR CONSTANT UA-ADDR
T{ UA-ADDR ALIGNED -> A-ADDR }T
T{ 1 A-ADDR C! A-ADDR C@ -> 1 }T
T{ 1234 A-ADDR ! A-ADDR @ -> 1234 }T
T{ 123 456 A-ADDR 2! A-ADDR 2@ -> 123 456 }T
T{ 2 A-ADDR CHAR+ C! A-ADDR CHAR+ C@ -> 2 }T
T{ 3 A-ADDR CELL+ C! A-ADDR CELL+ C@ -> 3 }T
T{ 1234 A-ADDR CELL+ ! A-ADDR CELL+ @ -> 1234 }T
T{ 123 456 A-ADDR CELL+ 2! A-ADDR CELL+ 2@ -> 123 456 }T
: BITS ( X -- U )
0 SWAP BEGIN DUP WHILE DUP MSB AND IF >R 1+ R> THEN 2* REPEAT DROP ;
( CHARACTERS >= 1 AU, <= SIZE OF CELL, >= 8 BITS )
T{ 1 CHARS 1 < -> <FALSE> }T
T{ 1 CHARS 1 CELLS > -> <FALSE> }T
( TBD: HOW TO FIND NUMBER OF BITS? )
( CELLS >= 1 AU, INTEGRAL MULTIPLE OF CHAR SIZE, >= 16 BITS )
T{ 1 CELLS 1 < -> <FALSE> }T
T{ 1 CELLS 1 CHARS MOD -> 0 }T
T{ 1S BITS 10 < -> <FALSE> }T
T{ 0 1ST ! -> }T
T{ 1 1ST +! -> }T
T{ 1ST @ -> 1 }T
T{ -1 1ST +! 1ST @ -> 0 }T
\ ------------------------------------------------------------------------
TESTING CHAR [CHAR] [ ] BL S"
T{ BL -> 20 }T
T{ CHAR X -> 58 }T
T{ CHAR HELLO -> 48 }T
T{ : GC1 [CHAR] X ; -> }T
T{ : GC2 [CHAR] HELLO ; -> }T
T{ GC1 -> 58 }T
T{ GC2 -> 48 }T
T{ : GC3 [ GC1 ] LITERAL ; -> }T
T{ GC3 -> 58 }T
T{ : GC4 S" XY" ; -> }T
T{ GC4 SWAP DROP -> 2 }T
T{ GC4 DROP DUP C@ SWAP CHAR+ C@ -> 58 59 }T
\ ------------------------------------------------------------------------
TESTING ' ['] FIND EXECUTE IMMEDIATE COUNT LITERAL POSTPONE STATE
T{ : GT1 123 ; -> }T
T{ ' GT1 EXECUTE -> 123 }T
T{ : GT2 ['] GT1 ; IMMEDIATE -> }T
T{ GT2 EXECUTE -> 123 }T
HERE 3 C, CHAR G C, CHAR T C, CHAR 1 C, CONSTANT GT1STRING
HERE 3 C, CHAR G C, CHAR T C, CHAR 2 C, CONSTANT GT2STRING
T{ GT1STRING FIND -> ' GT1 -1 }T
T{ GT2STRING FIND -> ' GT2 1 }T
( HOW TO SEARCH FOR NON-EXISTENT WORD? )
T{ : GT3 GT2 LITERAL ; -> }T
T{ GT3 -> ' GT1 }T
T{ GT1STRING COUNT -> GT1STRING CHAR+ 3 }T
T{ : GT4 POSTPONE GT1 ; IMMEDIATE -> }T
T{ : GT5 GT4 ; -> }T
T{ GT5 -> 123 }T
T{ : GT6 345 ; IMMEDIATE -> }T
T{ : GT7 POSTPONE GT6 ; -> }T
T{ GT7 -> 345 }T
T{ : GT8 STATE @ ; IMMEDIATE -> }T
T{ GT8 -> 0 }T
T{ : GT9 GT8 LITERAL ; -> }T
T{ GT9 0= -> <FALSE> }T
\ ------------------------------------------------------------------------
TESTING IF ELSE THEN BEGIN WHILE REPEAT UNTIL RECURSE
T{ : GI1 IF 123 THEN ; -> }T
T{ : GI2 IF 123 ELSE 234 THEN ; -> }T
T{ 0 GI1 -> }T
T{ 1 GI1 -> 123 }T
T{ -1 GI1 -> 123 }T
T{ 0 GI2 -> 234 }T
T{ 1 GI2 -> 123 }T
T{ -1 GI1 -> 123 }T
T{ : GI3 BEGIN DUP 5 < WHILE DUP 1+ REPEAT ; -> }T
T{ 0 GI3 -> 0 1 2 3 4 5 }T
T{ 4 GI3 -> 4 5 }T
T{ 5 GI3 -> 5 }T
T{ 6 GI3 -> 6 }T
T{ : GI4 BEGIN DUP 1+ DUP 5 > UNTIL ; -> }T
T{ 3 GI4 -> 3 4 5 6 }T
T{ 5 GI4 -> 5 6 }T
T{ 6 GI4 -> 6 7 }T
T{ : GI5 BEGIN DUP 2 >
WHILE DUP 5 < WHILE DUP 1+ REPEAT 123 ELSE 345 THEN ; -> }T
T{ 1 GI5 -> 1 345 }T
T{ 2 GI5 -> 2 345 }T
T{ 3 GI5 -> 3 4 5 123 }T
T{ 4 GI5 -> 4 5 123 }T
T{ 5 GI5 -> 5 123 }T
T{ : GI6 ( N -- 0,1,..N ) DUP IF DUP >R 1- RECURSE R> THEN ; -> }T
T{ 0 GI6 -> 0 }T
T{ 1 GI6 -> 0 1 }T
T{ 2 GI6 -> 0 1 2 }T
T{ 3 GI6 -> 0 1 2 3 }T
T{ 4 GI6 -> 0 1 2 3 4 }T
\ ------------------------------------------------------------------------
TESTING DO LOOP +LOOP I J UNLOOP LEAVE EXIT
T{ : GD1 DO I LOOP ; -> }T
T{ 4 1 GD1 -> 1 2 3 }T
T{ 2 -1 GD1 -> -1 0 1 }T
T{ MID-UINT+1 MID-UINT GD1 -> MID-UINT }T
T{ : GD2 DO I -1 +LOOP ; -> }T
T{ 1 4 GD2 -> 4 3 2 1 }T
T{ -1 2 GD2 -> 2 1 0 -1 }T
T{ MID-UINT MID-UINT+1 GD2 -> MID-UINT+1 MID-UINT }T
T{ : GD3 DO 1 0 DO J LOOP LOOP ; -> }T
T{ 4 1 GD3 -> 1 2 3 }T
T{ 2 -1 GD3 -> -1 0 1 }T
T{ MID-UINT+1 MID-UINT GD3 -> MID-UINT }T
T{ : GD4 DO 1 0 DO J LOOP -1 +LOOP ; -> }T
T{ 1 4 GD4 -> 4 3 2 1 }T
T{ -1 2 GD4 -> 2 1 0 -1 }T
T{ MID-UINT MID-UINT+1 GD4 -> MID-UINT+1 MID-UINT }T
T{ : GD5 123 SWAP 0 DO I 4 > IF DROP 234 LEAVE THEN LOOP ; -> }T
T{ 1 GD5 -> 123 }T
T{ 5 GD5 -> 123 }T
T{ 6 GD5 -> 234 }T
T{ : GD6 ( PAT: T{0 0},{0 0}{1 0}{1 1},{0 0}{1 0}{1 1}{2 0}{2 1}{2 2} )
0 SWAP 0 DO
I 1+ 0 DO I J + 3 = IF I UNLOOP I UNLOOP EXIT THEN 1+ LOOP
LOOP ; -> }T
T{ 1 GD6 -> 1 }T
T{ 2 GD6 -> 3 }T
T{ 3 GD6 -> 4 1 2 }T
\ ------------------------------------------------------------------------
TESTING DEFINING WORDS: : ; CONSTANT VARIABLE CREATE DOES> >BODY
T{ 123 CONSTANT X123 -> }T
T{ X123 -> 123 }T
T{ : EQU CONSTANT ; -> }T
T{ X123 EQU Y123 -> }T
T{ Y123 -> 123 }T
T{ VARIABLE V1 -> }T
T{ 123 V1 ! -> }T
T{ V1 @ -> 123 }T
T{ : NOP : POSTPONE ; ; -> }T
T{ NOP NOP1 NOP NOP2 -> }T
T{ NOP1 -> }T
T{ NOP2 -> }T
T{ : DOES1 DOES> @ 1 + ; -> }T
T{ : DOES2 DOES> @ 2 + ; -> }T
T{ CREATE CR1 -> }T
T{ CR1 -> HERE }T
T{ ' CR1 >BODY -> HERE }T
T{ 1 , -> }T
T{ CR1 @ -> 1 }T
T{ DOES1 -> }T
T{ CR1 -> 2 }T
T{ DOES2 -> }T
T{ CR1 -> 3 }T
T{ : WEIRD: CREATE DOES> 1 + DOES> 2 + ; -> }T
T{ WEIRD: W1 -> }T
T{ ' W1 >BODY -> HERE }T
T{ W1 -> HERE 1 + }T
T{ W1 -> HERE 2 + }T
0 [if] \ TODO
\ ------------------------------------------------------------------------
TESTING EVALUATE
: GE1 S" 123" ; IMMEDIATE
: GE2 S" 123 1+" ; IMMEDIATE
: GE3 S" : GE4 345 ;" ;
: GE5 EVALUATE ; IMMEDIATE
T{ GE1 EVALUATE -> 123 }T ( TEST EVALUATE IN INTERP. STATE )
T{ GE2 EVALUATE -> 124 }T
T{ GE3 EVALUATE -> }T
T{ GE4 -> 345 }T
T{ : GE6 GE1 GE5 ; -> }T ( TEST EVALUATE IN COMPILE STATE )
T{ GE6 -> 123 }T
T{ : GE7 GE2 GE5 ; -> }T
T{ GE7 -> 124 }T
\ ------------------------------------------------------------------------
TESTING SOURCE >IN WORD
: GS1 S" SOURCE" 2DUP EVALUATE
>R SWAP >R = R> R> = ;
T{ GS1 -> <TRUE> <TRUE> }T
VARIABLE SCANS
: RESCAN? -1 SCANS +! SCANS @ IF 0 >IN ! THEN ;
T{ 2 SCANS !
345 RESCAN?
-> 345 345 }T
: GS2 5 SCANS ! S" 123 RESCAN?" EVALUATE ;
T{ GS2 -> 123 123 123 123 123 }T
: GS3 WORD COUNT SWAP C@ ;
T{ BL GS3 HELLO -> 5 CHAR H }T
T{ CHAR " GS3 GOODBYE" -> 7 CHAR G }T
T{ BL GS3
DROP -> 0 }T \ BLANK LINE RETURN ZERO-LENGTH STRING
: GS4 SOURCE >IN ! DROP ;
T{ GS4 123 456
-> }T
[then]
\ ------------------------------------------------------------------------
TESTING <# # #S #> HOLD SIGN BASE >NUMBER HEX DECIMAL
: S= \ ( ADDR1 C1 ADDR2 C2 -- T/F ) COMPARE TWO STRINGS.
>R SWAP R@ = IF \ MAKE SURE STRINGS HAVE SAME LENGTH
R> ?DUP IF \ IF NON-EMPTY STRINGS
0 DO
OVER C@ OVER C@ - IF 2DROP <FALSE> UNLOOP EXIT THEN
SWAP CHAR+ SWAP CHAR+
LOOP
THEN
2DROP <TRUE> \ IF WE GET HERE, STRINGS MATCH
ELSE
R> DROP 2DROP <FALSE> \ LENGTHS MISMATCH
THEN ;
: GP1 <# 41 HOLD 42 HOLD 0 0 #> S" BA" S= ;
T{ GP1 -> <TRUE> }T
: GP2 <# -1 SIGN 0 SIGN -1 SIGN 0 0 #> S" --" S= ;
T{ GP2 -> <TRUE> }T
: GP3 <# 1 0 # # #> S" 01" S= ;
T{ GP3 -> <TRUE> }T
: GP4 <# 1 0 #S #> S" 1" S= ;
T{ GP4 -> <TRUE> }T
24 CONSTANT MAX-BASE \ BASE 2 .. 36
: COUNT-BITS
0 0 INVERT BEGIN DUP WHILE >R 1+ R> 2* REPEAT DROP ;
COUNT-BITS 2* CONSTANT #BITS-UD \ NUMBER OF BITS IN UD
: GP5
BASE @ <TRUE>
MAX-BASE 1+ 2 DO \ FOR EACH POSSIBLE BASE
I BASE ! \ TBD: ASSUMES BASE WORKS
I 0 <# #S #> S" 10" S= AND
LOOP
SWAP BASE ! ;
T{ GP5 -> <TRUE> }T
: GP6
BASE @ >R 2 BASE !
MAX-UINT MAX-UINT <# #S #> \ MAXIMUM UD TO BINARY
R> BASE ! \ S: C-ADDR U
DUP #BITS-UD = SWAP
0 DO \ S: C-ADDR FLAG
OVER C@ [CHAR] 1 = AND \ ALL ONES
>R CHAR+ R>
LOOP SWAP DROP ;
T{ GP6 -> <TRUE> }T
: GP7
BASE @ >R MAX-BASE BASE !
<TRUE>
A 0 DO
I 0 <# #S #>
1 = SWAP C@ I 30 + = AND AND
LOOP
MAX-BASE A DO
I 0 <# #S #>
1 = SWAP C@ 41 I A - + = AND AND
LOOP
R> BASE ! ;
T{ GP7 -> <TRUE> }T
\ >NUMBER TESTS
CREATE GN-BUF 0 C,
: GN-STRING GN-BUF 1 ;
: GN-CONSUMED GN-BUF CHAR+ 0 ;
: GN' [CHAR] ' WORD CHAR+ C@ GN-BUF C! GN-STRING ;
T{ 0 0 GN' 0' >NUMBER -> 0 0 GN-CONSUMED }T
T{ 0 0 GN' 1' >NUMBER -> 1 0 GN-CONSUMED }T
T{ 1 0 GN' 1' >NUMBER -> BASE @ 1+ 0 GN-CONSUMED }T
T{ 0 0 GN' -' >NUMBER -> 0 0 GN-STRING }T \ SHOULD FAIL TO CONVERT THESE
T{ 0 0 GN' +' >NUMBER -> 0 0 GN-STRING }T
T{ 0 0 GN' .' >NUMBER -> 0 0 GN-STRING }T
: >NUMBER-BASED
BASE @ >R BASE ! >NUMBER R> BASE ! ;
T{ 0 0 GN' 2' 10 >NUMBER-BASED -> 2 0 GN-CONSUMED }T
T{ 0 0 GN' 2' 2 >NUMBER-BASED -> 0 0 GN-STRING }T
T{ 0 0 GN' F' 10 >NUMBER-BASED -> F 0 GN-CONSUMED }T
T{ 0 0 GN' G' 10 >NUMBER-BASED -> 0 0 GN-STRING }T
T{ 0 0 GN' G' MAX-BASE >NUMBER-BASED -> 10 0 GN-CONSUMED }T
T{ 0 0 GN' Z' MAX-BASE >NUMBER-BASED -> 23 0 GN-CONSUMED }T
: GN1 \ ( UD BASE -- UD' LEN ) UD SHOULD EQUAL UD' AND LEN SHOULD BE ZERO.
BASE @ >R BASE !
<# #S #>
0 0 2SWAP >NUMBER SWAP DROP \ RETURN LENGTH ONLY
R> BASE ! ;
T{ 0 0 2 GN1 -> 0 0 0 }T
T{ MAX-UINT 0 2 GN1 -> MAX-UINT 0 0 }T
T{ MAX-UINT DUP 2 GN1 -> MAX-UINT DUP 0 }T
T{ 0 0 MAX-BASE GN1 -> 0 0 0 }T
T{ MAX-UINT 0 MAX-BASE GN1 -> MAX-UINT 0 0 }T
T{ MAX-UINT DUP MAX-BASE GN1 -> MAX-UINT DUP 0 }T
: GN2 \ ( -- 16 10 )
BASE @ >R HEX BASE @ DECIMAL BASE @ R> BASE ! ;
T{ GN2 -> 10 A }T
\ ------------------------------------------------------------------------
TESTING FILL MOVE
CREATE FBUF 00 C, 00 C, 00 C,
CREATE SBUF 12 C, 34 C, 56 C,
: SEEBUF FBUF C@ FBUF CHAR+ C@ FBUF CHAR+ CHAR+ C@ ;
T{ FBUF 0 20 FILL -> }T
T{ SEEBUF -> 00 00 00 }T
T{ FBUF 1 20 FILL -> }T
T{ SEEBUF -> 20 00 00 }T
T{ FBUF 3 20 FILL -> }T
T{ SEEBUF -> 20 20 20 }T
T{ FBUF FBUF 3 CHARS MOVE -> }T \ BIZARRE SPECIAL CASE
T{ SEEBUF -> 20 20 20 }T
T{ SBUF FBUF 0 CHARS MOVE -> }T
T{ SEEBUF -> 20 20 20 }T
T{ SBUF FBUF 1 CHARS MOVE -> }T
T{ SEEBUF -> 12 20 20 }T
T{ SBUF FBUF 3 CHARS MOVE -> }T
T{ SEEBUF -> 12 34 56 }T
T{ FBUF FBUF CHAR+ 2 CHARS MOVE -> }T
T{ SEEBUF -> 12 12 34 }T
T{ FBUF CHAR+ FBUF 2 CHARS MOVE -> }T
T{ SEEBUF -> 12 34 34 }T
\ ------------------------------------------------------------------------
TESTING OUTPUT: . ." CR EMIT SPACE SPACES TYPE U.
: OUTPUT-TEST
." YOU SHOULD SEE THE STANDARD GRAPHIC CHARACTERS:" CR
41 BL DO I EMIT LOOP CR
61 41 DO I EMIT LOOP CR
7F 61 DO I EMIT LOOP CR
." YOU SHOULD SEE 0-9 SEPARATED BY A SPACE:" CR
9 1+ 0 DO I . LOOP CR
." YOU SHOULD SEE 0-9 (WITH NO SPACES):" CR
[CHAR] 9 1+ [CHAR] 0 DO I 0 SPACES EMIT LOOP CR
." YOU SHOULD SEE A-G SEPARATED BY A SPACE:" CR
[CHAR] G 1+ [CHAR] A DO I EMIT SPACE LOOP CR
." YOU SHOULD SEE 0-5 SEPARATED BY TWO SPACES:" CR
5 1+ 0 DO I [CHAR] 0 + EMIT 2 SPACES LOOP CR
." YOU SHOULD SEE TWO SEPARATE LINES:" CR
S" LINE 1" TYPE CR S" LINE 2" TYPE CR
." YOU SHOULD SEE THE NUMBER RANGES OF SIGNED AND UNSIGNED NUMBERS:" CR
." SIGNED: " MIN-INT . MAX-INT . CR
." UNSIGNED: " 0 U. MAX-UINT U. CR
;
T{ OUTPUT-TEST -> }T
\ ------------------------------------------------------------------------
TESTING INPUT: ACCEPT
CREATE ABUF 50 CHARS ALLOT
: ACCEPT-TEST
CR ." PLEASE TYPE UP TO 80 CHARACTERS:" CR
ABUF 50 ACCEPT
CR ." RECEIVED: " [CHAR] " EMIT
ABUF SWAP TYPE [CHAR] " EMIT CR
;
T{ ACCEPT-TEST -> }T
\ ------------------------------------------------------------------------
TESTING DICTIONARY SEARCH RULES
T{ : GDX 123 ; : GDX GDX 234 ; -> }T
T{ GDX -> 123 234 }T
CR .( End of Core word set tests) CR
\ To test the ANS Forth Core Extension word set
\ This program was written by Gerry Jackson in 2006, with contributions from
\ others where indicated, and is in the public domain - it can be distributed
\ and/or modified in any way but please retain this notice.
\ This program is distributed in the hope that it will be useful,
\ but WITHOUT ANY WARRANTY; without even the implied warranty of
\ MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
\ The tests are not claimed to be comprehensive or correct
\ ------------------------------------------------------------------------------
\ Version 0.13 28 October 2015
\ Replace <FALSE> and <TRUE> with FALSE and TRUE to avoid
\ dependence on Core tests
\ Moved SAVE-INPUT and RESTORE-INPUT tests in a file to filetest.fth
\ Use of 2VARIABLE (from optional wordset) replaced with CREATE.
\ Minor lower to upper case conversions.
\ Calls to COMPARE replaced by S= (in utilities.fth) to avoid use
\ of a word from an optional word set.
\ UNUSED tests revised as UNUSED UNUSED = may return FALSE when an
\ implementation has the data stack sharing unused dataspace.
\ Double number input dependency removed from the HOLDS tests.
\ Minor case sensitivities removed in definition names.
\ 0.11 25 April 2015
\ Added tests for PARSE-NAME HOLDS BUFFER:
\ S\" tests added
\ DEFER IS ACTION-OF DEFER! DEFER@ tests added
\ Empty CASE statement test added
\ [COMPILE] tests removed because it is obsolescent in Forth 2012
\ 0.10 1 August 2014
\ Added tests contributed by James Bowman for:
\ <> U> 0<> 0> NIP TUCK ROLL PICK 2>R 2R@ 2R>
\ HEX WITHIN UNUSED AGAIN MARKER
\ Added tests for:
\ .R U.R ERASE PAD REFILL SOURCE-ID
\ Removed ABORT from NeverExecuted to enable Win32
\ to continue after failure of RESTORE-INPUT.
\ Removed max-intx which is no longer used.
\ 0.7 6 June 2012 Extra CASE test added
\ 0.6 1 April 2012 Tests placed in the public domain.
\ SAVE-INPUT & RESTORE-INPUT tests, position
\ of T{ moved so that tests work with ttester.fs
\ CONVERT test deleted - obsolete word removed from Forth 200X
\ IMMEDIATE VALUEs tested
\ RECURSE with :NONAME tested
\ PARSE and .( tested
\ Parsing behaviour of C" added
\ 0.5 14 September 2011 Removed the double [ELSE] from the
\ initial SAVE-INPUT & RESTORE-INPUT test
\ 0.4 30 November 2009 max-int replaced with max-intx to
\ avoid redefinition warnings.
\ 0.3 6 March 2009 { and } replaced with T{ and }T
\ CONVERT test now independent of cell size
\ 0.2 20 April 2007 ANS Forth words changed to upper case
\ Tests qd3 to qd6 by Reinhold Straub
\ 0.1 Oct 2006 First version released
\ -----------------------------------------------------------------------------
\ The tests are based on John Hayes test program for the core word set
\ Words tested in this file are:
\ .( .R 0<> 0> 2>R 2R> 2R@ :NONAME <> ?DO AGAIN C" CASE COMPILE, ENDCASE
\ ENDOF ERASE FALSE HEX MARKER NIP OF PAD PARSE PICK REFILL
\ RESTORE-INPUT ROLL SAVE-INPUT SOURCE-ID TO TRUE TUCK U.R U> UNUSED
\ VALUE WITHIN [COMPILE]
\ Words not tested or partially tested:
\ \ because it has been extensively used already and is, hence, unnecessary
\ REFILL and SOURCE-ID from the user input device which are not possible
\ when testing from a file such as this one
\ UNUSED (partially tested) as the value returned is system dependent
\ Obsolescent words #TIB CONVERT EXPECT QUERY SPAN TIB as they have been
\ removed from the Forth 2012 standard
\ Results from words that output to the user output device have to visually
\ checked for correctness. These are .R U.R .(
\ -----------------------------------------------------------------------------
\ Assumptions & dependencies:
\ - tester.fr (or ttester.fs), errorreport.fth and utilities.fth have been
\ included prior to this file
\ - the Core word set available
\ -----------------------------------------------------------------------------
TESTING Core Extension words
DECIMAL
TESTING TRUE FALSE
T{ TRUE -> 0 INVERT }T
T{ FALSE -> 0 }T
\ -----------------------------------------------------------------------------
TESTING <> U> (contributed by James Bowman)
T{ 0 0 <> -> FALSE }T
T{ 1 1 <> -> FALSE }T
T{ -1 -1 <> -> FALSE }T
T{ 1 0 <> -> TRUE }T
T{ -1 0 <> -> TRUE }T
T{ 0 1 <> -> TRUE }T
T{ 0 -1 <> -> TRUE }T
T{ 0 1 U> -> FALSE }T
T{ 1 2 U> -> FALSE }T
T{ 0 MID-UINT U> -> FALSE }T
T{ 0 MAX-UINT U> -> FALSE }T
T{ MID-UINT MAX-UINT U> -> FALSE }T
T{ 0 0 U> -> FALSE }T
T{ 1 1 U> -> FALSE }T
T{ 1 0 U> -> TRUE }T
T{ 2 1 U> -> TRUE }T
T{ MID-UINT 0 U> -> TRUE }T
T{ MAX-UINT 0 U> -> TRUE }T
T{ MAX-UINT MID-UINT U> -> TRUE }T
\ -----------------------------------------------------------------------------
TESTING 0<> 0> (contributed by James Bowman)
T{ 0 0<> -> FALSE }T
T{ 1 0<> -> TRUE }T
T{ 2 0<> -> TRUE }T
T{ -1 0<> -> TRUE }T
T{ MAX-UINT 0<> -> TRUE }T
T{ MIN-INT 0<> -> TRUE }T
T{ MAX-INT 0<> -> TRUE }T
T{ 0 0> -> FALSE }T
T{ -1 0> -> FALSE }T
T{ MIN-INT 0> -> FALSE }T
T{ 1 0> -> TRUE }T
T{ MAX-INT 0> -> TRUE }T
\ -----------------------------------------------------------------------------
TESTING NIP TUCK ROLL PICK (contributed by James Bowman)
T{ 1 2 NIP -> 2 }T
T{ 1 2 3 NIP -> 1 3 }T
T{ 1 2 TUCK -> 2 1 2 }T
T{ 1 2 3 TUCK -> 1 3 2 3 }T
T{ : RO5 100 200 300 400 500 ; -> }T
T{ RO5 3 ROLL -> 100 300 400 500 200 }T
T{ RO5 2 ROLL -> RO5 ROT }T
T{ RO5 1 ROLL -> RO5 SWAP }T
T{ RO5 0 ROLL -> RO5 }T
T{ RO5 2 PICK -> 100 200 300 400 500 300 }T
T{ RO5 1 PICK -> RO5 OVER }T
T{ RO5 0 PICK -> RO5 DUP }T
\ -----------------------------------------------------------------------------
TESTING 2>R 2R@ 2R> (contributed by James Bowman)
T{ : RR0 2>R 100 R> R> ; -> }T
T{ 300 400 RR0 -> 100 400 300 }T
T{ 200 300 400 RR0 -> 200 100 400 300 }T
T{ : RR1 2>R 100 2R@ R> R> ; -> }T
T{ 300 400 RR1 -> 100 300 400 400 300 }T
T{ 200 300 400 RR1 -> 200 100 300 400 400 300 }T
T{ : RR2 2>R 100 2R> ; -> }T
T{ 300 400 RR2 -> 100 300 400 }T
T{ 200 300 400 RR2 -> 200 100 300 400 }T
\ -----------------------------------------------------------------------------
TESTING HEX (contributed by James Bowman)
T{ BASE @ HEX BASE @ DECIMAL BASE @ - SWAP BASE ! -> 6 }T
\ -----------------------------------------------------------------------------
TESTING WITHIN (contributed by James Bowman)
T{ 0 0 0 WITHIN -> FALSE }T
T{ 0 0 MID-UINT WITHIN -> TRUE }T
T{ 0 0 MID-UINT+1 WITHIN -> TRUE }T
T{ 0 0 MAX-UINT WITHIN -> TRUE }T
T{ 0 MID-UINT 0 WITHIN -> FALSE }T
T{ 0 MID-UINT MID-UINT WITHIN -> FALSE }T
T{ 0 MID-UINT MID-UINT+1 WITHIN -> FALSE }T
T{ 0 MID-UINT MAX-UINT WITHIN -> FALSE }T
T{ 0 MID-UINT+1 0 WITHIN -> FALSE }T
T{ 0 MID-UINT+1 MID-UINT WITHIN -> TRUE }T
T{ 0 MID-UINT+1 MID-UINT+1 WITHIN -> FALSE }T
T{ 0 MID-UINT+1 MAX-UINT WITHIN -> FALSE }T
T{ 0 MAX-UINT 0 WITHIN -> FALSE }T
T{ 0 MAX-UINT MID-UINT WITHIN -> TRUE }T
T{ 0 MAX-UINT MID-UINT+1 WITHIN -> TRUE }T
T{ 0 MAX-UINT MAX-UINT WITHIN -> FALSE }T
T{ MID-UINT 0 0 WITHIN -> FALSE }T
T{ MID-UINT 0 MID-UINT WITHIN -> FALSE }T
T{ MID-UINT 0 MID-UINT+1 WITHIN -> TRUE }T
T{ MID-UINT 0 MAX-UINT WITHIN -> TRUE }T
T{ MID-UINT MID-UINT 0 WITHIN -> TRUE }T
T{ MID-UINT MID-UINT MID-UINT WITHIN -> FALSE }T
T{ MID-UINT MID-UINT MID-UINT+1 WITHIN -> TRUE }T
T{ MID-UINT MID-UINT MAX-UINT WITHIN -> TRUE }T
T{ MID-UINT MID-UINT+1 0 WITHIN -> FALSE }T
T{ MID-UINT MID-UINT+1 MID-UINT WITHIN -> FALSE }T
T{ MID-UINT MID-UINT+1 MID-UINT+1 WITHIN -> FALSE }T
T{ MID-UINT MID-UINT+1 MAX-UINT WITHIN -> FALSE }T
T{ MID-UINT MAX-UINT 0 WITHIN -> FALSE }T
T{ MID-UINT MAX-UINT MID-UINT WITHIN -> FALSE }T
T{ MID-UINT MAX-UINT MID-UINT+1 WITHIN -> TRUE }T
T{ MID-UINT MAX-UINT MAX-UINT WITHIN -> FALSE }T
T{ MID-UINT+1 0 0 WITHIN -> FALSE }T
T{ MID-UINT+1 0 MID-UINT WITHIN -> FALSE }T
T{ MID-UINT+1 0 MID-UINT+1 WITHIN -> FALSE }T
T{ MID-UINT+1 0 MAX-UINT WITHIN -> TRUE }T
T{ MID-UINT+1 MID-UINT 0 WITHIN -> TRUE }T
T{ MID-UINT+1 MID-UINT MID-UINT WITHIN -> FALSE }T
T{ MID-UINT+1 MID-UINT MID-UINT+1 WITHIN -> FALSE }T
T{ MID-UINT+1 MID-UINT MAX-UINT WITHIN -> TRUE }T
T{ MID-UINT+1 MID-UINT+1 0 WITHIN -> TRUE }T
T{ MID-UINT+1 MID-UINT+1 MID-UINT WITHIN -> TRUE }T
T{ MID-UINT+1 MID-UINT+1 MID-UINT+1 WITHIN -> FALSE }T
T{ MID-UINT+1 MID-UINT+1 MAX-UINT WITHIN -> TRUE }T
T{ MID-UINT+1 MAX-UINT 0 WITHIN -> FALSE }T
T{ MID-UINT+1 MAX-UINT MID-UINT WITHIN -> FALSE }T
T{ MID-UINT+1 MAX-UINT MID-UINT+1 WITHIN -> FALSE }T
T{ MID-UINT+1 MAX-UINT MAX-UINT WITHIN -> FALSE }T
T{ MAX-UINT 0 0 WITHIN -> FALSE }T
T{ MAX-UINT 0 MID-UINT WITHIN -> FALSE }T
T{ MAX-UINT 0 MID-UINT+1 WITHIN -> FALSE }T
T{ MAX-UINT 0 MAX-UINT WITHIN -> FALSE }T
T{ MAX-UINT MID-UINT 0 WITHIN -> TRUE }T
T{ MAX-UINT MID-UINT MID-UINT WITHIN -> FALSE }T
T{ MAX-UINT MID-UINT MID-UINT+1 WITHIN -> FALSE }T
T{ MAX-UINT MID-UINT MAX-UINT WITHIN -> FALSE }T
T{ MAX-UINT MID-UINT+1 0 WITHIN -> TRUE }T
T{ MAX-UINT MID-UINT+1 MID-UINT WITHIN -> TRUE }T
T{ MAX-UINT MID-UINT+1 MID-UINT+1 WITHIN -> FALSE }T
T{ MAX-UINT MID-UINT+1 MAX-UINT WITHIN -> FALSE }T
T{ MAX-UINT MAX-UINT 0 WITHIN -> TRUE }T
T{ MAX-UINT MAX-UINT MID-UINT WITHIN -> TRUE }T
T{ MAX-UINT MAX-UINT MID-UINT+1 WITHIN -> TRUE }T
T{ MAX-UINT MAX-UINT MAX-UINT WITHIN -> FALSE }T
T{ MIN-INT MIN-INT MIN-INT WITHIN -> FALSE }T
T{ MIN-INT MIN-INT 0 WITHIN -> TRUE }T
T{ MIN-INT MIN-INT 1 WITHIN -> TRUE }T
T{ MIN-INT MIN-INT MAX-INT WITHIN -> TRUE }T
T{ MIN-INT 0 MIN-INT WITHIN -> FALSE }T
T{ MIN-INT 0 0 WITHIN -> FALSE }T
T{ MIN-INT 0 1 WITHIN -> FALSE }T
T{ MIN-INT 0 MAX-INT WITHIN -> FALSE }T
T{ MIN-INT 1 MIN-INT WITHIN -> FALSE }T
T{ MIN-INT 1 0 WITHIN -> TRUE }T
T{ MIN-INT 1 1 WITHIN -> FALSE }T
T{ MIN-INT 1 MAX-INT WITHIN -> FALSE }T
T{ MIN-INT MAX-INT MIN-INT WITHIN -> FALSE }T
T{ MIN-INT MAX-INT 0 WITHIN -> TRUE }T
T{ MIN-INT MAX-INT 1 WITHIN -> TRUE }T
T{ MIN-INT MAX-INT MAX-INT WITHIN -> FALSE }T
T{ 0 MIN-INT MIN-INT WITHIN -> FALSE }T
T{ 0 MIN-INT 0 WITHIN -> FALSE }T
T{ 0 MIN-INT 1 WITHIN -> TRUE }T
T{ 0 MIN-INT MAX-INT WITHIN -> TRUE }T
T{ 0 0 MIN-INT WITHIN -> TRUE }T
T{ 0 0 0 WITHIN -> FALSE }T
T{ 0 0 1 WITHIN -> TRUE }T
T{ 0 0 MAX-INT WITHIN -> TRUE }T
T{ 0 1 MIN-INT WITHIN -> FALSE }T
T{ 0 1 0 WITHIN -> FALSE }T
T{ 0 1 1 WITHIN -> FALSE }T
T{ 0 1 MAX-INT WITHIN -> FALSE }T
T{ 0 MAX-INT MIN-INT WITHIN -> FALSE }T
T{ 0 MAX-INT 0 WITHIN -> FALSE }T
T{ 0 MAX-INT 1 WITHIN -> TRUE }T
T{ 0 MAX-INT MAX-INT WITHIN -> FALSE }T
T{ 1 MIN-INT MIN-INT WITHIN -> FALSE }T
T{ 1 MIN-INT 0 WITHIN -> FALSE }T
T{ 1 MIN-INT 1 WITHIN -> FALSE }T
T{ 1 MIN-INT MAX-INT WITHIN -> TRUE }T
T{ 1 0 MIN-INT WITHIN -> TRUE }T
T{ 1 0 0 WITHIN -> FALSE }T
T{ 1 0 1 WITHIN -> FALSE }T
T{ 1 0 MAX-INT WITHIN -> TRUE }T
T{ 1 1 MIN-INT WITHIN -> TRUE }T
T{ 1 1 0 WITHIN -> TRUE }T
T{ 1 1 1 WITHIN -> FALSE }T
T{ 1 1 MAX-INT WITHIN -> TRUE }T
T{ 1 MAX-INT MIN-INT WITHIN -> FALSE }T
T{ 1 MAX-INT 0 WITHIN -> FALSE }T
T{ 1 MAX-INT 1 WITHIN -> FALSE }T
T{ 1 MAX-INT MAX-INT WITHIN -> FALSE }T
T{ MAX-INT MIN-INT MIN-INT WITHIN -> FALSE }T
T{ MAX-INT MIN-INT 0 WITHIN -> FALSE }T
T{ MAX-INT MIN-INT 1 WITHIN -> FALSE }T
T{ MAX-INT MIN-INT MAX-INT WITHIN -> FALSE }T
T{ MAX-INT 0 MIN-INT WITHIN -> TRUE }T
T{ MAX-INT 0 0 WITHIN -> FALSE }T
T{ MAX-INT 0 1 WITHIN -> FALSE }T
T{ MAX-INT 0 MAX-INT WITHIN -> FALSE }T
T{ MAX-INT 1 MIN-INT WITHIN -> TRUE }T
T{ MAX-INT 1 0 WITHIN -> TRUE }T
T{ MAX-INT 1 1 WITHIN -> FALSE }T
T{ MAX-INT 1 MAX-INT WITHIN -> FALSE }T
T{ MAX-INT MAX-INT MIN-INT WITHIN -> TRUE }T
T{ MAX-INT MAX-INT 0 WITHIN -> TRUE }T
T{ MAX-INT MAX-INT 1 WITHIN -> TRUE }T
T{ MAX-INT MAX-INT MAX-INT WITHIN -> FALSE }T
\ -----------------------------------------------------------------------------
TESTING UNUSED (contributed by James Bowman & Peter Knaggs)
VARIABLE UNUSED0
T{ UNUSED DROP -> }T
T{ ALIGN UNUSED UNUSED0 ! 0 , UNUSED CELL+ UNUSED0 @ = -> TRUE }T
T{ UNUSED UNUSED0 ! 0 C, UNUSED CHAR+ UNUSED0 @ =
-> TRUE }T \ aligned -> unaligned
T{ UNUSED UNUSED0 ! 0 C, UNUSED CHAR+ UNUSED0 @ = -> TRUE }T \ unaligned -> ?
\ -----------------------------------------------------------------------------
TESTING AGAIN (contributed by James Bowman)
T{ : AG0 701 BEGIN DUP 7 MOD 0= IF EXIT THEN 1+ AGAIN ; -> }T
T{ AG0 -> 707 }T
\ -----------------------------------------------------------------------------
TESTING MARKER (contributed by James Bowman)
T{ : MA? BL WORD FIND NIP 0<> ; -> }T
T{ MARKER MA0 -> }T
T{ : MA1 111 ; -> }T
T{ MARKER MA2 -> }T
T{ : MA1 222 ; -> }T
T{ MA? MA0 MA? MA1 MA? MA2 -> TRUE TRUE TRUE }T
T{ MA1 MA2 MA1 -> 222 111 }T
T{ MA? MA0 MA? MA1 MA? MA2 -> TRUE TRUE FALSE }T
T{ MA0 -> }T
T{ MA? MA0 MA? MA1 MA? MA2 -> FALSE FALSE FALSE }T
\ -----------------------------------------------------------------------------
TESTING ?DO
: QD ?DO I LOOP ;
T{ 789 789 QD -> }T
T{ -9876 -9876 QD -> }T
T{ 5 0 QD -> 0 1 2 3 4 }T
: QD1 ?DO I 10 +LOOP ;
T{ 50 1 QD1 -> 1 11 21 31 41 }T
T{ 50 0 QD1 -> 0 10 20 30 40 }T
: QD2 ?DO I 3 > IF LEAVE ELSE I THEN LOOP ;
T{ 5 -1 QD2 -> -1 0 1 2 3 }T
: QD3 ?DO I 1 +LOOP ;
T{ 4 4 QD3 -> }T
T{ 4 1 QD3 -> 1 2 3 }T
T{ 2 -1 QD3 -> -1 0 1 }T
: QD4 ?DO I -1 +LOOP ;
T{ 4 4 QD4 -> }T
T{ 1 4 QD4 -> 4 3 2 1 }T
T{ -1 2 QD4 -> 2 1 0 -1 }T
: QD5 ?DO I -10 +LOOP ;
T{ 1 50 QD5 -> 50 40 30 20 10 }T
T{ 0 50 QD5 -> 50 40 30 20 10 0 }T
T{ -25 10 QD5 -> 10 0 -10 -20 }T
VARIABLE ITERS
VARIABLE INCRMNT
: QD6 ( limit start increment -- )
INCRMNT !
0 ITERS !
?DO
1 ITERS +!
I
ITERS @ 6 = IF LEAVE THEN
INCRMNT @
+LOOP ITERS @
;
T{ 4 4 -1 QD6 -> 0 }T
T{ 1 4 -1 QD6 -> 4 3 2 1 4 }T
T{ 4 1 -1 QD6 -> 1 0 -1 -2 -3 -4 6 }T
T{ 4 1 0 QD6 -> 1 1 1 1 1 1 6 }T
T{ 0 0 0 QD6 -> 0 }T
T{ 1 4 0 QD6 -> 4 4 4 4 4 4 6 }T
T{ 1 4 1 QD6 -> 4 5 6 7 8 9 6 }T
T{ 4 1 1 QD6 -> 1 2 3 3 }T
T{ 4 4 1 QD6 -> 0 }T
T{ 2 -1 -1 QD6 -> -1 -2 -3 -4 -5 -6 6 }T
T{ -1 2 -1 QD6 -> 2 1 0 -1 4 }T
T{ 2 -1 0 QD6 -> -1 -1 -1 -1 -1 -1 6 }T
T{ -1 2 0 QD6 -> 2 2 2 2 2 2 6 }T
T{ -1 2 1 QD6 -> 2 3 4 5 6 7 6 }T
T{ 2 -1 1 QD6 -> -1 0 1 3 }T
\ -----------------------------------------------------------------------------
TESTING BUFFER:
T{ 8 BUFFER: BUF:TEST -> }T
T{ BUF:TEST DUP ALIGNED = -> TRUE }T
T{ 111 BUF:TEST ! 222 BUF:TEST CELL+ ! -> }T
T{ BUF:TEST @ BUF:TEST CELL+ @ -> 111 222 }T
\ -----------------------------------------------------------------------------
TESTING VALUE TO
T{ 111 VALUE VAL1 -999 VALUE VAL2 -> }T
T{ VAL1 -> 111 }T
T{ VAL2 -> -999 }T
T{ 222 TO VAL1 -> }T
T{ VAL1 -> 222 }T
T{ : VD1 VAL1 ; -> }T
T{ VD1 -> 222 }T
T{ : VD2 TO VAL2 ; -> }T
T{ VAL2 -> -999 }T
T{ -333 VD2 -> }T
T{ VAL2 -> -333 }T
T{ VAL1 -> 222 }T
T{ 123 VALUE VAL3 IMMEDIATE VAL3 -> 123 }T
T{ : VD3 VAL3 LITERAL ; VD3 -> 123 }T
\ -----------------------------------------------------------------------------
TESTING CASE OF ENDOF ENDCASE
: CS1 CASE 1 OF 111 ENDOF
2 OF 222 ENDOF
3 OF 333 ENDOF
>R 999 R>
ENDCASE
;
T{ 1 CS1 -> 111 }T
T{ 2 CS1 -> 222 }T
T{ 3 CS1 -> 333 }T
T{ 4 CS1 -> 999 }T
\ Nested CASE's
: CS2 >R CASE -1 OF CASE R@ 1 OF 100 ENDOF
2 OF 200 ENDOF
>R -300 R>
ENDCASE
ENDOF
-2 OF CASE R@ 1 OF -99 ENDOF
>R -199 R>
ENDCASE
ENDOF
>R 299 R>
ENDCASE R> DROP
;
T{ -1 1 CS2 -> 100 }T
T{ -1 2 CS2 -> 200 }T
T{ -1 3 CS2 -> -300 }T
T{ -2 1 CS2 -> -99 }T
T{ -2 2 CS2 -> -199 }T
T{ 0 2 CS2 -> 299 }T
\ Boolean short circuiting using CASE
: CS3 ( N1 -- N2 )
CASE 1- FALSE OF 11 ENDOF
1- FALSE OF 22 ENDOF
1- FALSE OF 33 ENDOF
44 SWAP
ENDCASE
;
T{ 1 CS3 -> 11 }T
T{ 2 CS3 -> 22 }T
T{ 3 CS3 -> 33 }T
T{ 9 CS3 -> 44 }T
\ Empty CASE statements with/without default
T{ : CS4 CASE ENDCASE ; 1 CS4 -> }T
T{ : CS5 CASE 2 SWAP ENDCASE ; 1 CS5 -> 2 }T
T{ : CS6 CASE 1 OF ENDOF 2 ENDCASE ; 1 CS6 -> }T
T{ : CS7 CASE 3 OF ENDOF 2 ENDCASE ; 1 CS7 -> 1 }T
\ -----------------------------------------------------------------------------
TESTING :NONAME RECURSE
VARIABLE NN1
VARIABLE NN2
:NONAME 1234 ; NN1 !
:NONAME 9876 ; NN2 !
T{ NN1 @ EXECUTE -> 1234 }T
T{ NN2 @ EXECUTE -> 9876 }T
T{ :NONAME ( n -- 0,1,..n ) DUP IF DUP >R 1- RECURSE R> THEN ;
CONSTANT RN1 -> }T
T{ 0 RN1 EXECUTE -> 0 }T
T{ 4 RN1 EXECUTE -> 0 1 2 3 4 }T
:NONAME ( n -- n1 ) \ Multiple RECURSEs in one definition
1- DUP
CASE 0 OF EXIT ENDOF
1 OF 11 SWAP RECURSE ENDOF
2 OF 22 SWAP RECURSE ENDOF
3 OF 33 SWAP RECURSE ENDOF
DROP ABS RECURSE EXIT
ENDCASE
; CONSTANT RN2
T{ 1 RN2 EXECUTE -> 0 }T
T{ 2 RN2 EXECUTE -> 11 0 }T
T{ 4 RN2 EXECUTE -> 33 22 11 0 }T
T{ 25 RN2 EXECUTE -> 33 22 11 0 }T
\ -----------------------------------------------------------------------------
TESTING C"
T{ : CQ1 C" 123" ; -> }T
T{ CQ1 COUNT EVALUATE -> 123 }T
T{ : CQ2 C" " ; -> }T
T{ CQ2 COUNT EVALUATE -> }T
T{ : CQ3 C" 2345"COUNT EVALUATE ; CQ3 -> 2345 }T
\ -----------------------------------------------------------------------------
TESTING COMPILE,
:NONAME DUP + ; CONSTANT DUP+
T{ : Q DUP+ COMPILE, ; -> }T
T{ : AS1 [ Q ] ; -> }T
T{ 123 AS1 -> 246 }T
\ -----------------------------------------------------------------------------
\ Cannot automatically test SAVE-INPUT and RESTORE-INPUT from a console source
TESTING SAVE-INPUT and RESTORE-INPUT with a string source
VARIABLE SI_INC 0 SI_INC !
: SI1
SI_INC @ >IN +!
15 SI_INC !
;
: S$ S" SAVE-INPUT SI1 RESTORE-INPUT 12345" ;
T{ S$ EVALUATE SI_INC @ -> 0 2345 15 }T
\ -----------------------------------------------------------------------------
TESTING .(
CR CR .( Output from .()
T{ CR .( You should see -9876: ) -9876 . -> }T
T{ CR .( and again: ).( -9876)CR -> }T
CR CR .( On the next 2 lines you should see First then Second messages:)
T{ : DOTP CR ." Second message via ." [CHAR] " EMIT \ Check .( is immediate
[ CR ] .( First message via .( ) ; DOTP -> }T
CR CR
T{ : IMM? BL WORD FIND NIP ; IMM? .( -> 1 }T
\ -----------------------------------------------------------------------------
TESTING .R and U.R - has to handle different cell sizes
\ Create some large integers just below/above MAX and Min INTs
MAX-INT 73 79 */ CONSTANT LI1
MIN-INT 71 73 */ CONSTANT LI2
LI1 0 <# #S #> NIP CONSTANT LENLI1
: (.R&U.R) ( u1 u2 -- ) \ u1 <= string length, u2 is required indentation
TUCK + >R
LI1 OVER SPACES . CR R@ LI1 SWAP .R CR
LI2 OVER SPACES . CR R@ 1+ LI2 SWAP .R CR
LI1 OVER SPACES U. CR R@ LI1 SWAP U.R CR
LI2 SWAP SPACES U. CR R> LI2 SWAP U.R CR
;
: .R&U.R ( -- )
CR ." You should see lines duplicated:" CR
." indented by 0 spaces" CR 0 0 (.R&U.R) CR
." indented by 0 spaces" CR LENLI1 0 (.R&U.R) CR \ Just fits required width
." indented by 5 spaces" CR LENLI1 5 (.R&U.R) CR
;
CR CR .( Output from .R and U.R)
T{ .R&U.R -> }T
\ -----------------------------------------------------------------------------
TESTING PAD ERASE
\ Must handle different size characters i.e. 1 CHARS >= 1
84 CONSTANT CHARS/PAD \ Minimum size of PAD in chars
CHARS/PAD CHARS CONSTANT AUS/PAD
: CHECKPAD ( caddr u ch -- f ) \ f = TRUE if u chars = ch
SWAP 0
?DO
OVER I CHARS + C@ OVER <>
IF 2DROP UNLOOP FALSE EXIT THEN
LOOP
2DROP TRUE
;
T{ PAD DROP -> }T
T{ 0 INVERT PAD C! -> }T
T{ PAD C@ CONSTANT MAXCHAR -> }T
T{ PAD CHARS/PAD 2DUP MAXCHAR FILL MAXCHAR CHECKPAD -> TRUE }T
T{ PAD CHARS/PAD 2DUP CHARS ERASE 0 CHECKPAD -> TRUE }T
T{ PAD CHARS/PAD 2DUP MAXCHAR FILL PAD 0 ERASE MAXCHAR CHECKPAD -> TRUE }T
T{ PAD 43 CHARS + 9 CHARS ERASE -> }T
T{ PAD 43 MAXCHAR CHECKPAD -> TRUE }T
T{ PAD 43 CHARS + 9 0 CHECKPAD -> TRUE }T
T{ PAD 52 CHARS + CHARS/PAD 52 - MAXCHAR CHECKPAD -> TRUE }T
\ Check that use of WORD and pictured numeric output do not corrupt PAD
\ Minimum size of buffers for these are 33 chars and (2*n)+2 chars respectively
\ where n is number of bits per cell
PAD CHARS/PAD ERASE
2 BASE !
MAX-UINT MAX-UINT <# #S CHAR 1 DUP HOLD HOLD #> 2DROP
DECIMAL
BL WORD 12345678123456781234567812345678 DROP
T{ PAD CHARS/PAD 0 CHECKPAD -> TRUE }T
\ -----------------------------------------------------------------------------
TESTING PARSE
T{ CHAR | PARSE 1234| DUP ROT ROT EVALUATE -> 4 1234 }T
T{ CHAR ^ PARSE 23 45 ^ DUP ROT ROT EVALUATE -> 7 23 45 }T
: PA1 [CHAR] $ PARSE DUP >R PAD SWAP CHARS MOVE PAD R> ;
T{ PA1 3456
DUP ROT ROT EVALUATE -> 4 3456 }T
T{ CHAR A PARSE A SWAP DROP -> 0 }T
T{ CHAR Z PARSE
SWAP DROP -> 0 }T
T{ CHAR " PARSE 4567 "DUP ROT ROT EVALUATE -> 5 4567 }T
\ -----------------------------------------------------------------------------
TESTING PARSE-NAME (Forth 2012)
\ Adapted from the PARSE-NAME RfD tests
T{ PARSE-NAME abcd STR1 S= -> TRUE }T \ No leading spaces
T{ PARSE-NAME abcde STR2 S= -> TRUE }T \ Leading spaces
\ Test empty parse area, new lines are necessary
T{ PARSE-NAME
NIP -> 0 }T
\ Empty parse area with spaces after PARSE-NAME
T{ PARSE-NAME
NIP -> 0 }T
T{ : PARSE-NAME-TEST ( "name1" "name2" -- n )
PARSE-NAME PARSE-NAME S= ; -> }T
T{ PARSE-NAME-TEST abcd abcd -> TRUE }T
T{ PARSE-NAME-TEST abcd abcd -> TRUE }T \ Leading spaces
T{ PARSE-NAME-TEST abcde abcdf -> FALSE }T
T{ PARSE-NAME-TEST abcdf abcde -> FALSE }T
T{ PARSE-NAME-TEST abcde abcde
-> TRUE }T \ Parse to end of line
T{ PARSE-NAME-TEST abcde abcde
-> TRUE }T \ Leading and trailing spaces
\ -----------------------------------------------------------------------------
TESTING DEFER DEFER@ DEFER! IS ACTION-OF (Forth 2012)
\ Adapted from the Forth 200X RfD tests
T{ DEFER DEFER1 -> }T
T{ : MY-DEFER DEFER ; -> }T
T{ : IS-DEFER1 IS DEFER1 ; -> }T
T{ : ACTION-DEFER1 ACTION-OF DEFER1 ; -> }T
T{ : DEF! DEFER! ; -> }T
T{ : DEF@ DEFER@ ; -> }T
T{ ' * ' DEFER1 DEFER! -> }T
T{ 2 3 DEFER1 -> 6 }T
T{ ' DEFER1 DEFER@ -> ' * }T
T{ ' DEFER1 DEF@ -> ' * }T
T{ ACTION-OF DEFER1 -> ' * }T
T{ ACTION-DEFER1 -> ' * }T
T{ ' + IS DEFER1 -> }T
T{ 1 2 DEFER1 -> 3 }T
T{ ' DEFER1 DEFER@ -> ' + }T
T{ ' DEFER1 DEF@ -> ' + }T
T{ ACTION-OF DEFER1 -> ' + }T
T{ ACTION-DEFER1 -> ' + }T
T{ ' - IS-DEFER1 -> }T
T{ 1 2 DEFER1 -> -1 }T
T{ ' DEFER1 DEFER@ -> ' - }T
T{ ' DEFER1 DEF@ -> ' - }T
T{ ACTION-OF DEFER1 -> ' - }T
T{ ACTION-DEFER1 -> ' - }T
T{ MY-DEFER DEFER2 -> }T
T{ ' DUP IS DEFER2 -> }T
T{ 1 DEFER2 -> 1 1 }T
\ -----------------------------------------------------------------------------
TESTING HOLDS (Forth 2012)
: HTEST S" Testing HOLDS" ;
: HTEST2 S" works" ;
: HTEST3 S" Testing HOLDS works 123" ;
T{ 0 0 <# HTEST HOLDS #> HTEST S= -> TRUE }T
T{ 123 0 <# #S BL HOLD HTEST2 HOLDS BL HOLD HTEST HOLDS #>
HTEST3 S= -> TRUE }T
T{ : HLD HOLDS ; -> }T
T{ 0 0 <# HTEST HLD #> HTEST S= -> TRUE }T
\ -----------------------------------------------------------------------------
TESTING REFILL SOURCE-ID
\ REFILL and SOURCE-ID from the user input device can't be tested from a file,
\ can only be tested from a string via EVALUATE
T{ : RF1 S" REFILL" EVALUATE ; RF1 -> FALSE }T
T{ : SID1 S" SOURCE-ID" EVALUATE ; SID1 -> -1 }T
\ ------------------------------------------------------------------------------
TESTING S\" (Forth 2012 compilation mode)
\ Extended the Forth 200X RfD tests
\ Note this tests the Core Ext definition of S\" which has unedfined
\ interpretation semantics. S\" in interpretation mode is tested in the tests on
\ the File-Access word set
T{ : SSQ1 S\" abc" S" abc" S= ; -> }T \ No escapes
T{ SSQ1 -> TRUE }T
T{ : SSQ2 S\" " ; SSQ2 SWAP DROP -> 0 }T \ Empty string
T{ : SSQ3 S\" \a\b\e\f\l\m\q\r\t\v\x0F0\x1Fa\xaBx\z\"\\" ; -> }T
T{ SSQ3 SWAP DROP -> 20 }T \ String length
T{ SSQ3 DROP C@ -> 7 }T \ \a BEL Bell
T{ SSQ3 DROP 1 CHARS + C@ -> 8 }T \ \b BS Backspace
T{ SSQ3 DROP 2 CHARS + C@ -> 27 }T \ \e ESC Escape
T{ SSQ3 DROP 3 CHARS + C@ -> 12 }T \ \f FF Form feed
T{ SSQ3 DROP 4 CHARS + C@ -> 10 }T \ \l LF Line feed
T{ SSQ3 DROP 5 CHARS + C@ -> 13 }T \ \m CR of CR/LF pair
T{ SSQ3 DROP 6 CHARS + C@ -> 10 }T \ LF of CR/LF pair
T{ SSQ3 DROP 7 CHARS + C@ -> 34 }T \ \q " Double Quote
T{ SSQ3 DROP 8 CHARS + C@ -> 13 }T \ \r CR Carriage Return
T{ SSQ3 DROP 9 CHARS + C@ -> 9 }T \ \t TAB Horizontal Tab
T{ SSQ3 DROP 10 CHARS + C@ -> 11 }T \ \v VT Vertical Tab
T{ SSQ3 DROP 11 CHARS + C@ -> 15 }T \ \x0F Given Char
T{ SSQ3 DROP 12 CHARS + C@ -> 48 }T \ 0 0 Digit follow on
T{ SSQ3 DROP 13 CHARS + C@ -> 31 }T \ \x1F Given Char
T{ SSQ3 DROP 14 CHARS + C@ -> 97 }T \ a a Hex follow on
T{ SSQ3 DROP 15 CHARS + C@ -> 171 }T \ \xaB Insensitive Given Char
T{ SSQ3 DROP 16 CHARS + C@ -> 120 }T \ x x Non hex follow on
T{ SSQ3 DROP 17 CHARS + C@ -> 0 }T \ \z NUL No Character
T{ SSQ3 DROP 18 CHARS + C@ -> 34 }T \ \" " Double Quote
T{ SSQ3 DROP 19 CHARS + C@ -> 92 }T \ \\ \ Back Slash
\ The above does not test \n as this is a system dependent value.
\ Check it displays a new line
CR .( The next test should display:)
CR .( One line...)
CR .( another line)
T{ : SSQ4 S\" \nOne line...\nanotherLine\n" TYPE ; SSQ4 -> }T
\ Test bare escapable characters appear as themselves
T{ : SSQ5 S\" abeflmnqrtvxz" S" abeflmnqrtvxz" S= ; SSQ5 -> TRUE }T
T{ : SSQ6 S\" a\""2DROP 1111 ; SSQ6 -> 1111 }T \ Parsing behaviour
T{ : SSQ7 S\" 111 : SSQ8 S\\\" 222\" EVALUATE ; SSQ8 333" EVALUATE ; -> }T
T{ SSQ7 -> 111 222 333 }T
T{ : SSQ9 S\" 11 : SSQ10 S\\\" \\x32\\x32\" EVALUATE ; SSQ10 33" EVALUATE ; -> }T
T{ SSQ9 -> 11 22 33 }T
\ -----------------------------------------------------------------------------
CORE-EXT-ERRORS SET-ERROR-COUNT
CR .( End of Core Extension word tests) CR