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coop:loops/prolog coop:loops/erlang coop:loops/smalltalk coop:loops/forth coop:loops/lua coop:loops/haskell coop:loops/hs coop:architecture coop:main coop:wasm coop:macros coop:sx coop:exorcism coop:cssx coop:decoupling coop:sexpression coop:relations

16 Commits
loops/smal ... loops/fort

Author SHA1 Message Date
giles
b1a7852045 forth: [, ], STATE, EVALUATE (+5; Hayes 463→477, 74%)
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2026-04-25 01:23:23 +00:00
giles
89a879799a forth: parsing/dictionary '/[']/EXECUTE/LITERAL/POSTPONE/WORD/FIND/>BODY (Hayes 463/638, 72%)
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2026-04-25 00:55:34 +00:00
giles
47f66ad1be forth: pictured numeric output <#/#/#S/#>/HOLD/SIGN + U./U.R/.R (Hayes 448/638, 70%)
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2026-04-25 00:23:04 +00:00
giles
c726a9e0fe forth: double-cell ops D+/D-/DNEGATE/DABS/D=/D</D0=/D0</DMAX/DMIN (+18)
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2026-04-24 23:52:43 +00:00
giles
b6810e90ab forth: mixed/double-cell math (S>D M* UM* UM/MOD FM/MOD SM/REM */ */MOD); Hayes 342→446 (69%)
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2026-04-24 23:25:43 +00:00
giles
3ab01b271d forth: Phase 5 memory + unsigned compare (Hayes 268→342, 53%)
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2026-04-24 22:56:26 +00:00
giles
8e1466032a forth: LSHIFT/RSHIFT + 32-bit arith truncation + early binding (Hayes 174→268)
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2026-04-24 22:26:58 +00:00
giles
387a6e7f5d forth: SP@ / SP! (+4; Hayes 174/590)
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2026-04-24 21:07:10 +00:00
giles
acf9c273a2 forth: BASE/DECIMAL/HEX/BIN/OCTAL (+9; Hayes 174/590)
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2026-04-24 20:40:11 +00:00
giles
35ce18eb97 forth: CHAR/[CHAR]/KEY/ACCEPT (+7; Hayes 174/590)
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2026-04-24 20:12:31 +00:00
giles
1c975f229d forth: Phase 4 strings — S"/C"/."/TYPE/COUNT/CMOVE/FILL/BLANK (+16; Hayes 168/590)
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2026-04-24 19:45:40 +00:00
giles
0e509af0a2 forth: Hayes conformance runner + baseline scoreboard (165/590, 28%)
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2026-04-24 19:13:45 +00:00
giles
a47b3e5420 forth: vendor Gerry Jackson's forth2012-test-suite (Hayes Core + Ext)
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2026-04-24 18:25:39 +00:00
giles
e066e14267 forth: DO/LOOP/+LOOP/I/J/LEAVE + return stack words (+16)
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2026-04-24 17:58:37 +00:00
giles
bb16477fd4 forth: BEGIN/UNTIL/WHILE/REPEAT/AGAIN (+9)
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2026-04-24 17:33:25 +00:00
giles
b2939c1922 forth: IF/ELSE/THEN + PC-driven body runner (+18)
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2026-04-24 17:03:41 +00:00
27 changed files with 4651 additions and 3138 deletions
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14
lib/forth/ans-tests/README.md Normal file
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ANS Forth conformance tests — vendored from
https://github.com/gerryjackson/forth2012-test-suite (master, commit-locked
on first fetch: 2026-04-24).
Files in this directory are pristine copies of upstream — do not edit them.
They are consumed by the conformance runner in `lib/forth/conformance.sh`.
- `tester.fr` — John Hayes' test harness (`T{ ... -> ... }T`). (C) 1995
Johns Hopkins APL, distributable under its notice.
- `core.fr` — Core word set tests (Hayes, ~1000 lines).
- `coreexttest.fth` — Core Extension tests (Gerry Jackson).
Only `core.fr` is expected to run green end-to-end for Phase 3; the others
stay parked until later phases.

1009
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\ 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 0.15 1 August 2025 Added two tests to VALUE
\ 0.14 21 July 2022 Updated first line of BUFFER: test as recommended
\ in issue 32
\ 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{ 2 CELLS 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{ 444 TO VAL1 -> }T
T{ VD1 -> 444 }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

66
lib/forth/ans-tests/tester.fr Normal file
View File

@@ -0,0 +1,66 @@
\ 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 ;

690
lib/forth/compiler.sx
View File

@@ -24,18 +24,43 @@
(forth-execute-word state w)
(forth-compile-call state tok))
(let
((n (forth-parse-number tok (get state "base"))))
((n (forth-parse-number tok (get (get state "vars") "base"))))
(if
(not (nil? n))
(forth-compile-lit state n)
(forth-error state (str tok " ?"))))))))
;; Resolve the word NOW (early binding) so that `: X X ;` compiles a call
;; to the prior X — matching standard Forth redefinition semantics.
;; RECURSE is the one exception: it stays late-bound against the not-yet-
;; installed current definition.
(define
forth-compile-call
(fn
(state name)
(let
((op (fn (s) (let ((w (forth-lookup s name))) (if (nil? w) (forth-error s (str name " ? (compiled)")) (forth-execute-word s w))))))
((w (forth-lookup state name)))
(if
(nil? w)
(forth-error state (str name " ?"))
(let
((op (fn (s) (forth-execute-word s w))))
(forth-def-append! state op))))))
(define
forth-compile-recurse
(fn
(state name)
(let
((op
(fn
(s)
(let
((w (forth-lookup s name)))
(if
(nil? w)
(forth-error s (str "RECURSE: " name " not yet installed"))
(forth-execute-word s w))))))
(forth-def-append! state op))))
(define
@@ -52,9 +77,158 @@
((def (get state "current-def")))
(dict-set! def "body" (concat (get def "body") (list op))))))
(define
forth-def-length
(fn (state) (len (get (get state "current-def") "body"))))
(define
forth-make-branch
(fn
(kind target)
(let ((b (dict))) (dict-set! b "kind" kind) (dict-set! b "target" target) b)))
(define
forth-make-target
(fn () (let ((t (dict))) (dict-set! t "v" 0) t)))
(define
forth-make-colon-body
(fn (ops) (fn (s) (for-each (fn (op) (op s)) ops))))
(fn
(ops)
(let
((n (len ops)))
(fn
(s)
(let ((pc (dict))) (dict-set! pc "v" 0) (forth-run-body s ops pc n))))))
(define
forth-step-op
(fn
(s op pc)
(cond
((and (dict? op) (= (get op "kind") "bif"))
(if
(= (forth-pop s) 0)
(dict-set! pc "v" (get (get op "target") "v"))
(dict-set! pc "v" (+ (get pc "v") 1))))
((and (dict? op) (= (get op "kind") "branch"))
(dict-set! pc "v" (get (get op "target") "v")))
((and (dict? op) (= (get op "kind") "leave"))
(begin
(forth-rpop s)
(forth-rpop s)
(dict-set! pc "v" (get (get op "target") "v"))))
((and (dict? op) (= (get op "kind") "loop"))
(forth-loop-step s op pc))
((and (dict? op) (= (get op "kind") "+loop"))
(forth-plusloop-step s op pc))
(else (begin (op s) (dict-set! pc "v" (+ (get pc "v") 1)))))))
(define
forth-loop-step
(fn
(s op pc)
(let
((idx (forth-rpop s)))
(let
((lim (forth-rpeek s)))
(let
((next (+ idx 1)))
(if
(>= next lim)
(begin
(forth-rpop s)
(dict-set! pc "v" (+ (get pc "v") 1)))
(begin
(forth-rpush s next)
(dict-set! pc "v" (get (get op "target") "v")))))))))
(define
forth-plusloop-step
(fn
(s op pc)
(let
((inc (forth-pop s)))
(let
((idx (forth-rpop s)))
(let
((lim (forth-rpeek s)))
(let
((next (+ idx inc)))
(if
(if (>= inc 0) (>= next lim) (< next lim))
(begin
(forth-rpop s)
(dict-set! pc "v" (+ (get pc "v") 1)))
(begin
(forth-rpush s next)
(dict-set! pc "v" (get (get op "target") "v"))))))))))
;; Parse input tokens until one ends in `"`. Returns joined content with
;; single spaces between tokens (emulating standard Forth S"-style parse).
(define
forth-parse-quote
(fn
(state)
(forth-parse-quote-loop state (list))))
(define
forth-parse-quote-loop
(fn
(state parts)
(let
((tok (forth-next-token! state)))
(if
(nil? tok)
(forth-error state "unterminated string")
(let
((n (len tok)))
(if
(and (> n 0) (= (substr tok (- n 1) 1) "\""))
(let
((final (substr tok 0 (- n 1))))
(forth-join-parts (concat parts (list final)) " "))
(forth-parse-quote-loop state (concat parts (list tok)))))))))
(define
forth-join-parts
(fn
(parts sep)
(if
(= (len parts) 0)
""
(forth-join-loop (rest parts) sep (first parts)))))
(define
forth-join-loop
(fn
(xs sep acc)
(if
(= (len xs) 0)
acc
(forth-join-loop (rest-of xs) sep (str acc sep (first xs))))))
(define
forth-find-do
(fn
(cs)
(if
(= (len cs) 0)
nil
(if
(and (dict? (first cs)) (= (get (first cs) "kind") "do"))
(first cs)
(forth-find-do (rest cs))))))
(define
forth-run-body
(fn
(s ops pc n)
(when
(< (get pc "v") n)
(begin
(forth-step-op s (nth ops (get pc "v")) pc)
(forth-run-body s ops pc n)))))
;; Override forth-interpret-token to branch on compile mode.
(define
@@ -70,7 +244,7 @@
(not (nil? w))
(forth-execute-word state w)
(let
((n (forth-parse-number tok (get state "base"))))
((n (forth-parse-number tok (get (get state "vars") "base"))))
(if
(not (nil? n))
(forth-push state n)
@@ -111,6 +285,7 @@
(get s "dict")
(downcase (get def "name"))
(forth-make-word "colon-def" body-fn false))
(dict-set! s "last-defined" (get def "name"))
(dict-set! s "current-def" nil)
(dict-set! s "compiling" false))))))
(forth-def-prim-imm!
@@ -138,7 +313,289 @@
(forth-error s "RECURSE only in definition"))
(let
((name (get (get s "current-def") "name")))
(forth-compile-call s name))))
(forth-compile-recurse s name))))
(forth-def-prim-imm!
state
"IF"
(fn
(s)
(when (not (get s "compiling")) (forth-error s "IF outside definition"))
(let
((target (forth-make-target)))
(forth-def-append! s (forth-make-branch "bif" target))
(forth-cpush s target))))
(forth-def-prim-imm!
state
"ELSE"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "ELSE outside definition"))
(let
((new-target (forth-make-target)))
(forth-def-append! s (forth-make-branch "branch" new-target))
(let
((if-target (forth-cpop s)))
(dict-set! if-target "v" (forth-def-length s)))
(forth-cpush s new-target))))
(forth-def-prim-imm!
state
"THEN"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "THEN outside definition"))
(let
((target (forth-cpop s)))
(dict-set! target "v" (forth-def-length s)))))
(forth-def-prim-imm!
state
"BEGIN"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "BEGIN outside definition"))
(forth-cpush s (forth-def-length s))))
(forth-def-prim-imm!
state
"UNTIL"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "UNTIL outside definition"))
(let
((back-pc (forth-cpop s)))
(let
((target (forth-make-target)))
(dict-set! target "v" back-pc)
(forth-def-append! s (forth-make-branch "bif" target))))))
(forth-def-prim-imm!
state
"AGAIN"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "AGAIN outside definition"))
(let
((back-pc (forth-cpop s)))
(let
((target (forth-make-target)))
(dict-set! target "v" back-pc)
(forth-def-append! s (forth-make-branch "branch" target))))))
(forth-def-prim-imm!
state
"WHILE"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "WHILE outside definition"))
(let
((target (forth-make-target)))
(forth-def-append! s (forth-make-branch "bif" target))
(forth-cpush s target))))
(forth-def-prim-imm!
state
"REPEAT"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "REPEAT outside definition"))
(let
((while-target (forth-cpop s)))
(let
((back-pc (forth-cpop s)))
(let
((b-target (forth-make-target)))
(dict-set! b-target "v" back-pc)
(forth-def-append! s (forth-make-branch "branch" b-target))
(dict-set! while-target "v" (forth-def-length s)))))))
(forth-def-prim-imm!
state
"DO"
(fn
(s)
(when (not (get s "compiling")) (forth-error s "DO outside definition"))
(let
((op
(fn
(ss)
(let
((start (forth-pop ss)))
(let
((limit (forth-pop ss)))
(forth-rpush ss limit)
(forth-rpush ss start))))))
(forth-def-append! s op))
(let
((marker (dict)))
(dict-set! marker "kind" "do")
(dict-set! marker "back" (forth-def-length s))
(dict-set! marker "leaves" (list))
(forth-cpush s marker))))
(forth-def-prim-imm!
state
"LOOP"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "LOOP outside definition"))
(let
((marker (forth-cpop s)))
(when
(or (not (dict? marker)) (not (= (get marker "kind") "do")))
(forth-error s "LOOP without DO"))
(let
((target (forth-make-target)))
(dict-set! target "v" (get marker "back"))
(forth-def-append! s (forth-make-branch "loop" target)))
(let
((exit-pc (forth-def-length s)))
(for-each
(fn (t) (dict-set! t "v" exit-pc))
(get marker "leaves"))))))
(forth-def-prim-imm!
state
"+LOOP"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "+LOOP outside definition"))
(let
((marker (forth-cpop s)))
(when
(or (not (dict? marker)) (not (= (get marker "kind") "do")))
(forth-error s "+LOOP without DO"))
(let
((target (forth-make-target)))
(dict-set! target "v" (get marker "back"))
(forth-def-append! s (forth-make-branch "+loop" target)))
(let
((exit-pc (forth-def-length s)))
(for-each
(fn (t) (dict-set! t "v" exit-pc))
(get marker "leaves"))))))
(forth-def-prim!
state
"CHAR"
(fn
(s)
(let
((tok (forth-next-token! s)))
(when (nil? tok) (forth-error s "CHAR expects a word"))
(forth-push s (char-code (substr tok 0 1))))))
(forth-def-prim-imm!
state
"[CHAR]"
(fn
(s)
(let
((tok (forth-next-token! s)))
(when (nil? tok) (forth-error s "[CHAR] expects a word"))
(let
((c (char-code (substr tok 0 1))))
(if
(get s "compiling")
(forth-def-append! s (fn (ss) (forth-push ss c)))
(forth-push s c))))))
(forth-def-prim!
state
"KEY"
(fn
(s)
(let
((kb (or (get s "keybuf") "")))
(if
(= (len kb) 0)
(forth-error s "KEY: no input available")
(begin
(forth-push s (char-code (substr kb 0 1)))
(dict-set! s "keybuf" (substr kb 1 (- (len kb) 1))))))))
(forth-def-prim!
state
"ACCEPT"
(fn
(s)
(let
((n1 (forth-pop s)) (addr (forth-pop s)))
(let
((kb (or (get s "keybuf") "")))
(let
((n (if (< n1 (len kb)) n1 (len kb))))
(forth-mem-write-string! s addr (substr kb 0 n))
(dict-set! s "keybuf" (substr kb n (- (len kb) n)))
(forth-push s n))))))
(forth-def-prim-imm!
state
"S\""
(fn
(s)
(let
((content (forth-parse-quote s)))
(if
(get s "compiling")
(let
((addr (forth-alloc-bytes! s (len content))))
(forth-mem-write-string! s addr content)
(forth-def-append! s (fn (ss) (forth-push ss addr)))
(forth-def-append! s (fn (ss) (forth-push ss (len content)))))
(let
((addr (forth-alloc-bytes! s (len content))))
(forth-mem-write-string! s addr content)
(forth-push s addr)
(forth-push s (len content)))))))
(forth-def-prim-imm!
state
"C\""
(fn
(s)
(let
((content (forth-parse-quote s)))
(let
((addr (forth-alloc-bytes! s (+ 1 (len content)))))
(forth-mem-write! s addr (len content))
(forth-mem-write-string! s (+ addr 1) content)
(if
(get s "compiling")
(forth-def-append! s (fn (ss) (forth-push ss addr)))
(forth-push s addr))))))
(forth-def-prim-imm!
state
".\""
(fn
(s)
(let
((content (forth-parse-quote s)))
(if
(get s "compiling")
(forth-def-append! s (fn (ss) (forth-emit-str ss content)))
(forth-emit-str s content)))))
(forth-def-prim-imm!
state
"LEAVE"
(fn
(s)
(when
(not (get s "compiling"))
(forth-error s "LEAVE outside definition"))
(let
((marker (forth-find-do (get s "cstack"))))
(when (nil? marker) (forth-error s "LEAVE without DO"))
(let
((target (forth-make-target)))
(forth-def-append! s (forth-make-branch "leave" target))
(dict-set!
marker
"leaves"
(concat (get marker "leaves") (list target)))))))
(forth-def-prim!
state
"VARIABLE"
@@ -192,7 +649,13 @@
(s)
(let
((addr (forth-pop s)))
(forth-push s (or (get (get s "vars") addr) 0)))))
(cond
((= addr "@@state")
(forth-push s (if (get s "compiling") -1 0)))
((= addr "@@in") (forth-push s 0))
((string? addr)
(forth-push s (or (get (get s "vars") addr) 0)))
(else (forth-push s (forth-mem-read s addr)))))))
(forth-def-prim!
state
"!"
@@ -200,7 +663,10 @@
(s)
(let
((addr (forth-pop s)) (v (forth-pop s)))
(dict-set! (get s "vars") addr v))))
(if
(string? addr)
(dict-set! (get s "vars") addr v)
(forth-mem-write! s addr v)))))
(forth-def-prim!
state
"+!"
@@ -208,9 +674,215 @@
(s)
(let
((addr (forth-pop s)) (v (forth-pop s)))
(if
(string? addr)
(let
((cur (or (get (get s "vars") addr) 0)))
(dict-set! (get s "vars") addr (+ cur v)))
(forth-mem-write! s addr (+ (forth-mem-read s addr) v))))))
(forth-def-prim! state "HERE" (fn (s) (forth-push s (get s "here"))))
(forth-def-prim!
state
"ALLOT"
(fn
(s)
(let
((n (forth-pop s)))
(dict-set! s "here" (+ (get s "here") n)))))
(forth-def-prim!
state
","
(fn
(s)
(let
((v (forth-pop s)) (addr (forth-alloc-bytes! s 1)))
(forth-mem-write! s addr v))))
(forth-def-prim!
state
"C,"
(fn
(s)
(let
((v (forth-pop s)) (addr (forth-alloc-bytes! s 1)))
(forth-mem-write! s addr v))))
(forth-def-prim!
state
"CREATE"
(fn
(s)
(let
((name (forth-next-token! s)))
(when (nil? name) (forth-error s "CREATE expects name"))
(let
((cur (or (get (get s "vars") addr) 0)))
(dict-set! (get s "vars") addr (+ cur v))))))
((addr (get s "here")))
(forth-def-prim! s name (fn (ss) (forth-push ss addr)))
(let
((w (forth-lookup s name)))
(dict-set! w "body-addr" addr))))))
(forth-def-prim! state "CELL+" (fn (s) (forth-push s (+ (forth-pop s) 1))))
(forth-def-prim! state "CELLS" (fn (s) nil))
(forth-def-prim! state "ALIGN" (fn (s) nil))
(forth-def-prim! state "ALIGNED" (fn (s) nil))
(forth-def-prim!
state
"EXECUTE"
(fn (s) (let ((w (forth-pop s))) (forth-execute-word s w))))
(forth-def-prim!
state
"'"
(fn
(s)
(let
((name (forth-next-token! s)))
(when (nil? name) (forth-error s "' expects name"))
(let
((w (forth-lookup s name)))
(when (nil? w) (forth-error s (str name " ?")))
(forth-push s w)))))
(forth-def-prim-imm!
state
"[']"
(fn
(s)
(let
((name (forth-next-token! s)))
(when (nil? name) (forth-error s "['] expects name"))
(let
((w (forth-lookup s name)))
(when (nil? w) (forth-error s (str name " ?")))
(if
(get s "compiling")
(forth-def-append! s (fn (ss) (forth-push ss w)))
(forth-push s w))))))
(forth-def-prim-imm!
state
"LITERAL"
(fn
(s)
(let
((v (forth-pop s)))
(when
(not (get s "compiling"))
(forth-error s "LITERAL outside compile mode"))
(forth-def-append! s (fn (ss) (forth-push ss v))))))
(forth-def-prim-imm!
state
"POSTPONE"
(fn
(s)
(let
((name (forth-next-token! s)))
(when (nil? name) (forth-error s "POSTPONE expects name"))
(let
((w (forth-lookup s name)))
(when (nil? w) (forth-error s (str name " ?")))
(forth-def-append!
s
(fn
(ss)
(forth-def-append!
ss
(fn (sss) (forth-execute-word sss w)))))))))
(forth-def-prim!
state
">BODY"
(fn
(s)
(let
((w (forth-pop s)))
(forth-push s (or (get w "body-addr") 0)))))
(forth-def-prim-imm!
state
"["
(fn (s) (dict-set! s "compiling" false)))
(forth-def-prim! state "]" (fn (s) (dict-set! s "compiling" true)))
(forth-def-prim! state "STATE" (fn (s) (forth-push s "@@state")))
(forth-def-prim!
state
"EVALUATE"
(fn
(s)
(let
((u (forth-pop s)) (addr (forth-pop s)))
(let
((src (forth-mem-read-string s addr u)))
(let
((saved-input (get s "input")))
(dict-set! s "input" (forth-tokens src))
(forth-interpret-loop s)
(dict-set! s "input" saved-input))))))
(forth-def-prim!
state
"SOURCE"
(fn (s) (forth-push s 0) (forth-push s 0)))
(forth-def-prim! state ">IN" (fn (s) (forth-push s "@@in")))
(forth-def-prim!
state
"WORD"
(fn
(s)
(let
((delim (forth-pop s)) (tok (forth-next-token! s)))
(let
((str-out (or tok "")))
(let
((addr (forth-alloc-bytes! s (+ 1 (len str-out)))))
(forth-mem-write! s addr (len str-out))
(forth-mem-write-string! s (+ addr 1) str-out)
(forth-push s addr))))))
(forth-def-prim!
state
"FIND"
(fn
(s)
(let
((c-addr (forth-pop s)))
(let
((u (forth-mem-read s c-addr)))
(let
((str-name (forth-mem-read-string s (+ c-addr 1) u)))
(let
((w (forth-lookup s str-name)))
(if
(nil? w)
(begin (forth-push s c-addr) (forth-push s 0))
(begin
(forth-push s w)
(forth-push s (if (get w "immediate?") 1 -1))))))))))
(forth-def-prim!
state
"U<"
(forth-cmp
(fn (a b) (< (forth-to-unsigned a 32) (forth-to-unsigned b 32)))))
(forth-def-prim!
state
"U>"
(forth-cmp
(fn (a b) (> (forth-to-unsigned a 32) (forth-to-unsigned b 32)))))
(forth-def-prim!
state
"2@"
(fn
(s)
(let
((addr (forth-pop s)))
(if
(string? addr)
(forth-error s "2@ on var unsupported")
(begin
(forth-push s (forth-mem-read s (+ addr 1)))
(forth-push s (forth-mem-read s addr)))))))
(forth-def-prim!
state
"2!"
(fn
(s)
(let
((addr (forth-pop s))
(a (forth-pop s))
(b (forth-pop s)))
(forth-mem-write! s addr a)
(forth-mem-write! s (+ addr 1) b))))
state))
;; Track the most recently defined word name for IMMEDIATE.

166
lib/forth/conformance.sh Executable file
View File

@@ -0,0 +1,166 @@
#!/usr/bin/env bash
# Run the Hayes/Gerry-Jackson Core conformance suite against our Forth
# interpreter and emit scoreboard.json + scoreboard.md.
#
# Method:
# 1. Preprocess lib/forth/ans-tests/core.fr — strip \ comments, ( ... )
# comments, and TESTING … metadata lines.
# 2. Split into chunks ending at each `}T` so an error in one test
# chunk doesn't abort the run.
# 3. Emit an SX file that exposes those chunks as a list.
# 4. Run our Forth + hayes-runner under sx_server; record pass/fail/error.
set -e
FORTH_DIR="$(cd "$(dirname "$0")" && pwd)"
ROOT="$(cd "$FORTH_DIR/../.." && pwd)"
SX_SERVER="${SX_SERVER:-/root/rose-ash/hosts/ocaml/_build/default/bin/sx_server.exe}"
SOURCE="$FORTH_DIR/ans-tests/core.fr"
OUT_JSON="$FORTH_DIR/scoreboard.json"
OUT_MD="$FORTH_DIR/scoreboard.md"
TMP="$(mktemp -d)"
PREPROC="$TMP/preproc.forth"
CHUNKS_SX="$TMP/chunks.sx"
cd "$ROOT"
# 1. preprocess
awk '
{
line = $0
# strip leading/embedded \ line comments (must be \ followed by space or EOL)
gsub(/(^|[ \t])\\([ \t].*|$)/, " ", line)
# strip ( ... ) block comments that sit on one line
gsub(/\([^)]*\)/, " ", line)
# strip TESTING … metadata lines (rest of line, incl. bare TESTING)
sub(/TESTING([ \t].*)?$/, " ", line)
print line
}' "$SOURCE" > "$PREPROC"
# 2 + 3: split into chunks at each `}T` and emit as a SX file
#
# Cap chunks via MAX_CHUNKS env (default 638 = full Hayes Core). Lower
# it temporarily if later tests regress into an infinite loop while you
# are iterating on primitives.
MAX_CHUNKS="${MAX_CHUNKS:-638}"
MAX_CHUNKS="$MAX_CHUNKS" python3 - "$PREPROC" "$CHUNKS_SX" <<'PY'
import os, re, sys
preproc_path, out_path = sys.argv[1], sys.argv[2]
max_chunks = int(os.environ.get("MAX_CHUNKS", "590"))
text = open(preproc_path).read()
# keep the `}T` attached to the preceding chunk
parts = re.split(r'(\}T)', text)
chunks = []
buf = ""
for p in parts:
buf += p
if p == "}T":
s = buf.strip()
if s:
chunks.append(s)
buf = ""
if buf.strip():
chunks.append(buf.strip())
chunks = chunks[:max_chunks]
def esc(s):
s = s.replace('\\', '\\\\').replace('"', '\\"')
s = s.replace('\r', ' ').replace('\n', ' ')
s = re.sub(r'\s+', ' ', s).strip()
return s
with open(out_path, "w") as f:
f.write("(define hayes-chunks (list\n")
for c in chunks:
f.write(' "' + esc(c) + '"\n')
f.write("))\n\n")
f.write("(define\n")
f.write(" hayes-run-all\n")
f.write(" (fn\n")
f.write(" ()\n")
f.write(" (hayes-reset!)\n")
f.write(" (let ((s (hayes-boot)))\n")
f.write(" (for-each (fn (c) (hayes-run-chunk s c)) hayes-chunks))\n")
f.write(" (hayes-summary)))\n")
PY
# 4. run it
OUT=$(printf '(epoch 1)\n(load "lib/forth/runtime.sx")\n(epoch 2)\n(load "lib/forth/reader.sx")\n(epoch 3)\n(load "lib/forth/interpreter.sx")\n(epoch 4)\n(load "lib/forth/compiler.sx")\n(epoch 5)\n(load "lib/forth/hayes-runner.sx")\n(epoch 6)\n(load "%s")\n(epoch 7)\n(eval "(hayes-run-all)")\n' "$CHUNKS_SX" \
| timeout 180 "$SX_SERVER" 2>&1)
STATUS=$?
SUMMARY=$(printf '%s\n' "$OUT" | awk '/^\{:pass / {print; exit}')
PASS=$(printf '%s' "$SUMMARY" | sed -n 's/.*:pass \([0-9-]*\).*/\1/p')
FAIL=$(printf '%s' "$SUMMARY" | sed -n 's/.*:fail \([0-9-]*\).*/\1/p')
ERR=$(printf '%s' "$SUMMARY" | sed -n 's/.*:error \([0-9-]*\).*/\1/p')
TOTAL=$(printf '%s' "$SUMMARY" | sed -n 's/.*:total \([0-9-]*\).*/\1/p')
CHUNK_COUNT=$(grep -c '^ "' "$CHUNKS_SX" || echo 0)
TOTAL_AVAILABLE=$(grep -c '}T' "$PREPROC" || echo 0)
NOW="$(date -u +%Y-%m-%dT%H:%M:%SZ)"
if [ -z "$PASS" ]; then
PASS=0; FAIL=0; ERR=0; TOTAL=0
NOTE="runner halted before completing (timeout or SX error)"
else
NOTE="completed"
fi
PCT=0
if [ "$TOTAL" -gt 0 ]; then
PCT=$((PASS * 100 / TOTAL))
fi
cat > "$OUT_JSON" <<JSON
{
"source": "gerryjackson/forth2012-test-suite src/core.fr",
"generated_at": "$NOW",
"chunks_available": $TOTAL_AVAILABLE,
"chunks_fed": $CHUNK_COUNT,
"total": $TOTAL,
"pass": $PASS,
"fail": $FAIL,
"error": $ERR,
"percent": $PCT,
"note": "$NOTE"
}
JSON
cat > "$OUT_MD" <<MD
# Forth Hayes Core scoreboard
| metric | value |
| ----------------- | ----: |
| chunks available | $TOTAL_AVAILABLE |
| chunks fed | $CHUNK_COUNT |
| total | $TOTAL |
| pass | $PASS |
| fail | $FAIL |
| error | $ERR |
| percent | ${PCT}% |
- **Source**: \`gerryjackson/forth2012-test-suite\` \`src/core.fr\`
- **Generated**: $NOW
- **Note**: $NOTE
A "chunk" is any preprocessed segment ending at a \`}T\` (every Hayes test
is one chunk, plus the small declaration blocks between tests).
The runner catches raised errors at chunk boundaries so one bad chunk
does not abort the rest. \`error\` covers chunks that raised; \`fail\`
covers tests whose \`->\` / \`}T\` comparison mismatched.
### Chunk cap
\`conformance.sh\` processes the first \`\$MAX_CHUNKS\` chunks (default
**638**, i.e. the whole Hayes Core file). Lower the cap temporarily
while iterating on primitives if a regression re-opens an infinite
loop in later tests.
MD
echo "$SUMMARY"
echo "Scoreboard: $OUT_JSON"
echo " $OUT_MD"
if [ "$STATUS" -ne 0 ] && [ "$TOTAL" -eq 0 ]; then
exit 1
fi

134
lib/forth/hayes-runner.sx Normal file
View File

@@ -0,0 +1,134 @@
;; Hayes conformance test runner.
;; Installs T{ -> }T as Forth primitives that snapshot and compare dstack,
;; plus stub TESTING / HEX / DECIMAL so the Hayes Core file can stream
;; through the interpreter without halting on unsupported metadata words.
(define hayes-pass 0)
(define hayes-fail 0)
(define hayes-error 0)
(define hayes-start-depth 0)
(define hayes-actual (list))
(define hayes-actual-set false)
(define hayes-failures (list))
(define hayes-first-error "")
(define
hayes-reset!
(fn
()
(set! hayes-pass 0)
(set! hayes-fail 0)
(set! hayes-error 0)
(set! hayes-start-depth 0)
(set! hayes-actual (list))
(set! hayes-actual-set false)
(set! hayes-failures (list))
(set! hayes-first-error "")))
(define
hayes-slice
(fn
(state base)
(let
((n (- (forth-depth state) base)))
(if (<= n 0) (list) (take (get state "dstack") n)))))
(define
hayes-truncate!
(fn
(state base)
(let
((n (- (forth-depth state) base)))
(when (> n 0) (dict-set! state "dstack" (drop (get state "dstack") n))))))
(define
hayes-install!
(fn
(state)
(forth-def-prim!
state
"T{"
(fn
(s)
(set! hayes-start-depth (forth-depth s))
(set! hayes-actual-set false)
(set! hayes-actual (list))))
(forth-def-prim!
state
"->"
(fn
(s)
(set! hayes-actual (hayes-slice s hayes-start-depth))
(set! hayes-actual-set true)
(hayes-truncate! s hayes-start-depth)))
(forth-def-prim!
state
"}T"
(fn
(s)
(let
((expected (hayes-slice s hayes-start-depth)))
(hayes-truncate! s hayes-start-depth)
(if
(and hayes-actual-set (= expected hayes-actual))
(set! hayes-pass (+ hayes-pass 1))
(begin
(set! hayes-fail (+ hayes-fail 1))
(set!
hayes-failures
(concat
hayes-failures
(list
(dict
"kind"
"fail"
"expected"
(str expected)
"actual"
(str hayes-actual))))))))))
(forth-def-prim! state "TESTING" (fn (s) nil))
;; HEX/DECIMAL are real primitives now (runtime.sx) — no stub needed.
state))
(define
hayes-boot
(fn () (let ((s (forth-boot))) (hayes-install! s) (hayes-reset!) s)))
;; Run a single preprocessed chunk (string of Forth source) on the shared
;; state. Catch any raised error and move on — the chunk boundary is a
;; safe resume point.
(define
hayes-run-chunk
(fn
(state src)
(guard
(err
((= 1 1)
(begin
(set! hayes-error (+ hayes-error 1))
(when
(= (len hayes-first-error) 0)
(set! hayes-first-error (str err)))
(dict-set! state "dstack" (list))
(dict-set! state "rstack" (list))
(dict-set! state "compiling" false)
(dict-set! state "current-def" nil)
(dict-set! state "cstack" (list))
(dict-set! state "input" (list)))))
(forth-interpret state src))))
(define
hayes-summary
(fn
()
(dict
"pass"
hayes-pass
"fail"
hayes-fail
"error"
hayes-error
"total"
(+ (+ hayes-pass hayes-fail) hayes-error)
"first-error"
hayes-first-error)))

2
lib/forth/interpreter.sx
View File

@@ -17,7 +17,7 @@
(not (nil? w))
(forth-execute-word state w)
(let
((n (forth-parse-number tok (get state "base"))))
((n (forth-parse-number tok (get (get state "vars") "base"))))
(if
(not (nil? n))
(forth-push state n)

790
lib/forth/runtime.sx
View File

@@ -18,10 +18,119 @@
(dict-set! s "output" "")
(dict-set! s "compiling" false)
(dict-set! s "current-def" nil)
(dict-set! s "base" 10)
(dict-set! s "vars" (dict))
(dict-set! (get s "vars") "base" 10)
(dict-set! s "cstack" (list))
(dict-set! s "mem" (dict))
(dict-set! s "here" 0)
(dict-set! s "hold" (list))
s)))
(define
forth-mem-write!
(fn (state addr u) (dict-set! (get state "mem") (str addr) u)))
(define
forth-mem-read
(fn
(state addr)
(or (get (get state "mem") (str addr)) 0)))
(define
forth-alloc-bytes!
(fn
(state n)
(let
((addr (get state "here")))
(dict-set! state "here" (+ addr n))
addr)))
(define
forth-mem-write-string!
(fn
(state addr s)
(let
((n (len s)))
(forth-mem-write-string-loop! state addr s 0 n))))
(define
forth-mem-write-string-loop!
(fn
(state addr s i n)
(when
(< i n)
(begin
(forth-mem-write! state (+ addr i) (char-code (substr s i 1)))
(forth-mem-write-string-loop! state addr s (+ i 1) n)))))
(define
forth-mem-read-string
(fn
(state addr n)
(forth-mem-read-string-loop state addr 0 n "")))
(define
forth-mem-read-string-loop
(fn
(state addr i n acc)
(if
(>= i n)
acc
(forth-mem-read-string-loop
state
addr
(+ i 1)
n
(str acc (char-from-code (forth-mem-read state (+ addr i))))))))
(define
forth-fill-loop
(fn
(state addr u char i)
(when
(< i u)
(begin
(forth-mem-write! state (+ addr i) char)
(forth-fill-loop state addr u char (+ i 1))))))
(define
forth-cmove-loop
(fn
(state src dst u i)
(when
(< i u)
(begin
(forth-mem-write! state (+ dst i) (forth-mem-read state (+ src i)))
(forth-cmove-loop state src dst u (+ i 1))))))
(define
forth-cmove-loop-desc
(fn
(state src dst u i)
(when
(>= i 0)
(begin
(forth-mem-write! state (+ dst i) (forth-mem-read state (+ src i)))
(forth-cmove-loop-desc state src dst u (- i 1))))))
(define
forth-cpush
(fn (state v) (dict-set! state "cstack" (cons v (get state "cstack")))))
(define
forth-cpop
(fn
(state)
(let
((cs (get state "cstack")))
(if
(= (len cs) 0)
(forth-error state "control stack underflow")
(let
((top (first cs)))
(dict-set! state "cstack" (rest cs))
top)))))
(define
forth-error
(fn (state msg) (dict-set! state "error" msg) (raise msg)))
@@ -99,7 +208,8 @@
(dict-set!
(get state "dict")
(downcase name)
(forth-make-word "primitive" body false))))
(forth-make-word "primitive" body false))
(dict-set! state "last-defined" name)))
(define
forth-def-prim-imm!
@@ -108,7 +218,8 @@
(dict-set!
(get state "dict")
(downcase name)
(forth-make-word "primitive" body true))))
(forth-make-word "primitive" body true))
(dict-set! state "last-defined" name)))
(define
forth-lookup
@@ -166,6 +277,146 @@
(define forth-bits-width 32)
;; Truncate a number to the Forth 32-bit signed range (two's-complement).
;; Used by arithmetic primitives so wrap-around matches ANS semantics and
;; loop idioms that rely on MSB becoming 0 after enough shifts terminate.
(define
forth-clip
(fn
(n)
(forth-from-unsigned
(forth-to-unsigned n forth-bits-width)
forth-bits-width)))
;; Double-cell helpers. Single = 32-bit signed, double = 64-bit signed
;; represented on the data stack as (lo, hi) where hi is on top.
;; Reassembly converts the low cell as unsigned and the high cell as
;; signed (signed) or as unsigned (unsigned), then combines.
(define forth-2pow32 (pow 2 32))
(define forth-2pow64 (pow 2 64))
(define
forth-double-from-cells-u
(fn
(lo hi)
(+ (forth-to-unsigned lo 32) (* (forth-to-unsigned hi 32) forth-2pow32))))
(define
forth-double-from-cells-s
(fn (lo hi) (+ (forth-to-unsigned lo 32) (* hi forth-2pow32))))
(define
forth-double-push-u
(fn
(state d)
(let
((lo (mod d forth-2pow32)) (hi (floor (/ d forth-2pow32))))
(forth-push state (forth-from-unsigned lo 32))
(forth-push state (forth-from-unsigned hi 32)))))
(define
forth-num-to-string-loop
(fn
(u base acc)
(if
(= u 0)
acc
(let
((dig (mod u base)) (rest (floor (/ u base))))
(let
((ch
(if
(< dig 10)
(char-from-code (+ 48 dig))
(char-from-code (+ 55 dig)))))
(forth-num-to-string-loop rest base (str ch acc)))))))
(define
forth-num-to-string
(fn
(u base)
(if (= u 0) "0" (forth-num-to-string-loop u base ""))))
(define
forth-spaces-str
(fn
(n)
(if (<= n 0) "" (str " " (forth-spaces-str (- n 1))))))
(define
forth-join-hold
(fn
(parts)
(forth-join-hold-loop parts "")))
(define
forth-join-hold-loop
(fn
(parts acc)
(if
(= (len parts) 0)
acc
(forth-join-hold-loop (rest parts) (str acc (first parts))))))
(define
forth-pic-step
(fn
(state)
(let
((hi (forth-pop state)) (lo (forth-pop state)))
(let
((d (forth-double-from-cells-u lo hi))
(b (get (get state "vars") "base")))
(let
((dig (mod d b)) (rest (floor (/ d b))))
(let
((ch
(if
(< dig 10)
(char-from-code (+ 48 dig))
(char-from-code (+ 55 dig)))))
(dict-set! state "hold" (cons ch (get state "hold")))
(forth-double-push-u state rest)))))))
(define
forth-pic-S-loop
(fn
(state)
(forth-pic-step state)
(let
((hi (forth-pop state)) (lo (forth-pop state)))
(if
(and (= lo 0) (= hi 0))
(begin (forth-push state 0) (forth-push state 0))
(begin
(forth-push state lo)
(forth-push state hi)
(forth-pic-S-loop state))))))
(define
forth-double-push-s
(fn
(state d)
(if
(>= d 0)
(forth-double-push-u state d)
(let
((q (- 0 d)))
(let
((qlo (mod q forth-2pow32)) (qhi (floor (/ q forth-2pow32))))
(if
(= qlo 0)
(begin
(forth-push state 0)
(forth-push state (forth-from-unsigned (- forth-2pow32 qhi) 32)))
(begin
(forth-push
state
(forth-from-unsigned (- forth-2pow32 qlo) 32))
(forth-push
state
(forth-from-unsigned (- (- forth-2pow32 qhi) 1) 32)))))))))
(define
forth-to-unsigned
(fn (n w) (let ((m (pow 2 w))) (mod (+ (mod n m) m) m))))
@@ -285,6 +536,19 @@
(s)
(let ((a (forth-peek s))) (when (not (= a 0)) (forth-push s a)))))
(forth-def-prim! state "DEPTH" (fn (s) (forth-push s (forth-depth s))))
(forth-def-prim! state "SP@" (fn (s) (forth-push s (forth-depth s))))
(forth-def-prim!
state
"SP!"
(fn
(s)
(let
((n (forth-pop s)))
(let
((cur (forth-depth s)))
(when
(> cur n)
(dict-set! s "dstack" (drop (get s "dstack") (- cur n))))))))
(forth-def-prim!
state
"PICK"
@@ -354,11 +618,17 @@
(forth-push s d)
(forth-push s a)
(forth-push s b))))
(forth-def-prim! state "+" (forth-binop (fn (a b) (+ a b))))
(forth-def-prim! state "-" (forth-binop (fn (a b) (- a b))))
(forth-def-prim! state "*" (forth-binop (fn (a b) (* a b))))
(forth-def-prim! state "/" (forth-binop forth-div))
(forth-def-prim! state "MOD" (forth-binop forth-mod))
(forth-def-prim! state "+" (forth-binop (fn (a b) (forth-clip (+ a b)))))
(forth-def-prim! state "-" (forth-binop (fn (a b) (forth-clip (- a b)))))
(forth-def-prim! state "*" (forth-binop (fn (a b) (forth-clip (* a b)))))
(forth-def-prim!
state
"/"
(forth-binop (fn (a b) (forth-clip (forth-div a b)))))
(forth-def-prim!
state
"MOD"
(forth-binop (fn (a b) (forth-clip (forth-mod a b)))))
(forth-def-prim!
state
"/MOD"
@@ -368,8 +638,8 @@
((b (forth-pop s)) (a (forth-pop s)))
(forth-push s (forth-mod a b))
(forth-push s (forth-div a b)))))
(forth-def-prim! state "NEGATE" (forth-unop (fn (a) (- 0 a))))
(forth-def-prim! state "ABS" (forth-unop abs))
(forth-def-prim! state "NEGATE" (forth-unop (fn (a) (forth-clip (- 0 a)))))
(forth-def-prim! state "ABS" (forth-unop (fn (a) (forth-clip (abs a)))))
(forth-def-prim!
state
"MIN"
@@ -378,12 +648,15 @@
state
"MAX"
(forth-binop (fn (a b) (if (> a b) a b))))
(forth-def-prim! state "1+" (forth-unop (fn (a) (+ a 1))))
(forth-def-prim! state "1-" (forth-unop (fn (a) (- a 1))))
(forth-def-prim! state "2+" (forth-unop (fn (a) (+ a 2))))
(forth-def-prim! state "2-" (forth-unop (fn (a) (- a 2))))
(forth-def-prim! state "2*" (forth-unop (fn (a) (* a 2))))
(forth-def-prim! state "2/" (forth-unop (fn (a) (floor (/ a 2)))))
(forth-def-prim! state "1+" (forth-unop (fn (a) (forth-clip (+ a 1)))))
(forth-def-prim! state "1-" (forth-unop (fn (a) (forth-clip (- a 1)))))
(forth-def-prim! state "2+" (forth-unop (fn (a) (forth-clip (+ a 2)))))
(forth-def-prim! state "2-" (forth-unop (fn (a) (forth-clip (- a 2)))))
(forth-def-prim! state "2*" (forth-unop (fn (a) (forth-clip (* a 2)))))
(forth-def-prim!
state
"2/"
(forth-unop (fn (a) (forth-clip (floor (/ a 2))))))
(forth-def-prim! state "=" (forth-cmp (fn (a b) (= a b))))
(forth-def-prim! state "<>" (forth-cmp (fn (a b) (not (= a b)))))
(forth-def-prim! state "<" (forth-cmp (fn (a b) (< a b))))
@@ -398,6 +671,30 @@
(forth-def-prim! state "OR" (forth-binop forth-bit-or))
(forth-def-prim! state "XOR" (forth-binop forth-bit-xor))
(forth-def-prim! state "INVERT" (forth-unop forth-bit-invert))
(forth-def-prim!
state
"LSHIFT"
(fn
(s)
(let
((u (forth-pop s)) (x (forth-pop s)))
(let
((ux (forth-to-unsigned x forth-bits-width)))
(let
((res (mod (* ux (pow 2 u)) (pow 2 forth-bits-width))))
(forth-push s (forth-from-unsigned res forth-bits-width)))))))
(forth-def-prim!
state
"RSHIFT"
(fn
(s)
(let
((u (forth-pop s)) (x (forth-pop s)))
(let
((ux (forth-to-unsigned x forth-bits-width)))
(let
((res (floor (/ ux (pow 2 u)))))
(forth-push s (forth-from-unsigned res forth-bits-width)))))))
(forth-def-prim!
state
"."
@@ -416,7 +713,7 @@
(forth-def-prim!
state
"EMIT"
(fn (s) (forth-emit-str s (code-char (forth-pop s)))))
(fn (s) (forth-emit-str s (char-from-code (forth-pop s)))))
(forth-def-prim! state "CR" (fn (s) (forth-emit-str s "\n")))
(forth-def-prim! state "SPACE" (fn (s) (forth-emit-str s " ")))
(forth-def-prim!
@@ -430,4 +727,463 @@
(> n 0)
(for-each (fn (_) (forth-emit-str s " ")) (range 0 n))))))
(forth-def-prim! state "BL" (fn (s) (forth-push s 32)))
(forth-def-prim!
state
"DECIMAL"
(fn (s) (dict-set! (get s "vars") "base" 10)))
(forth-def-prim!
state
"HEX"
(fn (s) (dict-set! (get s "vars") "base" 16)))
(forth-def-prim!
state
"BIN"
(fn (s) (dict-set! (get s "vars") "base" 2)))
(forth-def-prim!
state
"OCTAL"
(fn (s) (dict-set! (get s "vars") "base" 8)))
(forth-def-prim! state "BASE" (fn (s) (forth-push s "base")))
(forth-def-prim! state "I" (fn (s) (forth-push s (forth-rpeek s))))
(forth-def-prim!
state
"J"
(fn (s) (forth-push s (nth (get s "rstack") 2))))
(forth-def-prim! state ">R" (fn (s) (forth-rpush s (forth-pop s))))
(forth-def-prim! state "R>" (fn (s) (forth-push s (forth-rpop s))))
(forth-def-prim! state "R@" (fn (s) (forth-push s (forth-rpeek s))))
(forth-def-prim!
state
"2>R"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-rpush s a)
(forth-rpush s b))))
(forth-def-prim!
state
"2R>"
(fn
(s)
(let
((b (forth-rpop s)) (a (forth-rpop s)))
(forth-push s a)
(forth-push s b))))
(forth-def-prim!
state
"2R@"
(fn
(s)
(let
((rs (get s "rstack")))
(when
(< (len rs) 2)
(forth-error s "return stack underflow"))
(forth-push s (nth rs 1))
(forth-push s (nth rs 0)))))
(forth-def-prim!
state
"C@"
(fn
(s)
(let ((addr (forth-pop s))) (forth-push s (forth-mem-read s addr)))))
(forth-def-prim!
state
"C!"
(fn
(s)
(let
((addr (forth-pop s)) (v (forth-pop s)))
(forth-mem-write! s addr v))))
(forth-def-prim! state "CHAR+" (fn (s) (forth-push s (+ (forth-pop s) 1))))
(forth-def-prim! state "CHARS" (fn (s) nil))
(forth-def-prim!
state
"TYPE"
(fn
(s)
(let
((u (forth-pop s)) (addr (forth-pop s)))
(forth-emit-str s (forth-mem-read-string s addr u)))))
(forth-def-prim!
state
"COUNT"
(fn
(s)
(let
((addr (forth-pop s)))
(let
((u (forth-mem-read s addr)))
(forth-push s (+ addr 1))
(forth-push s u)))))
(forth-def-prim!
state
"FILL"
(fn
(s)
(let
((char (forth-pop s)) (u (forth-pop s)) (addr (forth-pop s)))
(forth-fill-loop s addr u char 0))))
(forth-def-prim!
state
"BLANK"
(fn
(s)
(let
((u (forth-pop s)) (addr (forth-pop s)))
(forth-fill-loop s addr u 32 0))))
(forth-def-prim!
state
"CMOVE"
(fn
(s)
(let
((u (forth-pop s)) (dst (forth-pop s)) (src (forth-pop s)))
(forth-cmove-loop s src dst u 0))))
(forth-def-prim!
state
"CMOVE>"
(fn
(s)
(let
((u (forth-pop s)) (dst (forth-pop s)) (src (forth-pop s)))
(forth-cmove-loop-desc s src dst u (- u 1)))))
(forth-def-prim!
state
"MOVE"
(fn
(s)
(let
((u (forth-pop s)) (dst (forth-pop s)) (src (forth-pop s)))
(if
(or (<= dst src) (>= dst (+ src u)))
(forth-cmove-loop s src dst u 0)
(forth-cmove-loop-desc s src dst u (- u 1))))))
(forth-def-prim!
state
"S>D"
(fn
(s)
(let
((n (forth-pop s)))
(forth-push s n)
(forth-push s (if (< n 0) -1 0)))))
(forth-def-prim! state "D>S" (fn (s) (forth-pop s)))
(forth-def-prim!
state
"M*"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-double-push-s s (* a b)))))
(forth-def-prim!
state
"UM*"
(fn
(s)
(let
((b (forth-pop s)) (a (forth-pop s)))
(forth-double-push-u
s
(* (forth-to-unsigned a 32) (forth-to-unsigned b 32))))))
(forth-def-prim!
state
"UM/MOD"
(fn
(s)
(let
((u1 (forth-pop s)) (hi (forth-pop s)) (lo (forth-pop s)))
(let
((d (forth-double-from-cells-u lo hi))
(divisor (forth-to-unsigned u1 32)))
(when (= divisor 0) (forth-error s "division by zero"))
(let
((q (floor (/ d divisor))) (r (mod d divisor)))
(forth-push s (forth-from-unsigned r 32))
(forth-push s (forth-from-unsigned q 32)))))))
(forth-def-prim!
state
"FM/MOD"
(fn
(s)
(let
((n (forth-pop s)) (hi (forth-pop s)) (lo (forth-pop s)))
(let
((d (forth-double-from-cells-s lo hi)))
(when (= n 0) (forth-error s "division by zero"))
(let
((q (floor (/ d n))))
(let
((r (- d (* q n))))
(forth-push s (forth-clip r))
(forth-push s (forth-clip q))))))))
(forth-def-prim!
state
"SM/REM"
(fn
(s)
(let
((n (forth-pop s)) (hi (forth-pop s)) (lo (forth-pop s)))
(let
((d (forth-double-from-cells-s lo hi)))
(when (= n 0) (forth-error s "division by zero"))
(let
((q (forth-trunc (/ d n))))
(let
((r (- d (* q n))))
(forth-push s (forth-clip r))
(forth-push s (forth-clip q))))))))
(forth-def-prim!
state
"*/"
(fn
(s)
(let
((n3 (forth-pop s)) (n2 (forth-pop s)) (n1 (forth-pop s)))
(when (= n3 0) (forth-error s "division by zero"))
(forth-push s (forth-clip (forth-trunc (/ (* n1 n2) n3)))))))
(forth-def-prim!
state
"*/MOD"
(fn
(s)
(let
((n3 (forth-pop s)) (n2 (forth-pop s)) (n1 (forth-pop s)))
(when (= n3 0) (forth-error s "division by zero"))
(let
((d (* n1 n2)))
(let
((q (forth-trunc (/ d n3))))
(let
((r (- d (* q n3))))
(forth-push s (forth-clip r))
(forth-push s (forth-clip q))))))))
(forth-def-prim!
state
"D+"
(fn
(s)
(let
((hi2 (forth-pop s))
(lo2 (forth-pop s))
(hi1 (forth-pop s))
(lo1 (forth-pop s)))
(forth-double-push-s
s
(+
(forth-double-from-cells-s lo1 hi1)
(forth-double-from-cells-s lo2 hi2))))))
(forth-def-prim!
state
"D-"
(fn
(s)
(let
((hi2 (forth-pop s))
(lo2 (forth-pop s))
(hi1 (forth-pop s))
(lo1 (forth-pop s)))
(forth-double-push-s
s
(-
(forth-double-from-cells-s lo1 hi1)
(forth-double-from-cells-s lo2 hi2))))))
(forth-def-prim!
state
"DNEGATE"
(fn
(s)
(let
((hi (forth-pop s)) (lo (forth-pop s)))
(forth-double-push-s
s
(- 0 (forth-double-from-cells-s lo hi))))))
(forth-def-prim!
state
"DABS"
(fn
(s)
(let
((hi (forth-pop s)) (lo (forth-pop s)))
(forth-double-push-s s (abs (forth-double-from-cells-s lo hi))))))
(forth-def-prim!
state
"D="
(fn
(s)
(let
((hi2 (forth-pop s))
(lo2 (forth-pop s))
(hi1 (forth-pop s))
(lo1 (forth-pop s)))
(forth-push s (if (and (= lo1 lo2) (= hi1 hi2)) -1 0)))))
(forth-def-prim!
state
"D<"
(fn
(s)
(let
((hi2 (forth-pop s))
(lo2 (forth-pop s))
(hi1 (forth-pop s))
(lo1 (forth-pop s)))
(forth-push
s
(if
(<
(forth-double-from-cells-s lo1 hi1)
(forth-double-from-cells-s lo2 hi2))
-1
0)))))
(forth-def-prim!
state
"D0="
(fn
(s)
(let
((hi (forth-pop s)) (lo (forth-pop s)))
(forth-push s (if (and (= lo 0) (= hi 0)) -1 0)))))
(forth-def-prim!
state
"D0<"
(fn
(s)
(let
((hi (forth-pop s)) (lo (forth-pop s)))
(forth-push s (if (< hi 0) -1 0)))))
(forth-def-prim!
state
"DMAX"
(fn
(s)
(let
((hi2 (forth-pop s))
(lo2 (forth-pop s))
(hi1 (forth-pop s))
(lo1 (forth-pop s)))
(let
((d1 (forth-double-from-cells-s lo1 hi1))
(d2 (forth-double-from-cells-s lo2 hi2)))
(forth-double-push-s s (if (> d1 d2) d1 d2))))))
(forth-def-prim!
state
"DMIN"
(fn
(s)
(let
((hi2 (forth-pop s))
(lo2 (forth-pop s))
(hi1 (forth-pop s))
(lo1 (forth-pop s)))
(let
((d1 (forth-double-from-cells-s lo1 hi1))
(d2 (forth-double-from-cells-s lo2 hi2)))
(forth-double-push-s s (if (< d1 d2) d1 d2))))))
(forth-def-prim! state "<#" (fn (s) (dict-set! s "hold" (list))))
(forth-def-prim!
state
"HOLD"
(fn
(s)
(let
((c (forth-pop s)))
(dict-set!
s
"hold"
(cons (char-from-code c) (get s "hold"))))))
(forth-def-prim!
state
"SIGN"
(fn
(s)
(let
((n (forth-pop s)))
(when
(< n 0)
(dict-set! s "hold" (cons "-" (get s "hold")))))))
(forth-def-prim!
state
"#"
(fn
(s)
(let
((hi (forth-pop s)) (lo (forth-pop s)))
(let
((d (forth-double-from-cells-u lo hi))
(b (get (get s "vars") "base")))
(let
((dig (mod d b)) (rest (floor (/ d b))))
(let
((ch
(if
(< dig 10)
(char-from-code (+ 48 dig))
(char-from-code (+ 55 dig)))))
(dict-set! s "hold" (cons ch (get s "hold")))
(forth-double-push-u s rest)))))))
(forth-def-prim!
state
"#S"
(fn
(s)
(forth-pic-S-loop s)))
(forth-def-prim!
state
"#>"
(fn
(s)
(forth-pop s)
(forth-pop s)
(let
((str-out (forth-join-hold (get s "hold"))))
(let
((addr (forth-alloc-bytes! s (len str-out))))
(forth-mem-write-string! s addr str-out)
(forth-push s addr)
(forth-push s (len str-out))))))
(forth-def-prim!
state
"U."
(fn
(s)
(let
((u (forth-to-unsigned (forth-pop s) 32))
(b (get (get s "vars") "base")))
(forth-emit-str s (str (forth-num-to-string u b) " ")))))
(forth-def-prim!
state
"U.R"
(fn
(s)
(let
((width (forth-pop s))
(u (forth-to-unsigned (forth-pop s) 32))
(b (get (get s "vars") "base")))
(let
((digits (forth-num-to-string u b)))
(forth-emit-str
s
(forth-spaces-str (- width (len digits))))
(forth-emit-str s digits)))))
(forth-def-prim!
state
".R"
(fn
(s)
(let
((width (forth-pop s))
(n (forth-pop s))
(b (get (get s "vars") "base")))
(let
((sign-prefix (if (< n 0) "-" ""))
(abs-digits
(forth-num-to-string (forth-to-unsigned (abs n) 32) b)))
(let
((digits (str sign-prefix abs-digits)))
(forth-emit-str
s
(forth-spaces-str (- width (len digits))))
(forth-emit-str s digits))))))
state))

12
lib/forth/scoreboard.json Normal file
View File

@@ -0,0 +1,12 @@
{
"source": "gerryjackson/forth2012-test-suite src/core.fr",
"generated_at": "2026-04-25T01:22:10Z",
"chunks_available": 638,
"chunks_fed": 638,
"total": 638,
"pass": 477,
"fail": 14,
"error": 147,
"percent": 74,
"note": "completed"
}

28
lib/forth/scoreboard.md Normal file
View File

@@ -0,0 +1,28 @@
# Forth Hayes Core scoreboard
| metric | value |
| ----------------- | ----: |
| chunks available | 638 |
| chunks fed | 638 |
| total | 638 |
| pass | 477 |
| fail | 14 |
| error | 147 |
| percent | 74% |
- **Source**: `gerryjackson/forth2012-test-suite` `src/core.fr`
- **Generated**: 2026-04-25T01:22:10Z
- **Note**: completed
A "chunk" is any preprocessed segment ending at a `}T` (every Hayes test
is one chunk, plus the small declaration blocks between tests).
The runner catches raised errors at chunk boundaries so one bad chunk
does not abort the rest. `error` covers chunks that raised; `fail`
covers tests whose `->` / `}T` comparison mismatched.
### Chunk cap
`conformance.sh` processes the first `$MAX_CHUNKS` chunks (default
**638**, i.e. the whole Hayes Core file). Lower the cap temporarily
while iterating on primitives if a regression re-opens an infinite
loop in later tests.

239
lib/forth/tests/test-phase3.sx Normal file
View File

@@ -0,0 +1,239 @@
;; Phase 3 — control flow (IF/ELSE/THEN, BEGIN/UNTIL/WHILE/REPEAT/AGAIN,
;; DO/LOOP, return stack). Grows as each control construct lands.
(define forth-p3-passed 0)
(define forth-p3-failed 0)
(define forth-p3-failures (list))
(define
forth-p3-assert
(fn
(label expected actual)
(if
(= expected actual)
(set! forth-p3-passed (+ forth-p3-passed 1))
(begin
(set! forth-p3-failed (+ forth-p3-failed 1))
(set!
forth-p3-failures
(concat
forth-p3-failures
(list
(str label ": expected " (str expected) " got " (str actual)))))))))
(define
forth-p3-check-stack
(fn
(label src expected)
(let ((r (forth-run src))) (forth-p3-assert label expected (nth r 2)))))
(define
forth-p3-if-tests
(fn
()
(forth-p3-check-stack
"IF taken (-1)"
": Q -1 IF 10 THEN ; Q"
(list 10))
(forth-p3-check-stack
"IF not taken (0)"
": Q 0 IF 10 THEN ; Q"
(list))
(forth-p3-check-stack
"IF with non-zero truthy"
": Q 42 IF 10 THEN ; Q"
(list 10))
(forth-p3-check-stack
"IF ELSE — true branch"
": Q -1 IF 10 ELSE 20 THEN ; Q"
(list 10))
(forth-p3-check-stack
"IF ELSE — false branch"
": Q 0 IF 10 ELSE 20 THEN ; Q"
(list 20))
(forth-p3-check-stack
"IF consumes flag"
": Q IF 1 ELSE 2 THEN ; 0 Q"
(list 2))
(forth-p3-check-stack
"absolute value via IF"
": ABS2 DUP 0 < IF NEGATE THEN ; -7 ABS2"
(list 7))
(forth-p3-check-stack
"abs leaves positive alone"
": ABS2 DUP 0 < IF NEGATE THEN ; 7 ABS2"
(list 7))
(forth-p3-check-stack
"sign: negative"
": SIGN DUP 0 < IF DROP -1 ELSE DROP 1 THEN ; -3 SIGN"
(list -1))
(forth-p3-check-stack
"sign: positive"
": SIGN DUP 0 < IF DROP -1 ELSE DROP 1 THEN ; 3 SIGN"
(list 1))
(forth-p3-check-stack
"nested IF (both true)"
": Q 1 IF 1 IF 10 ELSE 20 THEN ELSE 30 THEN ; Q"
(list 10))
(forth-p3-check-stack
"nested IF (inner false)"
": Q 1 IF 0 IF 10 ELSE 20 THEN ELSE 30 THEN ; Q"
(list 20))
(forth-p3-check-stack
"nested IF (outer false)"
": Q 0 IF 0 IF 10 ELSE 20 THEN ELSE 30 THEN ; Q"
(list 30))
(forth-p3-check-stack
"IF before other ops"
": Q 1 IF 5 ELSE 6 THEN 2 * ; Q"
(list 10))
(forth-p3-check-stack
"IF in chained def"
": POS? 0 > ;
: DOUBLE-IF-POS DUP POS? IF 2 * THEN ;
3 DOUBLE-IF-POS"
(list 6))
(forth-p3-check-stack
"empty then branch"
": Q 1 IF THEN 99 ; Q"
(list 99))
(forth-p3-check-stack
"empty else branch"
": Q 0 IF 99 ELSE THEN ; Q"
(list))
(forth-p3-check-stack
"sequential IF blocks"
": Q -1 IF 1 THEN -1 IF 2 THEN ; Q"
(list 1 2))))
(define
forth-p3-loop-tests
(fn
()
(forth-p3-check-stack
"BEGIN UNTIL (countdown to zero)"
": CD BEGIN 1- DUP 0 = UNTIL ; 3 CD"
(list 0))
(forth-p3-check-stack
"BEGIN UNTIL — single pass (UNTIL true immediately)"
": Q BEGIN -1 UNTIL 42 ; Q"
(list 42))
(forth-p3-check-stack
"BEGIN UNTIL — accumulate sum 1+2+3"
": SUM3 0 3 BEGIN TUCK + SWAP 1- DUP 0 = UNTIL DROP ; SUM3"
(list 6))
(forth-p3-check-stack
"BEGIN WHILE REPEAT — triangular sum 5"
": TRI 0 5 BEGIN DUP 0 > WHILE TUCK + SWAP 1- REPEAT DROP ; TRI"
(list 15))
(forth-p3-check-stack
"BEGIN WHILE REPEAT — zero iterations"
": TRI 0 0 BEGIN DUP 0 > WHILE TUCK + SWAP 1- REPEAT DROP ; TRI"
(list 0))
(forth-p3-check-stack
"BEGIN WHILE REPEAT — one iteration"
": TRI 0 1 BEGIN DUP 0 > WHILE TUCK + SWAP 1- REPEAT DROP ; TRI"
(list 1))
(forth-p3-check-stack
"nested BEGIN UNTIL"
": INNER BEGIN 1- DUP 0 = UNTIL DROP ;
: OUTER BEGIN 3 INNER 1- DUP 0 = UNTIL ;
2 OUTER"
(list 0))
(forth-p3-check-stack
"BEGIN UNTIL after colon prefix"
": TEN 10 ;
: CD TEN BEGIN 1- DUP 0 = UNTIL ;
CD"
(list 0))
(forth-p3-check-stack
"WHILE inside IF branch"
": Q 1 IF 0 3 BEGIN DUP 0 > WHILE TUCK + SWAP 1- REPEAT DROP ELSE 99 THEN ; Q"
(list 6))))
(define
forth-p3-do-tests
(fn
()
(forth-p3-check-stack
"DO LOOP — simple sum 0..4"
": SUM 0 5 0 DO I + LOOP ; SUM"
(list 10))
(forth-p3-check-stack
"DO LOOP — 10..14 sum using I"
": SUM 0 15 10 DO I + LOOP ; SUM"
(list 60))
(forth-p3-check-stack
"DO LOOP — limit = start runs one pass"
": SUM 0 5 5 DO I + LOOP ; SUM"
(list 5))
(forth-p3-check-stack
"DO LOOP — count iterations"
": COUNT 0 4 0 DO 1+ LOOP ; COUNT"
(list 4))
(forth-p3-check-stack
"DO LOOP — nested, I inner / J outer"
": MATRIX 0 3 0 DO 3 0 DO I J + + LOOP LOOP ; MATRIX"
(list 18))
(forth-p3-check-stack
"DO LOOP — I used in arithmetic"
": DBL 0 5 1 DO I 2 * + LOOP ; DBL"
(list 20))
(forth-p3-check-stack
"+LOOP — count by 2"
": Q 0 10 0 DO I + 2 +LOOP ; Q"
(list 20))
(forth-p3-check-stack
"+LOOP — count by 3"
": Q 0 10 0 DO I + 3 +LOOP ; Q"
(list 18))
(forth-p3-check-stack
"+LOOP — negative step"
": Q 0 0 10 DO I + -1 +LOOP ; Q"
(list 55))
(forth-p3-check-stack
"LEAVE — early exit at I=3"
": Q 0 10 0 DO I 3 = IF LEAVE THEN I + LOOP ; Q"
(list 3))
(forth-p3-check-stack
"LEAVE — in nested loop exits only inner"
": Q 0 3 0 DO 5 0 DO I 2 = IF LEAVE THEN I + LOOP LOOP ; Q"
(list 3))
(forth-p3-check-stack
"DO LOOP preserves outer stack"
": Q 99 5 0 DO I + LOOP ; Q"
(list 109))
(forth-p3-check-stack
">R R>"
": Q 7 >R 11 R> ; Q"
(list 11 7))
(forth-p3-check-stack
">R R@ R>"
": Q 7 >R R@ R> ; Q"
(list 7 7))
(forth-p3-check-stack
"2>R 2R>"
": Q 1 2 2>R 99 2R> ; Q"
(list 99 1 2))
(forth-p3-check-stack
"2>R 2R@ 2R>"
": Q 3 4 2>R 2R@ 2R> ; Q"
(list 3 4 3 4))))
(define
forth-p3-run-all
(fn
()
(set! forth-p3-passed 0)
(set! forth-p3-failed 0)
(set! forth-p3-failures (list))
(forth-p3-if-tests)
(forth-p3-loop-tests)
(forth-p3-do-tests)
(dict
"passed"
forth-p3-passed
"failed"
forth-p3-failed
"failures"
forth-p3-failures)))

272
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;; Phase 4 — strings + more Core.
;; Uses the byte-memory model on state ("mem" dict + "here" cursor).
(define forth-p4-passed 0)
(define forth-p4-failed 0)
(define forth-p4-failures (list))
(define
forth-p4-assert
(fn
(label expected actual)
(if
(= expected actual)
(set! forth-p4-passed (+ forth-p4-passed 1))
(begin
(set! forth-p4-failed (+ forth-p4-failed 1))
(set!
forth-p4-failures
(concat
forth-p4-failures
(list
(str label ": expected " (str expected) " got " (str actual)))))))))
(define
forth-p4-check-output
(fn
(label src expected)
(let ((r (forth-run src))) (forth-p4-assert label expected (nth r 1)))))
(define
forth-p4-check-stack-size
(fn
(label src expected-n)
(let
((r (forth-run src)))
(forth-p4-assert label expected-n (len (nth r 2))))))
(define
forth-p4-check-top
(fn
(label src expected)
(let
((r (forth-run src)))
(let
((stk (nth r 2)))
(forth-p4-assert label expected (nth stk (- (len stk) 1)))))))
(define
forth-p4-check-typed
(fn
(label src expected)
(forth-p4-check-output label (str src " TYPE") expected)))
(define
forth-p4-string-tests
(fn
()
(forth-p4-check-typed
"S\" + TYPE — hello"
"S\" HELLO\""
"HELLO")
(forth-p4-check-typed
"S\" + TYPE — two words"
"S\" HELLO WORLD\""
"HELLO WORLD")
(forth-p4-check-typed
"S\" + TYPE — empty"
"S\" \""
"")
(forth-p4-check-typed
"S\" + TYPE — single char"
"S\" X\""
"X")
(forth-p4-check-stack-size
"S\" pushes (addr len)"
"S\" HI\""
2)
(forth-p4-check-top
"S\" length is correct"
"S\" HELLO\""
5)
(forth-p4-check-output
".\" prints at interpret time"
".\" HELLO\""
"HELLO")
(forth-p4-check-output
".\" in colon def"
": GREET .\" HI \" ; GREET GREET"
"HI HI ")))
(define
forth-p4-count-tests
(fn
()
(forth-p4-check-typed
"C\" + COUNT + TYPE"
"C\" ABC\" COUNT"
"ABC")
(forth-p4-check-typed
"C\" then COUNT leaves right len"
"C\" HI THERE\" COUNT"
"HI THERE")))
(define
forth-p4-fill-tests
(fn
()
(forth-p4-check-typed
"FILL overwrites prefix bytes"
"S\" ABCDE\" 2DUP DROP 3 65 FILL"
"AAADE")
(forth-p4-check-typed
"BLANK sets spaces"
"S\" XYZAB\" 2DUP DROP 3 BLANK"
" AB")))
(define
forth-p4-cmove-tests
(fn
()
(forth-p4-check-output
"CMOVE copies HELLO forward"
": MKH 72 0 C! 69 1 C! 76 2 C! 76 3 C! 79 4 C! ;
: T MKH 0 10 5 CMOVE 10 5 TYPE ; T"
"HELLO")
(forth-p4-check-output
"CMOVE> copies overlapping backward"
": MKA 65 0 C! 66 1 C! 67 2 C! ;
: T MKA 0 1 2 CMOVE> 0 3 TYPE ; T"
"AAB")
(forth-p4-check-output
"MOVE picks direction for overlap"
": MKA 65 0 C! 66 1 C! 67 2 C! ;
: T MKA 0 1 2 MOVE 0 3 TYPE ; T"
"AAB")))
(define
forth-p4-charplus-tests
(fn
()
(forth-p4-check-top
"CHAR+ increments"
"5 CHAR+"
6)))
(define
forth-p4-char-tests
(fn
()
(forth-p4-check-top "CHAR A -> 65" "CHAR A" 65)
(forth-p4-check-top "CHAR x -> 120" "CHAR x" 120)
(forth-p4-check-top "CHAR takes only first char" "CHAR HELLO" 72)
(forth-p4-check-top
"[CHAR] compiles literal"
": AA [CHAR] A ; AA"
65)
(forth-p4-check-top
"[CHAR] reads past IMMEDIATE"
": ZZ [CHAR] Z ; ZZ"
90)
(forth-p4-check-stack-size
"[CHAR] doesn't leak at compile time"
": FOO [CHAR] A ; "
0)))
(define
forth-p4-key-accept-tests
(fn
()
(let
((r (forth-run "1000 2 ACCEPT")))
(let ((stk (nth r 2))) (forth-p4-assert "ACCEPT empty buf -> 0" (list 0) stk)))))
(define
forth-p4-shift-tests
(fn
()
(forth-p4-check-top "1 0 LSHIFT" "1 0 LSHIFT" 1)
(forth-p4-check-top "1 1 LSHIFT" "1 1 LSHIFT" 2)
(forth-p4-check-top "1 2 LSHIFT" "1 2 LSHIFT" 4)
(forth-p4-check-top "1 15 LSHIFT" "1 15 LSHIFT" 32768)
(forth-p4-check-top "1 31 LSHIFT" "1 31 LSHIFT" -2147483648)
(forth-p4-check-top "1 0 RSHIFT" "1 0 RSHIFT" 1)
(forth-p4-check-top "1 1 RSHIFT" "1 1 RSHIFT" 0)
(forth-p4-check-top "2 1 RSHIFT" "2 1 RSHIFT" 1)
(forth-p4-check-top "4 2 RSHIFT" "4 2 RSHIFT" 1)
(forth-p4-check-top "-1 1 RSHIFT (logical, not arithmetic)" "-1 1 RSHIFT" 2147483647)
(forth-p4-check-top "MSB via 1S 1 RSHIFT INVERT" "0 INVERT 1 RSHIFT INVERT" -2147483648)))
(define
forth-p4-sp-tests
(fn
()
(forth-p4-check-top "SP@ returns depth (0)" "SP@" 0)
(forth-p4-check-top
"SP@ after pushes"
"1 2 3 SP@ SWAP DROP SWAP DROP SWAP DROP"
3)
(forth-p4-check-stack-size
"SP! truncates"
"1 2 3 4 5 2 SP!"
2)
(forth-p4-check-top
"SP! leaves base items intact"
"1 2 3 4 5 2 SP!"
2)))
(define
forth-p4-base-tests
(fn
()
(forth-p4-check-top
"BASE default is 10"
"BASE @"
10)
(forth-p4-check-top
"HEX switches base to 16"
"HEX BASE @"
16)
(forth-p4-check-top
"DECIMAL resets to 10"
"HEX DECIMAL BASE @"
10)
(forth-p4-check-top
"HEX parses 10 as 16"
"HEX 10"
16)
(forth-p4-check-top
"HEX parses FF as 255"
"HEX FF"
255)
(forth-p4-check-top
"DECIMAL parses 10 as 10"
"HEX DECIMAL 10"
10)
(forth-p4-check-top
"BIN parses 1010 as 10"
"BIN 1010"
10)
(forth-p4-check-top
"OCTAL parses 17 as 15"
"OCTAL 17"
15)
(forth-p4-check-top
"BASE @ ; 16 BASE ! ; BASE @"
"BASE @ 16 BASE ! BASE @ SWAP DROP"
16)))
(define
forth-p4-run-all
(fn
()
(set! forth-p4-passed 0)
(set! forth-p4-failed 0)
(set! forth-p4-failures (list))
(forth-p4-string-tests)
(forth-p4-count-tests)
(forth-p4-fill-tests)
(forth-p4-cmove-tests)
(forth-p4-charplus-tests)
(forth-p4-char-tests)
(forth-p4-key-accept-tests)
(forth-p4-base-tests)
(forth-p4-shift-tests)
(forth-p4-sp-tests)
(dict
"passed"
forth-p4-passed
"failed"
forth-p4-failed
"failures"
forth-p4-failures)))

256
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;; Phase 5 — Core Extension + memory primitives.
(define forth-p5-passed 0)
(define forth-p5-failed 0)
(define forth-p5-failures (list))
(define
forth-p5-assert
(fn
(label expected actual)
(if
(= expected actual)
(set! forth-p5-passed (+ forth-p5-passed 1))
(begin
(set! forth-p5-failed (+ forth-p5-failed 1))
(set!
forth-p5-failures
(concat
forth-p5-failures
(list
(str label ": expected " (str expected) " got " (str actual)))))))))
(define
forth-p5-check-stack
(fn
(label src expected)
(let ((r (forth-run src))) (forth-p5-assert label expected (nth r 2)))))
(define
forth-p5-check-top
(fn
(label src expected)
(let
((r (forth-run src)))
(let
((stk (nth r 2)))
(forth-p5-assert label expected (nth stk (- (len stk) 1)))))))
(define
forth-p5-create-tests
(fn
()
(forth-p5-check-top
"CREATE pushes HERE-at-creation"
"HERE CREATE FOO FOO ="
-1)
(forth-p5-check-top
"CREATE + ALLOT advances HERE"
"HERE 5 ALLOT HERE SWAP -"
5)
(forth-p5-check-top
"CREATE + , stores cell"
"CREATE FOO 42 , FOO @"
42)
(forth-p5-check-stack
"CREATE multiple ,"
"CREATE TBL 1 , 2 , 3 , TBL @ TBL CELL+ @ TBL CELL+ CELL+ @"
(list 1 2 3))
(forth-p5-check-top
"C, stores byte"
"CREATE B 65 C, 66 C, B C@"
65)))
(define
forth-p5-unsigned-tests
(fn
()
(forth-p5-check-top "1 2 U<" "1 2 U<" -1)
(forth-p5-check-top "2 1 U<" "2 1 U<" 0)
(forth-p5-check-top "0 1 U<" "0 1 U<" -1)
(forth-p5-check-top "-1 1 U< (since -1 unsigned is huge)" "-1 1 U<" 0)
(forth-p5-check-top "1 -1 U<" "1 -1 U<" -1)
(forth-p5-check-top "1 2 U>" "1 2 U>" 0)
(forth-p5-check-top "-1 1 U>" "-1 1 U>" -1)))
(define
forth-p5-2bang-tests
(fn
()
(forth-p5-check-stack
"2! / 2@"
"CREATE X 0 , 0 , 11 22 X 2! X 2@"
(list 11 22))))
(define
forth-p5-mixed-tests
(fn
()
(forth-p5-check-stack "S>D positive" "5 S>D" (list 5 0))
(forth-p5-check-stack "S>D negative" "-5 S>D" (list -5 -1))
(forth-p5-check-stack "S>D zero" "0 S>D" (list 0 0))
(forth-p5-check-top "D>S keeps low" "5 0 D>S" 5)
(forth-p5-check-stack "M* small positive" "3 4 M*" (list 12 0))
(forth-p5-check-stack "M* negative" "-3 4 M*" (list -12 -1))
(forth-p5-check-stack
"M* negative * negative"
"-3 -4 M*"
(list 12 0))
(forth-p5-check-stack "UM* small" "3 4 UM*" (list 12 0))
(forth-p5-check-stack
"UM/MOD: 100 0 / 5"
"100 0 5 UM/MOD"
(list 0 20))
(forth-p5-check-stack
"FM/MOD: -7 / 2 floored"
"-7 -1 2 FM/MOD"
(list 1 -4))
(forth-p5-check-stack
"SM/REM: -7 / 2 truncated"
"-7 -1 2 SM/REM"
(list -1 -3))
(forth-p5-check-top "*/ truncated" "7 11 13 */" 5)
(forth-p5-check-stack "*/MOD" "7 11 13 */MOD" (list 12 5))))
(define
forth-p5-double-tests
(fn
()
(forth-p5-check-stack "D+ small" "5 0 7 0 D+" (list 12 0))
(forth-p5-check-stack "D+ negative" "-5 -1 -3 -1 D+" (list -8 -1))
(forth-p5-check-stack "D- small" "10 0 3 0 D-" (list 7 0))
(forth-p5-check-stack "DNEGATE positive" "5 0 DNEGATE" (list -5 -1))
(forth-p5-check-stack "DNEGATE negative" "-5 -1 DNEGATE" (list 5 0))
(forth-p5-check-stack "DABS negative" "-7 -1 DABS" (list 7 0))
(forth-p5-check-stack "DABS positive" "7 0 DABS" (list 7 0))
(forth-p5-check-top "D= equal" "5 0 5 0 D=" -1)
(forth-p5-check-top "D= unequal lo" "5 0 7 0 D=" 0)
(forth-p5-check-top "D= unequal hi" "5 0 5 1 D=" 0)
(forth-p5-check-top "D< lt" "5 0 7 0 D<" -1)
(forth-p5-check-top "D< gt" "7 0 5 0 D<" 0)
(forth-p5-check-top "D0= zero" "0 0 D0=" -1)
(forth-p5-check-top "D0= nonzero" "5 0 D0=" 0)
(forth-p5-check-top "D0< neg" "-5 -1 D0<" -1)
(forth-p5-check-top "D0< pos" "5 0 D0<" 0)
(forth-p5-check-stack "DMAX" "5 0 7 0 DMAX" (list 7 0))
(forth-p5-check-stack "DMIN" "5 0 7 0 DMIN" (list 5 0))))
(define
forth-p5-format-tests
(fn
()
(forth-p4-check-output-passthrough
"U. prints with trailing space"
"123 U."
"123 ")
(forth-p4-check-output-passthrough
"<# #S #> TYPE — decimal"
"123 0 <# #S #> TYPE"
"123")
(forth-p4-check-output-passthrough
"<# #S #> TYPE — hex"
"255 HEX 0 <# #S #> TYPE"
"FF")
(forth-p4-check-output-passthrough
"<# # # #> partial"
"1234 0 <# # # #> TYPE"
"34")
(forth-p4-check-output-passthrough
"SIGN holds minus"
"<# -1 SIGN -1 SIGN 0 0 #> TYPE"
"--")
(forth-p4-check-output-passthrough
".R right-justifies"
"42 5 .R"
" 42")
(forth-p4-check-output-passthrough
".R negative"
"-42 5 .R"
" -42")
(forth-p4-check-output-passthrough
"U.R"
"42 5 U.R"
" 42")
(forth-p4-check-output-passthrough
"HOLD char"
"<# 0 0 65 HOLD #> TYPE"
"A")))
(define
forth-p5-dict-tests
(fn
()
(forth-p5-check-top
"EXECUTE via tick"
": INC 1+ ; 9 ' INC EXECUTE"
10)
(forth-p5-check-top
"['] inside def"
": DUB 2* ; : APPLY ['] DUB EXECUTE ; 5 APPLY"
10)
(forth-p5-check-top
">BODY of CREATE word"
"CREATE C 99 , ' C >BODY @"
99)
(forth-p5-check-stack
"WORD parses next token to counted-string"
": A 5 ; BL WORD A COUNT TYPE"
(list))
(forth-p5-check-top
"FIND on known word -> non-zero"
": A 5 ; BL WORD A FIND SWAP DROP"
-1)))
(define
forth-p5-state-tests
(fn
()
(forth-p5-check-top
"STATE @ in interpret mode"
"STATE @"
0)
(forth-p5-check-top
"STATE @ via IMMEDIATE inside compile"
": GT8 STATE @ ; IMMEDIATE : T GT8 LITERAL ; T"
-1)
(forth-p5-check-top
"[ ] LITERAL captures"
": SEVEN [ 7 ] LITERAL ; SEVEN"
7)
(forth-p5-check-top
"EVALUATE in interpret mode"
"S\" 5 7 +\" EVALUATE"
12)
(forth-p5-check-top
"EVALUATE inside def"
": A 100 ; : B S\" A\" EVALUATE ; B"
100)))
(define
forth-p4-check-output-passthrough
(fn
(label src expected)
(let ((r (forth-run src))) (forth-p5-assert label expected (nth r 1)))))
(define
forth-p5-run-all
(fn
()
(set! forth-p5-passed 0)
(set! forth-p5-failed 0)
(set! forth-p5-failures (list))
(forth-p5-create-tests)
(forth-p5-unsigned-tests)
(forth-p5-2bang-tests)
(forth-p5-mixed-tests)
(forth-p5-double-tests)
(forth-p5-format-tests)
(forth-p5-dict-tests)
(forth-p5-state-tests)
(dict
"passed"
forth-p5-passed
"failed"
forth-p5-failed
"failures"
forth-p5-failures)))

891
lib/smalltalk/parser.sx
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@@ -1,891 +0,0 @@
;; Smalltalk parser — produces an AST from the tokenizer's token stream.
;;
;; AST node shapes (dicts):
;; {:type "lit-int" :value N} integer
;; {:type "lit-float" :value F} float
;; {:type "lit-string" :value S} string
;; {:type "lit-char" :value C} character
;; {:type "lit-symbol" :value S} symbol literal (#foo)
;; {:type "lit-array" :elements (list ...)} literal array (#(1 2 #foo))
;; {:type "lit-byte-array" :elements (...)} byte array (#[1 2 3])
;; {:type "lit-nil" } / "lit-true" / "lit-false"
;; {:type "ident" :name "x"} variable reference
;; {:type "self"} / "super" / "thisContext" pseudo-variables
;; {:type "assign" :name "x" :expr E} x := E
;; {:type "return" :expr E} ^ E
;; {:type "send" :receiver R :selector S :args (list ...)}
;; {:type "cascade" :receiver R :messages (list {:selector :args} ...)}
;; {:type "block" :params (list "a") :temps (list "t") :body (list expr)}
;; {:type "seq" :exprs (list ...)} statement sequence
;; {:type "method" :selector S :params (list ...) :temps (list ...) :body (list ...) :pragmas (list ...)}
;;
;; A "chunk" / class-definition stream is parsed at a higher level (deferred).
;; ── Chunk-stream reader ────────────────────────────────────────────────
;; Pharo chunk format: chunks are separated by `!`. A doubled `!!` inside a
;; chunk represents a single literal `!`. Returns list of chunk strings with
;; surrounding whitespace trimmed.
(define
st-read-chunks
(fn
(src)
(let
((chunks (list))
(buf (list))
(pos 0)
(n (len src)))
(begin
(define
flush!
(fn
()
(let
((s (st-trim (join "" buf))))
(begin (append! chunks s) (set! buf (list))))))
(define
rc-loop
(fn
()
(when
(< pos n)
(let
((c (nth src pos)))
(cond
((= c "!")
(cond
((and (< (+ pos 1) n) (= (nth src (+ pos 1)) "!"))
(begin (append! buf "!") (set! pos (+ pos 2)) (rc-loop)))
(else
(begin (flush!) (set! pos (+ pos 1)) (rc-loop)))))
(else
(begin (append! buf c) (set! pos (+ pos 1)) (rc-loop))))))))
(rc-loop)
;; trailing text without a closing `!` — preserve as a chunk
(when (> (len buf) 0) (flush!))
chunks))))
(define
st-trim
(fn
(s)
(let
((n (len s)) (i 0) (j 0))
(begin
(set! j n)
(define
tl-loop
(fn
()
(when
(and (< i n) (st-trim-ws? (nth s i)))
(begin (set! i (+ i 1)) (tl-loop)))))
(tl-loop)
(define
tr-loop
(fn
()
(when
(and (> j i) (st-trim-ws? (nth s (- j 1))))
(begin (set! j (- j 1)) (tr-loop)))))
(tr-loop)
(slice s i j)))))
(define
st-trim-ws?
(fn (c) (or (= c " ") (= c "\t") (= c "\n") (= c "\r"))))
;; Parse a chunk stream. Walks chunks and applies the Pharo file-in
;; convention: a chunk that evaluates to "X methodsFor: 'cat'" or
;; "X class methodsFor: 'cat'" enters a methods batch — subsequent chunks
;; are method source until an empty chunk closes the batch.
;;
;; Returns list of entries:
;; {:kind "expr" :ast EXPR-AST}
;; {:kind "method" :class CLS :class-side? BOOL :category CAT :ast METHOD-AST}
;; {:kind "blank"} (empty chunks outside a methods batch)
;; {:kind "end-methods"} (empty chunk closing a methods batch)
(define
st-parse-chunks
(fn
(src)
(let
((chunks (st-read-chunks src))
(entries (list))
(mode "do-it")
(cls-name nil)
(class-side? false)
(category nil))
(begin
(for-each
(fn
(chunk)
(cond
((= chunk "")
(cond
((= mode "methods")
(begin
(append! entries {:kind "end-methods"})
(set! mode "do-it")
(set! cls-name nil)
(set! class-side? false)
(set! category nil)))
(else (append! entries {:kind "blank"}))))
((= mode "methods")
(append!
entries
{:kind "method"
:class cls-name
:class-side? class-side?
:category category
:ast (st-parse-method chunk)}))
(else
(let
((ast (st-parse-expr chunk)))
(begin
(append! entries {:kind "expr" :ast ast})
(let
((mf (st-detect-methods-for ast)))
(when
(not (= mf nil))
(begin
(set! mode "methods")
(set! cls-name (get mf :class))
(set! class-side? (get mf :class-side?))
(set! category (get mf :category))))))))))
chunks)
entries))))
;; Recognise `Foo methodsFor: 'cat'` (and related) as starting a methods batch.
;; Returns nil if the AST doesn't look like one of these forms.
(define
st-detect-methods-for
(fn
(ast)
(cond
((not (= (get ast :type) "send")) nil)
((not (st-is-methods-for-selector? (get ast :selector))) nil)
(else
(let
((recv (get ast :receiver)) (args (get ast :args)))
(let
((cat-arg (if (> (len args) 0) (nth args 0) nil)))
(let
((category
(cond
((= cat-arg nil) nil)
((= (get cat-arg :type) "lit-string") (get cat-arg :value))
((= (get cat-arg :type) "lit-symbol") (get cat-arg :value))
(else nil))))
(cond
((= (get recv :type) "ident")
{:class (get recv :name)
:class-side? false
:category category})
;; `Foo class methodsFor: 'cat'` — recv is a unary send `Foo class`
((and
(= (get recv :type) "send")
(= (get recv :selector) "class")
(= (get (get recv :receiver) :type) "ident"))
{:class (get (get recv :receiver) :name)
:class-side? true
:category category})
(else nil)))))))))
(define
st-is-methods-for-selector?
(fn
(sel)
(or
(= sel "methodsFor:")
(= sel "methodsFor:stamp:")
(= sel "category:"))))
(define st-tok-type (fn (t) (if (= t nil) "eof" (get t :type))))
(define st-tok-value (fn (t) (if (= t nil) nil (get t :value))))
;; Parse a *single* Smalltalk expression from source.
(define st-parse-expr (fn (src) (st-parse-with src "expr")))
;; Parse a sequence of statements separated by '.' Returns a {:type "seq"} node.
(define st-parse (fn (src) (st-parse-with src "seq")))
;; Parse a method body — `selector params | temps | body`.
;; Only the "method header + body" form (no chunk delimiters).
(define st-parse-method (fn (src) (st-parse-with src "method")))
(define
st-parse-with
(fn
(src mode)
(let
((tokens (st-tokenize src)) (idx 0) (tok-len 0))
(begin
(set! tok-len (len tokens))
(define peek-tok (fn () (nth tokens idx)))
(define
peek-tok-at
(fn (n) (if (< (+ idx n) tok-len) (nth tokens (+ idx n)) nil)))
(define advance-tok! (fn () (set! idx (+ idx 1))))
(define
at?
(fn
(type value)
(let
((t (peek-tok)))
(and
(= (st-tok-type t) type)
(or (= value nil) (= (st-tok-value t) value))))))
(define at-type? (fn (type) (= (st-tok-type (peek-tok)) type)))
(define
consume!
(fn
(type value)
(if
(at? type value)
(let ((t (peek-tok))) (begin (advance-tok!) t))
(error
(str
"st-parse: expected "
type
(if (= value nil) "" (str " '" value "'"))
" got "
(st-tok-type (peek-tok))
" '"
(st-tok-value (peek-tok))
"' at idx "
idx)))))
;; ── Primary: atoms, paren'd expr, blocks, literal arrays, byte arrays.
(define
parse-primary
(fn
()
(let
((t (peek-tok)))
(let
((ty (st-tok-type t)) (v (st-tok-value t)))
(cond
((= ty "number")
(begin
(advance-tok!)
(cond
((number? v) {:type (if (integer? v) "lit-int" "lit-float") :value v})
(else {:type "lit-int" :value v}))))
((= ty "string")
(begin (advance-tok!) {:type "lit-string" :value v}))
((= ty "char")
(begin (advance-tok!) {:type "lit-char" :value v}))
((= ty "symbol")
(begin (advance-tok!) {:type "lit-symbol" :value v}))
((= ty "array-open") (parse-literal-array))
((= ty "byte-array-open") (parse-byte-array))
((= ty "lparen")
(begin
(advance-tok!)
(let
((e (parse-expression)))
(begin (consume! "rparen" nil) e))))
((= ty "lbracket") (parse-block))
((= ty "ident")
(begin
(advance-tok!)
(cond
((= v "nil") {:type "lit-nil"})
((= v "true") {:type "lit-true"})
((= v "false") {:type "lit-false"})
((= v "self") {:type "self"})
((= v "super") {:type "super"})
((= v "thisContext") {:type "thisContext"})
(else {:type "ident" :name v}))))
((= ty "binary")
;; Negative numeric literal: '-' immediately before a number.
(cond
((and (= v "-") (= (st-tok-type (peek-tok-at 1)) "number"))
(let
((n (st-tok-value (peek-tok-at 1))))
(begin
(advance-tok!)
(advance-tok!)
(cond
((dict? n) {:type "lit-int" :value n})
((integer? n) {:type "lit-int" :value (- 0 n)})
(else {:type "lit-float" :value (- 0 n)})))))
(else
(error
(str "st-parse: unexpected binary '" v "' at idx " idx)))))
(else
(error
(str
"st-parse: unexpected "
ty
" '"
v
"' at idx "
idx))))))))
;; #(elem elem ...) — elements are atoms or nested parenthesised arrays.
(define
parse-literal-array
(fn
()
(let
((items (list)))
(begin
(consume! "array-open" nil)
(define
arr-loop
(fn
()
(cond
((at? "rparen" nil) (advance-tok!))
(else
(begin
(append! items (parse-array-element))
(arr-loop))))))
(arr-loop)
{:type "lit-array" :elements items}))))
;; #[1 2 3]
(define
parse-byte-array
(fn
()
(let
((items (list)))
(begin
(consume! "byte-array-open" nil)
(define
ba-loop
(fn
()
(cond
((at? "rbracket" nil) (advance-tok!))
(else
(let
((t (peek-tok)))
(cond
((= (st-tok-type t) "number")
(begin
(advance-tok!)
(append! items (st-tok-value t))
(ba-loop)))
(else
(error
(str
"st-parse: byte array expects number, got "
(st-tok-type t))))))))))
(ba-loop)
{:type "lit-byte-array" :elements items}))))
;; Inside a literal array: bare idents become symbols, nested (...) is a sub-array.
(define
parse-array-element
(fn
()
(let
((t (peek-tok)))
(let
((ty (st-tok-type t)) (v (st-tok-value t)))
(cond
((= ty "number") (begin (advance-tok!) {:type "lit-int" :value v}))
((= ty "string") (begin (advance-tok!) {:type "lit-string" :value v}))
((= ty "char") (begin (advance-tok!) {:type "lit-char" :value v}))
((= ty "symbol") (begin (advance-tok!) {:type "lit-symbol" :value v}))
((= ty "ident")
(begin
(advance-tok!)
(cond
((= v "nil") {:type "lit-nil"})
((= v "true") {:type "lit-true"})
((= v "false") {:type "lit-false"})
(else {:type "lit-symbol" :value v}))))
((= ty "keyword") (begin (advance-tok!) {:type "lit-symbol" :value v}))
((= ty "binary") (begin (advance-tok!) {:type "lit-symbol" :value v}))
((= ty "lparen")
(let ((items (list)))
(begin
(advance-tok!)
(define
sub-loop
(fn
()
(cond
((at? "rparen" nil) (advance-tok!))
(else
(begin (append! items (parse-array-element)) (sub-loop))))))
(sub-loop)
{:type "lit-array" :elements items})))
((= ty "array-open") (parse-literal-array))
((= ty "byte-array-open") (parse-byte-array))
(else
(error
(str "st-parse: bad literal-array element " ty " '" v "'"))))))))
;; [:a :b | | t1 t2 | body. body. ...]
(define
parse-block
(fn
()
(begin
(consume! "lbracket" nil)
(let
((params (list)) (temps (list)))
(begin
;; Block params
(define
p-loop
(fn
()
(when
(at? "colon" nil)
(begin
(advance-tok!)
(let
((t (consume! "ident" nil)))
(begin
(append! params (st-tok-value t))
(p-loop)))))))
(p-loop)
(when (> (len params) 0) (consume! "bar" nil))
;; Block temps: | t1 t2 |
(when
(and
(at? "bar" nil)
;; Not `|` followed immediately by binary content — the only
;; legitimate `|` inside a block here is the temp delimiter.
true)
(begin
(advance-tok!)
(define
t-loop
(fn
()
(when
(at? "ident" nil)
(let
((t (peek-tok)))
(begin
(advance-tok!)
(append! temps (st-tok-value t))
(t-loop))))))
(t-loop)
(consume! "bar" nil)))
;; Body: statements terminated by `.` or `]`
(let
((body (parse-statements "rbracket")))
(begin
(consume! "rbracket" nil)
{:type "block" :params params :temps temps :body body})))))))
;; Parse statements up to a closing token (rbracket or eof). Returns list.
(define
parse-statements
(fn
(terminator)
(let
((stmts (list)))
(begin
(define
s-loop
(fn
()
(cond
((at-type? terminator) nil)
((at-type? "eof") nil)
(else
(begin
(append! stmts (parse-statement))
;; consume optional period(s)
(define
dot-loop
(fn
()
(when
(at? "period" nil)
(begin (advance-tok!) (dot-loop)))))
(dot-loop)
(s-loop))))))
(s-loop)
stmts))))
;; Statement: ^expr | ident := expr | expr
(define
parse-statement
(fn
()
(cond
((at? "caret" nil)
(begin
(advance-tok!)
{:type "return" :expr (parse-expression)}))
((and (at-type? "ident") (= (st-tok-type (peek-tok-at 1)) "assign"))
(let
((name-tok (peek-tok)))
(begin
(advance-tok!)
(advance-tok!)
{:type "assign"
:name (st-tok-value name-tok)
:expr (parse-expression)})))
(else (parse-expression)))))
;; Top-level expression. Assignment (right-associative chain) sits at
;; the top; cascade is below.
(define
parse-expression
(fn
()
(cond
((and (at-type? "ident") (= (st-tok-type (peek-tok-at 1)) "assign"))
(let
((name-tok (peek-tok)))
(begin
(advance-tok!)
(advance-tok!)
{:type "assign"
:name (st-tok-value name-tok)
:expr (parse-expression)})))
(else (parse-cascade)))))
(define
parse-cascade
(fn
()
(let
((head (parse-keyword-message)))
(cond
((at? "semi" nil)
(let
((receiver (cascade-receiver head))
(first-msg (cascade-first-message head))
(msgs (list)))
(begin
(append! msgs first-msg)
(define
c-loop
(fn
()
(when
(at? "semi" nil)
(begin
(advance-tok!)
(append! msgs (parse-cascade-message))
(c-loop)))))
(c-loop)
{:type "cascade" :receiver receiver :messages msgs})))
(else head)))))
;; Extract the receiver from a head send so cascades share it.
(define
cascade-receiver
(fn
(head)
(cond
((= (get head :type) "send") (get head :receiver))
(else head))))
(define
cascade-first-message
(fn
(head)
(cond
((= (get head :type) "send")
{:selector (get head :selector) :args (get head :args)})
(else
;; Shouldn't happen — cascade requires at least one prior message.
(error "st-parse: cascade with no prior message")))))
;; Subsequent cascade message (after the `;`): unary | binary | keyword
(define
parse-cascade-message
(fn
()
(cond
((at-type? "ident")
(let ((t (peek-tok)))
(begin
(advance-tok!)
{:selector (st-tok-value t) :args (list)})))
((at-type? "binary")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(let
((arg (parse-unary-message)))
{:selector (st-tok-value t) :args (list arg)}))))
((at-type? "keyword")
(let
((sel-parts (list)) (args (list)))
(begin
(define
kw-loop
(fn
()
(when
(at-type? "keyword")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(append! sel-parts (st-tok-value t))
(append! args (parse-binary-message))
(kw-loop))))))
(kw-loop)
{:selector (join "" sel-parts) :args args})))
(else
(error
(str "st-parse: bad cascade message at idx " idx))))))
;; Keyword message: <binary> (kw <binary>)+
(define
parse-keyword-message
(fn
()
(let
((receiver (parse-binary-message)))
(cond
((at-type? "keyword")
(let
((sel-parts (list)) (args (list)))
(begin
(define
kw-loop
(fn
()
(when
(at-type? "keyword")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(append! sel-parts (st-tok-value t))
(append! args (parse-binary-message))
(kw-loop))))))
(kw-loop)
{:type "send"
:receiver receiver
:selector (join "" sel-parts)
:args args})))
(else receiver)))))
;; Binary message: <unary> (binop <unary>)*
(define
parse-binary-message
(fn
()
(let
((receiver (parse-unary-message)))
(begin
(define
b-loop
(fn
()
(when
(at-type? "binary")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(let
((arg (parse-unary-message)))
(set!
receiver
{:type "send"
:receiver receiver
:selector (st-tok-value t)
:args (list arg)}))
(b-loop))))))
(b-loop)
receiver))))
;; Unary message: <primary> ident* (ident NOT followed by ':')
(define
parse-unary-message
(fn
()
(let
((receiver (parse-primary)))
(begin
(define
u-loop
(fn
()
(when
(and
(at-type? "ident")
(let
((nxt (peek-tok-at 1)))
(not (= (st-tok-type nxt) "assign"))))
(let ((t (peek-tok)))
(begin
(advance-tok!)
(set!
receiver
{:type "send"
:receiver receiver
:selector (st-tok-value t)
:args (list)})
(u-loop))))))
(u-loop)
receiver))))
;; Parse a single pragma: `<keyword: literal (keyword: literal)* >`
;; Returns {:selector "primitive:" :args (list literal-asts)}.
(define
parse-pragma
(fn
()
(begin
(consume! "binary" "<")
(let
((sel-parts (list)) (args (list)))
(begin
(define
pr-loop
(fn
()
(when
(at-type? "keyword")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(append! sel-parts (st-tok-value t))
(append! args (parse-pragma-arg))
(pr-loop))))))
(pr-loop)
(consume! "binary" ">")
{:selector (join "" sel-parts) :args args})))))
;; Pragma arguments are literals only.
(define
parse-pragma-arg
(fn
()
(let
((t (peek-tok)))
(let
((ty (st-tok-type t)) (v (st-tok-value t)))
(cond
((= ty "number")
(begin
(advance-tok!)
{:type (if (integer? v) "lit-int" "lit-float") :value v}))
((= ty "string") (begin (advance-tok!) {:type "lit-string" :value v}))
((= ty "char") (begin (advance-tok!) {:type "lit-char" :value v}))
((= ty "symbol") (begin (advance-tok!) {:type "lit-symbol" :value v}))
((= ty "ident")
(begin
(advance-tok!)
(cond
((= v "nil") {:type "lit-nil"})
((= v "true") {:type "lit-true"})
((= v "false") {:type "lit-false"})
(else (error (str "st-parse: pragma arg must be literal, got ident " v))))))
((and (= ty "binary") (= v "-")
(= (st-tok-type (peek-tok-at 1)) "number"))
(let ((n (st-tok-value (peek-tok-at 1))))
(begin
(advance-tok!)
(advance-tok!)
{:type (if (integer? n) "lit-int" "lit-float")
:value (- 0 n)})))
(else
(error
(str "st-parse: pragma arg must be literal, got " ty))))))))
;; Method header: unary | binary arg | (kw arg)+
(define
parse-method
(fn
()
(let
((sel "")
(params (list))
(temps (list))
(pragmas (list))
(body (list)))
(begin
(cond
;; Unary header
((at-type? "ident")
(let ((t (peek-tok)))
(begin (advance-tok!) (set! sel (st-tok-value t)))))
;; Binary header: binop ident
((at-type? "binary")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(set! sel (st-tok-value t))
(let ((p (consume! "ident" nil)))
(append! params (st-tok-value p))))))
;; Keyword header: (kw ident)+
((at-type? "keyword")
(let ((sel-parts (list)))
(begin
(define
kh-loop
(fn
()
(when
(at-type? "keyword")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(append! sel-parts (st-tok-value t))
(let ((p (consume! "ident" nil)))
(append! params (st-tok-value p)))
(kh-loop))))))
(kh-loop)
(set! sel (join "" sel-parts)))))
(else
(error
(str
"st-parse-method: expected selector header, got "
(st-tok-type (peek-tok))))))
;; Pragmas and temps may appear in either order. Allow many
;; pragmas; one temps section.
(define
parse-temps!
(fn
()
(begin
(advance-tok!)
(define
th-loop
(fn
()
(when
(at-type? "ident")
(let ((t (peek-tok)))
(begin
(advance-tok!)
(append! temps (st-tok-value t))
(th-loop))))))
(th-loop)
(consume! "bar" nil))))
(define
pt-loop
(fn
()
(cond
((and
(at? "binary" "<")
(= (st-tok-type (peek-tok-at 1)) "keyword"))
(begin (append! pragmas (parse-pragma)) (pt-loop)))
((and (at? "bar" nil) (= (len temps) 0))
(begin (parse-temps!) (pt-loop)))
(else nil))))
(pt-loop)
;; Body statements
(set! body (parse-statements "eof"))
{:type "method"
:selector sel
:params params
:temps temps
:pragmas pragmas
:body body}))))
;; Top-level program: statements separated by '.'
(cond
((= mode "expr") (parse-expression))
((= mode "method") (parse-method))
(else
{:type "seq" :exprs (parse-statements "eof")}))))))

291
lib/smalltalk/runtime.sx
View File

@@ -1,291 +0,0 @@
;; Smalltalk runtime — class table, bootstrap hierarchy, type→class mapping,
;; instance construction. Method dispatch / eval-ast live in a later layer.
;;
;; Class record shape:
;; {:name "Foo"
;; :superclass "Object" ; or nil for Object itself
;; :ivars (list "x" "y") ; instance variable names declared on this class
;; :methods (dict selector→method-record)
;; :class-methods (dict selector→method-record)}
;;
;; A method record is the AST returned by st-parse-method, plus a :defining-class
;; field so super-sends can resolve from the right place. (Methods are registered
;; via runtime helpers that fill the field.)
;;
;; The class table is a single dict keyed by class name. Bootstrap installs the
;; canonical hierarchy. Test code resets it via (st-bootstrap-classes!).
(define st-class-table {})
(define st-class-table-clear! (fn () (set! st-class-table {})))
(define
st-class-define!
(fn
(name superclass ivars)
(begin
(set!
st-class-table
(assoc
st-class-table
name
{:name name
:superclass superclass
:ivars ivars
:methods {}
:class-methods {}}))
name)))
(define
st-class-get
(fn (name) (if (has-key? st-class-table name) (get st-class-table name) nil)))
(define
st-class-exists?
(fn (name) (has-key? st-class-table name)))
(define
st-class-superclass
(fn
(name)
(let
((c (st-class-get name)))
(cond ((= c nil) nil) (else (get c :superclass))))))
;; Walk class chain root-to-leaf? No, follow superclass chain leaf-to-root.
;; Returns list of class names starting at `name` and ending with the root.
(define
st-class-chain
(fn
(name)
(let ((acc (list)) (cur name))
(begin
(define
ch-loop
(fn
()
(when
(and (not (= cur nil)) (st-class-exists? cur))
(begin
(append! acc cur)
(set! cur (st-class-superclass cur))
(ch-loop)))))
(ch-loop)
acc))))
;; Inherited + own ivars in declaration order from root to leaf.
(define
st-class-all-ivars
(fn
(name)
(let ((chain (reverse (st-class-chain name))) (out (list)))
(begin
(for-each
(fn
(cn)
(let
((c (st-class-get cn)))
(when
(not (= c nil))
(for-each (fn (iv) (append! out iv)) (get c :ivars)))))
chain)
out))))
;; Method install. The defining-class field is stamped on the method record
;; so super-sends look up from the right point in the chain.
(define
st-class-add-method!
(fn
(cls-name selector method-ast)
(let
((cls (st-class-get cls-name)))
(cond
((= cls nil) (error (str "st-class-add-method!: unknown class " cls-name)))
(else
(let
((m (assoc method-ast :defining-class cls-name)))
(begin
(set!
st-class-table
(assoc
st-class-table
cls-name
(assoc
cls
:methods
(assoc (get cls :methods) selector m))))
selector)))))))
(define
st-class-add-class-method!
(fn
(cls-name selector method-ast)
(let
((cls (st-class-get cls-name)))
(cond
((= cls nil) (error (str "st-class-add-class-method!: unknown class " cls-name)))
(else
(let
((m (assoc method-ast :defining-class cls-name)))
(begin
(set!
st-class-table
(assoc
st-class-table
cls-name
(assoc
cls
:class-methods
(assoc (get cls :class-methods) selector m))))
selector)))))))
;; Method lookup: walk superclass chain starting at `cls-name`.
;; class-side? = true searches :class-methods, false searches :methods.
;; Returns the method record (with :defining-class) or nil.
(define
st-method-lookup
(fn
(cls-name selector class-side?)
(let
((found nil))
(begin
(define
ml-loop
(fn
(cur)
(when
(and (= found nil) (not (= cur nil)) (st-class-exists? cur))
(let
((c (st-class-get cur)))
(let
((dict (if class-side? (get c :class-methods) (get c :methods))))
(cond
((has-key? dict selector) (set! found (get dict selector)))
(else (ml-loop (get c :superclass)))))))))
(ml-loop cls-name)
found))))
;; SX value → Smalltalk class name. Native types are not boxed.
(define
st-class-of
(fn
(v)
(cond
((= v nil) "UndefinedObject")
((= v true) "True")
((= v false) "False")
((integer? v) "SmallInteger")
((number? v) "Float")
((string? v) "String")
((symbol? v) "Symbol")
((list? v) "Array")
((and (dict? v) (has-key? v :type) (= (get v :type) "st-instance"))
(get v :class))
((and (dict? v) (has-key? v :type) (= (get v :type) "block"))
"BlockClosure")
((and (dict? v) (has-key? v :st-block?) (get v :st-block?))
"BlockClosure")
((dict? v) "Dictionary")
((lambda? v) "BlockClosure")
(else "Object"))))
;; Construct a fresh instance of cls-name. Ivars (own + inherited) start as nil.
(define
st-make-instance
(fn
(cls-name)
(cond
((not (st-class-exists? cls-name))
(error (str "st-make-instance: unknown class " cls-name)))
(else
(let
((iv-names (st-class-all-ivars cls-name)) (ivars {}))
(begin
(for-each (fn (n) (set! ivars (assoc ivars n nil))) iv-names)
{:type "st-instance" :class cls-name :ivars ivars}))))))
(define
st-instance?
(fn
(v)
(and (dict? v) (has-key? v :type) (= (get v :type) "st-instance"))))
(define
st-iv-get
(fn
(inst name)
(let ((ivs (get inst :ivars)))
(if (has-key? ivs name) (get ivs name) nil))))
(define
st-iv-set!
(fn
(inst name value)
(let
((new-ivars (assoc (get inst :ivars) name value)))
(assoc inst :ivars new-ivars))))
;; Inherits-from check: is `descendant` either equal to `ancestor` or a subclass?
(define
st-class-inherits-from?
(fn
(descendant ancestor)
(let ((found false) (cur descendant))
(begin
(define
ih-loop
(fn
()
(when
(and (not found) (not (= cur nil)) (st-class-exists? cur))
(cond
((= cur ancestor) (set! found true))
(else
(begin
(set! cur (st-class-superclass cur))
(ih-loop)))))))
(ih-loop)
found))))
;; Bootstrap the canonical class hierarchy. Reset and rebuild.
(define
st-bootstrap-classes!
(fn
()
(begin
(st-class-table-clear!)
;; Root
(st-class-define! "Object" nil (list))
;; Class side machinery
(st-class-define! "Behavior" "Object" (list "superclass" "methodDict" "format"))
(st-class-define! "ClassDescription" "Behavior" (list "instanceVariables" "organization"))
(st-class-define! "Class" "ClassDescription" (list "name" "subclasses"))
(st-class-define! "Metaclass" "ClassDescription" (list "thisClass"))
;; Pseudo-variable types
(st-class-define! "UndefinedObject" "Object" (list))
(st-class-define! "Boolean" "Object" (list))
(st-class-define! "True" "Boolean" (list))
(st-class-define! "False" "Boolean" (list))
;; Magnitudes
(st-class-define! "Magnitude" "Object" (list))
(st-class-define! "Number" "Magnitude" (list))
(st-class-define! "Integer" "Number" (list))
(st-class-define! "SmallInteger" "Integer" (list))
(st-class-define! "LargePositiveInteger" "Integer" (list))
(st-class-define! "Float" "Number" (list))
(st-class-define! "Character" "Magnitude" (list "value"))
;; Collections
(st-class-define! "Collection" "Object" (list))
(st-class-define! "SequenceableCollection" "Collection" (list))
(st-class-define! "ArrayedCollection" "SequenceableCollection" (list))
(st-class-define! "Array" "ArrayedCollection" (list))
(st-class-define! "String" "ArrayedCollection" (list))
(st-class-define! "Symbol" "String" (list))
(st-class-define! "OrderedCollection" "SequenceableCollection" (list "array" "firstIndex" "lastIndex"))
(st-class-define! "Dictionary" "Collection" (list))
;; Blocks / contexts
(st-class-define! "BlockClosure" "Object" (list))
"ok")))
;; Initialise on load. Tests can re-bootstrap to reset state.
(st-bootstrap-classes!)

137
lib/smalltalk/test.sh
View File

@@ -1,137 +0,0 @@
#!/usr/bin/env bash
# Fast Smalltalk-on-SX test runner — pipes directly to sx_server.exe.
# Mirrors lib/haskell/test.sh.
#
# Usage:
# bash lib/smalltalk/test.sh # run all tests
# bash lib/smalltalk/test.sh -v # verbose
# bash lib/smalltalk/test.sh tests/tokenize.sx # run one file
set -uo pipefail
cd "$(git rev-parse --show-toplevel)"
SX_SERVER="hosts/ocaml/_build/default/bin/sx_server.exe"
if [ ! -x "$SX_SERVER" ]; then
MAIN_ROOT=$(git worktree list | head -1 | awk '{print $1}')
if [ -x "$MAIN_ROOT/$SX_SERVER" ]; then
SX_SERVER="$MAIN_ROOT/$SX_SERVER"
else
echo "ERROR: sx_server.exe not found. Run: cd hosts/ocaml && dune build"
exit 1
fi
fi
VERBOSE=""
FILES=()
for arg in "$@"; do
case "$arg" in
-v|--verbose) VERBOSE=1 ;;
*) FILES+=("$arg") ;;
esac
done
if [ ${#FILES[@]} -eq 0 ]; then
# tokenize.sx must load first — it defines the st-test helpers reused by
# subsequent test files. Sort enforces this lexicographically.
mapfile -t FILES < <(find lib/smalltalk/tests -maxdepth 2 -name '*.sx' | sort)
fi
TOTAL_PASS=0
TOTAL_FAIL=0
FAILED_FILES=()
for FILE in "${FILES[@]}"; do
[ -f "$FILE" ] || { echo "skip $FILE (not found)"; continue; }
TMPFILE=$(mktemp)
if [ "$(basename "$FILE")" = "tokenize.sx" ]; then
cat > "$TMPFILE" <<EPOCHS
(epoch 1)
(load "lib/smalltalk/tokenizer.sx")
(epoch 2)
(load "$FILE")
(epoch 3)
(eval "(list st-test-pass st-test-fail)")
EPOCHS
else
cat > "$TMPFILE" <<EPOCHS
(epoch 1)
(load "lib/smalltalk/tokenizer.sx")
(epoch 2)
(load "lib/smalltalk/parser.sx")
(epoch 3)
(load "lib/smalltalk/runtime.sx")
(epoch 4)
(load "lib/smalltalk/tests/tokenize.sx")
(epoch 5)
(load "$FILE")
(epoch 6)
(eval "(list st-test-pass st-test-fail)")
EPOCHS
fi
OUTPUT=$(timeout 60 "$SX_SERVER" < "$TMPFILE" 2>&1 || true)
rm -f "$TMPFILE"
# Final epoch's value: either (ok N (P F)) on one line or
# (ok-len N M)\n(P F) where the value is on the following line.
LINE=$(echo "$OUTPUT" | awk '/^\(ok-len [0-9]+ / {getline; print}' | tail -1)
if [ -z "$LINE" ]; then
LINE=$(echo "$OUTPUT" | grep -E '^\(ok [0-9]+ \([0-9]+ [0-9]+\)\)' | tail -1 \
| sed -E 's/^\(ok [0-9]+ //; s/\)$//')
fi
if [ -z "$LINE" ]; then
echo "X $FILE: could not extract summary"
echo "$OUTPUT" | tail -30
TOTAL_FAIL=$((TOTAL_FAIL + 1))
FAILED_FILES+=("$FILE")
continue
fi
P=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\1/')
F=$(echo "$LINE" | sed -E 's/^\(([0-9]+) ([0-9]+)\).*/\2/')
TOTAL_PASS=$((TOTAL_PASS + P))
TOTAL_FAIL=$((TOTAL_FAIL + F))
if [ "$F" -gt 0 ]; then
FAILED_FILES+=("$FILE")
printf 'X %-40s %d/%d\n' "$FILE" "$P" "$((P+F))"
TMPFILE2=$(mktemp)
if [ "$(basename "$FILE")" = "tokenize.sx" ]; then
cat > "$TMPFILE2" <<EPOCHS
(epoch 1)
(load "lib/smalltalk/tokenizer.sx")
(epoch 2)
(load "$FILE")
(epoch 3)
(eval "(map (fn (f) (get f :name)) st-test-fails)")
EPOCHS
else
cat > "$TMPFILE2" <<EPOCHS
(epoch 1)
(load "lib/smalltalk/tokenizer.sx")
(epoch 2)
(load "lib/smalltalk/parser.sx")
(epoch 3)
(load "lib/smalltalk/runtime.sx")
(epoch 4)
(load "lib/smalltalk/tests/tokenize.sx")
(epoch 5)
(load "$FILE")
(epoch 6)
(eval "(map (fn (f) (get f :name)) st-test-fails)")
EPOCHS
fi
FAILS=$(timeout 60 "$SX_SERVER" < "$TMPFILE2" 2>&1 | grep -E '^\(ok [0-9]+ \(' | tail -1 || true)
rm -f "$TMPFILE2"
echo " $FAILS"
elif [ "$VERBOSE" = "1" ]; then
printf 'OK %-40s %d passed\n' "$FILE" "$P"
fi
done
TOTAL=$((TOTAL_PASS + TOTAL_FAIL))
if [ $TOTAL_FAIL -eq 0 ]; then
echo "OK $TOTAL_PASS/$TOTAL smalltalk-on-sx tests passed"
else
echo "FAIL $TOTAL_PASS/$TOTAL passed, $TOTAL_FAIL failed in: ${FAILED_FILES[*]}"
fi
[ $TOTAL_FAIL -eq 0 ]

369
lib/smalltalk/tests/parse.sx
View File

@@ -1,369 +0,0 @@
;; Smalltalk parser tests.
;;
;; Reuses helpers (st-test, st-deep=?) from tokenize.sx. Counters reset
;; here so this file's summary covers parse tests only.
(set! st-test-pass 0)
(set! st-test-fail 0)
(set! st-test-fails (list))
;; ── 1. Atoms ──
(st-test "int" (st-parse-expr "42") {:type "lit-int" :value 42})
(st-test "float" (st-parse-expr "3.14") {:type "lit-float" :value 3.14})
(st-test "string" (st-parse-expr "'hi'") {:type "lit-string" :value "hi"})
(st-test "char" (st-parse-expr "$x") {:type "lit-char" :value "x"})
(st-test "symbol" (st-parse-expr "#foo") {:type "lit-symbol" :value "foo"})
(st-test "binary symbol" (st-parse-expr "#+") {:type "lit-symbol" :value "+"})
(st-test "keyword symbol" (st-parse-expr "#at:put:") {:type "lit-symbol" :value "at:put:"})
(st-test "nil" (st-parse-expr "nil") {:type "lit-nil"})
(st-test "true" (st-parse-expr "true") {:type "lit-true"})
(st-test "false" (st-parse-expr "false") {:type "lit-false"})
(st-test "self" (st-parse-expr "self") {:type "self"})
(st-test "super" (st-parse-expr "super") {:type "super"})
(st-test "ident" (st-parse-expr "x") {:type "ident" :name "x"})
(st-test "negative int" (st-parse-expr "-3") {:type "lit-int" :value -3})
;; ── 2. Literal arrays ──
(st-test
"literal array of ints"
(st-parse-expr "#(1 2 3)")
{:type "lit-array"
:elements (list
{:type "lit-int" :value 1}
{:type "lit-int" :value 2}
{:type "lit-int" :value 3})})
(st-test
"literal array mixed"
(st-parse-expr "#(1 #foo 'x' true)")
{:type "lit-array"
:elements (list
{:type "lit-int" :value 1}
{:type "lit-symbol" :value "foo"}
{:type "lit-string" :value "x"}
{:type "lit-true"})})
(st-test
"literal array bare ident is symbol"
(st-parse-expr "#(foo bar)")
{:type "lit-array"
:elements (list
{:type "lit-symbol" :value "foo"}
{:type "lit-symbol" :value "bar"})})
(st-test
"nested literal array"
(st-parse-expr "#(1 (2 3) 4)")
{:type "lit-array"
:elements (list
{:type "lit-int" :value 1}
{:type "lit-array"
:elements (list
{:type "lit-int" :value 2}
{:type "lit-int" :value 3})}
{:type "lit-int" :value 4})})
(st-test
"byte array"
(st-parse-expr "#[1 2 3]")
{:type "lit-byte-array" :elements (list 1 2 3)})
;; ── 3. Unary messages ──
(st-test
"unary single"
(st-parse-expr "x foo")
{:type "send"
:receiver {:type "ident" :name "x"}
:selector "foo"
:args (list)})
(st-test
"unary chain"
(st-parse-expr "x foo bar baz")
{:type "send"
:receiver {:type "send"
:receiver {:type "send"
:receiver {:type "ident" :name "x"}
:selector "foo"
:args (list)}
:selector "bar"
:args (list)}
:selector "baz"
:args (list)})
(st-test
"unary on literal"
(st-parse-expr "42 printNl")
{:type "send"
:receiver {:type "lit-int" :value 42}
:selector "printNl"
:args (list)})
;; ── 4. Binary messages ──
(st-test
"binary single"
(st-parse-expr "1 + 2")
{:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})})
(st-test
"binary left-assoc"
(st-parse-expr "1 + 2 + 3")
{:type "send"
:receiver {:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})}
:selector "+"
:args (list {:type "lit-int" :value 3})})
(st-test
"binary same precedence l-to-r"
(st-parse-expr "1 + 2 * 3")
{:type "send"
:receiver {:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})}
:selector "*"
:args (list {:type "lit-int" :value 3})})
;; ── 5. Precedence: unary binds tighter than binary ──
(st-test
"unary tighter than binary"
(st-parse-expr "3 + 4 factorial")
{:type "send"
:receiver {:type "lit-int" :value 3}
:selector "+"
:args (list
{:type "send"
:receiver {:type "lit-int" :value 4}
:selector "factorial"
:args (list)})})
;; ── 6. Keyword messages ──
(st-test
"keyword single"
(st-parse-expr "x at: 1")
{:type "send"
:receiver {:type "ident" :name "x"}
:selector "at:"
:args (list {:type "lit-int" :value 1})})
(st-test
"keyword chain"
(st-parse-expr "x at: 1 put: 'a'")
{:type "send"
:receiver {:type "ident" :name "x"}
:selector "at:put:"
:args (list {:type "lit-int" :value 1} {:type "lit-string" :value "a"})})
;; ── 7. Precedence: binary tighter than keyword ──
(st-test
"binary tighter than keyword"
(st-parse-expr "x at: 1 + 2")
{:type "send"
:receiver {:type "ident" :name "x"}
:selector "at:"
:args (list
{:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})})})
(st-test
"keyword absorbs trailing unary"
(st-parse-expr "a foo: b bar")
{:type "send"
:receiver {:type "ident" :name "a"}
:selector "foo:"
:args (list
{:type "send"
:receiver {:type "ident" :name "b"}
:selector "bar"
:args (list)})})
;; ── 8. Parens override precedence ──
(st-test
"paren forces grouping"
(st-parse-expr "(1 + 2) * 3")
{:type "send"
:receiver {:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})}
:selector "*"
:args (list {:type "lit-int" :value 3})})
;; ── 9. Cascade ──
(st-test
"simple cascade"
(st-parse-expr "x m1; m2")
{:type "cascade"
:receiver {:type "ident" :name "x"}
:messages (list
{:selector "m1" :args (list)}
{:selector "m2" :args (list)})})
(st-test
"cascade with binary and keyword"
(st-parse-expr "Stream new nl; tab; print: 1")
{:type "cascade"
:receiver {:type "send"
:receiver {:type "ident" :name "Stream"}
:selector "new"
:args (list)}
:messages (list
{:selector "nl" :args (list)}
{:selector "tab" :args (list)}
{:selector "print:" :args (list {:type "lit-int" :value 1})})})
;; ── 10. Blocks ──
(st-test
"empty block"
(st-parse-expr "[]")
{:type "block" :params (list) :temps (list) :body (list)})
(st-test
"block one expr"
(st-parse-expr "[1 + 2]")
{:type "block"
:params (list)
:temps (list)
:body (list
{:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})})})
(st-test
"block with params"
(st-parse-expr "[:a :b | a + b]")
{:type "block"
:params (list "a" "b")
:temps (list)
:body (list
{:type "send"
:receiver {:type "ident" :name "a"}
:selector "+"
:args (list {:type "ident" :name "b"})})})
(st-test
"block with temps"
(st-parse-expr "[| t | t := 1. t]")
{:type "block"
:params (list)
:temps (list "t")
:body (list
{:type "assign" :name "t" :expr {:type "lit-int" :value 1}}
{:type "ident" :name "t"})})
(st-test
"block with params and temps"
(st-parse-expr "[:x | | t | t := x + 1. t]")
{:type "block"
:params (list "x")
:temps (list "t")
:body (list
{:type "assign"
:name "t"
:expr {:type "send"
:receiver {:type "ident" :name "x"}
:selector "+"
:args (list {:type "lit-int" :value 1})}}
{:type "ident" :name "t"})})
;; ── 11. Assignment / return / statements ──
(st-test
"assignment"
(st-parse-expr "x := 1")
{:type "assign" :name "x" :expr {:type "lit-int" :value 1}})
(st-test
"return"
(st-parse-expr "1")
{:type "lit-int" :value 1})
(st-test
"return statement at top level"
(st-parse "^ 1")
{:type "seq"
:exprs (list {:type "return" :expr {:type "lit-int" :value 1}})})
(st-test
"two statements"
(st-parse "x := 1. y := 2")
{:type "seq"
:exprs (list
{:type "assign" :name "x" :expr {:type "lit-int" :value 1}}
{:type "assign" :name "y" :expr {:type "lit-int" :value 2}})})
(st-test
"trailing dot allowed"
(st-parse "1. 2.")
{:type "seq"
:exprs (list {:type "lit-int" :value 1} {:type "lit-int" :value 2})})
;; ── 12. Method headers ──
(st-test
"unary method"
(st-parse-method "factorial ^ self * (self - 1) factorial")
{:type "method"
:selector "factorial"
:params (list)
:temps (list)
:pragmas (list)
:body (list
{:type "return"
:expr {:type "send"
:receiver {:type "self"}
:selector "*"
:args (list
{:type "send"
:receiver {:type "send"
:receiver {:type "self"}
:selector "-"
:args (list {:type "lit-int" :value 1})}
:selector "factorial"
:args (list)})}})})
(st-test
"binary method"
(st-parse-method "+ other ^ 'plus'")
{:type "method"
:selector "+"
:params (list "other")
:temps (list)
:pragmas (list)
:body (list {:type "return" :expr {:type "lit-string" :value "plus"}})})
(st-test
"keyword method"
(st-parse-method "at: i put: v ^ v")
{:type "method"
:selector "at:put:"
:params (list "i" "v")
:temps (list)
:pragmas (list)
:body (list {:type "return" :expr {:type "ident" :name "v"}})})
(st-test
"method with temps"
(st-parse-method "twice: x | t | t := x + x. ^ t")
{:type "method"
:selector "twice:"
:params (list "x")
:temps (list "t")
:pragmas (list)
:body (list
{:type "assign"
:name "t"
:expr {:type "send"
:receiver {:type "ident" :name "x"}
:selector "+"
:args (list {:type "ident" :name "x"})}}
{:type "return" :expr {:type "ident" :name "t"}})})
(list st-test-pass st-test-fail)

294
lib/smalltalk/tests/parse_chunks.sx
View File

@@ -1,294 +0,0 @@
;; Smalltalk chunk-stream parser + pragma tests.
;;
;; Reuses helpers (st-test, st-deep=?) from tokenize.sx. Counters reset
;; here so this file's summary covers chunk + pragma tests only.
(set! st-test-pass 0)
(set! st-test-fail 0)
(set! st-test-fails (list))
;; ── 1. Raw chunk reader ──
(st-test "empty source" (st-read-chunks "") (list))
(st-test "single chunk" (st-read-chunks "foo!") (list "foo"))
(st-test "two chunks" (st-read-chunks "a! b!") (list "a" "b"))
(st-test "trailing no bang" (st-read-chunks "a! b") (list "a" "b"))
(st-test "empty chunk" (st-read-chunks "a! ! b!") (list "a" "" "b"))
(st-test
"doubled bang escapes"
(st-read-chunks "yes!! no!yes!")
(list "yes! no" "yes"))
(st-test
"whitespace trimmed"
(st-read-chunks " \n hello \n !")
(list "hello"))
;; ── 2. Chunk parser — do-it mode ──
(st-test
"single do-it chunk"
(st-parse-chunks "1 + 2!")
(list
{:kind "expr"
:ast {:type "send"
:receiver {:type "lit-int" :value 1}
:selector "+"
:args (list {:type "lit-int" :value 2})}}))
(st-test
"two do-it chunks"
(st-parse-chunks "x := 1! y := 2!")
(list
{:kind "expr"
:ast {:type "assign" :name "x" :expr {:type "lit-int" :value 1}}}
{:kind "expr"
:ast {:type "assign" :name "y" :expr {:type "lit-int" :value 2}}}))
(st-test
"blank chunk outside methods"
(st-parse-chunks "1! ! 2!")
(list
{:kind "expr" :ast {:type "lit-int" :value 1}}
{:kind "blank"}
{:kind "expr" :ast {:type "lit-int" :value 2}}))
;; ── 3. Methods batch ──
(st-test
"methodsFor opens method batch"
(st-parse-chunks
"Foo methodsFor: 'access'! foo ^ 1! bar ^ 2! !")
(list
{:kind "expr"
:ast {:type "send"
:receiver {:type "ident" :name "Foo"}
:selector "methodsFor:"
:args (list {:type "lit-string" :value "access"})}}
{:kind "method"
:class "Foo"
:class-side? false
:category "access"
:ast {:type "method"
:selector "foo"
:params (list)
:temps (list)
:pragmas (list)
:body (list
{:type "return" :expr {:type "lit-int" :value 1}})}}
{:kind "method"
:class "Foo"
:class-side? false
:category "access"
:ast {:type "method"
:selector "bar"
:params (list)
:temps (list)
:pragmas (list)
:body (list
{:type "return" :expr {:type "lit-int" :value 2}})}}
{:kind "end-methods"}))
(st-test
"class-side methodsFor"
(st-parse-chunks
"Foo class methodsFor: 'creation'! make ^ self new! !")
(list
{:kind "expr"
:ast {:type "send"
:receiver {:type "send"
:receiver {:type "ident" :name "Foo"}
:selector "class"
:args (list)}
:selector "methodsFor:"
:args (list {:type "lit-string" :value "creation"})}}
{:kind "method"
:class "Foo"
:class-side? true
:category "creation"
:ast {:type "method"
:selector "make"
:params (list)
:temps (list)
:pragmas (list)
:body (list
{:type "return"
:expr {:type "send"
:receiver {:type "self"}
:selector "new"
:args (list)}})}}
{:kind "end-methods"}))
(st-test
"method batch returns to do-it after empty chunk"
(st-parse-chunks
"Foo methodsFor: 'a'! m1 ^ 1! ! 99!")
(list
{:kind "expr"
:ast {:type "send"
:receiver {:type "ident" :name "Foo"}
:selector "methodsFor:"
:args (list {:type "lit-string" :value "a"})}}
{:kind "method"
:class "Foo"
:class-side? false
:category "a"
:ast {:type "method"
:selector "m1"
:params (list)
:temps (list)
:pragmas (list)
:body (list
{:type "return" :expr {:type "lit-int" :value 1}})}}
{:kind "end-methods"}
{:kind "expr" :ast {:type "lit-int" :value 99}}))
;; ── 4. Pragmas in method bodies ──
(st-test
"single pragma"
(st-parse-method "primAt: i <primitive: 60> ^ self")
{:type "method"
:selector "primAt:"
:params (list "i")
:temps (list)
:pragmas (list
{:selector "primitive:"
:args (list {:type "lit-int" :value 60})})
:body (list {:type "return" :expr {:type "self"}})})
(st-test
"pragma with two keyword pairs"
(st-parse-method "fft <primitive: 1 module: 'fft'> ^ nil")
{:type "method"
:selector "fft"
:params (list)
:temps (list)
:pragmas (list
{:selector "primitive:module:"
:args (list
{:type "lit-int" :value 1}
{:type "lit-string" :value "fft"})})
:body (list {:type "return" :expr {:type "lit-nil"}})})
(st-test
"pragma with negative number"
(st-parse-method "neg <primitive: -1> ^ nil")
{:type "method"
:selector "neg"
:params (list)
:temps (list)
:pragmas (list
{:selector "primitive:"
:args (list {:type "lit-int" :value -1})})
:body (list {:type "return" :expr {:type "lit-nil"}})})
(st-test
"pragma with symbol arg"
(st-parse-method "tagged <category: #algebra> ^ nil")
{:type "method"
:selector "tagged"
:params (list)
:temps (list)
:pragmas (list
{:selector "category:"
:args (list {:type "lit-symbol" :value "algebra"})})
:body (list {:type "return" :expr {:type "lit-nil"}})})
(st-test
"pragma then temps"
(st-parse-method "calc <primitive: 1> | t | t := 5. ^ t")
{:type "method"
:selector "calc"
:params (list)
:temps (list "t")
:pragmas (list
{:selector "primitive:"
:args (list {:type "lit-int" :value 1})})
:body (list
{:type "assign" :name "t" :expr {:type "lit-int" :value 5}}
{:type "return" :expr {:type "ident" :name "t"}})})
(st-test
"temps then pragma"
(st-parse-method "calc | t | <primitive: 1> t := 5. ^ t")
{:type "method"
:selector "calc"
:params (list)
:temps (list "t")
:pragmas (list
{:selector "primitive:"
:args (list {:type "lit-int" :value 1})})
:body (list
{:type "assign" :name "t" :expr {:type "lit-int" :value 5}}
{:type "return" :expr {:type "ident" :name "t"}})})
(st-test
"two pragmas"
(st-parse-method "m <primitive: 1> <category: 'a'> ^ self")
{:type "method"
:selector "m"
:params (list)
:temps (list)
:pragmas (list
{:selector "primitive:"
:args (list {:type "lit-int" :value 1})}
{:selector "category:"
:args (list {:type "lit-string" :value "a"})})
:body (list {:type "return" :expr {:type "self"}})})
;; ── 5. End-to-end: a small "filed-in" snippet ──
(st-test
"small filed-in class snippet"
(st-parse-chunks
"Object subclass: #Account
instanceVariableNames: 'balance'!
!Account methodsFor: 'access'!
balance
^ balance!
deposit: amount
balance := balance + amount.
^ self! !")
(list
{:kind "expr"
:ast {:type "send"
:receiver {:type "ident" :name "Object"}
:selector "subclass:instanceVariableNames:"
:args (list
{:type "lit-symbol" :value "Account"}
{:type "lit-string" :value "balance"})}}
{:kind "blank"}
{:kind "expr"
:ast {:type "send"
:receiver {:type "ident" :name "Account"}
:selector "methodsFor:"
:args (list {:type "lit-string" :value "access"})}}
{:kind "method"
:class "Account"
:class-side? false
:category "access"
:ast {:type "method"
:selector "balance"
:params (list)
:temps (list)
:pragmas (list)
:body (list
{:type "return"
:expr {:type "ident" :name "balance"}})}}
{:kind "method"
:class "Account"
:class-side? false
:category "access"
:ast {:type "method"
:selector "deposit:"
:params (list "amount")
:temps (list)
:pragmas (list)
:body (list
{:type "assign"
:name "balance"
:expr {:type "send"
:receiver {:type "ident" :name "balance"}
:selector "+"
:args (list {:type "ident" :name "amount"})}}
{:type "return" :expr {:type "self"}})}}
{:kind "end-methods"}))
(list st-test-pass st-test-fail)

182
lib/smalltalk/tests/runtime.sx
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@@ -1,182 +0,0 @@
;; Smalltalk runtime tests — class table, type→class mapping, instances.
;;
;; Reuses helpers (st-test, st-deep=?) from tokenize.sx. Counters reset
;; here so this file's summary covers runtime tests only.
(set! st-test-pass 0)
(set! st-test-fail 0)
(set! st-test-fails (list))
;; Fresh hierarchy for every test file.
(st-bootstrap-classes!)
;; ── 1. Bootstrap installed expected classes ──
(st-test "Object exists" (st-class-exists? "Object") true)
(st-test "Behavior exists" (st-class-exists? "Behavior") true)
(st-test "Metaclass exists" (st-class-exists? "Metaclass") true)
(st-test "True/False/UndefinedObject"
(and
(st-class-exists? "True")
(st-class-exists? "False")
(st-class-exists? "UndefinedObject"))
true)
(st-test "SmallInteger / Float / Symbol exist"
(and
(st-class-exists? "SmallInteger")
(st-class-exists? "Float")
(st-class-exists? "Symbol"))
true)
(st-test "BlockClosure exists" (st-class-exists? "BlockClosure") true)
;; ── 2. Superclass chain ──
(st-test "Object has no superclass" (st-class-superclass "Object") nil)
(st-test "Behavior super = Object" (st-class-superclass "Behavior") "Object")
(st-test "True super = Boolean" (st-class-superclass "True") "Boolean")
(st-test "Symbol super = String" (st-class-superclass "Symbol") "String")
(st-test
"String chain"
(st-class-chain "String")
(list "String" "ArrayedCollection" "SequenceableCollection" "Collection" "Object"))
(st-test
"SmallInteger chain"
(st-class-chain "SmallInteger")
(list "SmallInteger" "Integer" "Number" "Magnitude" "Object"))
;; ── 3. inherits-from? ──
(st-test "True inherits from Boolean" (st-class-inherits-from? "True" "Boolean") true)
(st-test "True inherits from Object" (st-class-inherits-from? "True" "Object") true)
(st-test "True inherits from True" (st-class-inherits-from? "True" "True") true)
(st-test
"True does not inherit from Number"
(st-class-inherits-from? "True" "Number")
false)
(st-test
"Object does not inherit from Number"
(st-class-inherits-from? "Object" "Number")
false)
;; ── 4. type→class mapping ──
(st-test "class-of nil" (st-class-of nil) "UndefinedObject")
(st-test "class-of true" (st-class-of true) "True")
(st-test "class-of false" (st-class-of false) "False")
(st-test "class-of int" (st-class-of 42) "SmallInteger")
(st-test "class-of zero" (st-class-of 0) "SmallInteger")
(st-test "class-of negative int" (st-class-of -3) "SmallInteger")
(st-test "class-of float" (st-class-of 3.14) "Float")
(st-test "class-of string" (st-class-of "hi") "String")
(st-test "class-of symbol" (st-class-of (quote foo)) "Symbol")
(st-test "class-of list" (st-class-of (list 1 2)) "Array")
(st-test "class-of empty list" (st-class-of (list)) "Array")
(st-test "class-of lambda" (st-class-of (fn (x) x)) "BlockClosure")
(st-test "class-of dict" (st-class-of {:a 1}) "Dictionary")
;; ── 5. User class definition ──
(st-class-define! "Account" "Object" (list "balance" "owner"))
(st-class-define! "SavingsAccount" "Account" (list "rate"))
(st-test "Account exists" (st-class-exists? "Account") true)
(st-test "Account super = Object" (st-class-superclass "Account") "Object")
(st-test
"SavingsAccount chain"
(st-class-chain "SavingsAccount")
(list "SavingsAccount" "Account" "Object"))
(st-test
"SavingsAccount own ivars"
(get (st-class-get "SavingsAccount") :ivars)
(list "rate"))
(st-test
"SavingsAccount inherited+own ivars"
(st-class-all-ivars "SavingsAccount")
(list "balance" "owner" "rate"))
;; ── 6. Instance construction ──
(define a1 (st-make-instance "Account"))
(st-test "instance is st-instance" (st-instance? a1) true)
(st-test "instance class" (get a1 :class) "Account")
(st-test "instance ivars start nil" (st-iv-get a1 "balance") nil)
(st-test
"instance has all expected ivars"
(sort (keys (get a1 :ivars)))
(sort (list "balance" "owner")))
(define a2 (st-iv-set! a1 "balance" 100))
(st-test "iv-set! returns updated copy" (st-iv-get a2 "balance") 100)
(st-test "iv-set! does not mutate original" (st-iv-get a1 "balance") nil)
(st-test "class-of instance" (st-class-of a1) "Account")
(define s1 (st-make-instance "SavingsAccount"))
(st-test
"subclass instance has all inherited ivars"
(sort (keys (get s1 :ivars)))
(sort (list "balance" "owner" "rate")))
;; ── 7. Method install + lookup ──
(st-class-add-method!
"Account"
"balance"
(st-parse-method "balance ^ balance"))
(st-class-add-method!
"Account"
"deposit:"
(st-parse-method "deposit: amount balance := balance + amount. ^ self"))
(st-test
"method registered"
(has-key? (get (st-class-get "Account") :methods) "balance")
true)
(st-test
"method lookup direct"
(= (st-method-lookup "Account" "balance" false) nil)
false)
(st-test
"method lookup walks superclass"
(= (st-method-lookup "SavingsAccount" "deposit:" false) nil)
false)
(st-test
"method lookup unknown selector"
(st-method-lookup "Account" "frobnicate" false)
nil)
(st-test
"method lookup records defining class"
(get (st-method-lookup "SavingsAccount" "balance" false) :defining-class)
"Account")
;; SavingsAccount overrides deposit:
(st-class-add-method!
"SavingsAccount"
"deposit:"
(st-parse-method "deposit: amount ^ super deposit: amount + 1"))
(st-test
"subclass override picked first"
(get (st-method-lookup "SavingsAccount" "deposit:" false) :defining-class)
"SavingsAccount")
(st-test
"Account still finds its own deposit:"
(get (st-method-lookup "Account" "deposit:" false) :defining-class)
"Account")
;; ── 8. Class-side methods ──
(st-class-add-class-method!
"Account"
"new"
(st-parse-method "new ^ super new"))
(st-test
"class-side lookup"
(= (st-method-lookup "Account" "new" true) nil)
false)
(st-test
"instance-side does not find class method"
(st-method-lookup "Account" "new" false)
nil)
;; ── 9. Re-bootstrap resets table ──
(st-bootstrap-classes!)
(st-test "after re-bootstrap Account gone" (st-class-exists? "Account") false)
(st-test "after re-bootstrap Object stays" (st-class-exists? "Object") true)
(list st-test-pass st-test-fail)

362
lib/smalltalk/tests/tokenize.sx
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@@ -1,362 +0,0 @@
;; Smalltalk tokenizer tests.
;;
;; Lightweight runner: each test checks actual vs expected with structural
;; equality and accumulates pass/fail counters. Final summary read by
;; lib/smalltalk/test.sh.
(define
st-deep=?
(fn
(a b)
(cond
((= a b) true)
((and (dict? a) (dict? b))
(let
((ak (keys a)) (bk (keys b)))
(if
(not (= (len ak) (len bk)))
false
(every?
(fn
(k)
(and (has-key? b k) (st-deep=? (get a k) (get b k))))
ak))))
((and (list? a) (list? b))
(if
(not (= (len a) (len b)))
false
(let
((i 0) (ok true))
(begin
(define
de-loop
(fn
()
(when
(and ok (< i (len a)))
(begin
(when
(not (st-deep=? (nth a i) (nth b i)))
(set! ok false))
(set! i (+ i 1))
(de-loop)))))
(de-loop)
ok))))
(:else false))))
(define st-test-pass 0)
(define st-test-fail 0)
(define st-test-fails (list))
(define
st-test
(fn
(name actual expected)
(if
(st-deep=? actual expected)
(set! st-test-pass (+ st-test-pass 1))
(begin
(set! st-test-fail (+ st-test-fail 1))
(append! st-test-fails {:actual actual :expected expected :name name})))))
;; Strip eof and project to just :type/:value.
(define
st-toks
(fn
(src)
(map
(fn (tok) {:type (get tok :type) :value (get tok :value)})
(filter
(fn (tok) (not (= (get tok :type) "eof")))
(st-tokenize src)))))
;; ── 1. Whitespace / empty ──
(st-test "empty input" (st-toks "") (list))
(st-test "all whitespace" (st-toks " \t\n ") (list))
;; ── 2. Identifiers ──
(st-test
"lowercase ident"
(st-toks "foo")
(list {:type "ident" :value "foo"}))
(st-test
"capitalised ident"
(st-toks "Foo")
(list {:type "ident" :value "Foo"}))
(st-test
"underscore ident"
(st-toks "_x")
(list {:type "ident" :value "_x"}))
(st-test
"digits in ident"
(st-toks "foo123")
(list {:type "ident" :value "foo123"}))
(st-test
"two idents separated"
(st-toks "foo bar")
(list {:type "ident" :value "foo"} {:type "ident" :value "bar"}))
;; ── 3. Keyword selectors ──
(st-test
"keyword selector"
(st-toks "foo:")
(list {:type "keyword" :value "foo:"}))
(st-test
"keyword call"
(st-toks "x at: 1")
(list
{:type "ident" :value "x"}
{:type "keyword" :value "at:"}
{:type "number" :value 1}))
(st-test
"two-keyword chain stays separate"
(st-toks "at: 1 put: 2")
(list
{:type "keyword" :value "at:"}
{:type "number" :value 1}
{:type "keyword" :value "put:"}
{:type "number" :value 2}))
(st-test
"ident then assign — not a keyword"
(st-toks "x := 1")
(list
{:type "ident" :value "x"}
{:type "assign" :value ":="}
{:type "number" :value 1}))
;; ── 4. Numbers ──
(st-test
"integer"
(st-toks "42")
(list {:type "number" :value 42}))
(st-test
"float"
(st-toks "3.14")
(list {:type "number" :value 3.14}))
(st-test
"hex radix"
(st-toks "16rFF")
(list
{:type "number"
:value
{:radix 16 :digits "FF" :value 255 :kind "radix"}}))
(st-test
"binary radix"
(st-toks "2r1011")
(list
{:type "number"
:value
{:radix 2 :digits "1011" :value 11 :kind "radix"}}))
(st-test
"exponent"
(st-toks "1e3")
(list {:type "number" :value 1000}))
(st-test
"negative exponent (parser handles minus)"
(st-toks "1.5e-2")
(list {:type "number" :value 0.015}))
;; ── 5. Strings ──
(st-test
"simple string"
(st-toks "'hi'")
(list {:type "string" :value "hi"}))
(st-test
"empty string"
(st-toks "''")
(list {:type "string" :value ""}))
(st-test
"doubled-quote escape"
(st-toks "'a''b'")
(list {:type "string" :value "a'b"}))
;; ── 6. Characters ──
(st-test
"char literal letter"
(st-toks "$a")
(list {:type "char" :value "a"}))
(st-test
"char literal punct"
(st-toks "$$")
(list {:type "char" :value "$"}))
(st-test
"char literal space"
(st-toks "$ ")
(list {:type "char" :value " "}))
;; ── 7. Symbols ──
(st-test
"symbol ident"
(st-toks "#foo")
(list {:type "symbol" :value "foo"}))
(st-test
"symbol binary"
(st-toks "#+")
(list {:type "symbol" :value "+"}))
(st-test
"symbol arrow"
(st-toks "#->")
(list {:type "symbol" :value "->"}))
(st-test
"symbol keyword chain"
(st-toks "#at:put:")
(list {:type "symbol" :value "at:put:"}))
(st-test
"quoted symbol with spaces"
(st-toks "#'foo bar'")
(list {:type "symbol" :value "foo bar"}))
;; ── 8. Literal arrays / byte arrays ──
(st-test
"literal array open"
(st-toks "#(1 2)")
(list
{:type "array-open" :value "#("}
{:type "number" :value 1}
{:type "number" :value 2}
{:type "rparen" :value ")"}))
(st-test
"byte array open"
(st-toks "#[1 2 3]")
(list
{:type "byte-array-open" :value "#["}
{:type "number" :value 1}
{:type "number" :value 2}
{:type "number" :value 3}
{:type "rbracket" :value "]"}))
;; ── 9. Binary selectors ──
(st-test "plus" (st-toks "+") (list {:type "binary" :value "+"}))
(st-test "minus" (st-toks "-") (list {:type "binary" :value "-"}))
(st-test "star" (st-toks "*") (list {:type "binary" :value "*"}))
(st-test "double-equal" (st-toks "==") (list {:type "binary" :value "=="}))
(st-test "leq" (st-toks "<=") (list {:type "binary" :value "<="}))
(st-test "geq" (st-toks ">=") (list {:type "binary" :value ">="}))
(st-test "neq" (st-toks "~=") (list {:type "binary" :value "~="}))
(st-test "arrow" (st-toks "->") (list {:type "binary" :value "->"}))
(st-test "comma" (st-toks ",") (list {:type "binary" :value ","}))
(st-test
"binary in expression"
(st-toks "a + b")
(list
{:type "ident" :value "a"}
{:type "binary" :value "+"}
{:type "ident" :value "b"}))
;; ── 10. Punctuation ──
(st-test "lparen" (st-toks "(") (list {:type "lparen" :value "("}))
(st-test "rparen" (st-toks ")") (list {:type "rparen" :value ")"}))
(st-test "lbracket" (st-toks "[") (list {:type "lbracket" :value "["}))
(st-test "rbracket" (st-toks "]") (list {:type "rbracket" :value "]"}))
(st-test "lbrace" (st-toks "{") (list {:type "lbrace" :value "{"}))
(st-test "rbrace" (st-toks "}") (list {:type "rbrace" :value "}"}))
(st-test "period" (st-toks ".") (list {:type "period" :value "."}))
(st-test "semi" (st-toks ";") (list {:type "semi" :value ";"}))
(st-test "bar" (st-toks "|") (list {:type "bar" :value "|"}))
(st-test "caret" (st-toks "^") (list {:type "caret" :value "^"}))
(st-test "bang" (st-toks "!") (list {:type "bang" :value "!"}))
(st-test "colon" (st-toks ":") (list {:type "colon" :value ":"}))
(st-test "assign" (st-toks ":=") (list {:type "assign" :value ":="}))
;; ── 11. Comments ──
(st-test "comment skipped" (st-toks "\"hello\"") (list))
(st-test
"comment between tokens"
(st-toks "a \"comment\" b")
(list {:type "ident" :value "a"} {:type "ident" :value "b"}))
(st-test
"multi-line comment"
(st-toks "\"line1\nline2\"42")
(list {:type "number" :value 42}))
;; ── 12. Compound expressions ──
(st-test
"block with params"
(st-toks "[:a :b | a + b]")
(list
{:type "lbracket" :value "["}
{:type "colon" :value ":"}
{:type "ident" :value "a"}
{:type "colon" :value ":"}
{:type "ident" :value "b"}
{:type "bar" :value "|"}
{:type "ident" :value "a"}
{:type "binary" :value "+"}
{:type "ident" :value "b"}
{:type "rbracket" :value "]"}))
(st-test
"cascade"
(st-toks "x m1; m2")
(list
{:type "ident" :value "x"}
{:type "ident" :value "m1"}
{:type "semi" :value ";"}
{:type "ident" :value "m2"}))
(st-test
"method body return"
(st-toks "^ self foo")
(list
{:type "caret" :value "^"}
{:type "ident" :value "self"}
{:type "ident" :value "foo"}))
(st-test
"class declaration head"
(st-toks "Object subclass: #Foo")
(list
{:type "ident" :value "Object"}
{:type "keyword" :value "subclass:"}
{:type "symbol" :value "Foo"}))
(st-test
"temp declaration"
(st-toks "| t1 t2 |")
(list
{:type "bar" :value "|"}
{:type "ident" :value "t1"}
{:type "ident" :value "t2"}
{:type "bar" :value "|"}))
(st-test
"chunk separator"
(st-toks "Foo bar !")
(list
{:type "ident" :value "Foo"}
{:type "ident" :value "bar"}
{:type "bang" :value "!"}))
(st-test
"keyword call with binary precedence"
(st-toks "x foo: 1 + 2")
(list
{:type "ident" :value "x"}
{:type "keyword" :value "foo:"}
{:type "number" :value 1}
{:type "binary" :value "+"}
{:type "number" :value 2}))
(list st-test-pass st-test-fail)

366
lib/smalltalk/tokenizer.sx
View File

@@ -1,366 +0,0 @@
;; Smalltalk tokenizer.
;;
;; Token types:
;; ident identifier (foo, Foo, _x)
;; keyword selector keyword (foo:) — value is "foo:" with the colon
;; binary binary selector chars run together (+, ==, ->, <=, ~=, ...)
;; number integer or float; radix integers like 16rFF supported
;; string 'hello''world' style
;; char $c
;; symbol #foo, #foo:bar:, #+, #'with spaces'
;; array-open #(
;; byte-array-open #[
;; lparen rparen lbracket rbracket lbrace rbrace
;; period semi bar caret colon assign bang
;; eof
;;
;; Comments "…" are skipped.
(define st-make-token (fn (type value pos) {:type type :value value :pos pos}))
(define st-digit? (fn (c) (and (not (= c nil)) (>= c "0") (<= c "9"))))
(define
st-letter?
(fn
(c)
(and
(not (= c nil))
(or (and (>= c "a") (<= c "z")) (and (>= c "A") (<= c "Z"))))))
(define st-ident-start? (fn (c) (or (st-letter? c) (= c "_"))))
(define st-ident-char? (fn (c) (or (st-ident-start? c) (st-digit? c))))
(define st-ws? (fn (c) (or (= c " ") (= c "\t") (= c "\n") (= c "\r"))))
(define
st-binary-chars
(list "+" "-" "*" "/" "\\" "~" "<" ">" "=" "@" "%" "&" "?" ","))
(define
st-binary-char?
(fn (c) (and (not (= c nil)) (contains? st-binary-chars c))))
(define
st-radix-digit?
(fn
(c)
(and
(not (= c nil))
(or (st-digit? c) (and (>= c "A") (<= c "Z"))))))
(define
st-tokenize
(fn
(src)
(let
((tokens (list)) (pos 0) (src-len (len src)))
(define
pk
(fn
(offset)
(if (< (+ pos offset) src-len) (nth src (+ pos offset)) nil)))
(define cur (fn () (pk 0)))
(define advance! (fn (n) (set! pos (+ pos n))))
(define
push!
(fn
(type value start)
(append! tokens (st-make-token type value start))))
(define
skip-comment!
(fn
()
(cond
((>= pos src-len) nil)
((= (cur) "\"") (advance! 1))
(else (begin (advance! 1) (skip-comment!))))))
(define
skip-ws!
(fn
()
(cond
((>= pos src-len) nil)
((st-ws? (cur)) (begin (advance! 1) (skip-ws!)))
((= (cur) "\"") (begin (advance! 1) (skip-comment!) (skip-ws!)))
(else nil))))
(define
read-ident-chars!
(fn
()
(when
(and (< pos src-len) (st-ident-char? (cur)))
(begin (advance! 1) (read-ident-chars!)))))
(define
read-decimal-digits!
(fn
()
(when
(and (< pos src-len) (st-digit? (cur)))
(begin (advance! 1) (read-decimal-digits!)))))
(define
read-radix-digits!
(fn
()
(when
(and (< pos src-len) (st-radix-digit? (cur)))
(begin (advance! 1) (read-radix-digits!)))))
(define
read-exp-part!
(fn
()
(when
(and
(< pos src-len)
(or (= (cur) "e") (= (cur) "E"))
(let
((p1 (pk 1)) (p2 (pk 2)))
(or
(st-digit? p1)
(and (or (= p1 "+") (= p1 "-")) (st-digit? p2)))))
(begin
(advance! 1)
(when
(and (< pos src-len) (or (= (cur) "+") (= (cur) "-")))
(advance! 1))
(read-decimal-digits!)))))
(define
read-number
(fn
(start)
(begin
(read-decimal-digits!)
(cond
((and (< pos src-len) (= (cur) "r"))
(let
((base-str (slice src start pos)))
(begin
(advance! 1)
(let
((rstart pos))
(begin
(read-radix-digits!)
(let
((digits (slice src rstart pos)))
{:radix (parse-number base-str)
:digits digits
:value (parse-radix base-str digits)
:kind "radix"}))))))
((and
(< pos src-len)
(= (cur) ".")
(st-digit? (pk 1)))
(begin
(advance! 1)
(read-decimal-digits!)
(read-exp-part!)
(parse-number (slice src start pos))))
(else
(begin
(read-exp-part!)
(parse-number (slice src start pos))))))))
(define
parse-radix
(fn
(base-str digits)
(let
((base (parse-number base-str))
(chars digits)
(n-len (len digits))
(idx 0)
(acc 0))
(begin
(define
rd-loop
(fn
()
(when
(< idx n-len)
(let
((c (nth chars idx)))
(let
((d (cond
((and (>= c "0") (<= c "9")) (- (char-code c) 48))
((and (>= c "A") (<= c "Z")) (- (char-code c) 55))
(else 0))))
(begin
(set! acc (+ (* acc base) d))
(set! idx (+ idx 1))
(rd-loop)))))))
(rd-loop)
acc))))
(define
read-string
(fn
()
(let
((chars (list)))
(begin
(advance! 1)
(define
loop
(fn
()
(cond
((>= pos src-len) nil)
((= (cur) "'")
(cond
((= (pk 1) "'")
(begin
(append! chars "'")
(advance! 2)
(loop)))
(else (advance! 1))))
(else
(begin (append! chars (cur)) (advance! 1) (loop))))))
(loop)
(join "" chars)))))
(define
read-binary-run!
(fn
()
(let
((start pos))
(begin
(define
bin-loop
(fn
()
(when
(and (< pos src-len) (st-binary-char? (cur)))
(begin (advance! 1) (bin-loop)))))
(bin-loop)
(slice src start pos)))))
(define
read-symbol
(fn
(start)
(cond
;; Quoted symbol: #'whatever'
((= (cur) "'")
(let ((s (read-string))) (push! "symbol" s start)))
;; Binary-char symbol: #+, #==, #->, #|
((or (st-binary-char? (cur)) (= (cur) "|"))
(let ((b (read-binary-run!)))
(cond
((= b "")
;; lone | wasn't binary; consume it
(begin (advance! 1) (push! "symbol" "|" start)))
(else (push! "symbol" b start)))))
;; Identifier or keyword chain: #foo, #foo:bar:
((st-ident-start? (cur))
(let ((id-start pos))
(begin
(read-ident-chars!)
(define
kw-loop
(fn
()
(when
(and (< pos src-len) (= (cur) ":"))
(begin
(advance! 1)
(when
(and (< pos src-len) (st-ident-start? (cur)))
(begin (read-ident-chars!) (kw-loop)))))))
(kw-loop)
(push! "symbol" (slice src id-start pos) start))))
(else
(error
(str "st-tokenize: bad symbol at " pos))))))
(define
step
(fn
()
(begin
(skip-ws!)
(when
(< pos src-len)
(let
((start pos) (c (cur)))
(cond
;; Identifier or keyword
((st-ident-start? c)
(begin
(read-ident-chars!)
(let
((word (slice src start pos)))
(cond
;; ident immediately followed by ':' (and not ':=') => keyword
((and
(< pos src-len)
(= (cur) ":")
(not (= (pk 1) "=")))
(begin
(advance! 1)
(push!
"keyword"
(str word ":")
start)))
(else (push! "ident" word start))))
(step)))
;; Number
((st-digit? c)
(let
((v (read-number start)))
(begin (push! "number" v start) (step))))
;; String
((= c "'")
(let
((s (read-string)))
(begin (push! "string" s start) (step))))
;; Character literal
((= c "$")
(cond
((>= (+ pos 1) src-len)
(error (str "st-tokenize: $ at end of input")))
(else
(begin
(advance! 1)
(push! "char" (cur) start)
(advance! 1)
(step)))))
;; Symbol or array literal
((= c "#")
(cond
((= (pk 1) "(")
(begin (advance! 2) (push! "array-open" "#(" start) (step)))
((= (pk 1) "[")
(begin (advance! 2) (push! "byte-array-open" "#[" start) (step)))
(else
(begin (advance! 1) (read-symbol start) (step)))))
;; Assignment := or bare colon
((= c ":")
(cond
((= (pk 1) "=")
(begin (advance! 2) (push! "assign" ":=" start) (step)))
(else
(begin (advance! 1) (push! "colon" ":" start) (step)))))
;; Single-char structural punctuation
((= c "(") (begin (advance! 1) (push! "lparen" "(" start) (step)))
((= c ")") (begin (advance! 1) (push! "rparen" ")" start) (step)))
((= c "[") (begin (advance! 1) (push! "lbracket" "[" start) (step)))
((= c "]") (begin (advance! 1) (push! "rbracket" "]" start) (step)))
((= c "{") (begin (advance! 1) (push! "lbrace" "{" start) (step)))
((= c "}") (begin (advance! 1) (push! "rbrace" "}" start) (step)))
((= c ".") (begin (advance! 1) (push! "period" "." start) (step)))
((= c ";") (begin (advance! 1) (push! "semi" ";" start) (step)))
((= c "|") (begin (advance! 1) (push! "bar" "|" start) (step)))
((= c "^") (begin (advance! 1) (push! "caret" "^" start) (step)))
((= c "!") (begin (advance! 1) (push! "bang" "!" start) (step)))
;; Binary selector run
((st-binary-char? c)
(let
((b (read-binary-run!)))
(begin (push! "binary" b start) (step))))
(else
(error
(str
"st-tokenize: unexpected char "
c
" at "
pos)))))))))
(step)
(push! "eof" nil pos)
tokens)))

77
plans/agent-briefings/smalltalk-loop.md
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@@ -1,77 +0,0 @@
# smalltalk-on-sx loop agent (single agent, queue-driven)
Role: iterates `plans/smalltalk-on-sx.md` forever. Message-passing OO + **blocks with non-local return** on delimited continuations. Non-local return is the headline showcase — every other Smalltalk reinvents it on the host stack; on SX it falls out of the captured method-return continuation.
```
description: smalltalk-on-sx queue loop
subagent_type: general-purpose
run_in_background: true
isolation: worktree
```
## Prompt
You are the sole background agent working `/root/rose-ash/plans/smalltalk-on-sx.md`. Isolated worktree, forever, one commit per feature. Never push.
## Restart baseline — check before iterating
1. Read `plans/smalltalk-on-sx.md` — roadmap + Progress log.
2. `ls lib/smalltalk/` — pick up from the most advanced file.
3. If `lib/smalltalk/tests/*.sx` exist, run them. Green before new work.
4. If `lib/smalltalk/scoreboard.md` exists, that's your baseline.
## The queue
Phase order per `plans/smalltalk-on-sx.md`:
- **Phase 1** — tokenizer + parser (chunk format, identifiers, keywords `foo:`, binary selectors, `#sym`, `#(…)`, `$c`, blocks `[:a | …]`, cascades, message precedence)
- **Phase 2** — object model + sequential eval (class table bootstrap, message dispatch, `super`, `doesNotUnderstand:`, instance variables)
- **Phase 3** — **THE SHOWCASE**: blocks with non-local return via captured method-return continuation. `whileTrue:` / `ifTrue:ifFalse:` as block sends. 5 classic programs (eight-queens, quicksort, mandelbrot, life, fibonacci) green.
- **Phase 4** — reflection + MOP: `perform:`, `respondsTo:`, runtime method addition, `becomeForward:`, `Exception` / `on:do:` / `ensure:` on top of `handler-bind`/`raise`
- **Phase 5** — collections + numeric tower + streams
- **Phase 6** — port SUnit, vendor Pharo Kernel-Tests slice, drive corpus to 200+
- **Phase 7** — speed (optional): inline caching, block intrinsification
Within a phase, pick the checkbox that unlocks the most tests per effort.
Every iteration: implement → test → commit → tick `[ ]` → Progress log → next.
## Ground rules (hard)
- **Scope:** only `lib/smalltalk/**` and `plans/smalltalk-on-sx.md`. Do **not** edit `spec/`, `hosts/`, `shared/`, other `lib/<lang>/` dirs, `lib/stdlib.sx`, or `lib/` root. Smalltalk primitives go in `lib/smalltalk/runtime.sx`.
- **NEVER call `sx_build`.** 600s watchdog. If sx_server binary broken → Blockers entry, stop.
- **Shared-file issues** → plan's Blockers with minimal repro.
- **Delimited continuations** are in `lib/callcc.sx` + `spec/evaluator.sx` Step 5. `sx_summarise` spec/evaluator.sx first — 2300+ lines.
- **SX files:** `sx-tree` MCP tools ONLY. `sx_validate` after edits.
- **Worktree:** commit locally. Never push. Never touch `main`.
- **Commit granularity:** one feature per commit.
- **Plan file:** update Progress log + tick boxes every commit.
## Smalltalk-specific gotchas
- **Method invocation captures `^k`** — the return continuation. Bind it as the block's escape token. `^expr` from inside any nested block invokes that captured `^k`. Escape past method return raises `BlockContext>>cannotReturn:`.
- **Blocks are lambdas + escape token**, not bare lambdas. `value`/`value:`/… invoke the lambda; `^` invokes the escape.
- **`ifTrue:` / `ifFalse:` / `whileTrue:` are ordinary block sends** — no special form. The runtime intrinsifies them in the JIT path (Tier 1 of bytecode expansion already covers this pattern).
- **Cascade** `r m1; m2; m3` desugars to `(let ((tmp r)) (st-send tmp 'm1 ()) (st-send tmp 'm2 ()) (st-send tmp 'm3 ()))`. Result is the cascade's last send (or first, depending on parser variant — pick one and document).
- **`super` send** looks up starting from the *defining* class's superclass, not the receiver class. Stash the defining class on the method record.
- **Selectors are interned symbols.** Use SX symbols.
- **Receiver dispatch:** tagged ints / floats / strings / symbols / `nil` / `true` / `false` aren't boxed. Their classes (`SmallInteger`, `Float`, `String`, `Symbol`, `UndefinedObject`, `True`, `False`) are looked up by SX type-of, not by an `:class` field.
- **Method precedence:** unary > binary > keyword. `3 + 4 factorial` is `3 + (4 factorial)`. `a foo: b bar` is `a foo: (b bar)` (keyword absorbs trailing unary).
- **Image / fileIn / become: between sessions** = out of scope. One-way `becomeForward:` only.
- **Test corpus:** ~200 hand-written + a slice of Pharo Kernel-Tests. Place programs in `lib/smalltalk/tests/programs/`.
## General gotchas (all loops)
- SX `do` = R7RS iteration. Use `begin` for multi-expr sequences.
- `cond`/`when`/`let` clauses evaluate only the last expr.
- `type-of` on user fn returns `"lambda"`.
- Shell heredoc `||` gets eaten — escape or use `case`.
## Style
- No comments in `.sx` unless non-obvious.
- No new planning docs — update `plans/smalltalk-on-sx.md` inline.
- Short, factual commit messages (`smalltalk: tokenizer + 56 tests`).
- One feature per iteration. Commit. Log. Next.
Go. Read the plan; find first `[ ]`; implement.

230
plans/forth-on-sx.md
View File

@@ -69,23 +69,30 @@ Representation:
- [x] Tests in `lib/forth/tests/test-phase2.sx` — 26/26 pass
### Phase 3 — control flow + first Hayes tests green
- [ ] `IF`, `ELSE`, `THEN` — compile to SX `if`
- [ ] `BEGIN`, `UNTIL`, `WHILE`, `REPEAT`, `AGAIN` — compile to loops
- [ ] `DO`, `LOOP`, `+LOOP`, `I`, `J`, `LEAVE` — counted loops (needs a return stack)
- [ ] Return stack: `>R`, `R>`, `R@`, `2>R`, `2R>`, `2R@`
- [ ] Vendor John Hayes' test suite to `lib/forth/ans-tests/`
- [ ] `lib/forth/conformance.sh` + runner; `scoreboard.json` + `scoreboard.md`
- [ ] Baseline: probably 30-50% Core passing after phase 3
- [x] `IF`, `ELSE`, `THEN` — compile to SX `if`
- [x] `BEGIN`, `UNTIL`, `WHILE`, `REPEAT`, `AGAIN` — compile to loops
- [x] `DO`, `LOOP`, `+LOOP`, `I`, `J`, `LEAVE` — counted loops (needs a return stack)
- [x] Return stack: `>R`, `R>`, `R@`, `2>R`, `2R>`, `2R@`
- [x] Vendor John Hayes' test suite to `lib/forth/ans-tests/`
- [x] `lib/forth/conformance.sh` + runner; `scoreboard.json` + `scoreboard.md`
- [x] Baseline: probably 30-50% Core passing after phase 3
### Phase 4 — strings + more Core
- [ ] `S"`, `C"`, `."`, `TYPE`, `COUNT`, `CMOVE`, `FILL`, `BLANK`
- [ ] `CHAR`, `[CHAR]`, `KEY`, `ACCEPT`
- [ ] `BASE` manipulation: `DECIMAL`, `HEX`
- [ ] `DEPTH`, `SP@`, `SP!`
- [ ] Drive Hayes Core pass-rate up
- [x] `S"`, `C"`, `."`, `TYPE`, `COUNT`, `CMOVE`, `FILL`, `BLANK`
- [x] `CHAR`, `[CHAR]`, `KEY`, `ACCEPT`
- [x] `BASE` manipulation: `DECIMAL`, `HEX`
- [x] `DEPTH`, `SP@`, `SP!`
- [x] Drive Hayes Core pass-rate up
### Phase 5 — Core Extension + optional word sets
- [ ] Full Core + Core Extension
- [x] Memory: `CREATE`, `HERE`, `ALLOT`, `,`, `C,`, `CELL+`, `CELLS`, `ALIGN`, `ALIGNED`, `2!`, `2@`
- [x] Unsigned compare: `U<`, `U>`
- [x] Mixed/double-cell math: `S>D`, `M*`, `UM*`, `UM/MOD`, `FM/MOD`, `SM/REM`, `*/`, `*/MOD`
- [x] Double-cell ops: `D+`, `D-`, `D=`, `D<`, `D0=`, `2DUP`, `2DROP`, `2OVER`, `2SWAP` (already), plus `D>S`, `DABS`, `DNEGATE`
- [x] Number formatting: `<#`, `#`, `#S`, `#>`, `HOLD`, `SIGN`, `.R`, `U.`, `U.R`
- [x] Parsing/dictionary: `WORD`, `FIND`, `EXECUTE`, `'`, `[']`, `LITERAL`, `POSTPONE`, `>BODY` (DOES> deferred — needs runtime-rebind of last CREATE)
- [x] Source/state: `EVALUATE`, `STATE`, `[`, `]` (`SOURCE`/`>IN` stubbed; tokenized input means the exact byte/offset semantics aren't useful here)
- [ ] Misc Core: `WITHIN`, `MAX`/`MIN` (already), `ABORT`, `ABORT"`, `EXIT`, `UNLOOP`
- [ ] File Access word set (via SX IO)
- [ ] String word set (`SLITERAL`, `COMPARE`, `SEARCH`)
- [ ] Target: 100% Hayes Core
@@ -99,6 +106,203 @@ Representation:
_Newest first._
- **Phase 5 — `[`, `]`, `STATE`, `EVALUATE` (+5; Hayes 463→477, 74%).**
`[` (IMMEDIATE) clears `state.compiling`, `]` sets it. `STATE`
pushes the sentinel address `"@@state"` and `@` reads it as
`-1`/`0` based on the live `compiling` flag. `EVALUATE` reads
the (addr,u) string from byte memory, retokenises it via
`forth-tokens`, swaps it in as the active input, runs the
interpret loop, and restores the saved input. `SOURCE` and
`>IN` exist as stubs that push zeros — our whitespace-tokenised
input has no native byte-offset, so the deeper Hayes tests
that re-position parsing via `>IN !` stay marked as errors
rather than silently misbehaving.
- **Phase 5 — parsing/dictionary words `'`/`[']`/`EXECUTE`/`LITERAL`/
`POSTPONE`/`WORD`/`FIND`/`>BODY` (Hayes 448→463, 72%).** xt is
represented as the SX dict reference of the word record, so
`'`/`[']` push the looked-up record and `EXECUTE` calls
`forth-execute-word` on the popped value. `LITERAL` (IMMEDIATE)
pops a value at compile time and emits a push-op. `POSTPONE`
(IMMEDIATE) compiles into the *outer* def an op that, when run
during a *later* compile, appends a call-w op to whatever def is
current — the standard two-tier compile semantic. Added
`state.last-defined` tracked by every primitive/colon definition
so `IMMEDIATE` can target the most-recent word even after `;`
closes the def. CREATE now stashes its data-field address on the
word record so `>BODY` can recover it. `WORD`/`FIND` use the byte
memory and counted-string layout already in place.
`DOES>` is deferred — needs a runtime mechanism to rebind the
last-CREATE'd word's action.
- **Phase 5 — pictured numeric output: `<#`/`#`/`#S`/`#>`/`HOLD`/`SIGN` +
`U.`/`U.R`/`.R` (+9; Hayes 446→448, 70%).** Added a `state.hold`
list of single-character strings — `<#` resets it, `HOLD` and
`SIGN` prepend, `#` divides ud by BASE and prepends one digit,
`#S` loops `#` until ud is zero (running once even on zero),
`#>` drops ud and copies the joined hold buffer into mem,
pushing `(addr, len)`. `U.` / `.R` / `U.R` use a separate
`forth-num-to-string` for one-shot decimal/hex output and
`forth-spaces-str` for right-justify padding.
- **Phase 5 — double-cell ops `D+`/`D-`/`DNEGATE`/`DABS`/`D=`/`D<`/`D0=`/
`D0<`/`DMAX`/`DMIN` (+18; Hayes unchanged).** Doubles get rebuilt
from `(lo, hi)` cells via `forth-double-from-cells-s`, the op runs
in bignum, and we push back via `forth-double-push-s`. Hayes Core
doesn't exercise D-words (those live in Gerry Jackson's separate
`doublest.fth` Double word-set tests we have not vendored), so the
scoreboard stays at 446/638 — but the words now exist for any
consumer that needs them.
- **Phase 5 — mixed/double-cell math; Hayes 342→446 (69%).** Added
`S>D`, `D>S`, `M*`, `UM*`, `UM/MOD`, `FM/MOD`, `SM/REM`, `*/`, `*/MOD`.
Doubles ride on the stack as `(lo, hi)` with `hi` on top.
Helpers `forth-double-push-{u,s}` / `forth-double-from-cells-{u,s}`
split & rebuild via 32-bit unsigned mod/div, picking the negative
path explicitly so we don't form `2^64 + small` (float precision
drops at ULP=2^12 once you cross 2^64). `M*`/`UM*` use bignum
multiply then split; `*/`/`*/MOD` use bignum intermediate and
truncated division. Hayes: 446 pass / 185 error / 7 fail.
- **Phase 5 — memory primitives + unsigned compare; Hayes 268→342 (53%).**
Added `CREATE`/`HERE`/`ALLOT`/`,`/`C,`/`CELL+`/`CELLS`/`ALIGN`/`ALIGNED`/
`2!`/`2@`/`U<`/`U>`. Generalised `@`/`!`/`+!` to dispatch on address
type: string addresses still go through `state.vars` (VARIABLE/VALUE
cells) while integer addresses now fall through to `state.mem`
letting CREATE-allocated cells coexist with existing variables.
Decomposed the original "Full Core + Core Extension" box into
smaller unticked sub-bullets so iterations land per cluster.
Hayes: 342 pass / 292 error / 4 fail (53%). 237/237 internal.
- **Phase 4 close — LSHIFT/RSHIFT, 32-bit arith truncation, early
binding; Hayes 174→268 (42%).** Added `LSHIFT` / `RSHIFT` as logical
shifts on 32-bit unsigned values, converted through
`forth-to-unsigned`/`forth-from-unsigned`. All arithmetic
primitives (`+` `-` `*` `/` `MOD` `NEGATE` `ABS` `1+` `1-` `2+`
`2-` `2*` `2/`) now clip results to 32-bit signed via a new
`forth-clip` helper, so loop idioms that rely on `2*` shifting the
MSB out (e.g. Hayes' `BITS` counter) actually terminate.
Changed colon-def call compilation from late-binding to early
binding: `forth-compile-call` now resolves the target word at
compile time, which makes `: GDX 123 ; : GDX GDX 234 ;` behave
per ANS (inner `GDX` → old def, not infinite recursion). `RECURSE`
keeps its late-binding thunk via the new `forth-compile-recurse`
helper. Raised `MAX_CHUNKS` default to 638 (full `core.fr`) now
that the BITS and COUNT-BITS loops terminate. Hayes: 268 pass /
368 error / 2 fail.
- **Phase 4 — `SP@`/`SP!` (+4; Hayes unchanged; `DEPTH` was already present).**
`SP@` pushes the current data-stack depth (our closest analogue to a
stack pointer — SX lists have no addressable backing). `SP!` pops a
target depth and truncates the stack via `drop` on the dstack list.
This preserves the save/restore idiom `SP@ … SP!` even though the
returned "pointer" is really a count.
- **Phase 4 — `BASE`/`DECIMAL`/`HEX`/`BIN`/`OCTAL` (+9; Hayes unchanged).**
Moved `base` from its top-level state slot into `state.vars["base"]`
so the regular `@`/`!`/VARIABLE machinery works on it.
`BASE` pushes the sentinel address `"base"`; `DECIMAL`/`HEX`/`BIN`/
`OCTAL` are thin primitives that write into that slot. Parser
reads through `vars` now. Hayes unchanged because the runner had
already been stubbing `HEX`/`DECIMAL` — now real words, stubs
removed from `hayes-runner.sx`.
- **Phase 4 — `CHAR`/`[CHAR]`/`KEY`/`ACCEPT` (+7 / Hayes 168→174).**
`CHAR` parses the next token and pushes the first-char code. `[CHAR]`
is IMMEDIATE: in compile mode it embeds the code as a compiled push
op, in interpret mode it pushes inline. `KEY`/`ACCEPT` read from an
optional `state.keybuf` string — empty buffer makes `KEY` raise
`"no input available"` (matches ANS when stdin is closed) and
`ACCEPT` returns `0`. Enough for Hayes to get past CHAR-gated
clusters; real interactive IO lands later.
- **Phase 4 — strings: `S"`/`C"`/`."`/`TYPE`/`COUNT`/`CMOVE`/`CMOVE>`/`MOVE`/`FILL`/`BLANK`/`C@`/`C!`/`CHAR+`/`CHARS` (+16 / Hayes 165→168).**
Added a byte-addressable memory model to state: `mem` (dict keyed by
stringified address → integer byte) and `here` (next-free integer
addr). Helpers `forth-alloc-bytes!` / `forth-mem-write-string!` /
`forth-mem-read-string`. `S"`/`C"`/`."` are IMMEDIATE parsing words
that consume tokens until one ends with `"`, then either copy content
into memory at compile time (and emit a push of `addr`/`addr len` for
the colon-def body) or do it inline in interpret mode. `TYPE` emits
`u` bytes from `addr` via `char-from-code`. `COUNT` reads the length
byte at a counted-string address and pushes (`addr+1`, `u`). `FILL`,
`BLANK` (FILL with space), `CMOVE` (forward), `CMOVE>` (backward),
and `MOVE` (auto-directional) mutate the byte dict. 193/193 internal
tests, Hayes 168/590 (+3).
- **Phase 3 — Hayes conformance runner + baseline scoreboard (165/590, 28%).**
`lib/forth/conformance.sh` preprocesses `ans-tests/core.fr` (strips `\`
and `( ... )` comments + `TESTING` lines), splits the source on every
`}T` so each Hayes test plus the small declaration blocks between
them are one safe-resume chunk, and emits an SX driver that feeds
the chunks through `lib/forth/hayes-runner.sx`. The runner registers
`T{`/`->`/`}T` as Forth primitives that snapshot the dstack depth on
`T{`, record actual on `->`, compare on `}T`, and install stub
`HEX`/`DECIMAL`/`TESTING` so metadata doesn't halt the stream. Errors
raised inside a chunk are caught by `guard` and the state is reset,
so one bad test does not break the rest. Outputs
`scoreboard.json` + `scoreboard.md`.
First-run baseline: 165 pass / 425 error / 0 fail on the first 590
chunks. The default cap sits at 590 because `core.fr` chunks beyond
that rely on unsigned-integer wrap-around (e.g. `COUNT-BITS` with
`BEGIN DUP WHILE … 2* REPEAT`) which never terminates on our
bignum-based Forth; raise `MAX_CHUNKS` once those tests unblock.
Majority of errors are missing Phase-4 words (`RSHIFT`, `LSHIFT`,
`CELLS`, `S"`, `CHAR`, `SOURCE`, etc.) — each one implemented should
convert a cluster of errors to passes.
- **Phase 3 — vendor Gerry Jackson's forth2012-test-suite.** Added
`lib/forth/ans-tests/{tester.fr, core.fr, coreexttest.fth}` from
https://github.com/gerryjackson/forth2012-test-suite (master, fetched
2026-04-24). `tester.fr` is Hayes' `T{ ... -> ... }T` harness; `core.fr`
is the ~1000-line Core word tests; `coreexttest.fth` is Core Ext
(parked for later phases). Files are pristine — the conformance runner
(next iteration) will consume them.
- **Phase 3 — `DO`/`LOOP`/`+LOOP`/`I`/`J`/`LEAVE` + return stack words (+16).**
Counted loops compile onto the same PC-driven body runner. DO emits an
enter-op (pops limit+start from data stack, pushes them to rstack) and
pushes a `{:kind "do" :back PC :leaves ()}` marker onto cstack. LOOP/+LOOP
emit a dict op (`:kind "loop"`/`"+loop"` with target=back-cell). The step
handler pops index & reads limit, increments, and either restores the
updated index + jumps back, or drops the frame and advances. LEAVE walks
cstack for the innermost DO marker, emits a `:kind "leave"` dict op with
a fresh target cell, and registers it on the marker's leaves list. LOOP
patches all registered leave-targets to the exit PC and drops the marker.
The leave op pops two from rstack (unloop) and branches. `I` peeks rtop;
`J` reads rstack index 2 (below inner frame). Added non-immediate
return-stack words `>R`, `R>`, `R@`, `2>R`, `2R>`, `2R@`. Nested
DO/LOOP with J tested; LEAVE in nested loops exits only the inner.
177/177 green.
- **Phase 3 — `BEGIN`/`UNTIL`/`WHILE`/`REPEAT`/`AGAIN` (+9).** Indefinite-loop
constructs built on the same PC-driven body runner introduced for `IF`.
BEGIN records the current body length on `state.cstack` (a plain numeric
back-target). UNTIL/AGAIN pop that back-target and emit a `bif`/`branch`
op whose target cell is set to the recorded PC. WHILE emits a forward
`bif` with a fresh target cell and pushes it on the cstack *above* the
BEGIN marker; REPEAT pops both (while-target first, then back-pc), emits
an unconditional branch back to BEGIN, then patches the while-target to
the current body length — so WHILE's false flag jumps past the REPEAT.
Mixed compile-time layout (numeric back-targets + dict forward targets
on the same cstack) is OK because the immediate words pop them in the
order they expect. AGAIN works structurally but lacks a test without a
usable mid-loop exit; revisit once `EXIT` lands. 161/161 green.
- **Phase 3 start — `IF`/`ELSE`/`THEN` (+18).** `lib/forth/compiler.sx`
+ `tests/test-phase3.sx`. Colon-def body switched from `for-each` to
a PC-driven runner so branch ops can jump: ops now include dict tags
`{"kind" "bif"|"branch" "target" cell}` alongside the existing
`(fn (s) ...)` shape. IF compiles a `bif` with a fresh target cell
pushed to `state.cstack`; ELSE emits an unconditional `branch`,
patches the IF's target to the instruction after this branch, and
pushes the new target; THEN patches the most recent target to the
current body length. Nested IF/ELSE/THEN works via the cstack.
Also fixed `EMIT`: `code-char``char-from-code` (spec-correct
primitive name) so Phase 1/2 tests run green on sx_server.
152/152 (Phase 1 + 2 + 3) green.
- **Phase 2 complete — colon defs, compile mode, VARIABLE/CONSTANT/VALUE/TO, @/!/+! (+26).**
`lib/forth/compiler.sx` plus `tests/test-phase2.sx`.
Colon-def body is a list of ops (one per source token) wrapped in a single

120
plans/smalltalk-on-sx.md
View File

@@ -1,120 +0,0 @@
# Smalltalk-on-SX: blocks with non-local return on delimited continuations
The headline showcase is **blocks** — Smalltalk's closures with non-local return (`^expr` aborts the enclosing *method*, not the block). Every other Smalltalk on top of a host VM (RSqueak on PyPy, GemStone on C, Maxine on Java) reinvents non-local return on whatever stack discipline the host gives them. On SX it's a one-liner: a block holds a captured continuation; `^` just invokes it. Message-passing OO falls out cheaply on top of the existing component / dispatch machinery.
End-state goal: ANSI-ish Smalltalk-80 subset, SUnit working, ~200 hand-written tests + a vendored slice of the Pharo kernel tests, classic corpus (eight queens, quicksort, mandelbrot, Conway's Life).
## Scope decisions (defaults — override by editing before we spawn)
- **Syntax:** Pharo / Squeak chunk format (`!` separators, `Object subclass: #Foo …`). No fileIn/fileOut images — text source only.
- **Conformance:** ANSI X3J20 *as a target*, not bug-for-bug Squeak. "Reads like Smalltalk, runs like Smalltalk."
- **Test corpus:** SUnit ported to SX-Smalltalk + custom programs + a curated slice of Pharo `Kernel-Tests` / `Collections-Tests`.
- **Image:** out of scope. Source-only. No `become:` between sessions, no snapshotting.
- **Reflection:** `class`, `respondsTo:`, `perform:`, `doesNotUnderstand:` in. `become:` (object-identity swap) **in** — it's a good CEK exercise. Method modification at runtime in.
- **GUI / Morphic / threads:** out entirely.
## Ground rules
- **Scope:** only touch `lib/smalltalk/**` and `plans/smalltalk-on-sx.md`. Don't edit `spec/`, `hosts/`, `shared/`, or any other `lib/<lang>/**`. Smalltalk primitives go in `lib/smalltalk/runtime.sx`.
- **SX files:** use `sx-tree` MCP tools only.
- **Commits:** one feature per commit. Keep `## Progress log` updated and tick roadmap boxes.
## Architecture sketch
```
Smalltalk source
lib/smalltalk/tokenizer.sx — selectors, keywords, literals, $c, #sym, #(…), $'…'
lib/smalltalk/parser.sx — AST: classes, methods, blocks, cascades, sends
lib/smalltalk/transpile.sx — AST → SX AST (entry: smalltalk-eval-ast)
lib/smalltalk/runtime.sx — class table, MOP, dispatch, primitives
```
Core mapping:
- **Class** = SX dict `{:name :superclass :ivars :methods :class-methods :metaclass}`. Class table is a flat dict keyed by class name.
- **Object** = SX dict `{:class :ivars}``ivars` keyed by symbol. Tagged ints / floats / strings / symbols are not boxed; their class is looked up by SX type.
- **Method** = SX lambda closing over a `self` binding + temps. Body wrapped in a delimited continuation so `^` can escape.
- **Message send** = `(st-send receiver selector args)` — does class-table lookup, walks superclass chain, falls back to `doesNotUnderstand:` with a `Message` object.
- **Block** `[:x | … ^v … ]` = lambda + captured `^k` (the method-return continuation). Invoking `^` calls `k`; outer block invocation past method return raises `BlockContext>>cannotReturn:`.
- **Cascade** `r m1; m2; m3` = `(let ((tmp r)) (st-send tmp 'm1 ()) (st-send tmp 'm2 ()) (st-send tmp 'm3 ()))`.
- **`ifTrue:ifFalse:` / `whileTrue:`** = ordinary block sends; the runtime intrinsifies them in the JIT path so they compile to native branches (Tier 1 of bytecode expansion already covers this pattern).
- **`become:`** = swap two object identities everywhere — in SX this is a heap walk, but we restrict to `oneWayBecome:` (cheap: rewrite class field) by default.
## Roadmap
### Phase 1 — tokenizer + parser
- [x] Tokenizer: identifiers, keywords (`foo:`), binary selectors (`+`, `==`, `,`, `->`, `~=` etc.), numbers (radix `16r1F`; **scaled `1.5s2` deferred**), strings `'…''…'`, characters `$c`, symbols `#foo` `#'foo bar'` `#+`, byte arrays `#[1 2 3]` (open token), literal arrays `#(1 #foo 'x')` (open token), comments `"…"`
- [x] Parser (expression level): blocks `[:a :b | | t1 t2 | …]`, cascades, message precedence (unary > binary > keyword), assignment, return, statement sequences, literal arrays, byte arrays, paren grouping, method headers (`+ other`, `at:put:`, unary, with temps and body). Class-definition keyword messages parse as ordinary keyword sends — no special-case needed.
- [x] Parser (chunk-stream level): `st-read-chunks` splits source on `!` (with `!!` doubling) and `st-parse-chunks` runs the Pharo file-in state machine — `methodsFor:` / `class methodsFor:` opens a method batch, an empty chunk closes it. Pragmas `<primitive: …>` (incl. multiple keyword pairs, before or after temps, multiple per method) parsed into the method AST.
- [x] Unit tests in `lib/smalltalk/tests/parse.sx`
### Phase 2 — object model + sequential eval
- [x] Class table + bootstrap (`lib/smalltalk/runtime.sx`): canonical hierarchy installed (`Object`, `Behavior`, `ClassDescription`, `Class`, `Metaclass`, `UndefinedObject`, `Boolean`/`True`/`False`, `Magnitude`/`Number`/`Integer`/`SmallInteger`/`Float`/`Character`, `Collection`/`SequenceableCollection`/`ArrayedCollection`/`Array`/`String`/`Symbol`/`OrderedCollection`/`Dictionary`, `BlockClosure`). User class definition via `st-class-define!`, methods via `st-class-add-method!` (stamps `:defining-class` for super), method lookup walks chain, ivars accumulated through superclass chain, native SX value types map to Smalltalk classes via `st-class-of`.
- [ ] `smalltalk-eval-ast`: literals, variable reference, assignment, message send, cascade, sequence, return
- [ ] Method lookup: walk class → superclass; cache hit-class on `(class, selector)`
- [ ] `doesNotUnderstand:` fallback constructing `Message` object
- [ ] `super` send (lookup starts at superclass of *defining* class, not receiver class)
- [ ] 30+ tests in `lib/smalltalk/tests/eval.sx`
### Phase 3 — blocks + non-local return (THE SHOWCASE)
- [ ] Method invocation captures a `^k` (the return continuation) and binds it as the block's escape
- [ ] `^expr` from inside a block invokes that captured `^k`
- [ ] `BlockContext>>value`, `value:`, `value:value:`, …, `valueWithArguments:`
- [ ] `whileTrue:` / `whileTrue` / `whileFalse:` / `whileFalse` as ordinary block sends — runtime intrinsifies the loop in the bytecode JIT
- [ ] `ifTrue:` / `ifFalse:` / `ifTrue:ifFalse:` as block sends, similarly intrinsified
- [ ] Escape past returned-from method raises `BlockContext>>cannotReturn:`
- [ ] Classic programs in `lib/smalltalk/tests/programs/`:
- [ ] `eight-queens.st`
- [ ] `quicksort.st`
- [ ] `mandelbrot.st`
- [ ] `life.st` (Conway's Life, glider gun)
- [ ] `fibonacci.st` (recursive + memoised)
- [ ] `lib/smalltalk/conformance.sh` + runner, `scoreboard.json` + `scoreboard.md`
### Phase 4 — reflection + MOP
- [ ] `Object>>class`, `class>>name`, `class>>superclass`, `class>>methodDict`, `class>>selectors`
- [ ] `Object>>perform:` / `perform:with:` / `perform:withArguments:`
- [ ] `Object>>respondsTo:`, `Object>>isKindOf:`, `Object>>isMemberOf:`
- [ ] `Behavior>>compile:` — runtime method addition
- [ ] `Object>>becomeForward:` (one-way become; rewrites the class field of `aReceiver`)
- [ ] Exceptions: `Exception`, `Error`, `signal`, `signal:`, `on:do:`, `ensure:`, `ifCurtailed:` — built on top of SX `handler-bind`/`raise`
### Phase 5 — collections + numeric tower
- [ ] `SequenceableCollection`/`OrderedCollection`/`Array`/`String`/`Symbol`
- [ ] `HashedCollection`/`Set`/`Dictionary`/`IdentityDictionary`
- [ ] `Stream` hierarchy: `ReadStream`/`WriteStream`/`ReadWriteStream`
- [ ] `Number` tower: `SmallInteger`/`LargePositiveInteger`/`Float`/`Fraction`
- [ ] `String>>format:`, `printOn:` for everything
### Phase 6 — SUnit + corpus to 200+
- [ ] Port SUnit (TestCase, TestSuite, TestResult) — written in SX-Smalltalk, runs in itself
- [ ] Vendor a slice of Pharo `Kernel-Tests` and `Collections-Tests`
- [ ] Drive the scoreboard up: aim for 200+ green tests
- [ ] Stretch: ANSI Smalltalk validator subset
### Phase 7 — speed (optional)
- [ ] Method-dictionary inline caching (already in CEK as a primitive; just wire selector cache)
- [ ] Block intrinsification beyond `whileTrue:` / `ifTrue:`
- [ ] Compare against GNU Smalltalk on the corpus
## Progress log
_Newest first. Agent appends on every commit._
- 2026-04-25: class table + bootstrap (`lib/smalltalk/runtime.sx`, `lib/smalltalk/tests/runtime.sx`). Canonical hierarchy, type→class mapping for native SX values, instance construction, ivar inheritance, method install with `:defining-class` stamp, instance- and class-side method lookup walking the superclass chain. 54 new tests, 185/185 total.
- 2026-04-25: chunk-stream parser + pragmas + 21 chunk/pragma tests (`lib/smalltalk/tests/parse_chunks.sx`). `st-read-chunks` (with `!!` doubling), `st-parse-chunks` state machine for `methodsFor:` batches incl. class-side. Pragmas with multiple keyword pairs, signed numeric / string / symbol args, in either pragma-then-temps or temps-then-pragma order. 131/131 tests pass.
- 2026-04-25: expression-level parser + 47 parse tests (`lib/smalltalk/parser.sx`, `lib/smalltalk/tests/parse.sx`). Full message precedence (unary > binary > keyword), cascades, blocks with params/temps, literal/byte arrays, assignment chain, method headers (unary/binary/keyword). Chunk-format `! !` driver deferred to a follow-up box. 110/110 tests pass.
- 2026-04-25: tokenizer + 63 tests (`lib/smalltalk/tokenizer.sx`, `lib/smalltalk/tests/tokenize.sx`, `lib/smalltalk/test.sh`). All token types covered except scaled decimals `1.5s2` (deferred). `#(` and `#[` emit open tokens; literal-array contents lexed as ordinary tokens for the parser to interpret.
## Blockers
_Shared-file issues that need someone else to fix. Minimal repro only._
- _(none yet)_

4
scripts/sx-loops-down.sh
View File

@@ -30,7 +30,7 @@ fi
if [ "$CLEAN" = "1" ]; then
cd "$(dirname "$0")/.."
for lang in lua prolog forth erlang haskell js hs smalltalk; do
for lang in lua prolog forth erlang haskell js hs; do
wt="$WORKTREE_BASE/$lang"
if [ -d "$wt" ]; then
git worktree remove --force "$wt" 2>/dev/null || rm -rf "$wt"
@@ -39,5 +39,5 @@ if [ "$CLEAN" = "1" ]; then
done
git worktree prune
echo "Worktree branches (loops/<lang>) are preserved. Delete manually if desired:"
echo " git branch -D loops/lua loops/prolog loops/forth loops/erlang loops/haskell loops/js loops/hs loops/smalltalk"
echo " git branch -D loops/lua loops/prolog loops/forth loops/erlang loops/haskell loops/js loops/hs"
fi

13
scripts/sx-loops-up.sh
View File

@@ -1,5 +1,5 @@
#!/usr/bin/env bash
# Spawn 8 claude sessions in tmux, one per language loop.
# Spawn 7 claude sessions in tmux, one per language loop.
# Each runs in its own git worktree rooted at /root/rose-ash-loops/<lang>,
# on branch loops/<lang>. No two loops share a working tree, so there's
# zero risk of file collisions between languages.
@@ -9,7 +9,7 @@
#
# After the script prints done:
# tmux a -t sx-loops
# Ctrl-B + <window-number> to switch (0=lua ... 7=smalltalk)
# Ctrl-B + <window-number> to switch (0=lua ... 6=hs)
# Ctrl-B + d to detach (loops keep running, SSH-safe)
#
# Stop: ./scripts/sx-loops-down.sh
@@ -38,9 +38,8 @@ declare -A BRIEFING=(
[haskell]=haskell-loop.md
[js]=loop.md
[hs]=hs-loop.md
[smalltalk]=smalltalk-loop.md
)
ORDER=(lua prolog forth erlang haskell js hs smalltalk)
ORDER=(lua prolog forth erlang haskell js hs)
mkdir -p "$WORKTREE_BASE"
@@ -67,7 +66,7 @@ for lang in "${ORDER[@]:1}"; do
tmux new-window -t "$SESSION" -n "$lang" -c "$WORKTREE_BASE/$lang"
done
echo "Starting 8 claude sessions..."
echo "Starting 7 claude sessions..."
for lang in "${ORDER[@]}"; do
tmux send-keys -t "$SESSION:$lang" "claude" C-m
done
@@ -90,10 +89,10 @@ for lang in "${ORDER[@]}"; do
done
echo ""
echo "Done. 8 loops started in tmux session '$SESSION', each in its own worktree."
echo "Done. 7 loops started in tmux session '$SESSION', each in its own worktree."
echo ""
echo " Attach: tmux a -t $SESSION"
echo " Switch: Ctrl-B <0..7> (0=lua 1=prolog 2=forth 3=erlang 4=haskell 5=js 6=hs 7=smalltalk)"
echo " Switch: Ctrl-B <0..6> (0=lua 1=prolog 2=forth 3=erlang 4=haskell 5=js 6=hs)"
echo " List: Ctrl-B w"
echo " Detach: Ctrl-B d"
echo " Stop: ./scripts/sx-loops-down.sh"