! Copyright (C) 2006 Chris Double.
! See http://factorcode.org/license.txt for BSD license.
!
-USING: accessors kernel math sequences words arrays io io.files
-math.parser assocs quotations parser lexer
-peg peg.ebnf peg.parsers tools.time io.encodings.binary sequences.deep
-symbols combinators fry namespaces ;
+USING:
+ accessors
+ arrays
+ assocs
+ combinators
+ fry
+ io
+ io.encodings.binary
+ io.files
+ io.pathnames
+ kernel
+ lexer
+ make
+ math
+ math.parser
+ namespaces
+ parser
+ peg
+ peg.ebnf
+ peg.parsers
+ quotations
+ sequences
+ sequences.deep
+ words
+;
IN: cpu.8080.emulator
TUPLE: cpu b c d e f h l a pc sp halted? last-interrupt cycles ram ;
#! an 8-bit value.
3drop ;
-: carry-flag HEX: 01 ; inline
-: parity-flag HEX: 04 ; inline
-: half-carry-flag HEX: 10 ; inline
-: interrupt-flag HEX: 20 ; inline
-: zero-flag HEX: 40 ; inline
-: sign-flag HEX: 80 ; inline
+CONSTANT: carry-flag 0x01
+CONSTANT: parity-flag 0x04
+CONSTANT: half-carry-flag 0x10
+CONSTANT: interrupt-flag 0x20
+CONSTANT: zero-flag 0x40
+CONSTANT: sign-flag 0x80
: >word< ( word -- byte byte )
#! Explode a word into its two 8 bit values.
- dup HEX: FF bitand swap -8 shift HEX: FF bitand swap ;
+ dup 0xFF bitand swap -8 shift 0xFF bitand swap ;
-: cpu-af ( cpu -- word )
+: af>> ( cpu -- word )
#! Return the 16-bit pseudo register AF.
- [ cpu-a 8 shift ] keep cpu-f bitor ;
+ [ a>> 8 shift ] keep f>> bitor ;
-: set-cpu-af ( value cpu -- )
+: af<< ( value cpu -- )
#! Set the value of the 16-bit pseudo register AF
- >r >word< r> tuck set-cpu-f set-cpu-a ;
+ [ >word< ] dip swap >>f swap >>a drop ;
-: cpu-bc ( cpu -- word )
+: bc>> ( cpu -- word )
#! Return the 16-bit pseudo register BC.
- [ cpu-b 8 shift ] keep cpu-c bitor ;
+ [ b>> 8 shift ] keep c>> bitor ;
-: set-cpu-bc ( value cpu -- )
+: bc<< ( value cpu -- )
#! Set the value of the 16-bit pseudo register BC
- >r >word< r> tuck set-cpu-c set-cpu-b ;
+ [ >word< ] dip swap >>c swap >>b drop ;
-: cpu-de ( cpu -- word )
+: de>> ( cpu -- word )
#! Return the 16-bit pseudo register DE.
- [ cpu-d 8 shift ] keep cpu-e bitor ;
+ [ d>> 8 shift ] keep e>> bitor ;
-: set-cpu-de ( value cpu -- )
+: de<< ( value cpu -- )
#! Set the value of the 16-bit pseudo register DE
- >r >word< r> tuck set-cpu-e set-cpu-d ;
+ [ >word< ] dip swap >>e swap >>d drop ;
-: cpu-hl ( cpu -- word )
+: hl>> ( cpu -- word )
#! Return the 16-bit pseudo register HL.
- [ cpu-h 8 shift ] keep cpu-l bitor ;
+ [ h>> 8 shift ] keep l>> bitor ;
-: set-cpu-hl ( value cpu -- )
+: hl<< ( value cpu -- )
#! Set the value of the 16-bit pseudo register HL
- >r >word< r> tuck set-cpu-l set-cpu-h ;
+ [ >word< ] dip swap >>l swap >>h drop ;
: flag-set? ( flag cpu -- bool )
- cpu-f bitand 0 = not ;
+ f>> bitand 0 = not ;
: flag-clear? ( flag cpu -- bool )
- cpu-f bitand 0 = ;
+ f>> bitand 0 = ;
: flag-nz? ( cpu -- bool )
#! Test flag status
- cpu-f zero-flag bitand 0 = ;
+ f>> zero-flag bitand 0 = ;
: flag-z? ( cpu -- bool )
#! Test flag status
- cpu-f zero-flag bitand 0 = not ;
+ f>> zero-flag bitand 0 = not ;
: flag-nc? ( cpu -- bool )
#! Test flag status
- cpu-f carry-flag bitand 0 = ;
+ f>> carry-flag bitand 0 = ;
: flag-c? ( cpu -- bool )
#! Test flag status
- cpu-f carry-flag bitand 0 = not ;
+ f>> carry-flag bitand 0 = not ;
: flag-po? ( cpu -- bool )
#! Test flag status
- cpu-f parity-flag bitand 0 = ;
+ f>> parity-flag bitand 0 = ;
: flag-pe? ( cpu -- bool )
#! Test flag status
- cpu-f parity-flag bitand 0 = not ;
+ f>> parity-flag bitand 0 = not ;
: flag-p? ( cpu -- bool )
#! Test flag status
- cpu-f sign-flag bitand 0 = ;
+ f>> sign-flag bitand 0 = ;
: flag-m? ( cpu -- bool )
#! Test flag status
- cpu-f sign-flag bitand 0 = not ;
+ f>> sign-flag bitand 0 = not ;
: read-byte ( addr cpu -- byte )
#! Read one byte from memory at the specified address.
#! The address is 16-bit, but if a value greater than
#! 0xFFFF is provided then return a default value.
- over HEX: FFFF <= [
- cpu-ram nth
+ over 0xFFFF <= [
+ ram>> nth
] [
- 2drop HEX: FF
+ 2drop 0xFF
] if ;
: read-word ( addr cpu -- word )
#! Read a 16-bit word from memory at the specified address.
#! The address is 16-bit, but if a value greater than
#! 0xFFFF is provided then return a default value.
- [ read-byte ] 2keep >r 1 + r> read-byte 8 shift bitor ;
+ [ read-byte ] 2keep [ 1 + ] dip read-byte 8 shift bitor ;
: next-byte ( cpu -- byte )
#! Return the value of the byte at PC, and increment PC.
- [ cpu-pc ] keep
+ [ pc>> ] keep
[ read-byte ] keep
- [ cpu-pc 1 + ] keep
- set-cpu-pc ;
+ [ pc>> 1 + ] keep
+ pc<< ;
: next-word ( cpu -- word )
#! Return the value of the word at PC, and increment PC.
- [ cpu-pc ] keep
+ [ pc>> ] keep
[ read-word ] keep
- [ cpu-pc 2 + ] keep
- set-cpu-pc ;
+ [ pc>> 2 + ] keep
+ pc<< ;
: write-byte ( value addr cpu -- )
#! Write a byte to the specified memory address.
- over dup HEX: 2000 < swap HEX: FFFF > or [
+ over dup 0x2000 < swap 0xFFFF > or [
3drop
] [
- 3dup cpu-ram set-nth
+ 3dup ram>> set-nth
update-video
] if ;
: write-word ( value addr cpu -- )
#! Write a 16-bit word to the specified memory address.
- >r >r >word< r> r> [ write-byte ] 2keep >r 1 + r> write-byte ;
+ [ >word< ] 2dip [ write-byte ] 2keep [ 1 + ] dip write-byte ;
: cpu-a-bitand ( quot cpu -- )
#! A &= quot call
- [ cpu-a swap call bitand ] keep set-cpu-a ; inline
+ [ a>> swap call bitand ] keep a<< ; inline
: cpu-a-bitor ( quot cpu -- )
#! A |= quot call
- [ cpu-a swap call bitor ] keep set-cpu-a ; inline
+ [ a>> swap call bitor ] keep a<< ; inline
: cpu-a-bitxor ( quot cpu -- )
#! A ^= quot call
- [ cpu-a swap call bitxor ] keep set-cpu-a ; inline
+ [ a>> swap call bitxor ] keep a<< ; inline
: cpu-a-bitxor= ( value cpu -- )
#! cpu-a ^= value
- [ cpu-a bitxor ] keep set-cpu-a ;
+ [ a>> bitxor ] keep a<< ;
: cpu-f-bitand ( quot cpu -- )
#! F &= quot call
- [ cpu-f swap call bitand ] keep set-cpu-f ; inline
+ [ f>> swap call bitand ] keep f<< ; inline
: cpu-f-bitor ( quot cpu -- )
#! F |= quot call
- [ cpu-f swap call bitor ] keep set-cpu-f ; inline
+ [ f>> swap call bitor ] keep f<< ; inline
: cpu-f-bitxor ( quot cpu -- )
#! F |= quot call
- [ cpu-f swap call bitxor ] keep set-cpu-f ; inline
+ [ f>> swap call bitxor ] keep f<< ; inline
: cpu-f-bitor= ( value cpu -- )
#! cpu-f |= value
- [ cpu-f bitor ] keep set-cpu-f ;
+ [ f>> bitor ] keep f<< ;
: cpu-f-bitand= ( value cpu -- )
#! cpu-f &= value
- [ cpu-f bitand ] keep set-cpu-f ;
+ [ f>> bitand ] keep f<< ;
: cpu-f-bitxor= ( value cpu -- )
#! cpu-f ^= value
- [ cpu-f bitxor ] keep set-cpu-f ;
+ [ f>> bitxor ] keep f<< ;
: set-flag ( cpu flag -- )
swap cpu-f-bitor= ;
: clear-flag ( cpu flag -- )
- bitnot HEX: FF bitand swap cpu-f-bitand= ;
+ bitnot 0xFF bitand swap cpu-f-bitand= ;
: update-zero-flag ( result cpu -- )
#! If the result of an instruction has the value 0, this
#! flag is set, otherwise it is reset.
- swap HEX: FF bitand 0 = [ zero-flag set-flag ] [ zero-flag clear-flag ] if ;
+ swap 0xFF bitand 0 = [ zero-flag set-flag ] [ zero-flag clear-flag ] if ;
: update-sign-flag ( result cpu -- )
#! If the most significant bit of the result
#! has the value 1 then the flag is set, otherwise
#! it is reset.
- swap HEX: 80 bitand 0 = [ sign-flag clear-flag ] [ sign-flag set-flag ] if ;
+ swap 0x80 bitand 0 = [ sign-flag clear-flag ] [ sign-flag set-flag ] if ;
: update-parity-flag ( result cpu -- )
#! If the modulo 2 sum of the bits of the result
#! is 0, (ie. if the result has even parity) this flag
#! is set, otherwise it is reset.
- swap HEX: FF bitand 2 mod 0 = [ parity-flag set-flag ] [ parity-flag clear-flag ] if ;
+ swap 0xFF bitand 2 mod 0 = [ parity-flag set-flag ] [ parity-flag clear-flag ] if ;
: update-carry-flag ( result cpu -- )
#! If the instruction resulted in a carry (from addition)
#! or a borrow (from subtraction or a comparison) out of the
#! higher order bit, this flag is set, otherwise it is reset.
- swap dup HEX: 100 >= swap 0 < or [ carry-flag set-flag ] [ carry-flag clear-flag ] if ;
+ swap dup 0x100 >= swap 0 < or [ carry-flag set-flag ] [ carry-flag clear-flag ] if ;
: update-half-carry-flag ( original change-by result cpu -- )
#! If the instruction caused a carry out of bit 3 and into bit 4 of the
#! The 'original' is the original value of the register being changed.
#! 'change-by' is the amount it is being added or decremented by.
#! 'result' is the result of that change.
- >r bitxor bitxor HEX: 10 bitand 0 = not r>
+ [ bitxor bitxor 0x10 bitand 0 = not ] dip
swap [ half-carry-flag set-flag ] [ half-carry-flag clear-flag ] if ;
: update-flags ( result cpu -- )
: add-byte ( lhs rhs cpu -- result )
#! Add rhs to lhs
- >r 2dup + r> ! lhs rhs result cpu
+ [ 2dup + ] dip
[ update-flags ] 2keep
[ update-half-carry-flag ] 2keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: add-carry ( change-by result cpu -- change-by result )
#! Add the effect of the carry flag to the result
- flag-c? [ 1 + >r 1 + r> ] when ;
+ flag-c? [ 1 + [ 1 + ] dip ] when ;
: add-byte-with-carry ( lhs rhs cpu -- result )
#! Add rhs to lhs plus carry.
- >r 2dup + r> ! lhs rhs result cpu
+ [ 2dup + ] dip
[ add-carry ] keep
[ update-flags ] 2keep
[ update-half-carry-flag ] 2keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: sub-carry ( change-by result cpu -- change-by result )
#! Subtract the effect of the carry flag from the result
- flag-c? [ 1 - >r 1 - r> ] when ;
+ flag-c? [ 1 - [ 1 - ] dip ] when ;
: sub-byte ( lhs rhs cpu -- result )
#! Subtract rhs from lhs
- >r 2dup - r>
+ [ 2dup - ] dip
[ update-flags ] 2keep
[ update-half-carry-flag ] 2keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: sub-byte-with-carry ( lhs rhs cpu -- result )
#! Subtract rhs from lhs and take carry into account
- >r 2dup - r>
+ [ 2dup - ] dip
[ sub-carry ] keep
[ update-flags ] 2keep
[ update-half-carry-flag ] 2keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: inc-byte ( byte cpu -- result )
#! Increment byte by one. Note that carry flag is not affected
#! by this operation.
- >r 1 2dup + r> ! lhs rhs result cpu
+ [ 1 2dup + ] dip
[ update-flags-no-carry ] 2keep
[ update-half-carry-flag ] 2keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: dec-byte ( byte cpu -- result )
#! Decrement byte by one. Note that carry flag is not affected
#! by this operation.
- >r 1 2dup - r> ! lhs rhs result cpu
+ [ 1 2dup - ] dip
[ update-flags-no-carry ] 2keep
[ update-half-carry-flag ] 2keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: inc-word ( w cpu -- w )
#! Increment word by one. Note that no flags are modified.
- drop 1 + HEX: FFFF bitand ;
+ drop 1 + 0xFFFF bitand ;
: dec-word ( w cpu -- w )
#! Decrement word by one. Note that no flags are modified.
- drop 1 - HEX: FFFF bitand ;
+ drop 1 - 0xFFFF bitand ;
: add-word ( lhs rhs cpu -- result )
#! Add rhs to lhs. Note that only the carry flag is modified
#! and only if there is a carry out of the double precision add.
- >r + r> over HEX: FFFF > [ carry-flag set-flag ] [ drop ] if HEX: FFFF bitand ;
+ [ + ] dip over 0xFFFF > [ carry-flag set-flag ] [ drop ] if 0xFFFF bitand ;
: bit3or ( lhs rhs -- 0|1 )
#! bitor bit 3 of the two numbers on the stack
- BIN: 00001000 bitand -3 shift >r
- BIN: 00001000 bitand -3 shift r>
+ 0b00001000 bitand -3 shift [
+ 0b00001000 bitand -3 shift
+ ] dip
bitor ;
: and-byte ( lhs rhs cpu -- result )
#! Logically and rhs to lhs. The carry flag is cleared and
#! the half carry is set to the ORing of bits 3 of the operands.
[ drop bit3or ] 3keep ! bit3or lhs rhs cpu
- >r bitand r> [ update-flags ] 2keep
+ [ bitand ] dip [ update-flags ] 2keep
[ carry-flag clear-flag ] keep
rot 0 = [ half-carry-flag set-flag ] [ half-carry-flag clear-flag ] if
- HEX: FF bitand ;
+ 0xFF bitand ;
: xor-byte ( lhs rhs cpu -- result )
#! Logically xor rhs to lhs. The carry and half-carry flags are cleared.
- >r bitxor r> [ update-flags ] 2keep
+ [ bitxor ] dip [ update-flags ] 2keep
[ half-carry-flag carry-flag bitor clear-flag ] keep
- drop HEX: FF bitand ;
+ drop 0xFF bitand ;
: or-byte ( lhs rhs cpu -- result )
#! Logically or rhs to lhs. The carry and half-carry flags are cleared.
- >r bitor r> [ update-flags ] 2keep
+ [ bitor ] dip [ update-flags ] 2keep
[ half-carry-flag carry-flag bitor clear-flag ] keep
- drop HEX: FF bitand ;
-
-: flags ( seq -- seq )
- [ 0 [ execute bitor ] reduce ] map ;
+ drop 0xFF bitand ;
: decrement-sp ( n cpu -- )
#! Decrement the stackpointer by n.
- [ cpu-sp ] keep
- >r swap - r> set-cpu-sp ;
+ [ sp>> ] keep
+ [ swap - ] dip sp<< ;
: save-pc ( cpu -- )
#! Save the value of the PC on the stack.
- [ cpu-pc ] keep ! pc cpu
- [ cpu-sp ] keep ! pc sp cpu
+ [ pc>> ] keep ! pc cpu
+ [ sp>> ] keep ! pc sp cpu
write-word ;
: push-pc ( cpu -- )
: pop-pc ( cpu -- pc )
#! Pop the value of the PC off the stack.
- [ cpu-sp ] keep
+ [ sp>> ] keep
[ read-word ] keep
-2 swap decrement-sp ;
: push-sp ( value cpu -- )
[ 2 swap decrement-sp ] keep
- [ cpu-sp ] keep
+ [ sp>> ] keep
write-word ;
: pop-sp ( cpu -- value )
- [ cpu-sp ] keep
+ [ sp>> ] keep
[ read-word ] keep
-2 swap decrement-sp ;
: call-sub ( addr cpu -- )
#! Call the address as a subroutine.
dup push-pc
- >r HEX: FFFF bitand r> set-cpu-pc ;
+ [ 0xFFFF bitand ] dip pc<< ;
: ret-from-sub ( cpu -- )
- [ pop-pc ] keep set-cpu-pc ;
+ [ pop-pc ] keep pc<< ;
: interrupt ( number cpu -- )
#! Perform a hardware interrupt
-! "***Interrupt: " write over 16 >base print
- dup cpu-f interrupt-flag bitand 0 = not [
+! "***Interrupt: " write over >hex print
+ dup f>> interrupt-flag bitand 0 = not [
dup push-pc
- set-cpu-pc
+ pc<<
] [
2drop
] if ;
: inc-cycles ( n cpu -- )
#! Increment the number of cpu cycles
- [ cpu-cycles + ] keep set-cpu-cycles ;
+ [ cycles>> + ] keep cycles<< ;
: instruction-cycles ( -- vector )
#! Return a 256 element vector containing the cycles for
#! each opcode in the 8080 instruction set.
- << 256 f <array> parsed >> ;
+ \ instruction-cycles get-global [
+ 256 f <array> \ instruction-cycles set-global
+ ] unless
+ \ instruction-cycles get-global ;
: not-implemented ( <cpu> -- )
drop ;
: instructions ( -- vector )
#! Return a 256 element vector containing the emulation words for
#! each opcode in the 8080 instruction set.
- << 256 [ [ not-implemented ] 2array ] map parsed >> ; inline
+ \ instructions get-global [
+ 256 [ not-implemented ] <array> \ instructions set-global
+ ] unless
+ \ instructions get-global ;
: set-instruction ( quot n -- )
- tuck >r 2array r> instructions set-nth ;
+ instructions set-nth ;
M: cpu reset ( cpu -- )
#! Reset the CPU to its poweron state
- [ 0 swap set-cpu-b ] keep
- [ 0 swap set-cpu-c ] keep
- [ 0 swap set-cpu-d ] keep
- [ 0 swap set-cpu-e ] keep
- [ 0 swap set-cpu-h ] keep
- [ 0 swap set-cpu-l ] keep
- [ 0 swap set-cpu-a ] keep
- [ 0 swap set-cpu-f ] keep
- [ 0 swap set-cpu-pc ] keep
- [ HEX: F000 swap set-cpu-sp ] keep
- [ HEX: FFFF 0 <array> swap set-cpu-ram ] keep
- [ f swap set-cpu-halted? ] keep
- [ HEX: 10 swap set-cpu-last-interrupt ] keep
- 0 swap set-cpu-cycles ;
+ 0 >>b
+ 0 >>c
+ 0 >>d
+ 0 >>e
+ 0 >>h
+ 0 >>l
+ 0 >>a
+ 0 >>f
+ 0 >>pc
+ 0xF000 >>sp
+ 0xFFFF 0 <array> >>ram
+ f >>halted?
+ 0x10 >>last-interrupt
+ 0 >>cycles
+ drop ;
: <cpu> ( -- cpu ) cpu new dup reset ;
: (load-rom) ( n ram -- )
read1 [ ! n ram ch
- -rot [ set-nth ] 2keep >r 1 + r> (load-rom)
+ -rot [ set-nth ] 2keep [ 1 + ] dip (load-rom)
] [
2drop
] if* ;
: load-rom ( filename cpu -- )
#! Load the contents of the file into ROM.
#! (address 0x0000-0x1FFF).
- cpu-ram swap binary [
+ ram>> swap binary [
0 swap (load-rom)
] with-file-reader ;
#! file will be loaded at the specified address. This
#! file path shoul dbe relative to the '/roms' resource path.
rom-dir [
- cpu-ram [
+ ram>> [
swap first2 rom-dir prepend-path binary [
swap (load-rom)
] with-file-reader
: read-instruction ( cpu -- word )
#! Read the next instruction from the cpu's program
#! counter, and increment the program counter.
- [ cpu-pc ] keep ! pc cpu
- [ over 1 + swap set-cpu-pc ] keep
+ [ pc>> ] keep ! pc cpu
+ [ over 1 + swap pc<< ] keep
read-byte ;
: get-cycles ( n -- opcode )
: process-interrupts ( cpu -- )
#! Process any hardware interrupts
- [ cpu-cycles ] keep
+ [ cycles>> ] keep
over 16667 < [
2drop
] [
- [ >r 16667 - r> set-cpu-cycles ] keep
- dup cpu-last-interrupt HEX: 10 = [
- HEX: 08 over set-cpu-last-interrupt HEX: 08 swap interrupt
+ [ [ 16667 - ] dip cycles<< ] keep
+ dup last-interrupt>> 0x10 = [
+ 0x08 over last-interrupt<< 0x08 swap interrupt
] [
- HEX: 10 over set-cpu-last-interrupt HEX: 10 swap interrupt
+ 0x10 over last-interrupt<< 0x10 swap interrupt
] if
] if ;
: peek-instruction ( cpu -- word )
#! Return the next instruction from the cpu's program
#! counter, but don't increment the counter.
- [ cpu-pc ] keep read-byte instructions nth first ;
+ [ pc>> ] keep read-byte instructions nth first ;
: cpu. ( cpu -- )
- [ " PC: " write cpu-pc 16 >base 4 CHAR: \s pad-left write ] keep
- [ " B: " write cpu-b 16 >base 2 CHAR: \s pad-left write ] keep
- [ " C: " write cpu-c 16 >base 2 CHAR: \s pad-left write ] keep
- [ " D: " write cpu-d 16 >base 2 CHAR: \s pad-left write ] keep
- [ " E: " write cpu-e 16 >base 2 CHAR: \s pad-left write ] keep
- [ " F: " write cpu-f 16 >base 2 CHAR: \s pad-left write ] keep
- [ " H: " write cpu-h 16 >base 2 CHAR: \s pad-left write ] keep
- [ " L: " write cpu-l 16 >base 2 CHAR: \s pad-left write ] keep
- [ " A: " write cpu-a 16 >base 2 CHAR: \s pad-left write ] keep
- [ " SP: " write cpu-sp 16 >base 4 CHAR: \s pad-left write ] keep
- [ " cycles: " write cpu-cycles number>string 5 CHAR: \s pad-left write ] keep
+ [ " PC: " write pc>> >hex 4 CHAR: \s pad-head write ] keep
+ [ " B: " write b>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " C: " write c>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " D: " write d>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " E: " write e>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " F: " write f>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " H: " write h>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " L: " write l>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " A: " write a>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " SP: " write sp>> >hex 4 CHAR: \s pad-head write ] keep
+ [ " cycles: " write cycles>> number>string 5 CHAR: \s pad-head write ] keep
[ " " write peek-instruction name>> write " " write ] keep
nl drop ;
: cpu*. ( cpu -- )
- [ " PC: " write cpu-pc 16 >base 4 CHAR: \s pad-left write ] keep
- [ " B: " write cpu-b 16 >base 2 CHAR: \s pad-left write ] keep
- [ " C: " write cpu-c 16 >base 2 CHAR: \s pad-left write ] keep
- [ " D: " write cpu-d 16 >base 2 CHAR: \s pad-left write ] keep
- [ " E: " write cpu-e 16 >base 2 CHAR: \s pad-left write ] keep
- [ " F: " write cpu-f 16 >base 2 CHAR: \s pad-left write ] keep
- [ " H: " write cpu-h 16 >base 2 CHAR: \s pad-left write ] keep
- [ " L: " write cpu-l 16 >base 2 CHAR: \s pad-left write ] keep
- [ " A: " write cpu-a 16 >base 2 CHAR: \s pad-left write ] keep
- [ " SP: " write cpu-sp 16 >base 4 CHAR: \s pad-left write ] keep
- [ " cycles: " write cpu-cycles number>string 5 CHAR: \s pad-left write ] keep
+ [ " PC: " write pc>> >hex 4 CHAR: \s pad-head write ] keep
+ [ " B: " write b>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " C: " write c>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " D: " write d>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " E: " write e>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " F: " write f>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " H: " write h>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " L: " write l>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " A: " write a>> >hex 2 CHAR: \s pad-head write ] keep
+ [ " SP: " write sp>> >hex 4 CHAR: \s pad-head write ] keep
+ [ " cycles: " write cycles>> number>string 5 CHAR: \s pad-head write ] keep
nl drop ;
: register-lookup ( string -- vector )
#! where the 1st item is the getter and the 2nd is the setter
#! for that register.
H{
- { "A" { cpu-a set-cpu-a } }
- { "B" { cpu-b set-cpu-b } }
- { "C" { cpu-c set-cpu-c } }
- { "D" { cpu-d set-cpu-d } }
- { "E" { cpu-e set-cpu-e } }
- { "H" { cpu-h set-cpu-h } }
- { "L" { cpu-l set-cpu-l } }
- { "AF" { cpu-af set-cpu-af } }
- { "BC" { cpu-bc set-cpu-bc } }
- { "DE" { cpu-de set-cpu-de } }
- { "HL" { cpu-hl set-cpu-hl } }
- { "SP" { cpu-sp set-cpu-sp } }
+ { "A" { a>> a<< } }
+ { "B" { b>> b<< } }
+ { "C" { c>> c<< } }
+ { "D" { d>> d<< } }
+ { "E" { e>> e<< } }
+ { "H" { h>> h<< } }
+ { "L" { l>> l<< } }
+ { "AF" { af>> af<< } }
+ { "BC" { bc>> bc<< } }
+ { "DE" { de>> de<< } }
+ { "HL" { hl>> hl<< } }
+ { "SP" { sp>> sp<< } }
} at ;
#! Given a string containing a flag name, return a vector
#! where the 1st item is a word that tests that flag.
H{
- { "NZ" { flag-nz? } }
- { "NC" { flag-nc? } }
- { "PO" { flag-po? } }
- { "PE" { flag-pe? } }
+ { "NZ" { flag-nz? } }
+ { "NC" { flag-nc? } }
+ { "PO" { flag-po? } }
+ { "PE" { flag-pe? } }
{ "Z" { flag-z? } }
{ "C" { flag-c? } }
{ "P" { flag-p? } }
- { "M" { flag-m? } }
+ { "M" { flag-m? } }
} at ;
SYMBOLS: $1 $2 $3 $4 ;
: (emulate-RST) ( n cpu -- )
#! RST nn
- [ cpu-sp 2 - dup ] keep ! sp sp cpu
- [ set-cpu-sp ] keep ! sp cpu
- [ cpu-pc ] keep ! sp pc cpu
+ [ sp>> 2 - dup ] keep ! sp sp cpu
+ [ sp<< ] keep ! sp cpu
+ [ pc>> ] keep ! sp pc cpu
swapd [ write-word ] keep ! cpu
- >r 8 * r> set-cpu-pc ;
+ [ 8 * ] dip pc<< ;
: (emulate-CALL) ( cpu -- )
#! 205 - CALL nn
- [ next-word HEX: FFFF bitand ] keep ! addr cpu
- [ cpu-sp 2 - dup ] keep ! addr sp sp cpu
- [ set-cpu-sp ] keep ! addr sp cpu
- [ cpu-pc ] keep ! addr sp pc cpu
+ [ next-word 0xFFFF bitand ] keep ! addr cpu
+ [ sp>> 2 - dup ] keep ! addr sp sp cpu
+ [ sp<< ] keep ! addr sp cpu
+ [ pc>> ] keep ! addr sp pc cpu
swapd [ write-word ] keep ! addr cpu
- set-cpu-pc ;
+ pc<< ;
: (emulate-RLCA) ( cpu -- )
#! The content of the accumulator is rotated left
#! one position. The low order bit and the carry flag
#! are both set to the value shifd out of the high
#! order bit position. Only the carry flag is affected.
- [ cpu-a -7 shift ] keep
+ [ a>> -7 shift ] keep
over 0 = [ dup carry-flag clear-flag ] [ dup carry-flag set-flag ] if
- [ cpu-a 1 shift HEX: FF bitand ] keep
- >r bitor r> set-cpu-a ;
+ [ a>> 1 shift 0xFF bitand ] keep
+ [ bitor ] dip a<< ;
: (emulate-RRCA) ( cpu -- )
#! The content of the accumulator is rotated right
#! one position. The high order bit and the carry flag
#! are both set to the value shifd out of the low
#! order bit position. Only the carry flag is affected.
- [ cpu-a 1 bitand 7 shift ] keep
+ [ a>> 1 bitand 7 shift ] keep
over 0 = [ dup carry-flag clear-flag ] [ dup carry-flag set-flag ] if
- [ cpu-a 254 bitand -1 shift ] keep
- >r bitor r> set-cpu-a ;
+ [ a>> 254 bitand -1 shift ] keep
+ [ bitor ] dip a<< ;
: (emulate-RLA) ( cpu -- )
#! The content of the accumulator is rotated left
#! of the high order bit. Only the carry flag is
#! affected.
[ carry-flag swap flag-set? [ 1 ] [ 0 ] if ] keep
- [ cpu-a 127 bitand 7 shift ] keep
- dup cpu-a 128 bitand 0 = [ dup carry-flag clear-flag ] [ dup carry-flag set-flag ] if
- >r bitor r> set-cpu-a ;
+ [ a>> 127 bitand 7 shift ] keep
+ dup a>> 128 bitand 0 = [ dup carry-flag clear-flag ] [ dup carry-flag set-flag ] if
+ [ bitor ] dip a<< ;
: (emulate-RRA) ( cpu -- )
#! The content of the accumulator is rotated right
#! bit is set to the carry flag and the carry flag is
#! set to the value shifd out of the low order bit.
#! Only the carry flag is affected.
- [ carry-flag swap flag-set? [ BIN: 10000000 ] [ 0 ] if ] keep
- [ cpu-a 254 bitand -1 shift ] keep
- dup cpu-a 1 bitand 0 = [ dup carry-flag clear-flag ] [ dup carry-flag set-flag ] if
- >r bitor r> set-cpu-a ;
+ [ carry-flag swap flag-set? [ 0b10000000 ] [ 0 ] if ] keep
+ [ a>> 254 bitand -1 shift ] keep
+ dup a>> 1 bitand 0 = [ dup carry-flag clear-flag ] [ dup carry-flag set-flag ] if
+ [ bitor ] dip a<< ;
: (emulate-CPL) ( cpu -- )
#! The contents of the accumulator are complemented
#! (zero bits become one, one bits becomes zero).
#! No flags are affected.
- HEX: FF swap cpu-a-bitxor= ;
+ 0xFF swap cpu-a-bitxor= ;
: (emulate-DAA) ( cpu -- )
#! The eight bit number in the accumulator is
#! digits.
[
dup half-carry-flag swap flag-set? swap
- cpu-a BIN: 1111 bitand 9 > or [ 6 ] [ 0 ] if
+ a>> 0b1111 bitand 9 > or [ 6 ] [ 0 ] if
] keep
- [ cpu-a + ] keep
+ [ a>> + ] keep
[ update-flags ] 2keep
- [ swap HEX: FF bitand swap set-cpu-a ] keep
+ [ swap 0xFF bitand swap a<< ] keep
[
dup carry-flag swap flag-set? swap
- cpu-a -4 shift BIN: 1111 bitand 9 > or [ 96 ] [ 0 ] if
+ a>> -4 shift 0b1111 bitand 9 > or [ 96 ] [ 0 ] if
] keep
- [ cpu-a + ] keep
+ [ a>> + ] keep
[ update-flags ] 2keep
- swap HEX: FF bitand swap set-cpu-a ;
+ swap 0xFF bitand swap a<< ;
: patterns ( -- hashtable )
#! table of code quotation patterns for each type of instruction.
H{
- { "NOP" [ drop ] }
- { "RET-NN" [ ret-from-sub ] }
- { "RST-0" [ 0 swap (emulate-RST) ] }
- { "RST-8" [ 8 swap (emulate-RST) ] }
- { "RST-10H" [ HEX: 10 swap (emulate-RST) ] }
- { "RST-18H" [ HEX: 18 swap (emulate-RST) ] }
- { "RST-20H" [ HEX: 20 swap (emulate-RST) ] }
- { "RST-28H" [ HEX: 28 swap (emulate-RST) ] }
- { "RST-30H" [ HEX: 30 swap (emulate-RST) ] }
- { "RST-38H" [ HEX: 38 swap (emulate-RST) ] }
- { "RET-F|FF" [ dup $1 [ 6 over inc-cycles ret-from-sub ] [ drop ] if ] }
- { "CP-N" [ [ cpu-a ] keep [ next-byte ] keep sub-byte drop ] }
- { "CP-R" [ [ cpu-a ] keep [ $1 ] keep sub-byte drop ] }
- { "CP-(RR)" [ [ cpu-a ] keep [ $1 ] keep [ read-byte ] keep sub-byte drop ] }
- { "OR-N" [ [ cpu-a ] keep [ next-byte ] keep [ or-byte ] keep set-cpu-a ] }
- { "OR-R" [ [ cpu-a ] keep [ $1 ] keep [ or-byte ] keep set-cpu-a ] }
- { "OR-(RR)" [ [ cpu-a ] keep [ $1 ] keep [ read-byte ] keep [ or-byte ] keep set-cpu-a ] }
- { "XOR-N" [ [ cpu-a ] keep [ next-byte ] keep [ xor-byte ] keep set-cpu-a ] }
- { "XOR-R" [ [ cpu-a ] keep [ $1 ] keep [ xor-byte ] keep set-cpu-a ] }
- { "XOR-(RR)" [ [ cpu-a ] keep [ $1 ] keep [ read-byte ] keep [ xor-byte ] keep set-cpu-a ] }
- { "AND-N" [ [ cpu-a ] keep [ next-byte ] keep [ and-byte ] keep set-cpu-a ] }
- { "AND-R" [ [ cpu-a ] keep [ $1 ] keep [ and-byte ] keep set-cpu-a ] }
- { "AND-(RR)" [ [ cpu-a ] keep [ $1 ] keep [ read-byte ] keep [ and-byte ] keep set-cpu-a ] }
- { "ADC-R,N" [ [ $1 ] keep [ next-byte ] keep [ add-byte-with-carry ] keep $2 ] }
- { "ADC-R,R" [ [ $1 ] keep [ $3 ] keep [ add-byte-with-carry ] keep $2 ] }
- { "ADC-R,(RR)" [ [ $1 ] keep [ $3 ] keep [ read-byte ] keep [ add-byte-with-carry ] keep $2 ] }
- { "ADD-R,N" [ [ $1 ] keep [ next-byte ] keep [ add-byte ] keep $2 ] }
- { "ADD-R,R" [ [ $1 ] keep [ $3 ] keep [ add-byte ] keep $2 ] }
- { "ADD-RR,RR" [ [ $1 ] keep [ $3 ] keep [ add-word ] keep $2 ] }
- { "ADD-R,(RR)" [ [ $1 ] keep [ $3 ] keep [ read-byte ] keep [ add-byte ] keep $2 ] }
- { "SBC-R,N" [ [ $1 ] keep [ next-byte ] keep [ sub-byte-with-carry ] keep $2 ] }
- { "SBC-R,R" [ [ $1 ] keep [ $3 ] keep [ sub-byte-with-carry ] keep $2 ] }
- { "SBC-R,(RR)" [ [ $1 ] keep [ $3 ] keep [ read-byte ] keep [ sub-byte-with-carry ] keep $2 ] }
- { "SUB-R" [ [ cpu-a ] keep [ $1 ] keep [ sub-byte ] keep set-cpu-a ] }
- { "SUB-(RR)" [ [ cpu-a ] keep [ $1 ] keep [ read-byte ] keep [ sub-byte ] keep set-cpu-a ] }
- { "SUB-N" [ [ cpu-a ] keep [ next-byte ] keep [ sub-byte ] keep set-cpu-a ] }
- { "CPL" [ (emulate-CPL) ] }
- { "DAA" [ (emulate-DAA) ] }
- { "RLA" [ (emulate-RLA) ] }
- { "RRA" [ (emulate-RRA) ] }
- { "CCF" [ carry-flag swap cpu-f-bitxor= ] }
- { "SCF" [ carry-flag swap cpu-f-bitor= ] }
- { "RLCA" [ (emulate-RLCA) ] }
- { "RRCA" [ (emulate-RRCA) ] }
- { "HALT" [ drop ] }
- { "DI" [ [ 255 interrupt-flag - ] swap cpu-f-bitand ] }
- { "EI" [ [ interrupt-flag ] swap cpu-f-bitor ] }
- { "POP-RR" [ [ pop-sp ] keep $2 ] }
- { "PUSH-RR" [ [ $1 ] keep push-sp ] }
- { "INC-R" [ [ $1 ] keep [ inc-byte ] keep $2 ] }
- { "DEC-R" [ [ $1 ] keep [ dec-byte ] keep $2 ] }
- { "INC-RR" [ [ $1 ] keep [ inc-word ] keep $2 ] }
- { "DEC-RR" [ [ $1 ] keep [ dec-word ] keep $2 ] }
- { "DEC-(RR)" [ [ $1 ] keep [ read-byte ] keep [ dec-byte ] keep [ $1 ] keep write-byte ] }
- { "INC-(RR)" [ [ $1 ] keep [ read-byte ] keep [ inc-byte ] keep [ $1 ] keep write-byte ] }
- { "JP-NN" [ [ cpu-pc ] keep [ read-word ] keep set-cpu-pc ] }
- { "JP-F|FF,NN" [ [ $1 ] keep swap [ [ next-word ] keep [ set-cpu-pc ] keep [ cpu-cycles ] keep swap 5 + swap set-cpu-cycles ] [ [ cpu-pc 2 + ] keep set-cpu-pc ] if ] }
- { "JP-(RR)" [ [ $1 ] keep set-cpu-pc ] }
- { "CALL-NN" [ (emulate-CALL) ] }
- { "CALL-F|FF,NN" [ [ $1 ] keep swap [ 7 over inc-cycles (emulate-CALL) ] [ [ cpu-pc 2 + ] keep set-cpu-pc ] if ] }
- { "LD-RR,NN" [ [ next-word ] keep $2 ] }
- { "LD-RR,RR" [ [ $3 ] keep $2 ] }
- { "LD-R,N" [ [ next-byte ] keep $2 ] }
- { "LD-(RR),N" [ [ next-byte ] keep [ $1 ] keep write-byte ] }
- { "LD-(RR),R" [ [ $3 ] keep [ $1 ] keep write-byte ] }
- { "LD-R,R" [ [ $3 ] keep $2 ] }
- { "LD-R,(RR)" [ [ $3 ] keep [ read-byte ] keep $2 ] }
- { "LD-(NN),RR" [ [ $1 ] keep [ next-word ] keep write-word ] }
- { "LD-(NN),R" [ [ $1 ] keep [ next-word ] keep write-byte ] }
- { "LD-RR,(NN)" [ [ next-word ] keep [ read-word ] keep $2 ] }
- { "LD-R,(NN)" [ [ next-word ] keep [ read-byte ] keep $2 ] }
- { "OUT-(N),R" [ [ $1 ] keep [ next-byte ] keep write-port ] }
- { "IN-R,(N)" [ [ next-byte ] keep [ read-port ] keep set-cpu-a ] }
- { "EX-(RR),RR" [ [ $1 ] keep [ read-word ] keep [ $3 ] keep [ $1 ] keep [ write-word ] keep $4 ] }
- { "EX-RR,RR" [ [ $1 ] keep [ $3 ] keep [ $2 ] keep $4 ] }
+ { "NOP" [ drop ] }
+ { "RET-NN" [ ret-from-sub ] }
+ { "RST-0" [ 0 swap (emulate-RST) ] }
+ { "RST-8" [ 8 swap (emulate-RST) ] }
+ { "RST-10H" [ 0x10 swap (emulate-RST) ] }
+ { "RST-18H" [ 0x18 swap (emulate-RST) ] }
+ { "RST-20H" [ 0x20 swap (emulate-RST) ] }
+ { "RST-28H" [ 0x28 swap (emulate-RST) ] }
+ { "RST-30H" [ 0x30 swap (emulate-RST) ] }
+ { "RST-38H" [ 0x38 swap (emulate-RST) ] }
+ { "RET-F|FF" [ dup $1 [ 6 over inc-cycles ret-from-sub ] [ drop ] if ] }
+ { "CP-N" [ [ a>> ] keep [ next-byte ] keep sub-byte drop ] }
+ { "CP-R" [ [ a>> ] keep [ $1 ] keep sub-byte drop ] }
+ { "CP-(RR)" [ [ a>> ] keep [ $1 ] keep [ read-byte ] keep sub-byte drop ] }
+ { "OR-N" [ [ a>> ] keep [ next-byte ] keep [ or-byte ] keep a<< ] }
+ { "OR-R" [ [ a>> ] keep [ $1 ] keep [ or-byte ] keep a<< ] }
+ { "OR-(RR)" [ [ a>> ] keep [ $1 ] keep [ read-byte ] keep [ or-byte ] keep a<< ] }
+ { "XOR-N" [ [ a>> ] keep [ next-byte ] keep [ xor-byte ] keep a<< ] }
+ { "XOR-R" [ [ a>> ] keep [ $1 ] keep [ xor-byte ] keep a<< ] }
+ { "XOR-(RR)" [ [ a>> ] keep [ $1 ] keep [ read-byte ] keep [ xor-byte ] keep a<< ] }
+ { "AND-N" [ [ a>> ] keep [ next-byte ] keep [ and-byte ] keep a<< ] }
+ { "AND-R" [ [ a>> ] keep [ $1 ] keep [ and-byte ] keep a<< ] }
+ { "AND-(RR)" [ [ a>> ] keep [ $1 ] keep [ read-byte ] keep [ and-byte ] keep a<< ] }
+ { "ADC-R,N" [ [ $1 ] keep [ next-byte ] keep [ add-byte-with-carry ] keep $2 ] }
+ { "ADC-R,R" [ [ $1 ] keep [ $3 ] keep [ add-byte-with-carry ] keep $2 ] }
+ { "ADC-R,(RR)" [ [ $1 ] keep [ $3 ] keep [ read-byte ] keep [ add-byte-with-carry ] keep $2 ] }
+ { "ADD-R,N" [ [ $1 ] keep [ next-byte ] keep [ add-byte ] keep $2 ] }
+ { "ADD-R,R" [ [ $1 ] keep [ $3 ] keep [ add-byte ] keep $2 ] }
+ { "ADD-RR,RR" [ [ $1 ] keep [ $3 ] keep [ add-word ] keep $2 ] }
+ { "ADD-R,(RR)" [ [ $1 ] keep [ $3 ] keep [ read-byte ] keep [ add-byte ] keep $2 ] }
+ { "SBC-R,N" [ [ $1 ] keep [ next-byte ] keep [ sub-byte-with-carry ] keep $2 ] }
+ { "SBC-R,R" [ [ $1 ] keep [ $3 ] keep [ sub-byte-with-carry ] keep $2 ] }
+ { "SBC-R,(RR)" [ [ $1 ] keep [ $3 ] keep [ read-byte ] keep [ sub-byte-with-carry ] keep $2 ] }
+ { "SUB-R" [ [ a>> ] keep [ $1 ] keep [ sub-byte ] keep a<< ] }
+ { "SUB-(RR)" [ [ a>> ] keep [ $1 ] keep [ read-byte ] keep [ sub-byte ] keep a<< ] }
+ { "SUB-N" [ [ a>> ] keep [ next-byte ] keep [ sub-byte ] keep a<< ] }
+ { "CPL" [ (emulate-CPL) ] }
+ { "DAA" [ (emulate-DAA) ] }
+ { "RLA" [ (emulate-RLA) ] }
+ { "RRA" [ (emulate-RRA) ] }
+ { "CCF" [ carry-flag swap cpu-f-bitxor= ] }
+ { "SCF" [ carry-flag swap cpu-f-bitor= ] }
+ { "RLCA" [ (emulate-RLCA) ] }
+ { "RRCA" [ (emulate-RRCA) ] }
+ { "HALT" [ drop ] }
+ { "DI" [ [ 255 interrupt-flag - ] swap cpu-f-bitand ] }
+ { "EI" [ [ interrupt-flag ] swap cpu-f-bitor ] }
+ { "POP-RR" [ [ pop-sp ] keep $2 ] }
+ { "PUSH-RR" [ [ $1 ] keep push-sp ] }
+ { "INC-R" [ [ $1 ] keep [ inc-byte ] keep $2 ] }
+ { "DEC-R" [ [ $1 ] keep [ dec-byte ] keep $2 ] }
+ { "INC-RR" [ [ $1 ] keep [ inc-word ] keep $2 ] }
+ { "DEC-RR" [ [ $1 ] keep [ dec-word ] keep $2 ] }
+ { "DEC-(RR)" [ [ $1 ] keep [ read-byte ] keep [ dec-byte ] keep [ $1 ] keep write-byte ] }
+ { "INC-(RR)" [ [ $1 ] keep [ read-byte ] keep [ inc-byte ] keep [ $1 ] keep write-byte ] }
+ { "JP-NN" [ [ pc>> ] keep [ read-word ] keep pc<< ] }
+ { "JP-F|FF,NN" [ [ $1 ] keep swap [ [ next-word ] keep [ pc<< ] keep [ cycles>> ] keep swap 5 + swap cycles<< ] [ [ pc>> 2 + ] keep pc<< ] if ] }
+ { "JP-(RR)" [ [ $1 ] keep pc<< ] }
+ { "CALL-NN" [ (emulate-CALL) ] }
+ { "CALL-F|FF,NN" [ [ $1 ] keep swap [ 7 over inc-cycles (emulate-CALL) ] [ [ pc>> 2 + ] keep pc<< ] if ] }
+ { "LD-RR,NN" [ [ next-word ] keep $2 ] }
+ { "LD-RR,RR" [ [ $3 ] keep $2 ] }
+ { "LD-R,N" [ [ next-byte ] keep $2 ] }
+ { "LD-(RR),N" [ [ next-byte ] keep [ $1 ] keep write-byte ] }
+ { "LD-(RR),R" [ [ $3 ] keep [ $1 ] keep write-byte ] }
+ { "LD-R,R" [ [ $3 ] keep $2 ] }
+ { "LD-R,(RR)" [ [ $3 ] keep [ read-byte ] keep $2 ] }
+ { "LD-(NN),RR" [ [ $1 ] keep [ next-word ] keep write-word ] }
+ { "LD-(NN),R" [ [ $1 ] keep [ next-word ] keep write-byte ] }
+ { "LD-RR,(NN)" [ [ next-word ] keep [ read-word ] keep $2 ] }
+ { "LD-R,(NN)" [ [ next-word ] keep [ read-byte ] keep $2 ] }
+ { "OUT-(N),R" [ [ $1 ] keep [ next-byte ] keep write-port ] }
+ { "IN-R,(N)" [ [ next-byte ] keep [ read-port ] keep a<< ] }
+ { "EX-(RR),RR" [ [ $1 ] keep [ read-word ] keep [ $3 ] keep [ $1 ] keep [ write-word ] keep $4 ] }
+ { "EX-RR,RR" [ [ $1 ] keep [ $3 ] keep [ $2 ] keep $4 ] }
} ;
: 8-bit-registers ( -- parser )
#! Return a parser for then instruction identified by the token.
#! The parser return parses the token only and expects no additional
#! arguments to the instruction.
- token [ '[ { } , generate-instruction ] ] action ;
+ token [ '[ { } _ generate-instruction ] ] action ;
: complex-instruction ( type token -- parser )
#! Return a parser for an instruction identified by the token.
#! The instruction is expected to take additional arguments by
#! being combined with other parsers. Then 'type' is used for a lookup
#! in a pattern hashtable to return the instruction quotation pattern.
- token swap [ nip '[ , generate-instruction ] ] curry action ;
+ token swap [ nip '[ _ generate-instruction ] ] curry action ;
: no-params ( ast -- ast )
first { } swap curry ;
IN-R,(N)-instruction ,
EX-(RR),RR-instruction ,
EX-RR,RR-instruction ,
- ] choice* [ call ] action ;
+ ] choice* [ call( -- quot ) ] action ;
: instruction-quotations ( string -- emulate-quot )
#! Given an instruction string, return the emulation quotation for
SYMBOL: last-instruction
SYMBOL: last-opcode
-: parse-instructions ( list -- emulate-quot )
+: parse-instructions ( list -- )
#! Process the list of strings, which should make
#! up an 8080 instruction, and output a quotation
#! that would implement that instruction.
dup " " join instruction-quotations
- >r "_" join [ "emulate-" % % ] "" make create-in dup last-instruction global set-at
- r> (( cpu -- )) define-declared ;
+ [
+ "_" join [ "emulate-" % % ] "" make create-in dup last-instruction set-global
+ ] dip ( cpu -- ) define-declared ;
-: INSTRUCTION: ";" parse-tokens parse-instructions ; parsing
+SYNTAX: INSTRUCTION: ";" parse-tokens parse-instructions ;
-: cycles ( -- )
- #! Set the number of cycles for the last instruction that was defined.
- scan string>number last-opcode global at instruction-cycles set-nth ; parsing
+SYNTAX: cycles
+ #! Set the number of cycles for the last instruction that was defined.
+ scan-token string>number last-opcode get-global instruction-cycles set-nth ;
-: opcode ( -- )
+SYNTAX: opcode
#! Set the opcode number for the last instruction that was defined.
- last-instruction global at 1quotation scan 16 base>
- dup last-opcode global set-at set-instruction ; parsing
+ last-instruction get-global 1quotation scan-token hex>
+ dup last-opcode set-global set-instruction ;