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7292d486dc
Allow us to rely a little less on labels. We now only need 4.
389 lines
7.0 KiB
Forth
389 lines
7.0 KiB
Forth
( Z80 assembler )
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: Z80AMEM+ 0x59 RAM+ @ + ;
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( H@ offset at which we consider our PC 0. Used to compute
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PC. To have a proper PC, call "H@ ORG !" at the beginning
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of your assembly process. )
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: ORG 0 Z80AMEM+ ;
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( Labels are a convenient way of managing relative jump
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calculations. Backward labels are easy. It is only a matter
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or recording "HERE" and do subtractions. Forward labels
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record the place where we should write the offset, and then
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when we get to that point later on, the label records the
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offset there.
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To avoid using dict memory in compilation targets, we
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pre-declare label variables here, which means we have a
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limited number of it. For now, 4 ought to be enough. )
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: L1 2 Z80AMEM+ ;
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: L2 4 Z80AMEM+ ;
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: L3 6 Z80AMEM+ ;
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: L4 8 Z80AMEM+ ;
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: Z80A$
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( 59 == z80a's memory )
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H@ 0x59 RAM+ !
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10 ALLOT
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;
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( Splits word into msb/lsb, lsb being on TOS )
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: SPLITB
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256 /MOD SWAP
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;
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: PC H@ ORG @ - ;
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( A, spits an assembled byte, A,, spits an assembled word
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Both increase PC. To debug, change C, to .X )
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: A, C, ;
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: A,, SPLITB A, A, ;
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( "r" register constants )
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7 CONSTANT A
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0 CONSTANT B
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1 CONSTANT C
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2 CONSTANT D
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3 CONSTANT E
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4 CONSTANT H
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5 CONSTANT L
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6 CONSTANT (HL)
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( "ss" register constants )
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0 CONSTANT BC
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1 CONSTANT DE
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2 CONSTANT HL
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3 CONSTANT AF
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3 CONSTANT SP
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( "cc" condition constants )
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0 CONSTANT CNZ
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1 CONSTANT CZ
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2 CONSTANT CNC
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3 CONSTANT CC
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4 CONSTANT CPO
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5 CONSTANT CPE
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6 CONSTANT CP
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7 CONSTANT CM
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( As a general rule, IX and IY are equivalent to spitting an
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extra 0xdd / 0xfd and then spit the equivalent of HL )
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: IX 0xdd A, HL ;
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: IY 0xfd A, HL ;
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: _ix+- 0xff AND 0xdd A, (HL) ;
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: _iy+- 0xff AND 0xfd A, (HL) ;
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: IX+ _ix+- ;
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: IX- 0 -^ _ix+- ;
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: IY+ _iy+- ;
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: IY- 0 -^ _iy+- ;
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: <<3 8 * ;
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: <<4 16 * ;
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( -- )
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: OP1 CREATE C, DOES> C@ A, ;
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0xf3 OP1 DI,
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0xfb OP1 EI,
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0xeb OP1 EXDEHL,
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0xd9 OP1 EXX,
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0x76 OP1 HALT,
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0xe9 OP1 JP(HL),
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0x12 OP1 LD(DE)A,
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0x1a OP1 LDA(DE),
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0x00 OP1 NOP,
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0xc9 OP1 RET,
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0x17 OP1 RLA,
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0x07 OP1 RLCA,
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0x1f OP1 RRA,
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0x0f OP1 RRCA,
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0x37 OP1 SCF,
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( Relative jumps are a bit special. They're supposed to take
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an argument, but they don't take it so they can work with
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the label system. Therefore, relative jumps are an OP1 but
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when you use them, you're expected to write the offset
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afterwards yourself. )
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0x18 OP1 JR,
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0x38 OP1 JRC,
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0x30 OP1 JRNC,
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0x28 OP1 JRZ,
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0x20 OP1 JRNZ,
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0x10 OP1 DJNZ,
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( r -- )
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: OP1r
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CREATE C,
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DOES>
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C@ ( r op )
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SWAP ( op r )
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<<3 ( op r<<3 )
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OR A,
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;
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0x04 OP1r INCr,
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0x05 OP1r DECr,
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( also works for cc )
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0xc0 OP1r RETcc,
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( r -- )
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: OP1r0
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CREATE C,
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DOES>
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C@ ( r op )
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OR A,
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;
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0x80 OP1r0 ADDr,
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0x88 OP1r0 ADCr,
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0xa0 OP1r0 ANDr,
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0xb8 OP1r0 CPr,
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0xb0 OP1r0 ORr,
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0x90 OP1r0 SUBr,
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0x98 OP1r0 SBCr,
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0xa8 OP1r0 XORr,
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( qq -- also works for ss )
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: OP1qq
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CREATE C,
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DOES>
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C@ ( qq op )
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SWAP ( op qq )
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<<4 ( op qq<<4 )
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OR A,
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;
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0xc5 OP1qq PUSHqq,
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0xc1 OP1qq POPqq,
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0x03 OP1qq INCss,
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0x0b OP1qq DECss,
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0x09 OP1qq ADDHLss,
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: _1rr
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C@ ( rd rr op )
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ROT ( rr op rd )
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<<3 ( rr op rd<<3 )
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OR OR A,
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;
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( rd rr )
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: OP1rr
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CREATE C,
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DOES>
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_1rr
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;
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0x40 OP1rr LDrr,
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( ixy+- HL rd )
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: LDIXYr,
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( dd/fd has already been spit )
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LDrr, ( ixy+- )
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A,
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;
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( rd ixy+- HL )
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: LDrIXY,
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ROT ( ixy+- HL rd )
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SWAP ( ixy+- rd HL )
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LDIXYr,
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;
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: OP2 CREATE , DOES> @ 256 /MOD A, A, ;
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0xedb1 OP2 CPIR,
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0xed46 OP2 IM0,
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0xed56 OP2 IM1,
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0xed5e OP2 IM2,
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0xed44 OP2 NEG,
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0xed4d OP2 RETI,
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( n -- )
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: OP2n
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CREATE C,
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DOES>
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C@ A, A,
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;
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0xd3 OP2n OUTnA,
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0xdb OP2n INAn,
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0xc6 OP2n ADDn,
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0xe6 OP2n ANDn,
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0xf6 OP2n Orn,
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0xd6 OP2n SUBn,
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( r n -- )
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: OP2rn
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CREATE C,
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DOES>
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C@ ( r n op )
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ROT ( n op r )
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<<3 ( n op r<<3 )
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OR A, A,
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;
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0x06 OP2rn LDrn,
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( b r -- )
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: OP2br
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CREATE C,
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DOES>
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0xcb A,
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C@ ( b r op )
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ROT ( r op b )
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<<3 ( r op b<<3 )
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OR OR A,
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;
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0xc0 OP2br SETbr,
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0x80 OP2br RESbr,
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0x40 OP2br BITbr,
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( bitwise rotation ops have a similar sig )
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( r -- )
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: OProt
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CREATE C,
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DOES>
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0xcb A,
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C@ ( r op )
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OR A,
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;
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0x10 OProt RLr,
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0x00 OProt RLCr,
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0x18 OProt RRr,
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0x08 OProt RRCr,
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0x20 OProt SLAr,
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0x38 OProt SRLr,
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( cell contains both bytes. MSB is spit as-is, LSB is ORed with r )
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( r -- )
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: OP2r
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CREATE ,
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DOES>
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@ SPLITB SWAP ( r lsb msb )
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A, ( r lsb )
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SWAP <<3 ( lsb r<<3 )
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OR A,
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;
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0xed41 OP2r OUT(C)r,
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0xed40 OP2r INr(C),
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( ss -- )
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: OP2ss
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CREATE C,
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DOES>
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0xed A,
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C@ SWAP ( op ss )
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<<4 ( op ss<< 4 )
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OR A,
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;
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0x4a OP2ss ADCHLss,
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0x42 OP2ss SBCHLss,
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( dd nn -- )
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: OP3ddnn
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CREATE C,
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DOES>
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C@ ( dd nn op )
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ROT ( nn op dd )
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<<4 ( nn op dd<<4 )
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OR A,
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A,,
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;
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0x01 OP3ddnn LDddnn,
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( nn -- )
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: OP3nn
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CREATE C,
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DOES>
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C@ A,
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A,,
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;
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0xcd OP3nn CALLnn,
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0xc3 OP3nn JPnn,
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0x22 OP3nn LD(nn)HL,
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0x2a OP3nn LDHL(nn),
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( Specials )
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( dd nn -- )
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: LDdd(nn),
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0xed A,
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SWAP <<4 0x4b OR A,
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A,,
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;
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( nn dd -- )
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: LD(nn)dd,
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0xed A,
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<<4 0x43 OR A,
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A,,
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;
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: JP(IX), IX DROP JP(HL), ;
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: JP(IY), IY DROP JP(HL), ;
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( 26 == next )
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: JPNEXT, 26 JPnn, ;
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: CODE
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( same as CREATE, but with native word )
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(entry)
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( 23 == nativeWord )
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23 ,
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;
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: ;CODE JPNEXT, ;
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( Macros )
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( clear carry + SBC )
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: SUBHLss, A ORr, SBCHLss, ;
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( Routines )
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( 29 == chkPS )
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: chkPS, 29 CALLnn, ;
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( Flow
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There are 2 label types: backward and forward. For each
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type, there are two actions: set and write. Setting a label
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is declaring where it is. It has to be performed at the
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label's destination. Writing a label is writing its offset
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difference to the binary result. It has to be done right
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after a relative jump operation. Yes, labels are only for
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relative jumps.
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For backward labels, set happens before write. For forward
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labels, write happen before set. The write operation writes
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a dummy placeholder, and then the set operation writes the
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offset at that placeholder's address.
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Variable actions are expected to be called with labels in
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front of them. Example, "L2 FSET"
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About that "1 -": z80 relative jumps record "e-2", that is,
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the offset that *counts the 2 bytes of the jump itself*.
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Because we set the label *after* the jump OP1 itself, that's
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1 byte that is taken care of. We still need to adjust by
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another byte before writing the offset.
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)
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( Place BEGIN, where you want to jump back and AGAIN after
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a relative jump operator. Just like BSET and BWR. )
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: BEGIN, PC ;
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: AGAIN, PC - 1 - A, ;
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: BSET PC SWAP ! ;
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: BWR @ AGAIN, ;
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( same as BSET, but we need to write a placeholder )
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: FJR, PC 0 A, ;
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: IFZ, JRZ, FJR, ;
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: IFNZ, JRNZ, FJR, ;
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: IFC, JRC, FJR, ;
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: IFNC, JRNC, FJR, ;
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: THEN,
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DUP PC ( l l pc )
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-^ 1 - ( l off )
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( warning: l is a PC offset, not a mem addr! )
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SWAP ORG @ + ( off addr )
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C!
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;
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: FWR BSET 0 A, ;
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: FSET @ THEN, ;
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