#define RCSID4 "$Header$" /* ** Zilog z8000 yacc parsing rules */ operation : f1 | f2 | f3 | f4 | f5 | f6 | f7 | f8 | f9 ; f1 : F1_1F2_3 dst { switch( ($1 & 0x0F00)>>8 ) { case 9: case 0xF: chtype( DST, TYPE_11a23 ); break; case 0xC: case 0xD: chtype( DST, TYPE_11b23 ); break; } emit2( mode | $1 | $2<<4 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } | F1_1a reg { chreg( $1, $2 ); emit2( $1 | $2<<4 ); } | F1_1b reg option { if ( $3 != 1 && $3 != 2 ) argerr(); emit2( $1 | $2<<4 | ($3-1)<<1 ); } | F1_2 dst option { chtype( DST, TYPE_12 ); fit(fit4($3-1)); emit2( mode | $1 | $2<<4 | $3-1 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } | LDK reg ',' imexpr { fit(fit4($4)); emit2( $1 | $2<<4 | $4 ); } | F1_2F6_3 dst ',' src { if ( oprtype[ DST ] == REG && oprtype[ SRC ] == REG ) { emit2( $1 | $4 ); emit2( $2<<8 ); } else if ( oprtype[ SRC ] == IM ) { chtype( DST, TYPE_1263 ); if ((immed.typ & ~S_EXT) != S_ABS) { serror("must be absolute"); } if ( bitset($1,8) ) /* word */ fit(fit4(immed.val)); else /* byte */ fit(fit3(immed.val)); emit2( mode | $1 | $2<<4 | (int)immed.val ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } else argerr(); } | JP coco1 dst { chtype( DST, TYPE_jp ); emit2( mode | $1 | $3<<4 | $2 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } | TCC coco1 reg { emit2( $1 | $3<<4 | $2 ); } ; f2 : F2_1 reg ',' src { switch( ($1 & 0xF000)>>12 ) { case 2: chtype( SRC, TYPE_21a ); break; case 3: chtype( SRC, TYPE_21b ); break; } emit2( mode | $1 | $4<<4 | $2 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } | F2_1F5_1 dst ',' src { switch( oprtype[ DST ] ) { case REG: chtype( SRC, TYPE_2151 ); chreg( $1, $2 ); emit2( mode | $1 | $4<<4 | $2 ); break; case IR: case DA: case X: if ( oprtype[ SRC ] == IM && ( $1 == 0x0B00 || $1 == 0x0A00 ) ) /* cp or cpb */ { setmode( DST ); emit2( mode | $1 + 0x201 | $2<<4 ); break; } default: argerr(); } if ( mode>>12 == 4 ) emit_ad( addr_inf ); if ( oprtype[ SRC ] == IM ) { if (bitset($1,8)) /* word */ { #ifdef RELOCATION newrelo(immed.typ, RELO2|RELBR); #endif emit2( (int)immed.val ); } else if (bitset($1,12)) /* long */ { #ifdef RELOCATION newrelo(immed.typ, RELO4|RELWR|RELBR); #endif emit4( immed.val ); } else /* byte */ { #ifdef RELOCATION newrelo(immed.typ, RELO1); #endif emit1((int) immed.val); /* emit1((int) immed.val); ??? twice ??? */ } } } | LDA R32 ',' src { switch( oprtype[ SRC ] ) { case DA: case X: emit2( 0x7600 | $4<<4 | $2 ); emit_ad( addr_inf ); break; case BA: emit2( 0x3400 | $4<<4 | $2 ); #ifdef RELOCATION newrelo(displ.typ,RELO2|RELBR); #endif emit2( (int) displ.val ); break; case BX: emit2( 0x7400 | $4<<4 | $2 ); emit2( index<<8 ); break; default: argerr(); } } | POP dst ',' ir { chtype( DST, TYPE_pop ); emit2( mode | $1 | $4<<4 | $2 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } | PUSH ir ',' src { chtype( SRC, TYPE_push ); switch ( oprtype[ SRC ] ) { case IM: if ( $1 == 0x1100 ) /* pushl */ argerr(); /* { emit2( 0x9109 | $2<<4 ); ** emit4( immed ); ** } */ else { emit2( 0x0D09 | $2<<4 ); #ifdef RELOCATION newrelo(immed.typ, RELO2|RELBR); #endif emit2( (int)immed.val ); } break; default: emit2( mode | $1 | $2<<4 | $4 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); } } | LD dst ',' src { if ( oprtype[ DST ] == REG ) { switch( oprtype[ SRC ] ) { case IM: if ( $1 == 0 ) /* ldb: F3.2 */ { /* fit(fits8(immed)); */ emit1( 0xC000 | $2<<8); #ifdef RELOCATION newrelo(immed.typ, RELO1); #endif emit1((int) immed.val); } else { /*fit(fits16(immed));*/ emit2( 0x2100 | $2 ); #ifdef RELOCATION newrelo(immed.typ, RELO2|RELBR); #endif emit2( (int)immed.val ); } break; case REG: case IR: case DA: case X: setmode( SRC ); emit2( mode | 0x2000 | $1 | $4<<4 | $2 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); break; case BA: emit2( 0x3000 | $1 | $4<<4 | $2 ); #ifdef RELOCATION newrelo(displ.typ,RELO2|RELBR); #endif emit2( (int) displ.val ); break; case BX: emit2( 0x7000 | $1 | $4<<4 | $2 ); emit2( index<<8 ); break; default: argerr(); } break; } if ( oprtype[ SRC ] == REG ) { switch( oprtype[ DST ] ) { case IR: case DA: case X: setmode( DST ); emit2( mode | 0x2E00 | $1 | $2<<4 | $4 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); break; case BA: emit2( 0x3200 | $1 | $2<<4 | $4 ); #ifdef RELOCATION newrelo(displ.typ,RELO2|RELBR); #endif emit2( (int) displ.val ); break; case BX: emit2( 0x7200 | $1 | $2<<4 | $4 ); emit2( index<<8 ); break; default: argerr(); } break; } if ( oprtype[ SRC ] == IM ) /* F5.1 */ { chtype( DST, TYPE_ld ); emit2( mode | 0xC05 | $1 | $2<<4 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); if ( $1 == 0 ) /* ldb */ { /* fit(fits8(immed)); */ #ifdef RELOCATION newrelo(immed.typ, RELO1); #endif emit1((int) immed.val); /* emit1((int) immed.val); ??? twice ??? */ } else /* ld */ { /*fit(fits16(immed));*/ #ifdef RELOCATION newrelo(immed.typ, RELO2 | RELBR); #endif emit2( (int)immed.val ); } break; } argerr(); } | LDL dst ',' src { if ( oprtype[ DST ] == REG ) { switch( oprtype[ SRC ] ) { case IM: emit2( 0x1400 | $2 ); #ifdef RELOCATION newrelo(immed.typ, RELO4|RELBR|RELWR); #endif emit4( immed.val ); break; case REG: case IR: case DA: case X: setmode( SRC ); emit2( mode | 0x1400 | $4<<4 | $2 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); break; case BA: emit2( 0x3500 | $4<<4 | $2 ); #ifdef RELOCATION newrelo(displ.typ,RELO2|RELBR); #endif emit2((int) displ.val ); break; case BX: emit2( 0x7500 | $4<<4 | $2 ); emit2( index<<8 ); break; default: argerr(); } break; } if ( oprtype[ SRC ] == REG ) { switch( oprtype[ DST ] ) { case IR: case DA: case X: setmode( DST ); emit2( mode | 0x1D00 | $2<<4 | $4 ); if ( mode>>12 == 4 ) emit_ad( addr_inf ); break; case BA: emit2( 0x3700 | $2<<4 | $4 ); #ifdef RELOCATION newrelo(displ.typ,RELO2|RELBR); #endif emit2( (int) displ.val ); break; case BX: emit2( 0x7700 | $2<<4 | $4 ); emit2( index<<8 ); break; default: argerr(); } break; } /* if ( oprtype[ SRC ] == IM ) ** { chtype( DST, TYPE_ld ); ** emit2( mode | 0xD07 | $2<<4 ); ** if ( mode>>12 == 4 ) emit_ad( addr_inf ); ** emit4( immed ); ** break; ** } */ argerr(); } ; f3 : DJNZ reg ',' ra { branch( $1 | $2<<8, $4 ); } | JR coco1 ra { branch( $1 | $2<<8, $3 ); } | CALR ra { branch( $1, $2 ); } ; f4 : LDR reg ',' ra { ldrel( $1 | $2, $4 ); } | LDR ra ',' reg { ldrel( $1 | 0x200 | $4, $2 ); } | LDAR R32 ',' ra { ldrel( $1 | $2, $4 ); } ; f5 : F5_1L reg option { if ( $3 < 0 ) { warning( "neg src results in a right shift!" ); warning( "warning only"); } shiftcode( $1 | $2<<4, $3 ); } | F5_1R reg option2 { if ( $3 > 0 ) { warning( "pos src results in a left shift!" ); warning( "warning only"); } shiftcode( $1 | $2<<4, $3 ); } ; option2 : ',' imexpr { $$ = $2; } | /* empty */ { $$ = -1; } ; f6 : LDM dst ',' src ',' imexpr { switch( oprtype[ DST ] ) { case REG: chtype( SRC, TYPE_ldm ); ldmcode( $1 | $4<<4, $2, $6 ); break; default: switch( oprtype[ SRC ] ) { case REG: chtype( DST, TYPE_ldm ); ldmcode($1+8 | $2<<4, $4, $6); break; default: argerr(); } } } | F6_4 ir ',' ir ',' R16 { /* For translate instructions the roles of $2 and $4 ** are interchanged with respect to the other ** instructions of this group. */ if ( ($1 & 0xB8FF) == $1 ) { /* translate instruction */ emit2( ($1 & ~0xF0) | $2<<4 ); emit2( ($1 & 0xF0)>>4 | $6<<8 | $4<<4 ); } else { emit2( ($1 & ~0xF0) | $4<<4 ); emit2( ($1 & 0xF0)>>4 | $6<<8 | $2<<4 ); } } | F6_5 dst ',' ir ',' R16 coco2 { switch( oprtype[ DST ] ) { case REG: if ( bitset($1,1) ) argerr(); break; case IR : if ( !bitset($1,1) ) argerr(); break; default : argerr(); } emit2( $1 | $4<<4 ); emit2( $6<<8 | $2<<4 | $7 ); } | F6_6 reg ',' R16 { emit2( $1 | $2<<4 ); emit2( $4<<8 ); } ; f7 : IN reg ',' da { emit2( $1 | 0xA04 | $2<<4 ); #ifdef RELOCATION newrelo(adr_inf.typ, RELO2|RELBR); #endif emit2( (short)addr_inf.val ); /* i/o address */ } | OUT da ',' reg { emit2( $1 | 0xA06 | $4<<4 ); #ifdef RELOCATION newrelo(adr_inf.typ, RELO2|RELBR); #endif emit2( (short)addr_inf.val ); /* i/o address */ } | IN reg ',' ir { if ( bitset($1,0) ) argerr(); emit2( $1 | 0xC00 | $4<<4 | $2 ); } | OUT ir ',' reg { if ( bitset($1,0) ) argerr(); emit2( $1 | 0xE00 | $2<<4 | $4 ); } ; f8 : LDCTL ctlargs { emit2( $1 | $2 ); } | LDCTLB ctlbargs { emit2( $1 | $2 ); } | MREQ reg { emit2( $1 | $2<<4 ); } ; ctlargs : CTLR ',' R16 { $$ = $3<<4 | $1 | 8; } | R16 ',' CTLR { $$ = $1<<4 | $3; } ; ctlbargs: CTLRFLAGS ',' R8 { $$ = $3<<4 | $1 | 8;} | R8 ',' CTLRFLAGS { $$ = $1<<4 | $3; } ; f9 : F9_1 flags { emit2( $1 | $2 ); } | F9_2 ints { emit2( $1 | $2 ); } | F9_3 { emit2( $1 ); } | RET { emit2( $1 | 8 ); } | RET CC { emit2( $1 | $2 ); } | SC imexpr { fit(fit8($2)); emit2( $1 | $2 ); } ; flags : flags ',' FLAG { $$ = $1 | $3; } | FLAG { $$ = $1; } ; ints : ints ',' INTCB { $$ = $1 | $3; } | INTCB { $$ = $1; } ; coco1 : CC ',' { $$ = $1; } | /* empty */ { $$ = 8; } ; coco2 : ',' CC { $$ = $2; } | /* empty */ { $$ = 8; } ; option : ',' imexpr { $$ = $2; } | /* empty */ { $$ = 1; } ; /* `imexpr', just as `im', is used to implement immediate data. ** But `imexpr' is used in those cases where the immediate value ** always will fit into 16 bits, so (long) `immed' is not needed. ** Those cases are in `option', `option2', f9-`SC', f6-`LDM' and ** f1-`LDK'. */ imexpr : '$' absexp { $$ = $2; } ; /* Destination (dst) as well as source (src) operands never ** have RA as addressing mode, except for some instructions of the ** F3 and F4 instruction format group. In those cases RA is even ** the only addressing mode which is allowed. This is why `ra' ** has a yacc-rule not being part of `opr'. */ ra : expr { $$ = $1; } ; dst : { operand = DST;} opr { $$ = $2; } ; src : { operand = SRC;} opr { $$ = $2; } ; opr : reg { settype( REG ); } | im { settype( IM ); } | ir { settype( IR ); } | da { settype( DA ); } | x { settype( X ); } | ba { settype( BA ); } | bx { settype( BX ); } ; reg : R8 | R16 | R32 | R64 ; im : '$' expr { $$ = 0; immed = $2; } | '$' '<' '<' expr '>' '>' expr { $$ = 0; immed.typ = combine($4.typ, $7.typ, '+'); immed.val = $4.val<<16 | $7.val; } ; ir : '*' R32 { if ( $2 == 0 ) regerr(); $$ = $2; } ; da : expr { $$ = 0; addr_inf = $1; } | '<' '<' expr '>' '>' expr { $$ = 0; addr_inf.typ = combine( $3.typ, $6.typ, '+' ); addr_inf.val = $3.val<<16 | $6.val; } ; x : expr '(' R16 ')' { if ( $3 == 0 ) regerr(); $$ = $3; addr_inf = $1; } | '<' '<' expr '>' '>' expr '(' R16 ')' { if ( $8 == 0 ) regerr(); $$ = $8; addr_inf.typ = combine( $3.typ, $6.typ, '+' ); addr_inf.val = $3.val<<16 | $6.val; } ; ba : R32 '(' '$' expr ')' { if ( $1 == 0 ) regerr(); $$ = $1; displ = $4; } ; bx : R32 '(' R16 ')' { if ( $1 == 0 || $3 == 0 ) regerr(); $$ = $1; index = $3; } ;