#define RCSID5 "$Header$" /* * NS 16032 special routines */ clrmode() { /* clear the current mode */ mode_ptr->m_ndisp = 0 ; } int ind_mode(type) { switch ( type ) { case 'b' : return 0x1C ; case 'w' : return 0x1D ; case 'd' : return 0x1E ; case 'q' : return 0x1F ; default : serror("illegal size indicator") ; return 0x1F ; } } badsyntax() { serror("bad operands"); } ill_imm() { serror("immediate operand not allowed") ; } /* Create the output formats */ form2(id,sval) { assert ( id_t1(id)==T_INT ) ; emit1( id_g1(id) | 0xC | (id_op(id)<<4) | ((sval&1)<<7 ) ) ; emit1( (sval>>1) | (mode1.m_mode<<3) ) ; } form3(id) { assert ( id_t1(id)==T_INT ) ; emit1( id_g1(id) | 0x7C | ((id_op(id)&1)<<7) ) ; emit1( (id_op(id)>>1) | (mode1.m_mode<<3) ) ; } form4(id) { assert ( id_t1(id)==T_INT && id_t2(id)==T_INT ); emit1( id_g2(id) | (id_op(id)<<2) | ((mode2.m_mode&3)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } form5(id,sval) { assert ( id_t1(id)==T_INT ) ; emit1(0xE) ; emit1( id_g1(id) | (id_op(id)<<2) | ((sval&1)<<7 ) ) ; emit1( (sval>>1) ) ; } form7x(id,i_type) { assert ( id_t1(id)==T_INT && id_t2(id)==T_INT ); emit1(0xCE) ; emit1( i_type | (id_op(id)<<2) | ((mode2.m_mode&3)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } form8(id,reg) { assert ( id_t1(id)==T_INT ) ; emit1( 0x2E | ((id_op(id)&3)<<6) ) ; emit1( id_g1(id) | (id_op(id)&04) | (reg<<3) | ((mode2.m_mode&03)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } form9(id,i_type,f_type) { emit1(0x3E) ; emit1( i_type | (f_type<<2) | (id_op(id)<<3) | ((mode2.m_mode&03)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } form11(id) { assert ( id_t1(id)==T_FL && id_t2(id)==T_FL && id_g1(id)==id_g2(id) ); emit1(0xBE) ; emit1( id_g1(id) | (id_op(id)<<2) | ((mode2.m_mode&3)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } form14(id,reg) { assert ( id_t1(id)==T_INT ) ; emit1(0x1E) ; emit1( id_g1(id) | (id_op(id)<<2) | ((reg&1)<<7 ) ) ; emit1( (reg>>1) | (mode1.m_mode<<3) ) ; } frm15_0(id,reg) { assert ( id_t1(id)==T_INT ) ; emit1(0x16 /* + slave<<5 */ ) ; emit1( id_g1(id) | (id_op(id)<<2) | ((reg&1)<<7 ) ) ; emit1( (reg>>1) | (mode1.m_mode<<3) ) ; } frm15_1(id,i_type,s_type) { emit1(0x16 /* + slave<<5 */ ) ; emit1( i_type | (s_type<<2) | (id_op(id)<<3) | ((mode2.m_mode&03)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } frm15_5(id) { assert(id_t1(id)==T_SLAVE&& id_t2(id)==T_SLAVE&& id_g1(id)==id_g2(id) ); emit1(0x16 /* + slave<<5 */ ) ; emit1( id_g1(id) | (id_op(id)<<2) | ((mode2.m_mode&3)<<6) ) ; emit1( (mode2.m_mode>>2) | (mode1.m_mode<<3) ) ; } gen1(id) { if ( (mode1.m_mode&0x1C)==0x1C ) { emit1(mode1.m_index) ; } if ( mode1.m_mode==0x14 ) { /* Immediate */ RELOMOVE(relonami, mode1.m_rel1); imm(id_g1(id),&mode1.m_expr1) ; } else if ( mode1.m_ndisp >0 ) { RELOMOVE(relonami, mode1.m_rel1); disp(&mode1.m_expr1, mode1.m_mode == 0x1B ? RELPC : 0) ; if ( mode1.m_ndisp >1 ) { RELOMOVE(relonami, mode1.m_rel2); disp(&mode1.m_expr2, 0) ; } } } gengen(id) { if ( (mode1.m_mode&0x1C)==0x1C ) { emit1(mode1.m_index) ; } if ( (mode2.m_mode&0x1C)==0x1C ) { emit1(mode2.m_index) ; } if ( mode1.m_mode==0x14 ) { /* Immediate */ RELOMOVE(relonami, mode1.m_rel1); imm(id_g1(id),&mode1.m_expr1) ; } else if ( mode1.m_ndisp >0 ) { RELOMOVE(relonami, mode1.m_rel1); disp(&mode1.m_expr1, mode1.m_mode == 0x1B ? RELPC : 0) ; if ( mode1.m_ndisp >1 ) { RELOMOVE(relonami, mode1.m_rel2); disp(&mode1.m_expr2, 0) ; } } if ( mode2.m_mode==0x14 ) { /* Immediate */ RELOMOVE(relonami, mode2.m_rel1); imm(id_g2(id),&mode2.m_expr1) ; } else if ( mode2.m_ndisp >0 ) { RELOMOVE(relonami, mode2.m_rel1); disp(&mode2.m_expr1, mode2.m_mode == 0x1B ? RELPC : 0) ; if ( mode2.m_ndisp >1 ) { RELOMOVE(relonami, mode2.m_rel2); disp(&mode2.m_expr2, 0) ; } } } disp(expr, relpc) register expr_t *expr ; { register sm1, sm2 ; sm1=0 ; sm2=0 ; if (DOTTYP >= 0x2 && DOTTYP<=0x7F && #ifdef ASLD (pass==PASS_1 ? expr->typ==S_ABS : expr->typ!=S_VAR ) ) { #else expr->typ == S_ABS) { #endif /* All non-text displacements are quad-sized. The algorithm currently used for minimizing the size (See CACM article) might generate assertion failures if any displacement it is trying to minimize increases during the assembly process. The only way to avoid increases like that is to fix the sizes of all displacements in non-text segments. If the framework included enough information one might detect in the first pass (0) whether the value of the expression depends on any symbols whose value might alter later on in the assembly process. In that case one could determine the right size in the first pass in most cases. */ if ( fitd_b(expr->val) ) { sm1=1 ; sm2= 1 ; } else { if ( fitd_w(expr->val) ) sm2=1 ; } } sm1=small(sm1,1) ; sm2=small(sm2,2) ; #ifdef RELOCATION newrelo(expr->typ, RELO4|RELBR|RELWR|relpc); #endif if ( sm1 ) putdisp(expr->val,1) ; else if ( sm2 ) putdisp(expr->val,2) ; else putdisp(expr->val,4) ; } putdisp(val,size) valu_t val ; { switch ( size ) { case 1 : emit1( ((int)val)&0x7F ) ; break ; case 2 : emit1( ( (((int)val)>>8)&0x3F ) | 0x80 ) ; emit1( ((int)val)&0xFF ) ; break ; case 4 : emit1( (((int)(val>>24)) | 0xC0) & 0xFF ) ; emit1( ((int)(val>>16)) & 0xFF ) ; emit1( (((int)val)>>8) & 0xFF ) ; emit1( ((int)val)&0xFF ) ; break ; } } dot_adjust(expr) register expr_t *expr ; { expr->val -= DOTVAL ; if ( pass==PASS_2 ) { if ( (expr->typ&S_DOT) == 0 && expr->val>0 ) { expr->val -= DOTGAIN; } } if ( (expr->typ & ~S_DOT) == DOTTYP ) { expr->typ=S_ABS ; } else { expr->typ=S_VAR ; } } /* The idea of the following is: * Give the assembler programmer a warning if he tries to store * an immediate value in a field which is too small to fit in. */ testsize(type,val) { /* check if value fits in type */ switch( type ) { case I_DOUBLE : return fit32(val); case I_WORD : return fit16(val); case I_BYTE : return fit8(val); } } imm(i_type,expr) register expr_t *expr ; { /* emit value of immediate expression , after check on FIT */ if (!testsize(i_type,(int)expr->val)) warning("immediate operand too large"); switch( i_type ) { case I_DOUBLE : #ifdef RELOCATION newrelo(expr->typ, RELO4|RELBR|RELWR); #endif emit1( ((int)(expr->val>>24)) & 0xFF ) ; emit1( ((int)(expr->val>>16)) & 0xFF ) ; emit1( (((int)expr->val)>>8) & 0xFF ) ; emit1( ((int)expr->val) & 0xFF ) ; break; case I_WORD: #ifdef RELOCATION newrelo(expr->typ, RELO2|RELBR); #endif emit1( (((int)expr->val)>>8) & 0xFF ) ; emit1( ((int)expr->val) & 0xFF ) ; break; case I_BYTE: #ifdef RELOCATION newrelo(expr->typ, RELO1); #endif emit1( ((int)expr->val) & 0xFF ) ; } } reg_list(list,reverse) { register rev_list, i ; if ( !reverse ) { return list ; } rev_list= 0 ; for ( i=0 ; i<8 ; i++ ) { if ( list & (1<