#ifndef NORCSID static char rcsid[] = "$Header$"; #endif /* * (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands. * See the copyright notice in the ACK home directory, in the file "Copyright". * */ /* * machine dependent back end routines for the Motorola 68000 */ #include "fppsim.h" con_part(sz,w) register sz; word w; { while (part_size % sz) part_size++; if (part_size == TEM_WSIZE) part_flush(); if (sz == 1) { w &= 0xFF; if (part_size == 0) w <<= 8; part_word |= w; } else { assert(sz == 2); part_word = w; } part_size += sz; } con_mult(sz) word sz; { if (sz != 4) fatal("bad icon/ucon size"); fprintf(codefile,".data4 %s\n",str); } #ifdef NOFLOAT con_float() { static int been_here; if (argval != 4 && argval != 8) fatal("bad fcon size"); fputs(".data4\t", codefile); if (argval == 8) fputs("0,", codefile); fputs("0 !dummy float\n", codefile); if ( !been_here++) { fputs("Warning : dummy float-constant(s)\n", stderr); } } #else #define IEEEFLOAT con_float() { double f; double atof(); float fl; int i; #ifndef OWNFLOAT double f1; double frexp(), modf(); int j; int sign = 0; int fraction[4] ; #else OWNFLOAT char *p; #endif OWNFLOAT if (argval!= 4 && argval!= 8) { fprintf(stderr,"float constant size = %d\n",argval); fatal("bad fcon size"); } fprintf(codefile,"!float %s sz %d\n", str, argval); f = atof(str); #ifdef OWNFLOAT if (argval == 4) { fl = f; p = (char *) &fl; } else { p = (char *) &f; } fprintf(codefile, ".data1 0%o", *p++ & 0377); for (i = argval-1; i; i--) { fprintf(codefile,",0%o", *p++ & 0377); } #else OWNFLOAT f = frexp(f, &i); if (f < 0) { f = -f; sign = 1; } if (f == 0) { if (argval == 8) fprintf(codefile, ".data2 0, 0\n"); fprintf(codefile, ".data2 0, 0\n"); return; } while (f < 0.5) { f += f; i --; } f = modf(2 * f, &f1); /* hidden bit */ #ifdef IEEEFLOAT if (argval == 4) { #endif IEEEFLOAT i = (i + 128) & 0377; fraction[0] = (sign << 15) | (i << 7); for (j = 6; j>= 0; j--) { if (f >= 0.5) fraction[0] |= (1 << j); f = modf(2*f, &f1); } #ifdef IEEEFLOAT } else { i = (i + 1024) & 03777; fraction[0] = (sign << 15) | (i << 4); for (j = 3; j>= 0; j--) { if (f >= 0.5) fraction[0] |= (1 << j); f = modf(2*f, &f1); } } #endif IEEEFLOAT for (i = 1; i < argval / 2; i++) { fraction[i] = 0; for (j = 15; j>= 0; j--) { if (f >= 0.5) fraction[i] |= (1 << j); f = modf(2*f, &f1); } } if (f >= 0.5) { for (i = argval/2 - 1; i >= 0; i--) { for (j = 0; j < 16; j++) { if (fraction[i] & (1 << j)) { fraction[i] &= ~(1 << j); } else { fraction[i] |= (1 << j); break; } } if (j != 16) break; } } for (i = 0; i < argval/2; i++) { fprintf(codefile, i != 0 ? ", 0%o, 0%o" : ".data1 0%o, 0%o", (fraction[i]>>8)&0377, fraction[i]&0377); } #endif OWNFLOAT putc('\n', codefile); } #endif #ifdef REGVARS regscore(off,size,typ,score,totyp) long off; { if (score == 0) return -1; switch(typ) { case reg_float: return -1; case reg_pointer: if (size != 4 || totyp != reg_pointer) return -1; score *= 2; break; case reg_loop: score += 5; /* fall through .. */ case reg_any: if (size != 2 || totyp == reg_pointer) return -1; break; } if (off >= 0) { /* parameters must be initialised with an instruction * like "move.w 4(a6),d0", which costs 2 words. */ score -= 2; } score -= 1; /* take save/restore into account */ return score; } struct regsav_t { char *rs_reg; /* e.g. "a3" or "d5" */ long rs_off; /* offset of variable */ int rs_size; /* 2 or 4 bytes */ } regsav[9]; int regnr; i_regsave() { regnr = 0; } #define MOVEM_LIMIT 2 /* If #registers to be saved exceeds MOVEM_LIMIT, we * use the movem instruction to save registers; else * we simply use several move.l's. */ save() { register struct regsav_t *p; if (regnr > MOVEM_LIMIT) { fprintf(codefile,"movem.l "); for (p = regsav; ;) { fprintf(codefile,"%s",p->rs_reg); if (++p == ®sav[regnr]) break; putc('/',codefile); } fprintf(codefile,",-(sp)\n"); } else { for (p = regsav; p < ®sav[regnr]; p++) { fprintf(codefile,"move.l %s,-(sp)\n",p->rs_reg); } } /* initialise register-parameters */ for (p = regsav; p < ®sav[regnr]; p++) { if (p->rs_off >= 0) { fprintf(codefile,"move.%c %ld(a6),%s\n", (p->rs_size == 4 ? 'l' : 'w'), p->rs_off, p->rs_reg); } } } restr() { register struct regsav_t *p; if (regnr > MOVEM_LIMIT) { fprintf(codefile,"movem.l (sp)+,"); for (p = regsav; ;) { fprintf(codefile,"%s",p->rs_reg); if (++p == ®sav[regnr]) break; putc('/',codefile); } putc('\n',codefile); } else { for (p = ®sav[regnr-1]; p >= regsav; p--) { fprintf(codefile,"move.l (sp)+,%s\n",p->rs_reg); } } fprintf(codefile,"unlk a6\n"); fprintf(codefile,"rts\n"); } f_regsave() { save(); } regsave(str,off,size) char *str; long off; { assert (regnr < 9); regsav[regnr].rs_reg = str; regsav[regnr].rs_off = off; regsav[regnr++].rs_size = size; fprintf(codefile, "!Local %ld into %s\n",off,str); } regreturn() { restr(); } #endif prolog(nlocals) full nlocals; { fprintf(codefile,"tst.b -%ld(sp)\nlink\ta6,#-%ld\n",nlocals+40,nlocals); } mes(type) word type ; { int argt ; switch ( (int)type ) { case ms_ext : for (;;) { switch ( argt=getarg( ptyp(sp_cend)|ptyp(sp_pnam)|sym_ptyp) ) { case sp_cend : return ; default: strarg(argt) ; fprintf(codefile,".define %s\n",argstr) ; break ; } } default : while ( getarg(any_ptyp) != sp_cend ) ; break ; } } char *segname[] = { ".sect .text", /* SEGTXT */ ".sect .data", /* SEGCON */ ".sect .rom", /* SEGROM */ ".sect .bss" /* SEGBSS */ };