/* catch register messages. BEWARE: code uses plain printf's (fprint's) * to generate code. This is not compatible with the usual procedure * used in the EM_table */ #define CODE_EXPANDER #include #include #include #include #include "mach.h" #include "push_pop.h" #include #define MAX_NR_REGS 12 #define MAX_NR_FLTS MAX_NR_FLT_REGS /* depends on using float or doubles */ #define RM_OFFSET 0 #define RM_SIZE 1 #define RM_TYPE 2 #define RM_COUNT 3 typedef struct reg_info { int offset; int size; /* 4 or 8 */ int pri; reg_t reg, reg2; /* reg2 used for doubles only */ } reg_info; static reg_info reg_dat[MAX_NR_REGS], flt_dat[MAX_NR_FLTS]; static int current_reg_mes[RM_COUNT+4]; static int in_reg_mes = 0; /* boolean */ static int reg_mes_nr; static int db_mes = 0; static int db_kind = 0; static int db_str = 0; static int db_nul = 0; /* boolean */ static int worst_reg_pri, worst_flt_pri; /* reset by C_prolog (to some large number) */ static int nr_reg_vars, nr_flt_vars; /* dito (both to 0) */ init_reg_man() { worst_reg_pri = worst_flt_pri = (unsigned)-1/2; nr_reg_vars = nr_flt_vars = 0; } static reg_t my_alloc_reg(pri,loc) int pri, *loc; { reg_t S1; int i; if ((S1 = alloc_reg_var()) == NULL) if (current_reg_mes[RM_COUNT] > worst_reg_pri) { for (i = 0; i < nr_reg_vars; i++) if (reg_dat[i].pri <= worst_reg_pri) { *loc = i; S1 = reg_dat[i].reg; break; } worst_reg_pri = (unsigned)-1/2; for (i = 0; i < nr_reg_vars; i++) if (reg_dat[i].pri <= worst_reg_pri) worst_reg_pri = reg_dat[i].pri; } else return NULL; /* SORRY, FULL HOUSE! */ else *loc = nr_reg_vars++; return S1; } static reg_t my_alloc_double(pri,loc,r2) int pri, *loc; reg_t *r2; /* implementation note: my_alloc_double only reclaims other doubles * when a better candidate is given. It never reclaims floats, even if * the current double is a mich better candidate. */ { reg_t S1; int i; if ((S1 = alloc_double_var(r2)) == NULL) if (current_reg_mes[RM_COUNT] > worst_flt_pri) { for (i = 0; i < nr_flt_vars; i++) if (flt_dat[i].pri <= worst_flt_pri && flt_dat[i].size == EM_DSIZE) { *loc = i; S1 = flt_dat[i].reg; *r2 = flt_dat[i].reg2; break; } worst_flt_pri = (unsigned)-1/2; for (i = 0; i < nr_flt_vars; i++) if (flt_dat[i].pri < worst_flt_pri) worst_flt_pri = flt_dat[i].pri; } else return NULL; /* SORRY, FULL HOUSE! */ else *loc = nr_flt_vars++; return S1; } static reg_t my_alloc_float(pri,loc) int pri, *loc; /* just as for my_alloc_double, my_alloc_float never reclaims a double, * even though this me be useful and easy. Sorry. */ { reg_t S1; int i; if ((S1 = alloc_float_var()) == NULL) if (current_reg_mes[RM_COUNT] > worst_flt_pri) { for (i = 0; i < nr_flt_vars; i++) if (flt_dat[i].pri <= worst_flt_pri && flt_dat[i].size == EM_WSIZE) { *loc = i; S1 = flt_dat[i].reg; break; } worst_flt_pri = (unsigned)-1/2; for (i = 0; i < nr_flt_vars; i++) if (flt_dat[i].pri <= worst_flt_pri) worst_flt_pri = flt_dat[i].pri; } else return NULL; /* SORRY, FULL HOUSE! */ else *loc = nr_flt_vars++; return S1; } free_all_reg_vars() { int i; for (i = 0; i < nr_reg_vars; i++) free_reg(reg_dat[i].reg); for (i = 0; i < nr_flt_vars; i++) switch (flt_dat[i].size) { case EM_WSIZE: free_reg(flt_dat[i].reg); break; case EM_DSIZE: free_double_reg(flt_dat[i].reg); break; } check_cache(); } alloc_all_reg_vars() { int i; for (i = 0; i < nr_reg_vars; i++) forced_alloc_reg(reg_dat[i].reg); for (i = 0; i < nr_flt_vars; i++) switch (flt_dat[i].size) { case EM_WSIZE: forced_alloc_reg(flt_dat[i].reg); break; case EM_DSIZE: forced_alloc_reg(flt_dat[i].reg); forced_alloc_reg(flt_dat[i].reg2); break; } check_cache(); } static params_to_regs() /* copy required parameters to registers */ { int i, j; for (i = 0; i < nr_flt_vars; i++) if (flt_dat[i].offset >= 4092) { fprint(codefile, "set %d, %%l2\n", flt_dat[i].offset); fprint(codefile, "ld [%%l1+%%l2], %s\n", flt_dat[i].reg); if (flt_dat[i].size == EM_DSIZE) { fprint(codefile, "set %d, %%l2\n", flt_dat[i].offset+4); fprint(codefile, "ld [%%l1+%%l2], %s\n", flt_dat[i].reg2); } } else if (flt_dat[i].offset > 0) { fprint(codefile, "ld [%%l1+%d], %s\n", flt_dat[i].offset, flt_dat[i].reg); if (flt_dat[i].size == EM_DSIZE) fprint(codefile, "ld [%%l1+%d], %s\n", flt_dat[i].offset + 4, flt_dat[i].reg2); } for (i = 0; i < nr_reg_vars; i++) if (reg_dat[i].offset >= 4096) { fprint(codefile, "set %d, %s\n", reg_dat[i].offset, reg_dat[i].reg); fprint(codefile, "ld [%%l1+%s], %s\n", reg_dat[i].reg, reg_dat[i].reg); } else if (reg_dat[i].offset > 0) fprint(codefile, "ld [%%l1+%d], %s\n", reg_dat[i].offset, reg_dat[i].reg); } static cmp_flt_dat(e1, e2) reg_info *e1, *e2; { return (e1->offset - e2->offset); } static save_float_regs() { int i; int offset; qsort(flt_dat, nr_flt_vars, sizeof(flt_dat[0]), cmp_flt_dat); for (i = 0, offset= 0; i < nr_flt_vars; i++, offset += 8) if ((i+1 < nr_flt_vars && flt_dat[i].offset == flt_dat[i+1].offset-4 && flt_dat[i].size == EM_FSIZE && flt_dat[i+1].size == EM_FSIZE) || (flt_dat[i].size == EM_DSIZE)) { fprint(codefile, "std %s, [%%fp + %d]\n", flt_dat[i].reg, FLTSAV_OFFSET + offset); if (flt_dat[i].size != EM_DSIZE) ++i; } else fprint(codefile, "st %s, [%%fp + %d]\n", flt_dat[i].reg, FLTSAV_OFFSET + offset); } load_float_regs() { int i; int offset; for (i = 0, offset= 0; i < nr_flt_vars; i++, offset += 8) if ((i+1 < nr_flt_vars && flt_dat[i].offset == flt_dat[i+1].offset-4 && flt_dat[i].size == EM_FSIZE && flt_dat[i+1].size == EM_FSIZE) || (flt_dat[i].size == EM_DSIZE)) { fprint(codefile, "ldd [%%fp + %d], %s\n", FLTSAV_OFFSET + offset, flt_dat[i].reg); if (flt_dat[i].size != EM_DSIZE) ++i; } else fprint(codefile, "ld [%%fp + %d], %s\n", FLTSAV_OFFSET + offset, flt_dat[i].reg); } void C_mes_begin( ms) int ms; { #ifdef __solaris__ static int inits; #endif reg_mes_nr = 0; in_reg_mes = (ms == ms_reg); if (ms == ms_gto) { free_all_reg_vars(); nr_reg_vars = 0; nr_flt_vars = 0; fprint(codefile, "ta 3\n"); } db_mes = (ms == ms_stb || ms == ms_std) ? ms : 0; #ifdef __solaris__ if (db_mes && ! inits) { fprint(codefile, ".pushsection \".text\"\nBtext.text:\n.popsection\n"); fprint(codefile, ".pushsection \".data\"\nBdata.data:\n.popsection\n"); fprint(codefile, ".pushsection \".bss\"\nBbss.bss:\n.popsection\n"); inits = 1; } #endif } static dump_reg_tabs(); #ifdef __solaris__ extern char *B_procnam; #endif void C_mes_end() { int pos; reg_t S1, S2; if (db_mes) { db_nul = 0; #ifdef __solaris__ if (db_mes == ms_std) { if (db_str == 2) { fprint(codefile, ",1f\n1:\n"); } else { fprint(codefile, ",1f-%s\n1:\n", B_procnam); } } #else if (db_mes == ms_std && db_str == 2) fprint(codefile,",1f\n1:\n"); #endif else fprint(codefile, "\n"); db_str = 0; db_mes = 0; db_kind = 0; } if (!in_reg_mes) /* end of some other mes */ return; if (reg_mes_nr == 0) { /* end of reg_mes's */ save_float_regs(); params_to_regs(); if (debug) dump_reg_tabs(codefile); return; } if (current_reg_mes[RM_COUNT] == 0) /* never used, so ignore */ return; if (current_reg_mes[RM_OFFSET] >= 0) current_reg_mes[RM_OFFSET] += EM_BSIZE; if (debug) fprint(codefile, "\t\t! Got reg_mes: %d %d %d %d\n", current_reg_mes[0], current_reg_mes[1], current_reg_mes[2], current_reg_mes[3]); if (current_reg_mes[RM_TYPE] == reg_float) { switch(current_reg_mes[RM_SIZE]) { case EM_WSIZE : if ((S1 = my_alloc_float(current_reg_mes[RM_COUNT], &pos)) == NULL) return; break; case EM_DSIZE: if ((S1 = my_alloc_double(current_reg_mes[RM_COUNT], &pos, &S2)) == NULL) return; flt_dat[pos].reg2 = S2; default: break; } flt_dat[pos].offset = current_reg_mes[RM_OFFSET]; flt_dat[pos].size = current_reg_mes[RM_SIZE]; flt_dat[pos].pri = current_reg_mes[RM_COUNT]; flt_dat[pos].reg = S1; } else { if (current_reg_mes[RM_SIZE] != EM_WSIZE) return; /* IGNORE THESE */ if ((S1 = my_alloc_reg(current_reg_mes[RM_COUNT], &pos)) == NULL) return; /* SORRY, FULL HOUSE! */ reg_dat[pos].offset = current_reg_mes[RM_OFFSET]; reg_dat[pos].size = current_reg_mes[RM_SIZE]; reg_dat[pos].pri = current_reg_mes[RM_COUNT]; reg_dat[pos].reg = S1; } } extern int __gdb_flag; void C_cst( l) arith l; { static int correct_offset; if (db_mes) { if (! db_kind) db_kind = l; if (! db_str) { switchseg( SEGTXT); if (l == N_SLINE && ! __gdb_flag) { flush_cache(); #ifdef __solaris__ fprint(codefile, "call $__uX_LiB\nnop\n"); #else fprint(codefile, "call ___uX_LiB\nnop\n"); #endif } #ifdef __solaris__ fprint(codefile, ".stabn 0x%lx,0", (long) l); #else if (db_mes == ms_std) { fprint(codefile, ".stabd 0x%lx,0", (long) l); } else fprint(codefile, ".stabn 0x%lx,0", (long) l); #endif db_str = 1; db_nul = 1; } else { if (correct_offset++ == -1) { l += EM_BSIZE; } fprint(codefile, ",0x%lx", (long) l); } if (! db_nul) { correct_offset = 0; if (l == N_PSYM && __gdb_flag) { correct_offset = -2; } fprint(codefile, ",0"); db_nul = 1; } } if (in_reg_mes) current_reg_mes[reg_mes_nr++] = l; } void C_scon(s, l) register char *s; register arith l; { if (db_mes) { fprint(codefile, ".stabs \""); while (--l) { register int c = *s++; if (isprint(c) && c != '"' && c != '\\') fprint(codefile, "%c", c); else fprint(codefile, "\\%03o", c); } fprint(codefile, "\""); db_str = 2; } } void C_dlb(l, off) label l; arith off; { if (db_mes) { fprint(codefile,","); fprint(codefile, DLB_FMT, (long) l); if (off) fprint(codefile,"+%ld", (long) off); #ifdef __solaris__ switch(db_kind) { case N_LCSYM: fprint(codefile, "-Bbss.bss"); break; case N_STSYM: fprint(codefile, "-Bdata.data"); break; } #endif } } void C_dnam(l, off) char *l; arith off; { if (db_mes) { fprint(codefile,","); fprint(codefile, DNAM_FMT, l); if (off) fprint(codefile,"+%ld", (long) off); #ifdef __solaris__ switch(db_kind) { case N_LCSYM: fprint(codefile, "-Bbss.bss"); break; case N_STSYM: fprint(codefile, "-Bdata.data"); break; } #endif } } extern int B_procno; void C_ilb(l) label l; { if (db_mes) { fprint(codefile,","); fprint(codefile, ILB_FMT, B_procno, (long)l); #ifdef __solaris__ fprint(codefile, "-Btext.text"); #endif } } void C_pnam(s) char *s; { if (db_mes) { fprint(codefile,","); fprint(codefile, NAME_FMT, s); #ifdef __solaris__ fprint(codefile, "-Btext.text"); #endif } } static dump_reg_tabs(stream) FILE *stream; { int i; fprint(stream, "!offset\tsize\tname (%d regvars)\n", nr_reg_vars); for (i = 0; i < nr_reg_vars; i++) fprint(stream, "! %d\t%d\t%s\n", reg_dat[i].offset, reg_dat[i].size, reg_dat[i].reg); fprint(stream, "!offset\tsize\tname (%d fltvars)\n", nr_flt_vars); for (i = 0; i < nr_flt_vars; i++) fprint(stream, "! %d\t%d\t%s\n", flt_dat[i].offset, flt_dat[i].size, flt_dat[i].reg); } reg_t find_local(offset, reg2) /* WARNING: no size checking here! */ int offset; reg_t *reg2; { int i; if (reg2) *reg2 = NULL; for (i = 0; i < nr_reg_vars; i++) if (reg_dat[i].offset == offset) return reg_dat[i].reg; for (i = 0; i < nr_flt_vars; i++) if (flt_dat[i].offset == offset) { if (flt_dat[i].size == EM_DSIZE) if (reg2) *reg2 = flt_dat[i].reg2; return flt_dat[i].reg; } return NULL; }