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view lwasm/insn_gen.c @ 362:d149e2b56981
Silence tautological comparison warnings
Because "char" may be signed or unsigned depending on the system, comparing
for byte values 128...255 has to be forced as an unsigned comparison to be
portable and clear. Modify two such comparisons in the symbol handling code
to treat the symbol offset as a pointer to unsigned. This quiets
tautological comparison warnings on systems with an 8 bit signed type as the
default char type.
| author | William Astle <lost@l-w.ca> |
|---|---|
| date | Tue, 26 May 2015 23:42:00 -0600 |
| parents | 3afb809c7add |
| children | 433dbc18fb41 |
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/* insn_gen.c, Copyright © 2009 William Astle This file is part of LWASM. LWASM is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see <http://www.gnu.org/licenses/>. Contains code for parsing general addressing modes (IMM+DIR+EXT+IND) */ #include <ctype.h> #include <stdlib.h> #include <lw_expr.h> #include "lwasm.h" #include "instab.h" extern void insn_indexed_parse_aux(asmstate_t *as, line_t *l, char **p); extern void insn_indexed_resolve_aux(asmstate_t *as, line_t *l, int force, int elen); extern void insn_indexed_emit_aux(asmstate_t *as, line_t *l); extern void insn_parse_indexed_aux(asmstate_t *as, line_t *l, char **p); extern void insn_resolve_indexed_aux(asmstate_t *as, line_t *l, int force, int elen); // "extra" is required due to the way OIM, EIM, TIM, and AIM work void insn_parse_gen_aux(asmstate_t *as, line_t *l, char **p, int elen) { const char *optr2; int v1, tv; lw_expr_t s; if (!**p) { lwasm_register_error(as, l, "Bad operand"); return; } optr2 = *p; while (*optr2 && !isspace(*optr2) && *optr2 != ',') optr2++ /* do nothing */ ; if (*optr2 == ',' || **p == '[') { l -> lint = -1; l -> lint2 = 1; insn_parse_indexed_aux(as, l, p); l -> minlen = OPLEN(instab[l -> insn].ops[1]) + 1 + elen; l -> maxlen = OPLEN(instab[l -> insn].ops[1]) + 3 + elen; goto out; } if (**p == '<') { (*p)++; l -> lint2 = 0; } // for compatibility with asxxxx // * followed by a digit, alpha, or _, or ., or ?, or another * is "f8" else if (**p == '*') { tv = *(*p + 1); if (isdigit(tv) || isalpha(tv) || tv == '_' || tv == '.' || tv == '?' || tv == '@' || tv == '*' || tv == '+' || tv == '-') { l -> lint2 = 0; (*p)++; } } else if (**p == '>') { (*p)++; l -> lint2 = 2; } else { l -> lint2 = -1; } l -> minlen = OPLEN(instab[l -> insn].ops[0]) + 1 + elen; l -> maxlen = OPLEN(instab[l -> insn].ops[2]) + 2 + elen; s = lwasm_parse_expr(as, p); if (!s) { lwasm_register_error(as, l, "Bad operand"); return; } lwasm_save_expr(l, 0, s); if (as -> output_format == OUTPUT_OBJ && l -> lint2 == -1) { l -> lint2 = 2; goto out; } if (l -> lint2 != -1) goto out; // if we have a constant now, figure out dp vs nondp if (lw_expr_istype(s, lw_expr_type_int)) { v1 = lw_expr_intval(s); if (((v1 >> 8) & 0xff) == (l -> dpval & 0xff)) { l -> lint2 = 0; goto out; } l -> lint2 = 2; } else { int min; int max; if (lwasm_calculate_range(as, s, &min, &max) == 0) { // fprintf(stderr, "range (P) %d...%d for %s\n", min, max, lw_expr_print(s)); if (min > max) { // we don't know what to do in this case so don't do anything goto out; } min = (min >> 8) & 0xff; max = (max >> 8) & 0xff; if ((l -> dpval & 0xff) < min || (l -> dpval & 0xff) > max) { l -> lint2 = 2; goto out; } if (min == max && (l -> dpval & 0xff) == min) { l -> lint2 = 0; goto out; } // if here, we don't know if the value is in the DP or not { l -> lint2 = -1; goto out; } } } out: if (l -> lint2 != -1) { if (l -> lint2 == 0) { l -> len = OPLEN(instab[l -> insn].ops[0]) + 1 + elen; } else if (l -> lint2 == 2) { l -> len = OPLEN(instab[l -> insn].ops[2]) + 2 + elen; } else if (l -> lint2 == 1 && l -> lint != -1) { l -> len = OPLEN(instab[l -> insn].ops[1]) + l -> lint + 1 + elen; } } } void insn_resolve_gen_aux(asmstate_t *as, line_t *l, int force, int elen) { lw_expr_t e; if (l -> lint2 == 1) { // indexed insn_resolve_indexed_aux(as, l, force, elen); goto out; } if (l -> lint2 != -1) return; e = lwasm_fetch_expr(l, 0); lwasm_reduce_expr(as, e); if (lw_expr_istype(e, lw_expr_type_int)) { int v; v = lw_expr_intval(e); if (((v >> 8) & 0xff) == (l -> dpval & 0xff)) { l -> lint2 = 0; goto out; } l -> lint2 = 2; goto out; } else { int min; int max; if (lwasm_calculate_range(as, e, &min, &max) == 0) { // fprintf(stderr, "range (R) %d...%d for %s\n", min, max, lw_expr_print(e)); if (min > max) { // we don't know what to do in this case so don't do anything goto out; } min = (min >> 8) & 0xff; max = (max >> 8) & 0xff; if ((l -> dpval & 0xff) < min || (l -> dpval & 0xff) > max) { l -> lint2 = 2; goto out; } if (min == max && (l -> dpval & 0xff) == min) { l -> lint2 = 0; goto out; } // if here, we don't know if the value is in the DP or not { l -> lint2 = -1; goto out; } } } if (force) { l -> lint2 = 2; } out: if (l -> lint2 != -1) { if (l -> lint2 == 0) { l -> len = OPLEN(instab[l -> insn].ops[0]) + 1 + elen; } else if (l -> lint2 == 2) { l -> len = OPLEN(instab[l -> insn].ops[2]) + 2 + elen; } else if (l -> lint2 == 1 && l -> lint != -1) { l -> len = OPLEN(instab[l -> insn].ops[1]) + l -> lint + 1 + elen; } } } void insn_emit_gen_aux(asmstate_t *as, line_t *l, int extra) { lw_expr_t e; e = lwasm_fetch_expr(l, 0); lwasm_emitop(l, instab[l -> insn].ops[l -> lint2]); if (extra != -1) lwasm_emit(l, extra); if (l -> lint2 == 1) { lwasm_emit(l, l -> pb); if (l -> lint > 0) { int i; i = lw_expr_intval(e); if (l -> lint == 1) { if (i < -128 || i > 127) lwasm_register_error(as, l, "Byte overflow"); } lwasm_emitexpr(l, e, l -> lint); } return; } if (l -> lint2 == 2) lwasm_emitexpr(l, e, 2); else lwasm_emitexpr(l, e, 1); } // the various insn_gen? functions have an immediate mode of ? bits PARSEFUNC(insn_parse_gen0) { if (**p == '#') { lwasm_register_error(as, l, "Immediate mode not allowed"); return; } // handle non-immediate insn_parse_gen_aux(as, l, p, 0); } RESOLVEFUNC(insn_resolve_gen0) { if (l -> len != -1) return; // handle non-immediate insn_resolve_gen_aux(as, l, force, 0); } EMITFUNC(insn_emit_gen0) { insn_emit_gen_aux(as, l, -1); } PARSEFUNC(insn_parse_gen8) { if (**p == '#') { lw_expr_t e; (*p)++; e = lwasm_parse_expr(as, p); if (!e) { lwasm_register_error(as, l, "Bad operand"); return; } l -> len = OPLEN(instab[l -> insn].ops[3]) + 1; l -> lint2 = 3; lwasm_save_expr(l, 0, e); return; } // handle non-immediate insn_parse_gen_aux(as, l, p, 0); if (l -> lint2 != -1) { if (l -> lint2 == 0) { l -> len = OPLEN(instab[l -> insn].ops[0]) + 1; } else if (l -> lint2 == 2) { l -> len = OPLEN(instab[l -> insn].ops[2]) + 2; } else if (l -> lint2 == 1 && l -> lint != -1) { l -> len = OPLEN(instab[l -> insn].ops[1]) + l -> lint + 1; } } } RESOLVEFUNC(insn_resolve_gen8) { if (l -> len != -1) return; // handle non-immediate insn_resolve_gen_aux(as, l, force, 0); } EMITFUNC(insn_emit_gen8) { if (l -> lint2 == 3) { lw_expr_t e; e = lwasm_fetch_expr(l, 0); if (lw_expr_istype(e, lw_expr_type_int)) { int i; i = lw_expr_intval(e); if (i < -128 || i > 255) { lwasm_register_error(as, l, "Byte overflow"); } } lwasm_emitop(l, instab[l -> insn].ops[3]); lwasm_emitexpr(l, e, 1); return; } insn_emit_gen_aux(as, l, -1); } PARSEFUNC(insn_parse_gen16) { if (**p == '#') { lw_expr_t e; (*p)++; e = lwasm_parse_expr(as, p); if (!e) { lwasm_register_error(as, l, "Bad operand"); return; } l -> len = OPLEN(instab[l -> insn].ops[3]) + 2; l -> lint2 = 3; lwasm_save_expr(l, 0, e); return; } // handle non-immediate insn_parse_gen_aux(as, l, p, 0); if (l -> lint2 != -1) { if (l -> lint2 == 0) { l -> len = OPLEN(instab[l -> insn].ops[0]) + 1; } else if (l -> lint2 == 2) { l -> len = OPLEN(instab[l -> insn].ops[2]) + 2; } else if (l -> lint2 == 1 && l -> lint != -1) { l -> len = OPLEN(instab[l -> insn].ops[1]) + l -> lint + 1; } } } RESOLVEFUNC(insn_resolve_gen16) { if (l -> len != -1) return; // handle non-immediate insn_resolve_gen_aux(as, l, force, 0); } EMITFUNC(insn_emit_gen16) { if (l -> lint2 == 3) { lw_expr_t e; e = lwasm_fetch_expr(l, 0); lwasm_emitop(l, instab[l -> insn].ops[3]); lwasm_emitexpr(l, e, 2); return; } insn_emit_gen_aux(as, l, -1); } PARSEFUNC(insn_parse_gen32) { if (**p == '#') { lw_expr_t e; (*p)++; e = lwasm_parse_expr(as, p); if (!e) { lwasm_register_error(as, l, "Bad operand"); return; } l -> len = OPLEN(instab[l -> insn].ops[3]) + 4; l -> lint2 = 3; lwasm_save_expr(l, 0, e); return; } // handle non-immediate insn_parse_gen_aux(as, l, p, 0); if (l -> lint2 != -1) { if (l -> lint2 == 0) { l -> len = OPLEN(instab[l -> insn].ops[0]) + 1; } else if (l -> lint2 == 2) { l -> len = OPLEN(instab[l -> insn].ops[2]) + 2; } else if (l -> lint2 == 1 && l -> lint != -1) { l -> len = OPLEN(instab[l -> insn].ops[1]) + l -> lint + 1; } } } RESOLVEFUNC(insn_resolve_gen32) { if (l -> len != -1) return; // handle non-immediate insn_resolve_gen_aux(as, l, force, 0); } EMITFUNC(insn_emit_gen32) { if (l -> lint2 == 3) { lw_expr_t e; e = lwasm_fetch_expr(l, 0); lwasm_emitop(l, instab[l -> insn].ops[3]); lwasm_emitexpr(l, e, 4); return; } insn_emit_gen_aux(as, l, -1); } PARSEFUNC(insn_parse_imm8) { lw_expr_t e; if (**p == '#') { (*p)++; e = lwasm_parse_expr(as, p); if (!e) { lwasm_register_error(as, l, "Bad operand"); return; } l -> len = OPLEN(instab[l -> insn].ops[0]) + 1; lwasm_save_expr(l, 0, e); } else { lwasm_register_error(as, l, "Bad operand"); } } EMITFUNC(insn_emit_imm8) { lw_expr_t e; lwasm_emitop(l, instab[l -> insn].ops[0]); e = lwasm_fetch_expr(l, 0); if (lw_expr_istype(e, lw_expr_type_int)) { int i; i = lw_expr_intval(e); if (i < -128 || i > 255) { lwasm_register_error(as, l, "Byte overflow"); } } lwasm_emitexpr(l, e, 1); }