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C/C++ Source or Header | 1994-03-14 | 22.2 KB | 789 lines

/* Bytecode conversion definitions for GNU C-compiler. Copyright (C) 1993, 1994 Free Software Foundation, Inc. This file is part of GNU CC. GNU CC 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 2, or (at your option) any later version. GNU CC 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 GNU CC; see the file COPYING. If not, write to the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "config.h" #include "tree.h" #include "rtl.h" #include "machmode.h" #include "obstack.h" #include "bytecode.h" #include "bc-typecd.h" #include "bc-opcode.h" #include "bc-optab.h" #define obstack_chunk_alloc xmalloc #define obstack_chunk_free free extern char *xmalloc (); extern void free (); /* Table relating interpreter typecodes to machine modes. */ #define GET_TYPECODE_MODE(CODE) (typecode_mode[((int) CODE)]) enum machine_mode typecode_mode[] = { #define DEFTYPECODE(CODE, NAME, MODE, TYPE) MODE, #include "bc-typecd.def" #undef DEFTYPECODE }; /* Machine mode to type code map */ static enum typecode signed_mode_to_code_map[MAX_MACHINE_MODE+1]; static enum typecode unsigned_mode_to_code_map[MAX_MACHINE_MODE+1]; #define GET_TYPECODE_SIZE(CODE) GET_MODE_SIZE (GET_TYPECODE_MODE (CODE)) #define BIG_ARBITRARY_NUMBER 100000 /* Table of recipes for conversions among scalar types, to be filled in as needed at run time. */ static struct conversion_recipe { unsigned char *opcodes; /* Bytecodes to emit in order. */ int nopcodes; /* Count of bytecodes. */ int cost; /* A rather arbitrary cost function. */ } conversion_recipe[NUM_TYPECODES][NUM_TYPECODES]; /* Binary operator tables. */ struct binary_operator optab_plus_expr[] = { { addSI, SIcode, SIcode, SIcode }, { addDI, DIcode, DIcode, DIcode }, { addSF, SFcode, SFcode, SFcode }, { addDF, DFcode, DFcode, DFcode }, { addXF, XFcode, XFcode, XFcode }, { addPSI, Pcode, Pcode, SIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_minus_expr[] = { { subSI, SIcode, SIcode, SIcode }, { subDI, DIcode, DIcode, DIcode }, { subSF, SFcode, SFcode, SFcode }, { subDF, DFcode, DFcode, DFcode }, { subXF, XFcode, XFcode, XFcode }, { subPP, SIcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; /* The ordering of the tables for multiplicative operators is such that unsigned operations will be preferred to signed operations when one argument is unsigned. */ struct binary_operator optab_mult_expr[] = { { mulSU, SUcode, SUcode, SUcode }, { mulDU, DUcode, DUcode, DUcode }, { mulSI, SIcode, SIcode, SIcode }, { mulDI, DIcode, DIcode, DIcode }, { mulSF, SFcode, SFcode, SFcode }, { mulDF, DFcode, DFcode, DFcode }, { mulXF, XFcode, XFcode, XFcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_trunc_div_expr[] = { { divSU, SUcode, SUcode, SUcode }, { divDU, DUcode, DUcode, DUcode }, { divSI, SIcode, SIcode, SIcode }, { divDI, DIcode, DIcode, DIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_trunc_mod_expr[] = { { modSU, SUcode, SUcode, SUcode }, { modDU, DUcode, DUcode, DUcode }, { modSI, SIcode, SIcode, SIcode }, { modDI, DIcode, DIcode, DIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_rdiv_expr[] = { { divSF, SFcode, SFcode, SFcode }, { divDF, DFcode, DFcode, DFcode }, { divXF, XFcode, XFcode, XFcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_bit_and_expr[] = { { andSI, SIcode, SIcode, SIcode }, { andDI, DIcode, DIcode, DIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_bit_ior_expr[] = { { iorSI, SIcode, SIcode, SIcode }, { iorDI, DIcode, DIcode, DIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_bit_xor_expr[] = { { xorSI, SIcode, SIcode, SIcode }, { xorDI, DIcode, DIcode, DIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_lshift_expr[] = { { lshiftSI, SIcode, SIcode, SIcode }, { lshiftSU, SUcode, SUcode, SIcode }, { lshiftDI, DIcode, DIcode, SIcode }, { lshiftDU, DUcode, DUcode, SIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_rshift_expr[] = { { rshiftSI, SIcode, SIcode, SIcode }, { rshiftSU, SUcode, SUcode, SIcode }, { rshiftDI, DIcode, DIcode, SIcode }, { rshiftDU, DUcode, DUcode, SIcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_truth_and_expr[] = { { andSI, SIcode, Tcode, Tcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_truth_or_expr[] = { { iorSI, SIcode, Tcode, Tcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_lt_expr[] = { { ltSI, Tcode, SIcode, SIcode }, { ltSU, Tcode, SUcode, SUcode }, { ltDI, Tcode, DIcode, DIcode }, { ltDU, Tcode, DUcode, DUcode }, { ltSF, Tcode, SFcode, SFcode }, { ltDF, Tcode, DFcode, DFcode }, { ltXF, Tcode, XFcode, XFcode }, { ltP, Tcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_le_expr[] = { { leSI, Tcode, SIcode, SIcode }, { leSU, Tcode, SUcode, SUcode }, { leDI, Tcode, DIcode, DIcode }, { leDU, Tcode, DUcode, DUcode }, { leSF, Tcode, SFcode, SFcode }, { leDF, Tcode, DFcode, DFcode }, { leXF, Tcode, XFcode, XFcode }, { leP, Tcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_ge_expr[] = { { geSI, Tcode, SIcode, SIcode }, { geSU, Tcode, SUcode, SUcode }, { geDI, Tcode, DIcode, DIcode }, { geDU, Tcode, DUcode, DUcode }, { geSF, Tcode, SFcode, SFcode }, { geDF, Tcode, DFcode, DFcode }, { geXF, Tcode, XFcode, XFcode }, { geP, Tcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_gt_expr[] = { { gtSI, Tcode, SIcode, SIcode }, { gtSU, Tcode, SUcode, SUcode }, { gtDI, Tcode, DIcode, DIcode }, { gtDU, Tcode, DUcode, DUcode }, { gtSF, Tcode, SFcode, SFcode }, { gtDF, Tcode, DFcode, DFcode }, { gtXF, Tcode, XFcode, XFcode }, { gtP, Tcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_eq_expr[] = { { eqSI, Tcode, SIcode, SIcode }, { eqDI, Tcode, DIcode, DIcode }, { eqSF, Tcode, SFcode, SFcode }, { eqDF, Tcode, DFcode, DFcode }, { eqXF, Tcode, XFcode, XFcode }, { eqP, Tcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; struct binary_operator optab_ne_expr[] = { { neSI, Tcode, SIcode, SIcode }, { neDI, Tcode, DIcode, DIcode }, { neSF, Tcode, SFcode, SFcode }, { neDF, Tcode, DFcode, DFcode }, { neXF, Tcode, XFcode, XFcode }, { neP, Tcode, Pcode, Pcode }, { -1, -1, -1, -1 }, }; /* Unary operator tables. */ struct unary_operator optab_negate_expr[] = { { negSI, SIcode, SIcode }, { negDI, DIcode, DIcode }, { negSF, SFcode, SFcode }, { negDF, DFcode, DFcode }, { negXF, XFcode, XFcode }, { -1, -1, -1 }, }; struct unary_operator optab_bit_not_expr[] = { { notSI, SIcode, SIcode }, { notDI, DIcode, DIcode }, { -1, -1, -1 }, }; struct unary_operator optab_truth_not_expr[] = { { notT, SIcode, SIcode }, { -1, -1, -1 }, }; /* Increment operator tables. */ struct increment_operator optab_predecrement_expr[] = { { predecQI, QIcode }, { predecQI, QUcode }, { predecHI, HIcode }, { predecHI, HUcode }, { predecSI, SIcode }, { predecSI, SUcode }, { predecDI, DIcode }, { predecDI, DUcode }, { predecP, Pcode }, { predecSF, SFcode }, { predecDF, DFcode }, { predecXF, XFcode }, { -1, -1 }, }; struct increment_operator optab_preincrement_expr[] = { { preincQI, QIcode }, { preincQI, QUcode }, { preincHI, HIcode }, { preincHI, HUcode }, { preincSI, SIcode }, { preincSI, SUcode }, { preincDI, DIcode }, { preincDI, DUcode }, { preincP, Pcode }, { preincSF, SFcode }, { preincDF, DFcode }, { preincXF, XFcode }, { -1, -1 }, }; struct increment_operator optab_postdecrement_expr[] = { { postdecQI, QIcode }, { postdecQI, QUcode }, { postdecHI, HIcode }, { postdecHI, HUcode }, { postdecSI, SIcode }, { postdecSI, SUcode }, { postdecDI, DIcode }, { postdecDI, DUcode }, { postdecP, Pcode }, { postdecSF, SFcode }, { postdecDF, DFcode }, { postdecXF, XFcode }, { -1, -1 }, }; struct increment_operator optab_postincrement_expr[] = { { postincQI, QIcode }, { postincQI, QUcode }, { postincHI, HIcode }, { postincHI, HUcode }, { postincSI, SIcode }, { postincSI, SUcode }, { postincDI, DIcode }, { postincDI, DUcode }, { postincP, Pcode }, { postincSF, SFcode }, { postincDF, DFcode }, { postincXF, XFcode }, { -1, -1 }, }; /* Table of conversions supported by the interpreter. */ static struct conversion_info { enum bytecode_opcode opcode; /* here indicates the conversion needs no opcode. */ enum typecode from; enum typecode to; int cost; /* 1 for no-op conversions, 2 for widening conversions, 4 for int/float conversions, 8 for narrowing conversions. */ } conversion_info[] = { { -1, QIcode, QUcode, 1 }, { -1, HIcode, HUcode, 1 }, { -1, SIcode, SUcode, 1 }, { -1, DIcode, DUcode, 1 }, { -1, QUcode, QIcode, 1 }, { -1, HUcode, HIcode, 1 }, { -1, SUcode, SIcode, 1 }, { -1, DUcode, DIcode, 1 }, { -1, Tcode, SIcode, 1 }, { convertQIHI, QIcode, HIcode, 2 }, { convertQUHU, QUcode, HUcode, 2 }, { convertQUSU, QUcode, SUcode, 2 }, { convertHISI, HIcode, SIcode, 2 }, { convertHUSU, HUcode, SUcode, 2 }, { convertSIDI, SIcode, DIcode, 2 }, { convertSUDU, SUcode, DUcode, 2 }, { convertSFDF, SFcode, DFcode, 2 }, { convertDFXF, DFcode, XFcode, 2 }, { convertHIQI, HIcode, QIcode, 8 }, { convertSIQI, SIcode, QIcode, 8 }, { convertSIHI, SIcode, HIcode, 8 }, { convertSUQU, SUcode, QUcode, 8 }, { convertDISI, DIcode, SIcode, 8 }, { convertDFSF, DFcode, SFcode, 8 }, { convertXFDF, XFcode, DFcode, 8 }, { convertPSI, Pcode, SIcode, 2 }, { convertSIP, SIcode, Pcode, 2 }, { convertSIT, SIcode, Tcode, 2 }, { convertDIT, DIcode, Tcode, 2 }, { convertSFT, SFcode, Tcode, 2 }, { convertDFT, DFcode, Tcode, 2 }, { convertXFT, XFcode, Tcode, 2 }, { convertQISI, QIcode, SIcode, 2 }, { convertPT, Pcode, Tcode, 2 }, { convertSISF, SIcode, SFcode, 4 }, { convertSIDF, SIcode, DFcode, 4 }, { convertSIXF, SIcode, XFcode, 4 }, { convertSUSF, SUcode, SFcode, 4 }, { convertSUDF, SUcode, DFcode, 4 }, { convertSUXF, SUcode, XFcode, 4 }, { convertDISF, DIcode, SFcode, 4 }, { convertDIDF, DIcode, DFcode, 4 }, { convertDIXF, DIcode, XFcode, 4 }, { convertDUSF, DUcode, SFcode, 4 }, { convertDUDF, DUcode, DFcode, 4 }, { convertDUXF, DUcode, XFcode, 4 }, { convertSFSI, SFcode, SIcode, 4 }, { convertDFSI, DFcode, SIcode, 4 }, { convertXFSI, XFcode, SIcode, 4 }, { convertSFSU, SFcode, SUcode, 4 }, { convertDFSU, DFcode, SUcode, 4 }, { convertXFSU, XFcode, SUcode, 4 }, { convertSFDI, SFcode, DIcode, 4 }, { convertDFDI, DFcode, DIcode, 4 }, { convertXFDI, XFcode, DIcode, 4 }, { convertSFDU, SFcode, DUcode, 4 }, { convertDFDU, DFcode, DUcode, 4 }, { convertXFDU, XFcode, DUcode, 4 }, { convertSIQI, SIcode, QIcode, 8 }, }; #define NUM_CONVERSIONS (sizeof conversion_info / sizeof (struct conversion_info)) /* List form of a conversion recipe. */ struct conversion_list { enum bytecode_opcode opcode; enum typecode to; int cost; struct conversion_list *prev; }; /* Determine if it is "reasonable" to add a given conversion to a given list of conversions. The following criteria define "reasonable" conversion lists: * No typecode appears more than once in the sequence (no loops). * At most one conversion from integer to float or vice versa is present. * Either sign extensions or zero extensions may be present, but not both. * No widening conversions occur after a signed/unsigned conversion. * The sequence of sizes must be strict nonincreasing or nondecreasing. */ static int conversion_reasonable_p (conversion, list) struct conversion_info *conversion; struct conversion_list *list; { struct conversion_list *curr; int curr_size, prev_size; int has_int_float, has_float_int; int has_sign_extend, has_zero_extend; int has_signed_unsigned, has_unsigned_signed; has_int_float = 0; has_float_int = 0; has_sign_extend = 0; has_zero_extend = 0; has_signed_unsigned = 0; has_unsigned_signed = 0; /* Make sure the destination typecode doesn't already appear in the list. */ for (curr = list; curr; curr = curr->prev) if (conversion->to == curr->to) return 0; /* Check for certain kinds of conversions. */ if (TYPECODE_INTEGER_P (conversion->from) && TYPECODE_FLOAT_P (conversion->to)) has_int_float = 1; if (TYPECODE_FLOAT_P (conversion->from) && TYPECODE_INTEGER_P (conversion->to)) has_float_int = 1; if (TYPECODE_SIGNED_P (conversion->from) && TYPECODE_SIGNED_P (conversion->to) && GET_TYPECODE_SIZE (conversion->from) < GET_TYPECODE_SIZE (conversion->to)) has_sign_extend = 1; if (TYPECODE_UNSIGNED_P (conversion->from) && TYPECODE_UNSIGNED_P (conversion->to) && GET_TYPECODE_SIZE (conversion->from) < GET_TYPECODE_SIZE (conversion->to)) has_zero_extend = 1; for (curr = list; curr && curr->prev; curr = curr->prev) { if (TYPECODE_INTEGER_P (curr->prev->to) && TYPECODE_FLOAT_P (curr->to)) has_int_float = 1; if (TYPECODE_FLOAT_P (curr->prev->to) && TYPECODE_INTEGER_P (curr->to)) has_float_int = 1; if (TYPECODE_SIGNED_P (curr->prev->to) && TYPECODE_SIGNED_P (curr->to) && GET_TYPECODE_SIZE (curr->prev->to) < GET_TYPECODE_SIZE (curr->to)) has_sign_extend = 1; if (TYPECODE_UNSIGNED_P (curr->prev->to) && TYPECODE_UNSIGNED_P (curr->to) && GET_TYPECODE_SIZE (curr->prev->to) < GET_TYPECODE_SIZE (curr->to)) has_zero_extend = 1; if (TYPECODE_SIGNED_P (curr->prev->to) && TYPECODE_UNSIGNED_P (curr->to)) has_signed_unsigned = 1; if (TYPECODE_UNSIGNED_P (curr->prev->to) && TYPECODE_SIGNED_P (curr->to)) has_unsigned_signed = 1; } if (TYPECODE_INTEGER_P (conversion->from) && TYPECODE_INTEGER_P (conversion->to) && GET_TYPECODE_SIZE (conversion->to) > GET_TYPECODE_SIZE (conversion->from) && (has_signed_unsigned || has_unsigned_signed)) return 0; if (has_float_int && has_int_float || has_sign_extend && has_zero_extend) return 0; /* Make sure the sequence of destination typecode sizes is strictly nondecreasing or strictly nonincreasing. */ prev_size = GET_TYPECODE_SIZE (conversion->to); for (curr = list; curr; curr = curr->prev) { curr_size = GET_TYPECODE_SIZE (curr->to); if (curr_size != prev_size) break; } if (!curr) return 1; if (curr_size < prev_size) for (prev_size = curr_size; curr; curr = curr->prev) { curr_size = GET_TYPECODE_SIZE (curr->to); if (curr_size > prev_size) return 0; prev_size = curr_size; } else for (prev_size = curr_size; curr; curr = curr->prev) { curr_size = GET_TYPECODE_SIZE (curr->to); if (curr_size < prev_size) return 0; prev_size = curr_size; } return 1; } /* Exhaustively search all reasonable conversions to find one to convert the given types. */ static struct conversion_recipe deduce_conversion (from, to) enum typecode from, to; { struct rl { struct conversion_list *list; struct rl *next; } *prev, curr, *good, *temp; struct conversion_list *conv, *best; int i, cost, bestcost; struct conversion_recipe result; struct obstack recipe_obstack; obstack_init (&recipe_obstack); curr.next = (struct rl *) obstack_alloc (&recipe_obstack, sizeof (struct rl)); curr.next->list = (struct conversion_list *) obstack_alloc (&recipe_obstack, sizeof (struct conversion_list)); curr.next->list->opcode = -1; curr.next->list->to = from; curr.next->list->cost = 0; curr.next->list->prev = 0; curr.next->next = 0; good = 0; while (curr.next) { /* Remove successful conversions from further consideration. */ for (prev = &curr; prev; prev = prev->next) if (prev->next && prev->next->list->to == to) { temp = prev->next->next; prev->next->next = good; good = prev->next; prev->next = temp; } /* Go through each of the pending conversion chains, trying all possible candidate conversions on them. */ for (prev = curr.next, curr.next = 0; prev; prev = prev->next) for (i = 0; i < NUM_CONVERSIONS; ++i) if (conversion_info[i].from == prev->list->to && conversion_reasonable_p (&conversion_info[i], prev->list)) { temp = (struct rl *) obstack_alloc (&recipe_obstack, sizeof (struct rl)); temp->list = (struct conversion_list *) obstack_alloc (&recipe_obstack, sizeof (struct conversion_list)); temp->list->opcode = conversion_info[i].opcode; temp->list->to = conversion_info[i].to; temp->list->cost = conversion_info[i].cost; temp->list->prev = prev->list; temp->next = curr.next; curr.next = temp; } } bestcost = BIG_ARBITRARY_NUMBER; best = 0; for (temp = good; temp; temp = temp->next) { for (conv = temp->list, cost = 0; conv; conv = conv->prev) cost += conv->cost; if (cost < bestcost) { bestcost = cost; best = temp->list; } } if (!best) abort (); for (i = 0, conv = best; conv; conv = conv->prev) if (conv->opcode != -1) ++i; result.opcodes = (unsigned char *) xmalloc (i); result.nopcodes = i; for (conv = best; conv; conv = conv->prev) if (conv->opcode != -1) result.opcodes[--i] = conv->opcode; result.cost = bestcost; obstack_free (&recipe_obstack, 0); return result; } #define DEDUCE_CONVERSION(FROM, TO) \ (conversion_recipe[(int) FROM][(int) TO].opcodes ? 0 \ : (conversion_recipe[(int) FROM][(int) TO] \ = deduce_conversion (FROM, TO), 0)) /* Emit a conversion between the given scalar types. */ void emit_typecode_conversion (from, to) enum typecode from, to; { int i; DEDUCE_CONVERSION (from, to); for (i = 0; i < conversion_recipe[(int) from][(int) to].nopcodes; ++i) bc_emit_instruction (conversion_recipe[(int) from][(int) to].opcodes[i]); } /* Initialize mode_to_code_map[] */ void bc_init_mode_to_code_map () { int mode; for (mode = 0; mode < MAX_MACHINE_MODE + 1; mode++) { signed_mode_to_code_map[mode] = unsigned_mode_to_code_map[mode] = LAST_AND_UNUSED_TYPECODE; } #define DEF_MODEMAP(SYM, CODE, UCODE, CONST, LOAD, STORE) \ { signed_mode_to_code_map[(int) SYM] = CODE; \ unsigned_mode_to_code_map[(int) SYM] = UCODE; } #include "modemap.def" #undef DEF_MODEMAP /* Initialize opcode maps for const, load, and store */ bc_init_mode_to_opcode_maps (); } /* Given a machine mode return the preferred typecode. */ enum typecode preferred_typecode (mode, unsignedp) enum machine_mode mode; int unsignedp; { enum typecode code = (unsignedp ? unsigned_mode_to_code_map : signed_mode_to_code_map) [MIN ((int) mode, (int) MAX_MACHINE_MODE)]; if (code == LAST_AND_UNUSED_TYPECODE) abort (); return code; } /* Expand a conversion between the given types. */ void bc_expand_conversion (from, to) tree from, to; { enum typecode fcode, tcode; fcode = preferred_typecode (TYPE_MODE (from), TREE_UNSIGNED (from)); tcode = preferred_typecode (TYPE_MODE (to), TREE_UNSIGNED (to)); emit_typecode_conversion (fcode, tcode); } /* Expand a conversion of the given type to a truth value. */ void bc_expand_truth_conversion (from) tree from; { enum typecode fcode; fcode = preferred_typecode (TYPE_MODE (from), TREE_UNSIGNED (from)); emit_typecode_conversion (fcode, Tcode); } /* Emit an appropriate binary operation. */ void bc_expand_binary_operation (optab, resulttype, arg0, arg1) struct binary_operator optab[]; tree resulttype, arg0, arg1; { int i, besti, cost, bestcost; enum typecode resultcode, arg0code, arg1code; resultcode = preferred_typecode (TYPE_MODE (resulttype), TREE_UNSIGNED (resulttype)); arg0code = preferred_typecode (TYPE_MODE (TREE_TYPE (arg0)), TREE_UNSIGNED (resulttype)); arg1code = preferred_typecode (TYPE_MODE (TREE_TYPE (arg1)), TREE_UNSIGNED (resulttype)); besti = -1; bestcost = BIG_ARBITRARY_NUMBER; for (i = 0; optab[i].opcode != -1; ++i) { cost = 0; DEDUCE_CONVERSION (arg0code, optab[i].arg0); cost += conversion_recipe[(int) arg0code][(int) optab[i].arg0].cost; DEDUCE_CONVERSION (arg1code, optab[i].arg1); cost += conversion_recipe[(int) arg1code][(int) optab[i].arg1].cost; if (cost < bestcost) { besti = i; bestcost = cost; } } if (besti == -1) abort (); expand_expr (arg1, 0, VOIDmode, 0); emit_typecode_conversion (arg1code, optab[besti].arg1); expand_expr (arg0, 0, VOIDmode, 0); emit_typecode_conversion (arg0code, optab[besti].arg0); bc_emit_instruction (optab[besti].opcode); emit_typecode_conversion (optab[besti].result, resultcode); } /* Emit an appropriate unary operation. */ void bc_expand_unary_operation (optab, resulttype, arg0) struct unary_operator optab[]; tree resulttype, arg0; { int i, besti, cost, bestcost; enum typecode resultcode, arg0code; resultcode = preferred_typecode (TYPE_MODE (resulttype), TREE_UNSIGNED (resulttype)); arg0code = preferred_typecode (TYPE_MODE (TREE_TYPE (arg0)), TREE_UNSIGNED (TREE_TYPE (arg0))); besti = -1; bestcost = BIG_ARBITRARY_NUMBER; for (i = 0; optab[i].opcode != -1; ++i) { DEDUCE_CONVERSION (arg0code, optab[i].arg0); cost = conversion_recipe[(int) arg0code][(int) optab[i].arg0].cost; if (cost < bestcost) { besti = i; bestcost = cost; } } if (besti == -1) abort (); expand_expr (arg0, 0, VOIDmode, 0); emit_typecode_conversion (arg0code, optab[besti].arg0); bc_emit_instruction (optab[besti].opcode); emit_typecode_conversion (optab[besti].result, resultcode); } /* Emit an appropriate increment. */ void bc_expand_increment (optab, type) struct increment_operator optab[]; tree type; { enum typecode code; int i; code = preferred_typecode (TYPE_MODE (type), TREE_UNSIGNED (type)); for (i = 0; (int) optab[i].opcode >= 0; ++i) if (code == optab[i].arg) { bc_emit_instruction (optab[i].opcode); return; } abort (); }