/* * builtin evaluation & expansion. * * Copyright (C) 2003 Transmeta Corp. * 2003-2004 Linus Torvalds * * Permission is hereby granted, free of charge, to any person obtaining a copy * of this software and associated documentation files (the "Software"), to deal * in the Software without restriction, including without limitation the rights * to use, copy, modify, merge, publish, distribute, sublicense, and/or sell * copies of the Software, and to permit persons to whom the Software is * furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN * THE SOFTWARE. */ #include "builtin.h" #include "expression.h" #include "evaluate.h" #include "expand.h" #include "symbol.h" #include "compat/bswap.h" #include #define dyntype incomplete_ctype static bool is_dynamic_type(struct symbol *t) { if (t->type == SYM_NODE) t = t->ctype.base_type; return t == &dyntype; } static int evaluate_to_int_const_expr(struct expression *expr) { expr->ctype = &int_ctype; expr->flags |= CEF_SET_ICE; return 1; } static int evaluate_pure_unop(struct expression *expr) { struct expression *arg = first_expression(expr->args); int flags = arg->flags; /* * Allow such functions with a constant integer expression * argument to be treated as a *constant* integer. * This allow us to use them in switch() { case ...: */ flags |= (flags & CEF_ICE) ? CEF_SET_INT : 0; expr->flags = flags; return 1; } /* * eval_args - check the number of arguments and evaluate them. */ static int eval_args(struct expression *expr, int n) { struct expression *arg; struct symbol *sym; const char *msg; int rc = 1; FOR_EACH_PTR(expr->args, arg) { if (n-- == 0) { msg = "too many arguments"; goto error; } if (!evaluate_expression(arg)) rc = 0; } END_FOR_EACH_PTR(arg); if (n > 0) { msg = "not enough arguments"; goto error; } return rc; error: sym = expr->fn->ctype; expression_error(expr, "%s for %s", msg, show_ident(sym->ident)); return 0; } static int args_prototype(struct expression *expr) { struct symbol *fntype = expr->fn->ctype->ctype.base_type; int n = symbol_list_size(fntype->arguments); return eval_args(expr, n); } static int args_triadic(struct expression *expr) { return eval_args(expr, 3); } static int evaluate_choose(struct expression *expr) { struct expression_list *list = expr->args; struct expression *arg, *args[3]; int n = 0; /* there will be exactly 3; we'd already verified that */ FOR_EACH_PTR(list, arg) { args[n++] = arg; } END_FOR_EACH_PTR(arg); *expr = get_expression_value(args[0]) ? *args[1] : *args[2]; return 1; } static int expand_expect(struct expression *expr, int cost) { struct expression *arg = first_ptr_list((struct ptr_list *) expr->args); if (arg) *expr = *arg; return 0; } /* * __builtin_warning() has type "int" and always returns 1, * so that you can use it in conditionals or whatever */ static int expand_warning(struct expression *expr, int cost) { struct expression *arg; struct expression_list *arglist = expr->args; FOR_EACH_PTR (arglist, arg) { /* * Constant strings get printed out as a warning. By the * time we get here, the EXPR_STRING has been fully * evaluated, so by now it's an anonymous symbol with a * string initializer. * * Just for the heck of it, allow any constant string * symbol. */ if (arg->type == EXPR_SYMBOL) { struct symbol *sym = arg->symbol; if (sym->initializer && sym->initializer->type == EXPR_STRING) { struct string *string = sym->initializer->string; warning(expr->pos, "%*s", string->length-1, string->data); } continue; } /* * Any other argument is a conditional. If it's * non-constant, or it is false, we exit and do * not print any warning. */ if (arg->type != EXPR_VALUE) goto out; if (!arg->value) goto out; } END_FOR_EACH_PTR(arg); out: expr->type = EXPR_VALUE; expr->value = 1; expr->taint = 0; return 0; } /* The arguments are constant if the cost of all of them is zero */ static int expand_constant_p(struct expression *expr, int cost) { expr->type = EXPR_VALUE; expr->value = !cost; expr->taint = 0; return 0; } /* The arguments are safe, if their cost is less than SIDE_EFFECTS */ static int expand_safe_p(struct expression *expr, int cost) { expr->type = EXPR_VALUE; expr->value = (cost < SIDE_EFFECTS); expr->taint = 0; return 0; } static struct symbol_op constant_p_op = { .evaluate = evaluate_to_int_const_expr, .expand = expand_constant_p }; static struct symbol_op safe_p_op = { .evaluate = evaluate_to_int_const_expr, .expand = expand_safe_p }; static struct symbol_op warning_op = { .evaluate = evaluate_to_int_const_expr, .expand = expand_warning }; static struct symbol_op expect_op = { .expand = expand_expect }; static struct symbol_op choose_op = { .args = args_triadic, .evaluate = evaluate_choose, }; /* The argument is constant and valid if the cost is zero */ static int expand_bswap(struct expression *expr, int cost) { struct expression *arg; long long val; if (cost) return cost; /* the arguments number & type have already been checked */ arg = first_expression(expr->args); val = get_expression_value_silent(arg); switch (expr->ctype->bit_size) { case 16: expr->value = bswap16(val); break; case 32: expr->value = bswap32(val); break; case 64: expr->value = bswap64(val); break; default: /* impossible error */ return SIDE_EFFECTS; } expr->type = EXPR_VALUE; expr->taint = 0; return 0; } static struct symbol_op bswap_op = { .evaluate = evaluate_pure_unop, .expand = expand_bswap, }; #define EXPAND_FINDBIT(name) \ static int expand_##name(struct expression *expr, int cost) \ { \ struct expression *arg; \ long long val; \ \ if (cost) \ return cost; \ \ arg = first_expression(expr->args); \ val = get_expression_value_silent(arg); \ switch (arg->ctype->bit_size) { \ case sizeof(int) * 8: \ val = __builtin_##name(val); break; \ case sizeof(long long) * 8: \ val = __builtin_##name##ll(val); break; \ default: /* impossible error */ \ return SIDE_EFFECTS; \ } \ \ expr->value = val; \ expr->type = EXPR_VALUE; \ expr->taint = 0; \ return 0; \ } \ \ static struct symbol_op name##_op = { \ .evaluate = evaluate_pure_unop, \ .expand = expand_##name, \ } EXPAND_FINDBIT(clz); EXPAND_FINDBIT(ctz); EXPAND_FINDBIT(clrsb); EXPAND_FINDBIT(ffs); EXPAND_FINDBIT(parity); EXPAND_FINDBIT(popcount); static int evaluate_fp_unop(struct expression *expr) { struct expression *arg; if (!eval_args(expr, 1)) return 0; arg = first_expression(expr->args); if (!is_float_type(arg->ctype)) { expression_error(expr, "non-floating-point argument in call to %s()", show_ident(expr->fn->ctype->ident)); return 0; } return 1; } static struct symbol_op fp_unop_op = { .evaluate = evaluate_fp_unop, }; static int expand_isdigit(struct expression *expr, int cost) { struct expression *arg = first_expression(expr->args); long long val = get_expression_value_silent(arg); if (cost) return cost; expr->value = (val >= '0') && (val <= '9'); expr->type = EXPR_VALUE; expr->taint = 0; return 0; } static struct symbol_op isdigit_op = { .evaluate = evaluate_pure_unop, .expand = expand_isdigit, }; static int evaluate_overflow_gen(struct expression *expr, int ptr) { struct expression *arg; int n = 0; /* there will be exactly 3; we'd already verified that */ FOR_EACH_PTR(expr->args, arg) { struct symbol *type; n++; if (!arg || !(type = arg->ctype)) return 0; // 1st & 2nd args must be a basic integer type // 3rd arg must be a pointer to such a type. if (n == 3 && ptr) { if (type->type == SYM_NODE) type = type->ctype.base_type; if (!type) return 0; if (type->type != SYM_PTR) goto err; type = type->ctype.base_type; if (!type) return 0; } if (type->type == SYM_NODE) type = type->ctype.base_type; if (!type) return 0; if (type->ctype.base_type != &int_type || type == &bool_ctype) goto err; } END_FOR_EACH_PTR(arg); // the builtin returns a bool expr->ctype = &bool_ctype; return 1; err: sparse_error(arg->pos, "invalid type for argument %d:", n); info(arg->pos, " %s", show_typename(arg->ctype)); expr->ctype = &bad_ctype; return 0; } static int evaluate_overflow(struct expression *expr) { return evaluate_overflow_gen(expr, 1); } static struct symbol_op overflow_op = { .args = args_triadic, .evaluate = evaluate_overflow, }; static int evaluate_overflow_p(struct expression *expr) { return evaluate_overflow_gen(expr, 0); } static struct symbol_op overflow_p_op = { .args = args_triadic, .evaluate = evaluate_overflow_p, }; /// // Evaluate the arguments of 'generic' integer operators. // // Parameters with a complete type are used like in a normal prototype. // The first parameter with a 'dynamic' type will be consider // as polymorphic and for each calls will be instancied with the type // of its effective argument. // The next dynamic parameters will the use this polymorphic type. // This allows to declare functions with some parameters having // a type variably defined at call time: // int foo(int, T, T); static int evaluate_generic_int_op(struct expression *expr) { struct symbol *fntype = expr->fn->ctype->ctype.base_type; struct symbol_list *types = NULL; struct symbol *ctype = NULL; struct expression *arg; struct symbol *t; int n = 0; PREPARE_PTR_LIST(fntype->arguments, t); FOR_EACH_PTR(expr->args, arg) { n++; if (!is_dynamic_type(t)) { ; } else if (!ctype) { // first 'dynamic' type, check that it's an integer t = arg->ctype; if (!t) return 0; if (t->type == SYM_NODE) t = t->ctype.base_type; if (!t) return 0; if (t->ctype.base_type != &int_type) goto err; // next 'dynamic' arguments will use this type ctype = t; } else { // use the previous 'dynamic' type t = ctype; } add_ptr_list(&types, t); NEXT_PTR_LIST(t); } END_FOR_EACH_PTR(arg); FINISH_PTR_LIST(t); return evaluate_arguments(types, expr->args); err: sparse_error(arg->pos, "non-integer type for argument %d:", n); info(arg->pos, " %s", show_typename(arg->ctype)); expr->ctype = &bad_ctype; return 0; } struct symbol_op generic_int_op = { .args = args_prototype, .evaluate = evaluate_generic_int_op, }; static int eval_atomic_common(struct expression *expr) { struct symbol *fntype = expr->fn->ctype->ctype.base_type; struct symbol_list *types = NULL; struct symbol *ctype = NULL; struct symbol *t; struct expression *arg; int n = 0; // The number of arguments has already be verified. // The first arg must be a pointer to an integral type. PREPARE_PTR_LIST(fntype->arguments, t); FOR_EACH_PTR(expr->args, arg) { struct symbol *ptrtype = NULL; if (++n == 1) { t = arg->ctype; if (!t) return 0; if (t->type == SYM_NODE) t = t->ctype.base_type; if (!t) return 0; if (t->type != SYM_PTR) goto err; ptrtype = t; t = t->ctype.base_type; if (!t) return 0; if (t->type == SYM_NODE) t = t->ctype.base_type; if (!t) return 0; if (t->type != SYM_PTR && t->ctype.base_type != &int_type) goto err; ctype = t; t = ptrtype; } else if (is_dynamic_type(t)) { t = ctype; } else if (t == &ptr_ctype) { t = ptrtype; } add_ptr_list(&types, t); NEXT_PTR_LIST(t); } END_FOR_EACH_PTR(arg); FINISH_PTR_LIST(t); if (!expr->ctype) // set the return type, if needed expr->ctype = ctype; return evaluate_arguments(types, expr->args); err: sparse_error(arg->pos, "invalid type for argument %d:", n); info(arg->pos, " %s", show_typename(arg->ctype)); expr->ctype = &bad_ctype; return 0; } static struct symbol_op atomic_op = { .args = args_prototype, .evaluate = eval_atomic_common, }; /// // expand __builtin_object_size() // // :note: type 1 and type 3 are not supported because the // needed information isn't available after evaluation. static int expand_object_size(struct expression *expr, int cost) { struct expression *arg = first_expression(expr->args); int type = get_expression_value_silent(ptr_list_nth(expr->args, 1)); unsigned long val = -1, off = 0; while (arg) { switch (arg->type) { case EXPR_IMPLIED_CAST: case EXPR_CAST: // ignore those arg = arg->cast_expression; continue; case EXPR_BINOP: // a constant add is (maybe) an offset if (!arg->right || arg->op != '+' || arg->right->type != EXPR_VALUE) break; off += arg->right->value; arg = arg->left; continue; case EXPR_PREOP: // a deref is just intermediate variable // and so the offset needs to be zeroed. if (arg->op == '*') { arg = arg->unop; off = 0; switch (arg->type) { case EXPR_SYMBOL: arg = arg->symbol->initializer; continue; default: break; } } break; case EXPR_SYMBOL: // the symbol we're looking after val = bits_to_bytes(arg->symbol->bit_size); break; case EXPR_CALL: // use alloc_size() attribute but only after linearization. return UNSAFE; default: break; } break; } if (val == -1) val = (type & 2) ? 0 : val; else if (type & 1) return UNSAFE; else val -= off; expr->flags |= CEF_SET_ICE; expr->type = EXPR_VALUE; expr->value = val; expr->taint = 0; return 0; } static struct symbol_op object_size_op = { .expand = expand_object_size, }; /* * Builtin functions */ static struct symbol size_t_alias; static struct symbol *get_ctype(struct symbol *sym) { if (sym == &size_t_alias) return size_t_ctype; return sym; } static void declare_builtin(int stream, const struct builtin_fn *entry) { struct symbol *sym = create_symbol(stream, entry->name, SYM_NODE, NS_SYMBOL); struct symbol *fun = alloc_symbol(sym->pos, SYM_FN); struct symbol *arg; int i; sym->ctype.base_type = fun; sym->ctype.modifiers = MOD_TOPLEVEL; sym->builtin = 1; sym->op = entry->op; fun->ctype.base_type = get_ctype(entry->ret_type); fun->variadic = entry->variadic; for (i = 0; (arg = entry->args[i]); i++) { struct symbol *anode = alloc_symbol(sym->pos, SYM_NODE); anode->ctype.base_type = get_ctype(arg); add_symbol(&fun->arguments, anode); } } void declare_builtins(int stream, const struct builtin_fn tbl[]) { if (!tbl) return; while (tbl->name) declare_builtin(stream, tbl++); } static const struct builtin_fn builtins_common[] = { #define size_t_ctype &size_t_alias #define va_list_ctype &ptr_ctype #define vol_ptr &volatile_ptr_ctype { "__atomic_add_fetch", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_always_lock_free", &bool_ctype, 0, { size_t_ctype, vol_ptr }}, { "__atomic_and_fetch", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_clear", &void_ctype, 0, { &volatile_bool_ptr_ctype, &int_ctype }}, { "__atomic_compare_exchange", &bool_ctype, 0, { vol_ptr, &ptr_ctype, &ptr_ctype, &bool_ctype, &int_ctype, &int_ctype }, .op = &atomic_op }, { "__atomic_compare_exchange_n", &bool_ctype, 0, { vol_ptr, &ptr_ctype, &dyntype, &bool_ctype, &int_ctype, &int_ctype }, .op = &atomic_op }, { "__atomic_exchange", &void_ctype, 0, { vol_ptr, &ptr_ctype, &ptr_ctype, &int_ctype }, .op = &atomic_op }, { "__atomic_exchange_n", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_fetch_add", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_fetch_and", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_fetch_nand",NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_fetch_or", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_fetch_sub", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_fetch_xor", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_is_lock_free", &bool_ctype, 0, { size_t_ctype, vol_ptr }}, { "__atomic_load", &void_ctype, 0, { vol_ptr, &ptr_ctype, &int_ctype }, .op = &atomic_op }, { "__atomic_load_n", NULL, 0, { vol_ptr, &int_ctype }, .op = &atomic_op }, { "__atomic_nand_fetch",NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_or_fetch", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_signal_fence", &void_ctype, 0, { &int_ctype }}, { "__atomic_store", &void_ctype, 0, { vol_ptr, &ptr_ctype, &int_ctype }, .op = &atomic_op }, { "__atomic_store_n", &void_ctype, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_sub_fetch", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__atomic_test_and_set", &bool_ctype, 0, { vol_ptr, &int_ctype }}, { "__atomic_thread_fence", &void_ctype, 0, { &int_ctype }}, { "__atomic_xor_fetch", NULL, 0, { vol_ptr, &dyntype, &int_ctype }, .op = &atomic_op }, { "__builtin_choose_expr", NULL, 1, .op = &choose_op }, { "__builtin_constant_p", NULL, 1, .op = &constant_p_op }, { "__builtin_expect", &long_ctype, 0, { &long_ctype ,&long_ctype }, .op = &expect_op }, { "__builtin_safe_p", NULL, 1, .op = &safe_p_op }, { "__builtin_warning", NULL, 1, .op = &warning_op }, { "__builtin_abort", &void_ctype, 0 }, { "__builtin_abs", &int_ctype , 0, { &int_ctype }}, { "__builtin_add_overflow", &bool_ctype, 1, .op = &overflow_op }, { "__builtin_add_overflow_p", &bool_ctype, 1, .op = &overflow_p_op }, { "__builtin_alloca", &ptr_ctype, 0, { size_t_ctype }}, { "__builtin_bcmp", &int_ctype , 0, { &const_ptr_ctype, &const_ptr_ctype, size_t_ctype }}, { "__builtin_bcopy", &void_ctype, 0, { &const_ptr_ctype, &ptr_ctype, size_t_ctype }}, { "__builtin_bswap16", &ushort_ctype, 0, { &ushort_ctype }, .op = &bswap_op }, { "__builtin_bswap32", &uint_ctype, 0, { &uint_ctype }, .op = &bswap_op }, { "__builtin_bswap64", &ullong_ctype, 0, { &ullong_ctype }, .op = &bswap_op }, { "__builtin_bzero", &void_ctype, 0, { &ptr_ctype, size_t_ctype }}, { "__builtin_calloc", &ptr_ctype, 0, { size_t_ctype, size_t_ctype }}, { "__builtin_clrsb", &int_ctype, 0, { &int_ctype }, .op = &clrsb_op }, { "__builtin_clrsbl", &int_ctype, 0, { &long_ctype }, .op = &clrsb_op }, { "__builtin_clrsbll", &int_ctype, 0, { &llong_ctype }, .op = &clrsb_op }, { "__builtin_clz", &int_ctype, 0, { &int_ctype }, .op = &clz_op }, { "__builtin_clzl", &int_ctype, 0, { &long_ctype }, .op = &clz_op }, { "__builtin_clzll", &int_ctype, 0, { &llong_ctype }, .op = &clz_op }, { "__builtin_ctz", &int_ctype, 0, { &int_ctype }, .op = &ctz_op }, { "__builtin_ctzl", &int_ctype, 0, { &long_ctype }, .op = &ctz_op }, { "__builtin_ctzll", &int_ctype, 0, { &llong_ctype }, .op = &ctz_op }, { "__builtin_exit", &void_ctype, 0, { &int_ctype }}, { "__builtin_extract_return_addr", &ptr_ctype, 0, { &ptr_ctype }}, { "__builtin_fabs", &double_ctype, 0, { &double_ctype }}, { "__builtin_ffs", &int_ctype, 0, { &int_ctype }, .op = &ffs_op }, { "__builtin_ffsl", &int_ctype, 0, { &long_ctype }, .op = &ffs_op }, { "__builtin_ffsll", &int_ctype, 0, { &llong_ctype }, .op = &ffs_op }, { "__builtin_fma", &double_ctype, 0, { &double_ctype, &double_ctype, &double_ctype }}, { "__builtin_fmaf", &float_ctype, 0, { &float_ctype, &float_ctype, &float_ctype }}, { "__builtin_fmal", &ldouble_ctype, 0, { &ldouble_ctype, &ldouble_ctype, &ldouble_ctype }}, { "__builtin_frame_address", &ptr_ctype, 0, { &uint_ctype }}, { "__builtin_free", &void_ctype, 0, { &ptr_ctype }}, { "__builtin_huge_val", &double_ctype, 0 }, { "__builtin_huge_valf", &float_ctype, 0 }, { "__builtin_huge_vall", &ldouble_ctype, 0 }, { "__builtin_index", &string_ctype, 0, { &const_string_ctype, &int_ctype }}, { "__builtin_inf", &double_ctype, 0 }, { "__builtin_inff", &float_ctype, 0 }, { "__builtin_infl", &ldouble_ctype, 0 }, { "__builtin_isdigit", &int_ctype, 0, { &int_ctype }, .op = &isdigit_op }, { "__builtin_isfinite", &int_ctype, 1, .op = &fp_unop_op }, { "__builtin_isgreater", &int_ctype, 0, { &float_ctype, &float_ctype }}, { "__builtin_isgreaterequal", &int_ctype, 0, { &float_ctype, &float_ctype }}, { "__builtin_isinf", &int_ctype, 1, .op = &fp_unop_op }, { "__builtin_isinf_sign", &int_ctype, 1, .op = &fp_unop_op }, { "__builtin_isless", &int_ctype, 0, { &float_ctype, &float_ctype }}, { "__builtin_islessequal", &int_ctype, 0, { &float_ctype, &float_ctype }}, { "__builtin_islessgreater", &int_ctype, 0, { &float_ctype, &float_ctype }}, { "__builtin_isnan", &int_ctype, 1, .op = &fp_unop_op }, { "__builtin_isnormal", &int_ctype, 1, .op = &fp_unop_op }, { "__builtin_isunordered", &int_ctype, 0, { &float_ctype, &float_ctype }}, { "__builtin_labs", &long_ctype, 0, { &long_ctype }}, { "__builtin_llabs", &llong_ctype, 0, { &llong_ctype }}, { "__builtin_malloc", &ptr_ctype, 0, { size_t_ctype }}, { "__builtin_memchr", &ptr_ctype, 0, { &const_ptr_ctype, &int_ctype, size_t_ctype }}, { "__builtin_memcmp", &int_ctype, 0, { &const_ptr_ctype, &const_ptr_ctype, size_t_ctype }}, { "__builtin_memcpy", &ptr_ctype, 0, { &ptr_ctype, &const_ptr_ctype, size_t_ctype }}, { "__builtin_memmove", &ptr_ctype, 0, { &ptr_ctype, &const_ptr_ctype, size_t_ctype }}, { "__builtin_mempcpy", &ptr_ctype, 0, { &ptr_ctype, &const_ptr_ctype, size_t_ctype }}, { "__builtin_memset", &ptr_ctype, 0, { &ptr_ctype, &int_ctype, size_t_ctype }}, { "__builtin_mul_overflow", &bool_ctype, 1, .op = &overflow_op }, { "__builtin_mul_overflow_p", &bool_ctype, 1, .op = &overflow_p_op }, { "__builtin_nan", &double_ctype, 0, { &const_string_ctype }}, { "__builtin_nanf", &float_ctype, 0, { &const_string_ctype }}, { "__builtin_nanl", &ldouble_ctype, 0, { &const_string_ctype }}, { "__builtin_object_size", size_t_ctype, 0, { &const_ptr_ctype, &int_ctype }, .op = &object_size_op}, { "__builtin_parity", &int_ctype, 0, { &uint_ctype }, .op = &parity_op }, { "__builtin_parityl", &int_ctype, 0, { &ulong_ctype }, .op = &parity_op }, { "__builtin_parityll", &int_ctype, 0, { &ullong_ctype }, .op = &parity_op }, { "__builtin_popcount", &int_ctype, 0, { &uint_ctype }, .op = &popcount_op }, { "__builtin_popcountl", &int_ctype, 0, { &ulong_ctype }, .op = &popcount_op }, { "__builtin_popcountll", &int_ctype, 0, { &ullong_ctype }, .op = &popcount_op }, { "__builtin_prefetch", &void_ctype, 1, { &const_ptr_ctype }}, { "__builtin_printf", &int_ctype, 1, { &const_string_ctype }}, { "__builtin_puts", &int_ctype, 0, { &const_string_ctype }}, { "__builtin_realloc", &ptr_ctype, 0, { &ptr_ctype, size_t_ctype }}, { "__builtin_return_address", &ptr_ctype, 0, { &uint_ctype }}, { "__builtin_rindex", &string_ctype, 0, { &const_string_ctype, &int_ctype }}, { "__builtin_sadd_overflow", &bool_ctype, 0, { &int_ctype, &int_ctype, &int_ptr_ctype }}, { "__builtin_saddl_overflow", &bool_ctype, 0, { &long_ctype, &long_ctype, &long_ptr_ctype }}, { "__builtin_saddll_overflow", &bool_ctype, 0, { &llong_ctype, &llong_ctype, &llong_ptr_ctype }}, { "__builtin_signbit", &int_ctype, 1 , .op = &fp_unop_op }, { "__builtin_smul_overflow", &bool_ctype, 0, { &int_ctype, &int_ctype, &int_ptr_ctype }}, { "__builtin_smull_overflow", &bool_ctype, 0, { &long_ctype, &long_ctype, &long_ptr_ctype }}, { "__builtin_smulll_overflow", &bool_ctype, 0, { &llong_ctype, &llong_ctype, &llong_ptr_ctype }}, { "__builtin_snprintf", &int_ctype, 1, { &string_ctype, size_t_ctype, &const_string_ctype }}, { "__builtin_sprintf", &int_ctype, 1, { &string_ctype, &const_string_ctype }}, { "__builtin_ssub_overflow", &bool_ctype, 0, { &int_ctype, &int_ctype, &int_ptr_ctype }}, { "__builtin_ssubl_overflow", &bool_ctype, 0, { &long_ctype, &long_ctype, &long_ptr_ctype }}, { "__builtin_ssubll_overflow", &bool_ctype, 0, { &llong_ctype, &llong_ctype, &llong_ptr_ctype }}, { "__builtin_stpcpy", &string_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_stpncpy", &string_ctype, 0, { &const_string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin_strcasecmp", &int_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_strcasestr", &string_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_strcat", &string_ctype, 0, { &string_ctype, &const_string_ctype }}, { "__builtin_strchr", &string_ctype, 0, { &const_string_ctype, &int_ctype }}, { "__builtin_strcmp", &int_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_strcpy", &string_ctype, 0, { &string_ctype, &const_string_ctype }}, { "__builtin_strcspn", size_t_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_strdup", &string_ctype, 0, { &const_string_ctype }}, { "__builtin_strlen", size_t_ctype, 0, { &const_string_ctype }}, { "__builtin_strncasecmp", &int_ctype, 0, { &const_string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin_strncat", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin_strncmp", &int_ctype, 0, { &const_string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin_strncpy", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin_strndup", &string_ctype, 0, { &const_string_ctype, size_t_ctype }}, { "__builtin_strnstr", &string_ctype, 0, { &const_string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin_strpbrk", &string_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_strrchr", &string_ctype, 0, { &const_string_ctype, &int_ctype }}, { "__builtin_strspn", size_t_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_strstr", &string_ctype, 0, { &const_string_ctype, &const_string_ctype }}, { "__builtin_sub_overflow", &bool_ctype, 1, .op = &overflow_op }, { "__builtin_sub_overflow_p", &bool_ctype, 1, .op = &overflow_p_op }, { "__builtin_trap", &void_ctype, 0 }, { "__builtin_uadd_overflow", &bool_ctype, 0, { &uint_ctype, &uint_ctype, &uint_ptr_ctype }}, { "__builtin_uaddl_overflow", &bool_ctype, 0, { &ulong_ctype, &ulong_ctype, &ulong_ptr_ctype }}, { "__builtin_uaddll_overflow", &bool_ctype, 0, { &ullong_ctype, &ullong_ctype, &ullong_ptr_ctype }}, { "__builtin_umul_overflow", &bool_ctype, 0, { &uint_ctype, &uint_ctype, &uint_ptr_ctype }}, { "__builtin_umull_overflow", &bool_ctype, 0, { &ulong_ctype, &ulong_ctype, &ulong_ptr_ctype }}, { "__builtin_umulll_overflow", &bool_ctype, 0, { &ullong_ctype, &ullong_ctype, &ullong_ptr_ctype }}, { "__builtin_unreachable", &void_ctype, 0 }, { "__builtin_usub_overflow", &bool_ctype, 0, { &uint_ctype, &uint_ctype, &uint_ptr_ctype }}, { "__builtin_usubl_overflow", &bool_ctype, 0, { &ulong_ctype, &ulong_ctype, &ulong_ptr_ctype }}, { "__builtin_usubll_overflow", &bool_ctype, 0, { &ullong_ctype, &ullong_ctype, &ullong_ptr_ctype }}, { "__builtin_va_arg_pack_len", size_t_ctype, 0 }, { "__builtin_vprintf", &int_ctype, 0, { &const_string_ctype, va_list_ctype }}, { "__builtin_vsnprintf", &int_ctype, 0, { &string_ctype, size_t_ctype, &const_string_ctype, va_list_ctype }}, { "__builtin_vsprintf", &int_ctype, 0, { &string_ctype, &const_string_ctype, va_list_ctype }}, { "__builtin___memcpy_chk", &ptr_ctype, 0, { &ptr_ctype, &const_ptr_ctype, size_t_ctype, size_t_ctype }}, { "__builtin___memmove_chk", &ptr_ctype, 0, { &ptr_ctype, &const_ptr_ctype, size_t_ctype, size_t_ctype }}, { "__builtin___mempcpy_chk", &ptr_ctype, 0, { &ptr_ctype, &const_ptr_ctype, size_t_ctype, size_t_ctype }}, { "__builtin___memset_chk", &ptr_ctype, 0, { &ptr_ctype, &int_ctype, size_t_ctype, size_t_ctype }}, { "__builtin___snprintf_chk", &int_ctype, 1, { &string_ctype, size_t_ctype, &int_ctype , size_t_ctype, &const_string_ctype }}, { "__builtin___sprintf_chk", &int_ctype, 1, { &string_ctype, &int_ctype, size_t_ctype, &const_string_ctype }}, { "__builtin___stpcpy_chk", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin___strcat_chk", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin___strcpy_chk", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype }}, { "__builtin___strncat_chk", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype, size_t_ctype }}, { "__builtin___strncpy_chk", &string_ctype, 0, { &string_ctype, &const_string_ctype, size_t_ctype, size_t_ctype }}, { "__builtin___vsnprintf_chk", &int_ctype, 0, { &string_ctype, size_t_ctype, &int_ctype, size_t_ctype, &const_string_ctype, va_list_ctype }}, { "__builtin___vsprintf_chk", &int_ctype, 0, { &string_ctype, &int_ctype, size_t_ctype, &const_string_ctype, va_list_ctype }}, { "__sync_add_and_fetch", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_and_and_fetch", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_bool_compare_and_swap", &bool_ctype, 1, { vol_ptr, &dyntype, &dyntype }, .op = &atomic_op}, { "__sync_fetch_and_add", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_fetch_and_and", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_fetch_and_nand", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_fetch_and_or", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_fetch_and_sub", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_fetch_and_xor", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_lock_release", &void_ctype, 1, { vol_ptr }, .op = &atomic_op }, { "__sync_lock_test_and_set", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_nand_and_fetch", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_or_and_fetch", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_sub_and_fetch", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { "__sync_synchronize", &void_ctype, 1 }, { "__sync_val_compare_and_swap", NULL, 1, { vol_ptr, &dyntype, &dyntype }, .op = &atomic_op }, { "__sync_xor_and_fetch", NULL, 1, { vol_ptr, &dyntype }, .op = &atomic_op }, { } }; void init_builtins(int stream) { declare_builtins(stream, builtins_common); declare_builtins(stream, arch_target->builtins); init_linearized_builtins(stream); }