/* * sparse/expand.c * * 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. * * expand constant expressions. */ #include #include #include #include #include #include #include #include #include #include "lib.h" #include "allocate.h" #include "parse.h" #include "token.h" #include "symbol.h" #include "target.h" #include "expression.h" #include "evaluate.h" #include "expand.h" static int expand_expression(struct expression *); static int expand_statement(struct statement *); // If set, don't issue a warning on divide-by-0, invalid shift, ... // and don't mark the expression as erroneous but leave it as-is. // This allows testing some characteristics of the expression // without creating any side-effects (e.g.: is_zero_constant()). static int conservative; static int expand_symbol_expression(struct expression *expr) { struct symbol *sym = expr->symbol; if (sym == &zero_int) { if (Wundef) warning(expr->pos, "undefined preprocessor identifier '%s'", show_ident(expr->symbol_name)); expr->type = EXPR_VALUE; expr->value = 0; expr->taint = 0; return 0; } // expand compound literals (C99 & C11 6.5.2.5) // FIXME: is this the correct way to identify them? // All compound literals are anonymous but is // the reverse true? if (sym->initializer && !expr->symbol_name) return expand_expression(sym->initializer); /* The cost of a symbol expression is lower for on-stack symbols */ return (sym->ctype.modifiers & (MOD_STATIC | MOD_EXTERN)) ? 2 : 1; } static long long get_longlong(struct expression *expr) { int no_expand = expr->ctype->ctype.modifiers & MOD_UNSIGNED; long long mask = 1ULL << (expr->ctype->bit_size - 1); long long value = expr->value; long long ormask, andmask; if (!(value & mask)) no_expand = 1; andmask = mask | (mask-1); ormask = ~andmask; if (no_expand) ormask = 0; return (value & andmask) | ormask; } void cast_value(struct expression *expr, struct symbol *newtype, struct expression *old) { struct symbol *oldtype = old->ctype; int old_size = oldtype->bit_size; int new_size = newtype->bit_size; long long value, mask, signmask; long long oldmask, oldsignmask, dropped; if (is_float_type(newtype) || is_float_type(oldtype)) goto Float; // For pointers and integers, we can just move the value around expr->type = EXPR_VALUE; expr->taint = old->taint; if (old_size == new_size) { expr->value = old->value; expr->ctype = newtype; return; } // expand it to the full "long long" value value = get_longlong(old); expr->ctype = newtype; Int: // _Bool requires a zero test rather than truncation. if (is_bool_type(newtype)) { expr->value = !!value; if (!conservative && value != 0 && value != 1) warning(old->pos, "odd constant _Bool cast (%llx becomes 1)", value); return; } // Truncate it to the new size signmask = 1ULL << (new_size-1); mask = signmask | (signmask-1); expr->value = value & mask; // Stop here unless checking for truncation if (!Wcast_truncate || conservative) return; // Check if we dropped any bits.. oldsignmask = 1ULL << (old_size-1); oldmask = oldsignmask | (oldsignmask-1); dropped = oldmask & ~mask; // OK if the bits were (and still are) purely sign bits if (value & dropped) { if (!(value & oldsignmask) || !(value & signmask) || (value & dropped) != dropped) warning(old->pos, "cast truncates bits from constant value (%llx becomes %llx)", value & oldmask, value & mask); } return; Float: if (!is_float_type(newtype)) { value = (long long)old->fvalue; expr->type = EXPR_VALUE; expr->taint = 0; expr->ctype = newtype; goto Int; } if (!is_float_type(oldtype)) expr->fvalue = (long double)get_longlong(old); else expr->fvalue = old->fvalue; if (newtype->rank <= 0) { if (newtype->rank == 0) expr->fvalue = (double)expr->fvalue; else expr->fvalue = (float)expr->fvalue; } expr->type = EXPR_FVALUE; expr->ctype = newtype; } /* Return true if constant shift size is valid */ static bool check_shift_count(struct expression *expr, struct expression *right) { struct symbol *ctype = expr->ctype; long long count = get_longlong(right); if (count >= 0 && count < ctype->bit_size) return true; return false; } /* * CAREFUL! We need to get the size and sign of the * result right! */ #define CONVERT(op,s) (((op)<<1)+(s)) #define SIGNED(op) CONVERT(op, 1) #define UNSIGNED(op) CONVERT(op, 0) static int simplify_int_binop(struct expression *expr, struct symbol *ctype) { struct expression *left = expr->left, *right = expr->right; unsigned long long v, l, r, mask; signed long long sl, sr; int is_signed; if (right->type != EXPR_VALUE) return 0; r = right->value; if (expr->op == SPECIAL_LEFTSHIFT || expr->op == SPECIAL_RIGHTSHIFT) { if (!check_shift_count(expr, right)) return 0; } if (left->type != EXPR_VALUE) return 0; l = left->value; r = right->value; is_signed = !(ctype->ctype.modifiers & MOD_UNSIGNED); mask = 1ULL << (ctype->bit_size-1); sl = l; sr = r; if (is_signed && (sl & mask)) sl |= ~(mask-1); if (is_signed && (sr & mask)) sr |= ~(mask-1); switch (CONVERT(expr->op,is_signed)) { case SIGNED('+'): case UNSIGNED('+'): v = l + r; break; case SIGNED('-'): case UNSIGNED('-'): v = l - r; break; case SIGNED('&'): case UNSIGNED('&'): v = l & r; break; case SIGNED('|'): case UNSIGNED('|'): v = l | r; break; case SIGNED('^'): case UNSIGNED('^'): v = l ^ r; break; case SIGNED('*'): v = sl * sr; break; case UNSIGNED('*'): v = l * r; break; case SIGNED('/'): if (!r) goto Div; if (l == mask && sr == -1) goto Overflow; v = sl / sr; break; case UNSIGNED('/'): if (!r) goto Div; v = l / r; break; case SIGNED('%'): if (!r) goto Div; if (l == mask && sr == -1) goto Overflow; v = sl % sr; break; case UNSIGNED('%'): if (!r) goto Div; v = l % r; break; case SIGNED(SPECIAL_LEFTSHIFT): case UNSIGNED(SPECIAL_LEFTSHIFT): v = l << r; break; case SIGNED(SPECIAL_RIGHTSHIFT): v = sl >> r; break; case UNSIGNED(SPECIAL_RIGHTSHIFT): v = l >> r; break; default: return 0; } mask = mask | (mask-1); expr->value = v & mask; expr->type = EXPR_VALUE; expr->taint = left->taint | right->taint; return 1; Div: if (!conservative) warning(expr->pos, "division by zero"); return 0; Overflow: if (!conservative) warning(expr->pos, "constant integer operation overflow"); return 0; } static int simplify_cmp_binop(struct expression *expr, struct symbol *ctype) { struct expression *left = expr->left, *right = expr->right; unsigned long long l, r, mask; signed long long sl, sr; if (left->type != EXPR_VALUE || right->type != EXPR_VALUE) return 0; l = left->value; r = right->value; mask = 1ULL << (ctype->bit_size-1); sl = l; sr = r; if (sl & mask) sl |= ~(mask-1); if (sr & mask) sr |= ~(mask-1); switch (expr->op) { case '<': expr->value = sl < sr; break; case '>': expr->value = sl > sr; break; case SPECIAL_LTE: expr->value = sl <= sr; break; case SPECIAL_GTE: expr->value = sl >= sr; break; case SPECIAL_EQUAL: expr->value = l == r; break; case SPECIAL_NOTEQUAL: expr->value = l != r; break; case SPECIAL_UNSIGNED_LT:expr->value = l < r; break; case SPECIAL_UNSIGNED_GT:expr->value = l > r; break; case SPECIAL_UNSIGNED_LTE:expr->value = l <= r; break; case SPECIAL_UNSIGNED_GTE:expr->value = l >= r; break; } expr->type = EXPR_VALUE; expr->taint = left->taint | right->taint; return 1; } static int simplify_float_binop(struct expression *expr) { struct expression *left = expr->left, *right = expr->right; int rank = expr->ctype->rank; long double l, r, res; if (left->type != EXPR_FVALUE || right->type != EXPR_FVALUE) return 0; l = left->fvalue; r = right->fvalue; if (rank > 0) { switch (expr->op) { case '+': res = l + r; break; case '-': res = l - r; break; case '*': res = l * r; break; case '/': if (!r) goto Div; res = l / r; break; default: return 0; } } else if (rank == 0) { switch (expr->op) { case '+': res = (double) l + (double) r; break; case '-': res = (double) l - (double) r; break; case '*': res = (double) l * (double) r; break; case '/': if (!r) goto Div; res = (double) l / (double) r; break; default: return 0; } } else { switch (expr->op) { case '+': res = (float)l + (float)r; break; case '-': res = (float)l - (float)r; break; case '*': res = (float)l * (float)r; break; case '/': if (!r) goto Div; res = (float)l / (float)r; break; default: return 0; } } expr->type = EXPR_FVALUE; expr->fvalue = res; return 1; Div: if (!conservative) warning(expr->pos, "division by zero"); return 0; } static int simplify_float_cmp(struct expression *expr, struct symbol *ctype) { struct expression *left = expr->left, *right = expr->right; long double l, r; if (left->type != EXPR_FVALUE || right->type != EXPR_FVALUE) return 0; l = left->fvalue; r = right->fvalue; switch (expr->op) { case '<': expr->value = l < r; break; case '>': expr->value = l > r; break; case SPECIAL_LTE: expr->value = l <= r; break; case SPECIAL_GTE: expr->value = l >= r; break; case SPECIAL_EQUAL: expr->value = l == r; break; case SPECIAL_NOTEQUAL: expr->value = l != r; break; } expr->type = EXPR_VALUE; expr->taint = 0; return 1; } static int expand_binop(struct expression *expr) { int cost; cost = expand_expression(expr->left); cost += expand_expression(expr->right); if (simplify_int_binop(expr, expr->ctype)) return 0; if (simplify_float_binop(expr)) return 0; return cost + 1; } static int expand_logical(struct expression *expr) { struct expression *left = expr->left; struct expression *right; int cost, rcost; /* Do immediate short-circuiting ... */ cost = expand_expression(left); if (left->type == EXPR_VALUE) { if (expr->op == SPECIAL_LOGICAL_AND) { if (!left->value) { expr->type = EXPR_VALUE; expr->value = 0; expr->taint = left->taint; return 0; } } else { if (left->value) { expr->type = EXPR_VALUE; expr->value = 1; expr->taint = left->taint; return 0; } } } right = expr->right; rcost = expand_expression(right); if (left->type == EXPR_VALUE && right->type == EXPR_VALUE) { /* * We know the left value doesn't matter, since * otherwise we would have short-circuited it.. */ expr->type = EXPR_VALUE; expr->value = right->value != 0; expr->taint = left->taint | right->taint; return 0; } /* * If the right side is safe and cheaper than a branch, * just avoid the branch and turn it into a regular binop * style SAFELOGICAL. */ if (rcost < BRANCH_COST) { expr->type = EXPR_BINOP; rcost -= BRANCH_COST - 1; } return cost + BRANCH_COST + rcost; } static int expand_comma(struct expression *expr) { int cost; cost = expand_expression(expr->left); cost += expand_expression(expr->right); if (expr->left->type == EXPR_VALUE || expr->left->type == EXPR_FVALUE) { unsigned flags = expr->flags; unsigned taint; taint = expr->left->type == EXPR_VALUE ? expr->left->taint : 0; *expr = *expr->right; expr->flags = flags; if (expr->type == EXPR_VALUE) expr->taint |= Taint_comma | taint; } return cost; } #define MOD_IGN (MOD_QUALIFIER) static int compare_types(int op, struct symbol *left, struct symbol *right) { struct ctype c1 = {.base_type = left}; struct ctype c2 = {.base_type = right}; switch (op) { case SPECIAL_EQUAL: return !type_difference(&c1, &c2, MOD_IGN, MOD_IGN); case SPECIAL_NOTEQUAL: return type_difference(&c1, &c2, MOD_IGN, MOD_IGN) != NULL; case '<': return left->bit_size < right->bit_size; case '>': return left->bit_size > right->bit_size; case SPECIAL_LTE: return left->bit_size <= right->bit_size; case SPECIAL_GTE: return left->bit_size >= right->bit_size; } return 0; } static int expand_compare(struct expression *expr) { struct expression *left = expr->left, *right = expr->right; int cost; cost = expand_expression(left); cost += expand_expression(right); if (left && right) { /* Type comparison? */ if (left->type == EXPR_TYPE && right->type == EXPR_TYPE) { int op = expr->op; expr->type = EXPR_VALUE; expr->value = compare_types(op, left->symbol, right->symbol); expr->taint = 0; return 0; } if (simplify_cmp_binop(expr, left->ctype)) return 0; if (simplify_float_cmp(expr, left->ctype)) return 0; } return cost + 1; } static int expand_conditional(struct expression *expr) { struct expression *cond = expr->conditional; struct expression *valt = expr->cond_true; struct expression *valf = expr->cond_false; int cost, cond_cost; cond_cost = expand_expression(cond); if (cond->type == EXPR_VALUE) { unsigned flags = expr->flags; if (!cond->value) valt = valf; if (!valt) valt = cond; cost = expand_expression(valt); *expr = *valt; expr->flags = flags; if (expr->type == EXPR_VALUE) expr->taint |= cond->taint; return cost; } cost = expand_expression(valt); cost += expand_expression(valf); if (cost < SELECT_COST) { expr->type = EXPR_SELECT; cost -= BRANCH_COST - 1; } return cost + cond_cost + BRANCH_COST; } static void check_assignment(struct expression *expr) { struct expression *right; switch (expr->op) { case SPECIAL_SHL_ASSIGN: case SPECIAL_SHR_ASSIGN: right = expr->right; if (right->type != EXPR_VALUE) break; check_shift_count(expr, right); break; } return; } static int expand_assignment(struct expression *expr) { expand_expression(expr->left); expand_expression(expr->right); if (!conservative) check_assignment(expr); return SIDE_EFFECTS; } static int expand_addressof(struct expression *expr) { return expand_expression(expr->unop); } /// // lookup the type of a struct's memeber at the requested offset static struct symbol *find_member(struct symbol *sym, int offset) { struct ptr_list *head, *list; head = (struct ptr_list *) sym->symbol_list; list = head; if (!head) return NULL; do { int nr = list->nr; int i; for (i = 0; i < nr; i++) { struct symbol *ent = (struct symbol *) list->list[i]; int curr = ent->offset; if (curr == offset) return ent; if (curr > offset) return NULL; } } while ((list = list->next) != head); return NULL; } /// // lookup a suitable default initializer value at the requested offset static struct expression *default_initializer(struct symbol *sym, int offset) { static struct expression value; struct symbol *type; redo: switch (sym->type) { case SYM_NODE: sym = sym->ctype.base_type; goto redo; case SYM_STRUCT: type = find_member(sym, offset); if (!type) return NULL; break; case SYM_ARRAY: type = sym->ctype.base_type; break; default: return NULL; } if (is_integral_type(type)) value.type = EXPR_VALUE; else if (is_float_type(type)) value.type = EXPR_FVALUE; else return NULL; value.ctype = type; return &value; } /* * Look up a trustable initializer value at the requested offset. * * Return NULL if no such value can be found or statically trusted. */ static struct expression *constant_symbol_value(struct symbol *sym, int offset) { struct expression *value; if (sym->ctype.modifiers & MOD_ACCESS) return NULL; value = sym->initializer; if (!value) return NULL; if (value->type == EXPR_INITIALIZER) { struct expression *entry; FOR_EACH_PTR(value->expr_list, entry) { if (entry->type != EXPR_POS) { if (offset) continue; return entry; } if (entry->init_offset < offset) continue; if (entry->init_offset > offset) break; return entry->init_expr; } END_FOR_EACH_PTR(entry); value = default_initializer(sym, offset); } return value; } static int expand_dereference(struct expression *expr) { struct expression *unop = expr->unop; unsigned int offset; expand_expression(unop); /* * NOTE! We get a bogus warning right now for some special * cases: apparently I've screwed up the optimization of * a zero-offset dereference, and the ctype is wrong. * * Leave the warning in anyway, since this is also a good * test for me to get the type evaluation right.. */ if (expr->ctype->ctype.modifiers & MOD_NODEREF) warning(unop->pos, "dereference of noderef expression"); /* * Is it "symbol" or "symbol + offset"? */ offset = 0; while (unop->type == EXPR_BINOP && unop->op == '+') { struct expression *right = unop->right; if (right->type != EXPR_VALUE) break; offset += right->value; unop = unop->left; } if (unop->type == EXPR_SYMBOL) { struct symbol *sym = unop->symbol; struct symbol *ctype = expr->ctype; struct expression *value = constant_symbol_value(sym, offset); /* Const symbol with a constant initializer? */ if (value && value->ctype) { if (ctype->bit_size != value->ctype->bit_size) return UNSAFE; if (value->type == EXPR_VALUE) { if (!is_integral_type(ctype)) return UNSAFE; if (is_bitfield_type(value->ctype)) return UNSAFE; expr->type = EXPR_VALUE; expr->value = value->value; expr->taint = 0; return 0; } else if (value->type == EXPR_FVALUE) { if (!is_float_type(ctype)) return UNSAFE; expr->type = EXPR_FVALUE; expr->fvalue = value->fvalue; return 0; } } /* Direct symbol dereference? Cheap and safe */ return (sym->ctype.modifiers & (MOD_STATIC | MOD_EXTERN)) ? 2 : 1; } return UNSAFE; } static int simplify_preop(struct expression *expr) { struct expression *op = expr->unop; unsigned long long v, mask; if (op->type != EXPR_VALUE) return 0; mask = 1ULL << (expr->ctype->bit_size-1); v = op->value; switch (expr->op) { case '+': break; case '-': if (v == mask && !(expr->ctype->ctype.modifiers & MOD_UNSIGNED)) goto Overflow; v = -v; break; case '!': v = !v; break; case '~': v = ~v; break; default: return 0; } mask = mask | (mask-1); expr->value = v & mask; expr->type = EXPR_VALUE; expr->taint = op->taint; return 1; Overflow: if (!conservative) warning(expr->pos, "constant integer operation overflow"); return 0; } static int simplify_float_preop(struct expression *expr) { struct expression *op = expr->unop; long double v; if (op->type != EXPR_FVALUE) return 0; v = op->fvalue; switch (expr->op) { case '+': break; case '-': v = -v; break; default: return 0; } expr->fvalue = v; expr->type = EXPR_FVALUE; return 1; } /* * Unary post-ops: x++ and x-- */ static int expand_postop(struct expression *expr) { expand_expression(expr->unop); return SIDE_EFFECTS; } static int expand_preop(struct expression *expr) { int cost; switch (expr->op) { case '*': return expand_dereference(expr); case '&': return expand_addressof(expr); case SPECIAL_INCREMENT: case SPECIAL_DECREMENT: /* * From a type evaluation standpoint the preops are * the same as the postops */ return expand_postop(expr); default: break; } cost = expand_expression(expr->unop); if (simplify_preop(expr)) return 0; if (simplify_float_preop(expr)) return 0; return cost + 1; } static int expand_arguments(struct expression_list *head) { int cost = 0; struct expression *expr; FOR_EACH_PTR (head, expr) { cost += expand_expression(expr); } END_FOR_EACH_PTR(expr); return cost; } static int expand_cast(struct expression *expr) { int cost; struct expression *target = expr->cast_expression; cost = expand_expression(target); /* Simplify normal integer casts.. */ if (target->type == EXPR_VALUE || target->type == EXPR_FVALUE) { cast_value(expr, expr->ctype, target); return 0; } return cost + 1; } /* * expand a call expression with a symbol. This * should expand builtins. */ static int expand_symbol_call(struct expression *expr, int cost) { struct expression *fn = expr->fn; struct symbol *ctype = fn->ctype; expand_expression(fn); if (fn->type != EXPR_PREOP) return SIDE_EFFECTS; if (ctype->ctype.modifiers & MOD_INLINE) { struct symbol *def; def = ctype->definition ? ctype->definition : ctype; if (inline_function(expr, def)) { struct symbol *fn = def->ctype.base_type; struct symbol *curr = current_fn; current_fn = def; evaluate_statement(expr->statement); current_fn = curr; fn->expanding = 1; cost = expand_expression(expr); fn->expanding = 0; return cost; } } if (ctype->op && ctype->op->expand) return ctype->op->expand(expr, cost); if (ctype->ctype.modifiers & MOD_PURE) return cost + 1; return SIDE_EFFECTS; } static int expand_call(struct expression *expr) { int cost; struct symbol *sym; struct expression *fn = expr->fn; cost = expand_arguments(expr->args); sym = fn->ctype; if (!sym) { expression_error(expr, "function has no type"); return SIDE_EFFECTS; } if (sym->type == SYM_NODE) return expand_symbol_call(expr, cost); return SIDE_EFFECTS; } static int expand_expression_list(struct expression_list *list) { int cost = 0; struct expression *expr; FOR_EACH_PTR(list, expr) { cost += expand_expression(expr); } END_FOR_EACH_PTR(expr); return cost; } /* * We can simplify nested position expressions if * this is a simple (single) positional expression. */ static int expand_pos_expression(struct expression *expr) { struct expression *nested = expr->init_expr; unsigned long offset = expr->init_offset; int nr = expr->init_nr; if (nr == 1) { switch (nested->type) { case EXPR_POS: offset += nested->init_offset; *expr = *nested; expr->init_offset = offset; nested = expr; break; case EXPR_INITIALIZER: { struct expression *reuse = nested, *entry; *expr = *nested; FOR_EACH_PTR(expr->expr_list, entry) { if (entry->type == EXPR_POS) { entry->init_offset += offset; } else { if (!reuse) { /* * This happens rarely, but it can happen * with bitfields that are all at offset * zero.. */ reuse = alloc_expression(entry->pos, EXPR_POS); } reuse->type = EXPR_POS; reuse->ctype = entry->ctype; reuse->init_offset = offset; reuse->init_nr = 1; reuse->init_expr = entry; REPLACE_CURRENT_PTR(entry, reuse); reuse = NULL; } } END_FOR_EACH_PTR(entry); nested = expr; break; } default: break; } } return expand_expression(nested); } static unsigned long bit_offset(const struct expression *expr) { unsigned long offset = 0; while (expr->type == EXPR_POS) { offset += bytes_to_bits(expr->init_offset); expr = expr->init_expr; } if (expr && expr->ctype) offset += expr->ctype->bit_offset; return offset; } static unsigned long bit_range(const struct expression *expr) { unsigned long range = 0; unsigned long size = 0; while (expr->type == EXPR_POS) { unsigned long nr = expr->init_nr; size = expr->ctype->bit_size; range += (nr - 1) * size; expr = expr->init_expr; } range += size; return range; } static int compare_expressions(const void *_a, const void *_b) { const struct expression *a = _a; const struct expression *b = _b; unsigned long a_pos = bit_offset(a); unsigned long b_pos = bit_offset(b); return (a_pos < b_pos) ? -1 : (a_pos == b_pos) ? 0 : 1; } static void sort_expression_list(struct expression_list **list) { sort_list((struct ptr_list **)list, compare_expressions); } static void verify_nonoverlapping(struct expression_list **list, struct expression *expr) { struct expression *a = NULL; unsigned long max = 0; unsigned long whole = expr->ctype->bit_size; struct expression *b; if (!Woverride_init) return; FOR_EACH_PTR(*list, b) { unsigned long off, end; if (!b->ctype || !b->ctype->bit_size) continue; off = bit_offset(b); if (a && off < max) { warning(a->pos, "Initializer entry defined twice"); info(b->pos, " also defined here"); if (!Woverride_init_all) return; } end = off + bit_range(b); if (!a && !Woverride_init_whole_range) { // If first entry is the whole range, do not let // any warning about it (this allow to initialize // an array with some default value and then override // some specific entries). if (off == 0 && end == whole) continue; } if (end > max) { max = end; a = b; } } END_FOR_EACH_PTR(b); } static int expand_expression(struct expression *expr) { if (!expr) return 0; if (!expr->ctype || expr->ctype == &bad_ctype) return UNSAFE; switch (expr->type) { case EXPR_VALUE: case EXPR_FVALUE: case EXPR_STRING: return 0; case EXPR_TYPE: case EXPR_SYMBOL: return expand_symbol_expression(expr); case EXPR_BINOP: return expand_binop(expr); case EXPR_LOGICAL: return expand_logical(expr); case EXPR_COMMA: return expand_comma(expr); case EXPR_COMPARE: return expand_compare(expr); case EXPR_ASSIGNMENT: return expand_assignment(expr); case EXPR_PREOP: return expand_preop(expr); case EXPR_POSTOP: return expand_postop(expr); case EXPR_CAST: case EXPR_FORCE_CAST: case EXPR_IMPLIED_CAST: return expand_cast(expr); case EXPR_CALL: return expand_call(expr); case EXPR_DEREF: warning(expr->pos, "we should not have an EXPR_DEREF left at expansion time"); return UNSAFE; case EXPR_SELECT: case EXPR_CONDITIONAL: return expand_conditional(expr); case EXPR_STATEMENT: { struct statement *stmt = expr->statement; int cost = expand_statement(stmt); if (stmt->type == STMT_EXPRESSION && stmt->expression) *expr = *stmt->expression; return cost; } case EXPR_LABEL: return 0; case EXPR_INITIALIZER: sort_expression_list(&expr->expr_list); verify_nonoverlapping(&expr->expr_list, expr); return expand_expression_list(expr->expr_list); case EXPR_IDENTIFIER: return UNSAFE; case EXPR_INDEX: return UNSAFE; case EXPR_SLICE: return expand_expression(expr->base) + 1; case EXPR_POS: return expand_pos_expression(expr); case EXPR_GENERIC: case EXPR_SIZEOF: case EXPR_PTRSIZEOF: case EXPR_ALIGNOF: case EXPR_OFFSETOF: expression_error(expr, "internal front-end error: sizeof in expansion?"); return UNSAFE; } return SIDE_EFFECTS; } static void expand_const_expression(struct expression *expr, const char *where) { if (expr) { expand_expression(expr); if (expr->type != EXPR_VALUE) { expression_error(expr, "Expected constant expression in %s", where); expr->ctype = &int_ctype; expr->type = EXPR_VALUE; expr->value = 0; } } } int expand_symbol(struct symbol *sym) { int retval; struct symbol *base_type; if (!sym) return 0; base_type = sym->ctype.base_type; if (!base_type) return 0; retval = expand_expression(sym->initializer); /* expand the body of the symbol */ if (base_type->type == SYM_FN) { if (base_type->stmt) expand_statement(base_type->stmt); } return retval; } static void expand_return_expression(struct statement *stmt) { expand_expression(stmt->expression); } static int expand_if_statement(struct statement *stmt) { struct expression *expr = stmt->if_conditional; if (!expr || !expr->ctype || expr->ctype == &bad_ctype) return UNSAFE; expand_expression(expr); /* This is only valid if nobody jumps into the "dead" side */ #if 0 /* Simplify constant conditionals without even evaluating the false side */ if (expr->type == EXPR_VALUE) { struct statement *simple; simple = expr->value ? stmt->if_true : stmt->if_false; /* Nothing? */ if (!simple) { stmt->type = STMT_NONE; return 0; } expand_statement(simple); *stmt = *simple; return SIDE_EFFECTS; } #endif expand_statement(stmt->if_true); expand_statement(stmt->if_false); return SIDE_EFFECTS; } static int expand_asm_statement(struct statement *stmt) { struct asm_operand *op; int cost = 0; FOR_EACH_PTR(stmt->asm_outputs, op) { cost += expand_expression(op->expr); } END_FOR_EACH_PTR(op); FOR_EACH_PTR(stmt->asm_inputs, op) { cost += expand_expression(op->expr); } END_FOR_EACH_PTR(op); return cost; } /* * Expanding a compound statement is really just * about adding up the costs of each individual * statement. * * We also collapse a simple compound statement: * this would trigger for simple inline functions, * except we would have to check the "return" * symbol usage. Next time. */ static int expand_compound(struct statement *stmt) { struct statement *s, *last; int cost, statements; if (stmt->ret) expand_symbol(stmt->ret); last = stmt->args; cost = expand_statement(last); statements = last != NULL; FOR_EACH_PTR(stmt->stmts, s) { statements++; last = s; cost += expand_statement(s); } END_FOR_EACH_PTR(s); if (statements == 1 && !stmt->ret) *stmt = *last; return cost; } static int expand_statement(struct statement *stmt) { if (!stmt) return 0; switch (stmt->type) { case STMT_DECLARATION: { struct symbol *sym; FOR_EACH_PTR(stmt->declaration, sym) { expand_symbol(sym); } END_FOR_EACH_PTR(sym); return SIDE_EFFECTS; } case STMT_RETURN: expand_return_expression(stmt); return SIDE_EFFECTS; case STMT_EXPRESSION: return expand_expression(stmt->expression); case STMT_COMPOUND: return expand_compound(stmt); case STMT_IF: return expand_if_statement(stmt); case STMT_ITERATOR: expand_expression(stmt->iterator_pre_condition); expand_expression(stmt->iterator_post_condition); expand_statement(stmt->iterator_pre_statement); expand_statement(stmt->iterator_statement); expand_statement(stmt->iterator_post_statement); return SIDE_EFFECTS; case STMT_SWITCH: expand_expression(stmt->switch_expression); expand_statement(stmt->switch_statement); return SIDE_EFFECTS; case STMT_CASE: expand_const_expression(stmt->case_expression, "case statement"); expand_const_expression(stmt->case_to, "case statement"); expand_statement(stmt->case_statement); return SIDE_EFFECTS; case STMT_LABEL: expand_statement(stmt->label_statement); return SIDE_EFFECTS; case STMT_GOTO: expand_expression(stmt->goto_expression); return SIDE_EFFECTS; case STMT_NONE: break; case STMT_ASM: expand_asm_statement(stmt); break; case STMT_CONTEXT: expand_expression(stmt->expression); break; case STMT_RANGE: expand_expression(stmt->range_expression); expand_expression(stmt->range_low); expand_expression(stmt->range_high); break; } return SIDE_EFFECTS; } static inline int bad_integer_constant_expression(struct expression *expr) { if (!(expr->flags & CEF_ICE)) return 1; if (expr->taint & Taint_comma) return 1; return 0; } static long long __get_expression_value(struct expression *expr, int strict) { long long value, mask; struct symbol *ctype; if (!expr) return 0; ctype = evaluate_expression(expr); if (!ctype) { expression_error(expr, "bad constant expression type"); return 0; } expand_expression(expr); if (expr->type != EXPR_VALUE) { if (strict != 2) expression_error(expr, "bad constant expression"); return 0; } if ((strict == 1) && bad_integer_constant_expression(expr)) { expression_error(expr, "bad integer constant expression"); return 0; } value = expr->value; mask = 1ULL << (ctype->bit_size-1); if (value & mask) { while (ctype->type != SYM_BASETYPE) ctype = ctype->ctype.base_type; if (!(ctype->ctype.modifiers & MOD_UNSIGNED)) value = value | mask | ~(mask-1); } return value; } long long get_expression_value(struct expression *expr) { return __get_expression_value(expr, 0); } long long const_expression_value(struct expression *expr) { return __get_expression_value(expr, 1); } long long get_expression_value_silent(struct expression *expr) { return __get_expression_value(expr, 2); } int expr_truth_value(struct expression *expr) { const int saved = conservative; struct symbol *ctype; if (!expr) return 0; ctype = evaluate_expression(expr); if (!ctype) return -1; conservative = 1; expand_expression(expr); conservative = saved; redo: switch (expr->type) { case EXPR_COMMA: expr = expr->right; goto redo; case EXPR_VALUE: return expr->value != 0; case EXPR_FVALUE: return expr->fvalue != 0; default: return -1; } } int is_zero_constant(struct expression *expr) { const int saved = conservative; conservative = 1; expand_expression(expr); conservative = saved; return expr->type == EXPR_VALUE && !expr->value; }