/** * Adjust the size of a node representing a stack alloc to a certain * stack_alignment. * * @param size the node containing the non-aligned size * @param block the block where new nodes are allocated on * @return a node representing the aligned size */ static ir_node *adjust_alloc_size(dbg_info *dbgi, ir_node *size, ir_node *block) { /* Example: po2_alignment 4 (align to 16 bytes): * size = (size+15) & 0xfff...f8 */ ir_mode *mode = get_irn_mode(size); ir_graph *irg = get_irn_irg(block); ir_tarval *allone = get_mode_all_one(mode); ir_tarval *shr = tarval_shr_unsigned(allone, po2_stack_alignment); ir_tarval *mask = tarval_shl_unsigned(shr, po2_stack_alignment); ir_tarval *invmask = tarval_not(mask); ir_node *addv = new_r_Const(irg, invmask); ir_node *add = new_rd_Add(dbgi, block, size, addv); ir_node *maskc = new_r_Const(irg, mask); ir_node *and = new_rd_And(dbgi, block, add, maskc); return and; }
static void check_mode(ir_mode *mode) { ir_tarval *zero = get_mode_null(mode); ir_tarval *minus_zero = tarval_neg(zero); ir_tarval *min = get_mode_min(mode); ir_tarval *max = get_mode_max(mode); ir_tarval *inf = get_mode_infinite(mode); ir_tarval *minus_inf = tarval_neg(inf); ir_tarval *one = get_mode_one(mode); ir_tarval *minus_one = tarval_neg(one); /* some random arithmetics */ ir_tarval *int_zero = get_mode_null(mode_Is); ir_tarval *int_one = get_mode_one(mode_Is); ir_tarval *int_minus_one = get_mode_all_one(mode_Is); ir_tarval *int_min = get_mode_min(mode_Is); ir_tarval *int_max = get_mode_max(mode_Is); assert(tarval_convert_to(zero, mode_Is) == int_zero); assert(tarval_convert_to(minus_zero, mode_Is) == int_zero); assert(tarval_convert_to(one, mode_Is) == int_one); assert(tarval_convert_to(minus_one, mode_Is) == int_minus_one); assert(tarval_convert_to(min, mode_Is) == int_min); assert(tarval_convert_to(max, mode_Is) == int_max); assert(tarval_convert_to(inf, mode_Is) == int_max); assert(tarval_convert_to(minus_inf, mode_Is) == int_min); static const char *const ints[] = { "0", "1", "-1", "12345", "2", "4", "8", "16", "32", "64", "128", "256", "512", "1024", "2048", "127", "2047" }; for (unsigned i = 0; i < ARRAY_SIZE(ints); ++i) { const char *str = ints[i]; ir_tarval *flt = new_tarval_from_str(str, strlen(str), mode); ir_tarval *intt = new_tarval_from_str(str, strlen(str), mode_Is); assert(tarval_convert_to(flt, mode_Is) == intt); assert(tarval_convert_to(intt, mode) == flt); } }
bool enum_bitfield_big_enough(enum_t *enume, type_t *base_type, unsigned bitfield_size) { ir_mode *mode = get_ir_mode_storage(base_type); ir_tarval *max = get_mode_max(mode); ir_tarval *min = get_mode_min(mode); bool is_signed = is_type_signed(base_type); unsigned mode_size = get_mode_size_bits(mode); unsigned shift_amount = mode_size - bitfield_size + is_signed; ir_tarval *adjusted_max; ir_tarval *adjusted_min; /* corner case: signed mode with just sign bit results in shift_amount * being as big as mode_size triggering "modulo shift" which is not what * we want here. */ if (shift_amount >= mode_size) { assert(bitfield_size == 1 && mode_is_signed(mode)); adjusted_max = get_mode_null(mode); adjusted_min = get_mode_all_one(mode); } else { adjusted_max = tarval_shr_unsigned(max, shift_amount); adjusted_min = tarval_shrs_unsigned(min, shift_amount); } for (entity_t *entry = enume->first_value; entry != NULL && entry->kind == ENTITY_ENUM_VALUE; entry = entry->base.next) { ir_tarval *tv = get_enum_value(&entry->enum_value); if (tv == NULL) continue; ir_tarval *tvc = tarval_convert_to(tv, mode); if (tarval_cmp(tvc, adjusted_min) == ir_relation_less || tarval_cmp(tvc, adjusted_max) == ir_relation_greater) { return false; } } return true; }
void x86_create_address_mode(x86_address_t *addr, ir_node *node, x86_create_am_flags_t flags) { addr->imm.kind = X86_IMM_VALUE; if (eat_immediate(addr, node, true)) { addr->variant = addr->ip_base ? X86_ADDR_RIP : X86_ADDR_JUST_IMM; return; } assert(!addr->ip_base); if (!(flags & x86_create_am_force) && x86_is_non_address_mode_node(node) && (!(flags & x86_create_am_double_use) || get_irn_n_edges(node) > 2)) { addr->variant = X86_ADDR_BASE; addr->base = node; return; } ir_node *eat_imms = eat_immediates(addr, node, flags, false); if (eat_imms != node) { if (flags & x86_create_am_force) eat_imms = be_skip_downconv(eat_imms, true); node = eat_imms; if (x86_is_non_address_mode_node(node)) { addr->variant = X86_ADDR_BASE; addr->base = node; return; } } /* starting point Add, Sub or Shl, FrameAddr */ if (is_Shl(node)) { /* We don't want to eat add x, x as shl here, so only test for real Shl * instructions, because we want the former as Lea x, x, not Shl x, 1 */ if (eat_shl(addr, node)) { addr->variant = X86_ADDR_INDEX; return; } } else if (eat_immediate(addr, node, true)) { /* we can hit this case in x86_create_am_force mode */ addr->variant = addr->ip_base ? X86_ADDR_RIP : X86_ADDR_JUST_IMM; return; } else if (is_Add(node)) { ir_node *left = get_Add_left(node); ir_node *right = get_Add_right(node); if (flags & x86_create_am_force) { left = be_skip_downconv(left, true); right = be_skip_downconv(right, true); } left = eat_immediates(addr, left, flags, false); right = eat_immediates(addr, right, flags, false); if (eat_shl(addr, left)) { left = NULL; } else if (eat_shl(addr, right)) { right = NULL; } /* (x & 0xFFFFFFFC) + (x >> 2) -> lea(x >> 2, x >> 2, 4) */ if (left != NULL && right != NULL) { ir_node *and; ir_node *shr; if (is_And(left) && (is_Shr(right) || is_Shrs(right))) { and = left; shr = right; goto tryit; } if (is_And(right) && (is_Shr(left) || is_Shrs(left))) { and = right; shr = left; tryit: if (get_And_left(and) == get_binop_left(shr)) { ir_node *and_right = get_And_right(and); ir_node *shr_right = get_binop_right(shr); if (is_Const(and_right) && is_Const(shr_right)) { ir_tarval *and_mask = get_Const_tarval(and_right); ir_tarval *shift_amount = get_Const_tarval(shr_right); ir_mode *mode = get_irn_mode(and); ir_tarval *all_one = get_mode_all_one(mode); ir_tarval *shift_mask = tarval_shl(tarval_shr(all_one, shift_amount), shift_amount); long val = get_tarval_long(shift_amount); if (and_mask == shift_mask && val >= 0 && val <= 3) { addr->variant = X86_ADDR_BASE_INDEX; addr->base = shr; addr->index = shr; addr->scale = val; return; } } } } } if (left != NULL) { ir_node *base = addr->base; if (base == NULL) { addr->variant = addr->index != NULL ? X86_ADDR_BASE_INDEX : X86_ADDR_BASE; addr->base = left; } else { addr->variant = X86_ADDR_BASE_INDEX; assert(addr->index == NULL && addr->scale == 0); assert(right == NULL); /* esp must be used as base */ if (is_Proj(left) && is_Start(get_Proj_pred(left))) { addr->index = base; addr->base = left; } else { addr->index = left; } } } if (right != NULL) { ir_node *base = addr->base; if (base == NULL) { addr->variant = addr->index != NULL ? X86_ADDR_BASE_INDEX : X86_ADDR_BASE; addr->base = right; } else { addr->variant = X86_ADDR_BASE_INDEX; assert(addr->index == NULL && addr->scale == 0); /* esp must be used as base */ if (is_Proj(right) && is_Start(get_Proj_pred(right))) { addr->index = base; addr->base = right; } else { addr->index = right; } } } return; } addr->variant = X86_ADDR_BASE; addr->base = node; }