// Copyright 2014 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "src/v8.h" #include "src/ic/ic.h" #include "src/ic/ic-state.h" namespace v8 { namespace internal { void ICUtility::Clear(Isolate* isolate, Address address, ConstantPoolArray* constant_pool) { IC::Clear(isolate, address, constant_pool); } CallICState::CallICState(ExtraICState extra_ic_state) : argc_(ArgcBits::decode(extra_ic_state)), call_type_(CallTypeBits::decode(extra_ic_state)) {} ExtraICState CallICState::GetExtraICState() const { ExtraICState extra_ic_state = ArgcBits::encode(argc_) | CallTypeBits::encode(call_type_); return extra_ic_state; } OStream& operator<<(OStream& os, const CallICState& s) { return os << "(args(" << s.arg_count() << "), " << (s.call_type() == CallICState::METHOD ? "METHOD" : "FUNCTION") << ", "; } BinaryOpICState::BinaryOpICState(Isolate* isolate, ExtraICState extra_ic_state) : isolate_(isolate) { op_ = static_cast(FIRST_TOKEN + OpField::decode(extra_ic_state)); mode_ = OverwriteModeField::decode(extra_ic_state); fixed_right_arg_ = Maybe(HasFixedRightArgField::decode(extra_ic_state), 1 << FixedRightArgValueField::decode(extra_ic_state)); left_kind_ = LeftKindField::decode(extra_ic_state); if (fixed_right_arg_.has_value) { right_kind_ = Smi::IsValid(fixed_right_arg_.value) ? SMI : INT32; } else { right_kind_ = RightKindField::decode(extra_ic_state); } result_kind_ = ResultKindField::decode(extra_ic_state); DCHECK_LE(FIRST_TOKEN, op_); DCHECK_LE(op_, LAST_TOKEN); } ExtraICState BinaryOpICState::GetExtraICState() const { ExtraICState extra_ic_state = OpField::encode(op_ - FIRST_TOKEN) | OverwriteModeField::encode(mode_) | LeftKindField::encode(left_kind_) | ResultKindField::encode(result_kind_) | HasFixedRightArgField::encode(fixed_right_arg_.has_value); if (fixed_right_arg_.has_value) { extra_ic_state = FixedRightArgValueField::update( extra_ic_state, WhichPowerOf2(fixed_right_arg_.value)); } else { extra_ic_state = RightKindField::update(extra_ic_state, right_kind_); } return extra_ic_state; } // static void BinaryOpICState::GenerateAheadOfTime( Isolate* isolate, void (*Generate)(Isolate*, const BinaryOpICState&)) { // TODO(olivf) We should investigate why adding stubs to the snapshot is so // expensive at runtime. When solved we should be able to add most binops to // the snapshot instead of hand-picking them. // Generated list of commonly used stubs #define GENERATE(op, left_kind, right_kind, result_kind, mode) \ do { \ BinaryOpICState state(isolate, op, mode); \ state.left_kind_ = left_kind; \ state.fixed_right_arg_.has_value = false; \ state.right_kind_ = right_kind; \ state.result_kind_ = result_kind; \ Generate(isolate, state); \ } while (false) GENERATE(Token::ADD, INT32, INT32, INT32, NO_OVERWRITE); GENERATE(Token::ADD, INT32, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::ADD, INT32, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, INT32, INT32, NUMBER, OVERWRITE_LEFT); GENERATE(Token::ADD, INT32, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, INT32, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::ADD, INT32, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::ADD, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::ADD, INT32, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::ADD, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::ADD, NUMBER, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); GENERATE(Token::ADD, NUMBER, INT32, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::ADD, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::ADD, NUMBER, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::ADD, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::ADD, SMI, INT32, INT32, NO_OVERWRITE); GENERATE(Token::ADD, SMI, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::ADD, SMI, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, SMI, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::ADD, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::ADD, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::ADD, SMI, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::ADD, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, INT32, INT32, INT32, NO_OVERWRITE); GENERATE(Token::BIT_AND, INT32, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_AND, INT32, INT32, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, INT32, INT32, SMI, NO_OVERWRITE); GENERATE(Token::BIT_AND, INT32, INT32, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::BIT_AND, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, INT32, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_AND, INT32, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_AND, INT32, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, NUMBER, INT32, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, NUMBER, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_AND, NUMBER, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, SMI, INT32, INT32, NO_OVERWRITE); GENERATE(Token::BIT_AND, SMI, INT32, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, SMI, NUMBER, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_AND, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_AND, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_AND, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, INT32, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, INT32, INT32, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, INT32, INT32, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::BIT_OR, INT32, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, INT32, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_OR, INT32, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, NO_OVERWRITE); GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, NUMBER, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, NUMBER, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_OR, NUMBER, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, SMI, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, SMI, INT32, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, SMI, INT32, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_OR, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_OR, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::BIT_XOR, INT32, INT32, INT32, NO_OVERWRITE); GENERATE(Token::BIT_XOR, INT32, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_XOR, INT32, INT32, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_XOR, INT32, INT32, SMI, NO_OVERWRITE); GENERATE(Token::BIT_XOR, INT32, INT32, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_XOR, INT32, NUMBER, SMI, NO_OVERWRITE); GENERATE(Token::BIT_XOR, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::BIT_XOR, INT32, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_XOR, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::BIT_XOR, NUMBER, INT32, INT32, NO_OVERWRITE); GENERATE(Token::BIT_XOR, NUMBER, SMI, INT32, NO_OVERWRITE); GENERATE(Token::BIT_XOR, NUMBER, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_XOR, SMI, INT32, INT32, NO_OVERWRITE); GENERATE(Token::BIT_XOR, SMI, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::BIT_XOR, SMI, INT32, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_XOR, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::BIT_XOR, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::BIT_XOR, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::DIV, INT32, INT32, INT32, NO_OVERWRITE); GENERATE(Token::DIV, INT32, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, INT32, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, INT32, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::DIV, INT32, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, NUMBER, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::DIV, NUMBER, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, SMI, INT32, INT32, NO_OVERWRITE); GENERATE(Token::DIV, SMI, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, SMI, INT32, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, SMI, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::DIV, SMI, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::DIV, SMI, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::DIV, SMI, SMI, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::DIV, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::DIV, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::DIV, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::MOD, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MOD, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::MOD, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::MUL, INT32, INT32, INT32, NO_OVERWRITE); GENERATE(Token::MUL, INT32, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, INT32, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, INT32, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MUL, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::MUL, INT32, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::MUL, INT32, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, NUMBER, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MUL, NUMBER, INT32, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::MUL, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MUL, NUMBER, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MUL, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::MUL, SMI, INT32, INT32, NO_OVERWRITE); GENERATE(Token::MUL, SMI, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::MUL, SMI, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, SMI, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MUL, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::MUL, SMI, SMI, INT32, NO_OVERWRITE); GENERATE(Token::MUL, SMI, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::MUL, SMI, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::MUL, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::MUL, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::MUL, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SAR, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::SAR, INT32, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SAR, INT32, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SAR, NUMBER, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SAR, NUMBER, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SAR, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::SAR, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SHL, INT32, SMI, INT32, NO_OVERWRITE); GENERATE(Token::SHL, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::SHL, INT32, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SHL, INT32, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SHL, NUMBER, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SHL, SMI, SMI, INT32, NO_OVERWRITE); GENERATE(Token::SHL, SMI, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::SHL, SMI, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::SHL, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SHL, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::SHL, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SHR, INT32, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SHR, INT32, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::SHR, INT32, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SHR, NUMBER, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SHR, NUMBER, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::SHR, NUMBER, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::SHR, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SHR, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::SHR, SMI, SMI, SMI, OVERWRITE_RIGHT); GENERATE(Token::SUB, INT32, INT32, INT32, NO_OVERWRITE); GENERATE(Token::SUB, INT32, INT32, INT32, OVERWRITE_LEFT); GENERATE(Token::SUB, INT32, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::SUB, INT32, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::SUB, INT32, SMI, INT32, OVERWRITE_LEFT); GENERATE(Token::SUB, INT32, SMI, INT32, OVERWRITE_RIGHT); GENERATE(Token::SUB, NUMBER, INT32, NUMBER, NO_OVERWRITE); GENERATE(Token::SUB, NUMBER, INT32, NUMBER, OVERWRITE_LEFT); GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::SUB, NUMBER, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::SUB, NUMBER, SMI, NUMBER, NO_OVERWRITE); GENERATE(Token::SUB, NUMBER, SMI, NUMBER, OVERWRITE_LEFT); GENERATE(Token::SUB, NUMBER, SMI, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::SUB, SMI, INT32, INT32, NO_OVERWRITE); GENERATE(Token::SUB, SMI, NUMBER, NUMBER, NO_OVERWRITE); GENERATE(Token::SUB, SMI, NUMBER, NUMBER, OVERWRITE_LEFT); GENERATE(Token::SUB, SMI, NUMBER, NUMBER, OVERWRITE_RIGHT); GENERATE(Token::SUB, SMI, SMI, SMI, NO_OVERWRITE); GENERATE(Token::SUB, SMI, SMI, SMI, OVERWRITE_LEFT); GENERATE(Token::SUB, SMI, SMI, SMI, OVERWRITE_RIGHT); #undef GENERATE #define GENERATE(op, left_kind, fixed_right_arg_value, result_kind, mode) \ do { \ BinaryOpICState state(isolate, op, mode); \ state.left_kind_ = left_kind; \ state.fixed_right_arg_.has_value = true; \ state.fixed_right_arg_.value = fixed_right_arg_value; \ state.right_kind_ = SMI; \ state.result_kind_ = result_kind; \ Generate(isolate, state); \ } while (false) GENERATE(Token::MOD, SMI, 2, SMI, NO_OVERWRITE); GENERATE(Token::MOD, SMI, 4, SMI, NO_OVERWRITE); GENERATE(Token::MOD, SMI, 4, SMI, OVERWRITE_LEFT); GENERATE(Token::MOD, SMI, 8, SMI, NO_OVERWRITE); GENERATE(Token::MOD, SMI, 16, SMI, OVERWRITE_LEFT); GENERATE(Token::MOD, SMI, 32, SMI, NO_OVERWRITE); GENERATE(Token::MOD, SMI, 2048, SMI, NO_OVERWRITE); #undef GENERATE } Type* BinaryOpICState::GetResultType(Zone* zone) const { Kind result_kind = result_kind_; if (HasSideEffects()) { result_kind = NONE; } else if (result_kind == GENERIC && op_ == Token::ADD) { return Type::Union(Type::Number(zone), Type::String(zone), zone); } else if (result_kind == NUMBER && op_ == Token::SHR) { return Type::Unsigned32(zone); } DCHECK_NE(GENERIC, result_kind); return KindToType(result_kind, zone); } OStream& operator<<(OStream& os, const BinaryOpICState& s) { os << "(" << Token::Name(s.op_); if (s.mode_ == OVERWRITE_LEFT) os << "_ReuseLeft"; else if (s.mode_ == OVERWRITE_RIGHT) os << "_ReuseRight"; if (s.CouldCreateAllocationMementos()) os << "_CreateAllocationMementos"; os << ":" << BinaryOpICState::KindToString(s.left_kind_) << "*"; if (s.fixed_right_arg_.has_value) { os << s.fixed_right_arg_.value; } else { os << BinaryOpICState::KindToString(s.right_kind_); } return os << "->" << BinaryOpICState::KindToString(s.result_kind_) << ")"; } void BinaryOpICState::Update(Handle left, Handle right, Handle result) { ExtraICState old_extra_ic_state = GetExtraICState(); left_kind_ = UpdateKind(left, left_kind_); right_kind_ = UpdateKind(right, right_kind_); int32_t fixed_right_arg_value = 0; bool has_fixed_right_arg = op_ == Token::MOD && right->ToInt32(&fixed_right_arg_value) && fixed_right_arg_value > 0 && base::bits::IsPowerOfTwo32(fixed_right_arg_value) && FixedRightArgValueField::is_valid(WhichPowerOf2(fixed_right_arg_value)) && (left_kind_ == SMI || left_kind_ == INT32) && (result_kind_ == NONE || !fixed_right_arg_.has_value); fixed_right_arg_ = Maybe(has_fixed_right_arg, fixed_right_arg_value); result_kind_ = UpdateKind(result, result_kind_); if (!Token::IsTruncatingBinaryOp(op_)) { Kind input_kind = Max(left_kind_, right_kind_); if (result_kind_ < input_kind && input_kind <= NUMBER) { result_kind_ = input_kind; } } // We don't want to distinguish INT32 and NUMBER for string add (because // NumberToString can't make use of this anyway). if (left_kind_ == STRING && right_kind_ == INT32) { DCHECK_EQ(STRING, result_kind_); DCHECK_EQ(Token::ADD, op_); right_kind_ = NUMBER; } else if (right_kind_ == STRING && left_kind_ == INT32) { DCHECK_EQ(STRING, result_kind_); DCHECK_EQ(Token::ADD, op_); left_kind_ = NUMBER; } // Reset overwrite mode unless we can actually make use of it, or may be able // to make use of it at some point in the future. if ((mode_ == OVERWRITE_LEFT && left_kind_ > NUMBER) || (mode_ == OVERWRITE_RIGHT && right_kind_ > NUMBER) || result_kind_ > NUMBER) { mode_ = NO_OVERWRITE; } if (old_extra_ic_state == GetExtraICState()) { // Tagged operations can lead to non-truncating HChanges if (left->IsUndefined() || left->IsBoolean()) { left_kind_ = GENERIC; } else { DCHECK(right->IsUndefined() || right->IsBoolean()); right_kind_ = GENERIC; } } } BinaryOpICState::Kind BinaryOpICState::UpdateKind(Handle object, Kind kind) const { Kind new_kind = GENERIC; bool is_truncating = Token::IsTruncatingBinaryOp(op()); if (object->IsBoolean() && is_truncating) { // Booleans will be automatically truncated by HChange. new_kind = INT32; } else if (object->IsUndefined()) { // Undefined will be automatically truncated by HChange. new_kind = is_truncating ? INT32 : NUMBER; } else if (object->IsSmi()) { new_kind = SMI; } else if (object->IsHeapNumber()) { double value = Handle::cast(object)->value(); new_kind = IsInt32Double(value) ? INT32 : NUMBER; } else if (object->IsString() && op() == Token::ADD) { new_kind = STRING; } if (new_kind == INT32 && SmiValuesAre32Bits()) { new_kind = NUMBER; } if (kind != NONE && ((new_kind <= NUMBER && kind > NUMBER) || (new_kind > NUMBER && kind <= NUMBER))) { new_kind = GENERIC; } return Max(kind, new_kind); } // static const char* BinaryOpICState::KindToString(Kind kind) { switch (kind) { case NONE: return "None"; case SMI: return "Smi"; case INT32: return "Int32"; case NUMBER: return "Number"; case STRING: return "String"; case GENERIC: return "Generic"; } UNREACHABLE(); return NULL; } // static Type* BinaryOpICState::KindToType(Kind kind, Zone* zone) { switch (kind) { case NONE: return Type::None(zone); case SMI: return Type::SignedSmall(zone); case INT32: return Type::Signed32(zone); case NUMBER: return Type::Number(zone); case STRING: return Type::String(zone); case GENERIC: return Type::Any(zone); } UNREACHABLE(); return NULL; } const char* CompareICState::GetStateName(State state) { switch (state) { case UNINITIALIZED: return "UNINITIALIZED"; case SMI: return "SMI"; case NUMBER: return "NUMBER"; case INTERNALIZED_STRING: return "INTERNALIZED_STRING"; case STRING: return "STRING"; case UNIQUE_NAME: return "UNIQUE_NAME"; case OBJECT: return "OBJECT"; case KNOWN_OBJECT: return "KNOWN_OBJECT"; case GENERIC: return "GENERIC"; } UNREACHABLE(); return NULL; } Type* CompareICState::StateToType(Zone* zone, State state, Handle map) { switch (state) { case UNINITIALIZED: return Type::None(zone); case SMI: return Type::SignedSmall(zone); case NUMBER: return Type::Number(zone); case STRING: return Type::String(zone); case INTERNALIZED_STRING: return Type::InternalizedString(zone); case UNIQUE_NAME: return Type::UniqueName(zone); case OBJECT: return Type::Receiver(zone); case KNOWN_OBJECT: return map.is_null() ? Type::Receiver(zone) : Type::Class(map, zone); case GENERIC: return Type::Any(zone); } UNREACHABLE(); return NULL; } CompareICState::State CompareICState::NewInputState(State old_state, Handle value) { switch (old_state) { case UNINITIALIZED: if (value->IsSmi()) return SMI; if (value->IsHeapNumber()) return NUMBER; if (value->IsInternalizedString()) return INTERNALIZED_STRING; if (value->IsString()) return STRING; if (value->IsSymbol()) return UNIQUE_NAME; if (value->IsJSObject()) return OBJECT; break; case SMI: if (value->IsSmi()) return SMI; if (value->IsHeapNumber()) return NUMBER; break; case NUMBER: if (value->IsNumber()) return NUMBER; break; case INTERNALIZED_STRING: if (value->IsInternalizedString()) return INTERNALIZED_STRING; if (value->IsString()) return STRING; if (value->IsSymbol()) return UNIQUE_NAME; break; case STRING: if (value->IsString()) return STRING; break; case UNIQUE_NAME: if (value->IsUniqueName()) return UNIQUE_NAME; break; case OBJECT: if (value->IsJSObject()) return OBJECT; break; case GENERIC: break; case KNOWN_OBJECT: UNREACHABLE(); break; } return GENERIC; } // static CompareICState::State CompareICState::TargetState( State old_state, State old_left, State old_right, Token::Value op, bool has_inlined_smi_code, Handle x, Handle y) { switch (old_state) { case UNINITIALIZED: if (x->IsSmi() && y->IsSmi()) return SMI; if (x->IsNumber() && y->IsNumber()) return NUMBER; if (Token::IsOrderedRelationalCompareOp(op)) { // Ordered comparisons treat undefined as NaN, so the // NUMBER stub will do the right thing. if ((x->IsNumber() && y->IsUndefined()) || (y->IsNumber() && x->IsUndefined())) { return NUMBER; } } if (x->IsInternalizedString() && y->IsInternalizedString()) { // We compare internalized strings as plain ones if we need to determine // the order in a non-equality compare. return Token::IsEqualityOp(op) ? INTERNALIZED_STRING : STRING; } if (x->IsString() && y->IsString()) return STRING; if (!Token::IsEqualityOp(op)) return GENERIC; if (x->IsUniqueName() && y->IsUniqueName()) return UNIQUE_NAME; if (x->IsJSObject() && y->IsJSObject()) { if (Handle::cast(x)->map() == Handle::cast(y)->map()) { return KNOWN_OBJECT; } else { return OBJECT; } } return GENERIC; case SMI: return x->IsNumber() && y->IsNumber() ? NUMBER : GENERIC; case INTERNALIZED_STRING: DCHECK(Token::IsEqualityOp(op)); if (x->IsString() && y->IsString()) return STRING; if (x->IsUniqueName() && y->IsUniqueName()) return UNIQUE_NAME; return GENERIC; case NUMBER: // If the failure was due to one side changing from smi to heap number, // then keep the state (if other changed at the same time, we will get // a second miss and then go to generic). if (old_left == SMI && x->IsHeapNumber()) return NUMBER; if (old_right == SMI && y->IsHeapNumber()) return NUMBER; return GENERIC; case KNOWN_OBJECT: DCHECK(Token::IsEqualityOp(op)); if (x->IsJSObject() && y->IsJSObject()) { return OBJECT; } return GENERIC; case STRING: case UNIQUE_NAME: case OBJECT: case GENERIC: return GENERIC; } UNREACHABLE(); return GENERIC; // Make the compiler happy. } } } // namespace v8::internal