// 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/compiler/verifier.h" #include #include #include #include #include #include "src/bit-vector.h" #include "src/compiler/all-nodes.h" #include "src/compiler/common-operator.h" #include "src/compiler/graph.h" #include "src/compiler/js-operator.h" #include "src/compiler/node-properties.h" #include "src/compiler/node.h" #include "src/compiler/opcodes.h" #include "src/compiler/operator-properties.h" #include "src/compiler/operator.h" #include "src/compiler/schedule.h" #include "src/compiler/simplified-operator.h" #include "src/compiler/type-cache.h" #include "src/ostreams.h" namespace v8 { namespace internal { namespace compiler { class Verifier::Visitor { public: Visitor(Zone* z, Typing typed, CheckInputs check_inputs, CodeType code_type) : zone(z), typing(typed), check_inputs(check_inputs), code_type(code_type) {} void Check(Node* node, const AllNodes& all); Zone* zone; Typing typing; CheckInputs check_inputs; CodeType code_type; private: void CheckNotTyped(Node* node) { if (NodeProperties::IsTyped(node)) { std::ostringstream str; str << "TypeError: node #" << node->id() << ":" << *node->op() << " should never have a type"; FATAL("%s", str.str().c_str()); } } void CheckTypeIs(Node* node, Type type) { if (typing == TYPED && !NodeProperties::GetType(node).Is(type)) { std::ostringstream str; str << "TypeError: node #" << node->id() << ":" << *node->op() << " type " << NodeProperties::GetType(node) << " is not " << type; FATAL("%s", str.str().c_str()); } } void CheckTypeMaybe(Node* node, Type type) { if (typing == TYPED && !NodeProperties::GetType(node).Maybe(type)) { std::ostringstream str; str << "TypeError: node #" << node->id() << ":" << *node->op() << " type " << NodeProperties::GetType(node) << " must intersect " << type; FATAL("%s", str.str().c_str()); } } void CheckValueInputIs(Node* node, int i, Type type) { Node* input = NodeProperties::GetValueInput(node, i); if (typing == TYPED && !NodeProperties::GetType(input).Is(type)) { std::ostringstream str; str << "TypeError: node #" << node->id() << ":" << *node->op() << "(input @" << i << " = " << input->opcode() << ":" << input->op()->mnemonic() << ") type " << NodeProperties::GetType(input) << " is not " << type; FATAL("%s", str.str().c_str()); } } void CheckOutput(Node* node, Node* use, int count, const char* kind) { if (count <= 0) { std::ostringstream str; str << "GraphError: node #" << node->id() << ":" << *node->op() << " does not produce " << kind << " output used by node #" << use->id() << ":" << *use->op(); FATAL("%s", str.str().c_str()); } } }; void Verifier::Visitor::Check(Node* node, const AllNodes& all) { int value_count = node->op()->ValueInputCount(); int context_count = OperatorProperties::GetContextInputCount(node->op()); int frame_state_count = OperatorProperties::GetFrameStateInputCount(node->op()); int effect_count = node->op()->EffectInputCount(); int control_count = node->op()->ControlInputCount(); // Verify number of inputs matches up. int input_count = value_count + context_count + frame_state_count; if (check_inputs == kAll) { input_count += effect_count + control_count; } CHECK_EQ(input_count, node->InputCount()); // If this node has any effect outputs, make sure that it is // consumed as an effect input somewhere else. // TODO(mvstanton): support this kind of verification for WASM // compiles, too. if (code_type != kWasm && node->op()->EffectOutputCount() > 0) { int effect_edges = 0; for (Edge edge : node->use_edges()) { if (all.IsLive(edge.from()) && NodeProperties::IsEffectEdge(edge)) { effect_edges++; } } DCHECK_GT(effect_edges, 0); } // Verify that frame state has been inserted for the nodes that need it. for (int i = 0; i < frame_state_count; i++) { Node* frame_state = NodeProperties::GetFrameStateInput(node); CHECK(frame_state->opcode() == IrOpcode::kFrameState || // kFrameState uses Start as a sentinel. (node->opcode() == IrOpcode::kFrameState && frame_state->opcode() == IrOpcode::kStart)); } // Verify all value inputs actually produce a value. for (int i = 0; i < value_count; ++i) { Node* value = NodeProperties::GetValueInput(node, i); CheckOutput(value, node, value->op()->ValueOutputCount(), "value"); // Verify that only parameters and projections can have input nodes with // multiple outputs. CHECK(node->opcode() == IrOpcode::kParameter || node->opcode() == IrOpcode::kProjection || value->op()->ValueOutputCount() <= 1); } // Verify all context inputs are value nodes. for (int i = 0; i < context_count; ++i) { Node* context = NodeProperties::GetContextInput(node); CheckOutput(context, node, context->op()->ValueOutputCount(), "context"); } if (check_inputs == kAll) { // Verify all effect inputs actually have an effect. for (int i = 0; i < effect_count; ++i) { Node* effect = NodeProperties::GetEffectInput(node); CheckOutput(effect, node, effect->op()->EffectOutputCount(), "effect"); } // Verify all control inputs are control nodes. for (int i = 0; i < control_count; ++i) { Node* control = NodeProperties::GetControlInput(node, i); CheckOutput(control, node, control->op()->ControlOutputCount(), "control"); } // Verify that nodes that can throw either have both IfSuccess/IfException // projections as the only control uses or no projections at all. if (!node->op()->HasProperty(Operator::kNoThrow)) { Node* discovered_if_exception = nullptr; Node* discovered_if_success = nullptr; int total_number_of_control_uses = 0; for (Edge edge : node->use_edges()) { if (!NodeProperties::IsControlEdge(edge)) { continue; } total_number_of_control_uses++; Node* control_use = edge.from(); if (control_use->opcode() == IrOpcode::kIfSuccess) { CHECK_NULL(discovered_if_success); // Only one allowed. discovered_if_success = control_use; } if (control_use->opcode() == IrOpcode::kIfException) { CHECK_NULL(discovered_if_exception); // Only one allowed. discovered_if_exception = control_use; } } if (discovered_if_success && !discovered_if_exception) { FATAL( "#%d:%s should be followed by IfSuccess/IfException, but is " "only followed by single #%d:%s", node->id(), node->op()->mnemonic(), discovered_if_success->id(), discovered_if_success->op()->mnemonic()); } if (discovered_if_exception && !discovered_if_success) { FATAL( "#%d:%s should be followed by IfSuccess/IfException, but is " "only followed by single #%d:%s", node->id(), node->op()->mnemonic(), discovered_if_exception->id(), discovered_if_exception->op()->mnemonic()); } if (discovered_if_success || discovered_if_exception) { CHECK_EQ(2, total_number_of_control_uses); } } } switch (node->opcode()) { case IrOpcode::kStart: // Start has no inputs. CHECK_EQ(0, input_count); // Type is a tuple. // TODO(rossberg): Multiple outputs are currently typed as Internal. CheckTypeIs(node, Type::Internal()); break; case IrOpcode::kEnd: // End has no outputs. CHECK_EQ(0, node->op()->ValueOutputCount()); CHECK_EQ(0, node->op()->EffectOutputCount()); CHECK_EQ(0, node->op()->ControlOutputCount()); // All inputs are graph terminators. for (const Node* input : node->inputs()) { CHECK(IrOpcode::IsGraphTerminator(input->opcode())); } // Type is empty. CheckNotTyped(node); break; case IrOpcode::kDead: // Dead is never connected to the graph. UNREACHABLE(); case IrOpcode::kDeadValue: CheckValueInputIs(node, 0, Type::None()); CheckTypeIs(node, Type::None()); break; case IrOpcode::kUnreachable: CheckTypeIs(node, Type::None()); for (Edge edge : node->use_edges()) { Node* use = edge.from(); if (NodeProperties::IsValueEdge(edge) && all.IsLive(use)) { // {Unreachable} nodes can only be used by {DeadValue}, because they // don't actually produce a value. CHECK_EQ(IrOpcode::kDeadValue, use->opcode()); } } break; case IrOpcode::kBranch: { // Branch uses are IfTrue and IfFalse. int count_true = 0, count_false = 0; for (const Node* use : node->uses()) { CHECK(all.IsLive(use) && (use->opcode() == IrOpcode::kIfTrue || use->opcode() == IrOpcode::kIfFalse)); if (use->opcode() == IrOpcode::kIfTrue) ++count_true; if (use->opcode() == IrOpcode::kIfFalse) ++count_false; } CHECK_EQ(1, count_true); CHECK_EQ(1, count_false); // The condition must be a Boolean. CheckValueInputIs(node, 0, Type::Boolean()); // Type is empty. CheckNotTyped(node); break; } case IrOpcode::kIfTrue: case IrOpcode::kIfFalse: { Node* control = NodeProperties::GetControlInput(node, 0); CHECK_EQ(IrOpcode::kBranch, control->opcode()); // Type is empty. CheckNotTyped(node); break; } case IrOpcode::kIfSuccess: { // IfSuccess and IfException continuation only on throwing nodes. Node* input = NodeProperties::GetControlInput(node, 0); CHECK(!input->op()->HasProperty(Operator::kNoThrow)); // Type is empty. CheckNotTyped(node); break; } case IrOpcode::kIfException: { // IfSuccess and IfException continuation only on throwing nodes. Node* input = NodeProperties::GetControlInput(node, 0); CHECK(!input->op()->HasProperty(Operator::kNoThrow)); // Type can be anything. CheckTypeIs(node, Type::Any()); break; } case IrOpcode::kSwitch: { // Switch uses are Case and Default. int count_case = 0, count_default = 0; for (const Node* use : node->uses()) { CHECK(all.IsLive(use)); switch (use->opcode()) { case IrOpcode::kIfValue: { for (const Node* user : node->uses()) { if (user != use && user->opcode() == IrOpcode::kIfValue) { CHECK_NE(IfValueParametersOf(use->op()).value(), IfValueParametersOf(user->op()).value()); } } ++count_case; break; } case IrOpcode::kIfDefault: { ++count_default; break; } default: { FATAL("Switch #%d illegally used by #%d:%s", node->id(), use->id(), use->op()->mnemonic()); break; } } } CHECK_EQ(1, count_default); CHECK_EQ(node->op()->ControlOutputCount(), count_case + count_default); // Type is empty. CheckNotTyped(node); break; } case IrOpcode::kIfValue: case IrOpcode::kIfDefault: CHECK_EQ(IrOpcode::kSwitch, NodeProperties::GetControlInput(node)->opcode()); // Type is empty. CheckNotTyped(node); break; case IrOpcode::kLoop: { CHECK_EQ(control_count, input_count); // Type is empty. CheckNotTyped(node); // All loops need to be connected to a {Terminate} node to ensure they // stay connected to the graph end. bool has_terminate = false; for (const Node* use : node->uses()) { if (all.IsLive(use) && use->opcode() == IrOpcode::kTerminate) { has_terminate = true; break; } } CHECK(has_terminate); break; } case IrOpcode::kMerge: CHECK_EQ(control_count, input_count); // Type is empty. CheckNotTyped(node); break; case IrOpcode::kDeoptimizeIf: case IrOpcode::kDeoptimizeUnless: // Type is empty. CheckNotTyped(node); break; case IrOpcode::kTrapIf: case IrOpcode::kTrapUnless: // Type is empty. CheckNotTyped(node); break; case IrOpcode::kDeoptimize: case IrOpcode::kReturn: case IrOpcode::kThrow: // Deoptimize, Return and Throw uses are End. for (const Node* use : node->uses()) { if (all.IsLive(use)) { CHECK_EQ(IrOpcode::kEnd, use->opcode()); } } // Type is empty. CheckNotTyped(node); break; case IrOpcode::kTerminate: // Terminates take one loop and effect. CHECK_EQ(1, control_count); CHECK_EQ(1, effect_count); CHECK_EQ(2, input_count); CHECK_EQ(IrOpcode::kLoop, NodeProperties::GetControlInput(node)->opcode()); // Terminate uses are End. for (const Node* use : node->uses()) { if (all.IsLive(use)) { CHECK_EQ(IrOpcode::kEnd, use->opcode()); } } // Type is empty. CheckNotTyped(node); break; case IrOpcode::kOsrNormalEntry: case IrOpcode::kOsrLoopEntry: // Osr entries take one control and effect. CHECK_EQ(1, control_count); CHECK_EQ(1, effect_count); CHECK_EQ(2, input_count); // Type is empty. CheckNotTyped(node); break; // Common operators // ---------------- case IrOpcode::kParameter: { // Parameters have the start node as inputs. CHECK_EQ(1, input_count); // Parameter has an input that produces enough values. int const index = ParameterIndexOf(node->op()); Node* const start = NodeProperties::GetValueInput(node, 0); CHECK_EQ(IrOpcode::kStart, start->opcode()); // Currently, parameter indices start at -1 instead of 0. CHECK_LE(-1, index); CHECK_LT(index + 1, start->op()->ValueOutputCount()); // Type can be anything. CheckTypeIs(node, Type::Any()); break; } case IrOpcode::kInt32Constant: // TODO(turbofan): rename Word32Constant? case IrOpcode::kInt64Constant: // TODO(turbofan): rename Word64Constant? case IrOpcode::kFloat32Constant: case IrOpcode::kFloat64Constant: case IrOpcode::kRelocatableInt32Constant: case IrOpcode::kRelocatableInt64Constant: // Constants have no inputs. CHECK_EQ(0, input_count); // Type is empty. CheckNotTyped(node); break; case IrOpcode::kNumberConstant: // Constants have no inputs. CHECK_EQ(0, input_count); // Type is a number. CheckTypeIs(node, Type::Number()); break; case IrOpcode::kHeapConstant: // Constants have no inputs. CHECK_EQ(0, input_count); // Type is anything. CheckTypeIs(node, Type::Any()); break; case IrOpcode::kExternalConstant: case IrOpcode::kPointerConstant: // Constants have no inputs. CHECK_EQ(0, input_count); // Type is an external pointer. CheckTypeIs(node, Type::ExternalPointer()); break; case IrOpcode::kOsrValue: // OSR values have a value and a control input. CHECK_EQ(1, control_count); CHECK_EQ(1, input_count); // Type is merged from other values in the graph and could be any. CheckTypeIs(node, Type::Any()); break; case IrOpcode::kProjection: { // Projection has an input that produces enough values. int index = static_cast(ProjectionIndexOf(node->op())); Node* input = NodeProperties::GetValueInput(node, 0); CHECK_GT(input->op()->ValueOutputCount(), index); // Type can be anything. // TODO(rossberg): Introduce tuple types for this. // TODO(titzer): Convince rossberg not to. CheckTypeIs(node, Type::Any()); break; } case IrOpcode::kSelect: { CHECK_EQ(0, effect_count); CHECK_EQ(0, control_count); CHECK_EQ(3, value_count); // The condition must be a Boolean. CheckValueInputIs(node, 0, Type::Boolean()); // Type can be anything. CheckTypeIs(node, Type::Any()); break; } case IrOpcode::kPhi: { // Phi input count matches parent control node. CHECK_EQ(0, effect_count); CHECK_EQ(1, control_count); Node* control = NodeProperties::GetControlInput(node, 0); CHECK_EQ(value_count, control->op()->ControlInputCount()); CHECK_EQ(input_count, 1 + value_count); // Type must be subsumed by all input types. // TODO(rossberg): for now at least, narrowing does not really hold. /* for (int i = 0; i < value_count; ++i) { CHECK(type_of(ValueInput(node, i))->Is(type_of(node))); } */ break; } case IrOpcode::kInductionVariablePhi: { // This is only a temporary node for the typer. UNREACHABLE(); break; } case IrOpcode::kEffectPhi: { // EffectPhi input count matches parent control node. CHECK_EQ(0, value_count); CHECK_EQ(1, control_count); Node* control = NodeProperties::GetControlInput(node, 0); CHECK_EQ(effect_count, control->op()->ControlInputCount()); CHECK_EQ(input_count, 1 + effect_count); // If the control input is a Merge, then make sure that at least one // of it's usages is non-phi. if (control->opcode() == IrOpcode::kMerge) { bool non_phi_use_found = false; for (Node* use : control->uses()) { if (all.IsLive(use) && use->opcode() != IrOpcode::kEffectPhi && use->opcode() != IrOpcode::kPhi) { non_phi_use_found = true; } } CHECK(non_phi_use_found); } break; } case IrOpcode::kLoopExit: { CHECK_EQ(2, control_count); Node* loop = NodeProperties::GetControlInput(node, 1); CHECK_EQ(IrOpcode::kLoop, loop->opcode()); break; } case IrOpcode::kLoopExitValue: { CHECK_EQ(1, control_count); Node* loop_exit = NodeProperties::GetControlInput(node, 0); CHECK_EQ(IrOpcode::kLoopExit, loop_exit->opcode()); break; } case IrOpcode::kLoopExitEffect: { CHECK_EQ(1, control_count); Node* loop_exit = NodeProperties::GetControlInput(node, 0); CHECK_EQ(IrOpcode::kLoopExit, loop_exit->opcode()); break; } case IrOpcode::kCheckpoint: // Type is empty. CheckNotTyped(node); break; case IrOpcode::kBeginRegion: // TODO(rossberg): what are the constraints on these? break; case IrOpcode::kFinishRegion: { // TODO(rossberg): what are the constraints on these? // Type must be subsumed by input type. if (typing == TYPED) { Node* val = NodeProperties::GetValueInput(node, 0); CHECK(NodeProperties::GetType(val).Is(NodeProperties::GetType(node))); } break; } case IrOpcode::kFrameState: { // TODO(jarin): what are the constraints on these? CHECK_EQ(5, value_count); CHECK_EQ(0, control_count); CHECK_EQ(0, effect_count); CHECK_EQ(6, input_count); // Check that the parameters and registers are kStateValues or // kTypedStateValues. for (int i = 0; i < 2; ++i) { CHECK(NodeProperties::GetValueInput(node, i)->opcode() == IrOpcode::kStateValues || NodeProperties::GetValueInput(node, i)->opcode() == IrOpcode::kTypedStateValues); } // The accumulator (InputAt(2)) cannot be kStateValues, but it can be // kTypedStateValues (to signal the type). Once AST graph builder // is removed, we should check this here. Until then, AST graph // builder can generate expression stack as InputAt(2), which can // still be kStateValues. break; } case IrOpcode::kObjectId: CheckTypeIs(node, Type::Object()); break; case IrOpcode::kStateValues: case IrOpcode::kTypedStateValues: case IrOpcode::kArgumentsElementsState: case IrOpcode::kArgumentsLengthState: case IrOpcode::kObjectState: case IrOpcode::kTypedObjectState: // TODO(jarin): what are the constraints on these? break; case IrOpcode::kCall: case IrOpcode::kCallWithCallerSavedRegisters: // TODO(rossberg): what are the constraints on these? break; case IrOpcode::kTailCall: // TODO(bmeurer): what are the constraints on these? break; // JavaScript operators // -------------------- case IrOpcode::kJSEqual: case IrOpcode::kJSStrictEqual: case IrOpcode::kJSLessThan: case IrOpcode::kJSGreaterThan: case IrOpcode::kJSLessThanOrEqual: case IrOpcode::kJSGreaterThanOrEqual: // Type is Boolean. CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kJSAdd: CheckTypeIs(node, Type::NumericOrString()); break; case IrOpcode::kJSBitwiseOr: case IrOpcode::kJSBitwiseXor: case IrOpcode::kJSBitwiseAnd: case IrOpcode::kJSShiftLeft: case IrOpcode::kJSShiftRight: case IrOpcode::kJSShiftRightLogical: case IrOpcode::kJSSubtract: case IrOpcode::kJSMultiply: case IrOpcode::kJSDivide: case IrOpcode::kJSModulus: case IrOpcode::kJSExponentiate: case IrOpcode::kJSBitwiseNot: case IrOpcode::kJSDecrement: case IrOpcode::kJSIncrement: case IrOpcode::kJSNegate: CheckTypeIs(node, Type::Numeric()); break; case IrOpcode::kToBoolean: // Type is Boolean. CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kJSToLength: CheckTypeIs(node, Type::Range(0, kMaxSafeInteger, zone)); break; case IrOpcode::kJSToName: // Type is Name. CheckTypeIs(node, Type::Name()); break; case IrOpcode::kJSToNumber: case IrOpcode::kJSToNumberConvertBigInt: // Type is Number. CheckTypeIs(node, Type::Number()); break; case IrOpcode::kJSToNumeric: // Type is Numeric. CheckTypeIs(node, Type::Numeric()); break; case IrOpcode::kJSToString: // Type is String. CheckTypeIs(node, Type::String()); break; case IrOpcode::kJSToObject: // Type is Receiver. CheckTypeIs(node, Type::Receiver()); break; case IrOpcode::kJSParseInt: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kJSRegExpTest: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::String()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kJSCreate: // Type is Object. CheckTypeIs(node, Type::Object()); break; case IrOpcode::kJSCreateArguments: // Type is Array \/ OtherObject. CheckTypeIs(node, Type::ArrayOrOtherObject()); break; case IrOpcode::kJSCreateArray: // Type is Array. CheckTypeIs(node, Type::Array()); break; case IrOpcode::kJSCreateArrayIterator: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateCollectionIterator: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateBoundFunction: // Type is BoundFunction. CheckTypeIs(node, Type::BoundFunction()); break; case IrOpcode::kJSCreateClosure: // Type is Function. CheckTypeIs(node, Type::Function()); break; case IrOpcode::kJSCreateIterResultObject: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateStringIterator: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateKeyValueArray: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateObject: // Type is Object. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreatePromise: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateTypedArray: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSCreateLiteralArray: // Type is Array. CheckTypeIs(node, Type::Array()); break; case IrOpcode::kJSCreateEmptyLiteralArray: // Type is Array. CheckTypeIs(node, Type::Array()); break; case IrOpcode::kJSCreateArrayFromIterable: // Type is Array. CheckTypeIs(node, Type::Array()); break; case IrOpcode::kJSCreateLiteralObject: case IrOpcode::kJSCreateEmptyLiteralObject: case IrOpcode::kJSCloneObject: case IrOpcode::kJSCreateLiteralRegExp: // Type is OtherObject. CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSLoadProperty: // Type can be anything. CheckTypeIs(node, Type::Any()); CHECK(PropertyAccessOf(node->op()).feedback().IsValid()); break; case IrOpcode::kJSLoadNamed: // Type can be anything. CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSLoadGlobal: // Type can be anything. CheckTypeIs(node, Type::Any()); CHECK(LoadGlobalParametersOf(node->op()).feedback().IsValid()); break; case IrOpcode::kJSStoreProperty: // Type is empty. CheckNotTyped(node); CHECK(PropertyAccessOf(node->op()).feedback().IsValid()); break; case IrOpcode::kJSStoreNamed: // Type is empty. CheckNotTyped(node); break; case IrOpcode::kJSStoreGlobal: // Type is empty. CheckNotTyped(node); CHECK(StoreGlobalParametersOf(node->op()).feedback().IsValid()); break; case IrOpcode::kJSStoreNamedOwn: // Type is empty. CheckNotTyped(node); CHECK(StoreNamedOwnParametersOf(node->op()).feedback().IsValid()); break; case IrOpcode::kJSStoreDataPropertyInLiteral: case IrOpcode::kJSStoreInArrayLiteral: // Type is empty. CheckNotTyped(node); CHECK(FeedbackParameterOf(node->op()).feedback().IsValid()); break; case IrOpcode::kJSDeleteProperty: case IrOpcode::kJSHasProperty: case IrOpcode::kJSHasInPrototypeChain: case IrOpcode::kJSInstanceOf: case IrOpcode::kJSOrdinaryHasInstance: // Type is Boolean. CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kTypeOf: // Type is InternalizedString. CheckTypeIs(node, Type::InternalizedString()); break; case IrOpcode::kJSGetSuperConstructor: // We don't check the input for Type::Function because // this_function can be context-allocated. // Any -> Callable. CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Callable()); break; case IrOpcode::kJSLoadContext: // Type can be anything. CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSStoreContext: // Type is empty. CheckNotTyped(node); break; case IrOpcode::kJSCreateFunctionContext: case IrOpcode::kJSCreateCatchContext: case IrOpcode::kJSCreateWithContext: case IrOpcode::kJSCreateBlockContext: { // Type is Context, and operand is Internal. Node* context = NodeProperties::GetContextInput(node); // TODO(bmeurer): This should say CheckTypeIs, but we don't have type // OtherInternal on certain contexts, i.e. those from OsrValue inputs. CheckTypeMaybe(context, Type::OtherInternal()); CheckTypeIs(node, Type::OtherInternal()); break; } case IrOpcode::kJSConstructForwardVarargs: case IrOpcode::kJSConstruct: case IrOpcode::kJSConstructWithArrayLike: case IrOpcode::kJSConstructWithSpread: // Type is Receiver. CheckTypeIs(node, Type::Receiver()); break; case IrOpcode::kJSCallForwardVarargs: case IrOpcode::kJSCall: case IrOpcode::kJSCallWithArrayLike: case IrOpcode::kJSCallWithSpread: case IrOpcode::kJSCallRuntime: // Type can be anything. CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSForInEnumerate: // Any -> OtherInternal. CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::OtherInternal()); break; case IrOpcode::kJSForInPrepare: // TODO(bmeurer): What are the constraints on thse? CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSForInNext: CheckTypeIs(node, Type::Union(Type::Name(), Type::Undefined(), zone)); break; case IrOpcode::kJSLoadMessage: case IrOpcode::kJSStoreMessage: break; case IrOpcode::kJSLoadModule: CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSStoreModule: CheckNotTyped(node); break; case IrOpcode::kJSGeneratorStore: CheckNotTyped(node); break; case IrOpcode::kJSCreateGeneratorObject: CheckTypeIs(node, Type::OtherObject()); break; case IrOpcode::kJSGeneratorRestoreContinuation: CheckTypeIs(node, Type::SignedSmall()); break; case IrOpcode::kJSGeneratorRestoreContext: CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSGeneratorRestoreRegister: CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSGeneratorRestoreInputOrDebugPos: CheckTypeIs(node, Type::Any()); break; case IrOpcode::kJSStackCheck: case IrOpcode::kJSDebugger: // Type is empty. CheckNotTyped(node); break; case IrOpcode::kJSFulfillPromise: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckTypeIs(node, Type::Undefined()); break; case IrOpcode::kJSPerformPromiseThen: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckValueInputIs(node, 2, Type::Any()); CheckValueInputIs(node, 3, Type::Any()); CheckTypeIs(node, Type::Receiver()); break; case IrOpcode::kJSPromiseResolve: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckTypeIs(node, Type::Receiver()); break; case IrOpcode::kJSRejectPromise: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckValueInputIs(node, 2, Type::Any()); CheckTypeIs(node, Type::Undefined()); break; case IrOpcode::kJSResolvePromise: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckTypeIs(node, Type::Undefined()); break; case IrOpcode::kJSObjectIsArray: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kComment: case IrOpcode::kDebugAbort: case IrOpcode::kDebugBreak: case IrOpcode::kRetain: case IrOpcode::kUnsafePointerAdd: case IrOpcode::kRuntimeAbort: CheckNotTyped(node); break; // Simplified operators // ------------------------------- case IrOpcode::kBooleanNot: // Boolean -> Boolean CheckValueInputIs(node, 0, Type::Boolean()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberEqual: // (Number, Number) -> Boolean CheckValueInputIs(node, 0, Type::Number()); CheckValueInputIs(node, 1, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberLessThan: case IrOpcode::kNumberLessThanOrEqual: // (Number, Number) -> Boolean CheckValueInputIs(node, 0, Type::Number()); CheckValueInputIs(node, 1, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kSpeculativeSafeIntegerAdd: case IrOpcode::kSpeculativeSafeIntegerSubtract: case IrOpcode::kSpeculativeNumberAdd: case IrOpcode::kSpeculativeNumberSubtract: case IrOpcode::kSpeculativeNumberMultiply: case IrOpcode::kSpeculativeNumberDivide: case IrOpcode::kSpeculativeNumberModulus: CheckTypeIs(node, Type::Number()); break; case IrOpcode::kSpeculativeNumberEqual: case IrOpcode::kSpeculativeNumberLessThan: case IrOpcode::kSpeculativeNumberLessThanOrEqual: CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberAdd: case IrOpcode::kNumberSubtract: case IrOpcode::kNumberMultiply: case IrOpcode::kNumberDivide: // (Number, Number) -> Number CheckValueInputIs(node, 0, Type::Number()); CheckValueInputIs(node, 1, Type::Number()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kNumberModulus: // (Number, Number) -> Number CheckValueInputIs(node, 0, Type::Number()); CheckValueInputIs(node, 1, Type::Number()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kNumberBitwiseOr: case IrOpcode::kNumberBitwiseXor: case IrOpcode::kNumberBitwiseAnd: // (Signed32, Signed32) -> Signed32 CheckValueInputIs(node, 0, Type::Signed32()); CheckValueInputIs(node, 1, Type::Signed32()); CheckTypeIs(node, Type::Signed32()); break; case IrOpcode::kSpeculativeNumberBitwiseOr: case IrOpcode::kSpeculativeNumberBitwiseXor: case IrOpcode::kSpeculativeNumberBitwiseAnd: CheckTypeIs(node, Type::Signed32()); break; case IrOpcode::kNumberShiftLeft: case IrOpcode::kNumberShiftRight: // (Signed32, Unsigned32) -> Signed32 CheckValueInputIs(node, 0, Type::Signed32()); CheckValueInputIs(node, 1, Type::Unsigned32()); CheckTypeIs(node, Type::Signed32()); break; case IrOpcode::kSpeculativeNumberShiftLeft: case IrOpcode::kSpeculativeNumberShiftRight: CheckTypeIs(node, Type::Signed32()); break; case IrOpcode::kNumberShiftRightLogical: // (Unsigned32, Unsigned32) -> Unsigned32 CheckValueInputIs(node, 0, Type::Unsigned32()); CheckValueInputIs(node, 1, Type::Unsigned32()); CheckTypeIs(node, Type::Unsigned32()); break; case IrOpcode::kSpeculativeNumberShiftRightLogical: CheckTypeIs(node, Type::Unsigned32()); break; case IrOpcode::kNumberImul: // (Unsigned32, Unsigned32) -> Signed32 CheckValueInputIs(node, 0, Type::Unsigned32()); CheckValueInputIs(node, 1, Type::Unsigned32()); CheckTypeIs(node, Type::Signed32()); break; case IrOpcode::kNumberClz32: // Unsigned32 -> Unsigned32 CheckValueInputIs(node, 0, Type::Unsigned32()); CheckTypeIs(node, Type::Unsigned32()); break; case IrOpcode::kNumberAtan2: case IrOpcode::kNumberMax: case IrOpcode::kNumberMin: case IrOpcode::kNumberPow: // (Number, Number) -> Number CheckValueInputIs(node, 0, Type::Number()); CheckValueInputIs(node, 1, Type::Number()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kNumberAbs: case IrOpcode::kNumberCeil: case IrOpcode::kNumberFloor: case IrOpcode::kNumberFround: case IrOpcode::kNumberAcos: case IrOpcode::kNumberAcosh: case IrOpcode::kNumberAsin: case IrOpcode::kNumberAsinh: case IrOpcode::kNumberAtan: case IrOpcode::kNumberAtanh: case IrOpcode::kNumberCos: case IrOpcode::kNumberCosh: case IrOpcode::kNumberExp: case IrOpcode::kNumberExpm1: case IrOpcode::kNumberLog: case IrOpcode::kNumberLog1p: case IrOpcode::kNumberLog2: case IrOpcode::kNumberLog10: case IrOpcode::kNumberCbrt: case IrOpcode::kNumberRound: case IrOpcode::kNumberSign: case IrOpcode::kNumberSin: case IrOpcode::kNumberSinh: case IrOpcode::kNumberSqrt: case IrOpcode::kNumberTan: case IrOpcode::kNumberTanh: case IrOpcode::kNumberTrunc: // Number -> Number CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kNumberToBoolean: // Number -> Boolean CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberToInt32: // Number -> Signed32 CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Signed32()); break; case IrOpcode::kNumberToString: // Number -> String CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kNumberToUint32: case IrOpcode::kNumberToUint8Clamped: // Number -> Unsigned32 CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Unsigned32()); break; case IrOpcode::kSpeculativeToNumber: // Any -> Number CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kPlainPrimitiveToNumber: // PlainPrimitive -> Number CheckValueInputIs(node, 0, Type::PlainPrimitive()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kPlainPrimitiveToWord32: // PlainPrimitive -> Integral32 CheckValueInputIs(node, 0, Type::PlainPrimitive()); CheckTypeIs(node, Type::Integral32()); break; case IrOpcode::kPlainPrimitiveToFloat64: // PlainPrimitive -> Number CheckValueInputIs(node, 0, Type::PlainPrimitive()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kStringConcat: CheckValueInputIs(node, 0, TypeCache::Get().kStringLengthType); CheckValueInputIs(node, 1, Type::String()); CheckValueInputIs(node, 2, Type::String()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kStringEqual: case IrOpcode::kStringLessThan: case IrOpcode::kStringLessThanOrEqual: // (String, String) -> Boolean CheckValueInputIs(node, 0, Type::String()); CheckValueInputIs(node, 1, Type::String()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kStringToNumber: // String -> Number CheckValueInputIs(node, 0, Type::String()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kStringCharCodeAt: // (String, Unsigned32) -> UnsignedSmall CheckValueInputIs(node, 0, Type::String()); CheckValueInputIs(node, 1, Type::Unsigned32()); CheckTypeIs(node, Type::UnsignedSmall()); break; case IrOpcode::kStringCodePointAt: // (String, Unsigned32) -> UnsignedSmall CheckValueInputIs(node, 0, Type::String()); CheckValueInputIs(node, 1, Type::Unsigned32()); CheckTypeIs(node, Type::UnsignedSmall()); break; case IrOpcode::kStringFromSingleCharCode: // Number -> String CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kStringFromSingleCodePoint: // (Unsigned32) -> String CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kStringIndexOf: // (String, String, SignedSmall) -> SignedSmall CheckValueInputIs(node, 0, Type::String()); CheckValueInputIs(node, 1, Type::String()); CheckValueInputIs(node, 2, Type::SignedSmall()); CheckTypeIs(node, Type::SignedSmall()); break; case IrOpcode::kStringLength: CheckValueInputIs(node, 0, Type::String()); CheckTypeIs(node, TypeCache::Get().kStringLengthType); break; case IrOpcode::kStringToLowerCaseIntl: case IrOpcode::kStringToUpperCaseIntl: CheckValueInputIs(node, 0, Type::String()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kStringSubstring: CheckValueInputIs(node, 0, Type::String()); CheckValueInputIs(node, 1, Type::SignedSmall()); CheckValueInputIs(node, 2, Type::SignedSmall()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kReferenceEqual: // (Unique, Any) -> Boolean and // (Any, Unique) -> Boolean CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kSameValue: // (Any, Any) -> Boolean CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kObjectIsArrayBufferView: case IrOpcode::kObjectIsBigInt: case IrOpcode::kObjectIsCallable: case IrOpcode::kObjectIsConstructor: case IrOpcode::kObjectIsDetectableCallable: case IrOpcode::kObjectIsMinusZero: case IrOpcode::kObjectIsNaN: case IrOpcode::kObjectIsNonCallable: case IrOpcode::kObjectIsNumber: case IrOpcode::kObjectIsReceiver: case IrOpcode::kObjectIsSmi: case IrOpcode::kObjectIsString: case IrOpcode::kObjectIsSymbol: case IrOpcode::kObjectIsUndetectable: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberIsFloat64Hole: CheckValueInputIs(node, 0, Type::NumberOrHole()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberIsFinite: CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberIsMinusZero: case IrOpcode::kNumberIsNaN: CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kObjectIsFiniteNumber: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberIsInteger: CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kObjectIsSafeInteger: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kNumberIsSafeInteger: CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kObjectIsInteger: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kFindOrderedHashMapEntry: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::SignedSmall()); break; case IrOpcode::kFindOrderedHashMapEntryForInt32Key: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Signed32()); CheckTypeIs(node, Type::SignedSmall()); break; case IrOpcode::kArgumentsLength: CheckValueInputIs(node, 0, Type::ExternalPointer()); CheckTypeIs(node, TypeCache::Get().kArgumentsLengthType); break; case IrOpcode::kArgumentsFrame: CheckTypeIs(node, Type::ExternalPointer()); break; case IrOpcode::kNewDoubleElements: case IrOpcode::kNewSmiOrObjectElements: CheckValueInputIs(node, 0, Type::Range(0.0, FixedArray::kMaxLength, zone)); CheckTypeIs(node, Type::OtherInternal()); break; case IrOpcode::kNewArgumentsElements: CheckValueInputIs(node, 0, Type::ExternalPointer()); CheckValueInputIs(node, 1, Type::Range(-Code::kMaxArguments, Code::kMaxArguments, zone)); CheckTypeIs(node, Type::OtherInternal()); break; case IrOpcode::kNewConsString: CheckValueInputIs(node, 0, TypeCache::Get().kStringLengthType); CheckValueInputIs(node, 1, Type::String()); CheckValueInputIs(node, 2, Type::String()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kDelayedStringConstant: CheckTypeIs(node, Type::String()); break; case IrOpcode::kAllocate: CheckValueInputIs(node, 0, Type::PlainNumber()); break; case IrOpcode::kAllocateRaw: // CheckValueInputIs(node, 0, Type::PlainNumber()); break; case IrOpcode::kEnsureWritableFastElements: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Internal()); CheckTypeIs(node, Type::Internal()); break; case IrOpcode::kMaybeGrowFastElements: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Internal()); CheckValueInputIs(node, 2, Type::Unsigned31()); CheckValueInputIs(node, 3, Type::Unsigned31()); CheckTypeIs(node, Type::Internal()); break; case IrOpcode::kTransitionElementsKind: CheckValueInputIs(node, 0, Type::Any()); CheckNotTyped(node); break; case IrOpcode::kChangeTaggedSignedToInt32: { // Signed32 /\ Tagged -> Signed32 /\ UntaggedInt32 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Signed32(), Type::Tagged()); // Type to = Type::Intersect(Type::Signed32(), Type::UntaggedInt32()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeTaggedSignedToInt64: break; case IrOpcode::kChangeTaggedToInt32: { // Signed32 /\ Tagged -> Signed32 /\ UntaggedInt32 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Signed32(), Type::Tagged()); // Type to = Type::Intersect(Type::Signed32(), Type::UntaggedInt32()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeTaggedToInt64: break; case IrOpcode::kChangeTaggedToUint32: { // Unsigned32 /\ Tagged -> Unsigned32 /\ UntaggedInt32 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Unsigned32(), Type::Tagged()); // Type to =Type::Intersect(Type::Unsigned32(), Type::UntaggedInt32()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeTaggedToFloat64: { // NumberOrUndefined /\ Tagged -> Number /\ UntaggedFloat64 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Number(), Type::Tagged()); // Type to = Type::Intersect(Type::Number(), Type::UntaggedFloat64()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeTaggedToTaggedSigned: break; case IrOpcode::kTruncateTaggedToFloat64: { // NumberOrUndefined /\ Tagged -> Number /\ UntaggedFloat64 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::NumberOrUndefined(), // Type::Tagged()); // Type to = Type::Intersect(Type::Number(), Type::UntaggedFloat64()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeInt31ToTaggedSigned: { // Signed31 /\ UntaggedInt32 -> Signed31 /\ Tagged // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from =Type::Intersect(Type::Signed31(), Type::UntaggedInt32()); // Type to = Type::Intersect(Type::Signed31(), Type::Tagged()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeInt32ToTagged: { // Signed32 /\ UntaggedInt32 -> Signed32 /\ Tagged // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from =Type::Intersect(Type::Signed32(), Type::UntaggedInt32()); // Type to = Type::Intersect(Type::Signed32(), Type::Tagged()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeInt64ToTagged: break; case IrOpcode::kChangeUint32ToTagged: { // Unsigned32 /\ UntaggedInt32 -> Unsigned32 /\ Tagged // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from=Type::Intersect(Type::Unsigned32(),Type::UntaggedInt32()); // Type to = Type::Intersect(Type::Unsigned32(), Type::Tagged()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeUint64ToTagged: break; case IrOpcode::kChangeFloat64ToTagged: { // Number /\ UntaggedFloat64 -> Number /\ Tagged // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from =Type::Intersect(Type::Number(), Type::UntaggedFloat64()); // Type to = Type::Intersect(Type::Number(), Type::Tagged()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeFloat64ToTaggedPointer: break; case IrOpcode::kChangeTaggedToBit: { // Boolean /\ TaggedPtr -> Boolean /\ UntaggedInt1 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Boolean(), Type::TaggedPtr()); // Type to = Type::Intersect(Type::Boolean(), Type::UntaggedInt1()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kChangeBitToTagged: { // Boolean /\ UntaggedInt1 -> Boolean /\ TaggedPtr // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Boolean(), Type::UntaggedInt1()); // Type to = Type::Intersect(Type::Boolean(), Type::TaggedPtr()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kTruncateTaggedToWord32: { // Number /\ Tagged -> Signed32 /\ UntaggedInt32 // TODO(neis): Activate once ChangeRepresentation works in typer. // Type from = Type::Intersect(Type::Number(), Type::Tagged()); // Type to = Type::Intersect(Type::Number(), Type::UntaggedInt32()); // CheckValueInputIs(node, 0, from)); // CheckTypeIs(node, to)); break; } case IrOpcode::kTruncateTaggedToBit: case IrOpcode::kTruncateTaggedPointerToBit: break; case IrOpcode::kCheckBounds: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Unsigned31()); CheckTypeIs(node, Type::Unsigned31()); break; case IrOpcode::kPoisonIndex: CheckValueInputIs(node, 0, Type::Unsigned32()); CheckTypeIs(node, Type::Unsigned32()); break; case IrOpcode::kCheckHeapObject: CheckValueInputIs(node, 0, Type::Any()); break; case IrOpcode::kCheckIf: CheckValueInputIs(node, 0, Type::Boolean()); CheckNotTyped(node); break; case IrOpcode::kCheckInternalizedString: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::InternalizedString()); break; case IrOpcode::kCheckMaps: CheckValueInputIs(node, 0, Type::Any()); CheckNotTyped(node); break; case IrOpcode::kCompareMaps: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Boolean()); break; case IrOpcode::kCheckNumber: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kCheckReceiver: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Receiver()); break; case IrOpcode::kCheckSmi: CheckValueInputIs(node, 0, Type::Any()); break; case IrOpcode::kCheckString: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::String()); break; case IrOpcode::kCheckSymbol: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::Symbol()); break; case IrOpcode::kConvertReceiver: // (Any, Any) -> Receiver CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::Any()); CheckTypeIs(node, Type::Receiver()); break; case IrOpcode::kCheckedInt32Add: case IrOpcode::kCheckedInt32Sub: case IrOpcode::kCheckedInt32Div: case IrOpcode::kCheckedInt32Mod: case IrOpcode::kCheckedUint32Div: case IrOpcode::kCheckedUint32Mod: case IrOpcode::kCheckedInt32Mul: case IrOpcode::kCheckedInt32ToTaggedSigned: case IrOpcode::kCheckedInt64ToInt32: case IrOpcode::kCheckedInt64ToTaggedSigned: case IrOpcode::kCheckedUint32ToInt32: case IrOpcode::kCheckedUint32ToTaggedSigned: case IrOpcode::kCheckedUint64ToInt32: case IrOpcode::kCheckedUint64ToTaggedSigned: case IrOpcode::kCheckedFloat64ToInt32: case IrOpcode::kCheckedTaggedSignedToInt32: case IrOpcode::kCheckedTaggedToInt32: case IrOpcode::kCheckedTaggedToFloat64: case IrOpcode::kCheckedTaggedToTaggedSigned: case IrOpcode::kCheckedTaggedToTaggedPointer: case IrOpcode::kCheckedTruncateTaggedToWord32: break; case IrOpcode::kCheckFloat64Hole: CheckValueInputIs(node, 0, Type::NumberOrHole()); CheckTypeIs(node, Type::NumberOrUndefined()); break; case IrOpcode::kCheckNotTaggedHole: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::NonInternal()); break; case IrOpcode::kConvertTaggedHoleToUndefined: CheckValueInputIs(node, 0, Type::Any()); CheckTypeIs(node, Type::NonInternal()); break; case IrOpcode::kCheckEqualsInternalizedString: CheckValueInputIs(node, 0, Type::InternalizedString()); CheckValueInputIs(node, 1, Type::Any()); CheckNotTyped(node); break; case IrOpcode::kCheckEqualsSymbol: CheckValueInputIs(node, 0, Type::Symbol()); CheckValueInputIs(node, 1, Type::Any()); CheckNotTyped(node); break; case IrOpcode::kLoadFieldByIndex: CheckValueInputIs(node, 0, Type::Any()); CheckValueInputIs(node, 1, Type::SignedSmall()); CheckTypeIs(node, Type::NonInternal()); break; case IrOpcode::kLoadField: // Object -> fieldtype // TODO(rossberg): activate once machine ops are typed. // CheckValueInputIs(node, 0, Type::Object()); // CheckTypeIs(node, FieldAccessOf(node->op()).type)); break; case IrOpcode::kLoadElement: // Object -> elementtype // TODO(rossberg): activate once machine ops are typed. // CheckValueInputIs(node, 0, Type::Object()); // CheckTypeIs(node, ElementAccessOf(node->op()).type)); break; case IrOpcode::kLoadTypedElement: break; case IrOpcode::kLoadDataViewElement: break; case IrOpcode::kStoreField: // (Object, fieldtype) -> _|_ // TODO(rossberg): activate once machine ops are typed. // CheckValueInputIs(node, 0, Type::Object()); // CheckValueInputIs(node, 1, FieldAccessOf(node->op()).type)); CheckNotTyped(node); break; case IrOpcode::kStoreElement: // (Object, elementtype) -> _|_ // TODO(rossberg): activate once machine ops are typed. // CheckValueInputIs(node, 0, Type::Object()); // CheckValueInputIs(node, 1, ElementAccessOf(node->op()).type)); CheckNotTyped(node); break; case IrOpcode::kTransitionAndStoreElement: CheckNotTyped(node); break; case IrOpcode::kTransitionAndStoreNumberElement: CheckNotTyped(node); break; case IrOpcode::kTransitionAndStoreNonNumberElement: CheckNotTyped(node); break; case IrOpcode::kStoreSignedSmallElement: CheckNotTyped(node); break; case IrOpcode::kStoreTypedElement: CheckNotTyped(node); break; case IrOpcode::kStoreDataViewElement: CheckNotTyped(node); break; case IrOpcode::kNumberSilenceNaN: CheckValueInputIs(node, 0, Type::Number()); CheckTypeIs(node, Type::Number()); break; case IrOpcode::kMapGuard: CheckNotTyped(node); break; case IrOpcode::kTypeGuard: CheckTypeIs(node, TypeGuardTypeOf(node->op())); break; case IrOpcode::kDateNow: CHECK_EQ(0, value_count); CheckTypeIs(node, Type::Number()); break; // Machine operators // ----------------------- case IrOpcode::kLoad: case IrOpcode::kPoisonedLoad: case IrOpcode::kProtectedLoad: case IrOpcode::kProtectedStore: case IrOpcode::kStore: case IrOpcode::kStackSlot: case IrOpcode::kWord32And: case IrOpcode::kWord32Or: case IrOpcode::kWord32Xor: case IrOpcode::kWord32Shl: case IrOpcode::kWord32Shr: case IrOpcode::kWord32Sar: case IrOpcode::kWord32Ror: case IrOpcode::kWord32Equal: case IrOpcode::kWord32Clz: case IrOpcode::kWord32Ctz: case IrOpcode::kWord32ReverseBits: case IrOpcode::kWord32ReverseBytes: case IrOpcode::kInt32AbsWithOverflow: case IrOpcode::kWord32Popcnt: case IrOpcode::kWord64And: case IrOpcode::kWord64Or: case IrOpcode::kWord64Xor: case IrOpcode::kWord64Shl: case IrOpcode::kWord64Shr: case IrOpcode::kWord64Sar: case IrOpcode::kWord64Ror: case IrOpcode::kWord64Clz: case IrOpcode::kWord64Popcnt: case IrOpcode::kWord64Ctz: case IrOpcode::kWord64ReverseBits: case IrOpcode::kWord64ReverseBytes: case IrOpcode::kInt64AbsWithOverflow: case IrOpcode::kWord64Equal: case IrOpcode::kInt32Add: case IrOpcode::kInt32AddWithOverflow: case IrOpcode::kInt32Sub: case IrOpcode::kInt32SubWithOverflow: case IrOpcode::kInt32Mul: case IrOpcode::kInt32MulWithOverflow: case IrOpcode::kInt32MulHigh: case IrOpcode::kInt32Div: case IrOpcode::kInt32Mod: case IrOpcode::kInt32LessThan: case IrOpcode::kInt32LessThanOrEqual: case IrOpcode::kUint32Div: case IrOpcode::kUint32Mod: case IrOpcode::kUint32MulHigh: case IrOpcode::kUint32LessThan: case IrOpcode::kUint32LessThanOrEqual: case IrOpcode::kInt64Add: case IrOpcode::kInt64AddWithOverflow: case IrOpcode::kInt64Sub: case IrOpcode::kInt64SubWithOverflow: case IrOpcode::kInt64Mul: case IrOpcode::kInt64Div: case IrOpcode::kInt64Mod: case IrOpcode::kInt64LessThan: case IrOpcode::kInt64LessThanOrEqual: case IrOpcode::kUint64Div: case IrOpcode::kUint64Mod: case IrOpcode::kUint64LessThan: case IrOpcode::kUint64LessThanOrEqual: case IrOpcode::kFloat32Add: case IrOpcode::kFloat32Sub: case IrOpcode::kFloat32Neg: case IrOpcode::kFloat32Mul: case IrOpcode::kFloat32Div: case IrOpcode::kFloat32Abs: case IrOpcode::kFloat32Sqrt: case IrOpcode::kFloat32Equal: case IrOpcode::kFloat32LessThan: case IrOpcode::kFloat32LessThanOrEqual: case IrOpcode::kFloat32Max: case IrOpcode::kFloat32Min: case IrOpcode::kFloat64Add: case IrOpcode::kFloat64Sub: case IrOpcode::kFloat64Neg: case IrOpcode::kFloat64Mul: case IrOpcode::kFloat64Div: case IrOpcode::kFloat64Mod: case IrOpcode::kFloat64Max: case IrOpcode::kFloat64Min: case IrOpcode::kFloat64Abs: case IrOpcode::kFloat64Acos: case IrOpcode::kFloat64Acosh: case IrOpcode::kFloat64Asin: case IrOpcode::kFloat64Asinh: case IrOpcode::kFloat64Atan: case IrOpcode::kFloat64Atan2: case IrOpcode::kFloat64Atanh: case IrOpcode::kFloat64Cbrt: case IrOpcode::kFloat64Cos: case IrOpcode::kFloat64Cosh: case IrOpcode::kFloat64Exp: case IrOpcode::kFloat64Expm1: case IrOpcode::kFloat64Log: case IrOpcode::kFloat64Log1p: case IrOpcode::kFloat64Log10: case IrOpcode::kFloat64Log2: case IrOpcode::kFloat64Pow: case IrOpcode::kFloat64Sin: case IrOpcode::kFloat64Sinh: case IrOpcode::kFloat64Sqrt: case IrOpcode::kFloat64Tan: case IrOpcode::kFloat64Tanh: case IrOpcode::kFloat32RoundDown: case IrOpcode::kFloat64RoundDown: case IrOpcode::kFloat32RoundUp: case IrOpcode::kFloat64RoundUp: case IrOpcode::kFloat32RoundTruncate: case IrOpcode::kFloat64RoundTruncate: case IrOpcode::kFloat64RoundTiesAway: case IrOpcode::kFloat32RoundTiesEven: case IrOpcode::kFloat64RoundTiesEven: case IrOpcode::kFloat64Equal: case IrOpcode::kFloat64LessThan: case IrOpcode::kFloat64LessThanOrEqual: case IrOpcode::kTruncateInt64ToInt32: case IrOpcode::kRoundFloat64ToInt32: case IrOpcode::kRoundInt32ToFloat32: case IrOpcode::kRoundInt64ToFloat32: case IrOpcode::kRoundInt64ToFloat64: case IrOpcode::kRoundUint32ToFloat32: case IrOpcode::kRoundUint64ToFloat64: case IrOpcode::kRoundUint64ToFloat32: case IrOpcode::kTruncateFloat64ToFloat32: case IrOpcode::kTruncateFloat64ToWord32: case IrOpcode::kBitcastFloat32ToInt32: case IrOpcode::kBitcastFloat64ToInt64: case IrOpcode::kBitcastInt32ToFloat32: case IrOpcode::kBitcastInt64ToFloat64: case IrOpcode::kBitcastTaggedToWord: case IrOpcode::kBitcastWordToTagged: case IrOpcode::kBitcastWordToTaggedSigned: case IrOpcode::kChangeInt32ToInt64: case IrOpcode::kChangeUint32ToUint64: case IrOpcode::kChangeInt32ToFloat64: case IrOpcode::kChangeInt64ToFloat64: case IrOpcode::kChangeUint32ToFloat64: case IrOpcode::kChangeFloat32ToFloat64: case IrOpcode::kChangeFloat64ToInt32: case IrOpcode::kChangeFloat64ToInt64: case IrOpcode::kChangeFloat64ToUint32: case IrOpcode::kChangeFloat64ToUint64: case IrOpcode::kFloat64SilenceNaN: case IrOpcode::kTruncateFloat64ToUint32: case IrOpcode::kTruncateFloat32ToInt32: case IrOpcode::kTruncateFloat32ToUint32: case IrOpcode::kTryTruncateFloat32ToInt64: case IrOpcode::kTryTruncateFloat64ToInt64: case IrOpcode::kTryTruncateFloat32ToUint64: case IrOpcode::kTryTruncateFloat64ToUint64: case IrOpcode::kFloat64ExtractLowWord32: case IrOpcode::kFloat64ExtractHighWord32: case IrOpcode::kFloat64InsertLowWord32: case IrOpcode::kFloat64InsertHighWord32: case IrOpcode::kInt32PairAdd: case IrOpcode::kInt32PairSub: case IrOpcode::kInt32PairMul: case IrOpcode::kWord32PairShl: case IrOpcode::kWord32PairShr: case IrOpcode::kWord32PairSar: case IrOpcode::kTaggedPoisonOnSpeculation: case IrOpcode::kWord32PoisonOnSpeculation: case IrOpcode::kWord64PoisonOnSpeculation: case IrOpcode::kLoadStackPointer: case IrOpcode::kLoadFramePointer: case IrOpcode::kLoadParentFramePointer: case IrOpcode::kUnalignedLoad: case IrOpcode::kUnalignedStore: case IrOpcode::kWord32AtomicLoad: case IrOpcode::kWord32AtomicStore: case IrOpcode::kWord32AtomicExchange: case IrOpcode::kWord32AtomicCompareExchange: case IrOpcode::kWord32AtomicAdd: case IrOpcode::kWord32AtomicSub: case IrOpcode::kWord32AtomicAnd: case IrOpcode::kWord32AtomicOr: case IrOpcode::kWord32AtomicXor: case IrOpcode::kWord64AtomicLoad: case IrOpcode::kWord64AtomicStore: case IrOpcode::kWord64AtomicAdd: case IrOpcode::kWord64AtomicSub: case IrOpcode::kWord64AtomicAnd: case IrOpcode::kWord64AtomicOr: case IrOpcode::kWord64AtomicXor: case IrOpcode::kWord64AtomicExchange: case IrOpcode::kWord64AtomicCompareExchange: case IrOpcode::kWord32AtomicPairLoad: case IrOpcode::kWord32AtomicPairStore: case IrOpcode::kWord32AtomicPairAdd: case IrOpcode::kWord32AtomicPairSub: case IrOpcode::kWord32AtomicPairAnd: case IrOpcode::kWord32AtomicPairOr: case IrOpcode::kWord32AtomicPairXor: case IrOpcode::kWord32AtomicPairExchange: case IrOpcode::kWord32AtomicPairCompareExchange: case IrOpcode::kSpeculationFence: case IrOpcode::kSignExtendWord8ToInt32: case IrOpcode::kSignExtendWord16ToInt32: case IrOpcode::kSignExtendWord8ToInt64: case IrOpcode::kSignExtendWord16ToInt64: case IrOpcode::kSignExtendWord32ToInt64: #define SIMD_MACHINE_OP_CASE(Name) case IrOpcode::k##Name: MACHINE_SIMD_OP_LIST(SIMD_MACHINE_OP_CASE) #undef SIMD_MACHINE_OP_CASE // TODO(rossberg): Check. break; } } // NOLINT(readability/fn_size) void Verifier::Run(Graph* graph, Typing typing, CheckInputs check_inputs, CodeType code_type) { CHECK_NOT_NULL(graph->start()); CHECK_NOT_NULL(graph->end()); Zone zone(graph->zone()->allocator(), ZONE_NAME); Visitor visitor(&zone, typing, check_inputs, code_type); AllNodes all(&zone, graph); for (Node* node : all.reachable) visitor.Check(node, all); // Check the uniqueness of projections. for (Node* proj : all.reachable) { if (proj->opcode() != IrOpcode::kProjection) continue; Node* node = proj->InputAt(0); for (Node* other : node->uses()) { if (all.IsLive(other) && other != proj && other->opcode() == IrOpcode::kProjection && other->InputAt(0) == node && ProjectionIndexOf(other->op()) == ProjectionIndexOf(proj->op())) { FATAL("Node #%d:%s has duplicate projections #%d and #%d", node->id(), node->op()->mnemonic(), proj->id(), other->id()); } } } } // ----------------------------------------------------------------------------- static bool HasDominatingDef(Schedule* schedule, Node* node, BasicBlock* container, BasicBlock* use_block, int use_pos) { BasicBlock* block = use_block; while (true) { while (use_pos >= 0) { if (block->NodeAt(use_pos) == node) return true; use_pos--; } block = block->dominator(); if (block == nullptr) break; use_pos = static_cast(block->NodeCount()) - 1; if (node == block->control_input()) return true; } return false; } static bool Dominates(Schedule* schedule, Node* dominator, Node* dominatee) { BasicBlock* dom = schedule->block(dominator); BasicBlock* sub = schedule->block(dominatee); while (sub != nullptr) { if (sub == dom) { return true; } sub = sub->dominator(); } return false; } static void CheckInputsDominate(Schedule* schedule, BasicBlock* block, Node* node, int use_pos) { for (int j = node->op()->ValueInputCount() - 1; j >= 0; j--) { BasicBlock* use_block = block; if (node->opcode() == IrOpcode::kPhi) { use_block = use_block->PredecessorAt(j); use_pos = static_cast(use_block->NodeCount()) - 1; } Node* input = node->InputAt(j); if (!HasDominatingDef(schedule, node->InputAt(j), block, use_block, use_pos)) { FATAL("Node #%d:%s in B%d is not dominated by input@%d #%d:%s", node->id(), node->op()->mnemonic(), block->rpo_number(), j, input->id(), input->op()->mnemonic()); } } // Ensure that nodes are dominated by their control inputs; // kEnd is an exception, as unreachable blocks resulting from kMerge // are not in the RPO. if (node->op()->ControlInputCount() == 1 && node->opcode() != IrOpcode::kEnd) { Node* ctl = NodeProperties::GetControlInput(node); if (!Dominates(schedule, ctl, node)) { FATAL("Node #%d:%s in B%d is not dominated by control input #%d:%s", node->id(), node->op()->mnemonic(), block->rpo_number(), ctl->id(), ctl->op()->mnemonic()); } } } void ScheduleVerifier::Run(Schedule* schedule) { const size_t count = schedule->BasicBlockCount(); Zone tmp_zone(schedule->zone()->allocator(), ZONE_NAME); Zone* zone = &tmp_zone; BasicBlock* start = schedule->start(); BasicBlockVector* rpo_order = schedule->rpo_order(); // Verify the RPO order contains only blocks from this schedule. CHECK_GE(count, rpo_order->size()); for (BasicBlockVector::iterator b = rpo_order->begin(); b != rpo_order->end(); ++b) { CHECK_EQ((*b), schedule->GetBlockById((*b)->id())); // All predecessors and successors should be in rpo and in this schedule. for (BasicBlock const* predecessor : (*b)->predecessors()) { CHECK_GE(predecessor->rpo_number(), 0); CHECK_EQ(predecessor, schedule->GetBlockById(predecessor->id())); } for (BasicBlock const* successor : (*b)->successors()) { CHECK_GE(successor->rpo_number(), 0); CHECK_EQ(successor, schedule->GetBlockById(successor->id())); } } // Verify RPO numbers of blocks. CHECK_EQ(start, rpo_order->at(0)); // Start should be first. for (size_t b = 0; b < rpo_order->size(); b++) { BasicBlock* block = rpo_order->at(b); CHECK_EQ(static_cast(b), block->rpo_number()); BasicBlock* dom = block->dominator(); if (b == 0) { // All blocks except start should have a dominator. CHECK_NULL(dom); } else { // Check that the immediate dominator appears somewhere before the block. CHECK_NOT_NULL(dom); CHECK_LT(dom->rpo_number(), block->rpo_number()); } } // Verify that all blocks reachable from start are in the RPO. BoolVector marked(static_cast(count), false, zone); { ZoneQueue queue(zone); queue.push(start); marked[start->id().ToSize()] = true; while (!queue.empty()) { BasicBlock* block = queue.front(); queue.pop(); for (size_t s = 0; s < block->SuccessorCount(); s++) { BasicBlock* succ = block->SuccessorAt(s); if (!marked[succ->id().ToSize()]) { marked[succ->id().ToSize()] = true; queue.push(succ); } } } } // Verify marked blocks are in the RPO. for (size_t i = 0; i < count; i++) { BasicBlock* block = schedule->GetBlockById(BasicBlock::Id::FromSize(i)); if (marked[i]) { CHECK_GE(block->rpo_number(), 0); CHECK_EQ(block, rpo_order->at(block->rpo_number())); } } // Verify RPO blocks are marked. for (size_t b = 0; b < rpo_order->size(); b++) { CHECK(marked[rpo_order->at(b)->id().ToSize()]); } { // Verify the dominance relation. ZoneVector dominators(zone); dominators.resize(count, nullptr); // Compute a set of all the nodes that dominate a given node by using // a forward fixpoint. O(n^2). ZoneQueue queue(zone); queue.push(start); dominators[start->id().ToSize()] = new (zone) BitVector(static_cast(count), zone); while (!queue.empty()) { BasicBlock* block = queue.front(); queue.pop(); BitVector* block_doms = dominators[block->id().ToSize()]; BasicBlock* idom = block->dominator(); if (idom != nullptr && !block_doms->Contains(idom->id().ToInt())) { FATAL("Block B%d is not dominated by B%d", block->rpo_number(), idom->rpo_number()); } for (size_t s = 0; s < block->SuccessorCount(); s++) { BasicBlock* succ = block->SuccessorAt(s); BitVector* succ_doms = dominators[succ->id().ToSize()]; if (succ_doms == nullptr) { // First time visiting the node. S.doms = B U B.doms succ_doms = new (zone) BitVector(static_cast(count), zone); succ_doms->CopyFrom(*block_doms); succ_doms->Add(block->id().ToInt()); dominators[succ->id().ToSize()] = succ_doms; queue.push(succ); } else { // Nth time visiting the successor. S.doms = S.doms ^ (B U B.doms) bool had = succ_doms->Contains(block->id().ToInt()); if (had) succ_doms->Remove(block->id().ToInt()); if (succ_doms->IntersectIsChanged(*block_doms)) queue.push(succ); if (had) succ_doms->Add(block->id().ToInt()); } } } // Verify the immediateness of dominators. for (BasicBlockVector::iterator b = rpo_order->begin(); b != rpo_order->end(); ++b) { BasicBlock* block = *b; BasicBlock* idom = block->dominator(); if (idom == nullptr) continue; BitVector* block_doms = dominators[block->id().ToSize()]; for (BitVector::Iterator it(block_doms); !it.Done(); it.Advance()) { BasicBlock* dom = schedule->GetBlockById(BasicBlock::Id::FromInt(it.Current())); if (dom != idom && !dominators[idom->id().ToSize()]->Contains(dom->id().ToInt())) { FATAL("Block B%d is not immediately dominated by B%d", block->rpo_number(), idom->rpo_number()); } } } } // Verify phis are placed in the block of their control input. for (BasicBlockVector::iterator b = rpo_order->begin(); b != rpo_order->end(); ++b) { for (BasicBlock::const_iterator i = (*b)->begin(); i != (*b)->end(); ++i) { Node* phi = *i; if (phi->opcode() != IrOpcode::kPhi) continue; // TODO(titzer): Nasty special case. Phis from RawMachineAssembler // schedules don't have control inputs. if (phi->InputCount() > phi->op()->ValueInputCount()) { Node* control = NodeProperties::GetControlInput(phi); CHECK(control->opcode() == IrOpcode::kMerge || control->opcode() == IrOpcode::kLoop); CHECK_EQ((*b), schedule->block(control)); } } } // Verify that all uses are dominated by their definitions. for (BasicBlockVector::iterator b = rpo_order->begin(); b != rpo_order->end(); ++b) { BasicBlock* block = *b; // Check inputs to control for this block. Node* control = block->control_input(); if (control != nullptr) { CHECK_EQ(block, schedule->block(control)); CheckInputsDominate(schedule, block, control, static_cast(block->NodeCount()) - 1); } // Check inputs for all nodes in the block. for (size_t i = 0; i < block->NodeCount(); i++) { Node* node = block->NodeAt(i); CheckInputsDominate(schedule, block, node, static_cast(i) - 1); } } } #ifdef DEBUG // static void Verifier::VerifyNode(Node* node) { DCHECK_EQ(OperatorProperties::GetTotalInputCount(node->op()), node->InputCount()); // If this node has no effect or no control outputs, // we check that none of its uses are effect or control inputs. bool check_no_control = node->op()->ControlOutputCount() == 0; bool check_no_effect = node->op()->EffectOutputCount() == 0; bool check_no_frame_state = node->opcode() != IrOpcode::kFrameState; int effect_edges = 0; if (check_no_effect || check_no_control) { for (Edge edge : node->use_edges()) { Node* const user = edge.from(); DCHECK(!user->IsDead()); if (NodeProperties::IsControlEdge(edge)) { DCHECK(!check_no_control); } else if (NodeProperties::IsEffectEdge(edge)) { DCHECK(!check_no_effect); effect_edges++; } else if (NodeProperties::IsFrameStateEdge(edge)) { DCHECK(!check_no_frame_state); } } } // Frame state input should be a frame state (or sentinel). if (OperatorProperties::GetFrameStateInputCount(node->op()) > 0) { Node* input = NodeProperties::GetFrameStateInput(node); DCHECK(input->opcode() == IrOpcode::kFrameState || input->opcode() == IrOpcode::kStart || input->opcode() == IrOpcode::kDead || input->opcode() == IrOpcode::kDeadValue); } // Effect inputs should be effect-producing nodes (or sentinels). for (int i = 0; i < node->op()->EffectInputCount(); i++) { Node* input = NodeProperties::GetEffectInput(node, i); DCHECK(input->op()->EffectOutputCount() > 0 || input->opcode() == IrOpcode::kDead); } // Control inputs should be control-producing nodes (or sentinels). for (int i = 0; i < node->op()->ControlInputCount(); i++) { Node* input = NodeProperties::GetControlInput(node, i); DCHECK(input->op()->ControlOutputCount() > 0 || input->opcode() == IrOpcode::kDead); } } void Verifier::VerifyEdgeInputReplacement(const Edge& edge, const Node* replacement) { // Check that the user does not misuse the replacement. DCHECK(!NodeProperties::IsControlEdge(edge) || replacement->op()->ControlOutputCount() > 0); DCHECK(!NodeProperties::IsEffectEdge(edge) || replacement->op()->EffectOutputCount() > 0); DCHECK(!NodeProperties::IsFrameStateEdge(edge) || replacement->opcode() == IrOpcode::kFrameState || replacement->opcode() == IrOpcode::kDead || replacement->opcode() == IrOpcode::kDeadValue); } #endif // DEBUG } // namespace compiler } // namespace internal } // namespace v8