// Copyright 2015 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/js-call-reducer.h"
#include "src/api-inl.h"
#include "src/builtins/builtins-promise-gen.h"
#include "src/builtins/builtins-utils.h"
#include "src/code-factory.h"
#include "src/code-stubs.h"
#include "src/compiler/access-builder.h"
#include "src/compiler/access-info.h"
#include "src/compiler/allocation-builder.h"
#include "src/compiler/compilation-dependencies.h"
#include "src/compiler/js-graph.h"
#include "src/compiler/linkage.h"
#include "src/compiler/node-matchers.h"
#include "src/compiler/property-access-builder.h"
#include "src/compiler/simplified-operator.h"
#include "src/compiler/type-cache.h"
#include "src/feedback-vector-inl.h"
#include "src/ic/call-optimization.h"
#include "src/objects-inl.h"
#include "src/objects/arguments-inl.h"
#include "src/objects/js-array-buffer-inl.h"
#include "src/objects/js-array-inl.h"
#include "src/vector-slot-pair.h"
namespace v8 {
namespace internal {
namespace compiler {
Reduction JSCallReducer::ReduceMathUnary(Node* node, const Operator* op) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->NaNConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* input = NodeProperties::GetValueInput(node, 2);
input = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
input, effect, control);
Node* value = graph()->NewNode(op, input);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
Reduction JSCallReducer::ReduceMathBinary(Node* node, const Operator* op) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->NaNConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* left = NodeProperties::GetValueInput(node, 2);
Node* right = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->NaNConstant();
left = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
left, effect, control);
right = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
right, effect, control);
Node* value = graph()->NewNode(op, left, right);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
// ES6 section 20.2.2.19 Math.imul ( x, y )
Reduction JSCallReducer::ReduceMathImul(Node* node) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->ZeroConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* left = NodeProperties::GetValueInput(node, 2);
Node* right = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->ZeroConstant();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
left = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
left, effect, control);
right = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
right, effect, control);
left = graph()->NewNode(simplified()->NumberToUint32(), left);
right = graph()->NewNode(simplified()->NumberToUint32(), right);
Node* value = graph()->NewNode(simplified()->NumberImul(), left, right);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
// ES6 section 20.2.2.11 Math.clz32 ( x )
Reduction JSCallReducer::ReduceMathClz32(Node* node) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->Constant(32);
ReplaceWithValue(node, value);
return Replace(value);
}
Node* input = NodeProperties::GetValueInput(node, 2);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
input = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
input, effect, control);
input = graph()->NewNode(simplified()->NumberToUint32(), input);
Node* value = graph()->NewNode(simplified()->NumberClz32(), input);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
// ES6 section 20.2.2.24 Math.max ( value1, value2, ...values )
// ES6 section 20.2.2.25 Math.min ( value1, value2, ...values )
Reduction JSCallReducer::ReduceMathMinMax(Node* node, const Operator* op,
Node* empty_value) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() <= 2) {
ReplaceWithValue(node, empty_value);
return Replace(empty_value);
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* value = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
NodeProperties::GetValueInput(node, 2), effect, control);
for (int i = 3; i < node->op()->ValueInputCount(); i++) {
Node* input = effect = graph()->NewNode(
simplified()->SpeculativeToNumber(NumberOperationHint::kNumberOrOddball,
p.feedback()),
NodeProperties::GetValueInput(node, i), effect, control);
value = graph()->NewNode(op, value, input);
}
ReplaceWithValue(node, value, effect);
return Replace(value);
}
Reduction JSCallReducer::Reduce(Node* node) {
switch (node->opcode()) {
case IrOpcode::kJSConstruct:
return ReduceJSConstruct(node);
case IrOpcode::kJSConstructWithArrayLike:
return ReduceJSConstructWithArrayLike(node);
case IrOpcode::kJSConstructWithSpread:
return ReduceJSConstructWithSpread(node);
case IrOpcode::kJSCall:
return ReduceJSCall(node);
case IrOpcode::kJSCallWithArrayLike:
return ReduceJSCallWithArrayLike(node);
case IrOpcode::kJSCallWithSpread:
return ReduceJSCallWithSpread(node);
default:
break;
}
return NoChange();
}
void JSCallReducer::Finalize() {
// TODO(turbofan): This is not the best solution; ideally we would be able
// to teach the GraphReducer about arbitrary dependencies between different
// nodes, even if they don't show up in the use list of the other node.
std::set<Node*> const waitlist = std::move(waitlist_);
for (Node* node : waitlist) {
if (!node->IsDead()) {
Reduction const reduction = Reduce(node);
if (reduction.Changed()) {
Node* replacement = reduction.replacement();
if (replacement != node) {
Replace(node, replacement);
}
}
}
}
}
// ES6 section 22.1.1 The Array Constructor
Reduction JSCallReducer::ReduceArrayConstructor(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* target = NodeProperties::GetValueInput(node, 0);
CallParameters const& p = CallParametersOf(node->op());
// Turn the {node} into a {JSCreateArray} call.
DCHECK_LE(2u, p.arity());
size_t const arity = p.arity() - 2;
NodeProperties::ReplaceValueInput(node, target, 0);
NodeProperties::ReplaceValueInput(node, target, 1);
NodeProperties::ChangeOp(
node, javascript()->CreateArray(arity, MaybeHandle<AllocationSite>()));
return Changed(node);
}
// ES6 section 19.3.1.1 Boolean ( value )
Reduction JSCallReducer::ReduceBooleanConstructor(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
// Replace the {node} with a proper {ToBoolean} operator.
DCHECK_LE(2u, p.arity());
Node* value = (p.arity() == 2) ? jsgraph()->UndefinedConstant()
: NodeProperties::GetValueInput(node, 2);
value = graph()->NewNode(simplified()->ToBoolean(), value);
ReplaceWithValue(node, value);
return Replace(value);
}
// ES section #sec-object-constructor
Reduction JSCallReducer::ReduceObjectConstructor(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.arity() < 3) return NoChange();
Node* value = (p.arity() >= 3) ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* effect = NodeProperties::GetEffectInput(node);
// We can fold away the Object(x) call if |x| is definitely not a primitive.
if (NodeProperties::CanBePrimitive(isolate(), value, effect)) {
if (!NodeProperties::CanBeNullOrUndefined(isolate(), value, effect)) {
// Turn the {node} into a {JSToObject} call if we know that
// the {value} cannot be null or undefined.
NodeProperties::ReplaceValueInputs(node, value);
NodeProperties::ChangeOp(node, javascript()->ToObject());
return Changed(node);
}
} else {
ReplaceWithValue(node, value);
return Replace(value);
}
return NoChange();
}
// ES6 section 19.2.3.1 Function.prototype.apply ( thisArg, argArray )
Reduction JSCallReducer::ReduceFunctionPrototypeApply(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
size_t arity = p.arity();
DCHECK_LE(2u, arity);
ConvertReceiverMode convert_mode = ConvertReceiverMode::kAny;
if (arity == 2) {
// Neither thisArg nor argArray was provided.
convert_mode = ConvertReceiverMode::kNullOrUndefined;
node->ReplaceInput(0, node->InputAt(1));
node->ReplaceInput(1, jsgraph()->UndefinedConstant());
} else if (arity == 3) {
// The argArray was not provided, just remove the {target}.
node->RemoveInput(0);
--arity;
} else {
Node* target = NodeProperties::GetValueInput(node, 1);
Node* this_argument = NodeProperties::GetValueInput(node, 2);
Node* arguments_list = NodeProperties::GetValueInput(node, 3);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// If {arguments_list} cannot be null or undefined, we don't need
// to expand this {node} to control-flow.
if (!NodeProperties::CanBeNullOrUndefined(isolate(), arguments_list,
effect)) {
// Massage the value inputs appropriately.
node->ReplaceInput(0, target);
node->ReplaceInput(1, this_argument);
node->ReplaceInput(2, arguments_list);
while (arity-- > 3) node->RemoveInput(3);
// Morph the {node} to a {JSCallWithArrayLike}.
NodeProperties::ChangeOp(node,
javascript()->CallWithArrayLike(p.frequency()));
Reduction const reduction = ReduceJSCallWithArrayLike(node);
return reduction.Changed() ? reduction : Changed(node);
} else {
// Check whether {arguments_list} is null.
Node* check_null =
graph()->NewNode(simplified()->ReferenceEqual(), arguments_list,
jsgraph()->NullConstant());
control = graph()->NewNode(common()->Branch(BranchHint::kFalse),
check_null, control);
Node* if_null = graph()->NewNode(common()->IfTrue(), control);
control = graph()->NewNode(common()->IfFalse(), control);
// Check whether {arguments_list} is undefined.
Node* check_undefined =
graph()->NewNode(simplified()->ReferenceEqual(), arguments_list,
jsgraph()->UndefinedConstant());
control = graph()->NewNode(common()->Branch(BranchHint::kFalse),
check_undefined, control);
Node* if_undefined = graph()->NewNode(common()->IfTrue(), control);
control = graph()->NewNode(common()->IfFalse(), control);
// Lower to {JSCallWithArrayLike} if {arguments_list} is neither null
// nor undefined.
Node* effect0 = effect;
Node* control0 = control;
Node* value0 = effect0 = control0 = graph()->NewNode(
javascript()->CallWithArrayLike(p.frequency()), target, this_argument,
arguments_list, context, frame_state, effect0, control0);
// Lower to {JSCall} if {arguments_list} is either null or undefined.
Node* effect1 = effect;
Node* control1 =
graph()->NewNode(common()->Merge(2), if_null, if_undefined);
Node* value1 = effect1 = control1 =
graph()->NewNode(javascript()->Call(2), target, this_argument,
context, frame_state, effect1, control1);
// Rewire potential exception edges.
Node* if_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &if_exception)) {
// Create appropriate {IfException} and {IfSuccess} nodes.
Node* if_exception0 =
graph()->NewNode(common()->IfException(), control0, effect0);
control0 = graph()->NewNode(common()->IfSuccess(), control0);
Node* if_exception1 =
graph()->NewNode(common()->IfException(), control1, effect1);
control1 = graph()->NewNode(common()->IfSuccess(), control1);
// Join the exception edges.
Node* merge =
graph()->NewNode(common()->Merge(2), if_exception0, if_exception1);
Node* ephi = graph()->NewNode(common()->EffectPhi(2), if_exception0,
if_exception1, merge);
Node* phi =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
if_exception0, if_exception1, merge);
ReplaceWithValue(if_exception, phi, ephi, merge);
}
// Join control paths.
control = graph()->NewNode(common()->Merge(2), control0, control1);
effect =
graph()->NewNode(common()->EffectPhi(2), effect0, effect1, control);
Node* value =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
value0, value1, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
}
// Change {node} to the new {JSCall} operator.
NodeProperties::ChangeOp(
node,
javascript()->Call(arity, p.frequency(), VectorSlotPair(), convert_mode));
// Try to further reduce the JSCall {node}.
Reduction const reduction = ReduceJSCall(node);
return reduction.Changed() ? reduction : Changed(node);
}
// ES section #sec-function.prototype.bind
Reduction JSCallReducer::ReduceFunctionPrototypeBind(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
// Value inputs to the {node} are as follows:
//
// - target, which is Function.prototype.bind JSFunction
// - receiver, which is the [[BoundTargetFunction]]
// - bound_this (optional), which is the [[BoundThis]]
// - and all the remaining value inouts are [[BoundArguments]]
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* bound_this = (node->op()->ValueInputCount() < 3)
? jsgraph()->UndefinedConstant()
: NodeProperties::GetValueInput(node, 2);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Ensure that the {receiver} is known to be a JSBoundFunction or
// a JSFunction with the same [[Prototype]], and all maps we've
// seen for the {receiver} so far indicate that {receiver} is
// definitely a constructor or not a constructor.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
bool const is_constructor = receiver_maps[0]->is_constructor();
Handle<Object> const prototype(receiver_maps[0]->prototype(), isolate());
for (Handle<Map> const receiver_map : receiver_maps) {
// Check for consistency among the {receiver_maps}.
STATIC_ASSERT(LAST_TYPE == LAST_FUNCTION_TYPE);
if (receiver_map->prototype() != *prototype) return NoChange();
if (receiver_map->is_constructor() != is_constructor) return NoChange();
if (receiver_map->instance_type() < FIRST_FUNCTION_TYPE) return NoChange();
// Disallow binding of slow-mode functions. We need to figure out
// whether the length and name property are in the original state.
if (receiver_map->is_dictionary_map()) return NoChange();
// Check whether the length and name properties are still present
// as AccessorInfo objects. In that case, their values can be
// recomputed even if the actual value of the object changes.
// This mirrors the checks done in builtins-function-gen.cc at
// runtime otherwise.
Handle<DescriptorArray> descriptors(receiver_map->instance_descriptors(),
isolate());
if (descriptors->number_of_descriptors() < 2) return NoChange();
if (descriptors->GetKey(JSFunction::kLengthDescriptorIndex) !=
ReadOnlyRoots(isolate()).length_string()) {
return NoChange();
}
if (!descriptors->GetStrongValue(JSFunction::kLengthDescriptorIndex)
->IsAccessorInfo()) {
return NoChange();
}
if (descriptors->GetKey(JSFunction::kNameDescriptorIndex) !=
ReadOnlyRoots(isolate()).name_string()) {
return NoChange();
}
if (!descriptors->GetStrongValue(JSFunction::kNameDescriptorIndex)
->IsAccessorInfo()) {
return NoChange();
}
}
// Setup the map for the resulting JSBoundFunction with the
// correct instance {prototype}.
Handle<Map> map(
is_constructor
? native_context()->bound_function_with_constructor_map()
: native_context()->bound_function_without_constructor_map(),
isolate());
if (map->prototype() != *prototype) {
map = Map::TransitionToPrototype(isolate(), map, prototype);
}
// Make sure we can rely on the {receiver_maps}.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect = graph()->NewNode(
simplified()->CheckMaps(CheckMapsFlag::kNone, receiver_maps), receiver,
effect, control);
}
// Replace the {node} with a JSCreateBoundFunction.
int const arity = std::max(0, node->op()->ValueInputCount() - 3);
int const input_count = 2 + arity + 3;
Node** inputs = graph()->zone()->NewArray<Node*>(input_count);
inputs[0] = receiver;
inputs[1] = bound_this;
for (int i = 0; i < arity; ++i) {
inputs[2 + i] = NodeProperties::GetValueInput(node, 3 + i);
}
inputs[2 + arity + 0] = context;
inputs[2 + arity + 1] = effect;
inputs[2 + arity + 2] = control;
Node* value = effect = graph()->NewNode(
javascript()->CreateBoundFunction(arity, map), input_count, inputs);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES6 section 19.2.3.3 Function.prototype.call (thisArg, ...args)
Reduction JSCallReducer::ReduceFunctionPrototypeCall(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
Node* target = NodeProperties::GetValueInput(node, 0);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Change context of {node} to the Function.prototype.call context,
// to ensure any exception is thrown in the correct context.
Node* context;
HeapObjectMatcher m(target);
if (m.HasValue()) {
Handle<JSFunction> function = Handle<JSFunction>::cast(m.Value());
context = jsgraph()->HeapConstant(handle(function->context(), isolate()));
} else {
context = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSFunctionContext()), target,
effect, control);
}
NodeProperties::ReplaceContextInput(node, context);
NodeProperties::ReplaceEffectInput(node, effect);
// Remove the target from {node} and use the receiver as target instead, and
// the thisArg becomes the new target. If thisArg was not provided, insert
// undefined instead.
size_t arity = p.arity();
DCHECK_LE(2u, arity);
ConvertReceiverMode convert_mode;
if (arity == 2) {
// The thisArg was not provided, use undefined as receiver.
convert_mode = ConvertReceiverMode::kNullOrUndefined;
node->ReplaceInput(0, node->InputAt(1));
node->ReplaceInput(1, jsgraph()->UndefinedConstant());
} else {
// Just remove the target, which is the first value input.
convert_mode = ConvertReceiverMode::kAny;
node->RemoveInput(0);
--arity;
}
NodeProperties::ChangeOp(
node,
javascript()->Call(arity, p.frequency(), VectorSlotPair(), convert_mode));
// Try to further reduce the JSCall {node}.
Reduction const reduction = ReduceJSCall(node);
return reduction.Changed() ? reduction : Changed(node);
}
// ES6 section 19.2.3.6 Function.prototype [ @@hasInstance ] (V)
Reduction JSCallReducer::ReduceFunctionPrototypeHasInstance(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* object = (node->op()->ValueInputCount() >= 3)
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// TODO(turbofan): If JSOrdinaryToInstance raises an exception, the
// stack trace doesn't contain the @@hasInstance call; we have the
// corresponding bug in the baseline case. Some massaging of the frame
// state would be necessary here.
// Morph this {node} into a JSOrdinaryHasInstance node.
node->ReplaceInput(0, receiver);
node->ReplaceInput(1, object);
node->ReplaceInput(2, context);
node->ReplaceInput(3, frame_state);
node->ReplaceInput(4, effect);
node->ReplaceInput(5, control);
node->TrimInputCount(6);
NodeProperties::ChangeOp(node, javascript()->OrdinaryHasInstance());
return Changed(node);
}
Reduction JSCallReducer::ReduceObjectGetPrototype(Node* node, Node* object) {
Node* effect = NodeProperties::GetEffectInput(node);
// Try to determine the {object} map.
ZoneHandleSet<Map> object_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), object, effect,
&object_maps);
if (result != NodeProperties::kNoReceiverMaps) {
Handle<Map> candidate_map = object_maps[0];
Handle<Object> candidate_prototype(candidate_map->prototype(), isolate());
// Check if we can constant-fold the {candidate_prototype}.
for (size_t i = 0; i < object_maps.size(); ++i) {
Handle<Map> object_map = object_maps[i];
if (object_map->IsSpecialReceiverMap() ||
object_map->has_hidden_prototype() ||
object_map->prototype() != *candidate_prototype) {
// We exclude special receivers, like JSProxy or API objects that
// might require access checks here; we also don't want to deal
// with hidden prototypes at this point.
return NoChange();
}
// The above check also excludes maps for primitive values, which is
// important because we are not applying [[ToObject]] here as expected.
DCHECK(!object_map->IsPrimitiveMap() && object_map->IsJSReceiverMap());
if (result == NodeProperties::kUnreliableReceiverMaps &&
!object_map->is_stable()) {
return NoChange();
}
}
if (result == NodeProperties::kUnreliableReceiverMaps) {
for (size_t i = 0; i < object_maps.size(); ++i) {
dependencies()->DependOnStableMap(
MapRef(js_heap_broker(), object_maps[i]));
}
}
Node* value = jsgraph()->Constant(candidate_prototype);
ReplaceWithValue(node, value);
return Replace(value);
}
return NoChange();
}
// ES6 section 19.1.2.11 Object.getPrototypeOf ( O )
Reduction JSCallReducer::ReduceObjectGetPrototypeOf(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* object = (node->op()->ValueInputCount() >= 3)
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
return ReduceObjectGetPrototype(node, object);
}
// ES section #sec-object.is
Reduction JSCallReducer::ReduceObjectIs(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& params = CallParametersOf(node->op());
int const argc = static_cast<int>(params.arity() - 2);
Node* lhs = (argc >= 1) ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* rhs = (argc >= 2) ? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
Node* value = graph()->NewNode(simplified()->SameValue(), lhs, rhs);
ReplaceWithValue(node, value);
return Replace(value);
}
// ES6 section B.2.2.1.1 get Object.prototype.__proto__
Reduction JSCallReducer::ReduceObjectPrototypeGetProto(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
return ReduceObjectGetPrototype(node, receiver);
}
// ES #sec-object.prototype.hasownproperty
Reduction JSCallReducer::ReduceObjectPrototypeHasOwnProperty(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& params = CallParametersOf(node->op());
int const argc = static_cast<int>(params.arity() - 2);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* name = (argc >= 1) ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// We can optimize a call to Object.prototype.hasOwnProperty if it's being
// used inside a fast-mode for..in, so for code like this:
//
// for (name in receiver) {
// if (receiver.hasOwnProperty(name)) {
// ...
// }
// }
//
// If the for..in is in fast-mode, we know that the {receiver} has {name}
// as own property, otherwise the enumeration wouldn't include it. The graph
// constructed by the BytecodeGraphBuilder in this case looks like this:
// receiver
// ^ ^
// | |
// | +-+
// | |
// | JSToObject
// | ^
// | |
// | JSForInNext
// | ^
// +----+ |
// | |
// JSCall[hasOwnProperty]
// We can constant-fold the {node} to True in this case, and insert
// a (potentially redundant) map check to guard the fact that the
// {receiver} map didn't change since the dominating JSForInNext. This
// map check is only necessary when TurboFan cannot prove that there
// is no observable side effect between the {JSForInNext} and the
// {JSCall} to Object.prototype.hasOwnProperty.
//
// Also note that it's safe to look through the {JSToObject}, since the
// Object.prototype.hasOwnProperty does an implicit ToObject anyway, and
// these operations are not observable.
if (name->opcode() == IrOpcode::kJSForInNext) {
ForInMode const mode = ForInModeOf(name->op());
if (mode != ForInMode::kGeneric) {
Node* object = NodeProperties::GetValueInput(name, 0);
Node* cache_type = NodeProperties::GetValueInput(name, 2);
if (object->opcode() == IrOpcode::kJSToObject) {
object = NodeProperties::GetValueInput(object, 0);
}
if (object == receiver) {
// No need to repeat the map check if we can prove that there's no
// observable side effect between {effect} and {name].
if (!NodeProperties::NoObservableSideEffectBetween(effect, name)) {
Node* receiver_map = effect =
graph()->NewNode(simplified()->LoadField(AccessBuilder::ForMap()),
receiver, effect, control);
Node* check = graph()->NewNode(simplified()->ReferenceEqual(),
receiver_map, cache_type);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kWrongMap), check, effect,
control);
}
Node* value = jsgraph()->TrueConstant();
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
}
}
return NoChange();
}
// ES #sec-object.prototype.isprototypeof
Reduction JSCallReducer::ReduceObjectPrototypeIsPrototypeOf(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* value = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* effect = NodeProperties::GetEffectInput(node);
// Ensure that the {receiver} is known to be a JSReceiver (so that
// the ToObject step of Object.prototype.isPrototypeOf is a no-op).
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
for (size_t i = 0; i < receiver_maps.size(); ++i) {
if (!receiver_maps[i]->IsJSReceiverMap()) return NoChange();
}
// We don't check whether {value} is a proper JSReceiver here explicitly,
// and don't explicitly rule out Primitive {value}s, since all of them
// have null as their prototype, so the prototype chain walk inside the
// JSHasInPrototypeChain operator immediately aborts and yields false.
NodeProperties::ReplaceValueInput(node, value, 0);
NodeProperties::ReplaceValueInput(node, receiver, 1);
for (int i = node->op()->ValueInputCount(); i-- > 2;) {
node->RemoveInput(i);
}
NodeProperties::ChangeOp(node, javascript()->HasInPrototypeChain());
return Changed(node);
}
// ES6 section 26.1.1 Reflect.apply ( target, thisArgument, argumentsList )
Reduction JSCallReducer::ReduceReflectApply(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
DCHECK_LE(0, arity);
// Massage value inputs appropriately.
node->RemoveInput(0);
node->RemoveInput(0);
while (arity < 3) {
node->InsertInput(graph()->zone(), arity++, jsgraph()->UndefinedConstant());
}
while (arity-- > 3) {
node->RemoveInput(arity);
}
NodeProperties::ChangeOp(node,
javascript()->CallWithArrayLike(p.frequency()));
Reduction const reduction = ReduceJSCallWithArrayLike(node);
return reduction.Changed() ? reduction : Changed(node);
}
// ES6 section 26.1.2 Reflect.construct ( target, argumentsList [, newTarget] )
Reduction JSCallReducer::ReduceReflectConstruct(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
DCHECK_LE(0, arity);
// Massage value inputs appropriately.
node->RemoveInput(0);
node->RemoveInput(0);
while (arity < 2) {
node->InsertInput(graph()->zone(), arity++, jsgraph()->UndefinedConstant());
}
if (arity < 3) {
node->InsertInput(graph()->zone(), arity++, node->InputAt(0));
}
while (arity-- > 3) {
node->RemoveInput(arity);
}
NodeProperties::ChangeOp(node,
javascript()->ConstructWithArrayLike(p.frequency()));
Reduction const reduction = ReduceJSConstructWithArrayLike(node);
return reduction.Changed() ? reduction : Changed(node);
}
// ES6 section 26.1.7 Reflect.getPrototypeOf ( target )
Reduction JSCallReducer::ReduceReflectGetPrototypeOf(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* target = (node->op()->ValueInputCount() >= 3)
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
return ReduceObjectGetPrototype(node, target);
}
// ES6 section #sec-object.create Object.create(proto, properties)
Reduction JSCallReducer::ReduceObjectCreate(Node* node) {
int arg_count = node->op()->ValueInputCount();
Node* properties = arg_count >= 4 ? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
if (properties != jsgraph()->UndefinedConstant()) return NoChange();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* prototype = arg_count >= 3 ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
node->ReplaceInput(0, prototype);
node->ReplaceInput(1, context);
node->ReplaceInput(2, frame_state);
node->ReplaceInput(3, effect);
node->ReplaceInput(4, control);
node->TrimInputCount(5);
NodeProperties::ChangeOp(node, javascript()->CreateObject());
return Changed(node);
}
// ES section #sec-reflect.get
Reduction JSCallReducer::ReduceReflectGet(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
if (arity != 2) return NoChange();
Node* target = NodeProperties::GetValueInput(node, 2);
Node* key = NodeProperties::GetValueInput(node, 3);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Check whether {target} is a JSReceiver.
Node* check = graph()->NewNode(simplified()->ObjectIsReceiver(), target);
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
// Throw an appropriate TypeError if the {target} is not a JSReceiver.
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
{
if_false = efalse = graph()->NewNode(
javascript()->CallRuntime(Runtime::kThrowTypeError, 2),
jsgraph()->Constant(MessageTemplate::kCalledOnNonObject),
jsgraph()->HeapConstant(
factory()->NewStringFromAsciiChecked("Reflect.get")),
context, frame_state, efalse, if_false);
}
// Otherwise just use the existing GetPropertyStub.
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue;
{
Callable callable =
Builtins::CallableFor(isolate(), Builtins::kGetProperty);
auto call_descriptor = Linkage::GetStubCallDescriptor(
graph()->zone(), callable.descriptor(), 0,
CallDescriptor::kNeedsFrameState, Operator::kNoProperties);
Node* stub_code = jsgraph()->HeapConstant(callable.code());
vtrue = etrue = if_true =
graph()->NewNode(common()->Call(call_descriptor), stub_code, target,
key, context, frame_state, etrue, if_true);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
// Create appropriate {IfException} and {IfSuccess} nodes.
Node* extrue = graph()->NewNode(common()->IfException(), etrue, if_true);
if_true = graph()->NewNode(common()->IfSuccess(), if_true);
Node* exfalse = graph()->NewNode(common()->IfException(), efalse, if_false);
if_false = graph()->NewNode(common()->IfSuccess(), if_false);
// Join the exception edges.
Node* merge = graph()->NewNode(common()->Merge(2), extrue, exfalse);
Node* ephi =
graph()->NewNode(common()->EffectPhi(2), extrue, exfalse, merge);
Node* phi =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
extrue, exfalse, merge);
ReplaceWithValue(on_exception, phi, ephi, merge);
}
// Connect the throwing path to end.
if_false = graph()->NewNode(common()->Throw(), efalse, if_false);
NodeProperties::MergeControlToEnd(graph(), common(), if_false);
// Continue on the regular path.
ReplaceWithValue(node, vtrue, etrue, if_true);
return Changed(vtrue);
}
// ES section #sec-reflect.has
Reduction JSCallReducer::ReduceReflectHas(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
DCHECK_LE(0, arity);
Node* target = (arity >= 1) ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* key = (arity >= 2) ? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Check whether {target} is a JSReceiver.
Node* check = graph()->NewNode(simplified()->ObjectIsReceiver(), target);
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
// Throw an appropriate TypeError if the {target} is not a JSReceiver.
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
{
if_false = efalse = graph()->NewNode(
javascript()->CallRuntime(Runtime::kThrowTypeError, 2),
jsgraph()->Constant(MessageTemplate::kCalledOnNonObject),
jsgraph()->HeapConstant(
factory()->NewStringFromAsciiChecked("Reflect.has")),
context, frame_state, efalse, if_false);
}
// Otherwise just use the existing {JSHasProperty} logic.
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue;
{
vtrue = etrue = if_true =
graph()->NewNode(javascript()->HasProperty(), target, key, context,
frame_state, etrue, if_true);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
// Create appropriate {IfException} and {IfSuccess} nodes.
Node* extrue = graph()->NewNode(common()->IfException(), etrue, if_true);
if_true = graph()->NewNode(common()->IfSuccess(), if_true);
Node* exfalse = graph()->NewNode(common()->IfException(), efalse, if_false);
if_false = graph()->NewNode(common()->IfSuccess(), if_false);
// Join the exception edges.
Node* merge = graph()->NewNode(common()->Merge(2), extrue, exfalse);
Node* ephi =
graph()->NewNode(common()->EffectPhi(2), extrue, exfalse, merge);
Node* phi =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
extrue, exfalse, merge);
ReplaceWithValue(on_exception, phi, ephi, merge);
}
// Connect the throwing path to end.
if_false = graph()->NewNode(common()->Throw(), efalse, if_false);
NodeProperties::MergeControlToEnd(graph(), common(), if_false);
// Continue on the regular path.
ReplaceWithValue(node, vtrue, etrue, if_true);
return Changed(vtrue);
}
bool CanInlineArrayIteratingBuiltin(Isolate* isolate,
Handle<Map> receiver_map) {
if (!receiver_map->prototype()->IsJSArray()) return false;
Handle<JSArray> receiver_prototype(JSArray::cast(receiver_map->prototype()),
isolate);
return receiver_map->instance_type() == JS_ARRAY_TYPE &&
IsFastElementsKind(receiver_map->elements_kind()) &&
isolate->IsNoElementsProtectorIntact() &&
isolate->IsAnyInitialArrayPrototype(receiver_prototype);
}
Node* JSCallReducer::WireInLoopStart(Node* k, Node** control, Node** effect) {
Node* loop = *control =
graph()->NewNode(common()->Loop(2), *control, *control);
Node* eloop = *effect =
graph()->NewNode(common()->EffectPhi(2), *effect, *effect, loop);
Node* terminate = graph()->NewNode(common()->Terminate(), eloop, loop);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
return graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2), k,
k, loop);
}
void JSCallReducer::WireInLoopEnd(Node* loop, Node* eloop, Node* vloop, Node* k,
Node* control, Node* effect) {
loop->ReplaceInput(1, control);
vloop->ReplaceInput(1, k);
eloop->ReplaceInput(1, effect);
}
Reduction JSCallReducer::ReduceArrayForEach(Node* node,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* this_arg = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
// By ensuring that {kind} is object or double, we can be polymorphic
// on different elements kinds.
ElementsKind kind = receiver_maps[0]->elements_kind();
if (IsSmiElementsKind(kind)) {
kind = FastSmiToObjectElementsKind(kind);
}
for (Handle<Map> receiver_map : receiver_maps) {
ElementsKind next_kind = receiver_map->elements_kind();
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map)) {
return NoChange();
}
if (!IsFastElementsKind(next_kind)) {
return NoChange();
}
if (IsDoubleElementsKind(kind) != IsDoubleElementsKind(next_kind)) {
return NoChange();
}
if (IsHoleyElementsKind(next_kind)) {
kind = GetHoleyElementsKind(kind);
}
}
// Install code dependencies on the {receiver} prototype maps and the
// global array protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* k = jsgraph()->ZeroConstant();
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
// Check whether the given callback function is callable. Note that this has
// to happen outside the loop to make sure we also throw on empty arrays.
Node* check_frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayForEachLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
Node* check_fail = nullptr;
Node* check_throw = nullptr;
WireInCallbackIsCallableCheck(fncallback, context, check_frame_state, effect,
&control, &check_fail, &check_throw);
// Start the loop.
Node* vloop = k = WireInLoopStart(k, &control, &effect);
Node *loop = control, *eloop = effect;
checkpoint_params[3] = k;
Node* continue_test =
graph()->NewNode(simplified()->NumberLessThan(), k, original_length);
Node* continue_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
continue_test, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), continue_branch);
Node* if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
control = if_true;
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayForEachLoopEagerDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
// Make sure the map hasn't changed during the iteration
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k =
graph()->NewNode(simplified()->NumberAdd(), k, jsgraph()->OneConstant());
checkpoint_params[3] = next_k;
Node* hole_true = nullptr;
Node* hole_false = nullptr;
Node* effect_true = effect;
if (IsHoleyElementsKind(kind)) {
// Holey elements kind require a hole check and skipping of the element in
// the case of a hole.
Node* check;
if (IsDoubleElementsKind(kind)) {
check = graph()->NewNode(simplified()->NumberIsFloat64Hole(), element);
} else {
check = graph()->NewNode(simplified()->ReferenceEqual(), element,
jsgraph()->TheHoleConstant());
}
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
hole_true = graph()->NewNode(common()->IfTrue(), branch);
hole_false = graph()->NewNode(common()->IfFalse(), branch);
control = hole_false;
// The contract is that we don't leak "the hole" into "user JavaScript",
// so we must rename the {element} here to explicitly exclude "the hole"
// from the type of {element}.
element = effect = graph()->NewNode(
common()->TypeGuard(Type::NonInternal()), element, effect, control);
}
frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayForEachLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
control = effect = graph()->NewNode(
javascript()->Call(5, p.frequency()), fncallback, this_arg, element, k,
receiver, context, frame_state, effect, control);
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
if (IsHoleyElementsKind(kind)) {
Node* after_call_control = control;
Node* after_call_effect = effect;
control = hole_true;
effect = effect_true;
control = graph()->NewNode(common()->Merge(2), control, after_call_control);
effect = graph()->NewNode(common()->EffectPhi(2), effect, after_call_effect,
control);
}
WireInLoopEnd(loop, eloop, vloop, next_k, control, effect);
control = if_false;
effect = eloop;
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, jsgraph()->UndefinedConstant(), effect, control);
return Replace(jsgraph()->UndefinedConstant());
}
Reduction JSCallReducer::ReduceArrayReduce(Node* node,
ArrayReduceDirection direction,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
bool left = direction == ArrayReduceDirection::kLeft;
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
if (!UnionElementsKindUptoSize(&kind, receiver_map->elements_kind()))
return NoChange();
}
std::function<Node*(Node*)> hole_check = [this, kind](Node* element) {
if (IsDoubleElementsKind(kind)) {
return graph()->NewNode(simplified()->NumberIsFloat64Hole(), element);
} else {
return graph()->NewNode(simplified()->ReferenceEqual(), element,
jsgraph()->TheHoleConstant());
}
};
// Install code dependencies on the {receiver} prototype maps and the
// global array protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(PACKED_ELEMENTS)),
receiver, effect, control);
Node* initial_index =
left ? jsgraph()->ZeroConstant()
: graph()->NewNode(simplified()->NumberSubtract(), original_length,
jsgraph()->OneConstant());
const Operator* next_op =
left ? simplified()->NumberAdd() : simplified()->NumberSubtract();
Node* k = initial_index;
Node* check_frame_state;
{
Builtins::Name builtin_lazy =
left ? Builtins::kArrayReduceLoopLazyDeoptContinuation
: Builtins::kArrayReduceRightLoopLazyDeoptContinuation;
const std::vector<Node*> checkpoint_params(
{receiver, fncallback, k, original_length,
jsgraph()->UndefinedConstant()});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
check_frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, builtin_lazy, node->InputAt(0), context,
checkpoint_params.data(), stack_parameters - 1, outer_frame_state,
ContinuationFrameStateMode::LAZY);
}
Node* check_fail = nullptr;
Node* check_throw = nullptr;
// Check whether the given callback function is callable. Note that
// this has to happen outside the loop to make sure we also throw on
// empty arrays.
WireInCallbackIsCallableCheck(fncallback, context, check_frame_state, effect,
&control, &check_fail, &check_throw);
// Set initial accumulator value
Node* cur = jsgraph()->TheHoleConstant();
if (node->op()->ValueInputCount() > 3) {
cur = NodeProperties::GetValueInput(node, 3);
} else {
// Find first/last non holey element. In case the search fails, we need a
// deopt continuation.
Builtins::Name builtin_eager =
left ? Builtins::kArrayReducePreLoopEagerDeoptContinuation
: Builtins::kArrayReduceRightPreLoopEagerDeoptContinuation;
const std::vector<Node*> checkpoint_params(
{receiver, fncallback, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* find_first_element_frame_state =
CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, builtin_eager, node->InputAt(0), context,
checkpoint_params.data(), stack_parameters, outer_frame_state,
ContinuationFrameStateMode::EAGER);
Node* vloop = k = WireInLoopStart(k, &control, &effect);
Node* loop = control;
Node* eloop = effect;
effect = graph()->NewNode(common()->Checkpoint(),
find_first_element_frame_state, effect, control);
Node* continue_test =
left ? graph()->NewNode(simplified()->NumberLessThan(), k,
original_length)
: graph()->NewNode(simplified()->NumberLessThanOrEqual(),
jsgraph()->ZeroConstant(), k);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kNoInitialElement),
continue_test, effect, control);
cur = SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k = graph()->NewNode(next_op, k, jsgraph()->OneConstant());
Node* hole_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
hole_check(cur), control);
Node* found_el = graph()->NewNode(common()->IfFalse(), hole_branch);
control = found_el;
Node* is_hole = graph()->NewNode(common()->IfTrue(), hole_branch);
WireInLoopEnd(loop, eloop, vloop, next_k, is_hole, effect);
// We did the hole-check, so exclude hole from the type.
cur = effect = graph()->NewNode(common()->TypeGuard(Type::NonInternal()),
cur, effect, control);
k = next_k;
}
// Start the loop.
Node* loop = control = graph()->NewNode(common()->Loop(2), control, control);
Node* eloop = effect =
graph()->NewNode(common()->EffectPhi(2), effect, effect, loop);
Node* terminate = graph()->NewNode(common()->Terminate(), eloop, loop);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
Node* kloop = k = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2), k, k, loop);
Node* curloop = cur = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2), cur, cur, loop);
control = loop;
effect = eloop;
Node* continue_test =
left
? graph()->NewNode(simplified()->NumberLessThan(), k, original_length)
: graph()->NewNode(simplified()->NumberLessThanOrEqual(),
jsgraph()->ZeroConstant(), k);
Node* continue_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
continue_test, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), continue_branch);
Node* if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
control = if_true;
{
Builtins::Name builtin_eager =
left ? Builtins::kArrayReduceLoopEagerDeoptContinuation
: Builtins::kArrayReduceRightLoopEagerDeoptContinuation;
const std::vector<Node*> checkpoint_params(
{receiver, fncallback, k, original_length, curloop});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, builtin_eager, node->InputAt(0), context,
checkpoint_params.data(), stack_parameters, outer_frame_state,
ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
}
// Make sure the map hasn't changed during the iteration
effect = graph()->NewNode(
simplified()->CheckMaps(CheckMapsFlag::kNone, receiver_maps), receiver,
effect, control);
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k = graph()->NewNode(next_op, k, jsgraph()->OneConstant());
Node* hole_true = nullptr;
Node* hole_false = nullptr;
Node* effect_true = effect;
if (IsHoleyElementsKind(kind)) {
// Holey elements kind require a hole check and skipping of the element in
// the case of a hole.
Node* branch = graph()->NewNode(common()->Branch(BranchHint::kFalse),
hole_check(element), control);
hole_true = graph()->NewNode(common()->IfTrue(), branch);
hole_false = graph()->NewNode(common()->IfFalse(), branch);
control = hole_false;
// The contract is that we don't leak "the hole" into "user JavaScript",
// so we must rename the {element} here to explicitly exclude "the hole"
// from the type of {element}.
element = effect = graph()->NewNode(
common()->TypeGuard(Type::NonInternal()), element, effect, control);
}
Node* next_cur;
{
Builtins::Name builtin_lazy =
left ? Builtins::kArrayReduceLoopLazyDeoptContinuation
: Builtins::kArrayReduceRightLoopLazyDeoptContinuation;
const std::vector<Node*> checkpoint_params(
{receiver, fncallback, next_k, original_length, curloop});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, builtin_lazy, node->InputAt(0), context,
checkpoint_params.data(), stack_parameters - 1, outer_frame_state,
ContinuationFrameStateMode::LAZY);
next_cur = control = effect =
graph()->NewNode(javascript()->Call(6, p.frequency()), fncallback,
jsgraph()->UndefinedConstant(), cur, element, k,
receiver, context, frame_state, effect, control);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
if (IsHoleyElementsKind(kind)) {
Node* after_call_control = control;
Node* after_call_effect = effect;
control = hole_true;
effect = effect_true;
control = graph()->NewNode(common()->Merge(2), control, after_call_control);
effect = graph()->NewNode(common()->EffectPhi(2), effect, after_call_effect,
control);
next_cur =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2), cur,
next_cur, control);
}
k = next_k;
cur = next_cur;
loop->ReplaceInput(1, control);
kloop->ReplaceInput(1, k);
curloop->ReplaceInput(1, cur);
eloop->ReplaceInput(1, effect);
control = if_false;
effect = eloop;
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, curloop, effect, control);
return Replace(curloop);
}
Reduction JSCallReducer::ReduceArrayMap(Node* node,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* this_arg = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
// Ensure that any changes to the Array species constructor cause deopt.
if (!isolate()->IsArraySpeciesLookupChainIntact()) return NoChange();
const ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
// We can handle different maps, as long as their elements kind are the
// same.
if (receiver_map->elements_kind() != kind) return NoChange();
}
if (IsHoleyElementsKind(kind)) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->array_species_protector()));
Handle<JSFunction> handle_constructor(
JSFunction::cast(
native_context()->GetInitialJSArrayMap(kind)->GetConstructor()),
isolate());
Node* array_constructor = jsgraph()->HeapConstant(handle_constructor);
Node* k = jsgraph()->ZeroConstant();
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
// Even though {JSCreateArray} is not marked as {kNoThrow}, we can elide the
// exceptional projections because it cannot throw with the given parameters.
Node* a = control = effect = graph()->NewNode(
javascript()->CreateArray(1, MaybeHandle<AllocationSite>()),
array_constructor, array_constructor, original_length, context,
outer_frame_state, effect, control);
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, a, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
// Check whether the given callback function is callable. Note that this has
// to happen outside the loop to make sure we also throw on empty arrays.
Node* check_frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayMapLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
Node* check_fail = nullptr;
Node* check_throw = nullptr;
WireInCallbackIsCallableCheck(fncallback, context, check_frame_state, effect,
&control, &check_fail, &check_throw);
// Start the loop.
Node* vloop = k = WireInLoopStart(k, &control, &effect);
Node *loop = control, *eloop = effect;
checkpoint_params[4] = k;
Node* continue_test =
graph()->NewNode(simplified()->NumberLessThan(), k, original_length);
Node* continue_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
continue_test, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), continue_branch);
Node* if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
control = if_true;
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayMapLoopEagerDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
// Make sure the map hasn't changed during the iteration
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k =
graph()->NewNode(simplified()->NumberAdd(), k, jsgraph()->OneConstant());
Node* hole_true = nullptr;
Node* hole_false = nullptr;
Node* effect_true = effect;
if (IsHoleyElementsKind(kind)) {
// Holey elements kind require a hole check and skipping of the element in
// the case of a hole.
Node* check;
if (IsDoubleElementsKind(kind)) {
check = graph()->NewNode(simplified()->NumberIsFloat64Hole(), element);
} else {
check = graph()->NewNode(simplified()->ReferenceEqual(), element,
jsgraph()->TheHoleConstant());
}
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
hole_true = graph()->NewNode(common()->IfTrue(), branch);
hole_false = graph()->NewNode(common()->IfFalse(), branch);
control = hole_false;
// The contract is that we don't leak "the hole" into "user JavaScript",
// so we must rename the {element} here to explicitly exclude "the hole"
// from the type of {element}.
element = effect = graph()->NewNode(
common()->TypeGuard(Type::NonInternal()), element, effect, control);
}
// This frame state is dealt with by hand in
// ArrayMapLoopLazyDeoptContinuation.
frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayMapLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
Node* callback_value = control = effect = graph()->NewNode(
javascript()->Call(5, p.frequency()), fncallback, this_arg, element, k,
receiver, context, frame_state, effect, control);
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
// The array {a} should be HOLEY_SMI_ELEMENTS because we'd only come into this
// loop if the input array length is non-zero, and "new Array({x > 0})" always
// produces a HOLEY array.
Handle<Map> double_map(Map::cast(native_context()->get(
Context::ArrayMapIndex(HOLEY_DOUBLE_ELEMENTS))),
isolate());
Handle<Map> fast_map(
Map::cast(native_context()->get(Context::ArrayMapIndex(HOLEY_ELEMENTS))),
isolate());
effect = graph()->NewNode(
simplified()->TransitionAndStoreElement(double_map, fast_map), a, k,
callback_value, effect, control);
if (IsHoleyElementsKind(kind)) {
Node* after_call_and_store_control = control;
Node* after_call_and_store_effect = effect;
control = hole_true;
effect = effect_true;
control = graph()->NewNode(common()->Merge(2), control,
after_call_and_store_control);
effect = graph()->NewNode(common()->EffectPhi(2), effect,
after_call_and_store_effect, control);
}
WireInLoopEnd(loop, eloop, vloop, next_k, control, effect);
control = if_false;
effect = eloop;
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, a, effect, control);
return Replace(a);
}
Reduction JSCallReducer::ReduceArrayFilter(Node* node,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* this_arg = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
// And ensure that any changes to the Array species constructor cause deopt.
if (!isolate()->IsArraySpeciesLookupChainIntact()) return NoChange();
const ElementsKind kind = receiver_maps[0]->elements_kind();
// The output array is packed (filter doesn't visit holes).
const ElementsKind packed_kind = GetPackedElementsKind(kind);
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map)) {
return NoChange();
}
// We can handle different maps, as long as their elements kind are the
// same.
if (receiver_map->elements_kind() != kind) return NoChange();
}
if (IsHoleyElementsKind(kind)) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->array_species_protector()));
Handle<Map> initial_map(
Map::cast(native_context()->GetInitialJSArrayMap(packed_kind)),
isolate());
Node* k = jsgraph()->ZeroConstant();
Node* to = jsgraph()->ZeroConstant();
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* a; // Construct the output array.
{
AllocationBuilder ab(jsgraph(), effect, control);
ab.Allocate(initial_map->instance_size(), NOT_TENURED, Type::Array());
ab.Store(AccessBuilder::ForMap(), initial_map);
Node* empty_fixed_array = jsgraph()->EmptyFixedArrayConstant();
ab.Store(AccessBuilder::ForJSObjectPropertiesOrHash(), empty_fixed_array);
ab.Store(AccessBuilder::ForJSObjectElements(), empty_fixed_array);
ab.Store(AccessBuilder::ForJSArrayLength(packed_kind),
jsgraph()->ZeroConstant());
for (int i = 0; i < initial_map->GetInObjectProperties(); ++i) {
ab.Store(AccessBuilder::ForJSObjectInObjectProperty(
MapRef(js_heap_broker(), initial_map), i),
jsgraph()->UndefinedConstant());
}
a = effect = ab.Finish();
}
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
// Check whether the given callback function is callable. Note that this has
// to happen outside the loop to make sure we also throw on empty arrays.
Node* check_fail = nullptr;
Node* check_throw = nullptr;
{
// This frame state doesn't ever call the deopt continuation, it's only
// necessary to specifiy a continuation in order to handle the exceptional
// case. We don't have all the values available to completely fill out
// checkpoint_params yet, but that's okay because it'll never be called.
// Therefore, "to" is mentioned twice, once standing in for the k_value
// value.
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, a, k, original_length, to, to});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* check_frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayFilterLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
WireInCallbackIsCallableCheck(fncallback, context, check_frame_state,
effect, &control, &check_fail, &check_throw);
}
// Start the loop.
Node* vloop = k = WireInLoopStart(k, &control, &effect);
Node *loop = control, *eloop = effect;
Node* v_to_loop = to = graph()->NewNode(
common()->Phi(MachineRepresentation::kTaggedSigned, 2), to, to, loop);
Node* continue_test =
graph()->NewNode(simplified()->NumberLessThan(), k, original_length);
Node* continue_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
continue_test, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), continue_branch);
Node* if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
control = if_true;
{
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, a, k, original_length, to});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayFilterLoopEagerDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
}
// Make sure the map hasn't changed during the iteration.
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k =
graph()->NewNode(simplified()->NumberAdd(), k, jsgraph()->OneConstant());
Node* hole_true = nullptr;
Node* hole_false = nullptr;
Node* effect_true = effect;
Node* hole_true_vto = to;
if (IsHoleyElementsKind(kind)) {
// Holey elements kind require a hole check and skipping of the element in
// the case of a hole.
Node* check;
if (IsDoubleElementsKind(kind)) {
check = graph()->NewNode(simplified()->NumberIsFloat64Hole(), element);
} else {
check = graph()->NewNode(simplified()->ReferenceEqual(), element,
jsgraph()->TheHoleConstant());
}
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
hole_true = graph()->NewNode(common()->IfTrue(), branch);
hole_false = graph()->NewNode(common()->IfFalse(), branch);
control = hole_false;
// The contract is that we don't leak "the hole" into "user JavaScript",
// so we must rename the {element} here to explicitly exclude "the hole"
// from the type of {element}.
element = effect = graph()->NewNode(
common()->TypeGuard(Type::NonInternal()), element, effect, control);
}
Node* callback_value = nullptr;
{
// This frame state is dealt with by hand in
// Builtins::kArrayFilterLoopLazyDeoptContinuation.
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, a, k, original_length, element, to});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayFilterLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
callback_value = control = effect = graph()->NewNode(
javascript()->Call(5, p.frequency()), fncallback, this_arg, element, k,
receiver, context, frame_state, effect, control);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
// We need an eager frame state for right after the callback function
// returned, just in case an attempt to grow the output array fails.
//
// Note that we are intentionally reusing the
// Builtins::kArrayFilterLoopLazyDeoptContinuation as an *eager* entry
// point in this case. This is safe, because re-evaluating a [ToBoolean]
// coercion is safe.
{
std::vector<Node*> checkpoint_params({receiver, fncallback, this_arg, a, k,
original_length, element, to,
callback_value});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayFilterLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
}
// We have to coerce callback_value to boolean, and only store the element in
// a if it's true. The checkpoint above protects against the case that
// growing {a} fails.
to = DoFilterPostCallbackWork(packed_kind, &control, &effect, a, to, element,
callback_value);
if (IsHoleyElementsKind(kind)) {
Node* after_call_control = control;
Node* after_call_effect = effect;
control = hole_true;
effect = effect_true;
control = graph()->NewNode(common()->Merge(2), control, after_call_control);
effect = graph()->NewNode(common()->EffectPhi(2), effect, after_call_effect,
control);
to =
graph()->NewNode(common()->Phi(MachineRepresentation::kTaggedSigned, 2),
hole_true_vto, to, control);
}
WireInLoopEnd(loop, eloop, vloop, next_k, control, effect);
v_to_loop->ReplaceInput(1, to);
control = if_false;
effect = eloop;
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, a, effect, control);
return Replace(a);
}
Reduction JSCallReducer::ReduceArrayFind(Node* node, ArrayFindVariant variant,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Builtins::Name eager_continuation_builtin;
Builtins::Name lazy_continuation_builtin;
Builtins::Name after_callback_lazy_continuation_builtin;
if (variant == ArrayFindVariant::kFind) {
eager_continuation_builtin = Builtins::kArrayFindLoopEagerDeoptContinuation;
lazy_continuation_builtin = Builtins::kArrayFindLoopLazyDeoptContinuation;
after_callback_lazy_continuation_builtin =
Builtins::kArrayFindLoopAfterCallbackLazyDeoptContinuation;
} else {
DCHECK_EQ(ArrayFindVariant::kFindIndex, variant);
eager_continuation_builtin =
Builtins::kArrayFindIndexLoopEagerDeoptContinuation;
lazy_continuation_builtin =
Builtins::kArrayFindIndexLoopLazyDeoptContinuation;
after_callback_lazy_continuation_builtin =
Builtins::kArrayFindIndexLoopAfterCallbackLazyDeoptContinuation;
}
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* this_arg = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
const ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
// We can handle different maps, as long as their elements kind are the
// same.
if (receiver_map->elements_kind() != kind) return NoChange();
}
// Install code dependencies on the {receiver} prototype maps and the
// global array protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* k = jsgraph()->ZeroConstant();
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
// Check whether the given callback function is callable. Note that this has
// to happen outside the loop to make sure we also throw on empty arrays.
Node* check_fail = nullptr;
Node* check_throw = nullptr;
{
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, lazy_continuation_builtin, node->InputAt(0), context,
&checkpoint_params[0], stack_parameters, outer_frame_state,
ContinuationFrameStateMode::LAZY);
WireInCallbackIsCallableCheck(fncallback, context, frame_state, effect,
&control, &check_fail, &check_throw);
}
// Start the loop.
Node* vloop = k = WireInLoopStart(k, &control, &effect);
Node *loop = control, *eloop = effect;
checkpoint_params[3] = k;
// Check if we've iterated past the last element of the array.
Node* if_false = nullptr;
{
Node* continue_test =
graph()->NewNode(simplified()->NumberLessThan(), k, original_length);
Node* continue_branch = graph()->NewNode(
common()->Branch(BranchHint::kTrue), continue_test, control);
control = graph()->NewNode(common()->IfTrue(), continue_branch);
if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
}
// Check the map hasn't changed during the iteration.
{
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, eager_continuation_builtin, node->InputAt(0),
context, &checkpoint_params[0], stack_parameters, outer_frame_state,
ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Load k-th element from receiver.
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
// Increment k for the next iteration.
Node* next_k = checkpoint_params[3] =
graph()->NewNode(simplified()->NumberAdd(), k, jsgraph()->OneConstant());
// Replace holes with undefined.
if (kind == HOLEY_DOUBLE_ELEMENTS) {
// TODO(7409): avoid deopt if not all uses of value are truncated.
CheckFloat64HoleMode mode = CheckFloat64HoleMode::kAllowReturnHole;
element = effect =
graph()->NewNode(simplified()->CheckFloat64Hole(mode, p.feedback()),
element, effect, control);
} else if (IsHoleyElementsKind(kind)) {
element =
graph()->NewNode(simplified()->ConvertTaggedHoleToUndefined(), element);
}
Node* if_found_return_value =
(variant == ArrayFindVariant::kFind) ? element : k;
// Call the callback.
Node* callback_value = nullptr;
{
std::vector<Node*> call_checkpoint_params({receiver, fncallback, this_arg,
next_k, original_length,
if_found_return_value});
const int call_stack_parameters =
static_cast<int>(call_checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, after_callback_lazy_continuation_builtin,
node->InputAt(0), context, &call_checkpoint_params[0],
call_stack_parameters, outer_frame_state,
ContinuationFrameStateMode::LAZY);
callback_value = control = effect = graph()->NewNode(
javascript()->Call(5, p.frequency()), fncallback, this_arg, element, k,
receiver, context, frame_state, effect, control);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
// Check whether the given callback function returned a truthy value.
Node* boolean_result =
graph()->NewNode(simplified()->ToBoolean(), callback_value);
Node* efound_branch = effect;
Node* found_branch = graph()->NewNode(common()->Branch(BranchHint::kFalse),
boolean_result, control);
Node* if_found = graph()->NewNode(common()->IfTrue(), found_branch);
Node* if_notfound = graph()->NewNode(common()->IfFalse(), found_branch);
control = if_notfound;
// Close the loop.
WireInLoopEnd(loop, eloop, vloop, next_k, control, effect);
control = graph()->NewNode(common()->Merge(2), if_found, if_false);
effect =
graph()->NewNode(common()->EffectPhi(2), efound_branch, eloop, control);
Node* if_not_found_value = (variant == ArrayFindVariant::kFind)
? jsgraph()->UndefinedConstant()
: jsgraph()->MinusOneConstant();
Node* return_value =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
if_found_return_value, if_not_found_value, control);
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, return_value, effect, control);
return Replace(return_value);
}
Node* JSCallReducer::DoFilterPostCallbackWork(ElementsKind kind, Node** control,
Node** effect, Node* a, Node* to,
Node* element,
Node* callback_value) {
Node* boolean_result =
graph()->NewNode(simplified()->ToBoolean(), callback_value);
Node* check_boolean_result =
graph()->NewNode(simplified()->ReferenceEqual(), boolean_result,
jsgraph()->TrueConstant());
Node* boolean_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
check_boolean_result, *control);
Node* if_true = graph()->NewNode(common()->IfTrue(), boolean_branch);
Node* etrue = *effect;
Node* vtrue;
{
// Load the elements backing store of the {receiver}.
Node* elements = etrue = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()), a, etrue,
if_true);
DCHECK(TypeCache::Get().kFixedDoubleArrayLengthType.Is(
TypeCache::Get().kFixedArrayLengthType));
Node* checked_to = etrue = graph()->NewNode(
common()->TypeGuard(TypeCache::Get().kFixedArrayLengthType), to, etrue,
if_true);
Node* elements_length = etrue = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForFixedArrayLength()), elements,
etrue, if_true);
GrowFastElementsMode mode =
IsDoubleElementsKind(kind) ? GrowFastElementsMode::kDoubleElements
: GrowFastElementsMode::kSmiOrObjectElements;
elements = etrue = graph()->NewNode(
simplified()->MaybeGrowFastElements(mode, VectorSlotPair()), a,
elements, checked_to, elements_length, etrue, if_true);
// Update the length of {a}.
Node* new_length_a = graph()->NewNode(simplified()->NumberAdd(), checked_to,
jsgraph()->OneConstant());
etrue = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSArrayLength(kind)), a,
new_length_a, etrue, if_true);
// Append the value to the {elements}.
etrue = graph()->NewNode(
simplified()->StoreElement(AccessBuilder::ForFixedArrayElement(kind)),
elements, checked_to, element, etrue, if_true);
vtrue = new_length_a;
}
Node* if_false = graph()->NewNode(common()->IfFalse(), boolean_branch);
Node* efalse = *effect;
Node* vfalse = to;
*control = graph()->NewNode(common()->Merge(2), if_true, if_false);
*effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, *control);
to = graph()->NewNode(common()->Phi(MachineRepresentation::kTaggedSigned, 2),
vtrue, vfalse, *control);
return to;
}
void JSCallReducer::WireInCallbackIsCallableCheck(
Node* fncallback, Node* context, Node* check_frame_state, Node* effect,
Node** control, Node** check_fail, Node** check_throw) {
Node* check = graph()->NewNode(simplified()->ObjectIsCallable(), fncallback);
Node* check_branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, *control);
*check_fail = graph()->NewNode(common()->IfFalse(), check_branch);
*check_throw = *check_fail = graph()->NewNode(
javascript()->CallRuntime(Runtime::kThrowTypeError, 2),
jsgraph()->Constant(MessageTemplate::kCalledNonCallable), fncallback,
context, check_frame_state, effect, *check_fail);
*control = graph()->NewNode(common()->IfTrue(), check_branch);
}
void JSCallReducer::RewirePostCallbackExceptionEdges(Node* check_throw,
Node* on_exception,
Node* effect,
Node** check_fail,
Node** control) {
// Create appropriate {IfException} and {IfSuccess} nodes.
Node* if_exception0 =
graph()->NewNode(common()->IfException(), check_throw, *check_fail);
*check_fail = graph()->NewNode(common()->IfSuccess(), *check_fail);
Node* if_exception1 =
graph()->NewNode(common()->IfException(), effect, *control);
*control = graph()->NewNode(common()->IfSuccess(), *control);
// Join the exception edges.
Node* merge =
graph()->NewNode(common()->Merge(2), if_exception0, if_exception1);
Node* ephi = graph()->NewNode(common()->EffectPhi(2), if_exception0,
if_exception1, merge);
Node* phi = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
if_exception0, if_exception1, merge);
ReplaceWithValue(on_exception, phi, ephi, merge);
}
Node* JSCallReducer::SafeLoadElement(ElementsKind kind, Node* receiver,
Node* control, Node** effect, Node** k,
const VectorSlotPair& feedback) {
// Make sure that the access is still in bounds, since the callback could have
// changed the array's size.
Node* length = *effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
*effect, control);
*k = *effect = graph()->NewNode(simplified()->CheckBounds(feedback), *k,
length, *effect, control);
// Reload the elements pointer before calling the callback, since the previous
// callback might have resized the array causing the elements buffer to be
// re-allocated.
Node* elements = *effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()), receiver,
*effect, control);
Node* element = *effect = graph()->NewNode(
simplified()->LoadElement(AccessBuilder::ForFixedArrayElement(
kind, LoadSensitivity::kCritical)),
elements, *k, *effect, control);
return element;
}
Reduction JSCallReducer::ReduceArrayEvery(Node* node,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* this_arg = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
// And ensure that any changes to the Array species constructor cause deopt.
if (!isolate()->IsArraySpeciesLookupChainIntact()) return NoChange();
const ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
// We can handle different maps, as long as their elements kind are the
// same.
if (receiver_map->elements_kind() != kind) return NoChange();
}
if (IsHoleyElementsKind(kind)) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->array_species_protector()));
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* k = jsgraph()->ZeroConstant();
// Make sure the map hasn't changed before we construct the output array.
effect = graph()->NewNode(
simplified()->CheckMaps(CheckMapsFlag::kNone, receiver_maps), receiver,
effect, control);
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
// Check whether the given callback function is callable. Note that this has
// to happen outside the loop to make sure we also throw on empty arrays.
Node* check_fail = nullptr;
Node* check_throw = nullptr;
{
// This frame state doesn't ever call the deopt continuation, it's only
// necessary to specifiy a continuation in order to handle the exceptional
// case.
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* check_frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayEveryLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
WireInCallbackIsCallableCheck(fncallback, context, check_frame_state,
effect, &control, &check_fail, &check_throw);
}
// Start the loop.
Node* vloop = k = WireInLoopStart(k, &control, &effect);
Node *loop = control, *eloop = effect;
Node* continue_test =
graph()->NewNode(simplified()->NumberLessThan(), k, original_length);
Node* continue_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
continue_test, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), continue_branch);
Node* if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
control = if_true;
{
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayEveryLoopEagerDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
}
// Make sure the map hasn't changed during the iteration.
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k =
graph()->NewNode(simplified()->NumberAdd(), k, jsgraph()->OneConstant());
Node* hole_true = nullptr;
Node* hole_false = nullptr;
Node* effect_true = effect;
if (IsHoleyElementsKind(kind)) {
// Holey elements kind require a hole check and skipping of the element in
// the case of a hole.
Node* check;
if (IsDoubleElementsKind(kind)) {
check = graph()->NewNode(simplified()->NumberIsFloat64Hole(), element);
} else {
check = graph()->NewNode(simplified()->ReferenceEqual(), element,
jsgraph()->TheHoleConstant());
}
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
hole_true = graph()->NewNode(common()->IfTrue(), branch);
hole_false = graph()->NewNode(common()->IfFalse(), branch);
control = hole_false;
// The contract is that we don't leak "the hole" into "user JavaScript",
// so we must rename the {element} here to explicitly exclude "the hole"
// from the type of {element}.
element = effect = graph()->NewNode(
common()->TypeGuard(Type::NonInternal()), element, effect, control);
}
Node* callback_value = nullptr;
{
// This frame state is dealt with by hand in
// Builtins::kArrayEveryLoopLazyDeoptContinuation.
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArrayEveryLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
callback_value = control = effect = graph()->NewNode(
javascript()->Call(5, p.frequency()), fncallback, this_arg, element, k,
receiver, context, frame_state, effect, control);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
// We have to coerce callback_value to boolean.
Node* if_false_callback;
Node* efalse_callback;
{
Node* boolean_result =
graph()->NewNode(simplified()->ToBoolean(), callback_value);
Node* check_boolean_result =
graph()->NewNode(simplified()->ReferenceEqual(), boolean_result,
jsgraph()->TrueConstant());
Node* boolean_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
check_boolean_result, control);
if_false_callback = graph()->NewNode(common()->IfFalse(), boolean_branch);
efalse_callback = effect;
// Nothing to do in the true case.
control = graph()->NewNode(common()->IfTrue(), boolean_branch);
}
if (IsHoleyElementsKind(kind)) {
Node* after_call_control = control;
Node* after_call_effect = effect;
control = hole_true;
effect = effect_true;
control = graph()->NewNode(common()->Merge(2), control, after_call_control);
effect = graph()->NewNode(common()->EffectPhi(2), effect, after_call_effect,
control);
}
WireInLoopEnd(loop, eloop, vloop, next_k, control, effect);
control = graph()->NewNode(common()->Merge(2), if_false, if_false_callback);
effect =
graph()->NewNode(common()->EffectPhi(2), eloop, efalse_callback, control);
Node* return_value = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2),
jsgraph()->TrueConstant(), jsgraph()->FalseConstant(), control);
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, return_value, effect, control);
return Replace(return_value);
}
namespace {
// Returns the correct Callable for Array's indexOf based on the receiver's
// |elements_kind| and |isolate|. Assumes that |elements_kind| is a fast one.
Callable GetCallableForArrayIndexOf(ElementsKind elements_kind,
Isolate* isolate) {
switch (elements_kind) {
case PACKED_SMI_ELEMENTS:
case HOLEY_SMI_ELEMENTS:
case PACKED_ELEMENTS:
case HOLEY_ELEMENTS:
return Builtins::CallableFor(isolate, Builtins::kArrayIndexOfSmiOrObject);
case PACKED_DOUBLE_ELEMENTS:
return Builtins::CallableFor(isolate,
Builtins::kArrayIndexOfPackedDoubles);
default:
DCHECK_EQ(HOLEY_DOUBLE_ELEMENTS, elements_kind);
return Builtins::CallableFor(isolate,
Builtins::kArrayIndexOfHoleyDoubles);
}
}
// Returns the correct Callable for Array's includes based on the receiver's
// |elements_kind| and |isolate|. Assumes that |elements_kind| is a fast one.
Callable GetCallableForArrayIncludes(ElementsKind elements_kind,
Isolate* isolate) {
switch (elements_kind) {
case PACKED_SMI_ELEMENTS:
case HOLEY_SMI_ELEMENTS:
case PACKED_ELEMENTS:
case HOLEY_ELEMENTS:
return Builtins::CallableFor(isolate,
Builtins::kArrayIncludesSmiOrObject);
case PACKED_DOUBLE_ELEMENTS:
return Builtins::CallableFor(isolate,
Builtins::kArrayIncludesPackedDoubles);
default:
DCHECK_EQ(HOLEY_DOUBLE_ELEMENTS, elements_kind);
return Builtins::CallableFor(isolate,
Builtins::kArrayIncludesHoleyDoubles);
}
}
} // namespace
// For search_variant == kIndexOf:
// ES6 Array.prototype.indexOf(searchElement[, fromIndex])
// #sec-array.prototype.indexof
// For search_variant == kIncludes:
// ES7 Array.prototype.inludes(searchElement[, fromIndex])
// #sec-array.prototype.includes
Reduction JSCallReducer::ReduceArrayIndexOfIncludes(
SearchVariant search_variant, Node* node) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Handle<Map> receiver_map;
if (!NodeProperties::GetMapWitness(isolate(), node).ToHandle(&receiver_map))
return NoChange();
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
if (IsHoleyElementsKind(receiver_map->elements_kind())) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
Callable const callable =
search_variant == SearchVariant::kIndexOf
? GetCallableForArrayIndexOf(receiver_map->elements_kind(), isolate())
: GetCallableForArrayIncludes(receiver_map->elements_kind(),
isolate());
CallDescriptor const* const desc = Linkage::GetStubCallDescriptor(
graph()->zone(), callable.descriptor(), 0, CallDescriptor::kNoFlags,
Operator::kEliminatable);
// The stub expects the following arguments: the receiver array, its elements,
// the search_element, the array length, and the index to start searching
// from.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* elements = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()), receiver,
effect, control);
Node* search_element = (node->op()->ValueInputCount() >= 3)
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* length = effect = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForJSArrayLength(receiver_map->elements_kind())),
receiver, effect, control);
Node* new_from_index = jsgraph()->ZeroConstant();
if (node->op()->ValueInputCount() >= 4) {
Node* from_index = NodeProperties::GetValueInput(node, 3);
from_index = effect = graph()->NewNode(simplified()->CheckSmi(p.feedback()),
from_index, effect, control);
// If the index is negative, it means the offset from the end and therefore
// needs to be added to the length. If the result is still negative, it
// needs to be clamped to 0.
new_from_index = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kFalse),
graph()->NewNode(simplified()->NumberLessThan(), from_index,
jsgraph()->ZeroConstant()),
graph()->NewNode(
simplified()->NumberMax(),
graph()->NewNode(simplified()->NumberAdd(), length, from_index),
jsgraph()->ZeroConstant()),
from_index);
}
Node* context = NodeProperties::GetContextInput(node);
Node* replacement_node = effect = graph()->NewNode(
common()->Call(desc), jsgraph()->HeapConstant(callable.code()), elements,
search_element, length, new_from_index, context, effect);
ReplaceWithValue(node, replacement_node, effect);
return Replace(replacement_node);
}
Reduction JSCallReducer::ReduceArraySome(Node* node,
Handle<SharedFunctionInfo> shared) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
// Try to determine the {receiver} map.
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* fncallback = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* this_arg = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
// And ensure that any changes to the Array species constructor cause deopt.
if (!isolate()->IsArraySpeciesLookupChainIntact()) return NoChange();
if (receiver_maps.size() == 0) return NoChange();
const ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
// We can handle different maps, as long as their elements kind are the
// same.
if (receiver_map->elements_kind() != kind) return NoChange();
}
if (IsHoleyElementsKind(kind)) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->array_species_protector()));
Node* k = jsgraph()->ZeroConstant();
// If we have unreliable maps, we need a map check.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Make sure the map hasn't changed before we construct the output array.
effect = graph()->NewNode(
simplified()->CheckMaps(CheckMapsFlag::kNone, receiver_maps), receiver,
effect, control);
Node* original_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
// Check whether the given callback function is callable. Note that this has
// to happen outside the loop to make sure we also throw on empty arrays.
Node* check_fail = nullptr;
Node* check_throw = nullptr;
{
// This frame state doesn't ever call the deopt continuation, it's only
// necessary to specifiy a continuation in order to handle the exceptional
// case.
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* check_frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArraySomeLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
WireInCallbackIsCallableCheck(fncallback, context, check_frame_state,
effect, &control, &check_fail, &check_throw);
}
// Start the loop.
Node* loop = control = graph()->NewNode(common()->Loop(2), control, control);
Node* eloop = effect =
graph()->NewNode(common()->EffectPhi(2), effect, effect, loop);
Node* terminate = graph()->NewNode(common()->Terminate(), eloop, loop);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
Node* vloop = k = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2), k, k, loop);
Node* continue_test =
graph()->NewNode(simplified()->NumberLessThan(), k, original_length);
Node* continue_branch = graph()->NewNode(common()->Branch(BranchHint::kTrue),
continue_test, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), continue_branch);
Node* if_false = graph()->NewNode(common()->IfFalse(), continue_branch);
control = if_true;
{
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArraySomeLoopEagerDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::EAGER);
effect =
graph()->NewNode(common()->Checkpoint(), frame_state, effect, control);
}
// Make sure the map hasn't changed during the iteration.
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
Node* element =
SafeLoadElement(kind, receiver, control, &effect, &k, p.feedback());
Node* next_k =
graph()->NewNode(simplified()->NumberAdd(), k, jsgraph()->OneConstant());
Node* hole_true = nullptr;
Node* hole_false = nullptr;
Node* effect_true = effect;
if (IsHoleyElementsKind(kind)) {
// Holey elements kind require a hole check and skipping of the element in
// the case of a hole.
Node* check;
if (IsDoubleElementsKind(kind)) {
check = graph()->NewNode(simplified()->NumberIsFloat64Hole(), element);
} else {
check = graph()->NewNode(simplified()->ReferenceEqual(), element,
jsgraph()->TheHoleConstant());
}
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
hole_true = graph()->NewNode(common()->IfTrue(), branch);
hole_false = graph()->NewNode(common()->IfFalse(), branch);
control = hole_false;
// The contract is that we don't leak "the hole" into "user JavaScript",
// so we must rename the {element} here to explicitly exclude "the hole"
// from the type of {element}.
element = effect = graph()->NewNode(
common()->TypeGuard(Type::NonInternal()), element, effect, control);
}
Node* callback_value = nullptr;
{
// This frame state is dealt with by hand in
// Builtins::kArrayEveryLoopLazyDeoptContinuation.
std::vector<Node*> checkpoint_params(
{receiver, fncallback, this_arg, k, original_length});
const int stack_parameters = static_cast<int>(checkpoint_params.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kArraySomeLoopLazyDeoptContinuation,
node->InputAt(0), context, &checkpoint_params[0], stack_parameters,
outer_frame_state, ContinuationFrameStateMode::LAZY);
callback_value = control = effect = graph()->NewNode(
javascript()->Call(5, p.frequency()), fncallback, this_arg, element, k,
receiver, context, frame_state, effect, control);
}
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception, effect,
&check_fail, &control);
}
// We have to coerce callback_value to boolean.
Node* if_true_callback;
Node* etrue_callback;
{
Node* boolean_result =
graph()->NewNode(simplified()->ToBoolean(), callback_value);
Node* check_boolean_result =
graph()->NewNode(simplified()->ReferenceEqual(), boolean_result,
jsgraph()->TrueConstant());
Node* boolean_branch = graph()->NewNode(
common()->Branch(BranchHint::kFalse), check_boolean_result, control);
if_true_callback = graph()->NewNode(common()->IfTrue(), boolean_branch);
etrue_callback = effect;
// Nothing to do in the false case.
control = graph()->NewNode(common()->IfFalse(), boolean_branch);
}
if (IsHoleyElementsKind(kind)) {
Node* after_call_control = control;
Node* after_call_effect = effect;
control = hole_true;
effect = effect_true;
control = graph()->NewNode(common()->Merge(2), control, after_call_control);
effect = graph()->NewNode(common()->EffectPhi(2), effect, after_call_effect,
control);
}
loop->ReplaceInput(1, control);
vloop->ReplaceInput(1, next_k);
eloop->ReplaceInput(1, effect);
control = graph()->NewNode(common()->Merge(2), if_false, if_true_callback);
effect =
graph()->NewNode(common()->EffectPhi(2), eloop, etrue_callback, control);
Node* return_value = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2),
jsgraph()->FalseConstant(), jsgraph()->TrueConstant(), control);
// Wire up the branch for the case when IsCallable fails for the callback.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, return_value, effect, control);
return Replace(return_value);
}
Reduction JSCallReducer::ReduceCallApiFunction(
Node* node, Handle<SharedFunctionInfo> shared) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
int const argc = static_cast<int>(p.arity()) - 2;
Node* target = NodeProperties::GetValueInput(node, 0);
Node* receiver = (p.convert_mode() == ConvertReceiverMode::kNullOrUndefined)
? jsgraph()->HeapConstant(global_proxy())
: NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Handle<FunctionTemplateInfo> function_template_info(
FunctionTemplateInfo::cast(shared->function_data()), isolate());
// CallApiCallbackStub expects the target in a register, so we count it out,
// and counts the receiver as an implicit argument, so we count the receiver
// out too.
if (argc > CallApiCallbackStub::kArgMax) return NoChange();
// Infer the {receiver} maps, and check if we can inline the API function
// callback based on those.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
for (size_t i = 0; i < receiver_maps.size(); ++i) {
Handle<Map> receiver_map = receiver_maps[i];
if (!receiver_map->IsJSObjectMap() ||
(!function_template_info->accept_any_receiver() &&
receiver_map->is_access_check_needed())) {
return NoChange();
}
// In case of unreliable {receiver} information, the {receiver_maps}
// must all be stable in order to consume the information.
if (result == NodeProperties::kUnreliableReceiverMaps) {
if (!receiver_map->is_stable()) return NoChange();
}
}
// See if we can constant-fold the compatible receiver checks.
CallOptimization call_optimization(isolate(), function_template_info);
if (!call_optimization.is_simple_api_call()) return NoChange();
CallOptimization::HolderLookup lookup;
Handle<JSObject> api_holder =
call_optimization.LookupHolderOfExpectedType(receiver_maps[0], &lookup);
if (lookup == CallOptimization::kHolderNotFound) return NoChange();
for (size_t i = 1; i < receiver_maps.size(); ++i) {
CallOptimization::HolderLookup lookupi;
Handle<JSObject> holder = call_optimization.LookupHolderOfExpectedType(
receiver_maps[i], &lookupi);
if (lookup != lookupi) return NoChange();
if (!api_holder.is_identical_to(holder)) return NoChange();
}
// Install stability dependencies for unreliable {receiver_maps}.
if (result == NodeProperties::kUnreliableReceiverMaps) {
for (size_t i = 0; i < receiver_maps.size(); ++i) {
dependencies()->DependOnStableMap(
MapRef(js_heap_broker(), receiver_maps[i]));
}
}
// Load the {target}s context.
Node* context = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSFunctionContext()), target,
effect, control);
// CallApiCallbackStub's register arguments: code, target, call data, holder,
// function address.
// TODO(turbofan): Consider introducing a JSCallApiCallback operator for
// this and lower it during JSGenericLowering, and unify this with the
// JSNativeContextSpecialization::InlineApiCall method a bit.
Handle<CallHandlerInfo> call_handler_info(
CallHandlerInfo::cast(function_template_info->call_code()), isolate());
Handle<Object> data(call_handler_info->data(), isolate());
Callable call_api_callback = CodeFactory::CallApiCallback(isolate(), argc);
CallInterfaceDescriptor cid = call_api_callback.descriptor();
auto call_descriptor = Linkage::GetStubCallDescriptor(
graph()->zone(), cid,
cid.GetStackParameterCount() + argc + 1 /* implicit receiver */,
CallDescriptor::kNeedsFrameState);
ApiFunction api_function(v8::ToCData<Address>(call_handler_info->callback()));
Node* holder = lookup == CallOptimization::kHolderFound
? jsgraph()->HeapConstant(api_holder)
: receiver;
ExternalReference function_reference = ExternalReference::Create(
&api_function, ExternalReference::DIRECT_API_CALL);
node->InsertInput(graph()->zone(), 0,
jsgraph()->HeapConstant(call_api_callback.code()));
node->ReplaceInput(1, context);
node->InsertInput(graph()->zone(), 2, jsgraph()->Constant(data));
node->InsertInput(graph()->zone(), 3, holder);
node->InsertInput(graph()->zone(), 4,
jsgraph()->ExternalConstant(function_reference));
node->ReplaceInput(5, receiver);
node->RemoveInput(6 + argc); // Remove context input.
node->ReplaceInput(7 + argc, effect); // Update effect input.
NodeProperties::ChangeOp(node, common()->Call(call_descriptor));
return Changed(node);
}
namespace {
// Check whether elements aren't mutated; we play it extremely safe here by
// explicitly checking that {node} is only used by {LoadField} or {LoadElement}.
bool IsSafeArgumentsElements(Node* node) {
for (Edge const edge : node->use_edges()) {
if (!NodeProperties::IsValueEdge(edge)) continue;
if (edge.from()->opcode() != IrOpcode::kLoadField &&
edge.from()->opcode() != IrOpcode::kLoadElement) {
return false;
}
}
return true;
}
} // namespace
Reduction JSCallReducer::ReduceCallOrConstructWithArrayLikeOrSpread(
Node* node, int arity, CallFrequency const& frequency,
VectorSlotPair const& feedback) {
DCHECK(node->opcode() == IrOpcode::kJSCallWithArrayLike ||
node->opcode() == IrOpcode::kJSCallWithSpread ||
node->opcode() == IrOpcode::kJSConstructWithArrayLike ||
node->opcode() == IrOpcode::kJSConstructWithSpread);
// In case of a call/construct with spread, we need to
// ensure that it's safe to avoid the actual iteration.
if ((node->opcode() == IrOpcode::kJSCallWithSpread ||
node->opcode() == IrOpcode::kJSConstructWithSpread) &&
!isolate()->IsArrayIteratorLookupChainIntact()) {
return NoChange();
}
// Check if {arguments_list} is an arguments object, and {node} is the only
// value user of {arguments_list} (except for value uses in frame states).
Node* arguments_list = NodeProperties::GetValueInput(node, arity);
if (arguments_list->opcode() != IrOpcode::kJSCreateArguments) {
return NoChange();
}
for (Edge edge : arguments_list->use_edges()) {
if (!NodeProperties::IsValueEdge(edge)) continue;
Node* const user = edge.from();
switch (user->opcode()) {
case IrOpcode::kCheckMaps:
case IrOpcode::kFrameState:
case IrOpcode::kStateValues:
case IrOpcode::kReferenceEqual:
case IrOpcode::kReturn:
// Ignore safe uses that definitely don't mess with the arguments.
continue;
case IrOpcode::kLoadField: {
DCHECK_EQ(arguments_list, user->InputAt(0));
FieldAccess const& access = FieldAccessOf(user->op());
if (access.offset == JSArray::kLengthOffset) {
// Ignore uses for arguments#length.
STATIC_ASSERT(JSArray::kLengthOffset ==
JSArgumentsObject::kLengthOffset);
continue;
} else if (access.offset == JSObject::kElementsOffset) {
// Ignore safe uses for arguments#elements.
if (IsSafeArgumentsElements(user)) continue;
}
break;
}
case IrOpcode::kJSCallWithArrayLike:
// Ignore uses as argumentsList input to calls with array like.
if (user->InputAt(2) == arguments_list) continue;
break;
case IrOpcode::kJSConstructWithArrayLike:
// Ignore uses as argumentsList input to calls with array like.
if (user->InputAt(1) == arguments_list) continue;
break;
case IrOpcode::kJSCallWithSpread: {
// Ignore uses as spread input to calls with spread.
CallParameters p = CallParametersOf(user->op());
int const arity = static_cast<int>(p.arity() - 1);
if (user->InputAt(arity) == arguments_list) continue;
break;
}
case IrOpcode::kJSConstructWithSpread: {
// Ignore uses as spread input to construct with spread.
ConstructParameters p = ConstructParametersOf(user->op());
int const arity = static_cast<int>(p.arity() - 2);
if (user->InputAt(arity) == arguments_list) continue;
break;
}
default:
break;
}
// We cannot currently reduce the {node} to something better than what
// it already is, but we might be able to do something about the {node}
// later, so put it on the waitlist and try again during finalization.
waitlist_.insert(node);
return NoChange();
}
// Get to the actual frame state from which to extract the arguments;
// we can only optimize this in case the {node} was already inlined into
// some other function (and same for the {arguments_list}).
CreateArgumentsType const type = CreateArgumentsTypeOf(arguments_list->op());
Node* frame_state = NodeProperties::GetFrameStateInput(arguments_list);
FrameStateInfo state_info = FrameStateInfoOf(frame_state->op());
int start_index = 0;
// Determine the formal parameter count;
Handle<SharedFunctionInfo> shared;
if (!state_info.shared_info().ToHandle(&shared)) return NoChange();
int formal_parameter_count = shared->internal_formal_parameter_count();
if (type == CreateArgumentsType::kMappedArguments) {
// Mapped arguments (sloppy mode) that are aliased can only be handled
// here if there's no side-effect between the {node} and the {arg_array}.
// TODO(turbofan): Further relax this constraint.
if (formal_parameter_count != 0) {
Node* effect = NodeProperties::GetEffectInput(node);
if (!NodeProperties::NoObservableSideEffectBetween(effect,
arguments_list)) {
return NoChange();
}
}
} else if (type == CreateArgumentsType::kRestParameter) {
start_index = formal_parameter_count;
}
// For call/construct with spread, we need to also install a code
// dependency on the array iterator lookup protector cell to ensure
// that no one messed with the %ArrayIteratorPrototype%.next method.
if (node->opcode() == IrOpcode::kJSCallWithSpread ||
node->opcode() == IrOpcode::kJSConstructWithSpread) {
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->array_iterator_protector()));
}
// Remove the {arguments_list} input from the {node}.
node->RemoveInput(arity--);
// Check if are spreading to inlined arguments or to the arguments of
// the outermost function.
Node* outer_state = frame_state->InputAt(kFrameStateOuterStateInput);
if (outer_state->opcode() != IrOpcode::kFrameState) {
Operator const* op =
(node->opcode() == IrOpcode::kJSCallWithArrayLike ||
node->opcode() == IrOpcode::kJSCallWithSpread)
? javascript()->CallForwardVarargs(arity + 1, start_index)
: javascript()->ConstructForwardVarargs(arity + 2, start_index);
NodeProperties::ChangeOp(node, op);
return Changed(node);
}
// Get to the actual frame state from which to extract the arguments;
// we can only optimize this in case the {node} was already inlined into
// some other function (and same for the {arg_array}).
FrameStateInfo outer_info = FrameStateInfoOf(outer_state->op());
if (outer_info.type() == FrameStateType::kArgumentsAdaptor) {
// Need to take the parameters from the arguments adaptor.
frame_state = outer_state;
}
// Add the actual parameters to the {node}, skipping the receiver.
Node* const parameters = frame_state->InputAt(kFrameStateParametersInput);
for (int i = start_index + 1; i < parameters->InputCount(); ++i) {
node->InsertInput(graph()->zone(), static_cast<int>(++arity),
parameters->InputAt(i));
}
if (node->opcode() == IrOpcode::kJSCallWithArrayLike ||
node->opcode() == IrOpcode::kJSCallWithSpread) {
NodeProperties::ChangeOp(
node, javascript()->Call(arity + 1, frequency, feedback));
Reduction const reduction = ReduceJSCall(node);
return reduction.Changed() ? reduction : Changed(node);
} else {
NodeProperties::ChangeOp(
node, javascript()->Construct(arity + 2, frequency, feedback));
Node* new_target = NodeProperties::GetValueInput(node, arity + 1);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Check whether the given new target value is a constructor function. The
// replacement {JSConstruct} operator only checks the passed target value
// but relies on the new target value to be implicitly valid.
Node* check =
graph()->NewNode(simplified()->ObjectIsConstructor(), new_target);
Node* check_branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
Node* check_fail = graph()->NewNode(common()->IfFalse(), check_branch);
Node* check_throw = check_fail =
graph()->NewNode(javascript()->CallRuntime(Runtime::kThrowTypeError, 2),
jsgraph()->Constant(MessageTemplate::kNotConstructor),
new_target, context, frame_state, effect, check_fail);
control = graph()->NewNode(common()->IfTrue(), check_branch);
NodeProperties::ReplaceControlInput(node, control);
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
// Create appropriate {IfException} and {IfSuccess} nodes.
Node* if_exception =
graph()->NewNode(common()->IfException(), check_throw, check_fail);
check_fail = graph()->NewNode(common()->IfSuccess(), check_fail);
// Join the exception edges.
Node* merge =
graph()->NewNode(common()->Merge(2), if_exception, on_exception);
Node* ephi = graph()->NewNode(common()->EffectPhi(2), if_exception,
on_exception, merge);
Node* phi =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
if_exception, on_exception, merge);
ReplaceWithValue(on_exception, phi, ephi, merge);
merge->ReplaceInput(1, on_exception);
ephi->ReplaceInput(1, on_exception);
phi->ReplaceInput(1, on_exception);
}
// The above %ThrowTypeError runtime call is an unconditional throw, making
// it impossible to return a successful completion in this case. We simply
// connect the successful completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
Reduction const reduction = ReduceJSConstruct(node);
return reduction.Changed() ? reduction : Changed(node);
}
}
namespace {
bool ShouldUseCallICFeedback(Node* node) {
HeapObjectMatcher m(node);
if (m.HasValue() || m.IsJSCreateClosure()) {
// Don't use CallIC feedback when we know the function
// being called, i.e. either know the closure itself or
// at least the SharedFunctionInfo.
return false;
} else if (m.IsPhi()) {
// Protect against endless loops here.
Node* control = NodeProperties::GetControlInput(node);
if (control->opcode() == IrOpcode::kLoop) return false;
// Check if {node} is a Phi of nodes which shouldn't
// use CallIC feedback (not looking through loops).
int const value_input_count = m.node()->op()->ValueInputCount();
for (int n = 0; n < value_input_count; ++n) {
if (ShouldUseCallICFeedback(node->InputAt(n))) return true;
}
return false;
}
return true;
}
} // namespace
Reduction JSCallReducer::ReduceJSCall(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
Node* target = NodeProperties::GetValueInput(node, 0);
Node* control = NodeProperties::GetControlInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
size_t arity = p.arity();
DCHECK_LE(2u, arity);
// Try to specialize JSCall {node}s with constant {target}s.
HeapObjectMatcher m(target);
if (m.HasValue()) {
if (m.Value()->IsJSFunction()) {
Handle<JSFunction> function = Handle<JSFunction>::cast(m.Value());
// Don't inline cross native context.
if (function->native_context() != *native_context()) return NoChange();
return ReduceJSCall(node, handle(function->shared(), isolate()));
} else if (m.Value()->IsJSBoundFunction()) {
Handle<JSBoundFunction> function =
Handle<JSBoundFunction>::cast(m.Value());
Handle<JSReceiver> bound_target_function(
function->bound_target_function(), isolate());
Handle<Object> bound_this(function->bound_this(), isolate());
Handle<FixedArray> bound_arguments(function->bound_arguments(),
isolate());
ConvertReceiverMode const convert_mode =
(bound_this->IsNullOrUndefined(isolate()))
? ConvertReceiverMode::kNullOrUndefined
: ConvertReceiverMode::kNotNullOrUndefined;
// Patch {node} to use [[BoundTargetFunction]] and [[BoundThis]].
NodeProperties::ReplaceValueInput(
node, jsgraph()->Constant(bound_target_function), 0);
NodeProperties::ReplaceValueInput(node, jsgraph()->Constant(bound_this),
1);
// Insert the [[BoundArguments]] for {node}.
for (int i = 0; i < bound_arguments->length(); ++i) {
node->InsertInput(
graph()->zone(), i + 2,
jsgraph()->Constant(handle(bound_arguments->get(i), isolate())));
arity++;
}
NodeProperties::ChangeOp(
node, javascript()->Call(arity, p.frequency(), VectorSlotPair(),
convert_mode));
// Try to further reduce the JSCall {node}.
Reduction const reduction = ReduceJSCall(node);
return reduction.Changed() ? reduction : Changed(node);
}
// Don't mess with other {node}s that have a constant {target}.
// TODO(bmeurer): Also support proxies here.
return NoChange();
}
// If {target} is the result of a JSCreateClosure operation, we can
// just immediately try to inline based on the SharedFunctionInfo,
// since TurboFan generally doesn't inline cross-context, and hence
// the {target} must have the same native context as the call site.
if (target->opcode() == IrOpcode::kJSCreateClosure) {
CreateClosureParameters const& p = CreateClosureParametersOf(target->op());
return ReduceJSCall(node, p.shared_info());
}
// If {target} is the result of a JSCreateBoundFunction operation,
// we can just fold the construction and call the bound target
// function directly instead.
if (target->opcode() == IrOpcode::kJSCreateBoundFunction) {
Node* bound_target_function = NodeProperties::GetValueInput(target, 0);
Node* bound_this = NodeProperties::GetValueInput(target, 1);
int const bound_arguments_length =
static_cast<int>(CreateBoundFunctionParametersOf(target->op()).arity());
// Patch the {node} to use [[BoundTargetFunction]] and [[BoundThis]].
NodeProperties::ReplaceValueInput(node, bound_target_function, 0);
NodeProperties::ReplaceValueInput(node, bound_this, 1);
// Insert the [[BoundArguments]] for {node}.
for (int i = 0; i < bound_arguments_length; ++i) {
Node* value = NodeProperties::GetValueInput(target, 2 + i);
node->InsertInput(graph()->zone(), 2 + i, value);
arity++;
}
// Update the JSCall operator on {node}.
ConvertReceiverMode const convert_mode =
NodeProperties::CanBeNullOrUndefined(isolate(), bound_this, effect)
? ConvertReceiverMode::kAny
: ConvertReceiverMode::kNotNullOrUndefined;
NodeProperties::ChangeOp(
node, javascript()->Call(arity, p.frequency(), VectorSlotPair(),
convert_mode));
// Try to further reduce the JSCall {node}.
Reduction const reduction = ReduceJSCall(node);
return reduction.Changed() ? reduction : Changed(node);
}
// Extract feedback from the {node} using the FeedbackNexus.
if (!p.feedback().IsValid()) return NoChange();
FeedbackNexus nexus(p.feedback().vector(), p.feedback().slot());
if (nexus.IsUninitialized()) {
if (flags() & kBailoutOnUninitialized) {
// Introduce a SOFT deopt if the call {node} wasn't executed so far.
return ReduceSoftDeoptimize(
node, DeoptimizeReason::kInsufficientTypeFeedbackForCall);
}
return NoChange();
}
HeapObject* heap_object;
if (nexus.GetFeedback()->ToWeakHeapObject(&heap_object)) {
Handle<HeapObject> feedback(heap_object, isolate());
// Check if we want to use CallIC feedback here.
if (!ShouldUseCallICFeedback(target)) return NoChange();
if (feedback->IsCallable()) {
Node* target_function = jsgraph()->Constant(feedback);
// Check that the {target} is still the {target_function}.
Node* check = graph()->NewNode(simplified()->ReferenceEqual(), target,
target_function);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kWrongCallTarget), check,
effect, control);
// Specialize the JSCall node to the {target_function}.
NodeProperties::ReplaceValueInput(node, target_function, 0);
NodeProperties::ReplaceEffectInput(node, effect);
// Try to further reduce the JSCall {node}.
Reduction const reduction = ReduceJSCall(node);
return reduction.Changed() ? reduction : Changed(node);
}
}
return NoChange();
}
Reduction JSCallReducer::ReduceJSCall(Node* node,
Handle<SharedFunctionInfo> shared) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* target = NodeProperties::GetValueInput(node, 0);
// Do not reduce calls to functions with break points.
if (shared->HasBreakInfo()) return NoChange();
// Raise a TypeError if the {target} is a "classConstructor".
if (IsClassConstructor(shared->kind())) {
NodeProperties::ReplaceValueInputs(node, target);
NodeProperties::ChangeOp(
node, javascript()->CallRuntime(
Runtime::kThrowConstructorNonCallableError, 1));
return Changed(node);
}
// Check for known builtin functions.
int builtin_id =
shared->HasBuiltinId() ? shared->builtin_id() : Builtins::kNoBuiltinId;
switch (builtin_id) {
case Builtins::kArrayConstructor:
return ReduceArrayConstructor(node);
case Builtins::kBooleanConstructor:
return ReduceBooleanConstructor(node);
case Builtins::kFunctionPrototypeApply:
return ReduceFunctionPrototypeApply(node);
case Builtins::kFastFunctionPrototypeBind:
return ReduceFunctionPrototypeBind(node);
case Builtins::kFunctionPrototypeCall:
return ReduceFunctionPrototypeCall(node);
case Builtins::kFunctionPrototypeHasInstance:
return ReduceFunctionPrototypeHasInstance(node);
case Builtins::kObjectConstructor:
return ReduceObjectConstructor(node);
case Builtins::kObjectCreate:
return ReduceObjectCreate(node);
case Builtins::kObjectGetPrototypeOf:
return ReduceObjectGetPrototypeOf(node);
case Builtins::kObjectIs:
return ReduceObjectIs(node);
case Builtins::kObjectPrototypeGetProto:
return ReduceObjectPrototypeGetProto(node);
case Builtins::kObjectPrototypeHasOwnProperty:
return ReduceObjectPrototypeHasOwnProperty(node);
case Builtins::kObjectPrototypeIsPrototypeOf:
return ReduceObjectPrototypeIsPrototypeOf(node);
case Builtins::kReflectApply:
return ReduceReflectApply(node);
case Builtins::kReflectConstruct:
return ReduceReflectConstruct(node);
case Builtins::kReflectGet:
return ReduceReflectGet(node);
case Builtins::kReflectGetPrototypeOf:
return ReduceReflectGetPrototypeOf(node);
case Builtins::kReflectHas:
return ReduceReflectHas(node);
case Builtins::kArrayForEach:
return ReduceArrayForEach(node, shared);
case Builtins::kArrayMap:
return ReduceArrayMap(node, shared);
case Builtins::kArrayFilter:
return ReduceArrayFilter(node, shared);
case Builtins::kArrayReduce:
return ReduceArrayReduce(node, ArrayReduceDirection::kLeft, shared);
case Builtins::kArrayReduceRight:
return ReduceArrayReduce(node, ArrayReduceDirection::kRight, shared);
case Builtins::kArrayPrototypeFind:
return ReduceArrayFind(node, ArrayFindVariant::kFind, shared);
case Builtins::kArrayPrototypeFindIndex:
return ReduceArrayFind(node, ArrayFindVariant::kFindIndex, shared);
case Builtins::kArrayEvery:
return ReduceArrayEvery(node, shared);
case Builtins::kArrayIndexOf:
return ReduceArrayIndexOfIncludes(SearchVariant::kIndexOf, node);
case Builtins::kArrayIncludes:
return ReduceArrayIndexOfIncludes(SearchVariant::kIncludes, node);
case Builtins::kArraySome:
return ReduceArraySome(node, shared);
case Builtins::kArrayPrototypePush:
return ReduceArrayPrototypePush(node);
case Builtins::kArrayPrototypePop:
return ReduceArrayPrototypePop(node);
case Builtins::kArrayPrototypeShift:
return ReduceArrayPrototypeShift(node);
case Builtins::kArrayPrototypeSlice:
return ReduceArrayPrototypeSlice(node);
case Builtins::kArrayPrototypeEntries:
return ReduceArrayIterator(node, IterationKind::kEntries);
case Builtins::kArrayPrototypeKeys:
return ReduceArrayIterator(node, IterationKind::kKeys);
case Builtins::kArrayPrototypeValues:
return ReduceArrayIterator(node, IterationKind::kValues);
case Builtins::kArrayIteratorPrototypeNext:
return ReduceArrayIteratorPrototypeNext(node);
case Builtins::kArrayIsArray:
return ReduceArrayIsArray(node);
case Builtins::kArrayBufferIsView:
return ReduceArrayBufferIsView(node);
case Builtins::kDataViewPrototypeGetByteLength:
return ReduceArrayBufferViewAccessor(
node, JS_DATA_VIEW_TYPE,
AccessBuilder::ForJSArrayBufferViewByteLength());
case Builtins::kDataViewPrototypeGetByteOffset:
return ReduceArrayBufferViewAccessor(
node, JS_DATA_VIEW_TYPE,
AccessBuilder::ForJSArrayBufferViewByteOffset());
case Builtins::kDataViewPrototypeGetUint8:
return ReduceDataViewPrototypeGet(node,
ExternalArrayType::kExternalUint8Array);
case Builtins::kDataViewPrototypeGetInt8:
return ReduceDataViewPrototypeGet(node,
ExternalArrayType::kExternalInt8Array);
case Builtins::kDataViewPrototypeGetUint16:
return ReduceDataViewPrototypeGet(
node, ExternalArrayType::kExternalUint16Array);
case Builtins::kDataViewPrototypeGetInt16:
return ReduceDataViewPrototypeGet(node,
ExternalArrayType::kExternalInt16Array);
case Builtins::kDataViewPrototypeGetUint32:
return ReduceDataViewPrototypeGet(
node, ExternalArrayType::kExternalUint32Array);
case Builtins::kDataViewPrototypeGetInt32:
return ReduceDataViewPrototypeGet(node,
ExternalArrayType::kExternalInt32Array);
case Builtins::kDataViewPrototypeGetFloat32:
return ReduceDataViewPrototypeGet(
node, ExternalArrayType::kExternalFloat32Array);
case Builtins::kDataViewPrototypeGetFloat64:
return ReduceDataViewPrototypeGet(
node, ExternalArrayType::kExternalFloat64Array);
case Builtins::kDataViewPrototypeSetUint8:
return ReduceDataViewPrototypeSet(node,
ExternalArrayType::kExternalUint8Array);
case Builtins::kDataViewPrototypeSetInt8:
return ReduceDataViewPrototypeSet(node,
ExternalArrayType::kExternalInt8Array);
case Builtins::kDataViewPrototypeSetUint16:
return ReduceDataViewPrototypeSet(
node, ExternalArrayType::kExternalUint16Array);
case Builtins::kDataViewPrototypeSetInt16:
return ReduceDataViewPrototypeSet(node,
ExternalArrayType::kExternalInt16Array);
case Builtins::kDataViewPrototypeSetUint32:
return ReduceDataViewPrototypeSet(
node, ExternalArrayType::kExternalUint32Array);
case Builtins::kDataViewPrototypeSetInt32:
return ReduceDataViewPrototypeSet(node,
ExternalArrayType::kExternalInt32Array);
case Builtins::kDataViewPrototypeSetFloat32:
return ReduceDataViewPrototypeSet(
node, ExternalArrayType::kExternalFloat32Array);
case Builtins::kDataViewPrototypeSetFloat64:
return ReduceDataViewPrototypeSet(
node, ExternalArrayType::kExternalFloat64Array);
case Builtins::kTypedArrayPrototypeByteLength:
return ReduceArrayBufferViewAccessor(
node, JS_TYPED_ARRAY_TYPE,
AccessBuilder::ForJSArrayBufferViewByteLength());
case Builtins::kTypedArrayPrototypeByteOffset:
return ReduceArrayBufferViewAccessor(
node, JS_TYPED_ARRAY_TYPE,
AccessBuilder::ForJSArrayBufferViewByteOffset());
case Builtins::kTypedArrayPrototypeLength:
return ReduceArrayBufferViewAccessor(
node, JS_TYPED_ARRAY_TYPE, AccessBuilder::ForJSTypedArrayLength());
case Builtins::kTypedArrayPrototypeToStringTag:
return ReduceTypedArrayPrototypeToStringTag(node);
case Builtins::kMathAbs:
return ReduceMathUnary(node, simplified()->NumberAbs());
case Builtins::kMathAcos:
return ReduceMathUnary(node, simplified()->NumberAcos());
case Builtins::kMathAcosh:
return ReduceMathUnary(node, simplified()->NumberAcosh());
case Builtins::kMathAsin:
return ReduceMathUnary(node, simplified()->NumberAsin());
case Builtins::kMathAsinh:
return ReduceMathUnary(node, simplified()->NumberAsinh());
case Builtins::kMathAtan:
return ReduceMathUnary(node, simplified()->NumberAtan());
case Builtins::kMathAtanh:
return ReduceMathUnary(node, simplified()->NumberAtanh());
case Builtins::kMathCbrt:
return ReduceMathUnary(node, simplified()->NumberCbrt());
case Builtins::kMathCeil:
return ReduceMathUnary(node, simplified()->NumberCeil());
case Builtins::kMathCos:
return ReduceMathUnary(node, simplified()->NumberCos());
case Builtins::kMathCosh:
return ReduceMathUnary(node, simplified()->NumberCosh());
case Builtins::kMathExp:
return ReduceMathUnary(node, simplified()->NumberExp());
case Builtins::kMathExpm1:
return ReduceMathUnary(node, simplified()->NumberExpm1());
case Builtins::kMathFloor:
return ReduceMathUnary(node, simplified()->NumberFloor());
case Builtins::kMathFround:
return ReduceMathUnary(node, simplified()->NumberFround());
case Builtins::kMathLog:
return ReduceMathUnary(node, simplified()->NumberLog());
case Builtins::kMathLog1p:
return ReduceMathUnary(node, simplified()->NumberLog1p());
case Builtins::kMathLog10:
return ReduceMathUnary(node, simplified()->NumberLog10());
case Builtins::kMathLog2:
return ReduceMathUnary(node, simplified()->NumberLog2());
case Builtins::kMathRound:
return ReduceMathUnary(node, simplified()->NumberRound());
case Builtins::kMathSign:
return ReduceMathUnary(node, simplified()->NumberSign());
case Builtins::kMathSin:
return ReduceMathUnary(node, simplified()->NumberSin());
case Builtins::kMathSinh:
return ReduceMathUnary(node, simplified()->NumberSinh());
case Builtins::kMathSqrt:
return ReduceMathUnary(node, simplified()->NumberSqrt());
case Builtins::kMathTan:
return ReduceMathUnary(node, simplified()->NumberTan());
case Builtins::kMathTanh:
return ReduceMathUnary(node, simplified()->NumberTanh());
case Builtins::kMathTrunc:
return ReduceMathUnary(node, simplified()->NumberTrunc());
case Builtins::kMathAtan2:
return ReduceMathBinary(node, simplified()->NumberAtan2());
case Builtins::kMathPow:
return ReduceMathBinary(node, simplified()->NumberPow());
case Builtins::kMathClz32:
return ReduceMathClz32(node);
case Builtins::kMathImul:
return ReduceMathImul(node);
case Builtins::kMathMax:
return ReduceMathMinMax(node, simplified()->NumberMax(),
jsgraph()->Constant(-V8_INFINITY));
case Builtins::kMathMin:
return ReduceMathMinMax(node, simplified()->NumberMin(),
jsgraph()->Constant(V8_INFINITY));
case Builtins::kNumberIsFinite:
return ReduceNumberIsFinite(node);
case Builtins::kNumberIsInteger:
return ReduceNumberIsInteger(node);
case Builtins::kNumberIsSafeInteger:
return ReduceNumberIsSafeInteger(node);
case Builtins::kNumberIsNaN:
return ReduceNumberIsNaN(node);
case Builtins::kNumberParseInt:
return ReduceNumberParseInt(node);
case Builtins::kGlobalIsFinite:
return ReduceGlobalIsFinite(node);
case Builtins::kGlobalIsNaN:
return ReduceGlobalIsNaN(node);
case Builtins::kMapPrototypeGet:
return ReduceMapPrototypeGet(node);
case Builtins::kMapPrototypeHas:
return ReduceMapPrototypeHas(node);
case Builtins::kRegExpPrototypeTest:
return ReduceRegExpPrototypeTest(node);
case Builtins::kReturnReceiver:
return ReduceReturnReceiver(node);
case Builtins::kStringPrototypeIndexOf:
return ReduceStringPrototypeIndexOf(node);
case Builtins::kStringPrototypeCharAt:
return ReduceStringPrototypeCharAt(node);
case Builtins::kStringPrototypeCharCodeAt:
return ReduceStringPrototypeStringAt(simplified()->StringCharCodeAt(),
node);
case Builtins::kStringPrototypeCodePointAt:
return ReduceStringPrototypeStringAt(
simplified()->StringCodePointAt(UnicodeEncoding::UTF32), node);
case Builtins::kStringPrototypeSubstring:
return ReduceStringPrototypeSubstring(node);
case Builtins::kStringPrototypeSlice:
return ReduceStringPrototypeSlice(node);
case Builtins::kStringPrototypeSubstr:
return ReduceStringPrototypeSubstr(node);
#ifdef V8_INTL_SUPPORT
case Builtins::kStringPrototypeToLowerCaseIntl:
return ReduceStringPrototypeToLowerCaseIntl(node);
case Builtins::kStringPrototypeToUpperCaseIntl:
return ReduceStringPrototypeToUpperCaseIntl(node);
#endif // V8_INTL_SUPPORT
case Builtins::kStringFromCharCode:
return ReduceStringFromCharCode(node);
case Builtins::kStringFromCodePoint:
return ReduceStringFromCodePoint(node);
case Builtins::kStringPrototypeIterator:
return ReduceStringPrototypeIterator(node);
case Builtins::kStringIteratorPrototypeNext:
return ReduceStringIteratorPrototypeNext(node);
case Builtins::kStringPrototypeConcat:
return ReduceStringPrototypeConcat(node, shared);
case Builtins::kTypedArrayPrototypeEntries:
return ReduceArrayIterator(node, IterationKind::kEntries);
case Builtins::kTypedArrayPrototypeKeys:
return ReduceArrayIterator(node, IterationKind::kKeys);
case Builtins::kTypedArrayPrototypeValues:
return ReduceArrayIterator(node, IterationKind::kValues);
case Builtins::kAsyncFunctionPromiseCreate:
return ReduceAsyncFunctionPromiseCreate(node);
case Builtins::kAsyncFunctionPromiseRelease:
return ReduceAsyncFunctionPromiseRelease(node);
case Builtins::kPromiseInternalConstructor:
return ReducePromiseInternalConstructor(node);
case Builtins::kPromiseInternalReject:
return ReducePromiseInternalReject(node);
case Builtins::kPromiseInternalResolve:
return ReducePromiseInternalResolve(node);
case Builtins::kPromisePrototypeCatch:
return ReducePromisePrototypeCatch(node);
case Builtins::kPromisePrototypeFinally:
return ReducePromisePrototypeFinally(node);
case Builtins::kPromisePrototypeThen:
return ReducePromisePrototypeThen(node);
case Builtins::kMapPrototypeEntries:
return ReduceCollectionIteration(node, CollectionKind::kMap,
IterationKind::kEntries);
case Builtins::kMapPrototypeKeys:
return ReduceCollectionIteration(node, CollectionKind::kMap,
IterationKind::kKeys);
case Builtins::kMapPrototypeGetSize:
return ReduceCollectionPrototypeSize(node, CollectionKind::kMap);
case Builtins::kMapPrototypeValues:
return ReduceCollectionIteration(node, CollectionKind::kMap,
IterationKind::kValues);
case Builtins::kMapIteratorPrototypeNext:
return ReduceCollectionIteratorPrototypeNext(
node, OrderedHashMap::kEntrySize, factory()->empty_ordered_hash_map(),
FIRST_MAP_ITERATOR_TYPE, LAST_MAP_ITERATOR_TYPE);
case Builtins::kSetPrototypeEntries:
return ReduceCollectionIteration(node, CollectionKind::kSet,
IterationKind::kEntries);
case Builtins::kSetPrototypeGetSize:
return ReduceCollectionPrototypeSize(node, CollectionKind::kSet);
case Builtins::kSetPrototypeValues:
return ReduceCollectionIteration(node, CollectionKind::kSet,
IterationKind::kValues);
case Builtins::kSetIteratorPrototypeNext:
return ReduceCollectionIteratorPrototypeNext(
node, OrderedHashSet::kEntrySize, factory()->empty_ordered_hash_set(),
FIRST_SET_ITERATOR_TYPE, LAST_SET_ITERATOR_TYPE);
case Builtins::kDatePrototypeGetTime:
return ReduceDatePrototypeGetTime(node);
case Builtins::kDateNow:
return ReduceDateNow(node);
case Builtins::kNumberConstructor:
return ReduceNumberConstructor(node);
default:
break;
}
if (!FLAG_runtime_stats && shared->IsApiFunction()) {
return ReduceCallApiFunction(node, shared);
}
return NoChange();
}
Reduction JSCallReducer::ReduceJSCallWithArrayLike(Node* node) {
DCHECK_EQ(IrOpcode::kJSCallWithArrayLike, node->opcode());
CallFrequency frequency = CallFrequencyOf(node->op());
VectorSlotPair feedback;
return ReduceCallOrConstructWithArrayLikeOrSpread(node, 2, frequency,
feedback);
}
Reduction JSCallReducer::ReduceJSCallWithSpread(Node* node) {
DCHECK_EQ(IrOpcode::kJSCallWithSpread, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
DCHECK_LE(3u, p.arity());
int arity = static_cast<int>(p.arity() - 1);
CallFrequency frequency = p.frequency();
VectorSlotPair feedback = p.feedback();
return ReduceCallOrConstructWithArrayLikeOrSpread(node, arity, frequency,
feedback);
}
Reduction JSCallReducer::ReduceJSConstruct(Node* node) {
DCHECK_EQ(IrOpcode::kJSConstruct, node->opcode());
ConstructParameters const& p = ConstructParametersOf(node->op());
DCHECK_LE(2u, p.arity());
int arity = static_cast<int>(p.arity() - 2);
Node* target = NodeProperties::GetValueInput(node, 0);
Node* new_target = NodeProperties::GetValueInput(node, arity + 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Extract feedback from the {node} using the FeedbackNexus.
if (p.feedback().IsValid()) {
FeedbackNexus nexus(p.feedback().vector(), p.feedback().slot());
if (nexus.IsUninitialized()) {
if (flags() & kBailoutOnUninitialized) {
// Introduce a SOFT deopt if the construct {node} wasn't executed so
// far.
return ReduceSoftDeoptimize(
node, DeoptimizeReason::kInsufficientTypeFeedbackForConstruct);
}
return NoChange();
}
HeapObject* feedback_object;
if (nexus.GetFeedback()->ToStrongHeapObject(&feedback_object) &&
feedback_object->IsAllocationSite()) {
// The feedback is an AllocationSite, which means we have called the
// Array function and collected transition (and pretenuring) feedback
// for the resulting arrays. This has to be kept in sync with the
// implementation in Ignition.
Handle<AllocationSite> site(AllocationSite::cast(feedback_object),
isolate());
// Retrieve the Array function from the {node}.
Node* array_function = jsgraph()->HeapConstant(
handle(native_context()->array_function(), isolate()));
// Check that the {target} is still the {array_function}.
Node* check = graph()->NewNode(simplified()->ReferenceEqual(), target,
array_function);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kWrongCallTarget), check,
effect, control);
// Turn the {node} into a {JSCreateArray} call.
NodeProperties::ReplaceEffectInput(node, effect);
for (int i = arity; i > 0; --i) {
NodeProperties::ReplaceValueInput(
node, NodeProperties::GetValueInput(node, i), i + 1);
}
NodeProperties::ReplaceValueInput(node, array_function, 1);
NodeProperties::ChangeOp(node, javascript()->CreateArray(arity, site));
return Changed(node);
} else if (nexus.GetFeedback()->ToWeakHeapObject(&feedback_object) &&
!HeapObjectMatcher(new_target).HasValue()) {
Handle<HeapObject> object(feedback_object, isolate());
if (object->IsConstructor()) {
Node* new_target_feedback = jsgraph()->Constant(object);
// Check that the {new_target} is still the {new_target_feedback}.
Node* check = graph()->NewNode(simplified()->ReferenceEqual(),
new_target, new_target_feedback);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kWrongCallTarget), check,
effect, control);
// Specialize the JSConstruct node to the {new_target_feedback}.
NodeProperties::ReplaceValueInput(node, new_target_feedback, arity + 1);
NodeProperties::ReplaceEffectInput(node, effect);
if (target == new_target) {
NodeProperties::ReplaceValueInput(node, new_target_feedback, 0);
}
// Try to further reduce the JSConstruct {node}.
Reduction const reduction = ReduceJSConstruct(node);
return reduction.Changed() ? reduction : Changed(node);
}
}
}
// Try to specialize JSConstruct {node}s with constant {target}s.
HeapObjectMatcher m(target);
if (m.HasValue()) {
// Raise a TypeError if the {target} is not a constructor.
if (!m.Value()->IsConstructor()) {
NodeProperties::ReplaceValueInputs(node, target);
NodeProperties::ChangeOp(node,
javascript()->CallRuntime(
Runtime::kThrowConstructedNonConstructable));
return Changed(node);
}
if (m.Value()->IsJSFunction()) {
Handle<JSFunction> function = Handle<JSFunction>::cast(m.Value());
// Do not reduce constructors with break points.
if (function->shared()->HasBreakInfo()) return NoChange();
// Don't inline cross native context.
if (function->native_context() != *native_context()) return NoChange();
// Check for known builtin functions.
int builtin_id = function->shared()->HasBuiltinId()
? function->shared()->builtin_id()
: Builtins::kNoBuiltinId;
switch (builtin_id) {
case Builtins::kArrayConstructor: {
// TODO(bmeurer): Deal with Array subclasses here.
Handle<AllocationSite> site;
// Turn the {node} into a {JSCreateArray} call.
for (int i = arity; i > 0; --i) {
NodeProperties::ReplaceValueInput(
node, NodeProperties::GetValueInput(node, i), i + 1);
}
NodeProperties::ReplaceValueInput(node, new_target, 1);
NodeProperties::ChangeOp(node,
javascript()->CreateArray(arity, site));
return Changed(node);
}
case Builtins::kObjectConstructor: {
// If no value is passed, we can immediately lower to a simple
// JSCreate and don't need to do any massaging of the {node}.
if (arity == 0) {
NodeProperties::ChangeOp(node, javascript()->Create());
return Changed(node);
}
// Otherwise we can only lower to JSCreate if we know that
// the value parameter is ignored, which is only the case if
// the {new_target} and {target} are definitely not identical.
HeapObjectMatcher mnew_target(new_target);
if (mnew_target.HasValue() && *mnew_target.Value() != *function) {
// Drop the value inputs.
for (int i = arity; i > 0; --i) node->RemoveInput(i);
NodeProperties::ChangeOp(node, javascript()->Create());
return Changed(node);
}
break;
}
case Builtins::kPromiseConstructor:
return ReducePromiseConstructor(node);
case Builtins::kTypedArrayConstructor:
return ReduceTypedArrayConstructor(
node, handle(function->shared(), isolate()));
default:
break;
}
} else if (m.Value()->IsJSBoundFunction()) {
Handle<JSBoundFunction> function =
Handle<JSBoundFunction>::cast(m.Value());
Handle<JSReceiver> bound_target_function(
function->bound_target_function(), isolate());
Handle<FixedArray> bound_arguments(function->bound_arguments(),
isolate());
// Patch {node} to use [[BoundTargetFunction]].
NodeProperties::ReplaceValueInput(
node, jsgraph()->Constant(bound_target_function), 0);
// Patch {node} to use [[BoundTargetFunction]]
// as new.target if {new_target} equals {target}.
NodeProperties::ReplaceValueInput(
node,
graph()->NewNode(common()->Select(MachineRepresentation::kTagged),
graph()->NewNode(simplified()->ReferenceEqual(),
target, new_target),
jsgraph()->Constant(bound_target_function),
new_target),
arity + 1);
// Insert the [[BoundArguments]] for {node}.
for (int i = 0; i < bound_arguments->length(); ++i) {
node->InsertInput(
graph()->zone(), i + 1,
jsgraph()->Constant(handle(bound_arguments->get(i), isolate())));
arity++;
}
// Update the JSConstruct operator on {node}.
NodeProperties::ChangeOp(
node,
javascript()->Construct(arity + 2, p.frequency(), VectorSlotPair()));
// Try to further reduce the JSConstruct {node}.
Reduction const reduction = ReduceJSConstruct(node);
return reduction.Changed() ? reduction : Changed(node);
}
// TODO(bmeurer): Also support optimizing proxies here.
}
// If {target} is the result of a JSCreateBoundFunction operation,
// we can just fold the construction and construct the bound target
// function directly instead.
if (target->opcode() == IrOpcode::kJSCreateBoundFunction) {
Node* bound_target_function = NodeProperties::GetValueInput(target, 0);
int const bound_arguments_length =
static_cast<int>(CreateBoundFunctionParametersOf(target->op()).arity());
// Patch the {node} to use [[BoundTargetFunction]].
NodeProperties::ReplaceValueInput(node, bound_target_function, 0);
// Patch {node} to use [[BoundTargetFunction]]
// as new.target if {new_target} equals {target}.
NodeProperties::ReplaceValueInput(
node,
graph()->NewNode(common()->Select(MachineRepresentation::kTagged),
graph()->NewNode(simplified()->ReferenceEqual(),
target, new_target),
bound_target_function, new_target),
arity + 1);
// Insert the [[BoundArguments]] for {node}.
for (int i = 0; i < bound_arguments_length; ++i) {
Node* value = NodeProperties::GetValueInput(target, 2 + i);
node->InsertInput(graph()->zone(), 1 + i, value);
arity++;
}
// Update the JSConstruct operator on {node}.
NodeProperties::ChangeOp(
node,
javascript()->Construct(arity + 2, p.frequency(), VectorSlotPair()));
// Try to further reduce the JSConstruct {node}.
Reduction const reduction = ReduceJSConstruct(node);
return reduction.Changed() ? reduction : Changed(node);
}
return NoChange();
}
// ES #sec-string.prototype.indexof
Reduction JSCallReducer::ReduceStringPrototypeIndexOf(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (node->op()->ValueInputCount() >= 3) {
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* new_receiver = effect = graph()->NewNode(
simplified()->CheckString(p.feedback()), receiver, effect, control);
Node* search_string = NodeProperties::GetValueInput(node, 2);
Node* new_search_string = effect =
graph()->NewNode(simplified()->CheckString(p.feedback()), search_string,
effect, control);
Node* new_position = jsgraph()->ZeroConstant();
if (node->op()->ValueInputCount() >= 4) {
Node* position = NodeProperties::GetValueInput(node, 3);
new_position = effect = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), position, effect, control);
}
NodeProperties::ReplaceEffectInput(node, effect);
RelaxEffectsAndControls(node);
node->ReplaceInput(0, new_receiver);
node->ReplaceInput(1, new_search_string);
node->ReplaceInput(2, new_position);
node->TrimInputCount(3);
NodeProperties::ChangeOp(node, simplified()->StringIndexOf());
return Changed(node);
}
return NoChange();
}
// ES #sec-string.prototype.substring
Reduction JSCallReducer::ReduceStringPrototypeSubstring(Node* node) {
if (node->op()->ValueInputCount() < 3) return NoChange();
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* start = NodeProperties::GetValueInput(node, 2);
Node* end = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
receiver = effect = graph()->NewNode(simplified()->CheckString(p.feedback()),
receiver, effect, control);
start = effect = graph()->NewNode(simplified()->CheckSmi(p.feedback()), start,
effect, control);
Node* length = graph()->NewNode(simplified()->StringLength(), receiver);
Node* check = graph()->NewNode(simplified()->ReferenceEqual(), end,
jsgraph()->UndefinedConstant());
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = length;
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse = efalse = graph()->NewNode(simplified()->CheckSmi(p.feedback()),
end, efalse, if_false);
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
end = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue, vfalse, control);
Node* finalStart =
graph()->NewNode(simplified()->NumberMin(),
graph()->NewNode(simplified()->NumberMax(), start,
jsgraph()->ZeroConstant()),
length);
Node* finalEnd =
graph()->NewNode(simplified()->NumberMin(),
graph()->NewNode(simplified()->NumberMax(), end,
jsgraph()->ZeroConstant()),
length);
Node* from =
graph()->NewNode(simplified()->NumberMin(), finalStart, finalEnd);
Node* to = graph()->NewNode(simplified()->NumberMax(), finalStart, finalEnd);
Node* value = effect = graph()->NewNode(simplified()->StringSubstring(),
receiver, from, to, effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES #sec-string.prototype.slice
Reduction JSCallReducer::ReduceStringPrototypeSlice(Node* node) {
if (node->op()->ValueInputCount() < 3) return NoChange();
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* start = NodeProperties::GetValueInput(node, 2);
Node* end = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
receiver = effect = graph()->NewNode(simplified()->CheckString(p.feedback()),
receiver, effect, control);
start = effect = graph()->NewNode(simplified()->CheckSmi(p.feedback()), start,
effect, control);
Node* length = graph()->NewNode(simplified()->StringLength(), receiver);
// Replace {end} argument with {length} if it is undefined.
{
Node* check = graph()->NewNode(simplified()->ReferenceEqual(), end,
jsgraph()->UndefinedConstant());
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = length;
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse = efalse = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), end, efalse, if_false);
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
end = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue, vfalse, control);
}
Node* from = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kFalse),
graph()->NewNode(simplified()->NumberLessThan(), start,
jsgraph()->ZeroConstant()),
graph()->NewNode(
simplified()->NumberMax(),
graph()->NewNode(simplified()->NumberAdd(), length, start),
jsgraph()->ZeroConstant()),
graph()->NewNode(simplified()->NumberMin(), start, length));
// {from} is always in non-negative Smi range, but our typer cannot
// figure that out yet.
from = effect = graph()->NewNode(common()->TypeGuard(Type::UnsignedSmall()),
from, effect, control);
Node* to = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kFalse),
graph()->NewNode(simplified()->NumberLessThan(), end,
jsgraph()->ZeroConstant()),
graph()->NewNode(simplified()->NumberMax(),
graph()->NewNode(simplified()->NumberAdd(), length, end),
jsgraph()->ZeroConstant()),
graph()->NewNode(simplified()->NumberMin(), end, length));
// {to} is always in non-negative Smi range, but our typer cannot
// figure that out yet.
to = effect = graph()->NewNode(common()->TypeGuard(Type::UnsignedSmall()), to,
effect, control);
Node* result_string = nullptr;
// Return empty string if {from} is smaller than {to}.
{
Node* check = graph()->NewNode(simplified()->NumberLessThan(), from, to);
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = etrue = graph()->NewNode(simplified()->StringSubstring(),
receiver, from, to, etrue, if_true);
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse = jsgraph()->EmptyStringConstant();
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
result_string =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue, vfalse, control);
}
ReplaceWithValue(node, result_string, effect, control);
return Replace(result_string);
}
// ES #sec-string.prototype.substr
Reduction JSCallReducer::ReduceStringPrototypeSubstr(Node* node) {
if (node->op()->ValueInputCount() < 3) return NoChange();
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* start = NodeProperties::GetValueInput(node, 2);
Node* end = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
receiver = effect = graph()->NewNode(simplified()->CheckString(p.feedback()),
receiver, effect, control);
start = effect = graph()->NewNode(simplified()->CheckSmi(p.feedback()), start,
effect, control);
Node* length = graph()->NewNode(simplified()->StringLength(), receiver);
// Replace {end} argument with {length} if it is undefined.
{
Node* check = graph()->NewNode(simplified()->ReferenceEqual(), end,
jsgraph()->UndefinedConstant());
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = length;
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse = efalse = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), end, efalse, if_false);
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
end = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue, vfalse, control);
}
Node* initStart = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kFalse),
graph()->NewNode(simplified()->NumberLessThan(), start,
jsgraph()->ZeroConstant()),
graph()->NewNode(
simplified()->NumberMax(),
graph()->NewNode(simplified()->NumberAdd(), length, start),
jsgraph()->ZeroConstant()),
start);
// The select above guarantees that initStart is non-negative, but
// our typer can't figure that out yet.
initStart = effect = graph()->NewNode(
common()->TypeGuard(Type::UnsignedSmall()), initStart, effect, control);
Node* resultLength = graph()->NewNode(
simplified()->NumberMin(),
graph()->NewNode(simplified()->NumberMax(), end,
jsgraph()->ZeroConstant()),
graph()->NewNode(simplified()->NumberSubtract(), length, initStart));
// The the select below uses {resultLength} only if {resultLength > 0},
// but our typer can't figure that out yet.
Node* to = effect = graph()->NewNode(
common()->TypeGuard(Type::UnsignedSmall()),
graph()->NewNode(simplified()->NumberAdd(), initStart, resultLength),
effect, control);
Node* result_string = nullptr;
// Return empty string if {from} is smaller than {to}.
{
Node* check = graph()->NewNode(simplified()->NumberLessThan(),
jsgraph()->ZeroConstant(), resultLength);
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = etrue =
graph()->NewNode(simplified()->StringSubstring(), receiver, initStart,
to, etrue, if_true);
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse = jsgraph()->EmptyStringConstant();
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
result_string =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue, vfalse, control);
}
ReplaceWithValue(node, result_string, effect, control);
return Replace(result_string);
}
Reduction JSCallReducer::ReduceJSConstructWithArrayLike(Node* node) {
DCHECK_EQ(IrOpcode::kJSConstructWithArrayLike, node->opcode());
CallFrequency frequency = CallFrequencyOf(node->op());
VectorSlotPair feedback;
return ReduceCallOrConstructWithArrayLikeOrSpread(node, 1, frequency,
feedback);
}
Reduction JSCallReducer::ReduceJSConstructWithSpread(Node* node) {
DCHECK_EQ(IrOpcode::kJSConstructWithSpread, node->opcode());
ConstructParameters const& p = ConstructParametersOf(node->op());
DCHECK_LE(3u, p.arity());
int arity = static_cast<int>(p.arity() - 2);
CallFrequency frequency = p.frequency();
VectorSlotPair feedback = p.feedback();
return ReduceCallOrConstructWithArrayLikeOrSpread(node, arity, frequency,
feedback);
}
Reduction JSCallReducer::ReduceReturnReceiver(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
ReplaceWithValue(node, receiver);
return Replace(receiver);
}
Reduction JSCallReducer::ReduceSoftDeoptimize(Node* node,
DeoptimizeReason reason) {
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* frame_state = NodeProperties::FindFrameStateBefore(node);
Node* deoptimize = graph()->NewNode(
common()->Deoptimize(DeoptimizeKind::kSoft, reason, VectorSlotPair()),
frame_state, effect, control);
// TODO(bmeurer): This should be on the AdvancedReducer somehow.
NodeProperties::MergeControlToEnd(graph(), common(), deoptimize);
Revisit(graph()->end());
node->TrimInputCount(0);
NodeProperties::ChangeOp(node, common()->Dead());
return Changed(node);
}
namespace {
// TODO(turbofan): This was copied from old compiler, might be too restrictive.
bool IsReadOnlyLengthDescriptor(Isolate* isolate, Handle<Map> jsarray_map) {
DCHECK(!jsarray_map->is_dictionary_map());
Handle<Name> length_string = isolate->factory()->length_string();
DescriptorArray* descriptors = jsarray_map->instance_descriptors();
int number = descriptors->Search(*length_string, *jsarray_map);
DCHECK_NE(DescriptorArray::kNotFound, number);
return descriptors->GetDetails(number).IsReadOnly();
}
// TODO(turbofan): This was copied from old compiler, might be too restrictive.
bool CanInlineArrayResizeOperation(Isolate* isolate, Handle<Map> receiver_map) {
if (!receiver_map->prototype()->IsJSArray()) return false;
Handle<JSArray> receiver_prototype(JSArray::cast(receiver_map->prototype()),
isolate);
return receiver_map->instance_type() == JS_ARRAY_TYPE &&
IsFastElementsKind(receiver_map->elements_kind()) &&
!receiver_map->is_dictionary_map() && receiver_map->is_extensible() &&
isolate->IsAnyInitialArrayPrototype(receiver_prototype) &&
!IsReadOnlyLengthDescriptor(isolate, receiver_map);
}
} // namespace
// ES6 section 22.1.3.18 Array.prototype.push ( )
Reduction JSCallReducer::ReduceArrayPrototypePush(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (!isolate()->IsNoElementsProtectorIntact()) return NoChange();
int const num_values = node->op()->ValueInputCount() - 2;
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Try to determine the {receiver} map(s).
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayResizeOperation(isolate(), receiver_map))
return NoChange();
if (!UnionElementsKindUptoPackedness(&kind, receiver_map->elements_kind()))
return NoChange();
}
// Install code dependencies on the {receiver} global array protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
// If the {receiver_maps} information is not reliable, we need
// to check that the {receiver} still has one of these maps.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Collect the value inputs to push.
std::vector<Node*> values(num_values);
for (int i = 0; i < num_values; ++i) {
values[i] = NodeProperties::GetValueInput(node, 2 + i);
}
for (auto& value : values) {
if (IsSmiElementsKind(kind)) {
value = effect = graph()->NewNode(simplified()->CheckSmi(p.feedback()),
value, effect, control);
} else if (IsDoubleElementsKind(kind)) {
value = effect = graph()->NewNode(simplified()->CheckNumber(p.feedback()),
value, effect, control);
// Make sure we do not store signaling NaNs into double arrays.
value = graph()->NewNode(simplified()->NumberSilenceNaN(), value);
}
}
// Load the "length" property of the {receiver}.
Node* length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
Node* value = length;
// Check if we have any {values} to push.
if (num_values > 0) {
// Compute the resulting "length" of the {receiver}.
Node* new_length = value = graph()->NewNode(
simplified()->NumberAdd(), length, jsgraph()->Constant(num_values));
// Load the elements backing store of the {receiver}.
Node* elements = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()), receiver,
effect, control);
Node* elements_length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForFixedArrayLength()), elements,
effect, control);
GrowFastElementsMode mode =
IsDoubleElementsKind(kind) ? GrowFastElementsMode::kDoubleElements
: GrowFastElementsMode::kSmiOrObjectElements;
elements = effect = graph()->NewNode(
simplified()->MaybeGrowFastElements(mode, p.feedback()), receiver,
elements,
graph()->NewNode(simplified()->NumberAdd(), length,
jsgraph()->Constant(num_values - 1)),
elements_length, effect, control);
// Update the JSArray::length field. Since this is observable,
// there must be no other check after this.
effect = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSArrayLength(kind)),
receiver, new_length, effect, control);
// Append the {values} to the {elements}.
for (int i = 0; i < num_values; ++i) {
Node* value = values[i];
Node* index = graph()->NewNode(simplified()->NumberAdd(), length,
jsgraph()->Constant(i));
effect = graph()->NewNode(
simplified()->StoreElement(AccessBuilder::ForFixedArrayElement(kind)),
elements, index, value, effect, control);
}
}
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES6 section 22.1.3.17 Array.prototype.pop ( )
Reduction JSCallReducer::ReduceArrayPrototypePop(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (!isolate()->IsNoElementsProtectorIntact()) return NoChange();
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayResizeOperation(isolate(), receiver_map))
return NoChange();
// TODO(turbofan): Extend this to also handle fast holey double elements
// once we got the hole NaN mess sorted out in TurboFan/V8.
if (receiver_map->elements_kind() == HOLEY_DOUBLE_ELEMENTS)
return NoChange();
if (!UnionElementsKindUptoSize(&kind, receiver_map->elements_kind()))
return NoChange();
}
// Install code dependencies on the {receiver} global array protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
// If the {receiver_maps} information is not reliable, we need
// to check that the {receiver} still has one of these maps.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Load the "length" property of the {receiver}.
Node* length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
// Check if the {receiver} has any elements.
Node* check = graph()->NewNode(simplified()->NumberEqual(), length,
jsgraph()->ZeroConstant());
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = jsgraph()->UndefinedConstant();
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse;
{
// TODO(tebbi): We should trim the backing store if the capacity is too
// big, as implemented in elements.cc:ElementsAccessorBase::SetLengthImpl.
// Load the elements backing store from the {receiver}.
Node* elements = efalse = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()), receiver,
efalse, if_false);
// Ensure that we aren't popping from a copy-on-write backing store.
if (IsSmiOrObjectElementsKind(kind)) {
elements = efalse =
graph()->NewNode(simplified()->EnsureWritableFastElements(), receiver,
elements, efalse, if_false);
}
// Compute the new {length}.
length = graph()->NewNode(simplified()->NumberSubtract(), length,
jsgraph()->OneConstant());
// Store the new {length} to the {receiver}.
efalse = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSArrayLength(kind)),
receiver, length, efalse, if_false);
// Load the last entry from the {elements}.
vfalse = efalse = graph()->NewNode(
simplified()->LoadElement(AccessBuilder::ForFixedArrayElement(kind)),
elements, length, efalse, if_false);
// Store a hole to the element we just removed from the {receiver}.
efalse = graph()->NewNode(
simplified()->StoreElement(
AccessBuilder::ForFixedArrayElement(GetHoleyElementsKind(kind))),
elements, length, jsgraph()->TheHoleConstant(), efalse, if_false);
}
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
Node* value = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2), vtrue, vfalse, control);
// Convert the hole to undefined. Do this last, so that we can optimize
// conversion operator via some smart strength reduction in many cases.
if (IsHoleyElementsKind(kind)) {
value =
graph()->NewNode(simplified()->ConvertTaggedHoleToUndefined(), value);
}
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES6 section 22.1.3.22 Array.prototype.shift ( )
Reduction JSCallReducer::ReduceArrayPrototypeShift(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (!isolate()->IsNoElementsProtectorIntact()) return NoChange();
Node* target = NodeProperties::GetValueInput(node, 0);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
ElementsKind kind = receiver_maps[0]->elements_kind();
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayResizeOperation(isolate(), receiver_map))
return NoChange();
// TODO(turbofan): Extend this to also handle fast holey double elements
// once we got the hole NaN mess sorted out in TurboFan/V8.
if (receiver_map->elements_kind() == HOLEY_DOUBLE_ELEMENTS)
return NoChange();
if (!UnionElementsKindUptoSize(&kind, receiver_map->elements_kind()))
return NoChange();
}
// Install code dependencies on the {receiver} global array protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
// If the {receiver_maps} information is not reliable, we need
// to check that the {receiver} still has one of these maps.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Load length of the {receiver}.
Node* length = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayLength(kind)), receiver,
effect, control);
// Return undefined if {receiver} has no elements.
Node* check0 = graph()->NewNode(simplified()->NumberEqual(), length,
jsgraph()->ZeroConstant());
Node* branch0 =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check0, control);
Node* if_true0 = graph()->NewNode(common()->IfTrue(), branch0);
Node* etrue0 = effect;
Node* vtrue0 = jsgraph()->UndefinedConstant();
Node* if_false0 = graph()->NewNode(common()->IfFalse(), branch0);
Node* efalse0 = effect;
Node* vfalse0;
{
// Check if we should take the fast-path.
Node* check1 =
graph()->NewNode(simplified()->NumberLessThanOrEqual(), length,
jsgraph()->Constant(JSArray::kMaxCopyElements));
Node* branch1 = graph()->NewNode(common()->Branch(BranchHint::kTrue),
check1, if_false0);
Node* if_true1 = graph()->NewNode(common()->IfTrue(), branch1);
Node* etrue1 = efalse0;
Node* vtrue1;
{
Node* elements = etrue1 = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()),
receiver, etrue1, if_true1);
// Load the first element here, which we return below.
vtrue1 = etrue1 = graph()->NewNode(
simplified()->LoadElement(AccessBuilder::ForFixedArrayElement(kind)),
elements, jsgraph()->ZeroConstant(), etrue1, if_true1);
// Ensure that we aren't shifting a copy-on-write backing store.
if (IsSmiOrObjectElementsKind(kind)) {
elements = etrue1 =
graph()->NewNode(simplified()->EnsureWritableFastElements(),
receiver, elements, etrue1, if_true1);
}
// Shift the remaining {elements} by one towards the start.
Node* loop = graph()->NewNode(common()->Loop(2), if_true1, if_true1);
Node* eloop =
graph()->NewNode(common()->EffectPhi(2), etrue1, etrue1, loop);
Node* terminate = graph()->NewNode(common()->Terminate(), eloop, loop);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
Node* index = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2),
jsgraph()->OneConstant(),
jsgraph()->Constant(JSArray::kMaxCopyElements - 1), loop);
{
Node* check2 =
graph()->NewNode(simplified()->NumberLessThan(), index, length);
Node* branch2 = graph()->NewNode(common()->Branch(), check2, loop);
if_true1 = graph()->NewNode(common()->IfFalse(), branch2);
etrue1 = eloop;
Node* control = graph()->NewNode(common()->IfTrue(), branch2);
Node* effect = etrue1;
ElementAccess const access = AccessBuilder::ForFixedArrayElement(kind);
Node* value = effect =
graph()->NewNode(simplified()->LoadElement(access), elements, index,
effect, control);
effect =
graph()->NewNode(simplified()->StoreElement(access), elements,
graph()->NewNode(simplified()->NumberSubtract(),
index, jsgraph()->OneConstant()),
value, effect, control);
loop->ReplaceInput(1, control);
eloop->ReplaceInput(1, effect);
index->ReplaceInput(1,
graph()->NewNode(simplified()->NumberAdd(), index,
jsgraph()->OneConstant()));
}
// Compute the new {length}.
length = graph()->NewNode(simplified()->NumberSubtract(), length,
jsgraph()->OneConstant());
// Store the new {length} to the {receiver}.
etrue1 = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSArrayLength(kind)),
receiver, length, etrue1, if_true1);
// Store a hole to the element we just removed from the {receiver}.
etrue1 = graph()->NewNode(
simplified()->StoreElement(
AccessBuilder::ForFixedArrayElement(GetHoleyElementsKind(kind))),
elements, length, jsgraph()->TheHoleConstant(), etrue1, if_true1);
}
Node* if_false1 = graph()->NewNode(common()->IfFalse(), branch1);
Node* efalse1 = efalse0;
Node* vfalse1;
{
// Call the generic C++ implementation.
const int builtin_index = Builtins::kArrayShift;
auto call_descriptor = Linkage::GetCEntryStubCallDescriptor(
graph()->zone(), 1, BuiltinArguments::kNumExtraArgsWithReceiver,
Builtins::name(builtin_index), node->op()->properties(),
CallDescriptor::kNeedsFrameState);
Node* stub_code =
jsgraph()->CEntryStubConstant(1, kDontSaveFPRegs, kArgvOnStack, true);
Address builtin_entry = Builtins::CppEntryOf(builtin_index);
Node* entry =
jsgraph()->ExternalConstant(ExternalReference::Create(builtin_entry));
Node* argc =
jsgraph()->Constant(BuiltinArguments::kNumExtraArgsWithReceiver);
if_false1 = efalse1 = vfalse1 =
graph()->NewNode(common()->Call(call_descriptor), stub_code, receiver,
jsgraph()->PaddingConstant(), argc, target,
jsgraph()->UndefinedConstant(), entry, argc, context,
frame_state, efalse1, if_false1);
}
if_false0 = graph()->NewNode(common()->Merge(2), if_true1, if_false1);
efalse0 =
graph()->NewNode(common()->EffectPhi(2), etrue1, efalse1, if_false0);
vfalse0 = graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue1, vfalse1, if_false0);
}
control = graph()->NewNode(common()->Merge(2), if_true0, if_false0);
effect = graph()->NewNode(common()->EffectPhi(2), etrue0, efalse0, control);
Node* value =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue0, vfalse0, control);
// Convert the hole to undefined. Do this last, so that we can optimize
// conversion operator via some smart strength reduction in many cases.
if (IsHoleyElementsKind(kind)) {
value =
graph()->NewNode(simplified()->ConvertTaggedHoleToUndefined(), value);
}
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES6 section 22.1.3.23 Array.prototype.slice ( )
Reduction JSCallReducer::ReduceArrayPrototypeSlice(Node* node) {
if (!FLAG_turbo_inline_array_builtins) return NoChange();
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
int arity = static_cast<int>(p.arity() - 2);
// Here we only optimize for cloning, that is when slice is called
// without arguments, or with a single argument that is the constant 0.
if (arity >= 2) return NoChange();
if (arity == 1) {
NumberMatcher m(NodeProperties::GetValueInput(node, 2));
if (!m.HasValue()) return NoChange();
if (m.Value() != 0) return NoChange();
}
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Try to determine the {receiver} map.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
// Ensure that any changes to the Array species constructor cause deopt.
if (!isolate()->IsArraySpeciesLookupChainIntact()) return NoChange();
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->array_species_protector()));
bool can_be_holey = false;
// Check that the maps are of JSArray (and more)
for (Handle<Map> receiver_map : receiver_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), receiver_map))
return NoChange();
if (IsHoleyElementsKind(receiver_map->elements_kind())) can_be_holey = true;
}
// Install code dependency on the array protector for holey arrays.
if (can_be_holey) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
// If we have unreliable maps, we need a map check.
// This is actually redundant due to how JSNativeContextSpecialization
// reduces the load of slice, but we do it here nevertheless for consistency
// and robustness.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
Node* context = NodeProperties::GetContextInput(node);
Callable callable =
Builtins::CallableFor(isolate(), Builtins::kCloneFastJSArray);
auto call_descriptor = Linkage::GetStubCallDescriptor(
graph()->zone(), callable.descriptor(), 0, CallDescriptor::kNoFlags,
Operator::kNoThrow | Operator::kNoDeopt);
// Calls to Builtins::kCloneFastJSArray produce COW arrays
// if the original array is COW
Node* clone = effect = graph()->NewNode(
common()->Call(call_descriptor), jsgraph()->HeapConstant(callable.code()),
receiver, context, effect, control);
ReplaceWithValue(node, clone, effect, control);
return Replace(clone);
}
// ES6 section 22.1.2.2 Array.isArray ( arg )
Reduction JSCallReducer::ReduceArrayIsArray(Node* node) {
// We certainly know that undefined is not an array.
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->FalseConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* object = NodeProperties::GetValueInput(node, 2);
node->ReplaceInput(0, object);
node->ReplaceInput(1, context);
node->ReplaceInput(2, frame_state);
node->ReplaceInput(3, effect);
node->ReplaceInput(4, control);
node->TrimInputCount(5);
NodeProperties::ChangeOp(node, javascript()->ObjectIsArray());
return Changed(node);
}
Reduction JSCallReducer::ReduceArrayIterator(Node* node, IterationKind kind) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Check if we know that {receiver} is a valid JSReceiver.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
for (Handle<Map> receiver_map : receiver_maps) {
if (!receiver_map->IsJSReceiverMap()) return NoChange();
}
// Morph the {node} into a JSCreateArrayIterator with the given {kind}.
RelaxControls(node);
node->ReplaceInput(0, receiver);
node->ReplaceInput(1, context);
node->ReplaceInput(2, effect);
node->ReplaceInput(3, control);
node->TrimInputCount(4);
NodeProperties::ChangeOp(node, javascript()->CreateArrayIterator(kind));
return Changed(node);
}
namespace {
bool InferIteratedObjectMaps(Isolate* isolate, Node* iterator,
ZoneHandleSet<Map>* iterated_object_maps) {
DCHECK_EQ(IrOpcode::kJSCreateArrayIterator, iterator->opcode());
Node* iterated_object = NodeProperties::GetValueInput(iterator, 0);
Node* effect = NodeProperties::GetEffectInput(iterator);
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate, iterated_object, effect,
iterated_object_maps);
return result != NodeProperties::kNoReceiverMaps;
}
} // namespace
// ES #sec-%arrayiteratorprototype%.next
Reduction JSCallReducer::ReduceArrayIteratorPrototypeNext(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
Node* iterator = NodeProperties::GetValueInput(node, 1);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
// Check if the {iterator} is a JSCreateArrayIterator.
if (iterator->opcode() != IrOpcode::kJSCreateArrayIterator) return NoChange();
IterationKind const iteration_kind =
CreateArrayIteratorParametersOf(iterator->op()).kind();
// Try to infer the [[IteratedObject]] maps from the {iterator}.
ZoneHandleSet<Map> iterated_object_maps;
if (!InferIteratedObjectMaps(isolate(), iterator, &iterated_object_maps)) {
return NoChange();
}
DCHECK_NE(0, iterated_object_maps.size());
// Check that various {iterated_object_maps} have compatible elements kinds.
ElementsKind elements_kind = iterated_object_maps[0]->elements_kind();
if (IsFixedTypedArrayElementsKind(elements_kind)) {
// TurboFan doesn't support loading from BigInt typed arrays yet.
if (elements_kind == BIGUINT64_ELEMENTS ||
elements_kind == BIGINT64_ELEMENTS) {
return NoChange();
}
for (Handle<Map> iterated_object_map : iterated_object_maps) {
if (iterated_object_map->elements_kind() != elements_kind) {
return NoChange();
}
}
} else {
for (Handle<Map> iterated_object_map : iterated_object_maps) {
if (!CanInlineArrayIteratingBuiltin(isolate(), iterated_object_map)) {
return NoChange();
}
if (!UnionElementsKindUptoSize(&elements_kind,
iterated_object_map->elements_kind())) {
return NoChange();
}
}
}
// Install code dependency on the array protector for holey arrays.
if (IsHoleyElementsKind(elements_kind)) {
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->no_elements_protector()));
}
// Load the (current) {iterated_object} from the {iterator}.
Node* iterated_object = effect =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForJSArrayIteratorIteratedObject()),
iterator, effect, control);
// Ensure that the {iterated_object} map didn't change.
effect = graph()->NewNode(
simplified()->CheckMaps(CheckMapsFlag::kNone, iterated_object_maps,
p.feedback()),
iterated_object, effect, control);
if (IsFixedTypedArrayElementsKind(elements_kind)) {
// See if we can skip the neutering check.
if (isolate()->IsArrayBufferNeuteringIntact()) {
// Add a code dependency so we are deoptimized in case an ArrayBuffer
// gets neutered.
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->array_buffer_neutering_protector()));
} else {
// Deoptimize if the array buffer was neutered.
Node* buffer = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayBufferViewBuffer()),
iterated_object, effect, control);
Node* check = effect = graph()->NewNode(
simplified()->ArrayBufferWasNeutered(), buffer, effect, control);
check = graph()->NewNode(simplified()->BooleanNot(), check);
// TODO(bmeurer): Pass p.feedback(), or better introduce
// CheckArrayBufferNotNeutered?
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kArrayBufferWasNeutered),
check, effect, control);
}
}
// Load the [[NextIndex]] from the {iterator} and leverage the fact
// that we definitely know that it's in Unsigned32 range since the
// {iterated_object} is either a JSArray or a JSTypedArray. For the
// latter case we even know that it's a Smi in UnsignedSmall range.
FieldAccess index_access = AccessBuilder::ForJSArrayIteratorNextIndex();
if (IsFixedTypedArrayElementsKind(elements_kind)) {
index_access.type = TypeCache::Get().kJSTypedArrayLengthType;
index_access.machine_type = MachineType::TaggedSigned();
index_access.write_barrier_kind = kNoWriteBarrier;
} else {
index_access.type = TypeCache::Get().kJSArrayLengthType;
}
Node* index = effect = graph()->NewNode(simplified()->LoadField(index_access),
iterator, effect, control);
// Load the elements of the {iterated_object}. While it feels
// counter-intuitive to place the elements pointer load before
// the condition below, as it might not be needed (if the {index}
// is out of bounds for the {iterated_object}), it's better this
// way as it allows the LoadElimination to eliminate redundant
// reloads of the elements pointer.
Node* elements = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSObjectElements()),
iterated_object, effect, control);
// Load the length of the {iterated_object}. Due to the map checks we
// already know something about the length here, which we can leverage
// to generate Word32 operations below without additional checking.
FieldAccess length_access =
IsFixedTypedArrayElementsKind(elements_kind)
? AccessBuilder::ForJSTypedArrayLength()
: AccessBuilder::ForJSArrayLength(elements_kind);
Node* length = effect = graph()->NewNode(
simplified()->LoadField(length_access), iterated_object, effect, control);
// Check whether {index} is within the valid range for the {iterated_object}.
Node* check = graph()->NewNode(simplified()->NumberLessThan(), index, length);
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
Node* done_true;
Node* value_true;
Node* etrue = effect;
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
{
// We know that the {index} is range of the {length} now.
index = etrue = graph()->NewNode(
common()->TypeGuard(
Type::Range(0.0, length_access.type.Max() - 1.0, graph()->zone())),
index, etrue, if_true);
done_true = jsgraph()->FalseConstant();
if (iteration_kind == IterationKind::kKeys) {
// Just return the {index}.
value_true = index;
} else {
DCHECK(iteration_kind == IterationKind::kEntries ||
iteration_kind == IterationKind::kValues);
if (IsFixedTypedArrayElementsKind(elements_kind)) {
Node* base_ptr = etrue = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForFixedTypedArrayBaseBasePointer()),
elements, etrue, if_true);
Node* external_ptr = etrue = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForFixedTypedArrayBaseExternalPointer()),
elements, etrue, if_true);
ExternalArrayType array_type = kExternalInt8Array;
switch (elements_kind) {
#define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) \
case TYPE##_ELEMENTS: \
array_type = kExternal##Type##Array; \
break;
TYPED_ARRAYS(TYPED_ARRAY_CASE)
default:
UNREACHABLE();
#undef TYPED_ARRAY_CASE
}
Node* buffer = etrue =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForJSArrayBufferViewBuffer()),
iterated_object, etrue, if_true);
value_true = etrue =
graph()->NewNode(simplified()->LoadTypedElement(array_type), buffer,
base_ptr, external_ptr, index, etrue, if_true);
} else {
value_true = etrue = graph()->NewNode(
simplified()->LoadElement(
AccessBuilder::ForFixedArrayElement(elements_kind)),
elements, index, etrue, if_true);
// Convert hole to undefined if needed.
if (elements_kind == HOLEY_ELEMENTS ||
elements_kind == HOLEY_SMI_ELEMENTS) {
value_true = graph()->NewNode(
simplified()->ConvertTaggedHoleToUndefined(), value_true);
} else if (elements_kind == HOLEY_DOUBLE_ELEMENTS) {
// TODO(6587): avoid deopt if not all uses of value are truncated.
CheckFloat64HoleMode mode = CheckFloat64HoleMode::kAllowReturnHole;
value_true = etrue = graph()->NewNode(
simplified()->CheckFloat64Hole(mode, p.feedback()), value_true,
etrue, if_true);
}
}
if (iteration_kind == IterationKind::kEntries) {
// Allocate elements for key/value pair
value_true = etrue =
graph()->NewNode(javascript()->CreateKeyValueArray(), index,
value_true, context, etrue);
} else {
DCHECK_EQ(IterationKind::kValues, iteration_kind);
}
}
// Increment the [[NextIndex]] field in the {iterator}. The TypeGuards
// above guarantee that the {next_index} is in the UnsignedSmall range.
Node* next_index = graph()->NewNode(simplified()->NumberAdd(), index,
jsgraph()->OneConstant());
etrue = graph()->NewNode(simplified()->StoreField(index_access), iterator,
next_index, etrue, if_true);
}
Node* done_false;
Node* value_false;
Node* efalse = effect;
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
{
// iterator.[[NextIndex]] >= array.length, stop iterating.
done_false = jsgraph()->TrueConstant();
value_false = jsgraph()->UndefinedConstant();
if (!IsFixedTypedArrayElementsKind(elements_kind)) {
// Mark the {iterator} as exhausted by setting the [[NextIndex]] to a
// value that will never pass the length check again (aka the maximum
// value possible for the specific iterated object). Note that this is
// different from what the specification says, which is changing the
// [[IteratedObject]] field to undefined, but that makes it difficult
// to eliminate the map checks and "length" accesses in for..of loops.
//
// This is not necessary for JSTypedArray's, since the length of those
// cannot change later and so if we were ever out of bounds for them
// we will stay out-of-bounds forever.
Node* end_index = jsgraph()->Constant(index_access.type.Max());
efalse = graph()->NewNode(simplified()->StoreField(index_access),
iterator, end_index, efalse, if_false);
}
}
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
Node* value =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
value_true, value_false, control);
Node* done =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
done_true, done_false, control);
// Create IteratorResult object.
value = effect = graph()->NewNode(javascript()->CreateIterResultObject(),
value, done, context, effect);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES6 section 21.1.3.2 String.prototype.charCodeAt ( pos )
// ES6 section 21.1.3.3 String.prototype.codePointAt ( pos )
Reduction JSCallReducer::ReduceStringPrototypeStringAt(
const Operator* string_access_operator, Node* node) {
DCHECK(string_access_operator->opcode() == IrOpcode::kStringCharCodeAt ||
string_access_operator->opcode() == IrOpcode::kStringCodePointAt);
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* index = node->op()->ValueInputCount() >= 3
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->ZeroConstant();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Ensure that the {receiver} is actually a String.
receiver = effect = graph()->NewNode(simplified()->CheckString(p.feedback()),
receiver, effect, control);
// Determine the {receiver} length.
Node* receiver_length =
graph()->NewNode(simplified()->StringLength(), receiver);
// Check that the {index} is within range.
index = effect = graph()->NewNode(simplified()->CheckBounds(p.feedback()),
index, receiver_length, effect, control);
// Return the character from the {receiver} as single character string.
Node* masked_index = graph()->NewNode(simplified()->PoisonIndex(), index);
Node* value = effect = graph()->NewNode(string_access_operator, receiver,
masked_index, effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES section 21.1.3.1 String.prototype.charAt ( pos )
Reduction JSCallReducer::ReduceStringPrototypeCharAt(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* index = node->op()->ValueInputCount() >= 3
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->ZeroConstant();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Ensure that the {receiver} is actually a String.
receiver = effect = graph()->NewNode(simplified()->CheckString(p.feedback()),
receiver, effect, control);
// Determine the {receiver} length.
Node* receiver_length =
graph()->NewNode(simplified()->StringLength(), receiver);
// Check that the {index} is within range.
index = effect = graph()->NewNode(simplified()->CheckBounds(p.feedback()),
index, receiver_length, effect, control);
// Return the character from the {receiver} as single character string.
Node* masked_index = graph()->NewNode(simplified()->PoisonIndex(), index);
Node* value = effect =
graph()->NewNode(simplified()->StringCharCodeAt(), receiver, masked_index,
effect, control);
value = graph()->NewNode(simplified()->StringFromSingleCharCode(), value);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
#ifdef V8_INTL_SUPPORT
Reduction JSCallReducer::ReduceStringPrototypeToLowerCaseIntl(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = effect =
graph()->NewNode(simplified()->CheckString(p.feedback()),
NodeProperties::GetValueInput(node, 1), effect, control);
NodeProperties::ReplaceEffectInput(node, effect);
RelaxEffectsAndControls(node);
node->ReplaceInput(0, receiver);
node->TrimInputCount(1);
NodeProperties::ChangeOp(node, simplified()->StringToLowerCaseIntl());
NodeProperties::SetType(node, Type::String());
return Changed(node);
}
Reduction JSCallReducer::ReduceStringPrototypeToUpperCaseIntl(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = effect =
graph()->NewNode(simplified()->CheckString(p.feedback()),
NodeProperties::GetValueInput(node, 1), effect, control);
NodeProperties::ReplaceEffectInput(node, effect);
RelaxEffectsAndControls(node);
node->ReplaceInput(0, receiver);
node->TrimInputCount(1);
NodeProperties::ChangeOp(node, simplified()->StringToUpperCaseIntl());
NodeProperties::SetType(node, Type::String());
return Changed(node);
}
#endif // V8_INTL_SUPPORT
// ES #sec-string.fromcharcode
Reduction JSCallReducer::ReduceStringFromCharCode(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() == 3) {
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* input = NodeProperties::GetValueInput(node, 2);
input = effect = graph()->NewNode(
simplified()->SpeculativeToNumber(NumberOperationHint::kNumberOrOddball,
p.feedback()),
input, effect, control);
Node* value =
graph()->NewNode(simplified()->StringFromSingleCharCode(), input);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
return NoChange();
}
// ES #sec-string.fromcodepoint
Reduction JSCallReducer::ReduceStringFromCodePoint(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() == 3) {
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* input = NodeProperties::GetValueInput(node, 2);
input = effect = graph()->NewNode(simplified()->CheckSmi(p.feedback()),
input, effect, control);
input = effect =
graph()->NewNode(simplified()->CheckBounds(p.feedback()), input,
jsgraph()->Constant(0x10FFFF + 1), effect, control);
Node* value = graph()->NewNode(
simplified()->StringFromSingleCodePoint(UnicodeEncoding::UTF32), input);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
return NoChange();
}
Reduction JSCallReducer::ReduceStringPrototypeIterator(Node* node) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = effect =
graph()->NewNode(simplified()->CheckString(p.feedback()),
NodeProperties::GetValueInput(node, 1), effect, control);
Node* iterator = effect =
graph()->NewNode(javascript()->CreateStringIterator(), receiver,
jsgraph()->NoContextConstant(), effect);
ReplaceWithValue(node, iterator, effect, control);
return Replace(iterator);
}
Reduction JSCallReducer::ReduceStringIteratorPrototypeNext(Node* node) {
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
if (NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
JS_STRING_ITERATOR_TYPE)) {
Node* string = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSStringIteratorString()),
receiver, effect, control);
Node* index = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSStringIteratorIndex()),
receiver, effect, control);
Node* length = graph()->NewNode(simplified()->StringLength(), string);
// branch0: if (index < length)
Node* check0 =
graph()->NewNode(simplified()->NumberLessThan(), index, length);
Node* branch0 =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check0, control);
Node* etrue0 = effect;
Node* if_true0 = graph()->NewNode(common()->IfTrue(), branch0);
Node* done_true;
Node* vtrue0;
{
done_true = jsgraph()->FalseConstant();
Node* codepoint = etrue0 = graph()->NewNode(
simplified()->StringCodePointAt(UnicodeEncoding::UTF16), string,
index, etrue0, if_true0);
vtrue0 = graph()->NewNode(
simplified()->StringFromSingleCodePoint(UnicodeEncoding::UTF16),
codepoint);
// Update iterator.[[NextIndex]]
Node* char_length =
graph()->NewNode(simplified()->StringLength(), vtrue0);
index = graph()->NewNode(simplified()->NumberAdd(), index, char_length);
etrue0 = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSStringIteratorIndex()),
receiver, index, etrue0, if_true0);
}
Node* if_false0 = graph()->NewNode(common()->IfFalse(), branch0);
Node* done_false;
Node* vfalse0;
{
vfalse0 = jsgraph()->UndefinedConstant();
done_false = jsgraph()->TrueConstant();
}
control = graph()->NewNode(common()->Merge(2), if_true0, if_false0);
effect = graph()->NewNode(common()->EffectPhi(2), etrue0, effect, control);
Node* value =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
vtrue0, vfalse0, control);
Node* done =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
done_true, done_false, control);
value = effect = graph()->NewNode(javascript()->CreateIterResultObject(),
value, done, context, effect);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
return NoChange();
}
// ES #sec-string.prototype.concat
Reduction JSCallReducer::ReduceStringPrototypeConcat(
Node* node, Handle<SharedFunctionInfo> shared) {
if (node->op()->ValueInputCount() < 2 || node->op()->ValueInputCount() > 3) {
return NoChange();
}
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* receiver = effect =
graph()->NewNode(simplified()->CheckString(p.feedback()),
NodeProperties::GetValueInput(node, 1), effect, control);
if (node->op()->ValueInputCount() < 3) {
ReplaceWithValue(node, receiver, effect, control);
return Replace(receiver);
}
Node* argument = effect =
graph()->NewNode(simplified()->CheckString(p.feedback()),
NodeProperties::GetValueInput(node, 2), effect, control);
Callable const callable =
CodeFactory::StringAdd(isolate(), STRING_ADD_CHECK_NONE, NOT_TENURED);
auto call_descriptor =
Linkage::GetStubCallDescriptor(graph()->zone(), callable.descriptor(), 0,
CallDescriptor::kNeedsFrameState,
Operator::kNoDeopt | Operator::kNoWrite);
// TODO(turbofan): Massage the FrameState of the {node} here once we
// have an artificial builtin frame type, so that it looks like the
// exception from StringAdd overflow came from String.prototype.concat
// builtin instead of the calling function.
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* value = effect = control = graph()->NewNode(
common()->Call(call_descriptor), jsgraph()->HeapConstant(callable.code()),
receiver, argument, context, outer_frame_state, effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
Reduction JSCallReducer::ReduceAsyncFunctionPromiseCreate(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
if (!isolate()->IsPromiseHookProtectorIntact()) return NoChange();
// Install a code dependency on the promise hook protector cell.
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_hook_protector()));
// Morph this {node} into a JSCreatePromise node.
RelaxControls(node);
node->ReplaceInput(0, context);
node->ReplaceInput(1, effect);
node->TrimInputCount(2);
NodeProperties::ChangeOp(node, javascript()->CreatePromise());
return Changed(node);
}
Reduction JSCallReducer::ReduceAsyncFunctionPromiseRelease(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
if (!isolate()->IsPromiseHookProtectorIntact()) return NoChange();
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_hook_protector()));
// The AsyncFunctionPromiseRelease builtin is a no-op as long as neither
// the debugger is active nor any promise hook has been installed (ever).
Node* value = jsgraph()->UndefinedConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* JSCallReducer::CreateArtificialFrameState(
Node* node, Node* outer_frame_state, int parameter_count,
BailoutId bailout_id, FrameStateType frame_state_type,
Handle<SharedFunctionInfo> shared) {
const FrameStateFunctionInfo* state_info =
common()->CreateFrameStateFunctionInfo(frame_state_type,
parameter_count + 1, 0, shared);
const Operator* op = common()->FrameState(
bailout_id, OutputFrameStateCombine::Ignore(), state_info);
const Operator* op0 = common()->StateValues(0, SparseInputMask::Dense());
Node* node0 = graph()->NewNode(op0);
std::vector<Node*> params;
for (int parameter = 0; parameter < parameter_count + 1; ++parameter) {
params.push_back(node->InputAt(1 + parameter));
}
const Operator* op_param = common()->StateValues(
static_cast<int>(params.size()), SparseInputMask::Dense());
Node* params_node = graph()->NewNode(
op_param, static_cast<int>(params.size()), ¶ms.front());
return graph()->NewNode(op, params_node, node0, node0,
jsgraph()->UndefinedConstant(), node->InputAt(0),
outer_frame_state);
}
Reduction JSCallReducer::ReducePromiseConstructor(Node* node) {
DCHECK_EQ(IrOpcode::kJSConstruct, node->opcode());
ConstructParameters const& p = ConstructParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
// We only inline when we have the executor.
if (arity < 1) return NoChange();
Node* target = NodeProperties::GetValueInput(node, 0);
Node* executor = NodeProperties::GetValueInput(node, 1);
Node* new_target = NodeProperties::GetValueInput(node, arity + 1);
Node* context = NodeProperties::GetContextInput(node);
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (!FLAG_experimental_inline_promise_constructor) return NoChange();
if (!isolate()->IsPromiseHookProtectorIntact()) return NoChange();
// Only handle builtins Promises, not subclasses.
if (target != new_target) return NoChange();
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_hook_protector()));
Handle<SharedFunctionInfo> promise_shared(
handle(native_context()->promise_function()->shared(), isolate()));
// Insert a construct stub frame into the chain of frame states. This will
// reconstruct the proper frame when deoptimizing within the constructor.
// For the frame state, we only provide the executor parameter, even if more
// arugments were passed. This is not observable from JS.
DCHECK_EQ(1, promise_shared->internal_formal_parameter_count());
Node* constructor_frame_state = CreateArtificialFrameState(
node, outer_frame_state, 1, BailoutId::ConstructStubInvoke(),
FrameStateType::kConstructStub, promise_shared);
// The deopt continuation of this frame state is never called; the frame state
// is only necessary to obtain the right stack trace.
const std::vector<Node*> checkpoint_parameters({
jsgraph()->UndefinedConstant(), /* receiver */
jsgraph()->UndefinedConstant(), /* promise */
jsgraph()->UndefinedConstant(), /* reject function */
jsgraph()->TheHoleConstant() /* exception */
});
int checkpoint_parameters_size =
static_cast<int>(checkpoint_parameters.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), promise_shared,
Builtins::kPromiseConstructorLazyDeoptContinuation, target, context,
checkpoint_parameters.data(), checkpoint_parameters_size,
constructor_frame_state, ContinuationFrameStateMode::LAZY);
// Check if executor is callable
Node* check_fail = nullptr;
Node* check_throw = nullptr;
WireInCallbackIsCallableCheck(executor, context, frame_state, effect,
&control, &check_fail, &check_throw);
// Create the resulting JSPromise.
Node* promise = effect =
graph()->NewNode(javascript()->CreatePromise(), context, effect);
// 8. CreatePromiseResolvingFunctions
// Allocate a promise context for the closures below.
Node* promise_context = effect =
graph()->NewNode(javascript()->CreateFunctionContext(
handle(native_context()->scope_info(), isolate()),
PromiseBuiltinsAssembler::kPromiseContextLength -
Context::MIN_CONTEXT_SLOTS,
FUNCTION_SCOPE),
context, effect, control);
effect =
graph()->NewNode(simplified()->StoreField(AccessBuilder::ForContextSlot(
PromiseBuiltinsAssembler::kPromiseSlot)),
promise_context, promise, effect, control);
effect = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForContextSlot(
PromiseBuiltinsAssembler::kAlreadyResolvedSlot)),
promise_context, jsgraph()->FalseConstant(), effect, control);
effect = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForContextSlot(
PromiseBuiltinsAssembler::kDebugEventSlot)),
promise_context, jsgraph()->TrueConstant(), effect, control);
// Allocate the closure for the resolve case.
Handle<SharedFunctionInfo> resolve_shared(
native_context()->promise_capability_default_resolve_shared_fun(),
isolate());
Node* resolve = effect =
graph()->NewNode(javascript()->CreateClosure(
resolve_shared, factory()->many_closures_cell(),
handle(resolve_shared->GetCode(), isolate())),
promise_context, effect, control);
// Allocate the closure for the reject case.
Handle<SharedFunctionInfo> reject_shared(
native_context()->promise_capability_default_reject_shared_fun(),
isolate());
Node* reject = effect =
graph()->NewNode(javascript()->CreateClosure(
reject_shared, factory()->many_closures_cell(),
handle(reject_shared->GetCode(), isolate())),
promise_context, effect, control);
const std::vector<Node*> checkpoint_parameters_continuation(
{jsgraph()->UndefinedConstant() /* receiver */, promise, reject});
int checkpoint_parameters_continuation_size =
static_cast<int>(checkpoint_parameters_continuation.size());
// This continuation just returns the created promise and takes care of
// exceptions thrown by the executor.
frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), promise_shared,
Builtins::kPromiseConstructorLazyDeoptContinuation, target, context,
checkpoint_parameters_continuation.data(),
checkpoint_parameters_continuation_size, constructor_frame_state,
ContinuationFrameStateMode::LAZY_WITH_CATCH);
// 9. Call executor with both resolving functions
effect = control = graph()->NewNode(
javascript()->Call(4, p.frequency(), VectorSlotPair(),
ConvertReceiverMode::kNullOrUndefined,
SpeculationMode::kDisallowSpeculation),
executor, jsgraph()->UndefinedConstant(), resolve, reject, context,
frame_state, effect, control);
Node* exception_effect = effect;
Node* exception_control = control;
{
Node* reason = exception_effect = exception_control = graph()->NewNode(
common()->IfException(), exception_control, exception_effect);
// 10a. Call reject if the call to executor threw.
exception_effect = exception_control = graph()->NewNode(
javascript()->Call(3, p.frequency(), VectorSlotPair(),
ConvertReceiverMode::kNullOrUndefined,
SpeculationMode::kDisallowSpeculation),
reject, jsgraph()->UndefinedConstant(), reason, context, frame_state,
exception_effect, exception_control);
// Rewire potential exception edges.
Node* on_exception = nullptr;
if (NodeProperties::IsExceptionalCall(node, &on_exception)) {
RewirePostCallbackExceptionEdges(check_throw, on_exception,
exception_effect, &check_fail,
&exception_control);
}
}
Node* success_effect = effect;
Node* success_control = control;
{
success_control = graph()->NewNode(common()->IfSuccess(), success_control);
}
control =
graph()->NewNode(common()->Merge(2), success_control, exception_control);
effect = graph()->NewNode(common()->EffectPhi(2), success_effect,
exception_effect, control);
// Wire up the branch for the case when IsCallable fails for the executor.
// Since {check_throw} is an unconditional throw, it's impossible to
// return a successful completion. Therefore, we simply connect the successful
// completion to the graph end.
Node* throw_node =
graph()->NewNode(common()->Throw(), check_throw, check_fail);
NodeProperties::MergeControlToEnd(graph(), common(), throw_node);
ReplaceWithValue(node, promise, effect, control);
return Replace(promise);
}
// V8 Extras: v8.createPromise(parent)
Reduction JSCallReducer::ReducePromiseInternalConstructor(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
// Check that promises aren't being observed through (debug) hooks.
if (!isolate()->IsPromiseHookProtectorIntact()) return NoChange();
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_hook_protector()));
// Create a new pending promise.
Node* value = effect =
graph()->NewNode(javascript()->CreatePromise(), context, effect);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
// V8 Extras: v8.rejectPromise(promise, reason)
Reduction JSCallReducer::ReducePromiseInternalReject(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* promise = node->op()->ValueInputCount() >= 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* reason = node->op()->ValueInputCount() >= 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
Node* debug_event = jsgraph()->TrueConstant();
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Reject the {promise} using the given {reason}, and trigger debug logic.
Node* value = effect =
graph()->NewNode(javascript()->RejectPromise(), promise, reason,
debug_event, context, frame_state, effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// V8 Extras: v8.resolvePromise(promise, resolution)
Reduction JSCallReducer::ReducePromiseInternalResolve(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* promise = node->op()->ValueInputCount() >= 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* resolution = node->op()->ValueInputCount() >= 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Resolve the {promise} using the given {resolution}.
Node* value = effect =
graph()->NewNode(javascript()->ResolvePromise(), promise, resolution,
context, frame_state, effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES section #sec-promise.prototype.catch
Reduction JSCallReducer::ReducePromisePrototypeCatch(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
int arity = static_cast<int>(p.arity() - 2);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Check that the Promise.then protector is intact. This protector guards
// that all JSPromise instances whose [[Prototype]] is the initial
// %PromisePrototype% yield the initial %PromisePrototype%.then method
// when looking up "then".
if (!isolate()->IsPromiseThenLookupChainIntact()) return NoChange();
// Check if we know something about {receiver} already.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
// Check whether all {receiver_maps} are JSPromise maps and
// have the initial Promise.prototype as their [[Prototype]].
for (Handle<Map> receiver_map : receiver_maps) {
if (!receiver_map->IsJSPromiseMap()) return NoChange();
if (receiver_map->prototype() != native_context()->promise_prototype()) {
return NoChange();
}
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_then_protector()));
// If the {receiver_maps} aren't reliable, we need to repeat the
// map check here, guarded by the CALL_IC.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Massage the {node} to call "then" instead by first removing all inputs
// following the onRejected parameter, and then filling up the parameters
// to two inputs from the left with undefined.
Node* target =
jsgraph()->Constant(handle(native_context()->promise_then(), isolate()));
NodeProperties::ReplaceValueInput(node, target, 0);
NodeProperties::ReplaceEffectInput(node, effect);
for (; arity > 1; --arity) node->RemoveInput(3);
for (; arity < 2; ++arity) {
node->InsertInput(graph()->zone(), 2, jsgraph()->UndefinedConstant());
}
NodeProperties::ChangeOp(
node, javascript()->Call(2 + arity, p.frequency(), p.feedback(),
ConvertReceiverMode::kNotNullOrUndefined,
p.speculation_mode()));
Reduction const reduction = ReducePromisePrototypeThen(node);
return reduction.Changed() ? reduction : Changed(node);
}
// ES section #sec-promise.prototype.finally
Reduction JSCallReducer::ReducePromisePrototypeFinally(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* on_finally = arity >= 1 ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
// Check that promises aren't being observed through (debug) hooks.
if (!isolate()->IsPromiseHookProtectorIntact()) return NoChange();
// Check that the Promise#then protector is intact. This protector guards
// that all JSPromise instances whose [[Prototype]] is the initial
// %PromisePrototype% yield the initial %PromisePrototype%.then method
// when looking up "then".
if (!isolate()->IsPromiseThenLookupChainIntact()) return NoChange();
// Also check that the @@species protector is intact, which guards the
// lookup of "constructor" on JSPromise instances, whoch [[Prototype]] is
// the initial %PromisePrototype%, and the Symbol.species lookup on the
// %PromisePrototype%.
if (!isolate()->IsPromiseSpeciesLookupChainIntact()) return NoChange();
// Check if we know something about {receiver} already.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
// Check whether all {receiver_maps} are JSPromise maps and
// have the initial Promise.prototype as their [[Prototype]].
for (Handle<Map> receiver_map : receiver_maps) {
if (!receiver_map->IsJSPromiseMap()) return NoChange();
if (receiver_map->prototype() != native_context()->promise_prototype()) {
return NoChange();
}
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_hook_protector()));
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_then_protector()));
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->promise_species_protector()));
// If the {receiver_maps} aren't reliable, we need to repeat the
// map check here, guarded by the CALL_IC.
if (result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Check if {on_finally} is callable, and if so wrap it into appropriate
// closures that perform the finalization.
Node* check = graph()->NewNode(simplified()->ObjectIsCallable(), on_finally);
Node* branch =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* catch_true;
Node* then_true;
{
Node* context = jsgraph()->HeapConstant(native_context());
Node* constructor = jsgraph()->HeapConstant(
handle(native_context()->promise_function(), isolate()));
// Allocate shared context for the closures below.
context = etrue = graph()->NewNode(
javascript()->CreateFunctionContext(
handle(native_context()->scope_info(), isolate()),
PromiseBuiltinsAssembler::kPromiseFinallyContextLength -
Context::MIN_CONTEXT_SLOTS,
FUNCTION_SCOPE),
context, etrue, if_true);
etrue =
graph()->NewNode(simplified()->StoreField(AccessBuilder::ForContextSlot(
PromiseBuiltinsAssembler::kOnFinallySlot)),
context, on_finally, etrue, if_true);
etrue =
graph()->NewNode(simplified()->StoreField(AccessBuilder::ForContextSlot(
PromiseBuiltinsAssembler::kConstructorSlot)),
context, constructor, etrue, if_true);
// Allocate the closure for the reject case.
Handle<SharedFunctionInfo> catch_finally(
native_context()->promise_catch_finally_shared_fun(), isolate());
catch_true = etrue =
graph()->NewNode(javascript()->CreateClosure(
catch_finally, factory()->many_closures_cell(),
handle(catch_finally->GetCode(), isolate())),
context, etrue, if_true);
// Allocate the closure for the fulfill case.
Handle<SharedFunctionInfo> then_finally(
native_context()->promise_then_finally_shared_fun(), isolate());
then_true = etrue =
graph()->NewNode(javascript()->CreateClosure(
then_finally, factory()->many_closures_cell(),
handle(then_finally->GetCode(), isolate())),
context, etrue, if_true);
}
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* catch_false = on_finally;
Node* then_false = on_finally;
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
Node* catch_finally =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
catch_true, catch_false, control);
Node* then_finally =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, 2),
then_true, then_false, control);
// At this point we definitely know that {receiver} has one of the
// {receiver_maps}, so insert a MapGuard as a hint for the lowering
// of the call to "then" below.
effect = graph()->NewNode(simplified()->MapGuard(receiver_maps), receiver,
effect, control);
// Massage the {node} to call "then" instead by first removing all inputs
// following the onFinally parameter, and then replacing the only parameter
// input with the {on_finally} value.
Node* target =
jsgraph()->Constant(handle(native_context()->promise_then(), isolate()));
NodeProperties::ReplaceValueInput(node, target, 0);
NodeProperties::ReplaceEffectInput(node, effect);
NodeProperties::ReplaceControlInput(node, control);
for (; arity > 2; --arity) node->RemoveInput(2);
for (; arity < 2; ++arity)
node->InsertInput(graph()->zone(), 2, then_finally);
node->ReplaceInput(2, then_finally);
node->ReplaceInput(3, catch_finally);
NodeProperties::ChangeOp(
node, javascript()->Call(2 + arity, p.frequency(), p.feedback(),
ConvertReceiverMode::kNotNullOrUndefined,
p.speculation_mode()));
Reduction const reduction = ReducePromisePrototypeThen(node);
return reduction.Changed() ? reduction : Changed(node);
}
Reduction JSCallReducer::ReducePromisePrototypeThen(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* on_fulfilled = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* on_rejected = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
// Check that promises aren't being observed through (debug) hooks.
if (!isolate()->IsPromiseHookProtectorIntact()) return NoChange();
// Check if the @@species protector is intact. The @@species protector
// guards the "constructor" lookup on all JSPromise instances and the
// initial Promise.prototype, as well as the Symbol.species lookup on
// the Promise constructor.
if (!isolate()->IsPromiseSpeciesLookupChainIntact()) return NoChange();
// Check if we know something about {receiver} already.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult infer_receiver_maps_result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (infer_receiver_maps_result == NodeProperties::kNoReceiverMaps) {
return NoChange();
}
DCHECK_NE(0, receiver_maps.size());
// Check whether all {receiver_maps} are JSPromise maps and
// have the initial Promise.prototype as their [[Prototype]].
for (Handle<Map> receiver_map : receiver_maps) {
if (!receiver_map->IsJSPromiseMap()) return NoChange();
if (receiver_map->prototype() != native_context()->promise_prototype()) {
return NoChange();
}
}
dependencies()->DependOnProtector(
PropertyCellRef(js_heap_broker(), factory()->promise_hook_protector()));
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->promise_species_protector()));
// If the {receiver_maps} aren't reliable, we need to repeat the
// map check here, guarded by the CALL_IC.
if (infer_receiver_maps_result == NodeProperties::kUnreliableReceiverMaps) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
receiver_maps, p.feedback()),
receiver, effect, control);
}
// Check that {on_fulfilled} is callable.
on_fulfilled = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kTrue),
graph()->NewNode(simplified()->ObjectIsCallable(), on_fulfilled),
on_fulfilled, jsgraph()->UndefinedConstant());
// Check that {on_rejected} is callable.
on_rejected = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kTrue),
graph()->NewNode(simplified()->ObjectIsCallable(), on_rejected),
on_rejected, jsgraph()->UndefinedConstant());
// Create the resulting JSPromise.
Node* result = effect =
graph()->NewNode(javascript()->CreatePromise(), context, effect);
// Chain {result} onto {receiver}.
result = effect = graph()->NewNode(
javascript()->PerformPromiseThen(), receiver, on_fulfilled, on_rejected,
result, context, frame_state, effect, control);
ReplaceWithValue(node, result, effect, control);
return Replace(result);
}
// ES section #sec-promise.resolve
Reduction JSCallReducer::ReducePromiseResolveTrampoline(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* value = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Check if we know something about {receiver} already.
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult infer_receiver_maps_result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (infer_receiver_maps_result == NodeProperties::kNoReceiverMaps) {
return NoChange();
}
DCHECK_NE(0, receiver_maps.size());
// Only reduce when all {receiver_maps} are JSReceiver maps.
for (Handle<Map> receiver_map : receiver_maps) {
if (!receiver_map->IsJSReceiverMap()) return NoChange();
}
// Morph the {node} into a JSPromiseResolve operation.
node->ReplaceInput(0, receiver);
node->ReplaceInput(1, value);
node->ReplaceInput(2, context);
node->ReplaceInput(3, frame_state);
node->ReplaceInput(4, effect);
node->ReplaceInput(5, control);
node->TrimInputCount(6);
NodeProperties::ChangeOp(node, javascript()->PromiseResolve());
return Changed(node);
}
// ES #sec-typedarray-constructors
Reduction JSCallReducer::ReduceTypedArrayConstructor(
Node* node, Handle<SharedFunctionInfo> shared) {
DCHECK_EQ(IrOpcode::kJSConstruct, node->opcode());
ConstructParameters const& p = ConstructParametersOf(node->op());
int arity = static_cast<int>(p.arity() - 2);
Node* target = NodeProperties::GetValueInput(node, 0);
Node* arg1 = (arity >= 1) ? NodeProperties::GetValueInput(node, 1)
: jsgraph()->UndefinedConstant();
Node* arg2 = (arity >= 2) ? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
Node* arg3 = (arity >= 3) ? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
Node* new_target = NodeProperties::GetValueInput(node, arity + 1);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// Insert a construct stub frame into the chain of frame states. This will
// reconstruct the proper frame when deoptimizing within the constructor.
frame_state = CreateArtificialFrameState(
node, frame_state, arity, BailoutId::ConstructStubInvoke(),
FrameStateType::kConstructStub, shared);
// This continuation just returns the newly created JSTypedArray. We
// pass the_hole as the receiver, just like the builtin construct stub
// does in this case.
Node* const parameters[] = {jsgraph()->TheHoleConstant()};
int const num_parameters = static_cast<int>(arraysize(parameters));
frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), shared, Builtins::kGenericConstructorLazyDeoptContinuation,
target, context, parameters, num_parameters, frame_state,
ContinuationFrameStateMode::LAZY);
Node* result =
graph()->NewNode(javascript()->CreateTypedArray(), target, new_target,
arg1, arg2, arg3, context, frame_state, effect, control);
return Replace(result);
}
// ES #sec-get-%typedarray%.prototype-@@tostringtag
Reduction JSCallReducer::ReduceTypedArrayPrototypeToStringTag(Node* node) {
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
NodeVector values(graph()->zone());
NodeVector effects(graph()->zone());
NodeVector controls(graph()->zone());
Node* check = graph()->NewNode(simplified()->ObjectIsSmi(), receiver);
control =
graph()->NewNode(common()->Branch(BranchHint::kFalse), check, control);
values.push_back(jsgraph()->UndefinedConstant());
effects.push_back(effect);
controls.push_back(graph()->NewNode(common()->IfTrue(), control));
control = graph()->NewNode(common()->IfFalse(), control);
Node* receiver_map = effect =
graph()->NewNode(simplified()->LoadField(AccessBuilder::ForMap()),
receiver, effect, control);
Node* receiver_bit_field2 = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForMapBitField2()), receiver_map,
effect, control);
Node* receiver_elements_kind = graph()->NewNode(
simplified()->NumberShiftRightLogical(),
graph()->NewNode(simplified()->NumberBitwiseAnd(), receiver_bit_field2,
jsgraph()->Constant(Map::ElementsKindBits::kMask)),
jsgraph()->Constant(Map::ElementsKindBits::kShift));
// Offset the elements kind by FIRST_FIXED_TYPED_ARRAY_ELEMENTS_KIND,
// so that the branch cascade below is turned into a simple table
// switch by the ControlFlowOptimizer later.
receiver_elements_kind = graph()->NewNode(
simplified()->NumberSubtract(), receiver_elements_kind,
jsgraph()->Constant(FIRST_FIXED_TYPED_ARRAY_ELEMENTS_KIND));
#define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) \
do { \
Node* check = graph()->NewNode( \
simplified()->NumberEqual(), receiver_elements_kind, \
jsgraph()->Constant(TYPE##_ELEMENTS - \
FIRST_FIXED_TYPED_ARRAY_ELEMENTS_KIND)); \
control = graph()->NewNode(common()->Branch(), check, control); \
values.push_back(jsgraph()->HeapConstant( \
factory()->InternalizeUtf8String(#Type "Array"))); \
effects.push_back(effect); \
controls.push_back(graph()->NewNode(common()->IfTrue(), control)); \
control = graph()->NewNode(common()->IfFalse(), control); \
} while (false);
TYPED_ARRAYS(TYPED_ARRAY_CASE)
#undef TYPED_ARRAY_CASE
values.push_back(jsgraph()->UndefinedConstant());
effects.push_back(effect);
controls.push_back(control);
int const count = static_cast<int>(controls.size());
control = graph()->NewNode(common()->Merge(count), count, &controls.front());
effects.push_back(control);
effect =
graph()->NewNode(common()->EffectPhi(count), count + 1, &effects.front());
values.push_back(control);
Node* value =
graph()->NewNode(common()->Phi(MachineRepresentation::kTagged, count),
count + 1, &values.front());
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES #sec-number.isfinite
Reduction JSCallReducer::ReduceNumberIsFinite(Node* node) {
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->FalseConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* input = NodeProperties::GetValueInput(node, 2);
Node* value = graph()->NewNode(simplified()->ObjectIsFiniteNumber(), input);
ReplaceWithValue(node, value);
return Replace(value);
}
// ES #sec-number.isfinite
Reduction JSCallReducer::ReduceNumberIsInteger(Node* node) {
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->FalseConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* input = NodeProperties::GetValueInput(node, 2);
Node* value = graph()->NewNode(simplified()->ObjectIsInteger(), input);
ReplaceWithValue(node, value);
return Replace(value);
}
// ES #sec-number.issafeinteger
Reduction JSCallReducer::ReduceNumberIsSafeInteger(Node* node) {
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->FalseConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* input = NodeProperties::GetValueInput(node, 2);
Node* value = graph()->NewNode(simplified()->ObjectIsSafeInteger(), input);
ReplaceWithValue(node, value);
return Replace(value);
}
// ES #sec-number.isnan
Reduction JSCallReducer::ReduceNumberIsNaN(Node* node) {
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->FalseConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* input = NodeProperties::GetValueInput(node, 2);
Node* value = graph()->NewNode(simplified()->ObjectIsNaN(), input);
ReplaceWithValue(node, value);
return Replace(value);
}
Reduction JSCallReducer::ReduceMapPrototypeGet(Node* node) {
// We only optimize if we have target, receiver and key parameters.
if (node->op()->ValueInputCount() != 3) return NoChange();
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* key = NodeProperties::GetValueInput(node, 2);
if (!NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
JS_MAP_TYPE))
return NoChange();
Node* table = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionTable()), receiver,
effect, control);
Node* entry = effect = graph()->NewNode(
simplified()->FindOrderedHashMapEntry(), table, key, effect, control);
Node* check = graph()->NewNode(simplified()->NumberEqual(), entry,
jsgraph()->MinusOneConstant());
Node* branch = graph()->NewNode(common()->Branch(), check, control);
// Key not found.
Node* if_true = graph()->NewNode(common()->IfTrue(), branch);
Node* etrue = effect;
Node* vtrue = jsgraph()->UndefinedConstant();
// Key found.
Node* if_false = graph()->NewNode(common()->IfFalse(), branch);
Node* efalse = effect;
Node* vfalse = efalse = graph()->NewNode(
simplified()->LoadElement(AccessBuilder::ForOrderedHashMapEntryValue()),
table, entry, efalse, if_false);
control = graph()->NewNode(common()->Merge(2), if_true, if_false);
Node* value = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2), vtrue, vfalse, control);
effect = graph()->NewNode(common()->EffectPhi(2), etrue, efalse, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
Reduction JSCallReducer::ReduceMapPrototypeHas(Node* node) {
// We only optimize if we have target, receiver and key parameters.
if (node->op()->ValueInputCount() != 3) return NoChange();
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* key = NodeProperties::GetValueInput(node, 2);
if (!NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
JS_MAP_TYPE))
return NoChange();
Node* table = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionTable()), receiver,
effect, control);
Node* index = effect = graph()->NewNode(
simplified()->FindOrderedHashMapEntry(), table, key, effect, control);
Node* value = graph()->NewNode(simplified()->NumberEqual(), index,
jsgraph()->MinusOneConstant());
value = graph()->NewNode(simplified()->BooleanNot(), value);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
namespace {
InstanceType InstanceTypeForCollectionKind(CollectionKind kind) {
switch (kind) {
case CollectionKind::kMap:
return JS_MAP_TYPE;
case CollectionKind::kSet:
return JS_SET_TYPE;
}
UNREACHABLE();
}
} // namespace
Reduction JSCallReducer::ReduceCollectionIteration(
Node* node, CollectionKind collection_kind, IterationKind iteration_kind) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (NodeProperties::HasInstanceTypeWitness(
isolate(), receiver, effect,
InstanceTypeForCollectionKind(collection_kind))) {
Node* js_create_iterator = effect = graph()->NewNode(
javascript()->CreateCollectionIterator(collection_kind, iteration_kind),
receiver, context, effect, control);
ReplaceWithValue(node, js_create_iterator, effect);
return Replace(js_create_iterator);
}
return NoChange();
}
Reduction JSCallReducer::ReduceCollectionPrototypeSize(
Node* node, CollectionKind collection_kind) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (NodeProperties::HasInstanceTypeWitness(
isolate(), receiver, effect,
InstanceTypeForCollectionKind(collection_kind))) {
Node* table = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionTable()),
receiver, effect, control);
Node* value = effect = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForOrderedHashTableBaseNumberOfElements()),
table, effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
return NoChange();
}
Reduction JSCallReducer::ReduceCollectionIteratorPrototypeNext(
Node* node, int entry_size, Handle<HeapObject> empty_collection,
InstanceType collection_iterator_instance_type_first,
InstanceType collection_iterator_instance_type_last) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* context = NodeProperties::GetContextInput(node);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
// A word of warning to begin with: This whole method might look a bit
// strange at times, but that's mostly because it was carefully handcrafted
// to allow for full escape analysis and scalar replacement of both the
// collection iterator object and the iterator results, including the
// key-value arrays in case of Set/Map entry iteration.
//
// TODO(turbofan): Currently the escape analysis (and the store-load
// forwarding) is unable to eliminate the allocations for the key-value
// arrays in case of Set/Map entry iteration, and we should investigate
// how to update the escape analysis / arrange the graph in a way that
// this becomes possible.
// Infer the {receiver} instance type.
InstanceType receiver_instance_type;
ZoneHandleSet<Map> receiver_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), receiver, effect,
&receiver_maps);
if (result == NodeProperties::kNoReceiverMaps) return NoChange();
DCHECK_NE(0, receiver_maps.size());
receiver_instance_type = receiver_maps[0]->instance_type();
for (size_t i = 1; i < receiver_maps.size(); ++i) {
if (receiver_maps[i]->instance_type() != receiver_instance_type) {
return NoChange();
}
}
if (receiver_instance_type < collection_iterator_instance_type_first ||
receiver_instance_type > collection_iterator_instance_type_last) {
return NoChange();
}
// Transition the JSCollectionIterator {receiver} if necessary
// (i.e. there were certain mutations while we're iterating).
{
Node* done_loop;
Node* done_eloop;
Node* loop = control =
graph()->NewNode(common()->Loop(2), control, control);
Node* eloop = effect =
graph()->NewNode(common()->EffectPhi(2), effect, effect, loop);
Node* terminate = graph()->NewNode(common()->Terminate(), eloop, loop);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
// Check if reached the final table of the {receiver}.
Node* table = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionIteratorTable()),
receiver, effect, control);
Node* next_table = effect =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForOrderedHashTableBaseNextTable()),
table, effect, control);
Node* check = graph()->NewNode(simplified()->ObjectIsSmi(), next_table);
control =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check, control);
// Abort the {loop} when we reach the final table.
done_loop = graph()->NewNode(common()->IfTrue(), control);
done_eloop = effect;
// Migrate to the {next_table} otherwise.
control = graph()->NewNode(common()->IfFalse(), control);
// Self-heal the {receiver}s index.
Node* index = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionIteratorIndex()),
receiver, effect, control);
Callable const callable =
Builtins::CallableFor(isolate(), Builtins::kOrderedHashTableHealIndex);
auto call_descriptor = Linkage::GetStubCallDescriptor(
graph()->zone(), callable.descriptor(), 0, CallDescriptor::kNoFlags,
Operator::kEliminatable);
index = effect =
graph()->NewNode(common()->Call(call_descriptor),
jsgraph()->HeapConstant(callable.code()), table, index,
jsgraph()->NoContextConstant(), effect);
index = effect = graph()->NewNode(
common()->TypeGuard(TypeCache::Get().kFixedArrayLengthType), index,
effect, control);
// Update the {index} and {table} on the {receiver}.
effect = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSCollectionIteratorIndex()),
receiver, index, effect, control);
effect = graph()->NewNode(
simplified()->StoreField(AccessBuilder::ForJSCollectionIteratorTable()),
receiver, next_table, effect, control);
// Tie the knot.
loop->ReplaceInput(1, control);
eloop->ReplaceInput(1, effect);
control = done_loop;
effect = done_eloop;
}
// Get current index and table from the JSCollectionIterator {receiver}.
Node* index = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionIteratorIndex()),
receiver, effect, control);
Node* table = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSCollectionIteratorTable()),
receiver, effect, control);
// Create the {JSIteratorResult} first to ensure that we always have
// a dominating Allocate node for the allocation folding phase.
Node* iterator_result = effect = graph()->NewNode(
javascript()->CreateIterResultObject(), jsgraph()->UndefinedConstant(),
jsgraph()->TrueConstant(), context, effect);
// Look for the next non-holey key, starting from {index} in the {table}.
Node* controls[2];
Node* effects[3];
{
// Compute the currently used capacity.
Node* number_of_buckets = effect = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForOrderedHashTableBaseNumberOfBuckets()),
table, effect, control);
Node* number_of_elements = effect = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForOrderedHashTableBaseNumberOfElements()),
table, effect, control);
Node* number_of_deleted_elements = effect = graph()->NewNode(
simplified()->LoadField(
AccessBuilder::ForOrderedHashTableBaseNumberOfDeletedElements()),
table, effect, control);
Node* used_capacity =
graph()->NewNode(simplified()->NumberAdd(), number_of_elements,
number_of_deleted_elements);
// Skip holes and update the {index}.
Node* loop = graph()->NewNode(common()->Loop(2), control, control);
Node* eloop =
graph()->NewNode(common()->EffectPhi(2), effect, effect, loop);
Node* terminate = graph()->NewNode(common()->Terminate(), eloop, loop);
NodeProperties::MergeControlToEnd(graph(), common(), terminate);
Node* iloop = graph()->NewNode(
common()->Phi(MachineRepresentation::kTagged, 2), index, index, loop);
Node* index = effect = graph()->NewNode(
common()->TypeGuard(TypeCache::Get().kFixedArrayLengthType), iloop,
eloop, control);
{
Node* check0 = graph()->NewNode(simplified()->NumberLessThan(), index,
used_capacity);
Node* branch0 =
graph()->NewNode(common()->Branch(BranchHint::kTrue), check0, loop);
Node* if_false0 = graph()->NewNode(common()->IfFalse(), branch0);
Node* efalse0 = effect;
{
// Mark the {receiver} as exhausted.
efalse0 = graph()->NewNode(
simplified()->StoreField(
AccessBuilder::ForJSCollectionIteratorTable()),
receiver, jsgraph()->HeapConstant(empty_collection), efalse0,
if_false0);
controls[0] = if_false0;
effects[0] = efalse0;
}
Node* if_true0 = graph()->NewNode(common()->IfTrue(), branch0);
Node* etrue0 = effect;
{
// Load the key of the entry.
Node* entry_start_position = graph()->NewNode(
simplified()->NumberAdd(),
graph()->NewNode(
simplified()->NumberAdd(),
graph()->NewNode(simplified()->NumberMultiply(), index,
jsgraph()->Constant(entry_size)),
number_of_buckets),
jsgraph()->Constant(OrderedHashTableBase::kHashTableStartIndex));
Node* entry_key = etrue0 = graph()->NewNode(
simplified()->LoadElement(AccessBuilder::ForFixedArrayElement()),
table, entry_start_position, etrue0, if_true0);
// Advance the index.
index = graph()->NewNode(simplified()->NumberAdd(), index,
jsgraph()->OneConstant());
Node* check1 =
graph()->NewNode(simplified()->ReferenceEqual(), entry_key,
jsgraph()->TheHoleConstant());
Node* branch1 = graph()->NewNode(common()->Branch(BranchHint::kFalse),
check1, if_true0);
{
// Abort loop with resulting value.
Node* control = graph()->NewNode(common()->IfFalse(), branch1);
Node* effect = etrue0;
Node* value = effect =
graph()->NewNode(common()->TypeGuard(Type::NonInternal()),
entry_key, effect, control);
Node* done = jsgraph()->FalseConstant();
// Advance the index on the {receiver}.
effect = graph()->NewNode(
simplified()->StoreField(
AccessBuilder::ForJSCollectionIteratorIndex()),
receiver, index, effect, control);
// The actual {value} depends on the {receiver} iteration type.
switch (receiver_instance_type) {
case JS_MAP_KEY_ITERATOR_TYPE:
case JS_SET_VALUE_ITERATOR_TYPE:
break;
case JS_SET_KEY_VALUE_ITERATOR_TYPE:
value = effect =
graph()->NewNode(javascript()->CreateKeyValueArray(), value,
value, context, effect);
break;
case JS_MAP_VALUE_ITERATOR_TYPE:
value = effect = graph()->NewNode(
simplified()->LoadElement(
AccessBuilder::ForFixedArrayElement()),
table,
graph()->NewNode(
simplified()->NumberAdd(), entry_start_position,
jsgraph()->Constant(OrderedHashMap::kValueOffset)),
effect, control);
break;
case JS_MAP_KEY_VALUE_ITERATOR_TYPE:
value = effect = graph()->NewNode(
simplified()->LoadElement(
AccessBuilder::ForFixedArrayElement()),
table,
graph()->NewNode(
simplified()->NumberAdd(), entry_start_position,
jsgraph()->Constant(OrderedHashMap::kValueOffset)),
effect, control);
value = effect =
graph()->NewNode(javascript()->CreateKeyValueArray(),
entry_key, value, context, effect);
break;
default:
UNREACHABLE();
break;
}
// Store final {value} and {done} into the {iterator_result}.
effect =
graph()->NewNode(simplified()->StoreField(
AccessBuilder::ForJSIteratorResultValue()),
iterator_result, value, effect, control);
effect =
graph()->NewNode(simplified()->StoreField(
AccessBuilder::ForJSIteratorResultDone()),
iterator_result, done, effect, control);
controls[1] = control;
effects[1] = effect;
}
// Continue with next loop index.
loop->ReplaceInput(1, graph()->NewNode(common()->IfTrue(), branch1));
eloop->ReplaceInput(1, etrue0);
iloop->ReplaceInput(1, index);
}
}
control = effects[2] = graph()->NewNode(common()->Merge(2), 2, controls);
effect = graph()->NewNode(common()->EffectPhi(2), 3, effects);
}
// Yield the final {iterator_result}.
ReplaceWithValue(node, iterator_result, effect, control);
return Replace(iterator_result);
}
Reduction JSCallReducer::ReduceArrayBufferIsView(Node* node) {
Node* value = node->op()->ValueInputCount() >= 3
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->UndefinedConstant();
RelaxEffectsAndControls(node);
node->ReplaceInput(0, value);
node->TrimInputCount(1);
NodeProperties::ChangeOp(node, simplified()->ObjectIsArrayBufferView());
return Changed(node);
}
Reduction JSCallReducer::ReduceArrayBufferViewAccessor(
Node* node, InstanceType instance_type, FieldAccess const& access) {
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
instance_type)) {
// Load the {receiver}s field.
Node* value = effect = graph()->NewNode(simplified()->LoadField(access),
receiver, effect, control);
// See if we can skip the neutering check.
if (isolate()->IsArrayBufferNeuteringIntact()) {
// Add a code dependency so we are deoptimized in case an ArrayBuffer
// gets neutered.
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->array_buffer_neutering_protector()));
} else {
// Check if the {receiver}s buffer was neutered.
Node* buffer = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayBufferViewBuffer()),
receiver, effect, control);
Node* check = effect = graph()->NewNode(
simplified()->ArrayBufferWasNeutered(), buffer, effect, control);
// Default to zero if the {receiver}s buffer was neutered.
value = graph()->NewNode(
common()->Select(MachineRepresentation::kTagged, BranchHint::kFalse),
check, jsgraph()->ZeroConstant(), value);
}
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
return NoChange();
}
namespace {
uint32_t ExternalArrayElementSize(const ExternalArrayType element_type) {
switch (element_type) {
#define TYPED_ARRAY_CASE(Type, type, TYPE, ctype) \
case kExternal##Type##Array: \
DCHECK_LE(sizeof(ctype), 8); \
return sizeof(ctype);
TYPED_ARRAYS(TYPED_ARRAY_CASE)
default:
UNREACHABLE();
#undef TYPED_ARRAY_CASE
}
}
} // namespace
Reduction JSCallReducer::ReduceDataViewPrototypeGet(
Node* node, ExternalArrayType element_type) {
uint32_t const element_size = ExternalArrayElementSize(element_type);
CallParameters const& p = CallParametersOf(node->op());
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = NodeProperties::GetValueInput(node, 1);
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* offset = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->ZeroConstant();
Node* is_little_endian = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->FalseConstant();
// Only do stuff if the {receiver} is really a DataView.
if (NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
JS_DATA_VIEW_TYPE)) {
// Check that the {offset} is within range for the {receiver}.
HeapObjectMatcher m(receiver);
if (m.HasValue()) {
// We only deal with DataViews here whose [[ByteLength]] is at least
// {element_size} and less than 2^31-{element_size}.
Handle<JSDataView> dataview = Handle<JSDataView>::cast(m.Value());
if (dataview->byte_length()->Number() < element_size ||
dataview->byte_length()->Number() - element_size > kMaxInt) {
return NoChange();
}
// The {receiver}s [[ByteOffset]] must be within Unsigned31 range.
if (dataview->byte_offset()->Number() > kMaxInt) {
return NoChange();
}
// Check that the {offset} is within range of the {byte_length}.
Node* byte_length = jsgraph()->Constant(
dataview->byte_length()->Number() - (element_size - 1));
offset = effect =
graph()->NewNode(simplified()->CheckBounds(p.feedback()), offset,
byte_length, effect, control);
// Add the [[ByteOffset]] to compute the effective offset.
Node* byte_offset =
jsgraph()->Constant(dataview->byte_offset()->Number());
offset = graph()->NewNode(simplified()->NumberAdd(), offset, byte_offset);
} else {
// We only deal with DataViews here that have Smi [[ByteLength]]s.
Node* byte_length = effect =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForJSArrayBufferViewByteLength()),
receiver, effect, control);
byte_length = effect = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), byte_length, effect, control);
// Check that the {offset} is within range of the {byte_length}.
offset = effect =
graph()->NewNode(simplified()->CheckBounds(p.feedback()), offset,
byte_length, effect, control);
if (element_size > 0) {
// For non-byte accesses we also need to check that the {offset}
// plus the {element_size}-1 fits within the given {byte_length}.
Node* end_offset =
graph()->NewNode(simplified()->NumberAdd(), offset,
jsgraph()->Constant(element_size - 1));
effect = graph()->NewNode(simplified()->CheckBounds(p.feedback()),
end_offset, byte_length, effect, control);
}
// The {receiver}s [[ByteOffset]] also needs to be a (positive) Smi.
Node* byte_offset = effect =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForJSArrayBufferViewByteOffset()),
receiver, effect, control);
byte_offset = effect = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), byte_offset, effect, control);
// Compute the buffer index at which we'll read.
offset = graph()->NewNode(simplified()->NumberAdd(), offset, byte_offset);
}
// Coerce {is_little_endian} to boolean.
is_little_endian =
graph()->NewNode(simplified()->ToBoolean(), is_little_endian);
// Get the underlying buffer and check that it has not been neutered.
Node* buffer = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayBufferViewBuffer()),
receiver, effect, control);
if (isolate()->IsArrayBufferNeuteringIntact()) {
// Add a code dependency so we are deoptimized in case an ArrayBuffer
// gets neutered.
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->array_buffer_neutering_protector()));
} else {
// If the buffer was neutered, deopt and let the unoptimized code throw.
Node* check_neutered = effect = graph()->NewNode(
simplified()->ArrayBufferWasNeutered(), buffer, effect, control);
check_neutered =
graph()->NewNode(simplified()->BooleanNot(), check_neutered);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kArrayBufferWasNeutered,
p.feedback()),
check_neutered, effect, control);
}
// Get the buffer's backing store.
Node* backing_store = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayBufferBackingStore()),
buffer, effect, control);
// Perform the load.
Node* value = effect = graph()->NewNode(
simplified()->LoadDataViewElement(element_type), buffer, backing_store,
offset, is_little_endian, effect, control);
// Continue on the regular path.
ReplaceWithValue(node, value, effect, control);
return Changed(value);
}
return NoChange();
}
Reduction JSCallReducer::ReduceDataViewPrototypeSet(
Node* node, ExternalArrayType element_type) {
uint32_t const element_size = ExternalArrayElementSize(element_type);
CallParameters const& p = CallParametersOf(node->op());
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* receiver = NodeProperties::GetValueInput(node, 1);
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* offset = node->op()->ValueInputCount() > 2
? NodeProperties::GetValueInput(node, 2)
: jsgraph()->ZeroConstant();
Node* value = node->op()->ValueInputCount() > 3
? NodeProperties::GetValueInput(node, 3)
: jsgraph()->ZeroConstant();
Node* is_little_endian = node->op()->ValueInputCount() > 4
? NodeProperties::GetValueInput(node, 4)
: jsgraph()->FalseConstant();
// Only do stuff if the {receiver} is really a DataView.
if (NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
JS_DATA_VIEW_TYPE)) {
// Check that the {offset} is within range for the {receiver}.
HeapObjectMatcher m(receiver);
if (m.HasValue()) {
// We only deal with DataViews here whose [[ByteLength]] is at least
// {element_size} and less than 2^31-{element_size}.
Handle<JSDataView> dataview = Handle<JSDataView>::cast(m.Value());
if (dataview->byte_length()->Number() < element_size ||
dataview->byte_length()->Number() - element_size > kMaxInt) {
return NoChange();
}
// The {receiver}s [[ByteOffset]] must be within Unsigned31 range.
if (dataview->byte_offset()->Number() > kMaxInt) {
return NoChange();
}
// Check that the {offset} is within range of the {byte_length}.
Node* byte_length = jsgraph()->Constant(
dataview->byte_length()->Number() - (element_size - 1));
offset = effect =
graph()->NewNode(simplified()->CheckBounds(p.feedback()), offset,
byte_length, effect, control);
// Add the [[ByteOffset]] to compute the effective offset.
Node* byte_offset =
jsgraph()->Constant(dataview->byte_offset()->Number());
offset = graph()->NewNode(simplified()->NumberAdd(), offset, byte_offset);
} else {
// We only deal with DataViews here that have Smi [[ByteLength]]s.
Node* byte_length = effect =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForJSArrayBufferViewByteLength()),
receiver, effect, control);
byte_length = effect = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), byte_length, effect, control);
// Check that the {offset} is within range of the {byte_length}.
offset = effect =
graph()->NewNode(simplified()->CheckBounds(p.feedback()), offset,
byte_length, effect, control);
if (element_size > 0) {
// For non-byte accesses we also need to check that the {offset}
// plus the {element_size}-1 fits within the given {byte_length}.
Node* end_offset =
graph()->NewNode(simplified()->NumberAdd(), offset,
jsgraph()->Constant(element_size - 1));
effect = graph()->NewNode(simplified()->CheckBounds(p.feedback()),
end_offset, byte_length, effect, control);
}
// The {receiver}s [[ByteOffset]] also needs to be a (positive) Smi.
Node* byte_offset = effect =
graph()->NewNode(simplified()->LoadField(
AccessBuilder::ForJSArrayBufferViewByteOffset()),
receiver, effect, control);
byte_offset = effect = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), byte_offset, effect, control);
// Compute the buffer index at which we'll read.
offset = graph()->NewNode(simplified()->NumberAdd(), offset, byte_offset);
}
// Coerce {is_little_endian} to boolean.
is_little_endian =
graph()->NewNode(simplified()->ToBoolean(), is_little_endian);
// Coerce {value} to Number.
value = effect = graph()->NewNode(
simplified()->SpeculativeToNumber(NumberOperationHint::kNumberOrOddball,
p.feedback()),
value, effect, control);
// Get the underlying buffer and check that it has not been neutered.
Node* buffer = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayBufferViewBuffer()),
receiver, effect, control);
if (isolate()->IsArrayBufferNeuteringIntact()) {
// Add a code dependency so we are deoptimized in case an ArrayBuffer
// gets neutered.
dependencies()->DependOnProtector(PropertyCellRef(
js_heap_broker(), factory()->array_buffer_neutering_protector()));
} else {
// If the buffer was neutered, deopt and let the unoptimized code throw.
Node* check_neutered = effect = graph()->NewNode(
simplified()->ArrayBufferWasNeutered(), buffer, effect, control);
check_neutered =
graph()->NewNode(simplified()->BooleanNot(), check_neutered);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kArrayBufferWasNeutered,
p.feedback()),
check_neutered, effect, control);
}
// Get the buffer's backing store.
Node* backing_store = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSArrayBufferBackingStore()),
buffer, effect, control);
// Perform the store.
effect = graph()->NewNode(simplified()->StoreDataViewElement(element_type),
buffer, backing_store, offset, value,
is_little_endian, effect, control);
Node* value = jsgraph()->UndefinedConstant();
// Continue on the regular path.
ReplaceWithValue(node, value, effect, control);
return Changed(value);
}
return NoChange();
}
// ES6 section 18.2.2 isFinite ( number )
Reduction JSCallReducer::ReduceGlobalIsFinite(Node* node) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->FalseConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* input = NodeProperties::GetValueInput(node, 2);
input = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
input, effect, control);
Node* value = graph()->NewNode(simplified()->NumberIsFinite(), input);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
// ES6 section 18.2.3 isNaN ( number )
Reduction JSCallReducer::ReduceGlobalIsNaN(Node* node) {
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->TrueConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* input = NodeProperties::GetValueInput(node, 2);
input = effect =
graph()->NewNode(simplified()->SpeculativeToNumber(
NumberOperationHint::kNumberOrOddball, p.feedback()),
input, effect, control);
Node* value = graph()->NewNode(simplified()->NumberIsNaN(), input);
ReplaceWithValue(node, value, effect);
return Replace(value);
}
// ES6 section 20.3.4.10 Date.prototype.getTime ( )
Reduction JSCallReducer::ReduceDatePrototypeGetTime(Node* node) {
Node* receiver = NodeProperties::GetValueInput(node, 1);
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
if (NodeProperties::HasInstanceTypeWitness(isolate(), receiver, effect,
JS_DATE_TYPE)) {
Node* value = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSDateValue()), receiver,
effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
return NoChange();
}
// ES6 section 20.3.3.1 Date.now ( )
Reduction JSCallReducer::ReduceDateNow(Node* node) {
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* value = effect =
graph()->NewNode(simplified()->DateNow(), effect, control);
ReplaceWithValue(node, value, effect, control);
return Replace(value);
}
// ES6 section 20.1.2.13 Number.parseInt ( string, radix )
Reduction JSCallReducer::ReduceNumberParseInt(Node* node) {
// We certainly know that undefined is not an array.
if (node->op()->ValueInputCount() < 3) {
Node* value = jsgraph()->NaNConstant();
ReplaceWithValue(node, value);
return Replace(value);
}
int arg_count = node->op()->ValueInputCount();
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* object = NodeProperties::GetValueInput(node, 2);
Node* radix = arg_count >= 4 ? NodeProperties::GetValueInput(node, 3)
: jsgraph()->UndefinedConstant();
node->ReplaceInput(0, object);
node->ReplaceInput(1, radix);
node->ReplaceInput(2, context);
node->ReplaceInput(3, frame_state);
node->ReplaceInput(4, effect);
node->ReplaceInput(5, control);
node->TrimInputCount(6);
NodeProperties::ChangeOp(node, javascript()->ParseInt());
return Changed(node);
}
Reduction JSCallReducer::ReduceRegExpPrototypeTest(Node* node) {
if (FLAG_force_slow_path) return NoChange();
if (node->op()->ValueInputCount() < 3) return NoChange();
CallParameters const& p = CallParametersOf(node->op());
if (p.speculation_mode() == SpeculationMode::kDisallowSpeculation) {
return NoChange();
}
Node* effect = NodeProperties::GetEffectInput(node);
Node* control = NodeProperties::GetControlInput(node);
Node* regexp = NodeProperties::GetValueInput(node, 1);
// Check if we know something about the {regexp}.
ZoneHandleSet<Map> regexp_maps;
NodeProperties::InferReceiverMapsResult result =
NodeProperties::InferReceiverMaps(isolate(), regexp, effect,
®exp_maps);
bool need_map_check = false;
switch (result) {
case NodeProperties::kNoReceiverMaps:
return NoChange();
case NodeProperties::kUnreliableReceiverMaps:
need_map_check = true;
break;
case NodeProperties::kReliableReceiverMaps:
break;
}
for (auto map : regexp_maps) {
if (map->instance_type() != JS_REGEXP_TYPE) return NoChange();
}
// Compute property access info for "exec" on {resolution}.
PropertyAccessInfo ai_exec;
AccessInfoFactory access_info_factory(js_heap_broker(), dependencies(),
native_context(), graph()->zone());
if (!access_info_factory.ComputePropertyAccessInfo(
MapHandles(regexp_maps.begin(), regexp_maps.end()),
factory()->exec_string(), AccessMode::kLoad, &ai_exec)) {
return NoChange();
}
// If "exec" has been modified on {regexp}, we can't do anything.
if (!ai_exec.IsDataConstant()) return NoChange();
Handle<Object> exec_on_proto = ai_exec.constant();
if (*exec_on_proto != *isolate()->regexp_exec_function()) return NoChange();
PropertyAccessBuilder access_builder(jsgraph(), js_heap_broker(),
dependencies());
// Add proper dependencies on the {regexp}s [[Prototype]]s.
Handle<JSObject> holder;
if (ai_exec.holder().ToHandle(&holder)) {
dependencies()->DependOnStablePrototypeChains(
js_heap_broker(), native_context(), ai_exec.receiver_maps(), holder);
}
if (need_map_check) {
effect =
graph()->NewNode(simplified()->CheckMaps(CheckMapsFlag::kNone,
regexp_maps, p.feedback()),
regexp, effect, control);
}
Node* context = NodeProperties::GetContextInput(node);
Node* frame_state = NodeProperties::GetFrameStateInput(node);
Node* search = NodeProperties::GetValueInput(node, 2);
Node* search_string = effect = graph()->NewNode(
simplified()->CheckString(p.feedback()), search, effect, control);
Node* lastIndex = effect = graph()->NewNode(
simplified()->LoadField(AccessBuilder::ForJSRegExpLastIndex()), regexp,
effect, control);
Node* lastIndexSmi = effect = graph()->NewNode(
simplified()->CheckSmi(p.feedback()), lastIndex, effect, control);
Node* is_positive = graph()->NewNode(simplified()->NumberLessThanOrEqual(),
jsgraph()->ZeroConstant(), lastIndexSmi);
effect = graph()->NewNode(
simplified()->CheckIf(DeoptimizeReason::kNotASmi, p.feedback()),
is_positive, effect, control);
node->ReplaceInput(0, regexp);
node->ReplaceInput(1, search_string);
node->ReplaceInput(2, context);
node->ReplaceInput(3, frame_state);
node->ReplaceInput(4, effect);
node->ReplaceInput(5, control);
node->TrimInputCount(6);
NodeProperties::ChangeOp(node, javascript()->RegExpTest());
return Changed(node);
}
// ES section #sec-number-constructor
Reduction JSCallReducer::ReduceNumberConstructor(Node* node) {
DCHECK_EQ(IrOpcode::kJSCall, node->opcode());
CallParameters const& p = CallParametersOf(node->op());
if (p.arity() <= 2) {
ReplaceWithValue(node, jsgraph()->ZeroConstant());
}
// We don't have a new.target argument, so we can convert to number,
// but must also convert BigInts.
if (p.arity() == 3) {
Node* target = NodeProperties::GetValueInput(node, 0);
Node* context = NodeProperties::GetContextInput(node);
Node* value = NodeProperties::GetValueInput(node, 2);
Node* outer_frame_state = NodeProperties::GetFrameStateInput(node);
Handle<SharedFunctionInfo> number_constructor(
handle(native_context()->number_function()->shared(), isolate()));
const std::vector<Node*> checkpoint_parameters({
jsgraph()->UndefinedConstant(), /* receiver */
});
int checkpoint_parameters_size =
static_cast<int>(checkpoint_parameters.size());
Node* frame_state = CreateJavaScriptBuiltinContinuationFrameState(
jsgraph(), number_constructor,
Builtins::kGenericConstructorLazyDeoptContinuation, target, context,
checkpoint_parameters.data(), checkpoint_parameters_size,
outer_frame_state, ContinuationFrameStateMode::LAZY);
NodeProperties::ReplaceValueInputs(node, value);
NodeProperties::ChangeOp(node, javascript()->ToNumberConvertBigInt());
NodeProperties::ReplaceFrameStateInput(node, frame_state);
return Changed(node);
}
return NoChange();
}
Graph* JSCallReducer::graph() const { return jsgraph()->graph(); }
Isolate* JSCallReducer::isolate() const { return jsgraph()->isolate(); }
Factory* JSCallReducer::factory() const { return isolate()->factory(); }
Handle<JSGlobalProxy> JSCallReducer::global_proxy() const {
return handle(JSGlobalProxy::cast(native_context()->global_proxy()),
isolate());
}
CommonOperatorBuilder* JSCallReducer::common() const {
return jsgraph()->common();
}
JSOperatorBuilder* JSCallReducer::javascript() const {
return jsgraph()->javascript();
}
SimplifiedOperatorBuilder* JSCallReducer::simplified() const {
return jsgraph()->simplified();
}
} // namespace compiler
} // namespace internal
} // namespace v8