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// Copyright 2012 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.
#ifndef V8_CODE_STUBS_H_
#define V8_CODE_STUBS_H_
#include "src/allocation.h"
#include "src/assembler.h"
#include "src/factory.h"
#include "src/globals.h"
#include "src/interface-descriptors.h"
#include "src/macro-assembler.h"
#include "src/ostreams.h"
#include "src/type-hints.h"
namespace v8 {
namespace internal {
// Forward declarations.
class CodeStubAssembler;
namespace compiler {
class CodeAssemblerLabel;
class CodeAssemblerState;
class Node;
}
// List of code stubs used on all platforms.
#define CODE_STUB_LIST_ALL_PLATFORMS(V) \
/* --- PlatformCodeStubs --- */ \
V(ArrayConstructor) \
V(CallApiCallback) \
V(CallApiGetter) \
V(CEntry) \
V(DoubleToI) \
V(InternalArrayConstructor) \
V(JSEntry) \
V(MathPow) \
V(ProfileEntryHook) \
V(StoreSlowElement) \
/* --- TurboFanCodeStubs --- */ \
V(ArrayNoArgumentConstructor) \
V(ArraySingleArgumentConstructor) \
V(ArrayNArgumentsConstructor) \
V(InternalArrayNoArgumentConstructor) \
V(InternalArraySingleArgumentConstructor) \
V(ElementsTransitionAndStore) \
V(KeyedLoadSloppyArguments) \
V(KeyedStoreSloppyArguments) \
V(StringAdd) \
V(GetProperty) \
V(StoreFastElement) \
V(StoreInterceptor) \
V(TransitionElementsKind) \
V(LoadIndexedInterceptor)
// List of code stubs only used on ARM 32 bits platforms.
#if V8_TARGET_ARCH_ARM
#define CODE_STUB_LIST_ARM(V) V(DirectCEntry)
#else
#define CODE_STUB_LIST_ARM(V)
#endif
// List of code stubs only used on ARM 64 bits platforms.
#if V8_TARGET_ARCH_ARM64
#define CODE_STUB_LIST_ARM64(V) V(DirectCEntry)
#else
#define CODE_STUB_LIST_ARM64(V)
#endif
// List of code stubs only used on PPC platforms.
#ifdef V8_TARGET_ARCH_PPC
#define CODE_STUB_LIST_PPC(V) V(DirectCEntry)
#else
#define CODE_STUB_LIST_PPC(V)
#endif
// List of code stubs only used on MIPS platforms.
#if V8_TARGET_ARCH_MIPS
#define CODE_STUB_LIST_MIPS(V) V(DirectCEntry)
#elif V8_TARGET_ARCH_MIPS64
#define CODE_STUB_LIST_MIPS(V) V(DirectCEntry)
#else
#define CODE_STUB_LIST_MIPS(V)
#endif
// List of code stubs only used on S390 platforms.
#ifdef V8_TARGET_ARCH_S390
#define CODE_STUB_LIST_S390(V) V(DirectCEntry)
#else
#define CODE_STUB_LIST_S390(V)
#endif
// Combined list of code stubs.
#define CODE_STUB_LIST(V) \
CODE_STUB_LIST_ALL_PLATFORMS(V) \
CODE_STUB_LIST_ARM(V) \
CODE_STUB_LIST_ARM64(V) \
CODE_STUB_LIST_PPC(V) \
CODE_STUB_LIST_MIPS(V) \
CODE_STUB_LIST_S390(V)
static const int kHasReturnedMinusZeroSentinel = 1;
class CodeStub : public ZoneObject {
public:
enum Major {
// TODO(mvstanton): eliminate the NoCache key by getting rid
// of the non-monomorphic-cache.
NoCache = 0, // marker for stubs that do custom caching]
#define DEF_ENUM(name) name,
CODE_STUB_LIST(DEF_ENUM)
#undef DEF_ENUM
NUMBER_OF_IDS
};
// Retrieve the code for the stub. Generate the code if needed.
Handle<Code> GetCode();
static Major MajorKeyFromKey(uint32_t key) {
return static_cast<Major>(MajorKeyBits::decode(key));
}
static uint32_t MinorKeyFromKey(uint32_t key) {
return MinorKeyBits::decode(key);
}
// Gets the major key from a code object that is a code stub or binary op IC.
static Major GetMajorKey(Code* code_stub);
static uint32_t NoCacheKey() { return MajorKeyBits::encode(NoCache); }
static const char* MajorName(Major major_key);
explicit CodeStub(Isolate* isolate) : minor_key_(0), isolate_(isolate) {}
virtual ~CodeStub() {}
static void GenerateStubsAheadOfTime(Isolate* isolate);
static void GenerateFPStubs(Isolate* isolate);
// Some stubs put untagged junk on the stack that cannot be scanned by the
// GC. This means that we must be statically sure that no GC can occur while
// they are running. If that is the case they should override this to return
// true, which will cause an assertion if we try to call something that can
// GC or if we try to put a stack frame on top of the junk, which would not
// result in a traversable stack.
virtual bool SometimesSetsUpAFrame() { return true; }
// Lookup the code in the (possibly custom) cache.
bool FindCodeInCache(Code** code_out);
virtual CallInterfaceDescriptor GetCallInterfaceDescriptor() const = 0;
virtual int GetStackParameterCount() const {
return GetCallInterfaceDescriptor().GetStackParameterCount();
}
virtual void InitializeDescriptor(CodeStubDescriptor* descriptor) {}
static void InitializeDescriptor(Isolate* isolate, uint32_t key,
CodeStubDescriptor* desc);
static MaybeHandle<Code> GetCode(Isolate* isolate, uint32_t key);
// Returns information for computing the number key.
virtual Major MajorKey() const = 0;
uint32_t MinorKey() const { return minor_key_; }
friend std::ostream& operator<<(std::ostream& os, const CodeStub& s) {
s.PrintName(os);
return os;
}
Isolate* isolate() const { return isolate_; }
void set_isolate(Isolate* isolate) {
DCHECK_NOT_NULL(isolate);
DCHECK(isolate_ == nullptr || isolate_ == isolate);
isolate_ = isolate;
}
void DeleteStubFromCacheForTesting();
protected:
CodeStub(uint32_t key, Isolate* isolate)
: minor_key_(MinorKeyFromKey(key)), isolate_(isolate) {}
// Generates the assembler code for the stub.
virtual Handle<Code> GenerateCode() = 0;
// Returns whether the code generated for this stub needs to be allocated as
// a fixed (non-moveable) code object.
virtual Movability NeedsImmovableCode() { return kMovable; }
virtual void PrintName(std::ostream& os) const; // NOLINT
virtual void PrintBaseName(std::ostream& os) const; // NOLINT
virtual void PrintState(std::ostream& os) const { ; } // NOLINT
// Computes the key based on major and minor.
uint32_t GetKey() {
DCHECK(static_cast<int>(MajorKey()) < NUMBER_OF_IDS);
return MinorKeyBits::encode(MinorKey()) | MajorKeyBits::encode(MajorKey());
}
uint32_t minor_key_;
private:
// Perform bookkeeping required after code generation when stub code is
// initially generated.
void RecordCodeGeneration(Handle<Code> code);
// Activate newly generated stub. Is called after
// registering stub in the stub cache.
virtual void Activate(Code* code) { }
// We use this dispatch to statically instantiate the correct code stub for
// the given stub key and call the passed function with that code stub.
typedef void (*DispatchedCall)(CodeStub* stub, void** value_out);
static void Dispatch(Isolate* isolate, uint32_t key, void** value_out,
DispatchedCall call);
static void GetCodeDispatchCall(CodeStub* stub, void** value_out);
STATIC_ASSERT(NUMBER_OF_IDS < (1 << kStubMajorKeyBits));
class MajorKeyBits: public BitField<uint32_t, 0, kStubMajorKeyBits> {};
class MinorKeyBits: public BitField<uint32_t,
kStubMajorKeyBits, kStubMinorKeyBits> {}; // NOLINT
friend class BreakPointIterator;
Isolate* isolate_;
};
#define DEFINE_CODE_STUB_BASE(NAME, SUPER) \
public: \
NAME(uint32_t key, Isolate* isolate) : SUPER(key, isolate) {} \
\
private: \
DISALLOW_COPY_AND_ASSIGN(NAME)
#define DEFINE_CODE_STUB(NAME, SUPER) \
public: \
inline Major MajorKey() const override { return NAME; }; \
\
DEFINE_CODE_STUB_BASE(NAME##Stub, SUPER)
#define DEFINE_PLATFORM_CODE_STUB(NAME, SUPER) \
private: \
void Generate(MacroAssembler* masm) override; \
DEFINE_CODE_STUB(NAME, SUPER)
#define DEFINE_TURBOFAN_CODE_STUB(NAME, SUPER) \
public: \
void GenerateAssembly(compiler::CodeAssemblerState* state) const override; \
DEFINE_CODE_STUB(NAME, SUPER)
#define DEFINE_CALL_INTERFACE_DESCRIPTOR(NAME) \
public: \
typedef NAME##Descriptor Descriptor; \
CallInterfaceDescriptor GetCallInterfaceDescriptor() const override { \
return Descriptor(isolate()); \
}
// There are some code stubs we just can't describe right now with a
// CallInterfaceDescriptor. Isolate behavior for those cases with this macro.
// An attempt to retrieve a descriptor will fail.
#define DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR() \
public: \
CallInterfaceDescriptor GetCallInterfaceDescriptor() const override { \
UNREACHABLE(); \
return CallInterfaceDescriptor(); \
}
class PlatformCodeStub : public CodeStub {
public:
// Retrieve the code for the stub. Generate the code if needed.
Handle<Code> GenerateCode() override;
protected:
explicit PlatformCodeStub(Isolate* isolate) : CodeStub(isolate) {}
// Generates the assembler code for the stub.
virtual void Generate(MacroAssembler* masm) = 0;
// Generates the exception handler table for the stub.
virtual Handle<HandlerTable> GenerateHandlerTable();
DEFINE_CODE_STUB_BASE(PlatformCodeStub, CodeStub);
};
enum StubFunctionMode { NOT_JS_FUNCTION_STUB_MODE, JS_FUNCTION_STUB_MODE };
class CodeStubDescriptor {
public:
explicit CodeStubDescriptor(CodeStub* stub);
CodeStubDescriptor(Isolate* isolate, uint32_t stub_key);
void Initialize(Address deoptimization_handler = nullptr,
int hint_stack_parameter_count = -1,
StubFunctionMode function_mode = NOT_JS_FUNCTION_STUB_MODE);
void Initialize(Register stack_parameter_count,
Address deoptimization_handler = nullptr,
int hint_stack_parameter_count = -1,
StubFunctionMode function_mode = NOT_JS_FUNCTION_STUB_MODE);
void SetMissHandler(Runtime::FunctionId id) {
miss_handler_id_ = id;
miss_handler_ = ExternalReference(Runtime::FunctionForId(id), isolate_);
has_miss_handler_ = true;
// Our miss handler infrastructure doesn't currently support
// variable stack parameter counts.
DCHECK(!stack_parameter_count_.is_valid());
}
void set_call_descriptor(CallInterfaceDescriptor d) { call_descriptor_ = d; }
CallInterfaceDescriptor call_descriptor() const { return call_descriptor_; }
int GetRegisterParameterCount() const {
return call_descriptor().GetRegisterParameterCount();
}
int GetStackParameterCount() const {
return call_descriptor().GetStackParameterCount();
}
int GetParameterCount() const {
return call_descriptor().GetParameterCount();
}
Register GetRegisterParameter(int index) const {
return call_descriptor().GetRegisterParameter(index);
}
MachineType GetParameterType(int index) const {
return call_descriptor().GetParameterType(index);
}
ExternalReference miss_handler() const {
DCHECK(has_miss_handler_);
return miss_handler_;
}
Runtime::FunctionId miss_handler_id() const {
DCHECK(has_miss_handler_);
return miss_handler_id_;
}
bool has_miss_handler() const {
return has_miss_handler_;
}
int GetHandlerParameterCount() const {
int params = GetParameterCount();
if (PassesArgumentsToDeoptimizationHandler()) {
params += 1;
}
return params;
}
int hint_stack_parameter_count() const { return hint_stack_parameter_count_; }
Register stack_parameter_count() const { return stack_parameter_count_; }
StubFunctionMode function_mode() const { return function_mode_; }
Address deoptimization_handler() const { return deoptimization_handler_; }
private:
bool PassesArgumentsToDeoptimizationHandler() const {
return stack_parameter_count_.is_valid();
}
Isolate* isolate_;
CallInterfaceDescriptor call_descriptor_;
Register stack_parameter_count_;
// If hint_stack_parameter_count_ > 0, the code stub can optimize the
// return sequence. Default value is -1, which means it is ignored.
int hint_stack_parameter_count_;
StubFunctionMode function_mode_;
Address deoptimization_handler_;
ExternalReference miss_handler_;
Runtime::FunctionId miss_handler_id_;
bool has_miss_handler_;
};
class TurboFanCodeStub : public CodeStub {
public:
// Retrieve the code for the stub. Generate the code if needed.
Handle<Code> GenerateCode() override;
int GetStackParameterCount() const override {
return GetCallInterfaceDescriptor().GetStackParameterCount();
}
protected:
explicit TurboFanCodeStub(Isolate* isolate) : CodeStub(isolate) {}
virtual void GenerateAssembly(compiler::CodeAssemblerState* state) const = 0;
private:
DEFINE_CODE_STUB_BASE(TurboFanCodeStub, CodeStub);
};
} // namespace internal
} // namespace v8
#if V8_TARGET_ARCH_IA32
#elif V8_TARGET_ARCH_X64
#elif V8_TARGET_ARCH_ARM64
#include "src/arm64/code-stubs-arm64.h"
#elif V8_TARGET_ARCH_ARM
#include "src/arm/code-stubs-arm.h"
#elif V8_TARGET_ARCH_PPC
#include "src/ppc/code-stubs-ppc.h"
#elif V8_TARGET_ARCH_MIPS
#include "src/mips/code-stubs-mips.h"
#elif V8_TARGET_ARCH_MIPS64
#include "src/mips64/code-stubs-mips64.h"
#elif V8_TARGET_ARCH_S390
#include "src/s390/code-stubs-s390.h"
#else
#error Unsupported target architecture.
#endif
namespace v8 {
namespace internal {
class StoreInterceptorStub : public TurboFanCodeStub {
public:
explicit StoreInterceptorStub(Isolate* isolate) : TurboFanCodeStub(isolate) {}
DEFINE_CALL_INTERFACE_DESCRIPTOR(StoreWithVector);
DEFINE_TURBOFAN_CODE_STUB(StoreInterceptor, TurboFanCodeStub);
};
class TransitionElementsKindStub : public TurboFanCodeStub {
public:
TransitionElementsKindStub(Isolate* isolate, ElementsKind from_kind,
ElementsKind to_kind, bool is_jsarray)
: TurboFanCodeStub(isolate) {
set_sub_minor_key(FromKindBits::encode(from_kind) |
ToKindBits::encode(to_kind) |
IsJSArrayBits::encode(is_jsarray));
}
void set_sub_minor_key(uint32_t key) { minor_key_ = key; }
uint32_t sub_minor_key() const { return minor_key_; }
ElementsKind from_kind() const {
return FromKindBits::decode(sub_minor_key());
}
ElementsKind to_kind() const { return ToKindBits::decode(sub_minor_key()); }
bool is_jsarray() const { return IsJSArrayBits::decode(sub_minor_key()); }
private:
class ToKindBits : public BitField<ElementsKind, 0, 8> {};
class FromKindBits : public BitField<ElementsKind, ToKindBits::kNext, 8> {};
class IsJSArrayBits : public BitField<bool, FromKindBits::kNext, 1> {};
DEFINE_CALL_INTERFACE_DESCRIPTOR(TransitionElementsKind);
DEFINE_TURBOFAN_CODE_STUB(TransitionElementsKind, TurboFanCodeStub);
};
class LoadIndexedInterceptorStub : public TurboFanCodeStub {
public:
explicit LoadIndexedInterceptorStub(Isolate* isolate)
: TurboFanCodeStub(isolate) {}
DEFINE_CALL_INTERFACE_DESCRIPTOR(LoadWithVector);
DEFINE_TURBOFAN_CODE_STUB(LoadIndexedInterceptor, TurboFanCodeStub);
};
// ES6 [[Get]] operation.
class GetPropertyStub : public TurboFanCodeStub {
public:
explicit GetPropertyStub(Isolate* isolate) : TurboFanCodeStub(isolate) {}
DEFINE_CALL_INTERFACE_DESCRIPTOR(GetProperty);
DEFINE_TURBOFAN_CODE_STUB(GetProperty, TurboFanCodeStub);
};
enum AllocationSiteOverrideMode {
DONT_OVERRIDE,
DISABLE_ALLOCATION_SITES,
LAST_ALLOCATION_SITE_OVERRIDE_MODE = DISABLE_ALLOCATION_SITES
};
class ArrayConstructorStub: public PlatformCodeStub {
public:
explicit ArrayConstructorStub(Isolate* isolate);
private:
void GenerateDispatchToArrayStub(MacroAssembler* masm,
AllocationSiteOverrideMode mode);
DEFINE_CALL_INTERFACE_DESCRIPTOR(ArrayConstructor);
DEFINE_PLATFORM_CODE_STUB(ArrayConstructor, PlatformCodeStub);
};
class InternalArrayConstructorStub: public PlatformCodeStub {
public:
explicit InternalArrayConstructorStub(Isolate* isolate);
private:
void GenerateCase(MacroAssembler* masm, ElementsKind kind);
DEFINE_CALL_INTERFACE_DESCRIPTOR(ArrayNArgumentsConstructor);
DEFINE_PLATFORM_CODE_STUB(InternalArrayConstructor, PlatformCodeStub);
};
class MathPowStub: public PlatformCodeStub {
public:
enum ExponentType { INTEGER, DOUBLE, TAGGED };
MathPowStub(Isolate* isolate, ExponentType exponent_type)
: PlatformCodeStub(isolate) {
minor_key_ = ExponentTypeBits::encode(exponent_type);
}
CallInterfaceDescriptor GetCallInterfaceDescriptor() const override {
if (exponent_type() == TAGGED) {
return MathPowTaggedDescriptor(isolate());
} else if (exponent_type() == INTEGER) {
return MathPowIntegerDescriptor(isolate());
} else {
// A CallInterfaceDescriptor doesn't specify double registers (yet).
DCHECK_EQ(DOUBLE, exponent_type());
return ContextOnlyDescriptor(isolate());
}
}
private:
ExponentType exponent_type() const {
return ExponentTypeBits::decode(minor_key_);
}
class ExponentTypeBits : public BitField<ExponentType, 0, 2> {};
DEFINE_PLATFORM_CODE_STUB(MathPow, PlatformCodeStub);
};
class KeyedLoadSloppyArgumentsStub : public TurboFanCodeStub {
public:
explicit KeyedLoadSloppyArgumentsStub(Isolate* isolate)
: TurboFanCodeStub(isolate) {}
protected:
DEFINE_CALL_INTERFACE_DESCRIPTOR(LoadWithVector);
DEFINE_TURBOFAN_CODE_STUB(KeyedLoadSloppyArguments, TurboFanCodeStub);
};
class CommonStoreModeBits : public BitField<KeyedAccessStoreMode, 0, 3> {};
class KeyedStoreSloppyArgumentsStub : public TurboFanCodeStub {
public:
explicit KeyedStoreSloppyArgumentsStub(Isolate* isolate,
KeyedAccessStoreMode mode)
: TurboFanCodeStub(isolate) {
minor_key_ = CommonStoreModeBits::encode(mode);
}
protected:
DEFINE_CALL_INTERFACE_DESCRIPTOR(StoreWithVector);
DEFINE_TURBOFAN_CODE_STUB(KeyedStoreSloppyArguments, TurboFanCodeStub);
};
class CallApiCallbackStub : public PlatformCodeStub {
public:
static const int kArgBits = 7;
static const int kArgMax = (1 << kArgBits) - 1;
CallApiCallbackStub(Isolate* isolate, int argc)
: PlatformCodeStub(isolate) {
CHECK_LE(0, argc);
CHECK_LE(argc, kArgMax);
minor_key_ = ArgumentBits::encode(argc);
}
private:
int argc() const { return ArgumentBits::decode(minor_key_); }
class ArgumentBits : public BitField<int, 0, kArgBits> {};
DEFINE_CALL_INTERFACE_DESCRIPTOR(ApiCallback);
DEFINE_PLATFORM_CODE_STUB(CallApiCallback, PlatformCodeStub);
};
class CallApiGetterStub : public PlatformCodeStub {
public:
explicit CallApiGetterStub(Isolate* isolate) : PlatformCodeStub(isolate) {}
DEFINE_CALL_INTERFACE_DESCRIPTOR(ApiGetter);
DEFINE_PLATFORM_CODE_STUB(CallApiGetter, PlatformCodeStub);
};
class StringAddStub final : public TurboFanCodeStub {
public:
StringAddStub(Isolate* isolate, StringAddFlags flags,
PretenureFlag pretenure_flag)
: TurboFanCodeStub(isolate) {
minor_key_ = (StringAddFlagsBits::encode(flags) |
PretenureFlagBits::encode(pretenure_flag));
}
StringAddFlags flags() const {
return StringAddFlagsBits::decode(minor_key_);
}
PretenureFlag pretenure_flag() const {
return PretenureFlagBits::decode(minor_key_);
}
private:
class StringAddFlagsBits : public BitField<StringAddFlags, 0, 3> {};
class PretenureFlagBits : public BitField<PretenureFlag, 3, 1> {};
void PrintBaseName(std::ostream& os) const override; // NOLINT
DEFINE_CALL_INTERFACE_DESCRIPTOR(StringAdd);
DEFINE_TURBOFAN_CODE_STUB(StringAdd, TurboFanCodeStub);
};
class CEntryStub : public PlatformCodeStub {
public:
CEntryStub(Isolate* isolate, int result_size,
SaveFPRegsMode save_doubles = kDontSaveFPRegs,
ArgvMode argv_mode = kArgvOnStack, bool builtin_exit_frame = false)
: PlatformCodeStub(isolate) {
minor_key_ = SaveDoublesBits::encode(save_doubles == kSaveFPRegs) |
FrameTypeBits::encode(builtin_exit_frame) |
ArgvMode::encode(argv_mode == kArgvInRegister);
DCHECK(result_size == 1 || result_size == 2);
minor_key_ = ResultSizeBits::update(minor_key_, result_size);
}
// The version of this stub that doesn't save doubles is generated ahead of
// time, so it's OK to call it from other stubs that can't cope with GC during
// their code generation. On machines that always have gp registers (x64) we
// can generate both variants ahead of time.
static void GenerateAheadOfTime(Isolate* isolate);
private:
bool save_doubles() const { return SaveDoublesBits::decode(minor_key_); }
bool argv_in_register() const { return ArgvMode::decode(minor_key_); }
bool is_builtin_exit() const { return FrameTypeBits::decode(minor_key_); }
int result_size() const { return ResultSizeBits::decode(minor_key_); }
Movability NeedsImmovableCode() override;
class SaveDoublesBits : public BitField<bool, 0, 1> {};
class ArgvMode : public BitField<bool, 1, 1> {};
class FrameTypeBits : public BitField<bool, 2, 1> {};
class ResultSizeBits : public BitField<int, 3, 3> {};
DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
DEFINE_PLATFORM_CODE_STUB(CEntry, PlatformCodeStub);
};
class JSEntryStub : public PlatformCodeStub {
public:
enum class SpecialTarget { kNone, kRunMicrotasks };
JSEntryStub(Isolate* isolate, StackFrame::Type type)
: PlatformCodeStub(isolate) {
DCHECK(type == StackFrame::ENTRY || type == StackFrame::CONSTRUCT_ENTRY);
minor_key_ = StackFrameTypeBits::encode(type) |
SpecialTargetBits::encode(SpecialTarget::kNone);
}
JSEntryStub(Isolate* isolate, SpecialTarget target)
: PlatformCodeStub(isolate) {
minor_key_ = StackFrameTypeBits::encode(StackFrame::ENTRY) |
SpecialTargetBits::encode(target);
}
private:
Handle<HandlerTable> GenerateHandlerTable() override;
void PrintName(std::ostream& os) const override { // NOLINT
os << (type() == StackFrame::ENTRY ? "JSEntryStub"
: "JSConstructEntryStub");
}
StackFrame::Type type() const {
return StackFrameTypeBits::decode(minor_key_);
}
SpecialTarget special_target() const {
return SpecialTargetBits::decode(minor_key_);
}
Handle<Code> EntryTrampoline() {
switch (special_target()) {
case SpecialTarget::kNone:
return (type() == StackFrame::CONSTRUCT_ENTRY)
? BUILTIN_CODE(isolate(), JSConstructEntryTrampoline)
: BUILTIN_CODE(isolate(), JSEntryTrampoline);
case SpecialTarget::kRunMicrotasks:
return BUILTIN_CODE(isolate(), RunMicrotasks);
}
UNREACHABLE();
return Handle<Code>();
}
class StackFrameTypeBits : public BitField<StackFrame::Type, 0, 5> {};
class SpecialTargetBits
: public BitField<SpecialTarget, StackFrameTypeBits::kNext, 1> {};
int handler_offset_;
DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
DEFINE_PLATFORM_CODE_STUB(JSEntry, PlatformCodeStub);
};
enum ReceiverCheckMode {
// We don't know anything about the receiver.
RECEIVER_IS_UNKNOWN,
// We know the receiver is a string.
RECEIVER_IS_STRING
};
enum EmbedMode {
// The code being generated is part of an IC handler, which may MISS
// to an IC in failure cases.
PART_OF_IC_HANDLER,
NOT_PART_OF_IC_HANDLER
};
class DoubleToIStub : public PlatformCodeStub {
public:
DoubleToIStub(Isolate* isolate, Register destination)
: PlatformCodeStub(isolate) {
minor_key_ = DestinationRegisterBits::encode(destination.code()) |
SSE3Bits::encode(CpuFeatures::IsSupported(SSE3) ? 1 : 0);
}
bool SometimesSetsUpAFrame() override { return false; }
private:
Register destination() const {
return Register::from_code(DestinationRegisterBits::decode(minor_key_));
}
static const int kBitsPerRegisterNumber = 6;
STATIC_ASSERT((1L << kBitsPerRegisterNumber) >= Register::kNumRegisters);
class DestinationRegisterBits
: public BitField<int, 0, kBitsPerRegisterNumber> {};
class SSE3Bits : public BitField<int, kBitsPerRegisterNumber, 1> {};
DEFINE_NULL_CALL_INTERFACE_DESCRIPTOR();
DEFINE_PLATFORM_CODE_STUB(DoubleToI, PlatformCodeStub);
};
class StoreFastElementStub : public TurboFanCodeStub {
public:
StoreFastElementStub(Isolate* isolate, bool is_js_array,
ElementsKind elements_kind, KeyedAccessStoreMode mode)
: TurboFanCodeStub(isolate) {
minor_key_ = CommonStoreModeBits::encode(mode) |
ElementsKindBits::encode(elements_kind) |
IsJSArrayBits::encode(is_js_array);
}
static void GenerateAheadOfTime(Isolate* isolate);
bool is_js_array() const { return IsJSArrayBits::decode(minor_key_); }
ElementsKind elements_kind() const {
return ElementsKindBits::decode(minor_key_);
}
KeyedAccessStoreMode store_mode() const {
return CommonStoreModeBits::decode(minor_key_);
}
private:
class ElementsKindBits
: public BitField<ElementsKind, CommonStoreModeBits::kNext, 8> {};
class IsJSArrayBits : public BitField<bool, ElementsKindBits::kNext, 1> {};
DEFINE_CALL_INTERFACE_DESCRIPTOR(StoreWithVector);
DEFINE_TURBOFAN_CODE_STUB(StoreFastElement, TurboFanCodeStub);
};
class CommonArrayConstructorStub : public TurboFanCodeStub {
protected:
CommonArrayConstructorStub(Isolate* isolate, ElementsKind kind,
AllocationSiteOverrideMode override_mode);
void set_sub_minor_key(uint32_t key) { minor_key_ = key; }
uint32_t sub_minor_key() const { return minor_key_; }
CommonArrayConstructorStub(uint32_t key, Isolate* isolate)
: TurboFanCodeStub(key, isolate) {}
public:
ElementsKind elements_kind() const {
return ElementsKindBits::decode(sub_minor_key());
}
AllocationSiteOverrideMode override_mode() const {
return AllocationSiteOverrideModeBits::decode(sub_minor_key());
}
static void GenerateStubsAheadOfTime(Isolate* isolate);
private:
// Ensure data fits within available bits.
STATIC_ASSERT(LAST_ALLOCATION_SITE_OVERRIDE_MODE == 1);
class ElementsKindBits : public BitField<ElementsKind, 0, 8> {};
class AllocationSiteOverrideModeBits
: public BitField<AllocationSiteOverrideMode, 8, 1> {}; // NOLINT
};
class ArrayNoArgumentConstructorStub : public CommonArrayConstructorStub {
public:
ArrayNoArgumentConstructorStub(
Isolate* isolate, ElementsKind kind,
AllocationSiteOverrideMode override_mode = DONT_OVERRIDE)
: CommonArrayConstructorStub(isolate, kind, override_mode) {}
private:
void PrintName(std::ostream& os) const override { // NOLINT
os << "ArrayNoArgumentConstructorStub";
}
DEFINE_CALL_INTERFACE_DESCRIPTOR(ArrayNoArgumentConstructor);
DEFINE_TURBOFAN_CODE_STUB(ArrayNoArgumentConstructor,
CommonArrayConstructorStub);
};
class InternalArrayNoArgumentConstructorStub
: public CommonArrayConstructorStub {
public:
InternalArrayNoArgumentConstructorStub(Isolate* isolate, ElementsKind kind)
: CommonArrayConstructorStub(isolate, kind, DONT_OVERRIDE) {}
private:
void PrintName(std::ostream& os) const override { // NOLINT
os << "InternalArrayNoArgumentConstructorStub";
}
DEFINE_CALL_INTERFACE_DESCRIPTOR(ArrayNoArgumentConstructor);
DEFINE_TURBOFAN_CODE_STUB(InternalArrayNoArgumentConstructor,
CommonArrayConstructorStub);
};
class ArraySingleArgumentConstructorStub : public CommonArrayConstructorStub {
public:
ArraySingleArgumentConstructorStub(
Isolate* isolate, ElementsKind kind,
AllocationSiteOverrideMode override_mode = DONT_OVERRIDE)
: CommonArrayConstructorStub(isolate, kind, override_mode) {}
private:
void PrintName(std::ostream& os) const override { // NOLINT
os << "ArraySingleArgumentConstructorStub";
}
DEFINE_CALL_INTERFACE_DESCRIPTOR(ArraySingleArgumentConstructor);
DEFINE_TURBOFAN_CODE_STUB(ArraySingleArgumentConstructor,
CommonArrayConstructorStub);
};
class InternalArraySingleArgumentConstructorStub
: public CommonArrayConstructorStub {
public:
InternalArraySingleArgumentConstructorStub(Isolate* isolate,
ElementsKind kind)
: CommonArrayConstructorStub(isolate, kind, DONT_OVERRIDE) {}
private:
void PrintName(std::ostream& os) const override { // NOLINT
os << "InternalArraySingleArgumentConstructorStub";
}
DEFINE_CALL_INTERFACE_DESCRIPTOR(ArraySingleArgumentConstructor);
DEFINE_TURBOFAN_CODE_STUB(InternalArraySingleArgumentConstructor,
CommonArrayConstructorStub);
};
class ArrayNArgumentsConstructorStub : public PlatformCodeStub {
public:
explicit ArrayNArgumentsConstructorStub(Isolate* isolate)
: PlatformCodeStub(isolate) {}
CallInterfaceDescriptor GetCallInterfaceDescriptor() const override {
return ArrayNArgumentsConstructorDescriptor(isolate());
}
private:
DEFINE_PLATFORM_CODE_STUB(ArrayNArgumentsConstructor, PlatformCodeStub);
};
class StoreSlowElementStub : public TurboFanCodeStub {
public:
StoreSlowElementStub(Isolate* isolate, KeyedAccessStoreMode mode)
: TurboFanCodeStub(isolate) {
minor_key_ = CommonStoreModeBits::encode(mode);
}
private:
DEFINE_CALL_INTERFACE_DESCRIPTOR(StoreWithVector);
DEFINE_TURBOFAN_CODE_STUB(StoreSlowElement, TurboFanCodeStub);
};
class ElementsTransitionAndStoreStub : public TurboFanCodeStub {
public:
ElementsTransitionAndStoreStub(Isolate* isolate, ElementsKind from_kind,
ElementsKind to_kind, bool is_jsarray,
KeyedAccessStoreMode store_mode)
: TurboFanCodeStub(isolate) {
minor_key_ = CommonStoreModeBits::encode(store_mode) |
FromBits::encode(from_kind) | ToBits::encode(to_kind) |
IsJSArrayBits::encode(is_jsarray);
}
ElementsKind from_kind() const { return FromBits::decode(minor_key_); }
ElementsKind to_kind() const { return ToBits::decode(minor_key_); }
bool is_jsarray() const { return IsJSArrayBits::decode(minor_key_); }
KeyedAccessStoreMode store_mode() const {
return CommonStoreModeBits::decode(minor_key_);
}
private:
class FromBits
: public BitField<ElementsKind, CommonStoreModeBits::kNext, 8> {};
class ToBits : public BitField<ElementsKind, 11, 8> {};
class IsJSArrayBits : public BitField<bool, 19, 1> {};
DEFINE_CALL_INTERFACE_DESCRIPTOR(StoreTransition);
DEFINE_TURBOFAN_CODE_STUB(ElementsTransitionAndStore, TurboFanCodeStub);
};
class ProfileEntryHookStub : public PlatformCodeStub {
public:
explicit ProfileEntryHookStub(Isolate* isolate) : PlatformCodeStub(isolate) {}
// The profile entry hook function is not allowed to cause a GC.
bool SometimesSetsUpAFrame() override { return false; }
// Generates a call to the entry hook if it's enabled.
static void MaybeCallEntryHook(MacroAssembler* masm);
static void MaybeCallEntryHookDelayed(TurboAssembler* tasm, Zone* zone);
private:
static void EntryHookTrampoline(intptr_t function,
intptr_t stack_pointer,
Isolate* isolate);
// ProfileEntryHookStub is called at the start of a function, so it has the
// same register set.
DEFINE_CALL_INTERFACE_DESCRIPTOR(CallFunction)
DEFINE_PLATFORM_CODE_STUB(ProfileEntryHook, PlatformCodeStub);
};
#undef DEFINE_CALL_INTERFACE_DESCRIPTOR
#undef DEFINE_PLATFORM_CODE_STUB
#undef DEFINE_CODE_STUB
#undef DEFINE_CODE_STUB_BASE
} // namespace internal
} // namespace v8
#endif // V8_CODE_STUBS_H_