// 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_COMPILER_H_
#define V8_COMPILER_H_
#include "src/allocation.h"
#include "src/ast.h"
#include "src/bailout-reason.h"
#include "src/zone.h"
namespace v8 {
namespace internal {
class AstValueFactory;
class HydrogenCodeStub;
// ParseRestriction is used to restrict the set of valid statements in a
// unit of compilation. Restriction violations cause a syntax error.
enum ParseRestriction {
NO_PARSE_RESTRICTION, // All expressions are allowed.
ONLY_SINGLE_FUNCTION_LITERAL // Only a single FunctionLiteral expression.
};
struct OffsetRange {
OffsetRange(int from, int to) : from(from), to(to) {}
int from;
int to;
};
class ScriptData {
public:
ScriptData(const byte* data, int length);
~ScriptData() {
if (owns_data_) DeleteArray(data_);
}
const byte* data() const { return data_; }
int length() const { return length_; }
void AcquireDataOwnership() {
DCHECK(!owns_data_);
owns_data_ = true;
}
void ReleaseDataOwnership() {
DCHECK(owns_data_);
owns_data_ = false;
}
private:
bool owns_data_;
const byte* data_;
int length_;
DISALLOW_COPY_AND_ASSIGN(ScriptData);
};
// CompilationInfo encapsulates some information known at compile time. It
// is constructed based on the resources available at compile-time.
class CompilationInfo {
public:
// Various configuration flags for a compilation, as well as some properties
// of the compiled code produced by a compilation.
enum Flag {
kLazy = 1 << 0,
kEval = 1 << 1,
kGlobal = 1 << 2,
kStrictMode = 1 << 3,
kThisHasUses = 1 << 4,
kNative = 1 << 5,
kDeferredCalling = 1 << 6,
kNonDeferredCalling = 1 << 7,
kSavesCallerDoubles = 1 << 8,
kRequiresFrame = 1 << 9,
kMustNotHaveEagerFrame = 1 << 10,
kDeoptimizationSupport = 1 << 11,
kDebug = 1 << 12,
kCompilingForDebugging = 1 << 13,
kParseRestriction = 1 << 14,
kSerializing = 1 << 15,
kContextSpecializing = 1 << 16,
kInliningEnabled = 1 << 17,
kTypingEnabled = 1 << 18,
kDisableFutureOptimization = 1 << 19
};
CompilationInfo(Handle<JSFunction> closure, Zone* zone);
CompilationInfo(Isolate* isolate, Zone* zone);
virtual ~CompilationInfo();
Isolate* isolate() const {
return isolate_;
}
Zone* zone() { return zone_; }
bool is_osr() const { return !osr_ast_id_.IsNone(); }
bool is_lazy() const { return GetFlag(kLazy); }
bool is_eval() const { return GetFlag(kEval); }
bool is_global() const { return GetFlag(kGlobal); }
StrictMode strict_mode() const {
return GetFlag(kStrictMode) ? STRICT : SLOPPY;
}
FunctionLiteral* function() const { return function_; }
Scope* scope() const { return scope_; }
Scope* global_scope() const { return global_scope_; }
Handle<Code> code() const { return code_; }
Handle<JSFunction> closure() const { return closure_; }
Handle<SharedFunctionInfo> shared_info() const { return shared_info_; }
Handle<Script> script() const { return script_; }
void set_script(Handle<Script> script) { script_ = script; }
HydrogenCodeStub* code_stub() const {return code_stub_; }
v8::Extension* extension() const { return extension_; }
ScriptData** cached_data() const { return cached_data_; }
ScriptCompiler::CompileOptions compile_options() const {
return compile_options_;
}
ScriptCompiler::ExternalSourceStream* source_stream() const {
return source_stream_;
}
ScriptCompiler::StreamedSource::Encoding source_stream_encoding() const {
return source_stream_encoding_;
}
Handle<Context> context() const { return context_; }
BailoutId osr_ast_id() const { return osr_ast_id_; }
Handle<Code> unoptimized_code() const { return unoptimized_code_; }
int opt_count() const { return opt_count_; }
int num_parameters() const;
int num_heap_slots() const;
Code::Flags flags() const;
void MarkAsEval() {
DCHECK(!is_lazy());
SetFlag(kEval);
}
void MarkAsGlobal() {
DCHECK(!is_lazy());
SetFlag(kGlobal);
}
void set_parameter_count(int parameter_count) {
DCHECK(IsStub());
parameter_count_ = parameter_count;
}
void set_this_has_uses(bool has_no_uses) {
SetFlag(kThisHasUses, has_no_uses);
}
bool this_has_uses() { return GetFlag(kThisHasUses); }
void SetStrictMode(StrictMode strict_mode) {
SetFlag(kStrictMode, strict_mode == STRICT);
}
void MarkAsNative() { SetFlag(kNative); }
bool is_native() const { return GetFlag(kNative); }
bool is_calling() const {
return GetFlag(kDeferredCalling) || GetFlag(kNonDeferredCalling);
}
void MarkAsDeferredCalling() { SetFlag(kDeferredCalling); }
bool is_deferred_calling() const { return GetFlag(kDeferredCalling); }
void MarkAsNonDeferredCalling() { SetFlag(kNonDeferredCalling); }
bool is_non_deferred_calling() const { return GetFlag(kNonDeferredCalling); }
void MarkAsSavesCallerDoubles() { SetFlag(kSavesCallerDoubles); }
bool saves_caller_doubles() const { return GetFlag(kSavesCallerDoubles); }
void MarkAsRequiresFrame() { SetFlag(kRequiresFrame); }
bool requires_frame() const { return GetFlag(kRequiresFrame); }
void MarkMustNotHaveEagerFrame() { SetFlag(kMustNotHaveEagerFrame); }
bool GetMustNotHaveEagerFrame() const {
return GetFlag(kMustNotHaveEagerFrame);
}
void MarkAsDebug() { SetFlag(kDebug); }
bool is_debug() const { return GetFlag(kDebug); }
void PrepareForSerializing() { SetFlag(kSerializing); }
bool will_serialize() const { return GetFlag(kSerializing); }
void MarkAsContextSpecializing() { SetFlag(kContextSpecializing); }
bool is_context_specializing() const { return GetFlag(kContextSpecializing); }
void MarkAsInliningEnabled() { SetFlag(kInliningEnabled); }
void MarkAsInliningDisabled() { SetFlag(kInliningEnabled, false); }
bool is_inlining_enabled() const { return GetFlag(kInliningEnabled); }
void MarkAsTypingEnabled() { SetFlag(kTypingEnabled); }
bool is_typing_enabled() const { return GetFlag(kTypingEnabled); }
bool IsCodePreAgingActive() const {
return FLAG_optimize_for_size && FLAG_age_code && !will_serialize() &&
!is_debug();
}
void SetParseRestriction(ParseRestriction restriction) {
SetFlag(kParseRestriction, restriction != NO_PARSE_RESTRICTION);
}
ParseRestriction parse_restriction() const {
return GetFlag(kParseRestriction) ? ONLY_SINGLE_FUNCTION_LITERAL
: NO_PARSE_RESTRICTION;
}
void SetFunction(FunctionLiteral* literal) {
DCHECK(function_ == NULL);
function_ = literal;
}
void PrepareForCompilation(Scope* scope);
void SetGlobalScope(Scope* global_scope) {
DCHECK(global_scope_ == NULL);
global_scope_ = global_scope;
}
Handle<TypeFeedbackVector> feedback_vector() const {
return feedback_vector_;
}
void SetCode(Handle<Code> code) { code_ = code; }
void SetExtension(v8::Extension* extension) {
DCHECK(!is_lazy());
extension_ = extension;
}
void SetCachedData(ScriptData** cached_data,
ScriptCompiler::CompileOptions compile_options) {
compile_options_ = compile_options;
if (compile_options == ScriptCompiler::kNoCompileOptions) {
cached_data_ = NULL;
} else {
DCHECK(!is_lazy());
cached_data_ = cached_data;
}
}
void SetContext(Handle<Context> context) {
context_ = context;
}
void MarkCompilingForDebugging() { SetFlag(kCompilingForDebugging); }
bool IsCompilingForDebugging() { return GetFlag(kCompilingForDebugging); }
void MarkNonOptimizable() {
SetMode(CompilationInfo::NONOPT);
}
bool ShouldTrapOnDeopt() const {
return (FLAG_trap_on_deopt && IsOptimizing()) ||
(FLAG_trap_on_stub_deopt && IsStub());
}
bool has_global_object() const {
return !closure().is_null() &&
(closure()->context()->global_object() != NULL);
}
GlobalObject* global_object() const {
return has_global_object() ? closure()->context()->global_object() : NULL;
}
// Accessors for the different compilation modes.
bool IsOptimizing() const { return mode_ == OPTIMIZE; }
bool IsOptimizable() const { return mode_ == BASE; }
bool IsStub() const { return mode_ == STUB; }
void SetOptimizing(BailoutId osr_ast_id, Handle<Code> unoptimized) {
DCHECK(!shared_info_.is_null());
SetMode(OPTIMIZE);
osr_ast_id_ = osr_ast_id;
unoptimized_code_ = unoptimized;
optimization_id_ = isolate()->NextOptimizationId();
}
// Deoptimization support.
bool HasDeoptimizationSupport() const {
return GetFlag(kDeoptimizationSupport);
}
void EnableDeoptimizationSupport() {
DCHECK(IsOptimizable());
SetFlag(kDeoptimizationSupport);
}
// Determines whether or not to insert a self-optimization header.
bool ShouldSelfOptimize();
void set_deferred_handles(DeferredHandles* deferred_handles) {
DCHECK(deferred_handles_ == NULL);
deferred_handles_ = deferred_handles;
}
ZoneList<Handle<HeapObject> >* dependencies(
DependentCode::DependencyGroup group) {
if (dependencies_[group] == NULL) {
dependencies_[group] = new(zone_) ZoneList<Handle<HeapObject> >(2, zone_);
}
return dependencies_[group];
}
void CommitDependencies(Handle<Code> code);
void RollbackDependencies();
void SaveHandles() {
SaveHandle(&closure_);
SaveHandle(&shared_info_);
SaveHandle(&context_);
SaveHandle(&script_);
SaveHandle(&unoptimized_code_);
}
void AbortOptimization(BailoutReason reason) {
if (bailout_reason_ != kNoReason) bailout_reason_ = reason;
SetFlag(kDisableFutureOptimization);
}
void RetryOptimization(BailoutReason reason) {
if (bailout_reason_ != kNoReason) bailout_reason_ = reason;
}
BailoutReason bailout_reason() const { return bailout_reason_; }
int prologue_offset() const {
DCHECK_NE(Code::kPrologueOffsetNotSet, prologue_offset_);
return prologue_offset_;
}
void set_prologue_offset(int prologue_offset) {
DCHECK_EQ(Code::kPrologueOffsetNotSet, prologue_offset_);
prologue_offset_ = prologue_offset;
}
// Adds offset range [from, to) where fp register does not point
// to the current frame base. Used in CPU profiler to detect stack
// samples where top frame is not set up.
inline void AddNoFrameRange(int from, int to) {
if (no_frame_ranges_) no_frame_ranges_->Add(OffsetRange(from, to));
}
List<OffsetRange>* ReleaseNoFrameRanges() {
List<OffsetRange>* result = no_frame_ranges_;
no_frame_ranges_ = NULL;
return result;
}
Handle<Foreign> object_wrapper() {
if (object_wrapper_.is_null()) {
object_wrapper_ =
isolate()->factory()->NewForeign(reinterpret_cast<Address>(this));
}
return object_wrapper_;
}
void AbortDueToDependencyChange() {
DCHECK(!OptimizingCompilerThread::IsOptimizerThread(isolate()));
aborted_due_to_dependency_change_ = true;
}
bool HasAbortedDueToDependencyChange() const {
DCHECK(!OptimizingCompilerThread::IsOptimizerThread(isolate()));
return aborted_due_to_dependency_change_;
}
bool HasSameOsrEntry(Handle<JSFunction> function, BailoutId osr_ast_id) {
return osr_ast_id_ == osr_ast_id && function.is_identical_to(closure_);
}
int optimization_id() const { return optimization_id_; }
AstValueFactory* ast_value_factory() const { return ast_value_factory_; }
void SetAstValueFactory(AstValueFactory* ast_value_factory,
bool owned = true) {
ast_value_factory_ = ast_value_factory;
ast_value_factory_owned_ = owned;
}
AstNode::IdGen* ast_node_id_gen() { return &ast_node_id_gen_; }
protected:
CompilationInfo(Handle<Script> script,
Zone* zone);
CompilationInfo(Handle<SharedFunctionInfo> shared_info,
Zone* zone);
CompilationInfo(HydrogenCodeStub* stub,
Isolate* isolate,
Zone* zone);
CompilationInfo(ScriptCompiler::ExternalSourceStream* source_stream,
ScriptCompiler::StreamedSource::Encoding encoding,
Isolate* isolate, Zone* zone);
private:
Isolate* isolate_;
// Compilation mode.
// BASE is generated by the full codegen, optionally prepared for bailouts.
// OPTIMIZE is optimized code generated by the Hydrogen-based backend.
// NONOPT is generated by the full codegen and is not prepared for
// recompilation/bailouts. These functions are never recompiled.
enum Mode {
BASE,
OPTIMIZE,
NONOPT,
STUB
};
void Initialize(Isolate* isolate, Mode mode, Zone* zone);
void SetMode(Mode mode) {
mode_ = mode;
}
void SetFlag(Flag flag) { flags_ |= flag; }
void SetFlag(Flag flag, bool value) {
flags_ = value ? flags_ | flag : flags_ & ~flag;
}
bool GetFlag(Flag flag) const { return (flags_ & flag) != 0; }
unsigned flags_;
// Fields filled in by the compilation pipeline.
// AST filled in by the parser.
FunctionLiteral* function_;
// The scope of the function literal as a convenience. Set to indicate
// that scopes have been analyzed.
Scope* scope_;
// The global scope provided as a convenience.
Scope* global_scope_;
// For compiled stubs, the stub object
HydrogenCodeStub* code_stub_;
// The compiled code.
Handle<Code> code_;
// Possible initial inputs to the compilation process.
Handle<JSFunction> closure_;
Handle<SharedFunctionInfo> shared_info_;
Handle<Script> script_;
ScriptCompiler::ExternalSourceStream* source_stream_; // Not owned.
ScriptCompiler::StreamedSource::Encoding source_stream_encoding_;
// Fields possibly needed for eager compilation, NULL by default.
v8::Extension* extension_;
ScriptData** cached_data_;
ScriptCompiler::CompileOptions compile_options_;
// The context of the caller for eval code, and the global context for a
// global script. Will be a null handle otherwise.
Handle<Context> context_;
// Used by codegen, ultimately kept rooted by the SharedFunctionInfo.
Handle<TypeFeedbackVector> feedback_vector_;
// Compilation mode flag and whether deoptimization is allowed.
Mode mode_;
BailoutId osr_ast_id_;
// The unoptimized code we patched for OSR may not be the shared code
// afterwards, since we may need to compile it again to include deoptimization
// data. Keep track which code we patched.
Handle<Code> unoptimized_code_;
// The zone from which the compilation pipeline working on this
// CompilationInfo allocates.
Zone* zone_;
DeferredHandles* deferred_handles_;
ZoneList<Handle<HeapObject> >* dependencies_[DependentCode::kGroupCount];
template<typename T>
void SaveHandle(Handle<T> *object) {
if (!object->is_null()) {
Handle<T> handle(*(*object));
*object = handle;
}
}
BailoutReason bailout_reason_;
int prologue_offset_;
List<OffsetRange>* no_frame_ranges_;
// A copy of shared_info()->opt_count() to avoid handle deref
// during graph optimization.
int opt_count_;
// Number of parameters used for compilation of stubs that require arguments.
int parameter_count_;
Handle<Foreign> object_wrapper_;
int optimization_id_;
AstValueFactory* ast_value_factory_;
bool ast_value_factory_owned_;
AstNode::IdGen ast_node_id_gen_;
// This flag is used by the main thread to track whether this compilation
// should be abandoned due to dependency change.
bool aborted_due_to_dependency_change_;
DISALLOW_COPY_AND_ASSIGN(CompilationInfo);
};
// Exactly like a CompilationInfo, except also creates and enters a
// Zone on construction and deallocates it on exit.
class CompilationInfoWithZone: public CompilationInfo {
public:
explicit CompilationInfoWithZone(Handle<Script> script)
: CompilationInfo(script, &zone_),
zone_(script->GetIsolate()) {}
explicit CompilationInfoWithZone(Handle<SharedFunctionInfo> shared_info)
: CompilationInfo(shared_info, &zone_),
zone_(shared_info->GetIsolate()) {}
explicit CompilationInfoWithZone(Handle<JSFunction> closure)
: CompilationInfo(closure, &zone_),
zone_(closure->GetIsolate()) {}
CompilationInfoWithZone(HydrogenCodeStub* stub, Isolate* isolate)
: CompilationInfo(stub, isolate, &zone_),
zone_(isolate) {}
CompilationInfoWithZone(ScriptCompiler::ExternalSourceStream* stream,
ScriptCompiler::StreamedSource::Encoding encoding,
Isolate* isolate)
: CompilationInfo(stream, encoding, isolate, &zone_), zone_(isolate) {}
// Virtual destructor because a CompilationInfoWithZone has to exit the
// zone scope and get rid of dependent maps even when the destructor is
// called when cast as a CompilationInfo.
virtual ~CompilationInfoWithZone() {
RollbackDependencies();
}
private:
Zone zone_;
};
// A wrapper around a CompilationInfo that detaches the Handles from
// the underlying DeferredHandleScope and stores them in info_ on
// destruction.
class CompilationHandleScope BASE_EMBEDDED {
public:
explicit CompilationHandleScope(CompilationInfo* info)
: deferred_(info->isolate()), info_(info) {}
~CompilationHandleScope() {
info_->set_deferred_handles(deferred_.Detach());
}
private:
DeferredHandleScope deferred_;
CompilationInfo* info_;
};
class HGraph;
class HOptimizedGraphBuilder;
class LChunk;
// A helper class that calls the three compilation phases in
// Crankshaft and keeps track of its state. The three phases
// CreateGraph, OptimizeGraph and GenerateAndInstallCode can either
// fail, bail-out to the full code generator or succeed. Apart from
// their return value, the status of the phase last run can be checked
// using last_status().
class OptimizedCompileJob: public ZoneObject {
public:
explicit OptimizedCompileJob(CompilationInfo* info)
: info_(info),
graph_builder_(NULL),
graph_(NULL),
chunk_(NULL),
last_status_(FAILED),
awaiting_install_(false) { }
enum Status {
FAILED, BAILED_OUT, SUCCEEDED
};
MUST_USE_RESULT Status CreateGraph();
MUST_USE_RESULT Status OptimizeGraph();
MUST_USE_RESULT Status GenerateCode();
Status last_status() const { return last_status_; }
CompilationInfo* info() const { return info_; }
Isolate* isolate() const { return info()->isolate(); }
Status RetryOptimization(BailoutReason reason) {
info_->RetryOptimization(reason);
return SetLastStatus(BAILED_OUT);
}
Status AbortOptimization(BailoutReason reason) {
info_->AbortOptimization(reason);
return SetLastStatus(BAILED_OUT);
}
void WaitForInstall() {
DCHECK(info_->is_osr());
awaiting_install_ = true;
}
bool IsWaitingForInstall() { return awaiting_install_; }
private:
CompilationInfo* info_;
HOptimizedGraphBuilder* graph_builder_;
HGraph* graph_;
LChunk* chunk_;
base::TimeDelta time_taken_to_create_graph_;
base::TimeDelta time_taken_to_optimize_;
base::TimeDelta time_taken_to_codegen_;
Status last_status_;
bool awaiting_install_;
MUST_USE_RESULT Status SetLastStatus(Status status) {
last_status_ = status;
return last_status_;
}
void RecordOptimizationStats();
struct Timer {
Timer(OptimizedCompileJob* job, base::TimeDelta* location)
: job_(job), location_(location) {
DCHECK(location_ != NULL);
timer_.Start();
}
~Timer() {
*location_ += timer_.Elapsed();
}
OptimizedCompileJob* job_;
base::ElapsedTimer timer_;
base::TimeDelta* location_;
};
};
// The V8 compiler
//
// General strategy: Source code is translated into an anonymous function w/o
// parameters which then can be executed. If the source code contains other
// functions, they will be compiled and allocated as part of the compilation
// of the source code.
// Please note this interface returns shared function infos. This means you
// need to call Factory::NewFunctionFromSharedFunctionInfo before you have a
// real function with a context.
class Compiler : public AllStatic {
public:
MUST_USE_RESULT static MaybeHandle<Code> GetUnoptimizedCode(
Handle<JSFunction> function);
MUST_USE_RESULT static MaybeHandle<Code> GetLazyCode(
Handle<JSFunction> function);
MUST_USE_RESULT static MaybeHandle<Code> GetUnoptimizedCode(
Handle<SharedFunctionInfo> shared);
MUST_USE_RESULT static MaybeHandle<Code> GetDebugCode(
Handle<JSFunction> function);
static bool EnsureCompiled(Handle<JSFunction> function,
ClearExceptionFlag flag);
static bool EnsureDeoptimizationSupport(CompilationInfo* info);
static void CompileForLiveEdit(Handle<Script> script);
// Compile a String source within a context for eval.
MUST_USE_RESULT static MaybeHandle<JSFunction> GetFunctionFromEval(
Handle<String> source, Handle<SharedFunctionInfo> outer_info,
Handle<Context> context, StrictMode strict_mode,
ParseRestriction restriction, int scope_position);
// Compile a String source within a context.
static Handle<SharedFunctionInfo> CompileScript(
Handle<String> source, Handle<Object> script_name, int line_offset,
int column_offset, bool is_shared_cross_origin, Handle<Context> context,
v8::Extension* extension, ScriptData** cached_data,
ScriptCompiler::CompileOptions compile_options,
NativesFlag is_natives_code);
static Handle<SharedFunctionInfo> CompileStreamedScript(CompilationInfo* info,
int source_length);
// Create a shared function info object (the code may be lazily compiled).
static Handle<SharedFunctionInfo> BuildFunctionInfo(FunctionLiteral* node,
Handle<Script> script,
CompilationInfo* outer);
enum ConcurrencyMode { NOT_CONCURRENT, CONCURRENT };
// Generate and return optimized code or start a concurrent optimization job.
// In the latter case, return the InOptimizationQueue builtin. On failure,
// return the empty handle.
MUST_USE_RESULT static MaybeHandle<Code> GetOptimizedCode(
Handle<JSFunction> function,
Handle<Code> current_code,
ConcurrencyMode mode,
BailoutId osr_ast_id = BailoutId::None());
// Generate and return code from previously queued optimization job.
// On failure, return the empty handle.
static Handle<Code> GetConcurrentlyOptimizedCode(OptimizedCompileJob* job);
static bool DebuggerWantsEagerCompilation(
CompilationInfo* info, bool allow_lazy_without_ctx = false);
};
class CompilationPhase BASE_EMBEDDED {
public:
CompilationPhase(const char* name, CompilationInfo* info);
~CompilationPhase();
protected:
bool ShouldProduceTraceOutput() const;
const char* name() const { return name_; }
CompilationInfo* info() const { return info_; }
Isolate* isolate() const { return info()->isolate(); }
Zone* zone() { return &zone_; }
private:
const char* name_;
CompilationInfo* info_;
Zone zone_;
unsigned info_zone_start_allocation_size_;
base::ElapsedTimer timer_;
DISALLOW_COPY_AND_ASSIGN(CompilationPhase);
};
} } // namespace v8::internal
#endif // V8_COMPILER_H_