// 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.
#include "src/v8.h"
#include "src/runtime-profiler.h"
#include "src/assembler.h"
#include "src/base/platform/platform.h"
#include "src/bootstrapper.h"
#include "src/code-stubs.h"
#include "src/compilation-cache.h"
#include "src/execution.h"
#include "src/full-codegen.h"
#include "src/global-handles.h"
#include "src/heap/mark-compact.h"
#include "src/isolate-inl.h"
#include "src/scopeinfo.h"
namespace v8 {
namespace internal {
// Number of times a function has to be seen on the stack before it is
// optimized.
static const int kProfilerTicksBeforeOptimization = 2;
// If the function optimization was disabled due to high deoptimization count,
// but the function is hot and has been seen on the stack this number of times,
// then we try to reenable optimization for this function.
static const int kProfilerTicksBeforeReenablingOptimization = 250;
// If a function does not have enough type info (according to
// FLAG_type_info_threshold), but has seen a huge number of ticks,
// optimize it as it is.
static const int kTicksWhenNotEnoughTypeInfo = 100;
// We only have one byte to store the number of ticks.
STATIC_ASSERT(kProfilerTicksBeforeOptimization < 256);
STATIC_ASSERT(kProfilerTicksBeforeReenablingOptimization < 256);
STATIC_ASSERT(kTicksWhenNotEnoughTypeInfo < 256);
// Maximum size in bytes of generate code for a function to allow OSR.
static const int kOSRCodeSizeAllowanceBase =
100 * FullCodeGenerator::kCodeSizeMultiplier;
static const int kOSRCodeSizeAllowancePerTick =
4 * FullCodeGenerator::kCodeSizeMultiplier;
// Maximum size in bytes of generated code for a function to be optimized
// the very first time it is seen on the stack.
static const int kMaxSizeEarlyOpt =
5 * FullCodeGenerator::kCodeSizeMultiplier;
RuntimeProfiler::RuntimeProfiler(Isolate* isolate)
: isolate_(isolate),
any_ic_changed_(false) {
}
static void GetICCounts(Code* shared_code, int* ic_with_type_info_count,
int* ic_generic_count, int* ic_total_count,
int* type_info_percentage, int* generic_percentage) {
*ic_total_count = 0;
*ic_generic_count = 0;
*ic_with_type_info_count = 0;
Object* raw_info = shared_code->type_feedback_info();
if (raw_info->IsTypeFeedbackInfo()) {
TypeFeedbackInfo* info = TypeFeedbackInfo::cast(raw_info);
*ic_with_type_info_count = info->ic_with_type_info_count();
*ic_generic_count = info->ic_generic_count();
*ic_total_count = info->ic_total_count();
}
if (*ic_total_count > 0) {
*type_info_percentage = 100 * *ic_with_type_info_count / *ic_total_count;
*generic_percentage = 100 * *ic_generic_count / *ic_total_count;
} else {
*type_info_percentage = 100; // Compared against lower bound.
*generic_percentage = 0; // Compared against upper bound.
}
}
void RuntimeProfiler::Optimize(JSFunction* function, const char* reason) {
DCHECK(function->IsOptimizable());
if (FLAG_trace_opt && function->PassesFilter(FLAG_hydrogen_filter)) {
PrintF("[marking ");
function->ShortPrint();
PrintF(" for recompilation, reason: %s", reason);
if (FLAG_type_info_threshold > 0) {
int typeinfo, generic, total, type_percentage, generic_percentage;
GetICCounts(function->shared()->code(), &typeinfo, &generic, &total,
&type_percentage, &generic_percentage);
PrintF(", ICs with typeinfo: %d/%d (%d%%)", typeinfo, total,
type_percentage);
PrintF(", generic ICs: %d/%d (%d%%)", generic, total, generic_percentage);
}
PrintF("]\n");
}
if (isolate_->concurrent_recompilation_enabled() &&
!isolate_->bootstrapper()->IsActive()) {
if (isolate_->concurrent_osr_enabled() &&
isolate_->optimizing_compiler_thread()->IsQueuedForOSR(function)) {
// Do not attempt regular recompilation if we already queued this for OSR.
// TODO(yangguo): This is necessary so that we don't install optimized
// code on a function that is already optimized, since OSR and regular
// recompilation race. This goes away as soon as OSR becomes one-shot.
return;
}
DCHECK(!function->IsInOptimizationQueue());
function->MarkForConcurrentOptimization();
} else {
// The next call to the function will trigger optimization.
function->MarkForOptimization();
}
}
void RuntimeProfiler::AttemptOnStackReplacement(JSFunction* function,
int loop_nesting_levels) {
SharedFunctionInfo* shared = function->shared();
// See AlwaysFullCompiler (in compiler.cc) comment on why we need
// Debug::has_break_points().
if (!FLAG_use_osr ||
isolate_->DebuggerHasBreakPoints() ||
function->IsBuiltin()) {
return;
}
// If the code is not optimizable, don't try OSR.
if (!shared->code()->optimizable()) return;
// We are not prepared to do OSR for a function that already has an
// allocated arguments object. The optimized code would bypass it for
// arguments accesses, which is unsound. Don't try OSR.
if (shared->uses_arguments()) return;
// We're using on-stack replacement: patch the unoptimized code so that
// any back edge in any unoptimized frame will trigger on-stack
// replacement for that frame.
if (FLAG_trace_osr) {
PrintF("[OSR - patching back edges in ");
function->PrintName();
PrintF("]\n");
}
for (int i = 0; i < loop_nesting_levels; i++) {
BackEdgeTable::Patch(isolate_, shared->code());
}
}
void RuntimeProfiler::OptimizeNow() {
HandleScope scope(isolate_);
if (isolate_->DebuggerHasBreakPoints()) return;
DisallowHeapAllocation no_gc;
// Run through the JavaScript frames and collect them. If we already
// have a sample of the function, we mark it for optimizations
// (eagerly or lazily).
int frame_count = 0;
int frame_count_limit = FLAG_frame_count;
for (JavaScriptFrameIterator it(isolate_);
frame_count++ < frame_count_limit && !it.done();
it.Advance()) {
JavaScriptFrame* frame = it.frame();
JSFunction* function = frame->function();
SharedFunctionInfo* shared = function->shared();
Code* shared_code = shared->code();
List<JSFunction*> functions(4);
frame->GetFunctions(&functions);
for (int i = functions.length(); --i >= 0; ) {
SharedFunctionInfo* shared_function_info = functions[i]->shared();
int ticks = shared_function_info->profiler_ticks();
if (ticks < Smi::kMaxValue) {
shared_function_info->set_profiler_ticks(ticks + 1);
}
}
if (shared_code->kind() != Code::FUNCTION) continue;
if (function->IsInOptimizationQueue()) continue;
if (FLAG_always_osr) {
AttemptOnStackReplacement(function, Code::kMaxLoopNestingMarker);
// Fall through and do a normal optimized compile as well.
} else if (!frame->is_optimized() &&
(function->IsMarkedForOptimization() ||
function->IsMarkedForConcurrentOptimization() ||
function->IsOptimized())) {
// Attempt OSR if we are still running unoptimized code even though the
// the function has long been marked or even already been optimized.
int ticks = shared_code->profiler_ticks();
int allowance = kOSRCodeSizeAllowanceBase +
ticks * kOSRCodeSizeAllowancePerTick;
if (shared_code->CodeSize() > allowance) {
if (ticks < 255) shared_code->set_profiler_ticks(ticks + 1);
} else {
AttemptOnStackReplacement(function);
}
continue;
}
// Only record top-level code on top of the execution stack and
// avoid optimizing excessively large scripts since top-level code
// will be executed only once.
const int kMaxToplevelSourceSize = 10 * 1024;
if (shared->is_toplevel() &&
(frame_count > 1 || shared->SourceSize() > kMaxToplevelSourceSize)) {
continue;
}
// Do not record non-optimizable functions.
if (shared->optimization_disabled()) {
if (shared->deopt_count() >= FLAG_max_opt_count) {
// If optimization was disabled due to many deoptimizations,
// then check if the function is hot and try to reenable optimization.
int ticks = shared_code->profiler_ticks();
if (ticks >= kProfilerTicksBeforeReenablingOptimization) {
shared_code->set_profiler_ticks(0);
shared->TryReenableOptimization();
} else {
shared_code->set_profiler_ticks(ticks + 1);
}
}
continue;
}
if (!function->IsOptimizable()) continue;
int ticks = shared_code->profiler_ticks();
if (ticks >= kProfilerTicksBeforeOptimization) {
int typeinfo, generic, total, type_percentage, generic_percentage;
GetICCounts(shared_code, &typeinfo, &generic, &total, &type_percentage,
&generic_percentage);
if (type_percentage >= FLAG_type_info_threshold &&
generic_percentage <= FLAG_generic_ic_threshold) {
// If this particular function hasn't had any ICs patched for enough
// ticks, optimize it now.
Optimize(function, "hot and stable");
} else if (ticks >= kTicksWhenNotEnoughTypeInfo) {
Optimize(function, "not much type info but very hot");
} else {
shared_code->set_profiler_ticks(ticks + 1);
if (FLAG_trace_opt_verbose) {
PrintF("[not yet optimizing ");
function->PrintName();
PrintF(", not enough type info: %d/%d (%d%%)]\n", typeinfo, total,
type_percentage);
}
}
} else if (!any_ic_changed_ &&
shared_code->instruction_size() < kMaxSizeEarlyOpt) {
// If no IC was patched since the last tick and this function is very
// small, optimistically optimize it now.
int typeinfo, generic, total, type_percentage, generic_percentage;
GetICCounts(shared_code, &typeinfo, &generic, &total, &type_percentage,
&generic_percentage);
if (type_percentage >= FLAG_type_info_threshold &&
generic_percentage <= FLAG_generic_ic_threshold) {
Optimize(function, "small function");
} else {
shared_code->set_profiler_ticks(ticks + 1);
}
} else {
shared_code->set_profiler_ticks(ticks + 1);
}
}
any_ic_changed_ = false;
}
} } // namespace v8::internal