src/heap.cc - platform/art - Gitiles

 // Copyright 2011 Google Inc. All Rights Reserved.
 // Author: cshapiro@google.com (Carl Shapiro)

 #include "heap.h"

 #include <vector>

 #include "mark_sweep.h"
 #include "object.h"
 #include "space.h"
 #include "scoped_ptr.h"
 #include "stl_util.h"

 namespace art {

 std::vector<Space*> Heap::spaces_;

 size_t Heap::startup_size_ = 0;

 size_t Heap::maximum_size_ = 0;

 size_t Heap::num_bytes_allocated_ = 0;

 size_t Heap::num_objects_allocated_ = 0;

 bool Heap::is_gc_running_ = false;

 HeapBitmap* Heap::mark_bitmap_ = NULL;

 HeapBitmap* Heap::live_bitmap_ = NULL;

 bool Heap::Init(size_t startup_size, size_t maximum_size) {
   Space* space = Space::Create(startup_size, maximum_size);
   if (space == NULL) {
     return false;
   }

   byte* base = space->GetBase();
   size_t num_bytes = space->Size();

   // Allocate the initial live bitmap.
   scoped_ptr<HeapBitmap> live_bitmap(HeapBitmap::Create(base, num_bytes));
   if (live_bitmap == NULL) {
     return false;
   }

   // Allocate the initial mark bitmap.
   scoped_ptr<HeapBitmap> mark_bitmap(HeapBitmap::Create(base, num_bytes));
   if (mark_bitmap == NULL) {
     return false;
   }

   spaces_.push_back(space);
   startup_size_ = startup_size;
   maximum_size_ = maximum_size;
   live_bitmap_ = live_bitmap.release();
   mark_bitmap_ = mark_bitmap.release();

   // TODO: allocate the card table

   return true;
 }

 void Heap::Destroy() {
   STLDeleteElements(&spaces_);
   delete mark_bitmap_;
   delete live_bitmap_;
 }

 Object* Heap::AllocObject(Class* klass, size_t num_bytes) {
   Object* obj = Allocate(num_bytes);
   if (obj != NULL) {
     obj->klass_ = klass;
   }
   return obj;
 }

 void Heap::RecordAllocation(Space* space, const Object* obj) {
   size_t size = space->AllocationSize(obj);
   DCHECK_NE(size, 0u);
   num_bytes_allocated_ += size;
   num_objects_allocated_ += 1;
   live_bitmap_->Set(obj);
 }

 void Heap::RecordFree(Space* space, const Object* obj) {
   size_t size = space->AllocationSize(obj);
   DCHECK_NE(size, 0u);
   if (size < num_bytes_allocated_) {
     num_bytes_allocated_ -= size;
   } else {
     num_bytes_allocated_ = 0;
   }
   live_bitmap_->Clear(obj);
   if (num_objects_allocated_ > 0) {
     num_objects_allocated_ -= 1;
   }
 }

 Object* Heap::Allocate(size_t size) {
   CHECK_EQ(spaces_.size(), 1u);
   Space* space = spaces_[0];
   Object* obj = Allocate(space, size);
   if (obj != NULL) {
     RecordAllocation(space, obj);
   }
   return obj;
 }

 Object* Heap::Allocate(Space* space, size_t size) {
   // Fail impossible allocations.  TODO: collect soft references.
   if (size > maximum_size_) {
     return NULL;
   }

   Object* ptr = space->AllocWithoutGrowth(size);
   if (ptr != NULL) {
     return ptr;
   }

   // The allocation failed.  If the GC is running, block until it
   // completes and retry.
   if (is_gc_running_) {
     // The GC is concurrently tracing the heap.  Release the heap
     // lock, wait for the GC to complete, and retrying allocating.
     WaitForConcurrentGcToComplete();
     ptr = space->AllocWithoutGrowth(size);
     if (ptr != NULL) {
       return ptr;
     }
   }

   // Another failure.  Our thread was starved or there may be too many
   // live objects.  Try a foreground GC.  This will have no effect if
   // the concurrent GC is already running.
   CollectGarbageInternal();
   ptr = space->AllocWithoutGrowth(size);
   if (ptr != NULL) {
     return ptr;
   }

   // Even that didn't work;  this is an exceptional state.
   // Try harder, growing the heap if necessary.
   ptr = space->AllocWithGrowth(size);
   if (ptr != NULL) {
     //size_t new_footprint = dvmHeapSourceGetIdealFootprint();
     size_t new_footprint = space->MaxAllowedFootprint();
     // TODO: may want to grow a little bit more so that the amount of
     //       free space is equal to the old free space + the
     //       utilization slop for the new allocation.
     LOG(INFO) << "Grow heap (frag case) to " << new_footprint / MB
               << "for " << size << "-byte allocation";
     return ptr;
   }

   // Most allocations should have succeeded by now, so the heap is
   // really full, really fragmented, or the requested size is really
   // big.  Do another GC, collecting SoftReferences this time.  The VM
   // spec requires that all SoftReferences have been collected and
   // cleared before throwing an OOME.

   // TODO: wait for the finalizers from the previous GC to finish
   LOG(INFO) << "Forcing collection of SoftReferences for "
             << size << "-byte allocation";
   CollectGarbageInternal();
   ptr = space->AllocWithGrowth(size);
   if (ptr != NULL) {
     return ptr;
   }

   LOG(ERROR) << "Out of memory on a " << size << " byte allocation";

   // TODO: tell the HeapSource to dump its state
   // TODO: dump stack traces for all threads

   return NULL;
 }

 void Heap::CollectGarbage() {
   CollectGarbageInternal();
 }

 void Heap::CollectGarbageInternal() {
   // TODO: check that heap lock is held

   // TODO: Suspend all threads
   {
     MarkSweep mark_sweep;

     mark_sweep.Init();

     mark_sweep.MarkRoots();

     // Push marked roots onto the mark stack

     // TODO: if concurrent
     //   unlock heap
     //   resume threads

     mark_sweep.RecursiveMark();

     // TODO: if concurrent
     //   lock heap
     //   suspend threads
     //   re-mark root set
     //   scan dirty objects

     mark_sweep.ProcessReferences(false);

     // TODO: swap bitmaps

     mark_sweep.Sweep();
   }

   GrowForUtilization();

   // TODO: Resume all threads
 }

 void Heap::WaitForConcurrentGcToComplete() {
 }

 // Given the current contents of the active heap, increase the allowed
 // heap footprint to match the target utilization ratio.  This should
 // only be called immediately after a full garbage collection.
 void Heap::GrowForUtilization() {
   LOG(ERROR) << "Unimplemented";
 }

 }  // namespace art
	// Copyright 2011 Google Inc. All Rights Reserved.
	// Author: cshapiro@google.com (Carl Shapiro)

	#include "heap.h"

	#include <vector>

	#include "mark_sweep.h"
	#include "object.h"
	#include "space.h"
	#include "scoped_ptr.h"
	#include "stl_util.h"

	namespace art {

	std::vector<Space*> Heap::spaces_;

	size_t Heap::startup_size_ = 0;

	size_t Heap::maximum_size_ = 0;

	size_t Heap::num_bytes_allocated_ = 0;

	size_t Heap::num_objects_allocated_ = 0;

	bool Heap::is_gc_running_ = false;

	HeapBitmap* Heap::mark_bitmap_ = NULL;

	HeapBitmap* Heap::live_bitmap_ = NULL;

	bool Heap::Init(size_t startup_size, size_t maximum_size) {
	Space* space = Space::Create(startup_size, maximum_size);
	if (space == NULL) {
	return false;
	}

	byte* base = space->GetBase();
	size_t num_bytes = space->Size();

	// Allocate the initial live bitmap.
	scoped_ptr<HeapBitmap> live_bitmap(HeapBitmap::Create(base, num_bytes));
	if (live_bitmap == NULL) {
	return false;
	}

	// Allocate the initial mark bitmap.
	scoped_ptr<HeapBitmap> mark_bitmap(HeapBitmap::Create(base, num_bytes));
	if (mark_bitmap == NULL) {
	return false;
	}

	spaces_.push_back(space);
	startup_size_ = startup_size;
	maximum_size_ = maximum_size;
	live_bitmap_ = live_bitmap.release();
	mark_bitmap_ = mark_bitmap.release();

	// TODO: allocate the card table

	return true;
	}

	void Heap::Destroy() {
	STLDeleteElements(&spaces_);
	delete mark_bitmap_;
	delete live_bitmap_;
	}

	Object* Heap::AllocObject(Class* klass, size_t num_bytes) {
	Object* obj = Allocate(num_bytes);
	if (obj != NULL) {
	obj->klass_ = klass;
	}
	return obj;
	}

	void Heap::RecordAllocation(Space* space, const Object* obj) {
	size_t size = space->AllocationSize(obj);
	DCHECK_NE(size, 0u);
	num_bytes_allocated_ += size;
	num_objects_allocated_ += 1;
	live_bitmap_->Set(obj);
	}

	void Heap::RecordFree(Space* space, const Object* obj) {
	size_t size = space->AllocationSize(obj);
	DCHECK_NE(size, 0u);
	if (size < num_bytes_allocated_) {
	num_bytes_allocated_ -= size;
	} else {
	num_bytes_allocated_ = 0;
	}
	live_bitmap_->Clear(obj);
	if (num_objects_allocated_ > 0) {
	num_objects_allocated_ -= 1;
	}
	}

	Object* Heap::Allocate(size_t size) {
	CHECK_EQ(spaces_.size(), 1u);
	Space* space = spaces_[0];
	Object* obj = Allocate(space, size);
	if (obj != NULL) {
	RecordAllocation(space, obj);
	}
	return obj;
	}

	Object* Heap::Allocate(Space* space, size_t size) {
	// Fail impossible allocations. TODO: collect soft references.
	if (size > maximum_size_) {
	return NULL;
	}

	Object* ptr = space->AllocWithoutGrowth(size);
	if (ptr != NULL) {
	return ptr;
	}

	// The allocation failed. If the GC is running, block until it
	// completes and retry.
	if (is_gc_running_) {
	// The GC is concurrently tracing the heap. Release the heap
	// lock, wait for the GC to complete, and retrying allocating.
	WaitForConcurrentGcToComplete();
	ptr = space->AllocWithoutGrowth(size);
	if (ptr != NULL) {
	return ptr;
	}
	}

	// Another failure. Our thread was starved or there may be too many
	// live objects. Try a foreground GC. This will have no effect if
	// the concurrent GC is already running.
	CollectGarbageInternal();
	ptr = space->AllocWithoutGrowth(size);
	if (ptr != NULL) {
	return ptr;
	}

	// Even that didn't work; this is an exceptional state.
	// Try harder, growing the heap if necessary.
	ptr = space->AllocWithGrowth(size);
	if (ptr != NULL) {
	//size_t new_footprint = dvmHeapSourceGetIdealFootprint();
	size_t new_footprint = space->MaxAllowedFootprint();
	// TODO: may want to grow a little bit more so that the amount of
	// free space is equal to the old free space + the
	// utilization slop for the new allocation.
	LOG(INFO) << "Grow heap (frag case) to " << new_footprint / MB
	<< "for " << size << "-byte allocation";
	return ptr;
	}

	// Most allocations should have succeeded by now, so the heap is
	// really full, really fragmented, or the requested size is really
	// big. Do another GC, collecting SoftReferences this time. The VM
	// spec requires that all SoftReferences have been collected and
	// cleared before throwing an OOME.

	// TODO: wait for the finalizers from the previous GC to finish
	LOG(INFO) << "Forcing collection of SoftReferences for "
	<< size << "-byte allocation";
	CollectGarbageInternal();
	ptr = space->AllocWithGrowth(size);
	if (ptr != NULL) {
	return ptr;
	}

	LOG(ERROR) << "Out of memory on a " << size << " byte allocation";

	// TODO: tell the HeapSource to dump its state
	// TODO: dump stack traces for all threads

	return NULL;
	}

	void Heap::CollectGarbage() {
	CollectGarbageInternal();
	}

	void Heap::CollectGarbageInternal() {
	// TODO: check that heap lock is held

	// TODO: Suspend all threads
	{
	MarkSweep mark_sweep;

	mark_sweep.Init();

	mark_sweep.MarkRoots();

	// Push marked roots onto the mark stack

	// TODO: if concurrent
	// unlock heap
	// resume threads

	mark_sweep.RecursiveMark();

	// TODO: if concurrent
	// lock heap
	// suspend threads
	// re-mark root set
	// scan dirty objects

	mark_sweep.ProcessReferences(false);

	// TODO: swap bitmaps

	mark_sweep.Sweep();
	}

	GrowForUtilization();

	// TODO: Resume all threads
	}

	void Heap::WaitForConcurrentGcToComplete() {
	}

	// Given the current contents of the active heap, increase the allowed
	// heap footprint to match the target utilization ratio. This should
	// only be called immediately after a full garbage collection.
	void Heap::GrowForUtilization() {
	LOG(ERROR) << "Unimplemented";
	}

	} // namespace art