runtime/gc/space/space_test.cc - platform/art - Git at Google

 /*
  * Copyright (C) 2011 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "dlmalloc_space.h"
 #include "large_object_space.h"

 #include "common_test.h"
 #include "globals.h"
 #include "UniquePtr.h"

 #include <stdint.h>

 namespace art {
 namespace gc {
 namespace space {

 class SpaceTest : public CommonTest {
  public:
   void SizeFootPrintGrowthLimitAndTrimBody(DlMallocSpace* space, intptr_t object_size,
                                            int round, size_t growth_limit);
   void SizeFootPrintGrowthLimitAndTrimDriver(size_t object_size);

   void AddContinuousSpace(ContinuousSpace* space) {
     Runtime::Current()->GetHeap()->AddContinuousSpace(space);
   }
 };

 static size_t test_rand(size_t* seed) {
   *seed = *seed * 1103515245 + 12345;
   return *seed;
 }

 TEST_F(SpaceTest, Init) {
   {
     // Init < max == growth
     UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 32 * MB, 32 * MB, NULL));
     EXPECT_TRUE(space.get() != NULL);
   }
   {
     // Init == max == growth
     UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 16 * MB, 16 * MB, NULL));
     EXPECT_TRUE(space.get() != NULL);
   }
   {
     // Init > max == growth
     UniquePtr<Space> space(DlMallocSpace::Create("test", 32 * MB, 16 * MB, 16 * MB, NULL));
     EXPECT_TRUE(space.get() == NULL);
   }
   {
     // Growth == init < max
     UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 16 * MB, 32 * MB, NULL));
     EXPECT_TRUE(space.get() != NULL);
   }
   {
     // Growth < init < max
     UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 8 * MB, 32 * MB, NULL));
     EXPECT_TRUE(space.get() == NULL);
   }
   {
     // Init < growth < max
     UniquePtr<Space> space(DlMallocSpace::Create("test", 8 * MB, 16 * MB, 32 * MB, NULL));
     EXPECT_TRUE(space.get() != NULL);
   }
   {
     // Init < max < growth
     UniquePtr<Space> space(DlMallocSpace::Create("test", 8 * MB, 32 * MB, 16 * MB, NULL));
     EXPECT_TRUE(space.get() == NULL);
   }
 }

 // TODO: This test is not very good, we should improve it.
 // The test should do more allocations before the creation of the ZygoteSpace, and then do
 // allocations after the ZygoteSpace is created. The test should also do some GCs to ensure that
 // the GC works with the ZygoteSpace.
 TEST_F(SpaceTest, ZygoteSpace) {
     size_t dummy = 0;
     DlMallocSpace* space(DlMallocSpace::Create("test", 4 * MB, 16 * MB, 16 * MB, NULL));
     ASSERT_TRUE(space != NULL);

     // Make space findable to the heap, will also delete space when runtime is cleaned up
     AddContinuousSpace(space);
     Thread* self = Thread::Current();

     // Succeeds, fits without adjusting the footprint limit.
     mirror::Object* ptr1 = space->Alloc(self, 1 * MB, &dummy);
     EXPECT_TRUE(ptr1 != NULL);

     // Fails, requires a higher footprint limit.
     mirror::Object* ptr2 = space->Alloc(self, 8 * MB, &dummy);
     EXPECT_TRUE(ptr2 == NULL);

     // Succeeds, adjusts the footprint.
     size_t ptr3_bytes_allocated;
     mirror::Object* ptr3 = space->AllocWithGrowth(self, 8 * MB, &ptr3_bytes_allocated);
     EXPECT_TRUE(ptr3 != NULL);
     EXPECT_LE(8U * MB, ptr3_bytes_allocated);

     // Fails, requires a higher footprint limit.
     mirror::Object* ptr4 = space->Alloc(self, 8 * MB, &dummy);
     EXPECT_TRUE(ptr4 == NULL);

     // Also fails, requires a higher allowed footprint.
     mirror::Object* ptr5 = space->AllocWithGrowth(self, 8 * MB, &dummy);
     EXPECT_TRUE(ptr5 == NULL);

     // Release some memory.
     size_t free3 = space->AllocationSize(ptr3);
     EXPECT_EQ(free3, ptr3_bytes_allocated);
     EXPECT_EQ(free3, space->Free(self, ptr3));
     EXPECT_LE(8U * MB, free3);

     // Succeeds, now that memory has been freed.
     void* ptr6 = space->AllocWithGrowth(self, 9 * MB, &dummy);
     EXPECT_TRUE(ptr6 != NULL);

     // Final clean up.
     size_t free1 = space->AllocationSize(ptr1);
     space->Free(self, ptr1);
     EXPECT_LE(1U * MB, free1);

     // Make sure that the zygote space isn't directly at the start of the space.
     space->Alloc(self, 1U * MB, &dummy);
     space = space->CreateZygoteSpace("alloc space");

     // Make space findable to the heap, will also delete space when runtime is cleaned up
     AddContinuousSpace(space);

     // Succeeds, fits without adjusting the footprint limit.
     ptr1 = space->Alloc(self, 1 * MB, &dummy);
     EXPECT_TRUE(ptr1 != NULL);

     // Fails, requires a higher footprint limit.
     ptr2 = space->Alloc(self, 8 * MB, &dummy);
     EXPECT_TRUE(ptr2 == NULL);

     // Succeeds, adjusts the footprint.
     ptr3 = space->AllocWithGrowth(self, 2 * MB, &dummy);
     EXPECT_TRUE(ptr3 != NULL);
     space->Free(self, ptr3);

     // Final clean up.
     free1 = space->AllocationSize(ptr1);
     space->Free(self, ptr1);
     EXPECT_LE(1U * MB, free1);
 }

 TEST_F(SpaceTest, AllocAndFree) {
   size_t dummy = 0;
   DlMallocSpace* space(DlMallocSpace::Create("test", 4 * MB, 16 * MB, 16 * MB, NULL));
   ASSERT_TRUE(space != NULL);
   Thread* self = Thread::Current();

   // Make space findable to the heap, will also delete space when runtime is cleaned up
   AddContinuousSpace(space);

   // Succeeds, fits without adjusting the footprint limit.
   mirror::Object* ptr1 = space->Alloc(self, 1 * MB, &dummy);
   EXPECT_TRUE(ptr1 != NULL);

   // Fails, requires a higher footprint limit.
   mirror::Object* ptr2 = space->Alloc(self, 8 * MB, &dummy);
   EXPECT_TRUE(ptr2 == NULL);

   // Succeeds, adjusts the footprint.
   size_t ptr3_bytes_allocated;
   mirror::Object* ptr3 = space->AllocWithGrowth(self, 8 * MB, &ptr3_bytes_allocated);
   EXPECT_TRUE(ptr3 != NULL);
   EXPECT_LE(8U * MB, ptr3_bytes_allocated);

   // Fails, requires a higher footprint limit.
   mirror::Object* ptr4 = space->Alloc(self, 8 * MB, &dummy);
   EXPECT_TRUE(ptr4 == NULL);

   // Also fails, requires a higher allowed footprint.
   mirror::Object* ptr5 = space->AllocWithGrowth(self, 8 * MB, &dummy);
   EXPECT_TRUE(ptr5 == NULL);

   // Release some memory.
   size_t free3 = space->AllocationSize(ptr3);
   EXPECT_EQ(free3, ptr3_bytes_allocated);
   space->Free(self, ptr3);
   EXPECT_LE(8U * MB, free3);

   // Succeeds, now that memory has been freed.
   void* ptr6 = space->AllocWithGrowth(self, 9 * MB, &dummy);
   EXPECT_TRUE(ptr6 != NULL);

   // Final clean up.
   size_t free1 = space->AllocationSize(ptr1);
   space->Free(self, ptr1);
   EXPECT_LE(1U * MB, free1);
 }

 TEST_F(SpaceTest, LargeObjectTest) {
   size_t rand_seed = 0;
   for (size_t i = 0; i < 2; ++i) {
     LargeObjectSpace* los = NULL;
     if (i == 0) {
       los = space::LargeObjectMapSpace::Create("large object space");
     } else {
       los = space::FreeListSpace::Create("large object space", NULL, 128 * MB);
     }

     static const size_t num_allocations = 64;
     static const size_t max_allocation_size = 0x100000;
     std::vector<std::pair<mirror::Object*, size_t> > requests;

     for (size_t phase = 0; phase < 2; ++phase) {
       while (requests.size() < num_allocations) {
         size_t request_size = test_rand(&rand_seed) % max_allocation_size;
         size_t allocation_size = 0;
         mirror::Object* obj = los->Alloc(Thread::Current(), request_size, &allocation_size);
         ASSERT_TRUE(obj != NULL);
         ASSERT_EQ(allocation_size, los->AllocationSize(obj));
         ASSERT_GE(allocation_size, request_size);
         // Fill in our magic value.
         byte magic = (request_size & 0xFF) | 1;
         memset(obj, magic, request_size);
         requests.push_back(std::make_pair(obj, request_size));
       }

       // "Randomly" shuffle the requests.
       for (size_t k = 0; k < 10; ++k) {
         for (size_t j = 0; j < requests.size(); ++j) {
           std::swap(requests[j], requests[test_rand(&rand_seed) % requests.size()]);
         }
       }

       // Free 1 / 2 the allocations the first phase, and all the second phase.
       size_t limit = !phase ? requests.size() / 2 : 0;
       while (requests.size() > limit) {
         mirror::Object* obj = requests.back().first;
         size_t request_size = requests.back().second;
         requests.pop_back();
         byte magic = (request_size & 0xFF) | 1;
         for (size_t k = 0; k < request_size; ++k) {
           ASSERT_EQ(reinterpret_cast<const byte*>(obj)[k], magic);
         }
         ASSERT_GE(los->Free(Thread::Current(), obj), request_size);
       }
     }

     size_t bytes_allocated = 0;
     // Checks that the coalescing works.
     mirror::Object* obj = los->Alloc(Thread::Current(), 100 * MB, &bytes_allocated);
     EXPECT_TRUE(obj != NULL);
     los->Free(Thread::Current(), obj);

     EXPECT_EQ(0U, los->GetBytesAllocated());
     EXPECT_EQ(0U, los->GetObjectsAllocated());
     delete los;
   }
 }

 TEST_F(SpaceTest, AllocAndFreeList) {
   DlMallocSpace* space(DlMallocSpace::Create("test", 4 * MB, 16 * MB, 16 * MB, NULL));
   ASSERT_TRUE(space != NULL);

   // Make space findable to the heap, will also delete space when runtime is cleaned up
   AddContinuousSpace(space);
   Thread* self = Thread::Current();

   // Succeeds, fits without adjusting the max allowed footprint.
   mirror::Object* lots_of_objects[1024];
   for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
     size_t allocation_size = 0;
     lots_of_objects[i] = space->Alloc(self, 16, &allocation_size);
     EXPECT_EQ(allocation_size, space->AllocationSize(lots_of_objects[i]));
     EXPECT_TRUE(lots_of_objects[i] != NULL);
   }

   // Release memory and check pointers are NULL
   space->FreeList(self, arraysize(lots_of_objects), lots_of_objects);
   for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
     EXPECT_TRUE(lots_of_objects[i] == NULL);
   }

   // Succeeds, fits by adjusting the max allowed footprint.
   for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
     size_t allocation_size = 0;
     lots_of_objects[i] = space->AllocWithGrowth(self, 1024, &allocation_size);
     EXPECT_EQ(allocation_size, space->AllocationSize(lots_of_objects[i]));
     EXPECT_TRUE(lots_of_objects[i] != NULL);
   }

   // Release memory and check pointers are NULL
   space->FreeList(self, arraysize(lots_of_objects), lots_of_objects);
   for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
     EXPECT_TRUE(lots_of_objects[i] == NULL);
   }
 }

 void SpaceTest::SizeFootPrintGrowthLimitAndTrimBody(DlMallocSpace* space, intptr_t object_size,
                                                     int round, size_t growth_limit) {
   if (((object_size > 0 && object_size >= static_cast<intptr_t>(growth_limit))) ||
       ((object_size < 0 && -object_size >= static_cast<intptr_t>(growth_limit)))) {
     // No allocation can succeed
     return;
   }
   // Mspace for raw dlmalloc operations
   void* mspace = space->GetMspace();

   // mspace's footprint equals amount of resources requested from system
   size_t footprint = mspace_footprint(mspace);

   // mspace must at least have its book keeping allocated
   EXPECT_GT(footprint, 0u);

   // mspace but it shouldn't exceed the initial size
   EXPECT_LE(footprint, growth_limit);

   // space's size shouldn't exceed the initial size
   EXPECT_LE(space->Size(), growth_limit);

   // this invariant should always hold or else the mspace has grown to be larger than what the
   // space believes its size is (which will break invariants)
   EXPECT_GE(space->Size(), footprint);

   // Fill the space with lots of small objects up to the growth limit
   size_t max_objects = (growth_limit / (object_size > 0 ? object_size : 8)) + 1;
   UniquePtr<mirror::Object*[]> lots_of_objects(new mirror::Object*[max_objects]);
   size_t last_object = 0;  // last object for which allocation succeeded
   size_t amount_allocated = 0;  // amount of space allocated
   Thread* self = Thread::Current();
   size_t rand_seed = 123456789;
   for (size_t i = 0; i < max_objects; i++) {
     size_t alloc_fails = 0;  // number of failed allocations
     size_t max_fails = 30;  // number of times we fail allocation before giving up
     for (; alloc_fails < max_fails; alloc_fails++) {
       size_t alloc_size;
       if (object_size > 0) {
         alloc_size = object_size;
       } else {
         alloc_size = test_rand(&rand_seed) % static_cast<size_t>(-object_size);
         if (alloc_size < 8) {
           alloc_size = 8;
         }
       }
       mirror::Object* object;
       size_t bytes_allocated = 0;
       if (round <= 1) {
         object = space->Alloc(self, alloc_size, &bytes_allocated);
       } else {
         object = space->AllocWithGrowth(self, alloc_size, &bytes_allocated);
       }
       footprint = mspace_footprint(mspace);
       EXPECT_GE(space->Size(), footprint);  // invariant
       if (object != NULL) {  // allocation succeeded
         lots_of_objects.get()[i] = object;
         size_t allocation_size = space->AllocationSize(object);
         EXPECT_EQ(bytes_allocated, allocation_size);
         if (object_size > 0) {
           EXPECT_GE(allocation_size, static_cast<size_t>(object_size));
         } else {
           EXPECT_GE(allocation_size, 8u);
         }
         amount_allocated += allocation_size;
         break;
       }
     }
     if (alloc_fails == max_fails) {
       last_object = i;
       break;
     }
   }
   CHECK_NE(last_object, 0u);  // we should have filled the space
   EXPECT_GT(amount_allocated, 0u);

   // We shouldn't have gone past the growth_limit
   EXPECT_LE(amount_allocated, growth_limit);
   EXPECT_LE(footprint, growth_limit);
   EXPECT_LE(space->Size(), growth_limit);

   // footprint and size should agree with amount allocated
   EXPECT_GE(footprint, amount_allocated);
   EXPECT_GE(space->Size(), amount_allocated);

   // Release storage in a semi-adhoc manner
   size_t free_increment = 96;
   while (true) {
     // Give the space a haircut
     space->Trim();

     // Bounds sanity
     footprint = mspace_footprint(mspace);
     EXPECT_LE(amount_allocated, growth_limit);
     EXPECT_GE(footprint, amount_allocated);
     EXPECT_LE(footprint, growth_limit);
     EXPECT_GE(space->Size(), amount_allocated);
     EXPECT_LE(space->Size(), growth_limit);

     if (free_increment == 0) {
       break;
     }

     // Free some objects
     for (size_t i = 0; i < last_object; i += free_increment) {
       mirror::Object* object = lots_of_objects.get()[i];
       if (object == NULL) {
         continue;
       }
       size_t allocation_size = space->AllocationSize(object);
       if (object_size > 0) {
         EXPECT_GE(allocation_size, static_cast<size_t>(object_size));
       } else {
         EXPECT_GE(allocation_size, 8u);
       }
       space->Free(self, object);
       lots_of_objects.get()[i] = NULL;
       amount_allocated -= allocation_size;
       footprint = mspace_footprint(mspace);
       EXPECT_GE(space->Size(), footprint);  // invariant
     }

     free_increment >>= 1;
   }

   // All memory was released, try a large allocation to check freed memory is being coalesced
   mirror::Object* large_object;
   size_t three_quarters_space = (growth_limit / 2) + (growth_limit / 4);
   size_t bytes_allocated = 0;
   if (round <= 1) {
     large_object = space->Alloc(self, three_quarters_space, &bytes_allocated);
   } else {
     large_object = space->AllocWithGrowth(self, three_quarters_space, &bytes_allocated);
   }
   EXPECT_TRUE(large_object != NULL);

   // Sanity check footprint
   footprint = mspace_footprint(mspace);
   EXPECT_LE(footprint, growth_limit);
   EXPECT_GE(space->Size(), footprint);
   EXPECT_LE(space->Size(), growth_limit);

   // Clean up
   space->Free(self, large_object);

   // Sanity check footprint
   footprint = mspace_footprint(mspace);
   EXPECT_LE(footprint, growth_limit);
   EXPECT_GE(space->Size(), footprint);
   EXPECT_LE(space->Size(), growth_limit);
 }

 void SpaceTest::SizeFootPrintGrowthLimitAndTrimDriver(size_t object_size) {
   size_t initial_size = 4 * MB;
   size_t growth_limit = 8 * MB;
   size_t capacity = 16 * MB;
   DlMallocSpace* space(DlMallocSpace::Create("test", initial_size, growth_limit, capacity, NULL));
   ASSERT_TRUE(space != NULL);

   // Basic sanity
   EXPECT_EQ(space->Capacity(), growth_limit);
   EXPECT_EQ(space->NonGrowthLimitCapacity(), capacity);

   // Make space findable to the heap, will also delete space when runtime is cleaned up
   AddContinuousSpace(space);

   // In this round we don't allocate with growth and therefore can't grow past the initial size.
   // This effectively makes the growth_limit the initial_size, so assert this.
   SizeFootPrintGrowthLimitAndTrimBody(space, object_size, 1, initial_size);
   SizeFootPrintGrowthLimitAndTrimBody(space, object_size, 2, growth_limit);
   // Remove growth limit
   space->ClearGrowthLimit();
   EXPECT_EQ(space->Capacity(), capacity);
   SizeFootPrintGrowthLimitAndTrimBody(space, object_size, 3, capacity);
 }

 #define TEST_SizeFootPrintGrowthLimitAndTrim(name, size) \
   TEST_F(SpaceTest, SizeFootPrintGrowthLimitAndTrim_AllocationsOf_##name) { \
     SizeFootPrintGrowthLimitAndTrimDriver(size); \
   } \
   TEST_F(SpaceTest, SizeFootPrintGrowthLimitAndTrim_RandomAllocationsWithMax_##name) { \
     SizeFootPrintGrowthLimitAndTrimDriver(-size); \
   }

 // Each size test is its own test so that we get a fresh heap each time
 TEST_F(SpaceTest, SizeFootPrintGrowthLimitAndTrim_AllocationsOf_8B) {
   SizeFootPrintGrowthLimitAndTrimDriver(8);
 }
 TEST_SizeFootPrintGrowthLimitAndTrim(16B, 16)
 TEST_SizeFootPrintGrowthLimitAndTrim(24B, 24)
 TEST_SizeFootPrintGrowthLimitAndTrim(32B, 32)
 TEST_SizeFootPrintGrowthLimitAndTrim(64B, 64)
 TEST_SizeFootPrintGrowthLimitAndTrim(128B, 128)
 TEST_SizeFootPrintGrowthLimitAndTrim(1KB, 1 * KB)
 TEST_SizeFootPrintGrowthLimitAndTrim(4KB, 4 * KB)
 TEST_SizeFootPrintGrowthLimitAndTrim(1MB, 1 * MB)
 TEST_SizeFootPrintGrowthLimitAndTrim(4MB, 4 * MB)
 TEST_SizeFootPrintGrowthLimitAndTrim(8MB, 8 * MB)

 }  // namespace space
 }  // namespace gc
 }  // namespace art
	/*
	* Copyright (C) 2011 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "dlmalloc_space.h"
	#include "large_object_space.h"

	#include "common_test.h"
	#include "globals.h"
	#include "UniquePtr.h"

	#include <stdint.h>

	namespace art {
	namespace gc {
	namespace space {

	class SpaceTest : public CommonTest {
	public:
	void SizeFootPrintGrowthLimitAndTrimBody(DlMallocSpace* space, intptr_t object_size,
	int round, size_t growth_limit);
	void SizeFootPrintGrowthLimitAndTrimDriver(size_t object_size);

	void AddContinuousSpace(ContinuousSpace* space) {
	Runtime::Current()->GetHeap()->AddContinuousSpace(space);
	}
	};

	static size_t test_rand(size_t* seed) {
	seed = seed * 1103515245 + 12345;
	return *seed;
	}

	TEST_F(SpaceTest, Init) {
	{
	// Init < max == growth
	UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 32 * MB, 32 * MB, NULL));
	EXPECT_TRUE(space.get() != NULL);
	}
	{
	// Init == max == growth
	UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 16 * MB, 16 * MB, NULL));
	EXPECT_TRUE(space.get() != NULL);
	}
	{
	// Init > max == growth
	UniquePtr<Space> space(DlMallocSpace::Create("test", 32 * MB, 16 * MB, 16 * MB, NULL));
	EXPECT_TRUE(space.get() == NULL);
	}
	{
	// Growth == init < max
	UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 16 * MB, 32 * MB, NULL));
	EXPECT_TRUE(space.get() != NULL);
	}
	{
	// Growth < init < max
	UniquePtr<Space> space(DlMallocSpace::Create("test", 16 * MB, 8 * MB, 32 * MB, NULL));
	EXPECT_TRUE(space.get() == NULL);
	}
	{
	// Init < growth < max
	UniquePtr<Space> space(DlMallocSpace::Create("test", 8 * MB, 16 * MB, 32 * MB, NULL));
	EXPECT_TRUE(space.get() != NULL);
	}
	{
	// Init < max < growth
	UniquePtr<Space> space(DlMallocSpace::Create("test", 8 * MB, 32 * MB, 16 * MB, NULL));
	EXPECT_TRUE(space.get() == NULL);
	}
	}

	// TODO: This test is not very good, we should improve it.
	// The test should do more allocations before the creation of the ZygoteSpace, and then do
	// allocations after the ZygoteSpace is created. The test should also do some GCs to ensure that
	// the GC works with the ZygoteSpace.
	TEST_F(SpaceTest, ZygoteSpace) {
	size_t dummy = 0;
	DlMallocSpace* space(DlMallocSpace::Create("test", 4 * MB, 16 * MB, 16 * MB, NULL));
	ASSERT_TRUE(space != NULL);

	// Make space findable to the heap, will also delete space when runtime is cleaned up
	AddContinuousSpace(space);
	Thread* self = Thread::Current();

	// Succeeds, fits without adjusting the footprint limit.
	mirror::Object* ptr1 = space->Alloc(self, 1 * MB, &dummy);
	EXPECT_TRUE(ptr1 != NULL);

	// Fails, requires a higher footprint limit.
	mirror::Object* ptr2 = space->Alloc(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr2 == NULL);

	// Succeeds, adjusts the footprint.
	size_t ptr3_bytes_allocated;
	mirror::Object* ptr3 = space->AllocWithGrowth(self, 8 * MB, &ptr3_bytes_allocated);
	EXPECT_TRUE(ptr3 != NULL);
	EXPECT_LE(8U * MB, ptr3_bytes_allocated);

	// Fails, requires a higher footprint limit.
	mirror::Object* ptr4 = space->Alloc(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr4 == NULL);

	// Also fails, requires a higher allowed footprint.
	mirror::Object* ptr5 = space->AllocWithGrowth(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr5 == NULL);

	// Release some memory.
	size_t free3 = space->AllocationSize(ptr3);
	EXPECT_EQ(free3, ptr3_bytes_allocated);
	EXPECT_EQ(free3, space->Free(self, ptr3));
	EXPECT_LE(8U * MB, free3);

	// Succeeds, now that memory has been freed.
	void* ptr6 = space->AllocWithGrowth(self, 9 * MB, &dummy);
	EXPECT_TRUE(ptr6 != NULL);

	// Final clean up.
	size_t free1 = space->AllocationSize(ptr1);
	space->Free(self, ptr1);
	EXPECT_LE(1U * MB, free1);

	// Make sure that the zygote space isn't directly at the start of the space.
	space->Alloc(self, 1U * MB, &dummy);
	space = space->CreateZygoteSpace("alloc space");

	// Make space findable to the heap, will also delete space when runtime is cleaned up
	AddContinuousSpace(space);

	// Succeeds, fits without adjusting the footprint limit.
	ptr1 = space->Alloc(self, 1 * MB, &dummy);
	EXPECT_TRUE(ptr1 != NULL);

	// Fails, requires a higher footprint limit.
	ptr2 = space->Alloc(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr2 == NULL);

	// Succeeds, adjusts the footprint.
	ptr3 = space->AllocWithGrowth(self, 2 * MB, &dummy);
	EXPECT_TRUE(ptr3 != NULL);
	space->Free(self, ptr3);

	// Final clean up.
	free1 = space->AllocationSize(ptr1);
	space->Free(self, ptr1);
	EXPECT_LE(1U * MB, free1);
	}

	TEST_F(SpaceTest, AllocAndFree) {
	size_t dummy = 0;
	DlMallocSpace* space(DlMallocSpace::Create("test", 4 * MB, 16 * MB, 16 * MB, NULL));
	ASSERT_TRUE(space != NULL);
	Thread* self = Thread::Current();

	// Make space findable to the heap, will also delete space when runtime is cleaned up
	AddContinuousSpace(space);

	// Succeeds, fits without adjusting the footprint limit.
	mirror::Object* ptr1 = space->Alloc(self, 1 * MB, &dummy);
	EXPECT_TRUE(ptr1 != NULL);

	// Fails, requires a higher footprint limit.
	mirror::Object* ptr2 = space->Alloc(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr2 == NULL);

	// Succeeds, adjusts the footprint.
	size_t ptr3_bytes_allocated;
	mirror::Object* ptr3 = space->AllocWithGrowth(self, 8 * MB, &ptr3_bytes_allocated);
	EXPECT_TRUE(ptr3 != NULL);
	EXPECT_LE(8U * MB, ptr3_bytes_allocated);

	// Fails, requires a higher footprint limit.
	mirror::Object* ptr4 = space->Alloc(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr4 == NULL);

	// Also fails, requires a higher allowed footprint.
	mirror::Object* ptr5 = space->AllocWithGrowth(self, 8 * MB, &dummy);
	EXPECT_TRUE(ptr5 == NULL);

	// Release some memory.
	size_t free3 = space->AllocationSize(ptr3);
	EXPECT_EQ(free3, ptr3_bytes_allocated);
	space->Free(self, ptr3);
	EXPECT_LE(8U * MB, free3);

	// Succeeds, now that memory has been freed.
	void* ptr6 = space->AllocWithGrowth(self, 9 * MB, &dummy);
	EXPECT_TRUE(ptr6 != NULL);

	// Final clean up.
	size_t free1 = space->AllocationSize(ptr1);
	space->Free(self, ptr1);
	EXPECT_LE(1U * MB, free1);
	}

	TEST_F(SpaceTest, LargeObjectTest) {
	size_t rand_seed = 0;
	for (size_t i = 0; i < 2; ++i) {
	LargeObjectSpace* los = NULL;
	if (i == 0) {
	los = space::LargeObjectMapSpace::Create("large object space");
	} else {
	los = space::FreeListSpace::Create("large object space", NULL, 128 * MB);
	}

	static const size_t num_allocations = 64;
	static const size_t max_allocation_size = 0x100000;
	std::vector<std::pair<mirror::Object*, size_t> > requests;

	for (size_t phase = 0; phase < 2; ++phase) {
	while (requests.size() < num_allocations) {
	size_t request_size = test_rand(&rand_seed) % max_allocation_size;
	size_t allocation_size = 0;
	mirror::Object* obj = los->Alloc(Thread::Current(), request_size, &allocation_size);
	ASSERT_TRUE(obj != NULL);
	ASSERT_EQ(allocation_size, los->AllocationSize(obj));
	ASSERT_GE(allocation_size, request_size);
	// Fill in our magic value.
	byte magic = (request_size & 0xFF) \| 1;
	memset(obj, magic, request_size);
	requests.push_back(std::make_pair(obj, request_size));
	}

	// "Randomly" shuffle the requests.
	for (size_t k = 0; k < 10; ++k) {
	for (size_t j = 0; j < requests.size(); ++j) {
	std::swap(requests[j], requests[test_rand(&rand_seed) % requests.size()]);
	}
	}

	// Free 1 / 2 the allocations the first phase, and all the second phase.
	size_t limit = !phase ? requests.size() / 2 : 0;
	while (requests.size() > limit) {
	mirror::Object* obj = requests.back().first;
	size_t request_size = requests.back().second;
	requests.pop_back();
	byte magic = (request_size & 0xFF) \| 1;
	for (size_t k = 0; k < request_size; ++k) {
	ASSERT_EQ(reinterpret_cast<const byte*>(obj)[k], magic);
	}
	ASSERT_GE(los->Free(Thread::Current(), obj), request_size);
	}
	}

	size_t bytes_allocated = 0;
	// Checks that the coalescing works.
	mirror::Object* obj = los->Alloc(Thread::Current(), 100 * MB, &bytes_allocated);
	EXPECT_TRUE(obj != NULL);
	los->Free(Thread::Current(), obj);

	EXPECT_EQ(0U, los->GetBytesAllocated());
	EXPECT_EQ(0U, los->GetObjectsAllocated());
	delete los;
	}
	}

	TEST_F(SpaceTest, AllocAndFreeList) {
	DlMallocSpace* space(DlMallocSpace::Create("test", 4 * MB, 16 * MB, 16 * MB, NULL));
	ASSERT_TRUE(space != NULL);

	// Make space findable to the heap, will also delete space when runtime is cleaned up
	AddContinuousSpace(space);
	Thread* self = Thread::Current();

	// Succeeds, fits without adjusting the max allowed footprint.
	mirror::Object* lots_of_objects[1024];
	for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
	size_t allocation_size = 0;
	lots_of_objects[i] = space->Alloc(self, 16, &allocation_size);
	EXPECT_EQ(allocation_size, space->AllocationSize(lots_of_objects[i]));
	EXPECT_TRUE(lots_of_objects[i] != NULL);
	}

	// Release memory and check pointers are NULL
	space->FreeList(self, arraysize(lots_of_objects), lots_of_objects);
	for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
	EXPECT_TRUE(lots_of_objects[i] == NULL);
	}

	// Succeeds, fits by adjusting the max allowed footprint.
	for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
	size_t allocation_size = 0;
	lots_of_objects[i] = space->AllocWithGrowth(self, 1024, &allocation_size);
	EXPECT_EQ(allocation_size, space->AllocationSize(lots_of_objects[i]));
	EXPECT_TRUE(lots_of_objects[i] != NULL);
	}

	// Release memory and check pointers are NULL
	space->FreeList(self, arraysize(lots_of_objects), lots_of_objects);
	for (size_t i = 0; i < arraysize(lots_of_objects); i++) {
	EXPECT_TRUE(lots_of_objects[i] == NULL);
	}
	}

	void SpaceTest::SizeFootPrintGrowthLimitAndTrimBody(DlMallocSpace* space, intptr_t object_size,
	int round, size_t growth_limit) {
	if (((object_size > 0 && object_size >= static_cast<intptr_t>(growth_limit))) \|\|
	((object_size < 0 && -object_size >= static_cast<intptr_t>(growth_limit)))) {
	// No allocation can succeed
	return;
	}
	// Mspace for raw dlmalloc operations
	void* mspace = space->GetMspace();

	// mspace's footprint equals amount of resources requested from system
	size_t footprint = mspace_footprint(mspace);

	// mspace must at least have its book keeping allocated
	EXPECT_GT(footprint, 0u);

	// mspace but it shouldn't exceed the initial size
	EXPECT_LE(footprint, growth_limit);

	// space's size shouldn't exceed the initial size
	EXPECT_LE(space->Size(), growth_limit);

	// this invariant should always hold or else the mspace has grown to be larger than what the
	// space believes its size is (which will break invariants)
	EXPECT_GE(space->Size(), footprint);

	// Fill the space with lots of small objects up to the growth limit
	size_t max_objects = (growth_limit / (object_size > 0 ? object_size : 8)) + 1;
	UniquePtr<mirror::Object[]> lots_of_objects(new mirror::Object[max_objects]);
	size_t last_object = 0; // last object for which allocation succeeded
	size_t amount_allocated = 0; // amount of space allocated
	Thread* self = Thread::Current();
	size_t rand_seed = 123456789;
	for (size_t i = 0; i < max_objects; i++) {
	size_t alloc_fails = 0; // number of failed allocations
	size_t max_fails = 30; // number of times we fail allocation before giving up
	for (; alloc_fails < max_fails; alloc_fails++) {
	size_t alloc_size;
	if (object_size > 0) {
	alloc_size = object_size;
	} else {
	alloc_size = test_rand(&rand_seed) % static_cast<size_t>(-object_size);
	if (alloc_size < 8) {
	alloc_size = 8;
	}
	}
	mirror::Object* object;
	size_t bytes_allocated = 0;
	if (round <= 1) {
	object = space->Alloc(self, alloc_size, &bytes_allocated);
	} else {
	object = space->AllocWithGrowth(self, alloc_size, &bytes_allocated);
	}
	footprint = mspace_footprint(mspace);
	EXPECT_GE(space->Size(), footprint); // invariant
	if (object != NULL) { // allocation succeeded
	lots_of_objects.get()[i] = object;
	size_t allocation_size = space->AllocationSize(object);
	EXPECT_EQ(bytes_allocated, allocation_size);
	if (object_size > 0) {
	EXPECT_GE(allocation_size, static_cast<size_t>(object_size));
	} else {
	EXPECT_GE(allocation_size, 8u);
	}
	amount_allocated += allocation_size;
	break;
	}
	}
	if (alloc_fails == max_fails) {
	last_object = i;
	break;
	}
	}
	CHECK_NE(last_object, 0u); // we should have filled the space
	EXPECT_GT(amount_allocated, 0u);

	// We shouldn't have gone past the growth_limit
	EXPECT_LE(amount_allocated, growth_limit);
	EXPECT_LE(footprint, growth_limit);
	EXPECT_LE(space->Size(), growth_limit);

	// footprint and size should agree with amount allocated
	EXPECT_GE(footprint, amount_allocated);
	EXPECT_GE(space->Size(), amount_allocated);

	// Release storage in a semi-adhoc manner
	size_t free_increment = 96;
	while (true) {
	// Give the space a haircut
	space->Trim();

	// Bounds sanity
	footprint = mspace_footprint(mspace);
	EXPECT_LE(amount_allocated, growth_limit);
	EXPECT_GE(footprint, amount_allocated);
	EXPECT_LE(footprint, growth_limit);
	EXPECT_GE(space->Size(), amount_allocated);
	EXPECT_LE(space->Size(), growth_limit);

	if (free_increment == 0) {
	break;
	}

	// Free some objects
	for (size_t i = 0; i < last_object; i += free_increment) {
	mirror::Object* object = lots_of_objects.get()[i];
	if (object == NULL) {
	continue;
	}
	size_t allocation_size = space->AllocationSize(object);
	if (object_size > 0) {
	EXPECT_GE(allocation_size, static_cast<size_t>(object_size));
	} else {
	EXPECT_GE(allocation_size, 8u);
	}
	space->Free(self, object);
	lots_of_objects.get()[i] = NULL;
	amount_allocated -= allocation_size;
	footprint = mspace_footprint(mspace);
	EXPECT_GE(space->Size(), footprint); // invariant
	}

	free_increment >>= 1;
	}

	// All memory was released, try a large allocation to check freed memory is being coalesced
	mirror::Object* large_object;
	size_t three_quarters_space = (growth_limit / 2) + (growth_limit / 4);
	size_t bytes_allocated = 0;
	if (round <= 1) {
	large_object = space->Alloc(self, three_quarters_space, &bytes_allocated);
	} else {
	large_object = space->AllocWithGrowth(self, three_quarters_space, &bytes_allocated);
	}
	EXPECT_TRUE(large_object != NULL);

	// Sanity check footprint
	footprint = mspace_footprint(mspace);
	EXPECT_LE(footprint, growth_limit);
	EXPECT_GE(space->Size(), footprint);
	EXPECT_LE(space->Size(), growth_limit);

	// Clean up
	space->Free(self, large_object);

	// Sanity check footprint
	footprint = mspace_footprint(mspace);
	EXPECT_LE(footprint, growth_limit);
	EXPECT_GE(space->Size(), footprint);
	EXPECT_LE(space->Size(), growth_limit);
	}

	void SpaceTest::SizeFootPrintGrowthLimitAndTrimDriver(size_t object_size) {
	size_t initial_size = 4 * MB;
	size_t growth_limit = 8 * MB;
	size_t capacity = 16 * MB;
	DlMallocSpace* space(DlMallocSpace::Create("test", initial_size, growth_limit, capacity, NULL));
	ASSERT_TRUE(space != NULL);

	// Basic sanity
	EXPECT_EQ(space->Capacity(), growth_limit);
	EXPECT_EQ(space->NonGrowthLimitCapacity(), capacity);

	// Make space findable to the heap, will also delete space when runtime is cleaned up
	AddContinuousSpace(space);

	// In this round we don't allocate with growth and therefore can't grow past the initial size.
	// This effectively makes the growth_limit the initial_size, so assert this.
	SizeFootPrintGrowthLimitAndTrimBody(space, object_size, 1, initial_size);
	SizeFootPrintGrowthLimitAndTrimBody(space, object_size, 2, growth_limit);
	// Remove growth limit
	space->ClearGrowthLimit();
	EXPECT_EQ(space->Capacity(), capacity);
	SizeFootPrintGrowthLimitAndTrimBody(space, object_size, 3, capacity);
	}

	#define TEST_SizeFootPrintGrowthLimitAndTrim(name, size) \
	TEST_F(SpaceTest, SizeFootPrintGrowthLimitAndTrim_AllocationsOf_##name) { \
	SizeFootPrintGrowthLimitAndTrimDriver(size); \
	} \
	TEST_F(SpaceTest, SizeFootPrintGrowthLimitAndTrim_RandomAllocationsWithMax_##name) { \
	SizeFootPrintGrowthLimitAndTrimDriver(-size); \
	}

	// Each size test is its own test so that we get a fresh heap each time
	TEST_F(SpaceTest, SizeFootPrintGrowthLimitAndTrim_AllocationsOf_8B) {
	SizeFootPrintGrowthLimitAndTrimDriver(8);
	}
	TEST_SizeFootPrintGrowthLimitAndTrim(16B, 16)
	TEST_SizeFootPrintGrowthLimitAndTrim(24B, 24)
	TEST_SizeFootPrintGrowthLimitAndTrim(32B, 32)
	TEST_SizeFootPrintGrowthLimitAndTrim(64B, 64)
	TEST_SizeFootPrintGrowthLimitAndTrim(128B, 128)
	TEST_SizeFootPrintGrowthLimitAndTrim(1KB, 1 * KB)
	TEST_SizeFootPrintGrowthLimitAndTrim(4KB, 4 * KB)
	TEST_SizeFootPrintGrowthLimitAndTrim(1MB, 1 * MB)
	TEST_SizeFootPrintGrowthLimitAndTrim(4MB, 4 * MB)
	TEST_SizeFootPrintGrowthLimitAndTrim(8MB, 8 * MB)

	} // namespace space
	} // namespace gc
	} // namespace art