base/process/memory_unittest.cc - platform/external/chromium_org - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #define _CRT_SECURE_NO_WARNINGS

 #include "base/process/memory.h"

 #include <limits>

 #include "base/compiler_specific.h"
 #include "base/debug/alias.h"
 #include "base/strings/stringprintf.h"
 #include "testing/gtest/include/gtest/gtest.h"

 #if defined(OS_WIN)
 #include <windows.h>
 #endif
 #if defined(OS_POSIX)
 #include <errno.h>
 #endif
 #if defined(OS_MACOSX)
 #include <malloc/malloc.h>
 #include "base/process/memory_unittest_mac.h"
 #endif
 #if defined(OS_LINUX)
 #include <malloc.h>
 #endif

 #if defined(OS_WIN)
 // HeapQueryInformation function pointer.
 typedef BOOL (WINAPI* HeapQueryFn)  \
     (HANDLE, HEAP_INFORMATION_CLASS, PVOID, SIZE_T, PSIZE_T);

 const int kConstantInModule = 42;

 TEST(ProcessMemoryTest, GetModuleFromAddress) {
   // Since the unit tests are their own EXE, this should be
   // equivalent to the EXE's HINSTANCE.
   //
   // kConstantInModule is a constant in this file and
   // therefore within the unit test EXE.
   EXPECT_EQ(::GetModuleHandle(NULL),
             base::GetModuleFromAddress(
                 const_cast<int*>(&kConstantInModule)));

   // Any address within the kernel32 module should return
   // kernel32's HMODULE.  Our only assumption here is that
   // kernel32 is larger than 4 bytes.
   HMODULE kernel32 = ::GetModuleHandle(L"kernel32.dll");
   HMODULE kernel32_from_address =
       base::GetModuleFromAddress(reinterpret_cast<DWORD*>(kernel32) + 1);
   EXPECT_EQ(kernel32, kernel32_from_address);
 }

 TEST(ProcessMemoryTest, EnableLFH) {
   ASSERT_TRUE(base::EnableLowFragmentationHeap());
   if (IsDebuggerPresent()) {
     // Under these conditions, LFH can't be enabled. There's no point to test
     // anything.
     const char* no_debug_env = getenv("_NO_DEBUG_HEAP");
     if (!no_debug_env || strcmp(no_debug_env, "1"))
       return;
   }
   HMODULE kernel32 = GetModuleHandle(L"kernel32.dll");
   ASSERT_TRUE(kernel32 != NULL);
   HeapQueryFn heap_query = reinterpret_cast<HeapQueryFn>(GetProcAddress(
       kernel32,
       "HeapQueryInformation"));

   // On Windows 2000, the function is not exported. This is not a reason to
   // fail but we won't be able to retrieves information about the heap, so we
   // should stop here.
   if (heap_query == NULL)
     return;

   HANDLE heaps[1024] = { 0 };
   unsigned number_heaps = GetProcessHeaps(1024, heaps);
   EXPECT_GT(number_heaps, 0u);
   for (unsigned i = 0; i < number_heaps; ++i) {
     ULONG flag = 0;
     SIZE_T length;
     ASSERT_NE(0, heap_query(heaps[i],
                             HeapCompatibilityInformation,
                             &flag,
                             sizeof(flag),
                             &length));
     // If flag is 0, the heap is a standard heap that does not support
     // look-asides. If flag is 1, the heap supports look-asides. If flag is 2,
     // the heap is a low-fragmentation heap (LFH). Note that look-asides are not
     // supported on the LFH.

     // We don't have any documented way of querying the HEAP_NO_SERIALIZE flag.
     EXPECT_LE(flag, 2u);
     EXPECT_NE(flag, 1u);
   }
 }
 #endif  // defined(OS_WIN)

 #if defined(OS_MACOSX)

 // For the following Mac tests:
 // Note that base::EnableTerminationOnHeapCorruption() is called as part of
 // test suite setup and does not need to be done again, else mach_override
 // will fail.

 #if !defined(ADDRESS_SANITIZER)
 // The following code tests the system implementation of malloc() thus no need
 // to test it under AddressSanitizer.
 TEST(ProcessMemoryTest, MacMallocFailureDoesNotTerminate) {
   // Test that ENOMEM doesn't crash via CrMallocErrorBreak two ways: the exit
   // code and lack of the error string. The number of bytes is one less than
   // MALLOC_ABSOLUTE_MAX_SIZE, more than which the system early-returns NULL and
   // does not call through malloc_error_break(). See the comment at
   // EnableTerminationOnOutOfMemory() for more information.
   void* buf = NULL;
   ASSERT_EXIT(
       {
         base::EnableTerminationOnOutOfMemory();

         buf = malloc(std::numeric_limits<size_t>::max() - (2 * PAGE_SIZE) - 1);
       },
       testing::KilledBySignal(SIGTRAP),
       "\\*\\*\\* error: can't allocate region.*\\n?.*");

   base::debug::Alias(buf);
 }
 #endif  // !defined(ADDRESS_SANITIZER)

 TEST(ProcessMemoryTest, MacTerminateOnHeapCorruption) {
   // Assert that freeing an unallocated pointer will crash the process.
   char buf[9];
   asm("" : "=r" (buf));  // Prevent clang from being too smart.
 #if ARCH_CPU_64_BITS
   // On 64 bit Macs, the malloc system automatically abort()s on heap corruption
   // but does not output anything.
   ASSERT_DEATH(free(buf), "");
 #elif defined(ADDRESS_SANITIZER)
   // AddressSanitizer replaces malloc() and prints a different error message on
   // heap corruption.
   ASSERT_DEATH(free(buf), "attempting free on address which "
       "was not malloc\\(\\)-ed");
 #else
   ASSERT_DEATH(free(buf), "being freed.*\\n?\\.*"
       "\\*\\*\\* set a breakpoint in malloc_error_break to debug.*\\n?.*"
       "Terminating process due to a potential for future heap corruption");
 #endif  // ARCH_CPU_64_BITS || defined(ADDRESS_SANITIZER)
 }

 #endif  // defined(OS_MACOSX)

 // Android doesn't implement set_new_handler, so we can't use the
 // OutOfMemoryTest cases.
 // OpenBSD does not support these tests either.
 // TODO(vandebo) make this work on Windows too.
 #if !defined(OS_ANDROID) && !defined(OS_OPENBSD) && \
     !defined(OS_WIN)

 #if defined(USE_TCMALLOC)
 extern "C" {
 int tc_set_new_mode(int mode);
 }
 #endif  // defined(USE_TCMALLOC)

 class OutOfMemoryTest : public testing::Test {
  public:
   OutOfMemoryTest()
     : value_(NULL),
     // Make test size as large as possible minus a few pages so
     // that alignment or other rounding doesn't make it wrap.
     test_size_(std::numeric_limits<std::size_t>::max() - 12 * 1024),
     signed_test_size_(std::numeric_limits<ssize_t>::max()) {
   }

 #if defined(USE_TCMALLOC)
   virtual void SetUp() OVERRIDE {
     tc_set_new_mode(1);
   }

   virtual void TearDown() OVERRIDE {
     tc_set_new_mode(0);
   }
 #endif  // defined(USE_TCMALLOC)

  protected:
   void* value_;
   size_t test_size_;
   ssize_t signed_test_size_;
 };

 class OutOfMemoryDeathTest : public OutOfMemoryTest {
  public:
   void SetUpInDeathAssert() {
     // Must call EnableTerminationOnOutOfMemory() because that is called from
     // chrome's main function and therefore hasn't been called yet.
     // Since this call may result in another thread being created and death
     // tests shouldn't be started in a multithread environment, this call
     // should be done inside of the ASSERT_DEATH.
     base::EnableTerminationOnOutOfMemory();
   }
 };

 TEST_F(OutOfMemoryDeathTest, New) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = operator new(test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, NewArray) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = new char[test_size_];
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, Malloc) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = malloc(test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, Realloc) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = realloc(NULL, test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, Calloc) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = calloc(1024, test_size_ / 1024L);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, Valloc) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = valloc(test_size_);
     }, "");
 }

 #if defined(OS_LINUX)

 #if PVALLOC_AVAILABLE == 1
 TEST_F(OutOfMemoryDeathTest, Pvalloc) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = pvalloc(test_size_);
     }, "");
 }
 #endif  // PVALLOC_AVAILABLE == 1

 TEST_F(OutOfMemoryDeathTest, Memalign) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = memalign(4, test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, ViaSharedLibraries) {
   // This tests that the run-time symbol resolution is overriding malloc for
   // shared libraries (including libc itself) as well as for our code.
   std::string format = base::StringPrintf("%%%zud", test_size_);
   char *value = NULL;
   ASSERT_DEATH({
       SetUpInDeathAssert();
       EXPECT_EQ(-1, asprintf(&value, format.c_str(), 0));
     }, "");
 }
 #endif  // OS_LINUX

 // Android doesn't implement posix_memalign().
 #if defined(OS_POSIX) && !defined(OS_ANDROID)
 TEST_F(OutOfMemoryDeathTest, Posix_memalign) {
   // Grab the return value of posix_memalign to silence a compiler warning
   // about unused return values. We don't actually care about the return
   // value, since we're asserting death.
   ASSERT_DEATH({
       SetUpInDeathAssert();
       EXPECT_EQ(ENOMEM, posix_memalign(&value_, 8, test_size_));
     }, "");
 }
 #endif  // defined(OS_POSIX) && !defined(OS_ANDROID)

 #if defined(OS_MACOSX)

 // Purgeable zone tests

 TEST_F(OutOfMemoryDeathTest, MallocPurgeable) {
   malloc_zone_t* zone = malloc_default_purgeable_zone();
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = malloc_zone_malloc(zone, test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, ReallocPurgeable) {
   malloc_zone_t* zone = malloc_default_purgeable_zone();
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = malloc_zone_realloc(zone, NULL, test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, CallocPurgeable) {
   malloc_zone_t* zone = malloc_default_purgeable_zone();
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = malloc_zone_calloc(zone, 1024, test_size_ / 1024L);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, VallocPurgeable) {
   malloc_zone_t* zone = malloc_default_purgeable_zone();
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = malloc_zone_valloc(zone, test_size_);
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, PosixMemalignPurgeable) {
   malloc_zone_t* zone = malloc_default_purgeable_zone();
   ASSERT_DEATH({
       SetUpInDeathAssert();
       value_ = malloc_zone_memalign(zone, 8, test_size_);
     }, "");
 }

 // Since these allocation functions take a signed size, it's possible that
 // calling them just once won't be enough to exhaust memory. In the 32-bit
 // environment, it's likely that these allocation attempts will fail because
 // not enough contiguous address space is available. In the 64-bit environment,
 // it's likely that they'll fail because they would require a preposterous
 // amount of (virtual) memory.

 TEST_F(OutOfMemoryDeathTest, CFAllocatorSystemDefault) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       while ((value_ =
               base::AllocateViaCFAllocatorSystemDefault(signed_test_size_))) {}
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, CFAllocatorMalloc) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       while ((value_ =
               base::AllocateViaCFAllocatorMalloc(signed_test_size_))) {}
     }, "");
 }

 TEST_F(OutOfMemoryDeathTest, CFAllocatorMallocZone) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       while ((value_ =
               base::AllocateViaCFAllocatorMallocZone(signed_test_size_))) {}
     }, "");
 }

 #if !defined(ARCH_CPU_64_BITS)

 // See process_util_unittest_mac.mm for an explanation of why this test isn't
 // run in the 64-bit environment.

 TEST_F(OutOfMemoryDeathTest, PsychoticallyBigObjCObject) {
   ASSERT_DEATH({
       SetUpInDeathAssert();
       while ((value_ = base::AllocatePsychoticallyBigObjCObject())) {}
     }, "");
 }

 #endif  // !ARCH_CPU_64_BITS
 #endif  // OS_MACOSX

 class OutOfMemoryHandledTest : public OutOfMemoryTest {
  public:
   static const size_t kSafeMallocSize = 512;
   static const size_t kSafeCallocSize = 128;
   static const size_t kSafeCallocItems = 4;

   virtual void SetUp() {
     OutOfMemoryTest::SetUp();

     // We enable termination on OOM - just as Chrome does at early
     // initialization - and test that UncheckedMalloc and  UncheckedCalloc
     // properly by-pass this in order to allow the caller to handle OOM.
     base::EnableTerminationOnOutOfMemory();
   }
 };

 // TODO(b.kelemen): make UncheckedMalloc and UncheckedCalloc work
 // on Windows as well.
 // UncheckedMalloc() and UncheckedCalloc() work as regular malloc()/calloc()
 // under sanitizer tools.
 #if !defined(MEMORY_TOOL_REPLACES_ALLOCATOR)
 TEST_F(OutOfMemoryHandledTest, UncheckedMalloc) {
   EXPECT_TRUE(base::UncheckedMalloc(kSafeMallocSize, &value_));
   EXPECT_TRUE(value_ != NULL);
   free(value_);

   EXPECT_FALSE(base::UncheckedMalloc(test_size_, &value_));
   EXPECT_TRUE(value_ == NULL);
 }

 TEST_F(OutOfMemoryHandledTest, UncheckedCalloc) {
   EXPECT_TRUE(base::UncheckedCalloc(1, kSafeMallocSize, &value_));
   EXPECT_TRUE(value_ != NULL);
   const char* bytes = static_cast<const char*>(value_);
   for (size_t i = 0; i < kSafeMallocSize; ++i)
     EXPECT_EQ(0, bytes[i]);
   free(value_);

   EXPECT_TRUE(
       base::UncheckedCalloc(kSafeCallocItems, kSafeCallocSize, &value_));
   EXPECT_TRUE(value_ != NULL);
   bytes = static_cast<const char*>(value_);
   for (size_t i = 0; i < (kSafeCallocItems * kSafeCallocSize); ++i)
     EXPECT_EQ(0, bytes[i]);
   free(value_);

   EXPECT_FALSE(base::UncheckedCalloc(1, test_size_, &value_));
   EXPECT_TRUE(value_ == NULL);
 }
 #endif  // !defined(MEMORY_TOOL_REPLACES_ALLOCATOR)
 #endif  // !defined(OS_ANDROID) && !defined(OS_OPENBSD) && !defined(OS_WIN)
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#define _CRT_SECURE_NO_WARNINGS

	#include "base/process/memory.h"

	#include <limits>

	#include "base/compiler_specific.h"
	#include "base/debug/alias.h"
	#include "base/strings/stringprintf.h"
	#include "testing/gtest/include/gtest/gtest.h"

	#if defined(OS_WIN)
	#include <windows.h>
	#endif
	#if defined(OS_POSIX)
	#include <errno.h>
	#endif
	#if defined(OS_MACOSX)
	#include <malloc/malloc.h>
	#include "base/process/memory_unittest_mac.h"
	#endif
	#if defined(OS_LINUX)
	#include <malloc.h>
	#endif

	#if defined(OS_WIN)
	// HeapQueryInformation function pointer.
	typedef BOOL (WINAPI* HeapQueryFn) \
	(HANDLE, HEAP_INFORMATION_CLASS, PVOID, SIZE_T, PSIZE_T);

	const int kConstantInModule = 42;

	TEST(ProcessMemoryTest, GetModuleFromAddress) {
	// Since the unit tests are their own EXE, this should be
	// equivalent to the EXE's HINSTANCE.
	//
	// kConstantInModule is a constant in this file and
	// therefore within the unit test EXE.
	EXPECT_EQ(::GetModuleHandle(NULL),
	base::GetModuleFromAddress(
	const_cast<int*>(&kConstantInModule)));

	// Any address within the kernel32 module should return
	// kernel32's HMODULE. Our only assumption here is that
	// kernel32 is larger than 4 bytes.
	HMODULE kernel32 = ::GetModuleHandle(L"kernel32.dll");
	HMODULE kernel32_from_address =
	base::GetModuleFromAddress(reinterpret_cast<DWORD*>(kernel32) + 1);
	EXPECT_EQ(kernel32, kernel32_from_address);
	}

	TEST(ProcessMemoryTest, EnableLFH) {
	ASSERT_TRUE(base::EnableLowFragmentationHeap());
	if (IsDebuggerPresent()) {
	// Under these conditions, LFH can't be enabled. There's no point to test
	// anything.
	const char* no_debug_env = getenv("_NO_DEBUG_HEAP");
	if (!no_debug_env \|\| strcmp(no_debug_env, "1"))
	return;
	}
	HMODULE kernel32 = GetModuleHandle(L"kernel32.dll");
	ASSERT_TRUE(kernel32 != NULL);
	HeapQueryFn heap_query = reinterpret_cast<HeapQueryFn>(GetProcAddress(
	kernel32,
	"HeapQueryInformation"));

	// On Windows 2000, the function is not exported. This is not a reason to
	// fail but we won't be able to retrieves information about the heap, so we
	// should stop here.
	if (heap_query == NULL)
	return;

	HANDLE heaps[1024] = { 0 };
	unsigned number_heaps = GetProcessHeaps(1024, heaps);
	EXPECT_GT(number_heaps, 0u);
	for (unsigned i = 0; i < number_heaps; ++i) {
	ULONG flag = 0;
	SIZE_T length;
	ASSERT_NE(0, heap_query(heaps[i],
	HeapCompatibilityInformation,
	&flag,
	sizeof(flag),
	&length));
	// If flag is 0, the heap is a standard heap that does not support
	// look-asides. If flag is 1, the heap supports look-asides. If flag is 2,
	// the heap is a low-fragmentation heap (LFH). Note that look-asides are not
	// supported on the LFH.

	// We don't have any documented way of querying the HEAP_NO_SERIALIZE flag.
	EXPECT_LE(flag, 2u);
	EXPECT_NE(flag, 1u);
	}
	}
	#endif // defined(OS_WIN)

	#if defined(OS_MACOSX)

	// For the following Mac tests:
	// Note that base::EnableTerminationOnHeapCorruption() is called as part of
	// test suite setup and does not need to be done again, else mach_override
	// will fail.

	#if !defined(ADDRESS_SANITIZER)
	// The following code tests the system implementation of malloc() thus no need
	// to test it under AddressSanitizer.
	TEST(ProcessMemoryTest, MacMallocFailureDoesNotTerminate) {
	// Test that ENOMEM doesn't crash via CrMallocErrorBreak two ways: the exit
	// code and lack of the error string. The number of bytes is one less than
	// MALLOC_ABSOLUTE_MAX_SIZE, more than which the system early-returns NULL and
	// does not call through malloc_error_break(). See the comment at
	// EnableTerminationOnOutOfMemory() for more information.
	void* buf = NULL;
	ASSERT_EXIT(
	{
	base::EnableTerminationOnOutOfMemory();

	buf = malloc(std::numeric_limits<size_t>::max() - (2 * PAGE_SIZE) - 1);
	},
	testing::KilledBySignal(SIGTRAP),
	"\\\\\\* error: can't allocate region.\\n?.");

	base::debug::Alias(buf);
	}
	#endif // !defined(ADDRESS_SANITIZER)

	TEST(ProcessMemoryTest, MacTerminateOnHeapCorruption) {
	// Assert that freeing an unallocated pointer will crash the process.
	char buf[9];
	asm("" : "=r" (buf)); // Prevent clang from being too smart.
	#if ARCH_CPU_64_BITS
	// On 64 bit Macs, the malloc system automatically abort()s on heap corruption
	// but does not output anything.
	ASSERT_DEATH(free(buf), "");
	#elif defined(ADDRESS_SANITIZER)
	// AddressSanitizer replaces malloc() and prints a different error message on
	// heap corruption.
	ASSERT_DEATH(free(buf), "attempting free on address which "
	"was not malloc\\(\\)-ed");
	#else
	ASSERT_DEATH(free(buf), "being freed.\\n?\\."
	"\\\\\\* set a breakpoint in malloc_error_break to debug.\\n?."
	"Terminating process due to a potential for future heap corruption");
	#endif // ARCH_CPU_64_BITS \|\| defined(ADDRESS_SANITIZER)
	}

	#endif // defined(OS_MACOSX)

	// Android doesn't implement set_new_handler, so we can't use the
	// OutOfMemoryTest cases.
	// OpenBSD does not support these tests either.
	// TODO(vandebo) make this work on Windows too.
	#if !defined(OS_ANDROID) && !defined(OS_OPENBSD) && \
	!defined(OS_WIN)

	#if defined(USE_TCMALLOC)
	extern "C" {
	int tc_set_new_mode(int mode);
	}
	#endif // defined(USE_TCMALLOC)

	class OutOfMemoryTest : public testing::Test {
	public:
	OutOfMemoryTest()
	: value_(NULL),
	// Make test size as large as possible minus a few pages so
	// that alignment or other rounding doesn't make it wrap.
	test_size_(std::numeric_limits<std::size_t>::max() - 12 * 1024),
	signed_test_size_(std::numeric_limits<ssize_t>::max()) {
	}

	#if defined(USE_TCMALLOC)
	virtual void SetUp() OVERRIDE {
	tc_set_new_mode(1);
	}

	virtual void TearDown() OVERRIDE {
	tc_set_new_mode(0);
	}
	#endif // defined(USE_TCMALLOC)

	protected:
	void* value_;
	size_t test_size_;
	ssize_t signed_test_size_;
	};

	class OutOfMemoryDeathTest : public OutOfMemoryTest {
	public:
	void SetUpInDeathAssert() {
	// Must call EnableTerminationOnOutOfMemory() because that is called from
	// chrome's main function and therefore hasn't been called yet.
	// Since this call may result in another thread being created and death
	// tests shouldn't be started in a multithread environment, this call
	// should be done inside of the ASSERT_DEATH.
	base::EnableTerminationOnOutOfMemory();
	}
	};

	TEST_F(OutOfMemoryDeathTest, New) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = operator new(test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, NewArray) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = new char[test_size_];
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, Malloc) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = malloc(test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, Realloc) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = realloc(NULL, test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, Calloc) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = calloc(1024, test_size_ / 1024L);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, Valloc) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = valloc(test_size_);
	}, "");
	}

	#if defined(OS_LINUX)

	#if PVALLOC_AVAILABLE == 1
	TEST_F(OutOfMemoryDeathTest, Pvalloc) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = pvalloc(test_size_);
	}, "");
	}
	#endif // PVALLOC_AVAILABLE == 1

	TEST_F(OutOfMemoryDeathTest, Memalign) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = memalign(4, test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, ViaSharedLibraries) {
	// This tests that the run-time symbol resolution is overriding malloc for
	// shared libraries (including libc itself) as well as for our code.
	std::string format = base::StringPrintf("%%%zud", test_size_);
	char *value = NULL;
	ASSERT_DEATH({
	SetUpInDeathAssert();
	EXPECT_EQ(-1, asprintf(&value, format.c_str(), 0));
	}, "");
	}
	#endif // OS_LINUX

	// Android doesn't implement posix_memalign().
	#if defined(OS_POSIX) && !defined(OS_ANDROID)
	TEST_F(OutOfMemoryDeathTest, Posix_memalign) {
	// Grab the return value of posix_memalign to silence a compiler warning
	// about unused return values. We don't actually care about the return
	// value, since we're asserting death.
	ASSERT_DEATH({
	SetUpInDeathAssert();
	EXPECT_EQ(ENOMEM, posix_memalign(&value_, 8, test_size_));
	}, "");
	}
	#endif // defined(OS_POSIX) && !defined(OS_ANDROID)

	#if defined(OS_MACOSX)

	// Purgeable zone tests

	TEST_F(OutOfMemoryDeathTest, MallocPurgeable) {
	malloc_zone_t* zone = malloc_default_purgeable_zone();
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = malloc_zone_malloc(zone, test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, ReallocPurgeable) {
	malloc_zone_t* zone = malloc_default_purgeable_zone();
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = malloc_zone_realloc(zone, NULL, test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, CallocPurgeable) {
	malloc_zone_t* zone = malloc_default_purgeable_zone();
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = malloc_zone_calloc(zone, 1024, test_size_ / 1024L);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, VallocPurgeable) {
	malloc_zone_t* zone = malloc_default_purgeable_zone();
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = malloc_zone_valloc(zone, test_size_);
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, PosixMemalignPurgeable) {
	malloc_zone_t* zone = malloc_default_purgeable_zone();
	ASSERT_DEATH({
	SetUpInDeathAssert();
	value_ = malloc_zone_memalign(zone, 8, test_size_);
	}, "");
	}

	// Since these allocation functions take a signed size, it's possible that
	// calling them just once won't be enough to exhaust memory. In the 32-bit
	// environment, it's likely that these allocation attempts will fail because
	// not enough contiguous address space is available. In the 64-bit environment,
	// it's likely that they'll fail because they would require a preposterous
	// amount of (virtual) memory.

	TEST_F(OutOfMemoryDeathTest, CFAllocatorSystemDefault) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	while ((value_ =
	base::AllocateViaCFAllocatorSystemDefault(signed_test_size_))) {}
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, CFAllocatorMalloc) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	while ((value_ =
	base::AllocateViaCFAllocatorMalloc(signed_test_size_))) {}
	}, "");
	}

	TEST_F(OutOfMemoryDeathTest, CFAllocatorMallocZone) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	while ((value_ =
	base::AllocateViaCFAllocatorMallocZone(signed_test_size_))) {}
	}, "");
	}

	#if !defined(ARCH_CPU_64_BITS)

	// See process_util_unittest_mac.mm for an explanation of why this test isn't
	// run in the 64-bit environment.

	TEST_F(OutOfMemoryDeathTest, PsychoticallyBigObjCObject) {
	ASSERT_DEATH({
	SetUpInDeathAssert();
	while ((value_ = base::AllocatePsychoticallyBigObjCObject())) {}
	}, "");
	}

	#endif // !ARCH_CPU_64_BITS
	#endif // OS_MACOSX

	class OutOfMemoryHandledTest : public OutOfMemoryTest {
	public:
	static const size_t kSafeMallocSize = 512;
	static const size_t kSafeCallocSize = 128;
	static const size_t kSafeCallocItems = 4;

	virtual void SetUp() {
	OutOfMemoryTest::SetUp();

	// We enable termination on OOM - just as Chrome does at early
	// initialization - and test that UncheckedMalloc and UncheckedCalloc
	// properly by-pass this in order to allow the caller to handle OOM.
	base::EnableTerminationOnOutOfMemory();
	}
	};

	// TODO(b.kelemen): make UncheckedMalloc and UncheckedCalloc work
	// on Windows as well.
	// UncheckedMalloc() and UncheckedCalloc() work as regular malloc()/calloc()
	// under sanitizer tools.
	#if !defined(MEMORY_TOOL_REPLACES_ALLOCATOR)
	TEST_F(OutOfMemoryHandledTest, UncheckedMalloc) {
	EXPECT_TRUE(base::UncheckedMalloc(kSafeMallocSize, &value_));
	EXPECT_TRUE(value_ != NULL);
	free(value_);

	EXPECT_FALSE(base::UncheckedMalloc(test_size_, &value_));
	EXPECT_TRUE(value_ == NULL);
	}

	TEST_F(OutOfMemoryHandledTest, UncheckedCalloc) {
	EXPECT_TRUE(base::UncheckedCalloc(1, kSafeMallocSize, &value_));
	EXPECT_TRUE(value_ != NULL);
	const char* bytes = static_cast<const char*>(value_);
	for (size_t i = 0; i < kSafeMallocSize; ++i)
	EXPECT_EQ(0, bytes[i]);
	free(value_);

	EXPECT_TRUE(
	base::UncheckedCalloc(kSafeCallocItems, kSafeCallocSize, &value_));
	EXPECT_TRUE(value_ != NULL);
	bytes = static_cast<const char*>(value_);
	for (size_t i = 0; i < (kSafeCallocItems * kSafeCallocSize); ++i)
	EXPECT_EQ(0, bytes[i]);
	free(value_);

	EXPECT_FALSE(base::UncheckedCalloc(1, test_size_, &value_));
	EXPECT_TRUE(value_ == NULL);
	}
	#endif // !defined(MEMORY_TOOL_REPLACES_ALLOCATOR)
	#endif // !defined(OS_ANDROID) && !defined(OS_OPENBSD) && !defined(OS_WIN)