core/fxcrt/fx_memory_unittest.cpp - pdfium - Git at Google

 // Copyright 2015 The PDFium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "core/fxcrt/fx_memory.h"

 #include <limits>
 #include <memory>

 #include "build/build_config.h"
 #include "core/fxcrt/compiler_specific.h"
 #include "testing/gtest/include/gtest/gtest.h"

 #if defined(PDF_USE_PARTITION_ALLOC)
 #include "partition_alloc/partition_address_space.h"
 #endif

 namespace {

 constexpr size_t kMaxByteAlloc = std::numeric_limits<size_t>::max();
 constexpr size_t kMaxIntAlloc = kMaxByteAlloc / sizeof(int);
 constexpr size_t kOverflowIntAlloc = kMaxIntAlloc + 100;
 constexpr size_t kWidth = 640;
 constexpr size_t kOverflowIntAlloc2D = kMaxIntAlloc / kWidth + 10;
 constexpr size_t kCloseToMaxIntAlloc = kMaxIntAlloc - 100;
 constexpr size_t kCloseToMaxByteAlloc = kMaxByteAlloc - 100;

 }  // namespace

 TEST(fxcrt, FX_AllocZero) {
   uint8_t* ptr = FX_Alloc(uint8_t, 0);
   uint8_t* ptr2 = FX_Alloc(uint8_t, 0);
   EXPECT_TRUE(ptr);      // Malloc(0) is distinguishable from OOM.
   EXPECT_NE(ptr, ptr2);  // Each malloc(0) is distinguishable.
   FX_Free(ptr2);
   FX_Free(ptr);
 }

 TEST(fxcrt, FXAllocOOM) {
   EXPECT_DEATH_IF_SUPPORTED((void)FX_Alloc(int, kCloseToMaxIntAlloc), "");

   int* ptr = FX_Alloc(int, 1);
   EXPECT_TRUE(ptr);
   EXPECT_DEATH_IF_SUPPORTED((void)FX_Realloc(int, ptr, kCloseToMaxIntAlloc),
                             "");
   FX_Free(ptr);
 }

 TEST(fxcrt, FX_AllocOverflow) {
   // |ptr| needs to be defined and used to avoid Clang optimizes away the
   // FX_Alloc() statement overzealously for optimized builds.
   int* ptr = nullptr;
   EXPECT_DEATH_IF_SUPPORTED(ptr = FX_Alloc(int, kOverflowIntAlloc), "") << ptr;

   ptr = FX_Alloc(int, 1);
   EXPECT_TRUE(ptr);
   EXPECT_DEATH_IF_SUPPORTED((void)FX_Realloc(int, ptr, kOverflowIntAlloc), "");
   FX_Free(ptr);
 }

 TEST(fxcrt, FX_AllocOverflow2D) {
   // |ptr| needs to be defined and used to avoid Clang optimizes away the
   // FX_Alloc() statement overzealously for optimized builds.
   int* ptr = nullptr;
   EXPECT_DEATH_IF_SUPPORTED(ptr = FX_Alloc2D(int, kWidth, kOverflowIntAlloc2D),
                             "")
       << ptr;
 }

 TEST(fxcrt, FXTryAllocOOM) {
   EXPECT_FALSE(FX_TryAlloc(int, kCloseToMaxIntAlloc));

   int* ptr = FX_Alloc(int, 1);
   EXPECT_TRUE(ptr);
   EXPECT_FALSE(FX_TryRealloc(int, ptr, kCloseToMaxIntAlloc));
   FX_Free(ptr);
 }

 #if !defined(COMPILER_GCC)
 TEST(fxcrt, FX_TryAllocOverflow) {
   // |ptr| needs to be defined and used to avoid Clang optimizes away the
   // calloc() statement overzealously for optimized builds.
   int* ptr = (int*)calloc(sizeof(int), kOverflowIntAlloc);
   EXPECT_FALSE(ptr) << ptr;

   ptr = FX_Alloc(int, 1);
   EXPECT_TRUE(ptr);
   *ptr = 1492;  // Arbitrary sentinel.
   EXPECT_FALSE(FX_TryRealloc(int, ptr, kOverflowIntAlloc));
   EXPECT_EQ(1492, *ptr);
   FX_Free(ptr);
 }
 #endif

 TEST(fxcrt, FXMEMDefaultOOM) {
   EXPECT_FALSE(FXMEM_DefaultAlloc(kCloseToMaxByteAlloc));

   void* ptr = FXMEM_DefaultAlloc(1);
   EXPECT_TRUE(ptr);
   EXPECT_FALSE(FXMEM_DefaultRealloc(ptr, kCloseToMaxByteAlloc));
   FXMEM_DefaultFree(ptr);
 }

 TEST(fxcrt, AllocZeroesMemory) {
   uint8_t* ptr = FX_Alloc(uint8_t, 32);
   ASSERT_TRUE(ptr);
   for (size_t i = 0; i < 32; ++i) {
     // TODO(tsepez): make safe.
     EXPECT_EQ(0, UNSAFE_BUFFERS(ptr[i]));
   }
   FX_Free(ptr);
 }

 TEST(fxcrt, FXAlign) {
   static_assert(std::numeric_limits<size_t>::max() % 2 == 1,
                 "numeric limit must be odd for this test");

   size_t s0 = 0;
   size_t s1 = 1;
   size_t s2 = 2;
   size_t sbig = std::numeric_limits<size_t>::max() - 2;
   EXPECT_EQ(0u, FxAlignToBoundary<2>(s0));
   EXPECT_EQ(2u, FxAlignToBoundary<2>(s1));
   EXPECT_EQ(2u, FxAlignToBoundary<2>(s2));
   EXPECT_EQ(std::numeric_limits<size_t>::max() - 1, FxAlignToBoundary<2>(sbig));

   int i0 = 0;
   int i511 = 511;
   int i512 = 512;
   int ineg = -513;
   EXPECT_EQ(0, FxAlignToBoundary<512>(i0));
   EXPECT_EQ(512, FxAlignToBoundary<512>(i511));
   EXPECT_EQ(512, FxAlignToBoundary<512>(i512));
   EXPECT_EQ(-512, FxAlignToBoundary<512>(ineg));
 }

 #if defined(PDF_USE_PARTITION_ALLOC)
 #if BUILDFLAG(USE_PARTITION_ALLOC_AS_MALLOC) && BUILDFLAG(HAS_64_BIT_POINTERS)
 TEST(FxMemory, NewOperatorResultIsPA) {
   auto obj = std::make_unique<double>(4.0);
   EXPECT_TRUE(partition_alloc::IsManagedByPartitionAlloc(
       reinterpret_cast<uintptr_t>(obj.get())));
 #if BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
   EXPECT_TRUE(partition_alloc::IsManagedByPartitionAllocBRPPool(
       reinterpret_cast<uintptr_t>(obj.get())));
 #endif  // BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
 }

 TEST(FxMemory, MallocResultIsPA) {
   void* obj = malloc(16);
   EXPECT_TRUE(partition_alloc::IsManagedByPartitionAlloc(
       reinterpret_cast<uintptr_t>(obj)));
 #if BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
   EXPECT_TRUE(partition_alloc::IsManagedByPartitionAllocBRPPool(
       reinterpret_cast<uintptr_t>(obj)));
 #endif  // BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
   free(obj);
 }

 TEST(FxMemory, StackObjectIsNotPA) {
   int x = 3;
   EXPECT_FALSE(partition_alloc::IsManagedByPartitionAlloc(
       reinterpret_cast<uintptr_t>(&x)));
 #if BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
   EXPECT_FALSE(partition_alloc::IsManagedByPartitionAllocBRPPool(
       reinterpret_cast<uintptr_t>(&x)));
 #endif  // BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
 }
 #endif  // BUILDFLAG(USE_PARTITION_ALLOC_AS_MALLOC) &&
         // BUILDFLAG(HAS_64_BIT_POINTERS)
 #endif  // defined(PDF_USE_PARTITION_ALLOC)
	// Copyright 2015 The PDFium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "core/fxcrt/fx_memory.h"

	#include <limits>
	#include <memory>

	#include "build/build_config.h"
	#include "core/fxcrt/compiler_specific.h"
	#include "testing/gtest/include/gtest/gtest.h"

	#if defined(PDF_USE_PARTITION_ALLOC)
	#include "partition_alloc/partition_address_space.h"
	#endif

	namespace {

	constexpr size_t kMaxByteAlloc = std::numeric_limits<size_t>::max();
	constexpr size_t kMaxIntAlloc = kMaxByteAlloc / sizeof(int);
	constexpr size_t kOverflowIntAlloc = kMaxIntAlloc + 100;
	constexpr size_t kWidth = 640;
	constexpr size_t kOverflowIntAlloc2D = kMaxIntAlloc / kWidth + 10;
	constexpr size_t kCloseToMaxIntAlloc = kMaxIntAlloc - 100;
	constexpr size_t kCloseToMaxByteAlloc = kMaxByteAlloc - 100;

	} // namespace

	TEST(fxcrt, FX_AllocZero) {
	uint8_t* ptr = FX_Alloc(uint8_t, 0);
	uint8_t* ptr2 = FX_Alloc(uint8_t, 0);
	EXPECT_TRUE(ptr); // Malloc(0) is distinguishable from OOM.
	EXPECT_NE(ptr, ptr2); // Each malloc(0) is distinguishable.
	FX_Free(ptr2);
	FX_Free(ptr);
	}

	TEST(fxcrt, FXAllocOOM) {
	EXPECT_DEATH_IF_SUPPORTED((void)FX_Alloc(int, kCloseToMaxIntAlloc), "");

	int* ptr = FX_Alloc(int, 1);
	EXPECT_TRUE(ptr);
	EXPECT_DEATH_IF_SUPPORTED((void)FX_Realloc(int, ptr, kCloseToMaxIntAlloc),
	"");
	FX_Free(ptr);
	}

	TEST(fxcrt, FX_AllocOverflow) {
	// \|ptr\| needs to be defined and used to avoid Clang optimizes away the
	// FX_Alloc() statement overzealously for optimized builds.
	int* ptr = nullptr;
	EXPECT_DEATH_IF_SUPPORTED(ptr = FX_Alloc(int, kOverflowIntAlloc), "") << ptr;

	ptr = FX_Alloc(int, 1);
	EXPECT_TRUE(ptr);
	EXPECT_DEATH_IF_SUPPORTED((void)FX_Realloc(int, ptr, kOverflowIntAlloc), "");
	FX_Free(ptr);
	}

	TEST(fxcrt, FX_AllocOverflow2D) {
	// \|ptr\| needs to be defined and used to avoid Clang optimizes away the
	// FX_Alloc() statement overzealously for optimized builds.
	int* ptr = nullptr;
	EXPECT_DEATH_IF_SUPPORTED(ptr = FX_Alloc2D(int, kWidth, kOverflowIntAlloc2D),
	"")
	<< ptr;
	}

	TEST(fxcrt, FXTryAllocOOM) {
	EXPECT_FALSE(FX_TryAlloc(int, kCloseToMaxIntAlloc));

	int* ptr = FX_Alloc(int, 1);
	EXPECT_TRUE(ptr);
	EXPECT_FALSE(FX_TryRealloc(int, ptr, kCloseToMaxIntAlloc));
	FX_Free(ptr);
	}

	#if !defined(COMPILER_GCC)
	TEST(fxcrt, FX_TryAllocOverflow) {
	// \|ptr\| needs to be defined and used to avoid Clang optimizes away the
	// calloc() statement overzealously for optimized builds.
	int* ptr = (int*)calloc(sizeof(int), kOverflowIntAlloc);
	EXPECT_FALSE(ptr) << ptr;

	ptr = FX_Alloc(int, 1);
	EXPECT_TRUE(ptr);
	*ptr = 1492; // Arbitrary sentinel.
	EXPECT_FALSE(FX_TryRealloc(int, ptr, kOverflowIntAlloc));
	EXPECT_EQ(1492, *ptr);
	FX_Free(ptr);
	}
	#endif

	TEST(fxcrt, FXMEMDefaultOOM) {
	EXPECT_FALSE(FXMEM_DefaultAlloc(kCloseToMaxByteAlloc));

	void* ptr = FXMEM_DefaultAlloc(1);
	EXPECT_TRUE(ptr);
	EXPECT_FALSE(FXMEM_DefaultRealloc(ptr, kCloseToMaxByteAlloc));
	FXMEM_DefaultFree(ptr);
	}

	TEST(fxcrt, AllocZeroesMemory) {
	uint8_t* ptr = FX_Alloc(uint8_t, 32);
	ASSERT_TRUE(ptr);
	for (size_t i = 0; i < 32; ++i) {
	// TODO(tsepez): make safe.
	EXPECT_EQ(0, UNSAFE_BUFFERS(ptr[i]));
	}
	FX_Free(ptr);
	}

	TEST(fxcrt, FXAlign) {
	static_assert(std::numeric_limits<size_t>::max() % 2 == 1,
	"numeric limit must be odd for this test");

	size_t s0 = 0;
	size_t s1 = 1;
	size_t s2 = 2;
	size_t sbig = std::numeric_limits<size_t>::max() - 2;
	EXPECT_EQ(0u, FxAlignToBoundary<2>(s0));
	EXPECT_EQ(2u, FxAlignToBoundary<2>(s1));
	EXPECT_EQ(2u, FxAlignToBoundary<2>(s2));
	EXPECT_EQ(std::numeric_limits<size_t>::max() - 1, FxAlignToBoundary<2>(sbig));

	int i0 = 0;
	int i511 = 511;
	int i512 = 512;
	int ineg = -513;
	EXPECT_EQ(0, FxAlignToBoundary<512>(i0));
	EXPECT_EQ(512, FxAlignToBoundary<512>(i511));
	EXPECT_EQ(512, FxAlignToBoundary<512>(i512));
	EXPECT_EQ(-512, FxAlignToBoundary<512>(ineg));
	}

	#if defined(PDF_USE_PARTITION_ALLOC)
	#if BUILDFLAG(USE_PARTITION_ALLOC_AS_MALLOC) && BUILDFLAG(HAS_64_BIT_POINTERS)
	TEST(FxMemory, NewOperatorResultIsPA) {
	auto obj = std::make_unique<double>(4.0);
	EXPECT_TRUE(partition_alloc::IsManagedByPartitionAlloc(
	reinterpret_cast<uintptr_t>(obj.get())));
	#if BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
	EXPECT_TRUE(partition_alloc::IsManagedByPartitionAllocBRPPool(
	reinterpret_cast<uintptr_t>(obj.get())));
	#endif // BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
	}

	TEST(FxMemory, MallocResultIsPA) {
	void* obj = malloc(16);
	EXPECT_TRUE(partition_alloc::IsManagedByPartitionAlloc(
	reinterpret_cast<uintptr_t>(obj)));
	#if BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
	EXPECT_TRUE(partition_alloc::IsManagedByPartitionAllocBRPPool(
	reinterpret_cast<uintptr_t>(obj)));
	#endif // BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
	free(obj);
	}

	TEST(FxMemory, StackObjectIsNotPA) {
	int x = 3;
	EXPECT_FALSE(partition_alloc::IsManagedByPartitionAlloc(
	reinterpret_cast<uintptr_t>(&x)));
	#if BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
	EXPECT_FALSE(partition_alloc::IsManagedByPartitionAllocBRPPool(
	reinterpret_cast<uintptr_t>(&x)));
	#endif // BUILDFLAG(ENABLE_BACKUP_REF_PTR_SUPPORT)
	}
	#endif // BUILDFLAG(USE_PARTITION_ALLOC_AS_MALLOC) &&
	// BUILDFLAG(HAS_64_BIT_POINTERS)
	#endif // defined(PDF_USE_PARTITION_ALLOC)