compiler-rt/lib/asan/tests/asan_interface_test.cc - nest-cam/4320010/compiler-rt - Git at Google

 //===-- asan_interface_test.cc --------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file is a part of AddressSanitizer, an address sanity checker.
 //
 //===----------------------------------------------------------------------===//
 #include "asan_test_utils.h"
 #include <sanitizer/allocator_interface.h>
 #include <sanitizer/asan_interface.h>

 TEST(AddressSanitizerInterface, GetEstimatedAllocatedSize) {
   EXPECT_EQ(0U, __sanitizer_get_estimated_allocated_size(0));
   const size_t sizes[] = { 1, 30, 1<<30 };
   for (size_t i = 0; i < 3; i++) {
     EXPECT_EQ(sizes[i], __sanitizer_get_estimated_allocated_size(sizes[i]));
   }
 }

 static const char* kGetAllocatedSizeErrorMsg =
   "attempting to call __sanitizer_get_allocated_size";

 TEST(AddressSanitizerInterface, GetAllocatedSizeAndOwnershipTest) {
   const size_t kArraySize = 100;
   char *array = Ident((char*)malloc(kArraySize));
   int *int_ptr = Ident(new int);

   // Allocated memory is owned by allocator. Allocated size should be
   // equal to requested size.
   EXPECT_EQ(true, __sanitizer_get_ownership(array));
   EXPECT_EQ(kArraySize, __sanitizer_get_allocated_size(array));
   EXPECT_EQ(true, __sanitizer_get_ownership(int_ptr));
   EXPECT_EQ(sizeof(int), __sanitizer_get_allocated_size(int_ptr));

   // We cannot call GetAllocatedSize from the memory we didn't map,
   // and from the interior pointers (not returned by previous malloc).
   void *wild_addr = (void*)0x1;
   EXPECT_FALSE(__sanitizer_get_ownership(wild_addr));
   EXPECT_DEATH(__sanitizer_get_allocated_size(wild_addr),
                kGetAllocatedSizeErrorMsg);
   EXPECT_FALSE(__sanitizer_get_ownership(array + kArraySize / 2));
   EXPECT_DEATH(__sanitizer_get_allocated_size(array + kArraySize / 2),
                kGetAllocatedSizeErrorMsg);

   // NULL is not owned, but is a valid argument for
   // __sanitizer_get_allocated_size().
   EXPECT_FALSE(__sanitizer_get_ownership(NULL));
   EXPECT_EQ(0U, __sanitizer_get_allocated_size(NULL));

   // When memory is freed, it's not owned, and call to GetAllocatedSize
   // is forbidden.
   free(array);
   EXPECT_FALSE(__sanitizer_get_ownership(array));
   EXPECT_DEATH(__sanitizer_get_allocated_size(array),
                kGetAllocatedSizeErrorMsg);
   delete int_ptr;

   void *zero_alloc = Ident(malloc(0));
   if (zero_alloc != 0) {
     // If malloc(0) is not null, this pointer is owned and should have valid
     // allocated size.
     EXPECT_TRUE(__sanitizer_get_ownership(zero_alloc));
     // Allocated size is 0 or 1 depending on the allocator used.
     EXPECT_LT(__sanitizer_get_allocated_size(zero_alloc), 2U);
   }
   free(zero_alloc);
 }

 TEST(AddressSanitizerInterface, GetCurrentAllocatedBytesTest) {
   size_t before_malloc, after_malloc, after_free;
   char *array;
   const size_t kMallocSize = 100;
   before_malloc = __sanitizer_get_current_allocated_bytes();

   array = Ident((char*)malloc(kMallocSize));
   after_malloc = __sanitizer_get_current_allocated_bytes();
   EXPECT_EQ(before_malloc + kMallocSize, after_malloc);

   free(array);
   after_free = __sanitizer_get_current_allocated_bytes();
   EXPECT_EQ(before_malloc, after_free);
 }

 TEST(AddressSanitizerInterface, GetHeapSizeTest) {
   // ASan allocator does not keep huge chunks in free list, but unmaps them.
   // The chunk should be greater than the quarantine size,
   // otherwise it will be stuck in quarantine instead of being unmaped.
   static const size_t kLargeMallocSize = (1 << 28) + 1;  // 256M
   free(Ident(malloc(kLargeMallocSize)));  // Drain quarantine.
   size_t old_heap_size = __sanitizer_get_heap_size();
   for (int i = 0; i < 3; i++) {
     // fprintf(stderr, "allocating %zu bytes:\n", kLargeMallocSize);
     free(Ident(malloc(kLargeMallocSize)));
     EXPECT_EQ(old_heap_size, __sanitizer_get_heap_size());
   }
 }

 static const size_t kManyThreadsMallocSizes[] = {5, 1UL<<10, 1UL<<14, 357};
 static const size_t kManyThreadsIterations = 250;
 static const size_t kManyThreadsNumThreads =
   (SANITIZER_WORDSIZE == 32) ? 40 : 200;

 static void *ManyThreadsWithStatsWorker(void *arg) {
   (void)arg;
   for (size_t iter = 0; iter < kManyThreadsIterations; iter++) {
     for (size_t size_index = 0; size_index < 4; size_index++) {
       free(Ident(malloc(kManyThreadsMallocSizes[size_index])));
     }
   }
   // Just one large allocation.
   free(Ident(malloc(1 << 20)));
   return 0;
 }

 TEST(AddressSanitizerInterface, ManyThreadsWithStatsStressTest) {
   size_t before_test, after_test, i;
   pthread_t threads[kManyThreadsNumThreads];
   before_test = __sanitizer_get_current_allocated_bytes();
   for (i = 0; i < kManyThreadsNumThreads; i++) {
     PTHREAD_CREATE(&threads[i], 0,
                    (void* (*)(void *x))ManyThreadsWithStatsWorker, (void*)i);
   }
   for (i = 0; i < kManyThreadsNumThreads; i++) {
     PTHREAD_JOIN(threads[i], 0);
   }
   after_test = __sanitizer_get_current_allocated_bytes();
   // ASan stats also reflect memory usage of internal ASan RTL structs,
   // so we can't check for equality here.
   EXPECT_LT(after_test, before_test + (1UL<<20));
 }

 static void DoDoubleFree() {
   int *x = Ident(new int);
   delete Ident(x);
   delete Ident(x);
 }

 static void MyDeathCallback() {
   fprintf(stderr, "MyDeathCallback\n");
   fflush(0);  // On Windows, stderr doesn't flush on crash.
 }

 TEST(AddressSanitizerInterface, DeathCallbackTest) {
   __asan_set_death_callback(MyDeathCallback);
   EXPECT_DEATH(DoDoubleFree(), "MyDeathCallback");
   __asan_set_death_callback(NULL);
 }

 static const char* kUseAfterPoisonErrorMessage = "use-after-poison";

 #define GOOD_ACCESS(ptr, offset)  \
     EXPECT_FALSE(__asan_address_is_poisoned(ptr + offset))

 #define BAD_ACCESS(ptr, offset) \
     EXPECT_TRUE(__asan_address_is_poisoned(ptr + offset))

 TEST(AddressSanitizerInterface, SimplePoisonMemoryRegionTest) {
   char *array = Ident((char*)malloc(120));
   // poison array[40..80)
   __asan_poison_memory_region(array + 40, 40);
   GOOD_ACCESS(array, 39);
   GOOD_ACCESS(array, 80);
   BAD_ACCESS(array, 40);
   BAD_ACCESS(array, 60);
   BAD_ACCESS(array, 79);
   char value;
   EXPECT_DEATH(value = Ident(array[40]), kUseAfterPoisonErrorMessage);
   __asan_unpoison_memory_region(array + 40, 40);
   // access previously poisoned memory.
   GOOD_ACCESS(array, 40);
   GOOD_ACCESS(array, 79);
   free(array);
 }

 TEST(AddressSanitizerInterface, OverlappingPoisonMemoryRegionTest) {
   char *array = Ident((char*)malloc(120));
   // Poison [0..40) and [80..120)
   __asan_poison_memory_region(array, 40);
   __asan_poison_memory_region(array + 80, 40);
   BAD_ACCESS(array, 20);
   GOOD_ACCESS(array, 60);
   BAD_ACCESS(array, 100);
   // Poison whole array - [0..120)
   __asan_poison_memory_region(array, 120);
   BAD_ACCESS(array, 60);
   // Unpoison [24..96)
   __asan_unpoison_memory_region(array + 24, 72);
   BAD_ACCESS(array, 23);
   GOOD_ACCESS(array, 24);
   GOOD_ACCESS(array, 60);
   GOOD_ACCESS(array, 95);
   BAD_ACCESS(array, 96);
   free(array);
 }

 TEST(AddressSanitizerInterface, PushAndPopWithPoisoningTest) {
   // Vector of capacity 20
   char *vec = Ident((char*)malloc(20));
   __asan_poison_memory_region(vec, 20);
   for (size_t i = 0; i < 7; i++) {
     // Simulate push_back.
     __asan_unpoison_memory_region(vec + i, 1);
     GOOD_ACCESS(vec, i);
     BAD_ACCESS(vec, i + 1);
   }
   for (size_t i = 7; i > 0; i--) {
     // Simulate pop_back.
     __asan_poison_memory_region(vec + i - 1, 1);
     BAD_ACCESS(vec, i - 1);
     if (i > 1) GOOD_ACCESS(vec, i - 2);
   }
   free(vec);
 }

 // Make sure that each aligned block of size "2^granularity" doesn't have
 // "true" value before "false" value.
 static void MakeShadowValid(bool *shadow, int length, int granularity) {
   bool can_be_poisoned = true;
   for (int i = length - 1; i >= 0; i--) {
     if (!shadow[i])
       can_be_poisoned = false;
     if (!can_be_poisoned)
       shadow[i] = false;
     if (i % (1 << granularity) == 0) {
       can_be_poisoned = true;
     }
   }
 }

 TEST(AddressSanitizerInterface, PoisoningStressTest) {
   const size_t kSize = 24;
   bool expected[kSize];
   char *arr = Ident((char*)malloc(kSize));
   for (size_t l1 = 0; l1 < kSize; l1++) {
     for (size_t s1 = 1; l1 + s1 <= kSize; s1++) {
       for (size_t l2 = 0; l2 < kSize; l2++) {
         for (size_t s2 = 1; l2 + s2 <= kSize; s2++) {
           // Poison [l1, l1+s1), [l2, l2+s2) and check result.
           __asan_unpoison_memory_region(arr, kSize);
           __asan_poison_memory_region(arr + l1, s1);
           __asan_poison_memory_region(arr + l2, s2);
           memset(expected, false, kSize);
           memset(expected + l1, true, s1);
           MakeShadowValid(expected, kSize, /*granularity*/ 3);
           memset(expected + l2, true, s2);
           MakeShadowValid(expected, kSize, /*granularity*/ 3);
           for (size_t i = 0; i < kSize; i++) {
             ASSERT_EQ(expected[i], __asan_address_is_poisoned(arr + i));
           }
           // Unpoison [l1, l1+s1) and [l2, l2+s2) and check result.
           __asan_poison_memory_region(arr, kSize);
           __asan_unpoison_memory_region(arr + l1, s1);
           __asan_unpoison_memory_region(arr + l2, s2);
           memset(expected, true, kSize);
           memset(expected + l1, false, s1);
           MakeShadowValid(expected, kSize, /*granularity*/ 3);
           memset(expected + l2, false, s2);
           MakeShadowValid(expected, kSize, /*granularity*/ 3);
           for (size_t i = 0; i < kSize; i++) {
             ASSERT_EQ(expected[i], __asan_address_is_poisoned(arr + i));
           }
         }
       }
     }
   }
   free(arr);
 }

 TEST(AddressSanitizerInterface, GlobalRedzones) {
   GOOD_ACCESS(glob1, 1 - 1);
   GOOD_ACCESS(glob2, 2 - 1);
   GOOD_ACCESS(glob3, 3 - 1);
   GOOD_ACCESS(glob4, 4 - 1);
   GOOD_ACCESS(glob5, 5 - 1);
   GOOD_ACCESS(glob6, 6 - 1);
   GOOD_ACCESS(glob7, 7 - 1);
   GOOD_ACCESS(glob8, 8 - 1);
   GOOD_ACCESS(glob9, 9 - 1);
   GOOD_ACCESS(glob10, 10 - 1);
   GOOD_ACCESS(glob11, 11 - 1);
   GOOD_ACCESS(glob12, 12 - 1);
   GOOD_ACCESS(glob13, 13 - 1);
   GOOD_ACCESS(glob14, 14 - 1);
   GOOD_ACCESS(glob15, 15 - 1);
   GOOD_ACCESS(glob16, 16 - 1);
   GOOD_ACCESS(glob17, 17 - 1);
   GOOD_ACCESS(glob1000, 1000 - 1);
   GOOD_ACCESS(glob10000, 10000 - 1);
   GOOD_ACCESS(glob100000, 100000 - 1);

   BAD_ACCESS(glob1, 1);
   BAD_ACCESS(glob2, 2);
   BAD_ACCESS(glob3, 3);
   BAD_ACCESS(glob4, 4);
   BAD_ACCESS(glob5, 5);
   BAD_ACCESS(glob6, 6);
   BAD_ACCESS(glob7, 7);
   BAD_ACCESS(glob8, 8);
   BAD_ACCESS(glob9, 9);
   BAD_ACCESS(glob10, 10);
   BAD_ACCESS(glob11, 11);
   BAD_ACCESS(glob12, 12);
   BAD_ACCESS(glob13, 13);
   BAD_ACCESS(glob14, 14);
   BAD_ACCESS(glob15, 15);
   BAD_ACCESS(glob16, 16);
   BAD_ACCESS(glob17, 17);
   BAD_ACCESS(glob1000, 1000);
   BAD_ACCESS(glob1000, 1100);  // Redzone is at least 101 bytes.
   BAD_ACCESS(glob10000, 10000);
   BAD_ACCESS(glob10000, 11000);  // Redzone is at least 1001 bytes.
   BAD_ACCESS(glob100000, 100000);
   BAD_ACCESS(glob100000, 110000);  // Redzone is at least 10001 bytes.
 }

 TEST(AddressSanitizerInterface, PoisonedRegion) {
   size_t rz = 16;
   for (size_t size = 1; size <= 64; size++) {
     char *p = new char[size];
     for (size_t beg = 0; beg < size + rz; beg++) {
       for (size_t end = beg; end < size + rz; end++) {
         void *first_poisoned = __asan_region_is_poisoned(p + beg, end - beg);
         if (beg == end) {
           EXPECT_FALSE(first_poisoned);
         } else if (beg < size && end <= size) {
           EXPECT_FALSE(first_poisoned);
         } else if (beg >= size) {
           EXPECT_EQ(p + beg, first_poisoned);
         } else {
           EXPECT_GT(end, size);
           EXPECT_EQ(p + size, first_poisoned);
         }
       }
     }
     delete [] p;
   }
 }

 // This is a performance benchmark for manual runs.
 // asan's memset interceptor calls mem_is_zero for the entire shadow region.
 // the profile should look like this:
 //     89.10%   [.] __memset_sse2
 //     10.50%   [.] __sanitizer::mem_is_zero
 // I.e. mem_is_zero should consume ~ SHADOW_GRANULARITY less CPU cycles
 // than memset itself.
 TEST(AddressSanitizerInterface, DISABLED_StressLargeMemset) {
   size_t size = 1 << 20;
   char *x = new char[size];
   for (int i = 0; i < 100000; i++)
     Ident(memset)(x, 0, size);
   delete [] x;
 }

 // Same here, but we run memset with small sizes.
 TEST(AddressSanitizerInterface, DISABLED_StressSmallMemset) {
   size_t size = 32;
   char *x = new char[size];
   for (int i = 0; i < 100000000; i++)
     Ident(memset)(x, 0, size);
   delete [] x;
 }
 static const char *kInvalidPoisonMessage = "invalid-poison-memory-range";
 static const char *kInvalidUnpoisonMessage = "invalid-unpoison-memory-range";

 TEST(AddressSanitizerInterface, DISABLED_InvalidPoisonAndUnpoisonCallsTest) {
   char *array = Ident((char*)malloc(120));
   __asan_unpoison_memory_region(array, 120);
   // Try to unpoison not owned memory
   EXPECT_DEATH(__asan_unpoison_memory_region(array, 121),
                kInvalidUnpoisonMessage);
   EXPECT_DEATH(__asan_unpoison_memory_region(array - 1, 120),
                kInvalidUnpoisonMessage);

   __asan_poison_memory_region(array, 120);
   // Try to poison not owned memory.
   EXPECT_DEATH(__asan_poison_memory_region(array, 121), kInvalidPoisonMessage);
   EXPECT_DEATH(__asan_poison_memory_region(array - 1, 120),
                kInvalidPoisonMessage);
   free(array);
 }

 #if !defined(_WIN32)  // FIXME: This should really be a lit test.
 static void ErrorReportCallbackOneToZ(const char *report) {
   int report_len = strlen(report);
   ASSERT_EQ(6, write(2, "ABCDEF", 6));
   ASSERT_EQ(report_len, write(2, report, report_len));
   ASSERT_EQ(6, write(2, "ABCDEF", 6));
   _exit(1);
 }

 TEST(AddressSanitizerInterface, SetErrorReportCallbackTest) {
   __asan_set_error_report_callback(ErrorReportCallbackOneToZ);
   EXPECT_DEATH(__asan_report_error(0, 0, 0, 0, true, 1),
                ASAN_PCRE_DOTALL "ABCDEF.*AddressSanitizer.*WRITE.*ABCDEF");
   __asan_set_error_report_callback(NULL);
 }
 #endif

 TEST(AddressSanitizerInterface, GetOwnershipStressTest) {
   std::vector<char *> pointers;
   std::vector<size_t> sizes;
   const size_t kNumMallocs = 1 << 9;
   for (size_t i = 0; i < kNumMallocs; i++) {
     size_t size = i * 100 + 1;
     pointers.push_back((char*)malloc(size));
     sizes.push_back(size);
   }
   for (size_t i = 0; i < 4000000; i++) {
     EXPECT_FALSE(__sanitizer_get_ownership(&pointers));
     EXPECT_FALSE(__sanitizer_get_ownership((void*)0x1234));
     size_t idx = i % kNumMallocs;
     EXPECT_TRUE(__sanitizer_get_ownership(pointers[idx]));
     EXPECT_EQ(sizes[idx], __sanitizer_get_allocated_size(pointers[idx]));
   }
   for (size_t i = 0, n = pointers.size(); i < n; i++)
     free(pointers[i]);
 }
	//===-- asan_interface_test.cc --------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file is a part of AddressSanitizer, an address sanity checker.
	//
	//===----------------------------------------------------------------------===//
	#include "asan_test_utils.h"
	#include <sanitizer/allocator_interface.h>
	#include <sanitizer/asan_interface.h>

	TEST(AddressSanitizerInterface, GetEstimatedAllocatedSize) {
	EXPECT_EQ(0U, __sanitizer_get_estimated_allocated_size(0));
	const size_t sizes[] = { 1, 30, 1<<30 };
	for (size_t i = 0; i < 3; i++) {
	EXPECT_EQ(sizes[i], __sanitizer_get_estimated_allocated_size(sizes[i]));
	}
	}

	static const char* kGetAllocatedSizeErrorMsg =
	"attempting to call __sanitizer_get_allocated_size";

	TEST(AddressSanitizerInterface, GetAllocatedSizeAndOwnershipTest) {
	const size_t kArraySize = 100;
	char array = Ident((char)malloc(kArraySize));
	int *int_ptr = Ident(new int);

	// Allocated memory is owned by allocator. Allocated size should be
	// equal to requested size.
	EXPECT_EQ(true, __sanitizer_get_ownership(array));
	EXPECT_EQ(kArraySize, __sanitizer_get_allocated_size(array));
	EXPECT_EQ(true, __sanitizer_get_ownership(int_ptr));
	EXPECT_EQ(sizeof(int), __sanitizer_get_allocated_size(int_ptr));

	// We cannot call GetAllocatedSize from the memory we didn't map,
	// and from the interior pointers (not returned by previous malloc).
	void wild_addr = (void)0x1;
	EXPECT_FALSE(__sanitizer_get_ownership(wild_addr));
	EXPECT_DEATH(__sanitizer_get_allocated_size(wild_addr),
	kGetAllocatedSizeErrorMsg);
	EXPECT_FALSE(__sanitizer_get_ownership(array + kArraySize / 2));
	EXPECT_DEATH(__sanitizer_get_allocated_size(array + kArraySize / 2),
	kGetAllocatedSizeErrorMsg);

	// NULL is not owned, but is a valid argument for
	// __sanitizer_get_allocated_size().
	EXPECT_FALSE(__sanitizer_get_ownership(NULL));
	EXPECT_EQ(0U, __sanitizer_get_allocated_size(NULL));

	// When memory is freed, it's not owned, and call to GetAllocatedSize
	// is forbidden.
	free(array);
	EXPECT_FALSE(__sanitizer_get_ownership(array));
	EXPECT_DEATH(__sanitizer_get_allocated_size(array),
	kGetAllocatedSizeErrorMsg);
	delete int_ptr;

	void *zero_alloc = Ident(malloc(0));
	if (zero_alloc != 0) {
	// If malloc(0) is not null, this pointer is owned and should have valid
	// allocated size.
	EXPECT_TRUE(__sanitizer_get_ownership(zero_alloc));
	// Allocated size is 0 or 1 depending on the allocator used.
	EXPECT_LT(__sanitizer_get_allocated_size(zero_alloc), 2U);
	}
	free(zero_alloc);
	}

	TEST(AddressSanitizerInterface, GetCurrentAllocatedBytesTest) {
	size_t before_malloc, after_malloc, after_free;
	char *array;
	const size_t kMallocSize = 100;
	before_malloc = __sanitizer_get_current_allocated_bytes();

	array = Ident((char*)malloc(kMallocSize));
	after_malloc = __sanitizer_get_current_allocated_bytes();
	EXPECT_EQ(before_malloc + kMallocSize, after_malloc);

	free(array);
	after_free = __sanitizer_get_current_allocated_bytes();
	EXPECT_EQ(before_malloc, after_free);
	}

	TEST(AddressSanitizerInterface, GetHeapSizeTest) {
	// ASan allocator does not keep huge chunks in free list, but unmaps them.
	// The chunk should be greater than the quarantine size,
	// otherwise it will be stuck in quarantine instead of being unmaped.
	static const size_t kLargeMallocSize = (1 << 28) + 1; // 256M
	free(Ident(malloc(kLargeMallocSize))); // Drain quarantine.
	size_t old_heap_size = __sanitizer_get_heap_size();
	for (int i = 0; i < 3; i++) {
	// fprintf(stderr, "allocating %zu bytes:\n", kLargeMallocSize);
	free(Ident(malloc(kLargeMallocSize)));
	EXPECT_EQ(old_heap_size, __sanitizer_get_heap_size());
	}
	}

	static const size_t kManyThreadsMallocSizes[] = {5, 1UL<<10, 1UL<<14, 357};
	static const size_t kManyThreadsIterations = 250;
	static const size_t kManyThreadsNumThreads =
	(SANITIZER_WORDSIZE == 32) ? 40 : 200;

	static void ManyThreadsWithStatsWorker(void arg) {
	(void)arg;
	for (size_t iter = 0; iter < kManyThreadsIterations; iter++) {
	for (size_t size_index = 0; size_index < 4; size_index++) {
	free(Ident(malloc(kManyThreadsMallocSizes[size_index])));
	}
	}
	// Just one large allocation.
	free(Ident(malloc(1 << 20)));
	return 0;
	}

	TEST(AddressSanitizerInterface, ManyThreadsWithStatsStressTest) {
	size_t before_test, after_test, i;
	pthread_t threads[kManyThreadsNumThreads];
	before_test = __sanitizer_get_current_allocated_bytes();
	for (i = 0; i < kManyThreadsNumThreads; i++) {
	PTHREAD_CREATE(&threads[i], 0,
	(void* ()(void x))ManyThreadsWithStatsWorker, (void*)i);
	}
	for (i = 0; i < kManyThreadsNumThreads; i++) {
	PTHREAD_JOIN(threads[i], 0);
	}
	after_test = __sanitizer_get_current_allocated_bytes();
	// ASan stats also reflect memory usage of internal ASan RTL structs,
	// so we can't check for equality here.
	EXPECT_LT(after_test, before_test + (1UL<<20));
	}

	static void DoDoubleFree() {
	int *x = Ident(new int);
	delete Ident(x);
	delete Ident(x);
	}

	static void MyDeathCallback() {
	fprintf(stderr, "MyDeathCallback\n");
	fflush(0); // On Windows, stderr doesn't flush on crash.
	}

	TEST(AddressSanitizerInterface, DeathCallbackTest) {
	__asan_set_death_callback(MyDeathCallback);
	EXPECT_DEATH(DoDoubleFree(), "MyDeathCallback");
	__asan_set_death_callback(NULL);
	}

	static const char* kUseAfterPoisonErrorMessage = "use-after-poison";

	#define GOOD_ACCESS(ptr, offset) \
	EXPECT_FALSE(__asan_address_is_poisoned(ptr + offset))

	#define BAD_ACCESS(ptr, offset) \
	EXPECT_TRUE(__asan_address_is_poisoned(ptr + offset))

	TEST(AddressSanitizerInterface, SimplePoisonMemoryRegionTest) {
	char array = Ident((char)malloc(120));
	// poison array[40..80)
	__asan_poison_memory_region(array + 40, 40);
	GOOD_ACCESS(array, 39);
	GOOD_ACCESS(array, 80);
	BAD_ACCESS(array, 40);
	BAD_ACCESS(array, 60);
	BAD_ACCESS(array, 79);
	char value;
	EXPECT_DEATH(value = Ident(array[40]), kUseAfterPoisonErrorMessage);
	__asan_unpoison_memory_region(array + 40, 40);
	// access previously poisoned memory.
	GOOD_ACCESS(array, 40);
	GOOD_ACCESS(array, 79);
	free(array);
	}

	TEST(AddressSanitizerInterface, OverlappingPoisonMemoryRegionTest) {
	char array = Ident((char)malloc(120));
	// Poison [0..40) and [80..120)
	__asan_poison_memory_region(array, 40);
	__asan_poison_memory_region(array + 80, 40);
	BAD_ACCESS(array, 20);
	GOOD_ACCESS(array, 60);
	BAD_ACCESS(array, 100);
	// Poison whole array - [0..120)
	__asan_poison_memory_region(array, 120);
	BAD_ACCESS(array, 60);
	// Unpoison [24..96)
	__asan_unpoison_memory_region(array + 24, 72);
	BAD_ACCESS(array, 23);
	GOOD_ACCESS(array, 24);
	GOOD_ACCESS(array, 60);
	GOOD_ACCESS(array, 95);
	BAD_ACCESS(array, 96);
	free(array);
	}

	TEST(AddressSanitizerInterface, PushAndPopWithPoisoningTest) {
	// Vector of capacity 20
	char vec = Ident((char)malloc(20));
	__asan_poison_memory_region(vec, 20);
	for (size_t i = 0; i < 7; i++) {
	// Simulate push_back.
	__asan_unpoison_memory_region(vec + i, 1);
	GOOD_ACCESS(vec, i);
	BAD_ACCESS(vec, i + 1);
	}
	for (size_t i = 7; i > 0; i--) {
	// Simulate pop_back.
	__asan_poison_memory_region(vec + i - 1, 1);
	BAD_ACCESS(vec, i - 1);
	if (i > 1) GOOD_ACCESS(vec, i - 2);
	}
	free(vec);
	}

	// Make sure that each aligned block of size "2^granularity" doesn't have
	// "true" value before "false" value.
	static void MakeShadowValid(bool *shadow, int length, int granularity) {
	bool can_be_poisoned = true;
	for (int i = length - 1; i >= 0; i--) {
	if (!shadow[i])
	can_be_poisoned = false;
	if (!can_be_poisoned)
	shadow[i] = false;
	if (i % (1 << granularity) == 0) {
	can_be_poisoned = true;
	}
	}
	}

	TEST(AddressSanitizerInterface, PoisoningStressTest) {
	const size_t kSize = 24;
	bool expected[kSize];
	char arr = Ident((char)malloc(kSize));
	for (size_t l1 = 0; l1 < kSize; l1++) {
	for (size_t s1 = 1; l1 + s1 <= kSize; s1++) {
	for (size_t l2 = 0; l2 < kSize; l2++) {
	for (size_t s2 = 1; l2 + s2 <= kSize; s2++) {
	// Poison [l1, l1+s1), [l2, l2+s2) and check result.
	__asan_unpoison_memory_region(arr, kSize);
	__asan_poison_memory_region(arr + l1, s1);
	__asan_poison_memory_region(arr + l2, s2);
	memset(expected, false, kSize);
	memset(expected + l1, true, s1);
	MakeShadowValid(expected, kSize, /granularity/ 3);
	memset(expected + l2, true, s2);
	MakeShadowValid(expected, kSize, /granularity/ 3);
	for (size_t i = 0; i < kSize; i++) {
	ASSERT_EQ(expected[i], __asan_address_is_poisoned(arr + i));
	}
	// Unpoison [l1, l1+s1) and [l2, l2+s2) and check result.
	__asan_poison_memory_region(arr, kSize);
	__asan_unpoison_memory_region(arr + l1, s1);
	__asan_unpoison_memory_region(arr + l2, s2);
	memset(expected, true, kSize);
	memset(expected + l1, false, s1);
	MakeShadowValid(expected, kSize, /granularity/ 3);
	memset(expected + l2, false, s2);
	MakeShadowValid(expected, kSize, /granularity/ 3);
	for (size_t i = 0; i < kSize; i++) {
	ASSERT_EQ(expected[i], __asan_address_is_poisoned(arr + i));
	}
	}
	}
	}
	}
	free(arr);
	}

	TEST(AddressSanitizerInterface, GlobalRedzones) {
	GOOD_ACCESS(glob1, 1 - 1);
	GOOD_ACCESS(glob2, 2 - 1);
	GOOD_ACCESS(glob3, 3 - 1);
	GOOD_ACCESS(glob4, 4 - 1);
	GOOD_ACCESS(glob5, 5 - 1);
	GOOD_ACCESS(glob6, 6 - 1);
	GOOD_ACCESS(glob7, 7 - 1);
	GOOD_ACCESS(glob8, 8 - 1);
	GOOD_ACCESS(glob9, 9 - 1);
	GOOD_ACCESS(glob10, 10 - 1);
	GOOD_ACCESS(glob11, 11 - 1);
	GOOD_ACCESS(glob12, 12 - 1);
	GOOD_ACCESS(glob13, 13 - 1);
	GOOD_ACCESS(glob14, 14 - 1);
	GOOD_ACCESS(glob15, 15 - 1);
	GOOD_ACCESS(glob16, 16 - 1);
	GOOD_ACCESS(glob17, 17 - 1);
	GOOD_ACCESS(glob1000, 1000 - 1);
	GOOD_ACCESS(glob10000, 10000 - 1);
	GOOD_ACCESS(glob100000, 100000 - 1);

	BAD_ACCESS(glob1, 1);
	BAD_ACCESS(glob2, 2);
	BAD_ACCESS(glob3, 3);
	BAD_ACCESS(glob4, 4);
	BAD_ACCESS(glob5, 5);
	BAD_ACCESS(glob6, 6);
	BAD_ACCESS(glob7, 7);
	BAD_ACCESS(glob8, 8);
	BAD_ACCESS(glob9, 9);
	BAD_ACCESS(glob10, 10);
	BAD_ACCESS(glob11, 11);
	BAD_ACCESS(glob12, 12);
	BAD_ACCESS(glob13, 13);
	BAD_ACCESS(glob14, 14);
	BAD_ACCESS(glob15, 15);
	BAD_ACCESS(glob16, 16);
	BAD_ACCESS(glob17, 17);
	BAD_ACCESS(glob1000, 1000);
	BAD_ACCESS(glob1000, 1100); // Redzone is at least 101 bytes.
	BAD_ACCESS(glob10000, 10000);
	BAD_ACCESS(glob10000, 11000); // Redzone is at least 1001 bytes.
	BAD_ACCESS(glob100000, 100000);
	BAD_ACCESS(glob100000, 110000); // Redzone is at least 10001 bytes.
	}

	TEST(AddressSanitizerInterface, PoisonedRegion) {
	size_t rz = 16;
	for (size_t size = 1; size <= 64; size++) {
	char *p = new char[size];
	for (size_t beg = 0; beg < size + rz; beg++) {
	for (size_t end = beg; end < size + rz; end++) {
	void *first_poisoned = __asan_region_is_poisoned(p + beg, end - beg);
	if (beg == end) {
	EXPECT_FALSE(first_poisoned);
	} else if (beg < size && end <= size) {
	EXPECT_FALSE(first_poisoned);
	} else if (beg >= size) {
	EXPECT_EQ(p + beg, first_poisoned);
	} else {
	EXPECT_GT(end, size);
	EXPECT_EQ(p + size, first_poisoned);
	}
	}
	}
	delete [] p;
	}
	}

	// This is a performance benchmark for manual runs.
	// asan's memset interceptor calls mem_is_zero for the entire shadow region.
	// the profile should look like this:
	// 89.10% [.] __memset_sse2
	// 10.50% [.] __sanitizer::mem_is_zero
	// I.e. mem_is_zero should consume ~ SHADOW_GRANULARITY less CPU cycles
	// than memset itself.
	TEST(AddressSanitizerInterface, DISABLED_StressLargeMemset) {
	size_t size = 1 << 20;
	char *x = new char[size];
	for (int i = 0; i < 100000; i++)
	Ident(memset)(x, 0, size);
	delete [] x;
	}

	// Same here, but we run memset with small sizes.
	TEST(AddressSanitizerInterface, DISABLED_StressSmallMemset) {
	size_t size = 32;
	char *x = new char[size];
	for (int i = 0; i < 100000000; i++)
	Ident(memset)(x, 0, size);
	delete [] x;
	}
	static const char *kInvalidPoisonMessage = "invalid-poison-memory-range";
	static const char *kInvalidUnpoisonMessage = "invalid-unpoison-memory-range";

	TEST(AddressSanitizerInterface, DISABLED_InvalidPoisonAndUnpoisonCallsTest) {
	char array = Ident((char)malloc(120));
	__asan_unpoison_memory_region(array, 120);
	// Try to unpoison not owned memory
	EXPECT_DEATH(__asan_unpoison_memory_region(array, 121),
	kInvalidUnpoisonMessage);
	EXPECT_DEATH(__asan_unpoison_memory_region(array - 1, 120),
	kInvalidUnpoisonMessage);

	__asan_poison_memory_region(array, 120);
	// Try to poison not owned memory.
	EXPECT_DEATH(__asan_poison_memory_region(array, 121), kInvalidPoisonMessage);
	EXPECT_DEATH(__asan_poison_memory_region(array - 1, 120),
	kInvalidPoisonMessage);
	free(array);
	}

	#if !defined(_WIN32) // FIXME: This should really be a lit test.
	static void ErrorReportCallbackOneToZ(const char *report) {
	int report_len = strlen(report);
	ASSERT_EQ(6, write(2, "ABCDEF", 6));
	ASSERT_EQ(report_len, write(2, report, report_len));
	ASSERT_EQ(6, write(2, "ABCDEF", 6));
	_exit(1);
	}

	TEST(AddressSanitizerInterface, SetErrorReportCallbackTest) {
	__asan_set_error_report_callback(ErrorReportCallbackOneToZ);
	EXPECT_DEATH(__asan_report_error(0, 0, 0, 0, true, 1),
	ASAN_PCRE_DOTALL "ABCDEF.AddressSanitizer.WRITE.*ABCDEF");
	__asan_set_error_report_callback(NULL);
	}
	#endif

	TEST(AddressSanitizerInterface, GetOwnershipStressTest) {
	std::vector<char *> pointers;
	std::vector<size_t> sizes;
	const size_t kNumMallocs = 1 << 9;
	for (size_t i = 0; i < kNumMallocs; i++) {
	size_t size = i * 100 + 1;
	pointers.push_back((char*)malloc(size));
	sizes.push_back(size);
	}
	for (size_t i = 0; i < 4000000; i++) {
	EXPECT_FALSE(__sanitizer_get_ownership(&pointers));
	EXPECT_FALSE(__sanitizer_get_ownership((void*)0x1234));
	size_t idx = i % kNumMallocs;
	EXPECT_TRUE(__sanitizer_get_ownership(pointers[idx]));
	EXPECT_EQ(sizes[idx], __sanitizer_get_allocated_size(pointers[idx]));
	}
	for (size_t i = 0, n = pointers.size(); i < n; i++)
	free(pointers[i]);
	}