//===-- asan_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 <stdio.h> #include <signal.h> #include <stdlib.h> #include <string.h> #include <strings.h> #include <pthread.h> #include <stdint.h> #include <setjmp.h> #include <assert.h> #if defined(__i386__) || defined(__x86_64__) #include <emmintrin.h> #endif #include "asan_test_config.h" #include "asan_test_utils.h" #ifndef __APPLE__ #include <malloc.h> #else #include <AvailabilityMacros.h> // For MAC_OS_X_VERSION_* #include <CoreFoundation/CFString.h> #endif // __APPLE__ #if ASAN_HAS_EXCEPTIONS # define ASAN_THROW(x) throw (x) #else # define ASAN_THROW(x) #endif #include <sys/mman.h> typedef uint8_t U1; typedef uint16_t U2; typedef uint32_t U4; typedef uint64_t U8; static const char *progname; static const int kPageSize = 4096; // Simple stand-alone pseudorandom number generator. // Current algorithm is ANSI C linear congruential PRNG. static inline uint32_t my_rand(uint32_t* state) { return (*state = *state * 1103515245 + 12345) >> 16; } static uint32_t global_seed = 0; const size_t kLargeMalloc = 1 << 24; template<typename T> NOINLINE void asan_write(T *a) { *a = 0; } NOINLINE void asan_write_sized_aligned(uint8_t *p, size_t size) { EXPECT_EQ(0, ((uintptr_t)p % size)); if (size == 1) asan_write((uint8_t*)p); else if (size == 2) asan_write((uint16_t*)p); else if (size == 4) asan_write((uint32_t*)p); else if (size == 8) asan_write((uint64_t*)p); } NOINLINE void *malloc_fff(size_t size) { void *res = malloc/**/(size); break_optimization(0); return res;} NOINLINE void *malloc_eee(size_t size) { void *res = malloc_fff(size); break_optimization(0); return res;} NOINLINE void *malloc_ddd(size_t size) { void *res = malloc_eee(size); break_optimization(0); return res;} NOINLINE void *malloc_ccc(size_t size) { void *res = malloc_ddd(size); break_optimization(0); return res;} NOINLINE void *malloc_bbb(size_t size) { void *res = malloc_ccc(size); break_optimization(0); return res;} NOINLINE void *malloc_aaa(size_t size) { void *res = malloc_bbb(size); break_optimization(0); return res;} #ifndef __APPLE__ NOINLINE void *memalign_fff(size_t alignment, size_t size) { void *res = memalign/**/(alignment, size); break_optimization(0); return res;} NOINLINE void *memalign_eee(size_t alignment, size_t size) { void *res = memalign_fff(alignment, size); break_optimization(0); return res;} NOINLINE void *memalign_ddd(size_t alignment, size_t size) { void *res = memalign_eee(alignment, size); break_optimization(0); return res;} NOINLINE void *memalign_ccc(size_t alignment, size_t size) { void *res = memalign_ddd(alignment, size); break_optimization(0); return res;} NOINLINE void *memalign_bbb(size_t alignment, size_t size) { void *res = memalign_ccc(alignment, size); break_optimization(0); return res;} NOINLINE void *memalign_aaa(size_t alignment, size_t size) { void *res = memalign_bbb(alignment, size); break_optimization(0); return res;} #endif // __APPLE__ NOINLINE void free_ccc(void *p) { free(p); break_optimization(0);} NOINLINE void free_bbb(void *p) { free_ccc(p); break_optimization(0);} NOINLINE void free_aaa(void *p) { free_bbb(p); break_optimization(0);} template<typename T> NOINLINE void oob_test(int size, int off) { char *p = (char*)malloc_aaa(size); // fprintf(stderr, "writing %d byte(s) into [%p,%p) with offset %d\n", // sizeof(T), p, p + size, off); asan_write((T*)(p + off)); free_aaa(p); } template<typename T> NOINLINE void uaf_test(int size, int off) { char *p = (char *)malloc_aaa(size); free_aaa(p); for (int i = 1; i < 100; i++) free_aaa(malloc_aaa(i)); fprintf(stderr, "writing %ld byte(s) at %p with offset %d\n", (long)sizeof(T), p, off); asan_write((T*)(p + off)); } TEST(AddressSanitizer, HasFeatureAddressSanitizerTest) { #if defined(__has_feature) && __has_feature(address_sanitizer) bool asan = 1; #else bool asan = 0; #endif EXPECT_EQ(true, asan); } TEST(AddressSanitizer, SimpleDeathTest) { EXPECT_DEATH(exit(1), ""); } TEST(AddressSanitizer, VariousMallocsTest) { // fprintf(stderr, "malloc:\n"); int *a = (int*)malloc(100 * sizeof(int)); a[50] = 0; free(a); // fprintf(stderr, "realloc:\n"); int *r = (int*)malloc(10); r = (int*)realloc(r, 2000 * sizeof(int)); r[1000] = 0; free(r); // fprintf(stderr, "operator new []\n"); int *b = new int[100]; b[50] = 0; delete [] b; // fprintf(stderr, "operator new\n"); int *c = new int; *c = 0; delete c; #if !defined(__APPLE__) && !defined(ANDROID) && !defined(__ANDROID__) // fprintf(stderr, "posix_memalign\n"); int *pm; int pm_res = posix_memalign((void**)&pm, kPageSize, kPageSize); EXPECT_EQ(0, pm_res); free(pm); #endif #if !defined(__APPLE__) int *ma = (int*)memalign(kPageSize, kPageSize); EXPECT_EQ(0, (uintptr_t)ma % kPageSize); ma[123] = 0; free(ma); #endif // __APPLE__ } TEST(AddressSanitizer, CallocTest) { int *a = (int*)calloc(100, sizeof(int)); EXPECT_EQ(0, a[10]); free(a); } TEST(AddressSanitizer, VallocTest) { void *a = valloc(100); EXPECT_EQ(0, (uintptr_t)a % kPageSize); free(a); } #ifndef __APPLE__ TEST(AddressSanitizer, PvallocTest) { char *a = (char*)pvalloc(kPageSize + 100); EXPECT_EQ(0, (uintptr_t)a % kPageSize); a[kPageSize + 101] = 1; // we should not report an error here. free(a); a = (char*)pvalloc(0); // pvalloc(0) should allocate at least one page. EXPECT_EQ(0, (uintptr_t)a % kPageSize); a[101] = 1; // we should not report an error here. free(a); } #endif // __APPLE__ void *TSDWorker(void *test_key) { if (test_key) { pthread_setspecific(*(pthread_key_t*)test_key, (void*)0xfeedface); } return NULL; } void TSDDestructor(void *tsd) { // Spawning a thread will check that the current thread id is not -1. pthread_t th; pthread_create(&th, NULL, TSDWorker, NULL); pthread_join(th, NULL); } // This tests triggers the thread-specific data destruction fiasco which occurs // if we don't manage the TSD destructors ourselves. We create a new pthread // key with a non-NULL destructor which is likely to be put after the destructor // of AsanThread in the list of destructors. // In this case the TSD for AsanThread will be destroyed before TSDDestructor // is called for the child thread, and a CHECK will fail when we call // pthread_create() to spawn the grandchild. TEST(AddressSanitizer, DISABLED_TSDTest) { pthread_t th; pthread_key_t test_key; pthread_key_create(&test_key, TSDDestructor); pthread_create(&th, NULL, TSDWorker, &test_key); pthread_join(th, NULL); pthread_key_delete(test_key); } template<typename T> void OOBTest() { char expected_str[100]; for (int size = sizeof(T); size < 20; size += 5) { for (int i = -5; i < 0; i++) { const char *str = "is located.*%d byte.*to the left"; sprintf(expected_str, str, abs(i)); EXPECT_DEATH(oob_test<T>(size, i), expected_str); } for (int i = 0; i < size - sizeof(T) + 1; i++) oob_test<T>(size, i); for (int i = size - sizeof(T) + 1; i <= size + 3 * sizeof(T); i++) { const char *str = "is located.*%d byte.*to the right"; int off = i >= size ? (i - size) : 0; // we don't catch unaligned partially OOB accesses. if (i % sizeof(T)) continue; sprintf(expected_str, str, off); EXPECT_DEATH(oob_test<T>(size, i), expected_str); } } EXPECT_DEATH(oob_test<T>(kLargeMalloc, -1), "is located.*1 byte.*to the left"); EXPECT_DEATH(oob_test<T>(kLargeMalloc, kLargeMalloc), "is located.*0 byte.*to the right"); } // TODO(glider): the following tests are EXTREMELY slow on Darwin: // AddressSanitizer.OOB_char (125503 ms) // AddressSanitizer.OOB_int (126890 ms) // AddressSanitizer.OOBRightTest (315605 ms) // AddressSanitizer.SimpleStackTest (366559 ms) TEST(AddressSanitizer, OOB_char) { OOBTest<U1>(); } TEST(AddressSanitizer, OOB_int) { OOBTest<U4>(); } TEST(AddressSanitizer, OOBRightTest) { for (size_t access_size = 1; access_size <= 8; access_size *= 2) { for (size_t alloc_size = 1; alloc_size <= 8; alloc_size++) { for (size_t offset = 0; offset <= 8; offset += access_size) { void *p = malloc(alloc_size); // allocated: [p, p + alloc_size) // accessed: [p + offset, p + offset + access_size) uint8_t *addr = (uint8_t*)p + offset; if (offset + access_size <= alloc_size) { asan_write_sized_aligned(addr, access_size); } else { int outside_bytes = offset > alloc_size ? (offset - alloc_size) : 0; const char *str = "is located.%d *byte.*to the right"; char expected_str[100]; sprintf(expected_str, str, outside_bytes); EXPECT_DEATH(asan_write_sized_aligned(addr, access_size), expected_str); } free(p); } } } } TEST(AddressSanitizer, UAF_char) { const char *uaf_string = "AddressSanitizer.*heap-use-after-free"; EXPECT_DEATH(uaf_test<U1>(1, 0), uaf_string); EXPECT_DEATH(uaf_test<U1>(10, 0), uaf_string); EXPECT_DEATH(uaf_test<U1>(10, 10), uaf_string); EXPECT_DEATH(uaf_test<U1>(kLargeMalloc, 0), uaf_string); EXPECT_DEATH(uaf_test<U1>(kLargeMalloc, kLargeMalloc / 2), uaf_string); } #if ASAN_HAS_BLACKLIST TEST(AddressSanitizer, IgnoreTest) { int *x = Ident(new int); delete Ident(x); *x = 0; } #endif // ASAN_HAS_BLACKLIST struct StructWithBitField { int bf1:1; int bf2:1; int bf3:1; int bf4:29; }; TEST(AddressSanitizer, BitFieldPositiveTest) { StructWithBitField *x = new StructWithBitField; delete Ident(x); EXPECT_DEATH(x->bf1 = 0, "use-after-free"); EXPECT_DEATH(x->bf2 = 0, "use-after-free"); EXPECT_DEATH(x->bf3 = 0, "use-after-free"); EXPECT_DEATH(x->bf4 = 0, "use-after-free"); }; struct StructWithBitFields_8_24 { int a:8; int b:24; }; TEST(AddressSanitizer, BitFieldNegativeTest) { StructWithBitFields_8_24 *x = Ident(new StructWithBitFields_8_24); x->a = 0; x->b = 0; delete Ident(x); } TEST(AddressSanitizer, OutOfMemoryTest) { size_t size = __WORDSIZE == 64 ? (size_t)(1ULL << 48) : (0xf0000000); EXPECT_EQ(0, realloc(0, size)); EXPECT_EQ(0, realloc(0, ~Ident(0))); EXPECT_EQ(0, malloc(size)); EXPECT_EQ(0, malloc(~Ident(0))); EXPECT_EQ(0, calloc(1, size)); EXPECT_EQ(0, calloc(1, ~Ident(0))); } #if ASAN_NEEDS_SEGV TEST(AddressSanitizer, WildAddressTest) { char *c = (char*)0x123; EXPECT_DEATH(*c = 0, "AddressSanitizer crashed on unknown address"); } #endif static void MallocStress(size_t n) { uint32_t seed = my_rand(&global_seed); for (size_t iter = 0; iter < 10; iter++) { vector<void *> vec; for (size_t i = 0; i < n; i++) { if ((i % 3) == 0) { if (vec.empty()) continue; size_t idx = my_rand(&seed) % vec.size(); void *ptr = vec[idx]; vec[idx] = vec.back(); vec.pop_back(); free_aaa(ptr); } else { size_t size = my_rand(&seed) % 1000 + 1; #ifndef __APPLE__ size_t alignment = 1 << (my_rand(&seed) % 7 + 3); char *ptr = (char*)memalign_aaa(alignment, size); #else char *ptr = (char*) malloc_aaa(size); #endif vec.push_back(ptr); ptr[0] = 0; ptr[size-1] = 0; ptr[size/2] = 0; } } for (size_t i = 0; i < vec.size(); i++) free_aaa(vec[i]); } } TEST(AddressSanitizer, MallocStressTest) { MallocStress((ASAN_LOW_MEMORY) ? 20000 : 200000); } static void TestLargeMalloc(size_t size) { char buff[1024]; sprintf(buff, "is located 1 bytes to the left of %lu-byte", (long)size); EXPECT_DEATH(Ident((char*)malloc(size))[-1] = 0, buff); } TEST(AddressSanitizer, LargeMallocTest) { for (int i = 113; i < (1 << 28); i = i * 2 + 13) { TestLargeMalloc(i); } } #if ASAN_LOW_MEMORY != 1 TEST(AddressSanitizer, HugeMallocTest) { #ifdef __APPLE__ // It was empirically found out that 1215 megabytes is the maximum amount of // memory available to the process under AddressSanitizer on 32-bit Mac 10.6. // 32-bit Mac 10.7 gives even less (< 1G). // (the libSystem malloc() allows allocating up to 2300 megabytes without // ASan). size_t n_megs = __WORDSIZE == 32 ? 500 : 4100; #else size_t n_megs = __WORDSIZE == 32 ? 2600 : 4100; #endif TestLargeMalloc(n_megs << 20); } #endif TEST(AddressSanitizer, ThreadedMallocStressTest) { const int kNumThreads = 4; const int kNumIterations = (ASAN_LOW_MEMORY) ? 10000 : 100000; pthread_t t[kNumThreads]; for (int i = 0; i < kNumThreads; i++) { pthread_create(&t[i], 0, (void* (*)(void *x))MallocStress, (void*)kNumIterations); } for (int i = 0; i < kNumThreads; i++) { pthread_join(t[i], 0); } } void *ManyThreadsWorker(void *a) { for (int iter = 0; iter < 100; iter++) { for (size_t size = 100; size < 2000; size *= 2) { free(Ident(malloc(size))); } } return 0; } TEST(AddressSanitizer, ManyThreadsTest) { const size_t kNumThreads = __WORDSIZE == 32 ? 30 : 1000; pthread_t t[kNumThreads]; for (size_t i = 0; i < kNumThreads; i++) { pthread_create(&t[i], 0, (void* (*)(void *x))ManyThreadsWorker, (void*)i); } for (size_t i = 0; i < kNumThreads; i++) { pthread_join(t[i], 0); } } TEST(AddressSanitizer, ReallocTest) { const int kMinElem = 5; int *ptr = (int*)malloc(sizeof(int) * kMinElem); ptr[3] = 3; for (int i = 0; i < 10000; i++) { ptr = (int*)realloc(ptr, (my_rand(&global_seed) % 1000 + kMinElem) * sizeof(int)); EXPECT_EQ(3, ptr[3]); } } #ifndef __APPLE__ static const char *kMallocUsableSizeErrorMsg = "AddressSanitizer attempting to call malloc_usable_size()"; TEST(AddressSanitizer, MallocUsableSizeTest) { const size_t kArraySize = 100; char *array = Ident((char*)malloc(kArraySize)); int *int_ptr = Ident(new int); EXPECT_EQ(0, malloc_usable_size(NULL)); EXPECT_EQ(kArraySize, malloc_usable_size(array)); EXPECT_EQ(sizeof(int), malloc_usable_size(int_ptr)); EXPECT_DEATH(malloc_usable_size((void*)0x123), kMallocUsableSizeErrorMsg); EXPECT_DEATH(malloc_usable_size(array + kArraySize / 2), kMallocUsableSizeErrorMsg); free(array); EXPECT_DEATH(malloc_usable_size(array), kMallocUsableSizeErrorMsg); } #endif void WrongFree() { int *x = (int*)malloc(100 * sizeof(int)); // Use the allocated memory, otherwise Clang will optimize it out. Ident(x); free(x + 1); } TEST(AddressSanitizer, WrongFreeTest) { EXPECT_DEATH(WrongFree(), "ERROR: AddressSanitizer attempting free.*not malloc"); } void DoubleFree() { int *x = (int*)malloc(100 * sizeof(int)); fprintf(stderr, "DoubleFree: x=%p\n", x); free(x); free(x); fprintf(stderr, "should have failed in the second free(%p)\n", x); abort(); } TEST(AddressSanitizer, DoubleFreeTest) { EXPECT_DEATH(DoubleFree(), ASAN_PCRE_DOTALL "ERROR: AddressSanitizer attempting double-free" ".*is located 0 bytes inside of 400-byte region" ".*freed by thread T0 here" ".*previously allocated by thread T0 here"); } template<int kSize> NOINLINE void SizedStackTest() { char a[kSize]; char *A = Ident((char*)&a); for (size_t i = 0; i < kSize; i++) A[i] = i; EXPECT_DEATH(A[-1] = 0, ""); EXPECT_DEATH(A[-20] = 0, ""); EXPECT_DEATH(A[-31] = 0, ""); EXPECT_DEATH(A[kSize] = 0, ""); EXPECT_DEATH(A[kSize + 1] = 0, ""); EXPECT_DEATH(A[kSize + 10] = 0, ""); EXPECT_DEATH(A[kSize + 31] = 0, ""); } TEST(AddressSanitizer, SimpleStackTest) { SizedStackTest<1>(); SizedStackTest<2>(); SizedStackTest<3>(); SizedStackTest<4>(); SizedStackTest<5>(); SizedStackTest<6>(); SizedStackTest<7>(); SizedStackTest<16>(); SizedStackTest<25>(); SizedStackTest<34>(); SizedStackTest<43>(); SizedStackTest<51>(); SizedStackTest<62>(); SizedStackTest<64>(); SizedStackTest<128>(); } TEST(AddressSanitizer, ManyStackObjectsTest) { char XXX[10]; char YYY[20]; char ZZZ[30]; Ident(XXX); Ident(YYY); EXPECT_DEATH(Ident(ZZZ)[-1] = 0, ASAN_PCRE_DOTALL "XXX.*YYY.*ZZZ"); } NOINLINE static void Frame0(int frame, char *a, char *b, char *c) { char d[4] = {0}; char *D = Ident(d); switch (frame) { case 3: a[5]++; break; case 2: b[5]++; break; case 1: c[5]++; break; case 0: D[5]++; break; } } NOINLINE static void Frame1(int frame, char *a, char *b) { char c[4] = {0}; Frame0(frame, a, b, c); break_optimization(0); } NOINLINE static void Frame2(int frame, char *a) { char b[4] = {0}; Frame1(frame, a, b); break_optimization(0); } NOINLINE static void Frame3(int frame) { char a[4] = {0}; Frame2(frame, a); break_optimization(0); } TEST(AddressSanitizer, GuiltyStackFrame0Test) { EXPECT_DEATH(Frame3(0), "located .*in frame <.*Frame0"); } TEST(AddressSanitizer, GuiltyStackFrame1Test) { EXPECT_DEATH(Frame3(1), "located .*in frame <.*Frame1"); } TEST(AddressSanitizer, GuiltyStackFrame2Test) { EXPECT_DEATH(Frame3(2), "located .*in frame <.*Frame2"); } TEST(AddressSanitizer, GuiltyStackFrame3Test) { EXPECT_DEATH(Frame3(3), "located .*in frame <.*Frame3"); } NOINLINE void LongJmpFunc1(jmp_buf buf) { // create three red zones for these two stack objects. int a; int b; int *A = Ident(&a); int *B = Ident(&b); *A = *B; longjmp(buf, 1); } NOINLINE void UnderscopeLongJmpFunc1(jmp_buf buf) { // create three red zones for these two stack objects. int a; int b; int *A = Ident(&a); int *B = Ident(&b); *A = *B; _longjmp(buf, 1); } NOINLINE void SigLongJmpFunc1(sigjmp_buf buf) { // create three red zones for these two stack objects. int a; int b; int *A = Ident(&a); int *B = Ident(&b); *A = *B; siglongjmp(buf, 1); } NOINLINE void TouchStackFunc() { int a[100]; // long array will intersect with redzones from LongJmpFunc1. int *A = Ident(a); for (int i = 0; i < 100; i++) A[i] = i*i; } // Test that we handle longjmp and do not report fals positives on stack. TEST(AddressSanitizer, LongJmpTest) { static jmp_buf buf; if (!setjmp(buf)) { LongJmpFunc1(buf); } else { TouchStackFunc(); } } TEST(AddressSanitizer, UnderscopeLongJmpTest) { static jmp_buf buf; if (!_setjmp(buf)) { UnderscopeLongJmpFunc1(buf); } else { TouchStackFunc(); } } TEST(AddressSanitizer, SigLongJmpTest) { static sigjmp_buf buf; if (!sigsetjmp(buf, 1)) { SigLongJmpFunc1(buf); } else { TouchStackFunc(); } } #ifdef __EXCEPTIONS NOINLINE void ThrowFunc() { // create three red zones for these two stack objects. int a; int b; int *A = Ident(&a); int *B = Ident(&b); *A = *B; ASAN_THROW(1); } TEST(AddressSanitizer, CxxExceptionTest) { if (ASAN_UAR) return; // TODO(kcc): this test crashes on 32-bit for some reason... if (__WORDSIZE == 32) return; try { ThrowFunc(); } catch(...) {} TouchStackFunc(); } #endif void *ThreadStackReuseFunc1(void *unused) { // create three red zones for these two stack objects. int a; int b; int *A = Ident(&a); int *B = Ident(&b); *A = *B; pthread_exit(0); return 0; } void *ThreadStackReuseFunc2(void *unused) { TouchStackFunc(); return 0; } TEST(AddressSanitizer, ThreadStackReuseTest) { pthread_t t; pthread_create(&t, 0, ThreadStackReuseFunc1, 0); pthread_join(t, 0); pthread_create(&t, 0, ThreadStackReuseFunc2, 0); pthread_join(t, 0); } #if defined(__i386__) || defined(__x86_64__) TEST(AddressSanitizer, Store128Test) { char *a = Ident((char*)malloc(Ident(12))); char *p = a; if (((uintptr_t)a % 16) != 0) p = a + 8; assert(((uintptr_t)p % 16) == 0); __m128i value_wide = _mm_set1_epi16(0x1234); EXPECT_DEATH(_mm_store_si128((__m128i*)p, value_wide), "AddressSanitizer heap-buffer-overflow"); EXPECT_DEATH(_mm_store_si128((__m128i*)p, value_wide), "WRITE of size 16"); EXPECT_DEATH(_mm_store_si128((__m128i*)p, value_wide), "located 0 bytes to the right of 12-byte"); free(a); } #endif static string RightOOBErrorMessage(int oob_distance) { assert(oob_distance >= 0); char expected_str[100]; sprintf(expected_str, "located %d bytes to the right", oob_distance); return string(expected_str); } static string LeftOOBErrorMessage(int oob_distance) { assert(oob_distance > 0); char expected_str[100]; sprintf(expected_str, "located %d bytes to the left", oob_distance); return string(expected_str); } template<typename T> void MemSetOOBTestTemplate(size_t length) { if (length == 0) return; size_t size = Ident(sizeof(T) * length); T *array = Ident((T*)malloc(size)); int element = Ident(42); int zero = Ident(0); // memset interval inside array memset(array, element, size); memset(array, element, size - 1); memset(array + length - 1, element, sizeof(T)); memset(array, element, 1); // memset 0 bytes memset(array - 10, element, zero); memset(array - 1, element, zero); memset(array, element, zero); memset(array + length, 0, zero); memset(array + length + 1, 0, zero); // try to memset bytes to the right of array EXPECT_DEATH(memset(array, 0, size + 1), RightOOBErrorMessage(0)); EXPECT_DEATH(memset((char*)(array + length) - 1, element, 6), RightOOBErrorMessage(4)); EXPECT_DEATH(memset(array + 1, element, size + sizeof(T)), RightOOBErrorMessage(2 * sizeof(T) - 1)); // whole interval is to the right EXPECT_DEATH(memset(array + length + 1, 0, 10), RightOOBErrorMessage(sizeof(T))); // try to memset bytes to the left of array EXPECT_DEATH(memset((char*)array - 1, element, size), LeftOOBErrorMessage(1)); EXPECT_DEATH(memset((char*)array - 5, 0, 6), LeftOOBErrorMessage(5)); EXPECT_DEATH(memset(array - 5, element, size + 5 * sizeof(T)), LeftOOBErrorMessage(5 * sizeof(T))); // whole interval is to the left EXPECT_DEATH(memset(array - 2, 0, sizeof(T)), LeftOOBErrorMessage(2 * sizeof(T))); // try to memset bytes both to the left & to the right EXPECT_DEATH(memset((char*)array - 2, element, size + 4), LeftOOBErrorMessage(2)); free(array); } TEST(AddressSanitizer, MemSetOOBTest) { MemSetOOBTestTemplate<char>(100); MemSetOOBTestTemplate<int>(5); MemSetOOBTestTemplate<double>(256); // We can test arrays of structres/classes here, but what for? } // Same test for memcpy and memmove functions template <typename T, class M> void MemTransferOOBTestTemplate(size_t length) { if (length == 0) return; size_t size = Ident(sizeof(T) * length); T *src = Ident((T*)malloc(size)); T *dest = Ident((T*)malloc(size)); int zero = Ident(0); // valid transfer of bytes between arrays M::transfer(dest, src, size); M::transfer(dest + 1, src, size - sizeof(T)); M::transfer(dest, src + length - 1, sizeof(T)); M::transfer(dest, src, 1); // transfer zero bytes M::transfer(dest - 1, src, 0); M::transfer(dest + length, src, zero); M::transfer(dest, src - 1, zero); M::transfer(dest, src, zero); // try to change mem to the right of dest EXPECT_DEATH(M::transfer(dest + 1, src, size), RightOOBErrorMessage(sizeof(T) - 1)); EXPECT_DEATH(M::transfer((char*)(dest + length) - 1, src, 5), RightOOBErrorMessage(3)); // try to change mem to the left of dest EXPECT_DEATH(M::transfer(dest - 2, src, size), LeftOOBErrorMessage(2 * sizeof(T))); EXPECT_DEATH(M::transfer((char*)dest - 3, src, 4), LeftOOBErrorMessage(3)); // try to access mem to the right of src EXPECT_DEATH(M::transfer(dest, src + 2, size), RightOOBErrorMessage(2 * sizeof(T) - 1)); EXPECT_DEATH(M::transfer(dest, (char*)(src + length) - 3, 6), RightOOBErrorMessage(2)); // try to access mem to the left of src EXPECT_DEATH(M::transfer(dest, src - 1, size), LeftOOBErrorMessage(sizeof(T))); EXPECT_DEATH(M::transfer(dest, (char*)src - 6, 7), LeftOOBErrorMessage(6)); // Generally we don't need to test cases where both accessing src and writing // to dest address to poisoned memory. T *big_src = Ident((T*)malloc(size * 2)); T *big_dest = Ident((T*)malloc(size * 2)); // try to change mem to both sides of dest EXPECT_DEATH(M::transfer(dest - 1, big_src, size * 2), LeftOOBErrorMessage(sizeof(T))); // try to access mem to both sides of src EXPECT_DEATH(M::transfer(big_dest, src - 2, size * 2), LeftOOBErrorMessage(2 * sizeof(T))); free(src); free(dest); free(big_src); free(big_dest); } class MemCpyWrapper { public: static void* transfer(void *to, const void *from, size_t size) { return memcpy(to, from, size); } }; TEST(AddressSanitizer, MemCpyOOBTest) { MemTransferOOBTestTemplate<char, MemCpyWrapper>(100); MemTransferOOBTestTemplate<int, MemCpyWrapper>(1024); } class MemMoveWrapper { public: static void* transfer(void *to, const void *from, size_t size) { return memmove(to, from, size); } }; TEST(AddressSanitizer, MemMoveOOBTest) { MemTransferOOBTestTemplate<char, MemMoveWrapper>(100); MemTransferOOBTestTemplate<int, MemMoveWrapper>(1024); } // Tests for string functions // Used for string functions tests static char global_string[] = "global"; static size_t global_string_length = 6; // Input to a test is a zero-terminated string str with given length // Accesses to the bytes to the left and to the right of str // are presumed to produce OOB errors void StrLenOOBTestTemplate(char *str, size_t length, bool is_global) { // Normal strlen calls EXPECT_EQ(strlen(str), length); if (length > 0) { EXPECT_EQ(strlen(str + 1), length - 1); EXPECT_EQ(strlen(str + length), 0); } // Arg of strlen is not malloced, OOB access if (!is_global) { // We don't insert RedZones to the left of global variables EXPECT_DEATH(Ident(strlen(str - 1)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strlen(str - 5)), LeftOOBErrorMessage(5)); } EXPECT_DEATH(Ident(strlen(str + length + 1)), RightOOBErrorMessage(0)); // Overwrite terminator str[length] = 'a'; // String is not zero-terminated, strlen will lead to OOB access EXPECT_DEATH(Ident(strlen(str)), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(strlen(str + length)), RightOOBErrorMessage(0)); // Restore terminator str[length] = 0; } TEST(AddressSanitizer, StrLenOOBTest) { // Check heap-allocated string size_t length = Ident(10); char *heap_string = Ident((char*)malloc(length + 1)); char stack_string[10 + 1]; for (int i = 0; i < length; i++) { heap_string[i] = 'a'; stack_string[i] = 'b'; } heap_string[length] = 0; stack_string[length] = 0; StrLenOOBTestTemplate(heap_string, length, false); // TODO(samsonov): Fix expected messages in StrLenOOBTestTemplate to // make test for stack_string work. Or move it to output tests. // StrLenOOBTestTemplate(stack_string, length, false); StrLenOOBTestTemplate(global_string, global_string_length, true); free(heap_string); } static inline char* MallocAndMemsetString(size_t size, char ch) { char *s = Ident((char*)malloc(size)); memset(s, ch, size); return s; } static inline char* MallocAndMemsetString(size_t size) { return MallocAndMemsetString(size, 'z'); } #ifndef __APPLE__ TEST(AddressSanitizer, StrNLenOOBTest) { size_t size = Ident(123); char *str = MallocAndMemsetString(size); // Normal strnlen calls. Ident(strnlen(str - 1, 0)); Ident(strnlen(str, size)); Ident(strnlen(str + size - 1, 1)); str[size - 1] = '\0'; Ident(strnlen(str, 2 * size)); // Argument points to not allocated memory. EXPECT_DEATH(Ident(strnlen(str - 1, 1)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strnlen(str + size, 1)), RightOOBErrorMessage(0)); // Overwrite the terminating '\0' and hit unallocated memory. str[size - 1] = 'z'; EXPECT_DEATH(Ident(strnlen(str, size + 1)), RightOOBErrorMessage(0)); free(str); } #endif TEST(AddressSanitizer, StrDupOOBTest) { size_t size = Ident(42); char *str = MallocAndMemsetString(size); char *new_str; // Normal strdup calls. str[size - 1] = '\0'; new_str = strdup(str); free(new_str); new_str = strdup(str + size - 1); free(new_str); // Argument points to not allocated memory. EXPECT_DEATH(Ident(strdup(str - 1)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strdup(str + size)), RightOOBErrorMessage(0)); // Overwrite the terminating '\0' and hit unallocated memory. str[size - 1] = 'z'; EXPECT_DEATH(Ident(strdup(str)), RightOOBErrorMessage(0)); free(str); } TEST(AddressSanitizer, StrCpyOOBTest) { size_t to_size = Ident(30); size_t from_size = Ident(6); // less than to_size char *to = Ident((char*)malloc(to_size)); char *from = Ident((char*)malloc(from_size)); // Normal strcpy calls. strcpy(from, "hello"); strcpy(to, from); strcpy(to + to_size - from_size, from); // Length of "from" is too small. EXPECT_DEATH(Ident(strcpy(from, "hello2")), RightOOBErrorMessage(0)); // "to" or "from" points to not allocated memory. EXPECT_DEATH(Ident(strcpy(to - 1, from)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strcpy(to, from - 1)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strcpy(to, from + from_size)), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(strcpy(to + to_size, from)), RightOOBErrorMessage(0)); // Overwrite the terminating '\0' character and hit unallocated memory. from[from_size - 1] = '!'; EXPECT_DEATH(Ident(strcpy(to, from)), RightOOBErrorMessage(0)); free(to); free(from); } TEST(AddressSanitizer, StrNCpyOOBTest) { size_t to_size = Ident(20); size_t from_size = Ident(6); // less than to_size char *to = Ident((char*)malloc(to_size)); // From is a zero-terminated string "hello\0" of length 6 char *from = Ident((char*)malloc(from_size)); strcpy(from, "hello"); // copy 0 bytes strncpy(to, from, 0); strncpy(to - 1, from - 1, 0); // normal strncpy calls strncpy(to, from, from_size); strncpy(to, from, to_size); strncpy(to, from + from_size - 1, to_size); strncpy(to + to_size - 1, from, 1); // One of {to, from} points to not allocated memory EXPECT_DEATH(Ident(strncpy(to, from - 1, from_size)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strncpy(to - 1, from, from_size)), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(strncpy(to, from + from_size, 1)), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(strncpy(to + to_size, from, 1)), RightOOBErrorMessage(0)); // Length of "to" is too small EXPECT_DEATH(Ident(strncpy(to + to_size - from_size + 1, from, from_size)), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(strncpy(to + 1, from, to_size)), RightOOBErrorMessage(0)); // Overwrite terminator in from from[from_size - 1] = '!'; // normal strncpy call strncpy(to, from, from_size); // Length of "from" is too small EXPECT_DEATH(Ident(strncpy(to, from, to_size)), RightOOBErrorMessage(0)); free(to); free(from); } typedef char*(*PointerToStrChr)(const char*, int); void RunStrChrTest(PointerToStrChr StrChr) { size_t size = Ident(100); char *str = MallocAndMemsetString(size); str[10] = 'q'; str[11] = '\0'; EXPECT_EQ(str, StrChr(str, 'z')); EXPECT_EQ(str + 10, StrChr(str, 'q')); EXPECT_EQ(NULL, StrChr(str, 'a')); // StrChr argument points to not allocated memory. EXPECT_DEATH(Ident(StrChr(str - 1, 'z')), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(StrChr(str + size, 'z')), RightOOBErrorMessage(0)); // Overwrite the terminator and hit not allocated memory. str[11] = 'z'; EXPECT_DEATH(Ident(StrChr(str, 'a')), RightOOBErrorMessage(0)); free(str); } TEST(AddressSanitizer, StrChrAndIndexOOBTest) { RunStrChrTest(&strchr); RunStrChrTest(&index); } TEST(AddressSanitizer, StrCmpAndFriendsLogicTest) { // strcmp EXPECT_EQ(0, strcmp("", "")); EXPECT_EQ(0, strcmp("abcd", "abcd")); EXPECT_GT(0, strcmp("ab", "ac")); EXPECT_GT(0, strcmp("abc", "abcd")); EXPECT_LT(0, strcmp("acc", "abc")); EXPECT_LT(0, strcmp("abcd", "abc")); // strncmp EXPECT_EQ(0, strncmp("a", "b", 0)); EXPECT_EQ(0, strncmp("abcd", "abcd", 10)); EXPECT_EQ(0, strncmp("abcd", "abcef", 3)); EXPECT_GT(0, strncmp("abcde", "abcfa", 4)); EXPECT_GT(0, strncmp("a", "b", 5)); EXPECT_GT(0, strncmp("bc", "bcde", 4)); EXPECT_LT(0, strncmp("xyz", "xyy", 10)); EXPECT_LT(0, strncmp("baa", "aaa", 1)); EXPECT_LT(0, strncmp("zyx", "", 2)); // strcasecmp EXPECT_EQ(0, strcasecmp("", "")); EXPECT_EQ(0, strcasecmp("zzz", "zzz")); EXPECT_EQ(0, strcasecmp("abCD", "ABcd")); EXPECT_GT(0, strcasecmp("aB", "Ac")); EXPECT_GT(0, strcasecmp("ABC", "ABCd")); EXPECT_LT(0, strcasecmp("acc", "abc")); EXPECT_LT(0, strcasecmp("ABCd", "abc")); // strncasecmp EXPECT_EQ(0, strncasecmp("a", "b", 0)); EXPECT_EQ(0, strncasecmp("abCD", "ABcd", 10)); EXPECT_EQ(0, strncasecmp("abCd", "ABcef", 3)); EXPECT_GT(0, strncasecmp("abcde", "ABCfa", 4)); EXPECT_GT(0, strncasecmp("a", "B", 5)); EXPECT_GT(0, strncasecmp("bc", "BCde", 4)); EXPECT_LT(0, strncasecmp("xyz", "xyy", 10)); EXPECT_LT(0, strncasecmp("Baa", "aaa", 1)); EXPECT_LT(0, strncasecmp("zyx", "", 2)); // memcmp EXPECT_EQ(0, memcmp("a", "b", 0)); EXPECT_EQ(0, memcmp("ab\0c", "ab\0c", 4)); EXPECT_GT(0, memcmp("\0ab", "\0ac", 3)); EXPECT_GT(0, memcmp("abb\0", "abba", 4)); EXPECT_LT(0, memcmp("ab\0cd", "ab\0c\0", 5)); EXPECT_LT(0, memcmp("zza", "zyx", 3)); } typedef int(*PointerToStrCmp)(const char*, const char*); void RunStrCmpTest(PointerToStrCmp StrCmp) { size_t size = Ident(100); char *s1 = MallocAndMemsetString(size); char *s2 = MallocAndMemsetString(size); s1[size - 1] = '\0'; s2[size - 1] = '\0'; // Normal StrCmp calls Ident(StrCmp(s1, s2)); Ident(StrCmp(s1, s2 + size - 1)); Ident(StrCmp(s1 + size - 1, s2 + size - 1)); s1[size - 1] = 'z'; s2[size - 1] = 'x'; Ident(StrCmp(s1, s2)); // One of arguments points to not allocated memory. EXPECT_DEATH(Ident(StrCmp)(s1 - 1, s2), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(StrCmp)(s1, s2 - 1), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(StrCmp)(s1 + size, s2), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(StrCmp)(s1, s2 + size), RightOOBErrorMessage(0)); // Hit unallocated memory and die. s2[size - 1] = 'z'; EXPECT_DEATH(Ident(StrCmp)(s1, s1), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(StrCmp)(s1 + size - 1, s2), RightOOBErrorMessage(0)); free(s1); free(s2); } TEST(AddressSanitizer, StrCmpOOBTest) { RunStrCmpTest(&strcmp); } TEST(AddressSanitizer, StrCaseCmpOOBTest) { RunStrCmpTest(&strcasecmp); } typedef int(*PointerToStrNCmp)(const char*, const char*, size_t); void RunStrNCmpTest(PointerToStrNCmp StrNCmp) { size_t size = Ident(100); char *s1 = MallocAndMemsetString(size); char *s2 = MallocAndMemsetString(size); s1[size - 1] = '\0'; s2[size - 1] = '\0'; // Normal StrNCmp calls Ident(StrNCmp(s1, s2, size + 2)); s1[size - 1] = 'z'; s2[size - 1] = 'x'; Ident(StrNCmp(s1 + size - 2, s2 + size - 2, size)); s2[size - 1] = 'z'; Ident(StrNCmp(s1 - 1, s2 - 1, 0)); Ident(StrNCmp(s1 + size - 1, s2 + size - 1, 1)); // One of arguments points to not allocated memory. EXPECT_DEATH(Ident(StrNCmp)(s1 - 1, s2, 1), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(StrNCmp)(s1, s2 - 1, 1), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(StrNCmp)(s1 + size, s2, 1), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(StrNCmp)(s1, s2 + size, 1), RightOOBErrorMessage(0)); // Hit unallocated memory and die. EXPECT_DEATH(Ident(StrNCmp)(s1 + 1, s2 + 1, size), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(StrNCmp)(s1 + size - 1, s2, 2), RightOOBErrorMessage(0)); free(s1); free(s2); } TEST(AddressSanitizer, StrNCmpOOBTest) { RunStrNCmpTest(&strncmp); } TEST(AddressSanitizer, StrNCaseCmpOOBTest) { RunStrNCmpTest(&strncasecmp); } TEST(AddressSanitizer, MemCmpOOBTest) { size_t size = Ident(100); char *s1 = MallocAndMemsetString(size); char *s2 = MallocAndMemsetString(size); // Normal memcmp calls. Ident(memcmp(s1, s2, size)); Ident(memcmp(s1 + size - 1, s2 + size - 1, 1)); Ident(memcmp(s1 - 1, s2 - 1, 0)); // One of arguments points to not allocated memory. EXPECT_DEATH(Ident(memcmp)(s1 - 1, s2, 1), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(memcmp)(s1, s2 - 1, 1), LeftOOBErrorMessage(1)); EXPECT_DEATH(Ident(memcmp)(s1 + size, s2, 1), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(memcmp)(s1, s2 + size, 1), RightOOBErrorMessage(0)); // Hit unallocated memory and die. EXPECT_DEATH(Ident(memcmp)(s1 + 1, s2 + 1, size), RightOOBErrorMessage(0)); EXPECT_DEATH(Ident(memcmp)(s1 + size - 1, s2, 2), RightOOBErrorMessage(0)); // Zero bytes are not terminators and don't prevent from OOB. s1[size - 1] = '\0'; s2[size - 1] = '\0'; EXPECT_DEATH(Ident(memcmp)(s1, s2, size + 1), RightOOBErrorMessage(0)); free(s1); free(s2); } TEST(AddressSanitizer, StrCatOOBTest) { size_t to_size = Ident(100); char *to = MallocAndMemsetString(to_size); to[0] = '\0'; size_t from_size = Ident(20); char *from = MallocAndMemsetString(from_size); from[from_size - 1] = '\0'; // Normal strcat calls. strcat(to, from); strcat(to, from); strcat(to + from_size, from + from_size - 2); // Passing an invalid pointer is an error even when concatenating an empty // string. EXPECT_DEATH(strcat(to - 1, from + from_size - 1), LeftOOBErrorMessage(1)); // One of arguments points to not allocated memory. EXPECT_DEATH(strcat(to - 1, from), LeftOOBErrorMessage(1)); EXPECT_DEATH(strcat(to, from - 1), LeftOOBErrorMessage(1)); EXPECT_DEATH(strcat(to + to_size, from), RightOOBErrorMessage(0)); EXPECT_DEATH(strcat(to, from + from_size), RightOOBErrorMessage(0)); // "from" is not zero-terminated. from[from_size - 1] = 'z'; EXPECT_DEATH(strcat(to, from), RightOOBErrorMessage(0)); from[from_size - 1] = '\0'; // "to" is not zero-terminated. memset(to, 'z', to_size); EXPECT_DEATH(strcat(to, from), RightOOBErrorMessage(0)); // "to" is too short to fit "from". to[to_size - from_size + 1] = '\0'; EXPECT_DEATH(strcat(to, from), RightOOBErrorMessage(0)); // length of "to" is just enough. strcat(to, from + 1); free(to); free(from); } TEST(AddressSanitizer, StrNCatOOBTest) { size_t to_size = Ident(100); char *to = MallocAndMemsetString(to_size); to[0] = '\0'; size_t from_size = Ident(20); char *from = MallocAndMemsetString(from_size); // Normal strncat calls. strncat(to, from, 0); strncat(to, from, from_size); from[from_size - 1] = '\0'; strncat(to, from, 2 * from_size); // Catenating empty string with an invalid string is still an error. EXPECT_DEATH(strncat(to - 1, from, 0), LeftOOBErrorMessage(1)); strncat(to, from + from_size - 1, 10); // One of arguments points to not allocated memory. EXPECT_DEATH(strncat(to - 1, from, 2), LeftOOBErrorMessage(1)); EXPECT_DEATH(strncat(to, from - 1, 2), LeftOOBErrorMessage(1)); EXPECT_DEATH(strncat(to + to_size, from, 2), RightOOBErrorMessage(0)); EXPECT_DEATH(strncat(to, from + from_size, 2), RightOOBErrorMessage(0)); memset(from, 'z', from_size); memset(to, 'z', to_size); to[0] = '\0'; // "from" is too short. EXPECT_DEATH(strncat(to, from, from_size + 1), RightOOBErrorMessage(0)); // "to" is not zero-terminated. EXPECT_DEATH(strncat(to + 1, from, 1), RightOOBErrorMessage(0)); // "to" is too short to fit "from". to[0] = 'z'; to[to_size - from_size + 1] = '\0'; EXPECT_DEATH(strncat(to, from, from_size - 1), RightOOBErrorMessage(0)); // "to" is just enough. strncat(to, from, from_size - 2); free(to); free(from); } static string OverlapErrorMessage(const string &func) { return func + "-param-overlap"; } TEST(AddressSanitizer, StrArgsOverlapTest) { size_t size = Ident(100); char *str = Ident((char*)malloc(size)); // Do not check memcpy() on OS X 10.7 and later, where it actually aliases // memmove(). #if !defined(__APPLE__) || !defined(MAC_OS_X_VERSION_10_7) || \ (MAC_OS_X_VERSION_MAX_ALLOWED < MAC_OS_X_VERSION_10_7) // Check "memcpy". Use Ident() to avoid inlining. memset(str, 'z', size); Ident(memcpy)(str + 1, str + 11, 10); Ident(memcpy)(str, str, 0); EXPECT_DEATH(Ident(memcpy)(str, str + 14, 15), OverlapErrorMessage("memcpy")); EXPECT_DEATH(Ident(memcpy)(str + 14, str, 15), OverlapErrorMessage("memcpy")); #endif // We do not treat memcpy with to==from as a bug. // See http://llvm.org/bugs/show_bug.cgi?id=11763. // EXPECT_DEATH(Ident(memcpy)(str + 20, str + 20, 1), // OverlapErrorMessage("memcpy")); // Check "strcpy". memset(str, 'z', size); str[9] = '\0'; strcpy(str + 10, str); EXPECT_DEATH(strcpy(str + 9, str), OverlapErrorMessage("strcpy")); EXPECT_DEATH(strcpy(str, str + 4), OverlapErrorMessage("strcpy")); strcpy(str, str + 5); // Check "strncpy". memset(str, 'z', size); strncpy(str, str + 10, 10); EXPECT_DEATH(strncpy(str, str + 9, 10), OverlapErrorMessage("strncpy")); EXPECT_DEATH(strncpy(str + 9, str, 10), OverlapErrorMessage("strncpy")); str[10] = '\0'; strncpy(str + 11, str, 20); EXPECT_DEATH(strncpy(str + 10, str, 20), OverlapErrorMessage("strncpy")); // Check "strcat". memset(str, 'z', size); str[10] = '\0'; str[20] = '\0'; strcat(str, str + 10); EXPECT_DEATH(strcat(str, str + 11), OverlapErrorMessage("strcat")); str[10] = '\0'; strcat(str + 11, str); EXPECT_DEATH(strcat(str, str + 9), OverlapErrorMessage("strcat")); EXPECT_DEATH(strcat(str + 9, str), OverlapErrorMessage("strcat")); EXPECT_DEATH(strcat(str + 10, str), OverlapErrorMessage("strcat")); // Check "strncat". memset(str, 'z', size); str[10] = '\0'; strncat(str, str + 10, 10); // from is empty EXPECT_DEATH(strncat(str, str + 11, 10), OverlapErrorMessage("strncat")); str[10] = '\0'; str[20] = '\0'; strncat(str + 5, str, 5); str[10] = '\0'; EXPECT_DEATH(strncat(str + 5, str, 6), OverlapErrorMessage("strncat")); EXPECT_DEATH(strncat(str, str + 9, 10), OverlapErrorMessage("strncat")); free(str); } void CallAtoi(const char *nptr) { Ident(atoi(nptr)); } void CallAtol(const char *nptr) { Ident(atol(nptr)); } void CallAtoll(const char *nptr) { Ident(atoll(nptr)); } typedef void(*PointerToCallAtoi)(const char*); void RunAtoiOOBTest(PointerToCallAtoi Atoi) { char *array = MallocAndMemsetString(10, '1'); // Invalid pointer to the string. EXPECT_DEATH(Atoi(array + 11), RightOOBErrorMessage(1)); EXPECT_DEATH(Atoi(array - 1), LeftOOBErrorMessage(1)); // Die if a buffer doesn't have terminating NULL. EXPECT_DEATH(Atoi(array), RightOOBErrorMessage(0)); // Make last symbol a terminating NULL or other non-digit. array[9] = '\0'; Atoi(array); array[9] = 'a'; Atoi(array); Atoi(array + 9); // Sometimes we need to detect overflow if no digits are found. memset(array, ' ', 10); EXPECT_DEATH(Atoi(array), RightOOBErrorMessage(0)); array[9] = '-'; EXPECT_DEATH(Atoi(array), RightOOBErrorMessage(0)); EXPECT_DEATH(Atoi(array + 9), RightOOBErrorMessage(0)); array[8] = '-'; Atoi(array); delete array; } TEST(AddressSanitizer, AtoiAndFriendsOOBTest) { RunAtoiOOBTest(&CallAtoi); RunAtoiOOBTest(&CallAtol); RunAtoiOOBTest(&CallAtoll); } void CallStrtol(const char *nptr, char **endptr, int base) { Ident(strtol(nptr, endptr, base)); } void CallStrtoll(const char *nptr, char **endptr, int base) { Ident(strtoll(nptr, endptr, base)); } typedef void(*PointerToCallStrtol)(const char*, char**, int); void RunStrtolOOBTest(PointerToCallStrtol Strtol) { char *array = MallocAndMemsetString(3); char *endptr = NULL; array[0] = '1'; array[1] = '2'; array[2] = '3'; // Invalid pointer to the string. EXPECT_DEATH(Strtol(array + 3, NULL, 0), RightOOBErrorMessage(0)); EXPECT_DEATH(Strtol(array - 1, NULL, 0), LeftOOBErrorMessage(1)); // Buffer overflow if there is no terminating null (depends on base). Strtol(array, &endptr, 3); EXPECT_EQ(array + 2, endptr); EXPECT_DEATH(Strtol(array, NULL, 0), RightOOBErrorMessage(0)); array[2] = 'z'; Strtol(array, &endptr, 35); EXPECT_EQ(array + 2, endptr); EXPECT_DEATH(Strtol(array, NULL, 36), RightOOBErrorMessage(0)); // Add terminating zero to get rid of overflow. array[2] = '\0'; Strtol(array, NULL, 36); // Don't check for overflow if base is invalid. Strtol(array - 1, NULL, -1); Strtol(array + 3, NULL, 1); // Sometimes we need to detect overflow if no digits are found. array[0] = array[1] = array[2] = ' '; EXPECT_DEATH(Strtol(array, NULL, 0), RightOOBErrorMessage(0)); array[2] = '+'; EXPECT_DEATH(Strtol(array, NULL, 0), RightOOBErrorMessage(0)); array[2] = '-'; EXPECT_DEATH(Strtol(array, NULL, 0), RightOOBErrorMessage(0)); array[1] = '+'; Strtol(array, NULL, 0); array[1] = array[2] = 'z'; Strtol(array, &endptr, 0); EXPECT_EQ(array, endptr); Strtol(array + 2, NULL, 0); EXPECT_EQ(array, endptr); delete array; } TEST(AddressSanitizer, StrtollOOBTest) { RunStrtolOOBTest(&CallStrtoll); } TEST(AddressSanitizer, StrtolOOBTest) { RunStrtolOOBTest(&CallStrtol); } // At the moment we instrument memcpy/memove/memset calls at compile time so we // can't handle OOB error if these functions are called by pointer, see disabled // MemIntrinsicCallByPointerTest below typedef void*(*PointerToMemTransfer)(void*, const void*, size_t); typedef void*(*PointerToMemSet)(void*, int, size_t); void CallMemSetByPointer(PointerToMemSet MemSet) { size_t size = Ident(100); char *array = Ident((char*)malloc(size)); EXPECT_DEATH(MemSet(array, 0, 101), RightOOBErrorMessage(0)); free(array); } void CallMemTransferByPointer(PointerToMemTransfer MemTransfer) { size_t size = Ident(100); char *src = Ident((char*)malloc(size)); char *dst = Ident((char*)malloc(size)); EXPECT_DEATH(MemTransfer(dst, src, 101), RightOOBErrorMessage(0)); free(src); free(dst); } TEST(AddressSanitizer, DISABLED_MemIntrinsicCallByPointerTest) { CallMemSetByPointer(&memset); CallMemTransferByPointer(&memcpy); CallMemTransferByPointer(&memmove); } // This test case fails // Clang optimizes memcpy/memset calls which lead to unaligned access TEST(AddressSanitizer, DISABLED_MemIntrinsicUnalignedAccessTest) { int size = Ident(4096); char *s = Ident((char*)malloc(size)); EXPECT_DEATH(memset(s + size - 1, 0, 2), RightOOBErrorMessage(0)); free(s); } // TODO(samsonov): Add a test with malloc(0) // TODO(samsonov): Add tests for str* and mem* functions. NOINLINE static int LargeFunction(bool do_bad_access) { int *x = new int[100]; x[0]++; x[1]++; x[2]++; x[3]++; x[4]++; x[5]++; x[6]++; x[7]++; x[8]++; x[9]++; x[do_bad_access ? 100 : 0]++; int res = __LINE__; x[10]++; x[11]++; x[12]++; x[13]++; x[14]++; x[15]++; x[16]++; x[17]++; x[18]++; x[19]++; delete x; return res; } // Test the we have correct debug info for the failing instruction. // This test requires the in-process symbolizer to be enabled by default. TEST(AddressSanitizer, DISABLED_LargeFunctionSymbolizeTest) { int failing_line = LargeFunction(false); char expected_warning[128]; sprintf(expected_warning, "LargeFunction.*asan_test.cc:%d", failing_line); EXPECT_DEATH(LargeFunction(true), expected_warning); } // Check that we unwind and symbolize correctly. TEST(AddressSanitizer, DISABLED_MallocFreeUnwindAndSymbolizeTest) { int *a = (int*)malloc_aaa(sizeof(int)); *a = 1; free_aaa(a); EXPECT_DEATH(*a = 1, "free_ccc.*free_bbb.*free_aaa.*" "malloc_fff.*malloc_eee.*malloc_ddd"); } void *ThreadedTestAlloc(void *a) { int **p = (int**)a; *p = new int; return 0; } void *ThreadedTestFree(void *a) { int **p = (int**)a; delete *p; return 0; } void *ThreadedTestUse(void *a) { int **p = (int**)a; **p = 1; return 0; } void ThreadedTestSpawn() { pthread_t t; int *x; pthread_create(&t, 0, ThreadedTestAlloc, &x); pthread_join(t, 0); pthread_create(&t, 0, ThreadedTestFree, &x); pthread_join(t, 0); pthread_create(&t, 0, ThreadedTestUse, &x); pthread_join(t, 0); } TEST(AddressSanitizer, ThreadedTest) { EXPECT_DEATH(ThreadedTestSpawn(), ASAN_PCRE_DOTALL "Thread T.*created" ".*Thread T.*created" ".*Thread T.*created"); } #if ASAN_NEEDS_SEGV TEST(AddressSanitizer, ShadowGapTest) { #if __WORDSIZE == 32 char *addr = (char*)0x22000000; #else char *addr = (char*)0x0000100000080000; #endif EXPECT_DEATH(*addr = 1, "AddressSanitizer crashed on unknown"); } #endif // ASAN_NEEDS_SEGV extern "C" { NOINLINE static void UseThenFreeThenUse() { char *x = Ident((char*)malloc(8)); *x = 1; free_aaa(x); *x = 2; } } TEST(AddressSanitizer, UseThenFreeThenUseTest) { EXPECT_DEATH(UseThenFreeThenUse(), "freed by thread"); } TEST(AddressSanitizer, StrDupTest) { free(strdup(Ident("123"))); } // Currently we create and poison redzone at right of global variables. char glob5[5]; static char static110[110]; const char ConstGlob[7] = {1, 2, 3, 4, 5, 6, 7}; static const char StaticConstGlob[3] = {9, 8, 7}; extern int GlobalsTest(int x); TEST(AddressSanitizer, GlobalTest) { static char func_static15[15]; static char fs1[10]; static char fs2[10]; static char fs3[10]; glob5[Ident(0)] = 0; glob5[Ident(1)] = 0; glob5[Ident(2)] = 0; glob5[Ident(3)] = 0; glob5[Ident(4)] = 0; EXPECT_DEATH(glob5[Ident(5)] = 0, "0 bytes to the right of global variable.*glob5.* size 5"); EXPECT_DEATH(glob5[Ident(5+6)] = 0, "6 bytes to the right of global variable.*glob5.* size 5"); Ident(static110); // avoid optimizations static110[Ident(0)] = 0; static110[Ident(109)] = 0; EXPECT_DEATH(static110[Ident(110)] = 0, "0 bytes to the right of global variable"); EXPECT_DEATH(static110[Ident(110+7)] = 0, "7 bytes to the right of global variable"); Ident(func_static15); // avoid optimizations func_static15[Ident(0)] = 0; EXPECT_DEATH(func_static15[Ident(15)] = 0, "0 bytes to the right of global variable"); EXPECT_DEATH(func_static15[Ident(15 + 9)] = 0, "9 bytes to the right of global variable"); Ident(fs1); Ident(fs2); Ident(fs3); // We don't create left redzones, so this is not 100% guaranteed to fail. // But most likely will. EXPECT_DEATH(fs2[Ident(-1)] = 0, "is located.*of global variable"); EXPECT_DEATH(Ident(Ident(ConstGlob)[8]), "is located 1 bytes to the right of .*ConstGlob"); EXPECT_DEATH(Ident(Ident(StaticConstGlob)[5]), "is located 2 bytes to the right of .*StaticConstGlob"); // call stuff from another file. GlobalsTest(0); } TEST(AddressSanitizer, GlobalStringConstTest) { static const char *zoo = "FOOBAR123"; const char *p = Ident(zoo); EXPECT_DEATH(Ident(p[15]), "is ascii string 'FOOBAR123'"); } TEST(AddressSanitizer, FileNameInGlobalReportTest) { static char zoo[10]; const char *p = Ident(zoo); // The file name should be present in the report. EXPECT_DEATH(Ident(p[15]), "zoo.*asan_test.cc"); } int *ReturnsPointerToALocalObject() { int a = 0; return Ident(&a); } #if ASAN_UAR == 1 TEST(AddressSanitizer, LocalReferenceReturnTest) { int *(*f)() = Ident(ReturnsPointerToALocalObject); int *p = f(); // Call 'f' a few more times, 'p' should still be poisoned. for (int i = 0; i < 32; i++) f(); EXPECT_DEATH(*p = 1, "AddressSanitizer stack-use-after-return"); EXPECT_DEATH(*p = 1, "is located.*in frame .*ReturnsPointerToALocal"); } #endif template <int kSize> NOINLINE static void FuncWithStack() { char x[kSize]; Ident(x)[0] = 0; Ident(x)[kSize-1] = 0; } static void LotsOfStackReuse() { int LargeStack[10000]; Ident(LargeStack)[0] = 0; for (int i = 0; i < 10000; i++) { FuncWithStack<128 * 1>(); FuncWithStack<128 * 2>(); FuncWithStack<128 * 4>(); FuncWithStack<128 * 8>(); FuncWithStack<128 * 16>(); FuncWithStack<128 * 32>(); FuncWithStack<128 * 64>(); FuncWithStack<128 * 128>(); FuncWithStack<128 * 256>(); FuncWithStack<128 * 512>(); Ident(LargeStack)[0] = 0; } } TEST(AddressSanitizer, StressStackReuseTest) { LotsOfStackReuse(); } TEST(AddressSanitizer, ThreadedStressStackReuseTest) { const int kNumThreads = 20; pthread_t t[kNumThreads]; for (int i = 0; i < kNumThreads; i++) { pthread_create(&t[i], 0, (void* (*)(void *x))LotsOfStackReuse, 0); } for (int i = 0; i < kNumThreads; i++) { pthread_join(t[i], 0); } } static void *PthreadExit(void *a) { pthread_exit(0); return 0; } TEST(AddressSanitizer, PthreadExitTest) { pthread_t t; for (int i = 0; i < 1000; i++) { pthread_create(&t, 0, PthreadExit, 0); pthread_join(t, 0); } } #ifdef __EXCEPTIONS NOINLINE static void StackReuseAndException() { int large_stack[1000]; Ident(large_stack); ASAN_THROW(1); } // TODO(kcc): support exceptions with use-after-return. TEST(AddressSanitizer, DISABLED_StressStackReuseAndExceptionsTest) { for (int i = 0; i < 10000; i++) { try { StackReuseAndException(); } catch(...) { } } } #endif TEST(AddressSanitizer, MlockTest) { EXPECT_EQ(0, mlockall(MCL_CURRENT)); EXPECT_EQ(0, mlock((void*)0x12345, 0x5678)); EXPECT_EQ(0, munlockall()); EXPECT_EQ(0, munlock((void*)0x987, 0x654)); } struct LargeStruct { int foo[100]; }; // Test for bug http://llvm.org/bugs/show_bug.cgi?id=11763. // Struct copy should not cause asan warning even if lhs == rhs. TEST(AddressSanitizer, LargeStructCopyTest) { LargeStruct a; *Ident(&a) = *Ident(&a); } __attribute__((no_address_safety_analysis)) static void NoAddressSafety() { char *foo = new char[10]; Ident(foo)[10] = 0; delete [] foo; } TEST(AddressSanitizer, AttributeNoAddressSafetyTest) { Ident(NoAddressSafety)(); } // ------------------ demo tests; run each one-by-one ------------- // e.g. --gtest_filter=*DemoOOBLeftHigh --gtest_also_run_disabled_tests TEST(AddressSanitizer, DISABLED_DemoThreadedTest) { ThreadedTestSpawn(); } void *SimpleBugOnSTack(void *x = 0) { char a[20]; Ident(a)[20] = 0; return 0; } TEST(AddressSanitizer, DISABLED_DemoStackTest) { SimpleBugOnSTack(); } TEST(AddressSanitizer, DISABLED_DemoThreadStackTest) { pthread_t t; pthread_create(&t, 0, SimpleBugOnSTack, 0); pthread_join(t, 0); } TEST(AddressSanitizer, DISABLED_DemoUAFLowIn) { uaf_test<U1>(10, 0); } TEST(AddressSanitizer, DISABLED_DemoUAFLowLeft) { uaf_test<U1>(10, -2); } TEST(AddressSanitizer, DISABLED_DemoUAFLowRight) { uaf_test<U1>(10, 10); } TEST(AddressSanitizer, DISABLED_DemoUAFHigh) { uaf_test<U1>(kLargeMalloc, 0); } TEST(AddressSanitizer, DISABLED_DemoOOBLeftLow) { oob_test<U1>(10, -1); } TEST(AddressSanitizer, DISABLED_DemoOOBLeftHigh) { oob_test<U1>(kLargeMalloc, -1); } TEST(AddressSanitizer, DISABLED_DemoOOBRightLow) { oob_test<U1>(10, 10); } TEST(AddressSanitizer, DISABLED_DemoOOBRightHigh) { oob_test<U1>(kLargeMalloc, kLargeMalloc); } TEST(AddressSanitizer, DISABLED_DemoOOM) { size_t size = __WORDSIZE == 64 ? (size_t)(1ULL << 40) : (0xf0000000); printf("%p\n", malloc(size)); } TEST(AddressSanitizer, DISABLED_DemoDoubleFreeTest) { DoubleFree(); } TEST(AddressSanitizer, DISABLED_DemoNullDerefTest) { int *a = 0; Ident(a)[10] = 0; } TEST(AddressSanitizer, DISABLED_DemoFunctionStaticTest) { static char a[100]; static char b[100]; static char c[100]; Ident(a); Ident(b); Ident(c); Ident(a)[5] = 0; Ident(b)[105] = 0; Ident(a)[5] = 0; } TEST(AddressSanitizer, DISABLED_DemoTooMuchMemoryTest) { const size_t kAllocSize = (1 << 28) - 1024; size_t total_size = 0; while (true) { char *x = (char*)malloc(kAllocSize); memset(x, 0, kAllocSize); total_size += kAllocSize; fprintf(stderr, "total: %ldM %p\n", (long)total_size >> 20, x); } } // http://code.google.com/p/address-sanitizer/issues/detail?id=66 TEST(AddressSanitizer, BufferOverflowAfterManyFrees) { for (int i = 0; i < 1000000; i++) { delete [] (Ident(new char [8644])); } char *x = new char[8192]; EXPECT_DEATH(x[Ident(8192)] = 0, "AddressSanitizer heap-buffer-overflow"); delete [] Ident(x); } #ifdef __APPLE__ #include "asan_mac_test.h" TEST(AddressSanitizerMac, CFAllocatorDefaultDoubleFree) { EXPECT_DEATH( CFAllocatorDefaultDoubleFree(NULL), "attempting double-free"); } void CFAllocator_DoubleFreeOnPthread() { pthread_t child; pthread_create(&child, NULL, CFAllocatorDefaultDoubleFree, NULL); pthread_join(child, NULL); // Shouldn't be reached. } TEST(AddressSanitizerMac, CFAllocatorDefaultDoubleFree_ChildPhread) { EXPECT_DEATH(CFAllocator_DoubleFreeOnPthread(), "attempting double-free"); } namespace { void *GLOB; void *CFAllocatorAllocateToGlob(void *unused) { GLOB = CFAllocatorAllocate(NULL, 100, /*hint*/0); return NULL; } void *CFAllocatorDeallocateFromGlob(void *unused) { char *p = (char*)GLOB; p[100] = 'A'; // ASan should report an error here. CFAllocatorDeallocate(NULL, GLOB); return NULL; } void CFAllocator_PassMemoryToAnotherThread() { pthread_t th1, th2; pthread_create(&th1, NULL, CFAllocatorAllocateToGlob, NULL); pthread_join(th1, NULL); pthread_create(&th2, NULL, CFAllocatorDeallocateFromGlob, NULL); pthread_join(th2, NULL); } TEST(AddressSanitizerMac, CFAllocator_PassMemoryToAnotherThread) { EXPECT_DEATH(CFAllocator_PassMemoryToAnotherThread(), "heap-buffer-overflow"); } } // namespace // TODO(glider): figure out whether we still need these tests. Is it correct // to intercept the non-default CFAllocators? TEST(AddressSanitizerMac, DISABLED_CFAllocatorSystemDefaultDoubleFree) { EXPECT_DEATH( CFAllocatorSystemDefaultDoubleFree(), "attempting double-free"); } // We're intercepting malloc, so kCFAllocatorMalloc is routed to ASan. TEST(AddressSanitizerMac, CFAllocatorMallocDoubleFree) { EXPECT_DEATH(CFAllocatorMallocDoubleFree(), "attempting double-free"); } TEST(AddressSanitizerMac, DISABLED_CFAllocatorMallocZoneDoubleFree) { EXPECT_DEATH(CFAllocatorMallocZoneDoubleFree(), "attempting double-free"); } TEST(AddressSanitizerMac, GCDDispatchAsync) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDDispatchAsync(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDDispatchSync) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDDispatchSync(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDReuseWqthreadsAsync) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDReuseWqthreadsAsync(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDReuseWqthreadsSync) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDReuseWqthreadsSync(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDDispatchAfter) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDDispatchAfter(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDSourceEvent) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDSourceEvent(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDSourceCancel) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDSourceCancel(), "Shadow byte and word"); } TEST(AddressSanitizerMac, GCDGroupAsync) { // Make sure the whole ASan report is printed, i.e. that we don't die // on a CHECK. EXPECT_DEATH(TestGCDGroupAsync(), "Shadow byte and word"); } void *MallocIntrospectionLockWorker(void *_) { const int kNumPointers = 100; int i; void *pointers[kNumPointers]; for (i = 0; i < kNumPointers; i++) { pointers[i] = malloc(i + 1); } for (i = 0; i < kNumPointers; i++) { free(pointers[i]); } return NULL; } void *MallocIntrospectionLockForker(void *_) { pid_t result = fork(); if (result == -1) { perror("fork"); } assert(result != -1); if (result == 0) { // Call malloc in the child process to make sure we won't deadlock. void *ptr = malloc(42); free(ptr); exit(0); } else { // Return in the parent process. return NULL; } } TEST(AddressSanitizerMac, MallocIntrospectionLock) { // Incorrect implementation of force_lock and force_unlock in our malloc zone // will cause forked processes to deadlock. // TODO(glider): need to detect that none of the child processes deadlocked. const int kNumWorkers = 5, kNumIterations = 100; int i, iter; for (iter = 0; iter < kNumIterations; iter++) { pthread_t workers[kNumWorkers], forker; for (i = 0; i < kNumWorkers; i++) { pthread_create(&workers[i], 0, MallocIntrospectionLockWorker, 0); } pthread_create(&forker, 0, MallocIntrospectionLockForker, 0); for (i = 0; i < kNumWorkers; i++) { pthread_join(workers[i], 0); } pthread_join(forker, 0); } } void *TSDAllocWorker(void *test_key) { if (test_key) { void *mem = malloc(10); pthread_setspecific(*(pthread_key_t*)test_key, mem); } return NULL; } TEST(AddressSanitizerMac, DISABLED_TSDWorkqueueTest) { pthread_t th; pthread_key_t test_key; pthread_key_create(&test_key, CallFreeOnWorkqueue); pthread_create(&th, NULL, TSDAllocWorker, &test_key); pthread_join(th, NULL); pthread_key_delete(test_key); } // Test that CFStringCreateCopy does not copy constant strings. TEST(AddressSanitizerMac, CFStringCreateCopy) { CFStringRef str = CFSTR("Hello world!\n"); CFStringRef str2 = CFStringCreateCopy(0, str); EXPECT_EQ(str, str2); } TEST(AddressSanitizerMac, NSObjectOOB) { // Make sure that our allocators are used for NSObjects. EXPECT_DEATH(TestOOBNSObjects(), "heap-buffer-overflow"); } // Make sure that correct pointer is passed to free() when deallocating a // NSURL object. // See http://code.google.com/p/address-sanitizer/issues/detail?id=70. TEST(AddressSanitizerMac, NSURLDeallocation) { TestNSURLDeallocation(); } #endif // __APPLE__ // Test that instrumentation of stack allocations takes into account // AllocSize of a type, and not its StoreSize (16 vs 10 bytes for long double). // See http://llvm.org/bugs/show_bug.cgi?id=12047 for more details. TEST(AddressSanitizer, LongDoubleNegativeTest) { long double a, b; static long double c; memcpy(Ident(&a), Ident(&b), sizeof(long double)); memcpy(Ident(&c), Ident(&b), sizeof(long double)); }; int main(int argc, char **argv) { progname = argv[0]; testing::GTEST_FLAG(death_test_style) = "threadsafe"; testing::InitGoogleTest(&argc, argv); return RUN_ALL_TESTS(); }