/* * Copyright (C) 2012 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include #include #include #define KB 1024 #define SMALL 1*KB #define LARGE 64*KB static int signum(int i) { if (i < 0) { return -1; } else if (i > 0) { return 1; } return 0; } TEST(string, strerror) { // Valid. ASSERT_STREQ("Success", strerror(0)); ASSERT_STREQ("Operation not permitted", strerror(1)); // Invalid. ASSERT_STREQ("Unknown error -1", strerror(-1)); ASSERT_STREQ("Unknown error 1234", strerror(1234)); } #if __BIONIC__ // glibc's strerror isn't thread safe, only its strsignal. static void* ConcurrentStrErrorFn(void*) { bool equal = (strcmp("Unknown error 2002", strerror(2002)) == 0); return reinterpret_cast(equal); } TEST(string, strerror_concurrent) { const char* strerror1001 = strerror(1001); ASSERT_STREQ("Unknown error 1001", strerror1001); pthread_t t; ASSERT_EQ(0, pthread_create(&t, NULL, ConcurrentStrErrorFn, NULL)); void* result; ASSERT_EQ(0, pthread_join(t, &result)); ASSERT_TRUE(static_cast(result)); ASSERT_STREQ("Unknown error 1001", strerror1001); } #endif #if __BIONIC__ // glibc's strerror_r doesn't even have the same signature as the POSIX one. TEST(string, strerror_r) { char buf[256]; // Valid. ASSERT_EQ(0, strerror_r(0, buf, sizeof(buf))); ASSERT_STREQ("Success", buf); ASSERT_EQ(0, strerror_r(1, buf, sizeof(buf))); ASSERT_STREQ("Operation not permitted", buf); // Invalid. ASSERT_EQ(0, strerror_r(-1, buf, sizeof(buf))); ASSERT_STREQ("Unknown error -1", buf); ASSERT_EQ(0, strerror_r(1234, buf, sizeof(buf))); ASSERT_STREQ("Unknown error 1234", buf); // Buffer too small. ASSERT_EQ(-1, strerror_r(0, buf, 2)); ASSERT_EQ(ERANGE, errno); } #endif TEST(string, strsignal) { // A regular signal. ASSERT_STREQ("Hangup", strsignal(1)); // A real-time signal. #ifdef __GLIBC__ // glibc reserves real-time signals for internal use, and doesn't count those. ASSERT_STREQ("Real-time signal 14", strsignal(48)); #else ASSERT_STREQ("Real-time signal 16", strsignal(48)); #endif // Errors. ASSERT_STREQ("Unknown signal -1", strsignal(-1)); // Too small. ASSERT_STREQ("Unknown signal 0", strsignal(0)); // Still too small. ASSERT_STREQ("Unknown signal 1234", strsignal(1234)); // Too large. } static void* ConcurrentStrSignalFn(void*) { bool equal = (strcmp("Unknown signal 2002", strsignal(2002)) == 0); return reinterpret_cast(equal); } TEST(string, strsignal_concurrent) { const char* strsignal1001 = strsignal(1001); ASSERT_STREQ("Unknown signal 1001", strsignal1001); pthread_t t; ASSERT_EQ(0, pthread_create(&t, NULL, ConcurrentStrSignalFn, NULL)); void* result; ASSERT_EQ(0, pthread_join(t, &result)); ASSERT_TRUE(static_cast(result)); ASSERT_STREQ("Unknown signal 1001", strsignal1001); } // TODO: where did these numbers come from? #define POS_ITER 10 #define ITER 500 // For every length we want to test, vary and change alignment // of allocated memory, fill it with some values, calculate // expected result and then run function and compare what we got. // These tests contributed by Intel Corporation. // TODO: make these tests more intention-revealing and less random. struct StringTestState { StringTestState(size_t MAX_LEN) : MAX_LEN(MAX_LEN) { int max_alignment = 64; // TODO: fix the tests to not sometimes use twice their specified "MAX_LEN". glob_ptr = reinterpret_cast(valloc(2 * MAX_LEN + max_alignment)); glob_ptr1 = reinterpret_cast(valloc(2 * MAX_LEN + max_alignment)); glob_ptr2 = reinterpret_cast(valloc(2 * MAX_LEN + max_alignment)); InitLenArray(); srandom(1234); } ~StringTestState() { free(glob_ptr); free(glob_ptr1); free(glob_ptr2); } void NewIteration() { int alignments[] = { 24, 32, 16, 48, 1, 2, 3, 0, 5, 11 }; int usable_alignments = 10; int align1 = alignments[random() % (usable_alignments - 1)]; int align2 = alignments[random() % (usable_alignments - 1)]; ptr = glob_ptr + align1; ptr1 = glob_ptr1 + align1; ptr2 = glob_ptr2 + align2; } const size_t MAX_LEN; char *ptr, *ptr1, *ptr2; size_t n; int len[ITER + 1]; private: char *glob_ptr, *glob_ptr1, *glob_ptr2; // Calculate input lengths and fill state.len with them. // Test small lengths with more density than big ones. Manually push // smallest (0) and biggest (MAX_LEN) lengths. Avoid repeats. // Return number of lengths to test. void InitLenArray() { n = 0; len[n++] = 0; for (size_t i = 1; i < ITER; ++i) { int l = (int) exp(log((double) MAX_LEN) * i / ITER); if (l != len[n - 1]) { len[n++] = l; } } len[n++] = MAX_LEN; } }; TEST(string, strcat) { StringTestState state(SMALL); for (size_t i = 1; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr2, '\2', state.MAX_LEN); state.ptr2[state.MAX_LEN - 1] = '\0'; memcpy(state.ptr, state.ptr2, 2 * state.MAX_LEN); memset(state.ptr1, random() & 255, state.len[i]); state.ptr1[random() % state.len[i]] = '\0'; state.ptr1[state.len[i] - 1] = '\0'; strcpy(state.ptr + state.MAX_LEN - 1, state.ptr1); EXPECT_TRUE(strcat(state.ptr2, state.ptr1) == state.ptr2); EXPECT_TRUE(memcmp(state.ptr, state.ptr2, 2 * state.MAX_LEN) == 0); } } } TEST(string, strchr) { int seek_char = random() & 255; StringTestState state(SMALL); for (size_t i = 1; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); if (~seek_char > 0) { memset(state.ptr1, ~seek_char, state.len[i]); } else { memset(state.ptr1, '\1', state.len[i]); } state.ptr1[state.len[i] - 1] = '\0'; int pos = random() % state.MAX_LEN; char* expected; if (pos >= state.len[i] - 1) { if (seek_char == 0) { expected = state.ptr1 + state.len[i] - 1; } else { expected = NULL; } } else { state.ptr1[pos] = seek_char; expected = state.ptr1 + pos; } ASSERT_TRUE(strchr(state.ptr1, seek_char) == expected); } } } TEST(string, strcmp) { StringTestState state(SMALL); for (size_t i = 1; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, 'v', state.MAX_LEN); memset(state.ptr2, 'n', state.MAX_LEN); state.ptr1[state.len[i] - 1] = '\0'; state.ptr2[state.len[i] - 1] = '\0'; int pos = 1 + (random() % (state.MAX_LEN - 1)); int actual; int expected; if (pos >= state.len[i] - 1) { memcpy(state.ptr1, state.ptr2, state.len[i]); expected = 0; actual = strcmp(state.ptr1, state.ptr2); } else { memcpy(state.ptr1, state.ptr2, pos); if (state.ptr1[pos] > state.ptr2[pos]) { expected = 1; } else if (state.ptr1[pos] == state.ptr2[pos]) { state.ptr1[pos + 1] = '\0'; state.ptr2[pos + 1] = '\0'; expected = 0; } else { expected = -1; } actual = strcmp(state.ptr1, state.ptr2); } ASSERT_EQ(expected, signum(actual)); } } } TEST(string, strcpy) { StringTestState state(SMALL); for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); size_t pos = random() % state.MAX_LEN; memset(state.ptr1, '\2', pos); state.ptr1[pos] = '\0'; state.ptr1[state.MAX_LEN - 1] = '\0'; memcpy(state.ptr, state.ptr1, state.MAX_LEN); memset(state.ptr2, '\1', state.MAX_LEN); state.ptr2[state.MAX_LEN - 1] = '\0'; memset(state.ptr + state.MAX_LEN, '\1', state.MAX_LEN); memcpy(state.ptr + state.MAX_LEN, state.ptr1, pos + 1); state.ptr[2 * state.MAX_LEN - 1] = '\0'; ASSERT_TRUE(strcpy(state.ptr2, state.ptr1) == state.ptr2); ASSERT_FALSE((memcmp(state.ptr1, state.ptr, state.MAX_LEN)) != 0 || (memcmp(state.ptr2, state.ptr + state.MAX_LEN, state.MAX_LEN) != 0)); } } #if __BIONIC__ // We have to say "DeathTest" here so gtest knows to run this test (which exits) // in its own process. TEST(string_DeathTest, strcpy_fortified) { ::testing::FLAGS_gtest_death_test_style = "threadsafe"; char buf[10]; char *orig = strdup("0123456789"); ASSERT_EXIT(strcpy(buf, orig), testing::KilledBySignal(SIGSEGV), ""); free(orig); } TEST(string_DeathTest, strlen_fortified) { ::testing::FLAGS_gtest_death_test_style = "threadsafe"; char buf[10]; memcpy(buf, "0123456789", sizeof(buf)); ASSERT_EXIT(printf("%d", strlen(buf)), testing::KilledBySignal(SIGSEGV), ""); } TEST(string_DeathTest, strchr_fortified) { ::testing::FLAGS_gtest_death_test_style = "threadsafe"; char buf[10]; memcpy(buf, "0123456789", sizeof(buf)); ASSERT_EXIT(printf("%s", strchr(buf, 'a')), testing::KilledBySignal(SIGSEGV), ""); } TEST(string_DeathTest, strrchr_fortified) { ::testing::FLAGS_gtest_death_test_style = "threadsafe"; char buf[10]; memcpy(buf, "0123456789", sizeof(buf)); ASSERT_EXIT(printf("%s", strrchr(buf, 'a')), testing::KilledBySignal(SIGSEGV), ""); } #endif #if __BIONIC__ TEST(string, strlcat) { StringTestState state(SMALL); for (size_t i = 0; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr2, '\2', state.MAX_LEN + state.len[i]); state.ptr2[state.MAX_LEN - 1] = '\0'; memcpy(state.ptr, state.ptr2, state.MAX_LEN + state.len[i]); int pos = random() % state.MAX_LEN; memset(state.ptr1, '\3', pos); state.ptr1[pos] = '\0'; if (pos < state.len[i]) { memcpy(state.ptr + state.MAX_LEN - 1, state.ptr1, pos + 1); } else { memcpy(state.ptr + state.MAX_LEN - 1, state.ptr1, state.len[i]); state.ptr[state.MAX_LEN + state.len[i] - 1] = '\0'; } strlcat(state.ptr2, state.ptr1, state.MAX_LEN + state.len[i]); ASSERT_TRUE(memcmp(state.ptr, state.ptr2, state.MAX_LEN + state.len[i]) == 0); } } } #endif #if __BIONIC__ TEST(string, strlcpy) { StringTestState state(SMALL); for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); int rand = random() & 255; if (rand < 1) { rand = 1; } memset(state.ptr1, rand, state.MAX_LEN); size_t pos = random() % state.MAX_LEN; if (pos < state.MAX_LEN) { state.ptr1[pos] = '\0'; } memcpy(state.ptr, state.ptr1, state.MAX_LEN); memset(state.ptr2, random() & 255, state.MAX_LEN); memcpy(state.ptr + state.MAX_LEN, state.ptr2, state.MAX_LEN); if (pos > state.MAX_LEN - 1) { memcpy(state.ptr + state.MAX_LEN, state.ptr1, state.MAX_LEN); state.ptr[2 * state.MAX_LEN - 1] = '\0'; } else { memcpy(state.ptr + state.MAX_LEN, state.ptr1, pos + 1); } ASSERT_EQ(strlcpy(state.ptr2, state.ptr1, state.MAX_LEN), strlen(state.ptr1)); ASSERT_FALSE((memcmp(state.ptr1, state.ptr, state.MAX_LEN) != 0) || (memcmp(state.ptr2, state.ptr + state.MAX_LEN, state.MAX_LEN) != 0)); } } #endif TEST(string, strncat) { StringTestState state(SMALL); for (size_t i = 1; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr2, '\2', state.MAX_LEN); state.ptr2[state.MAX_LEN - 1] = '\0'; memcpy(state.ptr, state.ptr2, 2 * state.MAX_LEN); memset(state.ptr1, random() & 255, state.len[i]); state.ptr1[random() % state.len[i]] = '\0'; state.ptr1[state.len[i] - 1] = '\0'; size_t pos = strlen(state.ptr1); size_t actual = random() % state.len[i]; strncpy(state.ptr + state.MAX_LEN - 1, state.ptr1, std::min(actual, pos)); state.ptr[state.MAX_LEN + std::min(actual, pos) - 1] = '\0'; ASSERT_TRUE(strncat(state.ptr2, state.ptr1, actual) == state.ptr2); ASSERT_EQ(memcmp(state.ptr, state.ptr2, 2 * state.MAX_LEN), 0); } } } TEST(string, strncmp) { StringTestState state(SMALL); for (size_t i = 1; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, 'v', state.MAX_LEN); memset(state.ptr2, 'n', state.MAX_LEN); state.ptr1[state.len[i] - 1] = '\0'; state.ptr2[state.len[i] - 1] = '\0'; int pos = 1 + (random() % (state.MAX_LEN - 1)); int actual; int expected; if (pos >= state.len[i] - 1) { memcpy(state.ptr1, state.ptr2, state.len[i]); expected = 0; actual = strncmp(state.ptr1, state.ptr2, state.len[i]); } else { memcpy(state.ptr1, state.ptr2, pos); if (state.ptr1[pos] > state.ptr2[pos]) { expected = 1; } else if (state.ptr1[pos] == state.ptr2[pos]) { state.ptr1[pos + 1] = '\0'; state.ptr2[pos + 1] = '\0'; expected = 0; } else { expected = -1; } actual = strncmp(state.ptr1, state.ptr2, state.len[i]); } ASSERT_EQ(expected, signum(actual)); } } } TEST(string, strncpy) { StringTestState state(SMALL); for (size_t j = 0; j < ITER; j++) { state.NewIteration(); memset(state.ptr1, random() & 255, state.MAX_LEN); state.ptr1[random () % state.MAX_LEN] = '\0'; memcpy(state.ptr, state.ptr1, state.MAX_LEN); memset(state.ptr2, '\1', state.MAX_LEN); size_t pos; if (memchr(state.ptr1, 0, state.MAX_LEN)) { pos = strlen(state.ptr1); } else { pos = state.MAX_LEN - 1; } memset(state.ptr + state.MAX_LEN, '\0', state.MAX_LEN); memcpy(state.ptr + state.MAX_LEN, state.ptr1, pos + 1); ASSERT_TRUE(strncpy(state.ptr2, state.ptr1, state.MAX_LEN) == state.ptr2); ASSERT_FALSE(memcmp(state.ptr1, state.ptr, state.MAX_LEN) != 0 || memcmp(state.ptr2, state.ptr + state.MAX_LEN, state.MAX_LEN) != 0); } } TEST(string, strrchr) { int seek_char = random() & 255; StringTestState state(SMALL); for (size_t i = 1; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); if (~seek_char > 0) { memset(state.ptr1, ~seek_char, state.len[i]); } else { memset(state.ptr1, '\1', state.len[i]); } state.ptr1[state.len[i] - 1] = '\0'; int pos = random() % state.MAX_LEN; char* expected; if (pos >= state.len[i] - 1) { if (seek_char == 0) { expected = state.ptr1 + state.len[i] - 1; } else { expected = NULL; } } else { state.ptr1[pos] = seek_char; expected = state.ptr1 + pos; } ASSERT_TRUE(strrchr(state.ptr1, seek_char) == expected); } } } TEST(string, memchr) { int seek_char = random() & 255; StringTestState state(SMALL); for (size_t i = 0; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, ~seek_char, state.len[i]); int pos = random() % state.MAX_LEN; char* expected; if (pos >= state.len[i]) { expected = NULL; } else { state.ptr1[pos] = seek_char; expected = state.ptr1 + pos; } ASSERT_TRUE(memchr(state.ptr1, seek_char, state.len[i]) == expected); } } } TEST(string, memrchr) { int seek_char = random() & 255; StringTestState state(SMALL); for (size_t i = 0; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, ~seek_char, state.len[i]); int pos = random() % state.MAX_LEN; char* expected; if (pos >= state.len[i]) { expected = NULL; } else { state.ptr1[pos] = seek_char; expected = state.ptr1 + pos; } ASSERT_TRUE(memrchr(state.ptr1, seek_char, state.len[i]) == expected); } } } TEST(string, memcmp) { StringTestState state(SMALL); for (size_t i = 0; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); int c1 = random() & 0xff; int c2 = random() & 0xff; memset(state.ptr1, c1, state.MAX_LEN); memset(state.ptr2, c1, state.MAX_LEN); int pos = (state.len[i] == 0) ? 0 : (random() % state.len[i]); state.ptr2[pos] = c2; int expected = (static_cast(c1) - static_cast(c2)); int actual = memcmp(state.ptr1, state.ptr2, state.MAX_LEN); ASSERT_EQ(signum(expected), signum(actual)); } } } TEST(string, memcpy) { StringTestState state(LARGE); int rand = random() & 255; for (size_t i = 0; i < state.n - 1; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); size_t pos = random() % (state.MAX_LEN - state.len[i]); memset(state.ptr1, rand, state.len[i]); memset(state.ptr1 + state.len[i], ~rand, state.MAX_LEN - state.len[i]); memset(state.ptr2, rand, state.len[i]); memset(state.ptr2 + state.len[i], ~rand, state.MAX_LEN - state.len[i]); memset(state.ptr2 + pos, '\0', state.len[i]); ASSERT_FALSE(memcpy(state.ptr2 + pos, state.ptr1 + pos, state.len[i]) != state.ptr2 + pos); ASSERT_EQ(0, memcmp(state.ptr1, state.ptr2, state.MAX_LEN)); } } } TEST(string, memset) { StringTestState state(LARGE); char ch = random () & 255; for (size_t i = 0; i < state.n - 1; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, ~ch, state.MAX_LEN); memcpy(state.ptr2, state.ptr1, state.MAX_LEN); size_t pos = random () % (state.MAX_LEN - state.len[i]); for (size_t k = pos; k < pos + state.len[i]; k++) { state.ptr1[k] = ch; } ASSERT_TRUE(memset(state.ptr2 + pos, ch, state.len[i]) == state.ptr2 + pos); ASSERT_EQ(0, memcmp(state.ptr1, state.ptr2, state.MAX_LEN)); } } } TEST(string, memmove) { StringTestState state(LARGE); for (size_t i = 0; i < state.n - 1; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, random() & 255, 2 * state.MAX_LEN); size_t pos = random() % (state.MAX_LEN - state.len[i]); memset(state.ptr1, random() & 255, state.len[i]); memcpy(state.ptr2, state.ptr1, 2 * state.MAX_LEN); memcpy(state.ptr, state.ptr1, state.len[i]); memcpy(state.ptr1 + pos, state.ptr, state.len[i]); ASSERT_TRUE(memmove(state.ptr2 + pos, state.ptr2, state.len[i]) == state.ptr2 + pos); ASSERT_EQ(0, memcmp(state.ptr2, state.ptr1, 2 * state.MAX_LEN)); } } } TEST(string, bcopy) { StringTestState state(LARGE); for (size_t i = 0; i < state.n; i++) { for (size_t j = 0; j < POS_ITER; j++) { state.NewIteration(); memset(state.ptr1, random() & 255, state.MAX_LEN); memset(state.ptr1 + state.MAX_LEN, random() & 255, state.MAX_LEN); memcpy(state.ptr2, state.ptr1, 2 * state.MAX_LEN); size_t start = random() % (2 * state.MAX_LEN - state.len[i]); memcpy(state.ptr2 + start, state.ptr1, state.len[i]); bcopy(state.ptr1, state.ptr1 + start, state.len[i]); ASSERT_EQ(0, memcmp(state.ptr1, state.ptr2, 2 * state.MAX_LEN)); } } } TEST(string, bzero) { StringTestState state(LARGE); for (size_t j = 0; j < ITER; j++) { state.NewIteration(); memset(state.ptr1, random() & 255, state.MAX_LEN); size_t start = random() % state.MAX_LEN; size_t end = start + random() % (state.MAX_LEN - start); memcpy(state.ptr2, state.ptr1, start); memset(state.ptr2 + start, '\0', end - start); memcpy(state.ptr2 + end, state.ptr1 + end, state.MAX_LEN - end); bzero(state.ptr1 + start, end - start); ASSERT_EQ(0, memcmp(state.ptr1, state.ptr2, state.MAX_LEN)); } }