/* * Copyright (C) 2013-2014 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 #include #include #include #include #include #include #include "benchmark.h" // enhanced version of LOG_FAILURE_RETRY to add support for EAGAIN and // non-syscall libs. Since we are benchmarking, or using this in the emergency // signal to stuff a terminating code, we do NOT want to introduce // a syscall or usleep on EAGAIN retry. #define LOG_FAILURE_RETRY(exp) ({ \ typeof (exp) _rc; \ do { \ _rc = (exp); \ } while (((_rc == -1) \ && ((errno == EINTR) \ || (errno == EAGAIN))) \ || (_rc == -EINTR) \ || (_rc == -EAGAIN)); \ _rc; }) /* * Measure the fastest rate we can reliabley stuff print messages into * the log at high pressure. Expect this to be less than double the process * wakeup time (2ms?) */ static void BM_log_maximum_retry(int iters) { StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { LOG_FAILURE_RETRY( __android_log_print(ANDROID_LOG_INFO, "BM_log_maximum_retry", "%d", i)); } StopBenchmarkTiming(); } BENCHMARK(BM_log_maximum_retry); /* * Measure the fastest rate we can stuff print messages into the log * at high pressure. Expect this to be less than double the process wakeup * time (2ms?) */ static void BM_log_maximum(int iters) { StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { __android_log_print(ANDROID_LOG_INFO, "BM_log_maximum", "%d", i); } StopBenchmarkTiming(); } BENCHMARK(BM_log_maximum); /* * Measure the time it takes to submit the android logging call using * discrete acquisition under light load. Expect this to be a pair of * syscall periods (2us). */ static void BM_clock_overhead(int iters) { for (int i = 0; i < iters; ++i) { StartBenchmarkTiming(); StopBenchmarkTiming(); } } BENCHMARK(BM_clock_overhead); /* * Measure the time it takes to submit the android logging data to pstore */ static void BM_pmsg_short(int iters) { int pstore_fd = TEMP_FAILURE_RETRY(open("/dev/pmsg0", O_WRONLY)); if (pstore_fd < 0) { return; } /* * struct { * // what we provide to pstore * android_pmsg_log_header_t pmsg_header; * // what we provide to socket * android_log_header_t header; * // caller provides * union { * struct { * char prio; * char payload[]; * } string; * struct { * uint32_t tag * char payload[]; * } binary; * }; * }; */ struct timespec ts; clock_gettime(android_log_clockid(), &ts); android_pmsg_log_header_t pmsg_header; pmsg_header.magic = LOGGER_MAGIC; pmsg_header.len = sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t); pmsg_header.uid = getuid(); pmsg_header.pid = getpid(); android_log_header_t header; header.tid = gettid(); header.realtime.tv_sec = ts.tv_sec; header.realtime.tv_nsec = ts.tv_nsec; static const unsigned nr = 1; static const unsigned header_length = 2; struct iovec newVec[nr + header_length]; newVec[0].iov_base = (unsigned char *) &pmsg_header; newVec[0].iov_len = sizeof(pmsg_header); newVec[1].iov_base = (unsigned char *) &header; newVec[1].iov_len = sizeof(header); android_log_event_int_t buffer; header.id = LOG_ID_EVENTS; buffer.header.tag = 0; buffer.payload.type = EVENT_TYPE_INT; uint32_t snapshot = 0; buffer.payload.data = htole32(snapshot); newVec[2].iov_base = &buffer; newVec[2].iov_len = sizeof(buffer); StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { ++snapshot; buffer.payload.data = htole32(snapshot); writev(pstore_fd, newVec, nr); } StopBenchmarkTiming(); close(pstore_fd); } BENCHMARK(BM_pmsg_short); /* * Measure the time it takes to submit the android logging data to pstore * best case aligned single block. */ static void BM_pmsg_short_aligned(int iters) { int pstore_fd = TEMP_FAILURE_RETRY(open("/dev/pmsg0", O_WRONLY)); if (pstore_fd < 0) { return; } /* * struct { * // what we provide to pstore * android_pmsg_log_header_t pmsg_header; * // what we provide to socket * android_log_header_t header; * // caller provides * union { * struct { * char prio; * char payload[]; * } string; * struct { * uint32_t tag * char payload[]; * } binary; * }; * }; */ struct timespec ts; clock_gettime(android_log_clockid(), &ts); struct packet { android_pmsg_log_header_t pmsg_header; android_log_header_t header; android_log_event_int_t payload; }; char buf[sizeof(struct packet) + 8] __aligned(8); memset(buf, 0, sizeof(buf)); struct packet *buffer = (struct packet*)(((uintptr_t)buf + 7) & ~7); if (((uintptr_t)&buffer->pmsg_header) & 7) { fprintf (stderr, "&buffer=0x%p iters=%d\n", &buffer->pmsg_header, iters); } buffer->pmsg_header.magic = LOGGER_MAGIC; buffer->pmsg_header.len = sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t); buffer->pmsg_header.uid = getuid(); buffer->pmsg_header.pid = getpid(); buffer->header.tid = gettid(); buffer->header.realtime.tv_sec = ts.tv_sec; buffer->header.realtime.tv_nsec = ts.tv_nsec; buffer->header.id = LOG_ID_EVENTS; buffer->payload.header.tag = 0; buffer->payload.payload.type = EVENT_TYPE_INT; uint32_t snapshot = 0; buffer->payload.payload.data = htole32(snapshot); StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { ++snapshot; buffer->payload.payload.data = htole32(snapshot); write(pstore_fd, &buffer->pmsg_header, sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t) + sizeof(android_log_event_int_t)); } StopBenchmarkTiming(); close(pstore_fd); } BENCHMARK(BM_pmsg_short_aligned); /* * Measure the time it takes to submit the android logging data to pstore * best case aligned single block. */ static void BM_pmsg_short_unaligned1(int iters) { int pstore_fd = TEMP_FAILURE_RETRY(open("/dev/pmsg0", O_WRONLY)); if (pstore_fd < 0) { return; } /* * struct { * // what we provide to pstore * android_pmsg_log_header_t pmsg_header; * // what we provide to socket * android_log_header_t header; * // caller provides * union { * struct { * char prio; * char payload[]; * } string; * struct { * uint32_t tag * char payload[]; * } binary; * }; * }; */ struct timespec ts; clock_gettime(android_log_clockid(), &ts); struct packet { android_pmsg_log_header_t pmsg_header; android_log_header_t header; android_log_event_int_t payload; }; char buf[sizeof(struct packet) + 8] __aligned(8); memset(buf, 0, sizeof(buf)); struct packet *buffer = (struct packet*)((((uintptr_t)buf + 7) & ~7) + 1); if ((((uintptr_t)&buffer->pmsg_header) & 7) != 1) { fprintf (stderr, "&buffer=0x%p iters=%d\n", &buffer->pmsg_header, iters); } buffer->pmsg_header.magic = LOGGER_MAGIC; buffer->pmsg_header.len = sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t); buffer->pmsg_header.uid = getuid(); buffer->pmsg_header.pid = getpid(); buffer->header.tid = gettid(); buffer->header.realtime.tv_sec = ts.tv_sec; buffer->header.realtime.tv_nsec = ts.tv_nsec; buffer->header.id = LOG_ID_EVENTS; buffer->payload.header.tag = 0; buffer->payload.payload.type = EVENT_TYPE_INT; uint32_t snapshot = 0; buffer->payload.payload.data = htole32(snapshot); StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { ++snapshot; buffer->payload.payload.data = htole32(snapshot); write(pstore_fd, &buffer->pmsg_header, sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t) + sizeof(android_log_event_int_t)); } StopBenchmarkTiming(); close(pstore_fd); } BENCHMARK(BM_pmsg_short_unaligned1); /* * Measure the time it takes to submit the android logging data to pstore * best case aligned single block. */ static void BM_pmsg_long_aligned(int iters) { int pstore_fd = TEMP_FAILURE_RETRY(open("/dev/pmsg0", O_WRONLY)); if (pstore_fd < 0) { return; } /* * struct { * // what we provide to pstore * android_pmsg_log_header_t pmsg_header; * // what we provide to socket * android_log_header_t header; * // caller provides * union { * struct { * char prio; * char payload[]; * } string; * struct { * uint32_t tag * char payload[]; * } binary; * }; * }; */ struct timespec ts; clock_gettime(android_log_clockid(), &ts); struct packet { android_pmsg_log_header_t pmsg_header; android_log_header_t header; android_log_event_int_t payload; }; char buf[sizeof(struct packet) + 8 + LOGGER_ENTRY_MAX_PAYLOAD] __aligned(8); memset(buf, 0, sizeof(buf)); struct packet *buffer = (struct packet*)(((uintptr_t)buf + 7) & ~7); if (((uintptr_t)&buffer->pmsg_header) & 7) { fprintf (stderr, "&buffer=0x%p iters=%d\n", &buffer->pmsg_header, iters); } buffer->pmsg_header.magic = LOGGER_MAGIC; buffer->pmsg_header.len = sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t); buffer->pmsg_header.uid = getuid(); buffer->pmsg_header.pid = getpid(); buffer->header.tid = gettid(); buffer->header.realtime.tv_sec = ts.tv_sec; buffer->header.realtime.tv_nsec = ts.tv_nsec; buffer->header.id = LOG_ID_EVENTS; buffer->payload.header.tag = 0; buffer->payload.payload.type = EVENT_TYPE_INT; uint32_t snapshot = 0; buffer->payload.payload.data = htole32(snapshot); StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { ++snapshot; buffer->payload.payload.data = htole32(snapshot); write(pstore_fd, &buffer->pmsg_header, LOGGER_ENTRY_MAX_PAYLOAD); } StopBenchmarkTiming(); close(pstore_fd); } BENCHMARK(BM_pmsg_long_aligned); /* * Measure the time it takes to submit the android logging data to pstore * best case aligned single block. */ static void BM_pmsg_long_unaligned1(int iters) { int pstore_fd = TEMP_FAILURE_RETRY(open("/dev/pmsg0", O_WRONLY)); if (pstore_fd < 0) { return; } /* * struct { * // what we provide to pstore * android_pmsg_log_header_t pmsg_header; * // what we provide to socket * android_log_header_t header; * // caller provides * union { * struct { * char prio; * char payload[]; * } string; * struct { * uint32_t tag * char payload[]; * } binary; * }; * }; */ struct timespec ts; clock_gettime(android_log_clockid(), &ts); struct packet { android_pmsg_log_header_t pmsg_header; android_log_header_t header; android_log_event_int_t payload; }; char buf[sizeof(struct packet) + 8 + LOGGER_ENTRY_MAX_PAYLOAD] __aligned(8); memset(buf, 0, sizeof(buf)); struct packet *buffer = (struct packet*)((((uintptr_t)buf + 7) & ~7) + 1); if ((((uintptr_t)&buffer->pmsg_header) & 7) != 1) { fprintf (stderr, "&buffer=0x%p iters=%d\n", &buffer->pmsg_header, iters); } buffer->pmsg_header.magic = LOGGER_MAGIC; buffer->pmsg_header.len = sizeof(android_pmsg_log_header_t) + sizeof(android_log_header_t); buffer->pmsg_header.uid = getuid(); buffer->pmsg_header.pid = getpid(); buffer->header.tid = gettid(); buffer->header.realtime.tv_sec = ts.tv_sec; buffer->header.realtime.tv_nsec = ts.tv_nsec; buffer->header.id = LOG_ID_EVENTS; buffer->payload.header.tag = 0; buffer->payload.payload.type = EVENT_TYPE_INT; uint32_t snapshot = 0; buffer->payload.payload.data = htole32(snapshot); StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { ++snapshot; buffer->payload.payload.data = htole32(snapshot); write(pstore_fd, &buffer->pmsg_header, LOGGER_ENTRY_MAX_PAYLOAD); } StopBenchmarkTiming(); close(pstore_fd); } BENCHMARK(BM_pmsg_long_unaligned1); /* * Measure the time it takes to submit the android logging call using * discrete acquisition under light load. Expect this to be a dozen or so * syscall periods (40us). */ static void BM_log_overhead(int iters) { for (int i = 0; i < iters; ++i) { StartBenchmarkTiming(); __android_log_print(ANDROID_LOG_INFO, "BM_log_overhead", "%d", i); StopBenchmarkTiming(); usleep(1000); } } BENCHMARK(BM_log_overhead); static void caught_latency(int /*signum*/) { unsigned long long v = 0xDEADBEEFA55A5AA5ULL; LOG_FAILURE_RETRY(__android_log_btwrite(0, EVENT_TYPE_LONG, &v, sizeof(v))); } static unsigned long long caught_convert(char *cp) { unsigned long long l = cp[0] & 0xFF; l |= (unsigned long long) (cp[1] & 0xFF) << 8; l |= (unsigned long long) (cp[2] & 0xFF) << 16; l |= (unsigned long long) (cp[3] & 0xFF) << 24; l |= (unsigned long long) (cp[4] & 0xFF) << 32; l |= (unsigned long long) (cp[5] & 0xFF) << 40; l |= (unsigned long long) (cp[6] & 0xFF) << 48; l |= (unsigned long long) (cp[7] & 0xFF) << 56; return l; } static const int alarm_time = 3; /* * Measure the time it takes for the logd posting call to acquire the * timestamp to place into the internal record. Expect this to be less than * 4 syscalls (3us). */ static void BM_log_latency(int iters) { pid_t pid = getpid(); struct logger_list * logger_list = android_logger_list_open(LOG_ID_EVENTS, ANDROID_LOG_RDONLY, 0, pid); if (!logger_list) { fprintf(stderr, "Unable to open events log: %s\n", strerror(errno)); exit(EXIT_FAILURE); } signal(SIGALRM, caught_latency); alarm(alarm_time); for (int j = 0, i = 0; i < iters && j < 10*iters; ++i, ++j) { log_time ts; LOG_FAILURE_RETRY(( ts = log_time(CLOCK_REALTIME), android_btWriteLog(0, EVENT_TYPE_LONG, &ts, sizeof(ts)))); for (;;) { log_msg log_msg; int ret = android_logger_list_read(logger_list, &log_msg); alarm(alarm_time); if (ret <= 0) { iters = i; break; } if ((log_msg.entry.len != (4 + 1 + 8)) || (log_msg.id() != LOG_ID_EVENTS)) { continue; } char* eventData = log_msg.msg(); if (eventData[4] != EVENT_TYPE_LONG) { continue; } log_time tx(eventData + 4 + 1); if (ts != tx) { if (0xDEADBEEFA55A5AA5ULL == caught_convert(eventData + 4 + 1)) { iters = i; break; } continue; } uint64_t start = ts.nsec(); uint64_t end = log_msg.nsec(); if (end >= start) { StartBenchmarkTiming(start); StopBenchmarkTiming(end); } else { --i; } break; } } signal(SIGALRM, SIG_DFL); alarm(0); android_logger_list_free(logger_list); } BENCHMARK(BM_log_latency); static void caught_delay(int /*signum*/) { unsigned long long v = 0xDEADBEEFA55A5AA6ULL; LOG_FAILURE_RETRY(__android_log_btwrite(0, EVENT_TYPE_LONG, &v, sizeof(v))); } /* * Measure the time it takes for the logd posting call to make it into * the logs. Expect this to be less than double the process wakeup time (2ms). */ static void BM_log_delay(int iters) { pid_t pid = getpid(); struct logger_list * logger_list = android_logger_list_open(LOG_ID_EVENTS, ANDROID_LOG_RDONLY, 0, pid); if (!logger_list) { fprintf(stderr, "Unable to open events log: %s\n", strerror(errno)); exit(EXIT_FAILURE); } signal(SIGALRM, caught_delay); alarm(alarm_time); StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { log_time ts(CLOCK_REALTIME); LOG_FAILURE_RETRY( android_btWriteLog(0, EVENT_TYPE_LONG, &ts, sizeof(ts))); for (;;) { log_msg log_msg; int ret = android_logger_list_read(logger_list, &log_msg); alarm(alarm_time); if (ret <= 0) { iters = i; break; } if ((log_msg.entry.len != (4 + 1 + 8)) || (log_msg.id() != LOG_ID_EVENTS)) { continue; } char* eventData = log_msg.msg(); if (eventData[4] != EVENT_TYPE_LONG) { continue; } log_time tx(eventData + 4 + 1); if (ts != tx) { if (0xDEADBEEFA55A5AA6ULL == caught_convert(eventData + 4 + 1)) { iters = i; break; } continue; } break; } } signal(SIGALRM, SIG_DFL); alarm(0); StopBenchmarkTiming(); android_logger_list_free(logger_list); } BENCHMARK(BM_log_delay); /* * Measure the time it takes for __android_log_is_loggable. */ static void BM_is_loggable(int iters) { StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { __android_log_is_loggable(ANDROID_LOG_WARN, "logd", ANDROID_LOG_VERBOSE); } StopBenchmarkTiming(); } BENCHMARK(BM_is_loggable); /* * Measure the time it takes for android_log_clockid. */ static void BM_clockid(int iters) { StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { android_log_clockid(); } StopBenchmarkTiming(); } BENCHMARK(BM_clockid); /* * Measure the time it takes for __android_log_security. */ static void BM_security(int iters) { StartBenchmarkTiming(); for (int i = 0; i < iters; ++i) { __android_log_security(); } StopBenchmarkTiming(); } BENCHMARK(BM_security);