/* * Copyright © 2014-2018 Intel Corporation * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS * IN THE SOFTWARE. * */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "igt.h" #define MB(x) ((uint64_t)(x) * 1024 * 1024) #ifndef PAGE_SIZE #define PAGE_SIZE 4096 #endif /* Currently the size of GuC log buffer is 19 pages & so is the size of relay * subbuffer. If the size changes in future, then this define also needs to be * updated accordingly. */ #define SUBBUF_SIZE (19*PAGE_SIZE) /* Need large buffering from logger side to hide the DISK IO latency, Driver * can only store 8 snapshots of GuC log buffer in relay. */ #define NUM_SUBBUFS 100 #define RELAY_FILE_NAME "guc_log" #define DEFAULT_OUTPUT_FILE_NAME "guc_log_dump.dat" #define CONTROL_FILE_NAME "i915_guc_log_control" char *read_buffer; char *out_filename; int poll_timeout = 2; /* by default 2ms timeout */ pthread_mutex_t mutex; pthread_t flush_thread; int verbosity_level = 3; /* by default capture logs at max verbosity */ uint32_t produced, consumed; uint64_t total_bytes_written; int num_buffers = NUM_SUBBUFS; int relay_fd, outfile_fd = -1; uint32_t test_duration, max_filesize; pthread_cond_t underflow_cond, overflow_cond; bool stop_logging, discard_oldlogs, capturing_stopped; static void guc_log_control(bool enable, uint32_t log_level) { int control_fd; char data[19]; uint64_t val; int ret; igt_assert_lte(log_level, 3); control_fd = igt_debugfs_open(-1, CONTROL_FILE_NAME, O_WRONLY); igt_assert_f(control_fd >= 0, "couldn't open the guc log control file\n"); /* * i915 expects GuC log level to be specified as: * 0: disabled * 1: enabled (verbosity level 0 = min) * 2: enabled (verbosity level 1) * 3: enabled (verbosity level 2) * 4: enabled (verbosity level 3 = max) */ val = enable ? log_level + 1 : 0; ret = snprintf(data, sizeof(data), "0x%" PRIx64, val); igt_assert(ret > 2 && ret < sizeof(data)); ret = write(control_fd, data, ret); igt_assert_f(ret > 0, "couldn't write to the log control file\n"); close(control_fd); } static void int_sig_handler(int sig) { igt_info("received signal %d\n", sig); stop_logging = true; } static void pull_leftover_data(void) { unsigned int bytes_read = 0; int ret; do { /* Read the logs from relay buffer */ ret = read(relay_fd, read_buffer, SUBBUF_SIZE); if (!ret) break; igt_assert_f(ret > 0, "failed to read from the guc log file\n"); igt_assert_f(ret == SUBBUF_SIZE, "invalid read from relay file\n"); bytes_read += ret; if (outfile_fd >= 0) { ret = write(outfile_fd, read_buffer, SUBBUF_SIZE); igt_assert_f(ret == SUBBUF_SIZE, "couldn't dump the logs in a file\n"); total_bytes_written += ret; } } while(1); igt_debug("%u bytes flushed\n", bytes_read); } static int num_filled_bufs(void) { return (produced - consumed); } static void pull_data(void) { char *ptr; int ret; pthread_mutex_lock(&mutex); while (num_filled_bufs() >= num_buffers) { igt_debug("overflow, will wait, produced %u, consumed %u\n", produced, consumed); /* Stall the main thread in case of overflow, as there are no * buffers available to store the new logs, otherwise there * could be corruption if both threads work on the same buffer. */ pthread_cond_wait(&overflow_cond, &mutex); }; pthread_mutex_unlock(&mutex); ptr = read_buffer + (produced % num_buffers) * SUBBUF_SIZE; /* Read the logs from relay buffer */ ret = read(relay_fd, ptr, SUBBUF_SIZE); igt_assert_f(ret >= 0, "failed to read from the guc log file\n"); igt_assert_f(!ret || ret == SUBBUF_SIZE, "invalid read from relay file\n"); if (ret) { pthread_mutex_lock(&mutex); produced++; pthread_cond_signal(&underflow_cond); pthread_mutex_unlock(&mutex); } else { /* Occasionally (very rare) read from the relay file returns no * data, albeit the polling done prior to read call indicated * availability of data. */ igt_debug("no data read from the relay file\n"); } } static void *flusher(void *arg) { char *ptr; int ret; igt_debug("execution started of flusher thread\n"); do { pthread_mutex_lock(&mutex); while (!num_filled_bufs()) { /* Exit only after completing the flush of all the filled * buffers as User would expect that all logs captured up * till the point of interruption/exit are written out to * the disk file. */ if (capturing_stopped) { igt_debug("flusher to exit now\n"); pthread_mutex_unlock(&mutex); return NULL; } pthread_cond_wait(&underflow_cond, &mutex); }; pthread_mutex_unlock(&mutex); ptr = read_buffer + (consumed % num_buffers) * SUBBUF_SIZE; ret = write(outfile_fd, ptr, SUBBUF_SIZE); igt_assert_f(ret == SUBBUF_SIZE, "couldn't dump the logs in a file\n"); total_bytes_written += ret; if (max_filesize && (total_bytes_written > MB(max_filesize))) { igt_debug("reached the target of %" PRIu64 " bytes\n", MB(max_filesize)); stop_logging = true; } pthread_mutex_lock(&mutex); consumed++; pthread_cond_signal(&overflow_cond); pthread_mutex_unlock(&mutex); } while(1); return NULL; } static void init_flusher_thread(void) { struct sched_param thread_sched; pthread_attr_t p_attr; int ret; pthread_cond_init(&underflow_cond, NULL); pthread_cond_init(&overflow_cond, NULL); pthread_mutex_init(&mutex, NULL); ret = pthread_attr_init(&p_attr); igt_assert_f(ret == 0, "error obtaining default thread attributes\n"); ret = pthread_attr_setinheritsched(&p_attr, PTHREAD_EXPLICIT_SCHED); igt_assert_f(ret == 0, "couldn't set inheritsched\n"); ret = pthread_attr_setschedpolicy(&p_attr, SCHED_RR); igt_assert_f(ret == 0, "couldn't set thread scheduling policy\n"); /* Keep the flusher task also at rt priority, so that it doesn't get * too late in flushing the collected logs in local buffers to the disk, * and so main thread always have spare buffers to collect the logs. */ thread_sched.sched_priority = 5; ret = pthread_attr_setschedparam(&p_attr, &thread_sched); igt_assert_f(ret == 0, "couldn't set thread priority\n"); ret = pthread_create(&flush_thread, &p_attr, flusher, NULL); igt_assert_f(ret == 0, "thread creation failed\n"); ret = pthread_attr_destroy(&p_attr); igt_assert_f(ret == 0, "error destroying thread attributes\n"); } static void open_relay_file(void) { relay_fd = igt_debugfs_open(-1, RELAY_FILE_NAME, O_RDONLY); igt_assert_f(relay_fd >= 0, "couldn't open the guc log file\n"); /* Purge the old/boot-time logs from the relay buffer. * This is more for Val team's requirement, where they have to first * purge the existing logs before starting the tests for which the logs * are actually needed. After this logger will enter into a loop and * wait for the new data, at that point benchmark can be launched from * a different shell. */ if (discard_oldlogs) pull_leftover_data(); } static void open_output_file(void) { /* Use Direct IO mode for the output file, as the data written is not * supposed to be accessed again, this saves a copy of data from App's * buffer to kernel buffer (Page cache). Due to no buffering on kernel * side, data is flushed out to disk faster and more buffering can be * done on the logger side to hide the disk IO latency. */ outfile_fd = open(out_filename ? : DEFAULT_OUTPUT_FILE_NAME, O_CREAT | O_WRONLY | O_TRUNC | O_DIRECT, 0440); igt_assert_f(outfile_fd >= 0, "couldn't open the output file\n"); free(out_filename); } static void init_main_thread(void) { struct sched_param thread_sched; int ret; /* Run the main thread at highest priority to ensure that it always * gets woken-up at earliest on arrival of new data and so is always * ready to pull the logs, otherwise there could be loss logs if * GuC firmware is generating logs at a very high rate. */ thread_sched.sched_priority = 1; ret = sched_setscheduler(getpid(), SCHED_FIFO, &thread_sched); igt_assert_f(ret == 0, "couldn't set the priority\n"); if (signal(SIGINT, int_sig_handler) == SIG_ERR) igt_assert_f(0, "SIGINT handler registration failed\n"); if (signal(SIGALRM, int_sig_handler) == SIG_ERR) igt_assert_f(0, "SIGALRM handler registration failed\n"); /* Need an aligned pointer for direct IO */ ret = posix_memalign((void **)&read_buffer, PAGE_SIZE, num_buffers * SUBBUF_SIZE); igt_assert_f(ret == 0, "couldn't allocate the read buffer\n"); /* Keep the pages locked in RAM, avoid page fault overhead */ ret = mlock(read_buffer, num_buffers * SUBBUF_SIZE); igt_assert_f(ret == 0, "failed to lock memory\n"); /* Enable the logging, it may not have been enabled from boot and so * the relay file also wouldn't have been created. */ guc_log_control(true, verbosity_level); open_relay_file(); open_output_file(); } static int parse_options(int opt, int opt_index, void *data) { igt_debug("opt %c optarg %s\n", opt, optarg); switch(opt) { case 'v': verbosity_level = atoi(optarg); igt_assert_f(verbosity_level >= 0 && verbosity_level <= 3, "invalid input for -v option\n"); igt_debug("verbosity level to be used is %d\n", verbosity_level); break; case 'o': out_filename = strdup(optarg); igt_assert_f(out_filename, "Couldn't allocate the o/p filename\n"); igt_debug("logs to be stored in file %s\n", out_filename); break; case 'b': num_buffers = atoi(optarg); igt_assert_f(num_buffers > 0, "invalid input for -b option\n"); igt_debug("number of buffers to be used is %d\n", num_buffers); break; case 't': test_duration = atoi(optarg); igt_assert_f(test_duration > 0, "invalid input for -t option\n"); igt_debug("logger to run for %d second\n", test_duration); break; case 'p': poll_timeout = atoi(optarg); igt_assert_f(poll_timeout != 0, "invalid input for -p option\n"); if (poll_timeout > 0) igt_debug("polling to be done with %d millisecond timeout\n", poll_timeout); break; case 's': max_filesize = atoi(optarg); igt_assert_f(max_filesize > 0, "invalid input for -s option\n"); igt_debug("max allowed size of the output file is %d MB\n", max_filesize); break; case 'd': discard_oldlogs = true; igt_debug("old/boot-time logs will be discarded\n"); break; } return 0; } static void process_command_line(int argc, char **argv) { static struct option long_options[] = { {"verbosity", required_argument, 0, 'v'}, {"outputfile", required_argument, 0, 'o'}, {"buffers", required_argument, 0, 'b'}, {"testduration", required_argument, 0, 't'}, {"polltimeout", required_argument, 0, 'p'}, {"size", required_argument, 0, 's'}, {"discard", no_argument, 0, 'd'}, { 0, 0, 0, 0 } }; const char *help = " -v --verbosity=level verbosity level of GuC logging (0-3)\n" " -o --outputfile=name name of the output file, including the location, where logs will be stored\n" " -b --buffers=num number of buffers to be maintained on logger side for storing logs\n" " -t --testduration=sec max duration in seconds for which the logger should run\n" " -p --polltimeout=ms polling timeout in ms, -1 == indefinite wait for the new data\n" " -s --size=MB max size of output file in MBs after which logging will be stopped\n" " -d --discard discard the old/boot-time logs before entering into the capture loop\n"; igt_simple_init_parse_opts(&argc, argv, "v:o:b:t:p:s:d", long_options, help, parse_options, NULL); } int main(int argc, char **argv) { struct pollfd relay_poll_fd; int nfds; int ret; process_command_line(argc, argv); init_main_thread(); /* Use a separate thread for flushing the logs to a file on disk. * Main thread will buffer the data from relay file in its pool of * buffers and other thread will flush the data to disk in background. * This is needed, albeit by default data is written out to disk in * async mode, as when there are too many dirty pages in the RAM, * (/proc/sys/vm/dirty_ratio), kernel starts blocking the processes * doing the file writes. */ init_flusher_thread(); relay_poll_fd.fd = relay_fd; relay_poll_fd.events = POLLIN; relay_poll_fd.revents = 0; nfds = 1; /* only one fd to poll */ alarm(test_duration); /* Start the alarm */ do { /* Wait/poll for the new data to be available, relay doesn't * provide a blocking read. * On older kernels need to do polling with a timeout instead of * indefinite wait to avoid relying on relay for the wakeup, as * relay used to do the wakeup in a deferred manner on jiffies * granularity by scheduling a timer and moreover that timer was * re-scheduled on every newly produced buffer and so was pushed * out if there were multiple flush interrupts in a very quick * succession (less than a jiffy gap between 2 flush interrupts) * causing relay to run out of sub buffers to store new logs. */ ret = poll(&relay_poll_fd, nfds, poll_timeout); if (ret < 0) { if (errno == EINTR) break; igt_assert_f(0, "poll call failed\n"); } /* No data available yet, poll again, hopefully new data is round the corner */ if (!relay_poll_fd.revents) continue; pull_data(); } while (!stop_logging); /* Pause logging on the GuC side */ guc_log_control(false, 0); /* Signal flusher thread to make an exit */ capturing_stopped = 1; pthread_cond_signal(&underflow_cond); pthread_join(flush_thread, NULL); pull_leftover_data(); igt_info("total bytes written %" PRIu64 "\n", total_bytes_written); free(read_buffer); close(relay_fd); close(outfile_fd); igt_exit(); }