/* Copyright (c) 2006-2012 Red Hat, Inc. This file is part of GlusterFS. This file is licensed to you under your choice of the GNU Lesser General Public License, version 3 or any later version (LGPLv3 or later), or the GNU General Public License, version 2 (GPLv2), in all cases as published by the Free Software Foundation. */ #include "xlator.h" #include "syscall.h" /** * xlators/debug/io_stats : * This translator maintains statistics of all filesystem activity * happening through it. The kind of statistics include: * * a) total read data - since process start, last interval and per fd * b) total write data - since process start, last interval and per fd * c) counts of read IO block size - since process start, last interval and per fd * d) counts of write IO block size - since process start, last interval and per fd * e) counts of all FOP types passing through it * * Usage: setfattr -n trusted.io-stats-dump /tmp/filename /mnt/gluster * output is written to /tmp/filename. * */ #include #include #include "glusterfs.h" #include "xlator.h" #include "io-stats-mem-types.h" #include #include "defaults.h" #include "logging.h" #include "cli1-xdr.h" #include "statedump.h" #include "syncop.h" #include #include #include "upcall-utils.h" #define MAX_LIST_MEMBERS 100 #define DEFAULT_PWD_BUF_SZ 16384 #define DEFAULT_GRP_BUF_SZ 16384 #define IOS_BLOCK_COUNT_SIZE 32 typedef enum { IOS_STATS_TYPE_NONE, IOS_STATS_TYPE_OPEN, IOS_STATS_TYPE_READ, IOS_STATS_TYPE_WRITE, IOS_STATS_TYPE_OPENDIR, IOS_STATS_TYPE_READDIRP, IOS_STATS_TYPE_READ_THROUGHPUT, IOS_STATS_TYPE_WRITE_THROUGHPUT, IOS_STATS_TYPE_MAX }ios_stats_type_t; typedef enum { IOS_STATS_THRU_READ, IOS_STATS_THRU_WRITE, IOS_STATS_THRU_MAX, }ios_stats_thru_t; struct ios_stat_lat { struct timeval time; double throughput; }; struct ios_stat { gf_lock_t lock; uuid_t gfid; char *filename; gf_atomic_t counters[IOS_STATS_TYPE_MAX]; struct ios_stat_lat thru_counters [IOS_STATS_THRU_MAX]; gf_atomic_t refcnt; }; struct ios_stat_list { struct list_head list; struct ios_stat *iosstat; double value; }; struct ios_stat_head { gf_lock_t lock; double min_cnt; uint64_t members; struct ios_stat_list *iosstats; }; typedef struct _ios_sample_t { uid_t uid; gid_t gid; char identifier[UNIX_PATH_MAX]; glusterfs_fop_t fop_type; struct timeval timestamp; double elapsed; } ios_sample_t; typedef struct _ios_sample_buf_t { uint64_t pos; /* Position in write buffer */ uint64_t size; /* Size of ring buffer */ uint64_t collected; /* Number of samples we've collected */ uint64_t observed; /* Number of FOPs we've observed */ ios_sample_t *ios_samples; /* Our list of samples */ } ios_sample_buf_t; struct ios_lat { double min; double max; double avg; uint64_t total; }; struct ios_global_stats { gf_atomic_t data_written; gf_atomic_t data_read; gf_atomic_t block_count_write[IOS_BLOCK_COUNT_SIZE]; gf_atomic_t block_count_read[IOS_BLOCK_COUNT_SIZE]; gf_atomic_t fop_hits[GF_FOP_MAXVALUE]; gf_atomic_t upcall_hits[GF_UPCALL_FLAGS_MAXVALUE]; struct timeval started_at; struct ios_lat latency[GF_FOP_MAXVALUE]; uint64_t nr_opens; uint64_t max_nr_opens; struct timeval max_openfd_time; }; typedef enum { IOS_DUMP_TYPE_NONE = 0, IOS_DUMP_TYPE_FILE = 1, IOS_DUMP_TYPE_DICT = 2, IOS_DUMP_TYPE_JSON_FILE = 3, IOS_DUMP_TYPE_SAMPLES = 4, IOS_DUMP_TYPE_MAX = 5 } ios_dump_type_t; struct ios_conf { gf_lock_t lock; struct ios_global_stats cumulative; uint64_t increment; struct ios_global_stats incremental; gf_boolean_t dump_fd_stats; gf_boolean_t count_fop_hits; gf_boolean_t measure_latency; struct ios_stat_head list[IOS_STATS_TYPE_MAX]; struct ios_stat_head thru_list[IOS_STATS_THRU_MAX]; int32_t ios_dump_interval; pthread_t dump_thread; gf_boolean_t dump_thread_should_die; gf_lock_t ios_sampling_lock; int32_t ios_sample_interval; int32_t ios_sample_buf_size; ios_sample_buf_t *ios_sample_buf; struct dnscache *dnscache; int32_t ios_dnscache_ttl_sec; /* * What we really need here is just a unique value to keep files * created by this instance distinct from those created by any other. * On the client side this isn't a problem, so we just use the * translator name. On the server side conflicts can occur, so the * volfile-generation code automatically sets this (via an option) * to be the brick path. * * NB While the *field* name has changed, it didn't seem worth changing * all of the cases where "xlator_name" is used as a *variable* name. */ char *unique_id; ios_dump_type_t dump_format; char *dump_format_str; }; struct ios_fd { char *filename; gf_atomic_t data_written; gf_atomic_t data_read; gf_atomic_t block_count_write[IOS_BLOCK_COUNT_SIZE]; gf_atomic_t block_count_read[IOS_BLOCK_COUNT_SIZE]; struct timeval opened_at; }; struct ios_dump_args { ios_dump_type_t type; union { FILE *logfp; dict_t *dict; } u; }; typedef int (*block_dump_func) (xlator_t *, struct ios_dump_args*, int , int , uint64_t ) ; struct ios_local { struct timeval wind_at; struct timeval unwind_at; }; struct volume_options options[]; static int is_fop_latency_started (call_frame_t *frame) { GF_ASSERT (frame); struct timeval epoch = {0,}; return memcmp (&frame->begin, &epoch, sizeof (epoch)); } #define _IOS_SAMP_DIR DEFAULT_LOG_FILE_DIRECTORY "/samples" #ifdef GF_LINUX_HOST_OS #define _IOS_DUMP_DIR DATADIR "/lib/glusterd/stats" #else #define _IOS_DUMP_DIR DATADIR "/db/glusterd/stats" #endif #define END_FOP_LATENCY(frame, op) \ do { \ struct ios_conf *conf = NULL; \ \ conf = this->private; \ if (conf && conf->measure_latency) { \ timespec_now (&frame->end); \ update_ios_latency (conf, frame, GF_FOP_##op); \ } \ } while (0) #define START_FOP_LATENCY(frame) \ do { \ struct ios_conf *conf = NULL; \ \ conf = this->private; \ if (conf && conf->measure_latency) { \ timespec_now (&frame->begin); \ } else { \ memset (&frame->begin, 0, sizeof (frame->begin));\ } \ } while (0) #define BUMP_FOP(op) \ do { \ struct ios_conf *conf = NULL; \ \ conf = this->private; \ if (!conf) \ break; \ GF_ATOMIC_INC (conf->cumulative.fop_hits[GF_FOP_##op]); \ GF_ATOMIC_INC (conf->incremental.fop_hits[GF_FOP_##op]);\ } while (0) #define UPDATE_PROFILE_STATS(frame, op) \ do { \ struct ios_conf *conf = NULL; \ \ if (!is_fop_latency_started (frame)) \ break; \ conf = this->private; \ if (conf && conf->measure_latency && \ conf->count_fop_hits) { \ BUMP_FOP (op); \ timespec_now (&frame->end); \ update_ios_latency (conf, frame, GF_FOP_##op); \ } \ } while (0) #define BUMP_THROUGHPUT(iosstat, type) \ do { \ struct ios_conf *conf = NULL; \ double elapsed; \ struct timespec *begin, *end; \ double throughput; \ int flag = 0; \ \ begin = &frame->begin; \ end = &frame->end; \ \ elapsed = ((end->tv_sec - begin->tv_sec) * 1e9 \ + (end->tv_nsec - begin->tv_nsec)) / 1000; \ throughput = op_ret / elapsed; \ \ conf = this->private; \ LOCK (&iosstat->lock); \ { \ if (iosstat->thru_counters[type].throughput \ <= throughput) { \ iosstat->thru_counters[type].throughput = \ throughput; \ gettimeofday (&iosstat-> \ thru_counters[type].time, NULL); \ flag = 1; \ } \ } \ UNLOCK (&iosstat->lock); \ if (flag) \ ios_stat_add_to_list (&conf->thru_list[type], \ throughput, iosstat); \ } while (0) static int ios_fd_ctx_get (fd_t *fd, xlator_t *this, struct ios_fd **iosfd) { uint64_t iosfd64 = 0; unsigned long iosfdlong = 0; int ret = 0; ret = fd_ctx_get (fd, this, &iosfd64); iosfdlong = iosfd64; if (ret != -1) *iosfd = (void *) iosfdlong; return ret; } static int ios_fd_ctx_set (fd_t *fd, xlator_t *this, struct ios_fd *iosfd) { uint64_t iosfd64 = 0; int ret = 0; iosfd64 = (unsigned long) iosfd; ret = fd_ctx_set (fd, this, iosfd64); return ret; } static int ios_stat_ref (struct ios_stat *iosstat) { uint64_t refcnt = 0; refcnt = GF_ATOMIC_INC (iosstat->refcnt); return refcnt; } static int ios_stat_unref (struct ios_stat *iosstat) { int cleanup = 0; uint64_t refcnt = 0; refcnt = GF_ATOMIC_DEC (iosstat->refcnt); if (refcnt == 0) { if (iosstat->filename) { GF_FREE (iosstat->filename); iosstat->filename = NULL; } cleanup = 1; } if (cleanup) { LOCK_DESTROY (&iosstat->lock); GF_FREE (iosstat); iosstat = NULL; } return 0; } static int ios_stat_add_to_list (struct ios_stat_head *list_head, uint64_t value, struct ios_stat *iosstat) { struct ios_stat_list *new = NULL; struct ios_stat_list *entry = NULL; struct ios_stat_list *t = NULL; struct ios_stat_list *list_entry = NULL; struct ios_stat_list *tmp = NULL; struct ios_stat_list *last = NULL; struct ios_stat *stat = NULL; int cnt = 0; int found = 0; int reposition = 0; double min_count = 0; LOCK (&list_head->lock); { if (list_head->min_cnt == 0) list_head->min_cnt = value; if ((list_head->members == MAX_LIST_MEMBERS) && (list_head->min_cnt > value)) goto out; list_for_each_entry_safe (entry, t, &list_head->iosstats->list, list) { cnt++; if (cnt == list_head->members) last = entry; if (!gf_uuid_compare (iosstat->gfid, entry->iosstat->gfid)) { list_entry = entry; found = cnt; entry->value = value; if (!reposition) { if (cnt == list_head->members) list_head->min_cnt = value; goto out; } break; } else if (entry->value <= value && !reposition) { reposition = cnt; tmp = entry; if (cnt == list_head->members - 1) min_count = entry->value; } } if (found) { list_del (&list_entry->list); list_add_tail (&list_entry->list, &tmp->list); if (min_count) list_head->min_cnt = min_count; goto out; } else if (list_head->members == MAX_LIST_MEMBERS && reposition) { new = GF_CALLOC (1, sizeof (*new), gf_io_stats_mt_ios_stat_list); new->iosstat = iosstat; new->value = value; ios_stat_ref (iosstat); list_add_tail (&new->list, &tmp->list); if (last) { stat = last->iosstat; last->iosstat = NULL; ios_stat_unref (stat); list_del (&last->list); GF_FREE (last); } if (reposition == MAX_LIST_MEMBERS) list_head->min_cnt = value; else if (min_count) { list_head->min_cnt = min_count; } } else if (list_head->members < MAX_LIST_MEMBERS) { new = GF_CALLOC (1, sizeof (*new), gf_io_stats_mt_ios_stat_list); new->iosstat = iosstat; new->value = value; ios_stat_ref (iosstat); if (reposition) { list_add_tail (&new->list, &tmp->list); } else { list_add_tail (&new->list, &entry->list); } list_head->members++; if (list_head->min_cnt > value) list_head->min_cnt = value; } } out: UNLOCK (&list_head->lock); return 0; } static void ios_bump_read (xlator_t *this, fd_t *fd, size_t len) { struct ios_conf *conf = NULL; struct ios_fd *iosfd = NULL; int lb2 = 0; conf = this->private; lb2 = log_base2 (len); ios_fd_ctx_get (fd, this, &iosfd); if (!conf) return; GF_ATOMIC_ADD (conf->cumulative.data_read, len); GF_ATOMIC_ADD (conf->incremental.data_read, len); GF_ATOMIC_INC (conf->cumulative.block_count_read[lb2]); GF_ATOMIC_INC (conf->incremental.block_count_read[lb2]); if (iosfd) { GF_ATOMIC_ADD (iosfd->data_read, len); GF_ATOMIC_INC (iosfd->block_count_read[lb2]); } } static void ios_bump_write (xlator_t *this, fd_t *fd, size_t len) { struct ios_conf *conf = NULL; struct ios_fd *iosfd = NULL; int lb2 = 0; conf = this->private; lb2 = log_base2 (len); ios_fd_ctx_get (fd, this, &iosfd); if (!conf) return; GF_ATOMIC_ADD (conf->cumulative.data_written, len); GF_ATOMIC_ADD (conf->incremental.data_written, len); GF_ATOMIC_INC (conf->cumulative.block_count_write[lb2]); GF_ATOMIC_INC (conf->incremental.block_count_write[lb2]); if (iosfd) { GF_ATOMIC_ADD (iosfd->data_written, len); GF_ATOMIC_INC (iosfd->block_count_write[lb2]); } } static void ios_bump_upcall (xlator_t *this, gf_upcall_flags_t event) { struct ios_conf *conf = NULL; conf = this->private; if (!conf) return; if (conf->count_fop_hits) { GF_ATOMIC_INC (conf->cumulative.upcall_hits[event]); GF_ATOMIC_INC (conf->incremental.upcall_hits[event]); } } static void ios_bump_stats (xlator_t *this, struct ios_stat *iosstat, ios_stats_type_t type) { struct ios_conf *conf = NULL; uint64_t value = 0; conf = this->private; value = GF_ATOMIC_INC (iosstat->counters[type]); ios_stat_add_to_list (&conf->list[type], value, iosstat); } int ios_inode_ctx_set (inode_t *inode, xlator_t *this, struct ios_stat *iosstat) { uint64_t iosstat64 = 0; int ret = 0; ios_stat_ref (iosstat); iosstat64 = (unsigned long) iosstat; ret = inode_ctx_put (inode, this, iosstat64); return ret; } int ios_inode_ctx_get (inode_t *inode, xlator_t *this, struct ios_stat **iosstat) { uint64_t iosstat64 = 0; unsigned long iosstatlong = 0; int ret = 0; ret = inode_ctx_get (inode, this, &iosstat64); iosstatlong = iosstat64; if (ret != -1) *iosstat = (void *) iosstatlong; return ret; } /* * So why goto all this trouble? Why not just queue up some samples in * a big list and malloc away? Well malloc is expensive relative * to what we are measuring, so cannot have any malloc's (or worse * callocs) in our measurement code paths. Instead, we are going to * pre-allocate a circular buffer and collect a maximum number of samples. * Prior to dumping them all we'll create a new buffer and swap the * old buffer with the new, and then proceed to dump the statistics * in our dump thread. * */ ios_sample_buf_t * ios_create_sample_buf (size_t buf_size) { ios_sample_buf_t *ios_sample_buf = NULL; ios_sample_t *ios_samples = NULL; ios_sample_buf = GF_CALLOC (1, sizeof (*ios_sample_buf), gf_io_stats_mt_ios_sample_buf); if (!ios_sample_buf) goto err; ios_samples = GF_CALLOC (buf_size, sizeof (*ios_samples), gf_io_stats_mt_ios_sample); if (!ios_samples) goto err; ios_sample_buf->ios_samples = ios_samples; ios_sample_buf->size = buf_size; ios_sample_buf->pos = 0; ios_sample_buf->observed = 0; ios_sample_buf->collected = 0; return ios_sample_buf; err: GF_FREE (ios_sample_buf); return NULL; } void ios_destroy_sample_buf (ios_sample_buf_t *ios_sample_buf) { GF_FREE (ios_sample_buf->ios_samples); GF_FREE (ios_sample_buf); } static int ios_init_sample_buf (struct ios_conf *conf) { int32_t ret = -1; GF_ASSERT (conf); LOCK (&conf->lock); conf->ios_sample_buf = ios_create_sample_buf ( conf->ios_sample_buf_size); if (!conf->ios_sample_buf) goto out; ret = 0; out: UNLOCK (&conf->lock); return ret; } static int ios_stats_cleanup (xlator_t *this, inode_t *inode) { struct ios_stat *iosstat = NULL; uint64_t iosstat64 = 0; inode_ctx_del (inode, this, &iosstat64); if (!iosstat64) { gf_log (this->name, GF_LOG_WARNING, "could not get inode ctx"); return 0; } iosstat = (void *) (long)iosstat64; if (iosstat) { ios_stat_unref (iosstat); } return 0; } #define ios_log(this, logfp, fmt ...) \ do { \ if (logfp) { \ fprintf (logfp, fmt); \ fprintf (logfp, "\n"); \ } \ gf_log (this->name, GF_LOG_DEBUG, fmt); \ } while (0) int ios_dump_file_stats (struct ios_stat_head *list_head, xlator_t *this, FILE *logfp) { struct ios_stat_list *entry = NULL; LOCK (&list_head->lock); { list_for_each_entry (entry, &list_head->iosstats->list, list) { ios_log (this, logfp, "%-12.0f %s", entry->value, entry->iosstat->filename); } } UNLOCK (&list_head->lock); return 0; } int ios_dump_throughput_stats (struct ios_stat_head *list_head, xlator_t *this, FILE *logfp, ios_stats_thru_t type) { struct ios_stat_list *entry = NULL; struct timeval time = {0, }; char timestr[256] = {0, }; LOCK (&list_head->lock); { list_for_each_entry (entry, &list_head->iosstats->list, list) { gf_time_fmt (timestr, sizeof timestr, entry->iosstat->thru_counters[type].time.tv_sec, gf_timefmt_FT); snprintf (timestr + strlen (timestr), sizeof timestr - strlen (timestr), ".%"GF_PRI_SUSECONDS, time.tv_usec); ios_log (this, logfp, "%s \t %-10.2f \t %s", timestr, entry->value, entry->iosstat->filename); } } UNLOCK (&list_head->lock); return 0; } int _io_stats_get_key_prefix (xlator_t *this, char **key_prefix) { char *key_root = "gluster"; char *xlator_name = NULL; char *instance_name = NULL; size_t key_len = 0; int bytes_written = 0; int i = 0; int ret = 0; struct ios_conf *conf = this->private; xlator_name = strdupa (conf->unique_id); for (i = 0; i < strlen (xlator_name); i++) { if (xlator_name[i] == '/') xlator_name[i] = '_'; } instance_name = this->instance_name; if (this->name && strcmp (this->name, "glustershd") == 0) { xlator_name = "shd"; } else if (this->prev && strcmp (this->prev->name, "nfs-server") == 0) { xlator_name = "nfsd"; if (this->prev->instance_name) instance_name = strdupa (this->prev->instance_name); } if (strcmp (__progname, "glusterfsd") == 0) key_root = "gluster.brick"; if (instance_name) { /* +3 for 2 x "." + NULL */ key_len = strlen (key_root) + strlen (xlator_name) + strlen (instance_name) + 3; *key_prefix = GF_CALLOC (key_len, sizeof (char), gf_common_mt_char); if (!*key_prefix) { ret = -ENOMEM; goto err; } bytes_written = snprintf (*key_prefix, key_len, "%s.%s.%s", key_root, xlator_name, instance_name); if (bytes_written != key_len - 1) { ret = -EINVAL; goto err; } } else { /* +2 for 1 x "." + NULL */ key_len = strlen (key_root) + strlen (xlator_name) + 2; *key_prefix = GF_CALLOC (key_len, sizeof (char), gf_common_mt_char); if (!*key_prefix) { ret = -ENOMEM; goto err; } bytes_written = snprintf (*key_prefix, key_len, "%s.%s", key_root, xlator_name); if (bytes_written != key_len - 1) { ret = -EINVAL; goto err; } } return 0; err: GF_FREE (*key_prefix); *key_prefix = NULL; return ret; } int io_stats_dump_global_to_json_logfp (xlator_t *this, struct ios_global_stats *stats, struct timeval *now, int interval, FILE *logfp) { int i = 0; int j = 0; struct ios_conf *conf = NULL; char *key_prefix = NULL; char *str_prefix = NULL; char *lc_fop_name = NULL; int ret = 1; /* Default to error */ int rw_size; char *rw_unit = NULL; uint64_t fop_hits; float fop_lat_ave; float fop_lat_min; float fop_lat_max; double interval_sec; double fop_ave_usec = 0.0; double fop_ave_usec_sum = 0.0; double weighted_fop_ave_usec = 0.0; double weighted_fop_ave_usec_sum = 0.0; long total_fop_hits = 0; loc_t unused_loc = {0, }; dict_t *xattr = NULL; interval_sec = ((now->tv_sec * 1000000.0 + now->tv_usec) - (stats->started_at.tv_sec * 1000000.0 + stats->started_at.tv_usec)) / 1000000.0; conf = this->private; ret = _io_stats_get_key_prefix (this, &key_prefix); if (ret) { goto out; } if (interval == -1) { str_prefix = "aggr"; } else { str_prefix = "inter"; } ios_log (this, logfp, "{"); for (i = 0; i < 31; i++) { rw_size = (1 << i); if (rw_size >= 1024 * 1024) { rw_size = rw_size / (1024 * 1024); rw_unit = "mb"; } else if (rw_size >= 1024) { rw_size = rw_size / 1024; rw_unit = "kb"; } else { rw_unit = "b"; } if (interval == -1) { ios_log (this, logfp, "\"%s.%s.read_%d%s\": \"%"GF_PRI_ATOMIC"\",", key_prefix, str_prefix, rw_size, rw_unit, GF_ATOMIC_GET (stats->block_count_read[i])); ios_log (this, logfp, "\"%s.%s.write_%d%s\": \"%"GF_PRI_ATOMIC"\",", key_prefix, str_prefix, rw_size, rw_unit, GF_ATOMIC_GET (stats->block_count_write[i])); } else { ios_log (this, logfp, "\"%s.%s.read_%d%s_per_sec\": \"%0.2lf\",", key_prefix, str_prefix, rw_size, rw_unit, (double) (GF_ATOMIC_GET (stats->block_count_read[i]) / interval_sec)); ios_log (this, logfp, "\"%s.%s.write_%d%s_per_sec\": \"%0.2lf\",", key_prefix, str_prefix, rw_size, rw_unit, (double) (GF_ATOMIC_GET (stats->block_count_write[i]) / interval_sec)); } } if (interval == -1) { ios_log (this, logfp, "\"%s.%s.fds.open_count\": \"%"PRId64 "\",", key_prefix, str_prefix, conf->cumulative.nr_opens); ios_log (this, logfp, "\"%s.%s.fds.max_open_count\": \"%"PRId64"\",", key_prefix, str_prefix, conf->cumulative.max_nr_opens); } for (i = 0; i < GF_FOP_MAXVALUE; i++) { lc_fop_name = strdupa (gf_fop_list[i]); for (j = 0; lc_fop_name[j]; j++) { lc_fop_name[j] = tolower (lc_fop_name[j]); } fop_hits = GF_ATOMIC_GET (stats->fop_hits[i]); fop_lat_ave = 0.0; fop_lat_min = 0.0; fop_lat_max = 0.0; if (fop_hits) { if (stats->latency[i].avg) { fop_lat_ave = stats->latency[i].avg; fop_lat_min = stats->latency[i].min; fop_lat_max = stats->latency[i].max; } } if (interval == -1) { ios_log (this, logfp, "\"%s.%s.fop.%s.count\": \"%"GF_PRI_ATOMIC"\",", key_prefix, str_prefix, lc_fop_name, fop_hits); } else { ios_log (this, logfp, "\"%s.%s.fop.%s.per_sec\": \"%0.2lf\",", key_prefix, str_prefix, lc_fop_name, (double)(fop_hits / interval_sec)); } ios_log (this, logfp, "\"%s.%s.fop.%s.latency_ave_usec\": \"%0.2lf\",", key_prefix, str_prefix, lc_fop_name, fop_lat_ave); ios_log (this, logfp, "\"%s.%s.fop.%s.latency_min_usec\": \"%0.2lf\",", key_prefix, str_prefix, lc_fop_name, fop_lat_min); ios_log (this, logfp, "\"%s.%s.fop.%s.latency_max_usec\": \"%0.2lf\",", key_prefix, str_prefix, lc_fop_name, fop_lat_max); fop_ave_usec_sum += fop_lat_ave; weighted_fop_ave_usec_sum += fop_hits * fop_lat_ave; total_fop_hits += fop_hits; } if (total_fop_hits) { weighted_fop_ave_usec = weighted_fop_ave_usec_sum/total_fop_hits; /* Extra key that does not print out an entry w/ 0.00 for * intervals with no data */ ios_log (this, logfp, "\"%s.%s.fop.weighted_latency_ave_usec_nozerofill\": " "\"%0.4lf\",", key_prefix, str_prefix, weighted_fop_ave_usec); } ios_log (this, logfp, "\"%s.%s.fop.weighted_latency_ave_usec\": \"%0.4lf\",", key_prefix, str_prefix, weighted_fop_ave_usec); ios_log (this, logfp, "\"%s.%s.fop.weighted_fop_count\": \"%ld\",", key_prefix, str_prefix, total_fop_hits); fop_ave_usec = fop_ave_usec_sum/GF_FOP_MAXVALUE; ios_log (this, logfp, "\"%s.%s.fop.unweighted_latency_ave_usec\":\"%0.4lf\",", key_prefix, str_prefix, fop_ave_usec); for (i = 0; i < GF_UPCALL_FLAGS_MAXVALUE; i++) { lc_fop_name = strdupa (gf_upcall_list[i]); for (j = 0; lc_fop_name[j]; j++) { lc_fop_name[j] = tolower (lc_fop_name[j]); } fop_hits = GF_ATOMIC_GET (stats->upcall_hits[i]); if (interval == -1) { ios_log (this, logfp, "\"%s.%s.fop.%s.count\": \"%"GF_PRI_ATOMIC"\",", key_prefix, str_prefix, lc_fop_name, fop_hits); } else { ios_log (this, logfp, "\"%s.%s.fop.%s.per_sec\": \"%0.2lf\",", key_prefix, str_prefix, lc_fop_name, (double)(fop_hits / interval_sec)); } } ret = syncop_getxattr (this, &unused_loc, &xattr, IO_THREADS_QUEUE_SIZE_KEY, NULL, NULL); if (xattr) { /* * Iterate over the dictionary returned to us by io-threads and * dump the results to the stats file. */ data_pair_t *curr = NULL; dict_foreach_inline (xattr, curr) { ios_log (this, logfp, "\"%s.%s.%s.queue_size\": \"%d\",", key_prefix, str_prefix, curr->key, data_to_int32 (curr->value)); } /* Free the dictionary */ dict_unref (xattr); } else { gf_log (this->name, GF_LOG_WARNING, "Unable to get queue size counts from " "the io-threads translator!"); } if (interval == -1) { ios_log (this, logfp, "\"%s.%s.uptime\": \"%"PRId64"\",", key_prefix, str_prefix, (uint64_t) (now->tv_sec - stats->started_at.tv_sec)); ios_log (this, logfp, "\"%s.%s.bytes_read\": \"" "%"GF_PRI_ATOMIC"\",", key_prefix, str_prefix, GF_ATOMIC_GET (stats->data_read)); ios_log (this, logfp, "\"%s.%s.bytes_written\": \"" "%"GF_PRI_ATOMIC"\"", key_prefix, str_prefix, GF_ATOMIC_GET (stats->data_written)); } else { ios_log (this, logfp, "\"%s.%s.sample_interval_sec\": \"%0.2lf\",", key_prefix, str_prefix, interval_sec); ios_log (this, logfp, "\"%s.%s.bytes_read_per_sec\": \"%0.2lf\",", key_prefix, str_prefix, (double) (GF_ATOMIC_GET (stats->data_read) / interval_sec)); ios_log (this, logfp, "\"%s.%s.bytes_written_per_sec\": \"%0.2lf\"", key_prefix, str_prefix, (double) (GF_ATOMIC_GET (stats->data_written) / interval_sec)); } ios_log (this, logfp, "}"); ret = 0; out: GF_FREE (key_prefix); return ret; } char * _resolve_username (xlator_t *this, uid_t uid) { struct passwd pwd; struct passwd *pwd_result = NULL; size_t pwd_buf_len; char *pwd_buf = NULL; char *ret = NULL; /* Prepare our buffer for the uid->username translation */ #ifdef _SC_GETGR_R_SIZE_MAX pwd_buf_len = sysconf (_SC_GETGR_R_SIZE_MAX); #else pwd_buf_len = -1; #endif if (pwd_buf_len == -1) { pwd_buf_len = DEFAULT_PWD_BUF_SZ; /* per the man page */ } pwd_buf = alloca (pwd_buf_len); if (!pwd_buf) goto err; getpwuid_r (uid, &pwd, pwd_buf, pwd_buf_len, &pwd_result); if (!pwd_result) goto err; ret = gf_strdup (pwd.pw_name); if (ret) return ret; else gf_log (this->name, GF_LOG_ERROR, "gf_strdup failed, failing username " "resolution."); err: return ret; } char * _resolve_group_name (xlator_t *this, gid_t gid) { struct group grp; struct group *grp_result = NULL; size_t grp_buf_len; char *grp_buf = NULL; char *ret = NULL; /* Prepare our buffer for the gid->group name translation */ #ifdef _SC_GETGR_R_SIZE_MAX grp_buf_len = sysconf (_SC_GETGR_R_SIZE_MAX); #else grp_buf_len = -1; #endif if (grp_buf_len == -1) { grp_buf_len = DEFAULT_GRP_BUF_SZ; /* per the man page */ } grp_buf = alloca (grp_buf_len); if (!grp_buf) { goto err; } if (getgrgid_r (gid, &grp, grp_buf, grp_buf_len, &grp_result) != 0) goto err; if (!grp_result) goto err; ret = gf_strdup (grp.gr_name); if (ret) return ret; else gf_log (this->name, GF_LOG_ERROR, "gf_strdup failed, failing username " "resolution."); err: return ret; } /* * This function writes out a latency sample to a given file descriptor * and beautifies the output in the process. */ void _io_stats_write_latency_sample (xlator_t *this, ios_sample_t *sample, FILE *logfp) { double epoch_time = 0.00; char *xlator_name = NULL; char *instance_name = NULL; char *hostname = NULL; char *identifier = NULL; char *port = NULL; char *port_pos = NULL; char *group_name = NULL; char *username = NULL; struct ios_conf *conf = NULL; conf = this->private; epoch_time = (sample->timestamp).tv_sec + ((sample->timestamp).tv_usec / 1000000.0); if (strlen (sample->identifier) == 0) { hostname = "Unknown"; port = "Unknown"; } else { identifier = strdupa (sample->identifier); port_pos = strrchr (identifier, ':'); if (!port_pos || strlen(port_pos) < 2) goto err; port = strdupa (port_pos + 1); if (!port) goto err; *port_pos = '\0'; hostname = gf_rev_dns_lookup_cached (identifier, conf->dnscache); if (!hostname) hostname = "Unknown"; } xlator_name = conf->unique_id; if (!xlator_name || strlen (xlator_name) == 0) xlator_name = "Unknown"; instance_name = this->instance_name; if (!instance_name || strlen (instance_name) == 0) instance_name = "N/A"; /* Resolve the UID to a string username */ username = _resolve_username (this, sample->uid); if (!username) { username = GF_MALLOC (30, gf_common_mt_char); if (!username) { goto out; } sprintf (username, "%d", (int32_t)sample->uid); } /* Resolve the GID to a string group name */ group_name = _resolve_group_name (this, sample->gid); if (!group_name) { group_name = GF_MALLOC (30, gf_common_mt_char); if (!group_name) { goto out; } sprintf (group_name, "%d", (int32_t)sample->gid); } ios_log (this, logfp, "%0.6lf,%s,%s,%0.4lf,%s,%s,%s,%s,%s,%s", epoch_time, fop_enum_to_pri_string (sample->fop_type), gf_fop_string (sample->fop_type), sample->elapsed, xlator_name, instance_name, username, group_name, hostname, port); goto out; err: gf_log (this->name, GF_LOG_ERROR, "Error parsing socket identifier"); out: GF_FREE (group_name); GF_FREE (username); } /* * Takes our current sample buffer in conf->io_sample_buf, and saves * a reference to this, init's a new buffer, and then dumps out the * contents of the saved reference. */ int io_stats_dump_latency_samples_logfp (xlator_t *this, FILE *logfp) { uint64_t i = 0; struct ios_conf *conf = NULL; ios_sample_buf_t *sample_buf = NULL; int ret = 1; /* Default to error */ conf = this->private; /* Save pointer to old buffer; the CS equivalent of * Indiana Jones: https://www.youtube.com/watch?v=Pr-8AP0To4k, * though ours will end better I hope! */ sample_buf = conf->ios_sample_buf; if (!sample_buf) { gf_log (this->name, GF_LOG_WARNING, "Sampling buffer is null, bailing!"); goto out; } /* Empty case, nothing to do, exit. */ if (sample_buf->collected == 0) { gf_log (this->name, GF_LOG_DEBUG, "No samples, dump not required."); ret = 0; goto out; } /* Init a new buffer, so we are free to work on the one we saved a * reference to above. */ if (ios_init_sample_buf (conf) != 0) { gf_log (this->name, GF_LOG_WARNING, "Failed to init new sampling buffer, out of memory?"); goto out; } /* Wrap-around case, dump from pos to sample_buf->size -1 * and then from 0 to sample_buf->pos (covered off by * "simple case") */ if (sample_buf->collected > sample_buf->pos + 1) { for (i = sample_buf->pos; i < sample_buf->size; i++) { _io_stats_write_latency_sample (this, &(sample_buf->ios_samples[i]), logfp); } } /* Simple case: Dump from 0 to sample_buf->pos */ for (i = 0; i < sample_buf->pos; i++) { _io_stats_write_latency_sample (this, &(sample_buf->ios_samples[i]), logfp); } ios_destroy_sample_buf (sample_buf); out: return ret; } int io_stats_dump_global_to_logfp (xlator_t *this, struct ios_global_stats *stats, struct timeval *now, int interval, FILE *logfp) { int i = 0; int per_line = 0; int index = 0; struct ios_stat_head *list_head = NULL; struct ios_conf *conf = NULL; char timestr[256] = {0, }; char str_header[128] = {0}; char str_read[128] = {0}; char str_write[128] = {0}; uint64_t fop_hits = 0; uint64_t block_count_read = 0; uint64_t block_count_write = 0; conf = this->private; if (interval == -1) ios_log (this, logfp, "\n=== Cumulative stats ==="); else ios_log (this, logfp, "\n=== Interval %d stats ===", interval); ios_log (this, logfp, " Duration : %"PRId64" secs", (uint64_t) (now->tv_sec - stats->started_at.tv_sec)); ios_log (this, logfp, " BytesRead : %"GF_PRI_ATOMIC, GF_ATOMIC_GET (stats->data_read)); ios_log (this, logfp, " BytesWritten : %"GF_PRI_ATOMIC"\n", GF_ATOMIC_GET (stats->data_written)); snprintf (str_header, sizeof (str_header), "%-12s %c", "Block Size", ':'); snprintf (str_read, sizeof (str_read), "%-12s %c", "Read Count", ':'); snprintf (str_write, sizeof (str_write), "%-12s %c", "Write Count", ':'); index = 14; for (i = 0; i < IOS_BLOCK_COUNT_SIZE; i++) { block_count_read = GF_ATOMIC_GET (stats->block_count_read[i]); block_count_write = GF_ATOMIC_GET (stats->block_count_write[i]); if ((block_count_read == 0) && (block_count_write == 0)) continue; per_line++; snprintf (str_header+index, sizeof (str_header)-index, "%16dB+", (1<fop_hits[i]); if (fop_hits && !stats->latency[i].avg) ios_log (this, logfp, "%-13s %10"GF_PRI_ATOMIC" %11s " "us %11s us %11s us", gf_fop_list[i], fop_hits, "0", "0", "0"); else if (fop_hits && stats->latency[i].avg) ios_log (this, logfp, "%-13s %10"GF_PRI_ATOMIC" " "%11.2lf us %11.2lf us %11.2lf us", gf_fop_list[i], fop_hits, stats->latency[i].avg, stats->latency[i].min, stats->latency[i].max); } for (i = 0; i < GF_UPCALL_FLAGS_MAXVALUE; i++) { fop_hits = GF_ATOMIC_GET (stats->upcall_hits[i]); if (fop_hits) ios_log (this, logfp, "%-13s %10"PRId64" %11s " "us %11s us %11s us", gf_upcall_list[i], fop_hits, "0", "0", "0"); } ios_log (this, logfp, "------ ----- ----- ----- ----- ----- ----- ----- " " ----- ----- ----- -----\n"); if (interval == -1) { LOCK (&conf->lock); { gf_time_fmt (timestr, sizeof timestr, conf->cumulative.max_openfd_time.tv_sec, gf_timefmt_FT); snprintf (timestr + strlen (timestr), sizeof timestr - strlen (timestr), ".%"GF_PRI_SUSECONDS, conf->cumulative.max_openfd_time.tv_usec); ios_log (this, logfp, "Current open fd's: %"PRId64 " Max open fd's: %"PRId64" time %s", conf->cumulative.nr_opens, conf->cumulative.max_nr_opens, timestr); } UNLOCK (&conf->lock); ios_log (this, logfp, "\n==========Open File Stats========"); ios_log (this, logfp, "\nCOUNT: \t FILE NAME"); list_head = &conf->list[IOS_STATS_TYPE_OPEN]; ios_dump_file_stats (list_head, this, logfp); ios_log (this, logfp, "\n==========Read File Stats========"); ios_log (this, logfp, "\nCOUNT: \t FILE NAME"); list_head = &conf->list[IOS_STATS_TYPE_READ]; ios_dump_file_stats (list_head, this, logfp); ios_log (this, logfp, "\n==========Write File Stats========"); ios_log (this, logfp, "\nCOUNT: \t FILE NAME"); list_head = &conf->list[IOS_STATS_TYPE_WRITE]; ios_dump_file_stats (list_head, this, logfp); ios_log (this, logfp, "\n==========Directory open stats========"); ios_log (this, logfp, "\nCOUNT: \t DIRECTORY NAME"); list_head = &conf->list[IOS_STATS_TYPE_OPENDIR]; ios_dump_file_stats (list_head, this, logfp); ios_log (this, logfp, "\n========Directory readdirp Stats======="); ios_log (this, logfp, "\nCOUNT: \t DIRECTORY NAME"); list_head = &conf->list[IOS_STATS_TYPE_READDIRP]; ios_dump_file_stats (list_head, this, logfp); ios_log (this, logfp, "\n========Read Throughput File Stats====="); ios_log (this, logfp, "\nTIMESTAMP \t\t\t THROUGHPUT(KBPS)" "\tFILE NAME"); list_head = &conf->thru_list[IOS_STATS_THRU_READ]; ios_dump_throughput_stats(list_head, this, logfp, IOS_STATS_THRU_READ); ios_log (this, logfp, "\n======Write Throughput File Stats======"); ios_log (this, logfp, "\nTIMESTAMP \t\t\t THROUGHPUT(KBPS)" "\tFILE NAME"); list_head = &conf->thru_list[IOS_STATS_THRU_WRITE]; ios_dump_throughput_stats (list_head, this, logfp, IOS_STATS_THRU_WRITE); } return 0; } int io_stats_dump_global_to_dict (xlator_t *this, struct ios_global_stats *stats, struct timeval *now, int interval, dict_t *dict) { int ret = 0; char key[256] = {0}; uint64_t sec = 0; int i = 0; uint64_t count = 0; uint64_t fop_hits = 0; GF_ASSERT (stats); GF_ASSERT (now); GF_ASSERT (dict); GF_ASSERT (this); if (interval == -1) snprintf (key, sizeof (key), "cumulative"); else snprintf (key, sizeof (key), "interval"); ret = dict_set_int32 (dict, key, interval); if (ret) gf_log (this->name, GF_LOG_ERROR, "failed to set " "interval %d", interval); memset (key, 0, sizeof (key)); snprintf (key, sizeof (key), "%d-duration", interval); sec = (uint64_t) (now->tv_sec - stats->started_at.tv_sec); ret = dict_set_uint64 (dict, key, sec); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set " "duration(%d) - %"PRId64, interval, sec); goto out; } memset (key, 0, sizeof (key)); snprintf (key, sizeof (key), "%d-total-read", interval); ret = dict_set_uint64 (dict, key, GF_ATOMIC_GET (stats->data_read)); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set total " "read(%d) - %"GF_PRI_ATOMIC, interval, GF_ATOMIC_GET (stats->data_read)); goto out; } memset (key, 0, sizeof (key)); snprintf (key, sizeof (key), "%d-total-write", interval); ret = dict_set_uint64 (dict, key, GF_ATOMIC_GET (stats->data_written)); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set total " "write(%d) - %"GF_PRI_ATOMIC, interval, GF_ATOMIC_GET (stats->data_written)); goto out; } for (i = 0; i < 32; i++) { count = GF_ATOMIC_GET (stats->block_count_read[i]); if (count) { memset (key, 0, sizeof (key)); snprintf (key, sizeof (key), "%d-read-%d", interval, (1 << i)); ret = dict_set_uint64 (dict, key, count); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to " "set read-%db+, with: %"PRId64, (1<block_count_write[i]); if (count) { snprintf (key, sizeof (key), "%d-write-%d", interval, (1<name, GF_LOG_ERROR, "failed to " "set write-%db+, with: %"PRId64, (1<fop_hits[i]); if (fop_hits == 0) continue; snprintf (key, sizeof (key), "%d-%d-hits", interval, i); ret = dict_set_uint64 (dict, key, fop_hits); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set " "%s-fop-hits: %"GF_PRI_ATOMIC, gf_fop_list[i], fop_hits); goto out; } if (stats->latency[i].avg == 0) continue; snprintf (key, sizeof (key), "%d-%d-avglatency", interval, i); ret = dict_set_double (dict, key, stats->latency[i].avg); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set %s " "avglatency(%d) with %f", gf_fop_list[i], interval, stats->latency[i].avg); goto out; } snprintf (key, sizeof (key), "%d-%d-minlatency", interval, i); ret = dict_set_double (dict, key, stats->latency[i].min); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set %s " "minlatency(%d) with %f", gf_fop_list[i], interval, stats->latency[i].min); goto out; } snprintf (key, sizeof (key), "%d-%d-maxlatency", interval, i); ret = dict_set_double (dict, key, stats->latency[i].max); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to set %s " "maxlatency(%d) with %f", gf_fop_list[i], interval, stats->latency[i].max); goto out; } } for (i = 0; i < GF_UPCALL_FLAGS_MAXVALUE; i++) { fop_hits = GF_ATOMIC_GET (stats->upcall_hits[i]); if (fop_hits == 0) continue; snprintf (key, sizeof (key), "%d-%d-upcall-hits", interval, i); ret = dict_set_uint64 (dict, key, fop_hits); if (ret) { gf_log (this->name, GF_LOG_ERROR, "failed to " "set %s-upcall-hits: %"PRIu64, gf_upcall_list[i], fop_hits); goto out; } } out: gf_log (this->name, GF_LOG_DEBUG, "returning %d", ret); return ret; } int io_stats_dump_global (xlator_t *this, struct ios_global_stats *stats, struct timeval *now, int interval, struct ios_dump_args *args) { int ret = -1; GF_ASSERT (args); GF_ASSERT (now); GF_ASSERT (stats); GF_ASSERT (this); switch (args->type) { case IOS_DUMP_TYPE_JSON_FILE: ret = io_stats_dump_global_to_json_logfp ( this, stats, now, interval, args->u.logfp); break; case IOS_DUMP_TYPE_FILE: ret = io_stats_dump_global_to_logfp (this, stats, now, interval, args->u.logfp); break; case IOS_DUMP_TYPE_DICT: ret = io_stats_dump_global_to_dict (this, stats, now, interval, args->u.dict); break; default: GF_ASSERT (0); ret = -1; break; } return ret; } int ios_dump_args_init (struct ios_dump_args *args, ios_dump_type_t type, void *output) { int ret = 0; GF_ASSERT (args); GF_ASSERT (type > IOS_DUMP_TYPE_NONE && type < IOS_DUMP_TYPE_MAX); GF_ASSERT (output); args->type = type; switch (args->type) { case IOS_DUMP_TYPE_JSON_FILE: case IOS_DUMP_TYPE_FILE: args->u.logfp = output; break; case IOS_DUMP_TYPE_DICT: args->u.dict = output; break; default: GF_ASSERT (0); ret = -1; } return ret; } static void ios_global_stats_clear (struct ios_global_stats *stats, struct timeval *now) { GF_ASSERT (stats); GF_ASSERT (now); memset (stats, 0, sizeof (*stats)); stats->started_at = *now; } int io_stats_dump (xlator_t *this, struct ios_dump_args *args, gf1_cli_info_op op, gf_boolean_t is_peek) { struct ios_conf *conf = NULL; struct ios_global_stats cumulative = { }; struct ios_global_stats incremental = { }; int increment = 0; struct timeval now; GF_ASSERT (this); GF_ASSERT (args); GF_ASSERT (args->type > IOS_DUMP_TYPE_NONE); GF_ASSERT (args->type < IOS_DUMP_TYPE_MAX); conf = this->private; gettimeofday (&now, NULL); LOCK (&conf->lock); { if (op == GF_CLI_INFO_ALL || op == GF_CLI_INFO_CUMULATIVE) cumulative = conf->cumulative; if (op == GF_CLI_INFO_ALL || op == GF_CLI_INFO_INCREMENTAL) { incremental = conf->incremental; increment = conf->increment; if (!is_peek) { increment = conf->increment++; ios_global_stats_clear (&conf->incremental, &now); } } } UNLOCK (&conf->lock); if (op == GF_CLI_INFO_ALL || op == GF_CLI_INFO_CUMULATIVE) io_stats_dump_global (this, &cumulative, &now, -1, args); if (op == GF_CLI_INFO_ALL || op == GF_CLI_INFO_INCREMENTAL) io_stats_dump_global (this, &incremental, &now, increment, args); return 0; } int io_stats_dump_fd (xlator_t *this, struct ios_fd *iosfd) { struct ios_conf *conf = NULL; struct timeval now; uint64_t sec = 0; uint64_t usec = 0; int i = 0; uint64_t data_read = 0; uint64_t data_written = 0; uint64_t block_count_read = 0; uint64_t block_count_write = 0; conf = this->private; if (!conf->dump_fd_stats) return 0; if (!iosfd) return 0; gettimeofday (&now, NULL); if (iosfd->opened_at.tv_usec > now.tv_usec) { now.tv_usec += 1000000; now.tv_usec--; } sec = now.tv_sec - iosfd->opened_at.tv_sec; usec = now.tv_usec - iosfd->opened_at.tv_usec; gf_log (this->name, GF_LOG_INFO, "--- fd stats ---"); if (iosfd->filename) gf_log (this->name, GF_LOG_INFO, " Filename : %s", iosfd->filename); if (sec) gf_log (this->name, GF_LOG_INFO, " Lifetime : %"PRId64"secs, %"PRId64"usecs", sec, usec); data_read = GF_ATOMIC_GET (iosfd->data_read); if (data_read) gf_log (this->name, GF_LOG_INFO, " BytesRead : %"PRId64" bytes", data_read); data_written = GF_ATOMIC_GET (iosfd->data_written); if (data_written) gf_log (this->name, GF_LOG_INFO, " BytesWritten : %"PRId64" bytes", data_written); for (i = 0; i < 32; i++) { block_count_read = GF_ATOMIC_GET (iosfd->block_count_read[i]); if (block_count_read) gf_log (this->name, GF_LOG_INFO, " Read %06db+ :" "%"PRId64, (1 << i), block_count_read); } for (i = 0; i < IOS_BLOCK_COUNT_SIZE; i++) { block_count_write = GF_ATOMIC_GET (iosfd->block_count_write[i]); if (block_count_write) gf_log (this->name, GF_LOG_INFO, "Write %06db+ : %"PRId64, (1 << i), block_count_write); } return 0; } void collect_ios_latency_sample (struct ios_conf *conf, glusterfs_fop_t fop_type, double elapsed, call_frame_t *frame) { ios_sample_buf_t *ios_sample_buf = NULL; ios_sample_t *ios_sample = NULL; struct timespec *timestamp = NULL; call_stack_t *root = NULL; ios_sample_buf = conf->ios_sample_buf; LOCK (&conf->ios_sampling_lock); if (conf->ios_sample_interval == 0 || ios_sample_buf->observed % conf->ios_sample_interval != 0) goto out; timestamp = &frame->begin; root = frame->root; ios_sample = &(ios_sample_buf->ios_samples[ios_sample_buf->pos]); ios_sample->elapsed = elapsed; ios_sample->fop_type = fop_type; ios_sample->uid = root->uid; ios_sample->gid = root->gid; (ios_sample->timestamp).tv_sec = timestamp->tv_sec; (ios_sample->timestamp).tv_usec = timestamp->tv_nsec / 1000; memcpy (&ios_sample->identifier, &root->identifier, sizeof (root->identifier)); /* We've reached the end of the circular buffer, start from the * beginning. */ if (ios_sample_buf->pos == (ios_sample_buf->size - 1)) ios_sample_buf->pos = 0; else ios_sample_buf->pos++; ios_sample_buf->collected++; out: ios_sample_buf->observed++; UNLOCK (&conf->ios_sampling_lock); return; } static void update_ios_latency_stats (struct ios_global_stats *stats, double elapsed, glusterfs_fop_t op) { double avg; GF_ASSERT (stats); stats->latency[op].total += elapsed; if (!stats->latency[op].min) stats->latency[op].min = elapsed; if (stats->latency[op].min > elapsed) stats->latency[op].min = elapsed; if (stats->latency[op].max < elapsed) stats->latency[op].max = elapsed; avg = stats->latency[op].avg; stats->latency[op].avg = avg + (elapsed - avg) / GF_ATOMIC_GET (stats->fop_hits[op]); } int update_ios_latency (struct ios_conf *conf, call_frame_t *frame, glusterfs_fop_t op) { double elapsed; struct timespec *begin, *end; begin = &frame->begin; end = &frame->end; elapsed = ((end->tv_sec - begin->tv_sec) * 1e9 + (end->tv_nsec - begin->tv_nsec)) / 1000; update_ios_latency_stats (&conf->cumulative, elapsed, op); update_ios_latency_stats (&conf->incremental, elapsed, op); collect_ios_latency_sample (conf, op, elapsed, frame); return 0; } int32_t io_stats_dump_stats_to_dict (xlator_t *this, dict_t *resp, ios_stats_type_t flags, int32_t list_cnt) { struct ios_conf *conf = NULL; int cnt = 0; char key[256]; struct ios_stat_head *list_head = NULL; struct ios_stat_list *entry = NULL; int ret = -1; ios_stats_thru_t index = IOS_STATS_THRU_MAX; char timestr[256] = {0, }; char *dict_timestr = NULL; conf = this->private; switch (flags) { case IOS_STATS_TYPE_OPEN: list_head = &conf->list[IOS_STATS_TYPE_OPEN]; LOCK (&conf->lock); { ret = dict_set_uint64 (resp, "current-open", conf->cumulative.nr_opens); if (ret) goto unlock; ret = dict_set_uint64 (resp, "max-open", conf->cumulative.max_nr_opens); gf_time_fmt (timestr, sizeof timestr, conf->cumulative.max_openfd_time.tv_sec, gf_timefmt_FT); if (conf->cumulative.max_openfd_time.tv_sec) snprintf (timestr + strlen (timestr), sizeof timestr - strlen (timestr), ".%"GF_PRI_SUSECONDS, conf->cumulative.max_openfd_time.tv_usec); dict_timestr = gf_strdup (timestr); if (!dict_timestr) goto unlock; ret = dict_set_dynstr (resp, "max-openfd-time", dict_timestr); if (ret) goto unlock; } unlock: UNLOCK (&conf->lock); /* Do not proceed if we came here because of some error * during the dict operation */ if (ret) goto out; break; case IOS_STATS_TYPE_READ: list_head = &conf->list[IOS_STATS_TYPE_READ]; break; case IOS_STATS_TYPE_WRITE: list_head = &conf->list[IOS_STATS_TYPE_WRITE]; break; case IOS_STATS_TYPE_OPENDIR: list_head = &conf->list[IOS_STATS_TYPE_OPENDIR]; break; case IOS_STATS_TYPE_READDIRP: list_head = &conf->list[IOS_STATS_TYPE_READDIRP]; break; case IOS_STATS_TYPE_READ_THROUGHPUT: list_head = &conf->thru_list[IOS_STATS_THRU_READ]; index = IOS_STATS_THRU_READ; break; case IOS_STATS_TYPE_WRITE_THROUGHPUT: list_head = &conf->thru_list[IOS_STATS_THRU_WRITE]; index = IOS_STATS_THRU_WRITE; break; default: goto out; } ret = dict_set_int32 (resp, "top-op", flags); if (!list_cnt) goto out; LOCK (&list_head->lock); { list_for_each_entry (entry, &list_head->iosstats->list, list) { cnt++; snprintf (key, 256, "%s-%d", "filename", cnt); ret = dict_set_str (resp, key, entry->iosstat->filename); if (ret) goto unlock_list_head; snprintf (key, 256, "%s-%d", "value",cnt); ret = dict_set_uint64 (resp, key, entry->value); if (ret) goto unlock_list_head; if (index != IOS_STATS_THRU_MAX) { snprintf (key, 256, "%s-%d", "time-sec", cnt); ret = dict_set_int32 (resp, key, entry->iosstat->thru_counters[index].time.tv_sec); if (ret) goto unlock_list_head; snprintf (key, 256, "%s-%d", "time-usec", cnt); ret = dict_set_int32 (resp, key, entry->iosstat->thru_counters[index].time.tv_usec); if (ret) goto unlock_list_head; } if (cnt == list_cnt) break; } } unlock_list_head: UNLOCK (&list_head->lock); /* ret is !=0 if some dict operation in the above critical region * failed. */ if (ret) goto out; ret = dict_set_int32 (resp, "members", cnt); out: return ret; } static struct ios_stat* ios_init_iosstat (xlator_t *this, char *path, uuid_t gfid, inode_t *inode) { struct ios_stat *iosstat = NULL; int i = 0; iosstat = GF_CALLOC (1, sizeof (*iosstat), gf_io_stats_mt_ios_stat); if (!iosstat) goto out; iosstat->filename = gf_strdup (path); gf_uuid_copy (iosstat->gfid, gfid); LOCK_INIT (&iosstat->lock); for (i = 0; i < IOS_STATS_TYPE_MAX; i++) GF_ATOMIC_INIT (iosstat->counters[i], 0); ios_inode_ctx_set (inode, this, iosstat); out: return iosstat; } int io_stats_create_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, fd_t *fd, inode_t *inode, struct iatt *buf, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { struct ios_fd *iosfd = NULL; char *path = NULL; struct ios_stat *iosstat = NULL; struct ios_conf *conf = NULL; conf = this->private; path = frame->local; frame->local = NULL; if (!path) goto unwind; if (op_ret < 0) { GF_FREE (path); goto unwind; } iosfd = GF_CALLOC (1, sizeof (*iosfd), gf_io_stats_mt_ios_fd); if (!iosfd) { GF_FREE (path); goto unwind; } iosfd->filename = path; gettimeofday (&iosfd->opened_at, NULL); ios_fd_ctx_set (fd, this, iosfd); LOCK (&conf->lock); { conf->cumulative.nr_opens++; if (conf->cumulative.nr_opens > conf->cumulative.max_nr_opens) { conf->cumulative.max_nr_opens = conf->cumulative.nr_opens; conf->cumulative.max_openfd_time = iosfd->opened_at; } } UNLOCK (&conf->lock); iosstat = ios_init_iosstat (this, path, buf->ia_gfid, inode); if (!iosstat) GF_FREE (path); unwind: UPDATE_PROFILE_STATS (frame, CREATE); STACK_UNWIND_STRICT (create, frame, op_ret, op_errno, fd, inode, buf, preparent, postparent, xdata); return 0; } int io_stats_open_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, fd_t *fd, dict_t *xdata) { struct ios_fd *iosfd = NULL; char *path = NULL; struct ios_stat *iosstat = NULL; struct ios_conf *conf = NULL; int i = 0; conf = this->private; path = frame->local; frame->local = NULL; if (!path) goto unwind; if (op_ret < 0) { GF_FREE (path); goto unwind; } iosfd = GF_CALLOC (1, sizeof (*iosfd), gf_io_stats_mt_ios_fd); if (!iosfd) { GF_FREE (path); goto unwind; } iosfd->filename = path; GF_ATOMIC_INIT (iosfd->data_read, 0); GF_ATOMIC_INIT (iosfd->data_written, 0); for (i = 0; i < IOS_BLOCK_COUNT_SIZE; i++) { GF_ATOMIC_INIT (iosfd->block_count_write[i], 0); GF_ATOMIC_INIT (iosfd->block_count_read[i], 0); } gettimeofday (&iosfd->opened_at, NULL); ios_fd_ctx_set (fd, this, iosfd); ios_inode_ctx_get (fd->inode, this, &iosstat); if (!iosstat) { iosstat = ios_init_iosstat (this, path, fd->inode->gfid, fd->inode); } LOCK (&conf->lock); { conf->cumulative.nr_opens++; if (conf->cumulative.nr_opens > conf->cumulative.max_nr_opens) { conf->cumulative.max_nr_opens = conf->cumulative.nr_opens; conf->cumulative.max_openfd_time = iosfd->opened_at; } } UNLOCK (&conf->lock); if (iosstat) { ios_bump_stats (this, iosstat, IOS_STATS_TYPE_OPEN); iosstat = NULL; } unwind: UPDATE_PROFILE_STATS (frame, OPEN); STACK_UNWIND_STRICT (open, frame, op_ret, op_errno, fd, xdata); return 0; } int io_stats_stat_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *buf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, STAT); STACK_UNWIND_STRICT (stat, frame, op_ret, op_errno, buf, xdata); return 0; } int io_stats_readv_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iovec *vector, int32_t count, struct iatt *buf, struct iobref *iobref, dict_t *xdata) { int len = 0; fd_t *fd = NULL; struct ios_stat *iosstat = NULL; fd = frame->local; frame->local = NULL; if (op_ret > 0) { len = iov_length (vector, count); ios_bump_read (this, fd, len); } UPDATE_PROFILE_STATS (frame, READ); ios_inode_ctx_get (fd->inode, this, &iosstat); if (iosstat) { ios_bump_stats (this, iosstat, IOS_STATS_TYPE_READ); BUMP_THROUGHPUT (iosstat, IOS_STATS_THRU_READ); iosstat = NULL; } STACK_UNWIND_STRICT (readv, frame, op_ret, op_errno, vector, count, buf, iobref, xdata); return 0; } int io_stats_writev_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { struct ios_stat *iosstat = NULL; inode_t *inode = NULL; UPDATE_PROFILE_STATS (frame, WRITE); if (frame->local){ inode = frame->local; frame->local = NULL; ios_inode_ctx_get (inode, this, &iosstat); if (iosstat) { ios_bump_stats (this, iosstat, IOS_STATS_TYPE_WRITE); BUMP_THROUGHPUT (iosstat, IOS_STATS_THRU_WRITE); inode = NULL; iosstat = NULL; } } STACK_UNWIND_STRICT (writev, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int io_stats_readdirp_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, gf_dirent_t *buf, dict_t *xdata) { struct ios_stat *iosstat = NULL; inode_t *inode = frame->local; frame->local = NULL; UPDATE_PROFILE_STATS (frame, READDIRP); ios_inode_ctx_get (inode, this, &iosstat); if (iosstat) { ios_bump_stats (this, iosstat, IOS_STATS_TYPE_READDIRP); iosstat = NULL; } STACK_UNWIND_STRICT (readdirp, frame, op_ret, op_errno, buf, xdata); return 0; } int io_stats_readdir_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, gf_dirent_t *buf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, READDIR); STACK_UNWIND_STRICT (readdir, frame, op_ret, op_errno, buf, xdata); return 0; } int io_stats_fsync_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FSYNC); STACK_UNWIND_STRICT (fsync, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int io_stats_setattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *preop, struct iatt *postop, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, SETATTR); STACK_UNWIND_STRICT (setattr, frame, op_ret, op_errno, preop, postop, xdata); return 0; } int io_stats_unlink_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, UNLINK); STACK_UNWIND_STRICT (unlink, frame, op_ret, op_errno, preparent, postparent, xdata); return 0; } int io_stats_rename_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *buf, struct iatt *preoldparent, struct iatt *postoldparent, struct iatt *prenewparent, struct iatt *postnewparent, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, RENAME); STACK_UNWIND_STRICT (rename, frame, op_ret, op_errno, buf, preoldparent, postoldparent, prenewparent, postnewparent, xdata); return 0; } int io_stats_readlink_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, const char *buf, struct iatt *sbuf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, READLINK); STACK_UNWIND_STRICT (readlink, frame, op_ret, op_errno, buf, sbuf, xdata); return 0; } int io_stats_lookup_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, inode_t *inode, struct iatt *buf, dict_t *xdata, struct iatt *postparent) { UPDATE_PROFILE_STATS (frame, LOOKUP); STACK_UNWIND_STRICT (lookup, frame, op_ret, op_errno, inode, buf, xdata, postparent); return 0; } int io_stats_symlink_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, inode_t *inode, struct iatt *buf, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, SYMLINK); STACK_UNWIND_STRICT (symlink, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int io_stats_mknod_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, inode_t *inode, struct iatt *buf, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, MKNOD); STACK_UNWIND_STRICT (mknod, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int io_stats_mkdir_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, inode_t *inode, struct iatt *buf, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { char *path = frame->local; if (!path) goto unwind; UPDATE_PROFILE_STATS (frame, MKDIR); if (op_ret < 0) goto unwind; /* allocate a struct ios_stat and set the inode ctx */ ios_init_iosstat (this, path, buf->ia_gfid, inode); unwind: /* local is assigned with path */ GF_FREE (frame->local); frame->local = NULL; STACK_UNWIND_STRICT (mkdir, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int io_stats_link_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, inode_t *inode, struct iatt *buf, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, LINK); STACK_UNWIND_STRICT (link, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int io_stats_flush_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FLUSH); STACK_UNWIND_STRICT (flush, frame, op_ret, op_errno, xdata); return 0; } int io_stats_opendir_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, fd_t *fd, dict_t *xdata) { struct ios_stat *iosstat = NULL; int ret = -1; UPDATE_PROFILE_STATS (frame, OPENDIR); if (op_ret < 0) goto unwind; ios_fd_ctx_set (fd, this, 0); ret = ios_inode_ctx_get (fd->inode, this, &iosstat); if (!ret) ios_bump_stats (this, iosstat, IOS_STATS_TYPE_OPENDIR); unwind: STACK_UNWIND_STRICT (opendir, frame, op_ret, op_errno, fd, xdata); return 0; } int io_stats_rmdir_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *preparent, struct iatt *postparent, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, RMDIR); STACK_UNWIND_STRICT (rmdir, frame, op_ret, op_errno, preparent, postparent, xdata); return 0; } int io_stats_truncate_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, TRUNCATE); STACK_UNWIND_STRICT (truncate, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int io_stats_statfs_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct statvfs *buf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, STATFS); STACK_UNWIND_STRICT (statfs, frame, op_ret, op_errno, buf, xdata); return 0; } int io_stats_setxattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, SETXATTR); STACK_UNWIND_STRICT (setxattr, frame, op_ret, op_errno, xdata); return 0; } int io_stats_getxattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *dict, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, GETXATTR); STACK_UNWIND_STRICT (getxattr, frame, op_ret, op_errno, dict, xdata); return 0; } int io_stats_removexattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, REMOVEXATTR); STACK_UNWIND_STRICT (removexattr, frame, op_ret, op_errno, xdata); return 0; } int io_stats_fsetxattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FSETXATTR); STACK_UNWIND_STRICT (fsetxattr, frame, op_ret, op_errno, xdata); return 0; } int io_stats_fgetxattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *dict, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FGETXATTR); STACK_UNWIND_STRICT (fgetxattr, frame, op_ret, op_errno, dict, xdata); return 0; } int io_stats_fremovexattr_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FREMOVEXATTR); STACK_UNWIND_STRICT (fremovexattr, frame, op_ret, op_errno, xdata); return 0; } int io_stats_fsyncdir_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FSYNCDIR); STACK_UNWIND_STRICT (fsyncdir, frame, op_ret, op_errno, xdata); return 0; } int io_stats_access_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, ACCESS); STACK_UNWIND_STRICT (access, frame, op_ret, op_errno, xdata); return 0; } int io_stats_ftruncate_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FTRUNCATE); STACK_UNWIND_STRICT (ftruncate, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int io_stats_fstat_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *buf, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FSTAT); STACK_UNWIND_STRICT (fstat, frame, op_ret, op_errno, buf, xdata); return 0; } int io_stats_fallocate_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { UPDATE_PROFILE_STATS(frame, FALLOCATE); STACK_UNWIND_STRICT(fallocate, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int io_stats_discard_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { UPDATE_PROFILE_STATS(frame, DISCARD); STACK_UNWIND_STRICT(discard, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int io_stats_zerofill_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *prebuf, struct iatt *postbuf, dict_t *xdata) { UPDATE_PROFILE_STATS(frame, ZEROFILL); STACK_UNWIND_STRICT(zerofill, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int32_t io_stats_ipc_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS(frame, IPC); STACK_UNWIND_STRICT (ipc, frame, op_ret, op_errno, xdata); return 0; } int io_stats_lk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct gf_flock *lock, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, LK); STACK_UNWIND_STRICT (lk, frame, op_ret, op_errno, lock, xdata); return 0; } int io_stats_entrylk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, ENTRYLK); STACK_UNWIND_STRICT (entrylk, frame, op_ret, op_errno, xdata); return 0; } int io_stats_fentrylk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FENTRYLK); STACK_UNWIND_STRICT (fentrylk, frame, op_ret, op_errno, xdata); return 0; } int io_stats_rchecksum_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, uint32_t weak_checksum, uint8_t *strong_checksum, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, RCHECKSUM); STACK_UNWIND_STRICT (rchecksum, frame, op_ret, op_errno, weak_checksum, strong_checksum, xdata); return 0; } int io_stats_seek_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, off_t offset, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, SEEK); STACK_UNWIND_STRICT (seek, frame, op_ret, op_errno, offset, xdata); return 0; } int io_stats_lease_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct gf_lease *lease, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, LEASE); STACK_UNWIND_STRICT (lease, frame, op_ret, op_errno, lease, xdata); return 0; } int io_stats_getactivelk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, lock_migration_info_t *locklist, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, GETACTIVELK); STACK_UNWIND_STRICT (getactivelk, frame, op_ret, op_errno, locklist, xdata); return 0; } int io_stats_setactivelk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, SETACTIVELK); STACK_UNWIND_STRICT (setactivelk, frame, op_ret, op_errno, xdata); return 0; } int io_stats_compound_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, void *data, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, COMPOUND); STACK_UNWIND_STRICT (compound, frame, op_ret, op_errno, data, xdata); return 0; } int io_stats_xattrop_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *dict, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, XATTROP); STACK_UNWIND_STRICT (xattrop, frame, op_ret, op_errno, dict, xdata); return 0; } int io_stats_fxattrop_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *dict, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FXATTROP); STACK_UNWIND_STRICT (fxattrop, frame, op_ret, op_errno, dict, xdata); return 0; } int io_stats_inodelk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, INODELK); STACK_UNWIND_STRICT (inodelk, frame, op_ret, op_errno, xdata); return 0; } int io_stats_entrylk (call_frame_t *frame, xlator_t *this, const char *volume, loc_t *loc, const char *basename, entrylk_cmd cmd, entrylk_type type, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_entrylk_cbk, FIRST_CHILD (this), FIRST_CHILD (this)->fops->entrylk, volume, loc, basename, cmd, type, xdata); return 0; } int io_stats_fentrylk (call_frame_t *frame, xlator_t *this, const char *volume, fd_t *fd, const char *basename, entrylk_cmd cmd, entrylk_type type, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fentrylk_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fentrylk, volume, fd, basename, cmd, type, xdata); return 0; } int io_stats_inodelk (call_frame_t *frame, xlator_t *this, const char *volume, loc_t *loc, int32_t cmd, struct gf_flock *flock, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_inodelk_cbk, FIRST_CHILD (this), FIRST_CHILD (this)->fops->inodelk, volume, loc, cmd, flock, xdata); return 0; } int io_stats_finodelk_cbk (call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { UPDATE_PROFILE_STATS (frame, FINODELK); STACK_UNWIND_STRICT (finodelk, frame, op_ret, op_errno, xdata); return 0; } int io_stats_finodelk (call_frame_t *frame, xlator_t *this, const char *volume, fd_t *fd, int32_t cmd, struct gf_flock *flock, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_finodelk_cbk, FIRST_CHILD (this), FIRST_CHILD (this)->fops->finodelk, volume, fd, cmd, flock, xdata); return 0; } int io_stats_xattrop (call_frame_t *frame, xlator_t *this, loc_t *loc, gf_xattrop_flags_t flags, dict_t *dict, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_xattrop_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->xattrop, loc, flags, dict, xdata); return 0; } int io_stats_fxattrop (call_frame_t *frame, xlator_t *this, fd_t *fd, gf_xattrop_flags_t flags, dict_t *dict, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fxattrop_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fxattrop, fd, flags, dict, xdata); return 0; } int io_stats_lookup (call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_lookup_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->lookup, loc, xdata); return 0; } int io_stats_stat (call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_stat_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->stat, loc, xdata); return 0; } int io_stats_readlink (call_frame_t *frame, xlator_t *this, loc_t *loc, size_t size, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_readlink_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readlink, loc, size, xdata); return 0; } int io_stats_mknod (call_frame_t *frame, xlator_t *this, loc_t *loc, mode_t mode, dev_t dev, mode_t umask, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_mknod_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->mknod, loc, mode, dev, umask, xdata); return 0; } int io_stats_mkdir (call_frame_t *frame, xlator_t *this, loc_t *loc, mode_t mode, mode_t umask, dict_t *xdata) { if (loc->path) frame->local = gf_strdup (loc->path); START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_mkdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->mkdir, loc, mode, umask, xdata); return 0; } int io_stats_unlink (call_frame_t *frame, xlator_t *this, loc_t *loc, int xflag, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_unlink_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->unlink, loc, xflag, xdata); return 0; } int io_stats_rmdir (call_frame_t *frame, xlator_t *this, loc_t *loc, int flags, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_rmdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->rmdir, loc, flags, xdata); return 0; } int io_stats_symlink (call_frame_t *frame, xlator_t *this, const char *linkpath, loc_t *loc, mode_t umask, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_symlink_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->symlink, linkpath, loc, umask, xdata); return 0; } int io_stats_rename (call_frame_t *frame, xlator_t *this, loc_t *oldloc, loc_t *newloc, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_rename_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->rename, oldloc, newloc, xdata); return 0; } int io_stats_link (call_frame_t *frame, xlator_t *this, loc_t *oldloc, loc_t *newloc, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_link_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->link, oldloc, newloc, xdata); return 0; } int io_stats_setattr (call_frame_t *frame, xlator_t *this, loc_t *loc, struct iatt *stbuf, int32_t valid, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_setattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->setattr, loc, stbuf, valid, xdata); return 0; } int io_stats_truncate (call_frame_t *frame, xlator_t *this, loc_t *loc, off_t offset, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_truncate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->truncate, loc, offset, xdata); return 0; } int io_stats_open (call_frame_t *frame, xlator_t *this, loc_t *loc, int32_t flags, fd_t *fd, dict_t *xdata) { if (loc->path) frame->local = gf_strdup (loc->path); START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_open_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->open, loc, flags, fd, xdata); return 0; } int io_stats_create (call_frame_t *frame, xlator_t *this, loc_t *loc, int32_t flags, mode_t mode, mode_t umask, fd_t *fd, dict_t *xdata) { if (loc->path) frame->local = gf_strdup (loc->path); START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_create_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->create, loc, flags, mode, umask, fd, xdata); return 0; } int io_stats_readv (call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, uint32_t flags, dict_t *xdata) { frame->local = fd; START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_readv_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readv, fd, size, offset, flags, xdata); return 0; } int io_stats_writev (call_frame_t *frame, xlator_t *this, fd_t *fd, struct iovec *vector, int32_t count, off_t offset, uint32_t flags, struct iobref *iobref, dict_t *xdata) { int len = 0; if (fd->inode) frame->local = fd->inode; len = iov_length (vector, count); ios_bump_write (this, fd, len); START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_writev_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->writev, fd, vector, count, offset, flags, iobref, xdata); return 0; } int io_stats_statfs (call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_statfs_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->statfs, loc, xdata); return 0; } int io_stats_flush (call_frame_t *frame, xlator_t *this, fd_t *fd, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_flush_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->flush, fd, xdata); return 0; } int io_stats_fsync (call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t flags, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fsync_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsync, fd, flags, xdata); return 0; } int conditional_dump (dict_t *dict, char *key, data_t *value, void *data) { struct { xlator_t *this; inode_t *inode; const char *path; } *stub; xlator_t *this = NULL; char *filename = NULL; FILE *logfp = NULL; struct ios_dump_args args = {0}; int pid, namelen; char dump_key[100]; char *slash_ptr = NULL; stub = data; this = stub->this; /* Create a file name that is appended with the io-stats instance name as well. This helps when there is more than a single io-stats instance in the graph, or the client and server processes are running on the same node */ /* hmmm... no check for this */ /* name format: . */ namelen = value->len + strlen (this->name) + 2; /* '.' and '\0' */ filename = alloca0 (namelen); memcpy (filename, data_to_str (value), value->len); memcpy (filename + value->len, ".", 1); memcpy (filename + value->len + 1, this->name, strlen(this->name)); /* convert any slashes to '-' so that fopen works correctly */ slash_ptr = strchr (filename + value->len + 1, '/'); while (slash_ptr) { *slash_ptr = '-'; slash_ptr = strchr (slash_ptr, '/'); } pid = getpid (); if (!strncmp (filename, "", 1)) { gf_log (this->name, GF_LOG_ERROR, "No filename given"); return -1; } logfp = fopen (filename, "w+"); if (!logfp) { gf_log (this->name, GF_LOG_ERROR, "failed to open %s " "for writing", filename); return -1; } sprintf (dump_key, "*io*stat*%d_json_dump", pid); if (fnmatch (dump_key, key, 0) == 0) { (void) ios_dump_args_init ( &args, IOS_DUMP_TYPE_JSON_FILE, logfp); } else { (void) ios_dump_args_init (&args, IOS_DUMP_TYPE_FILE, logfp); } io_stats_dump (this, &args, GF_CLI_INFO_ALL, _gf_false); fclose (logfp); return 0; } int _ios_destroy_dump_thread (struct ios_conf *conf) { conf->dump_thread_should_die = _gf_true; if (conf->ios_dump_interval > 0) { (void) pthread_cancel (conf->dump_thread); (void) pthread_join (conf->dump_thread, NULL); } return 0; } void * _ios_dump_thread (xlator_t *this) { struct ios_conf *conf = NULL; FILE *stats_logfp = NULL; FILE *samples_logfp = NULL; struct ios_dump_args args = {0}; int i; int stats_bytes_written = 0; int samples_bytes_written = 0; char stats_filename[PATH_MAX]; char samples_filename[PATH_MAX]; char *xlator_name; char *instance_name; gf_boolean_t log_stats_fopen_failure = _gf_true; gf_boolean_t log_samples_fopen_failure = _gf_true; int old_cancel_type; conf = this->private; gf_log (this->name, GF_LOG_INFO, "IO stats dump thread started, " "polling IO stats every %d seconds", conf->ios_dump_interval); xlator_name = strdupa (conf->unique_id); for (i = 0; i < strlen (xlator_name); i++) { if (xlator_name[i] == '/') xlator_name[i] = '_'; } instance_name = this->instance_name; if (this->name && strcmp (this->name, "glustershd") == 0) { xlator_name = "shd"; } else if (this->prev && strcmp (this->prev->name, "nfs-server") == 0) { xlator_name = "nfsd"; instance_name = this->prev->instance_name; } if (sys_mkdir (_IOS_DUMP_DIR, S_IRWXU | S_IRWXO | S_IRWXG) == (-1)) { if (errno != EEXIST) { gf_log (this->name, GF_LOG_ERROR, "could not create stats-dump directory %s", _IOS_DUMP_DIR); goto out; } } if (sys_mkdir (_IOS_SAMP_DIR, S_IRWXU | S_IRWXO | S_IRWXG) == (-1)) { if (errno != EEXIST) { gf_log (this->name, GF_LOG_ERROR, "could not create stats-sample directory %s", _IOS_SAMP_DIR); goto out; } } if (instance_name) { stats_bytes_written = snprintf (stats_filename, PATH_MAX, "%s/%s_%s_%s.dump", _IOS_DUMP_DIR, __progname, xlator_name, instance_name); samples_bytes_written = snprintf (samples_filename, PATH_MAX, "%s/%s_%s_%s.samp", _IOS_SAMP_DIR, __progname, xlator_name, instance_name); } else { stats_bytes_written = snprintf (stats_filename, PATH_MAX, "%s/%s_%s.dump", _IOS_DUMP_DIR, __progname, xlator_name); samples_bytes_written = snprintf (samples_filename, PATH_MAX, "%s/%s_%s.samp", _IOS_SAMP_DIR, __progname, xlator_name); } if ((stats_bytes_written >= PATH_MAX) || (samples_bytes_written >= PATH_MAX)) { gf_log (this->name, GF_LOG_ERROR, "Invalid path for stats dump (%s) and/or latency " "samples (%s)", stats_filename, samples_filename); goto out; } while (1) { if (conf->dump_thread_should_die) break; (void) pthread_setcanceltype (PTHREAD_CANCEL_ASYNCHRONOUS, &old_cancel_type); sleep (conf->ios_dump_interval); (void) pthread_setcanceltype (PTHREAD_CANCEL_DEFERRED, &old_cancel_type); /* * It's not clear whether we should reopen this each time, or * just hold it open and rewind/truncate on each iteration. * Leaving it alone for now. */ stats_logfp = fopen (stats_filename, "w+"); if (stats_logfp) { (void) ios_dump_args_init (&args, conf->dump_format, stats_logfp); io_stats_dump (this, &args, GF_CLI_INFO_ALL, _gf_false); fclose (stats_logfp); log_stats_fopen_failure = _gf_true; } else if (log_stats_fopen_failure) { gf_log (this->name, GF_LOG_ERROR, "could not open stats-dump file %s (%s)", stats_filename, strerror(errno)); log_stats_fopen_failure = _gf_false; } samples_logfp = fopen (samples_filename, "w+"); if (samples_logfp) { io_stats_dump_latency_samples_logfp (this, samples_logfp); fclose (samples_logfp); log_samples_fopen_failure = _gf_true; } else if (log_samples_fopen_failure) { gf_log (this->name, GF_LOG_ERROR, "could not open samples-dump file %s (%s)", samples_filename, strerror(errno)); log_samples_fopen_failure = _gf_false; } } out: gf_log (this->name, GF_LOG_INFO, "IO stats dump thread terminated"); return NULL; } static gf_boolean_t match_special_xattr (dict_t *d, char *k, data_t *val, void *mdata) { gf_boolean_t ret = _gf_false; if (fnmatch ("*io*stat*dump", k, 0) == 0) { ret = _gf_true; } return ret; } int io_stats_setxattr (call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *dict, int32_t flags, dict_t *xdata) { struct { xlator_t *this; inode_t *inode; const char *path; } stub; stub.this = this; stub.inode = loc->inode; stub.path = loc->path; (void) dict_foreach_match (dict, match_special_xattr, NULL, conditional_dump, &stub); START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_setxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->setxattr, loc, dict, flags, xdata); return 0; } int io_stats_getxattr (call_frame_t *frame, xlator_t *this, loc_t *loc, const char *name, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_getxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->getxattr, loc, name, xdata); return 0; } int io_stats_removexattr (call_frame_t *frame, xlator_t *this, loc_t *loc, const char *name, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_removexattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->removexattr, loc, name, xdata); return 0; } int io_stats_fsetxattr (call_frame_t *frame, xlator_t *this, fd_t *fd, dict_t *dict, int32_t flags, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fsetxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsetxattr, fd, dict, flags, xdata); return 0; } int io_stats_fgetxattr (call_frame_t *frame, xlator_t *this, fd_t *fd, const char *name, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fgetxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fgetxattr, fd, name, xdata); return 0; } int io_stats_fremovexattr (call_frame_t *frame, xlator_t *this, fd_t *fd, const char *name, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fremovexattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fremovexattr, fd, name, xdata); return 0; } int io_stats_opendir (call_frame_t *frame, xlator_t *this, loc_t *loc, fd_t *fd, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_opendir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->opendir, loc, fd, xdata); return 0; } int io_stats_readdirp (call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, dict_t *dict) { frame->local = fd->inode; START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_readdirp_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readdirp, fd, size, offset, dict); return 0; } int io_stats_readdir (call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_readdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readdir, fd, size, offset, xdata); return 0; } int io_stats_fsyncdir (call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t datasync, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fsyncdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsyncdir, fd, datasync, xdata); return 0; } int io_stats_access (call_frame_t *frame, xlator_t *this, loc_t *loc, int32_t mask, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_access_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->access, loc, mask, xdata); return 0; } int io_stats_ftruncate (call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_ftruncate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->ftruncate, fd, offset, xdata); return 0; } int io_stats_fsetattr (call_frame_t *frame, xlator_t *this, fd_t *fd, struct iatt *stbuf, int32_t valid, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_setattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsetattr, fd, stbuf, valid, xdata); return 0; } int io_stats_fstat (call_frame_t *frame, xlator_t *this, fd_t *fd, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_fstat_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fstat, fd, xdata); return 0; } int io_stats_fallocate(call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t mode, off_t offset, size_t len, dict_t *xdata) { START_FOP_LATENCY(frame); STACK_WIND(frame, io_stats_fallocate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fallocate, fd, mode, offset, len, xdata); return 0; } int io_stats_discard(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, size_t len, dict_t *xdata) { START_FOP_LATENCY(frame); STACK_WIND(frame, io_stats_discard_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->discard, fd, offset, len, xdata); return 0; } int io_stats_zerofill(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, off_t len, dict_t *xdata) { START_FOP_LATENCY(frame); STACK_WIND(frame, io_stats_zerofill_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->zerofill, fd, offset, len, xdata); return 0; } int32_t io_stats_ipc (call_frame_t *frame, xlator_t *this, int32_t op, dict_t *xdata) { START_FOP_LATENCY(frame); STACK_WIND (frame, io_stats_ipc_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->ipc, op, xdata); return 0; } int io_stats_lk (call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t cmd, struct gf_flock *lock, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_lk_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->lk, fd, cmd, lock, xdata); return 0; } int io_stats_rchecksum (call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, int32_t len, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_rchecksum_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->rchecksum, fd, offset, len, xdata); return 0; } int io_stats_seek (call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, gf_seek_what_t what, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_seek_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->seek, fd, offset, what, xdata); return 0; } int io_stats_lease (call_frame_t *frame, xlator_t *this, loc_t *loc, struct gf_lease *lease, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_lease_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->lease, loc, lease, xdata); return 0; } int io_stats_getactivelk (call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_getactivelk_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->getactivelk, loc, xdata); return 0; } int io_stats_setactivelk (call_frame_t *frame, xlator_t *this, loc_t *loc, lock_migration_info_t *locklist, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_setactivelk_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->setactivelk, loc, locklist, xdata); return 0; } int io_stats_compound (call_frame_t *frame, xlator_t *this, void *args, dict_t *xdata) { START_FOP_LATENCY (frame); STACK_WIND (frame, io_stats_compound_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->compound, args, xdata); return 0; } int io_stats_release (xlator_t *this, fd_t *fd) { struct ios_fd *iosfd = NULL; struct ios_conf *conf = NULL; BUMP_FOP (RELEASE); conf = this->private; LOCK (&conf->lock); { conf->cumulative.nr_opens--; } UNLOCK (&conf->lock); ios_fd_ctx_get (fd, this, &iosfd); if (iosfd) { io_stats_dump_fd (this, iosfd); GF_FREE (iosfd->filename); GF_FREE (iosfd); } return 0; } int io_stats_releasedir (xlator_t *this, fd_t *fd) { BUMP_FOP (RELEASEDIR); return 0; } int io_stats_forget (xlator_t *this, inode_t *inode) { BUMP_FOP (FORGET); ios_stats_cleanup (this, inode); return 0; } static int ios_init_top_stats (struct ios_conf *conf) { int i = 0; GF_ASSERT (conf); for (i = 0; i list[i].iosstats = GF_CALLOC (1, sizeof(*conf->list[i].iosstats), gf_io_stats_mt_ios_stat); if (!conf->list[i].iosstats) return -1; INIT_LIST_HEAD(&conf->list[i].iosstats->list); LOCK_INIT (&conf->list[i].lock); } for (i = 0; i < IOS_STATS_THRU_MAX; i ++) { conf->thru_list[i].iosstats = GF_CALLOC (1, sizeof (*conf->thru_list[i].iosstats), gf_io_stats_mt_ios_stat); if (!conf->thru_list[i].iosstats) return -1; INIT_LIST_HEAD(&conf->thru_list[i].iosstats->list); LOCK_INIT (&conf->thru_list[i].lock); } return 0; } static void ios_destroy_top_stats (struct ios_conf *conf) { int i = 0; struct ios_stat_head *list_head = NULL; struct ios_stat_list *entry = NULL; struct ios_stat_list *tmp = NULL; struct ios_stat_list *list = NULL; struct ios_stat *stat = NULL; GF_ASSERT (conf); LOCK (&conf->lock); conf->cumulative.nr_opens = 0; conf->cumulative.max_nr_opens = 0; conf->cumulative.max_openfd_time.tv_sec = 0; conf->cumulative.max_openfd_time.tv_usec = 0; for (i = 0; i < IOS_STATS_TYPE_MAX; i++) { list_head = &conf->list[i]; if (!list_head) continue; list_for_each_entry_safe (entry, tmp, &list_head->iosstats->list, list) { list = entry; stat = list->iosstat; ios_stat_unref (stat); list_del (&list->list); GF_FREE (list); list_head->members--; } GF_FREE (list_head->iosstats); } for (i = 0; i < IOS_STATS_THRU_MAX; i++) { list_head = &conf->thru_list[i]; if (!list_head) continue; list_for_each_entry_safe (entry, tmp, &list_head->iosstats->list, list) { list = entry; stat = list->iosstat; ios_stat_unref (stat); list_del (&list->list); GF_FREE (list); list_head->members--; } GF_FREE (list_head->iosstats); } UNLOCK (&conf->lock); return; } static int io_stats_clear (struct ios_conf *conf) { struct timeval now; int ret = -1; GF_ASSERT (conf); if (!gettimeofday (&now, NULL)) { LOCK (&conf->lock); { ios_global_stats_clear (&conf->cumulative, &now); ios_global_stats_clear (&conf->incremental, &now); conf->increment = 0; } UNLOCK (&conf->lock); ret = 0; } return ret; } int32_t io_priv (xlator_t *this) { int i; char key[GF_DUMP_MAX_BUF_LEN]; char key_prefix_cumulative[GF_DUMP_MAX_BUF_LEN]; char key_prefix_incremental[GF_DUMP_MAX_BUF_LEN]; double min, max, avg; uint64_t count, total; struct ios_conf *conf = NULL; conf = this->private; if (!conf) return -1; if(!conf->count_fop_hits || !conf->measure_latency) return -1; gf_proc_dump_write ("cumulative.data_read", "%"GF_PRI_ATOMIC, GF_ATOMIC_GET (conf->cumulative.data_read)); gf_proc_dump_write ("cumulative.data_written", "%"GF_PRI_ATOMIC, GF_ATOMIC_GET (conf->cumulative.data_written)); gf_proc_dump_write ("incremental.data_read", "%"GF_PRI_ATOMIC, GF_ATOMIC_GET (conf->incremental.data_read)); gf_proc_dump_write ("incremental.data_written", "%"GF_PRI_ATOMIC, GF_ATOMIC_GET (conf->incremental.data_written)); snprintf (key_prefix_cumulative, GF_DUMP_MAX_BUF_LEN, "%s.cumulative", this->name); snprintf (key_prefix_incremental, GF_DUMP_MAX_BUF_LEN, "%s.incremental", this->name); for (i = 0; i < GF_FOP_MAXVALUE; i++) { count = GF_ATOMIC_GET (conf->cumulative.fop_hits[i]); total = conf->cumulative.latency[i].total; min = conf->cumulative.latency[i].min; max = conf->cumulative.latency[i].max; avg = conf->cumulative.latency[i].avg; gf_proc_dump_build_key (key, key_prefix_cumulative, "%s", (char *)gf_fop_list[i]); gf_proc_dump_write (key,"%"PRId64",%"PRId64",%.03f,%.03f,%.03f", count, total, min, max, avg); count = GF_ATOMIC_GET (conf->incremental.fop_hits[i]); total = conf->incremental.latency[i].total; min = conf->incremental.latency[i].min; max = conf->incremental.latency[i].max; avg = conf->incremental.latency[i].avg; gf_proc_dump_build_key (key, key_prefix_incremental, "%s", (char *)gf_fop_list[i]); gf_proc_dump_write (key,"%"PRId64",%"PRId64",%.03f,%.03f,%.03f", count, total, min, max, avg); } return 0; } static void ios_set_log_format_code (struct ios_conf *conf) { if (strcmp (conf->dump_format_str, "json") == 0) conf->dump_format = IOS_DUMP_TYPE_JSON_FILE; else if (strcmp (conf->dump_format_str, "text") == 0) conf->dump_format = IOS_DUMP_TYPE_FILE; else if (strcmp (conf->dump_format_str, "dict") == 0) conf->dump_format = IOS_DUMP_TYPE_DICT; else if (strcmp (conf->dump_format_str, "samples") == 0) conf->dump_format = IOS_DUMP_TYPE_SAMPLES; } int reconfigure (xlator_t *this, dict_t *options) { struct ios_conf *conf = NULL; int ret = -1; char *sys_log_str = NULL; char *log_format_str = NULL; char *logger_str = NULL; int sys_log_level = -1; char *log_str = NULL; int log_level = -1; int log_format = -1; int logger = -1; uint32_t log_buf_size = 0; uint32_t log_flush_timeout = 0; int32_t old_dump_interval; if (!this || !this->private) goto out; conf = this->private; GF_OPTION_RECONF ("dump-fd-stats", conf->dump_fd_stats, options, bool, out); GF_OPTION_RECONF ("count-fop-hits", conf->count_fop_hits, options, bool, out); GF_OPTION_RECONF ("latency-measurement", conf->measure_latency, options, bool, out); old_dump_interval = conf->ios_dump_interval; GF_OPTION_RECONF ("ios-dump-interval", conf->ios_dump_interval, options, int32, out); if ((old_dump_interval <= 0) && (conf->ios_dump_interval > 0)) { ret = gf_thread_create (&conf->dump_thread, NULL, (void *) &_ios_dump_thread, this, "iosdump"); if (ret) { gf_log (this ? this->name : "io-stats", GF_LOG_ERROR, "Failed to start thread" "while reconfigure. Returning %d", ret); goto out; } } GF_OPTION_RECONF ("ios-sample-interval", conf->ios_sample_interval, options, int32, out); GF_OPTION_RECONF ("ios-dump-format", conf->dump_format_str, options, str, out); ios_set_log_format_code (conf); GF_OPTION_RECONF ("ios-sample-buf-size", conf->ios_sample_buf_size, options, int32, out); GF_OPTION_RECONF ("sys-log-level", sys_log_str, options, str, out); if (sys_log_str) { sys_log_level = glusterd_check_log_level (sys_log_str); set_sys_log_level (sys_log_level); } GF_OPTION_RECONF ("log-level", log_str, options, str, out); if (log_str) { log_level = glusterd_check_log_level (log_str); gf_log_set_loglevel (this->ctx, log_level); } GF_OPTION_RECONF ("logger", logger_str, options, str, out); if (logger_str) { logger = gf_check_logger (logger_str); gf_log_set_logger (logger); } GF_OPTION_RECONF ("log-format", log_format_str, options, str, out); if (log_format_str) { log_format = gf_check_log_format (log_format_str); gf_log_set_logformat (log_format); } GF_OPTION_RECONF ("log-buf-size", log_buf_size, options, uint32, out); gf_log_set_log_buf_size (log_buf_size); GF_OPTION_RECONF ("log-flush-timeout", log_flush_timeout, options, time, out); gf_log_set_log_flush_timeout (log_flush_timeout); ret = 0; out: gf_log (this ? this->name : "io-stats", GF_LOG_DEBUG, "reconfigure returning %d", ret); return ret; } int32_t mem_acct_init (xlator_t *this) { int ret = -1; if (!this) return ret; ret = xlator_mem_acct_init (this, gf_io_stats_mt_end + 1); if (ret != 0) { gf_log (this->name, GF_LOG_ERROR, "Memory accounting init" " failed"); return ret; } return ret; } void ios_conf_destroy (struct ios_conf *conf) { if (!conf) return; ios_destroy_top_stats (conf); _ios_destroy_dump_thread (conf); ios_destroy_sample_buf (conf->ios_sample_buf); LOCK_DESTROY (&conf->lock); GF_FREE(conf->dnscache); GF_FREE(conf); } static void ios_init_stats (struct ios_global_stats *stats) { int i = 0; GF_ATOMIC_INIT (stats->data_read, 0); GF_ATOMIC_INIT (stats->data_written, 0); for (i = 0; i < IOS_BLOCK_COUNT_SIZE; i++) { GF_ATOMIC_INIT (stats->block_count_write[i], 0); GF_ATOMIC_INIT (stats->block_count_read[i], 0); } for (i = 0; i < GF_FOP_MAXVALUE; i++) GF_ATOMIC_INIT (stats->fop_hits[i], 0); for (i = 0; i < GF_UPCALL_FLAGS_MAXVALUE; i++) GF_ATOMIC_INIT (stats->upcall_hits[i], 0); gettimeofday (&stats->started_at, NULL); } int init (xlator_t *this) { struct ios_conf *conf = NULL; char *sys_log_str = NULL; char *logger_str = NULL; char *log_format_str = NULL; int logger = -1; int log_format = -1; int sys_log_level = -1; char *log_str = NULL; int log_level = -1; int ret = -1; uint32_t log_buf_size = 0; uint32_t log_flush_timeout = 0; if (!this) return -1; if (!this->children) { gf_log (this->name, GF_LOG_ERROR, "io_stats translator requires atleast one subvolume"); return -1; } if (!this->parents) { /* This is very much valid as io-stats currently is loaded * on top of volumes on both client and server, hence this is * not an warning message */ gf_log (this->name, GF_LOG_DEBUG, "dangling volume. check volfile "); } conf = GF_CALLOC (1, sizeof(*conf), gf_io_stats_mt_ios_conf); if (!conf) goto out; if (dict_get_str (this->options, "unique-id", &conf->unique_id) != 0) { /* This is always set on servers, so we must be a client. */ conf->unique_id = this->name; } /* * Init it just after calloc, so that we are sure the lock is inited * in case of error paths. */ LOCK_INIT (&conf->lock); LOCK_INIT (&conf->ios_sampling_lock); ios_init_stats (&conf->cumulative); ios_init_stats (&conf->incremental); ret = ios_init_top_stats (conf); if (ret) goto out; GF_OPTION_INIT ("dump-fd-stats", conf->dump_fd_stats, bool, out); GF_OPTION_INIT ("count-fop-hits", conf->count_fop_hits, bool, out); GF_OPTION_INIT ("latency-measurement", conf->measure_latency, bool, out); GF_OPTION_INIT ("ios-dump-interval", conf->ios_dump_interval, int32, out); GF_OPTION_INIT ("ios-sample-interval", conf->ios_sample_interval, int32, out); GF_OPTION_INIT ("ios-dump-format", conf->dump_format_str, str, out); ios_set_log_format_code (conf); GF_OPTION_INIT ("ios-sample-buf-size", conf->ios_sample_buf_size, int32, out); ret = ios_init_sample_buf (conf); if (ret) { gf_log (this->name, GF_LOG_ERROR, "Out of memory."); goto out; } GF_OPTION_INIT ("ios-dnscache-ttl-sec", conf->ios_dnscache_ttl_sec, int32, out); conf->dnscache = gf_dnscache_init (conf->ios_dnscache_ttl_sec); GF_OPTION_INIT ("sys-log-level", sys_log_str, str, out); if (sys_log_str) { sys_log_level = glusterd_check_log_level (sys_log_str); set_sys_log_level (sys_log_level); } GF_OPTION_INIT ("log-level", log_str, str, out); if (log_str) { log_level = glusterd_check_log_level (log_str); if (DEFAULT_LOG_LEVEL != log_level) gf_log_set_loglevel (this->ctx, log_level); } GF_OPTION_INIT ("logger", logger_str, str, out); if (logger_str) { logger = gf_check_logger (logger_str); gf_log_set_logger (logger); } GF_OPTION_INIT ("log-format", log_format_str, str, out); if (log_format_str) { log_format = gf_check_log_format (log_format_str); gf_log_set_logformat (log_format); } GF_OPTION_INIT ("log-buf-size", log_buf_size, uint32, out); gf_log_set_log_buf_size (log_buf_size); GF_OPTION_INIT ("log-flush-timeout", log_flush_timeout, time, out); gf_log_set_log_flush_timeout (log_flush_timeout); this->private = conf; if (conf->ios_dump_interval > 0) { ret = gf_thread_create (&conf->dump_thread, NULL, (void *) &_ios_dump_thread, this, "iosdump"); if (ret) { gf_log (this ? this->name : "io-stats", GF_LOG_ERROR, "Failed to start thread" "in init. Returning %d", ret); goto out; } } return 0; out: ios_conf_destroy (conf); return ret; } void fini (xlator_t *this) { struct ios_conf *conf = NULL; if (!this) return; conf = this->private; ios_conf_destroy (conf); this->private = NULL; gf_log (this->name, GF_LOG_INFO, "io-stats translator unloaded"); return; } int notify (xlator_t *this, int32_t event, void *data, ...) { int ret = 0; struct ios_dump_args args = {0}; dict_t *output = NULL; dict_t *dict = NULL; int32_t op = 0; int32_t list_cnt = 0; double throughput = 0; double time = 0; gf_boolean_t is_peek = _gf_false; va_list ap; struct gf_upcall *up_data = NULL; struct gf_upcall_cache_invalidation *up_ci = NULL; dict = data; va_start (ap, data); output = va_arg (ap, dict_t*); va_end (ap); switch (event) { case GF_EVENT_TRANSLATOR_INFO: ret = dict_get_str_boolean (dict, "clear-stats", _gf_false); if (ret) { ret = dict_set_int32 (output, "top-op", op); if (ret) { gf_log (this->name, GF_LOG_ERROR, "Failed to set top-op in dict"); goto out; } ios_destroy_top_stats (this->private); ret = ios_init_top_stats (this->private); if (ret) gf_log (this->name, GF_LOG_ERROR, "Failed to reset top stats"); ret = dict_set_int32 (output, "stats-cleared", ret ? 0 : 1); if (ret) gf_log (this->name, GF_LOG_ERROR, "Failed to set stats-cleared" " in dict"); goto out; } ret = dict_get_int32 (dict, "top-op", &op); if (!ret) { ret = dict_get_int32 (dict, "list-cnt", &list_cnt); if (op > IOS_STATS_TYPE_NONE && op < IOS_STATS_TYPE_MAX) ret = io_stats_dump_stats_to_dict (this, output, op, list_cnt); if (op == IOS_STATS_TYPE_READ_THROUGHPUT || op == IOS_STATS_TYPE_WRITE_THROUGHPUT) { ret = dict_get_double (dict, "throughput", &throughput); if (!ret) { ret = dict_get_double (dict, "time", &time); if (ret) goto out; ret = dict_set_double (output, "throughput", throughput); if (ret) goto out; ret = dict_set_double (output, "time", time); if (ret) goto out; } ret = 0; } } else { ret = dict_get_int32 (dict, "info-op", &op); if (ret || op < GF_CLI_INFO_ALL || GF_CLI_INFO_CLEAR < op) op = GF_CLI_INFO_ALL; ret = dict_set_int32 (output, "info-op", op); if (ret) { gf_log (this->name, GF_LOG_ERROR, "Failed to set info-op in dict"); goto out; } if (GF_CLI_INFO_CLEAR == op) { ret = io_stats_clear (this->private); if (ret) gf_log (this->name, GF_LOG_ERROR, "Failed to clear info stats"); ret = dict_set_int32 (output, "stats-cleared", ret ? 0 : 1); if (ret) gf_log (this->name, GF_LOG_ERROR, "Failed to set stats-cleared" " in dict"); } else { ret = dict_get_str_boolean (dict, "peek", _gf_false); if (-1 != ret) is_peek = ret; (void) ios_dump_args_init (&args, IOS_DUMP_TYPE_DICT, output); ret = io_stats_dump (this, &args, op, is_peek); } } break; case GF_EVENT_UPCALL: up_data = (struct gf_upcall *)data; ios_bump_upcall (this, GF_UPCALL); switch (up_data->event_type) { case GF_UPCALL_RECALL_LEASE: ios_bump_upcall (this, GF_UPCALL_LEASE_RECALL); break; case GF_UPCALL_CACHE_INVALIDATION: up_ci = (struct gf_upcall_cache_invalidation *)up_data->data; if (up_ci->flags & (UP_XATTR | UP_XATTR_RM)) ios_bump_upcall (this, GF_UPCALL_CI_XATTR); if (up_ci->flags & IATT_UPDATE_FLAGS) ios_bump_upcall (this, GF_UPCALL_CI_STAT); if (up_ci->flags & UP_RENAME_FLAGS) ios_bump_upcall (this, GF_UPCALL_CI_RENAME); if (up_ci->flags & UP_FORGET) ios_bump_upcall (this, GF_UPCALL_CI_FORGET); if (up_ci->flags & UP_NLINK) ios_bump_upcall (this, GF_UPCALL_CI_NLINK); break; default: gf_msg_debug (this->name, 0, "Unknown upcall event " "type :%d", up_data->event_type); break; } default_notify (this, event, data); break; default: default_notify (this, event, data); break; } out: return ret; } struct xlator_dumpops dumpops = { .priv = io_priv }; struct xlator_fops fops = { .stat = io_stats_stat, .readlink = io_stats_readlink, .mknod = io_stats_mknod, .mkdir = io_stats_mkdir, .unlink = io_stats_unlink, .rmdir = io_stats_rmdir, .symlink = io_stats_symlink, .rename = io_stats_rename, .link = io_stats_link, .truncate = io_stats_truncate, .open = io_stats_open, .readv = io_stats_readv, .writev = io_stats_writev, .statfs = io_stats_statfs, .flush = io_stats_flush, .fsync = io_stats_fsync, .setxattr = io_stats_setxattr, .getxattr = io_stats_getxattr, .removexattr = io_stats_removexattr, .fsetxattr = io_stats_fsetxattr, .fgetxattr = io_stats_fgetxattr, .fremovexattr = io_stats_fremovexattr, .opendir = io_stats_opendir, .readdir = io_stats_readdir, .readdirp = io_stats_readdirp, .fsyncdir = io_stats_fsyncdir, .access = io_stats_access, .ftruncate = io_stats_ftruncate, .fstat = io_stats_fstat, .create = io_stats_create, .lk = io_stats_lk, .inodelk = io_stats_inodelk, .finodelk = io_stats_finodelk, .entrylk = io_stats_entrylk, .fentrylk = io_stats_fentrylk, .lookup = io_stats_lookup, .xattrop = io_stats_xattrop, .fxattrop = io_stats_fxattrop, .setattr = io_stats_setattr, .fsetattr = io_stats_fsetattr, .fallocate = io_stats_fallocate, .discard = io_stats_discard, .zerofill = io_stats_zerofill, .ipc = io_stats_ipc, .rchecksum = io_stats_rchecksum, .seek = io_stats_seek, .lease = io_stats_lease, .getactivelk = io_stats_getactivelk, .setactivelk = io_stats_setactivelk, .compound = io_stats_compound, }; struct xlator_cbks cbks = { .release = io_stats_release, .releasedir = io_stats_releasedir, .forget = io_stats_forget, }; struct volume_options options[] = { { .key = {"dump-fd-stats"}, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .type = GF_OPTION_TYPE_BOOL, .default_value = "off", .description = "If on stats related to file-operations would be " "tracked inside GlusterFS data-structures." }, { .key = { "ios-dump-interval" }, .type = GF_OPTION_TYPE_INT, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = 0, .max = 3600, .default_value = "0", .description = "Interval (in seconds) at which to auto-dump " "statistics. Zero disables automatic dumping." }, { .key = { "ios-sample-interval" }, .type = GF_OPTION_TYPE_INT, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = 0, .max = 65535, .default_value = "0", .description = "Interval in which we want to collect FOP latency " "samples. 2 means collect a sample every 2nd FOP." }, { .key = {"ios-dump-format"}, .type = GF_OPTION_TYPE_STR, .op_version = {GD_OP_VERSION_3_12_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = "json", .description = " The dump-format option specifies the format in which" " to dump the statistics. Select between \"text\", " "\"json\", \"dict\" and \"samples\". Default is " "\"json\".", .value = { "text", "json", "dict", "samples"} }, { .key = { "ios-sample-buf-size" }, .type = GF_OPTION_TYPE_INT, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = 1024, .max = 1024*1024, .default_value = "65535", .description = "The maximum size of our FOP sampling ring buffer." }, { .key = { "ios-dnscache-ttl-sec" }, .type = GF_OPTION_TYPE_INT, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = 1, .max = 3600 * 72, .default_value = "86400", .description = "The interval after wish a cached DNS entry will be " "re-validated. Default: 24 hrs" }, { .key = { "latency-measurement" }, .type = GF_OPTION_TYPE_BOOL, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = "off", .description = "If on stats related to the latency of each operation " "would be tracked inside GlusterFS data-structures. " }, { .key = {"count-fop-hits"}, .type = GF_OPTION_TYPE_BOOL, .op_version = {1}, .flags = OPT_FLAG_SETTABLE, .tags = {"io-stats"}, }, { .key = {"log-level"}, .type = GF_OPTION_TYPE_STR, .value = { "DEBUG", "WARNING", "ERROR", "INFO", "CRITICAL", "NONE", "TRACE"} }, /* These are synthetic entries to assist validation of CLI's * * volume set command */ { .key = {"client-log-level"}, .type = GF_OPTION_TYPE_STR, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_CLIENT_OPT | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = "INFO", .description = "Changes the log-level of the clients", .value = { "DEBUG", "WARNING", "ERROR", "INFO", "CRITICAL", "NONE", "TRACE"} }, { .key = {"sys-log-level"}, .type = GF_OPTION_TYPE_STR, .default_value = "CRITICAL", .description = "Gluster's syslog log-level", .value = { "WARNING", "ERROR", "INFO", "CRITICAL"} }, { .key = {"brick-log-level"}, .type = GF_OPTION_TYPE_STR, .op_version = {1}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = "INFO", .description = "Changes the log-level of the bricks", .value = { "DEBUG", "WARNING", "ERROR", "INFO", "CRITICAL", "NONE", "TRACE"} }, { .key = {"logger"}, .type = GF_OPTION_TYPE_STR, .value = { GF_LOGGER_GLUSTER_LOG, GF_LOGGER_SYSLOG} }, { .key = {"client-logger"}, .type = GF_OPTION_TYPE_STR, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_CLIENT_OPT | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = GF_LOGGER_GLUSTER_LOG, .description = "Changes the logging sub-system to log to, for the " "clients", .value = { GF_LOGGER_GLUSTER_LOG, GF_LOGGER_SYSLOG} }, { .key = {"brick-logger"}, .type = GF_OPTION_TYPE_STR, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = GF_LOGGER_GLUSTER_LOG, .description = "Changes the logging sub-system to log to, for the " "bricks", .value = { GF_LOGGER_GLUSTER_LOG, GF_LOGGER_SYSLOG} }, { .key = {"log-format"}, .type = GF_OPTION_TYPE_STR, .value = { GF_LOG_FORMAT_NO_MSG_ID, GF_LOG_FORMAT_WITH_MSG_ID} }, { .key = {"client-log-format"}, .type = GF_OPTION_TYPE_STR, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_CLIENT_OPT | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = GF_LOG_FORMAT_WITH_MSG_ID, .description = "Changes log format for the clients", .value = { GF_LOG_FORMAT_NO_MSG_ID, GF_LOG_FORMAT_WITH_MSG_ID} }, { .key = {"brick-log-format"}, .type = GF_OPTION_TYPE_STR, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .default_value = GF_LOG_FORMAT_WITH_MSG_ID, .description = "Changes the log format for the bricks", .value = { GF_LOG_FORMAT_NO_MSG_ID, GF_LOG_FORMAT_WITH_MSG_ID} }, { .key = {"log-buf-size"}, .type = GF_OPTION_TYPE_INT, .min = GF_LOG_LRU_BUFSIZE_MIN, .max = GF_LOG_LRU_BUFSIZE_MAX, .default_value = "5", }, { .key = {"client-log-buf-size"}, .type = GF_OPTION_TYPE_INT, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_CLIENT_OPT | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = GF_LOG_LRU_BUFSIZE_MIN, .max = GF_LOG_LRU_BUFSIZE_MAX, .default_value = "5", .description = "This option determines the maximum number of unique " "log messages that can be buffered for a time equal to" " the value of the option client-log-flush-timeout." }, { .key = {"brick-log-buf-size"}, .type = GF_OPTION_TYPE_INT, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = GF_LOG_LRU_BUFSIZE_MIN, .max = GF_LOG_LRU_BUFSIZE_MAX, .default_value = "5", .description = "This option determines the maximum number of unique " "log messages that can be buffered for a time equal to" " the value of the option brick-log-flush-timeout." }, { .key = {"log-flush-timeout"}, .type = GF_OPTION_TYPE_TIME, .min = GF_LOG_FLUSH_TIMEOUT_MIN, .max = GF_LOG_FLUSH_TIMEOUT_MAX, .default_value = "120", }, { .key = {"client-log-flush-timeout"}, .type = GF_OPTION_TYPE_TIME, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_CLIENT_OPT | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = GF_LOG_FLUSH_TIMEOUT_MIN, .max = GF_LOG_FLUSH_TIMEOUT_MAX, .default_value = "120", .description = "This option determines the maximum number of unique " "log messages that can be buffered for a time equal to" " the value of the option client-log-flush-timeout." }, { .key = {"brick-log-flush-timeout"}, .type = GF_OPTION_TYPE_TIME, .op_version = {GD_OP_VERSION_3_6_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"io-stats"}, .min = GF_LOG_FLUSH_TIMEOUT_MIN, .max = GF_LOG_FLUSH_TIMEOUT_MAX, .default_value = "120", .description = "This option determines the maximum number of unique " "log messages that can be buffered for a time equal to" " the value of the option brick-log-flush-timeout." }, { .key = {"unique-id"}, .type = GF_OPTION_TYPE_STR, .default_value = "/no/such/path", .description = "Unique ID for our files." }, { .key = {NULL} }, };