/* Copyright (c) 2015 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. */ #ifndef _CONFIG_H #define _CONFIG_H #include "config.h" #endif #include #include "dht-common.h" #include "tier.h" #include "tier-common.h" #include "syscall.h" /*Hard coded DB info*/ static gfdb_db_type_t dht_tier_db_type = GFDB_SQLITE3; /*Hard coded DB info*/ /*Mutex for updating the data movement stats*/ static pthread_mutex_t dm_stat_mutex = PTHREAD_MUTEX_INITIALIZER; static char *promotion_qfile; static char *demotion_qfile; static void *libhandle; static gfdb_methods_t gfdb_methods; #define DB_QUERY_RECORD_SIZE 4096 static int tier_check_same_node (xlator_t *this, loc_t *loc, gf_defrag_info_t *defrag) { int ret = -1; dict_t *dict = NULL; char *uuid_str = NULL; uuid_t node_uuid = {0,}; GF_VALIDATE_OR_GOTO ("tier", this, out); GF_VALIDATE_OR_GOTO (this->name, loc, out); GF_VALIDATE_OR_GOTO (this->name, defrag, out); if (syncop_getxattr (this, loc, &dict, GF_XATTR_NODE_UUID_KEY, NULL, NULL)) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Unable to get NODE_UUID_KEY %s %s\n", loc->name, loc->path); goto out; } if (dict_get_str (dict, GF_XATTR_NODE_UUID_KEY, &uuid_str) < 0) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to get node-uuid for %s", loc->path); goto out; } if (gf_uuid_parse (uuid_str, node_uuid)) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "uuid_parse failed for %s", loc->path); goto out; } if (gf_uuid_compare (node_uuid, defrag->node_uuid)) { gf_msg_trace (this->name, 0, "%s does not belong to this node", loc->path); ret = 1; goto out; } ret = 0; out: if (dict) dict_unref(dict); return ret; } int tier_do_migration (xlator_t *this, int promote) { gf_defrag_info_t *defrag = NULL; dht_conf_t *conf = NULL; long rand = 0; int migrate = 0; gf_tier_conf_t *tier_conf = NULL; conf = this->private; if (!conf) goto exit; defrag = conf->defrag; if (!defrag) goto exit; if (defrag->tier_conf.mode != TIER_MODE_WM) { migrate = 1; goto exit; } tier_conf = &defrag->tier_conf; switch (tier_conf->watermark_last) { case TIER_WM_LOW: migrate = promote ? 1 : 0; break; case TIER_WM_HI: migrate = promote ? 0 : 1; break; case TIER_WM_MID: rand = random() % 100; if (promote) { migrate = (rand > tier_conf->percent_full); } else { migrate = (rand <= tier_conf->percent_full); } break; } exit: return migrate; } int tier_check_watermark (xlator_t *this, loc_t *root_loc) { tier_watermark_op_t wm = TIER_WM_NONE; int ret = -1; gf_defrag_info_t *defrag = NULL; dht_conf_t *conf = NULL; dict_t *xdata = NULL; struct statvfs statfs = {0, }; gf_tier_conf_t *tier_conf = NULL; conf = this->private; if (!conf) goto exit; defrag = conf->defrag; if (!defrag) goto exit; tier_conf = &defrag->tier_conf; if (tier_conf->mode != TIER_MODE_WM) { ret = 0; goto exit; } /* Find how much free space is on the hot subvolume. Then see if that value */ /* is less than or greater than user defined watermarks. Stash results in */ /* the tier_conf data structure. */ ret = syncop_statfs (conf->subvolumes[1], root_loc, &statfs, xdata, NULL); if (ret) { gf_msg (this->name, GF_LOG_ERROR, -ret, DHT_MSG_LOG_TIER_STATUS, "Unable to obtain statfs."); goto exit; } pthread_mutex_lock (&dm_stat_mutex); tier_conf->blocks_total = statfs.f_blocks; tier_conf->blocks_used = statfs.f_blocks - statfs.f_bfree; tier_conf->percent_full = (100 * tier_conf->blocks_used) / statfs.f_blocks; pthread_mutex_unlock (&dm_stat_mutex); if (tier_conf->percent_full < tier_conf->watermark_low) { wm = TIER_WM_LOW; } else if (tier_conf->percent_full < tier_conf->watermark_hi) { wm = TIER_WM_MID; } else { wm = TIER_WM_HI; } if (wm != tier_conf->watermark_last) { tier_conf->watermark_last = wm; gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Tier watermark now %d", wm); } exit: return ret; } static int tier_migrate_using_query_file (void *_args) { int ret = -1; query_cbk_args_t *query_cbk_args = (query_cbk_args_t *) _args; xlator_t *this = NULL; gf_defrag_info_t *defrag = NULL; gfdb_query_record_t *query_record = NULL; gfdb_link_info_t *link_info = NULL; struct iatt par_stbuf = {0,}; struct iatt current = {0,}; loc_t p_loc = {0,}; loc_t loc = {0,}; dict_t *migrate_data = NULL; dict_t *xdata_request = NULL; dict_t *xdata_response = NULL; char *parent_path = NULL; inode_t *linked_inode = NULL; /* * per_file_status and per_link_status * 0 : success * -1 : failure * 1 : ignore the status and dont count for migration * */ int per_file_status = 0; int per_link_status = 0; int total_status = 0; int query_fd = 0; xlator_t *src_subvol = NULL; dht_conf_t *conf = NULL; uint64_t total_migrated_bytes = 0; int total_files = 0; GF_VALIDATE_OR_GOTO ("tier", query_cbk_args, out); GF_VALIDATE_OR_GOTO ("tier", query_cbk_args->this, out); this = query_cbk_args->this; GF_VALIDATE_OR_GOTO (this->name, query_cbk_args->defrag, out); GF_VALIDATE_OR_GOTO (this->name, (query_cbk_args->query_fd > 0), out); GF_VALIDATE_OR_GOTO (this->name, this->private, out); conf = this->private; defrag = query_cbk_args->defrag; query_fd = query_cbk_args->query_fd; migrate_data = dict_new (); if (!migrate_data) goto out; xdata_request = dict_new (); if (!xdata_request) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to create xdata_request dict"); goto out; } ret = dict_set_int32 (xdata_request, GET_ANCESTRY_PATH_KEY, 42); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to set value to dict : key %s \n", GET_ANCESTRY_PATH_KEY); goto out; } /* Per file */ while ((ret = gfdb_methods.gfdb_read_query_record (query_fd, &query_record)) != 0) { if (ret < 0) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to fetch query record " "from query file"); goto out; } per_file_status = 0; per_link_status = 0; dict_del (migrate_data, GF_XATTR_FILE_MIGRATE_KEY); dict_del (migrate_data, "from.migrator"); if (defrag->tier_conf.request_pause) { gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Tiering paused. " "Exiting tier_migrate_using_query_file"); break; } if (!tier_do_migration (this, query_cbk_args->is_promotion)) { gfdb_methods.gfdb_query_record_free (query_record); query_record = NULL; continue; } if (!list_empty (&query_record->link_list)) { per_file_status = dict_set_str (migrate_data, GF_XATTR_FILE_MIGRATE_KEY, "force"); if (per_file_status) { goto per_file_out; } /* Flag to suggest the xattr call is from migrator */ per_file_status = dict_set_str (migrate_data, "from.migrator", "yes"); if (per_file_status) { goto per_file_out; } /* Flag to suggest its a tiering migration * The reason for this dic key-value is that * promotions and demotions are multithreaded * so the original frame from gf_defrag_start() * is not carried. A new frame will be created when * we do syncop_setxattr(). This doesnot have the * frame->root->pid of the original frame. So we pass * this dic key-value when we do syncop_setxattr() to do * data migration and set the frame->root->pid to * GF_CLIENT_PID_TIER_DEFRAG in dht_setxattr() just before * calling dht_start_rebalance_task() */ per_file_status = dict_set_str (migrate_data, TIERING_MIGRATION_KEY, "yes"); if (per_file_status) { goto per_file_out; } } per_link_status = 0; /* For now we only support single link migration. And we will * ignore other hard links in the link info list of query record * TODO: Multiple hard links migration */ if (!list_empty (&query_record->link_list)) { link_info = list_first_entry (&query_record->link_list, gfdb_link_info_t, list); } if (link_info != NULL) { /* Lookup for parent and get the path of parent */ gf_uuid_copy (p_loc.gfid, link_info->pargfid); p_loc.inode = inode_new (defrag->root_inode->table); if (!p_loc.inode) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to create reference to inode"); per_link_status = -1; goto abort; } ret = syncop_lookup (this, &p_loc, &par_stbuf, NULL, xdata_request, &xdata_response); if (ret) { gf_msg (this->name, GF_LOG_ERROR, -ret, DHT_MSG_LOG_TIER_ERROR, " Error in parent lookup\n"); per_link_status = -1; goto abort; } ret = dict_get_str (xdata_response, GET_ANCESTRY_PATH_KEY, &parent_path); if (ret || !parent_path) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to get parent path\n"); per_link_status = -1; goto abort; } linked_inode = inode_link (p_loc.inode, NULL, NULL, &par_stbuf); inode_unref (p_loc.inode); p_loc.inode = linked_inode; /* Preparing File Inode */ gf_uuid_copy (loc.gfid, query_record->gfid); loc.inode = inode_new (defrag->root_inode->table); gf_uuid_copy (loc.pargfid, link_info->pargfid); loc.parent = inode_ref (p_loc.inode); /* Get filename and Construct file path */ loc.name = gf_strdup (link_info->file_name); if (!loc.name) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Memory " "allocation failed.\n"); per_link_status = -1; goto abort; } ret = gf_asprintf((char **)&(loc.path), "%s/%s", parent_path, loc.name); if (ret < 0) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed to " "construct file path for %s %s\n", parent_path, loc.name); per_link_status = -1; goto abort; } gf_uuid_copy (loc.parent->gfid, link_info->pargfid); /* lookup file inode */ ret = syncop_lookup (this, &loc, ¤t, NULL, NULL, NULL); if (ret) { gf_msg (this->name, GF_LOG_ERROR, -ret, DHT_MSG_LOG_TIER_ERROR, "Failed to do " "lookup on file %s\n", loc.name); per_link_status = -1; goto abort; } linked_inode = inode_link (loc.inode, NULL, NULL, ¤t); inode_unref (loc.inode); loc.inode = linked_inode; /* * Do not promote/demote if file already is where it * should be. It means another brick moved the file * so is not an error. */ src_subvol = dht_subvol_get_cached (this, loc.inode); if (src_subvol == NULL) goto abort; if (query_cbk_args->is_promotion && src_subvol == conf->subvolumes[1]) { goto abort; } if (!query_cbk_args->is_promotion && src_subvol == conf->subvolumes[0]) { goto abort; } gf_msg_debug (this->name, 0, "Tier %d" " src_subvol %s file %s", query_cbk_args->is_promotion, src_subvol->name, loc.name); ret = tier_check_same_node (this, &loc, defrag); if (ret != 0) { if (ret < 0) { per_link_status = -1; goto abort; } ret = 0; /* By setting per_link_status to 1 we are * ignoring this status and will not be counting * this file for migration */ per_link_status = 1; goto abort; } gf_uuid_copy (loc.gfid, loc.inode->gfid); if (defrag->tier_conf.request_pause) { gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Tiering paused. " "Exiting " "tier_migrate_using_query_file"); goto abort; } /* Data migration */ ret = syncop_setxattr (this, &loc, migrate_data, 0, NULL, NULL); if (ret) { gf_msg (this->name, GF_LOG_ERROR, -ret, DHT_MSG_LOG_TIER_ERROR, "Failed to " "migrate %s \n", loc.name); per_link_status = -1; goto abort; } if (query_cbk_args->is_promotion) { defrag->total_files_promoted++; total_migrated_bytes += defrag->tier_conf.st_last_promoted_size; pthread_mutex_lock (&dm_stat_mutex); defrag->tier_conf.blocks_used += defrag->tier_conf.st_last_promoted_size; pthread_mutex_unlock (&dm_stat_mutex); } else { defrag->total_files_demoted++; total_migrated_bytes += defrag->tier_conf.st_last_demoted_size; pthread_mutex_lock (&dm_stat_mutex); defrag->tier_conf.blocks_used -= defrag->tier_conf.st_last_demoted_size; pthread_mutex_unlock (&dm_stat_mutex); } if (defrag->tier_conf.blocks_total) { pthread_mutex_lock (&dm_stat_mutex); defrag->tier_conf.percent_full = (100 * defrag->tier_conf.blocks_used) / defrag->tier_conf.blocks_total; pthread_mutex_unlock (&dm_stat_mutex); } abort: GF_FREE ((char *) loc.name); loc.name = NULL; loc_wipe (&loc); loc_wipe (&p_loc); if ((++total_files > defrag->tier_conf.max_migrate_files) || (total_migrated_bytes > defrag->tier_conf.max_migrate_bytes)) { gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Reached cycle migration limit." "migrated bytes %"PRId64" files %d", total_migrated_bytes, total_files); goto out; } } per_file_status = per_link_status; per_file_out: if (per_file_status < 0) {/* Failure */ pthread_mutex_lock (&dm_stat_mutex); defrag->total_failures++; pthread_mutex_unlock (&dm_stat_mutex); } else if (per_file_status == 0) {/* Success */ pthread_mutex_lock (&dm_stat_mutex); defrag->total_files++; pthread_mutex_unlock (&dm_stat_mutex); } else if (per_file_status == 1) {/* Ignore */ per_file_status = 0; } total_status = total_status + per_file_status; per_link_status = 0; per_file_status = 0; gfdb_methods.gfdb_query_record_free (query_record); query_record = NULL; } out: if (xdata_request) { dict_unref (xdata_request); } if (migrate_data) dict_unref (migrate_data); gfdb_methods.gfdb_query_record_free (query_record); query_record = NULL; return total_status; } /* This is the call back function per record/file from data base */ static int tier_gf_query_callback (gfdb_query_record_t *gfdb_query_record, void *_args) { int ret = -1; query_cbk_args_t *query_cbk_args = _args; GF_VALIDATE_OR_GOTO ("tier", query_cbk_args, out); GF_VALIDATE_OR_GOTO ("tier", query_cbk_args->defrag, out); GF_VALIDATE_OR_GOTO ("tier", (query_cbk_args->query_fd > 0), out); ret = gfdb_methods.gfdb_write_query_record (query_cbk_args->query_fd, gfdb_query_record); if (ret) { gf_msg ("tier", GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed writing query record to query file"); goto out; } pthread_mutex_lock (&dm_stat_mutex); query_cbk_args->defrag->num_files_lookedup++; pthread_mutex_unlock (&dm_stat_mutex); ret = 0; out: return ret; } /* Create query file in tier process */ static int tier_process_self_query (tier_brick_list_t *local_brick, void *args) { int ret = -1; char *db_path = NULL; query_cbk_args_t *query_cbk_args = NULL; xlator_t *this = NULL; gfdb_conn_node_t *conn_node = NULL; dict_t *params_dict = NULL; dict_t *ctr_ipc_dict = NULL; gfdb_brick_info_t *gfdb_brick_info = args; /*Init of all the essentials*/ GF_VALIDATE_OR_GOTO ("tier", gfdb_brick_info , out); query_cbk_args = gfdb_brick_info->_query_cbk_args; GF_VALIDATE_OR_GOTO ("tier", query_cbk_args->this, out); this = query_cbk_args->this; GF_VALIDATE_OR_GOTO (this->name, gfdb_brick_info->_query_cbk_args, out); GF_VALIDATE_OR_GOTO (this->name, local_brick, out); GF_VALIDATE_OR_GOTO (this->name, local_brick->xlator, out); GF_VALIDATE_OR_GOTO (this->name, local_brick->brick_db_path, out); db_path = local_brick->brick_db_path; /*Preparing DB parameters before init_db i.e getting db connection*/ params_dict = dict_new (); if (!params_dict) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "DB Params cannot initialized"); goto out; } SET_DB_PARAM_TO_DICT(this->name, params_dict, (char *) gfdb_methods.get_db_path_key(), db_path, ret, out); /*Get the db connection*/ conn_node = gfdb_methods.init_db ((void *)params_dict, dht_tier_db_type); if (!conn_node) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "FATAL: Failed initializing db operations"); goto out; } /* Query for eligible files from db */ query_cbk_args->query_fd = open (GET_QFILE_PATH (gfdb_brick_info->_gfdb_promote), O_WRONLY | O_CREAT | O_APPEND, S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH); if (query_cbk_args->query_fd < 0) { gf_msg (this->name, GF_LOG_ERROR, errno, DHT_MSG_LOG_TIER_ERROR, "Failed to open query file %s", GET_QFILE_PATH (gfdb_brick_info->_gfdb_promote)); goto out; } if (!gfdb_brick_info->_gfdb_promote) { if (query_cbk_args->defrag->write_freq_threshold == 0 && query_cbk_args->defrag->read_freq_threshold == 0) { ret = gfdb_methods.find_unchanged_for_time ( conn_node, tier_gf_query_callback, (void *)query_cbk_args, gfdb_brick_info->time_stamp); } else { ret = gfdb_methods.find_unchanged_for_time_freq ( conn_node, tier_gf_query_callback, (void *)query_cbk_args, gfdb_brick_info->time_stamp, query_cbk_args->defrag-> write_freq_threshold, query_cbk_args->defrag-> read_freq_threshold, _gf_false); } } else { if (query_cbk_args->defrag->write_freq_threshold == 0 && query_cbk_args->defrag->read_freq_threshold == 0) { ret = gfdb_methods.find_recently_changed_files ( conn_node, tier_gf_query_callback, (void *)query_cbk_args, gfdb_brick_info->time_stamp); } else { ret = gfdb_methods.find_recently_changed_files_freq ( conn_node, tier_gf_query_callback, (void *)query_cbk_args, gfdb_brick_info->time_stamp, query_cbk_args->defrag-> write_freq_threshold, query_cbk_args->defrag->read_freq_threshold, _gf_false); } } if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "FATAL: query from db failed"); goto out; } /*Clear the heat on the DB entries*/ /*Preparing ctr_ipc_dict*/ ctr_ipc_dict = dict_new (); if (!ctr_ipc_dict) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "ctr_ipc_dict cannot initialized"); goto out; } SET_DB_PARAM_TO_DICT(this->name, ctr_ipc_dict, GFDB_IPC_CTR_KEY, GFDB_IPC_CTR_CLEAR_OPS, ret, out); ret = syncop_ipc (local_brick->xlator, GF_IPC_TARGET_CTR, ctr_ipc_dict, NULL); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed clearing the heat " "on db %s error %d", local_brick->brick_db_path, ret); goto out; } ret = 0; out: if (params_dict) { dict_unref (params_dict); params_dict = NULL; } if (ctr_ipc_dict) { dict_unref (ctr_ipc_dict); ctr_ipc_dict = NULL; } if (query_cbk_args && query_cbk_args->query_fd >= 0) { close (query_cbk_args->query_fd); query_cbk_args->query_fd = -1; } gfdb_methods.fini_db (conn_node); return ret; } /*Ask CTR to create the query file*/ static int tier_process_ctr_query (tier_brick_list_t *local_brick, void *args) { int ret = -1; query_cbk_args_t *query_cbk_args = NULL; xlator_t *this = NULL; dict_t *ctr_ipc_in_dict = NULL; dict_t *ctr_ipc_out_dict = NULL; gfdb_brick_info_t *gfdb_brick_info = args; gfdb_ipc_ctr_params_t *ipc_ctr_params = NULL; int count = 0; /*Init of all the essentials*/ GF_VALIDATE_OR_GOTO ("tier", gfdb_brick_info , out); query_cbk_args = gfdb_brick_info->_query_cbk_args; GF_VALIDATE_OR_GOTO ("tier", query_cbk_args->this, out); this = query_cbk_args->this; GF_VALIDATE_OR_GOTO (this->name, gfdb_brick_info->_query_cbk_args, out); GF_VALIDATE_OR_GOTO (this->name, local_brick, out); GF_VALIDATE_OR_GOTO (this->name, local_brick->xlator, out); GF_VALIDATE_OR_GOTO (this->name, local_brick->brick_db_path, out); /*Preparing ctr_ipc_in_dict*/ ctr_ipc_in_dict = dict_new (); if (!ctr_ipc_in_dict) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "ctr_ipc_in_dict cannot initialized"); goto out; } ipc_ctr_params = GF_CALLOC (1, sizeof (gfdb_ipc_ctr_params_t), gf_tier_mt_ipc_ctr_params_t); if (!ipc_ctr_params) { goto out; } /* set all the query params*/ ipc_ctr_params->is_promote = gfdb_brick_info->_gfdb_promote; ipc_ctr_params->write_freq_threshold = query_cbk_args-> defrag->write_freq_threshold; ipc_ctr_params->read_freq_threshold = query_cbk_args-> defrag->read_freq_threshold; memcpy (&ipc_ctr_params->time_stamp, gfdb_brick_info->time_stamp, sizeof (gfdb_time_t)); SET_DB_PARAM_TO_DICT(this->name, ctr_ipc_in_dict, GFDB_IPC_CTR_KEY, GFDB_IPC_CTR_QUERY_OPS, ret, out); SET_DB_PARAM_TO_DICT(this->name, ctr_ipc_in_dict, GFDB_IPC_CTR_GET_QFILE_PATH, GET_QFILE_PATH(ipc_ctr_params->is_promote), ret, out); ret = dict_set_bin (ctr_ipc_in_dict, GFDB_IPC_CTR_GET_QUERY_PARAMS, ipc_ctr_params, sizeof (*ipc_ctr_params)); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, LG_MSG_SET_PARAM_FAILED, "Failed setting %s to params dictionary", GFDB_IPC_CTR_GET_QUERY_PARAMS); goto out; } ret = syncop_ipc (local_brick->xlator, GF_IPC_TARGET_CTR, ctr_ipc_in_dict, &ctr_ipc_out_dict); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_IPC_TIER_ERROR, "Failed query on %s ret %d", local_brick->brick_db_path, ret); goto out; } ret = dict_get_int32(ctr_ipc_out_dict, GFDB_IPC_CTR_RET_QUERY_COUNT, &count); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed getting count " "of records on %s", local_brick->brick_db_path); goto out; } if (count < 0) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed query on %s", local_brick->brick_db_path); ret = -1; goto out; } pthread_mutex_lock (&dm_stat_mutex); query_cbk_args->defrag->num_files_lookedup = count; pthread_mutex_unlock (&dm_stat_mutex); ret = 0; out: if (ctr_ipc_in_dict) { dict_unref(ctr_ipc_in_dict); ctr_ipc_in_dict = NULL; } if (ctr_ipc_out_dict) { dict_unref(ctr_ipc_out_dict); ctr_ipc_out_dict = NULL; ipc_ctr_params = NULL; } GF_FREE (ipc_ctr_params); return ret; } /*This is the call back function for each brick from hot/cold bricklist * It picks up each bricks db and queries for eligible files for migration. * The list of eligible files are populated in appropriate query files*/ static int tier_process_brick (tier_brick_list_t *local_brick, void *args) { int ret = -1; dict_t *ctr_ipc_in_dict = NULL; dict_t *ctr_ipc_out_dict = NULL; char *strval = NULL; GF_VALIDATE_OR_GOTO ("tier", local_brick, out); GF_VALIDATE_OR_GOTO ("tier", local_brick->xlator, out); if (dht_tier_db_type == GFDB_SQLITE3) { /*Preparing ctr_ipc_in_dict*/ ctr_ipc_in_dict = dict_new (); if (!ctr_ipc_in_dict) { gf_msg ("tier", GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "ctr_ipc_in_dict cannot initialized"); goto out; } ret = dict_set_str (ctr_ipc_in_dict, GFDB_IPC_CTR_KEY, GFDB_IPC_CTR_GET_DB_PARAM_OPS); if (ret) { gf_msg ("tier", GF_LOG_ERROR, 0,\ LG_MSG_SET_PARAM_FAILED, "Failed setting %s " "to params dictionary", GFDB_IPC_CTR_KEY); goto out; } ret = dict_set_str (ctr_ipc_in_dict, GFDB_IPC_CTR_GET_DB_PARAM_OPS, ""); if (ret) { gf_msg ("tier", GF_LOG_ERROR, 0,\ LG_MSG_SET_PARAM_FAILED, "Failed setting %s " "to params dictionary", GFDB_IPC_CTR_GET_DB_PARAM_OPS); goto out; } ret = dict_set_str (ctr_ipc_in_dict, GFDB_IPC_CTR_GET_DB_KEY, "journal_mode"); if (ret) { gf_msg ("tier", GF_LOG_ERROR, 0, LG_MSG_SET_PARAM_FAILED, "Failed setting %s " "to params dictionary", GFDB_IPC_CTR_GET_DB_KEY);\ goto out; } ret = syncop_ipc (local_brick->xlator, GF_IPC_TARGET_CTR, ctr_ipc_in_dict, &ctr_ipc_out_dict); if (ret || ctr_ipc_out_dict == NULL) { gf_msg ("tier", GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed getting" "journal_mode of sql db %s", local_brick->brick_db_path); goto out; } ret = dict_get_str (ctr_ipc_out_dict, "journal_mode", &strval); if (ret) { gf_msg ("tier", GF_LOG_ERROR, 0, LG_MSG_GET_PARAM_FAILED, "Failed getting %s " "to params dictionary" "journal_mode", strval); goto out; } if (strval && (strncmp(strval, "wal", strlen ("wal")) == 0)) { ret = tier_process_self_query (local_brick, args); if (ret) { goto out; } } else { ret = tier_process_ctr_query (local_brick, args); if (ret) { goto out; } } ret = 0; } else { ret = tier_process_self_query (local_brick, args); if (ret) { goto out; } } ret = 0; out: if (ctr_ipc_in_dict) dict_unref (ctr_ipc_in_dict); if (ctr_ipc_out_dict) dict_unref (ctr_ipc_out_dict); return ret; } static int tier_build_migration_qfile (demotion_args_t *args, query_cbk_args_t *query_cbk_args, gf_boolean_t is_promotion) { gfdb_time_t current_time; gfdb_brick_info_t gfdb_brick_info; gfdb_time_t time_in_past; int ret = -1; tier_brick_list_t *local_brick = NULL; /* * The first time this function is called, query file will * not exist on a given instance of running the migration daemon. * The remove call is optimistic and it is legal if it fails. */ ret = remove (GET_QFILE_PATH (is_promotion)); if (ret == -1) { gf_msg_trace (args->this->name, 0, "Failed to remove %s", GET_QFILE_PATH (is_promotion)); } time_in_past.tv_sec = args->freq_time; time_in_past.tv_usec = 0; ret = gettimeofday (¤t_time, NULL); if (ret == -1) { gf_msg (args->this->name, GF_LOG_ERROR, errno, DHT_MSG_SYS_CALL_GET_TIME_FAILED, "Failed to get current time\n"); goto out; } time_in_past.tv_sec = current_time.tv_sec - time_in_past.tv_sec; /* The migration daemon may run a varrying numberof usec after the sleep */ /* call triggers. A file may be registered in CTR some number of usec X */ /* after the daemon started and missed in the subsequent cycle if the */ /* daemon starts Y usec after the period in seconds where Y>X. Normalize */ /* away this problem by always setting usec to 0. */ time_in_past.tv_usec = 0; gfdb_brick_info.time_stamp = &time_in_past; gfdb_brick_info._gfdb_promote = is_promotion; gfdb_brick_info._query_cbk_args = query_cbk_args; list_for_each_entry (local_brick, args->brick_list, list) { ret = tier_process_brick (local_brick, &gfdb_brick_info); if (ret) { gf_msg (args->this->name, GF_LOG_ERROR, 0, DHT_MSG_BRICK_QUERY_FAILED, "Brick %s query failed\n", local_brick->brick_db_path); } } ret = 0; out: return ret; } static inline int tier_migrate_files_using_qfile (demotion_args_t *comp, query_cbk_args_t *query_cbk_args, char *qfile) { char renamed_file[PATH_MAX] = ""; int ret = -1; query_cbk_args->query_fd = open (qfile, O_RDONLY); if (query_cbk_args->query_fd < 0) { gf_msg ("tier", GF_LOG_ERROR, errno, DHT_MSG_FOPEN_FAILED, "Failed to open %s for migration", qfile); goto out; } ret = tier_migrate_using_query_file ((void *)query_cbk_args); close (query_cbk_args->query_fd); query_cbk_args->query_fd = -1; if (ret) { sprintf (renamed_file, "%s.err", qfile); rename (qfile, renamed_file); } out: return ret; } /*Demotion Thread*/ static void * tier_demote (void *args) { int ret = -1; query_cbk_args_t query_cbk_args; demotion_args_t *demotion_args = args; GF_VALIDATE_OR_GOTO ("tier", demotion_args, out); GF_VALIDATE_OR_GOTO ("tier", demotion_args->this, out); GF_VALIDATE_OR_GOTO (demotion_args->this->name, demotion_args->brick_list, out); GF_VALIDATE_OR_GOTO (demotion_args->this->name, demotion_args->defrag, out); THIS = demotion_args->this; query_cbk_args.this = demotion_args->this; query_cbk_args.defrag = demotion_args->defrag; query_cbk_args.is_promotion = 0; /*Build the query file using bricklist*/ ret = tier_build_migration_qfile (demotion_args, &query_cbk_args, _gf_false); if (ret) goto out; /* Migrate files using the query file */ ret = tier_migrate_files_using_qfile (args, &query_cbk_args, demotion_qfile); if (ret) goto out; out: demotion_args->return_value = ret; return NULL; } /*Promotion Thread*/ static void *tier_promote (void *args) { int ret = -1; query_cbk_args_t query_cbk_args; promotion_args_t *promotion_args = args; GF_VALIDATE_OR_GOTO ("tier", promotion_args->this, out); GF_VALIDATE_OR_GOTO (promotion_args->this->name, promotion_args->brick_list, out); GF_VALIDATE_OR_GOTO (promotion_args->this->name, promotion_args->defrag, out); THIS = promotion_args->this; query_cbk_args.this = promotion_args->this; query_cbk_args.defrag = promotion_args->defrag; query_cbk_args.is_promotion = 1; /*Build the query file using bricklist*/ ret = tier_build_migration_qfile (promotion_args, &query_cbk_args, _gf_true); if (ret) goto out; /* Migrate files using the query file */ ret = tier_migrate_files_using_qfile (args, &query_cbk_args, promotion_qfile); if (ret) goto out; out: promotion_args->return_value = ret; return NULL; } static int tier_get_bricklist (xlator_t *xl, struct list_head *local_bricklist_head) { xlator_list_t *child = NULL; char *rv = NULL; char *rh = NULL; char localhost[256] = {0}; char *brickname = NULL; char db_name[PATH_MAX] = ""; int ret = 0; tier_brick_list_t *local_brick = NULL; GF_VALIDATE_OR_GOTO ("tier", xl, out); GF_VALIDATE_OR_GOTO ("tier", local_bricklist_head, out); gethostname (localhost, sizeof (localhost)); /* * This function obtains remote subvolumes and filters out only * those running on the same node as the tier daemon. */ if (strcmp(xl->type, "protocol/client") == 0) { ret = dict_get_str (xl->options, "remote-host", &rh); if (ret < 0) goto out; if (gf_is_local_addr (rh)) { local_brick = GF_CALLOC (1, sizeof(tier_brick_list_t), gf_tier_mt_bricklist_t); if (!local_brick) { goto out; } ret = dict_get_str (xl->options, "remote-subvolume", &rv); if (ret < 0) goto out; brickname = strrchr(rv, '/') + 1; snprintf(db_name, sizeof(db_name), "%s.db", brickname); local_brick->brick_db_path = GF_CALLOC (PATH_MAX, 1, gf_common_mt_char); if (!local_brick->brick_db_path) { gf_msg ("tier", GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_STATUS, "Failed. to allocate memory for bricklist"); goto out; } sprintf(local_brick->brick_db_path, "%s/%s/%s", rv, GF_HIDDEN_PATH, db_name); local_brick->xlator = xl; list_add_tail (&(local_brick->list), local_bricklist_head); ret = 0; goto out; } } for (child = xl->children; child; child = child->next) { ret = tier_get_bricklist (child->xlator, local_bricklist_head); if (ret) { goto out; } } ret = 0; out: if (ret) { if (local_brick) { GF_FREE (local_brick->brick_db_path); } GF_FREE (local_brick); } return ret; } int tier_get_freq_demote (gf_tier_conf_t *tier_conf) { if ((tier_conf->mode == TIER_MODE_WM) && (tier_conf->watermark_last == TIER_WM_HI)) return DEFAULT_DEMOTE_DEGRADED; else return tier_conf->tier_demote_frequency; } int tier_get_freq_promote (gf_tier_conf_t *tier_conf) { return tier_conf->tier_promote_frequency; } static int tier_check_demote (gfdb_time_t current_time, int freq_demote) { return ((current_time.tv_sec % freq_demote) == 0) ? _gf_true : _gf_false; } static gf_boolean_t tier_check_promote (gf_tier_conf_t *tier_conf, gfdb_time_t current_time, int freq_promote) { if ((tier_conf->mode == TIER_MODE_WM) && (tier_conf->watermark_last == TIER_WM_HI)) return _gf_false; else return ((current_time.tv_sec % freq_promote) == 0) ? _gf_true : _gf_false; } void clear_bricklist (struct list_head *brick_list) { tier_brick_list_t *local_brick = NULL; tier_brick_list_t *temp = NULL; if (list_empty(brick_list)) { return; } list_for_each_entry_safe (local_brick, temp, brick_list, list) { list_del (&local_brick->list); GF_FREE (local_brick->brick_db_path); GF_FREE (local_brick); } } int tier_start (xlator_t *this, gf_defrag_info_t *defrag) { struct list_head bricklist_hot = { 0 }; struct list_head bricklist_cold = { 0 }; dht_conf_t *conf = NULL; gfdb_time_t current_time; int freq_promote = 0; int freq_demote = 0; promotion_args_t promotion_args = { 0 }; demotion_args_t demotion_args = { 0 }; int ret_promotion = 0; int ret_demotion = 0; int ret = 0; pthread_t promote_thread; pthread_t demote_thread; gf_boolean_t is_promotion_triggered = _gf_false; gf_boolean_t is_demotion_triggered = _gf_false; xlator_t *any = NULL; xlator_t *xlator = NULL; gf_tier_conf_t *tier_conf = NULL; loc_t root_loc = { 0 }; conf = this->private; INIT_LIST_HEAD ((&bricklist_hot)); INIT_LIST_HEAD ((&bricklist_cold)); tier_get_bricklist (conf->subvolumes[0], &bricklist_cold); tier_get_bricklist (conf->subvolumes[1], &bricklist_hot); gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Begin run tier promote %d" " demote %d", freq_promote, freq_demote); defrag->defrag_status = GF_DEFRAG_STATUS_STARTED; tier_conf = &defrag->tier_conf; dht_build_root_loc (defrag->root_inode, &root_loc); while (1) { /* * Check if a graph switch occured. If so, stop migration * thread. It will need to be restarted manually. */ any = THIS->ctx->active->first; xlator = xlator_search_by_name (any, this->name); if (xlator != this) { gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Detected graph switch. Exiting migration daemon."); goto out; } if (defrag->tier_conf.request_pause) defrag->tier_conf.paused = _gf_true; else defrag->tier_conf.paused = _gf_false; sleep(1); if (defrag->defrag_status != GF_DEFRAG_STATUS_STARTED) { ret = 1; gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "defrag->defrag_status != " "GF_DEFRAG_STATUS_STARTED"); goto out; } if (defrag->cmd == GF_DEFRAG_CMD_START_DETACH_TIER) { ret = 0; defrag->defrag_status = GF_DEFRAG_STATUS_COMPLETE; gf_msg (this->name, GF_LOG_DEBUG, 0, DHT_MSG_LOG_TIER_ERROR, "defrag->defrag_cmd == " "GF_DEFRAG_CMD_START_DETACH_TIER"); goto out; } if ((defrag->tier_conf.paused) || (defrag->tier_conf.request_pause)) continue; /* To have proper synchronization amongst all * brick holding nodes, so that promotion and demotions * start atomicly w.r.t promotion/demotion frequency * period, all nodes should have thier system time * in-sync with each other either manually set or * using a NTP server*/ ret = gettimeofday (¤t_time, NULL); if (ret == -1) { gf_msg (this->name, GF_LOG_ERROR, errno, DHT_MSG_SYS_CALL_GET_TIME_FAILED, "Failed to get current time"); goto out; } freq_demote = tier_get_freq_demote (tier_conf); is_demotion_triggered = tier_check_demote (current_time, freq_demote); freq_promote = tier_get_freq_promote(tier_conf); is_promotion_triggered = tier_check_promote (tier_conf, current_time, freq_promote); /* If no promotion and no demotion is * scheduled/triggered skip an iteration */ if (!is_promotion_triggered && !is_demotion_triggered) continue; ret = tier_check_watermark (this, &root_loc); if (ret != 0) { gf_msg (this->name, GF_LOG_CRITICAL, errno, DHT_MSG_LOG_TIER_ERROR, "Failed to get watermark"); goto out; } ret_promotion = -1; ret_demotion = -1; if (is_demotion_triggered) { demotion_args.this = this; demotion_args.brick_list = &bricklist_hot; demotion_args.defrag = defrag; demotion_args.freq_time = freq_demote; ret_demotion = pthread_create (&demote_thread, NULL, &tier_demote, &demotion_args); if (ret_demotion) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed starting Demotion " "thread"); } } if (is_promotion_triggered) { promotion_args.this = this; promotion_args.brick_list = &bricklist_cold; promotion_args.defrag = defrag; promotion_args.freq_time = freq_promote; ret_promotion = pthread_create (&promote_thread, NULL, &tier_promote, &promotion_args); if (ret_promotion) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Failed starting Promotion " "thread"); } } if (ret_demotion == 0) { pthread_join (demote_thread, NULL); if (demotion_args.return_value) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Demotion failed"); } ret_demotion = demotion_args.return_value; } if (ret_promotion == 0) { pthread_join (promote_thread, NULL); if (promotion_args.return_value) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Promotion failed"); } ret_promotion = promotion_args.return_value; } /* Collect previous and current cummulative status */ /* If demotion was not triggered just pass 0 to ret */ ret = (is_demotion_triggered) ? ret_demotion : 0; /* If promotion was not triggered just pass 0 to ret */ ret = ret | (is_promotion_triggered) ? ret_promotion : 0; /* reseting promotion and demotion arguments for * next iteration*/ memset (&demotion_args, 0, sizeof(demotion_args_t)); memset (&promotion_args, 0, sizeof(promotion_args_t)); } ret = 0; out: clear_bricklist (&bricklist_cold); clear_bricklist (&bricklist_hot); return ret; } int32_t tier_migration_needed (xlator_t *this) { gf_defrag_info_t *defrag = NULL; dht_conf_t *conf = NULL; int ret = 0; conf = this->private; GF_VALIDATE_OR_GOTO (this->name, conf, out); GF_VALIDATE_OR_GOTO (this->name, conf->defrag, out); defrag = conf->defrag; if ((defrag->cmd == GF_DEFRAG_CMD_START_TIER) || (defrag->cmd == GF_DEFRAG_CMD_START_DETACH_TIER)) ret = 1; out: return ret; } int32_t tier_migration_get_dst (xlator_t *this, dht_local_t *local) { dht_conf_t *conf = NULL; int32_t ret = -1; gf_defrag_info_t *defrag = NULL; GF_VALIDATE_OR_GOTO ("tier", this, out); GF_VALIDATE_OR_GOTO (this->name, this->private, out); conf = this->private; defrag = conf->defrag; if (defrag && defrag->cmd == GF_DEFRAG_CMD_START_DETACH_TIER) { local->rebalance.target_node = conf->subvolumes[0]; } else if (conf->subvolumes[0] == local->cached_subvol) local->rebalance.target_node = conf->subvolumes[1]; else local->rebalance.target_node = conf->subvolumes[0]; if (local->rebalance.target_node) ret = 0; out: return ret; } xlator_t * tier_search (xlator_t *this, dht_layout_t *layout, const char *name) { xlator_t *subvol = NULL; dht_conf_t *conf = NULL; GF_VALIDATE_OR_GOTO ("tier", this, out); GF_VALIDATE_OR_GOTO (this->name, this->private, out); conf = this->private; subvol = TIER_HASHED_SUBVOL; out: return subvol; } dht_methods_t tier_methods = { .migration_get_dst_subvol = tier_migration_get_dst, .migration_other = tier_start, .migration_needed = tier_migration_needed, .layout_search = tier_search, }; static int tier_load_externals (xlator_t *this) { int ret = -1; char *libpathfull = (LIBDIR "/libgfdb.so.0"); get_gfdb_methods_t get_gfdb_methods; GF_VALIDATE_OR_GOTO ("this", this, out); libhandle = dlopen (libpathfull, RTLD_NOW); if (!libhandle) { gf_msg(this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Error loading libgfdb.so %s\n", dlerror()); ret = -1; goto out; } get_gfdb_methods = dlsym (libhandle, "get_gfdb_methods"); if (!get_gfdb_methods) { gf_msg(this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Error loading get_gfdb_methods()"); ret = -1; goto out; } get_gfdb_methods (&gfdb_methods); ret = 0; out: if (ret && libhandle) dlclose (libhandle); return ret; } static int tier_validate_mode (char *mode) { int ret = -1; if (strcmp (mode, "test") == 0) { ret = TIER_MODE_TEST; } else { ret = TIER_MODE_WM; } return ret; } int tier_init (xlator_t *this) { int ret = -1; int freq = 0; dht_conf_t *conf = NULL; gf_defrag_info_t *defrag = NULL; char *voldir = NULL; char *mode = NULL; char *paused = NULL; ret = dht_init (this); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "dht_init failed"); goto out; } conf = this->private; conf->methods = &tier_methods; if (conf->subvolume_cnt != 2) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Invalid number of subvolumes %d", conf->subvolume_cnt); goto out; } /* if instatiated from client side initialization is complete. */ if (!conf->defrag) { ret = 0; goto out; } /* if instatiated from server side, load db libraries */ ret = tier_load_externals (this); if (ret) { gf_msg(this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "Could not load externals. Aborting"); goto out; } defrag = conf->defrag; defrag->tier_conf.is_tier = 1; ret = dict_get_int32 (this->options, "tier-promote-frequency", &freq); if (ret) { freq = DEFAULT_PROMOTE_FREQ_SEC; } defrag->tier_conf.tier_promote_frequency = freq; ret = dict_get_int32 (this->options, "tier-demote-frequency", &freq); if (ret) { freq = DEFAULT_DEMOTE_FREQ_SEC; } defrag->tier_conf.tier_demote_frequency = freq; ret = dict_get_int32 (this->options, "watermark-hi", &freq); if (ret) { freq = DEFAULT_WM_HI; } defrag->tier_conf.watermark_hi = freq; ret = dict_get_int32 (this->options, "watermark-low", &freq); if (ret) { freq = DEFAULT_WM_LOW; } defrag->tier_conf.watermark_low = freq; ret = dict_get_int32 (this->options, "write-freq-threshold", &freq); if (ret) { freq = DEFAULT_WRITE_FREQ_SEC; } defrag->write_freq_threshold = freq; ret = dict_get_int32 (this->options, "read-freq-threshold", &freq); if (ret) { freq = DEFAULT_READ_FREQ_SEC; } defrag->read_freq_threshold = freq; ret = dict_get_int32 (this->options, "tier-max-mb", &freq); if (ret) { freq = DEFAULT_TIER_MAX_MIGRATE_MB; } defrag->tier_conf.max_migrate_bytes = freq * 1024 * 1024; ret = dict_get_int32 (this->options, "tier-max-files", &freq); if (ret) { freq = DEFAULT_TIER_MAX_MIGRATE_FILES; } defrag->tier_conf.max_migrate_files = freq; ret = dict_get_str (this->options, "tier-mode", &mode); if (ret) { defrag->tier_conf.mode = DEFAULT_TIER_MODE; } else { ret = tier_validate_mode (mode); if (ret < 0) { gf_msg(this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "tier_init failed - invalid mode"); goto out; } defrag->tier_conf.mode = ret; } defrag->tier_conf.request_pause = 0; ret = dict_get_str (this->options, "tier-pause", &paused); if (paused && strcmp (paused, "on") == 0) defrag->tier_conf.request_pause = 1; ret = gf_asprintf(&voldir, "%s/%s", DEFAULT_VAR_RUN_DIRECTORY, this->name); if (ret < 0) goto out; ret = mkdir_p(voldir, 0777, _gf_true); if (ret == -1 && errno != EEXIST) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "tier_init failed"); GF_FREE(voldir); goto out; } GF_FREE(voldir); ret = gf_asprintf (&promotion_qfile, "%s/%s/%s-%s", DEFAULT_VAR_RUN_DIRECTORY, this->name, PROMOTION_QFILE, this->name); if (ret < 0) goto out; ret = gf_asprintf (&demotion_qfile, "%s/%s/%s-%s", DEFAULT_VAR_RUN_DIRECTORY, this->name, DEMOTION_QFILE, this->name); if (ret < 0) { GF_FREE (promotion_qfile); goto out; } unlink (promotion_qfile); unlink (demotion_qfile); gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Promote/demote frequency %d/%d " "Write/Read freq thresholds %d/%d", defrag->tier_conf.tier_promote_frequency, defrag->tier_conf.tier_demote_frequency, defrag->write_freq_threshold, defrag->read_freq_threshold); gf_msg (this->name, GF_LOG_INFO, 0, DHT_MSG_LOG_TIER_STATUS, "Promote file %s demote file %s", promotion_qfile, demotion_qfile); ret = 0; out: return ret; } int tier_reconfigure (xlator_t *this, dict_t *options) { dht_conf_t *conf = NULL; gf_defrag_info_t *defrag = NULL; char *mode = NULL; int migrate_mb = 0; gf_boolean_t req_pause = _gf_false; int ret = 0; conf = this->private; if (conf->defrag) { defrag = conf->defrag; GF_OPTION_RECONF ("tier-promote-frequency", defrag->tier_conf.tier_promote_frequency, options, int32, out); GF_OPTION_RECONF ("tier-demote-frequency", defrag->tier_conf.tier_demote_frequency, options, int32, out); GF_OPTION_RECONF ("write-freq-threshold", defrag->write_freq_threshold, options, int32, out); GF_OPTION_RECONF ("read-freq-threshold", defrag->read_freq_threshold, options, int32, out); GF_OPTION_RECONF ("watermark-hi", defrag->tier_conf.watermark_hi, options, int32, out); GF_OPTION_RECONF ("watermark-low", defrag->tier_conf.watermark_low, options, int32, out); GF_OPTION_RECONF ("tier-mode", mode, options, str, out); defrag->tier_conf.mode = tier_validate_mode (mode); GF_OPTION_RECONF ("tier-max-mb", migrate_mb, options, int32, out); defrag->tier_conf.max_migrate_bytes = migrate_mb*1024*1024; GF_OPTION_RECONF ("tier-max-files", defrag->tier_conf.max_migrate_files, options, int32, out); GF_OPTION_RECONF ("tier-pause", req_pause, options, bool, out); if (req_pause == _gf_true) { ret = gf_defrag_pause_tier (this, defrag); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "pause tier failed on reconfigure"); } } else { ret = gf_defrag_resume_tier (this, defrag); if (ret) { gf_msg (this->name, GF_LOG_ERROR, 0, DHT_MSG_LOG_TIER_ERROR, "resume tier failed on reconfigure"); } } } out: return dht_reconfigure (this, options); } void tier_fini (xlator_t *this) { if (libhandle) dlclose (libhandle); GF_FREE (demotion_qfile); GF_FREE (promotion_qfile); dht_fini(this); } class_methods_t class_methods = { .init = tier_init, .fini = tier_fini, .reconfigure = tier_reconfigure, .notify = dht_notify }; struct xlator_fops fops = { .lookup = dht_lookup, .create = dht_create, .mknod = dht_mknod, .open = dht_open, .statfs = dht_statfs, .opendir = dht_opendir, .readdir = tier_readdir, .readdirp = tier_readdirp, .fsyncdir = dht_fsyncdir, .symlink = dht_symlink, .unlink = dht_unlink, .link = dht_link, .mkdir = dht_mkdir, .rmdir = dht_rmdir, .rename = dht_rename, .entrylk = dht_entrylk, .fentrylk = dht_fentrylk, /* Inode read operations */ .stat = dht_stat, .fstat = dht_fstat, .access = dht_access, .readlink = dht_readlink, .getxattr = dht_getxattr, .fgetxattr = dht_fgetxattr, .readv = dht_readv, .flush = dht_flush, .fsync = dht_fsync, .inodelk = dht_inodelk, .finodelk = dht_finodelk, .lk = dht_lk, /* Inode write operations */ .fremovexattr = dht_fremovexattr, .removexattr = dht_removexattr, .setxattr = dht_setxattr, .fsetxattr = dht_fsetxattr, .truncate = dht_truncate, .ftruncate = dht_ftruncate, .writev = dht_writev, .xattrop = dht_xattrop, .fxattrop = dht_fxattrop, .setattr = dht_setattr, .fsetattr = dht_fsetattr, .fallocate = dht_fallocate, .discard = dht_discard, .zerofill = dht_zerofill, }; struct xlator_cbks cbks = { .forget = dht_forget };