/* Copyright (c) 2006-2012, 2016 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 #include #include #include #include "glusterfs.h" #include "compat.h" #include "xlator.h" #include "logging.h" #include "common-utils.h" #include "locks.h" #include "common.h" #include "statedump.h" #include "clear.h" #include "defaults.h" #include "syncop.h" #include "pl-messages.h" #ifndef LLONG_MAX #define LLONG_MAX LONG_LONG_MAX /* compat with old gcc */ #endif /* LLONG_MAX */ /* Forward declarations */ void do_blocked_rw(pl_inode_t *); static int __rw_allowable(pl_inode_t *, posix_lock_t *, glusterfs_fop_t); static int format_brickname(char *); int pl_lockinfo_get_brickname(xlator_t *, inode_t *, int32_t *); static int fetch_pathinfo(xlator_t *, inode_t *, int32_t *, char **); #define PL_STACK_UNWIND_AND_FREE(__local, fop, frame, op_ret, params...) \ do { \ frame->local = NULL; \ STACK_UNWIND_STRICT(fop, frame, op_ret, params); \ if (__local) { \ if (__local->inodelk_dom_count_req) \ data_unref(__local->inodelk_dom_count_req); \ loc_wipe(&__local->loc[0]); \ loc_wipe(&__local->loc[1]); \ if (__local->fd) \ fd_unref(__local->fd); \ mem_put(__local); \ } \ } while (0) /* * The client is always requesting data, but older * servers were not returning it. Newer ones are, so * the client is receiving a mix of NULL and non-NULL * xdata in the answers when bricks are of different * versions. This triggers a bug in older clients. * To prevent that, we avoid returning extra xdata to * older clients (making the newer brick to behave as * an old brick). */ #define PL_STACK_UNWIND_FOR_CLIENT(fop, xdata, frame, op_ret, params...) \ do { \ pl_local_t *__local = NULL; \ if (frame->root->client && \ (frame->root->client->opversion < GD_OP_VERSION_3_10_0)) { \ __local = frame->local; \ PL_STACK_UNWIND_AND_FREE(__local, fop, frame, op_ret, params); \ } else { \ PL_STACK_UNWIND(fop, xdata, frame, op_ret, params); \ } \ } while (0) #define PL_STACK_UNWIND(fop, xdata, frame, op_ret, params...) \ do { \ pl_local_t *__local = NULL; \ inode_t *__parent = NULL; \ inode_t *__inode = NULL; \ char *__name = NULL; \ dict_t *__unref = NULL; \ int __i = 0; \ __local = frame->local; \ if (op_ret >= 0 && pl_needs_xdata_response(frame->local)) { \ if (xdata) \ dict_ref(xdata); \ else \ xdata = dict_new(); \ if (xdata) { \ __unref = xdata; \ while (__local->fd || __local->loc[__i].inode) { \ pl_get_xdata_rsp_args(__local, #fop, &__parent, &__inode, \ &__name, __i); \ pl_set_xdata_response(frame->this, __local, __parent, \ __inode, __name, xdata, __i > 0); \ if (__local->fd || __i == 1) \ break; \ __i++; \ } \ } \ } \ PL_STACK_UNWIND_AND_FREE(__local, fop, frame, op_ret, params); \ if (__unref) \ dict_unref(__unref); \ } while (0) #define PL_LOCAL_GET_REQUESTS(frame, this, xdata, __fd, __loc, __newloc) \ do { \ if (pl_has_xdata_requests(xdata)) { \ frame->local = mem_get0(this->local_pool); \ pl_local_t *__local = frame->local; \ if (__local) { \ if (__fd) { \ __local->fd = fd_ref(__fd); \ } else { \ if (__loc) \ loc_copy(&__local->loc[0], __loc); \ if (__newloc) \ loc_copy(&__local->loc[1], __newloc); \ } \ pl_get_xdata_requests(__local, xdata); \ } \ } \ } while (0) gf_boolean_t pl_has_xdata_requests(dict_t *xdata) { char *reqs[] = {GLUSTERFS_ENTRYLK_COUNT, GLUSTERFS_INODELK_COUNT, GLUSTERFS_INODELK_DOM_COUNT, GLUSTERFS_POSIXLK_COUNT, GLUSTERFS_PARENT_ENTRYLK, NULL}; int i = 0; if (!xdata) return _gf_false; for (i = 0; reqs[i]; i++) if (dict_get(xdata, reqs[i])) return _gf_true; return _gf_false; } void pl_get_xdata_requests(pl_local_t *local, dict_t *xdata) { if (!local || !xdata) return; if (dict_get(xdata, GLUSTERFS_ENTRYLK_COUNT)) { local->entrylk_count_req = 1; dict_del(xdata, GLUSTERFS_ENTRYLK_COUNT); } if (dict_get(xdata, GLUSTERFS_INODELK_COUNT)) { local->inodelk_count_req = 1; dict_del(xdata, GLUSTERFS_INODELK_COUNT); } local->inodelk_dom_count_req = dict_get(xdata, GLUSTERFS_INODELK_DOM_COUNT); if (local->inodelk_dom_count_req) { data_ref(local->inodelk_dom_count_req); dict_del(xdata, GLUSTERFS_INODELK_DOM_COUNT); } if (dict_get(xdata, GLUSTERFS_POSIXLK_COUNT)) { local->posixlk_count_req = 1; dict_del(xdata, GLUSTERFS_POSIXLK_COUNT); } if (dict_get(xdata, GLUSTERFS_PARENT_ENTRYLK)) { local->parent_entrylk_req = 1; dict_del(xdata, GLUSTERFS_PARENT_ENTRYLK); } } gf_boolean_t pl_needs_xdata_response(pl_local_t *local) { if (!local) return _gf_false; if (local->parent_entrylk_req) return _gf_true; if (local->entrylk_count_req) return _gf_true; if (local->inodelk_dom_count_req) return _gf_true; if (local->inodelk_count_req) return _gf_true; if (local->posixlk_count_req) return _gf_true; return _gf_false; } void pl_get_xdata_rsp_args(pl_local_t *local, char *fop, inode_t **parent, inode_t **inode, char **name, int i) { if (strcmp(fop, "lookup") == 0) { *parent = local->loc[0].parent; *inode = local->loc[0].inode; *name = (char *)local->loc[0].name; } else { if (local->fd) { *inode = local->fd->inode; } else { *inode = local->loc[i].parent; } } } int32_t __get_posixlk_count(xlator_t *this, pl_inode_t *pl_inode) { posix_lock_t *lock = NULL; int32_t count = 0; list_for_each_entry(lock, &pl_inode->ext_list, list) { count++; } return count; } int32_t get_posixlk_count(xlator_t *this, inode_t *inode) { pl_inode_t *pl_inode = NULL; uint64_t tmp_pl_inode = 0; int ret = 0; int32_t count = 0; ret = inode_ctx_get(inode, this, &tmp_pl_inode); if (ret != 0) { goto out; } pl_inode = (pl_inode_t *)(long)tmp_pl_inode; pthread_mutex_lock(&pl_inode->mutex); { count = __get_posixlk_count(this, pl_inode); } pthread_mutex_unlock(&pl_inode->mutex); out: return count; } void pl_parent_entrylk_xattr_fill(xlator_t *this, inode_t *parent, char *basename, dict_t *dict, gf_boolean_t keep_max) { int32_t entrylk = 0; int32_t maxcount = -1; int ret = -1; if (!parent || !basename || !strlen(basename)) goto out; if (keep_max) { ret = dict_get_int32(dict, GLUSTERFS_PARENT_ENTRYLK, &maxcount); if (ret < 0) gf_msg_debug(this->name, 0, " Failed to fetch the value for key %s", GLUSTERFS_PARENT_ENTRYLK); } entrylk = check_entrylk_on_basename(this, parent, basename); if (maxcount >= entrylk) return; out: ret = dict_set_int32(dict, GLUSTERFS_PARENT_ENTRYLK, entrylk); if (ret < 0) { gf_msg_debug(this->name, 0, " dict_set failed on key %s", GLUSTERFS_PARENT_ENTRYLK); } } void pl_entrylk_xattr_fill(xlator_t *this, inode_t *inode, dict_t *dict, gf_boolean_t keep_max) { int32_t count = 0; int32_t maxcount = -1; int ret = -1; if (keep_max) { ret = dict_get_int32(dict, GLUSTERFS_ENTRYLK_COUNT, &maxcount); if (ret < 0) gf_msg_debug(this->name, 0, " Failed to fetch the value for key %s", GLUSTERFS_ENTRYLK_COUNT); } count = get_entrylk_count(this, inode); if (maxcount >= count) return; ret = dict_set_int32(dict, GLUSTERFS_ENTRYLK_COUNT, count); if (ret < 0) { gf_msg_debug(this->name, 0, " dict_set failed on key %s", GLUSTERFS_ENTRYLK_COUNT); } } void pl_inodelk_xattr_fill(xlator_t *this, inode_t *inode, dict_t *dict, char *domname, gf_boolean_t keep_max) { int32_t count = 0; int32_t maxcount = -1; int ret = -1; if (keep_max) { ret = dict_get_int32(dict, GLUSTERFS_INODELK_COUNT, &maxcount); if (ret < 0) gf_msg_debug(this->name, 0, " Failed to fetch the value for key %s", GLUSTERFS_INODELK_COUNT); } count = get_inodelk_count(this, inode, domname); if (maxcount >= count) return; ret = dict_set_int32(dict, GLUSTERFS_INODELK_COUNT, count); if (ret < 0) { gf_msg_debug(this->name, 0, "Failed to set count for " "key %s", GLUSTERFS_INODELK_COUNT); } return; } void pl_posixlk_xattr_fill(xlator_t *this, inode_t *inode, dict_t *dict, gf_boolean_t keep_max) { int32_t count = 0; int32_t maxcount = -1; int ret = -1; if (keep_max) { ret = dict_get_int32(dict, GLUSTERFS_POSIXLK_COUNT, &maxcount); if (ret < 0) gf_msg_debug(this->name, 0, " Failed to fetch the value for key %s", GLUSTERFS_POSIXLK_COUNT); } count = get_posixlk_count(this, inode); if (maxcount >= count) return; ret = dict_set_int32(dict, GLUSTERFS_POSIXLK_COUNT, count); if (ret < 0) { gf_msg_debug(this->name, 0, " dict_set failed on key %s", GLUSTERFS_POSIXLK_COUNT); } } void pl_set_xdata_response(xlator_t *this, pl_local_t *local, inode_t *parent, inode_t *inode, char *name, dict_t *xdata, gf_boolean_t max_lock) { if (!xdata || !local) return; if (local->parent_entrylk_req && parent && name && strlen(name)) pl_parent_entrylk_xattr_fill(this, parent, name, xdata, max_lock); if (local->entrylk_count_req && inode) pl_entrylk_xattr_fill(this, inode, xdata, max_lock); if (local->inodelk_dom_count_req && inode) pl_inodelk_xattr_fill(this, inode, xdata, data_to_str(local->inodelk_dom_count_req), max_lock); if (local->inodelk_count_req && inode) pl_inodelk_xattr_fill(this, inode, xdata, NULL, max_lock); if (local->posixlk_count_req && inode) pl_posixlk_xattr_fill(this, inode, xdata, max_lock); } /* Return true in case we need to ensure mandatory-locking * semnatics under different modes. */ gf_boolean_t pl_is_mandatory_locking_enabled(pl_inode_t *pl_inode) { posix_locks_private_t *priv = NULL; priv = THIS->private; if (priv->mandatory_mode == MLK_FILE_BASED && pl_inode->mandatory) return _gf_true; else if (priv->mandatory_mode == MLK_FORCED || priv->mandatory_mode == MLK_OPTIMAL) return _gf_true; return _gf_false; } /* Checks whether the region where fop is acting upon conflicts * with existing locks. If there is no conflict function returns * 1 else returns 0 with can_block boolean set accordingly to * indicate block/fail the fop. */ int pl_is_fop_allowed(pl_inode_t *pl_inode, posix_lock_t *region, fd_t *fd, glusterfs_fop_t op, gf_boolean_t *can_block) { int ret = 0; if (!__rw_allowable(pl_inode, region, op)) { if ((!fd) || (fd && (fd->flags & O_NONBLOCK))) { gf_log("locks", GF_LOG_TRACE, "returning EAGAIN" " because fd is O_NONBLOCK"); *can_block = _gf_false; } else *can_block = _gf_true; } else ret = 1; return ret; } static pl_fdctx_t * pl_new_fdctx() { pl_fdctx_t *fdctx = NULL; fdctx = GF_CALLOC(1, sizeof(*fdctx), gf_locks_mt_pl_fdctx_t); GF_VALIDATE_OR_GOTO("posix-locks", fdctx, out); INIT_LIST_HEAD(&fdctx->locks_list); out: return fdctx; } static pl_fdctx_t * pl_check_n_create_fdctx(xlator_t *this, fd_t *fd) { int ret = 0; uint64_t tmp = 0; pl_fdctx_t *fdctx = NULL; GF_VALIDATE_OR_GOTO("posix-locks", this, out); GF_VALIDATE_OR_GOTO(this->name, fd, out); LOCK(&fd->lock); { ret = __fd_ctx_get(fd, this, &tmp); if ((ret != 0) || (tmp == 0)) { fdctx = pl_new_fdctx(); if (fdctx == NULL) { goto unlock; } } ret = __fd_ctx_set(fd, this, (uint64_t)(long)fdctx); if (ret != 0) { GF_FREE(fdctx); fdctx = NULL; gf_log(this->name, GF_LOG_DEBUG, "failed to set fd ctx"); } } unlock: UNLOCK(&fd->lock); out: return fdctx; } int32_t pl_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) { STACK_UNWIND_STRICT(discard, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int pl_discard_cont(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, size_t len, dict_t *xdata) { STACK_WIND(frame, pl_discard_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->discard, fd, offset, len, xdata); return 0; } int32_t pl_discard(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, size_t len, dict_t *xdata) { pl_inode_t *pl_inode = NULL; pl_rw_req_t *rw = NULL; posix_lock_t region = { .list = { 0, }, }; gf_boolean_t enabled = _gf_false; gf_boolean_t can_block = _gf_true; int op_ret = 0; int op_errno = 0; int allowed = 1; GF_VALIDATE_OR_GOTO("locks", this, unwind); pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { op_ret = -1; op_errno = ENOMEM; goto unwind; } enabled = pl_is_mandatory_locking_enabled(pl_inode); if (frame->root->pid < 0) enabled = _gf_false; if (enabled) { region.fl_start = offset; region.fl_end = offset + len - 1; region.client = frame->root->client; region.fd_num = fd_to_fdnum(fd); region.client_pid = frame->root->pid; region.owner = frame->root->lk_owner; pthread_mutex_lock(&pl_inode->mutex); { allowed = pl_is_fop_allowed(pl_inode, ®ion, fd, GF_FOP_DISCARD, &can_block); if (allowed == 1) goto unlock; else if (!can_block) { op_errno = EAGAIN; op_ret = -1; goto unlock; } rw = GF_CALLOC(1, sizeof(*rw), gf_locks_mt_pl_rw_req_t); if (!rw) { op_errno = ENOMEM; op_ret = -1; goto unlock; } rw->stub = fop_discard_stub(frame, pl_discard_cont, fd, offset, len, xdata); if (!rw->stub) { op_errno = ENOMEM; op_ret = -1; GF_FREE(rw); goto unlock; } rw->region = region; list_add_tail(&rw->list, &pl_inode->rw_list); } unlock: pthread_mutex_unlock(&pl_inode->mutex); } if (allowed == 1) STACK_WIND(frame, pl_discard_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->discard, fd, offset, len, xdata); unwind: if (op_ret == -1) STACK_UNWIND_STRICT(discard, frame, op_ret, op_errno, NULL, NULL, NULL); return 0; } int32_t pl_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) { STACK_UNWIND_STRICT(zerofill, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int pl_zerofill_cont(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, off_t len, dict_t *xdata) { STACK_WIND(frame, pl_zerofill_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->zerofill, fd, offset, len, xdata); return 0; } int32_t pl_zerofill(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, off_t len, dict_t *xdata) { pl_inode_t *pl_inode = NULL; pl_rw_req_t *rw = NULL; posix_lock_t region = { .list = { 0, }, }; gf_boolean_t enabled = _gf_false; gf_boolean_t can_block = _gf_true; int op_ret = 0; int op_errno = 0; int allowed = 1; GF_VALIDATE_OR_GOTO("locks", this, unwind); pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { op_ret = -1; op_errno = ENOMEM; goto unwind; } enabled = pl_is_mandatory_locking_enabled(pl_inode); if (frame->root->pid < 0) enabled = _gf_false; if (enabled) { region.fl_start = offset; region.fl_end = offset + len - 1; region.client = frame->root->client; region.fd_num = fd_to_fdnum(fd); region.client_pid = frame->root->pid; region.owner = frame->root->lk_owner; pthread_mutex_lock(&pl_inode->mutex); { allowed = pl_is_fop_allowed(pl_inode, ®ion, fd, GF_FOP_ZEROFILL, &can_block); if (allowed == 1) goto unlock; else if (!can_block) { op_errno = EAGAIN; op_ret = -1; goto unlock; } rw = GF_CALLOC(1, sizeof(*rw), gf_locks_mt_pl_rw_req_t); if (!rw) { op_errno = ENOMEM; op_ret = -1; goto unlock; } rw->stub = fop_zerofill_stub(frame, pl_zerofill_cont, fd, offset, len, xdata); if (!rw->stub) { op_errno = ENOMEM; op_ret = -1; GF_FREE(rw); goto unlock; } rw->region = region; list_add_tail(&rw->list, &pl_inode->rw_list); } unlock: pthread_mutex_unlock(&pl_inode->mutex); } if (allowed == 1) STACK_WIND(frame, pl_zerofill_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->zerofill, fd, offset, len, xdata); unwind: if (op_ret == -1) STACK_UNWIND_STRICT(zerofill, frame, op_ret, op_errno, NULL, NULL, NULL); return 0; } int pl_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) { pl_local_t *local = NULL; local = frame->local; if (local->op == GF_FOP_TRUNCATE) loc_wipe(&local->loc[0]); if (local->xdata) dict_unref(local->xdata); if (local->fd) fd_unref(local->fd); if (local->op == GF_FOP_TRUNCATE) STACK_UNWIND_STRICT(truncate, frame, op_ret, op_errno, prebuf, postbuf, xdata); else STACK_UNWIND_STRICT(ftruncate, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int pl_ftruncate_cont(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, dict_t *xdata) { STACK_WIND(frame, pl_truncate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->ftruncate, fd, offset, xdata); return 0; } int pl_truncate_cont(call_frame_t *frame, xlator_t *this, loc_t *loc, off_t offset, dict_t *xdata) { STACK_WIND(frame, pl_truncate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->truncate, loc, offset, xdata); return 0; } static int truncate_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) { pl_local_t *local = NULL; inode_t *inode = NULL; pl_inode_t *pl_inode = NULL; pl_rw_req_t *rw = NULL; posix_lock_t region = { .list = { 0, }, }; gf_boolean_t enabled = _gf_false; gf_boolean_t can_block = _gf_true; int allowed = 1; local = frame->local; GF_VALIDATE_OR_GOTO("locks", this, unwind); if (op_ret != 0) { gf_log(this->name, GF_LOG_ERROR, "got error (errno=%d, stderror=%s) from child", op_errno, strerror(op_errno)); goto unwind; } if (local->op == GF_FOP_TRUNCATE) inode = local->loc[0].inode; else inode = local->fd->inode; pl_inode = pl_inode_get(this, inode); if (!pl_inode) { op_ret = -1; op_errno = ENOMEM; goto unwind; } enabled = pl_is_mandatory_locking_enabled(pl_inode); if (frame->root->pid < 0) enabled = _gf_false; if (enabled) { region.fl_start = local->offset; region.fl_end = LLONG_MAX; region.client = frame->root->client; region.fd_num = fd_to_fdnum(local->fd); region.client_pid = frame->root->pid; region.owner = frame->root->lk_owner; pthread_mutex_lock(&pl_inode->mutex); { allowed = pl_is_fop_allowed(pl_inode, ®ion, local->fd, local->op, &can_block); if (allowed == 1) goto unlock; else if (!can_block) { op_errno = EAGAIN; op_ret = -1; goto unlock; } rw = GF_CALLOC(1, sizeof(*rw), gf_locks_mt_pl_rw_req_t); if (!rw) { op_errno = ENOMEM; op_ret = -1; goto unlock; } if (local->op == GF_FOP_TRUNCATE) rw->stub = fop_truncate_stub(frame, pl_truncate_cont, &local->loc[0], local->offset, local->xdata); else rw->stub = fop_ftruncate_stub(frame, pl_ftruncate_cont, local->fd, local->offset, local->xdata); if (!rw->stub) { op_errno = ENOMEM; op_ret = -1; GF_FREE(rw); goto unlock; } rw->region = region; list_add_tail(&rw->list, &pl_inode->rw_list); } unlock: pthread_mutex_unlock(&pl_inode->mutex); } if (allowed == 1) { switch (local->op) { case GF_FOP_TRUNCATE: STACK_WIND(frame, pl_truncate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->truncate, &local->loc[0], local->offset, local->xdata); break; case GF_FOP_FTRUNCATE: STACK_WIND(frame, pl_truncate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->ftruncate, local->fd, local->offset, local->xdata); break; default: break; } } unwind: if (op_ret == -1) { gf_log(this ? this->name : "locks", GF_LOG_ERROR, "truncate failed with " "ret: %d, error: %s", op_ret, strerror(op_errno)); if (local->op == GF_FOP_TRUNCATE) loc_wipe(&local->loc[0]); if (local->xdata) dict_unref(local->xdata); if (local->fd) fd_unref(local->fd); switch (local->op) { case GF_FOP_TRUNCATE: STACK_UNWIND_STRICT(truncate, frame, op_ret, op_errno, buf, NULL, xdata); break; case GF_FOP_FTRUNCATE: STACK_UNWIND_STRICT(ftruncate, frame, op_ret, op_errno, buf, NULL, xdata); break; default: break; } } return 0; } int pl_truncate(call_frame_t *frame, xlator_t *this, loc_t *loc, off_t offset, dict_t *xdata) { pl_local_t *local = NULL; int ret = -1; GF_VALIDATE_OR_GOTO("locks", this, unwind); local = mem_get0(this->local_pool); GF_VALIDATE_OR_GOTO(this->name, local, unwind); local->op = GF_FOP_TRUNCATE; local->offset = offset; loc_copy(&local->loc[0], loc); if (xdata) local->xdata = dict_ref(xdata); frame->local = local; STACK_WIND(frame, truncate_stat_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->stat, loc, NULL); ret = 0; unwind: if (ret == -1) { gf_log(this ? this->name : "locks", GF_LOG_ERROR, "truncate on %s failed with" " ret: %d, error: %s", loc->path, -1, strerror(ENOMEM)); STACK_UNWIND_STRICT(truncate, frame, -1, ENOMEM, NULL, NULL, NULL); } return 0; } int pl_ftruncate(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, dict_t *xdata) { pl_local_t *local = NULL; int ret = -1; GF_VALIDATE_OR_GOTO("locks", this, unwind); local = mem_get0(this->local_pool); GF_VALIDATE_OR_GOTO(this->name, local, unwind); local->op = GF_FOP_FTRUNCATE; local->offset = offset; local->fd = fd_ref(fd); if (xdata) local->xdata = dict_ref(xdata); frame->local = local; STACK_WIND(frame, truncate_stat_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fstat, fd, xdata); ret = 0; unwind: if (ret == -1) { gf_log(this ? this->name : "locks", GF_LOG_ERROR, "ftruncate failed with" " ret: %d, error: %s", -1, strerror(ENOMEM)); STACK_UNWIND_STRICT(ftruncate, frame, -1, ENOMEM, NULL, NULL, NULL); } return 0; } int pl_locks_by_fd(pl_inode_t *pl_inode, fd_t *fd) { posix_lock_t *l = NULL; int found = 0; pthread_mutex_lock(&pl_inode->mutex); { list_for_each_entry(l, &pl_inode->ext_list, list) { if (l->fd_num == fd_to_fdnum(fd)) { found = 1; break; } } } pthread_mutex_unlock(&pl_inode->mutex); return found; } static void delete_locks_of_fd(xlator_t *this, pl_inode_t *pl_inode, fd_t *fd) { posix_lock_t *tmp = NULL; posix_lock_t *l = NULL; struct list_head blocked_list; INIT_LIST_HEAD(&blocked_list); pthread_mutex_lock(&pl_inode->mutex); { list_for_each_entry_safe(l, tmp, &pl_inode->ext_list, list) { if (l->fd_num == fd_to_fdnum(fd)) { if (l->blocked) { list_move_tail(&l->list, &blocked_list); continue; } __delete_lock(l); __destroy_lock(l); } } } pthread_mutex_unlock(&pl_inode->mutex); list_for_each_entry_safe(l, tmp, &blocked_list, list) { list_del_init(&l->list); STACK_UNWIND_STRICT(lk, l->frame, -1, EAGAIN, &l->user_flock, NULL); __destroy_lock(l); } grant_blocked_locks(this, pl_inode); do_blocked_rw(pl_inode); } static void __delete_locks_of_owner(pl_inode_t *pl_inode, client_t *client, gf_lkowner_t *owner) { posix_lock_t *tmp = NULL; posix_lock_t *l = NULL; /* TODO: what if it is a blocked lock with pending l->frame */ list_for_each_entry_safe(l, tmp, &pl_inode->ext_list, list) { if (l->blocked) continue; if ((l->client == client) && is_same_lkowner(&l->owner, owner)) { gf_log("posix-locks", GF_LOG_TRACE, " Flushing lock" "%s (pid=%d) (lk-owner=%s) %" PRId64 " - %" PRId64 " state: %s", l->fl_type == F_UNLCK ? "Unlock" : "Lock", l->client_pid, lkowner_utoa(&l->owner), l->user_flock.l_start, l->user_flock.l_len, l->blocked == 1 ? "Blocked" : "Active"); __delete_lock(l); __destroy_lock(l); } } return; } int32_t pl_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) { STACK_UNWIND_STRICT(getxattr, frame, op_ret, op_errno, dict, xdata); return 0; } int32_t pl_getxattr(call_frame_t *frame, xlator_t *this, loc_t *loc, const char *name, dict_t *xdata) { int32_t op_errno = EINVAL; int op_ret = -1; int32_t bcount = 0; int32_t gcount = 0; char key[PATH_MAX] = { 0, }; char *lk_summary = NULL; pl_inode_t *pl_inode = NULL; dict_t *dict = NULL; clrlk_args args = { 0, }; char *brickname = NULL; if (!name) goto usual; if (strncmp(name, GF_XATTR_CLRLK_CMD, SLEN(GF_XATTR_CLRLK_CMD))) goto usual; if (clrlk_parse_args(name, &args)) { op_errno = EINVAL; goto out; } dict = dict_new(); if (!dict) { op_errno = ENOMEM; goto out; } pl_inode = pl_inode_get(this, loc->inode); if (!pl_inode) { op_errno = ENOMEM; goto out; } switch (args.type) { case CLRLK_INODE: case CLRLK_ENTRY: op_ret = clrlk_clear_lks_in_all_domains( this, pl_inode, &args, &bcount, &gcount, &op_errno); if (op_ret) goto out; break; case CLRLK_POSIX: op_ret = clrlk_clear_posixlk(this, pl_inode, &args, &bcount, &gcount, &op_errno); if (op_ret) goto out; break; case CLRLK_TYPE_MAX: op_errno = EINVAL; goto out; } op_ret = fetch_pathinfo(this, loc->inode, &op_errno, &brickname); if (op_ret) { gf_log(this->name, GF_LOG_WARNING, "Couldn't get brickname"); } else { op_ret = format_brickname(brickname); if (op_ret) { gf_log(this->name, GF_LOG_WARNING, "Couldn't format brickname"); GF_FREE(brickname); brickname = NULL; } } if (!gcount && !bcount) { if (gf_asprintf(&lk_summary, "No locks cleared.") == -1) { op_ret = -1; op_errno = ENOMEM; goto out; } } else if (gf_asprintf( &lk_summary, "%s: %s blocked locks=%d " "granted locks=%d", (brickname == NULL) ? this->name : brickname, (args.type == CLRLK_INODE) ? "inode" : (args.type == CLRLK_ENTRY) ? "entry" : (args.type == CLRLK_POSIX) ? "posix" : " ", bcount, gcount) == -1) { op_ret = -1; op_errno = ENOMEM; goto out; } if (snprintf(key, sizeof(key), "%s", name) >= sizeof(key)) { op_ret = -1; goto out; } if (dict_set_dynstr(dict, key, lk_summary)) { op_ret = -1; op_errno = ENOMEM; goto out; } op_ret = 0; out: GF_FREE(brickname); STACK_UNWIND_STRICT(getxattr, frame, op_ret, op_errno, dict, xdata); GF_FREE(args.opts); if (op_ret && lk_summary) GF_FREE(lk_summary); if (dict) dict_unref(dict); return 0; usual: STACK_WIND(frame, pl_getxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->getxattr, loc, name, xdata); return 0; } static int format_brickname(char *brickname) { int ret = -1; char *hostname = NULL; char *volume = NULL; char *saveptr = NULL; if (!brickname) goto out; strtok_r(brickname, ":", &saveptr); hostname = gf_strdup(strtok_r(NULL, ":", &saveptr)); if (hostname == NULL) goto out; volume = gf_strdup(strtok_r(NULL, ".", &saveptr)); if (volume == NULL) goto out; sprintf(brickname, "%s:%s", hostname, volume); ret = 0; out: GF_FREE(hostname); GF_FREE(volume); return ret; } static int fetch_pathinfo(xlator_t *this, inode_t *inode, int32_t *op_errno, char **brickname) { int ret = -1; loc_t loc = { 0, }; dict_t *dict = NULL; if (!brickname) goto out; if (!op_errno) goto out; gf_uuid_copy(loc.gfid, inode->gfid); loc.inode = inode_ref(inode); ret = syncop_getxattr(FIRST_CHILD(this), &loc, &dict, GF_XATTR_PATHINFO_KEY, NULL, NULL); if (ret < 0) { *op_errno = -ret; ret = -1; goto out; } ret = dict_get_str(dict, GF_XATTR_PATHINFO_KEY, brickname); if (ret) goto out; *brickname = gf_strdup(*brickname); if (*brickname == NULL) { ret = -1; goto out; } ret = 0; out: if (dict != NULL) { dict_unref(dict); } loc_wipe(&loc); return ret; } int pl_lockinfo_get_brickname(xlator_t *this, inode_t *inode, int32_t *op_errno) { int ret = -1; posix_locks_private_t *priv = NULL; char *brickname = NULL; char *end = NULL; char *tmp = NULL; priv = this->private; ret = fetch_pathinfo(this, inode, op_errno, &brickname); if (ret) goto out; end = strrchr(brickname, ':'); if (!end) { GF_FREE(brickname); ret = -1; goto out; } tmp = brickname; brickname = gf_strndup(brickname, (end - brickname)); if (brickname == NULL) { ret = -1; goto out; } priv->brickname = brickname; ret = 0; out: GF_FREE(tmp); return ret; } char * pl_lockinfo_key(xlator_t *this, inode_t *inode, int32_t *op_errno) { posix_locks_private_t *priv = NULL; char *key = NULL; int ret = 0; priv = this->private; if (priv->brickname == NULL) { ret = pl_lockinfo_get_brickname(this, inode, op_errno); if (ret < 0) { gf_log(this->name, GF_LOG_WARNING, "cannot get brickname"); goto out; } } key = priv->brickname; out: return key; } int32_t pl_fgetxattr_handle_lockinfo(xlator_t *this, fd_t *fd, dict_t *dict, int32_t *op_errno) { pl_inode_t *pl_inode = NULL; char *key = NULL, *buf = NULL; int32_t op_ret = 0; unsigned long fdnum = 0; int32_t len = 0; dict_t *tmp = NULL; pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { gf_log(this->name, GF_LOG_DEBUG, "Could not get inode."); *op_errno = EBADFD; op_ret = -1; goto out; } if (!pl_locks_by_fd(pl_inode, fd)) { op_ret = 0; goto out; } fdnum = fd_to_fdnum(fd); key = pl_lockinfo_key(this, fd->inode, op_errno); if (key == NULL) { op_ret = -1; goto out; } tmp = dict_new(); if (tmp == NULL) { op_ret = -1; *op_errno = ENOMEM; goto out; } op_ret = dict_set_uint64(tmp, key, fdnum); if (op_ret < 0) { *op_errno = -op_ret; op_ret = -1; gf_log(this->name, GF_LOG_WARNING, "setting lockinfo value " "(%lu) for fd (ptr:%p inode-gfid:%s) failed (%s)", fdnum, fd, uuid_utoa(fd->inode->gfid), strerror(*op_errno)); goto out; } len = dict_serialized_length(tmp); if (len < 0) { *op_errno = -op_ret; op_ret = -1; gf_log(this->name, GF_LOG_WARNING, "dict_serialized_length failed (%s) while handling " "lockinfo for fd (ptr:%p inode-gfid:%s)", strerror(*op_errno), fd, uuid_utoa(fd->inode->gfid)); goto out; } buf = GF_CALLOC(1, len, gf_common_mt_char); if (buf == NULL) { op_ret = -1; *op_errno = ENOMEM; goto out; } op_ret = dict_serialize(tmp, buf); if (op_ret < 0) { *op_errno = -op_ret; op_ret = -1; gf_log(this->name, GF_LOG_WARNING, "dict_serialize failed (%s) while handling lockinfo " "for fd (ptr: %p inode-gfid:%s)", strerror(*op_errno), fd, uuid_utoa(fd->inode->gfid)); goto out; } op_ret = dict_set_dynptr(dict, GF_XATTR_LOCKINFO_KEY, buf, len); if (op_ret < 0) { *op_errno = -op_ret; op_ret = -1; gf_log(this->name, GF_LOG_WARNING, "setting lockinfo value " "(%lu) for fd (ptr:%p inode-gfid:%s) failed (%s)", fdnum, fd, uuid_utoa(fd->inode->gfid), strerror(*op_errno)); goto out; } buf = NULL; out: if (tmp != NULL) { dict_unref(tmp); } if (buf != NULL) { GF_FREE(buf); } return op_ret; } int32_t pl_fgetxattr(call_frame_t *frame, xlator_t *this, fd_t *fd, const char *name, dict_t *xdata) { int32_t op_ret = 0, op_errno = 0; dict_t *dict = NULL; if (!name) { goto usual; } if (strcmp(name, GF_XATTR_LOCKINFO_KEY) == 0) { dict = dict_new(); if (dict == NULL) { op_ret = -1; op_errno = ENOMEM; goto unwind; } op_ret = pl_fgetxattr_handle_lockinfo(this, fd, dict, &op_errno); if (op_ret < 0) { gf_log(this->name, GF_LOG_WARNING, "getting lockinfo on fd (ptr:%p inode-gfid:%s) " "failed (%s)", fd, uuid_utoa(fd->inode->gfid), strerror(op_errno)); } goto unwind; } else { goto usual; } unwind: STACK_UNWIND_STRICT(fgetxattr, frame, op_ret, op_errno, dict, NULL); if (dict != NULL) { dict_unref(dict); } return 0; usual: STACK_WIND(frame, default_fgetxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fgetxattr, fd, name, xdata); return 0; } int32_t pl_migrate_locks(call_frame_t *frame, fd_t *newfd, uint64_t oldfd_num, int32_t *op_errno) { pl_inode_t *pl_inode = NULL; uint64_t newfd_num = 0; posix_lock_t *l = NULL; int32_t op_ret = 0; newfd_num = fd_to_fdnum(newfd); pl_inode = pl_inode_get(frame->this, newfd->inode); if (pl_inode == NULL) { op_ret = -1; *op_errno = EBADFD; goto out; } pthread_mutex_lock(&pl_inode->mutex); { list_for_each_entry(l, &pl_inode->ext_list, list) { if (l->fd_num == oldfd_num) { l->fd_num = newfd_num; l->client = frame->root->client; } } } pthread_mutex_unlock(&pl_inode->mutex); op_ret = 0; out: return op_ret; } int32_t pl_fsetxattr_handle_lockinfo(call_frame_t *frame, fd_t *fd, char *lockinfo_buf, int len, int32_t *op_errno) { int32_t op_ret = -1; dict_t *lockinfo = NULL; uint64_t oldfd_num = 0; char *key = NULL; lockinfo = dict_new(); if (lockinfo == NULL) { op_ret = -1; *op_errno = ENOMEM; goto out; } op_ret = dict_unserialize(lockinfo_buf, len, &lockinfo); if (op_ret < 0) { *op_errno = -op_ret; op_ret = -1; goto out; } key = pl_lockinfo_key(frame->this, fd->inode, op_errno); if (key == NULL) { op_ret = -1; goto out; } op_ret = dict_get_uint64(lockinfo, key, &oldfd_num); if (oldfd_num == 0) { op_ret = 0; goto out; } op_ret = pl_migrate_locks(frame, fd, oldfd_num, op_errno); if (op_ret < 0) { gf_log(frame->this->name, GF_LOG_WARNING, "migration of locks from oldfd (ptr:%p) to newfd " "(ptr:%p) (inode-gfid:%s)", (void *)(uintptr_t)oldfd_num, fd, uuid_utoa(fd->inode->gfid)); goto out; } out: dict_unref(lockinfo); return op_ret; } int32_t pl_fsetxattr_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(fsetxattr, xdata, frame, op_ret, op_errno, xdata); return 0; } int32_t pl_fsetxattr(call_frame_t *frame, xlator_t *this, fd_t *fd, dict_t *dict, int32_t flags, dict_t *xdata) { int32_t op_ret = 0, op_errno = 0; void *lockinfo_buf = NULL; int len = 0; op_ret = dict_get_ptr_and_len(dict, GF_XATTR_LOCKINFO_KEY, &lockinfo_buf, &len); if (lockinfo_buf == NULL) { goto usual; } op_ret = pl_fsetxattr_handle_lockinfo(frame, fd, lockinfo_buf, len, &op_errno); if (op_ret < 0) { goto unwind; } usual: PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fsetxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsetxattr, fd, dict, flags, xdata); return 0; unwind: STACK_UNWIND_STRICT(fsetxattr, frame, op_ret, op_errno, NULL); return 0; } int32_t pl_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) { pl_fdctx_t *fdctx = NULL; if (op_ret < 0) goto unwind; fdctx = pl_check_n_create_fdctx(this, fd); if (!fdctx) { op_errno = ENOMEM; op_ret = -1; goto unwind; } unwind: PL_STACK_UNWIND(opendir, xdata, frame, op_ret, op_errno, fd, xdata); return 0; } int32_t pl_opendir(call_frame_t *frame, xlator_t *this, loc_t *loc, fd_t *fd, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_opendir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->opendir, loc, fd, xdata); return 0; } int pl_flush_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(flush, xdata, frame, op_ret, op_errno, xdata); return 0; } int pl_flush(call_frame_t *frame, xlator_t *this, fd_t *fd, dict_t *xdata) { pl_inode_t *pl_inode = NULL; pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { gf_log(this->name, GF_LOG_DEBUG, "Could not get inode."); STACK_UNWIND_STRICT(flush, frame, -1, EBADFD, NULL); return 0; } pthread_mutex_lock(&pl_inode->mutex); { if (pl_inode->migrated) { pthread_mutex_unlock(&pl_inode->mutex); STACK_UNWIND_STRICT(flush, frame, -1, EREMOTE, NULL); return 0; } } pthread_mutex_unlock(&pl_inode->mutex); pl_trace_flush(this, frame, fd); if (frame->root->lk_owner.len == 0) { /* Handle special case when protocol/server sets lk-owner to zero. * This usually happens due to a client disconnection. Hence, free * all locks opened with this fd. */ gf_log(this->name, GF_LOG_TRACE, "Releasing all locks with fd %p", fd); delete_locks_of_fd(this, pl_inode, fd); goto wind; } pthread_mutex_lock(&pl_inode->mutex); { __delete_locks_of_owner(pl_inode, frame->root->client, &frame->root->lk_owner); } pthread_mutex_unlock(&pl_inode->mutex); grant_blocked_locks(this, pl_inode); do_blocked_rw(pl_inode); wind: PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_flush_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->flush, fd, xdata); return 0; } int pl_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) { pl_fdctx_t *fdctx = NULL; if (op_ret < 0) goto unwind; fdctx = pl_check_n_create_fdctx(this, fd); if (!fdctx) { op_errno = ENOMEM; op_ret = -1; goto unwind; } unwind: STACK_UNWIND_STRICT(open, frame, op_ret, op_errno, fd, xdata); return 0; } int pl_open(call_frame_t *frame, xlator_t *this, loc_t *loc, int32_t flags, fd_t *fd, dict_t *xdata) { int op_ret = -1; int op_errno = EINVAL; pl_inode_t *pl_inode = NULL; posix_lock_t *l = NULL; posix_locks_private_t *priv = NULL; priv = this->private; GF_VALIDATE_OR_GOTO("locks", this, unwind); op_ret = 0, op_errno = 0; pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { gf_msg(this->name, GF_LOG_ERROR, 0, ENOMEM, "Could not get inode"); op_ret = -1; op_errno = ENOMEM; goto unwind; } /* As per design, under forced and file-based mandatory locking modes * it doesn't matter whether inodes's lock list contain advisory or * mandatory type locks. So we just check whether inode's lock list is * empty or not to make sure that no locks are being held for the file. * Whereas under optimal mandatory locking mode, we strictly fail open * if and only if lock list contain mandatory locks. */ if (((priv->mandatory_mode == MLK_FILE_BASED) && pl_inode->mandatory) || priv->mandatory_mode == MLK_FORCED) { if (fd->flags & O_TRUNC) { pthread_mutex_lock(&pl_inode->mutex); { if (!list_empty(&pl_inode->ext_list)) { op_ret = -1; op_errno = EAGAIN; } } pthread_mutex_unlock(&pl_inode->mutex); } } else if (priv->mandatory_mode == MLK_OPTIMAL) { if (fd->flags & O_TRUNC) { pthread_mutex_lock(&pl_inode->mutex); { list_for_each_entry(l, &pl_inode->ext_list, list) { if ((l->lk_flags & GF_LK_MANDATORY)) { op_ret = -1; op_errno = EAGAIN; break; } } } pthread_mutex_unlock(&pl_inode->mutex); } } unwind: if (op_ret == -1) STACK_UNWIND_STRICT(open, frame, op_ret, op_errno, NULL, NULL); else STACK_WIND(frame, pl_open_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->open, loc, flags, fd, xdata); return 0; } int pl_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) { pl_fdctx_t *fdctx = NULL; if (op_ret < 0) goto unwind; fdctx = pl_check_n_create_fdctx(this, fd); if (!fdctx) { op_errno = ENOMEM; op_ret = -1; goto unwind; } unwind: PL_STACK_UNWIND(create, xdata, frame, op_ret, op_errno, fd, inode, buf, preparent, postparent, xdata); return 0; } int pl_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) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_create_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->create, loc, flags, mode, umask, fd, xdata); return 0; } int pl_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 *stbuf, struct iobref *iobref, dict_t *xdata) { PL_STACK_UNWIND(readv, xdata, frame, op_ret, op_errno, vector, count, stbuf, iobref, xdata); return 0; } int pl_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) { PL_STACK_UNWIND(writev, xdata, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } void do_blocked_rw(pl_inode_t *pl_inode) { struct list_head wind_list; pl_rw_req_t *rw = NULL; pl_rw_req_t *tmp = NULL; INIT_LIST_HEAD(&wind_list); pthread_mutex_lock(&pl_inode->mutex); { list_for_each_entry_safe(rw, tmp, &pl_inode->rw_list, list) { if (__rw_allowable(pl_inode, &rw->region, rw->stub->fop)) { list_del_init(&rw->list); list_add_tail(&rw->list, &wind_list); } } } pthread_mutex_unlock(&pl_inode->mutex); list_for_each_entry_safe(rw, tmp, &wind_list, list) { list_del_init(&rw->list); call_resume(rw->stub); GF_FREE(rw); } return; } static int __rw_allowable(pl_inode_t *pl_inode, posix_lock_t *region, glusterfs_fop_t op) { posix_lock_t *l = NULL; posix_locks_private_t *priv = NULL; int ret = 1; priv = THIS->private; list_for_each_entry(l, &pl_inode->ext_list, list) { if (!l->blocked && locks_overlap(l, region) && !same_owner(l, region)) { if ((op == GF_FOP_READ) && (l->fl_type != F_WRLCK)) continue; /* Check for mandatory lock under optimal * mandatory-locking mode */ if (priv->mandatory_mode == MLK_OPTIMAL && !(l->lk_flags & GF_LK_MANDATORY)) continue; ret = 0; break; } } return ret; } int pl_readv_cont(call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, uint32_t flags, dict_t *xdata) { STACK_WIND(frame, pl_readv_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readv, fd, size, offset, flags, xdata); return 0; } int pl_readv(call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, uint32_t flags, dict_t *xdata) { pl_inode_t *pl_inode = NULL; pl_rw_req_t *rw = NULL; posix_lock_t region = { .list = { 0, }, }; gf_boolean_t enabled = _gf_false; gf_boolean_t can_block = _gf_true; int op_ret = 0; int op_errno = 0; int allowed = 1; GF_VALIDATE_OR_GOTO("locks", this, unwind); pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { op_ret = -1; op_errno = ENOMEM; goto unwind; } PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); enabled = pl_is_mandatory_locking_enabled(pl_inode); if (frame->root->pid < 0) enabled = _gf_false; if (enabled) { region.fl_start = offset; region.fl_end = offset + size - 1; region.client = frame->root->client; region.fd_num = fd_to_fdnum(fd); region.client_pid = frame->root->pid; region.owner = frame->root->lk_owner; pthread_mutex_lock(&pl_inode->mutex); { allowed = pl_is_fop_allowed(pl_inode, ®ion, fd, GF_FOP_READ, &can_block); if (allowed == 1) goto unlock; else if (!can_block) { op_errno = EAGAIN; op_ret = -1; goto unlock; } rw = GF_CALLOC(1, sizeof(*rw), gf_locks_mt_pl_rw_req_t); if (!rw) { op_errno = ENOMEM; op_ret = -1; goto unlock; } rw->stub = fop_readv_stub(frame, pl_readv_cont, fd, size, offset, flags, xdata); if (!rw->stub) { op_errno = ENOMEM; op_ret = -1; GF_FREE(rw); goto unlock; } rw->region = region; list_add_tail(&rw->list, &pl_inode->rw_list); } unlock: pthread_mutex_unlock(&pl_inode->mutex); } if (allowed == 1) { STACK_WIND(frame, pl_readv_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readv, fd, size, offset, flags, xdata); } unwind: if (op_ret == -1) STACK_UNWIND_STRICT(readv, frame, op_ret, op_errno, NULL, 0, NULL, NULL, NULL); return 0; } int pl_writev_cont(call_frame_t *frame, xlator_t *this, fd_t *fd, struct iovec *vector, int count, off_t offset, uint32_t flags, struct iobref *iobref, dict_t *xdata) { STACK_WIND(frame, pl_writev_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->writev, fd, vector, count, offset, flags, iobref, xdata); return 0; } int pl_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) { pl_inode_t *pl_inode = NULL; pl_rw_req_t *rw = NULL; posix_lock_t region = { .list = { 0, }, }; gf_boolean_t enabled = _gf_false; gf_boolean_t can_block = _gf_true; int op_ret = 0; int op_errno = 0; int allowed = 1; GF_VALIDATE_OR_GOTO("locks", this, unwind); pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { op_ret = -1; op_errno = ENOMEM; goto unwind; } PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); enabled = pl_is_mandatory_locking_enabled(pl_inode); if (frame->root->pid < 0) enabled = _gf_false; if (enabled) { region.fl_start = offset; region.fl_end = offset + iov_length(vector, count) - 1; region.client = frame->root->client; region.fd_num = fd_to_fdnum(fd); region.client_pid = frame->root->pid; region.owner = frame->root->lk_owner; pthread_mutex_lock(&pl_inode->mutex); { allowed = pl_is_fop_allowed(pl_inode, ®ion, fd, GF_FOP_WRITE, &can_block); if (allowed == 1) goto unlock; else if (!can_block) { op_errno = EAGAIN; op_ret = -1; goto unlock; } rw = GF_CALLOC(1, sizeof(*rw), gf_locks_mt_pl_rw_req_t); if (!rw) { op_errno = ENOMEM; op_ret = -1; goto unlock; } rw->stub = fop_writev_stub(frame, pl_writev_cont, fd, vector, count, offset, flags, iobref, xdata); if (!rw->stub) { op_errno = ENOMEM; op_ret = -1; GF_FREE(rw); goto unlock; } rw->region = region; list_add_tail(&rw->list, &pl_inode->rw_list); } unlock: pthread_mutex_unlock(&pl_inode->mutex); } if (allowed == 1) { STACK_WIND(frame, pl_writev_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->writev, fd, vector, count, offset, flags, iobref, xdata); } unwind: if (op_ret == -1) STACK_UNWIND_STRICT(writev, frame, op_ret, op_errno, NULL, NULL, NULL); return 0; } static int __fd_has_locks(pl_inode_t *pl_inode, fd_t *fd) { int found = 0; posix_lock_t *l = NULL; list_for_each_entry(l, &pl_inode->ext_list, list) { if (l->fd_num == fd_to_fdnum(fd)) { found = 1; break; } } return found; } static posix_lock_t * lock_dup(posix_lock_t *lock) { posix_lock_t *new_lock = NULL; new_lock = new_posix_lock(&lock->user_flock, lock->client, lock->client_pid, &lock->owner, (fd_t *)lock->fd_num, lock->lk_flags, lock->blocking); return new_lock; } static int __dup_locks_to_fdctx(pl_inode_t *pl_inode, fd_t *fd, pl_fdctx_t *fdctx) { posix_lock_t *l = NULL; posix_lock_t *duplock = NULL; int ret = 0; list_for_each_entry(l, &pl_inode->ext_list, list) { if (l->fd_num == fd_to_fdnum(fd)) { duplock = lock_dup(l); if (!duplock) { ret = -1; break; } list_add_tail(&duplock->list, &fdctx->locks_list); } } return ret; } static int __copy_locks_to_fdctx(pl_inode_t *pl_inode, fd_t *fd, pl_fdctx_t *fdctx) { int ret = 0; ret = __dup_locks_to_fdctx(pl_inode, fd, fdctx); if (ret) goto out; out: return ret; } static void pl_mark_eol_lock(posix_lock_t *lock) { lock->user_flock.l_type = GF_LK_EOL; return; } static posix_lock_t * __get_next_fdctx_lock(pl_fdctx_t *fdctx) { posix_lock_t *lock = NULL; GF_ASSERT(fdctx); if (list_empty(&fdctx->locks_list)) { gf_log(THIS->name, GF_LOG_DEBUG, "fdctx lock list empty"); goto out; } lock = list_entry(fdctx->locks_list.next, typeof(*lock), list); GF_ASSERT(lock); list_del_init(&lock->list); out: return lock; } static int __set_next_lock_fd(pl_fdctx_t *fdctx, posix_lock_t *reqlock) { posix_lock_t *lock = NULL; int ret = 0; GF_ASSERT(fdctx); lock = __get_next_fdctx_lock(fdctx); if (!lock) { gf_log(THIS->name, GF_LOG_DEBUG, "marking EOL in reqlock"); pl_mark_eol_lock(reqlock); goto out; } reqlock->user_flock = lock->user_flock; reqlock->fl_start = lock->fl_start; reqlock->fl_type = lock->fl_type; reqlock->fl_end = lock->fl_end; reqlock->owner = lock->owner; out: if (lock) __destroy_lock(lock); return ret; } static int pl_getlk_fd(xlator_t *this, pl_inode_t *pl_inode, fd_t *fd, posix_lock_t *reqlock) { uint64_t tmp = 0; pl_fdctx_t *fdctx = NULL; int ret = 0; pthread_mutex_lock(&pl_inode->mutex); { if (!__fd_has_locks(pl_inode, fd)) { gf_log(this->name, GF_LOG_DEBUG, "fd=%p has no active locks", fd); ret = 0; goto unlock; } gf_log(this->name, GF_LOG_DEBUG, "There are active locks on fd"); ret = fd_ctx_get(fd, this, &tmp); fdctx = (pl_fdctx_t *)(long)tmp; if (list_empty(&fdctx->locks_list)) { gf_log(this->name, GF_LOG_TRACE, "no fdctx -> copying all locks on fd"); ret = __copy_locks_to_fdctx(pl_inode, fd, fdctx); if (ret) { goto unlock; } ret = __set_next_lock_fd(fdctx, reqlock); } else { gf_log(this->name, GF_LOG_TRACE, "fdctx present -> returning the next lock"); ret = __set_next_lock_fd(fdctx, reqlock); if (ret) { gf_log(this->name, GF_LOG_DEBUG, "could not get next lock of fd"); goto unlock; } } } unlock: pthread_mutex_unlock(&pl_inode->mutex); return ret; } int pl_metalock_is_active(pl_inode_t *pl_inode) { if (list_empty(&pl_inode->metalk_list)) return 0; else return 1; } int __pl_queue_lock(pl_inode_t *pl_inode, posix_lock_t *reqlock, int can_block) { list_add_tail(&reqlock->list, &pl_inode->queued_locks); return 0; } int pl_lk(call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t cmd, struct gf_flock *flock, dict_t *xdata) { pl_inode_t *pl_inode = NULL; int op_ret = 0; int op_errno = 0; int can_block = 0; posix_lock_t *reqlock = NULL; posix_lock_t *conf = NULL; int ret = 0; uint32_t lk_flags = 0; posix_locks_private_t *priv = NULL; priv = this->private; ret = dict_get_uint32(xdata, GF_LOCK_MODE, &lk_flags); if (ret == 0) { if (priv->mandatory_mode == MLK_NONE) gf_log(this->name, GF_LOG_DEBUG, "Lock flags received " "in a non-mandatory locking environment, " "continuing"); else gf_log(this->name, GF_LOG_DEBUG, "Lock flags received, " "continuing"); } if ((flock->l_start < 0) || ((flock->l_start + flock->l_len) < 0)) { op_ret = -1; op_errno = EINVAL; goto unwind; } /* As per 'man 3 fcntl', the value of l_len may be * negative. In such cases, lock request should be * considered for the range starting at 'l_start+l_len' * and ending at 'l_start-1'. Update the fields accordingly. */ if (flock->l_len < 0) { flock->l_start += flock->l_len; flock->l_len = labs(flock->l_len); } pl_inode = pl_inode_get(this, fd->inode); if (!pl_inode) { op_ret = -1; op_errno = ENOMEM; goto unwind; } reqlock = new_posix_lock(flock, frame->root->client, frame->root->pid, &frame->root->lk_owner, fd, lk_flags, can_block); if (!reqlock) { op_ret = -1; op_errno = ENOMEM; goto unwind; } pl_trace_in(this, frame, fd, NULL, cmd, flock, NULL); switch (cmd) { case F_RESLK_LCKW: can_block = 1; /* fall through */ case F_RESLK_LCK: reqlock->frame = frame; reqlock->this = this; ret = pl_reserve_setlk(this, pl_inode, reqlock, can_block); if (ret < 0) { if (can_block) goto out; op_ret = -1; op_errno = -ret; __destroy_lock(reqlock); goto unwind; } /* Finally a getlk and return the call */ conf = pl_getlk(pl_inode, reqlock); if (conf) posix_lock_to_flock(conf, flock); break; case F_RESLK_UNLCK: reqlock->frame = frame; reqlock->this = this; ret = pl_reserve_unlock(this, pl_inode, reqlock); if (ret < 0) { op_ret = -1; op_errno = -ret; } __destroy_lock(reqlock); goto unwind; break; case F_GETLK_FD: reqlock->frame = frame; reqlock->this = this; ret = pl_verify_reservelk(this, pl_inode, reqlock, can_block); GF_ASSERT(ret >= 0); ret = pl_getlk_fd(this, pl_inode, fd, reqlock); if (ret < 0) { gf_log(this->name, GF_LOG_DEBUG, "getting locks on fd failed"); op_ret = -1; op_errno = ENOLCK; goto unwind; } gf_log(this->name, GF_LOG_TRACE, "Replying with a lock on fd for healing"); posix_lock_to_flock(reqlock, flock); __destroy_lock(reqlock); break; #if F_GETLK != F_GETLK64 case F_GETLK64: #endif case F_GETLK: conf = pl_getlk(pl_inode, reqlock); posix_lock_to_flock(conf, flock); __destroy_lock(reqlock); break; #if F_SETLKW != F_SETLKW64 case F_SETLKW64: #endif case F_SETLKW: can_block = 1; reqlock->frame = frame; reqlock->this = this; reqlock->blocking = can_block; /* fall through */ #if F_SETLK != F_SETLK64 case F_SETLK64: #endif case F_SETLK: reqlock->frame = frame; reqlock->this = this; pthread_mutex_lock(&pl_inode->mutex); { if (pl_inode->migrated) { op_errno = EREMOTE; pthread_mutex_unlock(&pl_inode->mutex); STACK_UNWIND_STRICT(lk, frame, -1, op_errno, flock, xdata); __destroy_lock(reqlock); goto out; } } pthread_mutex_unlock(&pl_inode->mutex); ret = pl_verify_reservelk(this, pl_inode, reqlock, can_block); if (ret < 0) { gf_log(this->name, GF_LOG_TRACE, "Lock blocked due to conflicting reserve lock"); goto out; } ret = pl_setlk(this, pl_inode, reqlock, can_block); if (ret == -1) { if ((can_block) && (F_UNLCK != flock->l_type)) { pl_trace_block(this, frame, fd, NULL, cmd, flock, NULL); goto out; } gf_log(this->name, GF_LOG_DEBUG, "returning EAGAIN"); op_ret = -1; op_errno = EAGAIN; __destroy_lock(reqlock); } else if (ret == -2) { goto out; } else if ((0 == ret) && (F_UNLCK == flock->l_type)) { /* For NLM's last "unlock on fd" detection */ if (pl_locks_by_fd(pl_inode, fd)) flock->l_type = F_RDLCK; else flock->l_type = F_UNLCK; } } unwind: pl_trace_out(this, frame, fd, NULL, cmd, flock, op_ret, op_errno, NULL); pl_update_refkeeper(this, fd->inode); STACK_UNWIND_STRICT(lk, frame, op_ret, op_errno, flock, xdata); out: return 0; } /* TODO: this function just logs, no action required?? */ int pl_forget(xlator_t *this, inode_t *inode) { pl_inode_t *pl_inode = NULL; posix_lock_t *ext_tmp = NULL; posix_lock_t *ext_l = NULL; struct list_head posixlks_released; pl_inode_lock_t *ino_tmp = NULL; pl_inode_lock_t *ino_l = NULL; struct list_head inodelks_released; pl_rw_req_t *rw_tmp = NULL; pl_rw_req_t *rw_req = NULL; pl_entry_lock_t *entry_tmp = NULL; pl_entry_lock_t *entry_l = NULL; struct list_head entrylks_released; pl_dom_list_t *dom = NULL; pl_dom_list_t *dom_tmp = NULL; INIT_LIST_HEAD(&posixlks_released); INIT_LIST_HEAD(&inodelks_released); INIT_LIST_HEAD(&entrylks_released); pl_inode = pl_inode_get(this, inode); if (!pl_inode) return 0; pthread_mutex_lock(&pl_inode->mutex); { if (!list_empty(&pl_inode->rw_list)) { gf_log(this->name, GF_LOG_WARNING, "Pending R/W requests found, releasing."); list_for_each_entry_safe(rw_req, rw_tmp, &pl_inode->rw_list, list) { list_del(&rw_req->list); call_stub_destroy(rw_req->stub); GF_FREE(rw_req); } } if (!list_empty(&pl_inode->ext_list)) { gf_log(this->name, GF_LOG_WARNING, "Pending fcntl locks found, releasing."); list_for_each_entry_safe(ext_l, ext_tmp, &pl_inode->ext_list, list) { __delete_lock(ext_l); if (ext_l->blocked) { list_add_tail(&ext_l->list, &posixlks_released); continue; } __destroy_lock(ext_l); } } list_for_each_entry_safe(dom, dom_tmp, &pl_inode->dom_list, inode_list) { if (!list_empty(&dom->inodelk_list)) { gf_log(this->name, GF_LOG_WARNING, "Pending inode locks found, releasing."); list_for_each_entry_safe(ino_l, ino_tmp, &dom->inodelk_list, list) { __delete_inode_lock(ino_l); __pl_inodelk_unref(ino_l); } list_splice_init(&dom->blocked_inodelks, &inodelks_released); } if (!list_empty(&dom->entrylk_list)) { gf_log(this->name, GF_LOG_WARNING, "Pending entry locks found, releasing."); list_for_each_entry_safe(entry_l, entry_tmp, &dom->entrylk_list, domain_list) { list_del_init(&entry_l->domain_list); GF_FREE((char *)entry_l->basename); GF_FREE(entry_l->connection_id); GF_FREE(entry_l); } list_splice_init(&dom->blocked_entrylks, &entrylks_released); } list_del(&dom->inode_list); gf_log("posix-locks", GF_LOG_TRACE, " Cleaning up domain: %s", dom->domain); GF_FREE((char *)(dom->domain)); GF_FREE(dom); } } pthread_mutex_unlock(&pl_inode->mutex); list_for_each_entry_safe(ext_l, ext_tmp, &posixlks_released, list) { STACK_UNWIND_STRICT(lk, ext_l->frame, -1, 0, &ext_l->user_flock, NULL); __destroy_lock(ext_l); } list_for_each_entry_safe(ino_l, ino_tmp, &inodelks_released, blocked_locks) { STACK_UNWIND_STRICT(inodelk, ino_l->frame, -1, 0, NULL); __pl_inodelk_unref(ino_l); } list_for_each_entry_safe(entry_l, entry_tmp, &entrylks_released, blocked_locks) { STACK_UNWIND_STRICT(entrylk, entry_l->frame, -1, 0, NULL); GF_FREE((char *)entry_l->basename); GF_FREE(entry_l->connection_id); GF_FREE(entry_l); } pthread_mutex_destroy(&pl_inode->mutex); GF_FREE(pl_inode); return 0; } int pl_release(xlator_t *this, fd_t *fd) { pl_inode_t *pl_inode = NULL; uint64_t tmp_pl_inode = 0; int ret = -1; uint64_t tmp = 0; pl_fdctx_t *fdctx = NULL; if (fd == NULL) { goto out; } ret = inode_ctx_get(fd->inode, this, &tmp_pl_inode); if (ret != 0) goto clean; pl_inode = (pl_inode_t *)(long)tmp_pl_inode; pl_trace_release(this, fd); gf_log(this->name, GF_LOG_TRACE, "Releasing all locks with fd %p", fd); delete_locks_of_fd(this, pl_inode, fd); pl_update_refkeeper(this, fd->inode); clean: ret = fd_ctx_del(fd, this, &tmp); if (ret) { gf_log(this->name, GF_LOG_DEBUG, "Could not get fdctx"); goto out; } fdctx = (pl_fdctx_t *)(long)tmp; GF_FREE(fdctx); out: return ret; } int pl_releasedir(xlator_t *this, fd_t *fd) { int ret = -1; uint64_t tmp = 0; pl_fdctx_t *fdctx = NULL; if (fd == NULL) { goto out; } ret = fd_ctx_del(fd, this, &tmp); if (ret) { gf_log(this->name, GF_LOG_DEBUG, "Could not get fdctx"); goto out; } fdctx = (pl_fdctx_t *)(long)tmp; GF_FREE(fdctx); out: return ret; } int32_t pl_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) { PL_STACK_UNWIND(lookup, xdata, frame, op_ret, op_errno, inode, buf, xdata, postparent); return 0; } int32_t pl_lookup(call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_lookup_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->lookup, loc, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND(fstat, xdata, frame, op_ret, op_errno, buf, xdata); return 0; } int32_t pl_fstat(call_frame_t *frame, xlator_t *this, fd_t *fd, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fstat_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fstat, fd, xdata); return 0; } int pl_readdirp_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int op_ret, int op_errno, gf_dirent_t *entries, dict_t *xdata) { pl_local_t *local = NULL; gf_dirent_t *entry = NULL; if (op_ret <= 0) goto unwind; local = frame->local; if (!local) goto unwind; list_for_each_entry(entry, &entries->list, list) { pl_set_xdata_response(this, local, local->fd->inode, entry->inode, entry->d_name, entry->dict, 0); } unwind: PL_STACK_UNWIND(readdirp, xdata, frame, op_ret, op_errno, entries, xdata); return 0; } int pl_readdirp(call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_readdirp_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readdirp, fd, size, offset, xdata); return 0; } lock_migration_info_t * gf_mig_info_for_lock(posix_lock_t *lock) { lock_migration_info_t *new = NULL; new = GF_CALLOC(1, sizeof(lock_migration_info_t), gf_common_mt_lock_mig); if (new == NULL) { goto out; } INIT_LIST_HEAD(&new->list); posix_lock_to_flock(lock, &new->flock); new->lk_flags = lock->lk_flags; new->client_uid = gf_strdup(lock->client_uid); out: return new; } int pl_fill_active_locks(pl_inode_t *pl_inode, lock_migration_info_t *lmi) { posix_lock_t *temp = NULL; lock_migration_info_t *newlock = NULL; int count = 0; pthread_mutex_lock(&pl_inode->mutex); { if (list_empty(&pl_inode->ext_list)) { count = 0; goto out; } list_for_each_entry(temp, &pl_inode->ext_list, list) { if (temp->blocked) continue; newlock = gf_mig_info_for_lock(temp); if (!newlock) { gf_msg(THIS->name, GF_LOG_ERROR, 0, 0, "lock_dup failed"); count = -1; goto out; } list_add_tail(&newlock->list, &lmi->list); count++; } } out: pthread_mutex_unlock(&pl_inode->mutex); return count; } /* This function reads only active locks */ static int pl_getactivelk(call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { pl_inode_t *pl_inode = NULL; lock_migration_info_t locks; int op_ret = 0; int op_errno = 0; int count = 0; INIT_LIST_HEAD(&locks.list); pl_inode = pl_inode_get(this, loc->inode); if (!pl_inode) { gf_msg(this->name, GF_LOG_ERROR, 0, 0, "pl_inode_get failed"); op_ret = -1; op_errno = ENOMEM; goto out; } count = pl_fill_active_locks(pl_inode, &locks); op_ret = count; out: STACK_UNWIND_STRICT(getactivelk, frame, op_ret, op_errno, &locks, NULL); gf_free_mig_locks(&locks); return 0; } void pl_metalk_unref(pl_meta_lock_t *lock) { lock->ref--; if (!lock->ref) { GF_FREE(lock->client_uid); GF_FREE(lock); } } void __pl_metalk_ref(pl_meta_lock_t *lock) { lock->ref++; } pl_meta_lock_t * new_meta_lock(call_frame_t *frame, xlator_t *this) { pl_meta_lock_t *lock = NULL; lock = GF_CALLOC(1, sizeof(*lock), gf_locks_mt_pl_meta_lock_t); if (!lock) { gf_msg(this->name, GF_LOG_ERROR, 0, ENOMEM, "mem allocation" " failed for meta lock"); goto out; } INIT_LIST_HEAD(&lock->list); INIT_LIST_HEAD(&lock->client_list); lock->client_uid = gf_strdup(frame->root->client->client_uid); if (!lock->client_uid) { gf_msg(this->name, GF_LOG_ERROR, 0, ENOMEM, "mem allocation" " failed for client_uid"); GF_FREE(lock); lock = NULL; goto out; } __pl_metalk_ref(lock); out: return lock; } int pl_insert_metalk(pl_inode_t *pl_inode, pl_ctx_t *ctx, pl_meta_lock_t *lock) { int ret = 0; if (!pl_inode || !ctx || !lock) { gf_msg(THIS->name, GF_LOG_INFO, 0, 0, "NULL parameter"); ret = -1; goto out; } lock->pl_inode = pl_inode; /* refer function pl_inode_setlk for more info for this ref. * This should be unrefed on meta-unlock triggered by rebalance or * in cleanup with client disconnect*/ /*TODO: unref this in cleanup code for disconnect and meta-unlock*/ pl_inode->inode = inode_ref(pl_inode->inode); /* NOTE:In case of a client-server disconnect we need to cleanup metalk. * Hence, adding the metalk to pl_ctx_t as well. The mutex lock order * should always be on ctx and then on pl_inode*/ pthread_mutex_lock(&ctx->lock); { pthread_mutex_lock(&pl_inode->mutex); { list_add_tail(&lock->list, &pl_inode->metalk_list); } pthread_mutex_unlock(&pl_inode->mutex); list_add_tail(&lock->client_list, &ctx->metalk_list); } pthread_mutex_unlock(&ctx->lock); out: return ret; } int32_t pl_metalk(call_frame_t *frame, xlator_t *this, inode_t *inode) { pl_inode_t *pl_inode = NULL; int ret = 0; pl_meta_lock_t *reqlk = NULL; pl_ctx_t *ctx = NULL; pl_inode = pl_inode_get(this, inode); if (!pl_inode) { gf_msg(this->name, GF_LOG_ERROR, 0, ENOMEM, "pl_inode mem allocation failedd"); ret = -1; goto out; } /* Non rebalance process trying to do metalock */ if (frame->root->pid != GF_CLIENT_PID_DEFRAG) { ret = -1; goto out; } /* Note: In the current scheme of glusterfs where lock migration is * experimental, (ideally) the rebalance process which is migrating * the file should request for a metalock. Hence, the metalock count * should not be more than one for an inode. In future, if there is a * need for meta-lock from other clients, the following block can be * removed. * * Since pl_metalk is called as part of setxattr operation, any client * process(non-rebalance) residing outside trusted network can exhaust * memory of the server node by issuing setxattr repetitively on the * metalock key. The following code makes sure that more than * one metalock cannot be granted on an inode*/ pthread_mutex_lock(&pl_inode->mutex); { if (pl_metalock_is_active(pl_inode)) { ret = -1; } } pthread_mutex_unlock(&pl_inode->mutex); if (ret == -1) { gf_msg(this->name, GF_LOG_WARNING, EINVAL, 0, "More than one meta-lock cannot be granted on" " the inode"); goto out; } if (frame->root->client) { ctx = pl_ctx_get(frame->root->client, this); if (!ctx) { gf_msg(this->name, GF_LOG_ERROR, 0, 0, "pl_ctx_get failed"); ret = -1; goto out; } } else { gf_msg(this->name, GF_LOG_INFO, 0, 0, "frame-root-client " "is NULL"); ret = -1; goto out; } reqlk = new_meta_lock(frame, this); if (!reqlk) { ret = -1; goto out; } ret = pl_insert_metalk(pl_inode, ctx, reqlk); if (ret < 0) { pl_metalk_unref(reqlk); } out: return ret; } void __unwind_queued_locks(xlator_t *this, pl_inode_t *pl_inode, struct list_head *tmp_list) { if (list_empty(&pl_inode->queued_locks)) return; list_splice_init(&pl_inode->queued_locks, tmp_list); } void __unwind_blocked_locks(xlator_t *this, pl_inode_t *pl_inode, struct list_head *tmp_list) { posix_lock_t *lock = NULL; posix_lock_t *tmp = NULL; if (list_empty(&pl_inode->ext_list)) return; list_for_each_entry_safe(lock, tmp, &pl_inode->ext_list, list) { if (!lock->blocking) continue; list_del_init(&lock->list); list_add_tail(&lock->list, tmp_list); } } int pl_metaunlock(call_frame_t *frame, xlator_t *this, inode_t *inode, dict_t *dict) { pl_inode_t *pl_inode = NULL; int ret = 0; pl_meta_lock_t *meta_lock = NULL; pl_meta_lock_t *tmp_metalk = NULL; pl_ctx_t *ctx = NULL; posix_lock_t *posix_lock = NULL; posix_lock_t *tmp_posixlk = NULL; struct list_head tmp_posixlk_list; INIT_LIST_HEAD(&tmp_posixlk_list); if (frame->root->client) { ctx = pl_ctx_get(frame->root->client, this); if (!ctx) { gf_msg(this->name, GF_LOG_ERROR, 0, 0, "pl_ctx_get failed"); ret = -1; goto out; } } else { gf_msg(this->name, GF_LOG_ERROR, 0, 0, "frame-root-client is " "NULL"); ret = -1; goto out; } pl_inode = pl_inode_get(this, inode); if (!pl_inode) { ret = -1; goto out; } pthread_mutex_lock(&ctx->lock); { pthread_mutex_lock(&pl_inode->mutex); { /* Unwind queued locks regardless of migration status */ __unwind_queued_locks(this, pl_inode, &tmp_posixlk_list); /* Unwind blocked locks only for successful migration */ if (dict_get(dict, "status")) { /* unwind all blocked locks */ __unwind_blocked_locks(this, pl_inode, &tmp_posixlk_list); } /* unlock metalk */ /* if this list is empty then pl_inode->metalk_list * should be empty too. meta lock should in all cases * be added/removed from both pl_ctx_t and pl_inode */ if (list_empty(&ctx->metalk_list)) goto unlock; list_for_each_entry_safe(meta_lock, tmp_metalk, &ctx->metalk_list, client_list) { list_del_init(&meta_lock->client_list); pl_inode = meta_lock->pl_inode; list_del_init(&meta_lock->list); pl_metalk_unref(meta_lock); /* The corresponding ref is taken in * pl_insert_metalk*/ inode_unref(pl_inode->inode); } if (dict_get(dict, "status")) pl_inode->migrated = _gf_true; else pl_inode->migrated = _gf_false; } unlock: pthread_mutex_unlock(&pl_inode->mutex); } pthread_mutex_unlock(&ctx->lock); out: list_for_each_entry_safe(posix_lock, tmp_posixlk, &tmp_posixlk_list, list) { list_del_init(&posix_lock->list); STACK_UNWIND_STRICT(lk, posix_lock->frame, -1, EREMOTE, &posix_lock->user_flock, NULL); __destroy_lock(posix_lock); } return ret; } int32_t pl_setxattr_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(setxattr, xdata, frame, op_ret, op_errno, xdata); return 0; } int32_t pl_setxattr(call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *dict, int flags, dict_t *xdata) { int op_ret = 0; int op_errno = EINVAL; dict_t *xdata_rsp = NULL; PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); if (dict_get(dict, GF_META_LOCK_KEY)) { op_ret = pl_metalk(frame, this, loc->inode); } else if (dict_get(dict, GF_META_UNLOCK_KEY)) { op_ret = pl_metaunlock(frame, this, loc->inode, dict); } else { goto usual; } PL_STACK_UNWIND_FOR_CLIENT(setxattr, xdata_rsp, frame, op_ret, op_errno, xdata_rsp); return 0; usual: STACK_WIND(frame, pl_setxattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->setxattr, loc, dict, flags, xdata); return 0; } void pl_dump_lock(char *str, int size, struct gf_flock *flock, gf_lkowner_t *owner, void *trans, char *conn_id, time_t *granted_time, time_t *blkd_time, gf_boolean_t active) { char *type_str = NULL; char granted[256] = { 0, }; char blocked[256] = { 0, }; if (granted_time) gf_time_fmt(granted, sizeof(granted), *granted_time, gf_timefmt_FT); if (blkd_time) gf_time_fmt(blocked, sizeof(blocked), *blkd_time, gf_timefmt_FT); switch (flock->l_type) { case F_RDLCK: type_str = "READ"; break; case F_WRLCK: type_str = "WRITE"; break; case F_UNLCK: type_str = "UNLOCK"; break; default: type_str = "UNKNOWN"; break; } if (active) { if (blkd_time && *blkd_time == 0) { snprintf(str, size, RANGE_GRNTD_FMT, type_str, flock->l_whence, (unsigned long long)flock->l_start, (unsigned long long)flock->l_len, (unsigned long long)flock->l_pid, lkowner_utoa(owner), trans, conn_id, granted); } else { snprintf(str, size, RANGE_BLKD_GRNTD_FMT, type_str, flock->l_whence, (unsigned long long)flock->l_start, (unsigned long long)flock->l_len, (unsigned long long)flock->l_pid, lkowner_utoa(owner), trans, conn_id, blocked, granted); } } else { snprintf(str, size, RANGE_BLKD_FMT, type_str, flock->l_whence, (unsigned long long)flock->l_start, (unsigned long long)flock->l_len, (unsigned long long)flock->l_pid, lkowner_utoa(owner), trans, conn_id, blocked); } } void __dump_entrylks(pl_inode_t *pl_inode) { pl_dom_list_t *dom = NULL; pl_entry_lock_t *lock = NULL; char blocked[256] = { 0, }; char granted[256] = { 0, }; int count = 0; char key[GF_DUMP_MAX_BUF_LEN] = { 0, }; char *k = "xlator.feature.locks.lock-dump.domain.entrylk"; char tmp[4098]; list_for_each_entry(dom, &pl_inode->dom_list, inode_list) { count = 0; gf_proc_dump_build_key(key, "lock-dump.domain", "domain"); gf_proc_dump_write(key, "%s", dom->domain); list_for_each_entry(lock, &dom->entrylk_list, domain_list) { gf_time_fmt(granted, sizeof(granted), lock->granted_time.tv_sec, gf_timefmt_FT); gf_proc_dump_build_key(key, k, "entrylk[%d](ACTIVE)", count); if (lock->blkd_time.tv_sec == 0) { snprintf(tmp, sizeof(tmp), ENTRY_GRNTD_FMT, lock->type == ENTRYLK_RDLCK ? "ENTRYLK_RDLCK" : "ENTRYLK_WRLCK", lock->basename, (unsigned long long)lock->client_pid, lkowner_utoa(&lock->owner), lock->client, lock->connection_id, granted); } else { gf_time_fmt(blocked, sizeof(blocked), lock->blkd_time.tv_sec, gf_timefmt_FT); snprintf(tmp, sizeof(tmp), ENTRY_BLKD_GRNTD_FMT, lock->type == ENTRYLK_RDLCK ? "ENTRYLK_RDLCK" : "ENTRYLK_WRLCK", lock->basename, (unsigned long long)lock->client_pid, lkowner_utoa(&lock->owner), lock->client, lock->connection_id, blocked, granted); } gf_proc_dump_write(key, "%s", tmp); count++; } list_for_each_entry(lock, &dom->blocked_entrylks, blocked_locks) { gf_time_fmt(blocked, sizeof(blocked), lock->blkd_time.tv_sec, gf_timefmt_FT); gf_proc_dump_build_key(key, k, "entrylk[%d](BLOCKED)", count); snprintf( tmp, sizeof(tmp), ENTRY_BLKD_FMT, lock->type == ENTRYLK_RDLCK ? "ENTRYLK_RDLCK" : "ENTRYLK_WRLCK", lock->basename, (unsigned long long)lock->client_pid, lkowner_utoa(&lock->owner), lock->client, lock->connection_id, blocked); gf_proc_dump_write(key, "%s", tmp); count++; } } } void dump_entrylks(pl_inode_t *pl_inode) { pthread_mutex_lock(&pl_inode->mutex); { __dump_entrylks(pl_inode); } pthread_mutex_unlock(&pl_inode->mutex); } void __dump_inodelks(pl_inode_t *pl_inode) { pl_dom_list_t *dom = NULL; pl_inode_lock_t *lock = NULL; int count = 0; char key[GF_DUMP_MAX_BUF_LEN]; char tmp[4098]; list_for_each_entry(dom, &pl_inode->dom_list, inode_list) { count = 0; gf_proc_dump_build_key(key, "lock-dump.domain", "domain"); gf_proc_dump_write(key, "%s", dom->domain); list_for_each_entry(lock, &dom->inodelk_list, list) { gf_proc_dump_build_key(key, "inodelk", "inodelk[%d](ACTIVE)", count); SET_FLOCK_PID(&lock->user_flock, lock); pl_dump_lock(tmp, sizeof(tmp), &lock->user_flock, &lock->owner, lock->client, lock->connection_id, &lock->granted_time.tv_sec, &lock->blkd_time.tv_sec, _gf_true); gf_proc_dump_write(key, "%s", tmp); count++; } list_for_each_entry(lock, &dom->blocked_inodelks, blocked_locks) { gf_proc_dump_build_key(key, "inodelk", "inodelk[%d](BLOCKED)", count); SET_FLOCK_PID(&lock->user_flock, lock); pl_dump_lock(tmp, sizeof(tmp), &lock->user_flock, &lock->owner, lock->client, lock->connection_id, 0, &lock->blkd_time.tv_sec, _gf_false); gf_proc_dump_write(key, "%s", tmp); count++; } } } void dump_inodelks(pl_inode_t *pl_inode) { pthread_mutex_lock(&pl_inode->mutex); { __dump_inodelks(pl_inode); } pthread_mutex_unlock(&pl_inode->mutex); } void __dump_posixlks(pl_inode_t *pl_inode) { posix_lock_t *lock = NULL; int count = 0; char key[GF_DUMP_MAX_BUF_LEN]; char tmp[4098]; list_for_each_entry(lock, &pl_inode->ext_list, list) { SET_FLOCK_PID(&lock->user_flock, lock); gf_proc_dump_build_key(key, "posixlk", "posixlk[%d](%s)", count, lock->blocked ? "BLOCKED" : "ACTIVE"); pl_dump_lock(tmp, sizeof(tmp), &lock->user_flock, &lock->owner, lock->client, NULL, &lock->granted_time.tv_sec, &lock->blkd_time.tv_sec, (lock->blocked) ? _gf_false : _gf_true); gf_proc_dump_write(key, "%s", tmp); count++; } } void dump_posixlks(pl_inode_t *pl_inode) { pthread_mutex_lock(&pl_inode->mutex); { __dump_posixlks(pl_inode); } pthread_mutex_unlock(&pl_inode->mutex); } int32_t pl_dump_inode_priv(xlator_t *this, inode_t *inode) { int ret = -1; uint64_t tmp_pl_inode = 0; pl_inode_t *pl_inode = NULL; char *pathname = NULL; gf_boolean_t section_added = _gf_false; int count = 0; if (!inode) { errno = EINVAL; goto out; } ret = TRY_LOCK(&inode->lock); if (ret) goto out; { ret = __inode_ctx_get(inode, this, &tmp_pl_inode); if (ret) goto unlock; } unlock: UNLOCK(&inode->lock); if (ret) goto out; pl_inode = (pl_inode_t *)(long)tmp_pl_inode; if (!pl_inode) { ret = -1; goto out; } gf_proc_dump_add_section("xlator.features.locks.%s.inode", this->name); section_added = _gf_true; /*We are safe to call __inode_path since we have the * inode->table->lock */ __inode_path(inode, NULL, &pathname); if (pathname) gf_proc_dump_write("path", "%s", pathname); gf_proc_dump_write("mandatory", "%d", pl_inode->mandatory); ret = pthread_mutex_trylock(&pl_inode->mutex); if (ret) goto out; { count = __get_entrylk_count(this, pl_inode); if (count) { gf_proc_dump_write("entrylk-count", "%d", count); __dump_entrylks(pl_inode); } count = __get_inodelk_count(this, pl_inode, NULL); if (count) { gf_proc_dump_write("inodelk-count", "%d", count); __dump_inodelks(pl_inode); } count = __get_posixlk_count(this, pl_inode); if (count) { gf_proc_dump_write("posixlk-count", "%d", count); __dump_posixlks(pl_inode); } } pthread_mutex_unlock(&pl_inode->mutex); out: GF_FREE(pathname); if (ret && inode) { if (!section_added) gf_proc_dump_add_section( "xlator.features.locks.%s." "inode", this->name); gf_proc_dump_write("Unable to print lock state", "(Lock " "acquisition failure) %s", uuid_utoa(inode->gfid)); } return ret; } int32_t mem_acct_init(xlator_t *this) { int ret = -1; if (!this) return ret; ret = xlator_mem_acct_init(this, gf_locks_mt_end + 1); if (ret != 0) { gf_log(this->name, GF_LOG_ERROR, "Memory accounting init" "failed"); return ret; } return ret; } pl_ctx_t * pl_ctx_get(client_t *client, xlator_t *xlator) { void *tmp = NULL; pl_ctx_t *ctx = NULL; pl_ctx_t *setted_ctx = NULL; client_ctx_get(client, xlator, &tmp); ctx = tmp; if (ctx != NULL) goto out; ctx = GF_CALLOC(1, sizeof(pl_ctx_t), gf_locks_mt_posix_lock_t); if (ctx == NULL) goto out; pthread_mutex_init(&ctx->lock, NULL); INIT_LIST_HEAD(&ctx->inodelk_lockers); INIT_LIST_HEAD(&ctx->entrylk_lockers); INIT_LIST_HEAD(&ctx->metalk_list); setted_ctx = client_ctx_set(client, xlator, ctx); if (ctx != setted_ctx) { pthread_mutex_destroy(&ctx->lock); GF_FREE(ctx); ctx = setted_ctx; } out: return ctx; } int pl_metalk_client_cleanup(xlator_t *this, pl_ctx_t *ctx) { pl_meta_lock_t *meta_lock = NULL; pl_meta_lock_t *tmp_metalk = NULL; pl_inode_t *pl_inode = NULL; posix_lock_t *posix_lock = NULL; posix_lock_t *tmp_posixlk = NULL; struct list_head tmp_posixlk_list; INIT_LIST_HEAD(&tmp_posixlk_list); pthread_mutex_lock(&ctx->lock); { /* if this list is empty then pl_inode->metalk_list should be * empty too. meta lock should in all cases be added/removed * from both pl_ctx_t and pl_inode */ if (list_empty(&ctx->metalk_list)) goto unlock; list_for_each_entry_safe(meta_lock, tmp_metalk, &ctx->metalk_list, client_list) { list_del_init(&meta_lock->client_list); pl_inode = meta_lock->pl_inode; pthread_mutex_lock(&pl_inode->mutex); { /* Since the migration status is unknown here * unwind all queued and blocked locks to check * migration status and find the correct * destination */ __unwind_queued_locks(this, pl_inode, &tmp_posixlk_list); __unwind_blocked_locks(this, pl_inode, &tmp_posixlk_list); list_del_init(&meta_lock->list); pl_metalk_unref(meta_lock); } pthread_mutex_unlock(&pl_inode->mutex); /* The corresponding ref is taken in * pl_insert_metalk*/ inode_unref(pl_inode->inode); } } unlock: pthread_mutex_unlock(&ctx->lock); list_for_each_entry_safe(posix_lock, tmp_posixlk, &tmp_posixlk_list, list) { list_del_init(&posix_lock->list); STACK_UNWIND_STRICT(lk, posix_lock->frame, -1, EREMOTE, &posix_lock->user_flock, NULL); __destroy_lock(posix_lock); } return 0; } static int pl_client_disconnect_cbk(xlator_t *this, client_t *client) { pl_ctx_t *pl_ctx = NULL; pl_ctx = pl_ctx_get(client, this); if (pl_ctx) { pl_inodelk_client_cleanup(this, pl_ctx); pl_entrylk_client_cleanup(this, pl_ctx); pl_metalk_client_cleanup(this, pl_ctx); } return 0; } static int pl_client_destroy_cbk(xlator_t *this, client_t *client) { void *tmp = NULL; pl_ctx_t *pl_ctx = NULL; pl_client_disconnect_cbk(this, client); client_ctx_del(client, this, &tmp); if (tmp == NULL) return 0; pl_ctx = tmp; GF_ASSERT(list_empty(&pl_ctx->inodelk_lockers)); GF_ASSERT(list_empty(&pl_ctx->entrylk_lockers)); pthread_mutex_destroy(&pl_ctx->lock); GF_FREE(pl_ctx); return 0; } int reconfigure(xlator_t *this, dict_t *options) { posix_locks_private_t *priv = NULL; int ret = -1; priv = this->private; GF_OPTION_RECONF("trace", priv->trace, options, bool, out); GF_OPTION_RECONF("monkey-unlocking", priv->monkey_unlocking, options, bool, out); GF_OPTION_RECONF("revocation-secs", priv->revocation_secs, options, uint32, out); GF_OPTION_RECONF("revocation-clear-all", priv->revocation_clear_all, options, bool, out); GF_OPTION_RECONF("revocation-max-blocked", priv->revocation_max_blocked, options, uint32, out); GF_OPTION_RECONF("notify-contention", priv->notify_contention, options, bool, out); GF_OPTION_RECONF("notify-contention-delay", priv->notify_contention_delay, options, uint32, out); ret = 0; out: return ret; } int init(xlator_t *this) { posix_locks_private_t *priv = NULL; xlator_list_t *trav = NULL; char *tmp_str = NULL; int ret = -1; if (!this->children || this->children->next) { gf_log(this->name, GF_LOG_CRITICAL, "FATAL: posix-locks should have exactly one child"); goto out; } if (!this->parents) { gf_log(this->name, GF_LOG_WARNING, "Volume is dangling. Please check the volume file."); } trav = this->children; while (trav->xlator->children) trav = trav->xlator->children; if (strncmp("storage/", trav->xlator->type, 8)) { gf_log(this->name, GF_LOG_CRITICAL, "'locks' translator is not loaded over a storage " "translator"); goto out; } priv = GF_CALLOC(1, sizeof(*priv), gf_locks_mt_posix_locks_private_t); GF_OPTION_INIT("mandatory-locking", tmp_str, str, out); if (!strcmp(tmp_str, "forced")) priv->mandatory_mode = MLK_FORCED; else if (!strcmp(tmp_str, "file")) priv->mandatory_mode = MLK_FILE_BASED; else if (!strcmp(tmp_str, "optimal")) priv->mandatory_mode = MLK_OPTIMAL; else priv->mandatory_mode = MLK_NONE; tmp_str = NULL; GF_OPTION_INIT("trace", priv->trace, bool, out); GF_OPTION_INIT("monkey-unlocking", priv->monkey_unlocking, bool, out); GF_OPTION_INIT("revocation-secs", priv->revocation_secs, uint32, out); GF_OPTION_INIT("revocation-clear-all", priv->revocation_clear_all, bool, out); GF_OPTION_INIT("revocation-max-blocked", priv->revocation_max_blocked, uint32, out); GF_OPTION_INIT("notify-contention", priv->notify_contention, bool, out); GF_OPTION_INIT("notify-contention-delay", priv->notify_contention_delay, uint32, out); this->local_pool = mem_pool_new(pl_local_t, 32); if (!this->local_pool) { ret = -1; gf_log(this->name, GF_LOG_ERROR, "failed to create local_t's memory pool"); goto out; } this->private = priv; ret = 0; out: if (ret) { GF_FREE(priv); } return ret; } int fini(xlator_t *this) { posix_locks_private_t *priv = NULL; priv = this->private; if (!priv) return 0; this->private = NULL; GF_FREE(priv->brickname); GF_FREE(priv); return 0; } int pl_inodelk(call_frame_t *frame, xlator_t *this, const char *volume, loc_t *loc, int32_t cmd, struct gf_flock *flock, dict_t *xdata); int pl_finodelk(call_frame_t *frame, xlator_t *this, const char *volume, fd_t *fd, int32_t cmd, struct gf_flock *flock, dict_t *xdata); int pl_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); int pl_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); int32_t pl_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) { PL_STACK_UNWIND(rename, xdata, frame, op_ret, op_errno, buf, preoldparent, postoldparent, prenewparent, postnewparent, xdata); return 0; } int32_t pl_rename(call_frame_t *frame, xlator_t *this, loc_t *oldloc, loc_t *newloc, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, oldloc, newloc); STACK_WIND(frame, pl_rename_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->rename, oldloc, newloc, xdata); return 0; } posix_lock_t * gf_lkmig_info_to_posix_lock(call_frame_t *frame, lock_migration_info_t *lmi) { posix_lock_t *lock = NULL; lock = GF_CALLOC(1, sizeof(posix_lock_t), gf_locks_mt_posix_lock_t); if (!lock) goto out; lock->fl_start = lmi->flock.l_start; lock->fl_type = lmi->flock.l_type; if (lmi->flock.l_len == 0) lock->fl_end = LLONG_MAX; else lock->fl_end = lmi->flock.l_start + lmi->flock.l_len - 1; lock->client = frame->root->client; lock->lk_flags = lmi->lk_flags; lock->client_uid = gf_strdup(lmi->client_uid); if (lock->client_uid == NULL) { GF_FREE(lock); lock = NULL; goto out; } lock->client_pid = lmi->flock.l_pid; lock->owner = lmi->flock.l_owner; INIT_LIST_HEAD(&lock->list); out: return lock; } /* This function is supposed to write the active locks from the source brick(in * rebalance context) and write here. Hence, will add the locks directly to the * pl_inode->ext_list*/ int pl_write_active_locks(call_frame_t *frame, pl_inode_t *pl_inode, lock_migration_info_t *locklist) { posix_lock_t *newlock = NULL; lock_migration_info_t *temp = NULL; int ret = 0; pthread_mutex_lock(&pl_inode->mutex); { /* Just making sure the activelk list is empty. Should not * happen though*/ if (!list_empty(&pl_inode->ext_list)) { gf_msg(THIS->name, GF_LOG_ERROR, 0, 0, "invalid locks found"); ret = -1; goto out; } /* This list also should not be empty */ if (list_empty(&locklist->list)) { gf_msg(THIS->name, GF_LOG_ERROR, 0, 0, "empty lock list"); ret = -1; goto out; } list_for_each_entry(temp, &locklist->list, list) { newlock = gf_lkmig_info_to_posix_lock(frame, temp); if (!newlock) { gf_msg(THIS->name, GF_LOG_ERROR, 0, 0, "mem allocation failed for newlock"); ret = -1; goto out; } list_add_tail(&newlock->list, &pl_inode->ext_list); } } out: /*TODO: What if few lock add failed with ENOMEM. Should the already * added locks be clearted */ pthread_mutex_unlock(&pl_inode->mutex); return ret; } static int pl_setactivelk(call_frame_t *frame, xlator_t *this, loc_t *loc, lock_migration_info_t *locklist, dict_t *xdata) { pl_inode_t *pl_inode = NULL; int op_ret = 0; int op_errno = 0; int ret = 0; pl_inode = pl_inode_get(this, loc->inode); if (!pl_inode) { gf_msg(this->name, GF_LOG_ERROR, 0, 0, "pl_inode_get failed"); op_ret = -1; op_errno = ENOMEM; goto out; } ret = pl_write_active_locks(frame, pl_inode, locklist); op_ret = ret; out: STACK_UNWIND_STRICT(setactivelk, frame, op_ret, op_errno, NULL); return 0; } int32_t pl_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) { PL_STACK_UNWIND(unlink, xdata, frame, op_ret, op_errno, preparent, postparent, xdata); return 0; } int32_t pl_unlink(call_frame_t *frame, xlator_t *this, loc_t *loc, int xflag, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_unlink_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->unlink, loc, xflag, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(mkdir, xdata, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int pl_mkdir(call_frame_t *frame, xlator_t *this, loc_t *loc, mode_t mode, mode_t umask, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_mkdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->mkdir, loc, mode, umask, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(stat, xdata, frame, op_ret, op_errno, buf, xdata); return 0; } int pl_stat(call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_stat_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->stat, loc, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(mknod, xdata, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int pl_mknod(call_frame_t *frame, xlator_t *this, loc_t *loc, mode_t mode, dev_t rdev, mode_t umask, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_mknod_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->mknod, loc, mode, rdev, umask, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(rmdir, xdata, frame, op_ret, op_errno, preparent, postparent, xdata); return 0; } int pl_rmdir(call_frame_t *frame, xlator_t *this, loc_t *loc, int xflags, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_rmdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->rmdir, loc, xflags, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(symlink, xdata, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int pl_symlink(call_frame_t *frame, xlator_t *this, const char *linkname, loc_t *loc, mode_t umask, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_symlink_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->symlink, linkname, loc, umask, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(link, xdata, frame, op_ret, op_errno, inode, buf, preparent, postparent, xdata); return 0; } int pl_link(call_frame_t *frame, xlator_t *this, loc_t *oldloc, loc_t *newloc, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, oldloc, newloc); STACK_WIND(frame, pl_link_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->link, oldloc, newloc, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(fsync, xdata, frame, op_ret, op_errno, prebuf, postbuf, xdata); return 0; } int pl_fsync(call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t datasync, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fsync_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsync, fd, datasync, xdata); return 0; } int32_t pl_readdir_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, gf_dirent_t *entries, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(readdir, xdata, frame, op_ret, op_errno, entries, xdata); return 0; } int pl_readdir(call_frame_t *frame, xlator_t *this, fd_t *fd, size_t size, off_t offset, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_readdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readdir, fd, size, offset, xdata); return 0; } int32_t pl_fsyncdir_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(fsyncdir, xdata, frame, op_ret, op_errno, xdata); return 0; } int pl_fsyncdir(call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t datasync, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fsyncdir_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsyncdir, fd, datasync, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(statfs, xdata, frame, op_ret, op_errno, buf, xdata); return 0; } int pl_statfs(call_frame_t *frame, xlator_t *this, loc_t *loc, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_statfs_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->statfs, loc, xdata); return 0; } int32_t pl_removexattr_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(removexattr, xdata, frame, op_ret, op_errno, xdata); return 0; } int pl_removexattr(call_frame_t *frame, xlator_t *this, loc_t *loc, const char *name, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_removexattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->removexattr, loc, name, xdata); return 0; } int32_t pl_fremovexattr_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(fremovexattr, xdata, frame, op_ret, op_errno, xdata); return 0; } int pl_fremovexattr(call_frame_t *frame, xlator_t *this, fd_t *fd, const char *name, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fremovexattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fremovexattr, fd, name, xdata); return 0; } int32_t pl_rchecksum_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, uint32_t weak_cksum, uint8_t *strong_cksum, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(rchecksum, xdata, frame, op_ret, op_errno, weak_cksum, strong_cksum, xdata); return 0; } int pl_rchecksum(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, int32_t len, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_rchecksum_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->rchecksum, fd, offset, len, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(xattrop, xdata, frame, op_ret, op_errno, dict, xdata); return 0; } int pl_xattrop(call_frame_t *frame, xlator_t *this, loc_t *loc, gf_xattrop_flags_t optype, dict_t *xattr, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_xattrop_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->xattrop, loc, optype, xattr, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(fxattrop, xdata, frame, op_ret, op_errno, dict, xdata); return 0; } int pl_fxattrop(call_frame_t *frame, xlator_t *this, fd_t *fd, gf_xattrop_flags_t optype, dict_t *xattr, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fxattrop_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fxattrop, fd, optype, xattr, xdata); return 0; } int32_t pl_setattr_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *statpre, struct iatt *statpost, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(setattr, xdata, frame, op_ret, op_errno, statpre, statpost, xdata); return 0; } int pl_setattr(call_frame_t *frame, xlator_t *this, loc_t *loc, struct iatt *stbuf, int32_t valid, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_setattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->setattr, loc, stbuf, valid, xdata); return 0; } int32_t pl_fsetattr_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *statpre, struct iatt *statpost, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(fsetattr, xdata, frame, op_ret, op_errno, statpre, statpost, xdata); return 0; } int pl_fsetattr(call_frame_t *frame, xlator_t *this, fd_t *fd, struct iatt *stbuf, int32_t valid, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fsetattr_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fsetattr, fd, stbuf, valid, xdata); return 0; } int32_t pl_fallocate_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, struct iatt *pre, struct iatt *post, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(fallocate, xdata, frame, op_ret, op_errno, pre, post, xdata); return 0; } int pl_fallocate(call_frame_t *frame, xlator_t *this, fd_t *fd, int32_t keep_size, off_t offset, size_t len, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_fallocate_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->fallocate, fd, keep_size, offset, len, xdata); return 0; } int32_t pl_readlink_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, const char *path, struct iatt *buf, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(readlink, xdata, frame, op_ret, op_errno, path, buf, xdata); return 0; } int pl_readlink(call_frame_t *frame, xlator_t *this, loc_t *loc, size_t size, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_readlink_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->readlink, loc, size, xdata); return 0; } int32_t pl_access_cbk(call_frame_t *frame, void *cookie, xlator_t *this, int32_t op_ret, int32_t op_errno, dict_t *xdata) { PL_STACK_UNWIND_FOR_CLIENT(access, xdata, frame, op_ret, op_errno, xdata); return 0; } int pl_access(call_frame_t *frame, xlator_t *this, loc_t *loc, int32_t mask, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, NULL, loc, NULL); STACK_WIND(frame, pl_access_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->access, loc, mask, xdata); return 0; } int32_t pl_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) { PL_STACK_UNWIND_FOR_CLIENT(seek, xdata, frame, op_ret, op_errno, offset, xdata); return 0; } int32_t pl_seek(call_frame_t *frame, xlator_t *this, fd_t *fd, off_t offset, gf_seek_what_t what, dict_t *xdata) { PL_LOCAL_GET_REQUESTS(frame, this, xdata, fd, NULL, NULL); STACK_WIND(frame, pl_seek_cbk, FIRST_CHILD(this), FIRST_CHILD(this)->fops->seek, fd, offset, what, xdata); return 0; } struct xlator_fops fops = { .lookup = pl_lookup, .create = pl_create, .fstat = pl_fstat, .truncate = pl_truncate, .ftruncate = pl_ftruncate, .discard = pl_discard, .zerofill = pl_zerofill, .open = pl_open, .readv = pl_readv, .writev = pl_writev, .lk = pl_lk, .inodelk = pl_inodelk, .finodelk = pl_finodelk, .entrylk = pl_entrylk, .fentrylk = pl_fentrylk, .flush = pl_flush, .opendir = pl_opendir, .readdirp = pl_readdirp, .setxattr = pl_setxattr, .fsetxattr = pl_fsetxattr, .getxattr = pl_getxattr, .fgetxattr = pl_fgetxattr, .removexattr = pl_removexattr, .fremovexattr = pl_fremovexattr, .rename = pl_rename, .getactivelk = pl_getactivelk, .setactivelk = pl_setactivelk, .unlink = pl_unlink, .access = pl_access, .readlink = pl_readlink, .fallocate = pl_fallocate, .fsetattr = pl_fsetattr, .setattr = pl_setattr, .fxattrop = pl_fxattrop, .xattrop = pl_xattrop, .rchecksum = pl_rchecksum, .statfs = pl_statfs, .fsyncdir = pl_fsyncdir, .readdir = pl_readdir, .symlink = pl_symlink, .link = pl_link, .rmdir = pl_rmdir, .mknod = pl_mknod, .stat = pl_stat, .seek = pl_seek, }; struct xlator_dumpops dumpops = { .inodectx = pl_dump_inode_priv, }; struct xlator_cbks cbks = { .forget = pl_forget, .release = pl_release, .releasedir = pl_releasedir, .client_destroy = pl_client_destroy_cbk, .client_disconnect = pl_client_disconnect_cbk, }; struct volume_options options[] = { {.key = {"mandatory-locking"}, .type = GF_OPTION_TYPE_STR, .default_value = "off", .op_version = {GD_OP_VERSION_3_8_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"locks"}, .description = "Specifies the mandatory-locking mode. Valid options " "are 'file' to use linux style mandatory locks, " "'forced' to use volume strictly under mandatory lock " "semantics only and 'optimal' to treat advisory and " "mandatory locks separately on their own."}, {.key = {"trace"}, .type = GF_OPTION_TYPE_BOOL, .default_value = "off", .op_version = {GD_OP_VERSION_3_7_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"locks"}, .description = "Trace the different lock requests " "to logs."}, {.key = {"monkey-unlocking"}, .type = GF_OPTION_TYPE_BOOL, .default_value = "false", .op_version = {GD_OP_VERSION_3_9_0}, .flags = OPT_FLAG_SETTABLE, .tags = {"locks"}, .description = "Ignore a random number of unlock requests. Useful " "for testing/creating robust lock recovery mechanisms."}, { .key = {"revocation-secs"}, .type = GF_OPTION_TYPE_INT, .min = 0, .max = INT_MAX, .default_value = "0", .op_version = {GD_OP_VERSION_3_9_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"locks"}, .description = "Maximum time a lock can be taken out, before" "being revoked.", }, { .key = {"revocation-clear-all"}, .type = GF_OPTION_TYPE_BOOL, .default_value = "false", .op_version = {GD_OP_VERSION_3_9_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"locks"}, .description = "If set to true, will revoke BOTH granted and blocked " "(pending) lock requests if a revocation threshold is " "hit.", }, {.key = {"revocation-max-blocked"}, .type = GF_OPTION_TYPE_INT, .min = 0, .max = INT_MAX, .default_value = "0", .op_version = {GD_OP_VERSION_3_9_0}, .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .tags = {"locks"}, .description = "A number of blocked lock requests after which a lock " "will be revoked to allow the others to proceed. Can " "be used in conjunction w/ revocation-clear-all."}, {.key = {"notify-contention"}, .type = GF_OPTION_TYPE_BOOL, .default_value = "no", .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .op_version = {GD_OP_VERSION_4_0_0}, .tags = {"locks", "contention"}, .description = "When this option is enabled and a lock request " "conflicts with a currently granted lock, an upcall " "notification will be sent to the current owner of " "the lock to request it to be released as soon as " "possible."}, {.key = {"notify-contention-delay"}, .type = GF_OPTION_TYPE_INT, .min = 0, /* An upcall notification is sent every time a conflict is * detected. */ .max = 60, .default_value = "5", .flags = OPT_FLAG_SETTABLE | OPT_FLAG_DOC, .op_version = {GD_OP_VERSION_4_0_0}, .tags = {"locks", "contention", "timeout"}, .description = "This value determines the minimum amount of time " "(in seconds) between upcall contention notifications " "on the same inode. If multiple lock requests are " "received during this period, only one upcall will " "be sent."}, {.key = {NULL}}, };