// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*- // vim: ts=8 sw=2 smarttab /* * Ceph - scalable distributed file system * * Copyright (C) 2013 Inktank * * This is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License version 2.1, as published by the Free Software * Foundation. See file COPYING. * */ #include "acconfig.h" #ifdef HAVE_SYS_MOUNT_H #include #endif #ifdef HAVE_SYS_PARAM_H #include #endif #include "include/types.h" #include "include/stringify.h" #include "include/unordered_map.h" #include "common/errno.h" #include "MemStore.h" #include "include/compat.h" #define dout_context cct #define dout_subsys ceph_subsys_filestore #undef dout_prefix #define dout_prefix *_dout << "memstore(" << path << ") " // for comparing collections for lock ordering bool operator>(const MemStore::CollectionRef& l, const MemStore::CollectionRef& r) { return (unsigned long)l.get() > (unsigned long)r.get(); } int MemStore::mount() { int r = _load(); if (r < 0) return r; finisher.start(); return 0; } int MemStore::umount() { finisher.wait_for_empty(); finisher.stop(); return _save(); } int MemStore::_save() { dout(10) << __func__ << dendl; dump_all(); set collections; for (ceph::unordered_map::iterator p = coll_map.begin(); p != coll_map.end(); ++p) { dout(20) << __func__ << " coll " << p->first << " " << p->second << dendl; collections.insert(p->first); bufferlist bl; ceph_assert(p->second); p->second->encode(bl); string fn = path + "/" + stringify(p->first); int r = bl.write_file(fn.c_str()); if (r < 0) return r; } string fn = path + "/collections"; bufferlist bl; encode(collections, bl); int r = bl.write_file(fn.c_str()); if (r < 0) return r; return 0; } void MemStore::dump_all() { Formatter *f = Formatter::create("json-pretty"); f->open_object_section("store"); dump(f); f->close_section(); dout(0) << "dump:"; f->flush(*_dout); *_dout << dendl; delete f; } void MemStore::dump(Formatter *f) { f->open_array_section("collections"); for (ceph::unordered_map::iterator p = coll_map.begin(); p != coll_map.end(); ++p) { f->open_object_section("collection"); f->dump_string("name", stringify(p->first)); f->open_array_section("xattrs"); for (map::iterator q = p->second->xattr.begin(); q != p->second->xattr.end(); ++q) { f->open_object_section("xattr"); f->dump_string("name", q->first); f->dump_int("length", q->second.length()); f->close_section(); } f->close_section(); f->open_array_section("objects"); for (map::iterator q = p->second->object_map.begin(); q != p->second->object_map.end(); ++q) { f->open_object_section("object"); f->dump_string("name", stringify(q->first)); if (q->second) q->second->dump(f); f->close_section(); } f->close_section(); f->close_section(); } f->close_section(); } int MemStore::_load() { dout(10) << __func__ << dendl; bufferlist bl; string fn = path + "/collections"; string err; int r = bl.read_file(fn.c_str(), &err); if (r < 0) return r; set collections; auto p = bl.cbegin(); decode(collections, p); for (set::iterator q = collections.begin(); q != collections.end(); ++q) { string fn = path + "/" + stringify(*q); bufferlist cbl; int r = cbl.read_file(fn.c_str(), &err); if (r < 0) return r; CollectionRef c(new Collection(cct, *q)); auto p = cbl.cbegin(); c->decode(p); coll_map[*q] = c; used_bytes += c->used_bytes(); } dump_all(); return 0; } void MemStore::set_fsid(uuid_d u) { int r = write_meta("fsid", stringify(u)); ceph_assert(r >= 0); } uuid_d MemStore::get_fsid() { string fsid_str; int r = read_meta("fsid", &fsid_str); ceph_assert(r >= 0); uuid_d uuid; bool b = uuid.parse(fsid_str.c_str()); ceph_assert(b); return uuid; } int MemStore::mkfs() { string fsid_str; int r = read_meta("fsid", &fsid_str); if (r == -ENOENT) { uuid_d fsid; fsid.generate_random(); fsid_str = stringify(fsid); r = write_meta("fsid", fsid_str); if (r < 0) return r; dout(1) << __func__ << " new fsid " << fsid_str << dendl; } else if (r < 0) { return r; } else { dout(1) << __func__ << " had fsid " << fsid_str << dendl; } string fn = path + "/collections"; derr << path << dendl; bufferlist bl; set collections; encode(collections, bl); r = bl.write_file(fn.c_str()); if (r < 0) return r; r = write_meta("type", "memstore"); if (r < 0) return r; return 0; } int MemStore::statfs(struct store_statfs_t *st, osd_alert_list_t* alerts) { dout(10) << __func__ << dendl; if (alerts) { alerts->clear(); // returns nothing for now } st->reset(); st->total = cct->_conf->memstore_device_bytes; st->available = std::max(st->total - used_bytes, 0); dout(10) << __func__ << ": used_bytes: " << used_bytes << "/" << cct->_conf->memstore_device_bytes << dendl; return 0; } int MemStore::pool_statfs(uint64_t pool_id, struct store_statfs_t *buf) { return -ENOTSUP; } objectstore_perf_stat_t MemStore::get_cur_stats() { // fixme return objectstore_perf_stat_t(); } MemStore::CollectionRef MemStore::get_collection(const coll_t& cid) { std::shared_lock l{coll_lock}; ceph::unordered_map::iterator cp = coll_map.find(cid); if (cp == coll_map.end()) return CollectionRef(); return cp->second; } ObjectStore::CollectionHandle MemStore::create_new_collection(const coll_t& cid) { std::lock_guard l{coll_lock}; Collection *c = new Collection(cct, cid); new_coll_map[cid] = c; return c; } // --------------- // read operations bool MemStore::exists(CollectionHandle &c_, const ghobject_t& oid) { Collection *c = static_cast(c_.get()); dout(10) << __func__ << " " << c->get_cid() << " " << oid << dendl; if (!c->exists) return false; // Perform equivalent of c->get_object_(oid) != NULL. In C++11 the // shared_ptr needs to be compared to nullptr. return (bool)c->get_object(oid); } int MemStore::stat( CollectionHandle &c_, const ghobject_t& oid, struct stat *st, bool allow_eio) { Collection *c = static_cast(c_.get()); dout(10) << __func__ << " " << c->cid << " " << oid << dendl; if (!c->exists) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; st->st_size = o->get_size(); st->st_blksize = 4096; st->st_blocks = (st->st_size + st->st_blksize - 1) / st->st_blksize; st->st_nlink = 1; return 0; } int MemStore::set_collection_opts( CollectionHandle& ch, const pool_opts_t& opts) { return -EOPNOTSUPP; } int MemStore::read( CollectionHandle &c_, const ghobject_t& oid, uint64_t offset, size_t len, bufferlist& bl, uint32_t op_flags) { Collection *c = static_cast(c_.get()); dout(10) << __func__ << " " << c->cid << " " << oid << " " << offset << "~" << len << dendl; if (!c->exists) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; if (offset >= o->get_size()) return 0; size_t l = len; if (l == 0 && offset == 0) // note: len == 0 means read the entire object l = o->get_size(); else if (offset + l > o->get_size()) l = o->get_size() - offset; bl.clear(); return o->read(offset, l, bl); } int MemStore::fiemap(CollectionHandle& ch, const ghobject_t& oid, uint64_t offset, size_t len, bufferlist& bl) { map destmap; int r = fiemap(ch, oid, offset, len, destmap); if (r >= 0) encode(destmap, bl); return r; } int MemStore::fiemap(CollectionHandle& ch, const ghobject_t& oid, uint64_t offset, size_t len, map& destmap) { dout(10) << __func__ << " " << ch->cid << " " << oid << " " << offset << "~" << len << dendl; Collection *c = static_cast(ch.get()); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; size_t l = len; if (offset + l > o->get_size()) l = o->get_size() - offset; if (offset >= o->get_size()) goto out; destmap[offset] = l; out: return 0; } int MemStore::getattr(CollectionHandle &c_, const ghobject_t& oid, const char *name, bufferptr& value) { Collection *c = static_cast(c_.get()); dout(10) << __func__ << " " << c->cid << " " << oid << " " << name << dendl; if (!c->exists) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; string k(name); std::lock_guard lock{o->xattr_mutex}; if (!o->xattr.count(k)) { return -ENODATA; } value = o->xattr[k]; return 0; } int MemStore::getattrs(CollectionHandle &c_, const ghobject_t& oid, map& aset) { Collection *c = static_cast(c_.get()); dout(10) << __func__ << " " << c->cid << " " << oid << dendl; if (!c->exists) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->xattr_mutex}; aset = o->xattr; return 0; } int MemStore::list_collections(vector& ls) { dout(10) << __func__ << dendl; std::shared_lock l{coll_lock}; for (ceph::unordered_map::iterator p = coll_map.begin(); p != coll_map.end(); ++p) { ls.push_back(p->first); } return 0; } bool MemStore::collection_exists(const coll_t& cid) { dout(10) << __func__ << " " << cid << dendl; std::shared_lock l{coll_lock}; return coll_map.count(cid); } int MemStore::collection_empty(CollectionHandle& ch, bool *empty) { dout(10) << __func__ << " " << ch->cid << dendl; CollectionRef c = static_cast(ch.get()); std::shared_lock l{c->lock}; *empty = c->object_map.empty(); return 0; } int MemStore::collection_bits(CollectionHandle& ch) { dout(10) << __func__ << " " << ch->cid << dendl; Collection *c = static_cast(ch.get()); std::shared_lock l{c->lock}; return c->bits; } int MemStore::collection_list(CollectionHandle& ch, const ghobject_t& start, const ghobject_t& end, int max, vector *ls, ghobject_t *next) { Collection *c = static_cast(ch.get()); std::shared_lock l{c->lock}; dout(10) << __func__ << " cid " << ch->cid << " start " << start << " end " << end << dendl; map::iterator p = c->object_map.lower_bound(start); while (p != c->object_map.end() && ls->size() < (unsigned)max && p->first < end) { ls->push_back(p->first); ++p; } if (next != NULL) { if (p == c->object_map.end()) *next = ghobject_t::get_max(); else *next = p->first; } dout(10) << __func__ << " cid " << ch->cid << " got " << ls->size() << dendl; return 0; } int MemStore::omap_get( CollectionHandle& ch, ///< [in] Collection containing oid const ghobject_t &oid, ///< [in] Object containing omap bufferlist *header, ///< [out] omap header map *out /// < [out] Key to value map ) { dout(10) << __func__ << " " << ch->cid << " " << oid << dendl; Collection *c = static_cast(ch.get()); ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; *header = o->omap_header; *out = o->omap; return 0; } int MemStore::omap_get_header( CollectionHandle& ch, ///< [in] Collection containing oid const ghobject_t &oid, ///< [in] Object containing omap bufferlist *header, ///< [out] omap header bool allow_eio ///< [in] don't assert on eio ) { dout(10) << __func__ << " " << ch->cid << " " << oid << dendl; Collection *c = static_cast(ch.get()); ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; *header = o->omap_header; return 0; } int MemStore::omap_get_keys( CollectionHandle& ch, ///< [in] Collection containing oid const ghobject_t &oid, ///< [in] Object containing omap set *keys ///< [out] Keys defined on oid ) { dout(10) << __func__ << " " << ch->cid << " " << oid << dendl; Collection *c = static_cast(ch.get()); ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; for (map::iterator p = o->omap.begin(); p != o->omap.end(); ++p) keys->insert(p->first); return 0; } int MemStore::omap_get_values( CollectionHandle& ch, ///< [in] Collection containing oid const ghobject_t &oid, ///< [in] Object containing omap const set &keys, ///< [in] Keys to get map *out ///< [out] Returned keys and values ) { dout(10) << __func__ << " " << ch->cid << " " << oid << dendl; Collection *c = static_cast(ch.get()); ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; for (set::const_iterator p = keys.begin(); p != keys.end(); ++p) { map::iterator q = o->omap.find(*p); if (q != o->omap.end()) out->insert(*q); } return 0; } int MemStore::omap_check_keys( CollectionHandle& ch, ///< [in] Collection containing oid const ghobject_t &oid, ///< [in] Object containing omap const set &keys, ///< [in] Keys to check set *out ///< [out] Subset of keys defined on oid ) { dout(10) << __func__ << " " << ch->cid << " " << oid << dendl; Collection *c = static_cast(ch.get()); ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; for (set::const_iterator p = keys.begin(); p != keys.end(); ++p) { map::iterator q = o->omap.find(*p); if (q != o->omap.end()) out->insert(*p); } return 0; } class MemStore::OmapIteratorImpl : public ObjectMap::ObjectMapIteratorImpl { CollectionRef c; ObjectRef o; map::iterator it; public: OmapIteratorImpl(CollectionRef c, ObjectRef o) : c(c), o(o), it(o->omap.begin()) {} int seek_to_first() override { std::lock_guard lock{o->omap_mutex}; it = o->omap.begin(); return 0; } int upper_bound(const string &after) override { std::lock_guard lock{o->omap_mutex}; it = o->omap.upper_bound(after); return 0; } int lower_bound(const string &to) override { std::lock_guard lock{o->omap_mutex}; it = o->omap.lower_bound(to); return 0; } bool valid() override { std::lock_guard lock{o->omap_mutex}; return it != o->omap.end(); } int next() override { std::lock_guard lock{o->omap_mutex}; ++it; return 0; } string key() override { std::lock_guard lock{o->omap_mutex}; return it->first; } bufferlist value() override { std::lock_guard lock{o->omap_mutex}; return it->second; } int status() override { return 0; } }; ObjectMap::ObjectMapIterator MemStore::get_omap_iterator( CollectionHandle& ch, const ghobject_t& oid) { dout(10) << __func__ << " " << ch->cid << " " << oid << dendl; Collection *c = static_cast(ch.get()); ObjectRef o = c->get_object(oid); if (!o) return ObjectMap::ObjectMapIterator(); return ObjectMap::ObjectMapIterator(new OmapIteratorImpl(c, o)); } // --------------- // write operations int MemStore::queue_transactions( CollectionHandle& ch, vector& tls, TrackedOpRef op, ThreadPool::TPHandle *handle) { // because memstore operations are synchronous, we can implement the // Sequencer with a mutex. this guarantees ordering on a given sequencer, // while allowing operations on different sequencers to happen in parallel Collection *c = static_cast(ch.get()); std::unique_lock lock{c->sequencer_mutex}; for (vector::iterator p = tls.begin(); p != tls.end(); ++p) { // poke the TPHandle heartbeat just to exercise that code path if (handle) handle->reset_tp_timeout(); _do_transaction(*p); } Context *on_apply = NULL, *on_apply_sync = NULL, *on_commit = NULL; ObjectStore::Transaction::collect_contexts(tls, &on_apply, &on_commit, &on_apply_sync); if (on_apply_sync) on_apply_sync->complete(0); if (on_apply) finisher.queue(on_apply); if (on_commit) finisher.queue(on_commit); return 0; } void MemStore::_do_transaction(Transaction& t) { Transaction::iterator i = t.begin(); int pos = 0; while (i.have_op()) { Transaction::Op *op = i.decode_op(); int r = 0; switch (op->op) { case Transaction::OP_NOP: break; case Transaction::OP_TOUCH: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); r = _touch(cid, oid); } break; case Transaction::OP_WRITE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); uint64_t off = op->off; uint64_t len = op->len; uint32_t fadvise_flags = i.get_fadvise_flags(); bufferlist bl; i.decode_bl(bl); r = _write(cid, oid, off, len, bl, fadvise_flags); } break; case Transaction::OP_ZERO: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); uint64_t off = op->off; uint64_t len = op->len; r = _zero(cid, oid, off, len); } break; case Transaction::OP_TRIMCACHE: { // deprecated, no-op } break; case Transaction::OP_TRUNCATE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); uint64_t off = op->off; r = _truncate(cid, oid, off); } break; case Transaction::OP_REMOVE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); r = _remove(cid, oid); } break; case Transaction::OP_SETATTR: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); string name = i.decode_string(); bufferlist bl; i.decode_bl(bl); map to_set; to_set[name] = bufferptr(bl.c_str(), bl.length()); r = _setattrs(cid, oid, to_set); } break; case Transaction::OP_SETATTRS: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); map aset; i.decode_attrset(aset); r = _setattrs(cid, oid, aset); } break; case Transaction::OP_RMATTR: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); string name = i.decode_string(); r = _rmattr(cid, oid, name.c_str()); } break; case Transaction::OP_RMATTRS: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); r = _rmattrs(cid, oid); } break; case Transaction::OP_CLONE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); ghobject_t noid = i.get_oid(op->dest_oid); r = _clone(cid, oid, noid); } break; case Transaction::OP_CLONERANGE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); ghobject_t noid = i.get_oid(op->dest_oid); uint64_t off = op->off; uint64_t len = op->len; r = _clone_range(cid, oid, noid, off, len, off); } break; case Transaction::OP_CLONERANGE2: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); ghobject_t noid = i.get_oid(op->dest_oid); uint64_t srcoff = op->off; uint64_t len = op->len; uint64_t dstoff = op->dest_off; r = _clone_range(cid, oid, noid, srcoff, len, dstoff); } break; case Transaction::OP_MKCOLL: { coll_t cid = i.get_cid(op->cid); r = _create_collection(cid, op->split_bits); } break; case Transaction::OP_COLL_HINT: { coll_t cid = i.get_cid(op->cid); uint32_t type = op->hint_type; bufferlist hint; i.decode_bl(hint); auto hiter = hint.cbegin(); if (type == Transaction::COLL_HINT_EXPECTED_NUM_OBJECTS) { uint32_t pg_num; uint64_t num_objs; decode(pg_num, hiter); decode(num_objs, hiter); r = _collection_hint_expected_num_objs(cid, pg_num, num_objs); } else { // Ignore the hint dout(10) << "Unrecognized collection hint type: " << type << dendl; } } break; case Transaction::OP_RMCOLL: { coll_t cid = i.get_cid(op->cid); r = _destroy_collection(cid); } break; case Transaction::OP_COLL_ADD: { coll_t ocid = i.get_cid(op->cid); coll_t ncid = i.get_cid(op->dest_cid); ghobject_t oid = i.get_oid(op->oid); r = _collection_add(ncid, ocid, oid); } break; case Transaction::OP_COLL_REMOVE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); r = _remove(cid, oid); } break; case Transaction::OP_COLL_MOVE: ceph_abort_msg("deprecated"); break; case Transaction::OP_COLL_MOVE_RENAME: { coll_t oldcid = i.get_cid(op->cid); ghobject_t oldoid = i.get_oid(op->oid); coll_t newcid = i.get_cid(op->dest_cid); ghobject_t newoid = i.get_oid(op->dest_oid); r = _collection_move_rename(oldcid, oldoid, newcid, newoid); if (r == -ENOENT) r = 0; } break; case Transaction::OP_TRY_RENAME: { coll_t cid = i.get_cid(op->cid); ghobject_t oldoid = i.get_oid(op->oid); ghobject_t newoid = i.get_oid(op->dest_oid); r = _collection_move_rename(cid, oldoid, cid, newoid); if (r == -ENOENT) r = 0; } break; case Transaction::OP_COLL_SETATTR: { ceph_abort_msg("not implemented"); } break; case Transaction::OP_COLL_RMATTR: { ceph_abort_msg("not implemented"); } break; case Transaction::OP_COLL_RENAME: { ceph_abort_msg("not implemented"); } break; case Transaction::OP_OMAP_CLEAR: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); r = _omap_clear(cid, oid); } break; case Transaction::OP_OMAP_SETKEYS: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); bufferlist aset_bl; i.decode_attrset_bl(&aset_bl); r = _omap_setkeys(cid, oid, aset_bl); } break; case Transaction::OP_OMAP_RMKEYS: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); bufferlist keys_bl; i.decode_keyset_bl(&keys_bl); r = _omap_rmkeys(cid, oid, keys_bl); } break; case Transaction::OP_OMAP_RMKEYRANGE: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); string first, last; first = i.decode_string(); last = i.decode_string(); r = _omap_rmkeyrange(cid, oid, first, last); } break; case Transaction::OP_OMAP_SETHEADER: { coll_t cid = i.get_cid(op->cid); ghobject_t oid = i.get_oid(op->oid); bufferlist bl; i.decode_bl(bl); r = _omap_setheader(cid, oid, bl); } break; case Transaction::OP_SPLIT_COLLECTION: ceph_abort_msg("deprecated"); break; case Transaction::OP_SPLIT_COLLECTION2: { coll_t cid = i.get_cid(op->cid); uint32_t bits = op->split_bits; uint32_t rem = op->split_rem; coll_t dest = i.get_cid(op->dest_cid); r = _split_collection(cid, bits, rem, dest); } break; case Transaction::OP_MERGE_COLLECTION: { coll_t cid = i.get_cid(op->cid); uint32_t bits = op->split_bits; coll_t dest = i.get_cid(op->dest_cid); r = _merge_collection(cid, bits, dest); } break; case Transaction::OP_SETALLOCHINT: { r = 0; } break; case Transaction::OP_COLL_SET_BITS: { r = 0; } break; default: derr << "bad op " << op->op << dendl; ceph_abort(); } if (r < 0) { bool ok = false; if (r == -ENOENT && !(op->op == Transaction::OP_CLONERANGE || op->op == Transaction::OP_CLONE || op->op == Transaction::OP_CLONERANGE2 || op->op == Transaction::OP_COLL_ADD)) // -ENOENT is usually okay ok = true; if (r == -ENODATA) ok = true; if (!ok) { const char *msg = "unexpected error code"; if (r == -ENOENT && (op->op == Transaction::OP_CLONERANGE || op->op == Transaction::OP_CLONE || op->op == Transaction::OP_CLONERANGE2)) msg = "ENOENT on clone suggests osd bug"; if (r == -ENOSPC) // For now, if we hit _any_ ENOSPC, crash, before we do any damage // by partially applying transactions. msg = "ENOSPC from MemStore, misconfigured cluster or insufficient memory"; if (r == -ENOTEMPTY) { msg = "ENOTEMPTY suggests garbage data in osd data dir"; dump_all(); } derr << " error " << cpp_strerror(r) << " not handled on operation " << op->op << " (op " << pos << ", counting from 0)" << dendl; dout(0) << msg << dendl; dout(0) << " transaction dump:\n"; JSONFormatter f(true); f.open_object_section("transaction"); t.dump(&f); f.close_section(); f.flush(*_dout); *_dout << dendl; ceph_abort_msg("unexpected error"); } } ++pos; } } int MemStore::_touch(const coll_t& cid, const ghobject_t& oid) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; c->get_or_create_object(oid); return 0; } int MemStore::_write(const coll_t& cid, const ghobject_t& oid, uint64_t offset, size_t len, const bufferlist& bl, uint32_t fadvise_flags) { dout(10) << __func__ << " " << cid << " " << oid << " " << offset << "~" << len << dendl; ceph_assert(len == bl.length()); CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_or_create_object(oid); if (len > 0) { const ssize_t old_size = o->get_size(); o->write(offset, bl); used_bytes += (o->get_size() - old_size); } return 0; } int MemStore::_zero(const coll_t& cid, const ghobject_t& oid, uint64_t offset, size_t len) { dout(10) << __func__ << " " << cid << " " << oid << " " << offset << "~" << len << dendl; bufferlist bl; bl.append_zero(len); return _write(cid, oid, offset, len, bl); } int MemStore::_truncate(const coll_t& cid, const ghobject_t& oid, uint64_t size) { dout(10) << __func__ << " " << cid << " " << oid << " " << size << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; const ssize_t old_size = o->get_size(); int r = o->truncate(size); used_bytes += (o->get_size() - old_size); return r; } int MemStore::_remove(const coll_t& cid, const ghobject_t& oid) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; std::lock_guard l{c->lock}; auto i = c->object_hash.find(oid); if (i == c->object_hash.end()) return -ENOENT; used_bytes -= i->second->get_size(); c->object_hash.erase(i); c->object_map.erase(oid); return 0; } int MemStore::_setattrs(const coll_t& cid, const ghobject_t& oid, map& aset) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->xattr_mutex}; for (map::const_iterator p = aset.begin(); p != aset.end(); ++p) o->xattr[p->first] = p->second; return 0; } int MemStore::_rmattr(const coll_t& cid, const ghobject_t& oid, const char *name) { dout(10) << __func__ << " " << cid << " " << oid << " " << name << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->xattr_mutex}; auto i = o->xattr.find(name); if (i == o->xattr.end()) return -ENODATA; o->xattr.erase(i); return 0; } int MemStore::_rmattrs(const coll_t& cid, const ghobject_t& oid) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->xattr_mutex}; o->xattr.clear(); return 0; } int MemStore::_clone(const coll_t& cid, const ghobject_t& oldoid, const ghobject_t& newoid) { dout(10) << __func__ << " " << cid << " " << oldoid << " -> " << newoid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef oo = c->get_object(oldoid); if (!oo) return -ENOENT; ObjectRef no = c->get_or_create_object(newoid); used_bytes += oo->get_size() - no->get_size(); no->clone(oo.get(), 0, oo->get_size(), 0); // take xattr and omap locks with std::lock() std::scoped_lock l{oo->xattr_mutex, no->xattr_mutex, oo->omap_mutex, no->omap_mutex}; no->omap_header = oo->omap_header; no->omap = oo->omap; no->xattr = oo->xattr; return 0; } int MemStore::_clone_range(const coll_t& cid, const ghobject_t& oldoid, const ghobject_t& newoid, uint64_t srcoff, uint64_t len, uint64_t dstoff) { dout(10) << __func__ << " " << cid << " " << oldoid << " " << srcoff << "~" << len << " -> " << newoid << " " << dstoff << "~" << len << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef oo = c->get_object(oldoid); if (!oo) return -ENOENT; ObjectRef no = c->get_or_create_object(newoid); if (srcoff >= oo->get_size()) return 0; if (srcoff + len >= oo->get_size()) len = oo->get_size() - srcoff; const ssize_t old_size = no->get_size(); no->clone(oo.get(), srcoff, len, dstoff); used_bytes += (no->get_size() - old_size); return len; } int MemStore::_omap_clear(const coll_t& cid, const ghobject_t &oid) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; o->omap.clear(); o->omap_header.clear(); return 0; } int MemStore::_omap_setkeys(const coll_t& cid, const ghobject_t &oid, bufferlist& aset_bl) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; auto p = aset_bl.cbegin(); __u32 num; decode(num, p); while (num--) { string key; decode(key, p); decode(o->omap[key], p); } return 0; } int MemStore::_omap_rmkeys(const coll_t& cid, const ghobject_t &oid, bufferlist& keys_bl) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; auto p = keys_bl.cbegin(); __u32 num; decode(num, p); while (num--) { string key; decode(key, p); o->omap.erase(key); } return 0; } int MemStore::_omap_rmkeyrange(const coll_t& cid, const ghobject_t &oid, const string& first, const string& last) { dout(10) << __func__ << " " << cid << " " << oid << " " << first << " " << last << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; map::iterator p = o->omap.lower_bound(first); map::iterator e = o->omap.lower_bound(last); o->omap.erase(p, e); return 0; } int MemStore::_omap_setheader(const coll_t& cid, const ghobject_t &oid, const bufferlist &bl) { dout(10) << __func__ << " " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; ObjectRef o = c->get_object(oid); if (!o) return -ENOENT; std::lock_guard lock{o->omap_mutex}; o->omap_header = bl; return 0; } int MemStore::_create_collection(const coll_t& cid, int bits) { dout(10) << __func__ << " " << cid << dendl; std::lock_guard l{coll_lock}; auto result = coll_map.insert(std::make_pair(cid, CollectionRef())); if (!result.second) return -EEXIST; auto p = new_coll_map.find(cid); ceph_assert(p != new_coll_map.end()); result.first->second = p->second; result.first->second->bits = bits; new_coll_map.erase(p); return 0; } int MemStore::_destroy_collection(const coll_t& cid) { dout(10) << __func__ << " " << cid << dendl; std::lock_guard l{coll_lock}; ceph::unordered_map::iterator cp = coll_map.find(cid); if (cp == coll_map.end()) return -ENOENT; { std::shared_lock l2{cp->second->lock}; if (!cp->second->object_map.empty()) return -ENOTEMPTY; cp->second->exists = false; } used_bytes -= cp->second->used_bytes(); coll_map.erase(cp); return 0; } int MemStore::_collection_add(const coll_t& cid, const coll_t& ocid, const ghobject_t& oid) { dout(10) << __func__ << " " << cid << " " << ocid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; CollectionRef oc = get_collection(ocid); if (!oc) return -ENOENT; std::scoped_lock l{std::min(&(*c), &(*oc))->lock, std::max(&(*c), &(*oc))->lock}; if (c->object_hash.count(oid)) return -EEXIST; if (oc->object_hash.count(oid) == 0) return -ENOENT; ObjectRef o = oc->object_hash[oid]; c->object_map[oid] = o; c->object_hash[oid] = o; return 0; } int MemStore::_collection_move_rename(const coll_t& oldcid, const ghobject_t& oldoid, coll_t cid, const ghobject_t& oid) { dout(10) << __func__ << " " << oldcid << " " << oldoid << " -> " << cid << " " << oid << dendl; CollectionRef c = get_collection(cid); if (!c) return -ENOENT; CollectionRef oc = get_collection(oldcid); if (!oc) return -ENOENT; // note: c and oc may be the same ceph_assert(&(*c) == &(*oc)); std::lock_guard l{c->lock}; if (c->object_hash.count(oid)) return -EEXIST; if (oc->object_hash.count(oldoid) == 0) return -ENOENT; { ObjectRef o = oc->object_hash[oldoid]; c->object_map[oid] = o; c->object_hash[oid] = o; oc->object_map.erase(oldoid); oc->object_hash.erase(oldoid); } return 0; } int MemStore::_split_collection(const coll_t& cid, uint32_t bits, uint32_t match, coll_t dest) { dout(10) << __func__ << " " << cid << " " << bits << " " << match << " " << dest << dendl; CollectionRef sc = get_collection(cid); if (!sc) return -ENOENT; CollectionRef dc = get_collection(dest); if (!dc) return -ENOENT; std::scoped_lock l{std::min(&(*sc), &(*dc))->lock, std::max(&(*sc), &(*dc))->lock}; map::iterator p = sc->object_map.begin(); while (p != sc->object_map.end()) { if (p->first.match(bits, match)) { dout(20) << " moving " << p->first << dendl; dc->object_map.insert(make_pair(p->first, p->second)); dc->object_hash.insert(make_pair(p->first, p->second)); sc->object_hash.erase(p->first); sc->object_map.erase(p++); } else { ++p; } } sc->bits = bits; ceph_assert(dc->bits == (int)bits); return 0; } int MemStore::_merge_collection(const coll_t& cid, uint32_t bits, coll_t dest) { dout(10) << __func__ << " " << cid << " " << bits << " " << dest << dendl; CollectionRef sc = get_collection(cid); if (!sc) return -ENOENT; CollectionRef dc = get_collection(dest); if (!dc) return -ENOENT; { std::scoped_lock l{std::min(&(*sc), &(*dc))->lock, std::max(&(*sc), &(*dc))->lock}; map::iterator p = sc->object_map.begin(); while (p != sc->object_map.end()) { dout(20) << " moving " << p->first << dendl; dc->object_map.insert(make_pair(p->first, p->second)); dc->object_hash.insert(make_pair(p->first, p->second)); sc->object_hash.erase(p->first); sc->object_map.erase(p++); } dc->bits = bits; } { std::lock_guard l{coll_lock}; ceph::unordered_map::iterator cp = coll_map.find(cid); ceph_assert(cp != coll_map.end()); used_bytes -= cp->second->used_bytes(); coll_map.erase(cp); } return 0; } namespace { struct BufferlistObject : public MemStore::Object { ceph::spinlock mutex; bufferlist data; size_t get_size() const override { return data.length(); } int read(uint64_t offset, uint64_t len, bufferlist &bl) override; int write(uint64_t offset, const bufferlist &bl) override; int clone(Object *src, uint64_t srcoff, uint64_t len, uint64_t dstoff) override; int truncate(uint64_t offset) override; void encode(bufferlist& bl) const override { ENCODE_START(1, 1, bl); encode(data, bl); encode_base(bl); ENCODE_FINISH(bl); } void decode(bufferlist::const_iterator& p) override { DECODE_START(1, p); decode(data, p); decode_base(p); DECODE_FINISH(p); } }; } // BufferlistObject int BufferlistObject::read(uint64_t offset, uint64_t len, bufferlist &bl) { std::lock_guard lock(mutex); bl.substr_of(data, offset, len); return bl.length(); } int BufferlistObject::write(uint64_t offset, const bufferlist &src) { unsigned len = src.length(); std::lock_guard lock(mutex); // before bufferlist newdata; if (get_size() >= offset) { newdata.substr_of(data, 0, offset); } else { if (get_size()) { newdata.substr_of(data, 0, get_size()); } newdata.append_zero(offset - get_size()); } newdata.append(src); // after if (get_size() > offset + len) { bufferlist tail; tail.substr_of(data, offset + len, get_size() - (offset + len)); newdata.append(tail); } data.claim(newdata); return 0; } int BufferlistObject::clone(Object *src, uint64_t srcoff, uint64_t len, uint64_t dstoff) { auto srcbl = dynamic_cast(src); if (srcbl == nullptr) return -ENOTSUP; bufferlist bl; { std::lock_guardmutex)> lock(srcbl->mutex); if (srcoff == dstoff && len == src->get_size()) { data = srcbl->data; return 0; } bl.substr_of(srcbl->data, srcoff, len); } return write(dstoff, bl); } int BufferlistObject::truncate(uint64_t size) { std::lock_guard lock(mutex); if (get_size() > size) { bufferlist bl; bl.substr_of(data, 0, size); data.claim(bl); } else if (get_size() == size) { // do nothing } else { data.append_zero(size - get_size()); } return 0; } // PageSetObject struct MemStore::PageSetObject : public Object { PageSet data; uint64_t data_len; #if defined(__GLIBCXX__) // use a thread-local vector for the pages returned by PageSet, so we // can avoid allocations in read/write() static thread_local PageSet::page_vector tls_pages; #endif explicit PageSetObject(size_t page_size) : data(page_size), data_len(0) {} size_t get_size() const override { return data_len; } int read(uint64_t offset, uint64_t len, bufferlist &bl) override; int write(uint64_t offset, const bufferlist &bl) override; int clone(Object *src, uint64_t srcoff, uint64_t len, uint64_t dstoff) override; int truncate(uint64_t offset) override; void encode(bufferlist& bl) const override { ENCODE_START(1, 1, bl); encode(data_len, bl); data.encode(bl); encode_base(bl); ENCODE_FINISH(bl); } void decode(bufferlist::const_iterator& p) override { DECODE_START(1, p); decode(data_len, p); data.decode(p); decode_base(p); DECODE_FINISH(p); } }; #if defined(__GLIBCXX__) // use a thread-local vector for the pages returned by PageSet, so we // can avoid allocations in read/write() thread_local PageSet::page_vector MemStore::PageSetObject::tls_pages; #define DEFINE_PAGE_VECTOR(name) #else #define DEFINE_PAGE_VECTOR(name) PageSet::page_vector name; #endif int MemStore::PageSetObject::read(uint64_t offset, uint64_t len, bufferlist& bl) { const auto start = offset; const auto end = offset + len; auto remaining = len; DEFINE_PAGE_VECTOR(tls_pages); data.get_range(offset, len, tls_pages); // allocate a buffer for the data buffer::ptr buf(len); auto p = tls_pages.begin(); while (remaining) { // no more pages in range if (p == tls_pages.end() || (*p)->offset >= end) { buf.zero(offset - start, remaining); break; } auto page = *p; // fill any holes between pages with zeroes if (page->offset > offset) { const auto count = std::min(remaining, page->offset - offset); buf.zero(offset - start, count); remaining -= count; offset = page->offset; if (!remaining) break; } // read from page const auto page_offset = offset - page->offset; const auto count = min(remaining, data.get_page_size() - page_offset); buf.copy_in(offset - start, count, page->data + page_offset); remaining -= count; offset += count; ++p; } tls_pages.clear(); // drop page refs bl.append(std::move(buf)); return len; } int MemStore::PageSetObject::write(uint64_t offset, const bufferlist &src) { unsigned len = src.length(); DEFINE_PAGE_VECTOR(tls_pages); // make sure the page range is allocated data.alloc_range(offset, src.length(), tls_pages); auto page = tls_pages.begin(); auto p = src.begin(); while (len > 0) { unsigned page_offset = offset - (*page)->offset; unsigned pageoff = data.get_page_size() - page_offset; unsigned count = min(len, pageoff); p.copy(count, (*page)->data + page_offset); offset += count; len -= count; if (count == pageoff) ++page; } if (data_len < offset) data_len = offset; tls_pages.clear(); // drop page refs return 0; } int MemStore::PageSetObject::clone(Object *src, uint64_t srcoff, uint64_t len, uint64_t dstoff) { const int64_t delta = dstoff - srcoff; auto &src_data = static_cast(src)->data; const uint64_t src_page_size = src_data.get_page_size(); auto &dst_data = data; const auto dst_page_size = dst_data.get_page_size(); DEFINE_PAGE_VECTOR(tls_pages); PageSet::page_vector dst_pages; while (len) { // limit to 16 pages at a time so tls_pages doesn't balloon in size auto count = std::min(len, (uint64_t)src_page_size * 16); src_data.get_range(srcoff, count, tls_pages); // allocate the destination range // TODO: avoid allocating pages for holes in the source range dst_data.alloc_range(srcoff + delta, count, dst_pages); auto dst_iter = dst_pages.begin(); for (auto &src_page : tls_pages) { auto sbegin = std::max(srcoff, src_page->offset); auto send = std::min(srcoff + count, src_page->offset + src_page_size); // zero-fill holes before src_page if (srcoff < sbegin) { while (dst_iter != dst_pages.end()) { auto &dst_page = *dst_iter; auto dbegin = std::max(srcoff + delta, dst_page->offset); auto dend = std::min(sbegin + delta, dst_page->offset + dst_page_size); std::fill(dst_page->data + dbegin - dst_page->offset, dst_page->data + dend - dst_page->offset, 0); if (dend < dst_page->offset + dst_page_size) break; ++dst_iter; } const auto c = sbegin - srcoff; count -= c; len -= c; } // copy data from src page to dst pages while (dst_iter != dst_pages.end()) { auto &dst_page = *dst_iter; auto dbegin = std::max(sbegin + delta, dst_page->offset); auto dend = std::min(send + delta, dst_page->offset + dst_page_size); std::copy(src_page->data + (dbegin - delta) - src_page->offset, src_page->data + (dend - delta) - src_page->offset, dst_page->data + dbegin - dst_page->offset); if (dend < dst_page->offset + dst_page_size) break; ++dst_iter; } const auto c = send - sbegin; count -= c; len -= c; srcoff = send; dstoff = send + delta; } tls_pages.clear(); // drop page refs // zero-fill holes after the last src_page if (count > 0) { while (dst_iter != dst_pages.end()) { auto &dst_page = *dst_iter; auto dbegin = std::max(dstoff, dst_page->offset); auto dend = std::min(dstoff + count, dst_page->offset + dst_page_size); std::fill(dst_page->data + dbegin - dst_page->offset, dst_page->data + dend - dst_page->offset, 0); ++dst_iter; } srcoff += count; dstoff += count; len -= count; } dst_pages.clear(); // drop page refs } // update object size if (data_len < dstoff) data_len = dstoff; return 0; } int MemStore::PageSetObject::truncate(uint64_t size) { data.free_pages_after(size); data_len = size; const auto page_size = data.get_page_size(); const auto page_offset = size & ~(page_size-1); if (page_offset == size) return 0; DEFINE_PAGE_VECTOR(tls_pages); // write zeroes to the rest of the last page data.get_range(page_offset, page_size, tls_pages); if (tls_pages.empty()) return 0; auto page = tls_pages.begin(); auto data = (*page)->data; std::fill(data + (size - page_offset), data + page_size, 0); tls_pages.clear(); // drop page ref return 0; } MemStore::ObjectRef MemStore::Collection::create_object() const { if (use_page_set) return new PageSetObject(cct->_conf->memstore_page_size); return new BufferlistObject(); }