2020-12-09 21:09:46 +01:00
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/* -*- mode: C++; c-basic-offset: 4; indent-tabs-mode: nil -*- */
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// vim: ft=cpp:expandtab:ts=8:sw=4:softtabstop=4:
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#ident "$Id$"
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/*======
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This file is part of PerconaFT.
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Copyright (c) 2006, 2015, Percona and/or its affiliates. All rights reserved.
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PerconaFT is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License, version 2,
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as published by the Free Software Foundation.
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PerconaFT is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with PerconaFT. If not, see <http://www.gnu.org/licenses/>.
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----------------------------------------
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PerconaFT is free software: you can redistribute it and/or modify
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it under the terms of the GNU Affero General Public License, version 3,
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as published by the Free Software Foundation.
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PerconaFT is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU Affero General Public License for more details.
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You should have received a copy of the GNU Affero General Public License
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along with PerconaFT. If not, see <http://www.gnu.org/licenses/>.
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----------------------------------------
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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2020-12-22 23:46:20 +01:00
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limitations under the License.
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2020-12-09 21:09:46 +01:00
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======= */
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#ident \
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"Copyright (c) 2006, 2015, Percona and/or its affiliates. All rights reserved."
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#pragma once
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#include <atomic>
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#include "../db.h"
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#include "../ft/comparator.h"
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#include "../portability/toku_external_pthread.h"
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#include "../portability/toku_pthread.h"
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#include "../portability/toku_time.h"
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// PORT #include <ft/ft-ops.h> // just for DICTIONARY_ID..
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// PORT: ft-status for LTM_STATUS:
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#include "../ft/ft-status.h"
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struct DICTIONARY_ID {
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uint64_t dictid;
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};
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#include "../util/omt.h"
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#include "range_buffer.h"
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#include "txnid_set.h"
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#include "wfg.h"
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namespace toku {
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class locktree;
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class locktree_manager;
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class lock_request;
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class concurrent_tree;
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typedef int (*lt_create_cb)(locktree *lt, void *extra);
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typedef void (*lt_destroy_cb)(locktree *lt);
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typedef void (*lt_escalate_cb)(TXNID txnid, const locktree *lt,
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const range_buffer &buffer, void *extra);
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struct lt_counters {
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uint64_t wait_count, wait_time;
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uint64_t long_wait_count, long_wait_time;
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uint64_t timeout_count;
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void add(const lt_counters &rhs) {
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wait_count += rhs.wait_count;
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wait_time += rhs.wait_time;
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long_wait_count += rhs.long_wait_count;
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long_wait_time += rhs.long_wait_time;
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timeout_count += rhs.timeout_count;
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}
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};
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// Lock request state for some locktree
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struct lt_lock_request_info {
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omt<lock_request *> pending_lock_requests;
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std::atomic_bool pending_is_empty;
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toku_external_mutex_t mutex;
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bool should_retry_lock_requests;
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lt_counters counters;
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std::atomic_ullong retry_want;
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unsigned long long retry_done;
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toku_mutex_t retry_mutex;
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toku_cond_t retry_cv;
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bool running_retry;
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void init(toku_external_mutex_factory_t mutex_factory);
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void destroy(void);
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};
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// The locktree manager manages a set of locktrees, one for each open
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// dictionary. Locktrees are retrieved from the manager. When they are no
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// longer needed, they are be released by the user.
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class locktree_manager {
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public:
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// param: create_cb, called just after a locktree is first created.
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// destroy_cb, called just before a locktree is destroyed.
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// escalate_cb, called after a locktree is escalated (with extra
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// param)
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void create(lt_create_cb create_cb, lt_destroy_cb destroy_cb,
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lt_escalate_cb escalate_cb, void *extra,
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toku_external_mutex_factory_t mutex_factory_arg);
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void destroy(void);
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size_t get_max_lock_memory(void);
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int set_max_lock_memory(size_t max_lock_memory);
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// effect: Get a locktree from the manager. If a locktree exists with the
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// given
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// dict_id, it is referenced and then returned. If one did not exist,
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// it is created. It will use the comparator for comparing keys. The
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// on_create callback (passed to locktree_manager::create()) will be
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// called with the given extra parameter.
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locktree *get_lt(DICTIONARY_ID dict_id, const comparator &cmp,
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void *on_create_extra);
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void reference_lt(locktree *lt);
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// effect: Releases one reference on a locktree. If the reference count
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// transitions
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// to zero, the on_destroy callback is called before it gets
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// destroyed.
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void release_lt(locktree *lt);
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void get_status(LTM_STATUS status);
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// effect: calls the iterate function on each pending lock request
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// note: holds the manager's mutex
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typedef int (*lock_request_iterate_callback)(DICTIONARY_ID dict_id,
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TXNID txnid, const DBT *left_key,
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const DBT *right_key,
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TXNID blocking_txnid,
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uint64_t start_time,
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void *extra);
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int iterate_pending_lock_requests(lock_request_iterate_callback cb,
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void *extra);
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// effect: Determines if too many locks or too much memory is being used,
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// Runs escalation on the manager if so.
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// param: big_txn, if the current transaction is 'big' (has spilled rollback
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// logs) returns: 0 if there enough resources to create a new lock, or
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// TOKUDB_OUT_OF_LOCKS
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// if there are not enough resources and lock escalation failed to
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// free up enough resources for a new lock.
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int check_current_lock_constraints(bool big_txn);
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bool over_big_threshold(void);
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void note_mem_used(uint64_t mem_used);
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void note_mem_released(uint64_t mem_freed);
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bool out_of_locks(void) const;
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// Escalate all locktrees
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void escalate_all_locktrees(void);
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// Escalate a set of locktrees
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void escalate_locktrees(locktree **locktrees, int num_locktrees);
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// effect: calls the private function run_escalation(), only ok to
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// do for tests.
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// rationale: to get better stress test coverage, we want a way to
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// deterministicly trigger lock escalation.
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void run_escalation_for_test(void);
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void run_escalation(void);
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// Add time t to the escalator's wait time statistics
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void add_escalator_wait_time(uint64_t t);
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void kill_waiter(void *extra);
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private:
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static const uint64_t DEFAULT_MAX_LOCK_MEMORY = 64L * 1024 * 1024;
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// tracks the current number of locks and lock memory
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uint64_t m_max_lock_memory;
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uint64_t m_current_lock_memory;
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struct lt_counters m_lt_counters;
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// the create and destroy callbacks for the locktrees
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lt_create_cb m_lt_create_callback;
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lt_destroy_cb m_lt_destroy_callback;
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lt_escalate_cb m_lt_escalate_callback;
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void *m_lt_escalate_callback_extra;
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omt<locktree *> m_locktree_map;
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toku_external_mutex_factory_t mutex_factory;
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// the manager's mutex protects the locktree map
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toku_mutex_t m_mutex;
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void mutex_lock(void);
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void mutex_unlock(void);
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// Manage the set of open locktrees
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locktree *locktree_map_find(const DICTIONARY_ID &dict_id);
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void locktree_map_put(locktree *lt);
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void locktree_map_remove(locktree *lt);
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static int find_by_dict_id(locktree *const <, const DICTIONARY_ID &dict_id);
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void escalator_init(void);
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void escalator_destroy(void);
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// statistics about lock escalation.
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toku_mutex_t m_escalation_mutex;
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uint64_t m_escalation_count;
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tokutime_t m_escalation_time;
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uint64_t m_escalation_latest_result;
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uint64_t m_wait_escalation_count;
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uint64_t m_wait_escalation_time;
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uint64_t m_long_wait_escalation_count;
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uint64_t m_long_wait_escalation_time;
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// the escalator coordinates escalation on a set of locktrees for a bunch of
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// threads
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class locktree_escalator {
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public:
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void create(void);
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void destroy(void);
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void run(locktree_manager *mgr, void (*escalate_locktrees_fun)(void *extra),
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void *extra);
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private:
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toku_mutex_t m_escalator_mutex;
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toku_cond_t m_escalator_done;
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bool m_escalator_running;
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};
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locktree_escalator m_escalator;
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friend class manager_unit_test;
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};
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// A locktree represents the set of row locks owned by all transactions
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// over an open dictionary. Read and write ranges are represented as
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// a left and right key which are compared with the given comparator
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//
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// Locktrees are not created and destroyed by the user. Instead, they are
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// referenced and released using the locktree manager.
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//
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// A sample workflow looks like this:
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// - Create a manager.
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// - Get a locktree by dictionaroy id from the manager.
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// - Perform read/write lock acquision on the locktree, add references to
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// the locktree using the manager, release locks, release references, etc.
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// - ...
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// - Release the final reference to the locktree. It will be destroyed.
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// - Destroy the manager.
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class locktree {
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public:
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// effect: Creates a locktree
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void create(locktree_manager *mgr, DICTIONARY_ID dict_id,
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const comparator &cmp,
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toku_external_mutex_factory_t mutex_factory);
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void destroy(void);
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// For thread-safe, external reference counting
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void add_reference(void);
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// requires: the reference count is > 0
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// returns: the reference count, after decrementing it by one
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uint32_t release_reference(void);
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// returns: the current reference count
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uint32_t get_reference_count(void);
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// effect: Attempts to grant a read lock for the range of keys between
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// [left_key, right_key]. returns: If the lock cannot be granted, return
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// DB_LOCK_NOTGRANTED, and populate the
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// given conflicts set with the txnids that hold conflicting locks in
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// the range. If the locktree cannot create more locks, return
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// TOKUDB_OUT_OF_LOCKS.
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// note: Read locks cannot be shared between txnids, as one would expect.
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// This is for simplicity since read locks are rare in MySQL.
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int acquire_read_lock(TXNID txnid, const DBT *left_key, const DBT *right_key,
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txnid_set *conflicts, bool big_txn);
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// effect: Attempts to grant a write lock for the range of keys between
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// [left_key, right_key]. returns: If the lock cannot be granted, return
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// DB_LOCK_NOTGRANTED, and populate the
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// given conflicts set with the txnids that hold conflicting locks in
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// the range. If the locktree cannot create more locks, return
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// TOKUDB_OUT_OF_LOCKS.
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int acquire_write_lock(TXNID txnid, const DBT *left_key, const DBT *right_key,
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txnid_set *conflicts, bool big_txn);
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// effect: populate the conflicts set with the txnids that would preventing
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// the given txnid from getting a lock on [left_key, right_key]
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void get_conflicts(bool is_write_request, TXNID txnid, const DBT *left_key,
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const DBT *right_key, txnid_set *conflicts);
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// effect: Release all of the lock ranges represented by the range buffer for
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// a txnid.
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void release_locks(TXNID txnid, const range_buffer *ranges,
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bool all_trx_locks_hint = false);
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// effect: Runs escalation on this locktree
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void escalate(lt_escalate_cb after_escalate_callback, void *extra);
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// returns: The userdata associated with this locktree, or null if it has not
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// been set.
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void *get_userdata(void) const;
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void set_userdata(void *userdata);
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locktree_manager *get_manager(void) const;
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void set_comparator(const comparator &cmp);
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int compare(const locktree *lt) const;
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DICTIONARY_ID get_dict_id() const;
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// Private info struct for storing pending lock request state.
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// Only to be used by lock requests. We store it here as
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// something less opaque than usual to strike a tradeoff between
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// abstraction and code complexity. It is still fairly abstract
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// since the lock_request object is opaque
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struct lt_lock_request_info *get_lock_request_info(void);
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typedef void (*dump_callback)(void *cdata, const DBT *left, const DBT *right,
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TXNID txnid, bool is_shared,
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TxnidVector *owners);
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void dump_locks(void *cdata, dump_callback cb);
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private:
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locktree_manager *m_mgr;
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DICTIONARY_ID m_dict_id;
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uint32_t m_reference_count;
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// Since the memory referenced by this comparator is not owned by the
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// locktree, the user must guarantee it will outlive the locktree.
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//
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// The ydb API accomplishes this by opening an ft_handle in the on_create
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// callback, which will keep the underlying FT (and its descriptor) in memory
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// for as long as the handle is open. The ft_handle is stored opaquely in the
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// userdata pointer below. see locktree_manager::get_lt w/ on_create_extra
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comparator m_cmp;
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concurrent_tree *m_rangetree;
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void *m_userdata;
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struct lt_lock_request_info m_lock_request_info;
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// psergey-todo:
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// Each transaction also keeps a list of ranges it has locked.
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// So, when a transaction is running in STO mode, two identical
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// lists are kept: the STO lock list and transaction's owned locks
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// list. Why can't we do with just one list?
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// The following fields and members prefixed with "sto_" are for
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// the single txnid optimization, intended to speed up the case
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// when only one transaction is using the locktree. If we know
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// the locktree has only one transaction, then acquiring locks
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// takes O(1) work and releasing all locks takes O(1) work.
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//
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// How do we know that the locktree only has a single txnid?
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// What do we do if it does?
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//
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// When a txn with txnid T requests a lock:
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// - If the tree is empty, the optimization is possible. Set the single
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// txnid to T, and insert the lock range into the buffer.
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// - If the tree is not empty, check if the single txnid is T. If so,
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// append the lock range to the buffer. Otherwise, migrate all of
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// the locks in the buffer into the rangetree on behalf of txnid T,
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// and invalid the single txnid.
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//
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// When a txn with txnid T releases its locks:
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// - If the single txnid is valid, it must be for T. Destroy the buffer.
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// - If it's not valid, release locks the normal way in the rangetree.
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//
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// To carry out the optimization we need to record a single txnid
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// and a range buffer for each locktree, each protected by the root
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// lock of the locktree's rangetree. The root lock for a rangetree
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// is grabbed by preparing a locked keyrange on the rangetree.
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TXNID m_sto_txnid;
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range_buffer m_sto_buffer;
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// The single txnid optimization speeds up the case when only one
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// transaction is using the locktree. But it has the potential to
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// hurt the case when more than one txnid exists.
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//
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// There are two things we need to do to make the optimization only
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// optimize the case we care about, and not hurt the general case.
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//
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// Bound the worst-case latency for lock migration when the
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// optimization stops working:
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// - Idea: Stop the optimization and migrate immediate if we notice
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// the single txnid has takes many locks in the range buffer.
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// - Implementation: Enforce a max size on the single txnid range buffer.
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// - Analysis: Choosing the perfect max value, M, is difficult to do
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// without some feedback from the field. Intuition tells us that M should
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// not be so small that the optimization is worthless, and it should not
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// be so big that it's unreasonable to have to wait behind a thread doing
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// the work of converting M buffer locks into rangetree locks.
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//
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// Prevent concurrent-transaction workloads from trying the optimization
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// in vain:
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// - Idea: Don't even bother trying the optimization if we think the
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// system is in a concurrent-transaction state.
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// - Implementation: Do something even simpler than detecting whether the
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// system is in a concurent-transaction state. Just keep a "score" value
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// and some threshold. If at any time the locktree is eligible for the
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// optimization, only do it if the score is at this threshold. When you
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// actually do the optimization but someone has to migrate locks in the buffer
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// (expensive), then reset the score back to zero. Each time a txn
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// releases locks, the score is incremented by 1.
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// - Analysis: If you let the threshold be "C", then at most 1 / C txns will
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// do the optimization in a concurrent-transaction system. Similarly, it
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// takes at most C txns to start using the single txnid optimzation, which
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// is good when the system transitions from multithreaded to single threaded.
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//
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// STO_BUFFER_MAX_SIZE:
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//
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// We choose the max value to be 1 million since most transactions are smaller
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// than 1 million and we can create a rangetree of 1 million elements in
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// less than a second. So we can be pretty confident that this threshold
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// enables the optimization almost always, and prevents super pathological
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// latency issues for the first lock taken by a second thread.
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//
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// STO_SCORE_THRESHOLD:
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//
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// A simple first guess at a good value for the score threshold is 100.
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// By our analysis, we'd end up doing the optimization in vain for
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// around 1% of all transactions, which seems reasonable. Further,
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// if the system goes single threaded, it ought to be pretty quick
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// for 100 transactions to go by, so we won't have to wait long before
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// we start doing the single txind optimzation again.
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static const int STO_BUFFER_MAX_SIZE = 50 * 1024;
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static const int STO_SCORE_THRESHOLD = 100;
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int m_sto_score;
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// statistics about time spent ending the STO early
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uint64_t m_sto_end_early_count;
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tokutime_t m_sto_end_early_time;
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// effect: begins the single txnid optimizaiton, setting m_sto_txnid
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// to the given txnid.
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// requires: m_sto_txnid is invalid
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void sto_begin(TXNID txnid);
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// effect: append a range to the sto buffer
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// requires: m_sto_txnid is valid
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void sto_append(const DBT *left_key, const DBT *right_key,
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bool is_write_request);
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// effect: ends the single txnid optimization, releaseing any memory
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// stored in the sto buffer, notifying the tracker, and
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// invalidating m_sto_txnid.
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// requires: m_sto_txnid is valid
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void sto_end(void);
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// params: prepared_lkr is a void * to a prepared locked keyrange. see below.
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// effect: ends the single txnid optimization early, migrating buffer locks
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// into the rangetree, calling sto_end(), and then setting the
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// sto_score back to zero.
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// requires: m_sto_txnid is valid
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void sto_end_early(void *prepared_lkr);
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void sto_end_early_no_accounting(void *prepared_lkr);
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// params: prepared_lkr is a void * to a prepared locked keyrange. we can't
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// use
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// the real type because the compiler won't allow us to forward
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|
// declare concurrent_tree::locked_keyrange without including
|
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|
// concurrent_tree.h, which we cannot do here because it is a template
|
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// implementation.
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// requires: the prepared locked keyrange is for the locktree's rangetree
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// requires: m_sto_txnid is valid
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// effect: migrates each lock in the single txnid buffer into the locktree's
|
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// rangetree, notifying the memory tracker as necessary.
|
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|
void sto_migrate_buffer_ranges_to_tree(void *prepared_lkr);
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// effect: If m_sto_txnid is valid, then release the txnid's locks
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// by ending the optimization.
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|
// requires: If m_sto_txnid is valid, it is equal to the given txnid
|
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// returns: True if locks were released for this txnid
|
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|
|
bool sto_try_release(TXNID txnid);
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|
// params: prepared_lkr is a void * to a prepared locked keyrange. see above.
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|
// requires: the prepared locked keyrange is for the locktree's rangetree
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|
// effect: If m_sto_txnid is valid and equal to the given txnid, then
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|
// append a range onto the buffer. Otherwise, if m_sto_txnid is valid
|
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|
|
// but not equal to this txnid, then migrate the buffer's locks
|
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|
|
// into the rangetree and end the optimization, setting the score
|
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|
// back to zero.
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|
// returns: true if the lock was acquired for this txnid
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|
|
bool sto_try_acquire(void *prepared_lkr, TXNID txnid, const DBT *left_key,
|
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|
|
const DBT *right_key, bool is_write_request);
|
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|
|
// Effect:
|
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|
|
// Provides a hook for a helgrind suppression.
|
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|
|
// Returns:
|
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|
|
// true if m_sto_txnid is not TXNID_NONE
|
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|
|
bool sto_txnid_is_valid_unsafe(void) const;
|
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|
|
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|
|
// Effect:
|
|
|
|
// Provides a hook for a helgrind suppression.
|
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|
|
// Returns:
|
|
|
|
// m_sto_score
|
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|
|
int sto_get_score_unsafe(void) const;
|
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|
|
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|
|
void remove_overlapping_locks_for_txnid(TXNID txnid, const DBT *left_key,
|
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|
|
const DBT *right_key);
|
|
|
|
|
|
|
|
int acquire_lock_consolidated(void *prepared_lkr, TXNID txnid,
|
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|
|
const DBT *left_key, const DBT *right_key,
|
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|
|
bool is_write_request, txnid_set *conflicts);
|
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|
|
|
|
|
|
int acquire_lock(bool is_write_request, TXNID txnid, const DBT *left_key,
|
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|
|
const DBT *right_key, txnid_set *conflicts);
|
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|
|
|
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|
|
int try_acquire_lock(bool is_write_request, TXNID txnid, const DBT *left_key,
|
|
|
|
const DBT *right_key, txnid_set *conflicts,
|
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|
|
bool big_txn);
|
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|
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|
friend class locktree_unit_test;
|
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|
|
friend class manager_unit_test;
|
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|
|
friend class lock_request_unit_test;
|
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|
|
// engine status reaches into the locktree to read some stats
|
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|
|
friend void locktree_manager::get_status(LTM_STATUS status);
|
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|
|
};
|
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|
} /* namespace toku */
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