/***************************************************************************** Copyright (c) 1995, 2016, Oracle and/or its affiliates. All Rights Reserved. Copyright (c) 2008, Google Inc. Copyright (c) 2017, 2020, MariaDB Corporation. Portions of this file contain modifications contributed and copyrighted by Google, Inc. Those modifications are gratefully acknowledged and are described briefly in the InnoDB documentation. The contributions by Google are incorporated with their permission, and subject to the conditions contained in the file COPYING.Google. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; version 2 of the License. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1335 USA *****************************************************************************/ /**************************************************//** @file sync/sync0rw.cc The read-write lock (for thread synchronization) Created 9/11/1995 Heikki Tuuri *******************************************************/ #include "sync0rw.h" #include "my_cpu.h" #include /* IMPLEMENTATION OF THE RW_LOCK ============================= The status of a rw_lock is held in lock_word. The initial value of lock_word is X_LOCK_DECR. lock_word is decremented by 1 for each s-lock and by X_LOCK_DECR or 1 for each x-lock. This describes the lock state for each value of lock_word: lock_word == X_LOCK_DECR: Unlocked. X_LOCK_HALF_DECR < lock_word < X_LOCK_DECR: S locked, no waiting writers. (X_LOCK_DECR - lock_word) is the number of S locks. lock_word == X_LOCK_HALF_DECR: SX locked, no waiting writers. 0 < lock_word < X_LOCK_HALF_DECR: SX locked AND S locked, no waiting writers. (X_LOCK_HALF_DECR - lock_word) is the number of S locks. lock_word == 0: X locked, no waiting writers. -X_LOCK_HALF_DECR < lock_word < 0: S locked, with a waiting writer. (-lock_word) is the number of S locks. lock_word == -X_LOCK_HALF_DECR: X locked and SX locked, no waiting writers. -X_LOCK_DECR < lock_word < -X_LOCK_HALF_DECR: S locked, with a waiting writer which has SX lock. -(lock_word + X_LOCK_HALF_DECR) is the number of S locks. lock_word == -X_LOCK_DECR: X locked with recursive X lock (2 X locks). -(X_LOCK_DECR + X_LOCK_HALF_DECR) < lock_word < -X_LOCK_DECR: X locked. The number of the X locks is: 2 - (lock_word + X_LOCK_DECR) lock_word == -(X_LOCK_DECR + X_LOCK_HALF_DECR): X locked with recursive X lock (2 X locks) and SX locked. lock_word < -(X_LOCK_DECR + X_LOCK_HALF_DECR): X locked and SX locked. The number of the X locks is: 2 - (lock_word + X_LOCK_DECR + X_LOCK_HALF_DECR) LOCK COMPATIBILITY MATRIX | S|SX| X| --+--+--+--+ S| +| +| -| --+--+--+--+ SX| +| -| -| --+--+--+--+ X| -| -| -| --+--+--+--+ The lock_word is always read and updated atomically and consistently, so that it always represents the state of the lock, and the state of the lock changes with a single atomic operation. This lock_word holds all of the information that a thread needs in order to determine if it is eligible to gain the lock or if it must spin or sleep. The one exception to this is that writer_thread must be verified before recursive write locks: to solve this scenario, we make writer_thread readable by all threads, but only writeable by the x-lock or sx-lock holder. The other members of the lock obey the following rules to remain consistent: writer_thread: Is used only in recursive x-locking or sx-locking. This field is 0 at lock creation time and is updated when x-lock is acquired or when move_ownership is called. A thread is only allowed to set the value of this field to it's thread_id i.e.: a thread cannot set writer_thread to some other thread's id. waiters: May be set to 1 anytime, but to avoid unnecessary wake-up signals, it should only be set to 1 when there are threads waiting on event. Must be 1 when a writer starts waiting to ensure the current x-locking thread sends a wake-up signal during unlock. May only be reset to 0 immediately before a a wake-up signal is sent to event. On most platforms, a memory barrier is required after waiters is set, and before verifying lock_word is still held, to ensure some unlocker really does see the flags new value. event: Threads wait on event for read or writer lock when another thread has an x-lock or an x-lock reservation (wait_ex). A thread may only wait on event after performing the following actions in order: (1) Record the counter value of event (with os_event_reset). (2) Set waiters to 1. (3) Verify lock_word <= 0. (1) must come before (2) to ensure signal is not missed. (2) must come before (3) to ensure a signal is sent. These restrictions force the above ordering. Immediately before sending the wake-up signal, we should: (1) Verify lock_word == X_LOCK_DECR (unlocked) (2) Reset waiters to 0. wait_ex_event: A thread may only wait on the wait_ex_event after it has performed the following actions in order: (1) Decrement lock_word by X_LOCK_DECR. (2) Record counter value of wait_ex_event (os_event_reset, called from sync_array_reserve_cell). (3) Verify that lock_word < 0. (1) must come first to ensures no other threads become reader or next writer, and notifies unlocker that signal must be sent. (2) must come before (3) to ensure the signal is not missed. These restrictions force the above ordering. Immediately before sending the wake-up signal, we should: Verify lock_word == 0 (waiting thread holds x_lock) */ rw_lock_stats_t rw_lock_stats; /* The global list of rw-locks */ ilist rw_lock_list; ib_mutex_t rw_lock_list_mutex; #ifdef UNIV_DEBUG /******************************************************************//** Creates a debug info struct. */ static rw_lock_debug_t* rw_lock_debug_create(void); /*======================*/ /******************************************************************//** Frees a debug info struct. */ static void rw_lock_debug_free( /*===============*/ rw_lock_debug_t* info); /******************************************************************//** Creates a debug info struct. @return own: debug info struct */ static rw_lock_debug_t* rw_lock_debug_create(void) /*======================*/ { return((rw_lock_debug_t*) ut_malloc_nokey(sizeof(rw_lock_debug_t))); } /******************************************************************//** Frees a debug info struct. */ static void rw_lock_debug_free( /*===============*/ rw_lock_debug_t* info) { ut_free(info); } #endif /* UNIV_DEBUG */ /******************************************************************//** Creates, or rather, initializes an rw-lock object in a specified memory location (which must be appropriately aligned). The rw-lock is initialized to the non-locked state. Explicit freeing of the rw-lock with rw_lock_free is necessary only if the memory block containing it is freed. */ void rw_lock_create_func( /*================*/ rw_lock_t* lock, /*!< in: pointer to memory */ #ifdef UNIV_DEBUG latch_level_t level, /*!< in: level */ #endif /* UNIV_DEBUG */ const char* cfile_name, /*!< in: file name where created */ unsigned cline) /*!< in: file line where created */ { #if defined(UNIV_DEBUG) && !defined(UNIV_PFS_RWLOCK) /* It should have been created in pfs_rw_lock_create_func() */ new(lock) rw_lock_t(); #endif /* UNIV_DEBUG */ lock->lock_word = X_LOCK_DECR; lock->waiters = 0; lock->sx_recursive = 0; lock->writer_thread= 0; #ifdef UNIV_DEBUG lock->m_rw_lock = true; UT_LIST_INIT(lock->debug_list, &rw_lock_debug_t::list); lock->m_id = sync_latch_get_id(sync_latch_get_name(level)); ut_a(lock->m_id != LATCH_ID_NONE); lock->level = level; #endif /* UNIV_DEBUG */ lock->cfile_name = cfile_name; /* This should hold in practice. If it doesn't then we need to split the source file anyway. Or create the locks on lines less than 8192. cline is unsigned:13. */ ut_ad(cline <= ((1U << 13) - 1)); lock->cline = cline & ((1U << 13) - 1); lock->count_os_wait = 0; lock->last_x_file_name = "not yet reserved"; lock->last_x_line = 0; lock->event = os_event_create(0); lock->wait_ex_event = os_event_create(0); lock->is_block_lock = 0; ut_d(lock->created = true); mutex_enter(&rw_lock_list_mutex); rw_lock_list.push_front(*lock); mutex_exit(&rw_lock_list_mutex); } /******************************************************************//** Calling this function is obligatory only if the memory buffer containing the rw-lock is freed. Removes an rw-lock object from the global list. The rw-lock is checked to be in the non-locked state. */ void rw_lock_free_func( /*==============*/ rw_lock_t* lock) /*!< in/out: rw-lock */ { ut_ad(rw_lock_validate(lock)); ut_a(lock->lock_word == X_LOCK_DECR); ut_d(lock->created = false); mutex_enter(&rw_lock_list_mutex); os_event_destroy(lock->event); os_event_destroy(lock->wait_ex_event); rw_lock_list.remove(*lock); mutex_exit(&rw_lock_list_mutex); } /******************************************************************//** Lock an rw-lock in shared mode for the current thread. If the rw-lock is locked in exclusive mode, or there is an exclusive lock request waiting, the function spins a preset time (controlled by srv_n_spin_wait_rounds), waiting for the lock, before suspending the thread. */ void rw_lock_s_lock_spin( /*================*/ rw_lock_t* lock, /*!< in: pointer to rw-lock */ ulint pass, /*!< in: pass value; != 0, if the lock will be passed to another thread to unlock */ const char* file_name, /*!< in: file name where lock requested */ unsigned line) /*!< in: line where requested */ { ulint i = 0; /* spin round count */ sync_array_t* sync_arr; lint spin_count = 0; int64_t count_os_wait = 0; /* We reuse the thread id to index into the counter, cache it here for efficiency. */ ut_ad(rw_lock_validate(lock)); rw_lock_stats.rw_s_spin_wait_count.inc(); lock_loop: /* Spin waiting for the writer field to become free */ HMT_low(); ulint j = i; while (i < srv_n_spin_wait_rounds && lock->lock_word <= 0) { ut_delay(srv_spin_wait_delay); i++; } HMT_medium(); if (i >= srv_n_spin_wait_rounds) { os_thread_yield(); } spin_count += lint(i - j); /* We try once again to obtain the lock */ if (rw_lock_s_lock_low(lock, pass, file_name, line)) { if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_s_os_wait_count.add(count_os_wait); } rw_lock_stats.rw_s_spin_round_count.add(spin_count); return; /* Success */ } else { if (i < srv_n_spin_wait_rounds) { goto lock_loop; } ++count_os_wait; sync_cell_t* cell; sync_arr = sync_array_get_and_reserve_cell( lock, RW_LOCK_S, file_name, line, &cell); /* Set waiters before checking lock_word to ensure wake-up signal is sent. This may lead to some unnecessary signals. */ lock->waiters.exchange(1, std::memory_order_acquire); if (rw_lock_s_lock_low(lock, pass, file_name, line)) { sync_array_free_cell(sync_arr, cell); if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_s_os_wait_count.add( count_os_wait); } rw_lock_stats.rw_s_spin_round_count.add(spin_count); return; /* Success */ } /* see comments in trx_commit_low() to before_trx_state_committed_in_memory explaining this care to invoke the following sync check.*/ #ifndef DBUG_OFF #ifdef UNIV_DEBUG if (lock->get_level() != SYNC_DICT_OPERATION) { DEBUG_SYNC_C("rw_s_lock_waiting"); } #endif #endif sync_array_wait_event(sync_arr, cell); i = 0; goto lock_loop; } } /******************************************************************//** This function is used in the insert buffer to move the ownership of an x-latch on a buffer frame to the current thread. The x-latch was set by the buffer read operation and it protected the buffer frame while the read was done. The ownership is moved because we want that the current thread is able to acquire a second x-latch which is stored in an mtr. This, in turn, is needed to pass the debug checks of index page operations. */ void rw_lock_x_lock_move_ownership( /*==========================*/ rw_lock_t* lock) /*!< in: lock which was x-locked in the buffer read */ { ut_ad(rw_lock_is_locked(lock, RW_LOCK_X)); lock->writer_thread = os_thread_get_curr_id(); } /******************************************************************//** Function for the next writer to call. Waits for readers to exit. The caller must have already decremented lock_word by X_LOCK_DECR. */ UNIV_INLINE void rw_lock_x_lock_wait_func( /*=====================*/ rw_lock_t* lock, /*!< in: pointer to rw-lock */ #ifdef UNIV_DEBUG ulint pass, /*!< in: pass value; != 0, if the lock will be passed to another thread to unlock */ #endif lint threshold,/*!< in: threshold to wait for */ const char* file_name,/*!< in: file name where lock requested */ unsigned line) /*!< in: line where requested */ { ulint i = 0; lint n_spins = 0; sync_array_t* sync_arr; int64_t count_os_wait = 0; ut_ad(lock->lock_word <= threshold); HMT_low(); while (lock->lock_word < threshold) { ut_delay(srv_spin_wait_delay); if (i < srv_n_spin_wait_rounds) { i++; continue; } /* If there is still a reader, then go to sleep.*/ n_spins += i; sync_cell_t* cell; sync_arr = sync_array_get_and_reserve_cell( lock, RW_LOCK_X_WAIT, file_name, line, &cell); i = 0; /* Check lock_word to ensure wake-up isn't missed.*/ if (lock->lock_word < threshold) { ++count_os_wait; /* Add debug info as it is needed to detect possible deadlock. We must add info for WAIT_EX thread for deadlock detection to work properly. */ ut_d(rw_lock_add_debug_info( lock, pass, RW_LOCK_X_WAIT, file_name, line)); sync_array_wait_event(sync_arr, cell); ut_d(rw_lock_remove_debug_info( lock, pass, RW_LOCK_X_WAIT)); /* It is possible to wake when lock_word < 0. We must pass the while-loop check to proceed.*/ } else { sync_array_free_cell(sync_arr, cell); break; } } HMT_medium(); rw_lock_stats.rw_x_spin_round_count.add(n_spins); if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_x_os_wait_count.add(count_os_wait); } } #ifdef UNIV_DEBUG # define rw_lock_x_lock_wait(L, P, T, F, O) \ rw_lock_x_lock_wait_func(L, P, T, F, O) #else # define rw_lock_x_lock_wait(L, P, T, F, O) \ rw_lock_x_lock_wait_func(L, T, F, O) #endif /* UNIV_DBEUG */ /******************************************************************//** Low-level function for acquiring an exclusive lock. @return FALSE if did not succeed, TRUE if success. */ UNIV_INLINE ibool rw_lock_x_lock_low( /*===============*/ rw_lock_t* lock, /*!< in: pointer to rw-lock */ ulint pass, /*!< in: pass value; != 0, if the lock will be passed to another thread to unlock */ const char* file_name,/*!< in: file name where lock requested */ unsigned line) /*!< in: line where requested */ { if (rw_lock_lock_word_decr(lock, X_LOCK_DECR, X_LOCK_HALF_DECR)) { /* As we are going to write our own thread id in that field it must be that the current writer_thread value is not active. */ ut_a(!lock->writer_thread); /* Decrement occurred: we are writer or next-writer. */ if (!pass) { lock->writer_thread = os_thread_get_curr_id(); } rw_lock_x_lock_wait(lock, pass, 0, file_name, line); } else { os_thread_id_t thread_id = os_thread_get_curr_id(); /* Decrement failed: An X or SX lock is held by either this thread or another. Try to relock. */ if (!pass && os_thread_eq(lock->writer_thread, thread_id)) { /* Other s-locks can be allowed. If it is request x recursively while holding sx lock, this x lock should be along with the latching-order. */ /* The existing X or SX lock is from this thread */ if (rw_lock_lock_word_decr(lock, X_LOCK_DECR, 0)) { /* There is at least one SX-lock from this thread, but no X-lock. */ /* Wait for any the other S-locks to be released. */ rw_lock_x_lock_wait( lock, pass, -X_LOCK_HALF_DECR, file_name, line); } else { int32_t lock_word = lock->lock_word; /* At least one X lock by this thread already exists. Add another. */ if (lock_word == 0 || lock_word == -X_LOCK_HALF_DECR) { lock->lock_word.fetch_sub(X_LOCK_DECR); } else { ut_ad(lock_word <= -X_LOCK_DECR); lock->lock_word.fetch_sub(1); } } } else { /* Another thread locked before us */ return(FALSE); } } ut_d(rw_lock_add_debug_info(lock, pass, RW_LOCK_X, file_name, line)); lock->last_x_file_name = file_name; lock->last_x_line = line & ((1U << 14) - 1); return(TRUE); } /******************************************************************//** Low-level function for acquiring an sx lock. @return FALSE if did not succeed, TRUE if success. */ ibool rw_lock_sx_lock_low( /*================*/ rw_lock_t* lock, /*!< in: pointer to rw-lock */ ulint pass, /*!< in: pass value; != 0, if the lock will be passed to another thread to unlock */ const char* file_name,/*!< in: file name where lock requested */ unsigned line) /*!< in: line where requested */ { if (rw_lock_lock_word_decr(lock, X_LOCK_HALF_DECR, X_LOCK_HALF_DECR)) { /* As we are going to write our own thread id in that field it must be that the current writer_thread value is not active. */ ut_a(!lock->writer_thread); /* Decrement occurred: we are the SX lock owner. */ if (!pass) { lock->writer_thread = os_thread_get_curr_id(); } lock->sx_recursive = 1; } else { os_thread_id_t thread_id = os_thread_get_curr_id(); /* Decrement failed: It already has an X or SX lock by this thread or another thread. If it is this thread, relock, else fail. */ if (!pass && os_thread_eq(lock->writer_thread, thread_id)) { /* This thread owns an X or SX lock */ if (lock->sx_recursive++ == 0) { /* This thread is making first SX-lock request and it must be holding at least one X-lock here because: * There can't be a WAIT_EX thread because we are the thread which has it's thread_id written in the writer_thread field and we are not waiting. * Any other X-lock thread cannot exist because it must update recursive flag only after updating the thread_id. Had there been a concurrent X-locking thread which succeeded in decrementing the lock_word it must have written it's thread_id before setting the recursive flag. As we cleared the if() condition above therefore we must be the only thread working on this lock and it is safe to read and write to the lock_word. */ #ifdef UNIV_DEBUG auto lock_word = #endif lock->lock_word.fetch_sub(X_LOCK_HALF_DECR, std::memory_order_relaxed); ut_ad((lock_word == 0) || ((lock_word <= -X_LOCK_DECR) && (lock_word > -(X_LOCK_DECR + X_LOCK_HALF_DECR)))); } } else { /* Another thread locked before us */ return(FALSE); } } ut_d(rw_lock_add_debug_info(lock, pass, RW_LOCK_SX, file_name, line)); lock->last_x_file_name = file_name; lock->last_x_line = line & ((1U << 14) - 1); return(TRUE); } /******************************************************************//** NOTE! Use the corresponding macro, not directly this function! Lock an rw-lock in exclusive mode for the current thread. If the rw-lock is locked in shared or exclusive mode, or there is an exclusive lock request waiting, the function spins a preset time (controlled by srv_n_spin_wait_rounds), waiting for the lock before suspending the thread. If the same thread has an x-lock on the rw-lock, locking succeed, with the following exception: if pass != 0, only a single x-lock may be taken on the lock. NOTE: If the same thread has an s-lock, locking does not succeed! */ void rw_lock_x_lock_func( /*================*/ rw_lock_t* lock, /*!< in: pointer to rw-lock */ ulint pass, /*!< in: pass value; != 0, if the lock will be passed to another thread to unlock */ const char* file_name,/*!< in: file name where lock requested */ unsigned line) /*!< in: line where requested */ { ulint i = 0; sync_array_t* sync_arr; lint spin_count = 0; int64_t count_os_wait = 0; ut_ad(rw_lock_validate(lock)); ut_ad(!rw_lock_own(lock, RW_LOCK_S)); if (rw_lock_x_lock_low(lock, pass, file_name, line)) { /* Locking succeeded */ return; } rw_lock_stats.rw_x_spin_wait_count.inc(); lock_loop: if (rw_lock_x_lock_low(lock, pass, file_name, line)) { if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_x_os_wait_count.add(count_os_wait); } rw_lock_stats.rw_x_spin_round_count.add(spin_count); /* Locking succeeded */ return; } else { /* Spin waiting for the lock_word to become free */ HMT_low(); ulint j = i; while (i < srv_n_spin_wait_rounds && lock->lock_word <= X_LOCK_HALF_DECR) { ut_delay(srv_spin_wait_delay); i++; } HMT_medium(); spin_count += lint(i - j); if (i >= srv_n_spin_wait_rounds) { os_thread_yield(); } else { goto lock_loop; } } sync_cell_t* cell; sync_arr = sync_array_get_and_reserve_cell( lock, RW_LOCK_X, file_name, line, &cell); /* Waiters must be set before checking lock_word, to ensure signal is sent. This could lead to a few unnecessary wake-up signals. */ lock->waiters.exchange(1, std::memory_order_acquire); if (rw_lock_x_lock_low(lock, pass, file_name, line)) { sync_array_free_cell(sync_arr, cell); if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_x_os_wait_count.add(count_os_wait); } rw_lock_stats.rw_x_spin_round_count.add(spin_count); /* Locking succeeded */ return; } ++count_os_wait; sync_array_wait_event(sync_arr, cell); i = 0; goto lock_loop; } /******************************************************************//** NOTE! Use the corresponding macro, not directly this function! Lock an rw-lock in SX mode for the current thread. If the rw-lock is locked in exclusive mode, or there is an exclusive lock request waiting, the function spins a preset time (controlled by SYNC_SPIN_ROUNDS), waiting for the lock, before suspending the thread. If the same thread has an x-lock on the rw-lock, locking succeed, with the following exception: if pass != 0, only a single sx-lock may be taken on the lock. NOTE: If the same thread has an s-lock, locking does not succeed! */ void rw_lock_sx_lock_func( /*=================*/ rw_lock_t* lock, /*!< in: pointer to rw-lock */ ulint pass, /*!< in: pass value; != 0, if the lock will be passed to another thread to unlock */ const char* file_name,/*!< in: file name where lock requested */ unsigned line) /*!< in: line where requested */ { ulint i = 0; sync_array_t* sync_arr; lint spin_count = 0; int64_t count_os_wait = 0; ut_ad(rw_lock_validate(lock)); ut_ad(!rw_lock_own(lock, RW_LOCK_S)); if (rw_lock_sx_lock_low(lock, pass, file_name, line)) { /* Locking succeeded */ return; } rw_lock_stats.rw_sx_spin_wait_count.inc(); lock_loop: if (rw_lock_sx_lock_low(lock, pass, file_name, line)) { if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_sx_os_wait_count.add(count_os_wait); } rw_lock_stats.rw_sx_spin_round_count.add(spin_count); /* Locking succeeded */ return; } else { /* Spin waiting for the lock_word to become free */ ulint j = i; while (i < srv_n_spin_wait_rounds && lock->lock_word <= X_LOCK_HALF_DECR) { ut_delay(srv_spin_wait_delay); i++; } spin_count += lint(i - j); if (i >= srv_n_spin_wait_rounds) { os_thread_yield(); } else { goto lock_loop; } } sync_cell_t* cell; sync_arr = sync_array_get_and_reserve_cell( lock, RW_LOCK_SX, file_name, line, &cell); /* Waiters must be set before checking lock_word, to ensure signal is sent. This could lead to a few unnecessary wake-up signals. */ lock->waiters.exchange(1, std::memory_order_acquire); if (rw_lock_sx_lock_low(lock, pass, file_name, line)) { sync_array_free_cell(sync_arr, cell); if (count_os_wait > 0) { lock->count_os_wait += static_cast(count_os_wait); rw_lock_stats.rw_sx_os_wait_count.add(count_os_wait); } rw_lock_stats.rw_sx_spin_round_count.add(spin_count); /* Locking succeeded */ return; } ++count_os_wait; sync_array_wait_event(sync_arr, cell); i = 0; goto lock_loop; } #ifdef UNIV_DEBUG /******************************************************************//** Checks that the rw-lock has been initialized and that there are no simultaneous shared and exclusive locks. @return true */ bool rw_lock_validate( /*=============*/ const rw_lock_t* lock) /*!< in: rw-lock */ { ut_ad(lock); ut_ad(lock->created); int32_t lock_word = lock->lock_word; ut_ad(lock->waiters < 2); ut_ad(lock_word > -(2 * X_LOCK_DECR)); ut_ad(lock_word <= X_LOCK_DECR); return(true); } /******************************************************************//** Checks if somebody has locked the rw-lock in the specified mode. @return true if locked */ bool rw_lock_is_locked( /*==============*/ rw_lock_t* lock, /*!< in: rw-lock */ ulint lock_type) /*!< in: lock type: RW_LOCK_S, RW_LOCK_X or RW_LOCK_SX */ { ut_ad(rw_lock_validate(lock)); switch (lock_type) { case RW_LOCK_S: return(rw_lock_get_reader_count(lock) > 0); case RW_LOCK_X: return(rw_lock_get_writer(lock) == RW_LOCK_X); case RW_LOCK_SX: return(rw_lock_get_sx_lock_count(lock) > 0); default: ut_error; } return(false); /* avoid compiler warnings */ } /******************************************************************//** Inserts the debug information for an rw-lock. */ void rw_lock_add_debug_info( /*===================*/ rw_lock_t* lock, /*!< in: rw-lock */ ulint pass, /*!< in: pass value */ ulint lock_type, /*!< in: lock type */ const char* file_name, /*!< in: file where requested */ unsigned line) /*!< in: line where requested */ { ut_ad(file_name != NULL); rw_lock_debug_t* info = rw_lock_debug_create(); rw_lock_debug_mutex_enter(); info->pass = pass; info->line = line; info->lock_type = lock_type; info->file_name = file_name; info->thread_id = os_thread_get_curr_id(); UT_LIST_ADD_FIRST(lock->debug_list, info); rw_lock_debug_mutex_exit(); if (pass == 0 && lock_type != RW_LOCK_X_WAIT) { int32_t lock_word = lock->lock_word; /* Recursive x while holding SX (lock_type == RW_LOCK_X && lock_word == -X_LOCK_HALF_DECR) is treated as not-relock (new lock). */ if ((lock_type == RW_LOCK_X && lock_word < -X_LOCK_HALF_DECR) || (lock_type == RW_LOCK_SX && (lock_word < 0 || lock->sx_recursive == 1))) { sync_check_lock_validate(lock); sync_check_lock_granted(lock); } else { sync_check_relock(lock); } } } /******************************************************************//** Removes a debug information struct for an rw-lock. */ void rw_lock_remove_debug_info( /*======================*/ rw_lock_t* lock, /*!< in: rw-lock */ ulint pass, /*!< in: pass value */ ulint lock_type) /*!< in: lock type */ { rw_lock_debug_t* info; ut_ad(lock); if (pass == 0 && lock_type != RW_LOCK_X_WAIT) { sync_check_unlock(lock); } rw_lock_debug_mutex_enter(); for (info = UT_LIST_GET_FIRST(lock->debug_list); info != 0; info = UT_LIST_GET_NEXT(list, info)) { if (pass == info->pass && (pass != 0 || os_thread_eq(info->thread_id, os_thread_get_curr_id())) && info->lock_type == lock_type) { /* Found! */ UT_LIST_REMOVE(lock->debug_list, info); rw_lock_debug_mutex_exit(); rw_lock_debug_free(info); return; } } ut_error; } /******************************************************************//** Checks if the thread has locked the rw-lock in the specified mode, with the pass value == 0. @return TRUE if locked */ bool rw_lock_own( /*========*/ const rw_lock_t*lock, /*!< in: rw-lock */ ulint lock_type) /*!< in: lock type: RW_LOCK_S, RW_LOCK_X */ { ut_ad(lock); ut_ad(rw_lock_validate(lock)); const os_thread_id_t thread_id = os_thread_get_curr_id(); if (!os_thread_eq(lock->writer_thread, thread_id)) { } else if (lock_type == RW_LOCK_X && rw_lock_get_x_lock_count(lock)) { return TRUE; } else if (lock_type == RW_LOCK_SX && rw_lock_get_sx_lock_count(lock)) { return TRUE; } rw_lock_debug_mutex_enter(); for (const rw_lock_debug_t* info = UT_LIST_GET_FIRST(lock->debug_list); info != NULL; info = UT_LIST_GET_NEXT(list, info)) { if (os_thread_eq(info->thread_id, thread_id) && info->pass == 0 && info->lock_type == lock_type) { rw_lock_debug_mutex_exit(); /* Found! */ return(true); } } rw_lock_debug_mutex_exit(); return(false); } /** Checks if the thread has locked the rw-lock in the specified mode, with the pass value == 0. @param[in] lock rw-lock @param[in] flags specify lock types with OR of the rw_lock_flag_t values @return true if locked */ bool rw_lock_own_flagged(const rw_lock_t* lock, rw_lock_flags_t flags) { ut_ad(rw_lock_validate(lock)); const os_thread_id_t thread_id = os_thread_get_curr_id(); if (!os_thread_eq(lock->writer_thread, thread_id)) { } else if ((flags & RW_LOCK_FLAG_X) && rw_lock_get_x_lock_count(lock)) { return true; } else if ((flags & RW_LOCK_FLAG_SX) && rw_lock_get_sx_lock_count(lock)) { return true; } rw_lock_debug_mutex_enter(); for (rw_lock_debug_t* info = UT_LIST_GET_FIRST(lock->debug_list); info != NULL; info = UT_LIST_GET_NEXT(list, info)) { if (!os_thread_eq(info->thread_id, thread_id) || info->pass) { continue; } switch (info->lock_type) { case RW_LOCK_S: if (!(flags & RW_LOCK_FLAG_S)) { continue; } break; case RW_LOCK_X: if (!(flags & RW_LOCK_FLAG_X)) { continue; } break; case RW_LOCK_SX: if (!(flags & RW_LOCK_FLAG_SX)) { continue; } break; } rw_lock_debug_mutex_exit(); return true; } rw_lock_debug_mutex_exit(); return false; } /***************************************************************//** Prints debug info of currently locked rw-locks. */ void rw_lock_list_print_info( /*====================*/ FILE* file) /*!< in: file where to print */ { ulint count = 0; mutex_enter(&rw_lock_list_mutex); fputs("-------------\n" "RW-LATCH INFO\n" "-------------\n", file); for (const rw_lock_t& lock : rw_lock_list) { count++; if (lock.lock_word != X_LOCK_DECR) { fprintf(file, "RW-LOCK: %p ", (void*) &lock); if (int32_t waiters= lock.waiters) { fprintf(file, " (%d waiters)\n", waiters); } else { putc('\n', file); } rw_lock_debug_t* info; rw_lock_debug_mutex_enter(); for (info = UT_LIST_GET_FIRST(lock.debug_list); info != NULL; info = UT_LIST_GET_NEXT(list, info)) { rw_lock_debug_print(file, info); } rw_lock_debug_mutex_exit(); } } fprintf(file, "Total number of rw-locks " ULINTPF "\n", count); mutex_exit(&rw_lock_list_mutex); } /*********************************************************************//** Prints info of a debug struct. */ void rw_lock_debug_print( /*================*/ FILE* f, /*!< in: output stream */ const rw_lock_debug_t* info) /*!< in: debug struct */ { ulint rwt = info->lock_type; fprintf(f, "Locked: thread " ULINTPF " file %s line %u ", ulint(info->thread_id), sync_basename(info->file_name), info->line); switch (rwt) { case RW_LOCK_S: fputs("S-LOCK", f); break; case RW_LOCK_X: fputs("X-LOCK", f); break; case RW_LOCK_SX: fputs("SX-LOCK", f); break; case RW_LOCK_X_WAIT: fputs("WAIT X-LOCK", f); break; default: ut_error; } if (info->pass != 0) { fprintf(f, " pass value %lu", (ulong) info->pass); } fprintf(f, "\n"); } /** Print the rw-lock information. @return the string representation */ std::string rw_lock_t::to_string() const { /* Note: For X locks it can be locked form multiple places because the same thread can call X lock recursively. */ std::ostringstream msg; bool written = false; ut_ad(rw_lock_validate(this)); msg << "RW-LATCH: " << "thread id " << os_thread_get_curr_id() << " addr: " << this << " Locked from: "; rw_lock_debug_mutex_enter(); for (rw_lock_debug_t* info = UT_LIST_GET_FIRST(debug_list); info != NULL; info = UT_LIST_GET_NEXT(list, info)) { if (!os_thread_eq(info->thread_id, os_thread_get_curr_id())) { continue; } if (written) { msg << ", "; } written = true; msg << info->file_name << ":" << info->line; } rw_lock_debug_mutex_exit(); return(msg.str()); } #endif /* UNIV_DEBUG */