1 files changed, 384 insertions, 0 deletions
diff --git a/sql/rpl_gtid.h b/sql/rpl_gtid.h
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+++ b/sql/rpl_gtid.h
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+/* Copyright (c) 2013, Kristian Nielsen and MariaDB Services Ab.
+
+   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 St, Fifth Floor, Boston, MA 02110-1335  USA */
+
+#ifndef RPL_GTID_H
+#define RPL_GTID_H
+
+#include "hash.h"
+#include "queues.h"
+#include <atomic>
+
+/* Definitions for MariaDB global transaction ID (GTID). */
+
+
+extern const LEX_CSTRING rpl_gtid_slave_state_table_name;
+
+class String;
+
+#define GTID_MAX_STR_LENGTH (10+1+10+1+20)
+
+struct rpl_gtid
+{
+  uint32 domain_id;
+  uint32 server_id;
+  uint64 seq_no;
+};
+
+inline bool operator==(const rpl_gtid& lhs, const rpl_gtid& rhs)
+{
+  return
+    lhs.domain_id == rhs.domain_id &&
+    lhs.server_id == rhs.server_id &&
+    lhs.seq_no    == rhs.seq_no;
+};
+
+enum enum_gtid_skip_type {
+  GTID_SKIP_NOT, GTID_SKIP_STANDALONE, GTID_SKIP_TRANSACTION
+};
+
+
+/*
+  Structure to keep track of threads waiting in MASTER_GTID_WAIT().
+
+  Since replication is (mostly) single-threaded, we want to minimise the
+  performance impact on that from MASTER_GTID_WAIT(). To achieve this, we
+  are careful to keep the common lock between replication threads and
+  MASTER_GTID_WAIT threads held for as short as possible. We keep only
+  a single thread waiting to be notified by the replication threads; this
+  thread then handles all the (potentially heavy) lifting of dealing with
+  all current waiting threads.
+*/
+struct gtid_waiting {
+  /* Elements in the hash, basically a priority queue for each domain. */
+  struct hash_element {
+    QUEUE queue;
+    uint32 domain_id;
+  };
+  /* A priority queue to handle waiters in one domain in seq_no order. */
+  struct queue_element {
+    uint64 wait_seq_no;
+    THD *thd;
+    int queue_idx;
+    /*
+      do_small_wait is true if we have responsibility for ensuring that there
+      is a small waiter.
+    */
+    bool do_small_wait;
+    /*
+      The flag `done' is set when the wait is completed (either due to reaching
+      the position waited for, or due to timeout or kill). The queue_element
+      is in the queue if and only if `done' is true.
+    */
+    bool done;
+  };
+
+  mysql_mutex_t LOCK_gtid_waiting;
+  HASH hash;
+
+  void init();
+  void destroy();
+  hash_element *get_entry(uint32 domain_id);
+  int wait_for_pos(THD *thd, String *gtid_str, longlong timeout_us);
+  void promote_new_waiter(gtid_waiting::hash_element *he);
+  int wait_for_gtid(THD *thd, rpl_gtid *wait_gtid, struct timespec *wait_until);
+  void process_wait_hash(uint64 wakeup_seq_no, gtid_waiting::hash_element *he);
+  int register_in_wait_queue(THD *thd, rpl_gtid *wait_gtid, hash_element *he,
+                             queue_element *elem);
+  void remove_from_wait_queue(hash_element *he, queue_element *elem);
+};
+
+
+class Relay_log_info;
+struct rpl_group_info;
+class Gtid_list_log_event;
+
+/*
+  Replication slave state.
+
+  For every independent replication stream (identified by domain_id), this
+  remembers the last gtid applied on the slave within this domain.
+
+  Since events are always committed in-order within a single domain, this is
+  sufficient to maintain the state of the replication slave.
+*/
+struct rpl_slave_state
+{
+  /* Elements in the list of GTIDs kept for each domain_id. */
+  struct list_element
+  {
+    struct list_element *next;
+    uint64 sub_id;
+    uint32 domain_id;
+    uint32 server_id;
+    uint64 seq_no;
+    /*
+      hton of mysql.gtid_slave_pos* table used to record this GTID.
+      Can be NULL if the gtid table failed to load (eg. missing
+      mysql.gtid_slave_pos table following an upgrade).
+    */
+    void *hton;
+  };
+
+  /* Elements in the HASH that hold the state for one domain_id. */
+  struct element
+  {
+    struct list_element *list;
+    uint32 domain_id;
+    /* Highest seq_no seen so far in this domain. */
+    uint64 highest_seq_no;
+    /*
+      If this is non-NULL, then it is the waiter responsible for the small
+      wait in MASTER_GTID_WAIT().
+    */
+    gtid_waiting::queue_element *gtid_waiter;
+    /*
+      If gtid_waiter is non-NULL, then this is the seq_no that its
+      MASTER_GTID_WAIT() is waiting on. When we reach this seq_no, we need to
+      signal the waiter on COND_wait_gtid.
+    */
+    uint64 min_wait_seq_no;
+    mysql_cond_t COND_wait_gtid;
+
+    /*
+      For --gtid-ignore-duplicates. The Relay_log_info that currently owns
+      this domain, and the number of worker threads that are active in it.
+
+      The idea is that only one of multiple master connections is allowed to
+      actively apply events for a given domain. Other connections must either
+      discard the events (if the seq_no in GTID shows they have already been
+      applied), or wait to see if the current owner will apply it.
+    */
+    const Relay_log_info *owner_rli;
+    uint32 owner_count;
+    mysql_cond_t COND_gtid_ignore_duplicates;
+
+    list_element *grab_list() { list_element *l= list; list= NULL; return l; }
+    void add(list_element *l)
+    {
+      l->next= list;
+      list= l;
+    }
+  };
+
+  /* Descriptor for mysql.gtid_slave_posXXX table in specific engine. */
+  enum gtid_pos_table_state {
+    GTID_POS_AUTO_CREATE,
+    GTID_POS_CREATE_REQUESTED,
+    GTID_POS_CREATE_IN_PROGRESS,
+    GTID_POS_AVAILABLE
+  };
+  struct gtid_pos_table {
+    struct gtid_pos_table *next;
+    /*
+      Use a void * here, rather than handlerton *, to make explicit that we
+      are not using the value to access any functionality in the engine. It
+      is just used as an opaque value to identify which engine we are using
+      for each GTID row.
+    */
+    void *table_hton;
+    LEX_CSTRING table_name;
+    uint8 state;
+  };
+
+  /* Mapping from domain_id to its element. */
+  HASH hash;
+  /* GTIDs added since last purge of old mysql.gtid_slave_pos rows. */
+  uint32 pending_gtid_count;
+  /* Mutex protecting access to the state. */
+  mysql_mutex_t LOCK_slave_state;
+  /* Auxiliary buffer to sort gtid list. */
+  DYNAMIC_ARRAY gtid_sort_array;
+
+  uint64 last_sub_id;
+  /*
+    List of tables available for durably storing the slave GTID position.
+
+    Accesses to this table is protected by LOCK_slave_state. However for
+    efficiency, there is also a provision for read access to it from a running
+    slave without lock.
+
+    An element can be added at the head of a list by storing the new
+    gtid_pos_tables pointer atomically with release semantics, to ensure that
+    the next pointer of the new element is visible to readers of the new list.
+    Other changes (like deleting or replacing elements) must happen only while
+    all SQL driver threads are stopped. LOCK_slave_state must be held in any
+    case.
+
+    The list can be read without lock by an SQL driver thread or worker thread
+    by reading the gtid_pos_tables pointer atomically with acquire semantics,
+    to ensure that it will see the correct next pointer of a new head element.
+  */
+  std::atomic<gtid_pos_table*> gtid_pos_tables;
+  /* The default entry in gtid_pos_tables, mysql.gtid_slave_pos. */
+  std::atomic<gtid_pos_table*> default_gtid_pos_table;
+  bool loaded;
+
+  rpl_slave_state();
+  ~rpl_slave_state();
+
+  void truncate_hash();
+  ulong count() const { return hash.records; }
+  int update(uint32 domain_id, uint32 server_id, uint64 sub_id,
+             uint64 seq_no, void *hton, rpl_group_info *rgi);
+  int truncate_state_table(THD *thd);
+  void select_gtid_pos_table(THD *thd, LEX_CSTRING *out_tablename);
+  int record_gtid(THD *thd, const rpl_gtid *gtid, uint64 sub_id,
+                  bool in_transaction, bool in_statement, void **out_hton);
+  list_element *gtid_grab_pending_delete_list();
+  LEX_CSTRING *select_gtid_pos_table(void *hton);
+  void gtid_delete_pending(THD *thd, rpl_slave_state::list_element **list_ptr);
+  uint64 next_sub_id(uint32 domain_id);
+  int iterate(int (*cb)(rpl_gtid *, void *), void *data,
+              rpl_gtid *extra_gtids, uint32 num_extra,
+              bool sort);
+  int tostring(String *dest, rpl_gtid *extra_gtids, uint32 num_extra);
+  bool domain_to_gtid(uint32 domain_id, rpl_gtid *out_gtid);
+  int load(THD *thd, const char *state_from_master, size_t len, bool reset,
+           bool in_statement);
+  bool is_empty();
+
+  element *get_element(uint32 domain_id);
+  int put_back_list(list_element *list);
+
+  void update_state_hash(uint64 sub_id, rpl_gtid *gtid, void *hton,
+                         rpl_group_info *rgi);
+  int record_and_update_gtid(THD *thd, struct rpl_group_info *rgi);
+  int check_duplicate_gtid(rpl_gtid *gtid, rpl_group_info *rgi);
+  void release_domain_owner(rpl_group_info *rgi);
+  void set_gtid_pos_tables_list(gtid_pos_table *new_list,
+                                gtid_pos_table *default_entry);
+  void add_gtid_pos_table(gtid_pos_table *entry);
+  struct gtid_pos_table *alloc_gtid_pos_table(LEX_CSTRING *table_name,
+      void *hton, rpl_slave_state::gtid_pos_table_state state);
+  void free_gtid_pos_tables(struct gtid_pos_table *list);
+};
+
+
+/*
+  Binlog state.
+  This keeps the last GTID written to the binlog for every distinct
+  (domain_id, server_id) pair.
+  This will be logged at the start of the next binlog file as a
+  Gtid_list_log_event; this way, it is easy to find the binlog file
+  containing a given GTID, by simply scanning backwards from the newest
+  one until a lower seq_no is found in the Gtid_list_log_event at the
+  start of a binlog for the given domain_id and server_id.
+
+  We also remember the last logged GTID for every domain_id. This is used
+  to know where to start when a master is changed to a slave. As a side
+  effect, it also allows to skip a hash lookup in the very common case of
+  logging a new GTID with same server id as last GTID.
+*/
+struct rpl_binlog_state
+{
+  struct element {
+    uint32 domain_id;
+    HASH hash;                /* Containing all server_id for one domain_id */
+    /* The most recent entry in the hash. */
+    rpl_gtid *last_gtid;
+    /* Counter to allocate next seq_no for this domain. */
+    uint64 seq_no_counter;
+
+    int update_element(const rpl_gtid *gtid);
+  };
+  /* Mapping from domain_id to collection of elements. */
+  HASH hash;
+  /* Mutex protecting access to the state. */
+  mysql_mutex_t LOCK_binlog_state;
+  my_bool initialized;
+
+  /* Auxiliary buffer to sort gtid list. */
+  DYNAMIC_ARRAY gtid_sort_array;
+
+   rpl_binlog_state() :initialized(0) {}
+  ~rpl_binlog_state();
+
+  void init();
+  void reset_nolock();
+  void reset();
+  void free();
+  bool load(struct rpl_gtid *list, uint32 count);
+  bool load(rpl_slave_state *slave_pos);
+  int update_nolock(const struct rpl_gtid *gtid, bool strict);
+  int update(const struct rpl_gtid *gtid, bool strict);
+  int update_with_next_gtid(uint32 domain_id, uint32 server_id,
+                             rpl_gtid *gtid);
+  int alloc_element_nolock(const rpl_gtid *gtid);
+  bool check_strict_sequence(uint32 domain_id, uint32 server_id, uint64 seq_no);
+  int bump_seq_no_if_needed(uint32 domain_id, uint64 seq_no);
+  int write_to_iocache(IO_CACHE *dest);
+  int read_from_iocache(IO_CACHE *src);
+  uint32 count();
+  int get_gtid_list(rpl_gtid *gtid_list, uint32 list_size);
+  int get_most_recent_gtid_list(rpl_gtid **list, uint32 *size);
+  bool append_pos(String *str);
+  bool append_state(String *str);
+  rpl_gtid *find_nolock(uint32 domain_id, uint32 server_id);
+  rpl_gtid *find(uint32 domain_id, uint32 server_id);
+  rpl_gtid *find_most_recent(uint32 domain_id);
+  const char* drop_domain(DYNAMIC_ARRAY *ids, Gtid_list_log_event *glev, char*);
+};
+
+
+/*
+  Represent the GTID state that a slave connection to a master requests
+  the master to start sending binlog events from.
+*/
+struct slave_connection_state
+{
+  struct entry {
+    rpl_gtid gtid;
+    uint32 flags;
+  };
+  /* Bits for 'flags' */
+  enum start_flags
+  {
+    START_OWN_SLAVE_POS= 0x1,
+    START_ON_EMPTY_DOMAIN= 0x2
+  };
+
+  /* Mapping from domain_id to the entry with GTID requested for that domain. */
+  HASH hash;
+
+  /* Auxiliary buffer to sort gtid list. */
+  DYNAMIC_ARRAY gtid_sort_array;
+
+  slave_connection_state();
+  ~slave_connection_state();
+
+  void reset() { my_hash_reset(&hash); }
+  int load(const char *slave_request, size_t len);
+  int load(const rpl_gtid *gtid_list, uint32 count);
+  int load(rpl_slave_state *state, rpl_gtid *extra_gtids, uint32 num_extra);
+  rpl_gtid *find(uint32 domain_id);
+  entry *find_entry(uint32 domain_id);
+  int update(const rpl_gtid *in_gtid);
+  void remove(const rpl_gtid *gtid);
+  void remove_if_present(const rpl_gtid *in_gtid);
+  ulong count() const { return hash.records; }
+  int to_string(String *out_str);
+  int append_to_string(String *out_str);
+  int get_gtid_list(rpl_gtid *gtid_list, uint32 list_size);
+  bool is_pos_reached();
+};
+
+
+extern bool rpl_slave_state_tostring_helper(String *dest, const rpl_gtid *gtid,
+                                            bool *first);
+extern int gtid_check_rpl_slave_state_table(TABLE *table);
+extern rpl_gtid *gtid_parse_string_to_list(const char *p, size_t len,
+                                           uint32 *out_len);
+
+#endif  /* RPL_GTID_H */