/* Copyright (c) 2000, 2019, Oracle and/or its affiliates. Copyright (c) 2009, 2020, MariaDB 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 */ #include "mariadb.h" #include "sql_priv.h" #ifndef MYSQL_CLIENT #include "unireg.h" #include "log_event.h" #include "sql_base.h" // close_thread_tables #include "sql_cache.h" // QUERY_CACHE_FLAGS_SIZE #include "sql_locale.h" // MY_LOCALE, my_locale_by_number, my_locale_en_US #include "key.h" // key_copy #include "lock.h" // mysql_unlock_tables #include "sql_parse.h" // mysql_test_parse_for_slave #include "tztime.h" // struct Time_zone #include "sql_load.h" // mysql_load #include "sql_db.h" // load_db_opt_by_name #include "slave.h" #include "rpl_rli.h" #include "rpl_mi.h" #include "rpl_filter.h" #include "rpl_record.h" #include "transaction.h" #include #include "sql_show.h" // append_identifier #include "debug_sync.h" // debug_sync #include #include #include "compat56.h" #include "wsrep_mysqld.h" #include "sql_insert.h" #else #include "mysqld_error.h" #endif /* MYSQL_CLIENT */ #include #include "rpl_utility.h" #include "rpl_constants.h" #include "sql_digest.h" #include "zlib.h" #define my_b_write_string(A, B) my_b_write((A), (uchar*)(B), (uint) (sizeof(B) - 1)) /** BINLOG_CHECKSUM variable. */ const char *binlog_checksum_type_names[]= { "NONE", "CRC32", NullS }; unsigned int binlog_checksum_type_length[]= { sizeof("NONE") - 1, sizeof("CRC32") - 1, 0 }; TYPELIB binlog_checksum_typelib= { array_elements(binlog_checksum_type_names) - 1, "", binlog_checksum_type_names, binlog_checksum_type_length }; #define log_cs &my_charset_latin1 #define FLAGSTR(V,F) ((V)&(F)?#F" ":"") /* Size of buffer for printing a double in format %.g optional '-' + optional zero + '.' + PREC digits + 'e' + sign + exponent digits + '\0' */ #define FMT_G_BUFSIZE(PREC) (3 + (PREC) + 5 + 1) /* replication event checksum is introduced in the following "checksum-home" version. The checksum-aware servers extract FD's version to decide whether the FD event carries checksum info. TODO: correct the constant when it has been determined (which main tree to push and when) */ const Version checksum_version_split_mysql(5, 6, 1); const Version checksum_version_split_mariadb(5, 3, 0); // First MySQL version with fraction seconds const Version fsp_version_split_mysql(5, 6, 0); #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) static int rows_event_stmt_cleanup(rpl_group_info *rgi, THD* thd); static const char *HA_ERR(int i) { /* This function should only be called in case of an error was detected */ DBUG_ASSERT(i != 0); switch (i) { case HA_ERR_KEY_NOT_FOUND: return "HA_ERR_KEY_NOT_FOUND"; case HA_ERR_FOUND_DUPP_KEY: return "HA_ERR_FOUND_DUPP_KEY"; case HA_ERR_RECORD_CHANGED: return "HA_ERR_RECORD_CHANGED"; case HA_ERR_WRONG_INDEX: return "HA_ERR_WRONG_INDEX"; case HA_ERR_CRASHED: return "HA_ERR_CRASHED"; case HA_ERR_WRONG_IN_RECORD: return "HA_ERR_WRONG_IN_RECORD"; case HA_ERR_OUT_OF_MEM: return "HA_ERR_OUT_OF_MEM"; case HA_ERR_NOT_A_TABLE: return "HA_ERR_NOT_A_TABLE"; case HA_ERR_WRONG_COMMAND: return "HA_ERR_WRONG_COMMAND"; case HA_ERR_OLD_FILE: return "HA_ERR_OLD_FILE"; case HA_ERR_NO_ACTIVE_RECORD: return "HA_ERR_NO_ACTIVE_RECORD"; case HA_ERR_RECORD_DELETED: return "HA_ERR_RECORD_DELETED"; case HA_ERR_RECORD_FILE_FULL: return "HA_ERR_RECORD_FILE_FULL"; case HA_ERR_INDEX_FILE_FULL: return "HA_ERR_INDEX_FILE_FULL"; case HA_ERR_END_OF_FILE: return "HA_ERR_END_OF_FILE"; case HA_ERR_UNSUPPORTED: return "HA_ERR_UNSUPPORTED"; case HA_ERR_TO_BIG_ROW: return "HA_ERR_TO_BIG_ROW"; case HA_WRONG_CREATE_OPTION: return "HA_WRONG_CREATE_OPTION"; case HA_ERR_FOUND_DUPP_UNIQUE: return "HA_ERR_FOUND_DUPP_UNIQUE"; case HA_ERR_UNKNOWN_CHARSET: return "HA_ERR_UNKNOWN_CHARSET"; case HA_ERR_WRONG_MRG_TABLE_DEF: return "HA_ERR_WRONG_MRG_TABLE_DEF"; case HA_ERR_CRASHED_ON_REPAIR: return "HA_ERR_CRASHED_ON_REPAIR"; case HA_ERR_CRASHED_ON_USAGE: return "HA_ERR_CRASHED_ON_USAGE"; case HA_ERR_LOCK_WAIT_TIMEOUT: return "HA_ERR_LOCK_WAIT_TIMEOUT"; case HA_ERR_LOCK_TABLE_FULL: return "HA_ERR_LOCK_TABLE_FULL"; case HA_ERR_READ_ONLY_TRANSACTION: return "HA_ERR_READ_ONLY_TRANSACTION"; case HA_ERR_LOCK_DEADLOCK: return "HA_ERR_LOCK_DEADLOCK"; case HA_ERR_CANNOT_ADD_FOREIGN: return "HA_ERR_CANNOT_ADD_FOREIGN"; case HA_ERR_NO_REFERENCED_ROW: return "HA_ERR_NO_REFERENCED_ROW"; case HA_ERR_ROW_IS_REFERENCED: return "HA_ERR_ROW_IS_REFERENCED"; case HA_ERR_NO_SAVEPOINT: return "HA_ERR_NO_SAVEPOINT"; case HA_ERR_NON_UNIQUE_BLOCK_SIZE: return "HA_ERR_NON_UNIQUE_BLOCK_SIZE"; case HA_ERR_NO_SUCH_TABLE: return "HA_ERR_NO_SUCH_TABLE"; case HA_ERR_TABLE_EXIST: return "HA_ERR_TABLE_EXIST"; case HA_ERR_NO_CONNECTION: return "HA_ERR_NO_CONNECTION"; case HA_ERR_NULL_IN_SPATIAL: return "HA_ERR_NULL_IN_SPATIAL"; case HA_ERR_TABLE_DEF_CHANGED: return "HA_ERR_TABLE_DEF_CHANGED"; case HA_ERR_NO_PARTITION_FOUND: return "HA_ERR_NO_PARTITION_FOUND"; case HA_ERR_RBR_LOGGING_FAILED: return "HA_ERR_RBR_LOGGING_FAILED"; case HA_ERR_DROP_INDEX_FK: return "HA_ERR_DROP_INDEX_FK"; case HA_ERR_FOREIGN_DUPLICATE_KEY: return "HA_ERR_FOREIGN_DUPLICATE_KEY"; case HA_ERR_TABLE_NEEDS_UPGRADE: return "HA_ERR_TABLE_NEEDS_UPGRADE"; case HA_ERR_TABLE_READONLY: return "HA_ERR_TABLE_READONLY"; case HA_ERR_AUTOINC_READ_FAILED: return "HA_ERR_AUTOINC_READ_FAILED"; case HA_ERR_AUTOINC_ERANGE: return "HA_ERR_AUTOINC_ERANGE"; case HA_ERR_GENERIC: return "HA_ERR_GENERIC"; case HA_ERR_RECORD_IS_THE_SAME: return "HA_ERR_RECORD_IS_THE_SAME"; case HA_ERR_LOGGING_IMPOSSIBLE: return "HA_ERR_LOGGING_IMPOSSIBLE"; case HA_ERR_CORRUPT_EVENT: return "HA_ERR_CORRUPT_EVENT"; case HA_ERR_ROWS_EVENT_APPLY : return "HA_ERR_ROWS_EVENT_APPLY"; } return "No Error!"; } /* Return true if an error caught during event execution is a temporary error that will cause automatic retry of the event group during parallel replication, false otherwise. In parallel replication, conflicting transactions can occasionally cause deadlocks; such errors are handled automatically by rolling back re-trying the transactions, so should not pollute the error log. */ static bool is_parallel_retry_error(rpl_group_info *rgi, int err) { if (!rgi->is_parallel_exec) return false; if (rgi->speculation == rpl_group_info::SPECULATE_OPTIMISTIC) return true; if (rgi->killed_for_retry && (err == ER_QUERY_INTERRUPTED || err == ER_CONNECTION_KILLED)) return true; return has_temporary_error(rgi->thd); } /** Error reporting facility for Rows_log_event::do_apply_event @param level error, warning or info @param ha_error HA_ERR_ code @param rli pointer to the active Relay_log_info instance @param thd pointer to the slave thread's thd @param table pointer to the event's table object @param type the type of the event @param log_name the master binlog file name @param pos the master binlog file pos (the next after the event) */ static void inline slave_rows_error_report(enum loglevel level, int ha_error, rpl_group_info *rgi, THD *thd, TABLE *table, const char * type, const char *log_name, my_off_t pos) { const char *handler_error= (ha_error ? HA_ERR(ha_error) : NULL); char buff[MAX_SLAVE_ERRMSG], *slider; const char *buff_end= buff + sizeof(buff); size_t len; Diagnostics_area::Sql_condition_iterator it= thd->get_stmt_da()->sql_conditions(); Relay_log_info const *rli= rgi->rli; const Sql_condition *err; buff[0]= 0; int errcode= thd->is_error() ? thd->get_stmt_da()->sql_errno() : 0; /* In parallel replication, deadlocks or other temporary errors can happen occasionally in normal operation, they will be handled correctly and automatically by re-trying the transactions. So do not pollute the error log with messages about them. */ if (is_parallel_retry_error(rgi, errcode)) return; for (err= it++, slider= buff; err && slider < buff_end - 1; slider += len, err= it++) { len= my_snprintf(slider, buff_end - slider, " %s, Error_code: %d;", err->get_message_text(), err->get_sql_errno()); } if (ha_error != 0) rli->report(level, errcode, rgi->gtid_info(), "Could not execute %s event on table %s.%s;" "%s handler error %s; " "the event's master log %s, end_log_pos %llu", type, table->s->db.str, table->s->table_name.str, buff, handler_error == NULL ? "" : handler_error, log_name, pos); else rli->report(level, errcode, rgi->gtid_info(), "Could not execute %s event on table %s.%s;" "%s the event's master log %s, end_log_pos %llu", type, table->s->db.str, table->s->table_name.str, buff, log_name, pos); } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) static void set_thd_db(THD *thd, Rpl_filter *rpl_filter, const char *db, uint32 db_len) { char lcase_db_buf[NAME_LEN +1]; LEX_CSTRING new_db; new_db.length= db_len; if (lower_case_table_names == 1) { strmov(lcase_db_buf, db); my_casedn_str(system_charset_info, lcase_db_buf); new_db.str= lcase_db_buf; } else new_db.str= db; /* TODO WARNING this makes rewrite_db respect lower_case_table_names values * for more info look MDEV-17446 */ new_db.str= rpl_filter->get_rewrite_db(new_db.str, &new_db.length); thd->set_db(&new_db); } #endif /* Cache that will automatically be written to a dedicated file on destruction. DESCRIPTION */ class Write_on_release_cache { public: enum flag { FLUSH_F= 1 }; typedef unsigned short flag_set; /* Constructor. SYNOPSIS Write_on_release_cache cache Pointer to cache to use file File to write cache to upon destruction flags Flags for the cache DESCRIPTION Cache common parameters and ensure common flush_data() code on successful copy of the cache, the cache will be reinited as a WRITE_CACHE. Currently, a pointer to the cache is provided in the constructor, but it would be possible to create a subclass holding the IO_CACHE itself. */ Write_on_release_cache(IO_CACHE *cache, FILE *file, flag_set flags = 0, Log_event *ev = NULL) : m_cache(cache), m_file(file), m_flags(flags), m_ev(ev) { reinit_io_cache(m_cache, WRITE_CACHE, 0L, FALSE, TRUE); } ~Write_on_release_cache() {} bool flush_data() { #ifdef MYSQL_CLIENT if (m_ev == NULL) { if (copy_event_cache_to_file_and_reinit(m_cache, m_file)) return 1; if ((m_flags & FLUSH_F) && fflush(m_file)) return 1; } else // if m_ev<>NULL, then storing the output in output_buf { LEX_STRING tmp_str; bool res; if (copy_event_cache_to_string_and_reinit(m_cache, &tmp_str)) return 1; /* use 2 argument append as tmp_str is not \0 terminated */ res= m_ev->output_buf.append(tmp_str.str, tmp_str.length); my_free(tmp_str.str); return res ? res : 0; } #else /* MySQL_SERVER */ if (copy_event_cache_to_file_and_reinit(m_cache, m_file)) return 1; if ((m_flags & FLUSH_F) && fflush(m_file)) return 1; #endif return 0; } /* Return a pointer to the internal IO_CACHE. SYNOPSIS operator&() DESCRIPTION Function to return a pointer to the internal cache, so that the object can be treated as a IO_CACHE and used with the my_b_* IO_CACHE functions RETURN VALUE A pointer to the internal IO_CACHE. */ IO_CACHE *operator&() { return m_cache; } private: // Hidden, to prevent usage. Write_on_release_cache(Write_on_release_cache const&); IO_CACHE *m_cache; FILE *m_file; flag_set m_flags; Log_event *m_ev; // Used for Flashback }; /* pretty_print_str() */ #ifdef MYSQL_CLIENT static bool pretty_print_str(IO_CACHE* cache, const char* str, int len) { const char* end = str + len; if (my_b_write_byte(cache, '\'')) goto err; while (str < end) { char c; int error; switch ((c=*str++)) { case '\n': error= my_b_write(cache, (uchar*)"\\n", 2); break; case '\r': error= my_b_write(cache, (uchar*)"\\r", 2); break; case '\\': error= my_b_write(cache, (uchar*)"\\\\", 2); break; case '\b': error= my_b_write(cache, (uchar*)"\\b", 2); break; case '\t': error= my_b_write(cache, (uchar*)"\\t", 2); break; case '\'': error= my_b_write(cache, (uchar*)"\\'", 2); break; case 0 : error= my_b_write(cache, (uchar*)"\\0", 2); break; default: error= my_b_write_byte(cache, c); break; } if (unlikely(error)) goto err; } return my_b_write_byte(cache, '\''); err: return 1; } #endif /* MYSQL_CLIENT */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) inline int idempotent_error_code(int err_code) { int ret= 0; switch (err_code) { case 0: ret= 1; break; /* The following list of "idempotent" errors means that an error from the list might happen because of idempotent (more than once) applying of a binlog file. Notice, that binlog has a ddl operation its second applying may cause case HA_ERR_TABLE_DEF_CHANGED: case HA_ERR_CANNOT_ADD_FOREIGN: which are not included into to the list. Note that HA_ERR_RECORD_DELETED is not in the list since do_exec_row() should not return that error code. */ case HA_ERR_RECORD_CHANGED: case HA_ERR_KEY_NOT_FOUND: case HA_ERR_END_OF_FILE: case HA_ERR_FOUND_DUPP_KEY: case HA_ERR_FOUND_DUPP_UNIQUE: case HA_ERR_FOREIGN_DUPLICATE_KEY: case HA_ERR_NO_REFERENCED_ROW: case HA_ERR_ROW_IS_REFERENCED: ret= 1; break; default: ret= 0; break; } return (ret); } /** Ignore error code specified on command line. */ inline int ignored_error_code(int err_code) { if (use_slave_mask && bitmap_is_set(&slave_error_mask, err_code)) { statistic_increment(slave_skipped_errors, LOCK_status); return 1; } return err_code == ER_SLAVE_IGNORED_TABLE; } /* This function converts an engine's error to a server error. If the thread does not have an error already reported, it tries to define it by calling the engine's method print_error. However, if a mapping is not found, it uses the ER_UNKNOWN_ERROR and prints out a warning message. */ int convert_handler_error(int error, THD* thd, TABLE *table) { uint actual_error= (thd->is_error() ? thd->get_stmt_da()->sql_errno() : 0); if (actual_error == 0) { table->file->print_error(error, MYF(0)); actual_error= (thd->is_error() ? thd->get_stmt_da()->sql_errno() : ER_UNKNOWN_ERROR); if (actual_error == ER_UNKNOWN_ERROR) if (global_system_variables.log_warnings) sql_print_warning("Unknown error detected %d in handler", error); } return (actual_error); } inline bool concurrency_error_code(int error) { switch (error) { case ER_LOCK_WAIT_TIMEOUT: case ER_LOCK_DEADLOCK: case ER_XA_RBDEADLOCK: return TRUE; default: return (FALSE); } } inline bool unexpected_error_code(int unexpected_error) { switch (unexpected_error) { case ER_NET_READ_ERROR: case ER_NET_ERROR_ON_WRITE: case ER_QUERY_INTERRUPTED: case ER_STATEMENT_TIMEOUT: case ER_CONNECTION_KILLED: case ER_SERVER_SHUTDOWN: case ER_NEW_ABORTING_CONNECTION: return(TRUE); default: return(FALSE); } } /* pretty_print_str() */ static void pretty_print_str(String *packet, const char *str, int len) { const char *end= str + len; packet->append(STRING_WITH_LEN("'")); while (str < end) { char c; switch ((c=*str++)) { case '\n': packet->append(STRING_WITH_LEN("\\n")); break; case '\r': packet->append(STRING_WITH_LEN("\\r")); break; case '\\': packet->append(STRING_WITH_LEN("\\\\")); break; case '\b': packet->append(STRING_WITH_LEN("\\b")); break; case '\t': packet->append(STRING_WITH_LEN("\\t")); break; case '\'': packet->append(STRING_WITH_LEN("\\'")); break; case 0 : packet->append(STRING_WITH_LEN("\\0")); break; default: packet->append(&c, 1); break; } } packet->append(STRING_WITH_LEN("'")); } #endif /* !MYSQL_CLIENT */ #ifndef DBUG_OFF #define DBUG_DUMP_EVENT_BUF(B,L) \ do { \ const uchar *_buf=(uchar*)(B); \ size_t _len=(L); \ if (_len >= LOG_EVENT_MINIMAL_HEADER_LEN) \ { \ DBUG_PRINT("data", ("header: timestamp:%u type:%u server_id:%u len:%u log_pos:%u flags:%u", \ uint4korr(_buf), _buf[EVENT_TYPE_OFFSET], \ uint4korr(_buf+SERVER_ID_OFFSET), \ uint4korr(_buf+EVENT_LEN_OFFSET), \ uint4korr(_buf+LOG_POS_OFFSET), \ uint4korr(_buf+FLAGS_OFFSET))); \ DBUG_DUMP("data", _buf+LOG_EVENT_MINIMAL_HEADER_LEN, \ _len-LOG_EVENT_MINIMAL_HEADER_LEN); \ } \ else \ DBUG_DUMP("data", _buf, _len); \ } while(0) #else #define DBUG_DUMP_EVENT_BUF(B,L) do { } while(0) #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /** Create a prefix for the temporary files that is to be used for load data file name for this master @param name Store prefix of name here @param connection_name Connection name @return pointer to end of name @description We assume that FN_REFLEN is big enough to hold MAX_CONNECTION_NAME * MAX_FILENAME_MBWIDTH characters + 2 numbers + a short extension. The resulting file name has the following parts, each separated with a '-' - PREFIX_SQL_LOAD (SQL_LOAD-) - If a connection name is given (multi-master setup): - Add an extra '-' to mark that this is a multi-master file - connection name in lower case, converted to safe file characters. (see create_logfile_name_with_suffix()). - server_id - A last '-' (after server_id). */ static char *load_data_tmp_prefix(char *name, LEX_CSTRING *connection_name) { name= strmov(name, PREFIX_SQL_LOAD); if (connection_name->length) { uint buf_length; uint errors; /* Add marker that this is a multi-master-file */ *name++='-'; /* Convert connection_name to a safe filename */ buf_length= strconvert(system_charset_info, connection_name->str, FN_REFLEN, &my_charset_filename, name, FN_REFLEN, &errors); name+= buf_length; *name++= '-'; } name= int10_to_str(global_system_variables.server_id, name, 10); *name++ = '-'; *name= '\0'; // For testing prefixes return name; } /** Creates a temporary name for LOAD DATA INFILE @param buf Store new filename here @param file_id File_id (part of file name) @param event_server_id Event_id (part of file name) @param ext Extension for file name @return Pointer to start of extension */ static char *slave_load_file_stem(char *buf, uint file_id, int event_server_id, const char *ext, LEX_CSTRING *connection_name) { char *res; res= buf+ unpack_dirname(buf, slave_load_tmpdir); to_unix_path(buf); buf= load_data_tmp_prefix(res, connection_name); buf= int10_to_str(event_server_id, buf, 10); *buf++ = '-'; res= int10_to_str(file_id, buf, 10); strmov(res, ext); // Add extension last return res; // Pointer to extension } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /** Delete all temporary files used for SQL_LOAD. */ static void cleanup_load_tmpdir(LEX_CSTRING *connection_name) { MY_DIR *dirp; FILEINFO *file; uint i; char dir[FN_REFLEN], fname[FN_REFLEN]; char prefbuf[31 + MAX_CONNECTION_NAME* MAX_FILENAME_MBWIDTH + 1]; DBUG_ENTER("cleanup_load_tmpdir"); unpack_dirname(dir, slave_load_tmpdir); if (!(dirp=my_dir(dir, MYF(MY_WME)))) return; /* When we are deleting temporary files, we should only remove the files associated with the server id of our server. We don't use event_server_id here because since we've disabled direct binlogging of Create_file/Append_file/Exec_load events we cannot meet Start_log event in the middle of events from one LOAD DATA. */ load_data_tmp_prefix(prefbuf, connection_name); DBUG_PRINT("enter", ("dir: '%s' prefix: '%s'", dir, prefbuf)); for (i=0 ; i < (uint)dirp->number_of_files; i++) { file=dirp->dir_entry+i; if (is_prefix(file->name, prefbuf)) { fn_format(fname,file->name,slave_load_tmpdir,"",MY_UNPACK_FILENAME); mysql_file_delete(key_file_misc, fname, MYF(0)); } } my_dirend(dirp); DBUG_VOID_RETURN; } #endif /* read_str() */ static inline int read_str(const char **buf, const char *buf_end, const char **str, uint8 *len) { if (*buf + ((uint) (uchar) **buf) >= buf_end) return 1; *len= (uint8) **buf; *str= (*buf)+1; (*buf)+= (uint) *len+1; return 0; } /** Transforms a string into "" or its expression in X'HHHH' form. */ char *str_to_hex(char *to, const char *from, size_t len) { if (len) { *to++= 'X'; *to++= '\''; to= octet2hex(to, from, len); *to++= '\''; *to= '\0'; } else to= strmov(to, "\"\""); return to; // pointer to end 0 of 'to' } #define BINLOG_COMPRESSED_HEADER_LEN 1 #define BINLOG_COMPRESSED_ORIGINAL_LENGTH_MAX_BYTES 4 /** Compressed Record Record Header: 1 Byte 7 Bit: Always 1, mean compressed; 4-6 Bit: Compressed algorithm - Always 0, means zlib It maybe support other compression algorithm in the future. 0-3 Bit: Bytes of "Record Original Length" Record Original Length: 1-4 Bytes Compressed Buf: */ /** Get the length of compress content. */ uint32 binlog_get_compress_len(uint32 len) { /* 5 for the begin content, 1 reserved for a '\0'*/ return ALIGN_SIZE((BINLOG_COMPRESSED_HEADER_LEN + BINLOG_COMPRESSED_ORIGINAL_LENGTH_MAX_BYTES) + compressBound(len) + 1); } /** Compress buf from 'src' to 'dst'. Note: 1) Then the caller should guarantee the length of 'dst', which can be got by binlog_get_uncompress_len, is enough to hold the content uncompressed. 2) The 'comlen' should stored the length of 'dst', and it will be set as the size of compressed content after return. return zero if successful, others otherwise. */ int binlog_buf_compress(const char *src, char *dst, uint32 len, uint32 *comlen) { uchar lenlen; if (len & 0xFF000000) { dst[1] = uchar(len >> 24); dst[2] = uchar(len >> 16); dst[3] = uchar(len >> 8); dst[4] = uchar(len); lenlen = 4; } else if (len & 0x00FF0000) { dst[1] = uchar(len >> 16); dst[2] = uchar(len >> 8); dst[3] = uchar(len); lenlen = 3; } else if (len & 0x0000FF00) { dst[1] = uchar(len >> 8); dst[2] = uchar(len); lenlen = 2; } else { dst[1] = uchar(len); lenlen = 1; } dst[0] = 0x80 | (lenlen & 0x07); uLongf tmplen = (uLongf)*comlen - BINLOG_COMPRESSED_HEADER_LEN - lenlen - 1; if (compress((Bytef *)dst + BINLOG_COMPRESSED_HEADER_LEN + lenlen, &tmplen, (const Bytef *)src, (uLongf)len) != Z_OK) { return 1; } *comlen = (uint32)tmplen + BINLOG_COMPRESSED_HEADER_LEN + lenlen; return 0; } /** Convert a query_compressed_log_event to query_log_event from 'src' to 'dst', the size after compression stored in 'newlen'. @Note: 1) The caller should call my_free to release 'dst' if *is_malloc is returned as true. 2) If *is_malloc is retuened as false, then 'dst' reuses the passed-in 'buf'. return zero if successful, non-zero otherwise. */ int query_event_uncompress(const Format_description_log_event *description_event, bool contain_checksum, const char *src, ulong src_len, char* buf, ulong buf_size, bool* is_malloc, char **dst, ulong *newlen) { ulong len = uint4korr(src + EVENT_LEN_OFFSET); const char *tmp = src; const char *end = src + len; // bad event if (src_len < len ) return 1; DBUG_ASSERT((uchar)src[EVENT_TYPE_OFFSET] == QUERY_COMPRESSED_EVENT); uint8 common_header_len= description_event->common_header_len; uint8 post_header_len= description_event->post_header_len[QUERY_COMPRESSED_EVENT-1]; *is_malloc = false; tmp += common_header_len; // bad event if (end <= tmp) return 1; uint db_len = (uint)tmp[Q_DB_LEN_OFFSET]; uint16 status_vars_len= uint2korr(tmp + Q_STATUS_VARS_LEN_OFFSET); tmp += post_header_len + status_vars_len + db_len + 1; // bad event if (end <= tmp) return 1; int32 comp_len = (int32)(len - (tmp - src) - (contain_checksum ? BINLOG_CHECKSUM_LEN : 0)); uint32 un_len = binlog_get_uncompress_len(tmp); // bad event if (comp_len < 0 || un_len == 0) return 1; *newlen = (ulong)(tmp - src) + un_len; if(contain_checksum) *newlen += BINLOG_CHECKSUM_LEN; uint32 alloc_size = (uint32)ALIGN_SIZE(*newlen); char *new_dst = NULL; if (alloc_size <= buf_size) { new_dst = buf; } else { new_dst = (char *)my_malloc(alloc_size, MYF(MY_WME)); if (!new_dst) return 1; *is_malloc = true; } /* copy the head*/ memcpy(new_dst, src , tmp - src); if (binlog_buf_uncompress(tmp, new_dst + (tmp - src), comp_len, &un_len)) { if (*is_malloc) my_free(new_dst); *is_malloc = false; return 1; } new_dst[EVENT_TYPE_OFFSET] = QUERY_EVENT; int4store(new_dst + EVENT_LEN_OFFSET, *newlen); if(contain_checksum) { ulong clear_len = *newlen - BINLOG_CHECKSUM_LEN; int4store(new_dst + clear_len, my_checksum(0L, (uchar *)new_dst, clear_len)); } *dst = new_dst; return 0; } int row_log_event_uncompress(const Format_description_log_event *description_event, bool contain_checksum, const char *src, ulong src_len, char* buf, ulong buf_size, bool* is_malloc, char **dst, ulong *newlen) { Log_event_type type = (Log_event_type)(uchar)src[EVENT_TYPE_OFFSET]; ulong len = uint4korr(src + EVENT_LEN_OFFSET); const char *tmp = src; char *new_dst = NULL; const char *end = tmp + len; // bad event if (src_len < len) return 1; DBUG_ASSERT(LOG_EVENT_IS_ROW_COMPRESSED(type)); uint8 common_header_len= description_event->common_header_len; uint8 post_header_len= description_event->post_header_len[type-1]; tmp += common_header_len + ROWS_HEADER_LEN_V1; if (post_header_len == ROWS_HEADER_LEN_V2) { /* Have variable length header, check length, which includes length bytes */ // bad event if (end - tmp <= 2) return 1; uint16 var_header_len= uint2korr(tmp); DBUG_ASSERT(var_header_len >= 2); /* skip over var-len header, extracting 'chunks' */ tmp += var_header_len; /* get the uncompressed event type */ type= (Log_event_type)(type - WRITE_ROWS_COMPRESSED_EVENT + WRITE_ROWS_EVENT); } else { /* get the uncompressed event type */ type= (Log_event_type) (type - WRITE_ROWS_COMPRESSED_EVENT_V1 + WRITE_ROWS_EVENT_V1); } //bad event if (end <= tmp) return 1; ulong m_width = net_field_length((uchar **)&tmp); tmp += (m_width + 7) / 8; if (type == UPDATE_ROWS_EVENT_V1 || type == UPDATE_ROWS_EVENT) { tmp += (m_width + 7) / 8; } //bad event if (end <= tmp) return 1; uint32 un_len = binlog_get_uncompress_len(tmp); //bad event if (un_len == 0) return 1; int32 comp_len = (int32)(len - (tmp - src) - (contain_checksum ? BINLOG_CHECKSUM_LEN : 0)); //bad event if (comp_len <=0) return 1; *newlen = ulong(tmp - src) + un_len; if(contain_checksum) *newlen += BINLOG_CHECKSUM_LEN; size_t alloc_size = ALIGN_SIZE(*newlen); *is_malloc = false; if (alloc_size <= buf_size) { new_dst = buf; } else { new_dst = (char *)my_malloc(alloc_size, MYF(MY_WME)); if (!new_dst) return 1; *is_malloc = true; } /* Copy the head. */ memcpy(new_dst, src , tmp - src); /* Uncompress the body. */ if (binlog_buf_uncompress(tmp, new_dst + (tmp - src), comp_len, &un_len)) { if (*is_malloc) my_free(new_dst); return 1; } new_dst[EVENT_TYPE_OFFSET] = type; int4store(new_dst + EVENT_LEN_OFFSET, *newlen); if(contain_checksum){ ulong clear_len = *newlen - BINLOG_CHECKSUM_LEN; int4store(new_dst + clear_len, my_checksum(0L, (uchar *)new_dst, clear_len)); } *dst = new_dst; return 0; } /** Get the length of uncompress content. return 0 means error. */ uint32 binlog_get_uncompress_len(const char *buf) { uint32 len = 0; uint32 lenlen = 0; if ((buf == NULL) || ((buf[0] & 0xe0) != 0x80)) return len; lenlen = buf[0] & 0x07; switch(lenlen) { case 1: len = uchar(buf[1]); break; case 2: len = uchar(buf[1]) << 8 | uchar(buf[2]); break; case 3: len = uchar(buf[1]) << 16 | uchar(buf[2]) << 8 | uchar(buf[3]); break; case 4: len = uchar(buf[1]) << 24 | uchar(buf[2]) << 16 | uchar(buf[3]) << 8 | uchar(buf[4]); break; default: DBUG_ASSERT(lenlen >= 1 && lenlen <= 4); break; } return len; } /** Uncompress the content in 'src' with length of 'len' to 'dst'. Note: 1) Then the caller should guarantee the length of 'dst' (which can be got by statement_get_uncompress_len) is enough to hold the content uncompressed. 2) The 'newlen' should stored the length of 'dst', and it will be set as the size of uncompressed content after return. return zero if successful, others otherwise. */ int binlog_buf_uncompress(const char *src, char *dst, uint32 len, uint32 *newlen) { if((src[0] & 0x80) == 0) { return 1; } uint32 lenlen= src[0] & 0x07; uLongf buflen= *newlen; uint32 alg = (src[0] & 0x70) >> 4; switch(alg) { case 0: // zlib if(uncompress((Bytef *)dst, &buflen, (const Bytef*)src + 1 + lenlen, len - 1 - lenlen) != Z_OK) { return 1; } break; default: //TODO //bad algorithm return 1; } DBUG_ASSERT(*newlen == (uint32)buflen); *newlen = (uint32)buflen; return 0; } #ifndef MYSQL_CLIENT /** Append a version of the 'str' string suitable for use in a query to the 'to' string. To generate a correct escaping, the character set information in 'csinfo' is used. */ int append_query_string(CHARSET_INFO *csinfo, String *to, const char *str, size_t len, bool no_backslash) { char *beg, *ptr; uint32 const orig_len= to->length(); if (to->reserve(orig_len + len * 2 + 4)) return 1; beg= (char*) to->ptr() + to->length(); ptr= beg; if (csinfo->escape_with_backslash_is_dangerous) ptr= str_to_hex(ptr, str, len); else { *ptr++= '\''; if (!no_backslash) { ptr+= escape_string_for_mysql(csinfo, ptr, 0, str, len); } else { const char *frm_str= str; for (; frm_str < (str + len); frm_str++) { /* Using '' way to represent "'" */ if (*frm_str == '\'') *ptr++= *frm_str; *ptr++= *frm_str; } } *ptr++= '\''; } to->length((uint32)(orig_len + ptr - beg)); return 0; } #endif /** Prints a "session_var=value" string. Used by mysqlbinlog to print some SET commands just before it prints a query. */ #ifdef MYSQL_CLIENT static bool print_set_option(IO_CACHE* file, uint32 bits_changed, uint32 option, uint32 flags, const char* name, bool* need_comma) { if (bits_changed & option) { if (*need_comma) if (my_b_write(file, (uchar*)", ", 2)) goto err; if (my_b_printf(file, "%s=%d", name, MY_TEST(flags & option))) goto err; *need_comma= 1; } return 0; err: return 1; } #endif /************************************************************************** Log_event methods (= the parent class of all events) **************************************************************************/ /** @return returns the human readable name of the event's type */ const char* Log_event::get_type_str(Log_event_type type) { switch(type) { case START_EVENT_V3: return "Start_v3"; case STOP_EVENT: return "Stop"; case QUERY_EVENT: return "Query"; case ROTATE_EVENT: return "Rotate"; case INTVAR_EVENT: return "Intvar"; case LOAD_EVENT: return "Load"; case NEW_LOAD_EVENT: return "New_load"; case SLAVE_EVENT: return "Slave"; case CREATE_FILE_EVENT: return "Create_file"; case APPEND_BLOCK_EVENT: return "Append_block"; case DELETE_FILE_EVENT: return "Delete_file"; case EXEC_LOAD_EVENT: return "Exec_load"; case RAND_EVENT: return "RAND"; case XID_EVENT: return "Xid"; case USER_VAR_EVENT: return "User var"; case FORMAT_DESCRIPTION_EVENT: return "Format_desc"; case TABLE_MAP_EVENT: return "Table_map"; case PRE_GA_WRITE_ROWS_EVENT: return "Write_rows_event_old"; case PRE_GA_UPDATE_ROWS_EVENT: return "Update_rows_event_old"; case PRE_GA_DELETE_ROWS_EVENT: return "Delete_rows_event_old"; case WRITE_ROWS_EVENT_V1: return "Write_rows_v1"; case UPDATE_ROWS_EVENT_V1: return "Update_rows_v1"; case DELETE_ROWS_EVENT_V1: return "Delete_rows_v1"; case WRITE_ROWS_EVENT: return "Write_rows"; case UPDATE_ROWS_EVENT: return "Update_rows"; case DELETE_ROWS_EVENT: return "Delete_rows"; case BEGIN_LOAD_QUERY_EVENT: return "Begin_load_query"; case EXECUTE_LOAD_QUERY_EVENT: return "Execute_load_query"; case INCIDENT_EVENT: return "Incident"; case ANNOTATE_ROWS_EVENT: return "Annotate_rows"; case BINLOG_CHECKPOINT_EVENT: return "Binlog_checkpoint"; case GTID_EVENT: return "Gtid"; case GTID_LIST_EVENT: return "Gtid_list"; case START_ENCRYPTION_EVENT: return "Start_encryption"; /* The following is only for mysqlbinlog */ case IGNORABLE_LOG_EVENT: return "Ignorable log event"; case ROWS_QUERY_LOG_EVENT: return "MySQL Rows_query"; case GTID_LOG_EVENT: return "MySQL Gtid"; case ANONYMOUS_GTID_LOG_EVENT: return "MySQL Anonymous_Gtid"; case PREVIOUS_GTIDS_LOG_EVENT: return "MySQL Previous_gtids"; case HEARTBEAT_LOG_EVENT: return "Heartbeat"; case TRANSACTION_CONTEXT_EVENT: return "Transaction_context"; case VIEW_CHANGE_EVENT: return "View_change"; case XA_PREPARE_LOG_EVENT: return "XA_prepare"; case QUERY_COMPRESSED_EVENT: return "Query_compressed"; case WRITE_ROWS_COMPRESSED_EVENT: return "Write_rows_compressed"; case UPDATE_ROWS_COMPRESSED_EVENT: return "Update_rows_compressed"; case DELETE_ROWS_COMPRESSED_EVENT: return "Delete_rows_compressed"; case WRITE_ROWS_COMPRESSED_EVENT_V1: return "Write_rows_compressed_v1"; case UPDATE_ROWS_COMPRESSED_EVENT_V1: return "Update_rows_compressed_v1"; case DELETE_ROWS_COMPRESSED_EVENT_V1: return "Delete_rows_compressed_v1"; default: return "Unknown"; /* impossible */ } } const char* Log_event::get_type_str() { return get_type_str(get_type_code()); } /* Log_event::Log_event() */ #ifndef MYSQL_CLIENT Log_event::Log_event(THD* thd_arg, uint16 flags_arg, bool using_trans) :log_pos(0), temp_buf(0), exec_time(0), thd(thd_arg), checksum_alg(BINLOG_CHECKSUM_ALG_UNDEF) { server_id= thd->variables.server_id; when= thd->start_time; when_sec_part=thd->start_time_sec_part; if (using_trans) cache_type= Log_event::EVENT_TRANSACTIONAL_CACHE; else cache_type= Log_event::EVENT_STMT_CACHE; flags= flags_arg | (thd->variables.option_bits & OPTION_SKIP_REPLICATION ? LOG_EVENT_SKIP_REPLICATION_F : 0); } /** This minimal constructor is for when you are not even sure that there is a valid THD. For example in the server when we are shutting down or flushing logs after receiving a SIGHUP (then we must write a Rotate to the binlog but we have no THD, so we need this minimal constructor). */ Log_event::Log_event() :temp_buf(0), exec_time(0), flags(0), cache_type(EVENT_INVALID_CACHE), thd(0), checksum_alg(BINLOG_CHECKSUM_ALG_UNDEF) { server_id= global_system_variables.server_id; /* We can't call my_time() here as this would cause a call before my_init() is called */ when= 0; when_sec_part=0; log_pos= 0; } #endif /* !MYSQL_CLIENT */ /* Log_event::Log_event() */ Log_event::Log_event(const char* buf, const Format_description_log_event* description_event) :temp_buf(0), exec_time(0), cache_type(Log_event::EVENT_INVALID_CACHE), checksum_alg(BINLOG_CHECKSUM_ALG_UNDEF) { #ifndef MYSQL_CLIENT thd = 0; #endif when = uint4korr(buf); when_sec_part= ~0UL; server_id = uint4korr(buf + SERVER_ID_OFFSET); data_written= uint4korr(buf + EVENT_LEN_OFFSET); if (description_event->binlog_version==1) { log_pos= 0; flags= 0; return; } /* 4.0 or newer */ log_pos= uint4korr(buf + LOG_POS_OFFSET); /* If the log is 4.0 (so here it can only be a 4.0 relay log read by the SQL thread or a 4.0 master binlog read by the I/O thread), log_pos is the beginning of the event: we transform it into the end of the event, which is more useful. But how do you know that the log is 4.0: you know it if description_event is version 3 *and* you are not reading a Format_desc (remember that mysqlbinlog starts by assuming that 5.0 logs are in 4.0 format, until it finds a Format_desc). */ if (description_event->binlog_version==3 && (uchar)buf[EVENT_TYPE_OFFSET]group_master_log_pos" (see inc_group_relay_log_pos()). As it is unreal log_pos, adding the event len's is nonsense. For example, a fake Rotate event should not have its log_pos (which is 0) changed or it will modify Exec_master_log_pos in SHOW SLAVE STATUS, displaying a nonsense value of (a non-zero offset which does not exist in the master's binlog, so which will cause problems if the user uses this value in CHANGE MASTER). */ log_pos+= data_written; /* purecov: inspected */ } DBUG_PRINT("info", ("log_pos: %llu", log_pos)); flags= uint2korr(buf + FLAGS_OFFSET); if (((uchar)buf[EVENT_TYPE_OFFSET] == FORMAT_DESCRIPTION_EVENT) || ((uchar)buf[EVENT_TYPE_OFFSET] == ROTATE_EVENT)) { /* These events always have a header which stops here (i.e. their header is FROZEN). */ /* Initialization to zero of all other Log_event members as they're not specified. Currently there are no such members; in the future there will be an event UID (but Format_description and Rotate don't need this UID, as they are not propagated through --log-slave-updates (remember the UID is used to not play a query twice when you have two masters which are slaves of a 3rd master). Then we are done. */ return; } /* otherwise, go on with reading the header from buf (nothing now) */ } #ifndef MYSQL_CLIENT #ifdef HAVE_REPLICATION int Log_event::do_update_pos(rpl_group_info *rgi) { Relay_log_info *rli= rgi->rli; DBUG_ENTER("Log_event::do_update_pos"); DBUG_ASSERT(!rli->belongs_to_client()); /* rli is null when (as far as I (Guilhem) know) the caller is Load_log_event::do_apply_event *and* that one is called from Execute_load_log_event::do_apply_event. In this case, we don't do anything here ; Execute_load_log_event::do_apply_event will call Log_event::do_apply_event again later with the proper rli. Strictly speaking, if we were sure that rli is null only in the case discussed above, 'if (rli)' is useless here. But as we are not 100% sure, keep it for now. Matz: I don't think we will need this check with this refactoring. */ if (rli) { /* In parallel execution, delay position update for the events that are not part of event groups (format description, rotate, and such) until the actual event execution reaches that point. */ if (!rgi->is_parallel_exec || is_group_event(get_type_code())) rli->stmt_done(log_pos, thd, rgi); } DBUG_RETURN(0); // Cannot fail currently } Log_event::enum_skip_reason Log_event::do_shall_skip(rpl_group_info *rgi) { Relay_log_info *rli= rgi->rli; DBUG_PRINT("info", ("ev->server_id: %lu, ::server_id: %lu," " rli->replicate_same_server_id: %d," " rli->slave_skip_counter: %llu", (ulong) server_id, (ulong) global_system_variables.server_id, rli->replicate_same_server_id, rli->slave_skip_counter)); if ((server_id == global_system_variables.server_id && !rli->replicate_same_server_id) || (rli->slave_skip_counter == 1 && rli->is_in_group()) || (flags & LOG_EVENT_SKIP_REPLICATION_F && opt_replicate_events_marked_for_skip != RPL_SKIP_REPLICATE)) return EVENT_SKIP_IGNORE; if (rli->slave_skip_counter > 0) return EVENT_SKIP_COUNT; return EVENT_SKIP_NOT; } /* Log_event::pack_info() */ void Log_event::pack_info(Protocol *protocol) { protocol->store("", &my_charset_bin); } /** Only called by SHOW BINLOG EVENTS */ int Log_event::net_send(Protocol *protocol, const char* log_name, my_off_t pos) { const char *p= strrchr(log_name, FN_LIBCHAR); const char *event_type; if (p) log_name = p + 1; protocol->prepare_for_resend(); protocol->store(log_name, &my_charset_bin); protocol->store((ulonglong) pos); event_type = get_type_str(); protocol->store(event_type, strlen(event_type), &my_charset_bin); protocol->store((uint32) server_id); protocol->store((ulonglong) log_pos); pack_info(protocol); return protocol->write(); } #endif /* HAVE_REPLICATION */ /** init_show_field_list() prepares the column names and types for the output of SHOW BINLOG EVENTS; it is used only by SHOW BINLOG EVENTS. */ void Log_event::init_show_field_list(THD *thd, List* field_list) { MEM_ROOT *mem_root= thd->mem_root; field_list->push_back(new (mem_root) Item_empty_string(thd, "Log_name", 20), mem_root); field_list->push_back(new (mem_root) Item_return_int(thd, "Pos", MY_INT64_NUM_DECIMAL_DIGITS, MYSQL_TYPE_LONGLONG), mem_root); field_list->push_back(new (mem_root) Item_empty_string(thd, "Event_type", 20), mem_root); field_list->push_back(new (mem_root) Item_return_int(thd, "Server_id", 10, MYSQL_TYPE_LONG), mem_root); field_list->push_back(new (mem_root) Item_return_int(thd, "End_log_pos", MY_INT64_NUM_DECIMAL_DIGITS, MYSQL_TYPE_LONGLONG), mem_root); field_list->push_back(new (mem_root) Item_empty_string(thd, "Info", 20), mem_root); } /** A decider of whether to trigger checksum computation or not. To be invoked in Log_event::write() stack. The decision is positive S,M) if it's been marked for checksumming with @c checksum_alg M) otherwise, if @@global.binlog_checksum is not NONE and the event is directly written to the binlog file. The to-be-cached event decides at @c write_cache() time. Otherwise the decision is negative. @note A side effect of the method is altering Log_event::checksum_alg it the latter was undefined at calling. @return true (positive) or false (negative) */ my_bool Log_event::need_checksum() { DBUG_ENTER("Log_event::need_checksum"); my_bool ret; /* few callers of Log_event::write (incl FD::write, FD constructing code on the slave side, Rotate relay log and Stop event) provides their checksum alg preference through Log_event::checksum_alg. */ if (checksum_alg != BINLOG_CHECKSUM_ALG_UNDEF) ret= checksum_alg != BINLOG_CHECKSUM_ALG_OFF; else { ret= binlog_checksum_options && cache_type == Log_event::EVENT_NO_CACHE; checksum_alg= ret ? (enum_binlog_checksum_alg)binlog_checksum_options : BINLOG_CHECKSUM_ALG_OFF; } /* FD calls the methods before data_written has been calculated. The following invariant claims if the current is not the first call (and therefore data_written is not zero) then `ret' must be TRUE. It may not be null because FD is always checksummed. */ DBUG_ASSERT(get_type_code() != FORMAT_DESCRIPTION_EVENT || ret || data_written == 0); DBUG_ASSERT(!ret || ((checksum_alg == binlog_checksum_options || /* Stop event closes the relay-log and its checksum alg preference is set by the caller can be different from the server's binlog_checksum_options. */ get_type_code() == STOP_EVENT || /* Rotate:s can be checksummed regardless of the server's binlog_checksum_options. That applies to both the local RL's Rotate and the master's Rotate which IO thread instantiates via queue_binlog_ver_3_event. */ get_type_code() == ROTATE_EVENT || get_type_code() == START_ENCRYPTION_EVENT || /* FD is always checksummed */ get_type_code() == FORMAT_DESCRIPTION_EVENT) && checksum_alg != BINLOG_CHECKSUM_ALG_OFF)); DBUG_ASSERT(checksum_alg != BINLOG_CHECKSUM_ALG_UNDEF); DBUG_ASSERT(((get_type_code() != ROTATE_EVENT && get_type_code() != STOP_EVENT) || get_type_code() != FORMAT_DESCRIPTION_EVENT) || cache_type == Log_event::EVENT_NO_CACHE); DBUG_RETURN(ret); } int Log_event_writer::write_internal(const uchar *pos, size_t len) { if (my_b_safe_write(file, pos, len)) return 1; bytes_written+= len; return 0; } /* as soon as encryption produces the first output block, write event_len where it should be in a valid event header */ int Log_event_writer::maybe_write_event_len(uchar *pos, size_t len) { if (len && event_len) { DBUG_ASSERT(len >= EVENT_LEN_OFFSET); if (write_internal(pos + EVENT_LEN_OFFSET - 4, 4)) return 1; int4store(pos + EVENT_LEN_OFFSET - 4, event_len); event_len= 0; } return 0; } int Log_event_writer::encrypt_and_write(const uchar *pos, size_t len) { uchar *dst= 0; size_t dstsize= 0; if (ctx) { dstsize= encryption_encrypted_length((uint)len, ENCRYPTION_KEY_SYSTEM_DATA, crypto->key_version); if (!(dst= (uchar*)my_safe_alloca(dstsize))) return 1; uint dstlen; if (len == 0) dstlen= 0; else if (encryption_ctx_update(ctx, pos, (uint)len, dst, &dstlen)) goto err; if (maybe_write_event_len(dst, dstlen)) return 1; pos= dst; len= dstlen; } if (write_internal(pos, len)) goto err; my_safe_afree(dst, dstsize); return 0; err: my_safe_afree(dst, dstsize); return 1; } int Log_event_writer::write_header(uchar *pos, size_t len) { DBUG_ENTER("Log_event_writer::write_header"); /* recording checksum of FD event computed with dropped possibly active LOG_EVENT_BINLOG_IN_USE_F flag. Similar step at verication: the active flag is dropped before checksum computing. */ if (checksum_len) { uchar save=pos[FLAGS_OFFSET]; pos[FLAGS_OFFSET]&= ~LOG_EVENT_BINLOG_IN_USE_F; crc= my_checksum(0, pos, len); pos[FLAGS_OFFSET]= save; } if (ctx) { uchar iv[BINLOG_IV_LENGTH]; crypto->set_iv(iv, (uint32)my_b_safe_tell(file)); if (encryption_ctx_init(ctx, crypto->key, crypto->key_length, iv, sizeof(iv), ENCRYPTION_FLAG_ENCRYPT | ENCRYPTION_FLAG_NOPAD, ENCRYPTION_KEY_SYSTEM_DATA, crypto->key_version)) DBUG_RETURN(1); DBUG_ASSERT(len >= LOG_EVENT_HEADER_LEN); event_len= uint4korr(pos + EVENT_LEN_OFFSET); DBUG_ASSERT(event_len >= len); memcpy(pos + EVENT_LEN_OFFSET, pos, 4); pos+= 4; len-= 4; } DBUG_RETURN(encrypt_and_write(pos, len)); } int Log_event_writer::write_data(const uchar *pos, size_t len) { DBUG_ENTER("Log_event_writer::write_data"); if (checksum_len) crc= my_checksum(crc, pos, len); DBUG_RETURN(encrypt_and_write(pos, len)); } int Log_event_writer::write_footer() { DBUG_ENTER("Log_event_writer::write_footer"); if (checksum_len) { uchar checksum_buf[BINLOG_CHECKSUM_LEN]; int4store(checksum_buf, crc); if (encrypt_and_write(checksum_buf, BINLOG_CHECKSUM_LEN)) DBUG_RETURN(ER_ERROR_ON_WRITE); } if (ctx) { uint dstlen; uchar dst[MY_AES_BLOCK_SIZE*2]; if (encryption_ctx_finish(ctx, dst, &dstlen)) DBUG_RETURN(1); if (maybe_write_event_len(dst, dstlen) || write_internal(dst, dstlen)) DBUG_RETURN(ER_ERROR_ON_WRITE); } DBUG_RETURN(0); } /* Log_event::write_header() */ bool Log_event::write_header(size_t event_data_length) { uchar header[LOG_EVENT_HEADER_LEN]; ulong now; DBUG_ENTER("Log_event::write_header"); DBUG_PRINT("enter", ("filepos: %lld length: %zu type: %d", (longlong) writer->pos(), event_data_length, (int) get_type_code())); writer->checksum_len= need_checksum() ? BINLOG_CHECKSUM_LEN : 0; /* Store number of bytes that will be written by this event */ data_written= event_data_length + sizeof(header) + writer->checksum_len; /* log_pos != 0 if this is relay-log event. In this case we should not change the position */ if (is_artificial_event()) { /* Artificial events are automatically generated and do not exist in master's binary log, so log_pos should be set to 0. */ log_pos= 0; } else if (!log_pos) { /* Calculate the position of where the next event will start (end of this event, that is). */ log_pos= writer->pos() + data_written; DBUG_EXECUTE_IF("dbug_master_binlog_over_2GB", log_pos += (1ULL <<31);); } now= get_time(); // Query start time /* Header will be of size LOG_EVENT_HEADER_LEN for all events, except for FORMAT_DESCRIPTION_EVENT and ROTATE_EVENT, where it will be LOG_EVENT_MINIMAL_HEADER_LEN (remember these 2 have a frozen header, because we read them before knowing the format). */ int4store(header, now); // timestamp header[EVENT_TYPE_OFFSET]= get_type_code(); int4store(header+ SERVER_ID_OFFSET, server_id); int4store(header+ EVENT_LEN_OFFSET, data_written); int4store(header+ LOG_POS_OFFSET, log_pos); int2store(header + FLAGS_OFFSET, flags); bool ret= writer->write_header(header, sizeof(header)); DBUG_RETURN(ret); } #endif /* !MYSQL_CLIENT */ /** This needn't be format-tolerant, because we only parse the first LOG_EVENT_MINIMAL_HEADER_LEN bytes (just need the event's length). */ int Log_event::read_log_event(IO_CACHE* file, String* packet, const Format_description_log_event *fdle, enum enum_binlog_checksum_alg checksum_alg_arg) { ulong data_len; char buf[LOG_EVENT_MINIMAL_HEADER_LEN]; uchar ev_offset= packet->length(); #if !defined(MYSQL_CLIENT) THD *thd=current_thd; ulong max_allowed_packet= thd ? thd->slave_thread ? slave_max_allowed_packet : thd->variables.max_allowed_packet : ~(uint)0; #endif DBUG_ENTER("Log_event::read_log_event(IO_CACHE*,String*...)"); if (my_b_read(file, (uchar*) buf, sizeof(buf))) { /* If the read hits eof, we must report it as eof so the caller will know it can go into cond_wait to be woken up on the next update to the log. */ DBUG_PRINT("error",("file->error: %d", file->error)); DBUG_RETURN(file->error == 0 ? LOG_READ_EOF : file->error > 0 ? LOG_READ_TRUNC : LOG_READ_IO); } data_len= uint4korr(buf + EVENT_LEN_OFFSET); /* Append the log event header to packet */ if (packet->append(buf, sizeof(buf))) DBUG_RETURN(LOG_READ_MEM); if (data_len < LOG_EVENT_MINIMAL_HEADER_LEN) DBUG_RETURN(LOG_READ_BOGUS); if (data_len > MY_MAX(max_allowed_packet, opt_binlog_rows_event_max_size + MAX_LOG_EVENT_HEADER)) DBUG_RETURN(LOG_READ_TOO_LARGE); if (likely(data_len > LOG_EVENT_MINIMAL_HEADER_LEN)) { /* Append rest of event, read directly from file into packet */ if (packet->append(file, data_len - LOG_EVENT_MINIMAL_HEADER_LEN)) { /* Fatal error occurred when appending rest of the event to packet, possible failures: 1. EOF occurred when reading from file, it's really an error as there's supposed to be more bytes available. file->error will have been set to number of bytes left to read 2. Read was interrupted, file->error would normally be set to -1 3. Failed to allocate memory for packet, my_errno will be ENOMEM(file->error should be 0, but since the memory allocation occurs before the call to read it might be uninitialized) */ DBUG_RETURN(my_errno == ENOMEM ? LOG_READ_MEM : (file->error >= 0 ? LOG_READ_TRUNC: LOG_READ_IO)); } } if (fdle->crypto_data.scheme) { uchar iv[BINLOG_IV_LENGTH]; fdle->crypto_data.set_iv(iv, (uint32) (my_b_tell(file) - data_len)); size_t sz= data_len + ev_offset + 1; #ifdef HAVE_WOLFSSL /* Workaround for MDEV-19582. WolfSSL reads memory out of bounds with decryption/NOPAD) We allocate a little more memory therefore. */ sz += MY_AES_BLOCK_SIZE; #endif char *newpkt= (char*)my_malloc(sz, MYF(MY_WME)); if (!newpkt) DBUG_RETURN(LOG_READ_MEM); memcpy(newpkt, packet->ptr(), ev_offset); uint dstlen; uchar *src= (uchar*)packet->ptr() + ev_offset; uchar *dst= (uchar*)newpkt + ev_offset; memcpy(src + EVENT_LEN_OFFSET, src, 4); if (encryption_crypt(src + 4, data_len - 4, dst + 4, &dstlen, fdle->crypto_data.key, fdle->crypto_data.key_length, iv, sizeof(iv), ENCRYPTION_FLAG_DECRYPT | ENCRYPTION_FLAG_NOPAD, ENCRYPTION_KEY_SYSTEM_DATA, fdle->crypto_data.key_version)) { my_free(newpkt); DBUG_RETURN(LOG_READ_DECRYPT); } DBUG_ASSERT(dstlen == data_len - 4); memcpy(dst, dst + EVENT_LEN_OFFSET, 4); int4store(dst + EVENT_LEN_OFFSET, data_len); packet->reset(newpkt, data_len + ev_offset, data_len + ev_offset + 1, &my_charset_bin); } /* CRC verification of the Dump thread */ if (data_len > LOG_EVENT_MINIMAL_HEADER_LEN) { /* Corrupt the event for Dump thread*/ DBUG_EXECUTE_IF("corrupt_read_log_event2", uchar *debug_event_buf_c = (uchar*) packet->ptr() + ev_offset; if (debug_event_buf_c[EVENT_TYPE_OFFSET] != FORMAT_DESCRIPTION_EVENT) { int debug_cor_pos = rand() % (data_len - BINLOG_CHECKSUM_LEN); debug_event_buf_c[debug_cor_pos] =~ debug_event_buf_c[debug_cor_pos]; DBUG_PRINT("info", ("Corrupt the event at Log_event::read_log_event: byte on position %d", debug_cor_pos)); DBUG_SET("-d,corrupt_read_log_event2"); } ); if (event_checksum_test((uchar*) packet->ptr() + ev_offset, data_len, checksum_alg_arg)) DBUG_RETURN(LOG_READ_CHECKSUM_FAILURE); } DBUG_RETURN(0); } Log_event* Log_event::read_log_event(IO_CACHE* file, const Format_description_log_event *fdle, my_bool crc_check) { DBUG_ENTER("Log_event::read_log_event(IO_CACHE*,Format_description_log_event*...)"); DBUG_ASSERT(fdle != 0); String event; const char *error= 0; Log_event *res= 0; switch (read_log_event(file, &event, fdle, BINLOG_CHECKSUM_ALG_OFF)) { case 0: break; case LOG_READ_EOF: // no error here; we are at the file's end goto err; case LOG_READ_BOGUS: error= "Event invalid"; goto err; case LOG_READ_IO: error= "read error"; goto err; case LOG_READ_MEM: error= "Out of memory"; goto err; case LOG_READ_TRUNC: error= "Event truncated"; goto err; case LOG_READ_TOO_LARGE: error= "Event too big"; goto err; case LOG_READ_DECRYPT: error= "Event decryption failure"; goto err; case LOG_READ_CHECKSUM_FAILURE: default: DBUG_ASSERT(0); error= "internal error"; goto err; } if ((res= read_log_event(event.ptr(), event.length(), &error, fdle, crc_check))) res->register_temp_buf(event.release(), true); err: if (unlikely(error)) { DBUG_ASSERT(!res); #ifdef MYSQL_CLIENT if (force_opt) DBUG_RETURN(new Unknown_log_event()); #endif if (event.length() >= OLD_HEADER_LEN) sql_print_error("Error in Log_event::read_log_event(): '%s'," " data_len: %lu, event_type: %u", error, (ulong) uint4korr(&event[EVENT_LEN_OFFSET]), (uint) (uchar)event[EVENT_TYPE_OFFSET]); else sql_print_error("Error in Log_event::read_log_event(): '%s'", error); /* The SQL slave thread will check if file->error<0 to know if there was an I/O error. Even if there is no "low-level" I/O errors with 'file', any of the high-level above errors is worrying enough to stop the SQL thread now ; as we are skipping the current event, going on with reading and successfully executing other events can only corrupt the slave's databases. So stop. */ file->error= -1; } DBUG_RETURN(res); } /** Binlog format tolerance is in (buf, event_len, fdle) constructors. */ Log_event* Log_event::read_log_event(const char* buf, uint event_len, const char **error, const Format_description_log_event *fdle, my_bool crc_check) { Log_event* ev; enum enum_binlog_checksum_alg alg; DBUG_ENTER("Log_event::read_log_event(char*,...)"); DBUG_ASSERT(fdle != 0); DBUG_PRINT("info", ("binlog_version: %d", fdle->binlog_version)); DBUG_DUMP_EVENT_BUF(buf, event_len); /* Check the integrity; This is needed because handle_slave_io() doesn't check if packet is of proper length. */ if (event_len < EVENT_LEN_OFFSET) { *error="Sanity check failed"; // Needed to free buffer DBUG_RETURN(NULL); // general sanity check - will fail on a partial read } uint event_type= (uchar)buf[EVENT_TYPE_OFFSET]; // all following START events in the current file are without checksum if (event_type == START_EVENT_V3) (const_cast< Format_description_log_event *>(fdle))->checksum_alg= BINLOG_CHECKSUM_ALG_OFF; /* CRC verification by SQL and Show-Binlog-Events master side. The caller has to provide @fdle->checksum_alg to be the last seen FD's (A) descriptor. If event is FD the descriptor is in it. Notice, FD of the binlog can be only in one instance and therefore Show-Binlog-Events executing master side thread needs just to know the only FD's (A) value - whereas RL can contain more. In the RL case, the alg is kept in FD_e (@fdle) which is reset to the newer read-out event after its execution with possibly new alg descriptor. Therefore in a typical sequence of RL: {FD_s^0, FD_m, E_m^1} E_m^1 will be verified with (A) of FD_m. See legends definition on MYSQL_BIN_LOG::relay_log_checksum_alg docs lines (log.h). Notice, a pre-checksum FD version forces alg := BINLOG_CHECKSUM_ALG_UNDEF. */ alg= (event_type != FORMAT_DESCRIPTION_EVENT) ? fdle->checksum_alg : get_checksum_alg(buf, event_len); // Emulate the corruption during reading an event DBUG_EXECUTE_IF("corrupt_read_log_event_char", if (event_type != FORMAT_DESCRIPTION_EVENT) { char *debug_event_buf_c = (char *)buf; int debug_cor_pos = rand() % (event_len - BINLOG_CHECKSUM_LEN); debug_event_buf_c[debug_cor_pos] =~ debug_event_buf_c[debug_cor_pos]; DBUG_PRINT("info", ("Corrupt the event at Log_event::read_log_event(char*,...): byte on position %d", debug_cor_pos)); DBUG_SET("-d,corrupt_read_log_event_char"); } ); if (crc_check && event_checksum_test((uchar *) buf, event_len, alg)) { #ifdef MYSQL_CLIENT *error= "Event crc check failed! Most likely there is event corruption."; if (force_opt) { ev= new Unknown_log_event(buf, fdle); DBUG_RETURN(ev); } else DBUG_RETURN(NULL); #else *error= ER_THD_OR_DEFAULT(current_thd, ER_BINLOG_READ_EVENT_CHECKSUM_FAILURE); sql_print_error("%s", *error); DBUG_RETURN(NULL); #endif } if (event_type > fdle->number_of_event_types && event_type != FORMAT_DESCRIPTION_EVENT) { /* It is unsafe to use the fdle if its post_header_len array does not include the event type. */ DBUG_PRINT("error", ("event type %d found, but the current " "Format_description_log_event supports only %d event " "types", event_type, fdle->number_of_event_types)); ev= NULL; } else { /* In some previuos versions (see comment in Format_description_log_event::Format_description_log_event(char*,...)), event types were assigned different id numbers than in the present version. In order to replicate from such versions to the present version, we must map those event type id's to our event type id's. The mapping is done with the event_type_permutation array, which was set up when the Format_description_log_event was read. */ if (fdle->event_type_permutation) { int new_event_type= fdle->event_type_permutation[event_type]; DBUG_PRINT("info", ("converting event type %d to %d (%s)", event_type, new_event_type, get_type_str((Log_event_type)new_event_type))); event_type= new_event_type; } if (alg != BINLOG_CHECKSUM_ALG_UNDEF && (event_type == FORMAT_DESCRIPTION_EVENT || alg != BINLOG_CHECKSUM_ALG_OFF)) event_len= event_len - BINLOG_CHECKSUM_LEN; /* Create an object of Ignorable_log_event for unrecognized sub-class. So that SLAVE SQL THREAD will only update the position and continue. We should look for this flag first instead of judging by event_type Any event can be Ignorable_log_event if it has this flag on. look into @note of Ignorable_log_event */ if (uint2korr(buf + FLAGS_OFFSET) & LOG_EVENT_IGNORABLE_F) { ev= new Ignorable_log_event(buf, fdle, get_type_str((Log_event_type) event_type)); goto exit; } switch(event_type) { case QUERY_EVENT: ev = new Query_log_event(buf, event_len, fdle, QUERY_EVENT); break; case QUERY_COMPRESSED_EVENT: ev = new Query_compressed_log_event(buf, event_len, fdle, QUERY_COMPRESSED_EVENT); break; case LOAD_EVENT: ev = new Load_log_event(buf, event_len, fdle); break; case NEW_LOAD_EVENT: ev = new Load_log_event(buf, event_len, fdle); break; case ROTATE_EVENT: ev = new Rotate_log_event(buf, event_len, fdle); break; case BINLOG_CHECKPOINT_EVENT: ev = new Binlog_checkpoint_log_event(buf, event_len, fdle); break; case GTID_EVENT: ev = new Gtid_log_event(buf, event_len, fdle); break; case GTID_LIST_EVENT: ev = new Gtid_list_log_event(buf, event_len, fdle); break; case CREATE_FILE_EVENT: ev = new Create_file_log_event(buf, event_len, fdle); break; case APPEND_BLOCK_EVENT: ev = new Append_block_log_event(buf, event_len, fdle); break; case DELETE_FILE_EVENT: ev = new Delete_file_log_event(buf, event_len, fdle); break; case EXEC_LOAD_EVENT: ev = new Execute_load_log_event(buf, event_len, fdle); break; case START_EVENT_V3: /* this is sent only by MySQL <=4.x */ ev = new Start_log_event_v3(buf, event_len, fdle); break; case STOP_EVENT: ev = new Stop_log_event(buf, fdle); break; case INTVAR_EVENT: ev = new Intvar_log_event(buf, fdle); break; case XID_EVENT: ev = new Xid_log_event(buf, fdle); break; case RAND_EVENT: ev = new Rand_log_event(buf, fdle); break; case USER_VAR_EVENT: ev = new User_var_log_event(buf, event_len, fdle); break; case FORMAT_DESCRIPTION_EVENT: ev = new Format_description_log_event(buf, event_len, fdle); break; #if defined(HAVE_REPLICATION) case PRE_GA_WRITE_ROWS_EVENT: ev = new Write_rows_log_event_old(buf, event_len, fdle); break; case PRE_GA_UPDATE_ROWS_EVENT: ev = new Update_rows_log_event_old(buf, event_len, fdle); break; case PRE_GA_DELETE_ROWS_EVENT: ev = new Delete_rows_log_event_old(buf, event_len, fdle); break; case WRITE_ROWS_EVENT_V1: case WRITE_ROWS_EVENT: ev = new Write_rows_log_event(buf, event_len, fdle); break; case UPDATE_ROWS_EVENT_V1: case UPDATE_ROWS_EVENT: ev = new Update_rows_log_event(buf, event_len, fdle); break; case DELETE_ROWS_EVENT_V1: case DELETE_ROWS_EVENT: ev = new Delete_rows_log_event(buf, event_len, fdle); break; case WRITE_ROWS_COMPRESSED_EVENT: case WRITE_ROWS_COMPRESSED_EVENT_V1: ev = new Write_rows_compressed_log_event(buf, event_len, fdle); break; case UPDATE_ROWS_COMPRESSED_EVENT: case UPDATE_ROWS_COMPRESSED_EVENT_V1: ev = new Update_rows_compressed_log_event(buf, event_len, fdle); break; case DELETE_ROWS_COMPRESSED_EVENT: case DELETE_ROWS_COMPRESSED_EVENT_V1: ev = new Delete_rows_compressed_log_event(buf, event_len, fdle); break; /* MySQL GTID events are ignored */ case GTID_LOG_EVENT: case ANONYMOUS_GTID_LOG_EVENT: case PREVIOUS_GTIDS_LOG_EVENT: case TRANSACTION_CONTEXT_EVENT: case VIEW_CHANGE_EVENT: case XA_PREPARE_LOG_EVENT: ev= new Ignorable_log_event(buf, fdle, get_type_str((Log_event_type) event_type)); break; case TABLE_MAP_EVENT: ev = new Table_map_log_event(buf, event_len, fdle); break; #endif case BEGIN_LOAD_QUERY_EVENT: ev = new Begin_load_query_log_event(buf, event_len, fdle); break; case EXECUTE_LOAD_QUERY_EVENT: ev= new Execute_load_query_log_event(buf, event_len, fdle); break; case INCIDENT_EVENT: ev = new Incident_log_event(buf, event_len, fdle); break; case ANNOTATE_ROWS_EVENT: ev = new Annotate_rows_log_event(buf, event_len, fdle); break; case START_ENCRYPTION_EVENT: ev = new Start_encryption_log_event(buf, event_len, fdle); break; default: DBUG_PRINT("error",("Unknown event code: %d", (uchar) buf[EVENT_TYPE_OFFSET])); ev= NULL; break; } } exit: if (ev) { ev->checksum_alg= alg; #ifdef MYSQL_CLIENT if (ev->checksum_alg != BINLOG_CHECKSUM_ALG_OFF && ev->checksum_alg != BINLOG_CHECKSUM_ALG_UNDEF) ev->crc= uint4korr(buf + (event_len)); #endif } DBUG_PRINT("read_event", ("%s(type_code: %u; event_len: %u)", ev ? ev->get_type_str() : "", (uchar)buf[EVENT_TYPE_OFFSET], event_len)); /* is_valid() are small event-specific sanity tests which are important; for example there are some my_malloc() in constructors (e.g. Query_log_event::Query_log_event(char*...)); when these my_malloc() fail we can't return an error out of the constructor (because constructor is "void") ; so instead we leave the pointer we wanted to allocate (e.g. 'query') to 0 and we test it in is_valid(). Same for Format_description_log_event, member 'post_header_len'. SLAVE_EVENT is never used, so it should not be read ever. */ if (!ev || !ev->is_valid() || (event_type == SLAVE_EVENT)) { DBUG_PRINT("error",("Found invalid event in binary log")); delete ev; #ifdef MYSQL_CLIENT if (!force_opt) /* then mysqlbinlog dies */ { *error= "Found invalid event in binary log"; DBUG_RETURN(0); } ev= new Unknown_log_event(buf, fdle); #else *error= "Found invalid event in binary log"; DBUG_RETURN(0); #endif } DBUG_RETURN(ev); } #ifdef MYSQL_CLIENT static bool hexdump_minimal_header_to_io_cache(IO_CACHE *file, my_off_t offset, uchar *ptr) { DBUG_ASSERT(LOG_EVENT_MINIMAL_HEADER_LEN == 19); /* Pretty-print the first LOG_EVENT_MINIMAL_HEADER_LEN (19) bytes of the common header, which contains the basic information about the log event. Every event will have at least this much header, but events could contain more headers (which must be printed by other methods, if desired). */ char emit_buf[120]; // Enough for storing one line size_t emit_buf_written; if (my_b_printf(file, "# " "|Timestamp " "|Type " "|Master ID " "|Size " "|Master Pos " "|Flags\n")) goto err; emit_buf_written= my_snprintf(emit_buf, sizeof(emit_buf), "# %8llx " /* Position */ "|%02x %02x %02x %02x " /* Timestamp */ "|%02x " /* Type */ "|%02x %02x %02x %02x " /* Master ID */ "|%02x %02x %02x %02x " /* Size */ "|%02x %02x %02x %02x " /* Master Pos */ "|%02x %02x\n", /* Flags */ (ulonglong) offset, /* Position */ ptr[0], ptr[1], ptr[2], ptr[3], /* Timestamp */ ptr[4], /* Type */ ptr[5], ptr[6], ptr[7], ptr[8], /* Master ID */ ptr[9], ptr[10], ptr[11], ptr[12], /* Size */ ptr[13], ptr[14], ptr[15], ptr[16], /* Master Pos */ ptr[17], ptr[18]); /* Flags */ DBUG_ASSERT(static_cast(emit_buf_written) < sizeof(emit_buf)); if (my_b_write(file, reinterpret_cast(emit_buf), emit_buf_written) || my_b_write(file, (uchar*)"#\n", 2)) goto err; return 0; err: return 1; } /* The number of bytes to print per line. Should be an even number, and "hexdump -C" uses 16, so we'll duplicate that here. */ #define HEXDUMP_BYTES_PER_LINE 16 static void format_hex_line(char *emit_buff) { memset(emit_buff + 1, ' ', 1 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2 + HEXDUMP_BYTES_PER_LINE); emit_buff[0]= '#'; emit_buff[2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 1]= '|'; emit_buff[2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2 + HEXDUMP_BYTES_PER_LINE]= '|'; emit_buff[2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2 + HEXDUMP_BYTES_PER_LINE + 1]= '\n'; emit_buff[2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2 + HEXDUMP_BYTES_PER_LINE + 2]= '\0'; } static bool hexdump_data_to_io_cache(IO_CACHE *file, my_off_t offset, uchar *ptr, my_off_t size) { /* 2 = '# ' 8 = address 2 = ' ' (HEXDUMP_BYTES_PER_LINE * 3 + 1) = Each byte prints as two hex digits, plus a space 2 = ' |' HEXDUMP_BYTES_PER_LINE = text representation 2 = '|\n' 1 = '\0' */ char emit_buffer[2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2 + HEXDUMP_BYTES_PER_LINE + 2 + 1 ]; char *h,*c; my_off_t i; if (size == 0) return 0; // ok, nothing to do format_hex_line(emit_buffer); /* Print the rest of the event (without common header) */ my_off_t starting_offset = offset; for (i= 0, c= emit_buffer + 2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2, h= emit_buffer + 2 + 8 + 2; i < size; i++, ptr++) { my_snprintf(h, 4, "%02x ", *ptr); h+= 3; *c++= my_isprint(&my_charset_bin, *ptr) ? *ptr : '.'; /* Print in groups of HEXDUMP_BYTES_PER_LINE characters. */ if ((i % HEXDUMP_BYTES_PER_LINE) == (HEXDUMP_BYTES_PER_LINE - 1)) { /* remove \0 left after printing hex byte representation */ *h= ' '; /* prepare space to print address */ memset(emit_buffer + 2, ' ', 8); /* print address */ size_t const emit_buf_written= my_snprintf(emit_buffer + 2, 9, "%8llx", (ulonglong) starting_offset); /* remove \0 left after printing address */ emit_buffer[2 + emit_buf_written]= ' '; if (my_b_write(file, reinterpret_cast(emit_buffer), sizeof(emit_buffer) - 1)) goto err; c= emit_buffer + 2 + 8 + 2 + (HEXDUMP_BYTES_PER_LINE * 3 + 1) + 2; h= emit_buffer + 2 + 8 + 2; format_hex_line(emit_buffer); starting_offset+= HEXDUMP_BYTES_PER_LINE; } else if ((i % (HEXDUMP_BYTES_PER_LINE / 2)) == ((HEXDUMP_BYTES_PER_LINE / 2) - 1)) { /* In the middle of the group of HEXDUMP_BYTES_PER_LINE, emit an extra space in the hex string, to make two groups. */ *h++= ' '; } } /* There is still data left in our buffer, which means that the previous line was not perfectly HEXDUMP_BYTES_PER_LINE characters, so write an incomplete line, with spaces to pad out to the same length as a full line would be, to make things more readable. */ if (h != emit_buffer + 2 + 8 + 2) { *h= ' '; *c++= '|'; *c++= '\n'; memset(emit_buffer + 2, ' ', 8); size_t const emit_buf_written= my_snprintf(emit_buffer + 2, 9, "%8llx", (ulonglong) starting_offset); emit_buffer[2 + emit_buf_written]= ' '; /* pad unprinted area */ memset(h, ' ', (HEXDUMP_BYTES_PER_LINE * 3 + 1) - (h - (emit_buffer + 2 + 8 + 2))); if (my_b_write(file, reinterpret_cast(emit_buffer), c - emit_buffer)) goto err; } if (my_b_write(file, (uchar*)"#\n", 2)) goto err; return 0; err: return 1; } /* Log_event::print_header() */ bool Log_event::print_header(IO_CACHE* file, PRINT_EVENT_INFO* print_event_info, bool is_more __attribute__((unused))) { char llbuff[22]; my_off_t hexdump_from= print_event_info->hexdump_from; DBUG_ENTER("Log_event::print_header"); if (my_b_write_byte(file, '#') || print_timestamp(file) || my_b_printf(file, " server id %lu end_log_pos %s ", (ulong) server_id, llstr(log_pos,llbuff))) goto err; /* print the checksum */ if (checksum_alg != BINLOG_CHECKSUM_ALG_OFF && checksum_alg != BINLOG_CHECKSUM_ALG_UNDEF) { char checksum_buf[BINLOG_CHECKSUM_LEN * 2 + 4]; // to fit to "%p " size_t const bytes_written= my_snprintf(checksum_buf, sizeof(checksum_buf), "0x%08x ", crc); if (my_b_printf(file, "%s ", get_type(&binlog_checksum_typelib, checksum_alg)) || my_b_printf(file, checksum_buf, bytes_written)) goto err; } /* mysqlbinlog --hexdump */ if (print_event_info->hexdump_from) { my_b_write_byte(file, '\n'); uchar *ptr= (uchar*)temp_buf; my_off_t size= uint4korr(ptr + EVENT_LEN_OFFSET); my_off_t hdr_len= get_header_len(print_event_info->common_header_len); size-= hdr_len; if (my_b_printf(file, "# Position\n")) goto err; /* Write the header, nicely formatted by field. */ if (hexdump_minimal_header_to_io_cache(file, hexdump_from, ptr)) goto err; ptr+= hdr_len; hexdump_from+= hdr_len; /* Print the rest of the data, mimicking "hexdump -C" output. */ if (hexdump_data_to_io_cache(file, hexdump_from, ptr, size)) goto err; /* Prefix the next line so that the output from print_helper() will appear as a comment. */ if (my_b_write(file, (uchar*)"# Event: ", 9)) goto err; } DBUG_RETURN(0); err: DBUG_RETURN(1); } /** Prints a quoted string to io cache. Control characters are displayed as hex sequence, e.g. \x00 Single-quote and backslash characters are escaped with a \ @param[in] file IO cache @param[in] prt Pointer to string @param[in] length String length */ static void my_b_write_quoted(IO_CACHE *file, const uchar *ptr, uint length) { const uchar *s; my_b_write_byte(file, '\''); for (s= ptr; length > 0 ; s++, length--) { if (*s > 0x1F) my_b_write_byte(file, *s); else if (*s == '\'') my_b_write(file, (uchar*)"\\'", 2); else if (*s == '\\') my_b_write(file, (uchar*)"\\\\", 2); else { uchar hex[10]; size_t len= my_snprintf((char*) hex, sizeof(hex), "%s%02x", "\\x", *s); my_b_write(file, hex, len); } } my_b_write_byte(file, '\''); } /** Prints a bit string to io cache in format b'1010'. @param[in] file IO cache @param[in] ptr Pointer to string @param[in] nbits Number of bits */ static void my_b_write_bit(IO_CACHE *file, const uchar *ptr, uint nbits) { uint bitnum, nbits8= ((nbits + 7) / 8) * 8, skip_bits= nbits8 - nbits; my_b_write(file, (uchar*)"b'", 2); for (bitnum= skip_bits ; bitnum < nbits8; bitnum++) { int is_set= (ptr[(bitnum) / 8] >> (7 - bitnum % 8)) & 0x01; my_b_write_byte(file, (is_set ? '1' : '0')); } my_b_write_byte(file, '\''); } /** Prints a packed string to io cache. The string consists of length packed to 1 or 2 bytes, followed by string data itself. @param[in] file IO cache @param[in] ptr Pointer to string @param[in] length String size @retval - number of bytes scanned. */ static size_t my_b_write_quoted_with_length(IO_CACHE *file, const uchar *ptr, uint length) { if (length < 256) { length= *ptr; my_b_write_quoted(file, ptr + 1, length); return length + 1; } else { length= uint2korr(ptr); my_b_write_quoted(file, ptr + 2, length); return length + 2; } } /** Prints a 32-bit number in both signed and unsigned representation @param[in] file IO cache @param[in] sl Signed number @param[in] ul Unsigned number */ static bool my_b_write_sint32_and_uint32(IO_CACHE *file, int32 si, uint32 ui) { bool res= my_b_printf(file, "%d", si); if (si < 0) if (my_b_printf(file, " (%u)", ui)) res= 1; return res; } /** Print a packed value of the given SQL type into IO cache @param[in] file IO cache @param[in] ptr Pointer to string @param[in] type Column type @param[in] meta Column meta information @param[out] typestr SQL type string buffer (for verbose output) @param[out] typestr_length Size of typestr @retval - number of bytes scanned from ptr. Except in case of NULL, in which case we return 1 to indicate ok */ static size_t log_event_print_value(IO_CACHE *file, PRINT_EVENT_INFO *print_event_info, const uchar *ptr, uint type, uint meta, char *typestr, size_t typestr_length) { uint32 length= 0; if (type == MYSQL_TYPE_STRING) { if (meta >= 256) { uint byte0= meta >> 8; uint byte1= meta & 0xFF; if ((byte0 & 0x30) != 0x30) { /* a long CHAR() field: see #37426 */ length= byte1 | (((byte0 & 0x30) ^ 0x30) << 4); type= byte0 | 0x30; } else length = meta & 0xFF; } else length= meta; } switch (type) { case MYSQL_TYPE_LONG: { strmake(typestr, "INT", typestr_length); if (!ptr) goto return_null; int32 si= sint4korr(ptr); uint32 ui= uint4korr(ptr); my_b_write_sint32_and_uint32(file, si, ui); return 4; } case MYSQL_TYPE_TINY: { strmake(typestr, "TINYINT", typestr_length); if (!ptr) goto return_null; my_b_write_sint32_and_uint32(file, (int) (signed char) *ptr, (uint) (unsigned char) *ptr); return 1; } case MYSQL_TYPE_SHORT: { strmake(typestr, "SHORTINT", typestr_length); if (!ptr) goto return_null; int32 si= (int32) sint2korr(ptr); uint32 ui= (uint32) uint2korr(ptr); my_b_write_sint32_and_uint32(file, si, ui); return 2; } case MYSQL_TYPE_INT24: { strmake(typestr, "MEDIUMINT", typestr_length); if (!ptr) goto return_null; int32 si= sint3korr(ptr); uint32 ui= uint3korr(ptr); my_b_write_sint32_and_uint32(file, si, ui); return 3; } case MYSQL_TYPE_LONGLONG: { strmake(typestr, "LONGINT", typestr_length); if (!ptr) goto return_null; char tmp[64]; size_t length; longlong si= sint8korr(ptr); length= (longlong10_to_str(si, tmp, -10) - tmp); my_b_write(file, (uchar*)tmp, length); if (si < 0) { ulonglong ui= uint8korr(ptr); longlong10_to_str((longlong) ui, tmp, 10); my_b_printf(file, " (%s)", tmp); } return 8; } case MYSQL_TYPE_NEWDECIMAL: { uint precision= meta >> 8; uint decimals= meta & 0xFF; my_snprintf(typestr, typestr_length, "DECIMAL(%d,%d)", precision, decimals); if (!ptr) goto return_null; uint bin_size= my_decimal_get_binary_size(precision, decimals); my_decimal dec((const uchar *) ptr, precision, decimals); int length= DECIMAL_MAX_STR_LENGTH; char buff[DECIMAL_MAX_STR_LENGTH + 1]; decimal2string(&dec, buff, &length, 0, 0, 0); my_b_write(file, (uchar*)buff, length); return bin_size; } case MYSQL_TYPE_FLOAT: { strmake(typestr, "FLOAT", typestr_length); if (!ptr) goto return_null; float fl; float4get(fl, ptr); char tmp[320]; sprintf(tmp, "%-20g", (double) fl); my_b_printf(file, "%s", tmp); /* my_snprintf doesn't support %-20g */ return 4; } case MYSQL_TYPE_DOUBLE: { double dbl; strmake(typestr, "DOUBLE", typestr_length); if (!ptr) goto return_null; float8get(dbl, ptr); char tmp[320]; sprintf(tmp, "%-.20g", dbl); /* strmake doesn't support %-20g */ my_b_printf(file, tmp, "%s"); return 8; } case MYSQL_TYPE_BIT: { /* Meta-data: bit_len, bytes_in_rec, 2 bytes */ uint nbits= ((meta >> 8) * 8) + (meta & 0xFF); my_snprintf(typestr, typestr_length, "BIT(%d)", nbits); if (!ptr) goto return_null; length= (nbits + 7) / 8; my_b_write_bit(file, ptr, nbits); return length; } case MYSQL_TYPE_TIMESTAMP: { strmake(typestr, "TIMESTAMP", typestr_length); if (!ptr) goto return_null; uint32 i32= uint4korr(ptr); my_b_printf(file, "%d", i32); return 4; } case MYSQL_TYPE_TIMESTAMP2: { my_snprintf(typestr, typestr_length, "TIMESTAMP(%d)", meta); if (!ptr) goto return_null; char buf[MAX_DATE_STRING_REP_LENGTH]; struct timeval tm; my_timestamp_from_binary(&tm, ptr, meta); int buflen= my_timeval_to_str(&tm, buf, meta); my_b_write(file, (uchar*)buf, buflen); return my_timestamp_binary_length(meta); } case MYSQL_TYPE_DATETIME: { strmake(typestr, "DATETIME", typestr_length); if (!ptr) goto return_null; ulong d, t; uint64 i64= uint8korr(ptr); /* YYYYMMDDhhmmss */ d= (ulong) (i64 / 1000000); t= (ulong) (i64 % 1000000); my_b_printf(file, "'%04d-%02d-%02d %02d:%02d:%02d'", (int) (d / 10000), (int) (d % 10000) / 100, (int) (d % 100), (int) (t / 10000), (int) (t % 10000) / 100, (int) t % 100); return 8; } case MYSQL_TYPE_DATETIME2: { my_snprintf(typestr, typestr_length, "DATETIME(%d)", meta); if (!ptr) goto return_null; char buf[MAX_DATE_STRING_REP_LENGTH]; MYSQL_TIME ltime; longlong packed= my_datetime_packed_from_binary(ptr, meta); TIME_from_longlong_datetime_packed(<ime, packed); int buflen= my_datetime_to_str(<ime, buf, meta); my_b_write_quoted(file, (uchar *) buf, buflen); return my_datetime_binary_length(meta); } case MYSQL_TYPE_TIME: { strmake(typestr, "TIME", typestr_length); if (!ptr) goto return_null; int32 tmp= sint3korr(ptr); int32 i32= tmp >= 0 ? tmp : - tmp; const char *sign= tmp < 0 ? "-" : ""; my_b_printf(file, "'%s%02d:%02d:%02d'", sign, i32 / 10000, (i32 % 10000) / 100, i32 % 100, i32); return 3; } case MYSQL_TYPE_TIME2: { my_snprintf(typestr, typestr_length, "TIME(%d)", meta); if (!ptr) goto return_null; char buf[MAX_DATE_STRING_REP_LENGTH]; MYSQL_TIME ltime; longlong packed= my_time_packed_from_binary(ptr, meta); TIME_from_longlong_time_packed(<ime, packed); int buflen= my_time_to_str(<ime, buf, meta); my_b_write_quoted(file, (uchar *) buf, buflen); return my_time_binary_length(meta); } case MYSQL_TYPE_NEWDATE: { strmake(typestr, "DATE", typestr_length); if (!ptr) goto return_null; uint32 tmp= uint3korr(ptr); int part; char buf[11]; char *pos= &buf[10]; // start from '\0' to the beginning /* Copied from field.cc */ *pos--=0; // End NULL part=(int) (tmp & 31); *pos--= (char) ('0'+part%10); *pos--= (char) ('0'+part/10); *pos--= ':'; part=(int) (tmp >> 5 & 15); *pos--= (char) ('0'+part%10); *pos--= (char) ('0'+part/10); *pos--= ':'; part=(int) (tmp >> 9); *pos--= (char) ('0'+part%10); part/=10; *pos--= (char) ('0'+part%10); part/=10; *pos--= (char) ('0'+part%10); part/=10; *pos= (char) ('0'+part); my_b_printf(file , "'%s'", buf); return 3; } case MYSQL_TYPE_DATE: { strmake(typestr, "DATE", typestr_length); if (!ptr) goto return_null; uint i32= uint3korr(ptr); my_b_printf(file , "'%04d:%02d:%02d'", (int)(i32 / (16L * 32L)), (int)(i32 / 32L % 16L), (int)(i32 % 32L)); return 3; } case MYSQL_TYPE_YEAR: { strmake(typestr, "YEAR", typestr_length); if (!ptr) goto return_null; uint32 i32= *ptr; my_b_printf(file, "%04d", i32+ 1900); return 1; } case MYSQL_TYPE_ENUM: switch (meta & 0xFF) { case 1: strmake(typestr, "ENUM(1 byte)", typestr_length); if (!ptr) goto return_null; my_b_printf(file, "%d", (int) *ptr); return 1; case 2: { strmake(typestr, "ENUM(2 bytes)", typestr_length); if (!ptr) goto return_null; int32 i32= uint2korr(ptr); my_b_printf(file, "%d", i32); return 2; } default: my_b_printf(file, "!! Unknown ENUM packlen=%d", meta & 0xFF); return 0; } break; case MYSQL_TYPE_SET: my_snprintf(typestr, typestr_length, "SET(%d bytes)", meta & 0xFF); if (!ptr) goto return_null; my_b_write_bit(file, ptr , (meta & 0xFF) * 8); return meta & 0xFF; case MYSQL_TYPE_BLOB: switch (meta) { case 1: strmake(typestr, "TINYBLOB/TINYTEXT", typestr_length); if (!ptr) goto return_null; length= *ptr; my_b_write_quoted(file, ptr + 1, length); return length + 1; case 2: strmake(typestr, "BLOB/TEXT", typestr_length); if (!ptr) goto return_null; length= uint2korr(ptr); my_b_write_quoted(file, ptr + 2, length); return length + 2; case 3: strmake(typestr, "MEDIUMBLOB/MEDIUMTEXT", typestr_length); if (!ptr) goto return_null; length= uint3korr(ptr); my_b_write_quoted(file, ptr + 3, length); return length + 3; case 4: strmake(typestr, "LONGBLOB/LONGTEXT", typestr_length); if (!ptr) goto return_null; length= uint4korr(ptr); my_b_write_quoted(file, ptr + 4, length); return length + 4; default: my_b_printf(file, "!! Unknown BLOB packlen=%d", length); return 0; } case MYSQL_TYPE_VARCHAR: case MYSQL_TYPE_VAR_STRING: length= meta; my_snprintf(typestr, typestr_length, "VARSTRING(%d)", length); if (!ptr) goto return_null; return my_b_write_quoted_with_length(file, ptr, length); case MYSQL_TYPE_STRING: my_snprintf(typestr, typestr_length, "STRING(%d)", length); if (!ptr) goto return_null; return my_b_write_quoted_with_length(file, ptr, length); case MYSQL_TYPE_DECIMAL: print_event_info->flush_for_error(); fprintf(stderr, "\nError: Found Old DECIMAL (mysql-4.1 or earlier). " "Not enough metadata to display the value.\n"); break; case MYSQL_TYPE_GEOMETRY: strmake(typestr, "GEOMETRY", typestr_length); if (!ptr) goto return_null; length= uint4korr(ptr); my_b_write_quoted(file, ptr + meta, length); return length + meta; default: print_event_info->flush_for_error(); fprintf(stderr, "\nError: Don't know how to handle column type: %d meta: %d (%04x)\n", type, meta, meta); break; } *typestr= 0; return 0; return_null: return my_b_write(file, (uchar*) "NULL", 4) ? 0 : 1; } /** Print a packed row into IO cache @param[in] file IO cache @param[in] td Table definition @param[in] print_event_into Print parameters @param[in] cols_bitmap Column bitmaps. @param[in] value Pointer to packed row @param[in] prefix Row's SQL clause ("SET", "WHERE", etc) @retval 0 error # number of bytes scanned. */ size_t Rows_log_event::print_verbose_one_row(IO_CACHE *file, table_def *td, PRINT_EVENT_INFO *print_event_info, MY_BITMAP *cols_bitmap, const uchar *value, const uchar *prefix, const my_bool no_fill_output) { const uchar *value0= value; const uchar *null_bits= value; uint null_bit_index= 0; char typestr[64]= ""; #ifdef WHEN_FLASHBACK_REVIEW_READY /* Storing the review SQL */ IO_CACHE *review_sql= &print_event_info->review_sql_cache; LEX_STRING review_str; #endif /* Skip metadata bytes which gives the information about nullabity of master columns. Master writes one bit for each affected column. */ value+= (bitmap_bits_set(cols_bitmap) + 7) / 8; if (!no_fill_output) if (my_b_printf(file, "%s", prefix)) goto err; for (uint i= 0; i < (uint)td->size(); i ++) { size_t size; int is_null= (null_bits[null_bit_index / 8] >> (null_bit_index % 8)) & 0x01; if (bitmap_is_set(cols_bitmap, i) == 0) continue; if (!no_fill_output) if (my_b_printf(file, "### @%d=", static_cast(i + 1))) goto err; if (!is_null) { size_t fsize= td->calc_field_size((uint)i, (uchar*) value); if (value + fsize > m_rows_end) { if (!no_fill_output) if (my_b_printf(file, "***Corrupted replication event was detected." " Not printing the value***\n")) goto err; value+= fsize; return 0; } } if (!no_fill_output) { size= log_event_print_value(file, print_event_info, is_null? NULL: value, td->type(i), td->field_metadata(i), typestr, sizeof(typestr)); #ifdef WHEN_FLASHBACK_REVIEW_READY if (need_flashback_review) { String tmp_str, hex_str; IO_CACHE tmp_cache; // Using a tmp IO_CACHE to get the value output open_cached_file(&tmp_cache, NULL, NULL, 0, MYF(MY_WME | MY_NABP)); size= log_event_print_value(&tmp_cache, print_event_info, is_null ? NULL: value, td->type(i), td->field_metadata(i), typestr, sizeof(typestr)); error= copy_event_cache_to_string_and_reinit(&tmp_cache, &review_str); close_cached_file(&tmp_cache); if (unlikely(error)) return 0; switch (td->type(i)) // Converting a string to HEX format { case MYSQL_TYPE_VARCHAR: case MYSQL_TYPE_VAR_STRING: case MYSQL_TYPE_STRING: case MYSQL_TYPE_BLOB: // Avoid write_pos changed to a new area // tmp_str.free(); tmp_str.append(review_str.str + 1, review_str.length - 2); // Removing quotation marks if (hex_str.alloc(tmp_str.length()*2+1)) // If out of memory { fprintf(stderr, "\nError: Out of memory. " "Could not print correct binlog event.\n"); exit(1); } octet2hex((char*) hex_str.ptr(), tmp_str.ptr(), tmp_str.length()); if (my_b_printf(review_sql, ", UNHEX('%s')", hex_str.ptr())) goto err; break; default: tmp_str.free(); if (tmp_str.append(review_str.str, review_str.length) || my_b_printf(review_sql, ", %s", tmp_str.ptr())) goto err; break; } my_free(revieww_str.str); } #endif } else { IO_CACHE tmp_cache; open_cached_file(&tmp_cache, NULL, NULL, 0, MYF(MY_WME | MY_NABP)); size= log_event_print_value(&tmp_cache, print_event_info, is_null ? NULL: value, td->type(i), td->field_metadata(i), typestr, sizeof(typestr)); close_cached_file(&tmp_cache); } if (!size) goto err; if (!is_null) value+= size; if (print_event_info->verbose > 1 && !no_fill_output) { if (my_b_write(file, (uchar*)" /* ", 4) || my_b_printf(file, "%s ", typestr) || my_b_printf(file, "meta=%d nullable=%d is_null=%d ", td->field_metadata(i), td->maybe_null(i), is_null) || my_b_write(file, (uchar*)"*/", 2)) goto err; } if (!no_fill_output) if (my_b_write_byte(file, '\n')) goto err; null_bit_index++; } return value - value0; err: return 0; } /** Exchange the SET part and WHERE part for the Update events. Revert the operations order for the Write and Delete events. And then revert the events order from the last one to the first one. @param[in] print_event_info PRINT_EVENT_INFO @param[in] rows_buff Packed event buff */ void Rows_log_event::change_to_flashback_event(PRINT_EVENT_INFO *print_event_info, uchar *rows_buff, Log_event_type ev_type) { Table_map_log_event *map; table_def *td; DYNAMIC_ARRAY rows_arr; uchar *swap_buff1; uchar *rows_pos= rows_buff + m_rows_before_size; if (!(map= print_event_info->m_table_map.get_table(m_table_id)) || !(td= map->create_table_def())) return; /* If the write rows event contained no values for the AI */ if (((get_general_type_code() == WRITE_ROWS_EVENT) && (m_rows_buf==m_rows_end))) goto end; (void) my_init_dynamic_array(&rows_arr, sizeof(LEX_STRING), 8, 8, MYF(0)); for (uchar *value= m_rows_buf; value < m_rows_end; ) { uchar *start_pos= value; size_t length1= 0; if (!(length1= print_verbose_one_row(NULL, td, print_event_info, &m_cols, value, (const uchar*) "", TRUE))) { fprintf(stderr, "\nError row length: %zu\n", length1); exit(1); } value+= length1; swap_buff1= (uchar *) my_malloc(length1, MYF(0)); if (!swap_buff1) { fprintf(stderr, "\nError: Out of memory. " "Could not exchange to flashback event.\n"); exit(1); } memcpy(swap_buff1, start_pos, length1); // For Update_event, we have the second part size_t length2= 0; if (ev_type == UPDATE_ROWS_EVENT || ev_type == UPDATE_ROWS_EVENT_V1) { if (!(length2= print_verbose_one_row(NULL, td, print_event_info, &m_cols, value, (const uchar*) "", TRUE))) { fprintf(stderr, "\nError row length: %zu\n", length2); exit(1); } value+= length2; void *swap_buff2= my_malloc(length2, MYF(0)); if (!swap_buff2) { fprintf(stderr, "\nError: Out of memory. " "Could not exchange to flashback event.\n"); exit(1); } memcpy(swap_buff2, start_pos + length1, length2); // WHERE part /* Swap SET and WHERE part */ memcpy(start_pos, swap_buff2, length2); memcpy(start_pos + length2, swap_buff1, length1); my_free(swap_buff2); } my_free(swap_buff1); /* Copying one row into a buff, and pushing into the array */ LEX_STRING one_row; one_row.length= length1 + length2; one_row.str= (char *) my_malloc(one_row.length, MYF(0)); memcpy(one_row.str, start_pos, one_row.length); if (one_row.str == NULL || push_dynamic(&rows_arr, (uchar *) &one_row)) { fprintf(stderr, "\nError: Out of memory. " "Could not push flashback event into array.\n"); exit(1); } } /* Copying rows from the end to the begining into event */ for (uint i= rows_arr.elements; i > 0; --i) { LEX_STRING *one_row= dynamic_element(&rows_arr, i - 1, LEX_STRING*); memcpy(rows_pos, (uchar *)one_row->str, one_row->length); rows_pos+= one_row->length; my_free(one_row->str); } delete_dynamic(&rows_arr); end: delete td; } /** Calc length of a packed value of the given SQL type @param[in] ptr Pointer to string @param[in] type Column type @param[in] meta Column meta information @retval - number of bytes scanned from ptr. Except in case of NULL, in which case we return 1 to indicate ok */ static size_t calc_field_event_length(const uchar *ptr, uint type, uint meta) { uint32 length= 0; if (type == MYSQL_TYPE_STRING) { if (meta >= 256) { uint byte0= meta >> 8; uint byte1= meta & 0xFF; if ((byte0 & 0x30) != 0x30) { /* a long CHAR() field: see #37426 */ length= byte1 | (((byte0 & 0x30) ^ 0x30) << 4); type= byte0 | 0x30; } else length = meta & 0xFF; } else length= meta; } switch (type) { case MYSQL_TYPE_LONG: case MYSQL_TYPE_TIMESTAMP: return 4; case MYSQL_TYPE_TINY: case MYSQL_TYPE_YEAR: return 1; case MYSQL_TYPE_SHORT: return 2; case MYSQL_TYPE_INT24: case MYSQL_TYPE_TIME: case MYSQL_TYPE_NEWDATE: case MYSQL_TYPE_DATE: return 3; case MYSQL_TYPE_LONGLONG: case MYSQL_TYPE_DATETIME: return 8; case MYSQL_TYPE_NEWDECIMAL: { uint precision= meta >> 8; uint decimals= meta & 0xFF; uint bin_size= my_decimal_get_binary_size(precision, decimals); return bin_size; } case MYSQL_TYPE_FLOAT: return 4; case MYSQL_TYPE_DOUBLE: return 8; case MYSQL_TYPE_BIT: { /* Meta-data: bit_len, bytes_in_rec, 2 bytes */ uint nbits= ((meta >> 8) * 8) + (meta & 0xFF); length= (nbits + 7) / 8; return length; } case MYSQL_TYPE_TIMESTAMP2: return my_timestamp_binary_length(meta); case MYSQL_TYPE_DATETIME2: return my_datetime_binary_length(meta); case MYSQL_TYPE_TIME2: return my_time_binary_length(meta); case MYSQL_TYPE_ENUM: switch (meta & 0xFF) { case 1: case 2: return (meta & 0xFF); default: /* Unknown ENUM packlen=%d", meta & 0xFF */ return 0; } break; case MYSQL_TYPE_SET: return meta & 0xFF; case MYSQL_TYPE_BLOB: switch (meta) { default: return 0; case 1: return *ptr + 1; case 2: return uint2korr(ptr) + 2; case 3: return uint3korr(ptr) + 3; case 4: return uint4korr(ptr) + 4; } case MYSQL_TYPE_VARCHAR: case MYSQL_TYPE_VAR_STRING: length= meta; /* fall through */ case MYSQL_TYPE_STRING: if (length < 256) return (uint) *ptr + 1; return uint2korr(ptr) + 2; case MYSQL_TYPE_DECIMAL: break; default: break; } return 0; } size_t Rows_log_event::calc_row_event_length(table_def *td, PRINT_EVENT_INFO *print_event_info, MY_BITMAP *cols_bitmap, const uchar *value) { const uchar *value0= value; const uchar *null_bits= value; uint null_bit_index= 0; /* Skip metadata bytes which gives the information about nullabity of master columns. Master writes one bit for each affected column. */ value+= (bitmap_bits_set(cols_bitmap) + 7) / 8; for (uint i= 0; i < (uint)td->size(); i ++) { int is_null; is_null= (null_bits[null_bit_index / 8] >> (null_bit_index % 8)) & 0x01; if (bitmap_is_set(cols_bitmap, i) == 0) continue; if (!is_null) { size_t size; size_t fsize= td->calc_field_size((uint)i, (uchar*) value); if (value + fsize > m_rows_end) { /* Corrupted replication event was detected, skipping entry */ return 0; } if (!(size= calc_field_event_length(value, td->type(i), td->field_metadata(i)))) return 0; value+= size; } null_bit_index++; } return value - value0; } /** Calculate how many rows there are in the event @param[in] file IO cache @param[in] print_event_into Print parameters */ void Rows_log_event::count_row_events(PRINT_EVENT_INFO *print_event_info) { Table_map_log_event *map; table_def *td; uint row_events; Log_event_type general_type_code= get_general_type_code(); switch (general_type_code) { case WRITE_ROWS_EVENT: case DELETE_ROWS_EVENT: row_events= 1; break; case UPDATE_ROWS_EVENT: row_events= 2; break; default: DBUG_ASSERT(0); /* Not possible */ return; } if (!(map= print_event_info->m_table_map.get_table(m_table_id)) || !(td= map->create_table_def())) { /* Row event for unknown table */ return; } for (const uchar *value= m_rows_buf; value < m_rows_end; ) { size_t length; print_event_info->row_events++; /* Print the first image */ if (!(length= calc_row_event_length(td, print_event_info, &m_cols, value))) break; value+= length; DBUG_ASSERT(value <= m_rows_end); /* Print the second image (for UPDATE only) */ if (row_events == 2) { if (!(length= calc_row_event_length(td, print_event_info, &m_cols_ai, value))) break; value+= length; DBUG_ASSERT(value <= m_rows_end); } } delete td; } /** Print a row event into IO cache in human readable form (in SQL format) @param[in] file IO cache @param[in] print_event_into Print parameters */ bool Rows_log_event::print_verbose(IO_CACHE *file, PRINT_EVENT_INFO *print_event_info) { Table_map_log_event *map; table_def *td= 0; const char *sql_command, *sql_clause1, *sql_clause2; const char *sql_command_short __attribute__((unused)); Log_event_type general_type_code= get_general_type_code(); #ifdef WHEN_FLASHBACK_REVIEW_READY IO_CACHE *review_sql= &print_event_info->review_sql_cache; #endif if (m_extra_row_data) { uint8 extra_data_len= m_extra_row_data[EXTRA_ROW_INFO_LEN_OFFSET]; uint8 extra_payload_len= extra_data_len - EXTRA_ROW_INFO_HDR_BYTES; assert(extra_data_len >= EXTRA_ROW_INFO_HDR_BYTES); if (my_b_printf(file, "### Extra row data format: %u, len: %u :", m_extra_row_data[EXTRA_ROW_INFO_FORMAT_OFFSET], extra_payload_len)) goto err; if (extra_payload_len) { /* Buffer for hex view of string, including '0x' prefix, 2 hex chars / byte and trailing 0 */ const int buff_len= 2 + (256 * 2) + 1; char buff[buff_len]; str_to_hex(buff, (const char*) &m_extra_row_data[EXTRA_ROW_INFO_HDR_BYTES], extra_payload_len); if (my_b_printf(file, "%s", buff)) goto err; } if (my_b_printf(file, "\n")) goto err; } switch (general_type_code) { case WRITE_ROWS_EVENT: sql_command= "INSERT INTO"; sql_clause1= "### SET\n"; sql_clause2= NULL; sql_command_short= "I"; break; case DELETE_ROWS_EVENT: sql_command= "DELETE FROM"; sql_clause1= "### WHERE\n"; sql_clause2= NULL; sql_command_short= "D"; break; case UPDATE_ROWS_EVENT: sql_command= "UPDATE"; sql_clause1= "### WHERE\n"; sql_clause2= "### SET\n"; sql_command_short= "U"; break; default: sql_command= sql_clause1= sql_clause2= NULL; sql_command_short= ""; DBUG_ASSERT(0); /* Not possible */ } if (!(map= print_event_info->m_table_map.get_table(m_table_id)) || !(td= map->create_table_def())) { return (my_b_printf(file, "### Row event for unknown table #%lu", (ulong) m_table_id)); } /* If the write rows event contained no values for the AI */ if (((general_type_code == WRITE_ROWS_EVENT) && (m_rows_buf==m_rows_end))) { if (my_b_printf(file, "### INSERT INTO %`s.%`s VALUES ()\n", map->get_db_name(), map->get_table_name())) goto err; goto end; } for (const uchar *value= m_rows_buf; value < m_rows_end; ) { size_t length; print_event_info->row_events++; if (my_b_printf(file, "### %s %`s.%`s\n", sql_command, map->get_db_name(), map->get_table_name())) goto err; #ifdef WHEN_FLASHBACK_REVIEW_READY if (need_flashback_review) if (my_b_printf(review_sql, "\nINSERT INTO `%s`.`%s` VALUES ('%s'", map->get_review_dbname(), map->get_review_tablename(), sql_command_short)) goto err; #endif /* Print the first image */ if (!(length= print_verbose_one_row(file, td, print_event_info, &m_cols, value, (const uchar*) sql_clause1))) goto err; value+= length; /* Print the second image (for UPDATE only) */ if (sql_clause2) { if (!(length= print_verbose_one_row(file, td, print_event_info, &m_cols_ai, value, (const uchar*) sql_clause2))) goto err; value+= length; } #ifdef WHEN_FLASHBACK_REVIEW_READY else { if (need_flashback_review) for (size_t i= 0; i < td->size(); i ++) if (my_b_printf(review_sql, ", NULL")) goto err; } if (need_flashback_review) if (my_b_printf(review_sql, ")%s\n", print_event_info->delimiter)) goto err; #endif } end: delete td; return 0; err: delete td; return 1; } void free_table_map_log_event(Table_map_log_event *event) { delete event; } /** Encode the event, optionally per 'do_print_encoded' arg store the result into the argument cache; optionally per event_info's 'verbose' print into the cache a verbose representation of the event. Note, no extra wrapping is done to the being io-cached data, like to producing a BINLOG query. It's left for a routine that extracts from the cache. @param file pointer to IO_CACHE @param print_event_info pointer to print_event_info specializing what out of and how to print the event @param do_print_encoded whether to store base64-encoded event into @file. */ bool Log_event::print_base64(IO_CACHE* file, PRINT_EVENT_INFO* print_event_info, bool do_print_encoded) { uchar *ptr= (uchar *)temp_buf; uint32 size= uint4korr(ptr + EVENT_LEN_OFFSET); DBUG_ENTER("Log_event::print_base64"); if (is_flashback) { uint tmp_size= size; Rows_log_event *ev= NULL; Log_event_type ev_type = (enum Log_event_type) ptr[EVENT_TYPE_OFFSET]; if (checksum_alg != BINLOG_CHECKSUM_ALG_UNDEF && checksum_alg != BINLOG_CHECKSUM_ALG_OFF) tmp_size-= BINLOG_CHECKSUM_LEN; // checksum is displayed through the header switch (ev_type) { case WRITE_ROWS_EVENT: ptr[EVENT_TYPE_OFFSET]= DELETE_ROWS_EVENT; ev= new Delete_rows_log_event((const char*) ptr, tmp_size, glob_description_event); ev->change_to_flashback_event(print_event_info, ptr, ev_type); break; case WRITE_ROWS_EVENT_V1: ptr[EVENT_TYPE_OFFSET]= DELETE_ROWS_EVENT_V1; ev= new Delete_rows_log_event((const char*) ptr, tmp_size, glob_description_event); ev->change_to_flashback_event(print_event_info, ptr, ev_type); break; case DELETE_ROWS_EVENT: ptr[EVENT_TYPE_OFFSET]= WRITE_ROWS_EVENT; ev= new Write_rows_log_event((const char*) ptr, tmp_size, glob_description_event); ev->change_to_flashback_event(print_event_info, ptr, ev_type); break; case DELETE_ROWS_EVENT_V1: ptr[EVENT_TYPE_OFFSET]= WRITE_ROWS_EVENT_V1; ev= new Write_rows_log_event((const char*) ptr, tmp_size, glob_description_event); ev->change_to_flashback_event(print_event_info, ptr, ev_type); break; case UPDATE_ROWS_EVENT: case UPDATE_ROWS_EVENT_V1: ev= new Update_rows_log_event((const char*) ptr, tmp_size, glob_description_event); ev->change_to_flashback_event(print_event_info, ptr, ev_type); break; default: break; } delete ev; } if (do_print_encoded) { size_t const tmp_str_sz= my_base64_needed_encoded_length((int) size); char *tmp_str; if (!(tmp_str= (char *) my_malloc(tmp_str_sz, MYF(MY_WME)))) goto err; if (my_base64_encode(ptr, (size_t) size, tmp_str)) { DBUG_ASSERT(0); } my_b_printf(file, "%s\n", tmp_str); my_free(tmp_str); } #ifdef WHEN_FLASHBACK_REVIEW_READY if (print_event_info->verbose || print_event_info->print_row_count || need_flashback_review) #else // Flashback need the table_map to parse the event if (print_event_info->verbose || print_event_info->print_row_count || is_flashback) #endif { Rows_log_event *ev= NULL; Log_event_type et= (Log_event_type) ptr[EVENT_TYPE_OFFSET]; if (checksum_alg != BINLOG_CHECKSUM_ALG_UNDEF && checksum_alg != BINLOG_CHECKSUM_ALG_OFF) size-= BINLOG_CHECKSUM_LEN; // checksum is displayed through the header switch (et) { case TABLE_MAP_EVENT: { Table_map_log_event *map; map= new Table_map_log_event((const char*) ptr, size, glob_description_event); #ifdef WHEN_FLASHBACK_REVIEW_READY if (need_flashback_review) { map->set_review_dbname(m_review_dbname.ptr()); map->set_review_tablename(m_review_tablename.ptr()); } #endif print_event_info->m_table_map.set_table(map->get_table_id(), map); break; } case WRITE_ROWS_EVENT: case WRITE_ROWS_EVENT_V1: { ev= new Write_rows_log_event((const char*) ptr, size, glob_description_event); break; } case DELETE_ROWS_EVENT: case DELETE_ROWS_EVENT_V1: { ev= new Delete_rows_log_event((const char*) ptr, size, glob_description_event); break; } case UPDATE_ROWS_EVENT: case UPDATE_ROWS_EVENT_V1: { ev= new Update_rows_log_event((const char*) ptr, size, glob_description_event); break; } case WRITE_ROWS_COMPRESSED_EVENT: case WRITE_ROWS_COMPRESSED_EVENT_V1: { ev= new Write_rows_compressed_log_event((const char*) ptr, size, glob_description_event); break; } case UPDATE_ROWS_COMPRESSED_EVENT: case UPDATE_ROWS_COMPRESSED_EVENT_V1: { ev= new Update_rows_compressed_log_event((const char*) ptr, size, glob_description_event); break; } case DELETE_ROWS_COMPRESSED_EVENT: case DELETE_ROWS_COMPRESSED_EVENT_V1: { ev= new Delete_rows_compressed_log_event((const char*) ptr, size, glob_description_event); break; } default: break; } if (ev) { bool error= 0; #ifdef WHEN_FLASHBACK_REVIEW_READY ev->need_flashback_review= need_flashback_review; if (print_event_info->verbose) { if (ev->print_verbose(&print_event_info->tail_cache, print_event_info)) goto err; } else { IO_CACHE tmp_cache; if (open_cached_file(&tmp_cache, NULL, NULL, 0, MYF(MY_WME | MY_NABP))) { delete ev; goto err; } error= ev->print_verbose(&tmp_cache, print_event_info); close_cached_file(&tmp_cache); if (unlikely(error)) { delete ev; goto err; } } #else if (print_event_info->verbose) error= ev->print_verbose(&print_event_info->tail_cache, print_event_info); else ev->count_row_events(print_event_info); #endif delete ev; if (unlikely(error)) goto err; } } DBUG_RETURN(0); err: DBUG_RETURN(1); } /* Log_event::print_timestamp() */ bool Log_event::print_timestamp(IO_CACHE* file, time_t* ts) { struct tm *res; time_t my_when= when; DBUG_ENTER("Log_event::print_timestamp"); if (!ts) ts = &my_when; res=localtime(ts); DBUG_RETURN(my_b_printf(file,"%02d%02d%02d %2d:%02d:%02d", res->tm_year % 100, res->tm_mon+1, res->tm_mday, res->tm_hour, res->tm_min, res->tm_sec)); } #endif /* MYSQL_CLIENT */ #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) inline Log_event::enum_skip_reason Log_event::continue_group(rpl_group_info *rgi) { if (rgi->rli->slave_skip_counter == 1) return Log_event::EVENT_SKIP_IGNORE; return Log_event::do_shall_skip(rgi); } #endif /************************************************************************** Query_log_event methods **************************************************************************/ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /** This (which is used only for SHOW BINLOG EVENTS) could be updated to print SET @@session_var=. But this is not urgent, as SHOW BINLOG EVENTS is only an information, it does not produce suitable queries to replay (for example it does not print LOAD DATA INFILE). @todo show the catalog ?? */ void Query_log_event::pack_info(Protocol *protocol) { // TODO: show the catalog ?? char buf_mem[1024]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); buf.real_alloc(9 + db_len + q_len); if (!(flags & LOG_EVENT_SUPPRESS_USE_F) && db && db_len) { buf.append(STRING_WITH_LEN("use ")); append_identifier(protocol->thd, &buf, db, db_len); buf.append(STRING_WITH_LEN("; ")); } if (query && q_len) buf.append(query, q_len); protocol->store(&buf); } #endif #ifndef MYSQL_CLIENT /** Utility function for the next method (Query_log_event::write()) . */ static void store_str_with_code_and_len(uchar **dst, const char *src, uint len, uint code) { /* only 1 byte to store the length of catalog, so it should not surpass 255 */ DBUG_ASSERT(len <= 255); DBUG_ASSERT(src); *((*dst)++)= (uchar) code; *((*dst)++)= (uchar) len; bmove(*dst, src, len); (*dst)+= len; } /** Query_log_event::write(). @note In this event we have to modify the header to have the correct EVENT_LEN_OFFSET as we don't yet know how many status variables we will print! */ bool Query_log_event::write() { uchar buf[QUERY_HEADER_LEN + MAX_SIZE_LOG_EVENT_STATUS]; uchar *start, *start_of_status; ulong event_length; if (!query) return 1; // Something wrong with event /* We want to store the thread id: (- as an information for the user when he reads the binlog) - if the query uses temporary table: for the slave SQL thread to know to which master connection the temp table belongs. Now imagine we (write()) are called by the slave SQL thread (we are logging a query executed by this thread; the slave runs with --log-slave-updates). Then this query will be logged with thread_id=the_thread_id_of_the_SQL_thread. Imagine that 2 temp tables of the same name were created simultaneously on the master (in the master binlog you have CREATE TEMPORARY TABLE t; (thread 1) CREATE TEMPORARY TABLE t; (thread 2) ...) then in the slave's binlog there will be CREATE TEMPORARY TABLE t; (thread_id_of_the_slave_SQL_thread) CREATE TEMPORARY TABLE t; (thread_id_of_the_slave_SQL_thread) which is bad (same thread id!). To avoid this, we log the thread's thread id EXCEPT for the SQL slave thread for which we log the original (master's) thread id. Now this moves the bug: what happens if the thread id on the master was 10 and when the slave replicates the query, a connection number 10 is opened by a normal client on the slave, and updates a temp table of the same name? We get a problem again. To avoid this, in the handling of temp tables (sql_base.cc) we use thread_id AND server_id. TODO when this is merged into 4.1: in 4.1, slave_proxy_id has been renamed to pseudo_thread_id and is a session variable: that's to make mysqlbinlog work with temp tables. We probably need to introduce SET PSEUDO_SERVER_ID for mysqlbinlog in 4.1. mysqlbinlog would print: SET PSEUDO_SERVER_ID= SET PSEUDO_THREAD_ID= for each query using temp tables. */ int4store(buf + Q_THREAD_ID_OFFSET, slave_proxy_id); int4store(buf + Q_EXEC_TIME_OFFSET, exec_time); buf[Q_DB_LEN_OFFSET] = (char) db_len; int2store(buf + Q_ERR_CODE_OFFSET, error_code); /* You MUST always write status vars in increasing order of code. This guarantees that a slightly older slave will be able to parse those he knows. */ start_of_status= start= buf+QUERY_HEADER_LEN; if (flags2_inited) { *start++= Q_FLAGS2_CODE; int4store(start, flags2); start+= 4; } if (sql_mode_inited) { *start++= Q_SQL_MODE_CODE; int8store(start, (ulonglong)sql_mode); start+= 8; } if (catalog_len) // i.e. this var is inited (false for 4.0 events) { store_str_with_code_and_len(&start, catalog, catalog_len, Q_CATALOG_NZ_CODE); /* In 5.0.x where x<4 masters we used to store the end zero here. This was a waste of one byte so we don't do it in x>=4 masters. We change code to Q_CATALOG_NZ_CODE, because re-using the old code would make x<4 slaves of this x>=4 master segfault (expecting a zero when there is none). Remaining compatibility problems are: the older slave will not find the catalog; but it is will not crash, and it's not an issue that it does not find the catalog as catalogs were not used in these older MySQL versions (we store it in binlog and read it from relay log but do nothing useful with it). What is an issue is that the older slave will stop processing the Q_* blocks (and jumps to the db/query) as soon as it sees unknown Q_CATALOG_NZ_CODE; so it will not be able to read Q_AUTO_INCREMENT*, Q_CHARSET and so replication will fail silently in various ways. Documented that you should not mix alpha/beta versions if they are not exactly the same version, with example of 5.0.3->5.0.2 and 5.0.4->5.0.3. If replication is from older to new, the new will recognize Q_CATALOG_CODE and have no problem. */ } if (auto_increment_increment != 1 || auto_increment_offset != 1) { *start++= Q_AUTO_INCREMENT; int2store(start, auto_increment_increment); int2store(start+2, auto_increment_offset); start+= 4; } if (charset_inited) { *start++= Q_CHARSET_CODE; memcpy(start, charset, 6); start+= 6; } if (time_zone_len) { /* In the TZ sys table, column Name is of length 64 so this should be ok */ DBUG_ASSERT(time_zone_len <= MAX_TIME_ZONE_NAME_LENGTH); store_str_with_code_and_len(&start, time_zone_str, time_zone_len, Q_TIME_ZONE_CODE); } if (lc_time_names_number) { DBUG_ASSERT(lc_time_names_number <= 0xFFFF); *start++= Q_LC_TIME_NAMES_CODE; int2store(start, lc_time_names_number); start+= 2; } if (charset_database_number) { DBUG_ASSERT(charset_database_number <= 0xFFFF); *start++= Q_CHARSET_DATABASE_CODE; int2store(start, charset_database_number); start+= 2; } if (table_map_for_update) { *start++= Q_TABLE_MAP_FOR_UPDATE_CODE; int8store(start, table_map_for_update); start+= 8; } if (master_data_written != 0) { /* Q_MASTER_DATA_WRITTEN_CODE only exists in relay logs where the master has binlog_version<4 and the slave has binlog_version=4. See comment for master_data_written in log_event.h for details. */ *start++= Q_MASTER_DATA_WRITTEN_CODE; int4store(start, master_data_written); start+= 4; } if (thd && thd->need_binlog_invoker()) { LEX_CSTRING user; LEX_CSTRING host; memset(&user, 0, sizeof(user)); memset(&host, 0, sizeof(host)); if (thd->slave_thread && thd->has_invoker()) { /* user will be null, if master is older than this patch */ user= thd->get_invoker_user(); host= thd->get_invoker_host(); } else { Security_context *ctx= thd->security_ctx; if (thd->need_binlog_invoker() == THD::INVOKER_USER) { user.str= ctx->priv_user; host.str= ctx->priv_host; host.length= strlen(host.str); } else { user.str= ctx->priv_role; host= empty_clex_str; } user.length= strlen(user.str); } if (user.length > 0) { *start++= Q_INVOKER; /* Store user length and user. The max length of use is 16, so 1 byte is enough to store the user's length. */ *start++= (uchar)user.length; memcpy(start, user.str, user.length); start+= user.length; /* Store host length and host. The max length of host is 60, so 1 byte is enough to store the host's length. */ *start++= (uchar)host.length; memcpy(start, host.str, host.length); start+= host.length; } } if (thd && thd->query_start_sec_part_used) { *start++= Q_HRNOW; get_time(); int3store(start, when_sec_part); start+= 3; } /* NOTE: When adding new status vars, please don't forget to update the MAX_SIZE_LOG_EVENT_STATUS in log_event.h and update the function code_name() in this file. Here there could be code like if (command-line-option-which-says-"log_this_variable" && inited) { *start++= Q_THIS_VARIABLE_CODE; int4store(start, this_variable); start+= 4; } */ /* Store length of status variables */ status_vars_len= (uint) (start-start_of_status); DBUG_ASSERT(status_vars_len <= MAX_SIZE_LOG_EVENT_STATUS); int2store(buf + Q_STATUS_VARS_LEN_OFFSET, status_vars_len); /* Calculate length of whole event The "1" below is the \0 in the db's length */ event_length= (uint) (start-buf) + get_post_header_size_for_derived() + db_len + 1 + q_len; return write_header(event_length) || write_data(buf, QUERY_HEADER_LEN) || write_post_header_for_derived() || write_data(start_of_status, (uint) (start-start_of_status)) || write_data(safe_str(db), db_len + 1) || write_data(query, q_len) || write_footer(); } bool Query_compressed_log_event::write() { const char *query_tmp = query; uint32 q_len_tmp = q_len; uint32 alloc_size; bool ret = true; q_len = alloc_size = binlog_get_compress_len(q_len); query = (char *)my_safe_alloca(alloc_size); if(query && !binlog_buf_compress(query_tmp, (char *)query, q_len_tmp, &q_len)) { ret = Query_log_event::write(); } my_safe_afree((void *)query, alloc_size); query = query_tmp; q_len = q_len_tmp; return ret; } /** The simplest constructor that could possibly work. This is used for creating static objects that have a special meaning and are invisible to the log. */ Query_log_event::Query_log_event() :Log_event(), data_buf(0) { memset(&user, 0, sizeof(user)); memset(&host, 0, sizeof(host)); } /* SYNOPSIS Query_log_event::Query_log_event() thd_arg - thread handle query_arg - array of char representing the query query_length - size of the `query_arg' array using_trans - there is a modified transactional table direct - Don't cache statement suppress_use - suppress the generation of 'USE' statements errcode - the error code of the query DESCRIPTION Creates an event for binlogging The value for `errcode' should be supplied by caller. */ Query_log_event::Query_log_event(THD* thd_arg, const char* query_arg, size_t query_length, bool using_trans, bool direct, bool suppress_use, int errcode) :Log_event(thd_arg, (thd_arg->thread_specific_used ? LOG_EVENT_THREAD_SPECIFIC_F : 0) | (suppress_use ? LOG_EVENT_SUPPRESS_USE_F : 0), using_trans), data_buf(0), query(query_arg), catalog(thd_arg->catalog), db(thd_arg->db.str), q_len((uint32) query_length), thread_id(thd_arg->thread_id), /* save the original thread id; we already know the server id */ slave_proxy_id((ulong)thd_arg->variables.pseudo_thread_id), flags2_inited(1), sql_mode_inited(1), charset_inited(1), sql_mode(thd_arg->variables.sql_mode), auto_increment_increment(thd_arg->variables.auto_increment_increment), auto_increment_offset(thd_arg->variables.auto_increment_offset), lc_time_names_number(thd_arg->variables.lc_time_names->number), charset_database_number(0), table_map_for_update((ulonglong)thd_arg->table_map_for_update), master_data_written(0) { time_t end_time; #ifdef WITH_WSREP /* If Query_log_event will contain non trans keyword (not BEGIN, COMMIT, SAVEPOINT or ROLLBACK) we disable PA for this transaction. Note that here WSREP(thd) might not be true e.g. when wsrep_shcema is created we create tables with thd->variables.wsrep_on=false to avoid replicating wsrep_schema tables to other nodes. */ if (WSREP_ON && !is_trans_keyword()) { thd->wsrep_PA_safe= false; } #endif /* WITH_WSREP */ memset(&user, 0, sizeof(user)); memset(&host, 0, sizeof(host)); error_code= errcode; end_time= my_time(0); exec_time = (ulong) (end_time - thd_arg->start_time); /** @todo this means that if we have no catalog, then it is replicated as an existing catalog of length zero. is that safe? /sven */ catalog_len = (catalog) ? (uint32) strlen(catalog) : 0; /* status_vars_len is set just before writing the event */ db_len = (db) ? (uint32) strlen(db) : 0; if (thd_arg->variables.collation_database != thd_arg->db_charset) charset_database_number= thd_arg->variables.collation_database->number; /* We only replicate over the bits of flags2 that we need: the rest are masked out by "& OPTIONS_WRITTEN_TO_BINLOG". We also force AUTOCOMMIT=1. Rationale (cf. BUG#29288): After fixing BUG#26395, we always write BEGIN and COMMIT around all transactions (even single statements in autocommit mode). This is so that replication from non-transactional to transactional table and error recovery from XA to non-XA table should work as expected. The BEGIN/COMMIT are added in log.cc. However, there is one exception: MyISAM bypasses log.cc and writes directly to the binlog. So if autocommit is off, master has MyISAM, and slave has a transactional engine, then the slave will just see one long never-ending transaction. The only way to bypass explicit BEGIN/COMMIT in the binlog is by using a non-transactional table. So setting AUTOCOMMIT=1 will make this work as expected. Note: explicitly replicate AUTOCOMMIT=1 from master. We do not assume AUTOCOMMIT=1 on slave; the slave still reads the state of the autocommit flag as written by the master to the binlog. This behavior may change after WL#4162 has been implemented. */ flags2= (uint32) (thd_arg->variables.option_bits & (OPTIONS_WRITTEN_TO_BIN_LOG & ~OPTION_NOT_AUTOCOMMIT)); DBUG_ASSERT(thd_arg->variables.character_set_client->number < 256*256); DBUG_ASSERT(thd_arg->variables.collation_connection->number < 256*256); DBUG_ASSERT(thd_arg->variables.collation_server->number < 256*256); DBUG_ASSERT(thd_arg->variables.character_set_client->mbminlen == 1); int2store(charset, thd_arg->variables.character_set_client->number); int2store(charset+2, thd_arg->variables.collation_connection->number); int2store(charset+4, thd_arg->variables.collation_server->number); if (thd_arg->time_zone_used) { /* Note that our event becomes dependent on the Time_zone object representing the time zone. Fortunately such objects are never deleted or changed during mysqld's lifetime. */ time_zone_len= thd_arg->variables.time_zone->get_name()->length(); time_zone_str= thd_arg->variables.time_zone->get_name()->ptr(); } else time_zone_len= 0; LEX *lex= thd->lex; /* Defines that the statement will be written directly to the binary log without being wrapped by a BEGIN...COMMIT. Otherwise, the statement will be written to either the trx-cache or stmt-cache. Note that a cache will not be used if the parameter direct is TRUE. */ bool use_cache= FALSE; /* TRUE defines that the trx-cache must be used and by consequence the use_cache is TRUE. Note that a cache will not be used if the parameter direct is TRUE. */ bool trx_cache= FALSE; cache_type= Log_event::EVENT_INVALID_CACHE; if (!direct) { switch (lex->sql_command) { case SQLCOM_DROP_TABLE: case SQLCOM_DROP_SEQUENCE: use_cache= (lex->tmp_table() && thd->in_multi_stmt_transaction_mode()); break; case SQLCOM_CREATE_TABLE: case SQLCOM_CREATE_SEQUENCE: /* If we are using CREATE ... SELECT or if we are a slave executing BEGIN...COMMIT (generated by CREATE...SELECT) we have to use the transactional cache to ensure we don't calculate any checksum for the CREATE part. */ trx_cache= (lex->first_select_lex()->item_list.elements && thd->is_current_stmt_binlog_format_row()) || (thd->variables.option_bits & OPTION_GTID_BEGIN); use_cache= (lex->tmp_table() && thd->in_multi_stmt_transaction_mode()) || trx_cache; break; case SQLCOM_SET_OPTION: if (lex->autocommit) use_cache= trx_cache= FALSE; else use_cache= TRUE; break; case SQLCOM_RELEASE_SAVEPOINT: case SQLCOM_ROLLBACK_TO_SAVEPOINT: case SQLCOM_SAVEPOINT: use_cache= trx_cache= TRUE; break; default: use_cache= sqlcom_can_generate_row_events(thd); break; } } if (!use_cache || direct) { cache_type= Log_event::EVENT_NO_CACHE; } else if (using_trans || trx_cache || stmt_has_updated_trans_table(thd) || thd->lex->is_mixed_stmt_unsafe(thd->in_multi_stmt_transaction_mode(), thd->variables.binlog_direct_non_trans_update, trans_has_updated_trans_table(thd), thd->tx_isolation)) cache_type= Log_event::EVENT_TRANSACTIONAL_CACHE; else cache_type= Log_event::EVENT_STMT_CACHE; DBUG_ASSERT(cache_type != Log_event::EVENT_INVALID_CACHE); DBUG_PRINT("info",("Query_log_event has flags2: %lu sql_mode: %llu cache_tye: %d", (ulong) flags2, sql_mode, cache_type)); } Query_compressed_log_event::Query_compressed_log_event(THD* thd_arg, const char* query_arg, ulong query_length, bool using_trans, bool direct, bool suppress_use, int errcode) :Query_log_event(thd_arg, query_arg, query_length, using_trans, direct, suppress_use, errcode), query_buf(0) { } #endif /* MYSQL_CLIENT */ /* 2 utility functions for the next method */ /** Read a string with length from memory. This function reads the string-with-length stored at src and extract the length into *len and a pointer to the start of the string into *dst. The string can then be copied using memcpy() with the number of bytes given in *len. @param src Pointer to variable holding a pointer to the memory to read the string from. @param dst Pointer to variable holding a pointer where the actual string starts. Starting from this position, the string can be copied using @c memcpy(). @param len Pointer to variable where the length will be stored. @param end One-past-the-end of the memory where the string is stored. @return Zero if the entire string can be copied successfully, @c UINT_MAX if the length could not be read from memory (that is, if *src >= end), otherwise the number of bytes that are missing to read the full string, which happends *dst + *len >= end. */ static int get_str_len_and_pointer(const Log_event::Byte **src, const char **dst, uint *len, const Log_event::Byte *end) { if (*src >= end) return -1; // Will be UINT_MAX in two-complement arithmetic uint length= **src; if (length > 0) { if (*src + length >= end) return (int)(*src + length - end + 1); // Number of bytes missing *dst= (char *)*src + 1; // Will be copied later } *len= length; *src+= length + 1; return 0; } static void copy_str_and_move(const char **src, Log_event::Byte **dst, size_t len) { memcpy(*dst, *src, len); *src= (const char *)*dst; (*dst)+= len; *(*dst)++= 0; } #ifndef DBUG_OFF static char const * code_name(int code) { static char buf[255]; switch (code) { case Q_FLAGS2_CODE: return "Q_FLAGS2_CODE"; case Q_SQL_MODE_CODE: return "Q_SQL_MODE_CODE"; case Q_CATALOG_CODE: return "Q_CATALOG_CODE"; case Q_AUTO_INCREMENT: return "Q_AUTO_INCREMENT"; case Q_CHARSET_CODE: return "Q_CHARSET_CODE"; case Q_TIME_ZONE_CODE: return "Q_TIME_ZONE_CODE"; case Q_CATALOG_NZ_CODE: return "Q_CATALOG_NZ_CODE"; case Q_LC_TIME_NAMES_CODE: return "Q_LC_TIME_NAMES_CODE"; case Q_CHARSET_DATABASE_CODE: return "Q_CHARSET_DATABASE_CODE"; case Q_TABLE_MAP_FOR_UPDATE_CODE: return "Q_TABLE_MAP_FOR_UPDATE_CODE"; case Q_MASTER_DATA_WRITTEN_CODE: return "Q_MASTER_DATA_WRITTEN_CODE"; case Q_HRNOW: return "Q_HRNOW"; } sprintf(buf, "CODE#%d", code); return buf; } #endif #define VALIDATE_BYTES_READ(CUR_POS, START, EVENT_LEN) \ do { \ uchar *cur_pos= (uchar *)CUR_POS; \ uchar *start= (uchar *)START; \ uint len= EVENT_LEN; \ uint bytes_read= (uint)(cur_pos - start); \ DBUG_PRINT("info", ("Bytes read: %u event_len:%u.\n",\ bytes_read, len)); \ if (bytes_read >= len) \ DBUG_VOID_RETURN; \ } while (0) /** Macro to check that there is enough space to read from memory. @param PTR Pointer to memory @param END End of memory @param CNT Number of bytes that should be read. */ #define CHECK_SPACE(PTR,END,CNT) \ do { \ DBUG_PRINT("info", ("Read %s", code_name(pos[-1]))); \ if ((PTR) + (CNT) > (END)) { \ DBUG_PRINT("info", ("query= 0")); \ query= 0; \ DBUG_VOID_RETURN; \ } \ } while (0) /** This is used by the SQL slave thread to prepare the event before execution. */ Query_log_event::Query_log_event(const char* buf, uint event_len, const Format_description_log_event *description_event, Log_event_type event_type) :Log_event(buf, description_event), data_buf(0), query(NullS), db(NullS), catalog_len(0), status_vars_len(0), flags2_inited(0), sql_mode_inited(0), charset_inited(0), auto_increment_increment(1), auto_increment_offset(1), time_zone_len(0), lc_time_names_number(0), charset_database_number(0), table_map_for_update(0), master_data_written(0) { ulong data_len; uint32 tmp; uint8 common_header_len, post_header_len; Log_event::Byte *start; const Log_event::Byte *end; bool catalog_nz= 1; DBUG_ENTER("Query_log_event::Query_log_event(char*,...)"); memset(&user, 0, sizeof(user)); memset(&host, 0, sizeof(host)); common_header_len= description_event->common_header_len; post_header_len= description_event->post_header_len[event_type-1]; DBUG_PRINT("info",("event_len: %u common_header_len: %d post_header_len: %d", event_len, common_header_len, post_header_len)); /* We test if the event's length is sensible, and if so we compute data_len. We cannot rely on QUERY_HEADER_LEN here as it would not be format-tolerant. We use QUERY_HEADER_MINIMAL_LEN which is the same for 3.23, 4.0 & 5.0. */ if (event_len < (uint)(common_header_len + post_header_len)) DBUG_VOID_RETURN; data_len = event_len - (common_header_len + post_header_len); buf+= common_header_len; thread_id = slave_proxy_id = uint4korr(buf + Q_THREAD_ID_OFFSET); exec_time = uint4korr(buf + Q_EXEC_TIME_OFFSET); db_len = (uchar)buf[Q_DB_LEN_OFFSET]; // TODO: add a check of all *_len vars error_code = uint2korr(buf + Q_ERR_CODE_OFFSET); /* 5.0 format starts here. Depending on the format, we may or not have affected/warnings etc The remnent post-header to be parsed has length: */ tmp= post_header_len - QUERY_HEADER_MINIMAL_LEN; if (tmp) { status_vars_len= uint2korr(buf + Q_STATUS_VARS_LEN_OFFSET); /* Check if status variable length is corrupt and will lead to very wrong data. We could be even more strict and require data_len to be even bigger, but this will suffice to catch most corruption errors that can lead to a crash. */ if (status_vars_len > MY_MIN(data_len, MAX_SIZE_LOG_EVENT_STATUS)) { DBUG_PRINT("info", ("status_vars_len (%u) > data_len (%lu); query= 0", status_vars_len, data_len)); query= 0; DBUG_VOID_RETURN; } data_len-= status_vars_len; DBUG_PRINT("info", ("Query_log_event has status_vars_len: %u", (uint) status_vars_len)); tmp-= 2; } else { /* server version < 5.0 / binlog_version < 4 master's event is relay-logged with storing the original size of the event in Q_MASTER_DATA_WRITTEN_CODE status variable. The size is to be restored at reading Q_MASTER_DATA_WRITTEN_CODE-marked event from the relay log. */ DBUG_ASSERT(description_event->binlog_version < 4); master_data_written= (uint32)data_written; } /* We have parsed everything we know in the post header for QUERY_EVENT, the rest of post header is either comes from older version MySQL or dedicated to derived events (e.g. Execute_load_query...) */ /* variable-part: the status vars; only in MySQL 5.0 */ start= (Log_event::Byte*) (buf+post_header_len); end= (const Log_event::Byte*) (start+status_vars_len); for (const Log_event::Byte* pos= start; pos < end;) { switch (*pos++) { case Q_FLAGS2_CODE: CHECK_SPACE(pos, end, 4); flags2_inited= 1; flags2= uint4korr(pos); DBUG_PRINT("info",("In Query_log_event, read flags2: %lu", (ulong) flags2)); pos+= 4; break; case Q_SQL_MODE_CODE: { CHECK_SPACE(pos, end, 8); sql_mode_inited= 1; sql_mode= (sql_mode_t) uint8korr(pos); DBUG_PRINT("info",("In Query_log_event, read sql_mode: %llu", sql_mode)); pos+= 8; break; } case Q_CATALOG_NZ_CODE: DBUG_PRINT("info", ("case Q_CATALOG_NZ_CODE; pos:%p; end:%p", pos, end)); if (get_str_len_and_pointer(&pos, &catalog, &catalog_len, end)) { DBUG_PRINT("info", ("query= 0")); query= 0; DBUG_VOID_RETURN; } break; case Q_AUTO_INCREMENT: CHECK_SPACE(pos, end, 4); auto_increment_increment= uint2korr(pos); auto_increment_offset= uint2korr(pos+2); pos+= 4; break; case Q_CHARSET_CODE: { CHECK_SPACE(pos, end, 6); charset_inited= 1; memcpy(charset, pos, 6); pos+= 6; break; } case Q_TIME_ZONE_CODE: { if (get_str_len_and_pointer(&pos, &time_zone_str, &time_zone_len, end)) { DBUG_PRINT("info", ("Q_TIME_ZONE_CODE: query= 0")); query= 0; DBUG_VOID_RETURN; } break; } case Q_CATALOG_CODE: /* for 5.0.x where 0<=x<=3 masters */ CHECK_SPACE(pos, end, 1); if ((catalog_len= *pos)) catalog= (char*) pos+1; // Will be copied later CHECK_SPACE(pos, end, catalog_len + 2); pos+= catalog_len+2; // leap over end 0 catalog_nz= 0; // catalog has end 0 in event break; case Q_LC_TIME_NAMES_CODE: CHECK_SPACE(pos, end, 2); lc_time_names_number= uint2korr(pos); pos+= 2; break; case Q_CHARSET_DATABASE_CODE: CHECK_SPACE(pos, end, 2); charset_database_number= uint2korr(pos); pos+= 2; break; case Q_TABLE_MAP_FOR_UPDATE_CODE: CHECK_SPACE(pos, end, 8); table_map_for_update= uint8korr(pos); pos+= 8; break; case Q_MASTER_DATA_WRITTEN_CODE: CHECK_SPACE(pos, end, 4); data_written= master_data_written= uint4korr(pos); pos+= 4; break; case Q_INVOKER: { CHECK_SPACE(pos, end, 1); user.length= *pos++; CHECK_SPACE(pos, end, user.length); user.str= (char *)pos; pos+= user.length; CHECK_SPACE(pos, end, 1); host.length= *pos++; CHECK_SPACE(pos, end, host.length); host.str= (char *)pos; pos+= host.length; break; } case Q_HRNOW: { CHECK_SPACE(pos, end, 3); when_sec_part= uint3korr(pos); pos+= 3; break; } default: /* That's why you must write status vars in growing order of code */ DBUG_PRINT("info",("Query_log_event has unknown status vars (first has\ code: %u), skipping the rest of them", (uint) *(pos-1))); pos= (const uchar*) end; // Break loop } } #if !defined(MYSQL_CLIENT) if (description_event->server_version_split.kind == Format_description_log_event::master_version_split::KIND_MYSQL) { // Handle MariaDB/MySQL incompatible sql_mode bits sql_mode_t mysql_sql_mode= sql_mode; sql_mode&= MODE_MASK_MYSQL_COMPATIBLE; // Unset MySQL specific bits /* sql_mode flags related to fraction second rounding/truncation have opposite meaning in MySQL vs MariaDB. MySQL: - rounds fractional seconds by default - truncates if TIME_TRUNCATE_FRACTIONAL is set MariaDB: - truncates fractional seconds by default - rounds if TIME_ROUND_FRACTIONAL is set */ if (description_event->server_version_split >= fsp_version_split_mysql && !(mysql_sql_mode & MODE_MYSQL80_TIME_TRUNCATE_FRACTIONAL)) sql_mode|= MODE_TIME_ROUND_FRACTIONAL; } #endif /** Layout for the data buffer is as follows +--------+-----------+------+------+---------+----+-------+ | catlog | time_zone | user | host | db name | \0 | Query | +--------+-----------+------+------+---------+----+-------+ To support the query cache we append the following buffer to the above +-------+----------------------------------------+-------+ |db len | uninitiatlized space of size of db len | FLAGS | +-------+----------------------------------------+-------+ The area of buffer starting from Query field all the way to the end belongs to the Query buffer and its structure is described in alloc_query() in sql_parse.cc */ #if !defined(MYSQL_CLIENT) && defined(HAVE_QUERY_CACHE) if (!(start= data_buf = (Log_event::Byte*) my_malloc(catalog_len + 1 + time_zone_len + 1 + user.length + 1 + host.length + 1 + data_len + 1 + sizeof(size_t)//for db_len + db_len + 1 + QUERY_CACHE_DB_LENGTH_SIZE + QUERY_CACHE_FLAGS_SIZE, MYF(MY_WME)))) #else if (!(start= data_buf = (Log_event::Byte*) my_malloc(catalog_len + 1 + time_zone_len + 1 + user.length + 1 + host.length + 1 + data_len + 1, MYF(MY_WME)))) #endif DBUG_VOID_RETURN; if (catalog_len) // If catalog is given { /** @todo we should clean up and do only copy_str_and_move; it works for both cases. Then we can remove the catalog_nz flag. /sven */ if (likely(catalog_nz)) // true except if event comes from 5.0.0|1|2|3. copy_str_and_move(&catalog, &start, catalog_len); else { memcpy(start, catalog, catalog_len+1); // copy end 0 catalog= (const char *)start; start+= catalog_len+1; } } if (time_zone_len) copy_str_and_move(&time_zone_str, &start, time_zone_len); if (user.length) { copy_str_and_move(&user.str, &start, user.length); } else { user.str= (char*) start; *(start++)= 0; } if (host.length) copy_str_and_move(&host.str, &start, host.length); else { host.str= (char*) start; *(start++)= 0; } /** if time_zone_len or catalog_len are 0, then time_zone and catalog are uninitialized at this point. shouldn't they point to the zero-length null-terminated strings we allocated space for in the my_alloc call above? /sven */ /* A 2nd variable part; this is common to all versions */ memcpy((char*) start, end, data_len); // Copy db and query start[data_len]= '\0'; // End query with \0 (For safety) db= (char *)start; query= (char *)(start + db_len + 1); q_len= data_len - db_len -1; if (data_len && (data_len < db_len || data_len < q_len || data_len != (db_len + q_len + 1))) { q_len= 0; query= NULL; DBUG_VOID_RETURN; } uint32 max_length= uint32(event_len - ((const char*)(end + db_len + 1) - (buf - common_header_len))); if (q_len != max_length || (event_len < uint((const char*)(end + db_len + 1) - (buf - common_header_len)))) { q_len= 0; query= NULL; DBUG_VOID_RETURN; } /** Append the db length at the end of the buffer. This will be used by Query_cache::send_result_to_client() in case the query cache is On. */ #if !defined(MYSQL_CLIENT) && defined(HAVE_QUERY_CACHE) size_t db_length= (size_t)db_len; memcpy(start + data_len + 1, &db_length, sizeof(size_t)); #endif DBUG_VOID_RETURN; } Query_compressed_log_event::Query_compressed_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event, Log_event_type event_type) :Query_log_event(buf, event_len, description_event, event_type), query_buf(NULL) { if(query) { uint32 un_len=binlog_get_uncompress_len(query); if (!un_len) { query = 0; return; } /* Reserve one byte for '\0' */ query_buf = (Log_event::Byte*)my_malloc(ALIGN_SIZE(un_len + 1), MYF(MY_WME)); if(query_buf && !binlog_buf_uncompress(query, (char *)query_buf, q_len, &un_len)) { query_buf[un_len] = 0; query = (const char *)query_buf; q_len = un_len; } else { query= 0; } } } /* Replace a binlog event read into a packet with a dummy event. Either a Query_log_event that has just a comment, or if that will not fit in the space used for the event to be replaced, then a NULL user_var event. This is used when sending binlog data to a slave which does not understand this particular event and which is too old to support informational events or holes in the event stream. This allows to write such events into the binlog on the master and still be able to replicate against old slaves without them breaking. Clears the flag LOG_EVENT_THREAD_SPECIFIC_F and set LOG_EVENT_SUPPRESS_USE_F. Overwrites the type with QUERY_EVENT (or USER_VAR_EVENT), and replaces the body with a minimal query / NULL user var. Returns zero on success, -1 if error due to too little space in original event. A minimum of 25 bytes (19 bytes fixed header + 6 bytes in the body) is needed in any event to be replaced with a dummy event. */ int Query_log_event::dummy_event(String *packet, ulong ev_offset, enum enum_binlog_checksum_alg checksum_alg) { uchar *p= (uchar *)packet->ptr() + ev_offset; size_t data_len= packet->length() - ev_offset; uint16 flags; static const size_t min_user_var_event_len= LOG_EVENT_HEADER_LEN + UV_NAME_LEN_SIZE + 1 + UV_VAL_IS_NULL; // 25 static const size_t min_query_event_len= LOG_EVENT_HEADER_LEN + QUERY_HEADER_LEN + 1 + 1; // 34 if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) data_len-= BINLOG_CHECKSUM_LEN; else DBUG_ASSERT(checksum_alg == BINLOG_CHECKSUM_ALG_UNDEF || checksum_alg == BINLOG_CHECKSUM_ALG_OFF); if (data_len < min_user_var_event_len) /* Cannot replace with dummy, event too short. */ return -1; flags= uint2korr(p + FLAGS_OFFSET); flags&= ~LOG_EVENT_THREAD_SPECIFIC_F; flags|= LOG_EVENT_SUPPRESS_USE_F; int2store(p + FLAGS_OFFSET, flags); if (data_len < min_query_event_len) { /* Have to use dummy user_var event for such a short packet. This works, but the event will be considered part of an event group with the following event. So for example @@global.sql_slave_skip_counter=1 will skip not only the dummy event, but also the immediately following event. We write a NULL user var with the name @`!dummyvar` (or as much as that as will fit within the size of the original event - so possibly just @`!`). */ static const char var_name[]= "!dummyvar"; size_t name_len= data_len - (min_user_var_event_len - 1); p[EVENT_TYPE_OFFSET]= USER_VAR_EVENT; int4store(p + LOG_EVENT_HEADER_LEN, name_len); memcpy(p + LOG_EVENT_HEADER_LEN + UV_NAME_LEN_SIZE, var_name, name_len); p[LOG_EVENT_HEADER_LEN + UV_NAME_LEN_SIZE + name_len]= 1; // indicates NULL } else { /* Use a dummy query event, just a comment. */ static const char message[]= "# Dummy event replacing event type %u that slave cannot handle."; char buf[sizeof(message)+1]; /* +1, as %u can expand to 3 digits. */ uchar old_type= p[EVENT_TYPE_OFFSET]; uchar *q= p + LOG_EVENT_HEADER_LEN; size_t comment_len, len; p[EVENT_TYPE_OFFSET]= QUERY_EVENT; int4store(q + Q_THREAD_ID_OFFSET, 0); int4store(q + Q_EXEC_TIME_OFFSET, 0); q[Q_DB_LEN_OFFSET]= 0; int2store(q + Q_ERR_CODE_OFFSET, 0); int2store(q + Q_STATUS_VARS_LEN_OFFSET, 0); q[Q_DATA_OFFSET]= 0; /* Zero terminator for empty db */ q+= Q_DATA_OFFSET + 1; len= my_snprintf(buf, sizeof(buf), message, old_type); comment_len= data_len - (min_query_event_len - 1); if (comment_len <= len) memcpy(q, buf, comment_len); else { memcpy(q, buf, len); memset(q+len, ' ', comment_len - len); } } if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) { ha_checksum crc= my_checksum(0, p, data_len); int4store(p + data_len, crc); } return 0; } /* Replace an event (GTID event) with a BEGIN query event, to be compatible with an old slave. */ int Query_log_event::begin_event(String *packet, ulong ev_offset, enum enum_binlog_checksum_alg checksum_alg) { uchar *p= (uchar *)packet->ptr() + ev_offset; uchar *q= p + LOG_EVENT_HEADER_LEN; size_t data_len= packet->length() - ev_offset; uint16 flags; if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) data_len-= BINLOG_CHECKSUM_LEN; else DBUG_ASSERT(checksum_alg == BINLOG_CHECKSUM_ALG_UNDEF || checksum_alg == BINLOG_CHECKSUM_ALG_OFF); /* Currently we only need to replace GTID event. The length of GTID differs depending on whether it contains commit id. */ DBUG_ASSERT(data_len == LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN || data_len == LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN + 2); if (data_len != LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN && data_len != LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN + 2) return 1; flags= uint2korr(p + FLAGS_OFFSET); flags&= ~LOG_EVENT_THREAD_SPECIFIC_F; flags|= LOG_EVENT_SUPPRESS_USE_F; int2store(p + FLAGS_OFFSET, flags); p[EVENT_TYPE_OFFSET]= QUERY_EVENT; int4store(q + Q_THREAD_ID_OFFSET, 0); int4store(q + Q_EXEC_TIME_OFFSET, 0); q[Q_DB_LEN_OFFSET]= 0; int2store(q + Q_ERR_CODE_OFFSET, 0); if (data_len == LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN) { int2store(q + Q_STATUS_VARS_LEN_OFFSET, 0); q[Q_DATA_OFFSET]= 0; /* Zero terminator for empty db */ q+= Q_DATA_OFFSET + 1; } else { DBUG_ASSERT(data_len == LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN + 2); /* Put in an empty time_zone_str to take up the extra 2 bytes. */ int2store(q + Q_STATUS_VARS_LEN_OFFSET, 2); q[Q_DATA_OFFSET]= Q_TIME_ZONE_CODE; q[Q_DATA_OFFSET+1]= 0; /* Zero length for empty time_zone_str */ q[Q_DATA_OFFSET+2]= 0; /* Zero terminator for empty db */ q+= Q_DATA_OFFSET + 3; } memcpy(q, "BEGIN", 5); if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) { ha_checksum crc= my_checksum(0, p, data_len); int4store(p + data_len, crc); } return 0; } #ifdef MYSQL_CLIENT /** Query_log_event::print(). @todo print the catalog ?? */ bool Query_log_event::print_query_header(IO_CACHE* file, PRINT_EVENT_INFO* print_event_info) { // TODO: print the catalog ?? char buff[64], *end; // Enough for SET TIMESTAMP bool different_db= 1; uint32 tmp; if (!print_event_info->short_form) { if (print_header(file, print_event_info, FALSE) || my_b_printf(file, "\t%s\tthread_id=%lu\texec_time=%lu\terror_code=%d\n", get_type_str(), (ulong) thread_id, (ulong) exec_time, error_code)) goto err; } if ((flags & LOG_EVENT_SUPPRESS_USE_F)) { if (!is_trans_keyword()) print_event_info->db[0]= '\0'; } else if (db) { different_db= memcmp(print_event_info->db, db, db_len + 1); if (different_db) memcpy(print_event_info->db, db, db_len + 1); if (db[0] && different_db) if (my_b_printf(file, "use %`s%s\n", db, print_event_info->delimiter)) goto err; } end=int10_to_str((long) when, strmov(buff,"SET TIMESTAMP="),10); if (when_sec_part && when_sec_part <= TIME_MAX_SECOND_PART) { *end++= '.'; end=int10_to_str(when_sec_part, end, 10); } end= strmov(end, print_event_info->delimiter); *end++='\n'; if (my_b_write(file, (uchar*) buff, (uint) (end-buff))) goto err; if ((!print_event_info->thread_id_printed || ((flags & LOG_EVENT_THREAD_SPECIFIC_F) && thread_id != print_event_info->thread_id))) { // If --short-form, print deterministic value instead of pseudo_thread_id. if (my_b_printf(file,"SET @@session.pseudo_thread_id=%lu%s\n", short_form ? 999999999 : (ulong)thread_id, print_event_info->delimiter)) goto err; print_event_info->thread_id= thread_id; print_event_info->thread_id_printed= 1; } /* If flags2_inited==0, this is an event from 3.23 or 4.0; nothing to print (remember we don't produce mixed relay logs so there cannot be 5.0 events before that one so there is nothing to reset). */ if (likely(flags2_inited)) /* likely as this will mainly read 5.0 logs */ { /* tmp is a bitmask of bits which have changed. */ if (likely(print_event_info->flags2_inited)) /* All bits which have changed */ tmp= (print_event_info->flags2) ^ flags2; else /* that's the first Query event we read */ { print_event_info->flags2_inited= 1; tmp= ~((uint32)0); /* all bits have changed */ } if (unlikely(tmp)) /* some bits have changed */ { bool need_comma= 0; if (my_b_write_string(file, "SET ") || print_set_option(file, tmp, OPTION_NO_FOREIGN_KEY_CHECKS, ~flags2, "@@session.foreign_key_checks", &need_comma)|| print_set_option(file, tmp, OPTION_AUTO_IS_NULL, flags2, "@@session.sql_auto_is_null", &need_comma) || print_set_option(file, tmp, OPTION_RELAXED_UNIQUE_CHECKS, ~flags2, "@@session.unique_checks", &need_comma) || print_set_option(file, tmp, OPTION_NOT_AUTOCOMMIT, ~flags2, "@@session.autocommit", &need_comma) || print_set_option(file, tmp, OPTION_NO_CHECK_CONSTRAINT_CHECKS, ~flags2, "@@session.check_constraint_checks", &need_comma) || my_b_printf(file,"%s\n", print_event_info->delimiter)) goto err; print_event_info->flags2= flags2; } } /* Now the session variables; it's more efficient to pass SQL_MODE as a number instead of a comma-separated list. FOREIGN_KEY_CHECKS, SQL_AUTO_IS_NULL, UNIQUE_CHECKS are session-only variables (they have no global version; they're not listed in sql_class.h), The tests below work for pure binlogs or pure relay logs. Won't work for mixed relay logs but we don't create mixed relay logs (that is, there is no relay log with a format change except within the 3 first events, which mysqlbinlog handles gracefully). So this code should always be good. */ if (likely(sql_mode_inited) && (unlikely(print_event_info->sql_mode != sql_mode || !print_event_info->sql_mode_inited))) { char llbuff[22]; if (my_b_printf(file,"SET @@session.sql_mode=%s%s\n", ullstr(sql_mode, llbuff), print_event_info->delimiter)) goto err; print_event_info->sql_mode= sql_mode; print_event_info->sql_mode_inited= 1; } if (print_event_info->auto_increment_increment != auto_increment_increment || print_event_info->auto_increment_offset != auto_increment_offset) { if (my_b_printf(file,"SET @@session.auto_increment_increment=%lu, @@session.auto_increment_offset=%lu%s\n", auto_increment_increment,auto_increment_offset, print_event_info->delimiter)) goto err; print_event_info->auto_increment_increment= auto_increment_increment; print_event_info->auto_increment_offset= auto_increment_offset; } /* TODO: print the catalog when we feature SET CATALOG */ if (likely(charset_inited) && (unlikely(!print_event_info->charset_inited || memcmp(print_event_info->charset, charset, 6)))) { CHARSET_INFO *cs_info= get_charset(uint2korr(charset), MYF(MY_WME)); if (cs_info) { /* for mysql client */ if (my_b_printf(file, "/*!\\C %s */%s\n", cs_info->csname, print_event_info->delimiter)) goto err; } if (my_b_printf(file,"SET " "@@session.character_set_client=%d," "@@session.collation_connection=%d," "@@session.collation_server=%d" "%s\n", uint2korr(charset), uint2korr(charset+2), uint2korr(charset+4), print_event_info->delimiter)) goto err; memcpy(print_event_info->charset, charset, 6); print_event_info->charset_inited= 1; } if (time_zone_len) { if (memcmp(print_event_info->time_zone_str, time_zone_str, time_zone_len+1)) { if (my_b_printf(file,"SET @@session.time_zone='%s'%s\n", time_zone_str, print_event_info->delimiter)) goto err; memcpy(print_event_info->time_zone_str, time_zone_str, time_zone_len+1); } } if (lc_time_names_number != print_event_info->lc_time_names_number) { if (my_b_printf(file, "SET @@session.lc_time_names=%d%s\n", lc_time_names_number, print_event_info->delimiter)) goto err; print_event_info->lc_time_names_number= lc_time_names_number; } if (charset_database_number != print_event_info->charset_database_number) { if (charset_database_number) { if (my_b_printf(file, "SET @@session.collation_database=%d%s\n", charset_database_number, print_event_info->delimiter)) goto err; } else if (my_b_printf(file, "SET @@session.collation_database=DEFAULT%s\n", print_event_info->delimiter)) goto err; print_event_info->charset_database_number= charset_database_number; } return 0; err: return 1; } bool Query_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { Write_on_release_cache cache(&print_event_info->head_cache, file, 0, this); /** reduce the size of io cache so that the write function is called for every call to my_b_write(). */ DBUG_EXECUTE_IF ("simulate_file_write_error", {(&cache)->write_pos= (&cache)->write_end- 500;}); if (print_query_header(&cache, print_event_info)) goto err; if (!is_flashback) { if (my_b_write(&cache, (uchar*) query, q_len) || my_b_printf(&cache, "\n%s\n", print_event_info->delimiter)) goto err; } else // is_flashback == 1 { if (strcmp("BEGIN", query) == 0) { if (my_b_write(&cache, (uchar*) "COMMIT", 6) || my_b_printf(&cache, "\n%s\n", print_event_info->delimiter)) goto err; } else if (strcmp("COMMIT", query) == 0) { if (my_b_printf(&cache, "START TRANSACTION\n%s\n", print_event_info->delimiter)) goto err; } } return cache.flush_data(); err: return 1; } #endif /* MYSQL_CLIENT */ /* Query_log_event::do_apply_event() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Query_log_event::do_apply_event(rpl_group_info *rgi) { return do_apply_event(rgi, query, q_len); } /** Compare if two errors should be regarded as equal. This is to handle the case when you can get slightly different errors on master and slave for the same thing. @param expected_error Error we got on master actual_error Error we got on slave @return 1 Errors are equal 0 Errors are different */ bool test_if_equal_repl_errors(int expected_error, int actual_error) { if (expected_error == actual_error) return 1; switch (expected_error) { case ER_DUP_ENTRY: case ER_DUP_ENTRY_WITH_KEY_NAME: case ER_DUP_KEY: case ER_AUTOINC_READ_FAILED: return (actual_error == ER_DUP_ENTRY || actual_error == ER_DUP_ENTRY_WITH_KEY_NAME || actual_error == ER_DUP_KEY || actual_error == ER_AUTOINC_READ_FAILED || actual_error == HA_ERR_AUTOINC_ERANGE); case ER_UNKNOWN_TABLE: return actual_error == ER_IT_IS_A_VIEW; default: break; } return 0; } /** @todo Compare the values of "affected rows" around here. Something like: @code if ((uint32) affected_in_event != (uint32) affected_on_slave) { sql_print_error("Slave: did not get the expected number of affected \ rows running query from master - expected %d, got %d (this numbers \ should have matched modulo 4294967296).", 0, ...); thd->query_error = 1; } @endcode We may also want an option to tell the slave to ignore "affected" mismatch. This mismatch could be implemented with a new ER_ code, and to ignore it you would use --slave-skip-errors... */ int Query_log_event::do_apply_event(rpl_group_info *rgi, const char *query_arg, uint32 q_len_arg) { int expected_error,actual_error= 0; Schema_specification_st db_options; uint64 sub_id= 0; void *hton= NULL; rpl_gtid gtid; Relay_log_info const *rli= rgi->rli; Rpl_filter *rpl_filter= rli->mi->rpl_filter; bool current_stmt_is_commit; DBUG_ENTER("Query_log_event::do_apply_event"); /* Colleagues: please never free(thd->catalog) in MySQL. This would lead to bugs as here thd->catalog is a part of an alloced block, not an entire alloced block (see Query_log_event::do_apply_event()). Same for thd->db. Thank you. */ thd->catalog= catalog_len ? (char *) catalog : (char *)""; size_t valid_len= Well_formed_prefix(system_charset_info, db, db_len, NAME_LEN).length(); if (valid_len != db_len) { rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "Invalid database name in Query event."); thd->is_slave_error= true; goto end; } set_thd_db(thd, rpl_filter, db, db_len); /* Setting the character set and collation of the current database thd->db. */ load_db_opt_by_name(thd, thd->db.str, &db_options); if (db_options.default_table_charset) thd->db_charset= db_options.default_table_charset; thd->variables.auto_increment_increment= auto_increment_increment; thd->variables.auto_increment_offset= auto_increment_offset; DBUG_PRINT("info", ("log_pos: %lu", (ulong) log_pos)); thd->clear_error(1); current_stmt_is_commit= is_commit(); DBUG_ASSERT(!current_stmt_is_commit || !rgi->tables_to_lock); rgi->slave_close_thread_tables(thd); /* Note: We do not need to execute reset_one_shot_variables() if this db_ok() test fails. Reason: The db stored in binlog events is the same for SET and for its companion query. If the SET is ignored because of db_ok(), the companion query will also be ignored, and if the companion query is ignored in the db_ok() test of ::do_apply_event(), then the companion SET also have so we don't need to reset_one_shot_variables(). */ if (is_trans_keyword() || rpl_filter->db_ok(thd->db.str)) { thd->set_time(when, when_sec_part); thd->set_query_and_id((char*)query_arg, q_len_arg, thd->charset(), next_query_id()); thd->variables.pseudo_thread_id= thread_id; // for temp tables DBUG_PRINT("query",("%s", thd->query())); if (unlikely(!(expected_error= error_code)) || ignored_error_code(expected_error) || !unexpected_error_code(expected_error)) { thd->slave_expected_error= expected_error; if (flags2_inited) /* all bits of thd->variables.option_bits which are 1 in OPTIONS_WRITTEN_TO_BIN_LOG must take their value from flags2. */ thd->variables.option_bits= flags2|(thd->variables.option_bits & ~OPTIONS_WRITTEN_TO_BIN_LOG); /* else, we are in a 3.23/4.0 binlog; we previously received a Rotate_log_event which reset thd->variables.option_bits and sql_mode etc, so nothing to do. */ /* We do not replicate MODE_NO_DIR_IN_CREATE. That is, if the master is a slave which runs with SQL_MODE=MODE_NO_DIR_IN_CREATE, this should not force us to ignore the dir too. Imagine you are a ring of machines, and one has a disk problem so that you temporarily need MODE_NO_DIR_IN_CREATE on this machine; you don't want it to propagate elsewhere (you don't want all slaves to start ignoring the dirs). */ if (sql_mode_inited) thd->variables.sql_mode= (sql_mode_t) ((thd->variables.sql_mode & MODE_NO_DIR_IN_CREATE) | (sql_mode & ~(sql_mode_t) MODE_NO_DIR_IN_CREATE)); if (charset_inited) { rpl_sql_thread_info *sql_info= thd->system_thread_info.rpl_sql_info; if (sql_info->cached_charset_compare(charset)) { /* Verify that we support the charsets found in the event. */ if (!(thd->variables.character_set_client= get_charset(uint2korr(charset), MYF(MY_WME))) || !(thd->variables.collation_connection= get_charset(uint2korr(charset+2), MYF(MY_WME))) || !(thd->variables.collation_server= get_charset(uint2korr(charset+4), MYF(MY_WME)))) { /* We updated the thd->variables with nonsensical values (0). Let's set them to something safe (i.e. which avoids crash), and we'll stop with EE_UNKNOWN_CHARSET in compare_errors (unless set to ignore this error). */ set_slave_thread_default_charset(thd, rgi); goto compare_errors; } thd->update_charset(); // for the charset change to take effect /* Reset thd->query_string.cs to the newly set value. Note, there is a small flaw here. For a very short time frame if the new charset is different from the old charset and if another thread executes "SHOW PROCESSLIST" after the above thd->set_query_and_id() and before this thd->set_query(), and if the current query has some non-ASCII characters, the another thread may see some '?' marks in the PROCESSLIST result. This should be acceptable now. This is a reminder to fix this if any refactoring happens here sometime. */ thd->set_query((char*) query_arg, q_len_arg, thd->charset()); } } if (time_zone_len) { String tmp(time_zone_str, time_zone_len, &my_charset_bin); if (!(thd->variables.time_zone= my_tz_find(thd, &tmp))) { my_error(ER_UNKNOWN_TIME_ZONE, MYF(0), tmp.c_ptr()); thd->variables.time_zone= global_system_variables.time_zone; goto compare_errors; } } if (lc_time_names_number) { if (!(thd->variables.lc_time_names= my_locale_by_number(lc_time_names_number))) { my_printf_error(ER_UNKNOWN_ERROR, "Unknown locale: '%d'", MYF(0), lc_time_names_number); thd->variables.lc_time_names= &my_locale_en_US; goto compare_errors; } } else thd->variables.lc_time_names= &my_locale_en_US; if (charset_database_number) { CHARSET_INFO *cs; if (!(cs= get_charset(charset_database_number, MYF(0)))) { char buf[20]; int10_to_str((int) charset_database_number, buf, -10); my_error(ER_UNKNOWN_COLLATION, MYF(0), buf); goto compare_errors; } thd->variables.collation_database= cs; } else thd->variables.collation_database= thd->db_charset; { const CHARSET_INFO *cs= thd->charset(); /* We cannot ask for parsing a statement using a character set without state_maps (parser internal data). */ if (!cs->state_map) { rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "character_set cannot be parsed"); thd->is_slave_error= true; goto end; } } /* Record any GTID in the same transaction, so slave state is transactionally consistent. */ if (current_stmt_is_commit) { thd->variables.option_bits&= ~OPTION_GTID_BEGIN; if (rgi->gtid_pending) { sub_id= rgi->gtid_sub_id; rgi->gtid_pending= false; gtid= rgi->current_gtid; if (unlikely(rpl_global_gtid_slave_state->record_gtid(thd, >id, sub_id, true, false, &hton))) { int errcode= thd->get_stmt_da()->sql_errno(); if (!is_parallel_retry_error(rgi, errcode)) rli->report(ERROR_LEVEL, ER_CANNOT_UPDATE_GTID_STATE, rgi->gtid_info(), "Error during COMMIT: failed to update GTID state in " "%s.%s: %d: %s", "mysql", rpl_gtid_slave_state_table_name.str, errcode, thd->get_stmt_da()->message()); sub_id= 0; thd->is_slave_error= 1; goto end; } } } thd->table_map_for_update= (table_map)table_map_for_update; thd->set_invoker(&user, &host); /* Flag if we need to rollback the statement transaction on slave if it by chance succeeds. If we expected a non-zero error code and get nothing and, it is a concurrency issue or ignorable issue, effects of the statement should be rolled back. */ if (unlikely(expected_error) && (ignored_error_code(expected_error) || concurrency_error_code(expected_error))) { thd->variables.option_bits|= OPTION_MASTER_SQL_ERROR; thd->variables.option_bits&= ~OPTION_GTID_BEGIN; } /* Execute the query (note that we bypass dispatch_command()) */ Parser_state parser_state; if (!parser_state.init(thd, thd->query(), thd->query_length())) { DBUG_ASSERT(thd->m_digest == NULL); thd->m_digest= & thd->m_digest_state; DBUG_ASSERT(thd->m_statement_psi == NULL); thd->m_statement_psi= MYSQL_START_STATEMENT(&thd->m_statement_state, stmt_info_rpl.m_key, thd->db.str, thd->db.length, thd->charset()); THD_STAGE_INFO(thd, stage_init); MYSQL_SET_STATEMENT_TEXT(thd->m_statement_psi, thd->query(), thd->query_length()); if (thd->m_digest != NULL) thd->m_digest->reset(thd->m_token_array, max_digest_length); if (thd->slave_thread) { /* To be compatible with previous releases, the slave thread uses the global log_slow_disabled_statements value, wich can be changed dynamically, so we have to set the sql_log_slow respectively. */ thd->variables.sql_log_slow= !MY_TEST(global_system_variables.log_slow_disabled_statements & LOG_SLOW_DISABLE_SLAVE); } mysql_parse(thd, thd->query(), thd->query_length(), &parser_state, FALSE, FALSE); /* Finalize server status flags after executing a statement. */ thd->update_server_status(); log_slow_statement(thd); thd->lex->restore_set_statement_var(); } thd->variables.option_bits&= ~OPTION_MASTER_SQL_ERROR; } else { /* The query got a really bad error on the master (thread killed etc), which could be inconsistent. Parse it to test the table names: if the replicate-*-do|ignore-table rules say "this query must be ignored" then we exit gracefully; otherwise we warn about the bad error and tell DBA to check/fix it. */ if (mysql_test_parse_for_slave(thd, thd->query(), thd->query_length())) thd->clear_error(1); else { rli->report(ERROR_LEVEL, expected_error, rgi->gtid_info(), "\ Query partially completed on the master (error on master: %d) \ and was aborted. There is a chance that your master is inconsistent at this \ point. If you are sure that your master is ok, run this query manually on the \ slave and then restart the slave with SET GLOBAL SQL_SLAVE_SKIP_COUNTER=1; \ START SLAVE; . Query: '%s'", expected_error, thd->query()); thd->is_slave_error= 1; } goto end; } /* If the query was not ignored, it is printed to the general log */ if (likely(!thd->is_error()) || thd->get_stmt_da()->sql_errno() != ER_SLAVE_IGNORED_TABLE) general_log_write(thd, COM_QUERY, thd->query(), thd->query_length()); else { /* Bug#54201: If we skip an INSERT query that uses auto_increment, then we should reset any @@INSERT_ID set by an Intvar_log_event associated with the query; otherwise the @@INSERT_ID will linger until the next INSERT that uses auto_increment and may affect extra triggers on the slave etc. We reset INSERT_ID unconditionally; it is probably cheaper than checking if it is necessary. */ thd->auto_inc_intervals_forced.empty(); } compare_errors: /* In the slave thread, we may sometimes execute some DROP / * 40005 TEMPORARY * / TABLE that come from parts of binlogs (likely if we use RESET SLAVE or CHANGE MASTER TO), while the temporary table has already been dropped. To ignore such irrelevant "table does not exist errors", we silently clear the error if TEMPORARY was used. */ if ((thd->lex->sql_command == SQLCOM_DROP_TABLE || thd->lex->sql_command == SQLCOM_DROP_SEQUENCE) && thd->lex->tmp_table() && thd->is_error() && thd->get_stmt_da()->sql_errno() == ER_BAD_TABLE_ERROR && !expected_error) thd->get_stmt_da()->reset_diagnostics_area(); /* If we expected a non-zero error code, and we don't get the same error code, and it should be ignored or is related to a concurrency issue. */ actual_error= thd->is_error() ? thd->get_stmt_da()->sql_errno() : 0; DBUG_PRINT("info",("expected_error: %d sql_errno: %d", expected_error, actual_error)); if ((unlikely(expected_error) && !test_if_equal_repl_errors(expected_error, actual_error) && !concurrency_error_code(expected_error)) && !ignored_error_code(actual_error) && !ignored_error_code(expected_error)) { rli->report(ERROR_LEVEL, 0, rgi->gtid_info(), "Query caused different errors on master and slave. " "Error on master: message (format)='%s' error code=%d ; " "Error on slave: actual message='%s', error code=%d. " "Default database: '%s'. Query: '%s'", ER_THD(thd, expected_error), expected_error, actual_error ? thd->get_stmt_da()->message() : "no error", actual_error, print_slave_db_safe(db), query_arg); thd->is_slave_error= 1; } /* If we get the same error code as expected and it is not a concurrency issue, or should be ignored. */ else if ((test_if_equal_repl_errors(expected_error, actual_error) && !concurrency_error_code(expected_error)) || ignored_error_code(actual_error)) { DBUG_PRINT("info",("error ignored")); thd->clear_error(1); if (actual_error == ER_QUERY_INTERRUPTED || actual_error == ER_CONNECTION_KILLED) thd->reset_killed(); } /* Other cases: mostly we expected no error and get one. */ else if (unlikely(thd->is_slave_error || thd->is_fatal_error)) { if (!is_parallel_retry_error(rgi, actual_error)) rli->report(ERROR_LEVEL, actual_error, rgi->gtid_info(), "Error '%s' on query. Default database: '%s'. Query: '%s'", (actual_error ? thd->get_stmt_da()->message() : "unexpected success or fatal error"), thd->get_db(), query_arg); thd->is_slave_error= 1; #ifdef WITH_WSREP if (wsrep_thd_is_toi(thd) && wsrep_must_ignore_error(thd)) { thd->clear_error(1); thd->killed= NOT_KILLED; thd->wsrep_has_ignored_error= true; } #endif /* WITH_WSREP */ } /* TODO: compare the values of "affected rows" around here. Something like: if ((uint32) affected_in_event != (uint32) affected_on_slave) { sql_print_error("Slave: did not get the expected number of affected \ rows running query from master - expected %d, got %d (this numbers \ should have matched modulo 4294967296).", 0, ...); thd->is_slave_error = 1; } We may also want an option to tell the slave to ignore "affected" mismatch. This mismatch could be implemented with a new ER_ code, and to ignore it you would use --slave-skip-errors... To do the comparison we need to know the value of "affected" which the above mysql_parse() computed. And we need to know the value of "affected" in the master's binlog. Both will be implemented later. The important thing is that we now have the format ready to log the values of "affected" in the binlog. So we can release 5.0.0 before effectively logging "affected" and effectively comparing it. */ } /* End of if (db_ok(... */ { /** The following failure injecion works in cooperation with tests setting @@global.debug= 'd,stop_slave_middle_group'. The sql thread receives the killed status and will proceed to shutdown trying to finish incomplete events group. */ DBUG_EXECUTE_IF("stop_slave_middle_group", if (!current_stmt_is_commit && is_begin() == 0) { if (thd->transaction.all.modified_non_trans_table) const_cast(rli)->abort_slave= 1; };); } end: if (unlikely(sub_id && !thd->is_slave_error)) rpl_global_gtid_slave_state->update_state_hash(sub_id, >id, hton, rgi); /* Probably we have set thd->query, thd->db, thd->catalog to point to places in the data_buf of this event. Now the event is going to be deleted probably, so data_buf will be freed, so the thd->... listed above will be pointers to freed memory. So we must set them to 0, so that those bad pointers values are not later used. Note that "cleanup" queries like automatic DROP TEMPORARY TABLE don't suffer from these assignments to 0 as DROP TEMPORARY TABLE uses the db.table syntax. */ thd->catalog= 0; thd->set_db(&null_clex_str); /* will free the current database */ thd->reset_query(); DBUG_PRINT("info", ("end: query= 0")); /* Mark the statement completed. */ MYSQL_END_STATEMENT(thd->m_statement_psi, thd->get_stmt_da()); thd->m_statement_psi= NULL; thd->m_digest= NULL; /* As a disk space optimization, future masters will not log an event for LAST_INSERT_ID() if that function returned 0 (and thus they will be able to replace the THD::stmt_depends_on_first_successful_insert_id_in_prev_stmt variable by (THD->first_successful_insert_id_in_prev_stmt > 0) ; with the resetting below we are ready to support that. */ thd->first_successful_insert_id_in_prev_stmt_for_binlog= 0; thd->first_successful_insert_id_in_prev_stmt= 0; thd->stmt_depends_on_first_successful_insert_id_in_prev_stmt= 0; free_root(thd->mem_root,MYF(MY_KEEP_PREALLOC)); DBUG_RETURN(thd->is_slave_error); } Log_event::enum_skip_reason Query_log_event::do_shall_skip(rpl_group_info *rgi) { Relay_log_info *rli= rgi->rli; DBUG_ENTER("Query_log_event::do_shall_skip"); DBUG_PRINT("debug", ("query: '%s' q_len: %d", query, q_len)); DBUG_ASSERT(query && q_len > 0); DBUG_ASSERT(thd == rgi->thd); /* An event skipped due to @@skip_replication must not be counted towards the number of events to be skipped due to @@sql_slave_skip_counter. */ if (flags & LOG_EVENT_SKIP_REPLICATION_F && opt_replicate_events_marked_for_skip != RPL_SKIP_REPLICATE) DBUG_RETURN(Log_event::EVENT_SKIP_IGNORE); if (rli->slave_skip_counter > 0) { if (is_begin()) { thd->variables.option_bits|= OPTION_BEGIN | OPTION_GTID_BEGIN; DBUG_RETURN(Log_event::continue_group(rgi)); } if (is_commit() || is_rollback()) { thd->variables.option_bits&= ~(OPTION_BEGIN | OPTION_GTID_BEGIN); DBUG_RETURN(Log_event::EVENT_SKIP_COUNT); } } #ifdef WITH_WSREP else if (WSREP(thd) && wsrep_mysql_replication_bundle && opt_slave_domain_parallel_threads == 0 && thd->wsrep_mysql_replicated > 0 && (is_begin() || is_commit())) { if (++thd->wsrep_mysql_replicated < (int)wsrep_mysql_replication_bundle) { WSREP_DEBUG("skipping wsrep commit %d", thd->wsrep_mysql_replicated); DBUG_RETURN(Log_event::EVENT_SKIP_IGNORE); } else { thd->wsrep_mysql_replicated = 0; } } #endif /* WITH_WSREP */ DBUG_RETURN(Log_event::do_shall_skip(rgi)); } bool Query_log_event::peek_is_commit_rollback(const char *event_start, size_t event_len, enum enum_binlog_checksum_alg checksum_alg) { if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) { if (event_len > BINLOG_CHECKSUM_LEN) event_len-= BINLOG_CHECKSUM_LEN; else event_len= 0; } else DBUG_ASSERT(checksum_alg == BINLOG_CHECKSUM_ALG_UNDEF || checksum_alg == BINLOG_CHECKSUM_ALG_OFF); if (event_len < LOG_EVENT_HEADER_LEN + QUERY_HEADER_LEN || event_len < 9) return false; return !memcmp(event_start + (event_len-7), "\0COMMIT", 7) || !memcmp(event_start + (event_len-9), "\0ROLLBACK", 9); } #endif /************************************************************************** Start_log_event_v3 methods **************************************************************************/ #ifndef MYSQL_CLIENT Start_log_event_v3::Start_log_event_v3() :Log_event(), created(0), binlog_version(BINLOG_VERSION), dont_set_created(0) { memcpy(server_version, ::server_version, ST_SERVER_VER_LEN); } #endif /* Start_log_event_v3::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Start_log_event_v3::pack_info(Protocol *protocol) { char buf[12 + ST_SERVER_VER_LEN + 14 + 22], *pos; pos= strmov(buf, "Server ver: "); pos= strmov(pos, server_version); pos= strmov(pos, ", Binlog ver: "); pos= int10_to_str(binlog_version, pos, 10); protocol->store(buf, (uint) (pos-buf), &my_charset_bin); } #endif /* Start_log_event_v3::print() */ #ifdef MYSQL_CLIENT bool Start_log_event_v3::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { DBUG_ENTER("Start_log_event_v3::print"); Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); if (!print_event_info->short_form) { if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\tStart: binlog v %d, server v %s created ", binlog_version, server_version) || print_timestamp(&cache)) goto err; if (created) if (my_b_printf(&cache," at startup")) goto err; if (my_b_printf(&cache, "\n")) goto err; if (flags & LOG_EVENT_BINLOG_IN_USE_F) if (my_b_printf(&cache, "# Warning: this binlog is either in use or was not " "closed properly.\n")) goto err; } if (!is_artificial_event() && created) { #ifdef WHEN_WE_HAVE_THE_RESET_CONNECTION_SQL_COMMAND /* This is for mysqlbinlog: like in replication, we want to delete the stale tmp files left by an unclean shutdown of mysqld (temporary tables) and rollback unfinished transaction. Probably this can be done with RESET CONNECTION (syntax to be defined). */ if (my_b_printf(&cache,"RESET CONNECTION%s\n", print_event_info->delimiter)) goto err; #else if (my_b_printf(&cache,"ROLLBACK%s\n", print_event_info->delimiter)) goto err; #endif } if (temp_buf && print_event_info->base64_output_mode != BASE64_OUTPUT_NEVER && !print_event_info->short_form) { /* BINLOG is matched with the delimiter below on the same level */ bool do_print_encoded= print_event_info->base64_output_mode != BASE64_OUTPUT_DECODE_ROWS; if (do_print_encoded) my_b_printf(&cache, "BINLOG '\n"); if (print_base64(&cache, print_event_info, do_print_encoded)) goto err; if (do_print_encoded) my_b_printf(&cache, "'%s\n", print_event_info->delimiter); print_event_info->printed_fd_event= TRUE; } DBUG_RETURN(cache.flush_data()); err: DBUG_RETURN(1); } #endif /* MYSQL_CLIENT */ /* Start_log_event_v3::Start_log_event_v3() */ Start_log_event_v3::Start_log_event_v3(const char* buf, uint event_len, const Format_description_log_event *description_event) :Log_event(buf, description_event), binlog_version(BINLOG_VERSION) { if (event_len < LOG_EVENT_MINIMAL_HEADER_LEN + ST_COMMON_HEADER_LEN_OFFSET) { server_version[0]= 0; return; } buf+= LOG_EVENT_MINIMAL_HEADER_LEN; binlog_version= uint2korr(buf+ST_BINLOG_VER_OFFSET); memcpy(server_version, buf+ST_SERVER_VER_OFFSET, ST_SERVER_VER_LEN); // prevent overrun if log is corrupted on disk server_version[ST_SERVER_VER_LEN-1]= 0; created= uint4korr(buf+ST_CREATED_OFFSET); dont_set_created= 1; } /* Start_log_event_v3::write() */ #ifndef MYSQL_CLIENT bool Start_log_event_v3::write() { char buff[START_V3_HEADER_LEN]; int2store(buff + ST_BINLOG_VER_OFFSET,binlog_version); memcpy(buff + ST_SERVER_VER_OFFSET,server_version,ST_SERVER_VER_LEN); if (!dont_set_created) created= get_time(); // this sets when and when_sec_part as a side effect int4store(buff + ST_CREATED_OFFSET,created); return write_header(sizeof(buff)) || write_data(buff, sizeof(buff)) || write_footer(); } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /** Start_log_event_v3::do_apply_event() . The master started IMPLEMENTATION - To handle the case where the master died without having time to write DROP TEMPORARY TABLE, DO RELEASE_LOCK (prepared statements' deletion is TODO), we clean up all temporary tables that we got, if we are sure we can (see below). @todo - Remove all active user locks. Guilhem 2003-06: this is true but not urgent: the worst it can cause is the use of a bit of memory for a user lock which will not be used anymore. If the user lock is later used, the old one will be released. In other words, no deadlock problem. */ int Start_log_event_v3::do_apply_event(rpl_group_info *rgi) { DBUG_ENTER("Start_log_event_v3::do_apply_event"); int error= 0; Relay_log_info *rli= rgi->rli; switch (binlog_version) { case 3: case 4: /* This can either be 4.x (then a Start_log_event_v3 is only at master startup so we are sure the master has restarted and cleared his temp tables; the event always has 'created'>0) or 5.0 (then we have to test 'created'). */ if (created) { rli->close_temporary_tables(); /* The following is only false if we get here with a BINLOG statement */ if (rli->mi) cleanup_load_tmpdir(&rli->mi->cmp_connection_name); } break; /* Now the older formats; in that case load_tmpdir is cleaned up by the I/O thread. */ case 1: if (strncmp(rli->relay_log.description_event_for_exec->server_version, "3.23.57",7) >= 0 && created) { /* Can distinguish, based on the value of 'created': this event was generated at master startup. */ rli->close_temporary_tables(); } /* Otherwise, can't distinguish a Start_log_event generated at master startup and one generated by master FLUSH LOGS, so cannot be sure temp tables have to be dropped. So do nothing. */ break; default: /* This case is not expected. It can be either an event corruption or an unsupported binary log version. */ rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "Binlog version not supported"); DBUG_RETURN(1); } DBUG_RETURN(error); } #endif /* defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ /*************************************************************************** Format_description_log_event methods ****************************************************************************/ /** Format_description_log_event 1st ctor. Ctor. Can be used to create the event to write to the binary log (when the server starts or when FLUSH LOGS), or to create artificial events to parse binlogs from MySQL 3.23 or 4.x. When in a client, only the 2nd use is possible. @param binlog_version the binlog version for which we want to build an event. Can be 1 (=MySQL 3.23), 3 (=4.0.x x>=2 and 4.1) or 4 (MySQL 5.0). Note that the old 4.0 (binlog version 2) is not supported; it should not be used for replication with 5.0. @param server_ver a string containing the server version. */ Format_description_log_event:: Format_description_log_event(uint8 binlog_ver, const char* server_ver) :Start_log_event_v3(), event_type_permutation(0) { binlog_version= binlog_ver; switch (binlog_ver) { case 4: /* MySQL 5.0 */ memcpy(server_version, ::server_version, ST_SERVER_VER_LEN); DBUG_EXECUTE_IF("pretend_version_50034_in_binlog", strmov(server_version, "5.0.34");); common_header_len= LOG_EVENT_HEADER_LEN; number_of_event_types= LOG_EVENT_TYPES; /* we'll catch my_malloc() error in is_valid() */ post_header_len=(uint8*) my_malloc(number_of_event_types*sizeof(uint8) + BINLOG_CHECKSUM_ALG_DESC_LEN, MYF(0)); /* This long list of assignments is not beautiful, but I see no way to make it nicer, as the right members are #defines, not array members, so it's impossible to write a loop. */ if (post_header_len) { #ifndef DBUG_OFF // Allows us to sanity-check that all events initialized their // events (see the end of this 'if' block). memset(post_header_len, 255, number_of_event_types*sizeof(uint8)); #endif /* Note: all event types must explicitly fill in their lengths here. */ post_header_len[START_EVENT_V3-1]= START_V3_HEADER_LEN; post_header_len[QUERY_EVENT-1]= QUERY_HEADER_LEN; post_header_len[STOP_EVENT-1]= STOP_HEADER_LEN; post_header_len[ROTATE_EVENT-1]= ROTATE_HEADER_LEN; post_header_len[INTVAR_EVENT-1]= INTVAR_HEADER_LEN; post_header_len[LOAD_EVENT-1]= LOAD_HEADER_LEN; post_header_len[SLAVE_EVENT-1]= SLAVE_HEADER_LEN; post_header_len[CREATE_FILE_EVENT-1]= CREATE_FILE_HEADER_LEN; post_header_len[APPEND_BLOCK_EVENT-1]= APPEND_BLOCK_HEADER_LEN; post_header_len[EXEC_LOAD_EVENT-1]= EXEC_LOAD_HEADER_LEN; post_header_len[DELETE_FILE_EVENT-1]= DELETE_FILE_HEADER_LEN; post_header_len[NEW_LOAD_EVENT-1]= NEW_LOAD_HEADER_LEN; post_header_len[RAND_EVENT-1]= RAND_HEADER_LEN; post_header_len[USER_VAR_EVENT-1]= USER_VAR_HEADER_LEN; post_header_len[FORMAT_DESCRIPTION_EVENT-1]= FORMAT_DESCRIPTION_HEADER_LEN; post_header_len[XID_EVENT-1]= XID_HEADER_LEN; post_header_len[BEGIN_LOAD_QUERY_EVENT-1]= BEGIN_LOAD_QUERY_HEADER_LEN; post_header_len[EXECUTE_LOAD_QUERY_EVENT-1]= EXECUTE_LOAD_QUERY_HEADER_LEN; /* The PRE_GA events are never be written to any binlog, but their lengths are included in Format_description_log_event. Hence, we need to be assign some value here, to avoid reading uninitialized memory when the array is written to disk. */ post_header_len[PRE_GA_WRITE_ROWS_EVENT-1] = 0; post_header_len[PRE_GA_UPDATE_ROWS_EVENT-1] = 0; post_header_len[PRE_GA_DELETE_ROWS_EVENT-1] = 0; post_header_len[TABLE_MAP_EVENT-1]= TABLE_MAP_HEADER_LEN; post_header_len[WRITE_ROWS_EVENT_V1-1]= ROWS_HEADER_LEN_V1; post_header_len[UPDATE_ROWS_EVENT_V1-1]= ROWS_HEADER_LEN_V1; post_header_len[DELETE_ROWS_EVENT_V1-1]= ROWS_HEADER_LEN_V1; /* We here have the possibility to simulate a master of before we changed the table map id to be stored in 6 bytes: when it was stored in 4 bytes (=> post_header_len was 6). This is used to test backward compatibility. This code can be removed after a few months (today is Dec 21st 2005), when we know that the 4-byte masters are not deployed anymore (check with Tomas Ulin first!), and the accompanying test (rpl_row_4_bytes) too. */ DBUG_EXECUTE_IF("old_row_based_repl_4_byte_map_id_master", post_header_len[TABLE_MAP_EVENT-1]= post_header_len[WRITE_ROWS_EVENT_V1-1]= post_header_len[UPDATE_ROWS_EVENT_V1-1]= post_header_len[DELETE_ROWS_EVENT_V1-1]= 6;); post_header_len[INCIDENT_EVENT-1]= INCIDENT_HEADER_LEN; post_header_len[HEARTBEAT_LOG_EVENT-1]= 0; post_header_len[IGNORABLE_LOG_EVENT-1]= 0; post_header_len[ROWS_QUERY_LOG_EVENT-1]= 0; post_header_len[GTID_LOG_EVENT-1]= 0; post_header_len[ANONYMOUS_GTID_LOG_EVENT-1]= 0; post_header_len[PREVIOUS_GTIDS_LOG_EVENT-1]= 0; post_header_len[TRANSACTION_CONTEXT_EVENT-1]= 0; post_header_len[VIEW_CHANGE_EVENT-1]= 0; post_header_len[XA_PREPARE_LOG_EVENT-1]= 0; post_header_len[WRITE_ROWS_EVENT-1]= ROWS_HEADER_LEN_V2; post_header_len[UPDATE_ROWS_EVENT-1]= ROWS_HEADER_LEN_V2; post_header_len[DELETE_ROWS_EVENT-1]= ROWS_HEADER_LEN_V2; // Set header length of the reserved events to 0 memset(post_header_len + MYSQL_EVENTS_END - 1, 0, (MARIA_EVENTS_BEGIN - MYSQL_EVENTS_END)*sizeof(uint8)); // Set header lengths of Maria events post_header_len[ANNOTATE_ROWS_EVENT-1]= ANNOTATE_ROWS_HEADER_LEN; post_header_len[BINLOG_CHECKPOINT_EVENT-1]= BINLOG_CHECKPOINT_HEADER_LEN; post_header_len[GTID_EVENT-1]= GTID_HEADER_LEN; post_header_len[GTID_LIST_EVENT-1]= GTID_LIST_HEADER_LEN; post_header_len[START_ENCRYPTION_EVENT-1]= START_ENCRYPTION_HEADER_LEN; //compressed event post_header_len[QUERY_COMPRESSED_EVENT-1]= QUERY_HEADER_LEN; post_header_len[WRITE_ROWS_COMPRESSED_EVENT-1]= ROWS_HEADER_LEN_V2; post_header_len[UPDATE_ROWS_COMPRESSED_EVENT-1]= ROWS_HEADER_LEN_V2; post_header_len[DELETE_ROWS_COMPRESSED_EVENT-1]= ROWS_HEADER_LEN_V2; post_header_len[WRITE_ROWS_COMPRESSED_EVENT_V1-1]= ROWS_HEADER_LEN_V1; post_header_len[UPDATE_ROWS_COMPRESSED_EVENT_V1-1]= ROWS_HEADER_LEN_V1; post_header_len[DELETE_ROWS_COMPRESSED_EVENT_V1-1]= ROWS_HEADER_LEN_V1; // Sanity-check that all post header lengths are initialized. int i; for (i=0; i=2 */ /* We build an artificial (i.e. not sent by the master) event, which describes what those old master versions send. */ if (binlog_ver==1) strmov(server_version, server_ver ? server_ver : "3.23"); else strmov(server_version, server_ver ? server_ver : "4.0"); common_header_len= binlog_ver==1 ? OLD_HEADER_LEN : LOG_EVENT_MINIMAL_HEADER_LEN; /* The first new event in binlog version 4 is Format_desc. So any event type after that does not exist in older versions. We use the events known by version 3, even if version 1 had only a subset of them (this is not a problem: it uses a few bytes for nothing but unifies code; it does not make the slave detect less corruptions). */ number_of_event_types= FORMAT_DESCRIPTION_EVENT - 1; post_header_len=(uint8*) my_malloc(number_of_event_types*sizeof(uint8), MYF(0)); if (post_header_len) { post_header_len[START_EVENT_V3-1]= START_V3_HEADER_LEN; post_header_len[QUERY_EVENT-1]= QUERY_HEADER_MINIMAL_LEN; post_header_len[STOP_EVENT-1]= 0; post_header_len[ROTATE_EVENT-1]= (binlog_ver==1) ? 0 : ROTATE_HEADER_LEN; post_header_len[INTVAR_EVENT-1]= 0; post_header_len[LOAD_EVENT-1]= LOAD_HEADER_LEN; post_header_len[SLAVE_EVENT-1]= 0; post_header_len[CREATE_FILE_EVENT-1]= CREATE_FILE_HEADER_LEN; post_header_len[APPEND_BLOCK_EVENT-1]= APPEND_BLOCK_HEADER_LEN; post_header_len[EXEC_LOAD_EVENT-1]= EXEC_LOAD_HEADER_LEN; post_header_len[DELETE_FILE_EVENT-1]= DELETE_FILE_HEADER_LEN; post_header_len[NEW_LOAD_EVENT-1]= post_header_len[LOAD_EVENT-1]; post_header_len[RAND_EVENT-1]= 0; post_header_len[USER_VAR_EVENT-1]= 0; } break; default: /* Includes binlog version 2 i.e. 4.0.x x<=1 */ post_header_len= 0; /* will make is_valid() fail */ break; } calc_server_version_split(); checksum_alg= BINLOG_CHECKSUM_ALG_UNDEF; reset_crypto(); } /** The problem with this constructor is that the fixed header may have a length different from this version, but we don't know this length as we have not read the Format_description_log_event which says it, yet. This length is in the post-header of the event, but we don't know where the post-header starts. So this type of event HAS to: - either have the header's length at the beginning (in the header, at a fixed position which will never be changed), not in the post-header. That would make the header be "shifted" compared to other events. - or have a header of size LOG_EVENT_MINIMAL_HEADER_LEN (19), in all future versions, so that we know for sure. I (Guilhem) chose the 2nd solution. Rotate has the same constraint (because it is sent before Format_description_log_event). */ Format_description_log_event:: Format_description_log_event(const char* buf, uint event_len, const Format_description_log_event* description_event) :Start_log_event_v3(buf, event_len, description_event), common_header_len(0), post_header_len(NULL), event_type_permutation(0) { DBUG_ENTER("Format_description_log_event::Format_description_log_event(char*,...)"); if (!Start_log_event_v3::is_valid()) DBUG_VOID_RETURN; /* sanity check */ buf+= LOG_EVENT_MINIMAL_HEADER_LEN; if ((common_header_len=buf[ST_COMMON_HEADER_LEN_OFFSET]) < OLD_HEADER_LEN) DBUG_VOID_RETURN; /* sanity check */ number_of_event_types= event_len - (LOG_EVENT_MINIMAL_HEADER_LEN + ST_COMMON_HEADER_LEN_OFFSET + 1); DBUG_PRINT("info", ("common_header_len=%d number_of_event_types=%d", common_header_len, number_of_event_types)); /* If alloc fails, we'll detect it in is_valid() */ post_header_len= (uint8*) my_memdup((uchar*)buf+ST_COMMON_HEADER_LEN_OFFSET+1, number_of_event_types* sizeof(*post_header_len), MYF(0)); calc_server_version_split(); if (!is_version_before_checksum(&server_version_split)) { /* the last bytes are the checksum alg desc and value (or value's room) */ number_of_event_types -= BINLOG_CHECKSUM_ALG_DESC_LEN; checksum_alg= (enum_binlog_checksum_alg)post_header_len[number_of_event_types]; } else { checksum_alg= BINLOG_CHECKSUM_ALG_UNDEF; } reset_crypto(); DBUG_VOID_RETURN; } #ifndef MYSQL_CLIENT bool Format_description_log_event::write() { bool ret; bool no_checksum; /* We don't call Start_log_event_v3::write() because this would make 2 my_b_safe_write(). */ uchar buff[START_V3_HEADER_LEN+1]; size_t rec_size= sizeof(buff) + BINLOG_CHECKSUM_ALG_DESC_LEN + number_of_event_types; int2store(buff + ST_BINLOG_VER_OFFSET,binlog_version); memcpy((char*) buff + ST_SERVER_VER_OFFSET,server_version,ST_SERVER_VER_LEN); if (!dont_set_created) created= get_time(); int4store(buff + ST_CREATED_OFFSET,created); buff[ST_COMMON_HEADER_LEN_OFFSET]= common_header_len; /* if checksum is requested record the checksum-algorithm descriptor next to post_header_len vector which will be followed by the checksum value. Master is supposed to trigger checksum computing by binlog_checksum_options, slave does it via marking the event according to FD_queue checksum_alg value. */ compile_time_assert(BINLOG_CHECKSUM_ALG_DESC_LEN == 1); #ifdef DBUG_ASSERT_EXISTS data_written= 0; // to prepare for need_checksum assert #endif uint8 checksum_byte= (uint8) (need_checksum() ? checksum_alg : BINLOG_CHECKSUM_ALG_OFF); /* FD of checksum-aware server is always checksum-equipped, (V) is in, regardless of @@global.binlog_checksum policy. Thereby a combination of (A) == 0, (V) != 0 means it's the checksum-aware server's FD event that heads checksum-free binlog file. Here 0 stands for checksumming OFF to evaluate (V) as 0 is that case. A combination of (A) != 0, (V) != 0 denotes FD of the checksum-aware server heading the checksummed binlog. (A), (V) presence in FD of the checksum-aware server makes the event 1 + 4 bytes bigger comparing to the former FD. */ if ((no_checksum= (checksum_alg == BINLOG_CHECKSUM_ALG_OFF))) { checksum_alg= BINLOG_CHECKSUM_ALG_CRC32; // Forcing (V) room to fill anyway } ret= write_header(rec_size) || write_data(buff, sizeof(buff)) || write_data(post_header_len, number_of_event_types) || write_data(&checksum_byte, sizeof(checksum_byte)) || write_footer(); if (no_checksum) checksum_alg= BINLOG_CHECKSUM_ALG_OFF; return ret; } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Format_description_log_event::do_apply_event(rpl_group_info *rgi) { int ret= 0; Relay_log_info *rli= rgi->rli; DBUG_ENTER("Format_description_log_event::do_apply_event"); /* As a transaction NEVER spans on 2 or more binlogs: if we have an active transaction at this point, the master died while writing the transaction to the binary log, i.e. while flushing the binlog cache to the binlog. XA guarantees that master has rolled back. So we roll back. Note: this event could be sent by the master to inform us of the format of its binlog; in other words maybe it is not at its original place when it comes to us; we'll know this by checking log_pos ("artificial" events have log_pos == 0). */ if (!is_artificial_event() && created && thd->transaction.all.ha_list) { /* This is not an error (XA is safe), just an information */ rli->report(INFORMATION_LEVEL, 0, NULL, "Rolling back unfinished transaction (no COMMIT " "or ROLLBACK in relay log). A probable cause is that " "the master died while writing the transaction to " "its binary log, thus rolled back too."); rgi->cleanup_context(thd, 1); } /* If this event comes from ourselves, there is no cleaning task to perform, we don't call Start_log_event_v3::do_apply_event() (this was just to update the log's description event). */ if (server_id != (uint32) global_system_variables.server_id) { /* If the event was not requested by the slave i.e. the master sent it while the slave asked for a position >4, the event will make rli->group_master_log_pos advance. Say that the slave asked for position 1000, and the Format_desc event's end is 96. Then in the beginning of replication rli->group_master_log_pos will be 0, then 96, then jump to first really asked event (which is >96). So this is ok. */ ret= Start_log_event_v3::do_apply_event(rgi); } if (!ret) { /* Save the information describing this binlog */ copy_crypto_data(rli->relay_log.description_event_for_exec); delete rli->relay_log.description_event_for_exec; rli->relay_log.description_event_for_exec= this; } DBUG_RETURN(ret); } int Format_description_log_event::do_update_pos(rpl_group_info *rgi) { if (server_id == (uint32) global_system_variables.server_id) { /* We only increase the relay log position if we are skipping events and do not touch any group_* variables, nor flush the relay log info. If there is a crash, we will have to re-skip the events again, but that is a minor issue. If we do not skip stepping the group log position (and the server id was changed when restarting the server), it might well be that we start executing at a position that is invalid, e.g., at a Rows_log_event or a Query_log_event preceded by a Intvar_log_event instead of starting at a Table_map_log_event or the Intvar_log_event respectively. */ rgi->inc_event_relay_log_pos(); return 0; } else { return Log_event::do_update_pos(rgi); } } Log_event::enum_skip_reason Format_description_log_event::do_shall_skip(rpl_group_info *rgi) { return Log_event::EVENT_SKIP_NOT; } #endif bool Format_description_log_event::start_decryption(Start_encryption_log_event* sele) { DBUG_ASSERT(crypto_data.scheme == 0); if (!sele->is_valid()) return 1; memcpy(crypto_data.nonce, sele->nonce, BINLOG_NONCE_LENGTH); return crypto_data.init(sele->crypto_scheme, sele->key_version); } Version::Version(const char *version, const char **endptr) { const char *p= version; ulong number; for (uint i= 0; i<=2; i++) { char *r; number= strtoul(p, &r, 10); /* It is an invalid version if any version number greater than 255 or first number is not followed by '.'. */ if (number < 256 && (*r == '.' || i != 0)) m_ver[i]= (uchar) number; else { *this= Version(); break; } p= r; if (*r == '.') p++; // skip the dot } endptr[0]= p; } Format_description_log_event:: master_version_split::master_version_split(const char *version) { const char *p; static_cast(this)[0]= Version(version, &p); if (strstr(p, "MariaDB") != 0 || strstr(p, "-maria-") != 0) kind= KIND_MARIADB; else kind= KIND_MYSQL; } /** Splits the event's 'server_version' string into three numeric pieces stored into 'server_version_split': X.Y.Zabc (X,Y,Z numbers, a not a digit) -> {X,Y,Z} X.Yabc -> {X,Y,0} 'server_version_split' is then used for lookups to find if the server which created this event has some known bug. */ void Format_description_log_event::calc_server_version_split() { server_version_split= master_version_split(server_version); DBUG_PRINT("info",("Format_description_log_event::server_version_split:" " '%s' %d %d %d", server_version, server_version_split[0], server_version_split[1], server_version_split[2])); } /** @return TRUE is the event's version is earlier than one that introduced the replication event checksum. FALSE otherwise. */ bool Format_description_log_event::is_version_before_checksum(const master_version_split *version_split) { return *version_split < (version_split->kind == master_version_split::KIND_MARIADB ? checksum_version_split_mariadb : checksum_version_split_mysql); } /** @param buf buffer holding serialized FD event @param len netto (possible checksum is stripped off) length of the event buf @return the version-safe checksum alg descriptor where zero designates no checksum, 255 - the orginator is checksum-unaware (effectively no checksum) and the actual [1-254] range alg descriptor. */ enum enum_binlog_checksum_alg get_checksum_alg(const char* buf, ulong len) { enum enum_binlog_checksum_alg ret; char version[ST_SERVER_VER_LEN]; DBUG_ENTER("get_checksum_alg"); DBUG_ASSERT(buf[EVENT_TYPE_OFFSET] == FORMAT_DESCRIPTION_EVENT); memcpy(version, buf + LOG_EVENT_MINIMAL_HEADER_LEN + ST_SERVER_VER_OFFSET, ST_SERVER_VER_LEN); version[ST_SERVER_VER_LEN - 1]= 0; Format_description_log_event::master_version_split version_split(version); ret= Format_description_log_event::is_version_before_checksum(&version_split) ? BINLOG_CHECKSUM_ALG_UNDEF : (enum_binlog_checksum_alg)buf[len - BINLOG_CHECKSUM_LEN - BINLOG_CHECKSUM_ALG_DESC_LEN]; DBUG_ASSERT(ret == BINLOG_CHECKSUM_ALG_OFF || ret == BINLOG_CHECKSUM_ALG_UNDEF || ret == BINLOG_CHECKSUM_ALG_CRC32); DBUG_RETURN(ret); } Start_encryption_log_event::Start_encryption_log_event( const char* buf, uint event_len, const Format_description_log_event* description_event) :Log_event(buf, description_event) { if ((int)event_len == LOG_EVENT_MINIMAL_HEADER_LEN + Start_encryption_log_event::get_data_size()) { buf += LOG_EVENT_MINIMAL_HEADER_LEN; crypto_scheme = *(uchar*)buf; key_version = uint4korr(buf + BINLOG_CRYPTO_SCHEME_LENGTH); memcpy(nonce, buf + BINLOG_CRYPTO_SCHEME_LENGTH + BINLOG_KEY_VERSION_LENGTH, BINLOG_NONCE_LENGTH); } else crypto_scheme= ~0; // invalid } #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Start_encryption_log_event::do_apply_event(rpl_group_info* rgi) { return rgi->rli->relay_log.description_event_for_exec->start_decryption(this); } int Start_encryption_log_event::do_update_pos(rpl_group_info *rgi) { /* master never sends Start_encryption_log_event, any SELE that a slave might see was created locally in MYSQL_BIN_LOG::open() on the slave */ rgi->inc_event_relay_log_pos(); return 0; } #endif #ifndef MYSQL_SERVER bool Start_encryption_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { Write_on_release_cache cache(&print_event_info->head_cache, file); StringBuffer<1024> buf; buf.append(STRING_WITH_LEN("# Encryption scheme: ")); buf.append_ulonglong(crypto_scheme); buf.append(STRING_WITH_LEN(", key_version: ")); buf.append_ulonglong(key_version); buf.append(STRING_WITH_LEN(", nonce: ")); buf.append_hex(nonce, BINLOG_NONCE_LENGTH); buf.append(STRING_WITH_LEN("\n# The rest of the binlog is encrypted!\n")); if (my_b_write(&cache, (uchar*)buf.ptr(), buf.length())) return 1; return (cache.flush_data()); } #endif /************************************************************************** Load_log_event methods General note about Load_log_event: the binlogging of LOAD DATA INFILE is going to be changed in 5.0 (or maybe in 5.1; not decided yet). However, the 5.0 slave could still have to read such events (from a 4.x master), convert them (which just means maybe expand the header, when 5.0 servers have a UID in events) (remember that whatever is after the header will be like in 4.x, as this event's format is not modified in 5.0 as we will use new types of events to log the new LOAD DATA INFILE features). To be able to read/convert, we just need to not assume that the common header is of length LOG_EVENT_HEADER_LEN (we must use the description event). Note that I (Guilhem) manually tested replication of a big LOAD DATA INFILE between 3.23 and 5.0, and between 4.0 and 5.0, and it works fine (and the positions displayed in SHOW SLAVE STATUS then are fine too). **************************************************************************/ /* Load_log_event::print_query() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) bool Load_log_event::print_query(THD *thd, bool need_db, const char *cs, String *buf, my_off_t *fn_start, my_off_t *fn_end, const char *qualify_db) { if (need_db && db && db_len) { buf->append(STRING_WITH_LEN("use ")); append_identifier(thd, buf, db, db_len); buf->append(STRING_WITH_LEN("; ")); } buf->append(STRING_WITH_LEN("LOAD DATA ")); if (is_concurrent) buf->append(STRING_WITH_LEN("CONCURRENT ")); if (fn_start) *fn_start= buf->length(); if (check_fname_outside_temp_buf()) buf->append(STRING_WITH_LEN("LOCAL ")); buf->append(STRING_WITH_LEN("INFILE '")); buf->append_for_single_quote(fname, fname_len); buf->append(STRING_WITH_LEN("' ")); if (sql_ex.opt_flags & REPLACE_FLAG) buf->append(STRING_WITH_LEN("REPLACE ")); else if (sql_ex.opt_flags & IGNORE_FLAG) buf->append(STRING_WITH_LEN("IGNORE ")); buf->append(STRING_WITH_LEN("INTO")); if (fn_end) *fn_end= buf->length(); buf->append(STRING_WITH_LEN(" TABLE ")); if (qualify_db) { append_identifier(thd, buf, qualify_db, strlen(qualify_db)); buf->append(STRING_WITH_LEN(".")); } append_identifier(thd, buf, table_name, table_name_len); if (cs != NULL) { buf->append(STRING_WITH_LEN(" CHARACTER SET ")); buf->append(cs, strlen(cs)); } /* We have to create all optional fields as the default is not empty */ buf->append(STRING_WITH_LEN(" FIELDS TERMINATED BY ")); pretty_print_str(buf, sql_ex.field_term, sql_ex.field_term_len); if (sql_ex.opt_flags & OPT_ENCLOSED_FLAG) buf->append(STRING_WITH_LEN(" OPTIONALLY ")); buf->append(STRING_WITH_LEN(" ENCLOSED BY ")); pretty_print_str(buf, sql_ex.enclosed, sql_ex.enclosed_len); buf->append(STRING_WITH_LEN(" ESCAPED BY ")); pretty_print_str(buf, sql_ex.escaped, sql_ex.escaped_len); buf->append(STRING_WITH_LEN(" LINES TERMINATED BY ")); pretty_print_str(buf, sql_ex.line_term, sql_ex.line_term_len); if (sql_ex.line_start_len) { buf->append(STRING_WITH_LEN(" STARTING BY ")); pretty_print_str(buf, sql_ex.line_start, sql_ex.line_start_len); } if ((long) skip_lines > 0) { buf->append(STRING_WITH_LEN(" IGNORE ")); buf->append_ulonglong(skip_lines); buf->append(STRING_WITH_LEN(" LINES ")); } if (num_fields) { uint i; const char *field= fields; buf->append(STRING_WITH_LEN(" (")); for (i = 0; i < num_fields; i++) { if (i) { /* Yes, the space and comma is reversed here. But this is mostly dead code, at most used when reading really old binlogs from old servers, so better just leave it as is... */ buf->append(STRING_WITH_LEN(" ,")); } append_identifier(thd, buf, field, field_lens[i]); field+= field_lens[i] + 1; } buf->append(STRING_WITH_LEN(")")); } return 0; } void Load_log_event::pack_info(Protocol *protocol) { char query_buffer[1024]; String query_str(query_buffer, sizeof(query_buffer), system_charset_info); query_str.length(0); print_query(protocol->thd, TRUE, NULL, &query_str, 0, 0, NULL); protocol->store(query_str.ptr(), query_str.length(), &my_charset_bin); } #endif /* defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ #ifndef MYSQL_CLIENT /* Load_log_event::write_data_header() */ bool Load_log_event::write_data_header() { char buf[LOAD_HEADER_LEN]; int4store(buf + L_THREAD_ID_OFFSET, slave_proxy_id); int4store(buf + L_EXEC_TIME_OFFSET, exec_time); int4store(buf + L_SKIP_LINES_OFFSET, skip_lines); buf[L_TBL_LEN_OFFSET] = (char)table_name_len; buf[L_DB_LEN_OFFSET] = (char)db_len; int4store(buf + L_NUM_FIELDS_OFFSET, num_fields); return write_data(buf, LOAD_HEADER_LEN) != 0; } /* Load_log_event::write_data_body() */ bool Load_log_event::write_data_body() { if (sql_ex.write_data(writer)) return 1; if (num_fields && fields && field_lens) { if (write_data(field_lens, num_fields) || write_data(fields, field_block_len)) return 1; } return (write_data(table_name, table_name_len + 1) || write_data(db, db_len + 1) || write_data(fname, fname_len)); } /* Load_log_event::Load_log_event() */ Load_log_event::Load_log_event(THD *thd_arg, const sql_exchange *ex, const char *db_arg, const char *table_name_arg, List &fields_arg, bool is_concurrent_arg, enum enum_duplicates handle_dup, bool ignore, bool using_trans) :Log_event(thd_arg, thd_arg->thread_specific_used ? LOG_EVENT_THREAD_SPECIFIC_F : 0, using_trans), thread_id(thd_arg->thread_id), slave_proxy_id((ulong)thd_arg->variables.pseudo_thread_id), num_fields(0),fields(0), field_lens(0),field_block_len(0), table_name(table_name_arg ? table_name_arg : ""), db(db_arg), fname(ex->file_name), local_fname(FALSE), is_concurrent(is_concurrent_arg) { time_t end_time; time(&end_time); exec_time = (ulong) (end_time - thd_arg->start_time); /* db can never be a zero pointer in 4.0 */ db_len = (uint32) strlen(db); table_name_len = (uint32) strlen(table_name); fname_len = (fname) ? (uint) strlen(fname) : 0; sql_ex.field_term = ex->field_term->ptr(); sql_ex.field_term_len = (uint8) ex->field_term->length(); sql_ex.enclosed = ex->enclosed->ptr(); sql_ex.enclosed_len = (uint8) ex->enclosed->length(); sql_ex.line_term = ex->line_term->ptr(); sql_ex.line_term_len = (uint8) ex->line_term->length(); sql_ex.line_start = ex->line_start->ptr(); sql_ex.line_start_len = (uint8) ex->line_start->length(); sql_ex.escaped = ex->escaped->ptr(); sql_ex.escaped_len = (uint8) ex->escaped->length(); sql_ex.opt_flags = 0; sql_ex.cached_new_format = -1; if (ex->dumpfile) sql_ex.opt_flags|= DUMPFILE_FLAG; if (ex->opt_enclosed) sql_ex.opt_flags|= OPT_ENCLOSED_FLAG; sql_ex.empty_flags= 0; switch (handle_dup) { case DUP_REPLACE: sql_ex.opt_flags|= REPLACE_FLAG; break; case DUP_UPDATE: // Impossible here case DUP_ERROR: break; } if (ignore) sql_ex.opt_flags|= IGNORE_FLAG; if (!ex->field_term->length()) sql_ex.empty_flags |= FIELD_TERM_EMPTY; if (!ex->enclosed->length()) sql_ex.empty_flags |= ENCLOSED_EMPTY; if (!ex->line_term->length()) sql_ex.empty_flags |= LINE_TERM_EMPTY; if (!ex->line_start->length()) sql_ex.empty_flags |= LINE_START_EMPTY; if (!ex->escaped->length()) sql_ex.empty_flags |= ESCAPED_EMPTY; skip_lines = ex->skip_lines; List_iterator li(fields_arg); field_lens_buf.length(0); fields_buf.length(0); Item* item; while ((item = li++)) { num_fields++; uchar len= (uchar) item->name.length; field_block_len += len + 1; fields_buf.append(item->name.str, len + 1); field_lens_buf.append((char*)&len, 1); } field_lens = (const uchar*)field_lens_buf.ptr(); fields = fields_buf.ptr(); } #endif /* !MYSQL_CLIENT */ /** @note The caller must do buf[event_len] = 0 before he starts using the constructed event. */ Load_log_event::Load_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) :Log_event(buf, description_event), num_fields(0), fields(0), field_lens(0),field_block_len(0), table_name(0), db(0), fname(0), local_fname(FALSE), /* Load_log_event which comes from the binary log does not contain information about the type of insert which was used on the master. Assume that it was an ordinary, non-concurrent LOAD DATA. */ is_concurrent(FALSE) { DBUG_ENTER("Load_log_event"); /* I (Guilhem) manually tested replication of LOAD DATA INFILE for 3.23->5.0, 4.0->5.0 and 5.0->5.0 and it works. */ if (event_len) copy_log_event(buf, event_len, (((uchar)buf[EVENT_TYPE_OFFSET] == LOAD_EVENT) ? LOAD_HEADER_LEN + description_event->common_header_len : LOAD_HEADER_LEN + LOG_EVENT_HEADER_LEN), description_event); /* otherwise it's a derived class, will call copy_log_event() itself */ DBUG_VOID_RETURN; } /* Load_log_event::copy_log_event() */ int Load_log_event::copy_log_event(const char *buf, ulong event_len, int body_offset, const Format_description_log_event *description_event) { DBUG_ENTER("Load_log_event::copy_log_event"); uint data_len; if ((int) event_len <= body_offset) DBUG_RETURN(1); char* buf_end = (char*)buf + event_len; /* this is the beginning of the post-header */ const char* data_head = buf + description_event->common_header_len; thread_id= slave_proxy_id= uint4korr(data_head + L_THREAD_ID_OFFSET); exec_time = uint4korr(data_head + L_EXEC_TIME_OFFSET); skip_lines = uint4korr(data_head + L_SKIP_LINES_OFFSET); table_name_len = (uint)data_head[L_TBL_LEN_OFFSET]; db_len = (uint)data_head[L_DB_LEN_OFFSET]; num_fields = uint4korr(data_head + L_NUM_FIELDS_OFFSET); /* Sql_ex.init() on success returns the pointer to the first byte after the sql_ex structure, which is the start of field lengths array. */ if (!(field_lens= (uchar*)sql_ex.init((char*)buf + body_offset, buf_end, (uchar)buf[EVENT_TYPE_OFFSET] != LOAD_EVENT))) DBUG_RETURN(1); data_len = event_len - body_offset; if (num_fields > data_len) // simple sanity check against corruption DBUG_RETURN(1); for (uint i = 0; i < num_fields; i++) field_block_len += (uint)field_lens[i] + 1; fields = (char*)field_lens + num_fields; table_name = fields + field_block_len; if (strlen(table_name) > NAME_LEN) goto err; db = table_name + table_name_len + 1; DBUG_EXECUTE_IF ("simulate_invalid_address", db_len = data_len;); fname = db + db_len + 1; if ((db_len > data_len) || (fname > buf_end)) goto err; fname_len = (uint) strlen(fname); if ((fname_len > data_len) || (fname + fname_len > buf_end)) goto err; // null termination is accomplished by the caller doing buf[event_len]=0 DBUG_RETURN(0); err: // Invalid event. table_name = 0; DBUG_RETURN(1); } /* Load_log_event::print() */ #ifdef MYSQL_CLIENT bool Load_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { return print(file, print_event_info, 0); } bool Load_log_event::print(FILE* file_arg, PRINT_EVENT_INFO* print_event_info, bool commented) { Write_on_release_cache cache(&print_event_info->head_cache, file_arg); bool different_db= 1; DBUG_ENTER("Load_log_event::print"); if (!print_event_info->short_form) { if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\tQuery\tthread_id=%ld\texec_time=%ld\n", thread_id, exec_time)) goto err; } if (db) { /* If the database is different from the one of the previous statement, we need to print the "use" command, and we update the last_db. But if commented, the "use" is going to be commented so we should not update the last_db. */ if ((different_db= memcmp(print_event_info->db, db, db_len + 1)) && !commented) memcpy(print_event_info->db, db, db_len + 1); } if (db && db[0] && different_db) if (my_b_printf(&cache, "%suse %`s%s\n", commented ? "# " : "", db, print_event_info->delimiter)) goto err; if (flags & LOG_EVENT_THREAD_SPECIFIC_F) if (my_b_printf(&cache,"%sSET @@session.pseudo_thread_id=%lu%s\n", commented ? "# " : "", (ulong)thread_id, print_event_info->delimiter)) goto err; if (my_b_printf(&cache, "%sLOAD DATA ", commented ? "# " : "")) goto err; if (check_fname_outside_temp_buf()) if (my_b_write_string(&cache, "LOCAL ")) goto err; if (my_b_printf(&cache, "INFILE '%-*s' ", fname_len, fname)) goto err; if (sql_ex.opt_flags & REPLACE_FLAG) { if (my_b_write_string(&cache, "REPLACE ")) goto err; } else if (sql_ex.opt_flags & IGNORE_FLAG) if (my_b_write_string(&cache, "IGNORE ")) goto err; if (my_b_printf(&cache, "INTO TABLE `%s`", table_name) || my_b_write_string(&cache, " FIELDS TERMINATED BY ") || pretty_print_str(&cache, sql_ex.field_term, sql_ex.field_term_len)) goto err; if (sql_ex.opt_flags & OPT_ENCLOSED_FLAG) if (my_b_write_string(&cache, " OPTIONALLY ")) goto err; if (my_b_write_string(&cache, " ENCLOSED BY ") || pretty_print_str(&cache, sql_ex.enclosed, sql_ex.enclosed_len) || my_b_write_string(&cache, " ESCAPED BY ") || pretty_print_str(&cache, sql_ex.escaped, sql_ex.escaped_len) || my_b_write_string(&cache, " LINES TERMINATED BY ") || pretty_print_str(&cache, sql_ex.line_term, sql_ex.line_term_len)) goto err; if (sql_ex.line_start) { if (my_b_write_string(&cache," STARTING BY ") || pretty_print_str(&cache, sql_ex.line_start, sql_ex.line_start_len)) goto err; } if ((long) skip_lines > 0) if (my_b_printf(&cache, " IGNORE %ld LINES", (long) skip_lines)) goto err; if (num_fields) { uint i; const char* field = fields; if (my_b_write_string(&cache, " (")) goto err; for (i = 0; i < num_fields; i++) { if (i) if (my_b_write_byte(&cache, ',')) goto err; if (my_b_printf(&cache, "%`s", field)) goto err; field += field_lens[i] + 1; } if (my_b_write_byte(&cache, ')')) goto err; } if (my_b_printf(&cache, "%s\n", print_event_info->delimiter)) goto err; DBUG_RETURN(cache.flush_data()); err: DBUG_RETURN(1); } #endif /* MYSQL_CLIENT */ #ifndef MYSQL_CLIENT /** Load_log_event::set_fields() @note This function can not use the member variable for the database, since LOAD DATA INFILE on the slave can be for a different database than the current one. This is the reason for the affected_db argument to this method. */ void Load_log_event::set_fields(const char* affected_db, List &field_list, Name_resolution_context *context) { uint i; const char* field = fields; for (i= 0; i < num_fields; i++) { LEX_CSTRING field_name= {field, field_lens[i] }; field_list.push_back(new (thd->mem_root) Item_field(thd, context, affected_db, table_name, &field_name), thd->mem_root); field+= field_lens[i] + 1; } } #endif /* !MYSQL_CLIENT */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /** Does the data loading job when executing a LOAD DATA on the slave. @param net @param rli @param use_rli_only_for_errors If set to 1, rli is provided to Load_log_event::exec_event only for this function to have RPL_LOG_NAME and rli->last_slave_error, both being used by error reports. rli's position advancing is skipped (done by the caller which is Execute_load_log_event::exec_event). If set to 0, rli is provided for full use, i.e. for error reports and position advancing. @todo fix this; this can be done by testing rules in Create_file_log_event::exec_event() and then discarding Append_block and al. @todo this is a bug - this needs to be moved to the I/O thread @retval 0 Success @retval 1 Failure */ int Load_log_event::do_apply_event(NET* net, rpl_group_info *rgi, bool use_rli_only_for_errors) { Relay_log_info const *rli= rgi->rli; Rpl_filter *rpl_filter= rli->mi->rpl_filter; DBUG_ENTER("Load_log_event::do_apply_event"); DBUG_ASSERT(thd->query() == 0); set_thd_db(thd, rpl_filter, db, db_len); thd->clear_error(1); /* see Query_log_event::do_apply_event() and BUG#13360 */ DBUG_ASSERT(!rgi->m_table_map.count()); /* Usually lex_start() is called by mysql_parse(), but we need it here as the present method does not call mysql_parse(). */ lex_start(thd); thd->lex->local_file= local_fname; thd->reset_for_next_command(0); // Errors are cleared above /* We test replicate_*_db rules. Note that we have already prepared the file to load, even if we are going to ignore and delete it now. So it is possible that we did a lot of disk writes for nothing. In other words, a big LOAD DATA INFILE on the master will still consume a lot of space on the slave (space in the relay log + space of temp files: twice the space of the file to load...) even if it will finally be ignored. TODO: fix this; this can be done by testing rules in Create_file_log_event::do_apply_event() and then discarding Append_block and al. Another way is do the filtering in the I/O thread (more efficient: no disk writes at all). Note: We do not need to execute reset_one_shot_variables() if this db_ok() test fails. Reason: The db stored in binlog events is the same for SET and for its companion query. If the SET is ignored because of db_ok(), the companion query will also be ignored, and if the companion query is ignored in the db_ok() test of ::do_apply_event(), then the companion SET also have so we don't need to reset_one_shot_variables(). */ if (rpl_filter->db_ok(thd->db.str)) { thd->set_time(when, when_sec_part); thd->set_query_id(next_query_id()); thd->get_stmt_da()->opt_clear_warning_info(thd->query_id); TABLE_LIST tables; LEX_CSTRING db_name= { thd->strmake(thd->db.str, thd->db.length), thd->db.length }; if (lower_case_table_names) my_casedn_str(system_charset_info, (char *)table_name); LEX_CSTRING tbl_name= { table_name, strlen(table_name) }; tables.init_one_table(&db_name, &tbl_name, 0, TL_WRITE); tables.updating= 1; // the table will be opened in mysql_load if (rpl_filter->is_on() && !rpl_filter->tables_ok(thd->db.str, &tables)) { // TODO: this is a bug - this needs to be moved to the I/O thread if (net) skip_load_data_infile(net); } else { enum enum_duplicates handle_dup; bool ignore= 0; char query_buffer[1024]; String query_str(query_buffer, sizeof(query_buffer), system_charset_info); char *load_data_query; query_str.length(0); /* Forge LOAD DATA INFILE query which will be used in SHOW PROCESS LIST and written to slave's binlog if binlogging is on. */ print_query(thd, FALSE, NULL, &query_str, NULL, NULL, NULL); if (!(load_data_query= (char *)thd->strmake(query_str.ptr(), query_str.length()))) { /* This will set thd->fatal_error in case of OOM. So we surely will notice that something is wrong. */ goto error; } thd->set_query(load_data_query, (uint) (query_str.length())); if (sql_ex.opt_flags & REPLACE_FLAG) handle_dup= DUP_REPLACE; else if (sql_ex.opt_flags & IGNORE_FLAG) { ignore= 1; handle_dup= DUP_ERROR; } else { /* When replication is running fine, if it was DUP_ERROR on the master then we could choose IGNORE here, because if DUP_ERROR succeeded on master, and data is identical on the master and slave, then there should be no uniqueness errors on slave, so IGNORE is the same as DUP_ERROR. But in the unlikely case of uniqueness errors (because the data on the master and slave happen to be different (user error or bug), we want LOAD DATA to print an error message on the slave to discover the problem. If reading from net (a 3.23 master), mysql_load() will change this to IGNORE. */ handle_dup= DUP_ERROR; } /* We need to set thd->lex->sql_command and thd->lex->duplicates since InnoDB tests these variables to decide if this is a LOAD DATA ... REPLACE INTO ... statement even though mysql_parse() is not called. This is not needed in 5.0 since there the LOAD DATA ... statement is replicated using mysql_parse(), which sets the thd->lex fields correctly. */ thd->lex->sql_command= SQLCOM_LOAD; thd->lex->duplicates= handle_dup; sql_exchange ex((char*)fname, sql_ex.opt_flags & DUMPFILE_FLAG); String field_term(sql_ex.field_term,sql_ex.field_term_len,log_cs); String enclosed(sql_ex.enclosed,sql_ex.enclosed_len,log_cs); String line_term(sql_ex.line_term,sql_ex.line_term_len,log_cs); String line_start(sql_ex.line_start,sql_ex.line_start_len,log_cs); String escaped(sql_ex.escaped,sql_ex.escaped_len, log_cs); ex.field_term= &field_term; ex.enclosed= &enclosed; ex.line_term= &line_term; ex.line_start= &line_start; ex.escaped= &escaped; ex.opt_enclosed = (sql_ex.opt_flags & OPT_ENCLOSED_FLAG); if (sql_ex.empty_flags & FIELD_TERM_EMPTY) ex.field_term->length(0); ex.skip_lines = skip_lines; List field_list; thd->lex->first_select_lex()->context.resolve_in_table_list_only(&tables); set_fields(tables.db.str, field_list, &thd->lex->first_select_lex()->context); thd->variables.pseudo_thread_id= thread_id; if (net) { // mysql_load will use thd->net to read the file thd->net.vio = net->vio; // Make sure the client does not get confused about the packet sequence thd->net.pkt_nr = net->pkt_nr; } /* It is safe to use tmp_list twice because we are not going to update it inside mysql_load(). */ List tmp_list; if (thd->open_temporary_tables(&tables) || mysql_load(thd, &ex, &tables, field_list, tmp_list, tmp_list, handle_dup, ignore, net != 0)) thd->is_slave_error= 1; if (thd->cuted_fields) { /* log_pos is the position of the LOAD event in the master log */ sql_print_warning("Slave: load data infile on table '%s' at " "log position %llu in log '%s' produced %ld " "warning(s). Default database: '%s'", (char*) table_name, log_pos, RPL_LOG_NAME, (ulong) thd->cuted_fields, thd->get_db()); } if (net) net->pkt_nr= thd->net.pkt_nr; } } else { /* We will just ask the master to send us /dev/null if we do not want to load the data. TODO: this a bug - needs to be done in I/O thread */ if (net) skip_load_data_infile(net); } error: thd->net.vio = 0; const char *remember_db= thd->get_db(); thd->catalog= 0; thd->set_db(&null_clex_str); /* will free the current database */ thd->reset_query(); thd->get_stmt_da()->set_overwrite_status(true); thd->is_error() ? trans_rollback_stmt(thd) : trans_commit_stmt(thd); thd->variables.option_bits&= ~(OPTION_BEGIN | OPTION_GTID_BEGIN); thd->get_stmt_da()->set_overwrite_status(false); close_thread_tables(thd); /* - If transaction rollback was requested due to deadlock perform it and release metadata locks. - If inside a multi-statement transaction, defer the release of metadata locks until the current transaction is either committed or rolled back. This prevents other statements from modifying the table for the entire duration of this transaction. This provides commit ordering and guarantees serializability across multiple transactions. - If in autocommit mode, or outside a transactional context, automatically release metadata locks of the current statement. */ if (thd->transaction_rollback_request) { trans_rollback_implicit(thd); thd->release_transactional_locks(); } else if (! thd->in_multi_stmt_transaction_mode()) thd->release_transactional_locks(); else thd->mdl_context.release_statement_locks(); DBUG_EXECUTE_IF("LOAD_DATA_INFILE_has_fatal_error", thd->is_slave_error= 0; thd->is_fatal_error= 1;); if (unlikely(thd->is_slave_error)) { /* this err/sql_errno code is copy-paste from net_send_error() */ const char *err; int sql_errno; if (thd->is_error()) { err= thd->get_stmt_da()->message(); sql_errno= thd->get_stmt_da()->sql_errno(); } else { sql_errno=ER_UNKNOWN_ERROR; err= ER_THD(thd, sql_errno); } rli->report(ERROR_LEVEL, sql_errno, rgi->gtid_info(), "\ Error '%s' running LOAD DATA INFILE on table '%s'. Default database: '%s'", err, (char*)table_name, remember_db); free_root(thd->mem_root,MYF(MY_KEEP_PREALLOC)); DBUG_RETURN(1); } free_root(thd->mem_root,MYF(MY_KEEP_PREALLOC)); if (unlikely(thd->is_fatal_error)) { char buf[256]; my_snprintf(buf, sizeof(buf), "Running LOAD DATA INFILE on table '%-.64s'." " Default database: '%-.64s'", (char*)table_name, remember_db); rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, rgi->gtid_info(), ER_THD(thd, ER_SLAVE_FATAL_ERROR), buf); DBUG_RETURN(1); } DBUG_RETURN( use_rli_only_for_errors ? 0 : Log_event::do_apply_event(rgi) ); } #endif /************************************************************************** Rotate_log_event methods **************************************************************************/ /* Rotate_log_event::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Rotate_log_event::pack_info(Protocol *protocol) { StringBuffer<256> tmp(log_cs); tmp.length(0); tmp.append(new_log_ident, ident_len); tmp.append(STRING_WITH_LEN(";pos=")); tmp.append_ulonglong(pos); protocol->store(tmp.ptr(), tmp.length(), &my_charset_bin); } #endif /* Rotate_log_event::print() */ #ifdef MYSQL_CLIENT bool Rotate_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { if (print_event_info->short_form) return 0; char buf[22]; Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); if (print_header(&cache, print_event_info, FALSE) || my_b_write_string(&cache, "\tRotate to ")) goto err; if (new_log_ident) if (my_b_write(&cache, (uchar*) new_log_ident, (uint)ident_len)) goto err; if (my_b_printf(&cache, " pos: %s\n", llstr(pos, buf))) goto err; return cache.flush_data(); err: return 1; } #endif /* MYSQL_CLIENT */ /* Rotate_log_event::Rotate_log_event() (2 constructors) */ #ifndef MYSQL_CLIENT Rotate_log_event::Rotate_log_event(const char* new_log_ident_arg, uint ident_len_arg, ulonglong pos_arg, uint flags_arg) :Log_event(), new_log_ident(new_log_ident_arg), pos(pos_arg),ident_len(ident_len_arg ? ident_len_arg : (uint) strlen(new_log_ident_arg)), flags(flags_arg) { DBUG_ENTER("Rotate_log_event::Rotate_log_event(...,flags)"); DBUG_PRINT("enter",("new_log_ident: %s pos: %llu flags: %lu", new_log_ident_arg, pos_arg, (ulong) flags)); cache_type= EVENT_NO_CACHE; if (flags & DUP_NAME) new_log_ident= my_strndup(new_log_ident_arg, ident_len, MYF(MY_WME)); if (flags & RELAY_LOG) set_relay_log_event(); DBUG_VOID_RETURN; } #endif Rotate_log_event::Rotate_log_event(const char* buf, uint event_len, const Format_description_log_event* description_event) :Log_event(buf, description_event) ,new_log_ident(0), flags(DUP_NAME) { DBUG_ENTER("Rotate_log_event::Rotate_log_event(char*,...)"); // The caller will ensure that event_len is what we have at EVENT_LEN_OFFSET uint8 post_header_len= description_event->post_header_len[ROTATE_EVENT-1]; uint ident_offset; if (event_len < (uint)(LOG_EVENT_MINIMAL_HEADER_LEN + post_header_len)) DBUG_VOID_RETURN; buf+= LOG_EVENT_MINIMAL_HEADER_LEN; pos= post_header_len ? uint8korr(buf + R_POS_OFFSET) : 4; ident_len= (uint)(event_len - (LOG_EVENT_MINIMAL_HEADER_LEN + post_header_len)); ident_offset= post_header_len; set_if_smaller(ident_len,FN_REFLEN-1); new_log_ident= my_strndup(buf + ident_offset, (uint) ident_len, MYF(MY_WME)); DBUG_PRINT("debug", ("new_log_ident: '%s'", new_log_ident)); DBUG_VOID_RETURN; } /* Rotate_log_event::write() */ #ifndef MYSQL_CLIENT bool Rotate_log_event::write() { char buf[ROTATE_HEADER_LEN]; int8store(buf + R_POS_OFFSET, pos); return (write_header(ROTATE_HEADER_LEN + ident_len) || write_data(buf, ROTATE_HEADER_LEN) || write_data(new_log_ident, (uint) ident_len) || write_footer()); } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /* Got a rotate log event from the master. This is mainly used so that we can later figure out the logname and position for the master. We can't rotate the slave's BINlog as this will cause infinitive rotations in a A -> B -> A setup. The NOTES below is a wrong comment which will disappear when 4.1 is merged. This must only be called from the Slave SQL thread, since it calls Relay_log_info::flush(). @retval 0 ok 1 error */ int Rotate_log_event::do_update_pos(rpl_group_info *rgi) { int error= 0; Relay_log_info *rli= rgi->rli; DBUG_ENTER("Rotate_log_event::do_update_pos"); DBUG_PRINT("info", ("server_id=%lu; ::server_id=%lu", (ulong) this->server_id, (ulong) global_system_variables.server_id)); DBUG_PRINT("info", ("new_log_ident: %s", this->new_log_ident)); DBUG_PRINT("info", ("pos: %llu", this->pos)); /* If we are in a transaction or in a group: the only normal case is when the I/O thread was copying a big transaction, then it was stopped and restarted: we have this in the relay log: BEGIN ... ROTATE (a fake one) ... COMMIT or ROLLBACK In that case, we don't want to touch the coordinates which correspond to the beginning of the transaction. Starting from 5.0.0, there also are some rotates from the slave itself, in the relay log, which shall not change the group positions. In parallel replication, rotate event is executed out-of-band with normal events, so we cannot update group_master_log_name or _pos here, it will be updated with the next normal event instead. */ if ((server_id != global_system_variables.server_id || rli->replicate_same_server_id) && !is_relay_log_event() && !rli->is_in_group() && !rgi->is_parallel_exec) { mysql_mutex_lock(&rli->data_lock); DBUG_PRINT("info", ("old group_master_log_name: '%s' " "old group_master_log_pos: %lu", rli->group_master_log_name, (ulong) rli->group_master_log_pos)); memcpy(rli->group_master_log_name, new_log_ident, ident_len+1); rli->notify_group_master_log_name_update(); rli->inc_group_relay_log_pos(pos, rgi, TRUE /* skip_lock */); DBUG_PRINT("info", ("new group_master_log_name: '%s' " "new group_master_log_pos: %lu", rli->group_master_log_name, (ulong) rli->group_master_log_pos)); mysql_mutex_unlock(&rli->data_lock); rpl_global_gtid_slave_state->record_and_update_gtid(thd, rgi); error= rli->flush(); /* Reset thd->variables.option_bits and sql_mode etc, because this could be the signal of a master's downgrade from 5.0 to 4.0. However, no need to reset description_event_for_exec: indeed, if the next master is 5.0 (even 5.0.1) we will soon get a Format_desc; if the next master is 4.0 then the events are in the slave's format (conversion). */ set_slave_thread_options(thd); set_slave_thread_default_charset(thd, rgi); thd->variables.sql_mode= global_system_variables.sql_mode; thd->variables.auto_increment_increment= thd->variables.auto_increment_offset= 1; } else rgi->inc_event_relay_log_pos(); DBUG_RETURN(error); } Log_event::enum_skip_reason Rotate_log_event::do_shall_skip(rpl_group_info *rgi) { enum_skip_reason reason= Log_event::do_shall_skip(rgi); switch (reason) { case Log_event::EVENT_SKIP_NOT: case Log_event::EVENT_SKIP_COUNT: return Log_event::EVENT_SKIP_NOT; case Log_event::EVENT_SKIP_IGNORE: return Log_event::EVENT_SKIP_IGNORE; } DBUG_ASSERT(0); return Log_event::EVENT_SKIP_NOT; // To keep compiler happy } #endif /************************************************************************** Binlog_checkpoint_log_event methods **************************************************************************/ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Binlog_checkpoint_log_event::pack_info(Protocol *protocol) { protocol->store(binlog_file_name, binlog_file_len, &my_charset_bin); } Log_event::enum_skip_reason Binlog_checkpoint_log_event::do_shall_skip(rpl_group_info *rgi) { enum_skip_reason reason= Log_event::do_shall_skip(rgi); if (reason == EVENT_SKIP_COUNT) reason= EVENT_SKIP_NOT; return reason; } #endif #ifdef MYSQL_CLIENT bool Binlog_checkpoint_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); if (print_header(&cache, print_event_info, FALSE) || my_b_write_string(&cache, "\tBinlog checkpoint ") || my_b_write(&cache, (uchar*)binlog_file_name, binlog_file_len) || my_b_write_byte(&cache, '\n')) return 1; return cache.flush_data(); } #endif /* MYSQL_CLIENT */ #ifdef MYSQL_SERVER Binlog_checkpoint_log_event::Binlog_checkpoint_log_event( const char *binlog_file_name_arg, uint binlog_file_len_arg) :Log_event(), binlog_file_name(my_strndup(binlog_file_name_arg, binlog_file_len_arg, MYF(MY_WME))), binlog_file_len(binlog_file_len_arg) { cache_type= EVENT_NO_CACHE; } #endif /* MYSQL_SERVER */ Binlog_checkpoint_log_event::Binlog_checkpoint_log_event( const char *buf, uint event_len, const Format_description_log_event *description_event) :Log_event(buf, description_event), binlog_file_name(0) { uint8 header_size= description_event->common_header_len; uint8 post_header_len= description_event->post_header_len[BINLOG_CHECKPOINT_EVENT-1]; if (event_len < (uint) header_size + (uint) post_header_len || post_header_len < BINLOG_CHECKPOINT_HEADER_LEN) return; buf+= header_size; /* See uint4korr and int4store below */ compile_time_assert(BINLOG_CHECKPOINT_HEADER_LEN == 4); binlog_file_len= uint4korr(buf); if (event_len - (header_size + post_header_len) < binlog_file_len) return; binlog_file_name= my_strndup(buf + post_header_len, binlog_file_len, MYF(MY_WME)); return; } #ifndef MYSQL_CLIENT bool Binlog_checkpoint_log_event::write() { uchar buf[BINLOG_CHECKPOINT_HEADER_LEN]; int4store(buf, binlog_file_len); return write_header(BINLOG_CHECKPOINT_HEADER_LEN + binlog_file_len) || write_data(buf, BINLOG_CHECKPOINT_HEADER_LEN) || write_data(binlog_file_name, binlog_file_len) || write_footer(); } #endif /* MYSQL_CLIENT */ /************************************************************************** Global transaction ID stuff **************************************************************************/ Gtid_log_event::Gtid_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Log_event(buf, description_event), seq_no(0), commit_id(0) { uint8 header_size= description_event->common_header_len; uint8 post_header_len= description_event->post_header_len[GTID_EVENT-1]; if (event_len < (uint) header_size + (uint) post_header_len || post_header_len < GTID_HEADER_LEN) return; buf+= header_size; seq_no= uint8korr(buf); buf+= 8; domain_id= uint4korr(buf); buf+= 4; flags2= *buf; if (flags2 & FL_GROUP_COMMIT_ID) { if (event_len < (uint)header_size + GTID_HEADER_LEN + 2) { seq_no= 0; // So is_valid() returns false return; } ++buf; commit_id= uint8korr(buf); } } #ifdef MYSQL_SERVER Gtid_log_event::Gtid_log_event(THD *thd_arg, uint64 seq_no_arg, uint32 domain_id_arg, bool standalone, uint16 flags_arg, bool is_transactional, uint64 commit_id_arg) : Log_event(thd_arg, flags_arg, is_transactional), seq_no(seq_no_arg), commit_id(commit_id_arg), domain_id(domain_id_arg), flags2((standalone ? FL_STANDALONE : 0) | (commit_id_arg ? FL_GROUP_COMMIT_ID : 0)) { cache_type= Log_event::EVENT_NO_CACHE; bool is_tmp_table= thd_arg->lex->stmt_accessed_temp_table(); if (thd_arg->transaction.stmt.trans_did_wait() || thd_arg->transaction.all.trans_did_wait()) flags2|= FL_WAITED; if (thd_arg->transaction.stmt.trans_did_ddl() || thd_arg->transaction.stmt.has_created_dropped_temp_table() || thd_arg->transaction.all.trans_did_ddl() || thd_arg->transaction.all.has_created_dropped_temp_table()) flags2|= FL_DDL; else if (is_transactional && !is_tmp_table) flags2|= FL_TRANSACTIONAL; if (!(thd_arg->variables.option_bits & OPTION_RPL_SKIP_PARALLEL)) flags2|= FL_ALLOW_PARALLEL; /* Preserve any DDL or WAITED flag in the slave's binlog. */ if (thd_arg->rgi_slave) flags2|= (thd_arg->rgi_slave->gtid_ev_flags2 & (FL_DDL|FL_WAITED)); } /* Used to record GTID while sending binlog to slave, without having to fully construct every Gtid_log_event() needlessly. */ bool Gtid_log_event::peek(const char *event_start, size_t event_len, enum enum_binlog_checksum_alg checksum_alg, uint32 *domain_id, uint32 *server_id, uint64 *seq_no, uchar *flags2, const Format_description_log_event *fdev) { const char *p; if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) { if (event_len > BINLOG_CHECKSUM_LEN) event_len-= BINLOG_CHECKSUM_LEN; else event_len= 0; } else DBUG_ASSERT(checksum_alg == BINLOG_CHECKSUM_ALG_UNDEF || checksum_alg == BINLOG_CHECKSUM_ALG_OFF); if (event_len < (uint32)fdev->common_header_len + GTID_HEADER_LEN) return true; *server_id= uint4korr(event_start + SERVER_ID_OFFSET); p= event_start + fdev->common_header_len; *seq_no= uint8korr(p); p+= 8; *domain_id= uint4korr(p); p+= 4; *flags2= (uchar)*p; return false; } bool Gtid_log_event::write() { uchar buf[GTID_HEADER_LEN+2]; size_t write_len; int8store(buf, seq_no); int4store(buf+8, domain_id); buf[12]= flags2; if (flags2 & FL_GROUP_COMMIT_ID) { int8store(buf+13, commit_id); write_len= GTID_HEADER_LEN + 2; } else { bzero(buf+13, GTID_HEADER_LEN-13); write_len= GTID_HEADER_LEN; } return write_header(write_len) || write_data(buf, write_len) || write_footer(); } /* Replace a GTID event with either a BEGIN event, dummy event, or nothing, as appropriate to work with old slave that does not know global transaction id. The need_dummy_event argument is an IN/OUT argument. It is passed as TRUE if slave has capability lower than MARIA_SLAVE_CAPABILITY_TOLERATE_HOLES. It is returned TRUE if we return a BEGIN (or dummy) event to be sent to the slave, FALSE if event should be skipped completely. */ int Gtid_log_event::make_compatible_event(String *packet, bool *need_dummy_event, ulong ev_offset, enum enum_binlog_checksum_alg checksum_alg) { uchar flags2; if (packet->length() - ev_offset < LOG_EVENT_HEADER_LEN + GTID_HEADER_LEN) return 1; flags2= (*packet)[ev_offset + LOG_EVENT_HEADER_LEN + 12]; if (flags2 & FL_STANDALONE) { if (*need_dummy_event) return Query_log_event::dummy_event(packet, ev_offset, checksum_alg); return 0; } *need_dummy_event= true; return Query_log_event::begin_event(packet, ev_offset, checksum_alg); } #ifdef HAVE_REPLICATION void Gtid_log_event::pack_info(Protocol *protocol) { char buf[6+5+10+1+10+1+20+1+4+20+1]; char *p; p = strmov(buf, (flags2 & FL_STANDALONE ? "GTID " : "BEGIN GTID ")); p= longlong10_to_str(domain_id, p, 10); *p++= '-'; p= longlong10_to_str(server_id, p, 10); *p++= '-'; p= longlong10_to_str(seq_no, p, 10); if (flags2 & FL_GROUP_COMMIT_ID) { p= strmov(p, " cid="); p= longlong10_to_str(commit_id, p, 10); } protocol->store(buf, p-buf, &my_charset_bin); } static char gtid_begin_string[] = "BEGIN"; int Gtid_log_event::do_apply_event(rpl_group_info *rgi) { ulonglong bits= thd->variables.option_bits; thd->variables.server_id= this->server_id; thd->variables.gtid_domain_id= this->domain_id; thd->variables.gtid_seq_no= this->seq_no; rgi->gtid_ev_flags2= flags2; thd->reset_for_next_command(); if (opt_gtid_strict_mode && opt_bin_log && opt_log_slave_updates) { if (mysql_bin_log.check_strict_gtid_sequence(this->domain_id, this->server_id, this->seq_no)) return 1; } DBUG_ASSERT((bits & OPTION_GTID_BEGIN) == 0); Master_info *mi=rgi->rli->mi; switch (flags2 & (FL_DDL | FL_TRANSACTIONAL)) { case FL_TRANSACTIONAL: mi->total_trans_groups++; break; case FL_DDL: mi->total_ddl_groups++; break; default: mi->total_non_trans_groups++; } if (flags2 & FL_STANDALONE) return 0; /* Execute this like a BEGIN query event. */ bits|= OPTION_GTID_BEGIN; if (flags2 & FL_ALLOW_PARALLEL) bits&= ~(ulonglong)OPTION_RPL_SKIP_PARALLEL; else bits|= (ulonglong)OPTION_RPL_SKIP_PARALLEL; thd->variables.option_bits= bits; DBUG_PRINT("info", ("Set OPTION_GTID_BEGIN")); thd->set_query_and_id(gtid_begin_string, sizeof(gtid_begin_string)-1, &my_charset_bin, next_query_id()); thd->lex->sql_command= SQLCOM_BEGIN; thd->is_slave_error= 0; status_var_increment(thd->status_var.com_stat[thd->lex->sql_command]); if (trans_begin(thd, 0)) { DBUG_PRINT("error", ("trans_begin() failed")); thd->is_slave_error= 1; } thd->update_stats(); if (likely(!thd->is_slave_error)) general_log_write(thd, COM_QUERY, thd->query(), thd->query_length()); thd->reset_query(); free_root(thd->mem_root,MYF(MY_KEEP_PREALLOC)); return thd->is_slave_error; } int Gtid_log_event::do_update_pos(rpl_group_info *rgi) { rgi->inc_event_relay_log_pos(); return 0; } Log_event::enum_skip_reason Gtid_log_event::do_shall_skip(rpl_group_info *rgi) { Relay_log_info *rli= rgi->rli; /* An event skipped due to @@skip_replication must not be counted towards the number of events to be skipped due to @@sql_slave_skip_counter. */ if (flags & LOG_EVENT_SKIP_REPLICATION_F && opt_replicate_events_marked_for_skip != RPL_SKIP_REPLICATE) return Log_event::EVENT_SKIP_IGNORE; if (rli->slave_skip_counter > 0) { if (!(flags2 & FL_STANDALONE)) { thd->variables.option_bits|= OPTION_BEGIN; DBUG_ASSERT(rgi->rli->get_flag(Relay_log_info::IN_TRANSACTION)); } return Log_event::continue_group(rgi); } return Log_event::do_shall_skip(rgi); } #endif /* HAVE_REPLICATION */ #else /* !MYSQL_SERVER */ bool Gtid_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F, this); char buf[21]; char buf2[21]; if (!print_event_info->short_form && !is_flashback) { print_header(&cache, print_event_info, FALSE); longlong10_to_str(seq_no, buf, 10); if (my_b_printf(&cache, "\tGTID %u-%u-%s", domain_id, server_id, buf)) goto err; if (flags2 & FL_GROUP_COMMIT_ID) { longlong10_to_str(commit_id, buf2, 10); if (my_b_printf(&cache, " cid=%s", buf2)) goto err; } if (flags2 & FL_DDL) if (my_b_write_string(&cache, " ddl")) goto err; if (flags2 & FL_TRANSACTIONAL) if (my_b_write_string(&cache, " trans")) goto err; if (flags2 & FL_WAITED) if (my_b_write_string(&cache, " waited")) goto err; if (my_b_printf(&cache, "\n")) goto err; if (!print_event_info->allow_parallel_printed || print_event_info->allow_parallel != !!(flags2 & FL_ALLOW_PARALLEL)) { if (my_b_printf(&cache, "/*!100101 SET @@session.skip_parallel_replication=%u*/%s\n", !(flags2 & FL_ALLOW_PARALLEL), print_event_info->delimiter)) goto err; print_event_info->allow_parallel= !!(flags2 & FL_ALLOW_PARALLEL); print_event_info->allow_parallel_printed= true; } if (!print_event_info->domain_id_printed || print_event_info->domain_id != domain_id) { if (my_b_printf(&cache, "/*!100001 SET @@session.gtid_domain_id=%u*/%s\n", domain_id, print_event_info->delimiter)) goto err; print_event_info->domain_id= domain_id; print_event_info->domain_id_printed= true; } if (!print_event_info->server_id_printed || print_event_info->server_id != server_id) { if (my_b_printf(&cache, "/*!100001 SET @@session.server_id=%u*/%s\n", server_id, print_event_info->delimiter)) goto err; print_event_info->server_id= server_id; print_event_info->server_id_printed= true; } if (!is_flashback) if (my_b_printf(&cache, "/*!100001 SET @@session.gtid_seq_no=%s*/%s\n", buf, print_event_info->delimiter)) goto err; } if (!(flags2 & FL_STANDALONE)) if (my_b_printf(&cache, is_flashback ? "COMMIT\n%s\n" : "START TRANSACTION\n%s\n", print_event_info->delimiter)) goto err; return cache.flush_data(); err: return 1; } #endif /* MYSQL_SERVER */ /* GTID list. */ Gtid_list_log_event::Gtid_list_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Log_event(buf, description_event), count(0), list(0), sub_id_list(0) { uint32 i; uint32 val; uint8 header_size= description_event->common_header_len; uint8 post_header_len= description_event->post_header_len[GTID_LIST_EVENT-1]; if (event_len < (uint) header_size + (uint) post_header_len || post_header_len < GTID_LIST_HEADER_LEN) return; buf+= header_size; val= uint4korr(buf); count= val & ((1<<28)-1); gl_flags= val & ((uint32)0xf << 28); buf+= 4; if (event_len - (header_size + post_header_len) < count*element_size || (!(list= (rpl_gtid *)my_malloc(count*sizeof(*list) + (count == 0), MYF(MY_WME))))) return; for (i= 0; i < count; ++i) { list[i].domain_id= uint4korr(buf); buf+= 4; list[i].server_id= uint4korr(buf); buf+= 4; list[i].seq_no= uint8korr(buf); buf+= 8; } #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) if ((gl_flags & FLAG_IGN_GTIDS)) { uint32 i; if (!(sub_id_list= (uint64 *)my_malloc(count*sizeof(uint64), MYF(MY_WME)))) { my_free(list); list= NULL; return; } for (i= 0; i < count; ++i) { if (!(sub_id_list[i]= rpl_global_gtid_slave_state->next_sub_id(list[i].domain_id))) { my_free(list); my_free(sub_id_list); list= NULL; sub_id_list= NULL; return; } } } #endif } #ifdef MYSQL_SERVER Gtid_list_log_event::Gtid_list_log_event(rpl_binlog_state *gtid_set, uint32 gl_flags_) : count(gtid_set->count()), gl_flags(gl_flags_), list(0), sub_id_list(0) { cache_type= EVENT_NO_CACHE; /* Failure to allocate memory will be caught by is_valid() returning false. */ if (count < (1<<28) && (list = (rpl_gtid *)my_malloc(count * sizeof(*list) + (count == 0), MYF(MY_WME)))) gtid_set->get_gtid_list(list, count); } Gtid_list_log_event::Gtid_list_log_event(slave_connection_state *gtid_set, uint32 gl_flags_) : count(gtid_set->count()), gl_flags(gl_flags_), list(0), sub_id_list(0) { cache_type= EVENT_NO_CACHE; /* Failure to allocate memory will be caught by is_valid() returning false. */ if (count < (1<<28) && (list = (rpl_gtid *)my_malloc(count * sizeof(*list) + (count == 0), MYF(MY_WME)))) { gtid_set->get_gtid_list(list, count); #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) if (gl_flags & FLAG_IGN_GTIDS) { uint32 i; if (!(sub_id_list= (uint64 *)my_malloc(count * sizeof(uint64), MYF(MY_WME)))) { my_free(list); list= NULL; return; } for (i= 0; i < count; ++i) { if (!(sub_id_list[i]= rpl_global_gtid_slave_state->next_sub_id(list[i].domain_id))) { my_free(list); my_free(sub_id_list); list= NULL; sub_id_list= NULL; return; } } } #endif } } #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) bool Gtid_list_log_event::to_packet(String *packet) { uint32 i; uchar *p; uint32 needed_length; DBUG_ASSERT(count < 1<<28); needed_length= packet->length() + get_data_size(); if (packet->reserve(needed_length)) return true; p= (uchar *)packet->ptr() + packet->length();; packet->length(needed_length); int4store(p, (count & ((1<<28)-1)) | gl_flags); p += 4; /* Initialise the padding for empty Gtid_list. */ if (count == 0) int2store(p, 0); for (i= 0; i < count; ++i) { int4store(p, list[i].domain_id); int4store(p+4, list[i].server_id); int8store(p+8, list[i].seq_no); p += 16; } return false; } bool Gtid_list_log_event::write() { char buf[128]; String packet(buf, sizeof(buf), system_charset_info); packet.length(0); if (to_packet(&packet)) return true; return write_header(get_data_size()) || write_data(packet.ptr(), packet.length()) || write_footer(); } int Gtid_list_log_event::do_apply_event(rpl_group_info *rgi) { Relay_log_info *rli= const_cast(rgi->rli); int ret; if (gl_flags & FLAG_IGN_GTIDS) { void *hton= NULL; uint32 i; for (i= 0; i < count; ++i) { if ((ret= rpl_global_gtid_slave_state->record_gtid(thd, &list[i], sub_id_list[i], false, false, &hton))) return ret; rpl_global_gtid_slave_state->update_state_hash(sub_id_list[i], &list[i], hton, NULL); } } ret= Log_event::do_apply_event(rgi); if (rli->until_condition == Relay_log_info::UNTIL_GTID && (gl_flags & FLAG_UNTIL_REACHED)) { char str_buf[128]; String str(str_buf, sizeof(str_buf), system_charset_info); rli->until_gtid_pos.to_string(&str); sql_print_information("Slave SQL thread stops because it reached its" " UNTIL master_gtid_pos %s", str.c_ptr_safe()); rli->abort_slave= true; rli->stop_for_until= true; } free_root(thd->mem_root, MYF(MY_KEEP_PREALLOC)); return ret; } Log_event::enum_skip_reason Gtid_list_log_event::do_shall_skip(rpl_group_info *rgi) { enum_skip_reason reason= Log_event::do_shall_skip(rgi); if (reason == EVENT_SKIP_COUNT) reason= EVENT_SKIP_NOT; return reason; } void Gtid_list_log_event::pack_info(Protocol *protocol) { char buf_mem[1024]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); uint32 i; bool first; buf.length(0); buf.append(STRING_WITH_LEN("[")); first= true; for (i= 0; i < count; ++i) rpl_slave_state_tostring_helper(&buf, &list[i], &first); buf.append(STRING_WITH_LEN("]")); protocol->store(&buf); } #endif /* HAVE_REPLICATION */ #else /* !MYSQL_SERVER */ bool Gtid_list_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); char buf[21]; uint32 i; if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\tGtid list [")) goto err; for (i= 0; i < count; ++i) { longlong10_to_str(list[i].seq_no, buf, 10); if (my_b_printf(&cache, "%u-%u-%s", list[i].domain_id, list[i].server_id, buf)) goto err; if (i < count-1) if (my_b_printf(&cache, ",\n# ")) goto err; } if (my_b_printf(&cache, "]\n")) goto err; return cache.flush_data(); err: return 1; } #endif /* MYSQL_SERVER */ /* Used to record gtid_list event while sending binlog to slave, without having to fully construct the event object. */ bool Gtid_list_log_event::peek(const char *event_start, size_t event_len, enum enum_binlog_checksum_alg checksum_alg, rpl_gtid **out_gtid_list, uint32 *out_list_len, const Format_description_log_event *fdev) { const char *p; uint32 count_field, count; rpl_gtid *gtid_list; if (checksum_alg == BINLOG_CHECKSUM_ALG_CRC32) { if (event_len > BINLOG_CHECKSUM_LEN) event_len-= BINLOG_CHECKSUM_LEN; else event_len= 0; } else DBUG_ASSERT(checksum_alg == BINLOG_CHECKSUM_ALG_UNDEF || checksum_alg == BINLOG_CHECKSUM_ALG_OFF); if (event_len < (uint32)fdev->common_header_len + GTID_LIST_HEADER_LEN) return true; p= event_start + fdev->common_header_len; count_field= uint4korr(p); p+= 4; count= count_field & ((1<<28)-1); if (event_len < (uint32)fdev->common_header_len + GTID_LIST_HEADER_LEN + 16 * count) return true; if (!(gtid_list= (rpl_gtid *)my_malloc(sizeof(rpl_gtid)*count + (count == 0), MYF(MY_WME)))) return true; *out_gtid_list= gtid_list; *out_list_len= count; while (count--) { gtid_list->domain_id= uint4korr(p); p+= 4; gtid_list->server_id= uint4korr(p); p+= 4; gtid_list->seq_no= uint8korr(p); p+= 8; ++gtid_list; } return false; } /************************************************************************** Intvar_log_event methods **************************************************************************/ /* Intvar_log_event::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Intvar_log_event::pack_info(Protocol *protocol) { char buf[256], *pos; pos= strmake(buf, get_var_type_name(), sizeof(buf)-23); *pos++= '='; pos= longlong10_to_str(val, pos, -10); protocol->store(buf, (uint) (pos-buf), &my_charset_bin); } #endif /* Intvar_log_event::Intvar_log_event() */ Intvar_log_event::Intvar_log_event(const char* buf, const Format_description_log_event* description_event) :Log_event(buf, description_event) { /* The Post-Header is empty. The Variable Data part begins immediately. */ buf+= description_event->common_header_len + description_event->post_header_len[INTVAR_EVENT-1]; type= buf[I_TYPE_OFFSET]; val= uint8korr(buf+I_VAL_OFFSET); } /* Intvar_log_event::get_var_type_name() */ const char* Intvar_log_event::get_var_type_name() { switch(type) { case LAST_INSERT_ID_EVENT: return "LAST_INSERT_ID"; case INSERT_ID_EVENT: return "INSERT_ID"; default: /* impossible */ return "UNKNOWN"; } } /* Intvar_log_event::write() */ #ifndef MYSQL_CLIENT bool Intvar_log_event::write() { uchar buf[9]; buf[I_TYPE_OFFSET]= (uchar) type; int8store(buf + I_VAL_OFFSET, val); return write_header(sizeof(buf)) || write_data(buf, sizeof(buf)) || write_footer(); } #endif /* Intvar_log_event::print() */ #ifdef MYSQL_CLIENT bool Intvar_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { char llbuff[22]; const char *UNINIT_VAR(msg); Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); if (!print_event_info->short_form) { if (print_header(&cache, print_event_info, FALSE) || my_b_write_string(&cache, "\tIntvar\n")) goto err; } if (my_b_printf(&cache, "SET ")) goto err; switch (type) { case LAST_INSERT_ID_EVENT: msg="LAST_INSERT_ID"; break; case INSERT_ID_EVENT: msg="INSERT_ID"; break; case INVALID_INT_EVENT: default: // cannot happen msg="INVALID_INT"; break; } if (my_b_printf(&cache, "%s=%s%s\n", msg, llstr(val,llbuff), print_event_info->delimiter)) goto err; return cache.flush_data(); err: return 1; } #endif #if defined(HAVE_REPLICATION)&& !defined(MYSQL_CLIENT) /* Intvar_log_event::do_apply_event() */ int Intvar_log_event::do_apply_event(rpl_group_info *rgi) { DBUG_ENTER("Intvar_log_event::do_apply_event"); if (rgi->deferred_events_collecting) { DBUG_PRINT("info",("deferring event")); DBUG_RETURN(rgi->deferred_events->add(this)); } switch (type) { case LAST_INSERT_ID_EVENT: thd->first_successful_insert_id_in_prev_stmt= val; DBUG_PRINT("info",("last_insert_id_event: %ld", (long) val)); break; case INSERT_ID_EVENT: thd->force_one_auto_inc_interval(val); break; } DBUG_RETURN(0); } int Intvar_log_event::do_update_pos(rpl_group_info *rgi) { rgi->inc_event_relay_log_pos(); return 0; } Log_event::enum_skip_reason Intvar_log_event::do_shall_skip(rpl_group_info *rgi) { /* It is a common error to set the slave skip counter to 1 instead of 2 when recovering from an insert which used a auto increment, rand, or user var. Therefore, if the slave skip counter is 1, we just say that this event should be skipped by ignoring it, meaning that we do not change the value of the slave skip counter since it will be decreased by the following insert event. */ return continue_group(rgi); } #endif /************************************************************************** Rand_log_event methods **************************************************************************/ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Rand_log_event::pack_info(Protocol *protocol) { char buf1[256], *pos; pos= strmov(buf1,"rand_seed1="); pos= int10_to_str((long) seed1, pos, 10); pos= strmov(pos, ",rand_seed2="); pos= int10_to_str((long) seed2, pos, 10); protocol->store(buf1, (uint) (pos-buf1), &my_charset_bin); } #endif Rand_log_event::Rand_log_event(const char* buf, const Format_description_log_event* description_event) :Log_event(buf, description_event) { /* The Post-Header is empty. The Variable Data part begins immediately. */ buf+= description_event->common_header_len + description_event->post_header_len[RAND_EVENT-1]; seed1= uint8korr(buf+RAND_SEED1_OFFSET); seed2= uint8korr(buf+RAND_SEED2_OFFSET); } #ifndef MYSQL_CLIENT bool Rand_log_event::write() { uchar buf[16]; int8store(buf + RAND_SEED1_OFFSET, seed1); int8store(buf + RAND_SEED2_OFFSET, seed2); return write_header(sizeof(buf)) || write_data(buf, sizeof(buf)) || write_footer(); } #endif #ifdef MYSQL_CLIENT bool Rand_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); char llbuff[22],llbuff2[22]; if (!print_event_info->short_form) { if (print_header(&cache, print_event_info, FALSE) || my_b_write_string(&cache, "\tRand\n")) goto err; } if (my_b_printf(&cache, "SET @@RAND_SEED1=%s, @@RAND_SEED2=%s%s\n", llstr(seed1, llbuff),llstr(seed2, llbuff2), print_event_info->delimiter)) goto err; return cache.flush_data(); err: return 1; } #endif /* MYSQL_CLIENT */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Rand_log_event::do_apply_event(rpl_group_info *rgi) { if (rgi->deferred_events_collecting) return rgi->deferred_events->add(this); thd->rand.seed1= (ulong) seed1; thd->rand.seed2= (ulong) seed2; return 0; } int Rand_log_event::do_update_pos(rpl_group_info *rgi) { rgi->inc_event_relay_log_pos(); return 0; } Log_event::enum_skip_reason Rand_log_event::do_shall_skip(rpl_group_info *rgi) { /* It is a common error to set the slave skip counter to 1 instead of 2 when recovering from an insert which used a auto increment, rand, or user var. Therefore, if the slave skip counter is 1, we just say that this event should be skipped by ignoring it, meaning that we do not change the value of the slave skip counter since it will be decreased by the following insert event. */ return continue_group(rgi); } /** Exec deferred Int-, Rand- and User- var events prefixing a Query-log-event event. @param thd THD handle @return false on success, true if a failure in an event applying occurred. */ bool slave_execute_deferred_events(THD *thd) { bool res= false; rpl_group_info *rgi= thd->rgi_slave; DBUG_ASSERT(rgi && (!rgi->deferred_events_collecting || rgi->deferred_events)); if (!rgi->deferred_events_collecting || rgi->deferred_events->is_empty()) return res; res= rgi->deferred_events->execute(rgi); rgi->deferred_events->rewind(); return res; } #endif /* !MYSQL_CLIENT */ /************************************************************************** Xid_log_event methods **************************************************************************/ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Xid_log_event::pack_info(Protocol *protocol) { char buf[128], *pos; pos= strmov(buf, "COMMIT /* xid="); pos= longlong10_to_str(xid, pos, 10); pos= strmov(pos, " */"); protocol->store(buf, (uint) (pos-buf), &my_charset_bin); } #endif /** @note It's ok not to use int8store here, as long as xid_t::set(ulonglong) and xid_t::get_my_xid doesn't do it either. We don't care about actual values of xids as long as identical numbers compare identically */ Xid_log_event:: Xid_log_event(const char* buf, const Format_description_log_event *description_event) :Log_event(buf, description_event) { /* The Post-Header is empty. The Variable Data part begins immediately. */ buf+= description_event->common_header_len + description_event->post_header_len[XID_EVENT-1]; memcpy((char*) &xid, buf, sizeof(xid)); } #ifndef MYSQL_CLIENT bool Xid_log_event::write() { DBUG_EXECUTE_IF("do_not_write_xid", return 0;); return write_header(sizeof(xid)) || write_data((uchar*)&xid, sizeof(xid)) || write_footer(); } #endif #ifdef MYSQL_CLIENT bool Xid_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F, this); if (!print_event_info->short_form) { char buf[64]; longlong10_to_str(xid, buf, 10); if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\tXid = %s\n", buf)) goto err; } if (my_b_printf(&cache, is_flashback ? "START TRANSACTION%s\n" : "COMMIT%s\n", print_event_info->delimiter)) goto err; return cache.flush_data(); err: return 1; } #endif /* MYSQL_CLIENT */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Xid_log_event::do_apply_event(rpl_group_info *rgi) { bool res; int err; rpl_gtid gtid; uint64 sub_id= 0; Relay_log_info const *rli= rgi->rli; void *hton= NULL; /* XID_EVENT works like a COMMIT statement. And it also updates the mysql.gtid_slave_pos table with the GTID of the current transaction. Therefore, it acts much like a normal SQL statement, so we need to do THD::reset_for_next_command() as if starting a new statement. */ thd->reset_for_next_command(); /* Record any GTID in the same transaction, so slave state is transactionally consistent. */ #ifdef WITH_WSREP thd->wsrep_affected_rows= 0; #endif if (rgi->gtid_pending) { sub_id= rgi->gtid_sub_id; rgi->gtid_pending= false; gtid= rgi->current_gtid; err= rpl_global_gtid_slave_state->record_gtid(thd, >id, sub_id, true, false, &hton); if (unlikely(err)) { int ec= thd->get_stmt_da()->sql_errno(); /* Do not report an error if this is really a kill due to a deadlock. In this case, the transaction will be re-tried instead. */ if (!is_parallel_retry_error(rgi, ec)) rli->report(ERROR_LEVEL, ER_CANNOT_UPDATE_GTID_STATE, rgi->gtid_info(), "Error during XID COMMIT: failed to update GTID state in " "%s.%s: %d: %s", "mysql", rpl_gtid_slave_state_table_name.str, ec, thd->get_stmt_da()->message()); thd->is_slave_error= 1; return err; } DBUG_EXECUTE_IF("gtid_fail_after_record_gtid", { my_error(ER_ERROR_DURING_COMMIT, MYF(0), HA_ERR_WRONG_COMMAND); thd->is_slave_error= 1; return 1; }); } /* For a slave Xid_log_event is COMMIT */ general_log_print(thd, COM_QUERY, "COMMIT /* implicit, from Xid_log_event */"); thd->variables.option_bits&= ~OPTION_GTID_BEGIN; res= trans_commit(thd); /* Automatically rolls back on error. */ thd->release_transactional_locks(); #ifdef WITH_WSREP if (WSREP(thd)) mysql_mutex_lock(&thd->LOCK_thd_data); if ((!res || (WSREP(thd) && thd->wsrep_trx().state() == wsrep::transaction::s_must_replay )) && sub_id) #else if (likely(!res) && sub_id) #endif /* WITH_WSREP */ rpl_global_gtid_slave_state->update_state_hash(sub_id, >id, hton, rgi); #ifdef WITH_WSREP if (WSREP(thd)) mysql_mutex_unlock(&thd->LOCK_thd_data); #endif /* WITH_WSREP */ /* Increment the global status commit count variable */ status_var_increment(thd->status_var.com_stat[SQLCOM_COMMIT]); return res; } Log_event::enum_skip_reason Xid_log_event::do_shall_skip(rpl_group_info *rgi) { DBUG_ENTER("Xid_log_event::do_shall_skip"); if (rgi->rli->slave_skip_counter > 0) { DBUG_ASSERT(!rgi->rli->get_flag(Relay_log_info::IN_TRANSACTION)); thd->variables.option_bits&= ~(OPTION_BEGIN | OPTION_GTID_BEGIN); DBUG_RETURN(Log_event::EVENT_SKIP_COUNT); } #ifdef WITH_WSREP else if (WSREP(thd) && wsrep_mysql_replication_bundle && opt_slave_domain_parallel_threads == 0) { if (++thd->wsrep_mysql_replicated < (int)wsrep_mysql_replication_bundle) { WSREP_DEBUG("skipping wsrep commit %d", thd->wsrep_mysql_replicated); DBUG_RETURN(Log_event::EVENT_SKIP_IGNORE); } else { thd->wsrep_mysql_replicated = 0; } } #endif DBUG_RETURN(Log_event::do_shall_skip(rgi)); } #endif /* !MYSQL_CLIENT */ /************************************************************************** User_var_log_event methods **************************************************************************/ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) static bool user_var_append_name_part(THD *thd, String *buf, const char *name, size_t name_len) { return buf->append("@") || append_identifier(thd, buf, name, name_len) || buf->append("="); } void User_var_log_event::pack_info(Protocol* protocol) { if (is_null) { char buf_mem[FN_REFLEN+7]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); buf.length(0); if (user_var_append_name_part(protocol->thd, &buf, name, name_len) || buf.append("NULL")) return; protocol->store(buf.ptr(), buf.length(), &my_charset_bin); } else { switch (type) { case REAL_RESULT: { double real_val; char buf2[MY_GCVT_MAX_FIELD_WIDTH+1]; char buf_mem[FN_REFLEN + MY_GCVT_MAX_FIELD_WIDTH + 1]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); float8get(real_val, val); buf.length(0); if (user_var_append_name_part(protocol->thd, &buf, name, name_len) || buf.append(buf2, my_gcvt(real_val, MY_GCVT_ARG_DOUBLE, MY_GCVT_MAX_FIELD_WIDTH, buf2, NULL))) return; protocol->store(buf.ptr(), buf.length(), &my_charset_bin); break; } case INT_RESULT: { char buf2[22]; char buf_mem[FN_REFLEN + 22]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); buf.length(0); if (user_var_append_name_part(protocol->thd, &buf, name, name_len) || buf.append(buf2, longlong10_to_str(uint8korr(val), buf2, ((flags & User_var_log_event::UNSIGNED_F) ? 10 : -10))-buf2)) return; protocol->store(buf.ptr(), buf.length(), &my_charset_bin); break; } case DECIMAL_RESULT: { char buf_mem[FN_REFLEN + DECIMAL_MAX_STR_LENGTH]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); char buf2[DECIMAL_MAX_STR_LENGTH+1]; String str(buf2, sizeof(buf2), &my_charset_bin); buf.length(0); my_decimal((const uchar *) (val + 2), val[0], val[1]).to_string(&str); if (user_var_append_name_part(protocol->thd, &buf, name, name_len) || buf.append(buf2)) return; protocol->store(buf.ptr(), buf.length(), &my_charset_bin); break; } case STRING_RESULT: { /* 15 is for 'COLLATE' and other chars */ char buf_mem[FN_REFLEN + 512 + 1 + 2*MY_CS_NAME_SIZE+15]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); CHARSET_INFO *cs; buf.length(0); if (!(cs= get_charset(charset_number, MYF(0)))) { if (buf.append("???")) return; } else { size_t old_len; char *beg, *end; if (user_var_append_name_part(protocol->thd, &buf, name, name_len) || buf.append("_") || buf.append(cs->csname) || buf.append(" ")) return; old_len= buf.length(); if (buf.reserve(old_len + val_len * 2 + 3 + sizeof(" COLLATE ") + MY_CS_NAME_SIZE)) return; beg= const_cast(buf.ptr()) + old_len; end= str_to_hex(beg, val, val_len); buf.length(old_len + (end - beg)); if (buf.append(" COLLATE ") || buf.append(cs->name)) return; } protocol->store(buf.ptr(), buf.length(), &my_charset_bin); break; } case ROW_RESULT: default: DBUG_ASSERT(0); return; } } } #endif /* !MYSQL_CLIENT */ User_var_log_event:: User_var_log_event(const char* buf, uint event_len, const Format_description_log_event* description_event) :Log_event(buf, description_event) #ifndef MYSQL_CLIENT , deferred(false), query_id(0) #endif { bool error= false; const char* buf_start= buf, *buf_end= buf + event_len; /* The Post-Header is empty. The Variable Data part begins immediately. */ buf+= description_event->common_header_len + description_event->post_header_len[USER_VAR_EVENT-1]; name_len= uint4korr(buf); /* Avoid reading out of buffer */ if ((buf - buf_start) + UV_NAME_LEN_SIZE + name_len > event_len) { error= true; goto err; } name= (char *) buf + UV_NAME_LEN_SIZE; /* We don't know yet is_null value, so we must assume that name_len may have the bigger value possible, is_null= True and there is no payload for val, or even that name_len is 0. */ if (name + name_len + UV_VAL_IS_NULL > buf_end) { error= true; goto err; } buf+= UV_NAME_LEN_SIZE + name_len; is_null= (bool) *buf; flags= User_var_log_event::UNDEF_F; // defaults to UNDEF_F if (is_null) { type= STRING_RESULT; charset_number= my_charset_bin.number; val_len= 0; val= 0; } else { val= (char *) (buf + UV_VAL_IS_NULL + UV_VAL_TYPE_SIZE + UV_CHARSET_NUMBER_SIZE + UV_VAL_LEN_SIZE); if (val > buf_end) { error= true; goto err; } type= (Item_result) buf[UV_VAL_IS_NULL]; charset_number= uint4korr(buf + UV_VAL_IS_NULL + UV_VAL_TYPE_SIZE); val_len= uint4korr(buf + UV_VAL_IS_NULL + UV_VAL_TYPE_SIZE + UV_CHARSET_NUMBER_SIZE); /** We need to check if this is from an old server that did not pack information for flags. We do this by checking if there are extra bytes after the packed value. If there are we take the extra byte and it's value is assumed to contain the flags value. Old events will not have this extra byte, thence, we keep the flags set to UNDEF_F. */ size_t bytes_read= (val + val_len) - buf_start; if (bytes_read > event_len) { error= true; goto err; } if ((data_written - bytes_read) > 0) { flags= (uint) *(buf + UV_VAL_IS_NULL + UV_VAL_TYPE_SIZE + UV_CHARSET_NUMBER_SIZE + UV_VAL_LEN_SIZE + val_len); } } err: if (unlikely(error)) name= 0; } #ifndef MYSQL_CLIENT bool User_var_log_event::write() { char buf[UV_NAME_LEN_SIZE]; char buf1[UV_VAL_IS_NULL + UV_VAL_TYPE_SIZE + UV_CHARSET_NUMBER_SIZE + UV_VAL_LEN_SIZE]; uchar buf2[MY_MAX(8, DECIMAL_MAX_FIELD_SIZE + 2)], *pos= buf2; uint unsigned_len= 0; uint buf1_length; size_t event_length; int4store(buf, name_len); if ((buf1[0]= is_null)) { buf1_length= 1; val_len= 0; // Length of 'pos' } else { buf1[1]= type; int4store(buf1 + 2, charset_number); switch (type) { case REAL_RESULT: float8store(buf2, *(double*) val); break; case INT_RESULT: int8store(buf2, *(longlong*) val); unsigned_len= 1; break; case DECIMAL_RESULT: { my_decimal *dec= (my_decimal *)val; dec->fix_buffer_pointer(); buf2[0]= (char)(dec->intg + dec->frac); buf2[1]= (char)dec->frac; decimal2bin((decimal_t*)val, buf2+2, buf2[0], buf2[1]); val_len= decimal_bin_size(buf2[0], buf2[1]) + 2; break; } case STRING_RESULT: pos= (uchar*) val; break; case ROW_RESULT: default: DBUG_ASSERT(0); return 0; } int4store(buf1 + 2 + UV_CHARSET_NUMBER_SIZE, val_len); buf1_length= 10; } /* Length of the whole event */ event_length= sizeof(buf)+ name_len + buf1_length + val_len + unsigned_len; return write_header(event_length) || write_data(buf, sizeof(buf)) || write_data(name, name_len) || write_data(buf1, buf1_length) || write_data(pos, val_len) || write_data(&flags, unsigned_len) || write_footer(); } #endif /* User_var_log_event::print() */ #ifdef MYSQL_CLIENT bool User_var_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F); if (!print_event_info->short_form) { if (print_header(&cache, print_event_info, FALSE) || my_b_write_string(&cache, "\tUser_var\n")) goto err; } if (my_b_write_string(&cache, "SET @") || my_b_write_backtick_quote(&cache, name, name_len)) goto err; if (is_null) { if (my_b_printf(&cache, ":=NULL%s\n", print_event_info->delimiter)) goto err; } else { switch (type) { case REAL_RESULT: double real_val; char real_buf[FMT_G_BUFSIZE(14)]; float8get(real_val, val); sprintf(real_buf, "%.14g", real_val); if (my_b_printf(&cache, ":=%s%s\n", real_buf, print_event_info->delimiter)) goto err; break; case INT_RESULT: char int_buf[22]; longlong10_to_str(uint8korr(val), int_buf, ((flags & User_var_log_event::UNSIGNED_F) ? 10 : -10)); if (my_b_printf(&cache, ":=%s%s\n", int_buf, print_event_info->delimiter)) goto err; break; case DECIMAL_RESULT: { char str_buf[200]; int str_len= sizeof(str_buf) - 1; int precision= (int)val[0]; int scale= (int)val[1]; decimal_digit_t dec_buf[10]; decimal_t dec; dec.len= 10; dec.buf= dec_buf; bin2decimal((uchar*) val+2, &dec, precision, scale); decimal2string(&dec, str_buf, &str_len, 0, 0, 0); str_buf[str_len]= 0; if (my_b_printf(&cache, ":=%s%s\n", str_buf, print_event_info->delimiter)) goto err; break; } case STRING_RESULT: { /* Let's express the string in hex. That's the most robust way. If we print it in character form instead, we need to escape it with character_set_client which we don't know (we will know it in 5.0, but in 4.1 we don't know it easily when we are printing User_var_log_event). Explanation why we would need to bother with character_set_client (quoting Bar): > Note, the parser doesn't switch to another unescaping mode after > it has met a character set introducer. > For example, if an SJIS client says something like: > SET @a= _ucs2 \0a\0b' > the string constant is still unescaped according to SJIS, not > according to UCS2. */ char *hex_str; CHARSET_INFO *cs; bool error; // 2 hex digits / byte hex_str= (char *) my_malloc(2 * val_len + 1 + 3, MYF(MY_WME)); if (!hex_str) goto err; str_to_hex(hex_str, val, val_len); /* For proper behaviour when mysqlbinlog|mysql, we need to explicitly specify the variable's collation. It will however cause problems when people want to mysqlbinlog|mysql into another server not supporting the character set. But there's not much to do about this and it's unlikely. */ if (!(cs= get_charset(charset_number, MYF(0)))) { /* Generate an unusable command (=> syntax error) is probably the best thing we can do here. */ error= my_b_printf(&cache, ":=???%s\n", print_event_info->delimiter); } else error= my_b_printf(&cache, ":=_%s %s COLLATE `%s`%s\n", cs->csname, hex_str, cs->name, print_event_info->delimiter); my_free(hex_str); if (unlikely(error)) goto err; break; } case ROW_RESULT: default: DBUG_ASSERT(0); break; } } return cache.flush_data(); err: return 1; } #endif /* User_var_log_event::do_apply_event() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int User_var_log_event::do_apply_event(rpl_group_info *rgi) { Item *it= 0; CHARSET_INFO *charset; DBUG_ENTER("User_var_log_event::do_apply_event"); query_id_t sav_query_id= 0; /* memorize orig id when deferred applying */ if (rgi->deferred_events_collecting) { set_deferred(current_thd->query_id); DBUG_RETURN(rgi->deferred_events->add(this)); } else if (is_deferred()) { sav_query_id= current_thd->query_id; current_thd->query_id= query_id; /* recreating original time context */ } if (!(charset= get_charset(charset_number, MYF(MY_WME)))) { rgi->rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "Invalid character set for User var event"); DBUG_RETURN(1); } LEX_CSTRING user_var_name; user_var_name.str= name; user_var_name.length= name_len; double real_val; longlong int_val; if (is_null) { it= new (thd->mem_root) Item_null(thd); } else { switch (type) { case REAL_RESULT: if (val_len != 8) { rgi->rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "Invalid variable length at User var event"); return 1; } float8get(real_val, val); it= new (thd->mem_root) Item_float(thd, real_val, 0); val= (char*) &real_val; // Pointer to value in native format val_len= 8; break; case INT_RESULT: if (val_len != 8) { rgi->rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "Invalid variable length at User var event"); return 1; } int_val= (longlong) uint8korr(val); it= new (thd->mem_root) Item_int(thd, int_val); val= (char*) &int_val; // Pointer to value in native format val_len= 8; break; case DECIMAL_RESULT: { if (val_len < 3) { rgi->rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, ER_THD(thd, ER_SLAVE_FATAL_ERROR), "Invalid variable length at User var event"); return 1; } Item_decimal *dec= new (thd->mem_root) Item_decimal(thd, (uchar*) val+2, val[0], val[1]); it= dec; val= (char *)dec->val_decimal(NULL); val_len= sizeof(my_decimal); break; } case STRING_RESULT: it= new (thd->mem_root) Item_string(thd, val, (uint)val_len, charset); break; case ROW_RESULT: default: DBUG_ASSERT(0); DBUG_RETURN(0); } } Item_func_set_user_var *e= new (thd->mem_root) Item_func_set_user_var(thd, &user_var_name, it); /* Item_func_set_user_var can't substitute something else on its place => 0 can be passed as last argument (reference on item) Fix_fields() can fail, in which case a call of update_hash() might crash the server, so if fix fields fails, we just return with an error. */ if (e->fix_fields(thd, 0)) DBUG_RETURN(1); /* A variable can just be considered as a table with a single record and with a single column. Thus, like a column value, it could always have IMPLICIT derivation. */ e->update_hash((void*) val, val_len, type, charset, (flags & User_var_log_event::UNSIGNED_F)); if (!is_deferred()) free_root(thd->mem_root, 0); else current_thd->query_id= sav_query_id; /* restore current query's context */ DBUG_RETURN(0); } int User_var_log_event::do_update_pos(rpl_group_info *rgi) { rgi->inc_event_relay_log_pos(); return 0; } Log_event::enum_skip_reason User_var_log_event::do_shall_skip(rpl_group_info *rgi) { /* It is a common error to set the slave skip counter to 1 instead of 2 when recovering from an insert which used a auto increment, rand, or user var. Therefore, if the slave skip counter is 1, we just say that this event should be skipped by ignoring it, meaning that we do not change the value of the slave skip counter since it will be decreased by the following insert event. */ return continue_group(rgi); } #endif /* !MYSQL_CLIENT */ #ifdef HAVE_REPLICATION #ifdef MYSQL_CLIENT bool Unknown_log_event::print(FILE* file_arg, PRINT_EVENT_INFO* print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file_arg); if (what != ENCRYPTED) { if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\n# Unknown event\n")) goto err; } else if (my_b_printf(&cache, "# Encrypted event\n")) goto err; return cache.flush_data(); err: return 1; } #endif /************************************************************************** Stop_log_event methods **************************************************************************/ /* Stop_log_event::print() */ #ifdef MYSQL_CLIENT bool Stop_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file, Write_on_release_cache::FLUSH_F, this); if (print_header(&cache, print_event_info, FALSE) || my_b_write_string(&cache, "\tStop\n")) return 1; return cache.flush_data(); } #endif /* MYSQL_CLIENT */ #ifndef MYSQL_CLIENT /* The master stopped. We used to clean up all temporary tables but this is useless as, as the master has shut down properly, it has written all DROP TEMPORARY TABLE (prepared statements' deletion is TODO only when we binlog prep stmts). We used to clean up slave_load_tmpdir, but this is useless as it has been cleared at the end of LOAD DATA INFILE. So we have nothing to do here. The place were we must do this cleaning is in Start_log_event_v3::do_apply_event(), not here. Because if we come here, the master was sane. This must only be called from the Slave SQL thread, since it calls Relay_log_info::flush(). */ int Stop_log_event::do_update_pos(rpl_group_info *rgi) { int error= 0; Relay_log_info *rli= rgi->rli; DBUG_ENTER("Stop_log_event::do_update_pos"); /* We do not want to update master_log pos because we get a rotate event before stop, so by now group_master_log_name is set to the next log. If we updated it, we will have incorrect master coordinates and this could give false triggers in MASTER_POS_WAIT() that we have reached the target position when in fact we have not. */ if (rli->get_flag(Relay_log_info::IN_TRANSACTION)) rgi->inc_event_relay_log_pos(); else if (!rgi->is_parallel_exec) { rpl_global_gtid_slave_state->record_and_update_gtid(thd, rgi); rli->inc_group_relay_log_pos(0, rgi); if (rli->flush()) error= 1; } DBUG_RETURN(error); } #endif /* !MYSQL_CLIENT */ #endif /* HAVE_REPLICATION */ /************************************************************************** Create_file_log_event methods **************************************************************************/ /* Create_file_log_event ctor */ #ifndef MYSQL_CLIENT Create_file_log_event:: Create_file_log_event(THD* thd_arg, sql_exchange* ex, const char* db_arg, const char* table_name_arg, List& fields_arg, bool is_concurrent_arg, enum enum_duplicates handle_dup, bool ignore, uchar* block_arg, uint block_len_arg, bool using_trans) :Load_log_event(thd_arg, ex, db_arg, table_name_arg, fields_arg, is_concurrent_arg, handle_dup, ignore, using_trans), fake_base(0), block(block_arg), event_buf(0), block_len(block_len_arg), file_id(thd_arg->file_id = mysql_bin_log.next_file_id()) { DBUG_ENTER("Create_file_log_event"); sql_ex.force_new_format(); DBUG_VOID_RETURN; } /* Create_file_log_event::write_data_body() */ bool Create_file_log_event::write_data_body() { bool res; if ((res= Load_log_event::write_data_body()) || fake_base) return res; return write_data("", 1) || write_data(block, block_len); } /* Create_file_log_event::write_data_header() */ bool Create_file_log_event::write_data_header() { bool res; uchar buf[CREATE_FILE_HEADER_LEN]; if ((res= Load_log_event::write_data_header()) || fake_base) return res; int4store(buf + CF_FILE_ID_OFFSET, file_id); return write_data(buf, CREATE_FILE_HEADER_LEN) != 0; } /* Create_file_log_event::write_base() */ bool Create_file_log_event::write_base() { bool res; fake_base= 1; // pretend we are Load event res= write(); fake_base= 0; return res; } #endif /* !MYSQL_CLIENT */ /* Create_file_log_event ctor */ Create_file_log_event::Create_file_log_event(const char* buf, uint len, const Format_description_log_event* description_event) :Load_log_event(buf,0,description_event),fake_base(0),block(0),inited_from_old(0) { DBUG_ENTER("Create_file_log_event::Create_file_log_event(char*,...)"); uint block_offset; uint header_len= description_event->common_header_len; uint8 load_header_len= description_event->post_header_len[LOAD_EVENT-1]; uint8 create_file_header_len= description_event->post_header_len[CREATE_FILE_EVENT-1]; if (!(event_buf= (char*) my_memdup(buf, len, MYF(MY_WME))) || copy_log_event(event_buf,len, (((uchar)buf[EVENT_TYPE_OFFSET] == LOAD_EVENT) ? load_header_len + header_len : (fake_base ? (header_len+load_header_len) : (header_len+load_header_len) + create_file_header_len)), description_event)) DBUG_VOID_RETURN; if (description_event->binlog_version!=1) { file_id= uint4korr(buf + header_len + load_header_len + CF_FILE_ID_OFFSET); /* Note that it's ok to use get_data_size() below, because it is computed with values we have already read from this event (because we called copy_log_event()); we are not using slave's format info to decode master's format, we are really using master's format info. Anyway, both formats should be identical (except the common_header_len) as these Load events are not changed between 4.0 and 5.0 (as logging of LOAD DATA INFILE does not use Load_log_event in 5.0). The + 1 is for \0 terminating fname */ block_offset= (description_event->common_header_len + Load_log_event::get_data_size() + create_file_header_len + 1); if (len < block_offset) DBUG_VOID_RETURN; block = (uchar*)buf + block_offset; block_len = len - block_offset; } else { sql_ex.force_new_format(); inited_from_old = 1; } DBUG_VOID_RETURN; } /* Create_file_log_event::print() */ #ifdef MYSQL_CLIENT bool Create_file_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info, bool enable_local) { if (print_event_info->short_form) { if (enable_local && check_fname_outside_temp_buf()) return Load_log_event::print(file, print_event_info); return 0; } Write_on_release_cache cache(&print_event_info->head_cache, file); if (enable_local) { if (Load_log_event::print(file, print_event_info, !check_fname_outside_temp_buf())) goto err; /** reduce the size of io cache so that the write function is called for every call to my_b_printf(). */ DBUG_EXECUTE_IF ("simulate_create_event_write_error", {(&cache)->write_pos= (&cache)->write_end; DBUG_SET("+d,simulate_file_write_error");}); /* That one is for "file_id: etc" below: in mysqlbinlog we want the #, in SHOW BINLOG EVENTS we don't. */ if (my_b_write_byte(&cache, '#')) goto err; } if (my_b_printf(&cache, " file_id: %d block_len: %d\n", file_id, block_len)) goto err; return cache.flush_data(); err: return 1; } bool Create_file_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { return print(file, print_event_info, 0); } #endif /* MYSQL_CLIENT */ /* Create_file_log_event::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Create_file_log_event::pack_info(Protocol *protocol) { char buf[SAFE_NAME_LEN*2 + 30 + 21*2], *pos; pos= strmov(buf, "db="); memcpy(pos, db, db_len); pos= strmov(pos + db_len, ";table="); memcpy(pos, table_name, table_name_len); pos= strmov(pos + table_name_len, ";file_id="); pos= int10_to_str((long) file_id, pos, 10); pos= strmov(pos, ";block_len="); pos= int10_to_str((long) block_len, pos, 10); protocol->store(buf, (uint) (pos-buf), &my_charset_bin); } #endif /* defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ /** Create_file_log_event::do_apply_event() Constructor for Create_file_log_event to instantiate an event from the relay log on the slave. @retval 0 Success @retval 1 Failure */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Create_file_log_event::do_apply_event(rpl_group_info *rgi) { char fname_buf[FN_REFLEN]; char *ext; int fd = -1; IO_CACHE file; Log_event_writer lew(&file, 0); int error = 1; Relay_log_info const *rli= rgi->rli; THD_STAGE_INFO(thd, stage_making_temp_file_create_before_load_data); bzero((char*)&file, sizeof(file)); ext= slave_load_file_stem(fname_buf, file_id, server_id, ".info", &rli->mi->connection_name); /* old copy may exist already */ mysql_file_delete(key_file_log_event_info, fname_buf, MYF(0)); if ((fd= mysql_file_create(key_file_log_event_info, fname_buf, CREATE_MODE, O_WRONLY | O_BINARY | O_EXCL | O_NOFOLLOW, MYF(MY_WME))) < 0 || init_io_cache(&file, fd, IO_SIZE, WRITE_CACHE, (my_off_t)0, 0, MYF(MY_WME|MY_NABP))) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in Create_file event: could not open file '%s'", fname_buf); goto err; } // a trick to avoid allocating another buffer fname= fname_buf; fname_len= (uint) (strmov(ext, ".data") - fname); writer= &lew; if (write_base()) { strmov(ext, ".info"); // to have it right in the error message rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in Create_file event: could not write to file '%s'", fname_buf); goto err; } end_io_cache(&file); mysql_file_close(fd, MYF(0)); // fname_buf now already has .data, not .info, because we did our trick /* old copy may exist already */ mysql_file_delete(key_file_log_event_data, fname_buf, MYF(0)); if ((fd= mysql_file_create(key_file_log_event_data, fname_buf, CREATE_MODE, O_WRONLY | O_BINARY | O_EXCL | O_NOFOLLOW, MYF(MY_WME))) < 0) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in Create_file event: could not open file '%s'", fname_buf); goto err; } if (mysql_file_write(fd, (uchar*) block, block_len, MYF(MY_WME+MY_NABP))) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in Create_file event: write to '%s' failed", fname_buf); goto err; } error=0; // Everything is ok err: if (unlikely(error)) end_io_cache(&file); if (likely(fd >= 0)) mysql_file_close(fd, MYF(0)); return error != 0; } #endif /* defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ /************************************************************************** Append_block_log_event methods **************************************************************************/ /* Append_block_log_event ctor */ #ifndef MYSQL_CLIENT Append_block_log_event::Append_block_log_event(THD *thd_arg, const char *db_arg, uchar *block_arg, uint block_len_arg, bool using_trans) :Log_event(thd_arg,0, using_trans), block(block_arg), block_len(block_len_arg), file_id(thd_arg->file_id), db(db_arg) { } #endif /* Append_block_log_event ctor */ Append_block_log_event::Append_block_log_event(const char* buf, uint len, const Format_description_log_event* description_event) :Log_event(buf, description_event),block(0) { DBUG_ENTER("Append_block_log_event::Append_block_log_event(char*,...)"); uint8 common_header_len= description_event->common_header_len; uint8 append_block_header_len= description_event->post_header_len[APPEND_BLOCK_EVENT-1]; uint total_header_len= common_header_len+append_block_header_len; if (len < total_header_len) DBUG_VOID_RETURN; file_id= uint4korr(buf + common_header_len + AB_FILE_ID_OFFSET); block= (uchar*)buf + total_header_len; block_len= len - total_header_len; DBUG_VOID_RETURN; } /* Append_block_log_event::write() */ #ifndef MYSQL_CLIENT bool Append_block_log_event::write() { uchar buf[APPEND_BLOCK_HEADER_LEN]; int4store(buf + AB_FILE_ID_OFFSET, file_id); return write_header(APPEND_BLOCK_HEADER_LEN + block_len) || write_data(buf, APPEND_BLOCK_HEADER_LEN) || write_data(block, block_len) || write_footer(); } #endif /* Append_block_log_event::print() */ #ifdef MYSQL_CLIENT bool Append_block_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file); if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\n#%s: file_id: %d block_len: %d\n", get_type_str(), file_id, block_len)) goto err; return cache.flush_data(); err: return 1; } #endif /* MYSQL_CLIENT */ /* Append_block_log_event::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Append_block_log_event::pack_info(Protocol *protocol) { char buf[256]; uint length; length= (uint) sprintf(buf, ";file_id=%u;block_len=%u", file_id, block_len); protocol->store(buf, length, &my_charset_bin); } /* Append_block_log_event::get_create_or_append() */ int Append_block_log_event::get_create_or_append() const { return 0; /* append to the file, fail if not exists */ } /* Append_block_log_event::do_apply_event() */ int Append_block_log_event::do_apply_event(rpl_group_info *rgi) { char fname[FN_REFLEN]; int fd; int error = 1; Relay_log_info const *rli= rgi->rli; DBUG_ENTER("Append_block_log_event::do_apply_event"); THD_STAGE_INFO(thd, stage_making_temp_file_append_before_load_data); slave_load_file_stem(fname, file_id, server_id, ".data", &rli->mi->cmp_connection_name); if (get_create_or_append()) { /* Usually lex_start() is called by mysql_parse(), but we need it here as the present method does not call mysql_parse(). */ lex_start(thd); thd->reset_for_next_command(); /* old copy may exist already */ mysql_file_delete(key_file_log_event_data, fname, MYF(0)); if ((fd= mysql_file_create(key_file_log_event_data, fname, CREATE_MODE, O_WRONLY | O_BINARY | O_EXCL | O_NOFOLLOW, MYF(MY_WME))) < 0) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in %s event: could not create file '%s'", get_type_str(), fname); goto err; } } else if ((fd= mysql_file_open(key_file_log_event_data, fname, O_WRONLY | O_APPEND | O_BINARY | O_NOFOLLOW, MYF(MY_WME))) < 0) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in %s event: could not open file '%s'", get_type_str(), fname); goto err; } DBUG_EXECUTE_IF("remove_slave_load_file_before_write", { my_delete(fname, MYF(0)); }); if (mysql_file_write(fd, (uchar*) block, block_len, MYF(MY_WME+MY_NABP))) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in %s event: write to '%s' failed", get_type_str(), fname); goto err; } error=0; err: if (fd >= 0) mysql_file_close(fd, MYF(0)); DBUG_RETURN(error); } #endif /************************************************************************** Delete_file_log_event methods **************************************************************************/ /* Delete_file_log_event ctor */ #ifndef MYSQL_CLIENT Delete_file_log_event::Delete_file_log_event(THD *thd_arg, const char* db_arg, bool using_trans) :Log_event(thd_arg, 0, using_trans), file_id(thd_arg->file_id), db(db_arg) { } #endif /* Delete_file_log_event ctor */ Delete_file_log_event::Delete_file_log_event(const char* buf, uint len, const Format_description_log_event* description_event) :Log_event(buf, description_event),file_id(0) { uint8 common_header_len= description_event->common_header_len; uint8 delete_file_header_len= description_event->post_header_len[DELETE_FILE_EVENT-1]; if (len < (uint)(common_header_len + delete_file_header_len)) return; file_id= uint4korr(buf + common_header_len + DF_FILE_ID_OFFSET); } /* Delete_file_log_event::write() */ #ifndef MYSQL_CLIENT bool Delete_file_log_event::write() { uchar buf[DELETE_FILE_HEADER_LEN]; int4store(buf + DF_FILE_ID_OFFSET, file_id); return write_header(sizeof(buf)) || write_data(buf, sizeof(buf)) || write_footer(); } #endif /* Delete_file_log_event::print() */ #ifdef MYSQL_CLIENT bool Delete_file_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file); if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\n#Delete_file: file_id=%u\n", file_id)) return 1; return cache.flush_data(); } #endif /* MYSQL_CLIENT */ /* Delete_file_log_event::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Delete_file_log_event::pack_info(Protocol *protocol) { char buf[64]; uint length; length= (uint) sprintf(buf, ";file_id=%u", (uint) file_id); protocol->store(buf, (int32) length, &my_charset_bin); } #endif /* Delete_file_log_event::do_apply_event() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Delete_file_log_event::do_apply_event(rpl_group_info *rgi) { char fname[FN_REFLEN+10]; Relay_log_info const *rli= rgi->rli; char *ext= slave_load_file_stem(fname, file_id, server_id, ".data", &rli->mi->cmp_connection_name); mysql_file_delete(key_file_log_event_data, fname, MYF(MY_WME)); strmov(ext, ".info"); mysql_file_delete(key_file_log_event_info, fname, MYF(MY_WME)); return 0; } #endif /* defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ /************************************************************************** Execute_load_log_event methods **************************************************************************/ /* Execute_load_log_event ctor */ #ifndef MYSQL_CLIENT Execute_load_log_event::Execute_load_log_event(THD *thd_arg, const char* db_arg, bool using_trans) :Log_event(thd_arg, 0, using_trans), file_id(thd_arg->file_id), db(db_arg) { } #endif /* Execute_load_log_event ctor */ Execute_load_log_event::Execute_load_log_event(const char* buf, uint len, const Format_description_log_event* description_event) :Log_event(buf, description_event), file_id(0) { uint8 common_header_len= description_event->common_header_len; uint8 exec_load_header_len= description_event->post_header_len[EXEC_LOAD_EVENT-1]; if (len < (uint)(common_header_len+exec_load_header_len)) return; file_id= uint4korr(buf + common_header_len + EL_FILE_ID_OFFSET); } /* Execute_load_log_event::write() */ #ifndef MYSQL_CLIENT bool Execute_load_log_event::write() { uchar buf[EXEC_LOAD_HEADER_LEN]; int4store(buf + EL_FILE_ID_OFFSET, file_id); return write_header(sizeof(buf)) || write_data(buf, sizeof(buf)) || write_footer(); } #endif /* Execute_load_log_event::print() */ #ifdef MYSQL_CLIENT bool Execute_load_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file); if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\n#Exec_load: file_id=%d\n", file_id)) return 1; return cache.flush_data(); } #endif /* Execute_load_log_event::pack_info() */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Execute_load_log_event::pack_info(Protocol *protocol) { char buf[64]; uint length; length= (uint) sprintf(buf, ";file_id=%u", (uint) file_id); protocol->store(buf, (int32) length, &my_charset_bin); } /* Execute_load_log_event::do_apply_event() */ int Execute_load_log_event::do_apply_event(rpl_group_info *rgi) { char fname[FN_REFLEN+10]; char *ext; int fd; int error= 1; IO_CACHE file; Load_log_event *lev= 0; Relay_log_info const *rli= rgi->rli; ext= slave_load_file_stem(fname, file_id, server_id, ".info", &rli->mi->cmp_connection_name); if ((fd= mysql_file_open(key_file_log_event_info, fname, O_RDONLY | O_BINARY | O_NOFOLLOW, MYF(MY_WME))) < 0 || init_io_cache(&file, fd, IO_SIZE, READ_CACHE, (my_off_t)0, 0, MYF(MY_WME|MY_NABP))) { rli->report(ERROR_LEVEL, my_errno, rgi->gtid_info(), "Error in Exec_load event: could not open file '%s'", fname); goto err; } if (!(lev= (Load_log_event*) Log_event::read_log_event(&file, rli->relay_log.description_event_for_exec, opt_slave_sql_verify_checksum)) || lev->get_type_code() != NEW_LOAD_EVENT) { rli->report(ERROR_LEVEL, 0, rgi->gtid_info(), "Error in Exec_load event: " "file '%s' appears corrupted", fname); goto err; } lev->thd = thd; /* lev->do_apply_event should use rli only for errors i.e. should not advance rli's position. lev->do_apply_event is the place where the table is loaded (it calls mysql_load()). */ if (lev->do_apply_event(0,rgi,1)) { /* We want to indicate the name of the file that could not be loaded (SQL_LOADxxx). But as we are here we are sure the error is in rli->last_slave_error and rli->last_slave_errno (example of error: duplicate entry for key), so we don't want to overwrite it with the filename. What we want instead is add the filename to the current error message. */ char *tmp= my_strdup(rli->last_error().message, MYF(MY_WME)); if (tmp) { rli->report(ERROR_LEVEL, rli->last_error().number, rgi->gtid_info(), "%s. Failed executing load from '%s'", tmp, fname); my_free(tmp); } goto err; } /* We have an open file descriptor to the .info file; we need to close it or Windows will refuse to delete the file in mysql_file_delete(). */ if (fd >= 0) { mysql_file_close(fd, MYF(0)); end_io_cache(&file); fd= -1; } mysql_file_delete(key_file_log_event_info, fname, MYF(MY_WME)); memcpy(ext, ".data", 6); mysql_file_delete(key_file_log_event_data, fname, MYF(MY_WME)); error = 0; err: delete lev; if (fd >= 0) { mysql_file_close(fd, MYF(0)); end_io_cache(&file); } return error; } #endif /* defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ /************************************************************************** Begin_load_query_log_event methods **************************************************************************/ #ifndef MYSQL_CLIENT Begin_load_query_log_event:: Begin_load_query_log_event(THD* thd_arg, const char* db_arg, uchar* block_arg, uint block_len_arg, bool using_trans) :Append_block_log_event(thd_arg, db_arg, block_arg, block_len_arg, using_trans) { file_id= thd_arg->file_id= mysql_bin_log.next_file_id(); } #endif Begin_load_query_log_event:: Begin_load_query_log_event(const char* buf, uint len, const Format_description_log_event* desc_event) :Append_block_log_event(buf, len, desc_event) { } #if defined( HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Begin_load_query_log_event::get_create_or_append() const { return 1; /* create the file */ } #endif /* defined( HAVE_REPLICATION) && !defined(MYSQL_CLIENT) */ #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) Log_event::enum_skip_reason Begin_load_query_log_event::do_shall_skip(rpl_group_info *rgi) { /* If the slave skip counter is 1, then we should not start executing on the next event. */ return continue_group(rgi); } #endif /************************************************************************** Execute_load_query_log_event methods **************************************************************************/ #ifndef MYSQL_CLIENT Execute_load_query_log_event:: Execute_load_query_log_event(THD *thd_arg, const char* query_arg, ulong query_length_arg, uint fn_pos_start_arg, uint fn_pos_end_arg, enum_load_dup_handling dup_handling_arg, bool using_trans, bool direct, bool suppress_use, int errcode): Query_log_event(thd_arg, query_arg, query_length_arg, using_trans, direct, suppress_use, errcode), file_id(thd_arg->file_id), fn_pos_start(fn_pos_start_arg), fn_pos_end(fn_pos_end_arg), dup_handling(dup_handling_arg) { } #endif /* !MYSQL_CLIENT */ Execute_load_query_log_event:: Execute_load_query_log_event(const char* buf, uint event_len, const Format_description_log_event* desc_event): Query_log_event(buf, event_len, desc_event, EXECUTE_LOAD_QUERY_EVENT), file_id(0), fn_pos_start(0), fn_pos_end(0) { if (!Query_log_event::is_valid()) return; buf+= desc_event->common_header_len; fn_pos_start= uint4korr(buf + ELQ_FN_POS_START_OFFSET); fn_pos_end= uint4korr(buf + ELQ_FN_POS_END_OFFSET); dup_handling= (enum_load_dup_handling)(*(buf + ELQ_DUP_HANDLING_OFFSET)); if (fn_pos_start > q_len || fn_pos_end > q_len || dup_handling > LOAD_DUP_REPLACE) return; file_id= uint4korr(buf + ELQ_FILE_ID_OFFSET); } ulong Execute_load_query_log_event::get_post_header_size_for_derived() { return EXECUTE_LOAD_QUERY_EXTRA_HEADER_LEN; } #ifndef MYSQL_CLIENT bool Execute_load_query_log_event::write_post_header_for_derived() { uchar buf[EXECUTE_LOAD_QUERY_EXTRA_HEADER_LEN]; int4store(buf, file_id); int4store(buf + 4, fn_pos_start); int4store(buf + 4 + 4, fn_pos_end); *(buf + 4 + 4 + 4)= (uchar) dup_handling; return write_data(buf, EXECUTE_LOAD_QUERY_EXTRA_HEADER_LEN); } #endif #ifdef MYSQL_CLIENT bool Execute_load_query_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info) { return print(file, print_event_info, 0); } /** Prints the query as LOAD DATA LOCAL and with rewritten filename. */ bool Execute_load_query_log_event::print(FILE* file, PRINT_EVENT_INFO* print_event_info, const char *local_fname) { Write_on_release_cache cache(&print_event_info->head_cache, file); if (print_query_header(&cache, print_event_info)) goto err; /** reduce the size of io cache so that the write function is called for every call to my_b_printf(). */ DBUG_EXECUTE_IF ("simulate_execute_event_write_error", {(&cache)->write_pos= (&cache)->write_end; DBUG_SET("+d,simulate_file_write_error");}); if (local_fname) { if (my_b_write(&cache, (uchar*) query, fn_pos_start) || my_b_write_string(&cache, " LOCAL INFILE ") || pretty_print_str(&cache, local_fname, (int)strlen(local_fname))) goto err; if (dup_handling == LOAD_DUP_REPLACE) if (my_b_write_string(&cache, " REPLACE")) goto err; if (my_b_write_string(&cache, " INTO") || my_b_write(&cache, (uchar*) query + fn_pos_end, q_len-fn_pos_end) || my_b_printf(&cache, "\n%s\n", print_event_info->delimiter)) goto err; } else { if (my_b_write(&cache, (uchar*) query, q_len) || my_b_printf(&cache, "\n%s\n", print_event_info->delimiter)) goto err; } if (!print_event_info->short_form) my_b_printf(&cache, "# file_id: %d \n", file_id); return cache.flush_data(); err: return 1; } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Execute_load_query_log_event::pack_info(Protocol *protocol) { char buf_mem[1024]; String buf(buf_mem, sizeof(buf_mem), system_charset_info); buf.real_alloc(9 + db_len + q_len + 10 + 21); if (db && db_len) { if (buf.append(STRING_WITH_LEN("use ")) || append_identifier(protocol->thd, &buf, db, db_len) || buf.append(STRING_WITH_LEN("; "))) return; } if (query && q_len && buf.append(query, q_len)) return; if (buf.append(" ;file_id=") || buf.append_ulonglong(file_id)) return; protocol->store(buf.ptr(), buf.length(), &my_charset_bin); } int Execute_load_query_log_event::do_apply_event(rpl_group_info *rgi) { char *p; char *buf; char *fname; char *fname_end; int error; Relay_log_info const *rli= rgi->rli; buf= (char*) my_malloc(q_len + 1 - (fn_pos_end - fn_pos_start) + (FN_REFLEN + 10) + 10 + 8 + 5, MYF(MY_WME)); DBUG_EXECUTE_IF("LOAD_DATA_INFILE_has_fatal_error", my_free(buf); buf= NULL;); /* Replace filename and LOCAL keyword in query before executing it */ if (buf == NULL) { rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, rgi->gtid_info(), ER_THD(rgi->thd, ER_SLAVE_FATAL_ERROR), "Not enough memory"); return 1; } p= buf; memcpy(p, query, fn_pos_start); p+= fn_pos_start; fname= (p= strmake(p, STRING_WITH_LEN(" INFILE \'"))); p= slave_load_file_stem(p, file_id, server_id, ".data", &rli->mi->cmp_connection_name); fname_end= p= strend(p); // Safer than p=p+5 *(p++)='\''; switch (dup_handling) { case LOAD_DUP_IGNORE: p= strmake(p, STRING_WITH_LEN(" IGNORE")); break; case LOAD_DUP_REPLACE: p= strmake(p, STRING_WITH_LEN(" REPLACE")); break; default: /* Ordinary load data */ break; } p= strmake(p, STRING_WITH_LEN(" INTO ")); p= strmake(p, query+fn_pos_end, q_len-fn_pos_end); error= Query_log_event::do_apply_event(rgi, buf, (uint32)(p-buf)); /* Forging file name for deletion in same buffer */ *fname_end= 0; /* If there was an error the slave is going to stop, leave the file so that we can re-execute this event at START SLAVE. */ if (unlikely(!error)) mysql_file_delete(key_file_log_event_data, fname, MYF(MY_WME)); my_free(buf); return error; } #endif /************************************************************************** sql_ex_info methods **************************************************************************/ /* sql_ex_info::init() */ const char *sql_ex_info::init(const char *buf, const char *buf_end, bool use_new_format) { cached_new_format = use_new_format; if (use_new_format) { empty_flags=0; /* The code below assumes that buf will not disappear from under our feet during the lifetime of the event. This assumption holds true in the slave thread if the log is in new format, but is not the case when we have old format because we will be reusing net buffer to read the actual file before we write out the Create_file event. */ if (read_str(&buf, buf_end, &field_term, &field_term_len) || read_str(&buf, buf_end, &enclosed, &enclosed_len) || read_str(&buf, buf_end, &line_term, &line_term_len) || read_str(&buf, buf_end, &line_start, &line_start_len) || read_str(&buf, buf_end, &escaped, &escaped_len)) return 0; opt_flags = *buf++; } else { if (buf_end - buf < 7) return 0; // Wrong data field_term_len= enclosed_len= line_term_len= line_start_len= escaped_len=1; field_term = buf++; // Use first byte in string enclosed= buf++; line_term= buf++; line_start= buf++; escaped= buf++; opt_flags = *buf++; empty_flags= *buf++; if (empty_flags & FIELD_TERM_EMPTY) field_term_len=0; if (empty_flags & ENCLOSED_EMPTY) enclosed_len=0; if (empty_flags & LINE_TERM_EMPTY) line_term_len=0; if (empty_flags & LINE_START_EMPTY) line_start_len=0; if (empty_flags & ESCAPED_EMPTY) escaped_len=0; } return buf; } #ifndef MYSQL_CLIENT /* write_str() */ static bool write_str(Log_event_writer *writer, const char *str, uint length) { uchar tmp[1]; tmp[0]= (uchar) length; return (writer->write_data(tmp, sizeof(tmp)) || writer->write_data((uchar*) str, length)); } /* sql_ex_info::write_data() */ bool sql_ex_info::write_data(Log_event_writer *writer) { if (new_format()) { return write_str(writer, field_term, field_term_len) || write_str(writer, enclosed, enclosed_len) || write_str(writer, line_term, line_term_len) || write_str(writer, line_start, line_start_len) || write_str(writer, escaped, escaped_len) || writer->write_data((uchar*) &opt_flags, 1); } else { uchar old_ex[7]; old_ex[0]= *field_term; old_ex[1]= *enclosed; old_ex[2]= *line_term; old_ex[3]= *line_start; old_ex[4]= *escaped; old_ex[5]= opt_flags; old_ex[6]= empty_flags; return writer->write_data(old_ex, sizeof(old_ex)); } } /************************************************************************** Rows_log_event member functions **************************************************************************/ Rows_log_event::Rows_log_event(THD *thd_arg, TABLE *tbl_arg, ulong tid, MY_BITMAP const *cols, bool is_transactional, Log_event_type event_type) : Log_event(thd_arg, 0, is_transactional), m_row_count(0), m_table(tbl_arg), m_table_id(tid), m_width(tbl_arg ? tbl_arg->s->fields : 1), m_rows_buf(0), m_rows_cur(0), m_rows_end(0), m_flags(0), m_type(event_type), m_extra_row_data(0) #ifdef HAVE_REPLICATION , m_curr_row(NULL), m_curr_row_end(NULL), m_key(NULL), m_key_info(NULL), m_key_nr(0), master_had_triggers(0) #endif { /* We allow a special form of dummy event when the table, and cols are null and the table id is ~0UL. This is a temporary solution, to be able to terminate a started statement in the binary log: the extraneous events will be removed in the future. */ DBUG_ASSERT((tbl_arg && tbl_arg->s && tid != ~0UL) || (!tbl_arg && !cols && tid == ~0UL)); if (thd_arg->variables.option_bits & OPTION_NO_FOREIGN_KEY_CHECKS) set_flags(NO_FOREIGN_KEY_CHECKS_F); if (thd_arg->variables.option_bits & OPTION_RELAXED_UNIQUE_CHECKS) set_flags(RELAXED_UNIQUE_CHECKS_F); if (thd_arg->variables.option_bits & OPTION_NO_CHECK_CONSTRAINT_CHECKS) set_flags(NO_CHECK_CONSTRAINT_CHECKS_F); /* if my_bitmap_init fails, caught in is_valid() */ if (likely(!my_bitmap_init(&m_cols, m_width <= sizeof(m_bitbuf)*8 ? m_bitbuf : NULL, m_width, false))) { /* Cols can be zero if this is a dummy binrows event */ if (likely(cols != NULL)) { memcpy(m_cols.bitmap, cols->bitmap, no_bytes_in_map(cols)); create_last_word_mask(&m_cols); } } else { // Needed because my_bitmap_init() does not set it to null on failure m_cols.bitmap= 0; } } #endif Rows_log_event::Rows_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Log_event(buf, description_event), m_row_count(0), #ifndef MYSQL_CLIENT m_table(NULL), #endif m_table_id(0), m_rows_buf(0), m_rows_cur(0), m_rows_end(0), m_extra_row_data(0) #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) , m_curr_row(NULL), m_curr_row_end(NULL), m_key(NULL), m_key_info(NULL), m_key_nr(0), master_had_triggers(0) #endif { DBUG_ENTER("Rows_log_event::Rows_log_event(const char*,...)"); uint8 const common_header_len= description_event->common_header_len; Log_event_type event_type= (Log_event_type)(uchar)buf[EVENT_TYPE_OFFSET]; m_type= event_type; m_cols_ai.bitmap= 0; uint8 const post_header_len= description_event->post_header_len[event_type-1]; if (event_len < (uint)(common_header_len + post_header_len)) { m_cols.bitmap= 0; DBUG_VOID_RETURN; } DBUG_PRINT("enter",("event_len: %u common_header_len: %d " "post_header_len: %d", event_len, common_header_len, post_header_len)); const char *post_start= buf + common_header_len; post_start+= RW_MAPID_OFFSET; if (post_header_len == 6) { /* Master is of an intermediate source tree before 5.1.4. Id is 4 bytes */ m_table_id= uint4korr(post_start); post_start+= 4; } else { m_table_id= (ulong) uint6korr(post_start); post_start+= RW_FLAGS_OFFSET; } m_flags_pos= post_start - buf; m_flags= uint2korr(post_start); post_start+= 2; uint16 var_header_len= 0; if (post_header_len == ROWS_HEADER_LEN_V2) { /* Have variable length header, check length, which includes length bytes */ var_header_len= uint2korr(post_start); /* Check length and also avoid out of buffer read */ if (var_header_len < 2 || event_len < static_cast(var_header_len + (post_start - buf))) { m_cols.bitmap= 0; DBUG_VOID_RETURN; } var_header_len-= 2; /* Iterate over var-len header, extracting 'chunks' */ const char* start= post_start + 2; const char* end= start + var_header_len; for (const char* pos= start; pos < end;) { switch(*pos++) { case RW_V_EXTRAINFO_TAG: { /* Have an 'extra info' section, read it in */ assert((end - pos) >= EXTRA_ROW_INFO_HDR_BYTES); uint8 infoLen= pos[EXTRA_ROW_INFO_LEN_OFFSET]; assert((end - pos) >= infoLen); /* Just store/use the first tag of this type, skip others */ if (likely(!m_extra_row_data)) { m_extra_row_data= (uchar*) my_malloc(infoLen, MYF(MY_WME)); if (likely(m_extra_row_data != NULL)) { memcpy(m_extra_row_data, pos, infoLen); } } pos+= infoLen; break; } default: /* Unknown code, we will not understand anything further here */ pos= end; /* Break loop */ } } } uchar const *const var_start= (const uchar *)buf + common_header_len + post_header_len + var_header_len; uchar const *const ptr_width= var_start; uchar *ptr_after_width= (uchar*) ptr_width; DBUG_PRINT("debug", ("Reading from %p", ptr_after_width)); m_width = net_field_length(&ptr_after_width); DBUG_PRINT("debug", ("m_width=%lu", m_width)); /* Avoid reading out of buffer */ if (ptr_after_width + (m_width + 7) / 8 > (uchar*)buf + event_len) { m_cols.bitmap= NULL; DBUG_VOID_RETURN; } /* if my_bitmap_init fails, caught in is_valid() */ if (likely(!my_bitmap_init(&m_cols, m_width <= sizeof(m_bitbuf)*8 ? m_bitbuf : NULL, m_width, false))) { DBUG_PRINT("debug", ("Reading from %p", ptr_after_width)); memcpy(m_cols.bitmap, ptr_after_width, (m_width + 7) / 8); create_last_word_mask(&m_cols); ptr_after_width+= (m_width + 7) / 8; DBUG_DUMP("m_cols", (uchar*) m_cols.bitmap, no_bytes_in_map(&m_cols)); } else { // Needed because my_bitmap_init() does not set it to null on failure m_cols.bitmap= NULL; DBUG_VOID_RETURN; } m_cols_ai.bitmap= m_cols.bitmap; /* See explanation in is_valid() */ if (LOG_EVENT_IS_UPDATE_ROW(event_type)) { DBUG_PRINT("debug", ("Reading from %p", ptr_after_width)); /* if my_bitmap_init fails, caught in is_valid() */ if (likely(!my_bitmap_init(&m_cols_ai, m_width <= sizeof(m_bitbuf_ai)*8 ? m_bitbuf_ai : NULL, m_width, false))) { DBUG_PRINT("debug", ("Reading from %p", ptr_after_width)); memcpy(m_cols_ai.bitmap, ptr_after_width, (m_width + 7) / 8); create_last_word_mask(&m_cols_ai); ptr_after_width+= (m_width + 7) / 8; DBUG_DUMP("m_cols_ai", (uchar*) m_cols_ai.bitmap, no_bytes_in_map(&m_cols_ai)); } else { // Needed because my_bitmap_init() does not set it to null on failure m_cols_ai.bitmap= 0; DBUG_VOID_RETURN; } } const uchar* const ptr_rows_data= (const uchar*) ptr_after_width; size_t const read_size= ptr_rows_data - (const unsigned char *) buf; if (read_size > event_len) { DBUG_VOID_RETURN; } size_t const data_size= event_len - read_size; DBUG_PRINT("info",("m_table_id: %llu m_flags: %d m_width: %lu data_size: %lu", m_table_id, m_flags, m_width, (ulong) data_size)); m_rows_buf= (uchar*) my_malloc(data_size, MYF(MY_WME)); if (likely((bool)m_rows_buf)) { #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) m_curr_row= m_rows_buf; #endif m_rows_end= m_rows_buf + data_size; m_rows_cur= m_rows_end; memcpy(m_rows_buf, ptr_rows_data, data_size); m_rows_before_size= ptr_rows_data - (const uchar *) buf; // Get the size that before SET part } else m_cols.bitmap= 0; // to not free it DBUG_VOID_RETURN; } void Rows_log_event::uncompress_buf() { uint32 un_len = binlog_get_uncompress_len((char *)m_rows_buf); if (!un_len) return; uchar *new_buf= (uchar*) my_malloc(ALIGN_SIZE(un_len), MYF(MY_WME)); if (new_buf) { if(!binlog_buf_uncompress((char *)m_rows_buf, (char *)new_buf, (uint32)(m_rows_cur - m_rows_buf), &un_len)) { my_free(m_rows_buf); m_rows_buf = new_buf; #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) m_curr_row= m_rows_buf; #endif m_rows_end= m_rows_buf + un_len; m_rows_cur= m_rows_end; return; } else { my_free(new_buf); } } m_cols.bitmap= 0; // catch it in is_valid } Rows_log_event::~Rows_log_event() { if (m_cols.bitmap == m_bitbuf) // no my_malloc happened m_cols.bitmap= 0; // so no my_free in my_bitmap_free my_bitmap_free(&m_cols); // To pair with my_bitmap_init(). my_free(m_rows_buf); my_free(m_extra_row_data); } int Rows_log_event::get_data_size() { int const general_type_code= get_general_type_code(); uchar buf[MAX_INT_WIDTH]; uchar *end= net_store_length(buf, m_width); DBUG_EXECUTE_IF("old_row_based_repl_4_byte_map_id_master", return (int)(6 + no_bytes_in_map(&m_cols) + (end - buf) + (general_type_code == UPDATE_ROWS_EVENT ? no_bytes_in_map(&m_cols_ai) : 0) + m_rows_cur - m_rows_buf);); int data_size= 0; Log_event_type type = get_type_code(); bool is_v2_event= LOG_EVENT_IS_ROW_V2(type); if (is_v2_event) { data_size= ROWS_HEADER_LEN_V2 + (m_extra_row_data ? RW_V_TAG_LEN + m_extra_row_data[EXTRA_ROW_INFO_LEN_OFFSET]: 0); } else { data_size= ROWS_HEADER_LEN_V1; } data_size+= no_bytes_in_map(&m_cols); data_size+= (uint) (end - buf); if (general_type_code == UPDATE_ROWS_EVENT) data_size+= no_bytes_in_map(&m_cols_ai); data_size+= (uint) (m_rows_cur - m_rows_buf); return data_size; } #ifndef MYSQL_CLIENT int Rows_log_event::do_add_row_data(uchar *row_data, size_t length) { /* When the table has a primary key, we would probably want, by default, to log only the primary key value instead of the entire "before image". This would save binlog space. TODO */ DBUG_ENTER("Rows_log_event::do_add_row_data"); DBUG_PRINT("enter", ("row_data:%p length: %lu", row_data, (ulong) length)); /* If length is zero, there is nothing to write, so we just return. Note that this is not an optimization, since calling realloc() with size 0 means free(). */ if (length == 0) { m_row_count++; DBUG_RETURN(0); } /* Don't print debug messages when running valgrind since they can trigger false warnings. */ #ifndef HAVE_valgrind DBUG_DUMP("row_data", row_data, MY_MIN(length, 32)); #endif DBUG_ASSERT(m_rows_buf <= m_rows_cur); DBUG_ASSERT(!m_rows_buf || (m_rows_end && m_rows_buf < m_rows_end)); DBUG_ASSERT(m_rows_cur <= m_rows_end); /* The cast will always work since m_rows_cur <= m_rows_end */ if (static_cast(m_rows_end - m_rows_cur) <= length) { size_t const block_size= 1024; size_t cur_size= m_rows_cur - m_rows_buf; DBUG_EXECUTE_IF("simulate_too_big_row_case1", cur_size= UINT_MAX32 - (block_size * 10); length= UINT_MAX32 - (block_size * 10);); DBUG_EXECUTE_IF("simulate_too_big_row_case2", cur_size= UINT_MAX32 - (block_size * 10); length= block_size * 10;); DBUG_EXECUTE_IF("simulate_too_big_row_case3", cur_size= block_size * 10; length= UINT_MAX32 - (block_size * 10);); DBUG_EXECUTE_IF("simulate_too_big_row_case4", cur_size= UINT_MAX32 - (block_size * 10); length= (block_size * 10) - block_size + 1;); size_t remaining_space= UINT_MAX32 - cur_size; /* Check that the new data fits within remaining space and we can add block_size without wrapping. */ if (cur_size > UINT_MAX32 || length > remaining_space || ((length + block_size) > remaining_space)) { sql_print_error("The row data is greater than 4GB, which is too big to " "write to the binary log."); DBUG_RETURN(ER_BINLOG_ROW_LOGGING_FAILED); } size_t const new_alloc= block_size * ((cur_size + length + block_size - 1) / block_size); uchar* const new_buf= (uchar*)my_realloc((uchar*)m_rows_buf, new_alloc, MYF(MY_ALLOW_ZERO_PTR|MY_WME)); if (unlikely(!new_buf)) DBUG_RETURN(HA_ERR_OUT_OF_MEM); /* If the memory moved, we need to move the pointers */ if (new_buf != m_rows_buf) { m_rows_buf= new_buf; m_rows_cur= m_rows_buf + cur_size; } /* The end pointer should always be changed to point to the end of the allocated memory. */ m_rows_end= m_rows_buf + new_alloc; } DBUG_ASSERT(m_rows_cur + length <= m_rows_end); memcpy(m_rows_cur, row_data, length); m_rows_cur+= length; m_row_count++; DBUG_RETURN(0); } #endif #if defined(MYSQL_SERVER) && defined(HAVE_REPLICATION) /** Restores empty table list as it was before trigger processing. @note We have a lot of ASSERTS that check the lists when we close tables. There was the same problem with MERGE MYISAM tables and so here we try to go the same way. */ static void restore_empty_query_table_list(LEX *lex) { if (lex->first_not_own_table()) (*lex->first_not_own_table()->prev_global)= NULL; lex->query_tables= NULL; lex->query_tables_last= &lex->query_tables; } int Rows_log_event::do_apply_event(rpl_group_info *rgi) { Relay_log_info const *rli= rgi->rli; TABLE* table; DBUG_ENTER("Rows_log_event::do_apply_event(Relay_log_info*)"); int error= 0; /* If m_table_id == ~0ULL, then we have a dummy event that does not contain any data. In that case, we just remove all tables in the tables_to_lock list, close the thread tables, and return with success. */ if (m_table_id == ~0ULL) { /* This one is supposed to be set: just an extra check so that nothing strange has happened. */ DBUG_ASSERT(get_flags(STMT_END_F)); rgi->slave_close_thread_tables(thd); thd->clear_error(); DBUG_RETURN(0); } /* 'thd' has been set by exec_relay_log_event(), just before calling do_apply_event(). We still check here to prevent future coding errors. */ DBUG_ASSERT(rgi->thd == thd); /* If there is no locks taken, this is the first binrow event seen after the table map events. We should then lock all the tables used in the transaction and proceed with execution of the actual event. */ if (!thd->lock) { /* Lock_tables() reads the contents of thd->lex, so they must be initialized. We also call the THD::reset_for_next_command(), since this is the logical start of the next "statement". Note that this call might reset the value of current_stmt_binlog_format, so we need to do any changes to that value after this function. */ delete_explain_query(thd->lex); lex_start(thd); thd->reset_for_next_command(); /* The current statement is just about to begin and has not yet modified anything. Note, all.modified is reset by THD::reset_for_next_command(). */ thd->transaction.stmt.modified_non_trans_table= FALSE; thd->transaction.stmt.m_unsafe_rollback_flags&= ~THD_TRANS::DID_WAIT; /* This is a row injection, so we flag the "statement" as such. Note that this code is called both when the slave does row injections and when the BINLOG statement is used to do row injections. */ thd->lex->set_stmt_row_injection(); /* There are a few flags that are replicated with each row event. Make sure to set/clear them before executing the main body of the event. */ if (get_flags(NO_FOREIGN_KEY_CHECKS_F)) thd->variables.option_bits|= OPTION_NO_FOREIGN_KEY_CHECKS; else thd->variables.option_bits&= ~OPTION_NO_FOREIGN_KEY_CHECKS; if (get_flags(RELAXED_UNIQUE_CHECKS_F)) thd->variables.option_bits|= OPTION_RELAXED_UNIQUE_CHECKS; else thd->variables.option_bits&= ~OPTION_RELAXED_UNIQUE_CHECKS; if (get_flags(NO_CHECK_CONSTRAINT_CHECKS_F)) thd->variables.option_bits|= OPTION_NO_CHECK_CONSTRAINT_CHECKS; else thd->variables.option_bits&= ~OPTION_NO_CHECK_CONSTRAINT_CHECKS; /* A small test to verify that objects have consistent types */ DBUG_ASSERT(sizeof(thd->variables.option_bits) == sizeof(OPTION_RELAXED_UNIQUE_CHECKS)); DBUG_EXECUTE_IF("rows_log_event_before_open_table", { const char action[] = "now SIGNAL before_open_table WAIT_FOR go_ahead_sql"; DBUG_ASSERT(!debug_sync_set_action(thd, STRING_WITH_LEN(action))); };); if (slave_run_triggers_for_rbr) { LEX *lex= thd->lex; uint8 new_trg_event_map= get_trg_event_map(); /* Trigger's procedures work with global table list. So we have to add rgi->tables_to_lock content there to get trigger's in the list. Then restore_empty_query_table_list() restore the list as it was */ DBUG_ASSERT(lex->query_tables == NULL); if ((lex->query_tables= rgi->tables_to_lock)) rgi->tables_to_lock->prev_global= &lex->query_tables; for (TABLE_LIST *tables= rgi->tables_to_lock; tables; tables= tables->next_global) { tables->trg_event_map= new_trg_event_map; lex->query_tables_last= &tables->next_global; } } if (unlikely(open_and_lock_tables(thd, rgi->tables_to_lock, FALSE, 0))) { #ifdef WITH_WSREP if (WSREP(thd)) { WSREP_WARN("BF applier failed to open_and_lock_tables: %u, fatal: %d " "wsrep = (exec_mode: %d conflict_state: %d seqno: %lld)", thd->get_stmt_da()->sql_errno(), thd->is_fatal_error, thd->wsrep_cs().mode(), thd->wsrep_trx().state(), (long long) wsrep_thd_trx_seqno(thd)); } #endif /* WITH_WSREP */ if (thd->is_error() && !is_parallel_retry_error(rgi, error= thd->get_stmt_da()->sql_errno())) { /* Error reporting borrowed from Query_log_event with many excessive simplifications. We should not honour --slave-skip-errors at this point as we are having severe errors which should not be skipped. */ rli->report(ERROR_LEVEL, error, rgi->gtid_info(), "Error executing row event: '%s'", (error ? thd->get_stmt_da()->message() : "unexpected success or fatal error")); thd->is_slave_error= 1; } /* remove trigger's tables */ goto err; } /* When the open and locking succeeded, we check all tables to ensure that they still have the correct type. */ { DBUG_PRINT("debug", ("Checking compatibility of tables to lock - tables_to_lock: %p", rgi->tables_to_lock)); /** When using RBR and MyISAM MERGE tables the base tables that make up the MERGE table can be appended to the list of tables to lock. Thus, we just check compatibility for those that tables that have a correspondent table map event (ie, those that are actually going to be accessed while applying the event). That's why the loop stops at rli->tables_to_lock_count . NOTE: The base tables are added here are removed when close_thread_tables is called. */ TABLE_LIST *table_list_ptr= rgi->tables_to_lock; for (uint i=0 ; table_list_ptr && (i < rgi->tables_to_lock_count); table_list_ptr= table_list_ptr->next_global, i++) { /* Below if condition takes care of skipping base tables that make up the MERGE table (which are added by open_tables() call). They are added next to the merge table in the list. For eg: If RPL_TABLE_LIST is t3->t1->t2 (where t1 and t2 are base tables for merge table 't3'), open_tables will modify the list by adding t1 and t2 again immediately after t3 in the list (*not at the end of the list*). New table_to_lock list will look like t3->t1'->t2'->t1->t2 (where t1' and t2' are TABLE_LIST objects added by open_tables() call). There is no flag(or logic) in open_tables() that can skip adding these base tables to the list. So the logic here should take care of skipping them. tables_to_lock_count logic will take care of skipping base tables that are added at the end of the list. For eg: If RPL_TABLE_LIST is t1->t2->t3, open_tables will modify the list into t1->t2->t3->t1'->t2'. t1' and t2' will be skipped because tables_to_lock_count logic in this for loop. */ if (table_list_ptr->parent_l) continue; /* We can use a down cast here since we know that every table added to the tables_to_lock is a RPL_TABLE_LIST (or child table which is skipped above). */ RPL_TABLE_LIST *ptr= static_cast(table_list_ptr); DBUG_ASSERT(ptr->m_tabledef_valid); TABLE *conv_table; if (!ptr->m_tabledef.compatible_with(thd, rgi, ptr->table, &conv_table)) { DBUG_PRINT("debug", ("Table: %s.%s is not compatible with master", ptr->table->s->db.str, ptr->table->s->table_name.str)); /* We should not honour --slave-skip-errors at this point as we are having severe errors which should not be skipped. */ thd->is_slave_error= 1; /* remove trigger's tables */ error= ERR_BAD_TABLE_DEF; goto err; } DBUG_PRINT("debug", ("Table: %s.%s is compatible with master" " - conv_table: %p", ptr->table->s->db.str, ptr->table->s->table_name.str, conv_table)); ptr->m_conv_table= conv_table; } } /* ... and then we add all the tables to the table map and but keep them in the tables to lock list. We also invalidate the query cache for all the tables, since they will now be changed. TODO [/Matz]: Maybe the query cache should not be invalidated here? It might be that a table is not changed, even though it was locked for the statement. We do know that each Rows_log_event contain at least one row, so after processing one Rows_log_event, we can invalidate the query cache for the associated table. */ TABLE_LIST *ptr= rgi->tables_to_lock; for (uint i=0 ; ptr && (i < rgi->tables_to_lock_count); ptr= ptr->next_global, i++) { /* Please see comment in above 'for' loop to know the reason for this if condition */ if (ptr->parent_l) continue; rgi->m_table_map.set_table(ptr->table_id, ptr->table); /* Following is passing flag about triggers on the server. The problem was to pass it between table map event and row event. I do it via extended TABLE_LIST (RPL_TABLE_LIST) but row event uses only TABLE so I need to find somehow the corresponding TABLE_LIST. */ if (m_table_id == ptr->table_id) { ptr->table->master_had_triggers= ((RPL_TABLE_LIST*)ptr)->master_had_triggers; } } #ifdef HAVE_QUERY_CACHE #ifdef WITH_WSREP /* Moved invalidation right before the call to rows_event_stmt_cleanup(), to avoid query cache being polluted with stale entries, */ if (! (WSREP(thd) && wsrep_thd_is_applying(thd))) { #endif /* WITH_WSREP */ query_cache.invalidate_locked_for_write(thd, rgi->tables_to_lock); #ifdef WITH_WSREP } #endif /* WITH_WSREP */ #endif } table= m_table= rgi->m_table_map.get_table(m_table_id); DBUG_PRINT("debug", ("m_table:%p, m_table_id: %llu%s", m_table, m_table_id, table && master_had_triggers ? " (master had triggers)" : "")); if (table) { master_had_triggers= table->master_had_triggers; bool transactional_table= table->file->has_transactions(); /* table == NULL means that this table should not be replicated (this was set up by Table_map_log_event::do_apply_event() which tested replicate-* rules). */ /* It's not needed to set_time() but 1) it continues the property that "Time" in SHOW PROCESSLIST shows how much slave is behind 2) it will be needed when we allow replication from a table with no TIMESTAMP column to a table with one. So we call set_time(), like in SBR. Presently it changes nothing. */ thd->set_time(when, when_sec_part); if (m_width == table->s->fields && bitmap_is_set_all(&m_cols)) set_flags(COMPLETE_ROWS_F); /* Set tables write and read sets. Read_set contains all slave columns (in case we are going to fetch a complete record from slave) Write_set equals the m_cols bitmap sent from master but it can be longer if slave has extra columns. */ DBUG_PRINT_BITSET("debug", "Setting table's read_set from: %s", &m_cols); bitmap_set_all(table->read_set); if (get_general_type_code() == DELETE_ROWS_EVENT || get_general_type_code() == UPDATE_ROWS_EVENT) bitmap_intersect(table->read_set,&m_cols); bitmap_set_all(table->write_set); table->rpl_write_set= table->write_set; /* WRITE ROWS EVENTS store the bitmap in m_cols instead of m_cols_ai */ MY_BITMAP *after_image= ((get_general_type_code() == UPDATE_ROWS_EVENT) ? &m_cols_ai : &m_cols); bitmap_intersect(table->write_set, after_image); this->slave_exec_mode= slave_exec_mode_options; // fix the mode // Do event specific preparations error= do_before_row_operations(rli); /* Bug#56662 Assertion failed: next_insert_id == 0, file handler.cc Don't allow generation of auto_increment value when processing rows event by setting 'MODE_NO_AUTO_VALUE_ON_ZERO'. The exception to this rule happens when the auto_inc column exists on some extra columns on the slave. In that case, do not force MODE_NO_AUTO_VALUE_ON_ZERO. */ sql_mode_t saved_sql_mode= thd->variables.sql_mode; if (!is_auto_inc_in_extra_columns()) thd->variables.sql_mode= MODE_NO_AUTO_VALUE_ON_ZERO; // row processing loop /* set the initial time of this ROWS statement if it was not done before in some other ROWS event. */ rgi->set_row_stmt_start_timestamp(); THD_STAGE_INFO(thd, stage_executing); do { /* in_use can have been set to NULL in close_tables_for_reopen */ THD* old_thd= table->in_use; if (!table->in_use) table->in_use= thd; error= do_exec_row(rgi); if (unlikely(error)) DBUG_PRINT("info", ("error: %s", HA_ERR(error))); DBUG_ASSERT(error != HA_ERR_RECORD_DELETED); table->in_use = old_thd; if (unlikely(error)) { int actual_error= convert_handler_error(error, thd, table); bool idempotent_error= (idempotent_error_code(error) && (slave_exec_mode == SLAVE_EXEC_MODE_IDEMPOTENT)); bool ignored_error= (idempotent_error == 0 ? ignored_error_code(actual_error) : 0); #ifdef WITH_WSREP if (WSREP(thd) && wsrep_ignored_error_code(this, actual_error)) { idempotent_error= true; thd->wsrep_has_ignored_error= true; } #endif /* WITH_WSREP */ if (idempotent_error || ignored_error) { if (global_system_variables.log_warnings) slave_rows_error_report(WARNING_LEVEL, error, rgi, thd, table, get_type_str(), RPL_LOG_NAME, log_pos); thd->clear_error(1); error= 0; if (idempotent_error == 0) break; } } /* If m_curr_row_end was not set during event execution (e.g., because of errors) we can't proceed to the next row. If the error is transient (i.e., error==0 at this point) we must call unpack_current_row() to set m_curr_row_end. */ DBUG_PRINT("info", ("curr_row: %p; curr_row_end: %p; rows_end:%p", m_curr_row, m_curr_row_end, m_rows_end)); if (!m_curr_row_end && likely(!error)) error= unpack_current_row(rgi); m_curr_row= m_curr_row_end; if (likely(error == 0) && !transactional_table) thd->transaction.all.modified_non_trans_table= thd->transaction.stmt.modified_non_trans_table= TRUE; } // row processing loop while (error == 0 && (m_curr_row != m_rows_end)); /* Restore the sql_mode after the rows event is processed. */ thd->variables.sql_mode= saved_sql_mode; {/** The following failure injecion works in cooperation with tests setting @@global.debug= 'd,stop_slave_middle_group'. The sql thread receives the killed status and will proceed to shutdown trying to finish incomplete events group. */ DBUG_EXECUTE_IF("stop_slave_middle_group", if (thd->transaction.all.modified_non_trans_table) const_cast(rli)->abort_slave= 1;); } if (unlikely(error= do_after_row_operations(rli, error)) && ignored_error_code(convert_handler_error(error, thd, table))) { if (global_system_variables.log_warnings) slave_rows_error_report(WARNING_LEVEL, error, rgi, thd, table, get_type_str(), RPL_LOG_NAME, log_pos); thd->clear_error(1); error= 0; } } // if (table) if (unlikely(error)) { slave_rows_error_report(ERROR_LEVEL, error, rgi, thd, table, get_type_str(), RPL_LOG_NAME, log_pos); /* @todo We should probably not call reset_current_stmt_binlog_format_row() from here. Note: this applies to log_event_old.cc too. /Sven */ thd->reset_current_stmt_binlog_format_row(); thd->is_slave_error= 1; /* remove trigger's tables */ goto err; } /* remove trigger's tables */ if (slave_run_triggers_for_rbr) restore_empty_query_table_list(thd->lex); #if defined(WITH_WSREP) && defined(HAVE_QUERY_CACHE) if (WSREP(thd) && wsrep_thd_is_applying(thd)) { query_cache.invalidate_locked_for_write(thd, rgi->tables_to_lock); } #endif /* WITH_WSREP && HAVE_QUERY_CACHE */ if (unlikely(get_flags(STMT_END_F) && (error= rows_event_stmt_cleanup(rgi, thd)))) slave_rows_error_report(ERROR_LEVEL, thd->is_error() ? 0 : error, rgi, thd, table, get_type_str(), RPL_LOG_NAME, log_pos); DBUG_RETURN(error); err: if (slave_run_triggers_for_rbr) restore_empty_query_table_list(thd->lex); rgi->slave_close_thread_tables(thd); DBUG_RETURN(error); } Log_event::enum_skip_reason Rows_log_event::do_shall_skip(rpl_group_info *rgi) { /* If the slave skip counter is 1 and this event does not end a statement, then we should not start executing on the next event. Otherwise, we defer the decision to the normal skipping logic. */ if (rgi->rli->slave_skip_counter == 1 && !get_flags(STMT_END_F)) return Log_event::EVENT_SKIP_IGNORE; else return Log_event::do_shall_skip(rgi); } /** The function is called at Rows_log_event statement commit time, normally from Rows_log_event::do_update_pos() and possibly from Query_log_event::do_apply_event() of the COMMIT. The function commits the last statement for engines, binlog and releases resources have been allocated for the statement. @retval 0 Ok. @retval non-zero Error at the commit. */ static int rows_event_stmt_cleanup(rpl_group_info *rgi, THD * thd) { int error; DBUG_ENTER("rows_event_stmt_cleanup"); { /* This is the end of a statement or transaction, so close (and unlock) the tables we opened when processing the Table_map_log_event starting the statement. OBSERVER. This will clear *all* mappings, not only those that are open for the table. There is not good handle for on-close actions for tables. NOTE. Even if we have no table ('table' == 0) we still need to be here, so that we increase the group relay log position. If we didn't, we could have a group relay log position which lags behind "forever" (assume the last master's transaction is ignored by the slave because of replicate-ignore rules). */ error= thd->binlog_flush_pending_rows_event(TRUE); /* If this event is not in a transaction, the call below will, if some transactional storage engines are involved, commit the statement into them and flush the pending event to binlog. If this event is in a transaction, the call will do nothing, but a Xid_log_event will come next which will, if some transactional engines are involved, commit the transaction and flush the pending event to the binlog. If there was a deadlock the transaction should have been rolled back already. So there should be no need to rollback the transaction. */ DBUG_ASSERT(! thd->transaction_rollback_request); error|= (int)(error ? trans_rollback_stmt(thd) : trans_commit_stmt(thd)); /* Now what if this is not a transactional engine? we still need to flush the pending event to the binlog; we did it with thd->binlog_flush_pending_rows_event(). Note that we imitate what is done for real queries: a call to ha_autocommit_or_rollback() (sometimes only if involves a transactional engine), and a call to be sure to have the pending event flushed. */ /* @todo We should probably not call reset_current_stmt_binlog_format_row() from here. Note: this applies to log_event_old.cc too Btw, the previous comment about transactional engines does not seem related to anything that happens here. /Sven */ thd->reset_current_stmt_binlog_format_row(); /* Reset modified_non_trans_table that we have set in rows_log_event::do_apply_event() */ if (!thd->in_multi_stmt_transaction_mode()) { thd->transaction.all.modified_non_trans_table= 0; thd->transaction.all.m_unsafe_rollback_flags&= ~THD_TRANS::DID_WAIT; } rgi->cleanup_context(thd, 0); } DBUG_RETURN(error); } /** The method either increments the relay log position or commits the current statement and increments the master group position if the event is STMT_END_F flagged and the statement corresponds to the autocommit query (i.e replicated without wrapping in BEGIN/COMMIT) @retval 0 Success @retval non-zero Error in the statement commit */ int Rows_log_event::do_update_pos(rpl_group_info *rgi) { Relay_log_info *rli= rgi->rli; int error= 0; DBUG_ENTER("Rows_log_event::do_update_pos"); DBUG_PRINT("info", ("flags: %s", get_flags(STMT_END_F) ? "STMT_END_F " : "")); if (get_flags(STMT_END_F)) { /* Indicate that a statement is finished. Step the group log position if we are not in a transaction, otherwise increase the event log position. */ error= rli->stmt_done(log_pos, thd, rgi); /* Clear any errors in thd->net.last_err*. It is not known if this is needed or not. It is believed that any errors that may exist in thd->net.last_err* are allowed. Examples of errors are "key not found", which is produced in the test case rpl_row_conflicts.test */ thd->clear_error(); } else { rgi->inc_event_relay_log_pos(); } DBUG_RETURN(error); } #endif /* !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) */ #ifndef MYSQL_CLIENT bool Rows_log_event::write_data_header() { uchar buf[ROWS_HEADER_LEN_V2]; // No need to init the buffer DBUG_ASSERT(m_table_id != ~0ULL); DBUG_EXECUTE_IF("old_row_based_repl_4_byte_map_id_master", { int4store(buf + 0, m_table_id); int2store(buf + 4, m_flags); return (write_data(buf, 6)); }); int6store(buf + RW_MAPID_OFFSET, m_table_id); int2store(buf + RW_FLAGS_OFFSET, m_flags); return write_data(buf, ROWS_HEADER_LEN); } bool Rows_log_event::write_data_body() { /* Note that this should be the number of *bits*, not the number of bytes. */ uchar sbuf[MAX_INT_WIDTH]; my_ptrdiff_t const data_size= m_rows_cur - m_rows_buf; bool res= false; uchar *const sbuf_end= net_store_length(sbuf, (size_t) m_width); DBUG_ASSERT(static_cast(sbuf_end - sbuf) <= sizeof(sbuf)); DBUG_DUMP("m_width", sbuf, (size_t) (sbuf_end - sbuf)); res= res || write_data(sbuf, (size_t) (sbuf_end - sbuf)); DBUG_DUMP("m_cols", (uchar*) m_cols.bitmap, no_bytes_in_map(&m_cols)); res= res || write_data((uchar*)m_cols.bitmap, no_bytes_in_map(&m_cols)); /* TODO[refactor write]: Remove the "down cast" here (and elsewhere). */ if (get_general_type_code() == UPDATE_ROWS_EVENT) { DBUG_DUMP("m_cols_ai", (uchar*) m_cols_ai.bitmap, no_bytes_in_map(&m_cols_ai)); res= res || write_data((uchar*)m_cols_ai.bitmap, no_bytes_in_map(&m_cols_ai)); } DBUG_DUMP("rows", m_rows_buf, data_size); res= res || write_data(m_rows_buf, (size_t) data_size); return res; } bool Rows_log_event::write_compressed() { uchar *m_rows_buf_tmp = m_rows_buf; uchar *m_rows_cur_tmp = m_rows_cur; bool ret = true; uint32 comlen, alloc_size; comlen= alloc_size= binlog_get_compress_len((uint32)(m_rows_cur_tmp - m_rows_buf_tmp)); m_rows_buf = (uchar *)my_safe_alloca(alloc_size); if(m_rows_buf && !binlog_buf_compress((const char *)m_rows_buf_tmp, (char *)m_rows_buf, (uint32)(m_rows_cur_tmp - m_rows_buf_tmp), &comlen)) { m_rows_cur= comlen + m_rows_buf; ret= Log_event::write(); } my_safe_afree(m_rows_buf, alloc_size); m_rows_buf= m_rows_buf_tmp; m_rows_cur= m_rows_cur_tmp; return ret; } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Rows_log_event::pack_info(Protocol *protocol) { char buf[256]; char const *const flagstr= get_flags(STMT_END_F) ? " flags: STMT_END_F" : ""; size_t bytes= my_snprintf(buf, sizeof(buf), "table_id: %llu%s", m_table_id, flagstr); protocol->store(buf, bytes, &my_charset_bin); } #endif #ifdef MYSQL_CLIENT const char str_binlog[]= "\nBINLOG '\n"; const char fmt_delim[]= "'%s\n"; const char fmt_n_delim[]= "\n'%s"; const char fmt_frag[]= "\nSET @binlog_fragment_%d ='\n"; const char fmt_binlog2[]= "BINLOG @binlog_fragment_0, @binlog_fragment_1%s\n"; /** Print an event "body" cache to @c file possibly in two fragments. Each fragement is optionally per @c do_wrap to produce an SQL statement. @param file a file to print to @param body the "body" IO_CACHE of event @param do_wrap whether to wrap base64-encoded strings with SQL cover. @param delimiter delimiter string @param is_verbose MDEV-10362 workraround parameter to pass info on presence of verbose printout in cache encoded data The function signals on any error through setting @c body->error to -1. */ bool copy_cache_to_file_wrapped(IO_CACHE *body, FILE *file, bool do_wrap, const char *delimiter, bool is_verbose /*TODO: remove */) { const my_off_t cache_size= my_b_tell(body); if (reinit_io_cache(body, READ_CACHE, 0L, FALSE, FALSE)) goto err; if (!do_wrap) { my_b_copy_to_file(body, file, SIZE_T_MAX); } else if (4 + sizeof(str_binlog) + cache_size + sizeof(fmt_delim) > opt_binlog_rows_event_max_encoded_size) { /* 2 fragments can always represent near 1GB row-based base64-encoded event as two strings each of size less than max(max_allowed_packet). Greater number of fragments does not save from potential need to tweak (increase) @@max_allowed_packet before to process the fragments. So 2 is safe and enough. Split the big query when its packet size's estimation exceeds a limit. The estimate includes the maximum packet header contribution of non-compressed packet. */ my_fprintf(file, fmt_frag, 0); if (my_b_copy_to_file(body, file, (size_t) cache_size/2 + 1)) goto err; my_fprintf(file, fmt_n_delim, delimiter); my_fprintf(file, fmt_frag, 1); if (my_b_copy_to_file(body, file, SIZE_T_MAX)) goto err; my_fprintf(file, fmt_delim, delimiter); my_fprintf(file, fmt_binlog2, delimiter); } else { my_fprintf(file, str_binlog); if (my_b_copy_to_file(body, file, SIZE_T_MAX)) goto err; my_fprintf(file, fmt_delim, delimiter); } reinit_io_cache(body, WRITE_CACHE, 0, FALSE, TRUE); return false; err: body->error = -1; return true; } /** Print an event "body" cache to @c file possibly in two fragments. Each fragment is optionally per @c do_wrap to produce an SQL statement. @param file a file to print to @param body the "body" IO_CACHE of event @param do_wrap whether to wrap base64-encoded strings with SQL cover. @param delimiter delimiter string The function signals on any error through setting @c body->error to -1. */ bool copy_cache_to_string_wrapped(IO_CACHE *cache, LEX_STRING *to, bool do_wrap, const char *delimiter, bool is_verbose) { const my_off_t cache_size= my_b_tell(cache); // contribution to total size estimate of formating const size_t fmt_size= sizeof(str_binlog) + 2*(sizeof(fmt_frag) + 2 /* %d */) + sizeof(fmt_delim) + sizeof(fmt_n_delim) + sizeof(fmt_binlog2) + 3*PRINT_EVENT_INFO::max_delimiter_size; if (reinit_io_cache(cache, READ_CACHE, 0L, FALSE, FALSE)) goto err; if (!(to->str= (char*) my_malloc((size_t)cache->end_of_file + fmt_size, MYF(0)))) { perror("Out of memory: can't allocate memory in " "copy_cache_to_string_wrapped()."); goto err; } if (!do_wrap) { if (my_b_read(cache, (uchar*) to->str, (to->length= (size_t)cache->end_of_file))) goto err; } else if (4 + sizeof(str_binlog) + cache_size + sizeof(fmt_delim) > opt_binlog_rows_event_max_encoded_size) { /* 2 fragments can always represent near 1GB row-based base64-encoded event as two strings each of size less than max(max_allowed_packet). Greater number of fragments does not save from potential need to tweak (increase) @@max_allowed_packet before to process the fragments. So 2 is safe and enough. Split the big query when its packet size's estimation exceeds a limit. The estimate includes the maximum packet header contribution of non-compressed packet. */ char *str= to->str; size_t add_to_len; str += (to->length= sprintf(str, fmt_frag, 0)); if (my_b_read(cache, (uchar*) str, (uint32) (cache_size/2 + 1))) goto err; str += (add_to_len = (uint32) (cache_size/2 + 1)); to->length += add_to_len; str += (add_to_len= sprintf(str, fmt_n_delim, delimiter)); to->length += add_to_len; str += (add_to_len= sprintf(str, fmt_frag, 1)); to->length += add_to_len; if (my_b_read(cache, (uchar*) str, uint32(cache->end_of_file - (cache_size/2 + 1)))) goto err; str += (add_to_len= uint32(cache->end_of_file - (cache_size/2 + 1))); to->length += add_to_len; { str += (add_to_len= sprintf(str , fmt_delim, delimiter)); to->length += add_to_len; } to->length += sprintf(str, fmt_binlog2, delimiter); } else { char *str= to->str; str += (to->length= sprintf(str, str_binlog)); if (my_b_read(cache, (uchar*) str, (size_t)cache->end_of_file)) goto err; str += cache->end_of_file; to->length += (size_t)cache->end_of_file; to->length += sprintf(str , fmt_delim, delimiter); } reinit_io_cache(cache, WRITE_CACHE, 0, FALSE, TRUE); return false; err: cache->error= -1; return true; } /** The function invokes base64 encoder to run on the current event string and store the result into two caches. When the event ends the current statement the caches are is copied into the argument file. Copying is also concerned how to wrap the event, specifically to produce a valid SQL syntax. When the encoded data size is within max(MAX_ALLOWED_PACKET) a regular BINLOG query is composed. Otherwise it is build as fragmented SET @binlog_fragment_0='...'; SET @binlog_fragment_1='...'; BINLOG @binlog_fragment_0, @binlog_fragment_1; where fragments are represented by a pair of indexed user "one shot" variables. @note If any changes made don't forget to duplicate them to Old_rows_log_event as long as it's supported. @param file pointer to IO_CACHE @param print_event_info pointer to print_event_info specializing what out of and how to print the event @param name the name of a table that the event operates on The function signals on any error of cache access through setting that cache's @c error to -1. */ bool Rows_log_event::print_helper(FILE *file, PRINT_EVENT_INFO *print_event_info, char const *const name) { IO_CACHE *const head= &print_event_info->head_cache; IO_CACHE *const body= &print_event_info->body_cache; IO_CACHE *const tail= &print_event_info->tail_cache; #ifdef WHEN_FLASHBACK_REVIEW_READY IO_CACHE *const sql= &print_event_info->review_sql_cache; #endif bool do_print_encoded= print_event_info->base64_output_mode != BASE64_OUTPUT_NEVER && print_event_info->base64_output_mode != BASE64_OUTPUT_DECODE_ROWS && !print_event_info->short_form; bool const last_stmt_event= get_flags(STMT_END_F); if (!print_event_info->short_form) { char llbuff[22]; print_header(head, print_event_info, !last_stmt_event); if (my_b_printf(head, "\t%s: table id %s%s\n", name, ullstr(m_table_id, llbuff), last_stmt_event ? " flags: STMT_END_F" : "")) goto err; } if (!print_event_info->short_form || print_event_info->print_row_count) if (print_base64(body, print_event_info, do_print_encoded)) goto err; if (last_stmt_event) { if (!is_flashback) { if (copy_event_cache_to_file_and_reinit(head, file) || copy_cache_to_file_wrapped(body, file, do_print_encoded, print_event_info->delimiter, print_event_info->verbose) || copy_event_cache_to_file_and_reinit(tail, file)) goto err; } else { LEX_STRING tmp_str; if (copy_event_cache_to_string_and_reinit(head, &tmp_str)) return 1; output_buf.append(tmp_str.str, tmp_str.length); // Not \0 terminated); my_free(tmp_str.str); if (copy_cache_to_string_wrapped(body, &tmp_str, do_print_encoded, print_event_info->delimiter, print_event_info->verbose)) return 1; output_buf.append(tmp_str.str, tmp_str.length); my_free(tmp_str.str); if (copy_event_cache_to_string_and_reinit(tail, &tmp_str)) return 1; output_buf.append(tmp_str.str, tmp_str.length); my_free(tmp_str.str); #ifdef WHEN_FLASHBACK_REVIEW_READY if (copy_event_cache_to_string_and_reinit(sql, &tmp_str)) return 1; output_buf.append(tmp_str.str, tmp_str.length); my_free(tmp_str.str); #endif } } return 0; err: return 1; } #endif /************************************************************************** Annotate_rows_log_event member functions **************************************************************************/ #ifndef MYSQL_CLIENT Annotate_rows_log_event::Annotate_rows_log_event(THD *thd, bool using_trans, bool direct) : Log_event(thd, 0, using_trans), m_save_thd_query_txt(0), m_save_thd_query_len(0), m_saved_thd_query(false), m_used_query_txt(0) { m_query_txt= thd->query(); m_query_len= thd->query_length(); if (direct) cache_type= Log_event::EVENT_NO_CACHE; } #endif Annotate_rows_log_event::Annotate_rows_log_event(const char *buf, uint event_len, const Format_description_log_event *desc) : Log_event(buf, desc), m_save_thd_query_txt(0), m_save_thd_query_len(0), m_saved_thd_query(false), m_used_query_txt(0) { m_query_len= event_len - desc->common_header_len; m_query_txt= (char*) buf + desc->common_header_len; } Annotate_rows_log_event::~Annotate_rows_log_event() { DBUG_ENTER("Annotate_rows_log_event::~Annotate_rows_log_event"); #ifndef MYSQL_CLIENT if (m_saved_thd_query) thd->set_query(m_save_thd_query_txt, m_save_thd_query_len); else if (m_used_query_txt) thd->reset_query(); #endif DBUG_VOID_RETURN; } int Annotate_rows_log_event::get_data_size() { return m_query_len; } Log_event_type Annotate_rows_log_event::get_type_code() { return ANNOTATE_ROWS_EVENT; } bool Annotate_rows_log_event::is_valid() const { return (m_query_txt != NULL && m_query_len != 0); } #ifndef MYSQL_CLIENT bool Annotate_rows_log_event::write_data_header() { return 0; } #endif #ifndef MYSQL_CLIENT bool Annotate_rows_log_event::write_data_body() { return write_data(m_query_txt, m_query_len); } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) void Annotate_rows_log_event::pack_info(Protocol* protocol) { if (m_query_txt && m_query_len) protocol->store(m_query_txt, m_query_len, &my_charset_bin); } #endif #ifdef MYSQL_CLIENT bool Annotate_rows_log_event::print(FILE *file, PRINT_EVENT_INFO *pinfo) { char *pbeg; // beginning of the next line char *pend; // end of the next line uint cnt= 0; // characters counter if (!pinfo->short_form) { if (print_header(&pinfo->head_cache, pinfo, TRUE) || my_b_printf(&pinfo->head_cache, "\tAnnotate_rows:\n")) goto err; } else if (my_b_printf(&pinfo->head_cache, "# Annotate_rows:\n")) goto err; for (pbeg= m_query_txt; ; pbeg= pend) { // skip all \r's and \n's at the beginning of the next line for (;; pbeg++) { if (++cnt > m_query_len) return 0; if (*pbeg != '\r' && *pbeg != '\n') break; } // find end of the next line for (pend= pbeg + 1; ++cnt <= m_query_len && *pend != '\r' && *pend != '\n'; pend++) ; // print next line if (my_b_write(&pinfo->head_cache, (const uchar*) "#Q> ", 4) || my_b_write(&pinfo->head_cache, (const uchar*) pbeg, pend - pbeg) || my_b_write(&pinfo->head_cache, (const uchar*) "\n", 1)) goto err; } return 0; err: return 1; } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) int Annotate_rows_log_event::do_apply_event(rpl_group_info *rgi) { rgi->free_annotate_event(); m_save_thd_query_txt= thd->query(); m_save_thd_query_len= thd->query_length(); m_saved_thd_query= true; m_used_query_txt= 1; thd->set_query(m_query_txt, m_query_len); return 0; } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) int Annotate_rows_log_event::do_update_pos(rpl_group_info *rgi) { rgi->inc_event_relay_log_pos(); return 0; } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) Log_event::enum_skip_reason Annotate_rows_log_event::do_shall_skip(rpl_group_info *rgi) { return continue_group(rgi); } #endif /************************************************************************** Table_map_log_event member functions and support functions **************************************************************************/ /** @page How replication of field metadata works. When a table map is created, the master first calls Table_map_log_event::save_field_metadata() which calculates how many values will be in the field metadata. Only those fields that require the extra data are added. The method also loops through all of the fields in the table calling the method Field::save_field_metadata() which returns the values for the field that will be saved in the metadata and replicated to the slave. Once all fields have been processed, the table map is written to the binlog adding the size of the field metadata and the field metadata to the end of the body of the table map. When a table map is read on the slave, the field metadata is read from the table map and passed to the table_def class constructor which saves the field metadata from the table map into an array based on the type of the field. Field metadata values not present (those fields that do not use extra data) in the table map are initialized as zero (0). The array size is the same as the columns for the table on the slave. Additionally, values saved for field metadata on the master are saved as a string of bytes (uchar) in the binlog. A field may require 1 or more bytes to store the information. In cases where values require multiple bytes (e.g. values > 255), the endian-safe methods are used to properly encode the values on the master and decode them on the slave. When the field metadata values are captured on the slave, they are stored in an array of type uint16. This allows the least number of casts to prevent casting bugs when the field metadata is used in comparisons of field attributes. When the field metadata is used for calculating addresses in pointer math, the type used is uint32. */ #if !defined(MYSQL_CLIENT) /** Save the field metadata based on the real_type of the field. The metadata saved depends on the type of the field. Some fields store a single byte for pack_length() while others store two bytes for field_length (max length). @retval 0 Ok. @todo We may want to consider changing the encoding of the information. Currently, the code attempts to minimize the number of bytes written to the tablemap. There are at least two other alternatives; 1) using net_store_length() to store the data allowing it to choose the number of bytes that are appropriate thereby making the code much easier to maintain (only 1 place to change the encoding), or 2) use a fixed number of bytes for each field. The problem with option 1 is that net_store_length() will use one byte if the value < 251, but 3 bytes if it is > 250. Thus, for fields like CHAR which can be no larger than 255 characters, the method will use 3 bytes when the value is > 250. Further, every value that is encoded using 2 parts (e.g., pack_length, field_length) will be numerically > 250 therefore will use 3 bytes for eah value. The problem with option 2 is less wasteful for space but does waste 1 byte for every field that does not encode 2 parts. */ int Table_map_log_event::save_field_metadata() { DBUG_ENTER("Table_map_log_event::save_field_metadata"); int index= 0; for (unsigned int i= 0 ; i < m_table->s->fields ; i++) { DBUG_PRINT("debug", ("field_type: %d", m_coltype[i])); index+= m_table->s->field[i]->save_field_metadata(&m_field_metadata[index]); } DBUG_RETURN(index); } #endif /* !defined(MYSQL_CLIENT) */ /* Constructor used to build an event for writing to the binary log. Mats says tbl->s lives longer than this event so it's ok to copy pointers (tbl->s->db etc) and not pointer content. */ #if !defined(MYSQL_CLIENT) Table_map_log_event::Table_map_log_event(THD *thd, TABLE *tbl, ulong tid, bool is_transactional) : Log_event(thd, 0, is_transactional), m_table(tbl), m_dbnam(tbl->s->db.str), m_dblen(m_dbnam ? tbl->s->db.length : 0), m_tblnam(tbl->s->table_name.str), m_tbllen(tbl->s->table_name.length), m_colcnt(tbl->s->fields), m_memory(NULL), m_table_id(tid), m_flags(TM_BIT_LEN_EXACT_F), m_data_size(0), m_field_metadata(0), m_field_metadata_size(0), m_null_bits(0), m_meta_memory(NULL) { uchar cbuf[MAX_INT_WIDTH]; uchar *cbuf_end; DBUG_ENTER("Table_map_log_event::Table_map_log_event(TABLE)"); DBUG_ASSERT(m_table_id != ~0ULL); /* In TABLE_SHARE, "db" and "table_name" are 0-terminated (see this comment in table.cc / alloc_table_share(): Use the fact the key is db/0/table_name/0 As we rely on this let's assert it. */ DBUG_ASSERT((tbl->s->db.str == 0) || (tbl->s->db.str[tbl->s->db.length] == 0)); DBUG_ASSERT(tbl->s->table_name.str[tbl->s->table_name.length] == 0); m_data_size= TABLE_MAP_HEADER_LEN; DBUG_EXECUTE_IF("old_row_based_repl_4_byte_map_id_master", m_data_size= 6;); m_data_size+= m_dblen + 2; // Include length and terminating \0 m_data_size+= m_tbllen + 2; // Include length and terminating \0 cbuf_end= net_store_length(cbuf, (size_t) m_colcnt); DBUG_ASSERT(static_cast(cbuf_end - cbuf) <= sizeof(cbuf)); m_data_size+= (cbuf_end - cbuf) + m_colcnt; // COLCNT and column types if (tbl->triggers) m_flags|= TM_BIT_HAS_TRIGGERS_F; /* If malloc fails, caught in is_valid() */ if ((m_memory= (uchar*) my_malloc(m_colcnt, MYF(MY_WME)))) { m_coltype= reinterpret_cast(m_memory); for (unsigned int i= 0 ; i < m_table->s->fields ; ++i) m_coltype[i]= m_table->field[i]->binlog_type(); } /* Calculate a bitmap for the results of maybe_null() for all columns. The bitmap is used to determine when there is a column from the master that is not on the slave and is null and thus not in the row data during replication. */ uint num_null_bytes= (m_table->s->fields + 7) / 8; m_data_size+= num_null_bytes; m_meta_memory= (uchar *)my_multi_malloc(MYF(MY_WME), &m_null_bits, num_null_bytes, &m_field_metadata, (m_colcnt * 2), NULL); bzero(m_field_metadata, (m_colcnt * 2)); /* Create an array for the field metadata and store it. */ m_field_metadata_size= save_field_metadata(); DBUG_ASSERT(m_field_metadata_size <= (m_colcnt * 2)); /* Now set the size of the data to the size of the field metadata array plus one or three bytes (see pack.c:net_store_length) for number of elements in the field metadata array. */ if (m_field_metadata_size < 251) m_data_size+= m_field_metadata_size + 1; else m_data_size+= m_field_metadata_size + 3; bzero(m_null_bits, num_null_bytes); for (unsigned int i= 0 ; i < m_table->s->fields ; ++i) if (m_table->field[i]->maybe_null()) m_null_bits[(i / 8)]+= 1 << (i % 8); DBUG_VOID_RETURN; } #endif /* !defined(MYSQL_CLIENT) */ /* Constructor used by slave to read the event from the binary log. */ #if defined(HAVE_REPLICATION) Table_map_log_event::Table_map_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Log_event(buf, description_event), #ifndef MYSQL_CLIENT m_table(NULL), #endif m_dbnam(NULL), m_dblen(0), m_tblnam(NULL), m_tbllen(0), m_colcnt(0), m_coltype(0), m_memory(NULL), m_table_id(ULONGLONG_MAX), m_flags(0), m_data_size(0), m_field_metadata(0), m_field_metadata_size(0), m_null_bits(0), m_meta_memory(NULL) { DBUG_ENTER("Table_map_log_event::Table_map_log_event(const char*,uint,...)"); uint8 common_header_len= description_event->common_header_len; uint8 post_header_len= description_event->post_header_len[TABLE_MAP_EVENT-1]; DBUG_PRINT("info",("event_len: %u common_header_len: %d post_header_len: %d", event_len, common_header_len, post_header_len)); /* Don't print debug messages when running valgrind since they can trigger false warnings. */ #ifndef HAVE_valgrind DBUG_DUMP("event buffer", (uchar*) buf, event_len); #endif if (event_len < (uint)(common_header_len + post_header_len)) DBUG_VOID_RETURN; /* Read the post-header */ const char *post_start= buf + common_header_len; post_start+= TM_MAPID_OFFSET; VALIDATE_BYTES_READ(post_start, buf, event_len); if (post_header_len == 6) { /* Master is of an intermediate source tree before 5.1.4. Id is 4 bytes */ m_table_id= uint4korr(post_start); post_start+= 4; } else { DBUG_ASSERT(post_header_len == TABLE_MAP_HEADER_LEN); m_table_id= (ulong) uint6korr(post_start); post_start+= TM_FLAGS_OFFSET; } DBUG_ASSERT(m_table_id != ~0ULL); m_flags= uint2korr(post_start); /* Read the variable part of the event */ const char *const vpart= buf + common_header_len + post_header_len; /* Extract the length of the various parts from the buffer */ uchar const *const ptr_dblen= (uchar const*)vpart + 0; VALIDATE_BYTES_READ(ptr_dblen, buf, event_len); m_dblen= *(uchar*) ptr_dblen; /* Length of database name + counter + terminating null */ uchar const *const ptr_tbllen= ptr_dblen + m_dblen + 2; VALIDATE_BYTES_READ(ptr_tbllen, buf, event_len); m_tbllen= *(uchar*) ptr_tbllen; /* Length of table name + counter + terminating null */ uchar const *const ptr_colcnt= ptr_tbllen + m_tbllen + 2; uchar *ptr_after_colcnt= (uchar*) ptr_colcnt; VALIDATE_BYTES_READ(ptr_after_colcnt, buf, event_len); m_colcnt= net_field_length(&ptr_after_colcnt); DBUG_PRINT("info",("m_dblen: %lu off: %ld m_tbllen: %lu off: %ld m_colcnt: %lu off: %ld", (ulong) m_dblen, (long) (ptr_dblen-(const uchar*)vpart), (ulong) m_tbllen, (long) (ptr_tbllen-(const uchar*)vpart), m_colcnt, (long) (ptr_colcnt-(const uchar*)vpart))); /* Allocate mem for all fields in one go. If fails, caught in is_valid() */ m_memory= (uchar*) my_multi_malloc(MYF(MY_WME), &m_dbnam, (uint) m_dblen + 1, &m_tblnam, (uint) m_tbllen + 1, &m_coltype, (uint) m_colcnt, NullS); if (m_memory) { /* Copy the different parts into their memory */ strncpy(const_cast(m_dbnam), (const char*)ptr_dblen + 1, m_dblen + 1); strncpy(const_cast(m_tblnam), (const char*)ptr_tbllen + 1, m_tbllen + 1); memcpy(m_coltype, ptr_after_colcnt, m_colcnt); ptr_after_colcnt= ptr_after_colcnt + m_colcnt; VALIDATE_BYTES_READ(ptr_after_colcnt, buf, event_len); m_field_metadata_size= net_field_length(&ptr_after_colcnt); if(m_field_metadata_size <= (m_colcnt * 2)) { uint num_null_bytes= (m_colcnt + 7) / 8; m_meta_memory= (uchar *)my_multi_malloc(MYF(MY_WME), &m_null_bits, num_null_bytes, &m_field_metadata, m_field_metadata_size, NULL); memcpy(m_field_metadata, ptr_after_colcnt, m_field_metadata_size); ptr_after_colcnt= (uchar*)ptr_after_colcnt + m_field_metadata_size; memcpy(m_null_bits, ptr_after_colcnt, num_null_bytes); } else { m_coltype= NULL; my_free(m_memory); m_memory= NULL; DBUG_VOID_RETURN; } } DBUG_VOID_RETURN; } #endif Table_map_log_event::~Table_map_log_event() { my_free(m_meta_memory); my_free(m_memory); } #ifdef MYSQL_CLIENT /* Rewrite database name for the event to name specified by new_db SYNOPSIS new_db Database name to change to new_len Length desc Event describing binlog that we're writing to. DESCRIPTION Reset db name. This function assumes that temp_buf member contains event representation taken from a binary log. It resets m_dbnam and m_dblen and rewrites temp_buf with new db name. RETURN 0 - Success other - Error */ int Table_map_log_event::rewrite_db(const char* new_db, size_t new_len, const Format_description_log_event* desc) { DBUG_ENTER("Table_map_log_event::rewrite_db"); DBUG_ASSERT(temp_buf); uint header_len= MY_MIN(desc->common_header_len, LOG_EVENT_MINIMAL_HEADER_LEN) + TABLE_MAP_HEADER_LEN; int len_diff; if (!(len_diff= (int)(new_len - m_dblen))) { memcpy((void*) (temp_buf + header_len + 1), new_db, m_dblen + 1); memcpy((void*) m_dbnam, new_db, m_dblen + 1); DBUG_RETURN(0); } // Create new temp_buf ulong event_cur_len= uint4korr(temp_buf + EVENT_LEN_OFFSET); ulong event_new_len= event_cur_len + len_diff; char* new_temp_buf= (char*) my_malloc(event_new_len, MYF(MY_WME)); if (!new_temp_buf) { sql_print_error("Table_map_log_event::rewrite_db: " "failed to allocate new temp_buf (%d bytes required)", event_new_len); DBUG_RETURN(-1); } // Rewrite temp_buf char* ptr= new_temp_buf; size_t cnt= 0; // Copy header and change event length memcpy(ptr, temp_buf, header_len); int4store(ptr + EVENT_LEN_OFFSET, event_new_len); ptr += header_len; cnt += header_len; // Write new db name length and new name DBUG_ASSERT(new_len < 0xff); *ptr++ = (char)new_len; memcpy(ptr, new_db, new_len + 1); ptr += new_len + 1; cnt += m_dblen + 2; // Copy rest part memcpy(ptr, temp_buf + cnt, event_cur_len - cnt); // Reregister temp buf free_temp_buf(); register_temp_buf(new_temp_buf, TRUE); // Reset m_dbnam and m_dblen members m_dblen= new_len; // m_dbnam resides in m_memory together with m_tblnam and m_coltype uchar* memory= m_memory; char const* tblnam= m_tblnam; uchar* coltype= m_coltype; m_memory= (uchar*) my_multi_malloc(MYF(MY_WME), &m_dbnam, (uint) m_dblen + 1, &m_tblnam, (uint) m_tbllen + 1, &m_coltype, (uint) m_colcnt, NullS); if (!m_memory) { sql_print_error("Table_map_log_event::rewrite_db: " "failed to allocate new m_memory (%d + %d + %d bytes required)", m_dblen + 1, m_tbllen + 1, m_colcnt); DBUG_RETURN(-1); } memcpy((void*)m_dbnam, new_db, m_dblen + 1); memcpy((void*)m_tblnam, tblnam, m_tbllen + 1); memcpy(m_coltype, coltype, m_colcnt); my_free(memory); DBUG_RETURN(0); } #endif /* MYSQL_CLIENT */ /* Return value is an error code, one of: -1 Failure to open table [from open_tables()] 0 Success 1 No room for more tables [from set_table()] 2 Out of memory [from set_table()] 3 Wrong table definition 4 Daisy-chaining RBR with SBR not possible */ #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) enum enum_tbl_map_status { /* no duplicate identifier found */ OK_TO_PROCESS= 0, /* this table map must be filtered out */ FILTERED_OUT= 1, /* identifier mapping table with different properties */ SAME_ID_MAPPING_DIFFERENT_TABLE= 2, /* a duplicate identifier was found mapping the same table */ SAME_ID_MAPPING_SAME_TABLE= 3 }; /* Checks if this table map event should be processed or not. First it checks the filtering rules, and then looks for duplicate identifiers in the existing list of rli->tables_to_lock. It checks that there hasn't been any corruption by verifying that there are no duplicate entries with different properties. In some cases, some binary logs could get corrupted, showing several tables mapped to the same table_id, 0 (see: BUG#56226). Thus we do this early sanity check for such cases and avoid that the server crashes later. In some corner cases, the master logs duplicate table map events, i.e., same id, same database name, same table name (see: BUG#37137). This is different from the above as it's the same table that is mapped again to the same identifier. Thus we cannot just check for same ids and assume that the event is corrupted we need to check every property. NOTE: in the event that BUG#37137 ever gets fixed, this extra check will still be valid because we would need to support old binary logs anyway. @param rli The relay log info reference. @param table_list A list element containing the table to check against. @return OK_TO_PROCESS if there was no identifier already in rli->tables_to_lock FILTERED_OUT if the event is filtered according to the filtering rules SAME_ID_MAPPING_DIFFERENT_TABLE if the same identifier already maps a different table in rli->tables_to_lock SAME_ID_MAPPING_SAME_TABLE if the same identifier already maps the same table in rli->tables_to_lock. */ static enum_tbl_map_status check_table_map(rpl_group_info *rgi, RPL_TABLE_LIST *table_list) { DBUG_ENTER("check_table_map"); enum_tbl_map_status res= OK_TO_PROCESS; Relay_log_info *rli= rgi->rli; if ((rgi->thd->slave_thread /* filtering is for slave only */ || IF_WSREP((WSREP(rgi->thd) && rgi->thd->wsrep_applier), 0)) && (!rli->mi->rpl_filter->db_ok(table_list->db.str) || (rli->mi->rpl_filter->is_on() && !rli->mi->rpl_filter->tables_ok("", table_list)))) res= FILTERED_OUT; else { RPL_TABLE_LIST *ptr= static_cast(rgi->tables_to_lock); for(uint i=0 ; ptr && (i< rgi->tables_to_lock_count); ptr= static_cast(ptr->next_local), i++) { if (ptr->table_id == table_list->table_id) { if (cmp(&ptr->db, &table_list->db) || cmp(&ptr->alias, &table_list->table_name) || ptr->lock_type != TL_WRITE) // the ::do_apply_event always sets TL_WRITE res= SAME_ID_MAPPING_DIFFERENT_TABLE; else res= SAME_ID_MAPPING_SAME_TABLE; break; } } } DBUG_PRINT("debug", ("check of table map ended up with: %u", res)); DBUG_RETURN(res); } int Table_map_log_event::do_apply_event(rpl_group_info *rgi) { RPL_TABLE_LIST *table_list; char *db_mem, *tname_mem, *ptr; size_t dummy_len, db_mem_length, tname_mem_length; void *memory; Rpl_filter *filter; Relay_log_info const *rli= rgi->rli; DBUG_ENTER("Table_map_log_event::do_apply_event(Relay_log_info*)"); /* Step the query id to mark what columns that are actually used. */ thd->set_query_id(next_query_id()); if (!(memory= my_multi_malloc(MYF(MY_WME), &table_list, (uint) sizeof(RPL_TABLE_LIST), &db_mem, (uint) NAME_LEN + 1, &tname_mem, (uint) NAME_LEN + 1, NullS))) DBUG_RETURN(HA_ERR_OUT_OF_MEM); db_mem_length= strmov(db_mem, m_dbnam) - db_mem; tname_mem_length= strmov(tname_mem, m_tblnam) - tname_mem; if (lower_case_table_names) { my_casedn_str(files_charset_info, (char*)tname_mem); my_casedn_str(files_charset_info, (char*)db_mem); } /* call from mysql_client_binlog_statement() will not set rli->mi */ filter= rgi->thd->slave_thread ? rli->mi->rpl_filter : global_rpl_filter; /* rewrite rules changed the database */ if (((ptr= (char*) filter->get_rewrite_db(db_mem, &dummy_len)) != db_mem)) db_mem_length= strmov(db_mem, ptr) - db_mem; LEX_CSTRING tmp_db_name= {db_mem, db_mem_length }; LEX_CSTRING tmp_tbl_name= {tname_mem, tname_mem_length }; table_list->init_one_table(&tmp_db_name, &tmp_tbl_name, 0, TL_WRITE); table_list->table_id= DBUG_EVALUATE_IF("inject_tblmap_same_id_maps_diff_table", 0, m_table_id); table_list->updating= 1; table_list->required_type= TABLE_TYPE_NORMAL; DBUG_PRINT("debug", ("table: %s is mapped to %llu", table_list->table_name.str, table_list->table_id)); table_list->master_had_triggers= ((m_flags & TM_BIT_HAS_TRIGGERS_F) ? 1 : 0); DBUG_PRINT("debug", ("table->master_had_triggers=%d", (int)table_list->master_had_triggers)); enum_tbl_map_status tblmap_status= check_table_map(rgi, table_list); if (tblmap_status == OK_TO_PROCESS) { DBUG_ASSERT(thd->lex->query_tables != table_list); /* Use placement new to construct the table_def instance in the memory allocated for it inside table_list. The memory allocated by the table_def structure (i.e., not the memory allocated *for* the table_def structure) is released inside Relay_log_info::clear_tables_to_lock() by calling the table_def destructor explicitly. */ new (&table_list->m_tabledef) table_def(m_coltype, m_colcnt, m_field_metadata, m_field_metadata_size, m_null_bits, m_flags); table_list->m_tabledef_valid= TRUE; table_list->m_conv_table= NULL; table_list->open_type= OT_BASE_ONLY; /* We record in the slave's information that the table should be locked by linking the table into the list of tables to lock. */ table_list->next_global= table_list->next_local= rgi->tables_to_lock; rgi->tables_to_lock= table_list; rgi->tables_to_lock_count++; /* 'memory' is freed in clear_tables_to_lock */ } else // FILTERED_OUT, SAME_ID_MAPPING_* { /* If mapped already but with different properties, we raise an error. If mapped already but with same properties we skip the event. If filtered out we skip the event. In all three cases, we need to free the memory previously allocated. */ if (tblmap_status == SAME_ID_MAPPING_DIFFERENT_TABLE) { /* Something bad has happened. We need to stop the slave as strange things could happen if we proceed: slave crash, wrong table being updated, ... As a consequence we push an error in this case. */ char buf[256]; my_snprintf(buf, sizeof(buf), "Found table map event mapping table id %u which " "was already mapped but with different settings.", table_list->table_id); if (thd->slave_thread) rli->report(ERROR_LEVEL, ER_SLAVE_FATAL_ERROR, rgi->gtid_info(), ER_THD(thd, ER_SLAVE_FATAL_ERROR), buf); else /* For the cases in which a 'BINLOG' statement is set to execute in a user session */ my_error(ER_SLAVE_FATAL_ERROR, MYF(0), buf); } my_free(memory); } DBUG_RETURN(tblmap_status == SAME_ID_MAPPING_DIFFERENT_TABLE); } Log_event::enum_skip_reason Table_map_log_event::do_shall_skip(rpl_group_info *rgi) { /* If the slave skip counter is 1, then we should not start executing on the next event. */ return continue_group(rgi); } int Table_map_log_event::do_update_pos(rpl_group_info *rgi) { rgi->inc_event_relay_log_pos(); return 0; } #endif /* !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) */ #ifndef MYSQL_CLIENT bool Table_map_log_event::write_data_header() { DBUG_ASSERT(m_table_id != ~0ULL); uchar buf[TABLE_MAP_HEADER_LEN]; DBUG_EXECUTE_IF("old_row_based_repl_4_byte_map_id_master", { int4store(buf + 0, m_table_id); int2store(buf + 4, m_flags); return (write_data(buf, 6)); }); int6store(buf + TM_MAPID_OFFSET, m_table_id); int2store(buf + TM_FLAGS_OFFSET, m_flags); return write_data(buf, TABLE_MAP_HEADER_LEN); } bool Table_map_log_event::write_data_body() { DBUG_ASSERT(m_dbnam != NULL); DBUG_ASSERT(m_tblnam != NULL); /* We use only one byte per length for storage in event: */ DBUG_ASSERT(m_dblen <= MY_MIN(NAME_LEN, 255)); DBUG_ASSERT(m_tbllen <= MY_MIN(NAME_LEN, 255)); uchar const dbuf[]= { (uchar) m_dblen }; uchar const tbuf[]= { (uchar) m_tbllen }; uchar cbuf[MAX_INT_WIDTH]; uchar *const cbuf_end= net_store_length(cbuf, (size_t) m_colcnt); DBUG_ASSERT(static_cast(cbuf_end - cbuf) <= sizeof(cbuf)); /* Store the size of the field metadata. */ uchar mbuf[MAX_INT_WIDTH]; uchar *const mbuf_end= net_store_length(mbuf, m_field_metadata_size); return write_data(dbuf, sizeof(dbuf)) || write_data(m_dbnam, m_dblen+1) || write_data(tbuf, sizeof(tbuf)) || write_data(m_tblnam, m_tbllen+1) || write_data(cbuf, (size_t) (cbuf_end - cbuf)) || write_data(m_coltype, m_colcnt) || write_data(mbuf, (size_t) (mbuf_end - mbuf)) || write_data(m_field_metadata, m_field_metadata_size), write_data(m_null_bits, (m_colcnt + 7) / 8); } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) /* Print some useful information for the SHOW BINARY LOG information field. */ #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) void Table_map_log_event::pack_info(Protocol *protocol) { char buf[256]; size_t bytes= my_snprintf(buf, sizeof(buf), "table_id: %llu (%s.%s)", m_table_id, m_dbnam, m_tblnam); protocol->store(buf, bytes, &my_charset_bin); } #endif #endif #ifdef MYSQL_CLIENT bool Table_map_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { if (!print_event_info->short_form) { char llbuff[22]; print_header(&print_event_info->head_cache, print_event_info, TRUE); if (my_b_printf(&print_event_info->head_cache, "\tTable_map: %`s.%`s mapped to number %s%s\n", m_dbnam, m_tblnam, ullstr(m_table_id, llbuff), ((m_flags & TM_BIT_HAS_TRIGGERS_F) ? " (has triggers)" : ""))) goto err; } if (!print_event_info->short_form || print_event_info->print_row_count) { bool do_print_encoded= print_event_info->base64_output_mode != BASE64_OUTPUT_NEVER && print_event_info->base64_output_mode != BASE64_OUTPUT_DECODE_ROWS && !print_event_info->short_form; if (print_base64(&print_event_info->body_cache, print_event_info, do_print_encoded) || copy_event_cache_to_file_and_reinit(&print_event_info->head_cache, file)) goto err; } return 0; err: return 1; } #endif /************************************************************************** Write_rows_log_event member functions **************************************************************************/ /* Constructor used to build an event for writing to the binary log. */ #if !defined(MYSQL_CLIENT) Write_rows_log_event::Write_rows_log_event(THD *thd_arg, TABLE *tbl_arg, ulong tid_arg, bool is_transactional) :Rows_log_event(thd_arg, tbl_arg, tid_arg, tbl_arg->rpl_write_set, is_transactional, WRITE_ROWS_EVENT_V1) { } Write_rows_compressed_log_event::Write_rows_compressed_log_event( THD *thd_arg, TABLE *tbl_arg, ulong tid_arg, bool is_transactional) : Write_rows_log_event(thd_arg, tbl_arg, tid_arg, is_transactional) { m_type = WRITE_ROWS_COMPRESSED_EVENT_V1; } bool Write_rows_compressed_log_event::write() { return Rows_log_event::write_compressed(); } #endif /* Constructor used by slave to read the event from the binary log. */ #ifdef HAVE_REPLICATION Write_rows_log_event::Write_rows_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Rows_log_event(buf, event_len, description_event) { } Write_rows_compressed_log_event::Write_rows_compressed_log_event( const char *buf, uint event_len, const Format_description_log_event *description_event) : Write_rows_log_event(buf, event_len, description_event) { uncompress_buf(); } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) int Write_rows_log_event::do_before_row_operations(const Slave_reporting_capability *const) { int error= 0; /* Increment the global status insert count variable */ if (get_flags(STMT_END_F)) status_var_increment(thd->status_var.com_stat[SQLCOM_INSERT]); /** todo: to introduce a property for the event (handler?) which forces applying the event in the replace (idempotent) fashion. */ if (slave_exec_mode == SLAVE_EXEC_MODE_IDEMPOTENT) { /* We are using REPLACE semantics and not INSERT IGNORE semantics when writing rows, that is: new rows replace old rows. We need to inform the storage engine that it should use this behaviour. */ /* Tell the storage engine that we are using REPLACE semantics. */ thd->lex->duplicates= DUP_REPLACE; /* Pretend we're executing a REPLACE command: this is needed for InnoDB since it is not (properly) checking the lex->duplicates flag. */ thd->lex->sql_command= SQLCOM_REPLACE; /* Do not raise the error flag in case of hitting to an unique attribute */ m_table->file->extra(HA_EXTRA_IGNORE_DUP_KEY); /* The following is needed in case if we have AFTER DELETE triggers. */ m_table->file->extra(HA_EXTRA_WRITE_CAN_REPLACE); m_table->file->extra(HA_EXTRA_IGNORE_NO_KEY); } if (slave_run_triggers_for_rbr && !master_had_triggers && m_table->triggers ) m_table->prepare_triggers_for_insert_stmt_or_event(); /* Honor next number column if present */ m_table->next_number_field= m_table->found_next_number_field; /* * Fixed Bug#45999, In RBR, Store engine of Slave auto-generates new * sequence numbers for auto_increment fields if the values of them are 0. * If generateing a sequence number is decided by the values of * table->auto_increment_field_not_null and SQL_MODE(if includes * MODE_NO_AUTO_VALUE_ON_ZERO) in update_auto_increment function. * SQL_MODE of slave sql thread is always consistency with master's. * In RBR, auto_increment fields never are NULL, except if the auto_inc * column exists only on the slave side (i.e., in an extra column * on the slave's table). */ if (!is_auto_inc_in_extra_columns()) m_table->auto_increment_field_not_null= TRUE; else { /* Here we have checked that there is an extra field on this server's table that has an auto_inc column. Mark that the auto_increment field is null and mark the read and write set bits. (There can only be one AUTO_INC column, it is always indexed and it cannot have a DEFAULT value). */ m_table->auto_increment_field_not_null= FALSE; m_table->mark_auto_increment_column(); } return error; } int Write_rows_log_event::do_after_row_operations(const Slave_reporting_capability *const, int error) { int local_error= 0; /** Clear the write_set bit for auto_inc field that only existed on the destination table as an extra column. */ if (is_auto_inc_in_extra_columns()) { bitmap_clear_bit(m_table->rpl_write_set, m_table->next_number_field->field_index); bitmap_clear_bit(m_table->read_set, m_table->next_number_field->field_index); if (get_flags(STMT_END_F)) m_table->file->ha_release_auto_increment(); } m_table->next_number_field=0; m_table->auto_increment_field_not_null= FALSE; if (slave_exec_mode == SLAVE_EXEC_MODE_IDEMPOTENT) { m_table->file->extra(HA_EXTRA_NO_IGNORE_DUP_KEY); m_table->file->extra(HA_EXTRA_WRITE_CANNOT_REPLACE); /* resetting the extra with table->file->extra(HA_EXTRA_NO_IGNORE_NO_KEY); fires bug#27077 explanation: file->reset() performs this duty ultimately. Still todo: fix */ } if (unlikely((local_error= m_table->file->ha_end_bulk_insert()))) { m_table->file->print_error(local_error, MYF(0)); } return error? error : local_error; } #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) bool Rows_log_event::process_triggers(trg_event_type event, trg_action_time_type time_type, bool old_row_is_record1) { bool result; DBUG_ENTER("Rows_log_event::process_triggers"); m_table->triggers->mark_fields_used(event); if (slave_run_triggers_for_rbr == SLAVE_RUN_TRIGGERS_FOR_RBR_YES) { tmp_disable_binlog(thd); /* Do not replicate the low-level changes. */ result= m_table->triggers->process_triggers(thd, event, time_type, old_row_is_record1); reenable_binlog(thd); } else result= m_table->triggers->process_triggers(thd, event, time_type, old_row_is_record1); DBUG_RETURN(result); } /* Check if there are more UNIQUE keys after the given key. */ static int last_uniq_key(TABLE *table, uint keyno) { while (++keyno < table->s->keys) if (table->key_info[keyno].flags & HA_NOSAME) return 0; return 1; } /** Check if an error is a duplicate key error. This function is used to check if an error code is one of the duplicate key error, i.e., and error code for which it is sensible to do a get_dup_key() to retrieve the duplicate key. @param errcode The error code to check. @return true if the error code is such that get_dup_key() will return true, false otherwise. */ bool is_duplicate_key_error(int errcode) { switch (errcode) { case HA_ERR_FOUND_DUPP_KEY: case HA_ERR_FOUND_DUPP_UNIQUE: return true; } return false; } /** Write the current row into event's table. The row is located in the row buffer, pointed by @c m_curr_row member. Number of columns of the row is stored in @c m_width member (it can be different from the number of columns in the table to which we insert). Bitmap @c m_cols indicates which columns are present in the row. It is assumed that event's table is already open and pointed by @c m_table. If the same record already exists in the table it can be either overwritten or an error is reported depending on the value of @c overwrite flag (error reporting not yet implemented). Note that the matching record can be different from the row we insert if we use primary keys to identify records in the table. The row to be inserted can contain values only for selected columns. The missing columns are filled with default values using @c prepare_record() function. If a matching record is found in the table and @c overwritte is true, the missing columns are taken from it. @param rli Relay log info (needed for row unpacking). @param overwrite Shall we overwrite if the row already exists or signal error (currently ignored). @returns Error code on failure, 0 on success. This method, if successful, sets @c m_curr_row_end pointer to point at the next row in the rows buffer. This is done when unpacking the row to be inserted. @note If a matching record is found, it is either updated using @c ha_update_row() or first deleted and then new record written. */ int Rows_log_event::write_row(rpl_group_info *rgi, const bool overwrite) { DBUG_ENTER("write_row"); DBUG_ASSERT(m_table != NULL && thd != NULL); TABLE *table= m_table; // pointer to event's table int error; int UNINIT_VAR(keynum); const bool invoke_triggers= slave_run_triggers_for_rbr && !master_had_triggers && table->triggers; auto_afree_ptr key(NULL); prepare_record(table, m_width, true); /* unpack row into table->record[0] */ if (unlikely((error= unpack_current_row(rgi)))) { table->file->print_error(error, MYF(0)); DBUG_RETURN(error); } if (m_curr_row == m_rows_buf && !invoke_triggers) { /* This table has no triggers so we can do bulk insert. This is the first row to be inserted, we estimate the rows with the size of the first row and use that value to initialize storage engine for bulk insertion. */ /* this is the first row to be inserted, we estimate the rows with the size of the first row and use that value to initialize storage engine for bulk insertion */ DBUG_ASSERT(!(m_curr_row > m_curr_row_end)); ha_rows estimated_rows= 0; if (m_curr_row < m_curr_row_end) estimated_rows= (m_rows_end - m_curr_row) / (m_curr_row_end - m_curr_row); else if (m_curr_row == m_curr_row_end) estimated_rows= 1; table->file->ha_start_bulk_insert(estimated_rows); } /* Explicitly set the auto_inc to null to make sure that it gets an auto_generated value. */ if (is_auto_inc_in_extra_columns()) m_table->next_number_field->set_null(); DBUG_DUMP("record[0]", table->record[0], table->s->reclength); DBUG_PRINT_BITSET("debug", "rpl_write_set: %s", table->rpl_write_set); DBUG_PRINT_BITSET("debug", "read_set: %s", table->read_set); if (invoke_triggers && unlikely(process_triggers(TRG_EVENT_INSERT, TRG_ACTION_BEFORE, TRUE))) { DBUG_RETURN(HA_ERR_GENERIC); // in case if error is not set yet } // Handle INSERT. if (table->versioned(VERS_TIMESTAMP)) { ulong sec_part; bitmap_set_bit(table->read_set, table->vers_start_field()->field_index); table->file->column_bitmaps_signal(); // Check whether a row came from unversioned table and fix vers fields. if (table->vers_start_field()->get_timestamp(&sec_part) == 0 && sec_part == 0) table->vers_update_fields(); } /* Try to write record. If a corresponding record already exists in the table, we try to change it using ha_update_row() if possible. Otherwise we delete it and repeat the whole process again. TODO: Add safety measures against infinite looping. */ if (table->s->sequence) error= update_sequence(); else while (unlikely(error= table->file->ha_write_row(table->record[0]))) { if (error == HA_ERR_LOCK_DEADLOCK || error == HA_ERR_LOCK_WAIT_TIMEOUT || (keynum= table->file->get_dup_key(error)) < 0 || !overwrite) { DBUG_PRINT("info",("get_dup_key returns %d)", keynum)); /* Deadlock, waiting for lock or just an error from the handler such as HA_ERR_FOUND_DUPP_KEY when overwrite is false. Retrieval of the duplicate key number may fail - either because the error was not "duplicate key" error - or because the information which key is not available */ table->file->print_error(error, MYF(0)); DBUG_RETURN(error); } /* We need to retrieve the old row into record[1] to be able to either update or delete the offending record. We either: - use rnd_pos() with a row-id (available as dupp_row) to the offending row, if that is possible (MyISAM and Blackhole), or else - use index_read_idx() with the key that is duplicated, to retrieve the offending row. */ if (table->file->ha_table_flags() & HA_DUPLICATE_POS) { DBUG_PRINT("info",("Locating offending record using rnd_pos()")); if ((error= table->file->ha_rnd_init_with_error(0))) { DBUG_RETURN(error); } error= table->file->ha_rnd_pos(table->record[1], table->file->dup_ref); if (unlikely(error)) { DBUG_PRINT("info",("rnd_pos() returns error %d",error)); table->file->print_error(error, MYF(0)); DBUG_RETURN(error); } table->file->ha_rnd_end(); } else { DBUG_PRINT("info",("Locating offending record using index_read_idx()")); if (table->file->extra(HA_EXTRA_FLUSH_CACHE)) { DBUG_PRINT("info",("Error when setting HA_EXTRA_FLUSH_CACHE")); DBUG_RETURN(my_errno); } if (key.get() == NULL) { key.assign(static_cast(my_alloca(table->s->max_unique_length))); if (key.get() == NULL) { DBUG_PRINT("info",("Can't allocate key buffer")); DBUG_RETURN(ENOMEM); } } key_copy((uchar*)key.get(), table->record[0], table->key_info + keynum, 0); error= table->file->ha_index_read_idx_map(table->record[1], keynum, (const uchar*)key.get(), HA_WHOLE_KEY, HA_READ_KEY_EXACT); if (unlikely(error)) { DBUG_PRINT("info",("index_read_idx() returns %s", HA_ERR(error))); table->file->print_error(error, MYF(0)); DBUG_RETURN(error); } } /* Now, record[1] should contain the offending row. That will enable us to update it or, alternatively, delete it (so that we can insert the new row afterwards). */ /* If row is incomplete we will use the record found to fill missing columns. */ if (!get_flags(COMPLETE_ROWS_F)) { restore_record(table,record[1]); error= unpack_current_row(rgi); } DBUG_PRINT("debug",("preparing for update: before and after image")); DBUG_DUMP("record[1] (before)", table->record[1], table->s->reclength); DBUG_DUMP("record[0] (after)", table->record[0], table->s->reclength); /* REPLACE is defined as either INSERT or DELETE + INSERT. If possible, we can replace it with an UPDATE, but that will not work on InnoDB if FOREIGN KEY checks are necessary. I (Matz) am not sure of the reason for the last_uniq_key() check as, but I'm guessing that it's something along the following lines. Suppose that we got the duplicate key to be a key that is not the last unique key for the table and we perform an update: then there might be another key for which the unique check will fail, so we're better off just deleting the row and inserting the correct row. Additionally we don't use UPDATE if rbr triggers should be invoked - when triggers are used we want a simple and predictable execution path. */ if (last_uniq_key(table, keynum) && !invoke_triggers && !table->file->referenced_by_foreign_key()) { DBUG_PRINT("info",("Updating row using ha_update_row()")); error= table->file->ha_update_row(table->record[1], table->record[0]); switch (error) { case HA_ERR_RECORD_IS_THE_SAME: DBUG_PRINT("info",("ignoring HA_ERR_RECORD_IS_THE_SAME error from" " ha_update_row()")); error= 0; case 0: break; default: DBUG_PRINT("info",("ha_update_row() returns error %d",error)); table->file->print_error(error, MYF(0)); } DBUG_RETURN(error); } else { DBUG_PRINT("info",("Deleting offending row and trying to write new one again")); if (invoke_triggers && unlikely(process_triggers(TRG_EVENT_DELETE, TRG_ACTION_BEFORE, TRUE))) error= HA_ERR_GENERIC; // in case if error is not set yet else { if (unlikely((error= table->file->ha_delete_row(table->record[1])))) { DBUG_PRINT("info",("ha_delete_row() returns error %d",error)); table->file->print_error(error, MYF(0)); DBUG_RETURN(error); } if (invoke_triggers && unlikely(process_triggers(TRG_EVENT_DELETE, TRG_ACTION_AFTER, TRUE))) DBUG_RETURN(HA_ERR_GENERIC); // in case if error is not set yet } /* Will retry ha_write_row() with the offending row removed. */ } } if (invoke_triggers && unlikely(process_triggers(TRG_EVENT_INSERT, TRG_ACTION_AFTER, TRUE))) error= HA_ERR_GENERIC; // in case if error is not set yet DBUG_RETURN(error); } int Rows_log_event::update_sequence() { TABLE *table= m_table; // pointer to event's table if (!bitmap_is_set(table->rpl_write_set, MIN_VALUE_FIELD_NO)) { /* This event come from a setval function executed on the master. Update the sequence next_number and round, like we do with setval() */ my_bitmap_map *old_map= dbug_tmp_use_all_columns(table, table->read_set); longlong nextval= table->field[NEXT_FIELD_NO]->val_int(); longlong round= table->field[ROUND_FIELD_NO]->val_int(); dbug_tmp_restore_column_map(table->read_set, old_map); return table->s->sequence->set_value(table, nextval, round, 0) > 0; } /* Update all fields in table and update the active sequence, like with ALTER SEQUENCE */ return table->file->ha_write_row(table->record[0]); } #endif int Write_rows_log_event::do_exec_row(rpl_group_info *rgi) { DBUG_ASSERT(m_table != NULL); const char *tmp= thd->get_proc_info(); const char *message= "Write_rows_log_event::write_row()"; int error; #ifdef WSREP_PROC_INFO my_snprintf(thd->wsrep_info, sizeof(thd->wsrep_info) - 1, "Write_rows_log_event::write_row(%lld)", (long long) wsrep_thd_trx_seqno(thd)); message= thd->wsrep_info; #endif /* WSREP_PROC_INFO */ thd_proc_info(thd, message); error= write_row(rgi, slave_exec_mode == SLAVE_EXEC_MODE_IDEMPOTENT); thd_proc_info(thd, tmp); if (unlikely(error) && unlikely(!thd->is_error())) { DBUG_ASSERT(0); my_error(ER_UNKNOWN_ERROR, MYF(0)); } return error; } #endif /* !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) */ #ifdef MYSQL_CLIENT bool Write_rows_log_event::print(FILE *file, PRINT_EVENT_INFO* print_event_info) { DBUG_EXECUTE_IF("simulate_cache_read_error", {DBUG_SET("+d,simulate_my_b_fill_error");}); return Rows_log_event::print_helper(file, print_event_info, is_flashback ? "Delete_rows" : "Write_rows"); } bool Write_rows_compressed_log_event::print(FILE *file, PRINT_EVENT_INFO* print_event_info) { char *new_buf; ulong len; bool is_malloc = false; if(!row_log_event_uncompress(glob_description_event, checksum_alg == BINLOG_CHECKSUM_ALG_CRC32, temp_buf, UINT_MAX32, NULL, 0, &is_malloc, &new_buf, &len)) { free_temp_buf(); register_temp_buf(new_buf, true); if (Rows_log_event::print_helper(file, print_event_info, "Write_compressed_rows")) goto err; } else { if (my_b_printf(&print_event_info->head_cache, "ERROR: uncompress write_compressed_rows failed\n")) goto err; } return 0; err: return 1; } #endif #if defined(MYSQL_SERVER) && defined(HAVE_REPLICATION) uint8 Write_rows_log_event::get_trg_event_map() { return trg2bit(TRG_EVENT_INSERT) | trg2bit(TRG_EVENT_UPDATE) | trg2bit(TRG_EVENT_DELETE); } #endif /************************************************************************** Delete_rows_log_event member functions **************************************************************************/ #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) /* Compares table->record[0] and table->record[1] Returns TRUE if different. */ static bool record_compare(TABLE *table) { bool result= FALSE; /** Compare full record only if: - there are no blob fields (otherwise we would also need to compare blobs contents as well); - there are no varchar fields (otherwise we would also need to compare varchar contents as well); - there are no null fields, otherwise NULLed fields contents (i.e., the don't care bytes) may show arbitrary values, depending on how each engine handles internally. */ if ((table->s->blob_fields + table->s->varchar_fields + table->s->null_fields) == 0) { result= cmp_record(table,record[1]); goto record_compare_exit; } /* Compare null bits */ if (memcmp(table->null_flags, table->null_flags+table->s->rec_buff_length, table->s->null_bytes)) { result= TRUE; // Diff in NULL value goto record_compare_exit; } /* Compare fields */ for (Field **ptr=table->field ; *ptr ; ptr++) { if (table->versioned() && (*ptr)->vers_sys_field()) { continue; } /** We only compare field contents that are not null. NULL fields (i.e., their null bits) were compared earlier. */ if (!(*(ptr))->is_null()) { if ((*ptr)->cmp_binary_offset(table->s->rec_buff_length)) { result= TRUE; goto record_compare_exit; } } } record_compare_exit: return result; } /** Find the best key to use when locating the row in @c find_row(). A primary key is preferred if it exists; otherwise a unique index is preferred. Else we pick the index with the smallest rec_per_key value. If a suitable key is found, set @c m_key, @c m_key_nr and @c m_key_info member fields appropriately. @returns Error code on failure, 0 on success. */ int Rows_log_event::find_key() { uint i, best_key_nr, last_part; KEY *key, *UNINIT_VAR(best_key); ulong UNINIT_VAR(best_rec_per_key), tmp; DBUG_ENTER("Rows_log_event::find_key"); DBUG_ASSERT(m_table); best_key_nr= MAX_KEY; /* Keys are sorted so that any primary key is first, followed by unique keys, followed by any other. So we will automatically pick the primary key if it exists. */ for (i= 0, key= m_table->key_info; i < m_table->s->keys; i++, key++) { if (!m_table->s->keys_in_use.is_set(i)) continue; /* We cannot use a unique key with NULL-able columns to uniquely identify a row (but we can still select it for range scan below if nothing better is available). */ if ((key->flags & (HA_NOSAME | HA_NULL_PART_KEY)) == HA_NOSAME) { best_key_nr= i; best_key= key; break; } /* We can only use a non-unique key if it allows range scans (ie. skip FULLTEXT indexes and such). */ last_part= key->user_defined_key_parts - 1; DBUG_PRINT("info", ("Index %s rec_per_key[%u]= %lu", key->name.str, last_part, key->rec_per_key[last_part])); if (!(m_table->file->index_flags(i, last_part, 1) & HA_READ_NEXT)) continue; tmp= key->rec_per_key[last_part]; if (best_key_nr == MAX_KEY || (tmp > 0 && tmp < best_rec_per_key)) { best_key_nr= i; best_key= key; best_rec_per_key= tmp; } } if (best_key_nr == MAX_KEY) { m_key_info= NULL; DBUG_RETURN(0); } // Allocate buffer for key searches m_key= (uchar *) my_malloc(best_key->key_length, MYF(MY_WME)); if (m_key == NULL) DBUG_RETURN(HA_ERR_OUT_OF_MEM); m_key_info= best_key; m_key_nr= best_key_nr; DBUG_RETURN(0);; } /* Check if we are already spending too much time on this statement. if we are, warn user that it might be because table does not have a PK, but only if the warning was not printed before for this STMT. @param type The event type code. @param table_name The name of the table that the slave is operating. @param is_index_scan States whether the slave is doing an index scan or not. @param rli The relay metadata info. */ static inline void issue_long_find_row_warning(Log_event_type type, const char *table_name, bool is_index_scan, rpl_group_info *rgi) { if ((global_system_variables.log_warnings > 1 && !rgi->is_long_find_row_note_printed())) { ulonglong now= microsecond_interval_timer(); ulonglong stmt_ts= rgi->get_row_stmt_start_timestamp(); DBUG_EXECUTE_IF("inject_long_find_row_note", stmt_ts-=(LONG_FIND_ROW_THRESHOLD*2*HRTIME_RESOLUTION);); longlong delta= (now - stmt_ts)/HRTIME_RESOLUTION; if (delta > LONG_FIND_ROW_THRESHOLD) { rgi->set_long_find_row_note_printed(); const char* evt_type= LOG_EVENT_IS_DELETE_ROW(type) ? " DELETE" : "n UPDATE"; const char* scan_type= is_index_scan ? "scanning an index" : "scanning the table"; sql_print_information("The slave is applying a ROW event on behalf of a%s statement " "on table %s and is currently taking a considerable amount " "of time (%lld seconds). This is due to the fact that it is %s " "while looking up records to be processed. Consider adding a " "primary key (or unique key) to the table to improve " "performance.", evt_type, table_name, (long) delta, scan_type); } } } /* HA_ERR_KEY_NOT_FOUND is a fatal error normally, but it's an expected error in speculate optimistic mode, so use something non-fatal instead */ static int row_not_found_error(rpl_group_info *rgi) { return rgi->speculation != rpl_group_info::SPECULATE_OPTIMISTIC ? HA_ERR_KEY_NOT_FOUND : HA_ERR_RECORD_CHANGED; } /** Locate the current row in event's table. The current row is pointed by @c m_curr_row. Member @c m_width tells how many columns are there in the row (this can be different from the number of columns in the table). It is assumed that event's table is already open and pointed by @c m_table. If a corresponding record is found in the table it is stored in @c m_table->record[0]. Note that when record is located based on a primary key, it is possible that the record found differs from the row being located. If no key is specified or table does not have keys, a table scan is used to find the row. In that case the row should be complete and contain values for all columns. However, it can still be shorter than the table, i.e. the table can contain extra columns not present in the row. It is also possible that the table has fewer columns than the row being located. @returns Error code on failure, 0 on success. @post In case of success @c m_table->record[0] contains the record found. Also, the internal "cursor" of the table is positioned at the record found. @note If the engine allows random access of the records, a combination of @c position() and @c rnd_pos() will be used. Note that one MUST call ha_index_or_rnd_end() after this function if it returns 0 as we must leave the row position in the handler intact for any following update/delete command. */ int Rows_log_event::find_row(rpl_group_info *rgi) { DBUG_ENTER("Rows_log_event::find_row"); DBUG_ASSERT(m_table && m_table->in_use != NULL); TABLE *table= m_table; int error= 0; bool is_table_scan= false, is_index_scan= false; /* rpl_row_tabledefs.test specifies that if the extra field on the slave does not have a default value and this is okay with Delete or Update events. Todo: fix wl3228 hld that requires defaults for all types of events */ prepare_record(table, m_width, FALSE); error= unpack_current_row(rgi); m_vers_from_plain= false; if (table->versioned()) { Field *row_end= table->vers_end_field(); DBUG_ASSERT(table->read_set); bitmap_set_bit(table->read_set, row_end->field_index); // check whether master table is unversioned if (row_end->val_int() == 0) { bitmap_set_bit(table->write_set, row_end->field_index); // Plain source table may have a PRIMARY KEY. And row_end is always // a part of PRIMARY KEY. Set it to max value for engine to find it in // index. Needed for an UPDATE/DELETE cases. table->vers_end_field()->set_max(); m_vers_from_plain= true; } table->file->column_bitmaps_signal(); } DBUG_PRINT("info",("looking for the following record")); DBUG_DUMP("record[0]", table->record[0], table->s->reclength); if ((table->file->ha_table_flags() & HA_PRIMARY_KEY_REQUIRED_FOR_POSITION) && table->s->primary_key < MAX_KEY) { /* Use a more efficient method to fetch the record given by table->record[0] if the engine allows it. We first compute a row reference using the position() member function (it will be stored in table->file->ref) and the use rnd_pos() to position the "cursor" (i.e., record[0] in this case) at the correct row. TODO: Add a check that the correct record has been fetched by comparing with the original record. Take into account that the record on the master and slave can be of different length. Something along these lines should work: ADD>>> store_record(table,record[1]); int error= table->file->ha_rnd_pos(table->record[0], table->file->ref); ADD>>> DBUG_ASSERT(memcmp(table->record[1], table->record[0], table->s->reclength) == 0); */ int error; DBUG_PRINT("info",("locating record using primary key (position)")); error= table->file->ha_rnd_pos_by_record(table->record[0]); if (unlikely(error)) { DBUG_PRINT("info",("rnd_pos returns error %d",error)); if (error == HA_ERR_KEY_NOT_FOUND) error= row_not_found_error(rgi); table->file->print_error(error, MYF(0)); } DBUG_RETURN(error); } // We can't use position() - try other methods. /* We need to retrieve all fields TODO: Move this out from this function to main loop */ table->use_all_columns(); /* Save copy of the record in table->record[1]. It might be needed later if linear search is used to find exact match. */ store_record(table,record[1]); if (m_key_info) { DBUG_PRINT("info",("locating record using key #%u [%s] (index_read)", m_key_nr, m_key_info->name.str)); /* We use this to test that the correct key is used in test cases. */ DBUG_EXECUTE_IF("slave_crash_if_wrong_index", if(0 != strcmp(m_key_info->name.str,"expected_key")) abort();); /* The key is active: search the table using the index */ if (!table->file->inited && (error= table->file->ha_index_init(m_key_nr, FALSE))) { DBUG_PRINT("info",("ha_index_init returns error %d",error)); table->file->print_error(error, MYF(0)); goto end; } /* Fill key data for the row */ DBUG_ASSERT(m_key); key_copy(m_key, table->record[0], m_key_info, 0); /* Don't print debug messages when running valgrind since they can trigger false warnings. */ #ifndef HAVE_valgrind DBUG_DUMP("key data", m_key, m_key_info->key_length); #endif /* We need to set the null bytes to ensure that the filler bit are all set when returning. There are storage engines that just set the necessary bits on the bytes and don't set the filler bits correctly. */ if (table->s->null_bytes > 0) table->record[0][table->s->null_bytes - 1]|= 256U - (1U << table->s->last_null_bit_pos); if (unlikely((error= table->file->ha_index_read_map(table->record[0], m_key, HA_WHOLE_KEY, HA_READ_KEY_EXACT)))) { DBUG_PRINT("info",("no record matching the key found in the table")); if (error == HA_ERR_KEY_NOT_FOUND) error= row_not_found_error(rgi); table->file->print_error(error, MYF(0)); table->file->ha_index_end(); goto end; } /* Don't print debug messages when running valgrind since they can trigger false warnings. */ #ifndef HAVE_valgrind DBUG_PRINT("info",("found first matching record")); DBUG_DUMP("record[0]", table->record[0], table->s->reclength); #endif /* Below is a minor "optimization". If the key (i.e., key number 0) has the HA_NOSAME flag set, we know that we have found the correct record (since there can be no duplicates); otherwise, we have to compare the record with the one found to see if it is the correct one. CAVEAT! This behaviour is essential for the replication of, e.g., the mysql.proc table since the correct record *shall* be found using the primary key *only*. There shall be no comparison of non-PK columns to decide if the correct record is found. I can see no scenario where it would be incorrect to chose the row to change only using a PK or an UNNI. */ if (table->key_info->flags & HA_NOSAME) { /* Unique does not have non nullable part */ if (!(table->key_info->flags & (HA_NULL_PART_KEY))) { error= 0; goto end; } else { KEY *keyinfo= table->key_info; /* Unique has nullable part. We need to check if there is any field in the BI image that is null and part of UNNI. */ bool null_found= FALSE; for (uint i=0; i < keyinfo->user_defined_key_parts && !null_found; i++) { uint fieldnr= keyinfo->key_part[i].fieldnr - 1; Field **f= table->field+fieldnr; null_found= (*f)->is_null(); } if (!null_found) { error= 0; goto end; } /* else fall through to index scan */ } } is_index_scan=true; /* In case key is not unique, we still have to iterate over records found and find the one which is identical to the row given. A copy of the record we are looking for is stored in record[1]. */ DBUG_PRINT("info",("non-unique index, scanning it to find matching record")); /* We use this to test that the correct key is used in test cases. */ DBUG_EXECUTE_IF("slave_crash_if_index_scan", abort();); while (record_compare(table)) { while ((error= table->file->ha_index_next(table->record[0]))) { DBUG_PRINT("info",("no record matching the given row found")); table->file->print_error(error, MYF(0)); table->file->ha_index_end(); goto end; } } } else { DBUG_PRINT("info",("locating record using table scan (rnd_next)")); /* We use this to test that the correct key is used in test cases. */ DBUG_EXECUTE_IF("slave_crash_if_table_scan", abort();); /* We don't have a key: search the table using rnd_next() */ if (unlikely((error= table->file->ha_rnd_init_with_error(1)))) { DBUG_PRINT("info",("error initializing table scan" " (ha_rnd_init returns %d)",error)); goto end; } is_table_scan= true; /* Continue until we find the right record or have made a full loop */ do { error= table->file->ha_rnd_next(table->record[0]); if (unlikely(error)) DBUG_PRINT("info", ("error: %s", HA_ERR(error))); switch (error) { case 0: DBUG_DUMP("record found", table->record[0], table->s->reclength); break; case HA_ERR_END_OF_FILE: DBUG_PRINT("info", ("Record not found")); table->file->ha_rnd_end(); goto end; default: DBUG_PRINT("info", ("Failed to get next record" " (rnd_next returns %d)",error)); table->file->print_error(error, MYF(0)); table->file->ha_rnd_end(); goto end; } } while (record_compare(table)); /* Note: above record_compare will take into account all record fields which might be incorrect in case a partial row was given in the event */ DBUG_ASSERT(error == HA_ERR_END_OF_FILE || error == 0); } end: if (is_table_scan || is_index_scan) issue_long_find_row_warning(get_general_type_code(), m_table->alias.c_ptr(), is_index_scan, rgi); DBUG_RETURN(error); } #endif /* Constructor used to build an event for writing to the binary log. */ #ifndef MYSQL_CLIENT Delete_rows_log_event::Delete_rows_log_event(THD *thd_arg, TABLE *tbl_arg, ulong tid, bool is_transactional) : Rows_log_event(thd_arg, tbl_arg, tid, tbl_arg->read_set, is_transactional, DELETE_ROWS_EVENT_V1) { } Delete_rows_compressed_log_event::Delete_rows_compressed_log_event( THD *thd_arg, TABLE *tbl_arg, ulong tid_arg, bool is_transactional) : Delete_rows_log_event(thd_arg, tbl_arg, tid_arg, is_transactional) { m_type= DELETE_ROWS_COMPRESSED_EVENT_V1; } bool Delete_rows_compressed_log_event::write() { return Rows_log_event::write_compressed(); } #endif /* #if !defined(MYSQL_CLIENT) */ /* Constructor used by slave to read the event from the binary log. */ #ifdef HAVE_REPLICATION Delete_rows_log_event::Delete_rows_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Rows_log_event(buf, event_len, description_event) { } Delete_rows_compressed_log_event::Delete_rows_compressed_log_event( const char *buf, uint event_len, const Format_description_log_event *description_event) : Delete_rows_log_event(buf, event_len, description_event) { uncompress_buf(); } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) int Delete_rows_log_event::do_before_row_operations(const Slave_reporting_capability *const) { /* Increment the global status delete count variable */ if (get_flags(STMT_END_F)) status_var_increment(thd->status_var.com_stat[SQLCOM_DELETE]); if ((m_table->file->ha_table_flags() & HA_PRIMARY_KEY_REQUIRED_FOR_POSITION) && m_table->s->primary_key < MAX_KEY) { /* We don't need to allocate any memory for m_key since it is not used. */ return 0; } if (slave_run_triggers_for_rbr && !master_had_triggers) m_table->prepare_triggers_for_delete_stmt_or_event(); return find_key(); } int Delete_rows_log_event::do_after_row_operations(const Slave_reporting_capability *const, int error) { m_table->file->ha_index_or_rnd_end(); my_free(m_key); m_key= NULL; m_key_info= NULL; return error; } int Delete_rows_log_event::do_exec_row(rpl_group_info *rgi) { int error; const char *tmp= thd->get_proc_info(); const char *message= "Delete_rows_log_event::find_row()"; const bool invoke_triggers= slave_run_triggers_for_rbr && !master_had_triggers && m_table->triggers; DBUG_ASSERT(m_table != NULL); #ifdef WSREP_PROC_INFO my_snprintf(thd->wsrep_info, sizeof(thd->wsrep_info) - 1, "Delete_rows_log_event::find_row(%lld)", (long long) wsrep_thd_trx_seqno(thd)); message= thd->wsrep_info; #endif /* WSREP_PROC_INFO */ thd_proc_info(thd, message); if (likely(!(error= find_row(rgi)))) { /* Delete the record found, located in record[0] */ message= "Delete_rows_log_event::ha_delete_row()"; #ifdef WSREP_PROC_INFO snprintf(thd->wsrep_info, sizeof(thd->wsrep_info) - 1, "Delete_rows_log_event::ha_delete_row(%lld)", (long long) wsrep_thd_trx_seqno(thd)); message= thd->wsrep_info; #endif thd_proc_info(thd, message); if (invoke_triggers && unlikely(process_triggers(TRG_EVENT_DELETE, TRG_ACTION_BEFORE, FALSE))) error= HA_ERR_GENERIC; // in case if error is not set yet if (likely(!error)) { m_table->mark_columns_per_binlog_row_image(); if (m_vers_from_plain && m_table->versioned(VERS_TIMESTAMP)) { Field *end= m_table->vers_end_field(); bitmap_set_bit(m_table->write_set, end->field_index); store_record(m_table, record[1]); end->set_time(); error= m_table->file->ha_update_row(m_table->record[1], m_table->record[0]); } else { error= m_table->file->ha_delete_row(m_table->record[0]); } m_table->default_column_bitmaps(); } if (invoke_triggers && likely(!error) && unlikely(process_triggers(TRG_EVENT_DELETE, TRG_ACTION_AFTER, FALSE))) error= HA_ERR_GENERIC; // in case if error is not set yet m_table->file->ha_index_or_rnd_end(); } thd_proc_info(thd, tmp); return error; } #endif /* !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) */ #ifdef MYSQL_CLIENT bool Delete_rows_log_event::print(FILE *file, PRINT_EVENT_INFO* print_event_info) { return Rows_log_event::print_helper(file, print_event_info, is_flashback ? "Write_rows" : "Delete_rows"); } bool Delete_rows_compressed_log_event::print(FILE *file, PRINT_EVENT_INFO* print_event_info) { char *new_buf; ulong len; bool is_malloc = false; if(!row_log_event_uncompress(glob_description_event, checksum_alg == BINLOG_CHECKSUM_ALG_CRC32, temp_buf, UINT_MAX32, NULL, 0, &is_malloc, &new_buf, &len)) { free_temp_buf(); register_temp_buf(new_buf, true); if (Rows_log_event::print_helper(file, print_event_info, "Delete_compressed_rows")) goto err; } else { if (my_b_printf(&print_event_info->head_cache, "ERROR: uncompress delete_compressed_rows failed\n")) goto err; } return 0; err: return 1; } #endif #if defined(MYSQL_SERVER) && defined(HAVE_REPLICATION) uint8 Delete_rows_log_event::get_trg_event_map() { return trg2bit(TRG_EVENT_DELETE); } #endif /************************************************************************** Update_rows_log_event member functions **************************************************************************/ /* Constructor used to build an event for writing to the binary log. */ #if !defined(MYSQL_CLIENT) Update_rows_log_event::Update_rows_log_event(THD *thd_arg, TABLE *tbl_arg, ulong tid, bool is_transactional) : Rows_log_event(thd_arg, tbl_arg, tid, tbl_arg->read_set, is_transactional, UPDATE_ROWS_EVENT_V1) { init(tbl_arg->rpl_write_set); } Update_rows_compressed_log_event::Update_rows_compressed_log_event(THD *thd_arg, TABLE *tbl_arg, ulong tid, bool is_transactional) : Update_rows_log_event(thd_arg, tbl_arg, tid, is_transactional) { m_type = UPDATE_ROWS_COMPRESSED_EVENT_V1; } bool Update_rows_compressed_log_event::write() { return Rows_log_event::write_compressed(); } void Update_rows_log_event::init(MY_BITMAP const *cols) { /* if my_bitmap_init fails, caught in is_valid() */ if (likely(!my_bitmap_init(&m_cols_ai, m_width <= sizeof(m_bitbuf_ai)*8 ? m_bitbuf_ai : NULL, m_width, false))) { /* Cols can be zero if this is a dummy binrows event */ if (likely(cols != NULL)) { memcpy(m_cols_ai.bitmap, cols->bitmap, no_bytes_in_map(cols)); create_last_word_mask(&m_cols_ai); } } } #endif /* !defined(MYSQL_CLIENT) */ Update_rows_log_event::~Update_rows_log_event() { if (m_cols_ai.bitmap) { if (m_cols_ai.bitmap == m_bitbuf_ai) // no my_malloc happened m_cols_ai.bitmap= 0; // so no my_free in my_bitmap_free my_bitmap_free(&m_cols_ai); // To pair with my_bitmap_init(). } } /* Constructor used by slave to read the event from the binary log. */ #ifdef HAVE_REPLICATION Update_rows_log_event::Update_rows_log_event(const char *buf, uint event_len, const Format_description_log_event *description_event) : Rows_log_event(buf, event_len, description_event) { } Update_rows_compressed_log_event::Update_rows_compressed_log_event( const char *buf, uint event_len, const Format_description_log_event *description_event) : Update_rows_log_event(buf, event_len, description_event) { uncompress_buf(); } #endif #if !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) int Update_rows_log_event::do_before_row_operations(const Slave_reporting_capability *const) { /* Increment the global status update count variable */ if (get_flags(STMT_END_F)) status_var_increment(thd->status_var.com_stat[SQLCOM_UPDATE]); int err; if ((err= find_key())) return err; if (slave_run_triggers_for_rbr && !master_had_triggers) m_table->prepare_triggers_for_update_stmt_or_event(); return 0; } int Update_rows_log_event::do_after_row_operations(const Slave_reporting_capability *const, int error) { /*error= ToDo:find out what this should really be, this triggers close_scan in nbd, returning error?*/ m_table->file->ha_index_or_rnd_end(); my_free(m_key); // Free for multi_malloc m_key= NULL; m_key_info= NULL; return error; } int Update_rows_log_event::do_exec_row(rpl_group_info *rgi) { const bool invoke_triggers= slave_run_triggers_for_rbr && !master_had_triggers && m_table->triggers; const char *tmp= thd->get_proc_info(); const char *message= "Update_rows_log_event::find_row()"; DBUG_ASSERT(m_table != NULL); #ifdef WSREP_PROC_INFO my_snprintf(thd->wsrep_info, sizeof(thd->wsrep_info) - 1, "Update_rows_log_event::find_row(%lld)", (long long) wsrep_thd_trx_seqno(thd)); message= thd->wsrep_info; #endif /* WSREP_PROC_INFO */ thd_proc_info(thd, message); // Temporary fix to find out why it fails [/Matz] memcpy(m_table->read_set->bitmap, m_cols.bitmap, (m_table->read_set->n_bits + 7) / 8); memcpy(m_table->write_set->bitmap, m_cols_ai.bitmap, (m_table->write_set->n_bits + 7) / 8); m_table->mark_columns_per_binlog_row_image(); int error= find_row(rgi); if (unlikely(error)) { /* We need to read the second image in the event of error to be able to skip to the next pair of updates */ if ((m_curr_row= m_curr_row_end)) unpack_current_row(rgi, &m_cols_ai); thd_proc_info(thd, tmp); return error; } /* This is the situation after locating BI: ===|=== before image ====|=== after image ===|=== ^ ^ m_curr_row m_curr_row_end BI found in the table is stored in record[0]. We copy it to record[1] and unpack AI to record[0]. */ store_record(m_table,record[1]); m_curr_row= m_curr_row_end; message= "Update_rows_log_event::unpack_current_row()"; #ifdef WSREP_PROC_INFO my_snprintf(thd->wsrep_info, sizeof(thd->wsrep_info) - 1, "Update_rows_log_event::unpack_current_row(%lld)", (long long) wsrep_thd_trx_seqno(thd)); message= thd->wsrep_info; #endif /* WSREP_PROC_INFO */ /* this also updates m_curr_row_end */ thd_proc_info(thd, message); if (unlikely((error= unpack_current_row(rgi, &m_cols_ai)))) goto err; /* Now we have the right row to update. The old row (the one we're looking for) is in record[1] and the new row is in record[0]. */ #ifndef HAVE_valgrind /* Don't print debug messages when running valgrind since they can trigger false warnings. */ DBUG_PRINT("info",("Updating row in table")); DBUG_DUMP("old record", m_table->record[1], m_table->s->reclength); DBUG_DUMP("new values", m_table->record[0], m_table->s->reclength); #endif message= "Update_rows_log_event::ha_update_row()"; #ifdef WSREP_PROC_INFO my_snprintf(thd->wsrep_info, sizeof(thd->wsrep_info) - 1, "Update_rows_log_event::ha_update_row(%lld)", (long long) wsrep_thd_trx_seqno(thd)); message= thd->wsrep_info; #endif /* WSREP_PROC_INFO */ thd_proc_info(thd, message); if (invoke_triggers && unlikely(process_triggers(TRG_EVENT_UPDATE, TRG_ACTION_BEFORE, TRUE))) { error= HA_ERR_GENERIC; // in case if error is not set yet goto err; } if (m_vers_from_plain && m_table->versioned(VERS_TIMESTAMP)) m_table->vers_update_fields(); error= m_table->file->ha_update_row(m_table->record[1], m_table->record[0]); if (unlikely(error == HA_ERR_RECORD_IS_THE_SAME)) error= 0; if (m_vers_from_plain && m_table->versioned(VERS_TIMESTAMP)) { store_record(m_table, record[2]); error= vers_insert_history_row(m_table); restore_record(m_table, record[2]); } m_table->default_column_bitmaps(); if (invoke_triggers && likely(!error) && unlikely(process_triggers(TRG_EVENT_UPDATE, TRG_ACTION_AFTER, TRUE))) error= HA_ERR_GENERIC; // in case if error is not set yet thd_proc_info(thd, tmp); err: m_table->file->ha_index_or_rnd_end(); return error; } #endif /* !defined(MYSQL_CLIENT) && defined(HAVE_REPLICATION) */ #ifdef MYSQL_CLIENT bool Update_rows_log_event::print(FILE *file, PRINT_EVENT_INFO* print_event_info) { return Rows_log_event::print_helper(file, print_event_info, "Update_rows"); } bool Update_rows_compressed_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { char *new_buf; ulong len; bool is_malloc= false; if(!row_log_event_uncompress(glob_description_event, checksum_alg == BINLOG_CHECKSUM_ALG_CRC32, temp_buf, UINT_MAX32, NULL, 0, &is_malloc, &new_buf, &len)) { free_temp_buf(); register_temp_buf(new_buf, true); if (Rows_log_event::print_helper(file, print_event_info, "Update_compressed_rows")) goto err; } else { if (my_b_printf(&print_event_info->head_cache, "ERROR: uncompress update_compressed_rows failed\n")) goto err; } return 0; err: return 1; } #endif #if defined(MYSQL_SERVER) && defined(HAVE_REPLICATION) uint8 Update_rows_log_event::get_trg_event_map() { return trg2bit(TRG_EVENT_UPDATE); } #endif Incident_log_event::Incident_log_event(const char *buf, uint event_len, const Format_description_log_event *descr_event) : Log_event(buf, descr_event) { DBUG_ENTER("Incident_log_event::Incident_log_event"); uint8 const common_header_len= descr_event->common_header_len; uint8 const post_header_len= descr_event->post_header_len[INCIDENT_EVENT-1]; DBUG_PRINT("info",("event_len: %u; common_header_len: %d; post_header_len: %d", event_len, common_header_len, post_header_len)); m_message.str= NULL; m_message.length= 0; int incident_number= uint2korr(buf + common_header_len); if (incident_number >= INCIDENT_COUNT || incident_number <= INCIDENT_NONE) { // If the incident is not recognized, this binlog event is // invalid. If we set incident_number to INCIDENT_NONE, the // invalidity will be detected by is_valid(). m_incident= INCIDENT_NONE; DBUG_VOID_RETURN; } m_incident= static_cast(incident_number); char const *ptr= buf + common_header_len + post_header_len; char const *const str_end= buf + event_len; uint8 len= 0; // Assignment to keep compiler happy const char *str= NULL; // Assignment to keep compiler happy if (read_str(&ptr, str_end, &str, &len)) { /* Mark this event invalid */ m_incident= INCIDENT_NONE; DBUG_VOID_RETURN; } if (!(m_message.str= (char*) my_malloc(len+1, MYF(MY_WME)))) { /* Mark this event invalid */ m_incident= INCIDENT_NONE; DBUG_VOID_RETURN; } strmake(m_message.str, str, len); m_message.length= len; DBUG_PRINT("info", ("m_incident: %d", m_incident)); DBUG_VOID_RETURN; } Incident_log_event::~Incident_log_event() { if (m_message.str) my_free(m_message.str); } const char * Incident_log_event::description() const { static const char *const description[]= { "NOTHING", // Not used "LOST_EVENTS" }; DBUG_PRINT("info", ("m_incident: %d", m_incident)); return description[m_incident]; } #ifndef MYSQL_CLIENT void Incident_log_event::pack_info(Protocol *protocol) { char buf[256]; size_t bytes; if (m_message.length > 0) bytes= my_snprintf(buf, sizeof(buf), "#%d (%s)", m_incident, description()); else bytes= my_snprintf(buf, sizeof(buf), "#%d (%s): %s", m_incident, description(), m_message.str); protocol->store(buf, bytes, &my_charset_bin); } #endif /* MYSQL_CLIENT */ #if defined(WITH_WSREP) && !defined(MYSQL_CLIENT) /* read the first event from (*buf). The size of the (*buf) is (*buf_len). At the end (*buf) is shitfed to point to the following event or NULL and (*buf_len) will be changed to account just being read bytes of the 1st event. */ #define WSREP_MAX_ALLOWED_PACKET 1024*1024*1024 // current protocol max Log_event* wsrep_read_log_event( char **arg_buf, size_t *arg_buf_len, const Format_description_log_event *description_event) { char *head= (*arg_buf); uint data_len = uint4korr(head + EVENT_LEN_OFFSET); char *buf= (*arg_buf); const char *error= 0; Log_event *res= 0; DBUG_ENTER("wsrep_read_log_event"); if (data_len > WSREP_MAX_ALLOWED_PACKET) { error = "Event too big"; goto err; } res= Log_event::read_log_event(buf, data_len, &error, description_event, false); err: if (!res) { DBUG_ASSERT(error != 0); sql_print_error("Error in Log_event::read_log_event(): " "'%s', data_len: %d, event_type: %d", error,data_len,(uchar)head[EVENT_TYPE_OFFSET]); } (*arg_buf)+= data_len; (*arg_buf_len)-= data_len; DBUG_RETURN(res); } #endif #ifdef MYSQL_CLIENT bool Incident_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { if (print_event_info->short_form) return 0; Write_on_release_cache cache(&print_event_info->head_cache, file); if (print_header(&cache, print_event_info, FALSE) || my_b_printf(&cache, "\n# Incident: %s\nRELOAD DATABASE; # Shall generate syntax error\n", description())) return 1; return cache.flush_data(); } #endif #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) int Incident_log_event::do_apply_event(rpl_group_info *rgi) { Relay_log_info const *rli= rgi->rli; DBUG_ENTER("Incident_log_event::do_apply_event"); if (ignored_error_code(ER_SLAVE_INCIDENT)) { DBUG_PRINT("info", ("Ignoring Incident")); DBUG_RETURN(0); } rli->report(ERROR_LEVEL, ER_SLAVE_INCIDENT, NULL, ER_THD(rgi->thd, ER_SLAVE_INCIDENT), description(), m_message.length > 0 ? m_message.str : ""); DBUG_RETURN(1); } #endif #ifdef MYSQL_SERVER bool Incident_log_event::write_data_header() { DBUG_ENTER("Incident_log_event::write_data_header"); DBUG_PRINT("enter", ("m_incident: %d", m_incident)); uchar buf[sizeof(int16)]; int2store(buf, (int16) m_incident); DBUG_RETURN(write_data(buf, sizeof(buf))); } bool Incident_log_event::write_data_body() { uchar tmp[1]; DBUG_ENTER("Incident_log_event::write_data_body"); tmp[0]= (uchar) m_message.length; DBUG_RETURN(write_data(tmp, sizeof(tmp)) || write_data(m_message.str, m_message.length)); } #endif Ignorable_log_event::Ignorable_log_event(const char *buf, const Format_description_log_event *descr_event, const char *event_name) :Log_event(buf, descr_event), number((int) (uchar) buf[EVENT_TYPE_OFFSET]), description(event_name) { DBUG_ENTER("Ignorable_log_event::Ignorable_log_event"); DBUG_VOID_RETURN; } Ignorable_log_event::~Ignorable_log_event() { } #ifndef MYSQL_CLIENT /* Pack info for its unrecognized ignorable event */ void Ignorable_log_event::pack_info(Protocol *protocol) { char buf[256]; size_t bytes; bytes= my_snprintf(buf, sizeof(buf), "# Ignorable event type %d (%s)", number, description); protocol->store(buf, bytes, &my_charset_bin); } #endif #ifdef MYSQL_CLIENT /* Print for its unrecognized ignorable event */ bool Ignorable_log_event::print(FILE *file, PRINT_EVENT_INFO *print_event_info) { if (print_event_info->short_form) return 0; if (print_header(&print_event_info->head_cache, print_event_info, FALSE) || my_b_printf(&print_event_info->head_cache, "\tIgnorable\n") || my_b_printf(&print_event_info->head_cache, "# Ignorable event type %d (%s)\n", number, description) || copy_event_cache_to_file_and_reinit(&print_event_info->head_cache, file)) return 1; return 0; } #endif #ifdef MYSQL_CLIENT /** The default values for these variables should be values that are *incorrect*, i.e., values that cannot occur in an event. This way, they will always be printed for the first event. */ st_print_event_info::st_print_event_info() { myf const flags = MYF(MY_WME | MY_NABP); /* Currently we only use static PRINT_EVENT_INFO objects, so zeroed at program's startup, but these explicit bzero() is for the day someone creates dynamic instances. */ bzero(db, sizeof(db)); bzero(charset, sizeof(charset)); bzero(time_zone_str, sizeof(time_zone_str)); delimiter[0]= ';'; delimiter[1]= 0; flags2_inited= 0; sql_mode_inited= 0; row_events= 0; sql_mode= 0; auto_increment_increment= 0; auto_increment_offset= 0; charset_inited= 0; lc_time_names_number= ~0; charset_database_number= ILLEGAL_CHARSET_INFO_NUMBER; thread_id= 0; server_id= 0; domain_id= 0; thread_id_printed= false; server_id_printed= false; domain_id_printed= false; allow_parallel= true; allow_parallel_printed= false; found_row_event= false; print_row_count= false; short_form= false; skip_replication= 0; printed_fd_event=FALSE; file= 0; base64_output_mode=BASE64_OUTPUT_UNSPEC; open_cached_file(&head_cache, NULL, NULL, 0, flags); open_cached_file(&body_cache, NULL, NULL, 0, flags); open_cached_file(&tail_cache, NULL, NULL, 0, flags); #ifdef WHEN_FLASHBACK_REVIEW_READY open_cached_file(&review_sql_cache, NULL, NULL, 0, flags); #endif } bool copy_event_cache_to_string_and_reinit(IO_CACHE *cache, LEX_STRING *to) { reinit_io_cache(cache, READ_CACHE, 0L, FALSE, FALSE); if (cache->end_of_file > SIZE_T_MAX || !(to->str= (char*) my_malloc((to->length= (size_t)cache->end_of_file), MYF(0)))) { perror("Out of memory: can't allocate memory in copy_event_cache_to_string_and_reinit()."); goto err; } if (my_b_read(cache, (uchar*) to->str, to->length)) { my_free(to->str); perror("Can't read data from IO_CACHE"); return true; } reinit_io_cache(cache, WRITE_CACHE, 0, FALSE, TRUE); return false; err: to->str= 0; to->length= 0; return true; } #endif /* MYSQL_CLIENT */ bool copy_event_cache_to_file_and_reinit(IO_CACHE *cache, FILE *file) { return (my_b_copy_all_to_file(cache, file) || reinit_io_cache(cache, WRITE_CACHE, 0, FALSE, TRUE)); } #if defined(HAVE_REPLICATION) && !defined(MYSQL_CLIENT) Heartbeat_log_event::Heartbeat_log_event(const char* buf, uint event_len, const Format_description_log_event* description_event) :Log_event(buf, description_event) { uint8 header_size= description_event->common_header_len; ident_len = event_len - header_size; set_if_smaller(ident_len,FN_REFLEN-1); log_ident= buf + header_size; } #endif #if defined(MYSQL_SERVER) /** Check if we should write event to the relay log This is used to skip events that is only supported by MySQL Return: 0 ok 1 Don't write event */ bool event_that_should_be_ignored(const char *buf) { uint event_type= (uchar)buf[EVENT_TYPE_OFFSET]; if (event_type == GTID_LOG_EVENT || event_type == ANONYMOUS_GTID_LOG_EVENT || event_type == PREVIOUS_GTIDS_LOG_EVENT || event_type == TRANSACTION_CONTEXT_EVENT || event_type == VIEW_CHANGE_EVENT || event_type == XA_PREPARE_LOG_EVENT || (uint2korr(buf + FLAGS_OFFSET) & LOG_EVENT_IGNORABLE_F)) return 1; return 0; } #endif /* MYSQL_SERVER */