\input texinfo @c -*-texinfo-*- @c Copyright 2002 MySQL AB @c @c %**start of header @setfilename internals.info @c We want the types in the same index @synindex cp fn @iftex @afourpaper @end iftex @c Get version and other info @include include.texi @ifclear tex-debug @c This removes the black squares in the right margin @finalout @end ifclear @c Set background for HTML @set _body_tags BGCOLOR=#FFFFFF TEXT=#000000 LINK=#101090 VLINK=#7030B0 @settitle @strong{MySQL} Internals Manual for version @value{mysql_version}. @setchapternewpage odd @paragraphindent 0 @c %**end of header @ifinfo @format START-INFO-DIR-ENTRY * mysql-internals: (mysql-internals). @strong{MySQL} internals. END-INFO-DIR-ENTRY @end format @end ifinfo @titlepage @sp 10 @center @titlefont{@strong{MySQL} Internals Manual} @sp 10 @center Copyright @copyright{} 1998-2002 MySQL AB @page @end titlepage @node Top, coding guidelines, (dir), (dir) @ifinfo This is a manual about @strong{MySQL} internals. @end ifinfo @menu * coding guidelines:: Coding Guidelines * caching:: How MySQL Handles Caching * join_buffer_size:: * flush tables:: How MySQL Handles @code{FLUSH TABLES} * Algorithms:: * mysys functions:: Functions In The @code{mysys} Library * DBUG:: DBUG Tags To Use * protocol:: MySQL Client/Server Protocol * Fulltext Search:: Fulltext Search in MySQL * MyISAM Record Structure:: MyISAM Record Structure * InnoDB Record Structure:: InnoDB Record Structure * InnoDB Page Structure:: InnoDB Page Structure * Files in MySQL Sources:: Annotated List Of Files in the MySQL Source Code Distribution * Files in InnoDB Sources:: Annotated List Of Files in the InnoDB Source Code Distribution @end menu @node coding guidelines, caching, Top, Top @chapter Coding Guidelines @itemize @bullet @item We use @uref{http://www.bitkeeper.com/, BitKeeper} for source management. @item You should use the @strong{MySQL} 4.1 source for all developments. @item If you have any questions about the @strong{MySQL} source, you can post these to @email{internals@@mysql.com} and we will answer them. @item Try to write code in a lot of black boxes that can be reused or use at least a clean, easy to change interface. @item Reuse code; There is already a lot of algorithms in MySQL for list handling, queues, dynamic and hashed arrays, sorting, etc. that can be reused. @item Use the @code{my_*} functions like @code{my_read()}/@code{my_write()}/ @code{my_malloc()} that you can find in the @code{mysys} library instead of the direct system calls; This will make your code easier to debug and more portable. @item Try to always write optimized code, so that you don't have to go back and rewrite it a couple of months later. It's better to spend 3 times as much time designing and writing an optimal function than having to do it all over again later on. @item Avoid CPU wasteful code, even where it does not matter, so that you will not develop sloppy coding habits. @item If you can write it in fewer lines, do it (as long as the code will not be slower or much harder to read). @item Don't use two commands on the same line. @item Do not check the same pointer for @code{NULL} more than once. @item Use long function and variable names in English. This makes your code easier to read. @item Use @code{my_var} as opposed to @code{myVar} or @code{MyVar} (@samp{_} rather than dancing SHIFT to seperate words in identifiers). @item Think assembly - make it easier for the compiler to optimize your code. @item Comment your code when you do something that someone else may think is not ``trivial''. @item Use @code{libstring} functions (in the @file{strings} directory) instead of standard @code{libc} string functions whenever possible. @item Avoid using @code{malloc()} (its REAL slow); For memory allocations that only need to live for the lifetime of one thread, one should use @code{sql_alloc()} instead. @item Before making big design decisions, please first post a summary of what you want to do, why you want to do it, and how you plan to do it. This way we can easily provide you with feedback and also easily discuss it thoroughly if some other developer thinks there is better way to do the same thing! @item Class names start with a capital letter. @item Structure types are @code{typedef}'ed to an all-caps identifier. @item Any @code{#define}'s are in all-caps. @item Matching @samp{@{} are in the same column. @item Put the @samp{@{} after a @code{switch} on the same line, as this gives better overall indentation for the switch statement: @example switch (arg) @{ @end example @item In all other cases, @samp{@{} and @samp{@}} should be on their own line, except if there is nothing inside @samp{@{} and @samp{@}}. @item Have a space after @code{if} @item Put a space after @samp{,} for function arguments @item Functions return @samp{0} on success, and non-zero on error, so you can do: @example if(a() || b() || c()) @{ error("something went wrong"); @} @end example @item Using @code{goto} is okay if not abused. @item Avoid default variable initalizations, use @code{LINT_INIT()} if the compiler complains after making sure that there is really no way the variable can be used uninitialized. @item Do not instantiate a class if you do not have to. @item Use pointers rather than array indexing when operating on strings. @end itemize Suggested mode in emacs: @example (load "cc-mode") (setq c-mode-common-hook '(lambda () (turn-on-font-lock) (setq comment-column 48))) (setq c-style-alist (cons '("MY" (c-basic-offset . 2) (c-comment-only-line-offset . 0) (c-offsets-alist . ((statement-block-intro . +) (knr-argdecl-intro . 0) (substatement-open . 0) (label . -) (statement-cont . +) (arglist-intro . c-lineup-arglist-intro-after-paren) (arglist-close . c-lineup-arglist) )) ) c-style-alist)) (c-set-style "MY") (setq c-default-style "MY") @end example @node caching, join_buffer_size, coding guidelines, Top @chapter How MySQL Handles Caching @strong{MySQL} has the following caches: (Note that the some of the filename have a wrong spelling of cache. :) @table @strong @item Key Cache A shared cache for all B-tree index blocks in the different NISAM files. Uses hashing and reverse linked lists for quick caching of the last used blocks and quick flushing of changed entries for a specific table. (@file{mysys/mf_keycash.c}) @item Record Cache This is used for quick scanning of all records in a table. (@file{mysys/mf_iocash.c} and @file{isam/_cash.c}) @item Table Cache This holds the last used tables. (@file{sql/sql_base.cc}) @item Hostname Cache For quick lookup (with reverse name resolving). Is a must when one has a slow DNS. (@file{sql/hostname.cc}) @item Privilege Cache To allow quick change between databases the last used privileges are cached for each user/database combination. (@file{sql/sql_acl.cc}) @item Heap Table Cache Many use of @code{GROUP BY} or @code{DISTINCT} caches all found rows in a @code{HEAP} table. (This is a very quick in-memory table with hash index.) @item Join buffer Cache For every full join in a @code{SELECT} statement (a full join here means there were no keys that one could use to find the next table in a list), the found rows are cached in a join cache. One @code{SELECT} query can use many join caches in the worst case. @end table @node join_buffer_size, flush tables, caching, Top @chapter How MySQL uses the join_buffer cache Basic information about @code{join_buffer_size}: @itemize @bullet @item It's only used in the case when join type is of type @code{ALL} or @code{index}; In other words: no possible keys can be used. @item A join buffer is never allocated for the first not-const table, even it it would be of type @code{ALL}/@code{index}. @item The buffer is allocated when we need to do a each full join between two tables and freed after the query is done. @item Accepted row combinations of tables before the @code{ALL}/@code{index} able is stored in the cache and is used to compare against each read row in the @code{ALL} table. @item We only store the used fields in the join_buffer cache, not the whole rows. @end itemize Assume you have the following join: @example Table name Type t1 range t2 ref t3 @code{ALL} @end example The join is then done as follows: @example - While rows in t1 matching range - Read through all rows in t2 according to reference key - Store used fields form t1,t2 in cache - If cache is full - Read through all rows in t3 - Compare t3 row against all t1,t2 combination in cache - If rows satisfying join condition, send it to client - Empty cache - Read through all rows in t3 - Compare t3 row against all stored t1,t2 combinations in cache - If rows satisfying join condition, send it to client @end example The above means that table t3 is scanned @example (size-of-stored-row(t1,t2) * accepted-row-cominations(t1,t2))/ join_buffer_size+1 @end example times. Some conclusions: @itemize @bullet @item The larger the join_buff_size, the fewer scans of t3. If @code{join_buff_size} is already large enough to hold all previous row combinations then there is no speed to gain by making it bigger. @item If there is several tables of @code{ALL}/@code{index} then the we allocate one @code{join_buffer_size buffer} for each of them and use the same algorithm described above to handle it. (In other words, we store the same row combination several times into different buffers) @end itemize @node flush tables, Algorithms, join_buffer_size, Top @chapter How MySQL Handles @code{FLUSH TABLES} @itemize @bullet @item Flush tables is handled in @file{sql/sql_base.cc::close_cached_tables()}. @item The idea of flush tables is to force all tables to be closed. This is mainly to ensure that if someone adds a new table outside of @strong{MySQL} (for example with @code{cp}) all threads will start using the new table. This will also ensure that all table changes are flushed to disk (but of course not as optimally as simple calling a sync on all tables)! @item When one does a @code{FLUSH TABLES}, the variable @code{refresh_version} will be incremented. Every time a thread releases a table it checks if the refresh version of the table (updated at open) is the same as the current @code{refresh_version}. If not it will close it and broadcast a signal on @code{COND_refresh} (to wait any thread that is waiting for all instanses of a table to be closed). @item The current @code{refresh_version} is also compared to the open @code{refresh_version} after a thread gets a lock on a table. If the refresh version is different the thread will free all locks, reopen the table and try to get the locks again; This is just to quickly get all tables to use the newest version. This is handled by @file{sql/lock.cc::mysql_lock_tables()} and @file{sql/sql_base.cc::wait_for_tables()}. @item When all tables has been closed @code{FLUSH TABLES} will return an ok to client. @item If the thread that is doing @code{FLUSH TABLES} has a lock on some tables, it will first close the locked tables, then wait until all other threads have also closed them, and then reopen them and get the locks. After this it will give other threads a chance to open the same tables. @end itemize @node Algorithms, mysys functions, flush tables, Top @chapter Different algoritms used in MySQL MySQL uses a lot of different algorithms. This chapter tries to describe some of these: @menu * filesort:: * bulk-insert:: @end menu @node filesort, bulk-insert, Algorithms, Algorithms @section How MySQL Does Sorting (@code{filesort}) @itemize @bullet @item Read all rows according to key or by table scanning. @item Store the sort-key in a buffer (@code{sort_buffer}). @item When the buffer gets full, run a @code{qsort} on it and store the result in a temporary file. Save a pointer to the sorted block. @item Repeat the above until all rows have been read. @item Repeat the following until there is less than @code{MERGEBUFF2} (15) blocks left. @item Do a multi-merge of up to @code{MERGEBUFF} (7) regions to one block in another temporary file. Repeat until all blocks from the first file are in the second file. @item On the last multi-merge, only the pointer to the row (last part of the sort-key) is written to a result file. @item Now the code in @file{sql/records.cc} will be used to read through them in sorted order by using the row pointers in the result file. To optimize this, we read in a big block of row pointers, sort these and then we read the rows in the sorted order into a row buffer (@code{record_buffer}). @end itemize @node bulk-insert, , filesort, Algorithms @section Bulk insert Logic behind bulk insert optimisation is simple. Instead of writing each key value to b-tree (that is to keycache, but bulk insert code doesn't know about keycache) keys are stored in balanced binary (red-black) tree, in memory. When this tree reaches its memory limit it's writes all keys to disk (to keycache, that is). But as key stream coming from the binary tree is already sorted inserting goes much faster, all the necessary pages are already in cache, disk access is minimized, etc. @node mysys functions, DBUG, Algorithms, Top @chapter Functions In The @code{mysys} Library Functions in @code{mysys}: (For flags see @file{my_sys.h}) @table @code @item int my_copy _A((const char *from, const char *to, myf MyFlags)); Copy file from @code{from} to @code{to}. @item int my_delete _A((const char *name, myf MyFlags)); Delete file @code{name}. @item int my_getwd _A((string buf, uint size, myf MyFlags)); @item int my_setwd _A((const char *dir, myf MyFlags)); Get and set working directory. @item string my_tempnam _A((const char *pfx, myf MyFlags)); Make a unique temporary file name by using dir and adding something after @code{pfx} to make name unique. The file name is made by adding a unique six character string and @code{TMP_EXT} after @code{pfx}. Returns pointer to @code{malloc()}'ed area for filename. Should be freed by @code{free()}. @item File my_open _A((const char *FileName,int Flags,myf MyFlags)); @item File my_create _A((const char *FileName, int CreateFlags, int AccsesFlags, myf MyFlags)); @item int my_close _A((File Filedes, myf MyFlags)); @item uint my_read _A((File Filedes, byte *Buffer, uint Count, myf MyFlags)); @item uint my_write _A((File Filedes, const byte *Buffer, uint Count, myf MyFlags)); @item ulong my_seek _A((File fd,ulong pos,int whence,myf MyFlags)); @item ulong my_tell _A((File fd,myf MyFlags)); Use instead of open, open-with-create-flag, close, read, and write to get automatic error messages (flag @code{MYF_WME}) and only have to test for != 0 if error (flag @code{MY_NABP}). @item int my_rename _A((const char *from, const char *to, myf MyFlags)); Rename file from @code{from} to @code{to}. @item FILE *my_fopen _A((const char *FileName,int Flags,myf MyFlags)); @item FILE *my_fdopen _A((File Filedes,int Flags,myf MyFlags)); @item int my_fclose _A((FILE *fd,myf MyFlags)); @item uint my_fread _A((FILE *stream,byte *Buffer,uint Count,myf MyFlags)); @item uint my_fwrite _A((FILE *stream,const byte *Buffer,uint Count, myf MyFlags)); @item ulong my_fseek _A((FILE *stream,ulong pos,int whence,myf MyFlags)); @item ulong my_ftell _A((FILE *stream,myf MyFlags)); Same read-interface for streams as for files. @item gptr _mymalloc _A((uint uSize,const char *sFile,uint uLine, myf MyFlag)); @item gptr _myrealloc _A((string pPtr,uint uSize,const char *sFile,uint uLine, myf MyFlag)); @item void _myfree _A((gptr pPtr,const char *sFile,uint uLine)); @item int _sanity _A((const char *sFile,unsigned int uLine)); @item gptr _myget_copy_of_memory _A((const byte *from,uint length,const char *sFile, uint uLine,myf MyFlag)); @code{malloc(size,myflag)} is mapped to these functions if not compiled with @code{-DSAFEMALLOC}. @item void TERMINATE _A((void)); Writes @code{malloc()} info on @code{stdout} if compiled with @code{-DSAFEMALLOC}. @item int my_chsize _A((File fd, ulong newlength, myf MyFlags)); Change size of file @code{fd} to @code{newlength}. @item void my_error _D((int nr, myf MyFlags, ...)); Writes message using error number (see @file{mysys/errors.h}) on @code{stdout}, or using curses, if @code{MYSYS_PROGRAM_USES_CURSES()} has been called. @item void my_message _A((const char *str, myf MyFlags)); Writes @code{str} on @code{stdout}, or using curses, if @code{MYSYS_PROGRAM_USES_CURSES()} has been called. @item void my_init _A((void )); Start each program (in @code{main()}) with this. @item void my_end _A((int infoflag)); Gives info about program. If @code{infoflag & MY_CHECK_ERROR}, prints if some files are left open. If @code{infoflag & MY_GIVE_INFO}, prints timing info and malloc info about program. @item int my_redel _A((const char *from, const char *to, int MyFlags)); Delete @code{from} before rename of @code{to} to @code{from}. Copies state from old file to new file. If @code{MY_COPY_TIME} is set, sets old time. @item int my_copystat _A((const char *from, const char *to, int MyFlags)); Copy state from old file to new file. If @code{MY_COPY_TIME} is set, sets old time. @item string my_filename _A((File fd)); Returns filename of open file. @item int dirname _A((string to, const char *name)); Copy name of directory from filename. @item int test_if_hard_path _A((const char *dir_name)); Test if @code{dir_name} is a hard path (starts from root). @item void convert_dirname _A((string name)); Convert dirname according to system. In MSDOS, changes all characters to capitals and changes @samp{/} to @samp{\}. @item string fn_ext _A((const char *name)); Returns pointer to extension in filename. @item string fn_format _A((string to,const char *name,const char *dsk,const char *form,int flag)); format a filename with replace of library and extension and converts between different systems. params to and name may be identicall function dosn't change name if name != to Flag may be: 1 force replace filnames library with 'dsk' 2 force replace extension with 'form' */ 4 force Unpack filename (replace ~ with home) 8 Pack filename as short as possibly for output to user. All open requests should allways use at least: "open(fn_format(temp_buffe,name,"","",4),...)" to unpack home and convert filename to system-form. @item string fn_same _A((string toname, const char *name, int flag)); Copys directory and extension from @code{name} to @code{toname} if neaded. Copying can be forced by same flags used in @code{fn_format()}. @item int wild_compare _A((const char *str, const char *wildstr)); Compare if @code{str} matches @code{wildstr}. @code{wildstr} can contain @samp{*} and @samp{?} as wildcard characters. Returns 0 if @code{str} and @code{wildstr} match. @item void get_date _A((string to, int timeflag)); Get current date in a form ready for printing. @item void soundex _A((string out_pntr, string in_pntr)) Makes @code{in_pntr} to a 5 char long string. All words that sound alike have the same string. @item int init_key_cache _A((ulong use_mem, ulong leave_this_much_mem)); Use caching of keys in MISAM, PISAM, and ISAM. @code{KEY_CACHE_SIZE} is a good size. Remember to lock databases for optimal caching. @item void end_key_cache _A((void)); End key caching. @end table @node DBUG, protocol, mysys functions, Top @chapter DBUG Tags To Use Here is some of the tags we now use: (We should probably add a couple of new ones) @table @code @item enter Arguments to the function. @item exit Results from the function. @item info Something that may be interesting. @item warning When something doesn't go the usual route or may be wrong. @item error When something went wrong. @item loop Write in a loop, that is probably only useful when debugging the loop. These should normally be deleted when one is satisfied with the code and it has been in real use for a while. @end table Some specific to mysqld, because we want to watch these carefully: @table @code @item trans Starting/stopping transactions. @item quit @code{info} when mysqld is preparing to die. @item query Print query. @end table @node protocol, Fulltext Search, DBUG, Top @chapter MySQL Client/Server Protocol @menu * raw packet without compression:: * raw packet with compression:: * basic packets:: * communication:: * fieldtype codes:: * protocol functions:: * protocol version 2:: * 4.1 protocol changes:: * 4.1 field packet:: * 4.1 field desc:: * 4.1 ok packet:: * 4.1 end packet:: * 4.1 error packet:: * 4.1 prep init:: * 4.1 long data:: * 4.1 execute:: * 4.1 binary result:: @end menu @node raw packet without compression, raw packet with compression, protocol, protocol @section Raw Packet Without Compression @example +-----------------------------------------------+ | Packet Length | Packet no | Data | | 3 Bytes | 1 Byte | n Bytes | +-----------------------------------------------+ @end example @table @asis @item 3 Byte packet length The length is calculated with int3store See include/global.h for details. The max packetsize can be 16 MB. @item 1 Byte packet no If no compression is used the first 4 bytes of each packet is the header of the packet. The packet number is incremented for each sent packet. The first packet starts with 0. @item n Byte data @end table The packet length can be recalculated with: @example length = byte1 + (256 * byte2) + (256 * 256 * byte3) @end example @node raw packet with compression, basic packets, raw packet without compression, protocol @section Raw Packet With Compression @example +---------------------------------------------------+ | Packet Length | Packet no | Uncomp. Packet Length | | 3 Bytes | 1 Byte | 3 Bytes | +---------------------------------------------------+ @end example @table @asis @item 3 Byte packet length The length is calculated with int3store See include/global.h for details. The max packetsize can be 16 MB. @item 1 Byte packet no @item 3 Byte uncompressed packet length @end table If compression is used the first 7 bytes of each packet is the header of the packet. @node basic packets, communication, raw packet with compression, protocol @section Basic Packets @menu * ok packet:: * error packet:: @end menu @node ok packet, error packet, basic packets, basic packets @subsection OK Packet For details, see @file{sql/net_pkg.cc::send_ok()}. @example +-----------------------------------------------+ | Header | No of Rows | Affected Rows | | | 1 Byte | 1-8 Byte | |-----------------------------------------------| | ID (last_insert_id) | Status | Length | | 1-8 Byte | 2 Byte | 1-8 Byte | |-----------------------------------------------| | Messagetext | | n Byte | +-----------------------------------------------+ @end example @table @asis @item Header @item 1 byte number of rows ? (always 0 ?) @item 1-8 bytes affected rows @item 1-8 byte id (last_insert_id) @item 2 byte Status (usually 0) @item If the OK-packege includes a message: @item 1-8 bytes length of message @item n bytes messagetext @end table @node error packet, , ok packet, basic packets @subsection Error Packet @example +-----------------------------------------------+ | Header | Status code | Error no | | | 1 Byte | 2 Byte | |-----------------------------------------------| | Messagetext | 0x00 | | n Byte | 1 Byte | +-----------------------------------------------+ @end example @table @asis @item Header @item 1 byte status code (0xFF = ERROR) @item 2 byte error number (is only sent to new 3.23 clients. @item n byte errortext @item 1 byte 0x00 @end table @node communication, fieldtype codes, basic packets, protocol @section Communication @example > Packet from server to client < Paket from client tor server Login ------ > 1. packet Header 1 byte protocolversion n byte serverversion 1 byte 0x00 4 byte threadnumber 8 byte crypt seed 1 byte 0x00 2 byte CLIENT_xxx options (see include/mysql_com.h that is supported by the server 1 byte number of current server charset 2 byte server status variables (SERVER_STATUS_xxx flags) 13 byte 0x00 (not used yet). < 2. packet Header 2 byte CLIENT_xxx options 3 byte max_allowed_packet for the client n byte username 1 byte 0x00 8 byte crypted password 1 byte 0x00 n byte databasename 1 byte 0x00 > 3. packet OK-packet Command -------- < 1. packet Header 1 byte command type (e.g.0x03 = query) n byte query Result set (after command) -------------------------- > 2. packet Header 1-8 byte field_count (packed with net_store_length()) If field_count == 0 (command): 1-8 byte affected rows 1-8 byte insert id 2 bytes server_status (SERVER_STATUS_xx) If field_count == NULL_LENGTH (251) LOAD DATA LOCAL INFILE If field_count > 0 Result Set: > n packets Header Info Column description: 5 data object /column (See code in unpack_fields()) Columninfo for each column: 1 data block table_name 1 byte length of block n byte data 1 data block field_name 1 byte length of block... n byte data 1 data block display length of field 1 byte length of block 3 bytes display length of filed 1 data block type field of type (enum_field_types) 1 byte length of block 1 bytexs field of type 1 data block flags 1 byte length of block 2 byte flags for the columns (NOT_NULL_FLAG, ZEROFILL_FLAG....) 1 byte decimals if table definition: 1 data block default value Actual result (one packet per row): 4 byte header 1-8 byte length of data n data @end example @node fieldtype codes, protocol functions, communication, protocol @section Fieldtype Codes @example display_length |enum_field_type |flags ---------------------------------------------------- Blob 03 FF FF 00 |01 FC |03 90 00 00 Mediumblob 03 FF FF FF |01 FC |03 90 00 00 Tinyblob 03 FF 00 00 |01 FC |03 90 00 00 Text 03 FF FF 00 |01 FC |03 10 00 00 Mediumtext 03 FF FF FF |01 FC |03 10 00 00 Tinytext 03 FF 00 00 |01 FC |03 10 00 00 Integer 03 0B 00 00 |01 03 |03 03 42 00 Mediumint 03 09 00 00 |01 09 |03 00 00 00 Smallint 03 06 00 00 |01 02 |03 00 00 00 Tinyint 03 04 00 00 |01 01 |03 00 00 00 Varchar 03 XX 00 00 |01 FD |03 00 00 00 Enum 03 05 00 00 |01 FE |03 00 01 00 Datetime 03 13 00 00 |01 0C |03 00 00 00 Timestamp 03 0E 00 00 |01 07 |03 61 04 00 Time 03 08 00 00 |01 0B |03 00 00 00 Date 03 0A 00 00 |01 0A |03 00 00 00 @end example @node protocol functions, protocol version 2, fieldtype codes, protocol @section Functions used to implement the protocol @c This should be merged with the above one and changed to texi format @example Raw packets ----------- - The my_net_xxxx() functions handles the packaging of a stream of data into a raw packet that contains a packet number, length and data. - This is implemented for the server in sql/net_serv.cc. The client file, libmysql/net.c, is symlinked to this file The important functions are: my_net_write() Store a packet (= # number of bytes) to be sent net_flush() Send the packets stored in the buffer net_write_command() Send a command (1 byte) + packet to the server. my_net_read() Read a packet Include files ------------- - include/mysql.h is included by all MySQL clients. It includes the MYSQL and MYSQL_RES structures. - include/mysql_com.h is include by mysql.h and mysql_priv.h (the server) and includes a lot of common functions and structures to handle the client/server protocol. Packets from server to client: ----------------------------- sql/net_pkg.cc: - Sending of error packets - Sending of OK packets (= end of data) - Storing of values in a packet sql/sql_base.cc: - Function send_fields() sends the field description to the client. sql/sql_show.cc: - Sends results for a lot of SHOW commands, including: SHOW DATABASES [like 'wildcard'] SHOW TABLES [like 'wildcard'] Packets from client to server: ------------------------------ This is done in libmysql/libmysql.c The important ones are: - mysql_real_connect() Connects to a mysqld server - mysql_real_query() Sends a query to the server and reads the ok packet or columns header. - mysql_store_result() Read a result set from the server to memory - mysql_use_result() Read a result set row by row from the server. - net_safe_read() Read a packet from the server with error handling. - net_field_length() Reads the length of a packet string. - simple_command() Sends a command/query to the server. Connecting to mysqld (the MySQL server) --------------------------------------- - On the client side: libmysql/libmysql.c::mysql_real_connect(). - On the server side: sql/sql_parse.cc::check_connections() The packets sent during a connection are as follows Server: Send greeting package (includes server capabilites, server version and a random string of bytes to be used to scramble the password. Client: Sends package with client capabilites, user name, scrambled password, database name Server: Sends ok package or error package. Client: If init command specified, send it t the server and read ok/error package. Password functions ------------------ The passwords are scrambled to a random number and are stored in hex format on the server. The password handling is done in sql/password.c. The important function is 'scramble()', which takes the a password in clear text and uses this to 'encrypt' the random string sent by the server to a new message. The encrypted message is sent to the server which uses the stored random number password to encrypt the random string sent to the client. If this is equal to the new message the client sends to the server then the password is accepted. @end example @node protocol version 2, 4.1 protocol changes, protocol functions, protocol @section Another description of the protocol @c This should be merged with the above one and changed to texi format. @example ***************************** * * PROTOCOL OVERVIEW * ***************************** The MySQL protocol is relatively simple, and is designed for high performance through minimisation of overhead, and extensibility through versioning and options flags. It is a request-response protocol, and does not allow multitasking or multiplexing over a single connection. There are two packet formats, 'raw' and 'compressed' (which is used when both client and server support zlib compression, and the client requests that data be compressed): * RAW PACKET, shorter than 16 M * +-----------------------------------------------+ | Packet Length | Packet no | Data | | 3 Bytes | 1 Byte | n Bytes | +-----------------------------------------------+ ^ ^ | 'HEADER' | +-------------------------------+ * Packet Length: Calculated with int3store. See include/global.h for details. The basic computation is length = byte1 + (256 * byte2) + (256 * 256 * byte3). The max packetsize can be 16 MB. * Packet no: The packet number is incremented for each sent packet. The first packet for each query from the client starts with 0. * Data: Specific to the operation being performed. Most often used to send string data, such as a SQL query. * COMPRESSED PACKET * +---------------------------------------------------+-----------------+ | Packet Length | Packet no | Uncomp. Packet Length | Compressed Data | | 3 Bytes | 1 Byte | 3 Bytes | n bytes | +---------------------------------------------------+-----------------+ ^ ^ | 'HEADER' | +---------------------------------------------------+ * Packet Length: Calculated with int3store. See include/my_global.h for details. The basic computation is length = byte1 + (256 * byte2) + (256 * 256 * byte3). The max packetsize can be 16 MB. * Packet no: The packet number is incremented for each sent packet. The first packet starts with 0. * Uncomp. Packet Length: The length of the original, uncompressed packet If this is zero then the data is not compressed. * Compressed Data: The original packet, compressed with zlib compression When using the compressed protocol, the client/server will only compress send packets where the new packet is smaller than the not compressed one. In other words, some packets may be compressed while others will not. The 'compressed data' is one or more packets in *RAW PACKET* format. ***************************** * * FLOW OF EVENTS * ***************************** To understand how a client communicates with a MySQL server, it is easiest to start with a high-level flow of events. Each event section will then be followed by details of the exact contents of each type of packet involved in the event flow. * * * CONNECTION ESTABLISHMENT * * * Clients connect to the server via a TCP/IP socket (port 3306 by default), a Unix Domain Socket, or named pipes (on Windows). Once connected, the following connection establishment sequence is followed: +--------+ +--------+ | Client | | Server | +--------+ +--------+ | | | Handshake initialisation, including MySQL server version, | | protocol version and options supported, as well as the seed | | for the password hash | | | | <-------------------------------------------------------------- | | | | Client options supported, max packet size for client | | username, password crypted with seed from server, database | | name. | | | | --------------------------------------------------------------> | | | | 'OK' packet if authentication succeeds, 'ERROR' packet if | | authentication fails. | | | | <-------------------------------------------------------------- | | | * HANDSHAKE INITIALISATION PACKET * +--------------------------------------------------------------------+ | Header | Prot. Version | Server Version String | 0x00 | | | 1 Byte | n bytes | 1 byte | |--------------------------------------------------------------------| | Thread Number | Crypt Seed | 0x00 | CLIENT_xxx options | | | | | supported by server | | 4 Bytes | 8 Bytes | 1 Byte | 2 Bytes | |--------------------------------------------------------------------| | Server charset no. | Server status variables | 0x00 padding | | 1 Byte | 2 Bytes | 13 bytes | +--------------------------------------------------------------------+ * Protocol version (currently '10') * Server Version String (e.g. '4.0.5-beta-log'). Can be any length as it's followed by a 0 byte. * Thread Number - ID of server thread handling this connection * Crypt seed - seed used to crypt password in auth packet from client * CLIENT_xxx options - see include/mysql_com.h * Server charset no. - Index of charset in use by server * Server status variables - see include/mysql_com.h * The padding bytes are reserverd for future extensions to the protocol * CLIENT AUTH PACKET * +--------------------------------------------------------------------+ | Header | CLIENT_xxx options supported | max_allowed_packet | | | by client | for client | | | 2 Bytes | 3 bytes | |--------------------------------------------------------------------| | User Name | 0x00 | Crypted Password | 0x00 | Database Name | | n Bytes | 1 Byte | 8 Bytes | 1 Byte | n Bytes | |--------------------------------------------------------------------| | 0x00 | | 1 Byte | +--------------------------------------------------------------------+ * CLIENT_xxx options that this client supports: #define CLIENT_LONG_PASSWORD 1 /* new more secure passwords */ #define CLIENT_FOUND_ROWS 2 /* Found instead of affected rows */ #define CLIENT_LONG_FLAG 4 /* Get all column flags */ #define CLIENT_CONNECT_WITH_DB 8 /* One can specify db on connect */ #define CLIENT_NO_SCHEMA 16 /* Don't allow database.table.column */ #define CLIENT_COMPRESS 32 /* Can use compression protocol */ #define CLIENT_ODBC 64 /* Odbc client */ #define CLIENT_LOCAL_FILES 128 /* Can use LOAD DATA LOCAL */ #define CLIENT_IGNORE_SPACE 256 /* Ignore spaces before '(' */ #define CLIENT_INTERACTIVE 1024 /* This is an interactive client */ #define CLIENT_SSL 2048 /* Switch to SSL after handshake */ #define CLIENT_IGNORE_SIGPIPE 4096 /* IGNORE sigpipes */ #define CLIENT_TRANSACTIONS 8192 /* Client knows about transactions */ * max_allowed_packet for the client (in 'int3store' form) * User Name - user to authenticate as. Is followed by a null byte. * Crypted Password - password crypted with seed given in packet from server, see scramble() in sql/password.c * Database name (optional) - initial database to use once connected Is followed by a null byte At the end of every client/server exchange there is either an 'OK' packet or an 'ERROR' packet sent from the server. To determine whether a packet is an 'OK' packet, or an 'ERROR' packet, check if the first byte (after the header) is 0xFF. If it has the value of 0xFF, the packet is an 'ERROR' packet. * OK PACKET * For details, see sql/net_pkg.cc::send_ok() +-----------------------------------------------+ | Header | No of Rows | Affected Rows | | | 1 Byte | 1-9 Byte | |-----------------------------------------------| | ID (last_insert_id) | Status | Length | | 1-9 Byte | 2 Byte | 1-9 Byte | |-----------------------------------------------| | Messagetext | | n Byte | +-----------------------------------------------+ * Number of rows, always 0 * Affected rows * ID (last_insert_id) - value for auto_increment column (if any) * Status (usually 0) In general, in the MySQL protocol, fields in a packet that that represent numeric data, such as lengths, that are labeled as '1-9' bytes can be decoded by the following logic: If the first byte is '251', the corresponding column value is NULL (only appropriate in 'ROW DATA' packets). If the first byte is '252', the value stored can be read from the following 2 bytes as a 16-bit integer. If the first byte is '253' the value stored can be read from the following 4 bytes as a 32-bit long integer If the first byte is '254', the value stored can be read from the following 8 bytes as a 64-byte long Otherwise (values 0-250), the value stored is the value of the first byte itself. If the OK-packet includes a message: * Length of message * Message Text * ERROR PACKET * +-----------------------------------------------+ | Header | Status code | Error no | | | 1 Byte | 2 Byte | |-----------------------------------------------| | Messagetext | | | n Byte | | +-----------------------------------------------+ * Status code (0xFF = ERROR) * Error number (is only sent to 3.23 and newer clients) * Error message text (ends at end of packet) Note that the error message is not null terminated. The client code can however assume that the packet ends with a null as my_net_read() will always add an end-null to all read packets to make things easier for the client. Example: Packet dump of client connecting to server: +------------------------- Protocol Version (10) | | +---------------------- Server Version String (0x00 terminated) | | | | 0a 34 2e 30 2e 35 2d 62 . 4 . 0 . 5 - b 65 74 61 2d 6c 6f 67 00 e t a - l o g . 15 00 00 00 2b 5a 65 6c . . . . + Z e l | | | +------------ First 4 bytes of crypt seed | +------------------------ Thread Number +------------------------- Last 4 bytes of crypt seed | | +-------- CLIENT_XXX Options supported by server | | | +-+--+ +--- Server charset index | | | | 6f 69 41 46 00 2c 28 08 o i A F . , ( . 02 00 00 00 00 00 00 00 . . . . . . . . | | | +---------------------- 0x00 padding begins | +------------------------- Server status (0x02 = SERVER_STATUS_AUTOCOMMIT) 00 00 00 00 00 00 00 00 . . . . . . . . * Client Authentication Response (Username 'test', no database selected) * +--------------------- Packet Length (0x13 = 19 bytes) | | +--------------- Packet Sequence # | | | | +----------- CLIENT_XXX Options supported by client | | +---+---+ | +-+-+ | | | | | 13 00 00 01 03 00 1e 00 . . . . . . . . 00 74 65 73 74 00 48 5e . t e s t . H ^ | | | +----+-----+ +------- Scrambled password, 0x00 terminated | +----------------- Username, 0x00 terminated 57 4a 4e 41 4a 4e 00 00 W J N A J N . . 00 . >From this point on, the server waits for 'commands' from the client which include queries, database shutdown, quit, change user, etc (see the COM_xxxx values in include/mysql_com.h for the latest command codes). * * * COMMAND PROCESSING * * * +--------+ +--------+ | Client | | Server | +--------+ +--------+ | | | A command packet, with a command code, and string data | | when appropriate (e.g. a query), (see the COM_xxxx values | | in include/mysql_com.h for the command codes) | | | | --------------------------------------------------------------> | | | | A 'RESULT' packet if the command completed successfully, | | an 'ERROR' packet if the command failed. 'RESULT' packets | | take different forms (see the details following this chart) | | depending on whether or not the command returns rows. | | | | <-------------------------------------------------------------- | | | | n 'FIELD PACKET's (if rows are returned) | | | | <-------------------------------------------------------------- | | | | 'LAST DATA' packet | | | | <-------------------------------------------------------------- | | | | n 'ROW PACKET's (if rows are returned) | | | | <-------------------------------------------------------------- | | | | 'LAST DATA' packet | | | | <-------------------------------------------------------------- | | | * Command Packet * +------------------------------------------------------+ | Header | Command type | Query (if applicable) | | | 1 Byte | n Bytes | +------------------------------------------------------+ * Command type: (e.g.0x03 = query, see the COM_xxxx values in include/mysql_com.h) * Query (if applicable) Note that my_net_read() null-terminates all packets on the receiving side of the channel to make it easier for the code examining the packets. The current command codes are: 0x00 COM_SLEEP 0x01 COM_QUIT 0x02 COM_INIT_DB 0x03 COM_QUERY 0x04 COM_FIELD_LIST 0x05 COM_CREATE_DB 0x06 COM_DROP_DB 0x07 COM_REFRESH 0x08 COM_SHUTDOWN 0x09 COM_STATISTICS 0x0a COM_PROCESS_INFO 0x0b COM_CONNECT 0x0c COM_PROCESS_KILL 0x0d COM_DEBUG 0x0e COM_PING 0x0f COM_TIME 0x10 COM_DELAYED_INSERT 0x11 COM_CHANGE_USER 0x12 COM_BINLOG_DUMP 0x13 COM_TABLE_DUMP 0x14 COM_CONNECT_OUT 0x15 COM_REGISTER_SLAVE * Result Packet * Result packet for a command returning _no_ rows: +-----------------------------------------------+ | Header | Field Count | Affected Rows | | | 1-9 Bytes | 1-9 Bytes | |-----------------------------------------------| | ID (last_insert_id) | Server Status | | 1-9 Bytes | 2 Bytes | +-----------------------------------------------+ * Field Count: Has value of '0' for commands returning _no_ rows * Affected rows: Count of rows affected by INSERT/UPDATE/DELETE, etc. * ID: value of auto_increment column in row (if any). 0 if * Server Status: Usually 0 Result packet for a command returning rows: +-------------------------------+ | Header | Field Count | | | 1-9 Bytes | +-------------------------------+ * Field Count: number of columns/fields in result set, (packed with net_store_length() in sql/net_pkg.cc) This is followed by as many packets as the number of fields ('Field Count') that contain the metadata for each column/field (see unpack_fields() in libmysql/libmysql.c): * FIELD PACKET * +-----------------------------------------------+ | Header | Table Name | | | length-coded-string | |-----------------------------------------------| | Field Name | | length-code-string | |-----------------------------------------------| | Display length of field | length-coded-binary (4 bytes) | |-----------------------------------------------| | Field Type (enum_field_types in mysql_com.h) | | length-coded-binary (2 bytes) | |-----------------------------------------------| | Field Flags | Decimal Places| | length-coded-binary (3 bytes) | 1 Byte | +--------------+-------------+------------------+ * A length coded string is a string where we first have a packet length (1-9 bytes, packed_with net_store_length()) followed by a string. * A length coded binary is a length (1 byte) followed by an integer value in low-byte-first order. For the moment this type is always fixed length in this packet. * Table Name - the name of the table the column comes from * Field Name - the name of the column/field * Display length of field - length of field * Field Type - Type of field, see enum_field_types in include/mysql_com.h Current field types are: 0x00 FIELD_TYPE_DECIMAL 0x01 FIELD_TYPE_TINY 0x02 FIELD_TYPE_SHORT 0x03 FIELD_TYPE_LONG 0x04 FIELD_TYPE_FLOAT 0x05 FIELD_TYPE_DOUBLE 0x06 FIELD_TYPE_NULL 0x07 FIELD_TYPE_TIMESTAMP 0x08 FIELD_TYPE_LONGLONG 0x09 FIELD_TYPE_INT24 0x0a FIELD_TYPE_DATE 0x0b FIELD_TYPE_TIME 0x0c FIELD_TYPE_DATETIME 0x0d FIELD_TYPE_YEAR 0x0e FIELD_TYPE_NEWDATE 0xf7 FIELD_TYPE_ENUM 0xf8 FIELD_TYPE_SET 0xf9 FIELD_TYPE_TINY_BLOB 0xfa FIELD_TYPE_MEDIUM_BLOB 0xfb FIELD_TYPE_LONG_BLOB 0xfc FIELD_TYPE_BLOB 0xfd FIELD_TYPE_VAR_STRING 0xfe FIELD_TYPE_STRING 0xff FIELD_TYPE_GEOMETRY * Field Flags - NOT_NULL_FLAG, PRI_KEY_FLAG, xxx_FLAG in include/mysql_com.h Note that the packet format in 4.1 has slightly changed to allow more values. * ROW PACKET * +-----------------------------------------------+ | Header | Data Length | Column Data | ....for each column | | 1-9 Bytes | n Bytes | +-----------------------------------------------+ * Data Length: (packed with net_store_length() in sql/net_pkg.cc) If 'Data Length' == 0, this is an 'ERROR PACKET'. * Column Data: String representation of data. MySQL always sends result set data as strings. * LAST DATA PACKET * Packet length is < 9 bytes, and first byte is 0xFE +--------+ | 0xFE | | 1 Byte | +--------+ Examples: *********** * * INITDB Command * *********** A client issuing an 'INITDB' (select the database to use) command, followed by an 'OK' packet with no rows and no affected rows from the server: * INITDB (select database to use) 'COMMAND' Packet * +--------------------- Packet Length (5 bytes) | | +--------------- Packet Sequence # | | | | +------------ Command # (INITDB = 0x02) | | +---+---+ | | +---------- Beginning of query data | | | | | 05 00 00 00 02 74 65 73 . . . . . t e s 74 t * 'OK' Packet with no rows, and no rows affected * +--------------------- Packet Length (3 bytes) | | +--------------- Packet Sequence # | | +---+---+ | | | | 03 00 00 01 00 00 00 . . . . . . . *********** * * SELECT query example * *********** Client issuing a 'SELECT *' query on the following table: CREATE TABLE number_test (minBigInt bigint, maxBigInt bigint, testBigInt bigint) * 'COMMAND' Packet with QUERY (select ...) * +--------------------- Packet Length (26) | | +--------------- Packet Sequence # | | | | +------------ Command # (QUERY = 0x03) | | +---+---+ | | +---------- Beginning of query data | | | | | 1a 00 00 00 03 53 45 4c . . . . . S E L 45 43 54 20 2a 20 66 72 E C T . * . f r 6f 6d 20 6e 75 6d 62 65 o m . n u m b e 72 5f 74 65 73 74 r _ t e s t and receiving an 'OK' packet with a 'FIELD COUNT' of 3 * 'OK' Packet with 3 fields * +--------------------- Packet Length (3 bytes) | | +--------------- Packet Sequence # | | +---+---+ | | | | 01 00 00 01 03 . . . . . Followed immediately by 3 'FIELD' Packets. Note, the individual packets are delimitted by =======, so that all fields can be annotated in the first 'FIELD' packet example: ============================================================= +--------------------- Packet Length (0x1f = 31 bytes) | | +--------------- Packet Sequence # | | | | +------------ Block Length (0x0b = 11 bytes) | | | +---+---+ | | +--------- Table Name (11 bytes long) | | | | | 1f 00 00 02 0b 6e 75 6d . . . . . n u m 62 65 72 5f 74 65 73 74 b e r _ t e s t +------------------------ Block Length (9 bytes) | | +--------------------- Column Name (9 bytes long) | | 09 6d 69 6e 42 69 67 49 . m i n B i g I 6e 74 03 14 00 00 01 08 n t . . . . . . | | | | | | +---+---+ | +--- Field Type (0x08 = FIELD_TYPE_LONGLONG) | | | | | +------ Block Length (1) | | | +--------------- Display Length (0x14 = 20 chars) | +------------------ Block Length (3) +------------------------ Block Length (2) | | +-------------------- Field Flags (0 - no flags set) | | | +---+ +--------------- Decimal Places (0) | | | | 02 00 00 00 . . . . ============================================================= 'FIELD' packet for the 'number_Test.maxBigInt' column 1f 00 00 03 0b 6e 75 6d . . . . . n u m 62 65 72 5f 74 65 73 74 b e r _ t e s t 09 6d 61 78 42 69 67 49 . m a x B i g I 6e 74 03 14 00 00 01 08 n t . . . . . . 02 00 00 00 . . . . ============================================================= 'FIELD' packet for the 'number_test.testBigInt' column 20 00 00 04 0b 6e 75 6d . . . . . n u m 62 65 72 5f 74 65 73 74 b e r _ t e s t 0a 74 65 73 74 42 69 67 . t e st B i g 49 6e 74 03 14 00 00 01 I n t . . . . . 08 02 00 00 00 . . . . . ============================================================= Followed immediately by one 'LAST DATA' packet: fe 00 . . Followed immediately by 'n' row packets (in this case, only one packet is sent from the server, for simplicity's sake): +--------------------- Packet Length (0x52 = 82 bytes) | | +--------------- Packet Sequence # | | | | +------------ Data Length (0x14 = 20 bytes) | | | +---+---+ | | +--------- String Data '-9223372036854775808' | | | | | (repeat Data Length/Data sequence) 52 00 00 06 14 2d 39 32 . . . . . - 9 2 32 33 33 37 32 30 33 36 2 3 3 7 2 0 3 6 38 35 34 37 37 35 38 30 8 5 4 7 7 5 8 0 38 13 39 32 32 33 33 37 8 . 9 2 2 3 3 7 32 30 33 36 38 35 34 37 2 0 3 6 8 5 4 7 37 35 38 30 37 0a 36 31 7 5 8 0 7 . 6 1 34 37 34 38 33 36 34 37 4 7 4 8 3 6 4 7 Followed immediately by one 'LAST DATA' packet: fe 00 . . @end example @c The Index was empty, and ugly, so I removed it. (jcole, Sep 7, 2000) @c @node Index @c @unnumbered Index @c @printindex fn @c @node 4.1 protocol,,, @c @chapter MySQL 4.1 protocol @node 4.1 protocol changes, 4.1 field packet, protocol version 2, protocol @section Changes to 4.0 protocol in 4.1 All basic packet handling is identical to 4.0. When communication with an old 4.0 or 3.x client we will use the old protocol. The new things that we support with 4.1 are: @itemize @bullet @item Warnings @item Prepared statements @item Binary protocol (will be faster than the current protocol that converts everything to strings) @end itemize What has changed in 4.1 are: @itemize @bullet @item A lot of new field information (database, real table name etc) @item The 'ok' packet has more status fields @item The 'end' packet (send last for each result set) now contains some extra information @item New protocol for prepared statements. In this case all parameters and results will sent as binary (low-byte-first). @end itemize @node 4.1 field packet, 4.1 field desc, 4.1 protocol changes, protocol @section 4.1 field description packet The field description packet is sent as a response to a query that contains a result set. It can be distinguished from a ok packet by the fact that the first byte can't be 0 for a field packet. @xref{4.1 ok packet}. The header packet has the following structure: @multitable @columnfractions .10 .90 @item Size @tab Comment @item 1-9 @tab Number of columns in result set (never 0) @item 1-9 @tab Extra information sent be some command (SHOW COLUMNS uses this to send the number of rows in the table) @end multitable This packet is always followed by a field description set. @xref{4.1 field desc}. @node 4.1 field desc, 4.1 ok packet, 4.1 field packet, protocol @section 4.1 field description result set The field description result set contains the meta info for a result set. @multitable @columnfractions .20 .80 @item Type @tab Comment @item string @tab Database name @item string @tab Table name alias (or table name if no alias) @item string @tab Real table name @item string @tab Alias for column name (or column name if not used) @item 3 byte int @tab Length of column definition @item 1 byte int @tab Enum value for field type @item 3 byte int @tab 2 byte column flags (NOT_NULL_FLAG etc..) + 1 byte number of decimals. @item string int @tab Default value, only set when using mysql_list_fields(). @end multitable @node 4.1 ok packet, 4.1 end packet, 4.1 field desc, protocol @section 4.1 ok packet The ok packet is the first that is sent as an response for a query that didn't return a result set. The ok packet has the following structure: @multitable @columnfractions .10 .90 @item Size @tab Comment @item 1 @tab 0 ; Marker for ok packet @item 1-9 @tab Affected rows @item 1-9 @tab Last insert id (0 if one wasn't used) @item 2 @tab Server status; Can be used by client to check if we are inside an transaction @item 2 @tab Warning count @item 1-9 @tab Message length (optional) @item xxx @tab Message (optional) @end multitable Size 1-9 means that the parameter is packed in to 1-9 bytes depending on the value. (See function sql/net_pkg.cc::net_store_length). The message is optional. For example for multi line INSERT it contains a string for how many rows was inserted / deleted. @node 4.1 end packet, 4.1 error packet, 4.1 ok packet, protocol @section 4.1 end packet The end packet is sent as the last packet for @itemize @bullet @item End of field information @item End of parameter type information @item End of result set @end itemize The end packet has the following structure: @multitable @columnfractions .10 .90 @item Size @tab Comment @item 1 @tab 254 ; Marker for EOF packet @item 2 @tab Warning count @item 2 @tab Status flags (For flags like SERVER_STATUS_MORE_RESULTS) @end multitable Note that a normal packet may start with byte 254, which means 'length stored in 9 bytes'. One can different between these cases by checking the packet length < 9 bytes (in which case it's and end packet). @node 4.1 error packet, 4.1 prep init, 4.1 end packet, protocol @section 4.1 error packet. The error packet is sent when something goes wrong. The error packet has the following structure: @multitable @columnfractions .10 .90 @item Size @tab Comment @item 1 @tab 255 Error packet marker @item 2 @tab Error code @item 1-255 @tab Null terminated error message @end multitable The client/server protocol is designed in such a way that a packet can only start with 255 if it's an error packet. @node 4.1 prep init, 4.1 long data, 4.1 error packet, protocol @section 4.1 prepared statement init packet This is the return packet when one sends a query with the COM_PREPARE command. @multitable @columnfractions .10 .90 @item Size @tab Comment @item 4 @tab Statement handler id @item 2 @tab Number of columns in result set @item 2 @tab Number of parameters in query @end multitable After this, there is a packet that contains the following for each parameter in the query: @multitable @columnfractions .10 .90 @item Size @tab Comment @item 2 @tab Enum value for field type. (MYSQL_TYPE_UNKNOWN if not known) @item 2 @tab 2 byte column flags (NOT_NULL_FLAG etc) @item 1 @tab Number of decimals @item 4 @tab Max column length. @end multitable Note that the above is not yet in 4.1 but will be added this month. As MySQL can have a parameter 'anywhere' it will in many cases not be able to provide the optimal information for all parameters. If number of columns, in the header packet, is not 0 then the prepared statement will contain a result set. In this case the packet is followed by a field description result set. @xref{4.1 field desc}. @node 4.1 long data, 4.1 execute, 4.1 prep init, protocol @section 4.1 long data handling This is used by mysql_send_long_data() to set any parameter to a string value. One can call mysql_send_long_data() multiple times for the same parameter; The server will concatenate the results to a one big string. The server will not require an end packet for the string. mysql_send_long_data() is responsible updating a flag that all data has been sent. (Ie; That the last call to mysql_send_long_data() has the 'last_data' flag set). This packet is sent from client -> server: @multitable @columnfractions .10 .90 @item Size @tab Comment @item 4 @tab Statement handler @item 2 @tab Parameter number @item 2 @tab Type of parameter (not used at this point) @item # @tab data (Rest of packet) @end multitable The server will NOT send an @code{ok} or @code{error} packet in responce for this. If there is any errors (like to big string), one will get the error when calling execute. @node 4.1 execute, 4.1 binary result, 4.1 long data, protocol @section 4.1 execute On execute we send all parameters to the server in a COM_EXECUTE packet. The packet contains the following information: @multitable @columnfractions .30 .70 @item Size @tab Comment @item (param_count+9)/8 @tab Null bit map (2 bits reserved for protocol) @item 1 @tab new_parameter_bound flag. Is set to 1 for first execute or if one has rebound the parameters. @item 2*param_count @tab Type of parameters (only given if new_parameter_bound flag is 1) @item # @tab Parameter data, repeated for each parameter that are NOT NULL and not used with mysql_send_long_data(). @end multitable The null-bit-map is for all parameters (including parameters sent with 'mysql_send_long_data). If parameter 0 is NULL, then bit 0 in the null-bit-map should be 1 (ie: first byte should be 1) The parameters are stored the following ways: @multitable @columnfractions .20 .10 .70 @item Type @tab Size @tab Comment @item tinyint @tab 1 @tab One byte integer @item short @tab 2 @tab @item int @tab 4 @tab @item longlong @tab 8 @tab @item float @tab 4 @tab @item double @tab 8 @tab @item string @tab 1-9 + # @tab Packed string length + string @end multitable The result for this will be either an ok packet or a binary result set. @node 4.1 binary result, , 4.1 execute, protocol @section 4.1 binary result set A binary result are sent the following way. For each result row: @itemize @item null bit map with first two bits set to 01 (bit 0,1 value 1) @item parameter data, repeated for each not null result column. @end itemize The idea with the reserving two bits in the null map is that we can use standard error (first byte 255) and ok packets (first byte 0) to end a result sets. Except that the null-bit-map is shifted two steps, the server is sending the data to the client the same way that the server is sending bound parameters to the client. The server is always sending the data as type given for 'column type' for respective column. It's up to the client to convert the parameter to the requested type. DATETIME, DATE and TIME are sent to the server in a binary format as follows: @multitable @columnfractions .20 .10 .70 @item Type @tab Size @tab Comment @item date @tab 1 + 0-11 @tab Length + 2 byte year, 1 byte MMDDHHMMSS, 4 byte billionth of a second @item datetime @tab 1 + 0-11 @tab Length + 2 byte year, 1 byte MMDDHHMMSS, 4 byte billionth of a second @item time @tab 1 + 0-14 @tab Length + sign (0 = pos, 1= neg), 4 byte days, 1 byte HHMMDD, 4 byte billionth of a second @end multitable The first byte is a length byte and then comes all parameters that are not 0. (Always counted from the beginning). @node Fulltext Search, MyISAM Record Structure, protocol, Top @chapter Fulltext Search in MySQL Hopefully, sometime there will be complete description of fulltext search algorithms. Now it's just unsorted notes. @menu * Weighting in boolean mode:: @end menu @node Weighting in boolean mode, , Fulltext Search, Fulltext Search @section Weighting in boolean mode The basic idea is as follows: in expression @code{A or B or (C and D and E)}, either @code{A} or @code{B} alone is enough to match the whole expression. While @code{C}, @code{D}, and @code{E} should @strong{all} match. So it's reasonable to assign weight 1 to @code{A}, @code{B}, and @code{(C and D and E)}. And @code{C}, @code{D}, and @code{E} should get a weight of 1/3. Things become more complicated when considering boolean operators, as used in MySQL FTB. Obvioulsy, @code{+A +B} should be treated as @code{A and B}, and @code{A B} - as @code{A or B}. The problem is, that @code{+A B} can @strong{not} be rewritten in and/or terms (that's the reason why this - extended - set of operators was chosen). Still, aproximations can be used. @code{+A B C} can be approximated as @code{A or (A and (B or C))} or as @code{A or (A and B) or (A and C) or (A and B and C)}. Applying the above logic (and omitting mathematical transformations and normalization) one gets that for @code{+A_1 +A_2 ... +A_N B_1 B_2 ... B_M} the weights should be: @code{A_i = 1/N}, @code{B_j=1} if @code{N==0}, and, otherwise, in the first rewritting approach @code{B_j = 1/3}, and in the second one - @code{B_j = (1+(M-1)*2^M)/(M*(2^(M+1)-1))}. The second expression gives somewhat steeper increase in total weight as number of matched B's increases, because it assigns higher weights to individual B's. Also the first expression in much simplier. So it is the first one, that is implemented in MySQL. @node MyISAM Record Structure, InnoDB Record Structure, Fulltext Search, Top @chapter MyISAM Record Structure @section Introduction When you say: @* @strong{CREATE TABLE Table1 ...} @* MySQL creates files named Table1.MYD ("MySQL Data"), Table1.MYI ("MySQL Index"), and Table1.frm ("Format"). These files will be in the directory: @* /// @* For example, if you use Linux, you might find the files here (assume your database name is "test"): @* /usr/local/var/test @* And if you use Windows, you might find the files in this directory: @* \mysql\data\test\ @*@* Let's look at the .MYD Data file (MyISAM SQL Data file) more closely. There are three possible formats -- fixed, dynamic, and packed. First, let's discuss the fixed format. @table @strong @item Page Size Unlike most DBMSs, MySQL doesn't store on disk using pages. Therefore you will not see filler space between rows. (Reminder: This does not refer to BDB and InnoDB tables, which do use pages). @* @item Record Header The minimal record header is a set of flags: @itemize @bullet @item "X bit" = 0 if row is deleted, = 1 if row is not deleted @item "Null Bits" = 0 if column is not NULL, = 1 if column is NULL @item "Filler Bits" = 1 @end itemize @end table @* The length of the record header is thus:@* (1 + number of NULL columns + 7) / 8 bytes@* After the header, all columns are stored in the order that they were created, which is the same order that you would get from SHOW COLUMNS. Here's an example. Suppose you say: @* @strong{CREATE TABLE Table1 (column1 CHAR(1), column2 CHAR(1), column3 CHAR(1))} @* @strong{INSERT INTO Table1 VALUES ('a', 'b', 'c')} @* @strong{INSERT INTO Table1 VALUES ('d', NULL, 'e')} @* A CHAR(1) column takes precisely one byte (plus one bit of overhead that is assigned to every column -- I'll describe the details of column storage later). So the file Table1.MYD looks like this: @* @strong{Hexadecimal Display of Table1.MYD file}@* @code{ F1 61 62 63 00 F5 64 00 66 00 ... .abc..d e. } @* Here's how to read this hexadecimal-dump display:@* @itemize @bullet @item The hexadecimal numbers @code{F1 61 62 63 00 F5 64 20 66 00} are byte values and the column on the right is an attempt to show the same bytes in ASCII. @item The @code{F1} byte means that there are no null fields in the first row. @item The @code{F5} byte means that the second column of the second row is NULL. @end itemize (It's probably easier to understand the flag setting if you restate @code{F5} as @code{11110101 binary}, and (a) notice that the third flag bit from the right is @code{on}, and (b) remember that the first flag bit is the X bit.) @* There are complications -- the record header is more complex if there are variable-length fields -- but the simple display shown in the example is exactly what you'd see if you looked at the MySQL Data file with a debugger or a hexadecimal file dumper. @* So much for the fixed format. Now, let's discuss the dynamic format. @* The dynamic file format is necessary if rows can vary in size. That will be the case if there are BLOB columns, or "true" VARCHAR columns. (Remember that MySQL may treat VARCHAR columns as if they're CHAR columns, in which case the fixed format is used.) A dynamic row has more fields in the header. The important ones are "the actual length", "the unused length", and "the overflow pointer". The actual length is the total number of bytes in all the columns. The unused length is the total number of bytes between one physical record and the next one. The overflow pointer is the location of the rest of the record if there are multiple parts. @* For example, here is a dynamic row: @* @example 03, 00 start of header 04 actual length 0c unused length 01, fc flags + overflow pointer **** data in the row ************ unused bytes <-- next row starts here) @end example In the example, the actual length and the unused length are short (one byte each) because the table definition says that the columns are short -- if the columns were potentially large, then the actual length and the unused length could be two bytes each, three bytes each, and so on. In this case, actual length plus unused length is 10 hexadecimal (sixteen decimal), which is a minimum. As for the third format -- packed -- we will only say briefly that: @itemize @bullet @item Numeric values are stored in a form that depends on the range (start/end values) for the data type. @item All columns are packed using either Huffman or enum coding. @end itemize For details, see the source files /myisam/mi_statrec.c (for fixed format), /myisam/mi_dynrec.c (for dynamic format), and /myisam/mi_packrec.c (for packed format). Note: Internally, MySQL uses a format much like the fixed format which it uses for disk storage. The main differences are: @enumerate @item BLOBs have a length and a memory pointer rather than being stored inline. @item "True VARCHAR" (a column storage which will be fully implemented in version 5.0) will have a 16-bit length plus the data. @item All integer or floating-point numbers are stored with the low byte first. Point (3) does not apply for ISAM storage or internals. @end enumerate @* @section Physical Attributes of Columns Next I'll describe the physical attributes of each column in a row. The format depends entirely on the data type and the size of the column, so, for every data type, I'll give a description and an example. @* @table @strong @item The character data types @strong{CHAR} @itemize @bullet @item Storage: fixed-length string with space padding on the right. @item Example: a CHAR(5) column containing the value 'A' looks like:@* @code{hexadecimal 41 20 20 20 20} -- (length = 5, value = @code{'A '}) @end itemize @strong{VARCHAR} @itemize @bullet @item Storage: variable-length string with a preceding length. @item Example: a VARCHAR(7) column containing 'A' looks like:@* @code{hexadecimal 01 41} -- (length = 1, value = @code{'A'}) @end itemize @item The numeric data types Important: MySQL almost always stores multi-byte binary numbers with the low byte first. This is called "little-endian" numeric storage; it's normal on Intel x86 machines; MySQL uses it even for non-Intel machines so that databases will be portable. @* @strong{TINYINT} @itemize @bullet @item Storage: fixed-length binary, always one byte. @item Example: a TINYINT column containing 65 looks like:@* @code{hexadecimal 41} -- (length = 1, value = 65) @end itemize @strong{SMALLINT} @itemize @bullet @item Storage: fixed-length binary, always two bytes. @item Example: a SMALLINT column containing 65 looks like:@* @code{hexadecimal 41 00} -- (length = 2, value = 65) @end itemize @strong{MEDIUMINT} @itemize @bullet @item Storage: fixed-length binary, always three bytes. @item Example: a MEDIUMINT column containing 65 looks like:@* @code{hexadecimal 41 00 00} -- (length = 3, value = 65) @end itemize @strong{INT} @itemize @bullet @item Storage: fixed-length binary, always four bytes. @item Example: an INT column containing 65 looks like:@* @code{hexadecimal 41 00 00 00} -- (length = 4, value = 65) @end itemize @strong{BIGINT} @itemize @bullet @item Storage: fixed-length binary, always eight bytes. @item Example: a BIGINT column containing 65 looks like:@* @code{hexadecimal 41 00 00 00 00 00 00 00} -- (length = 8, value = 65) @end itemize @strong{FLOAT} @itemize @bullet @item Storage: fixed-length binary, always four bytes. @item Example: a FLOAT column containing approximately 65 looks like:@* @code{hexadecimal 00 00 82 42} -- (length = 4, value = 65) @end itemize @strong{DOUBLE PRECISION} @itemize @bullet @item Storage: fixed-length binary, always eight bytes. @item Example: a DOUBLE PRECISION column containing approximately 65 looks like:@* @code{hexadecimal 00 00 00 00 00 40 50 40} -- (length = 8, value = 65) @end itemize @strong{REAL} @itemize @bullet @item Storage: same as FLOAT, or same as DOUBLE PRECISION, depending on setting of the --ansi switch. @end itemize @strong{DECIMAL} @itemize @bullet @item Storage: fixed-length string, with a leading byte for the sign, if any. @item Example: a DECIMAL(2) column containing 65 looks like:@* @code{hexadecimal 20 36 35} -- (length = 3, value = @code{' 65'}) @item Example: a DECIMAL(2) UNSIGNED column containing 65 looks like:@* @code{hexadecimal 36 35} -- (length = 2, value = @code{'65'}) @item Example: a DECIMAL(4,2) UNSIGNED column containing 65 looks like:@* @code{hexadecimal 36 35 2E 30 30} -- (length = 5, value = @code{'65.00'}) @end itemize @strong{NUMERIC} @itemize @bullet @item Storage: same as DECIMAL. @end itemize @strong{BOOL} @itemize @bullet @item Storage: same as TINYINT. @end itemize @item The temporal data types @strong{DATE} @itemize @bullet @item Storage: 3 byte integer, low byte first. Packed as: 'day + month*32 + year*16*32' @item Example: a DATE column containing '1962-01-02' looks like:@* @code{hexadecimal 22 54 0F} @end itemize @strong{DATETIME} @itemize @bullet @item Storage: eight bytes. @item Part 1 is a 32-bit integer containing year*10000 + month*100 + day. @item Part 2 is a 32-bit integer containing hour*10000 + minute*100 + second. @item Example: a DATETIME column for '0001-01-01 01:01:01' looks like:@* @code{hexadecimal B5 2E 11 5A 02 00 00 00} @end itemize @strong{TIME} @itemize @bullet @item Storage: 3 bytes, low byte first. This is stored as seconds: days*24*3600+hours*3600+minutes*60+seconds @item Example: a TIME column containing '1 02:03:04' (1 day 2 hour 3 minutes and 4 seconds) looks like:@* @code{hexadecimal 58 6E 01} @end itemize @strong{TIMESTAMP} @itemize @bullet @item Storage: 4 bytes, low byte first. Stored as unix @code{time()}, which is seconds since the Epoch (00:00:00 UTC, January 1, 1970). @item Example: a TIMESTAMP column containing '2003-01-01 01:01:01' looks like:@* @code{hexadecimal 4D AE 12 23} @end itemize @strong{YEAR} @itemize @bullet @item Storage: same as unsigned TINYINT with a base value of 0 = 1901. @end itemize @item Others @strong{SET} @itemize @bullet @item Storage: one byte for each eight members in the set. @item Maximum length: eight bytes (for maximum 64 members). @item This is a bit list. The least significant bit corresponds to the first listed member of the set. @item Example: a SET('A','B','C') column containing 'A' looks like:@* @code{01} -- (length = 1, value = 'A') @end itemize @strong{ENUM} @itemize @bullet @item Storage: one byte if less than 256 alternatives, else two bytes. @item This is an index. The value 1 corresponds to the first listed alternative. (Note: ENUM always reserves 0 for an erroneous value. This explains why 'A' is 1 instead of 0.) @item Example: an ENUM('A','B','C') column containing 'A' looks like:@* @code{01} -- (length = 1, value = 'A') @end itemize @item The Large-Object data types Warning: Because TINYBLOB's preceding length is one byte long (the size of a TINYINT) and MEDIUMBLOB's preceding length is three bytes long (the size of a MEDIUMINT), it's easy to think there's some sort of correspondence between the BLOB and the INT types. There isn't -- a BLOB's preceding length is not four bytes long (the size of an INT). @* @strong{TINYBLOB} @itemize @bullet @item Storage: variable-length string with a preceding one-byte length. @item Example: a TINYBLOB column containing 'A' looks like:@* @code{hexadecimal 01 41} -- (length = 2, value = 'A') @end itemize @strong{TINYTEXT} @itemize @bullet @item Storage: same as TINYBLOB. @end itemize @strong{BLOB} @itemize @bullet @item Storage: variable-length string with a preceding two-byte length. @item Example: a BLOB column containing 'A' looks like:@* @code{hexadecimal 01 00 41} -- (length = 2, value = 'A') @end itemize @strong{TEXT} @itemize @bullet @item Storage: same as BLOB. @end itemize @strong{MEDIUMBLOB} @itemize @bullet @item Storage: variable-length string with a preceding length. @item Example: a MEDIUMBLOB column containing 'A' looks like:@* @code{hexadecimal 01 00 00 41} -- (length = 4, value = 'A') @end itemize @strong{MEDIUMTEXT} @itemize @bullet @item Storage: same as MEDIUMBLOB. @end itemize @strong{LONGBLOB} @itemize @bullet @item Storage: variable-length string with a preceding four-byte length. @item Example: a LONGBLOB column containing 'A' looks like:@* @code{hexadecimal 01 00 00 00 41} -- (length = 5, value = 'A') @end itemize @strong{LONGTEXT} @itemize @bullet @item Storage: same as LONGBLOB. @end itemize @end table @section Where to Look For More Information @strong{References:} @* Most of the formatting work for MyISAM columns is visible in the program /sql/field.cc in the source code directory. And in the MyISAM directory, the files that do formatting work for different record formats are: /myisam/mi_statrec.c, /myisam/mi_dynrec.c, and /myisam/mi_packrec.c. @* @node InnoDB Record Structure, InnoDB Page Structure, MyISAM Record Structure, Top @chapter InnoDB Record Structure This page contains: @itemize @bullet @item A high-altitude "summary" picture of the parts of a MySQL/InnoDB record structure. @item A description of each part. @item An example. @end itemize After reading this page, you will know how MySQL/InnoDB stores a physical record. @* @section High-Altitude Picture The chart below shows the three parts of a physical record. @multitable @columnfractions .10 .35 @item @strong{Name} @tab @strong{Size} @item Field Start Offsets @tab (F*1) or (F*2) bytes @item Extra Bytes @tab 6 bytes @item Field Contents @tab depends on content @end multitable Legend: The letter 'F' stands for 'Number Of Fields'. The meaning of the parts is as follows: @itemize @bullet @item The FIELD START OFFSETS is a list of numbers containing the information "where a field starts". @item The EXTRA BYTES is a fixed-size header. @item The FIELD CONTENTS contains the actual data. @end itemize @strong{An Important Note About The Word "Origin"}@* The "Origin" or "Zero Point" of a record is the first byte of the Field Contents -- not the first byte of the Field Start Offsets. If there is a pointer to a record, that pointer is pointing to the Origin. Therefore the first two parts of the record are addressed by subtracting from the pointer, and only the third part is addressed by adding to the pointer. @subsection FIELD START OFFSETS The Field Start Offsets is a list in which each entry is the position, relative to the Origin, of the start of the next field. The entries are in reverse order, that is, the first field's offset is at the end of the list. @* An example: suppose there are three columns. The first column's length is 1, the second column's length is 2, and the third column's length is 4. In this case, the offset values are, respectively, 1, 3 (1+2), and 7 (1+2+4). Because values are reversed, a core dump of the Field Start Offsets would look like this: @code{07,03,01}. @* There are two complications for special cases: @itemize @bullet @item Complication #1: The size of each offset can be either one byte or two bytes. One-byte offsets are only usable if the total record size is less than 127. There is a flag in the "Extra Bytes" part which will tell you whether the size is one byte or two bytes. @item Complication #2: The most significant bits of an offset may contain flag values. The next two paragraphs explain what the contents are. @end itemize @strong{When The Size Of Each Offset Is One Byte} @itemize @bullet @item 1 bit = 0 if field is non-NULL, = 1 if field is NULL @item 7 bits = the actual offset, a number between 0 and 127 @end itemize @strong{When The Size Of Each Offset Is Two Bytes} @itemize @bullet @item 1 bit = 0 if field is non-NULL, = 1 if field is NULL @item 1 bit = 0 if field is on same page as offset, = 1 if field and offset are on different pages @item 14 bits = the actual offset, a number between 0 and 16383 @end itemize It is unlikely that the "field and offset are on different pages" unless the record contains a large BLOB. @subsection EXTRA BYTES The Extra Bytes are a fixed six-byte header. @multitable @columnfractions .10 .25 .35 @item @strong{Name} @tab @strong{Size} @tab @strong{Description} @item @strong{info_bits:} @item () @tab 1 bit @tab unused or unknown @item () @tab 1 bit @tab unused or unknown @item deleted_flag @tab 1 bit @tab 1 if record is deleted @item min_rec_flag @tab 1 bit @tab 1 if record is predefined minimum record @item n_owned @tab 4 bits @tab number of records owned by this record @item heap_no @tab 13 bits @tab record's order number in heap of index page @item n_fields @tab 10 bits @tab number of fields in this record, 1 to 1023 @item 1byte_offs_flag @tab 1 bit @tab 1 if each Field Start Offsets is 1 byte long (this item is also called the "short" flag) @item @strong{next 16 bits} @tab 16 bits @tab pointer to next record in page @item @strong{TOTAL} @tab 48 bits @end multitable Total size is 48 bits, which is six bytes. @* If you're just trying to read the record, the key bit in the Extra Bytes is 1byte_offs_flag -- you need to know if 1byte_offs_flag is 1 (i.e.: "short 1-byteoffsets") or 0 (i.e.: "2-byte offsets"). @* Given a pointer to the Origin, InnoDB finds the start of the record as follows: @itemize @bullet @item Let X = n_fields (the number of fields is by definition equal to the number of entries in the Field Start Offsets Table). @item If 1byte_offs_flag equals 0, then let X = X * 2 because there are two bytes for each entry instead of just one. @item Let X = X + 6, because the fixed size of Extra Bytes is 6. @item The start of the record is at (pointer value minus X). @end itemize @subsection FIELD CONTENTS The Field Contents part of the record has all the data. Fields are stored in the order they were defined in. @* There are no markers between fields, and there is no marker or filler at the end of a record. @* Here's an example. @itemize @bullet @item I made a table with this definition: @*@* @strong{CREATE TABLE T (FIELD1 VARCHAR(3), FIELD2 VARCHAR(3), FIELD3 VARCHAR(3)) Type=InnoDB;} @*@* To understand what follows, you must know that table T has six columns -- not three -- because InnoDB automatically added three "system columns" at the start for its own housekeeping. It happens that these system columns are the row ID, the transaction ID, and the rollback pointer, but their values don't matter now. Regard them as three black boxes. @*@* @item I put some rows in the table. My last three INSERTs were: @*@* @strong{INSERT INTO T VALUES ('PP', 'PP', 'PP')} @*@* @strong{INSERT INTO T VALUES ('Q', 'Q', 'Q')} @*@* @strong{INSERT INTO T VALUES ('R', NULL, NULL)} @*@* @item I ran Borland's TDUMP to get a hexadecimal dump of the contents of \mysql\data\ibdata1, which (in my case) is the MySQL/InnoDB data file (on Windows). @end itemize Here is an extract of the dump: @multitable @columnfractions .05 .95 @item @strong{Address Values In Hexadecimal} @tab @strong{Values In ASCII} @item @code{0D4280: 00 00 2D 00 84 4F 4F 4F 4F 4F 4F 4F 4F 4F 19 17} @tab @code{..-..OOOOOOOOO..} @item @code{0D4290: 15 13 0C 06 00 00 78 0D 02 BF 00 00 00 00 04 21} @tab @code{......x........!} @item @code{0D42A0: 00 00 00 00 09 2A 80 00 00 00 2D 00 84 50 50 50} @tab @code{.....*....-..PPP} @item @code{0D42B0: 50 50 50 16 15 14 13 0C 06 00 00 80 0D 02 E1 00} @tab @code{PPP.............} @item @code{0D42C0: 00 00 00 04 22 00 00 00 00 09 2B 80 00 00 00 2D} @tab @code{....".....+....-} @item @code{0D42D0: 00 84 51 51 51 94 94 14 13 0C 06 00 00 88 0D 00} @tab @code{..QQQ...........} @item @code{0D42E0: 74 00 00 00 00 04 23 00 00 00 00 09 2C 80 00 00} @tab @code{t.....#.....,...} @item @code{0D42F0: 00 2D 00 84 52 00 00 00 00 00 00 00 00 00 00 00} @tab @code{.-..R...........} @end multitable A reformatted version of the dump, showing only the relevant bytes, looks like this (I've put a line break after each field and added labels): @strong{Reformatted Hexadecimal Dump}@* @code{ 19 17 15 13 0C 06 Field Start Offsets /* First Row */@* 00 00 78 0D 02 BF Extra Bytes@* 00 00 00 00 04 21 System Column #1@* 00 00 00 00 09 2A System Column #2@* 80 00 00 00 2D 00 84 System Column #3@* 50 50 Field1 'PP'@* 50 50 Field2 'PP'@* 50 50 Field3 'PP'}@* @code{ 16 15 14 13 0C 06 Field Start Offsets /* Second Row */@* 00 00 80 0D 02 E1 Extra Bytes@* 00 00 00 00 04 22 System Column #1@* 00 00 00 00 09 2B 80 System Column #2@* 00 00 00 2D 00 84 System Column #3@* 51 Field1 'Q'@* 51 Field2 'Q'@* 51 Field3 'Q'}@* @code{ 94 94 14 13 0C 06 Field Start Offsets /* Third Row */@* 00 00 88 0D 00 74 Extra Bytes@* 00 00 00 00 04 23 System Column #1@* 00 00 00 00 09 2C System Column #2@* 80 00 00 00 2D 00 84 System Column #3@* 52 Field1 'R'}@* @* You won't need explanation if you followed everything I've said, but I'll add helpful notes for the three trickiest details. @itemize @bullet @item Helpful Notes About "Field Start Offsets": @* Notice that the sizes of the record's fields, in forward order, are: 6, 6, 7, 2, 2, 2. Since each offset is for the start of the "next" field, the hexadecimal offsets are 06, 0c (6+6), 13 (6+6+7), 15 (6+6+7+2), 17 (6+6+7+2+2), 19 (6+6+7+2+2+2). Reversing the order, the Field Start Offsets of the first record are: @code{19,17,15,13,0c,06}. @item Helpful Notes About "Extra Bytes": @* Look at the Extra Bytes of the first record: @code{00 00 78 0D 02 BF}. The fourth byte is @code{0D hexadecimal}, which is @code{1101 binary} ... the 110 is the last bits of n_fields (@code{110 binary} is 6 which is indeed the number of fields in the record) and the final 1 bit is 1byte_offs_flag. The fifth and sixth bytes, which contain @code{02 BF}, constitute the "next" field. Looking at the original hexadecimal dump, at address @code{0D42BF} (which is position @code{02BF} within the page), you'll see the beginning bytes of System Column #1 of the second row. In other words, the "next" field points to the "Origin" of the following row. @item Helpful Notes About NULLs:@* For the third row, I inserted NULLs in FIELD2 and FIELD3. Therefore in the Field Start Offsets the top bit is @code{on} for these fields (the values are @code{94 hexadecimal}, @code{94 hexadecimal}, instead of @code{14 hexadecimal}, @code{14 hexadecimal}). And the row is shorter because the NULLs take no space. @end itemize @section Where to Look For More Information @strong{References:} @* The most relevant InnoDB source-code files are rem0rec.c, rem0rec.ic, and rem0rec.h in the rem ("Record Manager") directory. @node InnoDB Page Structure, Files in MySQL Sources, InnoDB Record Structure, Top @chapter InnoDB Page Structure InnoDB stores all records inside a fixed-size unit which is commonly called a "page" (though InnoDB sometimes calls it a "block" instead). Currently all pages are the same size, 16KB. @* A page contains records, but it also contains headers and trailers. I'll start this description with a high-altitude view of a page's parts, then I'll describe each part of a page. Finally, I'll show an example. This discussion deals only with the most common format, for the leaf page of a data file. @* @section High-Altitude View An InnoDB page has seven parts: @itemize @bullet @item Fil Header @item Page Header @item Infimum + Supremum Records @item User Records @item Free Space @item Page Directory @item Fil Trailer @end itemize As you can see, a page has two header/trailer pairs. The inner pair, "Page Header" and "Page Directory", are mostly the concern of the \page program group, while the outer pair, "Fil Header" and "Fil Trailer", are mostly the concern of the \fil program group. The "Fil" header also goes goes by the name of "File Page Header". @* Sandwiched between the headers and trailers, are the records and the free (unused) space. A page always begins with two unchanging records called the Infimum and the Supremum. Then come the user records. Between the user records (which grow downwards) and the page directory (which grows upwards) there is space for new records. @* @subsection Fil Header The Fil Header has eight parts, as follows: @multitable @columnfractions .10 .30 .35 @item @strong{Name} @tab @strong{Size} @tab @strong{Remarks} @item FIL_PAGE_SPACE @tab 4 @tab 4 ID of the space the page is in @item FIL_PAGE_OFFSET @tab 4 @tab ordinal page number from start of space @item FIL_PAGE_PREV @tab 4 @tab offset of previous page in key order @item FIL_PAGE_NEXT @tab 4 @tab offset of next page in key order @item FIL_PAGE_LSN @tab 8 @tab log serial number of page's latest log record @item FIL_PAGE_TYPE @tab 2 @tab current defined types are: FIL_PAGE_INDEX, FIL_PAGE_UNDO_LOG, FIL_PAGE_INODE, FIL_PAGE_IBUF_FREE_LIST @item FIL_PAGE_FILE_FLUSH_LSN @tab 8 @tab "the file has been flushed to disk at least up to this lsn" (log serial number), valid only on the first page of the file @item FIL_PAGE_ARCH_LOG_NO @tab 4 @tab the latest archived log file number at the time that FIL_PAGE_FILE_FLUSH_LSN was written (in the log) @end multitable @itemize @item FIL_PAGE_SPACE is a necessary identifier because different pages might belong to different (table) spaces within the same file. The word "space" is generic jargon for either "log" or "tablespace". @*@* @item FIL_PAGE_PREV and FIL_PAGE_NEXT are the page's "backward" and "forward" pointers. To show what they're about, I'll draw a two-level B-tree. @*@* @example -------- - root - -------- | ---------------------- | | | | -------- -------- - leaf - <--> - leaf - -------- -------- @end example @* Everyone has seen a B-tree and knows that the entries in the root page point to the leaf pages. (I indicate those pointers with vertical '|' bars in the drawing.) But sometimes people miss the detail that leaf pages can also point to each other (I indicate those pointers with a horizontal two-way pointer '<-->' in the drawing). This feature allows InnoDB to navigate from leaf to leaf without having to back up to the root level. This is a sophistication which you won't find in the classic B-tree, which is why InnoDB should perhaps be called a B+-tree instead. @*@* @item The fields FIL_PAGE_FILE_FLUSH_LSN, FIL_PAGE_PREV, and FIL_PAGE_NEXT all have to do with logs, so I'll refer you to my article "How Logs Work With MySQL And InnoDB" on devarticles.com. @*@* @item FIL_PAGE_FILE_FLUSH_LSN and FIL_PAGE_ARCH_LOG_NO are only valid for the first page of a data file. @end itemize @subsection Page Header The Page Header has 14 parts, as follows: @*@* @multitable @columnfractions .10 .20 .30 @item @strong{Name} @tab @strong{Size} @tab @strong{Remarks} @item PAGE_N_DIR_SLOTS @tab 2 @tab number of directory slots in the Page Directory part; initial value = 2 @item PAGE_HEAP_TOP @tab 2 @tab record pointer to first record in heap @item PAGE_N_HEAP @tab 2 @tab number of heap records; initial value = 2 @item PAGE_FREE @tab 2 @tab record pointer to first free record @item PAGE_GARBAGE @tab 2 @tab "number of bytes in deleted records" @item PAGE_LAST_INSERT @tab 2 @tab record pointer to the last inserted record @item PAGE_DIRECTION @tab 2 @tab either PAGE_LEFT, PAGE_RIGHT, or PAGE_NO_DIRECTION @item PAGE_N_DIRECTION @tab 2 @tab number of consecutive inserts in the same direction, e.g. "last 5 were all to the left" @item PAGE_N_RECS @tab 2 @tab number of user records @item PAGE_MAX_TRX_ID @tab 8 @tab the highest ID of a transaction which might have changed a record on the page (only set for secondary indexes) @item PAGE_LEVEL @tab 2 @tab level within the index (0 for a leaf page) @item PAGE_INDEX_ID @tab 8 @tab identifier of the index the page belongs to @item PAGE_BTR_SEG_LEAF @tab 10 @tab "file segment header for the leaf pages in a B-tree" (this is irrelevant here) @item PAGE_BTR_SEG_TOP @tab 10 @tab "file segment header for the non-leaf pages in a B-tree" (this is irrelevant here) @end multitable @* (Note: I'll clarify what a "heap" is when I discuss the User Records part of the page.) @*@* Some of the Page Header parts require further explanation: @itemize @bullet @item PAGE_FREE: @* Records which have been freed (due to deletion or migration) are in a one-way linked list. The PAGE_FREE pointer in the page header points to the first record in the list. The "next" pointer in the record header (specifically, in the record's Extra Bytes) points to the next record in the list. @item PAGE_DIRECTION and PAGE_N_DIRECTION: @* It's useful to know whether inserts are coming in a constantly ascending sequence. That can affect InnoDB's efficiency. @item PAGE_HEAP_TOP and PAGE_FREE and PAGE_LAST_INSERT: @* Warning: Like all record pointers, these point not to the beginning of the record but to its Origin (see the earlier discussion of Record Structure). @item PAGE_BTR_SEG_LEAF and PAGE_BTR_SEG_TOP: @* These variables contain information (space ID, page number, and byte offset) about index node file segments. InnoDB uses the information for allocating new pages. There are two different variables because InnoDB allocates separately for leaf pages and upper-level pages. @end itemize @subsection The Infimum And Supremum Records "Infimum" and "supremum" are real English words but they are found only in arcane mathematical treatises, and in InnoDB comments. To InnoDB, an infimum is lower than the the lowest possible real value (negative infinity) and a supremum is greater than the greatest possible real value (positive infinity). InnoDB sets up an infimum record and a supremum record automatically at page-create time, and never deletes them. They make a useful barrier to navigation so that "get-prev" won't pass the beginning and "get-next" won't pass the end. Also, the infimum record can be a dummy target for temporary record locks. @*@* The InnoDB code comments distinguish between "the infimum and supremum records" and the "user records" (all other kinds). @*@* It's sometimes unclear whether InnoDB considers the infimum and supremum to be part of the header or not. Their size is fixed and their position is fixed, so I guess so. @subsection User Records In the User Records part of a page, you'll find all the records that the user inserted. @*@* There are two ways to navigate through the user records, depending whether you want to think of their organization as an unordered or an ordered list. @*@* An unordered list is often called a "heap". If you make a pile of stones by saying "whichever one I happen to pick up next will go on top" -- rather than organizing them according to size and colour -- then you end up with a heap. Similarly, InnoDB does not want to insert new rows according to the B-tree's key order (that would involve expensive shifting of large amounts of data), so it inserts new rows right after the end of the existing rows (at the top of the Free Space part) or wherever there's space left by a deleted row. @*@* But by definition the records of a B-tree must be accessible in order by key value, so there is a record pointer in each record (the "next" field in the Extra Bytes) which points to the next record in key order. In other words, the records are a one-way linked list. So InnoDB can access rows in key order when searching. @subsection Free Space I think it's clear what the Free Space part of a page is, from the discussion of other parts. @subsection Page Directory The Page Directory part of a page has a variable number of record pointers. Sometimes the record pointers are called "slots" or "directory slots". Unlike other DBMSs, InnoDB does not have a slot for every record in the page. Instead it keeps a sparse directory. In a fullish page, there will be one slot for every six records. @*@* The slots track the records' logical order (the order by key rather than the order by placement on the heap). Therefore, if the records are @code{'A' 'B' 'F' 'D'} the slots will be @code{(pointer to 'A') (pointer to 'B') (pointer to 'D') (pointer to 'F')}. Because the slots are in key order, and each slot has a fixed size, it's easy to do a binary search of the records on the page via the slots. @*@* (Since the Page Directory does not have a slot for every record, binary search can only give a rough position and then InnoDB must follow the "next" record pointers. InnoDB's "sparse slots" policy also accounts for the n_owned field in the Extra Bytes part of a record: n_owned indicates how many more records must be gone through because they don't have their own slots.) @subsection Fil Trailer The Fil Trailer has one part, as follows: @*@* @multitable @columnfractions .10 .35 .40 @item @strong{Name} @tab @strong{Size} @tab @strong{Remarks} @item FIL_PAGE_END_LSN @tab 8 @tab low 4 bytes = checksum of page, last 4 bytes = same as FIL_PAGE_LSN @end multitable @* The final part of a page, the fil trailer (or File Page Trailer), exists because InnoDB's architect worried about integrity. It's impossible for a page to be only half-written, or corrupted by crashes, because the log-recovery mechanism restores to a consistent state. But if something goes really wrong, then it's nice to have a checksum, and to have a value at the very end of the page which must be the same as a value at the very beginning of the page. @section Example For this example, I used Borland's TDUMP again, as I did for the earlier chapter on Record Format. This is what a page looked like: @*@* @multitable @columnfractions .05 .95 @item @strong{Address Values In Hexadecimal} @tab @strong{Values In ASCII} @item @code{0D4000: 00 00 00 00 00 00 00 35 FF FF FF FF FF FF FF FF} @tab @code{.......5........} @item @code{0D4010: 00 00 00 00 00 00 E2 64 45 BF 00 00 00 00 00 00} @tab @code{.......dE.......} @item @code{0D4020: 00 00 00 00 00 00 00 05 02 F5 00 12 00 00 00 00} @tab @code{................} @item @code{0D4030: 02 E1 00 02 00 0F 00 10 00 00 00 00 00 00 00 00} @tab @code{................} @item @code{0D4040: 00 00 00 00 00 00 00 00 00 14 00 00 00 00 00 00} @tab @code{................} @item @code{0D4050: 00 02 16 B2 00 00 00 00 00 00 00 02 15 F2 08 01} @tab @code{................} @item @code{0D4060: 00 00 03 00 89 69 6E 66 69 6D 75 6D 00 09 05 00} @tab @code{.....infimum....} @item @code{0D4070: 08 03 00 00 73 75 70 72 65 6D 75 6D 00 22 1D 18} @tab @code{....supremum."..} @item @code{0D4080: 13 0C 06 00 00 10 0D 00 B7 00 00 00 00 04 14 00} @tab @code{................} @item @code{0D4090: 00 00 00 09 1D 80 00 00 00 2D 00 84 41 41 41 41} @tab @code{.........-..AAAA} @item @code{0D40A0: 41 41 41 41 41 41 41 41 41 41 41 1F 1B 17 13 0C} @tab @code{AAAAAAAAAAA.....} @item @code{ ... } @item @code{ ... } @item @code{0D7FE0: 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 74} @tab @code{...............t} @item @code{0D7FF0: 02 47 01 AA 01 0A 00 65 3A E0 AA 71 00 00 E2 64} @tab @code{.G.....e:..q...d} @end multitable @*@* Let's skip past the first 38 bytes, which are Fil Header. The bytes of the Page Header start at location @code{0d4026 hexadecimal}: @*@* @multitable @columnfractions .10 .45 .60 @item @strong{Location} @tab @strong{Name} @tab @strong{Description} @item @code{00 05} @tab PAGE_N_DIR_SLOTS @tab There are 5 directory slots. @item @code{02 F5} @tab PAGE_HEAP_TOP @tab At location @code{0402F5}, not shown, is the beginning of free space. Maybe a better name would have been PAGE_HEAP_END @item @code{00 12} @tab PAGE_N_HEAP @tab There are 18 (hexadecimal 12) records in the page. @item @code{00 00} @tab PAGE_FREE @tab There are zero free (deleted) records. @item @code{00 00} @tab PAGE_GARBAGE @tab There are zero bytes in deleted records. @item @code{02 E1} @tab PAGE_LAST_INSERT @tab The last record was inserted at location @code{02E1}, not shown, within the page. @item @code{00 02} @tab PAGE_DIRECTION @tab A glance at page0page.h will tell you that 2 is the #defined value for PAGE_RIGHT. @item @code{00 0F} @tab PAGE_N_DIRECTION @tab The last 15 (hexadecimal 0F) inserts were all done "to the right" because I was inserting in ascending order. @item @code{00 10} @tab PAGE_N_RECS @tab There are 16 (hexadecimal 10) user records. Notice that PAGE_N_RECS is smaller than the earlier field, PAGE_N_HEAP. @item @code{00 00 00 00 00 00 00} @tab PAGE_MAX_TRX_ID @item @code{00 00} @tab PAGE_LEVEL @tab Zero because this is a leaf page. @item @code{00 00 00 00 00 00 00 14} @tab PAGE_INDEX_ID @tab This is index number 20. @item @code{00 00 00 00 00 00 00 02 16 B2} @tab PAGE_BTR_SEG_LEAF @item @code{00 00 00 00 00 00 00 02 15 F2} @tab PAGE_BTR_SEG_TOP @end multitable @* Immediately after the page header are the infimum and supremum records. Looking at the "Values In ASCII" column in the hexadecimal dump, you will see that the contents are in fact the words "infimum" and "supremum" respectively. @*@* Skipping past the User Records and the Free Space, many bytes later, is the end of the 16KB page. The values shown there are the two trailers. @itemize @bullet @item The first trailer (@code{00 74, 02 47, 01 AA, 01 0A, 00 65}) is the page directory. It has 5 entries, because the header field PAGE_N_DIR_SLOTS says there are 5. @item The next trailer (@code{3A E0 AA 71, 00 00 E2 64}) is the fil trailer. Notice that the last four bytes, @code{00 00 E2 64}, appeared before in the fil header. @end itemize @section Where to Look For More Information @strong{References:} @* The most relevant InnoDB source-code files are page0page.c, page0page.ic, and page0page.h in \page directory. @node Files in MySQL Sources, Files in InnoDB Sources, InnoDB Page Structure, Top @chapter Annotated List Of Files in the MySQL Source Code Distribution This is a description of the files that you get when you download the source code of MySQL. This description begins with a list of the main directories and a short comment about each one. Then, for each directory, in alphabetical order, a longer description is supplied. When a directory contains significant program files, a list of each C program is given along with an explanation of its intended function. @section Directory Listing @strong{Directory -- Short Comment} @itemize @bullet @item bdb -- The Berkeley Database table handler @item BitKeeper -- BitKeeper administration (not part of the source distribution) @item BUILD -- Frequently used build scripts @item Build-tools -- Build tools (not part of the source distribution) @item client -- Client library @item cmd-line-utils -- Command-line utilities (libedit and readline) @item dbug -- Fred Fish's dbug library @item Docs -- Preliminary documents about internals and new modules; will eventually be moved to the mysqldoc repository @item extra -- Some minor standalone utility programs @item heap -- The HEAP table handler @item include -- Header (*.h) files for most libraries; includes all header files distributed with the MySQL binary distribution @item innobase -- The Innobase (InnoDB) table handler @item libmysql -- For producing MySQL as a library (e.g. a Windows .DLL) @item libmysql_r -- For building a thread-safe libmysql library @item libmysqld -- The MySQL Server as an embeddable library @item man -- Some user-contributed manual pages @item myisam -- The MyISAM table handler @item myisammrg -- The MyISAM Merge table handler @item mysql-test -- A test suite for mysqld @item mysys -- MySQL system library (Low level routines for file access etc.) @item netware -- Files related to the Novell NetWare version of MySQL @item NEW-RPMS -- Directory to place RPMs while making a distribution @item os2 -- Routines for working with the OS/2 operating system @item pstack -- Process stack display (not currently used) @item regex -- Henry Spencer's Regular Expression library for support of REGEXP function @item SCCS -- Source Code Control System (not part of source distribution) @item scripts -- SQL batches, e.g. mysqlbug and mysql_install_db @item sql -- Programs for handling SQL commands; the "core" of MySQL @item sql-bench -- The MySQL benchmarks @item SSL -- Secure Sockets Layer; includes an example certification one can use to test an SSL (secure) database connection @item strings -- Library for C string routines, e.g. atof, strchr @item support-files -- Files used to build MySQL on different systems @item tests -- Tests in Perl and in C @item tools -- mysqlmanager.c (tool under development, not yet useful) @item VC++Files -- Includes this entire directory, repeated for VC++ (Windows) use @item vio -- Virtual I/O Library @item zlib -- Data compression library, used on Windows @end itemize @subsection bdb The Berkeley Database table handler. @*@* The Berkeley Database (BDB) is maintained by Sleepycat Software. MySQL AB maintains only a few small patches to make BDB work better with MySQL. @*@* The documentation for BDB is available at http://www.sleepycat.com/docs/. Since it's reasonably thorough documentation, a description of the BDB program files is not included in this document. @*@* @subsection BitKeeper BitKeeper administration. @*@* Bitkeeper administration is not part of the source distribution. This directory may be present if you downloaded the MySQL source using BitKeeper rather than via the mysql.com site. The files in the BitKeeper directory are for maintenance purposes only -- they are not part of the MySQL package. @*@* The MySQL Reference Manual explains how to use Bitkeeper to get the MySQL source. Please see @url{http://www.mysql.com/doc/en/Installing_source_tree.html} for more information. @*@* @subsection BUILD Frequently used build scripts. @*@* This directory contains the build switches for compilation on various platforms. There is a subdirectory for each set of options. The main ones are: @itemize @bullet @item alpha @item ia64 @item pentium (with and without debug or bdb, etc.) @item solaris @end itemize @*@* @subsection Build-tools Build tools. @*@* Build-tools is not part of the source distribution. This directory contains batch files for extracting, making directories, and making programs from source files. There are several subdirectories with different scripts -- for building Linux executables, for compiling, for performing all build steps, and so on. @*@* @subsection client Client library. @*@* The client library includes mysql.cc (the source of the 'mysql' executable) and other utilities. Most of the utilities are mentioned in the MySQL Reference Manual. Generally these are standalone C programs which one runs in "client mode", that is, they call the server. @*@* The C program files in the directory are: @itemize @bullet @item get_password.c -- ask for a password from the console @item mysql.cc -- "The MySQL command tool" @item mysqladmin.c -- maintenance of MySQL databases @item mysqlcheck.c -- check all databases, check connect, etc. @item mysqldump.c -- dump table's contents as SQL statements, suitable to backup a MySQL database @item mysqlimport.c -- import text files in different formats into tables @item mysqlmanager-pwgen.c -- pwgen stands for "password generation" (not currently maintained) @item mysqlmanagerc.c -- entry point for mysql manager (not currently maintained) @item mysqlshow.c -- show databases, tables or columns @item mysqltest.c -- test program used by the mysql-test suite, mysql-test-run @item password.c -- password checking routines (version 4.1 and up) @end itemize @*@* @subsection cmd-line-utils Command-line utilities (libedit and readline). @*@* There are two subdirectories: \readline and \libedit. All the files here are "non-MySQL" files, in the sense that MySQL AB didn't produce them, it just uses them. It should be unnecessary to study the programs in these files unless you are writing or debugging a tty-like client for MySQL, such as mysql.exe. @*@* The \readline subdirectory contains the files of the GNU Readline Library, "a library for reading lines of text with interactive input and history editing". The programs are copyrighted by the Free Software Foundation. @*@* The \libedit (library of edit functions) subdirectory has files written by Christos Zoulas. They are distributed and modifed under the BSD License. These files are for editing the line contents. @*@* These are the program files in the \libedit subdirectory: @itemize @bullet @item chared.c -- character editor @item common.c -- common editor functions @item el.c -- editline interface functions @item emacs.c -- emacs functions @item fgetln.c -- get line @item hist.c -- history access functions @item history.c -- more history access functions @item key.c -- procedures for maintaining the extended-key map @item map.c -- editor function definitions @item parse.c -- parse an editline extended command @item prompt.c -- prompt printing functions @item read.c -- terminal read functions @item readline.c -- read line @item refresh.c -- "lower level screen refreshing functions" @item search.c -- "history and character search functions" @item sig.c -- for signal handling @item strlcpy.c -- string copy @item term.c -- "editor/termcap-curses interface" @item tokenizer.c -- Bourne shell line tokenizer @item tty.c -- for a tty interface @item vi.c -- commands used when in the vi (editor) mode @end itemize @*@* @subsection dbug Fred Fish's dbug library. @*@* This is not really part of the MySQL package. Rather, it's a set of public-domain routines which are useful for debugging MySQL programs. The MySQL Server and all .c and .cc programs support the use of this package. @*@* How it works: One inserts a function call that begins with DBUG_* in one of the regular MYSQL programs. For example, in get_password.c, you will find this line: @* DBUG_ENTER("get_tty_password"); @* at the start of a routine, and this line: @* DBUG_RETURN(my_strdup(to,MYF(MY_FAE))); @* at the end of the routine. These lines don't affect production code. Features of the dbug library include extensive reporting and profiling (the latter has not been used by the MySQL team). @*@* The C programs in this directory are: @itemize @bullet @item dbug.c -- The main module @item dbug_analyze.c -- Reads a file produced by trace functions @item example1.c -- A tiny example @item example2.c -- A tiny example @item example3.c -- A tiny example @item factorial.c -- A tiny example @item main.c -- A tiny example @item sanity.c -- Declaration of a variable @end itemize @*@* @subsection Docs Preliminary documents about internals and new modules, which will eventually be moved to the mysqldoc repository. @*@* This directory doesn't have much at present that's very useful to the student, but the plan is that some documentation related to the source files and the internal workings of MySQL, including perhaps some documentation from developers themselves, will be placed here. Files in this directory will eventually be moved to the MySQL documentation repository. @*@* These sub-directories are part of this directory: @itemize @bullet @item books -- .gif images and empty .txt files; no real information @item flags -- images of flags of countries @item images -- flag backgrounds and the MySQL dolphin logo @item mysql-logos -- more MySQL-related logos, some of them moving @item raw-flags -- more country flags, all .gif files @item support -- various files for generating texinfo/docbook documentation @item to-be-included... -- contains a MySQL-for-dummies file @item translations -- some Portuguese myodbc documentation @end itemize @*@* In the main directory, you'll find some .txt files related to the methods that MySQL uses to produce its printed and html documents, odd bits in various languages, and the single file in the directory which has any importance -- internals.texi -- The "MySQL Internals" document. @*@* Despite the name, internals.texi is not yet much of a description of MySQL internals although work is in progress to make it so. However, there is some useful description of the functions in the mysys directory (see below), and of the structure of client/server messages (doubtless very useful for eople who want to make their own JDBC drivers, or just sniff). @*@* @subsection extra Some minor standalone utility programs. @*@* These programs are all standalone utilities, that is, they have a main() function and their main role is to show information that the MySQL server needs or produces. Most are unimportant. They are as follows: @itemize @bullet @item my_print_defaults.c -- print parameters from my.ini files. Can also be used in scripts to enable processing of my.ini files. @item mysql_waitpid.c -- wait for a program to terminate. Useful for shell scripts when one needs to wait until a process terminates. @item perror.c -- "print error" -- given error number, display message @item replace.c -- replace strings in text files or pipe @item resolve_stack_dump.c -- show symbolic information from a MySQL stack dump, normally found in the mysql.err file @item resolveip.c -- convert an IP address to a hostname, or vice versa @end itemize @*@* @subsection heap The HEAP table handler. @*@* All the MySQL table handlers (i.e. the handlers that MySQL itself produces) have files with similar names and functions. Thus, this (heap) directory contains a lot of duplication of the myisam directory (for the MyISAM table handler). Such duplicates have been marked with an "*" in the following list. For example, you will find that \heap\hp_extra.c has a close equivalent in the myisam directory (\myisam\mi_extra.c) with the same descriptive comment. (Some of the differences arise because HEAP has different structures. HEAP does not need to use the sort of B-tree indexing that ISAM and MyISAM use; instead there is a hash index. Most importantly, HEAP is entirely in memory. File-I/O routines lose some of their vitality in such a context.) @*@* @itemize @item hp_block.c -- Read/write a block (i.e. a page) @item hp_clear.c -- Remove all records in the table @item hp_close.c -- * close database @item hp_create.c -- * create a table @item hp_delete.c -- * delete a row @item hp_extra.c -- * for setting options and buffer sizes when optimizing @item hp_hash.c -- Hash functions used for saving keys @item hp_info.c -- * Information about database status @item hp_open.c -- * open database @item hp_panic.c -- * the hp_panic routine, for shutdowns and flushes @item hp_rename.c -- * rename a table @item hp_rfirst.c -- * read first row through a specific key (very short) @item hp_rkey.c -- * read record using a key @item hp_rlast.c -- * read last row with same key as previously-read row @item hp_rnext.c -- * read next row with same key as previously-read row @item hp_rprev.c -- * read previous row with same key as previously-read row @item hp_rrnd.c -- * read a row based on position @item hp_rsame.c -- * find current row using positional read or key-based read @item hp_scan.c -- * read all rows sequentially @item hp_static.c -- * static variables (very short) @item hp_test1.c -- * testing basic functions @item hp_test2.c -- * testing database and storing results @item hp_update.c -- * update an existing row @item hp_write.c -- * insert a new row @end itemize @*@* There are fewer files in the heap directory than in the myisam directory, because fewer are necessary. For example, there is no need for a \myisam\mi_cache.c equivalent (to cache reads) or a \myisam\log.c equivalent (to log statements). @*@* @subsection include Header (*.h) files for most libraries; includes all header files distributed with the MySQL binary distribution. @*@* These files may be included in C program files. Note that each individual directory will also have its own *.h files, for including in its own *.c programs. The *.h files in the include directory are ones that might be included from more than one place. @*@* For example, the mysys directory contains a C file named rijndael.c, but does not include rijndael.h. The include directory contains rijndael.h. Looking further, you'll find that rijndael.h is also included in other places: by my_aes.c and my_aes.h. @*@* The include directory contains 51 *.h (header) files. @*@* @subsection innobase The Innobase (InnoDB) table handler. @*@* A full description of these files can be found elsewhere in this document. @*@* @subsection libmysql The MySQL Library, Part 1. @*@* The files here are for producing MySQL as a library (e.g. a Windows DLL). The idea is that, instead of producing separate mysql (client) and mysqld (server) programs, one produces a library. Instead of sending messages, the client part merely calls the server part. @*@* The libmysql files are split into three directories: libmysql (this one), libmysql_r (the next one), and libmysqld (the next one after that). @*@* The "library of mysql" has some client-connection modules. For example, as described in an earlier section of this manual, there is a discussion of libmysql/libmysql.c which sends packets from the client to the server. Many of the entries in the libmysql directory (and in the following libmysqld directory) are 'symlinks' on Linux, that is, they are in fact pointers to files in other directories. @*@* The program files on this directory are: @itemize @bullet @item conf_to_src.c -- has to do with charsets @item dll.c -- initialization of the dll library @item errmsg.c -- English error messages, compare \mysys\errors.c @item get_password.c -- get password @item libmysql.c -- the code that implements the MySQL API, i.e. the functions a client that wants to connect to MySQL will call @item manager.c -- initialize/connect/fetch with MySQL manager @end itemize @*@* @subsection libmysql_r The MySQL Library, Part 2. @*@* There is only one file here, used to build a thread-safe libmysql library: @itemize @bullet @item makefile.am @end itemize @*@* @subsection libmysqld The MySQL library, Part 3. @*@* The Embedded MySQL Server Library. The product of libmysqld is not a client/server affair, but a library. There is a wrapper to emulate the client calls. The program files on this directory are: @itemize @bullet @item libmysqld.c -- The called side, compare the mysqld.exe source @item lib_vio.c -- Emulate the vio directory's communication buffer @end itemize @*@* @subsection man Some user-contributed manual pages @*@* These are user-contributed "man" (manual) pages in a special markup format. The format is described in a document with a heading like "man page for man" or "macros to format man pages" which you can find in a Linux directory or on the Internet. @*@* @subsection myisam The MyISAM table handler. @*@* The C files in this subdirectory come in six main groups: @itemize @bullet @item ft*.c files -- ft stands for "Full Text", code contributed by Sergei Golubchik @item mi*.c files -- mi stands for "My Isam", these are the main programs for Myisam @item myisam*.c files -- for example, "myisamchk" utility routine functions source @item rt*.c files -- rt stands for "rtree", some code was written by Alexander Barkov @item sp*.c files -- sp stands for "spatial", some code was written by Ramil Kalimullin @item sort.c -- this is a single file that sorts keys for index-create purposes @end itemize @*@* The "full text" and "rtree" and "spatial" program sets are for special purposes, so this document focuses only on the mi*.c "myisam" C programs. They are: @itemize @bullet @item mi_cache.c -- for reading records from a cache @item mi_changed.c -- a single routine for setting a "changed" flag (very short) @item mi_check.c -- for checking and repairing tables. Used by the myisamchk program and by the MySQL server. @item mi_checksum.c -- calculates a checksum for a row @item mi_close.c -- close database @item mi_create.c -- create a table @item mi_dbug.c -- support routines for use with "dbug" (see \dbug description) @item mi_delete.c -- delete a row @item mi_delete_all.c -- delete all rows @item mi_delete_table.c -- delete a table (very short) @item mi_dynrec.c -- functions to handle space-packed records and blobs @item mi_extra.c -- setting options and buffer sizes when optimizing @item mi_info.c -- return useful base information for an open table @item mi_key.c -- for handling keys @item mi_locking.c -- lock database @item mi_log.c -- save commands in a log file which myisamlog program can read. Can be used to exactly replay a set of changes to a table. @item mi_open.c -- open database @item mi_packrec.c -- read from a data file compresed with myisampack @item mi_page.c -- read and write pages containing keys @item mi_panic.c -- the mi_panic routine, probably for sudden shutdowns @item mi_range.c -- approximate count of how many records lie between two keys @item mi_rename.c -- rename a table @item mi_rfirst.c -- read first row through a specific key (very short) @item mi_rkey.c -- read a record using a key @item mi_rlast.c -- read last row with same key as previously-read row @item mi_rnext.c -- read next row with same key as previously-read row @item mi_rnext_same.c -- same as mi_rnext.c, but abort if the key changes @item mi_rprev.c -- read previous row with same key as previously-read row @item mi_rrnd.c -- read a row based on position @item mi_rsame.c -- find current row using positional read or key-based read @item mi_rsamepos.c -- positional read @item mi_scan.c -- read all rows sequentially @item mi_search.c -- key-handling functions @item mi_static.c -- static variables (very short) @item mi_statrec.c -- functions to handle fixed-length records @item mi_test1.c -- testing basic functions @item mi_test2.c -- testing database and storing results @item mi_test3.c -- testing locking @item mi_unique.c -- functions to check if a row is unique @item mi_update.c -- update an existing row @item mi_write.c -- insert a new row @end itemize @*@* @subsection myisammrg MyISAM Merge table handler. @*@* As with other table handlers, you'll find that the *.c files in the myissammrg directory have counterparts in the myisam directory. In fact, this general description of a myisammrg program is almost always true: The myisammrg function checks an argument, the myisammrg function formulates an expression for passing to a myisam function, the myisammrg calls a myisam function, the myisammrg function returns. @*@* These are the 21 files in the myisammrg directory, with notes about the myisam functions or programs they're connected with: @itemize @bullet @item myrg_close.c -- mi_close.c @item myrg_create.c -- mi_create.c @item myrg_delete.c -- mi_delete.c / delete last-read record @item myrg_extra.c -- mi_extra.c / "extra functions we want to do ..." @item myrg_info.c -- mi_info.c / display information about a mymerge file @item myrg_locking.c -- mi_locking.c / lock databases @item myrg_open.c -- mi_open.c / open a MyISAM MERGE table @item myrg_panic.c -- mi_panic.c / close in a hurry @item myrg_queue.c -- read record based on a key @item myrg_range.c -- mi_range.c / find records in a range @item myrg_rfirst.c -- mi_rfirst.c / read first record according to specific key @item myrg_rkey.c -- mi_rkey.c / read record based on a key @item myrg_rlast.c -- mi_rlast.c / read last row with same key as previous read @item myrg_rnext.c -- mi_rnext.c / read next row with same key as previous read @item myrg_rnext_same.c -- mi_rnext_same.c / read next row with same key @item myrg_rprev.c -- mi_rprev.c / read previous row with same key @item myrg_rrnd.c -- mi_rrnd.c / read record with random access @item myrg_rsame.c -- mi_rsame.c / call mi_rsame function, see \myisam\mi_rsame.c @item myrg_static.c -- mi_static.c / static variable declaration @item myrg_update.c -- mi_update.c / call mi_update function, see \myisam\mi_update.c @item myrg_write.c -- mi_write.c / call mi_write function, see \myisam\mi_write.c @end itemize @*@* @subsection mysql-test A test suite for mysqld. @*@* The directory has a README file which explains how to run the tests, how to make new tests (in files with the filename extension "*.test"), and how to report errors. @*@* There are four subdirectories: @itemize @bullet @item \misc -- contains one minor Perl program @item \r -- contains *.result, i.e. "what happened" files and *.required, i.e. "what should happen" file @item \std_data -- contains standard data for input to tests @item \t -- contains tests @end itemize @*@* There are 186 *.test files in the \t subdirectory. Primarily these are SQL scripts which try out a feature, output a result, and compare the result with what's required. Some samples of what the test files check are: latin1_de comparisons, date additions, the HAVING clause, outer joins, openSSL, load data, logging, truncate, and UNION. @*@* There are other tests in these directories: @itemize @bullet @item sql-bench @item tests @end itemize @subsection mysys MySQL system library. Low level routines for file access and so on. @*@* There are 115 *.c programs in this directory: @itemize @bullet @item array.c -- Dynamic array handling @item charset.c -- Using dynamic character sets, set default character set, ... @item charset2html.c -- Check what character set a browser is using @item checksum.c -- Calculate checksum for a memory block, used for pack_isam @item default.c -- Find defaults from *.cnf or *.ini files @item errors.c -- English text of global errors @item hash.c -- Hash search/compare/free functions "for saving keys" @item list.c -- Double-linked lists @item make-conf.c -- "Make a charset .conf file out of a ctype-charset.c file" @item md5.c -- MD5 ("Message Digest 5") algorithm from RSA Data Security @item mf_brkhant.c -- Prevent user from doing a Break during critical execution (not used in MySQL; can be used by standalone MyISAM applications) @item mf_cache.c -- "Open a temporary file and cache it with io_cache" @item mf_dirname.c -- Parse/convert directory names @item mf_fn_ext.c -- Get filename extension @item mf_format.c -- Format a filename @item mf_getdate.c -- Get date, return in yyyy-mm-dd hh:mm:ss format @item mf_iocache.c -- Cached read/write of files in fixed-size units @item mf_iocache2.c -- Continuation of mf_iocache.c @item mf_keycache.c -- Key block caching for certain file types @item mf_loadpath.c -- Return full path name (no ..\ stuff) @item mf_pack.c -- Packing/unpacking directory names for create purposes @item mf_path.c -- Determine where a program can find its files @item mf_qsort.c -- Quicksort @item mf_qsort2.c -- Quicksort, part 2 (allows the passing of an extra argument to the sort-compare routine) @item mf_radix.c -- Radix sort @item mf_same.c -- Determine whether filenames are the same @item mf_sort.c -- Sort with choice of Quicksort or Radix sort @item mf_soundex.c -- Soundex algorithm derived from EDN Nov. 14, 1985 (pg. 36) @item mf_strip.c -- Strip trail spaces from a string @item mf_tempdir.c -- Initialize/find/free temporary directory @item mf_tempfile.c -- Create a temporary file @item mf_unixpath.c -- Convert filename to UNIX-style filename @item mf_util.c -- Routines, #ifdef'd, which may be missing on some machines @item mf_wcomp.c -- Comparisons with wildcards @item mf_wfile.c -- Finding files with wildcards @item mulalloc.c -- Malloc many pointers at the same time @item my_aes.c -- AES encryption @item my_alarm.c -- Set a variable value when an alarm is received @item my_alloc.c -- malloc of results which will be freed simultaneously @item my_append.c -- one file to another @item my_bit.c -- smallest X where 2^X >= value, maybe useful for divisions @item my_bitmap.c -- Handle uchar arrays as large bitmaps @item my_chsize.c -- Truncate file if shorter, else fill with a filler character @item my_clock.c -- Time-of-day ("clock()") function, with OS-dependent #ifdef's @item my_compress.c -- Compress packet (see also description of \zlib directory) @item my_copy.c -- Copy files @item my_create.c -- Create file @item my_delete.c -- Delete file @item my_div.c -- Get file's name @item my_dup.c -- Open a duplicated file @item my_error.c -- Return formatted error to user @item my_fopen.c -- File open @item my_fstream.c -- Streaming file read/write @item my_getwd.c -- Get working directory @item my_gethostbyname.c -- Thread-safe version of standard net gethostbyname() func @item my_getopt.c -- Find out what options are in effect @item my_handler.c -- Compare two keys in various possible formats @item my_init.c -- Initialize variables and functions in the mysys library @item my_lib.c -- Compare/convert directory names and file names @item my_lock.c -- Lock part of a file @item my_lockmem.c -- "Allocate a block of locked memory" @item my_lread.c -- Read a specified number of bytes from a file into memory @item my_lwrite.c -- Write a specified number of bytes from memory into a file @item my_malloc.c -- Malloc (memory allocate) and dup functions @item my_messnc.c -- Put out a message on stderr with "no curses" @item my_mkdir.c -- Make directory @item my_net.c -- Thread-safe version of net inet_ntoa function @item my_netware.c -- Functions used only with the Novell Netware version of MySQL @item my_once.c -- Allocation / duplication for "things we don't need to free" @item my_open.c -- Open a file @item my_os2cond.c -- OS2-specific: "A simple implementation of posix conditions" @item my_os2dirsrch.c -- OS2-specific: Emulate a Win32 directory search @item my_os2dlfcn.c -- OS2-specific: Emulate UNIX dynamic loading @item my_os2file64.c -- OS2-specific: For File64bit setting @item my_os2mutex.c -- OS2-specific: For mutex handling @item my_os2thread.c -- OS2-specific: For thread handling @item my_os2tls.c -- OS2-specific: For thread-local storage @item my_port.c -- OS/machine-dependent porting functions, e.g. AIX-specific my_ulonglong2double() @item my_pread.c -- Read a specified number of bytes from a file @item my_pthread.c -- A wrapper for thread-handling functions in different OSs @item my_quick.c -- Read/write (labelled a "quicker" interface, perhaps obsolete) @item my_read.c -- Read a specified number of bytes from a file, possibly retry @item my_realloc.c -- Reallocate memory allocated with my_alloc.c (probably) @item my_redel.c -- Rename and delete file @item my_rename.c -- Rename without delete @item my_seek.c -- Seek, i.e. point to a spot within a file @item my_semaphore.c -- Semaphore routines, for use on OS that doesn't support them @item my_sleep.c -- Wait n microseconds @item my_static.c -- Static variables used by the mysys library @item my_symlink.c -- Read a symbolic link (symlinks are a UNIX thing, I guess) @item my_symlink2.c -- Part 2 of my_symlink.c @item my_tempnam.c -- Obsolete temporary-filename routine used by ISAM table handler @item my_thr_init.c -- initialize/allocate "all mysys & debug thread variables" @item my_wincond.c -- Windows-specific: emulate Posix conditions @item my_winsem.c -- Windows-specific: emulate Posix threads @item my_winthread.c -- Windows-specific: emulate Posix threads @item my_write.c -- Write a specified number of bytes to a file @item ptr_cmp.c -- Point to an optimal byte-comparison function @item queues.c -- Handle priority queues as in Robert Sedgewick's book @item raid2.c -- RAID support (the true implementation is in raid.cc) @item rijndael.c -- "Optimised ANSI C code for the Rijndael cipher (now AES") @item safemalloc.c -- A version of the standard malloc() with safety checking @item sha1.c -- Implementation of Secure Hashing Algorithm 1 @item string.c -- Initialize/append/free dynamically-sized strings; see also sql_string.cc in the /sql directory @item testhash.c -- Standalone program: test the hash library routines @item test_charset.c -- Standalone program: display character set information @item test_dir.c -- Standalone program: placeholder for "test all functions" idea @item test_fn.c -- Standalone program: apparently tests a function @item test_xml.c -- Standalone program: test XML routines @item thr_alarm.c -- Thread alarms and signal handling @item thr_lock.c -- "Read and write locks for Posix threads" @item thr_mutex.c -- A wrapper for mutex functions @item thr_rwlock.c -- Synchronizes the readers' thread locks with the writer's lock @item tree.c -- Initialize/search/free binary trees @item typelib.c -- Find a string in a set of strings; returns the offset to the string found @end itemize @*@* You can find documentation for the main functions in these files elsewhere in this document. For example, the main functions in my_getwd.c are described thus: @*@* @example "int my_getwd _A((string buf, uint size, myf MyFlags)); @* int my_setwd _A((const char *dir, myf MyFlags)); @* Get and set working directory." @* @end example @subsection netware Files related to the Novell NetWare version of MySQL. @*@* There are 39 files on this directory. Most have filename extensions of *.def, *.sql, or *.c. @*@* The twenty-five *.def files are all from Novell Inc. They contain import or export symbols. (".def" is a common filename extension for "definition".) @*@* The two *.sql files are short scripts of SQL statements used in testing. @*@* These are the five *.c files, all from Novell Inc.: @itemize @bullet @item libmysqlmain.c -- Only one function: init_available_charsets() @item my_manage.c -- Standalone management utility @item mysql_install_db.c -- Compare \scripts\mysql_install_db.sh @item mysql_test_run.c -- Short test program @item mysqld_safe.c -- Compare \scripts\mysqld_safe.sh @end itemize Perhaps the most important file is: @itemize @bullet @item netware.patch -- NetWare-specific build instructions and switches (compare \mysql-4.1\ltmain.sh) @end itemize @*@* For instructions about basic installation, see "Deployment Guide For NetWare AMP" at: @url{http://developer.novell.com/ndk/whitepapers/namp.htm} @* @subsection NEW-RPMS Directory to place RPMs while making a distribution. @*@* This directory is not part of the Windows distribution. It is a temporary directory used during RPM builds with Linux distributions. @*@* @subsection os2 Routines for working with the OS2 operating system. @*@* The files in this directory are the product of the efforts of three people from outside MySQL: Yuri Dario, Timo Maier, and John M Alfredsson. There are no .C program files in this directory. @*@* The contents of \os2 are: @itemize @bullet @item A Readme.Txt file @item An \include subdirectory containing .h files which are for OS/2 only @item Files used in the build process (configuration, switches, and one .obj) @end itemize @*@* The README file refers to MySQL version 3.23, which suggests that there have been no updates for MySQL 4.0 for this section. @*@* @subsection pstack Process stack display (not currently used). @*@* This is a set of publicly-available debugging aids which all do pretty well the same thing: display the contents of the stack, along with symbolic information, for a running process. There are versions for various object file formats (such as ELF and IEEE-695). Most of the programs are copyrighted by the Free Software Foundation and are marked as "part of GNU Binutils". @*@* In other words, the pstack files are not really part of the MySQL library. They are merely useful when you re-program some MYSQL code and it crashes. @*@* @subsection regex Henry Spencer's Regular Expression library for support of REGEXP function. @*@* This is the copyrighted product of Henry Spencer from the University of Toronto. It's a fairly-well-known implementation of the requirements of POSIX 1003.2 Section 2.8. The library is bundled with Apache and is the default implementation for regular-expression handling in BSD Unix. MySQL's Monty Widenius has made minor changes in three programs (debug.c, engine.c, regexec.c) but this is not a MySQL package. MySQL calls it only in order to support two MySQL functions: REGEXP and RLIKE. @*@* Some of Mr Spencer's documentation for the regex library can be found in the README and WHATSNEW files. @*@* One MySQL program which uses regex is \cmd-line-utils\libedit\search.c @*@* This program calls the 'regcomp' function, which is the entry point in \regex\regexp.c. @*@* @subsection SCCS Source Code Control System (not part of source distribution). @*@* You will see this directory if and only if you used BitKeeper for downloading the source. The files here are for BitKeeper administration and are not of interest to application programmers. @*@* @subsection scripts SQL batches, e.g. mysqlbug and mysql_install_db. @*@* The *.sh filename extension stands for "shell script". Linux programmers use it where Windows programmers would use a *.bat (batch filename extension). @*@* The *.sh files on this directory are: @itemize @bullet @item fill_help_tables.sh -- Create help-information tables and insert @item make_binary_distribution.sh -- Get configure information, make, produce tar @item msql2mysql.sh -- Convert (partly) mSQL programs and scripts to MySQL @item mysqlbug.sh -- Create a bug report and mail it @item mysqld_multi.sh -- Start/stop any number of mysqld instances @item mysqld_safe-watch.sh -- Start/restart in safe mode @item mysqld_safe.sh -- Start/restart in safe mode @item mysqldumpslow.sh -- Parse and summarize the slow query log @item mysqlhotcopy.sh -- Hot backup @item mysql_config.sh -- Get configuration information that might be needed to compile a client @item mysql_convert_table_format.sh -- Conversion, e.g. from ISAM to MyISAM @item mysql_explain_log.sh -- Put a log (made with --log) into a MySQL table @item mysql_find_rows.sh -- Search for queries containing @item mysql_fix_extensions.sh -- Renames some file extensions, not recommended @item mysql_fix_privilege_tables.sh -- Fix mysql.user etc. when upgrading. Can be safely run during any upgrade to get the newest MySQL privilege tables @item mysql_install_db.sh -- Create privilege tables and func table @item mysql_secure_installation.sh -- Disallow remote root login, eliminate test, etc. @item mysql_setpermission.sh -- Aid to add users or databases, sets privileges @item mysql_tableinfo.sh -- Puts info re MySQL tables into a MySQL table @item mysql_zap.sh -- Kill processes which match pattern @end itemize @*@* @subsection sql Programs for handling SQL commands. The "core" of MySQL. @*@* These are the .c and .cc files in the sql directory: @itemize @bullet @item convert.cc -- convert tables between different character sets @item derror.cc -- read language-dependent message file @item des_key_file.cc -- load DES keys from plaintext file @item field.cc -- "implement classes defined in field.h" (long); defines all storage methods MySQL uses to store field information into records that are then passed to handlers @item field_conv.cc -- functions to copy data between fields @item filesort.cc -- sort a result set, using memory or temporary files @item frm_crypt.cc -- contains only one short function: get_crypt_for_frm @item gen_lex_hash.cc -- Knuth's algorithm from Vol 3 Sorting and Searching, Chapter 6.3; used to search for SQL keywords in a query @item gstream.cc -- GTextReadStream, used to read GIS objects @item handler.cc -- handler-calling functions @item hash_filo.cc -- static-sized hash tables, used to store info like hostname -> ip tables in a FIFO manner @item ha_berkeley.cc -- Handler: BDB @item ha_heap.cc -- Handler: Heap @item ha_innodb.cc -- Handler: InnoDB @item ha_isam.cc -- Handler: ISAM @item ha_isammrg.cc -- Handler: (ISAM MERGE) @item ha_myisam.cc -- Handler: MyISAM @item ha_myisammrg.cc -- Handler: (MyISAM MERGE) @item hostname.cc -- Given IP, return hostname @item init.cc -- Init and dummy functions for interface with unireg @item item.cc -- Item functions @item item_buff.cc -- Buffers to save and compare item values @item item_cmpfunc.cc -- Definition of all compare functions @item item_create.cc -- Create an item. Used by lex.h. @item item_func.cc -- Numerical functions @item item_row.cc -- Row items for comparing rows and for IN on rows @item item_sum.cc -- Set functions (SUM, AVG, etc.) @item item_strfunc.cc -- String functions @item item_subselect.cc -- Item subselect @item item_timefunc.cc -- Date/time functions, e.g. week of year @item item_uniq.cc -- Empty file, here for compatibility reasons @item key.cc -- Functions to create keys from records and compare a key to a key in a record @item lock.cc -- Locks @item log.cc -- Logs @item log_event.cc -- Log event (a binary log consists of a stream of log events) @item matherr.c -- Handling overflow, underflow, etc. @item mf_iocache.cc -- Caching of (sequential) reads and writes @item mini_client.cc -- Client included in server for server-server messaging; used by the replication code @item mysqld.cc -- Source of mysqld.exe; includes the main() program that starts mysqld, handling of signals and connections @item my_lock.c -- Lock part of a file (like /mysys/my_lock.c, but with timeout handling for threads) @item net_serv.cc -- Read/write of packets on a network socket @item nt_servc.cc -- Initialize/register/remove an NT service @item opt_ft.cc -- Create a FT or QUICK RANGE based on a key (very short) @item opt_range.cc -- Range of keys @item opt_sum.cc -- Optimize functions in presence of (implied) GROUP BY @item password.c -- Password checking @item procedure.cc -- Procedure interface, as used in SELECT * FROM Table_name PROCEDURE ANALYSE @item protocol.cc -- Low level functions for PACKING data that is sent to client; actual sending done with net_serv.cc @item records.cc -- Functions for easy reading of records, possible through a cache @item repl_failsafe.cc -- Replication fail-save (not yet implemented) @item set_var.cc -- Set and retrieve MySQL user variables @item slave.cc -- Procedures for a slave in a master/slave (replication) relation @item spatial.cc -- Geometry stuff (lines, points, etc.) @item sql_acl.cc -- Functions related to ACL security; checks, stores, retrieves, and deletes MySQL user level privileges @item sql_analyse.cc -- Implements the PROCEDURE analyse, which analyses a query result and returns the 'optimal' data type for each result column @item sql_base.cc -- Basic functions needed by many modules, like opening and closing tables with table cache management @item sql_cache.cc -- SQL query cache, with long comments about how caching works @item sql_class.cc -- SQL class; implements the SQL base classes, of which THD (THREAD object) is the most important @item sql_crypt.cc -- Encode / decode, very short @item sql_db.cc -- Create / drop database @item sql_delete.cc -- The DELETE statement @item sql_derived.cc -- Derived tables, with long comments @item sql_do.cc -- The DO statement @item sql_error.cc -- Errors and warnings @item sql_handler.cc -- Implements the HANDLER interface, which gives direct access to rows in MyISAM and InnoDB @item sql_help.cc -- The HELP statement @item sql_insert.cc -- The INSERT statement @item sql_lex.cc -- Does lexical analysis of a query; i.e. breaks a query string into pieces and determines the basic type (number, string, keyword, etc.) of each piece @item sql_list.cc -- Only list_node_end_of_list, short (the rest of the list class is implemented in sql_list.h) @item sql_load.cc -- The LOAD DATA statement @item sql_map.cc -- Memory-mapped files (not yet in use) @item sql_manager.cc -- Maintenance tasks, e.g. flushing the buffers periodically; used with BDB table logs @item sql_olap.cc -- ROLLUP @item sql_parse.cc -- Parse an SQL statement; do initial checks and then jump to the function that should execute the statement @item sql_prepare.cc -- Prepare an SQL statement, or use a prepared statement @item sql_repl.cc -- Replication @item sql_rename.cc -- Rename table @item sql_select.cc -- Select and join optimisation @item sql_show.cc -- The SHOW statement @item sql_string.cc -- String functions: alloc, realloc, copy, convert, etc. @item sql_table.cc -- The DROP TABLE and ALTER TABLE statements @item sql_test.cc -- Some debugging information @item sql_udf.cc -- User-defined functions @item sql_union.cc -- The UNION operator @item sql_update.cc -- The UPDATE statement @item stacktrace.c -- Display stack trace (Linux/Intel only) @item table.cc -- Table metadata retrieval; read the table definition from a .frm file and store it in a TABLE object @item thr_malloc.cc -- Thread-safe interface to /mysys/my_alloc.c @item time.cc -- Date and time functions @item udf_example.cc -- Example file of user-defined functions @item uniques.cc -- Function to handle quick removal of duplicates @item unireg.cc -- Create a unireg form file (.frm) from a FIELD and field-info struct @end itemize @*@* @subsection sql-bench The MySQL Benchmarks. @*@* This directory has the programs and input files which MySQL uses for its comparisons of MySQL, PostgreSQL, mSQL, Solid, etc. Since MySQL publishes the comparative results, it's only right that it should make available all the material necessary to reproduce all the tests. @*@* There are five subdirectories and sub-subdirectories: @itemize @bullet @item \Comments -- Comments about results from tests of Access, Adabas, etc. @item \Data\ATIS -- .txt files containing input data for the "ATIS" tests @item \Data\Wisconsin -- .txt files containing input data for the "Wisconsin" tests @item \Results -- old test results @item \Results-win32 -- old test results from Windows 32-bit tests @end itemize @*@* There are twenty-four *.sh (shell script) files, which involve Perl programs. @*@* There are three *.bat (batch) files. @*@* There is one README file and one TODO file. @*@* @subsection SSL Secure Sockets Layer; includes an example certification one can use test an SSL (secure) database connection. @*@* This isn't a code directory. It contains a short note from Tonu Samuel (the NOTES file) and seven *.pem files. PEM stands for "Privacy Enhanced Mail" and is an Internet standard for adding security to electronic mail. Finally, there are two short scripts for running clients and servers over SSL connections. @*@* @subsection strings The string library. @*@* Many of the files in this subdirectory are equivalent to well-known functions that appear in most C string libraries. For those, there is documentation available in most compiler handbooks. @*@* On the other hand, some of the files are MySQL additions or improvements. Often the MySQL changes are attempts to optimize the standard libraries. It doesn't seem that anyone tried to optimize for recent Pentium class processors, though. @*@* The .C files are: @itemize @bullet @item atof.c -- ascii-to-float, MySQL version @item bchange.c -- short replacement routine written by Monty Widenius in 1987 @item bcmp.c -- binary compare, rarely used @item bcopy-duff.c -- block copy: attempt to copy memory blocks faster than cmemcpy @item bfill.c -- byte fill, to fill a buffer with (length) copies of a byte @item bmove.c -- block move @item bmove512.c -- "should be the fastest way to move a multiple of 512 bytes" @item bmove_upp.c -- bmove.c variant, starting with last byte @item bzero.c -- something like bfill with an argument of 0 @item conf_to_src.c -- reading a configuration file @item ctype*.c -- string handling programs for each char type MySQL handles @item do_ctype.c -- display case-conversion and sort-conversion tables @item int2str.c -- integer-to-string @item is_prefix.c -- checks whether string1 starts with string2 @item llstr.c -- convert long long to temporary-buffer string, return pointer @item longlong2str.c -- ditto, but to argument-buffer @item memcmp.c -- memory compare @item memset.c -- memory set @item my_vsnprintf.c -- variant of printf @item r_strinstr.c -- see if one string is within another @item str2int.c -- convert string to integer @item strappend.c -- fill up a string to n characters @item strcat.c -- concatenate strings @item strcend.c -- point to where a character C occurs within str, or NULL @item strchr.c -- point to first place in string where character occurs @item strcmp.c -- compare two strings @item strcont.c -- point to where any one of a set of characters appears @item strend.c -- point to the '\0' byte which terminates str @item strfill.c -- fill a string with n copies of a byte @item strinstr.c -- find string within string @item strlen.c -- return length of string in bytes @item strmake.c -- create new string from old string with fixed length, append end \0 if needed @item strmov.c -- move source to dest and return pointer to end @item strnlen.c -- return min(length of string, n) @item strnmov.c -- move source to dest for source size, or for n bytes @item strrchr.c -- find a character within string, searching from end @item strstr.c -- find an instance of pattern within source @item strto.c -- string to long, to long long, to unsigned long, etc. @item strtol.c -- string to long @item strtoll.c -- string to long long @item strtoul.c -- string to unsigned long @item strtoull.c -- string to unsigned long long @item strxmov.c -- move a series of concatenated source strings to dest @item strxnmov.c -- like strxmov.c but with a maximum length n @item str_test.c -- test of all the string functions encoded in assembler @item udiv.c -- unsigned long divide, for operating systems that don't support these @item xml.c -- read and parse XML strings; used to read character definition information stored in /sql/share/charsets @end itemize @*@* There are also four .ASM files -- macros.asm, ptr_cmp.asm, strings.asm, and strxmov.asm -- which can replace some of the C-program functions. But again, they look like optimizations for old members of the Intel processor family. @*@* @subsection support-files Files used to build MySQL on different systems. @*@* The files here are for building ("making") MySQL given a package manager, compiler, linker, and other build tools. The support files provide instructions and switches for the build processes. They include example my.cnf files one can use as a default setup for MySQL. @*@* @subsection tests Tests in Perl and in C. @*@* The files in this directory are test programs that can be used as a base to write a program to simulate problems in MySQL in various scenarios: forks, locks, big records, exporting, truncating, and so on. Some examples are: @itemize @bullet @item connect_test.c -- test that a connect is possible @item insert_test.c -- test that an insert is possible @item list_test.c -- test that a select is possible @item select_test.c -- test that a select is possible @item showdb_test.c -- test that a show-databases is possible @item ssl_test.c -- test that SSL is possible @item thread_test.c -- test that threading is possible @end itemize @*@* @subsection tools Tools -- well, actually, one tool. @*@* The only file is: @itemize @bullet @item mysqlmanager.c -- A "server management daemon" by Sasha Pachev. This is a tool under development and is not yet useful. Related to fail-safe replication. @end itemize @*@* @subsection VC++Files Visual C++ Files. @*@* Includes this entire directory, repeated for VC++ (Windows) use. @*@* VC++Files includes a complete environment to compile MySQL with the VC++ compiler. To use it, just copy the files on this directory; the make_win_src_distribution.sh script uses these files to create a Windows source installation. @*@* This directory has subdirectories which are copies of the main directories. For example, there is a subdirectory \VC++Files\heap, which has the Microsoft developer studio project file to compile \heap with VC++. So for a description of the files in \VC++Files\heap, see the description of the files in \heap. The same applies for almost all of VC++Files's subdirectories (bdb, client, isam, libmysql, etc.). The difference is that the \VC++Files variants are specifically for compilation with Microsoft Visual C++ in 32-bit Windows environments. @*@* In addition to the "subdirectories which are duplicates of directories", VC++Files contains these subdirectories, which are not duplicates: @itemize @bullet @item comp_err -- (nearly empty) @item contrib -- (nearly empty) @item InstallShield -- script files @item isamchk -- (nearly empty) @item libmysqltest -- one small non-MySQL test program: mytest.c @item myisamchk -- (nearly empty) @item myisamlog -- (nearly empty) @item myisammrg -- (nearly empty) @item mysqlbinlog -- (nearly empty) @item mysqlmanager -- MFC foundation class files created by AppWizard @item mysqlserver -- (nearly empty) @item mysqlshutdown -- one short program, mysqlshutdown.c @item mysqlwatch.c -- Windows service initialization and monitoring @item my_print_defaults -- (nearly empty) @item pack_isam -- (nearly empty) @item perror -- (nearly empty) @item prepare -- (nearly empty) @item replace -- (nearly empty) @item SCCS -- source code control system @item test1 -- tests connecting via X threads @item thr_insert_test -- (nearly empty) @item thr_test -- one short program used to test for memory-allocation bug @item winmysqladmin -- the winmysqladmin.exe source @end itemize @*@* The "nearly empty" subdirectories noted above (e.g. comp_err and isamchk) are needed because VC++ requires one directory per project (i.e. executable). We are trying to keep to the MySQL standard source layout and compile only to different directories. @*@* @subsection vio Virtual I/O Library. @*@* The VIO routines are wrappers for the various network I/O calls that happen with different protocols. The idea is that in the main modules one won't have to write separate bits of code for each protocol. Thus vio's purpose is somewhat like the purpose of Microsoft's winsock library. @*@* The underlying protocols at this moment are: TCP/IP, Named Pipes (for WindowsNT), Shared Memory, and Secure Sockets (SSL). @*@* The C programs are: @itemize @bullet @item test-ssl.c -- Short standalone test program: SSL @item test-sslclient.c -- Short standalone test program: clients @item test-sslserver.c -- Short standalone test program: server @item vio.c -- Declarations + open/close functions @item viosocket.c -- Send/retrieve functions @item viossl.c -- SSL variations for the above @item viosslfactories.c -- Certification / Verification @item viotest.cc -- Short standalone test program: general @item viotest-ssl.c -- Short standalone test program: SSL @item viotest-sslconnect.cc -- Short standalone test program: SSL connect @end itemize @*@* The older functions -- raw_net_read, raw_net_write -- are now obsolete. @*@* @subsection zlib Data compression library, used on Windows. @*@* zlib is a data compression library used to support the compressed protocol and the COMPRESS/UNCOMPRESS functions under Windows. On Unix, MySQL uses the system libgz.a library for this purpose. @*@* Zlib -- which presumably stands for "Zip Library" -- is not a MySQL package. It was produced by the GNU Zip (gzip.org) people. Zlib is a variation of the famous "Lempel-Ziv" method, which is also used by "Zip". The method for reducing the size of any arbitrary string of bytes is as follows: @itemize @bullet @item Find a substring which occurs twice in the string. @item Replace the second occurrence of the substring with (a) a pointer to the first occurrence, plus (b) an indication of the length of the first occurrence. @end itemize There is a full description of the library's functions in the gzip manual at: @* @url{http://www.gzip.org/zlib/manual.html} @* There is therefore no need to list the modules in this document. @*@* The MySQL program \mysys\my_compress.c uses zlib for packet compression. The client sends messages to the server which are compressed by zlib. See also: \sql\net_serv.cc. @node Files in InnoDB Sources, , Files in MySQL Sources, Top @chapter Annotated List Of Files in the InnoDB Source Code Distribution ERRATUM BY HEIKKI TUURI (START) @*@* Errata about InnoDB row locks:@*@* @example #define LOCK_S 4 /* shared */ #define LOCK_X 5 /* exclusive */ ... @strong{/* Waiting lock flag */} #define LOCK_WAIT 256 /* this wait bit should be so high that it can be ORed to the lock mode and type; when this bit is set, it means that the lock has not yet been granted, it is just waiting for its turn in the wait queue */ ... @strong{/* Precise modes */} #define LOCK_ORDINARY 0 /* this flag denotes an ordinary next-key lock in contrast to LOCK_GAP or LOCK_REC_NOT_GAP */ #define LOCK_GAP 512 /* this gap bit should be so high that it can be ORed to the other flags; when this bit is set, it means that the lock holds only on the gap before the record; for instance, an x-lock on the gap does not give permission to modify the record on which the bit is set; locks of this type are created when records are removed from the index chain of records */ #define LOCK_REC_NOT_GAP 1024 /* this bit means that the lock is only on the index record and does NOT block inserts to the gap before the index record; this is used in the case when we retrieve a record with a unique key, and is also used in locking plain SELECTs (not part of UPDATE or DELETE) when the user has set the READ COMMITTED isolation level */ #define LOCK_INSERT_INTENTION 2048 /* this bit is set when we place a waiting gap type record lock request in order to let an insert of an index record to wait until there are no conflicting locks by other transactions on the gap; note that this flag remains set when the waiting lock is granted, or if the lock is inherited to a neighboring record */ @end example @* ERRATUM BY HEIKKI TUURI (END) @*@* The InnoDB source files are the best place to look for information about internals of the file structure that MySQLites can optionally use for transaction support. But when you first look at all the subdirectories and file names you'll wonder: Where Do I Start? It can be daunting. @*@* Well, I've been through that phase, so I'll pass on what I had to learn on the first day that I looked at InnoDB source files. I am very sure that this will help you grasp, in overview, the organization of InnoDB modules. I'm also going to add comments about what is going on -- which you should mistrust! These comments are reasonable working hypotheses; nevertheless, they have not been subjected to expert peer review. @*@* Here's how I'm going to organize the discussion. I'll take each of the 32 InnoDB subdirectories that come with the MySQL 4.0 source code in \mysql\innobase (on my Windows directory). The format of each section will be like this every time: @*@* @strong{\subdirectory-name (LONGER EXPLANATORY NAME)}@* @multitable @columnfractions .10 .20 .40 .50 @item @strong{File Name} @tab @strong{What Name Stands For} @tab @strong{Size} @tab @strong{Comment Inside File} @item file-name @tab my-own-guess @tab in-bytes @tab from-the-file-itself @end multitable ...@* My-Comments@* @* For example: @* @example " @strong{\ha (HASHING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- ha0ha.c Hashing/Hashing 7,452 Hash table with external chains Comments about hashing will be here. " @end example @* The "Comment Inside File" column is a direct copy from the first /* comment */ line inside the file. All other comments are mine. After I've discussed each directory, I'll finish with some notes about naming conventions and a short list of URLs that you can use for further reference. @*@* Now let's begin. @*@* @example @strong{\ha (HASHING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- ha0ha.c Hashing / Hashing 7,452 Hash table with external chains I'll hold my comments until the next section, \hash (HASHING). @strong{\hash (HASHING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- hash0hash.c Hashing / Hashing 3,257 Simple hash table utility The two C programs in the \ha and \hashing directories -- ha0ha.c and hash0hash.c -- both refer to a "hash table" but hash0hash.c is specialized, it is mostly about accessing points in the table under mutex control. When a "database" is so small that InnoDB can load it all into memory at once, it's more efficient to access it via a hash table. After all, no disk i/o can be saved by using an index lookup, if there's no disk. @strong{\os (OPERATING SYSTEM)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- os0shm.c OS / Shared Memory 3,150 To shared memory primitives os0file.c OS / File 64,412 To i/o primitives os0thread.c OS / Thread 6,827 To thread control primitives os0proc.c OS / Process 3,700 To process control primitives os0sync.c OS / Synchronization 10,208 To synchronization primitives This is a group of utilities that other modules may call whenever they want to use an operating-system resource. For example, in os0file.c there is a public InnoDB function named os_file_create_simple(), which simply calls the Windows-API function CreateFile. Naturally the contents of this group are somewhat different for other operating systems. The "Shared Memory" functions in os0shm.c are only called from the communications program com0shm.c (see \com COMMUNICATIONS). The i/o and thread-control primitives are called extensively. The word "synchronization" in this context refers to the mutex-create and mutex-wait functionality. @strong{\ut (UTILITIES)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- ut0ut.c Utilities / Utilities 7,041 Various utilities ut0byte.c Utilities / Debug 1,856 Byte utilities ut0rnd.c Utilities / Random 1,475 Random numbers and hashing ut0mem.c Utilities / Memory 5,530 Memory primitives ut0dbg.c Utilities / Debug 642 Debug utilities The two functions in ut0byte.c are just for lower/upper case conversion and comparison. The single function in ut0rnd.c is for finding a prime slightly greater than the given argument, which is useful for hash functions, but unrelated to randomness. The functions in ut0mem.c are wrappers for "malloc" and "free" calls -- for the real "memory" module see section \mem (MEMORY). Finally, the functions in ut0ut.c are a miscellany that didn't fit better elsewhere: get_high_bytes, clock, time, difftime, get_year_month_day, and "sprintf" for various diagnostic purposes. In short: the \ut group is trivial. @strong{\buf (BUFFERING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- buf0buf.c Buffering / Buffering 53,246 The database buffer buf_pool buf0flu.c Buffering / Flush 23,711 ... flush algorithm buf0lru.c / least-recently-used 20,245 ... replacement algorithm buf0rea.c Buffering / read 17,399 ... read There is a separate file group (\mem MEMORY) which handles memory requests in general.A "buffer" usually has a more specific definition, as a memory area which contains copies of pages that ordinarily are in the main data file. The "buffer pool" is the set of all buffers (there are lots of them because InnoDB doesn't depend on the OS's caching to make things faster). The pool size is fixed (at the time of this writing) but the rest of the buffering architecture is sophisticated, involving a host of control structures. In general: when InnoDB needs to access a new page it looks first in the buffer pool; InnoDB reads from disk to a new buffer when the page isn't there; InnoDB chucks old buffers (basing its decision on a conventional Least-Recently-Used algorithm) when it has to make space for a new buffer. There are routines for checking a page's validity, and for read-ahead. An example of "read-ahead" use: if a sequential scan is going on, then a DBMS can read more than one page at a time, which is efficient because reading 32,768 bytes (two pages) takes less than twice as long as reading 16,384 bytes (one page). @strong{\btr (B-TREE)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- btr0btr.c B-tree / B-tree 74,255 B-tree btr0cur.c B-tree / Cursor 94,950 index tree cursor btr0sea.c B-tree / Search 36,580 index tree adaptive search btr0pcur.c B-tree / persistent cursor 14,548 index tree persistent cursor If you total up the sizes of the C files, you'll see that \btr is the second-largest file group in InnoDB. This is understandable because maintaining a B-tree is a relatively complex task. Luckily, there has been a lot of work done to describe efficient management of B-tree and B+-tree structures, much of it open-source or public-domain, since their original invention over thirty years ago. InnoDB likes to put everything in B-trees. This is what I'd call a "distinguishing characteristic" because in all the major DBMSs (like IBM DB2, Microsoft SQL Server, and Oracle), the main or default or classic structure is the heap-and-index. In InnoDB the main structure is just the index. To put it another way: InnoDB keeps the rows in the leaf node of the index, rather than in a separate file. Compare Oracle's Index Organized Tables, and Microsoft SQL Server's Clustered Indexes. This, by the way, has some consequences. For example, you may as well have a primary key since otherwise InnoDB will make one anyway. And that primary key should be the shortest of the candidate keys, since InnoDB will use it as a pointer if there are secondary indexes. Most importantly, it means that rows have no fixed address. Therefore the routines for managing file pages should be good. We'll see about that when we look at the \row (ROW) program group later. @strong{\com (COMMUNCATION)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- com0com.c Communication 6,913 Communication primitives com0shm.c Communication / 24,633 ... through shared memory Shared Memory The communication primitives in com0com.c are said to be modelled after the ones in Microsoft's winsock library (the Windows Sockets interface). The communication primitives in com0shm.c are at a slightly lower level, and are called from the routines in com0com.c. I was interested in seeing how InnoDB would handle inter-process communication, since there are many options -- named pipes, TCP/IP, Windows messaging, and Shared Memory being the main ones that come to mind. It appears that InnoDB prefers Shared Memory. The main idea is: there is an area of memory which two different processes (or threads, of course) can both access. To communicate, a thread gets an appropriate mutex, puts in a request, and waits for a response. Thread interaction is also a subject for the os0thread.c program in another program group, \os (OPERATING SYSTEM). @strong{\dyn (DYNAMICALLY ALLOCATED ARRAY)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- dyn0dyn.c Dynamic / Dynamic 994 dynamically allocated array There is a single function in the dyn0dyn.c program, for adding a block to the dynamically allocated array. InnoDB might use the array for managing concurrency between threads. At the moment, the \dyn program group is trivial. @strong{\fil (FILE)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- fil0fil.c File / File 39,725 The low-level file system The reads and writes to the database files happen here, in co-ordination with the low-level file i/o routines (see os0file.h in the \os program group). Briefly: a table's contents are in pages, which are in files, which are in tablespaces. Files do not grow; instead one can add new files to the tablespace. As we saw earlier (discussing the \btr program group) the pages are nodes of B-trees. Since that's the case, new additions can happen at various places in the logical file structure, not necessarily at the end. Reads and writes are asynchronous, and go into buffers, which are set up by routines in the \buf program group. @strong{\fsp (FILE SPACE)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- fsp0fsp.c File Space Management 100,271 File space management I would have thought that the \fil (FILE) and \fsp (FILE SPACE) MANAGEMENT programs would fit together in the same program group; however, I guess the InnoDB folk are splitters rather than lumpers. It's in fsp0fsp.c that one finds some of the descriptions and comments of extents, segments, and headers. For example, the "descriptor bitmap of the pages in the extent" is in here, and you can find as well how the free-page list is maintained, what's in the bitmaps, and what various header fields' contents are. @strong{\fut (FILE UTILITY)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- fut0fut.c File Utility / Utility 293 File-based utilities fut0lst.c File Utility / List 14,129 File-based list utilities Mainly these small programs affect only file-based lists, so maybe saying "File Utility" is too generic. The real work with data files goes on in the \fsp program group. @strong{\log (LOGGING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- log0log.c Logging / Logging 77,834 Database log log0recv.c Logging / Recovery 80,701 Recovery I've already written about the \log program group, so here's a link to my previous article: "How Logs work with MySQL and InnoDB": @url{http://www.devarticles.com/art/1/181/2} @strong{\mem (MEMORY)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- mem0mem.c Memory / Memory 9,971 The memory management mem0dbg.c Memory / Debug 21,297 ... the debug code mem0pool.c Memory / Pool 16,293 ... the lowest level There is a long comment at the start of the mem0pool.c program, which explains what the memory-consumers are, and how InnoDB tries to satisfy them. The main thing to know is that there are really three pools: the buffer pool (see the \buf program group), the log pool (see the \log program group), and the common pool, which is where everything that's not in the buffer or log pools goes (for example the parsed SQL statements and the data dictionary cache). @strong{\mtr (MINI-TRANSACTION)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- mtr0mtr.c Mini-transaction / 12,433 Mini-transaction buffer mtr0log.c Mini-transaction / Log 8,180 ... log routines The mini-transaction routines are called from most of the other program groups. I'd describe this as a low-level utility set. @strong{\que (QUERY GRAPH)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- que0que.c Query Graph / Query 35,964 Query graph The program que0que.c ostensibly is about the execution of stored procedures which contain commit/rollback statements. I took it that this has little importance for the average MySQL user. @strong{\rem (RECORD MANAGER)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- rem0rec.c Record Manager 14,961 Record Manager rem0cmp.c Record Manager / 25,263 Comparison services for records Comparison There's an extensive comment near the start of rem0rec.c title "Physical Record" and it's recommended reading. At some point you'll ask what are all those bits that surround the data in the rows on a page, and this is where you'll find the answer. @strong{\row (ROW)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- row0row.c Row / Row 16,764 General row routines row0uins.c Row / Undo Insert 7,199 Fresh insert undo row0umod.c Row / Undo Modify 17,147 Undo modify of a row row0undo.c Row / Undo 10,254 Row undo row0vers.c Row / Version 12,288 Row versions row0mysql.c Row / MySQL 63,556 Interface [to MySQL] row0ins.c Row / Insert 42,829 Insert into a table row0sel.c Row / Select 85,923 Select row0upd.c Row / Update 44,456 Update of a row row0purge.c Row / Purge 14,961 Purge obsolete records Rows can be selected, inserted, updated/deleted, or purged (a maintenance activity). These actions have ancillary actions, for example after insert there can be an index-update test, but it seems to me that sometimes the ancillary action has no MySQL equivalent (yet) and so is inoperative. Speaking of MySQL, notice that one of the larger programs in the \row program group is the "interface between Innobase row operations and MySQL" (row0mysql.c) -- information interchange happens at this level because rows in InnoDB and in MySQL are analogous, something which can't be said for pages and other levels. @strong{\srv (Server)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- srv0srv.c Server / Server 79,058 Server main program srv0que.c Server / Query 2,361 Server query execution srv0start.c Server / Start 34,586 Starts the server This is where the server reads the initial configuration files, splits up the threads, and gets going. There is a long comment deep in the program (you might miss it at first glance) titled "IMPLEMENTATION OF THE SERVER MAIN PROGRAM" in which you'll find explanations about thread priority, and about what the responsibiities are for various thread types. InnoDB has many threads, for example "user threads" (which wait for client requests and reply to them), "parallel communication threads" (which take part of a user thread's job if a query process can be split), "utility threads" (background priority), and a "master thread" (high priority, usually asleep). @strong{\thr (Thread Local Storage)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- thr0loc.c Thread / Local 5,261 The thread local storage InnoDB doesn't use the Windows-API thread-local-storage functions, perhaps because they're not portable enough. @strong{\trx (Transaction)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- trx0trx.c Transaction / 37,447 The transaction trx0purge.c Transaction / Purge 26,782 ... Purge old versions trx0rec.c Transaction / Record 36,525 ... Undo log record trx0sys.c Transaction / System 20,671 ... System trx0rseg.c / Rollback segment 6,214 ... Rollback segment trx0undo.c Transaction / Undo 46,595 ... Undo log InnoDB's transaction management is supposedly "in the style of Oracle" and that's close to true but can mislead you. @itemize @item First: InnoDB uses rollback segments like Oracle8i does -- but Oracle9i uses a different name @item Second: InnoDB uses multi-versioning like Oracle does -- but I see nothing that looks like an Oracle ITL being stored in the InnoDB data pages. @item Third: InnoDB and Oracle both have short (back-to-statement-start) versioning for the READ COMMITTED isolation level and long (back-to-transaction-start) versioning for higher levels -- but InnoDB and Oracle have different "default" isolation levels. @item Finally: InnoDB's documentation says it has to lock "the gaps before index keys" to prevent phantoms -- but any Oracle user will tell you that phantoms are impossible anyway at the SERIALIZABLE isolation level, so key-locks are unnecessary. @end itemize The main idea, though, is that InnoDB has multi-versioning. So does Oracle. This is very different from the way that DB2 and SQL Server do things. @strong{\usr (USER)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- usr0sess.c User / Session 27,415 Sessions One user can have multiple sessions (the session being all the things that happen betweeen a connect and disconnect). This is where InnoDB tracks session IDs, and server/client messaging. It's another of those items which is usually MySQL's job, though. @strong{\data (DATA)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- data0data.c Data / Data 26,002 SQL data field and tuple data0type.c Data / Type 2,122 Data types This is a collection of minor utility routines affecting rows. @strong{\dict (DICTIONARY)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- dict0dict.c Dictionary / Dictionary 84,667 Data dictionary system dict0boot.c Dictionary / boot 12,134 ... creation and booting dict0load.c Dictionary / load 26,546 ... load to memory cache dict0mem.c Dictionary / memory 8,221 ... memory object creation The data dictionary (known in some circles as the catalog) has the metadata information about objects in the database -- column sizes, table names, and the like. @strong{\eval (EVALUATING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- eval0eval.c Evaluating/Evaluating 15,682 SQL evaluator eval0proc.c Evaluating/Procedures 5,000 Executes SQL procedures The evaluating step is a late part of the process of interpreting an SQL statement -- parsing has already occurred during \pars (PARSING). The ability to execute SQL stored procedures is an InnoDB feature, but not a MySQL feature, so the eval0proc.c program is unimportant. @strong{\ibuf (INSERT BUFFER)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- ibuf0ibuf.c Insert Buffer / 69,884 Insert buffer The words "Insert Buffer" mean not "buffer used for INSERT" but "insertion of a buffer into the buffer pool" (see the \buf BUFFER program group description). The matter is complex due to possibilities for deadlocks, a problem to which the comments in the ibuf0ibuf.c program devote considerable attention. @strong{\mach (MACHINE FORMAT)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- mach0data.c Machine/Data 2,319 Utilities for converting The mach0data.c program has two small routines for reading compressed ulints (unsigned long integers). @strong{\lock (LOCKING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- lock0lock.c Lock / Lock 127,646 The transaction lock system If you've used DB2 or SQL Server, you might think that locks have their own in-memory table, that row locks might need occasional escalation to table locks, and that there are three lock types: Shared, Update, Exclusive. All those things are untrue with InnoDB! Locks are kept in the database pages. A bunch of row locks can't be rolled together into a single table lock. And most importantly there's only one lock type. I call this type "Update" because it has the characteristics of DB2 / SQL Server Update locks, that is, it blocks other updates but doesn't block reads. Unfortunately, InnoDB comments refer to them as "x-locks" etc. To sum it up: if your background is Oracle you won't find too much surprising, but if your background is DB2 or SQL Server the locking concepts and terminology will probably confuse you at first. You can find an online article about the differences between Oracle-style and DB2/SQL-Server-style locks at: @url{http://dbazine.com/gulutzan6.html} @strong{\odbc (ODBC)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- odbc0odbc.c ODBC / ODBC 16,865 ODBC client library The odbc0odbc.c program has a small selection of old ODBC-API functions: SQLAllocEnv, SQLAllocConnect, SQLAllocStmt, SQLConnect, SQLError, SQLPrepare, SQLBindParameter, SQLExecute. @strong{\page (PAGE)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- page0page.c Page / Page 44,309 Index page routines page0cur.c Page / Cursor 30,305 The page cursor It's in the page0page.c program that you'll learn as follows: index pages start with a header, entries in the page are in order, at the end of the page is a sparse "page directory" (what I would have called a slot table) which makes binary searches easier. Incidentally, the program comments refer to "a page size of 8 kB" which seems obsolete. In univ.i (a file containing universal constants) the page size is now #defined as 16KB. @strong{\pars (PARSING)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- pars0pars.c Parsing/Parsing 49,947 SQL parser pars0grm.c Parsing/Grammar 62,685 A Bison parser pars0opt.c Parsing/Optimizer 30,809 Simple SQL Optimizer pars0sym.c Parsing/Symbol Table 5,541 SQL parser symbol table lexyy.c ?/Lexer 59,948 Lexical scanner The job is to input a string containing an SQL statement and output an in-memory parse tree. The EVALUATING (subdirectory \eval) programs will use the tree. As is common practice, the Bison and Flex tools were used -- pars0grm.c is what the Bison parser produced from an original file named pars0grm.y (not supplied), and lexyy.c is what Flex produced. Since InnoDB is a DBMS by itself, it's natural to find SQL parsing in it. But in the MySQL/InnoDB combination, MySQL handles most of the parsing. These files are unimportant. @strong{\read (READ)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- read0read.c Read / Read 6,244 Cursor read The read0read.c program opens a "read view" of a query result, using some functions in the \trx program group. @strong{\sync (SYNCHRONIZATION)} File Name What Name Stands For Size Comment Inside File --------- -------------------- ------ ------------------- sync0sync.c Synchronization / 35,918 Mutex, the basic sync primitive sync0arr.c ... / array 26,461 Wait array used in primitives sync0ipm.c ... / interprocess 4,027 for interprocess sync sync0rw.c ... / read-write 22,220 read-write lock for thread sync A mutex (Mutual Exclusion) is an object which only one thread/process can hold at a time. Any modern operating system API has some functions for mutexes; however, as the comments in the sync0sync.c code indicate, it can be faster to write one's own low-level mechanism. In fact the old assembly-language XCHG trick is in here -- this is the only program that contains any assembly code. @end example @* @* This is the end of the section-by-section account of InnoDB subdirectories. @*@* @strong{A Note About File Naming} @*@* There appears to be a naming convention. The first letters of the file name are the same as the subdirectory name, then there is a '0' separator, then there is an individual name. For the main program in a subdirectory, the individual name may be a repeat of the subdirectory name. For example, there is a file named ha0ha.c (the first two letters ha mean "it's in in subdirectory ..\ha", the next letter 0 means "0 separator", the next two letters mean "this is the main ha program"). This naming convention is not strict, though: for example the file lexyy.c is in the \pars subdirectory. @*@* @strong{A Note About Copyrights} @*@* Most of the files begin with a copyright notice or a creation date, for example "Created 10/25/1995 Heikki Tuuri". I don't know a great deal about the history of InnoDB, but found it interesting that most creation dates were between 1994 and 1998. @*@* @strong{References} @*@* Ryan Bannon, Alvin Chin, Faryaaz Kassam and Andrew Roszko @* "InnoDB Concrete Architecture" @* @url{http://www.swen.uwaterloo.ca/~mrbannon/cs798/assignment_02/innodb.pdf} A student paper. It's an interesting attempt to figure out InnoDB's architecture using tools, but I didn't end up using it for the specific purposes of this article. @*@* Peter Gulutzan @* "How Logs Work With MySQL And InnoDB" @* @url{http://www.devarticles.com/art/1/181/2} @*@* Heikki Tuuri @* "InnoDB Engine in MySQL-Max-3.23.54 / MySQL-4.0.9: The Up-to-Date Reference Manual of InnoDB" @* @url{http://www.innodb.com/ibman.html} This is the natural starting point for all InnoDB information. Mr Tuuri also appears frequently on MySQL forums. @*@* @summarycontents @contents @bye