/* Copyright (C) 2000 MySQL AB & MySQL Finland AB & TCX DataKonsult AB

   This program is free software; you can redistribute it and/or modify
   it under the terms of the GNU General Public License as published by
   the Free Software Foundation; either version 2 of the License, or
   (at your option) any later version.

   This program is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with this program; if not, write to the Free Software
   Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA */


/* Classes in mysql */

#ifdef __GNUC__
#pragma interface			/* gcc class implementation */
#endif

// TODO: create log.h and move all the log header stuff there

class Query_log_event;
class Load_log_event;
class Slave_log_event;
class Format_description_log_event;
class sp_rcontext;
class sp_cache;

enum enum_enable_or_disable { LEAVE_AS_IS, ENABLE, DISABLE };
enum enum_ha_read_modes { RFIRST, RNEXT, RPREV, RLAST, RKEY };
enum enum_duplicates { DUP_ERROR, DUP_REPLACE, DUP_IGNORE, DUP_UPDATE };
enum enum_log_type { LOG_CLOSED, LOG_TO_BE_OPENED, LOG_NORMAL, LOG_NEW, LOG_BIN};
enum enum_delay_key_write { DELAY_KEY_WRITE_NONE, DELAY_KEY_WRITE_ON,
			    DELAY_KEY_WRITE_ALL };

enum enum_check_fields { CHECK_FIELD_IGNORE, CHECK_FIELD_WARN,
			 CHECK_FIELD_ERROR_FOR_NULL };

extern char internal_table_name[2];

/* log info errors */
#define LOG_INFO_EOF -1
#define LOG_INFO_IO  -2
#define LOG_INFO_INVALID -3
#define LOG_INFO_SEEK -4
#define LOG_INFO_MEM -6
#define LOG_INFO_FATAL -7
#define LOG_INFO_IN_USE -8

/* bitmap to SQL_LOG::close() */
#define LOG_CLOSE_INDEX		1
#define LOG_CLOSE_TO_BE_OPENED	2
#define LOG_CLOSE_STOP_EVENT	4

struct st_relay_log_info;

typedef struct st_log_info
{
  char log_file_name[FN_REFLEN];
  my_off_t index_file_offset, index_file_start_offset;
  my_off_t pos;
  bool fatal; // if the purge happens to give us a negative offset
  pthread_mutex_t lock;
  st_log_info():fatal(0) { pthread_mutex_init(&lock, MY_MUTEX_INIT_FAST);}
  ~st_log_info() { pthread_mutex_destroy(&lock);}
} LOG_INFO;

typedef struct st_user_var_events
{
  user_var_entry *user_var_event;
  char *value;
  ulong length;
  Item_result type;
  uint charset_number;
} BINLOG_USER_VAR_EVENT;

class Log_event;

class MYSQL_LOG
 {
 private:
  /* LOCK_log and LOCK_index are inited by init_pthread_objects() */
  pthread_mutex_t LOCK_log, LOCK_index;
  pthread_cond_t update_cond;
  ulonglong bytes_written;
  time_t last_time,query_start;
  IO_CACHE log_file;
  IO_CACHE index_file;
  char *name;
  char time_buff[20],db[NAME_LEN+1];
  char log_file_name[FN_REFLEN],index_file_name[FN_REFLEN];
  // current file sequence number for load data infile binary logging
  uint file_id;
  uint open_count;				// For replication
  volatile enum_log_type log_type;
  enum cache_type io_cache_type;
  bool write_error, inited;
  bool need_start_event;
  /*
    no_auto_events means we don't want any of these automatic events :
    Start/Rotate/Stop. That is, in 4.x when we rotate a relay log, we don't want
    a Rotate_log event to be written to the relay log. When we start a relay log
    etc. So in 4.x this is 1 for relay logs, 0 for binlogs.
    In 5.0 it's 0 for relay logs too!
  */
  bool no_auto_events;			     
  /* 
     The max size before rotation (usable only if log_type == LOG_BIN: binary
     logs and relay logs).
     For a binlog, max_size should be max_binlog_size.
     For a relay log, it should be max_relay_log_size if this is non-zero,
     max_binlog_size otherwise.
     max_size is set in init(), and dynamically changed (when one does SET
     GLOBAL MAX_BINLOG_SIZE|MAX_RELAY_LOG_SIZE) by fix_max_binlog_size and
     fix_max_relay_log_size). 
  */
  ulong max_size;
  friend class Log_event;

public:
  MYSQL_LOG();
  ~MYSQL_LOG();

  /* 
     These describe the log's format. This is used only for relay logs.
     _for_exec is used by the SQL thread, _for_queue by the I/O thread. It's
     necessary to have 2 distinct objects, because the I/O thread may be reading
     events in a different format from what the SQL thread is reading (consider
     the case of a master which has been upgraded from 5.0 to 5.1 without doing
     RESET MASTER, or from 4.x to 5.0).
  */
  Format_description_log_event *description_event_for_exec,
    *description_event_for_queue;

  void reset_bytes_written()
  {
    bytes_written = 0;
  }
  void harvest_bytes_written(ulonglong* counter)
  {
#ifndef DBUG_OFF
    char buf1[22],buf2[22];
#endif	
    DBUG_ENTER("harvest_bytes_written");
    (*counter)+=bytes_written;
    DBUG_PRINT("info",("counter: %s  bytes_written: %s", llstr(*counter,buf1),
		       llstr(bytes_written,buf2)));
    bytes_written=0;
    DBUG_VOID_RETURN;
  }
  void set_max_size(ulong max_size_arg);
  void signal_update() { pthread_cond_broadcast(&update_cond);}
  void wait_for_update(THD* thd, bool master_or_slave);
  void set_need_start_event() { need_start_event = 1; }
  void init(enum_log_type log_type_arg,
	    enum cache_type io_cache_type_arg,
	    bool no_auto_events_arg, ulong max_size);
  void init_pthread_objects();
  void cleanup();
  bool open(const char *log_name,enum_log_type log_type,
	    const char *new_name, const char *index_file_name_arg,
	    enum cache_type io_cache_type_arg,
	    bool no_auto_events_arg, ulong max_size,
            bool null_created);
  void new_file(bool need_lock= 1);
  bool write(THD *thd, enum enum_server_command command,
	     const char *format,...);
  bool write(THD *thd, const char *query, uint query_length,
	     time_t query_start=0);
  bool write(Log_event* event_info); // binary log write
  bool write(THD *thd, IO_CACHE *cache, bool commit_or_rollback);

  /*
    v stands for vector
    invoked as appendv(buf1,len1,buf2,len2,...,bufn,lenn,0)
  */
  bool appendv(const char* buf,uint len,...);
  bool append(Log_event* ev);
  
  int generate_new_name(char *new_name,const char *old_name);
  void make_log_name(char* buf, const char* log_ident);
  bool is_active(const char* log_file_name);
  int update_log_index(LOG_INFO* linfo, bool need_update_threads);
  int purge_logs(const char *to_log, bool included, 
                 bool need_mutex, bool need_update_threads,
                 ulonglong *decrease_log_space);
  int purge_logs_before_date(time_t purge_time);
  int purge_first_log(struct st_relay_log_info* rli, bool included); 
  bool reset_logs(THD* thd);
  void close(uint exiting);

  // iterating through the log index file
  int find_log_pos(LOG_INFO* linfo, const char* log_name,
		   bool need_mutex);
  int find_next_log(LOG_INFO* linfo, bool need_mutex);
  int get_current_log(LOG_INFO* linfo);
  uint next_file_id();
  inline bool is_open() { return log_type != LOG_CLOSED; }
  inline char* get_index_fname() { return index_file_name;}
  inline char* get_log_fname() { return log_file_name; }
  inline pthread_mutex_t* get_log_lock() { return &LOCK_log; }
  inline IO_CACHE* get_log_file() { return &log_file; }

  inline void lock_index() { pthread_mutex_lock(&LOCK_index);}
  inline void unlock_index() { pthread_mutex_unlock(&LOCK_index);}
  inline IO_CACHE *get_index_file() { return &index_file;}
  inline uint32 get_open_count() { return open_count; }
};

/* character conversion tables */


typedef struct st_copy_info {
  ha_rows records;
  ha_rows deleted;
  ha_rows copied;
  ha_rows error_count;
  enum enum_duplicates handle_duplicates;
  int escape_char, last_errno;
/* for INSERT ... UPDATE */
  List<Item> *update_fields;
  List<Item> *update_values;
} COPY_INFO;


class key_part_spec :public Sql_alloc {
public:
  const char *field_name;
  uint length;
  key_part_spec(const char *name,uint len=0) :field_name(name), length(len) {}
};


class Alter_drop :public Sql_alloc {
public:
  enum drop_type {KEY, COLUMN };
  const char *name;
  enum drop_type type;
  Alter_drop(enum drop_type par_type,const char *par_name)
    :name(par_name), type(par_type) {}
};


class Alter_column :public Sql_alloc {
public:
  const char *name;
  Item *def;
  Alter_column(const char *par_name,Item *literal)
    :name(par_name), def(literal) {}
};


class Key :public Sql_alloc {
public:
  enum Keytype { PRIMARY, UNIQUE, MULTIPLE, FULLTEXT, SPATIAL, FOREIGN_KEY};
  enum Keytype type;
  enum ha_key_alg algorithm;
  List<key_part_spec> columns;
  const char *name;

  Key(enum Keytype type_par, const char *name_arg, enum ha_key_alg alg_par,
      List<key_part_spec> &cols)
    :type(type_par), algorithm(alg_par), columns(cols), name(name_arg)
  {}
  ~Key() {}
};

class Table_ident;

class foreign_key: public Key {
public:
  enum fk_match_opt { FK_MATCH_UNDEF, FK_MATCH_FULL,
		      FK_MATCH_PARTIAL, FK_MATCH_SIMPLE};
  enum fk_option { FK_OPTION_UNDEF, FK_OPTION_RESTRICT, FK_OPTION_CASCADE,
		   FK_OPTION_SET_NULL, FK_OPTION_NO_ACTION, FK_OPTION_DEFAULT};

  Table_ident *ref_table;
  List<key_part_spec> ref_columns;
  uint delete_opt, update_opt, match_opt;
  foreign_key(const char *name_arg, List<key_part_spec> &cols,
	      Table_ident *table,   List<key_part_spec> &ref_cols,
	      uint delete_opt_arg, uint update_opt_arg, uint match_opt_arg)
    :Key(FOREIGN_KEY, name_arg, HA_KEY_ALG_UNDEF, cols),
    ref_table(table), ref_columns(cols),
    delete_opt(delete_opt_arg), update_opt(update_opt_arg),
    match_opt(match_opt_arg)
  {}
};

typedef struct st_mysql_lock
{
  TABLE **table;
  uint table_count,lock_count;
  THR_LOCK_DATA **locks;
} MYSQL_LOCK;


class LEX_COLUMN : public Sql_alloc
{
public:
  String column;
  uint rights;
  LEX_COLUMN (const String& x,const  uint& y ): column (x),rights (y) {}
};

#include "sql_lex.h"				/* Must be here */

/* Needed to be able to have an I_List of char* strings in mysqld.cc. */

class i_string: public ilink
{
public:
  char* ptr;
  i_string():ptr(0) { }
  i_string(char* s) : ptr(s) {}
};

/* needed for linked list of two strings for replicate-rewrite-db */
class i_string_pair: public ilink
{
public:
  char* key;
  char* val;
  i_string_pair():key(0),val(0) { }
  i_string_pair(char* key_arg, char* val_arg) : key(key_arg),val(val_arg) {}
};


class MYSQL_ERROR: public Sql_alloc
{
public:
  enum enum_warning_level
  { WARN_LEVEL_NOTE, WARN_LEVEL_WARN, WARN_LEVEL_ERROR, WARN_LEVEL_END};

  uint code;
  enum_warning_level level;
  char *msg;
  
  MYSQL_ERROR(THD *thd, uint code_arg, enum_warning_level level_arg,
	      const char *msg_arg)
    :code(code_arg), level(level_arg)
  {
    if (msg_arg)
      set_msg(thd, msg_arg);
  }
  void set_msg(THD *thd, const char *msg_arg);
};


class delayed_insert;
class select_result;

#define THD_SENTRY_MAGIC 0xfeedd1ff
#define THD_SENTRY_GONE  0xdeadbeef

#define THD_CHECK_SENTRY(thd) DBUG_ASSERT(thd->dbug_sentry == THD_SENTRY_MAGIC)

struct system_variables
{
  ulonglong myisam_max_extra_sort_file_size;
  ulonglong myisam_max_sort_file_size;
  ha_rows select_limit;
  ha_rows max_join_size;
  ulong bulk_insert_buff_size;
  ulong join_buff_size;
  ulong long_query_time;
  ulong max_allowed_packet;
  ulong max_error_count;
  ulong max_heap_table_size;
  ulong max_length_for_sort_data;
  ulong max_sort_length;
  ulong max_tmp_tables;
  ulong myisam_repair_threads;
  ulong myisam_sort_buff_size;
  ulong net_buffer_length;
  ulong net_interactive_timeout;
  ulong net_read_timeout;
  ulong net_retry_count;
  ulong net_wait_timeout;
  ulong net_write_timeout;
  ulong preload_buff_size;
  ulong query_cache_type;
  ulong read_buff_size;
  ulong read_rnd_buff_size;
  ulong sortbuff_size;
  ulong table_type;
  ulong tmp_table_size;
  ulong tx_isolation;
  /* Determines which non-standard SQL behaviour should be enabled */
  ulong sql_mode;
  ulong default_week_format;
  ulong max_seeks_for_key;
  ulong range_alloc_block_size;
  ulong query_alloc_block_size;
  ulong query_prealloc_size;
  ulong trans_alloc_block_size;
  ulong trans_prealloc_size;
  ulong group_concat_max_len;
  /*
    In slave thread we need to know in behalf of which
    thread the query is being run to replicate temp tables properly
  */
  ulong pseudo_thread_id;

  my_bool log_warnings;
  my_bool low_priority_updates;
  my_bool new_mode;
  my_bool old_passwords;
  
  /* Only charset part of these variables is sensible */
  CHARSET_INFO 	*character_set_client;
  CHARSET_INFO  *character_set_results;
  
  /* Both charset and collation parts of these variables are important */
  CHARSET_INFO	*collation_server;
  CHARSET_INFO	*collation_database;
  CHARSET_INFO  *collation_connection;

  /* DATE, DATETIME and TIME formats */
  DATE_TIME_FORMAT *date_format;
  DATE_TIME_FORMAT *datetime_format;
  DATE_TIME_FORMAT *time_format;
};

void free_tmp_table(THD *thd, TABLE *entry);


/*
  State of a single command executed against this connection.
  One connection can contain a lot of simultaneously running statements,
  some of which could be:
   - prepared, that is, contain placeholders,
   - opened as cursors. We maintain 1 to 1 relationship between
     statement and cursor - if user wants to create another cursor for his
     query, we create another statement for it. 
  To perform some action with statement we reset THD part to the state  of
  that statement, do the action, and then save back modified state from THD
  to the statement. It will be changed in near future, and Statement will
  be used explicitly.
*/

class Statement
{
  Statement(const Statement &rhs);              /* not implemented: */
  Statement &operator=(const Statement &rhs);   /* non-copyable */
public:
  /* FIXME: must be private */
  LEX     main_lex;
public:
  /*
    Uniquely identifies each statement object in thread scope; change during
    statement lifetime. FIXME: must be const
  */
   ulong id;

  /*
    Id of current query. Statement can be reused to execute several queries
    query_id is global in context of the whole MySQL server.
    ID is automatically generated from mutex-protected counter.
    It's used in handler code for various purposes: to check which columns
    from table are necessary for this select, to check if it's necessary to
    update auto-updatable fields (like auto_increment and timestamp).
  */
  ulong query_id;
  /*
    - if set_query_id=1, we set field->query_id for all fields. In that case 
    field list can not contain duplicates.
  */
  bool set_query_id;
  /*
    This variable is used in post-parse stage to declare that sum-functions,
    or functions which have sense only if GROUP BY is present, are allowed.
    For example in queries
    SELECT MIN(i) FROM foo
    SELECT GROUP_CONCAT(a, b, MIN(i)) FROM ... GROUP BY ...
    MIN(i) have no sense.
    Though it's grammar-related issue, it's hard to catch it out during the
    parse stage because GROUP BY clause goes in the end of query. This
    variable is mainly used in setup_fields/fix_fields.
    See item_sum.cc for details.
  */
  bool allow_sum_func;
  /*
    Type of current query: COM_PREPARE, COM_QUERY, etc. Set from 
    first byte of the packet in do_command()
  */
  enum enum_server_command command;

  LEX *lex;                                     // parse tree descriptor
  /*
    Points to the query associated with this statement. It's const, but
    we need to declare it char * because all table handlers are written
    in C and need to point to it.
  */
  char *query;
  uint32 query_length;                          // current query length
  /*
    List of items created in the parser for this query. Every item puts 
    itself to the list on creation (see Item::Item() for details))
  */
  Item *free_list;
  MEM_ROOT mem_root;

public:
  /* We build without RTTI, so dynamic_cast can't be used. */
  enum Type
  {
    STATEMENT,
    PREPARED_STATEMENT
  };

  /*
    This constructor is called when statement is a subobject of THD:
    some variables are initialized in THD::init due to locking problems
  */
  Statement();

  Statement(THD *thd);
  virtual ~Statement();

  /* Assign execution context (note: not all members) of given stmt to self */
  void set_statement(Statement *stmt);
  /* return class type */
  virtual Type type() const;
};


/*
  Used to seek all existing statements in the connection
  Deletes all statements in destructor.
*/

class Statement_map
{
public:
  Statement_map();
  
  int insert(Statement *statement)
  {
    int rc= my_hash_insert(&st_hash, (byte *) statement);
    if (rc == 0)
      last_found_statement= statement;
    return rc;
  }

  Statement *find(ulong id)
  {
    if (last_found_statement == 0 || id != last_found_statement->id)
      last_found_statement= (Statement *) hash_search(&st_hash, (byte *) &id,
                                                      sizeof(id));
    return last_found_statement;
  }
  void erase(Statement *statement)
  {
    if (statement == last_found_statement)
      last_found_statement= 0;
    hash_delete(&st_hash, (byte *) statement);
  }

  ~Statement_map()
  {
    hash_free(&st_hash);
  }
private:
  HASH st_hash;
  Statement *last_found_statement;
};


/*
  For each client connection we create a separate thread with THD serving as
  a thread/connection descriptor
*/

class THD :public ilink, 
           public Statement
{
public:
#ifdef EMBEDDED_LIBRARY
  struct st_mysql  *mysql;
  struct st_mysql_data *data;
  unsigned long	 client_stmt_id;
  unsigned long  client_param_count;
  struct st_mysql_bind *client_params;
  char *extra_data;
  ulong extra_length;
  String query_rest;
#endif
  NET	  net;				// client connection descriptor
  MEM_ROOT warn_root;			// For warnings and errors
  Protocol *protocol;			// Current protocol
  Protocol_simple protocol_simple;	// Normal protocol
  Protocol_prep protocol_prep;		// Binary protocol
  HASH    user_vars;			// hash for user variables
  String  packet;			// dynamic buffer for network I/O
  struct  sockaddr_in remote;		// client socket address
  struct  rand_struct rand;		// used for authentication
  struct  system_variables variables;	// Changeable local variables
  pthread_mutex_t LOCK_delete;		// Locked before thd is deleted

  /* all prepared statements and cursors of this connection */
  Statement_map stmt_map; 
  /*
    keeps THD state while it is used for active statement
    Note: we perform special cleanup for it in THD destructor.
  */
  Statement stmt_backup;
  /*
    A pointer to the stack frame of handle_one_connection(),
    which is called first in the thread for handling a client
  */
  char	  *thread_stack;

  /*
    host - host of the client
    user - user of the client, set to NULL until the user has been read from
     the connection
    priv_user - The user privilege we are using. May be '' for anonymous user.
    db - currently selected database
    catalog - currently selected catalog
    ip - client IP
    WARNING: some members of THD (currently 'db', 'catalog' and 'query')  are
    set and alloced by the slave SQL thread (for the THD of that thread); that
    thread is (and must remain, for now) the only responsible for freeing these
    3 members. If you add members here, and you add code to set them in
    replication, don't forget to free_them_and_set_them_to_0 in replication
    properly. For details see the 'err:' label of the pthread_handler_decl of
    the slave SQL thread, in sql/slave.cc.
   */
  char	  *host,*user,*priv_user,*db,*catalog,*ip;
  char	  priv_host[MAX_HOSTNAME];
  /* remote (peer) port */
  uint16 peer_port;
  /*
    Points to info-string that we show in SHOW PROCESSLIST
    You are supposed to update thd->proc_info only if you have coded
    a time-consuming piece that MySQL can get stuck in for a long time.
  */
  const char *proc_info;
  /* points to host if host is available, otherwise points to ip */
  const char *host_or_ip;

  ulong client_capabilities;		/* What the client supports */
  ulong max_client_packet_length;
  ulong master_access;			/* Global privileges from mysql.user */
  ulong db_access;			/* Privileges for current db */

  /*
    open_tables - list of regular tables in use by this thread
    temporary_tables - list of temp tables in use by this thread
    handler_tables - list of tables that were opened with HANDLER OPEN
     and are still in use by this thread
  */
  TABLE   *open_tables,*temporary_tables, *handler_tables, *derived_tables;
  /*
    During a MySQL session, one can lock tables in two modes: automatic
    or manual. In automatic mode all necessary tables are locked just before
    statement execution, and all acquired locks are stored in 'lock'
    member. Unlocking takes place automatically as well, when the
    statement ends.
    Manual mode comes into play when a user issues a 'LOCK TABLES'
    statement. In this mode the user can only use the locked tables.
    Trying to use any other tables will give an error. The locked tables are
    stored in 'locked_tables' member.  Manual locking is described in
    the 'LOCK_TABLES' chapter of the MySQL manual.
    See also lock_tables() for details.
  */
  MYSQL_LOCK	*lock;				/* Current locks */
  MYSQL_LOCK	*locked_tables;			/* Tables locked with LOCK */
  /*
    One thread can hold up to one named user-level lock. This variable
    points to a lock object if the lock is present. See item_func.cc and
    chapter 'Miscellaneous functions', for functions GET_LOCK, RELEASE_LOCK. 
  */
  ULL		*ull;
#ifndef DBUG_OFF
  uint dbug_sentry; // watch out for memory corruption
#endif
  struct st_my_thread_var *mysys_var;
  uint32     server_id;
  uint32     file_id;			// for LOAD DATA INFILE
  /*
    Used in error messages to tell user in what part of MySQL we found an
    error. E. g. when where= "having clause", if fix_fields() fails, user
    will know that the error was in having clause.
  */
  const char *where;
  time_t     start_time,time_after_lock,user_time;
  time_t     connect_time,thr_create_time; // track down slow pthread_create
  thr_lock_type update_lock_default;
  delayed_insert *di;
  my_bool    tablespace_op;	/* This is TRUE in DISCARD/IMPORT TABLESPACE */
  struct st_transactions {
    IO_CACHE trans_log;
    THD_TRANS all;			// Trans since BEGIN WORK
    THD_TRANS stmt;			// Trans for current statement
    uint bdb_lock_count;

    /*
       Tables changed in transaction (that must be invalidated in query cache).
       List contain only transactional tables, that not invalidated in query
       cache (instead of full list of changed in transaction tables).
    */
    CHANGED_TABLE_LIST* changed_tables;
    MEM_ROOT mem_root; // Transaction-life memory allocation pool
    void cleanup()
    {
      changed_tables = 0;
      free_root(&mem_root,MYF(MY_KEEP_PREALLOC));
    }
  } transaction;
  Field      *dupp_field;
#ifndef __WIN__
  sigset_t signals,block_signals;
#endif
#ifdef SIGNAL_WITH_VIO_CLOSE
  Vio* active_vio;
#endif
  /*
    next_insert_id is set on SET INSERT_ID= #. This is used as the next
    generated auto_increment value in handler.cc
  */
  ulonglong  next_insert_id;
  /*
    The insert_id used for the last statement or set by SET LAST_INSERT_ID=#
    or SELECT LAST_INSERT_ID(#).  Used for binary log and returned by
    LAST_INSERT_ID()
  */
  ulonglong  last_insert_id;
  /*
    Set to the first value that LAST_INSERT_ID() returned for the last
    statement.  When this is set, last_insert_id_used is set to true.
  */
  ulonglong  current_insert_id;
  ulonglong  limit_found_rows;
  ha_rows    cuted_fields,
             sent_row_count, examined_row_count;
  table_map  used_tables;
  USER_CONN *user_connect;
  CHARSET_INFO *db_charset;
  List<TABLE> temporary_tables_should_be_free; // list of temporary tables
  /*
    FIXME: this, and some other variables like 'count_cuted_fields'
    maybe should be statement/cursor local, that is, moved to Statement
    class. With current implementation warnings produced in each prepared
    statement/cursor settle here.
  */
  List	     <MYSQL_ERROR> warn_list;
  uint	     warn_count[(uint) MYSQL_ERROR::WARN_LEVEL_END];
  uint	     total_warn_count;
  ulong	     warn_id, version, options, thread_id, col_access;

  /* Statement id is thread-wide. This counter is used to generate ids */
  ulong      statement_id_counter;
  ulong	     rand_saved_seed1, rand_saved_seed2;
  ulong      row_count;  // Row counter, mainly for errors and warnings
  long	     dbug_thread_id;
  pthread_t  real_id;
  uint	     current_tablenr,tmp_table;
  uint	     server_status,open_options,system_thread;
  uint32     db_length;
  uint       select_number;             //number of select (used for EXPLAIN)
  /* variables.transaction_isolation is reset to this after each commit */
  enum_tx_isolation session_tx_isolation;
  enum_check_fields count_cuted_fields;
  /* for user variables replication*/
  DYNAMIC_ARRAY user_var_events;

  /* scramble - random string sent to client on handshake */
  char	     scramble[SCRAMBLE_LENGTH+1];

  bool       slave_thread;
  bool	     locked, some_tables_deleted;
  bool       last_cuted_field;
  bool	     no_errors, password, is_fatal_error;
  bool	     query_start_used,last_insert_id_used,insert_id_used,rand_used;
  bool	     in_lock_tables,global_read_lock;
  bool       query_error, bootstrap, cleanup_done;

  enum killed_state { NOT_KILLED=0, KILL_CONNECTION=ER_SERVER_SHUTDOWN, KILL_QUERY=ER_QUERY_INTERRUPTED };
  killed_state volatile killed;
  inline int killed_errno() const
  {
    return killed;
  }
  inline void send_kill_message() const
  {
    my_error(killed_errno(), MYF(0));
  }

  bool	     tmp_table_used;
  bool	     charset_is_system_charset, charset_is_collation_connection;
  bool       slow_command;

  sp_rcontext *spcont;		// SP runtime context
  sp_cache   *sp_proc_cache;
  sp_cache   *sp_func_cache;

  /*
    If we do a purge of binary logs, log index info of the threads
    that are currently reading it needs to be adjusted. To do that
    each thread that is using LOG_INFO needs to adjust the pointer to it
  */
  LOG_INFO*  current_linfo;
  NET*       slave_net;			// network connection from slave -> m.
  /* Used by the sys_var class to store temporary values */
  union
  {
    my_bool my_bool_value;
    long    long_value;
  } sys_var_tmp;

  THD();
  ~THD();

  void init(void);
  /*
    Initialize memory roots necessary for query processing and (!)
    pre-allocate memory for it. We can't do that in THD constructor because
    there are use cases (acl_init, delayed inserts, watcher threads,
    killing mysqld) where it's vital to not allocate excessive and not used
    memory. Note, that we still don't return error from init_for_queries():
    if preallocation fails, we should notice that at the first call to
    alloc_root. 
  */
  void init_for_queries();
  void change_user(void);
  void cleanup(void);
  bool store_globals();
#ifdef SIGNAL_WITH_VIO_CLOSE
  inline void set_active_vio(Vio* vio)
  {
    pthread_mutex_lock(&LOCK_delete);
    active_vio = vio;
    pthread_mutex_unlock(&LOCK_delete);
  }
  inline void clear_active_vio()
  {
    pthread_mutex_lock(&LOCK_delete);
    active_vio = 0;
    pthread_mutex_unlock(&LOCK_delete);
  }
  void close_active_vio();
#endif  
  void awake(THD::killed_state state_to_set);
  inline const char* enter_cond(pthread_cond_t *cond, pthread_mutex_t* mutex,
			  const char* msg)
  {
    const char* old_msg = proc_info;
    mysys_var->current_mutex = mutex;
    mysys_var->current_cond = cond;
    proc_info = msg;
    return old_msg;
  }
  inline void exit_cond(const char* old_msg)
  {
    pthread_mutex_lock(&mysys_var->mutex);
    mysys_var->current_mutex = 0;
    mysys_var->current_cond = 0;
    proc_info = old_msg;
    pthread_mutex_unlock(&mysys_var->mutex);
  }
  inline time_t query_start() { query_start_used=1; return start_time; }
  inline void	set_time()    { if (user_time) start_time=time_after_lock=user_time; else time_after_lock=time(&start_time); }
  inline void	end_time()    { time(&start_time); }
  inline void	set_time(time_t t) { time_after_lock=start_time=user_time=t; }
  inline void	lock_time()   { time(&time_after_lock); }
  inline void	insert_id(ulonglong id_arg)
  {
    last_insert_id= id_arg;
    insert_id_used=1;
  }
  inline ulonglong insert_id(void)
  {
    if (!last_insert_id_used)
    {      
      last_insert_id_used=1;
      current_insert_id=last_insert_id;
    }
    return last_insert_id;
  }
  inline ulonglong found_rows(void)
  {
    return limit_found_rows;
  }                                                                         
  inline bool active_transaction()
  {
#ifdef USING_TRANSACTIONS    
    return (transaction.all.bdb_tid != 0 ||
	    transaction.all.innodb_active_trans != 0);
#else
    return 0;
#endif
  }
  inline gptr alloc(unsigned int size) { return alloc_root(&mem_root,size); }
  inline gptr calloc(unsigned int size)
  {
    gptr ptr;
    if ((ptr=alloc_root(&mem_root,size)))
      bzero((char*) ptr,size);
    return ptr;
  }
  inline char *strdup(const char *str)
  { return strdup_root(&mem_root,str); }
  inline char *strmake(const char *str, uint size)
  { return strmake_root(&mem_root,str,size); }
  inline char *memdup(const char *str, uint size)
  { return memdup_root(&mem_root,str,size); }
  inline char *memdup_w_gap(const char *str, uint size, uint gap)
  {
    gptr ptr;
    if ((ptr=alloc_root(&mem_root,size+gap)))
      memcpy(ptr,str,size);
    return ptr;
  }
  bool convert_string(LEX_STRING *to, CHARSET_INFO *to_cs,
		      const char *from, uint from_length,
		      CHARSET_INFO *from_cs);
  inline gptr trans_alloc(unsigned int size) 
  { 
    return alloc_root(&transaction.mem_root,size);
  }
  void add_changed_table(TABLE *table);
  void add_changed_table(const char *key, long key_length);
  CHANGED_TABLE_LIST * changed_table_dup(const char *key, long key_length);
  int send_explain_fields(select_result *result);
#ifndef EMBEDDED_LIBRARY
  inline void clear_error()
  {
    net.last_error[0]= 0;
    net.last_errno= 0;
    net.report_error= 0;
  }
#else
  void clear_error();
#endif
  inline void fatal_error()
  {
    is_fatal_error= 1;
    net.report_error= 1; 
    DBUG_PRINT("error",("Fatal error set"));
  }
  inline CHARSET_INFO *charset() { return variables.character_set_client; }
  void update_charset();
};

/* Flags for the THD::system_thread (bitmap) variable */
#define SYSTEM_THREAD_DELAYED_INSERT 1
#define SYSTEM_THREAD_SLAVE_IO 2
#define SYSTEM_THREAD_SLAVE_SQL 4

/*
  Used to hold information about file and file structure in exchainge 
  via non-DB file (...INTO OUTFILE..., ...LOAD DATA...)
*/
class sql_exchange :public Sql_alloc
{
public:
  char *file_name;
  String *field_term,*enclosed,*line_term,*line_start,*escaped;
  bool opt_enclosed;
  bool dumpfile;
  ulong skip_lines;
  sql_exchange(char *name,bool dumpfile_flag);
  ~sql_exchange() {}
};

#include "log_event.h"

/*
  This is used to get result from a select
*/

class JOIN;

void send_error(THD *thd, uint sql_errno=0, const char *err=0);

class select_result :public Sql_alloc {
protected:
  THD *thd;
  SELECT_LEX_UNIT *unit;
public:
  select_result();
  virtual ~select_result() {};
  virtual int prepare(List<Item> &list, SELECT_LEX_UNIT *u)
  {
    unit= u;
    return 0;
  }
  virtual bool send_fields(List<Item> &list,uint flag)=0;
  virtual bool send_data(List<Item> &items)=0;
  virtual bool initialize_tables (JOIN *join=0) { return 0; }
  virtual void send_error(uint errcode,const char *err);
  virtual bool send_eof()=0;
  virtual void abort() {}
};


class select_send :public select_result {
public:
  select_send() {}
  bool send_fields(List<Item> &list,uint flag);
  bool send_data(List<Item> &items);
  bool send_eof();
};


class select_to_file :public select_result {
protected:
  sql_exchange *exchange;
  File file;
  IO_CACHE cache;
  ha_rows row_count;
  char path[FN_REFLEN];

public:
  select_to_file(sql_exchange *ex) :exchange(ex), file(-1),row_count(0L)
  { path[0]=0; }
  ~select_to_file();
  bool send_fields(List<Item> &list, uint flag) { return 0; }
  void send_error(uint errcode,const char *err);
};


class select_export :public select_to_file {
  uint field_term_length;
  int field_sep_char,escape_char,line_sep_char;
  bool fixed_row_size;
public:
  select_export(sql_exchange *ex) :select_to_file(ex) {}
  ~select_export();
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_data(List<Item> &items);
  bool send_eof();
};


class select_dump :public select_to_file {
public:
  select_dump(sql_exchange *ex) :select_to_file(ex) {}
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_data(List<Item> &items);
  bool send_eof();
};


class select_insert :public select_result {
 public:
  TABLE *table;
  List<Item> *fields;
  ulonglong last_insert_id;
  COPY_INFO info;

  select_insert(TABLE *table_par,List<Item> *fields_par,enum_duplicates duplic)
    :table(table_par),fields(fields_par), last_insert_id(0)
  {
    bzero((char*) &info,sizeof(info));
    info.handle_duplicates=duplic;
  }
  ~select_insert();
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_fields(List<Item> &list, uint flag)
  { return 0; }
  bool send_data(List<Item> &items);
  void send_error(uint errcode,const char *err);
  bool send_eof();
};


class select_create: public select_insert {
  ORDER *group;
  const char *db;
  const char *name;
  List<create_field> *extra_fields;
  List<Key> *keys;
  HA_CREATE_INFO *create_info;
  MYSQL_LOCK *lock;
  Field **field;
public:
  select_create (const char *db_name, const char *table_name,
		 HA_CREATE_INFO *create_info_par,
		 List<create_field> &fields_par,
		 List<Key> &keys_par,
		 List<Item> &select_fields,enum_duplicates duplic)
    :select_insert (NULL, &select_fields, duplic), db(db_name),
    name(table_name), extra_fields(&fields_par),keys(&keys_par),
    create_info(create_info_par), lock(0)
    {}
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_data(List<Item> &values);
  bool send_eof();
  void abort();
};

#include <myisam.h>

/* Param to create temporary tables when doing SELECT:s */

class TMP_TABLE_PARAM :public Sql_alloc
{
private:
  /* Prevent use of these (not safe because of lists and copy_field) */
  TMP_TABLE_PARAM(const TMP_TABLE_PARAM &);
  void operator=(TMP_TABLE_PARAM &);

public:
  List<Item> copy_funcs;
  List<Item> save_copy_funcs;
  List_iterator_fast<Item> copy_funcs_it;
  Copy_field *copy_field, *copy_field_end;
  Copy_field *save_copy_field, *save_copy_field_end;
  byte	    *group_buff;
  Item	    **items_to_copy;			/* Fields in tmp table */
  MI_COLUMNDEF *recinfo,*start_recinfo;
  KEY *keyinfo;
  ha_rows end_write_records;
  uint	field_count,sum_func_count,func_count;
  uint  hidden_field_count;
  uint	group_parts,group_length,group_null_parts;
  uint	quick_group;
  bool  using_indirect_summary_function;

  TMP_TABLE_PARAM()
    :copy_funcs_it(copy_funcs), copy_field(0), group_parts(0),
    group_length(0), group_null_parts(0)
  {}
  ~TMP_TABLE_PARAM()
  {
    cleanup();
  }
  void init(void);
  inline void cleanup(void)
  {
    if (copy_field)				/* Fix for Intel compiler */
    {
      delete [] copy_field;
      copy_field=0;
    }
  }
};

class select_union :public select_result {
 public:
  TABLE *table;
  COPY_INFO info;
  TMP_TABLE_PARAM tmp_table_param;
  bool not_describe;

  select_union(TABLE *table_par);
  ~select_union();
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_fields(List<Item> &list, uint flag)
  { return 0; }
  bool send_data(List<Item> &items);
  bool send_eof();
  bool flush();
  void set_table(TABLE *tbl) { table= tbl; }
};

/* Base subselect interface class */
class select_subselect :public select_result
{
protected:
  Item_subselect *item;
public:
  select_subselect(Item_subselect *item);
  bool send_fields(List<Item> &list, uint flag) { return 0; };
  bool send_data(List<Item> &items)=0;
  bool send_eof() { return 0; };

  friend class Ttem_subselect;
};

/* Single value subselect interface class */
class select_singlerow_subselect :public select_subselect
{
public:
  select_singlerow_subselect(Item_subselect *item):select_subselect(item){}
  bool send_data(List<Item> &items);
};

/* used in independent ALL/ANY optimisation */
class select_max_min_finder_subselect :public select_subselect
{
  Item_cache *cache;
  bool (select_max_min_finder_subselect::*op)();
  bool fmax;
public:
  select_max_min_finder_subselect(Item_subselect *item, bool mx)
    :select_subselect(item), cache(0), fmax(mx)
  {}
  bool send_data(List<Item> &items);
  bool cmp_real();
  bool cmp_int();
  bool cmp_str();
};

/* EXISTS subselect interface class */
class select_exists_subselect :public select_subselect
{
public:
  select_exists_subselect(Item_subselect *item):select_subselect(item){}
  bool send_data(List<Item> &items);
};

/* Structs used when sorting */

typedef struct st_sort_field {
  Field *field;				/* Field to sort */
  Item	*item;				/* Item if not sorting fields */
  uint	 length;			/* Length of sort field */
  Item_result result_type;		/* Type of item */
  bool reverse;				/* if descending sort */
  bool need_strxnfrm;			/* If we have to use strxnfrm() */
} SORT_FIELD;


typedef struct st_sort_buffer {
  uint index;					/* 0 or 1 */
  uint sort_orders;
  uint change_pos;				/* If sort-fields changed */
  char **buff;
  SORT_FIELD *sortorder;
} SORT_BUFFER;

/* Structure for db & table in sql_yacc */

class Table_ident :public Sql_alloc
{
 public:
  LEX_STRING db;
  LEX_STRING table;
  SELECT_LEX_UNIT *sel;
  inline Table_ident(THD *thd, LEX_STRING db_arg, LEX_STRING table_arg,
		     bool force)
    :table(table_arg), sel((SELECT_LEX_UNIT *)0)
  {
    if (!force && (thd->client_capabilities & CLIENT_NO_SCHEMA))
      db.str=0;
    else
      db= db_arg;
  }
  inline Table_ident(LEX_STRING table_arg) 
    :table(table_arg), sel((SELECT_LEX_UNIT *)0)
  {
    db.str=0;
  }
  inline Table_ident(SELECT_LEX_UNIT *s) : sel(s) 
  {
    /* We must have a table name here as this is used with add_table_to_list */
    db.str=0; table.str= internal_table_name; table.length=1;
  }
  inline void change_db(char *db_name)
  {
    db.str= db_name; db.length= (uint) strlen(db_name);
  }
};

// this is needed for user_vars hash
class user_var_entry
{
 public:
  LEX_STRING name;
  char *value;
  ulong length, update_query_id, used_query_id;
  Item_result type;

  double val(my_bool *null_value);
  longlong val_int(my_bool *null_value);
  String *val_str(my_bool *null_value, String *str, uint decimals);
  DTCollation collation;
};

/*
   Unique -- class for unique (removing of duplicates). 
   Puts all values to the TREE. If the tree becomes too big,
   it's dumped to the file. User can request sorted values, or
   just iterate through them. In the last case tree merging is performed in
   memory simultaneously with iteration, so it should be ~2-3x faster.
 */

class Unique :public Sql_alloc
{
  DYNAMIC_ARRAY file_ptrs;
  ulong max_elements, max_in_memory_size;
  IO_CACHE file;
  TREE tree;
  byte *record_pointers;
  bool flush();
  uint size;

public:
  ulong elements;
  Unique(qsort_cmp2 comp_func, void *comp_func_fixed_arg,
	 uint size_arg, ulong max_in_memory_size_arg);
  ~Unique();
  inline bool unique_add(void *ptr)
  {
    if (tree.elements_in_tree > max_elements && flush())
      return 1;
    return !tree_insert(&tree, ptr, 0, tree.custom_arg);
  }

  bool get(TABLE *table);
  static double get_use_cost(uint *buffer, uint nkeys, uint key_size, 
                             ulong max_in_memory_size);
  inline static int get_cost_calc_buff_size(ulong nkeys, uint key_size, 
                                            ulong max_in_memory_size)
  {
    register ulong max_elems_in_tree= 
      (1 + max_in_memory_size / ALIGN_SIZE(sizeof(TREE_ELEMENT)+key_size));
    return sizeof(uint)*(1 + nkeys/max_elems_in_tree);
  }

  void reset();
  bool walk(tree_walk_action action, void *walk_action_arg);

  friend int unique_write_to_file(gptr key, element_count count, Unique *unique);
  friend int unique_write_to_ptrs(gptr key, element_count count, Unique *unique);
};


class multi_delete :public select_result
{
  TABLE_LIST *delete_tables, *table_being_deleted;
  Unique **tempfiles;
  THD *thd;
  ha_rows deleted, found;
  uint num_of_tables;
  int error;
  bool do_delete, transactional_tables, log_delayed, normal_tables;
public:
  multi_delete(THD *thd, TABLE_LIST *dt, uint num_of_tables);
  ~multi_delete();
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_fields(List<Item> &list,
 		   uint flag) { return 0; }
  bool send_data(List<Item> &items);
  bool initialize_tables (JOIN *join);
  void send_error(uint errcode,const char *err);
  int  do_deletes (bool from_send_error);
  bool send_eof();
};


class multi_update :public select_result
{
  TABLE_LIST *all_tables, *update_tables, *table_being_updated;
  THD *thd;
  TABLE **tmp_tables, *main_table, *table_to_update;
  TMP_TABLE_PARAM *tmp_table_param;
  ha_rows updated, found;
  List <Item> *fields, *values;
  List <Item> **fields_for_table, **values_for_table;
  uint table_count;
  Copy_field *copy_field;
  enum enum_duplicates handle_duplicates;
  bool do_update, trans_safe, transactional_tables, log_delayed;

public:
  multi_update(THD *thd_arg, TABLE_LIST *ut, List<Item> *fields,
	       List<Item> *values, enum_duplicates handle_duplicates);
  ~multi_update();
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_fields(List<Item> &list, uint flag) { return 0; }
  bool send_data(List<Item> &items);
  bool initialize_tables (JOIN *join);
  void send_error(uint errcode,const char *err);
  int  do_updates (bool from_send_error);
  bool send_eof();
};

class my_var : public Sql_alloc  {
public:
  LEX_STRING s;
  bool local;
  uint offset;
  enum_field_types type;
  my_var (LEX_STRING& j, bool i, uint o, enum_field_types t)
    :s(j), local(i), offset(o), type(t)
  {}
  ~my_var() {}
};

class select_dumpvar :public select_result {
  ha_rows row_count;
public:
  List<my_var> var_list;
  List<Item_func_set_user_var> vars;
  List<Item_splocal> local_vars;
  select_dumpvar(void)  { var_list.empty(); local_vars.empty(); vars.empty(); row_count=0;}
  ~select_dumpvar() {}
  int prepare(List<Item> &list, SELECT_LEX_UNIT *u);
  bool send_fields(List<Item> &list, uint flag) {return 0;}
  bool send_data(List<Item> &items);
  bool send_eof();
};