/* Copyright (C) 2000 MySQL AB & MySQL Finland AB & InnoDB Oy

   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 */

/* This file defines the InnoDB handler: the interface between MySQL and
InnoDB */

/* TODO list for the InnoDB handler:
  - Ask Monty if strings of different languages can exist in the same
    database. Answer: in near future yes, but not yet.
*/

#ifdef __GNUC__
#pragma implementation				// gcc: Class implementation
#endif

#include "mysql_priv.h"
#ifdef HAVE_INNOBASE_DB
#include <m_ctype.h>
#include <assert.h>
#include <hash.h>
#include <myisampack.h>

#define MAX_ULONG_BIT ((ulong) 1 << (sizeof(ulong)*8-1))

#include "ha_innobase.h"

/* We must declare this here because we undef SAFE_MUTEX below */
pthread_mutex_t innobase_mutex;

/* Store MySQL definition of 'byte': in Linux it is char while InnoDB
uses unsigned char */
typedef byte	mysql_byte;

#ifdef SAFE_MUTEX
#undef pthread_mutex_t
#endif

#define INSIDE_HA_INNOBASE_CC

/* Include necessary InnoDB headers */
extern "C" {
#include "../innobase/include/univ.i"
#include "../innobase/include/srv0start.h"
#include "../innobase/include/srv0srv.h"
#include "../innobase/include/trx0roll.h"
#include "../innobase/include/trx0trx.h"
#include "../innobase/include/row0ins.h"
#include "../innobase/include/row0mysql.h"
#include "../innobase/include/row0sel.h"
#include "../innobase/include/row0upd.h"
#include "../innobase/include/log0log.h"
#include "../innobase/include/lock0lock.h"
#include "../innobase/include/dict0crea.h"
#include "../innobase/include/btr0cur.h"
#include "../innobase/include/btr0btr.h"
#include "../innobase/include/fsp0fsp.h"
}

#define HA_INNOBASE_ROWS_IN_TABLE 10000 /* to get optimization right */
#define HA_INNOBASE_RANGE_COUNT	  100

bool 	innodb_skip 		= 0;
uint 	innobase_init_flags 	= 0;
ulong 	innobase_cache_size 	= 0;

long innobase_mirrored_log_groups, innobase_log_files_in_group,
     innobase_log_file_size, innobase_log_buffer_size,
     innobase_buffer_pool_size, innobase_additional_mem_pool_size,
     innobase_file_io_threads, innobase_lock_wait_timeout;

char *innobase_data_home_dir, *innobase_data_file_path;
char *innobase_log_group_home_dir, *innobase_log_arch_dir;
char *innobase_unix_file_flush_method;
bool innobase_flush_log_at_trx_commit, innobase_log_archive,
	innobase_use_native_aio;

/* innobase_data_file_path=ibdata:15,idata2:1,... */

/* The following counter is used to convey information to InnoDB
about server activity: in selects it is not sensible to call
srv_active_wake_master_thread after each fetch or search, we only do
it every INNOBASE_WAKE_INTERVAL'th step. */

#define INNOBASE_WAKE_INTERVAL	32
ulong	innobase_active_counter	= 0;

char*	innobase_home 	= NULL;

char    innodb_dummy_stmt_trx_handle = 'D';

static HASH 	innobase_open_tables;

static mysql_byte* innobase_get_key(INNOBASE_SHARE *share,uint *length,
			      my_bool not_used __attribute__((unused)));
static INNOBASE_SHARE *get_share(const char *table_name);
static void free_share(INNOBASE_SHARE *share);
static void innobase_print_error(const char* db_errpfx, char* buffer);

/* General functions */

/************************************************************************
Increments innobase_active_counter and every INNOBASE_WAKE_INTERVALth
time calls srv_active_wake_master_thread. This function should be used
when a single database operation may introduce a small need for
server utility activity, like checkpointing. */
inline
void
innobase_active_small(void)
/*=======================*/
{
	innobase_active_counter++;

	if ((innobase_active_counter % INNOBASE_WAKE_INTERVAL) == 0) {
		srv_active_wake_master_thread();
	}
}

/************************************************************************
Converts an InnoDB error code to a MySQL error code. */
static
int
convert_error_code_to_mysql(
/*========================*/
			/* out: MySQL error code */
	int	error)	/* in: InnoDB error code */
{
	if (error == DB_SUCCESS) {

		return(0);

  	} else if (error == (int) DB_DUPLICATE_KEY) {

    		return(HA_ERR_FOUND_DUPP_KEY);

 	} else if (error == (int) DB_RECORD_NOT_FOUND) {

    		return(HA_ERR_NO_ACTIVE_RECORD);

 	} else if (error == (int) DB_ERROR) {

    		return(HA_ERR_NO_ACTIVE_RECORD);

 	} else if (error == (int) DB_DEADLOCK) {

    		return(1000000);

 	} else if (error == (int) DB_OUT_OF_FILE_SPACE) {

    		return(HA_ERR_RECORD_FILE_FULL);

 	} else if (error == (int) DB_TABLE_IS_BEING_USED) {

    		return(HA_ERR_WRONG_COMMAND);

 	} else if (error == (int) DB_TABLE_NOT_FOUND) {

    		return(HA_ERR_KEY_NOT_FOUND);

  	} else if (error == (int) DB_TOO_BIG_RECORD) {

    		return(HA_ERR_TO_BIG_ROW);

    	} else {
    		dbug_assert(0);

    		return(-1);			// Unknown error
    	}
}

extern "C" {
/*****************************************************************
Prints info of a THD object (== user session thread) to the
standatd output. NOTE that mysql/innobase/trx/trx0trx.c must contain
the prototype for this function! */

void
innobase_mysql_print_thd(
/*=====================*/
        void* input_thd)/* in: pointer to a MySQL THD object */
{
  	THD*  thd;

  	thd = (THD*) input_thd;

  	printf("MySQL thread id %lu, query id %lu",
	 			thd->thread_id, thd->query_id);
    	if (thd->host) {
    		printf(" %s", thd->host);
  	}

  	if (thd->ip) {
    		printf(" %s", thd->ip);
  	}

  	if (thd->user) {
    		printf(" %s", thd->user);
  	}

  	if (thd->proc_info) {
    		printf(" %s", thd->proc_info);
  	}

  	if (thd->query) {
    		printf(" %0.100s", thd->query);
  	}  

  	printf("\n");
}
}

/*************************************************************************
Gets the InnoDB transaction handle for a MySQL handler object, creates
an InnoDB transaction struct if the corresponding MySQL thread struct still
lacks one. */
static
trx_t*
check_trx_exists(
/*=============*/
			/* out: InnoDB transaction handle */
	THD*	thd)	/* in: user thread handle */
{
	trx_t*	trx;

	trx = (trx_t*) thd->transaction.all.innobase_tid;

	if (trx == NULL) {
	        dbug_assert(thd != NULL);
		trx = trx_allocate_for_mysql();

		trx->mysql_thd = thd;

		thd->transaction.all.innobase_tid = trx;

		/* The execution of a single SQL statement is denoted by
		a 'transaction' handle which is a dummy pointer: InnoDB
		remembers internally where the latest SQL statement
		started, and if error handling requires rolling back the
		latest statement, InnoDB does a rollback to a savepoint. */

		thd->transaction.stmt.innobase_tid =
		                  (void*)&innodb_dummy_stmt_trx_handle;
	}

	return(trx);
}

/*************************************************************************
Updates the user_thd field in a handle and also allocates a new InnoDB
transaction handle if needed, and updates the transaction fields in the
prebuilt struct. */
inline
int
ha_innobase::update_thd(
/*====================*/
			/* out: 0 or error code */
	THD*	thd)	/* in: thd to use the handle */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	trx_t*		trx;

	trx = check_trx_exists(thd);

	if (prebuilt->trx != trx) {

		row_update_prebuilt_trx(prebuilt, trx);
	}

	user_thd = thd;

	return(0);
}

/*************************************************************************
Reads the data files and their sizes from a character string given in
the .cnf file. */
static
bool
innobase_parse_data_file_paths_and_sizes(void)
/*==========================================*/
					/* out: TRUE if ok, FALSE if parsing
					error */
{
	char*	str;
	char*	endp;
	char*	path;
	ulint	size;
	ulint	i	= 0;

	str = innobase_data_file_path;

	/* First calculate the number of data files and check syntax:
	path:size[M];path:size[M]... . Note that a Windows path may
	contain a drive name and a ':'. */

	while (*str != '\0') {
		path = str;

		while ((*str != ':' && *str != '\0')
		       || (*str == ':'
			   && (*(str + 1) == '\\' || *(str + 1) == '/'))) {
			str++;
		}

		if (*str == '\0') {
			return(FALSE);
		}

		str++;

		size = strtoul(str, &endp, 10);

		str = endp;

		if ((*str != 'M') && (*str != 'G')) {
			size = size / (1024 * 1024);
		} else if (*str == 'G') {
		        size = size * 1024;
			str++;
		} else {
		        str++;
		}

		if (size >= 4096) {
		  fprintf(stderr,
		     "InnoDB: error: data file size must not be >= 4096M\n");
		  return(FALSE);
		}

	        if (strlen(str) >= 6
			   && *str == 'n'
			   && *(str + 1) == 'e' 
		           && *(str + 2) == 'w') {
		  str += 3;
		}

	        if (strlen(str) >= 3
			   && *str == 'r'
			   && *(str + 1) == 'a' 
		           && *(str + 2) == 'w') {
		  str += 3;
		}

		if (size == 0) {
			return(FALSE);
		}

		i++;

		if (*str == ';') {
			str++;
		} else if (*str != '\0') {

			return(FALSE);
		}
	}

	srv_data_file_names = (char**)ut_malloc(i * sizeof(void*));
	srv_data_file_sizes = (ulint*)ut_malloc(i * sizeof(ulint));
	srv_data_file_is_raw_partition = (ulint*)ut_malloc(i * sizeof(ulint));

	srv_n_data_files = i;

	/* Then store the actual values to our arrays */

	str = innobase_data_file_path;
	i = 0;

	while (*str != '\0') {
		path = str;

		/* Note that we must ignore the ':' in a Windows path */

		while ((*str != ':' && *str != '\0')
		       || (*str == ':'
			   && (*(str + 1) == '\\' || *(str + 1) == '/'))) {
			str++;
		}

		if (*str == ':') {
			/* Make path a null-terminated string */
			*str = '\0';
			str++;
		}

		size = strtoul(str, &endp, 10);

		str = endp;

		if ((*str != 'M') && (*str != 'G')) {
			size = size / (1024 * 1024);
		} else if (*str == 'G') {
		        size = size * 1024;
			str++;
		} else {
		        str++;
		}

		srv_data_file_is_raw_partition[i] = 0;

	        if (strlen(str) >= 6
			   && *str == 'n'
			   && *(str + 1) == 'e' 
		           && *(str + 2) == 'w') {
		  str += 3;
		  srv_data_file_is_raw_partition[i] = SRV_NEW_RAW;
		}

	        if (strlen(str) >= 3
			   && *str == 'r'
			   && *(str + 1) == 'a' 
		           && *(str + 2) == 'w') {
		  str += 3;
		  
		  if (srv_data_file_is_raw_partition[i] == 0) {
		    srv_data_file_is_raw_partition[i] = SRV_OLD_RAW;
		  }		  
		}

		srv_data_file_names[i] = path;
		srv_data_file_sizes[i] = size;

		i++;

		if (*str == ';') {
			str++;
		}
	}

	return(TRUE);
}

/*************************************************************************
Reads log group home directories from a character string given in
the .cnf file. */
static
bool
innobase_parse_log_group_home_dirs(void)
/*====================================*/
					/* out: TRUE if ok, FALSE if parsing
					error */
{
	char*	str;
	char*	path;
	ulint	i	= 0;

	str = innobase_log_group_home_dir;

	/* First calculate the number of directories and check syntax:
	path;path;... */

	while (*str != '\0') {
		path = str;

		while (*str != ';' && *str != '\0') {
			str++;
		}

		i++;

		if (*str == ';') {
			str++;
		} else if (*str != '\0') {

			return(FALSE);
		}
	}

	if (i != (ulint) innobase_mirrored_log_groups) {

		return(FALSE);
	}

	srv_log_group_home_dirs = (char**) ut_malloc(i * sizeof(void*));

	/* Then store the actual values to our array */

	str = innobase_log_group_home_dir;
	i = 0;

	while (*str != '\0') {
		path = str;

		while (*str != ';' && *str != '\0') {
			str++;
		}

		if (*str == ';') {
			*str = '\0';
			str++;
		}

		srv_log_group_home_dirs[i] = path;

		i++;
	}

	return(TRUE);
}

/*************************************************************************
Opens an InnoDB database. */

bool
innobase_init(void)
/*===============*/
			/* out: TRUE if error */
{
	static char 	current_dir[3];
	int		err;
	bool		ret;

  	DBUG_ENTER("innobase_init");

	if (specialflag & SPECIAL_NO_PRIOR) {
	        srv_set_thread_priorities = FALSE;
	} else {
	        srv_set_thread_priorities = TRUE;
	        srv_query_thread_priority = QUERY_PRIOR;
	}

	/* Use current_dir if no paths are set */
	current_dir[0]=FN_CURLIB;
	current_dir[1]=FN_LIBCHAR;
	current_dir[2]=0;

	/* Set InnoDB initialization parameters according to the values
	read from MySQL .cnf file */

	if (!innobase_data_file_path)
	{
	  fprintf(stderr,
       "Can't initialize InnoDB as 'innodb_data_file_path' is not set\n");
	  innodb_skip=1;
	  DBUG_RETURN(FALSE);			// Continue without innobase
	}

	srv_data_home = (innobase_data_home_dir ? innobase_data_home_dir :
			 current_dir);
	srv_logs_home = (char*) "";
	srv_arch_dir =  (innobase_log_arch_dir ? innobase_log_arch_dir :
			 current_dir);

	ret = innobase_parse_data_file_paths_and_sizes();

	if (ret == FALSE) {
	  fprintf(stderr, "InnoDB: syntax error in innodb_data_file_path\n");
	  DBUG_RETURN(TRUE);
	}

	if (!innobase_log_group_home_dir)
	  innobase_log_group_home_dir= current_dir;
	ret = innobase_parse_log_group_home_dirs();

	if (ret == FALSE) {
	  DBUG_RETURN(TRUE);
	}

	srv_unix_file_flush_method_str = (innobase_unix_file_flush_method ?
				      innobase_unix_file_flush_method :
				      (char*)"fdatasync");

	srv_n_log_groups = (ulint) innobase_mirrored_log_groups;
	srv_n_log_files = (ulint) innobase_log_files_in_group;
	srv_log_file_size = (ulint) innobase_log_file_size;

	srv_log_archive_on = (ulint) innobase_log_archive;
	srv_log_buffer_size = (ulint) innobase_log_buffer_size;
	srv_flush_log_at_trx_commit = (ulint) innobase_flush_log_at_trx_commit;

	srv_use_native_aio = 0;

	srv_pool_size = (ulint) innobase_buffer_pool_size;
	srv_mem_pool_size = (ulint) innobase_additional_mem_pool_size;

	srv_n_file_io_threads = (ulint) innobase_file_io_threads;

	srv_lock_wait_timeout = (ulint) innobase_lock_wait_timeout;

	err = innobase_start_or_create_for_mysql();

	if (err != DB_SUCCESS) {

	  DBUG_RETURN(1);
	}
	(void) hash_init(&innobase_open_tables,32,0,0,
			 (hash_get_key) innobase_get_key,0,0);
	pthread_mutex_init(&innobase_mutex,MY_MUTEX_INIT_FAST);
  	DBUG_RETURN(0);
}

/***********************************************************************
Closes an InnoDB database. */

bool
innobase_end(void)
/*==============*/
				/* out: TRUE if error */
{
	int	err;

	DBUG_ENTER("innobase_end");

	err = innobase_shutdown_for_mysql();
	hash_free(&innobase_open_tables);

	if (err != DB_SUCCESS) {

	  DBUG_RETURN(1);
	}

  	DBUG_RETURN(0);
}

/********************************************************************
Flushes InnoDB logs to disk and makes a checkpoint. Really, a commit
flushes logs, and the name of this function should be innobase_checkpoint. */

bool
innobase_flush_logs(void)
/*=====================*/
				/* out: TRUE if error */
{
  	bool 	result = 0;

  	DBUG_ENTER("innobase_flush_logs");

	log_make_checkpoint_at(ut_dulint_max, TRUE);

  	DBUG_RETURN(result);
}

/*************************************************************************
Gets the free space in an InnoDB database: returned in units of kB. */

uint
innobase_get_free_space(void)
/*=========================*/
			/* out: free space in kB */
{
	return((uint) fsp_get_available_space_in_free_extents(0));
}

/*********************************************************************
Commits a transaction in an InnoDB database. */

int
innobase_commit(
/*============*/
			/* out: 0 or error number */
	THD*	thd,	/* in: MySQL thread handle of the user for whom
			the transaction should be committed */
	void*	trx_handle)/* in: InnoDB trx handle or NULL: NULL means
			that the current SQL statement ended, and we should
			mark the start of a new statement with a savepoint */
{
	int	error	= 0;
	trx_t*	trx;

  	DBUG_ENTER("innobase_commit");
  	DBUG_PRINT("trans", ("ending transaction"));

	trx = check_trx_exists(thd);

	if (trx_handle != (void*)&innodb_dummy_stmt_trx_handle) {
		trx_commit_for_mysql(trx);
		trx_mark_sql_stat_end_do_not_start_new(trx);
	} else {
		trx_mark_sql_stat_end(trx);
	}

#ifndef DBUG_OFF
	if (error) {
    		DBUG_PRINT("error", ("error: %d", error));
    	}
#endif
	/* Tell InnoDB server that there might be work for
	utility threads: */

	srv_active_wake_master_thread();

	DBUG_RETURN(error);
}

/*********************************************************************
Rolls back a transaction in an InnoDB database. */

int
innobase_rollback(
/*==============*/
			/* out: 0 or error number */
	THD*	thd,	/* in: handle to the MySQL thread of the user
			whose transaction should be rolled back */
	void*	trx_handle)/* in: InnoDB trx handle or a dummy stmt handle */
{
	int	error = 0;
	trx_t*	trx;

	DBUG_ENTER("innobase_rollback");
	DBUG_PRINT("trans", ("aborting transaction"));

	trx = check_trx_exists(thd);

	if (trx_handle != (void*)&innodb_dummy_stmt_trx_handle) {
		error = trx_rollback_for_mysql(trx);
		trx_mark_sql_stat_end_do_not_start_new(trx);
	} else {
		error = trx_rollback_last_sql_stat_for_mysql(trx);
		trx_mark_sql_stat_end(trx);
	}

	DBUG_RETURN(convert_error_code_to_mysql(error));
}

/*********************************************************************
Frees a possible InnoDB trx object associated with the current
THD. */

int
innobase_close_connection(
/*======================*/
			/* out: 0 or error number */
	THD*	thd)	/* in: handle to the MySQL thread of the user
			whose transaction should be rolled back */
{
	if (NULL != thd->transaction.all.innobase_tid) {
	        trx_rollback_for_mysql((trx_t*)
				(thd->transaction.all.innobase_tid));
		trx_free_for_mysql((trx_t*)
				(thd->transaction.all.innobase_tid));
	}

	return(0);
}

/**********************************************************************
Prints an error message. */
static
void
innobase_print_error(
/*=================*/
	const char*	db_errpfx,	/* in: error prefix text */
	char*		buffer)		/* in: error text */
{
  	sql_print_error("%s:  %s", db_errpfx, buffer);
}


/*****************************************************************************
** InnoDB database tables
*****************************************************************************/

/********************************************************************
This function is not relevant since we store the tables and indexes
into our own tablespace, not as files, whose extension this function would
give. */

const char**
ha_innobase::bas_ext() const
/*========================*/
				/* out: file extension strings, currently not
				used */
{
	static const char* ext[] = {".InnoDB", NullS};

	return(ext);
}

/*********************************************************************
Normalizes a table name string. A normalized name consists of the
database name catenated to '/' and table name. An example:
test/mytable. */
static
void
normalize_table_name(
/*=================*/
	char*		norm_name,	/* out: normalized name as a
					null-terminated string */
	const char*	name)		/* in: table name string */
{
	char*	name_ptr;
	char*	db_ptr;
	char*	ptr;

	/* Scan name from the end */

	ptr = strend(name)-1;

	while (ptr >= name && *ptr != '\\' && *ptr != '/') {
		ptr--;
	}

	name_ptr = ptr + 1;

	dbug_assert(ptr > name);

	ptr--;

	while (ptr >= name && *ptr != '\\' && *ptr != '/') {
		ptr--;
	}

	db_ptr = ptr + 1;

	memcpy(norm_name, db_ptr, strlen(name) + 1 - (db_ptr - name));

	norm_name[name_ptr - db_ptr - 1] = '/';
}

/*********************************************************************
Creates and opens a handle to a table which already exists in an Innnobase
database. */

int
ha_innobase::open(
/*==============*/
					/* out: 1 if error, 0 if success */
	const char*	name,		/* in: table name */
	int 		mode,		/* in: not used */
	uint 		test_if_locked)	/* in: not used */
{
	dict_table_t*	ib_table;
  	int 		error	= 0;
  	uint		buff_len;
  	char		norm_name[1000];

	DBUG_ENTER("ha_innobase::open");

	UT_NOT_USED(mode);
	UT_NOT_USED(test_if_locked);

	normalize_table_name(norm_name, name);

	user_thd = NULL;

	last_query_id = (ulong)-1;

	if (!(share=get_share(name)))
	  DBUG_RETURN(1);

	/* Create buffers for packing the fields of a record. Why
	table->reclength did not work here? Obviously, because char
	fields when packed actually became 1 byte longer, when we also
	stored the string length as the first byte. */

	buff_len = table->reclength + table->max_key_length
							+ MAX_REF_PARTS * 3;
	if (!(mysql_byte*) my_multi_malloc(MYF(MY_WME),
				     &upd_buff, buff_len,
				     &key_val_buff, buff_len,
				     NullS)) {
	  	free_share(share);
	  	DBUG_RETURN(1);
  	}

	/* Get pointer to a table object in InnoDB dictionary cache */

 	if (NULL == (ib_table = dict_table_get(norm_name, NULL))) {

	  fprintf(stderr,
"Cannot find table %s from the internal data dictionary\n"
"of InnoDB though the .frm file for the table exists. Maybe you have deleted\n"
"and created again an InnoDB database but forgotten to delete the\n"
"corresponding .frm files of old InnoDB tables?\n",
		  norm_name);

	        free_share(share);
    		my_free((char*) upd_buff, MYF(0));
    		my_errno = ENOENT;
    		DBUG_RETURN(1);
  	}

	innobase_prebuilt = row_create_prebuilt(ib_table);

	((row_prebuilt_t*)innobase_prebuilt)->mysql_row_len = table->reclength;

  	primary_key = MAX_KEY;

  	if (!row_table_got_default_clust_index(ib_table)) {

		/* If we automatically created the clustered index,
		then MySQL does not know about it and it must not be aware
		of the index used on scan, to avoid checking if we update
		the column of the index. The column is the row id in
		the automatical case, and it will not be updated. */

		((row_prebuilt_t*)innobase_prebuilt)
				->clust_index_was_generated = FALSE;

		primary_key = 0;
		key_used_on_scan = 0;

 		/* MySQL allocates the buffer for ref */

  		ref_length = table->key_info->key_length
  				+ table->key_info->key_parts + 10;

  		/* One byte per key field is consumed to the SQL NULL
		info of the field; we add also 10 bytes of safety margin */
	} else {
		((row_prebuilt_t*)innobase_prebuilt)
				->clust_index_was_generated = TRUE;

  		ref_length = DATA_ROW_ID_LEN + 10;
				
		dbug_assert(key_used_on_scan == MAX_KEY);
	}

 	/* Init table lock structure */
	thr_lock_data_init(&share->lock,&lock,(void*) 0);

  	info(HA_STATUS_NO_LOCK | HA_STATUS_VARIABLE | HA_STATUS_CONST);

  	DBUG_RETURN(0);
}

/*********************************************************************
Does nothing. */

void
ha_innobase::initialize(void)
/*=========================*/
{
}

/**********************************************************************
Closes a handle to an InnoDB table. */

int
ha_innobase::close(void)
/*====================*/
				/* out: error number */
{
  	DBUG_ENTER("ha_innobase::close");

	row_prebuilt_free((row_prebuilt_t*) innobase_prebuilt);

    	my_free((char*) upd_buff, MYF(0));
        free_share(share);

	/* Tell InnoDB server that there might be work for
	utility threads: */

	srv_active_wake_master_thread();

  	DBUG_RETURN(0);
}

/* The following accessor functions should really be inside MySQL code! */

/******************************************************************
Gets field offset for a field in a table. */
inline
uint
get_field_offset(
/*=============*/
			/* out: offset */
	TABLE*	table,	/* in: MySQL table object */
	Field*	field)	/* in: MySQL field object */
{
	return((uint) (field->ptr - (char*) table->record[0]));
}

/******************************************************************
Checks if a field in a record is SQL NULL. Uses the record format
information in table to track the null bit in record. */
inline
uint
field_in_record_is_null(
/*====================*/
			/* out: 1 if NULL, 0 otherwise */
	TABLE*	table,	/* in: MySQL table object */
	Field*	field,	/* in: MySQL field object */
	char*	record)	/* in: a row in MySQL format */
{
	int	null_offset;

	if (!field->null_ptr) {

		return(0);
	}

	null_offset = (uint) ((char*) field->null_ptr
					- (char*) table->record[0]);

	if (record[null_offset] & field->null_bit) {

		return(1);
	}

	return(0);
}

/******************************************************************
Sets a field in a record to SQL NULL. Uses the record format
information in table to track the null bit in record. */
inline
void
set_field_in_record_to_null(
/*========================*/
	TABLE*	table,	/* in: MySQL table object */
	Field*	field,	/* in: MySQL field object */
	char*	record)	/* in: a row in MySQL format */
{
	int	null_offset;

	null_offset = (uint) ((char*) field->null_ptr
					- (char*) table->record[0]);

	record[null_offset] = record[null_offset] | field->null_bit;
}

/******************************************************************
Resets SQL NULL bits in a record to zero. */
inline
void
reset_null_bits(
/*============*/
	TABLE*	table,	/* in: MySQL table object */
	char*	record)	/* in: a row in MySQL format */
{
	bzero(record, table->null_bytes);
}

extern "C" {
/*****************************************************************
InnoDB uses this function is to compare two data fields for which the
data type is such that we must use MySQL code to compare them. NOTE that the
prototype of this function is in rem0cmp.c in InnoDB source code!
If you change this function, remember to update the prototype there! */

int
innobase_mysql_cmp(
/*===============*/
					/* out: 1, 0, -1, if a is greater,
					equal, less than b, respectively */
	int		mysql_type,	/* in: MySQL type */
	unsigned char*	a,		/* in: data field */
	unsigned int	a_length,	/* in: data field length,
					not UNIV_SQL_NULL */
	unsigned char*	b,		/* in: data field */
	unsigned int	b_length)	/* in: data field length,
					not UNIV_SQL_NULL */
{
	enum_field_types	mysql_tp;
	int                     ret;

	dbug_assert(a_length != UNIV_SQL_NULL);
	dbug_assert(b_length != UNIV_SQL_NULL);

	mysql_tp = (enum_field_types) mysql_type;

	switch (mysql_tp) {

	case FIELD_TYPE_STRING:
	case FIELD_TYPE_VAR_STRING:
  		ret = my_sortncmp((const char*) a, a_length,
				  (const char*) b, b_length);
		if (ret < 0) {
		  return(-1);
		} else if (ret > 0) {
		  return(1);
		} else {
		  return(0);
	        }
	default:
		assert(0);
	}

	return(0);
}
}

/******************************************************************
Converts a MySQL type to an InnoDB type. */
inline
ulint
get_innobase_type_from_mysql_type(
/*==============================*/
			/* out: DATA_BINARY, DATA_VARCHAR, ... */
	Field*	field)	/* in: MySQL field */
{
	/* The following asserts check that MySQL type code fits in
	8 bits: this is used in ibuf and also when DATA_NOT_NULL is
	ORed to the type */

	dbug_assert((ulint)FIELD_TYPE_STRING < 256);
	dbug_assert((ulint)FIELD_TYPE_VAR_STRING < 256);
	dbug_assert((ulint)FIELD_TYPE_DOUBLE < 256);
	dbug_assert((ulint)FIELD_TYPE_FLOAT < 256);
	dbug_assert((ulint)FIELD_TYPE_DECIMAL < 256);

	switch (field->type()) {
		case FIELD_TYPE_VAR_STRING: if (field->flags & BINARY_FLAG) {

						return(DATA_BINARY);
					} else if (strcmp(
						   default_charset_info->name,
							"latin1") == 0) {
						return(DATA_VARCHAR);
					} else {
						return(DATA_VARMYSQL);
					}
		case FIELD_TYPE_STRING: if (field->flags & BINARY_FLAG) {

						return(DATA_FIXBINARY);
					} else if (strcmp(
						   default_charset_info->name,
							"latin1") == 0) {
						return(DATA_CHAR);
					} else {
						return(DATA_MYSQL);
					}
		case FIELD_TYPE_LONG:
		case FIELD_TYPE_LONGLONG:
		case FIELD_TYPE_TINY:
		case FIELD_TYPE_SHORT:
		case FIELD_TYPE_INT24:
		case FIELD_TYPE_DATE:
		case FIELD_TYPE_DATETIME:
		case FIELD_TYPE_YEAR:
		case FIELD_TYPE_NEWDATE:
		case FIELD_TYPE_ENUM:
		case FIELD_TYPE_SET:
		case FIELD_TYPE_TIME:
		case FIELD_TYPE_TIMESTAMP:
					return(DATA_INT);
		case FIELD_TYPE_FLOAT:
					return(DATA_FLOAT);
		case FIELD_TYPE_DOUBLE:
					return(DATA_DOUBLE);
		case FIELD_TYPE_DECIMAL:
					return(DATA_DECIMAL);
		case FIELD_TYPE_TINY_BLOB:
		case FIELD_TYPE_MEDIUM_BLOB:
		case FIELD_TYPE_BLOB:
		case FIELD_TYPE_LONG_BLOB:
					return(DATA_BLOB);
		default:
					assert(0);
	}

	return(0);
}

/***********************************************************************
Stores a key value for a row to a buffer. */

uint
ha_innobase::store_key_val_for_row(
/*===============================*/
				/* out: key value length as stored in buff */
	uint 		keynr,	/* in: key number */
	char*		buff,	/* in/out: buffer for the key value (in MySQL
				format) */
	const mysql_byte* record)/* in: row in MySQL format */
{
	KEY*		key_info 	= table->key_info + keynr;
  	KEY_PART_INFO*	key_part	= key_info->key_part;
  	KEY_PART_INFO*	end		= key_part + key_info->key_parts;
	char*		buff_start	= buff;

  	DBUG_ENTER("store_key_val_for_row");

  	for (; key_part != end; key_part++) {

    		if (key_part->null_bit) {
      			/* Store 0 if the key part is a NULL part */

      			if (record[key_part->null_offset]
						& key_part->null_bit) {
				*buff++ = 1;
				continue;
      			}

      			*buff++ = 0;
    		}

		memcpy(buff, record + key_part->offset, key_part->length);
		buff += key_part->length;
  	}

	DBUG_RETURN(buff - buff_start);
}

/******************************************************************
Builds a template to the prebuilt struct. */
static
void
build_template(
/*===========*/
	row_prebuilt_t*	prebuilt,	/* in: prebuilt struct */
	THD*		thd,		/* in: current user thread, used
					only if templ_type is
					ROW_MYSQL_REC_FIELDS */
	TABLE*		table,		/* in: MySQL table */
	ulint		templ_type)	/* in: ROW_MYSQL_WHOLE_ROW or
					ROW_MYSQL_REC_FIELDS */
{
	dict_index_t*	index;
	dict_index_t*	clust_index;
	mysql_row_templ_t* templ;
	Field*		field;
	ulint		n_fields;
	ulint		n_requested_fields	= 0;
	ulint		i;

	clust_index = dict_table_get_first_index_noninline(prebuilt->table);

	if (!prebuilt->in_update_remember_pos) {
		/* We are building a temporary table: fetch all columns */

		templ_type = ROW_MYSQL_WHOLE_ROW;
	}

	if (prebuilt->select_lock_type == LOCK_X) {
	  /* TODO: should fix the code in sql_update so that we could do
	     with fetching only the needed columns */

	        templ_type = ROW_MYSQL_WHOLE_ROW;
	}


	if (templ_type == ROW_MYSQL_REC_FIELDS) {

		if (prebuilt->select_lock_type != LOCK_NONE) {
			/* Let index be the clustered index */

			index = clust_index;
		} else {
			index = prebuilt->index;
		}
	} else {
		index = clust_index;
	}

	if (index == clust_index) {
		prebuilt->need_to_access_clustered = TRUE;
	} else {
		prebuilt->need_to_access_clustered = FALSE;
		/* Below we check column by column if we need to access
		the clustered index */
	}

	n_fields = (ulint)table->fields;

	if (!prebuilt->mysql_template) {
		prebuilt->mysql_template = (mysql_row_templ_t*)
						mem_alloc_noninline(
					n_fields * sizeof(mysql_row_templ_t));
	}

	prebuilt->template_type = templ_type;
	prebuilt->null_bitmap_len = table->null_bytes;

	prebuilt->templ_contains_blob = FALSE;

	for (i = 0; i < n_fields; i++) {
		templ = prebuilt->mysql_template + n_requested_fields;
		field = table->field[i];

		if (templ_type == ROW_MYSQL_REC_FIELDS
			&& thd->query_id != field->query_id
			&& thd->query_id != (field->query_id ^ MAX_ULONG_BIT)
			&& thd->query_id !=
				(field->query_id ^ (MAX_ULONG_BIT >> 1))) {

			/* This field is not needed in the query, skip it */

			goto skip_field;
		}

		n_requested_fields++;

		templ->col_no = i;

		if (index == clust_index) {
			templ->rec_field_no = (index->table->cols + i)
								->clust_pos;
		} else {
			templ->rec_field_no = dict_index_get_nth_col_pos(
								index, i);
		}

		if (templ->rec_field_no == ULINT_UNDEFINED) {
			prebuilt->need_to_access_clustered = TRUE;
		}

		if (field->null_ptr) {
			templ->mysql_null_byte_offset =
				(ulint) ((char*) field->null_ptr
					- (char*) table->record[0]);

			templ->mysql_null_bit_mask = (ulint) field->null_bit;
		} else {
			templ->mysql_null_bit_mask = 0;
		}

		templ->mysql_col_offset = (ulint)
					get_field_offset(table, field);

		templ->mysql_col_len = (ulint) field->pack_length();
		templ->type = get_innobase_type_from_mysql_type(field);
		templ->is_unsigned = (ulint) (field->flags & UNSIGNED_FLAG);

		if (templ->type == DATA_BLOB) {
			prebuilt->templ_contains_blob = TRUE;
		}
skip_field:
		;
	}

	prebuilt->n_template = n_requested_fields;

	if (prebuilt->need_to_access_clustered) {
		/* Change rec_field_no's to correspond to the clustered index
		record */
		for (i = 0; i < n_requested_fields; i++) {
			templ = prebuilt->mysql_template + i;

			templ->rec_field_no =
			    (index->table->cols + templ->col_no)->clust_pos;
		}
	}

	if (templ_type == ROW_MYSQL_REC_FIELDS
				&& prebuilt->select_lock_type != LOCK_NONE) {

		prebuilt->need_to_access_clustered = TRUE;
	}
}

/************************************************************************
Stores a row in an InnoDB database, to the table specified in this
handle. */

int
ha_innobase::write_row(
/*===================*/
				/* out: error code */
	mysql_byte* 	record)	/* in: a row in MySQL format */
{
	row_prebuilt_t* prebuilt = (row_prebuilt_t*)innobase_prebuilt;
  	int 		error;
	longlong	auto_inc;
	
  	DBUG_ENTER("ha_innobase::write_row");

  	statistic_increment(ha_write_count, &LOCK_status);

  	if (table->time_stamp) {
    		update_timestamp(record + table->time_stamp - 1);
    	}

	if (last_query_id != user_thd->query_id) {
	        prebuilt->sql_stat_start = TRUE;
                last_query_id = user_thd->query_id;
	}

  	if (table->next_number_field && record == table->record[0]) {
	        /* Set the 'in_update_remember_pos' flag to FALSE to
	        make sure all columns are fetched in the select done by
	        update_auto_increment */

	        /* Fetch the value the user possibly has set in the
	        autoincrement field */
	        
	        auto_inc = table->next_number_field->val_int();

		/* In replication and also otherwise the auto-inc column 
		can be set with SET INSERT_ID. Then we must look at
		user_thd->next_insert_id. If it is nonzero and the user
		has not supplied a value, we must use it. */

		if (auto_inc == 0 && user_thd->next_insert_id != 0) {
		        auto_inc = user_thd->next_insert_id;
		}

		if (auto_inc != 0) {
			/* This call will calculate the max of the
			current value and the value supplied by the user, if
			the auto_inc counter is already initialized
			for the table */
			dict_table_autoinc_update(prebuilt->table, auto_inc);
		} else {
			auto_inc = dict_table_autoinc_get(prebuilt->table);

			/* If auto_inc is now != 0 the autoinc counter
			was already initialized for the table: we can give
			the new value for MySQL to place in the field */

			if (auto_inc != 0) {
				user_thd->next_insert_id = auto_inc;
			}
		}
	        
	        prebuilt->in_update_remember_pos = FALSE;
	        
    		update_auto_increment();

		if (auto_inc == 0) {
			/* The autoinc counter for our table was not yet
			initialized, initialize it now */

	        	auto_inc = table->next_number_field->val_int();

			dict_table_autoinc_initialize(prebuilt->table,
								auto_inc);
		}
    		
		/* We have to set sql_stat_start to TRUE because
		update_auto_increment has called a select, and
		has reset that flag; row_insert_for_mysql has to
		know to set the IX intention lock on the table, something
		it only does at the start of each statement */

		prebuilt->sql_stat_start = TRUE;
    	}

	if (prebuilt->mysql_template == NULL
			|| prebuilt->template_type != ROW_MYSQL_WHOLE_ROW) {
		/* Build the template used in converting quickly between
		the two database formats */

		build_template(prebuilt, NULL, table, ROW_MYSQL_WHOLE_ROW);
	}

	if (user_thd->lex.sql_command == SQLCOM_INSERT
	    && user_thd->lex.duplicates == DUP_IGNORE) {
	        prebuilt->trx->ignore_duplicates_in_insert = TRUE;
        } else {
	        prebuilt->trx->ignore_duplicates_in_insert = FALSE;
	}

	error = row_insert_for_mysql((byte*) record, prebuilt);

	prebuilt->trx->ignore_duplicates_in_insert = FALSE;

	error = convert_error_code_to_mysql(error);

	/* Tell InnoDB server that there might be work for
	utility threads: */

	innobase_active_small();

  	DBUG_RETURN(error);
}

/******************************************************************
Converts field data for storage in an InnoDB update vector. */
inline
mysql_byte*
innobase_convert_and_store_changed_col(
/*===================================*/
				/* out: pointer to the end of the converted
				data in the buffer */
	upd_field_t*	ufield,	/* in/out: field in the update vector */
	mysql_byte*	buf,	/* in: buffer we can use in conversion */
	mysql_byte*	data,	/* in: column data to store */
	ulint		len,	/* in: data len */
	ulint		col_type,/* in: data type in InnoDB type numbers */
	ulint		is_unsigned)/* in: != 0 if an unsigned integer type */
{
	uint	i;

	if (len == UNIV_SQL_NULL) {
		data = NULL;
	} else if (col_type == DATA_VARCHAR || col_type == DATA_BINARY
		   || col_type == DATA_VARMYSQL) {
	        /* Remove trailing spaces */
        	while (len > 0 && data[len - 1] == ' ') {
	                len--;
	        }

	} else if (col_type == DATA_INT) {
		/* Store integer data in InnoDB in a big-endian
		format, sign bit negated, if signed */

		for (i = 0; i < len; i++) {
			buf[len - 1 - i] = data[i];
		}

		if (!is_unsigned) {
			buf[0] = buf[0] ^ 128;
		}

		data = buf;

		buf += len;
	}

	ufield->new_val.data = data;
	ufield->new_val.len = len;

	return(buf);
}

/**************************************************************************
Checks which fields have changed in a row and stores information
of them to an update vector. */
static
int
calc_row_difference(
/*================*/
					/* out: error number or 0 */
	upd_t*		uvect,		/* in/out: update vector */
	mysql_byte* 	old_row,	/* in: old row in MySQL format */
	mysql_byte* 	new_row,	/* in: new row in MySQL format */
	struct st_table* table,		/* in: table in MySQL data dictionary */
	mysql_byte*	upd_buff,	/* in: buffer to use */
	row_prebuilt_t*	prebuilt,	/* in: InnoDB prebuilt struct */
	THD*		thd)		/* in: user thread */
{
	Field*		field;
	uint		n_fields;
	ulint		o_len;
	ulint		n_len;
	byte*	        o_ptr;
        byte*	        n_ptr;
        byte*	        buf;
	upd_field_t*	ufield;
	ulint		col_type;
	ulint		is_unsigned;
	ulint		n_changed = 0;
	uint		i;

	n_fields = table->fields;

	/* We use upd_buff to convert changed fields */
	buf = (byte*) upd_buff;

	for (i = 0; i < n_fields; i++) {
		field = table->field[i];

		/* if (thd->query_id != field->query_id) { */
			/* TODO: check that these fields cannot have
			changed! */

		/*	goto skip_field;
		}*/

		o_ptr = (byte*) old_row + get_field_offset(table, field);
		n_ptr = (byte*) new_row + get_field_offset(table, field);
		o_len = field->pack_length();
		n_len = field->pack_length();

		col_type = get_innobase_type_from_mysql_type(field);
		is_unsigned = (ulint) (field->flags & UNSIGNED_FLAG);

		switch (col_type) {

		case DATA_BLOB:
			o_ptr = row_mysql_read_blob_ref(&o_len, o_ptr, o_len);
			n_ptr = row_mysql_read_blob_ref(&n_len, n_ptr, n_len);
			break;
		case DATA_VARCHAR:
		case DATA_BINARY:
		case DATA_VARMYSQL:
			o_ptr = row_mysql_read_var_ref_noninline(&o_len, o_ptr);
			n_ptr = row_mysql_read_var_ref_noninline(&n_len, n_ptr);
		default:
			;
		}

		if (field->null_ptr) {
			if (field_in_record_is_null(table, field,
							(char*) old_row)) {
				o_len = UNIV_SQL_NULL;
			}

			if (field_in_record_is_null(table, field,
							(char*) new_row)) {
				n_len = UNIV_SQL_NULL;
			}
		}

		if (o_len != n_len || (o_len != UNIV_SQL_NULL &&
					0 != memcmp(o_ptr, n_ptr, o_len))) {
			/* The field has changed */

			ufield = uvect->fields + n_changed;

			buf = (byte*)
                          innobase_convert_and_store_changed_col(ufield,
					  (mysql_byte*)buf,
					  (mysql_byte*)n_ptr, n_len, col_type,
						is_unsigned);
			ufield->exp = NULL;
			ufield->field_no =
					(prebuilt->table->cols + i)->clust_pos;
			n_changed++;
		}
		;
	}

	uvect->n_fields = n_changed;
	uvect->info_bits = 0;

	return(0);
}

/**************************************************************************
Updates a row given as a parameter to a new value. Note that we are given
whole rows, not just the fields which are updated: this incurs some
overhead for CPU when we check which fields are actually updated.
TODO: currently InnoDB does not prevent the 'Halloween problem':
in a searched update a single row can get updated several times
if its index columns are updated! */

int
ha_innobase::update_row(
/*====================*/
					/* out: error number or 0 */
	const mysql_byte* 	old_row,/* in: old row in MySQL format */
	mysql_byte* 		new_row)/* in: new row in MySQL format */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	upd_t*		uvect;
	int		error = 0;

	DBUG_ENTER("ha_innobase::update_row");

        if (table->time_stamp) {
                update_timestamp(new_row + table->time_stamp - 1);
	}

	if (last_query_id != user_thd->query_id) {
	        prebuilt->sql_stat_start = TRUE;
                last_query_id = user_thd->query_id;
	}

	if (prebuilt->upd_node) {
		uvect = prebuilt->upd_node->update;
	} else {
		uvect = row_get_prebuilt_update_vector(prebuilt);
	}

	/* Build an update vector from the modified fields in the rows
	(uses upd_buff of the handle) */

	calc_row_difference(uvect, (mysql_byte*) old_row, new_row, table,
						upd_buff, prebuilt, user_thd);
	/* This is not a delete */
	prebuilt->upd_node->is_delete = FALSE;

	if (!prebuilt->in_update_remember_pos) {
		assert(prebuilt->template_type == ROW_MYSQL_WHOLE_ROW);
	}

	error = row_update_for_mysql((byte*) old_row, prebuilt);

	error = convert_error_code_to_mysql(error);

	/* Tell InnoDB server that there might be work for
	utility threads: */

	innobase_active_small();

	DBUG_RETURN(error);
}

/**************************************************************************
Deletes a row given as the parameter. */

int
ha_innobase::delete_row(
/*====================*/
					/* out: error number or 0 */
	const mysql_byte* record)	/* in: a row in MySQL format */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	int		error = 0;

	DBUG_ENTER("ha_innobase::delete_row");

	if (last_query_id != user_thd->query_id) {
	        prebuilt->sql_stat_start = TRUE;
                last_query_id = user_thd->query_id;
	}

	if (!prebuilt->upd_node) {
		row_get_prebuilt_update_vector(prebuilt);
	}

	/* This is a delete */

	prebuilt->upd_node->is_delete = TRUE;
	prebuilt->in_update_remember_pos = TRUE;

	error = row_update_for_mysql((byte*) record, prebuilt);

	error = convert_error_code_to_mysql(error);

	/* Tell the InnoDB server that there might be work for
	utility threads: */

	innobase_active_small();

	DBUG_RETURN(error);
}

/**********************************************************************
Initializes a handle to use an index. */

int
ha_innobase::index_init(
/*====================*/
			/* out: 0 or error number */
	uint 	keynr)	/* in: key (index) number */
{
	int 	error	= 0;
  	DBUG_ENTER("index_init");

	change_active_index(keynr);

  	DBUG_RETURN(error);
}

/**********************************************************************
?????????????????????????????????? */

int
ha_innobase::index_end(void)
/*========================*/
{
	int 	error	= 0;
  	DBUG_ENTER("index_end");

  	DBUG_RETURN(error);
}

/*************************************************************************
Converts a search mode flag understood by MySQL to a flag understood
by InnoDB. */
inline
ulint
convert_search_mode_to_innobase(
/*============================*/
	enum ha_rkey_function	find_flag)
{
	switch (find_flag) {
  		case HA_READ_KEY_EXACT:		return(PAGE_CUR_GE);
  			/* the above does not require the index to be UNIQUE */
  		case HA_READ_KEY_OR_NEXT:	return(PAGE_CUR_GE);
		case HA_READ_KEY_OR_PREV:	return(PAGE_CUR_LE);
		case HA_READ_AFTER_KEY:		return(PAGE_CUR_G);
		case HA_READ_BEFORE_KEY:	return(PAGE_CUR_L);
		case HA_READ_PREFIX:		return(PAGE_CUR_GE);
		case HA_READ_PREFIX_LAST:	return(PAGE_CUR_LE);
			/* the above PREFIX flags mean that the last
			field in the key value may just be a prefix
			of the complete fixed length field */
		default:			assert(0);
	}

	return(0);
}

/**************************************************************************
Positions an index cursor to the index specified in the handle. Fetches the
row if any. */

int
ha_innobase::index_read(
/*====================*/
					/* out: 0, HA_ERR_KEY_NOT_FOUND,
					or error number */
	mysql_byte*		buf,	/* in/out: buffer for the returned
					row */
	const mysql_byte* 	key_ptr,/* in: key value; if this is NULL
					we position the cursor at the
					start or end of index */
	uint			key_len,/* in: key value length */
	enum ha_rkey_function find_flag)/* in: search flags from my_base.h */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
	ulint		mode;
	dict_index_t*	index;
	ulint		match_mode 	= 0;
	int 		error;
	ulint		ret;

  	DBUG_ENTER("index_read");
  	statistic_increment(ha_read_key_count, &LOCK_status);

	if (last_query_id != user_thd->query_id) {
	        prebuilt->sql_stat_start = TRUE;
                last_query_id = user_thd->query_id;
	}

	index = prebuilt->index;

	/* Note that if the select is used for an update, we always
	fetch the clustered index record: therefore the index for which the
	template is built is not necessarily prebuilt->index, but can also
	be the clustered index */

	if (prebuilt->sql_stat_start) {
		build_template(prebuilt, user_thd, table,
							ROW_MYSQL_REC_FIELDS);
	}

	if (key_ptr) {
		row_sel_convert_mysql_key_to_innobase(prebuilt->search_tuple,
							(byte*) key_val_buff,
							index,
							(byte*) key_ptr,
							(ulint) key_len);
	} else {
		/* We position the cursor to the last or the first entry
		in the index */

 		dtuple_set_n_fields(prebuilt->search_tuple, 0);
	}

	mode = convert_search_mode_to_innobase(find_flag);

	match_mode = 0;

	if (find_flag == HA_READ_KEY_EXACT) {
		match_mode = ROW_SEL_EXACT;

	} else if (find_flag == HA_READ_PREFIX
				|| find_flag == HA_READ_PREFIX_LAST) {
		match_mode = ROW_SEL_EXACT_PREFIX;
	}

	last_match_mode = match_mode;

	ret = row_search_for_mysql((byte*) buf, mode, prebuilt, match_mode, 0);

	if (ret == DB_SUCCESS) {
		error = 0;
		table->status = 0;

	} else if (ret == DB_RECORD_NOT_FOUND) {
		error = HA_ERR_KEY_NOT_FOUND;
		table->status = STATUS_NOT_FOUND;

	} else if (ret == DB_END_OF_INDEX) {
		error = HA_ERR_KEY_NOT_FOUND;
		table->status = STATUS_NOT_FOUND;
	} else {
		error = convert_error_code_to_mysql(ret);
		table->status = STATUS_NOT_FOUND;
	}

	DBUG_RETURN(error);
}

/************************************************************************
Changes the active index of a handle. */

int
ha_innobase::change_active_index(
/*=============================*/
			/* out: 0 or error code */
	uint 	keynr)	/* in: use this index; MAX_KEY means always clustered
			index, even if it was internally generated by
			InnoDB */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
	KEY*		key;

  	statistic_increment(ha_read_key_count, &LOCK_status);

  	DBUG_ENTER("index_read_idx");

	active_index = keynr;

	if (keynr != MAX_KEY && table->keys > 0) {
		key = table->key_info + active_index;

		prebuilt->index = dict_table_get_index_noninline(
						prebuilt->table, key->name);
	} else {
		prebuilt->index = dict_table_get_first_index_noninline(
							prebuilt->table);
	}

	dtuple_set_n_fields(prebuilt->search_tuple, prebuilt->index->n_fields);

 	dict_index_copy_types(prebuilt->search_tuple, prebuilt->index,
						prebuilt->index->n_fields);
	assert(prebuilt->index);

	/* Maybe MySQL changes the active index for a handle also
	during some queries, we do not know: then it is safest to build
	the template such that all columns will be fetched */

	build_template(prebuilt, user_thd, table, ROW_MYSQL_WHOLE_ROW);

	return(0);
}

/**************************************************************************
Positions an index cursor to the index specified in keynr. Fetches the
row if any. */
/* ??? This is only used to read whole keys ??? */

int
ha_innobase::index_read_idx(
/*========================*/
					/* out: error number or 0 */
	mysql_byte*	buf,		/* in/out: buffer for the returned
					row */
	uint 		keynr,		/* in: use this index */
	const mysql_byte* key,		/* in: key value; if this is NULL
					we position the cursor at the
					start or end of index */
	uint		key_len,	/* in: key value length */
	enum ha_rkey_function find_flag)/* in: search flags from my_base.h */
{
	change_active_index(keynr);

	return(index_read(buf, key, key_len, find_flag));
}

/***************************************************************************
Reads the next or previous row from a cursor, which must have previously been
positioned using index_read. */

int
ha_innobase::general_fetch(
/*=======================*/
				/* out: 0, HA_ERR_END_OF_FILE, or error
				number */
	mysql_byte* 	buf,	/* in/out: buffer for next row in MySQL
				format */
	uint 	direction,	/* in: ROW_SEL_NEXT or ROW_SEL_PREV */
	uint	match_mode)	/* in: 0, ROW_SEL_EXACT, or
				ROW_SEL_EXACT_PREFIX */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	ulint		ret;
	int		error	= 0;

	DBUG_ENTER("general_fetch");

	ret = row_search_for_mysql((byte*)buf, 0, prebuilt,
                       match_mode, direction);

	if (ret == DB_SUCCESS) {
		error = 0;
		table->status = 0;

	} else if (ret == DB_RECORD_NOT_FOUND) {
		error = HA_ERR_END_OF_FILE;
		table->status = STATUS_NOT_FOUND;

	} else if (ret == DB_END_OF_INDEX) {
		error = HA_ERR_END_OF_FILE;
		table->status = STATUS_NOT_FOUND;
	} else {
		error = convert_error_code_to_mysql(ret);
		table->status = STATUS_NOT_FOUND;
	}

	DBUG_RETURN(error);
}

/***************************************************************************
Reads the next row from a cursor, which must have previously been
positioned using index_read. */

int
ha_innobase::index_next(
/*====================*/
				/* out: 0, HA_ERR_END_OF_FILE, or error
				number */
	mysql_byte* 	buf)	/* in/out: buffer for next row in MySQL
				format */
{
  	statistic_increment(ha_read_next_count, &LOCK_status);

	return(general_fetch(buf, ROW_SEL_NEXT, 0));
}

/***********************************************************************
Reads the next row matching to the key value given as the parameter. */

int
ha_innobase::index_next_same(
/*=========================*/
				/* out: 0, HA_ERR_END_OF_FILE, or error
				number */
	mysql_byte* 	buf,	/* in/out: buffer for the row */
	const mysql_byte* key,	/* in: key value */
	uint 		keylen)	/* in: key value length */
{
  	statistic_increment(ha_read_next_count, &LOCK_status);

	return(general_fetch(buf, ROW_SEL_NEXT, last_match_mode));
}

/***************************************************************************
Reads the previous row from a cursor, which must have previously been
positioned using index_read. */

int
ha_innobase::index_prev(
/*====================*/
				/* out: 0, HA_ERR_END_OF_FILE, or error
				number */
	mysql_byte* 	buf)	/* in/out: buffer for previous row in MySQL
				format */
{
	return(general_fetch(buf, ROW_SEL_PREV, 0));
}

/************************************************************************
Positions a cursor on the first record in an index and reads the
corresponding row to buf. */

int
ha_innobase::index_first(
/*=====================*/
				/* out: 0, HA_ERR_END_OF_FILE,
				or error code */
	mysql_byte*	buf)	/* in/out: buffer for the row */
{
	int	error;

  	DBUG_ENTER("index_first");
  	statistic_increment(ha_read_first_count, &LOCK_status);

  	error = index_read(buf, NULL, 0, HA_READ_AFTER_KEY);

        /* MySQL does not seem to allow this to return HA_ERR_KEY_NOT_FOUND */

  	if (error == HA_ERR_KEY_NOT_FOUND) {
  		error = HA_ERR_END_OF_FILE;
  	}

  	DBUG_RETURN(error);
}

/************************************************************************
Positions a cursor on the last record in an index and reads the
corresponding row to buf. */

int
ha_innobase::index_last(
/*====================*/
				/* out: 0, HA_ERR_END_OF_FILE, or error code */
	mysql_byte*	buf)	/* in/out: buffer for the row */
{
	int	error;

  	DBUG_ENTER("index_first");
  	statistic_increment(ha_read_last_count, &LOCK_status);

  	error = index_read(buf, NULL, 0, HA_READ_BEFORE_KEY);

        /* MySQL does not seem to allow this to return HA_ERR_KEY_NOT_FOUND */

  	if (error == HA_ERR_KEY_NOT_FOUND) {
  		error = HA_ERR_END_OF_FILE;
  	}

  	DBUG_RETURN(error);
}

/********************************************************************
Initialize a table scan. */

int
ha_innobase::rnd_init(
/*==================*/
			/* out: 0 or error number */
	bool	scan)	/* in: ???????? */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;

	if (prebuilt->clust_index_was_generated) {
		change_active_index(MAX_KEY);
	} else {
		change_active_index(primary_key);
	}

  	start_of_scan = 1;

 	return(0);
}

/*********************************************************************
Ends a table scan ???????????????? */

int
ha_innobase::rnd_end(void)
/*======================*/
				/* out: 0 or error number */
{
  	return(index_end());
}

/*********************************************************************
Reads the next row in a table scan (also used to read the FIRST row
in a table scan). */

int
ha_innobase::rnd_next(
/*==================*/
			/* out: 0, HA_ERR_END_OF_FILE, or error number */
	mysql_byte* buf)/* in/out: returns the row in this buffer,
			in MySQL format */
{
	int	error;

  	DBUG_ENTER("rnd_next");
  	statistic_increment(ha_read_rnd_next_count, &LOCK_status);

  	if (start_of_scan) {
		error = index_first(buf);
		if (error == HA_ERR_KEY_NOT_FOUND) {
			error = HA_ERR_END_OF_FILE;
		}
		start_of_scan = 0;
	} else {
		error = general_fetch(buf, ROW_SEL_NEXT, 0);
	}

  	DBUG_RETURN(error);
}

/**************************************************************************
Fetches a row from the table based on a reference. TODO: currently we use
'ref_stored_len' of the handle as the key length. This may change. */

int
ha_innobase::rnd_pos(
/*=================*/
				/* out: 0, HA_ERR_KEY_NOT_FOUND,
				or error code */
	mysql_byte* 	buf,	/* in/out: buffer for the row */
	mysql_byte*	pos)	/* in: primary key value in MySQL format */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	int		error;
	uint		keynr	= active_index;

	DBUG_ENTER("rnd_pos");
	statistic_increment(ha_read_rnd_count, &LOCK_status);

	if (prebuilt->clust_index_was_generated) {
		/* No primary key was defined for the table and we
		generated the clustered index from the row id: the
		row reference is the row id, not any key value
		that MySQL knows */

		change_active_index(MAX_KEY);
	} else {
		change_active_index(primary_key);
	}

	error = index_read(buf, pos, ref_stored_len, HA_READ_KEY_EXACT);

	change_active_index(keynr);

  	DBUG_RETURN(error);
}

/*************************************************************************
Stores a reference to the current row to 'ref' field of the handle. Note
that the function parameter is illogical: we must assume that 'record'
is the current 'position' of the handle, because if row ref is actually
the row id internally generated in InnoDB, then 'record' does not contain
it. We just guess that the row id must be for the record where the handle
was positioned the last time. */

void
ha_innobase::position(
/*==================*/
	const mysql_byte*	record)	/* in: row in MySQL format */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	uint		len;

	if (prebuilt->clust_index_was_generated) {
		/* No primary key was defined for the table and we
		generated the clustered index from row id: the
		row reference will be the row id, not any key value
		that MySQL knows */

		len = DATA_ROW_ID_LEN;

		memcpy(ref, prebuilt->row_id, len);
	} else {
		len = store_key_val_for_row(primary_key, (char*) ref, record);
	}

	dbug_assert(len <= ref_length);

	ref_stored_len = len;
}

/***********************************************************************
Tells something additional to the handler about how to do things. */

int
ha_innobase::extra(
/*===============*/
			   /* out: 0 or error number */
	enum ha_extra_function operation)
                           /* in: HA_EXTRA_DONT_USE_CURSOR_TO_UPDATE */
{
	row_prebuilt_t*	prebuilt = (row_prebuilt_t*) innobase_prebuilt;

	switch (operation) {
	        case HA_EXTRA_DONT_USE_CURSOR_TO_UPDATE:
				prebuilt->in_update_remember_pos = FALSE;
				break;
		default:	/* Do nothing */
				;
	}

	return(0);
}

int ha_innobase::reset(void)
{
  	return(0);
}

/**********************************************************************
As MySQL will execute an external lock for every new table it uses when it
starts to process an SQL statement, we can use this function to store the
pointer to the THD in the handle. We will also use this function to communicate
to InnoDB that a new SQL statement has started and that we must store a
savepoint to our transaction handle, so that we are able to roll back
the SQL statement in case of an error. */

int
ha_innobase::external_lock(
/*=======================*/
	THD*	thd,		/* in: handle to the user thread */
	int 	lock_type)	/* in: lock type */
{
	row_prebuilt_t* prebuilt = (row_prebuilt_t*) innobase_prebuilt;
	int 		error = 0;
	trx_t*		trx;

  	DBUG_ENTER("ha_innobase::external_lock");

	update_thd(thd);

	trx = prebuilt->trx;

	prebuilt->sql_stat_start = TRUE;
	prebuilt->in_update_remember_pos = TRUE;

	if (lock_type == F_WRLCK) {

		/* If this is a SELECT, then it is in UPDATE TABLE ...
		or SELECT ... FOR UPDATE */
		prebuilt->select_lock_type = LOCK_X;
	}

	if (lock_type != F_UNLCK) {
		if (trx->n_mysql_tables_in_use == 0) {
			trx_mark_sql_stat_end(trx);
		}
		thd->transaction.all.innodb_active_trans = 1;
		trx->n_mysql_tables_in_use++;

		if (prebuilt->select_lock_type != LOCK_NONE) {

		  	trx->mysql_n_tables_locked++;
		}
	} else {
		trx->n_mysql_tables_in_use--;

		if (trx->n_mysql_tables_in_use == 0) {

		  	trx->mysql_n_tables_locked = 0;

		  	if (trx->has_search_latch) {

		    		trx_search_latch_release_if_reserved(trx);
		  	}

		  	if (!(thd->options
				 & (OPTION_NOT_AUTO_COMMIT | OPTION_BEGIN))) {
		    		innobase_commit(thd, trx);
		  	}
		}
	}

	DBUG_RETURN(error);
}

/*********************************************************************
Creates a table definition to an InnoDB database. */
static
int
create_table_def(
/*=============*/
	trx_t*		trx,		/* in: InnoDB transaction handle */
	TABLE*		form,		/* in: information on table
					columns and indexes */
	const char*	table_name)	/* in: table name */
{
	Field*		field;
	dict_table_t*	table;
	ulint		n_cols;
  	int 		error;
  	ulint		col_type;
  	ulint		nulls_allowed;
	ulint		unsigned_type;
  	ulint		i;

  	DBUG_ENTER("create_table_def");
  	DBUG_PRINT("enter", ("table_name: %s", table_name));

	n_cols = form->fields;

	/* The '0' below specifies that everything is currently
	created in tablespace 0 */

	table = dict_mem_table_create((char*) table_name, 0, n_cols);

	for (i = 0; i < n_cols; i++) {
		field = form->field[i];

		col_type = get_innobase_type_from_mysql_type(field);
		if (field->null_ptr) {
			nulls_allowed = 0;
		} else {
			nulls_allowed = DATA_NOT_NULL;
		}

		if (field->flags & UNSIGNED_FLAG) {
			unsigned_type = DATA_UNSIGNED;
		} else {
			unsigned_type = 0;
		}

		dict_mem_table_add_col(table, (char*) field->field_name,
					col_type, (ulint)field->type()
					| nulls_allowed | unsigned_type,
					field->pack_length(), 0);
	}

	error = row_create_table_for_mysql(table, trx);

	error = convert_error_code_to_mysql(error);

	DBUG_RETURN(error);
}

/*********************************************************************
Creates an index in an InnoDB database. */
static
int
create_index(
/*=========*/
	trx_t*		trx,		/* in: InnoDB transaction handle */
	TABLE*		form,		/* in: information on table
					columns and indexes */
	const char*	table_name,	/* in: table name */
	uint		key_num)	/* in: index number */
{
	dict_index_t*	index;
  	int 		error;
	ulint		n_fields;
	KEY*		key;
	KEY_PART_INFO*	key_part;
	ulint		ind_type;
  	ulint		i;

  	DBUG_ENTER("create_index");

	key = form->key_info + key_num;

    	n_fields = key->key_parts;

    	ind_type = 0;

    	if (strcmp(key->name, "PRIMARY") == 0) {
		ind_type = ind_type | DICT_CLUSTERED;
	}

	if (key->flags & HA_NOSAME ) {
		ind_type = ind_type | DICT_UNIQUE;
	}

	/* The '0' below specifies that everything in InnoDB is currently
	created in tablespace 0 */

	index = dict_mem_index_create((char*) table_name, key->name, 0,
						ind_type, n_fields);
	for (i = 0; i < n_fields; i++) {
		key_part = key->key_part + i;

		/* We assume all fields should be sorted in ascending
		order, hence the '0': */
		dict_mem_index_add_field(index,
				(char*) key_part->field->field_name, 0);
	}

	error = row_create_index_for_mysql(index, trx);

	error = convert_error_code_to_mysql(error);

	DBUG_RETURN(error);
}

/*********************************************************************
Creates an index to an InnoDB table when the user has defined no
primary index. */
static
int
create_clustered_index_when_no_primary(
/*===================================*/
	trx_t*		trx,		/* in: InnoDB transaction handle */
	const char*	table_name)	/* in: table name */
{
	dict_index_t*	index;
  	int 		error;

	/* The first '0' below specifies that everything in InnoDB is
	currently created in file space 0 */

	index = dict_mem_index_create((char*) table_name,
				      (char*) "GEN_CLUST_INDEX",
				      0, DICT_CLUSTERED, 0);
	error = row_create_index_for_mysql(index, trx);

	error = convert_error_code_to_mysql(error);

	return(error);
}

/*********************************************************************
Creates a new table to an InnoDB database. */

int
ha_innobase::create(
/*================*/
					/* out: error number */
	const char*	name,		/* in: table name */
	TABLE*		form,		/* in: information on table
					columns and indexes */
	HA_CREATE_INFO*	create_info)	/* in: ??????? */
{
	int		error;
	dict_table_t*	innobase_table;
	trx_t*		trx;
	int		primary_key_no	= -1;
	KEY*		key;
	uint		i;
	char		name2[FN_REFLEN];
	char		norm_name[FN_REFLEN];

  	DBUG_ENTER("ha_innobase::create");

	trx = trx_allocate_for_mysql();

	fn_format(name2, name, "", "",2);	// Remove the .frm extension

	normalize_table_name(norm_name, name2);

  	/* Create the table definition in InnoDB */

  	if ((error = create_table_def(trx, form, norm_name))) {

		trx_commit_for_mysql(trx);

  		trx_free_for_mysql(trx);

 		DBUG_RETURN(error);
 	}

	/* Look for a primary key */

	for (i = 0; i < form->keys; i++) {
		key = form->key_info + i;

    		if (strcmp(key->name, "PRIMARY") == 0) {
    			primary_key_no = (int) i;
    		}
	}

	/* Our function row_get_mysql_key_number_for_index assumes
	the primary key is always number 0, if it exists */

	assert(primary_key_no == -1 || primary_key_no == 0);

	/* Create the keys */

	if (form->keys == 0 || primary_key_no == -1) {
		/* Create an index which is used as the clustered index;
		order the rows by their row id which is internally generated
		by InnoDB */

		error = create_clustered_index_when_no_primary(trx,
							norm_name);
  		if (error) {
			trx_commit_for_mysql(trx);

			trx_free_for_mysql(trx);

			DBUG_RETURN(error);
      		}
	}

	if (primary_key_no != -1) {
		/* In InnoDB the clustered index must always be created
		first */
	    	if ((error = create_index(trx, form, norm_name,
					  (uint) primary_key_no))) {
			trx_commit_for_mysql(trx);

  			trx_free_for_mysql(trx);

			DBUG_RETURN(error);
      		}
      	}

	for (i = 0; i < form->keys; i++) {

		if (i != (uint) primary_key_no) {

    			if ((error = create_index(trx, form, norm_name, i))) {

				trx_commit_for_mysql(trx);

  				trx_free_for_mysql(trx);

				DBUG_RETURN(error);
      			}
      		}
  	}

  	trx_commit_for_mysql(trx);

	innobase_table = dict_table_get(norm_name, NULL);

	assert(innobase_table);

	/* Tell the InnoDB server that there might be work for
	utility threads: */

	srv_active_wake_master_thread();

  	trx_free_for_mysql(trx);

	DBUG_RETURN(0);
}

/*********************************************************************
Drops a table from an InnoDB database. Before calling this function,
MySQL calls innobase_commit to commit the transaction of the current user.
Then the current user cannot have locks set on the table. Drop table
operation inside InnoDB will wait sleeping in a loop until no other
user has locks on the table. */

int
ha_innobase::delete_table(
/*======================*/
				/* out: error number */
	const char*	name)	/* in: table name */
{
	ulint	name_len;
	int	error;
	trx_t*	trx;
	char	norm_name[1000];

  	DBUG_ENTER("ha_innobase::delete_table");

	trx = trx_allocate_for_mysql();

	name_len = strlen(name);

	assert(name_len < 1000);

	/* Strangely, MySQL passes the table name without the '.frm'
	extension, in contrast to ::create */

	normalize_table_name(norm_name, name);

  	/* Drop the table in InnoDB */

  	error = row_drop_table_for_mysql(norm_name, trx, FALSE);

	/* Tell the InnoDB server that there might be work for
	utility threads: */

	srv_active_wake_master_thread();

  	trx_free_for_mysql(trx);

	error = convert_error_code_to_mysql(error);

	DBUG_RETURN(error);
}

/*************************************************************************
Renames an InnoDB table. */

int
ha_innobase::rename_table(
/*======================*/
				/* out: 0 or error code */
	const char*	from,	/* in: old name of the table */
	const char*	to)	/* in: new name of the table */
{
	ulint	name_len1;
	ulint	name_len2;
	int	error;
	trx_t*	trx;
	char	norm_from[1000];
	char	norm_to[1000];

  	DBUG_ENTER("ha_innobase::rename_table");

	trx = trx_allocate_for_mysql();

	name_len1 = strlen(from);
	name_len2 = strlen(to);

	assert(name_len1 < 1000);
	assert(name_len2 < 1000);

	normalize_table_name(norm_from, from);
	normalize_table_name(norm_to, to);

  	/* Rename the table in InnoDB */

  	error = row_rename_table_for_mysql(norm_from, norm_to, trx);

	/* Tell the InnoDB server that there might be work for
	utility threads: */

	srv_active_wake_master_thread();

  	trx_free_for_mysql(trx);

	error = convert_error_code_to_mysql(error);

	DBUG_RETURN(error);
}

/*************************************************************************
Estimates the number of index records in a range. */

ha_rows
ha_innobase::records_in_range(
/*==========================*/
						/* out: estimated number of rows,
						currently 32-bit int or uint */
	int 			keynr,		/* in: index number */
	const mysql_byte*	start_key,	/* in: start key value of the
						range, may also be empty */
	uint 			start_key_len,	/* in: start key val len, may
						also be 0 */
	enum ha_rkey_function 	start_search_flag,/* in: start search condition
						e.g., 'greater than' */
	const mysql_byte*	end_key,	/* in: range end key val, may
						also be empty */
	uint 			end_key_len,	/* in: range end key val len,
						may also be 0 */
	enum ha_rkey_function 	end_search_flag)/* in: range end search cond */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
	KEY*		key;
	dict_index_t*	index;
	mysql_byte*	key_val_buff2 	= (mysql_byte*) my_malloc(
							table->reclength,
								MYF(MY_WME));
	dtuple_t*	range_start;
	dtuple_t*	range_end;
	ulint		n_rows;
	ulint		mode1;
	ulint		mode2;
	void*           heap1;
	void*           heap2;

   	DBUG_ENTER("records_in_range");

	if (prebuilt->trx) {
		prebuilt->trx->op_info = "estimating range size";
	}
   	
	active_index = keynr;

	key = table->key_info + active_index;

	index = dict_table_get_index_noninline(prebuilt->table, key->name);

	range_start = dtuple_create_for_mysql(&heap1, key->key_parts);
 	dict_index_copy_types(range_start, index, key->key_parts);

	range_end = dtuple_create_for_mysql(&heap2, key->key_parts);
 	dict_index_copy_types(range_end, index, key->key_parts);

	row_sel_convert_mysql_key_to_innobase(
				range_start, (byte*) key_val_buff, index,
				(byte*) start_key,
				(ulint) start_key_len);

	row_sel_convert_mysql_key_to_innobase(
				range_end, (byte*) key_val_buff2, index,
				(byte*) end_key,
				(ulint) end_key_len);

	mode1 = convert_search_mode_to_innobase(start_search_flag);
	mode2 = convert_search_mode_to_innobase(end_search_flag);

	n_rows = btr_estimate_n_rows_in_range(index, range_start,
						mode1, range_end, mode2);
	dtuple_free_for_mysql(heap1);
	dtuple_free_for_mysql(heap2);

    	my_free((char*) key_val_buff2, MYF(0));

	if (prebuilt->trx) {
		prebuilt->trx->op_info = "";
	}
   	
	DBUG_RETURN((ha_rows) n_rows);
}

/*************************************************************************
Gives an UPPER BOUND to the number of rows in a table. This is used in
filesort.cc and the upper bound must hold. TODO: Since the number of
rows in a table may change after this function is called, we still may
get a 'Sort aborted' error in filesort.cc of MySQL. The ultimate fix is to
improve the algorithm of filesort.cc. */

ha_rows
ha_innobase::estimate_number_of_rows(void)
/*======================================*/
			/* out: upper bound of rows, currently 32-bit int
			or uint */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
	dict_table_t*	ib_table;

	if (prebuilt->trx) {
		prebuilt->trx->op_info =
				"estimating upper bound of table size";
	}   	

 	DBUG_ENTER("info");

 	ib_table = prebuilt->table;
 	
 	dict_update_statistics(ib_table);

	data_file_length = ((ulonglong)
				ib_table->stat_clustered_index_size)
    					* UNIV_PAGE_SIZE;

	/* The minimum clustered index record size is 20 bytes */

	if (prebuilt->trx) {
		prebuilt->trx->op_info = "";
	}
   	
	return((ha_rows) (1000 + data_file_length / 20));
}

/*************************************************************************
How many seeks it will take to read through the table. This is to be
comparable to the number returned by records_in_range so that we can
decide if we should scan the table or use keys. */

double
ha_innobase::scan_time()
/*====================*/
			/* out: estimated time measured in disk seeks */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;

	/* In the following formula we assume that scanning 5 pages
	takes the same time as a disk seek: */

	return((double) (1 + prebuilt->table->stat_clustered_index_size / 5));
}

/*************************************************************************
Returns statistics information of the table to the MySQL interpreter,
in various fields of the handle object. */

void
ha_innobase::info(
/*==============*/
	uint flag)	/* in: what information MySQL requests */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
	dict_table_t*	ib_table;
	dict_index_t*	index;
	uint		rec_per_key;
	uint		i;

 	DBUG_ENTER("info");

	if (prebuilt->trx) {
		prebuilt->trx->op_info = "calculating table stats";
	}
   	
 	ib_table = prebuilt->table;

 	if (flag & HA_STATUS_TIME) {
 		/* In sql_show we call with this flag: update then statistics
 		so that they are up-to-date */

 		dict_update_statistics(ib_table);
 	}

	if (flag & HA_STATUS_VARIABLE) {
    		records = ib_table->stat_n_rows;
    		deleted = 0;
    		data_file_length = ((ulonglong)
				ib_table->stat_clustered_index_size)
    					* UNIV_PAGE_SIZE;
    		index_file_length = ((ulonglong)
				ib_table->stat_sum_of_other_index_sizes)
    					* UNIV_PAGE_SIZE;
    		delete_length = 0;
    		check_time = 0;

    		if (records == 0) {
    			mean_rec_length = 0;
    		} else {
    			mean_rec_length = (ulong) data_file_length / records;
    		}
    	}

	if (flag & HA_STATUS_CONST) {
		index = dict_table_get_first_index_noninline(ib_table);

		if (prebuilt->clust_index_was_generated) {
			index = dict_table_get_next_index_noninline(index);
		}

		for (i = 0; i < table->keys; i++) {
			if (index->stat_n_diff_key_vals == 0) {
				rec_per_key = records;
			} else {
				rec_per_key = records /
					index->stat_n_diff_key_vals;
			}

			table->key_info[i].rec_per_key[
				table->key_info[i].key_parts - 1]
					= rec_per_key;
			index = dict_table_get_next_index_noninline(index);
		}
	}

	/* The trx struct in InnoDB contains a pthread mutex embedded:
	in the debug version of MySQL that it replaced by a 'safe mutex'
	which is of a different size. We have to use a function to access
	trx fields. Otherwise trx->error_info will be a random
	pointer and cause a seg fault. */

  	if (flag & HA_STATUS_ERRKEY) {
		errkey = (unsigned int) row_get_mysql_key_number_for_index(
				       (dict_index_t*)
				       trx_get_error_info(prebuilt->trx));
  	}

	if (prebuilt->trx) {
		prebuilt->trx->op_info = "";
	}
   	
  	DBUG_VOID_RETURN;
}

/***********************************************************************
Tries to check that an InnoDB table is not corrupted. If corruption is
noticed, prints to stderr information about it. In case of corruption
may also assert a failure and crash the server. */

int
ha_innobase::check(
/*===============*/
					/* out: HA_ADMIN_CORRUPT or
					HA_ADMIN_OK */
	THD* 		thd,		/* in: user thread handle */
	HA_CHECK_OPT* 	check_opt)	/* in: check options, currently
					ignored */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
	ulint		ret;
	
	if (prebuilt->mysql_template == NULL) {
		/* Build the template; we will use a dummy template
		in index scans done in checking */

		build_template(prebuilt, NULL, table, ROW_MYSQL_WHOLE_ROW);
	}

	ret = row_check_table_for_mysql(prebuilt);

	if (ret == DB_SUCCESS) {
		return(HA_ADMIN_OK);
	}
	
  	return(HA_ADMIN_CORRUPT); 
}

/*****************************************************************
Adds information about free space in the InnoDB tablespace to a
table comment which is printed out when a user calls SHOW TABLE STATUS. */

char*
ha_innobase::update_table_comment(
/*==============================*/
        const char* comment)
{
  uint length=strlen(comment);

  char *str=my_malloc(length + 100,MYF(0)), *pos;

  if (!str)
    return (char*)comment;

  pos=str;
  if (length)
  {
    pos=strmov(str,comment);
    *pos++=';';
    *pos++=' ';
  }
  sprintf(pos, "InnoDB free: %lu kB", (ulong) innobase_get_free_space());

  return(str);
}

/****************************************************************************
 Handling the shared INNOBASE_SHARE structure that is needed to provide table
 locking.
****************************************************************************/

static mysql_byte* innobase_get_key(INNOBASE_SHARE *share,uint *length,
			      my_bool not_used __attribute__((unused)))
{
  *length=share->table_name_length;
  return (mysql_byte*) share->table_name;
}

static INNOBASE_SHARE *get_share(const char *table_name)
{
  INNOBASE_SHARE *share;
  pthread_mutex_lock(&innobase_mutex);
  uint length=(uint) strlen(table_name);
  if (!(share=(INNOBASE_SHARE*) hash_search(&innobase_open_tables,
					(mysql_byte*) table_name,
					    length)))
  {
    if ((share=(INNOBASE_SHARE *) my_malloc(sizeof(*share)+length+1,
				       MYF(MY_WME | MY_ZEROFILL))))
    {
      share->table_name_length=length;
      share->table_name=(char*) (share+1);
      strmov(share->table_name,table_name);
      if (hash_insert(&innobase_open_tables, (mysql_byte*) share))
      {
	pthread_mutex_unlock(&innobase_mutex);
	my_free((gptr) share,0);
	return 0;
      }
      thr_lock_init(&share->lock);
      pthread_mutex_init(&share->mutex,MY_MUTEX_INIT_FAST);
    }
  }
  share->use_count++;
  pthread_mutex_unlock(&innobase_mutex);
  return share;
}

static void free_share(INNOBASE_SHARE *share)
{
  pthread_mutex_lock(&innobase_mutex);
  if (!--share->use_count)
  {
    hash_delete(&innobase_open_tables, (mysql_byte*) share);
    thr_lock_delete(&share->lock);
    pthread_mutex_destroy(&share->mutex);
    my_free((gptr) share, MYF(0));
  }
  pthread_mutex_unlock(&innobase_mutex);
}

/*********************************************************************
Stores a MySQL lock into a 'lock' field in a handle. */

THR_LOCK_DATA**
ha_innobase::store_lock(
/*====================*/
						/* out: pointer to the next
						element in the 'to' array */
	THD*			thd,		/* in: user thread handle */
	THR_LOCK_DATA**		to,		/* in: pointer to an array
						of pointers to lock structs;
						pointer to the 'lock' field
						of current handle is stored
						next to this array */
	enum thr_lock_type 	lock_type)	/* in: lock type to store in
						'lock' */
{
	row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;

	if (lock_type == TL_READ_WITH_SHARED_LOCKS ||
	    lock_type == TL_READ_NO_INSERT) {
		/* This is a SELECT ... IN SHARE MODE, or
		we are doing a complex SQL statement like
		INSERT INTO ... SELECT ... and the logical logging
		requires the use of a locking read */

		prebuilt->select_lock_type = LOCK_S;
	} else {
		/* We set possible LOCK_X value in external_lock, not yet
		here even if this would be SELECT ... FOR UPDATE */

		prebuilt->select_lock_type = LOCK_NONE;
	}

	if (lock_type != TL_IGNORE && lock.type == TL_UNLOCK) {

    		/* If we are not doing a LOCK TABLE, then allow multiple
		writers */

    		if ((lock_type >= TL_WRITE_CONCURRENT_INSERT &&
	 	    lock_type <= TL_WRITE) && !thd->in_lock_tables) {

      			lock_type = TL_WRITE_ALLOW_WRITE;
      		}

 		lock.type=lock_type;
  	}

  	*to++= &lock;

	return(to);
}

/***********************************************************************
Returns the next auto-increment column value for the table. write_row
normally fetches the value from the cache in the data dictionary. This
function in used by SHOW TABLE STATUS and when the first insert to the table
is done after database startup. */

longlong
ha_innobase::get_auto_increment()
/*=============================*/
                         /* out: the next auto-increment column value */
{
  row_prebuilt_t* prebuilt	= (row_prebuilt_t*) innobase_prebuilt;
  longlong        nr;
  int             error;

  (void) extra(HA_EXTRA_KEYREAD);
  index_init(table->next_number_index);

  /* We use an exclusive lock when we read the max key value from the
  auto-increment column index. This is because then build_template will
  advise InnoDB to fetch all columns. In SHOW TABLE STATUS the query
  id of the auto-increment column is not changed, and previously InnoDB
  did not fetch it, causing SHOW TABLE STATUS to show wrong values
  for the autoinc column. */

  prebuilt->select_lock_type = LOCK_X;
  prebuilt->trx->mysql_n_tables_locked += 1;
  
  error=index_last(table->record[1]);

  if (error) {
    nr = 1;
  } else {
    nr = (longlong) table->next_number_field->
                        val_int_offset(table->rec_buff_length) + 1;
  }

  (void) extra(HA_EXTRA_NO_KEYREAD);

  index_end();

  return(nr);
}


#endif /* HAVE_INNOBASE_DB */