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/*****************************************************************************
Copyright (c) 1997, 2010, Innobase Oy. All Rights Reserved.
This program is free software; you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free Software
Foundation; version 2 of the License.
This program is distributed in the hope that it will be useful, but WITHOUT
ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details.
You should have received a copy of the GNU General Public License along with
this program; if not, write to the Free Software Foundation, Inc., 59 Temple
Place, Suite 330, Boston, MA 02111-1307 USA
*****************************************************************************/
/**************************************************//**
@file row/row0uins.c
Fresh insert undo
Created 2/25/1997 Heikki Tuuri
*******************************************************/
#include "row0uins.h"
#ifdef UNIV_NONINL
#include "row0uins.ic"
#endif
#include "dict0dict.h"
#include "dict0boot.h"
#include "dict0crea.h"
#include "trx0undo.h"
#include "trx0roll.h"
#include "btr0btr.h"
#include "mach0data.h"
#include "row0undo.h"
#include "row0vers.h"
#include "trx0trx.h"
#include "trx0rec.h"
#include "row0row.h"
#include "row0upd.h"
#include "que0que.h"
#include "ibuf0ibuf.h"
#include "log0log.h"
/*************************************************************************
IMPORTANT NOTE: Any operation that generates redo MUST check that there
is enough space in the redo log before for that operation. This is
done by calling log_free_check(). The reason for checking the
availability of the redo log space before the start of the operation is
that we MUST not hold any synchonization objects when performing the
check.
If you make a change in this module make sure that no codepath is
introduced where a call to log_free_check() is bypassed. */
/***************************************************************//**
Removes a clustered index record. The pcur in node was positioned on the
record, now it is detached.
@return DB_SUCCESS or DB_OUT_OF_FILE_SPACE */
static
ulint
row_undo_ins_remove_clust_rec(
/*==========================*/
undo_node_t* node) /*!< in: undo node */
{
btr_cur_t* btr_cur;
ibool success;
ulint err;
ulint n_tries = 0;
mtr_t mtr;
mtr_start(&mtr);
success = btr_pcur_restore_position(BTR_MODIFY_LEAF, &(node->pcur),
&mtr);
ut_a(success);
if (ut_dulint_cmp(node->table->id, DICT_INDEXES_ID) == 0) {
ut_ad(node->trx->dict_operation_lock_mode == RW_X_LATCH);
/* Drop the index tree associated with the row in
SYS_INDEXES table: */
dict_drop_index_tree(btr_pcur_get_rec(&(node->pcur)), &mtr);
mtr_commit(&mtr);
mtr_start(&mtr);
success = btr_pcur_restore_position(BTR_MODIFY_LEAF,
&(node->pcur), &mtr);
ut_a(success);
}
btr_cur = btr_pcur_get_btr_cur(&(node->pcur));
success = btr_cur_optimistic_delete(btr_cur, &mtr);
btr_pcur_commit_specify_mtr(&(node->pcur), &mtr);
if (success) {
trx_undo_rec_release(node->trx, node->undo_no);
return(DB_SUCCESS);
}
retry:
/* If did not succeed, try pessimistic descent to tree */
mtr_start(&mtr);
success = btr_pcur_restore_position(BTR_MODIFY_TREE,
&(node->pcur), &mtr);
ut_a(success);
btr_cur_pessimistic_delete(&err, FALSE, btr_cur,
trx_is_recv(node->trx)
? RB_RECOVERY
: RB_NORMAL, &mtr);
/* The delete operation may fail if we have little
file space left: TODO: easiest to crash the database
and restart with more file space */
if (err == DB_OUT_OF_FILE_SPACE
&& n_tries < BTR_CUR_RETRY_DELETE_N_TIMES) {
btr_pcur_commit_specify_mtr(&(node->pcur), &mtr);
n_tries++;
os_thread_sleep(BTR_CUR_RETRY_SLEEP_TIME);
goto retry;
}
btr_pcur_commit_specify_mtr(&(node->pcur), &mtr);
trx_undo_rec_release(node->trx, node->undo_no);
return(err);
}
/***************************************************************//**
Removes a secondary index entry if found.
@return DB_SUCCESS, DB_FAIL, or DB_OUT_OF_FILE_SPACE */
static
ulint
row_undo_ins_remove_sec_low(
/*========================*/
ulint mode, /*!< in: BTR_MODIFY_LEAF or BTR_MODIFY_TREE,
depending on whether we wish optimistic or
pessimistic descent down the index tree */
dict_index_t* index, /*!< in: index */
dtuple_t* entry) /*!< in: index entry to remove */
{
btr_pcur_t pcur;
btr_cur_t* btr_cur;
ulint err;
mtr_t mtr;
enum row_search_result search_result;
mtr_start(&mtr);
btr_cur = btr_pcur_get_btr_cur(&pcur);
ut_ad(mode == BTR_MODIFY_TREE || mode == BTR_MODIFY_LEAF);
search_result = row_search_index_entry(index, entry, mode,
&pcur, &mtr);
switch (search_result) {
case ROW_NOT_FOUND:
err = DB_SUCCESS;
goto func_exit;
case ROW_FOUND:
break;
case ROW_BUFFERED:
case ROW_NOT_DELETED_REF:
/* These are invalid outcomes, because the mode passed
to row_search_index_entry() did not include any of the
flags BTR_INSERT, BTR_DELETE, or BTR_DELETE_MARK. */
ut_error;
}
if (mode == BTR_MODIFY_LEAF) {
err = btr_cur_optimistic_delete(btr_cur, &mtr)
? DB_SUCCESS : DB_FAIL;
} else {
ut_ad(mode == BTR_MODIFY_TREE);
/* No need to distinguish RB_RECOVERY here, because we
are deleting a secondary index record: the distinction
between RB_NORMAL and RB_RECOVERY only matters when
deleting a record that contains externally stored
columns. */
ut_ad(!dict_index_is_clust(index));
btr_cur_pessimistic_delete(&err, FALSE, btr_cur,
RB_NORMAL, &mtr);
}
func_exit:
btr_pcur_close(&pcur);
mtr_commit(&mtr);
return(err);
}
/***************************************************************//**
Removes a secondary index entry from the index if found. Tries first
optimistic, then pessimistic descent down the tree.
@return DB_SUCCESS or DB_OUT_OF_FILE_SPACE */
static
ulint
row_undo_ins_remove_sec(
/*====================*/
dict_index_t* index, /*!< in: index */
dtuple_t* entry) /*!< in: index entry to insert */
{
ulint err;
ulint n_tries = 0;
/* Try first optimistic descent to the B-tree */
err = row_undo_ins_remove_sec_low(BTR_MODIFY_LEAF, index, entry);
if (err == DB_SUCCESS) {
return(err);
}
/* Try then pessimistic descent to the B-tree */
retry:
err = row_undo_ins_remove_sec_low(BTR_MODIFY_TREE, index, entry);
/* The delete operation may fail if we have little
file space left: TODO: easiest to crash the database
and restart with more file space */
if (err != DB_SUCCESS && n_tries < BTR_CUR_RETRY_DELETE_N_TIMES) {
n_tries++;
os_thread_sleep(BTR_CUR_RETRY_SLEEP_TIME);
goto retry;
}
return(err);
}
/***********************************************************//**
Parses the row reference and other info in a fresh insert undo record. */
static
void
row_undo_ins_parse_undo_rec(
/*========================*/
undo_node_t* node) /*!< in/out: row undo node */
{
dict_index_t* clust_index;
byte* ptr;
undo_no_t undo_no;
dulint table_id;
ulint type;
ulint dummy;
ibool dummy_extern;
ut_ad(node);
ptr = trx_undo_rec_get_pars(node->undo_rec, &type, &dummy,
&dummy_extern, &undo_no, &table_id);
ut_ad(type == TRX_UNDO_INSERT_REC);
node->rec_type = type;
node->update = NULL;
node->table = dict_table_get_on_id(table_id, node->trx);
/* Skip the UNDO if we can't find the table or the .ibd file. */
if (UNIV_UNLIKELY(node->table == NULL)) {
} else if (UNIV_UNLIKELY(node->table->ibd_file_missing)) {
node->table = NULL;
} else {
clust_index = dict_table_get_first_index(node->table);
if (clust_index != NULL) {
ptr = trx_undo_rec_get_row_ref(
ptr, clust_index, &node->ref, node->heap);
} else {
ut_print_timestamp(stderr);
fprintf(stderr, " InnoDB: table ");
ut_print_name(stderr, node->trx, TRUE,
node->table->name);
fprintf(stderr, " has no indexes, "
"ignoring the table\n");
node->table = NULL;
}
}
}
/***********************************************************//**
Undoes a fresh insert of a row to a table. A fresh insert means that
the same clustered index unique key did not have any record, even delete
marked, at the time of the insert. InnoDB is eager in a rollback:
if it figures out that an index record will be removed in the purge
anyway, it will remove it in the rollback.
@return DB_SUCCESS or DB_OUT_OF_FILE_SPACE */
UNIV_INTERN
ulint
row_undo_ins(
/*=========*/
undo_node_t* node) /*!< in: row undo node */
{
ut_ad(node);
ut_ad(node->state == UNDO_NODE_INSERT);
row_undo_ins_parse_undo_rec(node);
if (!node->table || !row_undo_search_clust_to_pcur(node)) {
trx_undo_rec_release(node->trx, node->undo_no);
return(DB_SUCCESS);
}
/* Iterate over all the indexes and undo the insert.*/
/* Skip the clustered index (the first index) */
node->index = dict_table_get_next_index(
dict_table_get_first_index(node->table));
while (node->index != NULL) {
dtuple_t* entry;
ulint err;
entry = row_build_index_entry(node->row, node->ext,
node->index, node->heap);
if (UNIV_UNLIKELY(!entry)) {
/* The database must have crashed after
inserting a clustered index record but before
writing all the externally stored columns of
that record. Because secondary index entries
are inserted after the clustered index record,
we may assume that the secondary index record
does not exist. However, this situation may
only occur during the rollback of incomplete
transactions. */
ut_a(trx_is_recv(node->trx));
} else {
log_free_check();
err = row_undo_ins_remove_sec(node->index, entry);
if (err != DB_SUCCESS) {
return(err);
}
}
node->index = dict_table_get_next_index(node->index);
}
log_free_check();
return(row_undo_ins_remove_clust_rec(node));
}
|