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mariadb/storage/innobase/row/row0upd.c
aivanov@mysql.com 780f80be16 Applied innodb-5.1-ss475 snapshot. 
* Fix BUG#15650: "DELETE with LEFT JOIN crashes server with innodb_locks_unsafe_for binlog"
* Fix BUG#17134: "Partitions: uncommitted changes are visible"
* Fix BUG#17992: "Partitions: InnoDB, somehow rotten table after UPDATE"
  row0ins.c: MySQL's partitioned table code does not set preduilt->sql_stat_start right
  if it does an insert in the same statement after doing a search first in the same
  partition table. We now write trx id always to the buffer, not just when flag
  sql_stat_start is on. This will waste CPU time very sightly.
* Fix BUG#18077: "InnoDB uses full explicit table locks in stored FUNCTION"
* Fix BUG#18238: "When locks exhaust the buffer pool, InnoDB does not roll back the trx"
* Fix BUG#18252" "Disk space leak in updates of InnoDB BLOB rows in 5.0 and 5.1"
* Fix BUG#18283: "When InnoDB returns error 'lock table full', MySQL can write to binlog too much"
* Fix BUG#18350: "Use consistent read in CREATE ... SELECT ... if innodb_locks_unsafe_for_binlog"
* Fix BUG#18384: "InnoDB memory leak on duplicate key errors in 5.0 if row has many columns"
* Fix BUG#18934: "InnoDB crashes when table uses column names like DB_ROW_ID"
  Refuse tables that use reserved column names.
* InnoDB's SQL parser:
  - Add support for UNSIGNED types, EXIT keyword, quoted identifiers, user-function callbacks
    for processing results of FETCH statements, bound literals, DATA_VARCHAR for bound literals.
  - Allow bound literals of type non-INTEGER to be of length 0.
  - Add make_flex.sh and update lexer/parser generation documentation.
  - Add comment clarifying the difference between 'alias' and 'indirection' fields in sym_node_t.
  - Remove never reached duplicate code in pars_set_dfield_type().
  - Rewrite pars_info datatypes and APIs, add a few helper functions.
  - Since the functions definitions in pars_info_t are accessed after pars_sql() returns
    in the query graph execution stage, we can't free pars_info_t in pars_sql(). Instead,
    make pars_sql() transfer ownership of pars_info_t to the created query graph, and
    make que_graph_free() free it if needed.
  - Allow access to system columns like DB_ROW_ID.
* Use bound literals in row_truncate_table_for_mysql, row_drop_table_for_mysql,
  row_discard_tablespace_for_mysql, and row_rename_table_for_mysql.
* Setting an isolation level of the transaction to read committed weakens the locks for
  this session similarly like the option innodb_locks_unsafe_for binlog. This patch removes
  alnost all gap locking (used in next-key locking) and makes MySQL to release the row locks
  on the rows which does not belong to result set. Additionally, nonlocking selects on
  INSERT INTO SELECT, UPDATE ... (SELECT ...), and CREATE ... SELECT ... use a nonlocking
  consistent read. If a binlog is used, then binlog format should be set to row based
  binloging to make the execution of the complex SQL statements.
* Disable the statistic variables btr_search_n_hash_fail and n_hash_succ, n_hash_fail,
  n_patt_succ, and n_searches of btr_search_t in builds without #ifdef UNIV_SEARCH_PERF_STAT.
* Make innodb.test faster. Group all consistent read test cases to a one test case and
  wait their lock timeout after all have been send to the server. Decrease amount of rows
  inserted in a certain test - this has no effect on the effectiveness of the test and
  reduces the running time by ~10 sec. Remove temporary work-arounds from innodb.result
  now that ALTER TABLE DROP FOREIGN KEY works once again.
* Make innodb_unsafe_binlog.test faster. Grout all consistent read test cases to a one
  test case amd wait their lock timeout after all have been sent to the server. Remove
  unnecessary option --loose_innodb_lock_wait_timeout.
* Print dictionary memory size in SHOW INNODB STATUS.
* Fix memory leaks in row_create_table_for_mysql() in rare corner cases.
* Remove code related to clustered tables. They were never implemented, and the
  implementation would be challenging with ROW_FORMAT=COMPACT. Remove the table types
  DICT_TABLE_CLUSTER_MEMBER and DICT_TABLE_CLUSTER and all related tests and functions.
  dict_table_t: Remove mix_id, mix_len, mix_id_len, mix_id_buf, and cluster_name.
  plan_t: Remove mixed_index.
  dict_create_sys_tables_tuple(): Set MIX_ID=0, MIX_LEN=0, CLUSTER_NAME=NULL when
  inserting into SYS_TABLES.
  dict_tree_check_search_tuple(): Enclose in #ifdef UNIV_DEBUG.
* Move calling of thr_local_free() from trx_free_for_mysql() to
  innobase_close_connection().
2006-04-23 12:48:31 +04:00

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/******************************************************
Update of a row
(c) 1996 Innobase Oy
Created 12/27/1996 Heikki Tuuri
*******************************************************/
#include "row0upd.h"
#ifdef UNIV_NONINL
#include "row0upd.ic"
#endif
#include "dict0dict.h"
#include "dict0boot.h"
#include "dict0crea.h"
#include "mach0data.h"
#include "trx0undo.h"
#include "btr0btr.h"
#include "btr0cur.h"
#include "que0que.h"
#include "row0ins.h"
#include "row0sel.h"
#include "row0row.h"
#include "rem0cmp.h"
#include "lock0lock.h"
#include "log0log.h"
#include "pars0sym.h"
#include "eval0eval.h"
#include "buf0lru.h"
/* What kind of latch and lock can we assume when the control comes to
-------------------------------------------------------------------
an update node?
--------------
Efficiency of massive updates would require keeping an x-latch on a
clustered index page through many updates, and not setting an explicit
x-lock on clustered index records, as they anyway will get an implicit
x-lock when they are updated. A problem is that the read nodes in the
graph should know that they must keep the latch when passing the control
up to the update node, and not set any record lock on the record which
will be updated. Another problem occurs if the execution is stopped,
as the kernel switches to another query thread, or the transaction must
wait for a lock. Then we should be able to release the latch and, maybe,
acquire an explicit x-lock on the record.
Because this seems too complicated, we conclude that the less
efficient solution of releasing all the latches when the control is
transferred to another node, and acquiring explicit x-locks, is better. */
/* How is a delete performed? If there is a delete without an
explicit cursor, i.e., a searched delete, there are at least
two different situations:
the implicit select cursor may run on (1) the clustered index or
on (2) a secondary index. The delete is performed by setting
the delete bit in the record and substituting the id of the
deleting transaction for the original trx id, and substituting a
new roll ptr for previous roll ptr. The old trx id and roll ptr
are saved in the undo log record. Thus, no physical changes occur
in the index tree structure at the time of the delete. Only
when the undo log is purged, the index records will be physically
deleted from the index trees.
The query graph executing a searched delete would consist of
a delete node which has as a subtree a select subgraph.
The select subgraph should return a (persistent) cursor
in the clustered index, placed on page which is x-latched.
The delete node should look for all secondary index records for
this clustered index entry and mark them as deleted. When is
the x-latch freed? The most efficient way for performing a
searched delete is obviously to keep the x-latch for several
steps of query graph execution. */
/***************************************************************
Checks if an update vector changes some of the first ordering fields of an
index record. This is only used in foreign key checks and we can assume
that index does not contain column prefixes. */
static
ibool
row_upd_changes_first_fields_binary(
/*================================*/
/* out: TRUE if changes */
dtuple_t* entry, /* in: old value of index entry */
dict_index_t* index, /* in: index of entry */
upd_t* update, /* in: update vector for the row */
ulint n); /* in: how many first fields to check */
/*************************************************************************
Checks if index currently is mentioned as a referenced index in a foreign
key constraint. */
static
ibool
row_upd_index_is_referenced(
/*========================*/
/* out: TRUE if referenced; NOTE that since
we do not hold dict_operation_lock
when leaving the function, it may be that
the referencing table has been dropped when
we leave this function: this function is only
for heuristic use! */
dict_index_t* index, /* in: index */
trx_t* trx) /* in: transaction */
{
dict_table_t* table = index->table;
dict_foreign_t* foreign;
ibool froze_data_dict = FALSE;
if (!UT_LIST_GET_FIRST(table->referenced_list)) {
return(FALSE);
}
if (trx->dict_operation_lock_mode == 0) {
row_mysql_freeze_data_dictionary(trx);
froze_data_dict = TRUE;
}
foreign = UT_LIST_GET_FIRST(table->referenced_list);
while (foreign) {
if (foreign->referenced_index == index) {
if (froze_data_dict) {
row_mysql_unfreeze_data_dictionary(trx);
}
return(TRUE);
}
foreign = UT_LIST_GET_NEXT(referenced_list, foreign);
}
if (froze_data_dict) {
row_mysql_unfreeze_data_dictionary(trx);
}
return(FALSE);
}
/*************************************************************************
Checks if possible foreign key constraints hold after a delete of the record
under pcur. NOTE that this function will temporarily commit mtr and lose the
pcur position! */
static
ulint
row_upd_check_references_constraints(
/*=================================*/
/* out: DB_SUCCESS or an error code */
upd_node_t* node, /* in: row update node */
btr_pcur_t* pcur, /* in: cursor positioned on a record; NOTE: the
cursor position is lost in this function! */
dict_table_t* table, /* in: table in question */
dict_index_t* index, /* in: index of the cursor */
que_thr_t* thr, /* in: query thread */
mtr_t* mtr) /* in: mtr */
{
dict_foreign_t* foreign;
mem_heap_t* heap;
dtuple_t* entry;
trx_t* trx;
rec_t* rec;
ulint err;
ibool got_s_lock = FALSE;
if (UT_LIST_GET_FIRST(table->referenced_list) == NULL) {
return(DB_SUCCESS);
}
trx = thr_get_trx(thr);
rec = btr_pcur_get_rec(pcur);
heap = mem_heap_create(500);
entry = row_rec_to_index_entry(ROW_COPY_DATA, index, rec, heap);
mtr_commit(mtr);
mtr_start(mtr);
if (trx->dict_operation_lock_mode == 0) {
got_s_lock = TRUE;
row_mysql_freeze_data_dictionary(trx);
}
foreign = UT_LIST_GET_FIRST(table->referenced_list);
while (foreign) {
/* Note that we may have an update which updates the index
record, but does NOT update the first fields which are
referenced in a foreign key constraint. Then the update does
NOT break the constraint. */
if (foreign->referenced_index == index
&& (node->is_delete
|| row_upd_changes_first_fields_binary(
entry, index, node->update,
foreign->n_fields))) {
if (foreign->foreign_table == NULL) {
dict_table_get(foreign->foreign_table_name,
trx);
}
if (foreign->foreign_table) {
mutex_enter(&(dict_sys->mutex));
(foreign->foreign_table
->n_foreign_key_checks_running)++;
mutex_exit(&(dict_sys->mutex));
}
/* NOTE that if the thread ends up waiting for a lock
we will release dict_operation_lock temporarily!
But the counter on the table protects 'foreign' from
being dropped while the check is running. */
err = row_ins_check_foreign_constraint(FALSE, foreign,
table, entry, thr);
if (foreign->foreign_table) {
mutex_enter(&(dict_sys->mutex));
ut_a(foreign->foreign_table
->n_foreign_key_checks_running > 0);
(foreign->foreign_table
->n_foreign_key_checks_running)--;
mutex_exit(&(dict_sys->mutex));
}
if (err != DB_SUCCESS) {
if (got_s_lock) {
row_mysql_unfreeze_data_dictionary(
trx);
}
mem_heap_free(heap);
return(err);
}
}
foreign = UT_LIST_GET_NEXT(referenced_list, foreign);
}
if (got_s_lock) {
row_mysql_unfreeze_data_dictionary(trx);
}
mem_heap_free(heap);
return(DB_SUCCESS);
}
/*************************************************************************
Creates an update node for a query graph. */
upd_node_t*
upd_node_create(
/*============*/
/* out, own: update node */
mem_heap_t* heap) /* in: mem heap where created */
{
upd_node_t* node;
node = mem_heap_alloc(heap, sizeof(upd_node_t));
node->common.type = QUE_NODE_UPDATE;
node->state = UPD_NODE_UPDATE_CLUSTERED;
node->select_will_do_update = FALSE;
node->in_mysql_interface = FALSE;
node->row = NULL;
node->ext_vec = NULL;
node->index = NULL;
node->update = NULL;
node->foreign = NULL;
node->cascade_heap = NULL;
node->cascade_node = NULL;
node->select = NULL;
node->heap = mem_heap_create(128);
node->magic_n = UPD_NODE_MAGIC_N;
node->cmpl_info = 0;
return(node);
}
/*************************************************************************
Updates the trx id and roll ptr field in a clustered index record in database
recovery. */
void
row_upd_rec_sys_fields_in_recovery(
/*===============================*/
rec_t* rec, /* in: record */
const ulint* offsets,/* in: array returned by rec_get_offsets() */
ulint pos, /* in: TRX_ID position in rec */
dulint trx_id, /* in: transaction id */
dulint roll_ptr)/* in: roll ptr of the undo log record */
{
byte* field;
ulint len;
field = rec_get_nth_field(rec, offsets, pos, &len);
ut_ad(len == DATA_TRX_ID_LEN);
trx_write_trx_id(field, trx_id);
field = rec_get_nth_field(rec, offsets, pos + 1, &len);
ut_ad(len == DATA_ROLL_PTR_LEN);
trx_write_roll_ptr(field, roll_ptr);
}
/*************************************************************************
Sets the trx id or roll ptr field of a clustered index entry. */
void
row_upd_index_entry_sys_field(
/*==========================*/
dtuple_t* entry, /* in: index entry, where the memory buffers
for sys fields are already allocated:
the function just copies the new values to
them */
dict_index_t* index, /* in: clustered index */
ulint type, /* in: DATA_TRX_ID or DATA_ROLL_PTR */
dulint val) /* in: value to write */
{
dfield_t* dfield;
byte* field;
ulint pos;
ut_ad(index->type & DICT_CLUSTERED);
pos = dict_index_get_sys_col_pos(index, type);
dfield = dtuple_get_nth_field(entry, pos);
field = dfield_get_data(dfield);
if (type == DATA_TRX_ID) {
trx_write_trx_id(field, val);
} else {
ut_ad(type == DATA_ROLL_PTR);
trx_write_roll_ptr(field, val);
}
}
/***************************************************************
Returns TRUE if row update changes size of some field in index or if some
field to be updated is stored externally in rec or update. */
ibool
row_upd_changes_field_size_or_external(
/*===================================*/
/* out: TRUE if the update changes the size of
some field in index or the field is external
in rec or update */
dict_index_t* index, /* in: index */
const ulint* offsets,/* in: rec_get_offsets(rec, index) */
upd_t* update) /* in: update vector */
{
upd_field_t* upd_field;
dfield_t* new_val;
ulint old_len;
ulint new_len;
ulint n_fields;
ulint i;
ut_ad(rec_offs_validate(NULL, index, offsets));
n_fields = upd_get_n_fields(update);
for (i = 0; i < n_fields; i++) {
upd_field = upd_get_nth_field(update, i);
new_val = &(upd_field->new_val);
new_len = new_val->len;
if (new_len == UNIV_SQL_NULL && !rec_offs_comp(offsets)) {
/* A bug fixed on Dec 31st, 2004: we looked at the
SQL NULL size from the wrong field! We may backport
this fix also to 4.0. The merge to 5.0 will be made
manually immediately after we commit this to 4.1. */
new_len = dtype_get_sql_null_size(
dict_index_get_nth_type(index,
upd_field->field_no));
}
old_len = rec_offs_nth_size(offsets, upd_field->field_no);
if (rec_offs_comp(offsets)
&& rec_offs_nth_sql_null(offsets,
upd_field->field_no)) {
/* Note that in the compact table format, for a
variable length field, an SQL NULL will use zero
bytes in the offset array at the start of the physical
record, but a zero-length value (empty string) will
use one byte! Thus, we cannot use update-in-place
if we update an SQL NULL varchar to an empty string! */
old_len = UNIV_SQL_NULL;
}
if (old_len != new_len) {
return(TRUE);
}
if (rec_offs_nth_extern(offsets, upd_field->field_no)) {
return(TRUE);
}
if (upd_field->extern_storage) {
return(TRUE);
}
}
return(FALSE);
}
/***************************************************************
Replaces the new column values stored in the update vector to the record
given. No field size changes are allowed. This function is used only for
a clustered index */
void
row_upd_rec_in_place(
/*=================*/
rec_t* rec, /* in/out: record where replaced */
const ulint* offsets,/* in: array returned by rec_get_offsets() */
upd_t* update) /* in: update vector */
{
upd_field_t* upd_field;
dfield_t* new_val;
ulint n_fields;
ulint i;
ut_ad(rec_offs_validate(rec, NULL, offsets));
rec_set_info_bits(rec, rec_offs_comp(offsets), update->info_bits);
n_fields = upd_get_n_fields(update);
for (i = 0; i < n_fields; i++) {
upd_field = upd_get_nth_field(update, i);
new_val = &(upd_field->new_val);
rec_set_nth_field(rec, offsets, upd_field->field_no,
dfield_get_data(new_val),
dfield_get_len(new_val));
}
}
/*************************************************************************
Writes into the redo log the values of trx id and roll ptr and enough info
to determine their positions within a clustered index record. */
byte*
row_upd_write_sys_vals_to_log(
/*==========================*/
/* out: new pointer to mlog */
dict_index_t* index, /* in: clustered index */
trx_t* trx, /* in: transaction */
dulint roll_ptr,/* in: roll ptr of the undo log record */
byte* log_ptr,/* pointer to a buffer of size > 20 opened
in mlog */
mtr_t* mtr __attribute__((unused))) /* in: mtr */
{
ut_ad(index->type & DICT_CLUSTERED);
ut_ad(mtr);
log_ptr += mach_write_compressed(log_ptr,
dict_index_get_sys_col_pos(index, DATA_TRX_ID));
trx_write_roll_ptr(log_ptr, roll_ptr);
log_ptr += DATA_ROLL_PTR_LEN;
log_ptr += mach_dulint_write_compressed(log_ptr, trx->id);
return(log_ptr);
}
/*************************************************************************
Parses the log data of system field values. */
byte*
row_upd_parse_sys_vals(
/*===================*/
/* out: log data end or NULL */
byte* ptr, /* in: buffer */
byte* end_ptr,/* in: buffer end */
ulint* pos, /* out: TRX_ID position in record */
dulint* trx_id, /* out: trx id */
dulint* roll_ptr)/* out: roll ptr */
{
ptr = mach_parse_compressed(ptr, end_ptr, pos);
if (ptr == NULL) {
return(NULL);
}
if (end_ptr < ptr + DATA_ROLL_PTR_LEN) {
return(NULL);
}
*roll_ptr = trx_read_roll_ptr(ptr);
ptr += DATA_ROLL_PTR_LEN;
ptr = mach_dulint_parse_compressed(ptr, end_ptr, trx_id);
return(ptr);
}
/***************************************************************
Writes to the redo log the new values of the fields occurring in the index. */
void
row_upd_index_write_log(
/*====================*/
upd_t* update, /* in: update vector */
byte* log_ptr,/* in: pointer to mlog buffer: must contain at least
MLOG_BUF_MARGIN bytes of free space; the buffer is
closed within this function */
mtr_t* mtr) /* in: mtr into whose log to write */
{
upd_field_t* upd_field;
dfield_t* new_val;
ulint len;
ulint n_fields;
byte* buf_end;
ulint i;
n_fields = upd_get_n_fields(update);
buf_end = log_ptr + MLOG_BUF_MARGIN;
mach_write_to_1(log_ptr, update->info_bits);
log_ptr++;
log_ptr += mach_write_compressed(log_ptr, n_fields);
for (i = 0; i < n_fields; i++) {
#if MLOG_BUF_MARGIN <= 30
# error "MLOG_BUF_MARGIN <= 30"
#endif
if (log_ptr + 30 > buf_end) {
mlog_close(mtr, log_ptr);
log_ptr = mlog_open(mtr, MLOG_BUF_MARGIN);
buf_end = log_ptr + MLOG_BUF_MARGIN;
}
upd_field = upd_get_nth_field(update, i);
new_val = &(upd_field->new_val);
len = new_val->len;
log_ptr += mach_write_compressed(log_ptr, upd_field->field_no);
log_ptr += mach_write_compressed(log_ptr, len);
if (len != UNIV_SQL_NULL) {
if (log_ptr + len < buf_end) {
ut_memcpy(log_ptr, new_val->data, len);
log_ptr += len;
} else {
mlog_close(mtr, log_ptr);
mlog_catenate_string(mtr, new_val->data, len);
log_ptr = mlog_open(mtr, MLOG_BUF_MARGIN);
buf_end = log_ptr + MLOG_BUF_MARGIN;
}
}
}
mlog_close(mtr, log_ptr);
}
/*************************************************************************
Parses the log data written by row_upd_index_write_log. */
byte*
row_upd_index_parse(
/*================*/
/* out: log data end or NULL */
byte* ptr, /* in: buffer */
byte* end_ptr,/* in: buffer end */
mem_heap_t* heap, /* in: memory heap where update vector is
built */
upd_t** update_out)/* out: update vector */
{
upd_t* update;
upd_field_t* upd_field;
dfield_t* new_val;
ulint len;
ulint n_fields;
byte* buf;
ulint info_bits;
ulint i;
if (end_ptr < ptr + 1) {
return(NULL);
}
info_bits = mach_read_from_1(ptr);
ptr++;
ptr = mach_parse_compressed(ptr, end_ptr, &n_fields);
if (ptr == NULL) {
return(NULL);
}
update = upd_create(n_fields, heap);
update->info_bits = info_bits;
for (i = 0; i < n_fields; i++) {
upd_field = upd_get_nth_field(update, i);
new_val = &(upd_field->new_val);
ptr = mach_parse_compressed(ptr, end_ptr,
&(upd_field->field_no));
if (ptr == NULL) {
return(NULL);
}
ptr = mach_parse_compressed(ptr, end_ptr, &len);
if (ptr == NULL) {
return(NULL);
}
new_val->len = len;
if (len != UNIV_SQL_NULL) {
if (end_ptr < ptr + len) {
return(NULL);
} else {
buf = mem_heap_alloc(heap, len);
ut_memcpy(buf, ptr, len);
ptr += len;
new_val->data = buf;
}
}
}
*update_out = update;
return(ptr);
}
/*******************************************************************
Returns TRUE if ext_vec contains i. */
static
ibool
upd_ext_vec_contains(
/*=================*/
/* out: TRUE if i is in ext_vec */
ulint* ext_vec, /* in: array of indexes or NULL */
ulint n_ext_vec, /* in: number of numbers in ext_vec */
ulint i) /* in: a number */
{
ulint j;
if (ext_vec == NULL) {
return(FALSE);
}
for (j = 0; j < n_ext_vec; j++) {
if (ext_vec[j] == i) {
return(TRUE);
}
}
return(FALSE);
}
/*******************************************************************
Builds an update vector from those fields which in a secondary index entry
differ from a record that has the equal ordering fields. NOTE: we compare
the fields as binary strings! */
upd_t*
row_upd_build_sec_rec_difference_binary(
/*====================================*/
/* out, own: update vector of differing
fields */
dict_index_t* index, /* in: index */
dtuple_t* entry, /* in: entry to insert */
rec_t* rec, /* in: secondary index record */
trx_t* trx, /* in: transaction */
mem_heap_t* heap) /* in: memory heap from which allocated */
{
upd_field_t* upd_field;
dfield_t* dfield;
byte* data;
ulint len;
upd_t* update;
ulint n_diff;
ulint i;
ulint offsets_[REC_OFFS_SMALL_SIZE];
const ulint* offsets;
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
/* This function is used only for a secondary index */
ut_a(0 == (index->type & DICT_CLUSTERED));
update = upd_create(dtuple_get_n_fields(entry), heap);
n_diff = 0;
offsets = rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &heap);
for (i = 0; i < dtuple_get_n_fields(entry); i++) {
data = rec_get_nth_field(rec, offsets, i, &len);
dfield = dtuple_get_nth_field(entry, i);
/* NOTE that it may be that len != dfield_get_len(dfield) if we
are updating in a character set and collation where strings of
different length can be equal in an alphabetical comparison,
and also in the case where we have a column prefix index
and the last characters in the index field are spaces; the
latter case probably caused the assertion failures reported at
row0upd.c line 713 in versions 4.0.14 - 4.0.16. */
/* NOTE: we compare the fields as binary strings!
(No collation) */
if (!dfield_data_is_binary_equal(dfield, len, data)) {
upd_field = upd_get_nth_field(update, n_diff);
dfield_copy(&(upd_field->new_val), dfield);
upd_field_set_field_no(upd_field, i, index, trx);
upd_field->extern_storage = FALSE;
n_diff++;
}
}
update->n_fields = n_diff;
return(update);
}
/*******************************************************************
Builds an update vector from those fields, excluding the roll ptr and
trx id fields, which in an index entry differ from a record that has
the equal ordering fields. NOTE: we compare the fields as binary strings! */
upd_t*
row_upd_build_difference_binary(
/*============================*/
/* out, own: update vector of differing
fields, excluding roll ptr and trx id */
dict_index_t* index, /* in: clustered index */
dtuple_t* entry, /* in: entry to insert */
ulint* ext_vec,/* in: array containing field numbers of
externally stored fields in entry, or NULL */
ulint n_ext_vec,/* in: number of fields in ext_vec */
rec_t* rec, /* in: clustered index record */
trx_t* trx, /* in: transaction */
mem_heap_t* heap) /* in: memory heap from which allocated */
{
upd_field_t* upd_field;
dfield_t* dfield;
byte* data;
ulint len;
upd_t* update;
ulint n_diff;
ulint roll_ptr_pos;
ulint trx_id_pos;
ibool extern_bit;
ulint i;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
const ulint* offsets;
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
/* This function is used only for a clustered index */
ut_a(index->type & DICT_CLUSTERED);
update = upd_create(dtuple_get_n_fields(entry), heap);
n_diff = 0;
roll_ptr_pos = dict_index_get_sys_col_pos(index, DATA_ROLL_PTR);
trx_id_pos = dict_index_get_sys_col_pos(index, DATA_TRX_ID);
offsets = rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &heap);
for (i = 0; i < dtuple_get_n_fields(entry); i++) {
data = rec_get_nth_field(rec, offsets, i, &len);
dfield = dtuple_get_nth_field(entry, i);
/* NOTE: we compare the fields as binary strings!
(No collation) */
if (i == trx_id_pos || i == roll_ptr_pos) {
goto skip_compare;
}
extern_bit = upd_ext_vec_contains(ext_vec, n_ext_vec, i);
if (UNIV_UNLIKELY(extern_bit ==
(ibool)!rec_offs_nth_extern(offsets, i))
|| !dfield_data_is_binary_equal(dfield, len, data)) {
upd_field = upd_get_nth_field(update, n_diff);
dfield_copy(&(upd_field->new_val), dfield);
upd_field_set_field_no(upd_field, i, index, trx);
upd_field->extern_storage = extern_bit;
n_diff++;
}
skip_compare:
;
}
update->n_fields = n_diff;
return(update);
}
/***************************************************************
Replaces the new column values stored in the update vector to the index entry
given. */
void
row_upd_index_replace_new_col_vals_index_pos(
/*=========================================*/
dtuple_t* entry, /* in/out: index entry where replaced */
dict_index_t* index, /* in: index; NOTE that this may also be a
non-clustered index */
upd_t* update, /* in: an update vector built for the index so
that the field number in an upd_field is the
index position */
ibool order_only,
/* in: if TRUE, limit the replacement to
ordering fields of index; note that this
does not work for non-clustered indexes. */
mem_heap_t* heap) /* in: memory heap to which we allocate and
copy the new values, set this as NULL if you
do not want allocation */
{
dict_field_t* field;
upd_field_t* upd_field;
dfield_t* dfield;
dfield_t* new_val;
ulint j;
ulint i;
ulint n_fields;
dtype_t* cur_type;
ut_ad(index);
dtuple_set_info_bits(entry, update->info_bits);
if (order_only) {
n_fields = dict_index_get_n_unique(index);
} else {
n_fields = dict_index_get_n_fields(index);
}
for (j = 0; j < n_fields; j++) {
field = dict_index_get_nth_field(index, j);
for (i = 0; i < upd_get_n_fields(update); i++) {
upd_field = upd_get_nth_field(update, i);
if (upd_field->field_no == j) {
dfield = dtuple_get_nth_field(entry, j);
new_val = &(upd_field->new_val);
dfield_set_data(dfield, new_val->data,
new_val->len);
if (heap && new_val->len != UNIV_SQL_NULL) {
dfield->data = mem_heap_alloc(heap,
new_val->len);
ut_memcpy(dfield->data, new_val->data,
new_val->len);
}
if (field->prefix_len > 0
&& new_val->len != UNIV_SQL_NULL) {
cur_type = dict_col_get_type(
dict_field_get_col(field));
dfield->len =
dtype_get_at_most_n_mbchars(
cur_type,
field->prefix_len,
new_val->len,
new_val->data);
}
}
}
}
}
/***************************************************************
Replaces the new column values stored in the update vector to the index entry
given. */
void
row_upd_index_replace_new_col_vals(
/*===============================*/
dtuple_t* entry, /* in/out: index entry where replaced */
dict_index_t* index, /* in: index; NOTE that this may also be a
non-clustered index */
upd_t* update, /* in: an update vector built for the
CLUSTERED index so that the field number in
an upd_field is the clustered index position */
mem_heap_t* heap) /* in: memory heap to which we allocate and
copy the new values, set this as NULL if you
do not want allocation */
{
dict_field_t* field;
upd_field_t* upd_field;
dfield_t* dfield;
dfield_t* new_val;
ulint j;
ulint i;
dtype_t* cur_type;
ut_ad(index);
dtuple_set_info_bits(entry, update->info_bits);
for (j = 0; j < dict_index_get_n_fields(index); j++) {
field = dict_index_get_nth_field(index, j);
for (i = 0; i < upd_get_n_fields(update); i++) {
upd_field = upd_get_nth_field(update, i);
if (upd_field->field_no == field->col->clust_pos) {
dfield = dtuple_get_nth_field(entry, j);
new_val = &(upd_field->new_val);
dfield_set_data(dfield, new_val->data,
new_val->len);
if (heap && new_val->len != UNIV_SQL_NULL) {
dfield->data = mem_heap_alloc(heap,
new_val->len);
ut_memcpy(dfield->data, new_val->data,
new_val->len);
}
if (field->prefix_len > 0
&& new_val->len != UNIV_SQL_NULL) {
cur_type = dict_col_get_type(
dict_field_get_col(field));
dfield->len =
dtype_get_at_most_n_mbchars(
cur_type,
field->prefix_len,
new_val->len,
new_val->data);
}
}
}
}
}
/***************************************************************
Checks if an update vector changes an ordering field of an index record.
This function is fast if the update vector is short or the number of ordering
fields in the index is small. Otherwise, this can be quadratic.
NOTE: we compare the fields as binary strings! */
ibool
row_upd_changes_ord_field_binary(
/*=============================*/
/* out: TRUE if update vector changes
an ordering field in the index record;
NOTE: the fields are compared as binary
strings */
dtuple_t* row, /* in: old value of row, or NULL if the
row and the data values in update are not
known when this function is called, e.g., at
compile time */
dict_index_t* index, /* in: index of the record */
upd_t* update) /* in: update vector for the row; NOTE: the
field numbers in this MUST be clustered index
positions! */
{
upd_field_t* upd_field;
dict_field_t* ind_field;
dict_col_t* col;
ulint n_unique;
ulint n_upd_fields;
ulint col_pos;
ulint col_no;
ulint i, j;
ut_ad(update && index);
n_unique = dict_index_get_n_unique(index);
n_upd_fields = upd_get_n_fields(update);
for (i = 0; i < n_unique; i++) {
ind_field = dict_index_get_nth_field(index, i);
col = dict_field_get_col(ind_field);
col_pos = dict_col_get_clust_pos(col);
col_no = dict_col_get_no(col);
for (j = 0; j < n_upd_fields; j++) {
upd_field = upd_get_nth_field(update, j);
/* Note that if the index field is a column prefix
then it may be that row does not contain an externally
stored part of the column value, and we cannot compare
the datas */
if (col_pos == upd_field->field_no
&& (row == NULL
|| ind_field->prefix_len > 0
|| !dfield_datas_are_binary_equal(
dtuple_get_nth_field(row,
col_no),
&(upd_field->new_val)))) {
return(TRUE);
}
}
}
return(FALSE);
}
/***************************************************************
Checks if an update vector changes an ordering field of an index record.
NOTE: we compare the fields as binary strings! */
ibool
row_upd_changes_some_index_ord_field_binary(
/*========================================*/
/* out: TRUE if update vector may change
an ordering field in an index record */
dict_table_t* table, /* in: table */
upd_t* update) /* in: update vector for the row */
{
upd_field_t* upd_field;
dict_index_t* index;
ulint i;
index = dict_table_get_first_index(table);
for (i = 0; i < upd_get_n_fields(update); i++) {
upd_field = upd_get_nth_field(update, i);
if (dict_field_get_col(dict_index_get_nth_field(index,
upd_field->field_no))
->ord_part) {
return(TRUE);
}
}
return(FALSE);
}
/***************************************************************
Checks if an update vector changes some of the first ordering fields of an
index record. This is only used in foreign key checks and we can assume
that index does not contain column prefixes. */
static
ibool
row_upd_changes_first_fields_binary(
/*================================*/
/* out: TRUE if changes */
dtuple_t* entry, /* in: index entry */
dict_index_t* index, /* in: index of entry */
upd_t* update, /* in: update vector for the row */
ulint n) /* in: how many first fields to check */
{
upd_field_t* upd_field;
dict_field_t* ind_field;
dict_col_t* col;
ulint n_upd_fields;
ulint col_pos;
ulint i, j;
ut_a(update && index);
ut_a(n <= dict_index_get_n_fields(index));
n_upd_fields = upd_get_n_fields(update);
for (i = 0; i < n; i++) {
ind_field = dict_index_get_nth_field(index, i);
col = dict_field_get_col(ind_field);
col_pos = dict_col_get_clust_pos(col);
ut_a(ind_field->prefix_len == 0);
for (j = 0; j < n_upd_fields; j++) {
upd_field = upd_get_nth_field(update, j);
if (col_pos == upd_field->field_no
&& !dfield_datas_are_binary_equal(
dtuple_get_nth_field(entry, i),
&(upd_field->new_val))) {
return(TRUE);
}
}
}
return(FALSE);
}
/*************************************************************************
Copies the column values from a record. */
UNIV_INLINE
void
row_upd_copy_columns(
/*=================*/
rec_t* rec, /* in: record in a clustered index */
const ulint* offsets,/* in: array returned by rec_get_offsets() */
sym_node_t* column) /* in: first column in a column list, or
NULL */
{
byte* data;
ulint len;
while (column) {
data = rec_get_nth_field(rec, offsets,
column->field_nos[SYM_CLUST_FIELD_NO],
&len);
eval_node_copy_and_alloc_val(column, data, len);
column = UT_LIST_GET_NEXT(col_var_list, column);
}
}
/*************************************************************************
Calculates the new values for fields to update. Note that row_upd_copy_columns
must have been called first. */
UNIV_INLINE
void
row_upd_eval_new_vals(
/*==================*/
upd_t* update) /* in: update vector */
{
que_node_t* exp;
upd_field_t* upd_field;
ulint n_fields;
ulint i;
n_fields = upd_get_n_fields(update);
for (i = 0; i < n_fields; i++) {
upd_field = upd_get_nth_field(update, i);
exp = upd_field->exp;
eval_exp(exp);
dfield_copy_data(&(upd_field->new_val), que_node_get_val(exp));
}
}
/***************************************************************
Stores to the heap the row on which the node->pcur is positioned. */
static
void
row_upd_store_row(
/*==============*/
upd_node_t* node) /* in: row update node */
{
dict_index_t* clust_index;
upd_t* update;
rec_t* rec;
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
const ulint* offsets;
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
ut_ad(node->pcur->latch_mode != BTR_NO_LATCHES);
if (node->row != NULL) {
mem_heap_empty(node->heap);
node->row = NULL;
}
clust_index = dict_table_get_first_index(node->table);
rec = btr_pcur_get_rec(node->pcur);
offsets = rec_get_offsets(rec, clust_index, offsets_,
ULINT_UNDEFINED, &heap);
node->row = row_build(ROW_COPY_DATA, clust_index, rec, offsets,
node->heap);
node->ext_vec = mem_heap_alloc(node->heap, sizeof(ulint)
* rec_offs_n_fields(offsets));
if (node->is_delete) {
update = NULL;
} else {
update = node->update;
}
node->n_ext_vec = btr_push_update_extern_fields(node->ext_vec,
offsets, update);
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
}
/***************************************************************
Updates a secondary index entry of a row. */
static
ulint
row_upd_sec_index_entry(
/*====================*/
/* out: DB_SUCCESS if operation successfully
completed, else error code or DB_LOCK_WAIT */
upd_node_t* node, /* in: row update node */
que_thr_t* thr) /* in: query thread */
{
ibool check_ref;
ibool found;
dict_index_t* index;
dtuple_t* entry;
btr_pcur_t pcur;
btr_cur_t* btr_cur;
mem_heap_t* heap;
rec_t* rec;
ulint err = DB_SUCCESS;
mtr_t mtr;
trx_t* trx = thr_get_trx(thr);
index = node->index;
check_ref = row_upd_index_is_referenced(index, trx);
heap = mem_heap_create(1024);
/* Build old index entry */
entry = row_build_index_entry(node->row, index, heap);
log_free_check();
mtr_start(&mtr);
found = row_search_index_entry(index, entry, BTR_MODIFY_LEAF, &pcur,
&mtr);
btr_cur = btr_pcur_get_btr_cur(&pcur);
rec = btr_cur_get_rec(btr_cur);
if (UNIV_UNLIKELY(!found)) {
fputs("InnoDB: error in sec index entry update in\n"
"InnoDB: ", stderr);
dict_index_name_print(stderr, trx, index);
fputs("\n"
"InnoDB: tuple ", stderr);
dtuple_print(stderr, entry);
fputs("\n"
"InnoDB: record ", stderr);
rec_print(stderr, rec, index);
putc('\n', stderr);
trx_print(stderr, trx, 0);
fputs("\n"
"InnoDB: Submit a detailed bug report to http://bugs.mysql.com\n", stderr);
} else {
/* Delete mark the old index record; it can already be
delete marked if we return after a lock wait in
row_ins_index_entry below */
if (!rec_get_deleted_flag(rec,
dict_table_is_comp(index->table))) {
err = btr_cur_del_mark_set_sec_rec(0, btr_cur, TRUE,
thr, &mtr);
if (err == DB_SUCCESS && check_ref) {
/* NOTE that the following call loses
the position of pcur ! */
err = row_upd_check_references_constraints(
node,
&pcur, index->table,
index, thr, &mtr);
if (err != DB_SUCCESS) {
goto close_cur;
}
}
}
}
close_cur:
btr_pcur_close(&pcur);
mtr_commit(&mtr);
if (node->is_delete || err != DB_SUCCESS) {
mem_heap_free(heap);
return(err);
}
/* Build a new index entry */
row_upd_index_replace_new_col_vals(entry, index, node->update, NULL);
/* Insert new index entry */
err = row_ins_index_entry(index, entry, NULL, 0, thr);
mem_heap_free(heap);
return(err);
}
/***************************************************************
Updates secondary index record if it is changed in the row update. This
should be quite rare in database applications. */
UNIV_INLINE
ulint
row_upd_sec_step(
/*=============*/
/* out: DB_SUCCESS if operation successfully
completed, else error code or DB_LOCK_WAIT */
upd_node_t* node, /* in: row update node */
que_thr_t* thr) /* in: query thread */
{
ulint err;
ut_ad((node->state == UPD_NODE_UPDATE_ALL_SEC)
|| (node->state == UPD_NODE_UPDATE_SOME_SEC));
ut_ad(!(node->index->type & DICT_CLUSTERED));
if (node->state == UPD_NODE_UPDATE_ALL_SEC
|| row_upd_changes_ord_field_binary(node->row, node->index,
node->update)) {
err = row_upd_sec_index_entry(node, thr);
return(err);
}
return(DB_SUCCESS);
}
/***************************************************************
Marks the clustered index record deleted and inserts the updated version
of the record to the index. This function should be used when the ordering
fields of the clustered index record change. This should be quite rare in
database applications. */
static
ulint
row_upd_clust_rec_by_insert(
/*========================*/
/* out: DB_SUCCESS if operation successfully
completed, else error code or DB_LOCK_WAIT */
upd_node_t* node, /* in: row update node */
dict_index_t* index, /* in: clustered index of the record */
que_thr_t* thr, /* in: query thread */
ibool check_ref,/* in: TRUE if index may be referenced in
a foreign key constraint */
mtr_t* mtr) /* in: mtr; gets committed here */
{
mem_heap_t* heap = NULL;
btr_pcur_t* pcur;
btr_cur_t* btr_cur;
trx_t* trx;
dict_table_t* table;
dtuple_t* entry;
ulint err;
ut_ad(node);
ut_ad(index->type & DICT_CLUSTERED);
trx = thr_get_trx(thr);
table = node->table;
pcur = node->pcur;
btr_cur = btr_pcur_get_btr_cur(pcur);
if (node->state != UPD_NODE_INSERT_CLUSTERED) {
ulint offsets_[REC_OFFS_NORMAL_SIZE];
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
err = btr_cur_del_mark_set_clust_rec(BTR_NO_LOCKING_FLAG,
btr_cur, TRUE, thr, mtr);
if (err != DB_SUCCESS) {
mtr_commit(mtr);
return(err);
}
/* Mark as not-owned the externally stored fields which the new
row inherits from the delete marked record: purge should not
free those externally stored fields even if the delete marked
record is removed from the index tree, or updated. */
btr_cur_mark_extern_inherited_fields(btr_cur_get_rec(btr_cur),
rec_get_offsets(btr_cur_get_rec(btr_cur),
dict_table_get_first_index(table), offsets_,
ULINT_UNDEFINED, &heap), node->update, mtr);
if (check_ref) {
/* NOTE that the following call loses
the position of pcur ! */
err = row_upd_check_references_constraints(node,
pcur, table,
index, thr, mtr);
if (err != DB_SUCCESS) {
mtr_commit(mtr);
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
return(err);
}
}
}
mtr_commit(mtr);
if (!heap) {
heap = mem_heap_create(500);
}
node->state = UPD_NODE_INSERT_CLUSTERED;
entry = row_build_index_entry(node->row, index, heap);
row_upd_index_replace_new_col_vals(entry, index, node->update, NULL);
row_upd_index_entry_sys_field(entry, index, DATA_TRX_ID, trx->id);
/* If we return from a lock wait, for example, we may have
extern fields marked as not-owned in entry (marked in the
if-branch above). We must unmark them. */
btr_cur_unmark_dtuple_extern_fields(entry, node->ext_vec,
node->n_ext_vec);
/* We must mark non-updated extern fields in entry as inherited,
so that a possible rollback will not free them */
btr_cur_mark_dtuple_inherited_extern(entry, node->ext_vec,
node->n_ext_vec,
node->update);
err = row_ins_index_entry(index, entry, node->ext_vec,
node->n_ext_vec, thr);
mem_heap_free(heap);
return(err);
}
/***************************************************************
Updates a clustered index record of a row when the ordering fields do
not change. */
static
ulint
row_upd_clust_rec(
/*==============*/
/* out: DB_SUCCESS if operation successfully
completed, else error code or DB_LOCK_WAIT */
upd_node_t* node, /* in: row update node */
dict_index_t* index, /* in: clustered index */
que_thr_t* thr, /* in: query thread */
mtr_t* mtr) /* in: mtr; gets committed here */
{
big_rec_t* big_rec = NULL;
btr_pcur_t* pcur;
btr_cur_t* btr_cur;
ulint err;
ut_ad(node);
ut_ad(index->type & DICT_CLUSTERED);
pcur = node->pcur;
btr_cur = btr_pcur_get_btr_cur(pcur);
ut_ad(!rec_get_deleted_flag(btr_pcur_get_rec(pcur),
dict_table_is_comp(index->table)));
/* Try optimistic updating of the record, keeping changes within
the page; we do not check locks because we assume the x-lock on the
record to update */
if (node->cmpl_info & UPD_NODE_NO_SIZE_CHANGE) {
err = btr_cur_update_in_place(BTR_NO_LOCKING_FLAG,
btr_cur, node->update,
node->cmpl_info, thr, mtr);
} else {
err = btr_cur_optimistic_update(BTR_NO_LOCKING_FLAG,
btr_cur, node->update,
node->cmpl_info, thr, mtr);
}
mtr_commit(mtr);
if (err == DB_SUCCESS) {
return(err);
}
if (buf_LRU_buf_pool_running_out()) {
return(DB_LOCK_TABLE_FULL);
}
/* We may have to modify the tree structure: do a pessimistic descent
down the index tree */
mtr_start(mtr);
/* NOTE: this transaction has an s-lock or x-lock on the record and
therefore other transactions cannot modify the record when we have no
latch on the page. In addition, we assume that other query threads of
the same transaction do not modify the record in the meantime.
Therefore we can assert that the restoration of the cursor succeeds. */
ut_a(btr_pcur_restore_position(BTR_MODIFY_TREE, pcur, mtr));
ut_ad(!rec_get_deleted_flag(btr_pcur_get_rec(pcur),
dict_table_is_comp(index->table)));
err = btr_cur_pessimistic_update(BTR_NO_LOCKING_FLAG, btr_cur,
&big_rec, node->update,
node->cmpl_info, thr, mtr);
mtr_commit(mtr);
if (err == DB_SUCCESS && big_rec) {
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
rec_t* rec;
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
mtr_start(mtr);
ut_a(btr_pcur_restore_position(BTR_MODIFY_TREE, pcur, mtr));
rec = btr_cur_get_rec(btr_cur);
err = btr_store_big_rec_extern_fields(index, rec,
rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &heap),
big_rec, mtr);
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
mtr_commit(mtr);
}
if (big_rec) {
dtuple_big_rec_free(big_rec);
}
return(err);
}
/***************************************************************
Delete marks a clustered index record. */
static
ulint
row_upd_del_mark_clust_rec(
/*=======================*/
/* out: DB_SUCCESS if operation successfully
completed, else error code */
upd_node_t* node, /* in: row update node */
dict_index_t* index, /* in: clustered index */
que_thr_t* thr, /* in: query thread */
ibool check_ref,/* in: TRUE if index may be referenced in
a foreign key constraint */
mtr_t* mtr) /* in: mtr; gets committed here */
{
btr_pcur_t* pcur;
btr_cur_t* btr_cur;
ulint err;
ut_ad(node);
ut_ad(index->type & DICT_CLUSTERED);
ut_ad(node->is_delete);
pcur = node->pcur;
btr_cur = btr_pcur_get_btr_cur(pcur);
/* Store row because we have to build also the secondary index
entries */
row_upd_store_row(node);
/* Mark the clustered index record deleted; we do not have to check
locks, because we assume that we have an x-lock on the record */
err = btr_cur_del_mark_set_clust_rec(BTR_NO_LOCKING_FLAG,
btr_cur, TRUE, thr, mtr);
if (err == DB_SUCCESS && check_ref) {
/* NOTE that the following call loses the position of pcur ! */
err = row_upd_check_references_constraints(node,
pcur, index->table,
index, thr, mtr);
if (err != DB_SUCCESS) {
mtr_commit(mtr);
return(err);
}
}
mtr_commit(mtr);
return(err);
}
/***************************************************************
Updates the clustered index record. */
static
ulint
row_upd_clust_step(
/*===============*/
/* out: DB_SUCCESS if operation successfully
completed, DB_LOCK_WAIT in case of a lock wait,
else error code */
upd_node_t* node, /* in: row update node */
que_thr_t* thr) /* in: query thread */
{
dict_index_t* index;
btr_pcur_t* pcur;
ibool success;
ibool check_ref;
ulint err;
mtr_t* mtr;
mtr_t mtr_buf;
rec_t* rec;
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
const ulint* offsets;
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
index = dict_table_get_first_index(node->table);
check_ref = row_upd_index_is_referenced(index, thr_get_trx(thr));
pcur = node->pcur;
/* We have to restore the cursor to its position */
mtr = &mtr_buf;
mtr_start(mtr);
/* If the restoration does not succeed, then the same
transaction has deleted the record on which the cursor was,
and that is an SQL error. If the restoration succeeds, it may
still be that the same transaction has successively deleted
and inserted a record with the same ordering fields, but in
that case we know that the transaction has at least an
implicit x-lock on the record. */
ut_a(pcur->rel_pos == BTR_PCUR_ON);
success = btr_pcur_restore_position(BTR_MODIFY_LEAF, pcur, mtr);
if (!success) {
err = DB_RECORD_NOT_FOUND;
mtr_commit(mtr);
return(err);
}
/* If this is a row in SYS_INDEXES table of the data dictionary,
then we have to free the file segments of the index tree associated
with the index */
if (node->is_delete
&& ut_dulint_cmp(node->table->id, DICT_INDEXES_ID) == 0) {
dict_drop_index_tree(btr_pcur_get_rec(pcur), mtr);
mtr_commit(mtr);
mtr_start(mtr);
success = btr_pcur_restore_position(BTR_MODIFY_LEAF, pcur,
mtr);
if (!success) {
err = DB_ERROR;
mtr_commit(mtr);
return(err);
}
}
rec = btr_pcur_get_rec(pcur);
offsets = rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &heap);
if (!node->has_clust_rec_x_lock) {
err = lock_clust_rec_modify_check_and_lock(0,
rec, index, offsets, thr);
if (err != DB_SUCCESS) {
mtr_commit(mtr);
goto exit_func;
}
}
/* NOTE: the following function calls will also commit mtr */
if (node->is_delete) {
err = row_upd_del_mark_clust_rec(node, index, thr, check_ref,
mtr);
if (err == DB_SUCCESS) {
node->state = UPD_NODE_UPDATE_ALL_SEC;
node->index = dict_table_get_next_index(index);
}
exit_func:
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
return(err);
}
/* If the update is made for MySQL, we already have the update vector
ready, else we have to do some evaluation: */
if (!node->in_mysql_interface) {
/* Copy the necessary columns from clust_rec and calculate the
new values to set */
row_upd_copy_columns(rec, offsets,
UT_LIST_GET_FIRST(node->columns));
row_upd_eval_new_vals(node->update);
}
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
if (node->cmpl_info & UPD_NODE_NO_ORD_CHANGE) {
err = row_upd_clust_rec(node, index, thr, mtr);
return(err);
}
row_upd_store_row(node);
if (row_upd_changes_ord_field_binary(node->row, index, node->update)) {
/* Update causes an ordering field (ordering fields within
the B-tree) of the clustered index record to change: perform
the update by delete marking and inserting.
TODO! What to do to the 'Halloween problem', where an update
moves the record forward in index so that it is again
updated when the cursor arrives there? Solution: the
read operation must check the undo record undo number when
choosing records to update. MySQL solves now the problem
externally! */
err = row_upd_clust_rec_by_insert(node, index, thr, check_ref,
mtr);
if (err != DB_SUCCESS) {
return(err);
}
node->state = UPD_NODE_UPDATE_ALL_SEC;
} else {
err = row_upd_clust_rec(node, index, thr, mtr);
if (err != DB_SUCCESS) {
return(err);
}
node->state = UPD_NODE_UPDATE_SOME_SEC;
}
node->index = dict_table_get_next_index(index);
return(err);
}
/***************************************************************
Updates the affected index records of a row. When the control is transferred
to this node, we assume that we have a persistent cursor which was on a
record, and the position of the cursor is stored in the cursor. */
static
ulint
row_upd(
/*====*/
/* out: DB_SUCCESS if operation successfully
completed, else error code or DB_LOCK_WAIT */
upd_node_t* node, /* in: row update node */
que_thr_t* thr) /* in: query thread */
{
ulint err = DB_SUCCESS;
ut_ad(node && thr);
if (node->in_mysql_interface) {
/* We do not get the cmpl_info value from the MySQL
interpreter: we must calculate it on the fly: */
if (node->is_delete ||
row_upd_changes_some_index_ord_field_binary(
node->table, node->update)) {
node->cmpl_info = 0;
} else {
node->cmpl_info = UPD_NODE_NO_ORD_CHANGE;
}
}
if (node->state == UPD_NODE_UPDATE_CLUSTERED
|| node->state == UPD_NODE_INSERT_CLUSTERED) {
err = row_upd_clust_step(node, thr);
if (err != DB_SUCCESS) {
goto function_exit;
}
}
if (!node->is_delete && (node->cmpl_info & UPD_NODE_NO_ORD_CHANGE)) {
goto function_exit;
}
while (node->index != NULL) {
err = row_upd_sec_step(node, thr);
if (err != DB_SUCCESS) {
goto function_exit;
}
node->index = dict_table_get_next_index(node->index);
}
function_exit:
if (err == DB_SUCCESS) {
/* Do some cleanup */
if (node->row != NULL) {
node->row = NULL;
node->n_ext_vec = 0;
mem_heap_empty(node->heap);
}
node->state = UPD_NODE_UPDATE_CLUSTERED;
}
return(err);
}
/***************************************************************
Updates a row in a table. This is a high-level function used in SQL execution
graphs. */
que_thr_t*
row_upd_step(
/*=========*/
/* out: query thread to run next or NULL */
que_thr_t* thr) /* in: query thread */
{
upd_node_t* node;
sel_node_t* sel_node;
que_node_t* parent;
ulint err = DB_SUCCESS;
trx_t* trx;
ut_ad(thr);
trx = thr_get_trx(thr);
trx_start_if_not_started(trx);
node = thr->run_node;
sel_node = node->select;
parent = que_node_get_parent(node);
ut_ad(que_node_get_type(node) == QUE_NODE_UPDATE);
if (thr->prev_node == parent) {
node->state = UPD_NODE_SET_IX_LOCK;
}
if (node->state == UPD_NODE_SET_IX_LOCK) {
if (!node->has_clust_rec_x_lock) {
/* It may be that the current session has not yet
started its transaction, or it has been committed: */
err = lock_table(0, node->table, LOCK_IX, thr);
if (err != DB_SUCCESS) {
goto error_handling;
}
}
node->state = UPD_NODE_UPDATE_CLUSTERED;
if (node->searched_update) {
/* Reset the cursor */
sel_node->state = SEL_NODE_OPEN;
/* Fetch a row to update */
thr->run_node = sel_node;
return(thr);
}
}
/* sel_node is NULL if we are in the MySQL interface */
if (sel_node && (sel_node->state != SEL_NODE_FETCH)) {
if (!node->searched_update) {
/* An explicit cursor should be positioned on a row
to update */
ut_error;
err = DB_ERROR;
goto error_handling;
}
ut_ad(sel_node->state == SEL_NODE_NO_MORE_ROWS);
/* No more rows to update, or the select node performed the
updates directly in-place */
thr->run_node = parent;
return(thr);
}
/* DO THE CHECKS OF THE CONSISTENCY CONSTRAINTS HERE */
err = row_upd(node, thr);
error_handling:
trx->error_state = err;
if (err == DB_SUCCESS) {
/* Ok: do nothing */
} else if (err == DB_LOCK_WAIT) {
return(NULL);
} else {
return(NULL);
}
/* DO THE TRIGGER ACTIONS HERE */
if (node->searched_update) {
/* Fetch next row to update */
thr->run_node = sel_node;
} else {
/* It was an explicit cursor update */
thr->run_node = parent;
}
node->state = UPD_NODE_UPDATE_CLUSTERED;
return(thr);
}
/*************************************************************************
Performs an in-place update for the current clustered index record in
select. */
void
row_upd_in_place_in_select(
/*=======================*/
sel_node_t* sel_node, /* in: select node */
que_thr_t* thr, /* in: query thread */
mtr_t* mtr) /* in: mtr */
{
upd_node_t* node;
btr_pcur_t* pcur;
btr_cur_t* btr_cur;
ulint err;
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
*offsets_ = (sizeof offsets_) / sizeof *offsets_;
ut_ad(sel_node->select_will_do_update);
ut_ad(sel_node->latch_mode == BTR_MODIFY_LEAF);
ut_ad(sel_node->asc);
node = que_node_get_parent(sel_node);
ut_ad(que_node_get_type(node) == QUE_NODE_UPDATE);
pcur = node->pcur;
btr_cur = btr_pcur_get_btr_cur(pcur);
/* Copy the necessary columns from clust_rec and calculate the new
values to set */
row_upd_copy_columns(btr_pcur_get_rec(pcur), rec_get_offsets(
btr_pcur_get_rec(pcur), btr_cur->index, offsets_,
ULINT_UNDEFINED, &heap),
UT_LIST_GET_FIRST(node->columns));
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
row_upd_eval_new_vals(node->update);
ut_ad(!rec_get_deleted_flag(btr_pcur_get_rec(pcur),
dict_table_is_comp(btr_cur->index->table)));
ut_ad(node->cmpl_info & UPD_NODE_NO_SIZE_CHANGE);
ut_ad(node->cmpl_info & UPD_NODE_NO_ORD_CHANGE);
ut_ad(node->select_will_do_update);
err = btr_cur_update_in_place(BTR_NO_LOCKING_FLAG, btr_cur,
node->update, node->cmpl_info,
thr, mtr);
ut_ad(err == DB_SUCCESS);
}
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