database/mariadb
1
0
Fork 0
mirror of https://github.com/MariaDB/server.git synced 2025-08-29 00:08:14 +03:00
Code Activity
Files
a216c35b51b47aa1be2b4756685bc715a4bbec55
mariadb/storage/innodb_plugin/row/row0row.c
Marko Mäkelä f77329ace9 Bug#13721257 RACE CONDITION IN UPDATES OR INSERTS OF WIDE RECORDS 
This bug was originally filed and fixed as Bug#12612184. The original
fix was buggy, and it was patched by Bug#12704861. Also that patch was
buggy (potentially breaking crash recovery), and both fixes were
reverted.

This fix was not ported to the built-in InnoDB of MySQL 5.1, because
the function signatures of many core functions are different from
InnoDB Plugin and later versions. The block allocation routines and
their callers would have to changed so that they handle block
descriptors instead of page frames.

When a record is updated so that its size grows, non-updated columns
can be selected for external (off-page) storage. The bug is that the
initially inserted updated record contains an all-zero BLOB pointer to
the field that was not updated. Only after the BLOB pages have been
allocated and written, the valid pointer can be written to the record.

Between the release of the page latch in mtr_commit(mtr) after
btr_cur_pessimistic_update() and the re-latching of the page in
btr_pcur_restore_position(), other threads can see the invalid BLOB
pointer consisting of 20 zero bytes. Moreover, if the system crashes
at this point, the situation could persist after crash recovery, and
the contents of the non-updated column would be permanently lost.

The problem is amplified by the ROW_FORMAT=DYNAMIC and
ROW_FORMAT=COMPRESSED that were introduced in
innodb_file_format=barracuda in InnoDB Plugin, but the bug does exist
in all InnoDB versions.

The fix is as follows. After a pessimistic B-tree operation that needs
to write out off-page columns, allocate the pages for these columns in
the mini-transaction that performed the B-tree operation (btr_mtr),
but write the pages in a separate mini-transaction (blob_mtr). Do
mtr_commit(blob_mtr) before mtr_commit(btr_mtr). A quirk: Do not reuse
pages that were previously freed in btr_mtr. Only write the off-page
columns to 'fresh' pages.

In this way, crash recovery will see redo log entries for blob_mtr
before any redo log entry for btr_mtr. It will apply the BLOB page
writes to pages that were marked free at that point. If crash recovery
fails to see all of the btr_mtr redo log, there will be some
unreachable BLOB data in free pages, but the B-tree will be in a
consistent state.

btr_page_alloc_low(): Renamed from btr_page_alloc(). Add the parameter
init_mtr. Return an allocated block, or NULL. If init_mtr!=mtr but
the page was already X-latched in mtr, do not initialize the page.

btr_page_alloc(): Wrapper for btr_page_alloc_for_ibuf() and
btr_page_alloc_low().

btr_page_free(): Add a debug assertion that the page was a B-tree page.

btr_lift_page_up(): Return the father block.

btr_compress(), btr_cur_compress_if_useful(): Add the parameter ibool
adjust, for adjusting the cursor position.

btr_cur_pessimistic_update(): Preserve the cursor position when
big_rec will be written and the new flag BTR_KEEP_POS_FLAG is defined.
Remove a duplicate rec_get_offsets() call. Keep the X-latch on
index->lock when big_rec is needed.

btr_store_big_rec_extern_fields(): Replace update_inplace with
an operation code, and local_mtr with btr_mtr. When not doing a
fresh insert and btr_mtr has freed pages, put aside any pages that
were previously X-latched in btr_mtr, and free the pages after
writing out all data. The data must be written to 'fresh' pages,
because btr_mtr will be committed and written to the redo log after
the BLOB writes have been written to the redo log.

btr_blob_op_is_update(): Check if an operation passed to
btr_store_big_rec_extern_fields() is an update or insert-by-update.

fseg_alloc_free_page_low(), fsp_alloc_free_page(),
fseg_alloc_free_extent(), fseg_alloc_free_page_general(): Add the
parameter init_mtr. Return an allocated block, or NULL. If
init_mtr!=mtr but the page was already X-latched in mtr, do not
initialize the page.

xdes_get_descriptor_with_space_hdr(): Assert that the file space
header is being X-latched.

fsp_alloc_from_free_frag(): Refactored from fsp_alloc_free_page().

fsp_page_create(): New function, for allocating, X-latching and
potentially initializing a page. If init_mtr!=mtr but the page was
already X-latched in mtr, do not initialize the page.

fsp_free_page(): Add ut_ad(0) to the error outcomes.

fsp_free_page(), fseg_free_page_low(): Increment mtr->n_freed_pages.

fsp_alloc_seg_inode_page(), fseg_create_general(): Assert that the
page was not previously X-latched in the mini-transaction. A file
segment or inode page should never be allocated in the middle of an
mini-transaction that frees pages, such as btr_cur_pessimistic_delete().

fseg_alloc_free_page_low(): If the hinted page was allocated, skip the
check if the tablespace should be extended. Return NULL instead of
FIL_NULL on failure. Remove the flag frag_page_allocated. Instead,
return directly, because the page would already have been initialized.

fseg_find_free_frag_page_slot() would return ULINT_UNDEFINED on error,
not FIL_NULL. Correct a bogus assertion.

fseg_alloc_free_page(): Redefine as a wrapper macro around
fseg_alloc_free_page_general().

buf_block_buf_fix_inc(): Move the definition from the buf0buf.ic to
buf0buf.h, so that it can be called from other modules.

mtr_t: Add n_freed_pages (number of pages that have been freed).

page_rec_get_nth_const(), page_rec_get_nth(): The inverse function of
page_rec_get_n_recs_before(), get the nth record of the record
list. This is faster than iterating the linked list. Refactored from
page_get_middle_rec().

trx_undo_rec_copy(): Add a debug assertion for the length.

trx_undo_add_page(): Return a block descriptor or NULL instead of a
page number or FIL_NULL.

trx_undo_report_row_operation(): Add debug assertions.

trx_sys_create_doublewrite_buf(): Assert that each page was not
previously X-latched.

page_cur_insert_rec_zip_reorg(): Make use of page_rec_get_nth().

row_ins_clust_index_entry_by_modify(): Pass BTR_KEEP_POS_FLAG, so that
the repositioning of the cursor can be avoided.

row_ins_index_entry_low(): Add DEBUG_SYNC points before and after
writing off-page columns. If inserting by updating a delete-marked
record, do not reposition the cursor or commit the mini-transaction
before writing the off-page columns.

row_build(): Tighten a debug assertion about null BLOB pointers.

row_upd_clust_rec(): Add DEBUG_SYNC points before and after writing
off-page columns. Do not reposition the cursor or commit the
mini-transaction before writing the off-page columns.

rb:939 approved by Jimmy Yang
2012-02-17 11:42:04 +02:00

1212 lines
33 KiB
C
Raw Blame History

/*****************************************************************************
Copyright (c) 1996, 2012, Oracle and/or its affiliates. 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.,
51 Franklin Street, Suite 500, Boston, MA 02110-1335 USA
*****************************************************************************/
/**************************************************//**
@file row/row0row.c
General row routines
Created 4/20/1996 Heikki Tuuri
*******************************************************/
#include "row0row.h"
#ifdef UNIV_NONINL
#include "row0row.ic"
#endif
#include "data0type.h"
#include "dict0dict.h"
#include "btr0btr.h"
#include "ha_prototypes.h"
#include "mach0data.h"
#include "trx0rseg.h"
#include "trx0trx.h"
#include "trx0roll.h"
#include "trx0undo.h"
#include "trx0purge.h"
#include "trx0rec.h"
#include "que0que.h"
#include "row0ext.h"
#include "row0upd.h"
#include "rem0cmp.h"
#include "read0read.h"
#include "ut0mem.h"
/*****************************************************************//**
When an insert or purge to a table is performed, this function builds
the entry to be inserted into or purged from an index on the table.
@return index entry which should be inserted or purged, or NULL if the
externally stored columns in the clustered index record are
unavailable and ext != NULL */
UNIV_INTERN
dtuple_t*
row_build_index_entry(
/*==================*/
const dtuple_t* row, /*!< in: row which should be
inserted or purged */
row_ext_t* ext, /*!< in: externally stored column prefixes,
or NULL */
dict_index_t* index, /*!< in: index on the table */
mem_heap_t* heap) /*!< in: memory heap from which the memory for
the index entry is allocated */
{
dtuple_t* entry;
ulint entry_len;
ulint i;
ut_ad(row && index && heap);
ut_ad(dtuple_check_typed(row));
entry_len = dict_index_get_n_fields(index);
entry = dtuple_create(heap, entry_len);
if (UNIV_UNLIKELY(index->type & DICT_UNIVERSAL)) {
dtuple_set_n_fields_cmp(entry, entry_len);
/* There may only be externally stored columns
in a clustered index B-tree of a user table. */
ut_a(!ext);
} else {
dtuple_set_n_fields_cmp(
entry, dict_index_get_n_unique_in_tree(index));
}
for (i = 0; i < entry_len; i++) {
const dict_field_t* ind_field
= dict_index_get_nth_field(index, i);
const dict_col_t* col
= ind_field->col;
ulint col_no
= dict_col_get_no(col);
dfield_t* dfield
= dtuple_get_nth_field(entry, i);
const dfield_t* dfield2
= dtuple_get_nth_field(row, col_no);
ulint len
= dfield_get_len(dfield2);
dfield_copy(dfield, dfield2);
if (dfield_is_null(dfield)) {
continue;
}
if (ind_field->prefix_len == 0
&& (!dfield_is_ext(dfield)
|| dict_index_is_clust(index))) {
/* The dfield_copy() above suffices for
columns that are stored in-page, or for
clustered index record columns that are not
part of a column prefix in the PRIMARY KEY. */
continue;
}
/* If the column is stored externally (off-page) in
the clustered index, it must be an ordering field in
the secondary index. In the Antelope format, only
prefix-indexed columns may be stored off-page in the
clustered index record. In the Barracuda format, also
fully indexed long CHAR or VARCHAR columns may be
stored off-page. */
ut_ad(col->ord_part);
if (UNIV_LIKELY_NULL(ext)) {
/* See if the column is stored externally. */
const byte* buf = row_ext_lookup(ext, col_no,
&len);
if (UNIV_LIKELY_NULL(buf)) {
if (UNIV_UNLIKELY(buf == field_ref_zero)) {
return(NULL);
}
dfield_set_data(dfield, buf, len);
}
if (ind_field->prefix_len == 0) {
/* In the Barracuda format
(ROW_FORMAT=DYNAMIC or
ROW_FORMAT=COMPRESSED), we can have a
secondary index on an entire column
that is stored off-page in the
clustered index. As this is not a
prefix index (prefix_len == 0),
include the entire off-page column in
the secondary index record. */
continue;
}
} else if (dfield_is_ext(dfield)) {
/* This table is either in Antelope format
(ROW_FORMAT=REDUNDANT or ROW_FORMAT=COMPACT)
or a purge record where the ordered part of
the field is not external.
In Antelope, the maximum column prefix
index length is 767 bytes, and the clustered
index record contains a 768-byte prefix of
each off-page column. */
ut_a(len >= BTR_EXTERN_FIELD_REF_SIZE);
len -= BTR_EXTERN_FIELD_REF_SIZE;
dfield_set_len(dfield, len);
}
/* If a column prefix index, take only the prefix. */
if (ind_field->prefix_len) {
len = dtype_get_at_most_n_mbchars(
col->prtype, col->mbminlen, col->mbmaxlen,
ind_field->prefix_len, len,
dfield_get_data(dfield));
dfield_set_len(dfield, len);
}
}
ut_ad(dtuple_check_typed(entry));
return(entry);
}
/*******************************************************************//**
An inverse function to row_build_index_entry. Builds a row from a
record in a clustered index.
@return own: row built; see the NOTE below! */
UNIV_INTERN
dtuple_t*
row_build(
/*======*/
ulint type, /*!< in: ROW_COPY_POINTERS or
ROW_COPY_DATA; the latter
copies also the data fields to
heap while the first only
places pointers to data fields
on the index page, and thus is
more efficient */
const dict_index_t* index, /*!< in: clustered index */
const rec_t* rec, /*!< in: record in the clustered
index; NOTE: in the case
ROW_COPY_POINTERS the data
fields in the row will point
directly into this record,
therefore, the buffer page of
this record must be at least
s-latched and the latch held
as long as the row dtuple is used! */
const ulint* offsets,/*!< in: rec_get_offsets(rec,index)
or NULL, in which case this function
will invoke rec_get_offsets() */
const dict_table_t* col_table,
/*!< in: table, to check which
externally stored columns
occur in the ordering columns
of an index, or NULL if
index->table should be
consulted instead */
row_ext_t** ext, /*!< out, own: cache of
externally stored column
prefixes, or NULL */
mem_heap_t* heap) /*!< in: memory heap from which
the memory needed is allocated */
{
dtuple_t* row;
const dict_table_t* table;
ulint n_fields;
ulint n_ext_cols;
ulint* ext_cols = NULL; /* remove warning */
ulint len;
ulint row_len;
byte* buf;
ulint i;
ulint j;
mem_heap_t* tmp_heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
rec_offs_init(offsets_);
ut_ad(index && rec && heap);
ut_ad(dict_index_is_clust(index));
ut_ad(!mutex_own(&kernel_mutex));
if (!offsets) {
offsets = rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &tmp_heap);
} else {
ut_ad(rec_offs_validate(rec, index, offsets));
}
#if defined UNIV_DEBUG || defined UNIV_BLOB_LIGHT_DEBUG
if (rec_offs_any_null_extern(rec, offsets)) {
/* This condition can occur during crash recovery
before trx_rollback_active() has completed execution.
This condition is possible if the server crashed
during an insert or update-by-delete-and-insert before
btr_store_big_rec_extern_fields() did mtr_commit() all
BLOB pointers to the freshly inserted clustered index
record. */
ut_a(trx_assert_recovered(
row_get_rec_trx_id(rec, index, offsets)));
ut_a(trx_undo_roll_ptr_is_insert(
row_get_rec_roll_ptr(rec, index, offsets)));
}
#endif /* UNIV_DEBUG || UNIV_BLOB_LIGHT_DEBUG */
if (type != ROW_COPY_POINTERS) {
/* Take a copy of rec to heap */
buf = mem_heap_alloc(heap, rec_offs_size(offsets));
rec = rec_copy(buf, rec, offsets);
/* Avoid a debug assertion in rec_offs_validate(). */
rec_offs_make_valid(rec, index, (ulint*) offsets);
}
table = index->table;
row_len = dict_table_get_n_cols(table);
row = dtuple_create(heap, row_len);
dict_table_copy_types(row, table);
dtuple_set_info_bits(row, rec_get_info_bits(
rec, dict_table_is_comp(table)));
n_fields = rec_offs_n_fields(offsets);
n_ext_cols = rec_offs_n_extern(offsets);
if (n_ext_cols) {
ext_cols = mem_heap_alloc(heap, n_ext_cols * sizeof *ext_cols);
}
for (i = j = 0; i < n_fields; i++) {
dict_field_t* ind_field
= dict_index_get_nth_field(index, i);
const dict_col_t* col
= dict_field_get_col(ind_field);
ulint col_no
= dict_col_get_no(col);
dfield_t* dfield
= dtuple_get_nth_field(row, col_no);
if (ind_field->prefix_len == 0) {
const byte* field = rec_get_nth_field(
rec, offsets, i, &len);
dfield_set_data(dfield, field, len);
}
if (rec_offs_nth_extern(offsets, i)) {
dfield_set_ext(dfield);
if (UNIV_LIKELY_NULL(col_table)) {
ut_a(col_no
< dict_table_get_n_cols(col_table));
col = dict_table_get_nth_col(
col_table, col_no);
}
if (col->ord_part) {
/* We will have to fetch prefixes of
externally stored columns that are
referenced by column prefixes. */
ext_cols[j++] = col_no;
}
}
}
ut_ad(dtuple_check_typed(row));
if (!ext) {
/* REDUNDANT and COMPACT formats store a local
768-byte prefix of each externally stored
column. No cache is needed. */
ut_ad(dict_table_get_format(index->table)
< DICT_TF_FORMAT_ZIP);
} else if (j) {
*ext = row_ext_create(j, ext_cols, row,
dict_table_zip_size(index->table),
heap);
} else {
*ext = NULL;
}
if (tmp_heap) {
mem_heap_free(tmp_heap);
}
return(row);
}
/*******************************************************************//**
Converts an index record to a typed data tuple.
@return index entry built; does not set info_bits, and the data fields
in the entry will point directly to rec */
UNIV_INTERN
dtuple_t*
row_rec_to_index_entry_low(
/*=======================*/
const rec_t* rec, /*!< in: record in the index */
const dict_index_t* index, /*!< in: index */
const ulint* offsets,/*!< in: rec_get_offsets(rec, index) */
ulint* n_ext, /*!< out: number of externally
stored columns */
mem_heap_t* heap) /*!< in: memory heap from which
the memory needed is allocated */
{
dtuple_t* entry;
dfield_t* dfield;
ulint i;
const byte* field;
ulint len;
ulint rec_len;
ut_ad(rec && heap && index);
/* Because this function may be invoked by row0merge.c
on a record whose header is in different format, the check
rec_offs_validate(rec, index, offsets) must be avoided here. */
ut_ad(n_ext);
*n_ext = 0;
rec_len = rec_offs_n_fields(offsets);
entry = dtuple_create(heap, rec_len);
dtuple_set_n_fields_cmp(entry,
dict_index_get_n_unique_in_tree(index));
ut_ad(rec_len == dict_index_get_n_fields(index));
dict_index_copy_types(entry, index, rec_len);
for (i = 0; i < rec_len; i++) {
dfield = dtuple_get_nth_field(entry, i);
field = rec_get_nth_field(rec, offsets, i, &len);
dfield_set_data(dfield, field, len);
if (rec_offs_nth_extern(offsets, i)) {
dfield_set_ext(dfield);
(*n_ext)++;
}
}
ut_ad(dtuple_check_typed(entry));
return(entry);
}
/*******************************************************************//**
Converts an index record to a typed data tuple. NOTE that externally
stored (often big) fields are NOT copied to heap.
@return own: index entry built; see the NOTE below! */
UNIV_INTERN
dtuple_t*
row_rec_to_index_entry(
/*===================*/
ulint type, /*!< in: ROW_COPY_DATA, or
ROW_COPY_POINTERS: the former
copies also the data fields to
heap as the latter only places
pointers to data fields on the
index page */
const rec_t* rec, /*!< in: record in the index;
NOTE: in the case
ROW_COPY_POINTERS the data
fields in the row will point
directly into this record,
therefore, the buffer page of
this record must be at least
s-latched and the latch held
as long as the dtuple is used! */
const dict_index_t* index, /*!< in: index */
ulint* offsets,/*!< in/out: rec_get_offsets(rec) */
ulint* n_ext, /*!< out: number of externally
stored columns */
mem_heap_t* heap) /*!< in: memory heap from which
the memory needed is allocated */
{
dtuple_t* entry;
byte* buf;
ut_ad(rec && heap && index);
ut_ad(rec_offs_validate(rec, index, offsets));
if (type == ROW_COPY_DATA) {
/* Take a copy of rec to heap */
buf = mem_heap_alloc(heap, rec_offs_size(offsets));
rec = rec_copy(buf, rec, offsets);
/* Avoid a debug assertion in rec_offs_validate(). */
rec_offs_make_valid(rec, index, offsets);
#if defined UNIV_DEBUG || defined UNIV_BLOB_LIGHT_DEBUG
} else {
ut_a(!rec_offs_any_null_extern(rec, offsets));
#endif /* UNIV_DEBUG || UNIV_BLOB_LIGHT_DEBUG */
}
entry = row_rec_to_index_entry_low(rec, index, offsets, n_ext, heap);
dtuple_set_info_bits(entry,
rec_get_info_bits(rec, rec_offs_comp(offsets)));
return(entry);
}
/*******************************************************************//**
Builds from a secondary index record a row reference with which we can
search the clustered index record.
@return own: row reference built; see the NOTE below! */
UNIV_INTERN
dtuple_t*
row_build_row_ref(
/*==============*/
ulint type, /*!< in: ROW_COPY_DATA, or ROW_COPY_POINTERS:
the former copies also the data fields to
heap, whereas the latter only places pointers
to data fields on the index page */
dict_index_t* index, /*!< in: secondary index */
const rec_t* rec, /*!< in: record in the index;
NOTE: in the case ROW_COPY_POINTERS
the data fields in the row will point
directly into this record, therefore,
the buffer page of this record must be
at least s-latched and the latch held
as long as the row reference is used! */
mem_heap_t* heap) /*!< in: memory heap from which the memory
needed is allocated */
{
dict_table_t* table;
dict_index_t* clust_index;
dfield_t* dfield;
dtuple_t* ref;
const byte* field;
ulint len;
ulint ref_len;
ulint pos;
byte* buf;
ulint clust_col_prefix_len;
ulint i;
mem_heap_t* tmp_heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
ulint* offsets = offsets_;
rec_offs_init(offsets_);
ut_ad(index && rec && heap);
ut_ad(!dict_index_is_clust(index));
offsets = rec_get_offsets(rec, index, offsets,
ULINT_UNDEFINED, &tmp_heap);
/* Secondary indexes must not contain externally stored columns. */
ut_ad(!rec_offs_any_extern(offsets));
if (type == ROW_COPY_DATA) {
/* Take a copy of rec to heap */
buf = mem_heap_alloc(heap, rec_offs_size(offsets));
rec = rec_copy(buf, rec, offsets);
/* Avoid a debug assertion in rec_offs_validate(). */
rec_offs_make_valid(rec, index, offsets);
}
table = index->table;
clust_index = dict_table_get_first_index(table);
ref_len = dict_index_get_n_unique(clust_index);
ref = dtuple_create(heap, ref_len);
dict_index_copy_types(ref, clust_index, ref_len);
for (i = 0; i < ref_len; i++) {
dfield = dtuple_get_nth_field(ref, i);
pos = dict_index_get_nth_field_pos(index, clust_index, i);
ut_a(pos != ULINT_UNDEFINED);
field = rec_get_nth_field(rec, offsets, pos, &len);
dfield_set_data(dfield, field, len);
/* If the primary key contains a column prefix, then the
secondary index may contain a longer prefix of the same
column, or the full column, and we must adjust the length
accordingly. */
clust_col_prefix_len = dict_index_get_nth_field(
clust_index, i)->prefix_len;
if (clust_col_prefix_len > 0) {
if (len != UNIV_SQL_NULL) {
const dtype_t* dtype
= dfield_get_type(dfield);
dfield_set_len(dfield,
dtype_get_at_most_n_mbchars(
dtype->prtype,
dtype->mbminlen,
dtype->mbmaxlen,
clust_col_prefix_len,
len, (char*) field));
}
}
}
ut_ad(dtuple_check_typed(ref));
if (tmp_heap) {
mem_heap_free(tmp_heap);
}
return(ref);
}
/*******************************************************************//**
Builds from a secondary index record a row reference with which we can
search the clustered index record. */
UNIV_INTERN
void
row_build_row_ref_in_tuple(
/*=======================*/
dtuple_t* ref, /*!< in/out: row reference built;
see the NOTE below! */
const rec_t* rec, /*!< in: record in the index;
NOTE: the data fields in ref
will point directly into this
record, therefore, the buffer
page of this record must be at
least s-latched and the latch
held as long as the row
reference is used! */
const dict_index_t* index, /*!< in: secondary index */
ulint* offsets,/*!< in: rec_get_offsets(rec, index)
or NULL */
trx_t* trx) /*!< in: transaction */
{
const dict_index_t* clust_index;
dfield_t* dfield;
const byte* field;
ulint len;
ulint ref_len;
ulint pos;
ulint clust_col_prefix_len;
ulint i;
mem_heap_t* heap = NULL;
ulint offsets_[REC_OFFS_NORMAL_SIZE];
rec_offs_init(offsets_);
ut_a(ref);
ut_a(index);
ut_a(rec);
ut_ad(!dict_index_is_clust(index));
if (UNIV_UNLIKELY(!index->table)) {
fputs("InnoDB: table ", stderr);
notfound:
ut_print_name(stderr, trx, TRUE, index->table_name);
fputs(" for index ", stderr);
ut_print_name(stderr, trx, FALSE, index->name);
fputs(" not found\n", stderr);
ut_error;
}
clust_index = dict_table_get_first_index(index->table);
if (UNIV_UNLIKELY(!clust_index)) {
fputs("InnoDB: clust index for table ", stderr);
goto notfound;
}
if (!offsets) {
offsets = rec_get_offsets(rec, index, offsets_,
ULINT_UNDEFINED, &heap);
} else {
ut_ad(rec_offs_validate(rec, index, offsets));
}
/* Secondary indexes must not contain externally stored columns. */
ut_ad(!rec_offs_any_extern(offsets));
ref_len = dict_index_get_n_unique(clust_index);
ut_ad(ref_len == dtuple_get_n_fields(ref));
dict_index_copy_types(ref, clust_index, ref_len);
for (i = 0; i < ref_len; i++) {
dfield = dtuple_get_nth_field(ref, i);
pos = dict_index_get_nth_field_pos(index, clust_index, i);
ut_a(pos != ULINT_UNDEFINED);
field = rec_get_nth_field(rec, offsets, pos, &len);
dfield_set_data(dfield, field, len);
/* If the primary key contains a column prefix, then the
secondary index may contain a longer prefix of the same
column, or the full column, and we must adjust the length
accordingly. */
clust_col_prefix_len = dict_index_get_nth_field(
clust_index, i)->prefix_len;
if (clust_col_prefix_len > 0) {
if (len != UNIV_SQL_NULL) {
const dtype_t* dtype
= dfield_get_type(dfield);
dfield_set_len(dfield,
dtype_get_at_most_n_mbchars(
dtype->prtype,
dtype->mbminlen,
dtype->mbmaxlen,
clust_col_prefix_len,
len, (char*) field));
}
}
}
ut_ad(dtuple_check_typed(ref));
if (UNIV_LIKELY_NULL(heap)) {
mem_heap_free(heap);
}
}
/***************************************************************//**
Searches the clustered index record for a row, if we have the row reference.
@return TRUE if found */
UNIV_INTERN
ibool
row_search_on_row_ref(
/*==================*/
btr_pcur_t* pcur, /*!< out: persistent cursor, which must
be closed by the caller */
ulint mode, /*!< in: BTR_MODIFY_LEAF, ... */
const dict_table_t* table, /*!< in: table */
const dtuple_t* ref, /*!< in: row reference */
mtr_t* mtr) /*!< in/out: mtr */
{
ulint low_match;
rec_t* rec;
dict_index_t* index;
ut_ad(dtuple_check_typed(ref));
index = dict_table_get_first_index(table);
ut_a(dtuple_get_n_fields(ref) == dict_index_get_n_unique(index));
btr_pcur_open(index, ref, PAGE_CUR_LE, mode, pcur, mtr);
low_match = btr_pcur_get_low_match(pcur);
rec = btr_pcur_get_rec(pcur);
if (page_rec_is_infimum(rec)) {
return(FALSE);
}
if (low_match != dtuple_get_n_fields(ref)) {
return(FALSE);
}
return(TRUE);
}
/*********************************************************************//**
Fetches the clustered index record for a secondary index record. The latches
on the secondary index record are preserved.
@return record or NULL, if no record found */
UNIV_INTERN
rec_t*
row_get_clust_rec(
/*==============*/
ulint mode, /*!< in: BTR_MODIFY_LEAF, ... */
const rec_t* rec, /*!< in: record in a secondary index */
dict_index_t* index, /*!< in: secondary index */
dict_index_t** clust_index,/*!< out: clustered index */
mtr_t* mtr) /*!< in: mtr */
{
mem_heap_t* heap;
dtuple_t* ref;
dict_table_t* table;
btr_pcur_t pcur;
ibool found;
rec_t* clust_rec;
ut_ad(!dict_index_is_clust(index));
table = index->table;
heap = mem_heap_create(256);
ref = row_build_row_ref(ROW_COPY_POINTERS, index, rec, heap);
found = row_search_on_row_ref(&pcur, mode, table, ref, mtr);
clust_rec = found ? btr_pcur_get_rec(&pcur) : NULL;
mem_heap_free(heap);
btr_pcur_close(&pcur);
*clust_index = dict_table_get_first_index(table);
return(clust_rec);
}
/***************************************************************//**
Searches an index record.
@return TRUE if found */
UNIV_INTERN
ibool
row_search_index_entry(
/*===================*/
dict_index_t* index, /*!< in: index */
const dtuple_t* entry, /*!< in: index entry */
ulint mode, /*!< in: BTR_MODIFY_LEAF, ... */
btr_pcur_t* pcur, /*!< in/out: persistent cursor, which must
be closed by the caller */
mtr_t* mtr) /*!< in: mtr */
{
ulint n_fields;
ulint low_match;
rec_t* rec;
ut_ad(dtuple_check_typed(entry));
btr_pcur_open(index, entry, PAGE_CUR_LE, mode, pcur, mtr);
low_match = btr_pcur_get_low_match(pcur);
rec = btr_pcur_get_rec(pcur);
n_fields = dtuple_get_n_fields(entry);
return(!page_rec_is_infimum(rec) && low_match == n_fields);
}
#include <my_sys.h>
/*******************************************************************//**
Formats the raw data in "data" (in InnoDB on-disk format) that is of
type DATA_INT using "prtype" and writes the result to "buf".
If the data is in unknown format, then nothing is written to "buf",
0 is returned and "format_in_hex" is set to TRUE, otherwise
"format_in_hex" is left untouched.
Not more than "buf_size" bytes are written to "buf".
The result is always '\0'-terminated (provided buf_size > 0) and the
number of bytes that were written to "buf" is returned (including the
terminating '\0').
@return number of bytes that were written */
static
ulint
row_raw_format_int(
/*===============*/
const char* data, /*!< in: raw data */
ulint data_len, /*!< in: raw data length
in bytes */
ulint prtype, /*!< in: precise type */
char* buf, /*!< out: output buffer */
ulint buf_size, /*!< in: output buffer size
in bytes */
ibool* format_in_hex) /*!< out: should the data be
formated in hex */
{
ulint ret;
if (data_len <= sizeof(ullint)) {
ullint value;
ibool unsigned_type = prtype & DATA_UNSIGNED;
value = mach_read_int_type((const byte*) data,
data_len, unsigned_type);
if (unsigned_type) {
ret = ut_snprintf(buf, buf_size, "%llu",
value) + 1;
} else {
ret = ut_snprintf(buf, buf_size, "%lld",
(long long) value) + 1;
}
} else {
*format_in_hex = TRUE;
ret = 0;
}
return(ut_min(ret, buf_size));
}
/*******************************************************************//**
Formats the raw data in "data" (in InnoDB on-disk format) that is of
type DATA_(CHAR|VARCHAR|MYSQL|VARMYSQL) using "prtype" and writes the
result to "buf".
If the data is in binary format, then nothing is written to "buf",
0 is returned and "format_in_hex" is set to TRUE, otherwise
"format_in_hex" is left untouched.
Not more than "buf_size" bytes are written to "buf".
The result is always '\0'-terminated (provided buf_size > 0) and the
number of bytes that were written to "buf" is returned (including the
terminating '\0').
@return number of bytes that were written */
static
ulint
row_raw_format_str(
/*===============*/
const char* data, /*!< in: raw data */
ulint data_len, /*!< in: raw data length
in bytes */
ulint prtype, /*!< in: precise type */
char* buf, /*!< out: output buffer */
ulint buf_size, /*!< in: output buffer size
in bytes */
ibool* format_in_hex) /*!< out: should the data be
formated in hex */
{
ulint charset_coll;
if (buf_size == 0) {
return(0);
}
/* we assume system_charset_info is UTF-8 */
charset_coll = dtype_get_charset_coll(prtype);
if (UNIV_LIKELY(dtype_is_utf8(prtype))) {
return(ut_str_sql_format(data, data_len, buf, buf_size));
}
/* else */
if (charset_coll == DATA_MYSQL_BINARY_CHARSET_COLL) {
*format_in_hex = TRUE;
return(0);
}
/* else */
return(innobase_raw_format(data, data_len, charset_coll,
buf, buf_size));
}
/*******************************************************************//**
Formats the raw data in "data" (in InnoDB on-disk format) using
"dict_field" and writes the result to "buf".
Not more than "buf_size" bytes are written to "buf".
The result is always NUL-terminated (provided buf_size is positive) and the
number of bytes that were written to "buf" is returned (including the
terminating NUL).
@return number of bytes that were written */
UNIV_INTERN
ulint
row_raw_format(
/*===========*/
const char* data, /*!< in: raw data */
ulint data_len, /*!< in: raw data length
in bytes */
const dict_field_t* dict_field, /*!< in: index field */
char* buf, /*!< out: output buffer */
ulint buf_size) /*!< in: output buffer size
in bytes */
{
ulint mtype;
ulint prtype;
ulint ret;
ibool format_in_hex;
if (buf_size == 0) {
return(0);
}
if (data_len == UNIV_SQL_NULL) {
ret = ut_snprintf((char*) buf, buf_size, "NULL") + 1;
return(ut_min(ret, buf_size));
}
mtype = dict_field->col->mtype;
prtype = dict_field->col->prtype;
format_in_hex = FALSE;
switch (mtype) {
case DATA_INT:
ret = row_raw_format_int(data, data_len, prtype,
buf, buf_size, &format_in_hex);
if (format_in_hex) {
goto format_in_hex;
}
break;
case DATA_CHAR:
case DATA_VARCHAR:
case DATA_MYSQL:
case DATA_VARMYSQL:
ret = row_raw_format_str(data, data_len, prtype,
buf, buf_size, &format_in_hex);
if (format_in_hex) {
goto format_in_hex;
}
break;
/* XXX support more data types */
default:
format_in_hex:
if (UNIV_LIKELY(buf_size > 2)) {
memcpy(buf, "0x", 2);
buf += 2;
buf_size -= 2;
ret = 2 + ut_raw_to_hex(data, data_len,
buf, buf_size);
} else {
buf[0] = '\0';
ret = 1;
}
}
return(ret);
}
#ifdef UNIV_COMPILE_TEST_FUNCS
#include "ut0dbg.h"
void
test_row_raw_format_int()
{
ulint ret;
char buf[128];
ibool format_in_hex;
#define CALL_AND_TEST(data, data_len, prtype, buf, buf_size,\
ret_expected, buf_expected, format_in_hex_expected)\
do {\
ibool ok = TRUE;\
ulint i;\
memset(buf, 'x', 10);\
buf[10] = '\0';\
format_in_hex = FALSE;\
fprintf(stderr, "TESTING \"\\x");\
for (i = 0; i < data_len; i++) {\
fprintf(stderr, "%02hhX", data[i]);\
}\
fprintf(stderr, "\", %lu, %lu, %lu\n",\
(ulint) data_len, (ulint) prtype,\
(ulint) buf_size);\
ret = row_raw_format_int(data, data_len, prtype,\
buf, buf_size, &format_in_hex);\
if (ret != ret_expected) {\
fprintf(stderr, "expected ret %lu, got %lu\n",\
(ulint) ret_expected, ret);\
ok = FALSE;\
}\
if (strcmp((char*) buf, buf_expected) != 0) {\
fprintf(stderr, "expected buf \"%s\", got \"%s\"\n",\
buf_expected, buf);\
ok = FALSE;\
}\
if (format_in_hex != format_in_hex_expected) {\
fprintf(stderr, "expected format_in_hex %d, got %d\n",\
(int) format_in_hex_expected,\
(int) format_in_hex);\
ok = FALSE;\
}\
if (ok) {\
fprintf(stderr, "OK: %lu, \"%s\" %d\n\n",\
(ulint) ret, buf, (int) format_in_hex);\
} else {\
return;\
}\
} while (0)
#if 1
/* min values for signed 1-8 byte integers */
CALL_AND_TEST("\x00", 1, 0,
buf, sizeof(buf), 5, "-128", 0);
CALL_AND_TEST("\x00\x00", 2, 0,
buf, sizeof(buf), 7, "-32768", 0);
CALL_AND_TEST("\x00\x00\x00", 3, 0,
buf, sizeof(buf), 9, "-8388608", 0);
CALL_AND_TEST("\x00\x00\x00\x00", 4, 0,
buf, sizeof(buf), 12, "-2147483648", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00", 5, 0,
buf, sizeof(buf), 14, "-549755813888", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x00", 6, 0,
buf, sizeof(buf), 17, "-140737488355328", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x00\x00", 7, 0,
buf, sizeof(buf), 19, "-36028797018963968", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x00\x00\x00", 8, 0,
buf, sizeof(buf), 21, "-9223372036854775808", 0);
/* min values for unsigned 1-8 byte integers */
CALL_AND_TEST("\x00", 1, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00", 2, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00\x00", 3, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00\x00\x00", 4, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00", 5, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x00", 6, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x00\x00", 7, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x00\x00\x00", 8, DATA_UNSIGNED,
buf, sizeof(buf), 2, "0", 0);
/* max values for signed 1-8 byte integers */
CALL_AND_TEST("\xFF", 1, 0,
buf, sizeof(buf), 4, "127", 0);
CALL_AND_TEST("\xFF\xFF", 2, 0,
buf, sizeof(buf), 6, "32767", 0);
CALL_AND_TEST("\xFF\xFF\xFF", 3, 0,
buf, sizeof(buf), 8, "8388607", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF", 4, 0,
buf, sizeof(buf), 11, "2147483647", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF", 5, 0,
buf, sizeof(buf), 13, "549755813887", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF\xFF", 6, 0,
buf, sizeof(buf), 16, "140737488355327", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF\xFF\xFF", 7, 0,
buf, sizeof(buf), 18, "36028797018963967", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF", 8, 0,
buf, sizeof(buf), 20, "9223372036854775807", 0);
/* max values for unsigned 1-8 byte integers */
CALL_AND_TEST("\xFF", 1, DATA_UNSIGNED,
buf, sizeof(buf), 4, "255", 0);
CALL_AND_TEST("\xFF\xFF", 2, DATA_UNSIGNED,
buf, sizeof(buf), 6, "65535", 0);
CALL_AND_TEST("\xFF\xFF\xFF", 3, DATA_UNSIGNED,
buf, sizeof(buf), 9, "16777215", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF", 4, DATA_UNSIGNED,
buf, sizeof(buf), 11, "4294967295", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF", 5, DATA_UNSIGNED,
buf, sizeof(buf), 14, "1099511627775", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF\xFF", 6, DATA_UNSIGNED,
buf, sizeof(buf), 16, "281474976710655", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF\xFF\xFF", 7, DATA_UNSIGNED,
buf, sizeof(buf), 18, "72057594037927935", 0);
CALL_AND_TEST("\xFF\xFF\xFF\xFF\xFF\xFF\xFF\xFF", 8, DATA_UNSIGNED,
buf, sizeof(buf), 21, "18446744073709551615", 0);
/* some random values */
CALL_AND_TEST("\x52", 1, 0,
buf, sizeof(buf), 4, "-46", 0);
CALL_AND_TEST("\x0E", 1, DATA_UNSIGNED,
buf, sizeof(buf), 3, "14", 0);
CALL_AND_TEST("\x62\xCE", 2, 0,
buf, sizeof(buf), 6, "-7474", 0);
CALL_AND_TEST("\x29\xD6", 2, DATA_UNSIGNED,
buf, sizeof(buf), 6, "10710", 0);
CALL_AND_TEST("\x7F\xFF\x90", 3, 0,
buf, sizeof(buf), 5, "-112", 0);
CALL_AND_TEST("\x00\xA1\x16", 3, DATA_UNSIGNED,
buf, sizeof(buf), 6, "41238", 0);
CALL_AND_TEST("\x7F\xFF\xFF\xF7", 4, 0,
buf, sizeof(buf), 3, "-9", 0);
CALL_AND_TEST("\x00\x00\x00\x5C", 4, DATA_UNSIGNED,
buf, sizeof(buf), 3, "92", 0);
CALL_AND_TEST("\x7F\xFF\xFF\xFF\xFF\xFF\xDC\x63", 8, 0,
buf, sizeof(buf), 6, "-9117", 0);
CALL_AND_TEST("\x00\x00\x00\x00\x00\x01\x64\x62", 8, DATA_UNSIGNED,
buf, sizeof(buf), 6, "91234", 0);
#endif
/* speed test */
speedo_t speedo;
ulint i;
speedo_reset(&speedo);
for (i = 0; i < 1000000; i++) {
row_raw_format_int("\x23", 1,
0, buf, sizeof(buf),
&format_in_hex);
row_raw_format_int("\x23", 1,
DATA_UNSIGNED, buf, sizeof(buf),
&format_in_hex);
row_raw_format_int("\x00\x00\x00\x00\x00\x01\x64\x62", 8,
0, buf, sizeof(buf),
&format_in_hex);
row_raw_format_int("\x00\x00\x00\x00\x00\x01\x64\x62", 8,
DATA_UNSIGNED, buf, sizeof(buf),
&format_in_hex);
}
speedo_show(&speedo);
}
#endif /* UNIV_COMPILE_TEST_FUNCS */
View Git Blame Copy Permalink