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mariadb/storage/innobase/include/dict0dict.ic
Jan Lindström 765a43605a MDEV-12253: Buffer pool blocks are accessed after they have been freed 
Problem was that bpage was referenced after it was already freed
from LRU. Fixed by adding a new variable encrypted that is
passed down to buf_page_check_corrupt() and used in
buf_page_get_gen() to stop processing page read.

This patch should also address following test failures and
bugs:

MDEV-12419: IMPORT should not look up tablespace in
PageConverter::validate(). This is now removed.

MDEV-10099: encryption.innodb_onlinealter_encryption fails
sporadically in buildbot

MDEV-11420: encryption.innodb_encryption-page-compression
failed in buildbot

MDEV-11222: encryption.encrypt_and_grep failed in buildbot on P8

Removed dict_table_t::is_encrypted and dict_table_t::ibd_file_missing
and replaced these with dict_table_t::file_unreadable. Table
ibd file is missing if fil_get_space(space_id) returns NULL
and encrypted if not. Removed dict_table_t::is_corrupted field.

Ported FilSpace class from 10.2 and using that on buf_page_check_corrupt(),
buf_page_decrypt_after_read(), buf_page_encrypt_before_write(),
buf_dblwr_process(), buf_read_page(), dict_stats_save_defrag_stats().

Added test cases when enrypted page could be read while doing
redo log crash recovery. Also added test case for row compressed
blobs.

btr_cur_open_at_index_side_func(),
btr_cur_open_at_rnd_pos_func(): Avoid referencing block that is
NULL.

buf_page_get_zip(): Issue error if page read fails.

buf_page_get_gen(): Use dberr_t for error detection and
do not reference bpage after we hare freed it.

buf_mark_space_corrupt(): remove bpage from LRU also when
it is encrypted.

buf_page_check_corrupt(): @return DB_SUCCESS if page has
been read and is not corrupted,
DB_PAGE_CORRUPTED if page based on checksum check is corrupted,
DB_DECRYPTION_FAILED if page post encryption checksum matches but
after decryption normal page checksum does not match. In read
case only DB_SUCCESS is possible.

buf_page_io_complete(): use dberr_t for error handling.

buf_flush_write_block_low(),
buf_read_ahead_random(),
buf_read_page_async(),
buf_read_ahead_linear(),
buf_read_ibuf_merge_pages(),
buf_read_recv_pages(),
fil_aio_wait():
        Issue error if page read fails.

btr_pcur_move_to_next_page(): Do not reference page if it is
NULL.

Introduced dict_table_t::is_readable() and dict_index_t::is_readable()
that will return true if tablespace exists and pages read from
tablespace are not corrupted or page decryption failed.
Removed buf_page_t::key_version. After page decryption the
key version is not removed from page frame. For unencrypted
pages, old key_version is removed at buf_page_encrypt_before_write()

dict_stats_update_transient_for_index(),
dict_stats_update_transient()
        Do not continue if table decryption failed or table
        is corrupted.

dict0stats.cc: Introduced a dict_stats_report_error function
to avoid code duplication.

fil_parse_write_crypt_data():
        Check that key read from redo log entry is found from
        encryption plugin and if it is not, refuse to start.

PageConverter::validate(): Removed access to fil_space_t as
tablespace is not available during import.

Fixed error code on innodb.innodb test.

Merged test cased innodb-bad-key-change5 and innodb-bad-key-shutdown
to innodb-bad-key-change2.  Removed innodb-bad-key-change5 test.
Decreased unnecessary complexity on some long lasting tests.

Removed fil_inc_pending_ops(), fil_decr_pending_ops(),
fil_get_first_space(), fil_get_next_space(),
fil_get_first_space_safe(), fil_get_next_space_safe()
functions.

fil_space_verify_crypt_checksum(): Fixed bug found using ASAN
where FIL_PAGE_END_LSN_OLD_CHECKSUM field was incorrectly
accessed from row compressed tables. Fixed out of page frame
bug for row compressed tables in
fil_space_verify_crypt_checksum() found using ASAN. Incorrect
function was called for compressed table.

Added new tests for discard, rename table and drop (we should allow them
even when page decryption fails). Alter table rename is not allowed.
Added test for restart with innodb-force-recovery=1 when page read on
redo-recovery cant be decrypted. Added test for corrupted table where
both page data and FIL_PAGE_FILE_FLUSH_LSN_OR_KEY_VERSION is corrupted.

Adjusted the test case innodb_bug14147491 so that it does not anymore
expect crash. Instead table is just mostly not usable.

fil0fil.h: fil_space_acquire_low is not visible function
and fil_space_acquire and fil_space_acquire_silent are
inline functions. FilSpace class uses fil_space_acquire_low
directly.

recv_apply_hashed_log_recs() does not return anything.
2017-04-26 15:19:16 +03:00

1621 lines
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/*****************************************************************************
Copyright (c) 1996, 2016, Oracle and/or its affiliates. All Rights Reserved.
Copyright (c) 2013, 2017, MariaDB Corporation.
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 include/dict0dict.ic
Data dictionary system
Created 1/8/1996 Heikki Tuuri
***********************************************************************/
#include "data0type.h"
#ifndef UNIV_HOTBACKUP
#include "dict0load.h"
#include "rem0types.h"
#include "fsp0fsp.h"
#include "srv0srv.h"
#include "sync0rw.h" /* RW_S_LATCH */
/*********************************************************************//**
Gets the minimum number of bytes per character.
@return minimum multi-byte char size, in bytes */
UNIV_INLINE
ulint
dict_col_get_mbminlen(
/*==================*/
const dict_col_t* col) /*!< in: column */
{
return(DATA_MBMINLEN(col->mbminmaxlen));
}
/*********************************************************************//**
Gets the maximum number of bytes per character.
@return maximum multi-byte char size, in bytes */
UNIV_INLINE
ulint
dict_col_get_mbmaxlen(
/*==================*/
const dict_col_t* col) /*!< in: column */
{
return(DATA_MBMAXLEN(col->mbminmaxlen));
}
/*********************************************************************//**
Sets the minimum and maximum number of bytes per character. */
UNIV_INLINE
void
dict_col_set_mbminmaxlen(
/*=====================*/
dict_col_t* col, /*!< in/out: column */
ulint mbminlen, /*!< in: minimum multi-byte
character size, in bytes */
ulint mbmaxlen) /*!< in: minimum multi-byte
character size, in bytes */
{
ut_ad(mbminlen < DATA_MBMAX);
ut_ad(mbmaxlen < DATA_MBMAX);
ut_ad(mbminlen <= mbmaxlen);
col->mbminmaxlen = DATA_MBMINMAXLEN(mbminlen, mbmaxlen);
}
/*********************************************************************//**
Gets the column data type. */
UNIV_INLINE
void
dict_col_copy_type(
/*===============*/
const dict_col_t* col, /*!< in: column */
dtype_t* type) /*!< out: data type */
{
ut_ad(col != NULL);
ut_ad(type != NULL);
type->mtype = col->mtype;
type->prtype = col->prtype;
type->len = col->len;
type->mbminmaxlen = col->mbminmaxlen;
}
#endif /* !UNIV_HOTBACKUP */
#ifdef UNIV_DEBUG
/*********************************************************************//**
Assert that a column and a data type match.
@return TRUE */
UNIV_INLINE
ibool
dict_col_type_assert_equal(
/*=======================*/
const dict_col_t* col, /*!< in: column */
const dtype_t* type) /*!< in: data type */
{
ut_ad(col);
ut_ad(type);
ut_ad(col->mtype == type->mtype);
ut_ad(col->prtype == type->prtype);
//ut_ad(col->len == type->len);
# ifndef UNIV_HOTBACKUP
ut_ad(col->mbminmaxlen == type->mbminmaxlen);
# endif /* !UNIV_HOTBACKUP */
return(TRUE);
}
#endif /* UNIV_DEBUG */
#ifndef UNIV_HOTBACKUP
/***********************************************************************//**
Returns the minimum size of the column.
@return minimum size */
UNIV_INLINE
ulint
dict_col_get_min_size(
/*==================*/
const dict_col_t* col) /*!< in: column */
{
return(dtype_get_min_size_low(col->mtype, col->prtype, col->len,
col->mbminmaxlen));
}
/***********************************************************************//**
Returns the maximum size of the column.
@return maximum size */
UNIV_INLINE
ulint
dict_col_get_max_size(
/*==================*/
const dict_col_t* col) /*!< in: column */
{
return(dtype_get_max_size_low(col->mtype, col->len));
}
#endif /* !UNIV_HOTBACKUP */
/***********************************************************************//**
Returns the size of a fixed size column, 0 if not a fixed size column.
@return fixed size, or 0 */
UNIV_INLINE
ulint
dict_col_get_fixed_size(
/*====================*/
const dict_col_t* col, /*!< in: column */
ulint comp) /*!< in: nonzero=ROW_FORMAT=COMPACT */
{
return(dtype_get_fixed_size_low(col->mtype, col->prtype, col->len,
col->mbminmaxlen, comp));
}
/***********************************************************************//**
Returns the ROW_FORMAT=REDUNDANT stored SQL NULL size of a column.
For fixed length types it is the fixed length of the type, otherwise 0.
@return SQL null storage size in ROW_FORMAT=REDUNDANT */
UNIV_INLINE
ulint
dict_col_get_sql_null_size(
/*=======================*/
const dict_col_t* col, /*!< in: column */
ulint comp) /*!< in: nonzero=ROW_FORMAT=COMPACT */
{
return(dict_col_get_fixed_size(col, comp));
}
/*********************************************************************//**
Gets the column number.
@return col->ind, table column position (starting from 0) */
UNIV_INLINE
ulint
dict_col_get_no(
/*============*/
const dict_col_t* col) /*!< in: column */
{
ut_ad(col);
return(col->ind);
}
/*********************************************************************//**
Gets the column position in the clustered index. */
UNIV_INLINE
ulint
dict_col_get_clust_pos(
/*===================*/
const dict_col_t* col, /*!< in: table column */
const dict_index_t* clust_index) /*!< in: clustered index */
{
ulint i;
ut_ad(col);
ut_ad(clust_index);
ut_ad(dict_index_is_clust(clust_index));
for (i = 0; i < clust_index->n_def; i++) {
const dict_field_t* field = &clust_index->fields[i];
if (!field->prefix_len && field->col == col) {
return(i);
}
}
return(ULINT_UNDEFINED);
}
#ifndef UNIV_HOTBACKUP
#ifdef UNIV_DEBUG
/********************************************************************//**
Gets the first index on the table (the clustered index).
@return index, NULL if none exists */
UNIV_INLINE
dict_index_t*
dict_table_get_first_index(
/*=======================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return(UT_LIST_GET_FIRST(((dict_table_t*) table)->indexes));
}
/********************************************************************//**
Gets the last index on the table.
@return index, NULL if none exists */
UNIV_INLINE
dict_index_t*
dict_table_get_last_index(
/*=======================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return(UT_LIST_GET_LAST((const_cast<dict_table_t*>(table))
->indexes));
}
/********************************************************************//**
Gets the next index on the table.
@return index, NULL if none left */
UNIV_INLINE
dict_index_t*
dict_table_get_next_index(
/*======================*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(UT_LIST_GET_NEXT(indexes, (dict_index_t*) index));
}
#endif /* UNIV_DEBUG */
#endif /* !UNIV_HOTBACKUP */
/********************************************************************//**
Check whether the index is the clustered index.
@return nonzero for clustered index, zero for other indexes */
UNIV_INLINE
ulint
dict_index_is_clust(
/*================*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->type & DICT_CLUSTERED);
}
/********************************************************************//**
Check whether the index is unique.
@return nonzero for unique index, zero for other indexes */
UNIV_INLINE
ulint
dict_index_is_unique(
/*=================*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->type & DICT_UNIQUE);
}
/********************************************************************//**
Check whether the index is the insert buffer tree.
@return nonzero for insert buffer, zero for other indexes */
UNIV_INLINE
ulint
dict_index_is_ibuf(
/*===============*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->type & DICT_IBUF);
}
/********************************************************************//**
Check whether the index is an universal index tree.
@return nonzero for universal tree, zero for other indexes */
UNIV_INLINE
ulint
dict_index_is_univ(
/*===============*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->type & DICT_UNIVERSAL);
}
/********************************************************************//**
Check whether the index is a secondary index or the insert buffer tree.
@return nonzero for insert buffer, zero for other indexes */
UNIV_INLINE
ulint
dict_index_is_sec_or_ibuf(
/*======================*/
const dict_index_t* index) /*!< in: index */
{
ulint type;
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
type = index->type;
return(!(type & DICT_CLUSTERED) || (type & DICT_IBUF));
}
/********************************************************************//**
Gets the number of user-defined columns in a table in the dictionary
cache.
@return number of user-defined (e.g., not ROW_ID) columns of a table */
UNIV_INLINE
ulint
dict_table_get_n_user_cols(
/*=======================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return(table->n_cols - DATA_N_SYS_COLS);
}
/********************************************************************//**
Gets the number of system columns in a table in the dictionary cache.
@return number of system (e.g., ROW_ID) columns of a table */
UNIV_INLINE
ulint
dict_table_get_n_sys_cols(
/*======================*/
const dict_table_t* table MY_ATTRIBUTE((unused))) /*!< in: table */
{
ut_ad(table);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
ut_ad(table->cached);
return(DATA_N_SYS_COLS);
}
/********************************************************************//**
Gets the number of all columns (also system) in a table in the dictionary
cache.
@return number of columns of a table */
UNIV_INLINE
ulint
dict_table_get_n_cols(
/*==================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return(table->n_cols);
}
/********************************************************************//**
Gets the approximately estimated number of rows in the table.
@return estimated number of rows */
UNIV_INLINE
ib_uint64_t
dict_table_get_n_rows(
/*==================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table->stat_initialized);
return(table->stat_n_rows);
}
/********************************************************************//**
Increment the number of rows in the table by one.
Notice that this operation is not protected by any latch, the number is
approximate. */
UNIV_INLINE
void
dict_table_n_rows_inc(
/*==================*/
dict_table_t* table) /*!< in/out: table */
{
if (table->stat_initialized) {
ib_uint64_t n_rows = table->stat_n_rows;
if (n_rows < 0xFFFFFFFFFFFFFFFFULL) {
table->stat_n_rows = n_rows + 1;
}
}
}
/********************************************************************//**
Decrement the number of rows in the table by one.
Notice that this operation is not protected by any latch, the number is
approximate. */
UNIV_INLINE
void
dict_table_n_rows_dec(
/*==================*/
dict_table_t* table) /*!< in/out: table */
{
if (table->stat_initialized) {
ib_uint64_t n_rows = table->stat_n_rows;
if (n_rows > 0) {
table->stat_n_rows = n_rows - 1;
}
}
}
#ifdef UNIV_DEBUG
/********************************************************************//**
Gets the nth column of a table.
@return pointer to column object */
UNIV_INLINE
dict_col_t*
dict_table_get_nth_col(
/*===================*/
const dict_table_t* table, /*!< in: table */
ulint pos) /*!< in: position of column */
{
ut_ad(table);
ut_ad(pos < table->n_def);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return((dict_col_t*) (table->cols) + pos);
}
/********************************************************************//**
Gets the given system column of a table.
@return pointer to column object */
UNIV_INLINE
dict_col_t*
dict_table_get_sys_col(
/*===================*/
const dict_table_t* table, /*!< in: table */
ulint sys) /*!< in: DATA_ROW_ID, ... */
{
dict_col_t* col;
ut_ad(table);
ut_ad(sys < DATA_N_SYS_COLS);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
col = dict_table_get_nth_col(table, table->n_cols
- DATA_N_SYS_COLS + sys);
ut_ad(col->mtype == DATA_SYS);
ut_ad(col->prtype == (sys | DATA_NOT_NULL));
return(col);
}
#endif /* UNIV_DEBUG */
/********************************************************************//**
Gets the given system column number of a table.
@return column number */
UNIV_INLINE
ulint
dict_table_get_sys_col_no(
/*======================*/
const dict_table_t* table, /*!< in: table */
ulint sys) /*!< in: DATA_ROW_ID, ... */
{
ut_ad(table);
ut_ad(sys < DATA_N_SYS_COLS);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return(table->n_cols - DATA_N_SYS_COLS + sys);
}
/********************************************************************//**
Check whether the table uses the compact page format.
@return TRUE if table uses the compact page format */
UNIV_INLINE
ibool
dict_table_is_comp(
/*===============*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table);
#if DICT_TF_COMPACT != 1
#error "DICT_TF_COMPACT must be 1"
#endif
return(table->flags & DICT_TF_COMPACT);
}
/************************************************************************
Check if the table has an FTS index. */
UNIV_INLINE
ibool
dict_table_has_fts_index(
/*=====================*/
/* out: TRUE if table has an FTS index */
dict_table_t* table) /* in: table */
{
ut_ad(table);
return(DICT_TF2_FLAG_IS_SET(table, DICT_TF2_FTS));
}
/********************************************************************//**
Validate the table flags.
@return true if valid. */
UNIV_INLINE
bool
dict_tf_is_valid(
/*=============*/
ulint flags) /*!< in: table flags */
{
ulint compact = DICT_TF_GET_COMPACT(flags);
ulint zip_ssize = DICT_TF_GET_ZIP_SSIZE(flags);
ulint atomic_blobs = DICT_TF_HAS_ATOMIC_BLOBS(flags);
ulint unused = DICT_TF_GET_UNUSED(flags);
ulint page_compression = DICT_TF_GET_PAGE_COMPRESSION(flags);
ulint page_compression_level = DICT_TF_GET_PAGE_COMPRESSION_LEVEL(flags);
ulint data_dir = DICT_TF_HAS_DATA_DIR(flags);
ulint atomic_writes = DICT_TF_GET_ATOMIC_WRITES(flags);
/* Make sure there are no bits that we do not know about. */
if (unused != 0) {
fprintf(stderr,
"InnoDB: Error: table unused flags are " ULINTPF
" in the data dictionary and are corrupted\n"
"InnoDB: Error: data dictionary flags are\n"
"InnoDB: compact " ULINTPF " atomic_blobs " ULINTPF
"\nInnoDB: unused " ULINTPF " data_dir " ULINTPF
" zip_ssize " ULINTPF
"\nInnoDB: page_compression " ULINTPF
" page_compression_level " ULINTPF
"\nInnoDB: atomic_writes " ULINTPF "\n",
unused,
compact, atomic_blobs, unused, data_dir, zip_ssize,
page_compression, page_compression_level, atomic_writes
);
return(false);
} else if (atomic_blobs) {
/* Barracuda row formats COMPRESSED and DYNAMIC build on
the page structure introduced for the COMPACT row format
by allowing keys in secondary indexes to be made from
data stored off-page in the clustered index. */
if (!compact) {
fprintf(stderr,
"InnoDB: Error: table compact flags are "
ULINTPF
" in the data dictionary and are corrupted\n"
"InnoDB: Error: data dictionary flags are\n"
"InnoDB: compact " ULINTPF
" atomic_blobs " ULINTPF "\n"
"InnoDB: unused " ULINTPF
" data_dir " ULINTPF " zip_ssize " ULINTPF
"\nInnoDB: page_compression " ULINTPF
" page_compression_level " ULINTPF
"\nInnoDB: atomic_writes " ULINTPF "\n",
compact, compact, atomic_blobs, unused, data_dir, zip_ssize,
page_compression, page_compression_level, atomic_writes
);
return(false);
}
} else if (zip_ssize) {
/* Antelope does not support COMPRESSED row format. */
fprintf(stderr,
"InnoDB: Error: table flags are " ULINTPF
" in the data dictionary and are corrupted\n"
"InnoDB: Error: data dictionary flags are\n"
"InnoDB: compact " ULINTPF " atomic_blobs " ULINTPF
"\nInnoDB: unused " ULINTPF " data_dir " ULINTPF
" zip_ssize " ULINTPF
"\nInnoDB: page_compression " ULINTPF
" page_compression_level " ULINTPF
"\nInnoDB: atomic_writes " ULINTPF "\n",
flags, compact, atomic_blobs, unused, data_dir, zip_ssize,
page_compression, page_compression_level, atomic_writes
);
return(false);
}
if (zip_ssize) {
/* COMPRESSED row format must have compact and atomic_blobs
bits set and validate the number is within allowed range. */
if (!compact
|| !atomic_blobs
|| zip_ssize > PAGE_ZIP_SSIZE_MAX) {
fprintf(stderr,
"InnoDB: Error: table compact flags are "
ULINTPF
" in the data dictionary and are corrupted\n"
"InnoDB: Error: data dictionary flags are\n"
"InnoDB: compact " ULINTPF
" atomic_blobs " ULINTPF "\n"
"InnoDB: unused " ULINTPF
" data_dir " ULINTPF " zip_ssize " ULINTPF
"\nInnoDB: page_compression " ULINTPF
" page_compression_level " ULINTPF
"\nInnoDB: atomic_writes " ULINTPF "\n",
flags,
compact, atomic_blobs, unused, data_dir, zip_ssize,
page_compression, page_compression_level, atomic_writes
);
return(false);
}
}
if (page_compression || page_compression_level) {
/* Page compression format must have compact and
atomic_blobs and page_compression_level requires
page_compression */
if (!compact
|| !page_compression
|| !atomic_blobs) {
fprintf(stderr,
"InnoDB: Error: table flags are " ULINTPF
" in the data dictionary and are corrupted\n"
"InnoDB: Error: data dictionary flags are\n"
"InnoDB: compact " ULINTPF
" atomic_blobs " ULINTPF "\n"
"InnoDB: unused " ULINTPF
" data_dir " ULINTPF " zip_ssize " ULINTPF
"\nInnoDB: page_compression " ULINTPF
" page_compression_level " ULINTPF
"\nInnoDB: atomic_writes " ULINTPF "\n",
flags, compact, atomic_blobs, unused, data_dir, zip_ssize,
page_compression, page_compression_level, atomic_writes
);
return(false);
}
}
if (atomic_writes) {
if(atomic_writes > ATOMIC_WRITES_OFF) {
fprintf(stderr,
"InnoDB: Error: table flags are " ULINTPF
" in the data dictionary and are corrupted\n"
"InnoDB: Error: data dictionary flags are\n"
"InnoDB: compact " ULINTPF
" atomic_blobs " ULINTPF "\n"
"InnoDB: unused " ULINTPF
" data_dir " ULINTPF " zip_ssize " ULINTPF
"\nInnoDB: page_compression " ULINTPF
" page_compression_level " ULINTPF
"\nInnoDB: atomic_writes " ULINTPF "\n",
flags, compact, atomic_blobs, unused, data_dir, zip_ssize,
page_compression, page_compression_level, atomic_writes
);
return(false);
}
}
/* CREATE TABLE ... DATA DIRECTORY is supported for any row format,
so the DATA_DIR flag is compatible with all other table flags. */
return(true);
}
/********************************************************************//**
Validate a SYS_TABLES TYPE field and return it.
@return Same as input after validating it as a SYS_TABLES TYPE field.
If there is an error, return ULINT_UNDEFINED. */
UNIV_INLINE
ulint
dict_sys_tables_type_validate(
/*==========================*/
ulint type, /*!< in: SYS_TABLES.TYPE */
ulint n_cols) /*!< in: SYS_TABLES.N_COLS */
{
ulint low_order_bit = DICT_TF_GET_COMPACT(type);
ulint redundant = !(n_cols & DICT_N_COLS_COMPACT);
ulint zip_ssize = DICT_TF_GET_ZIP_SSIZE(type);
ulint atomic_blobs = DICT_TF_HAS_ATOMIC_BLOBS(type);
ulint unused = DICT_TF_GET_UNUSED(type);
ulint page_compression = DICT_TF_GET_PAGE_COMPRESSION(type);
ulint page_compression_level = DICT_TF_GET_PAGE_COMPRESSION_LEVEL(type);
ulint atomic_writes = DICT_TF_GET_ATOMIC_WRITES(type);
ut_a(atomic_writes <= ATOMIC_WRITES_OFF);
/* The low order bit of SYS_TABLES.TYPE is always set to 1.
If the format is UNIV_FORMAT_B or higher, this field is the same
as dict_table_t::flags. Zero is not allowed here. */
if (!low_order_bit) {
return(ULINT_UNDEFINED);
}
if (redundant) {
if (zip_ssize || atomic_blobs) {
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=Redundant, zip_ssize " ULINTPF " atomic_blobs " ULINTPF "\n",
zip_ssize, atomic_blobs);
return(ULINT_UNDEFINED);
}
}
/* Make sure there are no bits that we do not know about. */
if (unused) {
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=" ULINTPF ", unused " ULINTPF "\n",
type, unused);
return(ULINT_UNDEFINED);
}
if (atomic_blobs) {
/* Barracuda row formats COMPRESSED and DYNAMIC build on
the page structure introduced for the COMPACT row format
by allowing keys in secondary indexes to be made from
data stored off-page in the clustered index.
The DICT_N_COLS_COMPACT flag should be in N_COLS,
but we already know that. */
} else if (zip_ssize) {
/* Antelope does not support COMPRESSED format. */
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=" ULINTPF ", zip_ssize " ULINTPF "\n",
type, zip_ssize);
return(ULINT_UNDEFINED);
}
if (zip_ssize) {
/* COMPRESSED row format must have low_order_bit and
atomic_blobs bits set and the DICT_N_COLS_COMPACT flag
should be in N_COLS, but we already know about the
low_order_bit and DICT_N_COLS_COMPACT flags. */
if (!atomic_blobs) {
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=" ULINTPF ", zip_ssize " ULINTPF " atomic_blobs " ULINTPF "\n",
type, zip_ssize, atomic_blobs);
return(ULINT_UNDEFINED);
}
/* Validate that the number is within allowed range. */
if (zip_ssize > PAGE_ZIP_SSIZE_MAX) {
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=" ULINTPF ", zip_ssize " ULINTPF " max %d\n",
type, zip_ssize, PAGE_ZIP_SSIZE_MAX);
return(ULINT_UNDEFINED);
}
}
/* There is nothing to validate for the data_dir field.
CREATE TABLE ... DATA DIRECTORY is supported for any row
format, so the DATA_DIR flag is compatible with any other
table flags. However, it is not used with TEMPORARY tables.*/
if (page_compression || page_compression_level) {
/* page compressed row format must have low_order_bit and
atomic_blobs bits set and the DICT_N_COLS_COMPACT flag
should be in N_COLS, but we already know about the
low_order_bit and DICT_N_COLS_COMPACT flags. */
if (!atomic_blobs || !page_compression) {
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=" ULINTPF ", page_compression " ULINTPF " page_compression_level " ULINTPF "\n"
"InnoDB: Error: atomic_blobs " ULINTPF "\n",
type, page_compression, page_compression_level, atomic_blobs);
return(ULINT_UNDEFINED);
}
}
/* Validate that the atomic writes number is within allowed range. */
if (atomic_writes > ATOMIC_WRITES_OFF) {
fprintf(stderr, "InnoDB: Error: SYS_TABLES::TYPE=" ULINTPF ", atomic_writes " ULINTPF "\n",
type, atomic_writes);
return(ULINT_UNDEFINED);
}
/* Return the validated SYS_TABLES.TYPE. */
return(type);
}
/********************************************************************//**
Determine the file format from dict_table_t::flags
The low order bit will be zero for REDUNDANT and 1 for COMPACT. For any
other row_format, file_format is > 0 and DICT_TF_COMPACT will also be set.
@return file format version */
UNIV_INLINE
rec_format_t
dict_tf_get_rec_format(
/*===================*/
ulint flags) /*!< in: dict_table_t::flags */
{
ut_a(dict_tf_is_valid(flags));
if (!DICT_TF_GET_COMPACT(flags)) {
return(REC_FORMAT_REDUNDANT);
}
if (!DICT_TF_HAS_ATOMIC_BLOBS(flags)) {
return(REC_FORMAT_COMPACT);
}
if (DICT_TF_GET_ZIP_SSIZE(flags)) {
return(REC_FORMAT_COMPRESSED);
}
return(REC_FORMAT_DYNAMIC);
}
/********************************************************************//**
Determine the file format from a dict_table_t::flags.
@return file format version */
UNIV_INLINE
ulint
dict_tf_get_format(
/*===============*/
ulint flags) /*!< in: dict_table_t::flags */
{
if (DICT_TF_HAS_ATOMIC_BLOBS(flags)) {
return(UNIV_FORMAT_B);
}
return(UNIV_FORMAT_A);
}
/********************************************************************//**
Determine the file format of a table.
@return file format version */
UNIV_INLINE
ulint
dict_table_get_format(
/*==================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table);
return(dict_tf_get_format(table->flags));
}
/********************************************************************//**
Set the file format and zip size in a dict_table_t::flags. If zip size
is not needed, it should be 0. */
UNIV_INLINE
void
dict_tf_set(
/*========*/
ulint* flags, /*!< in/out: table flags */
rec_format_t format, /*!< in: file format */
ulint zip_ssize, /*!< in: zip shift size */
bool use_data_dir, /*!< in: table uses DATA DIRECTORY
*/
bool page_compressed,/*!< in: table uses page compressed
pages */
ulint page_compression_level, /*!< in: table page compression
level */
ulint atomic_writes) /*!< in: table atomic writes setup */
{
atomic_writes_t awrites = (atomic_writes_t)atomic_writes;
switch (format) {
case REC_FORMAT_REDUNDANT:
*flags = 0;
ut_ad(zip_ssize == 0);
break;
case REC_FORMAT_COMPACT:
*flags = DICT_TF_COMPACT;
ut_ad(zip_ssize == 0);
break;
case REC_FORMAT_COMPRESSED:
*flags = DICT_TF_COMPACT
| (1 << DICT_TF_POS_ATOMIC_BLOBS)
| (zip_ssize << DICT_TF_POS_ZIP_SSIZE);
break;
case REC_FORMAT_DYNAMIC:
*flags = DICT_TF_COMPACT
| (1 << DICT_TF_POS_ATOMIC_BLOBS);
ut_ad(zip_ssize == 0);
break;
}
if (page_compressed) {
*flags |= (1 << DICT_TF_POS_ATOMIC_BLOBS)
| (1 << DICT_TF_POS_PAGE_COMPRESSION)
| (page_compression_level << DICT_TF_POS_PAGE_COMPRESSION_LEVEL);
ut_ad(zip_ssize == 0);
ut_ad(dict_tf_get_page_compression(*flags) == TRUE);
ut_ad(dict_tf_get_page_compression_level(*flags) == page_compression_level);
}
*flags |= (atomic_writes << DICT_TF_POS_ATOMIC_WRITES);
ut_a(dict_tf_get_atomic_writes(*flags) == awrites);
if (use_data_dir) {
*flags |= (1 << DICT_TF_POS_DATA_DIR);
}
}
/********************************************************************//**
Convert a 32 bit integer table flags to the 32 bit integer that is
written into the tablespace header at the offset FSP_SPACE_FLAGS and is
also stored in the fil_space_t::flags field. The following chart shows
the translation of the low order bit. Other bits are the same.
========================= Low order bit ==========================
| REDUNDANT | COMPACT | COMPRESSED | DYNAMIC
dict_table_t::flags | 0 | 1 | 1 | 1
fil_space_t::flags | 0 | 0 | 1 | 1
==================================================================
@return tablespace flags (fil_space_t::flags) */
UNIV_INLINE
ulint
dict_tf_to_fsp_flags(
/*=================*/
ulint table_flags) /*!< in: dict_table_t::flags */
{
ulint fsp_flags;
ulint page_compression_level = DICT_TF_GET_PAGE_COMPRESSION_LEVEL(
table_flags);
ulint atomic_writes = DICT_TF_GET_ATOMIC_WRITES(table_flags);
ut_ad((DICT_TF_GET_PAGE_COMPRESSION(table_flags) == 0)
== (page_compression_level == 0));
DBUG_EXECUTE_IF("dict_tf_to_fsp_flags_failure",
return(ULINT_UNDEFINED););
/* Adjust bit zero. */
fsp_flags = DICT_TF_HAS_ATOMIC_BLOBS(table_flags) ? 1 : 0;
/* ZIP_SSIZE and ATOMIC_BLOBS are at the same position. */
fsp_flags |= table_flags
& (DICT_TF_MASK_ZIP_SSIZE | DICT_TF_MASK_ATOMIC_BLOBS);
fsp_flags |= FSP_FLAGS_PAGE_SSIZE();
if (page_compression_level) {
fsp_flags |= FSP_FLAGS_MASK_PAGE_COMPRESSION;
}
ut_a(fsp_flags_is_valid(fsp_flags));
if (DICT_TF_HAS_DATA_DIR(table_flags)) {
fsp_flags |= 1U << FSP_FLAGS_MEM_DATA_DIR;
}
fsp_flags |= atomic_writes << FSP_FLAGS_MEM_ATOMIC_WRITES;
fsp_flags |= page_compression_level << FSP_FLAGS_MEM_COMPRESSION_LEVEL;
return(fsp_flags);
}
/********************************************************************//**
Convert a 32 bit integer from SYS_TABLES.TYPE to dict_table_t::flags
The following chart shows the translation of the low order bit.
Other bits are the same.
========================= Low order bit ==========================
| REDUNDANT | COMPACT | COMPRESSED and DYNAMIC
SYS_TABLES.TYPE | 1 | 1 | 1
dict_table_t::flags | 0 | 1 | 1
==================================================================
@return ulint containing SYS_TABLES.TYPE */
UNIV_INLINE
ulint
dict_sys_tables_type_to_tf(
/*=======================*/
ulint type, /*!< in: SYS_TABLES.TYPE field */
ulint n_cols) /*!< in: SYS_TABLES.N_COLS field */
{
ulint flags;
ulint redundant = !(n_cols & DICT_N_COLS_COMPACT);
/* Adjust bit zero. */
flags = redundant ? 0 : 1;
/* ZIP_SSIZE, ATOMIC_BLOBS, DATA_DIR, PAGE_COMPRESSION,
PAGE_COMPRESSION_LEVEL, ATOMIC_WRITES are the same. */
flags |= type & (DICT_TF_MASK_ZIP_SSIZE
| DICT_TF_MASK_ATOMIC_BLOBS
| DICT_TF_MASK_DATA_DIR
| DICT_TF_MASK_PAGE_COMPRESSION
| DICT_TF_MASK_PAGE_COMPRESSION_LEVEL
| DICT_TF_MASK_ATOMIC_WRITES
);
return(flags);
}
/********************************************************************//**
Convert a 32 bit integer table flags to the 32bit integer that is written
to a SYS_TABLES.TYPE field. The following chart shows the translation of
the low order bit. Other bits are the same.
========================= Low order bit ==========================
| REDUNDANT | COMPACT | COMPRESSED and DYNAMIC
dict_table_t::flags | 0 | 1 | 1
SYS_TABLES.TYPE | 1 | 1 | 1
==================================================================
@return ulint containing SYS_TABLES.TYPE */
UNIV_INLINE
ulint
dict_tf_to_sys_tables_type(
/*=======================*/
ulint flags) /*!< in: dict_table_t::flags */
{
ulint type;
ut_a(dict_tf_is_valid(flags));
/* Adjust bit zero. It is always 1 in SYS_TABLES.TYPE */
type = 1;
/* ZIP_SSIZE, ATOMIC_BLOBS, DATA_DIR, PAGE_COMPRESSION,
PAGE_COMPRESSION_LEVEL, ATOMIC_WRITES are the same. */
type |= flags & (DICT_TF_MASK_ZIP_SSIZE
| DICT_TF_MASK_ATOMIC_BLOBS
| DICT_TF_MASK_DATA_DIR
| DICT_TF_MASK_PAGE_COMPRESSION
| DICT_TF_MASK_PAGE_COMPRESSION_LEVEL
| DICT_TF_MASK_ATOMIC_WRITES);
return(type);
}
/********************************************************************//**
Extract the compressed page size from dict_table_t::flags.
These flags are in memory, so assert that they are valid.
@return compressed page size, or 0 if not compressed */
UNIV_INLINE
ulint
dict_tf_get_zip_size(
/*=================*/
ulint flags) /*!< in: flags */
{
ulint zip_ssize = DICT_TF_GET_ZIP_SSIZE(flags);
ulint zip_size = (zip_ssize
? (UNIV_ZIP_SIZE_MIN >> 1) << zip_ssize
: 0);
ut_ad(zip_size <= UNIV_ZIP_SIZE_MAX);
return(zip_size);
}
/********************************************************************//**
Check whether the table uses the compressed compact page format.
@return compressed page size, or 0 if not compressed */
UNIV_INLINE
ulint
dict_table_zip_size(
/*================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table);
return(dict_tf_get_zip_size(table->flags));
}
#ifndef UNIV_HOTBACKUP
/*********************************************************************//**
Obtain exclusive locks on all index trees of the table. This is to prevent
accessing index trees while InnoDB is updating internal metadata for
operations such as truncate tables. */
UNIV_INLINE
void
dict_table_x_lock_indexes(
/*======================*/
dict_table_t* table) /*!< in: table */
{
dict_index_t* index;
ut_a(table);
ut_ad(mutex_own(&(dict_sys->mutex)));
/* Loop through each index of the table and lock them */
for (index = dict_table_get_first_index(table);
index != NULL;
index = dict_table_get_next_index(index)) {
rw_lock_x_lock(dict_index_get_lock(index));
}
}
/*********************************************************************//**
Release the exclusive locks on all index tree. */
UNIV_INLINE
void
dict_table_x_unlock_indexes(
/*========================*/
dict_table_t* table) /*!< in: table */
{
dict_index_t* index;
ut_a(table);
ut_ad(mutex_own(&(dict_sys->mutex)));
for (index = dict_table_get_first_index(table);
index != NULL;
index = dict_table_get_next_index(index)) {
rw_lock_x_unlock(dict_index_get_lock(index));
}
}
#endif /* !UNIV_HOTBACKUP */
/********************************************************************//**
Gets the number of fields in the internal representation of an index,
including fields added by the dictionary system.
@return number of fields */
UNIV_INLINE
ulint
dict_index_get_n_fields(
/*====================*/
const dict_index_t* index) /*!< in: an internal
representation of index (in
the dictionary cache) */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->n_fields);
}
/********************************************************************//**
Gets the number of fields in the internal representation of an index
that uniquely determine the position of an index entry in the index, if
we do not take multiversioning into account: in the B-tree use the value
returned by dict_index_get_n_unique_in_tree.
@return number of fields */
UNIV_INLINE
ulint
dict_index_get_n_unique(
/*====================*/
const dict_index_t* index) /*!< in: an internal representation
of index (in the dictionary cache) */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
ut_ad(index->cached);
return(index->n_uniq);
}
/********************************************************************//**
Gets the number of fields in the internal representation of an index
which uniquely determine the position of an index entry in the index, if
we also take multiversioning into account.
@return number of fields */
UNIV_INLINE
ulint
dict_index_get_n_unique_in_tree(
/*============================*/
const dict_index_t* index) /*!< in: an internal representation
of index (in the dictionary cache) */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
ut_ad(index->cached);
if (dict_index_is_clust(index)) {
return(dict_index_get_n_unique(index));
}
return(dict_index_get_n_fields(index));
}
/********************************************************************//**
Gets the number of user-defined ordering fields in the index. In the internal
representation of clustered indexes we add the row id to the ordering fields
to make a clustered index unique, but this function returns the number of
fields the user defined in the index as ordering fields.
@return number of fields */
UNIV_INLINE
ulint
dict_index_get_n_ordering_defined_by_user(
/*======================================*/
const dict_index_t* index) /*!< in: an internal representation
of index (in the dictionary cache) */
{
return(index->n_user_defined_cols);
}
#ifdef UNIV_DEBUG
/********************************************************************//**
Gets the nth field of an index.
@return pointer to field object */
UNIV_INLINE
dict_field_t*
dict_index_get_nth_field(
/*=====================*/
const dict_index_t* index, /*!< in: index */
ulint pos) /*!< in: position of field */
{
ut_ad(index);
ut_ad(pos < index->n_def);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return((dict_field_t*) (index->fields) + pos);
}
#endif /* UNIV_DEBUG */
/********************************************************************//**
Returns the position of a system column in an index.
@return position, ULINT_UNDEFINED if not contained */
UNIV_INLINE
ulint
dict_index_get_sys_col_pos(
/*=======================*/
const dict_index_t* index, /*!< in: index */
ulint type) /*!< in: DATA_ROW_ID, ... */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
ut_ad(!dict_index_is_univ(index));
if (dict_index_is_clust(index)) {
return(dict_col_get_clust_pos(
dict_table_get_sys_col(index->table, type),
index));
}
return(dict_index_get_nth_col_pos(
index, dict_table_get_sys_col_no(index->table, type),
NULL));
}
/*********************************************************************//**
Gets the field column.
@return field->col, pointer to the table column */
UNIV_INLINE
const dict_col_t*
dict_field_get_col(
/*===============*/
const dict_field_t* field) /*!< in: index field */
{
ut_ad(field);
return(field->col);
}
/********************************************************************//**
Gets pointer to the nth column in an index.
@return column */
UNIV_INLINE
const dict_col_t*
dict_index_get_nth_col(
/*===================*/
const dict_index_t* index, /*!< in: index */
ulint pos) /*!< in: position of the field */
{
return(dict_field_get_col(dict_index_get_nth_field(index, pos)));
}
/********************************************************************//**
Gets the column number the nth field in an index.
@return column number */
UNIV_INLINE
ulint
dict_index_get_nth_col_no(
/*======================*/
const dict_index_t* index, /*!< in: index */
ulint pos) /*!< in: position of the field */
{
return(dict_col_get_no(dict_index_get_nth_col(index, pos)));
}
/********************************************************************//**
Looks for column n in an index.
@return position in internal representation of the index;
ULINT_UNDEFINED if not contained */
UNIV_INLINE
ulint
dict_index_get_nth_col_pos(
/*=======================*/
const dict_index_t* index, /*!< in: index */
ulint n, /*!< in: column number */
ulint* prefix_col_pos) /*!< out: col num if prefix */
{
return(dict_index_get_nth_col_or_prefix_pos(index, n, FALSE,
prefix_col_pos));
}
#ifndef UNIV_HOTBACKUP
/********************************************************************//**
Returns the minimum data size of an index record.
@return minimum data size in bytes */
UNIV_INLINE
ulint
dict_index_get_min_size(
/*====================*/
const dict_index_t* index) /*!< in: index */
{
ulint n = dict_index_get_n_fields(index);
ulint size = 0;
while (n--) {
size += dict_col_get_min_size(dict_index_get_nth_col(index,
n));
}
return(size);
}
/*********************************************************************//**
Gets the space id of the root of the index tree.
@return space id */
UNIV_INLINE
ulint
dict_index_get_space(
/*=================*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->space);
}
/*********************************************************************//**
Sets the space id of the root of the index tree. */
UNIV_INLINE
void
dict_index_set_space(
/*=================*/
dict_index_t* index, /*!< in/out: index */
ulint space) /*!< in: space id */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
index->space = space;
}
/*********************************************************************//**
Gets the page number of the root of the index tree.
@return page number */
UNIV_INLINE
ulint
dict_index_get_page(
/*================*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(index->page);
}
/*********************************************************************//**
Gets the read-write lock of the index tree.
@return read-write lock */
UNIV_INLINE
rw_lock_t*
dict_index_get_lock(
/*================*/
dict_index_t* index) /*!< in: index */
{
ut_ad(index);
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return(&(index->lock));
}
/********************************************************************//**
Returns free space reserved for future updates of records. This is
relevant only in the case of many consecutive inserts, as updates
which make the records bigger might fragment the index.
@return number of free bytes on page, reserved for updates */
UNIV_INLINE
ulint
dict_index_get_space_reserve(void)
/*==============================*/
{
return(UNIV_PAGE_SIZE / 16);
}
/********************************************************************//**
Gets the status of online index creation.
@return the status */
UNIV_INLINE
enum online_index_status
dict_index_get_online_status(
/*=========================*/
const dict_index_t* index) /*!< in: secondary index */
{
enum online_index_status status;
status = (enum online_index_status) index->online_status;
/* Without the index->lock protection, the online
status can change from ONLINE_INDEX_CREATION to
ONLINE_INDEX_COMPLETE (or ONLINE_INDEX_ABORTED) in
row_log_apply() once log application is done. So to make
sure the status is ONLINE_INDEX_CREATION or ONLINE_INDEX_COMPLETE
you should always do the recheck after acquiring index->lock */
#ifdef UNIV_DEBUG
switch (status) {
case ONLINE_INDEX_COMPLETE:
case ONLINE_INDEX_CREATION:
case ONLINE_INDEX_ABORTED:
case ONLINE_INDEX_ABORTED_DROPPED:
return(status);
}
ut_error;
#endif /* UNIV_DEBUG */
return(status);
}
/********************************************************************//**
Sets the status of online index creation. */
UNIV_INLINE
void
dict_index_set_online_status(
/*=========================*/
dict_index_t* index, /*!< in/out: index */
enum online_index_status status) /*!< in: status */
{
ut_ad(!(index->type & DICT_FTS));
#ifdef UNIV_SYNC_DEBUG
ut_ad(rw_lock_own(dict_index_get_lock(index), RW_LOCK_EX));
#endif /* UNIV_SYNC_DEBUG */
#ifdef UNIV_DEBUG
switch (dict_index_get_online_status(index)) {
case ONLINE_INDEX_COMPLETE:
case ONLINE_INDEX_CREATION:
break;
case ONLINE_INDEX_ABORTED:
ut_ad(status == ONLINE_INDEX_ABORTED_DROPPED);
break;
case ONLINE_INDEX_ABORTED_DROPPED:
ut_error;
}
#endif /* UNIV_DEBUG */
index->online_status = status;
ut_ad(dict_index_get_online_status(index) == status);
}
/********************************************************************//**
Determines if a secondary index is being or has been created online,
or if the table is being rebuilt online, allowing concurrent modifications
to the table.
@retval true if the index is being or has been built online, or
if this is a clustered index and the table is being or has been rebuilt online
@retval false if the index has been created or the table has been
rebuilt completely */
UNIV_INLINE
bool
dict_index_is_online_ddl(
/*=====================*/
const dict_index_t* index) /*!< in: index */
{
#ifdef UNIV_DEBUG
if (dict_index_is_clust(index)) {
switch (dict_index_get_online_status(index)) {
case ONLINE_INDEX_CREATION:
return(true);
case ONLINE_INDEX_COMPLETE:
return(false);
case ONLINE_INDEX_ABORTED:
case ONLINE_INDEX_ABORTED_DROPPED:
break;
}
ut_ad(0);
return(false);
}
#endif /* UNIV_DEBUG */
return(UNIV_UNLIKELY(dict_index_get_online_status(index)
!= ONLINE_INDEX_COMPLETE));
}
/**********************************************************************//**
Check whether a column exists in an FTS index.
@return ULINT_UNDEFINED if no match else the offset within the vector */
UNIV_INLINE
ulint
dict_table_is_fts_column(
/*=====================*/
ib_vector_t* indexes,/*!< in: vector containing only FTS indexes */
ulint col_no) /*!< in: col number to search for */
{
ulint i;
for (i = 0; i < ib_vector_size(indexes); ++i) {
dict_index_t* index;
index = (dict_index_t*) ib_vector_getp(indexes, i);
if (dict_index_contains_col_or_prefix(index, col_no)) {
return(i);
}
}
return(ULINT_UNDEFINED);
}
/**********************************************************************//**
Determine bytes of column prefix to be stored in the undo log. Please
note if the table format is UNIV_FORMAT_A (< UNIV_FORMAT_B), no prefix
needs to be stored in the undo log.
@return bytes of column prefix to be stored in the undo log */
UNIV_INLINE
ulint
dict_max_field_len_store_undo(
/*==========================*/
dict_table_t* table, /*!< in: table */
const dict_col_t* col) /*!< in: column which index prefix
is based on */
{
ulint prefix_len = 0;
if (dict_table_get_format(table) >= UNIV_FORMAT_B)
{
prefix_len = col->max_prefix
? col->max_prefix
: DICT_MAX_FIELD_LEN_BY_FORMAT(table);
}
return(prefix_len);
}
/********************************************************************//**
Check whether the table is corrupted.
@return nonzero for corrupted table, zero for valid tables */
UNIV_INLINE
ulint
dict_table_is_corrupted(
/*====================*/
const dict_table_t* table) /*!< in: table */
{
ut_ad(table);
ut_ad(table->magic_n == DICT_TABLE_MAGIC_N);
return(table->corrupted);
}
/********************************************************************//**
Check whether the index is corrupted.
@return nonzero for corrupted index, zero for valid indexes */
UNIV_INLINE
ulint
dict_index_is_corrupted(
/*====================*/
const dict_index_t* index) /*!< in: index */
{
ut_ad(index->magic_n == DICT_INDEX_MAGIC_N);
return((index->type & DICT_CORRUPT)
|| (index->table && index->table->corrupted));
}
/********************************************************************//**
Check if the tablespace for the table has been discarded.
@return true if the tablespace has been discarded. */
UNIV_INLINE
bool
dict_table_is_discarded(
/*====================*/
const dict_table_t* table) /*!< in: table to check */
{
return(DICT_TF2_FLAG_IS_SET(table, DICT_TF2_DISCARDED));
}
/********************************************************************//**
Check if it is a temporary table.
@return true if temporary table flag is set. */
UNIV_INLINE
bool
dict_table_is_temporary(
/*====================*/
const dict_table_t* table) /*!< in: table to check */
{
return(DICT_TF2_FLAG_IS_SET(table, DICT_TF2_TEMPORARY));
}
/**********************************************************************//**
Get index by first field of the index
@return index which is having first field matches
with the field present in field_index position of table */
UNIV_INLINE
dict_index_t*
dict_table_get_index_on_first_col(
/*==============================*/
const dict_table_t* table, /*!< in: table */
ulint col_index) /*!< in: position of column
in table */
{
ut_ad(col_index < table->n_cols);
dict_col_t* column = dict_table_get_nth_col(table, col_index);
for (dict_index_t* index = dict_table_get_first_index(table);
index != NULL; index = dict_table_get_next_index(index)) {
if (index->fields[0].col == column) {
return(index);
}
}
ut_error;
return(0);
}
#endif /* !UNIV_HOTBACKUP */
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