/***************************************************************************** Copyright (c) 1994, 2016, Oracle and/or its affiliates. All Rights Reserved. Copyright (c) 2012, Facebook Inc. Copyright (c) 2014, 2022, 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, Fifth Floor, Boston, MA 02110-1335 USA *****************************************************************************/ /**************************************************//** @file include/btr0btr.h The B-tree Created 6/2/1994 Heikki Tuuri *******************************************************/ #pragma once #include "dict0dict.h" #include "data0data.h" #include "rem0types.h" #include "page0cur.h" #include "btr0types.h" #include "gis0type.h" #define BTR_MAX_NODE_LEVEL 50 /*!< Maximum B-tree page level (not really a hard limit). Used in debug assertions in btr_page_set_level and btr_page_get_level */ /** Maximum record size which can be stored on a page, without using the special big record storage structure */ #define BTR_PAGE_MAX_REC_SIZE (srv_page_size / 2 - 200) /** @brief Maximum depth of a B-tree in InnoDB. Note that this isn't a maximum as such; none of the tree operations avoid producing trees bigger than this. It is instead a "max depth that other code must work with", useful for e.g. fixed-size arrays that must store some information about each level in a tree. In other words: if a B-tree with bigger depth than this is encountered, it is not acceptable for it to lead to mysterious memory corruption, but it is acceptable for the program to die with a clear assert failure. */ #define BTR_MAX_LEVELS 100 #define BTR_LATCH_MODE_WITHOUT_FLAGS(latch_mode) \ btr_latch_mode((latch_mode) & ~(BTR_INSERT \ | BTR_DELETE_MARK \ | BTR_RTREE_UNDO_INS \ | BTR_RTREE_DELETE_MARK \ | BTR_DELETE \ | BTR_IGNORE_SEC_UNIQUE \ | BTR_ALREADY_S_LATCHED \ | BTR_LATCH_FOR_INSERT \ | BTR_LATCH_FOR_DELETE)) #define BTR_LATCH_MODE_WITHOUT_INTENTION(latch_mode) \ btr_latch_mode((latch_mode) \ & ~(BTR_LATCH_FOR_INSERT | BTR_LATCH_FOR_DELETE)) /**************************************************************//** Checks and adjusts the root node of a tree during IMPORT TABLESPACE. @return error code, or DB_SUCCESS */ dberr_t btr_root_adjust_on_import( /*======================*/ const dict_index_t* index) /*!< in: index tree */ MY_ATTRIBUTE((warn_unused_result)); /** Report a decryption failure. */ ATTRIBUTE_COLD void btr_decryption_failed(const dict_index_t &index); /** Get an index page and declare its latching order level. @param[in] index index tree @param[in] page page number @param[in] mode latch mode @param[in] merge whether change buffer merge should be attempted @param[in,out] mtr mini-transaction @param[out] err error code @return block */ buf_block_t *btr_block_get(const dict_index_t &index, uint32_t page, ulint mode, bool merge, mtr_t *mtr, dberr_t *err= nullptr); /**************************************************************//** Gets the index id field of a page. @return index id */ UNIV_INLINE index_id_t btr_page_get_index_id( /*==================*/ const page_t* page) /*!< in: index page */ MY_ATTRIBUTE((warn_unused_result)); /** Read the B-tree or R-tree PAGE_LEVEL. @param page B-tree or R-tree page @return number of child page links to reach the leaf level @retval 0 for leaf pages */ inline uint16_t btr_page_get_level(const page_t *page) { uint16_t level= mach_read_from_2(my_assume_aligned<2> (PAGE_HEADER + PAGE_LEVEL + page)); ut_ad(level <= BTR_MAX_NODE_LEVEL); return level; } MY_ATTRIBUTE((warn_unused_result)) /** Read FIL_PAGE_NEXT. @param page buffer pool page @return previous page number */ inline uint32_t btr_page_get_next(const page_t* page) { return mach_read_from_4(my_assume_aligned<4>(page + FIL_PAGE_NEXT)); } /** Read FIL_PAGE_PREV. @param page buffer pool page @return previous page number */ inline uint32_t btr_page_get_prev(const page_t* page) { return mach_read_from_4(my_assume_aligned<4>(page + FIL_PAGE_PREV)); } /**************************************************************//** Gets the child node file address in a node pointer. NOTE: the offsets array must contain all offsets for the record since we read the last field according to offsets and assume that it contains the child page number. In other words offsets must have been retrieved with rec_get_offsets(n_fields=ULINT_UNDEFINED). @return child node address */ UNIV_INLINE uint32_t btr_node_ptr_get_child_page_no( /*===========================*/ const rec_t* rec, /*!< in: node pointer record */ const rec_offs* offsets)/*!< in: array returned by rec_get_offsets() */ MY_ATTRIBUTE((warn_unused_result)); /** Create the root node for a new index tree. @param[in] type type of the index @param[in,out] space tablespace where created @param[in] index_id index id @param[in] index index, or NULL to create a system table @param[in,out] mtr mini-transaction @param[out] err error code @return page number of the created root @retval FIL_NULL if did not succeed */ uint32_t btr_create( ulint type, fil_space_t* space, index_id_t index_id, dict_index_t* index, mtr_t* mtr, dberr_t* err) MY_ATTRIBUTE((nonnull(2,5,6), warn_unused_result)); /** Free a persistent index tree if it exists. @param[in,out] space tablespce @param[in] page root page number @param[in] index_id PAGE_INDEX_ID contents @param[in,out] mtr mini-transaction */ void btr_free_if_exists(fil_space_t *space, uint32_t page, index_id_t index_id, mtr_t *mtr); /** Drop a temporary table @param table temporary table */ void btr_drop_temporary_table(const dict_table_t &table); /** Read the last used AUTO_INCREMENT value from PAGE_ROOT_AUTO_INC. @param[in,out] index clustered index @return the last used AUTO_INCREMENT value @retval 0 on error or if no AUTO_INCREMENT value was used yet */ ib_uint64_t btr_read_autoinc(dict_index_t* index) MY_ATTRIBUTE((nonnull, warn_unused_result)); /** Read the last used AUTO_INCREMENT value from PAGE_ROOT_AUTO_INC, or fall back to MAX(auto_increment_column). @param[in] table table containing an AUTO_INCREMENT column @param[in] col_no index of the AUTO_INCREMENT column @return the AUTO_INCREMENT value @retval 0 on error or if no AUTO_INCREMENT value was used yet */ ib_uint64_t btr_read_autoinc_with_fallback(const dict_table_t* table, unsigned col_no) MY_ATTRIBUTE((nonnull, warn_unused_result)); /** Write the next available AUTO_INCREMENT value to PAGE_ROOT_AUTO_INC. @param[in,out] index clustered index @param[in] autoinc the AUTO_INCREMENT value @param[in] reset whether to reset the AUTO_INCREMENT to a possibly smaller value than currently exists in the page */ void btr_write_autoinc(dict_index_t* index, ib_uint64_t autoinc, bool reset = false) MY_ATTRIBUTE((nonnull)); /** Write instant ALTER TABLE metadata to a root page. @param[in,out] root clustered index root page @param[in] index clustered index with instant ALTER TABLE @param[in,out] mtr mini-transaction */ void btr_set_instant(buf_block_t* root, const dict_index_t& index, mtr_t* mtr); ATTRIBUTE_COLD __attribute__((nonnull, warn_unused_result)) /** Reset the table to the canonical format on ROLLBACK of instant ALTER TABLE. @param[in] index clustered index with instant ALTER TABLE @param[in] all whether to reset FIL_PAGE_TYPE as well @param[in,out] mtr mini-transaction @return error code */ dberr_t btr_reset_instant(const dict_index_t &index, bool all, mtr_t *mtr); /*************************************************************//** Makes tree one level higher by splitting the root, and inserts the tuple. It is assumed that mtr contains an x-latch on the tree. NOTE that the operation of this function must always succeed, we cannot reverse it: therefore enough free disk space must be guaranteed to be available before this function is called. @return inserted record */ rec_t* btr_root_raise_and_insert( /*======================*/ ulint flags, /*!< in: undo logging and locking flags */ btr_cur_t* cursor, /*!< in: cursor at which to insert: must be on the root page; when the function returns, the cursor is positioned on the predecessor of the inserted record */ rec_offs** offsets,/*!< out: offsets on inserted record */ mem_heap_t** heap, /*!< in/out: pointer to memory heap that can be emptied, or NULL */ const dtuple_t* tuple, /*!< in: tuple to insert */ ulint n_ext, /*!< in: number of externally stored columns */ mtr_t* mtr, /*!< in: mtr */ dberr_t* err) /*!< out: error code */ MY_ATTRIBUTE((warn_unused_result)); /*************************************************************//** Reorganizes an index page. IMPORTANT: On success, the caller will have to update IBUF_BITMAP_FREE if this is a compressed leaf page in a secondary index. This has to be done either within the same mini-transaction, or by invoking ibuf_reset_free_bits() before mtr_commit(). On uncompressed pages, IBUF_BITMAP_FREE is unaffected by reorganization. @param cursor page cursor @param mtr mini-transaction @return error code @retval DB_FAIL if reorganizing a ROW_FORMAT=COMPRESSED page failed */ dberr_t btr_page_reorganize(page_cur_t *cursor, mtr_t *mtr) MY_ATTRIBUTE((nonnull, warn_unused_result)); /** Decide if the page should be split at the convergence point of inserts converging to the left. @param[in] cursor insert position @return the first record to be moved to the right half page @retval NULL if no split is recommended */ rec_t* btr_page_get_split_rec_to_left(const btr_cur_t* cursor); /** Decide if the page should be split at the convergence point of inserts converging to the right. @param[in] cursor insert position @param[out] split_rec if split recommended, the first record on the right half page, or NULL if the to-be-inserted record should be first @return whether split is recommended */ bool btr_page_get_split_rec_to_right(const btr_cur_t* cursor, rec_t** split_rec); /*************************************************************//** Splits an index page to halves and inserts the tuple. It is assumed that mtr holds an x-latch to the index tree. NOTE: the tree x-latch is released within this function! NOTE that the operation of this function must always succeed, we cannot reverse it: therefore enough free disk space (2 pages) must be guaranteed to be available before this function is called. @return inserted record */ rec_t* btr_page_split_and_insert( /*======================*/ ulint flags, /*!< in: undo logging and locking flags */ btr_cur_t* cursor, /*!< in: cursor at which to insert; when the function returns, the cursor is positioned on the predecessor of the inserted record */ rec_offs** offsets,/*!< out: offsets on inserted record */ mem_heap_t** heap, /*!< in/out: pointer to memory heap that can be emptied, or NULL */ const dtuple_t* tuple, /*!< in: tuple to insert */ ulint n_ext, /*!< in: number of externally stored columns */ mtr_t* mtr, /*!< in: mtr */ dberr_t* err) /*!< out: error code */ MY_ATTRIBUTE((nonnull, warn_unused_result)); /*******************************************************//** Inserts a data tuple to a tree on a non-leaf level. It is assumed that mtr holds an x-latch on the tree. */ dberr_t btr_insert_on_non_leaf_level( ulint flags, /*!< in: undo logging and locking flags */ dict_index_t* index, /*!< in: index */ ulint level, /*!< in: level, must be > 0 */ dtuple_t* tuple, /*!< in: the record to be inserted */ mtr_t* mtr) /*!< in: mtr */ MY_ATTRIBUTE((nonnull, warn_unused_result)); /** Set a child page pointer record as the predefined minimum record. @tparam has_prev whether the page is supposed to have a left sibling @param[in,out] rec leftmost record on a leftmost non-leaf page @param[in,out] block buffer pool block @param[in,out] mtr mini-transaction */ template inline void btr_set_min_rec_mark(rec_t *rec, const buf_block_t &block, mtr_t *mtr) { ut_ad(block.page.frame == page_align(rec)); ut_ad(!page_is_leaf(block.page.frame)); ut_ad(has_prev == page_has_prev(block.page.frame)); rec-= page_rec_is_comp(rec) ? REC_NEW_INFO_BITS : REC_OLD_INFO_BITS; if (block.page.zip.data) /* This flag is computed from other contents on a ROW_FORMAT=COMPRESSED page. We are not modifying the compressed page frame at all. */ *rec|= REC_INFO_MIN_REC_FLAG; else mtr->write<1>(block, rec, *rec | REC_INFO_MIN_REC_FLAG); } /** Seek to the parent page of a B-tree page. @param[in,out] mtr mini-transaction @param[in,out] cursor cursor pointing to the x-latched parent page @return whether the cursor was successfully positioned */ bool btr_page_get_father(mtr_t* mtr, btr_cur_t* cursor) MY_ATTRIBUTE((nonnull,warn_unused_result)); #ifdef UNIV_DEBUG /************************************************************//** Checks that the node pointer to a page is appropriate. @return TRUE */ ibool btr_check_node_ptr( /*===============*/ dict_index_t* index, /*!< in: index tree */ buf_block_t* block, /*!< in: index page */ mtr_t* mtr) /*!< in: mtr */ MY_ATTRIBUTE((warn_unused_result)); #endif /* UNIV_DEBUG */ /*************************************************************//** Tries to merge the page first to the left immediate brother if such a brother exists, and the node pointers to the current page and to the brother reside on the same page. If the left brother does not satisfy these conditions, looks at the right brother. If the page is the only one on that level lifts the records of the page to the father page, thus reducing the tree height. It is assumed that mtr holds an x-latch on the tree and on the page. If cursor is on the leaf level, mtr must also hold x-latches to the brothers, if they exist. @return error code @retval DB_FAIL if the tree could not be merged */ dberr_t btr_compress( /*=========*/ btr_cur_t* cursor, /*!< in/out: cursor on the page to merge or lift; the page must not be empty: when deleting records, use btr_discard_page() if the page would become empty */ bool adjust, /*!< in: whether the cursor position should be adjusted even when compression occurs */ mtr_t* mtr) /*!< in/out: mini-transaction */ MY_ATTRIBUTE((nonnull, warn_unused_result)); /*************************************************************//** Discards a page from a B-tree. This is used to remove the last record from a B-tree page: the whole page must be removed at the same time. This cannot be used for the root page, which is allowed to be empty. */ dberr_t btr_discard_page( /*=============*/ btr_cur_t* cursor, /*!< in: cursor on the page to discard: not on the root page */ mtr_t* mtr); /*!< in: mtr */ /**************************************************************//** Allocates a new file page to be used in an index tree. NOTE: we assume that the caller has made the reservation for free extents! @retval NULL if no page could be allocated */ buf_block_t* btr_page_alloc( /*===========*/ dict_index_t* index, /*!< in: index tree */ uint32_t hint_page_no, /*!< in: hint of a good page */ byte file_direction, /*!< in: direction where a possible page split is made */ ulint level, /*!< in: level where the page is placed in the tree */ mtr_t* mtr, /*!< in/out: mini-transaction for the allocation */ mtr_t* init_mtr, /*!< in/out: mini-transaction for x-latching and initializing the page */ dberr_t* err) /*!< out: error code */ MY_ATTRIBUTE((warn_unused_result)); /** Empty an index page (possibly the root page). @see btr_page_create(). @param[in,out] block page to be emptied @param[in,out] page_zip compressed page frame, or NULL @param[in] index index of the page @param[in] level B-tree level of the page (0=leaf) @param[in,out] mtr mini-transaction */ void btr_page_empty( buf_block_t* block, page_zip_des_t* page_zip, dict_index_t* index, ulint level, mtr_t* mtr) MY_ATTRIBUTE((nonnull(1, 3, 5))); /**************************************************************//** Creates a new index page (not the root, and also not used in page reorganization). @see btr_page_empty(). */ void btr_page_create( /*============*/ buf_block_t* block, /*!< in/out: page to be created */ page_zip_des_t* page_zip,/*!< in/out: compressed page, or NULL */ dict_index_t* index, /*!< in: index */ ulint level, /*!< in: the B-tree level of the page */ mtr_t* mtr); /*!< in: mtr */ /** Free an index page. @param[in,out] index index tree @param[in,out] block block to be freed @param[in,out] mtr mini-transaction @param[in] blob whether this is freeing a BLOB page @param[in] latched whether index->table->space->x_lock() was called */ MY_ATTRIBUTE((nonnull)) dberr_t btr_page_free(dict_index_t *index, buf_block_t *block, mtr_t *mtr, bool blob= false, bool space_latched= false); /**************************************************************//** Gets the root node of a tree and x- or s-latches it. @return root page, x- or s-latched */ buf_block_t* btr_root_block_get( /*===============*/ const dict_index_t* index, /*!< in: index tree */ rw_lock_type_t mode, /*!< in: either RW_S_LATCH or RW_X_LATCH */ mtr_t* mtr, /*!< in: mtr */ dberr_t* err); /*!< out: error code */ /*************************************************************//** Reorganizes an index page. IMPORTANT: On success, the caller will have to update IBUF_BITMAP_FREE if this is a compressed leaf page in a secondary index. This has to be done either within the same mini-transaction, or by invoking ibuf_reset_free_bits() before mtr_commit(). On uncompressed pages, IBUF_BITMAP_FREE is unaffected by reorganization. @return error code @retval DB_FAIL if reorganizing a ROW_FORMAT=COMPRESSED page failed */ dberr_t btr_page_reorganize_block( ulint z_level,/*!< in: compression level to be used if dealing with compressed page */ buf_block_t* block, /*!< in/out: B-tree page */ dict_index_t* index, /*!< in: the index tree of the page */ mtr_t* mtr) /*!< in/out: mini-transaction */ __attribute__((nonnull, warn_unused_result)); #ifdef UNIV_BTR_PRINT /*************************************************************//** Prints size info of a B-tree. */ void btr_print_size( /*===========*/ dict_index_t* index) /*!< in: index tree */ MY_ATTRIBUTE((nonnull)); /**************************************************************//** Prints directories and other info of all nodes in the index. */ void btr_print_index( /*============*/ dict_index_t* index, /*!< in: index */ ulint width) /*!< in: print this many entries from start and end */ MY_ATTRIBUTE((nonnull)); #endif /* UNIV_BTR_PRINT */ /************************************************************//** Checks the size and number of fields in a record based on the definition of the index. @return TRUE if ok */ ibool btr_index_rec_validate( /*===================*/ const rec_t* rec, /*!< in: index record */ const dict_index_t* index, /*!< in: index */ ibool dump_on_error) /*!< in: TRUE if the function should print hex dump of record and page on error */ MY_ATTRIBUTE((warn_unused_result)); /**************************************************************//** Checks the consistency of an index tree. @return DB_SUCCESS if ok, error code if not */ dberr_t btr_validate_index( /*===============*/ dict_index_t* index, /*!< in: index */ const trx_t* trx) /*!< in: transaction or 0 */ MY_ATTRIBUTE((warn_unused_result)); /** Remove a page from the level list of pages. @param[in] block page to remove @param[in] index index tree @param[in,out] mtr mini-transaction */ dberr_t btr_level_list_remove(const buf_block_t& block, const dict_index_t& index, mtr_t* mtr) MY_ATTRIBUTE((warn_unused_result)); /*************************************************************//** If page is the only on its level, this function moves its records to the father page, thus reducing the tree height. @return father block */ buf_block_t* btr_lift_page_up( dict_index_t* index, /*!< in: index tree */ buf_block_t* block, /*!< in: page which is the only on its level; must not be empty: use btr_discard_only_page_on_level if the last record from the page should be removed */ mtr_t* mtr, /*!< in/out: mini-transaction */ dberr_t* err) /*!< out: error code */ __attribute__((nonnull)); #define BTR_N_LEAF_PAGES 1 #define BTR_TOTAL_SIZE 2 #include "btr0btr.inl" /**************************************************************** Global variable controlling if scrubbing should be performed */ extern my_bool srv_immediate_scrub_data_uncompressed;