/***************************************************************************** Copyright (c) 1995, 2009, Innobase Oy. All Rights Reserved. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; version 2 of the License. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA *****************************************************************************/ /******************************************************************//** @file fsp/fsp0fsp.c File space management Created 11/29/1995 Heikki Tuuri ***********************************************************************/ #include "fsp0fsp.h" #ifdef UNIV_NONINL #include "fsp0fsp.ic" #endif #include "buf0buf.h" #include "fil0fil.h" #include "mtr0log.h" #include "ut0byte.h" #include "page0page.h" #include "page0zip.h" #ifdef UNIV_HOTBACKUP # include "fut0lst.h" #else /* UNIV_HOTBACKUP */ # include "sync0sync.h" # include "fut0fut.h" # include "srv0srv.h" # include "ibuf0ibuf.h" # include "btr0btr.h" # include "btr0sea.h" # include "dict0boot.h" # include "log0log.h" #endif /* UNIV_HOTBACKUP */ #include "dict0mem.h" #define FSP_HEADER_OFFSET FIL_PAGE_DATA /* Offset of the space header within a file page */ /* The data structures in files are defined just as byte strings in C */ typedef byte fsp_header_t; typedef byte xdes_t; /* SPACE HEADER ============ File space header data structure: this data structure is contained in the first page of a space. The space for this header is reserved in every extent descriptor page, but used only in the first. */ /*-------------------------------------*/ #define FSP_SPACE_ID 0 /* space id */ #define FSP_NOT_USED 4 /* this field contained a value up to which we know that the modifications in the database have been flushed to the file space; not used now */ #define FSP_SIZE 8 /* Current size of the space in pages */ #define FSP_FREE_LIMIT 12 /* Minimum page number for which the free list has not been initialized: the pages >= this limit are, by definition, free; note that in a single-table tablespace where size < 64 pages, this number is 64, i.e., we have initialized the space about the first extent, but have not physically allocted those pages to the file */ #define FSP_SPACE_FLAGS 16 /* table->flags & ~DICT_TF_COMPACT */ #define FSP_FRAG_N_USED 20 /* number of used pages in the FSP_FREE_FRAG list */ #define FSP_FREE 24 /* list of free extents */ #define FSP_FREE_FRAG (24 + FLST_BASE_NODE_SIZE) /* list of partially free extents not belonging to any segment */ #define FSP_FULL_FRAG (24 + 2 * FLST_BASE_NODE_SIZE) /* list of full extents not belonging to any segment */ #define FSP_SEG_ID (24 + 3 * FLST_BASE_NODE_SIZE) /* 8 bytes which give the first unused segment id */ #define FSP_SEG_INODES_FULL (32 + 3 * FLST_BASE_NODE_SIZE) /* list of pages containing segment headers, where all the segment inode slots are reserved */ #define FSP_SEG_INODES_FREE (32 + 4 * FLST_BASE_NODE_SIZE) /* list of pages containing segment headers, where not all the segment header slots are reserved */ /*-------------------------------------*/ /* File space header size */ #define FSP_HEADER_SIZE (32 + 5 * FLST_BASE_NODE_SIZE) #define FSP_FREE_ADD 4 /* this many free extents are added to the free list from above FSP_FREE_LIMIT at a time */ /* FILE SEGMENT INODE ================== Segment inode which is created for each segment in a tablespace. NOTE: in purge we assume that a segment having only one currently used page can be freed in a few steps, so that the freeing cannot fill the file buffer with bufferfixed file pages. */ typedef byte fseg_inode_t; #define FSEG_INODE_PAGE_NODE FSEG_PAGE_DATA /* the list node for linking segment inode pages */ #define FSEG_ARR_OFFSET (FSEG_PAGE_DATA + FLST_NODE_SIZE) /*-------------------------------------*/ #define FSEG_ID 0 /* 8 bytes of segment id: if this is ut_dulint_zero, it means that the header is unused */ #define FSEG_NOT_FULL_N_USED 8 /* number of used segment pages in the FSEG_NOT_FULL list */ #define FSEG_FREE 12 /* list of free extents of this segment */ #define FSEG_NOT_FULL (12 + FLST_BASE_NODE_SIZE) /* list of partially free extents */ #define FSEG_FULL (12 + 2 * FLST_BASE_NODE_SIZE) /* list of full extents */ #define FSEG_MAGIC_N (12 + 3 * FLST_BASE_NODE_SIZE) /* magic number used in debugging */ #define FSEG_FRAG_ARR (16 + 3 * FLST_BASE_NODE_SIZE) /* array of individual pages belonging to this segment in fsp fragment extent lists */ #define FSEG_FRAG_ARR_N_SLOTS (FSP_EXTENT_SIZE / 2) /* number of slots in the array for the fragment pages */ #define FSEG_FRAG_SLOT_SIZE 4 /* a fragment page slot contains its page number within space, FIL_NULL means that the slot is not in use */ /*-------------------------------------*/ #define FSEG_INODE_SIZE \ (16 + 3 * FLST_BASE_NODE_SIZE \ + FSEG_FRAG_ARR_N_SLOTS * FSEG_FRAG_SLOT_SIZE) #define FSP_SEG_INODES_PER_PAGE(zip_size) \ (((zip_size ? zip_size : UNIV_PAGE_SIZE) \ - FSEG_ARR_OFFSET - 10) / FSEG_INODE_SIZE) /* Number of segment inodes which fit on a single page */ #define FSEG_MAGIC_N_VALUE 97937874 #define FSEG_FILLFACTOR 8 /* If this value is x, then if the number of unused but reserved pages in a segment is less than reserved pages * 1/x, and there are at least FSEG_FRAG_LIMIT used pages, then we allow a new empty extent to be added to the segment in fseg_alloc_free_page. Otherwise, we use unused pages of the segment. */ #define FSEG_FRAG_LIMIT FSEG_FRAG_ARR_N_SLOTS /* If the segment has >= this many used pages, it may be expanded by allocating extents to the segment; until that only individual fragment pages are allocated from the space */ #define FSEG_FREE_LIST_LIMIT 40 /* If the reserved size of a segment is at least this many extents, we allow extents to be put to the free list of the extent: at most FSEG_FREE_LIST_MAX_LEN many */ #define FSEG_FREE_LIST_MAX_LEN 4 /* EXTENT DESCRIPTOR ================= File extent descriptor data structure: contains bits to tell which pages in the extent are free and which contain old tuple version to clean. */ /*-------------------------------------*/ #define XDES_ID 0 /* The identifier of the segment to which this extent belongs */ #define XDES_FLST_NODE 8 /* The list node data structure for the descriptors */ #define XDES_STATE (FLST_NODE_SIZE + 8) /* contains state information of the extent */ #define XDES_BITMAP (FLST_NODE_SIZE + 12) /* Descriptor bitmap of the pages in the extent */ /*-------------------------------------*/ #define XDES_BITS_PER_PAGE 2 /* How many bits are there per page */ #define XDES_FREE_BIT 0 /* Index of the bit which tells if the page is free */ #define XDES_CLEAN_BIT 1 /* NOTE: currently not used! Index of the bit which tells if there are old versions of tuples on the page */ /* States of a descriptor */ #define XDES_FREE 1 /* extent is in free list of space */ #define XDES_FREE_FRAG 2 /* extent is in free fragment list of space */ #define XDES_FULL_FRAG 3 /* extent is in full fragment list of space */ #define XDES_FSEG 4 /* extent belongs to a segment */ /* File extent data structure size in bytes. */ #define XDES_SIZE \ (XDES_BITMAP + UT_BITS_IN_BYTES(FSP_EXTENT_SIZE * XDES_BITS_PER_PAGE)) /* Offset of the descriptor array on a descriptor page */ #define XDES_ARR_OFFSET (FSP_HEADER_OFFSET + FSP_HEADER_SIZE) #ifndef UNIV_HOTBACKUP /**********************************************************************//** Returns an extent to the free list of a space. */ static void fsp_free_extent( /*============*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset in the extent */ mtr_t* mtr); /*!< in: mtr */ /**********************************************************************//** Frees an extent of a segment to the space free list. */ static void fseg_free_extent( /*=============*/ fseg_inode_t* seg_inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset in the extent */ mtr_t* mtr); /*!< in: mtr handle */ /**********************************************************************//** Calculates the number of pages reserved by a segment, and how many pages are currently used. @return number of reserved pages */ static ulint fseg_n_reserved_pages_low( /*======================*/ fseg_inode_t* header, /*!< in: segment inode */ ulint* used, /*!< out: number of pages used (not more than reserved) */ mtr_t* mtr); /*!< in: mtr handle */ /********************************************************************//** Marks a page used. The page must reside within the extents of the given segment. */ static void fseg_mark_page_used( /*================*/ fseg_inode_t* seg_inode,/*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset */ mtr_t* mtr); /*!< in: mtr */ /**********************************************************************//** Returns the first extent descriptor for a segment. We think of the extent lists of the segment catenated in the order FSEG_FULL -> FSEG_NOT_FULL -> FSEG_FREE. @return the first extent descriptor, or NULL if none */ static xdes_t* fseg_get_first_extent( /*==================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ mtr_t* mtr); /*!< in: mtr */ /**********************************************************************//** Puts new extents to the free list if there are free extents above the free limit. If an extent happens to contain an extent descriptor page, the extent is put to the FSP_FREE_FRAG list with the page marked as used. */ static void fsp_fill_free_list( /*===============*/ ibool init_space, /*!< in: TRUE if this is a single-table tablespace and we are only initing the tablespace's first extent descriptor page and ibuf bitmap page; then we do not allocate more extents */ ulint space, /*!< in: space */ fsp_header_t* header, /*!< in: space header */ mtr_t* mtr); /*!< in: mtr */ /**********************************************************************//** Allocates a single free page from a segment. This function implements the intelligent allocation strategy which tries to minimize file space fragmentation. @return the allocated page number, FIL_NULL if no page could be allocated */ static ulint fseg_alloc_free_page_low( /*=====================*/ ulint space, /*!< in: space */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ fseg_inode_t* seg_inode, /*!< in: segment inode */ ulint hint, /*!< in: hint of which page would be desirable */ byte direction, /*!< in: if the new page is needed because of an index page split, and records are inserted there in order, into which direction they go alphabetically: FSP_DOWN, FSP_UP, FSP_NO_DIR */ mtr_t* mtr); /*!< in: mtr handle */ #endif /* !UNIV_HOTBACKUP */ /**********************************************************************//** Reads the file space size stored in the header page. @return tablespace size stored in the space header */ UNIV_INTERN ulint fsp_get_size_low( /*=============*/ page_t* page) /*!< in: header page (page 0 in the tablespace) */ { return(mach_read_from_4(page + FSP_HEADER_OFFSET + FSP_SIZE)); } #ifndef UNIV_HOTBACKUP /**********************************************************************//** Gets a pointer to the space header and x-locks its page. @return pointer to the space header, page x-locked */ UNIV_INLINE fsp_header_t* fsp_get_space_header( /*=================*/ ulint id, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ mtr_t* mtr) /*!< in: mtr */ { buf_block_t* block; fsp_header_t* header; ut_ad(ut_is_2pow(zip_size)); ut_ad(zip_size <= UNIV_PAGE_SIZE); ut_ad(!zip_size || zip_size >= PAGE_ZIP_MIN_SIZE); ut_ad(id || !zip_size); block = buf_page_get(id, zip_size, 0, RW_X_LATCH, mtr); header = FSP_HEADER_OFFSET + buf_block_get_frame(block); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); ut_ad(id == mach_read_from_4(FSP_SPACE_ID + header)); ut_ad(zip_size == dict_table_flags_to_zip_size( mach_read_from_4(FSP_SPACE_FLAGS + header))); return(header); } /**********************************************************************//** Gets a descriptor bit of a page. @return TRUE if free */ UNIV_INLINE ibool xdes_get_bit( /*=========*/ xdes_t* descr, /*!< in: descriptor */ ulint bit, /*!< in: XDES_FREE_BIT or XDES_CLEAN_BIT */ ulint offset, /*!< in: page offset within extent: 0 ... FSP_EXTENT_SIZE - 1 */ mtr_t* mtr) /*!< in: mtr */ { ulint index; ulint byte_index; ulint bit_index; ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); ut_ad((bit == XDES_FREE_BIT) || (bit == XDES_CLEAN_BIT)); ut_ad(offset < FSP_EXTENT_SIZE); index = bit + XDES_BITS_PER_PAGE * offset; byte_index = index / 8; bit_index = index % 8; return(ut_bit_get_nth(mtr_read_ulint(descr + XDES_BITMAP + byte_index, MLOG_1BYTE, mtr), bit_index)); } /**********************************************************************//** Sets a descriptor bit of a page. */ UNIV_INLINE void xdes_set_bit( /*=========*/ xdes_t* descr, /*!< in: descriptor */ ulint bit, /*!< in: XDES_FREE_BIT or XDES_CLEAN_BIT */ ulint offset, /*!< in: page offset within extent: 0 ... FSP_EXTENT_SIZE - 1 */ ibool val, /*!< in: bit value */ mtr_t* mtr) /*!< in: mtr */ { ulint index; ulint byte_index; ulint bit_index; ulint descr_byte; ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); ut_ad((bit == XDES_FREE_BIT) || (bit == XDES_CLEAN_BIT)); ut_ad(offset < FSP_EXTENT_SIZE); index = bit + XDES_BITS_PER_PAGE * offset; byte_index = index / 8; bit_index = index % 8; descr_byte = mtr_read_ulint(descr + XDES_BITMAP + byte_index, MLOG_1BYTE, mtr); descr_byte = ut_bit_set_nth(descr_byte, bit_index, val); mlog_write_ulint(descr + XDES_BITMAP + byte_index, descr_byte, MLOG_1BYTE, mtr); } /**********************************************************************//** Looks for a descriptor bit having the desired value. Starts from hint and scans upward; at the end of the extent the search is wrapped to the start of the extent. @return bit index of the bit, ULINT_UNDEFINED if not found */ UNIV_INLINE ulint xdes_find_bit( /*==========*/ xdes_t* descr, /*!< in: descriptor */ ulint bit, /*!< in: XDES_FREE_BIT or XDES_CLEAN_BIT */ ibool val, /*!< in: desired bit value */ ulint hint, /*!< in: hint of which bit position would be desirable */ mtr_t* mtr) /*!< in: mtr */ { ulint i; ut_ad(descr && mtr); ut_ad(val <= TRUE); ut_ad(hint < FSP_EXTENT_SIZE); ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); for (i = hint; i < FSP_EXTENT_SIZE; i++) { if (val == xdes_get_bit(descr, bit, i, mtr)) { return(i); } } for (i = 0; i < hint; i++) { if (val == xdes_get_bit(descr, bit, i, mtr)) { return(i); } } return(ULINT_UNDEFINED); } /**********************************************************************//** Looks for a descriptor bit having the desired value. Scans the extent in a direction opposite to xdes_find_bit. @return bit index of the bit, ULINT_UNDEFINED if not found */ UNIV_INLINE ulint xdes_find_bit_downward( /*===================*/ xdes_t* descr, /*!< in: descriptor */ ulint bit, /*!< in: XDES_FREE_BIT or XDES_CLEAN_BIT */ ibool val, /*!< in: desired bit value */ ulint hint, /*!< in: hint of which bit position would be desirable */ mtr_t* mtr) /*!< in: mtr */ { ulint i; ut_ad(descr && mtr); ut_ad(val <= TRUE); ut_ad(hint < FSP_EXTENT_SIZE); ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); for (i = hint + 1; i > 0; i--) { if (val == xdes_get_bit(descr, bit, i - 1, mtr)) { return(i - 1); } } for (i = FSP_EXTENT_SIZE - 1; i > hint; i--) { if (val == xdes_get_bit(descr, bit, i, mtr)) { return(i); } } return(ULINT_UNDEFINED); } /**********************************************************************//** Returns the number of used pages in a descriptor. @return number of pages used */ UNIV_INLINE ulint xdes_get_n_used( /*============*/ xdes_t* descr, /*!< in: descriptor */ mtr_t* mtr) /*!< in: mtr */ { ulint i; ulint count = 0; ut_ad(descr && mtr); ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); for (i = 0; i < FSP_EXTENT_SIZE; i++) { if (FALSE == xdes_get_bit(descr, XDES_FREE_BIT, i, mtr)) { count++; } } return(count); } /**********************************************************************//** Returns true if extent contains no used pages. @return TRUE if totally free */ UNIV_INLINE ibool xdes_is_free( /*=========*/ xdes_t* descr, /*!< in: descriptor */ mtr_t* mtr) /*!< in: mtr */ { if (0 == xdes_get_n_used(descr, mtr)) { return(TRUE); } return(FALSE); } /**********************************************************************//** Returns true if extent contains no free pages. @return TRUE if full */ UNIV_INLINE ibool xdes_is_full( /*=========*/ xdes_t* descr, /*!< in: descriptor */ mtr_t* mtr) /*!< in: mtr */ { if (FSP_EXTENT_SIZE == xdes_get_n_used(descr, mtr)) { return(TRUE); } return(FALSE); } /**********************************************************************//** Sets the state of an xdes. */ UNIV_INLINE void xdes_set_state( /*===========*/ xdes_t* descr, /*!< in: descriptor */ ulint state, /*!< in: state to set */ mtr_t* mtr) /*!< in: mtr handle */ { ut_ad(descr && mtr); ut_ad(state >= XDES_FREE); ut_ad(state <= XDES_FSEG); ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); mlog_write_ulint(descr + XDES_STATE, state, MLOG_4BYTES, mtr); } /**********************************************************************//** Gets the state of an xdes. @return state */ UNIV_INLINE ulint xdes_get_state( /*===========*/ xdes_t* descr, /*!< in: descriptor */ mtr_t* mtr) /*!< in: mtr handle */ { ulint state; ut_ad(descr && mtr); ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); state = mtr_read_ulint(descr + XDES_STATE, MLOG_4BYTES, mtr); ut_ad(state - 1 < XDES_FSEG); return(state); } /**********************************************************************//** Inits an extent descriptor to the free and clean state. */ UNIV_INLINE void xdes_init( /*======*/ xdes_t* descr, /*!< in: descriptor */ mtr_t* mtr) /*!< in: mtr */ { ulint i; ut_ad(descr && mtr); ut_ad(mtr_memo_contains_page(mtr, descr, MTR_MEMO_PAGE_X_FIX)); ut_ad((XDES_SIZE - XDES_BITMAP) % 4 == 0); for (i = XDES_BITMAP; i < XDES_SIZE; i += 4) { mlog_write_ulint(descr + i, 0xFFFFFFFFUL, MLOG_4BYTES, mtr); } xdes_set_state(descr, XDES_FREE, mtr); } /********************************************************************//** Calculates the page where the descriptor of a page resides. @return descriptor page offset */ UNIV_INLINE ulint xdes_calc_descriptor_page( /*======================*/ ulint zip_size, /*!< in: compressed page size in bytes; 0 for uncompressed pages */ ulint offset) /*!< in: page offset */ { #ifndef DOXYGEN /* Doxygen gets confused of these */ # if UNIV_PAGE_SIZE <= XDES_ARR_OFFSET \ + (UNIV_PAGE_SIZE / FSP_EXTENT_SIZE) * XDES_SIZE # error # endif # if PAGE_ZIP_MIN_SIZE <= XDES_ARR_OFFSET \ + (PAGE_ZIP_MIN_SIZE / FSP_EXTENT_SIZE) * XDES_SIZE # error # endif #endif /* !DOXYGEN */ ut_ad(ut_is_2pow(zip_size)); if (!zip_size) { return(ut_2pow_round(offset, UNIV_PAGE_SIZE)); } else { ut_ad(zip_size > XDES_ARR_OFFSET + (zip_size / FSP_EXTENT_SIZE) * XDES_SIZE); return(ut_2pow_round(offset, zip_size)); } } /********************************************************************//** Calculates the descriptor index within a descriptor page. @return descriptor index */ UNIV_INLINE ulint xdes_calc_descriptor_index( /*=======================*/ ulint zip_size, /*!< in: compressed page size in bytes; 0 for uncompressed pages */ ulint offset) /*!< in: page offset */ { ut_ad(ut_is_2pow(zip_size)); if (!zip_size) { return(ut_2pow_remainder(offset, UNIV_PAGE_SIZE) / FSP_EXTENT_SIZE); } else { return(ut_2pow_remainder(offset, zip_size) / FSP_EXTENT_SIZE); } } /********************************************************************//** Gets pointer to a the extent descriptor of a page. The page where the extent descriptor resides is x-locked. If the page offset is equal to the free limit of the space, adds new extents from above the free limit to the space free list, if not free limit == space size. This adding is necessary to make the descriptor defined, as they are uninitialized above the free limit. @return pointer to the extent descriptor, NULL if the page does not exist in the space or if the offset exceeds the free limit */ UNIV_INLINE xdes_t* xdes_get_descriptor_with_space_hdr( /*===============================*/ fsp_header_t* sp_header,/*!< in: space header, x-latched */ ulint space, /*!< in: space id */ ulint offset, /*!< in: page offset; if equal to the free limit, we try to add new extents to the space free list */ mtr_t* mtr) /*!< in: mtr handle */ { ulint limit; ulint size; ulint zip_size; ulint descr_page_no; page_t* descr_page; ut_ad(mtr); ut_ad(mtr_memo_contains(mtr, fil_space_get_latch(space, NULL), MTR_MEMO_X_LOCK)); ut_ad(mtr_memo_contains_page(mtr, sp_header, MTR_MEMO_PAGE_S_FIX) || mtr_memo_contains_page(mtr, sp_header, MTR_MEMO_PAGE_X_FIX)); ut_ad(page_offset(sp_header) == FSP_HEADER_OFFSET); /* Read free limit and space size */ limit = mach_read_from_4(sp_header + FSP_FREE_LIMIT); size = mach_read_from_4(sp_header + FSP_SIZE); zip_size = dict_table_flags_to_zip_size( mach_read_from_4(sp_header + FSP_SPACE_FLAGS)); /* If offset is >= size or > limit, return NULL */ if ((offset >= size) || (offset > limit)) { return(NULL); } /* If offset is == limit, fill free list of the space. */ if (offset == limit) { fsp_fill_free_list(FALSE, space, sp_header, mtr); } descr_page_no = xdes_calc_descriptor_page(zip_size, offset); if (descr_page_no == 0) { /* It is on the space header page */ descr_page = page_align(sp_header); } else { buf_block_t* block; block = buf_page_get(space, zip_size, descr_page_no, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); descr_page = buf_block_get_frame(block); } return(descr_page + XDES_ARR_OFFSET + XDES_SIZE * xdes_calc_descriptor_index(zip_size, offset)); } /********************************************************************//** Gets pointer to a the extent descriptor of a page. The page where the extent descriptor resides is x-locked. If the page offset is equal to the free limit of the space, adds new extents from above the free limit to the space free list, if not free limit == space size. This adding is necessary to make the descriptor defined, as they are uninitialized above the free limit. @return pointer to the extent descriptor, NULL if the page does not exist in the space or if the offset exceeds the free limit */ static xdes_t* xdes_get_descriptor( /*================*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint offset, /*!< in: page offset; if equal to the free limit, we try to add new extents to the space free list */ mtr_t* mtr) /*!< in: mtr handle */ { buf_block_t* block; fsp_header_t* sp_header; block = buf_page_get(space, zip_size, 0, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); sp_header = FSP_HEADER_OFFSET + buf_block_get_frame(block); return(xdes_get_descriptor_with_space_hdr(sp_header, space, offset, mtr)); } /********************************************************************//** Gets pointer to a the extent descriptor if the file address of the descriptor list node is known. The page where the extent descriptor resides is x-locked. @return pointer to the extent descriptor */ UNIV_INLINE xdes_t* xdes_lst_get_descriptor( /*====================*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ fil_addr_t lst_node,/*!< in: file address of the list node contained in the descriptor */ mtr_t* mtr) /*!< in: mtr handle */ { xdes_t* descr; ut_ad(mtr); ut_ad(mtr_memo_contains(mtr, fil_space_get_latch(space, NULL), MTR_MEMO_X_LOCK)); descr = fut_get_ptr(space, zip_size, lst_node, RW_X_LATCH, mtr) - XDES_FLST_NODE; return(descr); } /********************************************************************//** Returns page offset of the first page in extent described by a descriptor. @return offset of the first page in extent */ UNIV_INLINE ulint xdes_get_offset( /*============*/ xdes_t* descr) /*!< in: extent descriptor */ { ut_ad(descr); return(page_get_page_no(page_align(descr)) + ((page_offset(descr) - XDES_ARR_OFFSET) / XDES_SIZE) * FSP_EXTENT_SIZE); } #endif /* !UNIV_HOTBACKUP */ /***********************************************************//** Inits a file page whose prior contents should be ignored. */ static void fsp_init_file_page_low( /*===================*/ buf_block_t* block) /*!< in: pointer to a page */ { page_t* page = buf_block_get_frame(block); page_zip_des_t* page_zip= buf_block_get_page_zip(block); #ifndef UNIV_HOTBACKUP block->check_index_page_at_flush = FALSE; #endif /* !UNIV_HOTBACKUP */ if (UNIV_LIKELY_NULL(page_zip)) { memset(page, 0, UNIV_PAGE_SIZE); memset(page_zip->data, 0, page_zip_get_size(page_zip)); mach_write_to_4(page + FIL_PAGE_OFFSET, buf_block_get_page_no(block)); mach_write_to_4(page + FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID, buf_block_get_space(block)); memcpy(page_zip->data + FIL_PAGE_OFFSET, page + FIL_PAGE_OFFSET, 4); memcpy(page_zip->data + FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID, page + FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID, 4); return; } #ifdef UNIV_BASIC_LOG_DEBUG memset(page, 0xff, UNIV_PAGE_SIZE); #endif mach_write_to_4(page + FIL_PAGE_OFFSET, buf_block_get_page_no(block)); memset(page + FIL_PAGE_LSN, 0, 8); mach_write_to_4(page + FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID, buf_block_get_space(block)); memset(page + UNIV_PAGE_SIZE - FIL_PAGE_END_LSN_OLD_CHKSUM, 0, 8); } #ifndef UNIV_HOTBACKUP /***********************************************************//** Inits a file page whose prior contents should be ignored. */ static void fsp_init_file_page( /*===============*/ buf_block_t* block, /*!< in: pointer to a page */ mtr_t* mtr) /*!< in: mtr */ { fsp_init_file_page_low(block); mlog_write_initial_log_record(buf_block_get_frame(block), MLOG_INIT_FILE_PAGE, mtr); } #endif /* !UNIV_HOTBACKUP */ /***********************************************************//** Parses a redo log record of a file page init. @return end of log record or NULL */ UNIV_INTERN byte* fsp_parse_init_file_page( /*=====================*/ byte* ptr, /*!< in: buffer */ byte* end_ptr __attribute__((unused)), /*!< in: buffer end */ buf_block_t* block) /*!< in: block or NULL */ { ut_ad(ptr && end_ptr); if (block) { fsp_init_file_page_low(block); } return(ptr); } /**********************************************************************//** Initializes the fsp system. */ UNIV_INTERN void fsp_init(void) /*==========*/ { /* Does nothing at the moment */ } /**********************************************************************//** Writes the space id and compressed page size to a tablespace header. This function is used past the buffer pool when we in fil0fil.c create a new single-table tablespace. */ UNIV_INTERN void fsp_header_init_fields( /*===================*/ page_t* page, /*!< in/out: first page in the space */ ulint space_id, /*!< in: space id */ ulint flags) /*!< in: tablespace flags (FSP_SPACE_FLAGS): 0, or table->flags if newer than COMPACT */ { /* The tablespace flags (FSP_SPACE_FLAGS) should be 0 for ROW_FORMAT=COMPACT (table->flags == DICT_TF_COMPACT) and ROW_FORMAT=REDUNDANT (table->flags == 0). For any other format, the tablespace flags should equal table->flags. */ ut_a(flags != DICT_TF_COMPACT); mach_write_to_4(FSP_HEADER_OFFSET + FSP_SPACE_ID + page, space_id); mach_write_to_4(FSP_HEADER_OFFSET + FSP_SPACE_FLAGS + page, flags); } #ifndef UNIV_HOTBACKUP /**********************************************************************//** Initializes the space header of a new created space and creates also the insert buffer tree root if space == 0. */ UNIV_INTERN void fsp_header_init( /*============*/ ulint space, /*!< in: space id */ ulint size, /*!< in: current size in blocks */ mtr_t* mtr) /*!< in: mini-transaction handle */ { fsp_header_t* header; buf_block_t* block; page_t* page; ulint flags; ulint zip_size; ut_ad(mtr); mtr_x_lock(fil_space_get_latch(space, &flags), mtr); zip_size = dict_table_flags_to_zip_size(flags); block = buf_page_create(space, 0, zip_size, mtr); buf_page_get(space, zip_size, 0, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); /* The prior contents of the file page should be ignored */ fsp_init_file_page(block, mtr); page = buf_block_get_frame(block); mlog_write_ulint(page + FIL_PAGE_TYPE, FIL_PAGE_TYPE_FSP_HDR, MLOG_2BYTES, mtr); header = FSP_HEADER_OFFSET + page; mlog_write_ulint(header + FSP_SPACE_ID, space, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_NOT_USED, 0, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_SIZE, size, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_FREE_LIMIT, 0, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_SPACE_FLAGS, flags, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_FRAG_N_USED, 0, MLOG_4BYTES, mtr); flst_init(header + FSP_FREE, mtr); flst_init(header + FSP_FREE_FRAG, mtr); flst_init(header + FSP_FULL_FRAG, mtr); flst_init(header + FSP_SEG_INODES_FULL, mtr); flst_init(header + FSP_SEG_INODES_FREE, mtr); mlog_write_dulint(header + FSP_SEG_ID, ut_dulint_create(0, 1), mtr); if (space == 0) { fsp_fill_free_list(FALSE, space, header, mtr); btr_create(DICT_CLUSTERED | DICT_UNIVERSAL | DICT_IBUF, 0, 0, ut_dulint_add(DICT_IBUF_ID_MIN, space), dict_ind_redundant, mtr); } else { fsp_fill_free_list(TRUE, space, header, mtr); } } #endif /* !UNIV_HOTBACKUP */ /**********************************************************************//** Reads the space id from the first page of a tablespace. @return space id, ULINT UNDEFINED if error */ UNIV_INTERN ulint fsp_header_get_space_id( /*====================*/ const page_t* page) /*!< in: first page of a tablespace */ { ulint fsp_id; ulint id; fsp_id = mach_read_from_4(FSP_HEADER_OFFSET + page + FSP_SPACE_ID); id = mach_read_from_4(page + FIL_PAGE_ARCH_LOG_NO_OR_SPACE_ID); if (id != fsp_id) { fprintf(stderr, "InnoDB: Error: space id in fsp header %lu," " but in the page header %lu\n", (ulong) fsp_id, (ulong) id); return(ULINT_UNDEFINED); } return(id); } /**********************************************************************//** Reads the space flags from the first page of a tablespace. @return flags */ UNIV_INTERN ulint fsp_header_get_flags( /*=================*/ const page_t* page) /*!< in: first page of a tablespace */ { ut_ad(!page_offset(page)); return(mach_read_from_4(FSP_HEADER_OFFSET + FSP_SPACE_FLAGS + page)); } /**********************************************************************//** Reads the compressed page size from the first page of a tablespace. @return compressed page size in bytes, or 0 if uncompressed */ UNIV_INTERN ulint fsp_header_get_zip_size( /*====================*/ const page_t* page) /*!< in: first page of a tablespace */ { ulint flags = fsp_header_get_flags(page); return(dict_table_flags_to_zip_size(flags)); } #ifndef UNIV_HOTBACKUP /**********************************************************************//** Increases the space size field of a space. */ UNIV_INTERN void fsp_header_inc_size( /*================*/ ulint space, /*!< in: space id */ ulint size_inc,/*!< in: size increment in pages */ mtr_t* mtr) /*!< in: mini-transaction handle */ { fsp_header_t* header; ulint size; ulint flags; ut_ad(mtr); mtr_x_lock(fil_space_get_latch(space, &flags), mtr); header = fsp_get_space_header(space, dict_table_flags_to_zip_size(flags), mtr); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_SIZE, size + size_inc, MLOG_4BYTES, mtr); } /**********************************************************************//** Gets the current free limit of the system tablespace. The free limit means the place of the first page which has never been put to the the free list for allocation. The space above that address is initialized to zero. Sets also the global variable log_fsp_current_free_limit. @return free limit in megabytes */ UNIV_INTERN ulint fsp_header_get_free_limit(void) /*===========================*/ { fsp_header_t* header; ulint limit; mtr_t mtr; mtr_start(&mtr); mtr_x_lock(fil_space_get_latch(0, NULL), &mtr); header = fsp_get_space_header(0, 0, &mtr); limit = mtr_read_ulint(header + FSP_FREE_LIMIT, MLOG_4BYTES, &mtr); limit /= ((1024 * 1024) / UNIV_PAGE_SIZE); log_fsp_current_free_limit_set_and_checkpoint(limit); mtr_commit(&mtr); return(limit); } /**********************************************************************//** Gets the size of the system tablespace from the tablespace header. If we do not have an auto-extending data file, this should be equal to the size of the data files. If there is an auto-extending data file, this can be smaller. @return size in pages */ UNIV_INTERN ulint fsp_header_get_tablespace_size(void) /*================================*/ { fsp_header_t* header; ulint size; mtr_t mtr; mtr_start(&mtr); mtr_x_lock(fil_space_get_latch(0, NULL), &mtr); header = fsp_get_space_header(0, 0, &mtr); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, &mtr); mtr_commit(&mtr); return(size); } /***********************************************************************//** Tries to extend a single-table tablespace so that a page would fit in the data file. @return TRUE if success */ static ibool fsp_try_extend_data_file_with_pages( /*================================*/ ulint space, /*!< in: space */ ulint page_no, /*!< in: page number */ fsp_header_t* header, /*!< in: space header */ mtr_t* mtr) /*!< in: mtr */ { ibool success; ulint actual_size; ulint size; ut_a(space != 0); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); ut_a(page_no >= size); success = fil_extend_space_to_desired_size(&actual_size, space, page_no + 1); /* actual_size now has the space size in pages; it may be less than we wanted if we ran out of disk space */ mlog_write_ulint(header + FSP_SIZE, actual_size, MLOG_4BYTES, mtr); return(success); } /***********************************************************************//** Tries to extend the last data file of a tablespace if it is auto-extending. @return FALSE if not auto-extending */ static ibool fsp_try_extend_data_file( /*=====================*/ ulint* actual_increase,/*!< out: actual increase in pages, where we measure the tablespace size from what the header field says; it may be the actual file size rounded down to megabyte */ ulint space, /*!< in: space */ fsp_header_t* header, /*!< in: space header */ mtr_t* mtr) /*!< in: mtr */ { ulint size; ulint zip_size; ulint new_size; ulint old_size; ulint size_increase; ulint actual_size; ibool success; *actual_increase = 0; if (space == 0 && !srv_auto_extend_last_data_file) { return(FALSE); } size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); zip_size = dict_table_flags_to_zip_size( mach_read_from_4(header + FSP_SPACE_FLAGS)); old_size = size; if (space == 0) { if (!srv_last_file_size_max) { size_increase = SRV_AUTO_EXTEND_INCREMENT; } else { if (srv_last_file_size_max < srv_data_file_sizes[srv_n_data_files - 1]) { fprintf(stderr, "InnoDB: Error: Last data file size" " is %lu, max size allowed %lu\n", (ulong) srv_data_file_sizes[ srv_n_data_files - 1], (ulong) srv_last_file_size_max); } size_increase = srv_last_file_size_max - srv_data_file_sizes[srv_n_data_files - 1]; if (size_increase > SRV_AUTO_EXTEND_INCREMENT) { size_increase = SRV_AUTO_EXTEND_INCREMENT; } } } else { /* We extend single-table tablespaces first one extent at a time, but for bigger tablespaces more. It is not enough to extend always by one extent, because some extents are frag page extents. */ ulint extent_size; /*!< one megabyte, in pages */ if (!zip_size) { extent_size = FSP_EXTENT_SIZE; } else { extent_size = FSP_EXTENT_SIZE * UNIV_PAGE_SIZE / zip_size; } if (size < extent_size) { /* Let us first extend the file to extent_size */ success = fsp_try_extend_data_file_with_pages( space, extent_size - 1, header, mtr); if (!success) { new_size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); *actual_increase = new_size - old_size; return(FALSE); } size = extent_size; } if (size < 32 * extent_size) { size_increase = extent_size; } else { /* Below in fsp_fill_free_list() we assume that we add at most FSP_FREE_ADD extents at a time */ size_increase = FSP_FREE_ADD * extent_size; } } if (size_increase == 0) { return(TRUE); } success = fil_extend_space_to_desired_size(&actual_size, space, size + size_increase); /* We ignore any fragments of a full megabyte when storing the size to the space header */ if (!zip_size) { new_size = ut_calc_align_down(actual_size, (1024 * 1024) / UNIV_PAGE_SIZE); } else { new_size = ut_calc_align_down(actual_size, (1024 * 1024) / zip_size); } mlog_write_ulint(header + FSP_SIZE, new_size, MLOG_4BYTES, mtr); *actual_increase = new_size - old_size; return(TRUE); } /**********************************************************************//** Puts new extents to the free list if there are free extents above the free limit. If an extent happens to contain an extent descriptor page, the extent is put to the FSP_FREE_FRAG list with the page marked as used. */ static void fsp_fill_free_list( /*===============*/ ibool init_space, /*!< in: TRUE if this is a single-table tablespace and we are only initing the tablespace's first extent descriptor page and ibuf bitmap page; then we do not allocate more extents */ ulint space, /*!< in: space */ fsp_header_t* header, /*!< in: space header */ mtr_t* mtr) /*!< in: mtr */ { ulint limit; ulint size; ulint zip_size; xdes_t* descr; ulint count = 0; ulint frag_n_used; ulint actual_increase; ulint i; mtr_t ibuf_mtr; ut_ad(header && mtr); ut_ad(page_offset(header) == FSP_HEADER_OFFSET); /* Check if we can fill free list from above the free list limit */ size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); limit = mtr_read_ulint(header + FSP_FREE_LIMIT, MLOG_4BYTES, mtr); zip_size = dict_table_flags_to_zip_size( mach_read_from_4(FSP_SPACE_FLAGS + header)); ut_a(ut_is_2pow(zip_size)); ut_a(zip_size <= UNIV_PAGE_SIZE); ut_a(!zip_size || zip_size >= PAGE_ZIP_MIN_SIZE); if (space == 0 && srv_auto_extend_last_data_file && size < limit + FSP_EXTENT_SIZE * FSP_FREE_ADD) { /* Try to increase the last data file size */ fsp_try_extend_data_file(&actual_increase, space, header, mtr); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); } if (space != 0 && !init_space && size < limit + FSP_EXTENT_SIZE * FSP_FREE_ADD) { /* Try to increase the .ibd file size */ fsp_try_extend_data_file(&actual_increase, space, header, mtr); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); } i = limit; while ((init_space && i < 1) || ((i + FSP_EXTENT_SIZE <= size) && (count < FSP_FREE_ADD))) { ibool init_xdes; if (zip_size) { init_xdes = ut_2pow_remainder(i, zip_size) == 0; } else { init_xdes = ut_2pow_remainder(i, UNIV_PAGE_SIZE) == 0; } mlog_write_ulint(header + FSP_FREE_LIMIT, i + FSP_EXTENT_SIZE, MLOG_4BYTES, mtr); /* Update the free limit info in the log system and make a checkpoint */ if (space == 0) { ut_a(!zip_size); log_fsp_current_free_limit_set_and_checkpoint( (i + FSP_EXTENT_SIZE) / ((1024 * 1024) / UNIV_PAGE_SIZE)); } if (UNIV_UNLIKELY(init_xdes)) { buf_block_t* block; /* We are going to initialize a new descriptor page and a new ibuf bitmap page: the prior contents of the pages should be ignored. */ if (i > 0) { block = buf_page_create( space, i, zip_size, mtr); buf_page_get(space, zip_size, i, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); fsp_init_file_page(block, mtr); mlog_write_ulint(buf_block_get_frame(block) + FIL_PAGE_TYPE, FIL_PAGE_TYPE_XDES, MLOG_2BYTES, mtr); } /* Initialize the ibuf bitmap page in a separate mini-transaction because it is low in the latching order, and we must be able to release its latch before returning from the fsp routine */ mtr_start(&ibuf_mtr); block = buf_page_create(space, i + FSP_IBUF_BITMAP_OFFSET, zip_size, &ibuf_mtr); buf_page_get(space, zip_size, i + FSP_IBUF_BITMAP_OFFSET, RW_X_LATCH, &ibuf_mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); fsp_init_file_page(block, &ibuf_mtr); ibuf_bitmap_page_init(block, &ibuf_mtr); mtr_commit(&ibuf_mtr); } descr = xdes_get_descriptor_with_space_hdr(header, space, i, mtr); xdes_init(descr, mtr); #if UNIV_PAGE_SIZE % FSP_EXTENT_SIZE # error "UNIV_PAGE_SIZE % FSP_EXTENT_SIZE != 0" #endif #if PAGE_ZIP_MIN_SIZE % FSP_EXTENT_SIZE # error "PAGE_ZIP_MIN_SIZE % FSP_EXTENT_SIZE != 0" #endif if (UNIV_UNLIKELY(init_xdes)) { /* The first page in the extent is a descriptor page and the second is an ibuf bitmap page: mark them used */ xdes_set_bit(descr, XDES_FREE_BIT, 0, FALSE, mtr); xdes_set_bit(descr, XDES_FREE_BIT, FSP_IBUF_BITMAP_OFFSET, FALSE, mtr); xdes_set_state(descr, XDES_FREE_FRAG, mtr); flst_add_last(header + FSP_FREE_FRAG, descr + XDES_FLST_NODE, mtr); frag_n_used = mtr_read_ulint(header + FSP_FRAG_N_USED, MLOG_4BYTES, mtr); mlog_write_ulint(header + FSP_FRAG_N_USED, frag_n_used + 2, MLOG_4BYTES, mtr); } else { flst_add_last(header + FSP_FREE, descr + XDES_FLST_NODE, mtr); count++; } i += FSP_EXTENT_SIZE; } } /**********************************************************************//** Allocates a new free extent. @return extent descriptor, NULL if cannot be allocated */ static xdes_t* fsp_alloc_free_extent( /*==================*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint hint, /*!< in: hint of which extent would be desirable: any page offset in the extent goes; the hint must not be > FSP_FREE_LIMIT */ mtr_t* mtr) /*!< in: mtr */ { fsp_header_t* header; fil_addr_t first; xdes_t* descr; ut_ad(mtr); header = fsp_get_space_header(space, zip_size, mtr); descr = xdes_get_descriptor_with_space_hdr(header, space, hint, mtr); if (descr && (xdes_get_state(descr, mtr) == XDES_FREE)) { /* Ok, we can take this extent */ } else { /* Take the first extent in the free list */ first = flst_get_first(header + FSP_FREE, mtr); if (fil_addr_is_null(first)) { fsp_fill_free_list(FALSE, space, header, mtr); first = flst_get_first(header + FSP_FREE, mtr); } if (fil_addr_is_null(first)) { return(NULL); /* No free extents left */ } descr = xdes_lst_get_descriptor(space, zip_size, first, mtr); } flst_remove(header + FSP_FREE, descr + XDES_FLST_NODE, mtr); return(descr); } /**********************************************************************//** Allocates a single free page from a space. The page is marked as used. @return the page offset, FIL_NULL if no page could be allocated */ static ulint fsp_alloc_free_page( /*================*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint hint, /*!< in: hint of which page would be desirable */ mtr_t* mtr) /*!< in: mtr handle */ { fsp_header_t* header; fil_addr_t first; xdes_t* descr; buf_block_t* block; ulint free; ulint frag_n_used; ulint page_no; ulint space_size; ibool success; ut_ad(mtr); header = fsp_get_space_header(space, zip_size, mtr); /* Get the hinted descriptor */ descr = xdes_get_descriptor_with_space_hdr(header, space, hint, mtr); if (descr && (xdes_get_state(descr, mtr) == XDES_FREE_FRAG)) { /* Ok, we can take this extent */ } else { /* Else take the first extent in free_frag list */ first = flst_get_first(header + FSP_FREE_FRAG, mtr); if (fil_addr_is_null(first)) { /* There are no partially full fragments: allocate a free extent and add it to the FREE_FRAG list. NOTE that the allocation may have as a side-effect that an extent containing a descriptor page is added to the FREE_FRAG list. But we will allocate our page from the the free extent anyway. */ descr = fsp_alloc_free_extent(space, zip_size, hint, mtr); if (descr == NULL) { /* No free space left */ return(FIL_NULL); } xdes_set_state(descr, XDES_FREE_FRAG, mtr); flst_add_last(header + FSP_FREE_FRAG, descr + XDES_FLST_NODE, mtr); } else { descr = xdes_lst_get_descriptor(space, zip_size, first, mtr); } /* Reset the hint */ hint = 0; } /* Now we have in descr an extent with at least one free page. Look for a free page in the extent. */ free = xdes_find_bit(descr, XDES_FREE_BIT, TRUE, hint % FSP_EXTENT_SIZE, mtr); if (free == ULINT_UNDEFINED) { ut_print_buf(stderr, ((byte*)descr) - 500, 1000); putc('\n', stderr); ut_error; } page_no = xdes_get_offset(descr) + free; space_size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, mtr); if (space_size <= page_no) { /* It must be that we are extending a single-table tablespace whose size is still < 64 pages */ ut_a(space != 0); if (page_no >= FSP_EXTENT_SIZE) { fprintf(stderr, "InnoDB: Error: trying to extend a" " single-table tablespace %lu\n" "InnoDB: by single page(s) though the" " space size %lu. Page no %lu.\n", (ulong) space, (ulong) space_size, (ulong) page_no); return(FIL_NULL); } success = fsp_try_extend_data_file_with_pages(space, page_no, header, mtr); if (!success) { /* No disk space left */ return(FIL_NULL); } } xdes_set_bit(descr, XDES_FREE_BIT, free, FALSE, mtr); /* Update the FRAG_N_USED field */ frag_n_used = mtr_read_ulint(header + FSP_FRAG_N_USED, MLOG_4BYTES, mtr); frag_n_used++; mlog_write_ulint(header + FSP_FRAG_N_USED, frag_n_used, MLOG_4BYTES, mtr); if (xdes_is_full(descr, mtr)) { /* The fragment is full: move it to another list */ flst_remove(header + FSP_FREE_FRAG, descr + XDES_FLST_NODE, mtr); xdes_set_state(descr, XDES_FULL_FRAG, mtr); flst_add_last(header + FSP_FULL_FRAG, descr + XDES_FLST_NODE, mtr); mlog_write_ulint(header + FSP_FRAG_N_USED, frag_n_used - FSP_EXTENT_SIZE, MLOG_4BYTES, mtr); } /* Initialize the allocated page to the buffer pool, so that it can be obtained immediately with buf_page_get without need for a disk read. */ buf_page_create(space, page_no, zip_size, mtr); block = buf_page_get(space, zip_size, page_no, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); /* Prior contents of the page should be ignored */ fsp_init_file_page(block, mtr); return(page_no); } /**********************************************************************//** Frees a single page of a space. The page is marked as free and clean. */ static void fsp_free_page( /*==========*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset */ mtr_t* mtr) /*!< in: mtr handle */ { fsp_header_t* header; xdes_t* descr; ulint state; ulint frag_n_used; ut_ad(mtr); /* fprintf(stderr, "Freeing page %lu in space %lu\n", page, space); */ header = fsp_get_space_header(space, zip_size, mtr); descr = xdes_get_descriptor_with_space_hdr(header, space, page, mtr); state = xdes_get_state(descr, mtr); if (state != XDES_FREE_FRAG && state != XDES_FULL_FRAG) { fprintf(stderr, "InnoDB: Error: File space extent descriptor" " of page %lu has state %lu\n", (ulong) page, (ulong) state); fputs("InnoDB: Dump of descriptor: ", stderr); ut_print_buf(stderr, ((byte*)descr) - 50, 200); putc('\n', stderr); if (state == XDES_FREE) { /* We put here some fault tolerance: if the page is already free, return without doing anything! */ return; } ut_error; } if (xdes_get_bit(descr, XDES_FREE_BIT, page % FSP_EXTENT_SIZE, mtr)) { fprintf(stderr, "InnoDB: Error: File space extent descriptor" " of page %lu says it is free\n" "InnoDB: Dump of descriptor: ", (ulong) page); ut_print_buf(stderr, ((byte*)descr) - 50, 200); putc('\n', stderr); /* We put here some fault tolerance: if the page is already free, return without doing anything! */ return; } xdes_set_bit(descr, XDES_FREE_BIT, page % FSP_EXTENT_SIZE, TRUE, mtr); xdes_set_bit(descr, XDES_CLEAN_BIT, page % FSP_EXTENT_SIZE, TRUE, mtr); frag_n_used = mtr_read_ulint(header + FSP_FRAG_N_USED, MLOG_4BYTES, mtr); if (state == XDES_FULL_FRAG) { /* The fragment was full: move it to another list */ flst_remove(header + FSP_FULL_FRAG, descr + XDES_FLST_NODE, mtr); xdes_set_state(descr, XDES_FREE_FRAG, mtr); flst_add_last(header + FSP_FREE_FRAG, descr + XDES_FLST_NODE, mtr); mlog_write_ulint(header + FSP_FRAG_N_USED, frag_n_used + FSP_EXTENT_SIZE - 1, MLOG_4BYTES, mtr); } else { ut_a(frag_n_used > 0); mlog_write_ulint(header + FSP_FRAG_N_USED, frag_n_used - 1, MLOG_4BYTES, mtr); } if (xdes_is_free(descr, mtr)) { /* The extent has become free: move it to another list */ flst_remove(header + FSP_FREE_FRAG, descr + XDES_FLST_NODE, mtr); fsp_free_extent(space, zip_size, page, mtr); } } /**********************************************************************//** Returns an extent to the free list of a space. */ static void fsp_free_extent( /*============*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset in the extent */ mtr_t* mtr) /*!< in: mtr */ { fsp_header_t* header; xdes_t* descr; ut_ad(mtr); header = fsp_get_space_header(space, zip_size, mtr); descr = xdes_get_descriptor_with_space_hdr(header, space, page, mtr); if (xdes_get_state(descr, mtr) == XDES_FREE) { ut_print_buf(stderr, (byte*)descr - 500, 1000); putc('\n', stderr); ut_error; } xdes_init(descr, mtr); flst_add_last(header + FSP_FREE, descr + XDES_FLST_NODE, mtr); } /**********************************************************************//** Returns the nth inode slot on an inode page. @return segment inode */ UNIV_INLINE fseg_inode_t* fsp_seg_inode_page_get_nth_inode( /*=============================*/ page_t* page, /*!< in: segment inode page */ ulint i, /*!< in: inode index on page */ ulint zip_size __attribute__((unused)), /*!< in: compressed page size, or 0 */ mtr_t* mtr __attribute__((unused))) /*!< in: mini-transaction handle */ { ut_ad(i < FSP_SEG_INODES_PER_PAGE(zip_size)); ut_ad(mtr_memo_contains_page(mtr, page, MTR_MEMO_PAGE_X_FIX)); return(page + FSEG_ARR_OFFSET + FSEG_INODE_SIZE * i); } /**********************************************************************//** Looks for a used segment inode on a segment inode page. @return segment inode index, or ULINT_UNDEFINED if not found */ static ulint fsp_seg_inode_page_find_used( /*=========================*/ page_t* page, /*!< in: segment inode page */ ulint zip_size,/*!< in: compressed page size, or 0 */ mtr_t* mtr) /*!< in: mini-transaction handle */ { ulint i; fseg_inode_t* inode; for (i = 0; i < FSP_SEG_INODES_PER_PAGE(zip_size); i++) { inode = fsp_seg_inode_page_get_nth_inode( page, i, zip_size, mtr); if (!ut_dulint_is_zero(mach_read_from_8(inode + FSEG_ID))) { /* This is used */ return(i); } } return(ULINT_UNDEFINED); } /**********************************************************************//** Looks for an unused segment inode on a segment inode page. @return segment inode index, or ULINT_UNDEFINED if not found */ static ulint fsp_seg_inode_page_find_free( /*=========================*/ page_t* page, /*!< in: segment inode page */ ulint i, /*!< in: search forward starting from this index */ ulint zip_size,/*!< in: compressed page size, or 0 */ mtr_t* mtr) /*!< in: mini-transaction handle */ { fseg_inode_t* inode; for (; i < FSP_SEG_INODES_PER_PAGE(zip_size); i++) { inode = fsp_seg_inode_page_get_nth_inode( page, i, zip_size, mtr); if (ut_dulint_is_zero(mach_read_from_8(inode + FSEG_ID))) { /* This is unused */ return(i); } } return(ULINT_UNDEFINED); } /**********************************************************************//** Allocates a new file segment inode page. @return TRUE if could be allocated */ static ibool fsp_alloc_seg_inode_page( /*=====================*/ fsp_header_t* space_header, /*!< in: space header */ mtr_t* mtr) /*!< in: mini-transaction handle */ { fseg_inode_t* inode; buf_block_t* block; page_t* page; ulint page_no; ulint space; ulint zip_size; ulint i; ut_ad(page_offset(space_header) == FSP_HEADER_OFFSET); space = page_get_space_id(page_align(space_header)); zip_size = dict_table_flags_to_zip_size( mach_read_from_4(FSP_SPACE_FLAGS + space_header)); page_no = fsp_alloc_free_page(space, zip_size, 0, mtr); if (page_no == FIL_NULL) { return(FALSE); } block = buf_page_get(space, zip_size, page_no, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); block->check_index_page_at_flush = FALSE; page = buf_block_get_frame(block); mlog_write_ulint(page + FIL_PAGE_TYPE, FIL_PAGE_INODE, MLOG_2BYTES, mtr); for (i = 0; i < FSP_SEG_INODES_PER_PAGE(zip_size); i++) { inode = fsp_seg_inode_page_get_nth_inode(page, i, zip_size, mtr); mlog_write_dulint(inode + FSEG_ID, ut_dulint_zero, mtr); } flst_add_last(space_header + FSP_SEG_INODES_FREE, page + FSEG_INODE_PAGE_NODE, mtr); return(TRUE); } /**********************************************************************//** Allocates a new file segment inode. @return segment inode, or NULL if not enough space */ static fseg_inode_t* fsp_alloc_seg_inode( /*================*/ fsp_header_t* space_header, /*!< in: space header */ mtr_t* mtr) /*!< in: mini-transaction handle */ { ulint page_no; buf_block_t* block; page_t* page; fseg_inode_t* inode; ibool success; ulint zip_size; ulint n; ut_ad(page_offset(space_header) == FSP_HEADER_OFFSET); if (flst_get_len(space_header + FSP_SEG_INODES_FREE, mtr) == 0) { /* Allocate a new segment inode page */ success = fsp_alloc_seg_inode_page(space_header, mtr); if (!success) { return(NULL); } } page_no = flst_get_first(space_header + FSP_SEG_INODES_FREE, mtr).page; zip_size = dict_table_flags_to_zip_size( mach_read_from_4(FSP_SPACE_FLAGS + space_header)); block = buf_page_get(page_get_space_id(page_align(space_header)), zip_size, page_no, RW_X_LATCH, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); page = buf_block_get_frame(block); n = fsp_seg_inode_page_find_free(page, 0, zip_size, mtr); ut_a(n != ULINT_UNDEFINED); inode = fsp_seg_inode_page_get_nth_inode(page, n, zip_size, mtr); if (ULINT_UNDEFINED == fsp_seg_inode_page_find_free(page, n + 1, zip_size, mtr)) { /* There are no other unused headers left on the page: move it to another list */ flst_remove(space_header + FSP_SEG_INODES_FREE, page + FSEG_INODE_PAGE_NODE, mtr); flst_add_last(space_header + FSP_SEG_INODES_FULL, page + FSEG_INODE_PAGE_NODE, mtr); } return(inode); } /**********************************************************************//** Frees a file segment inode. */ static void fsp_free_seg_inode( /*===============*/ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ fseg_inode_t* inode, /*!< in: segment inode */ mtr_t* mtr) /*!< in: mini-transaction handle */ { page_t* page; fsp_header_t* space_header; page = page_align(inode); space_header = fsp_get_space_header(space, zip_size, mtr); ut_ad(mach_read_from_4(inode + FSEG_MAGIC_N) == FSEG_MAGIC_N_VALUE); if (ULINT_UNDEFINED == fsp_seg_inode_page_find_free(page, 0, zip_size, mtr)) { /* Move the page to another list */ flst_remove(space_header + FSP_SEG_INODES_FULL, page + FSEG_INODE_PAGE_NODE, mtr); flst_add_last(space_header + FSP_SEG_INODES_FREE, page + FSEG_INODE_PAGE_NODE, mtr); } mlog_write_dulint(inode + FSEG_ID, ut_dulint_zero, mtr); mlog_write_ulint(inode + FSEG_MAGIC_N, 0, MLOG_4BYTES, mtr); if (ULINT_UNDEFINED == fsp_seg_inode_page_find_used(page, zip_size, mtr)) { /* There are no other used headers left on the page: free it */ flst_remove(space_header + FSP_SEG_INODES_FREE, page + FSEG_INODE_PAGE_NODE, mtr); fsp_free_page(space, zip_size, page_get_page_no(page), mtr); } } /**********************************************************************//** Returns the file segment inode, page x-latched. @return segment inode, page x-latched */ static fseg_inode_t* fseg_inode_get( /*===========*/ fseg_header_t* header, /*!< in: segment header */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ mtr_t* mtr) /*!< in: mtr handle */ { fil_addr_t inode_addr; fseg_inode_t* inode; inode_addr.page = mach_read_from_4(header + FSEG_HDR_PAGE_NO); inode_addr.boffset = mach_read_from_2(header + FSEG_HDR_OFFSET); ut_ad(space == mach_read_from_4(header + FSEG_HDR_SPACE)); inode = fut_get_ptr(space, zip_size, inode_addr, RW_X_LATCH, mtr); ut_ad(mach_read_from_4(inode + FSEG_MAGIC_N) == FSEG_MAGIC_N_VALUE); return(inode); } /**********************************************************************//** Gets the page number from the nth fragment page slot. @return page number, FIL_NULL if not in use */ UNIV_INLINE ulint fseg_get_nth_frag_page_no( /*======================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint n, /*!< in: slot index */ mtr_t* mtr __attribute__((unused))) /*!< in: mtr handle */ { ut_ad(inode && mtr); ut_ad(n < FSEG_FRAG_ARR_N_SLOTS); ut_ad(mtr_memo_contains_page(mtr, inode, MTR_MEMO_PAGE_X_FIX)); return(mach_read_from_4(inode + FSEG_FRAG_ARR + n * FSEG_FRAG_SLOT_SIZE)); } /**********************************************************************//** Sets the page number in the nth fragment page slot. */ UNIV_INLINE void fseg_set_nth_frag_page_no( /*======================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint n, /*!< in: slot index */ ulint page_no,/*!< in: page number to set */ mtr_t* mtr) /*!< in: mtr handle */ { ut_ad(inode && mtr); ut_ad(n < FSEG_FRAG_ARR_N_SLOTS); ut_ad(mtr_memo_contains_page(mtr, inode, MTR_MEMO_PAGE_X_FIX)); mlog_write_ulint(inode + FSEG_FRAG_ARR + n * FSEG_FRAG_SLOT_SIZE, page_no, MLOG_4BYTES, mtr); } /**********************************************************************//** Finds a fragment page slot which is free. @return slot index; ULINT_UNDEFINED if none found */ static ulint fseg_find_free_frag_page_slot( /*==========================*/ fseg_inode_t* inode, /*!< in: segment inode */ mtr_t* mtr) /*!< in: mtr handle */ { ulint i; ulint page_no; ut_ad(inode && mtr); for (i = 0; i < FSEG_FRAG_ARR_N_SLOTS; i++) { page_no = fseg_get_nth_frag_page_no(inode, i, mtr); if (page_no == FIL_NULL) { return(i); } } return(ULINT_UNDEFINED); } /**********************************************************************//** Finds a fragment page slot which is used and last in the array. @return slot index; ULINT_UNDEFINED if none found */ static ulint fseg_find_last_used_frag_page_slot( /*===============================*/ fseg_inode_t* inode, /*!< in: segment inode */ mtr_t* mtr) /*!< in: mtr handle */ { ulint i; ulint page_no; ut_ad(inode && mtr); for (i = 0; i < FSEG_FRAG_ARR_N_SLOTS; i++) { page_no = fseg_get_nth_frag_page_no( inode, FSEG_FRAG_ARR_N_SLOTS - i - 1, mtr); if (page_no != FIL_NULL) { return(FSEG_FRAG_ARR_N_SLOTS - i - 1); } } return(ULINT_UNDEFINED); } /**********************************************************************//** Calculates reserved fragment page slots. @return number of fragment pages */ static ulint fseg_get_n_frag_pages( /*==================*/ fseg_inode_t* inode, /*!< in: segment inode */ mtr_t* mtr) /*!< in: mtr handle */ { ulint i; ulint count = 0; ut_ad(inode && mtr); for (i = 0; i < FSEG_FRAG_ARR_N_SLOTS; i++) { if (FIL_NULL != fseg_get_nth_frag_page_no(inode, i, mtr)) { count++; } } return(count); } /**********************************************************************//** Creates a new segment. @return the block where the segment header is placed, x-latched, NULL if could not create segment because of lack of space */ UNIV_INTERN buf_block_t* fseg_create_general( /*================*/ ulint space, /*!< in: space id */ ulint page, /*!< in: page where the segment header is placed: if this is != 0, the page must belong to another segment, if this is 0, a new page will be allocated and it will belong to the created segment */ ulint byte_offset, /*!< in: byte offset of the created segment header on the page */ ibool has_done_reservation, /*!< in: TRUE if the caller has already done the reservation for the pages with fsp_reserve_free_extents (at least 2 extents: one for the inode and the other for the segment) then there is no need to do the check for this individual operation */ mtr_t* mtr) /*!< in: mtr */ { ulint flags; ulint zip_size; fsp_header_t* space_header; fseg_inode_t* inode; dulint seg_id; buf_block_t* block = 0; /* remove warning */ fseg_header_t* header = 0; /* remove warning */ rw_lock_t* latch; ibool success; ulint n_reserved; ulint i; ut_ad(mtr); ut_ad(byte_offset + FSEG_HEADER_SIZE <= UNIV_PAGE_SIZE - FIL_PAGE_DATA_END); latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); if (page != 0) { block = buf_page_get(space, zip_size, page, RW_X_LATCH, mtr); header = byte_offset + buf_block_get_frame(block); } ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); if (rw_lock_get_x_lock_count(latch) == 1) { /* This thread did not own the latch before this call: free excess pages from the insert buffer free list */ if (space == IBUF_SPACE_ID) { ibuf_free_excess_pages(); } } if (!has_done_reservation) { success = fsp_reserve_free_extents(&n_reserved, space, 2, FSP_NORMAL, mtr); if (!success) { return(NULL); } } space_header = fsp_get_space_header(space, zip_size, mtr); inode = fsp_alloc_seg_inode(space_header, mtr); if (inode == NULL) { goto funct_exit; } /* Read the next segment id from space header and increment the value in space header */ seg_id = mtr_read_dulint(space_header + FSP_SEG_ID, mtr); mlog_write_dulint(space_header + FSP_SEG_ID, ut_dulint_add(seg_id, 1), mtr); mlog_write_dulint(inode + FSEG_ID, seg_id, mtr); mlog_write_ulint(inode + FSEG_NOT_FULL_N_USED, 0, MLOG_4BYTES, mtr); flst_init(inode + FSEG_FREE, mtr); flst_init(inode + FSEG_NOT_FULL, mtr); flst_init(inode + FSEG_FULL, mtr); mlog_write_ulint(inode + FSEG_MAGIC_N, FSEG_MAGIC_N_VALUE, MLOG_4BYTES, mtr); for (i = 0; i < FSEG_FRAG_ARR_N_SLOTS; i++) { fseg_set_nth_frag_page_no(inode, i, FIL_NULL, mtr); } if (page == 0) { page = fseg_alloc_free_page_low(space, zip_size, inode, 0, FSP_UP, mtr); if (page == FIL_NULL) { fsp_free_seg_inode(space, zip_size, inode, mtr); goto funct_exit; } block = buf_page_get(space, zip_size, page, RW_X_LATCH, mtr); header = byte_offset + buf_block_get_frame(block); mlog_write_ulint(header - byte_offset + FIL_PAGE_TYPE, FIL_PAGE_TYPE_SYS, MLOG_2BYTES, mtr); } mlog_write_ulint(header + FSEG_HDR_OFFSET, page_offset(inode), MLOG_2BYTES, mtr); mlog_write_ulint(header + FSEG_HDR_PAGE_NO, page_get_page_no(page_align(inode)), MLOG_4BYTES, mtr); mlog_write_ulint(header + FSEG_HDR_SPACE, space, MLOG_4BYTES, mtr); funct_exit: if (!has_done_reservation) { fil_space_release_free_extents(space, n_reserved); } return(block); } /**********************************************************************//** Creates a new segment. @return the block where the segment header is placed, x-latched, NULL if could not create segment because of lack of space */ UNIV_INTERN buf_block_t* fseg_create( /*========*/ ulint space, /*!< in: space id */ ulint page, /*!< in: page where the segment header is placed: if this is != 0, the page must belong to another segment, if this is 0, a new page will be allocated and it will belong to the created segment */ ulint byte_offset, /*!< in: byte offset of the created segment header on the page */ mtr_t* mtr) /*!< in: mtr */ { return(fseg_create_general(space, page, byte_offset, FALSE, mtr)); } /**********************************************************************//** Calculates the number of pages reserved by a segment, and how many pages are currently used. @return number of reserved pages */ static ulint fseg_n_reserved_pages_low( /*======================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint* used, /*!< out: number of pages used (not more than reserved) */ mtr_t* mtr) /*!< in: mtr handle */ { ulint ret; ut_ad(inode && used && mtr); ut_ad(mtr_memo_contains_page(mtr, inode, MTR_MEMO_PAGE_X_FIX)); *used = mtr_read_ulint(inode + FSEG_NOT_FULL_N_USED, MLOG_4BYTES, mtr) + FSP_EXTENT_SIZE * flst_get_len(inode + FSEG_FULL, mtr) + fseg_get_n_frag_pages(inode, mtr); ret = fseg_get_n_frag_pages(inode, mtr) + FSP_EXTENT_SIZE * flst_get_len(inode + FSEG_FREE, mtr) + FSP_EXTENT_SIZE * flst_get_len(inode + FSEG_NOT_FULL, mtr) + FSP_EXTENT_SIZE * flst_get_len(inode + FSEG_FULL, mtr); return(ret); } /**********************************************************************//** Calculates the number of pages reserved by a segment, and how many pages are currently used. @return number of reserved pages */ UNIV_INTERN ulint fseg_n_reserved_pages( /*==================*/ fseg_header_t* header, /*!< in: segment header */ ulint* used, /*!< out: number of pages used (<= reserved) */ mtr_t* mtr) /*!< in: mtr handle */ { ulint ret; fseg_inode_t* inode; ulint space; ulint flags; ulint zip_size; rw_lock_t* latch; space = page_get_space_id(page_align(header)); latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); inode = fseg_inode_get(header, space, zip_size, mtr); ret = fseg_n_reserved_pages_low(inode, used, mtr); return(ret); } /*********************************************************************//** Tries to fill the free list of a segment with consecutive free extents. This happens if the segment is big enough to allow extents in the free list, the free list is empty, and the extents can be allocated consecutively from the hint onward. */ static void fseg_fill_free_list( /*================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint hint, /*!< in: hint which extent would be good as the first extent */ mtr_t* mtr) /*!< in: mtr */ { xdes_t* descr; ulint i; dulint seg_id; ulint reserved; ulint used; ut_ad(inode && mtr); ut_ad(!((page_offset(inode) - FSEG_ARR_OFFSET) % FSEG_INODE_SIZE)); reserved = fseg_n_reserved_pages_low(inode, &used, mtr); if (reserved < FSEG_FREE_LIST_LIMIT * FSP_EXTENT_SIZE) { /* The segment is too small to allow extents in free list */ return; } if (flst_get_len(inode + FSEG_FREE, mtr) > 0) { /* Free list is not empty */ return; } for (i = 0; i < FSEG_FREE_LIST_MAX_LEN; i++) { descr = xdes_get_descriptor(space, zip_size, hint, mtr); if ((descr == NULL) || (XDES_FREE != xdes_get_state(descr, mtr))) { /* We cannot allocate the desired extent: stop */ return; } descr = fsp_alloc_free_extent(space, zip_size, hint, mtr); xdes_set_state(descr, XDES_FSEG, mtr); seg_id = mtr_read_dulint(inode + FSEG_ID, mtr); mlog_write_dulint(descr + XDES_ID, seg_id, mtr); flst_add_last(inode + FSEG_FREE, descr + XDES_FLST_NODE, mtr); hint += FSP_EXTENT_SIZE; } } /*********************************************************************//** Allocates a free extent for the segment: looks first in the free list of the segment, then tries to allocate from the space free list. NOTE that the extent returned still resides in the segment free list, it is not yet taken off it! @return allocated extent, still placed in the segment free list, NULL if could not be allocated */ static xdes_t* fseg_alloc_free_extent( /*===================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ mtr_t* mtr) /*!< in: mtr */ { xdes_t* descr; dulint seg_id; fil_addr_t first; ut_ad(!((page_offset(inode) - FSEG_ARR_OFFSET) % FSEG_INODE_SIZE)); if (flst_get_len(inode + FSEG_FREE, mtr) > 0) { /* Segment free list is not empty, allocate from it */ first = flst_get_first(inode + FSEG_FREE, mtr); descr = xdes_lst_get_descriptor(space, zip_size, first, mtr); } else { /* Segment free list was empty, allocate from space */ descr = fsp_alloc_free_extent(space, zip_size, 0, mtr); if (descr == NULL) { return(NULL); } seg_id = mtr_read_dulint(inode + FSEG_ID, mtr); xdes_set_state(descr, XDES_FSEG, mtr); mlog_write_dulint(descr + XDES_ID, seg_id, mtr); flst_add_last(inode + FSEG_FREE, descr + XDES_FLST_NODE, mtr); /* Try to fill the segment free list */ fseg_fill_free_list(inode, space, zip_size, xdes_get_offset(descr) + FSP_EXTENT_SIZE, mtr); } return(descr); } /**********************************************************************//** Allocates a single free page from a segment. This function implements the intelligent allocation strategy which tries to minimize file space fragmentation. @return the allocated page number, FIL_NULL if no page could be allocated */ static ulint fseg_alloc_free_page_low( /*=====================*/ ulint space, /*!< in: space */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ fseg_inode_t* seg_inode, /*!< in: segment inode */ ulint hint, /*!< in: hint of which page would be desirable */ byte direction, /*!< in: if the new page is needed because of an index page split, and records are inserted there in order, into which direction they go alphabetically: FSP_DOWN, FSP_UP, FSP_NO_DIR */ mtr_t* mtr) /*!< in: mtr handle */ { fsp_header_t* space_header; ulint space_size; dulint seg_id; ulint used; ulint reserved; xdes_t* descr; /*!< extent of the hinted page */ ulint ret_page; /*!< the allocated page offset, FIL_NULL if could not be allocated */ xdes_t* ret_descr; /*!< the extent of the allocated page */ ibool frag_page_allocated = FALSE; ibool success; ulint n; ut_ad(mtr); ut_ad((direction >= FSP_UP) && (direction <= FSP_NO_DIR)); ut_ad(mach_read_from_4(seg_inode + FSEG_MAGIC_N) == FSEG_MAGIC_N_VALUE); ut_ad(!((page_offset(seg_inode) - FSEG_ARR_OFFSET) % FSEG_INODE_SIZE)); seg_id = mtr_read_dulint(seg_inode + FSEG_ID, mtr); ut_ad(!ut_dulint_is_zero(seg_id)); reserved = fseg_n_reserved_pages_low(seg_inode, &used, mtr); space_header = fsp_get_space_header(space, zip_size, mtr); descr = xdes_get_descriptor_with_space_hdr(space_header, space, hint, mtr); if (descr == NULL) { /* Hint outside space or too high above free limit: reset hint */ hint = 0; descr = xdes_get_descriptor(space, zip_size, hint, mtr); } /* In the big if-else below we look for ret_page and ret_descr */ /*-------------------------------------------------------------*/ if ((xdes_get_state(descr, mtr) == XDES_FSEG) && (0 == ut_dulint_cmp(mtr_read_dulint(descr + XDES_ID, mtr), seg_id)) && (xdes_get_bit(descr, XDES_FREE_BIT, hint % FSP_EXTENT_SIZE, mtr) == TRUE)) { /* 1. We can take the hinted page =================================*/ ret_descr = descr; ret_page = hint; /*-----------------------------------------------------------*/ } else if ((xdes_get_state(descr, mtr) == XDES_FREE) && ((reserved - used) < reserved / FSEG_FILLFACTOR) && (used >= FSEG_FRAG_LIMIT)) { /* 2. We allocate the free extent from space and can take ========================================================= the hinted page ===============*/ ret_descr = fsp_alloc_free_extent(space, zip_size, hint, mtr); ut_a(ret_descr == descr); xdes_set_state(ret_descr, XDES_FSEG, mtr); mlog_write_dulint(ret_descr + XDES_ID, seg_id, mtr); flst_add_last(seg_inode + FSEG_FREE, ret_descr + XDES_FLST_NODE, mtr); /* Try to fill the segment free list */ fseg_fill_free_list(seg_inode, space, zip_size, hint + FSP_EXTENT_SIZE, mtr); ret_page = hint; /*-----------------------------------------------------------*/ } else if ((direction != FSP_NO_DIR) && ((reserved - used) < reserved / FSEG_FILLFACTOR) && (used >= FSEG_FRAG_LIMIT) && (!!(ret_descr = fseg_alloc_free_extent(seg_inode, space, zip_size, mtr)))) { /* 3. We take any free extent (which was already assigned above =============================================================== in the if-condition to ret_descr) and take the lowest or ======================================================== highest page in it, depending on the direction ==============================================*/ ret_page = xdes_get_offset(ret_descr); if (direction == FSP_DOWN) { ret_page += FSP_EXTENT_SIZE - 1; } /*-----------------------------------------------------------*/ } else if ((xdes_get_state(descr, mtr) == XDES_FSEG) && (0 == ut_dulint_cmp(mtr_read_dulint(descr + XDES_ID, mtr), seg_id)) && (!xdes_is_full(descr, mtr))) { /* 4. We can take the page from the same extent as the ====================================================== hinted page (and the extent already belongs to the ================================================== segment) ========*/ ret_descr = descr; ret_page = xdes_get_offset(ret_descr) + xdes_find_bit(ret_descr, XDES_FREE_BIT, TRUE, hint % FSP_EXTENT_SIZE, mtr); /*-----------------------------------------------------------*/ } else if (reserved - used > 0) { /* 5. We take any unused page from the segment ==============================================*/ fil_addr_t first; if (flst_get_len(seg_inode + FSEG_NOT_FULL, mtr) > 0) { first = flst_get_first(seg_inode + FSEG_NOT_FULL, mtr); } else if (flst_get_len(seg_inode + FSEG_FREE, mtr) > 0) { first = flst_get_first(seg_inode + FSEG_FREE, mtr); } else { ut_error; return(FIL_NULL); } ret_descr = xdes_lst_get_descriptor(space, zip_size, first, mtr); ret_page = xdes_get_offset(ret_descr) + xdes_find_bit(ret_descr, XDES_FREE_BIT, TRUE, 0, mtr); /*-----------------------------------------------------------*/ } else if (used < FSEG_FRAG_LIMIT) { /* 6. We allocate an individual page from the space ===================================================*/ ret_page = fsp_alloc_free_page(space, zip_size, hint, mtr); ret_descr = NULL; frag_page_allocated = TRUE; if (ret_page != FIL_NULL) { /* Put the page in the fragment page array of the segment */ n = fseg_find_free_frag_page_slot(seg_inode, mtr); ut_a(n != FIL_NULL); fseg_set_nth_frag_page_no(seg_inode, n, ret_page, mtr); } /*-----------------------------------------------------------*/ } else { /* 7. We allocate a new extent and take its first page ======================================================*/ ret_descr = fseg_alloc_free_extent(seg_inode, space, zip_size, mtr); if (ret_descr == NULL) { ret_page = FIL_NULL; } else { ret_page = xdes_get_offset(ret_descr); } } if (ret_page == FIL_NULL) { /* Page could not be allocated */ return(FIL_NULL); } if (space != 0) { space_size = fil_space_get_size(space); if (space_size <= ret_page) { /* It must be that we are extending a single-table tablespace whose size is still < 64 pages */ if (ret_page >= FSP_EXTENT_SIZE) { fprintf(stderr, "InnoDB: Error (2): trying to extend" " a single-table tablespace %lu\n" "InnoDB: by single page(s) though" " the space size %lu. Page no %lu.\n", (ulong) space, (ulong) space_size, (ulong) ret_page); return(FIL_NULL); } success = fsp_try_extend_data_file_with_pages( space, ret_page, space_header, mtr); if (!success) { /* No disk space left */ return(FIL_NULL); } } } if (!frag_page_allocated) { /* Initialize the allocated page to buffer pool, so that it can be obtained immediately with buf_page_get without need for a disk read */ buf_block_t* block; ulint zip_size = dict_table_flags_to_zip_size( mach_read_from_4(FSP_SPACE_FLAGS + space_header)); block = buf_page_create(space, ret_page, zip_size, mtr); buf_block_dbg_add_level(block, SYNC_FSP_PAGE); if (UNIV_UNLIKELY(block != buf_page_get(space, zip_size, ret_page, RW_X_LATCH, mtr))) { ut_error; } /* The prior contents of the page should be ignored */ fsp_init_file_page(block, mtr); /* At this point we know the extent and the page offset. The extent is still in the appropriate list (FSEG_NOT_FULL or FSEG_FREE), and the page is not yet marked as used. */ ut_ad(xdes_get_descriptor(space, zip_size, ret_page, mtr) == ret_descr); ut_ad(xdes_get_bit(ret_descr, XDES_FREE_BIT, ret_page % FSP_EXTENT_SIZE, mtr) == TRUE); fseg_mark_page_used(seg_inode, space, zip_size, ret_page, mtr); } buf_reset_check_index_page_at_flush(space, ret_page); return(ret_page); } /**********************************************************************//** Allocates a single free page from a segment. This function implements the intelligent allocation strategy which tries to minimize file space fragmentation. @return allocated page offset, FIL_NULL if no page could be allocated */ UNIV_INTERN ulint fseg_alloc_free_page_general( /*=========================*/ fseg_header_t* seg_header,/*!< in: segment header */ ulint hint, /*!< in: hint of which page would be desirable */ byte direction,/*!< in: if the new page is needed because of an index page split, and records are inserted there in order, into which direction they go alphabetically: FSP_DOWN, FSP_UP, FSP_NO_DIR */ ibool has_done_reservation, /*!< in: TRUE if the caller has already done the reservation for the page with fsp_reserve_free_extents, then there is no need to do the check for this individual page */ mtr_t* mtr) /*!< in: mtr handle */ { fseg_inode_t* inode; ulint space; ulint flags; ulint zip_size; rw_lock_t* latch; ibool success; ulint page_no; ulint n_reserved; space = page_get_space_id(page_align(seg_header)); latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); if (rw_lock_get_x_lock_count(latch) == 1) { /* This thread did not own the latch before this call: free excess pages from the insert buffer free list */ if (space == IBUF_SPACE_ID) { ibuf_free_excess_pages(); } } inode = fseg_inode_get(seg_header, space, zip_size, mtr); if (!has_done_reservation) { success = fsp_reserve_free_extents(&n_reserved, space, 2, FSP_NORMAL, mtr); if (!success) { return(FIL_NULL); } } page_no = fseg_alloc_free_page_low(space, zip_size, inode, hint, direction, mtr); if (!has_done_reservation) { fil_space_release_free_extents(space, n_reserved); } return(page_no); } /**********************************************************************//** Allocates a single free page from a segment. This function implements the intelligent allocation strategy which tries to minimize file space fragmentation. @return allocated page offset, FIL_NULL if no page could be allocated */ UNIV_INTERN ulint fseg_alloc_free_page( /*=================*/ fseg_header_t* seg_header,/*!< in: segment header */ ulint hint, /*!< in: hint of which page would be desirable */ byte direction,/*!< in: if the new page is needed because of an index page split, and records are inserted there in order, into which direction they go alphabetically: FSP_DOWN, FSP_UP, FSP_NO_DIR */ mtr_t* mtr) /*!< in: mtr handle */ { return(fseg_alloc_free_page_general(seg_header, hint, direction, FALSE, mtr)); } /**********************************************************************//** Checks that we have at least 2 frag pages free in the first extent of a single-table tablespace, and they are also physically initialized to the data file. That is we have already extended the data file so that those pages are inside the data file. If not, this function extends the tablespace with pages. @return TRUE if there were >= 3 free pages, or we were able to extend */ static ibool fsp_reserve_free_pages( /*===================*/ ulint space, /*!< in: space id, must be != 0 */ fsp_header_t* space_header, /*!< in: header of that space, x-latched */ ulint size, /*!< in: size of the tablespace in pages, must be < FSP_EXTENT_SIZE / 2 */ mtr_t* mtr) /*!< in: mtr */ { xdes_t* descr; ulint n_used; ut_a(space != 0); ut_a(size < FSP_EXTENT_SIZE / 2); descr = xdes_get_descriptor_with_space_hdr(space_header, space, 0, mtr); n_used = xdes_get_n_used(descr, mtr); ut_a(n_used <= size); if (size >= n_used + 2) { return(TRUE); } return(fsp_try_extend_data_file_with_pages(space, n_used + 1, space_header, mtr)); } /**********************************************************************//** Reserves free pages from a tablespace. All mini-transactions which may use several pages from the tablespace should call this function beforehand and reserve enough free extents so that they certainly will be able to do their operation, like a B-tree page split, fully. Reservations must be released with function fil_space_release_free_extents! The alloc_type below has the following meaning: FSP_NORMAL means an operation which will probably result in more space usage, like an insert in a B-tree; FSP_UNDO means allocation to undo logs: if we are deleting rows, then this allocation will in the long run result in less space usage (after a purge); FSP_CLEANING means allocation done in a physical record delete (like in a purge) or other cleaning operation which will result in less space usage in the long run. We prefer the latter two types of allocation: when space is scarce, FSP_NORMAL allocations will not succeed, but the latter two allocations will succeed, if possible. The purpose is to avoid dead end where the database is full but the user cannot free any space because these freeing operations temporarily reserve some space. Single-table tablespaces whose size is < 32 pages are a special case. In this function we would liberally reserve several 64 page extents for every page split or merge in a B-tree. But we do not want to waste disk space if the table only occupies < 32 pages. That is why we apply different rules in that special case, just ensuring that there are 3 free pages available. @return TRUE if we were able to make the reservation */ UNIV_INTERN ibool fsp_reserve_free_extents( /*=====================*/ ulint* n_reserved,/*!< out: number of extents actually reserved; if we return TRUE and the tablespace size is < 64 pages, then this can be 0, otherwise it is n_ext */ ulint space, /*!< in: space id */ ulint n_ext, /*!< in: number of extents to reserve */ ulint alloc_type,/*!< in: FSP_NORMAL, FSP_UNDO, or FSP_CLEANING */ mtr_t* mtr) /*!< in: mtr */ { fsp_header_t* space_header; rw_lock_t* latch; ulint n_free_list_ext; ulint free_limit; ulint size; ulint flags; ulint zip_size; ulint n_free; ulint n_free_up; ulint reserve; ibool success; ulint n_pages_added; ut_ad(mtr); *n_reserved = n_ext; latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); space_header = fsp_get_space_header(space, zip_size, mtr); try_again: size = mtr_read_ulint(space_header + FSP_SIZE, MLOG_4BYTES, mtr); if (size < FSP_EXTENT_SIZE / 2) { /* Use different rules for small single-table tablespaces */ *n_reserved = 0; return(fsp_reserve_free_pages(space, space_header, size, mtr)); } n_free_list_ext = flst_get_len(space_header + FSP_FREE, mtr); free_limit = mtr_read_ulint(space_header + FSP_FREE_LIMIT, MLOG_4BYTES, mtr); /* Below we play safe when counting free extents above the free limit: some of them will contain extent descriptor pages, and therefore will not be free extents */ n_free_up = (size - free_limit) / FSP_EXTENT_SIZE; if (n_free_up > 0) { n_free_up--; if (!zip_size) { n_free_up -= n_free_up / (UNIV_PAGE_SIZE / FSP_EXTENT_SIZE); } else { n_free_up -= n_free_up / (zip_size / FSP_EXTENT_SIZE); } } n_free = n_free_list_ext + n_free_up; if (alloc_type == FSP_NORMAL) { /* We reserve 1 extent + 0.5 % of the space size to undo logs and 1 extent + 0.5 % to cleaning operations; NOTE: this source code is duplicated in the function below! */ reserve = 2 + ((size / FSP_EXTENT_SIZE) * 2) / 200; if (n_free <= reserve + n_ext) { goto try_to_extend; } } else if (alloc_type == FSP_UNDO) { /* We reserve 0.5 % of the space size to cleaning operations */ reserve = 1 + ((size / FSP_EXTENT_SIZE) * 1) / 200; if (n_free <= reserve + n_ext) { goto try_to_extend; } } else { ut_a(alloc_type == FSP_CLEANING); } success = fil_space_reserve_free_extents(space, n_free, n_ext); if (success) { return(TRUE); } try_to_extend: success = fsp_try_extend_data_file(&n_pages_added, space, space_header, mtr); if (success && n_pages_added > 0) { goto try_again; } return(FALSE); } /**********************************************************************//** This function should be used to get information on how much we still will be able to insert new data to the database without running out the tablespace. Only free extents are taken into account and we also subtract the safety margin required by the above function fsp_reserve_free_extents. @return available space in kB */ UNIV_INTERN ullint fsp_get_available_space_in_free_extents( /*====================================*/ ulint space) /*!< in: space id */ { fsp_header_t* space_header; ulint n_free_list_ext; ulint free_limit; ulint size; ulint flags; ulint zip_size; ulint n_free; ulint n_free_up; ulint reserve; rw_lock_t* latch; mtr_t mtr; ut_ad(!mutex_own(&kernel_mutex)); mtr_start(&mtr); latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); mtr_x_lock(latch, &mtr); space_header = fsp_get_space_header(space, zip_size, &mtr); size = mtr_read_ulint(space_header + FSP_SIZE, MLOG_4BYTES, &mtr); n_free_list_ext = flst_get_len(space_header + FSP_FREE, &mtr); free_limit = mtr_read_ulint(space_header + FSP_FREE_LIMIT, MLOG_4BYTES, &mtr); mtr_commit(&mtr); if (size < FSP_EXTENT_SIZE) { ut_a(space != 0); /* This must be a single-table tablespace */ return(0); /* TODO: count free frag pages and return a value based on that */ } /* Below we play safe when counting free extents above the free limit: some of them will contain extent descriptor pages, and therefore will not be free extents */ n_free_up = (size - free_limit) / FSP_EXTENT_SIZE; if (n_free_up > 0) { n_free_up--; if (!zip_size) { n_free_up -= n_free_up / (UNIV_PAGE_SIZE / FSP_EXTENT_SIZE); } else { n_free_up -= n_free_up / (zip_size / FSP_EXTENT_SIZE); } } n_free = n_free_list_ext + n_free_up; /* We reserve 1 extent + 0.5 % of the space size to undo logs and 1 extent + 0.5 % to cleaning operations; NOTE: this source code is duplicated in the function above! */ reserve = 2 + ((size / FSP_EXTENT_SIZE) * 2) / 200; if (reserve > n_free) { return(0); } if (!zip_size) { return((ullint) (n_free - reserve) * FSP_EXTENT_SIZE * (UNIV_PAGE_SIZE / 1024)); } else { return((ullint) (n_free - reserve) * FSP_EXTENT_SIZE * (zip_size / 1024)); } } /********************************************************************//** Marks a page used. The page must reside within the extents of the given segment. */ static void fseg_mark_page_used( /*================*/ fseg_inode_t* seg_inode,/*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset */ mtr_t* mtr) /*!< in: mtr */ { xdes_t* descr; ulint not_full_n_used; ut_ad(seg_inode && mtr); ut_ad(!((page_offset(seg_inode) - FSEG_ARR_OFFSET) % FSEG_INODE_SIZE)); descr = xdes_get_descriptor(space, zip_size, page, mtr); ut_ad(mtr_read_ulint(seg_inode + FSEG_ID, MLOG_4BYTES, mtr) == mtr_read_ulint(descr + XDES_ID, MLOG_4BYTES, mtr)); if (xdes_is_free(descr, mtr)) { /* We move the extent from the free list to the NOT_FULL list */ flst_remove(seg_inode + FSEG_FREE, descr + XDES_FLST_NODE, mtr); flst_add_last(seg_inode + FSEG_NOT_FULL, descr + XDES_FLST_NODE, mtr); } ut_ad(xdes_get_bit(descr, XDES_FREE_BIT, page % FSP_EXTENT_SIZE, mtr) == TRUE); /* We mark the page as used */ xdes_set_bit(descr, XDES_FREE_BIT, page % FSP_EXTENT_SIZE, FALSE, mtr); not_full_n_used = mtr_read_ulint(seg_inode + FSEG_NOT_FULL_N_USED, MLOG_4BYTES, mtr); not_full_n_used++; mlog_write_ulint(seg_inode + FSEG_NOT_FULL_N_USED, not_full_n_used, MLOG_4BYTES, mtr); if (xdes_is_full(descr, mtr)) { /* We move the extent from the NOT_FULL list to the FULL list */ flst_remove(seg_inode + FSEG_NOT_FULL, descr + XDES_FLST_NODE, mtr); flst_add_last(seg_inode + FSEG_FULL, descr + XDES_FLST_NODE, mtr); mlog_write_ulint(seg_inode + FSEG_NOT_FULL_N_USED, not_full_n_used - FSP_EXTENT_SIZE, MLOG_4BYTES, mtr); } } /**********************************************************************//** Frees a single page of a segment. */ static void fseg_free_page_low( /*===============*/ fseg_inode_t* seg_inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: page offset */ mtr_t* mtr) /*!< in: mtr handle */ { xdes_t* descr; ulint not_full_n_used; ulint state; dulint descr_id; dulint seg_id; ulint i; ut_ad(seg_inode && mtr); ut_ad(mach_read_from_4(seg_inode + FSEG_MAGIC_N) == FSEG_MAGIC_N_VALUE); ut_ad(!((page_offset(seg_inode) - FSEG_ARR_OFFSET) % FSEG_INODE_SIZE)); /* Drop search system page hash index if the page is found in the pool and is hashed */ btr_search_drop_page_hash_when_freed(space, zip_size, page); descr = xdes_get_descriptor(space, zip_size, page, mtr); ut_a(descr); if (xdes_get_bit(descr, XDES_FREE_BIT, page % FSP_EXTENT_SIZE, mtr)) { fputs("InnoDB: Dump of the tablespace extent descriptor: ", stderr); ut_print_buf(stderr, descr, 40); fprintf(stderr, "\n" "InnoDB: Serious error! InnoDB is trying to" " free page %lu\n" "InnoDB: though it is already marked as free" " in the tablespace!\n" "InnoDB: The tablespace free space info is corrupt.\n" "InnoDB: You may need to dump your" " InnoDB tables and recreate the whole\n" "InnoDB: database!\n", (ulong) page); crash: fputs("InnoDB: Please refer to\n" "InnoDB: " REFMAN "forcing-recovery.html\n" "InnoDB: about forcing recovery.\n", stderr); ut_error; } state = xdes_get_state(descr, mtr); if (state != XDES_FSEG) { /* The page is in the fragment pages of the segment */ for (i = 0;; i++) { if (fseg_get_nth_frag_page_no(seg_inode, i, mtr) == page) { fseg_set_nth_frag_page_no(seg_inode, i, FIL_NULL, mtr); break; } } fsp_free_page(space, zip_size, page, mtr); return; } /* If we get here, the page is in some extent of the segment */ descr_id = mtr_read_dulint(descr + XDES_ID, mtr); seg_id = mtr_read_dulint(seg_inode + FSEG_ID, mtr); #if 0 fprintf(stderr, "InnoDB: InnoDB is freeing space %lu page %lu,\n" "InnoDB: which belongs to descr seg %lu %lu\n" "InnoDB: segment %lu %lu.\n", (ulong) space, (ulong) page, (ulong) ut_dulint_get_high(descr_id), (ulong) ut_dulint_get_low(descr_id), (ulong) ut_dulint_get_high(seg_id), (ulong) ut_dulint_get_low(seg_id)); #endif /* 0 */ if (0 != ut_dulint_cmp(descr_id, seg_id)) { fputs("InnoDB: Dump of the tablespace extent descriptor: ", stderr); ut_print_buf(stderr, descr, 40); fputs("\nInnoDB: Dump of the segment inode: ", stderr); ut_print_buf(stderr, seg_inode, 40); putc('\n', stderr); fprintf(stderr, "InnoDB: Serious error: InnoDB is trying to" " free space %lu page %lu,\n" "InnoDB: which does not belong to" " segment %lu %lu but belongs\n" "InnoDB: to segment %lu %lu.\n", (ulong) space, (ulong) page, (ulong) ut_dulint_get_high(descr_id), (ulong) ut_dulint_get_low(descr_id), (ulong) ut_dulint_get_high(seg_id), (ulong) ut_dulint_get_low(seg_id)); goto crash; } not_full_n_used = mtr_read_ulint(seg_inode + FSEG_NOT_FULL_N_USED, MLOG_4BYTES, mtr); if (xdes_is_full(descr, mtr)) { /* The fragment is full: move it to another list */ flst_remove(seg_inode + FSEG_FULL, descr + XDES_FLST_NODE, mtr); flst_add_last(seg_inode + FSEG_NOT_FULL, descr + XDES_FLST_NODE, mtr); mlog_write_ulint(seg_inode + FSEG_NOT_FULL_N_USED, not_full_n_used + FSP_EXTENT_SIZE - 1, MLOG_4BYTES, mtr); } else { ut_a(not_full_n_used > 0); mlog_write_ulint(seg_inode + FSEG_NOT_FULL_N_USED, not_full_n_used - 1, MLOG_4BYTES, mtr); } xdes_set_bit(descr, XDES_FREE_BIT, page % FSP_EXTENT_SIZE, TRUE, mtr); xdes_set_bit(descr, XDES_CLEAN_BIT, page % FSP_EXTENT_SIZE, TRUE, mtr); if (xdes_is_free(descr, mtr)) { /* The extent has become free: free it to space */ flst_remove(seg_inode + FSEG_NOT_FULL, descr + XDES_FLST_NODE, mtr); fsp_free_extent(space, zip_size, page, mtr); } } /**********************************************************************//** Frees a single page of a segment. */ UNIV_INTERN void fseg_free_page( /*===========*/ fseg_header_t* seg_header, /*!< in: segment header */ ulint space, /*!< in: space id */ ulint page, /*!< in: page offset */ mtr_t* mtr) /*!< in: mtr handle */ { ulint flags; ulint zip_size; fseg_inode_t* seg_inode; rw_lock_t* latch; latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); seg_inode = fseg_inode_get(seg_header, space, zip_size, mtr); fseg_free_page_low(seg_inode, space, zip_size, page, mtr); #ifdef UNIV_DEBUG_FILE_ACCESSES buf_page_set_file_page_was_freed(space, page); #endif } /**********************************************************************//** Frees an extent of a segment to the space free list. */ static void fseg_free_extent( /*=============*/ fseg_inode_t* seg_inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ ulint page, /*!< in: a page in the extent */ mtr_t* mtr) /*!< in: mtr handle */ { ulint first_page_in_extent; xdes_t* descr; ulint not_full_n_used; ulint descr_n_used; ulint i; ut_ad(seg_inode && mtr); descr = xdes_get_descriptor(space, zip_size, page, mtr); ut_a(xdes_get_state(descr, mtr) == XDES_FSEG); ut_a(0 == ut_dulint_cmp(mtr_read_dulint(descr + XDES_ID, mtr), mtr_read_dulint(seg_inode + FSEG_ID, mtr))); first_page_in_extent = page - (page % FSP_EXTENT_SIZE); for (i = 0; i < FSP_EXTENT_SIZE; i++) { if (FALSE == xdes_get_bit(descr, XDES_FREE_BIT, i, mtr)) { /* Drop search system page hash index if the page is found in the pool and is hashed */ btr_search_drop_page_hash_when_freed( space, zip_size, first_page_in_extent + i); } } if (xdes_is_full(descr, mtr)) { flst_remove(seg_inode + FSEG_FULL, descr + XDES_FLST_NODE, mtr); } else if (xdes_is_free(descr, mtr)) { flst_remove(seg_inode + FSEG_FREE, descr + XDES_FLST_NODE, mtr); } else { flst_remove(seg_inode + FSEG_NOT_FULL, descr + XDES_FLST_NODE, mtr); not_full_n_used = mtr_read_ulint( seg_inode + FSEG_NOT_FULL_N_USED, MLOG_4BYTES, mtr); descr_n_used = xdes_get_n_used(descr, mtr); ut_a(not_full_n_used >= descr_n_used); mlog_write_ulint(seg_inode + FSEG_NOT_FULL_N_USED, not_full_n_used - descr_n_used, MLOG_4BYTES, mtr); } fsp_free_extent(space, zip_size, page, mtr); #ifdef UNIV_DEBUG_FILE_ACCESSES for (i = 0; i < FSP_EXTENT_SIZE; i++) { buf_page_set_file_page_was_freed(space, first_page_in_extent + i); } #endif } /**********************************************************************//** Frees part of a segment. This function can be used to free a segment by repeatedly calling this function in different mini-transactions. Doing the freeing in a single mini-transaction might result in too big a mini-transaction. @return TRUE if freeing completed */ UNIV_INTERN ibool fseg_free_step( /*===========*/ fseg_header_t* header, /*!< in, own: segment header; NOTE: if the header resides on the first page of the frag list of the segment, this pointer becomes obsolete after the last freeing step */ mtr_t* mtr) /*!< in: mtr */ { ulint n; ulint page; xdes_t* descr; fseg_inode_t* inode; ulint space; ulint flags; ulint zip_size; ulint header_page; rw_lock_t* latch; space = page_get_space_id(page_align(header)); header_page = page_get_page_no(page_align(header)); latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); descr = xdes_get_descriptor(space, zip_size, header_page, mtr); /* Check that the header resides on a page which has not been freed yet */ ut_a(descr); ut_a(xdes_get_bit(descr, XDES_FREE_BIT, header_page % FSP_EXTENT_SIZE, mtr) == FALSE); inode = fseg_inode_get(header, space, zip_size, mtr); descr = fseg_get_first_extent(inode, space, zip_size, mtr); if (descr != NULL) { /* Free the extent held by the segment */ page = xdes_get_offset(descr); fseg_free_extent(inode, space, zip_size, page, mtr); return(FALSE); } /* Free a frag page */ n = fseg_find_last_used_frag_page_slot(inode, mtr); if (n == ULINT_UNDEFINED) { /* Freeing completed: free the segment inode */ fsp_free_seg_inode(space, zip_size, inode, mtr); return(TRUE); } fseg_free_page_low(inode, space, zip_size, fseg_get_nth_frag_page_no(inode, n, mtr), mtr); n = fseg_find_last_used_frag_page_slot(inode, mtr); if (n == ULINT_UNDEFINED) { /* Freeing completed: free the segment inode */ fsp_free_seg_inode(space, zip_size, inode, mtr); return(TRUE); } return(FALSE); } /**********************************************************************//** Frees part of a segment. Differs from fseg_free_step because this function leaves the header page unfreed. @return TRUE if freeing completed, except the header page */ UNIV_INTERN ibool fseg_free_step_not_header( /*======================*/ fseg_header_t* header, /*!< in: segment header which must reside on the first fragment page of the segment */ mtr_t* mtr) /*!< in: mtr */ { ulint n; ulint page; xdes_t* descr; fseg_inode_t* inode; ulint space; ulint flags; ulint zip_size; ulint page_no; rw_lock_t* latch; space = page_get_space_id(page_align(header)); latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_ad(!mutex_own(&kernel_mutex) || mtr_memo_contains(mtr, latch, MTR_MEMO_X_LOCK)); mtr_x_lock(latch, mtr); inode = fseg_inode_get(header, space, zip_size, mtr); descr = fseg_get_first_extent(inode, space, zip_size, mtr); if (descr != NULL) { /* Free the extent held by the segment */ page = xdes_get_offset(descr); fseg_free_extent(inode, space, zip_size, page, mtr); return(FALSE); } /* Free a frag page */ n = fseg_find_last_used_frag_page_slot(inode, mtr); if (n == ULINT_UNDEFINED) { ut_error; } page_no = fseg_get_nth_frag_page_no(inode, n, mtr); if (page_no == page_get_page_no(page_align(header))) { return(TRUE); } fseg_free_page_low(inode, space, zip_size, page_no, mtr); return(FALSE); } /**********************************************************************//** Returns the first extent descriptor for a segment. We think of the extent lists of the segment catenated in the order FSEG_FULL -> FSEG_NOT_FULL -> FSEG_FREE. @return the first extent descriptor, or NULL if none */ static xdes_t* fseg_get_first_extent( /*==================*/ fseg_inode_t* inode, /*!< in: segment inode */ ulint space, /*!< in: space id */ ulint zip_size,/*!< in: compressed page size in bytes or 0 for uncompressed pages */ mtr_t* mtr) /*!< in: mtr */ { fil_addr_t first; xdes_t* descr; ut_ad(inode && mtr); ut_ad(space == page_get_space_id(page_align(inode))); first = fil_addr_null; if (flst_get_len(inode + FSEG_FULL, mtr) > 0) { first = flst_get_first(inode + FSEG_FULL, mtr); } else if (flst_get_len(inode + FSEG_NOT_FULL, mtr) > 0) { first = flst_get_first(inode + FSEG_NOT_FULL, mtr); } else if (flst_get_len(inode + FSEG_FREE, mtr) > 0) { first = flst_get_first(inode + FSEG_FREE, mtr); } if (first.page == FIL_NULL) { return(NULL); } descr = xdes_lst_get_descriptor(space, zip_size, first, mtr); return(descr); } /*******************************************************************//** Validates a segment. @return TRUE if ok */ static ibool fseg_validate_low( /*==============*/ fseg_inode_t* inode, /*!< in: segment inode */ mtr_t* mtr2) /*!< in: mtr */ { ulint space; dulint seg_id; mtr_t mtr; xdes_t* descr; fil_addr_t node_addr; ulint n_used = 0; ulint n_used2 = 0; ut_ad(mtr_memo_contains_page(mtr2, inode, MTR_MEMO_PAGE_X_FIX)); ut_ad(mach_read_from_4(inode + FSEG_MAGIC_N) == FSEG_MAGIC_N_VALUE); space = page_get_space_id(page_align(inode)); seg_id = mtr_read_dulint(inode + FSEG_ID, mtr2); n_used = mtr_read_ulint(inode + FSEG_NOT_FULL_N_USED, MLOG_4BYTES, mtr2); flst_validate(inode + FSEG_FREE, mtr2); flst_validate(inode + FSEG_NOT_FULL, mtr2); flst_validate(inode + FSEG_FULL, mtr2); /* Validate FSEG_FREE list */ node_addr = flst_get_first(inode + FSEG_FREE, mtr2); while (!fil_addr_is_null(node_addr)) { ulint flags; ulint zip_size; mtr_start(&mtr); mtr_x_lock(fil_space_get_latch(space, &flags), &mtr); zip_size = dict_table_flags_to_zip_size(flags); descr = xdes_lst_get_descriptor(space, zip_size, node_addr, &mtr); ut_a(xdes_get_n_used(descr, &mtr) == 0); ut_a(xdes_get_state(descr, &mtr) == XDES_FSEG); ut_a(!ut_dulint_cmp(mtr_read_dulint(descr + XDES_ID, &mtr), seg_id)); node_addr = flst_get_next_addr(descr + XDES_FLST_NODE, &mtr); mtr_commit(&mtr); } /* Validate FSEG_NOT_FULL list */ node_addr = flst_get_first(inode + FSEG_NOT_FULL, mtr2); while (!fil_addr_is_null(node_addr)) { ulint flags; ulint zip_size; mtr_start(&mtr); mtr_x_lock(fil_space_get_latch(space, &flags), &mtr); zip_size = dict_table_flags_to_zip_size(flags); descr = xdes_lst_get_descriptor(space, zip_size, node_addr, &mtr); ut_a(xdes_get_n_used(descr, &mtr) > 0); ut_a(xdes_get_n_used(descr, &mtr) < FSP_EXTENT_SIZE); ut_a(xdes_get_state(descr, &mtr) == XDES_FSEG); ut_a(!ut_dulint_cmp(mtr_read_dulint(descr + XDES_ID, &mtr), seg_id)); n_used2 += xdes_get_n_used(descr, &mtr); node_addr = flst_get_next_addr(descr + XDES_FLST_NODE, &mtr); mtr_commit(&mtr); } /* Validate FSEG_FULL list */ node_addr = flst_get_first(inode + FSEG_FULL, mtr2); while (!fil_addr_is_null(node_addr)) { ulint flags; ulint zip_size; mtr_start(&mtr); mtr_x_lock(fil_space_get_latch(space, &flags), &mtr); zip_size = dict_table_flags_to_zip_size(flags); descr = xdes_lst_get_descriptor(space, zip_size, node_addr, &mtr); ut_a(xdes_get_n_used(descr, &mtr) == FSP_EXTENT_SIZE); ut_a(xdes_get_state(descr, &mtr) == XDES_FSEG); ut_a(!ut_dulint_cmp(mtr_read_dulint(descr + XDES_ID, &mtr), seg_id)); node_addr = flst_get_next_addr(descr + XDES_FLST_NODE, &mtr); mtr_commit(&mtr); } ut_a(n_used == n_used2); return(TRUE); } #ifdef UNIV_DEBUG /*******************************************************************//** Validates a segment. @return TRUE if ok */ UNIV_INTERN ibool fseg_validate( /*==========*/ fseg_header_t* header, /*!< in: segment header */ mtr_t* mtr) /*!< in: mtr */ { fseg_inode_t* inode; ibool ret; ulint space; ulint flags; ulint zip_size; space = page_get_space_id(page_align(header)); mtr_x_lock(fil_space_get_latch(space, &flags), mtr); zip_size = dict_table_flags_to_zip_size(flags); inode = fseg_inode_get(header, space, zip_size, mtr); ret = fseg_validate_low(inode, mtr); return(ret); } #endif /* UNIV_DEBUG */ /*******************************************************************//** Writes info of a segment. */ static void fseg_print_low( /*===========*/ fseg_inode_t* inode, /*!< in: segment inode */ mtr_t* mtr) /*!< in: mtr */ { ulint space; ulint seg_id_low; ulint seg_id_high; ulint n_used; ulint n_frag; ulint n_free; ulint n_not_full; ulint n_full; ulint reserved; ulint used; ulint page_no; dulint d_var; ut_ad(mtr_memo_contains_page(mtr, inode, MTR_MEMO_PAGE_X_FIX)); space = page_get_space_id(page_align(inode)); page_no = page_get_page_no(page_align(inode)); reserved = fseg_n_reserved_pages_low(inode, &used, mtr); d_var = mtr_read_dulint(inode + FSEG_ID, mtr); seg_id_low = ut_dulint_get_low(d_var); seg_id_high = ut_dulint_get_high(d_var); n_used = mtr_read_ulint(inode + FSEG_NOT_FULL_N_USED, MLOG_4BYTES, mtr); n_frag = fseg_get_n_frag_pages(inode, mtr); n_free = flst_get_len(inode + FSEG_FREE, mtr); n_not_full = flst_get_len(inode + FSEG_NOT_FULL, mtr); n_full = flst_get_len(inode + FSEG_FULL, mtr); fprintf(stderr, "SEGMENT id %lu %lu space %lu; page %lu;" " res %lu used %lu; full ext %lu\n" "fragm pages %lu; free extents %lu;" " not full extents %lu: pages %lu\n", (ulong) seg_id_high, (ulong) seg_id_low, (ulong) space, (ulong) page_no, (ulong) reserved, (ulong) used, (ulong) n_full, (ulong) n_frag, (ulong) n_free, (ulong) n_not_full, (ulong) n_used); } #ifdef UNIV_BTR_PRINT /*******************************************************************//** Writes info of a segment. */ UNIV_INTERN void fseg_print( /*=======*/ fseg_header_t* header, /*!< in: segment header */ mtr_t* mtr) /*!< in: mtr */ { fseg_inode_t* inode; ulint space; ulint flags; ulint zip_size; space = page_get_space_id(page_align(header)); mtr_x_lock(fil_space_get_latch(space, &flags), mtr); zip_size = dict_table_flags_to_zip_size(flags); inode = fseg_inode_get(header, space, zip_size, mtr); fseg_print_low(inode, mtr); } #endif /* UNIV_BTR_PRINT */ /*******************************************************************//** Validates the file space system and its segments. @return TRUE if ok */ UNIV_INTERN ibool fsp_validate( /*=========*/ ulint space) /*!< in: space id */ { fsp_header_t* header; fseg_inode_t* seg_inode; page_t* seg_inode_page; rw_lock_t* latch; ulint size; ulint flags; ulint zip_size; ulint free_limit; ulint frag_n_used; mtr_t mtr; mtr_t mtr2; xdes_t* descr; fil_addr_t node_addr; fil_addr_t next_node_addr; ulint descr_count = 0; ulint n_used = 0; ulint n_used2 = 0; ulint n_full_frag_pages; ulint n; ulint seg_inode_len_free; ulint seg_inode_len_full; latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); ut_a(ut_is_2pow(zip_size)); ut_a(zip_size <= UNIV_PAGE_SIZE); ut_a(!zip_size || zip_size >= PAGE_ZIP_MIN_SIZE); /* Start first a mini-transaction mtr2 to lock out all other threads from the fsp system */ mtr_start(&mtr2); mtr_x_lock(latch, &mtr2); mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, &mtr); free_limit = mtr_read_ulint(header + FSP_FREE_LIMIT, MLOG_4BYTES, &mtr); frag_n_used = mtr_read_ulint(header + FSP_FRAG_N_USED, MLOG_4BYTES, &mtr); n_full_frag_pages = FSP_EXTENT_SIZE * flst_get_len(header + FSP_FULL_FRAG, &mtr); if (UNIV_UNLIKELY(free_limit > size)) { ut_a(space != 0); ut_a(size < FSP_EXTENT_SIZE); } flst_validate(header + FSP_FREE, &mtr); flst_validate(header + FSP_FREE_FRAG, &mtr); flst_validate(header + FSP_FULL_FRAG, &mtr); mtr_commit(&mtr); /* Validate FSP_FREE list */ mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_FREE, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { mtr_start(&mtr); mtr_x_lock(latch, &mtr); descr_count++; descr = xdes_lst_get_descriptor(space, zip_size, node_addr, &mtr); ut_a(xdes_get_n_used(descr, &mtr) == 0); ut_a(xdes_get_state(descr, &mtr) == XDES_FREE); node_addr = flst_get_next_addr(descr + XDES_FLST_NODE, &mtr); mtr_commit(&mtr); } /* Validate FSP_FREE_FRAG list */ mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_FREE_FRAG, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { mtr_start(&mtr); mtr_x_lock(latch, &mtr); descr_count++; descr = xdes_lst_get_descriptor(space, zip_size, node_addr, &mtr); ut_a(xdes_get_n_used(descr, &mtr) > 0); ut_a(xdes_get_n_used(descr, &mtr) < FSP_EXTENT_SIZE); ut_a(xdes_get_state(descr, &mtr) == XDES_FREE_FRAG); n_used += xdes_get_n_used(descr, &mtr); node_addr = flst_get_next_addr(descr + XDES_FLST_NODE, &mtr); mtr_commit(&mtr); } /* Validate FSP_FULL_FRAG list */ mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_FULL_FRAG, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { mtr_start(&mtr); mtr_x_lock(latch, &mtr); descr_count++; descr = xdes_lst_get_descriptor(space, zip_size, node_addr, &mtr); ut_a(xdes_get_n_used(descr, &mtr) == FSP_EXTENT_SIZE); ut_a(xdes_get_state(descr, &mtr) == XDES_FULL_FRAG); node_addr = flst_get_next_addr(descr + XDES_FLST_NODE, &mtr); mtr_commit(&mtr); } /* Validate segments */ mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_SEG_INODES_FULL, &mtr); seg_inode_len_full = flst_get_len(header + FSP_SEG_INODES_FULL, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { n = 0; do { mtr_start(&mtr); mtr_x_lock(latch, &mtr); seg_inode_page = fut_get_ptr( space, zip_size, node_addr, RW_X_LATCH, &mtr) - FSEG_INODE_PAGE_NODE; seg_inode = fsp_seg_inode_page_get_nth_inode( seg_inode_page, n, zip_size, &mtr); ut_a(!ut_dulint_is_zero( mach_read_from_8(seg_inode + FSEG_ID))); fseg_validate_low(seg_inode, &mtr); descr_count += flst_get_len(seg_inode + FSEG_FREE, &mtr); descr_count += flst_get_len(seg_inode + FSEG_FULL, &mtr); descr_count += flst_get_len(seg_inode + FSEG_NOT_FULL, &mtr); n_used2 += fseg_get_n_frag_pages(seg_inode, &mtr); next_node_addr = flst_get_next_addr( seg_inode_page + FSEG_INODE_PAGE_NODE, &mtr); mtr_commit(&mtr); } while (++n < FSP_SEG_INODES_PER_PAGE(zip_size)); node_addr = next_node_addr; } mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_SEG_INODES_FREE, &mtr); seg_inode_len_free = flst_get_len(header + FSP_SEG_INODES_FREE, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { n = 0; do { mtr_start(&mtr); mtr_x_lock(latch, &mtr); seg_inode_page = fut_get_ptr( space, zip_size, node_addr, RW_X_LATCH, &mtr) - FSEG_INODE_PAGE_NODE; seg_inode = fsp_seg_inode_page_get_nth_inode( seg_inode_page, n, zip_size, &mtr); if (!ut_dulint_is_zero( mach_read_from_8(seg_inode + FSEG_ID))) { fseg_validate_low(seg_inode, &mtr); descr_count += flst_get_len( seg_inode + FSEG_FREE, &mtr); descr_count += flst_get_len( seg_inode + FSEG_FULL, &mtr); descr_count += flst_get_len( seg_inode + FSEG_NOT_FULL, &mtr); n_used2 += fseg_get_n_frag_pages( seg_inode, &mtr); } next_node_addr = flst_get_next_addr( seg_inode_page + FSEG_INODE_PAGE_NODE, &mtr); mtr_commit(&mtr); } while (++n < FSP_SEG_INODES_PER_PAGE(zip_size)); node_addr = next_node_addr; } ut_a(descr_count * FSP_EXTENT_SIZE == free_limit); if (!zip_size) { ut_a(n_used + n_full_frag_pages == n_used2 + 2 * ((free_limit + (UNIV_PAGE_SIZE - 1)) / UNIV_PAGE_SIZE) + seg_inode_len_full + seg_inode_len_free); } else { ut_a(n_used + n_full_frag_pages == n_used2 + 2 * ((free_limit + (zip_size - 1)) / zip_size) + seg_inode_len_full + seg_inode_len_free); } ut_a(frag_n_used == n_used); mtr_commit(&mtr2); return(TRUE); } /*******************************************************************//** Prints info of a file space. */ UNIV_INTERN void fsp_print( /*======*/ ulint space) /*!< in: space id */ { fsp_header_t* header; fseg_inode_t* seg_inode; page_t* seg_inode_page; rw_lock_t* latch; ulint flags; ulint zip_size; ulint size; ulint free_limit; ulint frag_n_used; fil_addr_t node_addr; fil_addr_t next_node_addr; ulint n_free; ulint n_free_frag; ulint n_full_frag; ulint seg_id_low; ulint seg_id_high; ulint n; ulint n_segs = 0; dulint d_var; mtr_t mtr; mtr_t mtr2; latch = fil_space_get_latch(space, &flags); zip_size = dict_table_flags_to_zip_size(flags); /* Start first a mini-transaction mtr2 to lock out all other threads from the fsp system */ mtr_start(&mtr2); mtr_x_lock(latch, &mtr2); mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); size = mtr_read_ulint(header + FSP_SIZE, MLOG_4BYTES, &mtr); free_limit = mtr_read_ulint(header + FSP_FREE_LIMIT, MLOG_4BYTES, &mtr); frag_n_used = mtr_read_ulint(header + FSP_FRAG_N_USED, MLOG_4BYTES, &mtr); n_free = flst_get_len(header + FSP_FREE, &mtr); n_free_frag = flst_get_len(header + FSP_FREE_FRAG, &mtr); n_full_frag = flst_get_len(header + FSP_FULL_FRAG, &mtr); d_var = mtr_read_dulint(header + FSP_SEG_ID, &mtr); seg_id_low = ut_dulint_get_low(d_var); seg_id_high = ut_dulint_get_high(d_var); fprintf(stderr, "FILE SPACE INFO: id %lu\n" "size %lu, free limit %lu, free extents %lu\n" "not full frag extents %lu: used pages %lu," " full frag extents %lu\n" "first seg id not used %lu %lu\n", (ulong) space, (ulong) size, (ulong) free_limit, (ulong) n_free, (ulong) n_free_frag, (ulong) frag_n_used, (ulong) n_full_frag, (ulong) seg_id_high, (ulong) seg_id_low); mtr_commit(&mtr); /* Print segments */ mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_SEG_INODES_FULL, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { n = 0; do { mtr_start(&mtr); mtr_x_lock(latch, &mtr); seg_inode_page = fut_get_ptr( space, zip_size, node_addr, RW_X_LATCH, &mtr) - FSEG_INODE_PAGE_NODE; seg_inode = fsp_seg_inode_page_get_nth_inode( seg_inode_page, n, zip_size, &mtr); ut_a(!ut_dulint_is_zero( mach_read_from_8(seg_inode + FSEG_ID))); fseg_print_low(seg_inode, &mtr); n_segs++; next_node_addr = flst_get_next_addr( seg_inode_page + FSEG_INODE_PAGE_NODE, &mtr); mtr_commit(&mtr); } while (++n < FSP_SEG_INODES_PER_PAGE(zip_size)); node_addr = next_node_addr; } mtr_start(&mtr); mtr_x_lock(latch, &mtr); header = fsp_get_space_header(space, zip_size, &mtr); node_addr = flst_get_first(header + FSP_SEG_INODES_FREE, &mtr); mtr_commit(&mtr); while (!fil_addr_is_null(node_addr)) { n = 0; do { mtr_start(&mtr); mtr_x_lock(latch, &mtr); seg_inode_page = fut_get_ptr( space, zip_size, node_addr, RW_X_LATCH, &mtr) - FSEG_INODE_PAGE_NODE; seg_inode = fsp_seg_inode_page_get_nth_inode( seg_inode_page, n, zip_size, &mtr); if (!ut_dulint_is_zero( mach_read_from_8(seg_inode + FSEG_ID))) { fseg_print_low(seg_inode, &mtr); n_segs++; } next_node_addr = flst_get_next_addr( seg_inode_page + FSEG_INODE_PAGE_NODE, &mtr); mtr_commit(&mtr); } while (++n < FSP_SEG_INODES_PER_PAGE(zip_size)); node_addr = next_node_addr; } mtr_commit(&mtr2); fprintf(stderr, "NUMBER of file segments: %lu\n", (ulong) n_segs); } #endif /* !UNIV_HOTBACKUP */