/* Copyright (C) 2000-2006 MySQL AB 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 */ /* Describe, check and repair of MyISAM tables */ /* About checksum calculation. There are two types of checksums. Table checksum and row checksum. Row checksum is an additional byte at the end of dynamic length records. It must be calculated if the table is configured for them. Otherwise they must not be used. The variable MYISAM_SHARE::calc_checksum determines if row checksums are used. MI_INFO::checksum is used as temporary storage during row handling. For parallel repair we must assure that only one thread can use this variable. There is no problem on the write side as this is done by one thread only. But when checking a record after read this could go wrong. But since all threads read through a common read buffer, it is sufficient if only one thread checks it. Table checksum is an eight byte value in the header of the index file. It can be calculated even if row checksums are not used. The variable MI_CHECK::glob_crc is calculated over all records. MI_SORT_PARAM::calc_checksum determines if this should be done. This variable is not part of MI_CHECK because it must be set per thread for parallel repair. The global glob_crc must be changed by one thread only. And it is sufficient to calculate the checksum once only. */ #include "ftdefs.h" #include #include #include #ifdef HAVE_SYS_VADVISE_H #include #endif #ifdef HAVE_SYS_MMAN_H #include #endif #include "rt_index.h" #ifndef USE_RAID #define my_raid_create(A,B,C,D,E,F,G) my_create(A,B,C,G) #define my_raid_delete(A,B,C) my_delete(A,B) #endif /* Functions defined in this file */ static int check_k_link(MI_CHECK *param, MI_INFO *info,uint nr); static int chk_index(MI_CHECK *param, MI_INFO *info,MI_KEYDEF *keyinfo, my_off_t page, uchar *buff, ha_rows *keys, ha_checksum *key_checksum, uint level); static uint isam_key_length(MI_INFO *info,MI_KEYDEF *keyinfo); static ha_checksum calc_checksum(ha_rows count); static int writekeys(MI_SORT_PARAM *sort_param); static int sort_one_index(MI_CHECK *param, MI_INFO *info,MI_KEYDEF *keyinfo, my_off_t pagepos, File new_file); static int sort_key_read(MI_SORT_PARAM *sort_param,void *key); static int sort_ft_key_read(MI_SORT_PARAM *sort_param,void *key); static int sort_get_next_record(MI_SORT_PARAM *sort_param); static int sort_key_cmp(MI_SORT_PARAM *sort_param, const void *a,const void *b); static int sort_ft_key_write(MI_SORT_PARAM *sort_param, const void *a); static int sort_key_write(MI_SORT_PARAM *sort_param, const void *a); static my_off_t get_record_for_key(MI_INFO *info,MI_KEYDEF *keyinfo, uchar *key); static int sort_insert_key(MI_SORT_PARAM *sort_param, reg1 SORT_KEY_BLOCKS *key_block, uchar *key, my_off_t prev_block); static int sort_delete_record(MI_SORT_PARAM *sort_param); /*static int flush_pending_blocks(MI_CHECK *param);*/ static SORT_KEY_BLOCKS *alloc_key_blocks(MI_CHECK *param, uint blocks, uint buffer_length); static ha_checksum mi_byte_checksum(const byte *buf, uint length); static void set_data_file_type(SORT_INFO *sort_info, MYISAM_SHARE *share); void myisamchk_init(MI_CHECK *param) { bzero((gptr) param,sizeof(*param)); param->opt_follow_links=1; param->keys_in_use= ~(ulonglong) 0; param->search_after_block=HA_OFFSET_ERROR; param->auto_increment_value= 0; param->use_buffers=USE_BUFFER_INIT; param->read_buffer_length=READ_BUFFER_INIT; param->write_buffer_length=READ_BUFFER_INIT; param->sort_buffer_length=SORT_BUFFER_INIT; param->sort_key_blocks=BUFFERS_WHEN_SORTING; param->tmpfile_createflag=O_RDWR | O_TRUNC | O_EXCL; param->myf_rw=MYF(MY_NABP | MY_WME | MY_WAIT_IF_FULL); param->start_check_pos=0; param->max_record_length= LONGLONG_MAX; param->key_cache_block_size= KEY_CACHE_BLOCK_SIZE; param->stats_method= MI_STATS_METHOD_NULLS_NOT_EQUAL; } /* Check the status flags for the table */ int chk_status(MI_CHECK *param, register MI_INFO *info) { MYISAM_SHARE *share=info->s; if (mi_is_crashed_on_repair(info)) mi_check_print_warning(param, "Table is marked as crashed and last repair failed"); else if (mi_is_crashed(info)) mi_check_print_warning(param, "Table is marked as crashed"); if (share->state.open_count != (uint) (info->s->global_changed ? 1 : 0)) { /* Don't count this as a real warning, as check can correct this ! */ uint save=param->warning_printed; mi_check_print_warning(param, share->state.open_count==1 ? "%d client is using or hasn't closed the table properly" : "%d clients are using or haven't closed the table properly", share->state.open_count); /* If this will be fixed by the check, forget the warning */ if (param->testflag & T_UPDATE_STATE) param->warning_printed=save; } return 0; } /* Check delete links */ int chk_del(MI_CHECK *param, register MI_INFO *info, uint test_flag) { reg2 ha_rows i; uint delete_link_length; my_off_t empty,next_link,old_link; char buff[22],buff2[22]; DBUG_ENTER("chk_del"); LINT_INIT(old_link); param->record_checksum=0; delete_link_length=((info->s->options & HA_OPTION_PACK_RECORD) ? 20 : info->s->rec_reflength+1); if (!(test_flag & T_SILENT)) puts("- check record delete-chain"); next_link=info->s->state.dellink; if (info->state->del == 0) { if (test_flag & T_VERBOSE) { puts("No recordlinks"); } } else { if (test_flag & T_VERBOSE) printf("Recordlinks: "); empty=0; for (i= info->state->del ; i > 0L && next_link != HA_OFFSET_ERROR ; i--) { if (*killed_ptr(param)) DBUG_RETURN(1); if (test_flag & T_VERBOSE) printf(" %9s",llstr(next_link,buff)); if (next_link >= info->state->data_file_length) goto wrong; if (my_pread(info->dfile,(char*) buff,delete_link_length, next_link,MYF(MY_NABP))) { if (test_flag & T_VERBOSE) puts(""); mi_check_print_error(param,"Can't read delete-link at filepos: %s", llstr(next_link,buff)); DBUG_RETURN(1); } if (*buff != '\0') { if (test_flag & T_VERBOSE) puts(""); mi_check_print_error(param,"Record at pos: %s is not remove-marked", llstr(next_link,buff)); goto wrong; } if (info->s->options & HA_OPTION_PACK_RECORD) { my_off_t prev_link=mi_sizekorr(buff+12); if (empty && prev_link != old_link) { if (test_flag & T_VERBOSE) puts(""); mi_check_print_error(param,"Deleted block at %s doesn't point back at previous delete link",llstr(next_link,buff2)); goto wrong; } old_link=next_link; next_link=mi_sizekorr(buff+4); empty+=mi_uint3korr(buff+1); } else { param->record_checksum+=(ha_checksum) next_link; next_link=_mi_rec_pos(info->s,(uchar*) buff+1); empty+=info->s->base.pack_reclength; } } if (test_flag & T_VERBOSE) puts("\n"); if (empty != info->state->empty) { mi_check_print_warning(param, "Found %s deleted space in delete link chain. Should be %s", llstr(empty,buff2), llstr(info->state->empty,buff)); } if (next_link != HA_OFFSET_ERROR) { mi_check_print_error(param, "Found more than the expected %s deleted rows in delete link chain", llstr(info->state->del, buff)); goto wrong; } if (i != 0) { mi_check_print_error(param, "Found %s deleted rows in delete link chain. Should be %s", llstr(info->state->del - i, buff2), llstr(info->state->del, buff)); goto wrong; } } DBUG_RETURN(0); wrong: param->testflag|=T_RETRY_WITHOUT_QUICK; if (test_flag & T_VERBOSE) puts(""); mi_check_print_error(param,"record delete-link-chain corrupted"); DBUG_RETURN(1); } /* chk_del */ /* Check delete links in index file */ static int check_k_link(MI_CHECK *param, register MI_INFO *info, uint nr) { my_off_t next_link; uint block_size=(nr+1)*MI_MIN_KEY_BLOCK_LENGTH; ha_rows records; char llbuff[21], llbuff2[21], *buff; DBUG_ENTER("check_k_link"); DBUG_PRINT("enter", ("block_size: %u", block_size)); if (param->testflag & T_VERBOSE) printf("block_size %4u:", block_size); /* purecov: tested */ next_link=info->s->state.key_del[nr]; records= (ha_rows) (info->state->key_file_length / block_size); while (next_link != HA_OFFSET_ERROR && records > 0) { if (*killed_ptr(param)) DBUG_RETURN(1); if (param->testflag & T_VERBOSE) printf("%16s",llstr(next_link,llbuff)); /* Key blocks must lay within the key file length entirely. */ if (next_link + block_size > info->state->key_file_length) { /* purecov: begin tested */ mi_check_print_error(param, "Invalid key block position: %s " "key block size: %u file_length: %s", llstr(next_link, llbuff), block_size, llstr(info->state->key_file_length, llbuff2)); DBUG_RETURN(1); /* purecov: end */ } /* Key blocks must be aligned at MI_MIN_KEY_BLOCK_LENGTH. */ if (next_link & (MI_MIN_KEY_BLOCK_LENGTH - 1)) { /* purecov: begin tested */ mi_check_print_error(param, "Mis-aligned key block: %s " "minimum key block length: %u", llstr(next_link, llbuff), MI_MIN_KEY_BLOCK_LENGTH); DBUG_RETURN(1); /* purecov: end */ } /* Read the key block with MI_MIN_KEY_BLOCK_LENGTH to find next link. If the key cache block size is smaller than block_size, we can so avoid unecessary eviction of cache block. */ if (!(buff=key_cache_read(info->s->key_cache, info->s->kfile, next_link, DFLT_INIT_HITS, (byte*) info->buff, MI_MIN_KEY_BLOCK_LENGTH, MI_MIN_KEY_BLOCK_LENGTH, 1))) { /* purecov: begin tested */ mi_check_print_error(param, "key cache read error for block: %s", llstr(next_link,llbuff)); DBUG_RETURN(1); /* purecov: end */ } next_link=mi_sizekorr(buff); records--; param->key_file_blocks+=block_size; } if (param->testflag & T_VERBOSE) { if (next_link != HA_OFFSET_ERROR) printf("%16s\n",llstr(next_link,llbuff)); else puts(""); } DBUG_RETURN (next_link != HA_OFFSET_ERROR); } /* check_k_link */ /* Check sizes of files */ int chk_size(MI_CHECK *param, register MI_INFO *info) { int error=0; register my_off_t skr,size; char buff[22],buff2[22]; DBUG_ENTER("chk_size"); if (!(param->testflag & T_SILENT)) puts("- check file-size"); /* The following is needed if called externally (not from myisamchk) */ flush_key_blocks(info->s->key_cache, info->s->kfile, FLUSH_FORCE_WRITE); size= my_seek(info->s->kfile, 0L, MY_SEEK_END, MYF(MY_THREADSAFE)); if ((skr=(my_off_t) info->state->key_file_length) != size) { /* Don't give error if file generated by myisampack */ if (skr > size && mi_is_any_key_active(info->s->state.key_map)) { error=1; mi_check_print_error(param, "Size of indexfile is: %-8s Should be: %s", llstr(size,buff), llstr(skr,buff2)); } else mi_check_print_warning(param, "Size of indexfile is: %-8s Should be: %s", llstr(size,buff), llstr(skr,buff2)); } if (!(param->testflag & T_VERY_SILENT) && ! (info->s->options & HA_OPTION_COMPRESS_RECORD) && ulonglong2double(info->state->key_file_length) > ulonglong2double(info->s->base.margin_key_file_length)*0.9) mi_check_print_warning(param,"Keyfile is almost full, %10s of %10s used", llstr(info->state->key_file_length,buff), llstr(info->s->base.max_key_file_length-1,buff)); size=my_seek(info->dfile,0L,MY_SEEK_END,MYF(0)); skr=(my_off_t) info->state->data_file_length; if (info->s->options & HA_OPTION_COMPRESS_RECORD) skr+= MEMMAP_EXTRA_MARGIN; #ifdef USE_RELOC if (info->data_file_type == STATIC_RECORD && skr < (my_off_t) info->s->base.reloc*info->s->base.min_pack_length) skr=(my_off_t) info->s->base.reloc*info->s->base.min_pack_length; #endif if (skr != size) { info->state->data_file_length=size; /* Skip other errors */ if (skr > size && skr != size + MEMMAP_EXTRA_MARGIN) { error=1; mi_check_print_error(param,"Size of datafile is: %-9s Should be: %s", llstr(size,buff), llstr(skr,buff2)); param->testflag|=T_RETRY_WITHOUT_QUICK; } else { mi_check_print_warning(param, "Size of datafile is: %-9s Should be: %s", llstr(size,buff), llstr(skr,buff2)); } } if (!(param->testflag & T_VERY_SILENT) && !(info->s->options & HA_OPTION_COMPRESS_RECORD) && ulonglong2double(info->state->data_file_length) > (ulonglong2double(info->s->base.max_data_file_length)*0.9)) mi_check_print_warning(param, "Datafile is almost full, %10s of %10s used", llstr(info->state->data_file_length,buff), llstr(info->s->base.max_data_file_length-1,buff2)); DBUG_RETURN(error); } /* chk_size */ /* Check keys */ int chk_key(MI_CHECK *param, register MI_INFO *info) { uint key,found_keys=0,full_text_keys=0,result=0; ha_rows keys; ha_checksum old_record_checksum,init_checksum; my_off_t all_keydata,all_totaldata,key_totlength,length; ulong *rec_per_key_part; MYISAM_SHARE *share=info->s; MI_KEYDEF *keyinfo; char buff[22],buff2[22]; DBUG_ENTER("chk_key"); if (!(param->testflag & T_SILENT)) puts("- check key delete-chain"); param->key_file_blocks=info->s->base.keystart; for (key=0 ; key < info->s->state.header.max_block_size ; key++) if (check_k_link(param,info,key)) { if (param->testflag & T_VERBOSE) puts(""); mi_check_print_error(param,"key delete-link-chain corrupted"); DBUG_RETURN(-1); } if (!(param->testflag & T_SILENT)) puts("- check index reference"); all_keydata=all_totaldata=key_totlength=0; old_record_checksum=0; init_checksum=param->record_checksum; if (!(share->options & (HA_OPTION_PACK_RECORD | HA_OPTION_COMPRESS_RECORD))) old_record_checksum=calc_checksum(info->state->records+info->state->del-1)* share->base.pack_reclength; rec_per_key_part= param->rec_per_key_part; for (key= 0,keyinfo= &share->keyinfo[0]; key < share->base.keys ; rec_per_key_part+=keyinfo->keysegs, key++, keyinfo++) { param->key_crc[key]=0; if (! mi_is_key_active(share->state.key_map, key)) { /* Remember old statistics for key */ memcpy((char*) rec_per_key_part, (char*) (share->state.rec_per_key_part + (uint) (rec_per_key_part - param->rec_per_key_part)), keyinfo->keysegs*sizeof(*rec_per_key_part)); continue; } found_keys++; param->record_checksum=init_checksum; bzero((char*) ¶m->unique_count,sizeof(param->unique_count)); bzero((char*) ¶m->notnull_count,sizeof(param->notnull_count)); if ((!(param->testflag & T_SILENT))) printf ("- check data record references index: %d\n",key+1); if (keyinfo->flag & (HA_FULLTEXT | HA_SPATIAL)) full_text_keys++; if (share->state.key_root[key] == HA_OFFSET_ERROR && (info->state->records == 0 || keyinfo->flag & HA_FULLTEXT)) goto do_stat; if (!_mi_fetch_keypage(info,keyinfo,share->state.key_root[key], DFLT_INIT_HITS,info->buff,0)) { mi_check_print_error(param,"Can't read indexpage from filepos: %s", llstr(share->state.key_root[key],buff)); if (!(param->testflag & T_INFO)) DBUG_RETURN(-1); result= -1; continue; } param->key_file_blocks+=keyinfo->block_length; keys=0; param->keydata=param->totaldata=0; param->key_blocks=0; param->max_level=0; if (chk_index(param,info,keyinfo,share->state.key_root[key],info->buff, &keys, param->key_crc+key,1)) DBUG_RETURN(-1); if(!(keyinfo->flag & (HA_FULLTEXT | HA_SPATIAL))) { if (keys != info->state->records) { mi_check_print_error(param,"Found %s keys of %s",llstr(keys,buff), llstr(info->state->records,buff2)); if (!(param->testflag & T_INFO)) DBUG_RETURN(-1); result= -1; continue; } if (found_keys - full_text_keys == 1 && ((share->options & (HA_OPTION_PACK_RECORD | HA_OPTION_COMPRESS_RECORD)) || (param->testflag & T_DONT_CHECK_CHECKSUM))) old_record_checksum=param->record_checksum; else if (old_record_checksum != param->record_checksum) { if (key) mi_check_print_error(param,"Key %u doesn't point at same records that key 1", key+1); else mi_check_print_error(param,"Key 1 doesn't point at all records"); if (!(param->testflag & T_INFO)) DBUG_RETURN(-1); result= -1; continue; } } if ((uint) share->base.auto_key -1 == key) { /* Check that auto_increment key is bigger than max key value */ ulonglong auto_increment; info->lastinx=key; _mi_read_key_record(info, 0L, info->rec_buff); auto_increment= retrieve_auto_increment(info, info->rec_buff); if (auto_increment > info->s->state.auto_increment) { mi_check_print_warning(param, "Auto-increment value: %s is smaller " "than max used value: %s", llstr(info->s->state.auto_increment,buff2), llstr(auto_increment, buff)); } if (param->testflag & T_AUTO_INC) { set_if_bigger(info->s->state.auto_increment, auto_increment); set_if_bigger(info->s->state.auto_increment, param->auto_increment_value); } /* Check that there isn't a row with auto_increment = 0 in the table */ mi_extra(info,HA_EXTRA_KEYREAD,0); bzero(info->lastkey,keyinfo->seg->length); if (!mi_rkey(info, info->rec_buff, key, (const byte*) info->lastkey, keyinfo->seg->length, HA_READ_KEY_EXACT)) { /* Don't count this as a real warning, as myisamchk can't correct it */ uint save=param->warning_printed; mi_check_print_warning(param, "Found row where the auto_increment " "column has the value 0"); param->warning_printed=save; } mi_extra(info,HA_EXTRA_NO_KEYREAD,0); } length=(my_off_t) isam_key_length(info,keyinfo)*keys + param->key_blocks*2; if (param->testflag & T_INFO && param->totaldata != 0L && keys != 0L) printf("Key: %2d: Keyblocks used: %3d%% Packed: %4d%% Max levels: %2d\n", key+1, (int) (my_off_t2double(param->keydata)*100.0/my_off_t2double(param->totaldata)), (int) ((my_off_t2double(length) - my_off_t2double(param->keydata))*100.0/ my_off_t2double(length)), param->max_level); all_keydata+=param->keydata; all_totaldata+=param->totaldata; key_totlength+=length; do_stat: if (param->testflag & T_STATISTICS) update_key_parts(keyinfo, rec_per_key_part, param->unique_count, param->stats_method == MI_STATS_METHOD_IGNORE_NULLS? param->notnull_count: NULL, (ulonglong)info->state->records); } if (param->testflag & T_INFO) { if (all_totaldata != 0L && found_keys > 0) printf("Total: Keyblocks used: %3d%% Packed: %4d%%\n\n", (int) (my_off_t2double(all_keydata)*100.0/ my_off_t2double(all_totaldata)), (int) ((my_off_t2double(key_totlength) - my_off_t2double(all_keydata))*100.0/ my_off_t2double(key_totlength))); else if (all_totaldata != 0L && mi_is_any_key_active(share->state.key_map)) puts(""); } if (param->key_file_blocks != info->state->key_file_length && param->keys_in_use != ~(ulonglong) 0) mi_check_print_warning(param, "Some data are unreferenced in keyfile"); if (found_keys != full_text_keys) param->record_checksum=old_record_checksum-init_checksum; /* Remove delete links */ else param->record_checksum=0; DBUG_RETURN(result); } /* chk_key */ static int chk_index_down(MI_CHECK *param, MI_INFO *info, MI_KEYDEF *keyinfo, my_off_t page, uchar *buff, ha_rows *keys, ha_checksum *key_checksum, uint level) { char llbuff[22],llbuff2[22]; DBUG_ENTER("chk_index_down"); /* Key blocks must lay within the key file length entirely. */ if (page + keyinfo->block_length > info->state->key_file_length) { /* purecov: begin tested */ /* Give it a chance to fit in the real file size. */ my_off_t max_length= my_seek(info->s->kfile, 0L, MY_SEEK_END, MYF(MY_THREADSAFE)); mi_check_print_error(param, "Invalid key block position: %s " "key block size: %u file_length: %s", llstr(page, llbuff), keyinfo->block_length, llstr(info->state->key_file_length, llbuff2)); if (page + keyinfo->block_length > max_length) goto err; /* Fix the remebered key file length. */ info->state->key_file_length= (max_length & ~ (my_off_t) (keyinfo->block_length - 1)); /* purecov: end */ } /* Key blocks must be aligned at MI_MIN_KEY_BLOCK_LENGTH. */ if (page & (MI_MIN_KEY_BLOCK_LENGTH - 1)) { /* purecov: begin tested */ mi_check_print_error(param, "Mis-aligned key block: %s " "minimum key block length: %u", llstr(page, llbuff), MI_MIN_KEY_BLOCK_LENGTH); goto err; /* purecov: end */ } if (!_mi_fetch_keypage(info,keyinfo,page, DFLT_INIT_HITS,buff,0)) { mi_check_print_error(param,"Can't read key from filepos: %s", llstr(page,llbuff)); goto err; } param->key_file_blocks+=keyinfo->block_length; if (chk_index(param,info,keyinfo,page,buff,keys,key_checksum,level)) goto err; DBUG_RETURN(0); /* purecov: begin tested */ err: DBUG_RETURN(1); /* purecov: end */ } /* "Ignore NULLs" statistics collection method: process first index tuple. SYNOPSIS mi_collect_stats_nonulls_first() keyseg IN Array of key part descriptions notnull INOUT Array, notnull[i] = (number of {keypart1...keypart_i} tuples that don't contain NULLs) key IN Key values tuple DESCRIPTION Process the first index tuple - find out which prefix tuples don't contain NULLs, and update the array of notnull counters accordingly. */ static void mi_collect_stats_nonulls_first(HA_KEYSEG *keyseg, ulonglong *notnull, uchar *key) { uint first_null, kp; first_null= ha_find_null(keyseg, key) - keyseg; /* All prefix tuples that don't include keypart_{first_null} are not-null tuples (and all others aren't), increment counters for them. */ for (kp= 0; kp < first_null; kp++) notnull[kp]++; } /* "Ignore NULLs" statistics collection method: process next index tuple. SYNOPSIS mi_collect_stats_nonulls_next() keyseg IN Array of key part descriptions notnull INOUT Array, notnull[i] = (number of {keypart1...keypart_i} tuples that don't contain NULLs) prev_key IN Previous key values tuple last_key IN Next key values tuple DESCRIPTION Process the next index tuple: 1. Find out which prefix tuples of last_key don't contain NULLs, and update the array of notnull counters accordingly. 2. Find the first keypart number where the prev_key and last_key tuples are different(A), or last_key has NULL value(B), and return it, so the caller can count number of unique tuples for each key prefix. We don't need (B) to be counted, and that is compensated back in update_key_parts(). RETURN 1 + number of first keypart where values differ or last_key tuple has NULL */ static int mi_collect_stats_nonulls_next(HA_KEYSEG *keyseg, ulonglong *notnull, uchar *prev_key, uchar *last_key) { uint diffs[2]; uint first_null_seg, kp; HA_KEYSEG *seg; /* Find the first keypart where values are different or either of them is NULL. We get results in diffs array: diffs[0]= 1 + number of first different keypart diffs[1]=offset: (last_key + diffs[1]) points to first value in last_key that is NULL or different from corresponding value in prev_key. */ ha_key_cmp(keyseg, prev_key, last_key, USE_WHOLE_KEY, SEARCH_FIND | SEARCH_NULL_ARE_NOT_EQUAL, diffs); seg= keyseg + diffs[0] - 1; /* Find first NULL in last_key */ first_null_seg= ha_find_null(seg, last_key + diffs[1]) - keyseg; for (kp= 0; kp < first_null_seg; kp++) notnull[kp]++; /* Return 1+ number of first key part where values differ. Don't care if these were NULLs and not .... We compensate for that in update_key_parts. */ return diffs[0]; } /* Check if index is ok */ static int chk_index(MI_CHECK *param, MI_INFO *info, MI_KEYDEF *keyinfo, my_off_t page, uchar *buff, ha_rows *keys, ha_checksum *key_checksum, uint level) { int flag; uint used_length,comp_flag,nod_flag,key_length=0; uchar key[MI_MAX_POSSIBLE_KEY_BUFF],*temp_buff,*keypos,*old_keypos,*endpos; my_off_t next_page,record; char llbuff[22]; uint diff_pos[2]; DBUG_ENTER("chk_index"); DBUG_DUMP("buff",(uchar*) buff,mi_getint(buff)); /* TODO: implement appropriate check for RTree keys */ if (keyinfo->flag & HA_SPATIAL) DBUG_RETURN(0); if (!(temp_buff=(uchar*) my_alloca((uint) keyinfo->block_length))) { mi_check_print_error(param,"Not enough memory for keyblock"); DBUG_RETURN(-1); } if (keyinfo->flag & HA_NOSAME) comp_flag=SEARCH_FIND | SEARCH_UPDATE; /* Not real duplicates */ else comp_flag=SEARCH_SAME; /* Keys in positionorder */ nod_flag=mi_test_if_nod(buff); used_length=mi_getint(buff); keypos=buff+2+nod_flag; endpos=buff+used_length; param->keydata+=used_length; param->totaldata+=keyinfo->block_length; /* INFO */ param->key_blocks++; if (level > param->max_level) param->max_level=level; if (used_length > keyinfo->block_length) { mi_check_print_error(param,"Wrong pageinfo at page: %s", llstr(page,llbuff)); goto err; } for ( ;; ) { if (*killed_ptr(param)) goto err; memcpy((char*) info->lastkey,(char*) key,key_length); info->lastkey_length=key_length; if (nod_flag) { next_page=_mi_kpos(nod_flag,keypos); if (chk_index_down(param,info,keyinfo,next_page, temp_buff,keys,key_checksum,level+1)) goto err; } old_keypos=keypos; if (keypos >= endpos || (key_length=(*keyinfo->get_key)(keyinfo,nod_flag,&keypos,key)) == 0) break; if (keypos > endpos) { mi_check_print_error(param,"Wrong key block length at page: %s",llstr(page,llbuff)); goto err; } if ((*keys)++ && (flag=ha_key_cmp(keyinfo->seg,info->lastkey,key,key_length, comp_flag, diff_pos)) >=0) { DBUG_DUMP("old",(uchar*) info->lastkey, info->lastkey_length); DBUG_DUMP("new",(uchar*) key, key_length); DBUG_DUMP("new_in_page",(uchar*) old_keypos,(uint) (keypos-old_keypos)); if (comp_flag & SEARCH_FIND && flag == 0) mi_check_print_error(param,"Found duplicated key at page %s",llstr(page,llbuff)); else mi_check_print_error(param,"Key in wrong position at page %s",llstr(page,llbuff)); goto err; } if (param->testflag & T_STATISTICS) { if (*keys != 1L) /* not first_key */ { if (param->stats_method == MI_STATS_METHOD_NULLS_NOT_EQUAL) ha_key_cmp(keyinfo->seg,info->lastkey,key,USE_WHOLE_KEY, SEARCH_FIND | SEARCH_NULL_ARE_NOT_EQUAL, diff_pos); else if (param->stats_method == MI_STATS_METHOD_IGNORE_NULLS) { diff_pos[0]= mi_collect_stats_nonulls_next(keyinfo->seg, param->notnull_count, info->lastkey, key); } param->unique_count[diff_pos[0]-1]++; } else { if (param->stats_method == MI_STATS_METHOD_IGNORE_NULLS) mi_collect_stats_nonulls_first(keyinfo->seg, param->notnull_count, key); } } (*key_checksum)+= mi_byte_checksum((byte*) key, key_length- info->s->rec_reflength); record= _mi_dpos(info,0,key+key_length); if (keyinfo->flag & HA_FULLTEXT) /* special handling for ft2 */ { uint off; int subkeys; get_key_full_length_rdonly(off, key); subkeys=ft_sintXkorr(key+off); if (subkeys < 0) { ha_rows tmp_keys=0; if (chk_index_down(param,info,&info->s->ft2_keyinfo,record, temp_buff,&tmp_keys,key_checksum,1)) goto err; if (tmp_keys + subkeys) { mi_check_print_error(param, "Number of words in the 2nd level tree " "does not match the number in the header. " "Parent word in on the page %s, offset %u", llstr(page,llbuff), (uint) (old_keypos-buff)); goto err; } (*keys)+=tmp_keys-1; continue; } /* fall through */ } if (record >= info->state->data_file_length) { #ifndef DBUG_OFF char llbuff2[22], llbuff3[22]; #endif mi_check_print_error(param,"Found key at page %s that points to record outside datafile",llstr(page,llbuff)); DBUG_PRINT("test",("page: %s record: %s filelength: %s", llstr(page,llbuff),llstr(record,llbuff2), llstr(info->state->data_file_length,llbuff3))); DBUG_DUMP("key",(uchar*) key,key_length); DBUG_DUMP("new_in_page",(uchar*) old_keypos,(uint) (keypos-old_keypos)); goto err; } param->record_checksum+=(ha_checksum) record; } if (keypos != endpos) { mi_check_print_error(param,"Keyblock size at page %s is not correct. Block length: %d key length: %d", llstr(page,llbuff), used_length, (keypos - buff)); goto err; } my_afree((byte*) temp_buff); DBUG_RETURN(0); err: my_afree((byte*) temp_buff); DBUG_RETURN(1); } /* chk_index */ /* Calculate a checksum of 1+2+3+4...N = N*(N+1)/2 without overflow */ static ha_checksum calc_checksum(ha_rows count) { ulonglong sum,a,b; DBUG_ENTER("calc_checksum"); sum=0; a=count; b=count+1; if (a & 1) b>>=1; else a>>=1; while (b) { if (b & 1) sum+=a; a<<=1; b>>=1; } DBUG_PRINT("exit",("sum: %lx",(ulong) sum)); DBUG_RETURN((ha_checksum) sum); } /* calc_checksum */ /* Calc length of key in normal isam */ static uint isam_key_length(MI_INFO *info, register MI_KEYDEF *keyinfo) { uint length; HA_KEYSEG *keyseg; DBUG_ENTER("isam_key_length"); length= info->s->rec_reflength; for (keyseg=keyinfo->seg ; keyseg->type ; keyseg++) length+= keyseg->length; DBUG_PRINT("exit",("length: %d",length)); DBUG_RETURN(length); } /* key_length */ /* Check that record-link is ok */ int chk_data_link(MI_CHECK *param, MI_INFO *info,int extend) { int error,got_error,flag; uint key,left_length,b_type,field; ha_rows records,del_blocks; my_off_t used,empty,pos,splits,start_recpos, del_length,link_used,start_block; byte *record= 0, *to; char llbuff[22],llbuff2[22],llbuff3[22]; ha_checksum intern_record_checksum; ha_checksum key_checksum[MI_MAX_POSSIBLE_KEY]; my_bool static_row_size; MI_KEYDEF *keyinfo; MI_BLOCK_INFO block_info; DBUG_ENTER("chk_data_link"); if (!(param->testflag & T_SILENT)) { if (extend) puts("- check records and index references"); else puts("- check record links"); } if (!mi_alloc_rec_buff(info, -1, &record)) { mi_check_print_error(param,"Not enough memory for record"); DBUG_RETURN(-1); } records=del_blocks=0; used=link_used=splits=del_length=0; intern_record_checksum=param->glob_crc=0; LINT_INIT(left_length); LINT_INIT(start_recpos); LINT_INIT(to); got_error=error=0; empty=info->s->pack.header_length; /* Check how to calculate checksum of rows */ static_row_size=1; if (info->s->data_file_type == COMPRESSED_RECORD) { for (field=0 ; field < info->s->base.fields ; field++) { if (info->s->rec[field].base_type == FIELD_BLOB || info->s->rec[field].base_type == FIELD_VARCHAR) { static_row_size=0; break; } } } pos=my_b_tell(¶m->read_cache); bzero((char*) key_checksum, info->s->base.keys * sizeof(key_checksum[0])); while (pos < info->state->data_file_length) { if (*killed_ptr(param)) goto err2; switch (info->s->data_file_type) { case STATIC_RECORD: if (my_b_read(¶m->read_cache,(byte*) record, info->s->base.pack_reclength)) goto err; start_recpos=pos; pos+=info->s->base.pack_reclength; splits++; if (*record == '\0') { del_blocks++; del_length+=info->s->base.pack_reclength; continue; /* Record removed */ } param->glob_crc+= mi_static_checksum(info,record); used+=info->s->base.pack_reclength; break; case DYNAMIC_RECORD: flag=block_info.second_read=0; block_info.next_filepos=pos; do { if (_mi_read_cache(¶m->read_cache,(byte*) block_info.header, (start_block=block_info.next_filepos), sizeof(block_info.header), (flag ? 0 : READING_NEXT) | READING_HEADER)) goto err; if (start_block & (MI_DYN_ALIGN_SIZE-1)) { mi_check_print_error(param,"Wrong aligned block at %s", llstr(start_block,llbuff)); goto err2; } b_type=_mi_get_block_info(&block_info,-1,start_block); if (b_type & (BLOCK_DELETED | BLOCK_ERROR | BLOCK_SYNC_ERROR | BLOCK_FATAL_ERROR)) { if (b_type & BLOCK_SYNC_ERROR) { if (flag) { mi_check_print_error(param,"Unexpected byte: %d at link: %s", (int) block_info.header[0], llstr(start_block,llbuff)); goto err2; } pos=block_info.filepos+block_info.block_len; goto next; } if (b_type & BLOCK_DELETED) { if (block_info.block_len < info->s->base.min_block_length) { mi_check_print_error(param, "Deleted block with impossible length %lu at %s", block_info.block_len,llstr(pos,llbuff)); goto err2; } if ((block_info.next_filepos != HA_OFFSET_ERROR && block_info.next_filepos >= info->state->data_file_length) || (block_info.prev_filepos != HA_OFFSET_ERROR && block_info.prev_filepos >= info->state->data_file_length)) { mi_check_print_error(param,"Delete link points outside datafile at %s", llstr(pos,llbuff)); goto err2; } del_blocks++; del_length+=block_info.block_len; pos=block_info.filepos+block_info.block_len; splits++; goto next; } mi_check_print_error(param,"Wrong bytesec: %d-%d-%d at linkstart: %s", block_info.header[0],block_info.header[1], block_info.header[2], llstr(start_block,llbuff)); goto err2; } if (info->state->data_file_length < block_info.filepos+ block_info.block_len) { mi_check_print_error(param, "Recordlink that points outside datafile at %s", llstr(pos,llbuff)); got_error=1; break; } splits++; if (!flag++) /* First block */ { start_recpos=pos; pos=block_info.filepos+block_info.block_len; if (block_info.rec_len > (uint) info->s->base.max_pack_length) { mi_check_print_error(param,"Found too long record (%lu) at %s", (ulong) block_info.rec_len, llstr(start_recpos,llbuff)); got_error=1; break; } if (info->s->base.blobs) { if (!(to= mi_alloc_rec_buff(info, block_info.rec_len, &info->rec_buff))) { mi_check_print_error(param, "Not enough memory (%lu) for blob at %s", (ulong) block_info.rec_len, llstr(start_recpos,llbuff)); got_error=1; break; } } else to= info->rec_buff; left_length=block_info.rec_len; } if (left_length < block_info.data_len) { mi_check_print_error(param,"Found too long record (%lu) at %s", (ulong) block_info.data_len, llstr(start_recpos,llbuff)); got_error=1; break; } if (_mi_read_cache(¶m->read_cache,(byte*) to,block_info.filepos, (uint) block_info.data_len, flag == 1 ? READING_NEXT : 0)) goto err; to+=block_info.data_len; link_used+= block_info.filepos-start_block; used+= block_info.filepos - start_block + block_info.data_len; empty+=block_info.block_len-block_info.data_len; left_length-=block_info.data_len; if (left_length) { if (b_type & BLOCK_LAST) { mi_check_print_error(param, "Wrong record length %s of %s at %s", llstr(block_info.rec_len-left_length,llbuff), llstr(block_info.rec_len, llbuff2), llstr(start_recpos,llbuff3)); got_error=1; break; } if (info->state->data_file_length < block_info.next_filepos) { mi_check_print_error(param, "Found next-recordlink that points outside datafile at %s", llstr(block_info.filepos,llbuff)); got_error=1; break; } } } while (left_length); if (! got_error) { if (_mi_rec_unpack(info,record,info->rec_buff,block_info.rec_len) == MY_FILE_ERROR) { mi_check_print_error(param,"Found wrong record at %s", llstr(start_recpos,llbuff)); got_error=1; } else { info->checksum=mi_checksum(info,record); if (param->testflag & (T_EXTEND | T_MEDIUM | T_VERBOSE)) { if (_mi_rec_check(info,record, info->rec_buff,block_info.rec_len, test(info->s->calc_checksum))) { mi_check_print_error(param,"Found wrong packed record at %s", llstr(start_recpos,llbuff)); got_error=1; } } if (!got_error) param->glob_crc+= info->checksum; } } else if (!flag) pos=block_info.filepos+block_info.block_len; break; case COMPRESSED_RECORD: if (_mi_read_cache(¶m->read_cache,(byte*) block_info.header, pos, info->s->pack.ref_length, READING_NEXT)) goto err; start_recpos=pos; splits++; VOID(_mi_pack_get_block_info(info, &info->bit_buff, &block_info, &info->rec_buff, -1, start_recpos)); pos=block_info.filepos+block_info.rec_len; if (block_info.rec_len < (uint) info->s->min_pack_length || block_info.rec_len > (uint) info->s->max_pack_length) { mi_check_print_error(param, "Found block with wrong recordlength: %d at %s", block_info.rec_len, llstr(start_recpos,llbuff)); got_error=1; break; } if (_mi_read_cache(¶m->read_cache,(byte*) info->rec_buff, block_info.filepos, block_info.rec_len, READING_NEXT)) goto err; if (_mi_pack_rec_unpack(info, &info->bit_buff, record, info->rec_buff, block_info.rec_len)) { mi_check_print_error(param,"Found wrong record at %s", llstr(start_recpos,llbuff)); got_error=1; } if (static_row_size) param->glob_crc+= mi_static_checksum(info,record); else param->glob_crc+= mi_checksum(info,record); link_used+= (block_info.filepos - start_recpos); used+= (pos-start_recpos); } /* switch */ if (! got_error) { intern_record_checksum+=(ha_checksum) start_recpos; records++; if (param->testflag & T_WRITE_LOOP && records % WRITE_COUNT == 0) { printf("%s\r", llstr(records,llbuff)); VOID(fflush(stdout)); } /* Check if keys match the record */ for (key=0,keyinfo= info->s->keyinfo; key < info->s->base.keys; key++,keyinfo++) { if (mi_is_key_active(info->s->state.key_map, key)) { if(!(keyinfo->flag & HA_FULLTEXT)) { uint key_length=_mi_make_key(info,key,info->lastkey,record, start_recpos); if (extend) { /* We don't need to lock the key tree here as we don't allow concurrent threads when running myisamchk */ int search_result= #ifdef HAVE_RTREE_KEYS (keyinfo->flag & HA_SPATIAL) ? rtree_find_first(info, key, info->lastkey, key_length, MBR_EQUAL | MBR_DATA) : #endif _mi_search(info,keyinfo,info->lastkey,key_length, SEARCH_SAME, info->s->state.key_root[key]); if (search_result) { mi_check_print_error(param,"Record at: %10s " "Can't find key for index: %2d", llstr(start_recpos,llbuff),key+1); if (error++ > MAXERR || !(param->testflag & T_VERBOSE)) goto err2; } } else key_checksum[key]+=mi_byte_checksum((byte*) info->lastkey, key_length); } } } } else { got_error=0; if (error++ > MAXERR || !(param->testflag & T_VERBOSE)) goto err2; } next:; /* Next record */ } if (param->testflag & T_WRITE_LOOP) { VOID(fputs(" \r",stdout)); VOID(fflush(stdout)); } if (records != info->state->records) { mi_check_print_error(param,"Record-count is not ok; is %-10s Should be: %s", llstr(records,llbuff), llstr(info->state->records,llbuff2)); error=1; } else if (param->record_checksum && param->record_checksum != intern_record_checksum) { mi_check_print_error(param, "Keypointers and record positions doesn't match"); error=1; } else if (param->glob_crc != info->state->checksum && (info->s->options & (HA_OPTION_CHECKSUM | HA_OPTION_COMPRESS_RECORD))) { mi_check_print_warning(param, "Record checksum is not the same as checksum stored in the index file\n"); error=1; } else if (!extend) { for (key=0 ; key < info->s->base.keys; key++) { if (key_checksum[key] != param->key_crc[key] && !(info->s->keyinfo[key].flag & (HA_FULLTEXT | HA_SPATIAL))) { mi_check_print_error(param,"Checksum for key: %2d doesn't match checksum for records", key+1); error=1; } } } if (del_length != info->state->empty) { mi_check_print_warning(param, "Found %s deleted space. Should be %s", llstr(del_length,llbuff2), llstr(info->state->empty,llbuff)); } if (used+empty+del_length != info->state->data_file_length) { mi_check_print_warning(param, "Found %s record-data and %s unused data and %s deleted-data", llstr(used,llbuff),llstr(empty,llbuff2), llstr(del_length,llbuff3)); mi_check_print_warning(param, "Total %s, Should be: %s", llstr((used+empty+del_length),llbuff), llstr(info->state->data_file_length,llbuff2)); } if (del_blocks != info->state->del) { mi_check_print_warning(param, "Found %10s deleted blocks Should be: %s", llstr(del_blocks,llbuff), llstr(info->state->del,llbuff2)); } if (splits != info->s->state.split) { mi_check_print_warning(param, "Found %10s parts Should be: %s parts", llstr(splits,llbuff), llstr(info->s->state.split,llbuff2)); } if (param->testflag & T_INFO) { if (param->warning_printed || param->error_printed) puts(""); if (used != 0 && ! param->error_printed) { printf("Records:%18s M.recordlength:%9lu Packed:%14.0f%%\n", llstr(records,llbuff), (long)((used-link_used)/records), (info->s->base.blobs ? 0.0 : (ulonglong2double((ulonglong) info->s->base.reclength*records)- my_off_t2double(used))/ ulonglong2double((ulonglong) info->s->base.reclength*records)*100.0)); printf("Recordspace used:%9.0f%% Empty space:%12d%% Blocks/Record: %6.2f\n", (ulonglong2double(used-link_used)/ulonglong2double(used-link_used+empty)*100.0), (!records ? 100 : (int) (ulonglong2double(del_length+empty)/ my_off_t2double(used)*100.0)), ulonglong2double(splits - del_blocks) / records); } printf("Record blocks:%12s Delete blocks:%10s\n", llstr(splits-del_blocks,llbuff),llstr(del_blocks,llbuff2)); printf("Record data: %12s Deleted data: %10s\n", llstr(used-link_used,llbuff),llstr(del_length,llbuff2)); printf("Lost space: %12s Linkdata: %10s\n", llstr(empty,llbuff),llstr(link_used,llbuff2)); } my_free(mi_get_rec_buff_ptr(info, record), MYF(0)); DBUG_RETURN (error); err: mi_check_print_error(param,"got error: %d when reading datafile at record: %s",my_errno, llstr(records,llbuff)); err2: my_free(mi_get_rec_buff_ptr(info, record), MYF(0)); param->testflag|=T_RETRY_WITHOUT_QUICK; DBUG_RETURN(1); } /* chk_data_link */ /** @brief Drop all indexes @param[in] param check parameters @param[in] info MI_INFO handle @param[in] force if to force drop all indexes @return status @retval 0 OK @retval != 0 Error @note Once allocated, index blocks remain part of the key file forever. When indexes are disabled, no block is freed. When enabling indexes, no block is freed either. The new indexes are create from new blocks. (Bug #4692) Before recreating formerly disabled indexes, the unused blocks must be freed. There are two options to do this: - Follow the tree of disabled indexes, add all blocks to the deleted blocks chain. Would require a lot of random I/O. - Drop all blocks by clearing all index root pointers and all delete chain pointers and resetting key_file_length to the end of the index file header. This requires to recreate all indexes, even those that may still be intact. The second method is probably faster in most cases. When disabling indexes, MySQL disables either all indexes or all non-unique indexes. When MySQL [re-]enables disabled indexes (T_CREATE_MISSING_KEYS), then we either have "lost" blocks in the index file, or there are no non-unique indexes. In the latter case, mi_repair*() would not be called as there would be no disabled indexes. If there would be more unique indexes than disabled (non-unique) indexes, we could do the first method. But this is not implemented yet. By now we drop and recreate all indexes when repair is called. However, there is an exception. Sometimes MySQL disables non-unique indexes when the table is empty (e.g. when copying a table in mysql_alter_table()). When enabling the non-unique indexes, they are still empty. So there is no index block that can be lost. This optimization is implemented in this function. Note that in normal repair (T_CREATE_MISSING_KEYS not set) we recreate all enabled indexes unconditonally. We do not change the key_map. Otherwise we invert the key map temporarily (outside of this function) and recreate the then "seemingly" enabled indexes. When we cannot use the optimization, and drop all indexes, we pretend that all indexes were disabled. By the inversion, we will then recrate all indexes. */ static int mi_drop_all_indexes(MI_CHECK *param, MI_INFO *info, my_bool force) { MYISAM_SHARE *share= info->s; MI_STATE_INFO *state= &share->state; uint i; int error; DBUG_ENTER("mi_drop_all_indexes"); /* If any of the disabled indexes has a key block assigned, we must drop and recreate all indexes to avoid losing index blocks. If we want to recreate disabled indexes only _and_ all of these indexes are empty, we don't need to recreate the existing indexes. */ if (!force && (param->testflag & T_CREATE_MISSING_KEYS)) { DBUG_PRINT("repair", ("creating missing indexes")); for (i= 0; i < share->base.keys; i++) { DBUG_PRINT("repair", ("index #: %u key_root: 0x%lx active: %d", i, (long) state->key_root[i], mi_is_key_active(state->key_map, i))); if ((state->key_root[i] != HA_OFFSET_ERROR) && !mi_is_key_active(state->key_map, i)) { /* This index has at least one key block and it is disabled. We would lose its block(s) if would just recreate it. So we need to drop and recreate all indexes. */ DBUG_PRINT("repair", ("nonempty and disabled: recreate all")); break; } } if (i >= share->base.keys) { /* All of the disabled indexes are empty. We can just recreate them. Flush dirty blocks of this index file from key cache and remove all blocks of this index file from key cache. */ DBUG_PRINT("repair", ("all disabled are empty: create missing")); error= flush_key_blocks(share->key_cache, share->kfile, FLUSH_FORCE_WRITE); goto end; } /* We do now drop all indexes and declare them disabled. With the T_CREATE_MISSING_KEYS flag, mi_repair*() will recreate all disabled indexes and enable them. */ mi_clear_all_keys_active(state->key_map); DBUG_PRINT("repair", ("declared all indexes disabled")); } /* Remove all key blocks of this index file from key cache. */ if ((error= flush_key_blocks(share->key_cache, share->kfile, FLUSH_IGNORE_CHANGED))) goto end; /* purecov: inspected */ /* Clear index root block pointers. */ for (i= 0; i < share->base.keys; i++) state->key_root[i]= HA_OFFSET_ERROR; /* Clear the delete chains. */ for (i= 0; i < state->header.max_block_size; i++) state->key_del[i]= HA_OFFSET_ERROR; /* Reset index file length to end of index file header. */ info->state->key_file_length= share->base.keystart; DBUG_PRINT("repair", ("dropped all indexes")); /* error= 0; set by last (error= flush_key_bocks()). */ end: DBUG_RETURN(error); } /* Recover old table by reading each record and writing all keys */ /* Save new datafile-name in temp_filename */ int mi_repair(MI_CHECK *param, register MI_INFO *info, my_string name, int rep_quick) { int error,got_error; ha_rows start_records,new_header_length; my_off_t del; File new_file; MYISAM_SHARE *share=info->s; char llbuff[22],llbuff2[22]; SORT_INFO sort_info; MI_SORT_PARAM sort_param; DBUG_ENTER("mi_repair"); bzero((char *)&sort_info, sizeof(sort_info)); bzero((char *)&sort_param, sizeof(sort_param)); start_records=info->state->records; new_header_length=(param->testflag & T_UNPACK) ? 0L : share->pack.header_length; got_error=1; new_file= -1; sort_param.sort_info=&sort_info; if (!(param->testflag & T_SILENT)) { printf("- recovering (with keycache) MyISAM-table '%s'\n",name); printf("Data records: %s\n", llstr(info->state->records,llbuff)); } param->testflag|=T_REP; /* for easy checking */ if (info->s->options & (HA_OPTION_CHECKSUM | HA_OPTION_COMPRESS_RECORD)) param->testflag|=T_CALC_CHECKSUM; if (!param->using_global_keycache) VOID(init_key_cache(dflt_key_cache, param->key_cache_block_size, param->use_buffers, 0, 0)); if (init_io_cache(¶m->read_cache,info->dfile, (uint) param->read_buffer_length, READ_CACHE,share->pack.header_length,1,MYF(MY_WME))) { bzero(&info->rec_cache,sizeof(info->rec_cache)); goto err; } if (!rep_quick) if (init_io_cache(&info->rec_cache,-1,(uint) param->write_buffer_length, WRITE_CACHE, new_header_length, 1, MYF(MY_WME | MY_WAIT_IF_FULL))) goto err; info->opt_flag|=WRITE_CACHE_USED; if (!mi_alloc_rec_buff(info, -1, &sort_param.record) || !mi_alloc_rec_buff(info, -1, &sort_param.rec_buff)) { mi_check_print_error(param, "Not enough memory for extra record"); goto err; } if (!rep_quick) { /* Get real path for data file */ if ((new_file=my_raid_create(fn_format(param->temp_filename, share->data_file_name, "", DATA_TMP_EXT, 2+4), 0,param->tmpfile_createflag, share->base.raid_type, share->base.raid_chunks, share->base.raid_chunksize, MYF(0))) < 0) { mi_check_print_error(param,"Can't create new tempfile: '%s'", param->temp_filename); goto err; } if (new_header_length && filecopy(param,new_file,info->dfile,0L,new_header_length, "datafile-header")) goto err; info->s->state.dellink= HA_OFFSET_ERROR; info->rec_cache.file=new_file; if (param->testflag & T_UNPACK) { share->options&= ~HA_OPTION_COMPRESS_RECORD; mi_int2store(share->state.header.options,share->options); } } sort_info.info=info; sort_info.param = param; sort_param.read_cache=param->read_cache; sort_param.pos=sort_param.max_pos=share->pack.header_length; sort_param.filepos=new_header_length; param->read_cache.end_of_file=sort_info.filelength= my_seek(info->dfile,0L,MY_SEEK_END,MYF(0)); sort_info.dupp=0; sort_param.fix_datafile= (my_bool) (! rep_quick); sort_param.master=1; sort_info.max_records= ~(ha_rows) 0; set_data_file_type(&sort_info, share); del=info->state->del; info->state->records=info->state->del=share->state.split=0; info->state->empty=0; param->glob_crc=0; if (param->testflag & T_CALC_CHECKSUM) sort_param.calc_checksum= 1; info->update= (short) (HA_STATE_CHANGED | HA_STATE_ROW_CHANGED); /* This function always recreates all enabled indexes. */ if (param->testflag & T_CREATE_MISSING_KEYS) mi_set_all_keys_active(share->state.key_map, share->base.keys); mi_drop_all_indexes(param, info, TRUE); lock_memory(param); /* Everything is alloced */ /* Re-create all keys, which are set in key_map. */ while (!(error=sort_get_next_record(&sort_param))) { if (writekeys(&sort_param)) { if (my_errno != HA_ERR_FOUND_DUPP_KEY) goto err; DBUG_DUMP("record",(uchar*) sort_param.record,share->base.pack_reclength); mi_check_print_info(param,"Duplicate key %2d for record at %10s against new record at %10s", info->errkey+1, llstr(sort_param.start_recpos,llbuff), llstr(info->dupp_key_pos,llbuff2)); if (param->testflag & T_VERBOSE) { VOID(_mi_make_key(info,(uint) info->errkey,info->lastkey, sort_param.record,0L)); _mi_print_key(stdout,share->keyinfo[info->errkey].seg,info->lastkey, USE_WHOLE_KEY); } sort_info.dupp++; if ((param->testflag & (T_FORCE_UNIQUENESS|T_QUICK)) == T_QUICK) { param->testflag|=T_RETRY_WITHOUT_QUICK; param->error_printed=1; goto err; } continue; } if (sort_write_record(&sort_param)) goto err; } if (error > 0 || write_data_suffix(&sort_info, (my_bool)!rep_quick) || flush_io_cache(&info->rec_cache) || param->read_cache.error < 0) goto err; if (param->testflag & T_WRITE_LOOP) { VOID(fputs(" \r",stdout)); VOID(fflush(stdout)); } if (my_chsize(share->kfile,info->state->key_file_length,0,MYF(0))) { mi_check_print_warning(param, "Can't change size of indexfile, error: %d", my_errno); goto err; } if (rep_quick && del+sort_info.dupp != info->state->del) { mi_check_print_error(param,"Couldn't fix table with quick recovery: Found wrong number of deleted records"); mi_check_print_error(param,"Run recovery again without -q"); got_error=1; param->retry_repair=1; param->testflag|=T_RETRY_WITHOUT_QUICK; goto err; } if (param->testflag & T_SAFE_REPAIR) { /* Don't repair if we loosed more than one row */ if (info->state->records+1 < start_records) { info->state->records=start_records; got_error=1; goto err; } } if (!rep_quick) { my_close(info->dfile,MYF(0)); info->dfile=new_file; info->state->data_file_length=sort_param.filepos; share->state.version=(ulong) time((time_t*) 0); /* Force reopen */ } else { info->state->data_file_length=sort_param.max_pos; } if (param->testflag & T_CALC_CHECKSUM) info->state->checksum=param->glob_crc; if (!(param->testflag & T_SILENT)) { if (start_records != info->state->records) printf("Data records: %s\n", llstr(info->state->records,llbuff)); if (sort_info.dupp) mi_check_print_warning(param, "%s records have been removed", llstr(sort_info.dupp,llbuff)); } got_error=0; /* If invoked by external program that uses thr_lock */ if (&share->state.state != info->state) memcpy( &share->state.state, info->state, sizeof(*info->state)); err: if (!got_error) { /* Replace the actual file with the temporary file */ if (new_file >= 0) { my_close(new_file,MYF(0)); info->dfile=new_file= -1; if (change_to_newfile(share->data_file_name,MI_NAME_DEXT, DATA_TMP_EXT, share->base.raid_chunks, (param->testflag & T_BACKUP_DATA ? MYF(MY_REDEL_MAKE_BACKUP): MYF(0))) || mi_open_datafile(info,share,-1)) got_error=1; } } if (got_error) { if (! param->error_printed) mi_check_print_error(param,"%d for record at pos %s",my_errno, llstr(sort_param.start_recpos,llbuff)); if (new_file >= 0) { VOID(my_close(new_file,MYF(0))); VOID(my_raid_delete(param->temp_filename,info->s->base.raid_chunks, MYF(MY_WME))); info->rec_cache.file=-1; /* don't flush data to new_file, it's closed */ } mi_mark_crashed_on_repair(info); } my_free(mi_get_rec_buff_ptr(info, sort_param.rec_buff), MYF(MY_ALLOW_ZERO_PTR)); my_free(mi_get_rec_buff_ptr(info, sort_param.record), MYF(MY_ALLOW_ZERO_PTR)); my_free(sort_info.buff,MYF(MY_ALLOW_ZERO_PTR)); VOID(end_io_cache(¶m->read_cache)); info->opt_flag&= ~(READ_CACHE_USED | WRITE_CACHE_USED); VOID(end_io_cache(&info->rec_cache)); got_error|=flush_blocks(param, share->key_cache, share->kfile); if (!got_error && param->testflag & T_UNPACK) { share->state.header.options[0]&= (uchar) ~HA_OPTION_COMPRESS_RECORD; share->pack.header_length=0; share->data_file_type=sort_info.new_data_file_type; } share->state.changed|= (STATE_NOT_OPTIMIZED_KEYS | STATE_NOT_SORTED_PAGES | STATE_NOT_ANALYZED); DBUG_RETURN(got_error); } /* Uppate keyfile when doing repair */ static int writekeys(MI_SORT_PARAM *sort_param) { register uint i; uchar *key; MI_INFO *info= sort_param->sort_info->info; byte *buff= sort_param->record; my_off_t filepos= sort_param->filepos; DBUG_ENTER("writekeys"); key=info->lastkey+info->s->base.max_key_length; for (i=0 ; i < info->s->base.keys ; i++) { if (mi_is_key_active(info->s->state.key_map, i)) { if (info->s->keyinfo[i].flag & HA_FULLTEXT ) { if (_mi_ft_add(info,i,(char*) key,buff,filepos)) goto err; } #ifdef HAVE_SPATIAL else if (info->s->keyinfo[i].flag & HA_SPATIAL) { uint key_length=_mi_make_key(info,i,key,buff,filepos); if (rtree_insert(info, i, key, key_length)) goto err; } #endif /*HAVE_SPATIAL*/ else { uint key_length=_mi_make_key(info,i,key,buff,filepos); if (_mi_ck_write(info,i,key,key_length)) goto err; } } } DBUG_RETURN(0); err: if (my_errno == HA_ERR_FOUND_DUPP_KEY) { info->errkey=(int) i; /* This key was found */ while ( i-- > 0 ) { if (mi_is_key_active(info->s->state.key_map, i)) { if (info->s->keyinfo[i].flag & HA_FULLTEXT) { if (_mi_ft_del(info,i,(char*) key,buff,filepos)) break; } else { uint key_length=_mi_make_key(info,i,key,buff,filepos); if (_mi_ck_delete(info,i,key,key_length)) break; } } } } /* Remove checksum that was added to glob_crc in sort_get_next_record */ if (sort_param->calc_checksum) sort_param->sort_info->param->glob_crc-= info->checksum; DBUG_PRINT("error",("errno: %d",my_errno)); DBUG_RETURN(-1); } /* writekeys */ /* Change all key-pointers that points to a records */ int movepoint(register MI_INFO *info, byte *record, my_off_t oldpos, my_off_t newpos, uint prot_key) { register uint i; uchar *key; uint key_length; DBUG_ENTER("movepoint"); key=info->lastkey+info->s->base.max_key_length; for (i=0 ; i < info->s->base.keys; i++) { if (i != prot_key && mi_is_key_active(info->s->state.key_map, i)) { key_length=_mi_make_key(info,i,key,record,oldpos); if (info->s->keyinfo[i].flag & HA_NOSAME) { /* Change pointer direct */ uint nod_flag; MI_KEYDEF *keyinfo; keyinfo=info->s->keyinfo+i; if (_mi_search(info,keyinfo,key,USE_WHOLE_KEY, (uint) (SEARCH_SAME | SEARCH_SAVE_BUFF), info->s->state.key_root[i])) DBUG_RETURN(-1); nod_flag=mi_test_if_nod(info->buff); _mi_dpointer(info,info->int_keypos-nod_flag- info->s->rec_reflength,newpos); if (_mi_write_keypage(info,keyinfo,info->last_keypage, DFLT_INIT_HITS,info->buff)) DBUG_RETURN(-1); } else { /* Change old key to new */ if (_mi_ck_delete(info,i,key,key_length)) DBUG_RETURN(-1); key_length=_mi_make_key(info,i,key,record,newpos); if (_mi_ck_write(info,i,key,key_length)) DBUG_RETURN(-1); } } } DBUG_RETURN(0); } /* movepoint */ /* Tell system that we want all memory for our cache */ void lock_memory(MI_CHECK *param __attribute__((unused))) { #ifdef SUN_OS /* Key-cacheing thrases on sun 4.1 */ if (param->opt_lock_memory) { int success = mlockall(MCL_CURRENT); /* or plock(DATLOCK); */ if (geteuid() == 0 && success != 0) mi_check_print_warning(param, "Failed to lock memory. errno %d",my_errno); } #endif } /* lock_memory */ /* Flush all changed blocks to disk */ int flush_blocks(MI_CHECK *param, KEY_CACHE *key_cache, File file) { if (flush_key_blocks(key_cache, file, FLUSH_RELEASE)) { mi_check_print_error(param,"%d when trying to write bufferts",my_errno); return(1); } if (!param->using_global_keycache) end_key_cache(key_cache,1); return 0; } /* flush_blocks */ /* Sort index for more efficent reads */ int mi_sort_index(MI_CHECK *param, register MI_INFO *info, my_string name) { reg2 uint key; reg1 MI_KEYDEF *keyinfo; File new_file; my_off_t index_pos[MI_MAX_POSSIBLE_KEY]; uint r_locks,w_locks; int old_lock; MYISAM_SHARE *share=info->s; MI_STATE_INFO old_state; DBUG_ENTER("mi_sort_index"); /* cannot sort index files with R-tree indexes */ for (key= 0,keyinfo= &share->keyinfo[0]; key < share->base.keys ; key++,keyinfo++) if (keyinfo->key_alg == HA_KEY_ALG_RTREE) DBUG_RETURN(0); if (!(param->testflag & T_SILENT)) printf("- Sorting index for MyISAM-table '%s'\n",name); /* Get real path for index file */ fn_format(param->temp_filename,name,"", MI_NAME_IEXT,2+4+32); if ((new_file=my_create(fn_format(param->temp_filename,param->temp_filename, "", INDEX_TMP_EXT,2+4), 0,param->tmpfile_createflag,MYF(0))) <= 0) { mi_check_print_error(param,"Can't create new tempfile: '%s'", param->temp_filename); DBUG_RETURN(-1); } if (filecopy(param, new_file,share->kfile,0L, (ulong) share->base.keystart, "headerblock")) goto err; param->new_file_pos=share->base.keystart; for (key= 0,keyinfo= &share->keyinfo[0]; key < share->base.keys ; key++,keyinfo++) { if (! mi_is_key_active(info->s->state.key_map, key)) continue; if (share->state.key_root[key] != HA_OFFSET_ERROR) { index_pos[key]=param->new_file_pos; /* Write first block here */ if (sort_one_index(param,info,keyinfo,share->state.key_root[key], new_file)) goto err; } else index_pos[key]= HA_OFFSET_ERROR; /* No blocks */ } /* Flush key cache for this file if we are calling this outside myisamchk */ flush_key_blocks(share->key_cache,share->kfile, FLUSH_IGNORE_CHANGED); share->state.version=(ulong) time((time_t*) 0); old_state= share->state; /* save state if not stored */ r_locks= share->r_locks; w_locks= share->w_locks; old_lock= info->lock_type; /* Put same locks as old file */ share->r_locks= share->w_locks= share->tot_locks= 0; (void) _mi_writeinfo(info,WRITEINFO_UPDATE_KEYFILE); VOID(my_close(share->kfile,MYF(MY_WME))); share->kfile = -1; VOID(my_close(new_file,MYF(MY_WME))); if (change_to_newfile(share->index_file_name,MI_NAME_IEXT,INDEX_TMP_EXT,0, MYF(0)) || mi_open_keyfile(share)) goto err2; info->lock_type= F_UNLCK; /* Force mi_readinfo to lock */ _mi_readinfo(info,F_WRLCK,0); /* Will lock the table */ info->lock_type= old_lock; share->r_locks= r_locks; share->w_locks= w_locks; share->tot_locks= r_locks+w_locks; share->state= old_state; /* Restore old state */ info->state->key_file_length=param->new_file_pos; info->update= (short) (HA_STATE_CHANGED | HA_STATE_ROW_CHANGED); for (key=0 ; key < info->s->base.keys ; key++) info->s->state.key_root[key]=index_pos[key]; for (key=0 ; key < info->s->state.header.max_block_size ; key++) info->s->state.key_del[key]= HA_OFFSET_ERROR; info->s->state.changed&= ~STATE_NOT_SORTED_PAGES; DBUG_RETURN(0); err: VOID(my_close(new_file,MYF(MY_WME))); err2: VOID(my_delete(param->temp_filename,MYF(MY_WME))); DBUG_RETURN(-1); } /* mi_sort_index */ /* Sort records recursive using one index */ static int sort_one_index(MI_CHECK *param, MI_INFO *info, MI_KEYDEF *keyinfo, my_off_t pagepos, File new_file) { uint length,nod_flag,used_length, key_length; uchar *buff,*keypos,*endpos; uchar key[MI_MAX_POSSIBLE_KEY_BUFF]; my_off_t new_page_pos,next_page; char llbuff[22]; DBUG_ENTER("sort_one_index"); /* cannot walk over R-tree indices */ DBUG_ASSERT(keyinfo->key_alg != HA_KEY_ALG_RTREE); new_page_pos=param->new_file_pos; param->new_file_pos+=keyinfo->block_length; if (!(buff=(uchar*) my_alloca((uint) keyinfo->block_length))) { mi_check_print_error(param,"Not enough memory for key block"); DBUG_RETURN(-1); } if (!_mi_fetch_keypage(info,keyinfo,pagepos,DFLT_INIT_HITS,buff,0)) { mi_check_print_error(param,"Can't read key block from filepos: %s", llstr(pagepos,llbuff)); goto err; } if ((nod_flag=mi_test_if_nod(buff)) || keyinfo->flag & HA_FULLTEXT) { used_length=mi_getint(buff); keypos=buff+2+nod_flag; endpos=buff+used_length; for ( ;; ) { if (nod_flag) { next_page=_mi_kpos(nod_flag,keypos); _mi_kpointer(info,keypos-nod_flag,param->new_file_pos); /* Save new pos */ if (sort_one_index(param,info,keyinfo,next_page,new_file)) { DBUG_PRINT("error", ("From page: %ld, keyoffset: %lu used_length: %d", (ulong) pagepos, (ulong) (keypos - buff), (int) used_length)); DBUG_DUMP("buff",(uchar*) buff,used_length); goto err; } } if (keypos >= endpos || (key_length=(*keyinfo->get_key)(keyinfo,nod_flag,&keypos,key)) == 0) break; DBUG_ASSERT(keypos <= endpos); if (keyinfo->flag & HA_FULLTEXT) { uint off; int subkeys; get_key_full_length_rdonly(off, key); subkeys=ft_sintXkorr(key+off); if (subkeys < 0) { next_page= _mi_dpos(info,0,key+key_length); _mi_dpointer(info,keypos-nod_flag-info->s->rec_reflength, param->new_file_pos); /* Save new pos */ if (sort_one_index(param,info,&info->s->ft2_keyinfo, next_page,new_file)) goto err; } } } } /* Fill block with zero and write it to the new index file */ length=mi_getint(buff); bzero((byte*) buff+length,keyinfo->block_length-length); if (my_pwrite(new_file,(byte*) buff,(uint) keyinfo->block_length, new_page_pos,MYF(MY_NABP | MY_WAIT_IF_FULL))) { mi_check_print_error(param,"Can't write indexblock, error: %d",my_errno); goto err; } my_afree((gptr) buff); DBUG_RETURN(0); err: my_afree((gptr) buff); DBUG_RETURN(1); } /* sort_one_index */ /* Let temporary file replace old file. This assumes that the new file was created in the same directory as given by realpath(filename). This will ensure that any symlinks that are used will still work. Copy stats from old file to new file, deletes orignal and changes new file name to old file name */ int change_to_newfile(const char * filename, const char * old_ext, const char * new_ext, uint raid_chunks __attribute__((unused)), myf MyFlags) { char old_filename[FN_REFLEN],new_filename[FN_REFLEN]; #ifdef USE_RAID if (raid_chunks) return my_raid_redel(fn_format(old_filename,filename,"",old_ext,2+4), fn_format(new_filename,filename,"",new_ext,2+4), raid_chunks, MYF(MY_WME | MY_LINK_WARNING | MyFlags)); #endif /* Get real path to filename */ (void) fn_format(old_filename,filename,"",old_ext,2+4+32); return my_redel(old_filename, fn_format(new_filename,old_filename,"",new_ext,2+4), MYF(MY_WME | MY_LINK_WARNING | MyFlags)); } /* change_to_newfile */ /* Locks a whole file */ /* Gives an error-message if file can't be locked */ int lock_file(MI_CHECK *param, File file, my_off_t start, int lock_type, const char *filetype, const char *filename) { if (my_lock(file,lock_type,start,F_TO_EOF, param->testflag & T_WAIT_FOREVER ? MYF(MY_SEEK_NOT_DONE) : MYF(MY_SEEK_NOT_DONE | MY_DONT_WAIT))) { mi_check_print_error(param," %d when locking %s '%s'",my_errno,filetype,filename); param->error_printed=2; /* Don't give that data is crashed */ return 1; } return 0; } /* lock_file */ /* Copy a block between two files */ int filecopy(MI_CHECK *param, File to,File from,my_off_t start, my_off_t length, const char *type) { char tmp_buff[IO_SIZE],*buff; ulong buff_length; DBUG_ENTER("filecopy"); buff_length=(ulong) min(param->write_buffer_length,length); if (!(buff=my_malloc(buff_length,MYF(0)))) { buff=tmp_buff; buff_length=IO_SIZE; } VOID(my_seek(from,start,MY_SEEK_SET,MYF(0))); while (length > buff_length) { if (my_read(from,(byte*) buff,buff_length,MYF(MY_NABP)) || my_write(to,(byte*) buff,buff_length,param->myf_rw)) goto err; length-= buff_length; } if (my_read(from,(byte*) buff,(uint) length,MYF(MY_NABP)) || my_write(to,(byte*) buff,(uint) length,param->myf_rw)) goto err; if (buff != tmp_buff) my_free(buff,MYF(0)); DBUG_RETURN(0); err: if (buff != tmp_buff) my_free(buff,MYF(0)); mi_check_print_error(param,"Can't copy %s to tempfile, error %d", type,my_errno); DBUG_RETURN(1); } /* Repair table or given index using sorting SYNOPSIS mi_repair_by_sort() param Repair parameters info MyISAM handler to repair name Name of table (for warnings) rep_quick set to <> 0 if we should not change data file RESULT 0 ok <>0 Error */ int mi_repair_by_sort(MI_CHECK *param, register MI_INFO *info, const char * name, int rep_quick) { int got_error; uint i; ulong length; ha_rows start_records; my_off_t new_header_length,del; File new_file; MI_SORT_PARAM sort_param; MYISAM_SHARE *share=info->s; HA_KEYSEG *keyseg; ulong *rec_per_key_part; char llbuff[22]; SORT_INFO sort_info; ulonglong key_map; DBUG_ENTER("mi_repair_by_sort"); LINT_INIT(key_map); start_records=info->state->records; got_error=1; new_file= -1; new_header_length=(param->testflag & T_UNPACK) ? 0 : share->pack.header_length; if (!(param->testflag & T_SILENT)) { printf("- recovering (with sort) MyISAM-table '%s'\n",name); printf("Data records: %s\n", llstr(start_records,llbuff)); } param->testflag|=T_REP; /* for easy checking */ if (info->s->options & (HA_OPTION_CHECKSUM | HA_OPTION_COMPRESS_RECORD)) param->testflag|=T_CALC_CHECKSUM; bzero((char*)&sort_info,sizeof(sort_info)); bzero((char *)&sort_param, sizeof(sort_param)); if (!(sort_info.key_block= alloc_key_blocks(param, (uint) param->sort_key_blocks, share->base.max_key_block_length)) || init_io_cache(¶m->read_cache,info->dfile, (uint) param->read_buffer_length, READ_CACHE,share->pack.header_length,1,MYF(MY_WME)) || (! rep_quick && init_io_cache(&info->rec_cache,info->dfile, (uint) param->write_buffer_length, WRITE_CACHE,new_header_length,1, MYF(MY_WME | MY_WAIT_IF_FULL) & param->myf_rw))) goto err; sort_info.key_block_end=sort_info.key_block+param->sort_key_blocks; info->opt_flag|=WRITE_CACHE_USED; info->rec_cache.file=info->dfile; /* for sort_delete_record */ if (!mi_alloc_rec_buff(info, -1, &sort_param.record) || !mi_alloc_rec_buff(info, -1, &sort_param.rec_buff)) { mi_check_print_error(param, "Not enough memory for extra record"); goto err; } if (!rep_quick) { /* Get real path for data file */ if ((new_file=my_raid_create(fn_format(param->temp_filename, share->data_file_name, "", DATA_TMP_EXT, 2+4), 0,param->tmpfile_createflag, share->base.raid_type, share->base.raid_chunks, share->base.raid_chunksize, MYF(0))) < 0) { mi_check_print_error(param,"Can't create new tempfile: '%s'", param->temp_filename); goto err; } if (new_header_length && filecopy(param, new_file,info->dfile,0L,new_header_length, "datafile-header")) goto err; if (param->testflag & T_UNPACK) { share->options&= ~HA_OPTION_COMPRESS_RECORD; mi_int2store(share->state.header.options,share->options); } share->state.dellink= HA_OFFSET_ERROR; info->rec_cache.file=new_file; } info->update= (short) (HA_STATE_CHANGED | HA_STATE_ROW_CHANGED); /* Optionally drop indexes and optionally modify the key_map. */ mi_drop_all_indexes(param, info, FALSE); key_map= share->state.key_map; if (param->testflag & T_CREATE_MISSING_KEYS) { /* Invert the copied key_map to recreate all disabled indexes. */ key_map= ~key_map; } sort_info.info=info; sort_info.param = param; set_data_file_type(&sort_info, share); sort_param.filepos=new_header_length; sort_info.dupp=0; sort_info.buff=0; param->read_cache.end_of_file=sort_info.filelength= my_seek(param->read_cache.file,0L,MY_SEEK_END,MYF(0)); sort_param.wordlist=NULL; if (share->data_file_type == DYNAMIC_RECORD) length=max(share->base.min_pack_length+1,share->base.min_block_length); else if (share->data_file_type == COMPRESSED_RECORD) length=share->base.min_block_length; else length=share->base.pack_reclength; sort_info.max_records= ((param->testflag & T_CREATE_MISSING_KEYS) ? info->state->records : (ha_rows) (sort_info.filelength/length+1)); sort_param.key_cmp=sort_key_cmp; sort_param.lock_in_memory=lock_memory; sort_param.tmpdir=param->tmpdir; sort_param.sort_info=&sort_info; sort_param.fix_datafile= (my_bool) (! rep_quick); sort_param.master =1; del=info->state->del; param->glob_crc=0; if (param->testflag & T_CALC_CHECKSUM) sort_param.calc_checksum= 1; rec_per_key_part= param->rec_per_key_part; for (sort_param.key=0 ; sort_param.key < share->base.keys ; rec_per_key_part+=sort_param.keyinfo->keysegs, sort_param.key++) { sort_param.read_cache=param->read_cache; sort_param.keyinfo=share->keyinfo+sort_param.key; sort_param.seg=sort_param.keyinfo->seg; /* Skip this index if it is marked disabled in the copied (and possibly inverted) key_map. */ if (! mi_is_key_active(key_map, sort_param.key)) { /* Remember old statistics for key */ memcpy((char*) rec_per_key_part, (char*) (share->state.rec_per_key_part + (uint) (rec_per_key_part - param->rec_per_key_part)), sort_param.keyinfo->keysegs*sizeof(*rec_per_key_part)); DBUG_PRINT("repair", ("skipping seemingly disabled index #: %u", sort_param.key)); continue; } if ((!(param->testflag & T_SILENT))) printf ("- Fixing index %d\n",sort_param.key+1); sort_param.max_pos=sort_param.pos=share->pack.header_length; keyseg=sort_param.seg; bzero((char*) sort_param.unique,sizeof(sort_param.unique)); sort_param.key_length=share->rec_reflength; for (i=0 ; keyseg[i].type != HA_KEYTYPE_END; i++) { sort_param.key_length+=keyseg[i].length; if (keyseg[i].flag & HA_SPACE_PACK) sort_param.key_length+=get_pack_length(keyseg[i].length); if (keyseg[i].flag & (HA_BLOB_PART | HA_VAR_LENGTH_PART)) sort_param.key_length+=2 + test(keyseg[i].length >= 127); if (keyseg[i].flag & HA_NULL_PART) sort_param.key_length++; } info->state->records=info->state->del=share->state.split=0; info->state->empty=0; if (sort_param.keyinfo->flag & HA_FULLTEXT) { uint ft_max_word_len_for_sort=FT_MAX_WORD_LEN_FOR_SORT* sort_param.keyinfo->seg->charset->mbmaxlen; sort_info.max_records= (ha_rows) (sort_info.filelength/ft_min_word_len+1); sort_param.key_read=sort_ft_key_read; sort_param.key_write=sort_ft_key_write; sort_param.key_length+=ft_max_word_len_for_sort-HA_FT_MAXBYTELEN; } else { sort_param.key_read=sort_key_read; sort_param.key_write=sort_key_write; } if (_create_index_by_sort(&sort_param, (my_bool) (!(param->testflag & T_VERBOSE)), (uint) param->sort_buffer_length)) { param->retry_repair=1; goto err; } /* No need to calculate checksum again. */ sort_param.calc_checksum= 0; /* Set for next loop */ sort_info.max_records= (ha_rows) info->state->records; if (param->testflag & T_STATISTICS) update_key_parts(sort_param.keyinfo, rec_per_key_part, sort_param.unique, param->stats_method == MI_STATS_METHOD_IGNORE_NULLS? sort_param.notnull: NULL, (ulonglong) info->state->records); /* Enable this index in the permanent (not the copied) key_map. */ mi_set_key_active(share->state.key_map, sort_param.key); DBUG_PRINT("repair", ("set enabled index #: %u", sort_param.key)); if (sort_param.fix_datafile) { param->read_cache.end_of_file=sort_param.filepos; if (write_data_suffix(&sort_info,1) || end_io_cache(&info->rec_cache)) goto err; if (param->testflag & T_SAFE_REPAIR) { /* Don't repair if we loosed more than one row */ if (info->state->records+1 < start_records) { info->state->records=start_records; goto err; } } share->state.state.data_file_length = info->state->data_file_length= sort_param.filepos; /* Only whole records */ share->state.version=(ulong) time((time_t*) 0); my_close(info->dfile,MYF(0)); info->dfile=new_file; share->data_file_type=sort_info.new_data_file_type; share->pack.header_length=(ulong) new_header_length; sort_param.fix_datafile=0; } else info->state->data_file_length=sort_param.max_pos; param->read_cache.file=info->dfile; /* re-init read cache */ reinit_io_cache(¶m->read_cache,READ_CACHE,share->pack.header_length, 1,1); } if (param->testflag & T_WRITE_LOOP) { VOID(fputs(" \r",stdout)); VOID(fflush(stdout)); } if (rep_quick && del+sort_info.dupp != info->state->del) { mi_check_print_error(param,"Couldn't fix table with quick recovery: Found wrong number of deleted records"); mi_check_print_error(param,"Run recovery again without -q"); got_error=1; param->retry_repair=1; param->testflag|=T_RETRY_WITHOUT_QUICK; goto err; } if (rep_quick & T_FORCE_UNIQUENESS) { my_off_t skr=info->state->data_file_length+ (share->options & HA_OPTION_COMPRESS_RECORD ? MEMMAP_EXTRA_MARGIN : 0); #ifdef USE_RELOC if (share->data_file_type == STATIC_RECORD && skr < share->base.reloc*share->base.min_pack_length) skr=share->base.reloc*share->base.min_pack_length; #endif if (skr != sort_info.filelength && !info->s->base.raid_type) if (my_chsize(info->dfile,skr,0,MYF(0))) mi_check_print_warning(param, "Can't change size of datafile, error: %d", my_errno); } if (param->testflag & T_CALC_CHECKSUM) info->state->checksum=param->glob_crc; if (my_chsize(share->kfile,info->state->key_file_length,0,MYF(0))) mi_check_print_warning(param, "Can't change size of indexfile, error: %d", my_errno); if (!(param->testflag & T_SILENT)) { if (start_records != info->state->records) printf("Data records: %s\n", llstr(info->state->records,llbuff)); if (sort_info.dupp) mi_check_print_warning(param, "%s records have been removed", llstr(sort_info.dupp,llbuff)); } got_error=0; if (&share->state.state != info->state) memcpy( &share->state.state, info->state, sizeof(*info->state)); err: got_error|= flush_blocks(param, share->key_cache, share->kfile); VOID(end_io_cache(&info->rec_cache)); if (!got_error) { /* Replace the actual file with the temporary file */ if (new_file >= 0) { my_close(new_file,MYF(0)); info->dfile=new_file= -1; if (change_to_newfile(share->data_file_name,MI_NAME_DEXT, DATA_TMP_EXT, share->base.raid_chunks, (param->testflag & T_BACKUP_DATA ? MYF(MY_REDEL_MAKE_BACKUP): MYF(0))) || mi_open_datafile(info,share,-1)) got_error=1; } } if (got_error) { if (! param->error_printed) mi_check_print_error(param,"%d when fixing table",my_errno); if (new_file >= 0) { VOID(my_close(new_file,MYF(0))); VOID(my_raid_delete(param->temp_filename,share->base.raid_chunks, MYF(MY_WME))); if (info->dfile == new_file) info->dfile= -1; } mi_mark_crashed_on_repair(info); } else if (key_map == share->state.key_map) share->state.changed&= ~STATE_NOT_OPTIMIZED_KEYS; share->state.changed|=STATE_NOT_SORTED_PAGES; my_free(mi_get_rec_buff_ptr(info, sort_param.rec_buff), MYF(MY_ALLOW_ZERO_PTR)); my_free(mi_get_rec_buff_ptr(info, sort_param.record), MYF(MY_ALLOW_ZERO_PTR)); my_free((gptr) sort_info.key_block,MYF(MY_ALLOW_ZERO_PTR)); my_free((gptr) sort_info.ft_buf, MYF(MY_ALLOW_ZERO_PTR)); my_free(sort_info.buff,MYF(MY_ALLOW_ZERO_PTR)); VOID(end_io_cache(¶m->read_cache)); info->opt_flag&= ~(READ_CACHE_USED | WRITE_CACHE_USED); if (!got_error && (param->testflag & T_UNPACK)) { share->state.header.options[0]&= (uchar) ~HA_OPTION_COMPRESS_RECORD; share->pack.header_length=0; } DBUG_RETURN(got_error); } /* Threaded repair of table using sorting SYNOPSIS mi_repair_parallel() param Repair parameters info MyISAM handler to repair name Name of table (for warnings) rep_quick set to <> 0 if we should not change data file DESCRIPTION Same as mi_repair_by_sort but do it multithreaded Each key is handled by a separate thread. TODO: make a number of threads a parameter In parallel repair we use one thread per index. There are two modes: Quick Only the indexes are rebuilt. All threads share a read buffer. Every thread that needs fresh data in the buffer enters the shared cache lock. The last thread joining the lock reads the buffer from the data file and wakes all other threads. Non-quick The data file is rebuilt and all indexes are rebuilt to point to the new record positions. One thread is the master thread. It reads from the old data file and writes to the new data file. It also creates one of the indexes. The other threads read from a buffer which is filled by the master. If they need fresh data, they enter the shared cache lock. If the masters write buffer is full, it flushes it to the new data file and enters the shared cache lock too. When all threads joined in the lock, the master copies its write buffer to the read buffer for the other threads and wakes them. RESULT 0 ok <>0 Error */ int mi_repair_parallel(MI_CHECK *param, register MI_INFO *info, const char * name, int rep_quick) { #ifndef THREAD return mi_repair_by_sort(param, info, name, rep_quick); #else int got_error; uint i,key, total_key_length, istep; ulong rec_length; ha_rows start_records; my_off_t new_header_length,del; File new_file; MI_SORT_PARAM *sort_param=0; MYISAM_SHARE *share=info->s; ulong *rec_per_key_part; HA_KEYSEG *keyseg; char llbuff[22]; IO_CACHE new_data_cache; /* For non-quick repair. */ IO_CACHE_SHARE io_share; SORT_INFO sort_info; ulonglong key_map; pthread_attr_t thr_attr; ulong max_pack_reclength; DBUG_ENTER("mi_repair_parallel"); LINT_INIT(key_map); start_records=info->state->records; got_error=1; new_file= -1; new_header_length=(param->testflag & T_UNPACK) ? 0 : share->pack.header_length; if (!(param->testflag & T_SILENT)) { printf("- parallel recovering (with sort) MyISAM-table '%s'\n",name); printf("Data records: %s\n", llstr(start_records,llbuff)); } param->testflag|=T_REP; /* for easy checking */ if (info->s->options & (HA_OPTION_CHECKSUM | HA_OPTION_COMPRESS_RECORD)) param->testflag|=T_CALC_CHECKSUM; /* Quick repair (not touching data file, rebuilding indexes): { Read cache is (MI_CHECK *param)->read_cache using info->dfile. } Non-quick repair (rebuilding data file and indexes): { Master thread: Read cache is (MI_CHECK *param)->read_cache using info->dfile. Write cache is (MI_INFO *info)->rec_cache using new_file. Slave threads: Read cache is new_data_cache synced to master rec_cache. The final assignment of the filedescriptor for rec_cache is done after the cache creation. Don't check file size on new_data_cache, as the resulting file size is not known yet. As rec_cache and new_data_cache are synced, write_buffer_length is used for the read cache 'new_data_cache'. Both start at the same position 'new_header_length'. } */ DBUG_PRINT("info", ("is quick repair: %d", rep_quick)); bzero((char*)&sort_info,sizeof(sort_info)); /* Initialize pthread structures before goto err. */ pthread_mutex_init(&sort_info.mutex, MY_MUTEX_INIT_FAST); pthread_cond_init(&sort_info.cond, 0); if (!(sort_info.key_block= alloc_key_blocks(param, (uint) param->sort_key_blocks, share->base.max_key_block_length)) || init_io_cache(¶m->read_cache, info->dfile, (uint) param->read_buffer_length, READ_CACHE, share->pack.header_length, 1, MYF(MY_WME)) || (!rep_quick && (init_io_cache(&info->rec_cache, info->dfile, (uint) param->write_buffer_length, WRITE_CACHE, new_header_length, 1, MYF(MY_WME | MY_WAIT_IF_FULL) & param->myf_rw) || init_io_cache(&new_data_cache, -1, (uint) param->write_buffer_length, READ_CACHE, new_header_length, 1, MYF(MY_WME | MY_DONT_CHECK_FILESIZE))))) goto err; sort_info.key_block_end=sort_info.key_block+param->sort_key_blocks; info->opt_flag|=WRITE_CACHE_USED; info->rec_cache.file=info->dfile; /* for sort_delete_record */ if (!rep_quick) { /* Get real path for data file */ if ((new_file=my_raid_create(fn_format(param->temp_filename, share->data_file_name, "", DATA_TMP_EXT, 2+4), 0,param->tmpfile_createflag, share->base.raid_type, share->base.raid_chunks, share->base.raid_chunksize, MYF(0))) < 0) { mi_check_print_error(param,"Can't create new tempfile: '%s'", param->temp_filename); goto err; } if (new_header_length && filecopy(param, new_file,info->dfile,0L,new_header_length, "datafile-header")) goto err; if (param->testflag & T_UNPACK) { share->options&= ~HA_OPTION_COMPRESS_RECORD; mi_int2store(share->state.header.options,share->options); } share->state.dellink= HA_OFFSET_ERROR; info->rec_cache.file=new_file; } info->update= (short) (HA_STATE_CHANGED | HA_STATE_ROW_CHANGED); /* Optionally drop indexes and optionally modify the key_map. */ mi_drop_all_indexes(param, info, FALSE); key_map= share->state.key_map; if (param->testflag & T_CREATE_MISSING_KEYS) { /* Invert the copied key_map to recreate all disabled indexes. */ key_map= ~key_map; } sort_info.info=info; sort_info.param = param; set_data_file_type(&sort_info, share); sort_info.dupp=0; sort_info.buff=0; param->read_cache.end_of_file=sort_info.filelength= my_seek(param->read_cache.file,0L,MY_SEEK_END,MYF(0)); if (share->data_file_type == DYNAMIC_RECORD) rec_length=max(share->base.min_pack_length+1,share->base.min_block_length); else if (share->data_file_type == COMPRESSED_RECORD) rec_length=share->base.min_block_length; else rec_length=share->base.pack_reclength; /* +1 below is required hack for parallel repair mode. The info->state->records value, that is compared later to sort_info.max_records and cannot exceed it, is increased in sort_key_write. In mi_repair_by_sort, sort_key_write is called after sort_key_read, where the comparison is performed, but in parallel mode master thread can call sort_key_write before some other repair thread calls sort_key_read. Furthermore I'm not even sure +1 would be enough. May be sort_info.max_records shold be always set to max value in parallel mode. */ sort_info.max_records= ((param->testflag & T_CREATE_MISSING_KEYS) ? info->state->records + 1: (ha_rows) (sort_info.filelength/rec_length+1)); del=info->state->del; param->glob_crc=0; /* for compressed tables */ max_pack_reclength= share->base.pack_reclength; if (share->options & HA_OPTION_COMPRESS_RECORD) set_if_bigger(max_pack_reclength, share->max_pack_length); if (!(sort_param=(MI_SORT_PARAM *) my_malloc((uint) share->base.keys * (sizeof(MI_SORT_PARAM) + max_pack_reclength), MYF(MY_ZEROFILL)))) { mi_check_print_error(param,"Not enough memory for key!"); goto err; } total_key_length=0; rec_per_key_part= param->rec_per_key_part; info->state->records=info->state->del=share->state.split=0; info->state->empty=0; for (i=key=0, istep=1 ; key < share->base.keys ; rec_per_key_part+=sort_param[i].keyinfo->keysegs, i+=istep, key++) { sort_param[i].key=key; sort_param[i].keyinfo=share->keyinfo+key; sort_param[i].seg=sort_param[i].keyinfo->seg; /* Skip this index if it is marked disabled in the copied (and possibly inverted) key_map. */ if (! mi_is_key_active(key_map, key)) { /* Remember old statistics for key */ memcpy((char*) rec_per_key_part, (char*) (share->state.rec_per_key_part+ (uint) (rec_per_key_part - param->rec_per_key_part)), sort_param[i].keyinfo->keysegs*sizeof(*rec_per_key_part)); istep=0; continue; } istep=1; if ((!(param->testflag & T_SILENT))) printf ("- Fixing index %d\n",key+1); if (sort_param[i].keyinfo->flag & HA_FULLTEXT) { sort_param[i].key_read=sort_ft_key_read; sort_param[i].key_write=sort_ft_key_write; } else { sort_param[i].key_read=sort_key_read; sort_param[i].key_write=sort_key_write; } sort_param[i].key_cmp=sort_key_cmp; sort_param[i].lock_in_memory=lock_memory; sort_param[i].tmpdir=param->tmpdir; sort_param[i].sort_info=&sort_info; sort_param[i].master=0; sort_param[i].fix_datafile=0; sort_param[i].calc_checksum= 0; sort_param[i].filepos=new_header_length; sort_param[i].max_pos=sort_param[i].pos=share->pack.header_length; sort_param[i].record= (((char *)(sort_param+share->base.keys))+ (max_pack_reclength * i)); if (!mi_alloc_rec_buff(info, -1, &sort_param[i].rec_buff)) { mi_check_print_error(param,"Not enough memory!"); goto err; } sort_param[i].key_length=share->rec_reflength; for (keyseg=sort_param[i].seg; keyseg->type != HA_KEYTYPE_END; keyseg++) { sort_param[i].key_length+=keyseg->length; if (keyseg->flag & HA_SPACE_PACK) sort_param[i].key_length+=get_pack_length(keyseg->length); if (keyseg->flag & (HA_BLOB_PART | HA_VAR_LENGTH_PART)) sort_param[i].key_length+=2 + test(keyseg->length >= 127); if (keyseg->flag & HA_NULL_PART) sort_param[i].key_length++; } total_key_length+=sort_param[i].key_length; if (sort_param[i].keyinfo->flag & HA_FULLTEXT) { uint ft_max_word_len_for_sort=FT_MAX_WORD_LEN_FOR_SORT* sort_param[i].keyinfo->seg->charset->mbmaxlen; sort_param[i].key_length+=ft_max_word_len_for_sort-HA_FT_MAXBYTELEN; } } sort_info.total_keys=i; sort_param[0].master= 1; sort_param[0].fix_datafile= (my_bool)(! rep_quick); sort_param[0].calc_checksum= test(param->testflag & T_CALC_CHECKSUM); sort_info.got_error=0; pthread_mutex_lock(&sort_info.mutex); /* Initialize the I/O cache share for use with the read caches and, in case of non-quick repair, the write cache. When all threads join on the cache lock, the writer copies the write cache contents to the read caches. */ if (i > 1) { if (rep_quick) init_io_cache_share(¶m->read_cache, &io_share, NULL, i); else init_io_cache_share(&new_data_cache, &io_share, &info->rec_cache, i); } else io_share.total_threads= 0; /* share not used */ (void) pthread_attr_init(&thr_attr); (void) pthread_attr_setdetachstate(&thr_attr,PTHREAD_CREATE_DETACHED); for (i=0 ; i < sort_info.total_keys ; i++) { /* Copy the properly initialized IO_CACHE structure so that every thread has its own copy. In quick mode param->read_cache is shared for use by all threads. In non-quick mode all threads but the first copy the shared new_data_cache, which is synchronized to the write cache of the first thread. The first thread copies param->read_cache, which is not shared. */ sort_param[i].read_cache= ((rep_quick || !i) ? param->read_cache : new_data_cache); DBUG_PRINT("io_cache_share", ("thread: %u read_cache: 0x%lx", i, (long) &sort_param[i].read_cache)); /* two approaches: the same amount of memory for each thread or the memory for the same number of keys for each thread... In the second one all the threads will fill their sort_buffers (and call write_keys) at the same time, putting more stress on i/o. */ sort_param[i].sortbuff_size= #ifndef USING_SECOND_APPROACH param->sort_buffer_length/sort_info.total_keys; #else param->sort_buffer_length*sort_param[i].key_length/total_key_length; #endif if (pthread_create(&sort_param[i].thr, &thr_attr, thr_find_all_keys, (void *) (sort_param+i))) { mi_check_print_error(param,"Cannot start a repair thread"); /* Cleanup: Detach from the share. Avoid others to be blocked. */ if (io_share.total_threads) remove_io_thread(&sort_param[i].read_cache); DBUG_PRINT("error", ("Cannot start a repair thread")); sort_info.got_error=1; } else sort_info.threads_running++; } (void) pthread_attr_destroy(&thr_attr); /* waiting for all threads to finish */ while (sort_info.threads_running) pthread_cond_wait(&sort_info.cond, &sort_info.mutex); pthread_mutex_unlock(&sort_info.mutex); if ((got_error= thr_write_keys(sort_param))) { param->retry_repair=1; goto err; } got_error=1; /* Assume the following may go wrong */ if (sort_param[0].fix_datafile) { /* Append some nuls to the end of a memory mapped file. Destroy the write cache. The master thread did already detach from the share by remove_io_thread() in sort.c:thr_find_all_keys(). */ if (write_data_suffix(&sort_info,1) || end_io_cache(&info->rec_cache)) goto err; if (param->testflag & T_SAFE_REPAIR) { /* Don't repair if we loosed more than one row */ if (info->state->records+1 < start_records) { info->state->records=start_records; goto err; } } share->state.state.data_file_length= info->state->data_file_length= sort_param->filepos; /* Only whole records */ share->state.version=(ulong) time((time_t*) 0); /* Exchange the data file descriptor of the table, so that we use the new file from now on. */ my_close(info->dfile,MYF(0)); info->dfile=new_file; share->data_file_type=sort_info.new_data_file_type; share->pack.header_length=(ulong) new_header_length; } else info->state->data_file_length=sort_param->max_pos; if (rep_quick && del+sort_info.dupp != info->state->del) { mi_check_print_error(param,"Couldn't fix table with quick recovery: Found wrong number of deleted records"); mi_check_print_error(param,"Run recovery again without -q"); param->retry_repair=1; param->testflag|=T_RETRY_WITHOUT_QUICK; goto err; } if (rep_quick & T_FORCE_UNIQUENESS) { my_off_t skr=info->state->data_file_length+ (share->options & HA_OPTION_COMPRESS_RECORD ? MEMMAP_EXTRA_MARGIN : 0); #ifdef USE_RELOC if (share->data_file_type == STATIC_RECORD && skr < share->base.reloc*share->base.min_pack_length) skr=share->base.reloc*share->base.min_pack_length; #endif if (skr != sort_info.filelength && !info->s->base.raid_type) if (my_chsize(info->dfile,skr,0,MYF(0))) mi_check_print_warning(param, "Can't change size of datafile, error: %d", my_errno); } if (param->testflag & T_CALC_CHECKSUM) info->state->checksum=param->glob_crc; if (my_chsize(share->kfile,info->state->key_file_length,0,MYF(0))) mi_check_print_warning(param, "Can't change size of indexfile, error: %d", my_errno); if (!(param->testflag & T_SILENT)) { if (start_records != info->state->records) printf("Data records: %s\n", llstr(info->state->records,llbuff)); if (sort_info.dupp) mi_check_print_warning(param, "%s records have been removed", llstr(sort_info.dupp,llbuff)); } got_error=0; if (&share->state.state != info->state) memcpy(&share->state.state, info->state, sizeof(*info->state)); err: got_error|= flush_blocks(param, share->key_cache, share->kfile); /* Destroy the write cache. The master thread did already detach from the share by remove_io_thread() or it was not yet started (if the error happend before creating the thread). */ VOID(end_io_cache(&info->rec_cache)); /* Destroy the new data cache in case of non-quick repair. All slave threads did either detach from the share by remove_io_thread() already or they were not yet started (if the error happend before creating the threads). */ if (!rep_quick) VOID(end_io_cache(&new_data_cache)); if (!got_error) { /* Replace the actual file with the temporary file */ if (new_file >= 0) { my_close(new_file,MYF(0)); info->dfile=new_file= -1; if (change_to_newfile(share->data_file_name,MI_NAME_DEXT, DATA_TMP_EXT, share->base.raid_chunks, (param->testflag & T_BACKUP_DATA ? MYF(MY_REDEL_MAKE_BACKUP): MYF(0))) || mi_open_datafile(info,share,-1)) got_error=1; } } if (got_error) { if (! param->error_printed) mi_check_print_error(param,"%d when fixing table",my_errno); if (new_file >= 0) { VOID(my_close(new_file,MYF(0))); VOID(my_raid_delete(param->temp_filename,share->base.raid_chunks, MYF(MY_WME))); if (info->dfile == new_file) info->dfile= -1; } mi_mark_crashed_on_repair(info); } else if (key_map == share->state.key_map) share->state.changed&= ~STATE_NOT_OPTIMIZED_KEYS; share->state.changed|=STATE_NOT_SORTED_PAGES; pthread_cond_destroy (&sort_info.cond); pthread_mutex_destroy(&sort_info.mutex); my_free((gptr) sort_info.ft_buf, MYF(MY_ALLOW_ZERO_PTR)); my_free((gptr) sort_info.key_block,MYF(MY_ALLOW_ZERO_PTR)); my_free((gptr) sort_param,MYF(MY_ALLOW_ZERO_PTR)); my_free(sort_info.buff,MYF(MY_ALLOW_ZERO_PTR)); VOID(end_io_cache(¶m->read_cache)); info->opt_flag&= ~(READ_CACHE_USED | WRITE_CACHE_USED); if (!got_error && (param->testflag & T_UNPACK)) { share->state.header.options[0]&= (uchar) ~HA_OPTION_COMPRESS_RECORD; share->pack.header_length=0; } DBUG_RETURN(got_error); #endif /* THREAD */ } /* Read next record and return next key */ static int sort_key_read(MI_SORT_PARAM *sort_param, void *key) { int error; SORT_INFO *sort_info=sort_param->sort_info; MI_INFO *info=sort_info->info; DBUG_ENTER("sort_key_read"); if ((error=sort_get_next_record(sort_param))) DBUG_RETURN(error); if (info->state->records == sort_info->max_records) { mi_check_print_error(sort_info->param, "Key %d - Found too many records; Can't continue", sort_param->key+1); DBUG_RETURN(1); } sort_param->real_key_length= (info->s->rec_reflength+ _mi_make_key(info, sort_param->key, (uchar*) key, sort_param->record, sort_param->filepos)); #ifdef HAVE_purify bzero(key+sort_param->real_key_length, (sort_param->key_length-sort_param->real_key_length)); #endif DBUG_RETURN(sort_write_record(sort_param)); } /* sort_key_read */ static int sort_ft_key_read(MI_SORT_PARAM *sort_param, void *key) { int error; SORT_INFO *sort_info=sort_param->sort_info; MI_INFO *info=sort_info->info; FT_WORD *wptr=0; DBUG_ENTER("sort_ft_key_read"); if (!sort_param->wordlist) { for (;;) { my_free((char*) wptr, MYF(MY_ALLOW_ZERO_PTR)); if ((error=sort_get_next_record(sort_param))) DBUG_RETURN(error); if (!(wptr=_mi_ft_parserecord(info,sort_param->key,sort_param->record))) DBUG_RETURN(1); if (wptr->pos) break; error=sort_write_record(sort_param); } sort_param->wordptr=sort_param->wordlist=wptr; } else { error=0; wptr=(FT_WORD*)(sort_param->wordptr); } sort_param->real_key_length=(info->s->rec_reflength+ _ft_make_key(info, sort_param->key, key, wptr++, sort_param->filepos)); #ifdef HAVE_purify if (sort_param->key_length > sort_param->real_key_length) bzero(key+sort_param->real_key_length, (sort_param->key_length-sort_param->real_key_length)); #endif if (!wptr->pos) { my_free((char*) sort_param->wordlist, MYF(0)); sort_param->wordlist=0; error=sort_write_record(sort_param); } else sort_param->wordptr=(void*)wptr; DBUG_RETURN(error); } /* sort_ft_key_read */ /* Read next record from file using parameters in sort_info. SYNOPSIS sort_get_next_record() sort_param Information about and for the sort process NOTE Dynamic Records With Non-Quick Parallel Repair For non-quick parallel repair we use a synchronized read/write cache. This means that one thread is the master who fixes the data file by reading each record from the old data file and writing it to the new data file. By doing this the records in the new data file are written contiguously. Whenever the write buffer is full, it is copied to the read buffer. The slaves read from the read buffer, which is not associated with a file. Thus read_cache.file is -1. When using _mi_read_cache(), the slaves must always set flag to READING_NEXT so that the function never tries to read from file. This is safe because the records are contiguous. There is no need to read outside the cache. This condition is evaluated in the variable 'parallel_flag' for quick reference. read_cache.file must be >= 0 in every other case. RETURN -1 end of file 0 ok > 0 error */ static int sort_get_next_record(MI_SORT_PARAM *sort_param) { int searching; int parallel_flag; uint found_record,b_type,left_length; my_off_t pos; byte *to; MI_BLOCK_INFO block_info; SORT_INFO *sort_info=sort_param->sort_info; MI_CHECK *param=sort_info->param; MI_INFO *info=sort_info->info; MYISAM_SHARE *share=info->s; char llbuff[22],llbuff2[22]; DBUG_ENTER("sort_get_next_record"); if (*killed_ptr(param)) DBUG_RETURN(1); switch (share->data_file_type) { case STATIC_RECORD: for (;;) { if (my_b_read(&sort_param->read_cache,sort_param->record, share->base.pack_reclength)) { if (sort_param->read_cache.error) param->out_flag |= O_DATA_LOST; param->retry_repair=1; param->testflag|=T_RETRY_WITHOUT_QUICK; DBUG_RETURN(-1); } sort_param->start_recpos=sort_param->pos; if (!sort_param->fix_datafile) { sort_param->filepos=sort_param->pos; if (sort_param->master) share->state.split++; } sort_param->max_pos=(sort_param->pos+=share->base.pack_reclength); if (*sort_param->record) { if (sort_param->calc_checksum) param->glob_crc+= (info->checksum= mi_static_checksum(info,sort_param->record)); DBUG_RETURN(0); } if (!sort_param->fix_datafile && sort_param->master) { info->state->del++; info->state->empty+=share->base.pack_reclength; } } case DYNAMIC_RECORD: LINT_INIT(to); pos=sort_param->pos; searching=(sort_param->fix_datafile && (param->testflag & T_EXTEND)); parallel_flag= (sort_param->read_cache.file < 0) ? READING_NEXT : 0; for (;;) { found_record=block_info.second_read= 0; left_length=1; if (searching) { pos=MY_ALIGN(pos,MI_DYN_ALIGN_SIZE); param->testflag|=T_RETRY_WITHOUT_QUICK; sort_param->start_recpos=pos; } do { if (pos > sort_param->max_pos) sort_param->max_pos=pos; if (pos & (MI_DYN_ALIGN_SIZE-1)) { if ((param->testflag & T_VERBOSE) || searching == 0) mi_check_print_info(param,"Wrong aligned block at %s", llstr(pos,llbuff)); if (searching) goto try_next; } if (found_record && pos == param->search_after_block) mi_check_print_info(param,"Block: %s used by record at %s", llstr(param->search_after_block,llbuff), llstr(sort_param->start_recpos,llbuff2)); if (_mi_read_cache(&sort_param->read_cache, (byte*) block_info.header,pos, MI_BLOCK_INFO_HEADER_LENGTH, (! found_record ? READING_NEXT : 0) | parallel_flag | READING_HEADER)) { if (found_record) { mi_check_print_info(param, "Can't read whole record at %s (errno: %d)", llstr(sort_param->start_recpos,llbuff),errno); goto try_next; } DBUG_RETURN(-1); } if (searching && ! sort_param->fix_datafile) { param->error_printed=1; param->retry_repair=1; param->testflag|=T_RETRY_WITHOUT_QUICK; DBUG_RETURN(1); /* Something wrong with data */ } b_type=_mi_get_block_info(&block_info,-1,pos); if ((b_type & (BLOCK_ERROR | BLOCK_FATAL_ERROR)) || ((b_type & BLOCK_FIRST) && (block_info.rec_len < (uint) share->base.min_pack_length || block_info.rec_len > (uint) share->base.max_pack_length))) { uint i; if (param->testflag & T_VERBOSE || searching == 0) mi_check_print_info(param, "Wrong bytesec: %3d-%3d-%3d at %10s; Skipped", block_info.header[0],block_info.header[1], block_info.header[2],llstr(pos,llbuff)); if (found_record) goto try_next; block_info.second_read=0; searching=1; /* Search after block in read header string */ for (i=MI_DYN_ALIGN_SIZE ; i < MI_BLOCK_INFO_HEADER_LENGTH ; i+= MI_DYN_ALIGN_SIZE) if (block_info.header[i] >= 1 && block_info.header[i] <= MI_MAX_DYN_HEADER_BYTE) break; pos+=(ulong) i; sort_param->start_recpos=pos; continue; } if (b_type & BLOCK_DELETED) { bool error=0; if (block_info.block_len+ (uint) (block_info.filepos-pos) < share->base.min_block_length) { if (!searching) mi_check_print_info(param, "Deleted block with impossible length %u at %s", block_info.block_len,llstr(pos,llbuff)); error=1; } else { if ((block_info.next_filepos != HA_OFFSET_ERROR && block_info.next_filepos >= info->state->data_file_length) || (block_info.prev_filepos != HA_OFFSET_ERROR && block_info.prev_filepos >= info->state->data_file_length)) { if (!searching) mi_check_print_info(param, "Delete link points outside datafile at %s", llstr(pos,llbuff)); error=1; } } if (error) { if (found_record) goto try_next; searching=1; pos+= MI_DYN_ALIGN_SIZE; sort_param->start_recpos=pos; block_info.second_read=0; continue; } } else { if (block_info.block_len+ (uint) (block_info.filepos-pos) < share->base.min_block_length || block_info.block_len > (uint) share->base.max_pack_length+ MI_SPLIT_LENGTH) { if (!searching) mi_check_print_info(param, "Found block with impossible length %u at %s; Skipped", block_info.block_len+ (uint) (block_info.filepos-pos), llstr(pos,llbuff)); if (found_record) goto try_next; searching=1; pos+= MI_DYN_ALIGN_SIZE; sort_param->start_recpos=pos; block_info.second_read=0; continue; } } if (b_type & (BLOCK_DELETED | BLOCK_SYNC_ERROR)) { if (!sort_param->fix_datafile && sort_param->master && (b_type & BLOCK_DELETED)) { info->state->empty+=block_info.block_len; info->state->del++; share->state.split++; } if (found_record) goto try_next; if (searching) { pos+=MI_DYN_ALIGN_SIZE; sort_param->start_recpos=pos; } else pos=block_info.filepos+block_info.block_len; block_info.second_read=0; continue; } if (!sort_param->fix_datafile && sort_param->master) share->state.split++; if (! found_record++) { sort_param->find_length=left_length=block_info.rec_len; sort_param->start_recpos=pos; if (!sort_param->fix_datafile) sort_param->filepos=sort_param->start_recpos; if (sort_param->fix_datafile && (param->testflag & T_EXTEND)) sort_param->pos=block_info.filepos+1; else sort_param->pos=block_info.filepos+block_info.block_len; if (share->base.blobs) { if (!(to=mi_alloc_rec_buff(info,block_info.rec_len, &(sort_param->rec_buff)))) { if (param->max_record_length >= block_info.rec_len) { mi_check_print_error(param,"Not enough memory for blob at %s (need %lu)", llstr(sort_param->start_recpos,llbuff), (ulong) block_info.rec_len); DBUG_RETURN(1); } else { mi_check_print_info(param,"Not enough memory for blob at %s (need %lu); Row skipped", llstr(sort_param->start_recpos,llbuff), (ulong) block_info.rec_len); goto try_next; } } } else to= sort_param->rec_buff; } if (left_length < block_info.data_len || ! block_info.data_len) { mi_check_print_info(param, "Found block with too small length at %s; Skipped", llstr(sort_param->start_recpos,llbuff)); goto try_next; } if (block_info.filepos + block_info.data_len > sort_param->read_cache.end_of_file) { mi_check_print_info(param, "Found block that points outside data file at %s", llstr(sort_param->start_recpos,llbuff)); goto try_next; } /* Copy information that is already read. Avoid accessing data below the cache start. This could happen if the header streched over the end of the previous buffer contents. */ { uint header_len= (uint) (block_info.filepos - pos); uint prefetch_len= (MI_BLOCK_INFO_HEADER_LENGTH - header_len); if (prefetch_len > block_info.data_len) prefetch_len= block_info.data_len; if (prefetch_len) { memcpy(to, block_info.header + header_len, prefetch_len); block_info.filepos+= prefetch_len; block_info.data_len-= prefetch_len; left_length-= prefetch_len; to+= prefetch_len; } } if (block_info.data_len && _mi_read_cache(&sort_param->read_cache,to,block_info.filepos, block_info.data_len, (found_record == 1 ? READING_NEXT : 0) | parallel_flag)) { mi_check_print_info(param, "Read error for block at: %s (error: %d); Skipped", llstr(block_info.filepos,llbuff),my_errno); goto try_next; } left_length-=block_info.data_len; to+=block_info.data_len; pos=block_info.next_filepos; if (pos == HA_OFFSET_ERROR && left_length) { mi_check_print_info(param,"Wrong block with wrong total length starting at %s", llstr(sort_param->start_recpos,llbuff)); goto try_next; } if (pos + MI_BLOCK_INFO_HEADER_LENGTH > sort_param->read_cache.end_of_file) { mi_check_print_info(param,"Found link that points at %s (outside data file) at %s", llstr(pos,llbuff2), llstr(sort_param->start_recpos,llbuff)); goto try_next; } } while (left_length); if (_mi_rec_unpack(info,sort_param->record,sort_param->rec_buff, sort_param->find_length) != MY_FILE_ERROR) { if (sort_param->read_cache.error < 0) DBUG_RETURN(1); if (sort_param->calc_checksum) info->checksum= mi_checksum(info, sort_param->record); if ((param->testflag & (T_EXTEND | T_REP)) || searching) { if (_mi_rec_check(info, sort_param->record, sort_param->rec_buff, sort_param->find_length, (param->testflag & T_QUICK) && sort_param->calc_checksum && test(info->s->calc_checksum))) { mi_check_print_info(param,"Found wrong packed record at %s", llstr(sort_param->start_recpos,llbuff)); goto try_next; } } if (sort_param->calc_checksum) param->glob_crc+= info->checksum; DBUG_RETURN(0); } if (!searching) mi_check_print_info(param,"Key %d - Found wrong stored record at %s", sort_param->key+1, llstr(sort_param->start_recpos,llbuff)); try_next: pos=(sort_param->start_recpos+=MI_DYN_ALIGN_SIZE); searching=1; } case COMPRESSED_RECORD: for (searching=0 ;; searching=1, sort_param->pos++) { if (_mi_read_cache(&sort_param->read_cache,(byte*) block_info.header, sort_param->pos, share->pack.ref_length,READING_NEXT)) DBUG_RETURN(-1); if (searching && ! sort_param->fix_datafile) { param->error_printed=1; param->retry_repair=1; param->testflag|=T_RETRY_WITHOUT_QUICK; DBUG_RETURN(1); /* Something wrong with data */ } sort_param->start_recpos=sort_param->pos; if (_mi_pack_get_block_info(info, &sort_param->bit_buff, &block_info, &sort_param->rec_buff, -1, sort_param->pos)) DBUG_RETURN(-1); if (!block_info.rec_len && sort_param->pos + MEMMAP_EXTRA_MARGIN == sort_param->read_cache.end_of_file) DBUG_RETURN(-1); if (block_info.rec_len < (uint) share->min_pack_length || block_info.rec_len > (uint) share->max_pack_length) { if (! searching) mi_check_print_info(param,"Found block with wrong recordlength: %d at %s\n", block_info.rec_len, llstr(sort_param->pos,llbuff)); continue; } if (_mi_read_cache(&sort_param->read_cache,(byte*) sort_param->rec_buff, block_info.filepos, block_info.rec_len, READING_NEXT)) { if (! searching) mi_check_print_info(param,"Couldn't read whole record from %s", llstr(sort_param->pos,llbuff)); continue; } if (_mi_pack_rec_unpack(info, &sort_param->bit_buff, sort_param->record, sort_param->rec_buff, block_info.rec_len)) { if (! searching) mi_check_print_info(param,"Found wrong record at %s", llstr(sort_param->pos,llbuff)); continue; } if (!sort_param->fix_datafile) { sort_param->filepos=sort_param->pos; if (sort_param->master) share->state.split++; } sort_param->max_pos=(sort_param->pos=block_info.filepos+ block_info.rec_len); info->packed_length=block_info.rec_len; if (sort_param->calc_checksum) param->glob_crc+= (info->checksum= mi_checksum(info, sort_param->record)); DBUG_RETURN(0); } } DBUG_RETURN(1); /* Impossible */ } /* Write record to new file. SYNOPSIS sort_write_record() sort_param Sort parameters. NOTE This is only called by a master thread if parallel repair is used. RETURN 0 OK 1 Error */ int sort_write_record(MI_SORT_PARAM *sort_param) { int flag; uint length; ulong block_length,reclength; byte *from; byte block_buff[8]; SORT_INFO *sort_info=sort_param->sort_info; MI_CHECK *param=sort_info->param; MI_INFO *info=sort_info->info; MYISAM_SHARE *share=info->s; DBUG_ENTER("sort_write_record"); if (sort_param->fix_datafile) { switch (sort_info->new_data_file_type) { case STATIC_RECORD: if (my_b_write(&info->rec_cache,sort_param->record, share->base.pack_reclength)) { mi_check_print_error(param,"%d when writing to datafile",my_errno); DBUG_RETURN(1); } sort_param->filepos+=share->base.pack_reclength; info->s->state.split++; /* sort_info->param->glob_crc+=mi_static_checksum(info, sort_param->record); */ break; case DYNAMIC_RECORD: if (! info->blobs) from=sort_param->rec_buff; else { /* must be sure that local buffer is big enough */ reclength=info->s->base.pack_reclength+ _my_calc_total_blob_length(info,sort_param->record)+ ALIGN_SIZE(MI_MAX_DYN_BLOCK_HEADER)+MI_SPLIT_LENGTH+ MI_DYN_DELETE_BLOCK_HEADER; if (sort_info->buff_length < reclength) { if (!(sort_info->buff=my_realloc(sort_info->buff, (uint) reclength, MYF(MY_FREE_ON_ERROR | MY_ALLOW_ZERO_PTR)))) DBUG_RETURN(1); sort_info->buff_length=reclength; } from=sort_info->buff+ALIGN_SIZE(MI_MAX_DYN_BLOCK_HEADER); } /* We can use info->checksum here as only one thread calls this. */ info->checksum=mi_checksum(info,sort_param->record); reclength=_mi_rec_pack(info,from,sort_param->record); flag=0; /* sort_info->param->glob_crc+=info->checksum; */ do { block_length=reclength+ 3 + test(reclength >= (65520-3)); if (block_length < share->base.min_block_length) block_length=share->base.min_block_length; info->update|=HA_STATE_WRITE_AT_END; block_length=MY_ALIGN(block_length,MI_DYN_ALIGN_SIZE); if (block_length > MI_MAX_BLOCK_LENGTH) block_length=MI_MAX_BLOCK_LENGTH; if (_mi_write_part_record(info,0L,block_length, sort_param->filepos+block_length, &from,&reclength,&flag)) { mi_check_print_error(param,"%d when writing to datafile",my_errno); DBUG_RETURN(1); } sort_param->filepos+=block_length; info->s->state.split++; } while (reclength); /* sort_info->param->glob_crc+=info->checksum; */ break; case COMPRESSED_RECORD: reclength=info->packed_length; length= save_pack_length((uint) share->pack.version, block_buff, reclength); if (info->s->base.blobs) length+= save_pack_length((uint) share->pack.version, block_buff + length, info->blob_length); if (my_b_write(&info->rec_cache,block_buff,length) || my_b_write(&info->rec_cache,(byte*) sort_param->rec_buff,reclength)) { mi_check_print_error(param,"%d when writing to datafile",my_errno); DBUG_RETURN(1); } /* sort_info->param->glob_crc+=info->checksum; */ sort_param->filepos+=reclength+length; info->s->state.split++; break; } } if (sort_param->master) { info->state->records++; if ((param->testflag & T_WRITE_LOOP) && (info->state->records % WRITE_COUNT) == 0) { char llbuff[22]; printf("%s\r", llstr(info->state->records,llbuff)); VOID(fflush(stdout)); } } DBUG_RETURN(0); } /* sort_write_record */ /* Compare two keys from _create_index_by_sort */ static int sort_key_cmp(MI_SORT_PARAM *sort_param, const void *a, const void *b) { uint not_used[2]; return (ha_key_cmp(sort_param->seg, *((uchar**) a), *((uchar**) b), USE_WHOLE_KEY, SEARCH_SAME, not_used)); } /* sort_key_cmp */ static int sort_key_write(MI_SORT_PARAM *sort_param, const void *a) { uint diff_pos[2]; char llbuff[22],llbuff2[22]; SORT_INFO *sort_info=sort_param->sort_info; MI_CHECK *param= sort_info->param; int cmp; if (sort_info->key_block->inited) { cmp=ha_key_cmp(sort_param->seg,sort_info->key_block->lastkey, (uchar*) a, USE_WHOLE_KEY,SEARCH_FIND | SEARCH_UPDATE, diff_pos); if (param->stats_method == MI_STATS_METHOD_NULLS_NOT_EQUAL) ha_key_cmp(sort_param->seg,sort_info->key_block->lastkey, (uchar*) a, USE_WHOLE_KEY, SEARCH_FIND | SEARCH_NULL_ARE_NOT_EQUAL, diff_pos); else if (param->stats_method == MI_STATS_METHOD_IGNORE_NULLS) { diff_pos[0]= mi_collect_stats_nonulls_next(sort_param->seg, sort_param->notnull, sort_info->key_block->lastkey, (uchar*)a); } sort_param->unique[diff_pos[0]-1]++; } else { cmp= -1; if (param->stats_method == MI_STATS_METHOD_IGNORE_NULLS) mi_collect_stats_nonulls_first(sort_param->seg, sort_param->notnull, (uchar*)a); } if ((sort_param->keyinfo->flag & HA_NOSAME) && cmp == 0) { sort_info->dupp++; sort_info->info->lastpos=get_record_for_key(sort_info->info, sort_param->keyinfo, (uchar*) a); mi_check_print_warning(param, "Duplicate key for record at %10s against record at %10s", llstr(sort_info->info->lastpos,llbuff), llstr(get_record_for_key(sort_info->info, sort_param->keyinfo, sort_info->key_block-> lastkey), llbuff2)); param->testflag|=T_RETRY_WITHOUT_QUICK; if (sort_info->param->testflag & T_VERBOSE) _mi_print_key(stdout,sort_param->seg,(uchar*) a, USE_WHOLE_KEY); return (sort_delete_record(sort_param)); } #ifndef DBUG_OFF if (cmp > 0) { mi_check_print_error(param, "Internal error: Keys are not in order from sort"); return(1); } #endif return (sort_insert_key(sort_param,sort_info->key_block, (uchar*) a, HA_OFFSET_ERROR)); } /* sort_key_write */ int sort_ft_buf_flush(MI_SORT_PARAM *sort_param) { SORT_INFO *sort_info=sort_param->sort_info; SORT_KEY_BLOCKS *key_block=sort_info->key_block; MYISAM_SHARE *share=sort_info->info->s; uint val_off, val_len; int error; SORT_FT_BUF *ft_buf=sort_info->ft_buf; uchar *from, *to; val_len=share->ft2_keyinfo.keylength; get_key_full_length_rdonly(val_off, ft_buf->lastkey); to=ft_buf->lastkey+val_off; if (ft_buf->buf) { /* flushing first-level tree */ error=sort_insert_key(sort_param,key_block,ft_buf->lastkey, HA_OFFSET_ERROR); for (from=to+val_len; !error && from < ft_buf->buf; from+= val_len) { memcpy(to, from, val_len); error=sort_insert_key(sort_param,key_block,ft_buf->lastkey, HA_OFFSET_ERROR); } return error; } /* flushing second-level tree keyblocks */ error=flush_pending_blocks(sort_param); /* updating lastkey with second-level tree info */ ft_intXstore(ft_buf->lastkey+val_off, -ft_buf->count); _mi_dpointer(sort_info->info, ft_buf->lastkey+val_off+HA_FT_WLEN, share->state.key_root[sort_param->key]); /* restoring first level tree data in sort_info/sort_param */ sort_info->key_block=sort_info->key_block_end- sort_info->param->sort_key_blocks; sort_param->keyinfo=share->keyinfo+sort_param->key; share->state.key_root[sort_param->key]=HA_OFFSET_ERROR; /* writing lastkey in first-level tree */ return error ? error : sort_insert_key(sort_param,sort_info->key_block, ft_buf->lastkey,HA_OFFSET_ERROR); } static int sort_ft_key_write(MI_SORT_PARAM *sort_param, const void *a) { uint a_len, val_off, val_len, error; uchar *p; SORT_INFO *sort_info=sort_param->sort_info; SORT_FT_BUF *ft_buf=sort_info->ft_buf; SORT_KEY_BLOCKS *key_block=sort_info->key_block; val_len=HA_FT_WLEN+sort_info->info->s->base.rec_reflength; get_key_full_length_rdonly(a_len, (uchar *)a); if (!ft_buf) { /* use two-level tree only if key_reflength fits in rec_reflength place and row format is NOT static - for _mi_dpointer not to garble offsets */ if ((sort_info->info->s->base.key_reflength <= sort_info->info->s->base.rec_reflength) && (sort_info->info->s->options & (HA_OPTION_PACK_RECORD | HA_OPTION_COMPRESS_RECORD))) ft_buf=(SORT_FT_BUF *)my_malloc(sort_param->keyinfo->block_length + sizeof(SORT_FT_BUF), MYF(MY_WME)); if (!ft_buf) { sort_param->key_write=sort_key_write; return sort_key_write(sort_param, a); } sort_info->ft_buf=ft_buf; goto word_init_ft_buf; /* no need to duplicate the code */ } get_key_full_length_rdonly(val_off, ft_buf->lastkey); if (mi_compare_text(sort_param->seg->charset, ((uchar *)a)+1,a_len-1, ft_buf->lastkey+1,val_off-1, 0, 0)==0) { if (!ft_buf->buf) /* store in second-level tree */ { ft_buf->count++; return sort_insert_key(sort_param,key_block, ((uchar *)a)+a_len, HA_OFFSET_ERROR); } /* storing the key in the buffer. */ memcpy (ft_buf->buf, (char *)a+a_len, val_len); ft_buf->buf+=val_len; if (ft_buf->buf < ft_buf->end) return 0; /* converting to two-level tree */ p=ft_buf->lastkey+val_off; while (key_block->inited) key_block++; sort_info->key_block=key_block; sort_param->keyinfo=& sort_info->info->s->ft2_keyinfo; ft_buf->count=(ft_buf->buf - p)/val_len; /* flushing buffer to second-level tree */ for (error=0; !error && p < ft_buf->buf; p+= val_len) error=sort_insert_key(sort_param,key_block,p,HA_OFFSET_ERROR); ft_buf->buf=0; return error; } /* flushing buffer */ if ((error=sort_ft_buf_flush(sort_param))) return error; word_init_ft_buf: a_len+=val_len; memcpy(ft_buf->lastkey, a, a_len); ft_buf->buf=ft_buf->lastkey+a_len; /* 32 is just a safety margin here (at least max(val_len, sizeof(nod_flag)) should be there). May be better performance could be achieved if we'd put (sort_info->keyinfo->block_length-32)/XXX instead. TODO: benchmark the best value for XXX. */ ft_buf->end=ft_buf->lastkey+ (sort_param->keyinfo->block_length-32); return 0; } /* sort_ft_key_write */ /* get pointer to record from a key */ static my_off_t get_record_for_key(MI_INFO *info, MI_KEYDEF *keyinfo, uchar *key) { return _mi_dpos(info,0,key+_mi_keylength(keyinfo,key)); } /* get_record_for_key */ /* Insert a key in sort-key-blocks */ static int sort_insert_key(MI_SORT_PARAM *sort_param, register SORT_KEY_BLOCKS *key_block, uchar *key, my_off_t prev_block) { uint a_length,t_length,nod_flag; my_off_t filepos,key_file_length; uchar *anc_buff,*lastkey; MI_KEY_PARAM s_temp; MI_INFO *info; MI_KEYDEF *keyinfo=sort_param->keyinfo; SORT_INFO *sort_info= sort_param->sort_info; MI_CHECK *param=sort_info->param; DBUG_ENTER("sort_insert_key"); anc_buff=key_block->buff; info=sort_info->info; lastkey=key_block->lastkey; nod_flag= (key_block == sort_info->key_block ? 0 : info->s->base.key_reflength); if (!key_block->inited) { key_block->inited=1; if (key_block == sort_info->key_block_end) { mi_check_print_error(param,"To many key-block-levels; Try increasing sort_key_blocks"); DBUG_RETURN(1); } a_length=2+nod_flag; key_block->end_pos=anc_buff+2; lastkey=0; /* No previous key in block */ } else a_length=mi_getint(anc_buff); /* Save pointer to previous block */ if (nod_flag) _mi_kpointer(info,key_block->end_pos,prev_block); t_length=(*keyinfo->pack_key)(keyinfo,nod_flag, (uchar*) 0,lastkey,lastkey,key, &s_temp); (*keyinfo->store_key)(keyinfo, key_block->end_pos+nod_flag,&s_temp); a_length+=t_length; mi_putint(anc_buff,a_length,nod_flag); key_block->end_pos+=t_length; if (a_length <= keyinfo->block_length) { VOID(_mi_move_key(keyinfo,key_block->lastkey,key)); key_block->last_length=a_length-t_length; DBUG_RETURN(0); } /* Fill block with end-zero and write filled block */ mi_putint(anc_buff,key_block->last_length,nod_flag); bzero((byte*) anc_buff+key_block->last_length, keyinfo->block_length- key_block->last_length); key_file_length=info->state->key_file_length; if ((filepos=_mi_new(info,keyinfo,DFLT_INIT_HITS)) == HA_OFFSET_ERROR) DBUG_RETURN(1); /* If we read the page from the key cache, we have to write it back to it */ if (key_file_length == info->state->key_file_length) { if (_mi_write_keypage(info, keyinfo, filepos, DFLT_INIT_HITS, anc_buff)) DBUG_RETURN(1); } else if (my_pwrite(info->s->kfile,(byte*) anc_buff, (uint) keyinfo->block_length,filepos, param->myf_rw)) DBUG_RETURN(1); DBUG_DUMP("buff",(uchar*) anc_buff,mi_getint(anc_buff)); /* Write separator-key to block in next level */ if (sort_insert_key(sort_param,key_block+1,key_block->lastkey,filepos)) DBUG_RETURN(1); /* clear old block and write new key in it */ key_block->inited=0; DBUG_RETURN(sort_insert_key(sort_param, key_block,key,prev_block)); } /* sort_insert_key */ /* Delete record when we found a duplicated key */ static int sort_delete_record(MI_SORT_PARAM *sort_param) { uint i; int old_file,error; uchar *key; SORT_INFO *sort_info=sort_param->sort_info; MI_CHECK *param=sort_info->param; MI_INFO *info=sort_info->info; DBUG_ENTER("sort_delete_record"); if ((param->testflag & (T_FORCE_UNIQUENESS|T_QUICK)) == T_QUICK) { mi_check_print_error(param, "Quick-recover aborted; Run recovery without switch -q or with switch -qq"); DBUG_RETURN(1); } if (info->s->options & HA_OPTION_COMPRESS_RECORD) { mi_check_print_error(param, "Recover aborted; Can't run standard recovery on compressed tables with errors in data-file. Use switch 'myisamchk --safe-recover' to fix it\n",stderr);; DBUG_RETURN(1); } old_file=info->dfile; info->dfile=info->rec_cache.file; if (sort_info->current_key) { key=info->lastkey+info->s->base.max_key_length; if ((error=(*info->s->read_rnd)(info,sort_param->record,info->lastpos,0)) && error != HA_ERR_RECORD_DELETED) { mi_check_print_error(param,"Can't read record to be removed"); info->dfile=old_file; DBUG_RETURN(1); } for (i=0 ; i < sort_info->current_key ; i++) { uint key_length=_mi_make_key(info,i,key,sort_param->record,info->lastpos); if (_mi_ck_delete(info,i,key,key_length)) { mi_check_print_error(param,"Can't delete key %d from record to be removed",i+1); info->dfile=old_file; DBUG_RETURN(1); } } if (sort_param->calc_checksum) param->glob_crc-=(*info->s->calc_checksum)(info, sort_param->record); } error=flush_io_cache(&info->rec_cache) || (*info->s->delete_record)(info); info->dfile=old_file; /* restore actual value */ info->state->records--; DBUG_RETURN(error); } /* sort_delete_record */ /* Fix all pending blocks and flush everything to disk */ int flush_pending_blocks(MI_SORT_PARAM *sort_param) { uint nod_flag,length; my_off_t filepos,key_file_length; SORT_KEY_BLOCKS *key_block; SORT_INFO *sort_info= sort_param->sort_info; myf myf_rw=sort_info->param->myf_rw; MI_INFO *info=sort_info->info; MI_KEYDEF *keyinfo=sort_param->keyinfo; DBUG_ENTER("flush_pending_blocks"); filepos= HA_OFFSET_ERROR; /* if empty file */ nod_flag=0; for (key_block=sort_info->key_block ; key_block->inited ; key_block++) { key_block->inited=0; length=mi_getint(key_block->buff); if (nod_flag) _mi_kpointer(info,key_block->end_pos,filepos); key_file_length=info->state->key_file_length; bzero((byte*) key_block->buff+length, keyinfo->block_length-length); if ((filepos=_mi_new(info,keyinfo,DFLT_INIT_HITS)) == HA_OFFSET_ERROR) DBUG_RETURN(1); /* If we read the page from the key cache, we have to write it back */ if (key_file_length == info->state->key_file_length) { if (_mi_write_keypage(info, keyinfo, filepos, DFLT_INIT_HITS, key_block->buff)) DBUG_RETURN(1); } else if (my_pwrite(info->s->kfile,(byte*) key_block->buff, (uint) keyinfo->block_length,filepos, myf_rw)) DBUG_RETURN(1); DBUG_DUMP("buff",(uchar*) key_block->buff,length); nod_flag=1; } info->s->state.key_root[sort_param->key]=filepos; /* Last is root for tree */ DBUG_RETURN(0); } /* flush_pending_blocks */ /* alloc space and pointers for key_blocks */ static SORT_KEY_BLOCKS *alloc_key_blocks(MI_CHECK *param, uint blocks, uint buffer_length) { reg1 uint i; SORT_KEY_BLOCKS *block; DBUG_ENTER("alloc_key_blocks"); if (!(block=(SORT_KEY_BLOCKS*) my_malloc((sizeof(SORT_KEY_BLOCKS)+ buffer_length+IO_SIZE)*blocks, MYF(0)))) { mi_check_print_error(param,"Not enough memory for sort-key-blocks"); return(0); } for (i=0 ; i < blocks ; i++) { block[i].inited=0; block[i].buff=(uchar*) (block+blocks)+(buffer_length+IO_SIZE)*i; } DBUG_RETURN(block); } /* alloc_key_blocks */ /* Check if file is almost full */ int test_if_almost_full(MI_INFO *info) { if (info->s->options & HA_OPTION_COMPRESS_RECORD) return 0; return my_seek(info->s->kfile, 0L, MY_SEEK_END, MYF(MY_THREADSAFE)) / 10 * 9 > (my_off_t) info->s->base.max_key_file_length || my_seek(info->dfile, 0L, MY_SEEK_END, MYF(0)) / 10 * 9 > (my_off_t) info->s->base.max_data_file_length; } /* Recreate table with bigger more alloced record-data */ int recreate_table(MI_CHECK *param, MI_INFO **org_info, char *filename) { int error; MI_INFO info; MYISAM_SHARE share; MI_KEYDEF *keyinfo,*key,*key_end; HA_KEYSEG *keysegs,*keyseg; MI_COLUMNDEF *recdef,*rec,*end; MI_UNIQUEDEF *uniquedef,*u_ptr,*u_end; MI_STATUS_INFO status_info; uint unpack,key_parts; ha_rows max_records; ulonglong file_length,tmp_length; MI_CREATE_INFO create_info; DBUG_ENTER("recreate_table"); error=1; /* Default error */ info= **org_info; status_info= (*org_info)->state[0]; info.state= &status_info; share= *(*org_info)->s; unpack= (share.options & HA_OPTION_COMPRESS_RECORD) && (param->testflag & T_UNPACK); if (!(keyinfo=(MI_KEYDEF*) my_alloca(sizeof(MI_KEYDEF)*share.base.keys))) DBUG_RETURN(0); memcpy((byte*) keyinfo,(byte*) share.keyinfo, (size_t) (sizeof(MI_KEYDEF)*share.base.keys)); key_parts= share.base.all_key_parts; if (!(keysegs=(HA_KEYSEG*) my_alloca(sizeof(HA_KEYSEG)* (key_parts+share.base.keys)))) { my_afree((gptr) keyinfo); DBUG_RETURN(1); } if (!(recdef=(MI_COLUMNDEF*) my_alloca(sizeof(MI_COLUMNDEF)*(share.base.fields+1)))) { my_afree((gptr) keyinfo); my_afree((gptr) keysegs); DBUG_RETURN(1); } if (!(uniquedef=(MI_UNIQUEDEF*) my_alloca(sizeof(MI_UNIQUEDEF)*(share.state.header.uniques+1)))) { my_afree((gptr) recdef); my_afree((gptr) keyinfo); my_afree((gptr) keysegs); DBUG_RETURN(1); } /* Copy the column definitions */ memcpy((byte*) recdef,(byte*) share.rec, (size_t) (sizeof(MI_COLUMNDEF)*(share.base.fields+1))); for (rec=recdef,end=recdef+share.base.fields; rec != end ; rec++) { if (unpack && !(share.options & HA_OPTION_PACK_RECORD) && rec->type != FIELD_BLOB && rec->type != FIELD_VARCHAR && rec->type != FIELD_CHECK) rec->type=(int) FIELD_NORMAL; } /* Change the new key to point at the saved key segments */ memcpy((byte*) keysegs,(byte*) share.keyparts, (size_t) (sizeof(HA_KEYSEG)*(key_parts+share.base.keys+ share.state.header.uniques))); keyseg=keysegs; for (key=keyinfo,key_end=keyinfo+share.base.keys; key != key_end ; key++) { key->seg=keyseg; for (; keyseg->type ; keyseg++) { if (param->language) keyseg->language=param->language; /* change language */ } keyseg++; /* Skip end pointer */ } /* Copy the unique definitions and change them to point at the new key segments*/ memcpy((byte*) uniquedef,(byte*) share.uniqueinfo, (size_t) (sizeof(MI_UNIQUEDEF)*(share.state.header.uniques))); for (u_ptr=uniquedef,u_end=uniquedef+share.state.header.uniques; u_ptr != u_end ; u_ptr++) { u_ptr->seg=keyseg; keyseg+=u_ptr->keysegs+1; } if (share.options & HA_OPTION_COMPRESS_RECORD) share.base.records=max_records=info.state->records; else if (share.base.min_pack_length) max_records=(ha_rows) (my_seek(info.dfile,0L,MY_SEEK_END,MYF(0)) / (ulong) share.base.min_pack_length); else max_records=0; unpack= (share.options & HA_OPTION_COMPRESS_RECORD) && (param->testflag & T_UNPACK); share.options&= ~HA_OPTION_TEMP_COMPRESS_RECORD; file_length=(ulonglong) my_seek(info.dfile,0L,MY_SEEK_END,MYF(0)); tmp_length= file_length+file_length/10; set_if_bigger(file_length,param->max_data_file_length); set_if_bigger(file_length,tmp_length); set_if_bigger(file_length,(ulonglong) share.base.max_data_file_length); VOID(mi_close(*org_info)); bzero((char*) &create_info,sizeof(create_info)); create_info.max_rows=max(max_records,share.base.records); create_info.reloc_rows=share.base.reloc; create_info.old_options=(share.options | (unpack ? HA_OPTION_TEMP_COMPRESS_RECORD : 0)); create_info.data_file_length=file_length; create_info.auto_increment=share.state.auto_increment; create_info.raid_type= share.base.raid_type; create_info.raid_chunks= share.base.raid_chunks; create_info.raid_chunksize= share.base.raid_chunksize; create_info.language = (param->language ? param->language : share.state.header.language); create_info.key_file_length= status_info.key_file_length; /* Allow for creating an auto_increment key. This has an effect only if an auto_increment key exists in the original table. */ create_info.with_auto_increment= TRUE; /* We don't have to handle symlinks here because we are using HA_DONT_TOUCH_DATA */ if (mi_create(filename, share.base.keys - share.state.header.uniques, keyinfo, share.base.fields, recdef, share.state.header.uniques, uniquedef, &create_info, HA_DONT_TOUCH_DATA)) { mi_check_print_error(param,"Got error %d when trying to recreate indexfile",my_errno); goto end; } *org_info=mi_open(filename,O_RDWR, (param->testflag & T_WAIT_FOREVER) ? HA_OPEN_WAIT_IF_LOCKED : (param->testflag & T_DESCRIPT) ? HA_OPEN_IGNORE_IF_LOCKED : HA_OPEN_ABORT_IF_LOCKED); if (!*org_info) { mi_check_print_error(param,"Got error %d when trying to open re-created indexfile", my_errno); goto end; } /* We are modifing */ (*org_info)->s->options&= ~HA_OPTION_READ_ONLY_DATA; VOID(_mi_readinfo(*org_info,F_WRLCK,0)); (*org_info)->state->records=info.state->records; if (share.state.create_time) (*org_info)->s->state.create_time=share.state.create_time; (*org_info)->s->state.unique=(*org_info)->this_unique= share.state.unique; (*org_info)->state->checksum=info.state->checksum; (*org_info)->state->del=info.state->del; (*org_info)->s->state.dellink=share.state.dellink; (*org_info)->state->empty=info.state->empty; (*org_info)->state->data_file_length=info.state->data_file_length; if (update_state_info(param,*org_info,UPDATE_TIME | UPDATE_STAT | UPDATE_OPEN_COUNT)) goto end; error=0; end: my_afree((gptr) uniquedef); my_afree((gptr) keyinfo); my_afree((gptr) recdef); my_afree((gptr) keysegs); DBUG_RETURN(error); } /* write suffix to data file if neaded */ int write_data_suffix(SORT_INFO *sort_info, my_bool fix_datafile) { MI_INFO *info=sort_info->info; if (info->s->options & HA_OPTION_COMPRESS_RECORD && fix_datafile) { char buff[MEMMAP_EXTRA_MARGIN]; bzero(buff,sizeof(buff)); if (my_b_write(&info->rec_cache,buff,sizeof(buff))) { mi_check_print_error(sort_info->param, "%d when writing to datafile",my_errno); return 1; } sort_info->param->read_cache.end_of_file+=sizeof(buff); } return 0; } /* Update state and myisamchk_time of indexfile */ int update_state_info(MI_CHECK *param, MI_INFO *info,uint update) { MYISAM_SHARE *share=info->s; if (update & UPDATE_OPEN_COUNT) { share->state.open_count=0; share->global_changed=0; } if (update & UPDATE_STAT) { uint i, key_parts= mi_uint2korr(share->state.header.key_parts); share->state.rec_per_key_rows=info->state->records; share->state.changed&= ~STATE_NOT_ANALYZED; if (info->state->records) { for (i=0; istate.rec_per_key_part[i]=param->rec_per_key_part[i])) share->state.changed|= STATE_NOT_ANALYZED; } } } if (update & (UPDATE_STAT | UPDATE_SORT | UPDATE_TIME | UPDATE_AUTO_INC)) { if (update & UPDATE_TIME) { share->state.check_time= (long) time((time_t*) 0); if (!share->state.create_time) share->state.create_time=share->state.check_time; } /* When tables are locked we haven't synched the share state and the real state for a while so we better do it here before synching the share state to disk. Only when table is write locked is it necessary to perform this synch. */ if (info->lock_type == F_WRLCK) share->state.state= *info->state; if (mi_state_info_write(share->kfile,&share->state,1+2)) goto err; share->changed=0; } { /* Force update of status */ int error; uint r_locks=share->r_locks,w_locks=share->w_locks; share->r_locks= share->w_locks= share->tot_locks= 0; error=_mi_writeinfo(info,WRITEINFO_NO_UNLOCK); share->r_locks=r_locks; share->w_locks=w_locks; share->tot_locks=r_locks+w_locks; if (!error) return 0; } err: mi_check_print_error(param,"%d when updating keyfile",my_errno); return 1; } /* Update auto increment value for a table When setting the 'repair_only' flag we only want to change the old auto_increment value if its wrong (smaller than some given key). The reason is that we shouldn't change the auto_increment value for a table without good reason when only doing a repair; If the user have inserted and deleted rows, the auto_increment value may be bigger than the biggest current row and this is ok. If repair_only is not set, we will update the flag to the value in param->auto_increment is bigger than the biggest key. */ void update_auto_increment_key(MI_CHECK *param, MI_INFO *info, my_bool repair_only) { byte *record= 0; DBUG_ENTER("update_auto_increment_key"); if (!info->s->base.auto_key || ! mi_is_key_active(info->s->state.key_map, info->s->base.auto_key - 1)) { if (!(param->testflag & T_VERY_SILENT)) mi_check_print_info(param, "Table: %s doesn't have an auto increment key\n", param->isam_file_name); DBUG_VOID_RETURN; } if (!(param->testflag & T_SILENT) && !(param->testflag & T_REP)) printf("Updating MyISAM file: %s\n", param->isam_file_name); /* We have to use an allocated buffer instead of info->rec_buff as _mi_put_key_in_record() may use info->rec_buff */ if (!mi_alloc_rec_buff(info, -1, &record)) { mi_check_print_error(param,"Not enough memory for extra record"); DBUG_VOID_RETURN; } mi_extra(info,HA_EXTRA_KEYREAD,0); if (mi_rlast(info, record, info->s->base.auto_key-1)) { if (my_errno != HA_ERR_END_OF_FILE) { mi_extra(info,HA_EXTRA_NO_KEYREAD,0); my_free(mi_get_rec_buff_ptr(info, record), MYF(0)); mi_check_print_error(param,"%d when reading last record",my_errno); DBUG_VOID_RETURN; } if (!repair_only) info->s->state.auto_increment=param->auto_increment_value; } else { ulonglong auto_increment= retrieve_auto_increment(info, record); set_if_bigger(info->s->state.auto_increment,auto_increment); if (!repair_only) set_if_bigger(info->s->state.auto_increment, param->auto_increment_value); } mi_extra(info,HA_EXTRA_NO_KEYREAD,0); my_free(mi_get_rec_buff_ptr(info, record), MYF(0)); update_state_info(param, info, UPDATE_AUTO_INC); DBUG_VOID_RETURN; } /* Update statistics for each part of an index SYNOPSIS update_key_parts() keyinfo IN Index information (only key->keysegs used) rec_per_key_part OUT Store statistics here unique IN Array of (#distinct tuples) notnull_tuples IN Array of (#tuples), or NULL records Number of records in the table DESCRIPTION This function is called produce index statistics values from unique and notnull_tuples arrays after these arrays were produced with sequential index scan (the scan is done in two places: chk_index() and sort_key_write()). This function handles all 3 index statistics collection methods. Unique is an array: unique[0]= (#different values of {keypart1}) - 1 unique[1]= (#different values of {keypart1,keypart2} tuple)-unique[0]-1 ... For MI_STATS_METHOD_IGNORE_NULLS method, notnull_tuples is an array too: notnull_tuples[0]= (#of {keypart1} tuples such that keypart1 is not NULL) notnull_tuples[1]= (#of {keypart1,keypart2} tuples such that all keypart{i} are not NULL) ... For all other statistics collection methods notnull_tuples==NULL. Output is an array: rec_per_key_part[k] = = E(#records in the table such that keypart_1=c_1 AND ... AND keypart_k=c_k for arbitrary constants c_1 ... c_k) = {assuming that values have uniform distribution and index contains all tuples from the domain (or that {c_1, ..., c_k} tuple is choosen from index tuples} = #tuples-in-the-index / #distinct-tuples-in-the-index. The #tuples-in-the-index and #distinct-tuples-in-the-index have different meaning depending on which statistics collection method is used: MI_STATS_METHOD_* how are nulls compared? which tuples are counted? NULLS_EQUAL NULL == NULL all tuples in table NULLS_NOT_EQUAL NULL != NULL all tuples in table IGNORE_NULLS n/a tuples that don't have NULLs */ void update_key_parts(MI_KEYDEF *keyinfo, ulong *rec_per_key_part, ulonglong *unique, ulonglong *notnull, ulonglong records) { ulonglong count=0,tmp, unique_tuples; ulonglong tuples= records; uint parts; for (parts=0 ; parts < keyinfo->keysegs ; parts++) { count+=unique[parts]; unique_tuples= count + 1; if (notnull) { tuples= notnull[parts]; /* #(unique_tuples not counting tuples with NULLs) = #(unique_tuples counting tuples with NULLs as different) - #(tuples with NULLs) */ unique_tuples -= (records - notnull[parts]); } if (unique_tuples == 0) tmp= 1; else if (count == 0) tmp= tuples; /* 1 unique tuple */ else tmp= (tuples + unique_tuples/2) / unique_tuples; /* for some weird keys (e.g. FULLTEXT) tmp can be <1 here. let's ensure it is not */ set_if_bigger(tmp,1); if (tmp >= (ulonglong) ~(ulong) 0) tmp=(ulonglong) ~(ulong) 0; *rec_per_key_part=(ulong) tmp; rec_per_key_part++; } } static ha_checksum mi_byte_checksum(const byte *buf, uint length) { ha_checksum crc; const byte *end=buf+length; for (crc=0; buf != end; buf++) crc=((crc << 1) + *((uchar*) buf)) + test(crc & (((ha_checksum) 1) << (8*sizeof(ha_checksum)-1))); return crc; } static my_bool mi_too_big_key_for_sort(MI_KEYDEF *key, ha_rows rows) { uint key_maxlength=key->maxlength; if (key->flag & HA_FULLTEXT) { uint ft_max_word_len_for_sort=FT_MAX_WORD_LEN_FOR_SORT* key->seg->charset->mbmaxlen; key_maxlength+=ft_max_word_len_for_sort-HA_FT_MAXBYTELEN; } return (key->flag & HA_SPATIAL) || (key->flag & (HA_BINARY_PACK_KEY | HA_VAR_LENGTH_KEY | HA_FULLTEXT) && ((ulonglong) rows * key_maxlength > (ulonglong) myisam_max_temp_length)); } /* Deactivate all not unique index that can be recreated fast These include packed keys on which sorting will use more temporary space than the max allowed file length or for which the unpacked keys will take much more space than packed keys. Note that 'rows' may be zero for the case when we don't know how many rows we will put into the file. */ void mi_disable_non_unique_index(MI_INFO *info, ha_rows rows) { MYISAM_SHARE *share=info->s; MI_KEYDEF *key=share->keyinfo; uint i; DBUG_ASSERT(info->state->records == 0 && (!rows || rows >= MI_MIN_ROWS_TO_DISABLE_INDEXES)); for (i=0 ; i < share->base.keys ; i++,key++) { if (!(key->flag & (HA_NOSAME | HA_SPATIAL | HA_AUTO_KEY)) && ! mi_too_big_key_for_sort(key,rows) && info->s->base.auto_key != i+1) { mi_clear_key_active(share->state.key_map, i); info->update|= HA_STATE_CHANGED; } } } /* Return TRUE if we can use repair by sorting One can set the force argument to force to use sorting even if the temporary file would be quite big! */ my_bool mi_test_if_sort_rep(MI_INFO *info, ha_rows rows, ulonglong key_map, my_bool force) { MYISAM_SHARE *share=info->s; MI_KEYDEF *key=share->keyinfo; uint i; /* mi_repair_by_sort only works if we have at least one key. If we don't have any keys, we should use the normal repair. */ if (! mi_is_any_key_active(key_map)) return FALSE; /* Can't use sort */ for (i=0 ; i < share->base.keys ; i++,key++) { if (!force && mi_too_big_key_for_sort(key,rows)) return FALSE; } return TRUE; } static void set_data_file_type(SORT_INFO *sort_info, MYISAM_SHARE *share) { if ((sort_info->new_data_file_type=share->data_file_type) == COMPRESSED_RECORD && sort_info->param->testflag & T_UNPACK) { MYISAM_SHARE tmp; if (share->options & HA_OPTION_PACK_RECORD) sort_info->new_data_file_type = DYNAMIC_RECORD; else sort_info->new_data_file_type = STATIC_RECORD; /* Set delete_function for sort_delete_record() */ memcpy((char*) &tmp, share, sizeof(*share)); tmp.options= ~HA_OPTION_COMPRESS_RECORD; mi_setup_functions(&tmp); share->delete_record=tmp.delete_record; } }