/* Copyright (C) 2002-2006 MySQL AB & Ramil Kalimullin 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 */ #include "myisamdef.h" #ifdef HAVE_RTREE_KEYS #include "rt_index.h" #include "rt_key.h" #include "rt_mbr.h" #define REINSERT_BUFFER_INC 10 #define PICK_BY_AREA /*#define PICK_BY_PERIMETER*/ typedef struct st_page_level { uint level; my_off_t offs; } stPageLevel; typedef struct st_page_list { ulong n_pages; ulong m_pages; stPageLevel *pages; } stPageList; /* Find next key in r-tree according to search_flag recursively NOTES Used in rtree_find_first() and rtree_find_next() RETURN -1 Error 0 Found 1 Not found */ static int rtree_find_req(MI_INFO *info, MI_KEYDEF *keyinfo, uint search_flag, uint nod_cmp_flag, my_off_t page, int level) { uchar *k; uchar *last; uint nod_flag; int res; uchar *page_buf; int k_len; uint *saved_key = (uint*) (info->rtree_recursion_state) + level; if (!(page_buf = (uchar*)my_alloca((uint)keyinfo->block_length))) { my_errno = HA_ERR_OUT_OF_MEM; return -1; } if (!_mi_fetch_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf, 0)) goto err1; nod_flag = mi_test_if_nod(page_buf); k_len = keyinfo->keylength - info->s->base.rec_reflength; if(info->rtree_recursion_depth >= level) { k = page_buf + *saved_key; } else { k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); } last = rt_PAGE_END(page_buf); for (; k < last; k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag)) { if (nod_flag) { /* this is an internal node in the tree */ if (!(res = rtree_key_cmp(keyinfo->seg, info->first_mbr_key, k, info->last_rkey_length, nod_cmp_flag))) { switch ((res = rtree_find_req(info, keyinfo, search_flag, nod_cmp_flag, _mi_kpos(nod_flag, k), level + 1))) { case 0: /* found - exit from recursion */ *saved_key = (uint) (k - page_buf); goto ok; case 1: /* not found - continue searching */ info->rtree_recursion_depth = level; break; default: /* error */ case -1: goto err1; } } } else { /* this is a leaf */ if (!rtree_key_cmp(keyinfo->seg, info->first_mbr_key, k, info->last_rkey_length, search_flag)) { uchar *after_key = rt_PAGE_NEXT_KEY(k, k_len, nod_flag); info->lastpos = _mi_dpos(info, 0, after_key); info->lastkey_length = k_len + info->s->base.rec_reflength; memcpy(info->lastkey, k, info->lastkey_length); info->rtree_recursion_depth = level; *saved_key = (uint) (last - page_buf); if (after_key < last) { info->int_keypos = info->buff; info->int_maxpos = info->buff + (last - after_key); memcpy(info->buff, after_key, last - after_key); info->buff_used = 0; } else { info->buff_used = 1; } res = 0; goto ok; } } } info->lastpos = HA_OFFSET_ERROR; my_errno = HA_ERR_KEY_NOT_FOUND; res = 1; ok: my_afree((byte*)page_buf); return res; err1: my_afree((byte*)page_buf); info->lastpos = HA_OFFSET_ERROR; return -1; } /* Find first key in r-tree according to search_flag condition SYNOPSIS rtree_find_first() info Handler to MyISAM file uint keynr Key number to use key Key to search for key_length Length of 'key' search_flag Bitmap of flags how to do the search RETURN -1 Error 0 Found 1 Not found */ int rtree_find_first(MI_INFO *info, uint keynr, uchar *key, uint key_length, uint search_flag) { my_off_t root; uint nod_cmp_flag; MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; if ((root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) { my_errno= HA_ERR_END_OF_FILE; return -1; } /* Save searched key, include data pointer. The data pointer is required if the search_flag contains MBR_DATA. (minimum bounding rectangle) */ memcpy(info->first_mbr_key, key, keyinfo->keylength); info->last_rkey_length = key_length; info->rtree_recursion_depth = -1; info->buff_used = 1; nod_cmp_flag = ((search_flag & (MBR_EQUAL | MBR_WITHIN)) ? MBR_WITHIN : MBR_INTERSECT); return rtree_find_req(info, keyinfo, search_flag, nod_cmp_flag, root, 0); } /* Find next key in r-tree according to search_flag condition SYNOPSIS rtree_find_next() info Handler to MyISAM file uint keynr Key number to use search_flag Bitmap of flags how to do the search RETURN -1 Error 0 Found 1 Not found */ int rtree_find_next(MI_INFO *info, uint keynr, uint search_flag) { my_off_t root; uint nod_cmp_flag; MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; if (info->update & HA_STATE_DELETED) return rtree_find_first(info, keynr, info->lastkey, info->lastkey_length, search_flag); if (!info->buff_used) { uchar *key= info->int_keypos; while (key < info->int_maxpos) { if (!rtree_key_cmp(keyinfo->seg, info->first_mbr_key, key, info->last_rkey_length, search_flag)) { uchar *after_key = key + keyinfo->keylength; info->lastpos= _mi_dpos(info, 0, after_key); memcpy(info->lastkey, key, info->lastkey_length); if (after_key < info->int_maxpos) info->int_keypos= after_key; else info->buff_used= 1; return 0; } key+= keyinfo->keylength; } } if ((root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) { my_errno= HA_ERR_END_OF_FILE; return -1; } nod_cmp_flag = ((search_flag & (MBR_EQUAL | MBR_WITHIN)) ? MBR_WITHIN : MBR_INTERSECT); return rtree_find_req(info, keyinfo, search_flag, nod_cmp_flag, root, 0); } /* Get next key in r-tree recursively NOTES Used in rtree_get_first() and rtree_get_next() RETURN -1 Error 0 Found 1 Not found */ static int rtree_get_req(MI_INFO *info, MI_KEYDEF *keyinfo, uint key_length, my_off_t page, int level) { uchar *k; uchar *last; uint nod_flag; int res; uchar *page_buf; uint k_len; uint *saved_key = (uint*) (info->rtree_recursion_state) + level; if (!(page_buf = (uchar*)my_alloca((uint)keyinfo->block_length))) return -1; if (!_mi_fetch_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf, 0)) goto err1; nod_flag = mi_test_if_nod(page_buf); k_len = keyinfo->keylength - info->s->base.rec_reflength; if(info->rtree_recursion_depth >= level) { k = page_buf + *saved_key; if (!nod_flag) { /* Only leaf pages contain data references. */ /* Need to check next key with data reference. */ k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag); } } else { k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); } last = rt_PAGE_END(page_buf); for (; k < last; k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag)) { if (nod_flag) { /* this is an internal node in the tree */ switch ((res = rtree_get_req(info, keyinfo, key_length, _mi_kpos(nod_flag, k), level + 1))) { case 0: /* found - exit from recursion */ *saved_key = (uint) (k - page_buf); goto ok; case 1: /* not found - continue searching */ info->rtree_recursion_depth = level; break; default: case -1: /* error */ goto err1; } } else { /* this is a leaf */ uchar *after_key = rt_PAGE_NEXT_KEY(k, k_len, nod_flag); info->lastpos = _mi_dpos(info, 0, after_key); info->lastkey_length = k_len + info->s->base.rec_reflength; memcpy(info->lastkey, k, info->lastkey_length); info->rtree_recursion_depth = level; *saved_key = (uint) (k - page_buf); if (after_key < last) { info->int_keypos = (uchar*)saved_key; memcpy(info->buff, page_buf, keyinfo->block_length); info->int_maxpos = rt_PAGE_END(info->buff); info->buff_used = 0; } else { info->buff_used = 1; } res = 0; goto ok; } } info->lastpos = HA_OFFSET_ERROR; my_errno = HA_ERR_KEY_NOT_FOUND; res = 1; ok: my_afree((byte*)page_buf); return res; err1: my_afree((byte*)page_buf); info->lastpos = HA_OFFSET_ERROR; return -1; } /* Get first key in r-tree RETURN -1 Error 0 Found 1 Not found */ int rtree_get_first(MI_INFO *info, uint keynr, uint key_length) { my_off_t root; MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; if ((root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) { my_errno= HA_ERR_END_OF_FILE; return -1; } info->rtree_recursion_depth = -1; info->buff_used = 1; return rtree_get_req(info, keyinfo, key_length, root, 0); } /* Get next key in r-tree RETURN -1 Error 0 Found 1 Not found */ int rtree_get_next(MI_INFO *info, uint keynr, uint key_length) { my_off_t root; MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; if (!info->buff_used) { uint k_len = keyinfo->keylength - info->s->base.rec_reflength; /* rt_PAGE_NEXT_KEY(info->int_keypos) */ uchar *key = info->buff + *(int*)info->int_keypos + k_len + info->s->base.rec_reflength; /* rt_PAGE_NEXT_KEY(key) */ uchar *after_key = key + k_len + info->s->base.rec_reflength; info->lastpos = _mi_dpos(info, 0, after_key); info->lastkey_length = k_len + info->s->base.rec_reflength; memcpy(info->lastkey, key, k_len + info->s->base.rec_reflength); *(uint*)info->int_keypos = (uint) (key - info->buff); if (after_key >= info->int_maxpos) { info->buff_used = 1; } return 0; } else { if ((root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) { my_errno= HA_ERR_END_OF_FILE; return -1; } return rtree_get_req(info, keyinfo, key_length, root, 0); } } /* Choose non-leaf better key for insertion */ #ifdef PICK_BY_PERIMETER static uchar *rtree_pick_key(MI_INFO *info, MI_KEYDEF *keyinfo, uchar *key, uint key_length, uchar *page_buf, uint nod_flag) { double increase; double best_incr = DBL_MAX; double perimeter; double best_perimeter; uchar *best_key; uchar *k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); uchar *last = rt_PAGE_END(page_buf); LINT_INIT(best_perimeter); LINT_INIT(best_key); for (; k < last; k = rt_PAGE_NEXT_KEY(k, key_length, nod_flag)) { if ((increase = rtree_perimeter_increase(keyinfo->seg, k, key, key_length, &perimeter)) == -1) return NULL; if ((increase < best_incr)|| (increase == best_incr && perimeter < best_perimeter)) { best_key = k; best_perimeter= perimeter; best_incr = increase; } } return best_key; } #endif /*PICK_BY_PERIMETER*/ #ifdef PICK_BY_AREA static uchar *rtree_pick_key(MI_INFO *info, MI_KEYDEF *keyinfo, uchar *key, uint key_length, uchar *page_buf, uint nod_flag) { double increase; double best_incr; double area; double best_area; uchar *best_key= NULL; uchar *k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); uchar *last = rt_PAGE_END(page_buf); LINT_INIT(best_area); LINT_INIT(best_key); LINT_INIT(best_incr); for (; k < last; k = rt_PAGE_NEXT_KEY(k, key_length, nod_flag)) { /* The following is safe as -1.0 is an exact number */ if ((increase = rtree_area_increase(keyinfo->seg, k, key, key_length, &area)) == -1.0) return NULL; /* The following should be safe, even if we compare doubles */ if (!best_key || increase < best_incr || ((increase == best_incr) && (area < best_area))) { best_key = k; best_area = area; best_incr = increase; } } return best_key; } #endif /*PICK_BY_AREA*/ /* Go down and insert key into tree RETURN -1 Error 0 Child was not split 1 Child was split */ static int rtree_insert_req(MI_INFO *info, MI_KEYDEF *keyinfo, uchar *key, uint key_length, my_off_t page, my_off_t *new_page, int ins_level, int level) { uchar *k; uint nod_flag; uchar *page_buf; int res; DBUG_ENTER("rtree_insert_req"); if (!(page_buf = (uchar*)my_alloca((uint)keyinfo->block_length + MI_MAX_KEY_BUFF))) { my_errno = HA_ERR_OUT_OF_MEM; DBUG_RETURN(-1); /* purecov: inspected */ } if (!_mi_fetch_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf, 0)) goto err1; nod_flag = mi_test_if_nod(page_buf); DBUG_PRINT("rtree", ("page: %lu level: %d ins_level: %d nod_flag: %u", (ulong) page, level, ins_level, nod_flag)); if ((ins_level == -1 && nod_flag) || /* key: go down to leaf */ (ins_level > -1 && ins_level > level)) /* branch: go down to ins_level */ { if ((k = rtree_pick_key(info, keyinfo, key, key_length, page_buf, nod_flag)) == NULL) goto err1; switch ((res = rtree_insert_req(info, keyinfo, key, key_length, _mi_kpos(nod_flag, k), new_page, ins_level, level + 1))) { case 0: /* child was not split */ { rtree_combine_rect(keyinfo->seg, k, key, k, key_length); if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; goto ok; } case 1: /* child was split */ { uchar *new_key = page_buf + keyinfo->block_length + nod_flag; /* set proper MBR for key */ if (rtree_set_key_mbr(info, keyinfo, k, key_length, _mi_kpos(nod_flag, k))) goto err1; /* add new key for new page */ _mi_kpointer(info, new_key - nod_flag, *new_page); if (rtree_set_key_mbr(info, keyinfo, new_key, key_length, *new_page)) goto err1; res = rtree_add_key(info, keyinfo, new_key, key_length, page_buf, new_page); if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; goto ok; } default: case -1: /* error */ { goto err1; } } } else { res = rtree_add_key(info, keyinfo, key, key_length, page_buf, new_page); if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; goto ok; } ok: my_afree((byte*)page_buf); DBUG_RETURN(res); err1: my_afree((byte*)page_buf); DBUG_RETURN(-1); /* purecov: inspected */ } /* Insert key into the tree RETURN -1 Error 0 Root was not split 1 Root was split */ static int rtree_insert_level(MI_INFO *info, uint keynr, uchar *key, uint key_length, int ins_level) { my_off_t old_root; MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; int res; my_off_t new_page; DBUG_ENTER("rtree_insert_level"); if ((old_root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) { if ((old_root = _mi_new(info, keyinfo, DFLT_INIT_HITS)) == HA_OFFSET_ERROR) DBUG_RETURN(-1); info->buff_used = 1; mi_putint(info->buff, 2, 0); res = rtree_add_key(info, keyinfo, key, key_length, info->buff, NULL); if (_mi_write_keypage(info, keyinfo, old_root, DFLT_INIT_HITS, info->buff)) DBUG_RETURN(1); info->s->state.key_root[keynr] = old_root; DBUG_RETURN(res); } switch ((res = rtree_insert_req(info, keyinfo, key, key_length, old_root, &new_page, ins_level, 0))) { case 0: /* root was not split */ { break; } case 1: /* root was split, grow a new root */ { uchar *new_root_buf; my_off_t new_root; uchar *new_key; uint nod_flag = info->s->base.key_reflength; DBUG_PRINT("rtree", ("root was split, grow a new root")); if (!(new_root_buf = (uchar*)my_alloca((uint)keyinfo->block_length + MI_MAX_KEY_BUFF))) { my_errno = HA_ERR_OUT_OF_MEM; DBUG_RETURN(-1); /* purecov: inspected */ } mi_putint(new_root_buf, 2, nod_flag); if ((new_root = _mi_new(info, keyinfo, DFLT_INIT_HITS)) == HA_OFFSET_ERROR) goto err1; new_key = new_root_buf + keyinfo->block_length + nod_flag; _mi_kpointer(info, new_key - nod_flag, old_root); if (rtree_set_key_mbr(info, keyinfo, new_key, key_length, old_root)) goto err1; if (rtree_add_key(info, keyinfo, new_key, key_length, new_root_buf, NULL) == -1) goto err1; _mi_kpointer(info, new_key - nod_flag, new_page); if (rtree_set_key_mbr(info, keyinfo, new_key, key_length, new_page)) goto err1; if (rtree_add_key(info, keyinfo, new_key, key_length, new_root_buf, NULL) == -1) goto err1; if (_mi_write_keypage(info, keyinfo, new_root, DFLT_INIT_HITS, new_root_buf)) goto err1; info->s->state.key_root[keynr] = new_root; DBUG_PRINT("rtree", ("new root page: %lu level: %d nod_flag: %u", (ulong) new_root, 0, mi_test_if_nod(new_root_buf))); my_afree((byte*)new_root_buf); break; err1: my_afree((byte*)new_root_buf); DBUG_RETURN(-1); /* purecov: inspected */ } default: case -1: /* error */ { break; } } DBUG_RETURN(res); } /* Insert key into the tree - interface function RETURN -1 Error 0 OK */ int rtree_insert(MI_INFO *info, uint keynr, uchar *key, uint key_length) { DBUG_ENTER("rtree_insert"); DBUG_RETURN((!key_length || (rtree_insert_level(info, keynr, key, key_length, -1) == -1)) ? -1 : 0); } /* Fill reinsert page buffer RETURN -1 Error 0 OK */ static int rtree_fill_reinsert_list(stPageList *ReinsertList, my_off_t page, int level) { DBUG_ENTER("rtree_fill_reinsert_list"); DBUG_PRINT("rtree", ("page: %lu level: %d", (ulong) page, level)); if (ReinsertList->n_pages == ReinsertList->m_pages) { ReinsertList->m_pages += REINSERT_BUFFER_INC; if (!(ReinsertList->pages = (stPageLevel*)my_realloc((gptr)ReinsertList->pages, ReinsertList->m_pages * sizeof(stPageLevel), MYF(MY_ALLOW_ZERO_PTR)))) goto err1; } /* save page to ReinsertList */ ReinsertList->pages[ReinsertList->n_pages].offs = page; ReinsertList->pages[ReinsertList->n_pages].level = level; ReinsertList->n_pages++; DBUG_RETURN(0); err1: DBUG_RETURN(-1); /* purecov: inspected */ } /* Go down and delete key from the tree RETURN -1 Error 0 Deleted 1 Not found 2 Empty leaf */ static int rtree_delete_req(MI_INFO *info, MI_KEYDEF *keyinfo, uchar *key, uint key_length, my_off_t page, uint *page_size, stPageList *ReinsertList, int level) { uchar *k; uchar *last; ulong i; uint nod_flag; uchar *page_buf; int res; DBUG_ENTER("rtree_delete_req"); if (!(page_buf = (uchar*)my_alloca((uint)keyinfo->block_length))) { my_errno = HA_ERR_OUT_OF_MEM; DBUG_RETURN(-1); /* purecov: inspected */ } if (!_mi_fetch_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf, 0)) goto err1; nod_flag = mi_test_if_nod(page_buf); DBUG_PRINT("rtree", ("page: %lu level: %d nod_flag: %u", (ulong) page, level, nod_flag)); k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); last = rt_PAGE_END(page_buf); for (i = 0; k < last; k = rt_PAGE_NEXT_KEY(k, key_length, nod_flag), ++i) { if (nod_flag) { /* not leaf */ if (!rtree_key_cmp(keyinfo->seg, key, k, key_length, MBR_WITHIN)) { switch ((res = rtree_delete_req(info, keyinfo, key, key_length, _mi_kpos(nod_flag, k), page_size, ReinsertList, level + 1))) { case 0: /* deleted */ { /* test page filling */ if (*page_size + key_length >= rt_PAGE_MIN_SIZE(keyinfo->block_length)) { /* OK */ /* Calculate a new key value (MBR) for the shrinked block. */ if (rtree_set_key_mbr(info, keyinfo, k, key_length, _mi_kpos(nod_flag, k))) goto err1; if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; } else { /* Too small: delete key & add it descendant to reinsert list. Store position and level of the block so that it can be accessed later for inserting the remaining keys. */ DBUG_PRINT("rtree", ("too small. move block to reinsert list")); if (rtree_fill_reinsert_list(ReinsertList, _mi_kpos(nod_flag, k), level + 1)) goto err1; /* Delete the key that references the block. This makes the block disappear from the index. Hence we need to insert its remaining keys later. Note: if the block is a branch block, we do not only remove this block, but the whole subtree. So we need to re-insert its keys on the same level later to reintegrate the subtrees. */ rtree_delete_key(info, page_buf, k, key_length, nod_flag); if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; *page_size = mi_getint(page_buf); } goto ok; } case 1: /* not found - continue searching */ { break; } case 2: /* vacuous case: last key in the leaf */ { rtree_delete_key(info, page_buf, k, key_length, nod_flag); if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; *page_size = mi_getint(page_buf); res = 0; goto ok; } default: /* error */ case -1: { goto err1; } } } } else { /* leaf */ if (!rtree_key_cmp(keyinfo->seg, key, k, key_length, MBR_EQUAL | MBR_DATA)) { rtree_delete_key(info, page_buf, k, key_length, nod_flag); *page_size = mi_getint(page_buf); if (*page_size == 2) { /* last key in the leaf */ res = 2; if (_mi_dispose(info, keyinfo, page, DFLT_INIT_HITS)) goto err1; } else { res = 0; if (_mi_write_keypage(info, keyinfo, page, DFLT_INIT_HITS, page_buf)) goto err1; } goto ok; } } } res = 1; ok: my_afree((byte*)page_buf); DBUG_RETURN(res); err1: my_afree((byte*)page_buf); DBUG_RETURN(-1); /* purecov: inspected */ } /* Delete key - interface function RETURN -1 Error 0 Deleted */ int rtree_delete(MI_INFO *info, uint keynr, uchar *key, uint key_length) { uint page_size; stPageList ReinsertList; my_off_t old_root; MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; DBUG_ENTER("rtree_delete"); if ((old_root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) { my_errno= HA_ERR_END_OF_FILE; DBUG_RETURN(-1); /* purecov: inspected */ } DBUG_PRINT("rtree", ("starting deletion at root page: %lu", (ulong) old_root)); ReinsertList.pages = NULL; ReinsertList.n_pages = 0; ReinsertList.m_pages = 0; switch (rtree_delete_req(info, keyinfo, key, key_length, old_root, &page_size, &ReinsertList, 0)) { case 2: /* empty */ { info->s->state.key_root[keynr] = HA_OFFSET_ERROR; DBUG_RETURN(0); } case 0: /* deleted */ { uint nod_flag; ulong i; for (i = 0; i < ReinsertList.n_pages; ++i) { uchar *page_buf; uchar *k; uchar *last; if (!(page_buf = (uchar*)my_alloca((uint)keyinfo->block_length))) { my_errno = HA_ERR_OUT_OF_MEM; goto err1; } if (!_mi_fetch_keypage(info, keyinfo, ReinsertList.pages[i].offs, DFLT_INIT_HITS, page_buf, 0)) goto err1; nod_flag = mi_test_if_nod(page_buf); DBUG_PRINT("rtree", ("reinserting keys from " "page: %lu level: %d nod_flag: %u", (ulong) ReinsertList.pages[i].offs, ReinsertList.pages[i].level, nod_flag)); k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); last = rt_PAGE_END(page_buf); for (; k < last; k = rt_PAGE_NEXT_KEY(k, key_length, nod_flag)) { int res; if ((res= rtree_insert_level(info, keynr, k, key_length, ReinsertList.pages[i].level)) == -1) { my_afree((byte*)page_buf); goto err1; } if (res) { ulong j; DBUG_PRINT("rtree", ("root has been split, adjust levels")); for (j= i; j < ReinsertList.n_pages; j++) { ReinsertList.pages[j].level++; DBUG_PRINT("rtree", ("keys from page: %lu now level: %d", (ulong) ReinsertList.pages[i].offs, ReinsertList.pages[i].level)); } } } my_afree((byte*)page_buf); if (_mi_dispose(info, keyinfo, ReinsertList.pages[i].offs, DFLT_INIT_HITS)) goto err1; } if (ReinsertList.pages) my_free((byte*) ReinsertList.pages, MYF(0)); /* check for redundant root (not leaf, 1 child) and eliminate */ if ((old_root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) goto err1; if (!_mi_fetch_keypage(info, keyinfo, old_root, DFLT_INIT_HITS, info->buff, 0)) goto err1; nod_flag = mi_test_if_nod(info->buff); page_size = mi_getint(info->buff); if (nod_flag && (page_size == 2 + key_length + nod_flag)) { my_off_t new_root = _mi_kpos(nod_flag, rt_PAGE_FIRST_KEY(info->buff, nod_flag)); if (_mi_dispose(info, keyinfo, old_root, DFLT_INIT_HITS)) goto err1; info->s->state.key_root[keynr] = new_root; } info->update= HA_STATE_DELETED; DBUG_RETURN(0); err1: DBUG_RETURN(-1); /* purecov: inspected */ } case 1: /* not found */ { my_errno = HA_ERR_KEY_NOT_FOUND; DBUG_RETURN(-1); /* purecov: inspected */ } default: case -1: /* error */ { DBUG_RETURN(-1); /* purecov: inspected */ } } } /* Estimate number of suitable keys in the tree RETURN estimated value */ ha_rows rtree_estimate(MI_INFO *info, uint keynr, uchar *key, uint key_length, uint flag) { MI_KEYDEF *keyinfo = info->s->keyinfo + keynr; my_off_t root; uint i = 0; uchar *k; uchar *last; uint nod_flag; uchar *page_buf; uint k_len; double area = 0; ha_rows res = 0; if (flag & MBR_DISJOINT) return info->state->records; if ((root = info->s->state.key_root[keynr]) == HA_OFFSET_ERROR) return HA_POS_ERROR; if (!(page_buf = (uchar*)my_alloca((uint)keyinfo->block_length))) return HA_POS_ERROR; if (!_mi_fetch_keypage(info, keyinfo, root, DFLT_INIT_HITS, page_buf, 0)) goto err1; nod_flag = mi_test_if_nod(page_buf); k_len = keyinfo->keylength - info->s->base.rec_reflength; k = rt_PAGE_FIRST_KEY(page_buf, nod_flag); last = rt_PAGE_END(page_buf); for (; k < last; k = rt_PAGE_NEXT_KEY(k, k_len, nod_flag), ++i) { if (nod_flag) { double k_area = rtree_rect_volume(keyinfo->seg, k, key_length); /* The following should be safe, even if we compare doubles */ if (k_area == 0) { if (flag & (MBR_CONTAIN | MBR_INTERSECT)) { area += 1; } else if (flag & (MBR_WITHIN | MBR_EQUAL)) { if (!rtree_key_cmp(keyinfo->seg, key, k, key_length, MBR_WITHIN)) area += 1; } else goto err1; } else { if (flag & (MBR_CONTAIN | MBR_INTERSECT)) { area += rtree_overlapping_area(keyinfo->seg, key, k, key_length) / k_area; } else if (flag & (MBR_WITHIN | MBR_EQUAL)) { if (!rtree_key_cmp(keyinfo->seg, key, k, key_length, MBR_WITHIN)) area += rtree_rect_volume(keyinfo->seg, key, key_length) / k_area; } else goto err1; } } else { if (!rtree_key_cmp(keyinfo->seg, key, k, key_length, flag)) ++res; } } if (nod_flag) { if (i) res = (ha_rows) (area / i * info->state->records); else res = HA_POS_ERROR; } my_afree((byte*)page_buf); return res; err1: my_afree((byte*)page_buf); return HA_POS_ERROR; } #endif /*HAVE_RTREE_KEYS*/