/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Copyright by the Board of Trustees of the University of Illinois. * * All rights reserved. * * * * This file is part of HDF5. The full HDF5 copyright notice, including * * terms governing use, modification, and redistribution, is contained in * * the files COPYING and Copyright.html. COPYING can be found at the root * * of the source code distribution tree; Copyright.html can be found at the * * root level of an installed copy of the electronic HDF5 document set and * * is linked from the top-level documents page. It can also be found at * * http://hdf.ncsa.uiuc.edu/HDF5/doc/Copyright.html. If you do not have * * access to either file, you may request a copy from hdfhelp@ncsa.uiuc.edu. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ /*------------------------------------------------------------------------- * * Created: H5B2.c * Jan 31 2005 * Quincey Koziol * * Purpose: Implements a B-tree, with several modifications from * the "standard" methods. * * Please see the documentation in: * doc/html/TechNotes/Btrees.html for a full description * of how they work, etc. * *------------------------------------------------------------------------- */ #define H5B2_PACKAGE /*suppress error about including H5B2pkg */ /* Private headers */ #include "H5private.h" /* Generic Functions */ #include "H5B2pkg.h" /* B-trees */ #include "H5Eprivate.h" /* Error handling */ #include "H5MFprivate.h" /* File memory management */ /* Local macros */ /* Format overhead for each node (on disk) */ #define H5B2_OVERHEAD_SIZE (H5B2_SIZEOF_MAGIC+1) /* Signature + version # */ /* Number of records that fit into internal node */ #define H5B2_NUM_INT_REC(f,n,r) (((n)-(H5B2_OVERHEAD_SIZE+H5B2_NODE_POINTER_SIZE(f)))/((r)+H5B2_NODE_POINTER_SIZE(f))) /* Number of records that fit into leaf node */ #define H5B2_NUM_LEAF_REC(n,r) (((n)-H5B2_OVERHEAD_SIZE)/(r)) /* Uncomment this macro to enable extra sanity checking */ /* #define H5B2_DEBUG */ /* Local typedefs */ /* Local prototypes */ /* Helper functions */ static herr_t H5B2_create_leaf(H5F_t *f, hid_t dxpl_id, H5RC_t *bt2_shared, H5B2_node_ptr_t *node_ptr); static herr_t H5B2_create_internal(H5F_t *f, hid_t dxpl_id, H5RC_t *bt2_shared, H5B2_node_ptr_t *node_ptr); static int H5B2_locate_record(const H5B2_class_t *type, unsigned nrec, size_t *rec_off, const uint8_t *native, const void *udata, unsigned *idx); static herr_t H5B2_split_root(H5F_t *f, hid_t dxpl_id, H5B2_t *bt2, H5RC_t *bt2_shared); static herr_t H5B2_redistribute2(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_internal_t *internal, unsigned idx); static herr_t H5B2_split2(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_node_ptr_t *curr_node_ptr, H5AC_info_t *parent_cache_info, H5B2_internal_t *internal, unsigned idx); static herr_t H5B2_redistribute3(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_internal_t *internal, unsigned idx); static herr_t H5B2_iterate_node(H5F_t *f, hid_t dxpl_id, H5RC_t *bt2_shared, unsigned depth, const H5B2_node_ptr_t *curr_node, H5B2_operator_t op, void *op_data); #ifdef H5B2_DEBUG static herr_t H5B2_assert_leaf(H5B2_shared_t *shared, H5B2_leaf_t *leaf); static herr_t H5B2_assert_leaf2(H5B2_shared_t *shared, H5B2_leaf_t *leaf, H5B2_leaf_t *leaf2); static herr_t H5B2_assert_internal(hsize_t parent_all_nrec, H5B2_shared_t *shared, H5B2_internal_t *internal); static herr_t H5B2_assert_internal2(hsize_t parent_all_nrec, H5B2_shared_t *shared, H5B2_internal_t *internal, H5B2_internal_t *internal2); #endif /* H5B2_DEBUG */ /* Package variables */ /* Declare a free list to manage the H5B2_t struct */ H5FL_DEFINE(H5B2_t); /* Declare a free list to manage the H5B2_internal_t struct */ H5FL_DEFINE(H5B2_internal_t); /* Declare a free list to manage the H5B2_leaf_t struct */ H5FL_DEFINE(H5B2_leaf_t); /* Static variables */ /* Declare a free list to manage B-tree node pages to/from disk */ H5FL_BLK_DEFINE_STATIC(node_page); /* Declare a free list to manage the 'size_t' sequence information */ H5FL_SEQ_DEFINE_STATIC(size_t); /* Declare a free list to manage the H5B2_shared_t struct */ H5FL_DEFINE_STATIC(H5B2_shared_t); /*------------------------------------------------------------------------- * Function: H5B2_shared_init * * Purpose: Allocate & initialize shared B-tree info * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 2 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_shared_init (H5F_t *f, H5B2_t *bt2, const H5B2_class_t *type, size_t node_size, size_t rrec_size, unsigned split_percent, unsigned merge_percent) { H5B2_shared_t *shared = NULL; /* Shared B-tree information */ unsigned u; /* Local index variable */ herr_t ret_value=SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT(H5B2_shared_init) /* Allocate space for the shared information */ if(NULL==(shared = H5FL_CALLOC(H5B2_shared_t))) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree shared information") /* Assign user's information */ shared->split_percent = split_percent; shared->merge_percent = merge_percent; shared->node_size = node_size; shared->rrec_size = rrec_size; /* Compute derived information */ shared->internal_nrec = H5B2_NUM_INT_REC(f,shared->node_size,shared->rrec_size); shared->split_int_nrec = (shared->internal_nrec * shared->split_percent)/100; shared->merge_int_nrec = (shared->internal_nrec * shared->merge_percent)/100; shared->leaf_nrec = H5B2_NUM_LEAF_REC(shared->node_size,shared->rrec_size); shared->split_leaf_nrec = (shared->leaf_nrec * shared->split_percent)/100; shared->merge_leaf_nrec = (shared->leaf_nrec * shared->merge_percent)/100; /* Assign common type information */ shared->type = type; /* Allocate "page" for node I/O */ if((shared->page=H5FL_BLK_MALLOC(node_page,shared->node_size))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); #ifdef H5_USING_PURIFY HDmemset(shared->page,0,shared->node_size); #endif /* H5_USING_PURIFY */ /* Create factory for internal node native record storage */ if((shared->int_fac=H5FL_fac_init(type->nrec_size*shared->internal_nrec))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_CANTINIT, FAIL, "can't create internal node native key block factory") /* Create factory for leaf node native record storage */ if((shared->leaf_fac=H5FL_fac_init(type->nrec_size*shared->leaf_nrec))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_CANTINIT, FAIL, "can't create leaf node native key block factory") /* Create factory for internal node node pointer storage */ if((shared->node_ptr_fac=H5FL_fac_init(sizeof(H5B2_node_ptr_t)*(shared->internal_nrec+1)))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_CANTINIT, FAIL, "can't create internal node node pointer block factory") /* Allocate array of pointers to internal node native keys */ if((shared->nat_off=H5FL_SEQ_MALLOC(size_t,MAX(shared->internal_nrec,shared->leaf_nrec)))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed"); /* Initialize offsets in native key block */ for(u=0; uinternal_nrec,shared->leaf_nrec); u++) shared->nat_off[u]=type->nrec_size*u; /* Make shared B-tree info reference counted */ if(NULL==(bt2->shared=H5RC_create(shared,H5B2_shared_free))) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't create ref-count wrapper for shared B-tree info") done: if(ret_value<0) if(shared) H5B2_shared_free(shared); FUNC_LEAVE_NOAPI(ret_value) } /* end H5B2_shared_init() */ /*------------------------------------------------------------------------- * Function: H5B2_shared_free * * Purpose: Free shared B-tree info * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 2 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_shared_free (void *_shared) { H5B2_shared_t *shared = (H5B2_shared_t *)_shared; herr_t ret_value=SUCCEED; FUNC_ENTER_NOAPI_NOINIT(H5B2_shared_free) /* Sanity check */ HDassert(shared); /* Free the B-tree node buffer */ if(shared->page) H5FL_BLK_FREE(node_page,shared->page); /* Destroy factory for internal node native record storage */ if(shared->int_fac) if(H5FL_fac_term(shared->int_fac)<0) HGOTO_ERROR (H5E_RESOURCE, H5E_CANTRELEASE, FAIL, "can't destroy internal node native key block factory") /* Destroy factory for leaf node native record storage */ if(shared->leaf_fac) if(H5FL_fac_term(shared->leaf_fac)<0) HGOTO_ERROR (H5E_RESOURCE, H5E_CANTRELEASE, FAIL, "can't destroy leaf node native key block factory") /* Destroy factory for internal node node pointer storage */ if(shared->node_ptr_fac) if(H5FL_fac_term(shared->node_ptr_fac)<0) HGOTO_ERROR (H5E_RESOURCE, H5E_CANTRELEASE, FAIL, "can't destroy internal node node pointer block factory") /* Free the array of offsets into the native key block */ if(shared->nat_off) H5FL_SEQ_FREE(size_t,shared->nat_off); /* Free the shared B-tree info itself */ H5FL_FREE(H5B2_shared_t,shared); done: FUNC_LEAVE_NOAPI(ret_value) } /* end H5B2_shared_free() */ /*------------------------------------------------------------------------- * Function: H5B2_create * * Purpose: Creates a new empty B-tree in the file. * * Return: Success: Pointer to a new B-tree. * * Failure: NULL * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Jan 31 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_create(H5F_t *f, hid_t dxpl_id, const H5B2_class_t *type, size_t node_size, size_t rrec_size, unsigned split_percent, unsigned merge_percent, haddr_t *addr_p) { H5B2_t *bt2 = NULL; /* The new B-tree header information */ herr_t ret_value=SUCCEED; FUNC_ENTER_NOAPI(H5B2_create, FAIL) /* * Check arguments. */ HDassert(f); HDassert(type); HDassert(node_size>0); HDassert(rrec_size>0); HDassert(merge_percent>0 && merge_percent<=100); HDassert(split_percent>0 && split_percent<=100); HDassert(merge_percent<(split_percent/2)); /* * Allocate file and memory data structures. */ if (NULL==(bt2 = H5FL_MALLOC(H5B2_t))) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree header") /* Assign internal information */ HDmemset(&bt2->cache_info,0,sizeof(H5AC_info_t)); bt2->cache_info.is_dirty = TRUE; bt2->depth = 0; bt2->root.addr = HADDR_UNDEF; bt2->root.node_nrec = bt2->root.all_nrec = 0; /* Initialize shared B-tree info */ if(H5B2_shared_init(f, bt2, type, node_size, rrec_size, split_percent, merge_percent)<0) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't create shared B-tree info") /* Allocate space for the header on disk */ if (HADDR_UNDEF==(*addr_p=H5MF_alloc(f, H5FD_MEM_BTREE, dxpl_id, (hsize_t)H5B2_HEADER_SIZE(f)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "file allocation failed for B-tree header") /* Cache the new B-tree node */ if (H5AC_set(f, dxpl_id, H5AC_BT2_HDR, *addr_p, bt2, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "can't add B-tree header to cache") done: if (ret_value<0) { if (bt2) (void)H5B2_cache_hdr_dest(f,bt2); } /* end if */ FUNC_LEAVE_NOAPI(ret_value) } /* end H5B2_create() */ /*------------------------------------------------------------------------- * Function: H5B2_locate_record * * Purpose: Performs a binary search to locate a record in a sorted * array of records. * * Sets *IDX to location of record greater than or equal to * record to locate. * * Return: Comparison value for insertion location. Negative for record * to locate being less than value in *IDX. Zero for record to * locate equal to value in *IDX. Positive for record to locate * being greater than value in *IDX (which should only happen when * record to locate is greater than all records to search). * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 3 2005 * *------------------------------------------------------------------------- */ static int H5B2_locate_record(const H5B2_class_t *type, unsigned nrec, size_t *rec_off, const uint8_t *native, const void *udata, unsigned *idx) { unsigned lo = 0, hi; /* Low & high index values */ unsigned my_idx = 0; /* Final index value */ int cmp = -1; /* Key comparison value */ FUNC_ENTER_NOAPI_NOINIT_NOFUNC(H5B2_locate_record) hi = nrec; while (lo < hi && cmp) { my_idx = (lo + hi) / 2; if ((cmp = (type->compare)(udata, native+rec_off[my_idx])) < 0) hi = my_idx; else lo = my_idx + 1; } *idx = my_idx; FUNC_LEAVE_NOAPI(cmp); } /* end H5B2_locate_record */ /*------------------------------------------------------------------------- * Function: H5B2_split_root * * Purpose: Split the root node * * Return: Success: Non-negative * * Failure: Negative * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 3 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_split_root(H5F_t *f, hid_t dxpl_id, H5B2_t *bt2, H5RC_t *bt2_shared) { const H5AC_class_t *child_class; /* Pointer to child node's class info */ H5B2_internal_t *new_root; /* Pointer to new root node */ haddr_t left_addr, right_addr; /* Addresses of left & right child nodes */ void *left_child, *right_child; /* Pointers to child nodes */ unsigned *left_nrec, *right_nrec; /* Pointers to child # of records */ uint8_t *left_native, *right_native;/* Pointers to childs' native records */ H5B2_node_ptr_t *left_node_ptrs=NULL, *right_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_shared_t *shared; /* B-tree's shared info */ unsigned mid_record; /* Index of "middle" record in current node */ unsigned old_root_nrec; /* Number of records in root node */ herr_t ret_value=SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT(H5B2_split_root) HDassert(f); HDassert(bt2); HDassert(bt2_shared); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(bt2_shared); HDassert(shared); if(bt2->depth>0) { H5B2_internal_t *old_int=NULL, *new_int=NULL; /* Pointers to old & new internal nodes */ H5B2_node_ptr_t new_int_ptr; /* Node pointer to manage new internal node */ /* Create new internal node */ new_int_ptr.all_nrec=new_int_ptr.node_nrec=0; if(H5B2_create_internal(f, dxpl_id, bt2_shared, &new_int_ptr)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new internal node") /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_INT; left_addr = bt2->root.addr; right_addr = new_int_ptr.addr; /* Protect both leafs */ if (NULL == (old_int = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, left_addr, &(bt2->root.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") if (NULL == (new_int = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, right_addr, &(new_int_ptr.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* More setup for child nodes */ left_child = old_int; right_child = new_int; left_nrec = &(old_int->nrec); right_nrec = &(new_int->nrec); left_native = old_int->int_native; right_native = new_int->int_native; left_node_ptrs = old_int->node_ptrs; right_node_ptrs = new_int->node_ptrs; /* Mark child nodes as dirty now */ old_int->cache_info.is_dirty = TRUE; new_int->cache_info.is_dirty = TRUE; } /* end if */ else { H5B2_leaf_t *old_leaf=NULL, *new_leaf=NULL; /* Pointers to old & new leaf nodes */ H5B2_node_ptr_t new_leaf_ptr; /* Node pointer to manage new leaf node */ /* Create new leaf node */ new_leaf_ptr.all_nrec=new_leaf_ptr.node_nrec=0; if(H5B2_create_leaf(f, dxpl_id, bt2_shared, &new_leaf_ptr)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new leaf node") /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_LEAF; left_addr = bt2->root.addr; right_addr = new_leaf_ptr.addr; /* Protect both leafs */ if (NULL == (old_leaf = H5AC_protect(f, dxpl_id, H5AC_BT2_LEAF, left_addr, &(bt2->root.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (new_leaf = H5AC_protect(f, dxpl_id, H5AC_BT2_LEAF, right_addr, &(new_leaf_ptr.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* More setup for child nodes */ left_child = old_leaf; right_child = new_leaf; left_nrec = &(old_leaf->nrec); right_nrec = &(new_leaf->nrec); left_native = old_leaf->leaf_native; right_native = new_leaf->leaf_native; /* Mark child nodes as dirty now */ old_leaf->cache_info.is_dirty = TRUE; new_leaf->cache_info.is_dirty = TRUE; } /* end if */ /* Set the old number of records in root node */ old_root_nrec = bt2->root.node_nrec; /* Determine "middle" record to promote to new root */ mid_record = old_root_nrec/2; /* Copy "upper half" of records to new child */ HDmemcpy(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(left_native,shared,mid_record+1),shared->type->nrec_size*(old_root_nrec-(mid_record+1))); /* Copy "upper half" of format root's node pointers, if the children of the root are internal nodes */ if(bt2->depth>0) HDmemcpy(&(right_node_ptrs[0]),&(left_node_ptrs[mid_record+1]),sizeof(H5B2_node_ptr_t)*(old_root_nrec-mid_record)); /* Create new internal node to use as root */ if(H5B2_create_internal(f, dxpl_id, bt2_shared, &(bt2->root))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new internal node") /* Protect new internal node */ if (NULL == (new_root = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, bt2->root.addr, &(bt2->root.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Copy "middle" record to new internal node */ HDmemcpy(H5B2_INT_NREC(new_root,shared,0),H5B2_NAT_NREC(left_native,shared,mid_record),shared->type->nrec_size); /* Set internal node pointers to child nodes */ new_root->node_ptrs[0].addr = left_addr; new_root->node_ptrs[1].addr = right_addr; /* Update record counts in child nodes */ new_root->node_ptrs[0].node_nrec = *left_nrec = mid_record; new_root->node_ptrs[1].node_nrec = *right_nrec = old_root_nrec-(mid_record+1); /* Determine total number of records in new child nodes */ if(bt2->depth>0) { unsigned u; /* Local index variable */ unsigned new_left_all_nrec; /* New total number of records in left child */ unsigned new_right_all_nrec; /* New total number of records in right child */ /* Compute total of all records in each child node */ new_left_all_nrec = new_root->node_ptrs[0].node_nrec; for(u=0; u<(*left_nrec+1); u++) new_left_all_nrec += left_node_ptrs[u].all_nrec; new_right_all_nrec = new_root->node_ptrs[1].node_nrec; for(u=0; u<(*right_nrec+1); u++) new_right_all_nrec += right_node_ptrs[u].all_nrec; new_root->node_ptrs[0].all_nrec = new_left_all_nrec; new_root->node_ptrs[1].all_nrec = new_right_all_nrec; } /* end if */ else { new_root->node_ptrs[0].all_nrec = new_root->node_ptrs[0].node_nrec; new_root->node_ptrs[1].all_nrec = new_root->node_ptrs[1].node_nrec; } /* end else */ /* Update record count in new internal node */ new_root->nrec = 1; /* Mark new internal node as dirty */ new_root->cache_info.is_dirty = TRUE; #ifdef H5B2_DEBUG H5B2_assert_internal(bt2->root.all_nrec,shared,new_root); if(bt2->depth>0) { H5B2_assert_internal2(new_root->node_ptrs[0].all_nrec,shared,left_child,right_child); H5B2_assert_internal2(new_root->node_ptrs[1].all_nrec,shared,right_child,left_child); } /* end if */ else { H5B2_assert_leaf2(shared,left_child,right_child); H5B2_assert_leaf(shared,right_child); } /* end else */ #endif /* H5B2_DEBUG */ /* Release new internal node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, bt2->root.addr, new_root, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree internal node") /* Release child nodes */ if (H5AC_unprotect(f, dxpl_id, child_class, left_addr, left_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree leaf node") if (H5AC_unprotect(f, dxpl_id, child_class, right_addr, right_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree leaf node") /* Update depth of B-tree */ bt2->depth++; /* Update pointer to B-tree's root node to pointer to new internal node */ bt2->root.node_nrec = 1; /* Mark B-tree header as dirty */ bt2->cache_info.is_dirty = TRUE; done: FUNC_LEAVE_NOAPI(ret_value); } /* end H5B2_split_root */ /*------------------------------------------------------------------------- * Function: H5B2_redistribute2 * * Purpose: Redistribute records between two nodes * * Return: Success: Non-negative * * Failure: Negative * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 9 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_redistribute2(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_internal_t *internal, unsigned idx) { const H5AC_class_t *child_class; /* Pointer to child node's class info */ haddr_t left_addr, right_addr; /* Addresses of left & right child nodes */ void *left_child, *right_child; /* Pointers to child nodes */ unsigned *left_nrec, *right_nrec; /* Pointers to child # of records */ uint8_t *left_native, *right_native; /* Pointers to childs' native records */ H5B2_node_ptr_t *left_node_ptrs=NULL, *right_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_shared_t *shared; /* B-tree's shared info */ hssize_t left_moved_nrec=0, right_moved_nrec=0; /* Number of records moved, for internal redistrib */ herr_t ret_value=SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT(H5B2_redistribute2) HDassert(f); HDassert(internal); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(internal->shared); HDassert(shared); /* Check for the kind of B-tree node to redistribute */ if(depth>1) { H5B2_internal_t *left_internal; /* Pointer to left internal node */ H5B2_internal_t *right_internal; /* Pointer to right internal node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_INT; left_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+1].addr; /* Lock left & right B-tree child nodes */ if (NULL == (left_internal = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (right_internal = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* More setup for child nodes */ left_child = left_internal; right_child = right_internal; left_nrec = &(left_internal->nrec); right_nrec = &(right_internal->nrec); left_native = left_internal->int_native; right_native = right_internal->int_native; left_node_ptrs = left_internal->node_ptrs; right_node_ptrs = right_internal->node_ptrs; /* Mark child nodes as dirty now */ left_internal->cache_info.is_dirty = TRUE; right_internal->cache_info.is_dirty = TRUE; } /* end if */ else { H5B2_leaf_t *left_leaf; /* Pointer to left leaf node */ H5B2_leaf_t *right_leaf; /* Pointer to right leaf node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_LEAF; left_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+1].addr; /* Lock left & right B-tree child nodes */ if (NULL == (left_leaf = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (right_leaf = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* More setup for child nodes */ left_child = left_leaf; right_child = right_leaf; left_nrec = &(left_leaf->nrec); right_nrec = &(right_leaf->nrec); left_native = left_leaf->leaf_native; right_native = right_leaf->leaf_native; /* Mark child nodes as dirty now */ left_leaf->cache_info.is_dirty = TRUE; right_leaf->cache_info.is_dirty = TRUE; } /* end else */ #ifdef H5B2_DEBUG H5B2_assert_internal((hsize_t)0,shared,internal); if(depth>1) { H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,left_child,right_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,right_child,left_child); } /* end if */ else { H5B2_assert_leaf2(shared,left_child,right_child); H5B2_assert_leaf(shared,right_child); } /* end else */ #endif /* H5B2_DEBUG */ /* Determine whether to shuffle records left or right */ if(*left_nrec<*right_nrec) { /* Moving record from right node to left */ unsigned new_right_nrec = (*left_nrec+*right_nrec)/2; /* New number of records for right child */ unsigned move_nrec = *right_nrec - new_right_nrec; /* Number of records to move from right node to left */ /* Copy record from parent node down into left child */ HDmemcpy(H5B2_NAT_NREC(left_native,shared,*left_nrec),H5B2_INT_NREC(internal,shared,idx),shared->type->nrec_size); /* See if we need to move records from right node */ if(move_nrec>1) HDmemcpy(H5B2_NAT_NREC(left_native,shared,(*left_nrec+1)),H5B2_NAT_NREC(right_native,shared,0),shared->type->nrec_size*(move_nrec-1)); /* Move record from right node into parent node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx),H5B2_NAT_NREC(right_native,shared,(move_nrec-1)),shared->type->nrec_size); /* Slide records in right node down */ HDmemmove(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(right_native,shared,move_nrec),shared->type->nrec_size*new_right_nrec); /* Handle node pointers, if we have an internal node */ if(depth>1) { hsize_t moved_nrec=move_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Count the number of records being moved */ for(u=0; utype->nrec_size*(*right_nrec)); /* Copy record from parent node down into right child */ HDmemcpy(H5B2_NAT_NREC(right_native,shared,(move_nrec-1)),H5B2_INT_NREC(internal,shared,idx),shared->type->nrec_size); /* See if we need to move records from left node */ if(move_nrec>1) HDmemcpy(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(left_native,shared,((*left_nrec-move_nrec)+1)),shared->type->nrec_size*(move_nrec-1)); /* Move record from left node into parent node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx),H5B2_NAT_NREC(left_native,shared,(*left_nrec-move_nrec)),shared->type->nrec_size); /* Handle node pointers, if we have an internal node */ if(depth>1) { hsize_t moved_nrec=move_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Slide node pointers in right node up */ HDmemmove(&(right_node_ptrs[move_nrec]),&(right_node_ptrs[0]),sizeof(H5B2_node_ptr_t)*(*right_nrec+1)); /* Copy node pointers from left node to right */ HDmemcpy(&(right_node_ptrs[0]),&(left_node_ptrs[new_left_nrec+1]),sizeof(H5B2_node_ptr_t)*move_nrec); /* Count the number of records being moved */ for(u=0; unode_ptrs[idx].node_nrec = *left_nrec; internal->node_ptrs[idx+1].node_nrec = *right_nrec; /* Update total # of records in child B-trees */ if(depth>1) { internal->node_ptrs[idx].all_nrec += left_moved_nrec; internal->node_ptrs[idx+1].all_nrec += right_moved_nrec; } /* end if */ else { internal->node_ptrs[idx].all_nrec = internal->node_ptrs[idx].node_nrec; internal->node_ptrs[idx+1].all_nrec = internal->node_ptrs[idx+1].node_nrec; } /* end else */ #ifdef H5B2_DEBUG H5B2_assert_internal((hsize_t)0,shared,internal); if(depth>1) { H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,left_child,right_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,right_child,left_child); } /* end if */ else { H5B2_assert_leaf2(shared,left_child,right_child); H5B2_assert_leaf(shared,right_child); } /* end else */ #endif /* H5B2_DEBUG */ /* Unlock child nodes */ if (H5AC_unprotect(f, dxpl_id, child_class, left_addr, left_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, right_addr, right_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") done: FUNC_LEAVE_NOAPI(ret_value); } /* end H5B2_redistribute2 */ /*------------------------------------------------------------------------- * Function: H5B2_split2 * * Purpose: Perform a 2->3 node split * * Return: Success: Non-negative * * Failure: Negative * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 9 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_split2(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_node_ptr_t *curr_node_ptr, H5AC_info_t *parent_cache_info, H5B2_internal_t *internal, unsigned idx) { const H5AC_class_t *child_class; /* Pointer to child node's class info */ haddr_t left_addr, right_addr; /* Addresses of left & right child nodes */ haddr_t middle_addr; /* Address of middle child node */ void *left_child, *right_child; /* Pointers to left & right child nodes */ void *middle_child; /* Pointer to middle child node */ unsigned *left_nrec, *right_nrec; /* Pointers to left & right child # of records */ unsigned *middle_nrec; /* Pointer to middle child # of records */ uint8_t *left_native, *right_native; /* Pointers to left & right children's native records */ uint8_t *middle_native; /* Pointer to middle child's native records */ H5B2_node_ptr_t *left_node_ptrs=NULL, *right_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_node_ptr_t *middle_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_shared_t *shared; /* B-tree's shared info */ hssize_t left_moved_nrec=0, right_moved_nrec=0; /* Number of records moved, for internal split */ hsize_t middle_moved_nrec=0; /* Number of records moved, for internal split */ herr_t ret_value=SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT(H5B2_split2) HDassert(f); HDassert(internal); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(internal->shared); HDassert(shared); /* Slide records in parent node up one space, to make room for promoted record */ HDmemmove(H5B2_INT_NREC(internal,shared,idx+2),H5B2_INT_NREC(internal,shared,idx+1),shared->type->nrec_size*(internal->nrec-(idx+1))); HDmemmove(&(internal->node_ptrs[idx+2]),&(internal->node_ptrs[idx+1]),sizeof(H5B2_node_ptr_t)*(internal->nrec-idx)); /* Check for the kind of B-tree node to split */ if(depth>1) { H5B2_internal_t *left_internal; /* Pointer to left internal node */ H5B2_internal_t *middle_internal; /* Pointer to middle internal node */ H5B2_internal_t *right_internal; /* Pointer to right internal node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_INT; left_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+2].addr; /* Lock left & right B-tree child nodes */ if (NULL == (left_internal = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") if (NULL == (right_internal = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+2].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Create new empty "middle" internal node */ internal->node_ptrs[idx+1].all_nrec=internal->node_ptrs[idx+1].node_nrec=0; if(H5B2_create_internal(f, dxpl_id, internal->shared, &(internal->node_ptrs[idx+1]))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new internal node") /* Setup information for unlocking middle child node */ middle_addr = internal->node_ptrs[idx+1].addr; /* Lock "middle" internal node */ if (NULL == (middle_internal = H5AC_protect(f, dxpl_id, child_class, middle_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* More setup for accessing child node information */ left_child = left_internal; middle_child = middle_internal; right_child = right_internal; left_nrec = &(left_internal->nrec); middle_nrec = &(middle_internal->nrec); right_nrec = &(right_internal->nrec); left_native = left_internal->int_native; middle_native = middle_internal->int_native; right_native = right_internal->int_native; left_node_ptrs = left_internal->node_ptrs; middle_node_ptrs = middle_internal->node_ptrs; right_node_ptrs = right_internal->node_ptrs; /* Mark child nodes as dirty now */ left_internal->cache_info.is_dirty = TRUE; middle_internal->cache_info.is_dirty = TRUE; right_internal->cache_info.is_dirty = TRUE; } /* end if */ else { H5B2_leaf_t *left_leaf; /* Pointer to left leaf node */ H5B2_leaf_t *middle_leaf; /* Pointer to middle leaf node */ H5B2_leaf_t *right_leaf; /* Pointer to right leaf node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_LEAF; left_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+2].addr; /* Lock left & right B-tree child nodes */ if (NULL == (left_leaf = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (right_leaf = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+2].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* Create new empty "middle" leaf node */ internal->node_ptrs[idx+1].all_nrec=internal->node_ptrs[idx+1].node_nrec=0; if(H5B2_create_leaf(f, dxpl_id, internal->shared, &(internal->node_ptrs[idx+1]))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new leaf node") /* Setup information for unlocking middle child node */ middle_addr = internal->node_ptrs[idx+1].addr; /* Lock "middle" leaf node */ if (NULL == (middle_leaf = H5AC_protect(f, dxpl_id, child_class, middle_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* More setup for accessing child node information */ left_child = left_leaf; middle_child = middle_leaf; right_child = right_leaf; left_nrec = &(left_leaf->nrec); middle_nrec = &(middle_leaf->nrec); right_nrec = &(right_leaf->nrec); left_native = left_leaf->leaf_native; middle_native = middle_leaf->leaf_native; right_native = right_leaf->leaf_native; /* Mark child nodes as dirty now */ left_leaf->cache_info.is_dirty = TRUE; middle_leaf->cache_info.is_dirty = TRUE; right_leaf->cache_info.is_dirty = TRUE; } /* end else */ /* Redistribute records */ { /* Compute new # of records in each node */ unsigned total_nrec = *left_nrec + *right_nrec + 1; unsigned new_middle_nrec = (total_nrec-2)/3; unsigned new_left_nrec = ((total_nrec-2)-new_middle_nrec)/2; unsigned new_right_nrec = (total_nrec-2)-(new_left_nrec+new_middle_nrec); /* Fill new middle node */ { unsigned curr_middle_idx=0; /* Copy record(s) from left node to proper location */ if(new_left_nrec<(*left_nrec-1)) { curr_middle_idx=*left_nrec-(new_left_nrec+1); HDmemcpy(H5B2_NAT_NREC(middle_native,shared,0),H5B2_NAT_NREC(left_native,shared,(new_left_nrec+1)),shared->type->nrec_size*curr_middle_idx); } /* end if */ /* Copy record from parent node to proper location */ HDmemcpy(H5B2_NAT_NREC(middle_native,shared,curr_middle_idx),H5B2_INT_NREC(internal,shared,idx),shared->type->nrec_size); curr_middle_idx++; /* Copy record(s) from right node to proper location */ if(new_right_nrec<(*right_nrec-1)) HDmemcpy(H5B2_NAT_NREC(middle_native,shared,curr_middle_idx),H5B2_NAT_NREC(right_native,shared,0),shared->type->nrec_size*(*right_nrec-(new_right_nrec+1))); /* Copy node pointers from left and right nodes into middle node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned move_nptrs; /* Number of node pointers to move */ unsigned u; /* Local index variable */ /* Start tracking the total number of records in middle node */ middle_moved_nrec = new_middle_nrec; /* Copy node pointers from left node */ move_nptrs = (*left_nrec-new_left_nrec); HDmemcpy(&(middle_node_ptrs[0]),&(left_node_ptrs[new_left_nrec+1]),sizeof(H5B2_node_ptr_t)*move_nptrs); /* Count the number of records being moved from the left node */ for(u=0, moved_nrec=0; utype->nrec_size); HDmemcpy(H5B2_INT_NREC(internal,shared,idx+1),H5B2_NAT_NREC(right_native,shared,(*right_nrec-(new_right_nrec+1))),shared->type->nrec_size); /* Update # of records in left node */ *left_nrec = new_left_nrec; /* Slide records in right node to proper position */ HDmemmove(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(right_native,shared,(*right_nrec-new_right_nrec)),shared->type->nrec_size*new_right_nrec); /* Update # of records in right node */ *right_nrec = new_right_nrec; } /* end block */ /* Update # of records in child nodes */ internal->node_ptrs[idx].node_nrec = *left_nrec; internal->node_ptrs[idx+1].node_nrec = *middle_nrec; internal->node_ptrs[idx+2].node_nrec = *right_nrec; /* Update total # of records in child B-trees */ if(depth>1) { internal->node_ptrs[idx].all_nrec += left_moved_nrec; internal->node_ptrs[idx+1].all_nrec = middle_moved_nrec; internal->node_ptrs[idx+2].all_nrec += right_moved_nrec; } /* end if */ else { internal->node_ptrs[idx].all_nrec = internal->node_ptrs[idx].node_nrec; internal->node_ptrs[idx+1].all_nrec = internal->node_ptrs[idx+1].node_nrec; internal->node_ptrs[idx+2].all_nrec = internal->node_ptrs[idx+2].node_nrec; } /* end else */ /* Update # of records in parent node */ internal->nrec++; /* Mark parent as dirty */ internal->cache_info.is_dirty = TRUE; /* Update grandparent info */ curr_node_ptr->node_nrec++; /* Mark grandparent as dirty */ parent_cache_info->is_dirty = TRUE; #ifdef H5B2_DEBUG H5B2_assert_internal((hsize_t)0,shared,internal); if(depth>1) { H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,left_child,middle_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,middle_child,left_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,middle_child,right_child); H5B2_assert_internal2(internal->node_ptrs[idx+2].all_nrec,shared,right_child,middle_child); } /* end if */ else { H5B2_assert_leaf2(shared,left_child,middle_child); H5B2_assert_leaf2(shared,middle_child,right_child); H5B2_assert_leaf(shared,right_child); } /* end else */ #endif /* H5B2_DEBUG */ /* Unlock child nodes */ if (H5AC_unprotect(f, dxpl_id, child_class, left_addr, left_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, middle_addr, middle_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, right_addr, right_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") done: FUNC_LEAVE_NOAPI(ret_value); } /* end H5B2_split2 */ /*------------------------------------------------------------------------- * Function: H5B2_redistribute3 * * Purpose: Redistribute records between three nodes * * Return: Success: Non-negative * * Failure: Negative * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 9 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_redistribute3(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_internal_t *internal, unsigned idx) { const H5AC_class_t *child_class; /* Pointer to child node's class info */ haddr_t left_addr, right_addr; /* Addresses of left & right child nodes */ haddr_t middle_addr; /* Address of middle child node */ void *left_child, *right_child; /* Pointers to child nodes */ void *middle_child; /* Pointers to middle child node */ unsigned *left_nrec, *right_nrec; /* Pointers to child # of records */ unsigned *middle_nrec; /* Pointers to middle child # of records */ uint8_t *left_native, *right_native; /* Pointers to childs' native records */ uint8_t *middle_native; /* Pointers to middle child's native records */ H5B2_shared_t *shared; /* B-tree's shared info */ H5B2_node_ptr_t *left_node_ptrs=NULL, *right_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_node_ptr_t *middle_node_ptrs=NULL;/* Pointers to childs' node pointer info */ hssize_t left_moved_nrec=0, right_moved_nrec=0; /* Number of records moved, for internal split */ hssize_t middle_moved_nrec=0; /* Number of records moved, for internal split */ herr_t ret_value=SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT(H5B2_redistribute3) HDassert(f); HDassert(internal); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(internal->shared); HDassert(shared); /* Check for the kind of B-tree node to redistribute */ if(depth>1) { H5B2_internal_t *left_internal; /* Pointer to left internal node */ H5B2_internal_t *middle_internal; /* Pointer to middle internal node */ H5B2_internal_t *right_internal; /* Pointer to right internal node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_INT; left_addr = internal->node_ptrs[idx-1].addr; middle_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+1].addr; /* Lock B-tree child nodes */ if (NULL == (left_internal = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx-1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") if (NULL == (middle_internal = H5AC_protect(f, dxpl_id, child_class, middle_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") if (NULL == (right_internal = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* More setup for child nodes */ left_child = left_internal; middle_child = middle_internal; right_child = right_internal; left_nrec = &(left_internal->nrec); middle_nrec = &(middle_internal->nrec); right_nrec = &(right_internal->nrec); left_native = left_internal->int_native; middle_native = middle_internal->int_native; right_native = right_internal->int_native; left_node_ptrs = left_internal->node_ptrs; middle_node_ptrs = middle_internal->node_ptrs; right_node_ptrs = right_internal->node_ptrs; /* Mark child nodes as dirty now */ left_internal->cache_info.is_dirty = TRUE; middle_internal->cache_info.is_dirty = TRUE; right_internal->cache_info.is_dirty = TRUE; } /* end if */ else { H5B2_leaf_t *left_leaf; /* Pointer to left leaf node */ H5B2_leaf_t *middle_leaf; /* Pointer to middle leaf node */ H5B2_leaf_t *right_leaf; /* Pointer to right leaf node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_LEAF; left_addr = internal->node_ptrs[idx-1].addr; middle_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+1].addr; /* Lock B-tree child nodes */ if (NULL == (left_leaf = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx-1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (middle_leaf = H5AC_protect(f, dxpl_id, child_class, middle_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (right_leaf = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* More setup for child nodes */ left_child = left_leaf; middle_child = middle_leaf; right_child = right_leaf; left_nrec = &(left_leaf->nrec); middle_nrec = &(middle_leaf->nrec); right_nrec = &(right_leaf->nrec); left_native = left_leaf->leaf_native; middle_native = middle_leaf->leaf_native; right_native = right_leaf->leaf_native; /* Mark child nodes as dirty now */ left_leaf->cache_info.is_dirty = TRUE; middle_leaf->cache_info.is_dirty = TRUE; right_leaf->cache_info.is_dirty = TRUE; } /* end else */ /* Redistribute records */ { /* Compute new # of records in each node */ unsigned total_nrec = *left_nrec + *middle_nrec + *right_nrec + 2; unsigned new_middle_nrec = (total_nrec-2)/3; unsigned new_left_nrec = ((total_nrec-2)-new_middle_nrec)/2; unsigned new_right_nrec = (total_nrec-2)-(new_left_nrec+new_middle_nrec); unsigned curr_middle_nrec = *middle_nrec; /* Move records into left node */ if(new_left_nrec>*left_nrec) { unsigned moved_middle_nrec=0; /* Number of records moved into left node */ /* Move left parent record down to left node */ HDmemcpy(H5B2_NAT_NREC(left_native,shared,*left_nrec),H5B2_INT_NREC(internal,shared,idx-1),shared->type->nrec_size); /* Move records from middle node into left node */ if((new_left_nrec-1)>*left_nrec) { moved_middle_nrec = new_left_nrec-(*left_nrec+1); HDmemcpy(H5B2_NAT_NREC(left_native,shared,*left_nrec+1),H5B2_NAT_NREC(middle_native,shared,0),shared->type->nrec_size*moved_middle_nrec); } /* end if */ /* Move record from middle node up to parent node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx-1),H5B2_NAT_NREC(middle_native,shared,moved_middle_nrec),shared->type->nrec_size); moved_middle_nrec++; /* Slide records in middle node down */ HDmemmove(H5B2_NAT_NREC(middle_native,shared,0),H5B2_NAT_NREC(middle_native,shared,moved_middle_nrec),shared->type->nrec_size*(*middle_nrec-moved_middle_nrec)); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned move_nptrs; /* Number of node pointers to move */ unsigned u; /* Local index variable */ /* Move middle node pointers into left node */ move_nptrs = new_left_nrec - *left_nrec; HDmemcpy(&(left_node_ptrs[*left_nrec+1]),&(middle_node_ptrs[0]),sizeof(H5B2_node_ptr_t)*move_nptrs); /* Count the number of records being moved into the left node */ for(u=0, moved_nrec=0; u*right_nrec) { unsigned right_nrec_move = new_right_nrec-*right_nrec; /* Number of records to move out of right node */ /* Slide records in right node up */ HDmemmove(H5B2_NAT_NREC(right_native,shared,right_nrec_move),H5B2_NAT_NREC(right_native,shared,0),shared->type->nrec_size*(*right_nrec)); /* Move right parent record down to right node */ HDmemcpy(H5B2_NAT_NREC(right_native,shared,right_nrec_move-1),H5B2_INT_NREC(internal,shared,idx),shared->type->nrec_size); /* Move records from middle node into right node */ if(right_nrec_move>1) HDmemcpy(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(middle_native,shared,((curr_middle_nrec-right_nrec_move)+1)),shared->type->nrec_size*(right_nrec_move-1)); /* Move record from middle node up to parent node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx),H5B2_NAT_NREC(middle_native,shared,(curr_middle_nrec-right_nrec_move)),shared->type->nrec_size); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Slide the node pointers in right node up */ HDmemmove(&(right_node_ptrs[right_nrec_move]),&(right_node_ptrs[0]),sizeof(H5B2_node_ptr_t)*(*right_nrec+1)); /* Move middle node pointers into right node */ HDmemcpy(&(right_node_ptrs[0]),&(middle_node_ptrs[(curr_middle_nrec-right_nrec_move)+1]),sizeof(H5B2_node_ptr_t)*right_nrec_move); /* Count the number of records being moved into the right node */ for(u=0, moved_nrec=0; u*right_nrec); /* Slide middle records up */ HDmemmove(H5B2_NAT_NREC(middle_native,shared,left_nrec_move),H5B2_NAT_NREC(middle_native,shared,0),shared->type->nrec_size*curr_middle_nrec); /* Move left parent record down to middle node */ HDmemcpy(H5B2_NAT_NREC(middle_native,shared,left_nrec_move-1),H5B2_INT_NREC(internal,shared,idx-1),shared->type->nrec_size); /* Move left records to middle node */ if(left_nrec_move>1) HDmemmove(H5B2_NAT_NREC(middle_native,shared,0),H5B2_NAT_NREC(left_native,shared,new_left_nrec+1),shared->type->nrec_size*(left_nrec_move-1)); /* Move left parent record up from left node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx-1),H5B2_NAT_NREC(left_native,shared,new_left_nrec),shared->type->nrec_size); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Slide the node pointers in middle node up */ HDmemmove(&(middle_node_ptrs[left_nrec_move]),&(middle_node_ptrs[0]),sizeof(H5B2_node_ptr_t)*(curr_middle_nrec+1)); /* Move left node pointers into middle node */ HDmemcpy(&(middle_node_ptrs[0]),&(left_node_ptrs[new_left_nrec+1]),sizeof(H5B2_node_ptr_t)*left_nrec_move); /* Count the number of records being moved into the left node */ for(u=0, moved_nrec=0; u*left_nrec); /* Move right parent record down to middle node */ HDmemcpy(H5B2_NAT_NREC(middle_native,shared,curr_middle_nrec),H5B2_INT_NREC(internal,shared,idx),shared->type->nrec_size); /* Move right records to middle node */ HDmemmove(H5B2_NAT_NREC(middle_native,shared,(curr_middle_nrec+1)),H5B2_NAT_NREC(right_native,shared,0),shared->type->nrec_size*(right_nrec_move-1)); /* Move right parent record up from right node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx),H5B2_NAT_NREC(right_native,shared,right_nrec_move-1),shared->type->nrec_size); /* Slide right records down */ HDmemmove(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(right_native,shared,right_nrec_move),shared->type->nrec_size*new_right_nrec); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Move right node pointers into middle node */ HDmemcpy(&(middle_node_ptrs[curr_middle_nrec+1]),&(right_node_ptrs[0]),sizeof(H5B2_node_ptr_t)*right_nrec_move); /* Count the number of records being moved into the right node */ for(u=0, moved_nrec=0; unode_ptrs[idx-1].node_nrec = *left_nrec; internal->node_ptrs[idx].node_nrec = *middle_nrec; internal->node_ptrs[idx+1].node_nrec = *right_nrec; /* Update total # of records in child B-trees */ if(depth>1) { internal->node_ptrs[idx-1].all_nrec += left_moved_nrec; internal->node_ptrs[idx].all_nrec += middle_moved_nrec; internal->node_ptrs[idx+1].all_nrec += right_moved_nrec; } /* end if */ else { internal->node_ptrs[idx-1].all_nrec = internal->node_ptrs[idx-1].node_nrec; internal->node_ptrs[idx].all_nrec = internal->node_ptrs[idx].node_nrec; internal->node_ptrs[idx+1].all_nrec = internal->node_ptrs[idx+1].node_nrec; } /* end else */ /* Mark parent as dirty */ internal->cache_info.is_dirty = TRUE; #ifdef QAK { unsigned u; HDfprintf(stderr,"%s: Internal records:\n",FUNC); for(u=0; unrec; u++) { HDfprintf(stderr,"%s: u=%u\n",FUNC,u); (shared->type->debug)(stderr,f,dxpl_id,3,4,H5B2_INT_NREC(internal,shared,u),NULL); } /* end for */ HDfprintf(stderr,"%s: Left Child records:\n",FUNC); for(u=0; u<*left_nrec; u++) { HDfprintf(stderr,"%s: u=%u\n",FUNC,u); (shared->type->debug)(stderr,f,dxpl_id,3,4,H5B2_NAT_NREC(left_native,shared,u),NULL); } /* end for */ HDfprintf(stderr,"%s: Middle Child records:\n",FUNC); for(u=0; u<*middle_nrec; u++) { HDfprintf(stderr,"%s: u=%u\n",FUNC,u); (shared->type->debug)(stderr,f,dxpl_id,3,4,H5B2_NAT_NREC(middle_native,shared,u),NULL); } /* end for */ HDfprintf(stderr,"%s: Right Child records:\n",FUNC); for(u=0; u<*right_nrec; u++) { HDfprintf(stderr,"%s: u=%u\n",FUNC,u); (shared->type->debug)(stderr,f,dxpl_id,3,4,H5B2_NAT_NREC(right_native,shared,u),NULL); } /* end for */ for(u=0; unrec+1; u++) HDfprintf(stderr,"%s: internal->node_ptrs[%u]=(%Hu/%u/%a)\n",FUNC,u,internal->node_ptrs[u].all_nrec,internal->node_ptrs[u].node_nrec,internal->node_ptrs[u].addr); if(depth>1) { for(u=0; u<*left_nrec+1; u++) HDfprintf(stderr,"%s: left_node_ptr[%u]=(%Hu/%u/%a)\n",FUNC,u,left_node_ptrs[u].all_nrec,left_node_ptrs[u].node_nrec,left_node_ptrs[u].addr); for(u=0; u<*middle_nrec+1; u++) HDfprintf(stderr,"%s: middle_node_ptr[%u]=(%Hu/%u/%a)\n",FUNC,u,middle_node_ptrs[u].all_nrec,middle_node_ptrs[u].node_nrec,middle_node_ptrs[u].addr); for(u=0; u<*right_nrec+1; u++) HDfprintf(stderr,"%s: right_node_ptr[%u]=(%Hu/%u/%a)\n",FUNC,u,right_node_ptrs[u].all_nrec,right_node_ptrs[u].node_nrec,right_node_ptrs[u].addr); } /* end if */ } #endif /* QAK */ #ifdef H5B2_DEBUG H5B2_assert_internal((hsize_t)0,shared,internal); if(depth>1) { H5B2_assert_internal2(internal->node_ptrs[idx-1].all_nrec,shared,left_child,middle_child); H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,middle_child,left_child); H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,middle_child,right_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,right_child,middle_child); } /* end if */ else { H5B2_assert_leaf2(shared,left_child,middle_child); H5B2_assert_leaf2(shared,middle_child,right_child); H5B2_assert_leaf(shared,right_child); } /* end else */ #endif /* H5B2_DEBUG */ /* Unlock child nodes */ if (H5AC_unprotect(f, dxpl_id, child_class, left_addr, left_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, middle_addr, middle_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, right_addr, right_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") done: FUNC_LEAVE_NOAPI(ret_value); } /* end H5B2_redistribute3 */ /*------------------------------------------------------------------------- * Function: H5B2_split3 * * Purpose: Perform a 3->4 node split * * Return: Success: Non-negative * * Failure: Negative * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 10 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_split3(H5F_t *f, hid_t dxpl_id, unsigned depth, H5B2_node_ptr_t *curr_node_ptr, H5AC_info_t *parent_cache_info, H5B2_internal_t *internal, unsigned idx) { const H5AC_class_t *child_class; /* Pointer to child node's class info */ haddr_t left_addr, right_addr; /* Addresses of left & right child nodes */ haddr_t middle_addr; /* Address of middle child node */ haddr_t new_addr; /* Address of new child node */ void *left_child, *right_child; /* Pointers to left & right child nodes */ void *middle_child; /* Pointer to middle child node */ void *new_child; /* Pointer to new child node */ unsigned *left_nrec, *right_nrec; /* Pointers to left & right child # of records */ unsigned *middle_nrec; /* Pointer to middle child # of records */ unsigned *new_nrec; /* Pointer to new child # of records */ uint8_t *left_native, *right_native; /* Pointers to left & right children's native records */ uint8_t *middle_native; /* Pointer to middle child's native records */ uint8_t *new_native; /* Pointer to new child's native records */ H5B2_shared_t *shared; /* B-tree's shared info */ H5B2_node_ptr_t *left_node_ptrs=NULL, *right_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_node_ptr_t *middle_node_ptrs=NULL;/* Pointers to childs' node pointer info */ H5B2_node_ptr_t *new_node_ptrs=NULL;/* Pointers to childs' node pointer info */ hssize_t left_moved_nrec=0, right_moved_nrec=0; /* Number of records moved, for internal split */ hssize_t middle_moved_nrec=0; /* Number of records moved, for internal split */ hsize_t new_moved_nrec=0; /* Number of records moved, for internal split */ herr_t ret_value=SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT(H5B2_split3) HDassert(f); HDassert(internal); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(internal->shared); HDassert(shared); /* Slide records in parent node up one space, to make room for promoted record */ HDmemmove(H5B2_INT_NREC(internal,shared,idx+2),H5B2_INT_NREC(internal,shared,idx+1),shared->type->nrec_size*(internal->nrec-(idx+1))); HDmemmove(&(internal->node_ptrs[idx+2]),&(internal->node_ptrs[idx+1]),sizeof(H5B2_node_ptr_t)*(internal->nrec-idx)); /* Check for the kind of B-tree node to split */ if(depth>1) { H5B2_internal_t *left_internal; /* Pointer to left internal node */ H5B2_internal_t *right_internal; /* Pointer to right internal node */ H5B2_internal_t *middle_internal; /* Pointer to middle internal node */ H5B2_internal_t *new_internal; /* Pointer to new internal node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_INT; left_addr = internal->node_ptrs[idx-1].addr; middle_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+2].addr; /* Lock left & right B-tree child nodes */ if (NULL == (left_internal = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx-1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") if (NULL == (middle_internal = H5AC_protect(f, dxpl_id, child_class, middle_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") if (NULL == (right_internal = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+2].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Create new empty internal node */ internal->node_ptrs[idx+1].all_nrec=internal->node_ptrs[idx+1].node_nrec=0; if(H5B2_create_internal(f, dxpl_id, internal->shared, &(internal->node_ptrs[idx+1]))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new internal node") /* Setup information for unlocking middle child node */ new_addr = internal->node_ptrs[idx+1].addr; /* Lock "new" internal node */ if (NULL == (new_internal = H5AC_protect(f, dxpl_id, child_class, new_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* More setup for accessing child node information */ left_child = left_internal; middle_child = middle_internal; new_child = new_internal; right_child = right_internal; left_nrec = &(left_internal->nrec); middle_nrec = &(middle_internal->nrec); new_nrec = &(new_internal->nrec); right_nrec = &(right_internal->nrec); left_native = left_internal->int_native; middle_native = middle_internal->int_native; new_native = new_internal->int_native; right_native = right_internal->int_native; left_node_ptrs = left_internal->node_ptrs; middle_node_ptrs = middle_internal->node_ptrs; right_node_ptrs = right_internal->node_ptrs; new_node_ptrs = new_internal->node_ptrs; /* Mark child nodes as dirty now */ left_internal->cache_info.is_dirty = TRUE; middle_internal->cache_info.is_dirty = TRUE; new_internal->cache_info.is_dirty = TRUE; right_internal->cache_info.is_dirty = TRUE; } /* end if */ else { H5B2_leaf_t *left_leaf; /* Pointer to left leaf node */ H5B2_leaf_t *right_leaf; /* Pointer to right leaf node */ H5B2_leaf_t *middle_leaf; /* Pointer to middle leaf node */ H5B2_leaf_t *new_leaf; /* Pointer to new leaf node */ /* Setup information for unlocking child nodes */ child_class = H5AC_BT2_LEAF; left_addr = internal->node_ptrs[idx-1].addr; middle_addr = internal->node_ptrs[idx].addr; right_addr = internal->node_ptrs[idx+2].addr; /* Lock left & right B-tree child nodes */ if (NULL == (left_leaf = H5AC_protect(f, dxpl_id, child_class, left_addr, &(internal->node_ptrs[idx-1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (middle_leaf = H5AC_protect(f, dxpl_id, child_class, middle_addr, &(internal->node_ptrs[idx].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") if (NULL == (right_leaf = H5AC_protect(f, dxpl_id, child_class, right_addr, &(internal->node_ptrs[idx+2].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* Create new empty leaf node */ internal->node_ptrs[idx+1].all_nrec=internal->node_ptrs[idx+1].node_nrec=0; if(H5B2_create_leaf(f, dxpl_id, internal->shared, &(internal->node_ptrs[idx+1]))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create new leaf node") /* Setup information for unlocking middle child node */ new_addr = internal->node_ptrs[idx+1].addr; /* Lock "new" leaf node */ if (NULL == (new_leaf = H5AC_protect(f, dxpl_id, child_class, new_addr, &(internal->node_ptrs[idx+1].node_nrec), internal->shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* More setup for accessing child node information */ left_child = left_leaf; middle_child = middle_leaf; new_child = new_leaf; right_child = right_leaf; left_nrec = &(left_leaf->nrec); middle_nrec = &(middle_leaf->nrec); new_nrec = &(new_leaf->nrec); right_nrec = &(right_leaf->nrec); left_native = left_leaf->leaf_native; middle_native = middle_leaf->leaf_native; new_native = new_leaf->leaf_native; right_native = right_leaf->leaf_native; /* Mark child nodes as dirty now */ left_leaf->cache_info.is_dirty = TRUE; middle_leaf->cache_info.is_dirty = TRUE; new_leaf->cache_info.is_dirty = TRUE; right_leaf->cache_info.is_dirty = TRUE; } /* end else */ /* Redistribute records */ { /* Compute new # of records in each node */ unsigned total_nrec = *left_nrec + *middle_nrec + *right_nrec + 2; unsigned new_new_nrec = (total_nrec-3)/4; unsigned new_middle_nrec = ((total_nrec-3)-new_new_nrec)/3; unsigned new_left_nrec = ((total_nrec-3)-(new_middle_nrec+new_new_nrec))/2; unsigned new_right_nrec = (total_nrec-3)-(new_left_nrec+new_middle_nrec+new_new_nrec); /* Partially fill new node from right node */ { unsigned right_nrec_move = *right_nrec-new_right_nrec; /* Move right record down from parent into new node */ HDmemcpy(H5B2_NAT_NREC(new_native,shared,(new_new_nrec-right_nrec_move)),H5B2_INT_NREC(internal,shared,idx),shared->type->nrec_size); /* Move records from right node to new node */ HDmemcpy(H5B2_NAT_NREC(new_native,shared,((new_new_nrec-right_nrec_move)+1)),H5B2_NAT_NREC(right_native,shared,0),shared->type->nrec_size*(right_nrec_move-1)); /* Move record from right node up to parent node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx+1),H5B2_NAT_NREC(right_native,shared,(right_nrec_move-1)),shared->type->nrec_size); /* Slide records in right node down */ HDmemmove(H5B2_NAT_NREC(right_native,shared,0),H5B2_NAT_NREC(right_native,shared,right_nrec_move),shared->type->nrec_size*new_right_nrec); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Move right node pointers into new node */ HDmemcpy(&(new_node_ptrs[(new_new_nrec-right_nrec_move)+1]),&(right_node_ptrs[0]),sizeof(H5B2_node_ptr_t)*right_nrec_move); /* Count the number of records being moved into the new node */ for(u=0, moved_nrec=0; utype->nrec_size*new_nrec_move); /* Move record from middle node up to parent node */ HDmemcpy(H5B2_INT_NREC(internal,shared,idx),H5B2_NAT_NREC(middle_native,shared,((*middle_nrec-new_nrec_move)-1)),shared->type->nrec_size); /* Slide records in middle node up */ HDmemmove(H5B2_NAT_NREC(middle_native,shared,(new_middle_nrec-((*middle_nrec-new_nrec_move)-1))),H5B2_NAT_NREC(middle_native,shared,0),shared->type->nrec_size*(*middle_nrec-(new_nrec_move+1))); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Move middle node pointers into new node */ HDmemcpy(&(new_node_ptrs[0]),&(middle_node_ptrs[(*middle_nrec-new_nrec_move)]),sizeof(H5B2_node_ptr_t)*(new_nrec_move+1)); /* Count the number of records being moved into the new node */ for(u=0, moved_nrec=0; utype->nrec_size); /* Move records from left node to middle node */ HDmemcpy(H5B2_NAT_NREC(middle_native,shared,0),H5B2_NAT_NREC(left_native,shared,(new_left_nrec+1)),shared->type->nrec_size*(left_nrec_move-1)); /* Move node pointers also if this is an internal node */ if(depth>1) { hsize_t moved_nrec; /* Total number of records moved, for internal redistrib */ unsigned u; /* Local index variable */ /* Move left node pointers into middle node */ HDmemcpy(&(middle_node_ptrs[0]),&(left_node_ptrs[new_left_nrec+1]),sizeof(H5B2_node_ptr_t)*left_nrec_move); /* Count the number of records being moved into the middle node */ for(u=0, moved_nrec=0; utype->nrec_size); /* Update # of records in nodes */ *left_nrec = new_left_nrec; *middle_nrec = new_middle_nrec; *new_nrec = new_new_nrec; *right_nrec = new_right_nrec; } /* end block */ /* Update # of records in child nodes */ internal->node_ptrs[idx-1].node_nrec = *left_nrec; internal->node_ptrs[idx].node_nrec = *middle_nrec; internal->node_ptrs[idx+1].node_nrec = *new_nrec; internal->node_ptrs[idx+2].node_nrec = *right_nrec; /* Update total # of records in child B-trees */ if(depth>1) { internal->node_ptrs[idx-1].all_nrec += left_moved_nrec; internal->node_ptrs[idx].all_nrec += middle_moved_nrec; internal->node_ptrs[idx+1].all_nrec = new_moved_nrec; internal->node_ptrs[idx+2].all_nrec += right_moved_nrec; } /* end if */ else { internal->node_ptrs[idx-1].all_nrec = internal->node_ptrs[idx-1].node_nrec; internal->node_ptrs[idx].all_nrec = internal->node_ptrs[idx].node_nrec; internal->node_ptrs[idx+1].all_nrec = internal->node_ptrs[idx+1].node_nrec; internal->node_ptrs[idx+2].all_nrec = internal->node_ptrs[idx+2].node_nrec; } /* end else */ /* Update # of records in parent node */ internal->nrec++; /* Mark parent as dirty */ internal->cache_info.is_dirty = TRUE; /* Update grandparent info */ curr_node_ptr->node_nrec++; /* Mark grandparent as dirty */ parent_cache_info->is_dirty = TRUE; #ifdef H5B2_DEBUG H5B2_assert_internal((hsize_t)0,shared,internal); if(depth>1) { H5B2_assert_internal2(internal->node_ptrs[idx-1].all_nrec,shared,left_child,middle_child); H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,middle_child,left_child); H5B2_assert_internal2(internal->node_ptrs[idx].all_nrec,shared,middle_child,new_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,new_child,middle_child); H5B2_assert_internal2(internal->node_ptrs[idx+1].all_nrec,shared,new_child,right_child); H5B2_assert_internal2(internal->node_ptrs[idx+2].all_nrec,shared,right_child,new_child); } /* end if */ else { H5B2_assert_leaf2(shared,left_child,middle_child); H5B2_assert_leaf2(shared,middle_child,new_child); H5B2_assert_leaf2(shared,new_child,right_child); H5B2_assert_leaf(shared,right_child); } /* end else */ #endif /* H5B2_DEBUG */ /* Unlock child nodes */ if (H5AC_unprotect(f, dxpl_id, child_class, left_addr, left_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, middle_addr, middle_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, new_addr, new_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") if (H5AC_unprotect(f, dxpl_id, child_class, right_addr, right_child, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree child node") done: FUNC_LEAVE_NOAPI(ret_value); } /* end H5B2_split3 */ /*------------------------------------------------------------------------- * Function: H5B2_insert * * Purpose: Adds a new record to the B-tree. If the root node of * the B-tree splits then the B-tree header tracks the new * root node created. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 2 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_insert(H5F_t *f, hid_t dxpl_id, const H5B2_class_t *type, haddr_t addr, void *udata) { H5B2_t *bt2=NULL; /* Pointer to the B-tree header */ H5RC_t *bt2_shared=NULL; /* Pointer to ref-counter for shared B-tree info */ hbool_t incr_rc=FALSE; /* Flag to indicate that we've incremented the B-tree's shared info reference count */ H5B2_shared_t *shared; /* Pointer to B-tree's shared information */ H5B2_node_ptr_t leaf_ptr; /* Node pointer info for leaf node */ H5B2_leaf_t *leaf=NULL; /* Pointer to leaf node */ unsigned leaf_nrec; /* Number of records in leaf to modify */ int cmp; /* Comparison value of records */ unsigned idx; /* Location of record which matches key */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(H5B2_insert, FAIL) /* Check arguments. */ HDassert(f); HDassert(type); HDassert(H5F_addr_defined(addr)); /* Look up the b-tree header */ if (NULL == (bt2 = H5AC_protect(f, dxpl_id, H5AC_BT2_HDR, addr, type, NULL, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree header") /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(bt2->shared); HDassert(shared); /* Safely grab pointer to reference counted shared B-tree info, so we can release the B-tree header if necessary */ bt2_shared=bt2->shared; H5RC_INC(bt2_shared); incr_rc=TRUE; /* Check if the root node is allocated yet */ if(!H5F_addr_defined(bt2->root.addr)) { /* Create root node as leaf node in B-tree */ if(H5B2_create_leaf(f, dxpl_id, bt2_shared, &(bt2->root))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "unable to create root node") /* Mark B-tree header as dirty, since we updated the address of the root node */ bt2->cache_info.is_dirty = TRUE; } /* end if */ /* Check if we need to split the root node */ else if((bt2->depth==0 && bt2->root.node_nrec==shared->split_leaf_nrec) || (bt2->depth>0 && bt2->root.node_nrec==shared->split_int_nrec)) { /* Split root node */ if(H5B2_split_root(f, dxpl_id, bt2, bt2_shared)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTSPLIT, FAIL, "unable to split root node") } /* end if */ /* Check for non-trivial B-tree */ if(bt2->depth>0) { H5B2_internal_t *internal; /* Pointer to internal node in B-tree */ H5AC_info_t *parent_cache_info; /* Parent node's cache info */ haddr_t parent_addr; /* Address of parent which contain's node pointer to current node */ void *parent_ptr; /* Pointer to parent structure in memory */ H5AC_info_t *curr_cache_info=NULL; /* Current node's cache info */ H5B2_node_ptr_t *curr_node_ptr; /* Pointer to node pointer info for current node (in parent node) */ haddr_t curr_addr=HADDR_UNDEF; /* Address of current node */ void *curr_ptr=NULL; /* Pointer to current structure in memory */ H5B2_node_ptr_t *child_node_ptr=NULL; /* Pointer to node pointer info for child node */ unsigned depth; /* Depth of current node */ /* Track the depth of current node (leaves are depth 0) */ depth=bt2->depth; /* Set initial "parent" information to the B-tree header */ parent_cache_info=&(bt2->cache_info); parent_addr=addr; parent_ptr=bt2; /* Set initial node pointer for "current" node */ curr_node_ptr=&(bt2->root); /* Find correct leaf to insert node into */ while(depth>0) { unsigned retries; /* Lock B-tree current node */ if (NULL == (internal = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr->addr, &(curr_node_ptr->node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") #ifdef H5B2_DEBUG H5B2_assert_internal((hsize_t)0,shared,internal); #endif /* H5B2_DEBUG */ /* Set information for current (root) node */ curr_cache_info=&(internal->cache_info); curr_addr=curr_node_ptr->addr; curr_ptr=internal; /* Locate node pointer for child */ if((cmp=H5B2_locate_record(shared->type,internal->nrec,shared->nat_off,internal->int_native,udata,&idx)) == 0) HGOTO_ERROR(H5E_BTREE, H5E_EXISTS, FAIL, "record is already in B-tree") if(cmp>0) idx++; /* Get node pointer for child */ child_node_ptr=&(internal->node_ptrs[idx]); /* Set the number of redistribution retries */ /* This takes care of the case where a B-tree node needs to be * redistributed, but redistributing the node causes the index * for insertion to move to another node, which also needs to be * redistributed. Now, we loop trying to redistribute and then * eventually force a split */ retries = 2; /* Preemptively split/redistribute a node we will enter */ while((depth==1 && child_node_ptr->node_nrec==shared->split_leaf_nrec) || (depth>1 && child_node_ptr->node_nrec==shared->split_int_nrec)) { /* Attempt to redistribute records among children */ if(idx==0) { /* Left-most child */ if(retries>0 && ((depth==1 && internal->node_ptrs[idx+1].node_nrecsplit_leaf_nrec) || (depth>1 && internal->node_ptrs[idx+1].node_nrecsplit_int_nrec))) { if(H5B2_redistribute2(f,dxpl_id,depth,internal,(unsigned)idx)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTREDISTRIBUTE, FAIL, "unable to redistribute child node records") } /* end if */ else { if(H5B2_split2(f,dxpl_id,depth,curr_node_ptr,parent_cache_info,internal,(unsigned)idx)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTSPLIT, FAIL, "unable to split child node") } /* end else */ } /* end if */ else if((unsigned)idx==internal->nrec) { /* Right-most child */ if(retries>0 && ((depth==1 && internal->node_ptrs[idx-1].node_nrecsplit_leaf_nrec) || (depth>1 && internal->node_ptrs[idx-1].node_nrecsplit_int_nrec))) { if(H5B2_redistribute2(f,dxpl_id,depth,internal,(unsigned)(idx-1))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTREDISTRIBUTE, FAIL, "unable to redistribute child node records") } /* end if */ else { if(H5B2_split2(f,dxpl_id,depth,curr_node_ptr,parent_cache_info,internal,(unsigned)(idx-1))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTSPLIT, FAIL, "unable to split child node") } /* end else */ } /* end if */ else { /* Middle child */ if(retries>0 && ((depth==1 && ((internal->node_ptrs[idx+1].node_nrecsplit_leaf_nrec) || (internal->node_ptrs[idx-1].node_nrecsplit_leaf_nrec))) || (depth>1 && ((internal->node_ptrs[idx+1].node_nrecsplit_int_nrec) || (internal->node_ptrs[idx-1].node_nrecsplit_int_nrec))))) { if(H5B2_redistribute3(f,dxpl_id,depth,internal,(unsigned)idx)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTREDISTRIBUTE, FAIL, "unable to redistribute child node records") } /* end if */ else { if(H5B2_split3(f,dxpl_id,depth,curr_node_ptr,parent_cache_info,internal,(unsigned)idx)<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTSPLIT, FAIL, "unable to split child node") } /* end else */ } /* end else */ /* Locate node pointer for child (after split redistribute) */ /* Actually, this can be easily updated (for 2-node redistrib.) and shouldn't require re-searching */ if((cmp=H5B2_locate_record(shared->type,internal->nrec,shared->nat_off,internal->int_native,udata,&idx)) == 0) HGOTO_ERROR(H5E_BTREE, H5E_EXISTS, FAIL, "record is already in B-tree") if(cmp > 0) idx++; /* Update child_node_ptr (to reflect change in location from split/redistribution) */ child_node_ptr=&(internal->node_ptrs[idx]); /* Decrement the number of redistribution retries left */ retries--; } /* end if */ /* Update record count (in parent) */ curr_node_ptr->all_nrec++; /* Mark parent node as dirty */ parent_cache_info->is_dirty = TRUE; #ifdef H5B2_DEBUG if(parent_cache_info->type==H5AC_BT2_INT) H5B2_assert_internal((hsize_t)0,shared,parent_ptr); #endif /* H5B2_DEBUG */ /* Unlock parent node (possibly the B-tree header) */ if (H5AC_unprotect(f, dxpl_id, parent_cache_info->type, parent_addr, parent_ptr, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree info") /* Transition "current" info into "parent" info */ parent_cache_info = curr_cache_info; parent_addr = curr_addr; parent_ptr = curr_ptr; /* Transition "child" node pointer to "current" node pointer */ curr_node_ptr = child_node_ptr; /* Decrement depth of current node */ depth--; } /* end while */ /* Update record count for leaf (in current node) */ HDassert(curr_node_ptr); curr_node_ptr->all_nrec++; curr_node_ptr->node_nrec++; /* Mark parent node as dirty */ curr_cache_info->is_dirty = TRUE; /* Copy node pointer info for leaf */ leaf_ptr = *curr_node_ptr; #ifdef H5B2_DEBUG if(curr_cache_info->type==H5AC_BT2_INT) H5B2_assert_internal((hsize_t)0,shared,curr_ptr); #endif /* H5B2_DEBUG */ /* Release current node */ if (H5AC_unprotect(f, dxpl_id, curr_cache_info->type, curr_addr, curr_ptr, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") } /* end if */ else { /* Update record count for root node */ bt2->root.all_nrec++; bt2->root.node_nrec++; /* Mark parent node as dirty */ bt2->cache_info.is_dirty = TRUE; /* Copy node pointer info for leaf */ leaf_ptr = bt2->root; /* Release parent node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_HDR, addr, bt2, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree header info") bt2=NULL; } /* end else */ /* Get the actual # of records in leaf */ leaf_nrec = leaf_ptr.node_nrec - 1; /* Must have a leaf node with enough space to insert a record now */ HDassert(H5F_addr_defined(leaf_ptr.addr)); HDassert(leaf_nrec < shared->split_leaf_nrec); /* node pointer to leaf has already been incremented */ /* Look up the B-tree leaf node */ if (NULL == (leaf = H5AC_protect(f, dxpl_id, H5AC_BT2_LEAF, leaf_ptr.addr, &leaf_nrec, bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* Sanity check number of records */ HDassert(leaf_ptr.all_nrec == leaf_ptr.node_nrec); HDassert(leaf->nrec == leaf_nrec); /* Check for inserting into empty leaf */ if(leaf->nrec==0) idx=0; else { /* Sanity check for the leaf node being full */ HDassert(leaf->nrec!=shared->split_leaf_nrec); /* Find correct location to insert this record */ if((cmp = H5B2_locate_record(shared->type,leaf->nrec,shared->nat_off,leaf->leaf_native,udata,&idx)) == 0) { /* Release the B-tree leaf node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, leaf_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree leaf node") HGOTO_ERROR(H5E_BTREE, H5E_EXISTS, FAIL, "record is already in B-tree") } /* end if */ if(cmp > 0) idx++; /* Make room for new record */ if((unsigned)idxnrec) HDmemmove(H5B2_LEAF_NREC(leaf,shared,idx+1),H5B2_LEAF_NREC(leaf,shared,idx),shared->type->nrec_size*(leaf->nrec-idx)); } /* end else */ /* Make callback to store record in native form */ if((shared->type->store)(udata,H5B2_LEAF_NREC(leaf,shared,idx))<0) { /* Release the B-tree leaf node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, leaf_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree leaf node") HGOTO_ERROR(H5E_BTREE, H5E_CANTINSERT, FAIL, "unable to insert record into leaf node") } /* end if */ /* Update number of records in node */ leaf->nrec++; /* Mark leaf node as dirty also */ leaf->cache_info.is_dirty = TRUE; /* Release the B-tree leaf node */ #ifdef H5B2_DEBUG H5B2_assert_leaf(shared,leaf); #endif /* H5B2_DEBUG */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, leaf_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree leaf node") done: /* Check if we need to decrement the reference count for the B-tree's shared info */ if(incr_rc) H5RC_DEC(bt2_shared); FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_insert() */ /*------------------------------------------------------------------------- * Function: H5B2_create_leaf * * Purpose: Creates empty leaf node of a B-tree and update node pointer * to point to it. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 2 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_create_leaf(H5F_t *f, hid_t dxpl_id, H5RC_t *bt2_shared, H5B2_node_ptr_t *node_ptr) { H5B2_leaf_t *leaf=NULL; /* Pointer to new leaf node created */ H5B2_shared_t *shared; /* Shared B-tree information */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(H5B2_create_leaf, FAIL) /* Check arguments. */ HDassert(f); HDassert(bt2_shared); HDassert(node_ptr); /* Allocate memory for leaf information */ if (NULL==(leaf = H5FL_MALLOC(H5B2_leaf_t))) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree leaf info") /* Set metadata cache info */ HDmemset(&leaf->cache_info,0,sizeof(H5AC_info_t)); leaf->cache_info.is_dirty = TRUE; /* Share common B-tree information */ leaf->shared = bt2_shared; H5RC_INC(leaf->shared); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(leaf->shared); HDassert(shared); /* Allocate space for the native keys in memory */ if((leaf->leaf_native=H5FL_FAC_MALLOC(shared->leaf_fac))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree leaf native keys") #ifdef H5_USING_PURIFY HDmemset(leaf->leaf_native,0,shared->type->nrec_size*shared->leaf_nrec); #endif /* H5_USING_PURIFY */ /* Set number of records */ leaf->nrec=0; /* Allocate space on disk for the leaf */ if (HADDR_UNDEF==(node_ptr->addr=H5MF_alloc(f, H5FD_MEM_BTREE, dxpl_id, (hsize_t)shared->node_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "file allocation failed for B-tree leaf node") /* Cache the new B-tree node */ if (H5AC_set(f, dxpl_id, H5AC_BT2_LEAF, node_ptr->addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "can't add B-tree leaf to cache") done: if (ret_value<0) { if (leaf) (void)H5B2_cache_leaf_dest(f,leaf); } /* end if */ FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_create_leaf() */ /*------------------------------------------------------------------------- * Function: H5B2_create_internal * * Purpose: Creates empty internal node of a B-tree and update node pointer * to point to it. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 3 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_create_internal(H5F_t *f, hid_t dxpl_id, H5RC_t *bt2_shared, H5B2_node_ptr_t *node_ptr) { H5B2_internal_t *internal=NULL; /* Pointer to new internal node created */ H5B2_shared_t *shared; /* Shared B-tree information */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(H5B2_create_internal, FAIL) /* Check arguments. */ HDassert(f); HDassert(bt2_shared); HDassert(node_ptr); /* Allocate memory for internal node information */ if (NULL==(internal = H5FL_MALLOC(H5B2_internal_t))) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree internal info") /* Set metadata cache info */ HDmemset(&internal->cache_info,0,sizeof(H5AC_info_t)); internal->cache_info.is_dirty = TRUE; /* Share common B-tree information */ internal->shared = bt2_shared; H5RC_INC(internal->shared); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(internal->shared); HDassert(shared); /* Allocate space for the native keys in memory */ if((internal->int_native=H5FL_FAC_MALLOC(shared->int_fac))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree internal native keys") #ifdef H5_USING_PURIFY HDmemset(internal->int_native,0,shared->type->nrec_size*shared->internal_nrec); #endif /* H5_USING_PURIFY */ /* Allocate space for the node pointers in memory */ if((internal->node_ptrs=H5FL_FAC_MALLOC(shared->node_ptr_fac))==NULL) HGOTO_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for B-tree internal node pointers") #ifdef H5_USING_PURIFY HDmemset(internal->node_ptrs,0,sizeof(H5B2_node_ptr_t)*(shared->internal_nrec+1)); #endif /* H5_USING_PURIFY */ /* Set number of records */ internal->nrec=0; /* Allocate space on disk for the internal node */ if (HADDR_UNDEF==(node_ptr->addr=H5MF_alloc(f, H5FD_MEM_BTREE, dxpl_id, (hsize_t)shared->node_size))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "file allocation failed for B-tree internal node") /* Cache the new B-tree node */ if (H5AC_set(f, dxpl_id, H5AC_BT2_INT, node_ptr->addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTINIT, FAIL, "can't add B-tree internal node to cache") done: if (ret_value<0) { if (internal) (void)H5B2_cache_internal_dest(f,internal); } /* end if */ FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_create_internal() */ /*------------------------------------------------------------------------- * Function: H5B2_iterate_node * * Purpose: Iterate over all the records from a B-tree node, in "in-order" * order, making a callback for each record. * * If the callback returns non-zero, the iteration breaks out * without finishing all the records. * * Return: Value from callback, non-negative on success, negative on error * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 11 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_iterate_node(H5F_t *f, hid_t dxpl_id, H5RC_t *bt2_shared, unsigned depth, const H5B2_node_ptr_t *curr_node, H5B2_operator_t op, void *op_data) { H5B2_shared_t *shared; /* Pointer to B-tree's shared information */ const H5AC_class_t *curr_node_class=NULL; /* Pointer to current node's class info */ void *node=NULL; /* Pointers to current node */ uint8_t *native; /* Pointers to node's native records */ H5B2_node_ptr_t *node_ptrs=NULL; /* Pointers to node's node pointers */ unsigned u; /* Local index */ herr_t ret_value = H5B2_ITER_CONT; FUNC_ENTER_NOAPI(H5B2_iterate_node, FAIL) /* Check arguments. */ HDassert(f); HDassert(bt2_shared); HDassert(curr_node); HDassert(op); /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(bt2_shared); HDassert(shared); if(depth>0) { H5B2_internal_t *internal; /* Pointer to internal node */ /* Lock the current B-tree node */ if (NULL == (internal = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, curr_node->addr, &(curr_node->node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Set up information about current node */ curr_node_class = H5AC_BT2_INT; node = internal; native = internal->int_native; node_ptrs = internal->node_ptrs; } /* end if */ else { H5B2_leaf_t *leaf; /* Pointer to leaf node */ /* Lock the current B-tree node */ if (NULL == (leaf = H5AC_protect(f, dxpl_id, H5AC_BT2_LEAF, curr_node->addr, &(curr_node->node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree leaf node") /* Set up information about current node */ curr_node_class = H5AC_BT2_LEAF; node = leaf; native = leaf->leaf_native; } /* end else */ /* Iterate through records */ for(u=0; unode_nrec && !ret_value; u++) { /* Descend into child node, if current node is an internal node */ if(depth>0) { if((ret_value = H5B2_iterate_node(f,dxpl_id,bt2_shared,depth-1,&(node_ptrs[u]),op,op_data))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTLIST, FAIL, "node iteration failed") } /* end if */ /* Make callback for current record */ if ((ret_value = (op)(H5B2_NAT_NREC(native,shared,u), op_data)) <0) HGOTO_ERROR(H5E_BTREE, H5E_CANTLIST, FAIL, "iterator function failed") } /* end for */ /* Descend into last child node, if current node is an internal node */ if(!ret_value && depth>0) { if((ret_value = H5B2_iterate_node(f,dxpl_id,bt2_shared,depth-1,&(node_ptrs[u]),op,op_data))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTLIST, FAIL, "node iteration failed") } /* end if */ done: /* Unlock current node */ if(node) if (H5AC_unprotect(f, dxpl_id, curr_node_class, curr_node->addr, node, H5AC__NO_FLAGS_SET) < 0) HDONE_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_iterate_node() */ /*------------------------------------------------------------------------- * Function: H5B2_iterate * * Purpose: Iterate over all the records in the B-tree, in "in-order" * order, making a callback for each record. * * If the callback returns non-zero, the iteration breaks out * without finishing all the records. * * Return: Value from callback, non-negative on success, negative on error * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 11 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_iterate(H5F_t *f, hid_t dxpl_id, const H5B2_class_t *type, haddr_t addr, H5B2_operator_t op, void *op_data) { H5B2_t *bt2=NULL; /* Pointer to the B-tree header */ H5RC_t *bt2_shared=NULL; /* Pointer to ref-counter for shared B-tree info */ hbool_t incr_rc=FALSE; /* Flag to indicate that we've incremented the B-tree's shared info reference count */ H5B2_node_ptr_t root_ptr; /* Node pointer info for root node */ unsigned depth; /* Current depth of the tree */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(H5B2_iterate, FAIL) /* Check arguments. */ HDassert(f); HDassert(type); HDassert(H5F_addr_defined(addr)); HDassert(op); /* Look up the B-tree header */ if (NULL == (bt2 = H5AC_protect(f, dxpl_id, H5AC_BT2_HDR, addr, type, NULL, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree header") /* Safely grab pointer to reference counted shared B-tree info, so we can release the B-tree header if necessary */ bt2_shared=bt2->shared; H5RC_INC(bt2_shared); incr_rc=TRUE; /* Make copy of the root node pointer */ root_ptr = bt2->root; /* Current depth of the tree */ depth=bt2->depth; /* Release header */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_HDR, addr, bt2, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree header info") bt2=NULL; /* Iterate through records */ if(root_ptr.node_nrec>0) { /* Iterate through nodes */ if((ret_value=H5B2_iterate_node(f,dxpl_id,bt2_shared,depth,&root_ptr,op,op_data))<0) HGOTO_ERROR(H5E_BTREE, H5E_CANTLIST, FAIL, "node iteration failed") } /* end if */ done: /* Check if we need to decrement the reference count for the B-tree's shared info */ if(incr_rc) H5RC_DEC(bt2_shared); FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_iterate() */ /*------------------------------------------------------------------------- * Function: H5B2_find * * Purpose: Locate the specified information in a B-tree and return * that information by filling in fields of the caller-supplied * UDATA pointer depending on the type of leaf node * requested. The UDATA can point to additional data passed * to the key comparison function. * * The 'OP' routine is called with the record found and the * OP_DATA pointer, to allow caller to return information about * the record. * * Return: Non-negative on success, negative on failure. * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 23 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_find(H5F_t *f, hid_t dxpl_id, const H5B2_class_t *type, haddr_t addr, void *udata, H5B2_found_t op, void *op_data) { H5B2_t *bt2=NULL; /* Pointer to the B-tree header */ H5RC_t *bt2_shared=NULL; /* Pointer to ref-counter for shared B-tree info */ H5B2_shared_t *shared; /* Pointer to B-tree's shared information */ hbool_t incr_rc=FALSE; /* Flag to indicate that we've incremented the B-tree's shared info reference count */ H5B2_node_ptr_t curr_node_ptr; /* Node pointer info for current node */ unsigned depth; /* Current depth of the tree */ int cmp; /* Comparison value of records */ unsigned idx; /* Location of record which matches key */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(H5B2_find, FAIL) /* Check arguments. */ HDassert(f); HDassert(type); HDassert(H5F_addr_defined(addr)); HDassert(op); /* Look up the B-tree header */ if (NULL == (bt2 = H5AC_protect(f, dxpl_id, H5AC_BT2_HDR, addr, type, NULL, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree header") /* Safely grab pointer to reference counted shared B-tree info, so we can release the B-tree header if necessary */ bt2_shared=bt2->shared; H5RC_INC(bt2_shared); incr_rc=TRUE; /* Make copy of the root node pointer to start search with */ curr_node_ptr = bt2->root; /* Current depth of the tree */ depth=bt2->depth; /* Release header */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_HDR, addr, bt2, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree header info") bt2=NULL; /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(bt2_shared); HDassert(shared); /* Check for empty tree */ if(curr_node_ptr.node_nrec==0) HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "B-tree has no records") /* Walk down B-tree to find record or leaf node where record is located */ cmp = -1; while(depth>0 && cmp != 0) { H5B2_internal_t *internal; /* Pointer to internal node in B-tree */ H5B2_node_ptr_t next_node_ptr; /* Node pointer info for next node */ /* Lock B-tree current node */ if (NULL == (internal = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, &(curr_node_ptr.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Locate node pointer for child */ cmp = H5B2_locate_record(shared->type, internal->nrec, shared->nat_off, internal->int_native, udata, &idx); if(cmp > 0) idx++; if(cmp != 0) { /* Get node pointer for next node to search */ next_node_ptr=internal->node_ptrs[idx]; /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") /* Set pointer to next node to load */ curr_node_ptr = next_node_ptr; } /* end if */ else { /* Make callback for current record */ if ((op)(H5B2_INT_NREC(internal,shared,idx), op_data) <0) { /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "'found' callback failed for B-tree find operation") } /* end if */ /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") HGOTO_DONE(SUCCEED); } /* end else */ /* Decrement depth we're at in B-tree */ depth--; } /* end while */ { H5B2_leaf_t *leaf; /* Pointer to leaf node in B-tree */ /* Lock B-tree leaf node */ if (NULL == (leaf = H5AC_protect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, &(curr_node_ptr.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Locate record */ cmp = H5B2_locate_record(shared->type, leaf->nrec, shared->nat_off, leaf->leaf_native, udata, &idx); if(cmp != 0) { /* Unlock leaf node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") /* Note: don't push error on stack, leave that to next higher level, * since many times the B-tree is searched in order to determine * if an object exists in the B-tree or not. -QAK */ #ifdef OLD_WAY HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "key not found in leaf node") #else /* OLD_WAY */ HGOTO_DONE(FAIL) #endif /* OLD_WAY */ } /* end if */ else { /* Make callback for current record */ if ((op)(H5B2_LEAF_NREC(leaf,shared,idx), op_data) <0) { /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "'found' callback failed for B-tree find operation") } /* end if */ } /* end else */ /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") } done: /* Check if we need to decrement the reference count for the B-tree's shared info */ if(incr_rc) H5RC_DEC(bt2_shared); FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_find() */ /*------------------------------------------------------------------------- * Function: H5B2_index * * Purpose: Locate the IDX'th record in a B-tree according to the * ordering used by the B-tree. The IDX values are 0-based. * * The 'OP' routine is called with the record found and the * OP_DATA pointer, to allow caller to return information about * the record. * * Return: Non-negative on success, negative on failure. * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 23 2005 * *------------------------------------------------------------------------- */ herr_t H5B2_index(H5F_t *f, hid_t dxpl_id, const H5B2_class_t *type, haddr_t addr, hsize_t idx, H5B2_found_t op, void *op_data) { H5B2_t *bt2=NULL; /* Pointer to the B-tree header */ H5RC_t *bt2_shared=NULL; /* Pointer to ref-counter for shared B-tree info */ H5B2_shared_t *shared; /* Pointer to B-tree's shared information */ hbool_t incr_rc=FALSE; /* Flag to indicate that we've incremented the B-tree's shared info reference count */ H5B2_node_ptr_t curr_node_ptr; /* Node pointer info for current node */ unsigned depth; /* Current depth of the tree */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(H5B2_index, FAIL) /* Check arguments. */ HDassert(f); HDassert(type); HDassert(H5F_addr_defined(addr)); HDassert(op); /* Look up the B-tree header */ if (NULL == (bt2 = H5AC_protect(f, dxpl_id, H5AC_BT2_HDR, addr, type, NULL, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree header") /* Safely grab pointer to reference counted shared B-tree info, so we can release the B-tree header if necessary */ bt2_shared=bt2->shared; H5RC_INC(bt2_shared); incr_rc=TRUE; /* Make copy of the root node pointer to start search with */ curr_node_ptr = bt2->root; /* Current depth of the tree */ depth=bt2->depth; /* Release header */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_HDR, addr, bt2, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree header info") bt2=NULL; /* Get the pointer to the shared B-tree info */ shared=H5RC_GET_OBJ(bt2_shared); HDassert(shared); /* Check for empty tree */ if(curr_node_ptr.node_nrec==0) HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "B-tree has no records") /* Check for index greater than the number of records in the tree */ if(idx >= curr_node_ptr.all_nrec) HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "B-tree doesn't have that many records") /* Walk down B-tree to find record or leaf node where record is located */ while(depth>0) { H5B2_internal_t *internal; /* Pointer to internal node in B-tree */ H5B2_node_ptr_t next_node_ptr; /* Node pointer info for next node */ unsigned u; /* Local index variable */ /* Lock B-tree current node */ if (NULL == (internal = H5AC_protect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, &(curr_node_ptr.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Search for record with correct index */ for(u=0; unrec; u++) { /* Check if record is in child node */ if(internal->node_ptrs[u].all_nrec > idx) { /* Get node pointer for next node to search */ next_node_ptr=internal->node_ptrs[u]; /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") /* Set pointer to next node to load */ curr_node_ptr = next_node_ptr; /* Break out of for loop */ break; } /* end if */ /* Check if record is in this node */ if(internal->node_ptrs[u].all_nrec == idx) { /* Make callback for current record */ if ((op)(H5B2_INT_NREC(internal,shared,u), op_data) <0) { /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "'found' callback failed for B-tree find operation") } /* end if */ /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") HGOTO_DONE(SUCCEED); } /* end if */ /* Decrement index we are looking for to account for the node we */ /* just advanced past */ idx -= (internal->node_ptrs[u].all_nrec + 1); } /* end for */ /* Check last node pointer */ if(u==internal->nrec) { /* Check if record is in child node */ if(internal->node_ptrs[u].all_nrec > idx) { /* Get node pointer for next node to search */ next_node_ptr=internal->node_ptrs[u]; /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_INT, curr_node_ptr.addr, internal, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") /* Set pointer to next node to load */ curr_node_ptr = next_node_ptr; } /* end if */ else /* Index that is greater than the number of records in the tree? */ HDassert("Index off end of tree??" && 0); } /* end if */ /* Decrement depth we're at in B-tree */ depth--; } /* end while */ { H5B2_leaf_t *leaf; /* Pointer to leaf node in B-tree */ /* Lock B-tree leaf node */ if (NULL == (leaf = H5AC_protect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, &(curr_node_ptr.node_nrec), bt2_shared, H5AC_WRITE))) HGOTO_ERROR(H5E_BTREE, H5E_CANTPROTECT, FAIL, "unable to load B-tree internal node") /* Sanity check index */ HDassert(idx < leaf->nrec); /* Make callback for correct record */ if ((op)(H5B2_LEAF_NREC(leaf,shared,idx), op_data) <0) { /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") HGOTO_ERROR(H5E_BTREE, H5E_NOTFOUND, FAIL, "'found' callback failed for B-tree find operation") } /* end if */ /* Unlock current node */ if (H5AC_unprotect(f, dxpl_id, H5AC_BT2_LEAF, curr_node_ptr.addr, leaf, H5AC__NO_FLAGS_SET) < 0) HGOTO_ERROR(H5E_BTREE, H5E_CANTUNPROTECT, FAIL, "unable to release B-tree node") } done: /* Check if we need to decrement the reference count for the B-tree's shared info */ if(incr_rc) H5RC_DEC(bt2_shared); FUNC_LEAVE_NOAPI(ret_value) } /* H5B2_index() */ #ifdef H5B2_DEBUG /*------------------------------------------------------------------------- * Function: H5B2_assert_leaf * * Purpose: Verify than a leaf node is mostly sane * * Return: Non-negative on success, negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 19 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_assert_leaf(H5B2_shared_t *shared, H5B2_leaf_t *leaf) { unsigned u,v; /* Local index variables */ /* General sanity checking on node */ HDassert(leaf->nrec<=shared->split_leaf_nrec); /* Sanity checking on records */ for(u=0; unrec; u++) for(v=0; vtype->compare)(H5B2_LEAF_NREC(leaf,shared,u), H5B2_LEAF_NREC(leaf,shared,v))>0); return(0); } /* end H5B2_assert_leaf() */ /*------------------------------------------------------------------------- * Function: H5B2_assert_leaf2 * * Purpose: Verify than a leaf node is mostly sane * * Return: Non-negative on success, negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 19 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_assert_leaf2(H5B2_shared_t *shared, H5B2_leaf_t *leaf, H5B2_leaf_t *leaf2) { unsigned u,v; /* Local index variables */ /* General sanity checking on node */ HDassert(leaf->nrec<=shared->split_leaf_nrec); /* Sanity checking on records */ for(u=0; unrec; u++) { HDassert((shared->type->compare)(H5B2_LEAF_NREC(leaf2,shared,0), H5B2_LEAF_NREC(leaf,shared,u))>0); for(v=0; vtype->compare)(H5B2_LEAF_NREC(leaf,shared,u), H5B2_LEAF_NREC(leaf,shared,v))>0); } /* end for */ return(0); } /* end H5B2_assert_leaf() */ /*------------------------------------------------------------------------- * Function: H5B2_assert_internal * * Purpose: Verify than an internal node is mostly sane * * Return: Non-negative on success, negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 19 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_assert_internal(hsize_t parent_all_nrec, H5B2_shared_t *shared, H5B2_internal_t *internal) { hsize_t tot_all_nrec; /* Total number of records at or below this node */ unsigned u,v; /* Local index variables */ /* General sanity checking on node */ HDassert(internal->nrec<=shared->split_int_nrec); /* Sanity checking on records */ for(u=0; unrec; u++) for(v=0; vtype->compare)(H5B2_INT_NREC(internal,shared,u), H5B2_INT_NREC(internal,shared,v))>0); /* Sanity checking on node pointers */ tot_all_nrec=internal->nrec; for(u=0; unrec+1; u++) { tot_all_nrec += internal->node_ptrs[u].all_nrec; HDassert(H5F_addr_defined(internal->node_ptrs[u].addr)); HDassert(internal->node_ptrs[u].addr>0); for(v=0; vnode_ptrs[u].addr!=internal->node_ptrs[v].addr); } /* end for */ /* Sanity check all_nrec total in parent */ if(parent_all_nrec>0) HDassert(tot_all_nrec == parent_all_nrec); return(0); } /* end H5B2_assert_internal() */ /*------------------------------------------------------------------------- * Function: H5B2_assert_internal2 * * Purpose: Verify than internal nodes are mostly sane * * Return: Non-negative on success, negative on failure * * Programmer: Quincey Koziol * koziol@ncsa.uiuc.edu * Feb 19 2005 * *------------------------------------------------------------------------- */ static herr_t H5B2_assert_internal2(hsize_t parent_all_nrec, H5B2_shared_t *shared, H5B2_internal_t *internal, H5B2_internal_t *internal2) { hsize_t tot_all_nrec; /* Total number of records at or below this node */ unsigned u,v; /* Local index variables */ /* General sanity checking on node */ HDassert(internal->nrec<=shared->split_int_nrec); /* Sanity checking on records */ for(u=0; unrec; u++) for(v=0; vtype->compare)(H5B2_INT_NREC(internal,shared,u), H5B2_INT_NREC(internal,shared,v))>0); /* Sanity checking on node pointers */ tot_all_nrec=internal->nrec; for(u=0; unrec+1; u++) { tot_all_nrec += internal->node_ptrs[u].all_nrec; HDassert(H5F_addr_defined(internal->node_ptrs[u].addr)); HDassert(internal->node_ptrs[u].addr>0); for(v=0; vnode_ptrs[u].addr!=internal->node_ptrs[v].addr); for(v=0; vnrec+1; v++) HDassert(internal->node_ptrs[u].addr!=internal2->node_ptrs[v].addr); } /* end for */ /* Sanity check all_nrec total in parent */ if(parent_all_nrec>0) HDassert(tot_all_nrec == parent_all_nrec); return(0); } /* end H5B2_assert_internal2() */ #endif /* H5B2_DEBUG */