/*------------------------------------------------------------------------- * Copyright (C) 1997 National Center for Supercomputing Applications. * All rights reserved. * *------------------------------------------------------------------------- * * Created: snode.c * Jun 26 1997 * Robb Matzke * * Purpose: Functions for handling symbol table nodes. A * symbol table node is a small collection of symbol * table entries. A B-tree usually points to the * symbol table nodes for any given symbol table. * * Modifications: * *------------------------------------------------------------------------- */ #define H5G_PACKAGE /*suppress error message about including H5Gpkg.h */ /* Packages needed by this file... */ #include /*library */ #include /*cache */ #include /*B-link trees */ #include /*error handling */ #include /*me */ #include /*heap */ #include /*file memory management */ #include /*core memory management */ #include /*header messages */ #define PABLO_MASK H5G_node_mask /* PRIVATE PROTOTYPES */ static herr_t H5G_node_decode_key(H5F_t *f, H5B_t *bt, uint8 *raw, void *_key); static herr_t H5G_node_encode_key(H5F_t *f, H5B_t *bt, uint8 *raw, void *_key); static size_t H5G_node_size(H5F_t *f); static herr_t H5G_node_create(H5F_t *f, H5B_ins_t op, void *_lt_key, void *_udata, void *_rt_key, haddr_t *addr /*out */ ); static herr_t H5G_node_flush(H5F_t *f, hbool_t destroy, const haddr_t *addr, H5G_node_t *sym); static H5G_node_t *H5G_node_load(H5F_t *f, const haddr_t *addr, const void *_udata1, void *_udata2); static intn H5G_node_cmp2(H5F_t *f, void *_lt_key, void *_udata, void *_rt_key); static intn H5G_node_cmp3(H5F_t *f, void *_lt_key, void *_udata, void *_rt_key); static herr_t H5G_node_found(H5F_t *f, const haddr_t *addr, const void *_lt_key, void *_udata, const void *_rt_key); static H5B_ins_t H5G_node_insert(H5F_t *f, const haddr_t *addr, void *_lt_key, hbool_t *lt_key_changed, void *_md_key, void *_udata, void *_rt_key, hbool_t *rt_key_changed, haddr_t *new_node /*out */ ); static herr_t H5G_node_list(H5F_t *f, const haddr_t *addr, void *_udata); static size_t H5G_node_sizeof_rkey(H5F_t *f, const void *_udata); /* H5G inherits cache-like properties from H5AC */ const H5AC_class_t H5AC_SNODE[1] = { { H5AC_SNODE_ID, (void *(*)(H5F_t *, const haddr_t *, const void *, void *)) H5G_node_load, (herr_t (*)(H5F_t *, hbool_t, const haddr_t *, void *)) H5G_node_flush, }}; /* H5G inherits B-tree like properties from H5B */ H5B_class_t H5B_SNODE[1] = { { H5B_SNODE_ID, /*id */ sizeof(H5G_node_key_t), /*sizeof_nkey */ H5G_node_sizeof_rkey, /*get_sizeof_rkey */ H5G_node_create, /*new */ H5G_node_cmp2, /*cmp2 */ H5G_node_cmp3, /*cmp3 */ H5G_node_found, /*found */ H5G_node_insert, /*insert */ TRUE, /*follow min branch? */ TRUE, /*follow max branch? */ H5G_node_list, /*list */ H5G_node_decode_key, /*decode */ H5G_node_encode_key, /*encode */ }}; /* Interface initialization */ static intn interface_initialize_g = FALSE; #define INTERFACE_INIT NULL /*------------------------------------------------------------------------- * Function: H5G_node_sizeof_rkey * * Purpose: Returns the size of a raw B-link tree key for the specified * file. * * Return: Success: Size of the key. * * Failure: never fails * * Programmer: Robb Matzke * matzke@llnl.gov * Jul 14 1997 * * Modifications: * *------------------------------------------------------------------------- */ static size_t H5G_node_sizeof_rkey(H5F_t *f, const void *udata __attribute__((unused))) { return H5F_SIZEOF_SIZE(f); /*the name offset */ } /*------------------------------------------------------------------------- * Function: H5G_node_decode_key * * Purpose: Decodes a raw key into a native key. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Jul 8 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5G_node_decode_key(H5F_t *f, H5B_t *bt, uint8 *raw, void *_key) { H5G_node_key_t *key = (H5G_node_key_t *) _key; FUNC_ENTER(H5G_node_decode_key, FAIL); assert(f); assert(raw); assert(key); H5F_decode_length(f, raw, key->offset); FUNC_LEAVE(SUCCEED); } /*------------------------------------------------------------------------- * Function: H5G_node_encode_key * * Purpose: Encodes a native key into a raw key. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Jul 8 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5G_node_encode_key(H5F_t *f, H5B_t *bt, uint8 *raw, void *_key) { H5G_node_key_t *key = (H5G_node_key_t *) _key; FUNC_ENTER(H5G_node_encode_key, FAIL); assert(f); assert(raw); assert(key); H5F_encode_length(f, raw, key->offset); FUNC_LEAVE(SUCCEED); } /*------------------------------------------------------------------------- * Function: H5G_node_size * * Purpose: Returns the total size of a symbol table node. * * Return: Success: Total size of the node in bytes. * * Failure: Never fails. * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 23 1997 * * Modifications: * *------------------------------------------------------------------------- */ static size_t H5G_node_size(H5F_t *f) { return H5G_NODE_SIZEOF_HDR(f) + (2 * H5G_NODE_K(f)) * H5G_SIZEOF_ENTRY(f); } /*------------------------------------------------------------------------- * Function: H5G_node_create * * Purpose: Creates a new empty symbol table node. This function is * called by the B-tree insert function for an empty tree. It * is also called internally to split a symbol node with LT_KEY * and RT_KEY null pointers. * * Return: Success: SUCCEED. The address of symbol table node is * returned through the ADDR argument. * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 23 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5G_node_create(H5F_t *f, H5B_ins_t op, void *_lt_key, void *_udata, void *_rt_key, haddr_t *addr /*out */ ) { H5G_node_key_t *lt_key = (H5G_node_key_t *) _lt_key; H5G_node_key_t *rt_key = (H5G_node_key_t *) _rt_key; H5G_node_t *sym = NULL; size_t size = 0; FUNC_ENTER(H5G_node_create, FAIL); /* * Check arguments. */ assert(f); assert(H5B_INS_FIRST == op); sym = H5MM_xcalloc(1, sizeof(H5G_node_t)); size = H5G_node_size(f); if (H5MF_alloc(f, H5MF_META, size, addr /*out */ ) < 0) { H5MM_xfree(sym); HRETURN_ERROR(H5E_SYM, H5E_CANTINIT, FAIL, "unable to allocate file space"); } sym->dirty = TRUE; sym->entry = H5MM_xcalloc(2 * H5G_NODE_K(f), sizeof(H5G_entry_t)); if (H5AC_set(f, H5AC_SNODE, addr, sym) < 0) { H5MM_xfree(sym->entry); H5MM_xfree(sym); HRETURN_ERROR(H5E_SYM, H5E_CANTINIT, FAIL, "unable to cache symbol table leaf node"); } /* * The left and right symbols in an empty tree are both the * empty string stored at offset zero by the H5G functions. This * allows the comparison functions to work correctly without knowing * that there are no symbols. */ if (lt_key) lt_key->offset = 0; if (rt_key) rt_key->offset = 0; FUNC_LEAVE(SUCCEED); } /*------------------------------------------------------------------------- * Function: H5G_node_flush * * Purpose: Flush a symbol table node to disk. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 23 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5G_node_flush(H5F_t *f, hbool_t destroy, const haddr_t *addr, H5G_node_t *sym) { uint8 *buf = NULL, *p = NULL; size_t size; herr_t status; int i; FUNC_ENTER(H5G_node_flush, FAIL); /* * Check arguments. */ assert(f); assert(addr && H5F_addr_defined(addr)); assert(sym); /* * Look for dirty entries and set the node dirty flag. */ for (i = 0; i < sym->nsyms; i++) { if (sym->entry[i].dirty) sym->dirty = TRUE; } /* * Write the symbol node to disk. */ if (sym->dirty) { size = H5G_node_size(f); buf = p = H5MM_xmalloc(size); /* magic number */ HDmemcpy(p, H5G_NODE_MAGIC, H5G_NODE_SIZEOF_MAGIC); p += 4; /* version number */ *p++ = H5G_NODE_VERS; /* reserved */ *p++ = 0; /* number of symbols */ UINT16ENCODE(p, sym->nsyms); /* entries */ H5G_ent_encode_vec(f, &p, sym->entry, sym->nsyms); HDmemset(p, 0, size - (p - buf)); status = H5F_block_write(f, addr, size, buf); buf = H5MM_xfree(buf); if (status < 0) HRETURN_ERROR(H5E_SYM, H5E_WRITEERROR, FAIL, "unable to write symbol table node to " "the file"); } /* * Destroy the symbol node? This might happen if the node is being * preempted from the cache. */ if (destroy) { sym->entry = H5MM_xfree(sym->entry); H5MM_xfree(sym); } FUNC_LEAVE(SUCCEED); } /*------------------------------------------------------------------------- * Function: H5G_node_load * * Purpose: Loads a symbol table node from the file. * * Return: Success: Ptr to the new table. * * Failure: NULL * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 23 1997 * * Modifications: * *------------------------------------------------------------------------- */ static H5G_node_t * H5G_node_load(H5F_t *f, const haddr_t *addr, const void *_udata1, void *_udata2) { H5G_node_t *sym = NULL; size_t size = 0; uint8 *buf = NULL; const uint8 *p = NULL; H5G_node_t *ret_value = NULL; /*for error handling */ FUNC_ENTER(H5G_node_load, NULL); /* * Check arguments. */ assert(f); assert(addr && H5F_addr_defined(addr)); assert(!_udata1); assert(NULL == _udata2); /* * Initialize variables. */ size = H5G_node_size(f); p = buf = H5MM_xmalloc(size); sym = H5MM_xcalloc(1, sizeof(H5G_node_t)); sym->entry = H5MM_xcalloc(2 * H5G_NODE_K(f), sizeof(H5G_entry_t)); if (H5F_block_read(f, addr, size, buf) < 0) { HGOTO_ERROR(H5E_SYM, H5E_READERROR, NULL, "unabel to read symbol table node"); } /* magic */ if (HDmemcmp(p, H5G_NODE_MAGIC, H5G_NODE_SIZEOF_MAGIC)) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, NULL, "bad symbol table node signature"); } p += 4; /* version */ if (H5G_NODE_VERS != *p++) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, NULL, "bad symbol table node version"); } /* reserved */ p++; /* number of symbols */ UINT16DECODE(p, sym->nsyms); /* entries */ if (H5G_ent_decode_vec(f, &p, sym->entry, sym->nsyms) < 0) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, NULL, "unable to decode symbol table entries"); } buf = H5MM_xfree(buf); ret_value = sym; done: if (!ret_value) { buf = H5MM_xfree(buf); if (sym) { sym->entry = H5MM_xfree(sym->entry); sym = H5MM_xfree(sym); } } FUNC_LEAVE(ret_value); } /*------------------------------------------------------------------------- * Function: H5G_node_cmp2 * * Purpose: Compares two keys from a B-tree node (LT_KEY and RT_KEY). * The UDATA pointer supplies extra data not contained in the * keys (in this case, the heap address). * * Return: Success: negative if LT_KEY is less than RT_KEY. * * positive if LT_KEY is greater than RT_KEY. * * zero if LT_KEY and RT_KEY are equal. * * Failure: FAIL (same as LT_KEYheap_addr), lt_key->offset))) { HRETURN_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "unable to read symbol name"); } if (NULL == (s2 = H5H_peek(f, &(udata->heap_addr), rt_key->offset))) { HRETURN_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "unable to read symbol name"); } cmp = HDstrcmp(s1, s2); FUNC_LEAVE(cmp); } /*------------------------------------------------------------------------- * Function: H5G_node_cmp3 * * Purpose: Compares two keys from a B-tree node (LT_KEY and RT_KEY) * against another key (not necessarily the same type) * pointed to by UDATA. * * Return: Success: negative if the UDATA key is less than * or equal to the LT_KEY * * positive if the UDATA key is greater * than the RT_KEY. * * zero if the UDATA key falls between * the LT_KEY (exclusive) and the * RT_KEY (inclusive). * * Failure: FAIL (same as UDATA < LT_KEY) * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 23 1997 * * Modifications: * *------------------------------------------------------------------------- */ static intn H5G_node_cmp3(H5F_t *f, void *_lt_key, void *_udata, void *_rt_key) { H5G_bt_ud1_t *udata = (H5G_bt_ud1_t *) _udata; H5G_node_key_t *lt_key = (H5G_node_key_t *) _lt_key; H5G_node_key_t *rt_key = (H5G_node_key_t *) _rt_key; const char *s; FUNC_ENTER(H5G_node_cmp3, FAIL); /* left side */ if (NULL == (s = H5H_peek(f, &(udata->heap_addr), lt_key->offset))) { HRETURN_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "unable to read symbol name"); } if (HDstrcmp(udata->name, s) <= 0) HRETURN(-1); /* right side */ if (NULL == (s = H5H_peek(f, &(udata->heap_addr), rt_key->offset))) { HRETURN_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "unable to read symbol name"); } if (HDstrcmp(udata->name, s) > 0) HRETURN(1); FUNC_LEAVE(0); } /*------------------------------------------------------------------------- * Function: H5G_node_found * * Purpose: The B-tree search engine has found the symbol table node * which contains the requested symbol if the symbol exists. * This function should examine that node for the symbol and * return information about the symbol through the UDATA * structure which contains the symbol name on function * entry. * * If the operation flag in UDATA is H5G_OPER_FIND, then * the entry is copied from the symbol table to the UDATA * entry field. Otherwise the entry is copied from the * UDATA entry field to the symbol table. * * Return: Success: SUCCEED if found and data returned through * the UDATA pointer. * * Failure: FAIL if not found. * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 23 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5G_node_found(H5F_t *f, const haddr_t *addr, const void *_lt_key, void *_udata, const void *_rt_key) { H5G_bt_ud1_t *bt_udata = (H5G_bt_ud1_t *) _udata; H5G_node_t *sn = NULL; intn lt = 0, idx = 0, rt, cmp = 1; const char *s; herr_t ret_value = FAIL; FUNC_ENTER(H5G_node_found, FAIL); /* * Check arguments. */ assert(f); assert(addr && H5F_addr_defined(addr)); assert(bt_udata); /* * Load the symbol table node for exclusive access. */ if (NULL == (sn = H5AC_protect(f, H5AC_SNODE, addr, NULL, NULL))) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, FAIL, "unable to protect symbol table node"); } /* * Binary search. */ rt = sn->nsyms; while (lt < rt && cmp) { idx = (lt + rt) / 2; if (NULL == (s = H5H_peek(f, &(bt_udata->heap_addr), sn->entry[idx].name_off))) { HGOTO_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "unable to read symbol name"); } cmp = HDstrcmp(bt_udata->name, s); if (cmp < 0) { rt = idx; } else { lt = idx + 1; } } if (cmp) HGOTO_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "not found"); switch (bt_udata->operation) { case H5G_OPER_FIND: /* * The caller is querying the symbol entry. Return just a pointer to * the entry. The pointer is valid until the next call to H5AC. */ bt_udata->ent = sn->entry[idx]; break; default: HRETURN_ERROR(H5E_SYM, H5E_UNSUPPORTED, FAIL, "internal erorr (unknown symbol find operation)"); break; } ret_value = SUCCEED; done: if (sn && H5AC_unprotect(f, H5AC_SNODE, addr, sn) < 0) { HRETURN_ERROR(H5E_SYM, H5E_PROTECT, FAIL, "unable to release symbol table node"); } FUNC_LEAVE(ret_value); } /*------------------------------------------------------------------------- * Function: H5G_node_insert * * Purpose: The B-tree insertion engine has found the symbol table node * which should receive the new symbol/address pair. This * function adds it to that node unless it already existed. * * If the node has no room for the symbol then the node is * split into two nodes. The original node contains the * low values and the new node contains the high values. * The new symbol table entry is added to either node as * appropriate. When a split occurs, this function will * write the maximum key of the low node to the MID buffer * and return the address of the new node. * * If the new key is larger than RIGHT then update RIGHT * with the new key. * * Return: Success: An insertion command for the caller, one of * the H5B_INS_* constants. The address of the * new node, if any, is returned through the * NEW_NODE argument. NEW_NODE might not be * initialized if the return value is * H5B_INS_NOOP. * * Failure: H5B_INS_ERROR, NEW_NODE might not be * initialized. * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 24 1997 * * Modifications: * *------------------------------------------------------------------------- */ static H5B_ins_t H5G_node_insert(H5F_t *f, const haddr_t *addr, void *_lt_key, hbool_t *lt_key_changed, void *_md_key, void *_udata, void *_rt_key, hbool_t *rt_key_changed, haddr_t *new_node) { H5G_node_key_t *md_key = (H5G_node_key_t *) _md_key; H5G_node_key_t *rt_key = (H5G_node_key_t *) _rt_key; H5G_bt_ud1_t *bt_udata = (H5G_bt_ud1_t *) _udata; H5G_node_t *sn = NULL, *snrt = NULL; size_t offset; /*offset of name in heap */ const char *s; intn idx = -1, cmp = 1; intn lt = 0, rt; /*binary search cntrs */ H5B_ins_t ret_value = H5B_INS_ERROR; H5G_node_t *insert_into = NULL; /*node that gets new entry*/ haddr_t insert_addr; /*address of that node */ FUNC_ENTER(H5G_node_insert, H5B_INS_ERROR); /* * Check arguments. */ assert(f); assert(addr && H5F_addr_defined(addr)); assert(md_key); assert(rt_key); assert(bt_udata); assert(new_node); /* * Load the symbol node. */ if (NULL == (sn = H5AC_protect(f, H5AC_SNODE, addr, NULL, NULL))) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, H5B_INS_ERROR, "unable to protect symbol table node"); } /* * Where does the new symbol get inserted? We use a binary search. */ rt = sn->nsyms; while (lt < rt) { idx = (lt + rt) / 2; if (NULL == (s = H5H_peek(f, &(bt_udata->heap_addr), sn->entry[idx].name_off))) { HGOTO_ERROR(H5E_SYM, H5E_NOTFOUND, H5B_INS_ERROR, "unable to read symbol name"); } if (0 == (cmp = HDstrcmp(bt_udata->name, s))) { /*already present */ HGOTO_ERROR(H5E_SYM, H5E_CANTINSERT, H5B_INS_ERROR, "symbol is already present in symbol table"); } if (cmp < 0) { rt = idx; } else { lt = idx + 1; } } idx += cmp > 0 ? 1 : 0; /* * Add the new name to the heap. */ offset = H5H_insert(f, &(bt_udata->heap_addr), HDstrlen(bt_udata->name)+1, bt_udata->name); bt_udata->ent.name_off = offset; if (0==offset || (size_t)(-1)==offset) { HGOTO_ERROR(H5E_SYM, H5E_CANTINSERT, H5B_INS_ERROR, "unable to insert symbol name into heap"); } if (sn->nsyms >= 2 * H5G_NODE_K(f)) { /* * The node is full. Split it into a left and right * node and return the address of the new right node (the * left node is at the same address as the original node). */ ret_value = H5B_INS_RIGHT; /* The right node */ if (H5G_node_create(f, H5B_INS_FIRST, NULL, NULL, NULL, new_node /*out */ ) < 0) { HGOTO_ERROR(H5E_SYM, H5E_CANTINIT, H5B_INS_ERROR, "unable to split symbol table node"); } if (NULL == (snrt = H5AC_find(f, H5AC_SNODE, new_node, NULL, NULL))) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, H5B_INS_ERROR, "unable to split symbol table node"); } HDmemcpy(snrt->entry, sn->entry + H5G_NODE_K(f), H5G_NODE_K(f) * sizeof(H5G_entry_t)); snrt->nsyms = H5G_NODE_K(f); snrt->dirty = TRUE; /* The left node */ HDmemset(sn->entry + H5G_NODE_K(f), 0, H5G_NODE_K(f) * sizeof(H5G_entry_t)); sn->nsyms = H5G_NODE_K(f); sn->dirty = TRUE; /* The middle key */ md_key->offset = sn->entry[sn->nsyms - 1].name_off; /* Where to insert the new entry? */ if (idx <= H5G_NODE_K(f)) { insert_into = sn; insert_addr = *addr; if (idx == H5G_NODE_K(f)) md_key->offset = offset; } else { idx -= H5G_NODE_K(f); insert_into = snrt; insert_addr = *new_node; } } else { /* Where to insert the new entry? */ ret_value = H5B_INS_NOOP; sn->dirty = TRUE; insert_into = sn; insert_addr = *addr; if (idx == sn->nsyms) { rt_key->offset = offset; *rt_key_changed = TRUE; } } /* Move entries */ HDmemmove(insert_into->entry + idx + 1, insert_into->entry + idx, (insert_into->nsyms - idx) * sizeof(H5G_entry_t)); insert_into->entry[idx] = bt_udata->ent; insert_into->entry[idx].dirty = TRUE; insert_into->nsyms += 1; done: if (sn && H5AC_unprotect(f, H5AC_SNODE, addr, sn) < 0) { HRETURN_ERROR(H5E_SYM, H5E_PROTECT, H5B_INS_ERROR, "unable to release symbol table node"); } FUNC_LEAVE(ret_value); } /*------------------------------------------------------------------------- * Function: H5G_node_list * * Purpose: This function gets called during a group list operation. * It should fill in data in the UDATA struct. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Jun 24 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5G_node_list(H5F_t *f, const haddr_t *addr, void *_udata) { H5G_bt_ud2_t *bt_udata = (H5G_bt_ud2_t *) _udata; H5G_node_t *sn = NULL; intn i; const char *s; herr_t ret_value = FAIL; FUNC_ENTER(H5G_node_list, FAIL); /* * Check arguments. */ assert(f); assert(addr && H5F_addr_defined(addr)); assert(bt_udata); if (NULL == (sn = H5AC_protect(f, H5AC_SNODE, addr, NULL, NULL))) { HGOTO_ERROR(H5E_SYM, H5E_CANTLOAD, FAIL, "unable to protect symbol table node"); } /* * If we've already overflowed the user-supplied buffer, then just * keep track of how many names we've seen and don't bother doing * anything else. */ if (bt_udata->nsyms >= bt_udata->maxentries) { bt_udata->nsyms += sn->nsyms; HGOTO_DONE(SUCCEED); } /* * Save the symbol table entries. */ if (bt_udata->entry) { for (i = 0; i < sn->nsyms && bt_udata->nsyms + i < bt_udata->maxentries; i++) { bt_udata->entry[bt_udata->nsyms + i] = sn->entry[i]; } } if (bt_udata->name) { for (i = 0; i < sn->nsyms && bt_udata->nsyms + i < bt_udata->maxentries; i++) { if (NULL == (s = H5H_peek(f, &(bt_udata->heap_addr), sn->entry[i].name_off))) { HGOTO_ERROR(H5E_SYM, H5E_NOTFOUND, FAIL, "unable to read symbol name"); } bt_udata->name[bt_udata->nsyms + i] = H5MM_xstrdup(s); } } /* * Update the number of symbols. */ bt_udata->nsyms += sn->nsyms; ret_value = SUCCEED; done: if (sn && H5AC_unprotect(f, H5AC_SNODE, addr, sn) < 0) { HRETURN_ERROR(H5E_CACHE, H5E_PROTECT, FAIL, "unable to release symbol table node"); } FUNC_LEAVE(ret_value); } /*------------------------------------------------------------------------- * Function: H5G_node_debug * * Purpose: Prints debugging information about a symbol table node * or a B-tree node for a symbol table B-tree. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 4 1997 * * Modifications: * *------------------------------------------------------------------------- */ herr_t H5G_node_debug(H5F_t *f, const haddr_t *addr, FILE * stream, intn indent, intn fwidth, const haddr_t *heap) { int i; H5G_node_t *sn = NULL; herr_t status; const char *s; FUNC_ENTER(H5G_node_debug, FAIL); /* * Check arguments. */ assert(f); assert(addr && H5F_addr_defined(addr)); assert(stream); assert(indent >= 0); assert(fwidth >= 0); /* * If we couldn't load the symbol table node, then try loading the * B-tree node. */ if (NULL == (sn = H5AC_protect(f, H5AC_SNODE, addr, NULL, NULL))) { H5ECLEAR; /*discard that error */ status = H5B_debug(f, addr, stream, indent, fwidth, H5B_SNODE, NULL); if (status < 0) { HRETURN_ERROR(H5E_SYM, H5E_CANTLOAD, FAIL, "unable to debug B-tree node"); } HRETURN(SUCCEED); } fprintf(stream, "%*sSymbol Table Node...\n", indent, ""); fprintf(stream, "%*s%-*s %s\n", indent, "", fwidth, "Dirty:", sn->dirty ? "Yes" : "No"); fprintf(stream, "%*s%-*s %d of %d\n", indent, "", fwidth, "Number of Symbols:", sn->nsyms, 2 * H5G_NODE_K(f)); indent += 3; fwidth = MAX(0, fwidth - 3); for (i = 0; i < sn->nsyms; i++) { fprintf(stream, "%*sSymbol %d:\n", indent - 3, "", i); if (H5F_addr_defined(heap) && (s = H5H_peek(f, heap, sn->entry[i].name_off))) { fprintf(stream, "%*s%-*s `%s'\n", indent, "", fwidth, "Name:", s); } H5G_ent_debug(f, sn->entry + i, stream, indent, fwidth); } H5AC_unprotect(f, H5AC_SNODE, addr, sn); FUNC_LEAVE(SUCCEED); }