/*------------------------------------------------------------------------- * Copyright (C) 1997 National Center for Supercomputing Applications. * All rights reserved. * *------------------------------------------------------------------------- * * Created: H5O.c * Aug 5 1997 * Robb Matzke * * Purpose: Object header virtual functions. * * Modifications: * *------------------------------------------------------------------------- */ #include #include #include #include #include #include #include #define PABLO_MASK H5O_mask /* PRIVATE PROTOTYPES */ static herr_t H5O_flush (H5F_t *f, hbool_t destroy, haddr_t addr, H5O_t *oh); static H5O_t *H5O_load (H5F_t *f, haddr_t addr, void *_udata1, void *_udata2); static intn H5O_find_in_ohdr (H5F_t *f, haddr_t addr, const H5O_class_t **type_p, intn sequence); static intn H5O_alloc (H5F_t *f, H5O_t *oh, const H5O_class_t *type, size_t size); static intn H5O_alloc_extend_chunk (H5O_t *oh, intn chunkno, size_t size); static intn H5O_alloc_new_chunk (H5F_t *f, H5O_t *oh, size_t size); /* H5O inherits cache-like properties from H5AC */ static const H5AC_class_t H5AC_OHDR[1] = {{ (void*(*)(H5F_t*,haddr_t,void*,void*))H5O_load, (herr_t(*)(H5F_t*,hbool_t,haddr_t,void*))H5O_flush, }}; /* Is the interface initialized? */ static intn interface_initialize_g = FALSE; /* ID to type mapping */ static const H5O_class_t *const message_type_g[] = { H5O_NULL, /*0x0000 Null */ H5O_SIM_DIM, /*0x0001 Simple dimensionality */ NULL, /*0x0002 Data space (fiber bundle?) */ H5O_SIM_DTYPE, /*0x0003 Simple data type */ NULL, /*0x0004 Compound data type */ H5O_STD_STORE, /*0x0005 Data storage -- standard object */ NULL, /*0x0006 Data storage -- compact object */ NULL, /*0x0007 Data storage -- external object */ H5O_ISTORE, /*0x0008 Data storage -- indexed object */ NULL, /*0x0009 Not assigned */ NULL, /*0x000A Not assigned */ NULL, /*0x000B Data storage -- compressed object */ NULL, /*0x000C Attribute list */ H5O_NAME, /*0x000D Object name */ NULL, /*0x000E Object modification date and time */ NULL, /*0x000F Shared header message */ H5O_CONT, /*0x0010 Object header continuation */ H5O_STAB, /*0x0011 Symbol table */ }; /*------------------------------------------------------------------------- * Function: H5O_new * * Purpose: Creates a new object header, sets the link count * to NLINK, and caches the header. * * Return: Success: Address of new header. * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 5 1997 * * Modifications: * *------------------------------------------------------------------------- */ haddr_t H5O_new (H5F_t *f, intn nlink, size_t size_hint) { size_t size; /*total size of object header */ haddr_t addr = FAIL; /*address of object header */ H5O_t *oh = NULL; FUNC_ENTER (H5O_new, NULL, FAIL); /* check args */ assert (f); assert (nlink>=0); if (size_hintdirty = TRUE; oh->version = H5O_VERSION; oh->alignment = H5O_ALIGNMENT; oh->nlink = nlink; /* create the chunk list and initialize the first chunk */ oh->nchunks = 1; oh->alloc_nchunks = H5O_NCHUNKS; oh->chunk = H5MM_xmalloc (oh->alloc_nchunks * sizeof (H5O_chunk_t)); oh->chunk[0].dirty = TRUE; oh->chunk[0].addr = addr + H5O_SIZEOF_HDR(f); oh->chunk[0].size = size_hint; oh->chunk[0].image = H5MM_xcalloc (1, size_hint); /* create the message list and initialize the first message */ oh->nmesgs = 1; oh->alloc_nmesgs = H5O_NMESGS; oh->mesg = H5MM_xcalloc (oh->alloc_nmesgs, sizeof(H5O_mesg_t)); oh->mesg[0].type = H5O_NULL; oh->mesg[0].dirty = TRUE; oh->mesg[0].native = NULL; oh->mesg[0].raw = oh->chunk[0].image + 4; /*skip id and size fields */ oh->mesg[0].raw_size = size_hint - 4; oh->mesg[0].chunkno = 0; /* cache it */ if (H5AC_set (f, H5AC_OHDR, addr, oh)<0) { H5MM_xfree (oh); HRETURN_ERROR (H5E_OHDR, H5E_CANTINIT, FAIL); } FUNC_LEAVE (addr); } /*------------------------------------------------------------------------- * Function: H5O_load * * Purpose: Loads an object header from disk. * * Return: Success: Pointer to the new object header. * * Failure: NULL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 5 1997 * * Modifications: * * Robb Matzke, 30 Aug 1997 * Plugged memory leaks that occur during error handling. * *------------------------------------------------------------------------- */ static H5O_t * H5O_load (H5F_t *f, haddr_t addr, void *_udata1, void *_udata2) { H5O_t *oh = NULL; H5O_t *ret_value = (void*)1; /*kludge for HGOTO_ERROR*/ uint8 buf[16], *p; size_t hdr_size, mesg_size; uintn id; intn mesgno, chunkno, curmesg=0, nmesgs; haddr_t chunk_addr; size_t chunk_size; H5O_cont_t *cont=NULL; FUNC_ENTER (H5O_load, NULL, NULL); /* check args */ assert (f); assert (addr>=0); assert (!_udata1); assert (!_udata2); /* allocate ohdr and init chunk list */ oh = H5MM_xcalloc (1, sizeof(H5O_t)); /* read fixed-lenth part of object header */ hdr_size = H5O_SIZEOF_HDR (f); if (H5F_block_read (f, addr, hdr_size, buf)<0) { HGOTO_ERROR (H5E_OHDR, H5E_READERROR, NULL); } p = buf; /* decode version */ oh->version = *p++; if (H5O_VERSION!=oh->version) { HGOTO_ERROR (H5E_OHDR, H5E_VERSION, NULL); } /* decode alignment */ oh->alignment = *p++; if (4!=oh->alignment) { HGOTO_ERROR (H5E_OHDR, H5E_ALIGNMENT, NULL); } /* decode number of messages */ UINT16DECODE (p, nmesgs); /* decode link count */ UINT32DECODE (p, oh->nlink); /* decode first chunk info */ chunk_addr = addr + H5O_SIZEOF_HDR(f); UINT32DECODE (p, chunk_size); /* build the message array */ oh->alloc_nmesgs = MAX (H5O_NMESGS, nmesgs); oh->mesg = H5MM_xcalloc (oh->alloc_nmesgs, sizeof(H5O_mesg_t)); /* read each chunk from disk */ while (chunk_addr) { /* increase chunk array size */ if (oh->nchunks>=oh->alloc_nchunks) { oh->alloc_nchunks += H5O_NCHUNKS; oh->chunk = H5MM_xrealloc (oh->chunk, oh->alloc_nchunks * sizeof(H5O_chunk_t)); } /* read the chunk raw data */ chunkno = oh->nchunks++; oh->chunk[chunkno].dirty = FALSE; oh->chunk[chunkno].addr = chunk_addr; oh->chunk[chunkno].size = chunk_size; oh->chunk[chunkno].image = H5MM_xmalloc (chunk_size); if (H5F_block_read (f, chunk_addr, chunk_size, oh->chunk[chunkno].image)<0) { HGOTO_ERROR (H5E_OHDR, H5E_READERROR, NULL); } /* load messages from this chunk */ for (p = oh->chunk[chunkno].image; p < oh->chunk[chunkno].image + chunk_size; p += mesg_size) { UINT16DECODE (p, id); UINT16DECODE (p, mesg_size); if (id>=NELMTS(message_type_g) || NULL==message_type_g[id]) { HGOTO_ERROR (H5E_OHDR, H5E_BADMESG, NULL); } if (p + mesg_size > oh->chunk[chunkno].image + chunk_size) { HGOTO_ERROR (H5E_OHDR, H5E_CANTINIT, NULL); } if (H5O_NULL_ID==id && oh->nmesgs>0 && H5O_NULL_ID==oh->mesg[oh->nmesgs-1].type->id && oh->mesg[oh->nmesgs-1].chunkno==chunkno) { /* combine adjacent null messages */ mesgno = oh->nmesgs - 1; oh->mesg[mesgno].raw_size += 4 + mesg_size; } else { /* new message */ if (oh->nmesgs>=nmesgs) { HGOTO_ERROR (H5E_OHDR, H5E_CANTLOAD, NULL); } mesgno = oh->nmesgs++; oh->mesg[mesgno].type = message_type_g[id]; oh->mesg[mesgno].dirty = FALSE; oh->mesg[mesgno].native = NULL; oh->mesg[mesgno].raw = p; oh->mesg[mesgno].raw_size = mesg_size; oh->mesg[mesgno].chunkno = chunkno; } } assert (p == oh->chunk[chunkno].image + chunk_size); /* decode next object header continuation message */ for (chunk_addr=0; 0==chunk_addr && curmesgnmesgs; curmesg++) { if (H5O_CONT_ID==oh->mesg[curmesg].type->id) { uint8 *p2 = oh->mesg[curmesg].raw; cont = (H5O_CONT->decode)(f, oh->mesg[curmesg].raw_size, p2); oh->mesg[curmesg].native = cont; chunk_addr = cont->addr; chunk_size = cont->size; cont->chunkno = oh->nchunks; /*the next chunk to allocate*/ } } } done: if (!ret_value && oh) { /* * Free resources. */ int i; for (i=0; inchunks; i++) { oh->chunk[i].image = H5MM_xfree (oh->chunk[i].image); } oh->chunk = H5MM_xfree (oh->chunk); oh->mesg = H5MM_xfree (oh->mesg); oh = H5MM_xfree (oh); } FUNC_LEAVE (oh); } /*------------------------------------------------------------------------- * Function: H5O_flush * * Purpose: Flushes (and destroys) an object header. * * Return: Success: SUCCESS * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 5 1997 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5O_flush (H5F_t *f, hbool_t destroy, haddr_t addr, H5O_t *oh) { uint8 buf[16], *p; int i; H5O_cont_t *cont = NULL; FUNC_ENTER (H5O_flush, NULL, FAIL); /* check args */ assert (f); assert (addr>=0); assert (oh); /* flush */ if (oh->dirty) { p = buf; /* encode version */ *p++ = oh->version; /* encode alingment */ *p++ = oh->alignment; /* encode number of messages */ UINT16ENCODE (p, oh->nmesgs); /* encode link count */ UINT32ENCODE (p, oh->nlink); /* encode body size */ UINT32ENCODE (p, oh->chunk[0].size); /* write the object header header */ if (H5F_block_write (f, addr, H5O_SIZEOF_HDR(f), buf)<0) { HRETURN_ERROR (H5E_OHDR, H5E_WRITEERROR, FAIL); } /* encode messages */ for (i=0; inmesgs; i++) { if (oh->mesg[i].dirty) { p = oh->mesg[i].raw - 4; UINT16ENCODE (p, oh->mesg[i].type->id); UINT16ENCODE (p, oh->mesg[i].raw_size); if (oh->mesg[i].native) { assert (oh->mesg[i].type->encode); /* allocate file space for chunks that have none yet */ if (H5O_CONT_ID==oh->mesg[i].type->id && ((H5O_cont_t*)(oh->mesg[i].native))->addr<0) { cont = (H5O_cont_t*)(oh->mesg[i].native); assert (cont->chunkno >= 0); assert (cont->chunkno < oh->nchunks); assert (oh->chunk[cont->chunkno].addr<0); cont->size = oh->chunk[cont->chunkno].size; cont->addr = H5MF_alloc (f, cont->size); if (cont->addr<0) { HRETURN_ERROR (H5E_RESOURCE, H5E_NOSPACE, FAIL); } oh->chunk[cont->chunkno].addr = cont->addr; } /* encode the message */ assert (oh->mesg[i].raw >= oh->chunk[oh->mesg[i].chunkno].image); assert (oh->mesg[i].raw + oh->mesg[i].raw_size <= oh->chunk[oh->mesg[i].chunkno].image + oh->chunk[oh->mesg[i].chunkno].size); if ((oh->mesg[i].type->encode)(f, oh->mesg[i].raw_size, oh->mesg[i].raw, oh->mesg[i].native)<0) { HRETURN_ERROR (H5E_OHDR, H5E_CANTENCODE, FAIL); } } oh->mesg[i].dirty = FALSE; oh->chunk[oh->mesg[i].chunkno].dirty = TRUE; } } /* write each chunk to disk */ for (i=0; inchunks; i++) { if (oh->chunk[i].dirty) { assert (oh->chunk[i].addr>0); if (H5F_block_write (f, oh->chunk[i].addr, oh->chunk[i].size, oh->chunk[i].image)<0) { HRETURN_ERROR (H5E_OHDR, H5E_WRITEERROR, FAIL); } oh->chunk[i].dirty = FALSE; } } oh->dirty = FALSE; } if (destroy) { /* destroy chunks */ for (i=0; inchunks; i++) { oh->chunk[i].image = H5MM_xfree (oh->chunk[i].image); } oh->chunk = H5MM_xfree (oh->chunk); /* destroy messages */ for (i=0; inmesgs; i++) { H5O_reset (oh->mesg[i].type, oh->mesg[i].native); oh->mesg[i].native = H5MM_xfree (oh->mesg[i].native); } oh->mesg = H5MM_xfree (oh->mesg); /* destroy object header */ H5MM_xfree (oh); } FUNC_LEAVE (SUCCEED); } /*------------------------------------------------------------------------- * Function: H5O_reset * * Purpose: Some message data structures have internal fields that * need to be freed. This function does that if appropriate * but doesn't free NATIVE. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 12 1997 * * Modifications: * *------------------------------------------------------------------------- */ herr_t H5O_reset (const H5O_class_t *type, void *native) { FUNC_ENTER (H5O_reset, NULL, FAIL); if (native) { if (type->reset) { if ((type->reset)(native)<0) { /* reset class method failed */ HRETURN_ERROR (H5E_OHDR, H5E_CANTINIT, FAIL); } } else { HDmemset (native, 0, type->native_size); } } FUNC_LEAVE (SUCCEED); } /*------------------------------------------------------------------------- * Function: H5O_link * * Purpose: Adjust the link count for an object header by adding * ADJUST to the link count. * * Return: Success: New link count * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 5 1997 * * Modifications: * *------------------------------------------------------------------------- */ intn H5O_link (H5F_t *f, H5G_entry_t *ent, intn adjust) { H5O_t *oh = NULL; haddr_t addr; FUNC_ENTER (H5O_link, NULL, FAIL); /* check args */ assert (f); assert (ent && H5G_ent_addr (ent)>0); addr = H5G_ent_addr (ent); /* get header */ if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, FAIL); } /* adjust link count */ if (adjust<0) { if (oh->nlink + adjust < 0) { HRETURN_ERROR (H5E_OHDR, H5E_LINKCOUNT, FAIL); } oh->nlink += adjust; if (1==oh->nlink && ent) { fprintf (stderr, "H5O_link: no symbol table entry caching " "(not implemented yet)\n"); } } else { oh->nlink += adjust; if (oh->nlink>1) H5G_ent_invalidate (ent); } oh->dirty = TRUE; FUNC_LEAVE (oh->nlink); } /*------------------------------------------------------------------------- * Function: H5O_read * * Purpose: Reads a message from an object header and returns a pointer * to it. The caller will usually supply the memory through * MESG and the return value will be MESG. But if MESG is * the null pointer, then this function will malloc() memory * to hold the result and return its pointer instead. * * Return: Success: Ptr to message in native format. * * Failure: NULL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 6 1997 * * Modifications: * *------------------------------------------------------------------------- */ void * H5O_read (H5F_t *f, haddr_t addr, H5G_entry_t *ent, const H5O_class_t *type, intn sequence, void *mesg) { H5O_t *oh = NULL; void *retval = NULL; intn idx; H5G_cache_t *cache = NULL; H5G_type_t cache_type; FUNC_ENTER (H5O_read, NULL, NULL); /* check args */ assert (f); if (addr<=0 && !ent) { HRETURN_ERROR (H5E_OHDR, H5E_NOTFOUND, NULL); } if (addr<=0 && (addr=H5G_ent_addr (ent))<=0) { HRETURN_ERROR (H5E_OHDR, H5E_NOTFOUND, NULL); } assert (sequence>=0); /* can we get it from the symbol table? */ if (ent) { cache = H5G_ent_cache (ent, &cache_type); if (type && cache_type==type->cache_type && type->fast) { retval = (type->fast)(cache, mesg); if (retval) HRETURN (retval); H5ECLEAR; } } /* can we get it from the object header? */ if ((idx = H5O_find_in_ohdr (f, addr, &type, sequence))<0) { HRETURN_ERROR (H5E_OHDR, H5E_NOTFOUND, NULL); } #ifdef LATER /* should we cache it in ENT? */ #endif /* copy the message to the user-supplied buffer */ if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, NULL); } retval = (type->copy)(oh->mesg[idx].native, mesg); if (!retval) HRETURN_ERROR (H5E_OHDR, H5E_CANTINIT, NULL); FUNC_LEAVE (retval); } /*------------------------------------------------------------------------- * Function: H5O_find_in_ohdr * * Purpose: Find a message in the object header without consulting * a symbol table entry. * * Return: Success: Index number of message. * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 6 1997 * * Modifications: * *------------------------------------------------------------------------- */ static intn H5O_find_in_ohdr (H5F_t *f, haddr_t addr, const H5O_class_t **type_p, intn sequence) { H5O_t *oh = NULL; int i; FUNC_ENTER (H5O_find_in_ohdr, NULL, FAIL); /* check args */ assert (f); assert (addr>=0); assert (type_p); /* load the object header */ if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, FAIL); } /* scan through the messages looking for the right one */ for (i=0; inmesgs; i++) { if (*type_p && (*type_p)->id!=oh->mesg[i].type->id) continue; if (--sequence<0) break; } if (sequence>=0) HRETURN_ERROR (H5E_OHDR, H5E_NOTFOUND, FAIL); /* decode the message if necessary */ if (NULL==oh->mesg[i].native) { assert (oh->mesg[i].type->decode); oh->mesg[i].native = (oh->mesg[i].type->decode)(f, oh->mesg[i].raw_size, oh->mesg[i].raw); if (NULL==oh->mesg[i].native) { HRETURN_ERROR (H5E_OHDR, H5E_CANTDECODE, FAIL); } } /*return the message type */ *type_p = oh->mesg[i].type; FUNC_LEAVE (i); } /*------------------------------------------------------------------------- * Function: H5O_peek * * Purpose: Returns a pointer to a message stored in native format. * The returned memory is read-only, and points directly into * the cache. It is therefore valid only until the next cache * function is called. * * Return: Success: Ptr to read-only message in native format. * The pointer is guranteed to be valid only * until the next call (directly or indirectly) * to an H5AC function. * * Failure: NULL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 6 1997 * * Modifications: * *------------------------------------------------------------------------- */ const void * H5O_peek (H5F_t *f, haddr_t addr, const H5O_class_t *type, intn sequence) { intn idx; H5O_t *oh = NULL; FUNC_ENTER (H5O_peek, NULL, NULL); /* check args */ assert (f); assert (addr>0); if ((idx = H5O_find_in_ohdr (f, addr, &type, sequence))<0) { HRETURN_ERROR (H5E_OHDR, H5E_NOTFOUND, NULL); } if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, NULL); } FUNC_LEAVE (oh->mesg[idx].native); } /*------------------------------------------------------------------------- * Function: H5O_modify * * Purpose: Modifies an existing message or creates a new message. * The object header is at file address ADDR of file F (but if * ENT is present then its `header' field is used instead). An * optional symbol table entry ENT can be supplied in which * case the cache fields in that symbol table are updated if * appropriate. * * The OVERWRITE argument is either a sequence number of a * message to overwrite (usually zero) or the constant * H5O_NEW_MESSAGE (-1) to indicate that a new message is to * be created. If the message to overwrite doesn't exist then * it is created (but only if it can be inserted so its sequence * number is OVERWRITE; that is, you can create a message with * the sequence number 5 if there is no message with sequence * number 4). * * Return: Success: The sequence number of the message that * was modified or created. * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 6 1997 * * Modifications: * *------------------------------------------------------------------------- */ intn H5O_modify (H5F_t *f, haddr_t addr, H5G_entry_t *ent, const H5O_class_t *type, intn overwrite, const void *mesg) { H5O_t *oh = NULL; intn idx, sequence; size_t size; FUNC_ENTER (H5O_modify, NULL, FAIL); /* check args */ assert (f); assert (addr>0 || (ent && H5G_ent_addr (ent)>0)); assert (type); assert (mesg); if (addr<=0) addr = H5G_ent_addr (ent); if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, FAIL); } /* Count similar messages */ for (idx=0,sequence=-1; idxnmesgs; idx++) { if (type->id != oh->mesg[idx].type->id) continue; if (++sequence==overwrite) break; } /* Was the right message found? */ if (overwrite>=0 && (idx>=oh->nmesgs || sequence!=overwrite)) { /* But can we insert a new one with this sequence number? */ if (overwrite==sequence+1) { overwrite = -1; } else { HRETURN_ERROR (H5E_OHDR, H5E_NOTFOUND, FAIL); /*message not found*/ } } /* Allocate space for the new message */ if (overwrite<0) { size = (type->raw_size)(f, mesg); H5O_ALIGN (size, oh->alignment); idx = H5O_alloc (f, oh, type, size); if (idx<0) HRETURN_ERROR (H5E_OHDR, H5E_CANTINIT, FAIL); sequence++; } /* Copy the native value into the object header */ oh->mesg[idx].native = (type->copy)(mesg, oh->mesg[idx].native); if (NULL==oh->mesg[idx].native) { HRETURN_ERROR (H5E_OHDR, H5E_CANTINIT, FAIL); } oh->mesg[idx].dirty = TRUE; oh->dirty = TRUE; /* Copy into the symbol table entry */ if (oh->nlink<=1 && ent && type->cache) { H5G_type_t cache_type; H5G_cache_t *cache = H5G_ent_cache (ent, &cache_type); hbool_t modified = (type->cache)(&cache_type, cache, mesg); if (modified) H5G_ent_modified (ent, cache_type); } FUNC_LEAVE (sequence); } /*------------------------------------------------------------------------- * Function: H5O_remove * * Purpose: Removes the specified message from the object header. * If sequence is H5O_ALL (-1) then all messages of the * specified type are removed. Removing a message causes * the sequence numbers to change for subsequent messages of * the same type. * * If the messaage was cached in the symbol table entry then * the type field of the symbol table entry is changed to * H5G_NOTHING_CACHED and the ENT_MODIFIED argument will point * to non-zero (the ENT_MODIFIED argument is unchanged if * the ENT type field doesn't change). * * No attempt is made to join adjacent free areas of the * object header into a single larger free area. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 28 1997 * * Modifications: * *------------------------------------------------------------------------- */ herr_t H5O_remove (H5F_t *f, haddr_t addr, H5G_entry_t *ent, const H5O_class_t *type, intn sequence) { H5O_t *oh = NULL; intn i, seq; FUNC_ENTER (H5O_remove, NULL, FAIL); /* check args */ assert (f); assert (addr>0 || (ent && H5G_ent_addr (ent)>0)); assert (type); if (addr<=0) addr = H5G_ent_addr (ent); /* load the object header */ if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, FAIL); } for (i=seq=0; inmesgs; i++) { if (type->id != oh->mesg[i].type->id) continue; if (seq++ == sequence || H5O_ALL==sequence) { H5G_type_t cache_type; H5G_ent_cache (ent, &cache_type); /* clear symbol table entry cache */ if (ent && type->cache && type->cache_type==cache_type) { H5G_ent_invalidate (ent); } /* change message type to nil and zero it */ oh->mesg[i].type = H5O_NULL; HDmemset (oh->mesg[i].raw, 0, oh->mesg[i].raw_size); H5O_reset (type, oh->mesg[i].native); oh->mesg[i].native = H5MM_xfree (oh->mesg[i].native); oh->mesg[i].dirty = TRUE; oh->dirty = TRUE; } } FUNC_LEAVE (SUCCEED); } /*------------------------------------------------------------------------- * Function: H5O_alloc_extend_chunk * * Purpose: Extends a chunk which hasn't been allocated on disk yet * to make the chunk large enough to contain a message whose * data size is at least SIZE bytes. * * If the last message of the chunk is the null message, then * that message will be extended with the chunk. Otherwise a * new null message is created. * * Return: Success: Message index for null message which * is large enough to hold SIZE bytes. * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 7 1997 * * Modifications: * *------------------------------------------------------------------------- */ static intn H5O_alloc_extend_chunk (H5O_t *oh, intn chunkno, size_t size) { intn idx, i; size_t delta; uint8 *old_addr; FUNC_ENTER (H5O_alloc_extend_chunk, NULL, FAIL); /* check args */ assert (oh); assert (chunkno>=0 && chunknonchunks); assert (size>0); if (H5O_NO_ADDR!=oh->chunk[chunkno].addr) { HRETURN_ERROR (H5E_OHDR, H5E_NOSPACE, FAIL); /*chunk is on disk*/ } /* try to extend a null message */ for (idx=0; idxnmesgs; idx++) { if (H5O_NULL_ID==oh->mesg[idx].type->id && (oh->mesg[idx].raw + oh->mesg[idx].raw_size == oh->chunk[chunkno].image + oh->chunk[chunkno].size)) { delta = MAX (H5O_MIN_SIZE, size-oh->mesg[idx].raw_size); H5O_ALIGN (delta, oh->alignment); oh->mesg[idx].dirty = TRUE; oh->mesg[idx].raw_size += delta; old_addr = oh->chunk[chunkno].image; /* Be careful not to indroduce garbage */ oh->chunk[chunkno].image = H5MM_xrealloc (old_addr, (oh->chunk[chunkno].size + delta)); HDmemset (oh->chunk[chunkno].image + oh->chunk[chunkno].size, 0, delta); oh->chunk[chunkno].size += delta; /* adjust raw addresses for messages of this chunk */ if (old_addr != oh->chunk[chunkno].image) { for (i=0; inmesgs; i++) { if (oh->mesg[i].chunkno==chunkno) { oh->mesg[i].raw = oh->chunk[chunkno].image + (oh->mesg[i].raw - old_addr); } } } HRETURN (idx); } } /* create a new null message */ if (oh->nmesgs >= oh->alloc_nmesgs) { oh->alloc_nmesgs += H5O_NMESGS; oh->mesg = H5MM_xrealloc (oh->mesg, oh->alloc_nmesgs * sizeof(H5O_mesg_t)); } delta = MAX (H5O_MIN_SIZE, 4+size); H5O_ALIGN (delta, oh->alignment); idx = oh->nmesgs++; oh->mesg[idx].type = H5O_NULL; oh->mesg[idx].dirty = TRUE; oh->mesg[idx].native = NULL; oh->mesg[idx].raw = oh->chunk[chunkno].image + oh->chunk[chunkno].size + 4; oh->mesg[idx].raw_size = delta-4; oh->mesg[idx].chunkno = chunkno; old_addr = oh->chunk[chunkno].image; oh->chunk[chunkno].size += delta; oh->chunk[chunkno].image = H5MM_xrealloc (old_addr, oh->chunk[chunkno].size); /* adjust raw addresses for messages of this chunk */ if (old_addr != oh->chunk[chunkno].image) { for (i=0; inmesgs; i++) { if (oh->mesg[i].chunkno==chunkno) { oh->mesg[i].raw = oh->chunk[chunkno].image + (oh->mesg[i].raw - old_addr); } } } FUNC_LEAVE (idx); } /*------------------------------------------------------------------------- * Function: H5O_alloc_new_chunk * * Purpose: Allocates a new chunk for the object header but doen't * give the new chunk a file address yet. One of the other * chunks will get an object continuation message. If there * isn't room in any other chunk for the object continuation * message, then some message from another chunk is moved into * this chunk to make room. * * Return: Success: Index number of the null message for the * new chunk. The null message will be at * least SIZE bytes not counting the message * ID or size fields. * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 7 1997 * * Modifications: * *------------------------------------------------------------------------- */ static intn H5O_alloc_new_chunk (H5F_t *f, H5O_t *oh, size_t size) { size_t cont_size; /*continuation message size */ intn found_null=(-1); /*best fit null message */ intn found_other=(-1); /*best fit other message */ intn idx=FAIL; /*message number return value */ uint8 *p = NULL; /*ptr into new chunk */ H5O_cont_t *cont = NULL; /*native continuation message */ intn i, chunkno; FUNC_ENTER (H5O_alloc_new_chunk, NULL, FAIL); /* check args */ assert (oh); assert (size>0); /* * Find the smallest null message that will hold an object * continuation message. Failing that, find the smallest message * that could be moved to make room for the continuation message. * Don't ever move continuation message from one chunk to another. */ cont_size = H5F_SIZEOF_OFFSET(f) + H5F_SIZEOF_SIZE(f); for (i=0; inmesgs; i++) { if (H5O_NULL_ID == oh->mesg[i].type->id) { if (cont_size == oh->mesg[i].raw_size) { found_null = i; break; } else if (oh->mesg[i].raw_size >= cont_size && (found_null<0 || oh->mesg[i].raw_size < oh->mesg[found_null].raw_size)) { found_null = i; } } else if (H5O_CONT_ID == oh->mesg[i].type->id) { /*don't consider continuation messages */ } else if (oh->mesg[i].raw_size >= cont_size && (found_other<0 || oh->mesg[i].raw_size < oh->mesg[found_other].raw_size)) { found_other = i; } } assert (found_null>=0 || found_other>=0); /* * If we must move some other message to make room for the null * message, then make sure the new chunk has enough room for that * other message. */ if (found_null<0) size += 4 + oh->mesg[found_other].raw_size; /* * The total chunk size must include the requested space plus enough * for the message header. This must be at least some minimum and a * multiple of the alignment size. */ size = MAX (H5O_MIN_SIZE, size+4); H5O_ALIGN (size, oh->alignment); /* * Create the new chunk without giving it a file address. */ if (oh->nchunks >= oh->alloc_nchunks) { oh->alloc_nchunks += H5O_NCHUNKS; oh->chunk = H5MM_xrealloc (oh->chunk, oh->alloc_nchunks * sizeof(H5O_chunk_t)); } chunkno = oh->nchunks++; oh->chunk[chunkno].dirty = TRUE; oh->chunk[chunkno].addr = H5O_NO_ADDR; oh->chunk[chunkno].size = size; oh->chunk[chunkno].image = p = H5MM_xcalloc (1, size); /* * Make sure we have enough space for all possible new messages * that could be generated below. */ if (oh->nmesgs+3 > oh->alloc_nmesgs) { oh->alloc_nmesgs += MAX (H5O_NMESGS, 3); oh->mesg = H5MM_xrealloc (oh->mesg, oh->alloc_nmesgs * sizeof(H5O_mesg_t)); } /* * Describe the messages of the new chunk. */ if (found_null<0) { found_null = i = oh->nmesgs++; oh->mesg[i].type = H5O_NULL; oh->mesg[i].dirty = TRUE; oh->mesg[i].native = NULL; oh->mesg[i].raw = oh->mesg[found_other].raw; oh->mesg[i].raw_size = oh->mesg[found_other].raw_size; oh->mesg[i].chunkno = oh->mesg[found_other].chunkno; oh->mesg[found_other].dirty = TRUE; oh->mesg[found_other].raw = p+4; oh->mesg[found_other].chunkno = chunkno; p += 4 + oh->mesg[found_other].raw_size; size -= 4 + oh->mesg[found_other].raw_size; } idx = oh->nmesgs++; oh->mesg[idx].type = H5O_NULL; oh->mesg[idx].dirty = TRUE; oh->mesg[idx].native = NULL; oh->mesg[idx].raw = p+4; oh->mesg[idx].raw_size = size-4; oh->mesg[idx].chunkno = chunkno; /* * If the null message that will receive the continuation message * is larger than the continuation message, then split it into * two null messages. */ if (oh->mesg[found_null].raw_size > cont_size) { i = oh->nmesgs++; oh->mesg[i].type = H5O_NULL; oh->mesg[i].dirty = TRUE; oh->mesg[i].native = NULL; oh->mesg[i].raw = oh->mesg[found_null].raw + cont_size + 4; oh->mesg[i].raw_size = oh->mesg[found_null].raw_size - (cont_size+4); oh->mesg[i].chunkno = oh->mesg[found_null].chunkno; oh->mesg[found_null].dirty = TRUE; oh->mesg[found_null].raw_size = cont_size; } /* * Initialize the continuation message. */ oh->mesg[found_null].type = H5O_CONT; oh->mesg[found_null].dirty = TRUE; cont = H5MM_xcalloc (1, sizeof(H5O_cont_t)); cont->addr = H5O_NO_ADDR; cont->size = 0; cont->chunkno = chunkno; oh->mesg[found_null].native = cont; FUNC_LEAVE (idx); } /*------------------------------------------------------------------------- * Function: H5O_alloc * * Purpose: Allocate enough space in the object header for this message. * * Return: Success: Index of message * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 6 1997 * * Modifications: * *------------------------------------------------------------------------- */ static intn H5O_alloc (H5F_t *f, H5O_t *oh, const H5O_class_t *type, size_t size) { intn chunkno; intn idx; intn null_idx; FUNC_ENTER (H5O_alloc, NULL, FAIL); /* check args */ assert (oh); assert (type); H5O_ALIGN (size, oh->alignment); /* look for a null message which is large enough */ for (idx=0; idxnmesgs; idx++) { if (H5O_NULL_ID==oh->mesg[idx].type->id && oh->mesg[idx].raw_size>=size) break; } #ifdef LATER /* * Perhaps if we join adjacent null messages we could make one * large enough... we leave this as an exercise for future * programmers :-) This isn't a high priority because when an * object header is read from disk the null messages are combined * anyway. */ #endif /* if we didn't find one, then allocate more header space */ if (idx>=oh->nmesgs) { /* * Look for a chunk which hasn't had disk space allocated yet * since we can just increase the size of that chunk. */ for (chunkno=0; chunknonchunks; chunkno++) { if ((idx=H5O_alloc_extend_chunk (oh, chunkno, size))>=0) break; H5ECLEAR; } /* * Create a new chunk */ if (idx<0) { if ((idx=H5O_alloc_new_chunk (f, oh, size))<0) { HRETURN_ERROR (H5E_OHDR, H5E_NOSPACE, FAIL); } } } /* do we need to split the null message? */ if (oh->mesg[idx].raw_size > size) { assert (oh->mesg[idx].raw_size - size >= 4); /*room for type & size */ if (oh->nmesgs >= oh->alloc_nmesgs) { oh->alloc_nmesgs += H5O_NMESGS; oh->mesg = H5MM_xrealloc (oh->mesg, oh->alloc_nmesgs * sizeof(H5O_mesg_t)); } null_idx = oh->nmesgs++; oh->mesg[null_idx].type = H5O_NULL; oh->mesg[null_idx].dirty = TRUE; oh->mesg[null_idx].native = NULL; oh->mesg[null_idx].raw = oh->mesg[idx].raw + size + 4; oh->mesg[null_idx].raw_size = oh->mesg[idx].raw_size - (size + 4); oh->mesg[null_idx].chunkno = oh->mesg[idx].chunkno; oh->mesg[idx].raw_size = size; } /* initialize the new message */ oh->mesg[idx].type = type; oh->mesg[idx].dirty = TRUE; oh->mesg[idx].native = NULL; oh->dirty = TRUE; FUNC_LEAVE (idx); } /*------------------------------------------------------------------------- * Function: H5O_debug * * Purpose: Prints debugging info about an object header. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: Robb Matzke * matzke@llnl.gov * Aug 6 1997 * * Modifications: * *------------------------------------------------------------------------- */ herr_t H5O_debug (H5F_t *f, haddr_t addr, FILE *stream, intn indent, intn fwidth) { H5O_t *oh = NULL; intn i, chunkno; size_t mesg_total=0, chunk_total=0; int *sequence; FUNC_ENTER (H5O_debug, NULL, FAIL); /* check args */ assert (f); assert (addr>=0); assert (stream); assert (indent>=0); assert (fwidth>=0); if (NULL==(oh=H5AC_find (f, H5AC_OHDR, addr, NULL, NULL))) { HRETURN_ERROR (H5E_OHDR, H5E_CANTLOAD, FAIL); } /* debug */ fprintf (stream, "%*sObject Header...\n", indent, ""); fprintf (stream, "%*s%-*s %d\n", indent, "", fwidth, "Dirty:", (int)(oh->dirty)); fprintf (stream, "%*s%-*s %d\n", indent, "", fwidth, "Version:", (int)(oh->version)); fprintf (stream, "%*s%-*s %d\n", indent, "", fwidth, "Alignment:", (int)(oh->alignment)); fprintf (stream, "%*s%-*s %d\n", indent, "", fwidth, "Number of links:", (int)(oh->nlink)); fprintf (stream, "%*s%-*s %d (%d)\n", indent, "", fwidth, "Number of messages (allocated):", (int)(oh->nmesgs), (int)(oh->alloc_nmesgs)); fprintf (stream, "%*s%-*s %d (%d)\n", indent, "", fwidth, "Number of chunks (allocated):", (int)(oh->nchunks), (int)(oh->alloc_nchunks)); /* debug each chunk */ for (i=chunk_total=0; inchunks; i++) { chunk_total += oh->chunk[i].size; fprintf (stream, "%*sChunk %d...\n", indent, "", i); fprintf (stream, "%*s%-*s %d\n", indent+3, "", MAX(0,fwidth-3), "Dirty:", (int)(oh->chunk[i].dirty)); fprintf (stream, "%*s%-*s %lu\n", indent+3, "", MAX(0,fwidth-3), "Address:", (unsigned long)(oh->chunk[i].addr)); if (0==i && oh->chunk[i].addr!=addr+H5O_SIZEOF_HDR(f)) { fprintf (stream, "*** WRONG ADDRESS!\n"); } fprintf (stream, "%*s%-*s %lu\n", indent+3, "", MAX(0,fwidth-3), "Size in bytes:", (unsigned long)(oh->chunk[i].size)); } /* debug each message */ sequence = H5MM_xcalloc (NELMTS(message_type_g), sizeof(int)); for (i=mesg_total=0; inmesgs; i++) { mesg_total += 4 + oh->mesg[i].raw_size; fprintf (stream, "%*sMessage %d...\n", indent, "", i); /* check for bad message id */ if (oh->mesg[i].type->id<0 || oh->mesg[i].type->id>=NELMTS(message_type_g)) { fprintf (stream, "*** BAD MESSAGE ID 0x%04x\n", oh->mesg[i].type->id); continue; } /* message name and size */ fprintf (stream, "%*s%-*s 0x%04x %s(%d)\n", indent+3, "", MAX (0, fwidth-3), "Message ID:", (unsigned)(oh->mesg[i].type->id), oh->mesg[i].type->name, sequence[oh->mesg[i].type->id]++); fprintf (stream, "%*s%-*s %lu\n", indent+3, "", MAX (0, fwidth-3), "Raw size in bytes:", (unsigned long)(oh->mesg[i].raw_size)); fprintf (stream, "%*s%-*s %d\n", indent+3, "", MAX(0,fwidth-3), "Chunk number:", (int)(oh->mesg[i].chunkno)); chunkno = oh->mesg[i].chunkno; if (chunkno<0 || chunkno>=oh->nchunks) { fprintf (stream, "*** BAD CHUNK NUMBER\n"); } /* check the size */ if ((oh->mesg[i].raw + oh->mesg[i].raw_size > oh->chunk[chunkno].image + oh->chunk[chunkno].size) || (oh->mesg[i].raw < oh->chunk[chunkno].image)) { fprintf (stream, "*** BAD MESSAGE RAW ADDRESS\n"); } /* decode the message */ if (NULL==oh->mesg[i].native && oh->mesg[i].type->decode) { oh->mesg[i].native = (oh->mesg[i].type->decode)(f, oh->mesg[i].raw_size, oh->mesg[i].raw); } /* print the message */ if (oh->mesg[i].type->debug) { (oh->mesg[i].type->debug)(f, oh->mesg[i].native, stream, indent+3, MAX(0, fwidth-3)); } else { fprintf (stream, "%*sNo info for this message.\n", indent+3, ""); } } sequence = H5MM_xfree (sequence); if (mesg_total != chunk_total) { fprintf (stream, "*** TOTAL SIZE DOES NOT MATCH ALLOCATED SIZE!\n"); } FUNC_LEAVE (SUCCEED); }