/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * Copyright by The HDF Group. * * 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://hdfgroup.org/HDF5/doc/Copyright.html. If you do not have * * access to either file, you may request a copy from help@hdfgroup.org. * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */ /*------------------------------------------------------------------------- * * Created: H5C.c * June 1 2004 * John Mainzer * * Purpose: Functions in this file implement a generic cache for * things which exist on disk, and which may be * unambiguously referenced by their disk addresses. * * The code in this module was initially written in * support of a complete re-write of the metadata cache * in H5AC.c However, other uses for the cache code * suggested themselves, and thus this file was created * in an attempt to support re-use. * * For a detailed overview of the cache, please see the * header comment for H5C_t in H5Cpkg.h. * *------------------------------------------------------------------------- */ /************************************************************************** * * To Do: * * Code Changes: * * - Remove extra functionality in H5C_flush_single_entry()? * * - Change protect/unprotect to lock/unlock. * * - Flush entries in increasing address order in * H5C_make_space_in_cache(). * * - Also in H5C_make_space_in_cache(), use high and low water marks * to reduce the number of I/O calls. * * - When flushing, attempt to combine contiguous entries to reduce * I/O overhead. Can't do this just yet as some entries are not * contiguous. Do this in parallel only or in serial as well? * * - Create MPI type for dirty objects when flushing in parallel. * * - Now that TBBT routines aren't used, fix nodes in memory to * point directly to the skip list node from the LRU list, eliminating * skip list lookups when evicting objects from the cache. * * Tests: * * - Trim execution time. (This is no longer a major issue with the * shift from the TBBT to a hash table for indexing.) * * - Add random tests. * **************************************************************************/ #define H5C_PACKAGE /*suppress error about including H5Cpkg */ #define H5F_PACKAGE /*suppress error about including H5Fpkg */ #include "H5private.h" /* Generic Functions */ #ifdef H5_HAVE_PARALLEL #include "H5ACprivate.h" /* Metadata cache */ #endif /* H5_HAVE_PARALLEL */ #include "H5Cpkg.h" /* Cache */ #include "H5Dprivate.h" /* Dataset functions */ #include "H5Eprivate.h" /* Error handling */ #include "H5Fpkg.h" /* Files */ #include "H5FDprivate.h" /* File drivers */ #include "H5FLprivate.h" /* Free Lists */ #include "H5Iprivate.h" /* IDs */ #include "H5MMprivate.h" /* Memory management */ #include "H5Pprivate.h" /* Property lists */ #include "H5SLprivate.h" /* Skip lists */ /* * Private file-scope variables. */ /* Declare a free list to manage the H5C_t struct */ H5FL_DEFINE_STATIC(H5C_t); /* Declare a free list to manage flush dependency arrays */ H5FL_BLK_DEFINE_STATIC(parent); /* * Private file-scope function declarations: */ static herr_t H5C__auto_adjust_cache_size(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, hbool_t write_permitted, hbool_t * first_flush_ptr); static herr_t H5C__autoadjust__ageout(H5F_t * f, double hit_rate, enum H5C_resize_status * status_ptr, size_t * new_max_cache_size_ptr, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, hbool_t write_permitted, hbool_t * first_flush_ptr); static herr_t H5C__autoadjust__ageout__cycle_epoch_marker(H5C_t * cache_ptr); static herr_t H5C__autoadjust__ageout__evict_aged_out_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, hbool_t write_permitted, hbool_t * first_flush_ptr); static herr_t H5C__autoadjust__ageout__insert_new_marker(H5C_t * cache_ptr); static herr_t H5C__autoadjust__ageout__remove_all_markers(H5C_t * cache_ptr); static herr_t H5C__autoadjust__ageout__remove_excess_markers(H5C_t * cache_ptr); static herr_t H5C__flash_increase_cache_size(H5C_t * cache_ptr, size_t old_entry_size, size_t new_entry_size); static herr_t H5C_flush_single_entry(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, const H5C_class_t * type_ptr, haddr_t addr, unsigned flags, hbool_t * first_flush_ptr, hbool_t del_entry_from_slist_on_destroy); static herr_t H5C_flush_invalidate_cache(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, unsigned flags); static void * H5C_load_entry(H5F_t * f, hid_t dxpl_id, const H5C_class_t * type, haddr_t addr, void * udata); static herr_t H5C_make_space_in_cache(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, size_t space_needed, hbool_t write_permitted, hbool_t * first_flush_ptr); static herr_t H5C_tag_entry(H5C_t * cache_ptr, H5C_cache_entry_t * entry_ptr, hid_t dxpl_id); static herr_t H5C_mark_tagged_entries(H5C_t * cache_ptr, haddr_t tag, hbool_t mark_clean); static herr_t H5C_flush_marked_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, H5C_t * cache_ptr); static herr_t H5C_evict_marked_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, H5C_t * cache_ptr); static herr_t H5C__mark_flush_dep_dirty(H5C_cache_entry_t * entry); static herr_t H5C__mark_flush_dep_clean(H5C_cache_entry_t * entry); #if H5C_DO_EXTREME_SANITY_CHECKS static herr_t H5C_validate_lru_list(H5C_t * cache_ptr); static herr_t H5C_verify_not_in_index(H5C_t * cache_ptr, H5C_cache_entry_t * entry_ptr); #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ #ifndef NDEBUG static void H5C__assert_flush_dep_nocycle(H5C_cache_entry_t * entry, H5C_cache_entry_t * base_entry); #endif /* NDEBUG */ /**************************************************************************** * * #defines and declarations for epoch marker cache entries. * * As a strategy for automatic cache size reduction, the cache may insert * marker entries in the LRU list at the end of each epoch. These markers * are then used to identify entries that have not been accessed for n * epochs so that they can be evicted from the cache. * ****************************************************************************/ /* Note that H5C__MAX_EPOCH_MARKERS is defined in H5Cpkg.h, not here because * it is needed to dimension arrays in H5C_t. */ #define H5C__EPOCH_MARKER_TYPE H5C__MAX_NUM_TYPE_IDS static void *H5C_epoch_marker_load(H5F_t *f, hid_t dxpl_id, haddr_t addr, void *udata); static herr_t H5C_epoch_marker_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest, haddr_t addr, void *thing, unsigned *flags_ptr); static herr_t H5C_epoch_marker_dest(H5F_t *f, void *thing); static herr_t H5C_epoch_marker_clear(H5F_t *f, void *thing, hbool_t dest); static herr_t H5C_epoch_marker_notify(H5C_notify_action_t action, void *thing); static herr_t H5C_epoch_marker_size(const H5F_t *f, const void *thing, size_t *size_ptr); const H5C_class_t epoch_marker_class = { /* id = */ H5C__EPOCH_MARKER_TYPE, /* load = */ &H5C_epoch_marker_load, /* flush = */ &H5C_epoch_marker_flush, /* dest = */ &H5C_epoch_marker_dest, /* clear = */ &H5C_epoch_marker_clear, /* notify = */&H5C_epoch_marker_notify, /* size = */ &H5C_epoch_marker_size }; /*************************************************************************** * Class functions for H5C__EPOCH_MAKER_TYPE: * * None of these functions should ever be called, so there is no point in * documenting them separately. * JRM - 11/16/04 * ***************************************************************************/ static void * H5C_epoch_marker_load(H5F_t UNUSED * f, hid_t UNUSED dxpl_id, haddr_t UNUSED addr, void UNUSED * udata) { void * ret_value = NULL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, NULL, "called unreachable fcn.") done: FUNC_LEAVE_NOAPI(ret_value) } static herr_t H5C_epoch_marker_flush(H5F_t UNUSED *f, hid_t UNUSED dxpl_id, hbool_t UNUSED dest, haddr_t UNUSED addr, void UNUSED *thing, unsigned UNUSED * flags_ptr) { herr_t ret_value = FAIL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "called unreachable fcn.") done: FUNC_LEAVE_NOAPI(ret_value) } static herr_t H5C_epoch_marker_dest(H5F_t UNUSED * f, void UNUSED * thing) { herr_t ret_value = FAIL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "called unreachable fcn.") done: FUNC_LEAVE_NOAPI(ret_value) } static herr_t H5C_epoch_marker_clear(H5F_t UNUSED * f, void UNUSED * thing, hbool_t UNUSED dest) { herr_t ret_value = FAIL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "called unreachable fcn.") done: FUNC_LEAVE_NOAPI(ret_value) } static herr_t H5C_epoch_marker_notify(H5C_notify_action_t UNUSED action, void UNUSED * thing) { herr_t ret_value = FAIL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "called unreachable fcn.") done: FUNC_LEAVE_NOAPI(ret_value) } static herr_t H5C_epoch_marker_size(const H5F_t UNUSED * f, const void UNUSED * thing, size_t UNUSED * size_ptr) { herr_t ret_value = FAIL; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "called unreachable fcn.") done: FUNC_LEAVE_NOAPI(ret_value) } /*------------------------------------------------------------------------- * Function: H5C_apply_candidate_list * * Purpose: Apply the supplied candidate list. * * We used to do this by simply having each process write * every mpi_size-th entry in the candidate list, starting * at index mpi_rank, and mark all the others clean. * * However, this can cause unnecessary contention in a file * system by increasing the number of processes writing to * adjacent locations in the HDF5 file. * * To attempt to minimize this, we now arange matters such * that each process writes n adjacent entries in the * candidate list, and marks all others clean. We must do * this in such a fashion as to guarantee that each entry * on the candidate list is written by exactly one process, * and marked clean by all others. * * To do this, first construct a table mapping mpi_rank * to the index of the first entry in the candidate list to * be written by the process of that mpi_rank, and then use * the table to control which entries are written and which * are marked as clean as a function of the mpi_rank. * * Note that the table must be identical on all processes, as * all see the same candidate list, mpi_size, and mpi_rank -- * the inputs used to construct the table. * * We construct the table as follows. Let: * * n = num_candidates / mpi_size; * * m = num_candidates % mpi_size; * * Now allocate an array of integers of length mpi_size + 1, * and call this array candidate_assignment_table. * * Conceptually, if the number of candidates is a multiple * of the mpi_size, we simply pass through the candidate list * and assign n entries to each process to flush, with the * index of the first entry to flush in the location in * the candidate_assignment_table indicated by the mpi_rank * of the process. * * In the more common case in which the candidate list isn't * isn't a multiple of the mpi_size, we pretend it is, and * give num_candidates % mpi_size processes one extra entry * each to make things work out. * * Once the table is constructed, we determine the first and * last entry this process is to flush as follows: * * first_entry_to_flush = candidate_assignment_table[mpi_rank] * * last_entry_to_flush = * candidate_assignment_table[mpi_rank + 1] - 1; * * With these values determined, we simply scan through the * candidate list, marking all entries in the range * [first_entry_to_flush, last_entry_to_flush] for flush, * and all others to be cleaned. * * Finally, we scan the LRU from tail to head, flushing * or marking clean the candidate entries as indicated. * If necessary, we scan the pinned list as well. * * Note that this function will fail if any protected or * clean entries appear on the candidate list. * * This function is used in managing sync points, and * shouldn't be used elsewhere. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: John Mainzer * 3/17/10 * *------------------------------------------------------------------------- */ #ifdef H5_HAVE_PARALLEL #define H5C_APPLY_CANDIDATE_LIST__DEBUG 0 herr_t H5C_apply_candidate_list(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, H5C_t * cache_ptr, int num_candidates, haddr_t * candidates_list_ptr, int mpi_rank, int mpi_size) { hbool_t first_flush = FALSE; int i; int m; int n; int first_entry_to_flush; int last_entry_to_flush; int entries_to_clear = 0; int entries_to_flush = 0; int entries_to_flush_or_clear_last = 0; int entries_to_flush_collectively = 0; int entries_cleared = 0; int entries_flushed = 0; int entries_delayed = 0; int entries_flushed_or_cleared_last = 0; int entries_flushed_collectively = 0; int entries_examined = 0; int initial_list_len; int * candidate_assignment_table = NULL; haddr_t addr; H5C_cache_entry_t * clear_ptr = NULL; H5C_cache_entry_t * entry_ptr = NULL; H5C_cache_entry_t * flush_ptr = NULL; H5C_cache_entry_t * delayed_ptr = NULL; #if H5C_DO_SANITY_CHECKS haddr_t last_addr; #endif /* H5C_DO_SANITY_CHECKS */ #if H5C_APPLY_CANDIDATE_LIST__DEBUG char tbl_buf[1024]; #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( num_candidates > 0 ); HDassert( num_candidates <= cache_ptr->slist_len ); HDassert( candidates_list_ptr != NULL ); HDassert( 0 <= mpi_rank ); HDassert( mpi_rank < mpi_size ); #if H5C_APPLY_CANDIDATE_LIST__DEBUG HDfprintf(stdout, "%s:%d: setting up candidate assignment table.\n", FUNC, mpi_rank); for ( i = 0; i < 1024; i++ ) tbl_buf[i] = '\0'; sprintf(&(tbl_buf[0]), "candidate list = "); for ( i = 0; i < num_candidates; i++ ) { sprintf(&(tbl_buf[HDstrlen(tbl_buf)]), " 0x%llx", (long long)(*(candidates_list_ptr + i))); } sprintf(&(tbl_buf[HDstrlen(tbl_buf)]), "\n"); HDfprintf(stdout, "%s", tbl_buf); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ n = num_candidates / mpi_size; m = num_candidates % mpi_size; HDassert(n >= 0); if(NULL == (candidate_assignment_table = (int *)H5MM_malloc(sizeof(int) * (size_t)(mpi_size + 1)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for candidate assignment table") candidate_assignment_table[0] = 0; candidate_assignment_table[mpi_size] = num_candidates; if(m == 0) { /* mpi_size is an even divisor of num_candidates */ HDassert(n > 0); for(i = 1; i < mpi_size; i++) candidate_assignment_table[i] = candidate_assignment_table[i - 1] + n; } /* end if */ else { for(i = 1; i <= m; i++) candidate_assignment_table[i] = candidate_assignment_table[i - 1] + n + 1; if(num_candidates < mpi_size) { for(i = m + 1; i < mpi_size; i++) candidate_assignment_table[i] = num_candidates; } /* end if */ else { for(i = m + 1; i < mpi_size; i++) candidate_assignment_table[i] = candidate_assignment_table[i - 1] + n; } /* end else */ } /* end else */ HDassert((candidate_assignment_table[mpi_size - 1] + n) == num_candidates); #if H5C_DO_SANITY_CHECKS /* verify that the candidate assignment table has the expected form */ for ( i = 1; i < mpi_size - 1; i++ ) { int a, b; a = candidate_assignment_table[i] - candidate_assignment_table[i - 1]; b = candidate_assignment_table[i + 1] - candidate_assignment_table[i]; HDassert( n + 1 >= a ); HDassert( a >= b ); HDassert( b >= n ); } #endif /* H5C_DO_SANITY_CHECKS */ first_entry_to_flush = candidate_assignment_table[mpi_rank]; last_entry_to_flush = candidate_assignment_table[mpi_rank + 1] - 1; #if H5C_APPLY_CANDIDATE_LIST__DEBUG for ( i = 0; i < 1024; i++ ) tbl_buf[i] = '\0'; sprintf(&(tbl_buf[0]), "candidate assignment table = "); for(i = 0; i <= mpi_size; i++) sprintf(&(tbl_buf[HDstrlen(tbl_buf)]), " %d", candidate_assignment_table[i]); sprintf(&(tbl_buf[HDstrlen(tbl_buf)]), "\n"); HDfprintf(stdout, "%s", tbl_buf); HDfprintf(stdout, "%s:%d: flush entries [%d, %d].\n", FUNC, mpi_rank, first_entry_to_flush, last_entry_to_flush); HDfprintf(stdout, "%s:%d: marking entries.\n", FUNC, mpi_rank); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ for(i = 0; i < num_candidates; i++) { addr = candidates_list_ptr[i]; HDassert( H5F_addr_defined(addr) ); #if H5C_DO_SANITY_CHECKS if ( i > 0 ) { if ( last_addr == addr ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Duplicate entry in cleaned list.\n") } else if ( last_addr > addr ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "candidate list not sorted.\n") } } last_addr = addr; #endif /* H5C_DO_SANITY_CHECKS */ H5C__SEARCH_INDEX(cache_ptr, addr, entry_ptr, FAIL) if(entry_ptr == NULL) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Listed candidate entry not in cache?!?!?.") } else if(!entry_ptr->is_dirty) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Listed entry not dirty?!?!?.") } else if ( entry_ptr->is_protected ) { /* For now at least, we can't deal with protected entries. * If we encounter one, scream and die. If it becomes an * issue, we should be able to work around this. */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Listed entry is protected?!?!?.") } else { /* determine whether the entry is to be cleared or flushed, * and mark it accordingly. We will scan the protected and * pinned list shortly, and clear or flush according to these * markings. */ if((i >= first_entry_to_flush) && (i <= last_entry_to_flush)) { entries_to_flush++; entry_ptr->flush_immediately = TRUE; } /* end if */ else { entries_to_clear++; entry_ptr->clear_on_unprotect = TRUE; } /* end else */ } /* end else */ } /* end for */ #if H5C_APPLY_CANDIDATE_LIST__DEBUG HDfprintf(stdout, "%s:%d: num candidates/to clear/to flush = %d/%d/%d.\n", FUNC, mpi_rank, (int)num_candidates, (int)entries_to_clear, (int)entries_to_flush); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ /* We have now marked all the entries on the candidate list for * either flush or clear -- now scan the LRU and the pinned list * for these entries and do the deed. * * Note that we are doing things in this round about manner so as * to preserve the order of the LRU list to the best of our ability. * If we don't do this, my experiments indicate that we will have a * noticably poorer hit ratio as a result. */ #if H5C_APPLY_CANDIDATE_LIST__DEBUG HDfprintf(stdout, "%s:%d: scanning LRU list. len = %d.\n", FUNC, mpi_rank, (int)(cache_ptr->LRU_list_len)); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ /* ====================================================================== * * Now scan the LRU and PEL lists, flushing or clearing entries as * needed. * * The flush_me_last and flush_me_collectively flags may dictate how or * when some entries can be flushed, and should be addressed here. * However, in their initial implementation, these flags only apply to the * superblock, so there's only a relatively small change to this function * to account for this one case where they come into play. If these flags * are ever expanded upon, this function and the following flushing steps * should be reworked to account for additional cases. * ====================================================================== */ entries_examined = 0; initial_list_len = cache_ptr->LRU_list_len; entry_ptr = cache_ptr->LRU_tail_ptr; /* Examine each entry in the LRU list */ while((entry_ptr != NULL) && (entries_examined <= initial_list_len) && ((entries_cleared + entries_flushed) < num_candidates)) { /* If this process needs to clear this entry. */ if(entry_ptr->clear_on_unprotect) { entry_ptr->clear_on_unprotect = FALSE; clear_ptr = entry_ptr; entry_ptr = entry_ptr->prev; entries_cleared++; #if ( H5C_APPLY_CANDIDATE_LIST__DEBUG > 1 ) HDfprintf(stdout, "%s:%d: clearing 0x%llx.\n", FUNC, mpi_rank, (long long)clear_ptr->addr); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ if(H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, clear_ptr->type, clear_ptr->addr, H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't clear entry.") } /* end if */ /* Else, if this process needs to flush this entry. */ else if (entry_ptr->flush_immediately) { entry_ptr->flush_immediately = FALSE; flush_ptr = entry_ptr; entry_ptr = entry_ptr->prev; entries_flushed++; #if ( H5C_APPLY_CANDIDATE_LIST__DEBUG > 1 ) HDfprintf(stdout, "%s:%d: flushing 0x%llx.\n", FUNC, mpi_rank, (long long)flush_ptr->addr); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ if(H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, flush_ptr->type, flush_ptr->addr, H5C__NO_FLAGS_SET, &first_flush, TRUE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't flush entry.") } /* end else-if */ /* Otherwise, no action to be taken on this entry. Grab the next. */ else { entry_ptr = entry_ptr->prev; } /* end else */ entries_examined++; } /* end while */ #if H5C_APPLY_CANDIDATE_LIST__DEBUG HDfprintf(stdout, "%s:%d: entries examined/cleared/flushed = %d/%d/%d.\n", FUNC, mpi_rank, entries_examined, entries_cleared, entries_flushed); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ /* It is also possible that some of the cleared entries are on the * pinned list. Must scan that also. */ #if H5C_APPLY_CANDIDATE_LIST__DEBUG HDfprintf(stdout, "%s:%d: scanning pinned entry list. len = %d\n", FUNC, mpi_rank, (int)(cache_ptr->pel_len)); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ entry_ptr = cache_ptr->pel_head_ptr; while((entry_ptr != NULL) && ((entries_cleared + entries_flushed + entries_delayed) < num_candidates)) { /* If entry is marked for flush or for clear */ if((entry_ptr->clear_on_unprotect||entry_ptr->flush_immediately)) { /* If this entry needs to be flushed last */ if (entry_ptr->flush_me_last) { /* At this time, only the superblock supports being flushed last. Conveniently, it also happens to be the only entry that supports being flushed collectively, as well. Also conveniently, it's always pinned, so we only need to check for it while scanning the PEL here. Finally, it's never included in a candidate list that excludes other dirty entries in a cache, so we can handle this relatively simple case here. For now, this function asserts this and saves the entry to flush it after scanning the rest of the PEL list. If there are ever more entries that either need to be flushed last and/or flushed collectively, this whole routine will need to be reworked to handle all additional cases. As it is the simple case of a single pinned entry needing flushed last and collectively is just a minor addition to this routine, but signficantly buffing up the usage of flush_me_last or flush_me_collectively will require a more intense rework of this function and potentially the function of candidate lists as a whole. */ HDassert(entry_ptr->flush_me_collectively); entries_to_flush_or_clear_last++; entries_to_flush_collectively++; HDassert(entries_to_flush_or_clear_last == 1); HDassert(entries_to_flush_collectively == 1); /* Delay the entry. It will be flushed later. */ delayed_ptr = entry_ptr; entries_delayed++; HDassert(entries_delayed == 1); } /* end if */ /* Else, this process needs to clear this entry. */ else if (entry_ptr->clear_on_unprotect) { HDassert(!entry_ptr->flush_immediately); entry_ptr->clear_on_unprotect = FALSE; clear_ptr = entry_ptr; entry_ptr = entry_ptr->next; entries_cleared++; #if ( H5C_APPLY_CANDIDATE_LIST__DEBUG > 1 ) HDfprintf(stdout, "%s:%d: clearing 0x%llx.\n", FUNC, mpi_rank, (long long)clear_ptr->addr); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ if(H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, clear_ptr->type, clear_ptr->addr, H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't clear entry.") } /* end else-if */ /* Else, if this process needs to independently flush this entry. */ else if (entry_ptr->flush_immediately) { entry_ptr->flush_immediately = FALSE; flush_ptr = entry_ptr; entry_ptr = entry_ptr->next; entries_flushed++; #if ( H5C_APPLY_CANDIDATE_LIST__DEBUG > 1 ) HDfprintf(stdout, "%s:%d: flushing 0x%llx.\n", FUNC, mpi_rank, (long long)flush_ptr->addr); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ if(H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, flush_ptr->type, flush_ptr->addr, H5C__NO_FLAGS_SET, &first_flush, TRUE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't flush entry.") } /* end else-if */ } /* end if */ /* Otherwise, this entry is not marked for flush or clear. Grab the next. */ else { entry_ptr = entry_ptr->next; } /* end else */ } /* end while */ #if H5C_APPLY_CANDIDATE_LIST__DEBUG HDfprintf(stdout, "%s:%d: pel entries examined/cleared/flushed = %d/%d/%d.\n", FUNC, mpi_rank, entries_examined, entries_cleared, entries_flushed); HDfprintf(stdout, "%s:%d: done.\n", FUNC, mpi_rank); HDfsync(stdout); #endif /* H5C_APPLY_CANDIDATE_LIST__DEBUG */ /* ====================================================================== * * Now, handle all delayed entries. * * * * This can *only* be the superblock at this time, so it's relatively * * easy to deal with. We're collectively flushing the entry saved from * * above. This will need to be handled differently if there are ever more * * than one entry needing this special treatment.) * * ====================================================================== */ if (delayed_ptr) { if (delayed_ptr->clear_on_unprotect) { entry_ptr->clear_on_unprotect = FALSE; entries_cleared++; } else if (delayed_ptr->flush_immediately) { entry_ptr->flush_immediately = FALSE; entries_flushed++; } /* end if */ if(H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, delayed_ptr->type, delayed_ptr->addr, H5C__NO_FLAGS_SET, &first_flush, TRUE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't flush entry collectively.") entries_flushed_collectively++; entries_flushed_or_cleared_last++; } /* end if */ /* ====================================================================== * * Finished flushing everything. * * ====================================================================== */ HDassert((entries_flushed == entries_to_flush)); HDassert((entries_cleared == entries_to_clear)); HDassert((entries_flushed_or_cleared_last == entries_to_flush_or_clear_last)); HDassert((entries_flushed_collectively == entries_to_flush_collectively)); if((entries_flushed != entries_to_flush) || (entries_cleared != entries_to_clear) || (entries_flushed_or_cleared_last != entries_to_flush_or_clear_last) || (entries_flushed_collectively != entries_to_flush_collectively)) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "entry count mismatch.") done: if(candidate_assignment_table != NULL) candidate_assignment_table = (int *)H5MM_xfree((void *)candidate_assignment_table); FUNC_LEAVE_NOAPI(ret_value) } /* H5C_apply_candidate_list() */ #endif /* H5_HAVE_PARALLEL */ /*------------------------------------------------------------------------- * Function: H5C_construct_candidate_list__clean_cache * * Purpose: Construct the list of entries that should be flushed to * clean all entries in the cache. * * This function is used in managing sync points, and * shouldn't be used elsewhere. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: John Mainzer * 3/17/10 * *------------------------------------------------------------------------- */ #ifdef H5_HAVE_PARALLEL herr_t H5C_construct_candidate_list__clean_cache(H5C_t * cache_ptr) { size_t space_needed; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); /* As a sanity check, set space needed to the size of the skip list. * This should be the sum total of the sizes of all the dirty entries * in the metadata cache. */ space_needed = cache_ptr->slist_size; /* Recall that while we shouldn't have any protected entries at this * point, it is possible that some dirty entries may reside on the * pinned list at this point. */ HDassert( cache_ptr->slist_size <= (cache_ptr->dLRU_list_size + cache_ptr->pel_size) ); HDassert( cache_ptr->slist_len <= (cache_ptr->dLRU_list_len + cache_ptr->pel_len) ); if(space_needed > 0) { /* we have work to do */ H5C_cache_entry_t *entry_ptr; int nominated_entries_count = 0; size_t nominated_entries_size = 0; haddr_t nominated_addr; HDassert( cache_ptr->slist_len > 0 ); /* Scan the dirty LRU list from tail forward and nominate sufficient * entries to free up the necessary space. */ entry_ptr = cache_ptr->dLRU_tail_ptr; while((nominated_entries_size < space_needed) && (nominated_entries_count < cache_ptr->slist_len) && (entry_ptr != NULL)) { HDassert( ! (entry_ptr->is_protected) ); HDassert( ! (entry_ptr->is_read_only) ); HDassert( entry_ptr->ro_ref_count == 0 ); HDassert( entry_ptr->is_dirty ); HDassert( entry_ptr->in_slist ); nominated_addr = entry_ptr->addr; if(H5AC_add_candidate((H5AC_t *)cache_ptr, nominated_addr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "H5AC_add_candidate() failed(1).") nominated_entries_size += entry_ptr->size; nominated_entries_count++; entry_ptr = entry_ptr->aux_prev; } /* end while */ HDassert( entry_ptr == NULL ); /* it is possible that there are some dirty entries on the * protected entry list as well -- scan it too if necessary */ entry_ptr = cache_ptr->pel_head_ptr; while((nominated_entries_size < space_needed) && (nominated_entries_count < cache_ptr->slist_len) && (entry_ptr != NULL)) { if(entry_ptr->is_dirty) { HDassert( ! (entry_ptr->is_protected) ); HDassert( ! (entry_ptr->is_read_only) ); HDassert( entry_ptr->ro_ref_count == 0 ); HDassert( entry_ptr->is_dirty ); HDassert( entry_ptr->in_slist ); nominated_addr = entry_ptr->addr; if(H5AC_add_candidate((H5AC_t *)cache_ptr, nominated_addr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "H5AC_add_candidate() failed(2).") nominated_entries_size += entry_ptr->size; nominated_entries_count++; } /* end if */ entry_ptr = entry_ptr->next; } /* end while */ HDassert( nominated_entries_count == cache_ptr->slist_len ); HDassert( nominated_entries_size == space_needed ); } /* end if */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_construct_candidate_list__clean_cache() */ #endif /* H5_HAVE_PARALLEL */ /*------------------------------------------------------------------------- * Function: H5C_construct_candidate_list__min_clean * * Purpose: Construct the list of entries that should be flushed to * get the cache back within its min clean constraints. * * This function is used in managing sync points, and * shouldn't be used elsewhere. * * Return: Success: SUCCEED * * Failure: FAIL * * Programmer: John Mainzer * 3/17/10 * *------------------------------------------------------------------------- */ #ifdef H5_HAVE_PARALLEL herr_t H5C_construct_candidate_list__min_clean(H5C_t * cache_ptr) { size_t space_needed = 0; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); /* compute the number of bytes (if any) that must be flushed to get the * cache back within its min clean constraints. */ if(cache_ptr->max_cache_size > cache_ptr->index_size) { if(((cache_ptr->max_cache_size - cache_ptr->index_size) + cache_ptr->cLRU_list_size) >= cache_ptr->min_clean_size) space_needed = 0; else space_needed = cache_ptr->min_clean_size - ((cache_ptr->max_cache_size - cache_ptr->index_size) + cache_ptr->cLRU_list_size); } /* end if */ else { if(cache_ptr->min_clean_size <= cache_ptr->cLRU_list_size) space_needed = 0; else space_needed = cache_ptr->min_clean_size - cache_ptr->cLRU_list_size; } /* end else */ if(space_needed > 0) { /* we have work to do */ H5C_cache_entry_t *entry_ptr; int nominated_entries_count = 0; size_t nominated_entries_size = 0; HDassert( cache_ptr->slist_len > 0 ); /* Scan the dirty LRU list from tail forward and nominate sufficient * entries to free up the necessary space. */ entry_ptr = cache_ptr->dLRU_tail_ptr; while((nominated_entries_size < space_needed) && (nominated_entries_count < cache_ptr->slist_len) && (entry_ptr != NULL) && (!entry_ptr->flush_me_last)) { haddr_t nominated_addr; HDassert( ! (entry_ptr->is_protected) ); HDassert( ! (entry_ptr->is_read_only) ); HDassert( entry_ptr->ro_ref_count == 0 ); HDassert( entry_ptr->is_dirty ); HDassert( entry_ptr->in_slist ); nominated_addr = entry_ptr->addr; if(H5AC_add_candidate((H5AC_t *)cache_ptr, nominated_addr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "H5AC_add_candidate() failed.") nominated_entries_size += entry_ptr->size; nominated_entries_count++; entry_ptr = entry_ptr->aux_prev; } /* end while */ HDassert( nominated_entries_count <= cache_ptr->slist_len ); HDassert( nominated_entries_size >= space_needed ); } /* end if */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_construct_candidate_list__min_clean() */ #endif /* H5_HAVE_PARALLEL */ /*------------------------------------------------------------------------- * Function: H5C_create * * Purpose: Allocate, initialize, and return the address of a new * instance of H5C_t. * * In general, the max_cache_size parameter must be positive, * and the min_clean_size parameter must lie in the closed * interval [0, max_cache_size]. * * The check_write_permitted parameter must either be NULL, * or point to a function of type H5C_write_permitted_func_t. * If it is NULL, the cache will use the write_permitted * flag to determine whether writes are permitted. * * Return: Success: Pointer to the new instance. * * Failure: NULL * * Programmer: John Mainzer * 6/2/04 * *------------------------------------------------------------------------- */ H5C_t * H5C_create(size_t max_cache_size, size_t min_clean_size, int max_type_id, const char * (* type_name_table_ptr), H5C_write_permitted_func_t check_write_permitted, hbool_t write_permitted, H5C_log_flush_func_t log_flush, void * aux_ptr) { int i; H5C_t * cache_ptr = NULL; H5C_t * ret_value = NULL; /* Return value */ FUNC_ENTER_NOAPI(NULL) HDassert( max_cache_size >= H5C__MIN_MAX_CACHE_SIZE ); HDassert( max_cache_size <= H5C__MAX_MAX_CACHE_SIZE ); HDassert( min_clean_size <= max_cache_size ); HDassert( max_type_id >= 0 ); HDassert( max_type_id < H5C__MAX_NUM_TYPE_IDS ); HDassert( type_name_table_ptr ); HDassert( ( write_permitted == TRUE ) || ( write_permitted == FALSE ) ); for ( i = 0; i <= max_type_id; i++ ) { HDassert( (type_name_table_ptr)[i] ); HDassert( HDstrlen(( type_name_table_ptr)[i]) > 0 ); } if ( NULL == (cache_ptr = H5FL_CALLOC(H5C_t)) ) { HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, \ "memory allocation failed") } if ( (cache_ptr->slist_ptr = H5SL_create(H5SL_TYPE_HADDR, NULL)) == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTCREATE, NULL, "can't create skip list.") } /* If we get this far, we should succeed. Go ahead and initialize all * the fields. */ cache_ptr->magic = H5C__H5C_T_MAGIC; cache_ptr->flush_in_progress = FALSE; cache_ptr->trace_file_ptr = NULL; cache_ptr->aux_ptr = aux_ptr; cache_ptr->max_type_id = max_type_id; cache_ptr->type_name_table_ptr = type_name_table_ptr; cache_ptr->max_cache_size = max_cache_size; cache_ptr->min_clean_size = min_clean_size; cache_ptr->check_write_permitted = check_write_permitted; cache_ptr->write_permitted = write_permitted; cache_ptr->log_flush = log_flush; cache_ptr->evictions_enabled = TRUE; cache_ptr->index_len = 0; cache_ptr->index_size = (size_t)0; cache_ptr->clean_index_size = (size_t)0; cache_ptr->dirty_index_size = (size_t)0; /* Tagging Field Initializations */ cache_ptr->ignore_tags = FALSE; cache_ptr->slist_len = 0; cache_ptr->slist_size = (size_t)0; #if H5C_DO_SANITY_CHECKS cache_ptr->slist_len_increase = 0; cache_ptr->slist_size_increase = 0; #endif /* H5C_DO_SANITY_CHECKS */ for ( i = 0; i < H5C__HASH_TABLE_LEN; i++ ) { (cache_ptr->index)[i] = NULL; } cache_ptr->pl_len = 0; cache_ptr->pl_size = (size_t)0; cache_ptr->pl_head_ptr = NULL; cache_ptr->pl_tail_ptr = NULL; cache_ptr->pel_len = 0; cache_ptr->pel_size = (size_t)0; cache_ptr->pel_head_ptr = NULL; cache_ptr->pel_tail_ptr = NULL; cache_ptr->LRU_list_len = 0; cache_ptr->LRU_list_size = (size_t)0; cache_ptr->LRU_head_ptr = NULL; cache_ptr->LRU_tail_ptr = NULL; cache_ptr->cLRU_list_len = 0; cache_ptr->cLRU_list_size = (size_t)0; cache_ptr->cLRU_head_ptr = NULL; cache_ptr->cLRU_tail_ptr = NULL; cache_ptr->dLRU_list_len = 0; cache_ptr->dLRU_list_size = (size_t)0; cache_ptr->dLRU_head_ptr = NULL; cache_ptr->dLRU_tail_ptr = NULL; cache_ptr->size_increase_possible = FALSE; cache_ptr->flash_size_increase_possible = FALSE; cache_ptr->flash_size_increase_threshold = 0; cache_ptr->size_decrease_possible = FALSE; cache_ptr->resize_enabled = FALSE; cache_ptr->cache_full = FALSE; cache_ptr->size_decreased = FALSE; (cache_ptr->resize_ctl).version = H5C__CURR_AUTO_SIZE_CTL_VER; (cache_ptr->resize_ctl).rpt_fcn = NULL; (cache_ptr->resize_ctl).set_initial_size = FALSE; (cache_ptr->resize_ctl).initial_size = H5C__DEF_AR_INIT_SIZE; (cache_ptr->resize_ctl).min_clean_fraction = H5C__DEF_AR_MIN_CLEAN_FRAC; (cache_ptr->resize_ctl).max_size = H5C__DEF_AR_MAX_SIZE; (cache_ptr->resize_ctl).min_size = H5C__DEF_AR_MIN_SIZE; (cache_ptr->resize_ctl).epoch_length = H5C__DEF_AR_EPOCH_LENGTH; (cache_ptr->resize_ctl).incr_mode = H5C_incr__off; (cache_ptr->resize_ctl).lower_hr_threshold = H5C__DEF_AR_LOWER_THRESHHOLD; (cache_ptr->resize_ctl).increment = H5C__DEF_AR_INCREMENT; (cache_ptr->resize_ctl).apply_max_increment = TRUE; (cache_ptr->resize_ctl).max_increment = H5C__DEF_AR_MAX_INCREMENT; (cache_ptr->resize_ctl).flash_incr_mode = H5C_flash_incr__off; (cache_ptr->resize_ctl).flash_multiple = 1.0; (cache_ptr->resize_ctl).flash_threshold = 0.25; (cache_ptr->resize_ctl).decr_mode = H5C_decr__off; (cache_ptr->resize_ctl).upper_hr_threshold = H5C__DEF_AR_UPPER_THRESHHOLD; (cache_ptr->resize_ctl).decrement = H5C__DEF_AR_DECREMENT; (cache_ptr->resize_ctl).apply_max_decrement = TRUE; (cache_ptr->resize_ctl).max_decrement = H5C__DEF_AR_MAX_DECREMENT; (cache_ptr->resize_ctl).epochs_before_eviction = H5C__DEF_AR_EPCHS_B4_EVICT; (cache_ptr->resize_ctl).apply_empty_reserve = TRUE; (cache_ptr->resize_ctl).empty_reserve = H5C__DEF_AR_EMPTY_RESERVE; cache_ptr->epoch_markers_active = 0; /* no need to initialize the ring buffer itself */ cache_ptr->epoch_marker_ringbuf_first = 1; cache_ptr->epoch_marker_ringbuf_last = 0; cache_ptr->epoch_marker_ringbuf_size = 0; /* Initialize all epoch marker entries' fields to zero/FALSE/NULL */ HDmemset(cache_ptr->epoch_markers, 0, sizeof(cache_ptr->epoch_markers)); /* Set non-zero/FALSE/NULL fields for epoch markers */ for ( i = 0; i < H5C__MAX_EPOCH_MARKERS; i++ ) { (cache_ptr->epoch_marker_active)[i] = FALSE; #ifndef NDEBUG ((cache_ptr->epoch_markers)[i]).magic = H5C__H5C_CACHE_ENTRY_T_MAGIC; #endif /* NDEBUG */ ((cache_ptr->epoch_markers)[i]).addr = (haddr_t)i; ((cache_ptr->epoch_markers)[i]).type = &epoch_marker_class; } if ( H5C_reset_cache_hit_rate_stats(cache_ptr) != SUCCEED ) { /* this should be impossible... */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, NULL, \ "H5C_reset_cache_hit_rate_stats failed.") } H5C_stats__reset(cache_ptr); cache_ptr->prefix[0] = '\0'; /* empty string */ /* Set return value */ ret_value = cache_ptr; done: if ( ret_value == 0 ) { if ( cache_ptr != NULL ) { if ( cache_ptr->slist_ptr != NULL ) H5SL_close(cache_ptr->slist_ptr); cache_ptr->magic = 0; cache_ptr = H5FL_FREE(H5C_t, cache_ptr); } /* end if */ } /* end if */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_create() */ /*------------------------------------------------------------------------- * Function: H5C_def_auto_resize_rpt_fcn * * Purpose: Print results of a automatic cache resize. * * This function should only be used where HDprintf() behaves * well -- i.e. not on Windows. * * Return: void * * Programmer: John Mainzer * 10/27/04 * *------------------------------------------------------------------------- */ void H5C_def_auto_resize_rpt_fcn(H5C_t * cache_ptr, #ifndef NDEBUG int32_t version, #else /* NDEBUG */ int32_t UNUSED version, #endif /* NDEBUG */ double hit_rate, enum H5C_resize_status status, size_t old_max_cache_size, size_t new_max_cache_size, size_t old_min_clean_size, size_t new_min_clean_size) { HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( version == H5C__CURR_AUTO_RESIZE_RPT_FCN_VER ); switch ( status ) { case in_spec: HDfprintf(stdout, "%sAuto cache resize -- no change. (hit rate = %lf)\n", cache_ptr->prefix, hit_rate); break; case increase: HDassert( hit_rate < (cache_ptr->resize_ctl).lower_hr_threshold ); HDassert( old_max_cache_size < new_max_cache_size ); HDfprintf(stdout, "%sAuto cache resize -- hit rate (%lf) out of bounds low (%6.5lf).\n", cache_ptr->prefix, hit_rate, (cache_ptr->resize_ctl).lower_hr_threshold); HDfprintf(stdout, "%s cache size increased from (%Zu/%Zu) to (%Zu/%Zu).\n", cache_ptr->prefix, old_max_cache_size, old_min_clean_size, new_max_cache_size, new_min_clean_size); break; case flash_increase: HDassert( old_max_cache_size < new_max_cache_size ); HDfprintf(stdout, "%sflash cache resize(%d) -- size threshold = %Zu.\n", cache_ptr->prefix, (int)((cache_ptr->resize_ctl).flash_incr_mode), cache_ptr->flash_size_increase_threshold); HDfprintf(stdout, "%s cache size increased from (%Zu/%Zu) to (%Zu/%Zu).\n", cache_ptr->prefix, old_max_cache_size, old_min_clean_size, new_max_cache_size, new_min_clean_size); break; case decrease: HDassert( old_max_cache_size > new_max_cache_size ); switch ( (cache_ptr->resize_ctl).decr_mode ) { case H5C_decr__off: HDfprintf(stdout, "%sAuto cache resize -- decrease off. HR = %lf\n", cache_ptr->prefix, hit_rate); break; case H5C_decr__threshold: HDassert( hit_rate > (cache_ptr->resize_ctl).upper_hr_threshold ); HDfprintf(stdout, "%sAuto cache resize -- decrease by threshold. HR = %lf > %6.5lf\n", cache_ptr->prefix, hit_rate, (cache_ptr->resize_ctl).upper_hr_threshold); HDfprintf(stdout, "%sout of bounds high (%6.5lf).\n", cache_ptr->prefix, (cache_ptr->resize_ctl).upper_hr_threshold); break; case H5C_decr__age_out: HDfprintf(stdout, "%sAuto cache resize -- decrease by ageout. HR = %lf\n", cache_ptr->prefix, hit_rate); break; case H5C_decr__age_out_with_threshold: HDassert( hit_rate > (cache_ptr->resize_ctl).upper_hr_threshold ); HDfprintf(stdout, "%sAuto cache resize -- decrease by ageout with threshold. HR = %lf > %6.5lf\n", cache_ptr->prefix, hit_rate, (cache_ptr->resize_ctl).upper_hr_threshold); break; default: HDfprintf(stdout, "%sAuto cache resize -- decrease by unknown mode. HR = %lf\n", cache_ptr->prefix, hit_rate); } HDfprintf(stdout, "%s cache size decreased from (%Zu/%Zu) to (%Zu/%Zu).\n", cache_ptr->prefix, old_max_cache_size, old_min_clean_size, new_max_cache_size, new_min_clean_size); break; case at_max_size: HDfprintf(stdout, "%sAuto cache resize -- hit rate (%lf) out of bounds low (%6.5lf).\n", cache_ptr->prefix, hit_rate, (cache_ptr->resize_ctl).lower_hr_threshold); HDfprintf(stdout, "%s cache already at maximum size so no change.\n", cache_ptr->prefix); break; case at_min_size: HDfprintf(stdout, "%sAuto cache resize -- hit rate (%lf) -- can't decrease.\n", cache_ptr->prefix, hit_rate); HDfprintf(stdout, "%s cache already at minimum size.\n", cache_ptr->prefix); break; case increase_disabled: HDfprintf(stdout, "%sAuto cache resize -- increase disabled -- HR = %lf.", cache_ptr->prefix, hit_rate); break; case decrease_disabled: HDfprintf(stdout, "%sAuto cache resize -- decrease disabled -- HR = %lf.\n", cache_ptr->prefix, hit_rate); break; case not_full: HDassert( hit_rate < (cache_ptr->resize_ctl).lower_hr_threshold ); HDfprintf(stdout, "%sAuto cache resize -- hit rate (%lf) out of bounds low (%6.5lf).\n", cache_ptr->prefix, hit_rate, (cache_ptr->resize_ctl).lower_hr_threshold); HDfprintf(stdout, "%s cache not full so no increase in size.\n", cache_ptr->prefix); break; default: HDfprintf(stdout, "%sAuto cache resize -- unknown status code.\n", cache_ptr->prefix); break; } return; } /* H5C_def_auto_resize_rpt_fcn() */ /*------------------------------------------------------------------------- * Function: H5C_dest * * Purpose: Flush all data to disk and destroy the cache. * * This function fails if any object are protected since the * resulting file might not be consistent. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the destroy (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). This is useful in the metadata * cache, but may not be needed elsewhere. If so, just use the * same dxpl_id for both parameters. * * Note that *cache_ptr has been freed upon successful return. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 6/2/04 * *------------------------------------------------------------------------- */ herr_t H5C_dest(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id) { H5C_t * cache_ptr = f->shared->cache; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity check */ HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Flush and invalidate all cache entries */ if(H5C_flush_invalidate_cache(f, primary_dxpl_id, secondary_dxpl_id, H5C__NO_FLAGS_SET) < 0 ) HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "unable to flush cache") if(cache_ptr->slist_ptr != NULL) { H5SL_close(cache_ptr->slist_ptr); cache_ptr->slist_ptr = NULL; } /* end if */ cache_ptr->magic = 0; cache_ptr = H5FL_FREE(H5C_t, cache_ptr); done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_dest() */ /*------------------------------------------------------------------------- * * Function: H5C_expunge_entry * * Purpose: Use this function to tell the cache to expunge an entry * from the cache without writing it to disk even if it is * dirty. The entry may not be either pinned or protected. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 6/29/06 * *------------------------------------------------------------------------- */ herr_t H5C_expunge_entry(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, const H5C_class_t * type, haddr_t addr, unsigned flags) { H5C_t * cache_ptr; herr_t result; hbool_t first_flush = TRUE; H5C_cache_entry_t * entry_ptr = NULL; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( type ); HDassert( type->clear ); HDassert( type->dest ); HDassert( H5F_addr_defined(addr) ); #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ H5C__SEARCH_INDEX(cache_ptr, addr, entry_ptr, FAIL) if ( ( entry_ptr == NULL ) || ( entry_ptr->type != type ) ) { /* the target doesn't exist in the cache, so we are done. */ HGOTO_DONE(SUCCEED) } HDassert( entry_ptr->addr == addr ); HDassert( entry_ptr->type == type ); if ( entry_ptr->is_protected ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTEXPUNGE, FAIL, \ "Target entry is protected.") } if ( entry_ptr->is_pinned ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTEXPUNGE, FAIL, \ "Target entry is pinned.") } /* Pass along 'free file space' flag to cache client */ entry_ptr->free_file_space_on_destroy = ( (flags & H5C__FREE_FILE_SPACE_FLAG) != 0 ); /* If we get this far, call H5C_flush_single_entry() with the * H5C__FLUSH_INVALIDATE_FLAG and the H5C__FLUSH_CLEAR_ONLY_FLAG. * This will clear the entry, and then delete it from the cache. */ result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__FLUSH_INVALIDATE_FLAG | H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTEXPUNGE, FAIL, \ "H5C_flush_single_entry() failed.") } done: #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_expunge_entry() */ /*------------------------------------------------------------------------- * Function: H5C_flush_cache * * Purpose: Flush (and possibly destroy) the entries contained in the * specified cache. * * If the cache contains protected entries, the function will * fail, as protected entries cannot be flushed. However * all unprotected entries should be flushed before the * function returns failure. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the flush (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). This is useful in the metadata * cache, but may not be needed elsewhere. If so, just use the * same dxpl_id for both parameters. * * Return: Non-negative on success/Negative on failure or if there was * a request to flush all items and something was protected. * * Programmer: John Mainzer * 6/2/04 * *------------------------------------------------------------------------- */ herr_t H5C_flush_cache(H5F_t *f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, unsigned flags) { H5C_t * cache_ptr = f->shared->cache; herr_t status; herr_t ret_value = SUCCEED; hbool_t destroy; hbool_t flushed_entries_last_pass; hbool_t flush_marked_entries; hbool_t first_flush = TRUE; hbool_t ignore_protected; hbool_t tried_to_flush_protected_entry = FALSE; int32_t protected_entries = 0; H5SL_node_t * node_ptr = NULL; H5C_cache_entry_t * entry_ptr = NULL; H5C_cache_entry_t * next_entry_ptr = NULL; #if H5C_DO_SANITY_CHECKS int64_t flushed_entries_count; size_t flushed_entries_size; int64_t initial_slist_len; size_t initial_slist_size; #endif /* H5C_DO_SANITY_CHECKS */ FUNC_ENTER_NOAPI(FAIL) HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( cache_ptr->slist_ptr ); ignore_protected = ( (flags & H5C__FLUSH_IGNORE_PROTECTED_FLAG) != 0 ); destroy = ( (flags & H5C__FLUSH_INVALIDATE_FLAG) != 0 ); /* note that flush_marked_entries is set to FALSE if destroy is TRUE */ flush_marked_entries = ( ( (flags & H5C__FLUSH_MARKED_ENTRIES_FLAG) != 0 ) && ( ! destroy ) ); HDassert( ! ( destroy && ignore_protected ) ); HDassert( ! ( cache_ptr->flush_in_progress ) ); cache_ptr->flush_in_progress = TRUE; if ( destroy ) { status = H5C_flush_invalidate_cache(f, primary_dxpl_id, secondary_dxpl_id, flags); if ( status < 0 ) { /* This shouldn't happen -- if it does, we are toast so * just scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "flush invalidate failed.") } } else { /* When we are only flushing marked entries, the slist will usually * still contain entries when we have flushed everything we should. * Thus we track whether we have flushed any entries in the last * pass, and terminate if we haven't. */ flushed_entries_last_pass = TRUE; while ( ( cache_ptr->slist_len != 0 ) && ( protected_entries == 0 ) && ( flushed_entries_last_pass ) ) { flushed_entries_last_pass = FALSE; /* Start at beginning of skip list each time */ node_ptr = H5SL_first(cache_ptr->slist_ptr); HDassert( node_ptr != NULL ); /* Get cache entry for this node */ next_entry_ptr = (H5C_cache_entry_t *)H5SL_item(node_ptr); if ( NULL == next_entry_ptr ) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "next_entry_ptr == NULL ?!?!") HDassert( next_entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); HDassert( next_entry_ptr->is_dirty ); HDassert( next_entry_ptr->in_slist ); #if H5C_DO_SANITY_CHECKS /* For sanity checking, try to verify that the skip list has * the expected size and number of entries at the end of each * internal while loop (see below). * * Doing this get a bit tricky, as depending on flags, we may * or may not flush all the entries in the slist. * * To make things more entertaining, with the advent of the * fractal heap, the entry flush callback can cause entries * to be dirtied, resized, and/or moved. * * To deal with this, we first make note of the initial * skip list length and size: */ initial_slist_len = cache_ptr->slist_len; initial_slist_size = cache_ptr->slist_size; /* We then zero counters that we use to track the number * and total size of entries flushed: */ flushed_entries_count = 0; flushed_entries_size = 0; /* As mentioned above, there is the possibility that * entries will be dirtied, resized, and/or flushed during * our pass through the skip list. To capture the number * of entries added, and the skip list size delta, * zero the slist_len_increase and slist_size_increase of * the cache's instance of H5C_t. These fields will be * updated elsewhere to account for slist insertions and/or * dirty entry size changes. */ cache_ptr->slist_len_increase = 0; cache_ptr->slist_size_increase = 0; /* at the end of the loop, use these values to compute the * expected slist length and size and compare this with the * value recorded in the cache's instance of H5C_t. */ #endif /* H5C_DO_SANITY_CHECKS */ while ( node_ptr != NULL ) { entry_ptr = next_entry_ptr; /* With the advent of the fractal heap, it is possible * that the flush callback will dirty and/or resize * other entries in the cache. In particular, while * Quincey has promised me that this will never happen, * it is possible that the flush callback for an * entry may protect an entry that is not in the cache, * perhaps causing the cache to flush and possibly * evict the entry associated with node_ptr to make * space for the new entry. * * Thus we do a bit of extra sanity checking on entry_ptr, * and break out of this scan of the skip list if we * detect minor problems. We have a bit of leaway on the * number of passes though the skip list, so this shouldn't * be an issue in the flush in and of itself, as it should * be all but impossible for this to happen more than once * in any flush. * * Observe that that breaking out of the scan early * shouldn't break the sanity checks just after the end * of this while loop. * * If an entry has merely been marked clean and removed from * the s-list, we simply break out of the scan. * * If the entry has been evicted, we flag an error and * exit. */ #ifndef NDEBUG if ( entry_ptr->magic != H5C__H5C_CACHE_ENTRY_T_MAGIC ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "entry_ptr->magic is invalid ?!?!") } else #endif /* NDEBUG */ if ( ( ! entry_ptr->is_dirty ) || ( ! entry_ptr->in_slist ) ) { /* the s-list has been modified out from under us. * break out of the loop. */ goto end_of_inner_loop;; } /* increment node pointer now, before we delete its target * from the slist. */ node_ptr = H5SL_next(node_ptr); if ( node_ptr != NULL ) { next_entry_ptr = (H5C_cache_entry_t *)H5SL_item(node_ptr); if ( NULL == next_entry_ptr ) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "next_entry_ptr == NULL ?!?!") HDassert( next_entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); HDassert( next_entry_ptr->is_dirty ); HDassert( next_entry_ptr->in_slist ); } else { next_entry_ptr = NULL; } HDassert( entry_ptr != NULL ); HDassert( entry_ptr->in_slist ); if ( ( ( ! flush_marked_entries ) || ( entry_ptr->flush_marker ) ) && ( ( ! entry_ptr->flush_me_last ) || ( cache_ptr->num_last_entries >= cache_ptr->slist_len ) || ( flush_marked_entries && ( entry_ptr->flush_marker ) ) ) && ( ( entry_ptr->flush_dep_nchildren == 0 ) || ( ( ! destroy ) && ( entry_ptr->flush_dep_ndirty_children == 0 ) ) ) ) { if ( entry_ptr->is_protected ) { /* we probably have major problems -- but lets flush * everything we can before we decide whether to flag * an error. */ tried_to_flush_protected_entry = TRUE; protected_entries++; } else if ( entry_ptr->is_pinned ) { #if H5C_DO_SANITY_CHECKS flushed_entries_count++; flushed_entries_size += entry_ptr->size; #endif /* H5C_DO_SANITY_CHECKS */ status = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, NULL, entry_ptr->addr, flags, &first_flush, FALSE); if ( status < 0 ) { /* This shouldn't happen -- if it does, we are toast * so just scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "dirty pinned entry flush failed.") } /* end if */ flushed_entries_last_pass = TRUE; } /* end if */ else { #if H5C_DO_SANITY_CHECKS flushed_entries_count++; flushed_entries_size += entry_ptr->size; #endif /* H5C_DO_SANITY_CHECKS */ status = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, NULL, entry_ptr->addr, flags, &first_flush, FALSE); if ( status < 0 ) { /* This shouldn't happen -- if it does, we are * toast so just scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Can't flush entry.") } flushed_entries_last_pass = TRUE; } /* end else */ } /* end if */ } /* while ( node_ptr != NULL ) */ /* Note the extra ; is necessary so the label is not at the end of the compound * statement (the while loop), which is illegal */ end_of_inner_loop:; #if H5C_DO_SANITY_CHECKS /* Verify that the slist size and length are as expected. */ HDassert( (initial_slist_len + cache_ptr->slist_len_increase - flushed_entries_count) == cache_ptr->slist_len ); HDassert( (initial_slist_size + cache_ptr->slist_size_increase - flushed_entries_size) == cache_ptr->slist_size ); #endif /* H5C_DO_SANITY_CHECKS */ } /* while */ HDassert( protected_entries <= cache_ptr->pl_len ); if ( ( ( cache_ptr->pl_len > 0 ) && ( !ignore_protected ) ) || ( tried_to_flush_protected_entry ) ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "cache has protected items") } #if H5C_DO_SANITY_CHECKS if ( ! flush_marked_entries ) { HDassert( cache_ptr->slist_len == 0 ); HDassert( cache_ptr->slist_size == 0 ); } #endif /* H5C_DO_SANITY_CHECKS */ } done: cache_ptr->flush_in_progress = FALSE; FUNC_LEAVE_NOAPI(ret_value) } /* H5C_flush_cache() */ /*------------------------------------------------------------------------- * Function: H5C_flush_to_min_clean * * Purpose: Flush dirty entries until the caches min clean size is * attained. * * This function is used in the implementation of the * metadata cache in PHDF5. To avoid "messages from the * future", the cache on process 0 can't be allowed to * flush entries until the other processes have reached * the same point in the calculation. If this constraint * is not met, it is possible that the other processes will * read metadata generated at a future point in the * computation. * * * Return: Non-negative on success/Negative on failure or if * write is not permitted. * * Programmer: John Mainzer * 9/16/05 * *------------------------------------------------------------------------- */ herr_t H5C_flush_to_min_clean(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id) { H5C_t * cache_ptr; herr_t result; hbool_t first_flush = TRUE; hbool_t write_permitted; #if 0 /* modified code -- commented out for now */ int i; int flushed_entries_count = 0; size_t flushed_entries_size = 0; size_t space_needed = 0; haddr_t * flushed_entries_list = NULL; H5C_cache_entry_t * entry_ptr = NULL; #endif /* JRM */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(FAIL) HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); if ( cache_ptr->check_write_permitted != NULL ) { result = (cache_ptr->check_write_permitted)(f, primary_dxpl_id, &write_permitted); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Can't get write_permitted") } } else { write_permitted = cache_ptr->write_permitted; } if ( ! write_permitted ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "cache write is not permitted!?!\n"); } #if 1 /* original code */ result = H5C_make_space_in_cache(f, primary_dxpl_id, secondary_dxpl_id, (size_t)0, write_permitted, &first_flush); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "H5C_make_space_in_cache failed.") } #else /* modified code -- commented out for now */ if ( cache_ptr->max_cache_size > cache_ptr->index_size ) { if ( ((cache_ptr->max_cache_size - cache_ptr->index_size) + cache_ptr->cLRU_list_size) >= cache_ptr->min_clean_size ) { space_needed = 0; } else { space_needed = cache_ptr->min_clean_size - ((cache_ptr->max_cache_size - cache_ptr->index_size) + cache_ptr->cLRU_list_size); } } else { if ( cache_ptr->min_clean_size <= cache_ptr->cLRU_list_size ) { space_needed = 0; } else { space_needed = cache_ptr->min_clean_size - cache_ptr->cLRU_list_size; } } if ( space_needed > 0 ) { /* we have work to do */ HDassert( cache_ptr->slist_len > 0 ); /* allocate an array to keep a list of the entries that we * mark for flush. We need this list to touch up the LRU * list after the flush. */ flushed_entries_list = (haddr_t *)H5MM_malloc(sizeof(haddr_t) * (size_t)(cache_ptr->slist_len)); if ( flushed_entries_list == NULL ) { HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, \ "memory allocation failed for flushed entries list") } /* Scan the dirty LRU list from tail forward and mark sufficient * entries to free up the necessary space. Keep a list of the * entries marked in the order in which they are encountered. */ entry_ptr = cache_ptr->dLRU_tail_ptr; while ( ( flushed_entries_size < space_needed ) && ( flushed_entries_count < cache_ptr->slist_len ) && ( entry_ptr != NULL ) ) { HDassert( ! (entry_ptr->is_protected) ); HDassert( ! (entry_ptr->is_read_only) ); HDassert( entry_ptr->ro_ref_count == 0 ); HDassert( entry_ptr->is_dirty ); HDassert( entry_ptr->in_slist ); entry_ptr->flush_marker = TRUE; flushed_entries_size += entry_ptr->size; flushed_entries_list[flushed_entries_count] = entry_ptr->addr; flushed_entries_count++; entry_ptr = entry_ptr->aux_prev; } HDassert( flushed_entries_count <= cache_ptr->slist_len ); HDassert( flushed_entries_size >= space_needed ); /* Flush the marked entries */ result = H5C_flush_cache(f, primary_dxpl_id, secondary_dxpl_id, H5C__FLUSH_MARKED_ENTRIES_FLAG | H5C__FLUSH_IGNORE_PROTECTED_FLAG); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "H5C_flush_cache failed.") } /* Now touch up the LRU list so as to place the flushed entries in * the order they they would be in if we had flushed them in the * order we encountered them in. */ i = 0; while ( i < flushed_entries_count ) { H5C__SEARCH_INDEX_NO_STATS(cache_ptr, flushed_entries_list[i], \ entry_ptr, FAIL) /* At present, the above search must always succeed. However, * that may change. Write the code so we need only remove the * following assert in that event. */ HDassert( entry_ptr != NULL ); H5C__FAKE_RP_FOR_MOST_RECENT_ACCESS(cache_ptr, entry_ptr, FAIL) i++; } } /* if ( space_needed > 0 ) */ #endif /* end modified code -- commented out for now */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_flush_to_min_clean() */ /*------------------------------------------------------------------------- * Function: H5C_get_cache_auto_resize_config * * Purpose: Copy the current configuration of the cache automatic * re-sizing function into the instance of H5C_auto_size_ctl_t * pointed to by config_ptr. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer * 10/8/04 * *------------------------------------------------------------------------- */ herr_t H5C_get_cache_auto_resize_config(const H5C_t * cache_ptr, H5C_auto_size_ctl_t *config_ptr) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } if ( config_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad config_ptr on entry.") } *config_ptr = cache_ptr->resize_ctl; config_ptr->set_initial_size = FALSE; config_ptr->initial_size = cache_ptr->max_cache_size; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_get_cache_auto_resize_config() */ /*------------------------------------------------------------------------- * Function: H5C_get_cache_size * * Purpose: Return the cache maximum size, the minimum clean size, the * current size, and the current number of entries in * *max_size_ptr, *min_clean_size_ptr, *cur_size_ptr, and * *cur_num_entries_ptr respectively. If any of these * parameters are NULL, skip that value. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer * 10/8/04 * *------------------------------------------------------------------------- */ herr_t H5C_get_cache_size(H5C_t * cache_ptr, size_t * max_size_ptr, size_t * min_clean_size_ptr, size_t * cur_size_ptr, int32_t * cur_num_entries_ptr) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } if ( max_size_ptr != NULL ) { *max_size_ptr = cache_ptr->max_cache_size; } if ( min_clean_size_ptr != NULL ) { *min_clean_size_ptr = cache_ptr->min_clean_size; } if ( cur_size_ptr != NULL ) { *cur_size_ptr = cache_ptr->index_size; } if ( cur_num_entries_ptr != NULL ) { *cur_num_entries_ptr = cache_ptr->index_len; } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_get_cache_size() */ /*------------------------------------------------------------------------- * Function: H5C_get_cache_hit_rate * * Purpose: Compute and return the current cache hit rate in * *hit_rate_ptr. If there have been no accesses since the * last time the cache hit rate stats were reset, set * *hit_rate_ptr to 0.0. On error, *hit_rate_ptr is * undefined. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer * 10/7/04 * *------------------------------------------------------------------------- */ herr_t H5C_get_cache_hit_rate(H5C_t * cache_ptr, double * hit_rate_ptr) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } if ( hit_rate_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad hit_rate_ptr on entry.") } HDassert( cache_ptr->cache_hits >= 0 ); HDassert( cache_ptr->cache_accesses >= cache_ptr->cache_hits ); if ( cache_ptr->cache_accesses > 0 ) { *hit_rate_ptr = ((double)(cache_ptr->cache_hits)) / ((double)(cache_ptr->cache_accesses)); } else { *hit_rate_ptr = 0.0; } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_get_cache_hit_rate() */ /*------------------------------------------------------------------------- * * Function: H5C_get_entry_status * * Purpose: This function is used to determine whether the cache * contains an entry with the specified base address. If * the entry exists, it also reports some status information * on the entry. * * Status information is reported in the locations pointed * to by the size_ptr, in_cache_ptr, is_dirty_ptr, and * is_protected_ptr. While in_cache_ptr must be defined, * the remaining pointers may be NULL, in which case the * associated data is not reported. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 7/1/05 * *------------------------------------------------------------------------- */ herr_t H5C_get_entry_status(const H5F_t *f, haddr_t addr, size_t * size_ptr, hbool_t * in_cache_ptr, hbool_t * is_dirty_ptr, hbool_t * is_protected_ptr, hbool_t * is_pinned_ptr, hbool_t * is_flush_dep_parent_ptr, hbool_t * is_flush_dep_child_ptr) { H5C_t * cache_ptr; H5C_cache_entry_t * entry_ptr = NULL; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( H5F_addr_defined(addr) ); HDassert( in_cache_ptr != NULL ); /* this test duplicates two of the above asserts, but we need an * invocation of HGOTO_ERROR to keep the compiler happy. */ if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } H5C__SEARCH_INDEX(cache_ptr, addr, entry_ptr, FAIL) if ( entry_ptr == NULL ) { /* the entry doesn't exist in the cache -- report this * and quit. */ *in_cache_ptr = FALSE; } else { *in_cache_ptr = TRUE; if ( size_ptr != NULL ) { *size_ptr = entry_ptr->size; } if ( is_dirty_ptr != NULL ) { *is_dirty_ptr = entry_ptr->is_dirty; } if ( is_protected_ptr != NULL ) { *is_protected_ptr = entry_ptr->is_protected; } if ( is_pinned_ptr != NULL ) { *is_pinned_ptr = entry_ptr->is_pinned; } if ( is_flush_dep_parent_ptr != NULL ) { *is_flush_dep_parent_ptr = (entry_ptr->flush_dep_nchildren > 0); } if ( is_flush_dep_child_ptr != NULL ) { *is_flush_dep_child_ptr = (entry_ptr->flush_dep_nparents > 0); } } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_get_entry_status() */ /*------------------------------------------------------------------------- * Function: H5C_get_evictions_enabled() * * Purpose: Copy the current value of cache_ptr->evictions_enabled into * *evictions_enabled_ptr. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer * 7/27/07 * *------------------------------------------------------------------------- */ herr_t H5C_get_evictions_enabled(const H5C_t *cache_ptr, hbool_t * evictions_enabled_ptr) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } if ( evictions_enabled_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Bad evictions_enabled_ptr on entry.") } *evictions_enabled_ptr = cache_ptr->evictions_enabled; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_get_evictions_enabled() */ /*------------------------------------------------------------------------- * Function: H5C_get_trace_file_ptr * * Purpose: Get the trace_file_ptr field from the cache. * * This field will either be NULL (which indicates that trace * file logging is turned off), or contain a pointer to the * open file to which trace file data is to be written. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 1/20/06 * *------------------------------------------------------------------------- */ herr_t H5C_get_trace_file_ptr(const H5C_t *cache_ptr, FILE **trace_file_ptr_ptr) { FUNC_ENTER_NOAPI_NOERR HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); HDassert(trace_file_ptr_ptr); *trace_file_ptr_ptr = cache_ptr->trace_file_ptr; FUNC_LEAVE_NOAPI(SUCCEED) } /* H5C_get_trace_file_ptr() */ /*------------------------------------------------------------------------- * Function: H5C_get_trace_file_ptr_from_entry * * Purpose: Get the trace_file_ptr field from the cache, via an entry. * * This field will either be NULL (which indicates that trace * file logging is turned off), or contain a pointer to the * open file to which trace file data is to be written. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * 6/9/08 * *------------------------------------------------------------------------- */ herr_t H5C_get_trace_file_ptr_from_entry(const H5C_cache_entry_t *entry_ptr, FILE **trace_file_ptr_ptr) { FUNC_ENTER_NOAPI_NOERR /* Sanity checks */ HDassert(entry_ptr); HDassert(entry_ptr->cache_ptr); H5C_get_trace_file_ptr(entry_ptr->cache_ptr, trace_file_ptr_ptr); FUNC_LEAVE_NOAPI(SUCCEED) } /* H5C_get_trace_file_ptr_from_entry() */ /*------------------------------------------------------------------------- * Function: H5C_insert_entry * * Purpose: Adds the specified thing to the cache. The thing need not * exist on disk yet, but it must have an address and disk * space reserved. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the insertion (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). This is useful in the * metadata cache, but may not be needed elsewhere. If so, * just use the same dxpl_id for both parameters. * * The primary_dxpl_id is the dxpl_id passed to the * check_write_permitted function if such a function has been * provided. * * Observe that this function cannot occasion a read. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 6/2/04 * *------------------------------------------------------------------------- */ herr_t H5C_insert_entry(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, const H5C_class_t * type, haddr_t addr, void * thing, unsigned int flags) { H5C_t * cache_ptr; herr_t result; hbool_t first_flush = TRUE; hbool_t insert_pinned; hbool_t flush_last; #ifdef H5_HAVE_PARALLEL hbool_t flush_collectively; #endif hbool_t set_flush_marker; hbool_t write_permitted = TRUE; size_t empty_space; H5C_cache_entry_t * entry_ptr; H5C_cache_entry_t * test_entry_ptr; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( type ); HDassert( type->flush ); HDassert( type->size ); HDassert( H5F_addr_defined(addr) ); HDassert( thing ); #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_verify_not_in_index(cache_ptr, (H5C_cache_entry_t *)thing) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "thing already in index.\n"); } #endif /* H5C_DO_SANITY_CHECKS */ #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ set_flush_marker = ( (flags & H5C__SET_FLUSH_MARKER_FLAG) != 0 ); insert_pinned = ( (flags & H5C__PIN_ENTRY_FLAG) != 0 ); flush_last = ( (flags & H5C__FLUSH_LAST_FLAG) != 0 ); #ifdef H5_HAVE_PARALLEL flush_collectively = ( (flags & H5C__FLUSH_COLLECTIVELY_FLAG) != 0 ); #endif entry_ptr = (H5C_cache_entry_t *)thing; /* verify that the new entry isn't already in the hash table -- scream * and die if it is. */ H5C__SEARCH_INDEX(cache_ptr, addr, test_entry_ptr, FAIL) if ( test_entry_ptr != NULL ) { if ( test_entry_ptr == entry_ptr ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTINS, FAIL, \ "entry already in cache.") } else { HGOTO_ERROR(H5E_CACHE, H5E_CANTINS, FAIL, \ "duplicate entry in cache.") } } #ifndef NDEBUG entry_ptr->magic = H5C__H5C_CACHE_ENTRY_T_MAGIC; #endif /* NDEBUG */ entry_ptr->cache_ptr = cache_ptr; entry_ptr->addr = addr; entry_ptr->type = type; /* Apply tag to newly inserted entry */ if(H5C_tag_entry(cache_ptr, entry_ptr, primary_dxpl_id) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTTAG, FAIL, "Cannot tag entry") entry_ptr->is_protected = FALSE; entry_ptr->is_read_only = FALSE; entry_ptr->ro_ref_count = 0; entry_ptr->is_pinned = insert_pinned; entry_ptr->pinned_from_client = insert_pinned; entry_ptr->flush_me_last = flush_last; #ifdef H5_HAVE_PARALLEL entry_ptr->flush_me_collectively = flush_collectively; #endif /* newly inserted entries are assumed to be dirty */ entry_ptr->is_dirty = TRUE; /* not protected, so can't be dirtied */ entry_ptr->dirtied = FALSE; /* Retrieve the size of the thing */ if((type->size)(f, thing, &(entry_ptr->size)) < 0) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTGETSIZE, FAIL, "Can't get size of thing") HDassert(entry_ptr->size > 0 && entry_ptr->size < H5C_MAX_ENTRY_SIZE); entry_ptr->in_slist = FALSE; #ifdef H5_HAVE_PARALLEL entry_ptr->clear_on_unprotect = FALSE; entry_ptr->flush_immediately = FALSE; #endif /* H5_HAVE_PARALLEL */ entry_ptr->flush_in_progress = FALSE; entry_ptr->destroy_in_progress = FALSE; entry_ptr->free_file_space_on_destroy = FALSE; /* Initialize flush dependency height fields */ entry_ptr->flush_dep_parent = NULL; entry_ptr->flush_dep_nparents = 0; entry_ptr->flush_dep_parent_nalloc = 0; entry_ptr->flush_dep_nchildren = 0; entry_ptr->flush_dep_ndirty_children = 0; entry_ptr->ht_next = NULL; entry_ptr->ht_prev = NULL; entry_ptr->next = NULL; entry_ptr->prev = NULL; entry_ptr->aux_next = NULL; entry_ptr->aux_prev = NULL; H5C__RESET_CACHE_ENTRY_STATS(entry_ptr) if ( ( cache_ptr->flash_size_increase_possible ) && ( entry_ptr->size > cache_ptr->flash_size_increase_threshold ) ) { result = H5C__flash_increase_cache_size(cache_ptr, 0, entry_ptr->size); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTINS, FAIL, \ "H5C__flash_increase_cache_size failed.") } } if ( cache_ptr->index_size >= cache_ptr->max_cache_size ) { empty_space = 0; } else { empty_space = cache_ptr->max_cache_size - cache_ptr->index_size; } if ( ( cache_ptr->evictions_enabled ) && ( ( (cache_ptr->index_size + entry_ptr->size) > cache_ptr->max_cache_size ) || ( ( ( empty_space + cache_ptr->clean_index_size ) < cache_ptr->min_clean_size ) ) ) ) { size_t space_needed; if ( empty_space <= entry_ptr->size ) { cache_ptr->cache_full = TRUE; } if ( cache_ptr->check_write_permitted != NULL ) { result = (cache_ptr->check_write_permitted)(f, primary_dxpl_id, &write_permitted); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTINS, FAIL, \ "Can't get write_permitted") } } else { write_permitted = cache_ptr->write_permitted; } HDassert( entry_ptr->size <= H5C_MAX_ENTRY_SIZE ); space_needed = entry_ptr->size; if ( space_needed > cache_ptr->max_cache_size ) { space_needed = cache_ptr->max_cache_size; } /* Note that space_needed is just the amount of space that * needed to insert the new entry without exceeding the cache * size limit. The subsequent call to H5C_make_space_in_cache() * may evict the entries required to free more or less space * depending on conditions. It MAY be less if the cache is * currently undersized, or more if the cache is oversized. * * The cache can exceed its maximum size limit via the following * mechanisms: * * First, it is possible for the cache to grow without * bound as long as entries are protected and not unprotected. * * Second, when writes are not permitted it is also possible * for the cache to grow without bound. * * Finally, we usually don't check to see if the cache is * oversized at the end of an unprotect. As a result, it is * possible to have a vastly oversized cache with no protected * entries as long as all the protects preceed the unprotects. * * Since items 1 and 2 are not changing any time soon, I see * no point in worrying about the third. */ result = H5C_make_space_in_cache(f, primary_dxpl_id, secondary_dxpl_id, space_needed, write_permitted, &first_flush); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTINS, FAIL, \ "H5C_make_space_in_cache failed.") } } H5C__INSERT_IN_INDEX(cache_ptr, entry_ptr, FAIL) /* New entries are presumed to be dirty, so this if statement is * unnecessary. Rework it once the rest of the code changes are * in and tested. -- JRM */ if ( entry_ptr->is_dirty ) { entry_ptr->flush_marker = set_flush_marker; H5C__INSERT_ENTRY_IN_SLIST(cache_ptr, entry_ptr, FAIL) } else { entry_ptr->flush_marker = FALSE; } H5C__UPDATE_RP_FOR_INSERTION(cache_ptr, entry_ptr, FAIL) #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ /* If the entry's type has a 'notify' callback send a 'after insertion' * notice now that the entry is fully integrated into the cache. */ if(entry_ptr->type->notify && (entry_ptr->type->notify)(H5C_NOTIFY_ACTION_AFTER_INSERT, entry_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTNOTIFY, FAIL, "can't notify client about entry inserted into cache") H5C__UPDATE_STATS_FOR_INSERTION(cache_ptr, entry_ptr) done: #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_insert_entry() */ /*------------------------------------------------------------------------- * * Function: H5C_mark_entries_as_clean * * Purpose: When the H5C code is used to implement the metadata caches * in PHDF5, only the cache with MPI_rank 0 is allowed to * actually write entries to disk -- all other caches must * retain dirty entries until they are advised that the * entries are clean. * * This function exists to allow the H5C code to receive these * notifications. * * The function receives a list of entry base addresses * which must refer to dirty entries in the cache. If any * of the entries are either clean or don't exist, the * function flags an error. * * The function scans the list of entries and flushes all * those that are currently unprotected with the * H5C__FLUSH_CLEAR_ONLY_FLAG. Those that are currently * protected are flagged for clearing when they are * unprotected. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 7/5/05 * *------------------------------------------------------------------------- */ #ifdef H5_HAVE_PARALLEL herr_t H5C_mark_entries_as_clean(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, int32_t ce_array_len, haddr_t * ce_array_ptr) { H5C_t * cache_ptr; hbool_t first_flush = TRUE; int entries_cleared; int entries_examined; int i; int initial_list_len; haddr_t addr; #if H5C_DO_SANITY_CHECKS int pinned_entries_marked = 0; int protected_entries_marked = 0; int other_entries_marked = 0; haddr_t last_addr; #endif /* H5C_DO_SANITY_CHECKS */ H5C_cache_entry_t * clear_ptr = NULL; H5C_cache_entry_t * entry_ptr = NULL; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( ce_array_len > 0 ); HDassert( ce_array_ptr != NULL ); #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HDassert(0); HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ for ( i = 0; i < ce_array_len; i++ ) { addr = ce_array_ptr[i]; #if H5C_DO_SANITY_CHECKS if ( i == 0 ) { last_addr = addr; } else { if ( last_addr == addr ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Duplicate entry in cleaned list.\n"); } else if ( last_addr > addr ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "cleaned list not sorted.\n"); } } #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HDassert(0); HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ #endif /* H5C_DO_SANITY_CHECKS */ HDassert( H5F_addr_defined(addr) ); H5C__SEARCH_INDEX(cache_ptr, addr, entry_ptr, FAIL) if ( entry_ptr == NULL ) { #if H5C_DO_SANITY_CHECKS HDfprintf(stdout, "H5C_mark_entries_as_clean: entry[%d] = %ld not in cache.\n", (int)i, (long)addr); #endif /* H5C_DO_SANITY_CHECKS */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Listed entry not in cache?!?!?.") } else if ( ! entry_ptr->is_dirty ) { #if H5C_DO_SANITY_CHECKS HDfprintf(stdout, "H5C_mark_entries_as_clean: entry %ld is not dirty!?!\n", (long)addr); #endif /* H5C_DO_SANITY_CHECKS */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Listed entry not dirty?!?!?.") #if 0 /* original code */ } else if ( entry_ptr->is_protected ) { entry_ptr->clear_on_unprotect = TRUE; } else { if ( H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, addr, H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't clear entry.") } } #else /* modified code */ } else { /* Mark the entry to be cleared on unprotect. We will * scan the LRU list shortly, and clear all those entries * not currently protected. */ entry_ptr->clear_on_unprotect = TRUE; #if H5C_DO_SANITY_CHECKS if ( entry_ptr->is_protected ) { protected_entries_marked++; } else if ( entry_ptr->is_pinned ) { pinned_entries_marked++; } else { other_entries_marked++; } #endif /* H5C_DO_SANITY_CHECKS */ } #endif /* end modified code */ } #if 1 /* modified code */ /* Scan through the LRU list from back to front, and flush the * entries whose clear_on_unprotect flags are set. Observe that * any protected entries will not be on the LRU, and therefore * will not be flushed at this time. */ entries_cleared = 0; entries_examined = 0; initial_list_len = cache_ptr->LRU_list_len; entry_ptr = cache_ptr->LRU_tail_ptr; while ( ( entry_ptr != NULL ) && ( entries_examined <= initial_list_len ) && ( entries_cleared < ce_array_len ) ) { if ( entry_ptr->clear_on_unprotect ) { entry_ptr->clear_on_unprotect = FALSE; clear_ptr = entry_ptr; entry_ptr = entry_ptr->prev; entries_cleared++; if ( H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, clear_ptr->type, clear_ptr->addr, H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't clear entry.") } } else { entry_ptr = entry_ptr->prev; } entries_examined++; } #if H5C_DO_SANITY_CHECKS HDassert( entries_cleared == other_entries_marked ); #endif /* H5C_DO_SANITY_CHECKS */ /* It is also possible that some of the cleared entries are on the * pinned list. Must scan that also. */ entry_ptr = cache_ptr->pel_head_ptr; while ( entry_ptr != NULL ) { if ( entry_ptr->clear_on_unprotect ) { entry_ptr->clear_on_unprotect = FALSE; clear_ptr = entry_ptr; entry_ptr = entry_ptr->next; entries_cleared++; if ( H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, clear_ptr->type, clear_ptr->addr, H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't clear entry.") } } else { entry_ptr = entry_ptr->next; } } #if H5C_DO_SANITY_CHECKS HDassert( entries_cleared == pinned_entries_marked + other_entries_marked ); HDassert( entries_cleared + protected_entries_marked == ce_array_len ); #endif /* H5C_DO_SANITY_CHECKS */ HDassert( ( entries_cleared == ce_array_len ) || ( (ce_array_len - entries_cleared) <= cache_ptr->pl_len ) ); #if H5C_DO_SANITY_CHECKS i = 0; entry_ptr = cache_ptr->pl_head_ptr; while ( entry_ptr != NULL ) { if ( entry_ptr->clear_on_unprotect ) { i++; } entry_ptr = entry_ptr->next; } HDassert( (entries_cleared + i) == ce_array_len ); #endif /* H5C_DO_SANITY_CHECKS */ #endif /* modified code */ done: #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HDassert(0); HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_mark_entries_as_clean() */ #endif /* H5_HAVE_PARALLEL */ /*------------------------------------------------------------------------- * Function: H5C_mark_entry_dirty * * Purpose: Mark a pinned or protected entry as dirty. The target entry * MUST be either pinned or protected, and MAY be both. * * In the protected case, this call is the functional * equivalent of setting the H5C__DIRTIED_FLAG on an unprotect * call. * * In the pinned but not protected case, if the entry is not * already dirty, the function places function marks the entry * dirty and places it on the skip list. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 5/15/06 * * JRM -- 11/5/08 * Added call to H5C__UPDATE_INDEX_FOR_ENTRY_DIRTY() to * update the new clean_index_size and dirty_index_size * fields of H5C_t in the case that the entry was clean * prior to this call, and is pinned and not protected. * *------------------------------------------------------------------------- */ herr_t H5C_mark_entry_dirty(void *thing) { H5C_t * cache_ptr; H5C_cache_entry_t * entry_ptr = (H5C_cache_entry_t *)thing; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity checks */ HDassert(entry_ptr); HDassert(H5F_addr_defined(entry_ptr->addr)); cache_ptr = entry_ptr->cache_ptr; HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); if ( entry_ptr->is_protected ) { HDassert( ! ((entry_ptr)->is_read_only) ); /* set the dirtied flag */ entry_ptr->dirtied = TRUE; } else if ( entry_ptr->is_pinned ) { hbool_t was_pinned_unprotected_and_clean; was_pinned_unprotected_and_clean = ! ( entry_ptr->is_dirty ); /* mark the entry as dirty if it isn't already */ entry_ptr->is_dirty = TRUE; /* Propagate the dirty flag up the flush dependency chain if appropriate */ if ( was_pinned_unprotected_and_clean ) { H5C__UPDATE_INDEX_FOR_ENTRY_DIRTY(cache_ptr, entry_ptr); if ( ( entry_ptr->flush_dep_ndirty_children == 0) && ( entry_ptr->flush_dep_nparents > 0 ) ) { if ( H5C__mark_flush_dep_dirty(entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Can't propagate flush dep dirty flag") } } } if ( ! (entry_ptr->in_slist) ) { H5C__INSERT_ENTRY_IN_SLIST(cache_ptr, entry_ptr, FAIL) } H5C__UPDATE_STATS_FOR_DIRTY_PIN(cache_ptr, entry_ptr) } else { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Entry is neither pinned nor protected??") } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_mark_entry_dirty() */ /*------------------------------------------------------------------------- * * Function: H5C_move_entry * * Purpose: Use this function to notify the cache that an entry's * file address changed. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 6/2/04 * * JRM -- 11/5/08 * On review this function looks like no change is needed to * support the new clean_index_size and dirty_index_size * fields of H5C_t. * *------------------------------------------------------------------------- */ herr_t H5C_move_entry(H5C_t * cache_ptr, const H5C_class_t * type, haddr_t old_addr, haddr_t new_addr) { hbool_t was_dirty; H5C_cache_entry_t * entry_ptr = NULL; H5C_cache_entry_t * test_entry_ptr = NULL; #if H5C_DO_SANITY_CHECKS hbool_t removed_entry_from_slist = FALSE; #endif /* H5C_DO_SANITY_CHECKS */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( type ); HDassert( H5F_addr_defined(old_addr) ); HDassert( H5F_addr_defined(new_addr) ); HDassert( H5F_addr_ne(old_addr, new_addr) ); #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ H5C__SEARCH_INDEX(cache_ptr, old_addr, entry_ptr, FAIL) if ( ( entry_ptr == NULL ) || ( entry_ptr->type != type ) ) { /* the old item doesn't exist in the cache, so we are done. */ HGOTO_DONE(SUCCEED) } HDassert( entry_ptr->addr == old_addr ); HDassert( entry_ptr->type == type ); if ( entry_ptr->is_protected ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMOVE, FAIL, \ "Target entry is protected.") } H5C__SEARCH_INDEX(cache_ptr, new_addr, test_entry_ptr, FAIL) if ( test_entry_ptr != NULL ) { /* we are hosed */ if ( test_entry_ptr->type == type ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMOVE, FAIL, \ "Target already moved & reinserted???.") } else { HGOTO_ERROR(H5E_CACHE, H5E_CANTMOVE, FAIL, \ "New address already in use?.") } } /* If we get this far we have work to do. Remove *entry_ptr from * the hash table (and skip list if necessary), change its address to the * new address, mark it as dirty (if it isn't already) and then re-insert. * * Update the replacement policy for a hit to avoid an eviction before * the moved entry is touched. Update stats for a move. * * Note that we do not check the size of the cache, or evict anything. * Since this is a simple re-name, cache size should be unaffected. * * Check to see if the target entry is in the process of being destroyed * before we delete from the index, etc. If it is, all we do is * change the addr. If the entry is only in the process of being flushed, * don't mark it as dirty either, lest we confuse the flush call back. */ if ( ! ( entry_ptr->destroy_in_progress ) ) { H5C__DELETE_FROM_INDEX(cache_ptr, entry_ptr) if ( entry_ptr->in_slist ) { HDassert( cache_ptr->slist_ptr ); H5C__REMOVE_ENTRY_FROM_SLIST(cache_ptr, entry_ptr) #if H5C_DO_SANITY_CHECKS removed_entry_from_slist = TRUE; #endif /* H5C_DO_SANITY_CHECKS */ } } entry_ptr->addr = new_addr; if ( ! ( entry_ptr->destroy_in_progress ) ) { was_dirty = entry_ptr->is_dirty; if ( ! ( entry_ptr->flush_in_progress ) ) { entry_ptr->is_dirty = TRUE; /* Propagate the dirty flag up the flush dependency chain if * appropriate */ if ( ! ( was_dirty ) ) { if ( ( entry_ptr->flush_dep_ndirty_children == 0) && ( entry_ptr->flush_dep_nparents > 0 ) ) { if ( H5C__mark_flush_dep_dirty(entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Can't propagate flush dep dirty flag") } } } } H5C__INSERT_IN_INDEX(cache_ptr, entry_ptr, FAIL) if ( ! ( entry_ptr->flush_in_progress ) ) { H5C__INSERT_ENTRY_IN_SLIST(cache_ptr, entry_ptr, FAIL) #if H5C_DO_SANITY_CHECKS if ( removed_entry_from_slist ) { /* we just removed the entry from the slist. Thus we * must touch up cache_ptr->slist_len_increase and * cache_ptr->slist_size_increase to keep from skewing * the sanity checks. */ HDassert( cache_ptr->slist_len_increase > 1 ); HDassert( cache_ptr->slist_size_increase > entry_ptr->size ); cache_ptr->slist_len_increase -= 1; cache_ptr->slist_size_increase -= entry_ptr->size; } #endif /* H5C_DO_SANITY_CHECKS */ H5C__UPDATE_RP_FOR_MOVE(cache_ptr, entry_ptr, was_dirty, FAIL) } } H5C__UPDATE_STATS_FOR_MOVE(cache_ptr, entry_ptr) done: #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_move_entry() */ /*------------------------------------------------------------------------- * Function: H5C_resize_entry * * Purpose: Resize a pinned or protected entry. * * Resizing an entry dirties it, so if the entry is not * already dirty, the function places the entry on the * skip list. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 7/5/06 * *------------------------------------------------------------------------- */ herr_t H5C_resize_entry(void *thing, size_t new_size) { H5C_t * cache_ptr; H5C_cache_entry_t * entry_ptr = (H5C_cache_entry_t *)thing; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity checks */ HDassert(entry_ptr); HDassert(H5F_addr_defined(entry_ptr->addr)); cache_ptr = entry_ptr->cache_ptr; HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Check for usage errors */ if(new_size <= 0) HGOTO_ERROR(H5E_CACHE, H5E_BADVALUE, FAIL, "New size is non-positive.") if(!(entry_ptr->is_pinned || entry_ptr->is_protected)) HGOTO_ERROR(H5E_CACHE, H5E_BADTYPE, FAIL, "Entry isn't pinned or protected??") /* update for change in entry size if necessary */ if ( entry_ptr->size != new_size ) { hbool_t was_clean; /* make note of whether the entry was clean to begin with */ was_clean = ! ( entry_ptr->is_dirty ); /* mark the entry as dirty if it isn't already */ entry_ptr->is_dirty = TRUE; /* Propagate the dirty flag up the flush dependency chain if * appropriate */ if ( was_clean ) { if ( ( entry_ptr->flush_dep_ndirty_children == 0) && ( entry_ptr->flush_dep_nparents > 0 ) ) { if ( H5C__mark_flush_dep_dirty(entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Can't propagate flush dep dirty flag") } } } /* do a flash cache size increase if appropriate */ if ( cache_ptr->flash_size_increase_possible ) { if ( new_size > entry_ptr->size ) { size_t size_increase; size_increase = new_size - entry_ptr->size; if(size_increase >= cache_ptr->flash_size_increase_threshold) { if(H5C__flash_increase_cache_size(cache_ptr, entry_ptr->size, new_size) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTRESIZE, FAIL, "flash cache increase failed") } } } /* update the pinned and/or protected entry list */ if(entry_ptr->is_pinned) { H5C__DLL_UPDATE_FOR_SIZE_CHANGE((cache_ptr->pel_len), \ (cache_ptr->pel_size), \ (entry_ptr->size), (new_size)) } /* end if */ if(entry_ptr->is_protected) { H5C__DLL_UPDATE_FOR_SIZE_CHANGE((cache_ptr->pl_len), \ (cache_ptr->pl_size), \ (entry_ptr->size), (new_size)) } /* end if */ /* update the hash table */ H5C__UPDATE_INDEX_FOR_SIZE_CHANGE((cache_ptr), (entry_ptr->size),\ (new_size), (entry_ptr), (was_clean)); /* if the entry is in the skip list, update that too */ if ( entry_ptr->in_slist ) { H5C__UPDATE_SLIST_FOR_SIZE_CHANGE((cache_ptr), (entry_ptr->size),\ (new_size)); } /* end if */ /* update statistics just before changing the entry size */ H5C__UPDATE_STATS_FOR_ENTRY_SIZE_CHANGE((cache_ptr), (entry_ptr), \ (new_size)); /* finally, update the entry size proper */ entry_ptr->size = new_size; if(!entry_ptr->in_slist) { H5C__INSERT_ENTRY_IN_SLIST(cache_ptr, entry_ptr, FAIL) } /* end if */ if(entry_ptr->is_pinned) { H5C__UPDATE_STATS_FOR_DIRTY_PIN(cache_ptr, entry_ptr) } /* end if */ } /* end if */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_resize_entry() */ /*------------------------------------------------------------------------- * Function: H5C_pin_entry_from_client() * * Purpose: Internal routine to pin a cache entry from a client action. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * 3/26/09 * *------------------------------------------------------------------------- */ #ifndef NDEBUG static herr_t H5C_pin_entry_from_client(H5C_t * cache_ptr, H5C_cache_entry_t * entry_ptr) #else static herr_t H5C_pin_entry_from_client(H5C_t UNUSED * cache_ptr, H5C_cache_entry_t * entry_ptr) #endif { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT /* Sanity checks */ HDassert( cache_ptr ); HDassert( entry_ptr ); /* Check if the entry is already pinned */ if(entry_ptr->is_pinned) { /* Check if the entry was pinned through an explicit pin from a client */ if(entry_ptr->pinned_from_client) HGOTO_ERROR(H5E_CACHE, H5E_CANTPIN, FAIL, "Entry is already pinned") } /* end if */ else { entry_ptr->is_pinned = TRUE; H5C__UPDATE_STATS_FOR_PIN(cache_ptr, entry_ptr) } /* end else */ /* Mark that the entry was pinned through an explicit pin from a client */ entry_ptr->pinned_from_client = TRUE; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_pin_entry_from_client() */ /*------------------------------------------------------------------------- * Function: H5C_pin_protected_entry() * * Purpose: Pin a protected cache entry. The entry must be protected * at the time of call, and must be unpinned. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 4/26/06 * *------------------------------------------------------------------------- */ herr_t H5C_pin_protected_entry(void *thing) { H5C_t * cache_ptr; H5C_cache_entry_t * entry_ptr = (H5C_cache_entry_t *)thing; /* Pointer to entry to pin */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity checks */ HDassert(entry_ptr); HDassert(H5F_addr_defined(entry_ptr->addr)); cache_ptr = entry_ptr->cache_ptr; HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Only protected entries can be pinned */ if(!entry_ptr->is_protected) HGOTO_ERROR(H5E_CACHE, H5E_CANTPIN, FAIL, "Entry isn't protected") /* Pin the entry from a client */ if(H5C_pin_entry_from_client(cache_ptr, entry_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTPIN, FAIL, "Can't pin entry by client") done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_pin_protected_entry() */ /*------------------------------------------------------------------------- * Function: H5C_protect * * Purpose: If the target entry is not in the cache, load it. If * necessary, attempt to evict one or more entries to keep * the cache within its maximum size. * * Mark the target entry as protected, and return its address * to the caller. The caller must call H5C_unprotect() when * finished with the entry. * * While it is protected, the entry may not be either evicted * or flushed -- nor may it be accessed by another call to * H5C_protect. Any attempt to do so will result in a failure. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the insertion (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). This is useful in the * metadata cache, but may not be needed elsewhere. If so, * just use the same dxpl_id for both parameters. * * All reads are performed with the primary_dxpl_id. * * Similarly, the primary_dxpl_id is passed to the * check_write_permitted function if it is called. * * Return: Success: Ptr to the desired entry * Failure: NULL * * Programmer: John Mainzer - 6/2/04 * * JRM -- 11/13/08 * Modified function to call H5C_make_space_in_cache() when * the min_clean_size is violated, not just when there isn't * enough space for and entry that has just been loaded. * * The purpose of this modification is to avoid "metadata * blizzards" in the write only case. In such instances, * the cache was allowed to fill with dirty metadata. When * we finally needed to evict an entry to make space, we had * to flush out a whole cache full of metadata -- which has * interesting performance effects. We hope to avoid (or * perhaps more accurately hide) this effect by maintaining * the min_clean_size, which should force us to start flushing * entries long before we actually have to evict something * to make space. * *------------------------------------------------------------------------- */ void * H5C_protect(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, const H5C_class_t * type, haddr_t addr, void * udata, unsigned flags) { H5C_t * cache_ptr; hbool_t hit; hbool_t first_flush; hbool_t have_write_permitted = FALSE; hbool_t read_only = FALSE; hbool_t write_permitted; herr_t result; size_t empty_space; void * thing; H5C_cache_entry_t * entry_ptr; void * ret_value; /* Return value */ FUNC_ENTER_NOAPI(NULL) /* check args */ HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( type ); HDassert( type->flush ); HDassert( type->load ); HDassert( H5F_addr_defined(addr) ); #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HDassert(0); HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, NULL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ if ( (flags & H5C__READ_ONLY_FLAG) != 0 ) { read_only = TRUE; } /* first check to see if the target is in cache */ H5C__SEARCH_INDEX(cache_ptr, addr, entry_ptr, NULL) if ( entry_ptr != NULL ) { /* Check for trying to load the wrong type of entry from an address */ if(entry_ptr->type != type) HGOTO_ERROR(H5E_CACHE, H5E_BADTYPE, NULL, "incorrect cache entry type") hit = TRUE; thing = (void *)entry_ptr; } else { /* must try to load the entry from disk. */ hit = FALSE; thing = H5C_load_entry(f, primary_dxpl_id, type, addr, udata); if ( thing == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTLOAD, NULL, "can't load entry") } entry_ptr = (H5C_cache_entry_t *)thing; /* Apply tag to newly protected entry */ if(H5C_tag_entry(cache_ptr, entry_ptr, primary_dxpl_id) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTTAG, NULL, "Cannot tag entry") /* If the entry is very large, and we are configured to allow it, * we may wish to perform a flash cache size increase. */ if ( ( cache_ptr->flash_size_increase_possible ) && ( entry_ptr->size > cache_ptr->flash_size_increase_threshold ) ) { result = H5C__flash_increase_cache_size(cache_ptr, 0, entry_ptr->size); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "H5C__flash_increase_cache_size failed.") } } if ( cache_ptr->index_size >= cache_ptr->max_cache_size ) { empty_space = 0; } else { empty_space = cache_ptr->max_cache_size - cache_ptr->index_size; } /* try to free up if necceary and if evictions are permitted. Note * that if evictions are enabled, we will call H5C_make_space_in_cache() * regardless if the min_free_space requirement is not met. */ if ( ( cache_ptr->evictions_enabled ) && ( ( (cache_ptr->index_size + entry_ptr->size) > cache_ptr->max_cache_size) || ( ( empty_space + cache_ptr->clean_index_size ) < cache_ptr->min_clean_size ) ) ) { size_t space_needed; if ( empty_space <= entry_ptr->size ) { cache_ptr->cache_full = TRUE; } if ( cache_ptr->check_write_permitted != NULL ) { result = (cache_ptr->check_write_permitted)(f, primary_dxpl_id, &write_permitted); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "Can't get write_permitted 1") } else { have_write_permitted = TRUE; first_flush = TRUE; } } else { write_permitted = cache_ptr->write_permitted; have_write_permitted = TRUE; first_flush = TRUE; } HDassert( entry_ptr->size <= H5C_MAX_ENTRY_SIZE ); space_needed = entry_ptr->size; if ( space_needed > cache_ptr->max_cache_size ) { space_needed = cache_ptr->max_cache_size; } /* Note that space_needed is just the amount of space that * needed to insert the new entry without exceeding the cache * size limit. The subsequent call to H5C_make_space_in_cache() * may evict the entries required to free more or less space * depending on conditions. It MAY be less if the cache is * currently undersized, or more if the cache is oversized. * * The cache can exceed its maximum size limit via the following * mechanisms: * * First, it is possible for the cache to grow without * bound as long as entries are protected and not unprotected. * * Second, when writes are not permitted it is also possible * for the cache to grow without bound. * * Third, the user may choose to disable evictions -- causing * the cache to grow without bound until evictions are * re-enabled. * * Finally, we usually don't check to see if the cache is * oversized at the end of an unprotect. As a result, it is * possible to have a vastly oversized cache with no protected * entries as long as all the protects preceed the unprotects. * * Since items 1, 2, and 3 are not changing any time soon, I * see no point in worrying about the fourth. */ result = H5C_make_space_in_cache(f, primary_dxpl_id, secondary_dxpl_id, space_needed, write_permitted, &first_flush); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "H5C_make_space_in_cache failed 1.") } } /* Insert the entry in the hash table. It can't be dirty yet, so * we don't even check to see if it should go in the skip list. * * This is no longer true -- due to a bug fix, we may modify * data on load to repair a file. */ H5C__INSERT_IN_INDEX(cache_ptr, entry_ptr, NULL) if ( ( entry_ptr->is_dirty ) && ( ! (entry_ptr->in_slist) ) ) { H5C__INSERT_ENTRY_IN_SLIST(cache_ptr, entry_ptr, NULL) } /* insert the entry in the data structures used by the replacement * policy. We are just going to take it out again when we update * the replacement policy for a protect, but this simplifies the * code. If we do this often enough, we may want to optimize this. */ H5C__UPDATE_RP_FOR_INSERTION(cache_ptr, entry_ptr, NULL) } HDassert( entry_ptr->addr == addr ); HDassert( entry_ptr->type == type ); if ( entry_ptr->is_protected ) { if ( ( read_only ) && ( entry_ptr->is_read_only ) ) { HDassert( entry_ptr->ro_ref_count > 0 ); (entry_ptr->ro_ref_count)++; } else { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "Target already protected & not read only?!?.") } } else { H5C__UPDATE_RP_FOR_PROTECT(cache_ptr, entry_ptr, NULL) entry_ptr->is_protected = TRUE; if ( read_only ) { entry_ptr->is_read_only = TRUE; entry_ptr->ro_ref_count = 1; } entry_ptr->dirtied = FALSE; } H5C__UPDATE_CACHE_HIT_RATE_STATS(cache_ptr, hit) H5C__UPDATE_STATS_FOR_PROTECT(cache_ptr, entry_ptr, hit) ret_value = thing; if ( ( cache_ptr->evictions_enabled ) && ( ( cache_ptr->size_decreased ) || ( ( cache_ptr->resize_enabled ) && ( cache_ptr->cache_accesses >= (cache_ptr->resize_ctl).epoch_length ) ) ) ) { if ( ! have_write_permitted ) { if ( cache_ptr->check_write_permitted != NULL ) { result = (cache_ptr->check_write_permitted)(f, primary_dxpl_id, &write_permitted); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "Can't get write_permitted 2") } else { have_write_permitted = TRUE; first_flush = TRUE; } } else { write_permitted = cache_ptr->write_permitted; have_write_permitted = TRUE; first_flush = TRUE; } } if ( ( cache_ptr->resize_enabled ) && ( cache_ptr->cache_accesses >= (cache_ptr->resize_ctl).epoch_length ) ) { result = H5C__auto_adjust_cache_size(f, primary_dxpl_id, secondary_dxpl_id, write_permitted, &first_flush); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "Cache auto-resize failed.") } } if ( cache_ptr->size_decreased ) { cache_ptr->size_decreased = FALSE; /* check to see if the cache is now oversized due to the cache * size reduction. If it is, try to evict enough entries to * bring the cache size down to the current maximum cache size. * * Also, if the min_clean_size requirement is not met, we * should also call H5C_make_space_in_cache() to bring us * into complience. */ if ( cache_ptr->index_size >= cache_ptr->max_cache_size ) { empty_space = 0; } else { empty_space = cache_ptr->max_cache_size - cache_ptr->index_size; } if ( ( cache_ptr->index_size > cache_ptr->max_cache_size ) || ( ( empty_space + cache_ptr->clean_index_size ) < cache_ptr->min_clean_size) ) { if ( cache_ptr->index_size > cache_ptr->max_cache_size ) { cache_ptr->cache_full = TRUE; } result = H5C_make_space_in_cache(f, primary_dxpl_id, secondary_dxpl_id, (size_t)0, write_permitted, &first_flush); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTPROTECT, NULL, \ "H5C_make_space_in_cache failed 2.") } } } } /* If we loaded the entry and the entry's type has a 'notify' callback, send * a 'after insertion' notice now that the entry is fully integrated into * the cache and protected. We must wait until it is protected so it is not * evicted during the notify callback. */ if(!hit && entry_ptr->type->notify && (entry_ptr->type->notify)(H5C_NOTIFY_ACTION_AFTER_INSERT, entry_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTNOTIFY, NULL, "can't notify client about entry inserted into cache") done: #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, NULL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_protect() */ /*------------------------------------------------------------------------- * * Function: H5C_reset_cache_hit_rate_stats() * * Purpose: Reset the cache hit rate computation fields. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer, 10/5/04 * *------------------------------------------------------------------------- */ herr_t H5C_reset_cache_hit_rate_stats(H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } cache_ptr->cache_hits = 0; cache_ptr->cache_accesses = 0; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_reset_cache_hit_rate_stats() */ /*------------------------------------------------------------------------- * Function: H5C_set_cache_auto_resize_config * * Purpose: Set the cache automatic resize configuration to the * provided values if they are in range, and fail if they * are not. * * If the new configuration enables automatic cache resizing, * coerce the cache max size and min clean size into agreement * with the new policy and re-set the full cache hit rate * stats. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer * 10/8/04 * *------------------------------------------------------------------------- */ herr_t H5C_set_cache_auto_resize_config(H5C_t *cache_ptr, H5C_auto_size_ctl_t *config_ptr) { herr_t result; size_t new_max_cache_size; size_t new_min_clean_size; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } if ( config_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "NULL config_ptr on entry.") } if ( config_ptr->version != H5C__CURR_AUTO_SIZE_CTL_VER ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Unknown config version.") } /* check general configuration section of the config: */ if ( SUCCEED != H5C_validate_resize_config(config_ptr, H5C_RESIZE_CFG__VALIDATE_GENERAL) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADRANGE, FAIL, \ "error in general configuration fields of new config.") } /* check size increase control fields of the config: */ if ( SUCCEED != H5C_validate_resize_config(config_ptr, H5C_RESIZE_CFG__VALIDATE_INCREMENT) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADRANGE, FAIL, \ "error in the size increase control fields of new config.") } /* check size decrease control fields of the config: */ if ( SUCCEED != H5C_validate_resize_config(config_ptr, H5C_RESIZE_CFG__VALIDATE_DECREMENT) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADRANGE, FAIL, \ "error in the size decrease control fields of new config.") } /* check for conflicts between size increase and size decrease controls: */ if ( SUCCEED != H5C_validate_resize_config(config_ptr, H5C_RESIZE_CFG__VALIDATE_INTERACTIONS) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADRANGE, FAIL, \ "conflicting threshold fields in new config.") } /* will set the increase possible fields to FALSE later if needed */ cache_ptr->size_increase_possible = TRUE; cache_ptr->flash_size_increase_possible = TRUE; cache_ptr->size_decrease_possible = TRUE; switch ( config_ptr->incr_mode ) { case H5C_incr__off: cache_ptr->size_increase_possible = FALSE; break; case H5C_incr__threshold: if ( ( config_ptr->lower_hr_threshold <= 0.0 ) || ( config_ptr->increment <= 1.0 ) || ( ( config_ptr->apply_max_increment ) && ( config_ptr->max_increment <= 0 ) ) ) { cache_ptr->size_increase_possible = FALSE; } break; default: /* should be unreachable */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Unknown incr_mode?!?!?.") } /* logically, this is were configuration for flash cache size increases * should go. However, this configuration depends on max_cache_size, so * we wait until the end of the function, when this field is set. */ switch ( config_ptr->decr_mode ) { case H5C_decr__off: cache_ptr->size_decrease_possible = FALSE; break; case H5C_decr__threshold: if ( ( config_ptr->upper_hr_threshold >= 1.0 ) || ( config_ptr->decrement >= 1.0 ) || ( ( config_ptr->apply_max_decrement ) && ( config_ptr->max_decrement <= 0 ) ) ) { cache_ptr->size_decrease_possible = FALSE; } break; case H5C_decr__age_out: if ( ( ( config_ptr->apply_empty_reserve ) && ( config_ptr->empty_reserve >= 1.0 ) ) || ( ( config_ptr->apply_max_decrement ) && ( config_ptr->max_decrement <= 0 ) ) ) { cache_ptr->size_decrease_possible = FALSE; } break; case H5C_decr__age_out_with_threshold: if ( ( ( config_ptr->apply_empty_reserve ) && ( config_ptr->empty_reserve >= 1.0 ) ) || ( ( config_ptr->apply_max_decrement ) && ( config_ptr->max_decrement <= 0 ) ) || ( config_ptr->upper_hr_threshold >= 1.0 ) ) { cache_ptr->size_decrease_possible = FALSE; } break; default: /* should be unreachable */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Unknown decr_mode?!?!?.") } if ( config_ptr->max_size == config_ptr->min_size ) { cache_ptr->size_increase_possible = FALSE; cache_ptr->flash_size_increase_possible = FALSE; cache_ptr->size_decrease_possible = FALSE; } /* flash_size_increase_possible is intentionally omitted from the * following: */ cache_ptr->resize_enabled = cache_ptr->size_increase_possible || cache_ptr->size_decrease_possible; cache_ptr->resize_ctl = *config_ptr; /* Resize the cache to the supplied initial value if requested, or as * necessary to force it within the bounds of the current automatic * cache resizing configuration. * * Note that the min_clean_fraction may have changed, so we * go through the exercise even if the current size is within * range and an initial size has not been provided. */ if ( (cache_ptr->resize_ctl).set_initial_size ) { new_max_cache_size = (cache_ptr->resize_ctl).initial_size; } else if ( cache_ptr->max_cache_size > (cache_ptr->resize_ctl).max_size ) { new_max_cache_size = (cache_ptr->resize_ctl).max_size; } else if ( cache_ptr->max_cache_size < (cache_ptr->resize_ctl).min_size ) { new_max_cache_size = (cache_ptr->resize_ctl).min_size; } else { new_max_cache_size = cache_ptr->max_cache_size; } new_min_clean_size = (size_t) ((double)new_max_cache_size * ((cache_ptr->resize_ctl).min_clean_fraction)); /* since new_min_clean_size is of type size_t, we have * * ( 0 <= new_min_clean_size ) * * by definition. */ HDassert( new_min_clean_size <= new_max_cache_size ); HDassert( (cache_ptr->resize_ctl).min_size <= new_max_cache_size ); HDassert( new_max_cache_size <= (cache_ptr->resize_ctl).max_size ); if ( new_max_cache_size < cache_ptr->max_cache_size ) { cache_ptr->size_decreased = TRUE; } cache_ptr->max_cache_size = new_max_cache_size; cache_ptr->min_clean_size = new_min_clean_size; if ( H5C_reset_cache_hit_rate_stats(cache_ptr) != SUCCEED ) { /* this should be impossible... */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "H5C_reset_cache_hit_rate_stats failed.") } /* remove excess epoch markers if any */ if ( ( config_ptr->decr_mode == H5C_decr__age_out_with_threshold ) || ( config_ptr->decr_mode == H5C_decr__age_out ) ) { if ( cache_ptr->epoch_markers_active > (cache_ptr->resize_ctl).epochs_before_eviction ) { result = H5C__autoadjust__ageout__remove_excess_markers(cache_ptr); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "can't remove excess epoch markers.") } } } else if ( cache_ptr->epoch_markers_active > 0 ) { result = H5C__autoadjust__ageout__remove_all_markers(cache_ptr); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "error removing all epoch markers.") } } /* configure flash size increase facility. We wait until the * end of the function, as we need the max_cache_size set before * we start to keep things simple. * * If we haven't already ruled out flash cache size increases above, * go ahead and configure it. */ if ( cache_ptr->flash_size_increase_possible ) { switch ( config_ptr->flash_incr_mode ) { case H5C_flash_incr__off: cache_ptr->flash_size_increase_possible = FALSE; break; case H5C_flash_incr__add_space: cache_ptr->flash_size_increase_possible = TRUE; cache_ptr->flash_size_increase_threshold = (size_t) (((double)(cache_ptr->max_cache_size)) * ((cache_ptr->resize_ctl).flash_threshold)); break; default: /* should be unreachable */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Unknown flash_incr_mode?!?!?.") break; } } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_set_cache_auto_resize_config() */ /*------------------------------------------------------------------------- * Function: H5C_set_evictions_enabled() * * Purpose: Set cache_ptr->evictions_enabled to the value of the * evictions enabled parameter. * * Return: SUCCEED on success, and FAIL on failure. * * Programmer: John Mainzer * 7/27/07 * *------------------------------------------------------------------------- */ herr_t H5C_set_evictions_enabled(H5C_t *cache_ptr, hbool_t evictions_enabled) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr on entry.") } if ( ( evictions_enabled != TRUE ) && ( evictions_enabled != FALSE ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Bad evictions_enabled on entry.") } /* There is no fundamental reason why we should not permit * evictions to be disabled while automatic resize is enabled. * However, I can't think of any good reason why one would * want to, and allowing it would greatly complicate testing * the feature. Hence the following: */ if ( ( evictions_enabled != TRUE ) && ( ( cache_ptr->resize_ctl.incr_mode != H5C_incr__off ) || ( cache_ptr->resize_ctl.decr_mode != H5C_decr__off ) ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Can't disable evictions when auto resize enabled.") } cache_ptr->evictions_enabled = evictions_enabled; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_set_evictions_enabled() */ /*------------------------------------------------------------------------- * Function: H5C_set_prefix * * Purpose: Set the values of the prefix field of H5C_t. This * filed is used to label some debugging output. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 1/20/06 * *------------------------------------------------------------------------- */ herr_t H5C_set_prefix(H5C_t * cache_ptr, char * prefix) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( ( cache_ptr == NULL ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) || ( prefix == NULL ) || ( HDstrlen(prefix) >= H5C__PREFIX_LEN ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad param(s) on entry.") } HDstrncpy(&(cache_ptr->prefix[0]), prefix, (size_t)(H5C__PREFIX_LEN)); cache_ptr->prefix[H5C__PREFIX_LEN - 1] = '\0'; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_set_prefix() */ /*------------------------------------------------------------------------- * Function: H5C_set_trace_file_ptr * * Purpose: Set the trace_file_ptr field for the cache. * * This field must either be NULL (which turns of trace * file logging), or be a pointer to an open file to which * trace file data is to be written. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 1/20/06 * *------------------------------------------------------------------------- */ herr_t H5C_set_trace_file_ptr(H5C_t * cache_ptr, FILE * trace_file_ptr) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* This would normally be an assert, but we need to use an HGOTO_ERROR * call to shut up the compiler. */ if ( ( ! cache_ptr ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr") } cache_ptr->trace_file_ptr = trace_file_ptr; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_set_trace_file_ptr() */ /*------------------------------------------------------------------------- * Function: H5C_stats * * Purpose: Prints statistics about the cache. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 6/2/04 * * JRM -- 11/13/08 * Added code displaying the max_clean_index_size and * max_dirty_index_size. * * MAM -- 01/06/09 * Added code displaying the calls_to_msic, * total_entries_skipped_in_msic, total_entries_scanned_in_msic, * and max_entries_skipped_in_msic fields. * *------------------------------------------------------------------------- */ herr_t H5C_stats(H5C_t * cache_ptr, const char * cache_name, hbool_t #if !H5C_COLLECT_CACHE_STATS UNUSED #endif /* H5C_COLLECT_CACHE_STATS */ display_detailed_stats) { herr_t ret_value = SUCCEED; /* Return value */ #if H5C_COLLECT_CACHE_STATS int i; int64_t total_hits = 0; int64_t total_misses = 0; int64_t total_write_protects = 0; int64_t total_read_protects = 0; int64_t max_read_protects = 0; int64_t total_insertions = 0; int64_t total_pinned_insertions = 0; int64_t total_clears = 0; int64_t total_flushes = 0; int64_t total_evictions = 0; int64_t total_moves = 0; int64_t total_entry_flush_moves = 0; int64_t total_cache_flush_moves = 0; int64_t total_size_increases = 0; int64_t total_size_decreases = 0; int64_t total_entry_flush_size_changes = 0; int64_t total_cache_flush_size_changes = 0; int64_t total_pins = 0; int64_t total_unpins = 0; int64_t total_dirty_pins = 0; int64_t total_pinned_flushes = 0; int64_t total_pinned_clears = 0; int32_t aggregate_max_accesses = 0; int32_t aggregate_min_accesses = 1000000; int32_t aggregate_max_clears = 0; int32_t aggregate_max_flushes = 0; size_t aggregate_max_size = 0; int32_t aggregate_max_pins = 0; double hit_rate; double average_successful_search_depth = 0.0; double average_failed_search_depth = 0.0; double average_entries_skipped_per_calls_to_msic = 0.0; double average_entries_scanned_per_calls_to_msic = 0.0; #endif /* H5C_COLLECT_CACHE_STATS */ FUNC_ENTER_NOAPI(FAIL) /* This would normally be an assert, but we need to use an HGOTO_ERROR * call to shut up the compiler. */ if ( ( ! cache_ptr ) || ( cache_ptr->magic != H5C__H5C_T_MAGIC ) || ( !cache_name ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Bad cache_ptr or cache_name") } #if H5C_COLLECT_CACHE_STATS for ( i = 0; i <= cache_ptr->max_type_id; i++ ) { total_hits += cache_ptr->hits[i]; total_misses += cache_ptr->misses[i]; total_write_protects += cache_ptr->write_protects[i]; total_read_protects += cache_ptr->read_protects[i]; if ( max_read_protects < cache_ptr->max_read_protects[i] ) { max_read_protects = cache_ptr->max_read_protects[i]; } total_insertions += cache_ptr->insertions[i]; total_pinned_insertions += cache_ptr->pinned_insertions[i]; total_clears += cache_ptr->clears[i]; total_flushes += cache_ptr->flushes[i]; total_evictions += cache_ptr->evictions[i]; total_moves += cache_ptr->moves[i]; total_entry_flush_moves += cache_ptr->entry_flush_moves[i]; total_cache_flush_moves += cache_ptr->cache_flush_moves[i]; total_size_increases += cache_ptr->size_increases[i]; total_size_decreases += cache_ptr->size_decreases[i]; total_entry_flush_size_changes += cache_ptr->entry_flush_size_changes[i]; total_cache_flush_size_changes += cache_ptr->cache_flush_size_changes[i]; total_pins += cache_ptr->pins[i]; total_unpins += cache_ptr->unpins[i]; total_dirty_pins += cache_ptr->dirty_pins[i]; total_pinned_flushes += cache_ptr->pinned_flushes[i]; total_pinned_clears += cache_ptr->pinned_clears[i]; #if H5C_COLLECT_CACHE_ENTRY_STATS if ( aggregate_max_accesses < cache_ptr->max_accesses[i] ) aggregate_max_accesses = cache_ptr->max_accesses[i]; if ( aggregate_min_accesses > aggregate_max_accesses ) aggregate_min_accesses = aggregate_max_accesses; if ( aggregate_min_accesses > cache_ptr->min_accesses[i] ) aggregate_min_accesses = cache_ptr->min_accesses[i]; if ( aggregate_max_clears < cache_ptr->max_clears[i] ) aggregate_max_clears = cache_ptr->max_clears[i]; if ( aggregate_max_flushes < cache_ptr->max_flushes[i] ) aggregate_max_flushes = cache_ptr->max_flushes[i]; if ( aggregate_max_size < cache_ptr->max_size[i] ) aggregate_max_size = cache_ptr->max_size[i]; if ( aggregate_max_pins < cache_ptr->max_pins[i] ) aggregate_max_pins = cache_ptr->max_pins[i]; #endif /* H5C_COLLECT_CACHE_ENTRY_STATS */ } if ( ( total_hits > 0 ) || ( total_misses > 0 ) ) { hit_rate = 100.0 * ((double)(total_hits)) / ((double)(total_hits + total_misses)); } else { hit_rate = 0.0; } if ( cache_ptr->successful_ht_searches > 0 ) { average_successful_search_depth = ((double)(cache_ptr->total_successful_ht_search_depth)) / ((double)(cache_ptr->successful_ht_searches)); } if ( cache_ptr->failed_ht_searches > 0 ) { average_failed_search_depth = ((double)(cache_ptr->total_failed_ht_search_depth)) / ((double)(cache_ptr->failed_ht_searches)); } HDfprintf(stdout, "\n%sH5C: cache statistics for %s\n", cache_ptr->prefix, cache_name); HDfprintf(stdout, "\n"); HDfprintf(stdout, "%s hash table insertion / deletions = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->total_ht_insertions), (long)(cache_ptr->total_ht_deletions)); HDfprintf(stdout, "%s HT successful / failed searches = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->successful_ht_searches), (long)(cache_ptr->failed_ht_searches)); HDfprintf(stdout, "%s Av. HT suc / failed search depth = %f / %f\n", cache_ptr->prefix, average_successful_search_depth, average_failed_search_depth); HDfprintf(stdout, "%s current (max) index size / length = %ld (%ld) / %ld (%ld)\n", cache_ptr->prefix, (long)(cache_ptr->index_size), (long)(cache_ptr->max_index_size), (long)(cache_ptr->index_len), (long)(cache_ptr->max_index_len)); HDfprintf(stdout, "%s current (max) clean/dirty idx size = %ld (%ld) / %ld (%ld)\n", cache_ptr->prefix, (long)(cache_ptr->clean_index_size), (long)(cache_ptr->max_clean_index_size), (long)(cache_ptr->dirty_index_size), (long)(cache_ptr->max_dirty_index_size)); HDfprintf(stdout, "%s current (max) slist size / length = %ld (%ld) / %ld (%ld)\n", cache_ptr->prefix, (long)(cache_ptr->slist_size), (long)(cache_ptr->max_slist_size), (long)(cache_ptr->slist_len), (long)(cache_ptr->max_slist_len)); HDfprintf(stdout, "%s current (max) PL size / length = %ld (%ld) / %ld (%ld)\n", cache_ptr->prefix, (long)(cache_ptr->pl_size), (long)(cache_ptr->max_pl_size), (long)(cache_ptr->pl_len), (long)(cache_ptr->max_pl_len)); HDfprintf(stdout, "%s current (max) PEL size / length = %ld (%ld) / %ld (%ld)\n", cache_ptr->prefix, (long)(cache_ptr->pel_size), (long)(cache_ptr->max_pel_size), (long)(cache_ptr->pel_len), (long)(cache_ptr->max_pel_len)); HDfprintf(stdout, "%s current LRU list size / length = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->LRU_list_size), (long)(cache_ptr->LRU_list_len)); HDfprintf(stdout, "%s current clean LRU size / length = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->cLRU_list_size), (long)(cache_ptr->cLRU_list_len)); HDfprintf(stdout, "%s current dirty LRU size / length = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->dLRU_list_size), (long)(cache_ptr->dLRU_list_len)); HDfprintf(stdout, "%s Total hits / misses / hit_rate = %ld / %ld / %f\n", cache_ptr->prefix, (long)total_hits, (long)total_misses, hit_rate); HDfprintf(stdout, "%s Total write / read (max) protects = %ld / %ld (%ld)\n", cache_ptr->prefix, (long)total_write_protects, (long)total_read_protects, (long)max_read_protects); HDfprintf(stdout, "%s Total clears / flushes / evictions = %ld / %ld / %ld\n", cache_ptr->prefix, (long)total_clears, (long)total_flushes, (long)total_evictions); HDfprintf(stdout, "%s Total insertions(pinned) / moves = %ld(%ld) / %ld\n", cache_ptr->prefix, (long)total_insertions, (long)total_pinned_insertions, (long)total_moves); HDfprintf(stdout, "%s Total entry / cache flush moves = %ld / %ld\n", cache_ptr->prefix, (long)total_entry_flush_moves, (long)total_cache_flush_moves); HDfprintf(stdout, "%s Total entry size incrs / decrs = %ld / %ld\n", cache_ptr->prefix, (long)total_size_increases, (long)total_size_decreases); HDfprintf(stdout, "%s Ttl entry/cache flush size changes = %ld / %ld\n", cache_ptr->prefix, (long)total_entry_flush_size_changes, (long)total_cache_flush_size_changes); HDfprintf(stdout, "%s Total entry pins (dirty) / unpins = %ld (%ld) / %ld\n", cache_ptr->prefix, (long)total_pins, (long)total_dirty_pins, (long)total_unpins); HDfprintf(stdout, "%s Total pinned flushes / clears = %ld / %ld\n", cache_ptr->prefix, (long)total_pinned_flushes, (long)total_pinned_clears); HDfprintf(stdout, "%s MSIC: (make space in cache) calls = %lld\n", cache_ptr->prefix, (long long)(cache_ptr->calls_to_msic)); if (cache_ptr->calls_to_msic > 0) { average_entries_skipped_per_calls_to_msic = (((double)(cache_ptr->total_entries_skipped_in_msic)) / ((double)(cache_ptr->calls_to_msic))); } HDfprintf(stdout, "%s MSIC: Average/max entries skipped = %lf / %ld\n", cache_ptr->prefix, (float)average_entries_skipped_per_calls_to_msic, (long)(cache_ptr->max_entries_skipped_in_msic)); if (cache_ptr->calls_to_msic > 0) { average_entries_scanned_per_calls_to_msic = (((double)(cache_ptr->total_entries_scanned_in_msic)) / ((double)(cache_ptr->calls_to_msic))); } HDfprintf(stdout, "%s MSIC: Average/max entries scanned = %lf / %ld\n", cache_ptr->prefix, (float)average_entries_scanned_per_calls_to_msic, (long)(cache_ptr->max_entries_scanned_in_msic)); HDfprintf(stdout, "%s MSIC: Scanned to make space(evict) = %lld\n", cache_ptr->prefix, (long long)(cache_ptr->entries_scanned_to_make_space)); HDfprintf(stdout, "%s MSIC: Scanned to satisfy min_clean = %lld\n", cache_ptr->prefix, (long long)(cache_ptr->total_entries_scanned_in_msic - cache_ptr->entries_scanned_to_make_space)); #if H5C_COLLECT_CACHE_ENTRY_STATS HDfprintf(stdout, "%s aggregate max / min accesses = %d / %d\n", cache_ptr->prefix, (int)aggregate_max_accesses, (int)aggregate_min_accesses); HDfprintf(stdout, "%s aggregate max_clears / max_flushes = %d / %d\n", cache_ptr->prefix, (int)aggregate_max_clears, (int)aggregate_max_flushes); HDfprintf(stdout, "%s aggregate max_size / max_pins = %d / %d\n", cache_ptr->prefix, (int)aggregate_max_size, (int)aggregate_max_pins); #endif /* H5C_COLLECT_CACHE_ENTRY_STATS */ if ( display_detailed_stats ) { for ( i = 0; i <= cache_ptr->max_type_id; i++ ) { HDfprintf(stdout, "\n"); HDfprintf(stdout, "%s Stats on %s:\n", cache_ptr->prefix, ((cache_ptr->type_name_table_ptr))[i]); if ( ( cache_ptr->hits[i] > 0 ) || ( cache_ptr->misses[i] > 0 ) ) { hit_rate = 100.0 * ((double)(cache_ptr->hits[i])) / ((double)(cache_ptr->hits[i] + cache_ptr->misses[i])); } else { hit_rate = 0.0; } HDfprintf(stdout, "%s hits / misses / hit_rate = %ld / %ld / %f\n", cache_ptr->prefix, (long)(cache_ptr->hits[i]), (long)(cache_ptr->misses[i]), hit_rate); HDfprintf(stdout, "%s write / read (max) protects = %ld / %ld (%d)\n", cache_ptr->prefix, (long)(cache_ptr->write_protects[i]), (long)(cache_ptr->read_protects[i]), (int)(cache_ptr->max_read_protects[i])); HDfprintf(stdout, "%s clears / flushes / evictions = %ld / %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->clears[i]), (long)(cache_ptr->flushes[i]), (long)(cache_ptr->evictions[i])); HDfprintf(stdout, "%s insertions(pinned) / moves = %ld(%ld) / %ld\n", cache_ptr->prefix, (long)(cache_ptr->insertions[i]), (long)(cache_ptr->pinned_insertions[i]), (long)(cache_ptr->moves[i])); HDfprintf(stdout, "%s entry / cache flush moves = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->entry_flush_moves[i]), (long)(cache_ptr->cache_flush_moves[i])); HDfprintf(stdout, "%s size increases / decreases = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->size_increases[i]), (long)(cache_ptr->size_decreases[i])); HDfprintf(stdout, "%s entry/cache flush size changes = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->entry_flush_size_changes[i]), (long)(cache_ptr->cache_flush_size_changes[i])); HDfprintf(stdout, "%s entry pins / unpins = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->pins[i]), (long)(cache_ptr->unpins[i])); HDfprintf(stdout, "%s entry dirty pins/pin'd flushes = %ld / %ld\n", cache_ptr->prefix, (long)(cache_ptr->dirty_pins[i]), (long)(cache_ptr->pinned_flushes[i])); #if H5C_COLLECT_CACHE_ENTRY_STATS HDfprintf(stdout, "%s entry max / min accesses = %d / %d\n", cache_ptr->prefix, cache_ptr->max_accesses[i], cache_ptr->min_accesses[i]); HDfprintf(stdout, "%s entry max_clears / max_flushes = %d / %d\n", cache_ptr->prefix, cache_ptr->max_clears[i], cache_ptr->max_flushes[i]); HDfprintf(stdout, "%s entry max_size / max_pins = %d / %d\n", cache_ptr->prefix, (int)(cache_ptr->max_size[i]), (int)(cache_ptr->max_pins[i])); #endif /* H5C_COLLECT_CACHE_ENTRY_STATS */ } } HDfprintf(stdout, "\n"); #endif /* H5C_COLLECT_CACHE_STATS */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_stats() */ /*------------------------------------------------------------------------- * * Function: H5C_stats__reset * * Purpose: Reset the stats fields to their initial values. * * Return: void * * Programmer: John Mainzer, 4/28/04 * * JRM 11/13/08 * Added initialization for the new max_clean_index_size and * max_dirty_index_size fields. * * MAM -- 01/06/09 * Added code to initalize the calls_to_msic, * total_entries_skipped_in_msic, total_entries_scanned_in_msic, * and max_entries_skipped_in_msic fields. * *------------------------------------------------------------------------- */ void #ifndef NDEBUG H5C_stats__reset(H5C_t * cache_ptr) #else /* NDEBUG */ #if H5C_COLLECT_CACHE_STATS H5C_stats__reset(H5C_t * cache_ptr) #else /* H5C_COLLECT_CACHE_STATS */ H5C_stats__reset(H5C_t UNUSED * cache_ptr) #endif /* H5C_COLLECT_CACHE_STATS */ #endif /* NDEBUG */ { #if H5C_COLLECT_CACHE_STATS int i; #endif /* H5C_COLLECT_CACHE_STATS */ HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); #if H5C_COLLECT_CACHE_STATS for ( i = 0; i <= cache_ptr->max_type_id; i++ ) { cache_ptr->hits[i] = 0; cache_ptr->misses[i] = 0; cache_ptr->write_protects[i] = 0; cache_ptr->read_protects[i] = 0; cache_ptr->max_read_protects[i] = 0; cache_ptr->insertions[i] = 0; cache_ptr->pinned_insertions[i] = 0; cache_ptr->clears[i] = 0; cache_ptr->flushes[i] = 0; cache_ptr->evictions[i] = 0; cache_ptr->moves[i] = 0; cache_ptr->entry_flush_moves[i] = 0; cache_ptr->cache_flush_moves[i] = 0; cache_ptr->pins[i] = 0; cache_ptr->unpins[i] = 0; cache_ptr->dirty_pins[i] = 0; cache_ptr->pinned_flushes[i] = 0; cache_ptr->pinned_clears[i] = 0; cache_ptr->size_increases[i] = 0; cache_ptr->size_decreases[i] = 0; cache_ptr->entry_flush_size_changes[i] = 0; cache_ptr->cache_flush_size_changes[i] = 0; } cache_ptr->total_ht_insertions = 0; cache_ptr->total_ht_deletions = 0; cache_ptr->successful_ht_searches = 0; cache_ptr->total_successful_ht_search_depth = 0; cache_ptr->failed_ht_searches = 0; cache_ptr->total_failed_ht_search_depth = 0; cache_ptr->max_index_len = 0; cache_ptr->max_index_size = (size_t)0; cache_ptr->max_clean_index_size = (size_t)0; cache_ptr->max_dirty_index_size = (size_t)0; cache_ptr->max_slist_len = 0; cache_ptr->max_slist_size = (size_t)0; cache_ptr->max_pl_len = 0; cache_ptr->max_pl_size = (size_t)0; cache_ptr->max_pel_len = 0; cache_ptr->max_pel_size = (size_t)0; cache_ptr->calls_to_msic = 0; cache_ptr->total_entries_skipped_in_msic = 0; cache_ptr->total_entries_scanned_in_msic = 0; cache_ptr->max_entries_skipped_in_msic = 0; cache_ptr->max_entries_scanned_in_msic = 0; cache_ptr->entries_scanned_to_make_space = 0; #if H5C_COLLECT_CACHE_ENTRY_STATS for ( i = 0; i <= cache_ptr->max_type_id; i++ ) { cache_ptr->max_accesses[i] = 0; cache_ptr->min_accesses[i] = 1000000; cache_ptr->max_clears[i] = 0; cache_ptr->max_flushes[i] = 0; cache_ptr->max_size[i] = (size_t)0; cache_ptr->max_pins[i] = 0; } #endif /* H5C_COLLECT_CACHE_ENTRY_STATS */ #endif /* H5C_COLLECT_CACHE_STATS */ return; } /* H5C_stats__reset() */ /*------------------------------------------------------------------------- * Function: H5C_dump_cache * * Purpose: Print a summary of the contents of the metadata cache for * debugging purposes. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 10/10/10 * *------------------------------------------------------------------------- */ herr_t H5C_dump_cache(H5C_t * cache_ptr, const char * cache_name) { herr_t ret_value = SUCCEED; /* Return value */ int i; H5C_cache_entry_t * entry_ptr = NULL; H5SL_t * slist_ptr = NULL; H5SL_node_t * node_ptr = NULL; FUNC_ENTER_NOAPI(FAIL) HDassert(cache_ptr != NULL); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); HDassert(cache_name != NULL ); /* First, create a skip list */ slist_ptr = H5SL_create(H5SL_TYPE_HADDR, NULL); if ( slist_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTCREATE, FAIL, "can't create skip list.") } /* Next, scan the index, and insert all entries in the skip list. * Do this, as we want to display cache entries in increasing address * order. */ for ( i = 0; i < H5C__HASH_TABLE_LEN; i++ ) { entry_ptr = cache_ptr->index[i]; while ( entry_ptr != NULL ) { HDassert( entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); if ( H5SL_insert(slist_ptr, entry_ptr, &(entry_ptr->addr)) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_BADVALUE, FAIL, \ "Can't insert entry in skip list") } entry_ptr = entry_ptr->ht_next; } } /* If we get this far, all entries in the cache are listed in the * skip list -- scan the skip list generating the desired output. */ HDfprintf(stdout, "\n\nDump of metadata cache \"%s\".\n", cache_name); HDfprintf(stdout, "Num: Addr: Len: Type: Prot: Pinned: Dirty:\n"); i = 0; node_ptr = H5SL_first(slist_ptr); if ( node_ptr != NULL ) { entry_ptr = (H5C_cache_entry_t *)H5SL_item(node_ptr); } else { entry_ptr = NULL; } while ( entry_ptr != NULL ) { HDassert( entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); HDfprintf(stdout, "%s%d 0x%08llx 0x%3llx %2d %d %d %d\n", cache_ptr->prefix, i, (long long)(entry_ptr->addr), (long long)(entry_ptr->size), (int)(entry_ptr->type->id), (int)(entry_ptr->is_protected), (int)(entry_ptr->is_pinned), (int)(entry_ptr->is_dirty)); /* increment node_ptr before we delete its target */ node_ptr = H5SL_next(node_ptr); /* remove the first item in the skip list */ if ( H5SL_remove(slist_ptr, &(entry_ptr->addr)) != entry_ptr ) { HGOTO_ERROR(H5E_CACHE, H5E_BADVALUE, FAIL, \ "Can't delete entry from skip list.") } if ( node_ptr != NULL ) { entry_ptr = (H5C_cache_entry_t *)H5SL_item(node_ptr); } else { entry_ptr = NULL; } i++; } HDfprintf(stdout, "\n\n"); /* Finally, discard the skip list */ HDassert( H5SL_count(slist_ptr) == 0 ); H5SL_close(slist_ptr); done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_dump_cache() */ /*------------------------------------------------------------------------- * Function: H5C_unpin_entry_from_client() * * Purpose: Internal routine to unpin a cache entry from a client action. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * 3/24/09 * *------------------------------------------------------------------------- */ static herr_t H5C_unpin_entry_from_client(H5C_t * cache_ptr, H5C_cache_entry_t * entry_ptr, hbool_t update_rp) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT /* Sanity checking */ HDassert( cache_ptr ); HDassert( entry_ptr ); /* Error checking (should be sanity checks?) */ if(!entry_ptr->is_pinned) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPIN, FAIL, "Entry isn't pinned") if(!entry_ptr->pinned_from_client) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPIN, FAIL, "Entry wasn't pinned by cache client") /* Check if the entry is not pinned from a flush dependency */ if(!entry_ptr->pinned_from_cache) { /* If requested, update the replacement policy if the entry is not protected */ if(update_rp && !entry_ptr->is_protected) H5C__UPDATE_RP_FOR_UNPIN(cache_ptr, entry_ptr, FAIL) /* Unpin the entry now */ entry_ptr->is_pinned = FALSE; /* Update the stats for an unpin operation */ H5C__UPDATE_STATS_FOR_UNPIN(cache_ptr, entry_ptr) } /* end if */ /* Mark the entry as explicitly unpinned by the client */ entry_ptr->pinned_from_client = FALSE; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_unpin_entry_from_client() */ /*------------------------------------------------------------------------- * Function: H5C_unpin_entry() * * Purpose: Unpin a cache entry. The entry can be either protected or * unprotected at the time of call, but must be pinned. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 3/22/06 * *------------------------------------------------------------------------- */ herr_t H5C_unpin_entry(void *_entry_ptr) { H5C_t * cache_ptr; H5C_cache_entry_t * entry_ptr = (H5C_cache_entry_t *)_entry_ptr; /* Pointer to entry to unpin */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity check */ HDassert(entry_ptr); cache_ptr = entry_ptr->cache_ptr; HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Unpin the entry */ if(H5C_unpin_entry_from_client(cache_ptr, entry_ptr, TRUE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPIN, FAIL, "Can't unpin entry from client") done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_unpin_entry() */ /*------------------------------------------------------------------------- * Function: H5C_unprotect * * Purpose: Undo an H5C_protect() call -- specifically, mark the * entry as unprotected, remove it from the protected list, * and give it back to the replacement policy. * * The TYPE and ADDR arguments must be the same as those in * the corresponding call to H5C_protect() and the THING * argument must be the value returned by that call to * H5C_protect(). * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the unprotect (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). Since an uprotect cannot * occasion a write at present, all this is moot for now. * However, things change, and in any case, * H5C_flush_single_entry() needs primary_dxpl_id and * secondary_dxpl_id in its parameter list. * * The function can't cause a read either, so the dxpl_id * parameters are moot in this case as well. * * Return: Non-negative on success/Negative on failure * * If the deleted flag is TRUE, simply remove the target entry * from the cache, clear it, and free it without writing it to * disk. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 6/2/04 * *------------------------------------------------------------------------- */ herr_t H5C_unprotect(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, const H5C_class_t * type, haddr_t addr, void * thing, unsigned int flags) { H5C_t * cache_ptr; hbool_t deleted; hbool_t dirtied; hbool_t set_flush_marker; hbool_t pin_entry; hbool_t unpin_entry; hbool_t free_file_space; hbool_t take_ownership; hbool_t was_clean; #ifdef H5_HAVE_PARALLEL hbool_t clear_entry = FALSE; #endif /* H5_HAVE_PARALLEL */ H5C_cache_entry_t * entry_ptr; H5C_cache_entry_t * test_entry_ptr; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) deleted = ( (flags & H5C__DELETED_FLAG) != 0 ); dirtied = ( (flags & H5C__DIRTIED_FLAG) != 0 ); set_flush_marker = ( (flags & H5C__SET_FLUSH_MARKER_FLAG) != 0 ); pin_entry = ( (flags & H5C__PIN_ENTRY_FLAG) != 0 ); unpin_entry = ( (flags & H5C__UNPIN_ENTRY_FLAG) != 0 ); free_file_space = ( (flags & H5C__FREE_FILE_SPACE_FLAG) != 0 ); take_ownership = ( (flags & H5C__TAKE_OWNERSHIP_FLAG) != 0 ); HDassert( f ); HDassert( f->shared ); cache_ptr = f->shared->cache; HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( type ); HDassert( type->clear ); HDassert( type->flush ); HDassert( H5F_addr_defined(addr) ); HDassert( thing ); HDassert( ! ( pin_entry && unpin_entry ) ); HDassert( ( ! free_file_space ) || ( deleted ) ); /* deleted flag must accompany free_file_space */ HDassert( ( ! take_ownership ) || ( deleted ) ); /* deleted flag must accompany take_ownership */ HDassert( ! ( free_file_space && take_ownership ) ); /* can't have both free_file_space & take_ownership */ entry_ptr = (H5C_cache_entry_t *)thing; HDassert( entry_ptr->addr == addr ); HDassert( entry_ptr->type == type ); /* also set the dirtied variable if the dirtied field is set in * the entry. */ dirtied |= entry_ptr->dirtied; was_clean = ! ( entry_ptr->is_dirty ); #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ /* if the entry has multiple read only protects, just decrement * the ro_ref_counter. Don't actually unprotect until the ref count * drops to zero. */ if ( entry_ptr->ro_ref_count > 1 ) { HDassert( entry_ptr->is_protected ); HDassert( entry_ptr->is_read_only ); if ( dirtied ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "Read only entry modified(1)??") } (entry_ptr->ro_ref_count)--; /* Pin or unpin the entry as requested. */ if ( pin_entry ) { /* Pin the entry from a client */ if(H5C_pin_entry_from_client(cache_ptr, entry_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTPIN, FAIL, "Can't pin entry by client") } else if ( unpin_entry ) { /* Unpin the entry from a client */ if(H5C_unpin_entry_from_client(cache_ptr, entry_ptr, FALSE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPIN, FAIL, "Can't unpin entry by client") } } else { if ( entry_ptr->is_read_only ) { HDassert( entry_ptr->ro_ref_count == 1 ); if ( dirtied ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "Read only entry modified(2)??") } entry_ptr->is_read_only = FALSE; entry_ptr->ro_ref_count = 0; } #ifdef H5_HAVE_PARALLEL /* When the H5C code is used to implement the metadata cache in the * PHDF5 case, only the cache on process 0 is allowed to write to file. * All the other metadata caches must hold dirty entries until they * are told that the entries are clean. * * The clear_on_unprotect flag in the H5C_cache_entry_t structure * exists to deal with the case in which an entry is protected when * its cache receives word that the entry is now clean. In this case, * the clear_on_unprotect flag is set, and the entry is flushed with * the H5C__FLUSH_CLEAR_ONLY_FLAG. * * All this is a bit awkward, but until the metadata cache entries * are contiguous, with only one dirty flag, we have to let the supplied * functions deal with the reseting the is_dirty flag. */ if ( entry_ptr->clear_on_unprotect ) { HDassert( entry_ptr->is_dirty ); entry_ptr->clear_on_unprotect = FALSE; if ( ! dirtied ) { clear_entry = TRUE; } } #endif /* H5_HAVE_PARALLEL */ if ( ! (entry_ptr->is_protected) ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "Entry already unprotected??") } /* mark the entry as dirty if appropriate */ entry_ptr->is_dirty = ( (entry_ptr->is_dirty) || dirtied ); if ( ( was_clean ) && ( entry_ptr->is_dirty ) ) { /* Propagate the flush dep dirty flag up the flush dependency chain * if appropriate */ if ( ( entry_ptr->flush_dep_ndirty_children == 0) && ( entry_ptr->flush_dep_nparents > 0 ) ) { if ( H5C__mark_flush_dep_dirty(entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Can't propagate flush dep dirty flag") } } H5C__UPDATE_INDEX_FOR_ENTRY_DIRTY(cache_ptr, entry_ptr) } else if ( ! ( was_clean ) && ! ( entry_ptr->is_dirty ) ) { /* Propagate the flush dep clean flag up the flush dependency chain * if appropriate */ if ( ( entry_ptr->flush_dep_ndirty_children == 0) && ( entry_ptr->flush_dep_nparents > 0 ) ) { if ( H5C__mark_flush_dep_clean(entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Can't propagate flush dep dirty flag") } } } /* Pin or unpin the entry as requested. */ if ( pin_entry ) { /* Pin the entry from a client */ if(H5C_pin_entry_from_client(cache_ptr, entry_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTPIN, FAIL, "Can't pin entry by client") } else if ( unpin_entry ) { /* Unpin the entry from a client */ if(H5C_unpin_entry_from_client(cache_ptr, entry_ptr, FALSE) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPIN, FAIL, "Can't unpin entry by client") } /* H5C__UPDATE_RP_FOR_UNPROTECT will place the unprotected entry on * the pinned entry list if entry_ptr->is_pinned is TRUE. */ H5C__UPDATE_RP_FOR_UNPROTECT(cache_ptr, entry_ptr, FAIL) entry_ptr->is_protected = FALSE; /* if the entry is dirty, 'or' its flush_marker with the set flush flag, * and then add it to the skip list if it isn't there already. */ if ( entry_ptr->is_dirty ) { entry_ptr->flush_marker |= set_flush_marker; if ( ! (entry_ptr->in_slist) ) { H5C__INSERT_ENTRY_IN_SLIST(cache_ptr, entry_ptr, FAIL) } } /* this implementation of the "deleted" option is a bit inefficient, as * we re-insert the entry to be deleted into the replacement policy * data structures, only to remove them again. Depending on how often * we do this, we may want to optimize a bit. * * On the other hand, this implementation is reasonably clean, and * makes good use of existing code. * JRM - 5/19/04 */ if ( deleted ) { /* the following first flush flag will never be used as we are * calling H5C_flush_single_entry with both the * H5C__FLUSH_CLEAR_ONLY_FLAG and H5C__FLUSH_INVALIDATE_FLAG flags. * However, it is needed for the function call. */ hbool_t dummy_first_flush = TRUE; unsigned flush_flags = (H5C__FLUSH_CLEAR_ONLY_FLAG | H5C__FLUSH_INVALIDATE_FLAG); /* we can't delete a pinned entry */ HDassert ( ! (entry_ptr->is_pinned ) ); /* verify that the target entry is in the cache. */ H5C__SEARCH_INDEX(cache_ptr, addr, test_entry_ptr, FAIL) if ( test_entry_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "entry not in hash table?!?.") } else if ( test_entry_ptr != entry_ptr ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "hash table contains multiple entries for addr?!?.") } /* Pass along 'free file space' flag to cache client */ entry_ptr->free_file_space_on_destroy = free_file_space; /* Set the "take ownership" flag for the flush, if needed */ if ( take_ownership) { flush_flags |= H5C__TAKE_OWNERSHIP_FLAG; } if ( H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, type, addr, flush_flags, &dummy_first_flush, TRUE) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, "Can't flush.") } } #ifdef H5_HAVE_PARALLEL else if ( clear_entry ) { /* the following first flush flag will never be used as we are * calling H5C_flush_single_entry with the * H5C__FLUSH_CLEAR_ONLY_FLAG flag. However, it is needed for * the function call. */ hbool_t dummy_first_flush = TRUE; /* verify that the target entry is in the cache. */ H5C__SEARCH_INDEX(cache_ptr, addr, test_entry_ptr, FAIL) if ( test_entry_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "entry not in hash table?!?.") } else if ( test_entry_ptr != entry_ptr ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, \ "hash table contains multiple entries for addr?!?.") } if ( H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, type, addr, H5C__FLUSH_CLEAR_ONLY_FLAG, &dummy_first_flush, TRUE) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNPROTECT, FAIL, "Can't clear.") } } #endif /* H5_HAVE_PARALLEL */ } H5C__UPDATE_STATS_FOR_UNPROTECT(cache_ptr) done: #if H5C_DO_EXTREME_SANITY_CHECKS if ( H5C_validate_lru_list(cache_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "LRU sanity check failed.\n"); } #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_unprotect() */ /*------------------------------------------------------------------------- * Function: H5C_validate_resize_config() * * Purpose: Run a sanity check on the specified sections of the * provided instance of struct H5C_auto_size_ctl_t. * * Do nothing and return SUCCEED if no errors are detected, * and flag an error and return FAIL otherwise. * * Return: Non-negative on success/Negative on failure * * Programmer: John Mainzer * 3/23/05 * *------------------------------------------------------------------------- */ herr_t H5C_validate_resize_config(H5C_auto_size_ctl_t * config_ptr, unsigned int tests) { herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) if ( config_ptr == NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "NULL config_ptr on entry.") } if ( config_ptr->version != H5C__CURR_AUTO_SIZE_CTL_VER ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Unknown config version.") } if ( (tests & H5C_RESIZE_CFG__VALIDATE_GENERAL) != 0 ) { if ( ( config_ptr->set_initial_size != TRUE ) && ( config_ptr->set_initial_size != FALSE ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "set_initial_size must be either TRUE or FALSE"); } if ( config_ptr->max_size > H5C__MAX_MAX_CACHE_SIZE ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "max_size too big"); } if ( config_ptr->min_size < H5C__MIN_MAX_CACHE_SIZE ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "min_size too small"); } if ( config_ptr->min_size > config_ptr->max_size ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "min_size > max_size"); } if ( ( config_ptr->set_initial_size ) && ( ( config_ptr->initial_size < config_ptr->min_size ) || ( config_ptr->initial_size > config_ptr->max_size ) ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "initial_size must be in the interval [min_size, max_size]"); } if ( ( config_ptr->min_clean_fraction < 0.0 ) || ( config_ptr->min_clean_fraction > 1.0 ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "min_clean_fraction must be in the interval [0.0, 1.0]"); } if ( config_ptr->epoch_length < H5C__MIN_AR_EPOCH_LENGTH ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "epoch_length too small"); } if ( config_ptr->epoch_length > H5C__MAX_AR_EPOCH_LENGTH ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "epoch_length too big"); } } /* H5C_RESIZE_CFG__VALIDATE_GENERAL */ if ( (tests & H5C_RESIZE_CFG__VALIDATE_INCREMENT) != 0 ) { if ( ( config_ptr->incr_mode != H5C_incr__off ) && ( config_ptr->incr_mode != H5C_incr__threshold ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "Invalid incr_mode"); } if ( config_ptr->incr_mode == H5C_incr__threshold ) { if ( ( config_ptr->lower_hr_threshold < 0.0 ) || ( config_ptr->lower_hr_threshold > 1.0 ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "lower_hr_threshold must be in the range [0.0, 1.0]"); } if ( config_ptr->increment < 1.0 ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "increment must be greater than or equal to 1.0"); } if ( ( config_ptr->apply_max_increment != TRUE ) && ( config_ptr->apply_max_increment != FALSE ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "apply_max_increment must be either TRUE or FALSE"); } /* no need to check max_increment, as it is a size_t, * and thus must be non-negative. */ } /* H5C_incr__threshold */ switch ( config_ptr->flash_incr_mode ) { case H5C_flash_incr__off: /* nothing to do here */ break; case H5C_flash_incr__add_space: if ( ( config_ptr->flash_multiple < 0.1 ) || ( config_ptr->flash_multiple > 10.0 ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "flash_multiple must be in the range [0.1, 10.0]"); } if ( ( config_ptr->flash_threshold < 0.1 ) || ( config_ptr->flash_threshold > 1.0 ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "flash_threshold must be in the range [0.1, 1.0]"); } break; default: HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "Invalid flash_incr_mode"); break; } } /* H5C_RESIZE_CFG__VALIDATE_INCREMENT */ if ( (tests & H5C_RESIZE_CFG__VALIDATE_DECREMENT) != 0 ) { if ( ( config_ptr->decr_mode != H5C_decr__off ) && ( config_ptr->decr_mode != H5C_decr__threshold ) && ( config_ptr->decr_mode != H5C_decr__age_out ) && ( config_ptr->decr_mode != H5C_decr__age_out_with_threshold ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "Invalid decr_mode"); } if ( config_ptr->decr_mode == H5C_decr__threshold ) { if ( config_ptr->upper_hr_threshold > 1.0 ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "upper_hr_threshold must be <= 1.0"); } if ( ( config_ptr->decrement > 1.0 ) || ( config_ptr->decrement < 0.0 ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "decrement must be in the interval [0.0, 1.0]"); } /* no need to check max_decrement as it is a size_t * and thus must be non-negative. */ } /* H5C_decr__threshold */ if ( ( config_ptr->decr_mode == H5C_decr__age_out ) || ( config_ptr->decr_mode == H5C_decr__age_out_with_threshold ) ) { if ( config_ptr->epochs_before_eviction < 1 ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "epochs_before_eviction must be positive"); } if ( config_ptr->epochs_before_eviction > H5C__MAX_EPOCH_MARKERS ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "epochs_before_eviction too big"); } if ( ( config_ptr->apply_empty_reserve != TRUE ) && ( config_ptr->apply_empty_reserve != FALSE ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "apply_empty_reserve must be either TRUE or FALSE"); } if ( ( config_ptr->apply_empty_reserve ) && ( ( config_ptr->empty_reserve > 1.0 ) || ( config_ptr->empty_reserve < 0.0 ) ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "empty_reserve must be in the interval [0.0, 1.0]"); } /* no need to check max_decrement as it is a size_t * and thus must be non-negative. */ } /* H5C_decr__age_out || H5C_decr__age_out_with_threshold */ if ( config_ptr->decr_mode == H5C_decr__age_out_with_threshold ) { if ( ( config_ptr->upper_hr_threshold > 1.0 ) || ( config_ptr->upper_hr_threshold < 0.0 ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "upper_hr_threshold must be in the interval [0.0, 1.0]"); } } /* H5C_decr__age_out_with_threshold */ } /* H5C_RESIZE_CFG__VALIDATE_DECREMENT */ if ( (tests & H5C_RESIZE_CFG__VALIDATE_INTERACTIONS) != 0 ) { if ( ( config_ptr->incr_mode == H5C_incr__threshold ) && ( ( config_ptr->decr_mode == H5C_decr__threshold ) || ( config_ptr->decr_mode == H5C_decr__age_out_with_threshold ) ) && ( config_ptr->lower_hr_threshold >= config_ptr->upper_hr_threshold ) ) { HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, \ "conflicting threshold fields in config.") } } /* H5C_RESIZE_CFG__VALIDATE_INTERACTIONS */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_validate_resize_config() */ /*------------------------------------------------------------------------- * Function: H5C_create_flush_dependency() * * Purpose: Initiates a parent<->child entry flush dependency. The parent * entry must be pinned or protected at the time of call, and must * have all dependencies removed before the cache can shut down. * * Note: Flush dependencies in the cache indicate that a child entry * must be flushed to the file before its parent. (This is * currently used to implement Single-Writer/Multiple-Reader (SWMR) * I/O access for data structures in the file). * * Creating a flush dependency between two entries will also pin * the parent entry. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * 3/05/09 * *------------------------------------------------------------------------- */ herr_t H5C_create_flush_dependency(void * parent_thing, void * child_thing) { H5C_t * cache_ptr; H5C_cache_entry_t * parent_entry = (H5C_cache_entry_t *)parent_thing; /* Ptr to parent thing's entry */ H5C_cache_entry_t * child_entry = (H5C_cache_entry_t *)child_thing; /* Ptr to child thing's entry */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity checks */ HDassert(parent_entry); HDassert(parent_entry->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC); HDassert(H5F_addr_defined(parent_entry->addr)); HDassert(child_entry); HDassert(child_entry->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC); HDassert(H5F_addr_defined(child_entry->addr)); cache_ptr = parent_entry->cache_ptr; HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); HDassert(cache_ptr == child_entry->cache_ptr); #ifndef NDEBUG /* Make sure the parent is not already a parent */ { unsigned i; for(i=0; iflush_dep_nparents; i++) HDassert(child_entry->flush_dep_parent[i] != parent_entry); } /* end block */ #endif /* NDEBUG */ /* More sanity checks */ if(child_entry == parent_entry) HGOTO_ERROR(H5E_CACHE, H5E_CANTDEPEND, FAIL, "Child entry flush dependency parent can't be itself") if(!(parent_entry->is_protected || parent_entry->is_pinned)) HGOTO_ERROR(H5E_CACHE, H5E_CANTDEPEND, FAIL, "Parent entry isn't pinned or protected") /* Check for parent not pinned */ if(!parent_entry->is_pinned) { /* Sanity check */ HDassert(parent_entry->flush_dep_nchildren == 0); HDassert(!parent_entry->pinned_from_client); HDassert(!parent_entry->pinned_from_cache); /* Pin the parent entry */ parent_entry->is_pinned = TRUE; H5C__UPDATE_STATS_FOR_PIN(cache_ptr, parent_entry) } /* end else */ /* Mark the entry as pinned from the cache's action (possibly redundantly) */ parent_entry->pinned_from_cache = TRUE; /* Check if we need to resize the child's parent array */ if(child_entry->flush_dep_nparents >= child_entry->flush_dep_parent_nalloc) { if(child_entry->flush_dep_parent_nalloc == 0) { /* Array does not exist yet, allocate it */ HDassert(!child_entry->flush_dep_parent); if(NULL == (child_entry->flush_dep_parent = (H5C_cache_entry_t **)H5FL_BLK_MALLOC(parent, H5C_FLUSH_DEP_PARENT_INIT * sizeof(H5C_cache_entry_t *)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for flush dependency parent list") child_entry->flush_dep_parent_nalloc = H5C_FLUSH_DEP_PARENT_INIT; } /* end if */ else { /* Resize existing array */ HDassert(child_entry->flush_dep_parent); if(NULL == (child_entry->flush_dep_parent = (H5C_cache_entry_t **)H5FL_BLK_REALLOC(parent, child_entry->flush_dep_parent, 2 * child_entry->flush_dep_parent_nalloc * sizeof(H5C_cache_entry_t *)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for flush dependency parent list") child_entry->flush_dep_parent_nalloc *= 2; } /* end else */ } /* end if */ /* Add the dependency to the child's parent array */ child_entry->flush_dep_parent[child_entry->flush_dep_nparents] = parent_entry; child_entry->flush_dep_nparents++; /* Increment parent's number of children */ parent_entry->flush_dep_nchildren++; /* Adjust the number of dirty children */ if(child_entry->is_dirty || child_entry->flush_dep_ndirty_children > 0) { /* Sanity check */ HDassert(parent_entry->flush_dep_ndirty_children < parent_entry->flush_dep_nchildren); parent_entry->flush_dep_ndirty_children++; /* Propagate the flush dep dirty flag up the chain if necessary */ if(!parent_entry->is_dirty && parent_entry->flush_dep_ndirty_children == 1) if(H5C__mark_flush_dep_dirty(parent_entry) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, "can't propagate flush dep dirty flag") } /* end if */ /* Post-conditions, for successful operation */ HDassert(parent_entry->is_pinned); HDassert(parent_entry->flush_dep_nchildren > 0); HDassert(child_entry->flush_dep_parent); HDassert(child_entry->flush_dep_nparents > 0); HDassert(child_entry->flush_dep_parent_nalloc > 0); #ifndef NDEBUG H5C__assert_flush_dep_nocycle(parent_entry, child_entry); #endif /* NDEBUG */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_create_flush_dependency() */ /*------------------------------------------------------------------------- * Function: H5C_destroy_flush_dependency() * * Purpose: Terminates a parent<-> child entry flush dependency. The * parent entry must be pinned. * * Return: Non-negative on success/Negative on failure * * Programmer: Quincey Koziol * 3/05/09 * *------------------------------------------------------------------------- */ herr_t H5C_destroy_flush_dependency(void *parent_thing, void * child_thing) { H5C_t * cache_ptr; H5C_cache_entry_t * parent_entry = (H5C_cache_entry_t *)parent_thing; /* Ptr to parent entry */ H5C_cache_entry_t * child_entry = (H5C_cache_entry_t *)child_thing; /* Ptr to child entry */ unsigned i; /* Local index variable */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Sanity checks */ HDassert(parent_entry); HDassert(parent_entry->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC); HDassert(H5F_addr_defined(parent_entry->addr)); HDassert(child_entry); HDassert(child_entry->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC); HDassert(H5F_addr_defined(child_entry->addr)); cache_ptr = parent_entry->cache_ptr; HDassert(cache_ptr); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); HDassert(cache_ptr == child_entry->cache_ptr); /* Usage checks */ if(!parent_entry->is_pinned) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNDEPEND, FAIL, "Parent entry isn't pinned") if(NULL == child_entry->flush_dep_parent) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNDEPEND, FAIL, "Child entry doesn't have a flush dependency parent array") if(0 == parent_entry->flush_dep_nchildren) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNDEPEND, FAIL, "Parent entry flush dependency ref. count has no child dependencies") /* Search for parent in child's parent array. This is a linear search * because we do not expect large numbers of parents. If this changes, we * may wish to change the parent array to a skip list */ for(i=0; iflush_dep_nparents; i++) if(child_entry->flush_dep_parent[i] == parent_entry) break; if(i == child_entry->flush_dep_nparents) HGOTO_ERROR(H5E_CACHE, H5E_CANTUNDEPEND, FAIL, "Parent entry isn't a flush dependency parent for child entry") /* Remove parent entry from child's parent array */ if(i < child_entry->flush_dep_nparents - 1) HDmemmove(&child_entry->flush_dep_parent[i], &child_entry->flush_dep_parent[i+1], (child_entry->flush_dep_nparents - i - 1) * sizeof(child_entry->flush_dep_parent[0])); child_entry->flush_dep_nparents--; /* Adjust parent entry's nchildren and unpin parent if it goes to zero */ parent_entry->flush_dep_nchildren--; if(0 == parent_entry->flush_dep_nchildren) { /* Sanity check */ HDassert(parent_entry->pinned_from_cache); /* Check if we should unpin parent entry now */ if(!parent_entry->pinned_from_client) { /* Update the replacement policy if the entry is not protected */ if(!parent_entry->is_protected) H5C__UPDATE_RP_FOR_UNPIN(cache_ptr, parent_entry, FAIL) /* Unpin the entry now */ parent_entry->is_pinned = FALSE; /* Update the stats for an unpin operation */ H5C__UPDATE_STATS_FOR_UNPIN(cache_ptr, parent_entry) } /* end if */ /* Mark the entry as unpinned from the cache's action */ parent_entry->pinned_from_cache = FALSE; } /* end if */ /* Adjust parent entry's ndirty_children */ if(child_entry->is_dirty || child_entry->flush_dep_ndirty_children > 0) { /* Sanity check */ HDassert(parent_entry->flush_dep_ndirty_children > 0); parent_entry->flush_dep_ndirty_children--; /* Propagate the flush dep clean flag up the chain if necessary */ if(!parent_entry->is_dirty && parent_entry->flush_dep_ndirty_children == 0) if(H5C__mark_flush_dep_clean(parent_entry) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, "can't propagate flush dep clean flag") } /* end if */ /* Shrink or free the parent array if apporpriate */ if(child_entry->flush_dep_nparents == 0) { child_entry->flush_dep_parent = (H5C_cache_entry_t **)H5FL_BLK_FREE(parent, child_entry->flush_dep_parent); child_entry->flush_dep_parent_nalloc = 0; } /* end if */ else if(child_entry->flush_dep_parent_nalloc > H5C_FLUSH_DEP_PARENT_INIT && child_entry->flush_dep_nparents <= (child_entry->flush_dep_parent_nalloc / 4)) { if(NULL == (child_entry->flush_dep_parent = (H5C_cache_entry_t **)H5FL_BLK_REALLOC(parent, child_entry->flush_dep_parent, (child_entry->flush_dep_parent_nalloc / 4) * sizeof(H5C_cache_entry_t *)))) HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed for flush dependency parent list") child_entry->flush_dep_parent_nalloc /= 4; } /* end if */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_destroy_flush_dependency() */ /*************************************************************************/ /**************************** Private Functions: *************************/ /*************************************************************************/ /*------------------------------------------------------------------------- * * Function: H5C__auto_adjust_cache_size * * Purpose: Obtain the current full cache hit rate, and compare it * with the hit rate thresholds for modifying cache size. * If one of the thresholds has been crossed, adjusts the * size of the cache accordingly. * * The function then resets the full cache hit rate * statistics, and exits. * * Return: Non-negative on success/Negative on failure or if there was * an attempt to flush a protected item. * * * Programmer: John Mainzer, 10/7/04 * *------------------------------------------------------------------------- */ static herr_t H5C__auto_adjust_cache_size(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, hbool_t write_permitted, hbool_t * first_flush_ptr) { H5C_t * cache_ptr = f->shared->cache; herr_t result; hbool_t inserted_epoch_marker = FALSE; size_t new_max_cache_size = 0; size_t old_max_cache_size = 0; size_t new_min_clean_size = 0; size_t old_min_clean_size = 0; double hit_rate; enum H5C_resize_status status = in_spec; /* will change if needed */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert( f ); HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( cache_ptr->cache_accesses >= (cache_ptr->resize_ctl).epoch_length ); HDassert( 0.0 <= (cache_ptr->resize_ctl).min_clean_fraction ); HDassert( (cache_ptr->resize_ctl).min_clean_fraction <= 100.0 ); if ( !cache_ptr->resize_enabled ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Auto cache resize disabled.") } HDassert( ( (cache_ptr->resize_ctl).incr_mode != H5C_incr__off ) || \ ( (cache_ptr->resize_ctl).decr_mode != H5C_decr__off ) ); if ( H5C_get_cache_hit_rate(cache_ptr, &hit_rate) != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't get hit rate.") } HDassert( ( 0.0 <= hit_rate ) && ( hit_rate <= 1.0 ) ); switch ( (cache_ptr->resize_ctl).incr_mode ) { case H5C_incr__off: if ( cache_ptr->size_increase_possible ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "size_increase_possible but H5C_incr__off?!?!?") } break; case H5C_incr__threshold: if ( hit_rate < (cache_ptr->resize_ctl).lower_hr_threshold ) { if ( ! cache_ptr->size_increase_possible ) { status = increase_disabled; } else if ( cache_ptr->max_cache_size >= (cache_ptr->resize_ctl).max_size ) { HDassert( cache_ptr->max_cache_size == \ (cache_ptr->resize_ctl).max_size ); status = at_max_size; } else if ( ! cache_ptr->cache_full ) { status = not_full; } else { new_max_cache_size = (size_t) (((double)(cache_ptr->max_cache_size)) * (cache_ptr->resize_ctl).increment); /* clip to max size if necessary */ if ( new_max_cache_size > (cache_ptr->resize_ctl).max_size ) { new_max_cache_size = (cache_ptr->resize_ctl).max_size; } /* clip to max increment if necessary */ if ( ( (cache_ptr->resize_ctl).apply_max_increment ) && ( (cache_ptr->max_cache_size + (cache_ptr->resize_ctl).max_increment) < new_max_cache_size ) ) { new_max_cache_size = cache_ptr->max_cache_size + (cache_ptr->resize_ctl).max_increment; } status = increase; } } break; default: HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "unknown incr_mode.") } /* If the decr_mode is either age out or age out with threshold, we * must run the marker maintenance code, whether we run the size * reduction code or not. We do this in two places -- here we * insert a new marker if the number of active epoch markers is * is less than the the current epochs before eviction, and after * the ageout call, we cycle the markers. * * However, we can't call the ageout code or cycle the markers * unless there was a full complement of markers in place on * entry. The inserted_epoch_marker flag is used to track this. */ if ( ( ( (cache_ptr->resize_ctl).decr_mode == H5C_decr__age_out ) || ( (cache_ptr->resize_ctl).decr_mode == H5C_decr__age_out_with_threshold ) ) && ( cache_ptr->epoch_markers_active < (cache_ptr->resize_ctl).epochs_before_eviction ) ) { result = H5C__autoadjust__ageout__insert_new_marker(cache_ptr); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "can't insert new epoch marker.") } else { inserted_epoch_marker = TRUE; } } /* don't run the cache size decrease code unless the cache size * increase code is disabled, or the size increase code sees no need * for action. In either case, status == in_spec at this point. */ if ( status == in_spec ) { switch ( (cache_ptr->resize_ctl).decr_mode ) { case H5C_decr__off: break; case H5C_decr__threshold: if ( hit_rate > (cache_ptr->resize_ctl).upper_hr_threshold ) { if ( ! cache_ptr->size_decrease_possible ) { status = decrease_disabled; } else if ( cache_ptr->max_cache_size <= (cache_ptr->resize_ctl).min_size ) { HDassert( cache_ptr->max_cache_size == (cache_ptr->resize_ctl).min_size ); status = at_min_size; } else { new_max_cache_size = (size_t) (((double)(cache_ptr->max_cache_size)) * (cache_ptr->resize_ctl).decrement); /* clip to min size if necessary */ if ( new_max_cache_size < (cache_ptr->resize_ctl).min_size ) { new_max_cache_size = (cache_ptr->resize_ctl).min_size; } /* clip to max decrement if necessary */ if ( ( (cache_ptr->resize_ctl).apply_max_decrement ) && ( ((cache_ptr->resize_ctl).max_decrement + new_max_cache_size) < cache_ptr->max_cache_size ) ) { new_max_cache_size = cache_ptr->max_cache_size - (cache_ptr->resize_ctl).max_decrement; } status = decrease; } } break; case H5C_decr__age_out_with_threshold: case H5C_decr__age_out: if ( ! inserted_epoch_marker ) { if ( ! cache_ptr->size_decrease_possible ) { status = decrease_disabled; } else { result = H5C__autoadjust__ageout(f, hit_rate, &status, &new_max_cache_size, primary_dxpl_id, secondary_dxpl_id, write_permitted, first_flush_ptr); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "ageout code failed.") } } } break; default: HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "unknown incr_mode.") } } /* cycle the epoch markers here if appropriate */ if ( ( ( (cache_ptr->resize_ctl).decr_mode == H5C_decr__age_out ) || ( (cache_ptr->resize_ctl).decr_mode == H5C_decr__age_out_with_threshold ) ) && ( ! inserted_epoch_marker ) ) { /* move last epoch marker to the head of the LRU list */ result = H5C__autoadjust__ageout__cycle_epoch_marker(cache_ptr); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "error cycling epoch marker.") } } if ( ( status == increase ) || ( status == decrease ) ) { old_max_cache_size = cache_ptr->max_cache_size; old_min_clean_size = cache_ptr->min_clean_size; new_min_clean_size = (size_t) ((double)new_max_cache_size * ((cache_ptr->resize_ctl).min_clean_fraction)); /* new_min_clean_size is of size_t, and thus must be non-negative. * Hence we have * * ( 0 <= new_min_clean_size ). * * by definition. */ HDassert( new_min_clean_size <= new_max_cache_size ); HDassert( (cache_ptr->resize_ctl).min_size <= new_max_cache_size ); HDassert( new_max_cache_size <= (cache_ptr->resize_ctl).max_size ); cache_ptr->max_cache_size = new_max_cache_size; cache_ptr->min_clean_size = new_min_clean_size; if ( status == increase ) { cache_ptr->cache_full = FALSE; } else if ( status == decrease ) { cache_ptr->size_decreased = TRUE; } /* update flash cache size increase fields as appropriate */ if ( cache_ptr->flash_size_increase_possible ) { switch ( (cache_ptr->resize_ctl).flash_incr_mode ) { case H5C_flash_incr__off: HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "flash_size_increase_possible but H5C_flash_incr__off?!") break; case H5C_flash_incr__add_space: cache_ptr->flash_size_increase_threshold = (size_t) (((double)(cache_ptr->max_cache_size)) * ((cache_ptr->resize_ctl).flash_threshold)); break; default: /* should be unreachable */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Unknown flash_incr_mode?!?!?.") break; } } } if ( (cache_ptr->resize_ctl).rpt_fcn != NULL ) { (*((cache_ptr->resize_ctl).rpt_fcn)) (cache_ptr, H5C__CURR_AUTO_RESIZE_RPT_FCN_VER, hit_rate, status, old_max_cache_size, new_max_cache_size, old_min_clean_size, new_min_clean_size); } if ( H5C_reset_cache_hit_rate_stats(cache_ptr) != SUCCEED ) { /* this should be impossible... */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "H5C_reset_cache_hit_rate_stats failed.") } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__auto_adjust_cache_size() */ /*------------------------------------------------------------------------- * * Function: H5C__autoadjust__ageout * * Purpose: Implement the ageout automatic cache size decrement * algorithm. Note that while this code evicts aged out * entries, the code does not change the maximum cache size. * Instead, the function simply computes the new value (if * any change is indicated) and reports this value in * *new_max_cache_size_ptr. * * Return: Non-negative on success/Negative on failure or if there was * an attempt to flush a protected item. * * * Programmer: John Mainzer, 11/18/04 * *------------------------------------------------------------------------- */ static herr_t H5C__autoadjust__ageout(H5F_t * f, double hit_rate, enum H5C_resize_status * status_ptr, size_t * new_max_cache_size_ptr, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, hbool_t write_permitted, hbool_t * first_flush_ptr) { H5C_t * cache_ptr = f->shared->cache; herr_t result; size_t test_size; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert( f ); HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( ( status_ptr ) && ( *status_ptr == in_spec ) ); HDassert( ( new_max_cache_size_ptr ) && ( *new_max_cache_size_ptr == 0 ) ); /* remove excess epoch markers if any */ if ( cache_ptr->epoch_markers_active > (cache_ptr->resize_ctl).epochs_before_eviction ) { result = H5C__autoadjust__ageout__remove_excess_markers(cache_ptr); if ( result != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "can't remove excess epoch markers.") } } if ( ( (cache_ptr->resize_ctl).decr_mode == H5C_decr__age_out ) || ( ( (cache_ptr->resize_ctl).decr_mode == H5C_decr__age_out_with_threshold ) && ( hit_rate >= (cache_ptr->resize_ctl).upper_hr_threshold ) ) ) { if ( cache_ptr->max_cache_size > (cache_ptr->resize_ctl).min_size ){ /* evict aged out cache entries if appropriate... */ if(H5C__autoadjust__ageout__evict_aged_out_entries(f, primary_dxpl_id, secondary_dxpl_id, write_permitted, first_flush_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "error flushing aged out entries.") /* ... and then reduce cache size if appropriate */ if ( cache_ptr->index_size < cache_ptr->max_cache_size ) { if ( (cache_ptr->resize_ctl).apply_empty_reserve ) { test_size = (size_t)(((double)cache_ptr->index_size) / (1 - (cache_ptr->resize_ctl).empty_reserve)); if ( test_size < cache_ptr->max_cache_size ) { *status_ptr = decrease; *new_max_cache_size_ptr = test_size; } } else { *status_ptr = decrease; *new_max_cache_size_ptr = cache_ptr->index_size; } if ( *status_ptr == decrease ) { /* clip to min size if necessary */ if ( *new_max_cache_size_ptr < (cache_ptr->resize_ctl).min_size ) { *new_max_cache_size_ptr = (cache_ptr->resize_ctl).min_size; } /* clip to max decrement if necessary */ if ( ( (cache_ptr->resize_ctl).apply_max_decrement ) && ( ((cache_ptr->resize_ctl).max_decrement + *new_max_cache_size_ptr) < cache_ptr->max_cache_size ) ) { *new_max_cache_size_ptr = cache_ptr->max_cache_size - (cache_ptr->resize_ctl).max_decrement; } } } } else { *status_ptr = at_min_size; } } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__autoadjust__ageout() */ /*------------------------------------------------------------------------- * * Function: H5C__autoadjust__ageout__cycle_epoch_marker * * Purpose: Remove the oldest epoch marker from the LRU list, * and reinsert it at the head of the LRU list. Also * remove the epoch marker's index from the head of the * ring buffer, and re-insert it at the tail of the ring * buffer. * * Return: SUCCEED on success/FAIL on failure. * * Programmer: John Mainzer, 11/22/04 * *------------------------------------------------------------------------- */ static herr_t H5C__autoadjust__ageout__cycle_epoch_marker(H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; /* Return value */ int i; FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); if ( cache_ptr->epoch_markers_active <= 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "No active epoch markers on entry?!?!?.") } /* remove the last marker from both the ring buffer and the LRU list */ i = cache_ptr->epoch_marker_ringbuf[cache_ptr->epoch_marker_ringbuf_first]; cache_ptr->epoch_marker_ringbuf_first = (cache_ptr->epoch_marker_ringbuf_first + 1) % (H5C__MAX_EPOCH_MARKERS + 1); cache_ptr->epoch_marker_ringbuf_size -= 1; if ( cache_ptr->epoch_marker_ringbuf_size < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "ring buffer underflow.") } if ( (cache_ptr->epoch_marker_active)[i] != TRUE ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "unused marker in LRU?!?") } H5C__DLL_REMOVE((&((cache_ptr->epoch_markers)[i])), \ (cache_ptr)->LRU_head_ptr, \ (cache_ptr)->LRU_tail_ptr, \ (cache_ptr)->LRU_list_len, \ (cache_ptr)->LRU_list_size, \ (FAIL)) /* now, re-insert it at the head of the LRU list, and at the tail of * the ring buffer. */ HDassert( ((cache_ptr->epoch_markers)[i]).addr == (haddr_t)i ); HDassert( ((cache_ptr->epoch_markers)[i]).next == NULL ); HDassert( ((cache_ptr->epoch_markers)[i]).prev == NULL ); cache_ptr->epoch_marker_ringbuf_last = (cache_ptr->epoch_marker_ringbuf_last + 1) % (H5C__MAX_EPOCH_MARKERS + 1); (cache_ptr->epoch_marker_ringbuf)[cache_ptr->epoch_marker_ringbuf_last] = i; cache_ptr->epoch_marker_ringbuf_size += 1; if ( cache_ptr->epoch_marker_ringbuf_size > H5C__MAX_EPOCH_MARKERS ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "ring buffer overflow.") } H5C__DLL_PREPEND((&((cache_ptr->epoch_markers)[i])), \ (cache_ptr)->LRU_head_ptr, \ (cache_ptr)->LRU_tail_ptr, \ (cache_ptr)->LRU_list_len, \ (cache_ptr)->LRU_list_size, \ (FAIL)) done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__autoadjust__ageout__cycle_epoch_marker() */ /*------------------------------------------------------------------------- * * Function: H5C__autoadjust__ageout__evict_aged_out_entries * * Purpose: Evict clean entries in the cache that haven't * been accessed for at least * (cache_ptr->resize_ctl).epochs_before_eviction epochs, * and flush dirty entries that haven't been accessed for * that amount of time. * * Depending on configuration, the function will either * flush or evict all such entries, or all such entries it * encounters until it has freed the maximum amount of space * allowed under the maximum decrement. * * If we are running in parallel mode, writes may not be * permitted. If so, the function simply skips any dirty * entries it may encounter. * * The function makes no attempt to maintain the minimum * clean size, as there is no guarantee that the cache size * will be changed. * * If there is no cache size change, the minimum clean size * constraint will be met through a combination of clean * entries and free space in the cache. * * If there is a cache size reduction, the minimum clean size * will be re-calculated, and will be enforced the next time * we have to make space in the cache. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used depending on the value of * *first_flush_ptr. The idea is to use the primary_dxpl_id * on the first write in a sequence of writes, and to use * the secondary_dxpl_id on all subsequent writes. * * This is useful in the metadata cache, but may not be * needed elsewhere. If so, just use the same dxpl_id for * both parameters. * * Observe that this function cannot occasion a read. * * Return: Non-negative on success/Negative on failure. * * Programmer: John Mainzer, 11/22/04 * *------------------------------------------------------------------------- */ static herr_t H5C__autoadjust__ageout__evict_aged_out_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, hbool_t write_permitted, hbool_t * first_flush_ptr) { H5C_t * cache_ptr = f->shared->cache; herr_t result; size_t eviction_size_limit; size_t bytes_evicted = 0; hbool_t prev_is_dirty = FALSE; H5C_cache_entry_t * entry_ptr; H5C_cache_entry_t * next_ptr; H5C_cache_entry_t * prev_ptr; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert( f ); HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); /* if there is a limit on the amount that the cache size can be decrease * in any one round of the cache size reduction algorithm, load that * limit into eviction_size_limit. Otherwise, set eviction_size_limit * to the equivalent of infinity. The current size of the index will * do nicely. */ if ( (cache_ptr->resize_ctl).apply_max_decrement ) { eviction_size_limit = (cache_ptr->resize_ctl).max_decrement; } else { eviction_size_limit = cache_ptr->index_size; /* i.e. infinity */ } if ( write_permitted ) { entry_ptr = cache_ptr->LRU_tail_ptr; while ( ( entry_ptr != NULL ) && ( (entry_ptr->type)->id != H5C__EPOCH_MARKER_TYPE ) && ( bytes_evicted < eviction_size_limit ) ) { HDassert( ! (entry_ptr->is_protected) ); next_ptr = entry_ptr->next; prev_ptr = entry_ptr->prev; if ( prev_ptr != NULL ) { prev_is_dirty = prev_ptr->is_dirty; } if ( entry_ptr->is_dirty ) { result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__NO_FLAGS_SET, first_flush_ptr, FALSE); } else { bytes_evicted += entry_ptr->size; result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__FLUSH_INVALIDATE_FLAG, first_flush_ptr, TRUE); } if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "unable to flush entry") } if ( prev_ptr != NULL ) { #ifndef NDEBUG if ( prev_ptr->magic != H5C__H5C_CACHE_ENTRY_T_MAGIC ) { /* something horrible has happened to *prev_ptr -- * scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "*prev_ptr corrupt") } else #endif /* NDEBUG */ if ( ( prev_ptr->is_dirty != prev_is_dirty ) || ( prev_ptr->next != next_ptr ) || ( prev_ptr->is_protected ) || ( prev_ptr->is_pinned ) ) { /* something has happened to the LRU -- start over * from the tail. */ entry_ptr = cache_ptr->LRU_tail_ptr; } else { entry_ptr = prev_ptr; } } else { entry_ptr = NULL; } } /* end while */ /* for now at least, don't bother to maintain the minimum clean size, * as the cache should now be less than its maximum size. Due to * the vaguries of the cache size reduction algorthim, we may not * reduce the size of the cache. * * If we do, we will calculate a new minimum clean size, which will * be enforced the next time we try to make space in the cache. * * If we don't, no action is necessary, as we have just evicted and/or * or flushed a bunch of entries and therefore the sum of the clean * and free space in the cache must be greater than or equal to the * min clean space requirement (assuming that requirement was met on * entry). */ } else /* ! write_permitted */ { /* since we are not allowed to write, all we can do is evict * any clean entries that we may encounter before we either * hit the eviction size limit, or encounter the epoch marker. * * If we are operating read only, this isn't an issue, as there * will not be any dirty entries. * * If we are operating in R/W mode, all the dirty entries we * skip will be flushed the next time we attempt to make space * when writes are permitted. This may have some local * performance implications, but it shouldn't cause any net * slowdown. */ HDassert( H5C_MAINTAIN_CLEAN_AND_DIRTY_LRU_LISTS ); entry_ptr = cache_ptr->LRU_tail_ptr; while ( ( entry_ptr != NULL ) && ( (entry_ptr->type)->id != H5C__EPOCH_MARKER_TYPE ) && ( bytes_evicted < eviction_size_limit ) ) { HDassert( ! (entry_ptr->is_protected) ); prev_ptr = entry_ptr->prev; if ( ! (entry_ptr->is_dirty) ) { result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__FLUSH_INVALIDATE_FLAG, first_flush_ptr, TRUE); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "unable to flush clean entry") } } /* just skip the entry if it is dirty, as we can't do * anything with it now since we can't write. */ entry_ptr = prev_ptr; } /* end while */ } if ( cache_ptr->index_size < cache_ptr->max_cache_size ) { cache_ptr->cache_full = FALSE; } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__autoadjust__ageout__evict_aged_out_entries() */ /*------------------------------------------------------------------------- * * Function: H5C__autoadjust__ageout__insert_new_marker * * Purpose: Find an unused marker cache entry, mark it as used, and * insert it at the head of the LRU list. Also add the * marker's index in the epoch_markers array. * * Return: SUCCEED on success/FAIL on failure. * * Programmer: John Mainzer, 11/19/04 * *------------------------------------------------------------------------- */ static herr_t H5C__autoadjust__ageout__insert_new_marker(H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; /* Return value */ int i; FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); if ( cache_ptr->epoch_markers_active >= (cache_ptr->resize_ctl).epochs_before_eviction ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Already have a full complement of markers.") } /* find an unused marker */ i = 0; while ( ( (cache_ptr->epoch_marker_active)[i] ) && ( i < H5C__MAX_EPOCH_MARKERS ) ) { i++; } if(i >= H5C__MAX_EPOCH_MARKERS) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't find unused marker.") HDassert( ((cache_ptr->epoch_markers)[i]).addr == (haddr_t)i ); HDassert( ((cache_ptr->epoch_markers)[i]).next == NULL ); HDassert( ((cache_ptr->epoch_markers)[i]).prev == NULL ); (cache_ptr->epoch_marker_active)[i] = TRUE; cache_ptr->epoch_marker_ringbuf_last = (cache_ptr->epoch_marker_ringbuf_last + 1) % (H5C__MAX_EPOCH_MARKERS + 1); (cache_ptr->epoch_marker_ringbuf)[cache_ptr->epoch_marker_ringbuf_last] = i; cache_ptr->epoch_marker_ringbuf_size += 1; if ( cache_ptr->epoch_marker_ringbuf_size > H5C__MAX_EPOCH_MARKERS ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "ring buffer overflow.") } H5C__DLL_PREPEND((&((cache_ptr->epoch_markers)[i])), \ (cache_ptr)->LRU_head_ptr, \ (cache_ptr)->LRU_tail_ptr, \ (cache_ptr)->LRU_list_len, \ (cache_ptr)->LRU_list_size, \ (FAIL)) cache_ptr->epoch_markers_active += 1; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__autoadjust__ageout__insert_new_marker() */ /*------------------------------------------------------------------------- * * Function: H5C__autoadjust__ageout__remove_all_markers * * Purpose: Remove all epoch markers from the LRU list and mark them * as inactive. * * Return: SUCCEED on success/FAIL on failure. * * Programmer: John Mainzer, 11/22/04 * *------------------------------------------------------------------------- */ static herr_t H5C__autoadjust__ageout__remove_all_markers(H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; /* Return value */ int i; int ring_buf_index; FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); while ( cache_ptr->epoch_markers_active > 0 ) { /* get the index of the last epoch marker in the LRU list * and remove it from the ring buffer. */ ring_buf_index = cache_ptr->epoch_marker_ringbuf_first; i = (cache_ptr->epoch_marker_ringbuf)[ring_buf_index]; cache_ptr->epoch_marker_ringbuf_first = (cache_ptr->epoch_marker_ringbuf_first + 1) % (H5C__MAX_EPOCH_MARKERS + 1); cache_ptr->epoch_marker_ringbuf_size -= 1; if ( cache_ptr->epoch_marker_ringbuf_size < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "ring buffer underflow.") } if ( (cache_ptr->epoch_marker_active)[i] != TRUE ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "unused marker in LRU?!?") } /* remove the epoch marker from the LRU list */ H5C__DLL_REMOVE((&((cache_ptr->epoch_markers)[i])), \ (cache_ptr)->LRU_head_ptr, \ (cache_ptr)->LRU_tail_ptr, \ (cache_ptr)->LRU_list_len, \ (cache_ptr)->LRU_list_size, \ (FAIL)) /* mark the epoch marker as unused. */ (cache_ptr->epoch_marker_active)[i] = FALSE; HDassert( ((cache_ptr->epoch_markers)[i]).addr == (haddr_t)i ); HDassert( ((cache_ptr->epoch_markers)[i]).next == NULL ); HDassert( ((cache_ptr->epoch_markers)[i]).prev == NULL ); /* decrement the number of active epoch markers */ cache_ptr->epoch_markers_active -= 1; HDassert( cache_ptr->epoch_markers_active == \ cache_ptr->epoch_marker_ringbuf_size ); } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__autoadjust__ageout__remove_all_markers() */ /*------------------------------------------------------------------------- * * Function: H5C__autoadjust__ageout__remove_excess_markers * * Purpose: Remove epoch markers from the end of the LRU list and * mark them as inactive until the number of active markers * equals the the current value of * (cache_ptr->resize_ctl).epochs_before_eviction. * * Return: SUCCEED on success/FAIL on failure. * * Programmer: John Mainzer, 11/19/04 * *------------------------------------------------------------------------- */ static herr_t H5C__autoadjust__ageout__remove_excess_markers(H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; /* Return value */ int i; int ring_buf_index; FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); if ( cache_ptr->epoch_markers_active <= (cache_ptr->resize_ctl).epochs_before_eviction ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "no excess markers on entry.") } while ( cache_ptr->epoch_markers_active > (cache_ptr->resize_ctl).epochs_before_eviction ) { /* get the index of the last epoch marker in the LRU list * and remove it from the ring buffer. */ ring_buf_index = cache_ptr->epoch_marker_ringbuf_first; i = (cache_ptr->epoch_marker_ringbuf)[ring_buf_index]; cache_ptr->epoch_marker_ringbuf_first = (cache_ptr->epoch_marker_ringbuf_first + 1) % (H5C__MAX_EPOCH_MARKERS + 1); cache_ptr->epoch_marker_ringbuf_size -= 1; if ( cache_ptr->epoch_marker_ringbuf_size < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "ring buffer underflow.") } if ( (cache_ptr->epoch_marker_active)[i] != TRUE ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "unused marker in LRU?!?") } /* remove the epoch marker from the LRU list */ H5C__DLL_REMOVE((&((cache_ptr->epoch_markers)[i])), \ (cache_ptr)->LRU_head_ptr, \ (cache_ptr)->LRU_tail_ptr, \ (cache_ptr)->LRU_list_len, \ (cache_ptr)->LRU_list_size, \ (FAIL)) /* mark the epoch marker as unused. */ (cache_ptr->epoch_marker_active)[i] = FALSE; HDassert( ((cache_ptr->epoch_markers)[i]).addr == (haddr_t)i ); HDassert( ((cache_ptr->epoch_markers)[i]).next == NULL ); HDassert( ((cache_ptr->epoch_markers)[i]).prev == NULL ); /* decrement the number of active epoch markers */ cache_ptr->epoch_markers_active -= 1; HDassert( cache_ptr->epoch_markers_active == \ cache_ptr->epoch_marker_ringbuf_size ); } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__autoadjust__ageout__remove_excess_markers() */ /*------------------------------------------------------------------------- * * Function: H5C__flash_increase_cache_size * * Purpose: If there is not at least new_entry_size - old_entry_size * bytes of free space in the cache and the current * max_cache_size is less than (cache_ptr->resize_ctl).max_size, * perform a flash increase in the cache size and then reset * the full cache hit rate statistics, and exit. * * Return: Non-negative on success/Negative on failure. * * Programmer: John Mainzer, 12/31/07 * *------------------------------------------------------------------------- */ static herr_t H5C__flash_increase_cache_size(H5C_t * cache_ptr, size_t old_entry_size, size_t new_entry_size) { size_t new_max_cache_size = 0; size_t old_max_cache_size = 0; size_t new_min_clean_size = 0; size_t old_min_clean_size = 0; size_t space_needed; enum H5C_resize_status status = flash_increase; /* may change */ double hit_rate; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( cache_ptr->flash_size_increase_possible ); HDassert( new_entry_size > cache_ptr->flash_size_increase_threshold ); HDassert( old_entry_size < new_entry_size ); if ( old_entry_size >= new_entry_size ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "old_entry_size >= new_entry_size") } space_needed = new_entry_size - old_entry_size; if ( ( (cache_ptr->index_size + space_needed) > cache_ptr->max_cache_size ) && ( cache_ptr->max_cache_size < (cache_ptr->resize_ctl).max_size ) ) { /* we have work to do */ switch ( (cache_ptr->resize_ctl).flash_incr_mode ) { case H5C_flash_incr__off: HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "flash_size_increase_possible but H5C_flash_incr__off?!") break; case H5C_flash_incr__add_space: if ( cache_ptr->index_size < cache_ptr->max_cache_size ) { HDassert( (cache_ptr->max_cache_size - cache_ptr->index_size) < space_needed ); space_needed -= cache_ptr->max_cache_size - cache_ptr->index_size; } space_needed = (size_t)(((double)space_needed) * (cache_ptr->resize_ctl).flash_multiple); new_max_cache_size = cache_ptr->max_cache_size + space_needed; break; default: /* should be unreachable */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Unknown flash_incr_mode?!?!?.") break; } if ( new_max_cache_size > (cache_ptr->resize_ctl).max_size ) { new_max_cache_size = (cache_ptr->resize_ctl).max_size; } HDassert( new_max_cache_size > cache_ptr->max_cache_size ); new_min_clean_size = (size_t) ((double)new_max_cache_size * ((cache_ptr->resize_ctl).min_clean_fraction)); HDassert( new_min_clean_size <= new_max_cache_size ); old_max_cache_size = cache_ptr->max_cache_size; old_min_clean_size = cache_ptr->min_clean_size; cache_ptr->max_cache_size = new_max_cache_size; cache_ptr->min_clean_size = new_min_clean_size; /* update flash cache size increase fields as appropriate */ HDassert ( cache_ptr->flash_size_increase_possible ); switch ( (cache_ptr->resize_ctl).flash_incr_mode ) { case H5C_flash_incr__off: HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "flash_size_increase_possible but H5C_flash_incr__off?!") break; case H5C_flash_incr__add_space: cache_ptr->flash_size_increase_threshold = (size_t) (((double)(cache_ptr->max_cache_size)) * ((cache_ptr->resize_ctl).flash_threshold)); break; default: /* should be unreachable */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Unknown flash_incr_mode?!?!?.") break; } /* note that we don't cycle the epoch markers. We can * argue either way as to whether we should, but for now * we don't. */ if ( (cache_ptr->resize_ctl).rpt_fcn != NULL ) { /* get the hit rate for the reporting function. Should still * be good as we havent reset the hit rate statistics. */ if ( H5C_get_cache_hit_rate(cache_ptr, &hit_rate) != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Can't get hit rate.") } (*((cache_ptr->resize_ctl).rpt_fcn)) (cache_ptr, H5C__CURR_AUTO_RESIZE_RPT_FCN_VER, hit_rate, status, old_max_cache_size, new_max_cache_size, old_min_clean_size, new_min_clean_size); } if ( H5C_reset_cache_hit_rate_stats(cache_ptr) != SUCCEED ) { /* this should be impossible... */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "H5C_reset_cache_hit_rate_stats failed.") } } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__flash_increase_cache_size() */ /*------------------------------------------------------------------------- * Function: H5C_flush_invalidate_cache * * Purpose: Flush and destroy the entries contained in the target * cache. * * If the cache contains protected entries, the function will * fail, as protected entries cannot be either flushed or * destroyed. However all unprotected entries should be * flushed and destroyed before the function returns failure. * * While pinned entries can usually be flushed, they cannot * be destroyed. However, they should be unpinned when all * the entries that reference them have been destroyed (thus * reduding the pinned entry's reference count to 0, allowing * it to be unpinned). * * If pinned entries are present, the function makes repeated * passes through the cache, flushing all dirty entries * (including the pinned dirty entries where permitted) and * destroying all unpinned entries. This process is repeated * until either the cache is empty, or the number of pinned * entries stops decreasing on each pass. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the flush (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). * * Return: Non-negative on success/Negative on failure or if there was * a request to flush all items and something was protected. * * Programmer: John Mainzer * 3/24/065 * *------------------------------------------------------------------------- */ static herr_t H5C_flush_invalidate_cache(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, unsigned flags) { H5C_t * cache_ptr = f->shared->cache; herr_t status; hbool_t first_flush = TRUE; int32_t protected_entries = 0; int32_t i; int32_t cur_pel_len; int32_t old_pel_len; unsigned cooked_flags; H5SL_node_t * node_ptr = NULL; H5C_cache_entry_t * entry_ptr = NULL; H5C_cache_entry_t * next_entry_ptr = NULL; #if H5C_DO_SANITY_CHECKS int64_t actual_slist_len = 0; int64_t initial_slist_len = 0; size_t actual_slist_size = 0; size_t initial_slist_size = 0; #endif /* H5C_DO_SANITY_CHECKS */ herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(FAIL) HDassert( f ); HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( cache_ptr->slist_ptr ); /* Filter out the flags that are not relevant to the flush/invalidate. * At present, only the H5C__FLUSH_CLEAR_ONLY_FLAG is kept. */ cooked_flags = flags & H5C__FLUSH_CLEAR_ONLY_FLAG; /* remove ageout markers if present */ if ( cache_ptr->epoch_markers_active > 0 ) { status = H5C__autoadjust__ageout__remove_all_markers(cache_ptr); if ( status != SUCCEED ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "error removing all epoch markers.") } } /* The flush proceedure here is a bit strange. * * In the outer while loop we make at least one pass through the * cache, and then repeat until either all the pinned entries * unpin themselves, or until the number of pinned entries stops * declining. In this later case, we scream and die. * * Since the fractal heap can dirty, resize, and/or move entries * in is flush callback, it is possible that the cache will still * contain dirty entries at this point. If so, we must make more * passes through the skip list to allow it to empty. * * Further, since clean entries can be dirtied, resized, and/or moved * as the result of a flush call back (either the entries own, or that * for some other cache entry), we can no longer promise to flush * the cache entries in increasing address order. * * Instead, we just do the best we can -- making a pass through * the skip list, and then a pass through the "clean" entries, and * then repeating as needed. Thus it is quite possible that an * entry will be evicted from the cache only to be re-loaded later * in the flush process (From what Quincey tells me, the pin * mechanism makes this impossible, but even it it is true now, * we shouldn't count on it in the future.) * * The bottom line is that entries will probably be flushed in close * to increasing address order, but there are no guarantees. */ cur_pel_len = cache_ptr->pel_len; old_pel_len = cache_ptr->pel_len; while ( cache_ptr->index_len > 0 ) { protected_entries = 0; /* first, try to flush-destroy any dirty entries. Do this by * making a scan through the slist. Note that new dirty entries * may be created by the flush call backs. Thus it is possible * that the slist will not be empty after we finish the scan. */ if ( cache_ptr->slist_len == 0 ) { node_ptr = NULL; HDassert( cache_ptr->slist_size == 0 ); } else { /* Start at beginning of skip list each time */ node_ptr = H5SL_first(cache_ptr->slist_ptr); HDassert( node_ptr != NULL ); /* Get cache entry for this node */ next_entry_ptr = (H5C_cache_entry_t *)H5SL_item(node_ptr); if ( NULL == next_entry_ptr ) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "next_entry_ptr == NULL ?!?!") HDassert( next_entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); HDassert( next_entry_ptr->is_dirty ); HDassert( next_entry_ptr->in_slist ); } #if H5C_DO_SANITY_CHECKS /* Depending on circumstances, H5C_flush_single_entry() will * remove dirty entries from the slist as it flushes them. * Thus for sanity checks we must make note of the initial * slist length and size before we do any flushes. */ initial_slist_len = cache_ptr->slist_len; initial_slist_size = cache_ptr->slist_size; /* There is also the possibility that entries will be * dirtied, resized, and/or moved as the result of * calls to the flush callbacks. We use the slist_len_increase * and slist_size_increase increase fields in struct H5C_t * to track these changes for purpose of sanity checking. * To this end, we must zero these fields before we start * the pass through the slist. */ cache_ptr->slist_len_increase = 0; cache_ptr->slist_size_increase = 0; /* Finally, reset the actual_slist_len and actual_slist_size * fields to zero, as these fields are used to accumulate * the slist lenght and size that we see as we scan through * the slist. */ actual_slist_len = 0; actual_slist_size = 0; #endif /* H5C_DO_SANITY_CHECKS */ while ( node_ptr != NULL ) { entry_ptr = next_entry_ptr; /* With the advent of the fractal heap, it is possible * that the flush callback will dirty and/or resize * other entries in the cache. In particular, while * Quincey has promised me that this will never happen, * it is possible that the flush callback for an * entry may protect an entry that is not in the cache, * perhaps causing the cache to flush and possibly * evict the entry associated with node_ptr to make * space for the new entry. * * Thus we do a bit of extra sanity checking on entry_ptr, * and break out of this scan of the skip list if we * detect major problems. We have a bit of leaway on the * number of passes though the skip list, so this shouldn't * be an issue in the flush in and of itself, as it should * be all but impossible for this to happen more than once * in any flush. * * Observe that that breaking out of the scan early * shouldn't break the sanity checks just after the end * of this while loop. * * If an entry has merely been marked clean and removed from * the s-list, we simply break out of the scan. * * If the entry has been evicted, we flag an error and * exit. */ #ifndef NDEBUG if ( entry_ptr->magic != H5C__H5C_CACHE_ENTRY_T_MAGIC ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "entry_ptr->magic is invalid ?!?!") } else #endif /* NDEBUG */ if ( ( ! entry_ptr->is_dirty ) || ( ! entry_ptr->in_slist ) ) { /* the s-list has been modified out from under us. * break out of the loop. */ goto end_of_inner_loop;; } /* increment node pointer now, before we delete its target * from the slist. */ node_ptr = H5SL_next(node_ptr); if ( node_ptr != NULL ) { next_entry_ptr = (H5C_cache_entry_t *)H5SL_item(node_ptr); if ( NULL == next_entry_ptr ) HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "next_entry_ptr == NULL ?!?!") HDassert( next_entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); HDassert( next_entry_ptr->is_dirty ); HDassert( next_entry_ptr->in_slist ); } else { next_entry_ptr = NULL; } /* Note that we now remove nodes from the slist as we flush * the associated entries, instead of leaving them there * until we are done, and then destroying all nodes in * the slist. * * While this optimization used to be easy, with the possibility * of new entries being added to the slist in the midst of the * flush, we must keep the slist in cannonical form at all * times. */ HDassert( entry_ptr != NULL ); HDassert( entry_ptr->in_slist ); if ( ( ( ! entry_ptr->flush_me_last ) || ( ( entry_ptr->flush_me_last ) && ( cache_ptr->num_last_entries >= cache_ptr->slist_len ) ) ) && ( entry_ptr->flush_dep_nchildren == 0 ) ) { #if H5C_DO_SANITY_CHECKS /* update actual_slist_len & actual_slist_size before * the flush. Note that the entry will be removed * from the slist after the flush, and thus may be * resized by the flush callback. This is OK, as * we will catch the size delta in * cache_ptr->slist_size_increase. * * Note that we include pinned entries in this count, even * though we will not actually flush them. */ actual_slist_len++; actual_slist_size += entry_ptr->size; #endif /* H5C_DO_SANITY_CHECKS */ if ( entry_ptr->is_protected ) { /* we have major problems -- but lets flush * everything we can before we flag an error. */ protected_entries++; } else if ( entry_ptr->is_pinned ) { status = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, NULL, entry_ptr->addr, H5C__NO_FLAGS_SET, &first_flush, FALSE); if ( status < 0 ) { /* This shouldn't happen -- if it does, we are toast * so just scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "dirty pinned entry flush failed.") } /* end if */ } /* end if */ else { status = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, NULL, entry_ptr->addr, (cooked_flags | H5C__FLUSH_INVALIDATE_FLAG), &first_flush, TRUE); if ( status < 0 ) { /* This shouldn't happen -- if it does, we are toast so * just scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "dirty entry flush destroy failed.") } /* end if */ } /* end else */ } /* end if */ } /* end while loop scanning skip list */ #if H5C_DO_SANITY_CHECKS /* It is possible that entries were added to the slist during * the scan, either before or after scan pointer. The following * asserts take this into account. * * Don't bother with the sanity checks if node_ptr != NULL, as * in this case we broke out of the loop because it got changed * out from under us. */ if ( node_ptr == NULL ) { HDassert( (actual_slist_len + cache_ptr->slist_len) == (initial_slist_len + cache_ptr->slist_len_increase) ); HDassert( (actual_slist_size + cache_ptr->slist_size) == (initial_slist_size + cache_ptr->slist_size_increase) ); } #endif /* H5C_DO_SANITY_CHECKS */ /* Since we are doing a destroy, we must make a pass through * the hash table and try to flush - destroy all entries that * remain. * * It used to be that all entries remaining in the cache at * this point had to be clean, but with the fractal heap mods * this may not be the case. If so, we will flush entries out * of increasing address order. * * Writes to disk are possible here. */ for ( i = 0; i < H5C__HASH_TABLE_LEN; i++ ) { next_entry_ptr = cache_ptr->index[i]; while ( next_entry_ptr != NULL ) { entry_ptr = next_entry_ptr; #ifndef NDEBUG HDassert( entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ); #endif /* NDEBUG */ next_entry_ptr = entry_ptr->ht_next; HDassert ( ( next_entry_ptr == NULL ) || ( next_entry_ptr->magic == H5C__H5C_CACHE_ENTRY_T_MAGIC ) ); if ( ( ( ! entry_ptr->flush_me_last ) || ( ( entry_ptr->flush_me_last ) && ( cache_ptr->num_last_entries >= cache_ptr->slist_len ) ) ) && ( entry_ptr->flush_dep_nchildren == 0 ) ) { if ( entry_ptr->is_protected ) { /* we have major problems -- but lets flush and destroy * everything we can before we flag an error. */ protected_entries++; if ( ! entry_ptr->in_slist ) { HDassert( !(entry_ptr->is_dirty) ); } } else if ( ! ( entry_ptr->is_pinned ) ) { status = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, NULL, entry_ptr->addr, (cooked_flags | H5C__FLUSH_INVALIDATE_FLAG), &first_flush, TRUE); if ( status < 0 ) { /* This shouldn't happen -- if it does, we are toast so * just scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Entry flush destroy failed.") } } /* end if */ } /* end if */ /* We can't do anything if the entry is pinned. The * hope is that the entry will be unpinned as the * result of destroys of entries that reference it. * * We detect this by noting the change in the number * of pinned entries from pass to pass. If it stops * shrinking before it hits zero, we scream and die. */ /* if the flush function on the entry we last evicted * loaded an entry into cache (as Quincey has promised me * it never will), and if the cache was full, it is * possible that *next_entry_ptr was flushed or evicted. * * Test to see if this happened here. Note that if this * test is triggred, we are accessing a deallocated piece * of dynamically allocated memory, so we just scream and * die. */ #ifndef NDEBUG if ( ( next_entry_ptr != NULL ) && ( next_entry_ptr->magic != H5C__H5C_CACHE_ENTRY_T_MAGIC ) ) { /* Something horrible has happened to * *next_entry_ptr -- scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "next_entry_ptr->magic is invalid?!?!?.") } #endif /* NDEBUG */ } /* end while loop scanning hash table bin */ } /* end for loop scanning hash table */ end_of_inner_loop: old_pel_len = cur_pel_len; cur_pel_len = cache_ptr->pel_len; if ( ( cur_pel_len > 0 ) && ( cur_pel_len >= old_pel_len ) ) { /* The number of pinned entries is positive, and it is not * declining. Scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Pinned entry count not decreasing, cur_pel_len = %d, old_pel_len = %d", (int)cur_pel_len, (int)old_pel_len) } HDassert( protected_entries == cache_ptr->pl_len ); if ( ( protected_entries > 0 ) && ( protected_entries == cache_ptr->index_len ) ) { /* Only protected entries are left in the cache. Scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Only protected entries left in cache, protected_entries = %d", (int)protected_entries) } } /* main while loop */ /* Invariants, after destroying all entries in the hash table */ HDassert( cache_ptr->index_size == 0 ); HDassert( cache_ptr->clean_index_size == 0 ); HDassert( cache_ptr->dirty_index_size == 0 ); HDassert( cache_ptr->slist_len == 0 ); HDassert( cache_ptr->slist_size == 0 ); HDassert( cache_ptr->pel_len == 0 ); HDassert( cache_ptr->pel_size == 0 ); HDassert( cache_ptr->pl_len == 0 ); HDassert( cache_ptr->pl_size == 0 ); HDassert( cache_ptr->LRU_list_len == 0 ); HDassert( cache_ptr->LRU_list_size == 0 ); HDassert( protected_entries <= cache_ptr->pl_len ); if ( protected_entries > 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Cache has protected entries.") } else if ( cur_pel_len > 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Can't unpin all pinned entries.") } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_flush_invalidate_cache() */ /*------------------------------------------------------------------------- * * Function: H5C_flush_single_entry * * Purpose: Flush or clear (and evict if requested) the cache entry * with the specified address and type. If the type is NULL, * any unprotected entry at the specified address will be * flushed (and possibly evicted). * * Attempts to flush a protected entry will result in an * error. * * *first_flush_ptr should be true if only one * flush is contemplated before the next load, or if this * is the first of a sequence of flushes that will be * completed before the next load. *first_flush_ptr is set * to false if a flush actually takes place, and should be * left false until the end of the sequence. * * The primary_dxpl_id is used if *first_flush_ptr is TRUE * on entry, and a flush actually takes place. The * secondary_dxpl_id is used in any subsequent flush where * *first_flush_ptr is FALSE on entry. * * If the H5C__FLUSH_INVALIDATE_FLAG flag is set, the entry will * be cleared and not flushed -- in the case *first_flush_ptr, * primary_dxpl_id, and secondary_dxpl_id are all irrelevent, * and the call can't be part of a sequence of flushes. * * If the caller knows the address of the TBBT node at * which the target entry resides, it can avoid a lookup * by supplying that address in the tgt_node_ptr parameter. * If this parameter is NULL, the function will do a TBBT * search for the entry instead. * * The function does nothing silently if there is no entry * at the supplied address, or if the entry found has the * wrong type. * * Return: Non-negative on success/Negative on failure or if there was * an attempt to flush a protected item. * * Programmer: John Mainzer, 5/5/04 * *------------------------------------------------------------------------- */ static herr_t H5C_flush_single_entry(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, const H5C_class_t * type_ptr, haddr_t addr, unsigned flags, hbool_t * first_flush_ptr, hbool_t del_entry_from_slist_on_destroy) { H5C_t * cache_ptr = f->shared->cache; hbool_t destroy; hbool_t clear_only; hbool_t take_ownership; hbool_t was_dirty; hbool_t destroy_entry; herr_t status; int type_id; unsigned flush_flags = H5C_CALLBACK__NO_FLAGS_SET; H5C_cache_entry_t * entry_ptr = NULL; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert( f ); HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( H5F_addr_defined(addr) ); HDassert( first_flush_ptr ); destroy = ( (flags & H5C__FLUSH_INVALIDATE_FLAG) != 0 ); clear_only = ( (flags & H5C__FLUSH_CLEAR_ONLY_FLAG) != 0); take_ownership = ( (flags & H5C__TAKE_OWNERSHIP_FLAG) != 0); /* Set the flag for destroying the entry, based on the 'take ownership' * and 'destroy' flags */ if(take_ownership) destroy_entry = FALSE; else destroy_entry = destroy; /* attempt to find the target entry in the hash table */ H5C__SEARCH_INDEX(cache_ptr, addr, entry_ptr, FAIL) #if H5C_DO_SANITY_CHECKS if ( entry_ptr != NULL ) { HDassert( ! ( ( destroy ) && ( entry_ptr->is_pinned ) ) ); if ( entry_ptr->in_slist ) { if ( ( ( entry_ptr->flush_marker ) && ( ! entry_ptr->is_dirty ) ) || ( entry_ptr->addr != addr ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "entry in slist failed sanity checks.") } } else { if ( ( entry_ptr->is_dirty ) || ( entry_ptr->flush_marker ) || ( entry_ptr->addr != addr ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "entry failed sanity checks.") } } } #endif /* H5C_DO_SANITY_CHECKS */ if ( ( entry_ptr != NULL ) && ( entry_ptr->is_protected ) ) { /* Attempt to flush a protected entry -- scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_PROTECT, FAIL, \ "Attempt to flush a protected entry.") } if ( ( entry_ptr != NULL ) && ( ( type_ptr == NULL ) || ( type_ptr->id == entry_ptr->type->id ) ) ) { /* we have work to do */ /* We will set flush_in_progress back to FALSE at the end if the * entry still exists at that point. */ entry_ptr->flush_in_progress = TRUE; #ifdef H5_HAVE_PARALLEL #ifndef NDEBUG /* If MPI based VFD is used, do special parallel I/O sanity checks. * Note that we only do these sanity checks when the clear_only flag * is not set, and the entry to be flushed is dirty. Don't bother * otherwise as no file I/O can result. */ if(!clear_only && entry_ptr->is_dirty && H5F_HAS_FEATURE(f, H5FD_FEAT_HAS_MPI)) { H5P_genplist_t *dxpl; /* Dataset transfer property list */ unsigned coll_meta; /* Collective metadata write flag */ /* Get the dataset transfer property list */ if(NULL == (dxpl = H5I_object(primary_dxpl_id))) HGOTO_ERROR(H5E_CACHE, H5E_BADTYPE, FAIL, "not a dataset transfer property list") /* Get the collective metadata write property */ if(H5P_get(dxpl, H5AC_COLLECTIVE_META_WRITE_NAME, &coll_meta) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTGET, FAIL, "can't retrieve xfer mode") /* Sanity check collective metadata write flag */ HDassert(coll_meta); } /* end if */ #endif /* NDEBUG */ #endif /* H5_HAVE_PARALLEL */ was_dirty = entry_ptr->is_dirty; type_id = entry_ptr->type->id; entry_ptr->flush_marker = FALSE; if ( clear_only ) { H5C__UPDATE_STATS_FOR_CLEAR(cache_ptr, entry_ptr) } else { H5C__UPDATE_STATS_FOR_FLUSH(cache_ptr, entry_ptr) } if ( destroy ) { H5C__UPDATE_STATS_FOR_EVICTION(cache_ptr, entry_ptr) } /* If the entry's type has a 'notify' callback and the entry is about * to be removed from the cache, send a 'before eviction' notice while * the entry is still fully integrated in the cache. */ if(destroy) { if(entry_ptr->type->notify && (entry_ptr->type->notify)(H5C_NOTIFY_ACTION_BEFORE_EVICT, entry_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTNOTIFY, FAIL, "can't notify client about entry to evict") } /* end if */ /* Always remove the entry from the hash table on a destroy. On a * flush with destroy, it is cheaper to discard the skip list all at * once rather than remove the entries one by one, so we only delete * from the slist only if requested. * * We must do deletions now as the callback routines will free the * entry if destroy is true. * * Note that it is possible that the entry will be moved during * its call to flush. This will upset H5C_move_entry() if we * don't tell it that it doesn't have to worry about updating the * index and SLIST. Use the destroy_in_progress field for this * purpose. */ if ( destroy ) { entry_ptr->destroy_in_progress = TRUE; H5C__DELETE_FROM_INDEX(cache_ptr, entry_ptr) if ( ( entry_ptr->in_slist ) && ( del_entry_from_slist_on_destroy ) ) { H5C__REMOVE_ENTRY_FROM_SLIST(cache_ptr, entry_ptr) } } /* Update the replacement policy for the flush or eviction. * Again, do this now so we don't have to reference freed * memory in the destroy case. */ if ( destroy ) { /* AKA eviction */ H5C__UPDATE_RP_FOR_EVICTION(cache_ptr, entry_ptr, FAIL) } else { H5C__UPDATE_RP_FOR_FLUSH(cache_ptr, entry_ptr, FAIL) } /* Destroy parent flush dependencies and free flush dependency parent * array, if necessary */ if ( destroy ) { HDassert( entry_ptr->flush_dep_nchildren == 0 ); if ( entry_ptr->flush_dep_parent_nalloc > 0 ) { while ( entry_ptr->flush_dep_nparents > 0 ) { /* Since the flush_dep_parent array willbe resized every * a flush dependency is destroyed, we do not have to * iterate over all indices. Instead, always destroy the * last dependency so we can skip the memmove() in * H5C_destroy_flush_dependency(). */ if ( H5C_destroy_flush_dependency(entry_ptr->flush_dep_parent[entry_ptr->flush_dep_nparents - 1], entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTUNDEPEND, FAIL, \ "Can't remove flush dependency") } } /* H5C_destroy_flush_dependency should have freed the parent * array when it became empty */ HDassert( ! (entry_ptr->flush_dep_parent) ); HDassert( entry_ptr->flush_dep_parent_nalloc == 0 ); } } /* Clear the dirty flag only, if requested */ if ( clear_only ) { if ( destroy ) { #ifndef NDEBUG /* we are about to call the clear callback with the * destroy flag set -- this will result in *entry_ptr * being freed. Set the magic field to bad magic * so we can detect a freed cache entry if we see * one. */ entry_ptr->magic = H5C__H5C_CACHE_ENTRY_T_BAD_MAGIC; #endif /* NDEBUG */ entry_ptr->cache_ptr = NULL; } /* Call the callback routine to clear all dirty flags for object */ if ( (entry_ptr->type->clear)(f, entry_ptr, destroy_entry) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "can't clear entry") } } else { #if H5C_DO_SANITY_CHECKS if ( ( entry_ptr->is_dirty ) && ( cache_ptr->check_write_permitted == NULL ) && ( ! (cache_ptr->write_permitted) ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Write when writes are always forbidden!?!?!") } #endif /* H5C_DO_SANITY_CHECKS */ if ( destroy ) { #ifndef NDEBUG /* we are about to call the flush callback with the * destroy flag set -- this will result in *entry_ptr * being freed. Set the magic field to bad magic * so we can detect a freed cache entry if we see * one. */ entry_ptr->magic = H5C__H5C_CACHE_ENTRY_T_BAD_MAGIC; #endif /* NDEBUG */ entry_ptr->cache_ptr = NULL; } /* Only block for all the processes on the first piece of metadata */ if ( *first_flush_ptr && entry_ptr->is_dirty ) { status = (entry_ptr->type->flush)(f, primary_dxpl_id, destroy_entry, entry_ptr->addr, entry_ptr, &flush_flags); *first_flush_ptr = FALSE; } else { status = (entry_ptr->type->flush)(f, secondary_dxpl_id, destroy_entry, entry_ptr->addr, entry_ptr, &flush_flags); } if ( status < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "unable to flush entry") } #ifdef H5_HAVE_PARALLEL if ( flush_flags != H5C_CALLBACK__NO_FLAGS_SET ) { /* In the parallel case, flush operations can * cause problems. If they occur, scream and * die. * * At present, in the parallel case, the aux_ptr * will only be set if there is more than one * process. Thus we can use this to detect * the parallel case. * * This works for now, but if we start using the * aux_ptr for other purposes, we will have to * change this test accordingly. * * NB: While this test detects entryies that attempt * to resize or move themselves during a flush * in the parallel case, it will not detect an * entry that dirties, resizes, and/or moves * other entries during its flush. * * From what Quincey tells me, this test is * sufficient for now, as any flush routine that * does the latter will also do the former. * * If that ceases to be the case, further * tests will be necessary. */ if ( cache_ptr->aux_ptr != NULL ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "resize/move in serialize occured in parallel case.") } } #endif /* H5_HAVE_PARALLEL */ } if ( ( ! destroy ) && ( entry_ptr->in_slist ) ) { H5C__REMOVE_ENTRY_FROM_SLIST(cache_ptr, entry_ptr) } if ( ( ! destroy ) && ( was_dirty ) ) { H5C__UPDATE_INDEX_FOR_ENTRY_CLEAN(cache_ptr, entry_ptr); } if ( ! destroy ) { /* i.e. if the entry still exists */ HDassert( !(entry_ptr->is_dirty) ); HDassert( !(entry_ptr->flush_marker) ); HDassert( !(entry_ptr->in_slist) ); HDassert( !(entry_ptr->is_protected) ); HDassert( !(entry_ptr->is_read_only) ); HDassert( (entry_ptr->ro_ref_count) == 0 ); if ( (flush_flags & H5C_CALLBACK__SIZE_CHANGED_FLAG) != 0 ) { /* The entry size changed as a result of the flush. * * Most likely, the entry was compressed, and the * new version is of a different size than the old. * * In any case, we must update entry and cache size * accordingly. */ size_t new_size; if ( (entry_ptr->type->size)(f, (void *)entry_ptr, &new_size) < 0 ) { HGOTO_ERROR(H5E_RESOURCE, H5E_CANTGETSIZE, FAIL, \ "Can't get entry size after flush") } if ( new_size != entry_ptr->size ) { HDassert( entry_ptr->size < H5C_MAX_ENTRY_SIZE ); /* update the hash table for the size change * We pass TRUE as the was_clean parameter, as we * have already updated the clean and dirty index * size fields for the fact that the entry has * been flushed. (See above call to * H5C__UPDATE_INDEX_FOR_ENTRY_CLEAN()). */ H5C__UPDATE_INDEX_FOR_SIZE_CHANGE((cache_ptr), \ (entry_ptr->size), \ (new_size), \ (entry_ptr), \ (TRUE)) /* The entry can't be protected since we just flushed it. * Thus we must update the replacement policy data * structures for the size change. The macro deals * with the pinned case. */ H5C__UPDATE_RP_FOR_SIZE_CHANGE(cache_ptr, entry_ptr, \ new_size) /* The entry can't be in the slist, so no need to update * the slist for the size change. */ /* update stats for the size change */ H5C__UPDATE_STATS_FOR_ENTRY_SIZE_CHANGE(cache_ptr, \ entry_ptr, \ new_size) /* finally, update the entry size proper */ entry_ptr->size = new_size; } } if ( (flush_flags & H5C_CALLBACK__MOVED_FLAG) != 0 ) { /* The entry was moved as the result of the flush. * * Most likely, the entry was compressed, and the * new version is larger than the old and thus had * to be relocated. * * At preset, all processing for this case is * handled elsewhere. But lets keep the if statement * around just in case. */ } /* Propagate the clean flag up the flush dependency chain if * appropriate */ if ( was_dirty ) { HDassert( entry_ptr->flush_dep_ndirty_children == 0 ); if ( entry_ptr->flush_dep_nparents > 0 ) { if ( H5C__mark_flush_dep_clean(entry_ptr) < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, \ "Can't propagate flush dep clean flag") } } } entry_ptr->flush_in_progress = FALSE; } if ( cache_ptr->log_flush ) { status = (cache_ptr->log_flush)(cache_ptr, addr, was_dirty, flags, type_id); if ( status < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "log_flush callback failed.") } } } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_flush_single_entry() */ /*------------------------------------------------------------------------- * * Function: H5C_load_entry * * Purpose: Attempt to load the entry at the specified disk address * and with the specified type into memory. If successful. * return the in memory address of the entry. Return NULL * on failure. * * Note that this function simply loads the entry into * core. It does not insert it into the cache. * * Return: Non-NULL on success / NULL on failure. * * Programmer: John Mainzer, 5/18/04 * * QAK -- 1/31/08 * Added initialization for the new free_file_space_on_destroy * field. * *------------------------------------------------------------------------- */ static void * H5C_load_entry(H5F_t * f, hid_t dxpl_id, const H5C_class_t * type, haddr_t addr, void * udata) { void * thing = NULL; /* Pointer to thing loaded */ H5C_cache_entry_t * entry; /* Alias for thing loaded, as cache entry */ void * ret_value; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert(f); HDassert(f->shared); HDassert(f->shared->cache); HDassert(type); HDassert(type->load); HDassert(type->size); HDassert(H5F_addr_defined(addr)); if(NULL == (thing = (type->load)(f, dxpl_id, addr, udata))) HGOTO_ERROR(H5E_CACHE, H5E_CANTLOAD, NULL, "unable to load entry") entry = (H5C_cache_entry_t *)thing; /* In general, an entry should be clean just after it is loaded. * * However, when this code is used in the metadata cache, it is * possible that object headers will be dirty at this point, as * the load function will alter object headers if necessary to * fix an old bug. * * To support this bug fix, I have replace the old assert: * * HDassert( entry->is_dirty == FALSE ); * * with: * * HDassert( ( entry->is_dirty == FALSE ) || ( type->id == 5 ) ); * * Note that type id 5 is associated with object headers in the metadata * cache. * * When we get to using H5C for other purposes, we may wish to * tighten up the assert so that the loophole only applies to the * metadata cache. */ HDassert( ( entry->is_dirty == FALSE ) || ( type->id == 5 ) ); #ifndef NDEBUG entry->magic = H5C__H5C_CACHE_ENTRY_T_MAGIC; #endif /* NDEBUG */ entry->cache_ptr = f->shared->cache; entry->addr = addr; entry->type = type; entry->is_protected = FALSE; entry->is_read_only = FALSE; entry->ro_ref_count = 0; entry->in_slist = FALSE; entry->flush_marker = FALSE; #ifdef H5_HAVE_PARALLEL entry->clear_on_unprotect = FALSE; entry->flush_immediately = FALSE; #endif /* H5_HAVE_PARALLEL */ entry->flush_in_progress = FALSE; entry->destroy_in_progress = FALSE; entry->free_file_space_on_destroy = FALSE; if((type->size)(f, thing, &(entry->size)) < 0) HGOTO_ERROR(H5E_RESOURCE, H5E_CANTGETSIZE, NULL, "Can't get size of thing") HDassert( entry->size < H5C_MAX_ENTRY_SIZE ); /* Initialize flush dependency height fields */ entry->flush_dep_parent = NULL; entry->flush_dep_nparents = 0; entry->flush_dep_parent_nalloc = 0; entry->flush_dep_nchildren = 0; entry->flush_dep_ndirty_children = 0; entry->ht_next = NULL; entry->ht_prev = NULL; entry->next = NULL; entry->prev = NULL; entry->aux_next = NULL; entry->aux_prev = NULL; H5C__RESET_CACHE_ENTRY_STATS(entry); ret_value = thing; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_load_entry() */ /*------------------------------------------------------------------------- * * Function: H5C_make_space_in_cache * * Purpose: Attempt to evict cache entries until the index_size * is at least needed_space below max_cache_size. * * In passing, also attempt to bring cLRU_list_size to a * value greater than min_clean_size. * * Depending on circumstances, both of these goals may * be impossible, as in parallel mode, we must avoid generating * a write as part of a read (to avoid deadlock in collective * I/O), and in all cases, it is possible (though hopefully * highly unlikely) that the protected list may exceed the * maximum size of the cache. * * Thus the function simply does its best, returning success * unless an error is encountered. * * The primary_dxpl_id and secondary_dxpl_id parameters * specify the dxpl_ids used on the first write occasioned * by the call (primary_dxpl_id), and on all subsequent * writes (secondary_dxpl_id). This is useful in the metadata * cache, but may not be needed elsewhere. If so, just use the * same dxpl_id for both parameters. * * Observe that this function cannot occasion a read. * * Return: Non-negative on success/Negative on failure. * * Programmer: John Mainzer, 5/14/04 * * JRM -- 11/13/08 * Modified function to always observe the min_clean_size * whether we are maintaining the clean and dirt LRU lists * or not. To do this, we had to add the new clean_index_size * and dirty_index_size fields to H5C_t, and supporting code * as needed throughout the cache. * * The purpose of this modification is to avoid "metadata * blizzards" in the write only case. In such instances, * the cache was allowed to fill with dirty metadata. When * we finally needed to evict an entry to make space, we had * to flush out a whole cache full of metadata -- which has * interesting performance effects. We hope to avoid (or * perhaps more accurately hide) this effect by maintaining * the min_clean_size, which should force us to start flushing * entries long before we actually have to evict something * to make space. * * MAM -- 01/06/09 * Added code to maintain clean_entries_skipped and total_entries * scanned statistics. *------------------------------------------------------------------------- */ static herr_t H5C_make_space_in_cache(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, size_t space_needed, hbool_t write_permitted, hbool_t * first_flush_ptr) { H5C_t * cache_ptr = f->shared->cache; herr_t result; #if H5C_COLLECT_CACHE_STATS int32_t clean_entries_skipped = 0; int32_t total_entries_scanned = 0; #endif /* H5C_COLLECT_CACHE_STATS */ int32_t entries_examined = 0; int32_t initial_list_len; size_t empty_space; hbool_t prev_is_dirty = FALSE; hbool_t didnt_flush_entry = FALSE; H5C_cache_entry_t * entry_ptr; H5C_cache_entry_t * prev_ptr; H5C_cache_entry_t * next_ptr; herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT HDassert( f ); HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( first_flush_ptr != NULL ); HDassert( ( *first_flush_ptr == TRUE ) || ( *first_flush_ptr == FALSE ) ); HDassert( cache_ptr->index_size == (cache_ptr->clean_index_size + cache_ptr->dirty_index_size) ); if ( write_permitted ) { initial_list_len = cache_ptr->LRU_list_len; entry_ptr = cache_ptr->LRU_tail_ptr; if ( cache_ptr->index_size >= cache_ptr->max_cache_size ) { empty_space = 0; } else { empty_space = cache_ptr->max_cache_size - cache_ptr->index_size; } while ( ( ( (cache_ptr->index_size + space_needed) > cache_ptr->max_cache_size ) || ( ( empty_space + cache_ptr->clean_index_size ) < ( cache_ptr->min_clean_size ) ) ) && ( entries_examined <= (2 * initial_list_len) ) && ( entry_ptr != NULL ) ) { HDassert( ! (entry_ptr->is_protected) ); HDassert( ! (entry_ptr->is_read_only) ); HDassert( (entry_ptr->ro_ref_count) == 0 ); next_ptr = entry_ptr->next; prev_ptr = entry_ptr->prev; if ( prev_ptr != NULL ) { prev_is_dirty = prev_ptr->is_dirty; } if ( (entry_ptr->type)->id != H5C__EPOCH_MARKER_TYPE ) { didnt_flush_entry = FALSE; if ( entry_ptr->is_dirty ) { #if H5C_COLLECT_CACHE_STATS if ( (cache_ptr->index_size + space_needed) > cache_ptr->max_cache_size ) { cache_ptr->entries_scanned_to_make_space++; } #endif /* H5C_COLLECT_CACHE_STATS */ result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__NO_FLAGS_SET, first_flush_ptr, FALSE); } else if ( (cache_ptr->index_size + space_needed) > cache_ptr->max_cache_size ) { #if H5C_COLLECT_CACHE_STATS cache_ptr->entries_scanned_to_make_space++; #endif /* H5C_COLLECT_CACHE_STATS */ result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__FLUSH_INVALIDATE_FLAG, first_flush_ptr, TRUE); } else { /* We have enough space so don't flush clean entry. * Set result to SUCCEED to avoid triggering the error * code below. */ #if H5C_COLLECT_CACHE_STATS clean_entries_skipped++; #endif /* H5C_COLLECT_CACHE_STATS */ didnt_flush_entry = TRUE; result = SUCCEED; } #if H5C_COLLECT_CACHE_STATS total_entries_scanned++; #endif /* H5C_COLLECT_CACHE_STATS */ } else { /* Skip epoch markers. Set result to SUCCEED to avoid * triggering the error code below. */ didnt_flush_entry = TRUE; result = SUCCEED; } if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "unable to flush entry") } if ( prev_ptr != NULL ) { #ifndef NDEBUG if ( prev_ptr->magic != H5C__H5C_CACHE_ENTRY_T_MAGIC ) { /* something horrible has happened to *prev_ptr -- * scream and die. */ HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "*prev_ptr corrupt 1") } #endif /* NDEBUG */ if ( didnt_flush_entry ) { /* epoch markers don't get flushed, so the sanity checks * on normal entries will fail -- thus just set entry_ptr * to prev_ptr and go on. */ entry_ptr = prev_ptr; } else if ( ( prev_ptr->is_dirty != prev_is_dirty ) || ( prev_ptr->next != next_ptr ) || ( prev_ptr->is_protected ) || ( prev_ptr->is_pinned ) ) { /* something has happened to the LRU -- start over * from the tail. */ entry_ptr = cache_ptr->LRU_tail_ptr; } else { entry_ptr = prev_ptr; } } else { entry_ptr = NULL; } entries_examined++; if ( cache_ptr->index_size >= cache_ptr->max_cache_size ) { empty_space = 0; } else { empty_space = cache_ptr->max_cache_size - cache_ptr->index_size; } HDassert( cache_ptr->index_size == (cache_ptr->clean_index_size + cache_ptr->dirty_index_size) ); } #if H5C_COLLECT_CACHE_STATS cache_ptr->calls_to_msic++; cache_ptr->total_entries_skipped_in_msic += clean_entries_skipped; cache_ptr->total_entries_scanned_in_msic += total_entries_scanned; if ( clean_entries_skipped > cache_ptr->max_entries_skipped_in_msic ) { cache_ptr->max_entries_skipped_in_msic = clean_entries_skipped; } if ( total_entries_scanned > cache_ptr->max_entries_scanned_in_msic ) { cache_ptr->max_entries_scanned_in_msic = total_entries_scanned; } #endif /* H5C_COLLECT_CACHE_STATS */ HDassert( ( entries_examined > (2 * initial_list_len) ) || ( (cache_ptr->pl_size + cache_ptr->pel_size + cache_ptr->min_clean_size) > cache_ptr->max_cache_size ) || ( ( cache_ptr->clean_index_size + empty_space ) >= cache_ptr->min_clean_size ) ); #if H5C_MAINTAIN_CLEAN_AND_DIRTY_LRU_LISTS HDassert( ( entries_examined > (2 * initial_list_len) ) || ( cache_ptr->cLRU_list_size <= cache_ptr->clean_index_size ) ); HDassert( ( entries_examined > (2 * initial_list_len) ) || ( cache_ptr->dLRU_list_size <= cache_ptr->dirty_index_size ) ); #endif /* H5C_MAINTAIN_CLEAN_AND_DIRTY_LRU_LISTS */ } else { HDassert( H5C_MAINTAIN_CLEAN_AND_DIRTY_LRU_LISTS ); initial_list_len = cache_ptr->cLRU_list_len; entry_ptr = cache_ptr->cLRU_tail_ptr; while ( ( (cache_ptr->index_size + space_needed) > cache_ptr->max_cache_size ) && ( entries_examined <= initial_list_len ) && ( entry_ptr != NULL ) ) { HDassert( ! (entry_ptr->is_protected) ); HDassert( ! (entry_ptr->is_read_only) ); HDassert( (entry_ptr->ro_ref_count) == 0 ); HDassert( ! (entry_ptr->is_dirty) ); prev_ptr = entry_ptr->aux_prev; result = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__FLUSH_INVALIDATE_FLAG, first_flush_ptr, TRUE); if ( result < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "unable to flush entry") } entry_ptr = prev_ptr; entries_examined++; } } done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_make_space_in_cache() */ /*------------------------------------------------------------------------- * * Function: H5C_validate_lru_list * * Purpose: Debugging function that scans the LRU list for errors. * * If an error is detected, the function generates a * diagnostic and returns FAIL. If no error is detected, * the function returns SUCCEED. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: John Mainzer, 7/14/05 * *------------------------------------------------------------------------- */ #if H5C_DO_EXTREME_SANITY_CHECKS static herr_t H5C_validate_lru_list(H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; /* Return value */ int32_t len = 0; size_t size = 0; H5C_cache_entry_t * entry_ptr = NULL; FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); if ( ( ( cache_ptr->LRU_head_ptr == NULL ) || ( cache_ptr->LRU_tail_ptr == NULL ) ) && ( cache_ptr->LRU_head_ptr != cache_ptr->LRU_tail_ptr ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 1 failed") } if ( ( cache_ptr->LRU_list_len < 0 ) || ( cache_ptr->LRU_list_size < 0 ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 2 failed") } if ( ( cache_ptr->LRU_list_len == 1 ) && ( ( cache_ptr->LRU_head_ptr != cache_ptr->LRU_tail_ptr ) || ( cache_ptr->LRU_head_ptr == NULL ) || ( cache_ptr->LRU_head_ptr->size != cache_ptr->LRU_list_size ) ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 3 failed") } if ( ( cache_ptr->LRU_list_len >= 1 ) && ( ( cache_ptr->LRU_head_ptr == NULL ) || ( cache_ptr->LRU_head_ptr->prev != NULL ) || ( cache_ptr->LRU_tail_ptr == NULL ) || ( cache_ptr->LRU_tail_ptr->next != NULL ) ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 4 failed") } entry_ptr = cache_ptr->LRU_head_ptr; while ( entry_ptr != NULL ) { if ( ( entry_ptr != cache_ptr->LRU_head_ptr ) && ( ( entry_ptr->prev == NULL ) || ( entry_ptr->prev->next != entry_ptr ) ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 5 failed") } if ( ( entry_ptr != cache_ptr->LRU_tail_ptr ) && ( ( entry_ptr->next == NULL ) || ( entry_ptr->next->prev != entry_ptr ) ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 6 failed") } len++; size += entry_ptr->size; entry_ptr = entry_ptr->next; } if ( ( cache_ptr->LRU_list_len != len ) || ( cache_ptr->LRU_list_size != size ) ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, "Check 7 failed") } done: if ( ret_value != SUCCEED ) { HDassert(0); } FUNC_LEAVE_NOAPI(ret_value) } /* H5C_validate_lru_list() */ #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ /*------------------------------------------------------------------------- * * Function: H5C_verify_not_in_index * * Purpose: Debugging function that scans the hash table to verify * that the specified instance of H5C_cache_entry_t is not * present. * * If an error is detected, the function generates a * diagnostic and returns FAIL. If no error is detected, * the function returns SUCCEED. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: John Mainzer, 7/14/05 * *------------------------------------------------------------------------- */ #if H5C_DO_EXTREME_SANITY_CHECKS static herr_t H5C_verify_not_in_index(H5C_t * cache_ptr, H5C_cache_entry_t * entry_ptr) { herr_t ret_value = SUCCEED; /* Return value */ int32_t i; int32_t depth; H5C_cache_entry_t * scan_ptr = NULL; FUNC_ENTER_NOAPI_NOINIT HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); HDassert( entry_ptr != NULL ); for ( i = 0; i < H5C__HASH_TABLE_LEN; i++ ) { depth = 0; scan_ptr = cache_ptr->index[i]; while ( scan_ptr != NULL ) { if ( scan_ptr == entry_ptr ) { HGOTO_ERROR(H5E_CACHE, H5E_SYSTEM, FAIL, \ "Entry already in index.") } depth++; scan_ptr = scan_ptr->ht_next; } } done: if ( ret_value != SUCCEED ) { HDassert(0); } FUNC_LEAVE_NOAPI(ret_value) } /* H5C_verify_not_in_index() */ #endif /* H5C_DO_EXTREME_SANITY_CHECKS */ /*------------------------------------------------------------------------- * * Function: H5C_ignore_tags * * Purpose: Override all assertion frameworks associated with making * sure proper tags are applied to cache entries. * * NOTE: This should really only be used in tests that need * to access internal functions without going through * standard API paths. Since tags are set inside dxpl_id's * before coming into the cache, any external functions that * use the internal library functions (i.e., tests) should * use this function if they don't plan on setting up proper * tags. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * December 1, 2009 * *------------------------------------------------------------------------- */ herr_t H5C_ignore_tags(H5C_t * cache_ptr) { FUNC_ENTER_NOAPI_NOERR /* Assertions */ HDassert(cache_ptr != NULL); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Set variable to ignore tag values upon assignment */ cache_ptr->ignore_tags = TRUE; FUNC_LEAVE_NOAPI(SUCCEED) } /* H5C_ignore_tags */ /*------------------------------------------------------------------------- * * Function: H5C_tag_entry * * Purpose: Tags an entry with the provided tag (contained in the dxpl_id). * If sanity checking is enabled, this function will perform * validation that a proper tag is contained within the provided * data access property list id before application. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * January 14, 2010 * * Modifications: * *------------------------------------------------------------------------- */ static herr_t H5C_tag_entry(H5C_t * cache_ptr, H5C_cache_entry_t * entry_ptr, hid_t dxpl_id) { H5P_genplist_t *dxpl; /* dataset transfer property list */ H5C_tag_t tag; /* Tag structure */ hid_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI(FAIL) /* Assertions */ HDassert(cache_ptr != NULL); HDassert(entry_ptr != NULL); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Get the dataset transfer property list */ if(NULL == (dxpl = (H5P_genplist_t *)H5I_object_verify(dxpl_id, H5I_GENPROP_LST))) HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a property list") /* Get the tag from the DXPL */ if((H5P_get(dxpl, "H5C_tag", &tag)) < 0) HGOTO_ERROR(H5E_PLIST, H5E_CANTGET, FAIL, "unable to query property value") /* Apply the tag to the entry */ entry_ptr->tag = tag.value; /* Apply the tag globality to the entry */ entry_ptr->globality = tag.globality; done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_tag_entry */ /*------------------------------------------------------------------------- * * Function: H5C_flush_tagged_entries * * Purpose: Flushes all entries with the specified tag to disk. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * August 19, 2010 * *------------------------------------------------------------------------- */ herr_t H5C_flush_tagged_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, haddr_t tag) { /* Variable Declarations */ H5C_t *cache_ptr = NULL; herr_t result; herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI(FAIL) /* Assertions */ HDassert(f); HDassert(f->shared); /* Get cache pointer */ cache_ptr = f->shared->cache; /* Mark all entries with specified tag */ if ( (result = H5C_mark_tagged_entries(cache_ptr, tag, FALSE)) < 0 ) HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Can't mark tagged entries") /* Flush all marked entries */ if(H5C_flush_marked_entries(f, primary_dxpl_id, secondary_dxpl_id, cache_ptr) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Can't flush marked entries") done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_flush_tagged_entries */ /*------------------------------------------------------------------------- * * Function: H5C_evict_tagged_entries * * Purpose: Evicts all entries with the specified tag to disk. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * August 19, 2010 * *------------------------------------------------------------------------- */ herr_t H5C_evict_tagged_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, haddr_t tag) { /* Variables */ H5C_t *cache_ptr = NULL; herr_t result; herr_t ret_value = SUCCEED; /* Function Enter Macro */ FUNC_ENTER_NOAPI(FAIL) /* Assertions */ HDassert(f); HDassert(f->shared); /* Get cache pointer */ cache_ptr = f->shared->cache; /* Mark all entries with specified tag */ if ( (result = H5C_mark_tagged_entries(cache_ptr, tag, TRUE)) < 0 ) HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Can't mark tagged entries") /* Evict all marked entries */ if ( (result = H5C_evict_marked_entries(f, primary_dxpl_id, secondary_dxpl_id, cache_ptr)) < 0 ) HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Can't evict marked entries") done: /* Function Leave Macro */ FUNC_LEAVE_NOAPI(ret_value) } /* H5C_evict_tagged_entries */ /*------------------------------------------------------------------------- * * Function: H5C_mark_tagged_entries * * Purpose: Set the flush marker on dirty entries in the cache that have * the specified tag, as well as all globally tagged entries. * If mark_clean is set, this function will also mark all clean * entries, indicating they are to be evicted. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * September 9, 2010 * *------------------------------------------------------------------------- */ static herr_t H5C_mark_tagged_entries(H5C_t * cache_ptr, haddr_t tag, hbool_t mark_clean) { /* Variable Declarations */ int u; /* Iterator */ H5C_cache_entry_t *entry_ptr = NULL; /* entry pointer */ FUNC_ENTER_NOAPI_NOINIT_NOERR /* Assertions */ HDassert(cache_ptr != NULL); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Iterate through entries, marking those with specified tag, as * well as any major global entries which should always be flushed * when flushing based on tag value */ for(u = 0; u < H5C__HASH_TABLE_LEN; u++) { entry_ptr = cache_ptr->index[u]; while ( entry_ptr != NULL ) { if (( entry_ptr->tag == tag ) || ( entry_ptr->globality == H5C_GLOBALITY_MAJOR)) { /* We only want to set the flush marker on entries that * actually need flushed (i.e., dirty ones), unless * we've specified otherwise with the mark_clean flag */ if (entry_ptr->is_dirty || mark_clean) { entry_ptr->flush_marker = TRUE; } /* end if */ } /* end if */ entry_ptr = entry_ptr->ht_next; } /* end while */ } /* for */ FUNC_LEAVE_NOAPI(SUCCEED) } /* H5C_mark_tagged_entries */ /*------------------------------------------------------------------------- * * Function: H5C_flush_marked_entries * * Purpose: Flushes all marked entries in the cache. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * November 3, 2010 * *------------------------------------------------------------------------- */ static herr_t H5C_flush_marked_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, H5C_t * cache_ptr) { herr_t ret_value = SUCCEED; FUNC_ENTER_NOAPI_NOINIT /* Assertions */ HDassert(cache_ptr != NULL); HDassert(cache_ptr->magic == H5C__H5C_T_MAGIC); /* Flush all marked entries */ if(H5C_flush_cache(f, primary_dxpl_id, secondary_dxpl_id, H5C__FLUSH_MARKED_ENTRIES_FLAG | H5C__FLUSH_IGNORE_PROTECTED_FLAG) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Can't flush cache") done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C_flush_marked_entries */ /*------------------------------------------------------------------------- * * Function: H5C_evict_marked_entries * * Purpose: Evicts all marked entries in the cache. * * Return: FAIL if error is detected, SUCCEED otherwise. * * Programmer: Mike McGreevy * July 16, 2010 * *------------------------------------------------------------------------- */ static herr_t H5C_evict_marked_entries(H5F_t * f, hid_t primary_dxpl_id, hid_t secondary_dxpl_id, H5C_t * cache_ptr) { /* Variable Declarations */ herr_t status; herr_t ret_value = SUCCEED; H5C_cache_entry_t * entry_ptr = NULL; H5C_cache_entry_t * next_entry_ptr = NULL; int i; hbool_t evicted_entries_last_pass; hbool_t pinned_entries_need_evicted; hbool_t first_flush = TRUE; /* Function Enter Macro */ FUNC_ENTER_NOAPI_NOINIT /* Assertions */ HDassert( cache_ptr != NULL ); HDassert( cache_ptr->magic == H5C__H5C_T_MAGIC ); /* Start evicting entries */ do { /* Reset pinned/evicted trackers */ pinned_entries_need_evicted = FALSE; evicted_entries_last_pass = FALSE; /* Iterate through entries in the index. */ for (i = 0; i < H5C__HASH_TABLE_LEN; i++) { next_entry_ptr = cache_ptr->index[i]; while ( next_entry_ptr != NULL ) { entry_ptr = next_entry_ptr; next_entry_ptr = entry_ptr->ht_next; if ( entry_ptr->flush_marker == TRUE ) { /* This entry will need to be evicted */ if ( entry_ptr->is_protected ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Cannot evict protected entry"); } else if (entry_ptr->is_dirty) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Cannot evict dirty entry"); } else if (entry_ptr->is_pinned) { /* Can't evict at this time, but let's note that we hit a pinned entry and we'll loop back around again (as evicting other entries will hopefully unpin this entry) */ pinned_entries_need_evicted = TRUE; } else { /* Evict the Entry */ status = H5C_flush_single_entry(f, primary_dxpl_id, secondary_dxpl_id, entry_ptr->type, entry_ptr->addr, H5C__FLUSH_INVALIDATE_FLAG | H5C__FLUSH_CLEAR_ONLY_FLAG, &first_flush, TRUE); if ( status < 0 ) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, \ "Entry eviction failed.") } evicted_entries_last_pass = TRUE; } /* end if */ } /* end if */ } /* end while */ } /* end for */ /* Keep doing this until we have stopped evicted entries */ } while ((evicted_entries_last_pass == TRUE)); /* If we stop evicting entries and pinned entries still need evicted, then we have a problem. */ if (pinned_entries_need_evicted) { HGOTO_ERROR(H5E_CACHE, H5E_CANTFLUSH, FAIL, "Pinned entries still need evicted?!"); } /* end if */ done: FUNC_LEAVE_NOAPI(ret_value); } /* H5C_evict_marked_entries */ /*------------------------------------------------------------------------- * * Function: H5C_retag_entries * * Purpose: Searches through cache index for all entries with the * value specified by src_tag and changes it to the value * specified by dest_tag. * * Return: SUCCEED or FAIL. * * Programmer: Mike McGreevy * March 17, 2010 * *------------------------------------------------------------------------- */ void H5C_retag_entries(H5C_t * cache_ptr, haddr_t src_tag, haddr_t dest_tag) { unsigned u; /* Local index variable */ H5C_cache_entry_t *entry_ptr = NULL; /* entry pointer */ FUNC_ENTER_NOAPI_NOINIT_NOERR /* Iterate through entries, retagging those with the src_tag tag */ for(u = 0; u < H5C__HASH_TABLE_LEN; u++) { entry_ptr = cache_ptr->index[u]; while(entry_ptr != NULL) { if(cache_ptr->index[u] != NULL) { if((cache_ptr->index[u])->tag == src_tag) { (cache_ptr->index[u])->tag = dest_tag; } } /* end if */ entry_ptr = entry_ptr->ht_next; } /* end while */ } /* end for */ FUNC_LEAVE_NOAPI_VOID } /* H5C_retag_entries */ /*------------------------------------------------------------------------- * Function: H5C__mark_flush_dep_dirty() * * Purpose: Recursively propagate the flush_dep_ndirty_children flag * up the dependency chain in response to entry either * becoming dirty or having its flush_dep_ndirty_children * increased from 0. * * Return: Non-negative on success/Negative on failure * * Programmer: Neil Fortner * 11/13/12 * *------------------------------------------------------------------------- */ static herr_t H5C__mark_flush_dep_dirty(H5C_cache_entry_t * entry) { unsigned i; /* Local index variable */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT /* Sanity checks */ HDassert(entry); HDassert((entry->is_dirty && entry->flush_dep_ndirty_children == 0) || (!entry->is_dirty && entry->flush_dep_ndirty_children == 1)); /* Iterate over the parent entries, if any */ for(i=0; iflush_dep_nparents; i++) { /* Sanity check */ HDassert(entry->flush_dep_parent[i]->flush_dep_ndirty_children < entry->flush_dep_parent[i]->flush_dep_nchildren); /* Adjust the parent's number of dirty children */ entry->flush_dep_parent[i]->flush_dep_ndirty_children++; /* Propagate the flush dep dirty flag up the chain if necessary */ if(!entry->flush_dep_parent[i]->is_dirty && entry->flush_dep_parent[i]->flush_dep_ndirty_children == 1) if(H5C__mark_flush_dep_dirty(entry->flush_dep_parent[i]) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, "can't propagate flush dep dirty flag") } /* end for */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__mark_flush_dep_dirty() */ /*------------------------------------------------------------------------- * Function: H5C__mark_flush_dep_clean() * * Purpose: Recursively propagate the flush_dep_ndirty_children flag * up the dependency chain in response to entry either * becoming clean or having its flush_dep_ndirty_children * reduced to 0. * * Return: Non-negative on success/Negative on failure * * Programmer: Neil Fortner * 11/13/12 * *------------------------------------------------------------------------- */ static herr_t H5C__mark_flush_dep_clean(H5C_cache_entry_t * entry) { unsigned i; /* Local index variable */ herr_t ret_value = SUCCEED; /* Return value */ FUNC_ENTER_NOAPI_NOINIT /* Sanity checks */ HDassert(entry); HDassert(!entry->is_dirty && entry->flush_dep_ndirty_children == 0); /* Iterate over the parent entries, if any */ for(i=0; iflush_dep_nparents; i++) { /* Sanity check */ HDassert(entry->flush_dep_parent[i]->flush_dep_ndirty_children > 0); /* Adjust the parent's number of dirty children */ entry->flush_dep_parent[i]->flush_dep_ndirty_children--; /* Propagate the flush dep clean flag up the chain if necessary */ if(!entry->flush_dep_parent[i]->is_dirty && entry->flush_dep_parent[i]->flush_dep_ndirty_children == 0) if(H5C__mark_flush_dep_clean(entry->flush_dep_parent[i]) < 0) HGOTO_ERROR(H5E_CACHE, H5E_CANTMARKDIRTY, FAIL, "can't propagate flush dep clean flag") } /* end for */ done: FUNC_LEAVE_NOAPI(ret_value) } /* H5C__mark_flush_dep_clean() */ #ifndef NDEBUG /*------------------------------------------------------------------------- * Function: H5C__assert_flush_dep_nocycle() * * Purpose: Assert recursively that base_entry is not the same as * entry, and perform the same assertion on all of entry's * flush dependency parents. This is used to detect cycles * created by flush dependencies. * * Return: void * * Programmer: Neil Fortner * 12/10/12 * *------------------------------------------------------------------------- */ static void H5C__assert_flush_dep_nocycle(H5C_cache_entry_t * entry, H5C_cache_entry_t * base_entry) { unsigned i; /* Local index variable */ FUNC_ENTER_NOAPI_NOINIT_NOERR /* Sanity checks */ HDassert(entry); HDassert(base_entry); /* Make sure the entries are not the same */ HDassert(base_entry != entry); /* Iterate over entry's parents (if any) */ for(i=0; iflush_dep_nparents; i++) H5C__assert_flush_dep_nocycle(entry->flush_dep_parent[i], base_entry); FUNC_LEAVE_NOAPI_VOID } /* H5C__assert_flush_dep_nocycle() */ #endif /* NDEBUG */