hdf5/test/cache_common.h
Quincey Koziol 824d691cbf [svn-r18252] Description:
Rename test macros that are [nearly] identical to source code macros to
have "TEST" in their names, to avoid conflicts during compilation.  (And add
comment to originals in source code, to keep them in sync).

Tested on:
    Mac OS X/32 10.6.2 (amazon) w/debug & production
    up041 machines (at Sandia)
2010-02-14 14:27:07 -05:00

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/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* 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. *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/* Programmer: John Mainzer
* 10/27/05
*
* This file contains common #defines, type definitions, and
* externs for tests of the cache implemented in H5C.c
*/
#ifndef _CACHE_COMMON_H
#define _CACHE_COMMON_H
#define H5C_PACKAGE /*suppress error about including H5Cpkg */
#define H5F_PACKAGE /*suppress error about including H5Fpkg */
/* Include library header files */
#include "H5ACprivate.h"
#include "H5Cpkg.h"
#include "H5Fpkg.h"
#include "H5Iprivate.h"
/* Include test header files */
#include "h5test.h"
/* Macro to make error reporting easier */
#define CACHE_ERROR(s) {failure_mssg = "Line #" H5_TOSTRING(__LINE__) ": " s ; pass = FALSE; goto done;}
#define NO_CHANGE -1
/* with apologies for the abuse of terminology... */
#define PICO_ENTRY_TYPE 0
#define NANO_ENTRY_TYPE 1
#define MICRO_ENTRY_TYPE 2
#define TINY_ENTRY_TYPE 3
#define SMALL_ENTRY_TYPE 4
#define MEDIUM_ENTRY_TYPE 5
#define LARGE_ENTRY_TYPE 6
#define HUGE_ENTRY_TYPE 7
#define MONSTER_ENTRY_TYPE 8
#define VARIABLE_ENTRY_TYPE 9
#define NOTIFY_ENTRY_TYPE 10
#define NUMBER_OF_ENTRY_TYPES 11
#define PICO_ENTRY_SIZE (size_t)1
#define NANO_ENTRY_SIZE (size_t)4
#define MICRO_ENTRY_SIZE (size_t)16
#define TINY_ENTRY_SIZE (size_t)64
#define SMALL_ENTRY_SIZE (size_t)256
#define MEDIUM_ENTRY_SIZE (size_t)1024
#define LARGE_ENTRY_SIZE (size_t)(4 * 1024)
#define HUGE_ENTRY_SIZE (size_t)(16 * 1024)
#define MONSTER_ENTRY_SIZE (size_t)(64 * 1024)
#define VARIABLE_ENTRY_SIZE (size_t)(10 * 1024)
#define NOTIFY_ENTRY_SIZE (size_t)1
#define NUM_PICO_ENTRIES (10 * 1024)
#define NUM_NANO_ENTRIES (10 * 1024)
#define NUM_MICRO_ENTRIES (10 * 1024)
#define NUM_TINY_ENTRIES (10 * 1024)
#define NUM_SMALL_ENTRIES (10 * 1024)
#define NUM_MEDIUM_ENTRIES (10 * 1024)
#define NUM_LARGE_ENTRIES (10 * 1024)
#define NUM_HUGE_ENTRIES (10 * 1024)
#define NUM_MONSTER_ENTRIES (10 * 1024)
#define NUM_VARIABLE_ENTRIES (10 * 1024)
#define NUM_NOTIFY_ENTRIES (10 * 1024)
#define MAX_ENTRIES (10 * 1024)
/* The choice of the BASE_ADDR below is arbitrary -- it just has to be
* larger than the superblock.
*/
#define BASE_ADDR (haddr_t)1024
#define PICO_BASE_ADDR BASE_ADDR
#define NANO_BASE_ADDR (haddr_t)(PICO_BASE_ADDR + \
(PICO_ENTRY_SIZE * NUM_PICO_ENTRIES))
#define MICRO_BASE_ADDR (haddr_t)(NANO_BASE_ADDR + \
(NANO_ENTRY_SIZE * NUM_NANO_ENTRIES))
#define TINY_BASE_ADDR (haddr_t)(MICRO_BASE_ADDR + \
(MICRO_ENTRY_SIZE * NUM_MICRO_ENTRIES))
#define SMALL_BASE_ADDR (haddr_t)(TINY_BASE_ADDR + \
(TINY_ENTRY_SIZE * NUM_TINY_ENTRIES))
#define MEDIUM_BASE_ADDR (haddr_t)(SMALL_BASE_ADDR + \
(SMALL_ENTRY_SIZE * NUM_SMALL_ENTRIES))
#define LARGE_BASE_ADDR (haddr_t)(MEDIUM_BASE_ADDR + \
(MEDIUM_ENTRY_SIZE * NUM_MEDIUM_ENTRIES))
#define HUGE_BASE_ADDR (haddr_t)(LARGE_BASE_ADDR + \
(LARGE_ENTRY_SIZE * NUM_LARGE_ENTRIES))
#define MONSTER_BASE_ADDR (haddr_t)(HUGE_BASE_ADDR + \
(HUGE_ENTRY_SIZE * NUM_HUGE_ENTRIES))
#define VARIABLE_BASE_ADDR (haddr_t)(MONSTER_BASE_ADDR + \
(MONSTER_ENTRY_SIZE * NUM_MONSTER_ENTRIES))
#define NOTIFY_BASE_ADDR (haddr_t)(VARIABLE_BASE_ADDR + \
(VARIABLE_ENTRY_SIZE * NUM_VARIABLE_ENTRIES))
#define PICO_ALT_BASE_ADDR (haddr_t)(NOTIFY_BASE_ADDR + \
(NOTIFY_ENTRY_SIZE * NUM_NOTIFY_ENTRIES))
#define NANO_ALT_BASE_ADDR (haddr_t)(PICO_ALT_BASE_ADDR + \
(PICO_ENTRY_SIZE * NUM_PICO_ENTRIES))
#define MICRO_ALT_BASE_ADDR (haddr_t)(NANO_ALT_BASE_ADDR + \
(NANO_ENTRY_SIZE * NUM_NANO_ENTRIES))
#define TINY_ALT_BASE_ADDR (haddr_t)(MICRO_ALT_BASE_ADDR + \
(MICRO_ENTRY_SIZE * NUM_MICRO_ENTRIES))
#define SMALL_ALT_BASE_ADDR (haddr_t)(TINY_ALT_BASE_ADDR + \
(TINY_ENTRY_SIZE * NUM_TINY_ENTRIES))
#define MEDIUM_ALT_BASE_ADDR (haddr_t)(SMALL_ALT_BASE_ADDR + \
(SMALL_ENTRY_SIZE * NUM_SMALL_ENTRIES))
#define LARGE_ALT_BASE_ADDR (haddr_t)(MEDIUM_ALT_BASE_ADDR + \
(MEDIUM_ENTRY_SIZE * NUM_MEDIUM_ENTRIES))
#define HUGE_ALT_BASE_ADDR (haddr_t)(LARGE_ALT_BASE_ADDR + \
(LARGE_ENTRY_SIZE * NUM_LARGE_ENTRIES))
#define MONSTER_ALT_BASE_ADDR (haddr_t)(HUGE_ALT_BASE_ADDR + \
(HUGE_ENTRY_SIZE * NUM_HUGE_ENTRIES))
#define VARIABLE_ALT_BASE_ADDR (haddr_t)(MONSTER_ALT_BASE_ADDR + \
(MONSTER_ENTRY_SIZE * NUM_MONSTER_ENTRIES))
#define NOTIFY_ALT_BASE_ADDR (haddr_t)(VARIABLE_ALT_BASE_ADDR + \
(VARIABLE_ENTRY_SIZE * NUM_VARIABLE_ENTRIES))
#define MAX_ADDR (haddr_t)(NOTIFY_ALT_BASE_ADDR + \
(NOTIFY_ENTRY_SIZE * NUM_NOTIFY_ENTRIES))
#define ADDR_SPACE_SIZE (haddr_t)(MAX_ADDR - BASE_ADDR)
#define MAX_PINS 8 /* Maximum number of entries that can be
* directly pinned by a single entry.
*/
#define FLUSH_OP__NO_OP 0
#define FLUSH_OP__DIRTY 1
#define FLUSH_OP__RESIZE 2
#define FLUSH_OP__RENAME 3
#define FLUSH_OP__ORDER 4
#define FLUSH_OP__MAX_OP 4
#define MAX_FLUSH_OPS 10 /* Maximum number of flush operations
* that can be associated with a
* cache entry.
*/
typedef struct flush_op
{
int op_code; /* integer op code indicating the
* operation to be performed. At
* present it must be one of:
*
* FLUSH_OP__NO_OP
* FLUSH_OP__DIRTY
* FLUSH_OP__RESIZE
* FLUSH_OP__RENAME
* FLUSH_OP__ORDER
*/
int type; /* type code of the cache entry that
* is the target of the operation.
* This value is passed into the
* function implementing the flush
* operation.
*/
int idx; /* index of the cache entry that
* is the target of the operation.
* This value is passed into the
* function implementing the flush
* operation.
*/
hbool_t flag; /* boolean flag passed into the
* function implementing the flush
* operation. The meaning of the
* flag is dependant upon the flush
* operation:
*
* FLUSH_OP__DIRTY: TRUE iff the
* target is pinned, and is to
* be dirtied via the
* H5C_mark_pinned_entry_dirty()
* call.
*
* FLUSH_OP__RESIZE: TRUE iff the
* target is pinned, and is to
* be resized via the
* H5C_mark_pinned_entry_dirty()
* call.
*
* FLUSH_OP__RENAME: TRUE iff the
* target is to be renamed to
* its main address.
*/
size_t size; /* New target size in the
* FLUSH_OP__RENAME operation.
* Unused elsewhere.
*/
unsigned * order_ptr; /* Pointer to outside counter for
* recording the order of entries
* flushed.
*/
} flush_op;
typedef struct test_entry_t
{
H5C_cache_entry_t header; /* entry data used by the cache
* -- must be first
*/
struct test_entry_t * self; /* pointer to this entry -- used for
* sanity checking.
*/
H5C_t * cache_ptr; /* pointer to the cache in which
* the entry resides, or NULL if the
* entry is not in cache.
*/
haddr_t addr; /* where the cache thinks this entry
* is located
*/
hbool_t at_main_addr; /* boolean flag indicating whether
* the entry is supposed to be at
* either its main or alternate
* address.
*/
haddr_t main_addr; /* initial location of the entry
*/
haddr_t alt_addr; /* location to which the entry
* can be relocated or "renamed"
*/
size_t size; /* how big the cache thinks this
* entry is
*/
int32_t type; /* indicates which entry array this
* entry is in
*/
int32_t index; /* index in its entry array
*/
int32_t reads; /* number of times this entry has
* been loaded.
*/
int32_t writes; /* number of times this entry has
* been written
*/
hbool_t is_dirty; /* entry has been modified since
* last write
*/
hbool_t is_protected; /* entry should currently be on
* the cache's protected list.
*/
hbool_t is_read_only; /* TRUE iff the entry should be
* protected read only.
*/
int ro_ref_count; /* Number of outstanding read only
* protects on the entry.
*/
hbool_t is_pinned; /* entry is currently pinned in
* the cache.
*/
int pinning_ref_count; /* Number of entries that
* pin this entry in the cache.
* When this count drops to zero,
* this entry should be unpinned.
*/
int num_pins; /* Number of entries that this
* entry pins in the cache. This
* value must be in the range
* [0, MAX_PINS].
*/
int pin_type[MAX_PINS]; /* array of the types of entries
* pinned by this entry.
*/
int pin_idx[MAX_PINS]; /* array of the indicies of
* entries pinned by this entry.
*/
int num_flush_ops; /* integer field containing the
* number of flush operations to
* be executed when the entry is
* flushed. This value must lie in
* the closed interval
* [0, MAX_FLUSH_OPS].
*/
struct flush_op flush_ops[MAX_FLUSH_OPS]; /* Array of instances
* of struct flush_op detailing the
* flush operations (if any) that
* are to be executed when the entry
* is flushed from the cache.
*
* num_flush_ops contains the number
* of valid entries in this array.
*/
hbool_t flush_op_self_resize_in_progress; /* Boolean flag
* that is set to TRUE iff this
* entry is being flushed, it has
* been resized by a resize flush
* op, and the flush function has
* not yet returned, This field is
* used to turn off overactive santity
* checking code that would otherwise
* cause a false test failure.
*/
hbool_t loaded; /* entry has been loaded since the
* last time it was reset.
*/
hbool_t cleared; /* entry has been cleared since the
* last time it was reset.
*/
hbool_t flushed; /* entry has been flushed since the
* last time it was reset.
*/
hbool_t destroyed; /* entry has been destroyed since the
* last time it was reset.
*/
int flush_dep_par_type; /* Entry type of flush dependency parent */
int flush_dep_par_idx; /* Index of flush dependency parent */
uint64_t child_flush_dep_height_rc[H5C__NUM_FLUSH_DEP_HEIGHTS];
/* flush dependency heights of flush
* dependency children
*/
unsigned flush_dep_height; /* flush dependency height of entry */
hbool_t pinned_from_client; /* entry was pinned by client call */
hbool_t pinned_from_cache; /* entry was pinned by cache internally */
unsigned flush_order; /* Order that entry was flushed in */
unsigned notify_after_insert_count; /* Count of times that entry was inserted in cache */
unsigned notify_before_evict_count; /* Count of times that entry was removed in cache */
} test_entry_t;
/* The following is a cut down copy of the hash table manipulation
* macros from H5C.c, which have been further modified to avoid references
* to the error reporting macros. Needless to say, these macros must be
* updated as necessary.
*/
#define H5C__HASH_MASK ((size_t)(H5C__HASH_TABLE_LEN - 1) << 3)
#define H5C__HASH_FCN(x) (int)(((x) & H5C__HASH_MASK) >> 3)
#define H5C_TEST__PRE_HT_SEARCH_SC(cache_ptr, Addr) \
if ( ( (cache_ptr) == NULL ) || \
( (cache_ptr)->magic != H5C__H5C_T_MAGIC ) || \
( (cache_ptr)->index_size != \
((cache_ptr)->clean_index_size + (cache_ptr)->dirty_index_size) ) || \
( ! H5F_addr_defined(Addr) ) || \
( H5C__HASH_FCN(Addr) < 0 ) || \
( H5C__HASH_FCN(Addr) >= H5C__HASH_TABLE_LEN ) ) { \
HDfprintf(stdout, "Pre HT search SC failed.\n"); \
}
#define H5C_TEST__POST_SUC_HT_SEARCH_SC(cache_ptr, entry_ptr, Addr, k) \
if ( ( (cache_ptr) == NULL ) || \
( (cache_ptr)->magic != H5C__H5C_T_MAGIC ) || \
( (cache_ptr)->index_len < 1 ) || \
( (entry_ptr) == NULL ) || \
( (cache_ptr)->index_size < (entry_ptr)->size ) || \
( (cache_ptr)->index_size != \
((cache_ptr)->clean_index_size + (cache_ptr)->dirty_index_size) ) || \
( H5F_addr_ne((entry_ptr)->addr, (Addr)) ) || \
( (entry_ptr)->size <= 0 ) || \
( ((cache_ptr)->index)[k] == NULL ) || \
( ( ((cache_ptr)->index)[k] != (entry_ptr) ) && \
( (entry_ptr)->ht_prev == NULL ) ) || \
( ( ((cache_ptr)->index)[k] == (entry_ptr) ) && \
( (entry_ptr)->ht_prev != NULL ) ) || \
( ( (entry_ptr)->ht_prev != NULL ) && \
( (entry_ptr)->ht_prev->ht_next != (entry_ptr) ) ) || \
( ( (entry_ptr)->ht_next != NULL ) && \
( (entry_ptr)->ht_next->ht_prev != (entry_ptr) ) ) ) { \
HDfprintf(stdout, "Post successful HT search SC failed.\n"); \
}
#define H5C_TEST__POST_HT_SHIFT_TO_FRONT(cache_ptr, entry_ptr, k) \
if ( ( (cache_ptr) == NULL ) || \
( ((cache_ptr)->index)[k] != (entry_ptr) ) || \
( (entry_ptr)->ht_prev != NULL ) ) { \
HDfprintf(stdout, "Post HT shift to front failed.\n"); \
}
#define H5C_TEST__SEARCH_INDEX(cache_ptr, Addr, entry_ptr) \
{ \
int k; \
int depth = 0; \
H5C_TEST__PRE_HT_SEARCH_SC(cache_ptr, Addr) \
k = H5C__HASH_FCN(Addr); \
entry_ptr = ((cache_ptr)->index)[k]; \
while ( ( entry_ptr ) && ( H5F_addr_ne(Addr, (entry_ptr)->addr) ) ) \
{ \
(entry_ptr) = (entry_ptr)->ht_next; \
(depth)++; \
} \
if ( entry_ptr ) \
{ \
H5C_TEST__POST_SUC_HT_SEARCH_SC(cache_ptr, entry_ptr, Addr, k) \
if ( entry_ptr != ((cache_ptr)->index)[k] ) \
{ \
if ( (entry_ptr)->ht_next ) \
{ \
(entry_ptr)->ht_next->ht_prev = (entry_ptr)->ht_prev; \
} \
HDassert( (entry_ptr)->ht_prev != NULL ); \
(entry_ptr)->ht_prev->ht_next = (entry_ptr)->ht_next; \
((cache_ptr)->index)[k]->ht_prev = (entry_ptr); \
(entry_ptr)->ht_next = ((cache_ptr)->index)[k]; \
(entry_ptr)->ht_prev = NULL; \
((cache_ptr)->index)[k] = (entry_ptr); \
H5C_TEST__POST_HT_SHIFT_TO_FRONT(cache_ptr, entry_ptr, k) \
} \
} \
}
/* misc type definitions */
struct flush_cache_test_spec
{
int entry_num;
int entry_type;
int entry_index;
hbool_t insert_flag;
hbool_t dirty_flag;
unsigned int flags;
hbool_t expected_loaded;
hbool_t expected_cleared;
hbool_t expected_flushed;
hbool_t expected_destroyed;
};
struct pe_flush_cache_test_spec
{
int entry_num;
int entry_type;
int entry_index;
hbool_t insert_flag;
hbool_t dirty_flag;
unsigned int flags;
int num_pins;
int pin_type[MAX_PINS];
int pin_idx[MAX_PINS];
hbool_t expected_loaded;
hbool_t expected_cleared;
hbool_t expected_flushed;
hbool_t expected_destroyed;
};
struct fo_flush_entry_check
{
int entry_num;
int entry_type;
int entry_index;
size_t expected_size;
hbool_t in_cache;
hbool_t at_main_addr;
hbool_t is_dirty;
hbool_t is_protected;
hbool_t is_pinned;
hbool_t expected_loaded;
hbool_t expected_cleared;
hbool_t expected_flushed;
hbool_t expected_destroyed;
};
struct fo_flush_cache_test_spec
{
int entry_num;
int entry_type;
int entry_index;
hbool_t insert_flag;
unsigned int flags;
size_t new_size;
int num_pins;
int pin_type[MAX_PINS];
int pin_idx[MAX_PINS];
int num_flush_ops;
struct flush_op flush_ops[MAX_FLUSH_OPS];
hbool_t expected_loaded;
hbool_t expected_cleared;
hbool_t expected_flushed;
hbool_t expected_destroyed;
};
struct rename_entry_test_spec
{
int entry_type;
int entry_index;
hbool_t is_dirty;
hbool_t is_pinned;
};
struct expected_entry_status
{
int entry_type;
int entry_index;
size_t size;
unsigned char in_cache;
unsigned char at_main_addr;
unsigned char is_dirty;
unsigned char is_protected;
unsigned char is_pinned;
unsigned char loaded;
unsigned char cleared;
unsigned char flushed;
unsigned char destroyed;
int flush_dep_par_type; /* Entry type of flush dependency parent */
int flush_dep_par_idx; /* Index of flush dependency parent */
uint64_t child_flush_dep_height_rc[H5C__NUM_FLUSH_DEP_HEIGHTS];
/* flush dependency heights of flush
* dependency children
*/
unsigned flush_dep_height; /* flush dependency height of entry */
int flush_order; /* flush order of entry */
};
/* global variable externs: */
extern const char *FILENAME[];
extern hbool_t write_permitted;
extern hbool_t pass; /* set to false on error */
extern hbool_t skip_long_tests;
extern hbool_t run_full_test;
extern const char *failure_mssg;
extern test_entry_t pico_entries[NUM_PICO_ENTRIES];
extern test_entry_t nano_entries[NUM_NANO_ENTRIES];
extern test_entry_t micro_entries[NUM_MICRO_ENTRIES];
extern test_entry_t tiny_entries[NUM_TINY_ENTRIES];
extern test_entry_t small_entries[NUM_SMALL_ENTRIES];
extern test_entry_t medium_entries[NUM_MEDIUM_ENTRIES];
extern test_entry_t large_entries[NUM_LARGE_ENTRIES];
extern test_entry_t huge_entries[NUM_HUGE_ENTRIES];
extern test_entry_t monster_entries[NUM_MONSTER_ENTRIES];
extern test_entry_t * entries[NUMBER_OF_ENTRY_TYPES];
extern const int32_t max_indices[NUMBER_OF_ENTRY_TYPES];
extern const size_t entry_sizes[NUMBER_OF_ENTRY_TYPES];
extern const haddr_t base_addrs[NUMBER_OF_ENTRY_TYPES];
extern const haddr_t alt_base_addrs[NUMBER_OF_ENTRY_TYPES];
extern const char * entry_type_names[NUMBER_OF_ENTRY_TYPES];
/* call back function declarations: */
herr_t check_write_permitted(const H5F_t * f,
hid_t dxpl_id,
hbool_t * write_permitted_ptr);
herr_t pico_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t nano_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t micro_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t tiny_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t small_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t medium_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t large_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t huge_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t monster_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t variable_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t notify_clear(H5F_t * f, void * thing, hbool_t dest);
herr_t pico_dest(H5F_t * f, void * thing);
herr_t nano_dest(H5F_t * f, void * thing);
herr_t micro_dest(H5F_t * f, void * thing);
herr_t tiny_dest(H5F_t * f, void * thing);
herr_t small_dest(H5F_t * f, void * thing);
herr_t medium_dest(H5F_t * f, void * thing);
herr_t large_dest(H5F_t * f, void * thing);
herr_t huge_dest(H5F_t * f, void * thing);
herr_t monster_dest(H5F_t * f, void * thing);
herr_t variable_dest(H5F_t * f, void * thing);
herr_t notify_dest(H5F_t * f, void * thing);
herr_t pico_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t nano_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t micro_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t tiny_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t small_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t medium_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t large_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t huge_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t monster_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t variable_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
herr_t notify_flush(H5F_t *f, hid_t dxpl_id, hbool_t dest,
haddr_t addr, void *thing, unsigned * flags_ptr);
void * pico_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * nano_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * micro_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * tiny_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * small_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * medium_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * large_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * huge_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * monster_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * variable_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
void * notify_load(H5F_t *f, hid_t dxpl_id, haddr_t addr,
const void *udata1, void *udata2);
herr_t pico_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t nano_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t micro_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t tiny_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t small_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t medium_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t large_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t huge_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t monster_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t variable_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t notify_size(H5F_t * f, void * thing, size_t * size_ptr);
herr_t notify_notify(H5C_notify_action_t action, void *thing);
/* callback table extern */
extern const H5C_class_t types[NUMBER_OF_ENTRY_TYPES];
/* function declarations: */
void add_flush_op(int target_type,
int target_idx,
int op_code,
int type,
int idx,
hbool_t flag,
size_t size,
unsigned * order);
void addr_to_type_and_index(haddr_t addr,
int32_t * type_ptr,
int32_t * index_ptr);
#if 0 /* keep this for a while -- it may be useful */
haddr_t type_and_index_to_addr(int32_t type,
int32_t idx);
#endif
void dirty_entry(H5F_t * file_ptr,
int32_t type,
int32_t idx,
hbool_t dirty_pin);
void expunge_entry(H5F_t * file_ptr,
int32_t type,
int32_t idx);
void insert_entry(H5F_t * file_ptr,
int32_t type,
int32_t idx,
hbool_t dirty,
unsigned int flags);
void mark_pinned_entry_dirty(int32_t type,
int32_t idx,
hbool_t size_changed,
size_t new_size);
void mark_pinned_or_protected_entry_dirty(int32_t type,
int32_t idx);
void rename_entry(H5C_t * cache_ptr,
int32_t type,
int32_t idx,
hbool_t main_addr);
void protect_entry(H5F_t * file_ptr,
int32_t type,
int32_t idx);
void protect_entry_ro(H5F_t * file_ptr,
int32_t type,
int32_t idx);
void pin_entry(int32_t type,
int32_t idx);
hbool_t entry_in_cache(H5C_t * cache_ptr,
int32_t type,
int32_t idx);
void create_pinned_entry_dependency(H5F_t * file_ptr,
int pinning_type,
int pinning_idx,
int pinned_type,
int pinned_idx);
void reset_entries(void);
void resize_entry(H5F_t * file_ptr,
int32_t type,
int32_t idx,
size_t new_size,
hbool_t resize_pin);
void resize_pinned_entry(H5C_t * cache_ptr,
int32_t type,
int32_t idx,
size_t new_size);
H5F_t *setup_cache(size_t max_cache_size, size_t min_clean_size);
void row_major_scan_forward(H5F_t * file_ptr,
int32_t lag,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts,
hbool_t do_renames,
hbool_t rename_to_main_addr,
hbool_t do_destroys,
hbool_t do_mult_ro_protects,
int dirty_destroys,
int dirty_unprotects);
void hl_row_major_scan_forward(H5F_t * file_ptr,
int32_t max_index,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts);
void row_major_scan_backward(H5F_t * file_ptr,
int32_t lag,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts,
hbool_t do_renames,
hbool_t rename_to_main_addr,
hbool_t do_destroys,
hbool_t do_mult_ro_protects,
int dirty_destroys,
int dirty_unprotects);
void hl_row_major_scan_backward(H5F_t * file_ptr,
int32_t max_index,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts);
void col_major_scan_forward(H5F_t * file_ptr,
int32_t lag,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts,
int dirty_unprotects);
void hl_col_major_scan_forward(H5F_t * file_ptr,
int32_t max_index,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts,
int dirty_unprotects);
void col_major_scan_backward(H5F_t * file_ptr,
int32_t lag,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts,
int dirty_unprotects);
void hl_col_major_scan_backward(H5F_t * file_ptr,
int32_t max_index,
hbool_t verbose,
hbool_t reset_stats,
hbool_t display_stats,
hbool_t display_detailed_stats,
hbool_t do_inserts,
hbool_t dirty_inserts,
int dirty_unprotects);
void takedown_cache(H5F_t * file_ptr,
hbool_t dump_stats,
hbool_t dump_detailed_stats);
void flush_cache(H5F_t * file_ptr,
hbool_t destroy_entries,
hbool_t dump_stats,
hbool_t dump_detailed_stats);
void unpin_entry(int32_t type,
int32_t idx);
void unprotect_entry(H5F_t * file_ptr,
int32_t type,
int32_t idx,
int dirty,
unsigned int flags);
void unprotect_entry_with_size_change(H5F_t * file_ptr,
int32_t type,
int32_t idx,
unsigned int flags,
size_t new_size);
void verify_clean(void);
void verify_entry_status(H5C_t * cache_ptr,
int tag,
int num_entries,
struct expected_entry_status expected[]);
void verify_unprotected(void);
void create_flush_dependency(int32_t parent_type,
int32_t parent_idx,
int32_t child_type,
int32_t child_idx);
void destroy_flush_dependency(int32_t parent_type,
int32_t parent_idx,
int32_t child_type,
int32_t child_idx);
#endif /* _CACHE_COMMON_H */