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|
/* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* Copyright by The HDF Group. *
* 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 COPYING file, which can be found at the root of the source code *
* distribution tree, or in https://www.hdfgroup.org/licenses. *
* If you do not have access to either file, you may request a copy from *
* help@hdfgroup.org. *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
/*-------------------------------------------------------------------------
*
* Created: H5HFcache.c
*
* Purpose: Implement fractal heap metadata cache methods
*
*-------------------------------------------------------------------------
*/
/****************/
/* Module Setup */
/****************/
#include "H5HFmodule.h" /* This source code file is part of the H5HF module */
/***********/
/* Headers */
/***********/
#include "H5private.h" /* Generic Functions */
#include "H5ACprivate.h" /* Metadata cache */
#include "H5Eprivate.h" /* Error handling */
#include "H5HFpkg.h" /* Fractal heaps */
#include "H5MFprivate.h" /* File memory management */
#include "H5MMprivate.h" /* Memory management */
#include "H5VMprivate.h" /* Vectors and arrays */
#include "H5WBprivate.h" /* Wrapped Buffers */
/****************/
/* Local Macros */
/****************/
/* Fractal heap format version #'s */
#define H5HF_HDR_VERSION 0 /* Header */
#define H5HF_DBLOCK_VERSION 0 /* Direct block */
#define H5HF_IBLOCK_VERSION 0 /* Indirect block */
/******************/
/* Local Typedefs */
/******************/
/********************/
/* Package Typedefs */
/********************/
/********************/
/* Local Prototypes */
/********************/
/* Local encode/decode routines */
static herr_t H5HF__hdr_prefix_decode(H5HF_hdr_t *hdr, const uint8_t **image_ref);
static herr_t H5HF__dtable_encode(H5F_t *f, uint8_t **pp, const H5HF_dtable_t *dtable);
static herr_t H5HF__dtable_decode(H5F_t *f, const uint8_t **pp, H5HF_dtable_t *dtable);
/* Metadata cache (H5AC) callbacks */
static herr_t H5HF__cache_hdr_get_initial_load_size(void *udata, size_t *image_len);
static herr_t H5HF__cache_hdr_get_final_load_size(const void *image_ptr, size_t image_len, void *udata,
size_t *actual_len);
static htri_t H5HF__cache_hdr_verify_chksum(const void *image_ptr, size_t len, void *udata_ptr);
static void *H5HF__cache_hdr_deserialize(const void *image, size_t len, void *udata, bool *dirty);
static herr_t H5HF__cache_hdr_image_len(const void *thing, size_t *image_len);
static herr_t H5HF__cache_hdr_pre_serialize(H5F_t *f, void *thing, haddr_t addr, size_t len,
haddr_t *new_addr, size_t *new_len, unsigned *flags);
static herr_t H5HF__cache_hdr_serialize(const H5F_t *f, void *image, size_t len, void *thing);
static herr_t H5HF__cache_hdr_free_icr(void *thing);
static herr_t H5HF__cache_iblock_get_initial_load_size(void *udata, size_t *image_len);
static htri_t H5HF__cache_iblock_verify_chksum(const void *image_ptr, size_t len, void *udata_ptr);
static void *H5HF__cache_iblock_deserialize(const void *image, size_t len, void *udata, bool *dirty);
static herr_t H5HF__cache_iblock_image_len(const void *thing, size_t *image_len);
static herr_t H5HF__cache_iblock_pre_serialize(H5F_t *f, void *thing, haddr_t addr, size_t len,
haddr_t *new_addr, size_t *new_len, unsigned *flags);
static herr_t H5HF__cache_iblock_serialize(const H5F_t *f, void *image, size_t len, void *thing);
static herr_t H5HF__cache_iblock_notify(H5AC_notify_action_t action, void *thing);
static herr_t H5HF__cache_iblock_free_icr(void *thing);
static herr_t H5HF__cache_dblock_get_initial_load_size(void *udata, size_t *image_len);
static htri_t H5HF__cache_dblock_verify_chksum(const void *image_ptr, size_t len, void *udata_ptr);
static void *H5HF__cache_dblock_deserialize(const void *image, size_t len, void *udata, bool *dirty);
static herr_t H5HF__cache_dblock_image_len(const void *thing, size_t *image_len);
static herr_t H5HF__cache_dblock_pre_serialize(H5F_t *f, void *thing, haddr_t addr, size_t len,
haddr_t *new_addr, size_t *new_len, unsigned *flags);
static herr_t H5HF__cache_dblock_serialize(const H5F_t *f, void *image, size_t len, void *thing);
static herr_t H5HF__cache_dblock_notify(H5AC_notify_action_t action, void *thing);
static herr_t H5HF__cache_dblock_free_icr(void *thing);
static herr_t H5HF__cache_dblock_fsf_size(const void *_thing, hsize_t *fsf_size);
/* Debugging Function Prototypes */
#ifndef NDEBUG
static herr_t H5HF__cache_verify_hdr_descendants_clean(H5F_t *f, H5HF_hdr_t *hdr, bool *fd_clean,
bool *clean);
static herr_t H5HF__cache_verify_iblock_descendants_clean(H5F_t *f, haddr_t fd_parent_addr,
H5HF_indirect_t *iblock, unsigned *iblock_status,
bool *fd_clean, bool *clean);
static herr_t H5HF__cache_verify_iblocks_dblocks_clean(H5F_t *f, haddr_t fd_parent_addr,
H5HF_indirect_t *iblock, bool *fd_clean, bool *clean,
bool *has_dblocks);
static herr_t H5HF__cache_verify_descendant_iblocks_clean(H5F_t *f, haddr_t fd_parent_addr,
H5HF_indirect_t *iblock, bool *fd_clean,
bool *clean, bool *has_iblocks);
#endif /* NDEBUG */
/*********************/
/* Package Variables */
/*********************/
/* H5HF header inherits cache-like properties from H5AC */
const H5AC_class_t H5AC_FHEAP_HDR[1] = {{
H5AC_FHEAP_HDR_ID, /* Metadata client ID */
"fractal heap header", /* Metadata client name (for debugging) */
H5FD_MEM_FHEAP_HDR, /* File space memory type for client */
H5AC__CLASS_SPECULATIVE_LOAD_FLAG, /* Client class behavior flags */
H5HF__cache_hdr_get_initial_load_size, /* 'get_initial_load_size' callback */
H5HF__cache_hdr_get_final_load_size, /* 'get_final_load_size' callback */
H5HF__cache_hdr_verify_chksum, /* 'verify_chksum' callback */
H5HF__cache_hdr_deserialize, /* 'deserialize' callback */
H5HF__cache_hdr_image_len, /* 'image_len' callback */
H5HF__cache_hdr_pre_serialize, /* 'pre_serialize' callback */
H5HF__cache_hdr_serialize, /* 'serialize' callback */
NULL, /* 'notify' callback */
H5HF__cache_hdr_free_icr, /* 'free_icr' callback */
NULL, /* 'fsf_size' callback */
}};
/* H5HF indirect block inherits cache-like properties from H5AC */
const H5AC_class_t H5AC_FHEAP_IBLOCK[1] = {{
H5AC_FHEAP_IBLOCK_ID, /* Metadata client ID */
"fractal heap indirect block", /* Metadata client name (for debugging) */
H5FD_MEM_FHEAP_IBLOCK, /* File space memory type for client */
H5AC__CLASS_NO_FLAGS_SET, /* Client class behavior flags */
H5HF__cache_iblock_get_initial_load_size, /* 'get_initial_load_size' callback */
NULL, /* 'get_final_load_size' callback */
H5HF__cache_iblock_verify_chksum, /* 'verify_chksum' callback */
H5HF__cache_iblock_deserialize, /* 'deserialize' callback */
H5HF__cache_iblock_image_len, /* 'image_len' callback */
H5HF__cache_iblock_pre_serialize, /* 'pre_serialize' callback */
H5HF__cache_iblock_serialize, /* 'serialize' callback */
H5HF__cache_iblock_notify, /* 'notify' callback */
H5HF__cache_iblock_free_icr, /* 'free_icr' callback */
NULL, /* 'fsf_size' callback */
}};
/* H5HF direct block inherits cache-like properties from H5AC */
const H5AC_class_t H5AC_FHEAP_DBLOCK[1] = {{
H5AC_FHEAP_DBLOCK_ID, /* Metadata client ID */
"fractal heap direct block", /* Metadata client name (for debugging) */
H5FD_MEM_FHEAP_DBLOCK, /* File space memory type for client */
H5AC__CLASS_NO_FLAGS_SET, /* Client class behavior flags */
H5HF__cache_dblock_get_initial_load_size, /* 'get_initial_load_size' callback */
NULL, /* 'get_final_load_size' callback */
H5HF__cache_dblock_verify_chksum, /* 'verify_chksum' callback */
H5HF__cache_dblock_deserialize, /* 'deserialize' callback */
H5HF__cache_dblock_image_len, /* 'image_len' callback */
H5HF__cache_dblock_pre_serialize, /* 'pre_serialize' callback */
H5HF__cache_dblock_serialize, /* 'serialize' callback */
H5HF__cache_dblock_notify, /* 'notify' callback */
H5HF__cache_dblock_free_icr, /* 'free_icr' callback */
H5HF__cache_dblock_fsf_size, /* 'fsf_size' callback */
}};
/*****************************/
/* Library Private Variables */
/*****************************/
/*******************/
/* Local Variables */
/*******************/
/* Declare a free list to manage heap direct block data to/from disk */
H5FL_BLK_DEFINE(direct_block);
/*-------------------------------------------------------------------------
* Function: H5HF__hdr_prefix_decode()
*
* Purpose: Decode a fractal heap header's prefix
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__hdr_prefix_decode(H5HF_hdr_t *hdr, const uint8_t **image_ref)
{
const uint8_t *image = *image_ref; /* Pointer into into supplied image */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(hdr);
assert(image);
/* Magic number */
if (memcmp(image, H5HF_HDR_MAGIC, (size_t)H5_SIZEOF_MAGIC) != 0)
HGOTO_ERROR(H5E_HEAP, H5E_BADVALUE, FAIL, "wrong fractal heap header signature");
image += H5_SIZEOF_MAGIC;
/* Version */
if (*image++ != H5HF_HDR_VERSION)
HGOTO_ERROR(H5E_HEAP, H5E_VERSION, FAIL, "wrong fractal heap header version");
/* General heap information */
UINT16DECODE(image, hdr->id_len); /* Heap ID length */
UINT16DECODE(image, hdr->filter_len); /* I/O filters' encoded length */
/* Update the image buffer pointer */
*image_ref = image;
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__hdr_prefix_decode() */
/*-------------------------------------------------------------------------
* Function: H5HF__dtable_decode
*
* Purpose: Decodes the metadata for a doubling table
*
* Return: Success: Pointer to a new fractal heap
*
* Failure: NULL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__dtable_decode(H5F_t *f, const uint8_t **pp, H5HF_dtable_t *dtable)
{
FUNC_ENTER_PACKAGE_NOERR
/* Check arguments */
assert(f);
assert(pp && *pp);
assert(dtable);
/* Table width */
UINT16DECODE(*pp, dtable->cparam.width);
/* Starting block size */
H5F_DECODE_LENGTH(f, *pp, dtable->cparam.start_block_size);
/* Maximum direct block size */
H5F_DECODE_LENGTH(f, *pp, dtable->cparam.max_direct_size);
/* Maximum heap size (as # of bits) */
UINT16DECODE(*pp, dtable->cparam.max_index);
/* Starting # of rows in root indirect block */
UINT16DECODE(*pp, dtable->cparam.start_root_rows);
/* Address of table */
H5F_addr_decode(f, pp, &(dtable->table_addr));
/* Current # of rows in root indirect block */
UINT16DECODE(*pp, dtable->curr_root_rows);
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__dtable_decode() */
/*-------------------------------------------------------------------------
* Function: H5HF__dtable_encode
*
* Purpose: Encodes the metadata for a doubling table
*
* Return: Success: Pointer to a new fractal heap
*
* Failure: NULL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__dtable_encode(H5F_t *f, uint8_t **pp, const H5HF_dtable_t *dtable)
{
FUNC_ENTER_PACKAGE_NOERR
/* Check arguments */
assert(f);
assert(pp && *pp);
assert(dtable);
/* Table width */
UINT16ENCODE(*pp, dtable->cparam.width);
/* Starting block size */
H5F_ENCODE_LENGTH(f, *pp, dtable->cparam.start_block_size);
/* Maximum direct block size */
H5F_ENCODE_LENGTH(f, *pp, dtable->cparam.max_direct_size);
/* Maximum heap size (as # of bits) */
UINT16ENCODE(*pp, dtable->cparam.max_index);
/* Starting # of rows in root indirect block */
UINT16ENCODE(*pp, dtable->cparam.start_root_rows);
/* Address of root direct/indirect block */
H5F_addr_encode(f, pp, dtable->table_addr);
/* Current # of rows in root indirect block */
UINT16ENCODE(*pp, dtable->curr_root_rows);
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__dtable_encode() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_get_initial_load_size()
*
* Purpose: Determine the size of the fractal heap header on disk,
* and set *image_len to this value.
*
* Note also that the value returned by this function presumes that
* there is no I/O filtering data in the header. If there is, the
* size reported will be too small, and H5C__load_entry()
* will have to make two tries to load the fractal heap header.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_hdr_get_initial_load_size(void *_udata, size_t *image_len)
{
H5HF_hdr_cache_ud_t *udata = (H5HF_hdr_cache_ud_t *)_udata; /* Pointer to user data */
H5HF_hdr_t dummy_hdr; /* Dummy header -- to compute size */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(udata);
assert(image_len);
/* Set the internal parameters for the heap */
dummy_hdr.f = udata->f;
dummy_hdr.sizeof_size = H5F_SIZEOF_SIZE(udata->f);
dummy_hdr.sizeof_addr = H5F_SIZEOF_ADDR(udata->f);
/* Compute the 'base' size of the fractal heap header on disk */
*image_len = (size_t)H5HF_HEADER_SIZE(&dummy_hdr);
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_hdr_get_initial_load_size() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_get_final_load_size()
*
* Purpose: Determine the final size of the fractal heap header on disk,
* and set *actual_len to this value.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_hdr_get_final_load_size(const void *_image, size_t H5_ATTR_NDEBUG_UNUSED image_len, void *_udata,
size_t *actual_len)
{
H5HF_hdr_t hdr; /* Temporary fractal heap header */
const uint8_t *image = (const uint8_t *)_image; /* Pointer into into supplied image */
H5HF_hdr_cache_ud_t *udata = (H5HF_hdr_cache_ud_t *)_udata; /* User data for callback */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(image);
assert(udata);
assert(actual_len);
assert(*actual_len == image_len);
/* Deserialize the fractal heap header's prefix */
if (H5HF__hdr_prefix_decode(&hdr, &image) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDECODE, FAIL, "can't decode fractal heap header prefix");
/* Check for I/O filter info on this heap */
if (hdr.filter_len > 0)
/* Compute the extra heap header size */
*actual_len += (size_t)(H5F_SIZEOF_SIZE(udata->f) /* Size of size for filtered root direct block */
+ (unsigned)4 /* Size of filter mask for filtered root direct block */
+ hdr.filter_len); /* Size of encoded I/O filter info */
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_hdr_get_final_load_size() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_verify_chksum
*
* Purpose: Verify the computed checksum of the data structure is the
* same as the stored chksum.
*
* Return: Success: true/false
* Failure: Negative
*
*-------------------------------------------------------------------------
*/
static htri_t
H5HF__cache_hdr_verify_chksum(const void *_image, size_t len, void H5_ATTR_UNUSED *_udata)
{
const uint8_t *image = (const uint8_t *)_image; /* Pointer into raw data buffer */
uint32_t stored_chksum; /* Stored metadata checksum value */
uint32_t computed_chksum; /* Computed metadata checksum value */
htri_t ret_value = true; /* Return value */
FUNC_ENTER_PACKAGE_NOERR
/* Check arguments */
assert(image);
/* Get stored and computed checksums */
H5F_get_checksums(image, len, &stored_chksum, &computed_chksum);
if (stored_chksum != computed_chksum)
ret_value = false;
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_hdr_verify_chksum() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_deserialize
*
* Purpose: Given a buffer containing an on disk image of a fractal heap
* header block, allocate an instance of H5HF_hdr_t, load the contents
* of the buffer into into the new instance of H5HF_hdr_t, and then
* return a pointer to the new instance.
*
* Return: Success: Pointer to in core representation
* Failure: NULL
*
*-------------------------------------------------------------------------
*/
static void *
H5HF__cache_hdr_deserialize(const void *_image, size_t len, void *_udata, bool H5_ATTR_UNUSED *dirty)
{
H5HF_hdr_t *hdr = NULL; /* Fractal heap info */
H5HF_hdr_cache_ud_t *udata = (H5HF_hdr_cache_ud_t *)_udata; /* User data for callback */
const uint8_t *image = (const uint8_t *)_image; /* Pointer into into supplied image */
uint32_t stored_chksum; /* Stored metadata checksum value */
uint8_t heap_flags; /* Status flags for heap */
void *ret_value = NULL; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(image);
assert(len > 0);
assert(udata);
assert(dirty);
/* Allocate space for the fractal heap data structure */
if (NULL == (hdr = H5HF__hdr_alloc(udata->f)))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "memory allocation failed");
/* Deserialize the fractal heap header's prefix */
if (H5HF__hdr_prefix_decode(hdr, &image) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDECODE, NULL, "can't decode fractal heap header prefix");
/* Heap status flags */
/* (bit 0: "huge" object IDs have wrapped) */
/* (bit 1: checksum direct blocks) */
heap_flags = *image++;
hdr->huge_ids_wrapped = heap_flags & H5HF_HDR_FLAGS_HUGE_ID_WRAPPED;
hdr->checksum_dblocks = heap_flags & H5HF_HDR_FLAGS_CHECKSUM_DBLOCKS;
/* "Huge" object information */
UINT32DECODE(image, hdr->max_man_size); /* Max. size of "managed" objects */
H5F_DECODE_LENGTH(udata->f, image, hdr->huge_next_id); /* Next ID to use for "huge" object */
H5F_addr_decode(udata->f, &image, &hdr->huge_bt2_addr); /* Address of "huge" object tracker B-tree */
/* "Managed" object free space information */
H5F_DECODE_LENGTH(udata->f, image,
hdr->total_man_free); /* Internal free space in managed direct blocks */
H5F_addr_decode(udata->f, &image, &hdr->fs_addr); /* Address of free section header */
/* Heap statistics */
H5F_DECODE_LENGTH(udata->f, image, hdr->man_size);
H5F_DECODE_LENGTH(udata->f, image, hdr->man_alloc_size);
H5F_DECODE_LENGTH(udata->f, image, hdr->man_iter_off);
H5F_DECODE_LENGTH(udata->f, image, hdr->man_nobjs);
H5F_DECODE_LENGTH(udata->f, image, hdr->huge_size);
H5F_DECODE_LENGTH(udata->f, image, hdr->huge_nobjs);
H5F_DECODE_LENGTH(udata->f, image, hdr->tiny_size);
H5F_DECODE_LENGTH(udata->f, image, hdr->tiny_nobjs);
/* Managed objects' doubling-table info */
if (H5HF__dtable_decode(hdr->f, &image, &(hdr->man_dtable)) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTENCODE, NULL, "unable to encode managed obj. doubling table info");
/* Set the fractal heap header's 'base' size */
hdr->heap_size = (size_t)H5HF_HEADER_SIZE(hdr);
/* Sanity check */
/* (allow for checksum not decoded yet) */
assert((size_t)(image - (const uint8_t *)_image) == (hdr->heap_size - H5HF_SIZEOF_CHKSUM));
/* Check for I/O filter information to decode */
if (hdr->filter_len > 0) {
H5O_pline_t *pline; /* Pipeline information from the header on disk */
/* Sanity check */
assert(len > hdr->heap_size); /* A header with filter info is > than a standard header */
/* Compute the heap header's size */
hdr->heap_size += (size_t)(hdr->sizeof_size /* Size of size for filtered root direct block */
+ (unsigned)4 /* Size of filter mask for filtered root direct block */
+ hdr->filter_len); /* Size of encoded I/O filter info */
/* Decode the size of a filtered root direct block */
H5F_DECODE_LENGTH(udata->f, image, hdr->pline_root_direct_size);
/* Decode the filter mask for a filtered root direct block */
UINT32DECODE(image, hdr->pline_root_direct_filter_mask);
/* Decode I/O filter information */
if (NULL == (pline = (H5O_pline_t *)H5O_msg_decode(hdr->f, NULL, H5O_PLINE_ID, len, image)))
HGOTO_ERROR(H5E_HEAP, H5E_CANTDECODE, NULL, "can't decode I/O pipeline filters");
/* Advance past filter info to checksum */
image += hdr->filter_len;
/* Copy the information into the header's I/O pipeline structure */
if (NULL == H5O_msg_copy(H5O_PLINE_ID, pline, &(hdr->pline)))
HGOTO_ERROR(H5E_HEAP, H5E_CANTCOPY, NULL, "can't copy I/O filter pipeline");
/* Release the space allocated for the I/O pipeline filters */
H5O_msg_free(H5O_PLINE_ID, pline);
} /* end if */
/* Metadata checksum */
UINT32DECODE(image, stored_chksum);
/* Sanity check */
assert((size_t)(image - (const uint8_t *)_image) == hdr->heap_size);
/* Finish initialization of heap header */
if (H5HF__hdr_finish_init(hdr) < 0)
HGOTO_ERROR(H5E_RESOURCE, H5E_CANTINIT, NULL, "can't finish initializing shared fractal heap header");
/* Set return value */
ret_value = (void *)hdr;
done:
if (!ret_value && hdr)
if (H5HF__hdr_free(hdr) < 0)
HDONE_ERROR(H5E_HEAP, H5E_CANTRELEASE, NULL, "unable to release fractal heap header");
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_hdr_deserialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_image_len
*
* Purpose: Return the actual size of the fractal heap header on
* disk image.
*
* If the header contains filter information, this size will be
* larger than the value returned by H5HF__cache_hdr_get_initial_load_size().
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_hdr_image_len(const void *_thing, size_t *image_len)
{
const H5HF_hdr_t *hdr = (const H5HF_hdr_t *)_thing; /* Fractal heap info */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
assert(image_len);
*image_len = hdr->heap_size;
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_hdr_image_len() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_pre_serialize
*
* Purpose: As best I can tell, fractal heap header blocks are always
* allocated in real file space. Thus this routine simply verifies
* this, verifies that the len parameter contains the expected
* value, and returns an error if either of these checks fail.
*
* When compiled in debug mode, the function also verifies that all
* indirect and direct blocks that are children of the header are
* either clean, or not in the metadata cache.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_hdr_pre_serialize(H5F_t *f, void *_thing, haddr_t addr, size_t len,
haddr_t H5_ATTR_UNUSED *new_addr, size_t H5_ATTR_UNUSED *new_len,
unsigned *flags)
{
H5HF_hdr_t *hdr = (H5HF_hdr_t *)_thing; /* Fractal heap info */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
assert(H5_addr_defined(addr));
assert(addr == hdr->heap_addr);
assert(new_addr);
assert(new_len);
assert(flags);
#ifndef NDEBUG
{
bool descendants_clean = true;
bool fd_children_clean = true;
/* Verify that flush dependencies are working correctly. Do this
* by verifying that either:
*
* 1) the header has a root iblock, and that the root iblock and all
* of its children are clean, or
*
* 2) The header has a root dblock, which is clean, or
*
* 3) The heap is empty, and thus the header has neither a root
* iblock no a root dblock. In this case, the flush ordering
* constraint is met by default.
*
* Do this with a call to H5HF__cache_verify_hdr_descendants_clean().
*
* Note that descendants need not be clean if the pre_serialize call
* is made during a cache serialization instead of an entry or cache
* flush.
*
* Note also that with the recent change in the definition of flush
* dependency, not all descendants need be clean -- only direct flush
* dependency children.
*
* Finally, observe that the H5HF__cache_verify_hdr_descendants_clean()
* call still looks for dirty descendants. At present we do not check
* this value.
*/
if (H5HF__cache_verify_hdr_descendants_clean((H5F_t *)f, hdr, &fd_children_clean,
&descendants_clean) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "can't verify hdr descendants clean.");
assert(fd_children_clean);
}
#endif /* NDEBUG */
if (H5F_IS_TMP_ADDR(f, addr))
HGOTO_ERROR(H5E_HEAP, H5E_BADVALUE, FAIL, "addr in temporary space?!?.");
if (len != hdr->heap_size)
HGOTO_ERROR(H5E_HEAP, H5E_BADVALUE, FAIL, "unexpected image len.");
*flags = 0;
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_hdr_pre_serialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_serialize
*
* Purpose: Construct the on disk image of the header, and place it in
* the buffer pointed to by image. Return SUCCEED on success,
* and FAIL on failure.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_hdr_serialize(const H5F_t *f, void *_image, size_t H5_ATTR_NDEBUG_UNUSED len, void *_thing)
{
H5HF_hdr_t *hdr = (H5HF_hdr_t *)_thing; /* Fractal heap info */
uint8_t *image = (uint8_t *)_image; /* Pointer into raw data buffer */
uint8_t heap_flags; /* Status flags for heap */
uint32_t metadata_chksum; /* Computed metadata checksum value */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(image);
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
assert(len == hdr->heap_size);
/* Set the shared heap header's file context for this operation */
H5_GCC_DIAG_OFF("discarded-qualifiers")
H5_CLANG_DIAG_OFF("incompatible-pointer-types-discards-qualifiers")
hdr->f = f;
H5_GCC_DIAG_ON("discarded-qualifiers")
H5_CLANG_DIAG_ON("incompatible-pointer-types-discards-qualifiers")
/* Magic number */
H5MM_memcpy(image, H5HF_HDR_MAGIC, (size_t)H5_SIZEOF_MAGIC);
image += H5_SIZEOF_MAGIC;
/* Version # */
*image++ = H5HF_HDR_VERSION;
/* General heap information */
UINT16ENCODE(image, hdr->id_len); /* Heap ID length */
UINT16ENCODE(image, hdr->filter_len); /* I/O filters' encoded length */
/* Heap status flags */
/* (bit 0: "huge" object IDs have wrapped) */
/* (bit 1: checksum direct blocks) */
heap_flags = 0;
heap_flags = (uint8_t)(heap_flags | (hdr->huge_ids_wrapped ? H5HF_HDR_FLAGS_HUGE_ID_WRAPPED : 0));
heap_flags = (uint8_t)(heap_flags | (hdr->checksum_dblocks ? H5HF_HDR_FLAGS_CHECKSUM_DBLOCKS : 0));
*image++ = heap_flags;
/* "Huge" object information */
UINT32ENCODE(image, hdr->max_man_size); /* Max. size of "managed" objects */
H5F_ENCODE_LENGTH(f, image, hdr->huge_next_id); /* Next ID to use for "huge" object */
H5F_addr_encode(f, &image, hdr->huge_bt2_addr); /* Address of "huge" object tracker B-tree */
/* "Managed" object free space information */
H5F_ENCODE_LENGTH(f, image, hdr->total_man_free); /* Internal free space in managed direct blocks */
H5F_addr_encode(f, &image, hdr->fs_addr); /* Address of free section header */
/* Heap statistics */
H5F_ENCODE_LENGTH(f, image, hdr->man_size);
H5F_ENCODE_LENGTH(f, image, hdr->man_alloc_size);
H5F_ENCODE_LENGTH(f, image, hdr->man_iter_off);
H5F_ENCODE_LENGTH(f, image, hdr->man_nobjs);
H5F_ENCODE_LENGTH(f, image, hdr->huge_size);
H5F_ENCODE_LENGTH(f, image, hdr->huge_nobjs);
H5F_ENCODE_LENGTH(f, image, hdr->tiny_size);
H5F_ENCODE_LENGTH(f, image, hdr->tiny_nobjs);
/* Managed objects' doubling-table info */
if (H5HF__dtable_encode(hdr->f, &image, &(hdr->man_dtable)) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTENCODE, FAIL, "unable to encode managed obj. doubling table info");
/* Check for I/O filter information to encode */
if (hdr->filter_len > 0) {
/* Encode the size of a filtered root direct block */
H5F_ENCODE_LENGTH(f, image, hdr->pline_root_direct_size);
/* Encode the filter mask for a filtered root direct block */
UINT32ENCODE(image, hdr->pline_root_direct_filter_mask);
/* Encode I/O filter information */
if (H5O_msg_encode(hdr->f, H5O_PLINE_ID, false, image, &(hdr->pline)) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTENCODE, FAIL, "can't encode I/O pipeline filters");
image += hdr->filter_len;
} /* end if */
/* Compute metadata checksum */
metadata_chksum = H5_checksum_metadata(_image, (size_t)(image - (uint8_t *)_image), 0);
/* Metadata checksum */
UINT32ENCODE(image, metadata_chksum);
/* sanity check */
assert((size_t)(image - (uint8_t *)_image) == len);
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_hdr_serialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_hdr_free_icr
*
* Purpose: Free the in core representation of the fractal heap header.
*
* This routine frees just the header itself, not the
* associated version 2 B-Tree, the associated Free Space Manager,
* nor the indirect/direct block tree that is rooted in the header.
*
* This routine also does not free the file space that may
* be allocated to the header.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_hdr_free_icr(void *_thing)
{
H5HF_hdr_t *hdr = (H5HF_hdr_t *)_thing; /* Fractal heap info */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
assert(hdr->rc == 0);
if (H5HF__hdr_free(hdr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTRELEASE, FAIL, "unable to release fractal heap header");
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_hdr_free_icr() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_get_initial_load_size()
*
* Purpose: Compute the size of the on disk image of the indirect
* block, and place this value in *image_len.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_iblock_get_initial_load_size(void *_udata, size_t *image_len)
{
H5HF_iblock_cache_ud_t *udata = (H5HF_iblock_cache_ud_t *)_udata; /* User data for callback */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(udata);
assert(udata->par_info);
assert(udata->par_info->hdr);
assert(image_len);
/* Set the image length size */
*image_len = (size_t)H5HF_MAN_INDIRECT_SIZE(udata->par_info->hdr, *udata->nrows);
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_iblock_get_initial_load_size() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_verify_chksum
*
* Purpose: Verify the computed checksum of the data structure is the
* same as the stored checksum.
*
* Return: Success: true/false
* Failure: Negative
*
*-------------------------------------------------------------------------
*/
static htri_t
H5HF__cache_iblock_verify_chksum(const void *_image, size_t len, void H5_ATTR_UNUSED *_udata)
{
const uint8_t *image = (const uint8_t *)_image; /* Pointer into raw data buffer */
uint32_t stored_chksum; /* Stored metadata checksum value */
uint32_t computed_chksum; /* Computed metadata checksum value */
htri_t ret_value = true; /* Return value */
FUNC_ENTER_PACKAGE_NOERR
/* Check arguments */
assert(image);
/* Get stored and computed checksums */
H5F_get_checksums(image, len, &stored_chksum, &computed_chksum);
if (stored_chksum != computed_chksum)
ret_value = false;
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_iblock_verify_chksum() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_deserialize
*
* Purpose: Given a buffer containing the on disk image of the indirect
* block, allocate an instance of H5HF_indirect_t, load the data
* in the buffer into this new instance, and return a pointer to
* it.
*
* As best I can tell, the size of the indirect block image is fully
* know before the image is loaded, so this function should succeed
* unless the image is corrupt or memory allocation fails.
*
* Return: Success: Pointer to in core representation
* Failure: NULL
*
*-------------------------------------------------------------------------
*/
static void *
H5HF__cache_iblock_deserialize(const void *_image, size_t H5_ATTR_NDEBUG_UNUSED len, void *_udata,
bool H5_ATTR_UNUSED *dirty)
{
H5HF_hdr_t *hdr; /* Shared fractal heap information */
H5HF_iblock_cache_ud_t *udata = (H5HF_iblock_cache_ud_t *)_udata; /* User data for callback */
H5HF_indirect_t *iblock = NULL; /* Indirect block info */
const uint8_t *image = (const uint8_t *)_image; /* Pointer into raw data buffer */
haddr_t heap_addr; /* Address of heap header in the file */
uint32_t stored_chksum; /* Stored metadata checksum value */
unsigned u; /* Local index variable */
void *ret_value = NULL; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(image);
assert(udata);
assert(dirty);
hdr = udata->par_info->hdr;
assert(hdr->f);
/* Set the shared heap header's file context for this operation */
hdr->f = udata->f;
/* Allocate space for the fractal heap indirect block */
if (NULL == (iblock = H5FL_CALLOC(H5HF_indirect_t)))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "memory allocation failed");
/* Share common heap information */
iblock->hdr = hdr;
if (H5HF__hdr_incr(hdr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTINC, NULL, "can't increment reference count on shared heap header");
/* Set block's internal information */
iblock->rc = 0;
iblock->nrows = *udata->nrows;
iblock->nchildren = 0;
/* Compute size of indirect block */
iblock->size = H5HF_MAN_INDIRECT_SIZE(hdr, iblock->nrows);
/* sanity check */
assert(iblock->size == len);
/* Magic number */
if (memcmp(image, H5HF_IBLOCK_MAGIC, (size_t)H5_SIZEOF_MAGIC) != 0)
HGOTO_ERROR(H5E_HEAP, H5E_BADVALUE, NULL, "wrong fractal heap indirect block signature");
image += H5_SIZEOF_MAGIC;
/* Version */
if (*image++ != H5HF_IBLOCK_VERSION)
HGOTO_ERROR(H5E_HEAP, H5E_VERSION, NULL, "wrong fractal heap direct block version");
/* Address of heap that owns this block */
H5F_addr_decode(udata->f, &image, &heap_addr);
if (H5_addr_ne(heap_addr, hdr->heap_addr))
HGOTO_ERROR(H5E_HEAP, H5E_CANTLOAD, NULL, "incorrect heap header address for direct block");
/* Address of parent block */
iblock->parent = udata->par_info->iblock;
/* this copy of the parent pointer is needed by the notify callback so */
/* that it can take down flush dependencies on eviction even if */
/* the parent pointer has been nulled out. JRM -- 5/18/14 */
if (udata->par_info->iblock)
iblock->fd_parent = udata->par_info->iblock;
else
iblock->fd_parent = udata->par_info->hdr;
iblock->par_entry = udata->par_info->entry;
if (iblock->parent) {
/* Share parent block */
if (H5HF__iblock_incr(iblock->parent) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTINC, NULL,
"can't increment reference count on shared indirect block");
/* Set max. # of rows in this block */
iblock->max_rows = iblock->nrows;
} /* end if */
else {
/* Set max. # of rows in this block */
iblock->max_rows = hdr->man_dtable.max_root_rows;
} /* end else */
/* Offset of heap within the heap's address space */
UINT64DECODE_VAR(image, iblock->block_off, hdr->heap_off_size);
/* Allocate & decode child block entry tables */
assert(iblock->nrows > 0);
if (NULL == (iblock->ents = H5FL_SEQ_MALLOC(H5HF_indirect_ent_t,
(size_t)(iblock->nrows * hdr->man_dtable.cparam.width))))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "memory allocation failed for direct entries");
if (hdr->filter_len > 0) {
unsigned dir_rows; /* Number of direct rows in this indirect block */
/* Compute the number of direct rows for this indirect block */
dir_rows = MIN(iblock->nrows, hdr->man_dtable.max_direct_rows);
/* Allocate indirect block filtered entry array */
if (NULL == (iblock->filt_ents = H5FL_SEQ_MALLOC(H5HF_indirect_filt_ent_t,
(size_t)(dir_rows * hdr->man_dtable.cparam.width))))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "memory allocation failed for block entries");
} /* end if */
else
iblock->filt_ents = NULL;
for (u = 0; u < (iblock->nrows * hdr->man_dtable.cparam.width); u++) {
/* Decode child block address */
H5F_addr_decode(udata->f, &image, &(iblock->ents[u].addr));
/* Check for heap with I/O filters */
if (hdr->filter_len > 0) {
/* Sanity check */
assert(iblock->filt_ents);
/* Decode extra information for direct blocks */
if (u < (hdr->man_dtable.max_direct_rows * hdr->man_dtable.cparam.width)) {
/* Size of filtered direct block */
H5F_DECODE_LENGTH(udata->f, image, iblock->filt_ents[u].size);
/* Sanity check */
/* (either both the address & size are defined or both are
* not defined)
*/
assert((H5_addr_defined(iblock->ents[u].addr) && iblock->filt_ents[u].size) ||
(!H5_addr_defined(iblock->ents[u].addr) && iblock->filt_ents[u].size == 0));
/* I/O filter mask for filtered direct block */
UINT32DECODE(image, iblock->filt_ents[u].filter_mask);
} /* end if */
} /* end if */
/* Count child blocks */
if (H5_addr_defined(iblock->ents[u].addr)) {
iblock->nchildren++;
iblock->max_child = u;
} /* end if */
} /* end for */
/* Sanity check */
assert(iblock->nchildren); /* indirect blocks w/no children should have been deleted */
/* checksum verification already done by verify_chksum cb */
/* Metadata checksum */
UINT32DECODE(image, stored_chksum);
/* Sanity check */
assert((size_t)(image - (const uint8_t *)_image) == iblock->size);
/* Check if we have any indirect block children */
if (iblock->nrows > hdr->man_dtable.max_direct_rows) {
unsigned indir_rows; /* Number of indirect rows in this indirect block */
/* Compute the number of indirect rows for this indirect block */
indir_rows = iblock->nrows - hdr->man_dtable.max_direct_rows;
/* Allocate & initialize child indirect block pointer array */
if (NULL == (iblock->child_iblocks = H5FL_SEQ_CALLOC(
H5HF_indirect_ptr_t, (size_t)(indir_rows * hdr->man_dtable.cparam.width))))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, NULL, "memory allocation failed for block entries");
} /* end if */
else
iblock->child_iblocks = NULL;
/* Set return value */
ret_value = (void *)iblock;
done:
if (!ret_value && iblock)
if (H5HF__man_iblock_dest(iblock) < 0)
HDONE_ERROR(H5E_HEAP, H5E_CANTFREE, NULL, "unable to destroy fractal heap indirect block");
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_iblock_deserialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_image_len
*
* Purpose: Return the size of the on disk image of the iblock.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_iblock_image_len(const void *_thing, size_t *image_len)
{
const H5HF_indirect_t *iblock = (const H5HF_indirect_t *)_thing; /* Indirect block info */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(image_len);
*image_len = iblock->size;
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_iblock_image_len() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_pre_serialize
*
* Purpose: The primary objective of this function is to determine if the
* indirect block is currently allocated in temporary file space,
* and if so, to move it to real file space before the entry is
* serialized.
*
* In debug compiles, this function also verifies that all
* immediate flush dependency children of this indirect block
* are either clean or are not in cache.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_iblock_pre_serialize(H5F_t *f, void *_thing, haddr_t addr, size_t H5_ATTR_UNUSED len,
haddr_t *new_addr, size_t H5_ATTR_UNUSED *new_len, unsigned *flags)
{
H5HF_hdr_t *hdr; /* Shared fractal heap information */
H5HF_indirect_t *iblock = (H5HF_indirect_t *)_thing; /* Indirect block info */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(iblock->cache_info.size == iblock->size);
assert(H5_addr_defined(addr));
assert(H5_addr_eq(iblock->addr, addr));
assert(new_addr);
assert(new_len);
assert(flags);
hdr = iblock->hdr;
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
#ifndef NDEBUG
{
bool descendants_clean = true;
bool fd_children_clean = true;
unsigned iblock_status = 0;
/* verify that flush dependencies are working correctly. Do this
* by verifying that all immediate flush dependency children of this
* iblock are clean.
*/
if (H5AC_get_entry_status(f, iblock->addr, &iblock_status) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't get iblock status");
/* since the current iblock is the guest of honor in a flush, we know
* that it is locked into the cache for the duration of the call. Hence
* there is no need to check to see if it is pinned or protected, or to
* protect it if it is not.
*/
if (H5HF__cache_verify_iblock_descendants_clean((H5F_t *)f, iblock->addr, iblock, &iblock_status,
&fd_children_clean, &descendants_clean) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "can't verify descendants clean.");
assert(fd_children_clean);
}
#endif /* NDEBUG */
/* Check to see if we must re-allocate the iblock from temporary to
* normal (AKA real) file space.
*/
if (H5F_IS_TMP_ADDR(f, addr)) {
haddr_t iblock_addr;
/* Allocate 'normal' space for the new indirect block on disk */
if (HADDR_UNDEF ==
(iblock_addr = H5MF_alloc((H5F_t *)f, H5FD_MEM_FHEAP_IBLOCK, (hsize_t)iblock->size)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, FAIL,
"file allocation failed for fractal heap indirect block");
/* Sanity check */
assert(!H5_addr_eq(iblock->addr, iblock_addr));
/* Let the metadata cache know the block moved */
if (H5AC_move_entry((H5F_t *)f, H5AC_FHEAP_IBLOCK, iblock->addr, iblock_addr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTMOVE, FAIL, "unable to move indirect block");
/* Update the internal address for the block */
iblock->addr = iblock_addr;
/* Check for root indirect block */
if (NULL == iblock->parent) {
/* Update information about indirect block's location */
hdr->man_dtable.table_addr = iblock_addr;
/* Mark that heap header was modified */
if (H5HF__hdr_dirty(hdr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDIRTY, FAIL, "can't mark heap header as dirty");
} /* end if */
else {
H5HF_indirect_t *par_iblock; /* Parent indirect block */
unsigned par_entry; /* Entry in parent indirect block */
/* Get parent information */
par_iblock = iblock->parent;
par_entry = iblock->par_entry;
/* Update information about indirect block's location */
par_iblock->ents[par_entry].addr = iblock_addr;
/* Mark that parent was modified */
if (H5HF__iblock_dirty(par_iblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDIRTY, FAIL, "can't mark heap header as dirty");
} /* end if */
*new_addr = iblock_addr;
*flags = H5AC__SERIALIZE_MOVED_FLAG;
} /* end if */
else
*flags = 0;
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_iblock_pre_serialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_serialize
*
* Purpose: Given a pointer to an iblock, and a pointer to a buffer of
* the appropriate size, write the contents of the iblock to the
* buffer in format appropriate for writing to disk.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_iblock_serialize(const H5F_t *f, void *_image, size_t H5_ATTR_NDEBUG_UNUSED len, void *_thing)
{
H5HF_hdr_t *hdr; /* Shared fractal heap information */
H5HF_indirect_t *iblock = (H5HF_indirect_t *)_thing; /* Indirect block info */
uint8_t *image = (uint8_t *)_image; /* Pointer into raw data buffer */
#ifndef NDEBUG
unsigned nchildren = 0; /* Track # of children */
size_t max_child = 0; /* Track max. child entry used */
#endif /* NDEBUG */
uint32_t metadata_chksum; /* Computed metadata checksum value */
size_t u; /* Local index variable */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(f);
assert(image);
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(iblock->cache_info.size == iblock->size);
assert(len == iblock->size);
/* Indirect block must be in 'normal' file space */
assert(!H5F_IS_TMP_ADDR(f, iblock->addr));
assert(H5_addr_eq(iblock->addr, iblock->cache_info.addr));
/* Get the pointer to the shared heap header */
hdr = iblock->hdr;
/* Set the shared heap header's file context for this operation */
H5_GCC_DIAG_OFF("discarded-qualifiers")
H5_CLANG_DIAG_OFF("incompatible-pointer-types-discards-qualifiers")
hdr->f = f;
H5_GCC_DIAG_ON("discarded-qualifiers")
H5_CLANG_DIAG_ON("incompatible-pointer-types-discards-qualifiers")
/* Magic number */
H5MM_memcpy(image, H5HF_IBLOCK_MAGIC, (size_t)H5_SIZEOF_MAGIC);
image += H5_SIZEOF_MAGIC;
/* Version # */
*image++ = H5HF_IBLOCK_VERSION;
/* Address of heap header for heap which owns this block */
H5F_addr_encode(f, &image, hdr->heap_addr);
/* Offset of block in heap */
UINT64ENCODE_VAR(image, iblock->block_off, hdr->heap_off_size);
/* Encode indirect block-specific fields */
for (u = 0; u < (iblock->nrows * hdr->man_dtable.cparam.width); u++) {
/* Encode child block address */
H5F_addr_encode(f, &image, iblock->ents[u].addr);
/* Check for heap with I/O filters */
if (hdr->filter_len > 0) {
/* Sanity check */
assert(iblock->filt_ents);
/* Encode extra information for direct blocks */
if (u < (hdr->man_dtable.max_direct_rows * hdr->man_dtable.cparam.width)) {
/* Sanity check */
/* (either both the address & size are defined or both are
* not defined)
*/
assert((H5_addr_defined(iblock->ents[u].addr) && iblock->filt_ents[u].size) ||
(!H5_addr_defined(iblock->ents[u].addr) && iblock->filt_ents[u].size == 0));
/* Size of filtered direct block */
H5F_ENCODE_LENGTH(f, image, iblock->filt_ents[u].size);
/* I/O filter mask for filtered direct block */
UINT32ENCODE(image, iblock->filt_ents[u].filter_mask);
} /* end if */
} /* end if */
#ifndef NDEBUG
/* Count child blocks */
if (H5_addr_defined(iblock->ents[u].addr)) {
nchildren++;
if (u > max_child)
max_child = u;
} /* end if */
#endif /* NDEBUG */
} /* end for */
/* Compute checksum */
metadata_chksum = H5_checksum_metadata((uint8_t *)_image, (size_t)(image - (uint8_t *)_image), 0);
/* Metadata checksum */
UINT32ENCODE(image, metadata_chksum);
/* Sanity checks */
assert((size_t)(image - (uint8_t *)_image) == iblock->size);
#ifndef NDEBUG
assert(nchildren == iblock->nchildren);
assert(max_child == iblock->max_child);
#endif /* NDEBUG */
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_iblock_serialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_notify
*
* Purpose: This function is used to create and destroy flush dependency
* relationships between iblocks and their parents as indirect blocks
* are loaded / inserted and evicted from the metadata cache.
*
* In general, the parent will be another iblock, but it may be the
* header if the iblock in question is the root iblock.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_iblock_notify(H5AC_notify_action_t action, void *_thing)
{
H5HF_indirect_t *iblock = (H5HF_indirect_t *)_thing; /* Indirect block info */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(iblock->hdr);
/* further sanity checks */
if (iblock->parent == NULL) {
/* pointer from hdr to root iblock will not be set up unless */
/* the fractal heap has already pinned the hdr. Do what */
/* sanity checking we can. */
if ((iblock->block_off == 0) && (iblock->hdr->root_iblock_flags & H5HF_ROOT_IBLOCK_PINNED))
assert(iblock->hdr->root_iblock == iblock);
} /* end if */
else {
/* if this is a child iblock, verify that the pointers are */
/* either uninitialized or set up correctly. */
H5HF_indirect_t H5_ATTR_NDEBUG_UNUSED *par_iblock = iblock->parent;
unsigned H5_ATTR_NDEBUG_UNUSED indir_idx; /* Index in parent's child iblock pointer array */
/* Sanity check */
assert(par_iblock->child_iblocks);
assert(iblock->par_entry >=
(iblock->hdr->man_dtable.max_direct_rows * iblock->hdr->man_dtable.cparam.width));
/* Compute index in parent's child iblock pointer array */
indir_idx = iblock->par_entry -
(iblock->hdr->man_dtable.max_direct_rows * iblock->hdr->man_dtable.cparam.width);
/* The pointer to iblock in the parent may not be set yet -- */
/* verify that it is either NULL, or that it has been set to */
/* iblock. */
assert((NULL == par_iblock->child_iblocks[indir_idx]) ||
(par_iblock->child_iblocks[indir_idx] == iblock));
} /* end else */
switch (action) {
case H5AC_NOTIFY_ACTION_AFTER_INSERT:
case H5AC_NOTIFY_ACTION_AFTER_LOAD:
/* Create flush dependency with parent, if there is one */
if (iblock->fd_parent)
if (H5AC_create_flush_dependency(iblock->fd_parent, iblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDEPEND, FAIL, "unable to create flush dependency");
break;
case H5AC_NOTIFY_ACTION_AFTER_FLUSH:
case H5AC_NOTIFY_ACTION_ENTRY_DIRTIED:
case H5AC_NOTIFY_ACTION_ENTRY_CLEANED:
case H5AC_NOTIFY_ACTION_CHILD_DIRTIED:
case H5AC_NOTIFY_ACTION_CHILD_CLEANED:
case H5AC_NOTIFY_ACTION_CHILD_UNSERIALIZED:
case H5AC_NOTIFY_ACTION_CHILD_SERIALIZED:
/* do nothing */
break;
case H5AC_NOTIFY_ACTION_BEFORE_EVICT:
if (iblock->fd_parent) {
/* Destroy flush dependency with parent */
if (H5AC_destroy_flush_dependency(iblock->fd_parent, iblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTUNDEPEND, FAIL, "unable to destroy flush dependency");
iblock->fd_parent = NULL;
} /* end if */
break;
default:
HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "unknown action from metadata cache");
break;
} /* end switch */
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_iblock_notify() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_iblock_free_icr
*
* Purpose: Unlink the supplied instance of H5HF_indirect_t from the
* fractal heap and free its memory.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_iblock_free_icr(void *thing)
{
H5HF_indirect_t *iblock = (H5HF_indirect_t *)thing; /* Fractal heap indirect block to free */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(iblock->rc == 0);
assert(iblock->hdr);
/* Destroy fractal heap indirect block */
if (H5HF__man_iblock_dest(iblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTFREE, FAIL, "unable to destroy fractal heap indirect block");
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_iblock_free_icr() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_get_initial_load_size()
*
* Purpose: Determine the size of the direct block on disk image, and
* return it in *image_len.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_get_initial_load_size(void *_udata, size_t *image_len)
{
const H5HF_dblock_cache_ud_t *udata = (const H5HF_dblock_cache_ud_t *)_udata; /* User data for callback */
const H5HF_parent_t *par_info; /* Pointer to parent information */
const H5HF_hdr_t *hdr; /* Shared fractal heap information */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(udata);
assert(image_len);
/* Convenience variables */
par_info = (const H5HF_parent_t *)(&(udata->par_info));
assert(par_info);
hdr = par_info->hdr;
assert(hdr);
/* Check for I/O filters on this heap */
if (hdr->filter_len > 0) {
/* Check for root direct block */
if (par_info->iblock == NULL)
/* filtered root direct block */
*image_len = hdr->pline_root_direct_size;
else
/* filtered direct block */
*image_len = par_info->iblock->filt_ents[par_info->entry].size;
} /* end if */
else
*image_len = udata->dblock_size;
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_dblock_get_initial_load_size() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_verify_chksum
*
* Purpose: Verify the computed checksum of the data structure is the
* same as the stored chksum.
*
* Return: Success: true/false
* Failure: Negative
*
*-------------------------------------------------------------------------
*/
static htri_t
H5HF__cache_dblock_verify_chksum(const void *_image, size_t len, void *_udata)
{
const uint8_t *image = (const uint8_t *)_image; /* Pointer into raw data buffer */
H5HF_dblock_cache_ud_t *udata = (H5HF_dblock_cache_ud_t *)_udata; /* User data for callback */
void *read_buf = NULL; /* Pointer to buffer to read in */
H5HF_hdr_t *hdr; /* Shared fractal heap information */
H5HF_parent_t *par_info; /* Pointer to parent information */
uint32_t stored_chksum; /* Stored metadata checksum value */
uint32_t computed_chksum; /* Computed metadata checksum value */
size_t chk_size; /* The size for validating checksum */
uint8_t *chk_p; /* Pointer to the area for validating checksum */
htri_t ret_value = true; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(image);
assert(udata);
par_info = (H5HF_parent_t *)(&(udata->par_info));
assert(par_info);
hdr = par_info->hdr;
assert(hdr);
/* Get out if data block is not checksummed */
if (!(hdr->checksum_dblocks))
HGOTO_DONE(true);
if (hdr->filter_len > 0) {
size_t nbytes; /* Number of bytes used in buffer, after applying reverse filters */
unsigned filter_mask; /* Excluded filters for direct block */
H5Z_cb_t filter_cb; /* Filter callback structure */
/* Initialize the filter callback struct */
filter_cb.op_data = NULL;
filter_cb.func = NULL; /* no callback function when failed */
/* Allocate buffer to perform I/O filtering on and copy image into
* it. Must do this as H5Z_pipeline() may re-size the buffer
* provided to it.
*/
if (NULL == (read_buf = H5MM_malloc(len)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, FAIL, "memory allocation failed for pipeline buffer");
/* Set up parameters for filter pipeline */
nbytes = len;
filter_mask = udata->filter_mask;
H5MM_memcpy(read_buf, image, len);
/* Push direct block data through I/O filter pipeline */
if (H5Z_pipeline(&(hdr->pline), H5Z_FLAG_REVERSE, &filter_mask, H5Z_ENABLE_EDC, filter_cb, &nbytes,
&len, &read_buf) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTFILTER, FAIL, "output pipeline failed");
/* Update info about direct block */
udata->decompressed = true;
len = nbytes;
}
else {
/* If the data are unfiltered, we just point to the image, which we
* never modify. Casting away const is okay here.
*/
H5_GCC_CLANG_DIAG_OFF("cast-qual")
read_buf = (void *)image;
H5_GCC_CLANG_DIAG_OFF("cast-qual")
}
/* Decode checksum */
chk_size = (size_t)(H5HF_MAN_ABS_DIRECT_OVERHEAD(hdr) - H5HF_SIZEOF_CHKSUM);
chk_p = (uint8_t *)read_buf + chk_size;
/* Metadata checksum */
UINT32DECODE(chk_p, stored_chksum);
chk_p -= H5HF_SIZEOF_CHKSUM;
/* Reset checksum field, for computing the checksum */
memset(chk_p, 0, (size_t)H5HF_SIZEOF_CHKSUM);
/* Compute checksum on entire direct block */
computed_chksum = H5_checksum_metadata(read_buf, len, 0);
/* Restore the checksum */
UINT32ENCODE(chk_p, stored_chksum);
/* Verify checksum */
if (stored_chksum != computed_chksum)
HGOTO_DONE(false);
/* Save the decompressed data to be used later in deserialize callback */
if (hdr->filter_len > 0) {
/* Sanity check */
assert(udata->decompressed);
assert(len == udata->dblock_size);
/* Allocate block buffer */
if (NULL == (udata->dblk = H5FL_BLK_MALLOC(direct_block, (size_t)len)))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "memory allocation failed");
/* Copy un-filtered data into block's buffer */
H5MM_memcpy(udata->dblk, read_buf, len);
} /* end if */
done:
/* Release the read buffer */
if (read_buf && read_buf != image)
H5MM_xfree(read_buf);
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_dblock_verify_chksum() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_deserialize
*
* Purpose: Given a buffer containing the on disk image of a direct
* block, allocate an instance of H5HF_direct_t, load the data
* in the buffer into this new instance, and return a pointer to
* it.
*
* As best I can tell, the size of the direct block image is fully
* know before the image is loaded, so this function should succeed
* unless the image is corrupt or memory allocation fails.
*
* Return: Success: Pointer to in core representation
* Failure: NULL
*
*-------------------------------------------------------------------------
*/
static void *
H5HF__cache_dblock_deserialize(const void *_image, size_t len, void *_udata, bool H5_ATTR_UNUSED *dirty)
{
H5HF_hdr_t *hdr; /* Shared fractal heap information */
H5HF_dblock_cache_ud_t *udata = (H5HF_dblock_cache_ud_t *)_udata; /* User data for callback */
H5HF_parent_t *par_info; /* Pointer to parent information */
H5HF_direct_t *dblock = NULL; /* Direct block info */
const uint8_t *image = (const uint8_t *)_image; /* Pointer into raw data buffer */
void *read_buf = NULL; /* Pointer to buffer to decompress */
haddr_t heap_addr; /* Address of heap header in the file */
void *ret_value = NULL; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(image);
assert(udata);
par_info = (H5HF_parent_t *)(&(udata->par_info));
assert(par_info);
hdr = par_info->hdr;
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
assert(dirty);
/* Allocate space for the fractal heap direct block */
if (NULL == (dblock = H5FL_CALLOC(H5HF_direct_t)))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "memory allocation failed");
memset(&dblock->cache_info, 0, sizeof(H5AC_info_t));
/* Set the shared heap header's file context for this operation */
hdr->f = udata->f;
/* Share common heap information */
dblock->hdr = hdr;
if (H5HF__hdr_incr(hdr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTINC, NULL, "can't increment reference count on shared heap header");
/* Set block's internal information */
dblock->size = udata->dblock_size;
/* Check for I/O filters on this heap */
if (hdr->filter_len > 0) {
/* Direct block is already decompressed in verify_chksum callback */
if (udata->decompressed) {
/* Sanity check */
assert(udata->dblk);
/* Take ownership of the decompressed direct block */
dblock->blk = udata->dblk;
udata->dblk = NULL;
} /* end if */
else {
H5Z_cb_t filter_cb; /* Filter callback structure */
size_t nbytes; /* Number of bytes used in buffer, after applying reverse filters */
unsigned filter_mask; /* Excluded filters for direct block */
/* Sanity check */
assert(udata->dblk == NULL);
/* Initialize the filter callback struct */
filter_cb.op_data = NULL;
filter_cb.func = NULL; /* no callback function when failed */
/* Allocate buffer to perform I/O filtering on and copy image into
* it. Must do this as H5Z_pipeline() may resize the buffer
* provided to it.
*/
if (NULL == (read_buf = H5MM_malloc(len)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, NULL, "memory allocation failed for pipeline buffer");
/* Copy compressed image into buffer */
H5MM_memcpy(read_buf, image, len);
/* Push direct block data through I/O filter pipeline */
nbytes = len;
filter_mask = udata->filter_mask;
if (H5Z_pipeline(&(hdr->pline), H5Z_FLAG_REVERSE, &filter_mask, H5Z_ENABLE_EDC, filter_cb,
&nbytes, &len, &read_buf) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTFILTER, NULL, "output pipeline failed");
/* Sanity check */
assert(nbytes == dblock->size);
/* Copy un-filtered data into block's buffer */
H5MM_memcpy(dblock->blk, read_buf, dblock->size);
} /* end if */
} /* end if */
else {
/* Sanity checks */
assert(udata->dblk == NULL);
assert(!udata->decompressed);
/* Allocate block buffer */
/* XXX: Change to using free-list factories */
if (NULL == (dblock->blk = H5FL_BLK_MALLOC(direct_block, (size_t)dblock->size)))
HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "memory allocation failed");
/* Copy image to dblock->blk */
assert(dblock->size == len);
H5MM_memcpy(dblock->blk, image, dblock->size);
} /* end else */
/* Start decoding direct block */
image = dblock->blk;
/* Magic number */
if (memcmp(image, H5HF_DBLOCK_MAGIC, (size_t)H5_SIZEOF_MAGIC) != 0)
HGOTO_ERROR(H5E_HEAP, H5E_BADVALUE, NULL, "wrong fractal heap direct block signature");
image += H5_SIZEOF_MAGIC;
/* Version */
if (*image++ != H5HF_DBLOCK_VERSION)
HGOTO_ERROR(H5E_HEAP, H5E_VERSION, NULL, "wrong fractal heap direct block version");
/* Address of heap that owns this block (just for file integrity checks) */
H5F_addr_decode(udata->f, &image, &heap_addr);
if (H5_addr_ne(heap_addr, hdr->heap_addr))
HGOTO_ERROR(H5E_HEAP, H5E_CANTLOAD, NULL, "incorrect heap header address for direct block");
/* Address of parent block */
dblock->parent = par_info->iblock;
if (par_info->iblock)
dblock->fd_parent = par_info->iblock;
else
dblock->fd_parent = par_info->hdr;
dblock->par_entry = par_info->entry;
if (dblock->parent) {
/* Share parent block */
if (H5HF__iblock_incr(dblock->parent) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTINC, NULL,
"can't increment reference count on shared indirect block");
} /* end if */
/* Offset of heap within the heap's address space */
UINT64DECODE_VAR(image, dblock->block_off, hdr->heap_off_size);
/* Decode checksum on direct block, if requested */
if (hdr->checksum_dblocks) {
uint32_t stored_chksum; /* Metadata checksum value */
/* checksum verification already done in verify_chksum cb */
/* Metadata checksum */
UINT32DECODE(image, stored_chksum);
} /* end if */
/* Sanity check */
assert((size_t)(image - dblock->blk) == (size_t)H5HF_MAN_ABS_DIRECT_OVERHEAD(hdr));
/* Set return value */
ret_value = (void *)dblock;
done:
/* Release the read buffer */
if (read_buf)
H5MM_xfree(read_buf);
/* Cleanup on error */
if (!ret_value && dblock)
if (H5HF__man_dblock_dest(dblock) < 0)
HDONE_ERROR(H5E_HEAP, H5E_CANTFREE, NULL, "unable to destroy fractal heap direct block");
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_dblock_deserialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_image_len
*
* Purpose: Report the actual size of the direct block image on disk.
* Note that this value will probably be incorrect if compression
* is enabled and the entry is dirty.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_image_len(const void *_thing, size_t *image_len)
{
const H5HF_direct_t *dblock = (const H5HF_direct_t *)_thing; /* Direct block info */
const H5HF_hdr_t *hdr; /* Shared fractal heap information */
size_t size;
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(dblock);
assert(dblock->cache_info.type == H5AC_FHEAP_DBLOCK);
assert(image_len);
/* Set up convenience variables */
hdr = dblock->hdr;
assert(hdr);
/* Check for I/O filters on this heap */
if (hdr->filter_len > 0) {
/*
* If the data is available, set to the compressed
* size of the direct block -- otherwise set it equal to the
* uncompressed size.
*
* We have three possible scenarios here.
*
* First, the block may never have been flushed. In this
* case, both dblock->file_size and the size stored in the
* parent (either the header or the parent iblock) will all
* be zero. In this case, return the uncompressed size
* stored in dblock->size as the size.
*
* Second, the block may have just been serialized, in which
* case, dblock->file_size should be zero, and the correct
* on disk size should be stored in the parent (again, either
* the header or the parent iblock as case may be).
*
* Third, we may be in the process of discarding this
* dblock without writing it. In this case, dblock->file_size
* should be non-zero and have the correct size. Note that
* in this case, the direct block will have been detached,
* and thus looking up the parent will likely return incorrect
* data.
*/
if (dblock->file_size != 0)
size = dblock->file_size;
else {
const H5HF_indirect_t *par_iblock = dblock->parent; /* Parent iblock */
if (par_iblock)
size = par_iblock->filt_ents[dblock->par_entry].size;
else
size = hdr->pline_root_direct_size;
if (size == 0)
size = dblock->size;
} /* end else */
} /* end if */
else
size = dblock->size;
/* Set the image size */
assert(size > 0);
*image_len = size;
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_dblock_image_len() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_pre_serialize
*
* Purpose: In principle, the purpose of this function is to determine
* the size and location of the disk image of the target direct
* block. In this case, the uncompressed size of the block is
* fixed, but since the direct block could be compressed,
* we may need to compute and report the compressed size.
*
* This is a bit sticky in the case of a direct block when I/O
* filters are enabled, as the size of the compressed version
* of the on disk image is not known until the direct block has
* been run through the filters. Further, the location of the
* on disk image may change if the compressed size of the image
* changes as well.
*
* To complicate matters further, the direct block may have been
* initially allocated in temporary (AKA imaginary) file space.
* In this case, we must relocate the direct block's on-disk
* image to "real" file space regardless of whether it has changed
* size.
*
* One simplifying factor is the direct block's "blk" field,
* which contains a pointer to a buffer which (with the exception
* of a small header) contains the on disk image in uncompressed
* form.
*
* To square this particular circle, this function does
* everything the serialize function usually does, with the
* exception of copying the image into the image buffer provided
* to the serialize function by the metadata cache. The data to
* copy is provided to the serialize function in a buffer pointed
* to by the write_buf field.
*
* If I/O filters are enabled, on exit,
* H5HF__cache_dblock_pre_serialize() sets the write_buf field to
* point to a buffer containing the filtered image of the direct
* block. The serialize function should free this block, and set
* the write_buf field to NULL after copying it into the image
* buffer provided by the metadata cache.
*
* If I/O filters are not enabled, this function prepares
* the buffer pointed to by the blk field for copying to the
* image buffer provided by the metadata cache, and sets the
* write_buf field equal to the blk field. In this case, the
* serialize function should simply set the write_buf field to
* NULL after copying the direct block image into the image
* buffer.
*
* In both of the above cases, the length of the buffer pointed
* to by write_buf is provided in the write_len field. This
* field must contain 0 on entry to this function, and should
* be set back to 0 at the end of the serialize function.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_pre_serialize(H5F_t *f, void *_thing, haddr_t addr, size_t len, haddr_t *new_addr,
size_t *new_len, unsigned *flags)
{
bool at_tmp_addr; /* Flag to indicate direct block is */
/* at temporary address */
haddr_t dblock_addr;
H5HF_hdr_t *hdr; /* Shared fractal heap information */
H5HF_direct_t *dblock = (H5HF_direct_t *)_thing; /* Direct block info */
H5HF_indirect_t *par_iblock; /* Parent indirect block */
unsigned par_entry = 0; /* Entry in parent indirect block */
void *write_buf; /* Pointer to buffer to write out */
size_t write_size; /* Size of buffer to write out */
uint8_t *image; /* Pointer into raw data buffer */
unsigned dblock_flags = 0;
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(dblock);
assert(dblock->cache_info.type == H5AC_FHEAP_DBLOCK);
assert(dblock->write_buf == NULL);
assert(dblock->write_size == 0);
assert(dblock->cache_info.size == len);
assert(H5_addr_defined(addr));
assert(new_addr);
assert(new_len);
assert(flags);
/* Set up local variables */
hdr = dblock->hdr;
dblock_addr = addr; /* will update dblock_addr if we move the block */
/* Set the shared heap header's file context for this operation */
hdr->f = (H5F_t *)f;
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
if (dblock->parent) {
/* this is the common case, in which the direct block is the child
* of an indirect block. Set up the convenience variables we will
* need if the address and/or compressed size of the on disk image
* of the direct block changes, and do some sanity checking in
* passing.
*/
par_iblock = dblock->parent;
par_entry = dblock->par_entry;
assert(par_iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(H5_addr_eq(par_iblock->ents[par_entry].addr, addr));
} /* end if */
else {
/* the direct block is a root direct block -- just set par_iblock
* to NULL, as the field will not be used.
*/
par_iblock = NULL;
} /* end else */
at_tmp_addr = H5F_IS_TMP_ADDR(f, addr);
/* Begin by preping the direct block to be written to disk. Do
* this by writing the correct magic number, the dblock version,
* the address of the header, the offset of the block in the heap,
* and the checksum at the beginning of the block.
*/
assert(dblock->blk);
image = dblock->blk;
/* Magic number */
H5MM_memcpy(image, H5HF_DBLOCK_MAGIC, (size_t)H5_SIZEOF_MAGIC);
image += H5_SIZEOF_MAGIC;
/* Version # */
*image++ = H5HF_DBLOCK_VERSION;
/* Address of heap header for heap which owns this block */
H5F_addr_encode(f, &image, hdr->heap_addr);
/* Offset of block in heap */
UINT64ENCODE_VAR(image, dblock->block_off, hdr->heap_off_size);
/* Metadata checksum */
if (hdr->checksum_dblocks) {
uint32_t metadata_chksum; /* Computed metadata checksum value */
/* Clear the checksum field, to compute the checksum */
memset(image, 0, (size_t)H5HF_SIZEOF_CHKSUM);
/* Compute checksum on entire direct block */
metadata_chksum = H5_checksum_metadata(dblock->blk, dblock->size, 0);
/* Metadata checksum */
UINT32ENCODE(image, metadata_chksum);
} /* end if */
/* at this point, dblock->blk should point to an uncompressed image of
* the direct block. If I/O filters are not enabled, this image should
* be ready to hand off to the metadata cache.
*/
/* Sanity check */
assert((size_t)(image - dblock->blk) == (size_t)H5HF_MAN_ABS_DIRECT_OVERHEAD(hdr));
/* If I/O filters are enabled on this heap, we must run the direct block
* image through the filters to obtain the image that we will hand off
* to the metadata cache.
*/
/* Check for I/O filters on this heap */
if (hdr->filter_len > 0) {
H5Z_cb_t filter_cb; /* Filter callback structure */
size_t nbytes; /* Number of bytes used */
unsigned filter_mask = 0; /* Filter mask for block */
/* Initialize the filter callback struct */
filter_cb.op_data = NULL;
filter_cb.func = NULL; /* no callback function when failed */
/* Allocate buffer to perform I/O filtering on */
write_size = dblock->size;
if (NULL == (write_buf = H5MM_malloc(write_size)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, FAIL, "memory allocation failed for pipeline buffer");
/* Copy the direct block's image into the buffer to compress */
H5MM_memcpy(write_buf, dblock->blk, write_size);
/* Push direct block data through I/O filter pipeline */
nbytes = write_size;
if (H5Z_pipeline(&(hdr->pline), 0, &filter_mask, H5Z_ENABLE_EDC, filter_cb, &nbytes, &write_size,
&write_buf) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_WRITEERROR, FAIL, "output pipeline failed");
/* Use the compressed number of bytes as the size to write */
write_size = nbytes;
/* If the size and/or location of the on disk image of the
* direct block changes, we must touch up its parent to reflect
* these changes. Do this differently depending on whether the
* direct block's parent is an indirect block or (rarely) the
* fractal heap header. In this case, the direct block is known
* as a root direct block.
*/
/* Check for root direct block */
if (dblock->parent == NULL) {
bool hdr_changed = false; /* Whether the header info changed */
/* Sanity check */
assert(H5_addr_eq(hdr->man_dtable.table_addr, addr));
assert(hdr->pline_root_direct_size > 0);
/* Check if the filter mask changed */
if (hdr->pline_root_direct_filter_mask != filter_mask) {
hdr->pline_root_direct_filter_mask = filter_mask;
hdr_changed = true;
} /* end if */
/* verify that the cache's last record of the compressed
* size matches the heap's last record. This value will
* likely change shortly.
*/
assert(len == hdr->pline_root_direct_size);
/* Check if we need to re-size the block on disk */
if (hdr->pline_root_direct_size != write_size || at_tmp_addr) {
/* Check if the direct block is NOT currently allocated
* in temp. file space
*
* (temp. file space does not need to be freed)
*/
if (!at_tmp_addr)
/* Release direct block's current disk space */
if (H5MF_xfree(f, H5FD_MEM_FHEAP_DBLOCK, addr, (hsize_t)hdr->pline_root_direct_size) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTFREE, FAIL, "unable to free fractal heap direct block");
/* Allocate space for the compressed direct block */
if (HADDR_UNDEF ==
(dblock_addr = H5MF_alloc((H5F_t *)f, H5FD_MEM_FHEAP_DBLOCK, (hsize_t)write_size)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, FAIL,
"file allocation failed for fractal heap direct block");
/* Update information about compressed direct block's
* location & size
*/
assert(hdr->man_dtable.table_addr == addr);
assert(hdr->pline_root_direct_size == len);
hdr->man_dtable.table_addr = dblock_addr;
hdr->pline_root_direct_size = write_size;
/* Note that heap header was modified */
hdr_changed = true;
} /* end if */
/* Check if heap header was modified */
if (hdr_changed)
if (H5HF__hdr_dirty(hdr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDIRTY, FAIL, "can't mark heap header as dirty");
} /* end if */
else { /* the direct block's parent is an indirect block */
bool par_changed = false; /* Whether the parent's infochanged */
/* Sanity check */
assert(par_iblock);
assert(par_iblock->filt_ents[par_entry].size > 0);
/* Check if the filter mask changed */
if (par_iblock->filt_ents[par_entry].filter_mask != filter_mask) {
par_iblock->filt_ents[par_entry].filter_mask = filter_mask;
par_changed = true;
} /* end if */
/* verify that the cache's last record of the compressed
* size matches the heap's last record. This value will
* likely change shortly.
*/
assert(len == par_iblock->filt_ents[par_entry].size);
/* Check if we need to re-size the block on disk */
if (par_iblock->filt_ents[par_entry].size != write_size || at_tmp_addr) {
/* Check if the direct block is NOT currently allocated
* in temp. file space
*
* (temp. file space does not need to be freed)
*/
if (!at_tmp_addr)
/* Release direct block's current disk space */
if (H5MF_xfree(f, H5FD_MEM_FHEAP_DBLOCK, addr,
(hsize_t)par_iblock->filt_ents[par_entry].size) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTFREE, FAIL, "unable to free fractal heap direct block");
/* Allocate space for the compressed direct block */
if (HADDR_UNDEF ==
(dblock_addr = H5MF_alloc((H5F_t *)f, H5FD_MEM_FHEAP_DBLOCK, (hsize_t)write_size)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, FAIL,
"file allocation failed for fractal heap direct block");
/* Update information about compressed direct block's
* location & size
*/
assert(par_iblock->ents[par_entry].addr == addr);
assert(par_iblock->filt_ents[par_entry].size == len);
par_iblock->ents[par_entry].addr = dblock_addr;
par_iblock->filt_ents[par_entry].size = write_size;
/* Note that parent was modified */
par_changed = true;
} /* end if */
/* Check if parent was modified */
if (par_changed)
if (H5HF__iblock_dirty(par_iblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDIRTY, FAIL, "can't mark heap header as dirty");
} /* end else */
} /* end if */
else {
/* I/O filters are not enabled -- thus all we need to do is check to
* see if the direct block is in temporary (AKA imaginary) file
* space, and move it to real file space if it is.
*
* As in the I/O filters case above, we will have to touch up the
* direct blocks parent if the direct block is relocated.
*
* Recall that temporary file space need not be freed, which
* simplifies matters slightly.
*/
write_buf = dblock->blk;
write_size = dblock->size;
/* Check to see if we must re-allocate direct block from 'temp.'
* to 'normal' file space
*/
if (at_tmp_addr) {
/* Allocate 'normal' space for the direct block */
if (HADDR_UNDEF ==
(dblock_addr = H5MF_alloc((H5F_t *)f, H5FD_MEM_FHEAP_DBLOCK, (hsize_t)write_size)))
HGOTO_ERROR(H5E_HEAP, H5E_NOSPACE, FAIL,
"file allocation failed for fractal heap direct block");
/* Check for root direct block */
if (NULL == dblock->parent) {
/* Sanity checks */
assert(H5_addr_eq(hdr->man_dtable.table_addr, addr));
assert(!H5_addr_eq(hdr->man_dtable.table_addr, dblock_addr));
/* Update information about direct block's location */
hdr->man_dtable.table_addr = dblock_addr;
/* Mark that heap header was modified */
if (H5HF__hdr_dirty(hdr) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDIRTY, FAIL, "can't mark heap header as dirty");
} /* end if */
else { /* the direct block's parent is an indirect block */
/* Sanity checks */
assert(par_iblock);
assert(par_iblock->ents);
assert(H5_addr_eq(par_iblock->ents[par_entry].addr, addr));
assert(!H5_addr_eq(par_iblock->ents[par_entry].addr, dblock_addr));
/* Update information about direct block's location */
par_iblock->ents[par_entry].addr = dblock_addr;
/* Mark that parent was modified */
if (H5HF__iblock_dirty(par_iblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDIRTY, FAIL, "can't mark heap header as dirty");
} /* end else */
} /* end if */
} /* end else */
/* At this point, write_buf points to a buffer containing the image
* of the direct block that is ready to copy into the image buffer,
* and write_size contains the length of this buffer.
*
* Also, if image size or address has changed, the direct block's
* parent has been modified to reflect the change.
*
* Now, make note of the pointer and length of the above buffer for
* use by the serialize function.
*/
dblock->write_buf = (uint8_t *)write_buf;
dblock->write_size = write_size;
/* finally, pass data back to the metadata cache as appropriate */
if (!H5_addr_eq(addr, dblock_addr)) {
dblock_flags |= H5AC__SERIALIZE_MOVED_FLAG;
*new_addr = dblock_addr;
} /* end if */
if ((hdr->filter_len > 0) && (len != write_size)) {
dblock_flags |= H5AC__SERIALIZE_RESIZED_FLAG;
*new_len = write_size;
} /* end if */
*flags = dblock_flags;
/* final sanity check */
assert(dblock->write_buf);
assert(dblock->write_size > 0);
done:
/* discard the write buf if we have an error */
if (write_buf && (write_buf != dblock->blk) && (dblock->write_buf == NULL))
H5MM_xfree(write_buf);
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_dblock_pre_serialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_serialize
*
* Purpose: In principle, this function is supposed to construct the on
* disk image of the direct block, and place that image in the
* image buffer provided by the metadata cache.
*
* However, since there are cases in which the pre_serialize
* function has to construct the on disk image to determine its size
* and address, this function simply copies the image prepared by
* the pre-serialize function into the supplied image buffer, and
* discards a buffer if necessary.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_serialize(const H5F_t H5_ATTR_NDEBUG_UNUSED *f, void *image,
size_t H5_ATTR_NDEBUG_UNUSED len, void *_thing)
{
H5HF_direct_t *dblock = (H5HF_direct_t *)_thing; /* Direct block info */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(f);
assert(image);
assert(len > 0);
assert(dblock);
assert(dblock->cache_info.type == H5AC_FHEAP_DBLOCK);
assert((dblock->blk != dblock->write_buf) || (dblock->cache_info.size == dblock->size));
assert(dblock->write_buf);
assert(dblock->write_size > 0);
assert((dblock->blk != dblock->write_buf) || (dblock->write_size == dblock->size));
assert(dblock->write_size == len);
/* Copy the image from *(dblock->write_buf) to *image */
H5MM_memcpy(image, dblock->write_buf, dblock->write_size);
/* Free *(dblock->write_buf) if it was allocated by the
* pre-serialize function
*/
if (dblock->write_buf != dblock->blk)
H5MM_xfree(dblock->write_buf);
/* Reset the write_buf and write_size fields */
dblock->write_buf = NULL;
dblock->write_size = 0;
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_dblock_serialize() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_notify
*
* Purpose: Setup / takedown flush dependencies as direct blocks
* are loaded / inserted and evicted from the metadata cache.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_notify(H5AC_notify_action_t action, void *_thing)
{
H5HF_direct_t *dblock = (H5HF_direct_t *)_thing; /* Fractal heap direct block */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(dblock);
assert(dblock->cache_info.type == H5AC_FHEAP_DBLOCK);
assert(dblock->hdr);
switch (action) {
case H5AC_NOTIFY_ACTION_AFTER_INSERT:
case H5AC_NOTIFY_ACTION_AFTER_LOAD:
/* Create flush dependency with parent, if there is one */
if (dblock->fd_parent)
if (H5AC_create_flush_dependency(dblock->fd_parent, dblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTDEPEND, FAIL, "unable to create flush dependency");
break;
case H5AC_NOTIFY_ACTION_AFTER_FLUSH:
case H5AC_NOTIFY_ACTION_ENTRY_DIRTIED:
case H5AC_NOTIFY_ACTION_ENTRY_CLEANED:
case H5AC_NOTIFY_ACTION_CHILD_DIRTIED:
case H5AC_NOTIFY_ACTION_CHILD_CLEANED:
case H5AC_NOTIFY_ACTION_CHILD_UNSERIALIZED:
case H5AC_NOTIFY_ACTION_CHILD_SERIALIZED:
/* do nothing */
break;
case H5AC_NOTIFY_ACTION_BEFORE_EVICT:
if (dblock->fd_parent) {
/* Destroy flush dependency with parent */
if (H5AC_destroy_flush_dependency(dblock->fd_parent, dblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTUNDEPEND, FAIL, "unable to destroy flush dependency");
dblock->fd_parent = NULL;
} /* end if */
break;
default:
HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "unknown action from metadata cache");
break;
} /* end switch */
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_dblock_notify() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_free_icr
*
* Purpose: Free the in core memory allocated to the supplied direct
* block.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_free_icr(void *_thing)
{
H5HF_direct_t *dblock = (H5HF_direct_t *)_thing; /* Fractal heap direct block */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(dblock);
assert(dblock->cache_info.type == H5AC_FHEAP_DBLOCK);
/* Destroy fractal heap direct block */
if (H5HF__man_dblock_dest(dblock) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTFREE, FAIL, "unable to destroy fractal heap direct block");
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5HF__cache_dblock_free_icr() */
/*-------------------------------------------------------------------------
* Function: H5HF__cache_dblock_fsf_size
*
* Purpose: Tell the metadata cache the actual amount of file space
* to free when a dblock entry is destroyed with the free
* file space flag set.
*
* Return: Success: SUCCEED
* Failure: FAIL
*
*-------------------------------------------------------------------------
*/
static herr_t
H5HF__cache_dblock_fsf_size(const void *_thing, hsize_t *fsf_size)
{
const H5HF_direct_t *dblock = (const H5HF_direct_t *)_thing; /* Fractal heap direct block */
FUNC_ENTER_PACKAGE_NOERR
/* Sanity checks */
assert(dblock);
assert(dblock->cache_info.type == H5AC_FHEAP_DBLOCK);
assert(dblock->file_size > 0);
assert(fsf_size);
/* Set free space in file size */
*fsf_size = dblock->file_size;
FUNC_LEAVE_NOAPI(SUCCEED)
} /* end H5HF__cache_dblock_fsf_size() */
/*------------------------------------------------------------------------
* Function: H5HF__cache_verify_hdr_descendants_clean
*
* Purpose: Sanity checking routine that verifies that all indirect
* and direct blocks that are descendants of the supplied
* instance of H5HF_hdr_t are clean. Set *clean to
* true if this is the case, and to false otherwise.
*
* Update -- 8/24/15
*
* With the advent of the metadata cache image feature, it is
* possible for the pre-serialize and serialize calls to be
* invoked outside of a flush. While this serialization
* observes flush dependencies for the order of serialization,
* the entries are not written to disk, and hence dirty entries
* remain dirty.
*
* To address this, updated the sanity checks in this function
* to treat entries whose images are up to date as clean if
* a cache serialization is in progress.
*
* Update -- 9/29/16
*
* The implementation of flush dependencies has been changed.
* Prior to this change, a flush dependency parent could be
* flushed if and only if all its flush dependency descendants
* were clean. In the new definition, a flush dependency
* parent can be flushed if all its immediate flush dependency
* children are clean, regardless of any other dirty
* descendants.
*
* Further, metadata cache entries are now allowed to have
* multiple flush dependency parents.
*
* This means that the fractal heap is no longer necessarily
* flushed from the bottom up.
*
* For example, it is now possible for a dirty fractal heap
* header to be flushed before a dirty dblock, as long as the
* there in an intervening iblock, and the header has no
* dirty immediate flush dependency children.
*
* Also, I gather that under some circumstances, a dblock
* will be direct a flush dependency child both of the iblock
* that points to it, and of the fractal heap header.
*
* As a result of these changes, the functionality of these
* sanity checking routines has been modified significantly.
* Instead of scanning the fractal heap from a starting point
* down, and verifying that there were no dirty entries, the
* functions now scan downward from the starting point and
* verify that there are no dirty flush dependency children
* of the specified flush dependency parent. In passing,
* they also walk the data structure, and verify it.
*
*
* Return: Non-negative on success/Negative on failure
*
*-------------------------------------------------------------------------
*/
#ifndef NDEBUG
static herr_t
H5HF__cache_verify_hdr_descendants_clean(H5F_t *f, H5HF_hdr_t *hdr, bool *fd_clean, bool *clean)
{
bool fd_exists = false; /* whether flush dependency exists. */
haddr_t hdr_addr; /* Address of header */
unsigned hdr_status = 0; /* Header cache entry status */
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(hdr);
assert(hdr->cache_info.type == H5AC_FHEAP_HDR);
assert(fd_clean);
assert(clean);
hdr_addr = hdr->cache_info.addr;
assert(hdr_addr == hdr->heap_addr);
if (H5AC_get_entry_status(f, hdr_addr, &hdr_status) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't get hdr status");
assert(hdr_status & H5AC_ES__IN_CACHE);
/* We have three basic scenarios we have to deal with:
*
* The first, and most common case, is that there is a root iblock.
* In this case we need to verify that the root iblock and all its
* children are clean.
*
* The second, and much less common case, is that in which the
* the fractal heap contains only one direct block, which is
* pointed to by hdr->man_dtable.table_addr. In this case, all we
* need to do is verify that the root direct block is clean.
*
* Finally, it is possible that the fractal heap is empty, and
* has neither a root indirect block nor a root direct block.
* In this case, we have nothing to do.
*/
/* There are two ways in which we can arrive at the first scenario.
*
* By far the most common is when hdr->root_iblock contains a pointer
* to the root iblock -- in this case the root iblock is almost certainly
* pinned, although we can't count on that.
*
* However, it is also possible that there is a root iblock that
* is no longer pointed to by the header. In this case, the on
* disk address of the iblock will be in hdr->man_dtable.table_addr
* and hdr->man_dtable.curr_root_rows will contain a positive value.
*
* Since the former case is far and away the most common, we don't
* worry too much about efficiency in the second case.
*/
if (hdr->root_iblock ||
((hdr->man_dtable.curr_root_rows > 0) && (HADDR_UNDEF != hdr->man_dtable.table_addr))) {
H5HF_indirect_t *root_iblock = hdr->root_iblock;
haddr_t root_iblock_addr;
unsigned root_iblock_status = 0;
bool root_iblock_in_cache;
/* make note of the on disk address of the root iblock */
if (root_iblock == NULL)
/* hdr->man_dtable.table_addr must contain address of root
* iblock. Check to see if it is in cache. If it is,
* protect it and put its address in root_iblock.
*/
root_iblock_addr = hdr->man_dtable.table_addr;
else
root_iblock_addr = root_iblock->addr;
/* get the status of the root iblock */
assert(root_iblock_addr != HADDR_UNDEF);
if (H5AC_get_entry_status(f, root_iblock_addr, &root_iblock_status) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't get root iblock status");
root_iblock_in_cache = ((root_iblock_status & H5AC_ES__IN_CACHE) != 0);
assert(root_iblock_in_cache || (root_iblock == NULL));
if (!root_iblock_in_cache) { /* we are done */
*clean = true;
*fd_clean = true;
} /* end if */
else if ((root_iblock_status & H5AC_ES__IS_DIRTY) &&
(((root_iblock_status & H5AC_ES__IMAGE_IS_UP_TO_DATE) == 0) ||
(!H5AC_get_serialization_in_progress(f)))) {
*clean = false;
/* verify that a flush dependency exists between the header and
* the root inode.
*/
if (H5AC_flush_dependency_exists(f, hdr->heap_addr, root_iblock_addr, &fd_exists) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check flush dependency");
assert(fd_exists);
*fd_clean = false;
} /* end else-if */
else { /* must examine children */
bool unprotect_root_iblock = false;
/* At this point, the root iblock may be pinned, protected,
* both, or neither, and we may or may not have a pointer
* to root iblock in memory.
*
* Before we call H5HF__cache_verify_iblock_descendants_clean(),
* we must ensure that the root iblock is either pinned or
* protected or both, and that we have a pointer to it.
* Do this as follows:
*/
if (root_iblock == NULL) { /* we don't have ptr to root iblock */
if (0 == (root_iblock_status & H5AC_ES__IS_PROTECTED)) {
/* just protect the root iblock -- this will give us
* the pointer we need to proceed, and ensure that
* it is locked into the metadata cache for the
* duration.
*
* Note that the udata is only used in the load callback.
* While the fractal heap makes heavy use of the udata
* in this case, since we know that the entry is in cache,
* we can pass NULL udata.
*
* The tag specified in the API context we received
* as a parameter (via API context) may not be correct.
* Grab the (hopefully) correct tag from the header,
* and load it into the API context via the H5_BEGIN_TAG and
* H5_END_TAG macros. Note that any error bracked by
* these macros must be reported with HGOTO_ERROR_TAG.
*/
H5_BEGIN_TAG(hdr->heap_addr)
if (NULL == (root_iblock = (H5HF_indirect_t *)H5AC_protect(
f, H5AC_FHEAP_IBLOCK, root_iblock_addr, NULL, H5AC__READ_ONLY_FLAG)))
HGOTO_ERROR_TAG(H5E_HEAP, H5E_CANTPROTECT, FAIL, "H5AC_protect() failed.");
H5_END_TAG
unprotect_root_iblock = true;
} /* end if */
else {
/* the root iblock is protected, and we have no
* legitimate way of getting a pointer to it.
*
* We square this circle by using the
* H5AC_get_entry_ptr_from_addr() to get the needed
* pointer.
*
* WARNING: This call should be used only in debugging
* routines, and it should be avoided there when
* possible.
*
* Further, if we ever multi-thread the cache,
* this routine will have to be either discarded
* or heavily re-worked.
*
* Finally, keep in mind that the entry whose
* pointer is obtained in this fashion may not
* be in a stable state.
*
* Assuming that the flush dependency code is working
* as it should, the only reason for the root iblock to
* be unpinned is if none of its children are in cache.
* This unfortunately means that if it is protected and
* not pinned, the fractal heap is in the process of loading
* or inserting one of its children. The obvious
* implication is that there is a significant chance that
* the root iblock is in an unstable state.
*
* All this suggests that using
* H5AC_get_entry_ptr_from_addr() to obtain the pointer
* to the protected root iblock is questionable here.
* However, since this is test/debugging code, I expect
* that we will use this approach until it causes problems,
* or we think of a better way.
*/
if (H5AC_get_entry_ptr_from_addr(f, root_iblock_addr, (void **)(&root_iblock)) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "H5AC_get_entry_ptr_from_addr() failed.");
assert(root_iblock);
} /* end else */
} /* end if */
else { /* root_iblock != NULL */
/* we have the pointer to the root iblock. Protect it
* if it is neither pinned nor protected -- otherwise we
* are ready to go.
*/
H5HF_indirect_t *iblock = NULL;
if (((root_iblock_status & H5AC_ES__IS_PINNED) == 0) &&
((root_iblock_status & H5AC_ES__IS_PROTECTED) == 0)) {
/* the root iblock is neither pinned nor protected -- hence
* we must protect it before we proceed
*
* Note that the udata is only used in the load callback.
* While the fractal heap makes heavy use of the udata
* in this case, since we know that the entry is in cache,
* we can pass NULL udata.
*
* The tag associated specified in the API context we received
* as a parameter (via API context) may not be correct.
* Grab the (hopefully) correct tag from the header,
* and load it into the API context via the H5_BEGIN_TAG and
* H5_END_TAG macros. Note that any error bracked by
* these macros must be reported with HGOTO_ERROR_TAG.
*/
H5_BEGIN_TAG(hdr->heap_addr)
if (NULL == (iblock = (H5HF_indirect_t *)H5AC_protect(
f, H5AC_FHEAP_IBLOCK, root_iblock_addr, NULL, H5AC__READ_ONLY_FLAG)))
HGOTO_ERROR_TAG(H5E_HEAP, H5E_CANTPROTECT, FAIL, "H5AC_protect() failed.");
H5_END_TAG
unprotect_root_iblock = true;
assert(iblock == root_iblock);
} /* end if */
} /* end else */
/* at this point, one way or another, the root iblock is locked
* in memory for the duration of the call. Do some sanity checks,
* and then call H5HF__cache_verify_iblock_descendants_clean().
*/
assert(root_iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
if (H5HF__cache_verify_iblock_descendants_clean(f, hdr->heap_addr, root_iblock,
&root_iblock_status, fd_clean, clean) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "can't verify root iblock & descendants clean.");
/* Unprotect the root indirect block if required */
if (unprotect_root_iblock) {
assert(root_iblock);
if (H5AC_unprotect(f, H5AC_FHEAP_IBLOCK, root_iblock_addr, root_iblock, H5AC__NO_FLAGS_SET) <
0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTUNPROTECT, FAIL, "H5AC_unprotect() failed.");
} /* end if */
} /* end else */
} /* end if */
else if ((hdr->man_dtable.curr_root_rows == 0) && (HADDR_UNDEF != hdr->man_dtable.table_addr)) {
haddr_t root_dblock_addr;
unsigned root_dblock_status = 0;
bool in_cache;
bool type_ok;
/* this is scenario 2 -- we have a root dblock */
root_dblock_addr = hdr->man_dtable.table_addr;
if (H5AC_get_entry_status(f, root_dblock_addr, &root_dblock_status) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't get root dblock status");
if (root_dblock_status & H5AC_ES__IN_CACHE) {
if (H5AC_verify_entry_type(f, root_dblock_addr, &H5AC_FHEAP_DBLOCK[0], &in_cache, &type_ok) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check dblock type");
assert(in_cache);
if (!type_ok)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "root dblock addr doesn't refer to a dblock?!?");
/* If a root dblock is in cache, it must have a flush
* dependency relationship with the header, and it
* may not be the parent in any flush dependency
* relationship.
*
* We don't test this fully, but we will verify that
* the root iblock is a child in a flush dependency
* relationship with the header.
*/
if (H5AC_flush_dependency_exists(f, hdr->heap_addr, root_dblock_addr, &fd_exists) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check flush dependency");
if (!fd_exists)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "root dblock is not a flush dep parent of header.");
if (0 != (root_dblock_status & H5AC_ES__IS_FLUSH_DEP_PARENT))
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "root dblock in cache and is a flush dep parent.");
*clean = !((root_dblock_status & H5AC_ES__IS_DIRTY) &&
(((root_dblock_status & H5AC_ES__IMAGE_IS_UP_TO_DATE) == 0) ||
(!H5AC_get_serialization_in_progress(f))));
*fd_clean = *clean;
} /* end if */
else { /* root dblock not in cache */
*fd_clean = true;
*clean = true;
} /* end else */
} /* end else-if */
else {
/* this is scenario 3 -- the fractal heap is empty, and we
* have nothing to do.
*/
*fd_clean = true;
*clean = true;
} /* end else */
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* H5HF__cache_verify_hdr_descendants_clean() */
#endif /* NDEBUG */
/*------------------------------------------------------------------------
* Function: H5HF__cache_verify_iblock_descendants_clean
*
* Purpose: Sanity checking routine that verifies that all indirect
* and direct blocks that are descendants of the supplied
* instance of H5HF_indirect_t are clean. Set *clean
* to true if this is the case, and to false otherwise.
*
* In passing, the function also does a cursory check to
* spot any obvious errors in the flush dependency setup.
* If any problems are found, the function returns failure.
* Note that these checks are not exhaustive, thus passing
* them does not mean that the flush dependencies are
* correct -- only that there is nothing obviously wrong
* with them.
*
* WARNING: At its top level call, this function is
* intended to be called from H5HF_cache_iblock_flush(),
* and thus presumes that the supplied indirect block
* is in cache. Any other use of this function and
* its descendants must insure that this assumption is
* met.
*
* Note that this function and
* H5HF__cache_verify_descendant_iblocks_clean() are
* recursive co-routines.
*
* Update -- 9/29/16
*
* The implementation of flush dependencies has been changed.
* Prior to this change, a flush dependency parent could be
* flushed if and only if all its flush dependency descendants
* were clean. In the new definition, a flush dependency
* parent can be flushed if all its immediate flush dependency
* children are clean, regardless of any other dirty
* descendants.
*
* Further, metadata cache entries are now allowed to have
* multiple flush dependency parents.
*
* This means that the fractal heap is no longer necessarily
* flushed from the bottom up.
*
* For example, it is now possible for a dirty fractal heap
* header to be flushed before a dirty dblock, as long as the
* there in an intervening iblock, and the header has no
* dirty immediate flush dependency children.
*
* Also, I gather that under some circumstances, a dblock
* will be direct a flush dependency child both of the iblock
* that points to it, and of the fractal heap header.
*
* As a result of these changes, the functionality of these
* sanity checking routines has been modified significantly.
* Instead of scanning the fractal heap from a starting point
* down, and verifying that there were no dirty entries, the
* functions now scan downward from the starting point and
* verify that there are no dirty flush dependency children
* of the specified flush dependency parent. In passing,
* they also walk the data structure, and verify it.
*
* Return: Non-negative on success/Negative on failure
*
*-------------------------------------------------------------------------
*/
#ifndef NDEBUG
static herr_t
H5HF__cache_verify_iblock_descendants_clean(H5F_t *f, haddr_t fd_parent_addr, H5HF_indirect_t *iblock,
unsigned *iblock_status, bool *fd_clean, bool *clean)
{
bool has_dblocks = false;
bool has_iblocks = false;
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(H5_addr_defined(fd_parent_addr));
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(iblock_status);
assert(fd_clean);
assert(*fd_clean);
assert(clean); /* note that *clean need not be true */
if ((*fd_clean) && H5HF__cache_verify_iblocks_dblocks_clean(f, fd_parent_addr, iblock, fd_clean, clean,
&has_dblocks) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "can't verify dblocks clean.");
if ((*fd_clean) && H5HF__cache_verify_descendant_iblocks_clean(f, fd_parent_addr, iblock, fd_clean, clean,
&has_iblocks) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "can't verify iblocks clean.");
/* verify that flush dependency setup is plausible */
if (0 == (*iblock_status & H5AC_ES__IS_FLUSH_DEP_CHILD))
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "iblock is not a flush dep child.");
if (((has_dblocks || has_iblocks)) && (0 == (*iblock_status & H5AC_ES__IS_FLUSH_DEP_PARENT)))
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "iblock has children and is not a flush dep parent.");
if (((has_dblocks || has_iblocks)) && (0 == (*iblock_status & H5AC_ES__IS_PINNED)))
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "iblock has children and is not pinned.");
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* H5HF__cache_verify_iblock_descendants_clean() */
#endif /* NDEBUG */
/*------------------------------------------------------------------------
* Function: H5HF__cache_verify_iblocks_dblocks_clean
*
* Purpose: Sanity checking routine that attempts to verify that all
* direct blocks pointed to by the supplied indirect block
* are either clean, or not in the cache.
*
* In passing, the function also does a cursory check to
* spot any obvious errors in the flush dependency setup.
* If any problems are found, the function returns failure.
* Note that these checks are not exhaustive, thus passing
* them does not mean that the flush dependencies are
* correct -- only that there is nothing obviously wrong
* with them.
*
* WARNING: This function presumes that the supplied
* iblock is in the cache, and will not be removed
* during the call. Caller must ensure that this is
* the case before the call.
*
* Update -- 8/24/15
*
* With the advent of the metadata cache image feature, it is
* possible for the pre-serialize and serialize calls to be
* invoked outside of a flush. While this serialization
* observes flush dependencies for the order of serialization,
* the entries are not written to disk, and hence dirty entries
* remain dirty.
*
* To address this, updated the sanity checks in this function
* to treat entries whose images are up to date as clean if
* a cache serialization is in progress.
*
* Update -- 9/29/16
*
* The implementation of flush dependencies has been changed.
* Prior to this change, a flush dependency parent could be
* flushed if and only if all its flush dependency descendants
* were clean. In the new definition, a flush dependency
* parent can be flushed if all its immediate flush dependency
* children are clean, regardless of any other dirty
* descendants.
*
* Further, metadata cache entries are now allowed to have
* multiple flush dependency parents.
*
* This means that the fractal heap is no longer necessarily
* flushed from the bottom up.
*
* For example, it is now possible for a dirty fractal heap
* header to be flushed before a dirty dblock, as long as the
* there in an intervening iblock, and the header has no
* dirty immediate flush dependency children.
*
* Also, I gather that under some circumstances, a dblock
* will be direct a flush dependency child both of the iblock
* that points to it, and of the fractal heap header.
*
* As a result of these changes, the functionality of these
* sanity checking routines has been modified significantly.
* Instead of scanning the fractal heap from a starting point
* down, and verifying that there were no dirty entries, the
* functions now scan downward from the starting point and
* verify that there are no dirty flush dependency children
* of the specified flush dependency parent. In passing,
* they also walk the data structure, and verify it.
*
* Return: Non-negative on success/Negative on failure
*
*-------------------------------------------------------------------------
*/
#ifndef NDEBUG
static herr_t
H5HF__cache_verify_iblocks_dblocks_clean(H5F_t *f, haddr_t fd_parent_addr, H5HF_indirect_t *iblock,
bool *fd_clean, bool *clean, bool *has_dblocks)
{
unsigned num_direct_rows;
unsigned max_dblock_index;
unsigned i;
haddr_t iblock_addr;
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(H5_addr_defined(fd_parent_addr));
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(fd_clean);
assert(*fd_clean);
assert(clean); /* note that *clean need not be true */
assert(has_dblocks);
i = 0;
num_direct_rows = MIN(iblock->nrows, iblock->hdr->man_dtable.max_direct_rows);
assert(num_direct_rows <= iblock->nrows);
max_dblock_index = (num_direct_rows * iblock->hdr->man_dtable.cparam.width) - 1;
iblock_addr = iblock->addr;
assert(H5_addr_defined(iblock_addr));
while ((*fd_clean) && (i <= max_dblock_index)) {
haddr_t dblock_addr;
dblock_addr = iblock->ents[i].addr;
if (H5_addr_defined(dblock_addr)) {
bool in_cache;
bool type_ok;
if (H5AC_verify_entry_type(f, dblock_addr, &H5AC_FHEAP_DBLOCK[0], &in_cache, &type_ok) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check dblock type");
if (in_cache) { /* dblock is in cache */
bool fd_exists;
unsigned dblock_status = 0;
if (!type_ok)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "dblock addr doesn't refer to a dblock?!?");
if (H5AC_get_entry_status(f, dblock_addr, &dblock_status) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't get dblock status");
assert(dblock_status & H5AC_ES__IN_CACHE);
*has_dblocks = true;
if ((dblock_status & H5AC_ES__IS_DIRTY) &&
(((dblock_status & H5AC_ES__IMAGE_IS_UP_TO_DATE) == 0) ||
(!H5AC_get_serialization_in_progress(f)))) {
*clean = false;
if (H5AC_flush_dependency_exists(f, fd_parent_addr, dblock_addr, &fd_exists) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check flush dependency");
if (fd_exists)
*fd_clean = false;
} /* end if */
/* If a child dblock is in cache, it must have a flush
* dependency relationship with this iblock. Test this
* here.
*/
if (H5AC_flush_dependency_exists(f, iblock_addr, dblock_addr, &fd_exists) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check flush dependency");
if (!fd_exists)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL,
"dblock in cache and not a flush dep child of iblock.");
} /* end if */
} /* end if */
i++;
} /* end while */
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* H5HF__cache_verify_iblocks_dblocks_clean() */
#endif /* NDEBUG */
/*------------------------------------------------------------------------
* Function: H5HF__cache_verify_descendant_iblocks_clean
*
* Purpose: Sanity checking routine that attempts to verify that all
* direct blocks pointed to by the supplied indirect block
* are either clean, or not in the cache.
*
* In passing, the function also does a cursory check to
* spot any obvious errors in the flush dependency setup.
* If any problems are found, the function returns failure.
* Note that these checks are not exhaustive, thus passing
* them does not mean that the flush dependencies are
* correct -- only that there is nothing obviously wrong
* with them.
*
* WARNING: This function presumes that the supplied
* iblock is in the cache, and will not be removed
* during the call. Caller must ensure that this is
* the case before the call.
*
* Update -- 8/24/15
*
* With the advent of the metadata cache image feature, it is
* possible for the pre-serialize and serialize calls to be
* invoked outside of a flush. While this serialization
* observes flush dependencies for the order of serialization,
* the entries are not written to disk, and hence dirty entries
* remain dirty.
*
* To address this, updated the sanity checks in this function
* to treat entries whose images are up to date as clean if
* a cache serialization is in progress.
*
* Update -- 9/29/16
*
* The implementation of flush dependencies has been changed.
* Prior to this change, a flush dependency parent could be
* flushed if and only if all its flush dependency descendants
* were clean. In the new definition, a flush dependency
* parent can be flushed if all its immediate flush dependency
* children are clean, regardless of any other dirty
* descendants.
*
* Further, metadata cache entries are now allowed to have
* multiple flush dependency parents.
*
* This means that the fractal heap is no longer necessarily
* flushed from the bottom up.
*
* For example, it is now possible for a dirty fractal heap
* header to be flushed before a dirty dblock, as long as the
* there in an intervening iblock, and the header has no
* dirty immediate flush dependency children.
*
* Also, I gather that under some circumstances, a dblock
* will be direct a flush dependency child both of the iblock
* that points to it, and of the fractal heap header.
*
* As a result of these changes, the functionality of these
* sanity checking routines has been modified significantly.
* Instead of scanning the fractal heap from a starting point
* down, and verifying that there were no dirty entries, the
* functions now scan downward from the starting point and
* verify that there are no dirty flush dependency children
* of the specified flush dependency parent. In passing,
* they also walk the data structure, and verify it.
*
*
* Return: Non-negative on success/Negative on failure
*
*-------------------------------------------------------------------------
*/
#ifndef NDEBUG
static herr_t
H5HF__cache_verify_descendant_iblocks_clean(H5F_t *f, haddr_t fd_parent_addr, H5HF_indirect_t *iblock,
bool *fd_clean, bool *clean, bool *has_iblocks)
{
unsigned first_iblock_index;
unsigned last_iblock_index;
unsigned num_direct_rows;
unsigned i;
haddr_t iblock_addr;
herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_PACKAGE
/* Sanity checks */
assert(f);
assert(H5_addr_defined(fd_parent_addr));
assert(iblock);
assert(iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(fd_clean);
assert(*fd_clean);
assert(clean); /* note that *clean need not be true */
assert(has_iblocks);
num_direct_rows = MIN(iblock->nrows, iblock->hdr->man_dtable.max_direct_rows);
assert(num_direct_rows <= iblock->nrows);
iblock_addr = iblock->addr;
first_iblock_index = num_direct_rows * iblock->hdr->man_dtable.cparam.width;
last_iblock_index = (iblock->nrows * iblock->hdr->man_dtable.cparam.width) - 1;
i = first_iblock_index;
while ((*fd_clean) && (i <= last_iblock_index)) {
haddr_t child_iblock_addr = iblock->ents[i].addr;
if (H5_addr_defined(child_iblock_addr)) {
unsigned child_iblock_status = 0;
if (H5AC_get_entry_status(f, child_iblock_addr, &child_iblock_status) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't get iblock status");
if (child_iblock_status & H5AC_ES__IN_CACHE) {
bool fd_exists;
*has_iblocks = true;
if ((child_iblock_status & H5AC_ES__IS_DIRTY) &&
(((child_iblock_status & H5AC_ES__IMAGE_IS_UP_TO_DATE) == 0) ||
(!H5AC_get_serialization_in_progress(f)))) {
*clean = false;
if (H5AC_flush_dependency_exists(f, fd_parent_addr, child_iblock_addr, &fd_exists) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check flush dependency");
if (fd_exists)
*fd_clean = false;
} /* end if */
/* if the child iblock is in cache and *fd_clean is true,
* we must continue to explore down the fractal heap tree
* structure to verify that all descendant blocks that are
* flush dependency children of the entry at parent_addr are
* either clean, or not in the metadata cache. We do this
* with a recursive call to
* H5HF__cache_verify_iblock_descendants_clean().
* However, we can't make this call unless the child iblock
* is somehow locked into the cache -- typically via either
* pinning or protecting.
*
* If the child iblock is pinned, we can look up its pointer
* on the current iblock's pinned child iblock list, and
* and use that pointer in the recursive call.
*
* If the entry is unprotected and unpinned, we simply
* protect it.
*
* If, however, the child iblock is already protected,
* but not pinned, we have a bit of a problem, as we have
* no legitimate way of looking up its pointer in memory.
*
* To solve this problem, I have added a new metadata cache
* call to obtain the pointer.
*
* WARNING: This call should be used only in debugging
* routines, and it should be avoided there when
* possible.
*
* Further, if we ever multi-thread the cache,
* this routine will have to be either discarded
* or heavily re-worked.
*
* Finally, keep in mind that the entry whose
* pointer is obtained in this fashion may not
* be in a stable state.
*
* Assuming that the flush dependency code is working
* as it should, the only reason for the child entry to
* be unpinned is if none of its children are in cache.
* This unfortunately means that if it is protected and
* not pinned, the fractal heap is in the process of loading
* or inserting one of its children. The obvious implication
* is that there is a significant chance that the child
* iblock is in an unstable state.
*
* All this suggests that using the new call to obtain the
* pointer to the protected child iblock is questionable
* here. However, since this is test/debugging code, I
* expect that we will use this approach until it causes
* problems, or we think of a better way.
*/
if (*fd_clean) {
H5HF_indirect_t *child_iblock = NULL;
bool unprotect_child_iblock = false;
if (0 == (child_iblock_status & H5AC_ES__IS_PINNED)) {
/* child iblock is not pinned */
if (0 == (child_iblock_status & H5AC_ES__IS_PROTECTED)) {
/* child iblock is unprotected, and unpinned */
/* protect it. Note that the udata is only */
/* used in the load callback. While the */
/* fractal heap makes heavy use of the udata */
/* in this case, since we know that the */
/* entry is in cache, we can pass NULL udata */
/* */
/* The tag associated specified in the API context */
/* we received as a parameter (via API context) */
/* may not be correct. */
/* */
/* Grab the (hopefully) correct tag from the */
/* parent iblock, and load it into the API context */
/* via the H5_BEGIN_TAG and H5_END_TAG */
/* macros. Note that any error bracked by */
/* these macros must be reported with */
/* HGOTO_ERROR_TAG. */
H5_BEGIN_TAG(iblock->hdr->heap_addr)
if (NULL ==
(child_iblock = (H5HF_indirect_t *)H5AC_protect(
f, H5AC_FHEAP_IBLOCK, child_iblock_addr, NULL, H5AC__READ_ONLY_FLAG)))
HGOTO_ERROR_TAG(H5E_HEAP, H5E_CANTPROTECT, FAIL, "H5AC_protect() failed.");
H5_END_TAG
unprotect_child_iblock = true;
} /* end if */
else {
/* child iblock is protected -- use */
/* H5AC_get_entry_ptr_from_addr() to get a */
/* pointer to the entry. This is very slimy -- */
/* come up with a better solution. */
if (H5AC_get_entry_ptr_from_addr(f, child_iblock_addr, (void **)(&child_iblock)) <
0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL,
"H5AC_get_entry_ptr_from_addr() failed.");
assert(child_iblock);
} /* end else */
} /* end if */
else {
/* child iblock is pinned -- look it up in the */
/* parent iblocks child_iblocks array. */
assert(iblock->child_iblocks);
child_iblock = iblock->child_iblocks[i - first_iblock_index];
} /* end else */
/* At this point, one way or another we should have
* a pointer to the child iblock. Verify that we
* that we have the correct one.
*/
assert(child_iblock);
assert(child_iblock->cache_info.type == H5AC_FHEAP_IBLOCK);
assert(child_iblock->addr == child_iblock_addr);
/* now make the recursive call */
if (H5HF__cache_verify_iblock_descendants_clean(
f, fd_parent_addr, child_iblock, &child_iblock_status, fd_clean, clean) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL, "can't verify child iblock clean.");
/* if iblock_addr != fd_parent_addr, verify that a flush
* dependency relationship exists between iblock and
* the child iblock.
*/
if (fd_parent_addr != iblock_addr) {
if (H5AC_flush_dependency_exists(f, iblock_addr, child_iblock_addr, &fd_exists) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTGET, FAIL, "can't check flush dependency");
if (!fd_exists)
HGOTO_ERROR(H5E_HEAP, H5E_SYSTEM, FAIL,
"iblock is not a flush dep parent of child_iblock.");
} /* end if */
/* if we protected the child iblock, unprotect it now */
if (unprotect_child_iblock) {
if (H5AC_unprotect(f, H5AC_FHEAP_IBLOCK, child_iblock_addr, child_iblock,
H5AC__NO_FLAGS_SET) < 0)
HGOTO_ERROR(H5E_HEAP, H5E_CANTUNPROTECT, FAIL, "H5AC_unprotect() failed.");
} /* end if */
} /* end if */
} /* end if */
} /* end if */
i++;
} /* end while */
done:
FUNC_LEAVE_NOAPI(ret_value)
} /* H5HF__cache_verify_descendant_iblocks_clean() */
#endif /* NDEBUG */
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