summaryrefslogtreecommitdiffstats
path: root/src/H5Shyper.c
diff options
context:
space:
mode:
Diffstat (limited to 'src/H5Shyper.c')
-rw-r--r--src/H5Shyper.c4304
1 files changed, 1586 insertions, 2718 deletions
diff --git a/src/H5Shyper.c b/src/H5Shyper.c
index ed3fa45..c9fab38 100644
--- a/src/H5Shyper.c
+++ b/src/H5Shyper.c
@@ -18,21 +18,37 @@
* Purpose: Hyperslab selection dataspace I/O functions.
*/
+/****************/
+/* Module Setup */
+/****************/
+
#include "H5Smodule.h" /* This source code file is part of the H5S module */
+/***********/
+/* Headers */
+/***********/
#include "H5private.h" /* Generic Functions */
#include "H5Eprivate.h" /* Error handling */
#include "H5FLprivate.h" /* Free Lists */
#include "H5Iprivate.h" /* ID Functions */
#include "H5Spkg.h" /* Dataspace functions */
-#include "H5VMprivate.h" /* Vector functions */
+#include "H5VMprivate.h" /* Vector functions */
+
+/****************/
/* Local Macros */
+/****************/
+
+
+/******************/
+/* Local Typedefs */
+/******************/
-/* Local datatypes */
-/* Static function prototypes */
+/********************/
+/* Local Prototypes */
+/********************/
static H5S_hyper_span_t *H5S__hyper_new_span(hsize_t low, hsize_t high,
H5S_hyper_span_info_t *down, H5S_hyper_span_t *next);
static herr_t H5S__hyper_span_precompute(H5S_hyper_span_info_t *spans, size_t elmt_size);
@@ -64,10 +80,6 @@ static herr_t H5S__hyper_generate_spans(H5S_t *space);
static herr_t H5S__generate_hyperslab(H5S_t *space, H5S_seloper_t op,
const hsize_t start[], const hsize_t stride[], const hsize_t count[],
const hsize_t block[]);
-/* Needed for use in hyperslab code (H5Shyper.c) */
-#ifdef NEW_HYPERSLAB_API
-static herr_t H5S_select_select (H5S_t *space1, H5S_seloper_t op, H5S_t *space2);
-#endif /*NEW_HYPERSLAB_API*/
static void H5S__hyper_get_clip_diminfo(hsize_t start, hsize_t stride,
hsize_t *count, hsize_t *block, hsize_t clip_size);
static hsize_t H5S__hyper_get_clip_extent_real(const H5S_t *clip_space,
@@ -111,6 +123,15 @@ static hbool_t H5S__hyper_rebuild_helper(const H5S_hyper_span_t *span,
H5S_hyper_dim_t span_slab_info[], unsigned rank);
static hbool_t H5S__hyper_rebuild(H5S_t *space);
+/*****************************/
+/* Library Private Variables */
+/*****************************/
+
+
+/*********************/
+/* Package Variables */
+/*********************/
+
/* Selection properties for hyperslab selections */
const H5S_select_class_t H5S_sel_hyper[1] = {{
H5S_SEL_HYPERSLABS,
@@ -136,6 +157,11 @@ const H5S_select_class_t H5S_sel_hyper[1] = {{
H5S__hyper_iter_init,
}};
+
+/*******************/
+/* Local Variables */
+/*******************/
+
/* Iteration properties for hyperslab selections */
static const H5S_sel_iter_class_t H5S_sel_iter_hyper[1] = {{
H5S_SEL_HYPERSLABS,
@@ -153,16 +179,16 @@ static const H5S_sel_iter_class_t H5S_sel_iter_hyper[1] = {{
/* Static variables */
/* Arrays for default stride, block, etc. */
-static const hsize_t H5S_hyper_zeros_g[H5O_LAYOUT_NDIMS] = {
+static const hsize_t H5S_hyper_zeros_g[H5S_MAX_RANK] = {
0,0,0,0, 0,0,0,0,
0,0,0,0, 0,0,0,0,
0,0,0,0, 0,0,0,0,
- 0,0,0,0, 0,0,0,0,0};
-static const hsize_t H5S_hyper_ones_g[H5O_LAYOUT_NDIMS] = {
+ 0,0,0,0, 0,0,0,0};
+static const hsize_t H5S_hyper_ones_g[H5S_MAX_RANK] = {
1,1,1,1, 1,1,1,1,
1,1,1,1, 1,1,1,1,
1,1,1,1, 1,1,1,1,
- 1,1,1,1, 1,1,1,1,1};
+ 1,1,1,1, 1,1,1,1};
/* Declare a free list to manage the H5S_hyper_sel_t struct */
H5FL_DEFINE_STATIC(H5S_hyper_sel_t);
@@ -261,9 +287,9 @@ H5S__hyper_print_diminfo(FILE *f, const H5S_t *space)
/*-------------------------------------------------------------------------
* Function: H5S__hyper_iter_init
*
- * Purpose: Initializes iteration information for hyperslab span tree selection.
+ * Purpose: Initializes iteration information for hyperslab selection.
*
- * Return: non-negative on success, negative on failure.
+ * Return: Non-negative on success, negative on failure.
*
* Programmer: Quincey Koziol
* Saturday, February 24, 2001
@@ -278,11 +304,8 @@ H5S__hyper_print_diminfo(FILE *f, const H5S_t *space)
static herr_t
H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
{
- const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
- H5S_hyper_span_info_t *spans; /* Pointer to hyperslab span info node */
unsigned rank; /* Dataspace's dimension rank */
unsigned u; /* Index variable */
- int i; /* Index variable */
FUNC_ENTER_STATIC_NOERR
@@ -298,16 +321,16 @@ H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
/* Get the rank of the dataspace */
rank = space->extent.rank;
- /* Set the temporary pointer to the dimension information */
- tdiminfo = space->select.sel_info.hslab->opt_diminfo;
-
/* Check for the special case of just one H5Sselect_hyperslab call made */
if(space->select.sel_info.hslab->diminfo_valid) {
/* Initialize the information needed for regular hyperslab I/O */
+ const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
const hsize_t *mem_size; /* Temporary pointer to dataspace extent's dimension sizes */
- hsize_t acc; /* Accumulator for "flattened" dimension's sizes */
unsigned cont_dim = 0; /* # of contiguous dimensions */
+ /* Set the temporary pointer to the dimension information */
+ tdiminfo = space->select.sel_info.hslab->opt_diminfo;
+
/* Set the temporary pointer to the dataspace extent's dimension sizes */
mem_size = space->extent.size;
@@ -336,9 +359,11 @@ H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
/* Check if the regular selection can be "flattened" */
if(cont_dim > 0) {
- unsigned last_dim_flattened = 1; /* Flag to indicate that the last dimension was flattened */
+ hsize_t acc; /* Accumulator for "flattened" dimension's sizes */
+ hbool_t last_dim_flattened = TRUE; /* Flag to indicate that the last dimension was flattened */
unsigned flat_rank = rank-cont_dim; /* Number of dimensions after flattening */
unsigned curr_dim; /* Current dimension */
+ int i; /* Index variable */
/* Set the iterator's rank to the contiguous dimensions */
iter->u.hyp.iter_rank = flat_rank;
@@ -352,7 +377,7 @@ H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
acc *= mem_size[i];
/* Indicate that the dimension was flattened */
- last_dim_flattened = 1;
+ last_dim_flattened = TRUE;
} /* end if */
else {
if(last_dim_flattened) {
@@ -370,7 +395,7 @@ H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
iter->u.hyp.sel_off[curr_dim] = space->select.offset[i] * (hssize_t)acc;
/* Reset the "last dim flattened" flag to avoid flattened any further dimensions */
- last_dim_flattened = 0;
+ last_dim_flattened = FALSE;
/* Reset the "accumulator" for possible further dimension flattening */
acc = 1;
@@ -415,8 +440,9 @@ H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
/* Initialize irregular region information also (for release) */
iter->u.hyp.spans = NULL;
} /* end if */
- else {
-/* Initialize the information needed for non-regular hyperslab I/O */
+ else { /* Initialize the information needed for non-regular hyperslab I/O */
+ H5S_hyper_span_info_t *spans; /* Pointer to hyperslab span info node */
+
HDassert(space->select.sel_info.hslab->span_lst);
/* Make a copy of the span tree to iterate over */
iter->u.hyp.spans = H5S__hyper_copy_span(space->select.sel_info.hslab->span_lst);
@@ -458,7 +484,7 @@ H5S__hyper_iter_init(H5S_sel_iter_t *iter, const H5S_t *space)
* Purpose: Retrieve the current coordinates of iterator for current
* selection
*
- * Return: non-negative on success, negative on failure
+ * Return: Non-negative on success, negative on failure
*
* Programmer: Quincey Koziol
* Tuesday, April 22, 2003
@@ -543,7 +569,7 @@ H5S__hyper_iter_coords(const H5S_sel_iter_t *iter, hsize_t *coords)
* Purpose: Retrieve the current block of iterator for current
* selection
*
- * Return: non-negative on success, negative on failure
+ * Return: Non-negative on success, negative on failure
*
* Programmer: Quincey Koziol
* Monday, June 2, 2003
@@ -569,7 +595,7 @@ H5S__hyper_iter_block(const H5S_sel_iter_t *iter, hsize_t *start, hsize_t *end)
/* Check for a single "regular" hyperslab */
if(iter->u.hyp.diminfo_valid) {
- /* Compute the end of the block */
+ /* Copy the start and compute the end of the block */
for(u = 0; u < iter->rank; u++) {
start[u] = iter->u.hyp.off[u];
end[u] = (start[u] + iter->u.hyp.diminfo[u].block) - 1;
@@ -594,7 +620,7 @@ H5S__hyper_iter_block(const H5S_sel_iter_t *iter, hsize_t *start, hsize_t *end)
*
* Purpose: Return number of elements left to process in iterator
*
- * Return: non-negative number of elements on success, zero on failure
+ * Return: Non-negative number of elements on success, zero on failure
*
* Programmer: Quincey Koziol
* Tuesday, June 16, 1998
@@ -630,7 +656,7 @@ H5S__hyper_iter_nelmts(const H5S_sel_iter_t *iter)
EXAMPLES
REVISION LOG
--------------------------------------------------------------------------*/
-static htri_t
+static H5_ATTR_PURE htri_t
H5S__hyper_iter_has_next_block(const H5S_sel_iter_t *iter)
{
unsigned u; /* Local index variable */
@@ -688,7 +714,7 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
{
unsigned ndims; /* Number of dimensions of dataset */
int fast_dim; /* Rank of the fastest changing dimension for the dataspace */
- unsigned i; /* Counters */
+ unsigned u; /* Counters */
FUNC_ENTER_STATIC_NOERR
@@ -696,19 +722,17 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
/* (i.e. a regular hyperslab selection */
if(iter->u.hyp.diminfo_valid) {
const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
- hsize_t iter_offset[H5O_LAYOUT_NDIMS];
- hsize_t iter_count[H5O_LAYOUT_NDIMS];
+ hsize_t iter_offset[H5S_MAX_RANK];
+ hsize_t iter_count[H5S_MAX_RANK];
int temp_dim; /* Temporary rank holder */
/* Check if this is a "flattened" regular hyperslab selection */
- if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < iter->rank) {
+ if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < iter->rank)
/* Set the aliases for the dimension rank */
ndims = iter->u.hyp.iter_rank;
- } /* end if */
- else {
+ else
/* Set the aliases for the dimension rank */
ndims = iter->rank;
- } /* end else */
/* Set the fastest dimension rank */
fast_dim = (int)ndims - 1;
@@ -717,14 +741,14 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
tdiminfo = iter->u.hyp.diminfo;
/* Calculate the offset and block count for each dimension */
- for(i = 0; i < ndims; i++) {
- if(tdiminfo[i].count == 1) {
- iter_offset[i] = iter->u.hyp.off[i] - tdiminfo[i].start;
- iter_count[i] = 0;
+ for(u = 0; u < ndims; u++) {
+ if(tdiminfo[u].count == 1) {
+ iter_offset[u] = iter->u.hyp.off[u] - tdiminfo[u].start;
+ iter_count[u] = 0;
} /* end if */
else {
- iter_offset[i] = (iter->u.hyp.off[i] - tdiminfo[i].start) % tdiminfo[i].stride;
- iter_count[i] = (iter->u.hyp.off[i] - tdiminfo[i].start) / tdiminfo[i].stride;
+ iter_offset[u] = (iter->u.hyp.off[u] - tdiminfo[u].start) % tdiminfo[u].stride;
+ iter_count[u] = (iter->u.hyp.off[u] - tdiminfo[u].start) / tdiminfo[u].stride;
} /* end else */
} /* end for */
@@ -749,10 +773,9 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
/* Decrement the number of elements advanced */
nelem -= actual_elem;
} /* end if */
- else {
+ else
/* Move to the next row in the current dimension */
iter_offset[temp_dim]++;
- } /* end else */
/* If this block is still in the range of blocks to output for the dimension, break out of loop */
if(iter_offset[temp_dim] < tdiminfo[temp_dim].block)
@@ -775,8 +798,8 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
} /* end while */
/* Translate current iter_offset and iter_count into iterator position */
- for(i = 0; i < ndims; i++)
- iter->u.hyp.off[i] = tdiminfo[i].start + (tdiminfo[i].stride * iter_count[i]) + iter_offset[i];
+ for(u = 0; u < ndims; u++)
+ iter->u.hyp.off[u] = tdiminfo[u].start + (tdiminfo[u].stride * iter_count[u]) + iter_offset[u];
} /* end if */
/* Must be an irregular hyperslab selection */
else {
@@ -820,15 +843,13 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
/* Decrement the number of elements advanced */
nelem -= actual_elem;
} /* end if */
- else {
+ else
/* Move to the next row in the current dimension */
abs_arr[curr_dim]++;
- } /* end else */
/* Check if we are still within the span */
- if(abs_arr[curr_dim] <= curr_span->high) {
+ if(abs_arr[curr_dim] <= curr_span->high)
break;
- } /* end if */
/* If we walked off that span, advance to the next span */
else {
/* Advance span in this dimension */
@@ -844,10 +865,9 @@ H5S__hyper_iter_next(H5S_sel_iter_t *iter, size_t nelem)
break;
} /* end if */
- else {
+ else
/* If we finished the span list in this dimension, decrement the dimension worked on and loop again */
curr_dim--;
- } /* end else */
} /* end else */
} /* end while */
@@ -906,22 +926,20 @@ H5S__hyper_iter_next_block(H5S_sel_iter_t *iter)
FUNC_ENTER_STATIC_NOERR
/* Check for the special case of just one H5Sselect_hyperslab call made */
- /* (i.e. a regular hyperslab selection */
+ /* (i.e. a regular hyperslab selection) */
if(iter->u.hyp.diminfo_valid) {
const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
- hsize_t iter_offset[H5O_LAYOUT_NDIMS];
- hsize_t iter_count[H5O_LAYOUT_NDIMS];
+ hsize_t iter_offset[H5S_MAX_RANK];
+ hsize_t iter_count[H5S_MAX_RANK];
int temp_dim; /* Temporary rank holder */
/* Check if this is a "flattened" regular hyperslab selection */
- if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < iter->rank) {
+ if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < iter->rank)
/* Set the aliases for the dimension rank */
ndims = iter->u.hyp.iter_rank;
- } /* end if */
- else {
+ else
/* Set the aliases for the dimension rank */
ndims = iter->rank;
- } /* end else */
/* Set the fastest dimension rank */
fast_dim = (int)ndims - 1;
@@ -944,14 +962,12 @@ H5S__hyper_iter_next_block(H5S_sel_iter_t *iter)
/* Advance one block */
temp_dim = fast_dim; /* Start with the fastest changing dimension */
while(temp_dim >= 0) {
- if(temp_dim == fast_dim) {
+ if(temp_dim == fast_dim)
/* Move iterator over current block */
iter_offset[temp_dim] += tdiminfo[temp_dim].block;
- } /* end if */
- else {
+ else
/* Move to the next row in the current dimension */
iter_offset[temp_dim]++;
- } /* end else */
/* If this block is still in the range of blocks to output for the dimension, break out of loop */
if(iter_offset[temp_dim] < tdiminfo[temp_dim].block)
@@ -1000,19 +1016,16 @@ H5S__hyper_iter_next_block(H5S_sel_iter_t *iter)
curr_span = ispan[curr_dim];
/* Increment absolute position */
- if(curr_dim == fast_dim) {
+ if(curr_dim == fast_dim)
/* Move the iterator over rest of element in span */
abs_arr[curr_dim] = curr_span->high + 1;
- } /* end if */
- else {
+ else
/* Move to the next row in the current dimension */
abs_arr[curr_dim]++;
- } /* end else */
/* Check if we are still within the span */
- if(abs_arr[curr_dim] <= curr_span->high) {
+ if(abs_arr[curr_dim] <= curr_span->high)
break;
- } /* end if */
/* If we walked off that span, advance to the next span */
else {
/* Advance span in this dimension */
@@ -1028,10 +1041,9 @@ H5S__hyper_iter_next_block(H5S_sel_iter_t *iter)
break;
} /* end if */
- else {
+ else
/* If we finished the span list in this dimension, decrement the dimension worked on and loop again */
curr_dim--;
- } /* end else */
} /* end else */
} /* end while */
@@ -1062,7 +1074,1333 @@ H5S__hyper_iter_next_block(H5S_sel_iter_t *iter)
} /* end else */
FUNC_LEAVE_NOAPI(SUCCEED)
-} /* end H5S__hyper_iter_next() */
+} /* end H5S__hyper_iter_next_block() */
+
+
+/*--------------------------------------------------------------------------
+ NAME
+ H5S__hyper_get_seq_list_gen
+ PURPOSE
+ Create a list of offsets & lengths for a selection
+ USAGE
+ herr_t H5S_select_hyper_get_file_list_gen(space,iter,maxseq,maxelem,nseq,nelem,off,len)
+ H5S_t *space; IN: Dataspace containing selection to use.
+ H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
+ position of interest in selection.
+ size_t maxseq; IN: Maximum number of sequences to generate
+ size_t maxelem; IN: Maximum number of elements to include in the
+ generated sequences
+ size_t *nseq; OUT: Actual number of sequences generated
+ size_t *nelem; OUT: Actual number of elements in sequences generated
+ hsize_t *off; OUT: Array of offsets
+ size_t *len; OUT: Array of lengths
+ RETURNS
+ Non-negative on success/Negative on failure.
+ DESCRIPTION
+ Use the selection in the dataspace to generate a list of byte offsets and
+ lengths for the region(s) selected. Start/Restart from the position in the
+ ITER parameter. The number of sequences generated is limited by the MAXSEQ
+ parameter and the number of sequences actually generated is stored in the
+ NSEQ parameter.
+ GLOBAL VARIABLES
+ COMMENTS, BUGS, ASSUMPTIONS
+ EXAMPLES
+ REVISION LOG
+--------------------------------------------------------------------------*/
+static herr_t
+H5S__hyper_get_seq_list_gen(const H5S_t *space, H5S_sel_iter_t *iter,
+ size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
+ hsize_t *off, size_t *len)
+{
+ H5S_hyper_span_t *curr_span; /* Current hyperslab span node */
+ H5S_hyper_span_t **ispan; /* Iterator's hyperslab span nodes */
+ hsize_t slab[H5S_MAX_RANK]; /* Cumulative size of each dimension in bytes */
+ hsize_t acc; /* Accumulator for computing cumulative sizes */
+ hsize_t loc_off; /* Element offset in the dataspace */
+ hsize_t last_span_end = 0; /* The offset of the end of the last span */
+ hsize_t *abs_arr; /* Absolute hyperslab span position */
+ const hssize_t *off_arr; /* Offset within the dataspace extent */
+ size_t span_size = 0; /* Number of bytes in current span to actually process */
+ size_t io_left; /* Number of elements left to process */
+ size_t io_bytes_left; /* Number of bytes left to process */
+ size_t io_used; /* Number of elements processed */
+ size_t curr_seq = 0; /* Number of sequence/offsets stored in the arrays */
+ size_t elem_size; /* Size of each element iterating over */
+ unsigned ndims; /* Number of dimensions of dataset */
+ unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
+ int curr_dim; /* Current dimension being operated on */
+ unsigned u; /* Index variable */
+ int i; /* Index variable */
+
+ FUNC_ENTER_STATIC_NOERR
+
+ /* Check args */
+ HDassert(space);
+ HDassert(iter);
+ HDassert(maxseq > 0);
+ HDassert(maxelem > 0);
+ HDassert(nseq);
+ HDassert(nelem);
+ HDassert(off);
+ HDassert(len);
+
+ /* Set the rank of the fastest changing dimension */
+ ndims = space->extent.rank;
+ fast_dim = (ndims - 1);
+
+ /* Get the pointers to the current span info and span nodes */
+ curr_span = iter->u.hyp.span[fast_dim];
+ abs_arr = iter->u.hyp.off;
+ off_arr = space->select.offset;
+ ispan = iter->u.hyp.span;
+ elem_size = iter->elmt_size;
+
+ /* Set the amount of elements to perform I/O on, etc. */
+ H5_CHECK_OVERFLOW(iter->elmt_left, hsize_t, size_t);
+ io_left = MIN(maxelem, (size_t)iter->elmt_left);
+ io_bytes_left = io_left * elem_size;
+
+ /* Compute the cumulative size of dataspace dimensions */
+ for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
+ slab[i] = acc;
+ acc *= space->extent.size[i];
+ } /* end for */
+
+ /* Set the offset of the first element iterated on */
+ for(u = 0, loc_off = 0; u < ndims; u++)
+ /* Compute the sequential element offset */
+ loc_off += ((hsize_t)((hssize_t)abs_arr[u] + off_arr[u])) * slab[u];
+
+ /* Range check against number of elements left in selection */
+ HDassert(io_bytes_left <= (iter->elmt_left * elem_size));
+
+ /* Take care of any partial spans leftover from previous I/Os */
+ if(abs_arr[fast_dim] != curr_span->low) {
+ /* Finish the span in the fastest changing dimension */
+
+ /* Compute the number of bytes to attempt in this span */
+ H5_CHECKED_ASSIGN(span_size, size_t, ((curr_span->high - abs_arr[fast_dim])+1)*elem_size, hsize_t);
+
+ /* Check number of bytes against upper bounds allowed */
+ if(span_size > io_bytes_left)
+ span_size = io_bytes_left;
+
+ /* Add the partial span to the list of sequences */
+ off[curr_seq] = loc_off;
+ len[curr_seq] = span_size;
+
+ /* Increment sequence count */
+ curr_seq++;
+
+ /* Set the location of the last span's end */
+ last_span_end = loc_off + span_size;
+
+ /* Decrement I/O left to perform */
+ io_bytes_left -= span_size;
+
+ /* Check if we are done */
+ if(io_bytes_left > 0) {
+ /* Move to next span in fastest changing dimension */
+ curr_span = curr_span->next;
+
+ if(NULL != curr_span) {
+ /* Move location offset of destination */
+ loc_off += (curr_span->low - abs_arr[fast_dim]) * elem_size;
+
+ /* Move iterator for fastest changing dimension */
+ abs_arr[fast_dim] = curr_span->low;
+ } /* end if */
+ } /* end if */
+ else {
+ /* Advance the hyperslab iterator */
+ abs_arr[fast_dim] += span_size / elem_size;
+
+ /* Check if we are still within the span */
+ if(abs_arr[fast_dim] <= curr_span->high) {
+ iter->u.hyp.span[fast_dim] = curr_span;
+ } /* end if */
+ /* If we walked off that span, advance to the next span */
+ else {
+ /* Advance span in this dimension */
+ curr_span = curr_span->next;
+
+ /* Check if we have a valid span in this dimension still */
+ if(NULL != curr_span) {
+ /* Reset absolute position */
+ abs_arr[fast_dim] = curr_span->low;
+ iter->u.hyp.span[fast_dim] = curr_span;
+ } /* end if */
+ } /* end else */
+ } /* end else */
+
+ /* Adjust iterator pointers */
+
+ if(NULL == curr_span) {
+/* Same as code in main loop */
+ /* Start at the next fastest dim */
+ curr_dim = (int)(fast_dim - 1);
+
+ /* Work back up through the dimensions */
+ while(curr_dim >= 0) {
+ /* Reset the current span */
+ curr_span = iter->u.hyp.span[curr_dim];
+
+ /* Increment absolute position */
+ abs_arr[curr_dim]++;
+
+ /* Check if we are still within the span */
+ if(abs_arr[curr_dim] <= curr_span->high) {
+ break;
+ } /* end if */
+ /* If we walked off that span, advance to the next span */
+ else {
+ /* Advance span in this dimension */
+ curr_span = curr_span->next;
+
+ /* Check if we have a valid span in this dimension still */
+ if(NULL != curr_span) {
+ /* Reset the span in the current dimension */
+ ispan[curr_dim] = curr_span;
+
+ /* Reset absolute position */
+ abs_arr[curr_dim] = curr_span->low;
+
+ break;
+ } /* end if */
+ else
+ /* If we finished the span list in this dimension, decrement the dimension worked on and loop again */
+ curr_dim--;
+ } /* end else */
+ } /* end while */
+
+ /* Check if we have more spans in the tree */
+ if(curr_dim >= 0) {
+ /* Walk back down the iterator positions, resetting them */
+ while((unsigned)curr_dim < fast_dim) {
+ HDassert(curr_span);
+ HDassert(curr_span->down);
+ HDassert(curr_span->down->head);
+
+ /* Increment current dimension */
+ curr_dim++;
+
+ /* Set the new span_info & span for this dimension */
+ iter->u.hyp.span[curr_dim] = curr_span->down->head;
+
+ /* Advance span down the tree */
+ curr_span = curr_span->down->head;
+
+ /* Reset the absolute offset for the dim */
+ abs_arr[curr_dim] = curr_span->low;
+ } /* end while */
+
+ /* Verify that the curr_span points to the fastest dim */
+ HDassert(curr_span == iter->u.hyp.span[fast_dim]);
+
+ /* Reset the buffer offset */
+ for(u = 0, loc_off = 0; u < ndims; u++)
+ loc_off += ((hsize_t)((hssize_t)abs_arr[u] + off_arr[u])) * slab[u];
+ } /* end else */
+ else
+ /* We had better be done with I/O or bad things are going to happen... */
+ HDassert(io_bytes_left == 0);
+ } /* end if */
+ } /* end if */
+
+ /* Perform the I/O on the elements, based on the position of the iterator */
+ while(io_bytes_left > 0 && curr_seq < maxseq) {
+ /* Sanity check */
+ HDassert(curr_span);
+
+ /* Adjust location offset of destination to compensate for initial increment below */
+ loc_off -= curr_span->pstride;
+
+ /* Loop over all the spans in the fastest changing dimension */
+ while(curr_span != NULL) {
+ /* Move location offset of destination */
+ loc_off += curr_span->pstride;
+
+ /* Compute the number of elements to attempt in this span */
+ H5_CHECKED_ASSIGN(span_size, size_t, curr_span->nelem, hsize_t);
+
+ /* Check number of elements against upper bounds allowed */
+ if(span_size >= io_bytes_left) {
+ /* Trim the number of bytes to output */
+ span_size = io_bytes_left;
+ io_bytes_left = 0;
+
+/* COMMON */
+ /* Store the I/O information for the span */
+
+ /* Check if this is appending onto previous sequence */
+ if(curr_seq > 0 && last_span_end == loc_off)
+ len[curr_seq - 1] += span_size;
+ else {
+ off[curr_seq] = loc_off;
+ len[curr_seq] = span_size;
+
+ /* Increment the number of sequences in arrays */
+ curr_seq++;
+ } /* end else */
+
+ /* Set the location of the last span's end */
+ last_span_end = loc_off + span_size;
+/* end COMMON */
+
+ /* Break out now, we are finished with I/O */
+ break;
+ } /* end if */
+ else {
+ /* Decrement I/O left to perform */
+ io_bytes_left -= span_size;
+
+/* COMMON */
+ /* Store the I/O information for the span */
+
+ /* Check if this is appending onto previous sequence */
+ if(curr_seq > 0 && last_span_end == loc_off)
+ len[curr_seq - 1] += span_size;
+ else {
+ off[curr_seq] = loc_off;
+ len[curr_seq] = span_size;
+
+ /* Increment the number of sequences in arrays */
+ curr_seq++;
+ } /* end else */
+
+ /* Set the location of the last span's end */
+ last_span_end = loc_off + span_size;
+/* end COMMON */
+
+ /* If the sequence & offset arrays are full, do what? */
+ if(curr_seq >= maxseq)
+ /* Break out now, we are finished with sequences */
+ break;
+ } /* end else */
+
+ /* Move to next span in fastest changing dimension */
+ curr_span = curr_span->next;
+ } /* end while */
+
+ /* Check if we are done */
+ if(io_bytes_left == 0 || curr_seq >= maxseq) {
+ HDassert(curr_span);
+ abs_arr[fast_dim] = curr_span->low + (span_size / elem_size);
+
+ /* Check if we are still within the span */
+ if(abs_arr[fast_dim] <= curr_span->high) {
+ iter->u.hyp.span[fast_dim]=curr_span;
+ break;
+ } /* end if */
+ /* If we walked off that span, advance to the next span */
+ else {
+ /* Advance span in this dimension */
+ curr_span = curr_span->next;
+
+ /* Check if we have a valid span in this dimension still */
+ if(curr_span != NULL) {
+ /* Reset absolute position */
+ abs_arr[fast_dim] = curr_span->low;
+ iter->u.hyp.span[fast_dim] = curr_span;
+ break;
+ } /* end if */
+ } /* end else */
+ } /* end if */
+
+ /* Adjust iterator pointers */
+
+ /* Start at the next fastest dim */
+ curr_dim = (int)(fast_dim - 1);
+
+ /* Work back up through the dimensions */
+ while(curr_dim >= 0) {
+ /* Reset the current span */
+ curr_span=iter->u.hyp.span[curr_dim];
+
+ /* Increment absolute position */
+ abs_arr[curr_dim]++;
+
+ /* Check if we are still within the span */
+ if(abs_arr[curr_dim]<=curr_span->high) {
+ break;
+ } /* end if */
+ /* If we walked off that span, advance to the next span */
+ else {
+ /* Advance span in this dimension */
+ curr_span = curr_span->next;
+
+ /* Check if we have a valid span in this dimension still */
+ if(curr_span != NULL) {
+ /* Reset the span in the current dimension */
+ ispan[curr_dim] = curr_span;
+
+ /* Reset absolute position */
+ abs_arr[curr_dim] = curr_span->low;
+
+ break;
+ } /* end if */
+ else
+ /* If we finished the span list in this dimension, decrement the dimension worked on and loop again */
+ curr_dim--;
+ } /* end else */
+ } /* end while */
+
+ /* Check if we are finished with the spans in the tree */
+ if(curr_dim < 0) {
+ /* We had better be done with I/O or bad things are going to happen... */
+ HDassert(io_bytes_left == 0);
+ break;
+ } /* end if */
+ else {
+ /* Walk back down the iterator positions, resetting them */
+ while((unsigned)curr_dim < fast_dim) {
+ HDassert(curr_span);
+ HDassert(curr_span->down);
+ HDassert(curr_span->down->head);
+
+ /* Increment current dimension to the next dimension down */
+ curr_dim++;
+
+ /* Set the new span for the next dimension down */
+ iter->u.hyp.span[curr_dim] = curr_span->down->head;
+
+ /* Advance span down the tree */
+ curr_span = curr_span->down->head;
+
+ /* Reset the absolute offset for the dim */
+ abs_arr[curr_dim] = curr_span->low;
+ } /* end while */
+
+ /* Verify that the curr_span points to the fastest dim */
+ HDassert(curr_span == iter->u.hyp.span[fast_dim]);
+ } /* end else */
+
+ /* Reset the buffer offset */
+ for(u = 0, loc_off = 0; u < ndims; u++)
+ loc_off += ((hsize_t)((hssize_t)abs_arr[u] + off_arr[u])) * slab[u];
+ } /* end while */
+
+ /* Decrement number of elements left in iterator */
+ io_used = (io_left - (io_bytes_left / elem_size));
+ iter->elmt_left -= io_used;
+
+ /* Set the number of sequences generated */
+ *nseq = curr_seq;
+
+ /* Set the number of elements used */
+ *nelem = io_used;
+
+ FUNC_LEAVE_NOAPI(SUCCEED)
+} /* end H5S__hyper_get_seq_list_gen() */
+
+
+/*--------------------------------------------------------------------------
+ NAME
+ H5S__hyper_get_seq_list_opt
+ PURPOSE
+ Create a list of offsets & lengths for a selection
+ USAGE
+ herr_t H5S_select_hyper_get_file_list_opt(space,iter,maxseq,maxelem,nseq,nelem,off,len)
+ H5S_t *space; IN: Dataspace containing selection to use.
+ H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
+ position of interest in selection.
+ size_t maxseq; IN: Maximum number of sequences to generate
+ size_t maxelem; IN: Maximum number of elements to include in the
+ generated sequences
+ size_t *nseq; OUT: Actual number of sequences generated
+ size_t *nelem; OUT: Actual number of elements in sequences generated
+ hsize_t *off; OUT: Array of offsets
+ size_t *len; OUT: Array of lengths
+ RETURNS
+ Non-negative on success/Negative on failure.
+ DESCRIPTION
+ Use the selection in the dataspace to generate a list of byte offsets and
+ lengths for the region(s) selected. Start/Restart from the position in the
+ ITER parameter. The number of sequences generated is limited by the MAXSEQ
+ parameter and the number of sequences actually generated is stored in the
+ NSEQ parameter.
+ GLOBAL VARIABLES
+ COMMENTS, BUGS, ASSUMPTIONS
+ EXAMPLES
+ REVISION LOG
+--------------------------------------------------------------------------*/
+static herr_t
+H5S__hyper_get_seq_list_opt(const H5S_t *space, H5S_sel_iter_t *iter,
+ size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
+ hsize_t *off, size_t *len)
+{
+ hsize_t *mem_size; /* Size of the source buffer */
+ hsize_t slab[H5S_MAX_RANK]; /* Hyperslab size */
+ const hssize_t *sel_off; /* Selection offset in dataspace */
+ hsize_t offset[H5S_MAX_RANK]; /* Coordinate offset in dataspace */
+ hsize_t tmp_count[H5S_MAX_RANK]; /* Temporary block count */
+ hsize_t tmp_block[H5S_MAX_RANK]; /* Temporary block offset */
+ hsize_t wrap[H5S_MAX_RANK]; /* Bytes to wrap around at the end of a row */
+ hsize_t skip[H5S_MAX_RANK]; /* Bytes to skip between blocks */
+ const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
+ hsize_t fast_dim_start, /* Local copies of fastest changing dimension info */
+ fast_dim_stride,
+ fast_dim_block,
+ fast_dim_offset;
+ size_t fast_dim_buf_off; /* Local copy of amount to move fastest dimension buffer offset */
+ size_t fast_dim_count; /* Number of blocks left in fastest changing dimension */
+ size_t tot_blk_count; /* Total number of blocks left to output */
+ size_t act_blk_count; /* Actual number of blocks to output */
+ size_t total_rows; /* Total number of entire rows to output */
+ size_t curr_rows; /* Current number of entire rows to output */
+ unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
+ unsigned ndims; /* Number of dimensions of dataset */
+ int temp_dim; /* Temporary rank holder */
+ hsize_t acc; /* Accumulator */
+ hsize_t loc; /* Coordinate offset */
+ size_t curr_seq = 0; /* Current sequence being operated on */
+ size_t actual_elem; /* The actual number of elements to count */
+ size_t actual_bytes;/* The actual number of bytes to copy */
+ size_t io_left; /* The number of elements left in I/O operation */
+ size_t start_io_left; /* The initial number of elements left in I/O operation */
+ size_t elem_size; /* Size of each element iterating over */
+ unsigned u; /* Local index variable */
+ int i; /* Local index variable */
+
+ FUNC_ENTER_STATIC_NOERR
+
+ /* Check args */
+ HDassert(space);
+ HDassert(iter);
+ HDassert(maxseq > 0);
+ HDassert(maxelem > 0);
+ HDassert(nseq);
+ HDassert(nelem);
+ HDassert(off);
+ HDassert(len);
+
+ /* Set the local copy of the diminfo pointer */
+ tdiminfo = iter->u.hyp.diminfo;
+
+ /* Check if this is a "flattened" regular hyperslab selection */
+ if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < space->extent.rank) {
+ /* Set the aliases for a few important dimension ranks */
+ ndims = iter->u.hyp.iter_rank;
+ fast_dim = ndims - 1;
+
+ /* Set the local copy of the selection offset */
+ sel_off = iter->u.hyp.sel_off;
+
+ /* Set up the pointer to the size of the memory space */
+ mem_size = iter->u.hyp.size;
+ } /* end if */
+ else {
+ /* Set the aliases for a few important dimension ranks */
+ ndims = space->extent.rank;
+ fast_dim = ndims - 1;
+
+ /* Set the local copy of the selection offset */
+ sel_off = space->select.offset;
+
+ /* Set up the pointer to the size of the memory space */
+ mem_size = space->extent.size;
+ } /* end else */
+
+ /* initialize row sizes for each dimension */
+ elem_size = iter->elmt_size;
+ for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
+ slab[i] = acc;
+ acc *= mem_size[i];
+ } /* end for */
+
+ /* Calculate the number of elements to sequence through */
+ H5_CHECK_OVERFLOW(iter->elmt_left, hsize_t, size_t);
+ io_left = MIN((size_t)iter->elmt_left, maxelem);
+
+ /* Sanity check that there aren't any "remainder" sequences in process */
+ HDassert(!((iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start) % tdiminfo[fast_dim].stride != 0 ||
+ ((iter->u.hyp.off[fast_dim] != tdiminfo[fast_dim].start) && tdiminfo[fast_dim].count == 1)));
+
+ /* We've cleared the "remainder" of the previous fastest dimension
+ * sequence before calling this routine, so we must be at the beginning of
+ * a sequence. Use the fancy algorithm to compute the offsets and run
+ * through as many as possible, until the buffer fills up.
+ */
+
+ /* Keep the number of elements we started with */
+ start_io_left = io_left;
+
+ /* Compute the arrays to perform I/O on */
+
+ /* Copy the location of the point to get */
+ /* (Add in the selection offset) */
+ for(u = 0; u < ndims; u++)
+ offset[u] = (hsize_t)((hssize_t)iter->u.hyp.off[u] + sel_off[u]);
+
+ /* Compute the current "counts" for this location */
+ for(u = 0; u < ndims; u++) {
+ if(tdiminfo[u].count == 1) {
+ tmp_count[u] = 0;
+ tmp_block[u] = iter->u.hyp.off[u] - tdiminfo[u].start;
+ } /* end if */
+ else {
+ tmp_count[u] = (iter->u.hyp.off[u] - tdiminfo[u].start) / tdiminfo[u].stride;
+ tmp_block[u] = (iter->u.hyp.off[u] - tdiminfo[u].start) % tdiminfo[u].stride;
+ } /* end else */
+ } /* end for */
+
+ /* Compute the initial buffer offset */
+ for(u = 0, loc = 0; u < ndims; u++)
+ loc += offset[u] * slab[u];
+
+ /* Set the number of elements to write each time */
+ H5_CHECKED_ASSIGN(actual_elem, size_t, tdiminfo[fast_dim].block, hsize_t);
+
+ /* Set the number of actual bytes */
+ actual_bytes = actual_elem * elem_size;
+
+ /* Set local copies of information for the fastest changing dimension */
+ fast_dim_start = tdiminfo[fast_dim].start;
+ fast_dim_stride = tdiminfo[fast_dim].stride;
+ fast_dim_block = tdiminfo[fast_dim].block;
+ H5_CHECKED_ASSIGN(fast_dim_buf_off, size_t, slab[fast_dim] * fast_dim_stride, hsize_t);
+ fast_dim_offset = (hsize_t)((hssize_t)fast_dim_start + sel_off[fast_dim]);
+
+ /* Compute the number of blocks which would fit into the buffer */
+ H5_CHECK_OVERFLOW(io_left / fast_dim_block, hsize_t, size_t);
+ tot_blk_count = (size_t)(io_left / fast_dim_block);
+
+ /* Don't go over the maximum number of sequences allowed */
+ tot_blk_count = MIN(tot_blk_count, (maxseq - curr_seq));
+
+ /* Compute the amount to wrap at the end of each row */
+ for(u = 0; u < ndims; u++)
+ wrap[u] = (mem_size[u] - (tdiminfo[u].stride * tdiminfo[u].count)) * slab[u];
+
+ /* Compute the amount to skip between blocks */
+ for(u = 0; u < ndims; u++)
+ skip[u] = (tdiminfo[u].stride - tdiminfo[u].block) * slab[u];
+
+ /* Check if there is a partial row left (with full blocks) */
+ if(tmp_count[fast_dim] > 0) {
+ /* Get number of blocks in fastest dimension */
+ H5_CHECKED_ASSIGN(fast_dim_count, size_t, tdiminfo[fast_dim].count - tmp_count[fast_dim], hsize_t);
+
+ /* Make certain this entire row will fit into buffer */
+ fast_dim_count = MIN(fast_dim_count, tot_blk_count);
+
+ /* Number of blocks to sequence over */
+ act_blk_count = fast_dim_count;
+
+ /* Loop over all the blocks in the fastest changing dimension */
+ while(fast_dim_count > 0) {
+ /* Store the sequence information */
+ off[curr_seq] = loc;
+ len[curr_seq] = actual_bytes;
+
+ /* Increment sequence count */
+ curr_seq++;
+
+ /* Increment information to reflect block just processed */
+ loc += fast_dim_buf_off;
+
+ /* Decrement number of blocks */
+ fast_dim_count--;
+ } /* end while */
+
+ /* Decrement number of elements left */
+ io_left -= actual_elem * act_blk_count;
+
+ /* Decrement number of blocks left */
+ tot_blk_count -= act_blk_count;
+
+ /* Increment information to reflect block just processed */
+ tmp_count[fast_dim] += act_blk_count;
+
+ /* Check if we finished the entire row of blocks */
+ if(tmp_count[fast_dim] >= tdiminfo[fast_dim].count) {
+ /* Increment offset in destination buffer */
+ loc += wrap[fast_dim];
+
+ /* Increment information to reflect block just processed */
+ offset[fast_dim] = fast_dim_offset; /* reset the offset in the fastest dimension */
+ tmp_count[fast_dim] = 0;
+
+ /* Increment the offset and count for the other dimensions */
+ temp_dim = (int)fast_dim - 1;
+ while(temp_dim >= 0) {
+ /* Move to the next row in the curent dimension */
+ offset[temp_dim]++;
+ tmp_block[temp_dim]++;
+
+ /* If this block is still in the range of blocks to output for the dimension, break out of loop */
+ if(tmp_block[temp_dim] < tdiminfo[temp_dim].block)
+ break;
+ else {
+ /* Move to the next block in the current dimension */
+ offset[temp_dim] += (tdiminfo[temp_dim].stride - tdiminfo[temp_dim].block);
+ loc += skip[temp_dim];
+ tmp_block[temp_dim] = 0;
+ tmp_count[temp_dim]++;
+
+ /* If this block is still in the range of blocks to output for the dimension, break out of loop */
+ if(tmp_count[temp_dim] < tdiminfo[temp_dim].count)
+ break;
+ else {
+ offset[temp_dim] = (hsize_t)((hssize_t)tdiminfo[temp_dim].start + sel_off[temp_dim]);
+ loc += wrap[temp_dim];
+ tmp_count[temp_dim] = 0; /* reset back to the beginning of the line */
+ tmp_block[temp_dim] = 0;
+ } /* end else */
+ } /* end else */
+
+ /* Decrement dimension count */
+ temp_dim--;
+ } /* end while */
+ } /* end if */
+ else {
+ /* Update the offset in the fastest dimension */
+ offset[fast_dim] += (fast_dim_stride * act_blk_count);
+ } /* end else */
+ } /* end if */
+
+ /* Compute the number of entire rows to read in */
+ H5_CHECK_OVERFLOW(tot_blk_count / tdiminfo[fast_dim].count, hsize_t, size_t);
+ curr_rows = total_rows = (size_t)(tot_blk_count / tdiminfo[fast_dim].count);
+
+ /* Reset copy of number of blocks in fastest dimension */
+ H5_CHECKED_ASSIGN(fast_dim_count, size_t, tdiminfo[fast_dim].count, hsize_t);
+
+ /* Read in data until an entire sequence can't be written out any longer */
+ while(curr_rows > 0) {
+
+#define DUFF_GUTS \
+/* Store the sequence information */ \
+off[curr_seq] = loc; \
+len[curr_seq] = actual_bytes; \
+ \
+/* Increment sequence count */ \
+curr_seq++; \
+ \
+/* Increment information to reflect block just processed */ \
+loc += fast_dim_buf_off;
+
+#ifdef NO_DUFFS_DEVICE
+ /* Loop over all the blocks in the fastest changing dimension */
+ while(fast_dim_count > 0) {
+ DUFF_GUTS
+
+ /* Decrement number of blocks */
+ fast_dim_count--;
+ } /* end while */
+#else /* NO_DUFFS_DEVICE */
+ {
+ size_t duffs_index; /* Counting index for Duff's device */
+
+ duffs_index = (fast_dim_count + 7) / 8;
+ switch (fast_dim_count % 8) {
+ default:
+ HDassert(0 && "This Should never be executed!");
+ break;
+ case 0:
+ do
+ {
+ DUFF_GUTS
+ case 7:
+ DUFF_GUTS
+ case 6:
+ DUFF_GUTS
+ case 5:
+ DUFF_GUTS
+ case 4:
+ DUFF_GUTS
+ case 3:
+ DUFF_GUTS
+ case 2:
+ DUFF_GUTS
+ case 1:
+ DUFF_GUTS
+ } while (--duffs_index > 0);
+ } /* end switch */
+ }
+#endif /* NO_DUFFS_DEVICE */
+#undef DUFF_GUTS
+
+ /* Increment offset in destination buffer */
+ loc += wrap[fast_dim];
+
+ /* Increment the offset and count for the other dimensions */
+ temp_dim = (int)fast_dim - 1;
+ while(temp_dim >= 0) {
+ /* Move to the next row in the curent dimension */
+ offset[temp_dim]++;
+ tmp_block[temp_dim]++;
+
+ /* If this block is still in the range of blocks to output for the dimension, break out of loop */
+ if(tmp_block[temp_dim] < tdiminfo[temp_dim].block)
+ break;
+ else {
+ /* Move to the next block in the current dimension */
+ offset[temp_dim] += (tdiminfo[temp_dim].stride - tdiminfo[temp_dim].block);
+ loc += skip[temp_dim];
+ tmp_block[temp_dim] = 0;
+ tmp_count[temp_dim]++;
+
+ /* If this block is still in the range of blocks to output for the dimension, break out of loop */
+ if(tmp_count[temp_dim] < tdiminfo[temp_dim].count)
+ break;
+ else {
+ offset[temp_dim] = (hsize_t)((hssize_t)tdiminfo[temp_dim].start + sel_off[temp_dim]);
+ loc += wrap[temp_dim];
+ tmp_count[temp_dim] = 0; /* reset back to the beginning of the line */
+ tmp_block[temp_dim] = 0;
+ } /* end else */
+ } /* end else */
+
+ /* Decrement dimension count */
+ temp_dim--;
+ } /* end while */
+
+ /* Decrement the number of rows left */
+ curr_rows--;
+ } /* end while */
+
+ /* Adjust the number of blocks & elements left to transfer */
+
+ /* Decrement number of elements left */
+ H5_CHECK_OVERFLOW(actual_elem * (total_rows * tdiminfo[fast_dim].count), hsize_t, size_t);
+ io_left -= (size_t)(actual_elem * (total_rows * tdiminfo[fast_dim].count));
+
+ /* Decrement number of blocks left */
+ H5_CHECK_OVERFLOW((total_rows * tdiminfo[fast_dim].count), hsize_t, size_t);
+ tot_blk_count -= (size_t)(total_rows * tdiminfo[fast_dim].count);
+
+ /* Read in partial row of blocks */
+ if(io_left > 0 && curr_seq < maxseq) {
+ /* Get remaining number of blocks left to output */
+ fast_dim_count = tot_blk_count;
+
+ /* Loop over all the blocks in the fastest changing dimension */
+ while(fast_dim_count > 0) {
+ /* Store the sequence information */
+ off[curr_seq] = loc;
+ len[curr_seq] = actual_bytes;
+
+ /* Increment sequence count */
+ curr_seq++;
+
+ /* Increment information to reflect block just processed */
+ loc += fast_dim_buf_off;
+
+ /* Decrement number of blocks */
+ fast_dim_count--;
+ } /* end while */
+
+ /* Decrement number of elements left */
+ io_left -= actual_elem * tot_blk_count;
+
+ /* Increment information to reflect block just processed */
+ offset[fast_dim] += (fast_dim_stride * tot_blk_count); /* move the offset in the fastest dimension */
+
+ /* Handle any leftover, partial blocks in this row */
+ if(io_left > 0 && curr_seq < maxseq) {
+ actual_elem = io_left;
+ actual_bytes = actual_elem * elem_size;
+
+ /* Store the sequence information */
+ off[curr_seq] = loc;
+ len[curr_seq] = actual_bytes;
+
+ /* Increment sequence count */
+ curr_seq++;
+
+ /* Decrement the number of elements left */
+ io_left -= actual_elem;
+
+ /* Increment buffer correctly */
+ offset[fast_dim] += actual_elem;
+ } /* end if */
+
+ /* don't bother checking slower dimensions */
+ HDassert(io_left == 0 || curr_seq == maxseq);
+ } /* end if */
+
+ /* Update the iterator */
+
+ /* Update the iterator with the location we stopped */
+ /* (Subtract out the selection offset) */
+ for(u = 0; u < ndims; u++)
+ iter->u.hyp.off[u] = (hsize_t)((hssize_t)offset[u] - sel_off[u]);
+
+ /* Decrement the number of elements left in selection */
+ iter->elmt_left -= (start_io_left - io_left);
+
+ /* Increment the number of sequences generated */
+ *nseq += curr_seq;
+
+ /* Increment the number of elements used */
+ *nelem += start_io_left - io_left;
+
+ FUNC_LEAVE_NOAPI(SUCCEED)
+} /* end H5S__hyper_get_seq_list_opt() */
+
+
+/*--------------------------------------------------------------------------
+ NAME
+ H5S__hyper_get_seq_list_single
+ PURPOSE
+ Create a list of offsets & lengths for a selection
+ USAGE
+ herr_t H5S__hyper_get_seq_list_single(space, flags, iter, maxseq, maxelem, nseq, nelem, off, len)
+ H5S_t *space; IN: Dataspace containing selection to use.
+ unsigned flags; IN: Flags for extra information about operation
+ H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
+ position of interest in selection.
+ size_t maxseq; IN: Maximum number of sequences to generate
+ size_t maxelem; IN: Maximum number of elements to include in the
+ generated sequences
+ size_t *nseq; OUT: Actual number of sequences generated
+ size_t *nelem; OUT: Actual number of elements in sequences generated
+ hsize_t *off; OUT: Array of offsets
+ size_t *len; OUT: Array of lengths
+ RETURNS
+ Non-negative on success/Negative on failure.
+ DESCRIPTION
+ Use the selection in the dataspace to generate a list of byte offsets and
+ lengths for the region(s) selected. Start/Restart from the position in the
+ ITER parameter. The number of sequences generated is limited by the MAXSEQ
+ parameter and the number of sequences actually generated is stored in the
+ NSEQ parameter.
+ GLOBAL VARIABLES
+ COMMENTS, BUGS, ASSUMPTIONS
+ EXAMPLES
+ REVISION LOG
+--------------------------------------------------------------------------*/
+static herr_t
+H5S__hyper_get_seq_list_single(const H5S_t *space, H5S_sel_iter_t *iter,
+ size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
+ hsize_t *off, size_t *len)
+{
+ const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
+ const hssize_t *sel_off; /* Selection offset in dataspace */
+ hsize_t *mem_size; /* Size of the source buffer */
+ hsize_t base_offset[H5S_MAX_RANK]; /* Base coordinate offset in dataspace */
+ hsize_t offset[H5S_MAX_RANK]; /* Coordinate offset in dataspace */
+ hsize_t slab[H5S_MAX_RANK]; /* Hyperslab size */
+ hsize_t fast_dim_block; /* Local copies of fastest changing dimension info */
+ hsize_t acc; /* Accumulator */
+ hsize_t loc; /* Coordinate offset */
+ size_t tot_blk_count; /* Total number of blocks left to output */
+ size_t elem_size; /* Size of each element iterating over */
+ size_t io_left; /* The number of elements left in I/O operation */
+ size_t actual_elem; /* The actual number of elements to count */
+ unsigned ndims; /* Number of dimensions of dataset */
+ unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
+ unsigned skip_dim; /* Rank of the dimension to skip along */
+ unsigned u; /* Local index variable */
+ int i; /* Local index variable */
+
+ FUNC_ENTER_STATIC_NOERR
+
+ /* Check args */
+ HDassert(space);
+ HDassert(iter);
+ HDassert(maxseq > 0);
+ HDassert(maxelem > 0);
+ HDassert(nseq);
+ HDassert(nelem);
+ HDassert(off);
+ HDassert(len);
+
+ /* Set a local copy of the diminfo pointer */
+ tdiminfo = iter->u.hyp.diminfo;
+
+ /* Check if this is a "flattened" regular hyperslab selection */
+ if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < space->extent.rank) {
+ /* Set the aliases for a few important dimension ranks */
+ ndims = iter->u.hyp.iter_rank;
+
+ /* Set the local copy of the selection offset */
+ sel_off = iter->u.hyp.sel_off;
+
+ /* Set up the pointer to the size of the memory space */
+ mem_size = iter->u.hyp.size;
+ } /* end if */
+ else {
+ /* Set the aliases for a few important dimension ranks */
+ ndims = space->extent.rank;
+
+ /* Set the local copy of the selection offset */
+ sel_off = space->select.offset;
+
+ /* Set up the pointer to the size of the memory space */
+ mem_size = space->extent.size;
+ } /* end else */
+ fast_dim = ndims - 1;
+
+ /* initialize row sizes for each dimension */
+ elem_size = iter->elmt_size;
+ for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
+ slab[i] = acc;
+ acc *= mem_size[i];
+ } /* end for */
+
+ /* Copy the base location of the block */
+ /* (Add in the selection offset) */
+ for(u = 0; u < ndims; u++)
+ base_offset[u] = (hsize_t)((hssize_t)tdiminfo[u].start + sel_off[u]);
+
+ /* Copy the location of the point to get */
+ /* (Add in the selection offset) */
+ for(u = 0; u < ndims; u++)
+ offset[u] = (hsize_t)((hssize_t)iter->u.hyp.off[u] + sel_off[u]);
+
+ /* Compute the initial buffer offset */
+ for(u = 0, loc = 0; u < ndims; u++)
+ loc += offset[u] * slab[u];
+
+ /* Set local copies of information for the fastest changing dimension */
+ fast_dim_block = tdiminfo[fast_dim].block;
+
+ /* Calculate the number of elements to sequence through */
+ H5_CHECK_OVERFLOW(iter->elmt_left, hsize_t, size_t);
+ io_left = MIN((size_t)iter->elmt_left, maxelem);
+
+ /* Compute the number of blocks which would fit into the buffer */
+ H5_CHECK_OVERFLOW(io_left / fast_dim_block, hsize_t, size_t);
+ tot_blk_count = (size_t)(io_left / fast_dim_block);
+
+ /* Don't go over the maximum number of sequences allowed */
+ tot_blk_count = MIN(tot_blk_count, maxseq);
+
+ /* Set the number of elements to write each time */
+ H5_CHECKED_ASSIGN(actual_elem, size_t, fast_dim_block, hsize_t);
+
+ /* Check for blocks to operate on */
+ if(tot_blk_count > 0) {
+ size_t actual_bytes; /* The actual number of bytes to copy */
+
+ /* Set the number of actual bytes */
+ actual_bytes = actual_elem * elem_size;
+
+ /* Check for 1-dim selection */
+ if(0 == fast_dim) {
+ /* Sanity checks */
+ HDassert(1 == tot_blk_count);
+ HDassert(io_left == actual_elem);
+
+ /* Store the sequence information */
+ *off++ = loc;
+ *len++ = actual_bytes;
+ } /* end if */
+ else {
+ hsize_t skip_slab; /* Temporary copy of slab[fast_dim - 1] */
+ size_t blk_count; /* Total number of blocks left to output */
+
+ /* Find first dimension w/block >1 */
+ skip_dim = fast_dim;
+ for(i = (int)(fast_dim - 1); i >= 0; i--)
+ if(tdiminfo[i].block > 1) {
+ skip_dim = (unsigned)i;
+ break;
+ } /* end if */
+ skip_slab = slab[skip_dim];
+
+ /* Check for being able to use fast algorithm for 1-D */
+ if(0 == skip_dim) {
+ /* Create sequences until an entire row can't be used */
+ blk_count = tot_blk_count;
+ while(blk_count > 0) {
+ /* Store the sequence information */
+ *off++ = loc;
+ *len++ = actual_bytes;
+
+ /* Increment offset in destination buffer */
+ loc += skip_slab;
+
+ /* Decrement block count */
+ blk_count--;
+ } /* end while */
+
+ /* Move to the next location */
+ offset[skip_dim] += tot_blk_count;
+ } /* end if */
+ else {
+ hsize_t tmp_block[H5S_MAX_RANK]; /* Temporary block offset */
+ hsize_t skip[H5S_MAX_RANK]; /* Bytes to skip between blocks */
+ int temp_dim; /* Temporary rank holder */
+
+ /* Set the starting block location */
+ for(u = 0; u < ndims; u++)
+ tmp_block[u] = iter->u.hyp.off[u] - tdiminfo[u].start;
+
+ /* Compute the amount to skip between sequences */
+ for(u = 0; u < ndims; u++)
+ skip[u] = (mem_size[u] - tdiminfo[u].block) * slab[u];
+
+ /* Create sequences until an entire row can't be used */
+ blk_count = tot_blk_count;
+ while(blk_count > 0) {
+ /* Store the sequence information */
+ *off++ = loc;
+ *len++ = actual_bytes;
+
+ /* Set temporary dimension for advancing offsets */
+ temp_dim = (int)skip_dim;
+
+ /* Increment offset in destination buffer */
+ loc += skip_slab;
+
+ /* Increment the offset and count for the other dimensions */
+ while(temp_dim >= 0) {
+ /* Move to the next row in the curent dimension */
+ offset[temp_dim]++;
+ tmp_block[temp_dim]++;
+
+ /* If this block is still in the range of blocks to output for the dimension, break out of loop */
+ if(tmp_block[temp_dim] < tdiminfo[temp_dim].block)
+ break;
+ else {
+ offset[temp_dim] = base_offset[temp_dim];
+ loc += skip[temp_dim];
+ tmp_block[temp_dim] = 0;
+ } /* end else */
+
+ /* Decrement dimension count */
+ temp_dim--;
+ } /* end while */
+
+ /* Decrement block count */
+ blk_count--;
+ } /* end while */
+ } /* end else */
+ } /* end else */
+
+ /* Update the iterator, if there were any blocks used */
+
+ /* Decrement the number of elements left in selection */
+ iter->elmt_left -= tot_blk_count * actual_elem;
+
+ /* Check if there are elements left in iterator */
+ if(iter->elmt_left > 0) {
+ /* Update the iterator with the location we stopped */
+ /* (Subtract out the selection offset) */
+ for(u = 0; u < ndims; u++)
+ iter->u.hyp.off[u] = (hsize_t)((hssize_t)offset[u] - sel_off[u]);
+ } /* end if */
+
+ /* Increment the number of sequences generated */
+ *nseq += tot_blk_count;
+
+ /* Increment the number of elements used */
+ *nelem += tot_blk_count * actual_elem;
+ } /* end if */
+
+ /* Check for partial block, with room for another sequence */
+ if(io_left > (tot_blk_count * actual_elem) && tot_blk_count < maxseq) {
+ size_t elmt_remainder; /* Elements remaining */
+
+ /* Compute elements left */
+ elmt_remainder = io_left - (tot_blk_count * actual_elem);
+ HDassert(elmt_remainder < fast_dim_block);
+ HDassert(elmt_remainder > 0);
+
+ /* Store the sequence information */
+ *off++ = loc;
+ *len++ = elmt_remainder * elem_size;
+
+ /* Update the iterator with the location we stopped */
+ iter->u.hyp.off[fast_dim] += (hsize_t)elmt_remainder;
+
+ /* Decrement the number of elements left in selection */
+ iter->elmt_left -= elmt_remainder;
+
+ /* Increment the number of sequences generated */
+ (*nseq)++;
+
+ /* Increment the number of elements used */
+ *nelem += elmt_remainder;
+ } /* end if */
+
+ /* Sanity check */
+ HDassert(*nseq > 0);
+ HDassert(*nelem > 0);
+
+ FUNC_LEAVE_NOAPI(SUCCEED)
+} /* end H5S__hyper_get_seq_list_single() */
+
+
+/*--------------------------------------------------------------------------
+ NAME
+ H5S__hyper_get_seq_list
+ PURPOSE
+ Create a list of offsets & lengths for a selection
+ USAGE
+ herr_t H5S__hyper_get_seq_list(space,flags,iter,maxseq,maxelem,nseq,nelem,off,len)
+ H5S_t *space; IN: Dataspace containing selection to use.
+ unsigned flags; IN: Flags for extra information about operation
+ H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
+ position of interest in selection.
+ size_t maxseq; IN: Maximum number of sequences to generate
+ size_t maxelem; IN: Maximum number of elements to include in the
+ generated sequences
+ size_t *nseq; OUT: Actual number of sequences generated
+ size_t *nelem; OUT: Actual number of elements in sequences generated
+ hsize_t *off; OUT: Array of offsets (in bytes)
+ size_t *len; OUT: Array of lengths (in bytes)
+ RETURNS
+ Non-negative on success/Negative on failure.
+ DESCRIPTION
+ Use the selection in the dataspace to generate a list of byte offsets and
+ lengths for the region(s) selected. Start/Restart from the position in the
+ ITER parameter. The number of sequences generated is limited by the MAXSEQ
+ parameter and the number of sequences actually generated is stored in the
+ NSEQ parameter.
+ GLOBAL VARIABLES
+ COMMENTS, BUGS, ASSUMPTIONS
+ EXAMPLES
+ REVISION LOG
+--------------------------------------------------------------------------*/
+static herr_t
+H5S__hyper_get_seq_list(const H5S_t *space, unsigned H5_ATTR_UNUSED flags, H5S_sel_iter_t *iter,
+ size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
+ hsize_t *off, size_t *len)
+{
+ herr_t ret_value = FAIL; /* return value */
+
+ FUNC_ENTER_STATIC_NOERR
+
+ /* Check args */
+ HDassert(space);
+ HDassert(iter);
+ HDassert(iter->elmt_left > 0);
+ HDassert(maxseq > 0);
+ HDassert(maxelem > 0);
+ HDassert(nseq);
+ HDassert(nelem);
+ HDassert(off);
+ HDassert(len);
+ HDassert(space->select.sel_info.hslab->unlim_dim < 0);
+
+ /* Check for the special case of just one H5Sselect_hyperslab call made */
+ if(space->select.sel_info.hslab->diminfo_valid) {
+ const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
+ const hssize_t *sel_off; /* Selection offset in dataspace */
+ hsize_t *mem_size; /* Size of the source buffer */
+ unsigned ndims; /* Number of dimensions of dataset */
+ unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
+ hbool_t single_block; /* Whether the selection is a single block */
+ unsigned u; /* Local index variable */
+
+ /* Set a local copy of the diminfo pointer */
+ tdiminfo = iter->u.hyp.diminfo;
+
+ /* Check if this is a "flattened" regular hyperslab selection */
+ if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < space->extent.rank) {
+ /* Set the aliases for a few important dimension ranks */
+ ndims = iter->u.hyp.iter_rank;
+
+ /* Set the local copy of the selection offset */
+ sel_off = iter->u.hyp.sel_off;
+
+ /* Set up the pointer to the size of the memory space */
+ mem_size = iter->u.hyp.size;
+ } /* end if */
+ else {
+ /* Set the aliases for a few important dimension ranks */
+ ndims = space->extent.rank;
+
+ /* Set the local copy of the selection offset */
+ sel_off = space->select.offset;
+
+ /* Set up the pointer to the size of the memory space */
+ mem_size = space->extent.size;
+ } /* end else */
+ fast_dim = ndims - 1;
+
+ /* Check if we stopped in the middle of a sequence of elements */
+ if((iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start) % tdiminfo[fast_dim].stride != 0 ||
+ ((iter->u.hyp.off[fast_dim] != tdiminfo[fast_dim].start) && tdiminfo[fast_dim].count == 1)) {
+ hsize_t slab[H5S_MAX_RANK]; /* Hyperslab size */
+ hsize_t loc; /* Coordinate offset */
+ hsize_t acc; /* Accumulator */
+ size_t leftover; /* The number of elements left over from the last sequence */
+ size_t actual_elem; /* The actual number of elements to count */
+ size_t elem_size; /* Size of each element iterating over */
+ int i; /* Local index variable */
+
+
+ /* Calculate the number of elements left in the sequence */
+ if(tdiminfo[fast_dim].count == 1) {
+ H5_CHECKED_ASSIGN(leftover, size_t, tdiminfo[fast_dim].block - (iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start), hsize_t);
+ } /* end if */
+ else {
+ H5_CHECKED_ASSIGN(leftover, size_t, tdiminfo[fast_dim].block - ((iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start) % tdiminfo[fast_dim].stride), hsize_t);
+ } /* end else */
+
+ /* Make certain that we don't write too many */
+ actual_elem = MIN3(leftover, (size_t)iter->elmt_left, maxelem);
+
+ /* Initialize row sizes for each dimension */
+ elem_size = iter->elmt_size;
+ for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
+ slab[i] = acc;
+ acc *= mem_size[i];
+ } /* end for */
+
+ /* Compute the initial buffer offset */
+ for(u = 0, loc = 0; u < ndims; u++)
+ loc += ((hsize_t)((hssize_t)iter->u.hyp.off[u] + sel_off[u])) * slab[u];
+
+ /* Add a new sequence */
+ off[0] = loc;
+ H5_CHECKED_ASSIGN(len[0], size_t, actual_elem * elem_size, hsize_t);
+
+ /* Increment sequence array locations */
+ off++;
+ len++;
+
+ /* Advance the hyperslab iterator */
+ H5S__hyper_iter_next(iter, actual_elem);
+
+ /* Decrement the number of elements left in selection */
+ iter->elmt_left -= actual_elem;
+
+ /* Decrement element/sequence limits */
+ maxelem -= actual_elem;
+ maxseq--;
+
+ /* Set the number of sequences generated and elements used */
+ *nseq = 1;
+ *nelem = actual_elem;
+
+ /* Check for using up all the sequences/elements */
+ if(0 == iter->elmt_left || 0 == maxelem || 0 == maxseq)
+ return(SUCCEED);
+ } /* end if */
+ else {
+ /* Reset the number of sequences generated and elements used */
+ *nseq = 0;
+ *nelem = 0;
+ } /* end else */
+
+ /* Check for a single block selected */
+ single_block = TRUE;
+ for(u = 0; u < ndims; u++)
+ if(1 != tdiminfo[u].count) {
+ single_block = FALSE;
+ break;
+ } /* end if */
+
+ /* Check for single block selection */
+ if(single_block)
+ /* Use single-block optimized call to generate sequence list */
+ ret_value = H5S__hyper_get_seq_list_single(space, iter, maxseq, maxelem, nseq, nelem, off, len);
+ else
+ /* Use optimized call to generate sequence list */
+ ret_value = H5S__hyper_get_seq_list_opt(space, iter, maxseq, maxelem, nseq, nelem, off, len);
+ } /* end if */
+ else
+ /* Call the general sequence generator routine */
+ ret_value = H5S__hyper_get_seq_list_gen(space, iter, maxseq, maxelem, nseq, nelem, off, len);
+
+ FUNC_LEAVE_NOAPI(ret_value)
+} /* end H5S__hyper_get_seq_list() */
/*--------------------------------------------------------------------------
@@ -1090,8 +2428,7 @@ H5S__hyper_iter_release(H5S_sel_iter_t *iter)
/* Check args */
HDassert(iter);
-/* Release the information needed for non-regular hyperslab I/O */
- /* Free the copy of the selections span tree */
+ /* Free the copy of the hyperslab selection span tree */
if(iter->u.hyp.spans != NULL)
H5S__hyper_free_span_info(iter->u.hyp.spans);
@@ -1110,7 +2447,7 @@ H5S__hyper_iter_release(H5S_sel_iter_t *iter)
H5S_hyper_span_info_t *down; IN: Down span tree for new node
H5S_hyper_span_t *next; IN: Next span for new node
RETURNS
- Pointer to next span node on success, NULL on failure
+ Pointer to new span node on success, NULL on failure
DESCRIPTION
Allocate and initialize a new hyperslab span node, filling in the low &
high bounds, the down span and next span pointers also. Increment the
@@ -1121,7 +2458,8 @@ H5S__hyper_iter_release(H5S_sel_iter_t *iter)
REVISION LOG
--------------------------------------------------------------------------*/
static H5S_hyper_span_t *
-H5S__hyper_new_span(hsize_t low, hsize_t high, H5S_hyper_span_info_t *down, H5S_hyper_span_t *next)
+H5S__hyper_new_span(hsize_t low, hsize_t high, H5S_hyper_span_info_t *down,
+ H5S_hyper_span_t *next)
{
H5S_hyper_span_t *ret_value = NULL; /* Return value */
@@ -1403,6 +2741,7 @@ H5S__hyper_copy_span(H5S_hyper_span_info_t *spans)
FUNC_ENTER_STATIC
+ /* Sanity check */
HDassert(spans);
/* Copy the hyperslab span tree */
@@ -1421,92 +2760,88 @@ done:
NAME
H5S__hyper_cmp_spans
PURPOSE
- Check if two hyperslab slabs are the same
+ Check if two hyperslab span trees are the same
USAGE
hbool_t H5S__hyper_cmp_spans(span1, span2)
- H5S_hyper_span_t *span1; IN: First span tree to compare
- H5S_hyper_span_t *span2; IN: Second span tree to compare
+ H5S_hyper_span_info_t *span_info1; IN: First span tree to compare
+ H5S_hyper_span_info_t *span_info2; IN: Second span tree to compare
RETURNS
TRUE (1) or FALSE (0) on success, can't fail
DESCRIPTION
- Compare two hyperslab slabs to determine if they refer to the same
- selection. If span1 & span2 are both NULL, that counts as equal
+ Compare two hyperslab span trees to determine if they refer to the same
+ selection. If span1 & span2 are both NULL, that counts as equal.
GLOBAL VARIABLES
COMMENTS, BUGS, ASSUMPTIONS
EXAMPLES
REVISION LOG
--------------------------------------------------------------------------*/
-static hbool_t
-H5S__hyper_cmp_spans(const H5S_hyper_span_info_t *span_info1, const H5S_hyper_span_info_t *span_info2)
+static H5_ATTR_PURE hbool_t
+H5S__hyper_cmp_spans(const H5S_hyper_span_info_t *span_info1,
+ const H5S_hyper_span_info_t *span_info2)
{
hbool_t ret_value = FALSE; /* Return value */
FUNC_ENTER_STATIC_NOERR
- /* Check for redundant comparison */
+ /* Check for redundant comparison (or both spans being NULL) */
if(span_info1 == span_info2)
ret_value = TRUE;
else {
- const H5S_hyper_span_t *span1;
- const H5S_hyper_span_t *span2;
-
- /* Check for both spans being NULL */
- if(span_info1 == NULL && span_info2 == NULL)
- ret_value = TRUE;
+ /* Check for one span being NULL */
+ if(span_info1 == NULL || span_info2 == NULL)
+ ret_value = FALSE;
else {
- /* Check for one span being NULL */
- if(span_info1 == NULL || span_info2 == NULL)
- ret_value = FALSE;
- else {
- /* Get the pointers to the actual lists of spans */
- span1 = span_info1->head;
- span2 = span_info2->head;
-
- /* Sanity checking */
- HDassert(span1);
- HDassert(span2);
-
- /* infinite loop which must be broken out of */
- while(1) {
- /* Check for both spans being NULL */
- if(span1 == NULL && span2 == NULL) {
- ret_value = TRUE;
+ const H5S_hyper_span_t *span1;
+ const H5S_hyper_span_t *span2;
+
+ /* Get the pointers to the actual lists of spans */
+ span1 = span_info1->head;
+ span2 = span_info2->head;
+
+ /* Sanity checking */
+ HDassert(span1);
+ HDassert(span2);
+
+ /* infinite loop which must be broken out of */
+ while(1) {
+ /* Check for both spans being NULL */
+ if(span1 == NULL && span2 == NULL) {
+ ret_value = TRUE;
+ break;
+ } /* end if */
+ else {
+ /* Check for one span being NULL */
+ if(span1 == NULL || span2 == NULL) {
+ ret_value = FALSE;
break;
} /* end if */
else {
- /* Check for one span being NULL */
- if(span1 == NULL || span2 == NULL) {
+ /* Check if the actual low & high span information is the same */
+ if(span1->low != span2->low || span1->high != span2->high) {
ret_value = FALSE;
break;
} /* end if */
else {
- /* Check if the actual low & high span information is the same */
- if(span1->low != span2->low || span1->high != span2->high) {
- ret_value = FALSE;
- break;
- } /* end if */
- else {
- if(span1->down != NULL || span2 != NULL) {
- if(!H5S__hyper_cmp_spans(span1->down, span2->down)) {
- ret_value = FALSE;
- break;
- } /* end if */
- else {
- /* Keep going... */
- } /* end else */
+ if(span1->down != NULL || span2 != NULL) {
+ if(!H5S__hyper_cmp_spans(span1->down, span2->down)) {
+ ret_value = FALSE;
+ break;
} /* end if */
else {
/* Keep going... */
} /* end else */
+ } /* end if */
+ else {
+ /* Keep going... */
} /* end else */
} /* end else */
} /* end else */
+ } /* end else */
- /* Advance to the next nodes in the span list */
- span1 = span1->next;
- span2 = span2->next;
- } /* end while */
- } /* end else */
+ /* Advance to the next nodes in the span list */
+ span1 = span1->next;
+ span2 = span2->next;
+ } /* end while */
} /* end else */
} /* end else */
@@ -1614,9 +2949,10 @@ done:
PURPOSE
Copy a selection from one dataspace to another
USAGE
- herr_t H5S__hyper_copy(dst, src)
+ herr_t H5S__hyper_copy(dst, src, share_selection)
H5S_t *dst; OUT: Pointer to the destination dataspace
H5S_t *src; IN: Pointer to the source dataspace
+ hbool_t; IN: Whether to share the selection between the dataspaces
RETURNS
Non-negative on success/Negative on failure
DESCRIPTION
@@ -2049,7 +3385,7 @@ H5S__hyper_serialize_helper(const H5S_hyper_span_info_t *spans,
HDassert(spans);
HDassert(start);
HDassert(end);
- HDassert(rank < H5O_LAYOUT_NDIMS);
+ HDassert(rank < H5S_MAX_RANK);
HDassert(p && pp);
/* Walk through the list of spans, recursing or outputting them */
@@ -2092,7 +3428,7 @@ H5S__hyper_serialize_helper(const H5S_hyper_span_info_t *spans,
*p = pp;
FUNC_LEAVE_NOAPI_VOID
-} /* H5S__hyper_serialize_helper() */
+} /* end H5S__hyper_serialize_helper() */
/*--------------------------------------------------------------------------
@@ -2174,8 +3510,8 @@ H5S__hyper_serialize(const H5S_t *space, uint8_t **p)
/* Check for a "regular" hyperslab selection */
else if(space->select.sel_info.hslab->diminfo_valid) {
const H5S_hyper_dim_t *diminfo; /* Alias for dataspace's diminfo information */
- hsize_t offset[H5O_LAYOUT_NDIMS]; /* Offset of element in dataspace */
- hsize_t tmp_count[H5O_LAYOUT_NDIMS]; /* Temporary hyperslab counts */
+ hsize_t offset[H5S_MAX_RANK]; /* Offset of element in dataspace */
+ hsize_t tmp_count[H5S_MAX_RANK]; /* Temporary hyperslab counts */
unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
unsigned ndims; /* Rank of the dataspace */
unsigned u; /* Local counting variable */
@@ -2265,8 +3601,8 @@ H5S__hyper_serialize(const H5S_t *space, uint8_t **p)
} /* end while */
} /* end if */
else {
- hsize_t start[H5O_LAYOUT_NDIMS]; /* Location of start of hyperslab */
- hsize_t end[H5O_LAYOUT_NDIMS]; /* Location of end of hyperslab */
+ hsize_t start[H5S_MAX_RANK]; /* Location of start of hyperslab */
+ hsize_t end[H5S_MAX_RANK]; /* Location of end of hyperslab */
/* Encode number of hyperslabs */
block_count = H5S__hyper_span_nblocks(space->select.sel_info.hslab->span_lst);
@@ -2322,8 +3658,8 @@ H5S__hyper_deserialize(H5S_t *space, uint32_t H5_ATTR_UNUSED version, uint8_t fl
{
unsigned rank; /* Rank of points */
const uint8_t *pp; /* Local pointer for decoding */
- hsize_t start[H5O_LAYOUT_NDIMS]; /* Hyperslab start information */
- hsize_t block[H5O_LAYOUT_NDIMS]; /* Hyperslab block information */
+ hsize_t start[H5S_MAX_RANK]; /* Hyperslab start information */
+ hsize_t block[H5S_MAX_RANK]; /* Hyperslab block information */
unsigned u; /* Local counting variable */
herr_t ret_value = FAIL; /* Return value */
@@ -2341,8 +3677,8 @@ H5S__hyper_deserialize(H5S_t *space, uint32_t H5_ATTR_UNUSED version, uint8_t fl
/* If there is an unlimited dimension, only encode opt_unlim_diminfo */
if(flags & H5S_SELECT_FLAG_UNLIM) {
- hsize_t stride[H5O_LAYOUT_NDIMS]; /* Hyperslab stride information */
- hsize_t count[H5O_LAYOUT_NDIMS]; /* Hyperslab count information */
+ hsize_t stride[H5S_MAX_RANK]; /* Hyperslab stride information */
+ hsize_t count[H5S_MAX_RANK]; /* Hyperslab count information */
/* Sanity checks */
HDassert(H5S_UNLIMITED == HSIZE_UNDEF);
@@ -2364,21 +3700,21 @@ H5S__hyper_deserialize(H5S_t *space, uint32_t H5_ATTR_UNUSED version, uint8_t fl
else {
const hsize_t *stride; /* Hyperslab stride information */
const hsize_t *count; /* Hyperslab count information */
- hsize_t end[H5O_LAYOUT_NDIMS]; /* Hyperslab end information */
+ hsize_t end[H5S_MAX_RANK]; /* Hyperslab end information */
hsize_t *tstart; /* Temporary hyperslab pointers */
hsize_t *tend; /* Temporary hyperslab pointers */
hsize_t *tblock; /* Temporary hyperslab pointers */
- size_t num_elem; /* Number of elements in selection */
+ size_t block_count; /* Number of blocks in selection */
unsigned v; /* Local counting variable */
- /* Decode the number of points */
- UINT32DECODE(pp, num_elem);
+ /* Decode the number of blocks */
+ UINT32DECODE(pp, block_count);
/* Set the count & stride for all blocks */
stride = count = H5S_hyper_ones_g;
/* Retrieve the coordinates from the buffer */
- for(u = 0; u < num_elem; u++) {
+ for(u = 0; u < block_count; u++) {
/* Decode the starting points */
for(tstart = start, v = 0; v < rank; v++, tstart++)
UINT32DECODE(pp, *tstart);
@@ -2451,7 +3787,7 @@ H5S__hyper_span_blocklist(const H5S_hyper_span_info_t *spans, hsize_t start[],
/* Sanity checks */
HDassert(spans);
- HDassert(rank < H5O_LAYOUT_NDIMS);
+ HDassert(rank < H5S_MAX_RANK);
HDassert(start);
HDassert(end);
HDassert(startblock);
@@ -2555,8 +3891,8 @@ H5S__get_select_hyper_blocklist(H5S_t *space, hbool_t internal, hsize_t startblo
/* Check for a "regular" hyperslab selection */
if(space->select.sel_info.hslab->diminfo_valid) {
const H5S_hyper_dim_t *diminfo; /* Alias for dataspace's diminfo information */
- hsize_t tmp_count[H5O_LAYOUT_NDIMS]; /* Temporary hyperslab counts */
- hsize_t offset[H5O_LAYOUT_NDIMS]; /* Offset of element in dataspace */
+ hsize_t tmp_count[H5S_MAX_RANK]; /* Temporary hyperslab counts */
+ hsize_t offset[H5S_MAX_RANK]; /* Offset of element in dataspace */
unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
unsigned ndims; /* Rank of the dataspace */
hbool_t done; /* Whether we are done with the iteration */
@@ -2666,8 +4002,8 @@ H5S__get_select_hyper_blocklist(H5S_t *space, hbool_t internal, hsize_t startblo
} /* end while */
} /* end if */
else {
- hsize_t start[H5O_LAYOUT_NDIMS]; /* Location of start of hyperslab */
- hsize_t end[H5O_LAYOUT_NDIMS]; /* Location of end of hyperslab */
+ hsize_t start[H5S_MAX_RANK]; /* Location of start of hyperslab */
+ hsize_t end[H5S_MAX_RANK]; /* Location of end of hyperslab */
ret_value = H5S__hyper_span_blocklist(space->select.sel_info.hslab->span_lst, start, end, (hsize_t)0, &startblock, &numblocks, &buf);
} /* end else */
@@ -2775,7 +4111,7 @@ H5S_hyper_bounds_helper(const H5S_hyper_span_info_t *spans, const hssize_t *offs
HDassert(spans);
HDassert(offset);
- HDassert(rank < H5O_LAYOUT_NDIMS);
+ HDassert(rank < H5S_MAX_RANK);
HDassert(start);
HDassert(end);
@@ -3079,7 +4415,7 @@ done:
EXAMPLES
REVISION LOG
--------------------------------------------------------------------------*/
-static htri_t
+static H5_ATTR_PURE htri_t
H5S__hyper_is_contiguous(const H5S_t *space)
{
hbool_t small_contiguous, /* Flag for small contiguous block */
@@ -3149,10 +4485,10 @@ H5S__hyper_is_contiguous(const H5S_t *space)
/*
* For a hyperslab to be contiguous, it must have only one block and
- * (either it's size must be the same as the dataspace extent's in all
- * but the slowest changing dimension
- * OR
- * block size must be 1 in all but the fastest changing dimension).
+ * either it's size must be the same as the dataspace extent's in all
+ * but the slowest changing dimension
+ * OR
+ * block size must be 1 in all but the fastest changing dimension.
*/
/* Initialize flags */
large_contiguous = TRUE; /* assume true and reset if the dimensions don't match */
@@ -3264,7 +4600,7 @@ H5S__hyper_is_contiguous(const H5S_t *space)
EXAMPLES
REVISION LOG
--------------------------------------------------------------------------*/
-static htri_t
+static H5_ATTR_PURE htri_t
H5S__hyper_is_single(const H5S_t *space)
{
htri_t ret_value = TRUE; /* return value */
@@ -3283,10 +4619,9 @@ H5S__hyper_is_single(const H5S_t *space)
*/
/* Check for a single block */
- for(u = 0; u < space->extent.rank; u++) {
+ for(u = 0; u < space->extent.rank; u++)
if(space->select.sel_info.hslab->opt_diminfo[u].count > 1)
HGOTO_DONE(FALSE)
- } /* end for */
} /* end if */
else {
H5S_hyper_span_info_t *spans; /* Hyperslab span info node */
@@ -3893,125 +5228,6 @@ done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5S_hyper_convert() */
-#ifdef LATER
-
-/*--------------------------------------------------------------------------
- NAME
- H5S_hyper_intersect_helper
- PURPOSE
- Helper routine to detect intersections in span trees
- USAGE
- htri_t H5S_hyper_intersect_helper(spans1, spans2)
- H5S_hyper_span_info_t *spans1; IN: First span tree to operate with
- H5S_hyper_span_info_t *spans2; IN: Second span tree to operate with
- RETURNS
- Non-negative on success, negative on failure
- DESCRIPTION
- Quickly detect intersections between two span trees
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-static htri_t
-H5S_hyper_intersect_helper (H5S_hyper_span_info_t *spans1, H5S_hyper_span_info_t *spans2)
-{
- H5S_hyper_span_t *curr1; /* Pointer to current span in 1st span tree */
- H5S_hyper_span_t *curr2; /* Pointer to current span in 2nd span tree */
- htri_t status; /* Status from recursive call */
- htri_t ret_value=FALSE; /* Return value */
-
- FUNC_ENTER_NOAPI_NOINIT
-
- /* Sanity check */
- HDassert((spans1 && spans2) || (spans1 == NULL && spans2 == NULL));
-
- /* "NULL" span trees compare as overlapping */
- if(spans1==NULL && spans2==NULL)
- HGOTO_DONE(TRUE);
-
- /* Get the span lists for each span in this tree */
- curr1=spans1->head;
- curr2=spans2->head;
-
- /* Iterate over the spans in each tree */
- while(curr1!=NULL && curr2!=NULL) {
- /* Check for 1st span entirely before 2nd span */
- if(curr1->high<curr2->low)
- curr1=curr1->next;
- /* Check for 2nd span entirely before 1st span */
- else if(curr2->high<curr1->low)
- curr2=curr2->next;
- /* Spans must overlap */
- else {
- /* Recursively check spans in next dimension down */
- if((status=H5S_hyper_intersect_helper(curr1->down,curr2->down))<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_BADSELECT, FAIL, "can't perform hyperslab intersection check")
-
- /* If there is a span intersection in the down dimensions, the span trees overlap */
- if(status==TRUE)
- HGOTO_DONE(TRUE);
-
- /* No intersection in down dimensions, advance to next span */
- if(curr1->high<curr2->high)
- curr1=curr1->next;
- else
- curr2=curr2->next;
- } /* end else */
- } /* end while */
-
-done:
- FUNC_LEAVE_NOAPI(ret_value)
-} /* H5S_hyper_intersect_helper() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5S_hyper_intersect
- PURPOSE
- Detect intersections in span trees
- USAGE
- htri_t H5S_hyper_intersect(space1, space2)
- H5S_t *space1; IN: First dataspace to operate on span tree
- H5S_t *space2; IN: Second dataspace to operate on span tree
- RETURNS
- Non-negative on success, negative on failure
- DESCRIPTION
- Quickly detect intersections between two span trees
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-htri_t
-H5S_hyper_intersect (H5S_t *space1, H5S_t *space2)
-{
- htri_t ret_value=FAIL; /* Return value */
-
- FUNC_ENTER_NOAPI_NOINIT
-
- /* Sanity check */
- HDassert(space1);
- HDassert(space2);
-
- /* Check that the space selections both have span trees */
- if(space1->select.sel_info.hslab->span_lst==NULL ||
- space2->select.sel_info.hslab->span_lst==NULL)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNINITIALIZED, FAIL, "dataspace does not have span tree")
-
- /* Check that the dataspaces are both the same rank */
- if(space1->extent.rank!=space2->extent.rank)
- HGOTO_ERROR(H5E_DATASPACE, H5E_BADRANGE, FAIL, "dataspace ranks don't match")
-
- /* Perform the span-by-span intersection check */
- if((ret_value=H5S_hyper_intersect_helper(space1->select.sel_info.hslab->span_lst,space2->select.sel_info.hslab->span_lst))<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_BADSELECT, FAIL, "can't perform hyperslab intersection check")
-
-done:
- FUNC_LEAVE_NOAPI(ret_value)
-} /* H5S_hyper_intersect() */
-#endif /* LATER */
-
/*--------------------------------------------------------------------------
NAME
@@ -4019,13 +5235,12 @@ done:
PURPOSE
Helper routine to detect intersections in span trees
USAGE
- htri_t H5S_hyper_intersect_block_helper(spans, start, end)
+ hbool_t H5S__hyper_intersect_block_helper(spans, start, end)
H5S_hyper_span_info_t *spans; IN: First span tree to operate with
- hssize_t *offset; IN: Selection offset coordinate
hsize_t *start; IN: Starting coordinate for block
hsize_t *end; IN: Ending coordinate for block
RETURN
- Non-negative on success, negative on failure
+ Non-negative (TRUE/FALSE) on success, can't fail
DESCRIPTION
Quickly detect intersections between span tree and block
GLOBAL VARIABLES
@@ -4248,7 +5463,7 @@ H5S__hyper_adjust_u(H5S_t *space, const hsize_t *offset)
* Purpose: Projects a single element hyperslab selection into a scalar
* dataspace
*
- * Return: non-negative on success, negative on failure.
+ * Return: Non-negative on success, negative on failure.
*
* Programmer: Quincey Koziol
* Sunday, July 18, 2010
@@ -4311,7 +5526,7 @@ H5S__hyper_project_scalar(const H5S_t *space, hsize_t *offset)
* Purpose: Projects a hyperslab selection onto/into a simple dataspace
* of a lower rank
*
- * Return: non-negative on success, negative on failure.
+ * Return: Non-negative on success, negative on failure.
*
* Programmer: Quincey Koziol
* Sunday, July 18, 2010
@@ -4358,7 +5573,7 @@ H5S__hyper_project_simple_lower(const H5S_t *base_space, H5S_t *new_space)
* Purpose: Projects a hyperslab selection onto/into a simple dataspace
* of a higher rank
*
- * Return: non-negative on success, negative on failure.
+ * Return: Non-negative on success, negative on failure.
*
* Programmer: Quincey Koziol
* Sunday, July 18, 2010
@@ -4369,6 +5584,7 @@ static herr_t
H5S__hyper_project_simple_higher(const H5S_t *base_space, H5S_t *new_space)
{
H5S_hyper_span_t *prev_span = NULL; /* Pointer to previous list of spans */
+ unsigned delta_rank; /* Difference in dataspace ranks */
unsigned curr_dim; /* Current dimension being operated on */
herr_t ret_value = SUCCEED; /* Return value */
@@ -4382,7 +5598,8 @@ H5S__hyper_project_simple_higher(const H5S_t *base_space, H5S_t *new_space)
/* Create nodes until reaching the correct # of dimensions */
new_space->select.sel_info.hslab->span_lst = NULL;
curr_dim = 0;
- while(curr_dim < (new_space->extent.rank - base_space->extent.rank)) {
+ delta_rank = (new_space->extent.rank - base_space->extent.rank);
+ while(curr_dim < delta_rank) {
H5S_hyper_span_info_t *new_span_info; /* Pointer to list of spans */
H5S_hyper_span_t *new_span; /* Temporary hyperslab span */
@@ -4446,7 +5663,7 @@ done:
* Purpose: Projects a hyperslab selection onto/into a simple dataspace
* of a different rank
*
- * Return: non-negative on success, negative on failure.
+ * Return: Non-negative on success, negative on failure.
*
* Programmer: Quincey Koziol
* Sunday, July 18, 2010
@@ -4454,7 +5671,8 @@ done:
*-------------------------------------------------------------------------
*/
static herr_t
-H5S__hyper_project_simple(const H5S_t *base_space, H5S_t *new_space, hsize_t *offset)
+H5S__hyper_project_simple(const H5S_t *base_space, H5S_t *new_space,
+ hsize_t *offset)
{
herr_t ret_value = SUCCEED; /* Return value */
@@ -4723,11 +5941,11 @@ done:
"Normalize" a hyperslab selection by adjusting it's coordinates by the
amount of the selection offset.
USAGE
- hbool_t H5S_hyper_normalize_offset(space, old_offset)
+ htri_t H5S_hyper_normalize_offset(space, old_offset)
H5S_t *space; IN/OUT: Pointer to dataspace to move
hssize_t *old_offset; OUT: Pointer to space to store old offset
RETURNS
- TRUE if space has been normalized, FALSE if not
+ TRUE/FALSE for hyperslab selection, FAIL on error
DESCRIPTION
Copies the current selection offset into the array provided, then
inverts the selection offset, subtracts the offset from the hyperslab
@@ -4740,7 +5958,7 @@ done:
htri_t
H5S_hyper_normalize_offset(H5S_t *space, hssize_t *old_offset)
{
- htri_t ret_value = FALSE; /* Return value */
+ htri_t ret_value = FALSE; /* Return value */
FUNC_ENTER_NOAPI(FAIL)
@@ -4943,9 +6161,10 @@ done:
DESCRIPTION
Clip one span tree ('a') against another span tree ('b'). Creates span
trees for the area defined by the 'a' span tree which does not overlap the
- 'b' span tree, the area defined by the overlap of the 'a' hyperslab span
- tree and the 'b' span tree, and the area defined by the 'b' hyperslab span
- tree which does not overlap the 'a' span tree.
+ 'b' span tree ("a not b"), the area defined by the overlap of the 'a'
+ hyperslab span tree and the 'b' span tree ("a and b"), and the area defined
+ by the 'b' hyperslab span tree which does not overlap the 'a' span
+ tree ("b not a").
GLOBAL VARIABLES
COMMENTS, BUGS, ASSUMPTIONS
EXAMPLES
@@ -5101,10 +6320,10 @@ H5S__hyper_clip_spans(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_info_t *b_s
/* Split off upper part of span 'b' at upper span of span 'a' */
/* Check if there is actually an upper part of span 'b' to split off */
- if(span_a->high<span_b->high) {
+ if(span_a->high < span_b->high) {
/* Allocate new span node for upper part of span 'b' */
if(NULL == (tmp_span = H5S__hyper_new_span(span_a->high + 1, span_b->high, span_b->down, span_b->next)))
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't allocate hyperslab span")
+ HGOTO_ERROR(H5E_DATASPACE, H5E_NOSPACE, FAIL, "can't allocate hyperslab span")
/* Advance span 'a' */
H5S__hyper_recover_span(&recover_a,&span_a,span_a->next);
@@ -5269,12 +6488,12 @@ H5S__hyper_clip_spans(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_info_t *b_s
} /* end else */
/* Check if there is actually an upper part of span 'b' to split off */
- if(span_a->high<span_b->high) {
+ if(span_a->high < span_b->high) {
/* Split off upper part of span 'b' at upper span of span 'a' */
/* Allocate new span node for upper part of spans 'a' */
if(NULL == (tmp_span = H5S__hyper_new_span(span_a->high + 1, span_b->high, span_b->down, span_b->next)))
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't allocate hyperslab span")
+ HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate hyperslab span")
/* And advance span 'a' */
H5S__hyper_recover_span(&recover_a,&span_a,span_a->next);
@@ -5294,9 +6513,9 @@ H5S__hyper_clip_spans(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_info_t *b_s
/* AAAAAAAAAA */
/* <-----------------------------------> */
/* BBBBBBBBBB */
- else if((span_a->low>=span_b->low && span_a->low<=span_b->high) && span_a->high>span_b->high) {
+ else if((span_a->low >= span_b->low && span_a->low <= span_b->high) && span_a->high > span_b->high) {
/* Check if there is actually a lower part of span 'b' to split off */
- if(span_a->low>span_b->low) {
+ if(span_a->low > span_b->low) {
/* Split off lower part of span 'b' at lower span of span 'a' */
/* Merge/add lower part of span 'b' with/to b_not_a list */
@@ -5364,7 +6583,7 @@ H5S__hyper_clip_spans(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_info_t *b_s
/* Allocate new span node for upper part of span 'a' */
if(NULL == (tmp_span = H5S__hyper_new_span(span_b->high + 1, span_a->high, span_a->down, span_a->next)))
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't allocate hyperslab span")
+ HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate hyperslab span")
/* Make upper part of span 'a' into new span 'a' */
H5S__hyper_recover_span(&recover_a,&span_a,tmp_span);
@@ -5448,12 +6667,6 @@ static H5S_hyper_span_info_t *
H5S__hyper_merge_spans_helper(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_info_t *b_spans)
{
H5S_hyper_span_info_t *merged_spans = NULL; /* Pointer to the merged span tree */
- H5S_hyper_span_info_t *tmp_spans; /* Pointer to temporary new span tree */
- H5S_hyper_span_t *tmp_span; /* Pointer to temporary new span */
- H5S_hyper_span_t *span_a; /* Pointer to current span 'a' working on */
- H5S_hyper_span_t *span_b; /* Pointer to current span 'b' working on */
- H5S_hyper_span_t *prev_span_merge; /* Pointer to previous merged span */
- hbool_t recover_a, recover_b; /* Flags to indicate when to recover temporary spans */
H5S_hyper_span_info_t *ret_value = NULL; /* Return value */
FUNC_ENTER_STATIC
@@ -5472,6 +6685,11 @@ H5S__hyper_merge_spans_helper(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_inf
} /* end else */
} /* end if */
else {
+ H5S_hyper_span_t *span_a; /* Pointer to current span 'a' working on */
+ H5S_hyper_span_t *span_b; /* Pointer to current span 'b' working on */
+ H5S_hyper_span_t *prev_span_merge; /* Pointer to previous merged span */
+ hbool_t recover_a, recover_b; /* Flags to indicate when to recover temporary spans */
+
/* Get the pointers to the 'a' and 'b' span lists */
span_a = a_spans->head;
span_b = b_spans->head;
@@ -5484,6 +6702,9 @@ H5S__hyper_merge_spans_helper(H5S_hyper_span_info_t *a_spans, H5S_hyper_span_inf
/* Work through the list of spans in the new list */
while(span_a != NULL && span_b != NULL) {
+ H5S_hyper_span_info_t *tmp_spans; /* Pointer to temporary new span tree */
+ H5S_hyper_span_t *tmp_span; /* Pointer to temporary new span */
+
/* Check if the 'a' span is completely before 'b' span */
/* AAAAAAA */
/* <-----------------------------------> */
@@ -5766,7 +6987,7 @@ done:
static herr_t
H5S__hyper_merge_spans(H5S_t *space, H5S_hyper_span_info_t *new_spans, hbool_t can_own)
{
- FUNC_ENTER_NOAPI_NOINIT_NOERR
+ FUNC_ENTER_STATIC_NOERR
/* Check args */
HDassert(space);
@@ -5852,12 +7073,12 @@ H5S__hyper_spans_nelem(const H5S_hyper_span_info_t *spans)
Create a span tree
USAGE
H5S_hyper_span_t *H5S__hyper_make_spans(rank, start, stride, count, block)
- unsigned rank; IN: # of dimensions of the space
- const hsize_t *start; IN: Starting location of the hyperslabs
- const hsize_t *stride; IN: Stride from the beginning of one block to
+ unsigned rank; IN: # of dimensions of the space
+ const hsize_t *start; IN: Starting location of the hyperslabs
+ const hsize_t *stride; IN: Stride from the beginning of one block to
the next
- const hsize_t *count; IN: Number of blocks
- const hsize_t *block; IN: Size of hyperslab block
+ const hsize_t *count; IN: Number of blocks
+ const hsize_t *block; IN: Size of hyperslab block
RETURNS
Pointer to new span tree on success, NULL on failure
DESCRIPTION
@@ -6141,7 +7362,7 @@ done:
static hbool_t
H5S__hyper_rebuild(H5S_t *space)
{
- H5S_hyper_dim_t top_span_slab_info[H5O_LAYOUT_NDIMS];
+ H5S_hyper_dim_t top_span_slab_info[H5S_MAX_RANK];
unsigned rank, curr_dim;
hbool_t ret_value = TRUE; /* Return value */
@@ -6203,12 +7424,12 @@ done:
static herr_t
H5S__hyper_generate_spans(H5S_t *space)
{
- hsize_t tmp_start[H5O_LAYOUT_NDIMS]; /* Temporary start information */
- hsize_t tmp_stride[H5O_LAYOUT_NDIMS]; /* Temporary stride information */
- hsize_t tmp_count[H5O_LAYOUT_NDIMS]; /* Temporary count information */
- hsize_t tmp_block[H5O_LAYOUT_NDIMS]; /* Temporary block information */
- unsigned u; /* Local index variable */
- herr_t ret_value = SUCCEED; /* Return value */
+ hsize_t tmp_start[H5S_MAX_RANK]; /* Temporary start information */
+ hsize_t tmp_stride[H5S_MAX_RANK]; /* Temporary stride information */
+ hsize_t tmp_count[H5S_MAX_RANK]; /* Temporary count information */
+ hsize_t tmp_block[H5S_MAX_RANK]; /* Temporary block information */
+ unsigned u; /* Local index variable */
+ herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_STATIC
@@ -6240,7 +7461,6 @@ done:
FUNC_LEAVE_NOAPI(ret_value)
} /* end H5S__hyper_generate_spans() */
-#ifndef NEW_HYPERSLAB_API
/*-------------------------------------------------------------------------
* Function: H5S__generate_hyperlab
@@ -6249,19 +7469,14 @@ done:
*
* Return: Non-negative on success/Negative on failure
*
- * Programmer: Quincey Koziol (split from HS_select_hyperslab()).
+ * Programmer: Quincey Koziol
* Tuesday, September 12, 2000
*
- * Modifications:
- *
*-------------------------------------------------------------------------
*/
static herr_t
-H5S__generate_hyperslab (H5S_t *space, H5S_seloper_t op,
- const hsize_t start[],
- const hsize_t stride[],
- const hsize_t count[],
- const hsize_t block[])
+H5S__generate_hyperslab(H5S_t *space, H5S_seloper_t op, const hsize_t start[],
+ const hsize_t stride[], const hsize_t count[], const hsize_t block[])
{
H5S_hyper_span_info_t *new_spans=NULL; /* Span tree for new hyperslab */
H5S_hyper_span_info_t *a_not_b = NULL; /* Span tree for hyperslab spans in old span tree and not in new span tree */
@@ -6293,7 +7508,7 @@ H5S__generate_hyperslab (H5S_t *space, H5S_seloper_t op,
space->select.num_elem = H5S__hyper_spans_nelem(new_spans);
/* Indicate that the new_spans are owned */
- new_spans=NULL;
+ new_spans = NULL;
} /* end if */
else {
hbool_t updated_spans = FALSE; /* Whether the spans in the selection were modified */
@@ -6502,9 +7717,9 @@ herr_t
H5S_select_hyperslab(H5S_t *space, H5S_seloper_t op, const hsize_t start[],
const hsize_t *stride, const hsize_t count[], const hsize_t *block)
{
- hsize_t int_stride[H5O_LAYOUT_NDIMS]; /* Internal storage for stride information */
- hsize_t int_count[H5O_LAYOUT_NDIMS]; /* Internal storage for count information */
- hsize_t int_block[H5O_LAYOUT_NDIMS]; /* Internal storage for block information */
+ hsize_t int_stride[H5S_MAX_RANK]; /* Internal storage for stride information */
+ hsize_t int_count[H5S_MAX_RANK]; /* Internal storage for count information */
+ hsize_t int_block[H5S_MAX_RANK]; /* Internal storage for block information */
const hsize_t *opt_stride; /* Optimized stride information */
const hsize_t *opt_count; /* Optimized count information */
const hsize_t *opt_block; /* Optimized block information */
@@ -6528,9 +7743,7 @@ H5S_select_hyperslab(H5S_t *space, H5S_seloper_t op, const hsize_t start[],
if(block == NULL)
block = H5S_hyper_ones_g;
- /*
- * Check new selection.
- */
+ /* Check new selection */
for(u = 0; u < space->extent.rank; u++) {
/* Check for overlapping hyperslab blocks in new selection. */
if(count[u] > 1 && stride[u] < block[u])
@@ -6566,7 +7779,7 @@ H5S_select_hyperslab(H5S_t *space, H5S_seloper_t op, const hsize_t start[],
if(unlim_dim >= 0)
HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "cannot have more than one unlimited dimension in selection")
else {
- if(count[u] == block[u] /* == H5S_UNLIMITED */)
+ if(count[u] == block[u]) /* Both are H5S_UNLIMITED */
HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "count and block cannot both be unlimited")
unlim_dim = (int)u;
} /* end else */
@@ -6795,7 +8008,8 @@ H5S_select_hyperslab(H5S_t *space, H5S_seloper_t op, const hsize_t start[],
HGOTO_ERROR(H5E_DATASPACE, H5E_CANTGET, FAIL, "can't get selection bounds")
/* Patch count and block to remove unlimited and include the
- * existing selection */
+ * existing selection.
+ */
H5S__hyper_get_clip_diminfo(start[unlim_dim], opt_stride[unlim_dim], &tmp_count, &tmp_block, bounds_end[unlim_dim] + (hsize_t)1);
HDassert((tmp_count == 1) || (opt_count != H5S_hyper_ones_g));
HDassert((tmp_block == 1) || (opt_block != H5S_hyper_ones_g));
@@ -6895,2342 +8109,6 @@ H5Sselect_hyperslab(hid_t space_id, H5S_seloper_t op, const hsize_t start[],
done:
FUNC_LEAVE_API(ret_value)
} /* end H5Sselect_hyperslab() */
-#else /* NEW_HYPERSLAB_API */ /* Works */
-
-/*-------------------------------------------------------------------------
- * Function: H5S_operate_hyperslab
- *
- * Purpose: Combines two hyperslabs with an operation, putting the
- * result into a third hyperslab selection
- *
- * Return: non-negative on success/NULL on failure
- *
- * Programmer: Quincey Koziol
- * Tuesday, October 30, 2001
- *
- * Modifications:
- *
- *-------------------------------------------------------------------------
- */
-static herr_t
-H5S_operate_hyperslab (H5S_t *result, H5S_hyper_span_info_t *spans1, H5S_seloper_t op, H5S_hyper_span_info_t *spans2,
- hbool_t can_own_span2, hbool_t *span2_owned)
-{
- H5S_hyper_span_info_t *a_not_b=NULL; /* Span tree for hyperslab spans in old span tree and not in new span tree */
- H5S_hyper_span_info_t *a_and_b=NULL; /* Span tree for hyperslab spans in both old and new span trees */
- H5S_hyper_span_info_t *b_not_a=NULL; /* Span tree for hyperslab spans in new span tree and not in old span tree */
- herr_t ret_value=SUCCEED; /* Return value */
-
- FUNC_ENTER_NOAPI_NOINIT
-
- /* Check args */
- HDassert(result);
- HDassert(spans2);
- HDassert(op > H5S_SELECT_NOOP && op < H5S_SELECT_INVALID);
-
- /* Just copy the selection from spans2 if we are setting the selection */
- /* ('space1' to 'result' aliasing happens at the next layer up) */
- if(op==H5S_SELECT_SET) {
- if(H5S__hyper_merge_spans(result,spans2,can_own_span2)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem = H5S__hyper_spans_nelem(spans2);
-
- /* Indicate that we took ownership of span2, if allowed */
- if(can_own_span2)
- *span2_owned=TRUE;
- } /* end if */
- else {
- hbool_t updated_spans = FALSE; /* Whether the spans in the selection were modified */
-
- HDassert(spans1);
-
- /* Generate lists of spans which overlap and don't overlap */
- if(H5S__hyper_clip_spans(spans1,spans2,&a_not_b,&a_and_b,&b_not_a)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCLIP, FAIL, "can't clip hyperslab information")
-
- /* Switch on the operation */
- switch(op) {
- case H5S_SELECT_OR:
- /* Copy spans from spans1 to current selection */
- if(spans1!=NULL) {
- if(H5S__hyper_merge_spans(result,spans1,FALSE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem = H5S__hyper_spans_nelem(spans1);
- } /* end if */
-
- /* Add any new spans from spans2 to current selection */
- if(b_not_a!=NULL) {
- if(H5S__hyper_merge_spans(result,b_not_a,FALSE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem += H5S__hyper_spans_nelem(b_not_a);
-
- /* Indicate that the spans were updated */
- updated_spans = TRUE;
- } /* end if */
- break;
-
- case H5S_SELECT_AND:
- /* Check if there are any overlapped selections */
- if(a_and_b!=NULL) {
- if(H5S__hyper_merge_spans(result,a_and_b,TRUE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem = H5S__hyper_spans_nelem(a_and_b);
-
- /* Indicate that the result owns the a_and_b spans */
- a_and_b=NULL;
-
- /* Indicate that the spans were updated */
- updated_spans = TRUE;
- } /* end if */
- break;
-
- case H5S_SELECT_XOR:
- /* Check if there are any non-overlapped selections */
- if(a_not_b!=NULL) {
- if(H5S__hyper_merge_spans(result,a_not_b,FALSE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem = H5S__hyper_spans_nelem(a_not_b);
-
- /* Indicate that the spans were updated */
- updated_spans = TRUE;
- } /* end if */
- if(b_not_a!=NULL) {
- if(H5S__hyper_merge_spans(result,b_not_a,FALSE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem += H5S__hyper_spans_nelem(b_not_a);
-
- /* Indicate that the spans were updated */
- updated_spans = TRUE;
- } /* end if */
- break;
-
- case H5S_SELECT_NOTB:
- /* Check if there are any non-overlapped selections */
- if(a_not_b!=NULL) {
- if(H5S__hyper_merge_spans(result,a_not_b,TRUE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem = H5S__hyper_spans_nelem(a_not_b);
-
- /* Indicate that the result owns the a_not_b spans */
- a_not_b=NULL;
-
- /* Indicate that the spans were updated */
- updated_spans = TRUE;
- } /* end if */
- break;
-
- case H5S_SELECT_NOTA:
- /* Check if there are any non-overlapped selections */
- if(b_not_a!=NULL) {
- if(H5S__hyper_merge_spans(result,b_not_a,TRUE)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't insert hyperslabs")
-
- /* Update the number of elements in current selection */
- result->select.num_elem = H5S__hyper_spans_nelem(b_not_a);
-
- /* Indicate that the result owns the b_not_a spans */
- b_not_a=NULL;
-
- /* Indicate that the spans were updated */
- updated_spans = TRUE;
- } /* end if */
- break;
-
- default:
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
- } /* end switch */
-
- /* Free the hyperslab trees generated from the clipping algorithm */
- if(a_not_b)
- H5S__hyper_free_span_info(a_not_b);
- if(a_and_b)
- H5S__hyper_free_span_info(a_and_b);
- if(b_not_a)
- H5S__hyper_free_span_info(b_not_a);
-
- /* Check if the resulting hyperslab span tree is empty */
- if(result->select.sel_info.hslab->span_lst==NULL) {
- H5S_hyper_span_info_t *spans; /* Empty hyperslab span tree */
-
- /* Sanity check */
- HDassert(result->select.num_elem == 0);
-
- /* Allocate a span info node */
- if((spans = H5FL_MALLOC(H5S_hyper_span_info_t))==NULL)
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "can't allocate hyperslab span")
-
- /* Set the reference count */
- spans->count=1;
-
- /* Reset the scratch pad space */
- spans->scratch=0;
-
- /* Set to empty tree */
- spans->head=NULL;
-
- /* Set pointer to empty span tree */
- result->select.sel_info.hslab->span_lst=spans;
- } /* end if */
- else {
- /* Check if we updated the spans */
- if(updated_spans) {
- /* Attempt to rebuild "optimized" start/stride/count/block information.
- * from resulting hyperslab span tree
- */
- H5S__hyper_rebuild(result);
- } /* end if */
- } /* end else */
- } /* end else */
-
-done:
- FUNC_LEAVE_NOAPI(ret_value)
-} /* end H5S_operate_hyperslab() */
-
-
-/*-------------------------------------------------------------------------
- * Function: H5S_generate_hyperlab
- *
- * Purpose: Generate hyperslab information from H5S_select_hyperslab()
- *
- * Return: Non-negative on success/Negative on failure
- *
- * Programmer: Quincey Koziol (split from HS_select_hyperslab()).
- * Tuesday, September 12, 2000
- *
- * Modifications:
- *
- *-------------------------------------------------------------------------
- */
-static herr_t
-H5S__generate_hyperslab(H5S_t *space, H5S_seloper_t op, const hsize_t start[],
- const hsize_t stride[], const hsize_t count[], const hsize_t block[])
-{
- H5S_hyper_span_info_t *new_spans=NULL; /* Span tree for new hyperslab */
- H5S_hyper_span_info_t *tmp_spans=NULL; /* Temporary copy of selection */
- hbool_t span2_owned=FALSE; /* Flag to indicate that span2 was used in H5S_operate_hyperslab() */
- herr_t ret_value=SUCCEED; /* Return value */
-
- FUNC_ENTER_NOAPI_NOINIT
-
- /* Check args */
- HDassert(space);
- HDassert(op > H5S_SELECT_NOOP && op < H5S_SELECT_INVALID);
- HDassert(start);
- HDassert(stride);
- HDassert(count);
- HDassert(block);
-
- /* Generate span tree for new hyperslab information */
- if(NULL == (new_spans = H5S__hyper_make_spans(space->extent.rank, start, stride, count, block)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't create hyperslab information")
-
- /* Copy the original dataspace */
- if(space->select.sel_info.hslab->span_lst!=NULL) {
- /* Take ownership of the dataspace's hyperslab spans */
- /* (These are freed later) */
- tmp_spans=space->select.sel_info.hslab->span_lst;
- space->select.sel_info.hslab->span_lst=NULL;
-
- /* Reset the other dataspace selection information */
- if(H5S_SELECT_RELEASE(space)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, FAIL, "can't release selection")
-
- /* Allocate space for the hyperslab selection information */
- if((space->select.sel_info.hslab=H5FL_MALLOC(H5S_hyper_sel_t))==NULL)
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't allocate hyperslab info")
-
- /* Set unlim_dim */
- space->select.sel_info.hslab->unlim_dim = -1;
- } /* end if */
-
- /* Combine tmp_space (really space) & new_space, with the result in space */
- if(H5S_operate_hyperslab(space,tmp_spans,op,new_spans,TRUE,&span2_owned)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCLIP, FAIL, "can't clip hyperslab information")
-
-done:
- /* Free temporary data structures */
- if(tmp_spans!=NULL)
- if(H5S__hyper_free_span_info(tmp_spans)<0)
- HDONE_ERROR(H5E_INTERNAL, H5E_CANTFREE, FAIL, "failed to release temporary hyperslab spans")
- if(new_spans!=NULL && span2_owned==FALSE)
- if(H5S__hyper_free_span_info(new_spans)<0)
- HDONE_ERROR(H5E_INTERNAL, H5E_CANTFREE, FAIL, "failed to release temporary hyperslab spans")
-
- FUNC_LEAVE_NOAPI(ret_value)
-} /* end H5S__generate_hyperslab() */
-
-
-/*-------------------------------------------------------------------------
- * Function: H5S_select_hyperslab
- *
- * Purpose: Internal version of H5Sselect_hyperslab().
- *
- * Return: Non-negative on success/Negative on failure
- *
- * Programmer: Quincey Koziol
- * Wednesday, January 10, 2001
- *
- * Modifications:
- *
- *-------------------------------------------------------------------------
- */
-herr_t
-H5S_select_hyperslab (H5S_t *space, H5S_seloper_t op,
- const hsize_t start[],
- const hsize_t *stride,
- const hsize_t count[],
- const hsize_t *block)
-{
- hsize_t int_stride[H5O_LAYOUT_NDIMS]; /* Internal storage for stride information */
- hsize_t int_count[H5O_LAYOUT_NDIMS]; /* Internal storage for count information */
- hsize_t int_block[H5O_LAYOUT_NDIMS]; /* Internal storage for block information */
- const hsize_t *opt_stride; /* Optimized stride information */
- const hsize_t *opt_count; /* Optimized count information */
- const hsize_t *opt_block; /* Optimized block information */
- unsigned u; /* Counters */
- int unlim_dim = -1; /* Unlimited dimension in selection, of -1 if none */
- herr_t ret_value=SUCCEED; /* Return value */
-
- FUNC_ENTER_NOAPI(FAIL)
-
- /* Check args */
- HDassert(space);
- HDassert(start);
- HDassert(count);
- HDassert(op > H5S_SELECT_NOOP && op < H5S_SELECT_INVALID);
-
- /* Point to the correct stride values */
- if(stride==NULL)
- stride = H5S_hyper_ones_g;
-
- /* Point to the correct block values */
- if(block==NULL)
- block = H5S_hyper_ones_g;
-
- /* Check for unlimited dimension */
- for(u = 0; u<space->extent.rank; u++)
- if((count[u] == H5S_UNLIMITED) || (block[u] == H5S_UNLIMITED)) {
- if(unlim_dim >= 0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "cannot have more than one unlimited dimension in selection")
- else {
- if(count[u] == block[u] /* == H5S_UNLIMITED */)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "count and block cannot both be unlimited")
- unlim_dim = (int)u;
- } /* end else */
- } /* end if */
-
- /*
- * Check new selection.
- */
- for(u=0; u<space->extent.rank; u++) {
- /* Check for overlapping hyperslab blocks in new selection. */
- if(count[u]>1 && stride[u]<block[u])
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "hyperslab blocks overlap")
-
- /* Detect zero-sized hyperslabs in new selection */
- if(count[u] == 0 || block[u] == 0) {
- switch(op) {
- case H5S_SELECT_SET: /* Select "set" operation */
- case H5S_SELECT_AND: /* Binary "and" operation for hyperslabs */
- case H5S_SELECT_NOTA: /* Binary "B not A" operation for hyperslabs */
- /* Convert to "none" selection */
- if(H5S_select_none(space)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, FAIL, "can't convert selection")
- HGOTO_DONE(SUCCEED);
-
- case H5S_SELECT_OR: /* Binary "or" operation for hyperslabs */
- case H5S_SELECT_XOR: /* Binary "xor" operation for hyperslabs */
- case H5S_SELECT_NOTB: /* Binary "A not B" operation for hyperslabs */
- HGOTO_DONE(SUCCEED); /* Selection stays same */
-
- default:
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
- } /* end switch */
- } /* end if */
- } /* end for */
-
- /* Optimize hyperslab parameters to merge contiguous blocks, etc. */
- if(stride == H5S_hyper_ones_g && block == H5S_hyper_ones_g) {
- /* Point to existing arrays */
- opt_stride = H5S_hyper_ones_g;
- opt_count = H5S_hyper_ones_g;
- opt_block = count;
- } /* end if */
- else {
- /* Point to local arrays */
- opt_stride = int_stride;
- opt_count = int_count;
- opt_block = int_block;
- for(u=0; u<space->extent.rank; u++) {
- /* contiguous hyperslabs have the block size equal to the stride */
- if((stride[u] == block[u]) && (count[u] != H5S_UNLIMITED)) {
- int_count[u]=1;
- int_stride[u]=1;
- if(block[u]==1)
- int_block[u]=count[u];
- else
- int_block[u]=block[u]*count[u];
- } /* end if */
- else {
- if(count[u]==1)
- int_stride[u]=1;
- else {
- HDassert((stride[u] > block[u]) || ((stride[u] == block[u])
- && (count[u] == H5S_UNLIMITED)));
- int_stride[u]=stride[u];
- } /* end else */
- int_count[u]=count[u];
- int_block[u]=block[u];
- } /* end else */
- } /* end for */
- } /* end else */
-
- /* Check for operating on unlimited selection */
- if((H5S_GET_SELECT_TYPE(space) == H5S_SEL_HYPERSLABS)
- && (space->select.sel_info.hslab->unlim_dim >= 0)
- && (op != H5S_SELECT_SET))
- {
- /* Check for invalid operation */
- if(unlim_dim >= 0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "cannot modify unlimited selection with another unlimited selection")
- if(!((op == H5S_SELECT_AND) || (op == H5S_SELECT_NOTA)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "unsupported operation on unlimited selection")
- HDassert(space->select.sel_info.hslab->diminfo_valid);
-
- /* Clip unlimited selection to include new selection */
- if(H5S_hyper_clip_unlim(space,
- start[space->select.sel_info.hslab->unlim_dim]
- + ((opt_count[space->select.sel_info.hslab->unlim_dim]
- - (hsize_t)1)
- * opt_stride[space->select.sel_info.hslab->unlim_dim])
- + opt_block[space->select.sel_info.hslab->unlim_dim]) < 0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCLIP, FAIL, "failed to clip unlimited selection")
-
- /* If an empty space was returned it must be "none" */
- HDassert((space->select.num_elem > (hsize_t)0)
- || (space->select.type->type == H5S_SEL_NONE));
- } /* end if */
-
- /* Fixup operation for non-hyperslab selections */
- switch(H5S_GET_SELECT_TYPE(space)) {
- case H5S_SEL_NONE: /* No elements selected in dataspace */
- switch(op) {
- case H5S_SELECT_SET: /* Select "set" operation */
- /* Change "none" selection to hyperslab selection */
- break;
-
- case H5S_SELECT_OR: /* Binary "or" operation for hyperslabs */
- case H5S_SELECT_XOR: /* Binary "xor" operation for hyperslabs */
- case H5S_SELECT_NOTA: /* Binary "B not A" operation for hyperslabs */
- op=H5S_SELECT_SET; /* Maps to "set" operation when applied to "none" selection */
- break;
-
- case H5S_SELECT_AND: /* Binary "and" operation for hyperslabs */
- case H5S_SELECT_NOTB: /* Binary "A not B" operation for hyperslabs */
- HGOTO_DONE(SUCCEED); /* Selection stays "none" */
-
- default:
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
- } /* end switch */
- break;
-
- case H5S_SEL_ALL: /* All elements selected in dataspace */
- switch(op) {
- case H5S_SELECT_SET: /* Select "set" operation */
- /* Change "all" selection to hyperslab selection */
- break;
-
- case H5S_SELECT_OR: /* Binary "or" operation for hyperslabs */
- HGOTO_DONE(SUCCEED); /* Selection stays "all" */
-
- case H5S_SELECT_AND: /* Binary "and" operation for hyperslabs */
- op=H5S_SELECT_SET; /* Maps to "set" operation when applied to "none" selection */
- break;
-
- case H5S_SELECT_XOR: /* Binary "xor" operation for hyperslabs */
- case H5S_SELECT_NOTB: /* Binary "A not B" operation for hyperslabs */
- /* Convert current "all" selection to "real" hyperslab selection */
- /* Then allow operation to proceed */
- {
- hsize_t tmp_start[H5O_LAYOUT_NDIMS]; /* Temporary start information */
- hsize_t tmp_stride[H5O_LAYOUT_NDIMS]; /* Temporary stride information */
- hsize_t tmp_count[H5O_LAYOUT_NDIMS]; /* Temporary count information */
- hsize_t tmp_block[H5O_LAYOUT_NDIMS]; /* Temporary block information */
-
- /* Fill in temporary information for the dimensions */
- for(u=0; u<space->extent.rank; u++) {
- tmp_start[u]=0;
- tmp_stride[u]=1;
- tmp_count[u]=1;
- tmp_block[u]=space->extent.size[u];
- } /* end for */
-
- /* Convert to hyperslab selection */
- if(H5S_select_hyperslab(space,H5S_SELECT_SET,tmp_start,tmp_stride,tmp_count,tmp_block)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, FAIL, "can't convert selection")
- } /* end case */
- break;
-
- case H5S_SELECT_NOTA: /* Binary "B not A" operation for hyperslabs */
- /* Convert to "none" selection */
- if(H5S_select_none(space)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, FAIL, "can't convert selection")
- HGOTO_DONE(SUCCEED);
-
- default:
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
- } /* end switch */
- break;
-
- case H5S_SEL_HYPERSLABS:
- /* Hyperslab operation on hyperslab selection, OK */
- break;
-
- case H5S_SEL_POINTS: /* Can't combine hyperslab operations and point selections currently */
- if(op==H5S_SELECT_SET) /* Allow only "set" operation to proceed */
- break;
- /* Else fall through to error */
-
- default:
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
- } /* end switch */
-
-
- if(op==H5S_SELECT_SET) {
- /* If we are setting a new selection, remove current selection first */
- if(H5S_SELECT_RELEASE(space)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, FAIL, "can't release hyperslab")
-
- /* Allocate space for the hyperslab selection information */
- if(NULL == (space->select.sel_info.hslab = H5FL_MALLOC(H5S_hyper_sel_t)))
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't allocate hyperslab info")
-
- /* Save the diminfo */
- space->select.num_elem=1;
- for(u=0; u<space->extent.rank; u++) {
- space->select.sel_info.hslab->app_diminfo[u].start = start[u];
- space->select.sel_info.hslab->app_diminfo[u].stride = stride[u];
- space->select.sel_info.hslab->app_diminfo[u].count = count[u];
- space->select.sel_info.hslab->app_diminfo[u].block = block[u];
-
- space->select.sel_info.hslab->opt_diminfo[u].start = start[u];
- space->select.sel_info.hslab->opt_diminfo[u].stride = opt_stride[u];
- space->select.sel_info.hslab->opt_diminfo[u].count = opt_count[u];
- space->select.sel_info.hslab->opt_diminfo[u].block = opt_block[u];
-
- space->select.num_elem*=(opt_count[u]*opt_block[u]);
- } /* end for */
-
- /* Save unlim_dim */
- space->select.sel_info.hslab->unlim_dim = unlim_dim;
-
- /* Indicate that the dimension information is valid */
- space->select.sel_info.hslab->diminfo_valid = TRUE;
-
- /* Indicate that there's no slab information */
- space->select.sel_info.hslab->span_lst = NULL;
-
- /* Handle unlimited selections */
- if(unlim_dim >= 0) {
- /* Calculate num_elem_non_unlim */
- space->select.sel_info.hslab->num_elem_non_unlim = (hsize_t)1;
- for(u = 0; u < space->extent.rank; u++)
- if((int)u != unlim_dim)
- space->select.sel_info.hslab->num_elem_non_unlim *= (opt_count[u] * opt_block[u]);
-
- /* Set num_elem */
- if(space->select.num_elem != (hsize_t)0)
- space->select.num_elem = H5S_UNLIMITED;
- } /* end if */
- } /* end if */
- else if(op>=H5S_SELECT_OR && op<=H5S_SELECT_NOTA) {
- /* Sanity check */
- HDassert(H5S_GET_SELECT_TYPE(space) == H5S_SEL_HYPERSLABS);
-
- /* Handle unlimited selections */
- if(unlim_dim >= 0) {
- hsize_t bounds_start[H5S_MAX_RANK];
- hsize_t bounds_end[H5S_MAX_RANK];
- hsize_t tmp_count = opt_count[unlim_dim];
- hsize_t tmp_block = opt_block[unlim_dim];
-
- /* Check for invalid operation */
- if(space->select.sel_info.hslab->unlim_dim >= 0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "cannot modify unlimited selection with another unlimited selection")
- if(!((op == H5S_SELECT_AND) || (op == H5S_SELECT_NOTB)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNSUPPORTED, FAIL, "unsupported operation with unlimited selection")
-
- /* Get bounds of existing selection */
- if(H5S_hyper_bounds(space, bounds_start, bounds_end) < 0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTGET, FAIL, "can't get selection bounds")
-
- /* Patch count and block to remove unlimited and include the
- * existing selection */
- H5S__hyper_get_clip_diminfo(start[unlim_dim], opt_stride[unlim_dim], &tmp_count, &tmp_block, bounds_end[unlim_dim] + (hsize_t)1);
- HDassert((tmp_count == 1) || (opt_count != H5S_hyper_ones_g));
- HDassert((tmp_block == 1) || (opt_block != H5S_hyper_ones_g));
- if(opt_count != H5S_hyper_ones_g) {
- HDassert(opt_count == int_count);
- int_count[unlim_dim] = tmp_count;
- } /* end if */
- if(opt_block != H5S_hyper_ones_g) {
- HDassert(opt_block == int_block);
- int_block[unlim_dim] = tmp_block;
- } /* end if */
- } /* end if */
-
- /* Check if there's no hyperslab span information currently */
- if(NULL == space->select.sel_info.hslab->span_lst)
- if(H5S__hyper_generate_spans(space) < 0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNINITIALIZED, FAIL, "dataspace does not have span tree")
-
- /* Indicate that the regular dimensions are no longer valid */
- space->select.sel_info.hslab->diminfo_valid = FALSE;
-
- /* Add in the new hyperslab information */
- if(H5S__generate_hyperslab (space, op, start, opt_stride, opt_count, opt_block)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't generate hyperslabs")
- } /* end if */
- else
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
-
- /* Set selection type */
- space->select.type = H5S_sel_hyper;
-
-done:
- FUNC_LEAVE_NOAPI(ret_value)
-} /* end H5S_select_hyperslab() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5Sselect_hyperslab
- PURPOSE
- Specify a hyperslab to combine with the current hyperslab selection
- USAGE
- herr_t H5Sselect_hyperslab(dsid, op, start, stride, count, block)
- hid_t dsid; IN: Dataspace ID of selection to modify
- H5S_seloper_t op; IN: Operation to perform on current selection
- const hsize_t *start; IN: Offset of start of hyperslab
- const hsize_t *stride; IN: Hyperslab stride
- const hsize_t *count; IN: Number of blocks included in hyperslab
- const hsize_t *block; IN: Size of block in hyperslab
- RETURNS
- Non-negative on success/Negative on failure
- DESCRIPTION
- Combines a hyperslab selection with the current selection for a dataspace.
- If the current selection is not a hyperslab, it is freed and the hyperslab
- parameters passed in are combined with the H5S_SEL_ALL hyperslab (ie. a
- selection composing the entire current extent). If STRIDE or BLOCK is
- NULL, they are assumed to be set to all '1'.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-herr_t
-H5Sselect_hyperslab(hid_t space_id, H5S_seloper_t op, const hsize_t start[],
- const hsize_t stride[], const hsize_t count[], const hsize_t block[])
-{
- H5S_t *space = NULL; /* Dataspace to modify selection of */
- herr_t ret_value=SUCCEED; /* Return value */
-
- FUNC_ENTER_API(FAIL)
- H5TRACE6("e", "iSs*h*h*h*h", space_id, op, start, stride, count, block);
-
- /* Check args */
- if (NULL == (space = (H5S_t *)H5I_object_verify(space_id, H5I_DATASPACE)))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a dataspace")
- if (H5S_SCALAR==H5S_GET_EXTENT_TYPE(space))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "hyperslab doesn't support H5S_SCALAR space")
- if (H5S_NULL==H5S_GET_EXTENT_TYPE(space))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "hyperslab doesn't support H5S_NULL space")
- if(start==NULL || count==NULL)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "hyperslab not specified")
- if(!(op>H5S_SELECT_NOOP && op<H5S_SELECT_INVALID))
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
- if(stride!=NULL) {
- unsigned u; /* Local index variable */
-
- /* Check for 0-sized strides */
- for(u=0; u<space->extent.rank; u++) {
- if(stride[u]==0)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "invalid stride==0 value")
- } /* end for */
- } /* end if */
-
- if (H5S_select_hyperslab(space, op, start, stride, count, block)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINIT, FAIL, "unable to set hyperslab selection")
-
-done:
- FUNC_LEAVE_API(ret_value)
-} /* end H5Sselect_hyperslab() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5Scombine_hyperslab
- PURPOSE
- Specify a hyperslab to combine with the current hyperslab selection and
- return a new dataspace with the combined selection as the selection in the
- new dataspace.
- USAGE
- hid_t H5Srefine_hyperslab(dsid, op, start, stride, count, block)
- hid_t dsid; IN: Dataspace ID of selection to use
- H5S_seloper_t op; IN: Operation to perform on current selection
- const hsize_t *start; IN: Offset of start of hyperslab
- const hsize_t *stride; IN: Hyperslab stride
- const hsize_t *count; IN: Number of blocks included in hyperslab
- const hsize_t *block; IN: Size of block in hyperslab
- RETURNS
- Dataspace ID on success/Negative on failure
- DESCRIPTION
- Combines a hyperslab selection with the current selection for a dataspace,
- creating a new dataspace to return the generated selection.
- If the current selection is not a hyperslab, it is freed and the hyperslab
- parameters passed in are combined with the H5S_SEL_ALL hyperslab (ie. a
- selection composing the entire current extent). If STRIDE or BLOCK is
- NULL, they are assumed to be set to all '1'.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-hid_t
-H5Scombine_hyperslab(hid_t space_id, H5S_seloper_t op, const hsize_t start[],
- const hsize_t stride[], const hsize_t count[], const hsize_t block[])
-{
- H5S_t *space; /* Dataspace to modify selection of */
- H5S_t *new_space = NULL; /* New dataspace created */
- hid_t ret_value; /* Return value */
-
- FUNC_ENTER_API(FAIL)
- H5TRACE6("i", "iSs*h*h*h*h", space_id, op, start, stride, count, block);
-
- /* Check args */
- if(NULL == (space = (H5S_t *)H5I_object_verify(space_id, H5I_DATASPACE)))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a dataspace")
- if(start == NULL || count == NULL)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "hyperslab not specified")
- if(!(op >= H5S_SELECT_SET && op <= H5S_SELECT_NOTA))
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
-
- /* Copy the first dataspace */
- if (NULL == (new_space = H5S_copy (space, TRUE, TRUE)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINIT, NULL, "unable to copy dataspace")
-
- /* Go modify the selection in the new dataspace */
- if (H5S_select_hyperslab(new_space, op, start, stride, count, block)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINIT, FAIL, "unable to set hyperslab selection")
-
- /* Atomize */
- if((ret_value = H5I_register(H5I_DATASPACE, new_space, TRUE)) < 0)
- HGOTO_ERROR(H5E_ATOM, H5E_CANTREGISTER, FAIL, "unable to register dataspace atom")
-
-done:
- if(ret_value < 0 && new_space)
- H5S_close(new_space);
-
- FUNC_LEAVE_API(ret_value)
-} /* end H5Scombine_hyperslab() */
-
-
-/*-------------------------------------------------------------------------
- * Function: H5S__combine_select
- *
- * Purpose: Internal version of H5Scombine_select().
- *
- * Return: New dataspace on success/NULL on failure
- *
- * Programmer: Quincey Koziol
- * Tuesday, October 30, 2001
- *
- * Chao Mei
- * Wednesday, June 29, 2011
- *
- *-------------------------------------------------------------------------
- */
-static H5S_t *
-H5S__combine_select(H5S_t *space1, H5S_seloper_t op, H5S_t *space2)
-{
- H5S_t *new_space = NULL; /* New dataspace generated */
- hbool_t span2_owned=FALSE; /* Flag to indicate that span2 was used in H5S_operate_hyperslab() */
- H5S_t *ret_value; /* return value */
-
- FUNC_ENTER_STATIC
-
- /* Check args */
- HDassert(space1);
- HDassert(space2);
- HDassert(op >= H5S_SELECT_OR && op <= H5S_SELECT_NOTA);
-
- /* Check that the space selections both have span trees */
- if(space1->select.sel_info.hslab->span_lst==NULL)
- if(H5S__hyper_generate_spans(space1)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNINITIALIZED, NULL, "dataspace does not have span tree")
- if(space2->select.sel_info.hslab->span_lst==NULL)
- if(H5S__hyper_generate_spans(space2)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNINITIALIZED, NULL, "dataspace does not have span tree")
-
- /* Copy the first dataspace */
- if (NULL == (new_space = H5S_copy (space1, TRUE, TRUE)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINIT, NULL, "unable to copy dataspace")
-
- /* Free the current selection for the new dataspace */
- if(H5S_SELECT_RELEASE(new_space)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, NULL, "can't release selection")
-
- /* Allocate space for the hyperslab selection information */
- if((new_space->select.sel_info.hslab=H5FL_CALLOC(H5S_hyper_sel_t))==NULL)
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, NULL, "can't allocate hyperslab info")
-
- /* Set unlim_dim */
- new_space->select.sel_info.hslab->unlim_dim = -1;
-
- /* Combine space1 & space2, with the result in new_space */
- if(H5S_operate_hyperslab(new_space,space1->select.sel_info.hslab->span_lst,op,space2->select.sel_info.hslab->span_lst,FALSE,&span2_owned)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCLIP, NULL, "can't clip hyperslab information")
-
- /* Set return value */
- ret_value = new_space;
-
-done:
- if(ret_value == NULL && new_space)
- H5S_close(new_space);
-
- FUNC_LEAVE_NOAPI(ret_value)
-} /* end H5S__combine_select() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5Scombine_select
- PURPOSE
- Combine two hyperslab selections with an operation, returning a dataspace
- with the resulting selection.
- USAGE
- hid_t H5Scombine_select(space1, op, space2)
- hid_t space1; IN: First Dataspace ID
- H5S_seloper_t op; IN: Selection operation
- hid_t space2; IN: Second Dataspace ID
- RETURNS
- Dataspace ID on success/Negative on failure
- DESCRIPTION
- Combine two existing hyperslab selections with an operation, returning
- a new dataspace with the resulting selection. The dataspace extent from
- space1 is copied for the dataspace extent of the newly created dataspace.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-hid_t
-H5Scombine_select(hid_t space1_id, H5S_seloper_t op, hid_t space2_id)
-{
- H5S_t *space1; /* First Dataspace */
- H5S_t *space2; /* Second Dataspace */
- H5S_t *new_space = NULL; /* New Dataspace */
- hid_t ret_value; /* Return value */
-
- FUNC_ENTER_API(FAIL)
- H5TRACE3("i", "iSsi", space1_id, op, space2_id);
-
- /* Check args */
- if(NULL == (space1 = (H5S_t *)H5I_object_verify(space1_id, H5I_DATASPACE)))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a dataspace")
- if(NULL == (space2 = (H5S_t *)H5I_object_verify(space2_id, H5I_DATASPACE)))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a dataspace")
- if(!(op >= H5S_SELECT_OR && op <= H5S_SELECT_NOTA))
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
-
- /* Check that both dataspaces have the same rank */
- if(space1->extent.rank != space2->extent.rank)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "dataspaces not same rank")
-
- /* Check that both dataspaces have hyperslab selections */
- if(H5S_GET_SELECT_TYPE(space1) != H5S_SEL_HYPERSLABS || H5S_GET_SELECT_TYPE(space2) != H5S_SEL_HYPERSLABS)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "dataspaces don't have hyperslab selections")
-
- /* Go combine the dataspaces */
- if(NULL == (new_space = H5S__combine_select(space1, op, space2)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINIT, FAIL, "unable to create hyperslab selection")
-
- /* Atomize */
- if((ret_value = H5I_register(H5I_DATASPACE, new_space, TRUE)) < 0)
- HGOTO_ERROR(H5E_ATOM, H5E_CANTREGISTER, FAIL, "unable to register dataspace atom")
-
-done:
- if(ret_value < 0 && new_space)
- H5S_close(new_space);
-
- FUNC_LEAVE_API(ret_value)
-} /* end H5Scombine_select() */
-
-
-/*-------------------------------------------------------------------------
- * Function: H5S_select_select
- *
- * Purpose: Internal version of H5Sselect_select().
- *
- * Return: New dataspace on success/NULL on failure
- *
- * Programmer: Quincey Koziol
- * Tuesday, October 30, 2001
- *
- * Modifications:
- *
- *-------------------------------------------------------------------------
- */
-static herr_t
-H5S_select_select (H5S_t *space1, H5S_seloper_t op, H5S_t *space2)
-{
- H5S_hyper_span_info_t *tmp_spans=NULL; /* Temporary copy of selection */
- hbool_t span2_owned=FALSE; /* Flag to indicate that span2 was used in H5S_operate_hyperslab() */
- herr_t ret_value=SUCCEED; /* Return value */
-
- FUNC_ENTER_NOAPI_NOINIT
-
- /* Check args */
- HDassert(space1);
- HDassert(space2);
- HDassert(op > H5S_SELECT_NOOP && op < H5S_SELECT_INVALID);
-
- /* Check that the space selections both have span trees */
- if(space1->select.sel_info.hslab->span_lst==NULL)
- if(H5S__hyper_generate_spans(space1)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNINITIALIZED, FAIL, "dataspace does not have span tree")
- if(space2->select.sel_info.hslab->span_lst==NULL)
- if(H5S__hyper_generate_spans(space2)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_UNINITIALIZED, FAIL, "dataspace does not have span tree")
-
- /* Take ownership of the dataspace's hyperslab spans */
- /* (These are freed later) */
- tmp_spans=space1->select.sel_info.hslab->span_lst;
- space1->select.sel_info.hslab->span_lst=NULL;
-
- /* Reset the other dataspace selection information */
- if(H5S_SELECT_RELEASE(space1)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTDELETE, FAIL, "can't release selection")
-
- /* Allocate space for the hyperslab selection information */
- if((space1->select.sel_info.hslab=H5FL_CALLOC(H5S_hyper_sel_t))==NULL)
- HGOTO_ERROR(H5E_RESOURCE, H5E_NOSPACE, FAIL, "can't allocate hyperslab info")
-
- /* Set unlim_dim */
- space1->select.sel_info.hslab->unlim_dim = -1;
-
- /* Combine tmp_spans (from space1) & spans from space2, with the result in space1 */
- if(H5S_operate_hyperslab(space1,tmp_spans,op,space2->select.sel_info.hslab->span_lst,FALSE,&span2_owned)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCLIP, FAIL, "can't clip hyperslab information")
-
-done:
- if(tmp_spans!=NULL)
- H5S__hyper_free_span_info(tmp_spans);
-
- FUNC_LEAVE_NOAPI(ret_value)
-} /* end H5S_select_select() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5Sselect_select
- PURPOSE
- Refine a hyperslab selection with an operation using a second hyperslab
- to modify it.
- USAGE
- herr_t H5Sselect_select(space1, op, space2)
- hid_t space1; IN/OUT: First Dataspace ID
- H5S_seloper_t op; IN: Selection operation
- hid_t space2; IN: Second Dataspace ID
- RETURNS
- Non-negative on success/Negative on failure
- DESCRIPTION
- Refine an existing hyperslab selection with an operation, using a second
- hyperslab. The first selection is modified to contain the result of
- space1 operated on by space2.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-herr_t
-H5Sselect_select(hid_t space1_id, H5S_seloper_t op, hid_t space2_id)
-{
- H5S_t *space1; /* First Dataspace */
- H5S_t *space2; /* Second Dataspace */
- herr_t ret_value = SUCCEED; /* Return value */
-
- FUNC_ENTER_API(FAIL)
- H5TRACE3("e", "iSsi", space1_id, op, space2_id);
-
- /* Check args */
- if(NULL == (space1 = (H5S_t *)H5I_object_verify(space1_id, H5I_DATASPACE)))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a dataspace")
- if(NULL == (space2 = (H5S_t *)H5I_object_verify(space2_id, H5I_DATASPACE)))
- HGOTO_ERROR(H5E_ARGS, H5E_BADTYPE, FAIL, "not a dataspace")
- if(!(op >= H5S_SELECT_OR && op <= H5S_SELECT_NOTA))
- HGOTO_ERROR(H5E_ARGS, H5E_UNSUPPORTED, FAIL, "invalid selection operation")
-
- /* Check that both dataspaces have the same rank */
- if(space1->extent.rank != space2->extent.rank)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "dataspaces not same rank")
-
- /* Check that both dataspaces have hyperslab selections */
- if(H5S_GET_SELECT_TYPE(space1) != H5S_SEL_HYPERSLABS || H5S_GET_SELECT_TYPE(space2) != H5S_SEL_HYPERSLABS)
- HGOTO_ERROR(H5E_ARGS, H5E_BADVALUE, FAIL, "dataspaces don't have hyperslab selections")
-
- /* Go refine the first selection */
- if (H5S_select_select(space1, op, space2)<0)
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINIT, FAIL, "unable to modify hyperslab selection")
-
-done:
- FUNC_LEAVE_API(ret_value)
-} /* end H5Sselect_select() */
-#endif /* NEW_HYPERSLAB_API */ /* Works */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5S__hyper_get_seq_list_gen
- PURPOSE
- Create a list of offsets & lengths for a selection
- USAGE
- herr_t H5S_select_hyper_get_file_list_gen(space,iter,maxseq,maxelem,nseq,nelem,off,len)
- H5S_t *space; IN: Dataspace containing selection to use.
- H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
- position of interest in selection.
- size_t maxseq; IN: Maximum number of sequences to generate
- size_t maxelem; IN: Maximum number of elements to include in the
- generated sequences
- size_t *nseq; OUT: Actual number of sequences generated
- size_t *nelem; OUT: Actual number of elements in sequences generated
- hsize_t *off; OUT: Array of offsets
- size_t *len; OUT: Array of lengths
- RETURNS
- Non-negative on success/Negative on failure.
- DESCRIPTION
- Use the selection in the dataspace to generate a list of byte offsets and
- lengths for the region(s) selected. Start/Restart from the position in the
- ITER parameter. The number of sequences generated is limited by the MAXSEQ
- parameter and the number of sequences actually generated is stored in the
- NSEQ parameter.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-static herr_t
-H5S__hyper_get_seq_list_gen(const H5S_t *space, H5S_sel_iter_t *iter,
- size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
- hsize_t *off, size_t *len)
-{
- H5S_hyper_span_t *curr_span; /* Current hyperslab span node */
- H5S_hyper_span_t **ispan; /* Iterator's hyperslab span nodes */
- hsize_t slab[H5O_LAYOUT_NDIMS]; /* Cumulative size of each dimension in bytes */
- hsize_t acc; /* Accumulator for computing cumulative sizes */
- hsize_t loc_off; /* Element offset in the dataspace */
- hsize_t last_span_end = 0; /* The offset of the end of the last span */
- hsize_t *abs_arr; /* Absolute hyperslab span position */
- const hssize_t *off_arr; /* Offset within the dataspace extent */
- size_t span_size = 0; /* Number of bytes in current span to actually process */
- size_t io_left; /* Number of elements left to process */
- size_t io_bytes_left; /* Number of bytes left to process */
- size_t io_used; /* Number of elements processed */
- size_t curr_seq = 0; /* Number of sequence/offsets stored in the arrays */
- size_t elem_size; /* Size of each element iterating over */
- unsigned ndims; /* Number of dimensions of dataset */
- unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
- int curr_dim; /* Current dimension being operated on */
- unsigned u; /* Index variable */
- int i; /* Index variable */
-
- FUNC_ENTER_STATIC_NOERR
-
- /* Check args */
- HDassert(space);
- HDassert(iter);
- HDassert(maxseq > 0);
- HDassert(maxelem > 0);
- HDassert(nseq);
- HDassert(nelem);
- HDassert(off);
- HDassert(len);
-
- /* Set the rank of the fastest changing dimension */
- ndims = space->extent.rank;
- fast_dim = (ndims - 1);
-
- /* Get the pointers to the current span info and span nodes */
- curr_span = iter->u.hyp.span[fast_dim];
- abs_arr = iter->u.hyp.off;
- off_arr = space->select.offset;
- ispan = iter->u.hyp.span;
- elem_size = iter->elmt_size;
-
- /* Set the amount of elements to perform I/O on, etc. */
- H5_CHECK_OVERFLOW(iter->elmt_left, hsize_t, size_t);
- io_left = MIN(maxelem, (size_t)iter->elmt_left);
- io_bytes_left = io_left * elem_size;
-
- /* Compute the cumulative size of dataspace dimensions */
- for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
- slab[i] = acc;
- acc *= space->extent.size[i];
- } /* end for */
-
- /* Set the offset of the first element iterated on */
- for(u = 0, loc_off = 0; u < ndims; u++)
- /* Compute the sequential element offset */
- loc_off += ((hsize_t)((hssize_t)abs_arr[u] + off_arr[u])) * slab[u];
-
- /* Range check against number of elements left in selection */
- HDassert(io_bytes_left <= (iter->elmt_left * elem_size));
-
- /* Take care of any partial spans leftover from previous I/Os */
- if(abs_arr[fast_dim]!=curr_span->low) {
-
- /* Finish the span in the fastest changing dimension */
-
- /* Compute the number of bytes to attempt in this span */
- H5_CHECKED_ASSIGN(span_size, size_t, ((curr_span->high-abs_arr[fast_dim])+1)*elem_size, hsize_t);
-
- /* Check number of bytes against upper bounds allowed */
- if(span_size>io_bytes_left)
- span_size=io_bytes_left;
-
- /* Add the partial span to the list of sequences */
- off[curr_seq]=loc_off;
- len[curr_seq]=span_size;
-
- /* Increment sequence count */
- curr_seq++;
-
- /* Set the location of the last span's end */
- last_span_end=loc_off+span_size;
-
- /* Decrement I/O left to perform */
- io_bytes_left-=span_size;
-
- /* Advance the hyperslab iterator */
- /* Check if we are done */
- if(io_bytes_left > 0) {
- /* Move to next span in fastest changing dimension */
- curr_span = curr_span->next;
-
- if(NULL != curr_span) {
- /* Move location offset of destination */
- loc_off += (curr_span->low - abs_arr[fast_dim]) * elem_size;
-
- /* Move iterator for fastest changing dimension */
- abs_arr[fast_dim] = curr_span->low;
- } /* end if */
- } /* end if */
- else {
- abs_arr[fast_dim] += span_size / elem_size;
-
- /* Check if we are still within the span */
- if(abs_arr[fast_dim] <= curr_span->high) {
- iter->u.hyp.span[fast_dim] = curr_span;
- } /* end if */
- /* If we walked off that span, advance to the next span */
- else {
- /* Advance span in this dimension */
- curr_span = curr_span->next;
-
- /* Check if we have a valid span in this dimension still */
- if(NULL != curr_span) {
- /* Reset absolute position */
- abs_arr[fast_dim] = curr_span->low;
- iter->u.hyp.span[fast_dim] = curr_span;
- } /* end if */
- } /* end else */
- } /* end else */
-
- /* Adjust iterator pointers */
-
- if(NULL == curr_span) {
-/* Same as code in main loop */
- /* Start at the next fastest dim */
- curr_dim = (int)(fast_dim - 1);
-
- /* Work back up through the dimensions */
- while(curr_dim >= 0) {
- /* Reset the current span */
- curr_span = iter->u.hyp.span[curr_dim];
-
- /* Increment absolute position */
- abs_arr[curr_dim]++;
-
- /* Check if we are still within the span */
- if(abs_arr[curr_dim] <= curr_span->high) {
- break;
- } /* end if */
- /* If we walked off that span, advance to the next span */
- else {
- /* Advance span in this dimension */
- curr_span = curr_span->next;
-
- /* Check if we have a valid span in this dimension still */
- if(NULL != curr_span) {
- /* Reset the span in the current dimension */
- ispan[curr_dim] = curr_span;
-
- /* Reset absolute position */
- abs_arr[curr_dim] = curr_span->low;
-
- break;
- } /* end if */
- else {
- /* If we finished the span list in this dimension, decrement the dimension worked on and loop again */
- curr_dim--;
- } /* end else */
- } /* end else */
- } /* end while */
-
- /* Check if we have more spans in the tree */
- if(curr_dim >= 0) {
- /* Walk back down the iterator positions, resetting them */
- while((unsigned)curr_dim < fast_dim) {
- HDassert(curr_span);
- HDassert(curr_span->down);
- HDassert(curr_span->down->head);
-
- /* Increment current dimension */
- curr_dim++;
-
- /* Set the new span_info & span for this dimension */
- iter->u.hyp.span[curr_dim] = curr_span->down->head;
-
- /* Advance span down the tree */
- curr_span = curr_span->down->head;
-
- /* Reset the absolute offset for the dim */
- abs_arr[curr_dim] = curr_span->low;
- } /* end while */
-
- /* Verify that the curr_span points to the fastest dim */
- HDassert(curr_span == iter->u.hyp.span[fast_dim]);
-
- /* Reset the buffer offset */
- for(u = 0, loc_off = 0; u < ndims; u++)
- loc_off += ((hsize_t)((hssize_t)abs_arr[u] + off_arr[u])) * slab[u];
- } /* end else */
- else
- /* We had better be done with I/O or bad things are going to happen... */
- HDassert(io_bytes_left == 0);
- } /* end if */
- } /* end if */
-
- /* Perform the I/O on the elements, based on the position of the iterator */
- while(io_bytes_left > 0 && curr_seq < maxseq) {
- /* Sanity check */
- HDassert(curr_span);
-
- /* Adjust location offset of destination to compensate for initial increment below */
- loc_off -= curr_span->pstride;
-
- /* Loop over all the spans in the fastest changing dimension */
- while(curr_span != NULL) {
- /* Move location offset of destination */
- loc_off += curr_span->pstride;
-
- /* Compute the number of elements to attempt in this span */
- H5_CHECKED_ASSIGN(span_size, size_t, curr_span->nelem, hsize_t);
-
- /* Check number of elements against upper bounds allowed */
- if(span_size >= io_bytes_left) {
- /* Trim the number of bytes to output */
- span_size = io_bytes_left;
- io_bytes_left = 0;
-
-/* COMMON */
- /* Store the I/O information for the span */
-
- /* Check if this is appending onto previous sequence */
- if(curr_seq > 0 && last_span_end == loc_off)
- len[curr_seq - 1] += span_size;
- else {
- off[curr_seq] = loc_off;
- len[curr_seq] = span_size;
-
- /* Increment the number of sequences in arrays */
- curr_seq++;
- } /* end else */
-
- /* Set the location of the last span's end */
- last_span_end = loc_off + span_size;
-/* end COMMON */
-
- /* Break out now, we are finished with I/O */
- break;
- } /* end if */
- else {
- /* Decrement I/O left to perform */
- io_bytes_left -= span_size;
-
-/* COMMON */
- /* Store the I/O information for the span */
-
- /* Check if this is appending onto previous sequence */
- if(curr_seq > 0 && last_span_end == loc_off)
- len[curr_seq-1]+=span_size;
- else {
- off[curr_seq] = loc_off;
- len[curr_seq] = span_size;
-
- /* Increment the number of sequences in arrays */
- curr_seq++;
- } /* end else */
-
- /* Set the location of the last span's end */
- last_span_end = loc_off + span_size;
-/* end COMMON */
-
- /* If the sequence & offset arrays are full, do what? */
- if(curr_seq >= maxseq) {
- /* Break out now, we are finished with sequences */
- break;
- } /* end else */
- } /* end else */
-
- /* Move to next span in fastest changing dimension */
- curr_span=curr_span->next;
- } /* end while */
-
- /* Check if we are done */
- if(io_bytes_left==0 || curr_seq>=maxseq) {
- HDassert(curr_span);
- abs_arr[fast_dim]=curr_span->low+(span_size/elem_size);
-
- /* Check if we are still within the span */
- if(abs_arr[fast_dim]<=curr_span->high) {
- iter->u.hyp.span[fast_dim]=curr_span;
- break;
- } /* end if */
- /* If we walked off that span, advance to the next span */
- else {
- /* Advance span in this dimension */
- curr_span=curr_span->next;
-
- /* Check if we have a valid span in this dimension still */
- if(curr_span!=NULL) {
- /* Reset absolute position */
- abs_arr[fast_dim]=curr_span->low;
- iter->u.hyp.span[fast_dim]=curr_span;
- break;
- } /* end if */
- } /* end else */
- } /* end if */
-
- /* Adjust iterator pointers */
-
- /* Start at the next fastest dim */
- curr_dim = (int)(fast_dim - 1);
-
- /* Work back up through the dimensions */
- while(curr_dim >= 0) {
- /* Reset the current span */
- curr_span=iter->u.hyp.span[curr_dim];
-
- /* Increment absolute position */
- abs_arr[curr_dim]++;
-
- /* Check if we are still within the span */
- if(abs_arr[curr_dim]<=curr_span->high) {
- break;
- } /* end if */
- /* If we walked off that span, advance to the next span */
- else {
- /* Advance span in this dimension */
- curr_span=curr_span->next;
-
- /* Check if we have a valid span in this dimension still */
- if(curr_span!=NULL) {
- /* Reset the span in the current dimension */
- ispan[curr_dim]=curr_span;
-
- /* Reset absolute position */
- abs_arr[curr_dim]=curr_span->low;
-
- break;
- } /* end if */
- else {
- /* If we finished the span list in this dimension, decrement the dimension worked on and loop again */
- curr_dim--;
- } /* end else */
- } /* end else */
- } /* end while */
-
- /* Check if we are finished with the spans in the tree */
- if(curr_dim < 0) {
- /* We had better be done with I/O or bad things are going to happen... */
- HDassert(io_bytes_left == 0);
- break;
- } /* end if */
- else {
- /* Walk back down the iterator positions, resetting them */
- while((unsigned)curr_dim < fast_dim) {
- HDassert(curr_span);
- HDassert(curr_span->down);
- HDassert(curr_span->down->head);
-
- /* Increment current dimension to the next dimension down */
- curr_dim++;
-
- /* Set the new span for the next dimension down */
- iter->u.hyp.span[curr_dim] = curr_span->down->head;
-
- /* Advance span down the tree */
- curr_span = curr_span->down->head;
-
- /* Reset the absolute offset for the dim */
- abs_arr[curr_dim] = curr_span->low;
- } /* end while */
-
- /* Verify that the curr_span points to the fastest dim */
- HDassert(curr_span == iter->u.hyp.span[fast_dim]);
- } /* end else */
-
- /* Reset the buffer offset */
- for(u = 0, loc_off = 0; u < ndims; u++)
- loc_off += ((hsize_t)((hssize_t)abs_arr[u] + off_arr[u])) * slab[u];
- } /* end while */
-
- /* Decrement number of elements left in iterator */
- io_used = (io_left - (io_bytes_left / elem_size));
- iter->elmt_left -= io_used;
-
- /* Set the number of sequences generated */
- *nseq = curr_seq;
-
- /* Set the number of elements used */
- *nelem = io_used;
-
- FUNC_LEAVE_NOAPI(SUCCEED)
-} /* end H5S__hyper_get_seq_list_gen() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5S__hyper_get_seq_list_opt
- PURPOSE
- Create a list of offsets & lengths for a selection
- USAGE
- herr_t H5S_select_hyper_get_file_list_opt(space,iter,maxseq,maxelem,nseq,nelem,off,len)
- H5S_t *space; IN: Dataspace containing selection to use.
- H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
- position of interest in selection.
- size_t maxseq; IN: Maximum number of sequences to generate
- size_t maxelem; IN: Maximum number of elements to include in the
- generated sequences
- size_t *nseq; OUT: Actual number of sequences generated
- size_t *nelem; OUT: Actual number of elements in sequences generated
- hsize_t *off; OUT: Array of offsets
- size_t *len; OUT: Array of lengths
- RETURNS
- Non-negative on success/Negative on failure.
- DESCRIPTION
- Use the selection in the dataspace to generate a list of byte offsets and
- lengths for the region(s) selected. Start/Restart from the position in the
- ITER parameter. The number of sequences generated is limited by the MAXSEQ
- parameter and the number of sequences actually generated is stored in the
- NSEQ parameter.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-static herr_t
-H5S__hyper_get_seq_list_opt(const H5S_t *space, H5S_sel_iter_t *iter,
- size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
- hsize_t *off, size_t *len)
-{
- hsize_t *mem_size; /* Size of the source buffer */
- hsize_t slab[H5O_LAYOUT_NDIMS]; /* Hyperslab size */
- const hssize_t *sel_off; /* Selection offset in dataspace */
- hsize_t offset[H5O_LAYOUT_NDIMS]; /* Coordinate offset in dataspace */
- hsize_t tmp_count[H5O_LAYOUT_NDIMS];/* Temporary block count */
- hsize_t tmp_block[H5O_LAYOUT_NDIMS];/* Temporary block offset */
- hsize_t wrap[H5O_LAYOUT_NDIMS]; /* Bytes to wrap around at the end of a row */
- hsize_t skip[H5O_LAYOUT_NDIMS]; /* Bytes to skip between blocks */
- const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
- hsize_t fast_dim_start, /* Local copies of fastest changing dimension info */
- fast_dim_stride,
- fast_dim_block,
- fast_dim_offset;
- size_t fast_dim_buf_off; /* Local copy of amount to move fastest dimension buffer offset */
- size_t fast_dim_count; /* Number of blocks left in fastest changing dimension */
- size_t tot_blk_count; /* Total number of blocks left to output */
- size_t act_blk_count; /* Actual number of blocks to output */
- size_t total_rows; /* Total number of entire rows to output */
- size_t curr_rows; /* Current number of entire rows to output */
- unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
- unsigned ndims; /* Number of dimensions of dataset */
- int temp_dim; /* Temporary rank holder */
- hsize_t acc; /* Accumulator */
- hsize_t loc; /* Coordinate offset */
- size_t curr_seq = 0; /* Current sequence being operated on */
- size_t actual_elem; /* The actual number of elements to count */
- size_t actual_bytes;/* The actual number of bytes to copy */
- size_t io_left; /* The number of elements left in I/O operation */
- size_t start_io_left; /* The initial number of elements left in I/O operation */
- size_t elem_size; /* Size of each element iterating over */
- unsigned u; /* Local index variable */
- int i; /* Local index variable */
-
- FUNC_ENTER_STATIC_NOERR
-
- /* Check args */
- HDassert(space);
- HDassert(iter);
- HDassert(maxseq > 0);
- HDassert(maxelem > 0);
- HDassert(nseq);
- HDassert(nelem);
- HDassert(off);
- HDassert(len);
-
- /* Set the local copy of the diminfo pointer */
- tdiminfo = iter->u.hyp.diminfo;
-
- /* Check if this is a "flattened" regular hyperslab selection */
- if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < space->extent.rank) {
- /* Set the aliases for a few important dimension ranks */
- ndims = iter->u.hyp.iter_rank;
- fast_dim = ndims - 1;
-
- /* Set the local copy of the selection offset */
- sel_off = iter->u.hyp.sel_off;
-
- /* Set up the pointer to the size of the memory space */
- mem_size = iter->u.hyp.size;
- } /* end if */
- else {
- /* Set the aliases for a few important dimension ranks */
- ndims = space->extent.rank;
- fast_dim = ndims - 1;
-
- /* Set the local copy of the selection offset */
- sel_off = space->select.offset;
-
- /* Set up the pointer to the size of the memory space */
- mem_size = space->extent.size;
- } /* end else */
-
- /* initialize row sizes for each dimension */
- elem_size = iter->elmt_size;
- for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
- slab[i] = acc;
- acc *= mem_size[i];
- } /* end for */
-
- /* Calculate the number of elements to sequence through */
- H5_CHECK_OVERFLOW(iter->elmt_left, hsize_t, size_t);
- io_left = MIN((size_t)iter->elmt_left, maxelem);
-
- /* Sanity check that there aren't any "remainder" sequences in process */
- HDassert(!((iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start) % tdiminfo[fast_dim].stride != 0 ||
- ((iter->u.hyp.off[fast_dim] != tdiminfo[fast_dim].start) && tdiminfo[fast_dim].count == 1)));
-
- /* We've cleared the "remainder" of the previous fastest dimension
- * sequence before calling this routine, so we must be at the beginning of
- * a sequence. Use the fancy algorithm to compute the offsets and run
- * through as many as possible, until the buffer fills up.
- */
-
- /* Keep the number of elements we started with */
- start_io_left = io_left;
-
- /* Compute the arrays to perform I/O on */
-
- /* Copy the location of the point to get */
- /* (Add in the selection offset) */
- for(u = 0; u < ndims; u++)
- offset[u] = (hsize_t)((hssize_t)iter->u.hyp.off[u] + sel_off[u]);
-
- /* Compute the current "counts" for this location */
- for(u = 0; u < ndims; u++) {
- if(tdiminfo[u].count == 1) {
- tmp_count[u] = 0;
- tmp_block[u] = iter->u.hyp.off[u] - tdiminfo[u].start;
- } /* end if */
- else {
- tmp_count[u] = (iter->u.hyp.off[u] - tdiminfo[u].start) / tdiminfo[u].stride;
- tmp_block[u] = (iter->u.hyp.off[u] - tdiminfo[u].start) % tdiminfo[u].stride;
- } /* end else */
- } /* end for */
-
- /* Compute the initial buffer offset */
- for(u = 0, loc = 0; u < ndims; u++)
- loc += offset[u] * slab[u];
-
- /* Set the number of elements to write each time */
- H5_CHECKED_ASSIGN(actual_elem, size_t, tdiminfo[fast_dim].block, hsize_t);
-
- /* Set the number of actual bytes */
- actual_bytes = actual_elem * elem_size;
-
- /* Set local copies of information for the fastest changing dimension */
- fast_dim_start = tdiminfo[fast_dim].start;
- fast_dim_stride = tdiminfo[fast_dim].stride;
- fast_dim_block = tdiminfo[fast_dim].block;
- H5_CHECKED_ASSIGN(fast_dim_buf_off, size_t, slab[fast_dim] * fast_dim_stride, hsize_t);
- fast_dim_offset = (hsize_t)((hssize_t)fast_dim_start + sel_off[fast_dim]);
-
- /* Compute the number of blocks which would fit into the buffer */
- H5_CHECK_OVERFLOW(io_left / fast_dim_block, hsize_t, size_t);
- tot_blk_count = (size_t)(io_left / fast_dim_block);
-
- /* Don't go over the maximum number of sequences allowed */
- tot_blk_count = MIN(tot_blk_count, (maxseq - curr_seq));
-
- /* Compute the amount to wrap at the end of each row */
- for(u = 0; u < ndims; u++)
- wrap[u] = (mem_size[u] - (tdiminfo[u].stride * tdiminfo[u].count)) * slab[u];
-
- /* Compute the amount to skip between blocks */
- for(u = 0; u < ndims; u++)
- skip[u] = (tdiminfo[u].stride - tdiminfo[u].block) * slab[u];
-
- /* Check if there is a partial row left (with full blocks) */
- if(tmp_count[fast_dim] > 0) {
- /* Get number of blocks in fastest dimension */
- H5_CHECKED_ASSIGN(fast_dim_count, size_t, tdiminfo[fast_dim].count - tmp_count[fast_dim], hsize_t);
-
- /* Make certain this entire row will fit into buffer */
- fast_dim_count = MIN(fast_dim_count, tot_blk_count);
-
- /* Number of blocks to sequence over */
- act_blk_count = fast_dim_count;
-
- /* Loop over all the blocks in the fastest changing dimension */
- while(fast_dim_count > 0) {
- /* Store the sequence information */
- off[curr_seq] = loc;
- len[curr_seq] = actual_bytes;
-
- /* Increment sequence count */
- curr_seq++;
-
- /* Increment information to reflect block just processed */
- loc += fast_dim_buf_off;
-
- /* Decrement number of blocks */
- fast_dim_count--;
- } /* end while */
-
- /* Decrement number of elements left */
- io_left -= actual_elem * act_blk_count;
-
- /* Decrement number of blocks left */
- tot_blk_count -= act_blk_count;
-
- /* Increment information to reflect block just processed */
- tmp_count[fast_dim] += act_blk_count;
-
- /* Check if we finished the entire row of blocks */
- if(tmp_count[fast_dim] >= tdiminfo[fast_dim].count) {
- /* Increment offset in destination buffer */
- loc += wrap[fast_dim];
-
- /* Increment information to reflect block just processed */
- offset[fast_dim] = fast_dim_offset; /* reset the offset in the fastest dimension */
- tmp_count[fast_dim] = 0;
-
- /* Increment the offset and count for the other dimensions */
- temp_dim = (int)fast_dim - 1;
- while(temp_dim >= 0) {
- /* Move to the next row in the curent dimension */
- offset[temp_dim]++;
- tmp_block[temp_dim]++;
-
- /* If this block is still in the range of blocks to output for the dimension, break out of loop */
- if(tmp_block[temp_dim] < tdiminfo[temp_dim].block)
- break;
- else {
- /* Move to the next block in the current dimension */
- offset[temp_dim] += (tdiminfo[temp_dim].stride - tdiminfo[temp_dim].block);
- loc += skip[temp_dim];
- tmp_block[temp_dim] = 0;
- tmp_count[temp_dim]++;
-
- /* If this block is still in the range of blocks to output for the dimension, break out of loop */
- if(tmp_count[temp_dim] < tdiminfo[temp_dim].count)
- break;
- else {
- offset[temp_dim] = (hsize_t)((hssize_t)tdiminfo[temp_dim].start + sel_off[temp_dim]);
- loc += wrap[temp_dim];
- tmp_count[temp_dim] = 0; /* reset back to the beginning of the line */
- tmp_block[temp_dim] = 0;
- } /* end else */
- } /* end else */
-
- /* Decrement dimension count */
- temp_dim--;
- } /* end while */
- } /* end if */
- else {
- /* Update the offset in the fastest dimension */
- offset[fast_dim] += (fast_dim_stride * act_blk_count);
- } /* end else */
- } /* end if */
-
- /* Compute the number of entire rows to read in */
- H5_CHECK_OVERFLOW(tot_blk_count / tdiminfo[fast_dim].count, hsize_t, size_t);
- curr_rows = total_rows = (size_t)(tot_blk_count / tdiminfo[fast_dim].count);
-
- /* Reset copy of number of blocks in fastest dimension */
- H5_CHECKED_ASSIGN(fast_dim_count, size_t, tdiminfo[fast_dim].count, hsize_t);
-
- /* Read in data until an entire sequence can't be written out any longer */
- while(curr_rows > 0) {
-
-#define DUFF_GUTS \
-/* Store the sequence information */ \
-off[curr_seq] = loc; \
-len[curr_seq] = actual_bytes; \
- \
-/* Increment sequence count */ \
-curr_seq++; \
- \
-/* Increment information to reflect block just processed */ \
-loc += fast_dim_buf_off;
-
-#ifdef NO_DUFFS_DEVICE
- /* Loop over all the blocks in the fastest changing dimension */
- while(fast_dim_count > 0) {
- DUFF_GUTS
-
- /* Decrement number of blocks */
- fast_dim_count--;
- } /* end while */
-#else /* NO_DUFFS_DEVICE */
- {
- size_t duffs_index; /* Counting index for Duff's device */
-
- duffs_index = (fast_dim_count + 7) / 8;
- switch (fast_dim_count % 8) {
- default:
- HDassert(0 && "This Should never be executed!");
- break;
- case 0:
- do
- {
- DUFF_GUTS
- case 7:
- DUFF_GUTS
- case 6:
- DUFF_GUTS
- case 5:
- DUFF_GUTS
- case 4:
- DUFF_GUTS
- case 3:
- DUFF_GUTS
- case 2:
- DUFF_GUTS
- case 1:
- DUFF_GUTS
- } while (--duffs_index > 0);
- } /* end switch */
- }
-#endif /* NO_DUFFS_DEVICE */
-#undef DUFF_GUTS
-
- /* Increment offset in destination buffer */
- loc += wrap[fast_dim];
-
- /* Increment the offset and count for the other dimensions */
- temp_dim = (int)fast_dim - 1;
- while(temp_dim >= 0) {
- /* Move to the next row in the curent dimension */
- offset[temp_dim]++;
- tmp_block[temp_dim]++;
-
- /* If this block is still in the range of blocks to output for the dimension, break out of loop */
- if(tmp_block[temp_dim] < tdiminfo[temp_dim].block)
- break;
- else {
- /* Move to the next block in the current dimension */
- offset[temp_dim] += (tdiminfo[temp_dim].stride - tdiminfo[temp_dim].block);
- loc += skip[temp_dim];
- tmp_block[temp_dim] = 0;
- tmp_count[temp_dim]++;
-
- /* If this block is still in the range of blocks to output for the dimension, break out of loop */
- if(tmp_count[temp_dim] < tdiminfo[temp_dim].count)
- break;
- else {
- offset[temp_dim] = (hsize_t)((hssize_t)tdiminfo[temp_dim].start + sel_off[temp_dim]);
- loc += wrap[temp_dim];
- tmp_count[temp_dim] = 0; /* reset back to the beginning of the line */
- tmp_block[temp_dim] = 0;
- } /* end else */
- } /* end else */
-
- /* Decrement dimension count */
- temp_dim--;
- } /* end while */
-
- /* Decrement the number of rows left */
- curr_rows--;
- } /* end while */
-
- /* Adjust the number of blocks & elements left to transfer */
-
- /* Decrement number of elements left */
- H5_CHECK_OVERFLOW(actual_elem * (total_rows * tdiminfo[fast_dim].count), hsize_t, size_t);
- io_left -= (size_t)(actual_elem * (total_rows * tdiminfo[fast_dim].count));
-
- /* Decrement number of blocks left */
- H5_CHECK_OVERFLOW((total_rows * tdiminfo[fast_dim].count), hsize_t, size_t);
- tot_blk_count -= (size_t)(total_rows * tdiminfo[fast_dim].count);
-
- /* Read in partial row of blocks */
- if(io_left > 0 && curr_seq < maxseq) {
- /* Get remaining number of blocks left to output */
- fast_dim_count = tot_blk_count;
-
- /* Loop over all the blocks in the fastest changing dimension */
- while(fast_dim_count > 0) {
- /* Store the sequence information */
- off[curr_seq] = loc;
- len[curr_seq] = actual_bytes;
-
- /* Increment sequence count */
- curr_seq++;
-
- /* Increment information to reflect block just processed */
- loc += fast_dim_buf_off;
-
- /* Decrement number of blocks */
- fast_dim_count--;
- } /* end while */
-
- /* Decrement number of elements left */
- io_left -= actual_elem * tot_blk_count;
-
- /* Increment information to reflect block just processed */
- offset[fast_dim] += (fast_dim_stride * tot_blk_count); /* move the offset in the fastest dimension */
-
- /* Handle any leftover, partial blocks in this row */
- if(io_left > 0 && curr_seq < maxseq) {
- actual_elem = io_left;
- actual_bytes = actual_elem * elem_size;
-
- /* Store the sequence information */
- off[curr_seq] = loc;
- len[curr_seq] = actual_bytes;
-
- /* Increment sequence count */
- curr_seq++;
-
- /* Decrement the number of elements left */
- io_left -= actual_elem;
-
- /* Increment buffer correctly */
- offset[fast_dim] += actual_elem;
- } /* end if */
-
- /* don't bother checking slower dimensions */
- HDassert(io_left == 0 || curr_seq == maxseq);
- } /* end if */
-
- /* Update the iterator */
-
- /* Update the iterator with the location we stopped */
- /* (Subtract out the selection offset) */
- for(u = 0; u < ndims; u++)
- iter->u.hyp.off[u] = (hsize_t)((hssize_t)offset[u] - sel_off[u]);
-
- /* Decrement the number of elements left in selection */
- iter->elmt_left -= (start_io_left - io_left);
-
- /* Increment the number of sequences generated */
- *nseq += curr_seq;
-
- /* Increment the number of elements used */
- *nelem += start_io_left - io_left;
-
- FUNC_LEAVE_NOAPI(SUCCEED)
-} /* end H5S__hyper_get_seq_list_opt() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5S__hyper_get_seq_list_single
- PURPOSE
- Create a list of offsets & lengths for a selection
- USAGE
- herr_t H5S__hyper_get_seq_list_single(space, flags, iter, maxseq, maxelem, nseq, nelem, off, len)
- H5S_t *space; IN: Dataspace containing selection to use.
- unsigned flags; IN: Flags for extra information about operation
- H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
- position of interest in selection.
- size_t maxseq; IN: Maximum number of sequences to generate
- size_t maxelem; IN: Maximum number of elements to include in the
- generated sequences
- size_t *nseq; OUT: Actual number of sequences generated
- size_t *nelem; OUT: Actual number of elements in sequences generated
- hsize_t *off; OUT: Array of offsets
- size_t *len; OUT: Array of lengths
- RETURNS
- Non-negative on success/Negative on failure.
- DESCRIPTION
- Use the selection in the dataspace to generate a list of byte offsets and
- lengths for the region(s) selected. Start/Restart from the position in the
- ITER parameter. The number of sequences generated is limited by the MAXSEQ
- parameter and the number of sequences actually generated is stored in the
- NSEQ parameter.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-static herr_t
-H5S__hyper_get_seq_list_single(const H5S_t *space, H5S_sel_iter_t *iter,
- size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
- hsize_t *off, size_t *len)
-{
- const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
- const hssize_t *sel_off; /* Selection offset in dataspace */
- hsize_t *mem_size; /* Size of the source buffer */
- hsize_t base_offset[H5O_LAYOUT_NDIMS]; /* Base coordinate offset in dataspace */
- hsize_t offset[H5O_LAYOUT_NDIMS]; /* Coordinate offset in dataspace */
- hsize_t slab[H5O_LAYOUT_NDIMS]; /* Hyperslab size */
- hsize_t fast_dim_block; /* Local copies of fastest changing dimension info */
- hsize_t acc; /* Accumulator */
- hsize_t loc; /* Coordinate offset */
- size_t tot_blk_count; /* Total number of blocks left to output */
- size_t elem_size; /* Size of each element iterating over */
- size_t io_left; /* The number of elements left in I/O operation */
- size_t actual_elem; /* The actual number of elements to count */
- unsigned ndims; /* Number of dimensions of dataset */
- unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
- unsigned skip_dim; /* Rank of the dimension to skip along */
- unsigned u; /* Local index variable */
- int i; /* Local index variable */
-
- FUNC_ENTER_STATIC_NOERR
-
- /* Check args */
- HDassert(space);
- HDassert(iter);
- HDassert(maxseq > 0);
- HDassert(maxelem > 0);
- HDassert(nseq);
- HDassert(nelem);
- HDassert(off);
- HDassert(len);
-
- /* Set a local copy of the diminfo pointer */
- tdiminfo = iter->u.hyp.diminfo;
-
- /* Check if this is a "flattened" regular hyperslab selection */
- if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < space->extent.rank) {
- /* Set the aliases for a few important dimension ranks */
- ndims = iter->u.hyp.iter_rank;
-
- /* Set the local copy of the selection offset */
- sel_off = iter->u.hyp.sel_off;
-
- /* Set up the pointer to the size of the memory space */
- mem_size = iter->u.hyp.size;
- } /* end if */
- else {
- /* Set the aliases for a few important dimension ranks */
- ndims = space->extent.rank;
-
- /* Set the local copy of the selection offset */
- sel_off = space->select.offset;
-
- /* Set up the pointer to the size of the memory space */
- mem_size = space->extent.size;
- } /* end else */
- fast_dim = ndims - 1;
-
- /* initialize row sizes for each dimension */
- elem_size = iter->elmt_size;
- for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
- slab[i] = acc;
- acc *= mem_size[i];
- } /* end for */
-
- /* Copy the base location of the block */
- /* (Add in the selection offset) */
- for(u = 0; u < ndims; u++)
- base_offset[u] = (hsize_t)((hssize_t)tdiminfo[u].start + sel_off[u]);
-
- /* Copy the location of the point to get */
- /* (Add in the selection offset) */
- for(u = 0; u < ndims; u++)
- offset[u] = (hsize_t)((hssize_t)iter->u.hyp.off[u] + sel_off[u]);
-
- /* Compute the initial buffer offset */
- for(u = 0, loc = 0; u < ndims; u++)
- loc += offset[u] * slab[u];
-
- /* Set local copies of information for the fastest changing dimension */
- fast_dim_block = tdiminfo[fast_dim].block;
-
- /* Calculate the number of elements to sequence through */
- H5_CHECK_OVERFLOW(iter->elmt_left, hsize_t, size_t);
- io_left = MIN((size_t)iter->elmt_left, maxelem);
-
- /* Compute the number of blocks which would fit into the buffer */
- H5_CHECK_OVERFLOW(io_left / fast_dim_block, hsize_t, size_t);
- tot_blk_count = (size_t)(io_left / fast_dim_block);
-
- /* Don't go over the maximum number of sequences allowed */
- tot_blk_count = MIN(tot_blk_count, maxseq);
-
- /* Set the number of elements to write each time */
- H5_CHECKED_ASSIGN(actual_elem, size_t, fast_dim_block, hsize_t);
-
- /* Check for blocks to operate on */
- if(tot_blk_count > 0) {
- size_t actual_bytes; /* The actual number of bytes to copy */
-
- /* Set the number of actual bytes */
- actual_bytes = actual_elem * elem_size;
-
- /* Check for 1-dim selection */
- if(0 == fast_dim) {
- /* Sanity checks */
- HDassert(1 == tot_blk_count);
- HDassert(io_left == actual_elem);
-
- /* Store the sequence information */
- *off++ = loc;
- *len++ = actual_bytes;
- } /* end if */
- else {
- hsize_t skip_slab; /* Temporary copy of slab[fast_dim - 1] */
- size_t blk_count; /* Total number of blocks left to output */
-
- /* Find first dimension w/block >1 */
- skip_dim = fast_dim;
- for(i = (int)(fast_dim - 1); i >= 0; i--)
- if(tdiminfo[i].block > 1) {
- skip_dim = (unsigned)i;
- break;
- } /* end if */
- skip_slab = slab[skip_dim];
-
- /* Check for being able to use fast algorithm for 1-D */
- if(0 == skip_dim) {
- /* Create sequences until an entire row can't be used */
- blk_count = tot_blk_count;
- while(blk_count > 0) {
- /* Store the sequence information */
- *off++ = loc;
- *len++ = actual_bytes;
-
- /* Increment offset in destination buffer */
- loc += skip_slab;
-
- /* Decrement block count */
- blk_count--;
- } /* end while */
-
- /* Move to the next location */
- offset[skip_dim] += tot_blk_count;
- } /* end if */
- else {
- hsize_t tmp_block[H5O_LAYOUT_NDIMS];/* Temporary block offset */
- hsize_t skip[H5O_LAYOUT_NDIMS]; /* Bytes to skip between blocks */
- int temp_dim; /* Temporary rank holder */
-
- /* Set the starting block location */
- for(u = 0; u < ndims; u++)
- tmp_block[u] = iter->u.hyp.off[u] - tdiminfo[u].start;
-
- /* Compute the amount to skip between sequences */
- for(u = 0; u < ndims; u++)
- skip[u] = (mem_size[u] - tdiminfo[u].block) * slab[u];
-
- /* Create sequences until an entire row can't be used */
- blk_count = tot_blk_count;
- while(blk_count > 0) {
- /* Store the sequence information */
- *off++ = loc;
- *len++ = actual_bytes;
-
- /* Set temporary dimension for advancing offsets */
- temp_dim = (int)skip_dim;
-
- /* Increment offset in destination buffer */
- loc += skip_slab;
-
- /* Increment the offset and count for the other dimensions */
- while(temp_dim >= 0) {
- /* Move to the next row in the curent dimension */
- offset[temp_dim]++;
- tmp_block[temp_dim]++;
-
- /* If this block is still in the range of blocks to output for the dimension, break out of loop */
- if(tmp_block[temp_dim] < tdiminfo[temp_dim].block)
- break;
- else {
- offset[temp_dim] = base_offset[temp_dim];
- loc += skip[temp_dim];
- tmp_block[temp_dim] = 0;
- } /* end else */
-
- /* Decrement dimension count */
- temp_dim--;
- } /* end while */
-
- /* Decrement block count */
- blk_count--;
- } /* end while */
- } /* end else */
- } /* end else */
-
- /* Update the iterator, if there were any blocks used */
-
- /* Decrement the number of elements left in selection */
- iter->elmt_left -= tot_blk_count * actual_elem;
-
- /* Check if there are elements left in iterator */
- if(iter->elmt_left > 0) {
- /* Update the iterator with the location we stopped */
- /* (Subtract out the selection offset) */
- for(u = 0; u < ndims; u++)
- iter->u.hyp.off[u] = (hsize_t)((hssize_t)offset[u] - sel_off[u]);
- } /* end if */
-
- /* Increment the number of sequences generated */
- *nseq += tot_blk_count;
-
- /* Increment the number of elements used */
- *nelem += tot_blk_count * actual_elem;
- } /* end if */
-
- /* Check for partial block, with room for another sequence */
- if(io_left > (tot_blk_count * actual_elem) && tot_blk_count < maxseq) {
- size_t elmt_remainder; /* Elements remaining */
-
- /* Compute elements left */
- elmt_remainder = io_left - (tot_blk_count * actual_elem);
- HDassert(elmt_remainder < fast_dim_block);
- HDassert(elmt_remainder > 0);
-
- /* Store the sequence information */
- *off++ = loc;
- *len++ = elmt_remainder * elem_size;
-
- /* Update the iterator with the location we stopped */
- iter->u.hyp.off[fast_dim] += (hsize_t)elmt_remainder;
-
- /* Decrement the number of elements left in selection */
- iter->elmt_left -= elmt_remainder;
-
- /* Increment the number of sequences generated */
- (*nseq)++;
-
- /* Increment the number of elements used */
- *nelem += elmt_remainder;
- } /* end if */
-
- /* Sanity check */
- HDassert(*nseq > 0);
- HDassert(*nelem > 0);
-
- FUNC_LEAVE_NOAPI(SUCCEED)
-} /* end H5S__hyper_get_seq_list_single() */
-
-
-/*--------------------------------------------------------------------------
- NAME
- H5S__hyper_get_seq_list
- PURPOSE
- Create a list of offsets & lengths for a selection
- USAGE
- herr_t H5S__hyper_get_seq_list(space,flags,iter,maxseq,maxelem,nseq,nelem,off,len)
- H5S_t *space; IN: Dataspace containing selection to use.
- unsigned flags; IN: Flags for extra information about operation
- H5S_sel_iter_t *iter; IN/OUT: Selection iterator describing last
- position of interest in selection.
- size_t maxseq; IN: Maximum number of sequences to generate
- size_t maxelem; IN: Maximum number of elements to include in the
- generated sequences
- size_t *nseq; OUT: Actual number of sequences generated
- size_t *nelem; OUT: Actual number of elements in sequences generated
- hsize_t *off; OUT: Array of offsets
- size_t *len; OUT: Array of lengths
- RETURNS
- Non-negative on success/Negative on failure.
- DESCRIPTION
- Use the selection in the dataspace to generate a list of byte offsets and
- lengths for the region(s) selected. Start/Restart from the position in the
- ITER parameter. The number of sequences generated is limited by the MAXSEQ
- parameter and the number of sequences actually generated is stored in the
- NSEQ parameter.
- GLOBAL VARIABLES
- COMMENTS, BUGS, ASSUMPTIONS
- EXAMPLES
- REVISION LOG
---------------------------------------------------------------------------*/
-static herr_t
-H5S__hyper_get_seq_list(const H5S_t *space, unsigned H5_ATTR_UNUSED flags, H5S_sel_iter_t *iter,
- size_t maxseq, size_t maxelem, size_t *nseq, size_t *nelem,
- hsize_t *off, size_t *len)
-{
- herr_t ret_value = FAIL; /* return value */
-
- FUNC_ENTER_STATIC_NOERR
-
- /* Check args */
- HDassert(space);
- HDassert(iter);
- HDassert(iter->elmt_left > 0);
- HDassert(maxseq > 0);
- HDassert(maxelem > 0);
- HDassert(nseq);
- HDassert(nelem);
- HDassert(off);
- HDassert(len);
- HDassert(space->select.sel_info.hslab->unlim_dim < 0);
-
- /* Check for the special case of just one H5Sselect_hyperslab call made */
- if(space->select.sel_info.hslab->diminfo_valid) {
- const H5S_hyper_dim_t *tdiminfo; /* Temporary pointer to diminfo information */
- const hssize_t *sel_off; /* Selection offset in dataspace */
- hsize_t *mem_size; /* Size of the source buffer */
- unsigned ndims; /* Number of dimensions of dataset */
- unsigned fast_dim; /* Rank of the fastest changing dimension for the dataspace */
- hbool_t single_block; /* Whether the selection is a single block */
- unsigned u; /* Local index variable */
-
- /* Set a local copy of the diminfo pointer */
- tdiminfo = iter->u.hyp.diminfo;
-
- /* Check if this is a "flattened" regular hyperslab selection */
- if(iter->u.hyp.iter_rank != 0 && iter->u.hyp.iter_rank < space->extent.rank) {
- /* Set the aliases for a few important dimension ranks */
- ndims = iter->u.hyp.iter_rank;
-
- /* Set the local copy of the selection offset */
- sel_off = iter->u.hyp.sel_off;
-
- /* Set up the pointer to the size of the memory space */
- mem_size = iter->u.hyp.size;
- } /* end if */
- else {
- /* Set the aliases for a few important dimension ranks */
- ndims = space->extent.rank;
-
- /* Set the local copy of the selection offset */
- sel_off = space->select.offset;
-
- /* Set up the pointer to the size of the memory space */
- mem_size = space->extent.size;
- } /* end else */
- fast_dim = ndims - 1;
-
- /* Check if we stopped in the middle of a sequence of elements */
- if((iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start) % tdiminfo[fast_dim].stride != 0 ||
- ((iter->u.hyp.off[fast_dim] != tdiminfo[fast_dim].start) && tdiminfo[fast_dim].count == 1)) {
- hsize_t slab[H5O_LAYOUT_NDIMS]; /* Hyperslab size */
- hsize_t loc; /* Coordinate offset */
- hsize_t acc; /* Accumulator */
- size_t leftover; /* The number of elements left over from the last sequence */
- size_t actual_elem; /* The actual number of elements to count */
- size_t elem_size; /* Size of each element iterating over */
- int i; /* Local index variable */
-
-
- /* Calculate the number of elements left in the sequence */
- if(tdiminfo[fast_dim].count == 1) {
- H5_CHECKED_ASSIGN(leftover, size_t, tdiminfo[fast_dim].block - (iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start), hsize_t);
- } /* end if */
- else {
- H5_CHECKED_ASSIGN(leftover, size_t, tdiminfo[fast_dim].block - ((iter->u.hyp.off[fast_dim] - tdiminfo[fast_dim].start) % tdiminfo[fast_dim].stride), hsize_t);
- } /* end else */
-
- /* Make certain that we don't write too many */
- actual_elem = MIN3(leftover, (size_t)iter->elmt_left, maxelem);
-
- /* Initialize row sizes for each dimension */
- elem_size = iter->elmt_size;
- for(i = (int)fast_dim, acc = elem_size; i >= 0; i--) {
- slab[i] = acc;
- acc *= mem_size[i];
- } /* end for */
-
- /* Compute the initial buffer offset */
- for(u = 0, loc = 0; u < ndims; u++)
- loc += ((hsize_t)((hssize_t)iter->u.hyp.off[u] + sel_off[u])) * slab[u];
-
- /* Add a new sequence */
- off[0] = loc;
- H5_CHECKED_ASSIGN(len[0], size_t, actual_elem * elem_size, hsize_t);
-
- /* Increment sequence array locations */
- off++;
- len++;
-
- /* Advance the hyperslab iterator */
- H5S__hyper_iter_next(iter, actual_elem);
-
- /* Decrement the number of elements left in selection */
- iter->elmt_left -= actual_elem;
-
- /* Decrement element/sequence limits */
- maxelem -= actual_elem;
- maxseq--;
-
- /* Set the number of sequences generated and elements used */
- *nseq = 1;
- *nelem = actual_elem;
-
- /* Check for using up all the sequences/elements */
- if(0 == iter->elmt_left || 0 == maxelem || 0 == maxseq)
- return(SUCCEED);
- } /* end if */
- else {
- /* Reset the number of sequences generated and elements used */
- *nseq = 0;
- *nelem = 0;
- } /* end else */
-
- /* Check for a single block selected */
- single_block = TRUE;
- for(u = 0; u < ndims; u++)
- if(1 != tdiminfo[u].count) {
- single_block = FALSE;
- break;
- } /* end if */
-
- /* Check for single block selection */
- if(single_block)
- /* Use single-block optimized call to generate sequence list */
- ret_value = H5S__hyper_get_seq_list_single(space, iter, maxseq, maxelem, nseq, nelem, off, len);
- else
- /* Use optimized call to generate sequence list */
- ret_value = H5S__hyper_get_seq_list_opt(space, iter, maxseq, maxelem, nseq, nelem, off, len);
- } /* end if */
- else
- /* Call the general sequence generator routine */
- ret_value = H5S__hyper_get_seq_list_gen(space, iter, maxseq, maxelem, nseq, nelem, off, len);
-
- FUNC_LEAVE_NOAPI(ret_value)
-} /* end H5S__hyper_get_seq_list() */
/*--------------------------------------------------------------------------
@@ -9251,11 +8129,10 @@ H5S__hyper_get_seq_list(const H5S_t *space, unsigned H5_ATTR_UNUSED flags, H5S_s
DESCRIPTION
Projects the intersection of of the selections of src_space and
src_intersect_space within the selection of src_space as a selection
- within the selection of dst_space. The result is placed in the
- selection of proj_space. Note src_space, dst_space, and
- src_intersect_space do not need to use hyperslab selections, but they
- cannot use point selections. The result is always a hyperslab
- selection.
+ within the selection of dst_space. The result is placed in the selection
+ of proj_space. Note src_space, dst_space, and src_intersect_space do not
+ need to use hyperslab selections, but they cannot use point selections.
+ The result is always a hyperslab selection.
GLOBAL VARIABLES
COMMENTS, BUGS, ASSUMPTIONS
EXAMPLES
@@ -9314,24 +8191,20 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
HDassert(dst_space);
HDassert(src_intersect_space);
HDassert(proj_space);
-
+
/* Assert that src_space and src_intersect_space have same extent and there
* are no point selections */
- HDassert(H5S_GET_EXTENT_NDIMS(src_space)
- == H5S_GET_EXTENT_NDIMS(src_intersect_space));
+ HDassert(H5S_GET_EXTENT_NDIMS(src_space) == H5S_GET_EXTENT_NDIMS(src_intersect_space));
HDassert(!HDmemcmp(src_space->extent.size, src_intersect_space->extent.size,
- (size_t)H5S_GET_EXTENT_NDIMS(src_space)
- * sizeof(src_space->extent.size[0])));
+ (size_t)H5S_GET_EXTENT_NDIMS(src_space) * sizeof(src_space->extent.size[0])));
HDassert(H5S_GET_SELECT_TYPE(src_space) != H5S_SEL_POINTS);
HDassert(H5S_GET_SELECT_TYPE(dst_space) != H5S_SEL_POINTS);
HDassert(H5S_GET_SELECT_TYPE(src_intersect_space) != H5S_SEL_POINTS);
/* Initialize prev_space, curr_span_tree, and curr_span_up_dim */
- for(i = 0; i < H5S_MAX_RANK; i++) {
- curr_span_tree[i] = NULL;
- prev_span[i] = NULL;
- curr_span_up_dim[i] = (hsize_t)0;
- } /* end for */
+ HDmemset(curr_span_tree, 0, sizeof(curr_span_tree));
+ HDmemset(prev_span, 0, sizeof(prev_span));
+ HDmemset(curr_span_up_dim, 0, sizeof(curr_span_up_dim));
/* Save rank of projected space */
proj_rank = proj_space->extent.rank;
@@ -9343,8 +8216,7 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
sis_nelem = (size_t)H5S_GET_SELECT_NPOINTS(src_intersect_space);
HDassert(ss_nelem == ds_nelem);
- /* Calculate proj_down_dims (note loop relies on unsigned i wrapping around)
- */
+ /* Calculate proj_down_dims */
if(H5VM_array_down(proj_rank, proj_space->extent.size, proj_down_dims) < 0)
HGOTO_ERROR(H5E_DATASPACE, H5E_CANTSET, FAIL, "can't compute 'down' chunk size value")
@@ -9358,7 +8230,7 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
/* Allocate space for the hyperslab selection information (note this sets
* diminfo_valid to FALSE, diminfo arrays to 0, and span list to NULL) */
- if((proj_space->select.sel_info.hslab = H5FL_CALLOC(H5S_hyper_sel_t)) == NULL)
+ if(NULL == (proj_space->select.sel_info.hslab = H5FL_CALLOC(H5S_hyper_sel_t)))
HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate hyperslab info")
/* Set selection type */
@@ -9367,9 +8239,9 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
/* Set unlim_dim */
proj_space->select.sel_info.hslab->unlim_dim = -1;
- /* Allocate the source space iterator */
+ /* Allocate the source selection iterator */
if(NULL == (ss_iter = H5FL_MALLOC(H5S_sel_iter_t)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate source space iterator")
+ HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate source selection iterator")
/* Initialize source space iterator */
if(H5S_select_iter_init(ss_iter, src_space, (size_t)1) < 0)
@@ -9382,9 +8254,9 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
ss_nelem -= nelem;
HDassert(ss_nseq > 0);
- /* Allocate the destination space iterator */
+ /* Allocate the destination selection iterator */
if(NULL == (ds_iter = H5FL_MALLOC(H5S_sel_iter_t)))
- HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate destination space iterator")
+ HGOTO_ERROR(H5E_DATASPACE, H5E_CANTALLOC, FAIL, "can't allocate destination selection iterator")
/* Initialize destination space iterator */
if(H5S_select_iter_init(ds_iter, dst_space, (size_t)1) < 0)
@@ -9443,9 +8315,8 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
/* Reset advance_ss */
advance_ss = FALSE;
- } /* end if */
- if(advance_sis
- || (sis_off[sis_i] + sis_len[sis_i] <= ss_off[ss_i])) {
+ } /* end while */
+ if(advance_sis || (sis_off[sis_i] + sis_len[sis_i] <= ss_off[ss_i])) {
do {
/* Either we finished the current source intersect sequence or
* the sequences do not intersect. Advance source intersect
@@ -9483,7 +8354,7 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
* selection and advance any sequences we complete */
if(ss_off[ss_i] >= sis_off[sis_i])
int_sel_off = ss_sel_off;
- else
+ else
int_sel_off = sis_off[sis_i] - ss_off[ss_i] + ss_sel_off;
if((ss_off[ss_i] + (hsize_t)ss_len[ss_i]) <= (sis_off[sis_i]
+ (hsize_t)sis_len[sis_i])) {
@@ -9524,8 +8395,7 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
HDassert(ds_sel_off <= int_sel_off);
proj_off = ds_off[ds_i] + int_sel_off - ds_sel_off;
proj_len = proj_len_rem = (size_t)MIN(int_len,
- (size_t)(ds_sel_off + (hsize_t)ds_len[ds_i]
- - int_sel_off));
+ (size_t)(ds_sel_off + (hsize_t)ds_len[ds_i] - int_sel_off));
/* Add to span tree */
while(proj_len_rem > (size_t)0) {
@@ -9565,7 +8435,7 @@ H5S__hyper_project_intersection(const H5S_t *src_space, const H5S_t *dst_space,
(size_t)(proj_space->extent.size[proj_rank - 1]
- low));
HDassert(proj_len_rem >= span_len);
- high = low + (hsize_t)span_len - (hsize_t)1;
+ high = (low + (hsize_t)span_len) - (hsize_t)1;
/* Append span in lowest dimension */
if(H5S__hyper_append_span(&prev_span[proj_rank - 1], &curr_span_tree[proj_rank - 1], low, high, NULL, NULL) < 0)
@@ -9608,8 +8478,9 @@ loop_end:
/* Set the number of elements in current selection */
proj_space->select.num_elem = H5S__hyper_spans_nelem(proj_space->select.sel_info.hslab->span_lst);
- /* Attempt to rebuild "optimized" start/stride/count/block information.
- * from resulting hyperslab span tree */
+ /* Attempt to build "optimized" start/stride/count/block information
+ * from resulting hyperslab span tree.
+ */
H5S__hyper_rebuild(proj_space);
} /* end if */
else
@@ -9791,11 +8662,11 @@ done:
EXAMPLES
REVISION LOG
--------------------------------------------------------------------------*/
-void
+static void
H5S__hyper_get_clip_diminfo(hsize_t start, hsize_t stride, hsize_t *count,
hsize_t *block, hsize_t clip_size)
{
- FUNC_ENTER_PACKAGE_NOERR
+ FUNC_ENTER_STATIC_NOERR
/* Check for selection outside clip size */
if(start >= clip_size) {
@@ -9819,7 +8690,7 @@ H5S__hyper_get_clip_diminfo(hsize_t start, hsize_t stride, hsize_t *count,
} /* end else */
FUNC_LEAVE_NOAPI_VOID
-} /* end H5S_hyper_get_clip_diminfo() */
+} /* end H5S__hyper_get_clip_diminfo() */
/*--------------------------------------------------------------------------
@@ -9836,8 +8707,7 @@ H5S__hyper_get_clip_diminfo(hsize_t start, hsize_t stride, hsize_t *count,
Non-negative on success/Negative on failure.
DESCRIPTION
This function changes the unlimited selection into a limited selection
- with the extent of the formerly unlimited dimension specified by
- * clip_size.
+ with the extent of the formerly unlimited dimension specified by clip_size.
GLOBAL VARIABLES
COMMENTS, BUGS, ASSUMPTIONS
Note this function does not take the offset into account.
@@ -9851,7 +8721,7 @@ H5S_hyper_clip_unlim(H5S_t *space, hsize_t clip_size)
hsize_t orig_count; /* Original count in unlimited dimension */
int orig_unlim_dim; /* Original unliminted dimension */
H5S_hyper_dim_t *diminfo; /* Convenience pointer to opt_diminfo in unlimited dimension */
- herr_t ret_value = SUCCEED;
+ herr_t ret_value = SUCCEED; /* Return value */
FUNC_ENTER_NOAPI(FAIL)
@@ -9892,8 +8762,7 @@ H5S_hyper_clip_unlim(H5S_t *space, hsize_t clip_size)
} /* end if */
else {
/* Calculate number of elements */
- space->select.num_elem = diminfo->count * diminfo->block
- * hslab->num_elem_non_unlim;
+ space->select.num_elem = diminfo->count * diminfo->block * hslab->num_elem_non_unlim;
/* Check if last block is partial. If superset is set, just keep the
* last block complete to speed computation. */
@@ -9924,8 +8793,7 @@ H5S_hyper_clip_unlim(H5S_t *space, hsize_t clip_size)
/* Indicate that the regular dimensions are no longer valid */
hslab->diminfo_valid = FALSE;
- /* "And" selection with calculated block to perform clip operation
- */
+ /* "And" selection with calculated block to perform clip operation */
if(H5S__generate_hyperslab(space, H5S_SELECT_AND, start, H5S_hyper_ones_g, H5S_hyper_ones_g, block) < 0)
HGOTO_ERROR(H5E_DATASPACE, H5E_CANTINSERT, FAIL, "can't generate hyperslabs")
} /* end if */
@@ -10237,7 +9105,7 @@ H5S_hyper_get_unlim_block(const H5S_t *space, hsize_t block_index)
/* Create output space, copy extent */
if(NULL == (space_out = H5S_create(H5S_SIMPLE)))
HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCREATE, NULL, "unable to create output dataspace")
- if(H5S_extent_copy_real(&space_out->extent, &space->extent, TRUE) < 0)
+ if(H5S__extent_copy_real(&space_out->extent, &space->extent, TRUE) < 0)
HGOTO_ERROR(H5E_DATASPACE, H5E_CANTCOPY, NULL, "unable to copy destination space extent")
/* Select block as defined by start/stride/count/block computed above */
@@ -10364,12 +9232,12 @@ H5Sis_regular_hyperslab(hid_t spaceid)
done:
FUNC_LEAVE_API(ret_value)
-} /* H5Sis_regular_hyperslab() */
+} /* end H5Sis_regular_hyperslab() */
/*--------------------------------------------------------------------------
NAME
- H5Sgetregular_hyperslab
+ H5Sget_regular_hyperslab
PURPOSE
Retrieve a regular hyperslab selection
USAGE
@@ -10428,5 +9296,5 @@ H5Sget_regular_hyperslab(hid_t spaceid, hsize_t start[], hsize_t stride[],
done:
FUNC_LEAVE_API(ret_value)
-} /* H5Sget_regular_hyperslab() */
+} /* end H5Sget_regular_hyperslab() */
generated by cgit v0.12 at 2024-07-08 05:32:54 (GMT)