Introduction to HDF5

This is an introduction to the HDF5 data model and programming model. Being a Getting Started or QuickStart document, this Introduction to HDF5 is intended to provide enough information for you to develop a basic understanding of how HDF5 works and is meant to be used. Knowledge of the current version of HDF will make it easier to follow the text, but it is not required. More complete information of the sort you will need to actually use HDF5 is available in the HDF5 documentation. Available documents include the following:

• HDF5 User’s Guide. Where appropriate, this Introduction will refer to specific sections of the User’s Guide.
• HDF5 Reference Manual.

• The directories hdf5/examples, hdf5/doc/html/examples/, and hdf5/doc/html/Tutor/examples/ contain the examples used in this document.
• The directory hdf5/test contains the development tests used by the HDF5 developers. Since these codes are intended to fully exercise the system, they provide more diverse and sophisticated examples of what HDF5 can do.

1. What Is HDF5?

• A single file cannot store more than 20,000 complex objects, and a single file cannot be larger than 2 gigabytes.
• The data models are less consistent than they should be, there are more object types than necessary, and datatypes are too restricted.
• The library source is old and overly complex, does not support parallel I/O effectively, and is difficult to use in threaded applications.

• A new file format designed to address some of the deficiencies of HDF4.x, particularly the need to store larger files and more objects per file.
• A simpler, more comprehensive data model that includes only two basic structures: a multidimensional array of record structures, and a grouping structure.
• A simpler, better-engineered library and API, with improved support for parallel I/O, threads, and other requirements imposed by modern systems and applications.

(Return to TOC)

Changes in the Current Release

A detailed list of changes in HDF5 between the current release and the preceding major release can be found in the file RELEASE.txt, with a highlights summary in the document "HDF5 Software Changes from Release to Release" in the HDF5 Application Developer's Guide.

(Return to TOC)

2. HDF5 File Organization and Data Model

• HDF5 group: a grouping structure containing instances of zero or more groups or datasets, together with supporting metadata.
• HDF5 dataset: a multidimensional array of data elements, together with supporting metadata.

Working with groups and group members is similar in many ways to working with directories and files in UNIX. As with UNIX directories and files, objects in an HDF5 file are often described by giving their full (or absolute) path names.

/ signifies the root group.

/foo signifies a member of the root group called foo.

/foo/zoo signifies a member of the group foo, which in turn is a member of the root group.

(Return to TOC)

HDF5 Groups

• A group header, which contains a group name and a list of group attributes.
• A group symbol table, which is a list of the HDF5 objects that belong to the group.

(Return to TOC)

HDF5 Datasets

There are four essential classes of information in any header: name, datatype, dataspace, and storage layout:

Name. A dataset name is a sequence of alphanumeric ASCII characters.

Datatype. HDF5 allows one to define many different kinds of datatypes. There are two categories of datatypes: atomic datatypes and compound datatypes. Atomic datatypes can also be system-specific, or NATIVE, and all datatypes can be named:

• Atomic datatypes are those that are not decomposed at the datatype interface level, such as integers and floats.
• NATIVE datatypes are system-specific instances of atomic datatypes.
• Compound datatypes are made up of atomic datatypes.
• Named datatypes are either atomic or compound datatypes that have been specifically designated to be shared across datasets.

• Integer datatypes: 8-bit, 16-bit, 32-bit, and 64-bit integers in both little and big-endian format
• Floating-point numbers: IEEE 32-bit and 64-bit floating-point numbers in both little and big-endian format
• References
• Strings

NATIVE datatypes. Although it is possible to describe nearly any kind of atomic datatype, most applications will use predefined datatypes that are supported by their compiler. In HDF5 these are called native datatypes. NATIVE datatypes are C-like datatypes that are generally supported by the hardware of the machine on which the library was compiled. In order to be portable, applications should almost always use the NATIVE designation to describe data values in memory.

The NATIVE architecture has base names which do not follow the same rules as the others. Instead, native type names are similar to the C type names. The following figure shows several examples.

See Datatypes in the HDF User’s Guide for further information.

A compound datatype is one in which a collection of several datatypes are represented as a single unit, a compound datatype, similar to a struct in C. The parts of a compound datatype are called members. The members of a compound datatype may be of any datatype, including another compound datatype. It is possible to read members from a compound type without reading the whole type.

Named datatypes. Normally each dataset has its own datatype, but sometimes we may want to share a datatype among several datasets. This can be done using a named datatype. A named datatype is stored in the file independently of any dataset, and referenced by all datasets that have that datatype. Named datatypes may have an associated attributes list. See Datatypes in the HDF User’s Guide for further information.

Dataspace. A dataset dataspace describes the dimensionality of the dataset. The dimensions of a dataset can be fixed (unchanging), or they may be unlimited, which means that they are extendible (i.e. they can grow larger).

Properties of a dataspace consist of the rank (number of dimensions) of the data array, the actual sizes of the dimensions of the array, and the maximum sizes of the dimensions of the array. For a fixed-dimension dataset, the actual size is the same as the maximum size of a dimension. When a dimension is unlimited, the maximum size is set to the value H5P_UNLIMITED. (An example below shows how to create extendible datasets.)

A dataspace can also describe portions of a dataset, making it possible to do partial I/O operations on selections. Selection is supported by the dataspace interface (H5S). Given an n-dimensional dataset, there are currently four ways to do partial selection:

1. Select a logically contiguous n-dimensional hyperslab.
2. Select a non-contiguous hyperslab consisting of elements or blocks of elements (hyperslabs) that are equally spaced.
3. Select a union of hyperslabs.
4. Select a list of independent points.

See Dataspaces in the HDF User’s Guide for further information.

Storage layout. The HDF5 format makes it possible to store data in a variety of ways. The default storage layout format is contiguous, meaning that data is stored in the same linear way that it is organized in memory. Two other storage layout formats are currently defined for HDF5: compact, and chunked. In the future, other storage layouts may be added.

Compact storage is used when the amount of data is small and can be stored directly in the object header. (Note: Compact storage is not supported in this release.)

Chunked storage involves dividing the dataset into equal-sized "chunks" that are stored separately. Chunking has three important benefits.

1. It makes it possible to achieve good performance when accessing subsets of the datasets, even when the subset to be chosen is orthogonal to the normal storage order of the dataset.
2. It makes it possible to compress large datasets and still achieve good performance when accessing subsets of the dataset.
3. It makes it possible efficiently to extend the dimensions of a dataset in any direction.

See Datasets and Dataset Chunking Issues in the HDF User’s Guide for further information. We particularly encourage you to read Dataset Chunking Issues since the issue is complex and beyond the scope of this document.

(Return to TOC)

HDF5 Attributes

See Attributes in the HDF User’s Guide for further information.

(Return to TOC)

The File as Written to Media

For those who are interested, this section takes a look at the low-level elements of the file as the file is written to disk (or other storage media) and the relation of those low-level elements to the higher level elements with which users typically are more familiar. The HDF5 API generally exposes only the high-level elements to the user; the low-level elements are often hidden. The rest of this Introduction does not assume an understanding of this material.

The format of an HDF5 file on disk encompasses several key ideas of the HDF4 and AIO file formats as well as addressing some shortcomings therein. The new format is more self-describing than the HDF4 format and is more uniformly applied to data objects in the file.

Figure 1: Relationships among the HDF5 root group, other groups, and objects

An HDF5 file appears to the user as a directed graph. The nodes of this graph are the higher-level HDF5 objects that are exposed by the HDF5 APIs:

• Groups
• Datasets
• Datatypes
• Dataspaces

At the lowest level, as information is actually written to the disk, an HDF5 file is made up of the following objects:

• A super block
• B-tree nodes (containing either symbol nodes or raw data chunks)
• Object headers

  	Figure 2: HDF5 objects -- datasets, datatypes, or dataspaces

• Collections
• Local heaps
• Free space

See the HDF5 File Format Specification for further information.

(Return to TOC)

3. The HDF5 Applications Programming Interface (API)

The current HDF5 API is implemented only in C. The API provides routines for creating HDF5 files, creating and writing groups, datasets, and their attributes to HDF5 files, and reading groups, datasets and their attributes from HDF5 files.

Naming conventions

• H5F: File-level access routines.
  Example: H5Fopen, which opens an HDF5 file.
• H5G: Group functions, for creating and operating on groups of objects.
  Example: H5Gset,which sets the working group to the specified group.
• H5T: DataType functions, for creating and operating on simple and compound datatypes to be used as the elements in data arrays.
  Example: H5Tcopy,which creates a copy of an existing datatype.
• H5S: DataSpace functions, which create and manipulate the dataspace in which the elements of a data array are stored.
  Example: H5Screate_simple, which creates simple dataspaces.
• H5D: Dataset functions, which manipulate the data within datasets and determine how the data is to be stored in the file.
  Example: H5Dread, which reads all or part of a dataset into a buffer in memory.
• H5P: Property list functions, for manipulating object creation and access properties.
  Example: H5Pset_chunk, which sets the number of dimensions and the size of a chunk.
• H5A: Attribute access and manipulating routines.
  Example: H5Aget_name, which retrieves name of an attribute.
• H5Z: Compression registration routine.
  Example: H5Zregister, which registers new compression and uncompression functions for use with the HDF5 library.
• H5E: Error handling routines.
  Example: H5Eprint, which prints the current error stack.
• H5R: Reference routines.
  Example: H5Rcreate, which creates a reference.
• H5I: Identifier routine.
  Example: H5Iget_type, which retrieves the type of an object.

(Return to TOC)

Include Files

There are a number definitions and declarations that should be included with any HDF5 program. These definitions and declarations are contained in several include files. The main include file is hdf5.h. This file includes all of the other files that your program is likely to need. Be sure to include hdf5.h in any program that uses the HDF5 library.

(Return to TOC)

Programming Models

• Create a file.
• Create and initialize a dataset.
• Discard objects when they are no longer needed.
• Write a dataset to a new file.
• Obtain information about a dataset.
• Read a portion of a dataset.
• Create and write compound datatypes.
• Create and write extendible datasets.
• Create and populate groups.
• Work with attributes.

(Return to TOC)

How to create an HDF5 file

This programming model shows how to create a file and also how to close the file.

1. Create the file.
2. Close the file.

The following code fragment implements the specified model. If there is a possibility that the file already exists, the user must add the flag H5ACC_TRUNC to the access mode to overwrite the previous file's information.

hid_t       file;                          /* identifier */
/*
* Create a new file using H5ACC_TRUNC access,
* default file creation properties, and default file
* access properties.
* Then close the file.
*/
file = H5Fcreate(FILE, H5ACC_TRUNC, H5P_DEFAULT, H5P_DEFAULT);
status = H5Fclose(file); 

(Return to TOC)

How to create and initialize the essential components of a dataset for writing to a file

Recall that datatypes and dimensionality (dataspace) are independent objects, which are created separately from any dataset that they might be attached to. Because of this the creation of a dataset requires, at a minimum, separate definitions of datatype, dimensionality, and dataset. Hence, to create a dataset the following steps need to be taken:

1. Create and initialize a dataspace for the dataset to be written.
2. Define the datatype for the dataset to be written.
3. Create and initialize the dataset itself.

The following code illustrates the creation of these three components of a dataset object.

hid_t    dataset, datatype, dataspace;   /* declare identifiers */

/* 
 * Create dataspace: Describe the size of the array and 
 * create the data space for fixed size dataset. 
 */
dimsf[0] = NX;
dimsf[1] = NY;
dataspace = H5Screate_simple(RANK, dimsf, NULL); 
/*
 * Define datatype for the data in the file.
 * We will store little endian integer numbers.
 */
datatype = H5Tcopy(H5T_NATIVE_INT);
status = H5Tset_order(datatype, H5T_ORDER_LE);
/*
 * Create a new dataset within the file using defined 
 * dataspace and datatype and default dataset creation
 * properties.
 * NOTE: H5T_NATIVE_INT can be used as datatype if conversion
 * to little endian is not needed.
 */
dataset = H5Dcreate(file, DATASETNAME, datatype, dataspace, H5P_DEFAULT);

(Return to TOC)

How to discard objects when they are no longer needed

The datatype, dataspace and dataset objects should be released once they are no longer needed by a program. Since each is an independent object, the must be released (or closed) separately. The following lines of code close the datatype, dataspace, and datasets that were created in the preceding section.

H5Tclose(datatype);

H5Dclose(dataset);

H5Sclose(dataspace);

(Return to TOC)

How to write a dataset to a new file

Having defined the datatype, dataset, and dataspace parameters, you write out the data with a call to H5Dwrite.

/*
* Write the data to the dataset using default transfer
* properties.
*/
status = H5Dwrite(dataset, H5T_NATIVE_INT, H5S_ALL, H5S_ALL,
	  H5P_DEFAULT, data);

The third and fourth parameters of H5Dwrite in the example describe the dataspaces in memory and in the file, respectively. They are set to the value H5S_ALL to indicate that an entire dataset is to be written. In a later section we look at how we would access a portion of a dataset.

Example 1 contains a program that creates a file and a dataset, and writes the dataset to the file.

Reading is analogous to writing. If, in the previous example, we wish to read an entire dataset, we would use the same basic calls with the same parameters. Of course, the routine H5Dread would replace H5Dwrite.

(Return to TOC)

Getting information about a dataset

Although reading is analogous to writing, it is often necessary to query a file to obtain information about a dataset. For instance, we often need to know about the datatype associated with a dataset, as well dataspace information (e.g. rank and dimensions). There are several "get" routines for obtaining this information. The following code segment illustrates how we would get this kind of information:

/*
* Get datatype and dataspace identifiers and then query
* dataset class, order, size, rank and dimensions.
*/

datatype  = H5Dget_type(dataset);     /* datatype identifier */ 
class     = H5Tget_class(datatype);
if (class == H5T_INTEGER) printf("Data set has INTEGER type \n");
order     = H5Tget_order(datatype);
if (order == H5T_ORDER_LE) printf("Little endian order \n");

size  = H5Tget_size(datatype);
printf(" Data size is %d \n", size);

dataspace = H5Dget_space(dataset);    /* dataspace identifier */
rank      = H5Sget_simple_extent_ndims(dataspace);
status_n  = H5Sget_simple_extent_dims(dataspace, dims_out);
printf("rank %d, dimensions %d x %d \n", rank, dims_out[0], dims_out[1]);

(Return to TOC)

Reading and writing a portion of a dataset

In the previous discussion, we describe how to access an entire dataset with one write (or read) operation. HDF5 also supports access to portions (or selections) of a dataset in one read/write operation. Currently selections are limited to hyperslabs, their unions, and the lists of independent points. Both types of selection will be discussed in the following sections. Several sample cases of selection reading/writing are shown on the following figure.

a

b

c

d

In example (a) a single hyperslab is read from the midst of a two-dimensional array in a file and stored in the corner of a smaller two-dimensional array in memory. In (b) a regular series of blocks is read from a two-dimensional array in the file and stored as a contiguous sequence of values at a certain offset in a one-dimensional array in memory. In (c) a sequence of points with no regular pattern is read from a two-dimensional array in a file and stored as a sequence of points with no regular pattern in a three-dimensional array in memory. In (d) a union of hyperslabs in the file dataspace is read and the data is stored in another union of hyperslabs in the memory dataspace.

As these examples illustrate, whenever we perform partial read/write operations on the data, the following information must be provided: file dataspace, file dataspace selection, memory dataspace and memory dataspace selection. After the required information is specified, actual read/write operation on the portion of data is done in a single call to the HDF5 read/write functions H5Dread(write).

Selecting hyperslabs

Hyperslabs are portions of datasets. A hyperslab selection can be a logically contiguous collection of points in a dataspace, or it can be regular pattern of points or blocks in a dataspace. The following picture illustrates a selection of regularly spaced 3x2 blocks in an 8x12 dataspace.

• start: a starting location for the hyperslab. In the example start is (0,1).
• stride: the number of elements to separate each element or block to be selected. In the example stride is (4,3). If the stride parameter is set to NULL, the stride size defaults to 1 in each dimension.
• count: the number of elements or blocks to select along each dimension. In the example, count is (2,4).
• block: the size of the block selected from the dataspace. In the example, block is (3,2). If the block parameter is set to NULL, the block size defaults to a single element in each dimension, as if the block array was set to all 1s.

In what order is data copied? When actual I/O is performed data values are copied by default from one dataspace to another in so-called row-major, or C order. That is, it is assumed that the first dimension varies slowest, the second next slowest, and so forth.

Example without strides or blocks. Suppose we want to read a 3x4 hyperslab from a dataset in a file beginning at the element <1,2> in the dataset. In order to do this, we must create a dataspace that describes the overall rank and dimensions of the dataset in the file, as well as the position and size of the hyperslab that we are extracting from that dataset. The following code illustrates the selection of the hyperslab in the file dataspace.

/* 
* Define file dataspace.
*/
dataspace = H5Dget_space(dataset);    /* dataspace identifier */
rank      = H5Sget_simple_extent_ndims(dataspace);
status_n  = H5Sget_simple_extent_dims(dataspace, dims_out, NULL);

/* 
* Define hyperslab in the dataset. 
*/
offset[0] = 1;
offset[1] = 2;
count[0]  = 3;
count[1]  = 4;
status = H5Sselect_hyperslab(dataspace, H5S_SELECT_SET, offset, NULL, 
         count, NULL);

This describes the dataspace from which we wish to read. We need to define the dataspace in memory analogously. Suppose, for instance, that we have in memory a 3 dimensional 7x7x3 array into which we wish to read the 3x4 hyperslab described above beginning at the element <3,0,0>. Since the in-memory dataspace has three dimensions, we have to describe the hyperslab as an array with three dimensions, with the last dimension being 1: <3,4,1>.

Notice that we must describe two things: the dimensions of the in-memory array, and the size and position of the hyperslab that we wish to read in. The following code illustrates how this would be done.

/*
* Define memory dataspace.
*/
dimsm[0] = 7;
dimsm[1] = 7;
dimsm[2] = 3;
memspace = H5Screate_simple(RANK_OUT,dimsm,NULL);   

/* 
* Define memory hyperslab. 
*/
offset_out[0] = 3;
offset_out[1] = 0;
offset_out[2] = 0;
count_out[0]  = 3;
count_out[1]  = 4;
count_out[2]  = 1;
status = H5Sselect_hyperslab(memspace, H5S_SELECT_SET, offset_out, NULL, 
         count_out, NULL);

/*

Example 2 contains a complete program that performs these operations.

Example with strides and blocks. Consider the 8x12 dataspace described above, in which we selected eight 3x2 blocks. Suppose we wish to fill these eight blocks.

This hyperslab has the following parameters: start=(0,1), stride=(4,3), count=(2,4), block=(3,2).

Suppose that the source dataspace in memory is this 50-element one dimensional array called vector:

The following code will write 48 elements from vector to our file dataset, starting with the second element in vector.

/* Select hyperslab for the dataset in the file, using 3x2 blocks, (4,3) stride
 * (2,4) count starting at the position (0,1).
 */
start[0]  = 0; start[1]  = 1;
stride[0] = 4; stride[1] = 3;
count[0]  = 2; count[1]  = 4;    
block[0]  = 3; block[1]  = 2;
ret = H5Sselect_hyperslab(fid, H5S_SELECT_SET, start, stride, count, block);

/*
 * Create dataspace for the first dataset.
 */
mid1 = H5Screate_simple(MSPACE1_RANK, dim1, NULL);

/*
 * Select hyperslab. 
 * We will use 48 elements of the vector buffer starting at the second element.
 * Selected elements are 1 2 3 . . . 48
 */
start[0]  = 1;
stride[0] = 1;
count[0]  = 48;
block[0]  = 1;
ret = H5Sselect_hyperslab(mid1, H5S_SELECT_SET, start, stride, count, block);
 
/*
 * Write selection from the vector buffer to the dataset in the file.
 *
ret = H5Dwrite(dataset, H5T_NATIVE_INT, midd1, fid, H5P_DEFAULT, vector)

After these operations, the file dataspace will have the following values.

Notice that the values are inserted in the file dataset in row-major order.

Example 3 includes this code and other example code illustrating the use of hyperslab selection.

Selecting a list of independent points

#define FSPACE_RANK      2    /* Dataset rank as it is stored in the file */
#define NPOINTS          4    /* Number of points that will be selected 
                                 and overwritten */ 
#define MSPACE2_RANK     1    /* Rank of the second dataset in memory */ 
#define MSPACE2_DIM      4    /* Dataset size in memory */ 

 
hsize_t dim2[] = {MSPACE2_DIM};       /* Dimension size of the second 
                                         dataset (in memory) */ 
int     values[] = {53, 59, 61, 67};  /* New values to be written */
hsize_t coord[NPOINTS][FSPACE_RANK];  /* Array to store selected points 
                                         from the file dataspace */ 

/*
 * Create dataspace for the second dataset.
 */
mid2 = H5Screate_simple(MSPACE2_RANK, dim2, NULL);

/*
 * Select sequence of NPOINTS points in the file dataspace.
 */
coord[0][0] = 0; coord[0][1] = 0;
coord[1][0] = 3; coord[1][1] = 3;
coord[2][0] = 3; coord[2][1] = 5;
coord[3][0] = 5; coord[3][1] = 6;

ret = H5Sselect_elements(fid, H5S_SELECT_SET, NPOINTS, 
                         (const hsize_t **)coord);

/*
 * Write new selection of points to the dataset.
 */
ret = H5Dwrite(dataset, H5T_NATIVE_INT, mid2, fid, H5P_DEFAULT, values);   

After these operations, the file dataspace will have the following values:

Example 3 contains a complete program that performs these subsetting operations.

Selecting a union of hyperslabs

Suppose that we want to read two overlapping hyperslabs from the dataset written in the previous example into a union of hyperslabs in the memory dataset. This exercise is illustrated in the two figures immediately below. Note that the memory dataset has a different shape from the previously written dataset. Similarly, the selection in the memory dataset could have a different shape than the selected union of hyperslabs in the original file; for simplicity, we will preserve the selection's shape in this example.

The following lines of code show the required steps.

First obtain the dataspace identifier for the dataset in the file.

    /*
     * Get dataspace of the open dataset.
     */  
    fid = H5Dget_space(dataset);

    /*
     * Select first hyperslab for the dataset in the file. The following
     * elements are selected:
     *                     10  0 11 12
     *                     18  0 19 20
     *                      0 59  0 61
     *   
     */ 
    start[0] = 1; start[1] = 2;
    block[0] = 1; block[1] = 1;
    stride[0] = 1; stride[1] = 1;
    count[0]  = 3; count[1]  = 4;
    ret = H5Sselect_hyperslab(fid, H5S_SELECT_SET, start, stride, count, block); 

    /*
     * Add second selected hyperslab to the selection.
     * The following elements are selected:
     *                    19 20  0 21 22
     *                     0 61  0  0  0
     *                    27 28  0 29 30
     *                    35 36 67 37 38
     *                    43 44  0 45 46
     *                     0  0  0  0  0
     * Note that two hyperslabs overlap. Common elements are:
     *                                              19 20
     *                                               0 61
     */
    start[0] = 2; start[1] = 4;
    block[0] = 1; block[1] = 1;
    stride[0] = 1; stride[1] = 1;
    count[0]  = 6; count[1]  = 5;
    ret = H5Sselect_hyperslab(fid, H5S_SELECT_OR, start, stride, count, block);

Now define the memory dataspace and select the union of the hyperslabs in the memory dataset.

    /*
     * Create memory dataspace.
     */
    mid = H5Screate_simple(MSPACE_RANK, mdim, NULL);
     
    /*
     * Select two hyperslabs in memory. Hyperslabs has the same
     * size and shape as the selected hyperslabs for the file dataspace.
     */
    start[0] = 0; start[1] = 0;
    block[0] = 1; block[1] = 1;
    stride[0] = 1; stride[1] = 1;
    count[0]  = 3; count[1]  = 4;
    ret = H5Sselect_hyperslab(mid, H5S_SELECT_SET, start, stride, count, block);     
    start[0] = 1; start[1] = 2;
    block[0] = 1; block[1] = 1;
    stride[0] = 1; stride[1] = 1;
    count[0]  = 6; count[1]  = 5;
    ret = H5Sselect_hyperslab(mid, H5S_SELECT_OR, start, stride, count, block);

    ret = H5Dread(dataset, H5T_NATIVE_INT, mid, fid, H5P_DEFAULT, matrix_out);

Example 3 includes this code along with the previous selection example.

(Return to TOC)

Creating variable-length datatypes

VL datatypes are useful to the scientific community in many different ways, some of which are listed below:

• Ragged arrays: Multi-dimensional ragged arrays can be implemented with the last (fastest changing) dimension being ragged by using a VL datatype as the type of the element stored. (Or as a field in a compound datatype.)
• Fractal arrays: If a compound datatype has a VL field of another compound type with VL fields (a nested VL datatype), this can be used to implement ragged arrays of ragged arrays, to whatever nesting depth is required for the user.
• Polygon lists: A common storage requirement is to efficiently store arrays of polygons with different numbers of vertices. VL datatypes can be used to efficiently and succinctly describe an array of polygons with different numbers of vertices.
• Character strings: Perhaps the most common use of VL datatypes will be to store C-like VL character strings in dataset elements or as attributes of objects.
• Indices: An array of VL object references could be used as an index to all the objects in a file which contain a particular sequence of dataset values. Perhaps an array something like the following:

              Value1: Object1, Object3,  Object9
              Value2: Object0, Object12, Object14, Object21, Object22
              Value3: Object2
              Value4: <none>
              Value5: Object1, Object10, Object12
                  .
                  .
          

• Object Tracking: An array of VL dataset region references can be used as a method of tracking objects or features appearing in a sequence of datasets. Perhaps an array of them would look like:

              Feature1: Dataset1:Region,  Dataset3:Region,  Dataset9:Region
              Feature2: Dataset0:Region,  Dataset12:Region, Dataset14:Region,
                        Dataset21:Region, Dataset22:Region
              Feature3: Dataset2:Region
              Feature4: <none>
              Feature5: Dataset1:Region,  Dataset10:Region, Dataset12:Region
                  .
                  .
          

Variable-length datatype memory management

Variable-length datatypes cannot be divided

What happens if the library runs out of memory while reading?

Strings as variable-length datatypes

HDF5 has native VL strings for each language API, which are stored the same way on disk, but are exported through each language API in a natural way for that language. When retrieving VL strings from a dataset, users may choose to have them stored in memory as a native VL string or in HDF5's hvl_t struct for VL datatypes.

VL strings may be created in one of two ways: by creating a VL datatype with a base type of H5T_NATIVE_ASCII, H5T_NATIVE_UNICODE, etc., or by creating a string datatype and setting its length to H5T_VARIABLE. The second method is used to access native VL strings in memory. The library will convert between the two types, but they are stored on disk using different datatypes and have different memory representations.

Multi-byte character representations, such as UNICODE or wide characters in C/C++, will need the appropriate character and string datatypes created so that they can be described properly through the datatype API. Additional conversions between these types and the current ASCII characters will also be required.

Variable-width character strings (which might be compressed data or some other encoding) are not currently handled by this design. We will evaluate how to implement them based on user feedback.

Variable-length datatype APIs

Creation

type_id = H5Tvlen_create(hid_t base_type_id);

The base datatype will be the datatype that the sequence is composed of, characters for character strings, vertex coordinates for polygon lists, etc. The base datatype specified for the VL datatype can be of any HDF5 datatype, including another VL datatype, a compound datatype, or an atomic datatype.

Querying base datatype of VL datatype

Querying minimum memory required for VL information

herr_t H5Dvlen_get_buf_size(hid_t dataset_id, hid_t type_id, hid_t space_id, hsize_t *size)

This routine checks the number of bytes required to store the VL data from the dataset, using the space_id for the selection in the dataset on disk and the type_id for the memory representation of the VL data in memory. The *size value is modified according to how many bytes are required to store the VL data in memory.

Specifying how to manage memory for the VL datatype

Default memory management is set by using H5P_DEFAULT for the dataset transfer property list identifier. If H5P_DEFAULT is used with H5Dread, the system malloc and free calls will be used for allocating and freeing memory. In such a case, H5P_DEFAULT should also be passed as the property list identifier to H5Dvlen_reclaim.

The rest of this subsection is relevant only to those who choose not to use default memory management.

The user can choose whether to use the system malloc and free calls or user-defined, or custom, memory management functions. If user-defined memory management functions are to be used, the memory allocation and free routines must be defined via H5Pset_vlen_mem_manager(), as follows:

herr_t H5Pset_vlen_mem_manager(hid_t plist_id, H5MM_allocate_t alloc, void *alloc_info, H5MM_free_t free, void *free_info)

The alloc and free parameters identify the memory management routines to be used. If the user has defined custom memory management routines, alloc and/or free should be set to make those routine calls (i.e., the name of the routine is used as the value of the parameter); if the user prefers to use the system's malloc and/or free, the alloc and free parameters, respectively, should be set to NULL

The prototypes for the user-defined functions would appear as follows:

typedef void *(*H5MM_allocate_t)(size_t size, void *info) ;

typedef void (*H5MM_free_t)(void *mem, void *free_info) ;

The alloc_info and free_info parameters can be used to pass along any required information to the user's memory management routines.

In summary, if the user has defined custom memory management routines, the name(s) of the routines are passed in the alloc and free parameters and the custom routines' parameters are passed in the alloc_info and free_info parameters. If the user wishes to use the system malloc and free functions, the alloc and/or free parameters are set to NULL and the alloc_info and free_info parameters are ignored.

Recovering memory from VL buffers read in

herr_t H5Dvlen_reclaim(hid_t type_id, hid_t space_id, hid_t plist_id, void *buf);

The type_id must be the datatype stored in the buffer, space_id describes the selection for the memory buffer to free the VL datatypes within, plist_id is the dataset transfer property list which was used for the I/O transfer to create the buffer, and buf is the pointer to the buffer to free the VL memory within. The VL structures (hvl_t) in the user's buffer are modified to zero out the VL information after it has been freed.

If nested VL datatypes were used to create the buffer, this routine frees them from the bottom up, releasing all the memory without creating memory leaks.

Example 4 creates a dataset with the variable-length datatype using user-defined functions for memory management.

(Return to TOC)

Creating array datatypes

Arrays can be nested. Not only is an array datatype used as an element of an HDF5 dataset, but the elements of an array datatype may be of any datatype, including another array datatype.

Array datatypes cannot be subdivided for I/O; the entire array must be transferred from one dataset to another.

Within certain limitations, outlined in the next paragraph, array datatypes may be N-dimensional and of any dimension size. Unlimited dimensions, however, are not supported. Functionality similar to unlimited dimension arrays is available through the use of variable-length datatypes.

The maximum number of dimensions, i.e., the maximum rank, of an array datatype is specified by the HDF5 library constant H5S_MAX_RANK. The minimum rank is 1 (one). All dimension sizes must be greater than 0 (zero).

One array dataype may only be converted to another array datatype if the number of dimensions and the sizes of the dimensions are equal and the datatype of the first array's elements can be converted to the datatype of the second array's elements.

Array datatype APIs

Creating

• the base datatype of each element of the array,
• the rank of the array, i.e., the number of dimensions,
• the size of each dimension, and
• the dimension permutation of the array, i.e., whether the elements of the array are listed in C or FORTRAN order. (Note: The permutation feature is not implemented in Release 1.4.)

Working with existing array datatypes

The function H5Tget_array_ndims returns the rank of a specified array datatype.

Example 5 creates an array datatype and a dataset containing elements of the array datatype in an HDF5 file. It then writes the dataset to the file.

(Return to TOC)

Creating compound datatypes

Properties of compound datatypes. A compound datatype is similar to a struct in C or a common block in Fortran. It is a collection of one or more atomic types or small arrays of such types. To create and use of a compound datatype you need to refer to various properties of the data compound datatype:

• It is of class compound.
• It has a fixed total size, in bytes.
• It consists of zero or more members (defined in any order) with unique names and which occupy non-overlapping regions within the datum.
• Each member has its own datatype.
• Each member is referenced by an index number between zero and N-1, where N is the number of members in the compound datatype.
• Each member has a name which is unique among its siblings in a compound datatype.
• Each member has a fixed byte offset, which is the first byte (smallest byte address) of that member in a compound datatype.
• Each member can be a small array of up to four dimensions.

Offsets. Usually a C struct will be defined to hold a data point in memory, and the offsets of the members in memory will be the offsets of the struct members from the beginning of an instance of the struct. The library defines the macro to compute the offset of a member within a struct:
  HOFFSET(s,m)
This macro computes the offset of member m within a struct variable s.

Here is an example in which a compound datatype is created to describe complex numbers whose type is defined by the complex_t struct.

typedef struct {
   double re;   /*real part */
   double im;   /*imaginary part */
} complex_t;

complex_t tmp;  /*used only to compute offsets */
hid_t complex_id = H5Tcreate (H5T_COMPOUND, sizeof tmp);
H5Tinsert (complex_id, "real", HOFFSET(tmp,re),
           H5T_NATIVE_DOUBLE);
H5Tinsert (complex_id, "imaginary", HOFFSET(tmp,im),
           H5T_NATIVE_DOUBLE);

Example 6 shows how to create a compound datatype, write an array that has the compound datatype to the file, and read back subsets of the members.

(Return to TOC)

Creating and writing extendible and chunked datasets

For example, you can create and store the following 3x3 HDF5 dataset:

     1 1 1
     1 1 1 
     1 1 1 

then later to extend this into a 10x3 dataset by adding 7 rows, such as this:

     1 1 1 
     1 1 1 
     1 1 1 
     2 2 2
     2 2 2
     2 2 2
     2 2 2
     2 2 2
     2 2 2
     2 2 2

then further extend it to a 10x5 dataset by adding two columns, such as this:

     1 1 1 3 3 
     1 1 1 3 3 
     1 1 1 3 3 
     2 2 2 3 3
     2 2 2 3 3
     2 2 2 3 3
     2 2 2 3 3
     2 2 2 3 3
     2 2 2 3 3
     2 2 2 3 3

Declaring unlimited dimensions. We could declare the dataspace to have unlimited dimensions with the following code, which uses the predefined constant H5S_UNLIMITED to specify unlimited dimensions.

hsize_t dims[2] = { 3, 3}; /* dataset dimensions
at the creation time */ 
hsize_t maxdims[2] = {H5S_UNLIMITED, H5S_UNLIMITED};
/*
 * Create the data space with unlimited dimensions. 
 */
dataspace = H5Screate_simple(RANK, dims, maxdims); 

Enabling chunking. We can then set the dataset storage layout properties to enable chunking. We do this using the routine H5Pset_chunk:

hid_t cparms; 
hsize_t chunk_dims[2] ={2, 5};
/* 
 * Modify dataset creation properties to enable chunking.
 */
cparms = H5Pcreate (H5P_DATASET_CREATE);
status = H5Pset_chunk( cparms, RANK, chunk_dims);

/*
 * Create a new dataset within the file using cparms
 * creation properties.
 */
dataset = H5Dcreate(file, DATASETNAME, H5T_NATIVE_INT, dataspace,
                 cparms);

Extending dataset size. Finally, when we want to extend the size of the dataset, we invoke H5Dextend to extend the size of the dataset. In the following example, we extend the dataset along the first dimension, by seven rows, so that the new dimensions are <10,3>:

/*
 * Extend the dataset. Dataset becomes 10 x 3.
 */
dims[0] = dims[0] + 7;
size[0] = dims[0]; 
size[1] = dims[1]; 
status = H5Dextend (dataset, size);

Example 7 shows how to create a 3x3 extendible dataset, write the dataset, extend the dataset to 10x3, write the dataset again, extend it again to 10x5, write the dataset again.

Example 8 shows how to read the data written by Example 7.

(Return to TOC)

Working with groups in a file

Groups provide a mechanism for organizing meaningful and extendible sets of datasets within an HDF5 file. The H5G API contains routines for working with groups.

Creating a group. To create a group, use H5Gcreate. For example, the following code creates a group called Data in the root group.

 /*
  *  Create a group in the file.
  */
 grp = H5Gcreate(file, "/Data", 0);

 /*
  * Create group "Data_new" in the group "Data" by specifying
  * absolute name of the group.
  */
 grp_new = H5Gcreate(file, "/Data/Data_new", 0);

 /*
  * Create group "Data_new" in the "Data" group.
  */
 grp_new = H5Gcreate(grp, "Data_new", 0);

The third parameter in H5Gcreate optionally specifies how much file space to reserve to store the names that will appear in this group. If a non-positive value is supplied, then a default size is chosen.

H5Gclose closes the group and releases the group identifier.

Creating a dataset in a particular group. As with groups, a dataset can be created in a particular group by specifying its absolute name as illustrated in the following example:

 
 /*
  * Create the dataset "Compressed_Data" in the group using the 
  * absolute name. The dataset creation property list is modified 
  * to use GZIP compression with the compression effort set to 6.
  * Note that compression can be used only when the dataset is 
  * chunked.
  */
 dims[0] = 1000;
 dims[1] = 20;
 cdims[0] = 20;
 cdims[1] = 20;
 dataspace = H5Screate_simple(RANK, dims, NULL);
 plist     = H5Pcreate(H5P_DATASET_CREATE);
             H5Pset_chunk(plist, 2, cdims);
             H5Pset_deflate( plist, 6);
 dataset = H5Dcreate(file, "/Data/Compressed_Data", H5T_NATIVE_INT,
                     dataspace, plist);

 /* 
  * Open the group.
  */
 grp = H5Gopen(file, "Data");

 /*
  * Create the dataset "Compressed_Data" in the "Data" group
  * by providing a group identifier and a relative dataset 
  * name as parameters to the H5Dcreate function.
  */
 dataset = H5Dcreate(grp, "Compressed_Data", H5T_NATIVE_INT,
                     dataspace, plist);

Accessing an object in a group. Any object in a group can be accessed by its absolute or relative name. The following lines of code show how to use the absolute name to access the dataset Compressed_Data in the group Data created in the examples above:

  /*
   * Open the dataset "Compressed_Data" in the "Data" group. 
   */
  dataset = H5Dopen(file, "/Data/Compressed_Data");

  /*
   * Open the group "data" in the file.
   */
  grp  = H5Gopen(file, "Data");
 
  /*
   * Access the "Compressed_Data" dataset in the group.
   */
  dataset = H5Dopen(grp, "Compressed_Data");

Example 9 shows how to create a group in a file and a dataset in a group. It uses the iterator function H5Giterate to find the names of the objects in the root group, and H5Glink and H5Gunlink to create a new group name and delete the original name.

(Return to TOC)

Working with attributes

Think of an attribute as a small datasets that is attached to a normal dataset or group. The H5A API contains routines for working with attributes. Since attributes share many of the characteristics of datasets, the programming model for working with attributes is analogous in many ways to the model for working with datasets. The primary differences are that an attribute must be attached to a dataset or a group, and subsetting operations cannot be performed on attributes.

To create an attribute belonging to a particular dataset or group, first create a dataspace for the attribute with the call to H5Screate, then create the attribute using H5Acreate. For example, the following code creates an attribute called Integer_attribute that is a member of a dataset whose identifier is dataset. The attribute identifier is attr2. H5Awrite then sets the value of the attribute of that of the integer variable point. H5Aclose then releases the attribute identifier.

int point = 1;                         /* Value of the scalar attribute */ 

/*
 * Create scalar attribute.
 */
aid2  = H5Screate(H5S_SCALAR);
attr2 = H5Acreate(dataset, "Integer attribute", H5T_NATIVE_INT, aid2,
                  H5P_DEFAULT);

/*
 * Write scalar attribute.
 */
ret = H5Awrite(attr2, H5T_NATIVE_INT, &point); 

/*
 * Close attribute dataspace.
 */
ret = H5Sclose(aid2); 

/*
 * Close attribute.
 */
ret = H5Aclose(attr2); 

To read a scalar attribute whose name and datatype are known, first open the attribute using H5Aopen_name, then use H5Aread to get its value. For example the following reads a scalar attribute called Integer_attribute whose datatype is a native integer, and whose parent dataset has the identifier dataset.

/*
 * Attach to the scalar attribute using attribute name, then read and 
 * display its value.
 */
attr = H5Aopen_name(dataset,"Integer attribute");
ret  = H5Aread(attr, H5T_NATIVE_INT, &point_out);
printf("The value of the attribute \"Integer attribute\" is %d \n", point_out); 
ret =  H5Aclose(attr);

Reading an attribute whose characteristics are not known. It may be necessary to query a file to obtain information about an attribute, namely its name, datatype, rank and dimensions. The following code opens an attribute by its index value using H5Aopen_index, then reads in information about its datatype.

/*
 * Attach to the string attribute using its index, then read and display the value.
 */
attr =  H5Aopen_idx(dataset, 2);
atype = H5Tcopy(H5T_C_S1);
        H5Tset_size(atype, 4);
ret   = H5Aread(attr, atype, string_out);
printf("The value of the attribute with the index 2 is %s \n", string_out);

In practice, if the characteristics of attributes are not known, the code involved in accessing and processing the attribute can be quite complex. For this reason, HDF5 includes a function called H5Aiterate, which applies a user-supplied function to each of a set of attributes. The user-supplied function can contain the code that interprets, accesses and processes each attribute.

Example 10 illustrates the use of the H5Aiterate function, as well as the other attribute examples described above.

(Return to TOC)

Working with references to objects

An object reference is based on the relative file address of the object header in the file and is constant for the life of the object. Once a reference to an object is created and stored in a dataset in the file, it can be used to dereference the object it points to. References are handy for creating a file index or for grouping related objects by storing references to them in one dataset.

Creating and storing references to objects

1. Create the objects or open them if they already exist in the file.
2. Create a dataset to store the objects' references.
3. Create and store references to the objects in a buffer.
4. Write a buffer with the references to the dataset.

Programming example

Notes: Note the following elements of this example:

• The following code,

      dataset = H5Dcreate ( fid1,"Dataset3",H5T_STD_REF_OBJ,sid1,H5P_DEFAULT );
  

  creates a dataset to store references. Notice that the H5T_SDT_REF_OBJ datatype is used to specify that references to objects will be stored. The datatype H5T_STD_REF_DSETREG is used to store the dataset region references and is be discussed later.
• The next few calls to the H5Rcreate function create references to the objects and store them in the buffer wbuf. The signature of the H5Rcreate function is:

     herr_t H5Rcreate ( void* buf, hid_t loc_id, const char *name, 
                        H5R_type_t ref_type, hid_t space_id )    
  

  • The first argument specifies the buffer to store the reference.
  • The second and third arguments specify the name of the referenced object. In the example, the file identifier fid1 and absolute name of the dataset /Group1/Dataset1 identify the dataset. One could also use the group identifier of group Group1 and the relative name of the dataset Dataset1 to create the same reference.
  • The fourth argument specifies the type of the reference. The example uses references to the objects (H5R_OBJECT). Another type of reference, reference to the dataset region (H5R_DATASET_REGION), is discussed later.
  • The fifth argument specifies the space identifier. When references to the objects are created, it should be set to -1.
• The H5Dwrite function writes a dataset with the references to the file. Notice that the H5T_SDT_REF_OBJ datatype is used to describe the dataset's memory datatype.

HDF5 "trefer1.h5" {
GROUP "/" {
   DATASET "Dataset3" {
      DATATYPE { H5T_REFERENCE }
      DATASPACE { SIMPLE ( 4 ) / ( 4 ) }
      DATA {
         DATASET 0:1696, DATASET 0:2152, GROUP 0:1320, DATATYPE 0:2268
      }
   }
   GROUP "Group1" {
      DATASET "Dataset1" {
         DATATYPE { H5T_STD_U32LE }
         DATASPACE { SIMPLE ( 4 ) / ( 4 ) }
         DATA {
            0, 3, 6, 9
         }
      }
      DATASET "Dataset2" {
         DATATYPE { H5T_STD_U8LE }
         DATASPACE { SIMPLE ( 4 ) / ( 4 ) }
         DATA {
            0, 0, 0, 0
         }
      }
      DATATYPE "Datatype1" {
         H5T_STD_I32BE "a";
         H5T_STD_I32BE "b";
         H5T_IEEE_F32BE "c";
      }
   }
}
}

Reading references and accessing objects using references

1. Open the dataset with the references and read them. The H5T_STD_REF_OBJ datatype must be used to describe the memory datatype.
2. Use the read reference to obtain the identifier of the object the reference points to.
3. Open the dereferenced object and perform the desired operations.
4. Close all objects when the task is complete.

Programming example

Output file contents: The output of this program is as follows:

Dataset data : 
 0  3  6  9 

Group comment is Foo! 
 
Number of compound datatype members is 3 

Notes: Note the following elements of this example:

• The H5Dread function was used to read dataset Dataset3 containing the references to the objects. The H5T_STD_REF_OBJ memory datatype was used to read references to memory.
• H5Rdereference obtains the object's identifier. The signature of this function is:

           hid_t H5Rdereference (hid_t datatset, H5R_type_t ref_type, void *ref)
  

  • The first argument is an identifier of the dataset with the references.
  • The second argument specifies the reference type. H5R_OBJECT was used to specify a reference to an object. Another type, used to specifiy a reference to a dataset region and discussed later, is H5R_DATASET_REGION.
  • The third argument is a buffer to store the reference to be read.
  • The function returns an identifier of the object the reference points to. In this simplified situation, the type that was stored in the dataset is known. When the type of the object is unknown, H5Rget_object_type should be used to identify the type of object the reference points to.

(Return to TOC)

Working with references to dataset regions

Creating and storing references to dataset regions

1. Create a dataset to store the dataset regions (selections).

2. Create selections in the dataset(s). Dataset(s) should already exist in the file.

3. Create references to the selections and store them in a buffer.

4. Write references to the dataset regions in the file.

5. Close all objects.

Programming example

Notes: Note the following elements of this example:

• The code,

      dset1=H5Dcreate(fid1,"Dataset1",H5T_STD_REF_DSETREG,sid1,H5P_DEFAULT);
  

  creates a dataset to store references to the dataset(s) regions (selections). Notice that the H5T_STD_REF_DSETREG datatype is used.
• This program uses hyperslab and point selections. The dataspace handle sid2 is used for the calls to H5Sselect_hyperslab and H5Sselect_elements. The handle was created when dataset Dataset2 was created and it describes the dataset's dataspace. It was not closed when the dataset was closed to decrease the number of function calls used in the example. In a real application program, one should open the dataset and determine its dataspace using the H5Dget_space function.
• H5Rcreate is used to create a dataset region reference and store it in a buffer. The signature of the function is:

       herr_t H5Rcreate(void *buf, hid_t loc_id, const char *name,
                        H5R_type_t ref_type, hid_t space_id)
  

  • The first argument specifies the buffer to store the reference.
  • The second and third arguments specify the name of the referenced dataset. In the example, the file identifier fid1 and the absolute name of the dataset /Dataset2 were used to identify the dataset. The reference to the region of this dataset is stored in the buffer buf.
  • The fourth argument specifies the type of the reference. Since the example creates references to the dataset regions, the H5R_DATASET_REGION datatype is used.
  • The fifth argument is a dataspace identifier of the referenced dataset.

HDF5 "trefer2.h5" {
GROUP "/" {
   DATASET "Dataset1" {
      DATATYPE { H5T_REFERENCE }
      DATASPACE { SIMPLE ( 4 ) / ( 4 ) }
      DATA {
         DATASET 0:744 {(2,2)-(7,7)}, DATASET 0:744 {(6,9), (2,2), (8,4), (1,6),
          (2,8), (3,2), (0,4), (9,0), (7,1), (3,3)}, NULL, NULL
      }
   }
   DATASET "Dataset2" {
      DATATYPE { H5T_STD_U8LE }
      DATASPACE { SIMPLE ( 10, 10 ) / ( 10, 10 ) }
      DATA {
         0, 3, 6, 9, 12, 15, 18, 21, 24, 27,
         30, 33, 36, 39, 42, 45, 48, 51, 54, 57,
         60, 63, 66, 69, 72, 75, 78, 81, 84, 87,
         90, 93, 96, 99, 102, 105, 108, 111, 114, 117,
         120, 123, 126, 129, 132, 135, 138, 141, 144, 147,
         150, 153, 156, 159, 162, 165, 168, 171, 174, 177,
         180, 183, 186, 189, 192, 195, 198, 201, 204, 207,
         210, 213, 216, 219, 222, 225, 228, 231, 234, 237,
         240, 243, 246, 249, 252, 255, 255, 255, 255, 255,
         255, 255, 255, 255, 255, 255, 255, 255, 255, 255
      }
   }
}
}

Reading references to dataset regions

1. Open and read the dataset containing references to the dataset regions. The datatype H5T_STD_REF_DSETREG must be used during read operation.
2. Use H5Rdereference to obtain the dataset identifier from the read dataset region reference.

                          OR
       

   Use H5Rget_region to obtain the dataspace identifier for the dataset containing the selection from the read dataset region reference.
3. With the dataspace identifier, the H5S interface functions, H5Sget_select_*, can be used to obtain information about the selection.
4. Close all objects when they are no longer needed.

Programming example

Output: The output of this program is :

 Number of elements in the dataset is : 100
 0  3  6  9  12  15  18  21  24  27 
 30  33  36  39  42  45  48  51  54  57 
 60  63  66  69  72  75  78  81  84  87 
 90  93  96  99  102  105  108  111  114  117 
 120  123  126  129  132  135  138  141  144  147 
 150  153  156  159  162  165  168  171  174  177 
 180  183  186  189  192  195  198  201  204  207 
 210  213  216  219  222  225  228  231  234  237 
 240  243  246  249  252  255  255  255  255  255 
 255  255  255  255  255  255  255  255  255  255 
 Number of elements in the hyperslab is : 36 
 Hyperslab coordinates are : 
 ( 2 , 2 ) ( 7 , 7 ) 
 Number of selected elements is : 10
 Coordinates of selected elements are : 
 ( 6 , 9 ) 
 ( 2 , 2 ) 
 ( 8 , 4 ) 
 ( 1 , 6 ) 
 ( 2 , 8 ) 
 ( 3 , 2 ) 
 ( 0 , 4 ) 
 ( 9 , 0 ) 
 ( 7 , 1 ) 
 ( 3 , 3 ) 
 

• The dataset with the region references was read by H5Dread with the H5T_STD_REF_DSETREG datatype specified.
• The read reference can be used to obtain the dataset identifier with the following call:

      dset2 = H5Rdereference (dset1,H5R_DATASET_REGION,&rbuf[0]);
  

  or to obtain spacial information (dataspace and selection) with the call to H5Rget_region:

      sid2=H5Rget_region(dset1,H5R_DATASET_REGION,&rbuf[0]);
  

  The reference to the dataset region has information for both the dataset itself and its selection. In both functions:
  • The first parameter is an identifier of the dataset with the region references.
  • The second parameter specifies the type of reference stored. In this example, a reference to the dataset region is stored.
  • The third parameter is a buffer containing the reference of the specified type.
• This example introduces several H5Sget_select* functions used to obtain information about selections:
  H5Sget_select_npoints: returns the number of elements in the hyperslab
  H5Sget_select_hyper_nblocks: returns the number of blocks in the hyperslab
  H5Sget_select_blocklist: returns the "lower left" and "upper right" coordinates of the blocks in the hyperslab selection
  H5Sget_select_bounds: returns the coordinates of the "minimal" block containing a hyperslab selection
  H5Sget_select_elem_npoints: returns the number of points in the element selection
  H5Sget_select_elem_points: returns the coordinates of the element selection

(Return to TOC)

4. Example Codes

(Return to TOC)