HDF5 documents and links Introduction to HDF5 HDF5 User Guide |
And in this document, the
HDF5 Reference Manual
H5 H5A H5D H5E H5F H5G H5I H5P H5R H5S H5T H5Z Tools Datatypes |
The C Interfaces:
The FORTRAN90 Interfaces:
In general, each FORTRAN90 subroutine performs exactly the same task
as the corresponding C function. The links below go to the C function
descriptions, which serve as general descriptions for both. A button,
under Non-C API(s) at the end of the C function description,
opens an external browser window displaying the FORTRAN90-specific
information. You will probably want to adjust the size and location of
this external window so that both browser windows are visible and to
facilitate moving easily between them.
H5Pcreate
(H5P_class_t type
)
H5Pcreate
creates a new property as an instance of some
property list class. The new property list is initialized
with default values for the specified class. The classes are:
H5P_FILE_CREATE
H5P_FILE_ACCESS
H5P_DATASET_CREATE
H5P_DATASET_XFER
H5P_MOUNT
H5Pcreate
creates and returns a new mount property list
initialized with default values.
This property list must eventually be closed with
H5Pclose
;
otherwise, errors are likely to occur.
type
plist
) if successful;
otherwise Fail (-1).
H5Pclose
(hid_t plist
)
H5Pclose
terminates access to a property list.
All property lists should be closed when the application is
finished accessing them.
This frees resources used by the property list.
plist
H5Pget_class
(hid_t plist
)
H5Pget_class
returns the property list class for the
property list identified by the plist
parameter.
Valid property list classes are defined in the description of
H5Pcreate
.
plist
H5Pcopy
(hid_t plist
)
H5Pcopy
copies an existing property list to create
a new property list.
The new property list has the same properties and values
as the original property list.
plist
H5Pcreate_class
(
hid_t class
,
const char *name
,
H5P_cls_create_func_t create
,
H5P_cls_copy_func_t copy
,
H5P_cls_close_func_t H5Pcreate_class
registers a new property list class
with the library.
The new property list class can inherit from an existing property
list class or may be derived from the default "empty" class.
New classes with inherited properties from existing classes
may not remove those existing properties, only add or remove
their own class properties.
The create
routine is called when a new property list
of this class is being created.
The H5P_cls_create_func_t
callback function is defined
as follows:
H5P_cls_create_func_t
)(
hid_t prop_id
,
void * create_data
);
hid_t prop_id |
IN: The identifier of the property list being created |
void * create_data |
IN/OUT: User pointer to any class creation information needed |
create
routine is called after any registered
create
function is called for each property value.
If the create
routine returns a negative value,
the new list is not returned to the user and the
property list creation routine returns an error value.
The copy
routine is called when an existing property list
of this class is copied.
The H5P_cls_copy_func_t
callback function
is defined as follows:
H5P_cls_copy_func_t
)(
hid_t prop_id
,
void * copy_data
);
hid_t prop_id |
IN: The identifier of the property list created by copying |
void * copy_data |
IN/OUT: User pointer to any class copy information needed |
copy
routine is called after any registered
copy
function is called for each property value.
If the copy
routine returns a negative value, the new list
is not returned to the user and thenproperty list copy routine returns
an error value.
The close
routine is called when a property list of this
class
is being closed.
The
H5P_cls_close_func_t callback function is defined
as follows:
H5P_cls_close_func_t
)(
hid_t prop_id
,
void * close_data
);
hid_t prop_id |
IN: The identifier of the property list being closed |
void * close_data |
IN/OUT: User pointer to any class close information needed |
close
routine is called before any registered
close
function is called for each property value.
If the close
routine returns a negative value,
the property list close routine returns an error value
but the property list is still closed.
hid_t class |
IN: Property list class to inherit from. |
const char *name |
IN: Name of property list class to register |
H5P_cls_create_func_t create |
IN: Callback routine called when a property list is created |
H5P_cls_copy_func_t copy |
IN: Callback routine called when a property list is copied |
H5P_cls_close_func_t close |
IN: Callback routine called when a property list is being closed |
H5Pcreate_list
(
hid_t class
)
H5Pcreate_list
creates a new property list of a
given class. If a create
callback exists for the
property list class, it is called before the property list
is passed back to the user.
If create
callbacks exist for any individual properties
in the property list, they are called before the class
create
callback.
hid_t class ; |
IN: Class of property list to create. |
H5Pregister
(
hid_t class
,
const char * name
,
size_t size
,
void * default
,
H5P_prp_create_func_t create
,
H5P_prp_set_func_t set
,
H5P_prp_get_func_t get
,
H5P_prp_delete_func_t delete
,
H5P_prp_copy_func_t copy
,
H5P_prp_close_func_t close
)
H5Pregister
registers a new property with a
property list class.
The property will exist in all property list objects of
class
created after this routine finishes. The name
of the property must not already exist, or this routine will fail.
The default property value must be provided and all new property
lists created with this property will have the property value set
to the default value. Any of the callback routines may be set to
NULL if they are not needed.
Zero-sized properties are allowed and do not store any data in the
property list. These may be used as flags to indicate the presence
or absence of a particular piece of information. The default pointer
for a zero-sized property may be set to NULL.
The property create
and close
callbacks
are called for zero-sized properties, but the set
and
get
callbacks are never called.
create
routine is called when a new property list
with this property is being created.
The H5P_prp_create_func_t
callback function is defined
as follows:
H5P_prp_create_func_t
)(
const char *name
,
size_t size
,
void *initial_value
);
const char *name |
IN: The name of the property being modified |
size_t size |
IN: The size of the property in bytes |
void *initial_value |
IN/OUT: The default value for the property being created,
which will be passed to H5Pregister |
create
routine may modify the value to be set and
those changes will be stored as the initial value of the property.
If the create
routine returns a negative value,
the new property value is not copied into the property and the
create routine returns an error value.
The set
routine is called before a new value is copied
into the property.
The H5P_prp_set_func_t
callback function is defined
as follows:
prop_id
,
const char *name
,
size_t size
,
void *new_value
);
hid_t prop_id |
IN: The identifier of the property list being modified |
const char *name |
IN: The name of the property being modified |
size_t size |
IN: The size of the property in bytes |
void **new_value |
IN/OUT: Pointer to new value pointer for the property being modified |
set
routine may modify the value pointer to be set
and those changes will be used when setting the property's value.
If the set
routine returns a negative value, the new
property value is not copied into the property and the
set
routine returns an error value.
The set
routine will not be called for the initial
value, only the create
routine will be called.
The get
routine is called when a value is retrieved
from a property value.
The H5P_prp_get_func_t
callback function is defined
as follows:
H5P_prp_get_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *value
);
hid_t prop_id |
IN: The identifier of the property list being queried |
const char * name |
IN: The name of the property being queried |
size_t size |
IN: The size of the property in bytes |
void * value |
IN/OUT: The value of the property being returned |
get
routine may modify the value to be returned from
the query and those changes will be returned to the calling routine.
If the set
routine returns a negative value, the query
routine returns an error value.
The delete
routine is called when a property is being
deleted from a property list.
The H5P_prp_delete_func_t
callback function is defined
as follows:
H5P_prp_delete_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *value
);
hid_t prop_id |
IN: The identifier of the property list the property is being deleted from |
const char * name |
IN: The name of the property in the list |
size_t size |
IN: The size of the property in bytes |
void * value |
IN: The value for the property being deleted |
delete
routine may modify the value passed in,
but the value is not used by the library when the delete
routine returns. If the delete
routine returns
a negative value, the property list delete routine returns
an error value but the property is still deleted.
The copy
routine is called when a new property list with
this property is being created through a copy operation.
The H5P_prp_copy_func_t
callback function is defined
as follows:
H5P_prp_copy_func_t
)(
const char *name
,
size_t size
,
void *value
);
const char *name |
IN: The name of the property being copied |
size_t size |
IN: The size of the property in bytes |
void *value |
IN/OUT: The value for the property being copied |
copy
routine may modify the value to be set and
those changes will be stored as the new value of the property.
If the copy
routine returns a negative value,
the new property value is not copied into the property and
the copy routine returns an error value.
The close
routine is called when a property list with
this property is being closed.
The H5P_prp_close_func_t
callback function is defined
as follows:
H5P_prp_close_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *value
);
hid_t prop_id |
IN: The identifier of the property list being closed |
const char *name |
IN: The name of the property in the list |
size_t size |
IN: The size of the property in bytes |
void *value |
IN: The value for the property being closed |
close
routine may modify the value passed in,
but the value is not used by the library when the
close
routine returns.
If the close
routine returns a negative value,
the property list close routine returns an error value but
the property list is still closed.
hid_t class |
IN: Property list class to register permanent property within |
const char * name |
IN: Name of property to register |
size_t size |
IN: Size of property in bytes |
void * default |
IN: Default value for property in newly created property lists |
H5P_prp_create_func_t create |
IN: Callback routine called when a property list is being created and the property value will be initialized |
H5P_prp_set_func_t set |
IN: Callback routine called before a new value is copied into the property's value |
H5P_prp_get_func_t get |
IN: Callback routine called when a property value is retrieved from the property |
H5P_prp_delete_func_t delete |
IN: Callback routine called when a property is deleted from a property list |
H5P_prp_copy_func_t copy |
IN: Callback routine called when a property is copied from a property list |
H5P_prp_close_func_t close |
IN: Callback routine called when a property list is being closed and the property value will be disposed of |
set
callback function may be useful to range check the value being
set for the property or may perform some tranformation/translation of the
value set. The get
callback would then [probably] reverse the
transformation, etc. A single get
or set
callback could
handle multiple properties by performing different actions based on the
property name or other properties in the property list.
I would like to say "the property list is not closed" when a close
routine fails, but I don't think that's possible due to other properties in
the list being successfully closed and removed from the property list. I
suppose that it would be possible to just remove the properties which have
successful close
callbacks, but I'm not happy with the ramifications
of a mangled, un-closable property list hanging around... Any comments?
H5Pinsert
(
hid_t plid
,
const char *name
,
size_t size
,
void *value
,
H5P_prp_set_func_t set
,
H5P_prp_get_func_t get
,
H5P_prp_delete_func_t delete
,
H5P_prp_copy_func_t copy
,
H5P_prp_close_func_t close
)
H5Pinsert
create a new property in a property list.
The property will exist only in this property list and copies made
from it.
The initial property value must be provided in
value
and the property value will be set accordingly.
The name of the property must not already exist in this list, or this routine will fail.
The set
and get
callback routines may
be set to NULL if they are not needed.
Zero-sized properties are allowed and do not store any data in the property list. The default value of a zero-size property may be set to NULL. They may be used to indicate the presence or absence of a particular piece of information.
Theset
routine is called before a new value is copied
into the property.
The H5P_prp_set_func_t
calback function is defined
as follows:
H5P_prp_set_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *new_value
);
hid_t prop_id |
IN: The identifier of the property list being modified |
const char *name |
IN: The name of the property being modified |
size_t size |
IN: The size of the property in bytes |
void **new_value |
IN: Pointer to new value pointer for the property being modified |
set
routine may modify the value pointer to be set
and those changes will be used when setting the property's value.
If the set
routine returns a negative value, the new
property value is not copied into the property and the set routine
returns an error value.
The set
routine will be called for the initial value.
The get
routine is called when a value is retrieved
from a property value.
The H5P_prp_get_func_t
callback functioin is defined
as follows:
H5P_prp_get_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *value
);
hid_t prop_id |
IN: The identifier of the property list being queried |
const char * |
IN: The name of the property being queried |
size_t size |
IN: The size of the property in bytes |
void *value |
IN: The value of the property being returned |
get
routine may modify the value to be returned from
the query and those changes will be preserved.
If the get
routine returns a negative value, the query
routine returns an error value.
The delete
routine is called when a property is being
deleted from a property list.
The H5P_prp_delete_func_t
callback function is defined
as follows:
typedef herr_t
(*H5P_prp_delete_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *value
);
hid_t prop_id |
IN: The identifier of the property list the property is being deleted from |
const char * name |
IN: The name of the property in the list |
size_t size |
IN: The size of the property in bytes |
void * value |
IN: The value for the property being deleted |
delete
routine may modify the value passed in,
but the value is not used by the library when the delete
routine returns. If the delete
routine returns a
negative value, the property list delete routine returns an
error value but the property is still deleted.
The copy
routine is called when a new property list
with this property is being created through a copy operation.
The H5P_prp_copy_func_t
collback function is defined
as follows:
H5P_prp_copy_func_t
)(
const char *name
,
size_t size
,
void *value
);
const char *name |
IN: The name of the property being copied |
size_t size |
IN: The size of the property in bytes |
void * value |
IN/OUT: The value for the property being copied |
copy
routine may modify the value to be set and
those changes will be stored as the new value of the property.
If the copy
routine returns a negative value, the
new property value is not copied into the property and the
copy routine returns an error value.
The close
routine is called when a property list
with this property is being closed.
The H5P_prp_close_func_t
callback function is defined
as follows:
H5P_prp_close_func_t
)(
hid_t prop_id
,
const char *name
,
size_t size
,
void *value
);
hid_t |
IN: The ID of the property list being closed |
const char * name |
IN: The name of the property in the list |
size_t size |
IN: The size of the property in bytes |
void * value |
IN: The value for the property being closed |
close
routine may modify the value passed in, the value
is not used by the library when the close
routine returns.
If the close
routine returns a negative value, the
property list close routine returns an error value but the property list
is still closed.
hid_t plid |
IN: Property list identifier to create temporary property within |
const char *name |
IN: Name of property to create |
size_t size |
IN: Size of property in bytes |
void *value |
IN: Initial value for the property |
H5P_prp_set_func_t set |
IN: Callback routine called before a new value is copied into the property's value |
H5P_prp_get_func_t get |
IN: Callback routine called when a property value is retrieved from the property |
H5P_prp_delete_func_t delete |
IN: Callback routine called when a property is deleted from a property list |
H5P_prp_copy_func_t copy |
IN: Callback routine called when a property is copied from an existing property list |
H5P_prp_close_func_t close |
IN: Callback routine called when a property list is being closed and the property value will be disposed of |
set
callback function may be useful to range check
the value being set for the property or may perform some
tranformation/translation of the value set. The get
callback
would then [probably] reverse the transformation, etc. A single
get
or set
callback could handle
multiple properties by performing different actions based on the
property name or other properties in the property list.
There is no create
callback routine for temporary property
list objects, the initial value is assumed to have any necessary setup
already performed on it.
I would like to say "the property list is not closed" when a close
routine fails, but I don't think that's possible due to other properties in
the list being successfully closed and removed from the property list. I
suppose that it would be possible to just remove the properties which have
successful close
callbacks, but I'm not happy with the
ramifications of a mangled, un-closable property list hanging around...
Any comments?
H5Pset
(
hid_t plid
,
const char *name
,
void *value
)
)
H5Pset
sets a new value for a property in a
property list. If there is a set
callback
routine registered for this property, the value
will be
passed to that routine and any changes to the value
will be used when setting the property value.
The information pointed to by the value
pointer
(possibly modified by the set
callback) is copied into
the property list value and may be changed by the application making
the H5Pset
call without affecting the property value.
The property name must exist or this routine will fail.
If the set
callback routine returns an error, the
property value will not be modified.
This routine may not be called for zero-sized properties and will return an error in that case.
hid_t plid ;
| IN: Property list identifier to modify |
const char *name ;
| IN: Name of property to modify |
void *value ;
| IN: Pointer to value to set the property to |
H5Pexist
(
hid_t id
;
const char *name
)
H5Pexist
determines whether a property exists
within a property list or class.
hid_t id |
IN: Identifier for the property to query |
const char *name |
IN: Name of property to check for |
H5Pget_size
(
hid_t id
,
const char *name
,
size_t *size
)
H5Pget_size
retrieves the size of a
property's value in bytes. This function operates on both
poperty lists and property classes
Zero-sized properties are allowed and return 0
.
hid_t id |
IN: Identifier of property object to query |
const char *name |
IN: Name of property to query |
size_t *size |
OUT: Size of property in bytes |
H5Pget_nprops
(
hid_t id
,
size_t *nprops
)
H5Pget_nprops
retrieves the number of properties in a
property list or class.
If a property class identifier is given, the number of registered
properties in the class is returned in nprops
.
If a property list identifier is given, the current number of
properties in the list is returned in nprops
.
hid_t id |
IN: Identifier of property object to query |
size_t *nprops |
OUT: Number of properties in object |
H5Pget_class_name
(
hid_t pcid
)
H5Pget_class_name
retrieves the name of a
generic property list class. The pointer to the name
must be freed by the user after each successful call.
hid_t pcid |
IN: Identifier of the property class to query |
H5Pget_class_parent
(
hid_t pcid
)
H5Pget_class_parent
retrieves an identifier for the
parent class of a property class.
hid_t pcid |
IN: Identifier of the property class to query |
H5Pisa_class
(
hid_t plist
,
hid_t pclass
)
H5Pisa_class
checks to determine whether a property list
is a member of the specified class.
hid_t plist |
IN: Identifier of the property list |
hid_t pclass |
IN: Identifier of the property class |
H5Pget
(
hid_t plid
,
const char *name
,
void *value
)
H5Pget
retrieves a copy of the value for a property
in a property list. If there is a get
callback routine
registered for this property, the copy of the value of the property
will first be passed to that routine and any changes to the copy of
the value will be used when returning the property value from this
routine.
This routine may be called for zero-sized properties with the
value
set to NULL. The get
routine
will be called with a NULL value if the callback exists.
The property name must exist or this routine will fail.
If the get
callback routine returns an error,
value
will not be modified.
hid_t plid |
IN: Identifier of the property list to query |
const char *name |
IN: Name of property to query |
void *value |
OUT: Pointer to a location to which to copy the value of of the property |
H5Pequal
(
hid_t id1,
hid_t id2
)
H5Pequal
compares two property lists or classes
to determine whether they are equal to one another.
Either both id1
and id2
must be
property lists or both must be classes; comparing a list to a
class is an error.
hid_t id1 |
IN: First property object to be compared |
hid_t id2 |
IN: Second property object to be compared |
H5Piterate
(
hid_t id
,
int * idx
,
H5P_iterate_t iter_func
,
void * iter_data
)
H5Piterate
iterates over the properties in the
property object specified in id
, which may be either a
property list or a property class, performing a specified
operation on each property in turn.
For each property in the object, iter_func
and
the additional information specified below are passed to the
H5P_iterate_t
operator function.
(NOTE: iter_func
was changed to
H5P_iterate_t
in the preceding sentence.
Is this correct?)
The iteration begins with the idx
-th property in
the object; the next element to be processed by the operator
is returned in idx
.
If idx
is NULL, the iterator starts at the first
property; since no stopping point is returned in this case,
the iterator cannot be restarted if one of the calls to its
operator returns non-zero.
H5P_iterate_t
operator is
as follows:
H5P_iterate_t
)(
hid_t id
,
const char *>name
,
void *iter_data
)
id
,
the name of the current property within the object, name
,
and the pointer to the operator data passed in to
H5Piterate
, iter_data
.
The valid return values from an operator are as follows:
Zero | Causes the iterator to continue, returning zero when all properties have been processed |
Positive | Causes the iterator to immediately return that positive value, indicating short-circuit success. The iterator can be restarted at the index of the next property |
Negative | Causes the iterator to immediately return that value, indicating failure. The iterator can be restarted at the index of the next property |
H5Piterate
assumes that the properties in the object
identified by id
remain unchanged through the iteration.
If the membership changes during the iteration, the function's behavior
is undefined.
hid_t id |
IN: Identifier of property object to iterate over |
int * idx |
IN/OUT: Index of the property to begin with |
H5P_iterate_t iter_func |
IN: Function pointer to function to be called with each property iterated over |
void * iter_data |
IN/OUT: Pointer to iteration data from user |
iter_func
if it was non-zero;
zero if all properties have been processed
H5Pcopy_prop
(
hid_t dst_id
,
hid_t src_id
,
const char *name
)
H5Pcopy_prop
copies a property from one property
list or class to another.
If a property is copied from one class to another, all the property information will be first deleted from the destination class and then the property information will be copied from the source class into the destination class.
If a property is copied from one list to another, the property
will be first deleted from the destination list (generating a call
to the close
callback for the property, if one exists)
and then the property is copied from the source list to the
destination list (generating a call to the copy
callback for the property, if one exists).
If the property does not exist in the class or list, this call is
equivalent to calling H5Pregister
or H5Pinsert
(for a class or list, as appropriate) and the create
callback will be called in the case of the property being
copied into a list (if such a callback exists for the property).
hid_t dst_id |
IN: Identifier of the destination property list or class |
hid_t src_id |
IN: Identifier of the source property list or class |
const char *name |
IN: Name of the property to copy |
H5Premove
(plid, name
)
hid_t plid
;
const char *name
)
H5Premove
removes a property from a property list.
Both properties which were in existence when the property list
was created (i.e. properties registered with H5Pregister
)
and properties added to the list after it was created (i.e. added
with H5Pinsert
) may be removed from a property list.
Properties do not need to be removed from a property list before the
list itself is closed; they will be released automatically when
H5Pclose
is called.
If a close
callback exists for the removed property,
it will be called before the property is released.
hid_t plid |
IN: Identifier of the property list to modify |
const char *name |
IN: Name of property to remove |
H5Punregister
(
H5P_class_t class
,
const char *name
)
H5Punregister
removes a property from a
property list class.
Future property lists created of that class will not contain this property; existing property lists containing this property are not affected.
H5P_class_t class |
IN: Property list class from which to remove permanent property |
const char *name |
IN: Name of property to remove |
H5Pclose_list
(
hid_t plist
)
H5Pclose_list
closes a property list.
If a close
callback exists for the property list class,
it is called before the property list is destroyed.
If close
callbacks exist for any individual properties
in the property list, they are called after the class
close
callback.
hid_t plist | IN: Property list to close |
H5Pclose_class
(
hid_t class
)
Existing property lists of this class will continue to exist, but new ones are not able to be created.
hid_t class |
IN: Property list class to close |
H5Pget_version
(hid_t plist
,
int * super
,
int * freelist
,
int * stab
,
int * shhdr
)
H5Pget_version
retrieves the version information of various objects
for a file creation property list. Any pointer parameters which are
passed as NULL are not queried.
plist
super
freelist
stab
shhdr
H5Pset_userblock
(hid_t plist
,
hsize_t size
)
H5Pset_userblock
sets the user block size of a
file creation property list.
The default user block size is 0; it may be set to any
power of 2 equal to 512 or greater (512, 1024, 2048, etc.).
plist
size
H5Pget_userblock
(hid_t plist
,
hsize_t * size
)
H5Pget_userblock
retrieves the size of a user block
in a file creation property list.
plist
size
H5Pset_sizes
(hid_t plist
,
size_t sizeof_addr
,
size_t sizeof_size
)
H5Pset_sizes
sets the byte size of the offsets and lengths used to
address objects in an HDF5 file. This function is only valid for
file creation property lists. Passing in a value of 0 for one of the
sizeof parameters retains the current value. The default value
for both values is 4 bytes. Valid values currently are 2, 4, 8 and
16.
plist
sizeof_addr
sizeof_size
H5Pget_sizes
(hid_t plist
,
size_t * sizeof_addr
,
size_t * sizeof_size
)
H5Pget_sizes
retrieves the size of the offsets
and lengths used in an HDF5 file.
This function is only valid for file creation property lists.
plist
size
size
H5Pset_sym_k
(hid_t plist
,
int ik
,
int lk
)
H5Pset_sym_k
sets the size of parameters used to
control the symbol table nodes. This function is only valid
for file creation property lists. Passing in a value of 0 for
one of the parameters retains the current value.
ik
is one half the rank of a tree that stores a symbol
table for a group. Internal nodes of the symbol table are on
average 75% full. That is, the average rank of the tree is
1.5 times the value of ik
.
lk
is one half of the number of symbols that can
be stored in a symbol table node. A symbol table node is the
leaf of a symbol table tree which is used to store a group.
When symbols are inserted randomly into a group, the group's
symbol table nodes are 75% full on average. That is, they
contain 1.5 times the number of symbols specified by
lk
.
plist
ik
lk
H5Pget_sym_k
(hid_t plist
,
int * ik
,
int * lk
)
H5Pget_sym_k
retrieves the size of the
symbol table B-tree 1/2 rank and the symbol table leaf
node 1/2 size. This function is only valid for file creation
property lists. If a parameter valued is set to NULL, that
parameter is not retrieved. See the description for
H5Pset_sym_k for more
information.
plist
ik
size
H5Pset_istore_k
(hid_t plist
,
int ik
)
H5Pset_istore_k
sets the size of the parameter
used to control the B-trees for indexing chunked datasets.
This function is only valid for file creation property lists.
Passing in a value of 0 for one of the parameters retains
the current value.
ik
is one half the rank of a tree that stores
chunked raw data. On average, such a tree will be 75% full,
or have an average rank of 1.5 times the value of
ik
.
plist
ik
H5Pget_istore_k
(hid_t plist
,
int * ik
)
H5Pget_istore_k
queries the 1/2 rank of
an indexed storage B-tree.
The argument ik
may be the null pointer (NULL).
This function is only valid for file creation property lists.
See H5Pset_istore_k for details.
plist
ik
H5Pset_layout
(hid_t plist
,
H5D_layout_t layout
)
H5Pset_layout
sets the type of storage used to store the
raw data for a dataset.
This function is only valid for dataset creation property lists.
Valid values for layout
are:
plist
layout
H5Pget_layout
(hid_t plist
)
H5Pget_layout
returns the layout of the raw data for
a dataset. This function is only valid for dataset creation
property lists.
plist
Otherwise, returns a negative value indicating faliure.
H5Pset_chunk
(hid_t plist
,
int ndims
,
const hsize_t * dim
)
H5Pset_chunk
sets the size of the chunks used to
store a chunked layout dataset. This function is only valid
for dataset creation property lists.
The ndims
parameter currently must be the same size
as the rank of the dataset. The values of the dim
array define the size of the chunks to store the dataset's raw data.
As a side-effect, the layout of the dataset is changed to
H5D_CHUNKED
, if it is not already.
plist
ndims
dim
H5Pget_chunk
(hid_t plist
,
int max_ndims
,
hsize_t * dims
)
H5Pget_chunk
retrieves the size of chunks for the
raw data of a chunked layout dataset.
This function is only valid for dataset creation property lists.
At most, max_ndims
elements of dims
will be initialized.
plist
max_ndims
dims
array.
dims
H5Pset_alignment
(hid_t plist
,
hsize_t threshold
,
hsize_t alignment
)
H5Pset_alignment
sets the alignment properties
of a file access property list
so that any file object greater than or equal in size to
threshold
bytes will be aligned on an address
which is a multiple of alignment
. The addresses
are relative to the end of the user block; the alignment is
calculated by subtracting the user block size from the
absolute file address and then adjusting the address to be a
multiple of alignment
.
Default values for threshold
and
alignment
are one, implying
no alignment. Generally the default values will result in
the best performance for single-process access to the file.
For MPI-IO and other parallel systems, choose an alignment
which is a multiple of the disk block size.
plist
threshold
alignment
H5Pget_alignment
(hid_t plist
,
hsize_t *threshold
,
hsize_t *alignment
)
H5Pget_alignment
retrieves the current settings for
alignment properties from a file access property list.
The threshold
and/or alignment
pointers
may be null pointers (NULL).
plist
*threshold
*alignment
H5Pset_external
(hid_t plist
,
const char *name
,
off_t offset
,
hsize_t size
)
H5Pset_external
adds an external file to the
list of external files.
If a dataset is split across multiple files then the files
should be defined in order. The total size of the dataset is
the sum of the size
arguments for all the external files. If
the total size is larger than the size of a dataset then the
dataset can be extended (provided the data space also allows
the extending).
The size
argument specifies number of bytes reserved
for data in the external file.
If size
is set to H5F_UNLIMITED
, the
external file can be of unlimited size and no more files can be added to
the external files list.
plist
*name
offset
size
H5Pget_external_count
(hid_t plist
)
H5Pget_external_count
returns the number of external files
for the specified dataset.
plist
H5Pget_external
(hid_t plist
,
int idx
,
size_t name_size
,
char *name
,
off_t *offset
,
hsize_t *size
)
H5Pget_external
returns information about an external
file. The external file is specified by its index, idx
,
which is a number from zero to N-1, where N is the value
returned by H5Pget_external_count
.
At most name_size
characters are copied into the
name
array. If the external file name is
longer than name_size
with the null terminator, the
return value is not null terminated (similar to strncpy()
).
If name_size
is zero or name
is the
null pointer, the external file name is not returned.
If offset
or size
are null pointers
then the corresponding information is not returned.
plist
idx
name_size
name
array.
*name
*offset
*size
H5Pset_fill_value
(hid_t plist_id
,
hid_t type_id
,
const void *value
)
H5Pset_fill_value
sets the fill value for
a dataset in the dataset creation property list.
value
is interpreted as being of datatype
type_id
. This datatype may differ from that of
the dataset, but the HDF5 library must be able to convert
value
to the dataset datatype when the dataset
is created.
The default fill value is 0
(zero), which is
interpreted according to the actual dataset datatype.
Setting value
to NULL
indicates
that the fill value is to be undefined.
A fill value should be defined so that it is appropriate for
the application. While the HDF5 default fill value is
0
(zero), it is often appropriate to use another value.
It might be useful, for example, to use a value that is
known to be impossible for the application to legitimately generate.
H5Pset_fill_value
is designed to work in
concert with H5Pset_alloc_time
and
H5Pset_fill_time
.
H5Pset_alloc_time
and H5Pset_fill_time
govern the timing of dataset storage allocation and fill value
write operations and can be important in tuning application
performance.
plist_id
type_id
,
value
.
value
H5Pget_fill_value
(hid_t plist_id
,
hid_t type_id
,
void *value
)
H5Pget_fill_value
returns the dataset
fill value defined in the dataset creation property list
plist_id
.
The fill value is returned through the value
pointer and will be converted to the datatype specified
by type_id
.
This datatype may differ from the
fill value datatype in the property list,
but the HDF5 library must be able to convert between the
two datatypes.
If the fill value is undefined,
i.e., set to NULL
in the property list,
H5Pget_fill_value
will return an error.
H5Pfill_value_defined
should be used to
check for this condition before
H5Pget_fill_value
is called.
Memory must be allocated by the calling application.
H5Pget_fill_value
is designed to coordinate
with the dataset storage allocation time and
fill value write time properties, which can be retrieved
with the functions H5Pget_alloc_time
and H5Pget_fill_time
, respectively.
plist_id
type_id
,
value
.
value
H5Pfill_value_defined
(hid_t plist_id
,
H5D_fill_value_t *status
)
H5Pfill_value_defined
determines whether a fill value
is defined in the dataset creation property list plist_id
.
Valid values returnrd in status
are as follows:
H5D_FILL_VALUE_UNDEFINED
| Fill value is undefined. | |
H5D_FILL_VALUE_DEFAULT
| Fill value is the library default. | |
H5D_FILL_VALUE_USER_DEFINED
| Fill value is defined by the application. |
H5Pfill_value_defined
is designed for use in
concert with the dataset fill value properties functions
H5Pget_fill_value
and H5Pget_fill_time
.
plist_id
status
H5Pset_fill_time
(hid_t plist_id
,
H5D_fill_time_t fill_time
)
H5Pset_fill_time
sets up the timing for writing fill values
to a dataset.
This property is set in the dataset creation property list plist_id
.
Timing is specified in fill_time
with one of the following values:
H5D_FILL_TIME_ALLOC
| Write fill values to the dataset when storage space is allocated. (Default) | |
H5D_FILL_TIME_NEVER
| Never write fill values to the dataset. |
H5Pset_fill_time
is designed for coordination
with the dataset fill value and
dataset storage allocation time properties, set with the functions
H5Pset_fill_value
and H5Pset_alloc_time
.
plist_id
fill_time
H5Pget_fill_time
(hid_t plist_id
,
H5D_fill_time_t *fill_time
)
H5Pget_fill_time
examines the dataset creation
property list plist_id
to determine when fill values
are to be written to a dataset.
Valid values returned in fill_time
are as follows:
H5D_FILL_TIME_ALLOC
| Fill values are written to the dataset when storage space is allocated. (Default) | |
H5D_FILL_TIME_NEVER
| Fill values are never written to the dataset. |
H5Pget_fill_time
is designed to work in coordination
with the dataset fill value and
dataset storage allocation time properties, retrieved with the functions
H5Pget_fill_value
and H5Pget_alloc_time
.
plist_id
fill_time
H5Pset_alloc_time
(hid_t plist_id
,
H5D_alloc_time_t alloc_time
)
H5Pset_alloc_time
sets up the timing for the allocation of
storage space for a dataset's raw data.
This property is set in the dataset creation property list
plist_id
.
Timing is specified in fill_time
with one of the
following values:
H5D_ALLOC_TIME_DEFAULT
|
Allocate dataset storage space at the default time. (Defaults differ by storage method.) | |
H5D_ALLOC_TIME_EARLY
|
Allocate all space when the dataset is created. (Default for compact datasets.) | |
H5D_ALLOC_TIME_INCR
|
Allocate space incrementally, as data is written to the dataset. (Default for chunked storage datasets.) H5Pset_alloc_time will return an error.
| |
H5D_ALLOC_TIME_LATE
|
Allocate all space when data is first written to the dataset. (Default for contiguous datasets.) |
H5Pset_alloc_time
is designed to work in concert
with the dataset fill value and fill value write time properties,
set with the functions
H5Pset_fill_value
and H5Pset_fill_time
.
plist_id
alloc_time
H5Pget_alloc_time
(hid_t plist_id
,
H5D_alloc_time_t *alloc_time
)
H5Pget_alloc_time
retrieves the timing for allocating
storage space for a dataset's raw data.
This property is set in the dataset creation property list
plist_id
.
The timing setting is returned in fill_time
as one of the
following values:
H5D_ALLOC_TIME_DEFAULT
|
Uses the default allocation time, based on the dataset storage method. See the fill_time description in
H5Pset_alloc_time for
default allocation times for various storage methods.
| |
H5D_ALLOC_TIME_EARLY
| All space is allocated when the dataset is created. | |
H5D_ALLOC_TIME_INCR
| Space is allocated incrementally as data is written to the dataset. | |
H5D_ALLOC_TIME_LATE
| All space is allocated when data is first written to the dataset. |
H5Pget_alloc_time
is designed to work in concert
with the dataset fill value and fill value write time properties,
set with the functions
H5Pget_fill_value
and H5Pget_fill_time
.
plist_id
alloc_time
H5Pset_filter
(hid_t plist
,
H5Z_filter_t filter
,
unsigned int flags
,
size_t cd_nelmts
,
const unsigned int cd_values[]
)
H5Pset_filter
adds the specified
filter
and corresponding properties to the
end of an output filter pipeline.
If plist
is a dataset creation property list,
the filter is added to the permanent filter pipeline;
if plist
is a dataset transfer property list,
the filter is added to the transient filter pipeline.
The array cd_values
contains
cd_nelmts
integers which are auxiliary data
for the filter. The integer values will be stored in the
dataset object header as part of the filter information.
The flags
argument is a bit vector with
the following fields specifying certain general properties
of the filter:
H5Z_FLAG_OPTIONAL |
If this bit is set then the filter is
optional. If the filter fails (see below) during an
H5Dwrite operation then the filter is
just excluded from the pipeline for the chunk for which
it failed; the filter will not participate in the
pipeline during an H5Dread of the chunk.
This is commonly used for compression filters: if the
filter result would be larger than the input, then
the compression filter returns failure and the
uncompressed data is stored in the file. If this bit is
clear and a filter fails, then H5Dwrite
or H5Dread also fails.
This flag is mandatory for the Fletcher32 checksum filter. |
The filter
parameter specifies the filter to be set.
Valid values are as follows:
H5Z_FILTER_DEFLATE
| Data compression filter, employing the gzip algorithm |
H5Z_FILTER_SHUFFLE
| Data shuffling filter |
H5Z_FILTER_FLETCHER32
| Error detection filter, employing the Fletcher32 checksum algorithm |
plist
must be a dataset creation
property list.
plist
filter
flags
cd_nelmts
cd_values
.
cd_values[]
H5Pget_nfilters
(hid_t plist
)
H5Pget_nfilters
returns the number of filters
defined in the filter pipeline associated with the property list
plist
.
In each pipeline, the filters are numbered from 0 through N-1, where N is the value returned by this function. During output to the file, the filters are applied in increasing order; during input from the file, they are applied in decreasing order.
H5Pget_nfilters
returns the number of filters
in the pipeline, including zero (0
) if there
are none.
plist_id
must be a dataset creation
property list.
plist
H5Pget_filter
(hid_t plist
,
int filter_number
,
unsigned int *flags
,
size_t *cd_nelmts
,
unsigned int *cd_values
,
size_t namelen
,
char name[]
)
H5Pget_filter
returns information about a
filter, specified by its filter number, in a filter pipeline,
specified by the property list with which it is associated.
If plist
is a dataset creation property list,
the pipeline is a permanent filter pipeline;
if plist
is a dataset transfer property list,
the pipeline is a transient filter pipeline.
On input, cd_nelmts
indicates the number of entries
in the cd_values
array, as allocated by the caller;
on return,cd_nelmts
contains the number of values
defined by the filter.
filter_number
is a value between zero and
N-1, as described in
H5Pget_nfilters
.
The function will return a negative value if the filter number
is out of range.
If name
is a pointer to an array of at least
namelen
bytes, the filter name will be copied
into that array. The name will be null terminated if
namelen
is large enough. The filter name returned
will be the name appearing in the file, the name registered
for the filter, or an empty string.
The structure of the flags
argument is discussed
in H5Pset_filter
.
plist
must be a dataset creation property
list.
plist
filter_number
flags
cd_nelmts
cd_values
.
cd_values
namelen
name
.
name[]
H5Z_FILTER_DEFLATE
| Data compression filter, employing the gzip algorithm |
H5Z_FILTER_SHUFFLE
| Data shuffling filter |
H5Z_FILTER_FLETCHER32
| Error detection filter, employing the Fletcher32 checksum algorithm |
H5Pset_shuffle
(hid_t plist
,
unsigned int bytes_in_type
)
H5Pset_shuffle
sets the shuffle filter,
H5Z_FILTER_SHUFFLE
,
in the dataset creation property list plist
.
The parameter bytes_in_type
indicates the size
in bytes of the dataset's datatype.
If the datatype is a struct, bytes_in_type
specifies the size in bytes of the entire struct.
The shuffle filter de-interlaces
a block of data by reordering the bytes.
All the bytes from one consistent byte position of
each data element are placed together in one block;
all bytes from a second consistent byte position of
each data element are placed together in one block; etc.
For example, given three data elements of a 4-byte datatype
stored as 012301230123
,
shuffling will re-order data as 000111222333
.
This can be a valuable step in an effective compression
algorithm because the bytes in each byte position are often
closely related to each other and putting them together
can increase the compression ratio.
plist
bytes_in_type
H5Pset_fletcher32
(hid_t plist
)
H5Pset_fletcher32
sets the Fletcher32 checksum filter
in the dataset creation property list plist
.
plist
H5Pset_szip
(hid_t plist
,
unsigned int options_mask
,
unsigned int pixels_per_block
)
H5Pset_szip
sets the dataset compression method
to szip compression, H5Z_FILTER_SZIP
,
a compression designed for use with scientific data.
Szip options are passed in an options mask, options_mask
,
as follows.
Option |
Description (Paired options are mutually exclusive.) |
CHIP_OPTION_MASK
|
Compresses exactly as in hardware. |
ALLOW_K13_OPTION_MASK
| Allows k split = 13 compression mode. (Default) |
EC_OPTION_MASK
|
Selects entropy coding method. (Default) |
NN_OPTION_MASK
| Selects nearest neighbor coding method. |
LSB_OPTION_MASK
|
Data format is least significant byte first. (Default) |
MSB_OPTION_MASK
| Data format is most significant byte first. |
RAW_OPTION_MASK
|
Do not output szip header. Not a default setting, but should always be set in HDF5. |
|
|
LSB_OPTION_MASK
or
MSB_OPTION_MASK
is specified.
EC_OPTION_MASK
or
NN_OPTION_MASK
, is specified.
RAW_OPTION_MASK
and
ALLOW_K13_OPTION_MASK
are used.
Options are combined to create the options mask by means of
a logical OR
operation. For example, the
option mask can be set as follows:
options_mask = MSB_OPTION_MASK | NN_OPTION_MASK | RAW_OPTION_MASK;
Szip compresses data block by block, with a user-tunable block size.
This block size is passed in the parameter
pixels_per_block
and must be even,
with typical values being 8
, 10
,
16
, and 32
.
The more pixel values vary, the smaller this number should be.
For optimal performance, the number of pixels per scan line
(i.e., the size of the fastest-changing dimension in the dataspace)
should be an even multiple of the number of pixels per block.
Szip typically requires that the user application also supply the number of pixels in the object to be compressed, the number of bits per pixel, and the number of pixels per scan line. These values need not be independently supplied in the HDF5 environment as they are derived from the datatype and dataspace, which are already known.
plist
options_mask
pixels_per_block
H5Pset_edc_check
(hid_t plist
,
H5Z_EDC_t check
)
H5Pset_edc_check
sets the dataset transfer property
list plist
to enable or disable error detection
when reading data.
Whether error detection is enabled or disabled is specified
in the check
parameter.
Valid values are as follows:
H5Z_ENABLE_EDC
H5Z_DISABLE_EDC (default)
|
The error detection algorithm used is the algorithm previously specified in the corresponding dataset creation property list.
This function does not affect the use of error detection when writing data.
plist
check
H5Pget_edc_check
(hid_t plist
)
H5Pget_edc_check
queries the dataset transfer property
list plist
to determine whether error detection
is enabled for data read operations.
plist
H5P_ENABLE_EDC
or H5P_DISABLE_EDC
if successful;
otherwise returns a negative value.
H5Pset_filter_callback
(hid_t plist
,
H5Z_filter_func_t func
,
void *op_data
)
H5Pset_filter_callback
sets the user-defined
filter callback function func
in the
dataset transfer property list plist
.
The parameter op_data
is a pointer to user-defined
input data for the callback function and will be passed through
to the callback function.
The callback function func
defines the actions
an application is to take when a filter fails.
The function prototype is as follows:
typedef
H5Z_cb_return_t (H5Z_filter_func_t
)
(H5Z_filter_t filter
,
void *buf
,
size_t buf_size
,
void *op_data
)
where filter
indicates which filter has failed,
buf
and buf_size
are used to pass in
the failed data,
and op_data
is the required input data for this
callback function.
Valid callback function return values are
H5Z_CB_FAIL
and H5Z_CB_CONT
.
plist
func
op_data
H5Pset_meta_block_size
(
hid_t fapl_id
,
hsize_t size
)
H5Pset_meta_block_size
sets the
minimum size, in bytes, of metadata block allocations when
H5FD_FEAT_AGGREGATE_METADATA
is set by a VFL driver.
Each raw metadata block is initially allocated to be of the given size. Specific metadata objects (e.g., object headers, local heaps, B-trees) are then sub-allocated from this block.
The default setting is 2048 bytes, meaning that the library
will attempt to aggregate metadata in at least 2K blocks in the file.
Setting the value to 0
(zero) with this function
will turn off metadata aggregation, even if the VFL driver attempts
to use the metadata aggregation strategy.
Metadata aggregation reduces the number of small data objects in the file that would otherwise be required for metadata. The aggregated block of metadata is usually written in a single write action and always in a contiguous block, potentially significantly improving library and application performance.
fapl_id
size
H5Pget_meta_block_size
(
hid_t fapl_id
,
hsize_t *size
)
H5Pget_meta_block_size
returns the current
minimum size, in bytes, of new metadata block allocations.
This setting is retrieved from the file access property list
fapl_id
.
This value is set by
H5Pset_meta_block_size
and is retrieved from the file access property list
fapl_id
.
fapl_id
size
H5Pset_sieve_buf_size
(
hid_t fapl_id
,
hsize_t size
)
H5Pset_sieve_buf_size
sets size
,
the maximum size in bytes of the data sieve buffer, which is
used by file drivers that are capable of using data sieving.
The data sieve buffer is used when performing I/O on datasets in the file. Using a buffer which is large enough to hold several pieces of the dataset being read in for hyperslab selections boosts performance by quite a bit.
The default value is set to 64KB, indicating that file I/O for raw data reads and writes will occur in at least 64KB blocks. Setting the value to 0 with this API function will turn off the data sieving, even if the VFL driver attempts to use that strategy.
fapl_id
size
H5Pget_sieve_buf_size
(
hid_t fapl_id
,
hsize_t *size
)
H5Pget_sieve_buf_size
retrieves, size
,
the current maximum size of the data sieve buffer.
This value is set by
H5Pset_sieve_buf_size
and is retrieved from the file access property list
fapl_id
.
fapl_id
size
H5Pset_gc_reference
(hid_t plist
,
unsigned gc_ref
)
H5Pset_gc_references
sets the flag for
garbage collecting references for the file.
Dataset region references and other reference types use space in an HDF5 file's global heap. If garbage collection is on and the user passes in an uninitialized value in a reference structure, the heap might get corrupted. When garbage collection is off, however, and the user re-uses a reference, the previous heap block will be orphaned and not returned to the free heap space.
When garbage collection is on, the user must initialize the reference structures to 0 or risk heap corruption.
The default value for garbage collecting references is off.
plist
gc_ref
1
) or off (0
).
H5Pget_gc_references
(hid_t plist
,
unsigned *gc_ref
)
H5Pget_gc_references
returns the current setting
for the garbage collection references property from
the specified file access property list.
The garbage collection references property is set
by H5Pset_gc_references.
plist
gc_ref
1
indicates that
garbage collection is on while
0
indicates that garbage collection is off.
H5Pset_cache
(hid_t plist_id
,
int mdc_nelmts
,
int rdcc_nelmts
,
size_t rdcc_nbytes
,
double rdcc_w0
)
H5Pset_cache
sets
the number of elements (objects) in the meta data cache and
the number of elements, the total number of bytes, and
the preemption policy value in the raw data chunk cache.
The plist_id is a file access property list. The number of elements (objects) in the meta data cache and the raw data chunk cache are mdc_nelmts and rdcc_nelmts, respectively. The total size of the raw data chunk cache and the preemption policy are rdcc_nbytes and rdcc_w0.
Any (or all) of the H5Pget_cache
pointer arguments
may be null pointers.
The rdcc_w0 value should be between 0 and 1 inclusive and indicates how much chunks that have been fully read are favored for preemption. A value of zero means fully read chunks are treated no differently than other chunks (the preemption is strictly LRU) while a value of one means fully read chunks are always preempted before other chunks.
plist_id
mdc_nelmts
rdcc_nelmts
rdcc_nbytes
rdcc_w0
H5Pget_cache
(hid_t plist_id
,
int *mdc_nelmts
,
int *rdcc_nelmts
,
size_t *rdcc_nbytes
,
double *rdcc_w0
)
H5Pget_cache
retrieves the maximum possible
number of elements in the meta
data cache and raw data chunk cache, the maximum possible number of
bytes in the raw data chunk cache, and the preemption policy value.
Any (or all) arguments may be null pointers, in which case the corresponding datum is not returned.
plist_id
*mdc_nelmts
*rdcc_nelmts
*rdcc_nbytes
*rdcc_w0
H5Pset_hyper_cache
(hid_t plist
,
unsigned cache
,
unsigned limit
)
H5Pset_hyper_cache
indicates whether to cache hyperslab blocks during I/O,
a process which can significantly increase I/O speeds.
When working with hyperslab selections, it is possible to
significantly speed up I/O operations by retrieving an
entire hyperslab from the file in one operation and
caching it in memory.
The cache
parameter specifies whether to turn
caching on for hyperslab I/O operations.
If cache
is set to 1
,
caching is turned on;
if set to 0
, caching is turned off.
The parameter limit
sets the maximum size of the
hyperslab block to cache. If a block is smaller than that limit,
it may still not be cached if no memory is available.
Setting limit
to 0
(zero) indicates
no limitation on the size of block to attempt to cache.
The default is to cache blocks with no limit on block size for serial I/O and to not cache blocks for parallel I/O.
plist
cache
1
) or off (0
).
limit
0
(zero) indicates no limit.
H5Pget_hyper_cache
(hid_t plist
,
unsigned *cache
,
unsigned *limit
)
H5Pget_hyper_cache
returns instructions regarding the caching of hyperslab blocks during I/O.
These parameters are set with the H5Pset_hyper_cache
function.
plist
cache
1
) or off (0
).
limit
0
(zero) indicates no limit.
H5Pset_btree_ratios
(hid_t plist
,
double left
,
double middle
,
double right
)
H5Pset_btree_ratios
sets the B-tree split ratios
for a dataset transfer property list. The split ratios determine
what percent of children go in the first node when a node splits.
The ratio left
is used when the splitting node is
the left-most node at its level in the tree;
the ratio right
is used when the splitting node is
the right-most node at its level;
and the ratio middle
is used for all other cases.
A node which is the only node at its level in the tree uses
the ratio right
when it splits.
All ratios are real numbers between 0 and 1, inclusive.
plist
left
right
middle
H5Pget_btree_ratios
(hid_t plist
,
double *left
,
double *middle
,
double *right
)
H5Pget_btree_ratios
returns the B-tree split ratios
for a dataset transfer property list.
The B-tree split ratios are returned through the non-NULL
arguments left
, middle
, and right
,
as set by the H5Pset_btree_ratios function.
plist
left
right
middle
H5Pset_buffer
(hid_t plist
,
hsize_t size
,
void *tconv
,
void *bkg
)
H5Pset_buffer
sets the maximum size
for the type conversion buffer and background buffer and
optionally supplies pointers to application-allocated buffers.
If the buffer size is smaller than the entire amount of data
being transferred between the application and the file, and a type
conversion buffer or background buffer is required, then
strip mining will be used.
Note that there are minimum size requirements for the buffer. Strip mining can only break the data up along the first dimension, so the buffer must be large enough to accommodate a complete slice that encompasses all of the remaining dimensions. For example, when strip mining a 100x200x300 hyperslab of a simple data space, the buffer must be large enough to hold 1x200x300 data elements. When strip mining a 100x200x300x150 hyperslab of a simple data space, the buffer must be large enough to hold 1x200x300x150 data elements.
If tconv
and/or bkg
are null pointers,
then buffers will be allocated and freed during the data transfer.
The default value for the maximum buffer is 1 Mb.
plist
size
tconv
bkg
H5Pget_buffer
(hid_t plist
,
void **tconv
,
void **bkg
)
H5Pget_buffer
reads values previously set
with H5Pset_buffer.
plist
**tconv
**bkg
H5Pset_small_data_block_size
(hid_t fapl_id
,
hsize_t size
)
H5Pset_small_data_block_size
reserves blocks of
size
bytes for the contiguous storage of the raw data
portion of small datasets.
The HDF5 library then writes the raw data from small datasets
to this reserved space, thus reducing unnecessary discontinuities
within blocks of meta data and improving IO performance.
A small data block is actually allocated the first time a qualifying small dataset is written to the file. Space for the raw data portion of this small dataset is suballocated within the small data block. The raw data from each subsequent small dataset is also written to the small data block until it is filled; additional small data blocks are allocated as required.
The HDF5 library employs an algorithm that determines whether
IO performance is likely to benefit from the use of this mechanism
with each dataset as storage space is allocated in the file.
A larger size
will result in this mechanism being
employed with larger datasets.
The small data block size is set as an allocation property in the
file access property list identified by fapl_id
.
Setting size
to zero (0
) disables the
small data block mechanism.
fapl_id
size
2048
.
H5Pget_small_data_block_size
(hid_t fapl_id
,
hsize_t *size
)
H5Pget_small_data_block_size
retrieves the
current setting for the size of the small data block.
If the returned value is zero (0
), the small data
block mechanism has been disabled for the file.
fapl_id
size
H5Pset_preserve
(hid_t plist
,
hbool_t status
)
H5Pset_preserve
sets the
dataset transfer property list status to TRUE or FALSE.
When reading or writing compound data types and the destination is partially initialized and the read/write is intended to initialize the other members, one must set this property to TRUE. Otherwise the I/O pipeline treats the destination datapoints as completely uninitialized.
plist
status
H5Pget_preserve
(hid_t plist
)
H5Pget_preserve
checks the status of the
dataset transfer property list.
plist
H5Pset_deflate
(hid_t plist
,
int level
)
H5Pset_deflate
sets the compression method for a
dataset creation property list to H5D_COMPRESS_DEFLATE
and the compression level to level
, which should
be a value from zero to nine, inclusive.
Lower compression levels are faster but result in less compression.
This is the same algorithm as used by the GNU gzip program.
plist
level
H5Pset_vlen_mem_manager
(hid_t plist
,
H5MM_allocate_t alloc
,
void *alloc_info
,
H5MM_free_t free
,
void *free_info
)
H5Dread
and H5Dvlen_reclaim
.
H5Pset_vlen_mem_manager
sets the memory manager for
variable-length datatype allocation in H5Dread
and free in H5Dvlen_reclaim
.
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 these user-defined functions would appear as follows:
typedef void *(*H5MM_allocate_t
)(size_t size
,
void *alloc_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.
plist
alloc
NULL
for system malloc
.
alloc_info
NULL
.
free
NULL
for system free
.
free_info
NULL
.
H5Pget_vlen_mem_manager
(hid_t plist
,
H5MM_allocate_t *alloc
,
void **alloc_info
,
H5MM_free_t *free
,
void **free_info
)
H5Dread
and H5Dvlen_reclaim
.
H5Pget_vlen_mem_manager
is the companion function to
H5Pset_vlen_mem_manager
, returning the parameters
set by that function.
plist
alloc
NULL
for system malloc
.
alloc_info
NULL
.
free
NULL
for
system free
.
free_info
NULL
.
H5Pset_fapl_family
(
hid_t fapl_id
,
hsize_t memb_size
,
hid_t memb_fapl_id
)
H5Pset_fapl_family
sets the file access property list
identifier, fapl_id
, to use the family driver.
memb_size
is the size in bytes of each file member
and is used only when creating a new file.
memb_fapl_id
is the identifier of the
file access property list to be used for each family member.
fapl_id
memb_size
memb_fapl_id
H5Pget_fapl_family
(
hid_t fapl_id
,
hsize_t *memb_size
,
hid_t *memb_fapl_id
)
H5Pget_fapl_family
returns file access property list
for use with the family driver.
This information is returned through the output parameters.
fapl_id
memb_size
memb_fapl_id
H5Pset_fapl_log
(
hid_t fapl_id
,
const char *logfile
,
unsigned int flags
,
size_t buf_size
)
H5Pset_fapl_log
modifies the
file access property list to use the logging driver
H5FD_LOG
.
logfile
is the name of the file in which the
logging entries are to be recorded.
The actions to be logged are specified in the parameter flags
using the pre-defined constants described in the following table.
Multiple flags can be set through the use of an logical OR contained
in parentheses. For example, logging read and write locations would
be specified as (H5FD_LOG_LOC_READ|H5FD_LOG_LOC_WRITE)
.
Flag |
Description |
H5FD_LOG_LOC_READ
|
Track the location and length of every read, write, or seek operation. |
H5FD_LOG_LOC_WRITE
| |
H5FD_LOG_LOC_SEEK
| |
H5FD_LOG_LOC_IO
| Track all I/O locations and lengths. The logical equivalent of the following: |
|
(H5FD_LOG_LOC_READ | H5FD_LOG_LOC_WRITE | H5FD_LOG_LOC_SEEK)
|
H5FD_LOG_FILE_READ
|
Track the number of times each byte is read or written. |
H5FD_LOG_FILE_WRITE
| |
H5FD_LOG_FILE_IO
| Track the number of times each byte is read and written. The logical equivalent of the following: |
|
(H5FD_LOG_FILE_READ | H5FD_LOG_FILE_WRITE)
|
H5FD_LOG_FLAVOR
|
Track the type, or flavor, of information stored at each byte. |
H5FD_LOG_NUM_READ
|
Track the total number of read, write, or seek operations that occur. |
H5FD_LOG_NUM_WRITE
| |
H5FD_LOG_NUM_SEEK
| |
H5FD_LOG_NUM_IO
| Track the total number of all types of I/O operations. The logical equivalent of the following: |
|
(H5FD_LOG_NUM_READ | H5FD_LOG_NUM_WRITE | H5FD_LOG_NUM_SEEK)
|
H5FD_LOG_TIME_OPEN
|
Track the time spent in open, read, write, seek, or close operations. Partially implemented: write and seek Fully implemented: close |
H5FD_LOG_TIME_READ
| |
H5FD_LOG_TIME_WRITE
| |
H5FD_LOG_TIME_SEEK
| |
H5FD_LOG_TIME_CLOSE
| |
H5FD_LOG_TIME_IO
| Track the time spent in each of the above operations. The logical equivalent of the following: |
|
(H5FD_LOG_TIME_OPEN | H5FD_LOG_TIME_READ | H5FD_LOG_TIME_WRITE
| H5FD_LOG_TIME_SEEK | H5FD_LOG_TIME_CLOSE)
|
H5FD_LOG_ALLOC
|
Track the allocation of space in the file. |
H5FD_LOG_ALL
|
Track everything. The logical equivalent of the following: |
|
(H5FD_LOG_ALLOC | H5FD_LOG_TIME_IO | H5FD_LOG_NUM_IO | H5FD_LOG_FLAVOR
|H5FD_LOG_FILE_IO | H5FD_LOG_LOC_IO)
|
|
|
The logging driver can track the number of times
each byte in the file is read from or written to
(using H5FD_LOG_FILE_READ
and H5FD_LOG_FILE_WRITE
)
and what kind of data is at that location
(e.g., meta data, raw data; using H5FD_LOG_FLAVOR
).
This information is tracked in a buffer of size buf_size
,
which must be at least the size in bytes of the file to be logged.
fapl_id
logfile
flags
buf_size
H5Pset_fapl_mpio
(
hid_t fapl_id
,
MPI_Comm comm
,
MPI_Info info
)
H5Pset_fapl_mpio
stores the user-supplied
MPI IO parameters comm
, for communicator, and
info
, for information, in
the file access property list fapl_id
.
That property list can then be used to create and/or open the file.
H5Pset_fapl_mpio
is available only in the
parallel HDF5 library and is not a collective function.
comm
is the MPI communicator to be used for
file open as defined in MPI_FILE_OPEN
of MPI-2.
This function does not create a duplicated communicator.
Modifications to comm
after this function call
returns may have an undetermined effect on the access property list.
Users should not modify the communicator while it is defined
in a property list.
info
is the MPI info object to be used for
file open as defined in MPI_FILE_OPEN
of MPI-2.
This function does not create a duplicated info object.
Any modification to the info object after this function call
returns may have an undetermined effect on the access property list.
Users should not modify the info while it is defined
in a property list.
fapl_id
comm
info
H5Pget_fapl_mpio
(
hid_t fapl_id
,
MPI_Comm *comm
,
MPI_Info *info
)
H5FD_MPIO
driver, H5Pget_fapl_mpio
returns the MPI communicator and
information through the comm
and info
pointers, if those values are non-null.
Neither comm
nor info
is copied,
so they are valid only until the file access property list
is either modified or closed.
fapl_id
comm
info
H5Pset_dxpl_mpio
(
hid_t dxpl_id
,
H5FD_mpio_xfer_t xfer_mode
)
H5Pset_dxpl_mpio
sets the data transfer property list
dxpl_id
to use transfer mode xfer_mode
.
The property list can then be used to control the I/O transfer mode
during data I/O operations.
Valid transfer modes are as follows:
H5FD_MPIO_INDEPENDENT
H5FD_MPIO_COLLECTIVE
dxpl_id
xfer_mode
H5Pget_dxpl_mpio
(
hid_t dxpl_id
,
H5FD_mpio_xfer_t *xfer_mode
)
H5Pget_dxpl_mpio
queries the data transfer mode
currently set in the data transfer property list dxpl_id
.
Upon return, xfer_mode
contains the data transfer mode,
if it is non-null.
H5Pget_dxpl_mpio
is not a collective function.
dxpl_id
xfer_mode
H5Pset_fapl_multi
(
hid_t fapl_id
,
const H5FD_mem_t *memb_map
,
const hid_t *memb_fapl
,
const char **memb_name
,
const haddr_t *memb_addr
,
hbool_t relax
)
H5Pset_fapl_multi
sets the file access property list
fapl_id
to use the multi-file driver.
The multi-file driver enables different types of HDF5 data and metadata to be written to separate files. These files are viewed by the HDF5 library and the application as a single virtual HDF5 file with a single HDF5 file address space. The types of data that can be broken out into separate files include raw data, the superblock, B-tree data, global heap data, local heap data, and object headers. At the programmer's discretion, two or more types of data can be written to the same file while other types of data are written to separate files.
The array memb_map
maps memory usage types to other
memory usage types and is the mechanism that allows the caller
to specify how many files are created.
The array contains H5FD_MEM_NTYPES
entries,
which are either the value H5FD_MEM_DEFAULT
or a memory usage type.
The number of unique values determines the number of files
that are opened.
The array memb_fapl
contains a property list
for each memory usage type that will be associated with a file.
The array memb_name
should be a name generator
(a printf-style format with a %s which will be replaced with the
name passed to H5FDopen
, usually from
H5Fcreate
or H5Fopen
).
The array memb_addr
specifies the offsets within the
virtual address space, from 0
(zero) to
HADDR_MAX
, at which each type of data storage begins.
If relax
is set to TRUE
(or 1
),
then opening an existing file for read-only access will not fail
if some file members are missing.
This allows a file to be accessed in a limited sense if just the
meta data is available.
Default values for each of the optional arguments are as follows:
memb_map
H5FD_MEM_DEFAULT
for each element.
memb_fapl
H5P_DEFAULT
for each element.
memb_name
%s-X.h5
where X
is one of the
following letters:
s
for H5FD_MEM_SUPER
b
for H5FD_MEM_BTREE
r
for H5FD_MEM_DRAW
g
for H5FD_MEM_GHEAP
l
for H5FD_MEM_LHEAP
o
for H5FD_MEM_OHDR
memb_addr
HADDR_UNDEF
for each element.
fapl_id
memb_map
memb_fapl
memb_name
memb_addr
0
(zero) to HADDR_MAX
,
at which each type of data storage begins.
relax
TRUE
.
H5FD_mem_t mt, memb_map[H5FD_MEM_NTYPES]; hid_t memb_fapl[H5FD_MEM_NTYPES]; const char *memb[H5FD_MEM_NTYPES]; haddr_t memb_addr[H5FD_MEM_NTYPES]; // The mapping... for (mt=0; mt<H5FD_MEM_NTYPES; mt++) { memb_map[mt] = H5FD_MEM_SUPER; } memb_map[H5FD_MEM_DRAW] = H5FD_MEM_DRAW; // Member information memb_fapl[H5FD_MEM_SUPER] = H5P_DEFAULT; memb_name[H5FD_MEM_SUPER] = "%s.meta"; memb_addr[H5FD_MEM_SUPER] = 0; memb_fapl[H5FD_MEM_DRAW] = H5P_DEFAULT; memb_name[H5FD_MEM_DRAW] = "%s.raw"; memb_addr[H5FD_MEM_DRAW] = HADDR_MAX/2; hid_t fapl = H5Pcreate(H5P_FILE_ACCESS); H5Pset_fapl_multi(fapl, memb_map, memb_fapl, memb_name, memb_addr, TRUE);
H5Pget_fapl_multi
(
hid_t fapl_id
,
const H5FD_mem_t *memb_map
,
const hid_t *memb_fapl
,
const char **memb_name
,
const haddr_t *memb_addr
,
hbool_t *relax
)
H5Pget_fapl_multi
returns information about the
multi-file access property list.
fapl_id
memb_map
memb_fapl
memb_name
memb_addr
relax
TRUE
.
H5Pset_dxpl_multi
(
hid_t dxpl_id
,
const hid_t *memb_dxpl
)
H5Pset_dxpl_multi
sets the data transfer property list
dxpl_id
to use the multi-file driver for each
memory usage type memb_dxpl[]
.
H5Pset_dxpl_multi
can only be used after
the member map has been set with H5Pset_fapl_multi
.
dxpl_id
,
memb_dxpl
H5Pget_dxpl_multi
(
hid_t dxpl_id
,
const hid_t *memb_dxpl
)
H5Pget_dxpl_multi
returns the data transfer property list
information for the multi-file driver.
dxpl_id
,
memb_dxpl
H5Pset_fapl_split
(
hid_t fapl_id
,
const char *meta_ext
,
hid_t meta_plist_id
,
const char *raw_ext
,
hid_t raw_plist_id
)
H5Pset_fapl_split
is a compatibility function that
enables the multi-file driver to emulate the split driver from
HDF5 Releases 1.0 and 1.2.
The split file driver stored metadata and raw data in separate files
but provided no mechanism for separating types of metadata.
fapl_id
is a file access property list identifier.
meta_ext
is the filename extension for the metadata file.
The extension is appended to the name passed to H5FDopen
,
usually from H5Fcreate
or H5Fopen
,
to form the name of the metadata file.
If the string %s is used in the extension, it works like the
name generator as in H5Pset_fapl_multi
.
meta_plist_id
is the file access property list identifier
for the metadata file.
raw_ext
is the filename extension for the raw data file.
The extension is appended to the name passed to H5FDopen
,
usually from H5Fcreate
or H5Fopen
,
to form the name of the rawdata file.
If the string %s is used in the extension, it works like the
name generator as in H5Pset_fapl_multi
.
raw_plist_id
is the file access property list identifier
for the raw data file.
If a user wishes to check to see whether this driver is in use,
the user must call H5Pget_driver
and compare the
returned value to the string H5FD_MULTI
.
A positive match will confirm that the multi driver is in use;
HDF5 provides no mechanism to determine whether it was called
as the special case invoked by H5Pset_fapl_split
.
fapl_id
,
meta_ext
,
meta_plist_id
,
raw_ext
,
raw_plist_id
/* Example 1: Both metadata and rawdata files are in the same */ /* directory. Use Station1-m.h5 and Station1-r.h5 as */ /* the metadata and rawdata files. */ hid_t fapl, fid; fapl = H5Pcreate(H5P_FILE_ACCESS); H5Pset_fapl_split(fapl, "-m.h5", H5P_DEFAULT, "-r.h5", H5P_DEFAULT); fid=H5Fcreate("Station1",H5F_ACC_TRUNC,H5P_DEFAULT,fapl); /* Example 2: metadata and rawdata files are in different */ /* directories. Use PointA-m.h5 and /pfs/PointA-r.h5 as */ /* the metadata and rawdata files. */ hid_t fapl, fid; fapl = H5Pcreate(H5P_FILE_ACCESS); H5Pset_fapl_split(fapl, "-m.h5", H5P_DEFAULT, "/pfs/%s-r.h5", H5P_DEFAULT); fid=H5Fcreate("PointA",H5F_ACC_TRUNC,H5P_DEFAULT,fapl);
H5Pset_fapl_sec2
(
hid_t fapl_id
)
H5Pset_fapl_sec2
modifies the file access property list
to use the H5FD_SEC2
driver.
fapl_id
H5Pset_fapl_stdio
(
hid_t fapl_id
)
H5Pset_fapl_stdio
modifies the file access property list
to use the standard I/O driver, H5FD_STDIO
.
fapl_id
H5Pset_fapl_stream
(
hid_t fapl_id
,
H5FD_stream_fapl_t *fapl
)
H5Pset_fapl_stream
sets up the use of the
streaming I/O driver.
fapl_id
is the identifier for the
file access property list currently in use.
fapl
is the file access property list.
The H5FD_stream_fapl_t
struct contains the following
elements:
size_t | increment |
H5FD_STREAM_SOCKET_TYPE | socket |
hbool_t | do_socket_io |
unsigned int | backlog |
H5FD_stream_broadcast_t | broadcast_fn |
void * | broadcast_arg |
increment
specifies how much memory to allocate
each time additional memory is required.
socket
is an external socket descriptor;
if a valid socket argument is provided, that socket will be used.
do_socket_io
is a boolean value specifying whether
to perform I/O on socket
.
backlog
is the argument for the
listen
call.
broadcast_fn
is the broadcast callback function.
broadcast_arg
is the user argument to
the broadcast callback function.
H5Pset_fapl_stream
and H5Pget_fapl_stream
are not intended for use in a parallel environment.
fapl_id
fapl
H5Pget_fapl_stream
(
hid_t fapl_id
,
H5FD_stream_fapl_t *fapl
)
H5Pget_fapl_stream
returns the file access properties
set for the use of the streaming I/O driver.
H5Pset_fapl_stream
and H5Pget_fapl_stream
are not intended for use in a parallel environment.
fapl_id
fapl
H5Pget_driver
(
hid_t plist_id
)
H5Pget_driver
returns the identifier of the
low-level file driver associated with the file access property list
or data transfer property list plist_id
.
Valid driver identifiers with the standard HDF5 library distribution include the following:
H5FD_CORE H5FD_DPSS H5FD_FAMILY H5FD_GASS H5FD_LOG H5FD_MPIO H5FD_MULTI H5FD_SEC2 H5FD_STDIO H5FD_STREAMIf a user defines and registers custom drivers or if additional drivers are defined in an HDF5 distribution, this list will be longer.
The returned driver identifier is only valid as long as the file driver remains registered.
plist_id
H5Pset_fapl_gass
(
hid_t fapl_id
,
GASS_Info info
)
H5Pset_fapl_gass
stores user-supplied GASS information,
the GASS_Info struct data as passed in info
,
to the file access property list fapl_id
.
fapl_id
can then be used to create and/or open the file.
The GASS_Info object, info
, is used for
file open operations when using GASS in the Globus environment.
Any modification to info
after this function call
returns may have undetermined effect to the access property list.
Users must call H5Pset_fapl_gass
again to setup
the property list.
H5Pset_fapl_gass
is an experimental function.
It is designed for use only when accessing files via the
GASS facility of the Globus environment.
For further information, see
http//www.globus.org/.
fapl_id
,
info
H5Pget_fapl_gass
(
hid_t fapl_id
,
GASS_Info *info
)
fapl_id
is set
for use of the H5FD_GASS
driver,
H5Pget_fapl_gass
returns the GASS_Info
object through the info
pointer.
The GASS_Info information is copied, so it is valid only until the file access property list is modified or closed.
H5Pget_fapl_gass
is an experimental function.
It is designed for use only when accessing files via the
GASS facility of the Globus environment.
For further information, see
http//www.globus.org/.
fapl_id
,
info
H5Pset_fapl_srb
(
hid_t fapl_id
,
SRB_Info info
)
H5Pset_fapl_srb
stores the SRB client-to-server
connection handler SRB_CONN
after the connection
is established and other user-supplied SRB information.
The user-supplied SRB information is contained in the
SRB_Info struct pointed to by info
and is stored in the file access property list fapl_id
.
This information can then be used to create or open a file.
H5Pset_fapl_gass
is an experimental function.
It is designed for use only when accessing files via the
Storage Resource Broker (SRB). For further information, see
http//www.npaci.edu/Research/DI/srb/.
fapl_id
info
H5Pget_fapl_srb
(
hid_t fapl_id
,
SRB_Info *info
)
fapl_id
is set
for use of the H5FD_SRB
driver,
H5Pget_fapl_srb
returns the SRB_Info
object through the info
pointer.
The SRB_Info information is copied, so it is valid only until the file access property list is modified or closed.
H5Pset_fapl_gass
is an experimental function.
It is designed for use only when accessing files via the
Storage Resource Broker (SRB). For further information, see
http//www.npaci.edu/Research/DI/srb/.
fapl_id
info
H5Pset_fapl_core
(
hid_t fapl_id
,
size_t increment
,
hbool_t backing_store
)
H5FD_CORE
driver.
H5Pset_fapl_core
modifies the file access property list
to use the H5FD_CORE
driver.
The H5FD_CORE
driver enables an application to work
with a file in memory, speeding reads and writes as no disk access
is made. File contents are stored only in memory until the file
is closed. The backing_store
parameter determines
whether file contents are ever written to disk.
increment
specifies the increment by which allocated
memory is to be increased each time more memory is required.
If backing_store
is set to 1
(TRUE
), the file contents are flushed to a file
with the same name as this core file when the file is closed
or access to the file is terminated in memory.
H5FD_CORE
driver to manipulate the file.
fapl_id
increment
backing_store
H5Pget_fapl_core
(
hid_t fapl_id
,
size_t *increment
,
hbool_t *backing_store
)
H5Pget_fapl_core
queries the H5FD_CORE
driver properties as set by H5Pset_fapl_core
.
fapl_id
increment
backing_store
H5Pset_fclose_degree
(hid_t fapl_id
,
H5F_close_degree_t fc_degree
)
H5Pset_fclose_degree
sets the file close degree property fc_degree
in the file access property list fapl_id
.
The value of fc_degree
determines how aggressively H5Fclose
deals with objects within a file that remain open when H5Fclose
is called to close that file. fc_degree
can have any one of
four valid values:
Degree name | H5Fclose behavior with no open object
in file |
H5Fclose behavior with open object(s)
in file |
---|---|---|
H5F_CLOSE_WEAK |
Actual file is closed. | Access to file identifier is terminated; actual file close is delayed until all objects in file are closed |
H5F_CLOSE_SEMI |
Actual file is closed. | Function returns FAILURE |
H5F_CLOSE_STRONG |
Actual file is closed. | All open objects ramaining in the file are closed then file is closed |
H5F_CLOSE_DEFAULT |
The VFL driver chooses the behavior. Currently,
all VFL drivers set this value to H5F_CLOSE_WEAK , except
for the MPI-I/O driver, which sets it to H5F_CLOSE_SEMI .
|
fapl_id
fc_degree
fc_degree
.
H5Pget_fclose_degree
(hid_t fapl_id
,
H5F_close_degree_t fc_degree
)
H5Pget_fclose_degree
returns the current setting of the file
close degree property fc_degree
in the file access property list
fapl_id
.
The value of fc_degree
determines how aggressively H5Fclose
deals with objects within a file that remain open when H5Fclose
is called to close that file. fc_degree
can have any one of
four valid values as described above in H5Pset_fclose_degree
.
fapl_id
fc_degree
fc_degree
.
HDF5 documents and links Introduction to HDF5 HDF5 User Guide |
And in this document, the
HDF5 Reference Manual
H5 H5A H5D H5E H5F H5G H5I H5P H5R H5S H5T H5Z Tools Datatypes |