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--------------------------------------
EnSight User Defined Reader Capability
--------------------------------------
A user defined reader capability is included in EnSight which allows otherwise
unsupported structured or unstructured data to be read. The user defined
reader utilizes a dynamic shared library composed of routines defined in this
document, but produced by the user (or some third party). This capability is
currently available for dec, ibm, hp, sgi, and sun servers.
****************************************************************************
Note: Several user defined readers have been included with your EnSight
release and can be accessed by changing the ENSIGHT6_READER
environment variable as outlined in step 3. below. Please be aware
that these are "unsupported" readers, but many of them are being used
successfully.
****************************************************************************
The process for producing a user defined reader is:
--------------------------------------------------
1. Write code for all pertinent routines in the library (Unless someone else
has done this for you).
This is of course where the work is done by the user. The word
"pertinent" is used because depending on the nature of the data, some
of the routines in the library may be dummy routines.
The source code for a dummy library and for various other working or
sample libraries is copied from the installation CD during
installation. These will be located in directories under:
$ENSIGHT6_HOME/ensight62/user_defined_src/readers
examples:
--------
The default library. Basic dummy routines.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/dummy
Sample library which reads unstructured binary EnSight6 data.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/ensight6
Sample library which reads binary static plot3d data.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/plot3d
Reads binary LS-DYNA3D state database.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/ls-dyna3d
Reads FORTRAN binary Unstrutured dytran data base.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/dytran
Reads FlowScience "flsgrf" flow3d data.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/flow3d
Reads Tecplot "plt" files.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/tecplot
Reads Common File Format data.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/cff
Reads Cobalt grid and picture/restart file data.
$ENSIGHT6_HOME/ensight62/user_defined_src/readers/cobalt
You may find it useful to place your library source in this area as
well, but are not limited to this location.
* ===> The descriptions of each library routine and the order that the
routines are called, which is provided in this file, along with
the example libraries, should make it possible for you to produce
code for your own data reader.
2. Produce the dynamic shared library.
This is a compiling and loading process which varies according to
the type of machine you are on. Thus, a separate makefile is provided
for each machine type. Operating system level differences could cause
you to have to modify these makefiles slightly, but the general
process is very straightforward. Note that for the SGI environment you
must compile with the following flags to ensure compatability with
the EnSight server: Irix_5.3 -mips1
Irix_6.2 -mips2
Irix_6.5_n32 -mips3
Irix_6.5_n64 -mips4 -64
__________________________________________________________________
| MACHINE | MAKEFILE TO USE | SHARED LIBRARY NAME PRODUCED |
| TYPE |--------------------------------------------------------|
| | LD COMMAND USED IN MAKEFILE |
==================================================================
__________________________________________________________________
| sgi | makefile.sgi | libuserd.so |
| |--------------------------------------------------------|
| | ld -shared -all -o libuserd.so libuserd.o |
------------------------------------------------------------------
__________________________________________________________________
| hp | makefile.hp | libuserd.sl |
| |--------------------------------------------------------|
| | ld -b -o libuserd.sl libuserd.o |
------------------------------------------------------------------
__________________________________________________________________
| sun | makefile.sun | libuserd.so |
| |--------------------------------------------------------|
| | ld -G -o libuserd.so libuserd.o |
------------------------------------------------------------------
__________________________________________________________________
| dec | makefile.dec | libuserd.so |
| |--------------------------------------------------------|
| | ld -shared -all -o libuserd.so libuserd.o -lc |
------------------------------------------------------------------
__________________________________________________________________
| ibm | makefile.ibm | libuserd.so |
| |--------------------------------------------------------|
| | ld -G -o libuserd.so libuserd.o -bnoentry -bexpall -lc |
------------------------------------------------------------------
Once you have created your library, you should place it in a directory
of your choice under:
$ENSIGHT6_HOME/machines/$ENSIGHT6_ARCH/lib_readers
Thus, if you created a reader for "mydata", you should create the
following directory, and place your libuserd.so into it:
$ENSIGHT6_HOME/machines/$ENSIGHT6_ARCH/lib_readers/mydata
3. Set up the ENSIGHT6_READER environment variable so EnSight will know
which reader directory to use at runtime.
Ensight will look for the library under:
$ENSIGHT6_HOME/machines/$ENSIGHT6_ARCH/lib_readers/$ENSIGHT6_READER
When EnSight was installed, you set this variable to "dummy", with:
setenv ENSIGHT6_READER dummy
You can use any of the other provided readers by changing this variable.
For example, to use the dytran reader:
setenv ENSIGHT6_READER dytran
Thus, you can use your reader in the same way. If you provided "mydata",
change ENSIGHT6_READER to:
setenv ENSIGHT6_READER mydata
For your information, EnSight makes sure that the appropriate library
environment variable is set for your machine architecture. You do not
have to deal with this if you locate your library as outlined above.
The library environment variables used are:
Machine type Environment variable to set
------------ ---------------------------
sgi LD_LIBRARY_PATH
dec LD_LIBRARY_PATH
sun LD_LIBRARY_PATH
hp SHLIB_PATH
ibm LIBPATH
IMPORTANT: Unless the shared library is available in the
.../$ENSIGHT6_READER directory, EnSight will not run.
As always, EnSight support is available if you need it.
-------------------------------
Quick Index of Library Routines
-------------------------------
Generally Needed for UNSTRUCTURED data
--------------------------------------
USERD_get_number_of_global_nodes number of global nodes
USERD_get_global_coords global node coordinates
USERD_get_global_node_ids global node ids
USERD_get_element_connectivities_for_part part's element connectivites
USERD_get_element_ids_for_part part's element ids
USERD_get_scalar_values global scalar variables
USERD_get_vector_values global vector variables
Generally Needed for BLOCK data
-----------------------------------------
USERD_get_block_coords_by_component block coordinates
USERD_get_block_iblanking block iblanking values
USERD_get_block_scalar_values block scalar variables
USERD_get_block_vector_values_by_component block vector variables
Generally needed for either or both kinds of data
-------------------------------------------------
USERD_set_filenames filenames entered in GUI
USERD_set_time_step current time step
USERD_get_name_of_reader name of reader for GUI
USERD_get_number_of_files_in_dataset number of files in model
USERD_get_dataset_query_file_info info about each model file
USERD_get_changing_geometry_status changing geometry?
USERD_get_node_label_status node labels?
USERD_get_element_label_status element labels?
USERD_get_number_of_time_steps number of time steps
USERD_get_solution_times solution time values
USERD_get_description_lines file associated descrip lines
USERD_get_number_of_variables number of variables
USERD_get_variable_info variable type/descrip etc.
USERD_get_constant_value constant variable's value
USERD_get_number_of_model_parts number of model parts
USERD_get_part_build_info part type/descrip etc.
USERD_get_variable_value_at_specific node's or element's variable
value over time
USERD_stop_part_building cleanup routine
USERD_bkup archive routine
-------------------------
Order Routines are called
-------------------------
The various main operations are given basically in the order they will
be performed. Within each operation, the order the routines will be
called is given.
1. Setting name in the gui, and specifying one or two input fields
USERD_get_name_of_reader
2. Setting filenames and getting time info
USERD_set_filenames
USERD_get_number_of_time_steps
USERD_get_solution_times
USERD_set_time_step
3. Gathering info for part builder
USERD_set_time_step
USERD_get_changing_geometry_status
USERD_get_node_label_status
USERD_get_element_label_status
USERD_get_number_of_files_in_dataset
USERD_get_dataset_query_file_info
USERD_get_description_lines (for geometry)
USERD_get_number_of_model_parts
USERD_get_part_build_info
USERD_get_number_global_nodes
USERD_get_global_coords (for model extents)
USERD_get_block_coords_by_component (for model extents)
4. Gathering Variable info
USERD_get_number_of_variables
USERD_get_variable_info
5. Part building (per part created)
USERD_set_time_step
USERD_get_global_coords
USERD_get_global_node_ids
USERD_get_element_connectivities_for_part
USERD_get_element_ids_for_part
USERD_get_block_iblanking
USERD_get_block_coords_by_component
USERD_stop_part_building (only once when part builder
dialog is closed)
6. Loading Variables
constants:
---------
USERD_set_time_step
USERD_get_constant_value
scalars:
-------
USERD_get_description_lines
USERD_set_time_step
USERD_get_scalar_values
USERD_get_block_scalar_values
vectors:
-------
USERD_get_description_lines
USERD_set_time_step
USERD_get_vector_values
USERD_get_block_vector_values_by_component
7. Changing geometry
changing coords only:
--------------------
USERD_set_time_step
USERD_get_global_coords
USERD_get_block_coords_by_component
changing connectivity:
---------------------
USERD_set_time_step
USERD_get_number_of_model_parts
USERD_get_part_build_info
USERD_get_number_global_nodes
USERD_get_global_coords
USERD_get_global_node_ids
USERD_get_element_connectivities_for_part
USERD_get_element_ids_for_part
USERD_get_block_iblanking
USERD_get_block_coords_by_component
-----------------------
Detailed Specifications
-----------------------
Include files:
--------------
The following header file is required in any file containing these library
routines.
#include "global_extern.h"
Basis of arrays:
---------------
Unless explicitly stated otherwise, all arrays are zero based - in true C
fashion.
Global variables:
----------------
You will generally need to have a few global variables which are shared by
the various library routines. The detailed specifications below have assumed
the following are available. (Their names describe their purpose, and they
will be used in helping describe the details of the routines below).
static int Numparts_available = 0;
static int Num_unstructured_parts = 0;
static int Num_structured_blocks = 0;
/* Note: Numparts_available = Num_unstructured_parts + Num_structured_blocks */
static int Num_time_steps = 1;
static int Num_global_nodes = 0;
static int Num_variables = 0;
static int Num_dataset_files = 0;
static int Current_time_step = 0;
_________________________________________
-----------------------------------------
Library Routines (in alphabetical order):
_________________________________________
-----------------------------------------
--------------------------------------------------------------------
USERD_bkup
Description:
-----------
This routine is called during the EnSight archive process. You can
use it to save or restore info relating to your user defined reader.
Specification:
-------------
int USERD_bkup(FILE *archive_file,
int backup_type)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) archive_file = The archive file pointer
(IN) backup_type = Z_SAVE_ARCHIVE for saving archive
Z_REST_ARCHIVE for restoring archive
Notes:
-----
* Since EnSight's archive file is saved in binary form, you should
also do any writing to it or reading from it in binary.
* You should archive any variables, which will be needed for
future operations, that will not be read or computed again
before they will be needed. These are typically global
variables.
* Make sure that the number of bytes that you write on a save and
the number of bytes that you read on a restore are identical!!
* If any of the variables you save are allocated arrays, you must
do the allocations before restoring into them.
--------------------------------------------------------------------
USERD_get_block_coords_by_component
Description:
-----------
Get the coordinates of a given structured block, a component at a time.
Specification:
-------------
int USERD_get_block_coords_by_component(int block_number,
int which_component,
float *coord_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) block_number = The block part number
(IN) which_component = Z_COMPX if x component wanted
= Z_COMPY if y component wanted
= Z_COMPZ if z component wanted
(OUT) coord_array = 1D array containing x,y, or z
coordinate component of each node
(Array will have been allocated
i*j*k for the block long)
Notes:
-----
* Not called unless Num_structured_blocks is > 0
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_block_iblanking
Description:
-----------
Get the iblanking value at each node of a block (if the block is
iblanked).
Specification:
-------------
int USERD_get_block_iblanking(int block_number,
int *iblank_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) block_number = The block part number
(OUT) iblank_array = 1D array containing iblank value
for each node.
(Array will have been allocated
i*j*k for the block long)
possible values are: Z_EXT = exterior
Z_INT = interior
Z_BND = boundary
Z_INTBND = internal boundary
Z_SYM = symmetry plane
Notes:
-----
* Not called unless Num_structured_blocks is > 0 and you have
some iblanked blocks
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_block_scalar_values
Description:
-----------
if Z_PER_NODE:
Get the values at each node of a block, for a given scalar variable
or if Z_PER_ELEM:
Get the values at each element of a block, for a given scalar variable
Specification:
-------------
int USERD_get_block_scalar_values(int block_number,
int which_scalar,
float *scalar_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) block_number = The block part number
(IN) which_scalar = The variable number
(OUT) scalar_array = 1D array containing scalar values
for each node or element.
Array will have been allocated:
if Z_PER_NODE:
i*j*k for the block long
if Z_PER_ELEM:
(i-1)*(i-1)*(k-1) for the block long
Notes:
-----
* Not called unless Num_structured_blocks is > 0,
Num_variables is > 0, and there are some scalar type variables
* The per_node or per_elem classification must be obtainable from the
variable number (a var_classify array needs to be retained)
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_block_vector_values_by_component
Description:
-----------
if Z_PER_NODE:
Get the values at each node of a block, for a given vector
variable, one component at a time.
or if Z_PER_ELEM:
Get the values at each element of a block, for a given vector
variable, one component at a time.
Specification:
-------------
int USERD_get_block_vector_values_by_component(int block_number,
int which_vector,
int which_component,
float *vector_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) block_number = The block part number
(IN) which_vector = The variable number
(IN) which_component = Z_COMPX if x component wanted
= Z_COMPY if y component wanted
= Z_COMPZ if z component wanted
(OUT) vector_array = 1D array containing vector
component value for each node or element.
Array will have been allocated:
if Z_PER_NODE:
i*j*k for the block long
if Z_PER_ELEM:
(i-1)*(i-1)*(k-1) for the block long
Notes:
-----
* Not called unless Num_structured_blocks is > 0,
Num_variables is > 0, and there are some vector type variables
* The per_node or per_elem classification must be obtainable from the
variable number (a var_classify array needs to be retained)
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_changing_geometry_status
Description:
-----------
Gets the changing geometry status for the model
Specification:
-------------
int USERD_get_changing_geometry_status( void )
Returns:
-------
Z_STATIC if geometry does not change
Z_CHANGE_COORDS if changing coordinates only
Z_CHANGE_CONN if changing connectivity
Arguments:
---------
none
Notes:
-----
* EnSight does not support changing number of parts. But the
coords and/or the connectivity of the parts can change.
--------------------------------------------------------------------
USERD_get_constant_value
Description:
-----------
Get the value of a constant at a time step
Specification:
-------------
float USERD_get_constant_value(int which_var)
Returns:
-------
Value of the requested constant variable
Arguments:
---------
(IN) which_var = The variable number
Notes:
-----
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_dataset_query_file_info
Description:
-----------
Get the information about files in the dataset. Used for the
dataset query option within EnSight.
Specification:
-------------
int USERD_get_dataset_query_file_info(Z_QFILES *qfiles)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) qfiles = Structure containing information about each file
of the dataset. The Z_QFILES structure is defined
in the global_extern.h file
(The structure will have been allocated
Num_dataset_files long, with 10 description
lines per file).
qfiles[].name = The name of the file
(Z_MAXFILENP is the dimensioned length
of the name)
qfiles[].sizeb = The number of bytes in the file
(Typically obtained with a call to the
"stat" system routine)
qfiles[].timemod = The time the file was last modified
(Z_MAXTIMLEN is the dimensioned length
of this string)
(Typically obtained with a call to the
"stat" system routine)
qfiles[].num_d_lines = The number of description lines you
are providing from the file. Max = 10
qfiles[].f_desc[] = The description line(s) per file,
qfiles[].num_d_lines of them
(Z_BUFLEN is the allocated length of
each line)
Notes:
-----
* If Num_dataset_files is 0, this routine will not be called.
--------------------------------------------------------------------
USERD_get_description_lines
Description:
-----------
Get two description lines associated with geometry per time step,
or one description line associated with a variable per time step.
Specification:
-------------
int USERD_get_description_lines(int which_type,
int which_var,
char line1[Z_BUFL],
char line2[Z_BUFL])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) which_type = Z_GEOM for geometry (2 lines)
= Z_VARI for variable (1 line)
(IN) which_var = If it is a variable, which one.
Ignored if geometry type.
(OUT) line1 = The 1st geometry description line,
or the variable description line.
(OUT) line2 = The 2nd geometry description line
Not used if variable type.
Notes:
-----
* Will be based on Current_time_step
* These are the lines EnSight can echo to the screen in
annotation mode.
--------------------------------------------------------------------
USERD_get_element_connectivities_for_part
Description:
-----------
Gets the connectivities for the elements of an unstructured part
Specification:
-------------
int USERD_get_element_connectivities_for_part(int part_number,
int **conn_array[Z_MAXTYPE])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(OUT) conn_array = 3D array containing connectivity
of each element of each type.
(Array will have been allocated
Z_MAXTYPE by num_of_elements of
each type by connectivity length
of each type)
ex) If num_of_elements[Z_TRI03] = 25
num_of_elements[Z_QUA04] = 100
num_of_elements[Z_HEX08] = 30
as obtained in:
USERD_get_part_build_info
Then the allocated dimensions available
for this routine will be:
conn_array[Z_TRI03][25][3]
conn_array[Z_QUA04][100][4]
conn_array[Z_HEX08][30][8]
Notes:
-----
* Not called unless Num_unstructured_parts is > 0
* Will be based on Current_time_step
* The coord_array loaded in USERD_get_global_coords is zero-based,
but within EnSight it will become a one-based array.
Thus, coord_array[0] will be accessed by node 1 from the conn_array,
coord_array[1] will be accessed by node 2 from the conn_array, etc.
ex) Given a model of two triangles, you should load coord_array in
USERD_get_global_coords as follows:
node coordinates
---- -----------
4 --------- 3 1 coord_array[0].xyz[0] = 0.0
|\ | coord_array[0].xyz[1] = 0.0
| \ T2 | coord_array[0].xyz[2] = 0.0
| \ |
| \ | 2 coord_array[1].xyz[0] = 1.0
| \ | coord_array[1].xyz[1] = 0.0
| \ | coord_array[1].xyz[2] = 0.0
| \ |
| T1 \ | 3 coord_array[2].xyz[0] = 1.0
| \| coord_array[2].xyz[1] = 1.6
1 --------- 2 coord_array[2].xyz[2] = 0.0
4 coord_array[3].xyz[0] = 0.0
coord_array[3].xyz[1] = 1.6
coord_array[3].xyz[2] = 0.0
And conn_array here as follows:
Triangle Connectivity
-------- ------------
T1 conn_array[Z_TRI03][0][0] = 1
conn_array[Z_TRI03][0][1] = 2
conn_array[Z_TRI03][0][2] = 4
T2 conn_array[Z_TRI03][1][0] = 2
conn_array[Z_TRI03][1][1] = 3
conn_array[Z_TRI03][1][2] = 4
--------------------------------------------------------------------
USERD_get_element_ids_for_part
Description:
-----------
Gets the ids for the elements of an unstructured part.
Specification:
-------------
int USERD_get_element_ids_for_part(int part_number,
int *elemid_array[Z_MAXTYPE])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(OUT) elemid_array = 2D array containing id of each
element of each type.
(Array will have been allocated
Z_MAXTYPE by num_of_elements of
each type)
ex) If num_of_elements[Z_TRI03] = 25
num_of_elements[Z_QUA04] = 100
num_of_elements[Z_HEX08] = 30
as obtained in:
USERD_get_part_build_info
Then the allocated dimensions available
for this routine will be:
conn_array[Z_TRI03][25]
conn_array[Z_QUA04][100]
conn_array[Z_HEX08][30]
Notes:
-----
* Not called unless Num_unstructured_parts is > 0 and element
label status is TRUE
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_element_label_status
Description:
-----------
Answers the question as to whether element labels will be provided.
Specification:
-------------
int USERD_get_element_label_status( void )
Returns:
-------
TRUE if element labels will be provided
FALSE if element labels will NOT be provided
Arguments:
---------
none
Notes:
-----
* element lables are needed in order to do any element querying, or
element labeling on-screen within EnSight.
For unstructured parts, you can read them from your file if
available, or can assign them, etc. They need to be unique
per part, and are often unique per model.
USERD_get_element_ids_for_part is used to obtain the ids,
on a part by part basis, if TRUE status is returned here.
For structured parts, EnSight will assign ids if you return a
status of TRUE here. You cannot assign them youself!!
--------------------------------------------------------------------
USERD_get_global_coords
Description:
-----------
Gets the coordinates for the global nodes.
Specification:
-------------
int USERD_get_global_coords(CRD *coord_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) coord_array = 1D array of CRD structures,
which contains x,y,z coordinates
of each node.
(Array will have been allocated
Num_global_nodes long)
For reference, CRD structure (which is in global_extern) is:
typedef struct {
float xyz[3];
}CRD;
Notes:
-----
* Not called unless Num_unstructured_parts is > 0
* Will be based on Current_time_step
* The coord_array is zero-based, but within EnSight it will become
a one-based array.
Thus, coord_array[0] will be accessed by node 1 from the conn_array,
coord_array[1] will be accessed by node 2 from the conn_array, etc.
ex) Given a model of two triangles, you should load coord_array as
follows:
node coordinates
---- -----------
4 --------- 3 1 coord_array[0].xyz[0] = 0.0
|\ | coord_array[0].xyz[1] = 0.0
| \ T2 | coord_array[0].xyz[2] = 0.0
| \ |
| \ | 2 coord_array[1].xyz[0] = 1.0
| \ | coord_array[1].xyz[1] = 0.0
| \ | coord_array[1].xyz[2] = 0.0
| \ |
| T1 \ | 3 coord_array[2].xyz[0] = 1.0
| \| coord_array[2].xyz[1] = 1.6
1 --------- 2 coord_array[2].xyz[2] = 0.0
4 coord_array[3].xyz[0] = 0.0
coord_array[3].xyz[1] = 1.6
coord_array[3].xyz[2] = 0.0
And conn_array in USERD_get_element_connectivities_for_part
as follows:
Triangle Connectivity
-------- ------------
T1 conn_array[Z_TRI03][0][0] = 1
conn_array[Z_TRI03][0][1] = 2
conn_array[Z_TRI03][0][2] = 4
T2 conn_array[Z_TRI03][1][0] = 2
conn_array[Z_TRI03][1][1] = 3
conn_array[Z_TRI03][1][2] = 4
--------------------------------------------------------------------
USERD_get_global_node_ids
Description:
-----------
Gets the node ids assigned to each of the global nodes.
Specification:
-------------
int USERD_get_global_node_ids(int *nodeid_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) nodeid_array = 1D array containing node ids of
each node. The ids must be > 0
(Array will have been allocated
Num_global_nodes long)
Notes:
-----
* Not called unless Num_unstructured_parts is > 0 and node label
status is TRUE
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_name_of_reader
Description:
-----------
Gets the name of your user defined reader. The user interface will
ask for this and include it in the available reader list.
Specification:
-------------
int USERD_get_name_of_reader(char reader_name[Z_MAX_USERD_NAME],
int *two_fields)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) reader_name = the name of the your reader or data format.
(max length is Z_MAX_USERD_NAME, which is 20)
(OUT) *two_fields = FALSE if only one data field required
in the data dialog of EnSight.
TRUE if two data fields required.
Notes:
-----
* Always called. Provide a name for your custom reader format.
* If you don't want a custom reader to show up in the data dialog
choices, return a name of "No_Custom"
--------------------------------------------------------------------
USERD_get_node_label_status
Description:
-----------
Answers the question as to whether node labels will be provided.
Specification:
-------------
int USERD_get_node_label_status( void )
Returns:
-------
TRUE if node labels will be provided
FALSE if node labels will NOT be provided
Arguments:
---------
none
Notes:
-----
* Node ids are needed in order to do any node querying, or node
labeling on-screen within EnSight.
For unstructured parts, you can read them from your file if
available, or can assign them, etc. They need to be unique
per part, and are often unique per model. The must also be
positive numbers greater than zero.
USERD_get_global_node_ids is used to obtain the ids, if the
status returned here is TRUE.
Also be aware that if you say node labels are available,
the connectivity of elements must be according to these
node ids.
For structured parts, EnSight will assign ids if you return a
status of TRUE here. You cannot assign them yourself!!
--------------------------------------------------------------------
USERD_get_number_of_files_in_dataset
Description:
-----------
Get the total number of files in the dataset. Used for the
dataset query option within EnSight.
Specification:
-------------
int USERD_get_number_of_files_in_dataset( void )
Returns:
-------
The total number of files in the dataset.
Arguments:
---------
none
Notes:
-----
* You can be as complete as you want about this. If you don't
care about the dataset query option, return a value of 0
If you only want certain files, you can just include them. But,
you will need to supply the info in USERD_get_dataset_query_file_info
for each file you include here.
* Num_dataset_files would be set here
--------------------------------------------------------------------
USERD_get_number_of_global_nodes
Description:
-----------
Gets the number of global nodes, used for unstructured parts.
Specification:
-------------
int USERD_get_number_of_global_nodes()
Returns:
-------
Number of global nodes (>=0 if okay, <0 if problems)
Arguments:
---------
none
Notes:
-----
* Not called unless Num_unstructured_parts is > 0
* Will be based on Current_time_step
* For unstructured data:
EnSight wants 1. A global array of nodes
2. Element connectivities by part, which
reference the node numbers of the global
node array.
IMPORTANT:
---------
If you provide node ids, then element connectivities
must be in terms of the node ids. If you do not
provide node ids, then element connectivities must be
in terms of the index into the node array, but shifted
to start at 1
* Num_global_nodes would be set here
--------------------------------------------------------------------
USERD_get_number_of_model_parts
Description:
-----------
Gets the total number of unstructured and structured parts
in the model, for which you can supply information.
Specification:
-------------
int USERD_get_number_of_model_parts( void )
Returns:
-------
Number of parts (>0 if okay, <=0 if probs).
Arguments:
---------
none
Notes:
-----
* If going to have to read down through the parts in order to
know how many, you may want to build a table of pointers to
the various parts, so you can easily get to particular parts in
later processes. If you can simply read the number of parts
at the head of the file, then you would probably not build the
table at this time.
* This routine would set Numparts_available, which is equal to
Num_unstructured_parts + Num_structured_blocks.
--------------------------------------------------------------------
USERD_get_number_of_time_steps
Description:
-----------
Gets the number of time steps of data available.
Specification:
-------------
int USERD_get_number_of_time_steps( void )
Returns:
-------
Number of time steps (>0 if okay, <=0 if problems).
Arguments:
---------
none
Notes:
-----
* This should be >= 1 1 indicates a static model
>1 indicates a transient model
* Num_time_steps would be set here
--------------------------------------------------------------------
USERD_get_number_of_variables
Description:
-----------
Get the number of variables for which you will be providing info.
Specification:
-------------
int USERD_get_number_of_variables( void )
Returns:
-------
Number of variables (includes constant, scalar, and vector types)
(>=0 if okay, <0 if problem)
Arguments:
---------
none
Notes:
-----
*****************************************************************
* Variable numbers, by which references will be made, are implied
here. If you say there are 3 variables, the variable numbers
will be 1, 2, and 3.
*****************************************************************
* Num_variables would be set here
--------------------------------------------------------------------
USERD_get_part_build_info
Description:
-----------
Gets the info needed for the part building process.
Specification:
-------------
int USERD_get_part_build_info(int *part_numbers,
int *part_types,
char *part_description[Z_BUFL],
int *number_of_elements[Z_MAXTYPE],
int *ijk_dimensions[3],
int *iblanking_options[6])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) part_numbers = Array containing part numbers for
each of the model parts.
IMPORTANT:
Parts numbers must be >= 1
********************************************
The numbers provided here are the ones by
which the parts will be referred to in any
of the other routines which receive a part
number or block number as an argument!!
********************************************
(Array will have been allocated
Numparts_available long)
(OUT) part_types = Array containing one of the
following for each model part:
Z_UNSTRUCTURED or
Z_STRUCTURED or
Z_IBLANKED
(Array will have been allocated
Numparts_available long)
(OUT) part_description = Array containing a description
for each of the model parts
(Array will have been allocated
Numparts_available by Z_BUFL
long)
(OUT) number_of_elements = 2D array containing number of
each type of element for each
unstructured model part.
------------
Possible types are:
Z_POINT = point
Z_BAR02 = 2-noded bar
Z_BAR03 = 3-noded bar
Z_TRI03 = 3-noded triangle
Z_TRI06 = 6-noded triangle
Z_QUA04 = 4-noded quadrilateral
Z_QUA08 = 8-noded quadrilateral
Z_TET04 = 4-noded tetrahedron
Z_TET10 = 10-noded tetrahedron
Z_PYR05 = 5-noded pyramid
Z_PYR13 = 13-noded pyramid
Z_PEN06 = 6-noded pentahedron
Z_PEN15 = 15-noded pentahedron
Z_HEX08 = 8-noded hexahedron
Z_HEX20 = 20-noded hexahedron
(Ignored unless Z_UNSTRUCTURED type)
(Array will have been allocated
Numparts_available by
Z_MAXTYPE long)
(OUT) ijk_dimensions = 2D array containing ijk dimensions
for each structured model part.
----------
(Ignored if Z_UNSTRUCTURED type)
(Array will have been allocated
Numparts_available by 3 long)
ijk_dimensions[][0] = I dimension
ijk_dimensions[][1] = J dimension
ijk_dimensions[][2] = K dimension
(OUT) iblanking_options = 2D array containing iblanking
options possible for each
structured model part.
----------
(Ignored unless Z_IBLANKED type)
(Array will have been allocated
Numparts_available by 6 long)
iblanking_options[][Z_EXT] = TRUE if external (outside)
[][Z_INT] = TRUE if internal (inside)
[][Z_BND] = TRUE if boundary
[][Z_INTBND] = TRUE if internal boundary
[][Z_SYM] = TRUE if symmetry surface
Notes:
-----
* If you haven't built a table of pointers to the different parts,
you might want to do so here as you gather the needed info.
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_scalar_values
Description:
-----------
if Z_PER_NODE:
Get the values at each global node for a given scalar variable.
or if Z_PER_ELEM:
Get the values at each element of a specific part and type for a
given scalar variable.
Specification:
-------------
int USERD_get_scalar_values(int which_scalar,
int which_part,
int which_type,
float *scalar_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) which_scalar = The variable number (of scalar type)
(IN) which_part
if Z_PER_NODE: Not used
if Z_PER_ELEM: = The part number
(IN) which_type
if Z_PER_NODE: Not used
if Z_PER_ELEM: = The element type
(OUT) scalar_array
if Z_PER_NODE: = 1D array containing scalar values
for each node.
(Array will have been allocated
Num_global_nodes long)
if Z_PER_ELEM: = 1d array containing scalar values for
each element of a particular part and type.
(Array will have been allocated
number_of_elements[which_part][which_type]
long. See USERD_get_part_build_info)
Notes:
-----
* Not called unless Num_unstructured_parts is > 0,
Num_variables is > 0, and you have some scalar type variables.
* The per_node or per_elem classification must be obtainable from the
variable number (a var_classify array needs to be retained)
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_solution_times
Description:
-----------
Get the solution times associated with each time step.
Specification:
-------------
int USERD_get_solution_times(float *solution_times)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) solution_times = 1D array of solution times/time step
(Array will have been allocated
Num_time_steps long)
Notes:
-----
* The solution times must be non-negative and increasing.
--------------------------------------------------------------------
USERD_get_variable_info
Description:
-----------
Get the variable descriptions, types and filenames
Specification:
-------------
int USERD_get_variable_info(char **var_description,
char **var_filename,
int *var_type,
int *var_classify)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) var_description = Variable descriptions
(Array will have been allocated
Num_variables by Z_BUFL long)
(OUT) var_filename = Variable filenames
(Array will have been allocated
Num_variables by Z_BUFL long)
(OUT) var_type = Variable type
(Array will have been allocated
Num_variables long)
types are: Z_CONSTANT
Z_SCALAR
Z_VECTOR
(OUT) var_classify = Variable classification
(Array will have been allocated
Num_variables long)
types are: Z_PER_NODE
Z_PER_ELEM
Notes:
-----
* The implied variable numbers apply, but be aware that the
arrays are zero based.
So for variable 1, will need to provide var_description[0]
var_filename[0]
var_type[0]
var_classify[0]
for variable 2, will need to provide var_description[1]
var_filename[1]
var_type[1]
var_classify[1]
etc.
--------------------------------------------------------------------
USERD_get_variable_value_at_specific
Description:
-----------
if Z_PER_NODE:
Get the value of a particular variable at a particular node in a
particular part at a particular time.
or if Z_PER_ELEM:
Get the value of a particular variable at a particular element of
a particular type in a particular part at a particular time.
Specification:
-------------
int USERD_get_variable_value_at_specific(int which_var,
int which_node_or_elem,
int which_part,
int which_elem_type,
int time_step,
float values[3])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) which_var = The variable number
(IN) which_node_or_elem
If Z_PER_NODE:
= The node number. This is not the id, but is
the index of the global node
list (1 based), or the block's
node list (1 based).
Thus, coord_array[1]
coord_array[2]
coord_array[3]
. |
. |which_node_or_elem index
. ----
If Z_PER_ELEM:
= The element number. This is not the id, but is
the element number index
of the number_of_element array
(see USERD_get_part_build_info),
or the block's element list
zzzzz (1 based).
Thus, for which_part:
conn_array[which_elem_type][0]
conn_array[which_elem_type][1]
conn_array[which_elem_type][2]
. |
. which_node_or_elem index
. ----
(IN) which_part
If Z_PER_NODE, or block part:
= Not used
If Z_PER_ELEM:
= The part number
(IN) which_elem_type
If Z_PER_NODE, or block part:
= Not used
If Z_PER_ELEM:
= The element type. This is the element type index
of the number_of_element array
(see USERD_get_part_build_info)
(IN) time_step = The time step
(OUT) values = scalar or vector component value(s)
values[0] = scalar or vector[0]
values[1] = vector[1]
values[2] = vector[2]
Notes:
-----
* This routine is used in node querys over time (or element querys over
time for Z_PER_ELEM variables). If these operations are not critical
to you, this can be a dummy routine.
* The per_node or per_elem classification must be obtainable from the
variable number (a var_classify array needs to be retained)
--------------------------------------------------------------------
USERD_get_vector_values
Description:
-----------
if Z_PER_NODE:
Get the values at each global node for a given vector variable.
or if Z_PER_ELEM:
Get the values at each element of a specific part and type for a
given vector variable.
Specification:
-------------
int USERD_get_vector_values(int which_vector,
int which_part,
int which_type,
float *vector_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) which_vector = The variable number
(IN) which_part
if Z_PER_NODE: Not used
if Z_PER_ELEM: = The part number
(IN) which_type
if Z_PER_NODE: Not used
if Z_PER_ELEM: = The element type
(OUT) vector_array
if Z_PER_NODE: = 1D array containing vector values
for each node.
(Array will have been allocated
3 by Num_global_nodes long)
Info stored in this fashion:
vector_array[0] = xcomp of node 1
vector_array[1] = ycomp of node 1
vector_array[2] = zcomp of node 1
vector_array[3] = xcomp of node 2
vector_array[4] = ycomp of node 2
vector_array[5] = zcomp of node 2
vector_array[6] = xcomp of node 3
vector_array[7] = ycomp of node 3
vector_array[8] = zcomp of node 3
etc.
if Z_PER_ELEM: = 1d array containing vector values for
each element of a particular part and type.
(Array will have been allocated
3 by number_of_elements[which_part][which_type]
long. See USERD_get_part_build_info)
Info stored in this fashion:
vector_array[0] = xcomp of elem 1 (of part and type)
vector_array[1] = ycomp of elem 1 "
vector_array[2] = zcomp of elem 1 "
vector_array[3] = xcomp of elem 2 "
vector_array[4] = ycomp of elem 2 "
vector_array[5] = zcomp of elem 2 "
vector_array[6] = xcomp of elem 3 "
vector_array[7] = ycomp of elem 3 "
vector_array[8] = zcomp of elem 3 "
etc.
Notes:
-----
* Not called unless Num_unstructured_parts is > 0,
Num_variables is > 0, and you have some vector type variables
* The per_node or per_elem classification must be obtainable from the
variable number (a var_classify array needs to be retained)
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_set_filenames
Description:
-----------
Receives the geometry and result filenames entered in the data
dialog. The user written code will have to store and use these
as needed.
Specification:
-------------
int USERD_set_filenames(char filename_1[],
char filename_2[],
char the_path[],
int swapbytes)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) filename_1 = the filename entered into the geometry
field of the data dialog.
(IN) filename_2 = the filename entered into the result
field of the data dialog.
(If the two_fields flag in USERD_get_name_of_reader
is FALSE, this will be null string)
(IN) the_path = the path info from the data dialog.
Note: filename_1 and filename_2 have already
had the path prepended to them. This
is provided in case it is needed for
filenames contained in one of the files
(IN) swapbytes = TRUE if should swap bytes when reading data.
Notes:
-----
* Since you must manage everything from the input that is entered in
these data dialog fields, this is an important routine!
* It may be that you will need to have an executive type file that contains
info and other filenames within it, like EnSight6's case file.
--------------------------------------------------------------------
USERD_set_time_step
Description:
-----------
Set the current time step. All functions that need time, and
that do not explicitly pass it in, will use the time step set by
this routine.
Specification:
-------------
void USERD_set_time_step(int time_step)
Returns:
-------
nothing
Arguments:
---------
(IN) time_step - The current time step to set
Notes:
-----
* Current_time_step would be set here
--------------------------------------------------------------------
USERD_stop_part_building
Description:
-----------
This routine called when the part building dialog is closed. It is
provided in case you desire to release memory, etc. that was only needed
during the part building process.
Specification:
-------------
void USERD_stop_part_building( void )
Returns:
-------
nothing
Arguments:
---------
none
Notes:
-----