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README_USERD_2.03
=================
--------------------------------------
EnSight User Defined Reader Capability ===> (API 2.03)
--------------------------------------
A user defined reader capability is included in EnSight which can allow
otherwise unsupported structured or unstructured data to be read. The user
defined reader capability utilizes dynamic shared libraries composed of
routines defined in this document but produced by you, the user, (or some
third party). This capability is currently available for dec, ibm, hp, sgi,
sun, linux, alpha linux, and NT servers.
You should refer to beginning of README_USERD_2.0 and/or README_1.0_to_2.0
for a discussion of the differences between API 1.0 and API 2.*.
***>> API 2.03 additional capabilities (beyond API 2.01):
1. Routines to handle materials
2. Routines to handle nsided and nfaced elements
3. Modified routine to handle structured ranges
****************************************************************************
Note: The dummy_gold reader, the Ensight Gold example reader, and the
SILO reader have been moved to this 2.03 API level.
****************************************************************************
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_gold library and for various other
working or sample libraries is copied from the installation CD during
installation. These will be located in directories under:
$CEI_HOME/ensight76/user_defined_src/readers
examples:
--------
Basic dummy_gold routines provide skeleton for a new reader
$CEI_HOME/ensight76/user_defined_src/readers/dummy_gold
Sample library which reads unstructured binary EnSight Gold data
$CEI_HOME/ensight76/user_defined_src/readers/ensight_gold
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. In the user-defined-reader source
tree we have tried to isolate the machine dependent parts of the
build process using a set of files in the 'config' directory. In this
directory there is a configuration file for each platform on which
EnSight is supported. Before you can compile the installed readers
you should run the script called 'init' in the config directory.
i.e. (for UNIX)
cd config
./init sgi_6.5_n64
cd ..
make
If you are compiling for Windows NT, there are two options. If you
have the Cygwin GNU utilities installed, you can use GNU make as for
Unix. Otherwise, there is a script called makeall.cmd which will
build all of the readers using nmake. The Makefiles in each reader
directory will work using either make or nmake.
i.e. (WIN32 Cygwin) (using nmake)
cd config cd config
sh init win32 cp win32 config
cd .. cd ..
mkdir lib
make makeall.cmd
If you have platform-specific portions of code in your reader, the
build system defines a set of flags which can be used within
#ifdef ... #endif regions in your source, as shown in the table
below.
Because the readers are now dynamically opened by EnSight, you may
have to include dependent libraries on your link-line to avoid having
unresolved symbols. If you are having problems with a reader, start
ensight as "ensight7 -readerdbg" and you will get feedback on any
problems encountered in loading a reader. If there are unresolved
symbols, you need to find the library which contains the missing
symbols and link it into your reader by adding it to the example
link commands below.
If you choose to use a different build environment for your reader,
you should take care to use compatible compilation flags to ensure
compatibilty with the EnSight executables, most notably on the SGI
and HP-UX 11.0 platforms, which should use the following flags:
sgi_6.2_o32: -mips2
sgi_6.2_n64: -mips4 -64
sgi_6.5_n32: -mips3
sgi_6.5_n64: -mips4 -64
hp_11.0_32: +DA2.0
hp_11.0_64: +DA2.0W
______________________________________________________________________
| MACHINE | OS flag | SHARED LIBRARY NAME PRODUCED |
| TYPE |------------------------------------------------------------|
| | LD COMMAND USED IN MAKEFILE |
======================================================================
______________________________________________________________________
| sgi | -DSGI | libuserd-X.so |
| |------------------------------------------------------------|
| | ld -shared -all -o libuserd-X.so libuserd-X.o |
----------------------------------------------------------------------
______________________________________________________________________
| hp | -DHP | libuserd-X.sl |
| |------------------------------------------------------------|
| | ld -b -o libuserd-X.sl libuserd-X.o |
----------------------------------------------------------------------
______________________________________________________________________
| sun | -DSUN | libuserd-X.so |
| |------------------------------------------------------------|
| | ld -G -o libuserd-X.so libuserd-X.o |
----------------------------------------------------------------------
______________________________________________________________________
| dec | -DDEC | libuserd-X.so |
| |------------------------------------------------------------|
| | ld -shared -all -o libuserd-X.so libuserd-X.o -lc |
----------------------------------------------------------------------
______________________________________________________________________
| linux | -DLINUX | libuserd-X.so |
| |------------------------------------------------------------|
| | ld -shared -o libuserd-X.so libuserd-X.o -lc |
----------------------------------------------------------------------
______________________________________________________________________
| alpha | -DALINUX | libuserd-X.so |
| linux |------------------------------------------------------------|
| | ld -shared -o libuserd-X.so libuserd-X.o -lc |
----------------------------------------------------------------------
______________________________________________________________________
| ibm | -DIBM | libuserd-X.so |
| |------------------------------------------------------------|
| | ld -G -o libuserd-X.so libuserd-X.o -bnoentry -bexpall -lc |
----------------------------------------------------------------------
Once you have created your library, you should place it in a directory
of your choice or in the standard reader location:
$CEI_HOME/ensight76/machines/$CEI_ARCH/lib_readers
For example, if you created a reader for "mydata", you should create
the reader libuserd-mydata.so and place the file in your own reader
directory (see section 3 below) or in the standard location:
$CEI_HOME/ensight76/machines/$CEI_ARCH/lib_readers/libuserd-mydata.so
3. By default EnSight will load all readers found in the directory:
$CEI_HOME/ensight76/machines/$CEI_ARCH/lib_readers
Files with names "libuserd-X.so" (where X is a name unique to the reader)
are assumed to be user-defined readers.
There are two methods which can be used to supplement the default
behavior.
(1) A feature which is useful for site-level or user-level configuration
is the optional environment variable $ENSIGHT7_READER. This
variable directs EnSight to load all readers in the specified reader
directory (you should probably specify a full path) before loading
the built-in readers. If the same reader exists in both directories
(as determined by the name returned by USERD_get_name_of_reader(),
NOT by the filename), the locally configured reader will take
precedence.
(2) A useful feature for end-users is the use of the libuserd-devel
reader. EnSight will search for a reader named libuserd-devel.so
(.sl for HP or .dll for NT). This reader can exist anywhere in the
library path (see below) of the user. This is useful for an
individual actively developing a reader because the existence of a
libuserd-devel library will take precedence over any other library
which returns the same name from USERD_get_name_of_reader().
As an example, a site may install commonly used readers in a common
location, and users can set the ENSIGHT7_READER variable to access them:
setenv ENSIGHT7_READER /usr/local/lib/e7readers
A user working on a new reader may compile the reader and place it in
a directory specified by the library path:
cp libuserd-myreader.so ~/lib/libuserd-devel.so
setenv <librarypath> ~/lib:$<librarypath>
The user is responsible for correctly configuring the library path
variable in order to make use of the libuserd-devel feature. The
library environment variables used are:
Machine type Environment variable to set
------------ ---------------------------
sgi LD_LIBRARY_PATH
dec LD_LIBRARY_PATH
sun LD_LIBRARY_PATH
linux LD_LIBRARY_PATH
alpha linux LD_LIBRARY_PATH
hp SHLIB_PATH
ibm LIBPATH
As always, EnSight support is available if you need it.
-------------------------------
Quick Index of Library Routines
-------------------------------
Generally Needed for UNSTRUCTURED data
--------------------------------------
USERD_get_part_coords part's node coordinates
USERD_get_part_node_ids part's node ids
USERD_get_part_elements_by_type part's element connectivites
USERD_get_part_element_ids_by_type part's element ids
Generally Needed for BLOCK data
--------------------------------------
USERD_get_block_coords_by_component block coordinates
USERD_get_block_iblanking block iblanking values
USERD_get_ghosts_in_block_flag block ghost cell existence?
USERD_get_block_ghost_flags block ghost cell flags
These routines, which formerly were only for unstructured data, will now
also be called for structured data if you specify that ids will be given
in the USERD_get_node_label_status and USERD_get_element_label_status rotuines
------------------------------------------------------------------------------
USERD_get_part_node_ids part's node ids
USERD_get_part_element_ids_by_type part's element ids
Generally needed for either or both kinds of data
-------------------------------------------------
USERD_get_name_of_reader name of reader for GUI
USERD_get_reader_version provide reader version number
USERD_get_reader_descrip provide GUI more description (optional)
USERD_set_filenames filenames entered in GUI
USERD_set_server_number server which of how many
USERD_get_number_of_timesets number of timesets
USERD_get_timeset_description description of timeset
USERD_get_geom_timeset_number timeset # to use for geom
USERD_get_num_of_time_steps number of time steps
USERD_get_sol_times solution time values
USERD_set_time_set_and_step current timeset and time step
USERD_get_gold_part_build_info Gets the info needed for part building process
USERD_get_changing_geometry_status changing geometry?
USERD_get_node_label_status node labels?
USERD_get_element_label_status element labels?
USERD_get_model_extents provide model bounding extents
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_descrip_lines file associated description lines
USERD_get_number_of_model_parts number of model parts
USERD_get_part_build_info part/block type/descrip etc.
USERD_get_maxsize_info part/block allocation maximums
USERD_get_ghosts_in_model_flag model contains ghost cells?
USERD_get_nsided_conn Gets the element connectivities for nsided
elements. (utilizes the number of nodes
per element obtained in
USERD_get_part_elements_by_type)
USERD_get_nfaced_nodes_per_face Gets the number of nodes per face for nfaced
elements (utilizes the number of faces
per element obtained in
USERD_get_part_elements_by_type)
USERD_get_nfaced_conn Gets the element connectivities for nfaced
elements (utilizes the number of nodes
per face obtained in
USERD_get_nfaced_nodes_per_face)
USERD_get_border_availability part border provided?
USERD_get_border_elements_by_type part border conn and parent info
USERD_get_number_of_variables number of variables
USERD_get_gold_variable_info variable type/descrip etc.
USERD_get_var_by_component part or block variable values
USERD_get_constant_val constant variable's value
USERD_get_var_value_at_specific node's or element's variable value over time
USERD_stop_part_building cleanup after part build routine
USERD_get_number_of_material_sets Gets the number of material sets
USERD_get_matf_set_info Gets the material set indices and names
USERD_get_number_of_materials Gets the number of materials
USERD_get_matf_var_info Gets the material indices and descriptions
USERD_size_matf_data Gets the length of either the
material ids list,
mixed-material ids list, or
mixed-material values list
USERD_load_matf_data Gets the material ids list,
mixed-material ids list, or
mixed-material values list
USERD_bkup archive routine
USERD_exit_routine cleanup upon exit 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
USERD_get_reader_descrip (optional)
2. Getting the reader version (also distinguishes between API's)
USERD_get_reader_version
3. Setting filenames and getting timeset and time info
USERD_set_server_number
USERD_set_filenames
USERD_get_number_of_timesets
USERD_get_geom_timeset_number
for each timeset:
USERD_get_timeset_description
USERD_get_num_of_time_steps
USERD_get_sol_times
USERD_set_time_set_and_step
4. Gathering info for part builder
USERD_set_time_set_and_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_descrip_lines (for geometry)
USERD_get_number_of_model_parts
USERD_get_gold_part_build_info
USERD_get_ghosts_in_model_flag
USERD_get_maxsize_info
USERD_get_get_ghosts_in_block_flag (if any ghost cells in model)
USERD_get_model_extents OR (for model extents)
USERD_get_part_coords AND/OR
USERD_get_block_coords_by_component
5. Gathering Variable info
USERD_get_number_of_variables
USERD_get_gold_variable_info
6. Part building (per part created)
both unstructured and structured:
--------------------------------
USERD_set_time_set_and_step
if unstructured part:
--------------------
USERD_get_part_element_ids_by_type
USERD_get_part_elements_by_type
If any nsided elements:
USERD_get_nsided_conn
If any nfaced elements:
USERD_get_nfaced_nodes_per_face
USERD_get_nfaced_conn
USERD_get_part_coords
USERD_get_part_node_ids
else if structured part:
-----------------------
USERD_get_block_iblanking
USERD_get_block_coords_by_component
USERD_get_block_ghost_flags (If ghost cells in part)
USERD_get_part_node_ids (If node ids given)
USERD_get_part_element_ids_by_type (If element ids given)
both again:
----------
USERD_get_border_availability (If border representation
USERD_get_border_elements_by_type is selected)
USERD_stop_part_building (only once when part builder
dialog is closed)
7. Loading Variables
constants:
---------
USERD_set_time_set_and_step
USERD_get_constant_val
scalars/vectors/tensors:
------------------------
USERD_get_descrip_lines
USERD_set_time_set_and_step
USERD_get_var_by_component
8. Changing geometry
changing coords only (per part):
--------------------
USERD_set_time_set_and_step
USERD_get_descrip_lines
USERD_get_part_coords
USERD_get_block_coords_by_component
changing connectivity (per part):
---------------------
USERD_set_time_set_and_step
USERD_get_descrip_lines
USERD_get_number_of_model_parts
USERD_get_gold_part_build_info
USERD_get_ghosts_in_model_flag
USERD_get_get_ghosts_in_block_flag (if any ghost cells in model)
USERD_get_model_extents OR
USERD_get_part_coords AND/OR
USERD_get_block_coords_by_component
USERD_get_part_element_ids_by_type
USERD_get_part_elements_by_type
USERD_get_part_coords
USERD_get_part_node_ids
USERD_get_block_iblanking
USERD_get_block_coords_by_component
USERD_get_block_ghost_flags (If ghost cells in part)
USERD_get_part_node_ids (If node ids given)
USERD_get_part_element_ids_by_type (If element ids given)
USERD_get_border_availability (If border representation
USERD_get_border_elements_by_type is selected)
9. Node or Element queries over time
USERD_get_var_value_at_specific
10. To see if materials in the model
USERD_get_number_of_material_sets
USERD_get_matf_set_info
If any material sets in the model (calls these once per material set):
USERD_get_number_of_materials
USERD_get_matf_var_info
For each elment type of each part containing material ids, calls:
USERD_size_matf_data
USERD_load_matf_data
If there are any elements with mixed materials, when a domain or
interface is created, calls these again per part:
USERD_size_matf_data
USERD_load_matf_data
-----------------------
Detailed Specifications
-----------------------
Include files:
--------------
The following header file is required in any file containing these library
routines.
#include "global_extern.h"
And it references:
#include "global_extern_proto.h"
*******************************************************************************
****************************** Special Note ***********************************
*******************************************************************************
Make sure you use the proper define in the global_extern.h header file, namely:
#define USERD_API_203
Also, Make sure the api version in the USERD_get_reader_version routine is set
to "2.03" or larger.
Make sure your reader has access to the global_extern_proto.h This is a new
file which is accessed from the new 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_timesets = 1;
static int Current_timeset = 1;
static int Geom_timeset_number = 1;
static int Num_time_steps[Z_MAXSETS] = 1;
static int Current_time_step = 0;
static int Num_variables = 0;
static int Num_dataset_files = 0;
static int Server_Number = 1; Which server of
static int Tot_Servers = 1; the total number of servers
_________________________________________
-----------------------------------------
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_exit_routine
Description:
-----------
This routine is called as EnSight is exiting. It can be used to clean
up anything needed - such as removing temporary files, etc. - or can simply
be a dummy.
Specification:
-------------
void USERD_exit_routine( void )
Arguments:
---------
none
--------------------------------------------------------------------
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
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(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
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(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_ghost_flags
Description:
-----------
Get the ghost_flags value at each element of a block containing ghost cells.
Specification:
-------------
int USERD_get_block_ghost_flags(int block_number,
int *ghost_flags)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) block_number = The block number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(OUT) ghost_flags = 1D array containing ghost flag value
for each block cell.
(Array will have been allocated
(i-1)*(j-1)*(k-1) for the block long)
possible values are: 0 = non-ghost cell (normal cell)
>0 = ghost cell
Notes:
-----
* This routine is new in the 2.01 API
* This will be based on Current_time_step
* Only called for structured "block" parts that have some ghost cells
as indicated by the USERD_get_ghost_in_block_flag. The model must
of course also have been indicated to have some ghost cells in the
USERD_get_ghost_in_model_flag routine.
* It is sufficient to set the value to be 1 to flag as a ghost cell,
but the value can be any non-zero value, so you could use it to
indicate which block or which server (for Server-of-server use) the
cell is actually in.
--------------------------------------------------------------------
USERD_get_border_availability
Description:
-----------
Finds out if border elements are provided by the reader for the
desired part, or will need to be computed internally by EnSight.
Specification:
-------------
int USERD_get_border_availability(int part_number,
int number_of_elements[Z_MAXTYPE])
Returns:
-------
Z_OK if border elements will be provided by the reader.
(number_of_elements array will be loaded and
USERD_get_border_elements_by_type will be called)
Z_ERR if border elements are not available - thus EnSight must compute.
(USERD_get_border_elements_by_type will not be called)
Arguments:
---------
(IN) part_number = The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(OUT) number_of_elements = 2D array containing number of
each type of border element in
the 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
Notes:
-----
* Only called if border representation is used.
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_border_elements_by_type
Description:
-----------
Provides border element connectivity and parent information.
Specification:
-------------
int USERD_get_border_elements_by_type(int part_number,
int element_type,
int **conn_array,
short *parent_element_type,
int *parent_element_num)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(IN) element_type = One of the following (See global_extern.h)
Z_POINT node point element
Z_BAR02 2 node bar
Z_BAR03 3 node bar
Z_TRI03 3 node triangle
Z_TRI06 6 node triangle
Z_QUA04 4 node quad
Z_QUA08 8 node quad
(OUT) conn_array = 2D array containing connectivity
of each border element of the type.
(Array will have been allocated
num_of_elements of the type by
connectivity length of the type)
ex) If number_of_elements[Z_TRI03] = 25
number_of_elements[Z_QUA04] = 100
number_of_elements[Z_QUA08] = 30
as obtained in:
USERD_get_border_availability
Then the allocated dimensions available
for this routine will be:
conn_array[25][3] when called with Z_TRI03
conn_array[100][4] when called with Z_QUA04
conn_array[30][8] when called with Z_QUA08
(OUT) parent_element_type = 1D array containing element type of the
parent element (the one that the border
element is a face/edge of).
(Array will have been allocated
num_of_elements of the type long)
(OUT) parent_element_num = 1D array containing element number of the
parent element (the one that the border
element is a face/edge of).
(Array will have been allocated
num_of_elements of the type long)
Notes:
-----
* Not called unless USERD_get_border_availability returned Z_OK
* 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. Note that
a part is allowed to be empty (number of nodes and elements equal
to zero).
--------------------------------------------------------------------
USERD_get_constant_val
Description:
-----------
Get the value of a constant at a time step
Specification:
-------------
float USERD_get_constant_value(int which_var,
int imag_data)
Returns:
-------
Value of the requested constant variable
Arguments:
---------
(IN) which_var = The variable number
(IN) imag_data = TRUE if want imaginary data value.
FALSE if want real data value.
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) (Is a long)
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_MAXFILENP is the allocated length of
each line)
Notes:
-----
* If Num_dataset_files is 0, this routine will not be called.
(See USERD_get_number_of_files_in_dataset)
--------------------------------------------------------------------
USERD_get_descrip_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_descrip_lines(int which_type,
int which_var,
int imag_data,
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.
(IN) imag_data = TRUE if want imaginary data file.
FALSE if want real data file.
(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_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.
* Prior to API 2.01:
-----------------
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.
API 1.0:
USERD_get_element_ids_for_part is used to obtain the ids,
on a part by part basis, if TRUE status is returned here.
API 2.0:
USERD_get_part_element_ids_by_type is used to obtain the ids,
on a per part, per type 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!!
* Starting at API 2.01:
--------------------
For both unstructured and structured 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 (especially
if you are dealing with a decomposed dataset).
USERD_get_part_element_ids_by_type is used to obtain the ids,
on an element type by part basis, if TRUE status is returned here.
* Will call USERD_get_part_element_ids_by_type for each type of
of each part if this routine returns TRUE.
--------------------------------------------------------------------
USERD_get_geom_timeset_number -
Description:
-----------
Gets the timeset number to be used for geometry
Specification:
-------------
int USERD_get_geom_timeset_number( void )
Returns:
-------
Geom_timeset_number = The timeset number that will be used for geometry.
For example, if USERD_get_number_of timesets
returns 2, the valid timeset numbers would be
1 or 2.
Arguments:
---------
none
Notes:
-----
* If your model is static, which you indicated by returning a zero
in USERD_get_number_of_timesets, you can return a zero here as well.
--------------------------------------------------------------------
USERD_get_gold_part_build_info
Description:
-----------
Gets the info needed for the part building process.
Specification:
-------------
int USERD_get_gold_part_build_info(int *part_id,
int *part_types,
char *part_description[Z_BUFL],
int *number_of_nodes,
int *number_of_elements[Z_MAXTYPE],
int *ijk_dimensions[9],
int *iblanking_options[6])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) part_id = Array containing the external part
ids for each of the model parts.
IMPORTANT:
Parts numbers must be >= 1, because
of the way they are used in the GUI
*******************************************
The ids provided here are the numbers by
which the parts will be referred to in the
GUI (if possible). They are basically
labels as far as you are concerned.
Note: The part numbers you pass to routines
which receive a part_number or block_number
or which_part as an argument are the 1-based
table index of the parts!
example: If Numparts_available = 3
Table index part_id
----------- -------
1 13
2 57
3 125
^ ^
| |
| These are placed in:
| part_id[0] = 13
| part_id[1] = 57
| part_id[2] = 125
| for GUI labeling purposes.
|
These implied table indices are the part_number,
block_number, or which_part numbers that you would
pass to routines like:
USERD_get_part_coords(int part_number,...
USERD_get_part_node_ids(int part_number,...
USERD_get_part_elements_by_type(int part_number,...
USERD_get_part_element_ids_by_type(int part_number,...
USERD_get_block_coords_by_component(int block_number,...
USERD_get_block_iblanking(int block_number,...
USERD_get_block_ghost_flags(int block_number,...
USERD_get_ghosts_in_block_flag(int block_number)
USERD_get_border_availability(int part_number,...
USERD_get_border_elements_by_type(int part_number,...
USERD_get_var_by_component(int which_variable,
int which_part,...
USERD_get_var_value_at_specific(int which_var,
int which_node_or_elem,
int which_part,...
********************************************
(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_nodes = Number of unstructured nodes in the part
(Array will have been allocated
Numparts_available 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
Z_G_POINT = ghost node point element
Z_G_BAR02 = 2 node ghost bar
Z_G_BAR03 = 3 node ghost bar
Z_G_TRI03 = 3 node ghost triangle
Z_G_TRI06 = 6 node ghost triangle
Z_G_QUA04 = 4 node ghost quad
Z_G_QUA08 = 8 node ghost quad
Z_G_TET04 = 4 node ghost tetrahedron
Z_G_TET10 = 10 node ghost tetrahedron
Z_G_PYR05 = 5 node ghost pyramid
Z_G_PYR13 = 13 node ghost pyramid
Z_G_PEN06 = 6 node ghost pentahedron
Z_G_PEN15 = 15 node ghost pentahedron
Z_G_HEX08 = 8 node ghost hexahedron
Z_G_HEX20 = 20 node ghost hexahedron
(Ignored unless Z_UNSTRUCTURED type)
(Array will have been allocated
Numparts_available by
Z_MAXTYPE long)
(OUT) ijk_dimensions = 2D array containing ijk dimension info
for structured blocks
For Z_UNSTRUCTURED - is ignored
For Z_STRUCTURED or Z_IBLANKED
Prior to version 2.03:
----------------------
(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
Starting at version 2.03:
------------------------
(Array will have been allocated
Numparts_available by 9 long)
There are two ways to do this:
------------------------------
1. The simple one, without ranges.
This is good for all structured models
that will NOT be used in EnSight's
Server of Servers
Simply provide the ijk dimensions in the
first three slots and place a -1 in
the 4th slot. (The remaining slots will
be ignored).
Thus,
ijk_dimensions[][0] = I dimension of block
ijk_dimensions[][1] = J dimension of block
ijk_dimensions[][2] = K dimension of block
ijk_dimensions[][3] = -1
(J planes)
4 *-------*-------*
| | | ijk_dimension[0][0] = 3
| | | ijk_dimension[0][1] = 4
| | | ijk_dimension[0][2] = 1
3 *-------*-------*
| | | ijk_dimension[0][4] = -1
| | |
| | |
2 *-------*-------*
| | |
| | |
| | |
1 *-------*-------*
1 2 3 (I planes)
2. Using ranges.
This one can be used anytime, but MUST
be used if EnSight's Server of Servers
is to be used!
The first 3 slots contain the ijk dimension
of the complete block (of which this may be
a portion). The last 6 slots contain the
ijk min and max ranges within the complete.
Thus,
ijk_dimensions[][0] = I dim of complete block
ijk_dimensions[][1] = J dim of complete block
ijk_dimensions[][2] = K dim of complete block
ijk_dimensions[][3] = Imin of portion (1-based)
ijk_dimensions[][4] = Imax of portion (1-based)
ijk_dimensions[][5] = Jmin of portion (1-based)
ijk_dimensions[][6] = Jmax of portion (1-based)
ijk_dimensions[][7] = Kmin of portion (1-based)
ijk_dimensions[][8] = Kmax of portion (1-based)
example1: (Model has one part, a simple 2D block,
and want whole thing)
(J planes)
4 *-------*-------*
| | | ijk_dimension[0][0] = 3
| | | ijk_dimension[0][1] = 4
| | | ijk_dimension[0][2] = 1
3 *-------*-------*
| | | ijk_dimension[0][3] = 1
| | | ijk_dimension[0][4] = 3
| | | ijk_dimension[0][5] = 1
2 *-------*-------* ijk_dimension[0][6] = 4
| | | ijk_dimension[0][7] = 1
| | | ijk_dimension[0][8] = 1
| | |
1 *-------*-------*
1 2 3 (I planes)
example2: (Want to have the block represented
in two portions - 2 parts)
(J planes) top portion
4 *-------*-------*
| | | ijk_dimension[0][0] = 3
| | | ijk_dimension[0][1] = 4
| | | ijk_dimension[0][2] = 1
3 *-------*-------*
. . . ijk_dimension[0][3] = 1
. . . ijk_dimension[0][4] = 3
. . . ijk_dimension[0][5] = 3
2 ................. ijk_dimension[0][6] = 4
. . . ijk_dimension[0][7] = 1
. . . ijk_dimension[0][8] = 1
. . .
1 .................
1 2 3 (I planes)
(J planes) bottom portion
4 .................
. . . ijk_dimension[1][0] = 3
. . . ijk_dimension[2][1] = 4
. . . ijk_dimension[3][2] = 1
3 *-------*-------*
| | | ijk_dimension[1][3] = 1
| | | ijk_dimension[1][4] = 3
| | | ijk_dimension[1][5] = 1
2 *-------*-------* ijk_dimension[1][6] = 3
| | | ijk_dimension[1][7] = 1
| | | ijk_dimension[1][8] = 1
| | |
1 *-------*-------*
1 2 3 (I planes)
And note that if you were partioning this block for
EnSight's Server of Servers, you would only have one part,
instead of two. Each SOS server would return its appropriate
ranges in the last 6 slots. The first 3 slots would remain constant.
(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_gold_variable_info
Description:
-----------
Get the variable descriptions, types and filenames
Specification:
-------------
int USERD_get_gold_variable_info(char **var_description,
char **var_filename,
int *var_type,
int *var_classify,
int *var_complex,
char **var_ifilename,
float *var_freq,
int *var_contran,
int *var_timeset)
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)
variable description restrictions:
----------------------------------
1. Only first 19 characters used in EnSight.
2. Leading and trailing whitespace will be removed by EnSight.
3. Illegal characters will be replaced by underscores.
4. Thay may not start with a numeric digit.
4. No two variables may have the same description.
(OUT) var_filename = Variable real 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
Z_TENSOR
Z_TENSOR9
(OUT) var_classify = Variable classification
(Array will have been allocated
Num_variables long)
types are: Z_PER_NODE
Z_PER_ELEM
(OUT) var_complex = TRUE if complex, FALSE otherwise
(Array will have been allocated
Num_variables long)
(OUT) var_ifilename = Variable imaginary filenames (if complex)
(Array will have been allocated
Num_variables by Z_BUFL long)
(OUT) var_freq = complex frequency (if complex)
(Array will have been allocated
Num_variables long)
(OUT) var_contran = TRUE if constant changes per time step
FALSE if constant truly same at all time steps
(Array will have been allocated
Num_variables long)
(OUT) var_timeset = Timeset the variable will use (1 based).
(For static models, set it to 1)
(Array will have been allocated
Num_variables long)
For example: If USERD_get_number_of_timesets
returns 2, the valid
timeset_number's would be 1 or 2
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]
var_complex[0]
var_ifilename[0]
var_freq[0]
var_contran[0]
var_timeset[0]
for variable 2, will need to provide var_description[1]
var_filename[1]
var_type[1]
var_classify[1]
var_complex[1]
var_ifilename[1]
var_freq[1]
var_contran[1]
var_timeset[1]
etc.
--------------------------------------------------------------------
USERD_get_ghosts_in_block_flag
Description:
-----------
Gets whether ghost cells present in block or not
Specification:
-------------
int USERD_get_ghosts_in_block_flag(int block_number)
Returns:
-------
TRUE if any ghost cells in this structured part
FALSE if no ghost cells in this structured part
Arguments:
---------
(IN) block_number = The block part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
Notes:
-----
* This routine is new in the 2.01 API
* This will be based on Current_time_step
* Intended for structured parts only, value will be ignored for
unstructured parts
--------------------------------------------------------------------
USERD_get_ghosts_in_model_flag
Description:
-----------
Answers the question as to whether any ghost cells in the model.
Specification:
-------------
int USERD_get_ghosts_in_model_flag( void )
Returns:
-------
TRUE if any ghost cells in the model
FALSE if no ghost cells in the model
Arguments:
---------
Notes:
-----
* This routine is new in the 2.01 API
-------------------------------------------------------------------------
USERD_get_matf_set_info
Description:
-----------
Get the material set ids and names
Specification:
-------------
int USERD_get_matf_set_info(int *mat_set_ids,
char **mat_set_name)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) mat_set_ids = 1D material set ids array
(Array will have been allocated
Num_material_sets long)
(OUT) mat_set_name = 2D material set name array
(Array will have been allocated
Num_material_sets by Z_BUFL long)
Notes:
-----
* Will not be called if Num_material_sets is zero
* See USERD_get_number_of_material_sets header for explanatory example
--------------------------------------------------------------------
USERD_get_matf_var_info
Description:
-----------
Gets the material ids and descriptions for the material set
Specification:
-------------
int USERD_get_matf_var_info(int set_index,
int *mat_ids,
char **mat_desc)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) set_index = the material set index (zero based)
(OUT) mat_ids[set_index] = 1D integer array containing the material
ids to associated with each material
(Array will have been allocated
Num_materials[set_index] long)
(OUT) mat_desc[set_index] = 2D char array containing the material
descriptions to associated with each material
(Array will have been allocated
Num_materials[set_index] by Z_BUFL long)
Notes:
-----
* See USERD_get_number_of_material_sets header for explanatory example
* Will not be called if Num_material_sets is zero, or
Num_materials[set_index] is zero
--------------------------------------------------------------------
USERD_get_maxsize_info
Description:
-----------
Gets maximum part sizes for efficient memory allocation.
Transient models (especially those that increase in size) can cause
reallocations, at time step changes, to keep chewing up more and
more memory. The way to avoid this is to know what the maximum
size of such memory will be, and allocate for this maximum initially.
Accordingly, if you choose to provide this information (it is optional),
EnSight will take advantage of it.
Specification:
-------------
int USERD_get_maxsize_info(int *max_number_of_nodes,
int *max_number_of_elements[Z_MAXTYPE],
int *max_ijk_dimensions[3])
Returns:
-------
Z_OK if supplying maximum data
Z_ERR if not supplying maximum data, or some error occurred
while trying to obtain it.
Arguments:
---------
(OUT) max_number_of_nodes = Maximum number of unstructured nodes
in the part (over all time).
(Array will have been allocated
Numparts_available long)
(OUT) max_number_of_elements = 2D array containing maximum number of
each type of element for each
unstructured model part (over all time).
------------
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
Z_G_POINT = ghost node point element
Z_G_BAR02 = 2 node ghost bar
Z_G_BAR03 = 3 node ghost bar
Z_G_TRI03 = 3 node ghost triangle
Z_G_TRI06 = 6 node ghost triangle
Z_G_QUA04 = 4 node ghost quad
Z_G_QUA08 = 8 node ghost quad
Z_G_TET04 = 4 node ghost tetrahedron
Z_G_TET10 = 10 node ghost tetrahedron
Z_G_PYR05 = 5 node ghost pyramid
Z_G_PYR13 = 13 node ghost pyramid
Z_G_PEN06 = 6 node ghost pentahedron
Z_G_PEN15 = 15 node ghost pentahedron
Z_G_HEX08 = 8 node ghost hexahedron
Z_G_HEX20 = 20 node ghost hexahedron
(Ignored unless Z_UNSTRUCTURED type)
(Array will have been allocated
Numparts_available by
Z_MAXTYPE long)
(OUT) max_ijk_dimensions = 2D array containing maximum ijk dimensions
for each structured model part (over all time).
----------
(Ignored if Z_UNSTRUCTURED type)
(Array will have been allocated
Numparts_available by 3 long)
max_ijk_dimensions[][0] = maximum I dimension
max_ijk_dimensions[][1] = maximum J dimension
max_ijk_dimensions[][2] = maximum K dimension
Notes:
-----
* You need to have first called USERD_get_number_of_model_parts and
USERD_get_gold_part_build_info, so Numparts_available is known and
so EnSight will know what the type is (Z_UNSTRUCTURED, Z_STRUCTURED,
or Z_IBLANKED) of each part.
* This will NOT be based on Current_time_step - it is to be the maximum
values over all time!!
* This information is optional. If you return Z_ERR, Ensight will still
process things fine, reallocating as needed, etc. However, for
large transient models you will likely use considerably more memory
and take more processing time for the memory reallocations. So, if it
is possible to provide this information "up front", it is recommended
to do so.
--------------------------------------------------------------------
USERD_get_model_extents
Description:
-----------
Gets the model bounding box extents. If this routine supplys them
EnSight will not have to spend time doing so. If this routine
returns Z_ERR, EnSight will have to take the time to touch all the
nodes and gather the extent info.
Specification:
-------------
int USERD_get_model_extents(float extents[6])
Returns:
-------
Z_OK if successful
Z_ERR if not successful (whereupon EnSight will determine by reading
all coords of all parts)
Arguments:
---------
(OUT) extents[0] = min x
[1] = max x
[2] = min y
[3] = max y
[4] = min z
[5] = max z
Notes:
-----
* This 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. Please be sure to provide a name for your custom
reader format.
--------------------------------------------------------------------
USERD_get_nfaced_conn
Description:
-----------
Gets the array containing the connectivity of nsided faces of nfaced elements
Specification:
-------------int
int USERD_get_nfaced_conn(int part_number,
int *nfaced_conn_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = the part number
(OUT) nfaced_conn_array = 1D array of nsided face connectivies of nfaced
elements
(int array will have been allocated long enough to
hold all the nsided face connectivities. Which is
the sum of all the nodes per face values in the
nfaced_npf_array of USERD_get_nfaced_nodes_per_face)
Notes:
-----
* Will not be called unless there are some nfaced elements in the part
* Providing nfaced information to Ensight:
1. In USERD_get_gold_part_build_info, provide the number of nfaced
polyhedral elements in the part.
2. In USERD_get_part_elements_by_type, provide (in the conn_array),
the number of faces per nfaced element. (as if connectivity
length of an nfaced element is one)
3. In this routine, provide the streamed number of nodes per face
for each of the faces of the nfaced elements.
Simple example: 11 10 12
+--------+-----+
2 nfaced elements: /| |\ /|
(1 7-faced / | | \ / |
1 5-sided) / | | +9 |
/ | | /| |
/7 | 8 / | |
+-----------+/ | | |
| |5 | |4 | |6
| +-----|--+--|--+
| / | \ | /
| / | \|/3
| / | +
| / | /
|/1 |2 /
+-----------+/
1. In USERD_get_gold_part_build_info:
number_of_elements[Z_NFACED] = 2
.
/|\
|
2. In USERD_get_part_elements_by_type:
length of conn_array will be: 2 x 1
for element_type of Z_NFACED:
conn_array[0][0] = 7 (for the 7-faced element)
conn_array[1][0] = 5 (for the 5-faced element)
==
Sum 12 <---------+
|
3. In USERD_get_faced_nodes_per_face: |
length of nfaced_npf_array will be: 12
nfaced_npf_array[0] = 5 (5-noded top face of 7-faced element)
nfaced_npf_array[1] = 5 (5-noded bot face of 7-faced element)
nfaced_npf_array[2] = 4 (4-noded front face of 7-faced element)
nfaced_npf_array[3] = 4 (4-noded left face of 7-faced element)
nfaced_npf_array[4] = 4 (4-noded back face of 7-faced element)
nfaced_npf_array[5] = 4 (4-noded right front face of 7-faced element)
nfaced_npf_array[6] = 4 (4-noded right back face of 7-faced element)
nfaced_npf_array[7] = 3 (3-noded top face of 5-faced element)
nfaced_npf_array[8] = 3 (3-noded bot face of 5-faced element)
nfaced_npf_array[9] = 4 (4-noded back face of 5-faced element)
nfaced_npf_array[10] = 4 (4-noded right face of 5-faced element)
nfaced_npf_array[11] = 4 (4-noded left front face of 5-faced element)
==
Sum 48 <-------------+
|
4. In this function: |
length of the nfaced_conn_array will be: 48
nsided_conn_array[0] = 7 (conn of 5-noded top face of 7-faced elem)
nsided_conn_array[1] = 8
nsided_conn_array[2] = 9
nsided_conn_array[3] = 10
nsided_conn_array[4] = 11
nsided_conn_array[5] = 1 (conn of 5-noded bot face of 7-faced elem)
nsided_conn_array[6] = 5
nsided_conn_array[7] = 4
nsided_conn_array[8] = 3
nsided_conn_array[9] = 2
nsided_conn_array[10] = 1 (conn of 4-noded front face of 7-faced elem)
nsided_conn_array[11] = 2
nsided_conn_array[12] = 8
nsided_conn_array[13] = 7
nsided_conn_array[14] = 5 (conn of 4-noded left face of 7-faced elem)
nsided_conn_array[15] = 1
nsided_conn_array[16] = 7
nsided_conn_array[17] = 11
nsided_conn_array[18] = 4 (conn of 4-noded back face of 7-faced elem)
nsided_conn_array[19] = 5
nsided_conn_array[20] = 11
nsided_conn_array[21] = 10
nsided_conn_array[22] = 2 (conn of 4-noded right front face of 7-faced)
nsided_conn_array[23] = 3
nsided_conn_array[24] = 9
nsided_conn_array[25] = 8
nsided_conn_array[26] = 3 (conn of 4-noded right back face of 7-faced)
nsided_conn_array[27] = 4
nsided_conn_array[28] = 10
nsided_conn_array[29] = 9
nsided_conn_array[30] = 9 (conn of 3-noded top face of 5-faced elem)
nsided_conn_array[32] = 12
nsided_conn_array[32] = 10
nsided_conn_array[33] = 3 (conn of 3-noded bot face of 5-faced elem)
nsided_conn_array[34] = 4
nsided_conn_array[35] = 6
nsided_conn_array[36] = 6 (conn of 4-noded back face of 5-faced elem)
nsided_conn_array[37] = 4
nsided_conn_array[38] = 10
nsided_conn_array[39] = 12
nsided_conn_array[40] = 3 (conn of 4-noded right face of 5-faced elem)
nsided_conn_array[41] = 6
nsided_conn_array[42] = 12
nsided_conn_array[43] = 9
nsided_conn_array[44] = 4 (conn of 4-noded left front face of 5-faced)
nsided_conn_array[45] = 3
nsided_conn_array[46] = 9
nsided_conn_array[47] = 10
--------------------------------------------------------------------
USERD_get_nfaced_nodes_per_face -
Description:
-----------
Gets the array containing the number of nodes per face for each face
of the nfaced elements.
Specification:
-------------
int USERD_get_nfaced_nodes_per_face(int part_number,
int *nfaced_npf_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = the part number
(OUT) nfaced_npf_array = 1D array of nodes per face for all faces of
nfaced elements
(int array will have been allocated long enough
to hold all the nodes_per_face values. Which is
the sum of all the number of faces per element
values in the conn_array of
USERD_get_part_elements_by_type)
Notes:
-----
* Will not be called unless there are some nfaced elements in the
the part
* Providing nfaced information to Ensight:
1. In USERD_get_gold_part_build_info, provide the number of nfaced
polyhedral elements in the part.
2. In USERD_get_part_elements_by_type, provide (in the conn_array),
the number of faces per nfaced element. (as if connectivity
length of an nfaced element is one)
3. In this routine, provide the streamed number of nodes per face
for each of the faces of the nfaced elements.
Simple example: 11 10 12
+--------+-----+
2 nfaced elements: /| |\ /|
(1 7-faced / | | \ / |
1 5-sided) / | | +9 |
/ | | /| |
/7 | 8 / | |
+-----------+/ | | |
| |5 | |4 | |6
| +-----|--+--|--+
| / | \ | /
| / | \|/3
| / | +
| / | /
|/1 |2 /
+-----------+/
1. In USERD_get_gold_part_build_info:
number_of_elements[Z_NFACED] = 2
.
/|\
|
2. In USERD_get_part_elements_by_type:
length of conn_array will be: 2 x 1
for element_type of Z_NFACED:
conn_array[0][0] = 7 (for the 7-faced element)
conn_array[1][0] = 5 (for the 5-faced element)
==
Sum 12 <---------+
|
3. In this routine: |
length of nfaced_npf_array will be: 12
nfaced_npf_array[0] = 5 (5-noded top face of 7-faced element)
nfaced_npf_array[1] = 5 (5-noded bot face of 7-faced element)
nfaced_npf_array[2] = 4 (4-noded front face of 7-faced element)
nfaced_npf_array[3] = 4 (4-noded left face of 7-faced element)
nfaced_npf_array[4] = 4 (4-noded back face of 7-faced element)
nfaced_npf_array[5] = 4 (4-noded right front face of 7-faced element)
nfaced_npf_array[6] = 4 (4-noded right back face of 7-faced element)
nfaced_npf_array[7] = 3 (3-noded top face of 5-faced element)
nfaced_npf_array[8] = 3 (3-noded bot face of 5-faced element)
nfaced_npf_array[9] = 4 (4-noded back face of 5-faced element)
nfaced_npf_array[10] = 4 (4-noded right face of 5-faced element)
nfaced_npf_array[11] = 4 (4-noded left front face of 5-faced element)
==
Sum 48 <-------------+
|
4. In USERD_get_nfaced_conn: |
length of the nfaced_conn_array will be: 48
nsided_conn_array[0] = 7 (conn of 5-noded top face of 7-faced elem)
nsided_conn_array[1] = 8
nsided_conn_array[2] = 9
nsided_conn_array[3] = 10
nsided_conn_array[4] = 11
nsided_conn_array[5] = 1 (conn of 5-noded bot face of 7-faced elem)
nsided_conn_array[6] = 5
nsided_conn_array[7] = 4
nsided_conn_array[8] = 3
nsided_conn_array[9] = 2
nsided_conn_array[10] = 1 (conn of 4-noded front face of 7-faced elem)
nsided_conn_array[11] = 2
nsided_conn_array[12] = 8
nsided_conn_array[13] = 7
nsided_conn_array[14] = 5 (conn of 4-noded left face of 7-faced elem)
nsided_conn_array[15] = 1
nsided_conn_array[16] = 7
nsided_conn_array[17] = 11
nsided_conn_array[18] = 4 (conn of 4-noded back face of 7-faced elem)
nsided_conn_array[19] = 5
nsided_conn_array[20] = 11
nsided_conn_array[21] = 10
nsided_conn_array[22] = 2 (conn of 4-noded right front face of 7-faced)
nsided_conn_array[23] = 3
nsided_conn_array[24] = 9
nsided_conn_array[25] = 8
nsided_conn_array[26] = 3 (conn of 4-noded right back face of 7-faced)
nsided_conn_array[27] = 4
nsided_conn_array[28] = 10
nsided_conn_array[29] = 9
nsided_conn_array[30] = 9 (conn of 3-noded top face of 5-faced elem)
nsided_conn_array[32] = 12
nsided_conn_array[32] = 10
nsided_conn_array[33] = 3 (conn of 3-noded bot face of 5-faced elem)
nsided_conn_array[34] = 4
nsided_conn_array[35] = 6
nsided_conn_array[36] = 6 (conn of 4-noded back face of 5-faced elem)
nsided_conn_array[37] = 4
nsided_conn_array[38] = 10
nsided_conn_array[39] = 12
nsided_conn_array[40] = 3 (conn of 4-noded right face of 5-faced elem)
nsided_conn_array[41] = 6
nsided_conn_array[42] = 12
nsided_conn_array[43] = 9
nsided_conn_array[44] = 4 (conn of 4-noded left front face of 5-faced)
nsided_conn_array[45] = 3
nsided_conn_array[46] = 9
nsided_conn_array[47] = 10
--------------------------------------------------------------------
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.
* Prior to API 2.01:
-----------------
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. They must also be
positive numbers greater than zero.
USERD_get_part_node_ids is used to obtain the ids, if the
status returned here is TRUE.
(Unlike API 1.0, where the connectivity of elements had to be
according to the node ids - API 2.0's element connectivities
are not affected either way by the status here.)
For structured parts, EnSight will assign ids if you return a
status of TRUE here. You cannot assign them yourself!!
* Starting at API 2.01:
--------------------
For both unstructured and structured 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. They must
also be positive numbers greater than zero.
USERD_get_part_node_ids is used to obtain the ids, if the
status returned here is TRUE.
* Will call USERD_get_part_node_ids for each part if this routine
returns TRUE.
--------------------------------------------------------------------
USERD_get_nsided_conn -
Description:
-----------
Gets the array containing the connectivity of nsided elements
Specification:
-------------
int USERD_get_nsided_conn(int part_number,
int *nsided_conn_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = the part number
(OUT) nsided_conn_array = 1D array of nsided connectivies
(int array will have been allocated long enough
to hold all the nsided connectivities. Which is
the sum of all the nodes_per_element values in
the conn_array of USERD_get_part_elements_by_type)
Notes:
-----
* Will not be called unless there are some nsided elements in the the part.
* Providing nsided information to Ensight:
1. In USERD_get_gold_part_build_info, provide the number of nsided
elements in the part.
2. In USERD_get_part_elements_by_type, provide (in the conn_array),
the number of nodes per nsided element. (as if connectivity
length of an nsided element is one)
3. In this routine, provide the streamed connectivities for each of the
nsided elements.
Simple example: 5 6
+--------+
3 nsided elements: /| \
(1 4-sided / | \
1 3-sided / | \
1 7-sided) / | \ 7
/3 |4 +
+-----+ |
| | |
| | |8
| | +
| | /
| | /
| | /
|1 |2 /9
+-----+--------+
1. In USERD_get_gold_part_build_info:
number_of_elements[Z_NSIDED] = 3
.
/|\
|
2. In USERD_get_part_elements_by_type:
length of conn_array will be: 3 x 1
for element_type of Z_NSIDED:
conn_array[0][0] = 4 (for the 4-sided element)
conn_array[1][0] = 3 (for the 3-sided element)
conn_array[2][0] = 7 (for the 7-sided element)
Sum ===
14 <---------+
|
3. In this routine: |
length of nsided_conn_array will be: 14
nsided_conn_array[0] = 1 (connectivity of 4-sided element)
nsided_conn_array[1] = 2
nsided_conn_array[2] = 4
nsided_conn_array[3] = 3
nsided_conn_array[4] = 3 (connectivity of 3-sided element)
nsided_conn_array[5] = 4
nsided_conn_array[6] = 5
nsided_conn_array[7] = 2 (connectivity of 7-sided element)
nsided_conn_array[8] = 9
nsided_conn_array[9] = 8
nsided_conn_array[10] = 7
nsided_conn_array[11] = 6
nsided_conn_array[12] = 5
nsided_conn_array[13] = 4
--------------------------------------------------------------------
USERD_get_num_of_time_steps
Description:
-----------
Gets the number of time steps of data available for desired timeset.
Specification:
-------------
int USERD_get_num_of_time_steps( int timeset_number )
Returns:
-------
Number of time steps in timeset (>0 if okay, <=0 if problems).
Arguments:
---------
(IN) timeset number = the timeset number
For example: If USERD_get_number_of_timesets
returns 2, the valid
timeset_number's would be 1 and 2
Notes:
-----
* This should be >= 1 1 indicates a static model
>1 indicates a transient model
* Num_time_steps[timeset_number] would be set here
--------------------------------------------------------------------
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_material_sets -
Description:
-----------
Get the number of material sets in the model
Specification:
-------------
int USERD_get_number_of_material_sets( void )
Returns:
-------
Num_material_sets = number of material sets
(Zero would indicate that you have no materials
to deal with in the model)
or
-1 if an error condition
Arguments:
---------
none
Notes:
-----
* You may want to keep this as a global for use in other routines.
###############################################################
NOTE: For EnSight 7.6, only one material set is supported
within EnSight.
Thus the only valid returns here are:
0 (no materials)
1 (for the one material set allowed)
or -1 (if an error)
If the casefile has more than this, this reader will
read them, but EnSight will issue an error message and
choke on them!
###############################################################
================================================================
A very simple explanatory example, to use as a reference for the
materials routines:
Given a 2D mesh composed of 9 quad (Z_QUA04) elements, with two materials.
Most of the model is material 1, but the top left corner is material 9 -
basically as shown:
*--------*--------*--------*
| | / | |
| Mat 9 / | |
| | / | |
| |/ | |
| e7 / e8 | e9 |
| /| | |
| / | | |
| / | | |
*----/---*--------*--------*
| / | | |
| / | | |
| / | Mat 1 |
|/ | | |
| e4 | e5 | e6 |
| | | |
| | | |
| | | |
*--------*--------*--------*
| | | |
| | | |
| | | |
| | | |
| e1 | e2 | e3 |
| | | |
| | | |
| | | |
*--------*--------*--------*
Thus, in this routine, set:
Num_material_sets = 1
In USERD_get_matf_set_info, set:
mat_set_ids[0] = 1
mat_set_name[0] = "Material Set 1" (or whatever name desired)
In USERD_get_number_of_materials, input would be set_index = 0, and
would need to set:
Num_materials[0] = 2
For simplicity, the ids and descriptions that would be returned in
USERD_get_matf_var_info could be:
mat_ids[0] = 1
mat_ids[1] = 9
mat_desc[0] = "mat 1" (or whatever desired)
mat_desc[2] = "mat 9"
The per element material ids list would need to be:
material ids:
-------------
ids_list[0] = 1 (material id 1, for elem e1)
ids_list[1] = 1 ( " e2)
ids_list[2] = 1 ( " e3)
ids_list[3] = -1 (negative of index into mixed-material id list, for elem e4)
ids_list[5] = 1 (material id 1, for elem e5)
ids_list[5] = 1 ( " e6)
ids_list[5] = -5 (negative of index into mixed-material id list, for elem e7)
ids_list[5] = -9 ( " e8)
ids_list[5] = 1 (material id 1, for elem e9)
Finally we need the mixed material ids list and the mixed materials values list,
which would need to be:
mixed-material ids:
-------------------
==> 1 ids_list[0] = 2 (the -1 in the material variable points here,
2 indicates that two materials are present)
2 ids_list[1] = 1 (1st material is 1)
3 ids_list[2] = 9 (2nd material is 9)
4 ids_list[3] = -1 (negative of index into mixed-material val_list)
==> 5 ids_list[4] = 2 (the -5 in the material variable points here,
2 indicates that two materials are present)
6 ids_list[5] = 1 (1st material is 1)
7 ids_list[6] = 9 (2nd material is 9)
8 ids_list[7] = -3 (negative of index into mixed-material val_list)
==> 9 ids_list[8] = 2 etc.
10 ids_list[9] = 1
11 ids_list[10] = 9
12 ids_list[11] = -5
mixed-material values:
----------------------
==> 1 val_list[0] = 0.875 (the -1 in the mixed-material ids_list points here,
and this is the value for material 1)
2 val_list[1] = 0.125 (the value for material 9)
==> 3 val_list[2] = 0.125 (the -3 in the mixed-materials ids_list points here)
4 val_list[3] = 0.875
==> 5 val_list[4] = 0.875 (the -5 in the mixed-materials ids_list points here)
6 val_list[5] = 0.125
So, USERD_size_matf_data would need to return
matf_size = 8, when called with set_id = 1
part_id = 1
wtyp = Z_QUA04
mat_type = Z_MAT_INDEX
matf_size = 12, when called with set_id = 1
part_id = 1
mat_type = Z_MIX_INDEX
= 6, when called with set_id = 1
part_id = 1
mat_type = Z_MIX_VALUE
And, USERD_load_matf_data would need to return:
the int array ids_list as shown above when called with:
set_id = 1
part_id = 1
wtyp = Z_QUA04
mat_type = Z_MAT_INDEX (indicating id list).
the int array ids_list as shown above when called with:
set_id = 1
part_id = 1
mat_type = Z_MIX_INDEX (indicating id list).
the float array val_list as shown above when called with:
set_id = 1
part_id = 1
mat_type = Z_MIX_VALUE (indicating val list).
-------------------------------------------------------------------------
USERD_get_number_of_materials
Description:
-----------
Gets the number of materials in the material set
Specification:
-------------
int USERD_get_number_of_materials( int set_index )
Returns:
-------
Num_materials[set_index] = Number of materials in the set
0 indicates no materials information present
-1 indicates an error
Arguments:
---------
(IN) set_index = the material set index (zero based)
Notes:
-----
* See USERD_get_number_of_material_sets header for explanatory example
* Will not be called if Num_material_sets is zero
* You may want to keep this as a global for use in other routines.
--------------------------------------------------------------------
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 problems).
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_timesets
Description:
-----------
Gets the number of timesets used in the model.
Specification:
-------------
int USERD_get_number_of_timesets( void )
Returns:
-------
Number of timesets in the model
Arguments:
---------
none
Notes:
-----
* Num_timesets would be set here
* If you have a static model, both geometry and variables, you should
return a value of zero.
* If you have a transient model, then you should return one or more.
For example:
Geometry Variables No. of timesets
--------- ------------------------------ ---------------
static static 0
static transient, all using same timeset 1
transient transient, all using same timeset as geom 1
static transient, using 3 different timesets 3
transient transient, using 3 different timesets and
none of them the same as the
geometry timeset 4
etc.
NOTE: ALL GEOMETRY MUST USE THE SAME TIMESET!!! You will have to provide
the timeset number to use
for geometry in:
USERD_get_geom_timeset_number
Variables can use the same timeset as the geometry, or can use
other timesets. More than one variable can use the same timeset.
example: changing geometry at 5 steps, 0.0, 1.0, 2.0, 3.0, 4.0
variable 1 provided at these same five steps
variable 2 provided at 3 steps, 0.5, 1.25, 3.33
This routine should return a value of 2, because only
two different timesets are needed. Timeset 1 would be for the
geometry and variable 1 (they both use it). Timeset 2 would
be for variable 2, which needs its own in this case.
--------------------------------------------------------------------
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, vector and tensor 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_coords
Description:
-----------
Gets the coordinates for an unstructured part.
Specification:
-------------
int USERD_get_part_coords(int part_number, float **coord_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(OUT) coord_array = 2D float array which contains,
x,y,z coordinates of each node
in the part.
(IMPORTANT: The second dimension of this aray is 1-based!!!)
(Array will have been allocated
3 by (number_of_nodes + 1) for the part
long - see USERD_get_gold_part_build_info)
ex) If number_of_nodes = 100
as obtained in:
USERD_get_gold_part_build_info
Then the allocated dimensions of the
pointer sent to this routine will be:
coord_array[3][101]
Ignore the coord_array[0][0]
coord_array[1][0]
coord_array[2][0] locations and start
the node coordinates at:
coord_array[0][1]
coord_array[1][1]
coord_array[2][1]
coord_array[0][2]
coord_array[1][2]
coord_array[2][2]
etc.
Notes:
-----
* Not called unless Num_unstructured_parts is > 0
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_part_element_ids_by_type
Description:
-----------
Gets the ids for the elements of a particular type for an unstructured
or structured part.
Specification:
-------------
int USERD_get_part_element_ids_by_type(int part_number,
int element_type,
int *elemid_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(IN) element_type = One of the following (See global_extern.h)
Z_POINT node point element
Z_BAR02 2 node bar
Z_BAR03 3 node bar
Z_TRI03 3 node triangle
Z_TRI06 6 node triangle
Z_QUA04 4 node quad
Z_QUA08 8 node quad
Z_TET04 4 node tetrahedron
Z_TET10 10 node tetrahedron
Z_PYR05 5 node pyramid
Z_PYR13 13 node pyramid
Z_PEN06 6 node pentahedron
Z_PEN15 15 node pentahedron
Z_HEX08 8 node hexahedron
Z_HEX20 20 node hexahedron
Z_G_POINT ghost node point element
Z_G_BAR02 2 node ghost bar
Z_G_BAR03 3 node ghost bar
Z_G_TRI03 3 node ghost triangle
Z_G_TRI06 6 node ghost triangle
Z_G_QUA04 4 node ghost quad
Z_G_QUA08 8 node ghost quad
Z_G_TET04 4 node ghost tetrahedron
Z_G_TET10 10 node ghost tetrahedron
Z_G_PYR05 5 node ghost pyramid
Z_G_PYR13 13 node ghost pyramid
Z_G_PEN06 6 node ghost pentahedron
Z_G_PEN15 15 node ghost pentahedron
Z_G_HEX08 8 node ghost hexahedron
Z_G_HEX20 20 node ghost hexahedron
(OUT) elemid_array = 1D array containing id of each
element of the type.
(Array will have been allocated
number_of_elements of the type long)
ex) If number_of_elements[Z_TRI03] = 25
number_of_elements[Z_QUA04] = 100
number_of_elements[Z_HEX08] = 30
as obtained in:
USERD_get_gold_part_build_info
Then the allocated dimensions available
for this routine will be:
conn_array[25] when called with Z_TRI03
conn_array[100] when called with Z_QUA04
conn_array[30] when called with Z_HEX08
Notes:
-----
* Not called unless element label status is set to TRUE in
USERD_get_element_label_status
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_part_elements_by_type
Description:
-----------
Gets the connectivities for the elements of a particular type in an
unstructured part
Specification:
-------------
int USERD_get_part_elements_by_type(int part_number,
int element_type,
int **conn_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(IN) element_type = One of the following (See global_extern.h)
Z_POINT node point element
Z_BAR02 2 node bar
Z_BAR03 3 node bar
Z_TRI03 3 node triangle
Z_TRI06 6 node triangle
Z_QUA04 4 node quad
Z_QUA08 8 node quad
Z_TET04 4 node tetrahedron
Z_TET10 10 node tetrahedron
Z_PYR05 5 node pyramid
Z_PYR13 13 node pyramid
Z_PEN06 6 node pentahedron
Z_PEN15 15 node pentahedron
Z_HEX08 8 node hexahedron
Z_HEX20 20 node hexahedron
Z_G_POINT ghost node point element
Z_G_BAR02 2 node ghost bar
Z_G_BAR03 3 node ghost bar
Z_G_TRI03 3 node ghost triangle
Z_G_TRI06 6 node ghost triangle
Z_G_QUA04 4 node ghost quad
Z_G_QUA08 8 node ghost quad
Z_G_TET04 4 node ghost tetrahedron
Z_G_TET10 10 node ghost tetrahedron
Z_G_PYR05 5 node ghost pyramid
Z_G_PYR13 13 node ghost pyramid
Z_G_PEN06 6 node ghost pentahedron
Z_G_PEN15 15 node ghost pentahedron
Z_G_HEX08 8 node ghost hexahedron
Z_G_HEX20 20 node ghost hexahedron
(OUT) conn_array = 2D array containing connectivity
of each element of the type.
(Array will have been allocated
num_of_elements of the type by
connectivity length of the type)
ex) If number_of_elements[Z_TRI03] = 25
number_of_elements[Z_QUA04] = 100
number_of_elements[Z_HEX08] = 30
as obtained in:
USERD_get_gold_part_build_info
Then the allocated dimensions available
for this routine will be:
conn_array[25][3] when called with Z_TRI03
conn_array[100][4] when called with Z_QUA04
conn_array[30][8] when called with Z_HEX08
Notes:
-----
* Not called unless Num_unstructured_parts is > 0
* Will be based on Current_time_step
--------------------------------------------------------------------
USERD_get_part_node_ids
Description:
-----------
Gets the node ids of an unstructured or structured part.
Specification:
-------------
int USERD_get_part_node_ids(int part_number, int *nodeid_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) part_number = The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
(OUT) nodeid_array = 1D array containing node ids of
each node in the part.
(IMPORTANT: This array is 1-based!!!)
(Array will have been allocated
(number_of_nodes + 1) for the part long
see USERD_get_gold_part_build_info)
ex) If number_of_nodes = 100
as obtained in:
USERD_get_gold_part_build_info
Then the allocated dimensions of the
pointer sent to this routine will be:
nodeid_array[101]
Ignore the nodeid_array[0] location and start
the node ids at:
nodeid_array[1]
nodeid_array[2]
etc.
Notes:
-----
* Not called unless node label status is TRUE, as returned from
USERD_get_node_label_status
* Will be based on Current_time_step
* The ids are purely labels, used when displaying or querying node ids.
However, any node id < 0 will never be displayed
--------------------------------------------------------------------
USERD_get_reader_descrip
Description:
-----------
Gets the description of the reader, so gui can give more info
Specification:
-------------
int USERD_get_reader_descrip(char descrip[Z_MAXFILENP])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(OUT) descrip = the description of the reader (max length is MAXFILENP,
which is 255)
Notes:
-----
* OPTIONAL ROUTINE! You can have it or not.
--------------------------------------------------------------------
USERD_get_reader_version
Description:
-----------
Gets the version number of the user defined reader
Specification:
-------------
int USERD_get_reader_version(char version_number[Z_MAX_USERD_NAME])
Returns:
-------
Z_OK if successful
Z_ERR if not successful (and will assume is version 1.0)
Arguments:
---------
(OUT) version_number = the version number of the reader
(max length is Z_MAX_USERD_NAME, which
is 20)
Notes:
-----
* This needs to be "2.000" or greater. Otherwise EnSight will assume
this reader is API 1.0
* should set it to "2.010" for this version of the API
--------------------------------------------------------------------
USERD_get_sol_times
Description:
-----------
Get the solution times associated with each time step for
desired timeset.
Specification:
-------------
int USERD_get_sol_times(int timeset_number,
float *solution_times)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) timeset_number = the timeset number
For example: If USERD_get_number_of_timesets
returns 2, the valid
timeset_number's would be 1 and 2
(OUT) solution_times = 1D array of solution times per time step
(Array will have been allocated
Num_time_steps[timeset_number] long)
Notes:
-----
* The solution times must be non-negative and increasing.
--------------------------------------------------------------------
USERD_get_timeset_description -
Description:
-----------
Get the description to associate with the desired timeset.
Specification:
-------------
int USERD_get_timeset_description(int timeset_number,
char timeset_description[Z_BUFL])
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) timeset_number = the timeset number
For example: If USERD_get_number_of_timesets
returns 2, the valid
timeset_number's would be 1 and 2
(OUT) timeset_description = timeset description string
Notes:
-----
* A string of NULLs is valid for timeset_description
--------------------------------------------------------------------
USERD_get_var_by_component
Description:
-----------
Gets the values of a variable component. Both unstructured and structured
parts use this routine.
if Z_PER_NODE:
Get the component value at each node for a given variable in the part.
or if Z_PER_ELEM:
Get the component value at each element of a specific part and type
for a given variable.
Specification:
-------------
int USERD_get_var_by_component(int which_variable,
int which_part,
int var_type,
int which_type,
int imag_data,
int component,
float *var_array)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
or: Z_UNDEF, in which case you need not load any values into var_array
Arguments:
---------
(IN) which_variable = The variable number
(IN) which_part Since EnSight Version 7.4
-------------------------
= The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
Prior to EnSight Version 7.4
----------------------------
= The part id This is the part_id label loaded
in USERD_get_gold_part_build_info.
It is NOT the part table index.
(IN) var_type = Z_SCALAR
Z_VECTOR
Z_TENSOR (symmetric tensor)
Z_TENSOR9 (asymmetric tensor)
(IN) which_type
if Z_PER_NODE: Not used
if Z_PER_ELEM: = The element type
Z_POINT node point element
Z_BAR02 2 node bar
Z_BAR03 3 node bar
Z_TRI03 3 node triangle
Z_TRI06 6 node triangle
Z_QUA04 4 node quad
Z_QUA08 8 node quad
Z_TET04 4 node tetrahedron
Z_TET10 10 node tetrahedron
Z_PYR05 5 node pyramid
Z_PYR13 13 node pyramid
Z_PEN06 6 node pentahedron
Z_PEN15 15 node pentahedron
Z_HEX08 8 node hexahedron
Z_HEX20 20 node hexahedron
Z_G_POINT ghost node point element
Z_G_BAR02 2 node ghost bar
Z_G_BAR03 3 node ghost bar
Z_G_TRI03 3 node ghost triangle
Z_G_TRI06 6 node ghost triangle
Z_G_QUA04 4 node ghost quad
Z_G_QUA08 8 node ghost quad
Z_G_TET04 4 node ghost tetrahedron
Z_G_TET10 10 node ghost tetrahedron
Z_G_PYR05 5 node ghost pyramid
Z_G_PYR13 13 node ghost pyramid
Z_G_PEN06 6 node ghost pentahedron
Z_G_PEN15 15 node ghost pentahedron
Z_G_HEX08 8 node ghost hexahedron
Z_G_HEX20 20 node ghost hexahedron
(IN) imag_data = TRUE if imag component
FALSE if real component
(IN) component = The component: (0 if Z_SCALAR)
(0 - 2 if Z_VECTOR)
(0 - 5 if Z_TENSOR)
(0 - 8 if Z_TENSOR9)
* 6 Symmetric Indicies, 0:5 *
* ---------------------------- *
* | 11 12 13 | | 0 3 4 | *
* | | | | *
* T = | 22 23 | = | 1 5 | *
* | | | | *
* | 33 | | 2 | *
* 9 General Indicies, 0:8 *
* ---------------------------- *
* | 11 12 13 | | 0 3 4 | *
* | | | | *
* T = | 21 22 23 | = | 6 1 5 | *
* | | | | *
* | 31 32 33 | | 7 8 2 | *
(OUT) var_array
-----------------------------------------------------------------------
(IMPORTANT: this array is 1-based for both Z_PER_NODE and Z_PER_ELEM!!!)
-----------------------------------------------------------------------
if Z_PER_NODE: = 1D array containing variable component value
for each node.
(Array will have been allocated
(number_of_nodes + 1) long)
Info stored in this fashion:
var_array[0] = not used
var_array[1] = var component for node 1 of part
var_array[2] = var_component for node 2 of part
var_array[3] = var_component for node 3 of part
etc.
if Z_PER_ELEM: = 1D array containing variable component
value for each element of a particular
part and type.
(Array will have been allocated
(number_of_elements[which_part][which_type] + 1)
long. See USERD_get_gold_part_build_info)
Info stored in this fashion:
var_array[1] = var component for elem 1 (of part and type)
var_array[2] = var component for elem 2 (of part and type)
var_array[3] = var component for elem 3 (of part and type)
etc.
Notes:
-----
* Not called unless Num_variables is > 0
* 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
* If the variable is not defined for this part, simply return with a
value of Z_UNDEF. EnSight will treat the variable as undefined for
this part.
--------------------------------------------------------------------
USERD_get_var_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_var_value_at_specific(int which_var,
int which_node_or_elem,
int which_part,
int which_elem_type,
int time_step,
float values[3],
int imag_data)
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_gold_part_build_info),
or the block's element list (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 Since EnSight Version 7.4
-------------------------
= The part number
(1-based index of part table, namely:
1 ... Numparts_available.
It is NOT the part_id that
is loaded in USERD_get_gold_part_build_info)
Prior to EnSight Version 7.4
----------------------------
= The part id This is the part_id label loaded
in USERD_get_gold_part_build_info.
It is NOT the part table index.
(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_gold_part_build_info)
(IN) time_step = The time step
(IN) imag_data = TRUE if want imaginary value.
FALSE if want real value.
(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)
* The time step given is for the proper variable timeset.
----------------------------------------------------------------------
USERD_load_matf_data
Description:
-----------
Get the material id list, mixed-material id list, or
mixed-material values list for the given material set and part (and
element type if material id list)
Specification:
-------------
int USERD_load_matf_data( int set_index,
int part_id,
int wtyp,
int mat_type,
int *ids_list,
float *val_list)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) set_index = the material set index (zero based)
(IN) part_id = the part number desired
(IN) wtyp = the element type (used for Z_MAT_INDEX only)
Z_POINT node point element
Z_BAR02 2 node bar
Z_BAR03 3 node bar
Z_TRI03 3 node triangle
Z_TRI06 6 node triangle
Z_QUA04 4 node quad
Z_QUA08 8 node quad
Z_TET04 4 node tetrahedron
Z_TET10 10 node tetrahedron
Z_PYR05 5 node pyramid
Z_PYR13 13 node pyramid
Z_PEN06 6 node pentahedron
Z_PEN15 15 node pentahedron
Z_HEX08 8 node hexahedron
Z_HEX20 20 node hexahedron
Z_NSIDED nsided polygon
Z_NFACED nfaced polyhedron
Z_G_POINT ghost node point element
Z_G_BAR02 2 node ghost bar
Z_G_BAR03 3 node ghost bar
Z_G_TRI03 3 node ghost triangle
Z_G_TRI06 6 node ghost triangle
Z_G_QUA04 4 node ghost quad
Z_G_QUA08 8 node ghost quad
Z_G_TET04 4 node ghost tetrahedron
Z_G_TET10 10 node ghost tetrahedron
Z_G_PYR05 5 node ghost pyramid
Z_G_PYR13 13 node ghost pyramid
Z_G_PEN06 6 node ghost pentahedron
Z_G_PEN15 15 node ghost pentahedron
Z_G_HEX08 8 node ghost hexahedron
Z_G_HEX20 20 node ghost hexahedron
Z_G_NSIDED ghost nsided polygon
Z_G_NFACED ghost nfaced polyhedron
(IN) mat_type = Z_MAT_INDEX for material ids list
Z_MIX_INDEX for mixed-material ids list
Z_MIX_VALUE for mixed-material values list
(OUT) ids_list = If mat_type is Z_MAT_INDEX:
---------------------------
1D material id list
(Int array will have been allocated
the appropriate size, as returned in
USERD_size_matf_data for mat_type Z_MAT_INDEX)
If mat_type is Z_MIX_INDEX:
---------------------------
1D mixed-material id list
(Int array will have been allocated
the appropriate size, as returned in
USERD_size_matf_data for mat_type Z_MIX_INDEX)
(OUT) val_list = 1D mixed-materials values list
(only used if mat_type is Z_MIX_VALUE)
(Float array will have been allocated
the appropriate size, as returned in
USERD_size_matf_data for mat_type Z_MIX_VALUE)
Notes:
-----
* See USERD_get_number_of_material_sets header for explanatory example
* Will not be called if Num_material_sets is zero,
or Num_materials[set_index] is zero,
or the appropriate size from USERD_size_matf_data is zero
--------------------------------------------------------------------
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. The user written code must manage its own files!!
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.
= FALSE normally.
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_server_number
Description:
-----------
Receives the server number of how many total servers.
Specification:
-------------
int USERD_set_server_number(int cur_serv,
int tot_servs)
Returns:
-------
nothing
Arguments:
---------
(IN) cur_serv = the current server.
(IN) tot_servs = the total number of servers.
Notes:
-----
* Only useful if your user defined reader is being used with EnSight's
Server-of-Server capability. And even then, it may or may not be
something that you can take advantage of. If your data is already
partitioned in some manner, such that you can access the proper
portions using this information.
For all non-SOS uses, this will simply be 1 of 1
--------------------------------------------------------------------
USERD_set_time_set_and_step
Description:
-----------
Set the current time step in the desired timeset. All functions that
need time, and that do not explicitly pass it in, will use the timeset
and step set by this routine, if needed.
Specification:
-------------
void USERD_set_time_set_and_step(int timeset_number,
int time_step)
Returns:
-------
nothing
Arguments:
---------
(IN) timeset_number = the timeset number (1 based).
For example: If USERD_get_number_of_timesets
returns 2, the valid timeset_number's
would be 1 and 2.
(IN) time_step = The current time step to set
Notes:
-----
* Current_time_step and Current_timeset would be set here
--------------------------------------------------------------------
USERD_size_matf_data
Description:
-----------
Get the length of the material id list, mixed-material id list, or
mixed-material values list for the given material set and part (and
element type if material id list)
Specification:
-------------
int USERD_size_matf_data( int set_index,
int part_id,
int wtyp,
int mat_type,
int *matf_size)
Returns:
-------
Z_OK if successful
Z_ERR if not successful
Arguments:
---------
(IN) set_index = the material set index (zero based)
(IN) part_id = the part number desired
(IN) wtyp = the element type (used for Z_MAT_INDEX only)
Z_POINT node point element
Z_BAR02 2 node bar
Z_BAR03 3 node bar
Z_TRI03 3 node triangle
Z_TRI06 6 node triangle
Z_QUA04 4 node quad
Z_QUA08 8 node quad
Z_TET04 4 node tetrahedron
Z_TET10 10 node tetrahedron
Z_PYR05 5 node pyramid
Z_PYR13 13 node pyramid
Z_PEN06 6 node pentahedron
Z_PEN15 15 node pentahedron
Z_HEX08 8 node hexahedron
Z_HEX20 20 node hexahedron
Z_NSIDED nsided polygon
Z_NFACED nfaced polyhedron
Z_G_POINT ghost node point element
Z_G_BAR02 2 node ghost bar
Z_G_BAR03 3 node ghost bar
Z_G_TRI03 3 node ghost triangle
Z_G_TRI06 6 node ghost triangle
Z_G_QUA04 4 node ghost quad
Z_G_QUA08 8 node ghost quad
Z_G_TET04 4 node ghost tetrahedron
Z_G_TET10 10 node ghost tetrahedron
Z_G_PYR05 5 node ghost pyramid
Z_G_PYR13 13 node ghost pyramid
Z_G_PEN06 6 node ghost pentahedron
Z_G_PEN15 15 node ghost pentahedron
Z_G_HEX08 8 node ghost hexahedron
Z_G_HEX20 20 node ghost hexahedron
Z_G_NSIDED ghost nsided polygon
Z_G_NFACED ghost nfaced polyhedron
(IN) mat_type = Z_MAT_INDEX for material ids list
Z_MIX_INDEX for mixed-material ids list
Z_MIX_VALUE for mixed-material values list
(OUT) matf_size = the length of the material id list, or
mixed-material id list, or
mixed-material values list
for the given material set and part number
(and element type if Z_MAT_INDEX)
Notes:
-----
* See USERD_get_number_of_material_sets header for explanatory example
* Will not be called if Num_material_sets is zero, or
Num_materials[set_index] is zero
--------------------------------------------------------------------
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:
-----
---- end of doucment ----