A simulation target, or SIM target, is a MEX-file that implements a referenced model that executes in accelerator mode. Simulink® invokes the simulation target as needed during simulation to compute the behavior and outputs of the referenced model. Simulink uses the same simulation target for all accelerator mode instances of a given referenced model anywhere in a reference hierarchy.
If you have a Simulink Coder™ license, be careful not to confuse the simulation target of a referenced model with any of these other types of target:
Hardware target — A platform for which Simulink Coder generates code
System target — A file that tells Simulink Coder how to generate code for particular purpose
Rapid Simulation target (RSim) — A system target file supplied with Simulink Coder
Model reference target — A library module that contains Simulink Coder code for a referenced model
Simulink creates a simulation target only for a referenced model that has one or more accelerator mode instances in a reference hierarchy. A referenced model that executes only in normal mode always executes interpretively and does not use a simulation target. When one or more instance of a referenced model executes in normal mode, and one or more instance executes in accelerator mode:
Simulink creates a simulation target for the accelerator mode instances.
The normal mode instances do not use that simulation target.
Because accelerator mode requires code generation, it imposes some requirements and limitations that do not apply to normal mode. Aside from these constraints, you can generally ignore simulation targets and their details when you execute a referenced model in accelerator mode. See Limitations on Accelerator Mode Referenced Models for details.
Simulink by default generates the needed target from the referenced model:
If a simulation target does not exist at the beginning of a simulation
When you perform an update diagram for a parent model
If the simulation target already exists, then by default Simulink checks whether the referenced model has structural changes since the target was last generated. If so, Simulink regenerates the target to reflect changes in the model. For details about how Simulink detects whether to rebuild a model reference target, see the Rebuild parameter documentation.
You can change this default behavior to modify the rebuild criteria or specify that Simulink always or never rebuilds targets. See Rebuild for details.
To generate simulation targets interactively for accelerator mode referenced models, do one of these steps:
Update the diagram on a model that directly or indirectly references the model that is in accelerator mode
with appropriate arguments at the MATLAB® command line
While generating a simulation target, Simulink displays status messages at the MATLAB command line to enable you to monitor the target generation process. Target generation entails generating and compiling code and linking the compiled target code with compiled code from standard code libraries to create an executable file.
You can reduce the time that Simulink spends checking whether any or all simulation targets require rebuilding by setting configuration parameter values as follows:
In all referenced models throughout the hierarchy,
set Configuration Parameters > Diagnostics
> Data Validity > Signal resolution to
None. (See Signal resolution.)
To minimize change detection time, consider setting Configuration Parameters > Model Referencing > Rebuild
If any changes in known dependencies
detected on the top model. See Rebuild.
These parameter values exist in the configuration set of a referenced model, not in the individual Model block, so setting either value for any instance of a referenced model sets it for all instances of that model.
Simulink creates simulation targets in the
of the working folder. If
slprj does not exist, Simulink creates
Simulink Coder code generation also uses the
By default, the files generated by Simulink diagram updates
and model builds are placed in a build folder, the root of which is
the current working folder (
pwd). However, in some
situations, you might want the generated files to go to a root folder
outside the current working folder. For example:
You need to keep generated files separate from the models and other source materials used to generate them.
You want to reuse or share previously-built simulation targets without having to set the current working folder back to a previous working folder.
You might also want to separate generated simulation artifacts from generated production code.
To allow you to control the output locations for the files generated by diagram updates and model builds, the software allows you to separately specify the simulation cache folder build folder. The simulation cache folder is the root folder in which to place artifacts used for simulation.
To specify the simulation cache folder, use one of these approaches:
CacheFolder MATLAB session
In the Simulink Preferences > General dialog box, use the Simulation cache folder preference. This preference provides the initial defaults for the MATLAB session parameters.
To control the output location for files generated by Simulink diagram updates, in the Simulink Preferences > General dialog box, use the Simulation cache folder preference. To specify the root folder location for files generated by Simulink diagram updates, set the preference value by entering or browsing to a folder path, for example:
The folder path that you specify provides the initial default
for the MATLAB session parameter
When you initiate a Simulink diagram update, any files generated
are placed in a build folder at the root location specified by
any), rather than in the current working folder (
For example, using a 32-bit Windows® host platform, if you
set the Simulation cache folder to
then simulate the model
files are generated into the specified folder as follows:
As an alternative to using the Simulink preferences to set Simulation
cache folder, you also can get and set the preference
value from the command line using
>> get_param(0, 'CacheFolder') ans = '' >> set_param(0, 'CacheFolder', fullfile('C:','Work','mymodelsimcache')) >> get_param(0, 'CacheFolder') ans = C:\Work\mymodelsimcache
Also, you can choose to override the Simulation cache folder preference value for the current MATLAB session.
The Simulink preferences Simulation
cache folder and Code
generation folder provide the initial defaults
for the MATLAB session parameters
which determine where files generated by Simulink diagram updates
and model builds are placed. However, you can override these build
folder settings during the current MATLAB session, using the
Simulink.fileGenControl function. This function
allows you to directly manipulate the MATLAB session parameters,
for example, overriding or restoring the initial default values. The
values you set using
at the end of the current MATLAB session. For more information
and detailed examples, see the
In a parallel computing environment, you can increase the speed of diagram updates for models containing large model reference hierarchies by building referenced models that are configured in Accelerator mode in parallel whenever conditions allow. For example, if you have Parallel Computing Toolbox™ software, updating of each referenced model can be distributed across the cores of a multicore host computer. If you additionally have MATLAB Distributed Computing Server™ software, updating of each referenced model can be distributed across remote workers in your MATLAB Distributed Computing Server configuration.
The performance gain realized by using parallel builds for updating referenced models depends on several factors, including how many models can be built in parallel for a given model referencing hierarchy, the size of the referenced models, and parallel computing resources such as number of local and/or remote workers available and the hardware attributes of the local and remote machines (amount of RAM, number of cores, and so on).
For configuration requirements that might apply to your parallel computing environment, see Parallel Building Configuration Requirements.
For a description of the general workflow for building referenced models in parallel whenever conditions allow, see Update Models in a Parallel Computing Environment.
The following requirements apply to using parallel builds for updating model reference hierarchies:
For local pools, the host machine should have an appropriate
amount of RAM available for supporting the number of local workers
(MATLAB sessions) that you plan to use. For example, using
create a parallel pool with four workers results in five MATLAB sessions
on your machine, each using approximately 120 MB of memory at startup.
Remote MATLAB Distributed Computing Server workers participating in a parallel build must use a common platform and compiler.
A consistent MATLAB environment must be set up
in each MATLAB worker session as in the MATLAB client session
— for example, shared base workspace variables, MATLAB path
settings, and so forth. One approach is to use the
of the top model. If you configure your model to load the top model
with each MATLAB worker session, its preload function can be
used for any MATLAB worker session setup.
To take advantage of parallel building for a model reference hierarchy:
Set up a pool of local and/or remote MATLAB workers in your parallel computing environment.
Make sure that Parallel Computing Toolbox software is licensed and installed.
To use remote workers, make sure that MATLAB Distributed Computing Server software is licensed and installed.
Issue MATLAB commands to set up the worker pool,
From the top model of the model reference hierarchy, open the Configuration Parameters dialog box. Go to the Model Referencing pane and select the Enable parallel model reference builds option. This selection enables the parameter MATLAB worker initialization for builds.
For MATLAB worker initialization for builds, select one of the following values:
None if the software should
perform no special worker initialization. Specify this value if the
child models in the model reference hierarchy do not rely on anything
in the base workspace beyond what they explicitly set up (for example,
with a model load function).
Copy base workspace if
the software should attempt to copy the base workspace to each worker.
Specify this value if you use a setup script to prepare the base workspace
for multiple models to use.
Load top model if the software
should load the top model on each worker. Specify this value if the
top model in the model reference hierarchy handles all of the base
workspace setup (for example, with a model load function).
Note: You only need to set Enable parallel model reference builds for the top model of the model reference hierarchy to which it applies.
Optionally, turn on verbose messages for simulation builds. If you select verbose builds, the build messages report the progress of each parallel build with the name of the model.
To turn on verbose messages for simulation target builds, go to the All Parameters tab of the Configuration Parameters dialog box and select Verbose accelerator builds.
The Verbose accelerator builds option controls the verbosity of build messages both in the MATLAB Command Window and in parallel build log files.
Optionally, inspect the model reference hierarchy to determine, based on model dependencies, which models will be built in parallel. For example, you can use the Model Dependency Viewer from the Simulink Analysis > Model Dependencies menu.
Update your model. Messages in the MATLAB command window record when each parallel or serial build starts and finishes.
If you need more information about a parallel build, for example, if a build fails, see Locate Parallel Build Logs.
When you update a model for which referenced models are built in parallel, if verbose builds are turned on, messages in the MATLAB Command Window record when each parallel or serial build starts and finishes. For example,
### Initializing parallel workers for parallel model reference build. ### Parallel worker initialization complete. ### Starting parallel model reference SIM build for 'bot_model001' ### Starting parallel model reference SIM build for 'bot_model002' ### Starting parallel model reference SIM build for 'bot_model003' ### Starting parallel model reference SIM build for 'bot_model004' ### Finished parallel model reference SIM build for 'bot_model001' ### Finished parallel model reference SIM build for 'bot_model002' ### Finished parallel model reference SIM build for 'bot_model003' ### Finished parallel model reference SIM build for 'bot_model004'
To obtain more detailed information about a parallel build,
you can examine the parallel build log. For each referenced model
built in parallel, the build process generates a file named
is the name
of the referenced model. This file contains the full build log for
If a parallel build completes, you can find the build log file
in the build subfolder corresponding to the referenced model. For
example, for a build of referenced model
look for the build log file
the referenced model subfolder
If a parallel builds fails, you might see output similar to the following:
### Initializing parallel workers for parallel model reference build. ### Parallel worker initialization complete. ### Starting parallel model reference SIM build for 'bot_model002' ### Starting parallel model reference SIM build for 'bot_model003' ### Finished parallel model reference SIM build for 'bot_model002' ### Finished parallel model reference SIM build for 'bot_model003' ### Starting parallel model reference SIM build for 'bot_model001' ### Starting parallel model reference SIM build for 'bot_model004' ### Finished parallel model reference SIM build for 'bot_model004' ### The following error occurred during the parallel model reference SIM build for 'bot_model001': Error(s) encountered while building model "bot_model001" ### Cleaning up parallel workers.
If a parallel build fails, you can find the build log file in
a referenced model subfolder under the build subfolder
For example, for a failed parallel build of model
look for the build log file