Cross-Release Code Integration
If you have an Embedded Coder® license, you can integrate generated C code from previous releases with generated code from the current release when the source models are single-rate and the generated C code is from:
Top-model or subsystem build processes that use the nonreusable function code interface.
Single or multiple instance model reference build processes that suppress error status monitoring (
SuppressErrorStatus
ison
).
If you can reuse existing code without modification, you can reduce the cost of reverification.
Note
crossReleaseImport
(Embedded Coder) supports the import of
generated code from only the previous eight releases.
Workflow
Consider this control system model.
The Controller
Model block references a model that consists of three components:
P1
is a Model block, which references a model developed with a previous release, for example, R2015b. The generated model code, with the standalone code interface, is in the folderP1_ert_rtw
.C1
is a Model block, which references a model that you are developing in the current release.P2
is a subsystem block developed with a previous release, for example, R2016a. The generated subsystem code is in the folderP2_ert_rtw
.P3
is a Model block, which references a model developed with a previous release, for example, R2016b. The generated model code, with the model reference code interface, is in the folderslprj/ert/P3
.
To integrate code from previous releases with generated code from the current release, use this workflow:
Limitations
The cross-release code integration workflow does not support:
Export-function models for ERT code.
Simulink Function and Function Caller blocks across the boundaries of ERT code generated by different releases.
The integration of generated code from releases before R2010a.
The import of generated code from the current release into a previous release (forward compatibility).
The export of files located in the MATLAB® root folder of the previous release, for example, blockset library files.
The export and import of generated code from models with noninlined S-functions.
C-API (Embedded Coder).
At the end of the model build process, the code generation report displays shared files
that are directly used by the integration model, for example, Controller
.
The report does not display shared files used by the components of the model, for example,
P1
and P2
.
If your model has:
A cross-release SIL or PIL block, you cannot run rapid accelerator mode simulations.
A Model block that references a model containing a cross-release SIL or PIL block, you cannot run accelerator mode or rapid accelerator mode simulations.
You can run:
Top-model SIL simulations of models that contain cross-release SIL or PIL blocks. The models must not contain cross-release AUTOSAR Model blocks.
Model block SIL simulations of referenced models that contain cross-release SIL or PIL blocks. The referenced models must not contain cross-release AUTOSAR Model blocks.
For information about other cross-release AUTOSAR code integration limitations, see Import AUTOSAR Code from Previous Releases.
Simulink.Bus
Support
To use a bus object as a data type in cross-release ERT code integration, use one of these approaches.
Approach | Code Export | Code Import |
---|---|---|
Automatic |
In the previous release, before generating code, set the
The code generator creates the |
In the current release, before running When you build the integration model, the build process uses the
|
Exported bus |
In the previous release, before generating code, specify these properties of
the
The code generator creates For R2010a and R2010b, the |
In the current release, before running When you build the integration model that incorporates the imported SIL or PIL
block, the build process uses the If the imported code is from R2010a or R2010b, specify these properties of the
When you build the integration model, the build process uses the
|
Imported bus |
In the previous release, before generating code, specify these properties of
the
For R2010a and R2010b, the |
In the current release, after importing generated code, you do not have to
change the When you build the integration model that incorporates the imported SIL or PIL
block, the build process uses the If the imported code is from R2010a or R2010b, specify these properties of the
When you build the integration model, the build process uses the
|
Root-Level I/O Through Global Variables in Generated Code
When imported ERT code from a previous release implements an input or output port through a global variable, the code that is generated from the integration model depends on the properties of the signal connected to the port in the integration model.
If the integration model signal does not map to a generated code variable that has the same name as the signal in the imported code, the generated code:
Defines the variable if it is declared but undefined in the imported code.
Creates additional code to copy data between the variable generated from the integration model and the variable in the imported code.
If the integration model signal maps to a variable with the same name as the signal in the imported code, the variable used by the imported code is also used by the code generated from the integration model. You must use a compatible storage class for the signal.
Storage Class Property | Property Value Support |
---|---|
Type | Unstructured only |
Data access |
Cannot connect a port implemented as a Cannot connect a port implemented as a |
Data scope |
If the imported code declares but does not define the variable (i.e. code is
generated from a signal that uses the
If the imported code defines the variable (i.e. code is generated from a
signal that uses the
|
Communicate Between Current and Previous Release Components Through Global Data Stores
Current and previous release components can communicate through global data stores
associated with Simulink.Signal
objects in the MATLAB base workspace or a Simulink data dictionary. The workflow described here applies to cross-release ERT code
integration.
Code Generation Configuration
Before generating model component code in the old release, configure data store memory to use a storage class that imports external code.
If a top-model or subsystem build process generates the code, set the
Storage class property of the Simulink.Signal
objects to one of these classes:
ImportedExtern
ImportedExternPointer
ImportFromFile
custom storage class
If a model reference build process generates the code, you can also use these classes:
ExportedGlobal
ExportToFile
custom storage class
Import Configuration
In the current release, before you run crossReleaseImport
, define a
Simulink.Signal
object in the MATLAB base workspace or a Simulink data dictionary for each global data store of the component that you want to import:
For the object name and the Data type, Complexity, and Dimensions object properties, specify values that match values of the corresponding object in the component that you want to import.
For the Storage class property, specify a value that is compatible. If the previous release value is
ImportedExtern
, specify one of these values for the current release:ImportedExtern
ExportedGlobal
ImportFromFile
orExportToFile
custom storage class.
If the previous release value is
ImportedExternPointer
, then specifyImportedExternPointer
for the current release.For the Identifier property, specify a matching value only if the property is specified for the object in the component that you want to import.
Save the
Simulink.Signal
objects. The objects are required each time you simulate or build the imported SIL or PIL block.
For more information, see Data Stores in Generated Code.
Parameter Tuning
The cross-release ERT code integration workflow supports parameter tuning in an integration model that contains component code with tunable parameters from previous releases.
In the current release, before you run crossReleaseImport
, for each
tunable parameter of the component that you want to import:
Define a
Simulink.Parameter
object in the MATLAB base workspace or a Simulink data dictionary.For the object name and the Data type, Complexity, and Dimensions object properties, specify values that match the previous release object values. If the variable in the imported source code does not have the same name as the object, for the Identifier property, specify a value that matches the variable name.
If the previous release object uses the
GetSet
custom storage class, specify:A matching value for the Storage class object property.
The header file that defines the
get
andset
access functions. For details, see Control Data Representation by Configuring Storage Class Properties (Embedded Coder) and Access Data Through Functions with Storage Class GetSet (Embedded Coder).
Support of the
GetSet
custom storage class from a previous release applies only for R2011a and later releases.
For code generated by a top-model or subsystem build process in a previous release, these limitations apply:
If a tunable parameter specified by a
Simulink.Parameter
object in the previous release has storage class set toExportedGlobal
and the storage class of theSimulink.Parameter
object in the current release is alsoExportedGlobal
, an error occurs when you build the integration model.On a Mac operating system, if a tunable parameter specified by a
Simulink.Parameter
object in the previous release has storage class set toExportedGlobal
, you cannot build the integration model if the storage class of theSimulink.Parameter
object in the current release (with the same name or alias) isImportedExtern
. To work around this limitation, modify the default settings:Get the build tool from the default toolchain.
tc = coder.make.getDefaultToolchain; cComp = tc.getBuildTool('C Compiler');
Extract the C compiler standard options.
stdMaps = cComp.SupportedStandard.getLangStandardMaps; optionValues = stdMaps.getCompilerOptions('*');
Remove
-fno-common
from the standard options for the C and C++ compilers.optionToRemove = '-fno-common'; optionsToKeep = strrep(optionValues, optionToRemove, ''); c_standard_opts_id = '$(C_STANDARD_OPTS)'; custToolChainOpts = get_param(model,'CustomToolchainOptions'); custToolChainOpts{2} = ... strrep(custToolChainOpts{2}, c_standard_opts_id, optionsToKeep); set_param(model, 'CustomToolchainOptions',custToolChainOpts);
Use Multiple Instances of Code Generated from Reusable Referenced Model
Using a reusable referenced model, you can specify unique model argument values for each instance of the referenced model in a parent model. Import previously generated code for the reusable referenced model into the current release as a parameterized cross-release SIL or PIL block, and then insert multiple instances of the block into an integration model. For each block instance, you can specify unique model argument values.
Update existing shared code folder.
sharedCodeUpdate(sourceFolder,destinationFolder)
Import generated code for the reusable referenced model into the current release as a parameterized cross-release block, for example, a SIL block.
handleSILBlock = crossReleaseImport(reusableReferencedModelcodeLocation, ... configSetIntegrationModel, 'SimulationMode', 'SIL');
In the integration model, replace, for example, two instances of the referenced model with instances of the cross-release SIL block.
open_system(integrationModel); blockInstanceName1 = 'refModelInstanceName1'; blockinstanceName2 = 'refModelInstanceName2'; SILBlockFullName = getfullname(handleSILBlock); replace_block(integrationModel, 'Name', blockInstanceName1, ... SILBlockFullName, 'noprompt'); replace_block(integrationModel, 'Name', blockInstanceName2, ... SILBlockFullName, 'noprompt');
Suppose the reusable referenced model has model arguments
andparamA
, and the values for the referenced model instances,paramB
andrefModelInstanceName1
, are workspace variables. In this case, you can specify argument values for the cross-release block instances that are workspace variables.refModelInstanceName2
pathToBlockInstanceName1 = [integrationModel, '/', blockInstanceName1]; pathToBlockInstanceName2 = [integrationModel, '/', blockInstanceName2]; set_param(pathToBlockInstanceName1, 'paramA', 'paramA_instName1'); set_param(pathToBlockInstanceName1, 'paramB', 'paramB_instName1'); set_param(pathToBlockInstanceName2, 'paramA', 'paramA_instName2'); set_param(pathToBlockInstanceName2, 'paramB', 'paramB_instName2');
To specify unique model argument values for the block instances in the integration model, assign values to the workspace variables,
,paramA_instName1
,paramB_instName1
, andparamA_instName2
.paramB_instName2
Compare Simulation Behavior of Model Component in Current Release and Generated Code from Previous Release
In a previous release, suppose that you developed a model component, generated code for the component, and tested and deployed the generated code. Now, in the current release, you want to add features to the model component and use the model component in system development and code generation. Before you proceed, you can compare the functional behavior of the model component and the generated code from the previous release.
To test the numerical equivalence between the model component and the generated code from the previous release, use Simulink Test™. With the Test Manager (Simulink Test), you can perform back-to-back tests and output comparisons:
Bring the model component into the current release as a Model block with the Simulation mode block parameter set to
Normal
.With the Model block, create a top model that specifies test input data.
Import the code generated in the previous release into the current release as a SIL block.
With the SIL block, create another top model that specifies the same the test input data.
In the Test Manager, create an equivalence test case that runs simulations of the top models and compares outputs.
Run the test case and review results.
For more information, see Test Two Simulations for Equivalence (Simulink Test).
Note
If you want to compare the behavior of generated code from the current and previous release, in step 1, specify these Model block parameters:
Set Simulation mode to
Software-in-the-loop (SIL)
orProcessor-in-the-loop (PIL)
.Set Code interface to
Top model
.
Import AUTOSAR Code from Previous Releases
If you install the Embedded Coder Support Package for AUTOSAR Standard, you can import into the current release AUTOSAR component code that you generated in a previous release.
When you run crossReleaseImport
(Embedded Coder), the function imports the
AUTOSAR code as a cross-release Model block instead of a SIL or PIL block. The
Simulation mode parameter of the Model block is set to
Software-in-the-loop (SIL)
or
Processor-in-the-loop (PIL)
. Incorporate the
Model block into the current release model.
These limitations apply:
The cross-release workflow does not support per-instance memory that accesses NVRAM.
Tunable parameters must be mapped to AUTOSAR calibration parameters or AUTOSAR internal calibration parameters.
If the original model uses variants or symbolic dimensions (dimension variants), the imported model can use only the same variant and symbolic dimension configuration that was used when generating the code in the previous release.
See Also
sharedCodeMATLABVersions
(Embedded Coder) | sharedCodeUpdate
(Embedded Coder) |
crossReleaseImport
(Embedded Coder)
Related Topics
- Cross-Release Shared Utility Code Reuse (Embedded Coder)
- Generate Shared Utility Code (Embedded Coder)
- Generate Shared Utility Code for Fixed-Point Functions (Embedded Coder)
- Generate Shared Utility Code for Custom Data Types (Embedded Coder)
- Integrate Generated Code by Using Cross-Release Workflow (Embedded Coder)