Subsystem
Group blocks to create model hierarchy
Libraries:
Simulink /
Commonly Used Blocks
Simulink /
Ports & Subsystems
HDL Coder /
Ports & Subsystems
Alternative Configurations of Subsystem Block:
Atomic Subsystem | Subsystem Reference | Enabled Subsystem | Triggered Subsystem | Enabled and Triggered Subsystem | ...
Description
A Subsystem block contains a subset of blocks within a model or system. The Subsystem block can represent a virtual subsystem or a nonvirtual subsystem.
Virtual subsystems help visually organize a block diagram. When you group blocks in a virtual subsystem or expand a virtual subsystem, you can affect the execution order of blocks because of the changes to the block paths. Virtual subsystems are neither conditionally nor atomically executed. Virtual subsystems do not have checksums.
Nonvirtual subsystems, also known as atomic subsystems, help functionally organize a block diagram. When you group blocks in a nonvirtual subsystem or expand a nonvirtual subsystem, you change the model behavior. Each nonvirtual subsystem executes as a single block, or atomic unit, when the parent model executes. The blocks in a nonvirtual subsystem execute consecutively.
For information on the types of nonvirtual subsystems, see Explore Types of Subsystems.
To determine whether a subsystem is virtual or nonvirtual, use either of these strategies:
Check the border of the block. A block that represents a virtual subsystem has a thin border. A block that represents a nonvirtual subsystem has a thick border.
Use the
get_param
function to query the Boolean block parameterIsSubsystemVirtual
.
The ports on a Subsystem block correspond to blocks inside the subsystem. For more information, see Connect Subsystems.
The Subsystem block supports signal label propagation through subsystem Inport and Outport blocks. For more information, see Signal Label Propagation.
Examples
Create Subsystem
You can create a subsystem by adding a Subsystem block, then adding contents to the subsystem.
Insert a Subsystem block into your model.
For example:
Open the quick-insert menu by double-clicking the Simulink® canvas.
In the search box, start typing the name of the block. For example, type
subsystem
.In the list that appears, select the block for the type of subsystem that you want to implement in your model. Use the arrow keys and press Enter or click the block.
To view or edit the contents of a subsystem, double-click the Subsystem block. To exit the subsystem, below the left end of the Simulink Toolbar, click the Back button . For more information on how to navigate the hierarchy of a model with subsystems, see Navigate Model Hierarchy.
Convert Part of Block Diagram into Subsystem
You can create a subsystem by converting part of an existing model into a subsystem.
In the Simulink canvas, drag a selection box over the model elements that you want to include in the subsystem. An ellipsis appears next to the selection box.
Pause on the ellipsis. An action bar expands.
In the action bar, click Create Subsystem or another subsystem option.
To provide an interface for signals entering and leaving the subsystem, the Subsystem block contains blocks that correspond to input and output ports.
When the selection contains blocks that correspond to input and output ports, the new subsystem includes copies of those blocks. The new subsystem does not contain copies of blocks that correspond to control ports.
Replace Subsystem with its Contents
To replace a Subsystem block with its contents, you can expand the subsystem.
Select the Subsystem block. Then, in the Simulink Toolstrip, on the Subsystem Block tab, click Expand.
The contents of the subsystem appear in an area labeled with the name of the replaced block.
For more information, see Expand Subsystem Contents.
Determine Whether Subsystem Is Virtual
To determine whether a subsystem is virtual, use the get_param
function with the Boolean block parameter IsSubsystemVirtual
.
Open the example. Then, open the SubsystemExecution
model.
open_system("SubsystemExecution");
Check whether the Subsystem block named discrete cruise controller
is virtual.
get_param("SubsystemExecution/discrete cruise controller",... "IsSubsystemVirtual")
ans = 'off'
This subsystem is nonvirtual. The thick border of the block icon indicates that the subsystem is nonvirtual.
Check whether the Subsystem block named car dynamics
is virtual.
get_param("SubsystemExecution/car dynamics","IsSubsystemVirtual")
ans = 'on'
This subsystem is virtual.
Extended Examples
Simulink Subsystem Semantics
This set of examples shows different types of Simulink® Subsystems and what semantics are used when simulating these subsystems. Each example provides a description of the model and the subtleties governing how the model is executed.
Convert Subsystem to Referenced Model
Convert a subsystem to a referenced model by using the Model Reference Conversion Advisor or the Simulink.SubSystem.convertToModelReference function.
Single Hydraulic Cylinder Simulation
Use Simulink® to model a hydraulic cylinder. You can apply these concepts to applications where you need to model hydraulic behavior.
Ports
Input
In — Signal input to subsystem
scalar | vector | matrix | array | bus
Placing a block such as an Inport or In Bus Element block in a subsystem adds an external input port to the Subsystem block.
Use Inport or In Bus Element blocks to get signals from the local environment.
For more information, see Connect Subsystems.
Data Types: half
| single
| double
| int8
| int16
| int32
| int64
| uint8
| uint16
| uint32
| uint64
| Boolean
| fixed point
| enumerated
| bus
| image
Complex Number Support: Yes
reinit — Control signal for subsystem reinitialize event
scalar
A reinitialize event port provides a function-call control signal that triggers a subsystem reinitialize event, which resets the states of the subsystem.
The subsystem must contain a Reinitialize Function block that corresponds to each subsystem reinitialize event. For more information, see Using Initialize, Reinitialize, Reset, and Terminate Functions.
To specify the port name, use the Event name parameter of the Event Listener block in the Reinitialize Function block.
Dependencies
To enable this type of port, select Show subsystem reinitialize ports.
Output
Out — Signal output from subsystem
scalar | vector | matrix | array | bus
Placing a block such as an Outport or Out Bus Element block in a subsystem adds an output port from the Subsystem block.
Use Outport or Out Bus Element blocks to send signals to the local environment.
For more information, see Connect Subsystems.
Data Types: half
| single
| double
| int8
| int16
| int32
| int64
| uint8
| uint16
| uint32
| uint64
| Boolean
| fixed point
| enumerated
| bus
| image
Complex Number Support: Yes
Parameters
To edit block parameters interactively, use the Property Inspector. From the Simulink Toolstrip, on the Simulation tab, in the Prepare gallery, select Property Inspector.
Main
Show port labels — Display options for port labels
FromPortIcon
(default) | FromPortBlockName
| SignalName
| none
Select how to display port labels on the Subsystem block icon.
none
— Do not display port labels.FromPortIcon
— If the corresponding port icon displays a signal name, display the signal name on the Subsystem block. Otherwise, display the port block name or the port number if the block name is a default name.FromPortBlockName
— Display the name of the corresponding port block on the Subsystem block.SignalName
— If the signal connected to the port is named, display the name of the signal on the Subsystem block. Otherwise, display the name of the corresponding port block.
For port label editing on Subsystem blocks, see Edit Port Labels on Subsystem Blocks.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | ShowPortLabels |
Values: | 'FromPortIcon' (default) | 'FromPortBlockName' | 'SignalName' | 'none' |
Read/Write permissions — Levels of access to contents of subsystem
ReadWrite
(default) | ReadOnly
| NoReadOrWrite
Control user access to the contents of the subsystem.
ReadWrite
— Enable opening and modification of subsystem contents.ReadOnly
— Enable opening but not modification of the subsystem. If the subsystem resides in a block library, you can create and open links to the subsystem and can make and modify local copies of the subsystem but cannot change the permissions or modify the contents of the original library instance.NoReadOrWrite
— Disable opening or modification of subsystem. If the subsystem resides in a library, you can create links to the subsystem in a model but cannot open, modify, change permissions, or create local copies of the subsystem.
You do not receive a response if you attempt to view the contents of a subsystem whose Read/Write permissions parameter is set to NoReadOrWrite
. For example, when double-clicking such a subsystem, the software does not open the subsystem and does not display any messages.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | Permissions |
Values: | 'ReadWrite' (default) | 'ReadOnly' | 'NoReadOrWrite' |
Name of error callback function — Name of function to be called if error occurs
no default
Enter the name of a function to be called if an error occurs while the software executes the subsystem.
The software passes two arguments to the function: the handle of the subsystem and a character vector that specifies the error type. If no function is specified, the software displays a generic error message if executing the subsystem causes an error.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | ErrorFcn |
Values: | '' (default) | function name in quotes |
Data Types: | char | string |
Permit hierarchical resolution — Resolution for workspace variable names
All
(default) | ExplicitOnly
| None
Select whether to resolve names of workspace variables referenced by this subsystem.
For more information, see Symbol Resolution and Symbol Resolution Process.
All
— Resolve all names of workspace variables used by this subsystem, including those used to specify block parameter values and Simulink data objects (for example,Simulink.Signal
objects).ExplicitOnly
— Resolve only names of workspace variables used to specify block parameter values, data store memory (where no block exists), signals, and states marked as “must resolve”.None
— Do not resolve any workspace variable names.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | PermitHierarchicalResolution |
Values: | 'All' (default) | 'ExplicitOnly' | 'None' |
Treat as atomic unit — Option to execute subsystem as one unit
off
| on
Selecting this parameter causes the software to treat the subsystem as a unit when determining the execution order of block methods.
off
— Treat all blocks in the subsystem as being at the same level in the model hierarchy as the subsystem when determining block method execution order. This can cause execution of methods of blocks in the subsystem to be interleaved with execution of methods of blocks outside the subsystem.on
— Treat the subsystem as a unit when determining the execution order of block methods. For example, when it needs to compute the output of the subsystem, the software invokes the output methods of all the blocks in the subsystem before invoking the output methods of other blocks at the same level as the Subsystem block.
The default value depends on the block configuration. For example, the default value
for the Subsystem block is off
. The default value for
the Atomic Subsystem block is on
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | TreatAsAtomicUnit |
Values: | 'off' | 'on' |
Show subsystem reinitialize ports — Option to display reinitialize event ports
off
(default) | on
Select this parameter to display the reinitialize event ports. Clear this parameter to remove the ports.
Dependencies
To enable this parameter, select Treat as atomic unit.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | ShowSubsystemReinitializePorts |
Values: | 'off' (default) | 'on' |
Minimize algebraic loop occurrences — Option to eliminate artificial algebraic loops
off
(default) | on
Try to eliminate any artificial algebraic loops that include the atomic subsystem
off
— Do not try to eliminate any artificial algebraic loops that include the atomic subsystem.on
— Try to eliminate any artificial algebraic loops that include the atomic subsystem.
Dependencies
To enable this parameter, select Treat as atomic unit.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | MinAlgLoopOccurrences |
Values: | 'off' (default) | 'on' |
Schedule as — Type of scheduling
Sample time
(default) | Periodic partition
| Aperiodic partition
Specify how to schedule the subsystem.
Sample time
— Specify whether all blocks in this subsystem must run at the same rate or can run at different rates.Periodic partition
— Schedule the subsystem as a periodic partition. Specify a partition name and a sample time corresponding to the rate at which the partition runs.Aperiodic partition
— Schedule the subsystem as an aperiodic partition. Specify a partition name.
Dependencies
To enable this parameter, select Treat as atomic unit.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | ScheduleAs |
Values: | 'Sample time' (default) | 'Periodic partition' | 'Aperiodic partition' |
Partition name — Name of partition
no default
Specify the name of the partition for the subsystem.
Dependencies
To enable this parameter, select Treat as atomic unit and set
Schedule as to Periodic partition
or
Aperiodic partition
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | PartitionName |
Values: | '' (default) | partition name in quotes |
Data Types: | char | string |
Sample time — Time interval
-1
(default) | [Ts 0]
Specify whether all blocks in this subsystem must run at the same rate or can run at different rates.
-1
— Inherited sample time.[Ts 0]
— Periodic sample time.
If the blocks in the subsystem can run at different rates, specify the subsystem sample time
as inherited (-1
).
If all blocks must run at the same rate, specify the sample time corresponding to this rate as the value of the Sample time parameter.
If any of the blocks in the subsystem specify a different sample time (other than
-1
or inf
), the software displays an error message
when you update or simulate the model. For example, suppose all the blocks in the subsystem
must run 5
times a second. To ensure this rate, specify the sample time of
the subsystem as 0.2
. In this example, if any of the blocks in the
subsystem specify a sample time other than 0.2
, -1
, or
inf
, the software displays an error when you update or simulate the
model.
Dependencies
To enable this parameter, select Treat as atomic unit.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | SystemSampleTime |
Values: | '-1' (default) | '[Ts 0]' |
Treat as grouped when propagating variant conditions — Option to treat subsystem as unit when propagating variant conditions
on
(default) | off
Specify whether the software treats the subsystem as a unit when propagating variant conditions from Variant Source blocks or to Variant Sink blocks.
on
— The software treats the subsystem as a unit when propagating variant conditions from Variant Source blocks or to Variant Sink blocks. For example, when the software computes the variant condition of the subsystem, the software propagates that condition to all the blocks in the subsystem.off
— The software treats all blocks in the subsystem as being at the same level in the model hierarchy as the subsystem itself when determining their variant condition.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | TreatAsGroupedWhenPropagatingVariantConditions |
Values: | 'on' (default) | 'off' |
Dependencies
To enable this parameter, clear the Treat as atomic parameter.
Code Generation
Parameters on the Code Generation tab require a Simulink Coder™ or Embedded Coder® license.
Function packaging — Code format
Auto
| Inline
| Nonreusable function
| Reusable function
Select the code format to be generated for an atomic (nonvirtual) subsystem.
Auto
— The software chooses the optimal format for you based on the type and number of instances of the subsystem that exist in the model.Inline
— The software inlines the subsystem unconditionally.Nonreusable function
— If Filename options is set toAuto
, the software packages separate functions in the model file. If File name options is set toUse subsystem name
,Use function name
, orUser specified
using different filenames, the software packages separate functions in separate files.Subsystems with this setting generate functions that might have arguments depending on the Function interface parameter setting. You can name the generated function and file using parameters Function name and File name (no extension), respectively. These functions are not reentrant.
Reusable function
— The software generates a function with arguments that allows reuse of subsystem code when a model includes multiple instances of the subsystem.This option also generates a function with arguments that allows subsystem code to be reused in the generated code of a model reference hierarchy that includes multiple instances of a subsystem across referenced models. In this case, the subsystem must be in a library.
For more information, see:
Generate Code and Executables for Individual Subsystems (Simulink Coder)
Generate Inlined Subsystem Code (Simulink Coder)
Generate Subsystem Code as Separate Function and Files (Simulink Coder)
Generate Reusable Code from Library Subsystems Shared Across Models (Simulink Coder)
The default value depends on the block configuration. For example, the default
value for the Subsystem block is Auto
.
The default value for the CodeReuseSubsystem block is
Reusable function
.
Tips
When you want multiple instances of a subsystem to be represented as one reusable function, you can designate each one of them as
Auto
or asReusable function
. Using one or the other is best, as using both creates two reusable functions, one for each designation. The outcomes of these choices differ only when reuse is not possible. SelectingAuto
does not allow control of the function or filename for the subsystem code.The
Reusable function
andAuto
options both try to determine if multiple instances of a subsystem exist and if the code can be reused. The difference between the behavior of each option is that when reuse is not possible:Auto
yields inlined code, or if circumstances prohibit inlining, separate functions for each subsystem instance.Reusable function
yields a separate function with arguments for each subsystem instance in the model.
If you select
Reusable function
while your generated code is under source control, set File name options toUse subsystem name
,Use function name
, orUser specified
. Otherwise, the names of your code files change whenever you modify your model, which prevents source control on your files.If you select an option other than
Auto
orInline
and the model configuration parameter States, the code generator produces separate output and update methods. The code generator does not take into account the Combine output and update methods for code generation and simulation specification.
Dependencies
This parameter requires a Simulink Coder license for code generation.
To enable this parameter, select Treat as atomic unit.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWSystemCode |
Values: | 'Auto' | 'Inline' | 'Nonreusable function' | 'Reusable function' |
Function name options — How to name generated function
Auto
| Use subsystem name
| User specified
Select how the software names the function it generates for the subsystem.
If you have an Embedded Coder license, you can control function names with options on the Configuration Parameter Code Generation > Identifiers pane.
Auto
— Assign a unique function name using the default naming convention,
, wheremodel
_subsystem
()model
is the name of the model andsubsystem
is the name of the subsystem, or that of an identical one when code is being reused.If you select
Reusable function
for the Function packaging parameter and a model reference hierarchy contains multiple instances of the reusable subsystem, in order to generate reusable code for the subsystem, Function name options must be set toAuto
.Use subsystem name
— Use the subsystem name as the function name. By default, the function name uses the naming convention
.model
_subsystem
When a subsystem is in a library block and the subsystem parameter Function packaging is set to
Reusable function
, if you set theUse subsystem name
option, the code generator uses the name of the library block for the subsystem function name and filename.User specified
— Enable the Function name field. Enter any legal C or C++ function name, which must be unique.
For more information, see Generate Subsystem Code as Separate Function and Files (Simulink Coder).
The default value depends on the block configuration. For example, the default
value for the Subsystem block is Auto
.
The default value for the CodeReuseSubsystem block is
Use subsystem name
.
Dependencies
This parameter requires a Simulink Coder license.
To enable this parameter, set Function packaging to
Nonreusable function
orReusable function
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWFcnNameOpts |
Values: | 'Auto' | 'Use subsystem name' | 'User specified' |
Function name — Name of function for subsystem code
no default
Specify a unique, valid C or C++ function name for subsystem code.
Use this parameter if you want to give the function a specific name instead of allowing the Simulink Coder code generator to assign its own autogenerated name or use the subsystem name. For more information, see Generate Subsystem Code as Separate Function and Files (Simulink Coder).
Dependencies
This parameter requires a Simulink Coder license.
To enable this parameter, set Function name options to
User specified
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWFcnName |
Values: | '' (default) | function name in quotes |
Data Types: | char | string |
File name options — How to name generated file
Auto
| Use subsystem name
| Use function name
| User specified
Select how the software names the separate file for the function it generates for the subsystem.
Auto
— Depending on the configuration of the subsystem and how many instances are in the model,Auto
yields different results.If the code generator does not generate a separate file for the subsystem, the subsystem code is generated within the code module generated from the subsystem parent system. If the subsystem parent is the model itself, the subsystem code is generated within
ormodel
.c
.model
.cppIf you select
Reusable function
for the Function packaging parameter and your generated code is under source control, consider specifying a File name options value other thanAuto
. This prevents the generated filename from changing due to unrelated model modifications, which is problematic for using source control to manage configurations.If you select
Reusable function
for the Function packaging parameter and a model reference hierarchy contains multiple instances of the reusable subsystem, in order to generate reusable code for the subsystem, File name options must be set toAuto
.
Use subsystem name
— The code generator generates a separate file, using the subsystem (or library block) name as the filename.When File name options is set to
Use subsystem name
, the subsystem filename is mangled if the model contains Model blocks, or if a model reference target is being generated for the model. In these situations, the filename for the subsystem consists of the subsystem name prefixed by the model name.Use function name
— The code generator uses the function name specified by Function name options as the filename.User specified
— This option enables the File name (no extension) text entry field. The code generator uses the name you enter as the filename. Enter any filename, but do not include the.c
or.cpp
(or any other) extension. This filename need not be unique.While a subsystem source filename need not be unique, you must avoid giving nonunique names that result in cyclic dependencies. For example,
sys_a.h
includessys_b.h
,sys_b.h
includessys_c.h
, andsys_c.h
includessys_a.h
.
The default value depends on the block configuration. For example, the default
value for the Subsystem block is Auto
.
The default value for the CodeReuseSubsystem block is
Use function name
.
Dependencies
This parameter requires a Simulink Coder license.
To enable this parameter, set Function packaging to
Nonreusable function
orReusable function
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWFileNameOpts |
Values: | 'Auto' | 'Use subsystem name' | 'Use function name' | 'User specified' |
File name (no extension) — Name of generated file
no default
The filename that you specify does not have to be unique. However, avoid giving
non-unique names that result in cyclic dependencies. For example,
sys_a.h
includes sys_b.h
,
sys_b.h
includes sys_c.h
, and
sys_c.h
includes sys_a.h
.
For more information, see Generate Subsystem Code as Separate Function and Files (Simulink Coder).
Dependencies
This parameter requires a Simulink Coder license.
To enable this parameter, set File name options to
User specified
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWFileName |
Values: | '' (default) | filename in quotes |
Data Types: | char | string |
Function interface — How to use arguments with generated function
void_void
(default) | Allow arguments (Optimized)
| Allow arguments (Match graphical interface)
Select how to use arguments with the generated function.
void_void
— Generate a function without arguments and pass data as global variables. For example:void subsystem_function(void)
Allow arguments (Optimized)
— Generate a function that uses arguments instead of passing data as global variables. This specification reduces global RAM. This option might reduce code size and improve execution speed and enable the code generator to apply additional optimizations. For example:void subsystem_function(real_T rtu_In1, real_T rtu_In2, real_T *rty_Out1)
In some cases, when generating optimized code, the code generator might not generate a function that has arguments.
Allow arguments (Match graphical interface)
— Generate a function interface that uses arguments that match the Subsystem graphical block interface. The generated function interface is predictable and does not change. A predictable interface can be useful for debugging and testing your code and integrating with external applications. For example, if a model has two Inport blocks and two Outport blocks, then the generated function interface is:void subsystem_function(real_T rtu_In1, real_T rtu_In2, real_T *rty_Out1, real_T *rty_Out2)
For more information, see:
Reduce Global Variables in Nonreusable Subsystem Functions (Embedded Coder)
Generate Predictable Function Interface to Match Graphical Block Interface (Embedded Coder)
Generate Modular Function Code for Nonvirtual Subsystems (Embedded Coder)
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | FunctionInterfaceSpec |
Values: | 'void_void' (default) | 'Allow arguments (Optimized)' | 'Allow arguments (Match graphical interface)' |
Function with separate data — Control code generation for subsystem
off
(default) | on
Generate subsystem function code in which the internal data for an atomic subsystem is separated from its parent model and is owned by the subsystem.
off
— Do not generate subsystem function code in which the internal data for an atomic subsystem is separated from its parent model and is owned by the subsystem.on
— Generate subsystem function code in which the internal data for an atomic subsystem is separated from its parent model and is owned by the subsystem. The subsystem data structure is declared independently from the parent model data structures. A subsystem with separate data has its own block I/O andDWork
data structure. As a result, the generated code for the subsystem is easier to trace and test. The data separation also tends to reduce the maximum size of global data structures throughout the model, because they are split into multiple data structures.
For details on how to generate modular function code for an atomic subsystem, see Generate Modular Function Code for Nonvirtual Subsystems (Embedded Coder).
For details on how to apply memory sections to atomic subsystems, see Override Default Memory Placement for Subsystem Functions and Data (Embedded Coder).
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | FunctionWithSeparateData |
Values: | 'off' (default) | 'on' |
Memory section for initialize/terminate functions — How to apply memory sections
Inherit from model
(default) | Default
| model memory
section
Select how the software applies memory sections to the subsystem initialization and termination functions.
Inherit from model
— Apply the root model memory sections to the subsystem function code.Default
— Do not apply memory sections to the subsystem system code, overriding any model-level specification.Apply one of the model memory sections to the subsystem.
Tips
The possible values vary depending on what, if any, package of memory sections you have set for the model configuration. See Control Data and Function Placement in Memory by Inserting Pragmas (Embedded Coder) and Model Configuration Parameters: Code Generation (Simulink Coder).
If you have not configured the model with a package,
Inherit from model
is the only available value. Otherwise, the list includesDefault
and all memory sections the model package contains.These options can be useful for overriding the model memory section settings for the given subsystem. For details on how to apply memory sections to atomic subsystems, see Override Default Memory Placement for Subsystem Functions and Data (Embedded Coder).
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
orReusable function
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWMemSecFuncInitTerm |
Values: | 'Inherit from model' (default) | 'Default' | model memory section in quotes |
Memory section for execution functions — How to apply memory sections
Inherit from model
(default) | Default
| model memory section
Select how Embedded Coder applies memory sections to the subsystem execution functions.
Inherit from model
— Apply the root model memory sections to the subsystem function code.Default
— Do not apply memory sections to the subsystem system code, overriding any model-level specification.Apply one of the model memory sections to the subsystem.
Tips
The possible values vary depending on what, if any, package of memory sections you have set for the model configuration. See Control Data and Function Placement in Memory by Inserting Pragmas (Embedded Coder) and Model Configuration Parameters: Code Generation (Simulink Coder).
If you have not configured the model with a package,
Inherit from model
is the only available value. Otherwise, the list includesDefault
and all memory sections the model package contains.These options can be useful for overriding the model memory section settings for the given subsystem. For details on how to apply memory sections to atomic subsystems, see Override Default Memory Placement for Subsystem Functions and Data (Embedded Coder).
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
orReusable function
.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWMemSecFuncExecute |
Values: | 'Inherit from model' (default) | 'Default' | model memory section in quotes |
Memory section for constants — How to apply memory sections
Inherit from model
(default) | Default
| model memory section
Select how the software applies memory sections to the subsystem constants.
Inherit from model
— Apply the root model memory sections to the subsystem data.Default
— Do not apply memory sections to the subsystem data, overriding any model-level specification.Apply one of the model memory sections to the subsystem.
Tips
The memory section that you specify applies to the corresponding global data structures in the generated code. For basic information about the global data structures generated for atomic subsystems, see Standard Data Structures (Simulink Coder).
The possible values vary depending on what, if any, package of memory sections you have set for the model configuration. See Control Data and Function Placement in Memory by Inserting Pragmas (Embedded Coder).
If you have not configured the model with a package,
Inherit from model
is the only available value. Otherwise, the list includesDefault
and all memory sections the model package contains.These options can be useful for overriding the model memory section settings for the given subsystem. For details on how to apply memory sections to atomic subsystems, see Override Default Memory Placement for Subsystem Functions and Data (Embedded Coder).
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
and select the Function with separate data parameter.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWMemSecDataConstants |
Values: | 'Inherit from model' (default) | 'Default' | model memory section in quotes |
Memory section for internal data — How to apply memory sections
Inherit from model
(default) | Default
| model memory section
Select how the software applies memory sections to the subsystem internal data.
Inherit from model
— Apply the root model memory sections to the subsystem data.Default
— Do not apply memory sections to the subsystem data, overriding any model-level specification.Apply one of the model memory sections to the subsystem.
Tips
The memory section that you specify applies to the corresponding global data structures in the generated code. For basic information about the global data structures generated for atomic subsystems, see Standard Data Structures (Simulink Coder).
The possible values vary depending on what, if any, package of memory sections you have set for the model configuration. See Control Data and Function Placement in Memory by Inserting Pragmas (Embedded Coder).
If you have not configured the model with a package,
Inherit from model
is the only available value. Otherwise, the list includesDefault
and all memory sections the model package contains.These options can be useful for overriding the model memory section settings for the given subsystem. For details on how to apply memory sections to atomic subsystems, see Override Default Memory Placement for Subsystem Functions and Data (Embedded Coder).
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
and select the Function with separate data parameter.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWMemSecDataInternal |
Values: | 'Inherit from model' (default) | 'Default' | model memory section in quotes |
Memory section for parameters — How to apply memory sections
Inherit from model
(default) | Default
| model memory section
Select how the software applies memory sections to the subsystem parameters.
Inherit from model
— Apply the root model memory sections to the subsystem function code.Default
— Do not apply memory sections to the subsystem system code, overriding any model-level specification.Apply one of the model memory sections to the subsystem.
Tips
The memory section that you specify applies to the corresponding global data structure in the generated code. For basic information about the global data structures generated for atomic subsystems, see Standard Data Structures (Simulink Coder).
The possible values vary depending on what, if any, package of memory sections you have set for the model configuration. See Control Data and Function Placement in Memory by Inserting Pragmas (Embedded Coder).
If you have not configured the model with a package,
Inherit from model
is the only available value. Otherwise, the list includesDefault
and all memory sections the model package contains.These options can be useful for overriding the model memory section settings for the given subsystem. For details on how to apply memory sections to atomic subsystems, see Override Default Memory Placement for Subsystem Functions and Data (Embedded Coder).
Dependencies
This parameter requires an Embedded Coder license and an ERT-based system target file.
To enable this parameter, set Function packaging to
Nonreusable function
and select the Function with separate data parameter.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | RTWMemSecDataParameters |
Values: | 'Inherit from model' (default) | 'Default' | model memory section in quotes |
Subsystem Reference
Subsystem file name — Filename of referenced subsystem
no default
Specify the subsystem file you want to reference. For information about subsystem references, see Create and Use Referenced Subsystems in Models.
Dependencies
To access this parameter, in the Subsystem Reference section, click Convert.
For more information on how to convert a subsystem to a referenced subsystem, see Convert Subsystem to a Referenced Subsystem.
Programmatic Use
To set the block parameter value programmatically, use
the set_param
function.
Parameter: | ReferencedSubsystem |
Values: | '' (default) | subsystem filename in quotes |
Data Types: | char | string |
Block Characteristics
Alternative Configurations
Atomic Subsystem — Subsystem that executes as single unit when model runs
The Atomic Subsystem block selects the Treat as atomic unit parameter.
Libraries:
Simulink /
Ports & Subsystems
HDL Coder /
Ports & Subsystems
Subsystem Reference — Reference subsystem stored in subsystem file
The Subsystem Reference block references a subsystem stored in a
subsystem file (.slx
). For more information, see Create and Use Referenced Subsystems in Models.
Libraries:
Simulink /
Ports & Subsystems
Enabled Subsystem — Subsystem whose execution is enabled by external input
The Enabled Subsystem is a template that contains an Enable block.
Libraries:
Simulink /
Ports & Subsystems
HDL Coder /
Ports & Subsystems
Triggered Subsystem — Subsystem whose execution is triggered by external input
The Triggered Subsystem is a template that
contains a Trigger block with Trigger type set to
rising
.
Libraries:
Simulink /
Ports & Subsystems
HDL Coder /
Ports & Subsystems
Enabled and Triggered Subsystem — Subsystem whose execution is enabled and triggered by external inputs
The Enabled and Triggered Subsystem is a
template that contains an Enable block and a Trigger block
with Trigger type set to
rising
.
Libraries:
Simulink /
Ports & Subsystems
Resettable Subsystem — Subsystem whose block states reset with external trigger
The Resettable Subsystem is a template that contains a Reset block.
Libraries:
Simulink /
Ports & Subsystems
If Action Subsystem — Subsystem whose execution is enabled by If block
The If Action Subsystem is a template for creating a subsystem whose execution is controlled by an If block. The subsystem contains an Action Port block.
Libraries:
Simulink /
Ports & Subsystems
Switch Case Action Subsystem — Subsystem whose execution is enabled by Switch Case block
The Switch Case Action Subsystem is a template for creating a subsystem whose execution is controlled by a Switch Case block. The subsystem contains an Action Port block.
Libraries:
Simulink /
Ports & Subsystems
Function-Call Subsystem — Subsystem whose execution is controlled by external function-call input
The Function-Call Subsystem is a template that
contains a Trigger block with Trigger type set to
function-call
.
Libraries:
Simulink /
Ports & Subsystems
For Iterator Subsystem — Repeat subsystem execution during simulation time step for specified number of iterations
The For Iterator Subsystem is a template that contains a For Iterator block.
Libraries:
Simulink /
Ports & Subsystems
While Iterator Subsystem — Repeat subsystem execution during simulation time step while logical expression is true
The While Iterator Subsystem is a template that contains a While Iterator block.
Libraries:
Simulink /
Ports & Subsystems
For Each Subsystem — Apply algorithm to individual elements or subarrays of input signals or mask parameters
The For Each Subsystem is a template that contains a For Each block.
Libraries:
Simulink /
Ports & Subsystems
HDL Coder /
Ports & Subsystems
Message Polling Subsystem — Subsystem whose execution is controlled by message input during periodic checks
The Message Polling
Subsystem is a template that contains a Trigger block with
Trigger type set to message
and
Trigger time set to on sample time
hit
. The Trigger block replaces the Inport
block.
Libraries:
Simulink /
Messages & Events
Message Triggered Subsystem — Subsystem whose execution is controlled by message input
The Message Triggered
Subsystem is a template that contains a Trigger block with
Trigger type set to message
and
Trigger time set to on message
available
. The Trigger block replaces the
Inport block.
Libraries:
Simulink /
Messages & Events
CodeReuseSubsystem — Subsystem that specifies reusable function as code generation format
The CodeReuseSubsystem block selects the Treat as atomic
unit parameter and sets Function packaging to
Reusable function
.
Libraries:
Simulink /
Ports & Subsystems
Neighborhood Processing Subsystem — Create algorithm that follows the neighborhood pattern
The Neighborhood Processing Subsystem is a template that contains a Neighborhood block.
Libraries:
Simulink /
Matrix Operations
Tips
A signal viewing subsystem is an atomic subsystem that encapsulates processing and viewing of signals received from the target system in External mode. To specify an atomic subsystem as a signal viewing subsystem, set
SimViewingDevice
to'on'
. For more information, see Signal Viewing Subsystems (Simulink Coder).
Extended Capabilities
C/C++ Code Generation
Generate C and C++ code using Simulink® Coder™.
Actual code generation support depends on block implementation.
HDL Code Generation
Generate VHDL, Verilog and SystemVerilog code for FPGA and ASIC designs using HDL Coder™.
HDL Coder™ provides additional configuration options that affect HDL implementation and synthesized logic.
Architecture | Description |
---|---|
Module (default) | Generate code for the subsystem and the blocks within the subsystem. |
BlackBox | Generate a black box interface. The generated HDL code includes only the input/output port definitions for the subsystem. Therefore, you can use a subsystem in your model to generate an interface to existing, manually written HDL code. The black-box interface generation for subsystems is similar to the Model block interface generation without the clock signals. |
| Remove the subsystem from the generated code. You can use the subsystem in simulation, however, treat it as a “no-op” in the HDL code. |
For the BlackBox
architecture, you
can customize port names and set attributes of the external component
interface. See Customize Black Box or HDL Cosimulation Interface (HDL Coder).
General | |
---|---|
AdaptivePipelining | Automatic pipeline insertion based on the synthesis tool, target frequency, and
multiplier word-lengths. The default is |
ClockRatePipelining | Insert pipeline registers at a faster clock rate instead of the slower data rate. The
default is |
ConstrainedOutputPipeline | Number of registers to place at
the outputs by moving existing delays within your design. Distributed
pipelining does not redistribute these registers. The default is
|
DistributedPipelining | Pipeline register distribution,
or register retiming. The default is |
DSPStyle | Synthesis attributes for multiplier mapping. The default is |
FlattenHierarchy | Remove subsystem hierarchy from generated HDL code. The default
is |
InputPipeline | Number of input pipeline stages
to insert in the generated code. Distributed pipelining and constrained
output pipelining can move these registers. The default is
|
OutputPipeline | Number of output pipeline stages
to insert in the generated code. Distributed pipelining and constrained
output pipelining can move these registers. The default is
|
SharingFactor | Number of functionally equivalent resources to map to a single shared resource. The default is 0. See also Resource Sharing (HDL Coder). |
StreamingFactor | Number of parallel data paths, or vectors, that are time multiplexed to transform into serial, scalar data paths. The default is 0, which implements fully parallel data paths. See also Streaming (HDL Coder). |
If this block is not the DUT, the block property settings in the Target
Specification tab are ignored. In the HDL Workflow Advisor, if you use the
IP Core Generation workflow, these target specification block
property values are saved with the model. If you specify these target specification block
property values using hdlset_param
, when you open HDL Workflow Advisor,
the fields are populated with the corresponding values.
Target Specification | |
---|---|
AdditionalTargetInterfaces |
Additional target interfaces, specified as a character vector. To save this block property on the model, in the Set Target Interface task of the IP Core Generation workflow, corresponding to the DUT ports that you want to add more interfaces, select Add more.... You can then add more interfaces in the Add New Target Interfaces dialog box. Specify the type of interface, number of additional interfaces, and a unique name for each additional interface. Values: Example:
|
ProcessorFPGASynchronization | Processor/FPGA synchronization mode, specified as a character vector. To save this block property on the model, specify the Processor/FPGA Synchronization in the Set Target Interface task of the IP Core Generation workflow. Values: Example: |
TestPointMapping | To save this block property on the model, specify the mapping of test point ports to target platform interfaces in the Set Target Interface task of the IP Core Generation workflow. Values: Example: |
TunableParameterMapping | To save this block property on the model, specify the mapping of tunable parameter ports to target platform interfaces in the Set Target Interface task of the IP Core Generation workflow. Values: Example: |
AXI4RegisterReadback | To save this block property on the model, specify whether you want to enable readback on AXI4 subordinate write registers in the Generate RTL Code and IP Core task of the IP Core Generation workflow. To learn more, see Model Design for AXI4 Slave Interface Generation (HDL Coder). Values: |
AXI4SlaveIDWidth |
To save this block property on the model, specify the number of AXI manager interfaces that you want to connect the DUT IP core to by using the AXI4 Slave ID Width setting in the Generate RTL Code and IP Core task of the IP Core Generation workflow. To learn more, see Define Multiple AXI Master Interfaces in Reference Designs to Access DUT AXI4 Slave Interface (HDL Coder). Values: |
RegisterInterfaceReadPipeline |
To save this block property on the model, Specify the number of pipeline stages to insert in the read address decoder path by using the Register interface read pipeline setting in the Generate RTL Code and IP Core task of the IP Core Generation workflow. To learn more, see Model Design for AXI4 Slave Interface Generation (HDL Coder). Values: |
GenerateDefaultAXI4Slave | To save this block property on the model, specify whether you want to disable generation of default AXI4 subordinate interfaces in the Generate RTL Code and IP Core task of the IP Core Generation workflow. Values: |
IPCoreAdditionalFiles | Verilog®, SystemVerilog, or VHDL® files for black boxes in your design. Specify the full path to each file, and separate file names with a semicolon (;). You can set this property in the HDL Workflow Advisor, in the Additional source files field. Values: Example: |
IPCoreName | IP core name, specified as a character vector. You can set this property in the HDL Workflow Advisor, in the IP core name field. If this property is set to the default value, the HDL Workflow Advisor constructs the IP core name based on the name of the DUT. Values: Example: |
IPCoreVersion | IP core version number, specified as a character vector. You can set this property in the HDL Workflow Advisor, in the IP core version field. If this property is set to the default value, the HDL Workflow Advisor sets the IP core version. Values: Example: |
IPDataCaptureBufferSize |
FPGA Data Capture buffer size, specified as a character vector. Use FPGA Data Capture to observe signals in a design when running on an FPGA. The buffer size uses values that are 128*2^n, where n is an integer. By default, the buffer size is 128 (n=0). The maximum value of n is 13, which means that the maximum value for buffer size is 1048576 (=128*2^13). Values: Example: |
To generate HDL code for models that contain Subsystem blocks:
In the Configuration Parameters dialog box, click Diagnostics, and set the Algebraic loop parameter to
none
orwarning
.Open the block mask for the Subsystem block and select the Treat as atomic unit and Minimize algebraic loop occurrences parameters.
If your DUT is a masked subsystem, you can generate code only if it is at the top level of the model.
For more information, see:
External Component Interfaces (HDL Coder)
Generate Black Box Interface for Subsystem (HDL Coder)
PLC Code Generation
Generate Structured Text code using Simulink® PLC Coder™.
Subsystem must be atomic to support PLC code generation.
UseExternalDefinition | Suppress block definition in generated code. The default is
|
Fixed-Point Conversion
Design and simulate fixed-point systems using Fixed-Point Designer™.
Actual data type support depends on block implementation.
Version History
Introduced in R2007a
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