3.10. Example Generation¶
The RTI Code Generator available with Connext Micro can generate DDS example applications with a type definition file as input.
Note
Before running the RTI Code Generator, you might need to add
<Connext Micro install folder>/rtiddsgen/scripts
to your PATH environment variable.
To generate an example:
rtiddsgen -example -language <C|C++> [-namespace] <file with type definition>
This command generates an example using the default example template, which uses the Dynamic Participant Dynamic Endpoint (DPDE) discovery plugin.
rtiddsgen accepts the following options:
-example
: Generates type files, example files, and CMakelists files.-language <C|C++>
: Generates C or C++ code.-namespace
: Enables C++ namespaces when the language option is C++.
The generated example can be compiled using CMake <https://cmake.org/>_ and the CMakelists.txt file generated by the RTI Code Generator. A README.txt file is also generated with a description of the example and instructions for how to compile and run the examples.
The RTI Code Generator can also generate examples using custom templates by
using the option -exampleTemplate <templateName>
.
To generate an example using a custom template instead of the default one:
rtiddsgen -example -exampleTemplate <template name> -language <C|C++> [-namespace] <file with type definition>
To see the list of the available templates, use the following command:
rtiddsgen -showTemplates
The output from the command will look similar to this:
List of example templates per language:
- C:
- cert
- dpse
- static_udp
- waitsets
- C++:
- dpse
- waitsets
- C++ Namespace:
- dpse
- waitsets
The following command will generate an example in the C language, using the ‘waitsets’ custom template instead of the default template:
rtiddsgen -example -exampleTemplate waitsets -language C <file with type definition>
3.10.1. Description of Examples¶
All examples consist of a publication and subscription pair to send and receive the type provided by user. Two applications are compiled: one to send samples and another to receive samples.
- Default template
Discovery of endpoints is done with the dynamic-endpoint discovery. Only the UDP and INTRA transports are enabled. The subscriber application creates a DataReader, which uses a listener to receive notifications about new samples and matched publishers. These notifications are received in the middleware thread (instead of the application thread).
- cert
An example that only uses APIs that are compatible with Connext Cert.
- dpse
The only difference from the default template is that the discovery of endpoints is done with static-endpoint discovery. Static-endpoint discovery uses function calls to statically assert information about remote endpoints belonging to remote DomainParticipants.
- static_udp
The only difference from the default template is that this example uses a static UDP interface configuration. Using this API, the UDP transport is statically configured. This is useful in systems that are not able to return the installed UDP interfaces (name, IP address, mask…).
- waitsets
The only difference from the default template is that the Subscriber application creates a DataReader that uses a Waitset (instead of a listener) to receive notifications about new samples and matched publishers. These notifications are received in the middleware thread (instead of the application thread).
3.10.2. How to Compile the Generated Examples¶
Before compiling, set the environment variable RTIMEHOME to the Connext Micro installation directory.
Depending on the number of network interfaces installed on the local machine, you might need to restrict which interfaces are used by Connext Micro.
Use the option -udp_intf <interface name>
when running the example.
The Connext Micro source bundle includes rtime-make (on Linux and macOS systems) or rtime-make.bat (on Windows systems) to simplify invocation of CMake. This script is a convenient way to invoke CMake with the correct options. For example:
cd "<${envMap.idlFileName}Application directory>"
rtime-make --config <Debug|Release> --build --name x64Linux3gcc4.8.2 --target Linux --source-dir . \
-G "Unix Makefiles" --delete [-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE=true]
cd "<${envMap.idlFileName}Application directory>"
rtime-make --config <Debug|Release> --build --name x64Darwin17.3.0Clang9.0.0 --target Darwin --source-dir . \
-G "Unix Makefiles" --delete [-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE=true]
cd "<${envMap.idlFileName}Application directory>"
rtime-make.bat --config <Debug|Release> --build --name i86Win32VS2010 --target Windows --source-dir . \
-G "Visual Studio 10 2010" --delete [-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE_eq_true]
The executable can be found in the directory ‘objs’.
It is also possible to compile using CMake, e.g., when the Connext Micro source bundle is not installed.
cmake [-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE=true] [-DCMAKE_BUILD_TYPE=<Debug|Release>] -G "Unix Makefiles" \
-B./<your build directory> -H. -DRTIME_TARGET_NAME=x64Linux3gcc4.8.2"
cmake --build ./<your build directory> [--config <Debug|Release>]
cmake [-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE=true] [-DCMAKE_BUILD_TYPE=<Debug|Release>] -G "Unix Makefiles" \
-B./<your build directory> -H. -DRTIME_TARGET_NAME=x64Darwin17.3.0Clang9.0.0"
cmake --build ./<your build directory> [--config <Debug|Release>]
cmake [-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE=true] [-DCMAKE_BUILD_TYPE=<Debug|Release>] -G "Visual Studio 10 2010" \
-B./<your build directory> -H. -DRTIME_TARGET_NAME=i86Win32VS2010"
cmake --build .\<your build directory> [--config <Debug|Release>]
The executable can be found in the directory ‘objs’.
The following options are accepted:
-DRTIME_IDL_ADD_REGENERATE_TYPESUPPORT_RULE=true
adds a rule to regenerate type support plugin source files if the input file with the type definition changes. Default value is ‘false’.
3.10.3. How to Run the Generated Examples¶
By default, the example tries to guess which interfaces it should use to receive samples. This can cause communication problems if the number of available interfaces is greater than the maximum number of interfaces supported by Connext Micro. For this reason, it is recommended to restrict the number of interfaces used by the application.
Use the option -udp_intf <interface name>
when running the example.
For example, if the example has been compiled for Linux x64Linux3gcc4.8.2, run the subscriber with this command:
objs/x64Linux3gcc4.8.2/<Type definition file name>_subscriber [-domain <Domain_ID>] [-peer <address>] \
[-sleep <sleep_time>] [-count <seconds_to_run>] [-udp_intf <interface name>]
and run the publisher with this command:
objs/x64Linux3gcc4.8.2/<Type definition file name>_publisher [-domain <Domain_ID> -peer <address>] \
[-sleep <sleep_time>] [-count <seconds_to_run>] [-udp_intf <interface name>]