# Prerequisites
-- An AGL system installed with a Chinook version.
+* An AGL system installed with latest Daring Dab version with latest Application
+framework version >= 0.6.
-- Make sure you built the AGL generator else you will not be able to generate custom low-level CAN binding. Generator can be found [here](http://github.com/iotbzh/can-config-generator) with the attached instruction to install and run it. It will produce a *configuration-generated.cpp* file to paste in the source, *src/*, directory.
+* Make sure you built the AGL generator else you will not be able to generate custom low-level CAN binding.
-- Make sure you already set up the AGL SDK using the following [guide](http://docs.iot.bzh/docs/getting_started/en/dev/reference/setup-sdk-environment.html).
+It will produce a _application-generated.cpp_ file to paste in the source, _CAN-binder/low-can-binding/binding/_, directory.
-To get the correct SDK version installed, you **must** prepare your environment with the **chinook-next** version. To do so, run the following command in your docker image:
+* Make sure you already set up the AGL SDK using the following [Download or Build Your SDK Installer](../../../getting_started/reference/getting-started/app-workflow-sdk.html). Alternatively, please refer to official guides available on [AGL Developer Site](../../../devguides).
+
+If you need to have the graphic stack inside your SDK, you have to prepare your environment with the **iotbzh**, or **Daring Dab** flavor using _prepare_meta_ tool. To do so, run the following command in your docker image in the step 4 in place of `... [ prepare build environment ] ...`:
+
+> **NOTE** These commands assume that proprietary graphic drivers for Renesas Porter board are located in _/home/devel/share/proprietary-renesas-rcar_ directory.
```bash
-$ prepare_meta -f chinook-next -o /xdt -l /home/devel/mirror -p /home/devel/share/proprietary-renesas-rcar/ -t porter -e wipeconfig -e rm_work
+prepare_meta -f iotbzh -o /xdt -l /home/devel/mirror -p /home/devel/share/proprietary-renesas-rcar/ -t m3ulcb -e wipeconfig -e rm_work -e cleartemp
+/xdt/build/m3ulcb/agl-init-build-env
```
-- Check that you updated git submodules, executing the following commands from this repository:
+* (Optionnal) An [USB CAN adapter](https://shop.8devices.com/index.php?route=product/product&path=67&product_id=54) connected to connector through the [right cable](https://www.mouser.fr/ProductDetail/EasySync/OBD-M-DB9-F-ES?qs=pLQRQR43dtrcAQQLCUAIxA%3D%3D) if you want to connect to a real car through the OBD2 connector.
+
+<!-- pagebreak -->
+
+# Getting started
+
+## CAN config generator usage
+
+### Build requirements
+
+* CMake version 3.3 or later
+* G++, Clang++ or any C++11 compliant compiler.
+
+### Compile
```bash
-$ git submodule init
-$ git submodule update
+source /xdt/sdk/environment-setup-aarch64-agl-linux
+export PATH=$PATH:/xdt/sdk/sysroots/x86_64-aglsdk-linux/usr/bin
+export WD=$(pwd)
+git clone --recursive https://gerrit.automotivelinux.org/gerrit/apps/agl-service-can-low-level -b Renesas_delivery_Q2
+git clone --recursive https://gerrit.automotivelinux.org/gerrit/apps/low-level-can-generator
+cd ${WD}/low-level-can-generator
+mkdir -p build
+cd build
+cmake -G "Unix Makefiles" ..
+make
```
-- An [USB CAN adapter](http://shop.8devices.com/usb2can) connected to OBD2 connector through the [right cable](http://www.obd2cables.com/).
+### Naming convention
-# Getting started
+We chose a doted naming convention because it's a well know schema.
-## Compile and install the binding
+It separates and organize names into hierarchy. From the left to right, you describe your names using the more common ancestor at the left then more you go to the right the more it will be accurate.
+
+Let's take an example, here is an example about standard PID name following this convention:
+
+```
+engine.load
+engine.coolant.temperature
+fuel.pressure
+intake.manifold.pressure
+engine.speed
+vehicle.speed
+intake.air.temperature
+mass.airflow
+throttle.position
+running.time
+EGR.error
+fuel.level
+barometric.pressure
+commanded.throttle.position
+ethanol.fuel.percentage
+accelerator.pedal.position
+hybrid.battery-pack.remaining.life
+engine.oil.temperature
+engine.torque
+```
+
+> **NOTE** It's recommended that you follow this naming convention to named your CAN signals.
+>
+> There is only character `*` that is forbidden in names because it's used as wildcard for subscription and unsubscription.
+>
+> This described in the below chapter.
+
+### Available decoder
+
+You can use some basic decoder provided by default by the binding which are:
+
+* ***decoder_t::decode_noop*** : Default decoder if not specified, return raw value from signal's bitfield.
+* ***decoder_t::decode_boolean*** : Coerces a numerical value to a boolean.
+* ***decoder_t::decode_state*** : Find and return the corresponding string state for a CAN signal's raw integer value.
+
+### Generating JSON from Vector CANoe Database
+
+> **CAUTION** This chapter has not been tested since it haven't necessary automotive tools for that.
-With an AGL SDK environment correctly configured, I suggest you to set the TARGET variable in the root CMakeLists.txt file, if you have an AGL target already running in your network.
+If you use CANoe to store your `gold standard` CAN signal definitions, you may be able to use the OpenXC `xml_to_json.py` script to make your JSON for you. First, export the Canoe .dbc file as XML - you can do this with Vector CANdb++. Next, create a JSON file according to the format defined above, but only define:
-Then you can directly build and install the binding and source directory on your target system.
+* CAN messages.
+* Name of CAN signals within messages and their generic_name.
+* Optionnaly name of diagnostic messages and their name.
-Execute these commands to get your binding compile :
+To install the OpenXC utilities and runs `xml_to_json.py` script:
```bash
-$ mkdir build
-$ cd build
-$ cmake ..
-$ make
+sudo pip install openxc
+cd /usr/local/lib/python2.7/dist-packages/openxc/generator
```
-And if you have set TARGET variable, you can install it on your AGL system :
+Assuming the data exported from Vector is in `signals.xml` and your minimal mapping file is `mapping.json`, run the script:
```bash
-$ make install
-[ 16%] Built target bitfield
-[ 27%] Built target isotp
-[ 40%] Built target openxc
-[ 48%] Built target uds
-[ 97%] Built target low-can-binding
-[100%] Built target widget
-Install the project...
--- Install configuration: ""
-true
-{ "added": "low-can-binding@0.1" }
+python -m openxc.utils ./xml_to_json.py signals.xml mapping.json signals.json
```
-It's possible that you'll see the following message :
+The script scans `mapping.json` to identify the CAN messages and signals that you want to use from the XML file. It pulls the neccessary details of the messages (bit position, bit size, offset, etc) and outputs the resulting subset as JSON into the output file, `signals.json`.
+
+The resulting file together with `mapping.json` will work as input to the code generation script.
+
+### Generate your config file
+
+To generate your config file you just have to run the generator using the `-m` option to specify your JSON file.
```bash
-Error org.freedesktop.DBus.Error.Failed: "system error"
+./can-config-generator -m ../tests/basic.json -o application-generated.cpp
```
-It's because installation remove the binding before installing it.
+If you omit the `-o` option, then code is generated on the stdout.
+You also can specify a header and a footer file.
+These files must be valid C++ fragment as long as they will be inserted as is.
+Use the `-h` option to display help.
+
+> **CAUTION:** Each `diagnostic_message` must define the same `bus` as the binding will use only one bus.
+
+### Supported OpenXC items
+
+About now, compliance with OpenXC reference is in progress, can-config-generator and CAN\_signaling will implement them soon.
+`initializers`, `loopers`, `commands` and `handlers` nodes are ignored for now.
+
+This generator will follow OpenXC support status of the low level CAN signaling binding.
+
+> **NOTE**: The `buses` item will not be supported by this generator because the binding use another way to declare and configure buses. Please refer to the binding's documentation.
+
+## Compile and install the binding
+
+### Build requirements
-If it is the first time that you make the installation then you'll have this message in place of ***true***.
+* Kernel >= 4.8
+* CMake version 3.3 or later
+* G++, Clang++ or any C++11 compliant compiler.
+
+### Compile
+
+Clone the binding repository, copy the generated file and updated the git submodules.
+
+Execute the following commands from this repository:
+
+```bash
+cd ${WD}/agl-service-can-low-level
+cp ${WD}/low-level-can-generator/build/application-generated.cpp ../low-can-binding/binding
+```
+
+### Installation
+
+```bash
+cd ${WD}/agl-service-can-low-level
+mkdir build
+cd build
+cmake ..
+make
+make widget
+```
-To install it manually, you need to copy the *low-can-binding.wgt* file on your target, then from it execute the following commands :
+To install it manually, you need to copy the _low-can-service.wgt_ file on your target, then from it execute the following commands :
On your host, to copy over the network :
```bash
-$ scp low-can-binding.wgt root@<target_IP>:~
+scp low-can-service.wgt root@<target_IP>:~
```
-On the target, assuming ***wgt*** file is in the root home directory :
+On the target, assuming _**wgt**_ file is in the root home directory:
```bash
-~# afm-util install low-can-binding.wgt
-{ "added": "low-can-binding@0.1" }
+afm-util install low-can-service.wgt
+{ "added": "low-can-service@4.0" }
```
Code Review / apps / agl-service-can-low-level.git / blobdiff