Metadata-Version: 2.1
Name: yakut
Version: 0.3.1
Summary: Simple CLI tool for diagnostics and debugging of UAVCAN networks.
Home-page: https://uavcan.org
Author: UAVCAN Consortium
Author-email: consortium@uavcan.org
License: MIT
Description: # Yakut
        
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        Yakút is a simple cross-platform command-line interface (CLI) tool for diagnostics and debugging of
        [UAVCAN](https://uavcan.org) networks.
        By virtue of being based on [PyUAVCAN](https://github.com/UAVCAN/pyuavcan),
        Yakut supports all UAVCAN transports (UDP, serial, CAN, ...)
        and is compatible with all major features of the protocol.
        It is designed to be usable with GNU/Linux, Windows, and macOS.
        
        Ask questions and get assistance at [forum.uavcan.org](https://forum.uavcan.org/).
        
        ## Installing
        
        First, make sure to [have Python installed](https://docs.python.org/3/using/index.html).
        Windows users are recommended to grab the official distribution from Windows Store.
        Yakut requires **Python 3.7 or newer**.
        
        Install Yakut: **`pip install yakut`**
        
        Afterward do endeavor to read the docs: **`yakut --help`**
        
        Check for new versions every now and then: **`pip install --upgrade yakut`**
        
        ### Common issues
        
        If you are experiencing illegal instruction faults on aarch64, upgrade NumPy and Cython: `pip install -U numpy cython`.
        
        ## Invoking commands
        
        Any option can be supplied either as a command-line argument or as an environment variable named like
        `YAKUT_[subcommand_]option`.
        If both are provided, command-line options take precedence over environment variables.
        You can use this feature to configure desired defaults by exporting environment variables from the
        rc-file of your shell (for bash/zsh this is `~/.bashrc`/`~/.zshrc`, for PowerShell see `$profile`).
        
        Options for the main command shall be specified before the subcommand when invoking Yakut:
        
        ```bash
        yakut --path=/the/path compile path/to/my_namespace --output=destination/directory
        ```
        
        In this example, the corresponding environment variables are `YAKUT_PATH` and `YAKUT_COMPILE_OUTPUT`.
        
        Any subcommand like `yakut compile` can be used in an abbreviated form like `yakut com`
        as long as the resulting abbreviation is unambiguous.
        
        There is a dedicated `--help` option for every subcommand.
        
        ## Compiling DSDL
        
        Suppose we have our custom DSDL namespace that we want to use.
        First, it needs to be *compiled*:
        
        ```bash
        yakut compile ~/custom_data_types/sirius_cyber_corp
        ```
        
        Some commands require the standard namespace to be available,
        so let's compile it too, along with the regulated namespace:
        
        ```bash
        yakut compile  ~/public_regulated_data_types/uavcan  ~/public_regulated_data_types/reg
        ```
        
        Compilation outputs will be stored in the current working directory, but it can be overridden if needed
        via `--output` or `YAKUT_COMPILE_OUTPUT`.
        Naturally, Yakut needs to know where the outputs are located to use them;
        by default it looks in the current directory.
        You can specify additional search locations using `--path` or`YAKUT_PATH`.
        
        A question one is likely to ask here is:
        *Why don't you ship precompiled regulated DSDL together with the tool?*
        Indeed, that would be trivial to do, but we avoid that on purpose to emphasize our commitment to
        supporting vendor-specific and regulated DSDL at the same level.
        In the past we used to give regulated namespaces special treatment,
        which caused our users to acquire misconceptions about the purpose of DSDL.
        Specifically, there have been forks of the standard namespace extended with vendor-specific types,
        which is harmful to the ecosystem.
        
        Having to manually compile the regulated namespaces is not an issue because it is just a single command to run.
        You may opt to keeping compiled namespaces that you use often somewhere in a dedicated directory and put
        `YAKUT_PATH=/your/directory` into your shell's rc-file so that you don't have to manually specify
        the path when invoking Yakut.
        Similarly, you can configure it to use that directory as the default destination for compiled DSDL:
        
        ```bash
        # bash/zsh on GNU/Linux or macOS
        export YAKUT_COMPILE_OUTPUT=~/.yakut
        export YAKUT_PATH="$YAKUT_COMPILE_OUTPUT"
        ```
        
        ```powershell
        # PowerShell on Windows
        $env:YAKUT_COMPILE_OUTPUT="$env:APPDATA\Yakut"
        $env:YAKUT_PATH="$env:YAKUT_COMPILE_OUTPUT"
        ```
        
        So that you say simply `yakut compile path/to/my_namespace`
        knowing that the outputs will be always stored to and read from a fixed place unless you override it.
        
        ## Communicating
        
        Commands that access the network need to know how to do so.
        There are two ways to configure that:
        pass registers via environment variables (this is the default),
        or pass initialization expression via `--transport`/`YAKUT_TRANSPORT` (in which case the registers are ignored).
        
        ### Configuring the transport via UAVCAN registers
        
        UAVCAN registers are named values that contain various configuration parameters of a UAVCAN application/node.
        They are extensively described in the [UAVCAN Specification](https://uavcan.org/specification).
        When starting a new process, it is possible to pass arbitrary registers via environment variables.
        
        There are certain registers that are looked at by UAVCAN nodes to determine how to connect to the network.
        Some of them are given below, but the list is not exhaustive.
        The full description of supported registers is available in the API documentation for
        [`pyuavcan.application.make_transport()`](https://pyuavcan.readthedocs.io/en/stable/api/pyuavcan.application.html#pyuavcan.application.make_transport).
        
        If the available registers define more than one transport configuration, a redundant transport will be initialized.
        
        **This initialization method requires that the standard DSDL namespace `uavcan` is compiled.**
        
        Transport |Register name        |Register type  |Environment variable name|Semantics                                          |Example environment variable value
        ----------|---------------------|---------------|-------------------------|---------------------------------------------------|------------------------------------
        All       |`uavcan.node.id`     |`natural16[1]` |`UAVCAN__NODE__ID`       |The local node-ID; anonymous if not set            |`42`
        UDP       |`uavcan.udp.iface`   |`string`       |`UAVCAN__UDP__IFACE`     |Space-separated local IPs (16 LSB set to node-ID)  |`127.9.0.0 192.168.0.0`
        Serial    |`uavcan.serial.iface`|`string`       |`UAVCAN__SERIAL__IFACE`  |Space-separated serial port names                  |`COM9 socket://127.0.0.1:50905`
        CAN       |`uavcan.can.iface`   |`string`       |`UAVCAN__CAN__IFACE`     |Space-separated CAN iface names                    |`socketcan:vcan0 pcan:PCAN_USBBUS1`
        CAN       |`uavcan.can.mtu`     |`natural16[1]` |`UAVCAN__CAN__MTU`       |Maximum transmission unit; selects Classic/FD      |`64`
        CAN       |`uavcan.can.bitrate` |`natural32[2]` |`UAVCAN__CAN__BITRATE`   |Arbitration/data segment bits per second           |`1000000 4000000`
        Loopback  |`uavcan.loopback`    |`bit[1]`       |`UAVCAN__LOOPBACK`       |Use loopback interface (only for basic testing)    |`1`
        
        ### Configuring the transport via initialization expression
        
        Being specific to this tool, this method is not compatible with the UAVCAN ecosystem at large,
        but its advantages are that it does not require the standard DSDL namespace `uavcan` to be compiled beforehand
        and it allows one to force the tool to disregard the registers if they are irrelevant in the current context.
        
        The *transport initialization expression* is passed via `--transport`/`YAKUT_TRANSPORT`.
        Here are practical examples (don't forget to add quotes around the expression):
        
        - `UDP("127.0.0.1",None)` -- UAVCAN/UDP on the local loopback interface; local node anonymous.
        
        - `UDP("192.168.0.0",456)` -- UAVCAN/UDP on the local network; local node-ID 456, local IP address 192.168.1.200.
        
        - `Serial('/dev/ttyUSB0',None)` -- UAVCAN/serial over a USB CDC ACM port; local node anonymous.
        
        - `Serial('socket://localhost:50905',123)` -- UAVCAN/serial tunneled via TCP/IP instead of a real serial port.
          The local node-ID is 123.
        
        - `CAN(can.media.socketcan.SocketCANMedia('vcan1',32),3),CAN(can.media.socketcan.SocketCANMedia('vcan2',64),3)` --
          UAVCAN/CAN over a doubly-redundant CAN FD bus using a virtual (simulated) SocketCAN interface.
          The node-ID is 3, and the MTU is 32/64 bytes, respectively.
        
        - `Loopback(2222)` -- A null-transport for testing with node-ID 2222.
        
        To learn more, read `yakut --help`.
        If there is a particular transport you use often,
        consider configuring it as the default via environment variables as shown earlier.
        
        Next there are practical examples (configuring the transport is left as an exercise to the reader).
        
        ### Publishing messages
        
        Publishing two messages synchronously twice (four messages total);
        notice how we specify the subject-ID before the data type name:
        
        ```bash
        export UAVCAN__UDP__IFACE=127.63.0.0
        export UAVCAN__NODE__ID=42
        yakut pub 33:uavcan.si.unit.angle.Scalar.1.0 'radian: 2.31' uavcan.diagnostic.Record.1.1 'text: "2.31 rad"' -N2
        ```
        
        We did not specify the subject-ID for the second subject, so Yakut defaulted to the fixed subject-ID.
        
        ### Subscribing to subjects
        
        Subscribe to subject 33 of type `uavcan.si.unit.angle.Scalar.1.0`
        to receive messages published by the above command:
        
        ```bash
        $ export UAVCAN__UDP__IFACE=127.63.0.0
        $ yakut sub 33:uavcan.si.unit.angle.Scalar.1.0
        ---
        33:
          _metadata_:
            timestamp: {system: 1608987583.298886, monotonic: 788272.540747}
            priority: nominal
            transfer_id: 0
            source_node_id: 42
          radian: 2.309999942779541
        
        ---
        33:
          _metadata_:
            timestamp: {system: 1608987583.298886, monotonic: 788272.540747}
            priority: nominal
            transfer_id: 1
            source_node_id: 42
          radian: 2.309999942779541
        ```
        
        ### Invoking RPC-services
        
        Given custom data types:
        
        ```shell
        # sirius_cyber_corp.PerformLinearLeastSquaresFit.1.0
        PointXY.1.0[<64] points
        @extent 1024 * 8
        ---
        float64 slope
        float64 y_intercept
        @sealed
        ```
        
        ```shell
        # sirius_cyber_corp.PointXY.1.0
        float16 x
        float16 y
        @sealed
        ```
        
        Suppose that there is node 42 that serves `sirius_cyber_corp.PerformLinearLeastSquaresFit.1.0` at service-ID 123:
        
        ```bash
        $ export UAVCAN__UDP__IFACE=127.63.0.0
        $ export UAVCAN__NODE__ID=42
        $ yakut compile sirius_cyber_corp
        $ yakut call 42 123:sirius_cyber_corp.PerformLinearLeastSquaresFit.1.0 'points: [{x: 10, y: 1}, {x: 20, y: 2}]'
        ---
        123:
          slope: 0.1
          y_intercept: 0.0
        ```
        
        ## Updating node software
        
        The file server command can be used to serve files,
        run a plug-and-play node-ID allocator (some embedded bootloader implementations require that),
        and automatically send software update requests `uavcan.node.ExecuteCommand` to nodes whose software is old.
        
        To demonstrate this capability, suppose that the network contains the following nodes:
        
        - nodes 1, 2 named `com.example.foo`, software 1.0
        - nodes 3, 4 named `com.example.bar`, hardware v4.2, software v3.4
        - node 5 named `com.example.baz`
        
        Software updates are distributed as atomic package files.
        In case of embedded systems, the package is usually just the firmware image,
        possibly compressed or amended with some metadata.
        For the file server this is irrelevant since it never looks inside the files it serves.
        However, the name is relevant as it shall follow a particular pattern to make the server recognize
        the file as a software package.
        The full specification is given in the command help: `yakut file-server --help`.
        
        Suppose that we have the following packages that we need to deploy:
        
        - v1.1 for nodes `com.example.foo` with any hardware
        - v3.3 for nodes `com.example.bar` with hardware v4.x
        - v3.5 for nodes `com.example.bar` with hardware v5.6 only
        - nothing for `com.example.baz`
        
        ```shell
        $ ls *.app*                       # List all software packages
        com.example.foo-1.1.app.zip       # Any hardware
        com.example.bar-4-3.3.app.pkg     # Hardware v4.x
        com.example.bar-5.6-3.5.app.bin   # Hardware v5.6 only
        ```
        
        The server rescans its root directory whenever a new node is found online,
        meaning that packages can be added/removed at runtime and the server will pick up the changes on the fly.
        Launch the server:
        
        ```shell
        $ export UAVCAN__UDP__IFACE=127.63.0.0
        $ export UAVCAN__NODE__ID=42
        $ yakut file-server --plug-and-play=allocation_table.db --update-software
        ```
        
        If there are any nodes online (or if they join the network later),
        the server will check the version of each by sending `uavcan.node.GetInfo`,
        and if a newer package is available locally, it will request the node to install it
        by sending `uavcan.node.ExecuteCommand`.
        
        In this specific case, the following will happen:
        
        - Nodes 1 and 2 will be updated to v1.1.
        - Nodes 3 and 4 will not be updated because the newer package v3.5 is incompatible with hardware v4.2,
          and the compatible version v3.3 is too old.
        - Node 5 will not be updated because there are no suitable packages.
        
        Add `--verbose` to see how exactly the decisions are made.
        
        This command can be used to implement **automatic network-wide configuration management**.
        Start the server and leave it running.
        Store all relevant packages into its root directory.
        When a node is connected or restarted, the server will automatically compare the version of its software
        against the local files and perform an update if necessary.
        Therefore, the entire network will be kept up-to-date without manual intervention.
        
Keywords: uavcan,data-bus,can-bus,ethernet,vehicular,onboard-networking,avionics,communication-protocol,cli,utility
Platform: UNKNOWN
Classifier: Environment :: Console
Classifier: Intended Audience :: Developers
Classifier: Intended Audience :: Customer Service
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Classifier: Topic :: Scientific/Engineering :: Interface Engine/Protocol Translator
Classifier: Topic :: Scientific/Engineering :: Visualization
Classifier: Topic :: Software Development :: Object Brokering
Classifier: Topic :: System :: Distributed Computing
Classifier: Topic :: System :: Networking
Classifier: Topic :: System :: Monitoring
Classifier: Topic :: Terminals
Classifier: Topic :: Utilities
Classifier: License :: OSI Approved :: MIT License
Classifier: Programming Language :: Python
Classifier: Programming Language :: Python :: 3
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