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Robometry

Continuous Integration

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Telemetry suite for logging data from your robot 🤖.

Tested OSes

  • Windows 10
  • Ubuntu 20.04, 22.04
  • macOS >= 10.15

Installation from binaries

Conda packages

It is possible to install on linux, macOS and Windows via conda, just running:

conda install -c conda-forge librobometry

Installation from sources

Dependencies

The dependencies are:

The optional dependencies are:

Linux/macOS

git clone https://github.com/robotology/robometry
cd robometry
mkdir build && cd build
cmake ../
make
[sudo] make install

Notice: sudo is not necessary if you specify the CMAKE_INSTALL_PREFIX. In this case it is necessary to add in the .bashrc or .bash_profile the following lines:

export robometry_DIR=/path/where/you/installed/

Windows

With IDE build tool facilities, such as Visual Studio:

git clone https://github.com/robotology/robometry
cd robometry
mkdir build && cd build
cmake ..
cmake --build . --target ALL_BUILD --config Release
cmake --build . --target INSTALL --config Release

In order to allow CMake finding robometry, you have to specify the path where you installed in the CMAKE_PREFIX_PATH or exporting the robometry_DIR env variable pointing to the same path.

librobometry

In order to use this library in your own application, add this lines in your CMakeLists.txt

find_package(robometry)

add_executable(myApp)
target_link_libraries(myApp robometry::robometry)

Example scalar variable

Here is the code snippet for dumping in a .mat file 3 samples of the scalar variables "one" and "two". The type of the channel is inferred when pushing the first time

    robometry::BufferConfig bufferConfig;

    // We use the default config, setting only the number of samples (no auto/periodic saving)
    bufferConfig.n_samples = n_samples;

    robometry::BufferManager bm(bufferConfig);
    bm.setFileName("buffer_manager_test");
    robometry::ChannelInfo var_one{ "one", {1} };
    robometry::ChannelInfo var_two{ "two", {1} };

    bool ok = bm.addChannel(var_one);
    ok = ok && bm.addChannel(var_two);
    if (!ok) {
        std::cout << "Problem adding variables...."<<std::endl;
        return 1;
    }

    for (int i = 0; i < 3; i++) {
        bm.push_back(i , "one");
        std::this_thread::sleep_for(std::chrono::milliseconds(200));
        bm.push_back(i + 1.0, "two");
    }

    if (bm.saveToFile())
        std::cout << "File saved correctly!" << std::endl;
    else
        std::cout << "Something went wrong..." << std::endl;

And here is the resulting .mat file:

buffer_manager_test =

  struct with fields:

    description_list: {[1×0 char]}
                 two: [1×1 struct]
                 one: [1×1 struct]


buffer_manager_test.one =

  struct with fields:

              data: [1×3 int32]
        dimensions: [1 3]
    elements_names: {'element_0'}
  units_of_measure: {'n.d.'}
              name: 'one'
        timestamps: [1.6481e+09 1.6481e+09 1.6481e+09]

Example vector variable

It is possible to save and dump also vector variables. Here is the code snippet for dumping in a .mat file 3 samples of the 4x1 vector variables "one" and "two".

    robometry::BufferConfig bufferConfig;
    bufferConfig.auto_save = true; // It will save when invoking the destructor
    bufferConfig.channels = { {"one", {4,1}, {}, {"meters"}}, {"two", {4,1}, {}, {"degrees"}} };
    bufferConfig.filename = "buffer_manager_test_vector";
    bufferConfig.n_samples = 3;

    robometry::BufferManager bm_v(bufferConfig); //Only vectors of doubles are accepted
    for (int i = 0; i < 3; i++) {
        bm_v.push_back({ i+1.0, i+2.0, i+3.0, i+4.0  }, "one");
        std::this_thread::sleep_for(std::chrono::milliseconds(200));
        bm_v.push_back({ (double)i, i*2.0, i*3.0, i*4.0 }, "two");
    }
buffer_manager_test_vector =

  struct with fields:

    description_list: {[1×0 char]}
                 two: [1×1 struct]
                 one: [1×1 struct]


>> buffer_manager_test_vector.one

ans =

  struct with fields:

              data: [4×1×3 double]
        dimensions: [4 1 3]
    elements_names: {4×1 cell}
  units_of_measure: {4×1 cell}
              name: 'one'
        timestamps: [1.6481e+09 1.6481e+09 1.6481e+09]


>> buffer_manager_test_vector.one.elements_names

ans =

  4×1 cell array

    {'element_0'}
    {'element_1'}
    {'element_2'}
    {'element_3'}

>> buffer_manager_test_vector.one.units_of_measure

ans =

  4×1 cell array

    {'m'}
    {'m'}
    {'m'}
    {'m'}

It is also possible to specify the name of the elements of each variable with

robometry::ChannelInfo var_one{ "one", {4,1}, {"A", "B", "C", "D"}, {"m", "cm", "mm", "nm"}};

Example matrix variable

Here is the code snippet for dumping in a .mat file 3 samples of the 2x3 matrix variable"one" and of the 3x2 matrix variable "two". BufferManager expects all the inputs to be of vector types, but then input is remapped into a matrix of the specified type.

    robometry::BufferManager bm_m;
    bm_m.resize(3);
    bm_m.setFileName("buffer_manager_test_matrix");
    bm_m.enablePeriodicSave(0.1); // This will try to save a file each 0.1 sec
    bm_m.setDefaultPath("/my/preferred/path");
    bm_m.setDescriptionList({"head", "left_arm"});
    std::vector<robometry::ChannelInfo> vars{ { "one",{2,3} },
                                                    { "two",{3,2} } };

    bool ok = bm_m.addChannels(vars);
    if (!ok) {
        std::cout << "Problem adding variables...."<<std::endl;
        return 1;
    }

    for (int i = 0; i < 3; i++) {
        bm_m.push_back({ i + 1, i + 2, i + 3, i + 4, i + 5, i + 6 }, "one");
        std::this_thread::sleep_for(std::chrono::milliseconds(200));
        bm_m.push_back({ i * 1, i * 2, i * 3, i * 4, i * 5, i * 6 }, "two");
    }
>> buffer_manager_test_matrix.one

ans =

  struct with fields:

          data: [2×3×3 int32]
    dimensions: [2 3 3]
          name: 'one'
    timestamps: [112104.7605783 112104.9608881 112105.1611651]

Example nested struct

It is possible to save and dump vectors and matrices into nested mat structures. To add an element into the matlab struct the you should use the separator ::. For instance the to store a vector in A.B.C.my_vector you should define the channel name as A::B::C::my_vector Here is the code snippet for dumping in a .mat file 3 samples of the 4x1 vector variables "one" and "two" into struct1 and struct2.

    robometry::BufferConfig bufferConfig;
    bufferConfig.auto_save = true; // It will save when invoking the destructor
    bufferConfig.channels = { {"struct1::one",{4,1}}, {"struct1::two",{4,1}}, {"struct2::one",{4,1}} }; // Definition of the elements into substruct
    bufferConfig.filename = "buffer_manager_test_nested_vector";
    bufferConfig.n_samples = 3;

    robometry::BufferManager bm_v(bufferConfig);
    for (int i = 0; i < 3; i++) {
        bm_v.push_back({ i+1.0, i+2.0, i+3.0, i+4.0  }, "struct1::one");
        std::this_thread::sleep_for(std::chrono::milliseconds(200));
        bm_v.push_back({ (double)i, i*2.0, i*3.0, i*4.0 }, "struct1::two");
        std::this_thread::sleep_for(std::chrono::milliseconds(200));
        bm_v.push_back({ (double)i, i/2.0, i/3.0, i/4.0 }, "struct2::one");
    }
buffer_manager_test_nested_vector =

  struct with fields:

    description_list: {[1×0 char]}
             struct2: [1×1 struct]
             struct1: [1×1 struct]

>> buffer_manager_test_nested_vector.struct1

ans =

  struct with fields:

    two: [1×1 struct]
    one: [1×1 struct]

>> buffer_manager_test_nested_vector.struct1.one

ans =

  struct with fields:

          data: [4×1×3 double]
    dimensions: [4 1 3]
          name: 'one'
    timestamps: [1.6415e+09 1.6415e+09 1.6415e+09]

Example multiple types

BufferManager can be used to store channels of different types, including structs. In order to store a struct, it is necessary to use the VISITABLE_STRUCT macro (see https://github.com/garbageslam/visit_struct). The available conversions depend on matio-cpp.

struct testStruct
{
    int a;
    double b;
};
VISITABLE_STRUCT(testStruct, a, b);

...

    robometry::BufferManager bm;
    robometry::BufferConfig bufferConfig;

    robometry::ChannelInfo var_int{ "int_channel", {1}};
    robometry::ChannelInfo var_double{ "double_channel", {1}};
    robometry::ChannelInfo var_string{ "string_channel", {1}};
    robometry::ChannelInfo var_vector{ "vector_channel", {4, 1}};
    robometry::ChannelInfo var_struct{ "struct_channel", {1}};

    bm.addChannel(var_int);
    bm.addChannel(var_double);
    bm.addChannel(var_string);
    bm.addChannel(var_vector);
    bm.addChannel(var_struct);

    bufferConfig.n_samples = 3;
    bufferConfig.filename = "buffer_manager_test_multiple_types";
    bufferConfig.auto_save = true;

    bm.configure(bufferConfig);

    testStruct item;

    for (int i = 0; i < 3; i++) {
        bm.push_back(i, "int_channel");
        bm.push_back(i * 1.0, "double_channel");
        bm.push_back("iter" + std::to_string(i), "string_channel");
        bm.push_back({i + 0.0, i + 1.0, i + 2.0, i + 3.0}, "vector_channel");
        item.a = i;
        item.b = i;
        bm.push_back(item, "struct_channel");

        std::this_thread::sleep_for(std::chrono::milliseconds(10));
    }
}

The above snippet of code generates channels of different types. It produces the following output.

>> buffer_manager_test_multiple_types

buffer_manager_test_multiple_types =

  struct with fields:

    description_list: {[1×0 char]}
     yarp_robot_name: [1×0 char]
      struct_channel: [1×1 struct]
      vector_channel: [1×1 struct]
      string_channel: [1×1 struct]
      double_channel: [1×1 struct]
         int_channel: [1×1 struct]

>> buffer_manager_test_multiple_types.string_channel

ans =

  struct with fields:

              data: {1×3 cell}
        dimensions: [1 3]
    elements_names: {'element_0'}
  units_of_measure: {'n.d.'}
              name: 'string_channel'
        timestamps: [1.6512e+09 1.6512e+09 1.6512e+09]

>> buffer_manager_test_multiple_types.vector_channel

ans =

  struct with fields:

              data: [4×1×3 double]
        dimensions: [4 1 3]
    elements_names: {4×1 cell}
  units_of_measure: {'n.d.'}
              name: 'vector_channel'
        timestamps: [1.6512e+09 1.6512e+09 1.6512e+09]

Example additional callback

BufferManager can call an additional callback every time the save function is called. The following example define a custom callback that saves a dummy txt file along with the mat saved by the telemetry

bool myCallback(const std::string& file_name, const SaveCallbackSaveMethod& method) {
  std::string file_name_with_extension = file_name + ".txt";
  std::ofstream my_file(file_name_with_extension.c_str());

  // Write to the file
  my_file << "Dummy file!";

  // Close the file
  my_file.close();

  return true;
};


robometry::BufferManager bm;
bm.setSaveCallback(myCallback);

Example configuration file

It is possible to load the configuration of a BufferManager from a json file

   robometry::BufferManager bm;
   robometry::BufferConfig bufferConfig;
   bool ok = bufferConfigFromJson(bufferConfig,"test_json.json");
   ok = ok && bm.configure(bufferConfig);

Where the file has to have this format:

{
  "yarp_robot_name": "robot",
  "description_list": [
    "This is a test",
    "Or it isn't?"
  ],
  "path":"/my/preferred/path",
  "filename": "buffer_manager_test_conf_file",
  "n_samples": 20,
  "save_period": 1.0,
  "data_threshold": 10,
  "auto_save": true,
  "save_periodically": true,
  "channels": [
    {
      "dimensions": [1,1],
      "elements_names": ["element_0"],
      "name": "one",
      "units_of_measure": ["meters"]
    },
    {
      "dimensions": [1,1],
      "elements_names": ["element_0"],
      "name": "two",
      "units_of_measure": ["degrees"]
    }
  ],
  "enable_compression": true,
  "file_indexing": "%Y_%m_%d_%H_%M_%S",
  "mat_file_version": "v7_3"
}

The configuration can be saved to a json file

    robometry::BufferConfig bufferConfig;
    bufferConfig.n_samples = 10;
    bufferConfig.save_period = 0.1; //seconds
    bufferConfig.data_threshold = 5;
    bufferConfig.save_periodically = true;
    std::vector<robometry::ChannelInfo> vars{ { "one",{2,3} },
                                                    { "two",{3,2} } };
    bufferConfig.channels = vars;

    auto ok = bufferConfigToJson(bufferConfig, "test_json_write.json");

TelemetryDeviceDumper

The telemetryDeviceDumper is a yarp device that has to be launched through the yarprobotinterface for dumping quantities from your robot(e.g. encoders, velocities etc.) in base of what specified in the configuration. It currently needs icub-main version equal or higher than 2.7.0 Specificially this is needed when enabling the parameter logIRawValuesPublisher, which is used for dumping any type of raw data values coming from the low level, e.g. raw encoder data.

Export the env variables

  • Add ${CMAKE_INSTALL_PREFIX}/share/yarp (where ${CMAKE_INSTALL_PREFIX} needs to be substituted to the directory that you choose as the CMAKE_INSTALL_PREFIX) to your YARP_DATA_DIRS environment variable (for more on the YARP_DATA_DIRS env variable, see YARP documentation on data directories ).
  • Once you do that, you should be able to find the telemetryDeviceDumper device compiled by this repo using the command yarp plugin telemetryDeviceDumper, which should have an output similar to:
Yes, this is a YARP plugin
  * library:        CMAKE_INSTALL_PREFIX/lib/yarp/yarp_telemetryDeviceDumper.dll
  * system version: 5
  * class name:     robometry::TelemetryDeviceDumper
  * base class:     yarp::dev::DeviceDriver

If this is not the case, there could be some problems in finding the plugin. In that case, just move yourself to the ${CMAKE_INSTALL_PREFIX}/share/yarp directory and launch the device from there.

Further documentation about the configuration parameters and the mapping of the variables inside the .mat file can be browsed here

Contributing

Pull requests are welcome. For major changes, please open an issue first to discuss what you would like to change.

License

See License