diff --git a/docs/projects.rst b/docs/projects.rst index 2cf31f23f..8e8592532 100644 --- a/docs/projects.rst +++ b/docs/projects.rst @@ -1,18 +1,35 @@ .. _projects-label: -Develop your own project +================================================ +Develop your own FEDn project ================================================ -This guide explains how a FEDn project is structured, and details how to develop your own +This guide explains how a FEDn project is structured, and details how to develop and run your own projects. +**In this article** +`Prerequisites`_ +`Overview`_ +`Build a FEDn project`_ +`Deploy a FEDn project`_ + +Prerequisites +============== + + + +Overview +========== + A FEDn project is a convention for packaging/wrapping machine learning code to be used for federated learning with FEDn. At the core, a project is a directory of files (often a Git repository), containing your machine learning code, FEDn entry points, and a specification of the runtime environment (python environment or a Docker image). The FEDn API and command-line tools provides functionality to help a user automate deployment and management of a project that follows the conventions. - -Overview ------------------------------- + + + +Build a FEDn project +===================== We recommend that projects have roughly the following folder and file structure: @@ -20,8 +37,8 @@ We recommend that projects have roughly the following folder and file structure: | ├ client | │ ├ fedn.yaml | │ ├ python_env.yaml -| │ ├ data.py | │ ├ model.py +| │ ├ data.py | │ ├ train.py | │ └ validate.py | ├ data @@ -31,30 +48,27 @@ We recommend that projects have roughly the following folder and file structure: | └ Dockerfile / docker-compose.yaml | -The ``client`` folder is commonly referred to as the *compute package*. The file ``fedn.yaml`` is the FEDn Project File. It contains information about the ``entry points``. The entry points are used by the client to compute model updates (local training) and local validations (optional) . -To run a project in FEDn, the client folder is compressed as a .tgz bundle and pushed to the FEDn controller. FEDn then manages the distribution of the compute package to each client. -Upon recipt of the package, a client will unpack it and stage it locally. +The ``client`` folder is commonly referred to as the *compute package* and it contains files with logic specific to a single client. The file ``fedn.yaml`` is the FEDn Project File and contains information about the commands that fedn will run when a client recieves a new train or validation request. These fedn commmands are referred to as ``entry points`` and there are up to four entry points in the project folder example given above that need to be specified, namely: +**build** - used for any kind of setup that needs to be done before the client starts up, such as initializing the global seed model. In the `quickstart tutorial`_, it runs model.py when called +**startup** - used immediately after the client starts up and the environment has been initalized. In the `quickstart tutorial`_, it runs data.py when invoked +**train** - runs train.py when called +**validate** - runs validate.py when called -.. image:: img/ComputePackageOverview.png - :alt: Compute package overview - :width: 100% - :align: center - -The above figure provides a logical view of how FEDn uses the compute package (client folder). When the :py:mod:`fedn.network.clients` -recieves a model update request, it calls upon a Dispatcher that looks up entry point definitions -in the compute package from the FEDn Project File. +The compute package content (client folder) +------------------------------------------- -The Project File (fedn.yaml) ------------------------------- +**The Project File (fedn.yaml)** -FEDn uses on a project file named 'fedn.yaml' to specify which entrypoints to execute when the client recieves a training or validation request, and -what environment to execute those entrypoints in. +FEDn uses a project file named 'fedn.yaml' to specify which entry points to execute when the client recieves a training or validation request, and +what environment to execute those entry points in. .. code-block:: yaml python_env: python_env.yaml entry_points: + build: + command: python model.py startup: command: python data.py train: @@ -63,7 +77,7 @@ what environment to execute those entrypoints in. command: python validate.py -**Environment** +**Environment (python_env.yaml)** It is assumed that all entry points are executable within the client runtime environment. As a user, you have two main options to specify the environment: @@ -71,174 +85,93 @@ to specify the environment: 1. Provide a ``python_env`` in the ``fedn.yaml`` file. In this case, FEDn will create an isolated virtual environment and install the project dependencies into it before starting up the client. FEDn currently supports Virtualenv environments, with packages on PyPI. 2. Manage the environment manually. Here you have several options, such as managing your own virtualenv, running in a Docker container, etc. Remove the ``python_env`` tag from ``fedn.yaml`` to handle the environment manually. -Entry Points -------------- - -There are up to four Entry Points to be specified. **build (optional):** -This entrypoint is intended to be called **once** for building artifacts such as initial seed models. However, it not limited to artifacts, and can be used for any kind of setup that needs to be done before the client starts up. - -To invoke the build entrypoint using the CLI: - -.. code-block:: bash - fedn build -- +This entry point is used for any kind of setup that **needs to be done before the client starts up**, such as initializing the global seed model, and is intended to be called **once**. **startup (optional):** -This entrypoint is called **once**, immediately after the client starts up and the environment has been initalized. -It can be used to do runtime configurations of the local execution environment. For example, in the quickstart tutorial example, -the startup entrypoint invokes a script that downloads the MNIST dataset and creates a partition to be used by that client. +Like the 'build' entry point, 'startup' is also called **once**, immediately after the client starts up and the environment has been initalized. +It can be used to do runtime configurations of the local execution environment. For example, in the `quickstart tutorial`_, +the startup entry point invokes a script that downloads the MNIST dataset and creates a partition to be used by that client. This is a convenience useful for automation of experiments and not all clients will specify such a script. + **train (mandatory):** -This entrypoint is invoked every time the client recieves a new model update request. The training entry point must be a single-input single-output (SISO) program. It will be invoked by FEDn as such: +This entry point is invoked every time the client recieves a new model update (training) request. The training entry point must be a single-input single-output (SISO) program. It will be invoked by FEDn as such: .. code-block:: python python train.py model_in model_out -where 'model_in' is the file containing the current global model to be updated, and 'model_out' is a path to write the new model update to. -Download and upload of these files are handled automatically by the FEDn client, the user only specifies how to read and parse the data contained in them (see examples) . +where 'model_in' is the **file** containing the current global model to be updated, and 'model_out' is a **path** to write the new model update to. +Download and upload of these files are handled automatically by the FEDn client, the user only specifies how to read and parse the data contained in them (see `examples`_). + +The format of the input and output files (model updates) are using numpy ndarrays. A helper instance :py:mod:`fedn.utils.helpers.plugins.numpyhelper` is used to handle the serialization and deserialization of the model updates. + **validate (optional):** -The validation entry point works in a similar was as the trainig entrypoint. It can be used to specify how a client should validate the current global +The validation entry point is invoked every time the client recieves a validation request. It can be used to specify how a client should validate the current global model on local test/validation data. It should read a model update from file, validate it (in any way suitable to the user), and write a **json file** containing validation data: .. code-block:: python python validate.py model_in validations.json - The validate entrypoint is optional. +The validate entry point is optional. -**Example train entry point** -Below is an example training entry point taken from the PyTorch getting stated project. +Deploy a FEDn project +=================== -.. code-block:: python +We recommend you to test your entry points locally before deploying your FEDn project. You can test *train* and *validate* by (example for the mnist-keras +project): - import math - import os - import sys - - import torch - from data import load_data - from model import load_parameters, save_parameters - - from fedn.utils.helpers.helpers import save_metadata - - dir_path = os.path.dirname(os.path.realpath(__file__)) - sys.path.append(os.path.abspath(dir_path)) - - - def train(in_model_path, out_model_path, data_path=None, batch_size=32, epochs=1, lr=0.01): - """ Complete a model update. - - Load model paramters from in_model_path (managed by the FEDn client), - perform a model update, and write updated paramters - to out_model_path (picked up by the FEDn client). - - :param in_model_path: The path to the input model. - :type in_model_path: str - :param out_model_path: The path to save the output model to. - :type out_model_path: str - :param data_path: The path to the data file. - :type data_path: str - :param batch_size: The batch size to use. - :type batch_size: int - :param epochs: The number of epochs to train. - :type epochs: int - :param lr: The learning rate to use. - :type lr: float - """ - # Load data - x_train, y_train = load_data(data_path) - - # Load parmeters and initialize model - model = load_parameters(in_model_path) - - # Train - optimizer = torch.optim.SGD(model.parameters(), lr=lr) - n_batches = int(math.ceil(len(x_train) / batch_size)) - criterion = torch.nn.NLLLoss() - for e in range(epochs): # epoch loop - for b in range(n_batches): # batch loop - # Retrieve current batch - batch_x = x_train[b * batch_size:(b + 1) * batch_size] - batch_y = y_train[b * batch_size:(b + 1) * batch_size] - # Train on batch - optimizer.zero_grad() - outputs = model(batch_x) - loss = criterion(outputs, batch_y) - loss.backward() - optimizer.step() - # Log - if b % 100 == 0: - print( - f"Epoch {e}/{epochs-1} | Batch: {b}/{n_batches-1} | Loss: {loss.item()}") - - # Metadata needed for aggregation server side - metadata = { - # num_examples are mandatory - 'num_examples': len(x_train), - 'batch_size': batch_size, - 'epochs': epochs, - 'lr': lr - } - - # Save JSON metadata file (mandatory) - save_metadata(metadata, out_model_path) - - # Save model update (mandatory) - save_parameters(model, out_model_path) - - - if __name__ == "__main__": - train(sys.argv[1], sys.argv[2]) - - +.. code-block:: bash -The format of the input and output files (model updates) are using numpy ndarrays. A helper instance :py:mod:`fedn.utils.helpers.plugins.numpyhelper` is used to handle the serialization and deserialization of the model updates. -The first function (_compile_model) is used to define the model architecture and creates an initial model (which is then used by _init_seed). The second function (_load_data) is used to read the data (train and test) from disk. -The third function (_save_model) is used to save the model to disk using the numpy helper module :py:mod:`fedn.utils.helpers.plugins.numpyhelper`. The fourth function (_load_model) is used to load the model from disk, again -using the pytorch helper module. The fifth function (_init_seed) is used to initialize the seed model. The sixth function (_train) is used to train the model, observe the two first arguments which will be set by the FEDn client. -The seventh function (_validate) is used to validate the model, again observe the two first arguments which will be set by the FEDn client. + python train.py ../seed.npz ../model_update.npz --data_path ../data/mnist.npz + python validate.py ../model_update.npz ../validation.json --data_path ../data/mnist.npz +Note that we here assume execution in the correct Python environment. -Build a compute package --------------------------- -To deploy a project to FEDn (Studio or pseudo-local) we simply compress the *client* folder as .tgz file. using fedn command line tool or manually: +To deploy a project to FEDn (Studio or pseudo-local) we simply compress the compute package as a .tgz file. using fedn command line tool or manually: .. code-block:: bash fedn package create --path client -The created file package.tgz can then be uploaded to the FEDn network using the :py:meth:`fedn.network.api.client.APIClient.set_package`. - +The created file package.tgz can then be uploaded to the FEDn network using the :py:meth:`fedn.network.api.client.APIClient.set_package` API. FEDn then manages the distribution of the compute package to each client. +Upon receipt of the package, a client will unpack it and stage it locally. -More on local data access -------------------------- +.. image:: img/ComputePackageOverview.png + :alt: Compute package overview + :width: 100% + :align: center -There are many possible ways to interact with the local dataset. In principle, the only requirement is that the train and validate endpoints are able to correctly -read and use the data. In practice, it is then necessary to make some assumption on the local environemnt when writing entrypoint.py. This is best explained -by looking at the code above. Here we assume that the dataset is present in a file called "mnist.npz" in a folder "data" one level up in the file hierarchy relative to -the exection of entrypoint.py. Then, independent on the preferred way to run the client (native, Docker, K8s etc) this structure needs to be maintained for this particular -compute package. Note however, that there are many ways to accompish this on a local operational level. +The above figure provides a logical view of how FEDn uses the compute package. When the :py:mod:`fedn.network.client` +recieves a model update or validation request, it calls upon a Dispatcher that looks up entry point definitions +in the compute package from the FEDn Project File to determine which code files to execute. -Testing the entry points locally ---------------------------------- +Before starting a training or validation session, the global seed model needs to be initialized which in our example is done by invoking the build entry point. -We recommend you to test your entrypoints locally before uploading the compute package to Studio. You can test *train* and *validate* by (example for the mnist-keras -project): +To invoke the build entry point using the CLI: .. code-block:: bash + fedn run build --path client + + +More on local data access +-------------------------- + +There are many possible ways to interact with the local dataset. In principle, the only requirement is that the train and validate end points are able to correctly +read and use the data. In practice, it is then necessary to make some assumption on the local environemnt when writing entrypoint.py. This is best explained +by looking at the code above. Here we assume that the dataset is present in a file called "mnist.npz" in a folder "data" one level up in the file hierarchy relative to +the execution of entrypoint.py. Then, independent of the preferred way to run the client (native, Docker, K8s etc) this structure needs to be maintained for this particular +compute package. Note however, that there are many ways to accomplish this on a local operational level. - python train.py ../seed.npz ../model_update.npz --data_path ../data/mnist.npz - python validate.py ../model_update.npz ../validation.json --data_path ../data/mnist.npz -Note that we here assume execution in the correct Python environment.