# PaddlePaddle API ## Ingredients As the first step of our design, we list important concepts in deep learning and try to figure their relationship, as shown below: ``` Model = {topology, parameters} Evaluator = {Model*, activations} - forward - test GradientMachine = {Model*, gradients} - backward Optimizer = {Model*, Evaluator*, GradientMachine*} - train - update - checkpoint ``` where the pair of curly braces `{` and `}` indicate *composition*, `*` indicates a *reference*, and `-` marks a "class method". ### Model We used to think that parameters are part of the topology (or layers). But that is not true because multiple layers could share the same parameter matrix. An example is a network that compares two text segments in a semantic space: ``` semantic text A -> projection ---\ layer A \ cosine similarity -> output layer semantic / text B -> projection ---/ layer B ``` In this network, the two semantic projection layers (A and B) share the same parameter matrix. For more information about our API that specifies topology and parameter sharing, please refer to [TODO: API]. ### Evaluator Supposed that we have a trained ranking model, we should be able to use it in our search engine. The search engine's Web server is a concurrent program so to serve many HTTP requests simultaneously. It doesn't make sense for each of these threads to have its own copy of the model because that would duplicate topologies and parameters. However, each thread should be able to record layer outputs, i.e., activations, computed from an input, derived from the request. With *Evaluator* that saves activations, we can write the over-simplified server program as: ```python m = paddle.model.load("trained.model") http.handle("/", lambda req: e = paddle.evaluator.create(m) e.forward(req) e.activation(layer="output")) # returns activations of layer "output" ``` ### GradientMachine Similar to the evaluation, the training needs to compute gradients so to update model parameters. Because an [optimizer](#optimizer) might run multiple simultaneous threads to update the same model, gradients should be separated from the model. Because gradients are only used in training, but not serving, they should be separate from Evaluator. Hence the `GradientMachine`. ### Optimizer None of Model, Evaluator, nor GradientMachine implements the training loop, hence Optimizer. We can define a concurrent optimizer that runs multiple simultaneous threads to train a model -- just let each thread has its own GradientMachine object. Most models should be able to be trained using the `paddle.optimizer.SGD` by calling its `train` method. Many customizations to the SGD algorithm happens with the update equation, e.g., momentum and the Adam SGD algorithm. We make `train` calls `update` to do an update, so that we can derive a `paddle.optimizer.Adam` from `paddle.optimizer.SGD` by overrides only the `update` method. ## Programming A fictive example of PaddlePaddle program looks like the following: ```python import paddle def read(args): f = open_file(args["filename"]) mb = read_a_minibatch(f) end_pass = eof(f) if end_pass: f = open_file(args["filename"]) # rewind for reading again yield mb, end_pass input = paddle.layer.data(...) intermediate = paddle.layers.fc(input) output = paddle.layer.softmax(intermediate) model = paddle.model.create(output) paddle.train(model, data_provider=read) ``` This shows some important part of a program: 1. Define how to read (and augment) data by defining a function, in this example, `read`, that `yields` a minibatch and a boolean flag `eof_of_pass`. 1. Define the topology, `input`, `intermediate`, and `output` in this example. 1. Create parameters from the topology thus forms the model by calling `paddel.model.create`. 1. Train the model by calling `paddle.train`. ### Reader Not all programming frameworks allow users to define I/O functions. An example is Google MapReduce, which can only read from text, SSTable, and RecordIO files. Hadoop MapReduce allows users to define readers and writers by deriving from base classes `Reader` and `Writer`. The former is less flexible but also less error-prone. We decide to provide the flexibility to users to define their readers. #### A Synthetic Data Reader Sometimes we want to test a topology and/or a training algorithm using synthetic data. We can do this by defining the reader a synthesizer: ```python def read(args): x = sample_from_uniform(0.0, 1.0) y = sample_from_gauss(2 * x, sigma) yield {x, y}, False # no end-of-file so no end-of-pass ``` #### A Reader for Online Learning Readers can also read an infinite data stream, e.g., a log stream from a search engine and collected by Kafka: ```python def read(args): log_stream = kafka.open_channel(args["kafka channel name"]) yeild log_stream.read(), False # no end-of-pass in online learning ``` ### Topology By default, layers don't have names. But if we want to refer to a layer later some time, for example, when we do serving using the model and wants activations/outputs of a layer, we should give it a name. ```python input = paddle.layer.data(...) intermediate = paddle.layer.fc(input, name="inter", ...) output = paddle.layer.softmax(intermediate, name="output", ...) m = paddle.model.create(output) e = paddle.evaluator.create(model) e.forward(read_an_input()) # compute activations of all layers. print e.activations(layer="inter") # retrieve the activations of layer "inter" print e.activations(layer="output") # retrieve the activations of layer "output" ``` #### Sharing Parameters In [above section](#model) we shows a network whose two layers share the same parameter matrix. To specify such cases, we give "parameter names" to layers. If some layers have the same paraemter names, `paddle.model.create` creates a single parameter matrix for these layers: ```python text1 = paddle.layer.data(...) sematic1 = paddle.layer.fc(text1, ..., parameter_name="sematic_projection") text2 = paddle.layer.data(...) sematic2 = paddle.layer.fc(text2, ..., parameter_name="sematic_projection") out = paddle.layer.cosine(semantic1, semantic2) ``` We can also share parameter matrices between layers in different models. To do this, we need an additional parameter that refers to a model: ```python model1_input = paddle.layer.data(...) model1_output = paddle.layer.softmax(model1_input, ..., parameter_name="a_parameter_matrix") model1 = paddle.model.create(model1_output) # Another model model2_semantic = paddle.layer.fc(text2, ..., parameter_name="a_parameter_matrix", parameter_model=model1) ``` ### Training The recommended way to training a model is to call `paddle.train`, which simply calls `paddle.optimizer.Default`, a global variable of type `paddle.optimizer.SGD`. Equivalently, we can do ```python opt = paddle.optimizer.SGD(...) opt.train(model, reader=read, ...) ``` #### Distributed Training If users want to do distributed training on a cluster, s/he should call `paddle.dist_train` and provides access tokens to the cluster as a parameter. For example, if the user has a TLS certificate that allows him to access a Kubernetes cluster, s/he should be able to call ```python paddle.dist_train(model, reader=read, optimizer=paddle.optimizer.SGDOptimizer(...), k8s_user="yi", k8s_token="kube_cluster_tls.pem", k8s_job="hello", num_parameter_servers=15) ``` The pseudo code if `paddle.dist_train` is as follows: ```python def dist_train(): if os.getenv("KUBERNETES_SERVICE_HOST") == None: image_name = k8s_user + '/' + k8s_job docker_build(image_name) docker_push() kube_ctrl_start_job(image_name, k8s_user, k8s_token) else: rank = kube_list_containers_in_job_and_return_current_containers_rank() if rank == 0: master() elif rank < 15: parameter_server() else: optimizer.train(model, reader=read) ``` Please be aware that if a process is running on the Kubernetes cluster, it will have some environment variables pre-defined. If `dist_train` doesn't see these environment variables, it knowns that it's running on users' personal computer, and it should work as a *launcher*. Otherwise, it knows that it's running on the cluster and need to figure out its role as either the master, or a trainer, or a parameter server.