Execution engine is for running Retiarii Experiment. NNI supports three execution engines, users can choose a specific engine according to the type of their model mutation definition and their requirements for cross-model optimizations.
Pure-python execution engine is the default engine, it supports the model space expressed by mutation primitives.
CGO execution engine has the same requirements and capabilities as the Graph-based execution engine. But further enables cross-model optimizations, which makes model space exploration faster.
Pure-python Execution Engine¶
Pure-python Execution Engine is the default engine, we recommend users to keep using this execution engine, if they are new to NNI NAS. Pure-python execution engine plays magic within the scope of inline mutation APIs, while does not touch the rest of user model. Thus, it has minimal requirement on user model.
Rememeber to add
nni.retiarii.model_wrapper() decorator outside the whole PyTorch model before using this engine.
You should always use
super().__init__() instead of
super(MyNetwork, self).__init__() in the PyTorch model, because the latter one has issues with model wrapper.
Graph-based Execution Engine¶
For graph-based execution engine, it converts user-defined model to a graph representation (called graph IR) using TorchScript, each instantiated module in the model is converted to a subgraph. Then mutations are applied to the graph to generate new graphs. Each new graph is then converted back to PyTorch code and executed on the user specified training service.
Users may find
@basic_unit helpful in some cases.
nni.retiarii.basic_unit() here means the module will not be converted to a subgraph, instead, it is converted to a single graph node as a basic unit.
@basic_unit is usually used in the following cases:
When users want to tune initialization parameters of a module using
nni.retiarii.nn.pytorch.ValueChoice, then decorate the module with
@basic_unit. For example,
self.conv = MyConv(kernel_size=nn.ValueChoice([1, 3, 5])), here
MyConvshould be decorated.
When a module cannot be successfully parsed to a subgraph, decorate the module with
@basic_unit. The parse failure could be due to complex control flow. Currently Retiarii does not support adhoc loop, if there is adhoc loop in a module’s forward, this class should be decorated as serializable module. For example, the following
MyModuleshould be decorated.
@basic_unit class MyModule(nn.Module): def __init__(self): ... def forward(self, x): for i in range(10): # <- adhoc loop ...
Some inline mutation APIs require their handled module to be decorated with
@basic_unit. For example, user-defined module that is provided to
nni.retiarii.nn.pytorch.LayerChoiceas a candidate op should be decorated.
Three steps are need to use graph-based execution engine.
@nni.retiarii.model_wrapperif there is any in your model.
config.execution_engine = 'base'to
nni.retiarii.experiment.pytorch.RetiariiExeConfig. The default value of
execution_engineis ‘py’, which means pure-python execution engine.
@basic_unitwhen necessary following the above guidelines.
For exporting top models, graph-based execution engine supports exporting source code for top models by running
CGO Execution Engine (experimental)¶
CGO (Cross-Graph Optimization) execution engine does cross-model optimizations based on the graph-based execution engine. In CGO execution engine, multiple models could be merged and trained together in one trial.
Currently, it only supports
DedupInputOptimizer that can merge graphs sharing the same dataset to only loading and pre-processing each batch of data once, which can avoid bottleneck on data loading.
To use CGO engine, PyTorch Lightning >= 1.6.1 is required.
To enable CGO execution engine, you need to follow these steps:
Create RetiariiExeConfig with remote training service. CGO execution engine currently only supports remote training service.
Add configurations for remote training service
Add configurations for CGO engine
exp = RetiariiExperiment(base_model, trainer, mutators, strategy) config = RetiariiExeConfig('remote') # ... # other configurations of RetiariiExeConfig config.execution_engine = 'cgo' # set execution engine to CGO config.max_concurrency_cgo = 3 # the maximum number of concurrent models to merge config.batch_waiting_time = 10 # how many seconds CGO execution engine should wait before optimizing a new batch of models rm_conf = RemoteMachineConfig() # ... # server configuration in rm_conf rm_conf.gpu_indices = [0, 1, 2, 3] # gpu_indices must be set in RemoteMachineConfig for CGO execution engine config.training_service.machine_list = [rm_conf] exp.run(config, 8099)
CGO Execution Engine only supports pytorch-lightning trainer that inherits
For a trial running multiple models, the trainers inheriting
nni.retiarii.evaluator.pytorch.cgo.evaluator.MultiModelSupervisedLearningModule can handle the multiple outputs from the merged model for training, test and validation.
We have already implemented two trainers:
from nni.retiarii.evaluator.pytorch.cgo.evaluator import Classification trainer = Classification(train_dataloaders=pl.DataLoader(train_dataset, batch_size=100), val_dataloaders=pl.DataLoader(test_dataset, batch_size=100), max_epochs=1, limit_train_batches=0.2)
Advanced users can also implement their own trainers by inheriting
Sometimes, a mutated model cannot be executed (e.g., due to shape mismatch). When a trial running multiple models contains a bad model, CGO execution engine will re-run each model independently in separate trials without cross-model optimizations.