from __future__ import absolute_import, division, print_function, unicode_literals import torch import warnings def detach_variable(inputs): if isinstance(inputs, tuple): out = [] for inp in inputs: x = inp.detach() x.requires_grad = inp.requires_grad out.append(x) return tuple(out) else: raise RuntimeError( "Only tuple of tensors is supported. Got Unsupported input type: ", type(inputs).__name__) def check_backward_validity(inputs): if not any(inp.requires_grad for inp in inputs): warnings.warn("None of the inputs have requires_grad=True. Gradients will be None") # We can't know if the run_fn will internally move some args to different devices, # which would require logic to preserve rng states for those devices as well. # We could paranoically stash and restore ALL the rng states for all visible devices, # but that seems very wasteful for most cases. Compromise: Stash the RNG state for # the device of all Tensor args. # # To consider: maybe get_device_states and set_device_states should reside in torch/random.py? def get_device_states(*args): # This will not error out if "arg" is a CPU tensor or a non-tensor type because # the conditionals short-circuit. fwd_gpu_devices = list(set(arg.get_device() for arg in args if isinstance(arg, torch.Tensor) and arg.is_cuda)) fwd_gpu_states = [] for device in fwd_gpu_devices: with torch.cuda.device(device): fwd_gpu_states.append(torch.cuda.get_rng_state()) return fwd_gpu_devices, fwd_gpu_states def set_device_states(devices, states): for device, state in zip(devices, states): with torch.cuda.device(device): torch.cuda.set_rng_state(state) class CheckpointFunction(torch.autograd.Function): @staticmethod def forward(ctx, run_function, preserve_rng_state, *args): check_backward_validity(args) ctx.run_function = run_function ctx.preserve_rng_state = preserve_rng_state if preserve_rng_state: ctx.fwd_cpu_state = torch.get_rng_state() # Don't eagerly initialize the cuda context by accident. # (If the user intends that the context is initialized later, within their # run_function, we SHOULD actually stash the cuda state here. Unfortunately, # we have no way to anticipate this will happen before we run the function.) ctx.had_cuda_in_fwd = False if torch.cuda._initialized: ctx.had_cuda_in_fwd = True ctx.fwd_gpu_devices, ctx.fwd_gpu_states = get_device_states(*args) ctx.save_for_backward(*args) with torch.no_grad(): outputs = run_function(*args) return outputs @staticmethod def backward(ctx, *args): if not torch.autograd._is_checkpoint_valid(): raise RuntimeError("Checkpointing is not compatible with .grad(), please use .backward() if possible") inputs = ctx.saved_tensors # Stash the surrounding rng state, and mimic the state that was # present at this time during forward. Restore the surrouding state # when we're done. rng_devices = [] if ctx.preserve_rng_state and ctx.had_cuda_in_fwd: rng_devices = ctx.fwd_gpu_devices with torch.random.fork_rng(devices=rng_devices, enabled=ctx.preserve_rng_state): if ctx.preserve_rng_state: torch.set_rng_state(ctx.fwd_cpu_state) if ctx.had_cuda_in_fwd: set_device_states(ctx.fwd_gpu_devices, ctx.fwd_gpu_states) detached_inputs = detach_variable(inputs) with torch.enable_grad(): outputs = ctx.run_function(*detached_inputs) if isinstance(outputs, torch.Tensor): outputs = (outputs,) torch.autograd.backward(outputs, args) return (None, None) + tuple(inp.grad for inp in detached_inputs) def checkpoint(function, *args, **kwargs): r"""Checkpoint a model or part of the model Checkpointing works by trading compute for memory. Rather than storing all intermediate activations of the entire computation graph for computing backward, the checkpointed part does **not** save intermediate activations, and instead recomputes them in backward pass. It can be applied on any part of a model. Specifically, in the forward pass, :attr:`function` will run in :func:`torch.no_grad` manner, i.e., not storing the intermediate activations. Instead, the forward pass saves the inputs tuple and the :attr:`function` parameter. In the backwards pass, the saved inputs and :attr:`function` is retreived, and the forward pass is computed on :attr:`function` again, now tracking the intermediate activations, and then the gradients are calculated using these activation values. .. warning:: Checkpointing doesn't work with :func:`torch.autograd.grad`, but only with :func:`torch.autograd.backward`. .. warning:: If :attr:`function` invocation during backward does anything different than the one during forward, e.g., due to some global variable, the checkpointed version won't be equivalent, and unfortunately it can't be detected. .. warning: At least one of the inputs needs to have :code:`requires_grad=True` if grads are needed for model inputs, otherwise the checkpointed part of the model won't have gradients. Args: function: describes what to run in the forward pass of the model or part of the model. It should also know how to handle the inputs passed as the tuple. For example, in LSTM, if user passes ``(activation, hidden)``, :attr:`function` should correctly use the first input as ``activation`` and the second input as ``hidden`` preserve_rng_state(bool, optional, default=True): Omit stashing and restoring the RNG state during each checkpoint. args: tuple containing inputs to the :attr:`function` Returns: Output of running :attr:`function` on :attr:`*args` """ # Hack to mix *args with **kwargs in a python 2.7-compliant way preserve = kwargs.pop('preserve_rng_state', True) if kwargs: raise ValueError("Unexpected keyword arguments: " + ",".join(arg for arg in kwargs)) return CheckpointFunction.apply(function, preserve, *args) def checkpoint_sequential(functions, segments, *inputs, **kwargs): r"""A helper function for checkpointing sequential models. Sequential models execute a list of modules/functions in order (sequentially). Therefore, we can divide such a model in various segments and checkpoint each segment. All segments except the last will run in :func:`torch.no_grad` manner, i.e., not storing the intermediate activations. The inputs of each checkpointed segment will be saved for re-running the segment in the backward pass. See :func:`~torch.utils.checkpoint.checkpoint` on how checkpointing works. .. warning:: Checkpointing doesn't work with :func:`torch.autograd.grad`, but only with :func:`torch.autograd.backward`. .. warning: At least one of the inputs needs to have :code:`requires_grad=True` if grads are needed for model inputs, otherwise the checkpointed part of the model won't have gradients. Args: functions: A :class:`torch.nn.Sequential` or the list of modules or functions (comprising the model) to run sequentially. segments: Number of chunks to create in the model inputs: tuple of Tensors that are inputs to :attr:`functions` preserve_rng_state(bool, optional, default=True): Omit stashing and restoring the RNG state during each checkpoint. Returns: Output of running :attr:`functions` sequentially on :attr:`*inputs` Example: >>> model = nn.Sequential(...) >>> input_var = checkpoint_sequential(model, chunks, input_var) """ # Hack to mix *args with **kwargs in a python 2.7-compliant way preserve = kwargs.pop('preserve_rng_state', True) if kwargs: raise ValueError("Unexpected keyword arguments: " + ",".join(arg for arg in kwargs)) def run_function(start, end, functions): def forward(*inputs): for j in range(start, end + 1): if isinstance(inputs, tuple): inputs = functions[j](*inputs) else: inputs = functions[j](inputs) return inputs return forward if isinstance(functions, torch.nn.Sequential): functions = list(functions.children()) segment_size = len(functions) // segments # the last chunk has to be non-volatile end = -1 for start in range(0, segment_size * (segments - 1), segment_size): end = start + segment_size - 1 inputs = checkpoint(run_function(start, end, functions), *inputs, preserve_rng_state=preserve) if not isinstance(inputs, tuple): inputs = (inputs,) return run_function(end + 1, len(functions) - 1, functions)(*inputs)