#!/usr/bin/env python # -*- encoding: utf-8 -*- import weakref import torch from torch.utils.checkpoint import check_backward_validity, detach_variable from colossalai.legacy.context.random import get_current_mode, get_states, set_mode, set_seed_states, sync_states from colossalai.utils import get_current_device def copy_to_device(obj, device): if torch.is_tensor(obj): # Notice: # When in no_grad context, requires_gard is False after movement ret = obj.to(device).detach() ret.requires_grad = obj.requires_grad return ret elif isinstance(obj, list): return [copy_to_device(i, device) for i in obj] elif isinstance(obj, tuple): return tuple([copy_to_device(v, device) for v in obj]) elif isinstance(obj, dict): return {k: copy_to_device(v, device) for k, v in obj.items()} else: return obj class CheckpointFunction(torch.autograd.Function): @staticmethod def forward(ctx, run_function, activation_offload=False, *args): check_backward_validity(args) ctx.run_function = run_function ctx.activation_offload = activation_offload ctx.device = get_current_device() # preserve rng states ctx.fwd_cpu_rng_state = torch.get_rng_state() sync_states() ctx.fwd_seed_states = get_states(copy=True) ctx.fwd_current_mode = get_current_mode() if hasattr(torch, "is_autocast_enabled"): ctx.had_autocast_in_fwd = torch.is_autocast_enabled() else: ctx.had_autocast_in_fwd = False if activation_offload: inputs_cuda = copy_to_device(args, ctx.device) else: inputs_cuda = args with torch.no_grad(): outputs = run_function(*inputs_cuda) # Save non-tensor inputs in ctx, keep a placeholder None for tensors # to be filled out during the backward. ctx.inputs = [] ctx.tensor_indices = [] tensor_inputs = [] for i, arg in enumerate(args): if torch.is_tensor(arg): if activation_offload: tensor_inputs.append(copy_to_device(arg, "cpu")) else: tensor_inputs.append(arg) ctx.tensor_indices.append(i) ctx.inputs.append(None) else: ctx.inputs.append(arg) if activation_offload: ctx.tensor_inputs = tensor_inputs else: ctx.save_for_backward(*tensor_inputs) return outputs @staticmethod def backward(ctx, *args): if not torch.autograd._is_checkpoint_valid(): raise RuntimeError( "Checkpointing is not compatible with .grad() or when an `inputs` parameter is " "passed to .backward(). Please use .backward() and do not pass its `inputs` argument." ) # Copy the list to avoid modifying original list. inputs = list(ctx.inputs) tensor_indices = ctx.tensor_indices if ctx.activation_offload: tensors = ctx.tensor_inputs else: tensors = ctx.saved_tensors # store the current states bwd_cpu_rng_state = torch.get_rng_state() sync_states() bwd_seed_states = get_states(copy=True) bwd_current_mode = get_current_mode() # set the states to what it used to be torch.set_rng_state(ctx.fwd_cpu_rng_state) for parallel_mode, state in ctx.fwd_seed_states.items(): set_seed_states(parallel_mode, state) set_mode(ctx.fwd_current_mode) if ctx.activation_offload: tensors = copy_to_device(tensors, ctx.device) # Fill in inputs with appropriate saved tensors. for i, idx in enumerate(tensor_indices): inputs[idx] = tensors[i] detached_inputs = detach_variable(tuple(inputs)) if ctx.had_autocast_in_fwd: with torch.enable_grad(), torch.cuda.amp.autocast(): outputs = ctx.run_function(*detached_inputs) else: with torch.enable_grad(): outputs = ctx.run_function(*detached_inputs) if isinstance(outputs, torch.Tensor): outputs = (outputs,) # recover the rng states torch.set_rng_state(bwd_cpu_rng_state) for parallel_mode, state in bwd_seed_states.items(): set_seed_states(parallel_mode, state) set_mode(bwd_current_mode) # run backward() with only tensor that requires grad outputs_with_grad = [] args_with_grad = [] for i in range(len(outputs)): if torch.is_tensor(outputs[i]) and outputs[i].requires_grad: outputs_with_grad.append(outputs[i]) args_with_grad.append(args[i]) if len(outputs_with_grad) == 0: raise RuntimeError("none of output has requires_grad=True," " this checkpoint() is not necessary") torch.autograd.backward(outputs_with_grad, args_with_grad) grads = tuple(inp.grad if isinstance(inp, torch.Tensor) else None for inp in detached_inputs) return (None, None) + grads def checkpoint(function, activation_offload, *args, use_reentrant: bool = True): """Checkpoint the computation while preserve the rng states, modified from Pytorch torch.utils.checkpoint. Args: function: Describe the forward pass function. It should know how to handle the input tuples. activation_offload: The variable to check whether we should offload activation to cpu args (list): Tuple containing the parameters of the function use_reentrant: Bool type to check if we need to use_reentrant, if use_reentrant=False, there might be more flexibility for user to define there checkpoint function Returns: Output of running function with provided args. """ if use_reentrant: return CheckpointFunction.apply(function, activation_offload, *args) else: return _checkpoint_without_reentrant( function, activation_offload, *args, ) def _checkpoint_without_reentrant(function, activation_offload=False, *args): # store rng_state fwd_cpu_state = torch.get_rng_state() sync_states() fwd_seed_states = get_states(copy=True) fwd_current_mode = get_current_mode() # check if use autocast if hasattr(torch, "is_autocast_enabled"): has_autocast_in_fwd = torch.is_autocast_enabled() else: has_autocast_in_fwd = False # using WeakKeyDictionary to store all the activation the first time we call unpack storage: weakref.WeakKeyDictionary = weakref.WeakKeyDictionary() weak_holder_list = [] # class for weakref.ref class Holder: pass # return a Holder object for later unpack process def pack(x): res = Holder() weak_holder_list.append(weakref.ref(res)) return res # unpack hook def unpack(x): unpack_counter = 0 # re-compute all the activation inside the function when we first call unpack if len(storage) == 0: def inner_pack(inner): nonlocal unpack_counter unpack_counter += 1 # If the holder went out of scope, the SavedVariable is dead and so # the value will never be read from the storage. Skip filling it. if weak_holder_list[unpack_counter - 1]() is None: return # Use detach here to ensure we don't keep the temporary autograd # graph created during the second forward storage[weak_holder_list[unpack_counter - 1]()] = inner.detach() return def inner_unpack(packed): raise RuntimeError("You are calling backwards on a tensor that is never exposed. Please open an issue.") # restore rng state torch.set_rng_state(fwd_cpu_state) for parallel_mode, state in fwd_seed_states.items(): set_seed_states(parallel_mode, state) set_mode(fwd_current_mode) # reload arg into device if needed if activation_offload: for arg in args: if torch.is_tensor(arg): arg = arg.to(device=device) # rerun forward, the inner_pack will store all the activations in storage if has_autocast_in_fwd: with torch.enable_grad(), torch.cuda.amp.autocast(), torch.autograd.graph.saved_tensors_hooks( inner_pack, inner_unpack ): _unused = function(*args) else: with torch.enable_grad(), torch.autograd.graph.saved_tensors_hooks(inner_pack, inner_unpack): _unused = function(*args) if x not in storage: raise RuntimeError( "Attempt to retrieve a tensor saved by autograd multiple times without checkpoint" " recomputation being triggered in between, this is not currently supported. Please" " open an issue with details on your use case so that we can prioritize adding this." ) return storage[x] # get device if we need to offload the activation if activation_offload: device = get_current_device() # run function with pack and unpack as saved_tensors_hooks with torch.autograd.graph.saved_tensors_hooks(pack, unpack): output = function(*args) # offload activation if needed if activation_offload: for arg in args: if torch.is_tensor(arg): arg = arg.to(device="cpu") return output