# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except jin compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. import os import six import numpy as np from collections import OrderedDict from .. import core from . import layers from . import parallel_helper from .. import framework from ..layers import collective from . import to_variable, no_grad __all__ = ["prepare_context"] ParallelStrategy = core.ParallelStrategy def prepare_context(strategy=None): if strategy is None: strategy = ParallelStrategy() strategy.nranks = Env().nranks strategy.local_rank = Env().local_rank strategy.trainer_endpoints = Env().trainer_endpoints strategy.current_endpoint = Env().current_endpoint if strategy.nranks < 2: return assert framework.in_dygraph_mode() is True, \ "dygraph.parallel.prepare_context should be used with dygrahp mode." place = framework._current_expected_place() assert place is not None, \ "dygraph.parallel.prepare_context should be used in fluid.dygraph.guard(place) guard." if isinstance(place, core.CUDAPlace): parallel_helper._set_parallel_ctx( core.NCCLParallelContext(strategy, place)) else: # TODO(Yancey1989): add Gloo Parallel Context to support CPU parallel computation assert ("Only support CUDAPlace for now.") parallel_helper._init_parallel_ctx() return strategy class Env(object): def __init__(self): self._nranks = int(os.getenv("PADDLE_TRAINERS_NUM", "1")) self._local_rank = int(os.getenv("PADDLE_TRAINER_ID", "0")) self._dev_id = int(os.getenv("FLAGS_selected_gpus", "0")) self._trainer_endpoints = os.getenv("PADDLE_TRAINER_ENDPOINTS", "").split(",") self._current_endpoint = os.getenv("PADDLE_CURRENT_ENDPOINT", "") @property def nranks(self): return self._nranks @property def local_rank(self): return self._local_rank @property def dev_id(self): return self._dev_id @property def current_endpoint(self): return self._current_endpoint @property def trainer_endpoints(self): return self._trainer_endpoints class DataParallel(layers.Layer): """ Runs the module with data parallelism. Currently, DataParallel only supports to run the dynamic graph with multi-process. The usage is: `python -m paddle.distributed.launch --gpus 2 dynamic_graph_test.py`. And the content of `dynamic_graph_test.py` is the code of examples. Examples: .. code-block:: python import numpy as np import paddle.fluid as fluid import paddle.fluid.dygraph as dygraph from paddle.fluid.optimizer import AdamOptimizer from paddle.fluid.dygraph.nn import FC from paddle.fluid.dygraph.base import to_variable place = fluid.CUDAPlace(0) with fluid.dygraph.guard(place=place): # prepare the data parallel context strategy=dygraph.parallel.prepare_context() fc_layer = FC("FC", 10, act="softmax") adam = fluid.optimizer.AdamOptimizer() # make the module become the data parallelism module fc_layer = dygraph.parallel.DataParallel(fc_layer, strategy) x_data = np.random.random(size=[10, 1]).astype(np.float32) data = to_variable(x_data) hidden = fc_layer(data) avg_loss = fluid.layers.mean(hidden) # scale the loss according to the number of trainers. avg_loss = fc_layer.scale_loss(avg_loss) avg_loss.backward() # collect the gradients of trainers. fc_layer.apply_collective_grads() adam.minimize(avg_loss) fc_layer.clear_gradients() Args: layers(Layer): The module that should be executed by data parallel. strategy(ParallelStrategy): The strategy of data parallelism. Returns: Layer: The data paralleled module. """ def __init__(self, layers, strategy): super(DataParallel, self).__init__(layers.full_name() + "_data_parallel") self._layers = layers self._strategy = strategy def forward(self, *inputs, **kwargs): return self._layers(*inputs, **kwargs) def scale_loss(self, loss): """ Scale the loss. In data parallel mode, the loss should be scale with the number of trainers. If not in data parallel mode, return the loss directly. Args: loss(Layer): The loss of the current Model. Returns: Layer: the scaled loss. """ if not self._is_data_parallel_mode(): return loss loss_scale = to_variable( np.array([self._strategy.nranks]).astype("float32")) loss_scale.stop_gradient = True loss = loss / loss_scale return loss def _coalesce_tensors(self, var_groups): from ..layers import nn coalesced_grads_and_grad_vars = [] for group_id, grad_vars in var_groups.items(): flattened_vars = [] g_var_shapes = [] for g_var in grad_vars: g_var_shapes.append(g_var.shape) flattened_vars.append( nn.reshape( x=g_var, shape=[np.prod(g_var.shape)], inplace=True)) coalesced_grad = nn.concat(flattened_vars) coalesced_grads_and_grad_vars.append( [coalesced_grad, grad_vars, g_var_shapes]) return coalesced_grads_and_grad_vars def _reshape_inplace(self, x, shape): x_shape = self._helper.create_variable_for_type_inference(dtype=x.dtype) self._helper.append_op( type="reshape2", inputs={'X': x}, attrs={'shape': shape}, outputs={'Out': x, 'XShape': x_shape}) def _split_tensors(self, coalesced_grads_and_grad_vars): from ..layers import nn for coalesced_grad, origin_grad_vars, grad_shapes in coalesced_grads_and_grad_vars: grad_var_len = [np.prod(g_shape) for g_shape in grad_shapes] self._helper.main_program.current_block().append_op( type='split', inputs={'X': coalesced_grad}, outputs={'Out': origin_grad_vars}, attrs={'sections': grad_var_len, 'axis': 0}) for g_var, g_shape in zip(origin_grad_vars, grad_shapes): self._reshape_inplace(x=g_var, shape=g_shape) assert g_var.shape == g_shape @no_grad def apply_collective_grads(self): """ AllReduce the Parameters' gradient. """ if not self._is_data_parallel_mode(): return grad_var_set = set() grad_vars = [] for param in self._layers.parameters(): # NOTE(zcd): The grad_ivar maybe no generated. if param.trainable and param._grad_ivar(): g_var = param._grad_ivar() grad_vars.append(g_var) assert g_var not in grad_var_set grad_var_set.add(g_var) # FIXME(zcd): the type of the var should be LoDTensor, i.e # the gradients should be dense, otherwise, the following # logic should be updated. # 128 MB as a group mega_bytes = 128 * 1024 * 1024 group_idx = 0 memory_counter = 0 grad_var_groups = OrderedDict() dtype = grad_vars[0].dtype for g_var in grad_vars: # Note: the dtype of the same group should be the same. bytes = np.prod(g_var.shape) * core.size_of_dtype(g_var.dtype) if memory_counter < mega_bytes and dtype == g_var.dtype: memory_counter += bytes else: memory_counter = bytes group_idx += 1 grad_var_groups.setdefault(group_idx, []).append(g_var) coalesced_grads_and_vars = self._coalesce_tensors(grad_var_groups) for coalesced_grad, g_vars, g_shapes in coalesced_grads_and_vars: collective._allreduce( coalesced_grad, coalesced_grad, sync_mode=False) self._split_tensors(coalesced_grads_and_vars) def _is_data_parallel_mode(self): return self._strategy.nranks > 1