# Copyright (c) 2021 PaddlePaddle Authors. All Rights Reserved. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in 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 copy from collections import defaultdict import paddle.fluid from paddle.fluid import framework from paddle.fluid.framework import get_flags, set_flags from paddle.fluid import core from paddle.distributed.passes import PassContext from .dist_attribute import TensorDistributedAttribute from .dist_attribute import OperatorDistributedAttribute from .dist_tensor import DistributedTensor from .dist_op import DistributedOperator from .process_mesh import ProcessMesh # There always exists a default context for user. And user can set it to another one. _g_default_distributed_context = None def get_default_distributed_context(): global _g_default_distributed_context if _g_default_distributed_context is None: dist_context = DistributedContext() set_default_distributed_context(dist_context) return _g_default_distributed_context def set_default_distributed_context(dist_context): global _g_default_distributed_context _g_default_distributed_context = dist_context def _node_id(node): return (node.node.graph_id(), node.node.id()) class DistributedContext: """ DistributedContext is used to collect related distributed information for program and graph. One auto-parallel run should use its own DistributedContext to avoid interfering other run. """ def __init__(self, serial_main_prog=None, serial_startup_prog=None, serial_optimizer=None, serial_loss=None, feed_vars={}, fetch_vars={}, cluster=None, strategy=None): # Data members related to original programs (unchanged) self._original_serial_main_program = serial_main_prog self._original_serial_startup_program = serial_startup_prog self._original_serial_optimizer = serial_optimizer self._original_serial_loss = serial_loss self._original_serial_feed_vars = feed_vars self._original_serial_fetch_vars = fetch_vars self._original_serial_optimizer = serial_optimizer # Data members related to programs (changed) self._serial_main_program = None self._serial_startup_program = None self._serial_loss = None self._serial_optimizer = None self._serial_feed_vars = {} self._serial_fetch_vars = {} # Data members related to the program self._dist_tensors_for_program = {} self._dist_ops_for_program = {} # Data members related to the graph self._serial_graph = None self._dist_tensors_for_graph = {} self._dist_ops_for_graph = {} self._node_id_to_tensor_id = {} self._node_id_to_op_id = {} # Data members related to the distributed programs # Distributed programs self._dist_main_programs = {} self._dist_startup_programs = {} self._dist_op_context = DistributedOperatorContext() self._process_meshes = [] self._cluster = cluster self._strategy = strategy # Pass Context self._pass_context = PassContext() self._block_state = BlockState() # Other data members self._serial_ordered_tensor_nodes = [] self._serial_ordered_op_nodes = [] self._serial_ordered_nodes = [] # self._tensor_id_to_tensor_node_ids = {} self._is_initialized = False self._need_copy_dist_attr_to_graph = False self._backup_pass_context_stack = [] self._backup_block_state_stack = [] self._backup_dist_tensors_for_program_stack = [] self._backup_dist_ops_for_program_stack = [] self._backup_serial_main_program_stack = [] self._backup_serial_startup_program_stack = [] # flag whether scale gradient with dp size self._gradient_scale = True @property def serial_main_program(self): return self._serial_main_program @property def serial_startup_program(self): return self._serial_startup_program @property def serial_loss(self): return self._serial_loss @property def serial_optimizer(self): return self._serial_optimizer @property def serial_feed_vars(self): return self._serial_feed_vars @property def serial_fetch_vars(self): return self._serial_fetch_vars @property def dist_main_programs(self): return self._dist_main_programs @property def dist_startup_programs(self): return self._dist_startup_programs @property def cluster(self): return self._cluster @property def strategy(self): return self._strategy @property def serial_graph(self): return self._serial_graph @property def serial_ordered_nodes(self): return self._serial_ordered_nodes @property def process_meshes(self): return self._process_meshes @property def pass_context(self): return self._pass_context @property def dist_op_context(self): return self._dist_op_context @property def block_state(self): return self._block_state @property def has_annotation(self): return len(self._dist_tensors_for_program) or len( self._dist_ops_for_program) @property def gradient_scale(self): return self._gradient_scale @gradient_scale.setter def gradient_scale(self, gs): self._gradient_scale = gs def _backup_serial_info(self, mode): self._backup_serial_main_program_stack.append( self._serial_main_program.clone()) self._backup_serial_startup_program_stack.append( self._serial_startup_program.clone()) self._backup_pass_context_stack.append(copy.deepcopy( self._pass_context)) self._backup_block_state_stack.append(copy.deepcopy(self._block_state)) def _backup_dist_info(self, mode): self._backup_dist_tensors_for_program_stack.append( copy.deepcopy(self._dist_tensors_for_program)) self._backup_dist_ops_for_program_stack.append( copy.deepcopy(self._dist_ops_for_program)) def _backup(self, serial=True, serial_mode=None, dist=True, dist_mode=None): # Use this function carefully if serial: self._backup_serial_info(serial_mode) if dist: self._backup_dist_info(dist_mode) def _restore_serial_info(self, mode="to_backup"): if mode == "to_backup": self._serial_main_program = self._backup_serial_main_program_stack.pop( ) self._serial_startup_program = self._backup_serial_startup_program_stack.pop( ) elif mode == "to_original": assert self._original_serial_main_program is not None assert self._original_serial_startup_program is not None self._serial_main_program = self._original_serial_main_program.clone( ) self._serial_startup_program = self._original_serial_startup_program.clone( ) self._serial_optimizer = self._original_serial_optimizer if self._original_serial_loss: if isinstance(self._original_serial_loss, list): assert len(self._original_serial_loss) == 1 loss = self._original_serial_loss[0] block_idx = loss.block.idx var_name = loss.name var = self._serial_main_program.blocks[ block_idx]._var_recursive(var_name) self._serial_loss = var else: block_idx = self._original_serial_loss.block.idx var_name = self._original_serial_loss.name var = self._serial_main_program.blocks[ block_idx]._var_recursive(var_name) self._serial_loss = var for key, var_list in self._original_serial_feed_vars.items(): new_var_list = [] for var in var_list: block_idx = var.block.idx var_name = var.name var = self._serial_main_program.blocks[ block_idx]._var_recursive(var_name) new_var_list.append(var) self._serial_feed_vars[key] = new_var_list for key, var_list in self._original_serial_fetch_vars.items(): new_var_list = [] for var in var_list: block_idx = var.block.idx var_name = var.name var = self._serial_main_program.blocks[ block_idx]._var_recursive(var_name) new_var_list.append(var) self._serial_fetch_vars[key] = new_var_list self._pass_context = self._backup_pass_context_stack.pop() self._block_state = self._backup_block_state_stack.pop() def _restore_dist_info(self, mode="to_backup"): if mode == "to_backup": self._dist_tensors_for_program = self._backup_dist_tensors_for_program_stack.pop( ) self._dist_ops_for_program = self._backup_dist_ops_for_program_stack.pop( ) elif mode == "to_original": assert self._original_dist_tensors_for_program assert self._original_dist_ops_for_program self._dist_tensors_for_program = copy.deepcopy( self._original_dist_tensors_for_program) self._dist_ops_for_program = copy.deepcopy( self._original_dist_ops_for_program) elif mode == "to_default": new_tensors_ids = [] for tensor_id, dist_tensor in self._dist_tensors_for_program.items( ): if tensor_id in self._tensors_ids: dist_tensor.dist_attr.reset() else: new_tensors_ids.append(tensor_id) for tensor_id in new_tensors_ids: self._dist_tensors_for_program.pop(tensor_id) new_ops_ids = [] for op_id, dist_op in self._dist_ops_for_program.items(): if op_id in self._ops_ids: dist_op.dist_attr.reset() else: new_ops_ids.append(op_id) for op_id in new_ops_ids: self._dist_ops_for_program.pop(op_id) else: new_tensors_ids = [] for tensor_id, dist_tensor in self._dist_tensors_for_program.items( ): new_tensors_ids.append(tensor_id) for tensor_id in new_tensors_ids: self._dist_tensors_for_program.pop(tensor_id) new_ops_ids = [] for op_id, dist_op in self._dist_ops_for_program.items(): new_ops_ids.append(op_id) for op_id in new_ops_ids: self._dist_ops_for_program.pop(op_id) self._dist_main_programs = {} self._dist_startup_programs = {} self._dist_op_context = DistributedOperatorContext() self._need_copy_dist_attr_to_graph = True self._process_meshes = [] def _restore(self, serial=True, serial_mode="to_backup", dist=True, dist_mode="to_backup"): # Use this function carefully if serial: self._restore_serial_info(serial_mode) if dist: self._restore_dist_info(dist_mode) def initialize(self): if not self._is_initialized: if not self._serial_main_program: self._serial_main_program = self._original_serial_main_program if not self._serial_startup_program: self._serial_startup_program = self._original_serial_startup_program if not self._serial_loss: if isinstance(self._original_serial_loss, list): if len(self._original_serial_loss) == 1: self._serial_loss = self._original_serial_loss[0] elif len(self._original_serial_loss) == 0: self._serial_loss = self._original_serial_loss else: raise ValueError("multi loss vars are not supported.") else: self._serial_loss = self._original_serial_loss if not self._serial_optimizer: self._serial_optimizer = self._original_serial_optimizer if not self._serial_feed_vars: self._serial_feed_vars = self._original_serial_feed_vars if not self._serial_fetch_vars: self._serial_fetch_vars = self._original_serial_fetch_vars self._init_dist_attr_for_program() # Backup the original distributed information for later restore self._original_dist_tensors_for_program = copy.deepcopy( self._dist_tensors_for_program) self._original_dist_ops_for_program = copy.deepcopy( self._dist_ops_for_program) self._tensors_ids = list(self._dist_tensors_for_program.keys()) self._ops_ids = list(self._dist_ops_for_program.keys()) set_flags({"FLAGS_convert_all_blocks": True}) self._serial_graph = framework.IrGraph( core.Graph(self._serial_main_program.desc)) self._init_dist_attr_for_graph() self._is_initialized = True self._need_copy_dist_attr_to_graph = False if self._need_copy_dist_attr_to_graph: self.copy_dist_attr_from_program_to_graph() def add_process_mesh(self, process_mesh): assert isinstance(process_mesh, ProcessMesh), \ 'The type of dim_mapping must be ProcessMesh.' if process_mesh not in self.process_meshes: self._process_meshes.append(process_mesh) def add_dist_tensor_for_program(self, dist_tensor): inner_serial_tensor = dist_tensor.serial_tensor inner_serial_tensor_id = inner_serial_tensor.desc.original_id() self._dist_tensors_for_program[inner_serial_tensor_id] = dist_tensor def add_dist_op_for_program(self, dist_op): inner_serial_op = dist_op.serial_op inner_serial_op_id = inner_serial_op.desc.original_id() self._dist_ops_for_program[inner_serial_op_id] = dist_op def get_dist_tensor_for_program(self, serial_tensor): serial_tensor_id = serial_tensor.desc.id() dist_tensor = self._dist_tensors_for_program.get(serial_tensor_id, None) if dist_tensor: return dist_tensor else: serial_tensor_id = serial_tensor.desc.original_id() dist_tensor = self._dist_tensors_for_program.get( serial_tensor_id, None) if dist_tensor: return dist_tensor else: return None def get_dist_tensor_for_graph(self, serial_tensor_node): serial_tensor_node_id = _node_id(serial_tensor_node) return self._dist_tensors_for_graph.get(serial_tensor_node_id, None) def get_dist_op_for_program(self, serial_op): serial_op_id = serial_op.desc.id() dist_op = self._dist_ops_for_program.get(serial_op_id, None) if dist_op: return dist_op else: serial_op_id = serial_op.desc.original_id() dist_op = self._dist_ops_for_program.get(serial_op_id, None) if dist_op: return dist_op else: return None def del_dist_op_for_program(self, serial_tensor): serial_tensor_id = serial_tensor.desc.id() if self._dist_ops_for_program.get(serial_tensor_id, None): del self._dist_ops_for_program[serial_tensor_id] def get_dist_op_for_graph(self, serial_op_node): serial_op_node_id = _node_id(serial_op_node) return self._dist_ops_for_graph.get(serial_op_node_id, None) def get_tensor_dist_attr_for_program(self, serial_tensor): serial_tensor_id = serial_tensor.desc.id() dist_tensor = self._dist_tensors_for_program.get(serial_tensor_id, None) if dist_tensor: return dist_tensor.dist_attr else: serial_tensor_id = serial_tensor.desc.original_id() dist_tensor = self._dist_tensors_for_program.get( serial_tensor_id, None) if dist_tensor: return dist_tensor.dist_attr else: return None def get_tensor_dist_attr_for_program_with_id(self, tensor_id): dist_tensor = self._dist_tensors_for_program.get(tensor_id, None) if dist_tensor: return dist_tensor.dist_attr else: return None def set_tensor_dist_attr_for_program(self, serial_tensor, dist_attr): dist_tensor = DistributedTensor(serial_tensor, dist_attr) self.add_dist_tensor_for_program(dist_tensor) def get_tensor_dist_attr_for_graph(self, serial_tensor_node): serial_tensor_node_id = _node_id(serial_tensor_node) dist_tensor = self._dist_tensors_for_graph.get(serial_tensor_node_id, None) if dist_tensor: return dist_tensor.dist_attr else: return None def get_op_dist_attr_for_program(self, serial_op): serial_op_id = serial_op.desc.id() dist_op = self._dist_ops_for_program.get(serial_op_id, None) if dist_op: return dist_op.dist_attr else: serial_op_id = serial_op.desc.original_id() dist_op = self._dist_ops_for_program.get(serial_op_id, None) if dist_op: return dist_op.dist_attr else: return None def get_op_dist_attr_for_program_with_id(self, op_id): dist_op = self._dist_ops_for_program.get(op_id, None) if dist_op: return dist_op.dist_attr else: return None def set_op_dist_attr_for_program(self, serial_op, dist_attr): dist_op = DistributedOperator(serial_op, dist_attr) self.add_dist_op_for_program(dist_op) def get_op_dist_attr_for_graph(self, serial_op_node): serial_op_node_id = _node_id(serial_op_node) dist_op = self._dist_ops_for_graph.get(serial_op_node_id, None) if dist_op: return dist_op.dist_attr else: return None def get_dist_attr_for_graph(self, serial_node): if serial_node.is_var() and serial_node.var() is not None: serial_tensor_node_id = _node_id(serial_node) dist_tensor = self._dist_tensors_for_graph.get( serial_tensor_node_id, None) if dist_tensor: return dist_tensor.dist_attr else: return None if serial_node.is_op() and serial_node.op() is not None: serial_op_node_id = _node_id(serial_node) dist_op = self._dist_ops_for_graph.get(serial_op_node_id, None) if dist_op: return dist_op.dist_attr else: return None return None def _init_dist_attr_for_program(self, no_default=False): # Copy the dist tensors and dist ops annotated by users from the default context if not no_default: default_ctx = get_default_distributed_context() self._process_meshes = copy.deepcopy(default_ctx.process_meshes) else: default_ctx = self for block in self._serial_main_program.blocks: for tensor in block.vars.values(): # Copy the distributed tensors in the default context default_dist_tensor = default_ctx.get_dist_tensor_for_program( tensor) if default_dist_tensor and default_ctx is not self: self.add_dist_tensor_for_program(default_dist_tensor) current_dist_tensor = self.get_dist_tensor_for_program(tensor) if current_dist_tensor is None: dist_tensor = DistributedTensor(tensor) self.add_dist_tensor_for_program(dist_tensor) for op in block.ops: # Copy the distributed operators in the default context default_dist_op = default_ctx.get_dist_op_for_program(op) if default_dist_op and default_ctx is not self: self.add_dist_op_for_program(default_dist_op) current_dist_op = self.get_dist_op_for_program(op) if current_dist_op is None: dist_op = DistributedOperator(op) self.add_dist_op_for_program(dist_op) self._original_dist_tensors_for_program = copy.deepcopy( self._dist_tensors_for_program) self._original_dist_ops_for_program = copy.deepcopy( self._dist_ops_for_program) def _order_nodes_by_program_order(self): def _contains(nodes, target_node): for node in nodes: if _node_id(node) == _node_id(target_node): return True return False serial_ordered_tensor_nodes = [] serial_ordered_op_nodes = [] all_nodes = [] for idx, graph in enumerate(self._serial_graph.all_sub_graphs()): for node in graph.all_nodes(): all_nodes.append(node) for node in all_nodes: if node.is_var() and node.var() is not None: serial_ordered_tensor_nodes.append(node) if node.is_op() and node.op() is not None: serial_ordered_op_nodes.append(node) serial_ordered_tensor_nodes.sort( key=lambda node: node.node.original_desc_id()) serial_ordered_op_nodes.sort( key=lambda node: node.node.original_desc_id()) num_nodes_before = len(serial_ordered_tensor_nodes) + len( serial_ordered_op_nodes) new_serial_ordered_tensor_nodes = [] new_serial_ordered_op_nodes = [] new_serial_ordered_nodes = [] for op_node in serial_ordered_op_nodes: tensor_nodes = [] for tensor_node in op_node.inputs: if tensor_node.is_var() \ and tensor_node.var() is not None \ and not _contains(new_serial_ordered_nodes, tensor_node): tensor_nodes.append(tensor_node) new_serial_ordered_tensor_nodes.append(tensor_node) tensor_nodes.sort(key=lambda node: node.node.original_desc_id()) new_serial_ordered_nodes.extend(tensor_nodes) new_serial_ordered_nodes.append(op_node) new_serial_ordered_op_nodes.append(op_node) tensor_nodes = [] for tensor_node in op_node.outputs: if tensor_node.is_var() \ and tensor_node.var() is not None \ and not _contains(new_serial_ordered_nodes, tensor_node): tensor_nodes.append(tensor_node) new_serial_ordered_tensor_nodes.append(tensor_node) tensor_nodes.sort(key=lambda node: node.node.original_desc_id()) new_serial_ordered_nodes.extend(tensor_nodes) new_serial_ordered_tensor_nodes.sort( key=lambda node: node.node.original_desc_id()) new_serial_ordered_op_nodes.sort( key=lambda node: node.node.original_desc_id()) self._serial_ordered_tensor_nodes = new_serial_ordered_tensor_nodes self._serial_ordered_op_nodes = new_serial_ordered_op_nodes self._serial_ordered_nodes = new_serial_ordered_nodes assert len(self._serial_ordered_nodes) == len( self._serial_ordered_tensor_nodes) + len( self._serial_ordered_op_nodes) self._serial_orphan_tensor_nodes = [] for tensor_node in serial_ordered_tensor_nodes: if not _contains(self._serial_ordered_tensor_nodes, tensor_node): self._serial_orphan_tensor_nodes.append(tensor_node) if len(self._serial_ordered_nodes) != num_nodes_before: print( "WARNING: there are some orphan tensors or ops which are not used in the execution." ) def _init_dist_attr_for_graph(self): # Convert program to graph and initialize the distributed attributes self._order_nodes_by_program_order() for node in self.serial_ordered_nodes: if node.is_var() and node.var() is not None: dist_tensor = None tensor_id = node.node.original_desc_id() for cur_tensor_id, cur_dist_tensor in self._dist_tensors_for_program.items( ): if tensor_id == cur_tensor_id \ or tensor_id == cur_dist_tensor.serial_tensor.desc.original_id(): dist_tensor = cur_dist_tensor self._node_id_to_tensor_id[_node_id( node)] = cur_tensor_id assert dist_tensor is not None, \ "Tensor must have a distributed tensor after the initialization for program." serial_tensor_node_id = _node_id(node) new_dist_tensor = DistributedTensor(dist_tensor.serial_tensor, dist_tensor.dist_attr) self._dist_tensors_for_graph[ serial_tensor_node_id] = new_dist_tensor if node.is_op() and node.op() is not None: dist_op = None op_id = node.node.original_desc_id() for cur_op_id, cur_dist_op in self._dist_ops_for_program.items( ): if op_id == cur_op_id \ or op_id == cur_dist_op.serial_op.desc.original_id(): dist_op = cur_dist_op self._node_id_to_op_id[_node_id(node)] = cur_op_id assert dist_op is not None, \ "Operator must have a distributed operator after the initialization for program." serial_op_node_id = _node_id(node) new_dist_op = DistributedOperator(dist_op.serial_op, dist_op.dist_attr) self._dist_ops_for_graph[serial_op_node_id] = new_dist_op def clear_dist_info_for_program(self): self._dist_tensors_for_program.clear() self._dist_ops_for_program.clear() def clear_dist_info_for_graph(self): self._dist_tensors_for_graph.clear() self._dist_ops_for_graph.clear() def copy_dist_attr_from_program_to_graph(self): for node in self.serial_ordered_nodes: if node.is_var() and node.var() is not None: dist_tensor = None tensor_id = node.node.original_desc_id() for cur_tensor_id, cur_dist_tensor in self._dist_tensors_for_program.items( ): if tensor_id == cur_tensor_id \ or tensor_id == cur_dist_tensor.serial_tensor.desc.original_id(): dist_tensor = cur_dist_tensor assert dist_tensor is not None, \ "Tensor must have a distributed tensor after the initialization for program." serial_tensor_node_id = _node_id(node) new_dist_tensor = DistributedTensor(dist_tensor.serial_tensor, dist_tensor.dist_attr) self._dist_tensors_for_graph[ serial_tensor_node_id] = new_dist_tensor if node.is_op() and node.op() is not None: dist_op = None op_id = node.node.original_desc_id() for cur_op_id, cur_dist_op in self._dist_ops_for_program.items( ): if op_id == cur_op_id \ or op_id == cur_dist_op.serial_op.desc.original_id(): dist_op = cur_dist_op assert dist_op is not None, \ "Operator must have a distributed operator after the initialization for program." serial_op_node_id = _node_id(node) new_dist_op = DistributedOperator(dist_op.serial_op, dist_op.dist_attr) self._dist_ops_for_graph[serial_op_node_id] = new_dist_op def copy_dist_attr_from_graph_to_program(self): assert self._is_initialized, \ "Both program and graph must be initialized." updated_tensors = {} # all_nodes = self._serial_graph.all_nodes() all_nodes = self._serial_ordered_nodes for node in all_nodes: if node.is_var() and node.var() is not None: tensor_id = self._node_id_to_tensor_id[_node_id(node)] updated = updated_tensors.get(tensor_id, False) # If a var has multiples var nodes in graph, only use the first one for now if not updated: tensor_dist_attr_for_graph = self.get_tensor_dist_attr_for_graph( node) dist_tensor_for_program = self._dist_tensors_for_program[ tensor_id] dist_tensor_for_program.dist_attr = tensor_dist_attr_for_graph updated_tensors[tensor_id] = True if node.is_op() and node.op() is not None: op_id = self._node_id_to_op_id[_node_id(node)] op_dist_attr_for_graph = self.get_op_dist_attr_for_graph(node) dist_op_for_program = self._dist_ops_for_program[op_id] dist_op_for_program.dist_attr = op_dist_attr_for_graph # TODO: the completion algorithm will skipped orphan tensors, # here we just set there process_mesh to the first one. for orphan_node in self._serial_orphan_tensor_nodes: serial_tensor_id = orphan_node.var().id() dist_tensor = self._dist_tensors_for_program.get( serial_tensor_id, None) if dist_tensor: dist_tensor.dist_attr.process_mesh = self._process_meshes[0] else: serial_tensor_id = orphan_node.var().original_id() dist_tensor = self._dist_tensors_for_program.get( serial_tensor_id, None) dist_tensor.dist_attr.process_mesh = self._process_meshes[0] def amend_dist_attr_for_program(self): for dist_tensor in self._dist_tensors_for_program.values(): serial_tensor = dist_tensor.serial_tensor dist_attr = dist_tensor.dist_attr if serial_tensor.type == core.VarDesc.VarType.READER \ or serial_tensor.type == core.VarDesc.VarType.LOD_TENSOR_ARRAY \ or serial_tensor.type == core.VarDesc.VarType.STEP_SCOPES: tensor_shape = [] else: tensor_shape = serial_tensor.shape dims_mapping = dist_attr.dims_mapping process_mesh_shape = dist_attr.process_mesh.topology process_mesh_processes = dist_attr.process_mesh.processes # If the dimension of tensor is less than the sharding dimension of process mesh, # we just amend the dimension mapping to -1. (Is this really OK?) for i in range(len(tensor_shape)): if dims_mapping[i] != -1 and tensor_shape[i] > 0 \ and process_mesh_shape[dims_mapping[i]] > tensor_shape[i]: dims_mapping[i] = -1 if dims_mapping[i] != -1 and len(process_mesh_processes) == 1: dims_mapping[i] = -1 for dist_op in self._dist_ops_for_program.values(): serial_op = dist_op.serial_op dist_attr = dist_op.dist_attr process_mesh_shape = dist_attr.process_mesh.topology process_mesh_processes = dist_attr.process_mesh.processes for arg_name in serial_op.input_arg_names: if dist_op.get_serial_input(arg_name) is None: tensor_shape = [] else: if dist_op.get_serial_input(arg_name).type == core.VarDesc.VarType.READER \ or dist_op.get_serial_input(arg_name).type == core.VarDesc.VarType.LOD_TENSOR_ARRAY \ or dist_op.serial_op.type == "create_py_reader": tensor_shape = [] else: tensor_shape = dist_op.get_serial_input(arg_name).shape dims_mapping = dist_attr.get_input_dims_mapping(arg_name) # If the dimension of tensor is less than the sharding dimension of process mesh, # we just amend the dimension mapping to -1. (Is this really OK?) for i in range(len(tensor_shape)): if dims_mapping[i] != -1 and tensor_shape[i] > 0 \ and process_mesh_shape[dims_mapping[i]] > tensor_shape[i]: dims_mapping[i] = -1 if dims_mapping[i] != -1 and len( process_mesh_processes) == 1: dims_mapping[i] = -1 for arg_name in serial_op.output_arg_names: if dist_op.get_serial_output(arg_name).type == core.VarDesc.VarType.READER \ or dist_op.get_serial_output(arg_name).type == core.VarDesc.VarType.LOD_TENSOR_ARRAY \ or dist_op.get_serial_output(arg_name).type == core.VarDesc.VarType.STEP_SCOPES: tensor_shape = [] else: tensor_shape = dist_op.get_serial_output(arg_name).shape dims_mapping = dist_attr.get_output_dims_mapping(arg_name) # If the dimension of tensor is less than the sharding dimension of process mesh, # we just amend the dimension mapping to -1. (Is this really OK?) for i in range(len(tensor_shape)): if dims_mapping[i] != -1 and tensor_shape[i] > 0 \ and process_mesh_shape[dims_mapping[i]] > tensor_shape[i]: dims_mapping[i] = -1 if dims_mapping[i] != -1 and len( process_mesh_processes) == 1: dims_mapping[i] = -1 if len(process_mesh_processes) == 1: dist_op.dist_attr.impl_type = "default" dist_op.dist_attr.impl_idx = 0 def validate_dist_attr_for_program(self): if not self._is_initialized: assert False, \ "Program must be initialized before validating its distributed attributes" for block in self.serial_main_program.blocks: for tensor in block.vars.values(): dist_tensor = self.get_dist_tensor_for_program(tensor) assert dist_tensor is not None, \ "Tensor {} does not have a distributed attribute.".format( dist_tensor.serial_tensor.name) if (dist_tensor is not None) and (not dist_tensor.validate_dist_attr()): assert False, "Tensor {} (id: {}, original_id: {}) has a wrong distributed attributes {}.".format( dist_tensor.serial_tensor.name, dist_tensor.desc.id(), dist_tensor.desc.original_id(), dist_tensor.dist_attr) for op in block.ops: dist_op = self.get_dist_op_for_program(op) assert dist_op is not None, \ "Operator {} does not have a distributed attribute.".format( dist_op.serial_op.type) if (dist_op is not None) and (not dist_op.validate_dist_attr()): assert False, "Operator {} (id: {}, original_id: {}) has a wrong distributed attributes {} .".format( dist_op.serial_op.type, dist_op.serial_op.desc.id(), dist_op.serial_op.desc.original_id(), dist_op.dist_attr) return True def __deepcopy__(self, memo): cls = self.__class__ result = cls.__new__(cls) memo[id(self)] = result for k, v in self.__dict__.items(): if k in [ "_original_serial_main_program", "_original_serial_startup_program", \ "_serial_main_program", "_serial_startup_program", "_serial_graph", \ "_dist_main_programs", "_dist_startup_programs", \ "_serial_ordered_nodes", "_serial_ordered_tensor_nodes", \ "_serial_ordered_op_nodes"]: setattr(result, k, v) else: setattr(result, k, copy.deepcopy(v, memo)) # update dist tensor's dist_context for key in result._dist_tensors_for_program.keys(): result._dist_tensors_for_program[key]._dist_context = result return result class DistributedOperatorContext: """ DistributedOperatorContext is used to create a dist op desc in Program. Every time to create a new dist op, the context should be updated for it accordingly. """ def __init__(self): self._dst_main_program = None self._main_block = None self._dst_startup_program = None self._startup_block = None self._cur_src_op = None self._cur_dist_attr = None self.grad_op_id_to_op_id = {} self.grad_var_to_var = defaultdict(dict) self._work_block = None self.already_init_sync_vars = set() self.varname_mapping = None self.rank_id = None def __deepcopy__(self, memo): cls = self.__class__ result = cls.__new__(cls) memo[id(self)] = result for k, v in self.__dict__.items(): if k in [ "_dst_main_program", "_dst_startup_program", "_cur_src_op", "_work_block", "_main_block", "_startup_block" ]: setattr(result, k, v) else: setattr(result, k, copy.deepcopy(v, memo)) return result @property def dst_main_program(self): return self._dst_main_program @dst_main_program.setter def dst_main_program(self, prog): self._dst_main_program = prog self._main_block = prog.blocks[0] @property def main_block(self): return self._main_block @property def dst_startup_program(self): return self._dst_startup_program @dst_startup_program.setter def dst_startup_program(self, prog): self._dst_startup_program = prog self._startup_block = prog.blocks[0] @property def startup_block(self): return self._startup_block @property def work_block(self): assert self._work_block is not None return self._work_block @work_block.setter def work_block(self, block): assert block is not None self._work_block = block @property def cur_src_op(self): assert self._cur_src_op is not None return self._cur_src_op def prepare_context(self, src_op): self._cur_src_op = src_op # build input varname mapping kinputs = {} for input_name in src_op.desc.input_names(): varnames = [] for varname in src_op.desc.input(input_name): assert varname in self.varname_mapping varnames.append(self.varname_mapping[varname]) kinputs[input_name] = varnames # build output varname mapping koutputs = {} for output_name in src_op.desc.output_names(): varnames = [] for varname in src_op.desc.output(output_name): assert varname in self.varname_mapping varnames.append(self.varname_mapping[varname]) koutputs[output_name] = varnames return kinputs, koutputs class BlockState(object): def __init__(self): self.nblock = 0 self.forward_indices = [] self.backward_indices = [] self.backward_to_forward_index_map = {} def parse_forward_blocks(self, program): while program.current_block_idx != 0: program._rollback() assert program.current_block_idx == 0 for idx, block in enumerate(program.blocks): assert idx == block.idx, "index doesn't match" assert block.forward_block_idx == -1, "forward_block_idx of forward block [{}] is not [{}]".format( idx, block.forward_block_idx) self.forward_indices.append(idx) self.nblock += 1 assert self.nblock >= 1 def parse_backward_blocks(self, program): assert 0 in self.forward_indices, "forward block idx are{}".format( self.forward_indices) self.backward_to_forward_index_map[0] = 0 for idx, block in enumerate(program.blocks): if idx < len(self.forward_indices): continue assert idx == block.idx, "index doesn't match" assert block.forward_block_idx in self.forward_indices self.backward_indices.append(idx) self.backward_to_forward_index_map[idx] = block.forward_block_idx self.nblock += 1 assert self.nblock == len(program.blocks)