# 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 collections import copy import logging import os import queue import re import paddle from paddle.base.core import ( # noqa: F401 contains_spmd_rule, get_phi_spmd_rule, ) from paddle.base.framework import Operator from paddle.base.log_helper import get_logger from paddle.distributed.fleet.meta_optimizers.common import OpRole from paddle.framework import core from ..process_mesh import ProcessMesh, compute_compatible_process_mesh from .dist_attribute import OperatorDistAttr, TensorDistAttr from .dist_context import _node_id from .operators.common import ( _gradient_sync_by_partial_ops, find_compatible_distributed_operator_impls, find_distributed_operator_impl_container, ) from .process_group import get_world_process_group from .utils import ( __no_shape_var_type__, _g_gradient_clip_ops, get_pp_degree, is_gradient_clip_op, is_loss_grad_op, is_loss_op, is_naive_data_parallel, naive_set_dist_op_attr_for_program_by_mesh_and_mapping, set_var_dist_attr, ) _logger = get_logger( __name__, logging.INFO, fmt='%(asctime)s-%(levelname)s: %(message)s' ) __skip_dims_mapping_op__ = [ "create_py_reader", "create_double_buffer_reader", "while", "read", ] _skip_propagation_prefix = "Auto_Parallel_Completion_Skipped" _max_propagation_step = 500 def mark_as_sharding_propagation_skip_op(op): prefix = op.attr("op_namescope") if op.has_attr("op_namescope") else '/' op._set_attr('op_namescope', prefix + _skip_propagation_prefix) def is_sharding_propagation_skip_op(op): if isinstance(op, paddle.base.libpaddle.OpDesc): op_desc = op elif isinstance(op, Operator): op_desc = op.desc else: raise RuntimeError(f"static mode operator is expected but got [{op}]") return op_desc.has_attr( "op_namescope" ) and _skip_propagation_prefix in op_desc.attr("op_namescope") def compute_compatible_dim_mapping(dim_mapping_list): """Compute the compatible dim mapping given a list of dim mapping.""" if not dim_mapping_list: return None def _compute_compatible_dim_mapping_of_two(dm1, dm2): if dm1 == -1: return True, dm2 if dm2 == -1: return True, dm1 if dm1 == dm2: return True, dm1 return False, None compatible_result = -1 for mapping in dim_mapping_list: compatible, compatible_result = _compute_compatible_dim_mapping_of_two( compatible_result, mapping ) if not compatible: return None return compatible_result def compute_compatible_dims_mapping(dims_mapping_list): """Compute the compatible dims mapping given a list of dims mapping. Each of dims mapping is also a list. """ if not dims_mapping_list: return None length = len(dims_mapping_list[0]) for dims_mapping in dims_mapping_list: if dims_mapping is None: return None if len(dims_mapping) != length: return None compatible_result = [] for dim_mappings in zip(*dims_mapping_list): compatible_dim_mapping = compute_compatible_dim_mapping( list(dim_mappings) ) if compatible_dim_mapping is None: return None compatible_result.append(compatible_dim_mapping) return compatible_result def merge_process_mesh_two(pm1, pm2): process_set1 = set() process_set2 = set() if pm1 is None and pm2 is None: return None if pm1 is not None: process_set1 = set(pm1.process_ids) if pm2 is not None: process_set2 = set(pm2.process_ids) merged_process_set = process_set1.union(process_set2) merged_process_mesh = ProcessMesh(list(merged_process_set)) return merged_process_mesh def _validate_dims_mapping(dims_mapping, process_mesh): if dims_mapping is None: return False for i in range(len(dims_mapping)): if dims_mapping[i] < -1 or dims_mapping[i] >= len(process_mesh.shape): return False for i in range(len(process_mesh.shape)): if dims_mapping.count(i) > 1: return False return True def _can_apply_infer_spmd_rule(dist_op): enable = os.getenv("FLAGS_infer_spmd_enable", True) if isinstance(enable, str): enable = enable.lower() enable = True if enable == 'true' else False enable = bool(enable) # TODO remove me. ops to be adapted: squeeze2 __adapted_ops__ = [ "fused_rotary_position_embedding", "matmul_v2", "elementwise_div", "fused_softmax_mask_upper_triangle", "elementwise_add", "elementwise_mul", "assign", "scale", "dropout", "reduce_sum", "layer_norm", "lookup_table_v2", "reshape2", "transpose2", "split", "unsqueeze2", "silu", "concat", "expand_as_v2", "swiglu", "tile", "fused_rms_norm", "strided_slice", "stack", "gather_nd", ] parallel_ce = os.getenv("PARALLEL_CROSS_ENTROPY") if parallel_ce == "true": __adapted_ops__.append("softmax_with_cross_entropy") op_type = dist_op.serial_op.type return enable and contains_spmd_rule(op_type) and op_type in __adapted_ops__ def _update_op_dims_mapping_and_distoperatorimpl( dist_op, original_op_dist_attr, changed ): dist_op_container = find_distributed_operator_impl_container(dist_op) _logger.debug( f"Update Op [{dist_op.serial_op.type}] using DistOpContainer [{dist_op_container.type}]." ) updated = dist_op_container.update_dims_mapping(dist_op) changed = updated or changed # TODO(ljz) remove the below code once we introduce general reshard to replace specific distopimpls reverted = dist_op_container.mapping_to_dist_operator_impl( dist_op, original_op_dist_attr ) _logger.debug( f"Op [{dist_op.serial_op.type}] use dist op impl [{dist_op.dist_attr.impl_type}] idx [{dist_op.dist_attr.impl_idx}]." ) return changed and not (reverted) class Completer: def __init__(self, dist_context): assert dist_context is not None self._dist_context = dist_context self._has_prepared = False def _update_tensor_node_dims_mapping(self, tensor_node, fwd=True): changed = False if (not tensor_node.is_var()) or (tensor_node.var() is None): return False tensor_desc = tensor_node.var() # Skip reader tensor if tensor_desc.type() in __no_shape_var_type__: return False tensor_dist_attr = self._dist_context.get_tensor_dist_attr_for_graph( tensor_node ) assert tensor_dist_attr is not None if tensor_dist_attr.is_annotated("dims_mapping"): return False tensor_dims_mapping = tensor_dist_attr.dims_mapping if fwd: dims_mapping_list = [] for pred_op_node in tensor_node.inputs: if pred_op_node.op() is not None: if ( pred_op_node.op().type() == "create_py_reader" or pred_op_node.op().type() == "create_double_buffer_reader" or pred_op_node.op().type() == "read" # or is_sharding_propagation_skip_op(pred_op_node.op()) # reshard should only fwd tensor propagation ): continue op_dist_attr = ( self._dist_context.get_op_dist_attr_for_graph( pred_op_node ) ) if ( op_dist_attr.process_mesh == tensor_dist_attr.process_mesh ): op_dims_mapping = op_dist_attr.get_output_dims_mapping( tensor_desc.name() ) dims_mapping_list.append(op_dims_mapping) dims_mapping_list.append(tensor_dims_mapping) compatible_dims_mapping = compute_compatible_dims_mapping( dims_mapping_list ) if not _validate_dims_mapping( compatible_dims_mapping, tensor_dist_attr.process_mesh ): return False if (compatible_dims_mapping is not None) and ( compatible_dims_mapping != tensor_dims_mapping ): tensor_dist_attr.dims_mapping = compatible_dims_mapping changed = True else: dims_mapping_list = [] for succ_op_node in tensor_node.outputs: if succ_op_node.op() is not None: if ( succ_op_node.op().type() == "create_py_reader" or succ_op_node.op().type() == "create_double_buffer_reader" or succ_op_node.op().type() == "read" or is_sharding_propagation_skip_op(succ_op_node.op()) ): continue op_dist_attr = ( self._dist_context.get_op_dist_attr_for_graph( succ_op_node ) ) if ( op_dist_attr.process_mesh == tensor_dist_attr.process_mesh ): op_dims_mapping = op_dist_attr.get_input_dims_mapping( tensor_desc.name() ) dims_mapping_list.append(op_dims_mapping) dims_mapping_list.append(tensor_dims_mapping) compatible_dims_mapping = compute_compatible_dims_mapping( dims_mapping_list ) if not _validate_dims_mapping( compatible_dims_mapping, tensor_dist_attr.process_mesh ): return False if (compatible_dims_mapping is not None) and ( compatible_dims_mapping != tensor_dims_mapping ): tensor_dist_attr.dims_mapping = compatible_dims_mapping changed = True return changed def _update_op_node_dims_mapping(self, op_node, fwd=True): changed = False op_desc = op_node.op() # step0: skip corner cases if (not op_node.is_op()) or (op_node.op() is None): return False # Skip reader op if ( op_desc.type() in __skip_dims_mapping_op__ or is_sharding_propagation_skip_op(op_node.op()) ): return False dist_op = self._dist_context.get_dist_op_for_graph(op_node) op_dist_attr = dist_op.dist_attr original_op_dist_attr = copy.deepcopy(op_dist_attr) # step 1: merge the dims mappings from tensor nodes to op nodes if fwd: node_list = op_node.inputs else: node_list = op_node.outputs for tensor_node in node_list: if not tensor_node.is_var() or tensor_node.var() is None: continue if tensor_node.var().type() == core.VarDesc.VarType.READER: continue tensor_desc = tensor_node.var() if fwd: annotated = op_dist_attr.is_annotated_input_dims_mapping( tensor_desc.name() ) else: annotated = op_dist_attr.is_annotated_output_dims_mapping( tensor_desc.name() ) if annotated: continue tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph(tensor_node) ) if op_dist_attr.process_mesh == tensor_dist_attr.process_mesh: tensor_dims_mapping = tensor_dist_attr.dims_mapping if fwd: op_dims_mapping = op_dist_attr.get_input_dims_mapping( tensor_desc.name() ) else: op_dims_mapping = op_dist_attr.get_output_dims_mapping( tensor_desc.name() ) compatible_dims_mapping = compute_compatible_dims_mapping( [op_dims_mapping, tensor_dims_mapping] ) if not _validate_dims_mapping( compatible_dims_mapping, op_dist_attr.process_mesh ): continue if (compatible_dims_mapping is not None) and ( compatible_dims_mapping != op_dims_mapping ): if fwd: op_dist_attr.set_input_dims_mapping( tensor_desc.name(), compatible_dims_mapping ) else: op_dist_attr.set_output_dims_mapping( tensor_desc.name(), compatible_dims_mapping ) changed = True # step 2: Infer & Update dims mapping of op node using SPMD Rule. if _can_apply_infer_spmd_rule(dist_op): _logger.debug( f"Op [{dist_op.serial_op.type}] update dims mapping using New InferSPMD Rule." ) return _update_op_dims_mapping_and_distoperatorimpl( dist_op, original_op_dist_attr, changed ) else: _logger.debug( f"Op [{dist_op.serial_op.type}] update dims mapping using Original DistOp Rule." ) # update_op_dims_mapping_v1() op_dist_impls = find_compatible_distributed_operator_impls( dist_op, fwd=fwd ) if op_dist_impls is not None: not_compatible = True backup_op_dist_attr = copy.deepcopy(op_dist_attr) backup_changed = changed for op_dist_impl in op_dist_impls: dim_changed = op_dist_impl.update_dims_mapping(dist_op) if dim_changed: changed = True if ( op_dist_impl.is_auto_compatible(dist_op) and dist_op.validate_dist_attr() ): op_dist_attr.impl_type = op_dist_impl.type op_dist_attr.impl_idx = op_dist_impl.idx not_compatible = False break else: dist_op.dist_attr = backup_op_dist_attr changed = backup_changed if not_compatible: dist_op.dist_attr = original_op_dist_attr changed = False else: dist_op.dist_attr = original_op_dist_attr changed = False return changed def _update_dims_mapping_between_graphs(self): changed = False for parent_node, child_node in self._node_pairs_between_graphs: parent_node_dist_attr = self._dist_context.get_dist_attr_for_graph( parent_node ) child_node_dist_attr = self._dist_context.get_dist_attr_for_graph( child_node ) if ( parent_node_dist_attr.process_mesh != child_node_dist_attr.process_mesh ): continue parent_node_dims_mapping = parent_node_dist_attr.dims_mapping child_node_dims_mapping = child_node_dist_attr.dims_mapping compatible_dims_mapping = compute_compatible_dims_mapping( [parent_node_dims_mapping, child_node_dims_mapping] ) if not _validate_dims_mapping( compatible_dims_mapping, parent_node_dist_attr.process_mesh ): return False if (compatible_dims_mapping is not None) and ( compatible_dims_mapping != parent_node_dims_mapping ): parent_node_dist_attr.dims_mapping = compatible_dims_mapping changed = True if (compatible_dims_mapping is not None) and ( compatible_dims_mapping != child_node_dims_mapping ): child_node_dist_attr.dims_mapping = compatible_dims_mapping changed = True return changed def _update_dims_mapping_for_special(self): # Set the dims_mapping of a tensor to the dims_mapping inside the op which produces it op_nodes = self._dist_context._serial_ordered_op_nodes # NOTE: this list may be changed if Paddle changes the existing rules. related_reader_ops = [ "create_py_reader", "create_double_buffer_reader", "read", ] for op_node in op_nodes: if ( op_node.op() is not None and op_node.op().type() in related_reader_ops ): continue op_dist_attr = self._dist_context.get_dist_attr_for_graph(op_node) for tensor_node in op_node.outputs: if tensor_node.is_var() and tensor_node.var() is not None: if tensor_node.var().type() == core.VarDesc.VarType.READER: continue tensor_desc = tensor_node.var() tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph( tensor_node ) ) if ( op_dist_attr.process_mesh == tensor_dist_attr.process_mesh ): op_dims_mapping = op_dist_attr.get_output_dims_mapping( tensor_desc.name() ) tensor_dist_attr.dims_mapping = op_dims_mapping def _update_dims_mapping(self): # Complete dims_mapping for each node step = 0 reach_fix_point = False while (not reach_fix_point) and (step < _max_propagation_step): changed = False for is_fwd in [True, False]: all_nodes = ( self._dist_context.serial_ordered_nodes if is_fwd else reversed(self._dist_context.serial_ordered_nodes) ) for node in all_nodes: if node.is_var() and node.var() is not None: tensor_changed = self._update_tensor_node_dims_mapping( node, fwd=is_fwd ) if tensor_changed: changed = True if node.is_op() and node.op() is not None: op_changed = self._update_op_node_dims_mapping( node, fwd=is_fwd ) if op_changed: changed = True graph_changed = self._update_dims_mapping_between_graphs() if graph_changed: changed = True if changed: reach_fix_point = False else: reach_fix_point = True step += 1 # NOTE: this will be removed after changing the reshard rule if step >= _max_propagation_step: _logger.debug( "Sharding Propagation reach the Max Step and is NOT Converge! The Sharding Propagation Iteration is Terminated." ) self._update_dims_mapping_for_special() def _update_process_mesh_by_nearest(self, op_node, nearest_op_node): op_dist_attr = self._dist_context.get_dist_attr_for_graph(op_node) # Set the process mesh of the op node by its nearest op node if not op_dist_attr.is_annotated("process_mesh"): process_mesh = op_dist_attr.process_mesh nearest_op_dis_attr = self._dist_context.get_dist_attr_for_graph( nearest_op_node ) nearest_process_mesh = nearest_op_dis_attr.process_mesh compatible_process_mesh = compute_compatible_process_mesh( [process_mesh, nearest_process_mesh] ) if ( compatible_process_mesh is not None and process_mesh != compatible_process_mesh ): op_dist_attr.process_mesh = compatible_process_mesh # Skip the process_mesh setting of inputs and outputs of while_op if op_dist_attr.op_type == "while": return # Set the process mesh of the op node's leaf-inputs for tensor_node in op_node.inputs: if tensor_node.is_var() and tensor_node.var() is not None: tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph( tensor_node ) ) if tensor_dist_attr.is_annotated("process_mesh"): continue # Skip the non-leaf var node if len(tensor_node.inputs) != 0: continue compatible_process_mesh = compute_compatible_process_mesh( [tensor_dist_attr.process_mesh, op_dist_attr.process_mesh] ) if ( compatible_process_mesh is not None and tensor_dist_attr.process_mesh != compatible_process_mesh ): tensor_dist_attr.process_mesh = compatible_process_mesh # Set the process mesh of the op node's outputs for tensor_node in op_node.outputs: if tensor_node.is_var() and tensor_node.var() is not None: tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph( tensor_node ) ) if tensor_dist_attr.is_annotated("process_mesh"): continue compatible_process_mesh = compute_compatible_process_mesh( [tensor_dist_attr.process_mesh, op_dist_attr.process_mesh] ) if ( compatible_process_mesh is not None and tensor_dist_attr.process_mesh != compatible_process_mesh ): tensor_dist_attr.process_mesh = compatible_process_mesh def _update_process_mesh_for_specials(self): def _find_nearest_tensor_node_before(nodes, idx, var_name): for node in reversed(nodes[:idx]): if ( node.is_var() and node.var() is not None and node.var().name() == var_name ): return node def _find_nearest_tensor_node_after(nodes, idx, var_name): for node in nodes[idx + 1 :]: if ( node.is_var() and node.var() is not None and node.var().name() == var_name ): return node def _find_nodes_related_to_cond(source_node): related_nodes = [] visited = set() frontier = [] frontier.append(source_node) # BFS while len(frontier) != 0: cur = frontier[0] frontier = frontier[1:] if _node_id(cur) in visited: continue # TODO: need more restrictions neighbors = cur.inputs + cur.outputs for node in neighbors: if node.is_var() and node.var() is not None: if ( node.var().type() != core.VarDesc.VarType.READER and len(node.var().shape()) == 1 ): frontier.append(node) related_nodes.append(node) if node.is_op() and node.op() is not None: flag = True if ( node.op().type() == "create_py_reader" or node.op().type() == "create_double_buffer_reader" or node.op().type() == "read" ): flag = False for tensor_node in node.inputs: if ( tensor_node.is_var() and tensor_node.var() is not None ): if ( tensor_node.var().type() in __no_shape_var_type__ or len(tensor_node.var().shape()) != 1 ): flag = False break for tensor_node in node.outputs: if ( tensor_node.is_var() and tensor_node.var() is not None ): if ( tensor_node.var().type() in __no_shape_var_type__ or len(tensor_node.var().shape()) != 1 ): flag = False break if flag: frontier.append(node) related_nodes.append(node) visited.add(_node_id(cur)) return related_nodes def _make_dims_mapping_replicate(dist_attr): if isinstance(dist_attr, TensorDistAttr): for i, _ in enumerate(dist_attr.dims_mapping): dist_attr.dims_mapping[i] = -1 if isinstance(dist_attr, OperatorDistAttr): for arg_name in dist_attr.inputs_dist_attrs.keys(): new_dims_mapping = [] dims_mapping = dist_attr.get_input_dims_mapping(arg_name) for _ in dims_mapping: new_dims_mapping.append(-1) dist_attr.set_input_dims_mapping(arg_name, new_dims_mapping) for arg_name in dist_attr.outputs_dist_attrs.keys(): new_dims_mapping = [] dims_mapping = dist_attr.get_output_dims_mapping(arg_name) for _ in dims_mapping: new_dims_mapping.append(-1) dist_attr.set_output_dims_mapping( arg_name, new_dims_mapping ) # Amend the process meshes related to while_op for while_op_node, while_op_node_idx in self._while_op_nodes.values(): sub_graph_id = while_op_node.op()._block_attr_id("sub_block") sub_graph = self._dist_context.serial_graph.get_sub_graph( sub_graph_id ) sub_graph_nodes = list(sub_graph.all_nodes()) while_dist_op = self._dist_context.get_dist_op_for_graph( while_op_node ) while_op_dist_attr = while_dist_op.dist_attr # Step 1: set the process mesh of while_op to the merged process mesh of its subblock merged_process_mesh = while_op_dist_attr.process_mesh for node in sub_graph_nodes: if (node.is_var() and node.var() is not None) or ( node.is_op() and node.op() is not None ): dist_attr = self._dist_context.get_dist_attr_for_graph(node) merged_process_mesh = merge_process_mesh_two( merged_process_mesh, dist_attr.process_mesh ) while_op_dist_attr.process_mesh = merged_process_mesh _make_dims_mapping_replicate(while_op_dist_attr) # Step 2: set the related nodes of while_op to the process mesh of while_op # Step 2.1: Find related nodes of cond var the graph of while_op cond_tensor_related_nodes = [] cond_tensor_name = while_op_node.op().input("Condition")[0] cond_tensor_node = None for node in while_op_node.inputs: if ( node.is_var() and node.var() is not None and node.var().name() == cond_tensor_name ): cond_tensor_node = node cond_tensor_related_nodes.append(cond_tensor_node) break cond_tensor_related_nodes.extend( _find_nodes_related_to_cond(cond_tensor_node) ) # Step 2.2: Find related nodes of cond var in the subgraph of while_op cond_tensor_node = None for node in reversed(sub_graph_nodes): if ( node.is_var() and node.var() is not None and node.var().name() == cond_tensor_name and len(node.outputs) == 0 ): cond_tensor_node = node break cond_tensor_related_nodes.extend( _find_nodes_related_to_cond(cond_tensor_node) ) # Step 2.3: Add the StepScopes output of while_op stepscopes_tensor_name = while_op_node.op().output("StepScopes")[0] stepscopes_tensor_node = None for output_node in while_op_node.outputs: if ( output_node.is_var() and output_node.var() is not None and output_node.var().name() == stepscopes_tensor_name ): stepscopes_tensor_node = output_node cond_tensor_related_nodes.append(stepscopes_tensor_node) # Step 2.4: Set the process meshes of all nodes related to cond var to the process mesh of while op for node in cond_tensor_related_nodes: tensor_dist_attr = self._dist_context.get_dist_attr_for_graph( node ) tensor_dist_attr.process_mesh = merged_process_mesh _make_dims_mapping_replicate(tensor_dist_attr) # Step 3: set the process meshes of the inputs in while_op to the process meshes of the outside input nodes while_op_inputs_dist_attrs = while_op_dist_attr.inputs_dist_attrs for ( tensor_name, tensor_dist_attr, ) in while_op_inputs_dist_attrs.items(): nearest_tensor_node = _find_nearest_tensor_node_before( self._dist_context.serial_ordered_nodes, while_op_node_idx, tensor_name, ) nearest_tensor_dist_attr = ( self._dist_context.get_dist_attr_for_graph( nearest_tensor_node ) ) tensor_dist_attr.process_mesh = ( nearest_tensor_dist_attr.process_mesh ) for node in while_op_node.inputs: if node.var().name() == tensor_name: node_dist_attr = ( self._dist_context.get_dist_attr_for_graph(node) ) node_dist_attr.process_mesh = ( nearest_tensor_dist_attr.process_mesh ) # Step 4: set the process meshes of the outputs in while_op to the process meshes of the outside output nodes while_op_outputs_dist_attrs = while_op_dist_attr.outputs_dist_attrs for ( tensor_name, tensor_dist_attr, ) in while_op_outputs_dist_attrs.items(): nearest_tensor_node = _find_nearest_tensor_node_before( self._dist_context.serial_ordered_nodes, while_op_node_idx, tensor_name, ) if nearest_tensor_node is None: nearest_tensor_node = _find_nearest_tensor_node_after( self._dist_context.serial_ordered_nodes, while_op_node_idx, tensor_name, ) nearest_tensor_dist_attr = ( self._dist_context.get_dist_attr_for_graph( nearest_tensor_node ) ) tensor_dist_attr.process_mesh = ( nearest_tensor_dist_attr.process_mesh ) for node in while_op_node.outputs: if node.var().name() == tensor_name: node_dist_attr = ( self._dist_context.get_dist_attr_for_graph(node) ) node_dist_attr.process_mesh = ( nearest_tensor_dist_attr.process_mesh ) # Amend the process meshes related to array for array_node_list in self._array_nodes.values(): merged_process_mesh = None for array_node in array_node_list: dist_attr = self._dist_context.get_dist_attr_for_graph( array_node ) merged_process_mesh = merge_process_mesh_two( merged_process_mesh, dist_attr.process_mesh ) for array_node in array_node_list: dist_attr = self._dist_context.get_dist_attr_for_graph( array_node ) dist_attr.process_mesh = merged_process_mesh _make_dims_mapping_replicate(dist_attr) def _update_process_mesh_between_graphs(self): for parent_node, child_node in self._node_pairs_between_graphs: parent_node_dist_attr = self._dist_context.get_dist_attr_for_graph( parent_node ) child_node_dist_attr = self._dist_context.get_dist_attr_for_graph( child_node ) parent_node_dist_attr.process_mesh = ( child_node_dist_attr.process_mesh ) compatible_process_mesh = compute_compatible_process_mesh( [ parent_node_dist_attr.process_mesh, child_node_dist_attr.process_mesh, ] ) if ( compatible_process_mesh is not None and parent_node_dist_attr.process_mesh != compatible_process_mesh ): parent_node_dist_attr.process_mesh = compatible_process_mesh if ( compatible_process_mesh is not None and child_node_dist_attr.process_mesh != compatible_process_mesh ): child_node_dist_attr.process_mesh = compatible_process_mesh def _update_process_mesh(self): ordered_op_nodes = self._dist_context._serial_ordered_op_nodes # Step 1: Set the annotated process meshes from tensors to the first ops using them ordered_tensor_nodes = self._dist_context._serial_ordered_tensor_nodes for tensor_node in ordered_tensor_nodes: tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph(tensor_node) ) if not tensor_dist_attr.is_annotated("process_mesh"): continue first_op_node = None for op_node in ordered_op_nodes: # TODO: Need a better rule for the control flow ops. # For now, do not set the process mesh of while_op from its inputs if op_node.op().type() == "while": continue for input_tensor_node in op_node.inputs: if _node_id(tensor_node) == _node_id(input_tensor_node): first_op_node = op_node break if first_op_node is not None: break if first_op_node is None: continue op_dist_attr = self._dist_context.get_dist_attr_for_graph( first_op_node ) if op_dist_attr is not None and not op_dist_attr.is_annotated( "process_mesh" ): compatible_process_mesh = compute_compatible_process_mesh( [tensor_dist_attr.process_mesh, op_dist_attr.process_mesh] ) if ( compatible_process_mesh is not None and op_dist_attr.process_mesh != compatible_process_mesh ): op_dist_attr.process_mesh = compatible_process_mesh # Step 2: set the process meshes of ops with the nearest op before them # Step 2.1: find the first op node which has the process mesh idx_of_first_op_node_has_process_mesh = -1 for idx, op_node in enumerate(ordered_op_nodes): op_dist_attr = self._dist_context.get_dist_attr_for_graph(op_node) if ( op_dist_attr.process_mesh is not None and idx_of_first_op_node_has_process_mesh == -1 ): idx_of_first_op_node_has_process_mesh = idx # Reuse the following method to set the related tensors for same op node self._update_process_mesh_by_nearest(op_node, op_node) # Step 2.2: set the process meshes of ops by the nearest op node after the first op node if idx_of_first_op_node_has_process_mesh + 1 > len(ordered_op_nodes): return None for idx, op_node in enumerate( ordered_op_nodes[idx_of_first_op_node_has_process_mesh + 1 :] ): original_idx = idx_of_first_op_node_has_process_mesh + idx + 1 nearest_op_node = ordered_op_nodes[original_idx - 1] nearest_op_dist_attr = self._dist_context.get_dist_attr_for_graph( nearest_op_node ) op_dist_attr = self._dist_context.get_dist_attr_for_graph(op_node) assert nearest_op_dist_attr.process_mesh is not None self._update_process_mesh_by_nearest(op_node, nearest_op_node) # Step 2.3: set the process meshes of ops by the nearest op node before the first op node nearest_op_node = ordered_op_nodes[ idx_of_first_op_node_has_process_mesh ] for op_node in ordered_op_nodes[:idx_of_first_op_node_has_process_mesh]: self._update_process_mesh_by_nearest(op_node, nearest_op_node) # Step 3: adjust the process meshes for special ops self._update_process_mesh_for_specials() # Step 4: adjust the process meshes between graphs self._update_process_mesh_between_graphs() def _prepare(self): if self._has_prepared: return self._while_op_nodes = {} self._array_nodes = {} self._node_pairs_between_graphs = [] all_nodes = self._dist_context.serial_ordered_nodes for idx, node in enumerate(all_nodes): if node.is_op(): if node.op().type() == "while": self._while_op_nodes[_node_id(node)] = (node, idx) if node.op().type() == "read_from_array": array_var_name = node.op().input("X")[0] if self._array_nodes.get(array_var_name, None) is None: self._array_nodes[array_var_name] = [] self._array_nodes[array_var_name].append(node) # Add the array input node self._array_nodes[array_var_name].append(node.inputs[0]) if node.op().type() == "write_to_array": array_var_name = node.op().output("Out")[0] if self._array_nodes.get(array_var_name, None) is None: self._array_nodes[array_var_name] = [] self._array_nodes[array_var_name].append(node) self._array_nodes[array_var_name].append(node.outputs[0]) if node.is_var() and node.var() is not None: if node.node.graph_id() != 0: parent_nodes = ( self._dist_context._tensor_nodes_with_same_name[ node.node.graph_id() - 1 ].get(node.var().name(), None) ) if parent_nodes is not None: sorted_parent_nodes = sorted( parent_nodes, key=lambda x: x[0] ) for _, parent_node in sorted_parent_nodes: self._node_pairs_between_graphs.append( (parent_node, node) ) self._has_prepared = True def complete_forward_annotation(self, serial_main_program=None): """Complete annotation for the partial annotated serial_main_program. Arguments: serial_main_program: partial annotated serial_main_program. Returns: serial_main_program: completed annotated serial_main_program. """ if serial_main_program is None: serial_main_program = self._dist_context.serial_main_program else: self._dist_context._serial_main_program = serial_main_program tensor_names, ops = self._get_tensor_names_and_ops_with_global_mesh( serial_main_program ) if not is_naive_data_parallel(self._dist_context): self._dist_context.initialize(with_graph=True) self._prepare() self._update_process_mesh() self._update_dims_mapping() # Copy the corresponding distributed attribute from graph to serial_main_program self._dist_context.copy_dist_attr_from_graph_to_program() else: _logger.info("Default distributed attributed will be set.") self._dist_context.initialize(with_graph=False) # A fast and special completion for data parallel self._update_dist_attr_for_dp() self._complete_with_global_mesh(serial_main_program, tensor_names, ops) # NOTE:[HighOrderGrad] update vars and ops distributed attribute in high order gradient self._complete_high_order_grad_annotation(serial_main_program) self._complete_chunk_id(serial_main_program) # Do the validation check and amend some completion self._dist_context.amend_dist_attr_for_program() self._dist_context.validate_dist_attr_for_program() return serial_main_program def _get_tensor_names_and_ops_with_global_mesh(self, serial_main_program): if ( not self._dist_context.strategy or not self._dist_context.strategy.pipeline.enable ): return [], [] # step1: get tensor annotated with global mesh global_mesh = paddle.distributed.auto_parallel.get_mesh() if global_mesh is None: _logger.warning( "global_mesh is not set, tensor annotation with global mesh may be not work, please use paddle.distributed.auto_parallel.set_mesh(mesh) firstly." ) return [], [] global_mesh_process_ids = global_mesh._process_ids tensor_names_with_global_mesh = [] block = serial_main_program.global_block() for var in block.vars.values(): dist_var = self._dist_context.get_dist_tensor_for_program(var) mesh = dist_var.dist_attr.process_mesh if mesh is not None and sorted(mesh.process_ids) == sorted( global_mesh_process_ids ): tensor_names_with_global_mesh.append(var.name) # if no one tensor has global mesh, do nothing if len(tensor_names_with_global_mesh) == 0: return [], [] # step2: get all tensors and ops should annotated with global mesh tensor_name_to_op = {} ops = block.ops for op in ops: output_tensor_names = op.output_arg_names for tensor_name in output_tensor_names: tensor_name_to_op[tensor_name] = op ops_with_global_mesh = [] has_visited = set() tensor_name_queue = queue.Queue() for tensor_name in tensor_names_with_global_mesh: tensor_name_queue.put(tensor_name) tensor_names_with_global_mesh.clear() # BFS to find all tensors and ops should annotated with global mesh while not tensor_name_queue.empty(): tensor_name = tensor_name_queue.get() if tensor_name in has_visited: continue has_visited.add(tensor_name) tensor_names_with_global_mesh.append(tensor_name) op = tensor_name_to_op[tensor_name] ops_with_global_mesh.append(op) input_arg_names = op.input_arg_names for input_name in input_arg_names: tensor_name_queue.put(input_name) return tensor_names_with_global_mesh, ops_with_global_mesh def _complete_with_global_mesh( self, serial_main_program, tensor_names, ops ): if len(tensor_names) == 0: return # step1: get global mesh block = serial_main_program.global_block() # tensor_names[0] is a tensor annotated with global mesh tensor = block._var_recursive(tensor_names[0]) dist_tensor = self._dist_context.get_dist_tensor_for_program(tensor) global_mesh = dist_tensor.dist_attr.process_mesh # step2: set the global mesh to ops and tensors for op in ops: dist_op = self._dist_context.get_dist_op_for_program(op) dist_op.dist_attr.process_mesh = global_mesh for tensor_name in tensor_names: tensor = block._var_recursive(tensor_name) dist_tensor = self._dist_context.get_dist_tensor_for_program(tensor) dist_tensor.dist_attr.process_mesh = global_mesh def _complete_chunk_id(self, serial_main_program): def set_chunk_id(block, op, chunk_id, var_to_chunk_id): dist_op = self._dist_context.get_dist_op_for_program(op) dist_op.dist_attr.chunk_id = chunk_id for name in op.input_arg_names + op.output_arg_names: if "lod_tensor_blocking_queue" in name: continue if name not in var_to_chunk_id: var = block._find_var_recursive(name) dist_tensor = ( self._dist_context.get_dist_tensor_for_program(var) ) if ( dist_op.dist_attr.process_mesh == dist_tensor.dist_attr.process_mesh ): dist_tensor.dist_attr.chunk_id = chunk_id var_to_chunk_id[var.name] = chunk_id def set_process_mesh(block, op, process_mesh, var_to_process_mesh): dist_op = self._dist_context.get_dist_op_for_program(op) for name in op.input_arg_names: if name not in var_to_process_mesh: var = block._find_var_recursive(name) dist_tensor = ( self._dist_context.get_dist_tensor_for_program(var) ) if ( dist_op.dist_attr.process_mesh == dist_tensor.dist_attr.process_mesh ): dist_tensor.dist_attr.process_mesh = process_mesh var_to_process_mesh[var.name] = process_mesh for name in op.output_arg_names: if name not in var_to_process_mesh: var = block._find_var_recursive(name) dist_tensor = ( self._dist_context.get_dist_tensor_for_program(var) ) dist_tensor.dist_attr.process_mesh = process_mesh var_to_process_mesh[var.name] = process_mesh dist_op.dist_attr.process_mesh = process_mesh if ( not self._dist_context.strategy or not self._dist_context.strategy.pipeline.enable ): return pp_degree, sub_process_meshes = get_pp_degree(self._dist_context) vpp_degree = self._dist_context.strategy.pipeline.vpp_degree seg_method = self._dist_context.strategy.pipeline.vpp_seg_method schedule_mode = self._dist_context.strategy.pipeline.schedule_mode if pp_degree < 2 and vpp_degree > 1: raise ValueError( "VPP schedule mode only can be set in pipeline mode." ) if vpp_degree > 1 and ( not seg_method or schedule_mode not in ["VPP", "ZBVPP"] ): raise ValueError( "Please set right schedule_mode and vpp_seg_method for VPP and ZBVPP." ) if vpp_degree < 2: return block = serial_main_program.global_block() ops = block.ops # Step1: search seg_method in op's struct_name # 1. get op_idx of each segment # 2. get process_mesh or each segment seg_op_deps = collections.OrderedDict() # struct_name -> [idx] seg_op_mesh = collections.OrderedDict() # struct_name -> process_mesh regex = re.compile(seg_method, re.IGNORECASE) start_op_index = 0 for i, op in enumerate(ops): m = regex.search(op.struct_name) if m: start_op_index = i break total_op_num = len(ops) end_op_index = total_op_num - 1 for i in reversed(range(total_op_num)): m = regex.search(ops[i].struct_name) if m: end_op_index = i break # all ops between start_op_index and end_op_index should not be ignored for i in range(start_op_index, end_op_index + 1): struct_name = ops[i].struct_name m = regex.search(struct_name) if not m: # only assign op created by reshard is allowed if ( ops[i].type == "assign" and "reshard_api" in ops[i].output_arg_names[0] ): # this assign op belongs to next segment for j in range(i + 1, total_op_num): m = regex.search(ops[j].struct_name) if m: break assert m struct_name = ops[j].struct_name else: raise ValueError( f"The op {ops[i]} should only be created by reshard" ) struct_name = struct_name[m.start(0) :].split("/")[0] dist_op = self._dist_context.get_dist_op_for_program(ops[i]) if struct_name not in seg_op_deps: seg_op_deps[struct_name] = [i] seg_op_mesh[struct_name] = dist_op.dist_attr.process_mesh else: assert seg_op_deps[struct_name][-1] + 1 == i, ( "The segment's ops should be continuous." ) pre_mesh = seg_op_mesh[struct_name] assert pre_mesh == dist_op.dist_attr.process_mesh, ( "The segment's ops should have same process_mesh." ) seg_op_deps[struct_name].extend([i]) num_chunks = pp_degree * vpp_degree assert len(seg_op_deps) % num_chunks == 0, ( f"The number of layers[{seg_method}] ({len(seg_op_deps)}) should be divided by part number ({num_chunks})." ) # Step2: analysis whether the pp_stage is non-decreasing among segments # 1. if non_decreasing is True, the ops' process_mesh will be changed by vpp strategy # 2. if non_decreasing is False, the ops's process_mesh will not be changed. non_decreasing = True seg_pp_stages = [-1] for seg_pm in seg_op_mesh.values(): assert seg_pm in sub_process_meshes pp_stage = sub_process_meshes.index(seg_pm) if seg_pp_stages[-1] > pp_stage: non_decreasing = False break seg_pp_stages.append(pp_stage) if not non_decreasing: _logger.info("Cannot Use Auto VPP") else: _logger.info("Using Auto VPP") # Step3: Get op index boundary, pp_stage, chunk_id, struct_names of each segment seg_pp_stages = [] seg_pp_stage = list(range(pp_degree)) for _ in range(vpp_degree): seg_pp_stages.extend(seg_pp_stage) if schedule_mode == "ZBVPP": seg_pp_stage.reverse() seg_chunk_ids = [i // pp_degree for i in range(num_chunks)] part_size = len(seg_op_deps) // num_chunks segment_struct_names = [] segment_parts = [0] * (num_chunks + 1) memory_counter, seg_idx = 0, 1 struct_name = [] for name, idxs in seg_op_deps.items(): struct_name.append(name) memory_counter += 1 if memory_counter == part_size: segment_parts[seg_idx] = idxs[-1] + 1 memory_counter, seg_idx = 0, seg_idx + 1 segment_struct_names.append(struct_name) struct_name = [] segment_parts[num_chunks] = len(ops) # Step4: set right chunk_id and process_mesh for each op and var in each segment var_to_chunk_id = {} var_to_process_mesh = {} for seg_id in range(len(segment_parts) - 1): start_idx = segment_parts[seg_id] end_idx = segment_parts[seg_id + 1] pp_stage = seg_pp_stages[seg_id] chunk_id = seg_chunk_ids[seg_id] process_mesh = sub_process_meshes[pp_stage] struct_names = segment_struct_names[seg_id] seg_op_idx = [] for name in struct_names: seg_op_idx.extend(seg_op_deps[name]) _logger.info( f"stage=[{pp_stage}], chunk_id=[{chunk_id}], layer_name=[{struct_names}]" ) _logger.info( f"start op: [{ops[start_idx].type}]: [{ops[start_idx].input_arg_names}] [{ops[start_idx].output_arg_names}]" ) _logger.info( f"end op: [{ops[end_idx - 1].type}]: [{ops[end_idx - 1].input_arg_names}] [{ops[end_idx - 1].output_arg_names}]" ) for idx in range(start_idx, end_idx): op = ops[idx] if op.has_attr("sub_block"): block_id = op.attr('sub_block').id sub_block = serial_main_program.blocks[block_id] if non_decreasing and idx in seg_op_idx: set_process_mesh( block, op, process_mesh, var_to_process_mesh ) set_chunk_id(block, op, chunk_id, var_to_chunk_id) for sub_op in sub_block.ops: if non_decreasing and idx in seg_op_idx: set_process_mesh( sub_block, sub_op, process_mesh, var_to_process_mesh, ) set_chunk_id( sub_block, sub_op, chunk_id, var_to_chunk_id ) else: if non_decreasing and idx in seg_op_idx: set_process_mesh( block, op, process_mesh, var_to_process_mesh ) set_chunk_id(block, op, chunk_id, var_to_chunk_id) # Step5: set right chunk_id and process_mesh for loss op # Note(sonder): for zbvpp schedule mode, the loss will be calculated in the first stage when vpp_degree is even if schedule_mode == "ZBVPP" and vpp_degree % 2 == 0: for i in range(end_op_index, total_op_num): set_chunk_id(block, ops[i], vpp_degree - 1, var_to_chunk_id) set_process_mesh( block, ops[i], sub_process_meshes[0], var_to_process_mesh ) def _update_dist_attr_for_dp(self): # TODO: we must ensure the world process group contains all ranks ranks = get_world_process_group().ranks process_mesh = ProcessMesh(ranks) dist_tensors = self._dist_context._dist_tensors_for_program for dist_tensor in dist_tensors.values(): dist_tensor.dist_attr.process_mesh = process_mesh dist_ops = self._dist_context._dist_ops_for_program for dist_op in dist_ops.values(): serial_op = dist_op.serial_op op_dist_attr = dist_op.dist_attr op_dist_attr.process_mesh = process_mesh original_op_dist_attr = copy.deepcopy(op_dist_attr) if serial_op.type == "create_py_reader": continue for arg_name in serial_op.input_arg_names: serial_tensor = dist_op.get_serial_input(arg_name) if not serial_tensor.is_parameter: dist_tensor = ( self._dist_context.get_dist_tensor_for_program( serial_tensor ) ) op_dist_attr = dist_op.dist_attr op_dist_attr.process_mesh = ( dist_tensor.dist_attr.process_mesh ) op_dist_attr.set_input_dims_mapping( arg_name, dist_tensor.dist_attr.dims_mapping ) op_dist_impls = find_compatible_distributed_operator_impls( dist_op, fwd=True ) if op_dist_impls is not None: not_compatible = True backup_op_dist_attr = copy.deepcopy(op_dist_attr) for op_dist_impl in op_dist_impls: op_dist_impl.update_dims_mapping(dist_op) if ( op_dist_impl.is_auto_compatible(dist_op) and dist_op.validate_dist_attr() ): op_dist_attr.impl_type = op_dist_impl.type op_dist_attr.impl_idx = op_dist_impl.idx not_compatible = False break else: dist_op.dist_attr = backup_op_dist_attr if not_compatible: dist_op.dist_attr = original_op_dist_attr else: dist_op.dist_attr = original_op_dist_attr for arg_name in serial_op.output_arg_names: op_dist_attr = dist_op.dist_attr serial_tensor = dist_op.get_serial_output(arg_name) if serial_op.type in ["fill_constant"]: old_dims_mapping = op_dist_attr.get_output_dims_mapping( arg_name ) if len(old_dims_mapping) > 0: new_dims_mapping = [0] + [ -1 for _ in range(len(old_dims_mapping) - 1) ] op_dist_attr.set_output_dims_mapping( arg_name, new_dims_mapping ) dist_tensor = self._dist_context.get_dist_tensor_for_program( serial_tensor ) dist_tensor.dist_attr.dims_mapping = ( op_dist_attr.get_output_dims_mapping(arg_name) ) def _complete_tensor_dist_attr_by_op(self, serial_main_program=None): if serial_main_program is None: serial_main_program = self._dist_context.serial_main_program else: self._dist_context._serial_main_program = serial_main_program self._dist_context.initialize() self._prepare() has_set_dist_attr = set() all_nodes = self._dist_context.serial_ordered_nodes for node in all_nodes: if node.is_op(): if node.op().type() in ["while"]: continue dist_op = self._dist_context.get_dist_op_for_graph(node) op_dist_attr = dist_op.dist_attr for tensor_node in node.inputs: if tensor_node.is_var() and tensor_node.var() is not None: # Skip the non-leaf var node if len(tensor_node.inputs) != 0: continue tensor_desc = tensor_node.var() tensor_name = tensor_desc.name() tensor = dist_op.get_serial_input(tensor_name) # Use the first op to set the tensor dist attr if tensor_name in has_set_dist_attr: continue tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph( tensor_node ) ) tensor_dist_attr.process_mesh = ( op_dist_attr.process_mesh ) tensor_dist_attr.dims_mapping = ( op_dist_attr.get_input_dims_mapping(tensor_name) if tensor.is_parameter else [-1 for i in tensor_desc.shape()] ) has_set_dist_attr.add(tensor_name) for tensor_node in node.outputs: if tensor_node.is_var() and tensor_node.var() is not None: tensor_name = tensor_node.var().name() if tensor_name in has_set_dist_attr: continue tensor_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_graph( tensor_node ) ) tensor_dist_attr.process_mesh = ( op_dist_attr.process_mesh ) tensor_dist_attr.dims_mapping = ( op_dist_attr.get_output_dims_mapping(tensor_name) ) has_set_dist_attr.add(tensor_name) self._update_process_mesh_for_specials() self._update_process_mesh_between_graphs() self._update_dims_mapping_for_special() self._update_dims_mapping_between_graphs() # Copy the corresponding distributed attribute from graph to serial_main_program self._dist_context.copy_dist_attr_from_graph_to_program() # Do the validation check and amend some completion self._dist_context.amend_dist_attr_for_program() self._dist_context.validate_dist_attr_for_program() def _complete_high_order_grad_annotation(self, serial_main_program=None): """ NOTE: [HighOrderGrad] Complete the annotation of vars and ops only for high order gradient. This function is temporary to support high order gradient, and will be removed in the future. """ if serial_main_program is None: serial_main_program = self._dist_context.serial_main_program else: self._dist_context._serial_main_program = serial_main_program def _is_grad_var_name(name): if "@GRAD" in name: return True return False def _get_op_by_id(ops, id): for op in ops: if op.desc.original_id() == id: return op return None ops = list(serial_main_program.global_block().ops) vars = serial_main_program.global_block().vars dist_op_context = self._dist_context.dist_op_context grad_var_to_var = dist_op_context.grad_var_to_var if len(grad_var_to_var) < 2: return appended_grad_times = 0 for idx in range(0, len(ops)): op = ops[idx] if int(op.attr('op_role')) == int( core.op_proto_and_checker_maker.OpRole.Forward ): continue if int(op.attr('op_role')) == int( core.op_proto_and_checker_maker.OpRole.Backward ) and int(ops[idx - 1].attr('op_role')) == int( core.op_proto_and_checker_maker.OpRole.Forward ): appended_grad_times += 1 if int(op.attr('op_role')) == int( int(core.op_proto_and_checker_maker.OpRole.Backward) | int(core.op_proto_and_checker_maker.OpRole.Loss) ): assert op.type == "fill_constant" break # complete the annotation of grad op (xxx_grad op or sum op) # xxx_grad op will have a corresponding forward op in grad_op_id_to_op_id grad_op = ops[idx] if ( grad_op.desc.original_id() in dist_op_context.grad_op_id_to_op_id ): # TODO support the case where one forward op corresponding to multiple xxx_grad op forward_op = _get_op_by_id( ops, dist_op_context.grad_op_id_to_op_id[ grad_op.desc.original_id() ], ) assert forward_op is not None fwd_op_dist_attr = ( self._dist_context.get_op_dist_attr_for_program(forward_op) ) fwd_op_process_mesh = fwd_op_dist_attr.process_mesh grad_op_dist_attr = OperatorDistAttr() grad_op_dist_attr.process_mesh = fwd_op_process_mesh for input_name in grad_op.input_arg_names: if ( input_name not in forward_op.input_arg_names and input_name not in forward_op.output_arg_names ): if input_name in grad_var_to_var[appended_grad_times]: fwd_name = grad_var_to_var[appended_grad_times][ input_name ] ref_dims_mapping = ( fwd_op_dist_attr.get_output_dims_mapping( fwd_name ) ) else: input_var = vars[input_name] ref_dims_mapping = self._dist_context.get_tensor_dist_attr_for_program( input_var ).dims_mapping else: if input_name in forward_op.input_arg_names: ref_dims_mapping = ( fwd_op_dist_attr.get_input_dims_mapping( input_name ) ) else: ref_dims_mapping = ( fwd_op_dist_attr.get_output_dims_mapping( input_name ) ) assert ref_dims_mapping is not None, ( f"[{input_name}] 's dims mapping is NONE" ) grad_op_dist_attr.set_input_dims_mapping( input_name, ref_dims_mapping ) for output_name in grad_op.output_arg_names: assert output_name in grad_var_to_var[appended_grad_times] fwd_name = grad_var_to_var[appended_grad_times][output_name] ref_dims_mapping = fwd_op_dist_attr.get_input_dims_mapping( fwd_name ) # var output_var = vars[output_name] tensor_dist_attr = TensorDistAttr() tensor_dist_attr.dims_mapping = ref_dims_mapping tensor_dist_attr.process_mesh = fwd_op_process_mesh self._dist_context.set_tensor_dist_attr_for_program( output_var, tensor_dist_attr ) # op grad_op_dist_attr.set_output_dims_mapping( output_name, ref_dims_mapping ) self._dist_context.set_op_dist_attr_for_program( grad_op, grad_op_dist_attr ) # grad ops that have not a corresponding mapping in grad_op_id_to_op_id else: if grad_op.type == 'sum': assert all(map(_is_grad_var_name, grad_op.input_arg_names)) output_name = grad_op.output_arg_names[0] assert ( output_name in grad_var_to_var[appended_grad_times] ), ( f"sum op's output '{output_name}' has no corresponding var" ) ref_fwd_var_name = grad_var_to_var[appended_grad_times][ output_name ] ref_fwd_var = vars[ref_fwd_var_name] ref_fwd_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( ref_fwd_var ) ) ref_fwd_dims_mapping = ref_fwd_dist_attr.dims_mapping ref_fwd_process_mesh = ref_fwd_dist_attr.process_mesh # output tensor_dist_attr = TensorDistAttr() tensor_dist_attr.dims_mapping = ref_fwd_dims_mapping tensor_dist_attr.process_mesh = ref_fwd_process_mesh output_var = vars[output_name] self._dist_context.set_tensor_dist_attr_for_program( output_var, tensor_dist_attr ) # op grad_op_dist_attr = OperatorDistAttr() grad_op_dist_attr.process_mesh = ref_fwd_process_mesh for var_name in grad_op.input_arg_names: grad_op_dist_attr.set_input_dims_mapping( var_name, ref_fwd_dims_mapping ) grad_op_dist_attr.set_output_dims_mapping( output_name, ref_fwd_dims_mapping ) elif grad_op.type == 'fill_any_like': ref_var_name = grad_op.input_arg_names[0] ref_var = vars[ref_var_name] ref_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( ref_var ) ) ref_dims_mapping = ref_dist_attr.dims_mapping ref_process_mesh = ref_dist_attr.process_mesh # output tensor_dist_attr = TensorDistAttr() tensor_dist_attr.dims_mapping = ref_dims_mapping tensor_dist_attr.process_mesh = ref_process_mesh output_var_name = grad_op.output_arg_names[0] output_var = vars[output_var_name] self._dist_context.set_tensor_dist_attr_for_program( output_var, tensor_dist_attr ) # op grad_op_dist_attr = OperatorDistAttr() grad_op_dist_attr.process_mesh = ref_process_mesh grad_op_dist_attr.set_input_dims_mapping( ref_var_name, ref_dims_mapping ) grad_op_dist_attr.set_output_dims_mapping( output_var_name, ref_dims_mapping ) elif grad_op.type in ['shape', 'fill_constant']: continue else: raise ValueError(f"got unexpected op [{grad_op.type}]") self._dist_context.set_op_dist_attr_for_program( grad_op, grad_op_dist_attr ) def complete_backward_annotation(self, serial_main_program=None): """Complete the annotation of vars and ops in the backward phase for parallel program.""" if serial_main_program is None: serial_main_program = self._dist_context.serial_main_program else: self._dist_context._serial_main_program = serial_main_program def _is_grad_var_name(name): if "@GRAD" in name: return True return False def _get_forward_varname_from_grad_varname(grad_var_name): assert _is_grad_var_name(grad_var_name), ( f"[{grad_var_name}] is not a grad var name." ) return grad_var_name[: grad_var_name.find("@GRAD")] def _get_op_by_id(ops, id): for op in ops: if op.desc.original_id() == id: return op return None def _complete_grad_op_with_forward_op(forward_op, grad_op, vars): fwd_op_dist_attr = self._dist_context.get_op_dist_attr_for_program( forward_op ) grad_op_dist_attr = OperatorDistAttr() ref_process_mesh = fwd_op_dist_attr.process_mesh ref_chunk_id = fwd_op_dist_attr.chunk_id if grad_op.type == "concat" and forward_op.type == "split": split_input_var_name = forward_op.input("X")[0] ref_dims_mapping = fwd_op_dist_attr.get_input_dims_mapping( split_input_var_name ) # var output_var = vars[grad_op.desc.output('Out')[0]] set_var_dist_attr( self._dist_context, output_var, ref_dims_mapping, ref_process_mesh, chunk_id=ref_chunk_id, ) # op for input_name in grad_op.input_arg_names: grad_op_dist_attr.set_input_dims_mapping( input_name, ref_dims_mapping ) grad_op_dist_attr.set_output_dims_mapping( output_var.name, ref_dims_mapping ) else: # complete grad_op's input_dist_attrs, no need to complete input_var's tensor_dist_attr for input_name in grad_op.input_arg_names: if ( input_name not in forward_op.input_arg_names and input_name not in forward_op.output_arg_names ): if input_name in grad_var_to_var: fwd_name = grad_var_to_var[input_name] ref_dims_mapping = ( fwd_op_dist_attr.get_output_dims_mapping( fwd_name ) ) else: input_var = vars[input_name] ref_dims_mapping = self._dist_context.get_tensor_dist_attr_for_program( input_var ).dims_mapping else: if input_name in forward_op.input_arg_names: ref_dims_mapping = ( fwd_op_dist_attr.get_input_dims_mapping( input_name ) ) else: ref_dims_mapping = ( fwd_op_dist_attr.get_output_dims_mapping( input_name ) ) assert ref_dims_mapping is not None, ( f"[{input_name}] 's dims mapping is NONE" ) grad_op_dist_attr.set_input_dims_mapping( input_name, ref_dims_mapping ) # complete grad_op's output_dist_attrs, and output_var's tensor_dist_attr for output_name in grad_op.output_arg_names: if output_name == "@EMPTY@": output_var = vars[output_name] ref_dims_mapping = [ -1 for _ in range(len(output_var.shape)) ] set_var_dist_attr( self._dist_context, output_var, ref_dims_mapping, ref_process_mesh, chunk_id=ref_chunk_id, ) grad_op_dist_attr.set_output_dims_mapping( output_name, ref_dims_mapping ) continue assert output_name in grad_var_to_var fwd_name = grad_var_to_var[output_name] ref_dims_mapping = fwd_op_dist_attr.get_input_dims_mapping( fwd_name ) # var output_var = vars[output_name] set_var_dist_attr( self._dist_context, output_var, ref_dims_mapping, ref_process_mesh, chunk_id=ref_chunk_id, ) # op grad_op_dist_attr.set_output_dims_mapping( output_name, ref_dims_mapping ) grad_op_dist_attr.process_mesh = ref_process_mesh grad_op_dist_attr.chunk_id = ref_chunk_id grad_op_dist_attr.impl_type = fwd_op_dist_attr.impl_type grad_op_dist_attr.impl_idx = fwd_op_dist_attr.impl_idx grad_op_dist_attr.chunk_id = fwd_op_dist_attr.chunk_id # inference partial backward def infer_backward_op_partial_status( vars, grad_op, grad_op_dist_attr ): # NOTE Since we use composite op in static mode which might have implicit Reduction of broadcast axes for calculating parameter's gradient. # Those implicit Reduction hinder the Partial inference in a normal way, and we need a special method to handle it. param_grads = [] activation_grad = None broadcast_axis_indies = [] if ( grad_op.type == "matmul_v2_grad" and len(grad_op.output("Y@GRAD")) > 0 ): activation_grad = grad_op.input("Out@GRAD")[0] param_grads.extend(grad_op.output("Y@GRAD")) act_ndim = len(vars[activation_grad].shape) param_ndim = len(vars[grad_op.output("Y@GRAD")[0]].shape) # TODO handle case where trans_x or trans_y is true # NOTE we regard axis m as broadcast axis since it is the contracting axis when calculate param grad. if param_ndim <= 2: if act_ndim > 1: broadcast_axis_indies = list(range(act_ndim - 1)) elif act_ndim > param_ndim: broadcast_axis_indies = list( range(act_ndim - param_ndim) ) elif grad_op.type == "elementwise_add_grad": activation_grad = grad_op.input("Out@GRAD")[0] param_grads.extend(grad_op.output("Y@GRAD")) param_var = grad_op.input("Y")[0] broadcast_axis_indies = list( range( len(vars[activation_grad].shape) - len(vars[param_var].shape) ) ) elif grad_op.type == "layer_norm_grad": activation_grad = grad_op.input("Y@GRAD")[0] param_grads.extend(grad_op.output("Bias@GRAD")) param_grads.extend(grad_op.output("Scale@GRAD")) begin_norm_axis = int(grad_op.attr("begin_norm_axis")) broadcast_axis_indies = list(range(begin_norm_axis)) elif grad_op.type == "lookup_table_v2_grad": activation_grad = grad_op.input("Out@GRAD")[0] param_grads.extend(grad_op.output("W@GRAD")) broadcast_axis_indies = list( range(len(vars[activation_grad].shape) - 1) ) else: raise NotImplementedError( f"Backward Partial is not adapted for {grad_op}" ) # resolute partial # NOTE We set the Partial status in op_dist_attr instead tensor_dist_attr # since the Partial will be reshard as Replicated immediately after op output in static mode. if len(param_grads) > 0: activation_grad_dims_mapping = ( grad_op_dist_attr.get_input_dims_mapping( activation_grad ) ) for axis in broadcast_axis_indies: if activation_grad_dims_mapping[axis] != -1: partial_dim = activation_grad_dims_mapping[axis] for p_grad_name in param_grads: p_grad_dist_attr = ( grad_op_dist_attr.get_output_dist_attr( p_grad_name ) ) p_grad_dist_attr._set_partial_dims( [partial_dim] ) if grad_op.type in _gradient_sync_by_partial_ops: infer_backward_op_partial_status( vars, grad_op, grad_op_dist_attr ) self._dist_context.set_op_dist_attr_for_program( grad_op, grad_op_dist_attr ) loss_op = None first_backward_op_idx = -1 for idx, op in enumerate(serial_main_program.global_block().ops): if is_loss_op(op): loss_op = op if is_loss_grad_op(op): assert op.type == "fill_constant" first_backward_op_idx = idx break assert first_backward_op_idx >= 0 and loss_op is not None, ( "No backward procedure found in this program." ) ops = list(serial_main_program.global_block().ops) vars = serial_main_program.global_block().vars dist_op_context = self._dist_context.dist_op_context grad_var_to_var = dist_op_context.grad_var_to_var[ len(dist_op_context.grad_var_to_var) ] for idx in range(first_backward_op_idx, len(ops)): grad_op = ops[idx] # complete the initial grad loss op if idx == first_backward_op_idx: assert grad_op.type == "fill_constant" assert len(grad_op.input_arg_names) == 0, ( f"first backward op should has only ONE output, but got [{len(grad_op.input_arg_names)}]" ) assert len(grad_op.output_arg_names) == 1, ( f"first backward op should has only ONE output, but got [{len(grad_op.output_arg_names)}]" ) loss_var = vars[loss_op.output_arg_names[0]] loss_grad_var = vars[grad_op.output_arg_names[0]] assert loss_var.name + "@GRAD" == loss_grad_var.name dist_loss_var = self._dist_context.get_dist_tensor_for_program( loss_var ) dist_loss_op = self._dist_context.get_dist_op_for_program( loss_op ) set_var_dist_attr( self._dist_context, loss_grad_var, dist_loss_var.dist_attr.dims_mapping, dist_loss_var.dist_attr.process_mesh, chunk_id=dist_loss_var.dist_attr.chunk_id, ) naive_set_dist_op_attr_for_program_by_mesh_and_mapping( grad_op, dist_loss_op.dist_attr.process_mesh, dist_loss_op.dist_attr.get_output_dims_mapping( loss_var.name ), self._dist_context, chunk_id=dist_loss_op.dist_attr.chunk_id, ) continue # complete the annotation of grad op (xxx_grad op or sum op) # xxx_grad op will have a corresponding forward op in grad_op_id_to_op_id if ( grad_op.desc.original_id() in dist_op_context.grad_op_id_to_op_id ): # TODO support the case where one forward op corresponding to multiple xxx_grad op forward_op = _get_op_by_id( ops[:first_backward_op_idx], dist_op_context.grad_op_id_to_op_id[ grad_op.desc.original_id() ], ) assert forward_op is not None if grad_op.has_attr('sub_block') and forward_op.has_attr( 'sub_block' ): _complete_grad_op_with_forward_op(forward_op, grad_op, vars) grad_sub_block_id = grad_op.attr('sub_block').id forward_sub_block_id = forward_op.attr('sub_block').id grad_sub_block = serial_main_program.blocks[ grad_sub_block_id ] forward_sub_block = serial_main_program.blocks[ forward_sub_block_id ] for sub_grad_op in grad_sub_block.ops: sub_forward_op = _get_op_by_id( forward_sub_block.ops, dist_op_context.grad_op_id_to_op_id[ sub_grad_op.desc.original_id() ], ) _complete_grad_op_with_forward_op( sub_forward_op, sub_grad_op, grad_sub_block.vars ) else: _complete_grad_op_with_forward_op(forward_op, grad_op, vars) # grad ops that have not a corresponding mapping in grad_op_id_to_op_id else: if grad_op.type in ['sum', 'grad_add']: assert all(map(_is_grad_var_name, grad_op.input_arg_names)) output_name = grad_op.output_arg_names[0] assert output_name in grad_var_to_var, ( f"sum op's output '{output_name}' has no corresponding var" ) ref_fwd_var_name = grad_var_to_var[output_name] ref_fwd_var = vars[ref_fwd_var_name] ref_fwd_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( ref_fwd_var ) ) ref_fwd_dims_mapping = ref_fwd_dist_attr.dims_mapping ref_fwd_process_mesh = ref_fwd_dist_attr.process_mesh ref_fwd_chunk_id = ref_fwd_dist_attr.chunk_id # output output_var = vars[output_name] set_var_dist_attr( self._dist_context, output_var, ref_fwd_dims_mapping, ref_fwd_process_mesh, chunk_id=ref_fwd_chunk_id, ) # op grad_op_dist_attr = OperatorDistAttr() for var_name in grad_op.input_arg_names: grad_op_dist_attr.set_input_dims_mapping( var_name, ref_fwd_dims_mapping ) grad_op_dist_attr.set_output_dims_mapping( output_name, ref_fwd_dims_mapping ) # NOTE(zhaoyingli): # The sum op is used to accumulate the grads' value of the same forward var, # sum op's chunk_id is same with the last op which generate the grad. ref_chunk_id = None ref_process_mesh = None for pre_idx in range( idx - 1, first_backward_op_idx + 1, -1 ): pre_grad_op = ops[pre_idx] inter_arg_name = list( set(pre_grad_op.output_arg_names) & set(grad_op.input_arg_names) ) if len(inter_arg_name) > 0: pre_op_dist_attr = ( self._dist_context.get_op_dist_attr_for_program( pre_grad_op ) ) ref_chunk_id = pre_op_dist_attr.chunk_id ref_process_mesh = pre_op_dist_attr.process_mesh break assert ( ref_chunk_id is not None and ref_process_mesh is not None ) grad_op_dist_attr.process_mesh = ref_process_mesh grad_op_dist_attr.chunk_id = ref_chunk_id self._dist_context.set_op_dist_attr_for_program( grad_op, grad_op_dist_attr ) elif grad_op.type == 'fill_any_like': ref_var_name = grad_op.input_arg_names[0] ref_var = vars[ref_var_name] ref_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( ref_var ) ) ref_dims_mapping = ref_dist_attr.dims_mapping ref_process_mesh = ref_dist_attr.process_mesh ref_chunk_id = ref_dist_attr.chunk_id # var output_var_name = grad_op.output_arg_names[0] output_var = vars[output_var_name] set_var_dist_attr( self._dist_context, output_var, ref_dims_mapping, ref_process_mesh, chunk_id=ref_chunk_id, ) # op grad_op_dist_attr = OperatorDistAttr() grad_op_dist_attr.process_mesh = ref_process_mesh grad_op_dist_attr.chunk_id = ref_chunk_id grad_op_dist_attr.set_input_dims_mapping( ref_var_name, ref_dims_mapping ) grad_op_dist_attr.set_output_dims_mapping( output_var_name, ref_dims_mapping ) self._dist_context.set_op_dist_attr_for_program( grad_op, grad_op_dist_attr ) else: raise ValueError(f"got unexpected op [{grad_op.type}]") def complete_update_annotation(self, serial_main_program): """Complete the annotation of vars and ops in the update phase for parallel program.""" # Copy the dist tensors and dist ops annotated by users from the default context # global mesh from paddle.distributed.auto_parallel.static.process_group import ( get_world_process_group, ) world_ranks = get_world_process_group().ranks # Notice: serial_main_program is actually a dist_main_program of current rank, # and must be passed into this function. # TODO: We should fix this behavior. ops = list(serial_main_program.global_block().ops) vars = serial_main_program.global_block().vars learning_rate_completed = False for idx in range(len(ops)): # complete the annotation of the optimizer op. # TODO to add attribute for moment var op = ops[idx] if int(op.attr('op_role')) == int(OpRole.Optimize): if is_gradient_clip_op(op): if op.type in _g_gradient_clip_ops: # complete op dist_attr with global world ranks op_dist_attr = OperatorDistAttr() op_dist_attr.process_mesh = ProcessMesh(world_ranks) for in_name in op.input_arg_names: in_var = vars[in_name] in_dist_attr = self._dist_context.get_tensor_dist_attr_for_program( in_var ) op_dist_attr.set_input_dims_mapping( in_name, in_dist_attr.dims_mapping ) for out_name in op.output_arg_names: out_var = vars[out_name] out_dist_attr = TensorDistAttr() out_dist_attr.process_mesh = ProcessMesh( world_ranks ) out_dist_attr.dims_mapping = [ -1 for _ in out_var.shape ] self._dist_context.set_tensor_dist_attr_for_program( out_var, out_dist_attr ) op_dist_attr.set_output_dims_mapping( out_name, out_dist_attr.dims_mapping ) else: # get ref_process_mesh and ref_dims_mapping from input_var in_var = vars[op.input("X")[0]] in_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( in_var ) ) assert in_dist_attr is not None ref_process_mesh = in_dist_attr.process_mesh ref_dims_mapping = in_dist_attr.dims_mapping ref_chunk_id = in_dist_attr.chunk_id if ( op.type == "cast" and ops[idx + 1].type == "elementwise_mul" ): ref_var = vars[ops[idx + 1].input("X")[0]] ref_dist_attr = self._dist_context.get_tensor_dist_attr_for_program( ref_var ) assert ref_dist_attr is not None ref_process_mesh = ref_dist_attr.process_mesh # complete out_var's tensor_dist_attr out_var = vars[op.output("Out")[0]] out_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( out_var ) ) if not out_dist_attr: out_dist_attr = TensorDistAttr() out_dist_attr.process_mesh = ref_process_mesh out_dist_attr.chunk_id = ref_chunk_id if out_var.shape == in_var.shape: out_dist_attr.dims_mapping = ref_dims_mapping else: assert ( len(out_var.shape) == 1 and out_var.shape[0] == 1 ) out_dist_attr.dims_mapping = [ -1 for _ in out_var.shape ] self._dist_context.set_tensor_dist_attr_for_program( out_var, out_dist_attr ) # complete op's dist_attr op_dist_attr = OperatorDistAttr() op_dist_attr.process_mesh = ref_process_mesh for in_name in op.input_arg_names: in_var = vars[in_name] in_dist_attr = self._dist_context.get_tensor_dist_attr_for_program( in_var ) op_dist_attr.set_input_dims_mapping( in_name, in_dist_attr.dims_mapping ) for out_name in op.output_arg_names: out_var = vars[out_name] out_dist_attr = self._dist_context.get_tensor_dist_attr_for_program( out_var ) op_dist_attr.set_output_dims_mapping( out_name, out_dist_attr.dims_mapping ) self._dist_context.set_op_dist_attr_for_program( op, op_dist_attr ) if "Grad" in op.input_names and "Param" in ops[idx].input_names: assert len(op.input("Param")) == 1, ( "Only support one-to-one now." ) assert len(op.input("Grad")) == 1, ( "Only support one-to-one now." ) param = vars[op.input("Param")[0]] grad_var = vars[op.input("Grad")[0]] param_dist_attr = ( self._dist_context.get_tensor_dist_attr_for_program( param ) ) assert param_dist_attr is not None ref_process_mesh = ( self._dist_context.get_tensor_dist_attr_for_program( param ).process_mesh ) assert ref_process_mesh is not None ref_dims_mapping = ( self._dist_context.get_tensor_dist_attr_for_program( param ).dims_mapping ) assert ref_dims_mapping is not None op_dist_attr = OperatorDistAttr() op_dist_attr.process_mesh = ref_process_mesh op_dist_attr.set_input_dims_mapping( grad_var.name, ref_dims_mapping ) op_dist_attr.set_input_dims_mapping( param.name, ref_dims_mapping ) op_dist_attr.set_output_dims_mapping( param.name, ref_dims_mapping ) learning_var = vars[op.input("LearningRate")[0]] op_dist_attr.set_input_dims_mapping( learning_var.name, [-1 for _ in learning_var.shape] ) op_dist_attr.set_output_dims_mapping( learning_var.name, [-1 for _ in learning_var.shape] ) if not learning_rate_completed: learning_rate_completed = True var_dist_attr = TensorDistAttr() var_dist_attr.process_mesh = ProcessMesh(world_ranks) var_dist_attr.dims_mapping = [ -1 for _ in learning_var.shape ] self._dist_context.set_tensor_dist_attr_for_program( learning_var, var_dist_attr ) for input_name in op.desc.input_names(): if input_name in [ 'Param', 'Grad', 'LearningRate', "Beta1Tensor", "Beta2Tensor", "EpsilonTensor", ]: continue if len(op.desc.input(input_name)) == 0: continue assert len(op.desc.input(input_name)) == 1 input_var = vars[op.desc.input(input_name)[0]] input_var_attr = TensorDistAttr() if ( "Beta1Pow" in input_name or "Beta2Pow" in input_name or "SkipUpdate" in input_name ): input_var_attr.dims_mapping = [-1] op_dist_attr.set_input_dims_mapping( input_var.name, [-1 for _ in input_var.shape] ) op_dist_attr.set_output_dims_mapping( input_var.name, [-1 for _ in input_var.shape] ) else: input_var_attr.dims_mapping = ref_dims_mapping op_dist_attr.set_input_dims_mapping( input_var.name, ref_dims_mapping ) op_dist_attr.set_output_dims_mapping( input_var.name, ref_dims_mapping ) if "SkipUpdate" not in input_name: input_var_attr.process_mesh = ref_process_mesh self._dist_context.set_tensor_dist_attr_for_program( input_var, input_var_attr ) self._dist_context.set_op_dist_attr_for_program( op, op_dist_attr ) continue def complete_prim_annotation(self, serial_main_program=None): """ fill default data parallel annotation for program with primitive operators. Arguments: serial_main_program: partial annotated serial_main_program. Returns: serial_main_program: completed annotated serial_main_program. """ if serial_main_program is None: serial_main_program = self._dist_context.serial_main_program else: self._dist_context._serial_main_program = serial_main_program self._dist_context._is_initialized = True self._dist_context._init_dist_attr_for_program() self._init_global_mesh_for_program() # Do the validation check and amend some completion self._dist_context.amend_dist_attr_for_program() self._dist_context.validate_dist_attr_for_program() def _init_global_mesh_for_program(self): # Copy the dist tensors and dist ops annotated by users from the default context # global mesh from paddle.distributed.auto_parallel.static.process_group import ( get_world_process_group, ) world_ranks = get_world_process_group().ranks for block in self._dist_context._serial_main_program.blocks: for tensor in block.vars.values(): # Copy the distributed tensors in the default context dist_tensor = self._dist_context.get_dist_tensor_for_program( tensor ) assert dist_tensor is not None dist_tensor.dist_attr.process_mesh = ProcessMesh(world_ranks) for op in block.ops: # Copy the distributed operators in the default context dist_op = self._dist_context.get_dist_op_for_program(op) assert dist_op is not None dist_op.dist_attr.process_mesh = ProcessMesh(world_ranks) # Find the most compatible implementations from the distributed operator op_dist_impls = find_compatible_distributed_operator_impls( dist_op, fwd=True ) if op_dist_impls is not None: backup_op_dist_attr = copy.deepcopy(dist_op.dist_attr) for op_dist_impl in op_dist_impls: dim_changed = op_dist_impl.update_dims_mapping(dist_op) if op_dist_impl.is_auto_compatible(dist_op): # if op_dist_impl.type == "elementwise": # dist_op.dist_attr.impl_type = "default" # else: dist_op.dist_attr.impl_type = op_dist_impl.type # op_dist_attr.impl_type = op_dist_impl.type dist_op.dist_attr.impl_idx = op_dist_impl.idx break else: dist_op.dist_attr = backup_op_dist_attr