# Copyright (c) 2020 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 paddle from paddle.fluid import unique_name, core import paddle.fluid as fluid from paddle.distributed.fleet.meta_optimizers.common import OpRole, OP_ROLE_VAR_KEY, CollectiveHelper from paddle.distributed.fleet.meta_optimizers.common import is_backward_op, is_optimizer_op, is_update_op from paddle.distributed.fleet.meta_optimizers.meta_optimizer_base import MetaOptimizerBase from paddle.distributed.fleet.meta_optimizers.sharding.shard import Shard, ProgramSegment from paddle.distributed.fleet.meta_optimizers.sharding.fp16_helper import FP16Utils from paddle.distributed.fleet.meta_optimizers.sharding.weight_decay_helper import WeightDecayHelper from paddle.distributed.fleet.meta_optimizers.sharding.gradient_clip_helper import GradientClipHelper from .sharding.offload_helper import OffloadHelper from paddle.distributed.fleet.meta_optimizers.sharding.prune import ProgramDeps from paddle.distributed.fleet.meta_optimizers.sharding.utils import * from paddle.fluid.framework import Program, Variable, name_scope, default_main_program, default_startup_program, device_guard from paddle.fluid import layers import logging logger = logging.getLogger(__name__) formatter = logging.Formatter( fmt='%(asctime)s %(levelname)-8s %(message)s', datefmt='%Y-%m-%d %H:%M:%S') ch = logging.StreamHandler() ch.setFormatter(formatter) logger.addHandler(ch) from functools import reduce __all__ = [] class ShardingOptimizer(MetaOptimizerBase): """Sharding Optimizer.""" def __init__(self, optimizer): super(ShardingOptimizer, self).__init__(optimizer) self.inner_opt = optimizer self.meta_optimizers_white_list = [ "RecomputeOptimizer", "AMPOptimizer", "LarsOptimizer", "LambOptimizer", # "ModelParallelOptimizer", # "PipelineOptimizer", ] self.meta_optimizers_black_list = ["GraphExecutionOptimizer", ] self._main_program = None self._startup_program = None self._segments = [] # params and fp16 params is for broadcast self._params = set([]) self._broadcast_vars = set([]) # reduced grads to param name self._reduced_grads_to_param = {} self._shard = Shard() self._verbose = False # use sharding as outer parallelism (e.g. inner:Megatron & outer sharding) self.mp_degree = 1 def _can_apply(self): if not self.role_maker._is_collective: return False if self.role_maker._worker_num() <= 1: return False return self.user_defined_strategy.sharding def _disable_strategy(self, dist_strategy): dist_strategy.sharding = False dist_strategy.sharding_configs = {} def _enable_strategy(self, dist_strategy, context): dist_strategy.sharding = True dist_strategy.sharding_configs = {"segment_broadcast_MB": 32} def _get_sharding_segment_strategy(self): """ get self._sharding_segment_strategy 1. if by_size: self._broadcast_MB 2. if by_anchors: self._sharding_segment_anchors self._backward_remain_anchors self._forward_remain_anchors """ strategy = self.user_defined_strategy sharding_configs = strategy.sharding_configs segment_strategy = str(sharding_configs["sharding_segment_strategy"]) if segment_strategy == "segment_broadcast_MB": self._broadcast_MB = sharding_configs["segment_broadcast_MB"] assert self._broadcast_MB > 0, "segment size should larger than zero !" elif segment_strategy == "segment_anchors": self._sharding_segment_anchors = sharding_configs["segment_anchors"] assert len(self._sharding_segment_anchors ) > 0, "you should set the sharding segment anchors !" self._backward_remain_anchors = self._sharding_segment_anchors[:] self._forward_remain_anchors = [] else: raise NotImplementedError( "the sharding segment strategy [{}] is not implemented".format( str(segment_strategy))) self._sharding_segment_strategy = segment_strategy def _get_hybrid_degree(self): """ get self.hybrid_dp self.sharding_degree self.mp_degree self.pp_degree self.dp_degree """ strategy = self.user_defined_strategy sharding_configs = strategy.sharding_configs # parallelism sharding_degree = int(sharding_configs["sharding_degree"]) mp_degree = int(sharding_configs["mp_degree"]) pp_degree = int(sharding_configs["pp_degree"]) dp_degree = int(sharding_configs['dp_degree']) global_world_size = self.role_maker._worker_num() assert sharding_degree > 0, "sharding degree must be larger than zero" # pipeline setting # TODO (JZ-LIANG) should revise here for support mix parallelism with pipeline if pp_degree > 1: assert strategy.pipeline is True assert global_world_size == mp_degree * sharding_degree * pp_degree * dp_degree, \ "global work size [{}], mp_degree [{}], sharding_degree [{}], pp_degree [{}], dp_degree [{}].".format( global_world_size, mp_degree, sharding_degree, pp_degree, dp_degree) # FIXME (JZ-LIANG) deprecated hybrid_dp if sharding_configs["hybrid_dp"]: logger.warning( "[hybrid_dp] API setting is deprecated. Now when " "dp_degree >= 2, its will be in hybrid dp mode automatically") assert dp_degree >= 1 self.hybrid_dp = True if dp_degree > 1 else False self.sharding_degree = sharding_degree self.mp_degree = mp_degree self.pp_degree = pp_degree self.dp_degree = dp_degree def _get_hybrid_dp_mode(self): """ get self.hybrid_dp_mode self.gradient_merge_mode self._gradient_merge_acc_step self.pp_allreduce_in_optimize """ strategy = self.user_defined_strategy sharding_configs = strategy.sharding_configs # NOTE (JZ-LIANG) # There 2 kind of modes for gradient-merge and hybrid-dp in mixed parallelism [sharding] and [pipeline]. # We distinguish this two modes since the gm/hybrid-dp related allreduce should be insert in different place # according different mode to have best performance: # sharding: communication within node, and therefore should insert within backward segment # to overlap with bw calc, conduct every micro step. # pipeline: communication across nodes, and therefore should insert in update segment, # conduct just once per global step. dp_mode = None # dp here is the pure dp as the outest parallelism if self.hybrid_dp: if self.pp_degree > 1: dp_mode = "pp_hybrid_dp" else: assert self.sharding_degree > 1, \ "by now we only support five kind of hybrid dp: sharding_hybrid_dp, " \ "mp_sharding_hybrid_dp, pp_hybrid_dp, mp_sharding_pp_hybrid_dp, sharding_pp_hybrid_dp." dp_mode = "sharding_hybrid_dp" # gradient merge gm_mode = None gm_acc_step = int(sharding_configs["gradient_merge_acc_step"]) if self.pp_degree <= 1: gm_mode = "sharding_gm" self._grad2merged_grad = dict() else: gm_mode = "pp_gm" gm_acc_step = strategy.pipeline_configs['accumulate_steps'] if gm_acc_step > 1: logger.info("Gradient merge in [{}], acc step = [{}]".format( gm_mode, gm_acc_step)) self.hybrid_dp_mode = dp_mode self.gradient_merge_mode = gm_mode self._gradient_merge_acc_step = gm_acc_step # this feature is design for ascend, and should NOT be used in GPU training self.pp_allreduce_in_optimize = sharding_configs[ "pp_allreduce_in_optimize"] def _inner_opt_minimize(self, loss, startup_program, parameter_list, no_grad_set): pipeline_configs = self.user_defined_strategy.pipeline_configs if self.inner_opt is None: raise ValueError( "self.inner_opt of ShardingOptimizer should not be None.") if self.pp_degree > 1: pp_optimizer = fluid.optimizer.PipelineOptimizer( self.inner_opt, self._gradient_merge_acc_step) self._pp_optimizer = pp_optimizer global_rank = self.role_maker._worker_index() schedule_mode = pipeline_configs['schedule_mode'] pipeline_opt = { 'schedule_mode': schedule_mode, 'micro_batch_size': pipeline_configs['micro_batch_size'], 'local_rank': self.pp_rank, 'global_rank': global_rank, 'use_sharding': True, # TODO (JZ-LIANG) should revise here for support mix parallelism with pipeline 'ring_id': 20, 'global_ring_id': 3, 'mp_degree': self.mp_degree, 'mp_rank': global_rank % self.mp_degree, } main_program = loss.block.program main_program._pipeline_opt = pipeline_opt optimize_ops, params_grads, program_list, self.pipeline_pair, self.pp_ring_map = pp_optimizer.minimize( loss, startup_program, parameter_list, no_grad_set) assert self.pp_degree == len(program_list) else: optimize_ops, params_grads = self.inner_opt.minimize( loss, startup_program, parameter_list, no_grad_set) if startup_program is None: startup_program = default_startup_program() if self.pp_degree > 1: startup_program = startup_program._pipeline_opt['startup_program'] print("pp_rank:", self.pp_rank) main_program = program_list[self.pp_rank] with open("main_%d" % self.role_maker._worker_index(), 'w') as f: f.writelines(str(main_program)) main_block = main_program.global_block() new_params_grads = [] for param, grad in params_grads: if main_block.has_var(param.name): new_params_grads.append((param, grad)) params_grads = new_params_grads else: main_block = loss.block startup_block = startup_program.global_block() self._main_program = main_block.program self._startup_program = startup_program if self.pp_degree > 1: pp_optimizer._rename_gradient_var_name(main_block) with open("main_%d" % self.role_maker._worker_index(), 'w') as f: f.writelines(str(main_program)) return optimize_ops, params_grads def _apply_sharding_pass(self, params_grads): if self.sharding_degree == 1: return main_block = self._main_program.global_block() startup_block = self._startup_program.global_block() # step1: build shard self._build_shard(params_grads) # step2: split_program self._split_program(main_block) # step3: add broadcast and reduce ops self._add_broadcast_allreduce(main_block) main_block._sync_with_cpp() startup_block._sync_with_cpp() # step4: remove unneeded ops and vars from block self._prune_main_program(main_block) self._prune_startup_program(startup_block) def _insert_allreduce_for_pp(self): if self.pp_degree == 1: return strategy = self.user_defined_strategy main_block = self._main_program.global_block() startup_block = self._startup_program.global_block() # sharding-pp related logic # pp_optimizer._rename_gradient_var_name(main_block) # crop ops if self.sharding_degree > 1: for idx, op in reversed(list(enumerate(main_block.ops))): if is_update_op(op): op_role_var = op.attr('op_role_var') param_name = op_role_var[0] if not self._shard.has_param(param_name): main_block._remove_op(idx) for idx, op in reversed(list(enumerate(main_block.ops))): if op.type != 'cast': continue in_name = op.input_arg_names[0] if in_name not in self._params: continue #if self._shard.has_param(param_name): continue if in_name not in main_block.vars: main_block._remove_op(idx) accumulated_grad_names = self._pp_optimizer._accumulate_gradients( main_block) # accumulated_grad_names = sorted(accumulated_grad_names) if self.pp_allreduce_in_optimize: print("persistable FP32 grad: ") print(accumulated_grad_names) first_optimize_op_index = get_first_check_finite_and_unscale_op_idx( main_block, raise_error=strategy.amp) insert_reduce_ops( main_block, first_optimize_op_index, self.sharding_ring_id, accumulated_grad_names, self._shard, core.op_proto_and_checker_maker.OpRole.Optimize, use_calc_stream=True) if self.hybrid_dp and self.hybrid_dp_mode == "pp_hybrid_dp": first_optimize_op_index = get_first_check_finite_and_unscale_op_idx( main_block, raise_error=strategy.amp) if first_optimize_op_index >= 0: insert_allreduce_ops( main_block, first_optimize_op_index, self.dp_ring_id, accumulated_grad_names, core.op_proto_and_checker_maker.OpRole.Optimize, use_calc_stream=True, user_defined_strategy=strategy) def _adapt_amp_clip_without_sharding(self): if self.sharding_degree > 1: return # if not use sharding, adapt amp/clip, for remain parallelism. # cast --> amp --> clip --> opt main_block = self._main_program.global_block() startup_block = self._startup_program.global_block() # FIXME(wangxi): mp should prune duplicated param_grads when calc # amp inf_var & clip global_norm_var FP16Utils.sync_amp_check_nan_inf(main_block, [self.mp_ring_id, self.pp_ring_id]) gradientclip_helper = GradientClipHelper(None) gradientclip_helper.sync_global_norm( main_block, [self.mp_ring_id, self.pp_ring_id]) def _insert_loss_grad_scale_op(self): main_block = self._main_program.global_block() # step6: loss div dp_degree global_dp_degree = self.sharding_degree * self.dp_degree assert int(global_dp_degree) == global_dp_degree if global_dp_degree > 1: insert_scale_loss_grad_ops(main_block, scale=1.0 / global_dp_degree) main_block._sync_with_cpp() def _apply_optimize_offload_pass(self): strategy = self.user_defined_strategy sharding_configs = strategy.sharding_configs main_block = self._main_program.global_block() startup_block = self._startup_program.global_block() # optimize offload should be enable while gradient merge is enable and # acc_step is quite large (e.g. >> 100). Since its memcpy could not be # overlap with calc, otherwise it will slower down training severely. if sharding_configs["optimize_offload"]: logger.info("Sharding with optimize offload !") offload_helper = OffloadHelper() offload_helper.offload(main_block, startup_block) offload_helper.offload_fp32param(main_block, startup_block) def _dump_program_for_debug(self): main_block = self._main_program.global_block() startup_block = self._startup_program.global_block() with open("start_sharding_%d" % self.role_maker._worker_index(), 'w') as f: f.writelines(str(startup_block.program)) with open("main_sharding_%d" % self.role_maker._worker_index(), 'w') as f: f.writelines(str(main_block.program)) def minimize_impl(self, loss, startup_program=None, parameter_list=None, no_grad_set=None): # TODO: (JZ-LIANG) support multiple comm in future # self._nrings = self.user_defined_strategy.nccl_comm_num self._nrings_sharding = 1 self._nrings_dp = 1 self._get_sharding_segment_strategy() self._get_hybrid_degree() self._get_hybrid_dp_mode() # config sharding & dp groups self._build_groups() # inner optimize minimize optimize_ops, params_grads = self._inner_opt_minimize( loss, startup_program, parameter_list, no_grad_set) self._init_comm() self._apply_sharding_pass(params_grads) self._insert_allreduce_for_pp() self._adapt_amp_clip_without_sharding() # loss div dp_degree self._insert_loss_grad_scale_op() self._apply_optimize_offload_pass() # step6: (optional) sharding gradient merge self._sharding_gradient_merge() # # check op dependecy # FIXME (JZ-LIANG) enable checking in future. # check_broadcast(main_block) # check_allreduce_sum(main_block, self._shard, self.sharding_ring_id, # self.dp_ring_id) # NOTE(JZ-LIANG) ensure in both sharding_hybrid_dp & pp_hybrid_dp # init param broadcast should be called after startup pruning self._initialization_broadcast() self._dump_program_for_debug() # GPU need to wait server ready, GPU and NPU is Layered connection if not core.is_compiled_with_npu(): self._wait() return optimize_ops, params_grads def _init_pair_comm(self, pair, ring_id): pp_group_endpoints = [ self.pp_group_endpoints[pair[0]], self.pp_group_endpoints[pair[1]], ] pp_rank = 0 if self.pp_rank == pair[0] else 1 self._collective_helper._init_communicator( self._startup_program, self.current_endpoint, pp_group_endpoints, pp_rank, ring_id, False, sync=False) def _init_npu_pipeline_comm(self, startup_block): # NOTE(wangxi): some bug with hccl, must set pp_degree be even number assert (self.pp_degree % 2) == 0 max_ring_id = -1 my_pair = [] for pair in self.pipeline_pair: pair_key = pair[0] * 1000 + pair[1] ring_id = self.pp_ring_map[pair_key] max_ring_id = max(max_ring_id, ring_id) logger.info("pp pair:{}, ring_id: {}".format(pair, ring_id)) if self.pp_rank in pair: my_pair.append(pair) # for example: self.pp_rank=2, self.pp_degree=4 send_to_next_pair = (self.pp_rank, (self.pp_rank + 1) % self.pp_degree) # 2->3 recv_from_next_pair = ((self.pp_rank + 1) % self.pp_degree, self.pp_rank) # 3->2 recv_from_prev_pair = ((self.pp_rank - 1 + self.pp_degree) % self.pp_degree, self.pp_rank) # 1->2 send_to_prev_pair = (self.pp_rank, (self.pp_rank - 1 + self.pp_degree) % self.pp_degree) # 2->1 even = (self.pp_rank % 2) == 0 # 1. even send to next, odd recv from prev, 0->1, 2->3 pair = send_to_next_pair if even else recv_from_prev_pair ring_id = self.pp_ring_map[pair[0] * 1000 + pair[1]] self._init_pair_comm(pair, ring_id) my_pair.remove(pair) logger.info("pair0(even->odd): pp pair:{}, ring_id: {}".format(pair, ring_id)) # 2. even recv from next, odd send to prev, 1->0, 3->2 pair = recv_from_next_pair if even else send_to_prev_pair ring_id = self.pp_ring_map[pair[0] * 1000 + pair[1]] self._init_pair_comm(pair, ring_id) my_pair.remove(pair) logger.info("pair1(even<-odd): pp pair:{}, ring_id: {}".format(pair, ring_id)) # if pp_degree is 2, only need pair(0->1, 1->0) if self.pp_degree > 2: # 3. odd send to next, even recv from prev, 1->2, 3->0 pair = send_to_next_pair if not even else recv_from_prev_pair ring_id = self.pp_ring_map.get( pair[0] * 1000 + pair[1], max_ring_id + 1) # 3->0 not in pp_ring_map self._init_pair_comm(pair, ring_id) if self.pp_rank != 0 and self.pp_rank != self.pp_degree - 1: my_pair.remove(pair) logger.info("pair2(odd->even): pp pair:{}, ring_id: {}".format( pair, ring_id)) # 4. odd recv from next, even send to prev, 2->1, 0->3 pair = recv_from_next_pair if not even else send_to_prev_pair ring_id = self.pp_ring_map.get( pair[0] * 1000 + pair[1], max_ring_id + 2) # 0->3 not in pp_ring_map self._init_pair_comm(pair, ring_id) if self.pp_rank != 0 and self.pp_rank != self.pp_degree - 1: my_pair.remove(pair) logger.info("pair3(odd<-even): pp pair:{}, ring_id: {}".format( pair, ring_id)) assert len(my_pair) == 0, "Current pipeline does not support cross stage communication, " \ "please check unexpected pair {}".format(my_pair) def _init_pipeline_comm(self, startup_block): # TODO (JZ-LIANG) to unify pp_rank_ and pp_rank self._collective_helper._init_communicator( self._startup_program, self.current_endpoint, self.pp_group_endpoints, self.pp_rank, self.pp_ring_id, False, sync=False) if core.is_compiled_with_npu(): self._init_npu_pipeline_comm(startup_block) return # GPU for pair in self.pipeline_pair: pair_key = pair[0] * 1000 + pair[1] ring_id = self.pp_ring_map[pair_key] logger.info("pp pair:{}, ring_id: {}".format(pair, ring_id)) if self.pp_rank in pair: self._init_pair_comm(pair, ring_id) def _init_comm(self): # sync var startup_block = self._startup_program.global_block() # mp ring if self.mp_degree > 1: self._collective_helper._init_communicator( self._startup_program, self.current_endpoint, self.mp_group_endpoints, self.mp_rank, self.mp_ring_id, False, sync=False) # sharding ring if self.sharding_degree > 1: self._collective_helper._init_communicator( self._startup_program, self.current_endpoint, self.sharding_group_endpoints, self.sharding_rank, self.sharding_ring_id, False, sync=False) # pp ring if self.pp_degree > 1: self._init_pipeline_comm(startup_block) # pure dp ring if self.dp_degree > 1: self._collective_helper._init_communicator( self._startup_program, self.current_endpoint, self.dp_group_endpoints, self.dp_rank, self.dp_ring_id, False, sync=False) startup_block._sync_with_cpp() def _build_shard(self, params_grads): # step 2: split params self._params = set([x[0].name for x in params_grads]) self._shard.setup(params_grads, self.sharding_rank, self.sharding_degree) # step 3: get broadcast vars self._broadcast_vars = self._shard.find_broadcast_params( self._main_program.global_block()) def _wait(self, ): endpoints = self.global_endpoints[:] current_endpoint = endpoints[self.global_rank] if self.global_rank == 0: self._collective_helper._wait(current_endpoint, endpoints) def collect_segment(self, segment, op_idx, block): segment._start_idx = op_idx + 1 self._segments.insert(0, segment) new_segment = ProgramSegment(block) new_segment._end_idx = op_idx + 1 return new_segment def _split_program(self, block): for op_idx, op in reversed(list(enumerate(block.ops))): if int(op.attr('op_role')) != int(OpRole.Optimize): last_backward_op_idx = op_idx + 1 break var2broadcast_time = dict() segment = ProgramSegment(block) segment._end_idx = last_backward_op_idx for op_idx in reversed(range(last_backward_op_idx)): op = block.ops[op_idx] assert (int(op.attr('op_role')) != int(OpRole.Optimize)) if self._sharding_segment_strategy == "segment_broadcast_MB": if segment._param_mem >= self._broadcast_MB: segment = self.collect_segment(segment, op_idx, block) elif self._sharding_segment_strategy == "segment_anchors": if int(op.attr('op_role')) == int(OpRole.Backward): for input_name in op.desc.input_arg_names(): # NOTE (JZ-LIANG) naive rule to support amp, if amp change, should modify here accordingly if self.user_defined_strategy.amp: if ".cast_fp16@GRAD" not in input_name: continue else: input_name = input_name[:input_name.find( ".cast_fp16@GRAD")] if input_name in self._backward_remain_anchors: segment = self.collect_segment(segment, op_idx, block) assert input_name not in self._forward_remain_anchors, "segment anchor [{}] met twice !".format( input_name) self._backward_remain_anchors.remove(input_name) self._forward_remain_anchors.append(input_name) elif int(op.attr('op_role')) == int(OpRole.Forward): for output_name in op.desc.output_arg_names(): if output_name in self._forward_remain_anchors: segment = self.collect_segment(segment, op_idx, block) self._forward_remain_anchors.remove(output_name) # find broadcast vars for input_name in op.desc.input_arg_names(): if input_name not in self._broadcast_vars: continue if input_name in segment._param2broadcast: # skip broadcast because it reuse the old broadcast var broadcast_name = segment._param2broadcast[input_name] if input_name != broadcast_name: op._rename_input(input_name, broadcast_name) continue if self._shard.has_param(input_name): broadcast_var_name = input_name else: broadcast_var_name = unique_name.generate(input_name + "@BroadCast") segment._fill_constant_vars.append(broadcast_var_name) # (JZ-LIANG) should use Param base name ? broadcast_var_base_name = input_name if "subprog" in broadcast_var_base_name: # remove suffix broadcast_var_base_name = broadcast_var_base_name[: broadcast_var_base_name. find( ".subprog" )] var2broadcast_time[ broadcast_var_base_name] = var2broadcast_time.get( broadcast_var_base_name, 0) + 1 segment._param2broadcast[input_name] = broadcast_var_name segment._broadcast_vars.append((broadcast_var_name, self._shard.device(input_name))) segment._param_mem += get_var_size( self._main_program.global_block().var(input_name)) # find reduce vars if self.pp_degree > 1 and self.pp_allreduce_in_optimize: # place pipeline gradient allreduce in optimize pass else: if is_backward_op(op) and \ OP_ROLE_VAR_KEY in op.attr_names: op_role_var = op.all_attrs()[OP_ROLE_VAR_KEY] if len(op_role_var) != 0: assert len(op_role_var) % 2 == 0 for i in range(0, len(op_role_var), 2): param, reduced_grad = op_role_var[i], op_role_var[ i + 1] segment._allreduce_vars.append(reduced_grad) assert (reduced_grad not in self._reduced_grads_to_param) self._reduced_grads_to_param[reduced_grad] = param # find cast op if FP16Utils.is_fp16_cast_op(block, op, self._params): fp32_param = op.desc.input_arg_names()[0] fp16_param = op.desc.output_arg_names()[0] if self._shard.has_param(fp32_param): segment._cast_ops[fp16_param] = fp32_param if segment._param_mem > 0: segment._start_idx = 0 self._segments.insert(0, segment) if self._sharding_segment_strategy == "segment_anchors": assert len( self._forward_remain_anchors) == 0, "remain anchors {}".format( self._forward_remain_anchors) assert len( self._backward_remain_anchors) == 0, "remain anchors {}".format( self._backward_remain_anchors) if self._verbose: for varname in sorted( var2broadcast_time, key=var2broadcast_time.get, reverse=True): logger.info("Sharding broadcast: [{}] times [{}]".format( var2broadcast_time[varname], varname)) for idx_ in range(len(self._segments)): logger.info("segment [{}] :".format(idx_)) logger.info("start op: [{}] [{}]".format(block.ops[ self._segments[idx_]._start_idx].desc.type(), block.ops[ self._segments[idx_]._start_idx].desc.input_arg_names( ))) logger.info("end op: [{}] [{}]".format(block.ops[ self._segments[idx_]._end_idx].desc.type(), block.ops[ self._segments[idx_]._end_idx].desc.input_arg_names())) return def _prune_main_program(self, block): """ calculate deps from allredce op to optimize op, remove ops and vars not needed in this worker 1. prune regularization (weight decay) 2. prune cast_fp32_to_fp16; update amp_infine_checking 3. prune gradient_clip related; update global_norm_sum 4. prune optimizer op + param + gradient """ weightdecay_helper = WeightDecayHelper() weightdecay_helper.prune_weight_decay(block, self._shard) # FIXME(wangxi): mp should prune duplicated param_grads # NOTE (JZ-LIANG) the sync of FoundInfinite should among one entire Model Parallelism # group. and each Data Parallelism group should have its own sync of FoundInfinite # amp could use global group for sync FP16Utils.prune_fp16( block, self._shard, self._reduced_grads_to_param, [self.mp_ring_id, self.sharding_ring_id, self.pp_ring_id]) # clipbyglobalnorm should only use the Model paramllelism group (mp-sharding-pp) gradientclip_helper = GradientClipHelper(None) gradientclip_helper.prune_gradient_clip( block, self._shard, [self.mp_ring_id, self.sharding_ring_id, self.pp_ring_id]) # build prog deps reduced_grads = [] for idx, op in enumerate(block.ops): input_names = op.desc.input_arg_names() output_names = op.desc.output_arg_names() if op.type == "c_allreduce_sum": assert (len(output_names) == 1) output_name = output_names[0] reduced_grads.append(output_name) # prune optimizer state and param pruned_opti_vars = [] for var_name in list(block.vars.keys()): if self._shard.is_opti_var(var_name) and \ not self._shard.has_opt_var(var_name): pruned_opti_vars.append(var_name) program_deps = ProgramDeps(block, reduced_grads, pruned_opti_vars) # Init for var_name in program_deps._end_vars: program_deps._should_removed_var.add(var_name) # Prune for idx, op in reversed(list(enumerate(block.ops))): if op.type in [ "c_allreduce_sum", "c_sync_comm_stream", "c_calc_comm_stream", "c_gen_nccl_id", "c_comm_init", 'send_v2', 'recv_v2', ]: pass elif op.type == "conditional_block": assert (op.desc.has_attr("sub_block")) subblock_idx = op.desc.attr("sub_block").id subblock_deps = program_deps.get_sub_block_deps(subblock_idx) # only prune amp subblock if subblock_deps is None or not self._is_amp_subblock(op): continue # init reversed_output_vars = [] for output_name in op.desc.output("Out"): if output_name in program_deps._should_removed_var: subblock_deps._should_removed_var.add(output_name) program_deps.crop_output_var_from_op(idx, output_name) else: reversed_output_vars.append(output_name) # prune for sub_op_idx, _ in reversed( list(enumerate(subblock_deps._block.ops))): if subblock_deps.should_remove_op(sub_op_idx): subblock_deps.remove_op(sub_op_idx) reversed_input_vars = [] for input_name in op.desc.input('Input'): if input_name not in subblock_deps._should_removed_var: reversed_input_vars.append(input_name) else: program_deps.crop_input_var_from_op(idx, input_name) op.desc.set_input('Input', reversed_input_vars) op.desc.set_output('Out', reversed_output_vars) else: # if all outputs of this op are in _should_removed_var # _should_removed_var: opt state not cur shard if program_deps.should_remove_op(idx): program_deps.remove_op(idx) # NOTE (JZ-LIANG) revise and unify logic here # sharding support fp16_allreduce logic block._sync_with_cpp() for idx, op in reversed(list(enumerate(block.ops))): if op.type == 'concat' and is_optimizer_op(op): # remove inputs that not on this card reserved_x = [] for var_name in op.desc.input("X"): if block.has_var(var_name): reserved_x.append(var_name) op.desc.set_input('X', reserved_x) block._sync_with_cpp() return def _add_broadcast_allreduce(self, block): """ add broadcast allreduce op if enable gradient_merge, insert related ops if combined with pipeline(grad accumulate), the grad allreduce should be done in optimize role """ if len(self._segments) < 1: return # sharding if self.pp_degree > 1 and self.pp_allreduce_in_optimize: for idx in range(len(self._segments)): assert len(self._segments[idx]._allreduce_vars) == 0 # NOTE (JZ-LIANG) revise and unify logic here # fix the _end_idx for segments[-1] if pp is used. new_end_idx = self._segments[-1]._end_idx for idx in range(self._segments[-1]._end_idx - 1, self._segments[-1]._start_idx - 1, -1): op = block.ops[idx] if op.type == "fill_constant" or op.type == "sum": if "MERGED" in op.output_arg_names[0]: new_end_idx = idx + 1 elif op.type == "cast": if "@TMP" in op.output_arg_names[0]: new_end_idx = idx + 1 self._segments[-1]._end_idx = new_end_idx if self._segments[-1]._allreduce_vars: shard_allredue_vars = self._shard.filter_grads(self._segments[-1] ._allreduce_vars) if self.gradient_merge_mode != "sharding_gm" or self._gradient_merge_acc_step <= 1: if self.hybrid_dp and self.hybrid_dp_mode == "sharding_hybrid_dp" and len( shard_allredue_vars) >= 1: insert_sync_comm_ops(block, self._segments[-1]._end_idx, self.dp_ring_id, shard_allredue_vars) insert_allreduce_ops( block, self._segments[-1]._end_idx, self.dp_ring_id, shard_allredue_vars, user_defined_strategy=self.user_defined_strategy) # gradient merge elif self.gradient_merge_mode == "sharding_gm" and self._gradient_merge_acc_step > 1: self.create_persistable_gradients_and_insert_merge_ops( block, self._startup_program.global_block(), self._segments[-1]._end_idx, shard_allredue_vars, self._shard) insert_sync_comm_ops(block, self._segments[-1]._end_idx, self.sharding_ring_id, self._segments[-1]._allreduce_vars) # allreduce --> reduce insert_reduce_ops( block, self._segments[-1]._end_idx, self.sharding_ring_id, self._segments[-1]._allreduce_vars, self._shard, op_role=OpRole.Backward, use_calc_stream=False) for idx, segment in reversed(list(enumerate(self._segments))): allreduce_vars = self._segments[ idx - 1]._allreduce_vars if idx > 0 else [] broadcast_vars = self._segments[idx + 1]._broadcast_vars if idx < len( self._segments) - 1 else [] fill_constant_vars = self._segments[ idx + 2]._fill_constant_vars if idx < len( self._segments) - 2 else [] cast_ops = self._segments[idx + 2]._cast_ops if idx < len( self._segments) - 2 else {} for op_idx in reversed(range(segment._start_idx, segment._end_idx)): op = block.ops[op_idx] for input_name in op.desc.input_arg_names(): if input_name in segment._param2broadcast and \ input_name != segment._param2broadcast[input_name]: op._rename_input(input_name, segment._param2broadcast[input_name]) for param_name, broadcast_name in segment._param2broadcast.items(): if param_name != broadcast_name: block.create_var( name=broadcast_name, shape=self._main_program.global_block().var( param_name).shape, dtype=self._main_program.global_block().var(param_name) .dtype, persistable=False) # step1: remove cast ops block._sync_with_cpp() segment._end_idx += FP16Utils.remove_cast_op(block, self._params, segment, 0) # step2: add Sync ops shard_allredue_vars = self._shard.filter_grads(allreduce_vars) if self.gradient_merge_mode != "sharding_gm" or self._gradient_merge_acc_step <= 1: if self.hybrid_dp and self.hybrid_dp_mode == "sharding_hybrid_dp" and len( shard_allredue_vars) >= 1: insert_sync_comm_ops(block, segment._end_idx, self.dp_ring_id, shard_allredue_vars) broad_cast_vars = [x[0] for x in broadcast_vars] if len(broad_cast_vars) > 0: insert_sync_comm_ops(block, segment._end_idx, self.sharding_ring_id, broad_cast_vars) else: comm_dep_vars = allreduce_vars + [ x[0] for x in broadcast_vars ] if len(comm_dep_vars) > 0: insert_sync_comm_ops(block, segment._end_idx, self.sharding_ring_id, comm_dep_vars) # gradient merge elif self.gradient_merge_mode == "sharding_gm" and self._gradient_merge_acc_step > 1: broad_cast_vars = [x[0] for x in broadcast_vars] if len(broad_cast_vars) > 0: insert_sync_comm_ops(block, segment._end_idx, self.sharding_ring_id, broad_cast_vars) calc_dep_vars = fill_constant_vars + [ k for k, v in cast_ops.items() ] + self._segments[idx]._allreduce_vars if len(calc_dep_vars) > 0: insert_sync_calc_op(block, segment._end_idx, [calc_dep_vars[-1]]) # step3: insert `fill_constant` ops insert_fill_constant_ops(block, segment._end_idx, fill_constant_vars) # step4: add `cast` ops insert_cast_ops(block, segment._end_idx, cast_ops) # step5: add broadcast ops # gradient merge if self.gradient_merge_mode == "sharding_gm" and self._gradient_merge_acc_step > 1: self.create_persistable_gradients_and_insert_merge_ops( block, self._startup_program.global_block(), segment._start_idx, shard_allredue_vars, self._shard) insert_broadcast_ops(block, segment._start_idx, self.sharding_ring_id, broadcast_vars) # step6: add all_reduce ops # dp if self.gradient_merge_mode != "sharding_gm" or self._gradient_merge_acc_step <= 1: if self.hybrid_dp and self.hybrid_dp_mode == "sharding_hybrid_dp" and len( shard_allredue_vars) >= 1: insert_allreduce_ops( block, segment._start_idx, self.dp_ring_id, shard_allredue_vars, user_defined_strategy=self.user_defined_strategy) insert_sync_comm_ops(block, segment._start_idx, self.sharding_ring_id, allreduce_vars) # gradient merge elif self.gradient_merge_mode == "sharding_gm" and self._gradient_merge_acc_step > 1: insert_sync_comm_ops(block, segment._start_idx, self.sharding_ring_id, allreduce_vars) # sharding # allreduce --> reduce # TODO temp change if len(allreduce_vars) > 0: insert_reduce_ops( block, segment._start_idx, self.sharding_ring_id, allreduce_vars, self._shard, op_role=OpRole.Backward, use_calc_stream=False) block._sync_with_cpp() if self._segments[0]._broadcast_vars: broadcast_vars = [x[0] for x in self._segments[0]._broadcast_vars] insert_sync_comm_ops(block, self._segments[0]._start_idx, self.sharding_ring_id, broadcast_vars) insert_broadcast_ops(block, self._segments[0]._start_idx, self.sharding_ring_id, self._segments[0]._broadcast_vars) fill_constant_vars = [] for x in self._segments[:2]: fill_constant_vars += x._fill_constant_vars # Join cast_ops = {} for x in self._segments[:2]: for k, v in x._cast_ops.items(): cast_ops[k] = v calc_deps_vars = fill_constant_vars + [k for k, v in cast_ops.items()] if fill_constant_vars or cast_ops: insert_sync_calc_op(block, self._segments[0]._start_idx, [calc_deps_vars[-1]]) if fill_constant_vars: insert_fill_constant_ops(block, self._segments[0]._start_idx, fill_constant_vars) if cast_ops: insert_cast_ops(block, self._segments[0]._start_idx, cast_ops) return def _prune_startup_program(self, block): for idx, op in reversed(list(enumerate(block.ops))): for output_name in op.desc.output_arg_names(): if self._shard.has_var(output_name): continue #TODO why do we remove op, when only one var is removed block._remove_op(idx, sync=False) break for var_name in list(block.vars.keys()): if self._shard.has_var(var_name): continue block._remove_var(var_name, sync=False) block._sync_with_cpp() def _build_groups(self): """ pre-assign ring ids mp: 0 sharding: 1 pure-dp: 2 global: 3 pp: 4 pp-pair: >= 20 if one parallelism is not enable: -1 and only support parallelism hierarchy: mp --> sharding --> pp --> dp """ # step 1: initialize nccl self.global_word_size = self.role_maker._worker_num() self.global_rank = self.role_maker._worker_index() self.global_endpoints = self.role_maker._get_trainer_endpoints() self.current_endpoint = self.global_endpoints[self.global_rank] self._collective_helper = CollectiveHelper( self.role_maker, nrings=self._nrings_sharding) assert self.global_word_size % self.mp_degree == 0, \ "global_word_size: {} should be divisible to the mp_degree: {}".format(self.global_word_size, self.mp_degree) assert self.global_word_size % self.sharding_degree == 0, \ "global_word_size: {} should be divisible to the sharding_degree: {}".format(self.global_word_size, self.sharding_degree) assert self.global_word_size % self.pp_degree == 0, \ "global_word_size: {} should be divisible to the pp_degree: {}".format(self.global_word_size, self.pp_degree) assert self.global_word_size % self.dp_degree == 0, \ "global_word_size: {} should be divisible to the dp_degree: {}".format(self.global_word_size, self.dp_degree) # mp group if self.mp_degree > 1: self.mp_ring_id = 0 self.mp_rank = self.global_rank % self.mp_degree self.mp_group_id = self.global_rank // self.mp_degree self.mp_group_endpoints = [ ep for idx, ep in enumerate(self.global_endpoints) if idx // self.mp_degree == self.mp_group_id ] assert self.current_endpoint in self.mp_group_endpoints assert len( self.mp_group_endpoints ) == self.mp_degree, "num of mp worker in group is [{}], but mp group size is [{}]".format( len(self.mp_group_endpoints), self.mp_degree) else: self.mp_degree = 1 self.mp_ring_id = -1 self.mp_rank = -1 self.mp_group_id = -1 self.mp_group_endpoints = [] # sharding if self.sharding_degree > 1: self.sharding_ring_id = 1 self.sharding_rank = (self.global_rank // self.mp_degree) % self.sharding_degree self.sharding_group_id = self.global_rank // (self.mp_degree * self.sharding_degree) # mp + sharding + ... if self.mp_degree > 1: self.sharding_group_endpoints = [ ep for idx, ep in enumerate(self.global_endpoints) if (idx // (self.mp_degree * self.sharding_degree)) == self. sharding_group_id and idx % self.mp_degree == self.mp_rank ] # sharding + ... else: self.sharding_group_endpoints = [ ep for idx, ep in enumerate(self.global_endpoints) if (idx // (self.mp_degree * self.sharding_degree) ) == self.sharding_group_id ] assert self.current_endpoint in self.sharding_group_endpoints else: self.sharding_degree = 1 self.sharding_ring_id = -1 self.sharding_rank = -1 self.sharding_group_id = -1 self.sharding_group_endpoints = [] # pp if self.pp_degree > 1: self.pp_pair_ring_id = 20 # pipeline global ring_id set to 4 for sharding0, mp1, dp2, global3 self.pp_ring_id = 4 self.pp_rank = self.global_rank // (self.sharding_degree * self.mp_degree) % self.pp_degree # (NOTE): Already adjust for (outter-pure) dp self.pp_group_id = self.global_rank // ( self.mp_degree * self.sharding_degree * self.pp_degree) pp_first_stage_idx = self.global_rank % ( self.sharding_degree * self.mp_degree) + self.pp_group_id * ( self.mp_degree * self.sharding_degree * self.pp_degree) pp_stage_offset = self.sharding_degree * self.mp_degree self.pp_group_endpoints = [] for i in range(self.pp_degree): self.pp_group_endpoints.append(self.global_endpoints[ pp_first_stage_idx + pp_stage_offset * i]) assert self.current_endpoint in self.pp_group_endpoints else: self.pp_ring_id = -1 self.pp_degree = 1 self.pp_pair_ring_id = -1 self.pp_rank = -1 self.pp_group_id = -1 self.pp_group_endpoints = [] # outter-pure-dp group # NOTE (JZ-LIANG) support outter-pure-dp to scale the throughput in 3D parallelism # e.g. mp-sharding-pp-dp # sharding-hybrid-dp as one senario of outter-pure-dp assert self.global_word_size == self.mp_degree * self.sharding_degree * self.pp_degree * self.dp_degree, "mp_degree: [{}], sharding_degree: [{}], pp_degree: [{}], dp_degree: [{}]; BUT global nrank: [{}]".format( self.mp_degree, self.sharding_degree, self.pp_degree, self.dp_degree, self.global_word_size) if self.dp_degree > 1: self.dp_ring_id = 2 self.dp_rank = self.global_rank // (self.sharding_degree * self.mp_degree * self.pp_degree) dp_first_rank_idx = self.global_rank % ( self.sharding_degree * self.mp_degree * self.pp_degree) dp_offset = (self.sharding_degree * self.mp_degree * self.pp_degree) self.dp_group_endpoints = [] for i in range(self.dp_degree): self.dp_group_endpoints.append(self.global_endpoints[ dp_first_rank_idx + dp_offset * i]) assert self.current_endpoint in self.dp_group_endpoints logger.info("Hybrid DP mode turn on !") else: self.dp_ring_id = -1 self.dp_rank = -1 self.dp_group_endpoints = [] # global group # use for gen_nccl_comm_sync, amp check nan inf, clip by global norm # NOTE (JZ-LIANG) when use global ring for calc global norm and dp_degree > 1, the allreduce result should be devided by dp_degree self.global_ring_id = 3 logger.info("global word size: {}".format(self.global_word_size)) logger.info("global rank: {}".format(self.global_rank)) logger.info("global endpoints: {}".format(self.global_endpoints)) logger.info("global ring id: {}".format(self.global_ring_id)) logger.info("#####" * 6) logger.info("mp group size: {}".format(self.mp_degree)) logger.info("mp rank: {}".format(self.mp_rank)) logger.info("mp group id: {}".format(self.mp_group_id)) logger.info("mp group endpoints: {}".format(self.mp_group_endpoints)) logger.info("mp ring id: {}".format(self.mp_ring_id)) logger.info("#####" * 6) logger.info("sharding group size: {}".format(self.sharding_degree)) logger.info("sharding rank: {}".format(self.sharding_rank)) logger.info("sharding group id: {}".format(self.sharding_group_id)) logger.info("sharding group endpoints: {}".format( self.sharding_group_endpoints)) logger.info("sharding ring id: {}".format(self.sharding_ring_id)) logger.info("#####" * 6) logger.info("pp group size: {}".format(self.pp_degree)) logger.info("pp rank: {}".format(self.pp_rank)) logger.info("pp group id: {}".format(self.pp_group_id)) logger.info("pp group endpoints: {}".format(self.pp_group_endpoints)) logger.info("pp ring id: {}".format(self.pp_ring_id)) logger.info("#####" * 6) logger.info("pure dp group size: {}".format(self.dp_degree)) logger.info("pure dp rank: {}".format(self.dp_rank)) logger.info("pure dp group endpoints: {}".format( self.dp_group_endpoints)) logger.info("pure dp ring id: {}".format(self.dp_ring_id)) logger.info("#####" * 6) return def _initialization_broadcast(self): """ this funtion is to ensure the initialization between dp group to be identical when hybrid-dp is used. """ if not self.hybrid_dp: return startup_block = self._startup_program.global_block() params = [] for param in startup_block.iter_parameters(): params.append(param) startup_block.append_op( type='c_broadcast', inputs={'X': param}, outputs={'Out': param}, attrs={ 'ring_id': self.dp_ring_id, 'root': 0, OP_ROLE_KEY: OpRole.Forward }) startup_block.append_op( type='c_sync_comm_stream', inputs={'X': params}, outputs={'Out': params}, attrs={'ring_id': self.dp_ring_id, OP_ROLE_KEY: OpRole.Forward}) # sharding gradient merge def create_persistable_gradients_and_insert_merge_ops( self, main_block, startup_block, insert_idx, grad_names, shard): for grad_name in grad_names: assert get_grad_device( grad_name, shard ) == shard.worker_idx, "try to merge gradient not belong to current shard: [{}]".format( grad_name) persistable_grad_name = grad_name + '@GradiantMerge' assert grad_name not in self._grad2merged_grad, "grad [{}] already in grad2merged_grad, maybe you meet sharing weight case !".format( grad_name) self._grad2merged_grad[grad_name] = persistable_grad_name grad_var = main_block.var(grad_name) # create var gradient_merge_var = main_block.create_var( name=persistable_grad_name, shape=grad_var.shape, dtype=grad_var.dtype, persistable=True) startup_gradient_merge_var = startup_block.create_var( name=persistable_grad_name, shape=grad_var.shape, dtype=grad_var.dtype, persistable=True) # merge gradient main_block._insert_op_without_sync( insert_idx, type="elementwise_add", inputs={'X': grad_name, 'Y': gradient_merge_var}, outputs={'Out': gradient_merge_var}, attrs={ 'axis': -1, 'use_mkldnn': False, OP_ROLE_KEY: OpRole.Backward }) # startup initialization startup_block.append_op( type="fill_constant", outputs={"Out": startup_gradient_merge_var}, attrs={ "shape": grad_var.shape, "dtype": grad_var.dtype, "value": float(0), }) main_block._sync_with_cpp() startup_block._sync_with_cpp() def _create_gm_cond(self, main_block): # Add const var acc_step_var = layers.create_global_var( name="gradient_merge_acc_step", shape=[1], value=int(self._gradient_merge_acc_step), dtype='int32', persistable=True, force_cpu=True) zero_var = layers.create_global_var( name="gradient_merge_zero", shape=[1], value=int(0), dtype='int32', persistable=True, force_cpu=True) # Add step var & cond var current_step_var = layers.create_global_var( name="gradient_merge_current_step", shape=[1], value=int(0), dtype='int32', persistable=True, force_cpu=True) cond_var = layers.create_global_var( name="gradient_merge_cond", shape=[1], value=bool(0), dtype='bool', persistable=False, force_cpu=True) with device_guard("cpu"): # step_var = (step_var + 1) % k_step main_block.append_op( type='increment', inputs={'X': [current_step_var]}, outputs={'Out': [current_step_var]}, attrs={'step': float(1), OP_ROLE_KEY: OpRole.Optimize}) main_block.append_op( type='elementwise_mod', inputs={'X': current_step_var, 'Y': acc_step_var}, outputs={'Out': current_step_var}, attrs={ 'axis': -1, OP_ROLE_KEY: OpRole.Optimize, 'use_mkldnn': False }) # cond_var = (step_var == 0) main_block.append_op( type='equal', inputs={'X': current_step_var, 'Y': zero_var}, outputs={'Out': cond_var}, attrs={OP_ROLE_KEY: OpRole.Optimize}) # paddle.static.Print(current_step_var, message="in FWBW last conditional") return cond_var def _true_apply_gradient(self): """ allreduce grad@gradientmerge in dp group grad@gradientmerge / acc_step re-create all optimize ops of origin main block and rename them cast(backward) amp clip opt # fill constant grad@gradientmerge """ # current conditional block main_block = self._main_program.global_block() cur_block_idx = self._main_program.current_block_idx cur_block = self._main_program.current_block() self.cond_block = self._main_program.current_block() # cur_block's forward_block & backward_block is itself cur_block._set_forward_block_idx(cur_block_idx) # allreduce grad@gradientmerge if self.hybrid_dp: assert self.dp_ring_id >= 0, "dp_ring_id should larger than 0 when in sharding&DP mode" for grad, merged_grad in self._grad2merged_grad.items(): merged_grad_var = main_block.var(merged_grad) cur_block.append_op( type='c_allreduce_sum', inputs={'X': merged_grad_var}, outputs={'Out': merged_grad_var}, attrs={ 'ring_id': self.dp_ring_id, 'use_calc_stream': True, OP_ROLE_KEY: OpRole.Optimize }) # grad@gradientmerge / acc_step for grad, merged_grad in self._grad2merged_grad.items(): # grad /= k_steps merged_grad_var = main_block.var(merged_grad) cur_block.append_op( type='scale', inputs={'X': merged_grad_var}, outputs={'Out': merged_grad_var}, attrs={ 'scale': 1.0 / float(self._gradient_merge_acc_step), 'bias': 0.0, 'bias_after_scale': False, OP_ROLE_KEY: OpRole.Optimize }) # re-create optimize ops already_moved_var_names = [] for op_desc in self.original_optimize_ops_desc: new_op_desc = cur_block.desc.append_op() new_op_desc.copy_from(op_desc) for input_name in new_op_desc.input_arg_names(): if input_name in self._grad2merged_grad: new_op_desc._rename_input( input_name, self._grad2merged_grad[input_name]) for output_name in new_op_desc.output_arg_names(): if output_name in self._grad2merged_grad: new_op_desc._rename_output( output_name, self._grad2merged_grad[output_name]) # move non temp optimize vars from block0 to cond block if output_name not in already_moved_var_names and output_name not in self._grad2merged_grad.keys( ): var_ = self._main_program.global_block().var(output_name) if not var_.persistable: # move name_ = var_.name shape_ = var_.shape type_ = var_.dtype self._main_program.global_block()._remove_var( var_.name, sync=False) self.cond_block.create_var( name=name_, shape=shape_, dtype=type_, persistable=False) already_moved_var_names.append(name_) self._main_program.global_block()._sync_with_cpp() cur_block._sync_with_cpp() # fill zero to grad@gradientmerge for grad, merged_grad in self._grad2merged_grad.items(): merged_grad_var = main_block.var(merged_grad) cur_block.append_op( type='fill_constant', outputs={'Out': merged_grad_var}, attrs={ "shape": merged_grad_var.shape, "dtype": merged_grad_var.dtype, "value": float(0), OP_ROLE_KEY: OpRole.Optimize }) # lr_var = main_block.var("gradient_merge_current_step") # paddle.static.Print(lr_var, message="in OPTIMIZE last conditional") def _sharding_gradient_merge(self): """ copy all optimize ops in origin main block remove all optimize ops in origin main block create cond block """ if self.gradient_merge_mode != "sharding_gm" or self._gradient_merge_acc_step <= 1: return main_block = self._main_program.global_block() # copy original optimize ops to temp ops desc list # remove them from block 0 tmp_copy_block = self._main_program._create_block() self.original_optimize_ops_desc = [] for op_idx, op in reversed(list(enumerate(main_block.ops))): if int(op.attr('op_role')) != int(OpRole.Optimize): continue else: tmp_op_desc = tmp_copy_block.desc.append_op() tmp_op_desc.copy_from(op.desc) self.original_optimize_ops_desc.append(tmp_op_desc) main_block._remove_op(op_idx, sync=False) tmp_copy_block._sync_with_cpp() self.original_optimize_ops_desc = list( reversed(self.original_optimize_ops_desc)) # back to block 0 self._main_program._rollback() # create cond vars and ops at the end of block 0 cond = self._create_gm_cond(main_block) # create cond block cond_block = self._main_program._create_block() self._true_apply_gradient() # back to block 0 self._main_program._rollback() # cond op step_scope = self._main_program.global_block().create_var( type=core.VarDesc.VarType.STEP_SCOPES) conditional_block_op = self._main_program.global_block().append_op( type='conditional_block', inputs={ 'Cond': cond, 'Input': [], }, outputs={'Out': [], 'Scope': [step_scope]}, attrs={ 'sub_block': cond_block, 'is_scalar_condition': True, })