# Copyright (c) 2022 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 os import logging import random import numpy as np from collections import defaultdict import paddle import paddle.utils as utils from paddle import fluid, static from paddle.metric import Metric from paddle.static import InputSpec from paddle.fluid import core from paddle.fluid import Variable from paddle.fluid.layers.utils import flatten from paddle.fluid.executor import global_scope, _to_name_str from paddle.fluid.framework import Operator, _non_static_mode from paddle.fluid.framework import _current_expected_place as _get_device from paddle.fluid.dygraph.parallel import ParallelEnv from paddle.distributed import fleet from .callbacks import config_callbacks from .converter import Converter from .helper import ProgramHelper from .cluster import Cluster, get_default_cluster from .planner_v2 import Planner from .parallelizer_v2 import Parallelizer from .dist_op import DistributedOperator from .dist_saver import DistributedSaver from .dist_loader import DistributedDataLoaderFromGenerator, DistributedDataLoader from .utils import to_list, get_dist_attr, get_lr from .process_group import new_process_group, get_all_process_groups from .dist_context import DistributedContext, get_default_distributed_context from .strategy import Strategy from .interface import CollectionNames, get_collection from ..utils.log_utils import get_logger from .utils import initialize_pg_in_full_mode from .cost.estimate_cost import get_cost_from_engine class Engine: """ An Engine object can provide the full power of auto parallel to users. With the help of it, users can easily obtain the abilities of the distributed training and inference. It also support the dynamic graph and static graph at the same time. Args: model (paddle.nn.Layer, optional): The model is an instance of paddle.nn.Layer. loss (Loss|Callable|None, optional): The loss can be a `paddle.nn.Layer` instance or any callable function taken the predicted values and ground truth values as input. It can be None when there is no loss. Default: None. optimizer (Optimizer|None, optional): The optimizer need to be set in training and should be None in eval and predict mode. Default: None. metrics (Metric|list[Metric]|None, optional): If metrics is set, all metrics will be calculated and output in train/eval mode. Default: None. cluster (Cluster|None, optional): The cluster represents the topology information about the used physical devices. Default: None. (Unused for now) strategy (Strategy|None, optional): The strategy is used to configure the parallelization and optimization behaviors. Default: None. Examples: .. code-block:: python import paddle import paddle.vision.transforms as T from paddle.distributed.fleet import auto from paddle.vision.datasets import MNIST transform = T.Compose([ T.Transpose(), T.Normalize([127.5], [127.5]) ]) train_dataset = MNIST(mode='train', transform=transform) valid_dataset = MNIST(mode='test', transform=transform) model = paddle.vision.models.LeNet() loss = paddle.nn.CrossEntropyLoss() optimizer = paddle.optimizer.Adam( learning_rate=0.001, parameters=model.parameters()) metrics = paddle.metric.Accuracy(topk=(1, 2)) engine = auto.Engine(model, loss, optimizer, metrics) # fit engine.fit(train_dataset, epochs=2, batch_size=64) # evaluate engine.evaluate(valid_dataset, batch_size=64) # predict engine.predict(valid_dataset, batch_size=64) # save engine.save("./my_model") # load engine.load("./my_model") """ def __init__(self, model=None, loss=None, optimizer=None, metrics=None, cluster=None, strategy=None): if model and not isinstance(model, paddle.nn.Layer) and not callable(model): raise TypeError( "'model must be sub classes of `paddle.nn.Layer` or any callable function." ) self._model = model self._loss = loss if optimizer and not isinstance( optimizer, (paddle.optimizer.Optimizer, paddle.fluid.optimizer.Optimizer)): raise TypeError( "'optimizer' must be object of class `paddle.optimizer.Optimizer`" " or `paddle.fluid.optimizer.Optimizer`.") self._optimizer = self._validate_opt(optimizer) metrics = metrics or [] for metric in to_list(metrics): assert isinstance(metric, Metric), \ "{} is not sub class of Metric".format( metric.__class__.__name__) self._metrics = to_list(metrics) if cluster and not isinstance(cluster, Cluster): raise TypeError( "'cluster' must be the object or class `paddle.distributed.auto_parallel.Cluster`" ) self._cluster = cluster or get_default_cluster() if strategy and not isinstance(strategy, Strategy): raise TypeError( "'strategy' must be object of class `paddle.distributed.auto_parallel.Strategy`" ) self._strategy = strategy or Strategy() if os.getenv("POD_NAME"): print("Distribute training by paddle.distributed.launch", flush=True) fleet.init(is_collective=True) self._executor = None self._cur_rank = paddle.distributed.get_rank() self._nranks = paddle.distributed.get_world_size() self._saver = DistributedSaver() self._logger = get_logger(logging.INFO) self._orig_main_prog = static.default_main_program() self._orig_startup_prog = static.default_startup_program() self._orig_dist_context = get_default_distributed_context() self._dist_contexts = {} self._serial_main_progs = {} self._serial_startup_progs = {} self._dist_main_progs = defaultdict(dict) # dist main programs self._dist_startup_progs = defaultdict(dict) # dist startup programs self._feed_vars = {} self._fetch_vars = {} self._planners = {} self._has_prepared = {"train": False, "eval": False, "predict": False} self._has_prepared_reader = { "train": False, "eval": False, "predict": False } self._inputs_spec = [] self._labels_spec = [] self._inputs = [] self._labels = [] self._skip_build = False self._outside_dataloader = False self._planned_mode = None self._dygraph_mode = False self._tuning = self._strategy.tuning self._losses = None self.history = None def _prepare_data_spec(self, data, split, batch_size): inputs_spec = [] labels_spec = [] if isinstance(data, paddle.io.IterableDataset): if split is None: inputs, labels = next(iter(data)) else: sample = next(iter(data)) inputs = sample[:split] labels = sample[split:] elif isinstance(data, paddle.io.Dataset): if split is None: inputs, labels = data[0] else: sample = data[0] inputs = sample[:split] labels = sample[split:] else: raise ValueError( "Data should be a Dataset or IterableDatset, but received {}.". format(type(data).__name__)) inputs = to_list(inputs) labels = to_list(labels) num_shards = self._strategy.dataset.num_shards def _adjust_item_spec(num_shards, spec): if num_shards > 1 and len(spec.shape) > 1: spec.shape[0] = spec.shape[0] * num_shards def _infer_item_spec(item, name, batch_size, specs): if isinstance(item, np.ndarray): spec = InputSpec.from_numpy(item, name) if batch_size is None: _adjust_item_spec(num_shards, spec) specs.append(spec) else: specs.append(spec.batch(batch_size)) elif isinstance(item, (Variable, core.VarBase, core.eager.Tensor)): spec = InputSpec.from_tensor(item, name) _adjust_item_spec(num_shards, spec) if batch_size is None: specs.append(spec) else: specs.append(spec.batch(batch_size)) else: specs.append(InputSpec([batch_size], type(item), name)) if inputs is not None: for i, item in enumerate(inputs): assert item is not None, "Receive None input." name = "input" + str(i) _infer_item_spec(item, name, batch_size, inputs_spec) if labels is not None: for i, item in enumerate(labels): assert item is not None, "Receive None input." name = "label" + str(i) _infer_item_spec(item, name, batch_size, labels_spec) inputs_spec = self._validate_spec(inputs_spec) labels_spec = self._validate_spec(labels_spec) return inputs_spec, labels_spec def _prepare_data_tensor(self, inputs_spec, labels_spec, inputs=None, labels=None): if _non_static_mode() or self._dygraph_mode: return None, None inputs_spec = inputs_spec if inputs_spec else [] labels_spec = labels_spec if labels_spec else [] if inputs_spec: assert isinstance(inputs_spec, list), \ "inputs should be list, but received {}".format(type(inputs_spec)) if inputs is None: inputs = [s._create_feed_layer() for s in inputs_spec] else: assert isinstance(inputs, list), \ "inputs should be list, but received {}".format(type(inputs)) for input_spec, input in zip(inputs_spec, inputs): if input_spec.shape != input.shape: input.desc.set_shape(input_spec.shape) if labels_spec: assert isinstance(labels_spec, list), \ "labels should be list, but received {}".format(type(labels_spec)) if labels is None: labels = [s._create_feed_layer() for s in labels_spec] else: assert isinstance(labels, list), \ "labels should be list, but received {}".format(type(labels)) for label_spec, label in zip(labels_spec, labels): if label_spec.shape != label.shape: label.desc.set_shape(label_spec.shape) return inputs, labels def _prepare_reader(self): dist_main_prog = self._dist_main_progs[self._mode][self._cur_rank] dist_context = self._dist_contexts[self._mode] dist_main_block = dist_main_prog.global_block() # NOTE: this list may be changed if Paddle changes the existing rules. related_reader_ops = [ "create_py_reader", "create_double_buffer_reader", "read" ] # remove the first three ops if multiple run fit/evaluate/predict if dist_main_block.ops[0].type == 'create_py_reader': for i in range(len(related_reader_ops)): if dist_main_block.ops[0].type in related_reader_ops: dist_main_block._remove_op(0, sync=False) dist_main_block._sync_with_cpp() # Step 1: find the reader ops reader_op_indices = [] for idx, op in enumerate(dist_main_block.ops): if op.type in related_reader_ops: reader_op_indices.append(idx) # Step 2: insert the new reader ops to cpp new_reader_ops = [] for idx in reversed(reader_op_indices): new_op_desc = dist_main_block.desc._prepend_op() new_op_desc.copy_from(dist_main_block.ops[idx].desc) new_op = Operator(dist_main_block, new_op_desc, type=new_op_desc.type()) new_reader_ops.append(new_op) dist_op = DistributedOperator(new_op) dist_context.add_dist_op_for_program(dist_op) # Step 3: insert the new reader ops to python for new_op in new_reader_ops: dist_main_block.ops.insert(0, new_op) for i in range(len(reader_op_indices)): reader_op_indices[i] += len(reader_op_indices) # Step 4: remove the old reader ops from python and cpp for idx in reversed(reader_op_indices): op = dist_main_block.ops.pop(idx) dist_main_block.desc._remove_op(idx, idx + 1) dist_main_block._sync_with_cpp() self._has_prepared_reader[self._mode] = True def _prepare_feed(self, data, user_feeds, mode): feeds = {} if data is not None: if isinstance(data, (list, tuple)): if len(data) == 1 and isinstance(data[0], dict): for name, data in data[0].items(): feeds[name] = data else: raise ValueError("Unsupported data {}".format(data)) elif isinstance(data, dict): for name, data in data.items(): feeds[name] = data else: raise ValueError("Unsupported data {}".format(data)) if user_feeds is not None: assert isinstance(user_feeds, dict), \ "user_feeds must be a dict, but receive {}".format(type(user_feeds).__name__) for name, data in user_feeds.items(): feeds[name] = data return feeds def _prepare_fetch(self, user_fetches, mode): if user_fetches is not None: assert isinstance(user_fetches, list), \ "user_fetches must be a list, but receive {}".format(type(user_fetches).__name__) fetch_names = [] fetch_indices = [] def _process_fetch_group(group_name, var_list): group_indices = [] for var in var_list: # Remove duplicate var_names if self._is_local_var(var): var_name = _to_name_str(var) if var_name not in fetch_names: fetch_names.append(var_name) group_indices.append(fetch_names.index(var_name)) if not group_indices: fetch_names.append([]) fetch_indices.append(group_indices) if mode != "predict": _process_fetch_group("loss", self._fetch_vars[mode]["loss"]) if mode != "predict": metrics = self._fetch_vars[mode]["metrics"] for i, var_list in enumerate(metrics): _process_fetch_group("metrics_" + str(i), var_list) if mode == "predict": _process_fetch_group("outputs", self._fetch_vars[mode]["outputs"]) user_fetches_collection = [ item[1] for item in get_collection(CollectionNames.FETCHES) ] var_list = (user_fetches_collection or []) + (user_fetches or []) _process_fetch_group("fetches", var_list) return fetch_names, fetch_indices def _prepare_logger(self, outs, epoch=None, step=None, lr=None, fetch_names=None, fetch_indices=None, mode=None): logs = {} if epoch is not None: logs["epoch"] = epoch if step is not None: logs["step"] = step + 1 if lr is not None: logs["lr"] = lr group_idx = 0 if mode != "predict": # logging loss loss_indices = fetch_indices[group_idx] assert len(loss_indices) <= 1 for idx in loss_indices: logs["loss"] = outs[idx][0] group_idx += 1 # logging metrics metric_vars = self._fetch_vars[mode]["metrics"] if metric_vars: for metric in self._metrics: metrics_indices = fetch_indices[group_idx] metric_out = [] for idx in metrics_indices: metric_out.append(outs[idx]) if metric_out: metric.update(*metric_out) results = metric.accumulate() for i, res in enumerate(to_list(results)): logs[metric.name()[i]] = res group_idx += 1 # logging outputs elif mode == "predict": outputs_indices = fetch_indices[group_idx] logs_out = {} for idx in outputs_indices: logs_out["out%d" % (idx)] = outs[idx] logs["outputs"] = logs_out group_idx += 1 # logging user fetches collect_fetches = get_collection(CollectionNames.FETCHES) logs_fetch = {} for name, var in collect_fetches: if var.name in fetch_names: idx = fetch_names.index(var.name) logs_fetch[name or var.name] = outs[idx] logs["fetches"] = logs_fetch return logs def _prepare_program(self, mode): # Do the build process self._build(mode) # Do the planning process self._plan(mode) # Do the parallel process self._parallel(mode) # Init comm and startup program self._initialize(mode) self._has_prepared[mode] = True def _build(self, mode): if _non_static_mode() or self._dygraph_mode: paddle.disable_static() self._dygraph_mode = True self._logger.info("Building model with 'to_static' method.") inputs_spec = self._inputs_spec labels_spec = self._labels_spec if self._labels_spec else [] self.program_helper = ProgramHelper(self._model, self._loss, self._metrics, inputs_spec, labels_spec) # build forward main program self.program_helper.build_program(mode) self.concrete_program = self.program_helper.concrete_program serial_main_prog = self.program_helper.main_program serial_startup_prog = self.program_helper.startup_program inputs = self.program_helper.input_vars outputs = self.program_helper.output_vars labels = self.program_helper.label_vars losses = self.program_helper.loss_vars self._losses = losses metrics = self.program_helper.metric_vars self._inputs = inputs self._labels = labels paddle.enable_static() else: # build program in static mode serial_main_prog = self._serial_main_progs.get(mode, None) if serial_main_prog is not None: return outputs = [] losses = [] metrics = [] inputs = self._inputs if self._inputs else [] labels = self._labels if self._labels else [] serial_main_prog = self._orig_main_prog.clone() serial_startup_prog = self._orig_startup_prog.clone() if not self._skip_build: with static.program_guard(serial_main_prog, serial_startup_prog), \ utils.unique_name.guard(): outputs = to_list(self._model(*inputs)) if mode != "predict" and self._loss: losses = to_list(self._loss(*(outputs + labels))) self._losses = losses if mode != "predict" and (outputs or labels): for metric in self._metrics: metrics.append( to_list(metric.compute(*(outputs + labels)))) else: losses = to_list(self._loss) self.losses = losses default_ctx = get_default_distributed_context() if not default_ctx.has_annotation: # We build the world process group because the data parallel # needs all ranks by default. new_process_group(list(range(self._nranks))) default_ctx.data_parallel = True feed_vars = {"inputs": inputs, "labels": labels} fetch_vars = { "outputs": flatten(outputs), "loss": losses, "metrics": metrics } if mode != "train": serial_main_prog = serial_main_prog.clone(for_test=True) self._set_recompute_ckpts() self._dist_contexts[mode] = DistributedContext( serial_main_prog, serial_startup_prog, self._optimizer, losses, feed_vars, fetch_vars, self._cluster, self._strategy) self._dist_contexts[mode].gradient_scale = self._strategy.gradient_scale def _optimization_tuning(self, mode, dataset, batch_size): if not self._tuning.enable: raise ValueError("Please set `tuning.enable=True`.") assert mode == "train" # Do the build process self._build(mode) # Do the planning process self._plan(mode) dataset.dp_world_size = self._dp_world_sizes dataset.dp_rank = self._dp_ranks from .tuner.optimization_tuner import OptimizationTuner self._optimization_tuner = OptimizationTuner(self._tuning.to_dict(), self._dist_contexts[mode], dataset, self._inputs_spec, self._labels_spec, batch_size=batch_size, rank=self._cur_rank) self._optimization_tuner.tune() if self._tuning.run_after_tuning: # update the strategy self._dist_contexts[ mode]._strategy = self._optimization_tuner.get_best_config() def _plan(self, mode): if self._planned_mode is None: self._planned_mode = mode else: self._init_dist_context(mode) self._planners[mode] = Planner(mode, self._dist_contexts[mode]) self._planners[mode].plan() # infer data parallel info inputs_var = self._dist_contexts[mode].serial_feed_vars["inputs"] labels_var = self._dist_contexts[mode].serial_feed_vars["labels"] block = self._dist_contexts[mode].serial_main_program.global_block() # TODO: check this feed_list feed_list = [] for var in inputs_var + labels_var: if var.name in block.vars: feed_list.append(block.vars[var.name]) self._dp_world_sizes = [] self._dp_ranks = [] for feed_var in feed_list: dp_world_size, dp_rank = self._get_input_split_info( feed_var, self._dist_contexts[mode]) self._dp_world_sizes.append(dp_world_size) self._dp_ranks.append(dp_rank) def _parallel(self, mode, all_ranks=False): # Parallelize program based on the planner's results # For now, the completer has to be passed to the planner, # because we may use it to complete the annotation of the backwarkward and update. parallelizer = Parallelizer(mode, self._planners[mode].completer, self._dist_contexts[mode]) if not all_ranks: parallelizer.parallel(self._cur_rank) else: parallelizer.parallel_all() def _init_dist_context(self, mode): # Init dist_context['mode'] with the first planned dist_context # to guarantee that train/eval/predict mode have same parallel strategy dist_context = self._dist_contexts[mode] origin_main_prog = dist_context._original_serial_main_program ref_mode = self._planned_mode ref_dist_context = self._dist_contexts[ref_mode] ref_origin_main_prog = ref_dist_context._original_serial_main_program ref_blocks = ref_origin_main_prog.blocks for ib, block in enumerate(origin_main_prog.blocks): for iop, op in enumerate(block.ops): ref_op = ref_blocks[ib].ops[iop] assert op.type == ref_op.type, \ "'{}' mode op '{}' is different with '{}' op '{}'. ".format(mode, op.type, ref_mode, ref_op.type) ref_op_dist_attr = ref_dist_context.get_op_dist_attr_for_program( ref_op) dist_context.set_op_dist_attr_for_program(op, ref_op_dist_attr) def _initialize(self, mode): # Get the current content from the distributed context self._serial_main_progs[mode] = self._dist_contexts[ mode].serial_main_program self._serial_startup_progs[mode] = self._dist_contexts[ mode].serial_startup_program self._dist_main_progs[mode] = self._dist_contexts[ mode].dist_main_programs self._dist_startup_progs[mode] = self._dist_contexts[ mode].dist_startup_programs self._feed_vars[mode] = self._dist_contexts[mode].serial_feed_vars self._fetch_vars[mode] = self._dist_contexts[mode].serial_fetch_vars self._optimizer = self._dist_contexts[mode]._serial_optimizer if self._nranks > 1: # Traverse different rank programs and traverse each op of them, # instantiate communication by process_mapping. all_process_groups = get_all_process_groups() cur_rank = self._cur_rank # NOTE: After the implementation of the unified dynamic and static communication group initialization mode in the future, the initialization logic of full mode will be removed because port occupation error may occur. if self._strategy.auto_mode == "full": initialize_pg_in_full_mode(all_process_groups, cur_rank) else: for process_group in all_process_groups: if cur_rank not in process_group.ranks: continue process_group.instantiate() place = _get_device() if isinstance(place, fluid.CUDAPlace): place = fluid.CUDAPlace(ParallelEnv().dev_id) if self._strategy.seed: paddle.seed(self._strategy.seed + self._dp_ranks[0]) np.random.seed(self._strategy.seed + self._dp_ranks[0]) random.seed(self._strategy.seed + self._dp_ranks[0]) if self._dygraph_mode: dist_context = self._dist_contexts[mode] dist_main_program = self._dist_main_progs[mode][self._cur_rank] self.program_helper.init(dist_main_program, place, dist_context) if self._executor is None: self._executor = paddle.static.Executor(place) uninitialized = [] dist_startup_prog = self._dist_startup_progs[mode][self._cur_rank] for var in dist_startup_prog.list_vars(): scope_var = global_scope().find_var(var.name) if scope_var and scope_var.get_tensor()._is_initialized(): continue uninitialized.append(var) if uninitialized: prune_startup_prog = dist_startup_prog._prune(uninitialized) self._executor.run(prune_startup_prog) if hasattr(self, "_state_dict") and hasattr(self, "_dist_attr"): self._set_state_dict(mode, self._strict, self._state_dict, self._dist_attr) if self._strategy.reinit: self._logger.info("NOTE: parameters will be re-initialized.") dist_startup_prog = self._dist_startup_progs[mode][self._cur_rank] self._executor.run(dist_startup_prog) def fit(self, train_data, train_sample_split=None, batch_size=1, epochs=1, steps_per_epoch=None, log_freq=10, save_dir=None, save_freq=1, valid_data=None, valid_sample_split=None, valid_freq=1, valid_steps=None, collate_fn=None, callbacks=None, verbose=2): """ Trains the model for a fixed number of epochs. If `valid_data` is set, evaluation will be done at the end of each epoch. Args: train_data (Dataset): An instance of paddle paddle.io.Dataset. Default: None. train_sample_split (int, optional): Each sample of the train dataset is assumed to be a (input, label) pair by default and has two items. If each sample has more than two items, train_sample_split specifies how to split these items into input and label. The items before it are input and the left are label. Default: None. batch_size (int, optional): The batch size of train_data and valid_data if provided. The user's data will be used directly without batching if set to None. Default: 1. epochs (int, optional): The number of epochs to train the model. Default: 1. steps_per_epoch (int, optional): The total number of steps (batches of samples) is executed in one epoch before stating the next one. If None, it is equal to the number samples in your dataset divided by the batch size. Default: None. valid_data (Dataset, optional): An instance of paddle paddle.io.Dataset used for evaluation at the end of epoch. No evaluation will be done if set to None. Default: None. (Unsupported for now) valid_freq (int, optional): Only relevant if valid_data is provided. This specifies how many training epochs before a new evaluation is performed. Default: 1. valid_sample_split (int, optional): Only relevant if valid_data is provided. Each sample of the valid dataset is assumed to be a (input, label) pair by default and has two items. If each sample has more than two items, valid_sample_split specifies how to split these items into input and label. The items before it are input and the left are label. Default: None. valid_steps (int, optional): Only relevant if valid_data is provided. It is the total number of steps (batches of samples) to draw before stopping validation at the end of every epoch. If None, validation will run until the `valid_data` dataset is exhausted. The validation will start from the beginning of the dataset at each epoch. Default: None. collate_fn(callable, optional): function to generate mini-batch data by merging the sample list, None for only stack each fields of sample in axis 0. Default None. callbacks (Callback|None, optional): A list of `Callback` instances to apply during training. Default: None. (Unused for now) Returns: None Examples: .. code-block:: python import paddle import paddle.vision.transforms as T from paddle.distributed.fleet import auto from paddle.vision.datasets import MNIST transform = T.Compose([ T.Transpose(), T.Normalize([127.5], [127.5]) ]) train_dataset = MNIST(mode='train', transform=transform) model = paddle.vision.models.LeNet() loss = paddle.nn.CrossEntropyLoss() optimizer = paddle.optimizer.Adam( learning_rate=0.001, parameters=model.parameters()) metrics = paddle.metric.Accuracy(topk=(1, 2)) engine = auto.Engine(model, loss, optimizer, metrics) engine.fit(train_dataset, epochs=2, batch_size=64) """ self._mode = 'train' self._inputs_spec, self._labels_spec = self._prepare_data_spec( train_data, train_sample_split, batch_size) self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) assert self._mode in self._dist_main_progs, \ "train model is not ready, please call `engine._prepare_program('train')` first." train_dataloader = self._prepare_dataloader_from_generator( dataset=train_data, capacity=70, iterable=False, batch_size=batch_size, epochs=epochs, steps_per_epoch=steps_per_epoch, collate_fn=collate_fn) fetch_names, fetch_indices = self._prepare_fetch(None, mode=self._mode) cbks = config_callbacks( callbacks, engine=self, batch_size=batch_size, epochs=epochs, steps=train_dataloader._steps, log_freq=log_freq, save_freq=save_freq, save_dir=save_dir, verbose=verbose, metrics=self._metrics_name(), acc_step=self._k_steps, ) cbks.on_begin('train') for epoch in range(epochs): logs = {} cbks.on_epoch_begin(epoch) for step, _ in enumerate(train_dataloader): cbks.on_batch_begin('train', step, logs) try: outs = self._executor.run( self.main_program, fetch_list=fetch_names, use_program_cache=self._strategy.use_cache, return_numpy=self._strategy.return_numpy) except core.EOFException: break lr = get_lr(self._optimizer) logs = self._prepare_logger(outs, epoch, step, lr, fetch_names, fetch_indices, self._mode) cbks.on_batch_end('train', step, logs) if valid_data and (epoch + 1) % valid_freq == 0: val_logs = self.evaluate(valid_data, valid_sample_split, batch_size, valid_steps, log_freq, collate_fn, callbacks, verbose) val_logs = { "val_" + name: val for name, val in val_logs.items() } logs.update(val_logs) self._switch_mode("train") else: self._reset_metrics() cbks.on_epoch_end(epoch, logs) cbks.on_end('train', logs) return self.history def evaluate(self, valid_data, valid_sample_split=None, batch_size=1, steps=None, log_freq=10, collate_fn=None, callbacks=None, verbose=2): """ Evaluate the loss and metrics of the model on evaluation data. Args: valid_data (Dataset): An instance of paddle paddle.io.Dataset. Default: None. valid_sample_split (int, optional): Each sample of the eval dataset is assumed to be a (input, label) pair by default and has two items. If each sample has more than two items, valid_sample_split specifies how to split these items into input and label. The items before it are input and the left are label. Default: None. batch_size (int, optional): The batch size of valid_data. The user's data will be used directly without batching if set to None. Default: 1. steps (int, optional): It is the total number of steps (batches of samples) to draw before stopping evaluation. If None, evaluation will run until the `valid_data` dataset is exhausted. The evaluation will start from the beginning of the dataset in each run. Default: None. collate_fn(callable, optional): function to generate mini-batch data by merging the sample list, None for only stack each fields of sample in axis 0. Default None. callbacks (Callback|None, optional): A list of `Callback` instances to apply during evaluating. Default: None. (Unused for now) Returns: None Examples: .. code-block:: python import paddle import paddle.vision.transforms as T from paddle.distributed.fleet import auto from paddle.vision.datasets import MNIST transform = T.Compose([ T.Transpose(), T.Normalize([127.5], [127.5]) ]) valid_dataset = MNIST(mode='test', transform=transform) model = paddle.vision.models.LeNet() loss = paddle.nn.CrossEntropyLoss() metrics = paddle.metric.Accuracy(topk=(1, 2)) engine = auto.Engine(model, loss, metrics=metrics) engine.evaluate(valid_dataset, batch_size=64) """ self._mode = 'eval' self._inputs_spec, self._labels_spec = self._prepare_data_spec( valid_data, valid_sample_split, batch_size) self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) assert self._mode in self._dist_main_progs, \ "eval model is not ready, please call `engine._prepare_program('eval')` first." valid_dataloader = self._prepare_dataloader_from_generator( dataset=valid_data, capacity=70, iterable=False, batch_size=batch_size, steps_per_epoch=steps, collate_fn=collate_fn) fetch_names, fetch_indices = self._prepare_fetch(None, mode=self._mode) cbks = config_callbacks( callbacks, engine=self, batch_size=batch_size, log_freq=log_freq, verbose=verbose, metrics=self._metrics_name(), ) eval_steps = valid_dataloader._steps cbks.on_begin('eval', { 'steps': eval_steps, 'metrics': self._metrics_name() }) logs = {} for step, _ in enumerate(valid_dataloader): cbks.on_batch_begin('eval', step, logs) try: outs = self._executor.run( self.main_program, fetch_list=fetch_names, use_program_cache=self._strategy.use_cache, return_numpy=self._strategy.return_numpy) except core.EOFException: break logs = self._prepare_logger(outs, None, step, None, fetch_names, fetch_indices, self._mode) cbks.on_batch_end('eval', step, logs) cbks.on_end('eval', logs) self._reset_metrics() return logs def predict(self, test_data, test_sample_split=None, batch_size=1, steps=None, collate_fn=None, callbacks=None, verbose=2): """ Compute the output predictions on testing data. Args: test_data (Dataset): An instance of paddle paddle.io.Dataset. Default: None. test_sample_split (int, optional): Each sample of the test dataset is assumed to be a (input, label) pair by default and has two items. If each sample has more than two items, test_sample_split specifies how to split these items into input and label. The items before it are input and the left are label. Default: None. batch_size (int, optional): The batch size of test_data. The user's data will be used directly without batching if set to None. Default: 1. steps (int, optional): It is the total number of steps (batches of samples) to draw before stopping predict. If None, predict will run until the `test_data` dataset is exhausted. The predict will start from the beginning of the dataset in each run. Default: None. collate_fn(callable, optional): function to generate mini-batch data by merging the sample list, None for only stack each fields of sample in axis 0. Default None. callbacks (Callback|None, optional): A list of `Callback` instances to apply during testing. Default: None. (Unused for now) Returns: None Examples: .. code-block:: python import paddle import paddle.vision.transforms as T from paddle.distributed.fleet import auto from paddle.vision.datasets import MNIST transform = T.Compose([ T.Transpose(), T.Normalize([127.5], [127.5]) ]) valid_dataset = MNIST(mode='test', transform=transform) model = paddle.vision.models.LeNet() engine = auto.Engine(model) engine.predict(valid_dataset, batch_size=64) """ self._mode = 'predict' self._inputs_spec, self._labels_spec = self._prepare_data_spec( test_data, test_sample_split, batch_size) self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) assert self._mode in self._dist_main_progs, \ "predict model is not ready, please call `engine._prepare_program('predict')` first." test_dataloader = self._prepare_dataloader_from_generator( dataset=test_data, capacity=70, iterable=False, batch_size=batch_size, steps_per_epoch=steps, collate_fn=collate_fn) fetch_names, fetch_indices = self._prepare_fetch(None, mode=self._mode) outputs = [] cbks = config_callbacks(callbacks, engine=self, verbose=verbose) test_steps = test_dataloader._steps cbks.on_begin('predict', {'steps': test_steps}) logs = {} for step, _ in enumerate(test_dataloader): cbks.on_batch_begin('predict', step, logs) try: outs = self._executor.run( self.main_program, fetch_list=fetch_names, use_program_cache=self._strategy.use_cache, return_numpy=self._strategy.return_numpy) except core.EOFException: break logs = self._prepare_logger(outs, None, step, None, fetch_names, fetch_indices, self._mode) cbks.on_batch_end('predict', step, logs) outputs.append(list(logs["outputs"].values())) cbks.on_end('predict', logs) return outputs def dataloader(self, dataset, batch_size=1, shuffle=False, drop_last=False, collate_fn=None, num_workers=0, use_buffer_reader=True, use_shared_memory=True, timeout=0, worker_init_fn=None, epochs=1, steps_per_epoch=None, sample_split=1, mode=None): if mode is not None: self.to_mode(mode) self._inputs_spec, self._labels_spec = self._prepare_data_spec( dataset, sample_split, batch_size) self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) dataloader = self._prepare_dataloader( dataset, return_list=False, batch_size=batch_size, shuffle=shuffle, drop_last=drop_last, collate_fn=collate_fn, num_workers=num_workers, use_buffer_reader=use_buffer_reader, use_shared_memory=use_shared_memory, timeout=timeout, worker_init_fn=worker_init_fn, epochs=epochs, steps_per_epoch=steps_per_epoch) return dataloader def dataloader_from_generator(self, dataset, capacity=70, use_double_buffer=True, iterable=True, use_multiprocess=False, drop_last=True, batch_size=1, epochs=1, steps_per_epoch=None, collate_fn=None, sample_split=1, mode=None): if mode is not None: self.to_mode(mode) self._inputs_spec, self._labels_spec = self._prepare_data_spec( dataset, sample_split, batch_size) self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) dataloader = self._prepare_dataloader_from_generator( dataset=dataset, capacity=capacity, use_double_buffer=use_double_buffer, iterable=iterable, return_list=False, use_multiprocess=use_multiprocess, drop_last=drop_last, batch_size=batch_size, epochs=epochs, steps_per_epoch=steps_per_epoch, collate_fn=collate_fn) return dataloader def prepare(self, inputs_spec=None, labels_spec=None, inputs=None, labels=None, main_program=None, startup_program=None, mode=None): if mode is not None: self.to_mode(mode) if inputs or labels: self._skip_build = True self._inputs_spec = inputs_spec self._labels_spec = labels_spec self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec, inputs, labels) self._orig_main_prog = main_program if self._orig_main_prog is None: self._orig_main_prog = static.default_main_program() self._orig_startup_prog = startup_program if self._orig_startup_prog is None: self._orig_startup_prog = static.default_startup_program() if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) elif inputs_spec or labels_spec: self._inputs_spec = inputs_spec self._labels_spec = labels_spec self._outside_dataloader = True self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) self._orig_main_prog = main_program if self._orig_main_prog is None: self._orig_main_prog = static.default_main_program() self._orig_startup_prog = startup_program if self._orig_startup_prog is None: self._orig_startup_prog = static.default_startup_program() if not self._has_prepared[self._mode]: self._prepare_program(self._mode) else: self._switch_mode(self._mode) else: assert self._inputs_spec and self._labels_spec, \ "Please call the dataloader(...) before calling prepare(...)" def run(self, data=None, feed=None, fetch_list=None, mode=None): if mode is not None: self.to_mode(mode) feed_dict = self._prepare_feed(data, feed, self._mode) fetch_names, fetch_indices = self._prepare_fetch(fetch_list, self._mode) if self._outside_dataloader and not self._has_prepared_reader[ self._mode]: self._prepare_reader() outs = self._executor.run(self.main_program, feed=feed_dict, fetch_list=fetch_names, use_program_cache=self._strategy.use_cache, return_numpy=self._strategy.return_numpy) logs = self._prepare_logger(outs, None, None, None, fetch_names, fetch_indices, self._mode) return logs def _prepare_dataloader(self, dataset, return_list=True, batch_size=1, shuffle=False, drop_last=False, collate_fn=None, num_workers=0, use_buffer_reader=True, use_shared_memory=True, timeout=0, worker_init_fn=None, epochs=1, steps_per_epoch=None): if self._strategy.gradient_merge and batch_size is not None: assert batch_size % self._k_steps == 0, \ "Requires batch_size:[{}] to be divisible by k_steps:[{}].".format(batch_size, self._k_steps) batch_size //= self._k_steps dist_main_prog = self._dist_main_progs[self._mode][self._cur_rank] dist_startup_prog = self._dist_startup_progs[self._mode][self._cur_rank] dist_context = self._dist_contexts[self._mode] dist_main_block = dist_main_prog.global_block() # NOTE: Get feed_list, then insert dataloader op with sharded var shape. # Cause predict_program does not contain labels var, # then we will add labels var from serial_program to dist_program, # that maintains the length of feed_list equal to the length of dataset's values. inputs_var = self._feed_vars[self._mode]["inputs"] labels_var = self._feed_vars[self._mode]["labels"] feed_list = [] for var in inputs_var + labels_var: if var.name in dist_main_block.vars: feed_list.append(dist_main_block.vars[var.name]) else: copy_var = dist_main_block._clone_variable(var, var.persistable) copy_var.desc.set_original_id(var.desc.original_id()) feed_list.append(copy_var) # insert read op at the end of program places = paddle.static.cuda_places() with static.program_guard(dist_main_prog, dist_startup_prog): dataloader = DistributedDataLoader( dataset, feed_list=feed_list, places=places, return_list=return_list, batch_size=batch_size, shuffle=shuffle, drop_last=drop_last, collate_fn=collate_fn, num_workers=num_workers, use_buffer_reader=use_buffer_reader, use_shared_memory=use_shared_memory, timeout=timeout, worker_init_fn=worker_init_fn, epochs=epochs, steps_per_epoch=steps_per_epoch, split_data=self._strategy.split_data, data_parallel_world_size=self._dp_world_sizes, data_parallel_rank=self._dp_ranks) return dataloader def _prepare_dataloader_from_generator(self, dataset, capacity=None, use_double_buffer=True, iterable=True, return_list=False, use_multiprocess=False, drop_last=True, batch_size=1, epochs=1, steps_per_epoch=None, collate_fn=None): if self._strategy.gradient_merge and batch_size is not None: assert batch_size % self._k_steps == 0, \ "Requires batch_size:[{}] to be divisible by k_steps:[{}].".format(batch_size, self._k_steps) batch_size //= self._k_steps dist_main_prog = self._dist_main_progs[self._mode][self._cur_rank] dist_startup_prog = self._dist_startup_progs[self._mode][self._cur_rank] dist_context = self._dist_contexts[self._mode] dist_main_block = dist_main_prog.global_block() # NOTE: Get feed_list, then insert dataloader op with sharded var shape. # Cause predict_program does not contain labels var, # then we will add labels var from serial_program to dist_program, # that maintains the length of feed_list equal to the length of dataset's values. inputs_var = self._feed_vars[self._mode]["inputs"] labels_var = self._feed_vars[self._mode]["labels"] feed_list = [] for var in inputs_var + labels_var: if var.name in dist_main_block.vars: feed_list.append(dist_main_block.vars[var.name]) else: copy_var = dist_main_block._clone_variable(var, var.persistable) copy_var.desc.set_original_id(var.desc.original_id()) feed_list.append(copy_var) places = paddle.static.cuda_places() with static.program_guard(dist_main_prog, dist_startup_prog): dataloader = DistributedDataLoaderFromGenerator( dataset=dataset, feed_list=feed_list, capacity=capacity, use_double_buffer=use_double_buffer, iterable=iterable, return_list=return_list, use_multiprocess=use_multiprocess, drop_last=drop_last, places=places, batch_size=batch_size, epochs=epochs, steps_per_epoch=steps_per_epoch, collate_fn=collate_fn, split_data=self._strategy.split_data, data_parallel_world_size=self._dp_world_sizes, data_parallel_rank=self._dp_ranks) self._prepare_reader() return dataloader def _tune(self, tune_data, tune_sample_split=None, batch_size=1): self._mode = 'train' self._inputs_spec, self._labels_spec = self._prepare_data_spec( tune_data, tune_sample_split, batch_size) self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) self._optimization_tuning(self._mode, tune_data, batch_size) def _validate_spec(self, specs): specs = to_list(specs) self._k_steps = self._strategy.gradient_merge.k_steps if specs is not None: for i, spec in enumerate(specs): assert isinstance(spec, InputSpec) if spec.name is None: raise ValueError( "Requires Input[{}].name != None, but receive `None` with {}." .format(i, spec)) if self._k_steps > 1: shape = list(spec.shape) assert shape[0] % self._k_steps == 0, \ "Requires batch_size[{}] to be divisible by k_steps[{}].".format(spec.shape[0], self._k_steps) shape[0] //= self._k_steps spec.shape = shape return specs def _is_local_var(self, var): var_name = _to_name_str(var) return var_name in self.main_program.global_block().vars def _get_input_split_info(self, var, dist_context): # deduce how the input data is split among the cluster from .utils import _get_comm_group, _get_corresponding_rank tensor_dist_attr = dist_context.get_tensor_dist_attr_for_program(var) process_mesh = tensor_dist_attr.process_mesh dims_mapping = tensor_dist_attr.dims_mapping if self._cur_rank not in process_mesh.processes: rank_id = _get_corresponding_rank(dist_context, process_mesh, self._cur_rank) else: rank_id = self._cur_rank batch_size_axis = dims_mapping[0] if batch_size_axis > -1 and process_mesh.topology[batch_size_axis] > 1: group_ranks = _get_comm_group(process_mesh.processes, process_mesh.topology, batch_size_axis, rank_id) return len(group_ranks), group_ranks.index(rank_id) return 1, 0 def _set_recompute_ckpts(self): # NOTE hack to enable recompute in engine api for GPT-3 # TODO support more PaddleNLP/CV models here recompute = self._strategy.recompute # extract ckpts by specific model if isinstance(self._model, paddle.nn.Layer): if hasattr(self._model, "gpt") and self._model.__class__.__name__ in [ 'GPTForPretraining', 'GPTForPretrainingAuto' ]: exact_ckpts = self._model.gpt.checkpoints else: exact_ckpts = recompute.checkpoints else: exact_ckpts = recompute.checkpoints # modify strategy if recompute.enable: recompute.checkpoints = exact_ckpts[:] logs = { 'Model Class': self._model.__class__.__name__, 'Applied Recompute ckpts': exact_ckpts } self._logger.info(logs) def _validate_opt(self, optimizer): if optimizer is not None: optimizer._parameter_list = None optimizer._param_groups = None return optimizer def _reset_metrics(self): for metric in self._metrics: metric.reset() def _metrics_name(self): metrics_name = ['loss'] if self._loss else [] for m in self._metrics: metrics_name.extend(to_list(m.name())) return metrics_name def _switch_mode(self, mode): self.to_mode(mode) self._optimizer = self._dist_contexts[mode]._serial_optimizer def to_mode(self, mode): assert mode in ["train", "eval", "predict"], \ "mode {} should be one of ['train', 'eval', 'predict']".format(mode) self._mode = mode def _set_state_dict(self, mode, strict, state_dict, dist_attr): program = self._dist_main_progs[mode][self._cur_rank] dist_context = self._dist_contexts[mode] cur_dist_attr = get_dist_attr(program, dist_context) converter = Converter(state_dict, dist_attr, cur_dist_attr) state_dict = converter.convert(strict=strict) program.set_state_dict(state_dict) def save(self, path, training=True): """ Saves the model, parameters, optimizer state to path. If `training` is set to False, only inference model will be saved. Args: path (str): The file prefix to save model. The format is 'dirname/file_prefix' or 'file_prefix'. if empty str. A exception will be raised. training (bool, optional): Whether to save for training. If not, save for inference only. If `training` is set to True, the optimizer state will be saved. Otherwise, only the model and parameters are saved. This function will silently overwrite existing file at the target location. Default: True. Returns: None Examples: .. code-block:: python import paddle import paddle.vision.transforms as T from paddle.distributed.fleet import auto from paddle.vision.datasets import MNIST transform = T.Compose([ T.Transpose(), T.Normalize([127.5], [127.5]) ]) train_dataset = MNIST(mode='train', transform=transform) model = paddle.vision.models.LeNet() loss = paddle.nn.CrossEntropyLoss() optimizer = paddle.optimizer.Adam( learning_rate=0.001, parameters=model.parameters()) metrics = paddle.metric.Accuracy(topk=(1, 2)) engine = auto.Engine(model, loss, optimizer, metrics) engine.fit(train_dataset, epochs=1, batch_size=64) engine.save("./my_model") """ if training: assert self._mode in self._serial_main_progs serial_program = self._serial_main_progs[self._mode] dist_main_prog = self._dist_main_progs[self._mode][self._cur_rank] dist_context = self._dist_contexts[self._mode] self._saver.save(path, serial_program=serial_program, dist_main_program=dist_main_prog, dist_context=dist_context) else: assert "predict" in self._dist_main_progs feed_vars = self._feed_vars["predict"]['inputs'] fetch_vars = self._fetch_vars["predict"]['outputs'] dist_main_prog = self._dist_main_progs["predict"][self._cur_rank] self._saver.save_inference_model(path, feed_vars, fetch_vars, self._executor, program=dist_main_prog) def load(self, path, strict=True, load_optimizer=True): """ Load the stored model, parameters and optimizer states. Args: path (str): The prefix of files storing the model states and optimizer states. strict (bool, optional): Whether to skip the loading of mismatch parameter or raise an error when mismatch happens (not found the parameter in file storing model states of or receives a mismatch shape). Default: True. load_optimizer (bool, optional): If True, the stored optimizer states is restored. Otherwise, the optimizer states is initialized from scratch. Default: True. Returns: None Examples: .. code-block:: python import paddle import paddle.vision.transforms as T from paddle.distributed.fleet import auto from paddle.vision.datasets import MNIST transform = T.Compose([ T.Transpose(), T.Normalize([127.5], [127.5]) ]) train_dataset = MNIST(mode='train', transform=transform) model = paddle.vision.models.LeNet() loss = paddle.nn.CrossEntropyLoss() optimizer = paddle.optimizer.Adam( learning_rate=0.001, parameters=model.parameters()) metrics = paddle.metric.Accuracy(topk=(1, 2)) engine = auto.Engine(model, loss, optimizer, metrics) engine.fit(train_dataset, epochs=1, batch_size=64) engine.save("./my_model") engine.load("./my_model") """ self._strict = strict self._state_dict, self._dist_attr = self._saver.load( path, load_optimizer) return self._state_dict, self._dist_attr def cost(self, inputs_spec=None, labels_spec=None, mode="train"): """ Get and Print cost, including memory of every rank, max memory among all ranks, and the global cost of one step based on communication cost(computation cost is 0 by default). In the future, the flops information of every rank and global cost including computation cost will be added. Args: inputs_spec(InputSpec): The specification of inputs. Default: None. labels_spec(InputSpec): The specification of labels. Default: None. mode (str): The engine mode must be in ["train", "predict", "eval"]. Default: "train". Returns: Return the global execution time (ms) and max memory (B). """ # Check parallel mode if self._strategy.auto_mode == "full": print( "The cost will be calcudated in the search process when the auto mode is full." ) return # Check mode accepted_modes = ["train", "predict", "eval"] if mode not in accepted_modes: raise ValueError("The mode {} is not in accepted modes {}".format( mode, accepted_modes)) self.to_mode(mode) if inputs_spec is not None: self._inputs_spec, self._labels_spec = inputs_spec, labels_spec self._inputs, self._labels = self._prepare_data_tensor( self._inputs_spec, self._labels_spec) self._build(mode) self._plan(mode) else: if _non_static_mode() or self._dygraph_mode: raise ValueError( "Please call `engine._prepare_program('mode')` firstly when in the static graph mode." ) # Estimate the exec cost and max memory global_cost, max_memory = get_cost_from_engine(self, mode) return global_cost.time, max_memory @property def main_program(self): return self._dist_main_progs[self._mode][self._cur_rank] @property def startup_program(self): return self._dist_startup_progs[self._mode][self._cur_rank] @property def dist_context(self): return self._dist_contexts[self._mode] @property def serial_main_program(self): return self._serial_main_progs[self._mode] @property def serial_startup_program(self): return self._serial_startup_progs[self._mode] @property def fetch_vars(self): return self._fetch_vars[self._mode] @property def inputs(self): return self._inputs @property def labels(self): return self._labels