# Copyright (c) Microsoft Corporation. # SPDX-License-Identifier: Apache-2.0 # DeepSpeed Team """ coding=utf-8 Copyright (c) 2020, NVIDIA CORPORATION. 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. Part of this code was adopted from https://github.com/NVIDIA/Megatron-LM/blob/main/megatron/data/data_samplers.py """ import torch import os import numpy as np import deepspeed.comm as dist from deepspeed.utils import logger from deepspeed.accelerator import get_accelerator from ..constants import * from ..curriculum_scheduler import CurriculumScheduler from .indexed_dataset import MMapIndexedDataset from .utils import create_mmap_dataset_builder, close_mmap_dataset_builder, find_fit_int_dtype class DeepSpeedDataSampler(object): def __init__(self, data_efficiency_config, one_epoch_total_samples, micro_batch_size, data_parallel_rank, data_parallel_size, data_parallel_group, gradient_accumulation_steps, global_rank, drop_last=True): # Keep a copy of input params for later use. self.data_efficiency_config = data_efficiency_config self.one_epoch_total_samples = one_epoch_total_samples self.index_dtype = find_fit_int_dtype(0, one_epoch_total_samples) self.total_samples = one_epoch_total_samples * self.data_efficiency_config[DATA_SAMPLING][ DATA_SAMPLING_NUM_EPOCHS] self.micro_batch_size = micro_batch_size self.data_parallel_rank = data_parallel_rank self.data_parallel_group = data_parallel_group self.micro_batch_times_data_parallel_size = \ self.micro_batch_size * data_parallel_size self.gradient_accumulation_steps = gradient_accumulation_steps self.global_batch_size = self.micro_batch_times_data_parallel_size * \ self.gradient_accumulation_steps self.global_rank = global_rank self.drop_last = drop_last self.np_rng = np.random.default_rng(self.data_efficiency_config[DATA_EFFICIENCY_SEED]) self.state = {} self.batch = [] self.consumed_samples = 0 if self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_ENABLED]: self.curriculum_step = 0 self.current_difficulties = {} self.data_cluster_paths = [] self.data_cluster_current_position = [] self.curriculum_schedulers = {} self.curriculum_index_to_sample = {} self.curriculum_index_to_metric = {} self.difficulty_type = {} self.clustering_type = {} self.data_1epoch_size = None if self.global_rank == 0: self.data_clusters = [] self.data_cluster_sizes = [] cluster_path = self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][ CURRICULUM_LEARNING_CLUSTER_PATH] if not os.path.exists(cluster_path): os.makedirs(cluster_path) for metric in self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_METRICS]: self.curriculum_schedulers[metric] = CurriculumScheduler( data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_METRICS][metric]) self.difficulty_type[metric] = data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][ CURRICULUM_LEARNING_METRICS][metric][CURRICULUM_LEARNING_DIFFICULTY_TYPE] self.clustering_type[metric] = data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][ CURRICULUM_LEARNING_METRICS][metric][CURRICULUM_LEARNING_CLUSTERING_TYPE] if self.global_rank == 0: if self.clustering_type[metric] != CURRICULUM_LEARNING_SINGLE_CLUSTER: self.curriculum_index_to_sample[metric] = MMapIndexedDataset( data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_METRICS] [metric][CURRICULUM_LEARNING_SAMPLE_PATH], skip_warmup=True) if self.difficulty_type[metric] == CURRICULUM_LEARNING_VALUE_BASED: self.curriculum_index_to_metric[metric] = MMapIndexedDataset( data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_METRICS] [metric][CURRICULUM_LEARNING_METRIC_PATH], skip_warmup=True) # Sanity checks. assert self.total_samples > 0, \ 'no sample to consume: {}'.format(self.total_samples) assert self.micro_batch_size > 0 assert data_parallel_size > 0 assert self.data_parallel_rank < data_parallel_size, \ 'data_parallel_rank should be smaller than data size: {}, ' \ '{}'.format(self.data_parallel_rank, data_parallel_size) def __len__(self): return self.total_samples def set_custom_curriculum_learning_schedule(self, schedule_func_dict): for metric in self.curriculum_schedulers: if metric in schedule_func_dict: self.curriculum_schedulers[metric].set_custom_get_difficulty(schedule_func_dict[metric]) def get_start_end_idx(self, batch_len=None): """ given the length of a minibatch (defaults to micro-batch size * data_parallel_size), return the start and end indices of the current data parallel rank """ batch_len = batch_len or self.micro_batch_times_data_parallel_size start_idx_fn = lambda r: round(r * batch_len / self.data_parallel_group.size()) start_idx = start_idx_fn(self.data_parallel_rank) end_idx = start_idx_fn(self.data_parallel_rank + 1) return start_idx, end_idx def get_sample_based_on_metric_value(self, metric, value_start, value_end): new_samples = None for row in range(len(self.curriculum_index_to_sample[metric])): if self.curriculum_index_to_metric[metric][row] <= value_end and self.curriculum_index_to_metric[metric][ row] > value_start: row_samples = np.copy(self.curriculum_index_to_sample[metric][row]) new_samples = row_samples if new_samples is None else np.concatenate( (new_samples, row_samples), axis=None) return new_samples def get_sample_based_on_metric_percentile(self, metric, percentile_start, percentile_end): new_samples = None if self.data_1epoch_size is None: self.data_1epoch_size = sum(len(x) for x in self.curriculum_index_to_sample[metric]) max_percentile = self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_METRICS][ metric][CURRICULUM_LEARNING_MAX_DIFFICULTY] sample_per_percentile = self.data_1epoch_size // max_percentile start_count = sample_per_percentile * percentile_start end_count = sample_per_percentile * percentile_end if percentile_end == max_percentile: end_count = self.data_1epoch_size current_count = 0 for row in range(len(self.curriculum_index_to_sample[metric])): row_size = len(self.curriculum_index_to_sample[metric][row]) if current_count + row_size > start_count: row_start = max(0, start_count - current_count) if current_count + row_size <= end_count: row_end = row_size else: row_end = end_count - current_count row_samples = np.copy(self.curriculum_index_to_sample[metric][row][row_start:row_end]) new_samples = row_samples if new_samples is None else np.concatenate( (new_samples, row_samples), axis=None) current_count += row_size if current_count >= end_count: break return new_samples def get_new_cluster(self, previous_difficulties): cluster_fname = CURRICULUM_LEARNING_CLUSTER_PREFIX for metric in self.curriculum_schedulers: cluster_fname = f"{cluster_fname}_{metric}{self.current_difficulties[metric]}" cluster_path = self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][ CURRICULUM_LEARNING_CLUSTER_PATH] cluster_path = f"{cluster_path}/{cluster_fname}" if self.global_rank == 0: new_cluster = None need_clustering = 0 for metric in self.clustering_type: if self.clustering_type[metric] != CURRICULUM_LEARNING_SINGLE_CLUSTER: need_clustering += 1 if need_clustering > 1: for metric in self.curriculum_schedulers: if self.clustering_type[metric] == CURRICULUM_LEARNING_SINGLE_CLUSTER: metric_cluster = np.arange(start=0, stop=self.one_epoch_total_samples, step=1, dtype=self.index_dtype) else: if self.difficulty_type[metric] == CURRICULUM_LEARNING_VALUE_BASED: metric_cluster = self.get_sample_based_on_metric_value(metric, float('-inf'), self.current_difficulties[metric]) elif self.difficulty_type[metric] == CURRICULUM_LEARNING_PERCENTILE_BASED: metric_cluster = self.get_sample_based_on_metric_percentile( metric, 0, self.current_difficulties[metric]) new_cluster = metric_cluster if new_cluster is None else \ np.intersect1d(new_cluster, metric_cluster, assume_unique=True) for cluster in self.data_clusters: new_cluster = np.setdiff1d(new_cluster, cluster[0], assume_unique=True) else: if len(self.data_clusters) == 0: new_cluster = np.arange(start=0, stop=self.one_epoch_total_samples, step=1, dtype=self.index_dtype) for metric in self.curriculum_schedulers: if self.clustering_type[metric] != CURRICULUM_LEARNING_SINGLE_CLUSTER: if self.difficulty_type[metric] == CURRICULUM_LEARNING_VALUE_BASED: new_cluster = self.get_sample_based_on_metric_value(metric, previous_difficulties[metric], self.current_difficulties[metric]) elif self.difficulty_type[metric] == CURRICULUM_LEARNING_PERCENTILE_BASED: new_cluster = self.get_sample_based_on_metric_percentile( metric, previous_difficulties[metric], self.current_difficulties[metric]) if new_cluster is not None and len(new_cluster) > 0: logger.info( f"new data cluster (previous_difficulties {previous_difficulties}, current_difficulties {self.current_difficulties}) with size {len(new_cluster)} generated." ) self.np_rng.shuffle(new_cluster) cluster_builder = create_mmap_dataset_builder(cluster_path, self.index_dtype) cluster_builder.add_item_numpy(new_cluster) close_mmap_dataset_builder(cluster_builder, cluster_path) self.data_clusters.append(MMapIndexedDataset(cluster_path, skip_warmup=True)) self.data_cluster_sizes.append(len(self.data_clusters[-1][0])) else: logger.info( f"new data cluster (previous_difficulties {previous_difficulties}, current_difficulties {self.current_difficulties}) has no matched data thus skipped." ) dist.barrier(group=self.data_parallel_group) if os.path.isfile(f"{cluster_path}.bin"): self.data_cluster_paths.append(cluster_fname) self.data_cluster_current_position.append(0) def sample_from_clusters(self): num_clusters = len(self.data_clusters) weight_sum = sum(self.data_cluster_sizes) weights = [x / weight_sum for x in self.data_cluster_sizes] samples = self.np_rng.choice(num_clusters, self.global_batch_size, replace=True, p=weights) samples = np.bincount(samples, minlength=num_clusters) return samples def reshuffle_clusters(self, cidx): cluster_fname = self.data_cluster_paths[cidx] cluster_path = self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][ CURRICULUM_LEARNING_CLUSTER_PATH] cluster_path = f"{cluster_path}/{cluster_fname}" cluster = np.copy(self.data_clusters[cidx][0]) self.np_rng.shuffle(cluster) cluster_builder = create_mmap_dataset_builder(cluster_path, self.index_dtype) cluster_builder.add_item_numpy(cluster) close_mmap_dataset_builder(cluster_builder, cluster_path) self.data_clusters[cidx] = MMapIndexedDataset(cluster_path, skip_warmup=True) def get_sample_from_cluster(self, cidx, num_samples): start_idx = self.data_cluster_current_position[cidx] samples = list(np.copy(self.data_clusters[cidx][0][start_idx:(start_idx + num_samples)])) self.data_cluster_current_position[cidx] += num_samples if len(samples) < num_samples: num_samples_remained = num_samples - len(samples) logger.info(f"reshuffling cluster {cidx}.") self.reshuffle_clusters(cidx) samples += list(np.copy(self.data_clusters[cidx][0][:num_samples_remained])) self.data_cluster_current_position[cidx] = num_samples_remained return samples def get_next_global_batch(self): if self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][CURRICULUM_LEARNING_ENABLED]: self.curriculum_step += 1 new_cluster = False previous_difficulties = {} for metric in self.curriculum_schedulers: next_difficulty = self.curriculum_schedulers[metric].update_difficulty(self.curriculum_step) if metric not in self.current_difficulties or \ next_difficulty != self.current_difficulties[metric]: new_cluster = True if metric in self.current_difficulties: previous_difficulties[metric] = self.current_difficulties[metric] else: if self.difficulty_type[metric] == CURRICULUM_LEARNING_VALUE_BASED: previous_difficulties[metric] = float('-inf') elif self.difficulty_type[metric] == CURRICULUM_LEARNING_PERCENTILE_BASED: previous_difficulties[metric] = 0 self.current_difficulties[metric] = next_difficulty if new_cluster: self.get_new_cluster(previous_difficulties) if self.global_rank == 0: samples_per_cluster = self.sample_from_clusters() batch = [] for cidx in range(len(samples_per_cluster)): batch += self.get_sample_from_cluster(cidx, samples_per_cluster[cidx]) self.np_rng.shuffle(batch) # broadcast tensor must have same shape across participants. So we fill batch with -1s when not full assert len(batch) <= self.global_batch_size batch += [-1] * (self.global_batch_size - len(batch)) batch = torch.tensor(batch, device=get_accelerator().current_device_name(), dtype=torch.long).view(-1) else: batch = torch.empty(self.global_batch_size, device=get_accelerator().current_device_name(), dtype=torch.long) dist.broadcast(batch, 0, group=self.data_parallel_group) batch = batch[batch != -1] # remove trailing -1s used to fill incomplete batch tensor self.batch = batch.tolist() def __iter__(self): while self.consumed_samples <= self.total_samples: if len(self.batch) == 0: self.get_next_global_batch() current_batch = self.batch[:self.micro_batch_times_data_parallel_size] self.batch = self.batch[self.micro_batch_times_data_parallel_size:] if len(current_batch) == self.micro_batch_times_data_parallel_size or \ (len(current_batch) > 0 and not self.drop_last): start_idx, end_idx = self.get_start_end_idx(len(current_batch)) yield current_batch[start_idx:end_idx] self.consumed_samples += len(current_batch) current_batch = [] def state_dict(self): return { CURRICULUM_LEARNING_BATCH: self.batch, CURRICULUM_LEARNING_CONSUMED_SAMPLES: self.consumed_samples, CURRICULUM_LEARNING_STEP: self.curriculum_step, CURRICULUM_LEARNING_CURRENT_DIFFICULTIES: self.current_difficulties, CURRICULUM_LEARNING_DATA_CLUSTER_PATHS: self.data_cluster_paths, CURRICULUM_LEARNING_DATA_CLUSTER_CURRENT_POSITION: self.data_cluster_current_position, CURRICULUM_LEARNING_NP_RNG_STATE: np.random.get_state() } def load_state_dict(self, state_dict): self.batch = state_dict[CURRICULUM_LEARNING_BATCH] self.consumed_samples = state_dict[CURRICULUM_LEARNING_CONSUMED_SAMPLES] self.curriculum_step = state_dict[CURRICULUM_LEARNING_STEP] self.current_difficulties = state_dict[CURRICULUM_LEARNING_CURRENT_DIFFICULTIES] self.data_cluster_paths = state_dict[CURRICULUM_LEARNING_DATA_CLUSTER_PATHS] self.data_cluster_current_position = state_dict[CURRICULUM_LEARNING_DATA_CLUSTER_CURRENT_POSITION] np.random.set_state(state_dict[CURRICULUM_LEARNING_NP_RNG_STATE]) cluster_root_path = self.data_efficiency_config[DATA_SAMPLING][CURRICULUM_LEARNING][ CURRICULUM_LEARNING_CLUSTER_PATH] # Backward compatibility: previously data_cluster_paths were stored as # absolute paths. Now we changed it to just the file name so that even # if user moved the cluster files, the checkpoint loading still works # as long as user set the correct new CURRICULUM_LEARNING_CLUSTER_PATH # in deepspeed json config. for idx in range(len(self.data_cluster_paths)): if '/' in self.data_cluster_paths[idx]: self.data_cluster_paths[idx] = self.data_cluster_paths[idx].split('/')[-1] if self.global_rank == 0: for cluster_fname in self.data_cluster_paths: cluster_path = f"{cluster_root_path}/{cluster_fname}" self.data_clusters.append(MMapIndexedDataset(cluster_path, skip_warmup=True)) self.data_cluster_sizes.append(len(self.data_clusters[-1][0]))