mirror of https://github.com/hpcaitech/ColossalAI
263 lines
8.7 KiB
Python
263 lines
8.7 KiB
Python
import copy
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import heapq
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from colossalai.builder import build_model, build_layer
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from colossalai.context.parallel_mode import ParallelMode
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from colossalai.core import global_context as gpc
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from colossalai.logging import get_dist_logger
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import torch.nn as nn
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def _binary_partition(weights, st, ed):
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"""Returns the binary partition position of `weights`, given the start
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position `st` and the end position `ed`.
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Args:
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weights (list): A python list to be binary partitioned
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st (int): the start position of the binary partition
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ed (int): the end position of the binary partition
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Returns:
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int: the binary partition position of `weights`
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"""
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w_sum = weights[ed - 1]
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prefix = 0
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if st > 0:
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w_sum -= weights[st - 1]
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prefix = weights[st - 1]
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minimum = float("inf")
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for idx in range(st + 1, ed):
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front = weights[idx - 1] - prefix
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diff = abs(w_sum - 2 * front)
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if diff < minimum:
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pos = idx
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minimum = diff
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return st, pos, ed
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def _heap_addition(weights, intervals, add_cnt):
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"""
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"""
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def _heap_push(heap, st, ed):
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value = weights[ed - 1]
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if st > 0:
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value -= weights[st - 1]
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heapq.heappush(heap, (-value, st, ed))
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ret_intervals = []
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heap = []
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for st, ed in intervals:
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_heap_push(heap, st, ed)
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while add_cnt > 0:
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_, st, ed = heapq.heappop(heap)
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if ed - st == 1:
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ret_intervals.append((st, ed))
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else:
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l, m, r = _binary_partition(weights, st, ed)
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_heap_push(heap, l, m)
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_heap_push(heap, m, r)
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add_cnt -= 1
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while heap:
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_, st, ed = heapq.heappop(heap)
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ret_intervals.append((st, ed))
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ret_intervals.sort()
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return ret_intervals
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def _calc_partitions(weights, value):
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prev = 0
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prefix = 0
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num_block = 0
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intervals = []
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for idx, w in enumerate(weights):
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if weights[idx] - prefix > value:
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intervals.append((prev, idx))
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prev = idx
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prefix = weights[idx - 1]
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num_block += 1
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intervals.append((prev, len(weights)))
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return num_block + 1, intervals
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def _binary_search(weights, num):
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length = len(weights)
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prefix = [1 if w == 0 else w for w in weights]
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for i in range(1, length):
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prefix[i] += prefix[i - 1]
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lower_bound = max(weights)
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upper_bound = prefix[length - 1]
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while upper_bound > lower_bound:
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mid = (upper_bound + lower_bound) // 2
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number, _ = _calc_partitions(prefix, mid)
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if number <= num:
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upper_bound = mid
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else:
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lower_bound = mid + 1
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num_block, intervals = _calc_partitions(prefix, upper_bound)
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if num_block < num:
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intervals = _heap_addition(prefix, intervals, num - num_block)
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return intervals
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def partition_uniform(num_items, pipeline_parallel_size, num_chunks):
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assert num_items % num_chunks == 0, \
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"Layer length should be divided by the number of chunks, otherwise parameter method is recomended"
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logger = get_dist_logger()
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parts = [[] for _ in range(pipeline_parallel_size)]
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partition_items = num_items // num_chunks
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for idx in range(num_chunks):
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base_idx = idx * partition_items
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chunk_size = partition_items // pipeline_parallel_size
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left = pipeline_parallel_size - partition_items % pipeline_parallel_size
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if chunk_size == 0:
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logger.warning("Some nodes in Pipeline have no requests")
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for p in range(pipeline_parallel_size):
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st = base_idx
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base_idx += chunk_size + (p >= left)
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parts[p].append((st, base_idx))
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return parts
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def partition_balanced(weights, pipeline_parallel_size, num_chunks):
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num_total = pipeline_parallel_size * num_chunks
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num_items = len(weights)
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if num_items <= num_total:
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return partition_uniform(num_items, pipeline_parallel_size, num_chunks)
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intervals = _binary_search(weights, num_total)
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current = 0
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parts = [[] for _ in range(pipeline_parallel_size)]
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for inter in intervals:
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parts[current].append(inter)
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current = (current + 1) % pipeline_parallel_size
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return parts
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def count_layer_params(layers):
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"""Count the number of parameters in each layer
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"""
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param_counts = [0] * len(layers)
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for idx, cfg in enumerate(layers):
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layer = build_layer(cfg)
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params = filter(lambda p: p.requires_grad, layer.parameters())
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param_counts[idx] = sum(p.numel() for p in params)
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return param_counts
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def build_pipeline_model_from_cfg(config, num_chunks: int = 1, partition_method: str = 'parameter', verbose: bool = False):
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"""An initializer to split the model into different stages for pipeline parallelism.
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An example for the model config is shown below. The class VisionTransformerFromConfig should
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inherit colossalai.nn.model.ModelFromConfig to allow this initializer to build model from a sequence
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of layer configurations.
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::
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model_config = dict(
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type='VisionTransformerFromConfig',
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embedding_cfg=dict(...),
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...
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)
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Args:
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config (dict): Configuration of the model.
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num_chunks (int, optional): The number of chunks you want to have on the current stage.
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This value should be 1 in most cases unless you are using virtual pipeline parallelism.
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partition_method (str, optional): This parameter determines how you want to split your model
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layers into stages, you can set it as 'layer' or 'parameter'.
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verbose (bool, optional): Whether to print the logs.
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"""
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ori_model = build_model(config)
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layers = ori_model.layers_cfg
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layer_length = len(layers)
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logger = get_dist_logger()
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if verbose:
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logger.info(f"The total length of layers is {layer_length}", ranks=[0])
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pipeline_parallel_size = gpc.get_world_size(ParallelMode.PIPELINE)
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pipeline_rank = gpc.get_local_rank(ParallelMode.PIPELINE)
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method = partition_method.lower()
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# Make a partition
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if method == 'layer':
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num_layers = len(layers)
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parts = partition_uniform(num_layers, pipeline_parallel_size, num_chunks)
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elif method == 'parameter':
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param_counts = count_layer_params(layers)
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# print_rank_0(param_counts)
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parts = partition_balanced(param_counts, pipeline_parallel_size, num_chunks)
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else:
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raise ValueError("Method should be a pre-set string in [layer, parameter]")
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# Display the partition
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if verbose:
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log_str = 'Layer allocation after partitioning: \n'
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for stage in range(pipeline_parallel_size):
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num_layers = 0
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for st, ed in parts[stage]:
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num_layers += ed - st
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log_str += f'\n===== stage={stage}, layers={num_layers} =====\n'
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for st, ed in parts[stage]:
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for idx, layer in enumerate(layers[st: ed]):
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log_str += f'\t{idx + st:2d}: {layer}\n'
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logger.info(log_str, ranks=[0])
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# Save the partition
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interval = parts[pipeline_rank]
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models = []
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for st, ed in interval:
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model = copy.deepcopy(ori_model)
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model.build_from_cfg(st, ed)
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models.append(model)
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return nn.ModuleList(models) if len(models) > 1 else models[0]
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def build_pipeline_model(layers: nn.Sequential, num_chunks: int = 1, verbose: bool = False):
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"""An intializer to split the model into different stages for pipeline parallelism.
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Note that `layer` must be `torch.nn.Sequential`.
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Args:
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layers (`torch.nn.Sequential`): Layers of model
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num_chunks: The number of chunks you want to have on the current stage. This value should be 1
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in most cases unless you are using virtual pipeline parallelism.
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verbose (bool, optional): Whether to print the logs.
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"""
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pipeline_parallel_size = gpc.get_world_size(ParallelMode.PIPELINE)
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pipeline_rank = gpc.get_local_rank(ParallelMode.PIPELINE)
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partitions = partition_uniform(len(layers), pipeline_parallel_size, num_chunks)
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module_list = []
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for start, end in partitions[pipeline_rank]:
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module_list.append(nn.Sequential(*layers[start:end]))
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if verbose:
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logger = get_dist_logger()
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logger.info(f'Total {len(layers)} layers', ranks=[0])
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for rank, part in enumerate(partitions):
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log_str = f'===== stage={rank} =====\n'
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for chunk, (start, end) in enumerate(part):
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log_str += f'===== chunk={chunk}, layer=[{start}-{end}] =====\n'
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log_str += '\n'.join([str(layer) for layer in layers[start:end]]) + '\n'
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logger.info(log_str, ranks=[0])
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return nn.ModuleList(module_list) if len(module_list) > 1 else module_list[0]
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