import heapq import inspect from collections import OrderedDict from typing import List import torch from colossalai.legacy.nn.layer.utils import CheckpointModule from colossalai.logging import get_dist_logger def _binary_partition(weights: List, start: int, end: int): """Returns the binary partition position of `weights`, given the start position `st` and the end position `ed`. Args: weights (list): A python list to be binary partitioned start (int): the start position of the binary partition end (int): the end position of the binary partition Returns: int: the binary partition position of `weights` """ w_sum = weights[end - 1] prefix = 0 if start > 0: w_sum -= weights[start - 1] prefix = weights[start - 1] minimum = float("inf") for idx in range(start + 1, end): front = weights[idx - 1] - prefix diff = abs(w_sum - 2 * front) if diff < minimum: pos = idx minimum = diff return start, pos, end def _heap_addition(weights: List, intervals: int, add_cnt: int): """ """ def _heap_push(heap, st, ed): value = weights[ed - 1] if st > 0: value -= weights[st - 1] heapq.heappush(heap, (-value, st, ed)) ret_intervals = [] heap = [] for st, ed in intervals: _heap_push(heap, st, ed) while add_cnt > 0: _, st, ed = heapq.heappop(heap) if ed - st == 1: ret_intervals.append((st, ed)) else: l, m, r = _binary_partition(weights, st, ed) _heap_push(heap, l, m) _heap_push(heap, m, r) add_cnt -= 1 while heap: _, st, ed = heapq.heappop(heap) ret_intervals.append((st, ed)) ret_intervals.sort() return ret_intervals def _calc_partitions(weights, value): prev = 0 prefix = 0 num_block = 0 intervals = [] for idx, w in enumerate(weights): if weights[idx] - prefix > value: intervals.append((prev, idx)) prev = idx prefix = weights[idx - 1] num_block += 1 intervals.append((prev, len(weights))) return num_block + 1, intervals def _binary_search(weights, num): length = len(weights) prefix = [1 if w == 0 else w for w in weights] for i in range(1, length): prefix[i] += prefix[i - 1] lower_bound = max(weights) upper_bound = prefix[length - 1] while upper_bound > lower_bound: mid = (upper_bound + lower_bound) // 2 number, _ = _calc_partitions(prefix, mid) if number <= num: upper_bound = mid else: lower_bound = mid + 1 num_block, intervals = _calc_partitions(prefix, upper_bound) if num_block < num: intervals = _heap_addition(prefix, intervals, num - num_block) return intervals def partition_uniform(num_items, pipeline_parallel_size, num_chunks): assert ( num_items % num_chunks == 0 ), "Layer length should be divided by the number of chunks, otherwise parameter method is recommended" logger = get_dist_logger() parts = [[] for _ in range(pipeline_parallel_size)] partition_items = num_items // num_chunks for idx in range(num_chunks): base_idx = idx * partition_items chunk_size = partition_items // pipeline_parallel_size left = pipeline_parallel_size - partition_items % pipeline_parallel_size if chunk_size == 0: logger.warning("Some nodes in Pipeline have no requests") for p in range(pipeline_parallel_size): st = base_idx base_idx += chunk_size + (p >= left) parts[p].append((st, base_idx)) return parts def partition_balanced(weights, pipeline_parallel_size, num_chunks): num_total = pipeline_parallel_size * num_chunks num_items = len(weights) if num_items <= num_total: return partition_uniform(num_items, pipeline_parallel_size, num_chunks) intervals = _binary_search(weights, num_total) current = 0 parts = [[] for _ in range(pipeline_parallel_size)] for inter in intervals: parts[current].append(inter) current = (current + 1) % pipeline_parallel_size return parts def build_kwargs_for_module(function, input_tensor, kw_dict): """ Generally, the first argument of module.forward is an input tensor come from the previous layer. Therefore, we just filter the kwargs from second element of the dictionary. """ sig = inspect.signature(function) if input_tensor is None: kwargs_offset = 0 elif isinstance(input_tensor, torch.Tensor): kwargs_offset = 1 elif isinstance(input_tensor, (tuple, OrderedDict)): # assert isinstance(input_tensor, tuple), f'input_tensor should be a torch.Tensor or a tuple object.' # Huggingface will take their own structures based on OrderedDict as the output # between layers so we've to close this check. kwargs_offset = len(input_tensor) args_name_list = list(sig.parameters.keys()) kw_dict = {k: v for k, v in kw_dict.items() if k in args_name_list[kwargs_offset:]} if len(kw_dict) == 0: return None return kw_dict def build_kwargs_for_function(function, kw_dict): sig = inspect.signature(function) kw_dict = {k: v for k, v in kw_dict.items() if k in sig.parameters} if len(kw_dict) == 0: return None return kw_dict def exec_func_with_kwargs(func, kw_dict, input_tensor, kwargs): """ We suppose the callable object passed to to_layer_list method in two purpose: a. use the callable object to modify input tensor, such as \ lambda x: torch.flatten(x, 1) b. use the callable object to modify kwargs value, such as \ def foo(attention_mask=None): if attention_mask is not None: batch_size = input_ids.shape[0] attention_mask = attention_mask.view(batch_size, -1) return attention_mask """ if kw_dict is not None: rst = func(**kw_dict) if isinstance(rst, tuple): for i, k in enumerate(kw_dict.keys()): kwargs[k] = rst[i] else: for k in kw_dict.keys(): kwargs[k] = rst return input_tensor if isinstance(input_tensor, tuple): assert len(input_tensor) > 0, f"input_tensor should not be empty, when kw_dict is None." sig = inspect.signature(func) func_args_num = len(sig.parameters) assert func_args_num <= len( input_tensor ), f"func requires {func_args_num} arguments, but input_tensors only have {len(input_tensor)}." if func_args_num < len(input_tensor): return func(*input_tensor[:func_args_num]) else: return func(*input_tensor) assert isinstance(input_tensor, torch.Tensor), "input_tensor should be a type of torch.Tensor or tuple." return func(input_tensor) def exec_funcs_with_kwargs(func_dict, func_key, input_tensor, kwargs): assert func_key in func_dict, f"{func_key} is not in the function_dict." funcs_to_exec = func_dict[func_key] if isinstance(funcs_to_exec, list): for f in funcs_to_exec: f_kwargs = build_kwargs_for_function(f, kwargs) input_tensor = exec_func_with_kwargs(f, f_kwargs, input_tensor, kwargs) else: f_kwargs = build_kwargs_for_function(funcs_to_exec, kwargs) input_tensor = exec_func_with_kwargs(funcs_to_exec, f_kwargs, input_tensor, kwargs) return input_tensor def call_module(module, args=None, kwargs=None): if args is None: args = () if kwargs is None: kwargs = {} if isinstance(module, CheckpointModule): forward_func = module._forward else: forward_func = module.forward sig = inspect.signature(forward_func) param_nums = len(sig.parameters) len(args) + len(kwargs) args_needed_nums = param_nums - len(kwargs) args_needed = args[:args_needed_nums] if isinstance(module, CheckpointModule): convert_kwargs_to_args = [] for v in kwargs.values(): convert_kwargs_to_args.append(v) return module(*args_needed, *convert_kwargs_to_args) else: return module(*args_needed, **kwargs) def customized_partition(exec_seq): """ This function will analyze the exec_seq. In the exec_seq, users will use 'SPLIT_NODE' as an annotation to note the partition point. """ customized_parts = {} start = 0 stop = 0 rank = 0 for element in exec_seq: if isinstance(element, str): if element == "SPLIT_NODE": customized_parts[rank] = [(start, stop)] start = stop rank += 1 else: stop += 1 customized_parts[rank] = [(start, stop)] return customized_parts