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# Copyright 2024 Bytedance Ltd. and/or its affiliates
#
# 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 copy
import heapq
from typing import List, Tuple
import torch
from torch import distributed as dist
def karmarkar_karp(seqlen_list: List[int], k_partitions: int, equal_size: bool):
# see: https://en.wikipedia.org/wiki/Largest_differencing_method
class Set:
def __init__(self) -> None:
self.sum = 0
self.items = []
def add(self, idx: int, val: int):
self.items.append((idx, val))
self.sum += val
def merge(self, other):
for idx, val in other.items:
self.items.append((idx, val))
self.sum += val
def __lt__(self, other):
if self.sum != other.sum:
return self.sum < other.sum
if len(self.items) != len(other.items):
return len(self.items) < len(other.items)
return self.items < other.items
class State:
def __init__(self, items: List[Tuple[int, int]], k: int) -> None:
self.k = k
# sets should always be decreasing order
self.sets = [Set() for _ in range(k)]
assert len(items) in [1, k], f"{len(items)} not in [1, {k}]"
for i, (idx, seqlen) in enumerate(items):
self.sets[i].add(idx=idx, val=seqlen)
self.sets = sorted(self.sets, reverse=True)
def get_partitions(self):
partitions = []
for i in range(len(self.sets)):
cur_partition = []
for idx, _ in self.sets[i].items:
cur_partition.append(idx)
partitions.append(cur_partition)
return partitions
def merge(self, other):
for i in range(self.k):
self.sets[i].merge(other.sets[self.k - 1 - i])
self.sets = sorted(self.sets, reverse=True)
@property
def spread(self) -> int:
return self.sets[0].sum - self.sets[-1].sum
def __lt__(self, other):
# least heap, let the state with largest spread to be popped first,
# if the spread is the same, let the state who has the largest set
# to be popped first.
if self.spread != other.spread:
return self.spread > other.spread
return self.sets[0] > other.sets[0]
def __repr__(self) -> str:
repr_str = "["
for i in range(self.k):
if i > 0:
repr_str += ","
repr_str += "{"
for j, (_, seqlen) in enumerate(self.sets[i].items):
if j > 0:
repr_str += ","
repr_str += str(seqlen)
repr_str += "}"
repr_str += "]"
return repr_str
sorted_seqlen_list = sorted([(seqlen, i) for i, seqlen in enumerate(seqlen_list)])
states_pq = []
if equal_size:
assert len(seqlen_list) % k_partitions == 0, f"{len(seqlen_list)} % {k_partitions} != 0"
for offset in range(0, len(sorted_seqlen_list), k_partitions):
items = []
for i in range(k_partitions):
seqlen, idx = sorted_seqlen_list[offset + i]
items.append((idx, seqlen))
heapq.heappush(states_pq, State(items=items, k=k_partitions))
else:
for seqlen, idx in sorted_seqlen_list:
heapq.heappush(states_pq, State(items=[(idx, seqlen)], k=k_partitions))
while len(states_pq) > 1:
state0 = heapq.heappop(states_pq)
state1 = heapq.heappop(states_pq)
# merge states
state0.merge(state1)
heapq.heappush(states_pq, state0)
final_state = states_pq[0]
partitions = final_state.get_partitions()
if equal_size:
for i, partition in enumerate(partitions):
assert len(partition) * k_partitions == len(seqlen_list), f"{len(partition)} * {k_partitions} != {len(seqlen_list)}"
return partitions
def greedy_partition(seqlen_list: List[int], k_partitions: int, equal_size: bool):
bias = sum(seqlen_list) + 1 if equal_size else 0
sorted_seqlen = [(seqlen + bias, i) for i, seqlen in enumerate(seqlen_list)]
partitions = [[] for _ in range(k_partitions)]
partition_sums = [0 for _ in range(k_partitions)]
for seqlen, i in sorted_seqlen:
min_idx = None
for j in range(k_partitions):
if min_idx is None or partition_sums[j] < partition_sums[min_idx]:
min_idx = j
partitions[min_idx].append(i)
partition_sums[min_idx] += seqlen
if equal_size:
for i, partition in enumerate(partitions):
assert len(partition) * k_partitions == len(seqlen_list), f"{len(partition)} * {k_partitions} != {len(seqlen_list)}"
return partitions
def get_seqlen_balanced_partitions(seqlen_list: List[int], k_partitions: int, equal_size: bool):
"""get order of seq lengths to make partitions balanced, this is
used in balacing sum of seqlength across dp ranks and microbatches
Parameters:
seqlen_list (List[int]):
seq lengths of each items
k_partitions (int):
resulting number of partitions
equal_size (bool):
if True, number of items in each partitions must be equal.
if False, only consider balancing the sum, each partition can have
variable number of items
Returns:
partitions (List[List[int]]):
return k_partitions list containing the index of items.
"""
assert len(seqlen_list) >= k_partitions, f"number of items:[{len(seqlen_list)}] < k_partitions:[{k_partitions}]"
def _check_and_sort_partitions(partitions):
assert len(partitions) == k_partitions, f"{len(partitions)} != {k_partitions}"
seen_idx = set()
sorted_partitions = [None] * k_partitions
for i, partition in enumerate(partitions):
assert len(partition) > 0, f"the {i}-th partition is empty"
for idx in partition:
seen_idx.add(idx)
sorted_partitions[i] = sorted(partition)
assert seen_idx == set(range(len(seqlen_list)))
return sorted_partitions
partitions = karmarkar_karp(seqlen_list=seqlen_list, k_partitions=k_partitions, equal_size=equal_size)
return _check_and_sort_partitions(partitions)
def log_seqlen_unbalance(seqlen_list: List[int], partitions: List[List[int]], prefix):
# add some metrics of seqlen sum on dp ranks
k_partition = len(partitions)
# assert len(seqlen_list) % k_partition == 0
batch_size = len(seqlen_list) // k_partition
min_sum_seqlen = None
max_sum_seqlen = None
total_sum_seqlen = 0
for offset in range(0, len(seqlen_list), batch_size):
cur_sum_seqlen = sum(seqlen_list[offset : offset + batch_size])
if min_sum_seqlen is None or cur_sum_seqlen < min_sum_seqlen:
min_sum_seqlen = cur_sum_seqlen
if max_sum_seqlen is None or cur_sum_seqlen > max_sum_seqlen:
max_sum_seqlen = cur_sum_seqlen
total_sum_seqlen += cur_sum_seqlen
balanced_sum_seqlen_list = []
for partition in partitions:
cur_sum_seqlen_balanced = sum([seqlen_list[i] for i in partition])
balanced_sum_seqlen_list.append(cur_sum_seqlen_balanced)
# print("balanced_sum_seqlen_list: ", balanced_sum_seqlen_list)
min_sum_seqlen_balanced = min(balanced_sum_seqlen_list)
max_sum_seqlen_balanced = max(balanced_sum_seqlen_list)
return {
f"{prefix}/min": min_sum_seqlen,
f"{prefix}/max": max_sum_seqlen,
f"{prefix}/minmax_diff": max_sum_seqlen - min_sum_seqlen,
f"{prefix}/balanced_min": min_sum_seqlen_balanced,
f"{prefix}/balanced_max": max_sum_seqlen_balanced,
f"{prefix}/mean": total_sum_seqlen / len(partitions),
}
def ceildiv(a, b):
return -(a // -b)
def rearrange_micro_batches(batch, max_token_len, dp_group=None, same_micro_num_in_dp=True, min_num_micro_batch=None):
"""
Split a batch into micro-batches by total token count, with optional DP sync and padding.
Args:
batch (TensorDict): must include "attention_mask" (B*S); other fields are sliced similarly.
max_token_len (int): max sum of attention_mask per micro-batch.
dp_group (optional): torch.distributed group for data-parallel sync.
same_micro_num_in_dp (bool): if True and dp_group set, pad all ranks to the same count.
min_num_micro_batch (int, optional): force at least this many splits (pads empty ones).
Returns:
List[TensorDict]: the micro-batches.
List[List[int]]: index lists mapping each micro-batch back to original positions.
"""
# this is per local micro_bsz
max_seq_len = batch["attention_mask"].shape[-1]
assert max_token_len >= max_seq_len, f"max_token_len must be greater than the sequence length. Got {max_token_len=} and {max_seq_len=}"
seq_len_effective: torch.Tensor = batch["attention_mask"].sum(dim=1)
total_seqlen = seq_len_effective.sum().item()
# NOTE: num_microbatches <= batch_size, so take the min of this two.
num_micro_batches = min(len(seq_len_effective), ceildiv(total_seqlen, max_token_len))
if min_num_micro_batch is not None:
# used to support pp
num_micro_batches = max(min_num_micro_batch, num_micro_batches)
if dist.is_initialized() and same_micro_num_in_dp:
num_micro_batches = torch.tensor([num_micro_batches], device="cuda")
dist.all_reduce(num_micro_batches, op=dist.ReduceOp.MAX, group=dp_group)
num_micro_batches = num_micro_batches.cpu().item()
seq_len_effective = seq_len_effective.tolist()
assert num_micro_batches <= len(seq_len_effective)
micro_bsz_idx = get_seqlen_balanced_partitions(seq_len_effective, num_micro_batches, equal_size=False)
micro_batches = []
for partition in micro_bsz_idx:
curr_micro_batch = []
for idx in partition:
curr_micro_batch.append(batch[idx : idx + 1])
curr_micro_batch = torch.cat(curr_micro_batch)
micro_batches.append(curr_micro_batch)
return micro_batches, micro_bsz_idx
def get_reverse_idx(idx_map):
reverse_idx_map = copy.deepcopy(idx_map)
for i, idx in enumerate(idx_map):
reverse_idx_map[idx] = i
return reverse_idx_map
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