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ColossalAI/colossalai/moe/load_balance.py

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from copy import deepcopy
from typing import List, Optional, Tuple
import torch
import torch.distributed as dist
from torch import Tensor, nn
from torch.distributed import ProcessGroup
from colossalai.cluster import ProcessGroupMesh
from colossalai.moe.experts import MLPExperts
from colossalai.moe.manager import MOE_MANAGER
from colossalai.zero.low_level import LowLevelZeroOptimizer
class LoadBalancer:
def __init__(
self,
experts: MLPExperts,
gate: nn.Parameter,
local_expert_num: int,
expert_num: int,
ep_group: ProcessGroup,
dp_group: ProcessGroup,
tolerance: Optional[float] = 0.1,
beam_width: Optional[int] = 8,
group_swap_factor: Optional[float] = 0.4,
) -> None:
self.experts: MLPExperts = experts
self.gate: nn.Parameter = gate
self.moe_ep_group: ProcessGroup = ep_group
self.moe_ep_ranks = MOE_MANAGER.parallel_info_dict[dist.get_world_size(self.moe_ep_group)].ep_group_ranks
self.moe_dp_group: ProcessGroup = dp_group
self.tolerance = tolerance
self.beam_width = beam_width
self.group_swap_factor = group_swap_factor
self.local_expert_num = local_expert_num
self.expert_num = expert_num
self.local_load = None
# TODO: use a global process group mesh
pp_size = 1 if MOE_MANAGER.pp_size is None else MOE_MANAGER.pp_size
global_dp_group = ProcessGroupMesh(pp_size, dist.get_world_size() // pp_size)
self.global_dp_group = global_dp_group.get_group_along_axis(1)
self.global_dp_rank = dist.get_rank(self.global_dp_group)
self.global_dp_size = dist.get_world_size(self.global_dp_group)
def _clear_load(self) -> None:
self.local_load = None
def _sync_load(self) -> Tensor:
new_load = self.local_load.clone().detach()
# all reduce load between ep group
dist.all_reduce(new_load, group=self.moe_ep_group)
# all reduce load between dp group
dist.all_reduce(new_load, group=self.moe_dp_group)
return new_load
@staticmethod
def _get_diff_from_avg(data: List, group: int, avg: float) -> float:
return abs(sum(data[group]) / len(data[group]) - avg)
@staticmethod
def _swap_data(data: List, group_i: int, index_i: int, group_j: int, index_j: int) -> None:
data[group_i][index_i], data[group_j][index_j] = (
data[group_j][index_j],
data[group_i][index_i],
)
@staticmethod
def _normalize_data(data: List) -> List:
max_value = max(max(sublist) for sublist in data)
data = [[i / max_value for i in sublist] for sublist in data]
return data
@staticmethod
def _get_swap_loss(
group_swap_factor: float,
swap_list: List,
group_i: int,
index_i: int,
group_j: int,
index_j: int,
) -> float:
"""
Get swap loss. The swap loss is used to avoid the situation that
the same index is swapped twice and the same group is swapped for multiple times.
"""
swap_loss = 0
for swap in swap_list:
for group_id, index_id in zip([group_i, group_j], [index_i, index_j]):
# the group has been swapped
if group_id in [swap[0], swap[2]]:
# the index has been swapped
# we want to avoid the situation that the same index is swapped twice
if index_id in [swap[1], swap[3]]:
swap_loss += 1e5
# the index has not been swapped
# this is acceptable but as less as possible
else:
swap_loss += group_swap_factor
return swap_loss
@staticmethod
def _check_convergence(data: List, avg: float, tolerance: float):
"""
Check whether the data is converged after swap.
"""
for sublist in data:
if abs(sum(sublist) / len(sublist) - avg) > tolerance * avg:
return False
return True
def _beam_search(
self,
inputs: Tuple[List, float, List],
beam_width: int,
avg: float,
group_swap_factor: float,
) -> List:
"""
Beam search for the best swap combination.
Specifically, we swap two elements from two groups and calculate the score.
The score is the difference between the origin group sum and the new group sum.
The larger the score, the better the swap combination.
Args:
inputs (Tuple): (data, origin_score, swap_list)
beam_width (int): beam width for beam search
avg (float): average value of the data
group_swap_factor (float): group loss for group swap loss
Returns:
List: results list
"""
data, origin_score, swap_list = inputs
results = []
group_num = len(data)
group_size = len(data[0])
origin_diff_list = [self._get_diff_from_avg(data, i, avg) for i in range(group_num)]
for group_num_i in range(group_num):
for group_size_i in range(group_size):
for group_num_j in range(group_num_i + 1, group_num):
for group_size_j in range(group_size):
new_data = deepcopy(data)
# calculate origin group sum
origin_diff = origin_diff_list[group_num_i] + origin_diff_list[group_num_j]
# swap data
self._swap_data(
new_data,
group_num_i,
group_size_i,
group_num_j,
group_size_j,
)
# calculate new group sum
new_diff = self._get_diff_from_avg(new_data, group_num_i, avg) + self._get_diff_from_avg(
new_data, group_num_j, avg
)
# caculate score
new_score = origin_diff - new_diff
if new_score > 0:
new_score = origin_score + new_score
# get swap loss
swap_loss = self._get_swap_loss(
group_swap_factor,
swap_list,
group_num_i,
group_size_i,
group_num_j,
group_size_j,
)
new_score = new_score - swap_loss
# update swap list
new_swap_list = swap_list + [(group_num_i, group_size_i, group_num_j, group_size_j)]
results.append((new_data, new_score, new_swap_list))
# sort results
results.sort(key=lambda x: x[1], reverse=True)
# select top k results
results = results[:beam_width]
return results
def _load_to_list(self, load: Tensor) -> List:
load_len = len(load)
assert load_len % self.local_expert_num == 0
load_list = []
tmp_list = []
for i in range(len(load)):
tmp_list.append(float(load[i]))
if (i + 1) % self.local_expert_num == 0:
load_list.append(tmp_list)
tmp_list = []
return load_list
def _search_balance(
self,
data: List,
tolerance: Optional[float] = 0.1,
beam_width: Optional[int] = 8,
group_swap_factor: Optional[float] = 0.4,
return_swapped_data: Optional[bool] = False,
) -> Tuple[List, List]:
"""
Search for the best swap combination to balance the data within the specified tolerance.
And return the balanced data and the swap list. The swap list is used to record the swap.
The swap list is a list of tuples. Each tuple is a swap operation.
Args:
data (List): expert load list.
E.g. [[9.2, 8.3], [2.3, 10.0], [6.1, 7.2], [5.3, 3.2]]
This means there are 4 devices and each devices has 2 experts.
The value is the load of the expert.
tolerance (float): tolerance for balance.
beam_width (int): beam width for beam search.
group_swap_factor (float): group swap factor for group swap loss.
The bigger it is, the less times a group will be swapped.
return_swapped_data (bool): whether to return the swapped data.
Returns:
Tuple: (balanced data, swap list).
The swap list is a list of tuples. Each tuple is a swap operation.
E.g. [(0, 0, 1, 0), (...), (...)]. The first tuple means
the first expert of the first device is swapped with the first expert
of the second device.
"""
norm_data = self._normalize_data(data)
avg = sum(sum(sublist) / len(sublist) for sublist in norm_data) / len(norm_data)
results = [(norm_data, 0, [])]
stop_flag = False
while stop_flag == False:
new_results = []
best_score = results[0][1]
for i in range(len(results)):
new_results.extend(self._beam_search(results[i], beam_width, avg, group_swap_factor))
if len(new_results) == 0:
stop_flag = True
break
new_results.sort(key=lambda x: x[1], reverse=True)
new_best_score = new_results[0][1]
if new_best_score == best_score:
stop_flag = True
break
new_results = new_results[:beam_width]
results = new_results
for i in results:
if self._check_convergence(results[0][0], avg, tolerance):
stop_flag = True
break
swap_list = results[0][2]
if return_swapped_data:
out = deepcopy(data)
for swap in swap_list:
self._swap_data(out, *swap)
return out, swap_list
else:
return swap_list
@staticmethod
def _swap_expert_single_tensor(
weight: nn.Parameter,
expert_idx: int,
comm_group: ProcessGroup,
send_first: bool,
comm_rank: int,
):
# exchange weight
local_weight = weight.data[expert_idx]
new_weight = torch.empty_like(local_weight)
if send_first:
dist.send(local_weight, dst=comm_rank, group=comm_group)
dist.recv(new_weight, src=comm_rank, group=comm_group)
else:
dist.recv(new_weight, src=comm_rank, group=comm_group)
dist.send(local_weight, dst=comm_rank, group=comm_group)
weight.data[expert_idx] = new_weight
def _swap_expert_param_and_optim(
self,
weight: nn.Parameter,
expert_idx: int,
comm_group: ProcessGroup,
send_first: bool,
comm_rank: int,
optim: LowLevelZeroOptimizer,
):
# need to update master and working param if master param exists
# else just update working param
if weight in optim.optim.state:
master_weight_ptr = None
working_weight_ptr = weight
exp_avg_ptr = optim.optim.state[working_weight_ptr]["exp_avg"]
exp_avg_sq_ptr = optim.optim.state[working_weight_ptr]["exp_avg_sq"]
else:
master_weight_ptr = optim._param_store.working_to_master_param[id(weight)]
working_weight_ptr = weight
exp_avg_ptr = optim.optim.state[master_weight_ptr]["exp_avg"]
exp_avg_sq_ptr = optim.optim.state[master_weight_ptr]["exp_avg_sq"]
# exchange weight
self._swap_expert_single_tensor(
working_weight_ptr,
expert_idx,
comm_group,
send_first,
comm_rank,
)
if master_weight_ptr is not None:
# TODO: exchange master weight, skip for now
# master weight is shared by dp group
tmp = working_weight_ptr.view(-1).split(
working_weight_ptr.numel() // dist.get_world_size(self.moe_dp_group)
)[dist.get_rank(self.moe_dp_group)]
master_weight_ptr.data.copy_(tmp.clone().detach().to(master_weight_ptr.device).to(master_weight_ptr.dtype))
# exchange optim
self._swap_expert_single_tensor(exp_avg_ptr, expert_idx, comm_group, send_first, comm_rank)
self._swap_expert_single_tensor(exp_avg_sq_ptr, expert_idx, comm_group, send_first, comm_rank)
def _gather_global_dp_group(self, data: Tensor) -> Tensor:
data_list = [torch.zeros_like(data) for _ in range(self.global_dp_size)]
dist.all_gather(data_list, data, group=self.global_dp_group)
data_list = torch.cat(data_list, dim=0)
return data_list
def _swap_moe_param(self, swap_list: List, optim: LowLevelZeroOptimizer) -> None:
"""
Swap moe param and optim.
We use different strategies to swap expert and gate.
For expert, we exchange the param and optim of the expert by p2p.
For gate, we all gather the gate choose the part we want.
Args:
swap_list (List)
optim (LowLevelZeroOptimizer)
"""
# get all experts weights
local_rank = dist.get_rank(self.moe_ep_group)
if self.experts.gated:
weight_list = [self.experts.wi_up, self.experts.wi_gate]
else:
weight_list = [self.experts.wi]
weight_list.append(self.experts.wo)
# gate optim should be obtained first
gate_shape = self.gate.shape
# get master weight and optim
master_gate_weight = optim._param_store.working_to_master_param[id(self.gate)]
gate_exp_avg = optim.optim.state[master_gate_weight]["exp_avg"]
gate_exp_avg_sq = optim.optim.state[master_gate_weight]["exp_avg_sq"]
# gather
global_master_gate_weight = self._gather_global_dp_group(master_gate_weight).view(gate_shape)
global_gate_exp_avg = self._gather_global_dp_group(gate_exp_avg).view(gate_shape)
global_gate_exp_avg_sq = self._gather_global_dp_group(gate_exp_avg_sq).view(gate_shape)
assert (
self.gate.shape
== global_master_gate_weight.shape
== global_gate_exp_avg.shape
== global_gate_exp_avg_sq.shape
)
for swap in swap_list:
source_group, source_idx, target_group, target_idx = swap
source_rank = self.moe_ep_ranks[source_group]
target_rank = self.moe_ep_ranks[target_group]
# exchange expert
if local_rank in [source_group, target_group]:
for weight in weight_list:
if local_rank == source_group:
self._swap_expert_param_and_optim(
weight,
source_idx,
self.moe_ep_group,
True,
target_rank,
optim,
)
elif local_rank == target_group:
self._swap_expert_param_and_optim(
weight,
target_idx,
self.moe_ep_group,
False,
source_rank,
optim,
)
# exchange gate
source_expert_pos = source_group * self.local_expert_num + source_idx
target_expert_pos = target_group * self.local_expert_num + target_idx
for gate in [
self.gate,
global_master_gate_weight,
global_gate_exp_avg,
global_gate_exp_avg_sq,
]:
origin_source = gate.data[source_expert_pos].clone().detach()
origin_target = gate.data[target_expert_pos].clone().detach()
gate.data[source_expert_pos], gate.data[target_expert_pos] = (
origin_target,
origin_source,
)
# update gate
global_master_gate_weight = global_master_gate_weight.view(-1).split(
global_master_gate_weight.numel() // self.global_dp_size
)[self.global_dp_rank]
master_gate_weight.data.copy_(global_master_gate_weight)
global_gate_exp_avg = global_gate_exp_avg.view(-1).split(global_gate_exp_avg.numel() // self.global_dp_size)[
self.global_dp_rank
]
gate_exp_avg.data.copy_(global_gate_exp_avg)
global_gate_exp_avg_sq = global_gate_exp_avg_sq.view(-1).split(
global_gate_exp_avg_sq.numel() // self.global_dp_size
)[self.global_dp_rank]
gate_exp_avg_sq.data.copy_(global_gate_exp_avg_sq)
@torch.no_grad()
def update_load(self, load: Tensor) -> None:
if len(load) != self.expert_num:
padding_size = self.expert_num - len(load)
padding = torch.zeros(padding_size, dtype=load.dtype, device=load.device)
load = torch.cat((load, padding), dim=0)
if self.local_load is None:
self.local_load = load
else:
self.local_load += load
@torch.no_grad()
def balance_load(self, optim: LowLevelZeroOptimizer) -> None:
# prepare load
load = self._sync_load()
load = self._load_to_list(load)
# search balance
swap_list = self._search_balance(load)
if dist.get_rank() == 0:
if len(swap_list) > 0:
print(f"[Load Balance] Applying expert swap...")
else:
print(f"[Load Balance] Invalid swap, skip...")
# swap expert and gate
self._swap_moe_param(swap_list, optim)
# clear load
self._clear_load()