mirror of https://github.com/hpcaitech/ColossalAI
166 lines
5.9 KiB
Python
166 lines
5.9 KiB
Python
import math
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import torch
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import torch.nn as nn
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from colossalai.global_variables import moe_env
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from colossalai.context import ParallelMode, seed
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from colossalai.utils import get_current_device
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class MoeExperts(nn.Module):
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def __init__(self, comm: str):
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super().__init__()
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assert comm in {"all_to_all", "all_gather"}, \
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"This kind of communication has not been implemented yet.\n Please use Experts build function."
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self.comm = comm
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class Experts(MoeExperts):
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"""A wrapper class to create experts. It will create E experts across the
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moe model parallel group, where E is the number of experts. Every expert
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is a instence of the class, 'expert' in initialization parameters.
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:param expert: The class of all experts
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:param num_experts: The number of experts
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:param expert_args: Args used to initialize experts
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:type num_experts: int
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"""
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def __init__(self, expert, num_experts, **expert_args):
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super().__init__("all_to_all")
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assert num_experts % moe_env.model_parallel_size == 0, \
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"The number of experts should be divied by moe model size"
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num_local_experts = num_experts // moe_env.model_parallel_size
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with seed(ParallelMode.MOE_MODEL):
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self.experts = nn.ModuleList([expert(**expert_args) for _ in range(num_local_experts)])
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for exp in self.experts:
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for param in exp.parameters():
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param.__setattr__('moe_param', True)
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self.num_local_experts = num_local_experts
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def forward(self, inputs):
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expert_input = torch.chunk(inputs, self.num_local_experts, dim=1)
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expert_output = []
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for i in range(self.num_local_experts):
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expert_output.append(self.experts[i](expert_input[i]))
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output = torch.cat(expert_output, dim=1).contiguous()
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return output
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class FFNExperts(MoeExperts):
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def __init__(self, num_experts: int, d_model: int, d_ff: int, activation=None, drop_rate: float = 0):
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super().__init__("all_to_all")
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assert num_experts % moe_env.model_parallel_size == 0, \
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"The number of experts should be divied by moe model size"
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num_local_experts = num_experts // moe_env.model_parallel_size
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self.w1 = nn.Parameter(torch.empty(num_local_experts, d_model, d_ff, device=get_current_device()))
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self.b1 = nn.Parameter(torch.empty(num_local_experts, 1, d_ff, device=get_current_device()))
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self.w2 = nn.Parameter(torch.empty(num_local_experts, d_ff, d_model, device=get_current_device()))
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self.b2 = nn.Parameter(torch.empty(num_local_experts, 1, d_model, device=get_current_device()))
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s1 = math.sqrt(0.1 / d_model)
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s2 = math.sqrt(0.1 / d_ff)
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with seed(ParallelMode.MOE_MODEL):
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nn.init.trunc_normal_(self.w1, std=s1)
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nn.init.trunc_normal_(self.b1, std=s1)
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nn.init.trunc_normal_(self.w2, std=s2)
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nn.init.trunc_normal_(self.b2, std=s2)
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self.act = nn.GELU() if activation is None else activation
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self.drop = nn.Dropout(p=drop_rate)
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for param in self.parameters():
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param.__setattr__('moe_param', True)
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def forward(self, inputs): # inputs [g, el, c, h]
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el = inputs.size(1)
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h = inputs.size(-1)
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inputs = inputs.transpose(0, 1)
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inshape = inputs.shape
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inputs = inputs.reshape(el, -1, h)
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out_ff = torch.baddbmm(self.b1, inputs, self.w1)
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out_act = self.act(out_ff)
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with seed(ParallelMode.TENSOR):
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inter = self.drop(out_act)
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out_model = torch.baddbmm(self.b2, inter, self.w2)
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with seed(ParallelMode.TENSOR):
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outputs = self.drop(out_model) # outputs [el, gc, h]
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outputs = outputs.reshape(inshape)
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outputs = outputs.transpose(0, 1).contiguous()
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return outputs
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class TPExperts(MoeExperts):
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def __init__(self, num_experts: int, d_model: int, d_ff: int, activation=None, drop_rate: float = 0):
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super().__init__("all_gather")
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assert d_ff % moe_env.model_parallel_size == 0, \
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"d_ff should be divied by moe model size"
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p_ff = d_ff // moe_env.model_parallel_size
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self.w1 = nn.Parameter(torch.empty(num_experts, d_model, p_ff, device=get_current_device()))
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self.b1 = nn.Parameter(torch.empty(num_experts, 1, p_ff, device=get_current_device()))
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self.w2 = nn.Parameter(torch.empty(num_experts, p_ff, d_model, device=get_current_device()))
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self.b2 = nn.Parameter(torch.empty(num_experts, 1, d_model, device=get_current_device()))
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s1 = math.sqrt(0.1 / d_model)
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s2 = math.sqrt(0.1 / d_ff)
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with seed(ParallelMode.MOE_MODEL):
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nn.init.trunc_normal_(self.w1, std=s1)
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nn.init.trunc_normal_(self.b1, std=s1)
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nn.init.trunc_normal_(self.w2, std=s2)
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nn.init.trunc_normal_(self.b2, std=s2)
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self.act = nn.GELU() if activation is None else activation
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self.drop = nn.Dropout(p=drop_rate)
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self.w1.__setattr__('moe_param', True)
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self.w2.__setattr__('moe_param', True)
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self.b1.__setattr__('moe_param', True)
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def forward(self, inputs): # inputs [g, e, c, h]
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e = inputs.size(1)
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h = inputs.size(-1)
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inputs = inputs.transpose(0, 1)
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inshape = inputs.shape
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inputs = inputs.reshape(e, -1, h)
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out_ff = torch.baddbmm(self.b1, inputs, self.w1)
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out_act = self.act(out_ff)
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with seed(ParallelMode.TENSOR):
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inter = self.drop(out_act)
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out_model = torch.baddbmm(self.b2, inter, self.w2)
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outputs = self.drop(out_model) # outputs [e, gc, h]
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outputs = outputs.reshape(inshape)
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outputs = outputs.transpose(0, 1).contiguous()
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return outputs # outputs [g, e, c, h]
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