ColossalAI/tests/test_shardformer/test_layer/test_linearconv_1d.py

116 lines
3.6 KiB
Python
Raw Normal View History

import torch
import torch.distributed as dist
import torch.nn as nn
from torch.testing import assert_close
import colossalai
from colossalai.shardformer.layer import LinearConv1D_Col, LinearConv1D_Row
from colossalai.shardformer.layer.linear_conv import split_fused_qkv
from colossalai.testing import rerun_if_address_is_in_use, spawn
# This code is copied from https://github.com/huggingface/transformers
class Conv1D(nn.Module):
"""
1D-convolutional layer as defined by Radford et al. for OpenAI GPT (and also used in GPT-2).
Basically works like a linear layer but the weights are transposed.
Args:
nf (`int`): The number of output features.
nx (`int`): The number of input features.
"""
def __init__(self, nf, nx):
super().__init__()
self.nf = nf
self.weight = nn.Parameter(torch.empty(nx, nf))
self.bias = nn.Parameter(torch.zeros(nf))
nn.init.normal_(self.weight, std=0.02)
def forward(self, x):
size_out = x.size()[:-1] + (self.nf,)
x = torch.addmm(self.bias, x.view(-1, x.size(-1)), self.weight)
x = x.view(size_out)
return x
def rearrange(tensor: torch.Tensor, dim: int):
tensor = tensor.clone()
world_size = 2
order = torch.arange(world_size * 3)
new_order = []
for i in range(world_size):
new_order.append(order[i::world_size])
new_order = torch.cat(new_order)
tensor_chunks = torch.chunk(tensor, world_size * 3, dim=dim)
rearanged_tensor_chunks = [tensor_chunks[i] for i in new_order]
rearanged_tensor = torch.cat(rearanged_tensor_chunks, dim=dim)
return rearanged_tensor
def check_linear_conv_1d_col():
linear = Conv1D(192, 48).cuda()
linear_conv_col = LinearConv1D_Col.from_native_module(linear, process_group=None, gather_output=True, n_fused=3)
assert linear.weight.shape == torch.Size([48, 192])
assert linear.bias.shape == torch.Size([192])
assert linear_conv_col.weight.shape == torch.Size([48, 96])
assert linear_conv_col.bias.shape == torch.Size([96])
# ensure weights are reversibly loadable
linear_conv_col.load_state_dict(linear.state_dict())
linear.load_state_dict(linear_conv_col.state_dict())
# check computation correctness
x = torch.rand(4, 48).cuda()
out = linear(x)
gather_out = linear_conv_col(x)
assert_close(rearrange(out, 1), gather_out)
# check backward correctness
out.sum().backward()
gather_out.sum().backward()
target_grad = split_fused_qkv(linear.weight.grad, 3, None)
assert_close(target_grad, linear_conv_col.weight.grad)
def check_linear_conv_1d_row():
linear = Conv1D(192, 48).cuda()
linear_row = LinearConv1D_Row.from_native_module(linear, process_group=None, parallel_input=False)
assert linear.weight.shape == torch.Size([48, 192])
assert linear_row.weight.shape == torch.Size([24, 192])
assert linear_row.bias.shape == torch.Size([192])
# check computation correctness
x = torch.rand(4, 48).cuda()
out = linear(x)
gather_out = linear_row(x)
assert_close(out, gather_out)
# check backward correctness
out.sum().backward()
gather_out.sum().backward()
rank = dist.get_rank()
target_grad = torch.chunk(linear.weight.grad, 2, dim=0)[rank]
assert_close(target_grad, linear_row.weight.grad)
def run_dist(rank, world_size, port):
colossalai.launch(config={}, rank=rank, world_size=world_size, host='localhost', port=port, backend='nccl')
check_linear_conv_1d_col()
check_linear_conv_1d_row()
@rerun_if_address_is_in_use()
def test_linearconv():
spawn(run_dist, nprocs=2)
if __name__ == '__main__':
test_linearconv()