ColossalAI/tests/test_shardformer/test_layer/test_linear_1d.py

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 Linear1D_Col, Linear1D_Row
from colossalai.tensor.d_tensor import is_distributed_tensor
from colossalai.testing import rerun_if_address_is_in_use, spawn


def check_linear_1d_col():
    linear = nn.Linear(32, 128).cuda()
    linear_col = Linear1D_Col.from_native_module(linear, process_group=None, gather_output=True)

    # ensure that the parameters are distributed
    assert is_distributed_tensor(linear_col.weight)
    assert is_distributed_tensor(linear_col.bias)

    # ensure the shape is correct
    assert linear_col.weight.shape == torch.Size([64, 32])
    assert linear_col.bias.shape == torch.Size([64])

    # ensure state dict is reversibly loadable
    linear.load_state_dict(linear_col.state_dict())
    linear_col.load_state_dict(linear.state_dict())

    # check computation correctness
    x = torch.rand(4, 32).cuda()
    x_for_unshard = x.expand_as(x.clone())
    x_for_unshard.requires_grad_(True)
    x_for_shard = x.expand_as(x.clone())
    x_for_shard.requires_grad_(True)

    out = linear(x_for_unshard)
    gather_out = linear_col(x_for_shard)
    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_col.weight.grad)

    # check the input gradients
    assert x_for_shard.grad is not None
    assert x_for_unshard.grad is not None
    assert_close(x_for_unshard.grad, x_for_shard.grad)


def check_linear_1d_row():
    linear = nn.Linear(32, 128).cuda()
    linear_row = Linear1D_Row.from_native_module(linear, process_group=None, parallel_input=False)

    assert linear_row.weight.shape == torch.Size([128, 16])
    assert linear_row.bias.shape == torch.Size([128])

    # check computation correctness
    x = torch.rand(4, 32).cuda()
    x_for_unshard = x.expand_as(x.clone())
    x_for_unshard.requires_grad_(True)
    x_for_shard = x.expand_as(x.clone())
    x_for_shard.requires_grad_(True)

    # run forward
    out = linear(x_for_unshard)
    gather_out = linear_row(x_for_shard)
    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=1)[rank]
    assert_close(target_grad, linear_row.weight.grad)

    # check the input gradients
    assert x_for_shard.grad is not None
    assert x_for_unshard.grad is not None
    assert_close(x_for_unshard.grad, x_for_shard.grad)


def check_linear_col_plus_row():
    linear_1 = nn.Linear(32, 128).cuda()
    linear_2 = nn.Linear(128, 32).cuda()
    linear_col = Linear1D_Col.from_native_module(linear_1, process_group=None, gather_output=False)
    linear_row = Linear1D_Row.from_native_module(linear_2, process_group=None, parallel_input=True)

    # check computation correctness
    x = torch.rand(4, 32).cuda()
    x_for_unshard = x.expand_as(x.clone())
    x_for_unshard.requires_grad_(True)
    x_for_shard = x.expand_as(x.clone())
    x_for_shard.requires_grad_(True)

    # run forward
    unshard_out = linear_2(linear_1(x_for_unshard))
    shard_out = linear_row(linear_col(x_for_shard))
    assert_close(unshard_out, shard_out)

    # check backward correctness
    unshard_out.sum().backward()
    shard_out.sum().backward()

    rank = dist.get_rank()
    target_1_grad = torch.chunk(linear_1.weight.grad, 2, dim=0)[rank]
    assert_close(target_1_grad, linear_col.weight.grad)

    # check the input gradients
    assert x_for_shard.grad is not None
    assert x_for_unshard.grad is not None
    assert_close(x_for_unshard.grad, x_for_shard.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_1d_col()
    check_linear_1d_row()
    check_linear_col_plus_row()


@rerun_if_address_is_in_use()
def test_linear():
    spawn(run_dist, nprocs=2)


if __name__ == '__main__':
    test_linear()
[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago			`import torch`
			`import torch.distributed as dist`
			`import torch.nn as nn`
			`from torch.testing import assert_close`

			`import colossalai`
[shardformer] refactored the shardformer layer structure (#4053) 1 year ago			`from colossalai.shardformer.layer import Linear1D_Col, Linear1D_Row`
[shardformer] support module saving and loading (#4062) * [shardformer] support module saving and loading * polish code 1 year ago			`from colossalai.tensor.d_tensor import is_distributed_tensor`
[shardformer] refactored embedding and dropout to parallel module (#4013) * [shardformer] refactored embedding and dropout to parallel module * polish code 1 year ago			`from colossalai.testing import rerun_if_address_is_in_use, spawn`
[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago

			`def check_linear_1d_col():`
			`linear = nn.Linear(32, 128).cuda()`
			`linear_col = Linear1D_Col.from_native_module(linear, process_group=None, gather_output=True)`

[shardformer] support module saving and loading (#4062) * [shardformer] support module saving and loading * polish code 1 year ago			`# ensure that the parameters are distributed`
			`assert is_distributed_tensor(linear_col.weight)`
			`assert is_distributed_tensor(linear_col.bias)`

			`# ensure the shape is correct`
[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago			`assert linear_col.weight.shape == torch.Size([64, 32])`
			`assert linear_col.bias.shape == torch.Size([64])`

[shardformer] support module saving and loading (#4062) * [shardformer] support module saving and loading * polish code 1 year ago			`# ensure state dict is reversibly loadable`
			`linear.load_state_dict(linear_col.state_dict())`
			`linear_col.load_state_dict(linear.state_dict())`

[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago			`# check computation correctness`
			`x = torch.rand(4, 32).cuda()`
[shardformer] supported fused qkv checkpoint (#4073) 1 year ago			`x_for_unshard = x.expand_as(x.clone())`
			`x_for_unshard.requires_grad_(True)`
			`x_for_shard = x.expand_as(x.clone())`
			`x_for_shard.requires_grad_(True)`

			`out = linear(x_for_unshard)`
			`gather_out = linear_col(x_for_shard)`
[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago			`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_col.weight.grad)`

[shardformer] supported fused qkv checkpoint (#4073) 1 year ago			`# check the input gradients`
			`assert x_for_shard.grad is not None`
			`assert x_for_unshard.grad is not None`
			`assert_close(x_for_unshard.grad, x_for_shard.grad)`

[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago
			`def check_linear_1d_row():`
			`linear = nn.Linear(32, 128).cuda()`
			`linear_row = Linear1D_Row.from_native_module(linear, process_group=None, parallel_input=False)`

			`assert linear_row.weight.shape == torch.Size([128, 16])`
			`assert linear_row.bias.shape == torch.Size([128])`

			`# check computation correctness`
			`x = torch.rand(4, 32).cuda()`
[shardformer] supported fused qkv checkpoint (#4073) 1 year ago			`x_for_unshard = x.expand_as(x.clone())`
			`x_for_unshard.requires_grad_(True)`
			`x_for_shard = x.expand_as(x.clone())`
			`x_for_shard.requires_grad_(True)`

			`# run forward`
			`out = linear(x_for_unshard)`
			`gather_out = linear_row(x_for_shard)`
[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago			`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=1)[rank]`
			`assert_close(target_grad, linear_row.weight.grad)`

[shardformer] supported fused qkv checkpoint (#4073) 1 year ago			`# check the input gradients`
			`assert x_for_shard.grad is not None`
			`assert x_for_unshard.grad is not None`
			`assert_close(x_for_unshard.grad, x_for_shard.grad)`


			`def check_linear_col_plus_row():`
			`linear_1 = nn.Linear(32, 128).cuda()`
			`linear_2 = nn.Linear(128, 32).cuda()`
			`linear_col = Linear1D_Col.from_native_module(linear_1, process_group=None, gather_output=False)`
			`linear_row = Linear1D_Row.from_native_module(linear_2, process_group=None, parallel_input=True)`

			`# check computation correctness`
			`x = torch.rand(4, 32).cuda()`
			`x_for_unshard = x.expand_as(x.clone())`
			`x_for_unshard.requires_grad_(True)`
			`x_for_shard = x.expand_as(x.clone())`
			`x_for_shard.requires_grad_(True)`

			`# run forward`
			`unshard_out = linear_2(linear_1(x_for_unshard))`
			`shard_out = linear_row(linear_col(x_for_shard))`
			`assert_close(unshard_out, shard_out)`

			`# check backward correctness`
			`unshard_out.sum().backward()`
			`shard_out.sum().backward()`

			`rank = dist.get_rank()`
			`target_1_grad = torch.chunk(linear_1.weight.grad, 2, dim=0)[rank]`
			`assert_close(target_1_grad, linear_col.weight.grad)`

			`# check the input gradients`
			`assert x_for_shard.grad is not None`
			`assert x_for_unshard.grad is not None`
			`assert_close(x_for_unshard.grad, x_for_shard.grad)`

[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago
			`def run_dist(rank, world_size, port):`
			`colossalai.launch(config={}, rank=rank, world_size=world_size, host='localhost', port=port, backend='nccl')`
			`check_linear_1d_col()`
[shardformer] supported fused qkv checkpoint (#4073) 1 year ago			`check_linear_1d_row()`
			`check_linear_col_plus_row()`
[shardformer] integrated linear 1D with dtensor (#3996) * [shardformer] integrated linear 1D with dtensor * polish code 1 year ago

			`@rerun_if_address_is_in_use()`
			`def test_linear():`
			`spawn(run_dist, nprocs=2)`


			`if __name__ == '__main__':`
			`test_linear()`