import torch from torch.fx import GraphModule import torch.nn as nn import pytest from colossalai.fx.proxy import ColoProxy from colossalai.fx.tracer.tracer import ColoTracer from colossalai.tensor.sharding_spec import ShardingSpec, _DimSpec from colossalai.auto_parallel.solver.op_handler.dot_handler import DotHandler from colossalai.auto_parallel.solver.sharding_strategy import ShardingStrategy, StrategiesVector from colossalai.device.device_mesh import DeviceMesh class LinearModel(nn.Module): def __init__(self, in_features, out_features): super().__init__() self.linear = nn.Linear(in_features, out_features) def forward(self, x): x = x * 2 x = self.linear(x) return x def test_dot_handler(): physical_mesh_id = torch.arange(0, 4) mesh_shape = (2, 2) # [[0, 1] # [2, 3]] device_mesh = DeviceMesh(physical_mesh_id, mesh_shape) entire_shape = torch.Size((4, 8)) tracer = ColoTracer() model = LinearModel(8, 16) input_sample = {'x': torch.rand(4, 8).to('meta')} # graph(): # %x : torch.Tensor [#users=1] = placeholder[target=x] # %mul : [#users=1] = call_function[target=operator.mul](args = (%x, 2), kwargs = {}) # %conv : [#users=1] = call_module[target=conv](args = (%mul,), kwargs = {}) # return conv graph = tracer.trace(root=model, meta_args=input_sample) gm = GraphModule(model, graph, model.__class__.__name__) gm.recompile() # [x, mul, linear, output] nodes = [node for node in gm.graph.nodes] # find the sharding strategies for the input node of the conv node # strategies_for_input = [[R, R, R, R], [R, S0, R, R], [R, S1, R, R], [S0, R, R, R], [S0, S1, R, R], [S1, R, R, R], [S1, S0, R, R]] strategies_vector_for_input = StrategiesVector(node=nodes[1]) sharding_option = (None, 0, 1) for first_sharding_index in sharding_option: for second_sharding_index in sharding_option: if first_sharding_index is not None and second_sharding_index == first_sharding_index: continue if first_sharding_index is None: first_dim_spec = _DimSpec([]) else: first_dim_spec = _DimSpec([first_sharding_index]) if second_sharding_index is None: second_dim_spec = _DimSpec([]) else: second_dim_spec = _DimSpec([second_sharding_index]) sharding_sequence = [first_dim_spec, second_dim_spec] sharding_spec = ShardingSpec(device_mesh=device_mesh, entire_shape=entire_shape, sharding_sequence=sharding_sequence) strategy_name = str(sharding_spec.sharding_sequence) sharding_strategy = ShardingStrategy(name=strategy_name, output_sharding_spec=sharding_spec) strategies_vector_for_input.append(sharding_strategy) setattr(nodes[1], 'strategies_vector', strategies_vector_for_input) # generate dot strategy strategies_vector = StrategiesVector(node=nodes[2]) dot_handler = DotHandler( node=nodes[2], device_mesh=device_mesh, strategies_vector=strategies_vector, ) strategies_vector = dot_handler.register_strategy() # ['S0S1 = S0R x RS1', 'S1S0 = S1R x RS0', 'S0R = S0S1 x S1R', 'S1R = S1S0 x S0R', 'RS1 = RS0 x S0S1', 'RS0 = RS1 x S1S0', 'RS0 = RR x RS0', 'RS1 = RR x RS1', 'RR = RR x RR'] strategy_name_list = [strategy.name for strategy in strategies_vector] # SS = SR x RS assert 'S0S1 = S0R x RS1' in strategy_name_list assert 'S1S0 = S1R x RS0' in strategy_name_list # SR = SS x SR assert 'S0R = S0S1 x S1R' in strategy_name_list assert 'S1R = S1S0 x S0R' in strategy_name_list # RS = RS x SS assert 'RS0 = RS1 x S1S0' in strategy_name_list assert 'RS1 = RS0 x S0S1' in strategy_name_list # RR = RS x SR assert 'RR = RS0 x S0R' in strategy_name_list assert 'RR = RS1 x S1R' in strategy_name_list # RS= RR x RS assert 'RS0 = RR x RS0' in strategy_name_list assert 'RS1 = RR x RS1' in strategy_name_list if __name__ == '__main__': test_dot_handler()