ColossalAI/colossalai/fx/passes/adding_split_node_pass.py

128 lines
4.8 KiB
Python

import torch
from torch.fx import symbolic_trace
from torch.fx.node import Node
from colossalai.fx.passes.split_module import split_module
def pipe_split():
pass
def balanced_split_pass(gm: torch.fx.GraphModule, pp_size: int):
"""
In balanced_split_pass, we split module by the size of parameters(weights+bias).
"""
mod_graph = gm.graph
total_param_amount = 0
for param in mod_graph.owning_module.parameters():
total_param_amount += param.numel()
params_per_partition = total_param_amount // pp_size
accumulate_param_amount = 0
for node in mod_graph.nodes:
if pp_size <= 1:
break
if node.op == "call_module":
target_module = node.graph.owning_module.get_submodule(node.target)
for param in target_module.parameters():
accumulate_param_amount += param.numel()
if accumulate_param_amount >= params_per_partition:
accumulate_param_amount = 0
pp_size -= 1
# If the next node is output node, we will insert split annotation before
# node to make sure there is at least one node in last partition.
if node.next.op == 'output':
with mod_graph.inserting_before(node):
split_node = mod_graph.create_node('call_function', pipe_split)
else:
with mod_graph.inserting_after(node):
split_node = mod_graph.create_node('call_function', pipe_split)
gm.recompile()
return gm
def balanced_split_pass_v2(gm: torch.fx.GraphModule, pp_size: int):
"""
In balanced_split_pass_v12, we split module by the size of nodes(weights+bias+outputs).
"""
mod_graph = gm.graph
# To use balanced_split_pass_v2, we need run meta_info_prop interpreter first.
# If nodes don't have meta info, this pass will fall back to normal balanced split pass.
check_node = list(mod_graph.nodes)[0]
if 'tensor_meta' not in check_node.meta:
return balanced_split_pass(gm, pp_size)
total_element_size = 0
for node in mod_graph.nodes:
total_element_size += node.node_size
partition_size = total_element_size // pp_size
accumulate_node_size = 0
for node in mod_graph.nodes:
if pp_size <= 1:
break
if 'pipe_split' in node.name:
continue
accumulate_node_size += node.node_size
if accumulate_node_size >= partition_size:
accumulate_node_size = 0
pp_size -= 1
with mod_graph.inserting_after(node):
split_node = mod_graph.create_node('call_function', pipe_split)
gm.recompile()
return gm
def uniform_split_pass(gm: torch.fx.GraphModule, pp_size: int):
mod_graph = gm.graph
valid_children_size = 0
valid_children = []
for module in mod_graph.owning_module.children():
valid_children_size += 1
valid_children.append(module)
if valid_children_size < pp_size:
# If valid children is not enough to shard, we will use balanced policy instead of uniform policy.
return balanced_split_pass(gm, pp_size)
layers_per_partition = valid_children_size // pp_size
accumulate_layer_amount = 0
for node in mod_graph.nodes:
if pp_size <= 1:
break
if node.op == "call_module":
target_module = node.graph.owning_module.get_submodule(node.target)
if target_module in valid_children:
accumulate_layer_amount += 1
if accumulate_layer_amount == layers_per_partition:
accumulate_layer_amount = 0
pp_size -= 1
with mod_graph.inserting_after(node):
split_node = mod_graph.create_node('call_function', pipe_split)
gm.recompile()
return gm
def split_with_split_nodes_pass(annotated_gm: torch.fx.GraphModule):
# TODO(lyl): use partition IR to assign partition ID to each node.
# Currently: analyzing graph -> annotate graph by inserting split node -> use split module pass to split graph
# In future: graph to partitions -> analyzing partition IR -> recombining partitions to get best performance -> assign partition ID to each node
part_idx = 0
def split_callback(n: torch.fx.Node):
nonlocal part_idx
if (n.op, n.target) == ('call_function', pipe_split):
part_idx += 1
return part_idx
split_mod = split_module(annotated_gm, None, split_callback)
split_submodules = []
for name, submodule in split_mod.named_modules():
if isinstance(submodule, torch.fx.GraphModule):
for node in submodule.graph.nodes:
if (node.op, node.target) == ('call_function', pipe_split):
submodule.graph.erase_node(node)
submodule.recompile()
split_submodules.append(submodule)
return split_mod, split_submodules