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200 lines
10 KiB
200 lines
10 KiB
from copy import deepcopy
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from typing import List
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import torch
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from torch.fx import symbolic_trace
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from torch.fx.node import Node
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from colossalai.auto_parallel.tensor_shard.sharding_strategy import (
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CommAction,
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CommType,
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OperationDataType,
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ShardingStrategy,
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)
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from colossalai.device.device_mesh import DeviceMesh
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from colossalai.tensor.comm_spec import _all_reduce
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from colossalai.tensor.shape_consistency import ShapeConsistencyManager
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from colossalai.tensor.sharding_spec import ShardingSpec
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shape_consistency_manager = ShapeConsistencyManager()
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def _solution_annotatation(gm: torch.fx.GraphModule, solution: List[int]):
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"""
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This method is used to stick the solution strategy to the nodes and add the information
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required in runtime into graph as placeholder nodes.
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"""
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mod_graph = gm.graph
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nodes = tuple(mod_graph.nodes)
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# the dict to get origin sharding spec of node
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origin_node_sharding_spec_dict = {}
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for node_index, (node, strategy_index) in enumerate(zip(nodes, solution)):
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strategies_vector = node.strategies_vector
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# stick the solution strategy to the corresponding node
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setattr(node, 'best_strategy', strategies_vector[strategy_index])
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setattr(node, 'sharding_spec', strategies_vector[strategy_index].get_sharding_spec_by_name(str(node)))
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origin_node_sharding_spec_dict[node_index] = strategies_vector[strategy_index].get_sharding_spec_by_name(
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str(node))
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# the dict to get input sharding specs of user node
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sharding_spec_convert_dict = {}
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# the dict to record comm actions of nodes
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comm_actions_dict = {}
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for index, node in enumerate(nodes):
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target_sharding_specs = []
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for user_node in node.strategies_vector.successor_nodes:
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target_sharding_spec = user_node.best_strategy.get_sharding_spec_by_name(str(node.name))
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target_sharding_specs.append(target_sharding_spec)
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sharding_spec_convert_dict[index] = target_sharding_specs
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setattr(node, 'target_sharding_specs', target_sharding_specs)
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# the get_attr node strategy is kind of pending strategy, which means we will change it
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# to the same strategy of the user node.
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if node.op == 'get_attr':
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assert len(target_sharding_specs) == 1, f'sharing weight is not supported in current version.'
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new_sharding_spec = target_sharding_specs[0]
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user_strategy = node.strategies_vector.successor_nodes[0].best_strategy
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op_data_in_user = user_strategy.get_op_data_by_name(str(node))
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origin_node_sharding_spec_dict[index] = new_sharding_spec
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origin_pending_strategy = node.best_strategy
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origin_op_data = origin_pending_strategy.get_op_data_by_name(str(node))
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new_sharding_specs = origin_pending_strategy.sharding_specs
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new_sharding_specs[origin_op_data] = new_sharding_spec
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new_communication_actions = {}
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if op_data_in_user in user_strategy.communication_actions:
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new_communication_action = user_strategy.communication_actions.pop(op_data_in_user)
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new_communication_action.arg_index = 0
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new_communication_actions[origin_op_data] = new_communication_action
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new_strategy = ShardingStrategy(name=str(new_sharding_spec.sharding_sequence),
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sharding_specs=new_sharding_specs,
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compute_cost=origin_pending_strategy.compute_cost,
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communication_cost=origin_pending_strategy.communication_cost,
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memory_cost=origin_pending_strategy.memory_cost,
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communication_actions=new_communication_actions)
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setattr(node, 'best_strategy', new_strategy)
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setattr(node, 'sharding_spec', new_sharding_spec)
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comm_action_dict = {}
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for op_data, comm_action in node.best_strategy.communication_actions.items():
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comm_action_dict[op_data.name] = comm_action
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comm_actions_dict[index] = comm_action_dict
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# add above dicts into graph
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for node in nodes:
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if node.op != 'placeholder':
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with mod_graph.inserting_before(node):
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input_specs_node = mod_graph.create_node('placeholder', target='sharding_spec_convert_dict')
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origin_specs_node = mod_graph.create_node('placeholder', target='origin_node_sharding_spec_dict')
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comm_actions_dict_node = mod_graph.create_node('placeholder', target='comm_actions_dict')
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break
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return gm, sharding_spec_convert_dict, origin_node_sharding_spec_dict, comm_actions_dict
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def _module_params_sharding(gm: torch.fx.GraphModule, device_mesh):
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"""
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Apply the sharding action to the module parameters and buffers following the
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instructions of solver solution.
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"""
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mod_graph = gm.graph
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nodes = tuple(mod_graph.nodes)
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# This stream is created for overlaping the communication and computation.
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reduction_stream = torch.cuda.Stream()
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for node in nodes:
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if node.op == 'call_module':
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target_module = node.graph.owning_module.get_submodule(node.target)
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for name, param in target_module.named_parameters():
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target_sharding_spec = node.best_strategy.get_sharding_spec_by_name(name)
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# apply the sharding spec of parameters
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if target_sharding_spec.dim_partition_dict != {}:
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origin_sharding_spec = ShardingSpec(device_mesh, param.shape, {})
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setattr(param, 'sharding_spec', origin_sharding_spec)
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# TODO: build a ColoParamter class to manager the distributed parameters
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param_sharded = torch.nn.Parameter(
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shape_consistency_manager.apply_for_autoparallel_runtime(param.data, param.sharding_spec,
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target_sharding_spec).detach().clone())
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else:
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param_sharded = param
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setattr(target_module, name, param_sharded)
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comm_actions = node.best_strategy.communication_actions
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for operation_data, comm_action in comm_actions.items():
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comm_spec_to_use = comm_action.comm_spec
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# register hook to the parameters
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if operation_data.type == OperationDataType.PARAM and operation_data.name == name and comm_action.comm_type == CommType.HOOK:
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def wrapper(param, comm_spec):
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def hook_fn(grad):
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_all_reduce(grad, comm_spec, async_op=False)
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param.register_hook(hook_fn)
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wrapper(param_sharded, comm_spec_to_use)
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sharded_buffer_dict = {}
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# apply the sharding spec of buffers
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for name, buffer in target_module.named_buffers():
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origin_sharding_spec = ShardingSpec(device_mesh, buffer.shape, {})
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setattr(buffer, 'sharding_spec', origin_sharding_spec)
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target_sharding_spec = node.best_strategy.get_sharding_spec_by_name(name)
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buffer_sharded = shape_consistency_manager.apply(buffer, target_sharding_spec)
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sharded_buffer_dict[name] = buffer_sharded
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for name, buffer_sharded in sharded_buffer_dict.items():
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setattr(target_module, name, buffer_sharded.detach().clone())
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if node.op == 'get_attr':
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root = node.graph.owning_module
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atoms = node.target.split(".")
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attr_len = len(atoms)
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if attr_len == 1:
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target_module = root
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target = getattr(root, atoms[0])
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else:
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target_module = root.get_submodule(atoms[-2])
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target = getattr(target_module, atoms[-1])
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target_sharding_spec = node.sharding_spec
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if target_sharding_spec.dim_partition_dict != {}:
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origin_sharding_spec = ShardingSpec(device_mesh, target.shape, {})
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setattr(target, 'sharding_spec', origin_sharding_spec)
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# TODO: build a ColoParamter class to manager the distributed parameters
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target_sharded = torch.nn.Parameter(
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shape_consistency_manager.apply_for_autoparallel_runtime(target.data, target.sharding_spec,
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target_sharding_spec).detach().clone())
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else:
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target_sharded = target
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setattr(target_module, atoms[-1], target_sharded)
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comm_actions = node.best_strategy.communication_actions
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for operation_data, comm_action in comm_actions.items():
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comm_spec_to_use = comm_action.comm_spec
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# register hook to the parameters
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if isinstance(node._meta_data, torch.nn.parameter.Parameter) and comm_action.comm_type == CommType.HOOK:
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def wrapper(param, comm_spec):
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def hook_fn(grad):
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_all_reduce(grad, comm_spec, async_op=False)
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param.register_hook(hook_fn)
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wrapper(target_sharded, comm_spec_to_use)
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return gm
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def implicit_comm_action_apply(gm: torch.fx.GraphModule):
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"""
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replace the origin kernel into kernel with implicit communication inside.
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"""
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pass
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def runtime_preparation_pass(gm: torch.fx.GraphModule, solution: List[int], device_mesh: DeviceMesh):
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gm, sharding_spec_convert_dict, origin_node_sharding_spec_dict, comm_actions_dict = _solution_annotatation(
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gm, solution)
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# TODO: the pass below should be uncommented after the implementation of implicit_comm_action_apply_pass completed.
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# gm = implicit_comm_action_apply(gm)
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gm = _module_params_sharding(gm, device_mesh)
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return gm, sharding_spec_convert_dict, origin_node_sharding_spec_dict, comm_actions_dict
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