# Copyright (c) 2018 PaddlePaddle Authors. All Rights Reserve. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from collections import defaultdict import framework from framework import Program, default_main_program, Parameter, Variable import backward from backward import _rename_arg_ from . import core dtype_to_size = { core.DataType.FP16: 2, core.DataType.FP32: 4, core.DataType.FP64: 8, core.DataType.INT16: 2, core.DataType.INT32: 4, core.DataType.INT64: 8, core.DataType.BOOL: 1 } class ControlFlowGraph(object): def __init__(self, Program, ops, forward_num, skip_opt): self._program = Program self._ops = ops self._forward_num = forward_num self._successors = defaultdict(set) self._presuccessors = defaultdict(set) self._uses = defaultdict(set) self._defs = defaultdict(set) self._live_in = defaultdict(set) self._live_out = defaultdict(set) self._skip_opt = skip_opt def _add_connections(self, connections): for node1, node2 in connections: self._add(node1, node2) def _add(self, node1, node2): self._successors[node1].add(node2) self._presuccessors[node2].add(node1) def _build_graph(self): self.op_size = len(self._ops) op_node_connections = [(i, i + 1) for i in range(self.op_size - 1)] self._add_connections(op_node_connections) for i in range(self.op_size): self._uses[i].update(self._ops[i].input_arg_names()) self._defs[i].update(self._ops[i].output_arg_names()) def _update_graph(self, old_name, new_name, begin_idx=0): for i in range(begin_idx, self.op_size): if old_name in self._uses[i]: self._uses[i].remove(old_name) self._uses[i].add(new_name) if old_name in self._defs[i]: self._defs[i].remove(old_name) self._defs[i].add(new_name) if old_name in self._live_in[i]: self._live_in[i].remove(old_name) self._live_out[i].add(new_name) if old_name in self._live_out[i]: self._live_out[i].remove(old_name) self._live_out[i].add(new_name) def _reach_fixed_point(self, live_in, live_out): if len(live_in) != len(self._live_in): return False if len(live_out) != len(self._live_out): return False for i in range(self.op_size): if live_in[i] != self._live_in[i]: return False for i in range(self.op_size): if live_out[i] != self._live_out[i]: return False return True def _dataflow_analyze(self): self._build_graph() live_in = defaultdict(set) live_out = defaultdict(set) while True: for i in range(self.op_size): live_in[i] = set(self._live_in[i]) live_out[i] = set(self._live_out[i]) self._live_in[i] = self._uses[i] | ( self._live_out[i] - self._defs[i]) for s in self._successors[i]: self._live_out[i] |= self._live_in[s] if self._reach_fixed_point(live_in, live_out): break def _get_diff(self, a, b): u = a & b return a - u, b - u def _has_var(self, block_desc, var_name, is_forward): if is_forward: return block_desc.has_var(str(var_name)) else: return block_desc.has_var_recursive(str(var_name)) def _find_var(self, block_desc, var_name, is_forward): if is_forward: return block_desc.find_var(str(var_name)) else: return block_desc.find_var_recursive(str(var_name)) def memory_optimize(self): def check_var_validity(block_desc, x, is_forward): if str(x) == "@EMPTY@": return False if not self._has_var(block_desc, x, is_forward): return False if self._find_var(block_desc, x, is_forward).persistable(): return False if self._find_var( block_desc, x, is_forward).type() != core.VarDesc.VarType.LOD_TENSOR: return False if x in self._skip_opt: return False if not self._find_var(block_desc, x, is_forward).shape(): return False return True self._build_graph() self._dataflow_analyze() self.pool = [] for i in range(self.op_size): op = self._ops[i] if op.type() == "while" or op.type() == "while_grad": continue block_desc = op.block() self.current_block_desc = block_desc is_forward = i < self._forward_num if self.pool: defs_can_optimize = filter( lambda x: check_var_validity(block_desc, x, is_forward), self._defs[i]) out_pair = [ (x, self._find_var(block_desc, x, is_forward).shape()) for x in defs_can_optimize ] for x, x_shape in out_pair: for index, cache_pair in enumerate(self.pool): cache_var = cache_pair[0] cache_shape = cache_pair[1] if x_shape == cache_shape: if self._has_var(block_desc, cache_var, is_forward): x_dtype = self._find_var(block_desc, x, is_forward).dtype() cache_dtype = self._find_var( block_desc, cache_var, is_forward).dtype() # TODO(qijun): actually, we should compare dtype_to_size[x_dtype] # and dtype_to_size[cache_dtype] if x_dtype == cache_dtype: print(("Hit Cache !!!! cache pool index " "is %d, var name is %s, " "cached var name is %s, " "var shape is %s ") % (index, x, cache_var, str(cache_shape))) self.pool.pop(index) if x == cache_var: break _rename_arg_( self._ops, x, cache_var, begin_idx=i) self._program.block(block_desc.id).var( str(x)).desc = self._find_var( block_desc, cache_var, is_forward) self._update_graph( x, cache_var, begin_idx=i) break in_diff, out_diff = self._get_diff(self._live_in[i], self._live_out[i]) can_optimize = filter( lambda x: check_var_validity(block_desc, x, is_forward), in_diff) if can_optimize: for var_name in can_optimize: self.pool.append((var_name, self._find_var( block_desc, var_name, is_forward).shape())) def get_cfgs(input_program): ops_list = [] pdesc = input_program.get_desc() block_desc = pdesc.block(0) op_size = block_desc.op_size() # Get global block ops ops_list.append( ([block_desc.op(i) for i in range(op_size)], op_size, set())) while_sub_block_ids = [] while_grad_sub_block_ids = [] while_op_output = set() while_block_id_pair = [] for i in range(op_size): op = block_desc.op(i) if op.type() == "while": while_sub_block_ids.append(op.attr("sub_block").id) while_op_output.update(op.output_arg_names()) elif op.type() == "while_grad": while_grad_sub_block_ids.append(op.attr("sub_block").id) while_op_output.update(op.output_arg_names()) # Find while/while_grad block pair for grad_id in while_grad_sub_block_ids: parent_id = pdesc.block(grad_id).parent if parent_id in while_sub_block_ids: while_block_id_pair.append((parent_id, grad_id)) while_sub_block_ids.remove(parent_id) # Get while/while_grad block ops for parent_id, grad_id in while_block_id_pair: while_block_ops = [] while_block = pdesc.block(parent_id) while_block_op_size = while_block.op_size() for i in range(while_block_op_size): while_block_ops.append(while_block.op(i)) while_grad_block = pdesc.block(grad_id) while_grad_block_op_size = while_grad_block.op_size() for i in range(while_grad_block_op_size): while_block_ops.append(while_grad_block.op(i)) ops_list.append((while_block_ops, while_block_op_size, while_op_output)) # Process rest while block ops for parent_id in while_sub_block_ids: while_block_ops = [] while_block = pdesc.block(parent_id) while_block_op_size = while_block.op_size() for i in range(while_block_op_size): while_block_ops.append(while_block.op(i)) ops_list.append((while_block_ops, while_block_op_size)) cfgs = [ControlFlowGraph(input_program, i, j, k) for i, j, k in ops_list] return cfgs def memory_optimize(input_program): cfgs = get_cfgs(input_program) for cfg in cfgs: cfg.memory_optimize()