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paddlepaddle--paddle/python/paddle/distributed/auto_parallel/static/cost/estimate_cost.py
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2026-07-13 12:40:42 +08:00

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Python

# Copyright (c) 2022 PaddlePaddle Authors. All Rights Reserved.
#
# 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 OrderedDict
from functools import reduce
import paddle
from paddle.distributed.fleet.meta_optimizers.common import OpRole
from ..dist_tensor import DistributedTensor
from ..operators.common import get_distributed_operator_impl_container
from .base_cost import Cost
class CostEstimator:
_special_op_type = ["fused_attention", "fused_feedforward"]
def __init__(
self, program, cluster, mode="modeling", rank=None, loop_count=10
):
self._program = program
self._cluster = cluster
self._check_mode(mode)
self._mode = mode
self._rank = rank if rank is not None else paddle.distributed.get_rank()
self._loop_count = loop_count
self._global_cost = Cost()
self._local_cost_mapping = {}
self._detailed_cost = OrderedDict() # {`op_id`: {"reshard": [], "dist_op": [], "local_cost": local_cost}}}
self._bubble_time_mapping = {}
self._ordered_ops = []
self.max_memories = {}
self.max_memory = None
@property
def loop_count(self):
return self._loop_count
@property
def detailed_cost(self):
return self._detailed_cost
@property
def program(self):
return self._program
@property
def rank(self):
return self._rank
@property
def dist_context(self):
return self._dist_context
@property
def cluster(self):
return self._cluster
@property
def mode(self):
return self._mode
@property
def global_cost(self):
max_time = 0
memory = 0
flops = 0
for rank in self._local_cost_mapping:
cost = self._local_cost_mapping[rank]
if cost.time > max_time:
max_time = cost.time
memory += cost.memory
flops += cost.flops
self._global_cost.time = max_time
self._global_cost.memory = memory
self._global_cost.flops = flops
return self._global_cost
def local_cost(self, rank=None):
rank = self.rank if rank is None else rank
if rank not in self._local_cost_mapping:
self._local_cost_mapping[rank] = Cost()
return self._local_cost_mapping[rank]
def local_bubble_time(self, rank=None):
rank = self.rank if rank is None else rank
return self._bubble_time_mapping[rank]
def _check_mode(self, mode):
if mode not in ["modeling", "profiling"]:
raise ValueError(
f"Just support modeling and profiling, but got {mode}"
)
def _is_special_var_name(self, var_name):
special_var_name = ["lod_tensor_blocking_queue_0"]
if var_name in special_var_name:
return True
return False
def _estimate_core(self, dist_context, resharder, block):
from ..reshard import get_var_with_recursion
ops = block.ops
loop_count = None
if block.desc.id != self.program.global_block().desc.id:
loop_count = self.loop_count
else:
loop_count = 1
for i in range(loop_count):
for op in ops:
self._detailed_cost[op.desc.id()] = OrderedDict()
# If in the while sub block, the detail of cost is the last cost
detail = self._detailed_cost[op.desc.id()]
detail["reshard_cost"] = OrderedDict() #
detail["dist_op_cost"] = []
if int(op.attr('op_role')) == int(OpRole.Optimize):
continue
if op.type in [
"create_py_reader",
"create_double_buffer_reader",
"read",
]:
continue
# NOTE: It does not support nested loop and just supports while op when op has sub block now.
if op.type == "while":
while_block = self.program.blocks[op.attr("sub_block").id]
self._estimate_core(dist_context, resharder, while_block)
continue
for var_name in op.input_arg_names:
if self._is_special_var_name(var_name):
continue
var = get_var_with_recursion(var_name, block, self.program)
reshard_cost = resharder.get_cost(op, var, self.cluster)
# Calc reshard cost
if reshard_cost is not None:
detail["reshard_cost"][var_name] = reshard_cost
comm_costs = reshard_cost[0]
local_comp_cost = reshard_cost[1]
for comm_cost in comm_costs:
# Time is cumulative in global cost and local cost, but memory and flops just are cumulative in global cost.
# Comm sync
for item in comm_cost:
group_ranks, cost = item
max_time = None
cost_time = {}
for rank in group_ranks:
rank_cost = self.local_cost(rank)
cost_time[rank] = rank_cost.time
if max_time is None:
max_time = rank_cost.time
else:
if max_time < rank_cost.time:
max_time = rank_cost.time
for rank in group_ranks:
self.local_cost(rank).time = (
max_time + cost.time
)
if rank not in self._bubble_time_mapping:
self._bubble_time_mapping[rank] = 0
self._bubble_time_mapping[rank] += (
max_time - cost_time[rank]
)
for rank in local_comp_cost:
for comp_cost in local_comp_cost[rank]:
self.local_cost(rank).time += comp_cost.time
# Calc dist op cost
dist_op = dist_context.get_dist_op_for_program(op)
if not dist_op:
continue
op_dist_attr = dist_op.dist_attr
processes = op_dist_attr.process_mesh.process_ids
container = get_distributed_operator_impl_container(
op_dist_attr.impl_type
)
dist_impl = container.impls[op_dist_attr.impl_idx]
dist_op_cost = dist_impl.calc_cost(
op.attr('op_role'), dist_op, dist_context, self.cluster
)
detail["dist_op_cost"] = dist_op_cost
if dist_op_cost is None:
assert (
dist_op.serial_op.type in CostEstimator._special_op_type
)
continue
for item in dist_op_cost:
if isinstance(item, list):
# Comm sync
for comm_op_cost in item:
max_time = None
cost_time = {}
group_ranks = comm_op_cost.group_ranks
for rank in comm_op_cost.group_ranks:
rank_cost = self.local_cost(rank)
cost_time[rank] = rank_cost.time
if max_time is None:
max_time = rank_cost.time
else:
if max_time < rank_cost.time:
max_time = rank_cost.time
for rank in group_ranks:
self.local_cost(rank).time = (
max_time + comm_op_cost.time
if op.attr('op_role') != OpRole.Backward
else max_time + 0.9 * comm_op_cost.time
)
if rank not in self._bubble_time_mapping:
self._bubble_time_mapping[rank] = 0
self._bubble_time_mapping[rank] += (
max_time - cost_time[rank]
)
elif isinstance(item, dict):
# Op just one
for rank in processes:
# DP+PP+MP
if rank not in item:
continue
self.local_cost(rank).time += item[rank].time
def prepare(self):
self._global_cost = Cost()
self._local_cost_mapping = {}
self._detailed_cost = OrderedDict()
self._bubble_time_mapping = {}
def _calculate_bytes(self, sizes, dtype):
if sizes:
total_count = reduce(lambda x, y: x * y, sizes, 1)
else:
total_count = 0
if dtype == paddle.float64 or dtype == paddle.int64:
dtype_factor = 8
elif dtype == paddle.float32 or dtype == paddle.int32:
dtype_factor = 4
elif (
dtype == paddle.float16
or dtype == paddle.bfloat16
or dtype == paddle.int16
):
dtype_factor = 2
elif dtype == paddle.int8 or dtype == paddle.uint8:
dtype_factor = 1
else:
dtype_factor = 8
memory = total_count * dtype_factor
return memory
def _estimate_max_memory_by_dist_op(self, dist_context):
# This estimation will be improved, now reshard and inplace are not considered.
# Persist var is not free.
def _convert_pm_and_dm_to_str(process_mesh, dims_mapping):
processes = ",".join([str(x) for x in process_mesh.process_ids])
topology = ",".join([str(x) for x in process_mesh.shape])
dims_mapping = ",".join([str(x) for x in dims_mapping])
result = processes + topology + dims_mapping
return result
memories = {}
self.max_memories = {}
var_info = {} # var_name: [[process_mesh, dims_mapping], [id]], [[process_mesh, dims_mapping], [id]]}
for block in self.program.blocks:
for op in block.ops:
self._ordered_ops.append([op.desc.id(), op])
self._ordered_ops.sort(key=lambda x: x[0])
parameters = set()
for op_id, op in self._ordered_ops:
if op.type in [
"create_py_reader",
"create_double_buffer_reader",
"read",
]:
continue
dist_op = dist_context.get_dist_op_for_program(op)
if not dist_op:
continue
process_mesh = dist_op.dist_attr.process_mesh
for var_name in op.input_arg_names:
input_dims_mapping = dist_op.dist_attr.get_input_dims_mapping(
var_name
)
if var_name not in var_info:
var_info[var_name] = {}
key = _convert_pm_and_dm_to_str(
process_mesh, input_dims_mapping
)
if key not in var_info[var_name]:
var_info[var_name][key] = {}
# It is even partition now
if "position" not in var_info[var_name][key]:
var_info[var_name][key]["position"] = []
var_info[var_name][key]["position"].append(op_id)
if "memory" not in var_info[var_name][key]:
var = dist_op.get_serial_input(var_name)
global_sizes = var.shape
dtype = var.dtype
sizes = DistributedTensor.get_local_sizes(
global_sizes,
input_dims_mapping,
process_mesh.shape,
process_mesh.process_ids,
)
var_info[var_name][key]["memory"] = self._calculate_bytes(
sizes, dtype
)
if var.persistable:
name = var_name + key
if name not in parameters:
parameters.add(name)
for process in process_mesh.process_ids:
if process not in memories:
memories[process] = 0
memories[process] += var_info[var_name][key][
"memory"
]
for var_name in op.output_arg_names:
output_dims_mapping = dist_op.dist_attr.get_output_dims_mapping(
var_name
)
if var_name not in var_info:
var_info[var_name] = {}
key = _convert_pm_and_dm_to_str(
process_mesh, output_dims_mapping
)
if key not in var_info[var_name]:
var_info[var_name][key] = {}
if "position" not in var_info[var_name][key]:
var_info[var_name][key]["position"] = []
var_info[var_name][key]["position"].append(op_id)
if "memory" not in var_info[var_name][key]:
var = dist_op.get_serial_output(var_name)
global_sizes = var.shape
dtype = var.dtype
sizes = DistributedTensor.get_local_sizes(
global_sizes,
output_dims_mapping,
process_mesh.shape,
process_mesh.process_ids,
)
var_info[var_name][key]["memory"] = self._calculate_bytes(
sizes, dtype
)
if var.persistable:
name = var_name + key
if name not in parameters:
parameters.add(name)
for process in process_mesh.process_ids:
if process not in memories:
memories[process] = 0
memories[process] += var_info[var_name][key][
"memory"
]
has_used_vars = set()
not_calc_vars = set()
for op_id, op in self._ordered_ops:
if op.type in [
"create_py_reader",
"create_double_buffer_reader",
"read",
]:
continue
can_free_memories = {}
can_free_vars = set()
dist_op = dist_context.get_dist_op_for_program(op)
if not dist_op:
continue
process_mesh = dist_op.dist_attr.process_mesh
for var_name in op.input_arg_names:
input_dims_mapping = dist_op.dist_attr.get_input_dims_mapping(
var_name
)
key = _convert_pm_and_dm_to_str(
process_mesh, input_dims_mapping
)
has_used_var = var_name + key
var = dist_op.get_serial_input(var_name)
# Not used
if (
has_used_var not in has_used_vars
and has_used_var not in parameters
):
if has_used_var in not_calc_vars:
continue
has_used_vars.add(has_used_var)
for process in process_mesh.process_ids:
if process not in memories:
memories[process] = 0
memories[process] += var_info[var_name][key]["memory"]
# Used
if op_id == var_info[var_name][key]["position"][-1]:
if (
has_used_var not in can_free_vars
and not var.persistable
):
can_free_vars.add(has_used_var)
for process in process_mesh.process_ids:
if process not in can_free_memories:
can_free_memories[process] = 0
can_free_memories[process] += var_info[var_name][
key
]["memory"]
for var_name in op.output_arg_names:
output_dims_mapping = dist_op.dist_attr.get_output_dims_mapping(
var_name
)
key = _convert_pm_and_dm_to_str(
process_mesh, output_dims_mapping
)
has_used_var = var_name + key
var = dist_op.get_serial_output(var_name)
if (
op.type == "reshape2"
or op.type == "transpose2"
or op.type == "elementwise_add"
):
not_calc_vars.add(has_used_var)
continue
# Not used
if (
has_used_var not in has_used_vars
and has_used_var not in parameters
):
has_used_vars.add(has_used_var)
for process in process_mesh.process_ids:
if process not in memories:
memories[process] = 0
memories[process] += var_info[var_name][key]["memory"]
# Used
if op_id == var_info[var_name][key]["position"][-1]:
if (
has_used_var not in can_free_vars
and not var.persistable
):
can_free_vars.add(has_used_var)
for process in process_mesh.process_ids:
if process not in can_free_memories:
can_free_memories[process] = 0
can_free_memories[process] += var_info[var_name][
key
]["memory"]
# Calc peak memory
for process in memories:
if process not in self.max_memories:
self.max_memories[process] = memories[process]
else:
if memories[process] > self.max_memories[process]:
self.max_memories[process] = memories[process]
# Free memory
for process in can_free_memories:
if process in memories:
memories[process] -= can_free_memories[process]
# Calculate the max memory in all ranks
max_memory = max(self.max_memories.values())
self.max_memory = max_memory
return max_memory
def estimate(self, dist_context, resharder=None):
self.prepare()
from ..reshard import Resharder
resharder = (
Resharder(self.program, None, self.rank, dist_context, [])
if resharder is None
else resharder
)
block = self.program.global_block()
self._estimate_core(dist_context, resharder, block)
return self.global_cost
def _print_tag(self, max_len, length):
tag = "+" + "-" * max_len
for i in range(length):
print(tag, end="")
if i == length - 1:
print("+")
def _print_vals(self, vals, max_len):
for idx, val in enumerate(vals):
s = "|" + str(val).center(max_len)
print(s, end="")
if idx == len(vals) - 1:
print("|")
def _pretty_print_memory_cost(self):
"""Print memory of every rank prettily."""
if not self.max_memories or not self.max_memory:
raise ValueError("Please calculate memory cost before print.")
# Padding automatically
max_len = 0
header = ["Rank", "Memory(MiB)"]
memories = [
int(item // 1e6) for item in list(self.max_memories.values())
]
for memory in memories + header:
if len(str(memory)) > max_len:
max_len = len(str(memory))
max_len += 4 # for pretty print of center
# Print tag
self._print_tag(max_len, len(header))
# Print header
self._print_vals(header, max_len)
# Print tag
self._print_tag(max_len, len(header))
# Print rank and its memory
for i in range(len(self.max_memories)):
memory = memories[i]
vals = [i, memory]
self._print_vals(vals, max_len)
self._print_tag(max_len, len(header))
def _pretty_print_global(self):
"""Print global execution time and max memory prettily."""
if not self.max_memories or not self.max_memory:
raise ValueError("Please calculate cost before print.")
# Padding automatically
max_len = 0
header = ["Execution Time(us)", "Max Memory(MiB)"]
vals = [round(self.global_cost.time, 3), int(self.max_memory // 1e6)]
for memory in vals + header:
if len(str(memory)) > max_len:
max_len = len(str(memory))
max_len += 4 # for pretty print of center
# Print tag
self._print_tag(max_len, len(header))
# Print header
self._print_vals(header, max_len)
# Print tag
self._print_tag(max_len, len(header))
# Print exec time and max memory
self._print_vals(vals, max_len)
# Print tag
self._print_tag(max_len, len(header))
def pretty_print_cost(self):
"""Print cost prettily."""
print("The global execution time and max memory are as follows:")
self._pretty_print_global()
print("The memory of every rank is as follows:")
self._pretty_print_memory_cost()
def get_cost_from_engine(engine, mode):
import copy
from ..utils import to_list
# Construct cost estimator by original main program
serial_main_prog = (
engine._fwd_main_progs[mode].clone()
if mode in engine._fwd_main_progs
else engine._orig_main_prog.clone()
)
serial_startup_prog = (
engine._fwd_dist_contexts[mode]._original_serial_main_program.clone()
if mode in engine._fwd_dist_contexts
else engine._orig_startup_prog.clone()
)
losses = (
to_list(engine._loss)
if (
not isinstance(engine._loss, paddle.nn.Layer)
and not callable(engine._loss)
)
else engine._losses
)
serial_optimizer = copy.deepcopy(engine._orig_optimizer)
if mode in engine._fwd_dist_contexts:
dist_context = copy.deepcopy(engine._fwd_dist_contexts[mode])
else:
from ..dist_context import DistributedContext
dist_context = DistributedContext(
serial_main_prog,
serial_startup_prog,
serial_optimizer,
losses,
{},
{"loss": losses},
engine._cluster,
engine._strategy,
)
from ..completion import Completer
completer = Completer(dist_context)
completer.complete_forward_annotation()
dist_context.block_state.parse_forward_blocks(
dist_context.serial_main_program
)
if mode == "eval" or mode == "predict":
cost_estimator = CostEstimator(serial_main_prog, engine._cluster)
elif mode == "train":
from ..parallelizer_v2 import Parallelizer
# Get serial main program with backward
parallelizer = Parallelizer(mode, completer, dist_context)
# Generate backward
loss_name = dist_context.serial_loss.name
serial_loss = serial_main_prog.global_block()._var_recursive(loss_name)
params_grads = parallelizer._generate_backward(
serial_main_prog, serial_startup_prog, serial_loss
)
# Generate optimizer
optimizer_ops = parallelizer._generate_optimizer(
serial_main_prog,
serial_startup_prog,
serial_optimizer,
params_grads,
)
cost_estimator = CostEstimator(serial_main_prog, engine._cluster)
# Estimate global_cost and max memory
global_cost = cost_estimator.estimate(dist_context)
max_memory = cost_estimator._estimate_max_memory_by_dist_op(dist_context)
# Print the cost
cost_estimator.pretty_print_cost()
return global_cost, max_memory