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text2text / verl /single_controller /base /decorator.py
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 # Copyright 2024 Bytedance Ltd. and/or its affiliates
#
# 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.
import inspect
from functools import wraps
from types import FunctionType
from typing import Dict, List, Tuple
from verl.protocol import DataProtoFuture, _padding_size_key
from verl.utils.py_functional import DynamicEnum
# here we add a magic number of avoid user-defined function already have this attribute
MAGIC_ATTR = "attrs_3141562937"
class Dispatch(DynamicEnum):
_registry = {}
_next_value = 0
def init_predefined_dispatch_mode():
Dispatch.register("RANK_ZERO")
Dispatch.register("ONE_TO_ALL")
Dispatch.register("ALL_TO_ALL")
Dispatch.register("MEGATRON_COMPUTE")
Dispatch.register("MEGATRON_PP_AS_DP")
Dispatch.register("MEGATRON_PP_ONLY")
Dispatch.register("MEGATRON_COMPUTE_PROTO")
Dispatch.register("MEGATRON_PP_AS_DP_PROTO")
Dispatch.register("DP_COMPUTE")
Dispatch.register("DP_COMPUTE_PROTO")
Dispatch.register("DP_COMPUTE_PROTO_WITH_FUNC")
Dispatch.register("DP_COMPUTE_METRIC")
# This is a special dispatch mode for vllm ExternalRayDistributedExecutor
Dispatch.register("DIRECT_ROLLOUT_METHOD")
class Execute(DynamicEnum):
_registry = {}
_next_value = 0
def init_predefined_execute_mode():
Execute.register("ALL")
Execute.register("RANK_ZERO")
# Initialize the two Dynamic Enum Classes
init_predefined_dispatch_mode()
init_predefined_execute_mode()
def _split_args_kwargs_data_proto(chunks, *args, **kwargs):
from verl.protocol import DataProto, DataProtoFuture
splitted_args = []
for arg in args:
assert isinstance(arg, (DataProto, DataProtoFuture))
splitted_args.append(arg.chunk(chunks=chunks))
splitted_kwargs = {}
for key, val in kwargs.items():
assert isinstance(val, (DataProto, DataProtoFuture))
splitted_kwargs[key] = val.chunk(chunks=chunks)
return splitted_args, splitted_kwargs
def _split_args_kwargs_data_proto_with_auto_padding(chunks, *args, **kwargs):
from verl.protocol import DataProto, DataProtoFuture
splitted_args = []
splitted_kwargs = {}
data_proto_len = None
padding_size = None
for arg in args:
assert isinstance(arg, (DataProto, DataProtoFuture))
if isinstance(arg, DataProto) and arg.is_padding_enabled():
# for padding, we only support DataProto with same length
if data_proto_len is None:
data_proto_len = len(arg)
padding_size = (chunks - (data_proto_len % chunks)) if (data_proto_len % chunks > 0) else 0
splitted_kwargs[_padding_size_key] = padding_size
else:
assert data_proto_len == len(arg), f"expecting all arg share same length of {data_proto_len}, but got {len(arg)}"
data_proto_len = len(arg)
arg.padding(padding_size=padding_size)
splitted_args.append(arg.chunk(chunks=chunks))
for key, val in kwargs.items():
assert isinstance(val, (DataProto, DataProtoFuture))
if isinstance(val, DataProto) and val.is_padding_enabled():
# for padding, we only support DataProto with same length
if data_proto_len is None:
data_proto_len = len(val)
padding_size = chunks - (data_proto_len % chunks)
splitted_kwargs[_padding_size_key] = padding_size
else:
assert data_proto_len == len(val), f"expecting all arg share same length of {data_proto_len}, but got {len(val)}"
data_proto_len = len(val)
splitted_kwargs[key] = val.chunk(chunks=chunks)
return splitted_args, splitted_kwargs
def dispatch_one_to_all(worker_group, *args, **kwargs):
args = tuple([arg] * worker_group.world_size for arg in args)
kwargs = {k: [v] * worker_group.world_size for k, v in kwargs.items()}
return args, kwargs
def dummy_direct_rollout_call(worker_group, *args, **kwargs):
raise NotImplementedError("Direct rollout call is forbidden.")
def dispatch_all_to_all(worker_group, *args, **kwargs):
return args, kwargs
def collect_all_to_all(worker_group, output):
return output
def dispatch_megatron_compute(worker_group, *args, **kwargs):
"""
User passes in dp data. The data is dispatched to all tp/pp ranks with the same dp
"""
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup), f"worker_group must be MegatronWorkerGroup, Got {type(worker_group)}"
all_args = []
for arg in args:
assert isinstance(arg, (Tuple, List)) and len(arg) == worker_group.dp_size
transformed_args = []
for i in range(worker_group.world_size):
local_dp_rank = worker_group.get_megatron_rank_info(rank=i).dp_rank
transformed_args.append(arg[local_dp_rank])
all_args.append(transformed_args)
all_args = tuple(all_args)
all_kwargs = {}
for k, v in kwargs.items():
assert isinstance(v, (Tuple, List)) and len(v) == worker_group.dp_size
transformed_v = []
for i in range(worker_group.world_size):
local_dp_rank = worker_group.get_megatron_rank_info(rank=i).dp_rank
transformed_v.append(v[local_dp_rank])
all_kwargs[k] = transformed_v
return all_args, all_kwargs
def collect_megatron_compute(worker_group, output):
"""
Only collect the data from the tp=0 and pp=last and every dp ranks
"""
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
output_in_dp = []
pp_size = worker_group.get_megatron_global_info().pp_size
for global_rank in range(worker_group.world_size):
local_rank_info = worker_group.get_megatron_rank_info(rank=global_rank)
if local_rank_info.tp_rank == 0 and local_rank_info.pp_rank == pp_size - 1 and local_rank_info.cp_rank == 0:
output_in_dp.append(output[global_rank])
return output_in_dp
def dispatch_megatron_compute_data_proto(worker_group, *args, **kwargs):
"""
All the args and kwargs must be DataProto. The batch will be chunked by dp_size and passed to each rank
"""
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
splitted_args, splitted_kwargs = _split_args_kwargs_data_proto(worker_group.dp_size, *args, **kwargs)
return dispatch_megatron_compute(worker_group, *splitted_args, **splitted_kwargs)
def _concat_data_proto_or_future(output: List):
import ray
from verl.protocol import DataProto, DataProtoFuture
# make sure all the elements in output has the same type
for o in output:
assert type(o) is type(output[0])
o = output[0]
if isinstance(o, DataProto):
return DataProto.concat(output)
elif isinstance(o, ray.ObjectRef):
return DataProtoFuture.concat(output)
else:
raise NotImplementedError
def collect_megatron_compute_data_proto(worker_group, output):
"""
Each output must be a DataProto. We concat the dim=0 of output
"""
import ray
from verl.protocol import DataProto
output = collect_megatron_compute(worker_group, output)
for o in output:
assert isinstance(o, (DataProto, ray.ObjectRef)), f"expecting {o} to be DataProto, but got {type(o)}"
return _concat_data_proto_or_future(output)
def dispatch_megatron_pp_as_dp(worker_group, *args, **kwargs):
"""
treat pp as dp.
"""
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
pp_size = worker_group.pp_size
dp_size = worker_group.dp_size
cp_size = worker_group.cp_size
pp_dp_cp_size = pp_size * dp_size * cp_size
all_args = []
for arg in args:
assert isinstance(arg, (List, Tuple)) and len(arg) == pp_dp_cp_size
transformed_args = []
for i in range(worker_group.world_size):
local_dp_rank = worker_group.get_megatron_rank_info(rank=i).dp_rank
local_pp_rank = worker_group.get_megatron_rank_info(rank=i).pp_rank
local_cp_rank = worker_group.get_megatron_rank_info(rank=i).cp_rank
# compute the rank in arg. Note that the order is dp then cp then pp
# Also note that the outputs within a pp group will be firstly allgathered, then only the output of pp0 will be collected.
# For pp=2 dp=4, a batch of data "ABCDEFGH" should be dispatched and collected in below order:
# dispatch: pp_allgther: collect:
# dp 0 1 2 3 dp 0 1 2 3
# pp +---------+ pp +-------------+
# 0 | A C E G | 0 | AB CD EF GH | ABCDEFGH
# 1 | B D F H | 1 | AB CD EF GH |
# +---------+ +-------------+
dp_cp_rank = local_cp_rank * dp_size + local_dp_rank
arg_rank = dp_cp_rank * pp_size + local_pp_rank
transformed_args.append(arg[arg_rank])
all_args.append(transformed_args)
all_args = tuple(all_args)
all_kwargs = {}
for k, v in kwargs.items():
assert isinstance(v, (List, Tuple)) and len(v) == pp_dp_cp_size, f"expect len(v)=={pp_dp_cp_size}, got {len(v)}"
transformed_v = []
for i in range(worker_group.world_size):
local_dp_rank = worker_group.get_megatron_rank_info(rank=i).dp_rank
local_pp_rank = worker_group.get_megatron_rank_info(rank=i).pp_rank
local_cp_rank = worker_group.get_megatron_rank_info(rank=i).cp_rank
# compute the rank in arg. Note that the order is dp then cp then pp
dp_cp_rank = local_cp_rank * dp_size + local_dp_rank
arg_rank = dp_cp_rank * pp_size + local_pp_rank
transformed_v.append(v[arg_rank])
all_kwargs[k] = transformed_v
return all_args, all_kwargs
def collect_megatron_pp_as_dp(worker_group, output):
"""
treat pp as dp. Only collect data on tp=0
"""
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
output_in_dp = []
for global_rank in range(worker_group.world_size):
local_rank_info = worker_group.get_megatron_rank_info(rank=global_rank)
if local_rank_info.tp_rank == 0:
output_in_dp.append(output[global_rank])
return output_in_dp
def collect_megatron_pp_only(worker_group, output):
"""
Only collect output of megatron pp. This is useful when examine weight names as they are identical in tp/dp
"""
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
output_in_pp = []
for global_rank in range(worker_group.world_size):
local_rank_info = worker_group.get_megatron_rank_info(rank=global_rank)
if local_rank_info.tp_rank == 0 and local_rank_info.dp_rank == 0:
output_in_pp.append(output[global_rank])
return output_in_pp
def dispatch_megatron_pp_as_dp_data_proto(worker_group, *args, **kwargs):
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
pp_dp_cp_size = worker_group.dp_size * worker_group.pp_size * worker_group.cp_size
splitted_args, splitted_kwargs = _split_args_kwargs_data_proto(pp_dp_cp_size, *args, **kwargs)
ret = dispatch_megatron_pp_as_dp(worker_group, *splitted_args, **splitted_kwargs)
return ret
def collect_megatron_pp_as_dp_data_proto(worker_group, output):
from verl.single_controller.base.megatron.worker_group import MegatronWorkerGroup
assert isinstance(worker_group, MegatronWorkerGroup)
output = collect_megatron_pp_as_dp(worker_group, output)
return _concat_data_proto_or_future(output)
def dispatch_dp_compute(worker_group, *args, **kwargs):
from verl.single_controller.base.worker_group import WorkerGroup
assert isinstance(worker_group, WorkerGroup)
for arg in args:
assert isinstance(arg, (Tuple, List)) and len(arg) == worker_group.world_size
for k, v in kwargs.items():
assert isinstance(v, (Tuple, List)) and len(v) == worker_group.world_size
return args, kwargs
def collect_dp_compute(worker_group, output):
from verl.single_controller.base.worker_group import WorkerGroup
assert isinstance(worker_group, WorkerGroup)
assert len(output) == worker_group.world_size
return output
def dispatch_dp_compute_data_proto(worker_group, *args, **kwargs):
from verl.single_controller.base.worker_group import WorkerGroup
assert isinstance(worker_group, WorkerGroup)
# Note: enable auto padding for dp compute DatapProto
splitted_args, splitted_kwargs = _split_args_kwargs_data_proto_with_auto_padding(
worker_group.world_size,
*args,
**kwargs,
)
return splitted_args, splitted_kwargs
def dispatch_dp_compute_data_proto_with_func(worker_group, *args, **kwargs):
from verl.single_controller.base.worker_group import WorkerGroup
assert isinstance(worker_group, WorkerGroup)
assert isinstance(args[0], FunctionType) # NOTE: The first one args is a function!
splitted_args, splitted_kwargs = _split_args_kwargs_data_proto(worker_group.world_size, *args[1:], **kwargs)
splitted_args_with_func = [[args[0]] * worker_group.world_size] + splitted_args
return splitted_args_with_func, splitted_kwargs
def collect_dp_compute_data_proto(worker_group, output):
import ray
from verl.protocol import DataProto
for o in output:
assert isinstance(o, (DataProto, ray.ObjectRef)), f"expecting {o} to be DataProto, but got {type(o)}"
output = collect_dp_compute(worker_group, output)
return _concat_data_proto_or_future(output)
# Global registry for dispatch mode.
DISPATCH_MODE_FN_REGISTRY = {
Dispatch.ONE_TO_ALL: {
"dispatch_fn": dispatch_one_to_all,
"collect_fn": collect_all_to_all,
},
Dispatch.ALL_TO_ALL: {
"dispatch_fn": dispatch_all_to_all,
"collect_fn": collect_all_to_all,
},
Dispatch.MEGATRON_COMPUTE: {
"dispatch_fn": dispatch_megatron_compute,
"collect_fn": collect_megatron_compute,
},
Dispatch.MEGATRON_PP_AS_DP: {
"dispatch_fn": dispatch_megatron_pp_as_dp,
"collect_fn": collect_megatron_pp_as_dp,
},
Dispatch.MEGATRON_PP_ONLY: {"dispatch_fn": dispatch_one_to_all, "collect_fn": collect_megatron_pp_only},
Dispatch.MEGATRON_COMPUTE_PROTO: {
"dispatch_fn": dispatch_megatron_compute_data_proto,
"collect_fn": collect_megatron_compute_data_proto,
},
Dispatch.MEGATRON_PP_AS_DP_PROTO: {
"dispatch_fn": dispatch_megatron_pp_as_dp_data_proto,
"collect_fn": collect_megatron_pp_as_dp_data_proto,
},
Dispatch.DP_COMPUTE: {"dispatch_fn": dispatch_dp_compute, "collect_fn": collect_dp_compute},
Dispatch.DP_COMPUTE_PROTO: {
"dispatch_fn": dispatch_dp_compute_data_proto,
"collect_fn": collect_dp_compute_data_proto,
},
Dispatch.DP_COMPUTE_PROTO_WITH_FUNC: {
"dispatch_fn": dispatch_dp_compute_data_proto_with_func,
"collect_fn": collect_dp_compute_data_proto,
},
Dispatch.DP_COMPUTE_METRIC: {"dispatch_fn": dispatch_dp_compute_data_proto, "collect_fn": collect_dp_compute},
Dispatch.DIRECT_ROLLOUT_METHOD: {
"dispatch_fn": dummy_direct_rollout_call,
"collect_fn": dummy_direct_rollout_call,
},
}
def get_predefined_dispatch_fn(dispatch_mode):
return DISPATCH_MODE_FN_REGISTRY[dispatch_mode]
def register_dispatch_mode(dispatch_mode_name, dispatch_fn, collect_fn):
"""
Register a new dispatch mode.
"""
dispatch_mode = Dispatch.register(dispatch_mode_name)
_check_dispatch_mode(dispatch_mode)
assert dispatch_mode not in DISPATCH_MODE_FN_REGISTRY, f"dispatch_mode_name {dispatch_mode_name} already exists"
DISPATCH_MODE_FN_REGISTRY[dispatch_mode] = {"dispatch_fn": dispatch_fn, "collect_fn": collect_fn}
def update_dispatch_mode(dispatch_mode, dispatch_fn, collect_fn):
"""
Update the dispatch mode.
"""
_check_dispatch_mode(dispatch_mode)
assert dispatch_mode in DISPATCH_MODE_FN_REGISTRY, f"dispatch_mode {dispatch_mode} not found"
DISPATCH_MODE_FN_REGISTRY[dispatch_mode] = {"dispatch_fn": dispatch_fn, "collect_fn": collect_fn}
def get_predefined_execute_fn(execute_mode):
"""
Note that here we only asks execute_all and execute_rank_zero to be implemented
Leave the choice of how these two functions handle argument 'blocking' to users
"""
predefined_execute_mode_fn = {
Execute.ALL: {"execute_fn_name": "execute_all"},
Execute.RANK_ZERO: {"execute_fn_name": "execute_rank_zero"},
}
return predefined_execute_mode_fn[execute_mode]
def _check_dispatch_mode(dispatch_mode):
assert isinstance(dispatch_mode, (Dispatch, Dict)), f"dispatch_mode must be a Dispatch or a Dict. Got {dispatch_mode}"
if isinstance(dispatch_mode, Dict):
necessary_keys = ["dispatch_fn", "collect_fn"]
for key in necessary_keys:
assert key in dispatch_mode, f"key {key} should be in dispatch_mode if it is a dictionary"
def _check_execute_mode(execute_mode):
assert isinstance(execute_mode, Execute), f"execute_mode must be a Execute. Got {execute_mode}"
def _materialize_futures(*args, **kwargs):
new_args = []
for arg in args:
if isinstance(arg, DataProtoFuture):
arg = arg.get()
# add more type to materialize
new_args.append(arg)
for k, v in kwargs.items():
if isinstance(v, DataProtoFuture):
kwargs[k] = v.get()
new_args = tuple(new_args)
return new_args, kwargs
def register(dispatch_mode=Dispatch.ALL_TO_ALL, execute_mode=Execute.ALL, blocking=True, materialize_futures=True):
_check_dispatch_mode(dispatch_mode=dispatch_mode)
_check_execute_mode(execute_mode=execute_mode)
def decorator(func):
@wraps(func)
def inner(*args, **kwargs):
if materialize_futures:
args, kwargs = _materialize_futures(*args, **kwargs)
return func(*args, **kwargs)
@wraps(func)
async def async_inner(*args, **kwargs):
if materialize_futures:
args, kwargs = _materialize_futures(*args, **kwargs)
return await func(*args, **kwargs)
wrapper = async_inner if inspect.iscoroutinefunction(func) else inner
attrs = {"dispatch_mode": dispatch_mode, "execute_mode": execute_mode, "blocking": blocking}
setattr(wrapper, MAGIC_ATTR, attrs)
return wrapper
return decorator