benchmark_moe.py

# SPDX-License-Identifier: Apache-2.0

import argparse
import json
import time
from contextlib import nullcontext
from datetime import datetime
from itertools import product
from typing import Any, TypedDict

import ray
import torch
import triton
from ray.experimental.tqdm_ray import tqdm
from transformers import AutoConfig

from vllm.model_executor.layers.fused_moe.fused_moe import *
from vllm.platforms import current_platform
from vllm.utils import FlexibleArgumentParser

FP8_DTYPE = current_platform.fp8_dtype()


class BenchmarkConfig(TypedDict):
    BLOCK_SIZE_M: int
    BLOCK_SIZE_N: int
    BLOCK_SIZE_K: int
    GROUP_SIZE_M: int
    num_warps: int
    num_stages: int
    num_ldmatrixes: Optional[int]


def benchmark_config(
    config: BenchmarkConfig,
    num_tokens: int,
    num_experts: int,
    shard_intermediate_size: int,
    hidden_size: int,
    topk: int,
    dtype: torch.dtype,
    use_fp8_w8a8: bool,
    use_int8_w8a16: bool,
    num_iters: int = 100,
    block_quant_shape: List[int] = None,
    nn_moe: Optional[bool] = False,
    moe_ep_size: int = 1,
) -> float:
    init_dtype = torch.float16 if use_fp8_w8a8 else dtype
    x = torch.randn(num_tokens, hidden_size, dtype=dtype)
    if use_int8_w8a16:
        if not nn_moe:
            w1 = torch.randint(-127,
                            127, (
                                num_experts,
                                shard_intermediate_size,
                                hidden_size,
                            ),
                            dtype=torch.int8)
            w2 = torch.randint(-127,
                            127, (
                                num_experts,
                                hidden_size,
                                shard_intermediate_size // 2,
                            ),
                            dtype=torch.int8)
        else:
            w1 = torch.randint(-127,
                            127, (
                                num_experts,
                                hidden_size,
                                shard_intermediate_size
                            ),
                            dtype=torch.int8)
            w2 = torch.randint(-127,
                            127, (
                                num_experts,
                                shard_intermediate_size // 2,
                                hidden_size
                            ),
                            dtype=torch.int8)
    else:
        if not nn_moe:
            w1 = torch.randn(num_experts,
                            shard_intermediate_size,
                            hidden_size,
                            dtype=init_dtype)
            w2 = torch.randn(num_experts,
                            hidden_size,
                            shard_intermediate_size // 2,
                            dtype=init_dtype)
        else:
            w1 = torch.randn(num_experts,
                             hidden_size,
                            shard_intermediate_size,
                            dtype=init_dtype)
            w2 = torch.randn(num_experts,
                             shard_intermediate_size // 2,
                            hidden_size,
                            dtype=init_dtype)
    gating_output = torch.randn(num_iters,
                                num_tokens,
                                num_experts,
                                dtype=torch.float32)

    w1_scale = None
    w2_scale = None
    a1_scale = None
    a2_scale = None
    if use_int8_w8a16:
        w1_scale = torch.randn((num_experts, 2 * shard_intermediate_size),
                               dtype=torch.float32)
        w2_scale = torch.randn((hidden_size, num_experts), dtype=torch.float32)
    if use_fp8_w8a8:
        if block_quant_shape:
            block_n, block_k = block_quant_shape[0], block_quant_shape[1]
            E = num_experts
            N = shard_intermediate_size // 2
            K = hidden_size
            factor_for_scale = 1e-2
            n_tiles_w1 = (2 * N + block_n - 1) // block_n
            n_tiles_w2 = (K + block_n - 1) // block_n
            k_tiles_w1 = (K + block_k - 1) // block_k
            k_tiles_w2 = (N + block_k - 1) // block_k
            w1_scale = torch.rand((E, n_tiles_w1, k_tiles_w1),
                                  dtype=torch.float32) * factor_for_scale
            w2_scale = torch.rand((E, n_tiles_w2, k_tiles_w2),
                                  dtype=torch.float32) * factor_for_scale
        else:
            w1_scale = torch.randn(num_experts, dtype=torch.float32)
            w2_scale = torch.randn(num_experts, dtype=torch.float32)

        a1_scale = torch.randn(1, dtype=torch.float32)
        a2_scale = torch.randn(1, dtype=torch.float32)

        w1 = w1.to(FP8_DTYPE)
        w2 = w2.to(FP8_DTYPE)

    input_gating = torch.empty(num_tokens, num_experts, dtype=torch.float32)

    def prepare(i: int):
        input_gating.copy_(gating_output[i])

    def run():
        from vllm.model_executor.layers.fused_moe import override_config
        with override_config(config):
            fused_moe(
                x,
                w1,
                w2,
                input_gating,
                topk,
                renormalize=True,
                inplace=True,
                use_fp8_w8a8=use_fp8_w8a8,
                use_int8_w8a16=use_int8_w8a16,
                w1_scale=w1_scale,
                w2_scale=w2_scale,
                a1_scale=a1_scale,
                a2_scale=a2_scale,
                block_shape=block_quant_shape,
                use_nn_moe=nn_moe,
                moe_ep_size=moe_ep_size,
                start_expert=0,
                end_expert=num_experts,
            )

    # JIT compilation & warmup
    run()
    torch.cuda.synchronize()

    # Capture 10 invocations with CUDA graph
    graph = torch.cuda.CUDAGraph()
    with torch.cuda.graph(graph):
        for _ in range(10):
            run()
    torch.cuda.synchronize()

    # Warmup
    for _ in range(5):
        graph.replay()
        # run()
    torch.cuda.synchronize()

    start_event = torch.cuda.Event(enable_timing=True)
    end_event = torch.cuda.Event(enable_timing=True)

    latencies: list[float] = []
    for i in range(num_iters):
        prepare(i)
        torch.cuda.synchronize()

        start_event.record()
        graph.replay()
        # run()
        end_event.record()
        end_event.synchronize()
        latencies.append(start_event.elapsed_time(end_event))
    avg = sum(latencies) / (num_iters * 10) * 1000  # us
    graph.reset()
    return avg


def get_rocm_tuning_space(use_fp16, nn_moe: Optional[bool] = False):
    block_m_range = [16, 32, 64, 128, 256]
    block_n_range = [32, 64, 128, 256]
    block_k_range = [32, 64, 128, 256]
    if not use_fp16:
        block_k_range.remove(16)  # BLOCK_K=16 not supported for fp8
    num_warps_range = [2, 4, 8]
    group_m_range = [1, 16, 32, 64]
    num_stage_range = [2, 3, 4, 5]
    # waves_per_eu_range = [0]
    # matrix_instr_nonkdim_range = [16, 32] if use_fp16 else []
    # kpack_range = [1, 2] if use_fp16 else []

    param_ranges = {
        "BLOCK_SIZE_M": block_m_range,
        "BLOCK_SIZE_N": block_n_range,
        "BLOCK_SIZE_K": block_k_range,
        "GROUP_SIZE_M": group_m_range,
        "num_warps": num_warps_range,
        "num_stages": num_stage_range,
        # "waves_per_eu": waves_per_eu_range,
    }
    if nn_moe:
        param_ranges["num_ldmatrixes"] = [1]
    
    # DCU currently does not support the following parameters
    # if use_fp16:
    #     param_ranges["matrix_instr_nonkdim"] = matrix_instr_nonkdim_range
    #     param_ranges["kpack"] = kpack_range

    return param_ranges


def get_configs_compute_bound(use_fp16,
                              block_quant_shape, nn_moe: Optional[bool] = False) -> list[dict[str, int]]:
    configs: list[BenchmarkConfig] = []

    if current_platform.is_rocm():
        param_ranges = get_rocm_tuning_space(use_fp16, nn_moe)
    else:
        # Reduced search space for faster tuning.
        # TODO(woosuk): Increase the search space and use a performance model to
        # prune the search space.
        block_m_range = [16, 32, 64, 128, 256]
        block_n_range = [32, 64, 128, 256]
        block_k_range = [64, 128, 256]
        num_warps_range = [4, 8]
        group_m_range = [1, 16, 32, 64]
        num_stage_range = [2, 3, 4, 5]

        param_ranges = {
            "BLOCK_SIZE_M": block_m_range,
            "BLOCK_SIZE_N": block_n_range,
            "BLOCK_SIZE_K": block_k_range,
            "GROUP_SIZE_M": group_m_range,
            "num_warps": num_warps_range,
            "num_stages": num_stage_range,
        }

    keys, values = zip(*param_ranges.items())
    for config_values in product(*values):
        config = dict(zip(keys, config_values))
        configs.append(config)

    # Remove configs that are not compatible with fp8 block quantization
    # BLOCK_SIZE_K must be a multiple of block_k
    # BLOCK_SIZE_N must be a multiple of block_n
    if block_quant_shape is not None and not use_fp16:
        block_n, block_k = block_quant_shape[0], block_quant_shape[1]
        for config in configs[:]:
            if config["BLOCK_SIZE_K"] % block_k != 0 or config[
                    "BLOCK_SIZE_N"] % block_n != 0:
                configs.remove(config)
    return configs


def prune_rocm_search_space(num_tokens, shard_intermediate_size, hidden_size,
                            search_space, is_fp16, topk):
    N1, K1 = shard_intermediate_size, hidden_size
    N2, K2 = hidden_size, shard_intermediate_size // 2
    pruned_space_1 = prune_rocm_configs(num_tokens * topk, N1, K1,
                                        search_space, is_fp16)
    pruned_space_2 = prune_rocm_configs(num_tokens * topk, N2, K2,
                                        search_space, is_fp16)
    search_space = merge_unique_dicts(pruned_space_1, pruned_space_2)
    return search_space


# The following code is inspired by ROCm/Triton GEMM tuning script:
# https://github.com/ROCm/triton/blob/triton-mlir/scripts/amd/gemm/tune_gemm.py#L89
def prune_rocm_configs(M, N, K, configs, is_fp16=True):
    pruned_configs = []
    elemBytes_a = 2 if is_fp16 else 1
    elemBytes_b = 2 if is_fp16 else 1

    mfma = 16 if M < 32 or N < 32 else 32

    # TODO (zhanglx): figure out the boundary between large and small gemms
    large_gemm = False
    if M >= 2048 and N >= 2048:
        large_gemm = True

    for config in configs:
        BLOCK_SIZE_M = config.get("BLOCK_SIZE_M")
        BLOCK_SIZE_N = config.get("BLOCK_SIZE_N")
        BLOCK_SIZE_K = config.get("BLOCK_SIZE_K")
        num_warps = config.get("num_warps")

        # DCU currently does not support matrix_instr_nonkdim param
        # if is_fp16:
        #     matrix_instr_nonkdim = config.get("matrix_instr_nonkdim")
        #     if matrix_instr_nonkdim > mfma:
        #         continue
        if mfma == 4 and BLOCK_SIZE_K < 64:
            continue
        # some layouts could not work properly in case
        # number elements per thread is less 1
        if BLOCK_SIZE_M * BLOCK_SIZE_N < 64:
            continue
        SPLIT_K = config.get("SPLIT_K", 1)
        GROUP_M = config.get("GROUP_SIZE_M")

        # DCU currently does not support matrix_instr_nonkdim param
        # if is_fp16:
        #     if (matrix_instr_nonkdim > BLOCK_SIZE_M
        #             or matrix_instr_nonkdim > BLOCK_SIZE_N):
        #         continue
        #     if (matrix_instr_nonkdim >= M
        #             and matrix_instr_nonkdim != BLOCK_SIZE_M):
        #         continue
        #     if (matrix_instr_nonkdim >= N
        #             and matrix_instr_nonkdim != BLOCK_SIZE_N):
        #         continue
        # Skip BLOCK_SIZE that is too large compare to M/N
        # unless BLOCK_SIZE is already small enough
        if M * 2 < BLOCK_SIZE_M and BLOCK_SIZE_M != 16:
            continue
        if N * 2 < BLOCK_SIZE_N and BLOCK_SIZE_N != 16:
            continue
        # skip large split_k when not necessary
        if SPLIT_K != 1 and not need_split_k(M, N, K):
            continue
        # skip split_k that leads to EVEN_K = false
        leap = SPLIT_K * BLOCK_SIZE_K
        modv = K % leap
        if modv != 0:
            continue
        # skip large GROUP_M
        if GROUP_M * BLOCK_SIZE_M > M and GROUP_M != 1:
            continue
        # out of shared memory resource
        # TODO (zhanglx): This does not consider the LDS usage in the epilogue
        LDS = (BLOCK_SIZE_K * BLOCK_SIZE_M * elemBytes_a +
               BLOCK_SIZE_K * BLOCK_SIZE_N * elemBytes_b)
        if LDS > 65536:
            continue
        # Skip small block sizes and num_warps for large gemm
        # For fp16 and f8, we want to only use BLOCK_SIZE >= 64
        if large_gemm:
            if BLOCK_SIZE_M < 64 or BLOCK_SIZE_N < 64:
                continue
            if BLOCK_SIZE_K < 64:
                continue
            if num_warps < 4:
                continue

        pruned_configs.append(config)

    return pruned_configs


def need_split_k(SIZE_M, SIZE_N, SIZE_K):
    return (SIZE_M < 64 or SIZE_N < 64) and SIZE_K > 1024


def merge_unique_dicts(list1, list2):
    result = []
    combined_list = list1.copy()
    combined_list.extend(list2)
    for dictionary in combined_list:
        if dictionary not in result:
            result.append(dictionary)
    return result


@ray.remote(num_gpus=1)
class BenchmarkWorker:

    def __init__(self, seed: int, device_id: int) -> None:
        torch.set_default_device("cuda:"+ str(device_id))
        current_platform.seed_everything(seed)
        self.seed = seed
        # Get the device ID to allocate tensors and kernels
        # on the respective GPU. This is required for Ray to work
        # correctly with multi-GPU tuning on the ROCm platform.
        self.device_id = device_id

    def benchmark(
        self,
        num_tokens: int,
        num_experts: int,
        shard_intermediate_size: int,
        hidden_size: int,
        topk: int,
        dtype: torch.dtype,
        use_fp8_w8a8: bool,
        use_int8_w8a16: bool,
        block_quant_shape: List[int] = None,
        nn_moe: Optional[bool] = False,
        moe_ep_size: Optional[int] = 1,
    ) -> tuple[dict[str, int], float]:
        current_platform.seed_everything(self.seed)
        dtype_str = get_config_dtype_str(dtype,
                                         use_int8_w8a16=use_int8_w8a16,
                                         use_fp8_w8a8=use_fp8_w8a8)
        # NOTE(woosuk): The current naming convention uses w2.shape[2], which
        # is the intermediate size after silu_and_mul.
        op_config = get_moe_configs(num_experts, shard_intermediate_size // 2,
                                    dtype_str, use_nn_moe=nn_moe)
        if op_config is None:
            config = get_default_config(num_tokens,
                                        num_experts,
                                        shard_intermediate_size,
                                        hidden_size,
                                        topk,
                                        dtype_str,
                                        is_marlin=False,
                                        use_nn_moe=nn_moe)
        else:
            config = op_config[min(op_config.keys(),
                                   key=lambda x: abs(x - num_tokens))]
        kernel_time = benchmark_config(config,
                                       num_tokens,
                                       num_experts,
                                       shard_intermediate_size,
                                       hidden_size,
                                       topk,
                                       dtype,
                                       use_fp8_w8a8,
                                       use_int8_w8a16,
                                       num_iters=100,
                                       block_quant_shape=block_quant_shape,
                                       nn_moe=nn_moe,
                                       moe_ep_size=moe_ep_size)
        return config, kernel_time

    def tune(
        self,
        num_tokens: int,
        num_experts: int,
        shard_intermediate_size: int,
        hidden_size: int,
        topk: int,
        dtype: torch.dtype,
        use_fp8_w8a8: bool,
        use_int8_w8a16: bool,
        search_space: list[dict[str, int]],
        block_quant_shape: list[int],
        nn_moe: Optional[bool] = False,
        moe_ep_size: Optional[int] = 1,
    ) -> dict[str, int]:
        best_config = None
        best_time = float("inf")
        if current_platform.is_rocm():
            is_fp16 = not (use_fp8_w8a8 or use_int8_w8a16)
            search_space = prune_rocm_search_space(num_tokens,
                                                   shard_intermediate_size,
                                                   hidden_size, search_space,
                                                   is_fp16, topk)

        with torch.cuda.device(self.device_id) if current_platform.is_rocm(
        ) else nullcontext():
            for config in tqdm(search_space):
                try:
                    kernel_time = benchmark_config(
                        config,
                        num_tokens,
                        num_experts,
                        shard_intermediate_size,
                        hidden_size,
                        topk,
                        dtype,
                        use_fp8_w8a8,
                        use_int8_w8a16,
                        num_iters=20,
                        block_quant_shape=block_quant_shape,
                        nn_moe=nn_moe,
                        moe_ep_size=moe_ep_size)
                except triton.runtime.autotuner.OutOfResources:
                    # Some configurations may be invalid and fail to compile.
                    continue

                if kernel_time < best_time:
                    best_time = kernel_time
                    best_config = config
        now = datetime.now()
        print(f"{now.ctime()}] Completed tuning for batch_size={num_tokens}")
        assert best_config is not None
        return best_config


def sort_config(config: BenchmarkConfig) -> BenchmarkConfig:

    return {
            "BLOCK_SIZE_M": 
            config["BLOCK_SIZE_M"],
            "BLOCK_SIZE_N": 
            config["BLOCK_SIZE_N"],
            "BLOCK_SIZE_K": 
            config["BLOCK_SIZE_K"],
            "GROUP_SIZE_M": 
            config["GROUP_SIZE_M"],
            "num_warps": 
            config["num_warps"],
            "num_stages": 
            config["num_stages"],
            **({
            "num_ldmatrixes": config["num_ldmatrixes"]
            } if "num_ldmatrixes" in config else {}),
            **({
            "waves_per_eu": config["waves_per_eu"]
            } if "waves_per_eu" in config else {}),
            **({
                "matrix_instr_nonkdim": config["matrix_instr_nonkdim"]
            } if "matrix_instr_nonkdim" in config else {}),
            **({
                "kpack": config["kpack"]
            } if "kpack" in config else {}),
        }


def save_configs(configs: dict[int, BenchmarkConfig], num_experts: int,
                 shard_intermediate_size: int, hidden_size: int, topk: int,
                 dtype: torch.dtype, use_fp8_w8a8: bool, use_int8_w8a16: bool,
                 block_quant_shape: List[int], use_nn_moe: Optional[bool] = False) -> None:
    dtype_str = get_config_dtype_str(dtype,
                                     use_int8_w8a16=use_int8_w8a16,
                                     use_fp8_w8a8=use_fp8_w8a8)

    # NOTE(woosuk): The current naming convention uses w2.shape[2], which
    # is the intermediate size after silu_and_mul.
    filename = get_config_file_name(num_experts, shard_intermediate_size // 2,
                                    dtype_str, block_quant_shape, use_nn_moe=use_nn_moe)

    print(f"Writing best config to {filename}...")
    with open(filename, "w") as f:
        json.dump(configs, f, indent=4)
        f.write("\n")


def get_weight_block_size_safety(config, default_value=None):

    quantization_config = getattr(config, 'quantization_config', {})
    if isinstance(quantization_config, dict):
        return quantization_config.get('weight_block_size', default_value)
    return default_value


def main(args: argparse.Namespace):
    print(args)
    
    block_quant_shape = None

    moe_ep_size = args.moe_ep_size
    tp_size = args.tp_size
    if moe_ep_size > 1:
        tp_size = tp_size // moe_ep_size

    config = AutoConfig.from_pretrained(
        args.model, trust_remote_code=args.trust_remote_code)
    if config.architectures[0] == "DbrxForCausalLM":
        E = config.ffn_config.moe_num_experts
        E = E // moe_ep_size
        topk = config.ffn_config.moe_top_k
        intermediate_size = config.ffn_config.ffn_hidden_size
        shard_intermediate_size = 2 * intermediate_size // tp_size
    elif config.architectures[0] == "JambaForCausalLM":
        E = config.num_experts
        E = E // moe_ep_size
        topk = config.num_experts_per_tok
        intermediate_size = config.intermediate_size
        shard_intermediate_size = 2 * intermediate_size // tp_size
    elif (config.architectures[0] == "DeepseekV3ForCausalLM"
          or config.architectures[0] == "DeepseekV2ForCausalLM"):
        E = config.n_routed_experts
        E = E // moe_ep_size
        topk = config.num_experts_per_tok
        intermediate_size = config.moe_intermediate_size
        shard_intermediate_size = 2 * intermediate_size // tp_size
    elif config.architectures[0] == "Qwen2MoeForCausalLM":
        E = config.num_experts
        E = E // moe_ep_size
        topk = config.num_experts_per_tok
        intermediate_size = config.moe_intermediate_size
        shard_intermediate_size = 2 * intermediate_size // tp_size
        block_quant_shape = get_weight_block_size_safety(config)
    elif config.architectures[0] == "Qwen2MoeForCausalLM":
        E = config.num_experts
        topk = config.num_experts_per_tok
        intermediate_size = config.moe_intermediate_size
        shard_intermediate_size = 2 * intermediate_size // args.tp_size
    else:
        # Default: Mixtral.
        E = config.num_local_experts
        E = E // moe_ep_size
        topk = config.num_experts_per_tok
        intermediate_size = config.intermediate_size
        shard_intermediate_size = 2 * intermediate_size // tp_size

    hidden_size = config.hidden_size
    dtype = torch.float16 if current_platform.is_rocm() else config.torch_dtype
    use_fp8_w8a8 = args.dtype == "fp8_w8a8"
    use_int8_w8a16 = args.dtype == "int8_w8a16"

    if args.batch_size is None:
        batch_sizes = [
            1, 2, 4, 8, 16, 24, 32, 48, 64, 96, 128, 256, 512, 1024, 1536,
            2048, 3072, 4096
        ]
    else:
        batch_sizes = [args.batch_size]

    ray.init(address=None,
                 ignore_reinit_error=True,
                 num_gpus=args.num_gpus)
    num_gpus = int(ray.available_resources()["GPU"])
    workers = [BenchmarkWorker.remote(args.seed, i) for i in range(num_gpus)]

    def _distribute(method: str, inputs: list[Any]) -> list[Any]:
        outputs = []
        worker_idx = 0
        for input_args in inputs:
            worker = workers[worker_idx]
            worker_method = getattr(worker, method)
            output = worker_method.remote(*input_args)
            outputs.append(output)
            worker_idx = (worker_idx + 1) % num_gpus
        return ray.get(outputs)

    if args.tune:
        is_fp16 = not (use_fp8_w8a8 or use_int8_w8a16)
        search_space = get_configs_compute_bound(is_fp16, block_quant_shape, args.nn_moe)
        print(f"Start tuning over {len(search_space)} configurations...")

        start = time.time()
        configs = _distribute(
            "tune",
            [(batch_size, E, shard_intermediate_size, hidden_size, topk, dtype,
              use_fp8_w8a8, use_int8_w8a16, search_space, block_quant_shape, args.nn_moe, moe_ep_size)
             for batch_size in batch_sizes])
        best_configs = {
            M: sort_config(config)
            for M, config in zip(batch_sizes, configs)
        }
        save_configs(best_configs, E, shard_intermediate_size, hidden_size,
                     topk, dtype, use_fp8_w8a8, use_int8_w8a16,
                     block_quant_shape, use_nn_moe=args.nn_moe)
        end = time.time()
        print(f"Tuning took {end - start:.2f} seconds")
    else:
        outputs = _distribute(
            "benchmark",
            [(batch_size, E, shard_intermediate_size, hidden_size, topk, dtype,
              use_fp8_w8a8, use_int8_w8a16, block_quant_shape, args.nn_moe, moe_ep_size)
             for batch_size in batch_sizes])

        for batch_size, (config, kernel_time) in zip(batch_sizes, outputs):
            print(f"Batch size: {batch_size}, config: {config}")
            print(f"Kernel time: {kernel_time:.2f} us")


if __name__ == "__main__":
    parser = FlexibleArgumentParser()
    parser.add_argument("--model",
                        type=str,
                        default="mistralai/Mixtral-8x7B-Instruct-v0.1")
    parser.add_argument("--tp-size",
                        "-tp",
                        "--tensor-parallel-size",
                        type=int,
                        default=2)
    parser.add_argument("--dtype",
                        type=str,
                        choices=["auto", "fp8_w8a8", "int8_w8a16"],
                        default="auto")
    parser.add_argument("--seed", type=int, default=0)
    parser.add_argument("--batch-size", type=int, required=False)
    parser.add_argument("--tune", action="store_true")
    parser.add_argument("--nn-moe", action='store_true', default=False)
    parser.add_argument("--trust-remote-code", action="store_true")
    parser.add_argument("--moe-ep-size", "-ep", type=int, default=1)
    parser.add_argument("--num-gpus", type=int, default=1)
    args = parser.parse_args()

    main(args)