benchmark_moe.py

# SPDX-License-Identifier: Apache-2.0

import argparse
import time
from datetime import datetime
from itertools import product
from typing import Any, Dict, List, Tuple, 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 = torch.float8_e4m3fnuz if current_platform.is_rocm(
) else torch.float8_e4m3fn


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,
    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:
        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,
                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_mn_range = [16, 32, 64, 128, 256]
    block_k_range = [16, 32, 64, 128, 256]
    if not use_fp16:
        block_k_range.remove(16)  # BLOCK_K=16 not supported for fp8
    num_warps_range = [1, 2, 4, 8]
    group_m_range = [1, 4, 8, 16, 32]
    num_stage_range = [2]
    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_mn_range,
        "BLOCK_SIZE_N": block_mn_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
        
    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, 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)
    return configs


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

        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")
        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,
    ) -> 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)
        if op_config is None:
            config = get_default_config(num_tokens,
                                        num_experts,
                                        shard_intermediate_size,
                                        hidden_size,
                                        topk,
                                        dtype_str,
                                        is_marlin=False)
        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)
        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]],
        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)

        with torch.cuda.device(self.device_id):
            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,
                                                   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:
    
    if "num_ldmatrixes" not in config:
        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"],
            **({
            "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 {}),
        }
    else:
        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"],
            **({
            "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, 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, 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 main(args: argparse.Namespace):
    print(args)

    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] ==  "DeepseekV2ForCausalLM" or "DeepseekV3ForCausalLM":
        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
    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, 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, 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, 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)
                          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", type=bool, default=True)
    parser.add_argument("--trust-remote-code", action="store_true")
    parser.add_argument("--moe-ep-size", type=int, default=1)
    parser.add_argument("--num-gpus", type=int, default=1)
    args = parser.parse_args()

    main(args)