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# Copyright 2025 SGLang Team
# 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 argparse
import json
import multiprocessing as mp
import os
import time
from datetime import datetime
from typing import Any, Dict, List

import torch
import triton
from tqdm import tqdm

mp.set_start_method("spawn", force=True)

from sglang.srt.layers.quantization.fp8_kernel import (
    _w8a8_block_fp8_matmul,
    _w8a8_block_fp8_matmul_unrolledx4,
)
from sglang.srt.layers.quantization.int8_kernel import _w8a8_block_int8_matmul
from sglang.srt.utils import get_device_core_count, get_device_name, is_hip

_is_hip = is_hip()

DTYPE_MAP = {
    "float32": torch.float32,
    "float16": torch.float16,
    "half": torch.half,
    "bfloat16": torch.bfloat16,
}


def w8a8_block_matmul(
    A: torch.Tensor,
    B: torch.Tensor,
    As: torch.Tensor,
    Bs: torch.Tensor,
    block_size: List[int],
    config: Dict[str, Any],
    output_dtype: torch.dtype = torch.float16,
) -> torch.Tensor:
    """This function performs matrix multiplication with block-wise quantization.

    It takes two input tensors `A` and `B` with scales `As` and `Bs`.
    The output is returned in the specified `output_dtype`.

    Args:
        A: The input tensor, e.g., activation.
        B: The input tensor, e.g., weight.
        As: The per-token-group quantization scale for `A`.
        Bs: The per-block quantization scale for `B`.
        block_size: The block size for per-block quantization. It should be 2-dim, e.g., [128, 128].
        output_dytpe: The dtype of the returned tensor.

    Returns:
        torch.Tensor: The result of matmul.
    """
    assert len(block_size) == 2
    block_n, block_k = block_size[0], block_size[1]

    assert A.shape[-1] == B.shape[-1]
    assert A.shape[:-1] == As.shape[:-1] and A.is_contiguous()
    assert triton.cdiv(A.shape[-1], block_k) == As.shape[-1]
    M = A.numel() // A.shape[-1]

    assert B.ndim == 2 and B.is_contiguous() and Bs.ndim == 2
    N, K = B.shape
    assert triton.cdiv(N, block_n) == Bs.shape[0]
    assert triton.cdiv(K, block_k) == Bs.shape[1]

    C_shape = A.shape[:-1] + (N,)
    C = A.new_empty(C_shape, dtype=output_dtype)

    needs_masking = bool(K % config["BLOCK_SIZE_K"] != 0)

    def grid(META):
        return (
            triton.cdiv(M, META["BLOCK_SIZE_M"]) * triton.cdiv(N, META["BLOCK_SIZE_N"]),
        )

    # Use manually unrolledx4 kernel on AMD GPU when the grid size is small.
    # Empirical testing shows the sweet spot lies when it's less than the # of
    # compute units available on the device.
    num_workgroups = triton.cdiv(M, config["BLOCK_SIZE_M"]) * triton.cdiv(
        N, config["BLOCK_SIZE_N"]
    )

    if A.dtype == torch.float8_e4m3fnuz or A.dtype == torch.float8_e4m3fn:
        kernel = (
            _w8a8_block_fp8_matmul_unrolledx4
            if (_is_hip == True and num_workgroups <= get_device_core_count())
            else _w8a8_block_fp8_matmul
        )
    else:
        kernel = _w8a8_block_int8_matmul

    kernel[grid](
        A,
        B,
        C,
        As,
        Bs,
        M,
        N,
        K,
        block_n,
        block_k,
        A.stride(-2),
        A.stride(-1),
        B.stride(1),
        B.stride(0),
        C.stride(-2),
        C.stride(-1),
        As.stride(-2),
        As.stride(-1),
        Bs.stride(1),
        Bs.stride(0),
        **config,
        needs_masking=needs_masking,
    )

    return C


def get_rocm_configs_compute_bound():
    configs = []
    waves_per_eu_range = 0
    for num_stages in [2]:
        for block_m in [32, 64, 128, 256]:
            for block_k in [32, 64, 128, 256]:
                for block_n in [16, 32, 64, 128, 256]:
                    for num_warps in [4, 8]:
                        for group_size in [1, 4, 8, 16, 32]:
                            configs.append(
                                {
                                    "BLOCK_SIZE_M": block_m,
                                    "BLOCK_SIZE_N": block_n,
                                    "BLOCK_SIZE_K": block_k,
                                    "GROUP_SIZE_M": group_size,
                                    "num_warps": num_warps,
                                    "num_stages": num_stages,
                                    "waves_per_eu": waves_per_eu_range,
                                }
                            )
    return configs


def get_configs_compute_bound():
    configs = []
    if _is_hip:
        configs = get_rocm_configs_compute_bound()
    else:
        for num_stages in [2, 3, 4, 5]:
            for block_m in [16, 32, 64, 128, 256]:
                for block_k in [64, 128]:
                    for block_n in [32, 64, 128, 256]:
                        for num_warps in [4, 8]:
                            for group_size in [1, 16, 32, 64]:
                                configs.append(
                                    {
                                        "BLOCK_SIZE_M": block_m,
                                        "BLOCK_SIZE_N": block_n,
                                        "BLOCK_SIZE_K": block_k,
                                        "GROUP_SIZE_M": group_size,
                                        "num_warps": num_warps,
                                        "num_stages": num_stages,
                                    }
                                )
    return configs


def get_weight_shapes(tp_size):
    # NOTE(HandH1998): The weight shapes only works for DeepSeek-V3. Modify them, if you tune for another different model.
    # cannot TP
    total = [
        (512 + 64, 7168),
        ((128 + 64) * 128, 7168),
        (128 * (128 + 128), 512),
        (7168, 16384),
        (7168, 18432),
    ]
    # N can TP
    n_tp = [
        (18432 * 2, 7168),
        ((128 + 64) * 128, 7168),
        (128 * (128 + 128), 512),
        (24576, 1536),
        (4096, 7168),
    ]
    # K can TP
    k_tp = [(7168, 18432), (7168, 16384), (7168, 2048)]

    weight_shapes = []
    for t in total:
        weight_shapes.append(t)
    for n_t in n_tp:
        new_t = (n_t[0] // tp_size, n_t[1])
        weight_shapes.append(new_t)
    for k_t in k_tp:
        new_t = (k_t[0], k_t[1] // tp_size)
        weight_shapes.append(new_t)
    return weight_shapes


def benchmark_config(
    A, B, As, Bs, block_size, config, out_dtype=torch.float16, num_iters=10
):
    def run():
        w8a8_block_matmul(A, B, As, Bs, block_size, config, out_dtype)

    torch.cuda.synchronize()
    # JIT complication & warmup
    for _ in range(5):
        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):
        torch.cuda.synchronize()
        start_event.record()
        run()
        end_event.record()
        end_event.synchronize()
        latencies.append(start_event.elapsed_time(end_event))
    avg = sum(latencies) / (num_iters * 10) * 1000  # us
    return avg


def tune(M, N, K, block_size, out_dtype, search_space, input_type):
    factor_for_scale = 1e-2

    if input_type == "fp8":
        fp8_info = torch.finfo(
            torch.float8_e4m3fnuz if _is_hip else torch.float8_e4m3fn
        )
        fp8_max, fp8_min = fp8_info.max, fp8_info.min

        A_fp32 = (
            (torch.rand(M, K, dtype=torch.float32, device="cuda") - 0.5) * 2 * fp8_max
        )
        A = A_fp32.clamp(min=fp8_min, max=fp8_max).to(
            torch.float8_e4m3fnuz if _is_hip else torch.float8_e4m3fn
        )

        B_fp32 = (
            (torch.rand(N, K, dtype=torch.float32, device="cuda") - 0.5) * 2 * fp8_max
        )
        B = B_fp32.clamp(min=fp8_min, max=fp8_max).to(
            torch.float8_e4m3fnuz if _is_hip else torch.float8_e4m3fn
        )
    else:
        int8_info = torch.iinfo(torch.int8)
        int8_max, int8_min = int8_info.max, int8_info.min

        A_fp32 = (
            (torch.rand(M, K, dtype=torch.float32, device="cuda") - 0.5) * 2 * int8_max
        )
        A = A_fp32.clamp(min=int8_min, max=int8_max).to(torch.int8)

        B_fp32 = (
            (torch.rand(N, K, dtype=torch.float32, device="cuda") - 0.5) * 2 * int8_max
        )
        B = B_fp32.clamp(min=int8_min, max=int8_max).to(torch.int8)

    block_n, block_k = block_size[0], block_size[1]
    n_tiles = (N + block_n - 1) // block_n
    k_tiles = (K + block_k - 1) // block_k

    As = torch.rand(M, k_tiles, dtype=torch.float32, device="cuda") * factor_for_scale
    Bs = (
        torch.rand(n_tiles, k_tiles, dtype=torch.float32, device="cuda")
        * factor_for_scale
    )

    best_config = None
    best_time = float("inf")
    for config in tqdm(search_space):
        try:
            kernel_time = benchmark_config(
                A,
                B,
                As,
                Bs,
                block_size,
                config,
                out_dtype,
                num_iters=10,
            )
        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={M}")
    assert best_config is not None
    return best_config


def save_configs(
    N,
    K,
    block_n,
    block_k,
    configs,
    save_path,
    input_type="fp8",
) -> None:
    os.makedirs(save_path, exist_ok=True)
    device_name = get_device_name().replace(" ", "_")
    json_file_name = f"N={N},K={K},device_name={device_name},dtype={input_type}_w8a8,block_shape=[{block_n}, {block_k}].json"

    config_file_path = os.path.join(save_path, json_file_name)
    print(f"Writing best config to {config_file_path}...")

    with open(config_file_path, "w") as f:
        json.dump(configs, f, indent=4)
        f.write("\n")


def get_available_gpu_count():
    """Get the number of available GPUs."""
    return torch.cuda.device_count()


def tune_on_gpu(args_dict):
    """Run tuning on a specific GPU."""
    gpu_id = args_dict["gpu_id"]
    batch_sizes = args_dict["batch_sizes"]
    weight_shapes = args_dict["weight_shapes"]
    args = args_dict["args"]

    torch.cuda.set_device(gpu_id)
    print(f"Starting tuning on GPU {gpu_id} with batch sizes {batch_sizes}")

    block_n = args.block_n
    block_k = args.block_k
    out_dtype = DTYPE_MAP[args.out_dtype]
    save_path = args.save_path
    input_type = args.input_type

    search_space = get_configs_compute_bound()
    search_space = [
        config for config in search_space if block_k % config["BLOCK_SIZE_K"] == 0
    ]

    start = time.perf_counter()
    results = {}
    for shape in tqdm(weight_shapes, desc=f"GPU {gpu_id} - Shapes"):
        N, K = shape[0], shape[1]
        print(f"[GPU {gpu_id}] Tune for weight shape of `N: {N}, K: {K}`")
        benchmark_results = [
            tune(
                batch_size,
                N,
                K,
                [block_n, block_k],
                out_dtype,
                search_space,
                input_type,
            )
            for batch_size in tqdm(batch_sizes, desc=f"GPU {gpu_id} - Batch sizes")
        ]
        best_configs = {M: config for M, config in zip(batch_sizes, benchmark_results)}
        save_configs(N, K, block_n, block_k, best_configs, save_path, input_type)

    end = time.perf_counter()
    print(f"Tuning on GPU {gpu_id} took {end - start:.2f} seconds")


def distribute_batch_sizes(batch_sizes, num_gpus):
    """Distribute batch sizes across available GPUs."""
    batches_per_gpu = []
    for i in range(num_gpus):
        start_idx = i * len(batch_sizes) // num_gpus
        end_idx = (i + 1) * len(batch_sizes) // num_gpus
        batches_per_gpu.append(batch_sizes[start_idx:end_idx])
    return batches_per_gpu


def main(args):
    print(args)

    num_gpus = get_available_gpu_count()
    if num_gpus == 0:
        raise RuntimeError("No GPU available for tuning")
    print(f"Found {num_gpus} GPUs for parallel tuning")

    torch.cuda.init()

    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]
        num_gpus = 1  # If only one batch size, use only one GPU

    # Support manual N and K specification
    if args.N is not None and args.K is not None:
        weight_shapes = [(args.N, args.K)]
        print(f"Using manually specified weight shape: N={args.N}, K={args.K}")
    else:
        weight_shapes = get_weight_shapes(args.tp_size)
        print(f"Using predefined weight shapes for TP size {args.tp_size}")

    batches_per_gpu = distribute_batch_sizes(batch_sizes, num_gpus)

    process_args = []
    for gpu_id in range(num_gpus):
        process_args.append(
            {
                "gpu_id": gpu_id,
                "batch_sizes": batches_per_gpu[gpu_id],
                "weight_shapes": weight_shapes,  # Each GPU processes all weight shapes
                "args": args,
            }
        )

    ctx = mp.get_context("spawn")
    with ctx.Pool(num_gpus) as pool:
        pool.map(tune_on_gpu, process_args)

    print("Multi-GPU tuning completed")


if __name__ == "__main__":
    parser = argparse.ArgumentParser()

    parser.add_argument(
        "--tp-size",
        "-tp",
        type=int,
        default=8,
        help="Tensor parallelism size (ignored if --N and --K are specified)",
    )
    parser.add_argument(
        "--N",
        type=int,
        default=None,
        help="Output dimension of weight matrix (number of columns)",
    )
    parser.add_argument(
        "--K",
        type=int,
        default=None,
        help="Input dimension of weight matrix (number of rows)",
    )
    parser.add_argument(
        "--input-type", type=str, choices=["fp8", "int8"], default="fp8"
    )
    parser.add_argument(
        "--out-dtype",
        type=str,
        choices=["float32", "float16", "bfloat16", "half"],
        default="float16",
    )
    parser.add_argument("--block-n", type=int, default=128)
    parser.add_argument("--block-k", type=int, default=128)
    parser.add_argument("--batch-size", type=int, required=False)
    parser.add_argument(
        "--save-path", type=str, default="python/sglang/srt/layers/quantization/configs"
    )
    args = parser.parse_args()

    # Validate arguments
    if (args.N is None) != (args.K is None):
        parser.error("--N and --K must be specified together or not at all")

    main(args)