FastDeploy/benchmarks/benchmark_serving.py

"""
# Copyright (c) 2025  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.
"""

# This file is modified from https://github.com/vllm-project/vllm/blob/main/benchmarks/benchmark_serving.py


import argparse
import asyncio
import gc
import json
import os
import random
import time
import warnings
import yaml
from collections.abc import AsyncGenerator, Iterable
from dataclasses import dataclass
from datetime import datetime
from typing import Any, Optional

import numpy as np
from backend_request_func import (ASYNC_REQUEST_FUNCS,
                                  OPENAI_COMPATIBLE_BACKENDS, RequestFuncInput,
                                  RequestFuncOutput)
from tqdm.asyncio import tqdm

from argparse import ArgumentParser as FlexibleArgumentParser

from benchmark_dataset import (SampleRequest, EBDataset, EBChatDataset)
from benchmark_utils import convert_to_pytorch_benchmark_format, write_to_json

MILLISECONDS_TO_SECONDS_CONVERSION = 1000


@dataclass
class BenchmarkMetrics:
    """Class containing all metrics that are used in this script"""
    completed: int
    total_input: int
    total_output: int
    request_throughput: float
    request_goodput: float
    output_throughput: float
    total_token_throughput: float
    mean_s_decode: float
    median_s_decode: float
    std_s_decode: float
    percentiles_s_decode: list[tuple[float, float]]
    mean_ttft_ms: float
    median_ttft_ms: float
    std_ttft_ms: float
    percentiles_ttft_ms: list[tuple[float, float]]
    mean_s_ttft_ms: float
    median_s_ttft_ms: float
    std_s_ttft_ms: float
    percentiles_s_ttft_ms: list[tuple[float, float]]
    mean_tpot_ms: float
    median_tpot_ms: float
    std_tpot_ms: float
    percentiles_tpot_ms: list[tuple[float, float]]
    mean_itl_ms: float
    median_itl_ms: float
    std_itl_ms: float
    percentiles_itl_ms: list[tuple[float, float]]
    mean_s_itl_ms: float
    median_s_itl_ms: float
    std_s_itl_ms: float
    percentiles_s_itl_ms: list[tuple[float, float]]
    # E2EL stands for end-to-end latency per request.
    # It is the time taken on the client side from sending
    # a request to receiving a complete response.
    mean_e2el_ms: float
    median_e2el_ms: float
    std_e2el_ms: float
    percentiles_e2el_ms: list[tuple[float, float]]
    mean_s_e2el_ms: float
    median_s_e2el_ms: float
    std_s_e2el_ms: float
    percentiles_s_e2el_ms: list[tuple[float, float]]
    mean_input_len: float
    median_input_len: float
    std_input_len: float
    percentiles_input_len: list[tuple[float, float]]
    mean_s_input_len: float
    median_s_input_len: float
    std_s_input_len: float
    percentiles_s_input_len: list[tuple[float, float]]
    mean_output_len: float
    median_output_len: float
    std_output_len: float
    percentiles_output_len: list[tuple[float, float]]


async def get_request(
    input_requests: list[SampleRequest],
    request_rate: float,
    burstiness: float = 1.0,
) -> AsyncGenerator[SampleRequest, None]:
    """
    Asynchronously generates requests at a specified rate
    with OPTIONAL burstiness.

    Args:
        input_requests:
            A list of input requests, each represented as a SampleRequest.
        request_rate:
            The rate at which requests are generated (requests/s).
        burstiness (optional):
            The burstiness factor of the request generation.
            Only takes effect when request_rate is not inf.
            Default value is 1, which follows a Poisson process.
            Otherwise, the request intervals follow a gamma distribution.
            A lower burstiness value (0 < burstiness < 1) results
            in more bursty requests, while a higher burstiness value
            (burstiness > 1) results in a more uniform arrival of requests.
    """
    input_requests: Iterable[SampleRequest] = iter(input_requests)

    # Calculate scale parameter theta to maintain the desired request_rate.
    assert burstiness > 0, (
        f"A positive burstiness factor is expected, but given {burstiness}.")
    theta = 1.0 / (request_rate * burstiness)

    for request in input_requests:
        yield request

        if request_rate == float("inf"):
            # If the request rate is infinity, then we don't need to wait.
            continue

        # Sample the request interval from the gamma distribution.
        # If burstiness is 1, it follows exponential distribution.
        interval = np.random.gamma(shape=burstiness, scale=theta)
        # The next request will be sent after the interval.
        await asyncio.sleep(interval)


def calculate_metrics(
    input_requests: list[SampleRequest],
    outputs: list[RequestFuncOutput],
    dur_s: float,
    selected_percentiles: list[float],
    goodput_config_dict: dict[str, float],
) -> tuple[BenchmarkMetrics, list[int]]:
    """Calculates various performance metrics based on the inputs and outputs."""
    input_lens: list[int] = []
    infer_input_lens: list[int] = [] # 推理侧输入token数
    actual_output_lens: list[int] = []
    total_input = 0
    completed = 0
    good_completed = 0
    itls: list[float] = []
    s_itls: list[float] = []
    tpots: list[float] = []
    all_tpots: list[float] = []
    ttfts: list[float] = []
    s_ttfts: list[float] = []
    e2els: list[float] = []
    s_e2els: list[float] = []
    s_decodes: list[float] = []
    for i in range(len(outputs)):
        if outputs[i].success:
            output_len = outputs[i].output_tokens

            if not output_len:
                print("no output_len")
                # We use the tokenizer to count the number of output tokens
                # for some serving backends instead of looking at
                # len(outputs[i].itl) since multiple output tokens may be
                # bundled together
                # Note : this may inflate the output token count slightly

            actual_output_lens.append(output_len)
            input_lens.append(outputs[i].prompt_len)
            infer_input_lens.append(outputs[i].prompt_tokens)
            total_input += outputs[i].prompt_tokens
            tpot = 0
            if output_len > 1:
                latency_minus_ttft = outputs[i].latency - outputs[i].ttft
                tpot = latency_minus_ttft / (output_len - 1)
                tpots.append(tpot)
            # Note: if output_len <= 1, we regard tpot as 0 for goodput
            all_tpots.append(tpot)
            itls += outputs[i].itl
            # 推理侧ITL
            s_a = outputs[i].arrival_time[1:]
            for j in range(len(s_a) - 2):
                s_itls.append(s_a[j + 1] - s_a[j])
            ttfts.append(outputs[i].ttft)
            # 推理侧TTFT
            s_ttfts.append(outputs[i].arrival_time[1])
            e2els.append(outputs[i].latency)
            # 推理侧整句时延
            s_e2els.append(outputs[i].arrival_time[-1])
            # 解码速度去掉首token
            if len(outputs[i].arrival_time) > 2:
                s_decodes.append((outputs[i].output_tokens - 1) /
                                 (outputs[i].arrival_time[-1] - outputs[i].arrival_time[1]))
            completed += 1
        else:
            actual_output_lens.append(0)
            input_lens.append(0)
            infer_input_lens.append(0)

    if goodput_config_dict:
        valid_metrics = []
        slo_values = []

        if "ttft" in goodput_config_dict:
            valid_metrics.append(ttfts)
            slo_values.append(goodput_config_dict["ttft"] /
                              MILLISECONDS_TO_SECONDS_CONVERSION)
        if "tpot" in goodput_config_dict:
            valid_metrics.append(all_tpots)
            slo_values.append(goodput_config_dict["tpot"] /
                              MILLISECONDS_TO_SECONDS_CONVERSION)
        if "e2el" in goodput_config_dict:
            valid_metrics.append(e2els)
            slo_values.append(goodput_config_dict["e2el"] /
                              MILLISECONDS_TO_SECONDS_CONVERSION)

        for req_metric in zip(*valid_metrics):
            is_good_req = all([s >= r for s, r in zip(slo_values, req_metric)])
            if is_good_req:
                good_completed += 1

    if completed == 0:
        warnings.warn(
            "All requests failed. This is likely due to a misconfiguration "
            "on the benchmark arguments.",
            stacklevel=2)
    metrics = BenchmarkMetrics(
        completed=completed,
        total_input=total_input,
        total_output=sum(actual_output_lens),
        request_throughput=completed / dur_s,
        request_goodput=good_completed / dur_s,
        output_throughput=sum(actual_output_lens) / dur_s,
        total_token_throughput=(total_input + sum(actual_output_lens)) / dur_s,
        mean_s_decode=np.mean(s_decodes or 0) *
                       1,  # ttfts is empty if streaming is not supported by backend
        std_s_decode=np.std(s_decodes or 0) * 1,
        median_s_decode=np.median(s_decodes or 0) * 1,
        percentiles_s_decode=[(p, np.percentile(s_decodes or 0, p) * 1)
                               for p in selected_percentiles],
        mean_ttft_ms=np.mean(ttfts or 0) *
        1000,  # ttfts is empty if streaming is not supported by backend
        std_ttft_ms=np.std(ttfts or 0) * 1000,
        median_ttft_ms=np.median(ttfts or 0) * 1000,
        percentiles_ttft_ms=[(p, np.percentile(ttfts or 0, p) * 1000)
                             for p in selected_percentiles],
        mean_s_ttft_ms=np.mean(s_ttfts or 0) *
                     1000,  # ttfts is empty if streaming is not supported by backend
        std_s_ttft_ms=np.std(s_ttfts or 0) * 1000,
        median_s_ttft_ms=np.median(s_ttfts or 0) * 1000,
        percentiles_s_ttft_ms=[(p, np.percentile(s_ttfts or 0, p) * 1000)
                             for p in selected_percentiles],
        mean_tpot_ms=np.mean(tpots or 0) * 1000,
        std_tpot_ms=np.std(tpots or 0) * 1000,
        median_tpot_ms=np.median(tpots or 0) * 1000,
        percentiles_tpot_ms=[(p, np.percentile(tpots or 0, p) * 1000)
                             for p in selected_percentiles],
        mean_itl_ms=np.mean(itls or 0) * 1000,
        std_itl_ms=np.std(itls or 0) * 1000,
        median_itl_ms=np.median(itls or 0) * 1000,
        percentiles_itl_ms=[(p, np.percentile(itls or 0, p) * 1000)
                            for p in selected_percentiles],
        mean_s_itl_ms=np.mean(s_itls or 0) * 1000,
        std_s_itl_ms=np.std(s_itls or 0) * 1000,
        median_s_itl_ms=np.median(s_itls or 0) * 1000,
        percentiles_s_itl_ms=[(p, np.percentile(s_itls or 0, p) * 1000)
                            for p in selected_percentiles],
        mean_e2el_ms=np.mean(e2els or 0) * 1000,
        std_e2el_ms=np.std(e2els or 0) * 1000,
        median_e2el_ms=np.median(e2els or 0) * 1000,
        percentiles_e2el_ms=[(p, np.percentile(e2els or 0, p) * 1000)
                             for p in selected_percentiles],
        mean_s_e2el_ms=np.mean(s_e2els or 0) * 1000,
        std_s_e2el_ms=np.std(s_e2els or 0) * 1000,
        median_s_e2el_ms=np.median(s_e2els or 0) * 1000,
        percentiles_s_e2el_ms=[(p, np.percentile(s_e2els or 0, p) * 1000)
                             for p in selected_percentiles],
        mean_input_len=np.mean(input_lens or 0) * 1,
        std_input_len=np.std(input_lens or 0) * 1,
        median_input_len=np.median(input_lens or 0) * 1,
        percentiles_input_len=[(p, np.percentile(input_lens or 0, p))
                             for p in selected_percentiles],
        mean_s_input_len=np.mean(infer_input_lens or 0) * 1,
        std_s_input_len=np.std(infer_input_lens or 0) * 1,
        median_s_input_len=np.median(infer_input_lens or 0) * 1,
        percentiles_s_input_len=[(p, np.percentile(infer_input_lens or 0, p))
                               for p in selected_percentiles],
        mean_output_len=np.mean(actual_output_lens or 0) * 1,
        std_output_len=np.std(actual_output_lens or 0) * 1,
        median_output_len=np.median(actual_output_lens or 0) * 1,
        percentiles_output_len=[(p, np.percentile(actual_output_lens or 0, p))
                               for p in selected_percentiles],
    )

    return metrics, actual_output_lens


async def benchmark(
    backend: str,
    api_url: str,
    base_url: str,
    model_id: str,
    model_name: str,
    input_requests: list[SampleRequest],
    hyper_parameters: dict,
    logprobs: Optional[int],
    request_rate: float,
    burstiness: float,
    disable_tqdm: bool,
    profile: bool,
    selected_percentile_metrics: list[str],
    selected_percentiles: list[float],
    ignore_eos: bool,
    goodput_config_dict: dict[str, float],
    max_concurrency: Optional[int],
    lora_modules: Optional[Iterable[str]],
    extra_body: Optional[dict],
):
    """Benchmarks an API endpoint using a given set of sample inputs and returns"""
    if backend in ASYNC_REQUEST_FUNCS:
        request_func = ASYNC_REQUEST_FUNCS[backend]
    else:
        raise ValueError(f"Unknown backend: {backend}")

    print("Starting initial single prompt test run...")
    test_prompt, test_output_len = \
        input_requests[0].prompt, \
        input_requests[0].expected_output_len
    test_history_QA = input_requests[0].history_QA

    test_input = RequestFuncInput(
        model=model_id,
        model_name=model_name,
        prompt=test_prompt,
        prompt_len=0,
        history_QA=test_history_QA,
        hyper_parameters=hyper_parameters,
        api_url=api_url,
        output_len=test_output_len,
        logprobs=logprobs,
        ignore_eos=ignore_eos,
        extra_body=extra_body,
    )

    print("test_input:", test_input)

    test_output = await request_func(request_func_input=test_input)

    print("test_output:", test_output)

    if not test_output.success:
        raise ValueError(
            "Initial test run failed - Please make sure benchmark arguments "
            f"are correctly specified. Error: {test_output.error}")
    else:
        print("Initial test run completed. Starting main benchmark run...")

    if lora_modules:
        # For each input request, choose a LoRA module at random.
        lora_modules = iter(
            [random.choice(lora_modules) \
                for _ in range(len(input_requests))])

    if profile:
        print("Starting profiler...")
        profile_input = RequestFuncInput(model=model_id,
                                         model_name=model_name,
                                         prompt=test_prompt,
                                         api_url=base_url + "/start_profile",
                                         output_len=test_output_len,
                                         logprobs=logprobs,
                                         ignore_eos=ignore_eos,
                                         extra_body=extra_body)
        profile_output = await request_func(request_func_input=profile_input)
        if profile_output.success:
            print("Profiler started")

    if burstiness == 1.0:
        distribution = "Poisson process"
    else:
        distribution = "Gamma distribution"

    print(f"Traffic request rate: {request_rate}")
    print(f"Burstiness factor: {burstiness} ({distribution})")
    print(f"Maximum request concurrency: {max_concurrency}")

    pbar = None if disable_tqdm else tqdm(total=len(input_requests))

    # This can be used once the minimum Python version is 3.10 or higher,
    # and it will simplify the code in limited_request_func.
    #    semaphore = (asyncio.Semaphore(max_concurrency)
    #                 if max_concurrency else contextlib.nullcontext())
    semaphore = (asyncio.Semaphore(max_concurrency)
                 if max_concurrency else None)

    async def limited_request_func(request_func_input, pbar):
        if semaphore is None:
            return await request_func(request_func_input=request_func_input,
                                      pbar=pbar)
        async with semaphore:
            return await request_func(request_func_input=request_func_input,
                                      pbar=pbar)

    benchmark_start_time = time.perf_counter()
    tasks: list[asyncio.Task] = []
    async for request in get_request(input_requests, request_rate, burstiness):
        prompt, output_len = request.prompt, request.expected_output_len
        history_QA = request.history_QA

        req_model_id, req_model_name = model_id, model_name
        if lora_modules:
            req_lora_module = next(lora_modules)
            req_model_id, req_model_name = req_lora_module, req_lora_module

        request_func_input = RequestFuncInput(model=req_model_id,
                                              model_name=req_model_name,
                                              prompt=prompt,
                                              prompt_len=0,
                                              history_QA=history_QA,
                                              hyper_parameters=hyper_parameters,
                                              api_url=api_url,
                                              output_len=output_len,
                                              logprobs=logprobs,
                                              ignore_eos=ignore_eos,
                                              extra_body=extra_body)
        tasks.append(
            asyncio.create_task(
                limited_request_func(request_func_input=request_func_input,
                                     pbar=pbar)))
    outputs: list[RequestFuncOutput] = await asyncio.gather(*tasks)

    if profile:
        print("Stopping profiler...")
        profile_input = RequestFuncInput(
            model=model_id,
            prompt=test_prompt,
            api_url=base_url + "/stop_profile",
            output_len=test_output_len,
            logprobs=logprobs,
        )
        profile_output = await request_func(request_func_input=profile_input)
        if profile_output.success:
            print("Profiler stopped")

    if pbar is not None:
        pbar.close()

    benchmark_duration = time.perf_counter() - benchmark_start_time

    metrics, actual_output_lens = calculate_metrics(
        input_requests=input_requests,
        outputs=outputs,
        dur_s=benchmark_duration,
        # tokenizer=tokenizer,
        selected_percentiles=selected_percentiles,
        goodput_config_dict=goodput_config_dict,
    )

    print("{s:{c}^{n}}".format(s=' Serving Benchmark Result ', n=50, c='='))
    print("{:<40} {:<10}".format("Successful requests:", metrics.completed))
    print("{:<40} {:<10.2f}".format("Benchmark duration (s):",
                                    benchmark_duration))
    print("{:<40} {:<10}".format("Total input tokens:", metrics.total_input))
    print("{:<40} {:<10}".format("Total generated tokens:",
                                 metrics.total_output))
    print("{:<40} {:<10.3f}".format("Request throughput (req/s):",
                                    metrics.request_throughput))
    if goodput_config_dict:
        print("{:<40} {:<10.2f}".format("Request goodput (req/s):",
                                        metrics.request_goodput))
    print("{:<40} {:<10.2f}".format("Output token throughput (tok/s):",
                                    metrics.output_throughput))
    print("{:<40} {:<10.2f}".format("Total Token throughput (tok/s):",
                                    metrics.total_token_throughput))

    result = {
        "duration": benchmark_duration,
        "completed": metrics.completed,
        "total_input_tokens": metrics.total_input,
        "total_output_tokens": metrics.total_output,
        "request_throughput": metrics.request_throughput,
        "request_goodput:":
        metrics.request_goodput if goodput_config_dict else None,
        "output_throughput": metrics.output_throughput,
        "total_token_throughput": metrics.total_token_throughput,
        "input_lens": [output.prompt_len for output in outputs],
        "infer_input_lens": [output.prompt_tokens for output in outputs],
        "output_lens": actual_output_lens,
        "ttfts": [output.ttft for output in outputs],
        "itls": [output.itl for output in outputs],
        "input_texts": [input.prompt for input in input_requests],
        "generated_texts": [output.generated_text for output in outputs],
        "reasoning_contents": [output.reasoning_content for output in outputs],
        "errors": [output.error for output in outputs],
    }

    def process_one_metric(
        # E.g., "ttft"
        metric_attribute_name: str,
        # E.g., "TTFT"
        metric_name: str,
        # E.g., "Time to First Token"
        metric_header: str,
    ):
        # This function prints and adds statistics of the specified
        # metric.
        if metric_attribute_name not in selected_percentile_metrics:
            return
        print("{s:{c}^{n}}".format(s=metric_header, n=50, c='-'))
        print("{:<40} {:<10.2f}".format(
            f"Mean {metric_name} (ms):",
            getattr(metrics, f"mean_{metric_attribute_name}_ms")))
        print("{:<40} {:<10.2f}".format(
            f"Median {metric_name} (ms):",
            getattr(metrics, f"median_{metric_attribute_name}_ms")))
        result[f"mean_{metric_attribute_name}_ms"] = getattr(
            metrics, f"mean_{metric_attribute_name}_ms")
        result[f"median_{metric_attribute_name}_ms"] = getattr(
            metrics, f"median_{metric_attribute_name}_ms")
        result[f"std_{metric_attribute_name}_ms"] = getattr(
            metrics, f"std_{metric_attribute_name}_ms")
        for p, value in getattr(metrics,
                                f"percentiles_{metric_attribute_name}_ms"):
            p_word = str(int(p)) if int(p) == p else str(p)
            print("{:<40} {:<10.2f}".format(f"P{p_word} {metric_name} (ms):",
                                            value))
            result[f"p{p_word}_{metric_attribute_name}_ms"] = value

    def process_one_length(
        # E.g., "ttft"
        metric_attribute_name: str,
        # E.g., "TTFT"
        metric_name: str,
        # E.g., "Time to First Token"
        metric_header: str,
    ):
        # This function prints and adds statistics of the specified
        # metric.
        if metric_attribute_name not in selected_percentile_metrics:
            return
        print("{s:{c}^{n}}".format(s=metric_header, n=50, c='-'))
        print("{:<40} {:<10.2f}".format(
            f"Mean {metric_name}:",
            getattr(metrics, f"mean_{metric_attribute_name}")))
        print("{:<40} {:<10.2f}".format(
            f"Median {metric_name}:",
            getattr(metrics, f"median_{metric_attribute_name}")))
        result[f"mean_{metric_attribute_name}"] = getattr(
            metrics, f"mean_{metric_attribute_name}")
        result[f"median_{metric_attribute_name}"] = getattr(
            metrics, f"median_{metric_attribute_name}")
        result[f"std_{metric_attribute_name}"] = getattr(
            metrics, f"std_{metric_attribute_name}")
        for p, value in getattr(metrics,
                                f"percentiles_{metric_attribute_name}"):
            p_word = str(int(p)) if int(p) == p else str(p)
            print("{:<40} {:<10.2f}".format(f"P{p_word} {metric_name}:",
                                            value))
            result[f"p{p_word}_{metric_attribute_name}"] = value

    process_one_length("s_decode", "Decode", "解码速度(tok/s)")
    process_one_metric("ttft", "TTFT", "Time to First Token")
    process_one_metric("s_ttft", "S_TTFT", "Infer Time to First Token")
    process_one_metric("tpot", "TPOT",
                       "Time per Output Token (excl. 1st token)")
    process_one_metric("itl", "ITL", "Inter-token Latency")
    process_one_metric("s_itl", "S_ITL", "Infer Inter-token Latency")
    process_one_metric("e2el", "E2EL", "End-to-end Latency")
    process_one_metric("s_e2el", "S_E2EL", "Infer End-to-end Latency")
    process_one_length("input_len", "Cached Tokens", "Cached Tokens")
    process_one_length("s_input_len", "Input Length", "Infer Input Length")
    process_one_length("output_len", "Output Length", "Output Length")

    print("=" * 50)

    return result


def check_goodput_args(args):
    """Check whether the given argument has valid goodput configuration or not"""
    # Check and parse goodput arguments
    goodput_config_dict = {}
    VALID_NAMES = ["ttft", "tpot", "e2el"]
    if args.goodput:
        goodput_config_dict = parse_goodput(args.goodput)
        for slo_name, slo_val in goodput_config_dict.items():
            if slo_name not in VALID_NAMES:
                raise ValueError(
                    f"Invalid metric name found, {slo_name}: {slo_val}. "
                    "The service level objective name should be one of "
                    f"{str(VALID_NAMES)}. ")
            if slo_val < 0:
                raise ValueError(
                    f"Invalid value found, {slo_name}: {slo_val}. "
                    "The service level objective value should be "
                    "non-negative.")
    return goodput_config_dict


def parse_goodput(slo_pairs):
    """Parse the string into a dictionary with keys being names of SLOS and values being their corresponding values"""
    goodput_config_dict = {}
    try:
        for slo_pair in slo_pairs:
            slo_name, slo_val = slo_pair.split(":")
            goodput_config_dict[slo_name] = float(slo_val)
    except ValueError as err:
        raise argparse.ArgumentTypeError(
            "Invalid format found for service level objectives. "
            "Specify service level objectives for goodput as \"KEY:VALUE\" "
            "pairs, where the key is a metric name, and the value is a "
            "number in milliseconds.") from err
    return goodput_config_dict


def save_to_pytorch_benchmark_format(args: argparse.Namespace,
                                     results: dict[str, Any],
                                     file_name: str) -> None:
    """Save the benchmarking results to PyTorch Benchmark Format JSON file"""
    metrics = [
        "median_ttft_ms", "mean_ttft_ms", "std_ttft_ms", "p99_ttft_ms",
        "mean_tpot_ms", "median_tpot_ms", "std_tpot_ms", "p99_tpot_ms",
        "median_itl_ms", "mean_itl_ms", "std_itl_ms", "p99_itl_ms"
    ]
    # These raw data might be useful, but they are rather big. They can be added
    # later if needed
    ignored_metrics = ["ttfts", "itls", "generated_texts", "errors"]
    pt_records = convert_to_pytorch_benchmark_format(
        args=args,
        metrics={k: [results[k]]
                 for k in metrics},
        extra_info={
            k: results[k]
            for k in results if k not in metrics and k not in ignored_metrics
        })
    if pt_records:
        # Don't use json suffix here as we don't want CI to pick it up
        pt_file = f"{os.path.splitext(file_name)[0]}.pytorch.json"
        write_to_json(pt_file, pt_records)


def main(args: argparse.Namespace):
    """Main entry point"""
    print(args)
    random.seed(args.seed)
    np.random.seed(args.seed)

    backend = args.backend
    model_id = args.model
    model_name = args.served_model_name
    tokenizer_id = args.tokenizer if args.tokenizer is not None else args.model
    tokenizer_mode = args.tokenizer_mode

    if args.base_url is not None:
        api_url = f"{args.base_url}{args.endpoint}"
        base_url = f"{args.base_url}"
    else:
        api_url = f"http://{args.host}:{args.port}{args.endpoint}"
        base_url = f"http://{args.host}:{args.port}"

    if args.dataset_name is None:
        raise ValueError(
            "Please specify '--dataset-name' and the corresponding "
            "'--dataset-path' if required.")

    # For datasets that follow a similar structure, use a mapping.
    dataset_mapping = {
        "EB":
        lambda: EBDataset(random_seed=args.seed,
                          dataset_path=args.dataset_path).sample(
                              num_requests=args.num_prompts,
                              output_len=args.sharegpt_output_len,
        ),
        "EBChat":
            lambda: EBChatDataset(random_seed=args.seed,
                                  dataset_path=args.dataset_path).sample(
                num_requests=args.num_prompts,
                output_len=args.sharegpt_output_len,
        ),
    }

    try:
        input_requests = dataset_mapping[args.dataset_name]()
    except KeyError as err:
        raise ValueError(f"Unknown dataset: {args.dataset_name}") from err

    goodput_config_dict = check_goodput_args(args)

    # Collect the sampling parameters.
    sampling_params = {
        k: v
        for k, v in {
            "top_p": args.top_p,
            "top_k": args.top_k,
            "min_p": args.min_p,
            "temperature": args.temperature
        }.items() if v is not None
    }

    # Sampling parameters are only supported by openai-compatible backend.
    if sampling_params and args.backend not in OPENAI_COMPATIBLE_BACKENDS:
        raise ValueError(
            "Sampling parameters are only supported by openai-compatible "
            "backends.")

    if "temperature" not in sampling_params:
        sampling_params["temperature"] = 0.0  # Default to greedy decoding.

    # Avoid GC processing "static" data - reduce pause times.
    gc.collect()
    gc.freeze()

    # 超参由yaml传入
    if args.hyperparameter_path:
        with open(args.hyperparameter_path, "r") as f:
            hyper_parameters = yaml.safe_load(f)
    else:
        hyper_parameters = {}

    benchmark_result = asyncio.run(
        benchmark(
            backend=backend,
            api_url=api_url,
            base_url=base_url,
            model_id=model_id,
            model_name=model_name,
            input_requests=input_requests,
            hyper_parameters=hyper_parameters,
            logprobs=args.logprobs,
            request_rate=args.request_rate,
            burstiness=args.burstiness,
            disable_tqdm=args.disable_tqdm,
            profile=args.profile,
            selected_percentile_metrics=args.percentile_metrics.split(","),
            selected_percentiles=[
                float(p) for p in args.metric_percentiles.split(",")
            ],
            ignore_eos=args.ignore_eos,
            goodput_config_dict=goodput_config_dict,
            max_concurrency=args.max_concurrency,
            lora_modules=args.lora_modules,
            extra_body=sampling_params,
        ))

    # Save config and results to json
    if args.save_result:
        result_json: dict[str, Any] = {}

        # Setup
        current_dt = datetime.now().strftime("%Y%m%d-%H%M%S")
        result_json["date"] = current_dt
        result_json["backend"] = backend
        result_json["model_id"] = model_id
        result_json["tokenizer_id"] = tokenizer_id
        result_json["num_prompts"] = args.num_prompts

        # Metadata
        if args.metadata:
            for item in args.metadata:
                if "=" in item:
                    kvstring = item.split("=")
                    result_json[kvstring[0].strip()] = kvstring[1].strip()
                else:
                    raise ValueError(
                        "Invalid metadata format. Please use KEY=VALUE format."
                    )

        if not args.save_detailed:
            # Remove fields with too many data points
            for field in [
                    "input_lens", "output_lens", "ttfts", "itls",
                    "generated_texts", "errors"
            ]:
                if field in result_json:
                    del result_json[field]

        # Traffic
        result_json["request_rate"] = (args.request_rate if args.request_rate
                                       < float("inf") else "inf")
        result_json["burstiness"] = args.burstiness
        result_json["max_concurrency"] = args.max_concurrency

        # Merge with benchmark result
        result_json = {**result_json, **benchmark_result}

        # Save to file
        base_model_id = model_id.split("/")[-1]
        max_concurrency_str = (f"-concurrency{args.max_concurrency}"
                               if args.max_concurrency is not None else "")
        file_name = f"{backend}-{args.request_rate}qps{max_concurrency_str}-{base_model_id}-{current_dt}.json"  #noqa
        if args.result_filename:
            file_name = args.result_filename
        if args.result_dir:
            file_name = os.path.join(args.result_dir, file_name)
        with open(file_name, "w", encoding='utf-8') as outfile:
            json.dump(result_json, outfile)
        save_to_pytorch_benchmark_format(args, result_json, file_name)


if __name__ == "__main__":
    parser = FlexibleArgumentParser(
        description="Benchmark the online serving throughput.")
    parser.add_argument(
        "--backend",
        type=str,
        default="vllm",
        choices=list(ASYNC_REQUEST_FUNCS.keys()),
    )
    parser.add_argument(
        "--base-url",
        type=str,
        default=None,
        help="Server or API base url if not using http host and port.",
    )
    # Use 127.0.0.1 here instead of localhost to force the use of ipv4
    parser.add_argument("--host", type=str, default="127.0.0.1")
    parser.add_argument("--port", type=int, default=8000)
    parser.add_argument(
        "--endpoint",
        type=str,
        default="/v1/completions",
        help="API endpoint.",
    )
    parser.add_argument(
        "--dataset-name",
        type=str,
        default="sharegpt",
        choices=["sharegpt", "burstgpt", "sonnet", "random", "hf", "EB", "EBChat"],
        help="Name of the dataset to benchmark on.",
    )
    parser.add_argument("--dataset-path",
                        type=str,
                        default=None,
                        help="Path to the sharegpt/sonnet dataset. "
                        "Or the huggingface dataset ID if using HF dataset.")
    parser.add_argument("--hyperparameter-path",
                        type=str,
                        default=None,
                        help="Path to the hyperparameter. ")
    parser.add_argument(
        "--max-concurrency",
        type=int,
        default=None,
        help="Maximum number of concurrent requests. This can be used "
        "to help simulate an environment where a higher level component "
        "is enforcing a maximum number of concurrent requests. While the "
        "--request-rate argument controls the rate at which requests are "
        "initiated, this argument will control how many are actually allowed "
        "to execute at a time. This means that when used in combination, the "
        "actual request rate may be lower than specified with --request-rate, "
        "if the server is not processing requests fast enough to keep up.")

    parser.add_argument(
        "--model",
        type=str,
        required=True,
        help="Name of the model.",
    )
    parser.add_argument(
        "--tokenizer",
        type=str,
        help="Name or path of the tokenizer, if not using the default tokenizer.",  # noqa: E501
    )
    parser.add_argument("--use-beam-search", action="store_true")
    parser.add_argument(
        "--num-prompts",
        type=int,
        default=1000,
        help="Number of prompts to process.",
    )
    parser.add_argument(
        "--logprobs",
        type=int,
        default=None,
        help=("Number of logprobs-per-token to compute & return as part of "
              "the request. If unspecified, then either (1) if beam search "
              "is disabled, no logprobs are computed & a single dummy "
              "logprob is returned for each token; or (2) if beam search "
              "is enabled 1 logprob per token is computed"),
    )
    parser.add_argument(
        "--request-rate",
        type=float,
        default=float("inf"),
        help="Number of requests per second. If this is inf, "
        "then all the requests are sent at time 0. "
        "Otherwise, we use Poisson process or gamma distribution "
        "to synthesize the request arrival times.",
    )
    parser.add_argument(
        "--burstiness",
        type=float,
        default=1.0,
        help="Burstiness factor of the request generation. "
        "Only take effect when request_rate is not inf. "
        "Default value is 1, which follows Poisson process. "
        "Otherwise, the request intervals follow a gamma distribution. "
        "A lower burstiness value (0 < burstiness < 1) results in more "
        "bursty requests. A higher burstiness value (burstiness > 1) "
        "results in a more uniform arrival of requests.",
    )
    parser.add_argument("--seed", type=int, default=0)
    parser.add_argument(
        "--trust-remote-code",
        action="store_true",
        help="Trust remote code from huggingface",
    )
    parser.add_argument(
        "--disable-tqdm",
        action="store_true",
        help="Specify to disable tqdm progress bar.",
    )
    parser.add_argument(
        "--profile",
        action="store_true",
        help="Use Torch Profiler. The endpoint must be launched with "
        "VLLM_TORCH_PROFILER_DIR to enable profiler.",
    )
    parser.add_argument(
        "--save-result",
        action="store_true",
        help="Specify to save benchmark results to a json file",
    )
    parser.add_argument(
        "--save-detailed",
        action="store_true",
        help="When saving the results, whether to include per request "
        "information such as response, error, ttfs, tpots, etc.",
    )
    parser.add_argument(
        "--metadata",
        metavar="KEY=VALUE",
        nargs="*",
        help="Key-value pairs (e.g, --metadata version=0.3.3 tp=1) "
        "for metadata of this run to be saved in the result JSON file "
        "for record keeping purposes.",
    )
    parser.add_argument(
        "--result-dir",
        type=str,
        default=None,
        help="Specify directory to save benchmark json results."
        "If not specified, results are saved in the current directory.",
    )
    parser.add_argument(
        "--result-filename",
        type=str,
        default=None,
        help="Specify the filename to save benchmark json results."
        "If not specified, results will be saved in "
        "{backend}-{args.request_rate}qps-{base_model_id}-{current_dt}.json"
        " format.",
    )
    parser.add_argument(
        "--ignore-eos",
        action="store_true",
        help="Set ignore_eos flag when sending the benchmark request."
        "Warning: ignore_eos is not supported in deepspeed_mii and tgi.")
    parser.add_argument(
        "--percentile-metrics",
        type=str,
        default="ttft,tpot,itl",
        help="Comma-separated list of selected metrics to report percentils. "
        "This argument specifies the metrics to report percentiles. "
        "Allowed metric names are \"ttft\", \"tpot\", \"itl\", \"e2el\". "
        "Default value is \"ttft,tpot,itl\".")
    parser.add_argument(
        "--metric-percentiles",
        type=str,
        default="99",
        help="Comma-separated list of percentiles for selected metrics. "
        "To report 25-th, 50-th, and 75-th percentiles, use \"25,50,75\". "
        "Default value is \"99\". "
        "Use \"--percentile-metrics\" to select metrics.",
    )
    parser.add_argument(
        "--goodput",
        nargs="+",
        required=False,
        help="Specify service level objectives for goodput as \"KEY:VALUE\" "
        "pairs, where the key is a metric name, and the value is in "
        "milliseconds. Multiple \"KEY:VALUE\" pairs can be provided, "
        "separated by spaces. Allowed request level metric names are "
        "\"ttft\", \"tpot\", \"e2el\". For more context on the definition of "
        "goodput, refer to DistServe paper: https://arxiv.org/pdf/2401.09670 "
        "and the blog: https://hao-ai-lab.github.io/blogs/distserve")

    # group for dataset specific arguments
    sonnet_group = parser.add_argument_group("sonnet dataset options")
    sonnet_group.add_argument(
        "--sonnet-input-len",
        type=int,
        default=550,
        help="Number of input tokens per request, used only for sonnet dataset.",
    )
    sonnet_group.add_argument(
        "--sonnet-output-len",
        type=int,
        default=150,
        help="Number of output tokens per request, used only for sonnet dataset.",
    )
    sonnet_group.add_argument(
        "--sonnet-prefix-len",
        type=int,
        default=200,
        help="Number of prefix tokens per request, used only for sonnet dataset.",
    )

    sharegpt_group = parser.add_argument_group("sharegpt dataset options")
    sharegpt_group.add_argument(
        "--sharegpt-output-len",
        type=int,
        default=None,
        help="Output length for each request. Overrides the output length "
        "from the ShareGPT dataset.")

    random_group = parser.add_argument_group("random dataset options")
    random_group.add_argument(
        "--random-input-len",
        type=int,
        default=1024,
        help="Number of input tokens per request, used only for random sampling.",
    )
    random_group.add_argument(
        "--random-output-len",
        type=int,
        default=128,
        help="Number of output tokens per request, used only for random sampling.",
    )
    random_group.add_argument(
        "--random-range-ratio",
        type=float,
        default=0.0,
        help="Range ratio for sampling input/output length, "
        "used only for random sampling. Must be in the range [0, 1) to define "
        "a symmetric sampling range"
        "[length * (1 - range_ratio), length * (1 + range_ratio)].",
    )
    random_group.add_argument(
        "--random-prefix-len",
        type=int,
        default=0,
        help=("Number of fixed prefix tokens before the random context "
              "in a request. "
              "The total input length is the sum of `random-prefix-len` and "
              "a random "
              "context length sampled from [input_len * (1 - range_ratio), "
              "input_len * (1 + range_ratio)]."),
    )

    hf_group = parser.add_argument_group("hf dataset options")
    hf_group.add_argument("--hf-subset",
                          type=str,
                          default=None,
                          help="Subset of the HF dataset.")
    hf_group.add_argument("--hf-split",
                          type=str,
                          default=None,
                          help="Split of the HF dataset.")
    hf_group.add_argument(
        "--hf-output-len",
        type=int,
        default=None,
        help="Output length for each request. Overrides the output lengths "
        "from the sampled HF dataset.",
    )

    sampling_group = parser.add_argument_group("sampling parameters")
    sampling_group.add_argument(
        "--top-p",
        type=float,
        default=None,
        help="Top-p sampling parameter. Only has effect on openai-compatible "
        "backends.")
    sampling_group.add_argument(
        "--top-k",
        type=int,
        default=None,
        help="Top-k sampling parameter. Only has effect on openai-compatible "
        "backends.")
    sampling_group.add_argument(
        "--min-p",
        type=float,
        default=None,
        help="Min-p sampling parameter. Only has effect on openai-compatible "
        "backends.")
    sampling_group.add_argument(
        "--temperature",
        type=float,
        default=None,
        help="Temperature sampling parameter. Only has effect on "
        "openai-compatible backends. If not specified, default to greedy "
        "decoding (i.e. temperature==0.0).")

    parser.add_argument(
        '--tokenizer-mode',
        type=str,
        default="auto",
        choices=['auto', 'slow', 'mistral', 'custom'],
        help='The tokenizer mode.\n\n* "auto" will use the '
        'fast tokenizer if available.\n* "slow" will '
        'always use the slow tokenizer. \n* '
        '"mistral" will always use the `mistral_common` tokenizer. \n*'
        '"custom" will use --tokenizer to select the preregistered tokenizer.')

    parser.add_argument("--served-model-name",
                        type=str,
                        default=None,
                        help="The model name used in the API. "
                        "If not specified, the model name will be the "
                        "same as the ``--model`` argument. ")

    parser.add_argument("--lora-modules",
                        nargs='+',
                        default=None,
                        help="A subset of LoRA module names passed in when "
                        "launching the server. For each request, the "
                        "script chooses a LoRA module at random.")

    args = parser.parse_args()

    main(args)