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062/backend_request_func.py 0 → 100644
View file @ 49c10c0c
import json
import os
import sys
import time
import traceback
from dataclasses import dataclass, field
from typing import List, Optional, Union
import aiohttp
import huggingface_hub.constants
from tqdm.asyncio import tqdm
from transformers import (AutoTokenizer, PreTrainedTokenizer,
PreTrainedTokenizerFast)
AIOHTTP_TIMEOUT = aiohttp.ClientTimeout(total=6 * 60 * 60)
@dataclass
class RequestFuncInput:
prompt: str
api_url: str
prompt_len: int
output_len: int
model: str
best_of: int = 1
use_beam_search: bool = False
logprobs: Optional[int] = None
multi_modal_content: Optional[dict] = None
ignore_eos: bool = False
@dataclass
class RequestFuncOutput:
generated_text: str = ""
success: bool = False
latency: float = 0.0
ttft: float = 0.0 # Time to first token
itl: List[float] = field(
default_factory=list) # List of inter-token latencies
prompt_len: int = 0
error: str = ""
async def async_request_tgi(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith("generate_stream")
async with aiohttp.ClientSession(timeout=AIOHTTP_TIMEOUT) as session:
assert not request_func_input.use_beam_search
params = {
"best_of": request_func_input.best_of,
"max_new_tokens": request_func_input.output_len,
"do_sample": True,
"temperature": 0.01, # TGI does not accept 0.0 temperature.
"top_p": 0.99, # TGI does not accept 1.0 top_p.
}
payload = {
"inputs": request_func_input.prompt,
"parameters": params,
}
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk_bytes = chunk_bytes.decode("utf-8")
#NOTE: Sometimes TGI returns a ping response without
# any data, we should skip it.
if chunk_bytes.startswith(":"):
continue
chunk = remove_prefix(chunk_bytes, "data:")
data = json.loads(chunk)
timestamp = time.perf_counter()
# First token
if ttft == 0.0:
ttft = time.perf_counter() - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
most_recent_timestamp = timestamp
output.latency = most_recent_timestamp - st
output.success = True
output.generated_text = data["generated_text"]
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_trt_llm(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith("generate_stream")
async with aiohttp.ClientSession(timeout=AIOHTTP_TIMEOUT) as session:
assert not request_func_input.use_beam_search
assert request_func_input.best_of == 1
payload = {
"accumulate_tokens": True,
"text_input": request_func_input.prompt,
"temperature": 0.0,
"top_p": 1.0,
"max_tokens": request_func_input.output_len,
"stream": True,
}
if request_func_input.ignore_eos:
payload["min_length"] = request_func_input.output_len
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk = remove_prefix(chunk_bytes.decode("utf-8"),
"data:")
data = json.loads(chunk)
output.generated_text += data["text_output"]
timestamp = time.perf_counter()
# First token
if ttft == 0.0:
ttft = time.perf_counter() - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
most_recent_timestamp = timestamp
output.latency = most_recent_timestamp - st
output.success = True
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_deepspeed_mii(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
async with aiohttp.ClientSession(timeout=AIOHTTP_TIMEOUT) as session:
assert request_func_input.best_of == 1
assert not request_func_input.use_beam_search
payload = {
"prompt": request_func_input.prompt,
"max_tokens": request_func_input.output_len,
"temperature": 0.01, # deepspeed-mii does not accept 0.0 temp.
"top_p": 1.0,
}
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
# NOTE: DeepSpeed-MII doesn't support streaming as of Jan 28 2024,
# will use 0 as placeholder.
# See https://github.com/microsoft/DeepSpeed-MII/pull/311
output.ttft = 0
st = time.perf_counter()
try:
async with session.post(url=request_func_input.api_url,
json=payload) as response:
if response.status == 200:
parsed_resp = await response.json()
output.latency = time.perf_counter() - st
output.generated_text = parsed_resp["text"][0]
output.success = True
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_openai_completions(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith(
("completions", "profile")
), "OpenAI Completions API URL must end with 'completions' or 'profile'."
async with aiohttp.ClientSession(timeout=AIOHTTP_TIMEOUT) as session:
assert not request_func_input.use_beam_search
payload = {
"model": request_func_input.model,
"prompt": request_func_input.prompt,
"temperature": 0.0,
"best_of": request_func_input.best_of,
"max_tokens": request_func_input.output_len,
"logprobs": request_func_input.logprobs,
"stream": True,
}
headers = {
"Authorization": f"Bearer {os.environ.get('OPENAI_API_KEY')}"
}
if request_func_input.ignore_eos:
payload["ignore_eos"] = request_func_input.ignore_eos
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
generated_text = ""
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload,
headers=headers) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk = remove_prefix(chunk_bytes.decode("utf-8"),
"data: ")
if chunk == "[DONE]":
latency = time.perf_counter() - st
else:
data = json.loads(chunk)
# NOTE: Some completion API might have a last
# usage summary response without a token so we
# want to check a token was generated
if data["choices"][0]["text"]:
timestamp = time.perf_counter()
# First token
if ttft == 0.0:
ttft = time.perf_counter() - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
most_recent_timestamp = timestamp
generated_text += data["choices"][0]["text"]
output.generated_text = generated_text
output.success = True
output.latency = latency
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_openai_chat_completions(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith(
"chat/completions"
), "OpenAI Chat Completions API URL must end with 'chat/completions'."
async with aiohttp.ClientSession(timeout=AIOHTTP_TIMEOUT) as session:
assert not request_func_input.use_beam_search
content = [{"type": "text", "text": request_func_input.prompt}]
if request_func_input.multi_modal_content:
content.append(request_func_input.multi_modal_content)
payload = {
"model": request_func_input.model,
"messages": [
{
"role": "user",
"content": content
},
],
"temperature": 0.0,
"max_tokens": request_func_input.output_len,
"stream": True,
}
headers = {
"Content-Type": "application/json",
"Authorization": f"Bearer {os.environ.get('OPENAI_API_KEY')}",
}
if request_func_input.ignore_eos:
payload["ignore_eos"] = request_func_input.ignore_eos
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
generated_text = ""
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload,
headers=headers) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk = remove_prefix(chunk_bytes.decode("utf-8"),
"data: ")
if chunk == "[DONE]":
latency = time.perf_counter() - st
else:
timestamp = time.perf_counter()
data = json.loads(chunk)
delta = data["choices"][0]["delta"]
if delta.get("content", None):
# First token
if ttft == 0.0:
ttft = time.perf_counter() - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
generated_text += delta["content"]
most_recent_timestamp = timestamp
output.generated_text = generated_text
output.success = True
output.latency = latency
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
# Since vllm must support Python 3.8, we can't use str.removeprefix(prefix)
# introduced in Python 3.9
def remove_prefix(text: str, prefix: str) -> str:
if text.startswith(prefix):
return text[len(prefix):]
return text
def get_model(pretrained_model_name_or_path: str) -> str:
if os.getenv('VLLM_USE_MODELSCOPE', 'False').lower() == 'true':
from modelscope import snapshot_download
model_path = snapshot_download(
model_id=pretrained_model_name_or_path,
local_files_only=huggingface_hub.constants.HF_HUB_OFFLINE,
ignore_file_pattern=[".*.pt", ".*.safetensors", ".*.bin"])
return model_path
return pretrained_model_name_or_path
def get_tokenizer(
pretrained_model_name_or_path: str, trust_remote_code: bool
) -> Union[PreTrainedTokenizer, PreTrainedTokenizerFast]:
if pretrained_model_name_or_path is not None and not os.path.exists(
pretrained_model_name_or_path):
pretrained_model_name_or_path = get_model(
pretrained_model_name_or_path)
return AutoTokenizer.from_pretrained(pretrained_model_name_or_path,
trust_remote_code=trust_remote_code)
ASYNC_REQUEST_FUNCS = {
"tgi": async_request_tgi,
"vllm": async_request_openai_completions,
"lmdeploy": async_request_openai_completions,
"deepspeed-mii": async_request_deepspeed_mii,
"openai": async_request_openai_completions,
"openai-chat": async_request_openai_chat_completions,
"tensorrt-llm": async_request_trt_llm,
"scalellm": async_request_openai_completions,
}
062/benchmark_servein_0.6.2.py 0 → 100644
View file @ 49c10c0c
"""Benchmark online serving throughput.
On the server side, run one of the following commands:
vLLM OpenAI API server
vllm serve <your_model> \
--swap-space 16 \
--disable-log-requests
(TGI backend)
./launch_tgi_server.sh <your_model> <max_batch_total_tokens>
On the client side, run:
python benchmarks/benchmark_serving.py \
--backend <backend> \
--model <your_model> \
--dataset-name sharegpt \
--dataset-path <path to dataset> \
--request-rate <request_rate> \ # By default <request_rate> is inf
--num-prompts <num_prompts> # By default <num_prompts> is 1000
when using tgi backend, add
--endpoint /generate_stream
to the end of the command above.
"""
import argparse
import asyncio
import base64
import io
import json
import os
import random
import time
import warnings
from dataclasses import dataclass
from datetime import datetime
from typing import Any, AsyncGenerator, Collection, Dict, List, Optional, Tuple
import numpy as np
from backend_request_func import (ASYNC_REQUEST_FUNCS, RequestFuncInput,
RequestFuncOutput)
from datasets import load_dataset
from PIL.Image import Image
from tqdm.asyncio import tqdm
from transformers import PreTrainedTokenizerBase
try:
from vllm.transformers_utils.tokenizer import get_tokenizer
except ImportError:
from backend_request_func import get_tokenizer
try:
from vllm.utils import FlexibleArgumentParser
except ImportError:
from argparse import ArgumentParser as FlexibleArgumentParser
@dataclass
class BenchmarkMetrics:
completed: int
total_input: int
total_output: int
request_throughput: float
output_throughput: float
total_token_throughput: float
mean_ttft_ms: float
median_ttft_ms: float
std_ttft_ms: float
percentiles_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]]
# 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]]
def sample_sharegpt_requests(
dataset_path: str,
num_requests: int,
tokenizer: PreTrainedTokenizerBase,
fixed_output_len: Optional[int] = None,
) -> List[Tuple[str, int, int, None]]:
if fixed_output_len is not None and fixed_output_len < 4:
raise ValueError("output_len too small")
# Load the dataset.
with open(dataset_path) as f:
dataset = json.load(f)
# Filter out the conversations with less than 2 turns.
dataset = [data for data in dataset if len(data["conversations"]) >= 2]
# Only keep the first two turns of each conversation.
dataset = [(data["conversations"][0]["value"],
data["conversations"][1]["value"]) for data in dataset]
# Shuffle the dataset.
random.shuffle(dataset)
# Filter out sequences that are too long or too short
filtered_dataset: List[Tuple[str, int, int]] = []
for i in range(len(dataset)):
if len(filtered_dataset) == num_requests:
break
# Tokenize the prompts and completions.
prompt = dataset[i][0]
prompt_token_ids = tokenizer(prompt).input_ids
completion = dataset[i][1]
completion_token_ids = tokenizer(completion).input_ids
prompt_len = len(prompt_token_ids)
output_len = len(completion_token_ids
) if fixed_output_len is None else fixed_output_len
if prompt_len < 4 or output_len < 4:
# Prune too short sequences.
continue
if prompt_len > 1024 or prompt_len + output_len > 2048:
# Prune too long sequences.
continue
filtered_dataset.append((prompt, prompt_len, output_len, None))
return filtered_dataset
def sample_sonnet_requests(
dataset_path: str,
num_requests: int,
input_len: int,
output_len: int,
prefix_len: int,
tokenizer: PreTrainedTokenizerBase,
) -> List[Tuple[str, str, int, int, None]]:
assert (
input_len > prefix_len
), "'args.sonnet-input-len' must be greater than 'args.prefix-input-len'."
# Load the dataset.
with open(dataset_path) as f:
poem_lines = f.readlines()
# Tokenize the poem lines.
poem_token_ids = tokenizer(poem_lines).input_ids
average_poem_len = sum(
len(token_ids) for token_ids in poem_token_ids) / len(poem_token_ids)
# Base prefix for all requests.
base_prompt = "Pick as many lines as you can from these poem lines:\n"
base_message = [{
"role": "user",
"content": base_prompt,
}]
base_prompt_formatted = tokenizer.apply_chat_template(
base_message, add_generation_prompt=True, tokenize=False)
base_prompt_offset = len(tokenizer(base_prompt_formatted).input_ids)
assert (
input_len > base_prompt_offset
), f"Please set 'args.sonnet-input-len' higher than {base_prompt_offset}."
num_input_lines = round(
(input_len - base_prompt_offset) / average_poem_len)
# First approximately `prefix_len` number of tokens in the
# prompt are fixed poem lines.
assert (
prefix_len > base_prompt_offset
), f"Please set 'args.sonnet-prefix-len' higher than {base_prompt_offset}."
num_prefix_lines = round(
(prefix_len - base_prompt_offset) / average_poem_len)
prefix_lines = poem_lines[:num_prefix_lines]
# Sample the rest of lines per request.
sampled_requests: List[Tuple[str, int, int]] = []
for _ in range(num_requests):
sampled_lines = "".join(
prefix_lines +
random.sample(poem_lines, num_input_lines - num_prefix_lines))
prompt = f"{base_prompt}{sampled_lines}"
message = [
{
"role": "user",
"content": prompt,
},
]
prompt_formatted = tokenizer.apply_chat_template(
message, add_generation_prompt=True, tokenize=False)
prompt_len = len(tokenizer(prompt_formatted).input_ids)
sampled_requests.append(
(prompt, prompt_formatted, prompt_len, output_len, None))
return sampled_requests
def sample_hf_requests(
dataset_path: str,
dataset_subset: str,
dataset_split: str,
num_requests: int,
tokenizer: PreTrainedTokenizerBase,
fixed_output_len: Optional[int] = None,
) -> List[Tuple[str, str, int, Optional[Dict[str, Collection[str]]]]]:
dataset = load_dataset(dataset_path,
name=dataset_subset,
split=dataset_split,
streaming=True)
assert "conversations" in dataset.features, (
"HF Dataset must have 'conversations' column.")
filtered_dataset = dataset.shuffle().filter(
lambda x: len(x["conversations"]) >= 2)
sampled_requests: List[Tuple[str, int, int, Dict[str,
Collection[str]]]] = []
for data in filtered_dataset:
if len(sampled_requests) == num_requests:
break
# Tokenize the prompts and completions.
prompt = data["conversations"][0]["value"]
prompt_token_ids = tokenizer(prompt).input_ids
completion = data["conversations"][1]["value"]
completion_token_ids = tokenizer(completion).input_ids
prompt_len = len(prompt_token_ids)
output_len = len(completion_token_ids
) if fixed_output_len is None else fixed_output_len
if prompt_len < 4 or output_len < 4:
# Prune too short sequences.
continue
if prompt_len > 1024 or prompt_len + output_len > 2048:
# Prune too long sequences.
continue
if "image" in data and isinstance(data["image"], Image):
image: Image = data["image"]
image = image.convert("RGB")
image_data = io.BytesIO()
image.save(image_data, format='JPEG')
image_base64 = base64.b64encode(
image_data.getvalue()).decode("utf-8")
mm_content = {
"type": "image_url",
"image_url": {
"url": f"data:image/jpeg;base64,{image_base64}"
},
}
else:
mm_content = None
sampled_requests.append((prompt, prompt_len, output_len, mm_content))
return sampled_requests
def sample_random_requests(
prefix_len: int,
input_len: int,
output_len: int,
num_prompts: int,
range_ratio: float,
tokenizer: PreTrainedTokenizerBase,
) -> List[Tuple[str, int, int]]:
prefix_token_ids = np.random.randint(0,
tokenizer.vocab_size,
size=prefix_len).tolist()
input_lens = np.random.randint(
int(input_len * range_ratio),
input_len + 1,
size=num_prompts,
)
output_lens = np.random.randint(
int(output_len * range_ratio),
output_len + 1,
size=num_prompts,
)
offsets = np.random.randint(0, tokenizer.vocab_size, size=num_prompts)
input_requests = []
for i in range(num_prompts):
prompt = tokenizer.decode(prefix_token_ids +
[(offsets[i] + i + j) % tokenizer.vocab_size
for j in range(input_lens[i])])
input_requests.append((prompt, int(prefix_len + input_lens[i]),
int(output_lens[i]), None))
return input_requests
async def get_request(
input_requests: List[Tuple[str, int, int]],
request_rate: float,
) -> AsyncGenerator[Tuple[str, int, int], None]:
input_requests = iter(input_requests)
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 exponential distribution.
interval = np.random.exponential(1.0 / request_rate)
# The next request will be sent after the interval.
await asyncio.sleep(interval)
def calculate_metrics(
input_requests: List[Tuple[str, int, int]],
outputs: List[RequestFuncOutput],
dur_s: float,
tokenizer: PreTrainedTokenizerBase,
selected_percentile_metrics: List[str],
selected_percentiles: List[float],
) -> Tuple[BenchmarkMetrics, List[int]]:
actual_output_lens: List[int] = []
total_input = 0
completed = 0
itls: List[float] = []
tpots: List[float] = []
ttfts: List[float] = []
e2els: List[float] = []
for i in range(len(outputs)):
if outputs[i].success:
# We use the tokenizer to count the number of output tokens for all
# 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
output_len = len(
tokenizer(outputs[i].generated_text,
add_special_tokens=False).input_ids)
actual_output_lens.append(output_len)
total_input += input_requests[i][1]
if output_len > 1:
tpots.append(
(outputs[i].latency - outputs[i].ttft) / (output_len - 1))
itls += outputs[i].itl
ttfts.append(outputs[i].ttft)
e2els.append(outputs[i].latency)
completed += 1
else:
actual_output_lens.append(0)
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,
output_throughput=sum(actual_output_lens) / dur_s,
total_token_throughput=(total_input + sum(actual_output_lens)) / dur_s,
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_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_e2el_ms=np.median(e2els or 0) * 1000,
std_e2el_ms=np.std(e2els or 0) * 1000,
median_e2el_ms=np.mean(e2els or 0) * 1000,
percentiles_e2el_ms=[(p, np.percentile(e2els or 0, p) * 1000)
for p in selected_percentiles],
)
return metrics, actual_output_lens
async def benchmark(
backend: str,
api_url: str,
base_url: str,
model_id: str,
tokenizer: PreTrainedTokenizerBase,
input_requests: List[Tuple[str, int, int]],
logprobs: Optional[int],
best_of: int,
use_beam_search: bool,
request_rate: float,
disable_tqdm: bool,
profile: bool,
selected_percentile_metrics: List[str],
selected_percentiles: List[str],
ignore_eos: bool,
):
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_prompt_len, test_output_len, test_mm_content = (
input_requests[0])
if backend != "openai-chat" and test_mm_content is not None:
# multi-modal benchmark is only available on OpenAI Chat backend.
raise ValueError(
"Multi-modal content is only supported on 'openai-chat' backend.")
test_input = RequestFuncInput(
model=model_id,
prompt=test_prompt,
api_url=api_url,
prompt_len=test_prompt_len,
output_len=test_output_len,
logprobs=logprobs,
best_of=best_of,
ignore_eos=ignore_eos,
use_beam_search=use_beam_search,
multi_modal_content=test_mm_content,
)
test_output = await request_func(request_func_input=test_input)
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 profile:
print("Starting profiler...")
profile_input = RequestFuncInput(
model=model_id,
prompt=test_prompt,
api_url=base_url + "/start_profile",
prompt_len=test_prompt_len,
output_len=test_output_len,
logprobs=logprobs,
best_of=best_of,
use_beam_search=use_beam_search,
multi_modal_content=test_mm_content,
)
profile_output = await request_func(request_func_input=profile_input)
if profile_output.success:
print("Profiler started")
print(f"Traffic request rate: {request_rate}")
pbar = None if disable_tqdm else tqdm(total=len(input_requests))
benchmark_start_time = time.perf_counter()
tasks: List[asyncio.Task] = []
async for request in get_request(input_requests, request_rate):
prompt, prompt_len, output_len, mm_content = request
request_func_input = RequestFuncInput(
model=model_id,
prompt=prompt,
api_url=api_url,
prompt_len=prompt_len,
output_len=output_len,
logprobs=logprobs,
best_of=best_of,
use_beam_search=use_beam_search,
multi_modal_content=mm_content,
ignore_eos=ignore_eos
)
tasks.append(
asyncio.create_task(
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",
prompt_len=test_prompt_len,
output_len=test_output_len,
logprobs=logprobs,
best_of=best_of,
use_beam_search=use_beam_search,
)
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_percentile_metrics=selected_percentile_metrics,
selected_percentiles=selected_percentiles,
)
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} {:<10.2f}".format("Request throughput (req/s):",
metrics.request_throughput))
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,
"output_throughput": metrics.output_throughput,
"total_token_throughput": metrics.total_token_throughput,
"input_lens": [output.prompt_len for output in outputs],
"output_lens": actual_output_lens,
"ttfts": [output.ttft for output in outputs],
"itls": [output.itl for output in outputs],
"generated_texts": [output.generated_text 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 print and add 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
process_one_metric("ttft", "TTFT", "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("e2el", "E2EL", "End-to-end Latency")
print("=" * 50)
return result
def main(args: argparse.Namespace):
print(args)
random.seed(args.seed)
np.random.seed(args.seed)
backend = args.backend
model_id = args.model
tokenizer_id = args.tokenizer if args.tokenizer is not None else args.model
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}"
tokenizer = get_tokenizer(tokenizer_id,
trust_remote_code=args.trust_remote_code)
if args.dataset is not None:
warnings.warn(
"The '--dataset' argument will be deprecated in the next "
"release. Please use '--dataset-name' and "
"'--dataset-path' in the future runs.",
stacklevel=2)
input_requests = sample_sharegpt_requests(
dataset_path=args.dataset,
num_requests=args.num_prompts,
tokenizer=tokenizer,
fixed_output_len=args.sharegpt_output_len,
)
elif args.dataset_name == "sharegpt":
input_requests = sample_sharegpt_requests(
dataset_path=args.dataset_path,
num_requests=args.num_prompts,
tokenizer=tokenizer,
fixed_output_len=args.sharegpt_output_len,
)
elif args.dataset_name == "sonnet":
# Do not format the prompt, pass to message directly
if args.backend == "openai-chat":
input_requests = sample_sonnet_requests(
dataset_path=args.dataset_path,
num_requests=args.num_prompts,
input_len=args.sonnet_input_len,
output_len=args.sonnet_output_len,
prefix_len=args.sonnet_prefix_len,
tokenizer=tokenizer,
)
input_requests = [(prompt, prompt_len, output_len, None)
for prompt, prompt_formatted, prompt_len,
output_len, _ in input_requests]
else:
assert (
tokenizer.chat_template or tokenizer.default_chat_template
), "Tokenizer/model must have chat template for sonnet dataset."
input_requests = sample_sonnet_requests(
dataset_path=args.dataset_path,
num_requests=args.num_prompts,
input_len=args.sonnet_input_len,
output_len=args.sonnet_output_len,
prefix_len=args.sonnet_prefix_len,
tokenizer=tokenizer,
)
input_requests = [(prompt_formatted, prompt_len, output_len, None)
for prompt, prompt_formatted, prompt_len,
output_len, _ in input_requests]
elif args.dataset_name == "hf":
input_requests = sample_hf_requests(
dataset_path=args.dataset_path,
dataset_subset=args.hf_subset,
dataset_split=args.hf_split,
num_requests=args.num_prompts,
tokenizer=tokenizer,
fixed_output_len=args.hf_output_len,
)
elif args.dataset_name == "random":
input_requests = sample_random_requests(
prefix_len=args.random_prefix_len,
input_len=args.random_input_len,
output_len=args.random_output_len,
num_prompts=args.num_prompts,
range_ratio=args.random_range_ratio,
tokenizer=tokenizer,
)
else:
raise ValueError(f"Unknown dataset: {args.dataset_name}")
benchmark_result = asyncio.run(
benchmark(
backend=backend,
api_url=api_url,
base_url=base_url,
model_id=model_id,
tokenizer=tokenizer,
input_requests=input_requests,
logprobs=args.logprobs,
best_of=args.best_of,
use_beam_search=args.use_beam_search,
request_rate=args.request_rate,
disable_tqdm=args.disable_tqdm,
profile=args.profile,
ignore_eos=args.ignore_eos,
selected_percentile_metrics=args.percentile_metrics.split(","),
selected_percentiles=[
float(p) for p in args.metric_percentiles.split(",")
],
))
# 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["best_of"] = args.best_of
result_json["use_beam_search"] = args.use_beam_search
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."
)
# Traffic
result_json["request_rate"] = (
args.request_rate if args.request_rate < float("inf") else "inf")
# Merge with benchmark result
result_json = {**result_json, **benchmark_result}
# Save to file
base_model_id = model_id.split("/")[-1]
file_name = f"{backend}-{args.request_rate}qps-{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") as outfile:
json.dump(result_json, outfile)
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.",
)
parser.add_argument("--host", type=str, default="localhost")
parser.add_argument("--port", type=int, default=8000)
parser.add_argument(
"--endpoint",
type=str,
default="/v1/completions",
help="API endpoint.",
)
parser.add_argument(
"--dataset",
type=str,
default=None,
help="Path to the ShareGPT dataset, will be deprecated in the "
"next release.",
)
parser.add_argument(
"--dataset-name",
type=str,
default="sharegpt",
choices=["sharegpt", "sonnet", "random", "hf"],
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(
"--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(
"--best-of",
type=int,
default=1,
help="Generates `best_of` sequences per prompt and "
"returns the best one.",
)
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 to synthesize "
"the request arrival times.",
)
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(
"--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-seperated 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-seperated 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.",
)
# 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=1.0,
help="Range of sampled ratio of input/output length, "
"used only for random sampling.",
)
random_group.add_argument(
"--random-prefix-len",
type=int,
default=0,
help="Number of fixed prefix tokens before random "
" context. The length range of context in a random "
" request is [random-prefix-len, "
" random-prefix-len + random-prefix-len * random-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.",
)
args = parser.parse_args()
main(args)
062/benchmark_throughput_0.6.2.py 0 → 100644
View file @ 49c10c0c
"""Benchmark offline inference throughput."""
import argparse
import json
import random
import time
from typing import List, Optional, Tuple
import numpy as np
import torch
import uvloop
from tqdm import tqdm
from transformers import (AutoModelForCausalLM, AutoTokenizer,
PreTrainedTokenizerBase)
from vllm.inputs import PromptInputs
from vllm.engine.arg_utils import DEVICE_OPTIONS, AsyncEngineArgs, EngineArgs
from vllm.entrypoints.openai.api_server import (
build_async_engine_client_from_engine_args)
from vllm.model_executor.layers.quantization import QUANTIZATION_METHODS
from vllm.utils import FlexibleArgumentParser, merge_async_iterators
def sample_requests(
dataset_path: str,
num_requests: int,
tokenizer: PreTrainedTokenizerBase,
fixed_output_len: Optional[int],
) -> List[Tuple[str, int, int]]:
if fixed_output_len is not None and fixed_output_len < 4:
raise ValueError("output_len too small")
# Load the dataset.
with open(dataset_path) as f:
dataset = json.load(f)
# Filter out the conversations with less than 2 turns.
dataset = [data for data in dataset if len(data["conversations"]) >= 2]
# Only keep the first two turns of each conversation.
dataset = [(data["conversations"][0]["value"],
data["conversations"][1]["value"]) for data in dataset]
# Shuffle the dataset.
random.shuffle(dataset)
# Filter out sequences that are too long or too short
filtered_dataset: List[Tuple[str, int, int]] = []
for i in range(len(dataset)):
if len(filtered_dataset) == num_requests:
break
# Tokenize the prompts and completions.
prompt = dataset[i][0]
prompt_token_ids = tokenizer(prompt).input_ids
completion = dataset[i][1]
completion_token_ids = tokenizer(completion).input_ids
prompt_len = len(prompt_token_ids)
output_len = len(completion_token_ids
) if fixed_output_len is None else fixed_output_len
if prompt_len < 4 or output_len < 4:
# Prune too short sequences.
continue
if prompt_len > 1024 or prompt_len + output_len > 2048:
# Prune too long sequences.
continue
filtered_dataset.append((prompt, prompt_len, output_len))
return filtered_dataset
def run_vllm(
warmup_requests: List[Tuple[str, int, int]],
requests_json: List[Tuple[str, int, int]],
model: str,
tokenizer: str,
quantization: Optional[str],
tensor_parallel_size: int,
seed: int,
n: int,
use_beam_search: bool,
trust_remote_code: bool,
dtype: str,
max_model_len: Optional[int],
enforce_eager: bool,
kv_cache_dtype: str,
quantization_param_path: Optional[str],
device: str,
enable_prefix_caching: bool,
enable_chunked_prefill: bool,
max_num_batched_tokens: int,
distributed_executor_backend: Optional[str],
gpu_memory_utilization: float = 0.9,
num_scheduler_steps: int = 1,
use_v2_block_manager: bool = False,
download_dir: Optional[str] = None,
load_format: str = EngineArgs.load_format,
disable_async_output_proc: bool = False,
use_new_beam_search_impl: bool = False,
) -> float:
from vllm import LLM, SamplingParams
llm = LLM(
model=model,
tokenizer=tokenizer,
quantization=quantization,
tensor_parallel_size=tensor_parallel_size,
seed=seed,
trust_remote_code=trust_remote_code,
dtype=dtype,
max_model_len=max_model_len,
gpu_memory_utilization=gpu_memory_utilization,
enforce_eager=enforce_eager,
kv_cache_dtype=kv_cache_dtype,
quantization_param_path=quantization_param_path,
device=device,
enable_prefix_caching=enable_prefix_caching,
download_dir=download_dir,
enable_chunked_prefill=enable_chunked_prefill,
max_num_batched_tokens=max_num_batched_tokens,
distributed_executor_backend=distributed_executor_backend,
load_format=load_format,
num_scheduler_steps=num_scheduler_steps,
use_v2_block_manager=use_v2_block_manager,
disable_async_output_proc=disable_async_output_proc,
)
# warmup
warmup_prompts = []
warmup_sampling_params = []
for prompt, _, output_len in warmup_requests:
warmup_prompts.append(prompt)
warmup_sampling_params.append(
SamplingParams(
n=n,
temperature=0.0 if use_beam_search else 1.0,
top_p=1.0,
use_beam_search=use_beam_search,
ignore_eos=True,
max_tokens=output_len,
))
print("Warming up...")
for _ in tqdm(range(args.num_iters_warmup), desc="Warmup iterations"):
llm.generate(warmup_prompts, warmup_sampling_params, use_tqdm=True)
info_json={}
for ELEprompt in args.num_prompts:
for ELEinput,ELEoutput in zip(args.input_len,args.output_len):
info={}
requests=requests_json["{}_{}_{}".format(ELEprompt,ELEinput,ELEoutput)]
# Add the requests to the engine.
prompts: List[str] = []
sampling_params: List[SamplingParams] = []
for prompt, _, output_len in requests:
prompts.append(prompt)
sampling_params.append(
SamplingParams(
n=n,
temperature=0.0 if use_beam_search else 1.0,
top_p=1.0,
use_beam_search=use_beam_search,
ignore_eos=True,
max_tokens=output_len,
))
if not use_new_beam_search_impl:
start = time.perf_counter()
real_output = llm.generate(prompts, sampling_params, use_tqdm=True)
end = time.perf_counter()
else:
assert use_beam_search
prompts = [prompt for prompt, _, _ in requests]
# output_len should be the same for all requests.
output_len = requests[0][2]
for prompt, input_len, _output_len in requests:
assert _output_len == output_len
start = time.perf_counter()
llm.beam_search(prompts,
beam_width=n,
max_tokens=output_len,
ignore_eos=True)
end = time.perf_counter()
total_ttfts = []
total_tpops = []
total_output_token_throughput = []
total_inout_token_throughput = []
for output in real_output:
ttft_ = output.metrics.first_token_time - output.metrics.arrival_time
tpop_ = (output.metrics.finished_time - output.metrics.arrival_time - ttft_) / (ELEoutput-1)
output_token_throughput = (ELEoutput) / (output.metrics.finished_time - output.metrics.arrival_time)
inout_token_throughput = (ELEoutput + ELEinput) / (output.metrics.finished_time - output.metrics.arrival_time)
total_ttfts.append(ttft_)
total_tpops.append(tpop_)
total_output_token_throughput.append(output_token_throughput)
total_inout_token_throughput.append(inout_token_throughput)
# total_num_tokens = sum(request.prompt_len + request.expected_output_len
# for request in requests)
# total_output_tokens = sum(request.expected_output_len
# for request in requests)
total_num_tokens = sum(prompt_len + output_len
for _, prompt_len, output_len in requests)
total_output_tokens = sum(output_len
for _, prompt_len, output_len in requests)
info["elapsed_time"] = np.around(end - start,2)
info["Throughput"] = np.around(len(requests) / info['elapsed_time'],2)
info["total_tokens"] = np.around(total_num_tokens / info['elapsed_time'],2)
info["output_tokens"] = np.around(total_output_tokens / info['elapsed_time'],2)
info["ttft_mean"] = np.around(np.mean(total_ttfts),5)
info["ttft_median"] = np.around(np.median(total_ttfts or 0),5)
info["ttft_p99"] = np.around(np.percentile(total_ttfts or 0, 99),5)
info["tpop_mean"] = np.around(np.mean(total_tpops),4)
info["tpop_median"] = np.around(np.median(total_tpops or 0),5)
info["tpop_p99"] = np.around(np.percentile(total_tpops or 0, 99),5)
info["output_token_throughput_mean"] = np.around(np.mean(total_output_token_throughput),2)
info["output_token_throughput_median"] = np.around(np.median(total_output_token_throughput or 0),2)
info["output_token_throughput_p99"] = np.around(np.percentile(total_output_token_throughput or 0, 99),2)
info["inout_token_throughput_mean"] = np.around(np.mean(total_inout_token_throughput),2)
info["inout_token_throughput_median"] = np.around(np.median(total_inout_token_throughput or 0),2)
info["inout_token_throughput_p99"] = np.around(np.percentile(total_inout_token_throughput or 0, 99),2)
info_json["{}_{}_{}".format(ELEprompt,ELEinput,ELEoutput)] = info
print("promt:{},input:{},output:{}".format(ELEprompt,ELEinput,ELEoutput))
print(f"Latency: {info['elapsed_time']:.2f} s")
print(f"Throughput: {len(requests) / info['elapsed_time']:.2f} requests/s, "
f"{total_num_tokens / info['elapsed_time']:.2f} total tokens/s, "
f"{total_output_tokens / info['elapsed_time']:.2f} output tokens/s")
print("==============================================")
print(f"total_out_tokens: {total_output_tokens: .2f} tokens")
print(f"elapsed_time: {info['elapsed_time']: .2f} s") # 总耗时
print(f"TTFT_mean: {info['ttft_mean']: .5f} s") # 首字延时
print(f"ttft_p99: {info['ttft_p99']: .5f} s")
print(f"ttft_median: {info['ttft_median']: .5f} s")
print(f"TPOP_mean: {info['tpop_mean']: .5f} s") # 单字decode时间
print(f"tpop_median: {info['tpop_median']: .5f} s")
print(f"tpop_p99: {info['tpop_p99']: .5f} s")
print(f"output_token_throughput_mean: {info['output_token_throughput_mean']:.2f} tokens/s") # 单路生成吞吐
print(f"output_token_throughput_median: {info['output_token_throughput_median']:.2f} tokens/s")
print(f"output_token_throughput_p99: {info['output_token_throughput_p99']:.2f} tokens/s")
print(f"inout_token_throughput_mean: {info['inout_token_throughput_mean']:.2f} tokens/s") # 单路总吞吐
print(f"tinout_token_throughput_median: {info['inout_token_throughput_median']:.2f} tokens/s")
print(f"inout_token_throughput_p99: {info['inout_token_throughput_p99']:.2f} tokens/s")
print("==============================================")
print("\n")
return info_json
async def run_vllm_async(
requests: List[Tuple[str, int, int]],
model: str,
tokenizer: str,
quantization: Optional[str],
tensor_parallel_size: int,
seed: int,
n: int,
use_beam_search: bool,
trust_remote_code: bool,
dtype: str,
max_model_len: Optional[int],
enforce_eager: bool,
kv_cache_dtype: str,
quantization_param_path: Optional[str],
device: str,
enable_prefix_caching: bool,
enable_chunked_prefill: bool,
max_num_batched_tokens: int,
distributed_executor_backend: Optional[str],
gpu_memory_utilization: float = 0.9,
num_scheduler_steps: int = 1,
use_v2_block_manager: bool = False,
download_dir: Optional[str] = None,
load_format: str = EngineArgs.load_format,
disable_async_output_proc: bool = False,
disable_frontend_multiprocessing: bool = False,
) -> float:
from vllm import SamplingParams
engine_args = AsyncEngineArgs(
model=model,
tokenizer=tokenizer,
quantization=quantization,
tensor_parallel_size=tensor_parallel_size,
seed=seed,
trust_remote_code=trust_remote_code,
dtype=dtype,
max_model_len=max_model_len,
gpu_memory_utilization=gpu_memory_utilization,
enforce_eager=enforce_eager,
kv_cache_dtype=kv_cache_dtype,
quantization_param_path=quantization_param_path,
device=device,
enable_prefix_caching=enable_prefix_caching,
download_dir=download_dir,
enable_chunked_prefill=enable_chunked_prefill,
max_num_batched_tokens=max_num_batched_tokens,
distributed_executor_backend=distributed_executor_backend,
load_format=load_format,
num_scheduler_steps=num_scheduler_steps,
use_v2_block_manager=use_v2_block_manager,
disable_async_output_proc=disable_async_output_proc,
worker_use_ray=False,
disable_log_requests=True,
)
async with build_async_engine_client_from_engine_args(
engine_args, disable_frontend_multiprocessing) as llm:
# Add the requests to the engine.
prompts: List[str] = []
sampling_params: List[SamplingParams] = []
for prompt, _, output_len in requests:
prompts.append(prompt)
sampling_params.append(
SamplingParams(
n=n,
temperature=0.0 if use_beam_search else 1.0,
top_p=1.0,
use_beam_search=use_beam_search,
ignore_eos=True,
max_tokens=output_len,
))
generators = []
start = time.perf_counter()
for i, (prompt, sp) in enumerate(zip(prompts, sampling_params)):
generator = llm.generate(prompt, sp, request_id=f"test{i}")
generators.append(generator)
all_gens = merge_async_iterators(*generators)
async for i, res in all_gens:
pass
end = time.perf_counter()
return end - start
def run_hf(
requests: List[Tuple[str, int, int]],
model: str,
tokenizer: PreTrainedTokenizerBase,
n: int,
use_beam_search: bool,
max_batch_size: int,
trust_remote_code: bool,
) -> float:
assert not use_beam_search
llm = AutoModelForCausalLM.from_pretrained(
model, torch_dtype=torch.float16, trust_remote_code=trust_remote_code)
if llm.config.model_type == "llama":
# To enable padding in the HF backend.
tokenizer.pad_token = tokenizer.eos_token
llm = llm.cuda()
pbar = tqdm(total=len(requests))
start = time.perf_counter()
batch: List[str] = []
max_prompt_len = 0
max_output_len = 0
for i in range(len(requests)):
prompt, prompt_len, output_len = requests[i]
# Add the prompt to the batch.
batch.append(prompt)
max_prompt_len = max(max_prompt_len, prompt_len)
max_output_len = max(max_output_len, output_len)
if len(batch) < max_batch_size and i != len(requests) - 1:
# Check if we can add more requests to the batch.
_, next_prompt_len, next_output_len = requests[i + 1]
if (max(max_prompt_len, next_prompt_len) +
max(max_output_len, next_output_len)) <= 2048:
# We can add more requests to the batch.
continue
# Generate the sequences.
input_ids = tokenizer(batch, return_tensors="pt",
padding=True).input_ids
llm_outputs = llm.generate(
input_ids=input_ids.cuda(),
do_sample=not use_beam_search,
num_return_sequences=n,
temperature=1.0,
top_p=1.0,
use_cache=True,
max_new_tokens=max_output_len,
)
# Include the decoding time.
tokenizer.batch_decode(llm_outputs, skip_special_tokens=True)
pbar.update(len(batch))
# Clear the batch.
batch = []
max_prompt_len = 0
max_output_len = 0
end = time.perf_counter()
return end - start
def run_mii(
requests: List[Tuple[str, int, int]],
model: str,
tensor_parallel_size: int,
output_len: int,
) -> float:
from mii import client, serve
llm = serve(model, tensor_parallel=tensor_parallel_size)
prompts = [prompt for prompt, _, _ in requests]
start = time.perf_counter()
llm.generate(prompts, max_new_tokens=output_len)
end = time.perf_counter()
client = client(model)
client.terminate_server()
return end - start
def main(args: argparse.Namespace):
print(args)
random.seed(args.seed)
# Sample the requests.
tokenizer = AutoTokenizer.from_pretrained(
args.tokenizer, trust_remote_code=args.trust_remote_code)
warmup_prompt = "hi" * 10
warmup_requests = [(warmup_prompt, 10, 10)
for _ in range(1)]
if args.dataset is None:
requests_json={}
for ELEprompt in args.num_prompts:
for ELEinput,ELEoutput in zip(args.input_len,args.output_len):
# Synthesize a prompt with the given input length.
prompt = "hi" * (ELEinput - 1)
requests = [(prompt, ELEinput, ELEoutput)
for _ in range(ELEprompt)]
print("type(requests):",type(requests))
requests_json["{}_{}_{}".format(ELEprompt,ELEinput,ELEoutput)]=requests
else:
requests = sample_requests(args.dataset, args.num_prompts, tokenizer,
args.output_len)
if args.backend == "vllm":
if args.async_engine:
run_args = [
requests, args.model, args.tokenizer, args.quantization,
args.tensor_parallel_size, args.seed, args.n, args.use_beam_search,
args.trust_remote_code, args.dtype, args.max_model_len,
args.enforce_eager, args.kv_cache_dtype,
args.quantization_param_path, args.device,
args.enable_prefix_caching, args.enable_chunked_prefill,
args.max_num_batched_tokens, args.distributed_executor_backend,
args.gpu_memory_utilization, args.num_scheduler_steps,
args.use_v2_block_manager, args.download_dir, args.load_format,
args.disable_async_output_proc
]
else:
run_args = [
warmup_requests, requests_json, args.model, args.tokenizer, args.quantization,
args.tensor_parallel_size, args.seed, args.n, args.use_beam_search,
args.trust_remote_code, args.dtype, args.max_model_len,
args.enforce_eager, args.kv_cache_dtype,
args.quantization_param_path, args.device,
args.enable_prefix_caching, args.enable_chunked_prefill,
args.max_num_batched_tokens, args.distributed_executor_backend,
args.gpu_memory_utilization, args.num_scheduler_steps,
args.use_v2_block_manager, args.download_dir, args.load_format,
args.disable_async_output_proc
]
if args.async_engine:
run_args.append(args.disable_frontend_multiprocessing)
elapsed_time = uvloop.run(run_vllm_async(*run_args))
else:
info_json = run_vllm(*run_args, args.use_new_beam_search_impl)
elif args.backend == "hf":
assert args.tensor_parallel_size == 1
elapsed_time = run_hf(requests, args.model, tokenizer, args.n,
args.use_beam_search, args.hf_max_batch_size,
args.trust_remote_code)
elif args.backend == "mii":
elapsed_time = run_mii(requests, args.model, args.tensor_parallel_size,
args.output_len)
else:
raise ValueError(f"Unknown backend: {args.backend}")
# total_num_tokens = sum(prompt_len + output_len
# for _, prompt_len, output_len in requests)
# if args.dataset is None:
# total_out_tokens = args.output_len * args.num_prompts
# else:
# total_out_tokens = sum(output_len for _, _, output_len in requests)
# print(f"Latency: {elapsed_time:.2f} s")
# print(f"All Throughput: {len(requests) / elapsed_time:.2f} requests/s, "
# f"{total_num_tokens / elapsed_time:.2f} tokens/s")
# print(f"Generate Throughput: {total_out_tokens / elapsed_time:.2f} tokens/s")
with open(args.output_json,"w") as f:
title="bs_in_out"
data_keys=info_json[list(info_json.keys())[0]].keys()
keys_string = ','.join(data_keys)
title=title+","+keys_string
f.write(title)
f.write("\n")
for key, value in info_json.items():
values_as_strings = [str(value) for value in info_json[key].values()]
values_string = ','.join(values_as_strings)
key=key+","+values_string
f.writelines(key)
f.write("\n")
# Output JSON results if specified
# if args.output_json:
# results = {
# "elapsed_time": elapsed_time,
# "num_requests": len(requests),
# "total_num_tokens": total_num_tokens,
# "requests_per_second": len(requests) / elapsed_time,
# "tokens_per_second": total_num_tokens / elapsed_time,
# }
# with open(args.output_json, "w") as f:
# json.dump(results, f, indent=4)
if __name__ == "__main__":
parser = FlexibleArgumentParser(description="Benchmark the throughput.")
parser.add_argument("--backend",
type=str,
choices=["vllm", "hf", "mii"],
default="vllm")
parser.add_argument("--dataset",
type=str,
default=None,
help="Path to the dataset.")
parser.add_argument("--input-len",
type=int,
nargs="*",
default=None,
help="Input prompt length for each request")
parser.add_argument("--output-len",
type=int,
nargs="*",
default=None,
help="Output length for each request. Overrides the "
"output length from the dataset.")
parser.add_argument("--model", type=str, default="facebook/opt-125m")
parser.add_argument("--tokenizer", type=str, default=None)
parser.add_argument('--quantization',
'-q',
choices=[*QUANTIZATION_METHODS, None],
default=None)
parser.add_argument("--tensor-parallel-size", "-tp", type=int, default=1)
parser.add_argument("--n",
type=int,
default=1,
help="Number of generated sequences per prompt.")
parser.add_argument("--use-beam-search", action="store_true")
parser.add_argument('--num-iters-warmup',
type=int,
default=1,
help='Number of iterations to run for warmup.')
parser.add_argument("--use-new-beam-search-impl", action="store_true")
parser.add_argument("--num-prompts",
nargs="*",
type=int,
default=1000,
help="Number of prompts to process.")
parser.add_argument("--seed", type=int, default=0)
parser.add_argument("--hf-max-batch-size",
type=int,
default=None,
help="Maximum batch size for HF backend.")
parser.add_argument('--trust-remote-code',
action='store_true',
help='trust remote code from huggingface')
parser.add_argument(
'--max-model-len',
type=int,
default=None,
help='Maximum length of a sequence (including prompt and output). '
'If None, will be derived from the model.')
parser.add_argument(
'--dtype',
type=str,
default='auto',
choices=['auto', 'half', 'float16', 'bfloat16', 'float', 'float32'],
help='data type for model weights and activations. '
'The "auto" option will use FP16 precision '
'for FP32 and FP16 models, and BF16 precision '
'for BF16 models.')
parser.add_argument('--gpu-memory-utilization',
type=float,
default=0.9,
help='the fraction of GPU memory to be used for '
'the model executor, which can range from 0 to 1.'
'If unspecified, will use the default value of 0.9.')
parser.add_argument("--enforce-eager",
action="store_true",
help="enforce eager execution")
parser.add_argument(
'--kv-cache-dtype',
type=str,
choices=['auto', 'fp8', 'fp8_e5m2', 'fp8_e4m3'],
default="auto",
help='Data type for kv cache storage. If "auto", will use model '
'data type. CUDA 11.8+ supports fp8 (=fp8_e4m3) and fp8_e5m2. '
'ROCm (hcu) supports fp8 (=fp8_e4m3)')
parser.add_argument(
'--quantization-param-path',
type=str,
default=None,
help='Path to the JSON file containing the KV cache scaling factors. '
'This should generally be supplied, when KV cache dtype is FP8. '
'Otherwise, KV cache scaling factors default to 1.0, which may cause '
'accuracy issues. FP8_E5M2 (without scaling) is only supported on '
'cuda version greater than 11.8. On ROCm (hcu), FP8_E4M3 is '
'instead supported for common inference criteria.')
parser.add_argument("--device",
type=str,
default="auto",
choices=DEVICE_OPTIONS,
help='device type for vLLM execution')
parser.add_argument(
"--num-scheduler-steps",
type=int,
default=1,
help="Maximum number of forward steps per scheduler call.")
parser.add_argument("--use-v2-block-manager",
action='store_true',
help="Enable block manager v2.")
parser.add_argument(
"--enable-prefix-caching",
action='store_true',
help="Enable automatic prefix caching for vLLM backend.")
parser.add_argument("--enable-chunked-prefill",
action='store_true',
help="enable chunked prefill for vLLM backend.")
parser.add_argument('--max-num-batched-tokens',
type=int,
default=None,
help='maximum number of batched tokens per '
'iteration')
parser.add_argument('--download-dir',
type=str,
default=None,
help='directory to download and load the weights, '
'default to the default cache dir of huggingface')
parser.add_argument(
'--output-json',
type=str,
default=None,
help='Path to save the throughput results in JSON format.')
parser.add_argument(
'--distributed-executor-backend',
choices=['ray', 'mp'],
default=None,
help='Backend to use for distributed serving. When more than 1 GPU '
'is used, will be automatically set to "ray" if installed '
'or "mp" (multiprocessing) otherwise.')
parser.add_argument(
'--load-format',
type=str,
default=EngineArgs.load_format,
choices=[
'auto', 'pt', 'safetensors', 'npcache', 'dummy', 'tensorizer',
'bitsandbytes'
],
help='The format of the model weights to load.\n\n'
'* "auto" will try to load the weights in the safetensors format '
'and fall back to the pytorch bin format if safetensors format '
'is not available.\n'
'* "pt" will load the weights in the pytorch bin format.\n'
'* "safetensors" will load the weights in the safetensors format.\n'
'* "npcache" will load the weights in pytorch format and store '
'a numpy cache to speed up the loading.\n'
'* "dummy" will initialize the weights with random values, '
'which is mainly for profiling.\n'
'* "tensorizer" will load the weights using tensorizer from '
'CoreWeave. See the Tensorize vLLM Model script in the Examples'
'section for more information.\n'
'* "bitsandbytes" will load the weights using bitsandbytes '
'quantization.\n')
parser.add_argument(
"--disable-async-output-proc",
action='store_true',
default=False,
help="Disable async output processor for vLLM backend.")
parser.add_argument("--async-engine",
action='store_true',
default=False,
help="Use vLLM async engine rather than LLM class.")
parser.add_argument("--disable-frontend-multiprocessing",
action='store_true',
default=False,
help="Disable decoupled async engine frontend.")
args = parser.parse_args()
if args.tokenizer is None:
args.tokenizer = args.model
if args.dataset is None:
assert args.input_len is not None
assert args.output_len is not None
else:
assert args.input_len is None
if args.backend == "vllm":
if args.hf_max_batch_size is not None:
raise ValueError("HF max batch size is only for HF backend.")
elif args.backend == "hf":
if args.hf_max_batch_size is None:
raise ValueError("HF max batch size is required for HF backend.")
if args.quantization is not None:
raise ValueError("Quantization is only for vLLM backend.")
elif args.backend == "mii":
if args.dtype != "auto":
raise ValueError("dtype must be auto for MII backend.")
if args.n != 1:
raise ValueError("n must be 1 for MII backend.")
if args.use_beam_search:
raise ValueError("Beam search is not supported for MII backend.")
if args.quantization is not None:
raise ValueError("Quantization is only for vLLM backend.")
if args.hf_max_batch_size is not None:
raise ValueError("HF max batch size is only for HF backend.")
if args.tokenizer != args.model:
raise ValueError("Tokenizer must be the same as the model for MII "
"backend.")
main(args)
\ No newline at end of file
072/backend_request_func.py 0 → 100644
View file @ 49c10c0c
# SPDX-License-Identifier: Apache-2.0
import json
import os
import sys
import time
import traceback
from dataclasses import dataclass, field
from typing import List, Optional, Union
import aiohttp
import huggingface_hub.constants
from tqdm.asyncio import tqdm
from transformers import (AutoTokenizer, PreTrainedTokenizer,
PreTrainedTokenizerFast)
AIOHTTP_TIMEOUT = aiohttp.ClientTimeout(total=6 * 60 * 60)
@dataclass
class RequestFuncInput:
prompt: str
api_url: str
prompt_len: int
output_len: int
model: str
model_name: Optional[str] = None
best_of: int = 1
logprobs: Optional[int] = None
extra_body: Optional[dict] = None
multi_modal_content: Optional[dict] = None
ignore_eos: bool = False
@dataclass
class RequestFuncOutput:
generated_text: str = ""
success: bool = False
latency: float = 0.0
output_tokens: int = 0
ttft: float = 0.0 # Time to first token
itl: List[float] = field(
default_factory=list) # List of inter-token latencies
tpot: float = 0.0 # avg next-token latencies
prompt_len: int = 0
error: str = ""
async def async_request_tgi(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith("generate_stream")
async with aiohttp.ClientSession(trust_env=True,
timeout=AIOHTTP_TIMEOUT) as session:
params = {
"best_of": request_func_input.best_of,
"max_new_tokens": request_func_input.output_len,
"do_sample": True,
"temperature": 0.01, # TGI does not accept 0.0 temperature.
"top_p": 0.99, # TGI does not accept 1.0 top_p.
"truncate": request_func_input.prompt_len,
# TGI does not accept ignore_eos flag.
}
payload = {
"inputs": request_func_input.prompt,
"parameters": params,
}
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk_bytes = chunk_bytes.decode("utf-8")
# NOTE: Sometimes TGI returns a ping response without
# any data, we should skip it.
if chunk_bytes.startswith(":"):
continue
chunk = chunk_bytes.removeprefix("data:")
data = json.loads(chunk)
timestamp = time.perf_counter()
# First token
if ttft == 0.0:
ttft = time.perf_counter() - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
most_recent_timestamp = timestamp
output.latency = most_recent_timestamp - st
output.success = True
output.generated_text = data["generated_text"]
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_trt_llm(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith("generate_stream")
async with aiohttp.ClientSession(trust_env=True,
timeout=AIOHTTP_TIMEOUT) as session:
assert request_func_input.best_of == 1
payload = {
"accumulate_tokens": True,
"text_input": request_func_input.prompt,
"temperature": 0.0,
"top_p": 1.0,
"max_tokens": request_func_input.output_len,
"stream": True,
}
if request_func_input.ignore_eos:
payload["min_length"] = request_func_input.output_len
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk = chunk_bytes.decode("utf-8").removeprefix(
"data:")
data = json.loads(chunk)
output.generated_text += data["text_output"]
timestamp = time.perf_counter()
# First token
if ttft == 0.0:
ttft = timestamp - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
most_recent_timestamp = timestamp
output.latency = most_recent_timestamp - st
output.success = True
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_deepspeed_mii(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
async with aiohttp.ClientSession(trust_env=True,
timeout=AIOHTTP_TIMEOUT) as session:
assert request_func_input.best_of == 1
payload = {
"prompt": request_func_input.prompt,
"max_tokens": request_func_input.output_len,
"temperature": 0.01, # deepspeed-mii does not accept 0.0 temp.
"top_p": 1.0,
}
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
# NOTE: DeepSpeed-MII doesn't support streaming as of Jan 28 2024,
# will use 0 as placeholder.
# See https://github.com/microsoft/DeepSpeed-MII/pull/311
output.ttft = 0
st = time.perf_counter()
try:
async with session.post(url=request_func_input.api_url,
json=payload) as response:
if response.status == 200:
parsed_resp = await response.json()
output.latency = time.perf_counter() - st
output.generated_text = parsed_resp["text"][0]
output.success = True
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_openai_completions(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith(
("completions", "profile")
), "OpenAI Completions API URL must end with 'completions' or 'profile'."
async with aiohttp.ClientSession(trust_env=True,
timeout=AIOHTTP_TIMEOUT) as session:
payload = {
"model": request_func_input.model_name \
if request_func_input.model_name else request_func_input.model,
"prompt": request_func_input.prompt,
"temperature": 0.0,
"best_of": request_func_input.best_of,
"max_tokens": request_func_input.output_len,
"logprobs": request_func_input.logprobs,
"stream": True,
"stream_options": {
"include_usage": True,
},
}
if request_func_input.ignore_eos:
payload["ignore_eos"] = request_func_input.ignore_eos
if request_func_input.extra_body:
payload.update(request_func_input.extra_body)
headers = {
"Authorization": f"Bearer {os.environ.get('OPENAI_API_KEY')}"
}
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
generated_text = ""
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload,
headers=headers) as response:
if response.status == 200:
first_chunk_received = False
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk = chunk_bytes.decode("utf-8").removeprefix(
"data: ")
if chunk != "[DONE]":
data = json.loads(chunk)
# NOTE: Some completion API might have a last
# usage summary response without a token so we
# want to check a token was generated
if choices := data.get("choices"):
# Note that text could be empty here
# e.g. for special tokens
text = choices[0].get("text")
timestamp = time.perf_counter()
# First token
if not first_chunk_received:
first_chunk_received = True
ttft = time.perf_counter() - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
most_recent_timestamp = timestamp
generated_text += text or ""
elif usage := data.get("usage"):
output.output_tokens = usage.get(
"completion_tokens")
if first_chunk_received:
output.success = True
else:
output.success = False
output.error = (
"Never received a valid chunk to calculate TTFT."
"This response will be marked as failed!")
output.generated_text = generated_text
output.latency = most_recent_timestamp - st
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
async def async_request_openai_chat_completions(
request_func_input: RequestFuncInput,
pbar: Optional[tqdm] = None,
) -> RequestFuncOutput:
api_url = request_func_input.api_url
assert api_url.endswith(
"chat/completions"
), "OpenAI Chat Completions API URL must end with 'chat/completions'."
async with aiohttp.ClientSession(trust_env=True,
timeout=AIOHTTP_TIMEOUT) as session:
content = [{"type": "text", "text": request_func_input.prompt}]
if request_func_input.multi_modal_content:
content.append(request_func_input.multi_modal_content)
payload = {
"model": request_func_input.model_name \
if request_func_input.model_name else request_func_input.model,
"messages": [
{
"role": "user",
"content": content
},
],
"temperature": 0.0,
"max_completion_tokens": request_func_input.output_len,
"stream": True,
"stream_options": {
"include_usage": True,
},
}
if request_func_input.ignore_eos:
payload["ignore_eos"] = request_func_input.ignore_eos
if request_func_input.extra_body:
payload.update(request_func_input.extra_body)
headers = {
"Content-Type": "application/json",
"Authorization": f"Bearer {os.environ.get('OPENAI_API_KEY')}",
}
output = RequestFuncOutput()
output.prompt_len = request_func_input.prompt_len
generated_text = ""
ttft = 0.0
st = time.perf_counter()
most_recent_timestamp = st
try:
async with session.post(url=api_url, json=payload,
headers=headers) as response:
if response.status == 200:
async for chunk_bytes in response.content:
chunk_bytes = chunk_bytes.strip()
if not chunk_bytes:
continue
chunk = chunk_bytes.decode("utf-8").removeprefix(
"data: ")
if chunk != "[DONE]":
timestamp = time.perf_counter()
data = json.loads(chunk)
if choices := data.get("choices"):
content = choices[0]["delta"].get("content")
# First token
if ttft == 0.0:
ttft = timestamp - st
output.ttft = ttft
# Decoding phase
else:
output.itl.append(timestamp -
most_recent_timestamp)
generated_text += content or ""
elif usage := data.get("usage"):
output.output_tokens = usage.get(
"completion_tokens")
most_recent_timestamp = timestamp
output.generated_text = generated_text
output.success = True
output.latency = most_recent_timestamp - st
else:
output.error = response.reason or ""
output.success = False
except Exception:
output.success = False
exc_info = sys.exc_info()
output.error = "".join(traceback.format_exception(*exc_info))
if pbar:
pbar.update(1)
return output
def get_model(pretrained_model_name_or_path: str) -> str:
if os.getenv('VLLM_USE_MODELSCOPE', 'False').lower() == 'true':
from modelscope import snapshot_download
model_path = snapshot_download(
model_id=pretrained_model_name_or_path,
local_files_only=huggingface_hub.constants.HF_HUB_OFFLINE,
ignore_file_pattern=[".*.pt", ".*.safetensors", ".*.bin"])
return model_path
return pretrained_model_name_or_path
def get_tokenizer(
pretrained_model_name_or_path: str,
tokenizer_mode: str = "auto",
trust_remote_code: bool = False,
**kwargs,
) -> Union[PreTrainedTokenizer, PreTrainedTokenizerFast]:
if pretrained_model_name_or_path is not None and not os.path.exists(
pretrained_model_name_or_path):
pretrained_model_name_or_path = get_model(
pretrained_model_name_or_path)
if tokenizer_mode == "slow":
if kwargs.get("use_fast", False):
raise ValueError(
"Cannot use the fast tokenizer in slow tokenizer mode.")
kwargs["use_fast"] = False
if tokenizer_mode == "mistral":
try:
from vllm.transformers_utils.tokenizer import MistralTokenizer
except ImportError as e:
raise ImportError("MistralTokenizer requires vllm package.\n"
"Please install it with `pip install vllm` "
"to use mistral tokenizer mode.") from e
return MistralTokenizer.from_pretrained(
str(pretrained_model_name_or_path))
else:
return AutoTokenizer.from_pretrained(
pretrained_model_name_or_path,
trust_remote_code=trust_remote_code,
**kwargs,
)
ASYNC_REQUEST_FUNCS = {
"tgi": async_request_tgi,
"vllm": async_request_openai_completions,
"lmdeploy": async_request_openai_completions,
"deepspeed-mii": async_request_deepspeed_mii,
"openai": async_request_openai_completions,
"openai-chat": async_request_openai_chat_completions,
"tensorrt-llm": async_request_trt_llm,
"scalellm": async_request_openai_completions,
"sglang": async_request_openai_completions,
}
072/benchmark_servein_0.7.2.py 0 → 100644
View file @ 49c10c0c
# SPDX-License-Identifier: Apache-2.0
r"""Benchmark online serving throughput.
On the server side, run one of the following commands:
vLLM OpenAI API server
vllm serve <your_model> \
--swap-space 16 \
--disable-log-requests
(TGI backend)
./launch_tgi_server.sh <your_model> <max_batch_total_tokens>
On the client side, run:
python benchmarks/benchmark_serving.py \
--backend <backend> \
--model <your_model> \
--dataset-name sharegpt \
--dataset-path <path to dataset> \
--request-rate <request_rate> \ # By default <request_rate> is inf
--num-prompts <num_prompts> # By default <num_prompts> is 1000
when using tgi backend, add
--endpoint /generate_stream
to the end of the command above.
"""
import argparse
import asyncio
import base64
import gc
import io
import json
import os
import random
import time
import warnings
from dataclasses import dataclass
from datetime import datetime
from typing import Any, AsyncGenerator, Collection, Dict, List, Optional, Tuple
import numpy as np
from backend_request_func import (ASYNC_REQUEST_FUNCS, RequestFuncInput,
RequestFuncOutput)
from datasets import load_dataset
from PIL.Image import Image
from tqdm.asyncio import tqdm
from transformers import PreTrainedTokenizerBase
try:
from vllm.transformers_utils.tokenizer import get_tokenizer
except ImportError:
from backend_request_func import get_tokenizer
try:
from vllm.utils import FlexibleArgumentParser
except ImportError:
from argparse import ArgumentParser as FlexibleArgumentParser
MILLISECONDS_TO_SECONDS_CONVERSION = 1000
@dataclass
class BenchmarkMetrics:
completed: int
total_input: int
total_output: int
request_throughput: float
request_goodput: float
output_throughput: float
total_token_throughput: float
mean_ttft_ms: float
median_ttft_ms: float
std_ttft_ms: float
percentiles_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]]
# 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]]
def sample_sharegpt_requests(
dataset_path: str,
num_requests: int,
tokenizer: PreTrainedTokenizerBase,
fixed_output_len: Optional[int] = None,
) -> List[Tuple[str, int, int, None]]:
# Load the dataset.
with open(dataset_path, encoding='utf-8') as f:
dataset = json.load(f)
# Filter out the conversations with less than 2 turns.
dataset = [data for data in dataset if len(data["conversations"]) >= 2]
# Only keep the first two turns of each conversation.
dataset = [(data["conversations"][0]["value"],
data["conversations"][1]["value"]) for data in dataset]
# Shuffle the dataset.
random.shuffle(dataset)
# Filter out sequences that are too long or too short
filtered_dataset: List[Tuple[str, int, int]] = []
for i in range(len(dataset)):
if len(filtered_dataset) == num_requests:
break
# Tokenize the prompts and completions.
prompt = dataset[i][0]
prompt_token_ids = tokenizer(prompt).input_ids
completion = dataset[i][1]
completion_token_ids = tokenizer(completion).input_ids
prompt_len = len(prompt_token_ids)
output_len = len(completion_token_ids
) if fixed_output_len is None else fixed_output_len
if prompt_len < 4 or (fixed_output_len is None and output_len < 4):
# Prune too short sequences.
continue
if prompt_len > 1024 or prompt_len + output_len > 2048:
# Prune too long sequences.
continue
filtered_dataset.append((prompt, prompt_len, output_len, None))
return filtered_dataset
def sample_sonnet_requests(
dataset_path: str,
num_requests: int,
input_len: int,
output_len: int,
prefix_len: int,
tokenizer: PreTrainedTokenizerBase,
) -> List[Tuple[str, str, int, int, None]]:
assert (
input_len > prefix_len
), "'args.sonnet-input-len' must be greater than 'args.prefix-input-len'."
# Load the dataset.
with open(dataset_path, encoding='utf-8') as f:
poem_lines = f.readlines()
# Tokenize the poem lines.
poem_token_ids = tokenizer(poem_lines).input_ids
average_poem_len = sum(
len(token_ids) for token_ids in poem_token_ids) / len(poem_token_ids)
# Base prefix for all requests.
base_prompt = "Pick as many lines as you can from these poem lines:\n"
base_message = [{
"role": "user",
"content": base_prompt,
}]
base_prompt_formatted = tokenizer.apply_chat_template(
base_message, add_generation_prompt=True, tokenize=False)
base_prompt_offset = len(tokenizer(base_prompt_formatted).input_ids)
assert (
input_len > base_prompt_offset
), f"Please set 'args.sonnet-input-len' higher than {base_prompt_offset}."
num_input_lines = round(
(input_len - base_prompt_offset) / average_poem_len)
# First approximately `prefix_len` number of tokens in the
# prompt are fixed poem lines.
assert (
prefix_len > base_prompt_offset
), f"Please set 'args.sonnet-prefix-len' higher than {base_prompt_offset}."
num_prefix_lines = round(
(prefix_len - base_prompt_offset) / average_poem_len)
prefix_lines = poem_lines[:num_prefix_lines]
# Sample the rest of lines per request.
sampled_requests: List[Tuple[str, int, int]] = []
for _ in range(num_requests):
num_lines_needed = num_input_lines - num_prefix_lines
sampled_lines = "".join(prefix_lines +
random.choices(poem_lines, k=num_lines_needed))
prompt = f"{base_prompt}{sampled_lines}"
message = [
{
"role": "user",
"content": prompt,
},
]
prompt_formatted = tokenizer.apply_chat_template(
message, add_generation_prompt=True, tokenize=False)
prompt_len = len(tokenizer(prompt_formatted).input_ids)
sampled_requests.append(
(prompt, prompt_formatted, prompt_len, output_len, None))
return sampled_requests
def sample_vision_arena_requests(
dataset,
num_requests: int,
tokenizer: PreTrainedTokenizerBase,
fixed_output_len: Optional[int] = None,
) -> List[Tuple[str, str, int, Optional[Dict[str, Collection[str]]]]]:
sampled_requests: List[Tuple[str, int, int, Dict[str,
Collection[str]]]] = []
for data in dataset:
if len(sampled_requests) == num_requests:
break
prompt = data["turns"][0][0]['content']
prompt_token_ids = tokenizer(prompt).input_ids
if fixed_output_len is None:
# Default max output len is set to 128
print("--hf-output-len is not provided. Using default value 128.")
fixed_output_len = 128
prompt_len = len(prompt_token_ids)
output_len = fixed_output_len
assert isinstance(
data["images"][0],
Image), ("Input image format must be `PIL.Image.Image`, "
f"given {type(data['image'])}.")
image: Image = data["images"][0]
image = image.convert("RGB")
image_data = io.BytesIO()
image.save(image_data, format='JPEG')
image_base64 = base64.b64encode(image_data.getvalue()).decode("utf-8")
mm_content = {
"type": "image_url",
"image_url": {
"url": f"data:image/jpeg;base64,{image_base64}"
},
}
sampled_requests.append((prompt, prompt_len, output_len, mm_content))
return sampled_requests
def sample_hf_requests(
dataset_path: str,
dataset_subset: Optional[str],
dataset_split: str,
num_requests: int,
tokenizer: PreTrainedTokenizerBase,
random_seed: int,
fixed_output_len: Optional[int] = None,
) -> List[Tuple[str, str, int, Optional[Dict[str, Collection[str]]]]]:
# Special case for vision_arena dataset
if dataset_path == 'lmarena-ai/vision-arena-bench-v0.1' \
and dataset_subset is None:
assert dataset_split == "train"
dataset = load_dataset(dataset_path,
name=dataset_subset,
split=dataset_split,
streaming=True)
dataset = dataset.shuffle(seed=random_seed)
return sample_vision_arena_requests(dataset, num_requests, tokenizer,
fixed_output_len)
dataset = load_dataset(dataset_path,
name=dataset_subset,
split=dataset_split,
streaming=True)
assert "conversations" in dataset.features, (
"HF Dataset must have 'conversations' column.")
filter_func = lambda x: len(x["conversations"]) >= 2
filtered_dataset = dataset.shuffle(seed=random_seed).filter(filter_func)
sampled_requests: List[Tuple[str, int, int, Dict[str,
Collection[str]]]] = []
for data in filtered_dataset:
if len(sampled_requests) == num_requests:
break
# Tokenize the prompts and completions.
prompt = data["conversations"][0]["value"]
prompt_token_ids = tokenizer(prompt).input_ids
completion = data["conversations"][1]["value"]
completion_token_ids = tokenizer(completion).input_ids
prompt_len = len(prompt_token_ids)
output_len = len(completion_token_ids
) if fixed_output_len is None else fixed_output_len
if fixed_output_len is None and (prompt_len < 4 or output_len < 4):
# Prune too short sequences.
continue
if fixed_output_len is None and \
(prompt_len > 1024 or prompt_len + output_len > 2048):
# Prune too long sequences.
continue
if "image" in data and isinstance(data["image"], Image):
image: Image = data["image"]
image = image.convert("RGB")
image_data = io.BytesIO()
image.save(image_data, format='JPEG')
image_base64 = base64.b64encode(
image_data.getvalue()).decode("utf-8")
mm_content = {
"type": "image_url",
"image_url": {
"url": f"data:image/jpeg;base64,{image_base64}"
},
}
elif "image" in data and isinstance(data["image"], str):
if (data["image"].startswith("http://") or \
data["image"].startswith("file://")):
image_url = data["image"]
else:
image_url = f"file://{data['image']}"
mm_content = {
"type": "image_url",
"image_url": {
"url": image_url
},
}
else:
mm_content = None
sampled_requests.append((prompt, prompt_len, output_len, mm_content))
return sampled_requests
def sample_random_requests(
prefix_len: int,
input_len: int,
output_len: int,
num_prompts: int,
range_ratio: float,
tokenizer: PreTrainedTokenizerBase,
) -> List[Tuple[str, int, int]]:
prefix_token_ids = np.random.randint(0,
tokenizer.vocab_size,
size=prefix_len).tolist()
input_lens = np.random.randint(
int(input_len * range_ratio),
input_len + 1,
size=num_prompts,
)
output_lens = np.random.randint(
int(output_len * range_ratio),
output_len + 1,
size=num_prompts,
)
offsets = np.random.randint(0, tokenizer.vocab_size, size=num_prompts)
input_requests = []
for i in range(num_prompts):
prompt = tokenizer.decode(prefix_token_ids +
[(offsets[i] + i + j) % tokenizer.vocab_size
for j in range(input_lens[i])])
input_requests.append((prompt, int(prefix_len + input_lens[i]),
int(output_lens[i]), None))
return input_requests
async def get_request(
input_requests: List[Tuple[str, int, int]],
request_rate: float,
burstiness: float = 1.0,
) -> AsyncGenerator[Tuple[str, int, int], None]:
"""
Asynchronously generates requests at a specified rate
with OPTIONAL burstiness.
Args:
input_requests:
A list of input requests, each represented as a tuple.
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 = 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[Tuple[str, int, int]],
outputs: List[RequestFuncOutput],
dur_s: float,
tokenizer: PreTrainedTokenizerBase,
selected_percentile_metrics: List[str],
selected_percentiles: List[float],
goodput_config_dict: Dict[str, float],
) -> Tuple[BenchmarkMetrics, List[int]]:
actual_output_lens: List[int] = []
total_input = 0
completed = 0
good_completed = 0
itls: List[float] = []
tpots: List[float] = []
all_tpots: List[float] = []
ttfts: List[float] = []
e2els: List[float] = []
for i in range(len(outputs)):
if outputs[i].success:
output_len = outputs[i].output_tokens
if output_len is None:
# 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
output_len = len(
tokenizer(outputs[i].generated_text,
add_special_tokens=False).input_ids)
actual_output_lens.append(output_len)
total_input += input_requests[i][1]
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
ttfts.append(outputs[i].ttft)
e2els.append(outputs[i].latency)
completed += 1
else:
actual_output_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_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_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_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],
)
return metrics, actual_output_lens
async def benchmark(
backend: str,
api_url: str,
base_url: str,
model_id: str,
model_name: str,
tokenizer: PreTrainedTokenizerBase,
input_requests: List[Tuple[str, int, int]],
logprobs: Optional[int],
best_of: int,
request_rate: float,
burstiness: float,
disable_tqdm: bool,
profile: bool,
selected_percentile_metrics: List[str],
selected_percentiles: List[str],
ignore_eos: bool,
goodput_config_dict: Dict[str, float],
max_concurrency: Optional[int],
):
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_prompt_len, test_output_len, test_mm_content = (
input_requests[0])
if backend != "openai-chat" and test_mm_content is not None:
# multi-modal benchmark is only available on OpenAI Chat backend.
raise ValueError(
"Multi-modal content is only supported on 'openai-chat' backend.")
test_input = RequestFuncInput(
model=model_id,
model_name=model_name,
prompt=test_prompt,
api_url=api_url,
prompt_len=test_prompt_len,
output_len=test_output_len,
logprobs=logprobs,
best_of=best_of,
multi_modal_content=test_mm_content,
ignore_eos=ignore_eos,
)
test_output = await request_func(request_func_input=test_input)
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 profile:
print("Starting profiler...")
profile_input = RequestFuncInput(model=model_id,
model_name=model_name,
prompt=test_prompt,
api_url=base_url + "/start_profile",
prompt_len=test_prompt_len,
output_len=test_output_len,
logprobs=logprobs,
best_of=best_of,
multi_modal_content=test_mm_content,
ignore_eos=ignore_eos)
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, prompt_len, output_len, mm_content = request
request_func_input = RequestFuncInput(model=model_id,
model_name=model_name,
prompt=prompt,
api_url=api_url,
prompt_len=prompt_len,
output_len=output_len,
logprobs=logprobs,
best_of=best_of,
multi_modal_content=mm_content,
ignore_eos=ignore_eos)
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",
prompt_len=test_prompt_len,
output_len=test_output_len,
logprobs=logprobs,
best_of=best_of,
)
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_percentile_metrics=selected_percentile_metrics,
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} {:<10.2f}".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],
"output_lens": actual_output_lens,
"ttfts": [output.ttft for output in outputs],
"itls": [output.itl for output in outputs],
"generated_texts": [output.generated_text 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
process_one_metric("ttft", "TTFT", "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("e2el", "E2EL", "End-to-end Latency")
print("=" * 50)
return result
def check_goodput_args(args):
# 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):
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 main(args: argparse.Namespace):
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}"
tokenizer = get_tokenizer(tokenizer_id,
tokenizer_mode=tokenizer_mode,
trust_remote_code=args.trust_remote_code)
if args.dataset is not None:
warnings.warn(
"The '--dataset' argument will be deprecated in the next "
"release. Please use '--dataset-name' and "
"'--dataset-path' in the future runs.",
stacklevel=2)
input_requests = sample_sharegpt_requests(
dataset_path=args.dataset,
num_requests=args.num_prompts,
tokenizer=tokenizer,
fixed_output_len=args.sharegpt_output_len,
)
elif args.dataset_name == "sharegpt":
input_requests = sample_sharegpt_requests(
dataset_path=args.dataset_path,
num_requests=args.num_prompts,
tokenizer=tokenizer,
fixed_output_len=args.sharegpt_output_len,
)
elif args.dataset_name == "sonnet":
# Do not format the prompt, pass to message directly
if args.backend == "openai-chat":
input_requests = sample_sonnet_requests(
dataset_path=args.dataset_path,
num_requests=args.num_prompts,
input_len=args.sonnet_input_len,
output_len=args.sonnet_output_len,
prefix_len=args.sonnet_prefix_len,
tokenizer=tokenizer,
)
input_requests = [(prompt, prompt_len, output_len, None)
for prompt, prompt_formatted, prompt_len,
output_len, _ in input_requests]
else:
assert (
tokenizer.chat_template or tokenizer.default_chat_template
), "Tokenizer/model must have chat template for sonnet dataset."
input_requests = sample_sonnet_requests(
dataset_path=args.dataset_path,
num_requests=args.num_prompts,
input_len=args.sonnet_input_len,
output_len=args.sonnet_output_len,
prefix_len=args.sonnet_prefix_len,
tokenizer=tokenizer,
)
input_requests = [(prompt_formatted, prompt_len, output_len, None)
for prompt, prompt_formatted, prompt_len,
output_len, _ in input_requests]
elif args.dataset_name == "hf":
input_requests = sample_hf_requests(
dataset_path=args.dataset_path,
dataset_subset=args.hf_subset,
dataset_split=args.hf_split,
num_requests=args.num_prompts,
tokenizer=tokenizer,
random_seed=args.seed,
fixed_output_len=args.hf_output_len,
)
elif args.dataset_name == "random":
input_requests = sample_random_requests(
prefix_len=args.random_prefix_len,
input_len=args.random_input_len,
output_len=args.random_output_len,
num_prompts=args.num_prompts,
range_ratio=args.random_range_ratio,
tokenizer=tokenizer,
)
else:
raise ValueError(f"Unknown dataset: {args.dataset_name}")
goodput_config_dict = check_goodput_args(args)
# Avoid GC processing "static" data - reduce pause times.
gc.collect()
gc.freeze()
benchmark_result = asyncio.run(
benchmark(
backend=backend,
api_url=api_url,
base_url=base_url,
model_id=model_id,
model_name=model_name,
tokenizer=tokenizer,
input_requests=input_requests,
logprobs=args.logprobs,
best_of=args.best_of,
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,
))
# 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["best_of"] = args.best_of
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."
)
# 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)
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.",
)
parser.add_argument("--host", type=str, default="localhost")
parser.add_argument("--port", type=int, default=8000)
parser.add_argument(
"--endpoint",
type=str,
default="/v1/completions",
help="API endpoint.",
)
parser.add_argument(
"--dataset",
type=str,
default=None,
help="Path to the ShareGPT dataset, will be deprecated in the "
"next release.",
)
parser.add_argument(
"--dataset-name",
type=str,
default="sharegpt",
choices=["sharegpt", "sonnet", "random", "hf"],
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(
"--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(
"--best-of",
type=int,
default=1,
help="Generates `best_of` sequences per prompt and "
"returns the best one.",
)
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(
"--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-seperated 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-seperated 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=1.0,
help="Range of sampled ratio of input/output length, "
"used only for random sampling.",
)
random_group.add_argument(
"--random-prefix-len",
type=int,
default=0,
help="Number of fixed prefix tokens before random "
" context. The length range of context in a random "
" request is [random-prefix-len, "
" random-prefix-len + random-prefix-len * random-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.",
)
parser.add_argument(
'--tokenizer-mode',
type=str,
default="auto",
choices=['auto', 'slow', 'mistral'],
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.')
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. ")
args = parser.parse_args()
main(args)
072/benchmark_throughput_0.7.2.py 0 → 100644
View file @ 49c10c0c
# SPDX-License-Identifier: Apache-2.0
"""Benchmark offline inference throughput."""
import argparse
import dataclasses
import json
import random
import time
from functools import cache
from typing import Dict, List, Optional, Tuple
import numpy as np
import torch
import uvloop
from PIL import Image
from tqdm import tqdm
from transformers import (AutoModelForCausalLM, AutoTokenizer,
PreTrainedTokenizerBase)
from vllm.inputs import PromptType
from vllm.engine.arg_utils import AsyncEngineArgs, EngineArgs
from vllm.entrypoints.openai.api_server import (
build_async_engine_client_from_engine_args)
from vllm.inputs import TextPrompt
from vllm.lora.request import LoRARequest
from vllm.lora.utils import get_adapter_absolute_path
from vllm.multimodal import MultiModalDataDict
from vllm.sampling_params import BeamSearchParams
from vllm.transformers_utils.tokenizer import AnyTokenizer, get_lora_tokenizer
from vllm.utils import FlexibleArgumentParser, merge_async_iterators
@dataclasses.dataclass
class SampleRequest:
"""A class representing a single inference request for benchmarking.
Attributes:
prompt: The input text prompt for the model.
prompt_len: The length of the prompt in tokens.
expected_output_len: The expected length of the output in tokens.
multi_modal_data: Optional dictionary containing multi-modal data (e.g.
images).
lora_request: Optional LoRARequest specifying the LoRA to use.
"""
prompt: str
prompt_len: int
expected_output_len: int
multi_modal_data: Optional[MultiModalDataDict] = None
lora_request: Optional[LoRARequest] = None
def _get_prompt_for_image_model(question: str, *, model: str) -> str:
"""Prepend and append special tokens around the question to form a prompt.
Args:
question: The input question text to wrap with special tokens
model: The name of the model being used, to determine which special
tokens to add
Returns:
The formatted prompt string with appropriate special tokens for the
model
Raises:
ValueError: If an unsupported model name is provided
"""
model = model.lower()
if "pixtral" in model:
return f"<s>[INST]{question}\n[IMG][/INST]"
raise ValueError(f"Unsupported model {model}")
@cache
def lora_path_on_disk(lora_path: str) -> str:
return get_adapter_absolute_path(lora_path)
lora_tokenizer_cache: Dict[int, AnyTokenizer] = {}
def get_random_lora_request(
args: argparse.Namespace
) -> Tuple[LoRARequest, Optional[AnyTokenizer]]:
global lora_tokenizer_cache
lora_id = random.randint(1, args.max_loras)
lora_request = LoRARequest(lora_name=str(lora_id),
lora_int_id=lora_id,
lora_path=lora_path_on_disk(args.lora_path))
if lora_id not in lora_tokenizer_cache:
lora_tokenizer_cache[lora_id] = get_lora_tokenizer(lora_request)
return lora_request, lora_tokenizer_cache[lora_id]
def sample_requests(tokenizer: PreTrainedTokenizerBase,
args: argparse.Namespace) -> List[SampleRequest]:
dataset_path: str = args.dataset
num_requests: int = args.num_prompts
fixed_output_len: Optional[int] = args.output_len
model: str = args.model
if fixed_output_len is not None and fixed_output_len < 4:
raise ValueError("output_len too small")
# Load the dataset.
with open(dataset_path) as f:
dataset = json.load(f)
# Filter out the conversations with less than 2 turns.
dataset = [data for data in dataset if len(data["conversations"]) >= 2]
# Shuffle the dataset.
random.shuffle(dataset)
# Filter out sequences that are too long or too short
filtered_dataset: List[SampleRequest] = []
for data in tqdm(dataset,
total=len(filtered_dataset),
desc="sampling requests"):
if len(filtered_dataset) == num_requests:
break
# Only keep the first two turns of each conversation.
prompt = data["conversations"][0]["value"]
completion = data["conversations"][1]["value"]
multi_modal_data: Optional[MultiModalDataDict] = None
if "image" in data:
multi_modal_data = multi_modal_data or {}
image_path = data["image"]
# TODO(vllm-project/vllm/issues/9778): Support multiple images.
assert isinstance(image_path,
str), "Only support single image input"
try:
multi_modal_data["image"] = Image.open(image_path).convert(
"RGB")
except FileNotFoundError:
# Ignore datapoint where asset is missing
continue
prompt = _get_prompt_for_image_model(question=prompt, model=model)
request_tokenizer = tokenizer
lora_request: Optional[LoRARequest] = None
if args.enable_lora:
lora_request, lora_tokenizer = get_random_lora_request(args)
if lora_tokenizer:
request_tokenizer = lora_tokenizer
# Tokenize the prompts and completions.
prompt_token_ids = request_tokenizer(prompt).input_ids
completion_token_ids = request_tokenizer(completion).input_ids
prompt_len = len(prompt_token_ids)
output_len = len(completion_token_ids
) if fixed_output_len is None else fixed_output_len
if prompt_len < 4 or output_len < 4:
# Prune too short sequences.
continue
if prompt_len > 1024 or prompt_len + output_len > 2048:
# Prune too long sequences.
continue
filtered_dataset.append(
SampleRequest(prompt=prompt,
prompt_len=prompt_len,
expected_output_len=output_len,
multi_modal_data=multi_modal_data,
lora_request=lora_request))
return filtered_dataset
def run_vllm(
requests_json: List[SampleRequest],
n: int,
num_iters_warmup: int,
engine_args: EngineArgs,
) -> float:
from vllm import LLM, SamplingParams
llm = LLM(**dataclasses.asdict(engine_args))
# warmup
warmup_sampling_params = SamplingParams(
n=args.n,
temperature=1.0,
top_p=1.0,
ignore_eos=True,
max_tokens=10,
)
dummy_prompt_token_ids = np.random.randint(10000, size=(1,10))
dummy_prompts: List[PromptType] = [{
"prompt_token_ids": batch
} for batch in dummy_prompt_token_ids.tolist()]
print("Warming up...")
for _ in tqdm(range(num_iters_warmup), desc="Warmup iterations"):
llm.generate(dummy_prompts,
sampling_params=warmup_sampling_params,
use_tqdm=False)
info_json={}
for ELEprompt in args.num_prompts:
for ELEinput,ELEoutput in zip(args.input_len,args.output_len):
info={}
requests=requests_json["{}_{}_{}".format(ELEprompt,ELEinput,ELEoutput)]
# Add the requests to the engine.
prompts: List[TextPrompt] = []
sampling_params: List[SamplingParams] = []
for request in requests:
prompts.append(
TextPrompt(prompt=request.prompt,
multi_modal_data=request.multi_modal_data))
sampling_params.append(
SamplingParams(
n=n,
temperature=1.0,
top_p=1.0,
ignore_eos=True,
max_tokens=request.expected_output_len,
))
lora_requests: Optional[List[LoRARequest]] = None
if engine_args.enable_lora:
lora_requests = [request.lora_request for request in requests]
use_beam_search = False
if not use_beam_search:
start = time.perf_counter()
real_output=llm.generate(prompts,
sampling_params,
lora_request=lora_requests,
use_tqdm=True)
end = time.perf_counter()
else:
assert lora_requests is None, "BeamSearch API does not support LoRA"
prompts = [request.prompt for request in requests]
# output_len should be the same for all requests.
output_len = requests[0][2]
for request in requests:
assert request.expected_output_len == output_len
start = time.perf_counter()
real_output = llm.beam_search(
prompts,
BeamSearchParams(
beam_width=n,
max_tokens=output_len,
ignore_eos=True,
))
end = time.perf_counter()
total_ttfts = []
total_tpops = []
total_output_token_throughput = []
total_inout_token_throughput = []
for output in real_output:
ttft_ = output.metrics.first_token_time - output.metrics.arrival_time
tpop_ = (output.metrics.finished_time - output.metrics.arrival_time - ttft_) / (ELEoutput-1)
output_token_throughput = (ELEoutput) / (output.metrics.finished_time - output.metrics.arrival_time)
inout_token_throughput = (ELEoutput + ELEinput) / (output.metrics.finished_time - output.metrics.arrival_time)
total_ttfts.append(ttft_)
total_tpops.append(tpop_)
total_output_token_throughput.append(output_token_throughput)
total_inout_token_throughput.append(inout_token_throughput)
total_num_tokens = sum(request.prompt_len + request.expected_output_len
for request in requests)
total_output_tokens = sum(request.expected_output_len
for request in requests)
# ttft_mean = np.mean(total_ttfts)
# ttft_median = np.median(total_ttfts or 0)
# ttft_p99 = np.percentile(total_ttfts or 0, 99)
# tpop_mean = np.mean(total_tpops)
# tpop_median = np.median(total_tpops or 0)
# tpop_p99 = np.percentile(total_tpops or 0, 99)
# output_token_throughput_mean = np.mean(total_output_token_throughput)
# output_token_throughput_median = np.median(total_output_token_throughput or 0)
# output_token_throughput_p99 = np.percentile(total_output_token_throughput or 0, 99)
# inout_token_throughput_mean = np.mean(total_inout_token_throughput)
# inout_token_throughput_median = np.median(total_inout_token_throughput or 0)
# inout_token_throughput_p99 = np.percentile(total_inout_token_throughput or 0, 99)
info["elapsed_time"] = np.around(end - start,2)
info["Throughput"] = np.around(len(requests) / info['elapsed_time'],2)
info["total_tokens"] = np.around(total_num_tokens / info['elapsed_time'],2)
info["output_tokens"] = np.around(total_output_tokens / info['elapsed_time'],2)
info["ttft_mean"] = np.around(np.mean(total_ttfts),5)
info["ttft_median"] = np.around(np.median(total_ttfts or 0),5)
info["ttft_p99"] = np.around(np.percentile(total_ttfts or 0, 99),5)
info["tpop_mean"] = np.around(np.mean(total_tpops),4)
info["tpop_median"] = np.around(np.median(total_tpops or 0),5)
info["tpop_p99"] = np.around(np.percentile(total_tpops or 0, 99),5)
info["output_token_throughput_mean"] = np.around(np.mean(total_output_token_throughput),2)
info["output_token_throughput_median"] = np.around(np.median(total_output_token_throughput or 0),2)
info["output_token_throughput_p99"] = np.around(np.percentile(total_output_token_throughput or 0, 99),2)
info["inout_token_throughput_mean"] = np.around(np.mean(total_inout_token_throughput),2)
info["inout_token_throughput_median"] = np.around(np.median(total_inout_token_throughput or 0),2)
info["inout_token_throughput_p99"] = np.around(np.percentile(total_inout_token_throughput or 0, 99),2)
info_json["{}_{}_{}".format(ELEprompt,ELEinput,ELEoutput)] = info
print("promt:{},input:{},output:{}".format(ELEprompt,ELEinput,ELEoutput))
print(f"Latency: {info['elapsed_time']:.2f} s")
print(f"Throughput: {len(requests) / info['elapsed_time']:.2f} requests/s, "
f"{total_num_tokens / info['elapsed_time']:.2f} total tokens/s, "
f"{total_output_tokens / info['elapsed_time']:.2f} output tokens/s")
print("==============================================")
print(f"total_out_tokens: {total_output_tokens: .2f} tokens")
print(f"elapsed_time: {info['elapsed_time']: .2f} s") # 总耗时
print(f"TTFT_mean: {info['ttft_mean']: .5f} s") # 首字延时
print(f"ttft_p99: {info['ttft_p99']: .5f} s")
print(f"ttft_median: {info['ttft_median']: .5f} s")
print(f"TPOP_mean: {info['tpop_mean']: .5f} s") # 单字decode时间
print(f"tpop_median: {info['tpop_median']: .5f} s")
print(f"tpop_p99: {info['tpop_p99']: .5f} s")
print(f"output_token_throughput_mean: {info['output_token_throughput_mean']:.2f} tokens/s") # 单路生成吞吐
print(f"output_token_throughput_median: {info['output_token_throughput_median']:.2f} tokens/s")
print(f"output_token_throughput_p99: {info['output_token_throughput_p99']:.2f} tokens/s")
print(f"inout_token_throughput_mean: {info['inout_token_throughput_mean']:.2f} tokens/s") # 单路总吞吐
print(f"tinout_token_throughput_median: {info['inout_token_throughput_median']:.2f} tokens/s")
print(f"inout_token_throughput_p99: {info['inout_token_throughput_p99']:.2f} tokens/s")
print("==============================================")
print("\n")
return info_json
async def run_vllm_async(
requests: List[SampleRequest],
n: int,
engine_args: AsyncEngineArgs,
disable_frontend_multiprocessing: bool = False,
) -> float:
from vllm import SamplingParams
async with build_async_engine_client_from_engine_args(
engine_args, disable_frontend_multiprocessing) as llm:
# Add the requests to the engine.
prompts: List[TextPrompt] = []
sampling_params: List[SamplingParams] = []
lora_requests: List[Optional[LoRARequest]] = []
for request in requests:
prompts.append(
TextPrompt(prompt=request.prompt,
multi_modal_data=request.multi_modal_data))
sampling_params.append(
SamplingParams(
n=n,
temperature=1.0,
top_p=1.0,
ignore_eos=True,
max_tokens=request.expected_output_len,
))
lora_requests.append(request.lora_request)
generators = []
start = time.perf_counter()
for i, (prompt, sp,
lr) in enumerate(zip(prompts, sampling_params, lora_requests)):
generator = llm.generate(prompt,
sp,
lora_request=lr,
request_id=f"test{i}")
generators.append(generator)
all_gens = merge_async_iterators(*generators)
async for i, res in all_gens:
pass
end = time.perf_counter()
return end - start
def run_hf(
requests: List[SampleRequest],
model: str,
tokenizer: PreTrainedTokenizerBase,
n: int,
max_batch_size: int,
trust_remote_code: bool,
) -> float:
llm = AutoModelForCausalLM.from_pretrained(
model, torch_dtype=torch.float16, trust_remote_code=trust_remote_code)
if llm.config.model_type == "llama":
# To enable padding in the HF backend.
tokenizer.pad_token = tokenizer.eos_token
llm = llm.cuda()
pbar = tqdm(total=len(requests))
start = time.perf_counter()
batch: List[str] = []
max_prompt_len = 0
max_output_len = 0
for i in range(len(requests)):
prompt, prompt_len, output_len = requests[i]
# Add the prompt to the batch.
batch.append(prompt)
max_prompt_len = max(max_prompt_len, prompt_len)
max_output_len = max(max_output_len, output_len)
if len(batch) < max_batch_size and i != len(requests) - 1:
# Check if we can add more requests to the batch.
_, next_prompt_len, next_output_len = requests[i + 1]
if (max(max_prompt_len, next_prompt_len) +
max(max_output_len, next_output_len)) <= 2048:
# We can add more requests to the batch.
continue
# Generate the sequences.
input_ids = tokenizer(batch, return_tensors="pt",
padding=True).input_ids
llm_outputs = llm.generate(
input_ids=input_ids.cuda(),
do_sample=True,
num_return_sequences=n,
temperature=1.0,
top_p=1.0,
use_cache=True,
max_new_tokens=max_output_len,
)
# Include the decoding time.
tokenizer.batch_decode(llm_outputs, skip_special_tokens=True)
pbar.update(len(batch))
# Clear the batch.
batch = []
max_prompt_len = 0
max_output_len = 0
end = time.perf_counter()
return end - start
def run_mii(
requests: List[SampleRequest],
model: str,
tensor_parallel_size: int,
output_len: int,
) -> float:
from mii import client, serve
llm = serve(model, tensor_parallel=tensor_parallel_size)
prompts = [request.prompt for request in requests]
start = time.perf_counter()
llm.generate(prompts, max_new_tokens=output_len)
end = time.perf_counter()
client = client(model)
client.terminate_server()
return end - start
def main(args: argparse.Namespace):
print(args)
random.seed(args.seed)
# Sample the requests.
tokenizer = AutoTokenizer.from_pretrained(
args.tokenizer, trust_remote_code=args.trust_remote_code)
if args.dataset is None:
vocab_size = tokenizer.vocab_size
requests_json={}
for ELEprompt in args.num_prompts:
for ELEinput,ELEoutput in zip(args.input_len,args.output_len):
requests = []
for _ in range(ELEprompt):
request_tokenizer = tokenizer
lora_request: Optional[LoRARequest] = None
if args.enable_lora:
lora_request, lora_tokenizer = get_random_lora_request(args)
if lora_tokenizer:
request_tokenizer = lora_tokenizer
# Synthesize a prompt with the given input length.
candidate_ids = [
random.randint(0, vocab_size - 1)
for _ in range(ELEinput)
]
# As tokenizer may add additional tokens like BOS, we need to try
# different lengths to get the desired input length.
for _ in range(5): # Max attempts to correct
candidate_prompt = request_tokenizer.decode(candidate_ids)
tokenized_len = len(request_tokenizer.encode(candidate_prompt))
if tokenized_len == ELEinput:
break
# Adjust length based on difference
diff = ELEinput - tokenized_len
if diff > 0:
candidate_ids.extend([
random.randint(100, vocab_size - 100)
for _ in range(diff)
])
else:
candidate_ids = candidate_ids[:diff]
requests.append(
SampleRequest(prompt=candidate_prompt,
prompt_len=ELEinput,
expected_output_len=ELEoutput,
lora_request=lora_request))
requests_json["{}_{}_{}".format(ELEprompt,ELEinput,ELEoutput)]=requests
else:
requests = sample_requests(tokenizer, args)
is_multi_modal = any(request.multi_modal_data is not None
for request in requests)
if args.backend == "vllm":
if args.async_engine:
elapsed_time = uvloop.run(
run_vllm_async(
requests,
args.n,
AsyncEngineArgs.from_cli_args(args),
args.disable_frontend_multiprocessing,
))
else:
info_json = run_vllm(requests_json, args.n, args.num_iters_warmup,
EngineArgs.from_cli_args(args))
elif args.backend == "hf":
assert args.tensor_parallel_size == 1
elapsed_time = run_hf(requests, args.model, tokenizer, args.n,
args.hf_max_batch_size, args.trust_remote_code)
elif args.backend == "mii":
elapsed_time = run_mii(requests, args.model, args.tensor_parallel_size,
args.output_len)
else:
raise ValueError(f"Unknown backend: {args.backend}")
# file_name=args.model.rsplit("/")[-1]+"-tp"+str(args.tensor_parallel_size)+".txt"
if is_multi_modal:
print("\033[91mWARNING\033[0m: Multi-modal request detected. The "
"following metrics are not accurate because image tokens are not"
" counted. See vllm-project/vllm/issues/9778 for details.")
with open(args.output_json,"w") as f:
title="bs_in_out"
data_keys=info_json[list(info_json.keys())[0]].keys()
keys_string = ','.join(data_keys)
title=title+","+keys_string
f.write(title)
f.write("\n")
for key, value in info_json.items():
values_as_strings = [str(value) for value in info_json[key].values()]
values_string = ','.join(values_as_strings)
key=key+","+values_string
f.writelines(key)
f.write("\n")
# json.dump(info_json, f, indent=4)
# Output JSON results if specified
# if args.output_json:
# results = {
# "elapsed_time": elapsed_time,
# "num_requests": len(requests),
# "total_num_tokens": total_num_tokens,
# "requests_per_second": len(requests) / elapsed_time,
# "tokens_per_second": total_num_tokens / elapsed_time,
# }
# with open(args.output_json, "w") as f:
# json.dump(results, f, indent=4)
if __name__ == "__main__":
parser = FlexibleArgumentParser(description="Benchmark the throughput.")
parser.add_argument("--backend",
type=str,
choices=["vllm", "hf", "mii"],
default="vllm")
parser.add_argument("--dataset",
type=str,
default=None,
help="Path to the dataset. The dataset is expected to "
"be a json in form of List[Dict[..., conversations: "
"List[Dict[..., value: <prompt_or_response>]]]]")
parser.add_argument("--input-len",
type=int,
nargs="*",
default=None,
help="Input prompt length for each request")
parser.add_argument("--output-len",
type=int,
nargs="*",
default=None,
help="Output length for each request. Overrides the "
"output length from the dataset.")
parser.add_argument("--n",
type=int,
default=1,
help="Number of generated sequences per prompt.")
parser.add_argument('--num-iters-warmup',
type=int,
default=1,
help='Number of iterations to run for warmup.')
parser.add_argument("--num-prompts",
type=int,
nargs="*",
default=1000,
help="Number of prompts to process.")
parser.add_argument("--hf-max-batch-size",
type=int,
default=None,
help="Maximum batch size for HF backend.")
parser.add_argument(
'--output-json',
type=str,
default=None,
help='Path to save the throughput results in JSON format.')
parser.add_argument("--async-engine",
action='store_true',
default=False,
help="Use vLLM async engine rather than LLM class.")
parser.add_argument("--disable-frontend-multiprocessing",
action='store_true',
default=False,
help="Disable decoupled async engine frontend.")
# LoRA
parser.add_argument(
"--lora-path",
type=str,
default=None,
help="Path to the lora adapters to use. This can be an absolute path, "
"a relative path, or a Hugging Face model identifier.")
parser = AsyncEngineArgs.add_cli_args(parser)
args = parser.parse_args()
if args.tokenizer is None:
args.tokenizer = args.model
if args.dataset is None:
assert args.input_len is not None
assert args.output_len is not None
else:
assert args.input_len is None
if args.enable_lora:
assert args.lora_path is not None
if args.backend == "vllm":
if args.hf_max_batch_size is not None:
raise ValueError("HF max batch size is only for HF backend.")
elif args.backend == "hf":
if args.hf_max_batch_size is None:
raise ValueError("HF max batch size is required for HF backend.")
if args.quantization is not None:
raise ValueError("Quantization is only for vLLM backend.")
if args.enable_lora is not None:
raise ValueError("LoRA benchmarking is only supported for vLLM"
" backend")
elif args.backend == "mii":
if args.dtype != "auto":
raise ValueError("dtype must be auto for MII backend.")
if args.n != 1:
raise ValueError("n must be 1 for MII backend.")
if args.quantization is not None:
raise ValueError("Quantization is only for vLLM backend.")
if args.hf_max_batch_size is not None:
raise ValueError("HF max batch size is only for HF backend.")
if args.tokenizer != args.model:
raise ValueError("Tokenizer must be the same as the model for MII "
"backend.")
if args.enable_lora is not None:
raise ValueError("LoRA benchmarking is only supported for vLLM"
" backend")
main(args)
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