Efficient, easy-to-use platform for inference and serving local LLMs including an OpenAI compatible API server.
- OpenAI compatible API server provided for serving LLMs.
- Highly extensible trait-based system to allow rapid implementation of new module pipelines,
- Streaming support in generation.
- Efficient management of key-value cache with PagedAttention.
- Continuous batching.
In-situ
quantization (andIn-situ
marlin format conversion)GPTQ/Marlin
format quantization (4-bit)
Currently, candle-vllm supports chat serving for the following models.
Model ID | Model Type | Supported | Speed (A100, BF16 ) |
Throughput (BF16 , bs=16 ) |
Quantized (A100, Q4K or Marlin ) |
Throughput (GTPQ/Marlin , bs=16 ) |
---|---|---|---|---|---|---|
#1 | LLAMA | ✅ | 65 tks/s (LLaMa3.1 8B) | 553 tks/s (LLaMa3.1 8B) | 75 tks/s (LLaMa3.1 8B), 115 tks/s (LLaMa3.1 8B, Marlin) | 968 tks/s (LLaMa3.1 8B) |
#2 | Mistral | ✅ | 70 tks/s (7B) | 585 tks/s (7B) | 96 tks/s (7B), 115 tks/s (7B, Marlin) | 981 tks/s (7B) |
#3 | Phi (v1, v1.5, v2) | ✅ | 97 tks/s (2.7B, F32+BF16) | TBD | - | TBD |
#4 | Phi-3 (3.8B, 7B) | ✅ | 107 tks/s (3.8B) | 744 tks/s (3.8B) | 135 tks/s (3.8B) | TBD |
#5 | Yi | ✅ | 75 tks/s (6B) | 566 tks/s (6B) | 105 tks/s (6B) | TBD |
#6 | StableLM | ✅ | 99 tks/s (3B) | TBD | - | TBD |
#7 | BigCode/StarCode | TBD | TBD | TBD | - | TBD |
#8 | ChatGLM | TBD | TBD | TBD | - | TBD |
#9 | QWen2 (1.8B, 7B) | ✅ | 148 tks/s (1.8B) | 784 tks/s (1.8B) | - | TBD |
#10 | Google Gemma | ✅ | 130 tks/s (2B) | TBD | 73 tks/s (Gemma2-9B, Marlin) | 587 tks/s (Gemma2-9B) |
#11 | Blip-large (Multimodal) | TBD | TBD | TBD | - | TBD |
#12 | Moondream-2 (Multimodal LLM) | TBD | TBD | TBD | - | TBD |
LLaMa3.1-8B-Marlin-A100.mp4
See this folder for some examples.
curl --proto '=https' --tlsv1.2 -sSf https://sh.rustup.rs | sh
sudo apt install libssl-dev
sudo apt install pkg-config
git clone [email protected]:EricLBuehler/candle-vllm.git
cd candle-vllm
cargo run --release -- --port 2000 --weight-path /home/llama2_7b/ llama
You may also run specific model using huggingface model-id, e.g.,
cargo run --release -- --port 2000 --model-id meta-llama/Llama-2-7b-chat-hf llama
Run latest LLaMa3.1 using local weights
cargo run --release -- --port 2000 --weight-path /home/Meta-Llama-3.1-8B-Instruct/ llama3 --temperature 0. --penalty 1.0
Refer to Marlin quantization below for running quantized GPTQ models.
Install ChatUI and its dependencies:
git clone [email protected]:guoqingbao/candle-vllm-demo.git
cd candle-vllm-demo
apt install npm #install npm if needed
npm install n -g #update node js if needed
n stable #update node js if needed
npm i -g pnpm #install pnpm manager
pnpm install #install ChatUI dependencies
Launching the ChatUI:
pnpm run dev # run the ChatUI
ENOSPC: System limit for number of file watchers reached
echo fs.inotify.max_user_watches=524288 | sudo tee -a /etc/sysctl.conf && sudo sysctl -p
curl -X POST "http://127.0.0.1:2000/v1/chat/completions" \
-H "Content-Type: application/json" \
-H "Authorization: Bearer YOUR_API_KEY" \
-d '{
"model": "llama7b",
"messages": [
{"role": "user", "content": "Explain how to best learn Rust."}
],
"temperature": 0.7,
"max_tokens": 128,
"stop": {"Single":"</s>"}
}'
Sample response:
{"id":"cmpl-53092967-c9cf-40e0-ae26-d7ac786d59e8","choices":[{"message":{"content":" Learning any programming language requires a combination of theory, practice, and dedication. Here are some steps and resources to help you learn Rust effectively:\n\n1. Start with the basics:\n\t* Understand the syntax and basic structure of Rust programs.\n\t* Learn about variables, data types, loops, and control structures.\n\t* Familiarize yourself with Rust's ownership system and borrowing mechanism.\n2. Read the Rust book:\n\t* The Rust book is an official resource that provides a comprehensive introduction to the language.\n\t* It covers topics such","role":"[INST]"},"finish_reason":"length","index":0,"logprobs":null}],"created":1718784498,"model":"llama7b","object":"chat.completion","usage":{"completion_tokens":129,"prompt_tokens":29,"total_tokens":158}}
In your terminal, install the openai
Python package by running pip install openai
. I use version 1.3.5
.
Then, create a new Python file and write the following code:
import openai
openai.api_key = "EMPTY"
openai.base_url = "http://localhost:2000/v1/"
completion = openai.chat.completions.create(
model="llama",
messages=[
{
"role": "user",
"content": "Explain how to best learn Rust.",
},
],
max_tokens = 64,
)
print(completion.choices[0].message.content)
After the candle-vllm
service is running, run the Python script and enjoy efficient inference with an OpenAI compatible API server!
Install openai API first
python3 -m pip install openai
Run the benchmark test
python3 examples/benchmark.py --batch 16 --max_tokens 1024
Refer to examples/benchmark.py
async def benchmark():
model = "mistral7b"
max_tokens = 1024
# 16 requests
prompts = ["Explain how to best learn Rust.",
"Please talk about deep learning in 100 words.",
"Do you know the capital city of China? Talk the details of you known.",
"Who is the best female actor in the world? Explain why.",
"How to dealing with depression?",
"How to make money in short time?",
"What is the future trend of large language model?",
"The famous tech companies in the world.",
"Explain how to best learn Rust.",
"Please talk about deep learning in 100 words.",
"Do you know the capital city of China? Talk the details of you known.",
"Who is the best female actor in the world? Explain why.",
"How to dealing with depression?",
"How to make money in short time?",
"What is the future trend of large language model?",
"The famous tech companies in the world."]
# send 16 chat requests at the same time
tasks: List[asyncio.Task] = []
for i in range(len(prompts)):
tasks.append(
asyncio.create_task(
chat_completion(model, max_tokens, prompts[i]))
)
# obtain the corresponding stream object for each request
outputs: List[Stream[ChatCompletionChunk]] = await asyncio.gather(*tasks)
# tasks for streaming chat responses
tasks_stream: List[asyncio.Task] = []
for i in range(len(outputs)):
tasks_stream.append(
asyncio.create_task(
stream_response(i, outputs[i]))
)
# gathering the response texts
outputs: List[(int, str)] = await asyncio.gather(*tasks_stream)
# print the results, you may find chat completion statistics in the backend server (i.e., candle-vllm)
for idx, output in outputs:
print("\n\n Response {}: \n\n {}".format(idx, output))
asyncio.run(benchmark())
Candle-vllm now supports GPTQ (Marlin kernel), you may supply the quant
(marlin) parameter if you have Marlin
format quantized weights, such as:
cargo run --release -- --port 2000 --dtype f16 --weight-path /home/Meta-Llama-3.1-8B-Instruct-GPTQ-INT4-Marlin/ llama3 --quant marlin --temperature 0. --penalty 1.
You may also use AutoGPTQ
to transform a model to marlin format by loading the (quantized) model, supplying the use_marlin=True
in AutoGPTQ
and resaving it with "save_pretrained".
Note: only 4-bit GPTQ (marlin format) quantization supported at the moment, and the input data type should be f16
(--dtype f16) or bf16
(--dtype bf16). You need rename the transformed marlin weight to "model.safetensors" and copy the "tokenizer.json" from the source model folder.
Candle-vllm now supports in-situ quantization, allowing the transformation of default weights (F32/F16/BF16) or 4-bit GPTQ
weights into any GGML format (or marlin format
) during model loading. This feature helps conserve GPU memory (or speedup inference performance through marlin kernel), making it more efficient for consumer-grade GPUs (e.g., RTX 4090). To use this feature, simply supply the quant parameter when running candle-vllm.
For unquantized models:
cargo run --release -- --port 2000 --weight-path /home/Meta-Llama-3.1-8B-Instruct/ llama3 --quant q4k
For quantized 4-bit GPTQ model:
cargo run --release -- --port 2000 --weight-path /home/mistral_7b-int4/ mistral --quant marlin
Options for quant
parameters: ["q4_0", "q4_1", "q5_0", "q5_1", "q8_0", "q2k", "q3k","q4k","q5k","q6k", "marlin"]
Please note:
-
It may takes few minutes to load F32/F16/BF16 models into quantized;
-
Marlin format in-situ conversion only support 4-bit GPTQ (with
sym=True
,groupsize=128
or -1,desc_act=False
).
For general configuration help, run cargo run -- --help
.
For model-specific help, run cargo run -- --port 2000 <MODEL_TYPE> --help
For local model weights, run cargo run --release -- --port 2000 --weight-path /home/llama2_7b/ llama
, change the path when needed.
MODEL_TYPE
= ["llama", "llama3", "mistral", "phi2", "phi3", "qwen2", "gemma", "yi", "stable-lm"]
WEIGHT_FILE_PATH
= Corresponding weight path for the given model type
cargo run --release -- --port 2000 --weight-path <WEIGHT_FILE_PATH> <MODEL_TYPE>
or
MODEL_ID
= Huggingface model id
cargo run --release -- --port 2000 --model-id <MODEL_ID> <MODEL_TYPE>
For kvcache configuration, set kvcache_mem_cpu
and kvcache_mem_gpu
, default 4GB CPU memory and 4GB GPU memory for kvcache.
For chat history settings, set record_conversation
to true
to let candle-vllm remember chat history. By default
, candle-vllm does not
record chat history; instead, the client sends both the messages and the contextual history to candle-vllm. If record_conversation is set to true
, the client sends only new chat messages to candle-vllm, and candle-vllm is responsible for recording the previous chat messages. However, this approach requires per-session chat recording, which is not yet implemented, so the default approach record_conversation=false
is recommended.
For chat streaming, the stream
flag in chat request need to be set to True
.
You may supply penalty
and temperature
to the model to prevent potential repetitions, for example:
cargo run --release -- --port 2000 --weight-path /home/mistral_7b/ mistral --repeat-last-n 64 --penalty 1.1 --temperature 0.7
--max-gen-tokens
parameter is used to control the maximum output tokens per chat response. The value will be set to 1/5 of max_sequence_len by default.
For consumer GPUs
, it is suggested to run the models under GGML formats (or Marlin format), e.g.,
cargo run --release -- --port 2000 --weight-path /home/Meta-Llama-3.1-8B-Instruct/ llama3 --quant q4k
where quant
is one of ["q4_0", "q4_1", "q5_0", "q5_1", "q8_0", "q2k", "q3k","q4k","q5k","q6k", "marlin"].
Installing candle-vllm
is as simple as the following steps. If you have any problems, please create an
issue.
The following features are planned to be implemented, but contributions are especially welcome:
- Sampling methods:
- Beam search (huggingface/candle#1319)
- More pipelines (from
candle-transformers
)
- Python implementation:
vllm-project
vllm
paper