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DeepCompressor Logo

Model Compression Toolbox for Large Language Models and Diffusion Models

Apache License

News

  • [2024/11] 🔥 Our latest W4A4 diffusion model quantization work SVDQuant algorithm and Nunchaku system is publicly released! Check our paper!
  • [2024/05] 🔥 Our latest W4A8KV4 LLM quantization work QoQ algorithm and QServe system is publicly released! QoQ is short for quattuor-octō-quattuor which is 4-8-4 in latin. Check our paper!

Key Features

DeepCompressor is an open source model compression toolbox for large language models and diffusion models based on PyTorch. DeepCompressor currently supports fake quantization with any integer and floating-point data type within 8 bits, e.g., INT8, INT4 and FP4_E2M1. Here are examples that implement the following algorithms.

DeepCompressor also contains examples that integrate with other inference libraries.

Installation

Install from Source

  1. Clone this repository and navigate to deepcompressor folder
git clone https://github.com/mit-han-lab/deepcompressor
cd deepcompressor
  1. Install Package
conda env create -f environment.yml
poetry install

Highlights

SVDQuant: Absorbing Outliers by Low-Rank Components for 4-Bit Diffusion Models

[Website][Paper][Nunchaku Inference System]

Diffusion models have been proven highly effective at generating high-quality images. However, as these models grow larger, they require significantly more memory and suffer from higher latency, posing substantial challenges for deployment. In this work, we aim to accelerate diffusion models by quantizing their weights and activations to 4 bits. At such an aggressive level, both weights and activations are highly sensitive, where conventional post-training quantization methods for large language models like smoothing become insufficient. To overcome this limitation, we propose SVDQuant, a new 4-bit quantization paradigm. Different from smoothing which redistributes outliers between weights and activations, our approach absorbs these outliers using a low-rank branch. We first consolidate the outliers by shifting them from activations to weights, then employ a high-precision low-rank branch to take in the weight outliers with Singular Value Decomposition (SVD). This process eases the quantization on both sides. However, naïvely running the low-rank branch independently incurs significant overhead due to extra data movement of activations, negating the quantization speedup. To address this, we co-design an inference engine Nunchaku that fuses the kernels of the low-rank branch into those of the low-bit branch to cut off redundant memory access. It can also seamlessly support off-the-shelf low-rank adapters (LoRAs) without the need for re-quantization. Extensive experiments on SDXL, PixArt-∑, and FLUX.1 validate the effectiveness of SVDQuant in preserving image quality. We reduce the memory usage for the 12B FLUX.1 models by 3.5×, achieving 3.0× speedup over the 4-bit weight-only quantized baseline on the 16GB laptop 4090 GPU, paving the way for more interactive applications on PCs.

Teaser SVDQuant

Quality Evaluation

Below is the quality and similarity evaluated with 5000 samples from MJHQ-30K dataset. IR means ImageReward. Our 4-bit results outperform other 4-bit baselines, effectively preserving the visual quality of 16-bit models.

Model Precision Method FID ($\downarrow$) IR ($\uparrow$) LPIPS ($\downarrow$) PSNR( $\uparrow$)
FLUX.1-dev (50 Steps) BF16 -- 20.3 0.953 -- --
INT W8A8 Ours 20.4 0.948 0.089 27.0
W4A16 NF4 20.6 0.910 0.272 19.5
INT W4A4 Ours 19.86 0.932 0.254 20.1
FP W4A4 Ours 21.0 0.933 0.247 20.2
FLUX.1-schnell (4 Steps) BF16 -- 19.2 0.938 -- --
INT W8A8 Ours 19.2 0.966 0.120 22.9
W4A16 NF4 18.9 0.943 0.257 18.2
INT W4A4 Ours 18.4 0.969 0.292 17.5
FP W4A4 Ours 19.9 0.956 0.279 17.5
FP16 -- 16.6 0.944 -- --
PixArt-Sigma (20 Steps) INT W8A8 ViDiT-Q 15.7 0.944 0.137 22.5
INT W8A8 Ours 16.3 0.955 0.109 23.7
INT W4A8 ViDiT-Q 37.3 0.573 0.611 12.0
INT W4A4 Ours 20.1 0.898 0.394 16.2
FP W4A4 Ours 18.3 0.946 0.326 17.4

QServe: W4A8KV4 Quantization for Efficient LLM Serving

[Website][Paper][QoQ Algorithm Code][QServe GPU System]

Quantization can accelerate large language model (LLM) inference. Going beyond INT8 quantization, the research community is actively exploring even lower precision, such as INT4. Nonetheless, state-of-the-art INT4 quantization techniques only accelerate low-batch, edge LLM inference, failing to deliver performance gains in large-batch, cloud-based LLM serving. We uncover a critical issue: existing INT4 quantization methods suffer from significant runtime overhead (20-90%) when dequantizing either weights or partial sums on GPUs. To address this challenge, we introduce QoQ, a W4A8KV4 quantization algorithm with 4-bit weight, 8-bit activation, and 4-bit KV cache. QoQ stands for quattuor-octo-quattuor, which represents 4-8-4 in Latin. QoQ is implemented by the QServe inference library that achieves measured speedup. The key insight driving QServe is that the efficiency of LLM serving on GPUs is critically influenced by operations on low-throughput CUDA cores. Building upon this insight, in QoQ algorithm, we introduce progressive quantization that can allow low dequantization overhead in W4A8 GEMM. Additionally, we develop SmoothAttention to effectively mitigate the accuracy degradation incurred by 4-bit KV quantization. In the QServe system, we perform compute-aware weight reordering and take advantage of register-level parallelism to reduce dequantization latency. We also make fused attention memory-bound, harnessing the performance gain brought by KV4 quantization. As a result, QServe improves the maximum achievable serving throughput of Llama-3-8B by 1.2× on A100, 1.4× on L40S; and Qwen1.5-72B by 2.4× on A100, 3.5× on L40S, compared to TensorRT-LLM.

QoQ-QServe QoQ

Perplexity Evaluation

Below is the WikiText2 perplexity evaluated with 2048 sequence length. The lower is the better.

Methods Precision Llama-3.1 70B Llama-3.1 8B Llama-3 70B Llama-3 8B Llama-2 7B Llama-2 13B Llama-2 70B Llama 7B Llama 13B Llama 30B Mistral 7B Yi 34B
FP16 2.81 6.24 2.85 6.14 5.47 4.88 3.32 5.68 5.09 4.10 5.25 4.60
SmoothQuant W8A8 3.23 6.38 3.14 6.28 5.54 4.95 3.36 5.73 5.13 4.23 5.29 4.69
GPTQ-R W4A16 g128 3.46 6.64 3.42 6.56 5.63 4.99 3.43 5.83 5.20 4.22 5.39 4.68
AWQ W4A16 g128 3.22 6.60 3.20 6.54 5.60 4.97 3.41 5.78 5.19 4.21 5.37 4.67
QuaRot W4A4 5.97 8.32 6.75 8.33 6.19 5.45 3.83 6.34 5.58 4.64 5.77 NaN
Atom W4A4 g128 - - 4.33 7.78 6.12 5.31 3.73 6.25 5.52 4.61 5.76 4.97
QoQ W4A8KV4 3.69 6.91 3.65 6.84 5.75 5.11 3.51 5.92 5.27 4.32 5.45 4.73
QoQ W4A8KV4 g128 3.54 6.80 3.51 6.73 5.68 5.05 3.46 5.88 5.23 4.27 5.41 4.73

* SmoothQuant is evaluated with per-tensor static KV cache quantization.

Efficiency Benchmarks

When serving the large language models Llama-3-8B and Qwen1.5-72B on L40S and A100 GPUs, QServe demonstrates superior performance, achieving 1.2x-1.4x higher throughput compared to the leading industry solution, TensorRT-LLM, for Llama-3-8B, and a 2.4x-3.5x higher throughput for Qwen1.5-72B.

See more about benchmarking setting in QServe GPU Inference System.

L40S (48G) Llama-3-8B Llama-2-7B Mistral-7B Llama-2-13B Llama-30B Yi-34B Llama-2-70B Qwen-1.5-72B
TRT-LLM-FP16 1326 444 1566 92 OOM OOM OOM OOM
TRT-LLM-W4A16 1431 681 1457 368 148 313 119 17
TRT-LLM-W8A8 2634 1271 2569 440 123 364 OOM OOM
Atom-W4A4 -- 2120 -- -- -- -- -- --
QuaRot-W4A4 -- 805 -- 413 133 -- -- 15
QServe-W4A8KV4 3656 2394 3774 1327 504 869 286 59
Throughput Increase* 1.39x 1.13x 1.47x 3.02x 3.41x 2.39x 2.40x 3.47x
A100 (80G) Llama-3-8B Llama-2-7B Mistral-7B Llama-2-13B Llama-30B Yi-34B Llama-2-70B Qwen-1.5-72B
TRT-LLM-FP16 2503 1549 2371 488 80 145 OOM OOM
TRT-LLM-W4A16 2370 1549 2403 871 352 569 358 143
TRT-LLM-W8A8 2396 2334 2427 1277 361 649 235 53
Atom-W4A4 -- 1160 -- -- -- -- -- --
QuaRot-W4A4 -- 1370 -- 289 267 -- -- 68
QServe-W4A8KV4 3005 2908 2970 1741 749 803 419 340
Throughput Increase* 1.20x 1.25x 1.22x 1.36x 2.07x 1.23x 1.17x 2.38x

The absolute token generation throughputs of QServe and baseline systems (Unit: tokens/second. -- means unsupported). All experiments were conducted under the same device memory budget. Throughput increase of QServe is calculated with regard to the best baseline in each column.

Reference

If you find deepcompressor useful or relevant to your research, please kindly cite our paper:

@article{lin2024qserve,
  title={QServe: W4A8KV4 Quantization and System Co-design for Efficient LLM Serving},
  author={Lin*, Yujun and Tang*, Haotian and Yang*, Shang and Zhang, Zhekai and Xiao, Guangxuan and Gan, Chuang and Han, Song},
  journal={arXiv preprint arXiv:2405.04532},
  year={2024}
}

@article{
  li2024svdquant,
  title={SVDQuant: Absorbing Outliers by Low-Rank Components for 4-Bit Diffusion Models},
  author={Li*, Muyang and Lin*, Yujun and Zhang*, Zhekai and Cai, Tianle and Li, Xiuyu and Guo, Junxian and Xie, Enze and Meng, Chenlin and Zhu, Jun-Yan and Han, Song},
  journal={arXiv preprint arXiv:2411.05007},
  year={2024}
}

Related Projects

The following projects are highly related to QServe. Our group has developed full-stack application-algorithm-system-hardware support for efficient large models, receiving 9k+ GitHub stars and over 1M Huggingface community downloads.

You are also welcome to check out MIT HAN Lab for other exciting projects on Efficient Generative AI!

Acknowledgments

DeepCompressor is inspired by many open-source libraries, including (but not limited to) GPTQ, QuaRot and Atom.

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