Repository of AutoRound: Advanced Weight-Only Quantization Algorithm for LLMs
Project description
AutoRound
Advanced Weight-Only Quantization Algorithm for LLMs
AutoRound is an advanced weight-only quantization algorithm for low-bits LLM inference. It's tailored for a wide range of models and consistently delivers noticeable improvements, often significantly outperforming SignRound with the cost of more tuning time for quantization.
Our method adopts sign gradient descent to fine-tune rounding values and minmax values of weights in just 200 steps, which competes impressively against recent methods without introducing any additional inference overhead. The below image presents an overview of AutoRound.
What's New
- [2024/05] Check out our updated paper on arxiv
- [2024/05] AutoRound supports lm-head quantization, saving 0.7G for LLaMA3-8B at W4G128.
- [2024/05] AutoRound performs well in low_bit_open_llm_leaderboard
Prerequisites
- Python 3.9 or higher
Installation
Build from Source
pip install -r requirements.txt
python setup.py install
Install from pypi
pip install auto-round
Model quantization
Gaudi2/ CPU/ GPU
We found a significant accuracy discrepancy with the qdq model using the AutoGPTQ GPU backend with asymmetric quantization in some scenarios. Please switch to symmetric quantization to alleviate this issue.
from transformers import AutoModelForCausalLM, AutoTokenizer
model_name = "meta-llama/Llama-2-7b-hf"
model = AutoModelForCausalLM.from_pretrained(model_name, torch_dtype="auto", trust_remote_code=True)
tokenizer = AutoTokenizer.from_pretrained(model_name, trust_remote_code=True)
from auto_round import AutoRound
bits, group_size, sym = 4, 128, False
##device:Optional["auto", None, "hpu", "cpu", "cuda"]
autoround = AutoRound(model, tokenizer, bits=bits, group_size=group_size, sym=sym, device=None)
autoround.quantize()
output_dir = "./tmp_autoround"
autoround.save_quantized(output_dir)
Detailed Hyperparameters
-
model
: The PyTorch model to be quantized. -
tokenizer
: An optional tokenizer for processing input data. If none, a dataset must be provided. -
bits (int)
: Number of bits for quantization (default is 4). -
group_size (int)
: Size of the quantization group (default is 128). -
sym (bool)
: Whether to use symmetric quantization (default is False). -
enable_quanted_input (bool)
: Whether to use the output of the previous quantized block as the input for the current block for tuning (default is True). -
enable_minmax_tuning (bool)
: Whether to enable weight min-max tuning (default is True). -
iters (int)
: Number of tuning iterations (default is 200). -
lr (float)
: The learning rate for rounding value (default is None, it will be set to 1.0/iters automatically). -
minmax_lr (float)
: The learning rate for min-max tuning (default is None, it will be set to lr automatically). -
n_samples (int)
: Number of samples for tuning (default is 512). -
seqlen (int)
: Data length of the sequence for tuning (default is 2048). -
batch_size (int)
: Batch size for training (default is 8). -
scale_dtype (str)
: The data type of quantization scale to be used (default is "float16"), different kernels have different choices. -
amp (bool)
: Whether to use automatic mixed precision (default is True). -
n_blocks (int)
: Packing several blocks as one for tuning together (default is 1). -
gradient_accumulate_steps (int)
: Number of gradient accumulation steps (default is 1). -
low_gpu_mem_usage (bool)
: Whether to save GPU memory at the cost of ~20% more tuning time (default is True). -
dataset Union[str, list, tuple, torch.utils.data.DataLoader]
: The dataset name for tuning (default is " NeelNanda/pile-10k"). Local json file and combination of datasets have been supported, e.g. " ./tmp.json,NeelNanda/pile-10k:train, mbpp:train+validation+test" -
weight_config (dict)
: Configuration for weight quantization (default is an empty dictionary), mainly for mixed bits or mixed precision. -
device
: The device to be used for tuning. The default is set to 'auto', allowing for automatic detection.
Model inference
Please run the quantization code first.
CPU
##Install the latest https://github.com/intel/intel-extension-for-transformers from source first.
from intel_extension_for_transformers.transformers import AutoModelForCausalLM
from transformers import AutoTokenizer
quantized_model_path = "./tmp_autoround"
model = AutoModelForCausalLM.from_pretrained(quantized_model_path, device_map="auto", trust_remote_code=True)
tokenizer = AutoTokenizer.from_pretrained(quantized_model_path, use_fast=True)
text = "There is a girl who likes adventure,"
inputs = tokenizer(text, return_tensors="pt").to(model.device)
print(tokenizer.decode(model.generate(**inputs, max_new_tokens=50)[0]))
GPU
from transformers import AutoModelForCausalLM, AutoTokenizer
##from auto_round.auto_quantizer import AutoHfQuantizer ## uncomment it for models with quantized lm-head
quantized_model_path = "./tmp_autoround"
model = AutoModelForCausalLM.from_pretrained(quantized_model_path, device_map="auto", trust_remote_code=True)
tokenizer = AutoTokenizer.from_pretrained(quantized_model_path, use_fast=True)
text = "There is a girl who likes adventure,"
inputs = tokenizer(text, return_tensors="pt").to(model.device)
print(tokenizer.decode(model.generate(**inputs, max_new_tokens=50)[0]))
Support List
Model | Supported |
---|---|
Intel/neural-chat-7b-v3-3 | HF-int4-model, accuracy, recipe, example |
Intel/neural-chat-7b-v3-1 | HF-int4-model, accuracy, recipe, example |
mistralai/Mistral-7B-v0.1 | HF-int4-model-lmhead,HF-int4-model, accuracy, recipe, example |
microsoft/phi-2 | HF-int4-sym-model, accuracy, recipe, example |
google/gemma-2b | HF-int4-model, accuracy, recipe, example |
tiiuae/falcon-7b | HF-int4-model-G64, accuracy, recipe, example |
mistralai/Mistral-7B-Instruct-v0.2 | HF-int4-model (under review), accuracy, recipe, example |
google/gemma-7b | HF-int4-model (under review), accuracy, recipe, example |
mistralai/Mixtral-8x7B-Instruct-v0.1 | HF-int4-model (under review), accuracy, recipe, example |
mistralai/Mixtral-8x7B-v0.1 | HF-int4-model (under review), accuracy, recipe, example |
meta-llama/Meta-Llama-3-8B-Instruct | accuracy, recipe, example |
meta-llama/Llama-2-7b-chat-hf | accuracy, recipe, example |
Qwen/Qwen1.5-7B-Chat | accuracy, sym recipe, asym recipe , example |
baichuan-inc/Baichuan2-7B-Chat | accuracy, recipe, example |
01-ai/Yi-6B-Chat | accuracy, recipe, example |
facebook/opt-2.7b | accuracy, recipe, example |
bigscience/bloom-3b | accuracy, recipe, example |
EleutherAI/gpt-j-6b | accuracy, recipe, example |
Salesforce/codegen25-7b-multi | example |
huggyllama/llama-7b | example |
mosaicml/mpt-7b | example |
THUDM/chatglm3-6b | example |
MBZUAI/LaMini-GPT-124M | example |
EleutherAI/gpt-neo-125m | example |
databricks/dolly-v2-3b | example |
stabilityai/stablelm-base-alpha-3b | example |
Comparison with other methods
We provide a comprehensive analysis with other methods in our accuracy data section. In summary, our approach achieved superior performance compared to GPTQ, scoring 30/32, AWQ with 27/32, HQQ with 15/16, and OmniQuant with a perfect score of 16/16 across llamv1/llamav2/mistral-7b on W4G-1, W4G128, W3G128, and W2G128, based on the average accuracies of 11 zero-shot tasks.
Tips
1 Consider increasing tuning steps to achieve better results, albeit with increased tuning time.
2 Setting 'enable_quanted_input' to False has been observed to occasionally yield improved results.
3 Setting 'minmax_lr' to 2.0/iters has been observed to occasionally yield improved results.
Reference
If you find SignRound useful for your research, please cite our paper:
@article{cheng2023optimize,
title={Optimize Weight Rounding via Signed Gradient Descent for the Quantization of LLMs},
author={Cheng, Wenhua and Zhang, Weiwei and Shen, Haihao and Cai, Yiyang and He, Xin and Lv, Kaokao and Liu, Yi},
journal={arXiv preprint arXiv:2309.05516},
year={2023}
}
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