# INT8 W4A8 vLLM supports quantizing weights to INT4 and activations to INT8 for memory savings and inference acceleration. This quantization method is particularly useful for reducing model size while maintaining good performance. ## Prerequisites To use INT8 W4A8 quantization with vLLM, you'll need to install the [llm-compressor](https://github.com/vllm-project/llm-compressor/) library. ```bash (venv-llm-compressor) pip install llmcompressor ``` Additionally, install `vllm` and `lm-evaluation-harness` for evaluation: ```bash (venv-vllm) pip install vllm "lm-eval[api]>=0.4.12" ``` Please use separate environments for vLLM and llm-compressor as they might not work together. ## Quantization Process The quantization process involves four main steps: 1. Loading the model 2. Preparing calibration data 3. Applying quantization 4. Evaluating accuracy in vLLM ### 1. Loading the Model Load your model and tokenizer using the standard `transformers` AutoModel classes: ```python from transformers import AutoTokenizer, AutoModelForCausalLM MODEL_ID = "meta-llama/Meta-Llama-3-8B-Instruct" model = AutoModelForCausalLM.from_pretrained( MODEL_ID, dtype="auto", ) tokenizer = AutoTokenizer.from_pretrained(MODEL_ID) ``` ### 2. Preparing Calibration Data When quantizing activations to INT8 and weights to INT4, you need sample data to estimate the activation scales. It's best to use calibration data that closely matches your deployment data. For a general-purpose instruction-tuned model, you can use a dataset like `ultrachat`: ```python from datasets import load_dataset NUM_CALIBRATION_SAMPLES = 512 MAX_SEQUENCE_LENGTH = 2048 # Load and preprocess the dataset ds = load_dataset("HuggingFaceH4/ultrachat_200k", split="train_sft") ds = ds.shuffle(seed=42).select(range(NUM_CALIBRATION_SAMPLES)) def preprocess(example): return {"text": tokenizer.apply_chat_template(example["messages"], tokenize=False)} ds = ds.map(preprocess) def tokenize(sample): return tokenizer(sample["text"], padding=False, max_length=MAX_SEQUENCE_LENGTH, truncation=True, add_special_tokens=False) ds = ds.map(tokenize, remove_columns=ds.column_names) ``` ### 3. Applying Quantization Now, apply the quantization algorithms. The following recipes create W4A8 models (int4 weights, int8 activations). On ArmĀ® CPUs, this is accelerated through [KleidiAI](https://github.com/ARM-software/kleidiai). Use groupwise for best accuracy, and channelwise for best inference performance. === "Groupwise" ```python from llmcompressor import oneshot from llmcompressor.modifiers.quantization import GPTQModifier # Configure the quantization algorithms recipe = [ GPTQModifier( targets="Linear", scheme="W4A8", ignore=["lm_head"], dampening_frac=0.01 ), ] # Apply quantization oneshot( model=model, dataset=ds, recipe=recipe, max_seq_length=MAX_SEQUENCE_LENGTH, num_calibration_samples=NUM_CALIBRATION_SAMPLES, ) # Save the compressed model: Meta-Llama-3-8B-Instruct-W4A8-G128-Dynamic-Per-Token SAVE_DIR = MODEL_ID.split("/")[1] + "-W4A8-G128-Dynamic-Per-Token" model.save_pretrained(SAVE_DIR, save_compressed=True) tokenizer.save_pretrained(SAVE_DIR) ``` === "Channelwise" ```python from llmcompressor import oneshot from llmcompressor.modifiers.quantization import GPTQModifier from compressed_tensors.quantization import QuantizationStrategy, QuantizationType scheme = { "targets": ["Linear"], "weights": { "num_bits": 4, "type": QuantizationType.INT, "strategy": QuantizationStrategy.CHANNEL, "symmetric": True, "dynamic": False, "group_size": None, }, "input_activations": { "num_bits": 8, "type": QuantizationType.INT, "strategy": QuantizationStrategy.TOKEN, "dynamic": True, "symmetric": False, "observer": None, }, "output_activations": None, } recipe = [ GPTQModifier( targets="Linear", config_groups={"group_0": scheme}, ignore=["lm_head"], dampening_frac=0.01, ), ] oneshot( model=model, dataset=ds, recipe=recipe, max_seq_length=MAX_SEQUENCE_LENGTH, num_calibration_samples=NUM_CALIBRATION_SAMPLES, ) # Save the compressed model: Meta-Llama-3-8B-Instruct-W4A8-Channelwise-Dynamic-Per-Token SAVE_DIR = MODEL_ID.split("/")[1] + "-W4A8-Channelwise-Dynamic-Per-Token" model.save_pretrained(SAVE_DIR, save_compressed=True) tokenizer.save_pretrained(SAVE_DIR) ``` ### 4. Evaluating Accuracy === "Groupwise" After quantization, you can load and run the model in vLLM: ```python from vllm import LLM llm = LLM("./Meta-Llama-3-8B-Instruct-W4A8-G128-Dynamic-Per-Token") ``` To evaluate accuracy, you can use `lm_eval`: ```bash lm_eval --model vllm \ --model_args pretrained="./Meta-Llama-3-8B-Instruct-W4A8-G128-Dynamic-Per-Token",add_bos_token=true \ --tasks gsm8k \ --num_fewshot 5 \ --limit 250 \ --batch_size 'auto' ``` === "Channelwise" After quantization, you can load and run the model in vLLM: ```python from vllm import LLM llm = LLM("./Meta-Llama-3-8B-Instruct-W4A8-Channelwise-Dynamic-Per-Token") ``` To evaluate accuracy, you can use `lm_eval`: ```bash lm_eval --model vllm \ --model_args pretrained="./Meta-Llama-3-8B-Instruct-W4A8-Channelwise-Dynamic-Per-Token",add_bos_token=true \ --tasks gsm8k \ --num_fewshot 5 \ --limit 250 \ --batch_size 'auto' ``` !!! note Quantized models can be sensitive to the presence of the `bos` token. Make sure to include the `add_bos_token=True` argument when running evaluations. ## Best Practices - Start with 512 samples for calibration data (increase if accuracy drops) - Use a sequence length of 2048 as a starting point - Employ the chat template or instruction template that the model was trained with - If you've fine-tuned a model, consider using a sample of your training data for calibration ## Troubleshooting and Support If you encounter any issues or have feature requests, please open an issue on the [vllm-project/llm-compressor](https://github.com/vllm-project/llm-compressor/issues) GitHub repository.