# Online Quantization Online quantization lets you take a BF16/FP16 model and quantize its Linear and MoE weights to lower precision (such as FP8) at load time, without needing a pre-quantized checkpoint or calibration data. Weights are converted during model loading and activations are dynamically scaled during each forward pass. ## Quick Start Pass a scheme name to the `quantization` parameter: ```python from vllm import LLM # Per-tensor FP8 quantization (one scale per weight tensor) llm = LLM("meta-llama/Llama-3.1-8B", quantization="fp8_per_tensor") # Per-block FP8 quantization (128x128 block scaling for weights and 1x128 block scaling for activations) llm = LLM("meta-llama/Llama-3.1-8B", quantization="fp8_per_block") # MXFP8 quantization for weights and activations llm = LLM("meta-llama/Llama-3.1-8B", quantization="mxfp8") ``` Or with the CLI: ```bash vllm serve meta-llama/Llama-3.1-8B --quantization fp8_per_tensor vllm serve meta-llama/Llama-3.1-8B --quantization fp8_per_block vllm serve meta-llama/Llama-3.1-8B --quantization mxfp8 ``` ## Supported Schemes | Scheme | Weight recipe | Activation recipe | Notes | | ------ | ------------- | ------------------ | ----- | | `fp8_per_tensor` | fp8_e4m3 data, fp32 per-tensor scale | fp8_e4m3 data, fp32 per-tensor scale | On some GPUs (Ada, Hopper) linear activations use per-token scaling for better performance | | `fp8_per_block` | fp8_e4m3 data, fp32 per-128x128-block scale | fp8_e4m3 data, fp32 per-1x128-block scale | | | `mxfp8` | fp8_e4m3 data, e8m0 per-1x32-block scale | fp8_e4m3 data, e8m0 per-1x32-block scale | Requires SM 100+ (Blackwell or newer) for w8a8, other GPUs use a w8a16 fallback | ## Advanced Configuration For fine-grained control, use a `quantization_config` dictionary. ### Schema ```yaml quantization_config: linear: weight: # see QUANT_KEY_NAMES in vllm/config/quantization.py activation: moe: weight: activation: ignore: [, ...] ``` `linear` and `moe` accept a full `{weight, activation}` dict, or a bare string. A string resolves first against the `--quantization` shorthands (taking the matching layer-kind slot), then against `QUANT_KEY_NAMES` as a weight name. Unset fields fall back to the `--quantization` shorthand's defaults, or for already-quantized checkpoints to whatever the checkpoint declares. On XPU, non-block FP8 scaled-mm linear layers default to W8A16; setting `--linear-backend xpu` forces W8A8. Use `--linear-backend xpu_woq` to explicitly select weight-only quantization (W8A16). The CLI accepts the same shape as JSON or as dotted keys: ```bash vllm serve --quantization-config '{"moe":{"activation":"mxfp8"}}' vllm serve --quantization-config.moe.activation mxfp8 ``` ### Activation overrides on already-quantized checkpoints For checkpoint-quantized models, `quantization_config` lets you pick an activation format independently of the baked-in weights. The supported overrides are checkpoint-specific; today this is wired up for MXFP4 MoE checkpoints (gpt-oss) where you can opt into FP8 activations: ```bash vllm serve openai/gpt-oss-20b --quantization-config.moe.activation mxfp8 ``` Combine with `--moe-backend` to pin a specific kernel family. ### Separate Schemes for Dense and MoE Layers You can apply different quantization schemes to dense linear layers and MoE expert layers via the `linear` and `moe` fields. Each accepts either a full spec dict, or a bare string naming an online shorthand (e.g. `"fp8_per_block"`) or weight format (e.g. `"fp8_per_block_static"`); fields not set fall back to the shorthand defaults. ```python from vllm import LLM # Linear: per-block FP8; MoE: per-tensor FP8 (inherited from the shorthand) llm = LLM( "ibm-granite/granite-3.0-1b-a400m-base", quantization="fp8_per_tensor", quantization_config={ "linear": "fp8_per_block", }, ) ``` Or, ```python from vllm import LLM # Linear: per-tensor FP8 (inherited); MoE: per-block FP8 llm = LLM( "ibm-granite/granite-3.0-1b-a400m-base", quantization="fp8_per_tensor", quantization_config={ "moe": "fp8_per_block", }, ) ``` ### Excluding Layers from Quantization Use the `ignore` parameter to skip specific layers. It accepts exact layer names and regex patterns (prefixed with `re:`): ```python from vllm import LLM llm = LLM( "ibm-granite/granite-3.0-1b-a400m-base", quantization="fp8_per_tensor", quantization_config={ "ignore": [ # exact layer name "model.layers.1.self_attn.o_proj", # regex: skip all QKV projections "re:.*[qkv]_proj", ], }, ) ``` !!! note For fused layers (e.g., `qkv_proj` which fuses `q_proj`, `k_proj`, `v_proj`), the ignore pattern must match the **unfused** shard names (`q_proj`, `k_proj`, `v_proj`), not the fused name.