# The Comfy guide to Quantization ## How does quantization work? Quantization aims to map a high-precision value x_f to a lower precision format with minimal loss in accuracy. These smaller formats then serve to reduce the models memory footprint and increase throughput by using specialized hardware. When simply converting a value from FP16 to FP8 using the round-nearest method we might hit two issues: - The dynamic range of FP16 (-65,504, 65,504) far exceeds FP8 formats like E4M3 (-448, 448) or E5M2 (-57,344, 57,344), potentially resulting in clipped values - The original values are concentrated in a small range (e.g. -1,1) leaving many FP8-bits "unused" By using a scaling factor, we aim to map these values into the quantized-dtype range, making use of the full spectrum. One of the easiest approaches, and common, is using per-tensor absolute-maximum scaling. ``` absmax = max(abs(tensor)) scale = amax / max_dynamic_range_low_precision # Quantization tensor_q = (tensor / scale).to(low_precision_dtype) # De-Quantization tensor_dq = tensor_q.to(fp16) * scale tensor_dq ~ tensor ``` Given that additional information (scaling factor) is needed to "interpret" the quantized values, we describe those as derived datatypes. ## Quantization in Comfy ``` QuantizedTensor (torch.Tensor subclass) ↓ __torch_dispatch__ Two-Level Registry (generic + layout handlers) ↓ MixedPrecisionOps + Metadata Detection ``` ### Representation To represent these derived datatypes, ComfyUI uses a subclass of torch.Tensor to implements these using the `QuantizedTensor` class found in `comfy/quant_ops.py` A `Layout` class defines how a specific quantization format behaves: - Required parameters - Quantize method - De-Quantize method ```python from comfy.quant_ops import QuantizedLayout class MyLayout(QuantizedLayout): @classmethod def quantize(cls, tensor, **kwargs): # Convert to quantized format qdata = ... params = {'scale': ..., 'orig_dtype': tensor.dtype} return qdata, params @staticmethod def dequantize(qdata, scale, orig_dtype, **kwargs): return qdata.to(orig_dtype) * scale ``` To then run operations using these QuantizedTensors we use two registry systems to define supported operations. The first is a **generic registry** that handles operations common to all quantized formats (e.g., `.to()`, `.clone()`, `.reshape()`). The second registry is layout-specific and allows to implement fast-paths like nn.Linear. ```python from comfy.quant_ops import register_layout_op @register_layout_op(torch.ops.aten.linear.default, MyLayout) def my_linear(func, args, kwargs): # Extract tensors, call optimized kernel ... ``` When `torch.nn.functional.linear()` is called with QuantizedTensor arguments, `__torch_dispatch__` automatically routes to the registered implementation. For any unsupported operation, QuantizedTensor will fallback to call `dequantize` and dispatch using the high-precision implementation. ### Mixed Precision The `MixedPrecisionOps` class (lines 542-648 in `comfy/ops.py`) enables per-layer quantization decisions, allowing different layers in a model to use different precisions. This is activated when a model config contains a `layer_quant_config` dictionary that specifies which layers should be quantized and how. **Architecture:** ```python class MixedPrecisionOps(disable_weight_init): _layer_quant_config = {} # Maps layer names to quantization configs _compute_dtype = torch.bfloat16 # Default compute / dequantize precision ``` **Key mechanism:** The custom `Linear._load_from_state_dict()` method inspects each layer during model loading: - If the layer name is **not** in `_layer_quant_config`: load weight as regular tensor in `_compute_dtype` - If the layer name **is** in `_layer_quant_config`: - Load weight as `QuantizedTensor` with the specified layout (e.g., `TensorCoreFP8Layout`) - Load associated quantization parameters (scales, block_size, etc.) **Why it's needed:** Not all layers tolerate quantization equally. Sensitive operations like final projections can be kept in higher precision, while compute-heavy matmuls are quantized. This provides most of the performance benefits while maintaining quality. The system is selected in `pick_operations()` when `model_config.layer_quant_config` is present, making it the highest-priority operation mode. ## Checkpoint Format Quantized checkpoints are stored as standard safetensors files with quantized weight tensors and associated scaling parameters, plus a `_quantization_metadata` JSON entry describing the quantization scheme. The quantized checkpoint will contain the same layers as the original checkpoint but: - The weights are stored as quantized values, sometimes using a different storage datatype. E.g. uint8 container for fp8. - For each quantized weight a number of additional scaling parameters are stored alongside depending on the recipe. - We store a metadata.json in the metadata of the final safetensor containing the `_quantization_metadata` describing which layers are quantized and what layout has been used. ### Scaling Parameters details We define 4 possible scaling parameters that should cover most recipes in the near-future: - **weight_scale**: quantization scalers for the weights - **weight_scale_2**: global scalers in the context of double scaling - **pre_quant_scale**: scalers used for smoothing salient weights - **input_scale**: quantization scalers for the activations | Format | Storage dtype | weight_scale | weight_scale_2 | pre_quant_scale | input_scale | |--------|---------------|--------------|----------------|-----------------|-------------| | float8_e4m3fn | float32 | float32 (scalar) | - | - | float32 (scalar) | You can find the defined formats in `comfy/quant_ops.py` (QUANT_ALGOS). ### Quantization Metadata The metadata stored alongside the checkpoint contains: - **format_version**: String to define a version of the standard - **layers**: A dictionary mapping layer names to their quantization format. The format string maps to the definitions found in `QUANT_ALGOS`. Example: ```json { "_quantization_metadata": { "format_version": "1.0", "layers": { "model.layers.0.mlp.up_proj": "float8_e4m3fn", "model.layers.0.mlp.down_proj": "float8_e4m3fn", "model.layers.1.mlp.up_proj": "float8_e4m3fn" } } } ``` ## Creating Quantized Checkpoints To create compatible checkpoints, use any quantization tool provided the output follows the checkpoint format described above and uses a layout defined in `QUANT_ALGOS`. ### Weight Quantization Weight quantization is straightforward - compute the scaling factor directly from the weight tensor using the absolute maximum method described earlier. Each layer's weights are quantized independently and stored with their corresponding `weight_scale` parameter. ### Calibration (for Activation Quantization) Activation quantization (e.g., for FP8 Tensor Core operations) requires `input_scale` parameters that cannot be determined from static weights alone. Since activation values depend on actual inputs, we use **post-training calibration (PTQ)**: 1. **Collect statistics**: Run inference on N representative samples 2. **Track activations**: Record the absolute maximum (`amax`) of inputs to each quantized layer 3. **Compute scales**: Derive `input_scale` from collected statistics 4. **Store in checkpoint**: Save `input_scale` parameters alongside weights The calibration dataset should be representative of your target use case. For diffusion models, this typically means a diverse set of prompts and generation parameters.