from typing import Any, Dict, List, Optional import torch from loguru import logger from torch.nn import Module from torch.nn.parameter import Parameter import aphrodite.common.envs as envs from aphrodite import _custom_ops as ops from aphrodite.common.utils import is_hip, print_warning_once from aphrodite.modeling.layers.fused_moe import FusedMoE, FusedMoEMethodBase from aphrodite.modeling.layers.linear import (LinearBase, LinearMethodBase, UnquantizedLinearMethod) from aphrodite.modeling.utils import set_weight_attrs from aphrodite.platforms import current_platform from aphrodite.quantization.base_config import (QuantizationConfig, QuantizeMethodBase) from aphrodite.quantization.kv_cache import BaseKVCacheMethod from aphrodite.quantization.utils.marlin_utils_fp8 import ( apply_fp8_marlin_linear, prepare_fp8_layer_for_marlin) from aphrodite.quantization.utils.quant_utils import is_layer_skipped from aphrodite.quantization.utils.w8a8_utils import ( all_close_1d, apply_fp8_linear, convert_to_channelwise, create_per_tensor_scale_param, cutlass_fp8_supported, normalize_e4m3fn_to_e4m3fnuz, per_tensor_dequantize, requantize_with_max_scale) ACTIVATION_SCHEMES = ["static", "dynamic"] APHRODITE_TEST_FORCE_FP8_MARLIN = envs.APHRODITE_TEST_FORCE_FP8_MARLIN class Fp8Config(QuantizationConfig): """Config class for FP8.""" def __init__( self, is_checkpoint_fp8_serialized: bool = False, activation_scheme: str = "dynamic", ignored_layers: Optional[List[str]] = None, ) -> None: self.is_checkpoint_fp8_serialized = is_checkpoint_fp8_serialized if is_checkpoint_fp8_serialized: logger.warning("Detected fp8 checkpoint. Please note that the " "format is experimental and subject to change.") if activation_scheme not in ACTIVATION_SCHEMES: raise ValueError( f"Unsupported activation scheme {activation_scheme}") self.activation_scheme = activation_scheme self.ignored_layers = ignored_layers or [] @classmethod def get_name(cls) -> str: return "fp8" @classmethod def get_supported_act_dtypes(cls) -> List[torch.dtype]: return [torch.bfloat16, torch.half] @classmethod def get_min_capability(cls) -> int: return 80 @classmethod def get_config_filenames(cls) -> List[str]: return [] @classmethod def from_config(cls, config: Dict[str, Any]) -> "Fp8Config": quant_method = cls.get_from_keys(config, ["quant_method"]) is_checkpoint_fp8_serialized = ("fp8" in quant_method) activation_scheme = cls.get_from_keys(config, ["activation_scheme"]) ignored_layers = cls.get_from_keys_or(config, ["ignored_layers"], None) return cls(is_checkpoint_fp8_serialized=is_checkpoint_fp8_serialized, activation_scheme=activation_scheme, ignored_layers=ignored_layers) def get_quant_method(self, layer: torch.nn.Module, prefix: str) -> Optional["QuantizeMethodBase"]: from aphrodite.attention.layer import ( Attention) # Avoid circular import if isinstance(layer, LinearBase): if is_layer_skipped(prefix, self.ignored_layers): return UnquantizedLinearMethod() return Fp8LinearMethod(self) elif isinstance(layer, FusedMoE): return Fp8MoEMethod(self) elif isinstance(layer, Attention): return Fp8KVCacheMethod(self) return None def get_scaled_act_names(self) -> List[str]: return [] class Fp8LinearMethod(LinearMethodBase): """Linear method for FP8. Supports loading FP8 checkpoints with static weight scale and dynamic/static activation scale. Also supports loading quantized FP16/BF16 model checkpoints with dynamic activation scaling. The weight scaling factor will be initialized after the model weights are loaded. Limitations: 1. Only support per-tensor quantization due to torch._scaled_mm support. 2. Only support float8_e4m3fn data type due to the limitation of torch._scaled_mm (https://github.com/pytorch/pytorch/blob/2e48b39603411a41c5025efbe52f89560b827825/aten/src/ATen/native/cuda/Blas.cpp#L854-L856) Args: quant_config: The quantization config. """ def __init__(self, quant_config: Fp8Config): self.quant_config = quant_config self.cutlass_fp8_supported = cutlass_fp8_supported() # For GPUs that lack FP8 hardware support, we can leverage the Marlin # kernel for fast weight-only FP8 quantization capability = current_platform.get_device_capability() capability = capability[0] * 10 + capability[1] self.use_marlin = capability < 89 or APHRODITE_TEST_FORCE_FP8_MARLIN # Disable marlin for rocm if is_hip(): self.use_marlin = False def create_weights( self, layer: torch.nn.Module, input_size_per_partition: int, output_partition_sizes: List[int], input_size: int, output_size: int, params_dtype: torch.dtype, **extra_weight_attrs, ): del input_size, output_size output_size_per_partition = sum(output_partition_sizes) layer.logical_widths = output_partition_sizes layer.input_size_per_partition = input_size_per_partition layer.output_size_per_partition = output_size_per_partition layer.orig_dtype = params_dtype # WEIGHT weight_dtype = (torch.float8_e4m3fn if self.quant_config.is_checkpoint_fp8_serialized else params_dtype) weight = Parameter(torch.empty(output_size_per_partition, input_size_per_partition, dtype=weight_dtype), requires_grad=False) layer.register_parameter("weight", weight) set_weight_attrs(weight, { **extra_weight_attrs, "input_dim": 1, "output_dim": 0, }) # If checkpoint is serialized fp8, load them. # Otherwise, wait until process_weights_after_loading. if self.quant_config.is_checkpoint_fp8_serialized: # WEIGHT SCALE scale = create_per_tensor_scale_param(output_partition_sizes, **extra_weight_attrs) layer.register_parameter("weight_scale", scale) # INPUT ACTIVATION SCALE if self.quant_config.activation_scheme == "static": scale = create_per_tensor_scale_param(output_partition_sizes, **extra_weight_attrs) layer.register_parameter("input_scale", scale) else: layer.register_parameter("input_scale", None) def process_weights_after_loading(self, layer: Module) -> None: # If checkpoint not serialized fp8, quantize the weights. if not self.quant_config.is_checkpoint_fp8_serialized: qweight, weight_scale = ops.scaled_fp8_quant(layer.weight, scale=None) # If using marlin (w8a16), kernel uses channelwise weights, # so extend the weight scales to be channelwise. if self.use_marlin: assert weight_scale.numel() == 1 weight_scale = convert_to_channelwise( weight_scale.expand(len(layer.logical_widths)), layer.logical_widths) # Update the layer with the new values. layer.weight = Parameter(qweight.t(), requires_grad=False) layer.weight_scale = Parameter(weight_scale, requires_grad=False) layer.input_scale = None # If checkpoint is fp8, handle that there are N scales for N # shards in a fused module else: # If using marlin (w8a16), kernel uses channelwise weights, # so extend the weight scales to be channelwise. if self.use_marlin: weight = layer.weight weight_scale = convert_to_channelwise(layer.weight_scale, layer.logical_widths) # If using w8a8, torch._scaled_mm needs per tensor, so # requantize the logical shards as a single weight. else: # Dequant -> Quant with max scale so we can run per tensor. weight = layer.weight weight_scale = layer.weight_scale # If rocm, use float8_e4m3fnuz. if is_hip(): weight, weight_scale, input_scale = \ normalize_e4m3fn_to_e4m3fnuz( weight=weight, weight_scale=weight_scale, input_scale=layer.input_scale) if input_scale is not None: layer.input_scale = Parameter(input_scale, requires_grad=False) weight_scale, weight = requantize_with_max_scale( weight=weight, weight_scale=weight_scale, logical_widths=layer.logical_widths, ) # Update layer with new values. layer.weight = Parameter(weight.t(), requires_grad=False) layer.weight_scale = Parameter(weight_scale, requires_grad=False) if self.quant_config.activation_scheme == "static": layer.input_scale = Parameter(layer.input_scale.max(), requires_grad=False) if self.use_marlin: prepare_fp8_layer_for_marlin(layer) # Activations not quantized for marlin. del layer.input_scale def apply(self, layer: torch.nn.Module, x: torch.Tensor, bias: Optional[torch.Tensor] = None) -> torch.Tensor: if self.use_marlin: return apply_fp8_marlin_linear( input=x, weight=layer.weight, weight_scale=layer.weight_scale, workspace=layer.workspace, size_n=layer.output_size_per_partition, size_k=layer.input_size_per_partition, bias=bias) return apply_fp8_linear( input=x, weight=layer.weight, weight_scale=layer.weight_scale, input_scale=layer.input_scale, bias=bias, cutlass_fp8_supported=self.cutlass_fp8_supported, use_per_token_if_dynamic=False) class Fp8MoEMethod(FusedMoEMethodBase): """MoE method for FP8. Supports loading FP8 checkpoints with static weight scale and dynamic/static activation scale. Also supports loading quantized FP16/BF16 model checkpoints with dynamic activation scaling. The weight scaling factor will be initialized after the model weights are loaded. Args: quant_config: The quantization config. """ def __init__(self, quant_config: Fp8Config): self.quant_config = quant_config def create_weights(self, layer: Module, num_experts: int, hidden_size: int, intermediate_size: int, params_dtype: torch.dtype, **extra_weight_attrs): if self.quant_config.is_checkpoint_fp8_serialized: params_dtype = torch.float8_e4m3fn # WEIGHTS w13_weight = torch.nn.Parameter(torch.empty(num_experts, 2 * intermediate_size, hidden_size, dtype=params_dtype), requires_grad=False) layer.register_parameter("w13_weight", w13_weight) set_weight_attrs(w13_weight, extra_weight_attrs) w2_weight = torch.nn.Parameter(torch.empty(num_experts, hidden_size, intermediate_size, dtype=params_dtype), requires_grad=False) layer.register_parameter("w2_weight", w2_weight) set_weight_attrs(w2_weight, extra_weight_attrs) # WEIGHT_SCALES # Allocate 2 scales for w1 and w3 respectively. # They will be combined to a single scale after weight loading. w13_weight_scale = torch.nn.Parameter(torch.ones(num_experts, 2, dtype=torch.float32), requires_grad=False) layer.register_parameter("w13_weight_scale", w13_weight_scale) w2_weight_scale = torch.nn.Parameter(torch.ones(num_experts, dtype=torch.float32), requires_grad=False) layer.register_parameter("w2_weight_scale", w2_weight_scale) # If loading fp8 checkpoint, pass the weight loaders. # If loading an fp16 checkpoint, do not (we will quantize in # process_weights_after_loading() if self.quant_config.is_checkpoint_fp8_serialized: set_weight_attrs(w13_weight_scale, { "is_fp8_scale": True, **extra_weight_attrs }) set_weight_attrs(w2_weight_scale, { "is_fp8_scale": True, **extra_weight_attrs }) # INPUT_SCALES if self.quant_config.activation_scheme == "static": if not self.quant_config.is_checkpoint_fp8_serialized: raise ValueError( "Found static activation scheme for checkpoint that " "was not serialized fp8.") w13_input_scale = torch.nn.Parameter(torch.ones( num_experts, dtype=torch.float32), requires_grad=False) layer.register_parameter("w13_input_scale", w13_input_scale) set_weight_attrs(w13_input_scale, { "is_fp8_scale": True, **extra_weight_attrs }) w2_input_scale = torch.nn.Parameter(torch.ones( num_experts, dtype=torch.float32), requires_grad=False) layer.register_parameter("w2_input_scale", w2_input_scale) set_weight_attrs(w2_input_scale, { "is_fp8_scale": True, **extra_weight_attrs }) else: layer.w13_input_scale = None layer.w2_input_scale = None def process_weights_after_loading(self, layer: Module) -> None: # If checkpoint is fp16, quantize in place. if not self.quant_config.is_checkpoint_fp8_serialized: # If rocm, use float8_e4m3fnuz as dtype fp8_dtype = torch.float8_e4m3fnuz \ if is_hip() else torch.float8_e4m3fn w13_weight = torch.empty_like(layer.w13_weight.data, dtype=fp8_dtype) w2_weight = torch.empty_like(layer.w2_weight.data, dtype=fp8_dtype) # Re-initialize w13_scale because we directly quantize # merged w13 weights and generate a single scaling factor. layer.w13_weight_scale = torch.nn.Parameter(torch.ones( layer.num_experts, dtype=torch.float32, device=w13_weight.device), requires_grad=False) for expert in range(layer.num_experts): w13_weight[expert, :, :], layer.w13_weight_scale[ expert] = ops.scaled_fp8_quant( layer.w13_weight.data[expert, :, :]) w2_weight[expert, :, :], layer.w2_weight_scale[ expert] = ops.scaled_fp8_quant( layer.w2_weight.data[expert, :, :]) layer.w13_weight = torch.nn.Parameter(w13_weight, requires_grad=False) layer.w2_weight = torch.nn.Parameter(w2_weight, requires_grad=False) return # If checkpoint is fp8, we need to handle that the # MoE kernels require single activation scale and single weight # scale for w13 per expert. else: # Fp8 moe kernels require a single activation scale. # We take the max of all the scales in case they differ. if self.quant_config.activation_scheme == "static": if (layer.w13_input_scale is None or layer.w2_input_scale is None): raise ValueError( "QuantConfig has static quantization, but found " "activation scales are None.") if (not all_close_1d(layer.w13_input_scale) or not all_close_1d(layer.w2_input_scale)): print_warning_once( "Found input_scales that are not equal for " "fp8 MoE layer. Using the maximum across experts " "for each layer. ") layer.w13_input_scale = torch.nn.Parameter( layer.w13_input_scale.max(), requires_grad=False) layer.w2_input_scale = torch.nn.Parameter( layer.w2_input_scale.max(), requires_grad=False) # If rocm, normalize the weights and scales to e4m3fnuz if is_hip(): # Normalize the weights and scales w13_weight, w13_weight_scale, w13_input_scale = \ normalize_e4m3fn_to_e4m3fnuz( layer.w13_weight, layer.w13_weight_scale, layer.w13_input_scale) w2_weight, w2_weight_scale, w2_input_scale = \ normalize_e4m3fn_to_e4m3fnuz( layer.w2_weight, layer.w2_weight_scale, layer.w2_input_scale) # Reset the parameter layer.w13_weight = torch.nn.Parameter(w13_weight, requires_grad=False) layer.w13_weight_scale = torch.nn.Parameter( w13_weight_scale, requires_grad=False) if w13_input_scale is not None: layer.w13_input_scale = torch.nn.Parameter( w13_input_scale, requires_grad=False) layer.w2_weight = torch.nn.Parameter(w2_weight, requires_grad=False) layer.w2_weight_scale = torch.nn.Parameter(w2_weight_scale, requires_grad=False) if w2_input_scale is not None: layer.w2_input_scale = torch.nn.Parameter( w2_input_scale, requires_grad=False) # Fp8 moe kernel needs single weight scale for w13 per expert. # We take the max then dequant and requant each expert. assert layer.w13_weight_scale is not None shard_size = layer.intermediate_size_per_partition max_w13_scales = layer.w13_weight_scale.max(dim=1).values for expert_id in range(layer.num_experts): start = 0 for shard_id in range(2): dq_weight = per_tensor_dequantize( layer.w13_weight[expert_id][start:start + shard_size, :], layer.w13_weight_scale[expert_id][shard_id]) layer.w13_weight[expert_id][ start:start + shard_size, :], _ = ops.scaled_fp8_quant( dq_weight, max_w13_scales[expert_id]) start += shard_size layer.w13_weight_scale = torch.nn.Parameter(max_w13_scales, requires_grad=False) return def apply(self, layer: torch.nn.Module, x: torch.Tensor, router_logits: torch.Tensor, top_k: int, renormalize: bool, use_grouped_topk: bool, topk_group: Optional[int] = None, num_expert_group: Optional[int] = None) -> torch.Tensor: from aphrodite.modeling.layers.fused_moe import fused_experts topk_weights, topk_ids = FusedMoE.select_experts( hidden_states=x, router_logits=router_logits, use_grouped_topk=use_grouped_topk, top_k=top_k, renormalize=renormalize, topk_group=topk_group, num_expert_group=num_expert_group) return fused_experts(x, layer.w13_weight, layer.w2_weight, topk_weights=topk_weights, topk_ids=topk_ids, inplace=True, use_fp8_w8a8=True, w1_scale=layer.w13_weight_scale, w2_scale=layer.w2_weight_scale, a1_scale=layer.w13_input_scale, a2_scale=layer.w2_input_scale) class Fp8KVCacheMethod(BaseKVCacheMethod): """ Supports loading kv-cache scaling factors from FP8 checkpoints. """ def __init__(self, quant_config: Fp8Config): super().__init__(quant_config)