# # Copyright (c) 2025 Huawei Technologies Co., Ltd. All Rights Reserved. # This file is a part of the vllm-ascend project. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # http://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. # from typing import Any import torch import torch_npu from vllm_ascend.utils import ( COMPRESSED_TENSORS_METHOD, get_weight_prefetch_method, maybe_trans_nz, ) from .base import AscendLinearScheme from .registry import register_scheme @register_scheme("W8A8", "linear") class AscendW8A8LinearMethod(AscendLinearScheme): """Linear method for Ascend W8A8 static quantization. This scheme uses static per-tensor quantization for activations and per-channel quantization for weights. """ def __init__(self) -> None: pass def get_weight( self, input_size: int, output_size: int, params_dtype: torch.dtype = torch.bfloat16, ) -> dict[str, Any]: params_dict = {"weight": torch.empty(output_size, input_size, dtype=torch.int8)} return params_dict def get_pertensor_param(self, params_dtype: torch.dtype) -> dict[str, Any]: params_dict = {} params_dict["input_scale"] = torch.empty(1, dtype=params_dtype) params_dict["input_offset"] = torch.empty(1, dtype=torch.int8) return params_dict def get_perchannel_param( self, output_size: int, params_dtype: torch.dtype, ) -> dict[str, Any]: params_dict = {} params_dict["quant_bias"] = torch.empty(output_size, dtype=torch.int32) if params_dtype == torch.bfloat16: params_dict["deq_scale"] = torch.empty(output_size, dtype=torch.float32) elif params_dtype == torch.float16: params_dict["deq_scale"] = torch.empty(output_size, dtype=torch.int64) params_dict["weight_scale"] = torch.empty(output_size, 1, dtype=params_dtype) params_dict["weight_offset"] = torch.empty(output_size, 1, dtype=params_dtype) return params_dict def apply( self, layer: torch.nn.Module, x: torch.Tensor, bias: torch.Tensor | None = None, tp_rank: int | None = 0, ) -> torch.Tensor: if x.dtype != torch.int8: layer_cls_name = layer.__class__.__name__ weight_prefetch_method = get_weight_prefetch_method() # prefetch qkvo_proj.weight preprocess if weight_prefetch_method: weight_prefetch_method.maybe_prefetch_attn_weight_preprocess( layer_cls_name=layer_cls_name, weight=layer.weight, start_flag=x, ) try: quant_comm_config = layer._quant_comm_config except AttributeError: quant_comm_config = {} comm_fn = quant_comm_config.get("communication_fn") enable_flashcomm2_quant_comm = comm_fn is not None and ( "o_proj" in layer.prefix or "out_proj" in layer.prefix ) if enable_flashcomm2_quant_comm: quant_input_x = x.contiguous().view(-1, layer.aclnn_input_scale_reciprocal.size(0)) quant_x = torch.ops.vllm.quantize( quant_input_x, layer.aclnn_input_scale, layer.aclnn_input_scale_reciprocal, layer.aclnn_input_offset, ) comm_input = quant_x.view(x.size(0), -1) assert comm_fn is not None x = comm_fn(comm_input) else: # quant x = torch.ops.vllm.quantize( x, layer.aclnn_input_scale, layer.aclnn_input_scale_reciprocal, layer.aclnn_input_offset, ) # prefetch qkvo_proj.weight postprocess if weight_prefetch_method: weight_prefetch_method.maybe_prefetch_attn_weight_postprocess( layer_cls_name=layer_cls_name, stop_flag=x, ) quant_bias = layer.quant_bias if tp_rank == 0 else None try: ascend_quant_method = layer.ascend_quant_method except AttributeError: ascend_quant_method = "" if ascend_quant_method == COMPRESSED_TENSORS_METHOD: quant_bias = bias output = torch_npu.npu_quant_matmul( x, layer.weight, layer.deq_scale, bias=quant_bias, output_dtype=layer.params_dtype, ) return output def process_weights_after_loading(self, layer): expanding_factor = layer.weight.data.shape[1] layer.aclnn_input_scale = torch.nn.Parameter( layer.input_scale.data.repeat(expanding_factor), requires_grad=False ) layer.aclnn_input_scale_reciprocal = 1 / torch.nn.Parameter( layer.input_scale.data.repeat(expanding_factor), requires_grad=False ) layer.aclnn_input_offset = torch.nn.Parameter( layer.input_offset.data.repeat(expanding_factor), requires_grad=False ).to(layer.aclnn_input_scale.dtype) layer.weight.data = layer.weight.data.transpose(0, 1).contiguous() layer.weight.data = maybe_trans_nz(layer.weight.data) layer.weight_scale.data = torch.flatten(layer.weight_scale.data) layer.weight_offset.data = torch.flatten(layer.weight_offset.data) ascend_quant_method = getattr(layer, "ascend_quant_method", "") if ascend_quant_method == COMPRESSED_TENSORS_METHOD: deq_scale = layer.input_scale.data * layer.weight_scale.data layer.deq_scale = torch.nn.Parameter(deq_scale, requires_grad=False)