# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project from typing import Any, Optional import torch from packaging import version from torch.nn.parameter import Parameter from vllm.logger import init_logger from vllm.model_executor.layers.linear import (LinearBase, LinearMethodBase, set_weight_attrs) from vllm.model_executor.layers.quantization import QuantizationMethods from vllm.model_executor.layers.quantization.base_config import ( QuantizationConfig) from vllm.model_executor.layers.quantization.kernels.mixed_precision import ( BitBLASLinearKernel, MPLinearLayerConfig) from vllm.model_executor.layers.quantization.utils.bitblas_utils import ( BITBLAS_SUPPORTED_NUM_BITS as GPTQ_BITBLAS_SUPPORTED_NUM_BITS) from vllm.model_executor.layers.quantization.utils.bitblas_utils import ( BITBLAS_SUPPORTED_SYM as GPTQ_BITBLAS_SUPPORTED_SYM) from vllm.model_executor.layers.quantization.utils.bitblas_utils import ( MINIMUM_BITBLAS_VERSION, bitblas_repeat_scales_on_all_ranks, check_bitblas_supported, verify_bitblas_supported) from vllm.model_executor.layers.vocab_parallel_embedding import ParallelLMHead from vllm.model_executor.parameter import (ChannelQuantScaleParameter, GroupQuantScaleParameter, PackedColumnParameter, PackedvLLMParameter, RowvLLMParameter) from vllm.platforms import current_platform from vllm.scalar_type import scalar_types logger = init_logger(__name__) class GPTQBitBLASConfig(QuantizationConfig): """Config class for GPTQ BitBLAS""" # (num_bits, is_sym) -> quant_type TYPE_MAP = { (4, True): scalar_types.uint4b8, (8, True): scalar_types.uint8b128, } TORCH_DTYPE = torch.float16 GPTQ_CKPT_STORAGE_DTYPE = ( "int32" # GPTQ Default Checkpoints use int32 as storage dtype ) GPTQ_BITBLAS_STORAGE_DTYPE = "int8" # BitBLAS uses int8 as storage dtype TORCH_BITBLAS_STORAGE_DTYPE = getattr(torch, GPTQ_BITBLAS_STORAGE_DTYPE) # "original" or "rescale" or "quantized", # the gptq_bitblas prefer "quantized" ZEROS_MODE = "quantized" def __init__( self, weight_bits: int, group_size: int, desc_act: bool, is_sym: bool, quant_method: Optional[str], lm_head_quantized: bool, ) -> None: try: import bitblas if version.parse(bitblas.__version__) < version.parse( MINIMUM_BITBLAS_VERSION): raise ImportError( "bitblas version is wrong. Please " f"install bitblas>={MINIMUM_BITBLAS_VERSION}") except ImportError as e: bitblas_import_exception = e raise ValueError( "Trying to use the bitblas backend, but could not import" f"with the following error: {bitblas_import_exception}. " "Please install bitblas through the following command: " f"`pip install bitblas>={MINIMUM_BITBLAS_VERSION}`" ) from bitblas_import_exception if desc_act and group_size == -1: # In this case, act_order == True is the same as act_order == False # (since we have only one group per output channel) desc_act = False super().__init__() self.weight_bits = weight_bits self.group_size = group_size self.desc_act = desc_act self.is_sym = is_sym self.quant_method = quant_method self.lm_head_quantized = lm_head_quantized # Verify if self.weight_bits not in GPTQ_BITBLAS_SUPPORTED_NUM_BITS: raise ValueError( f"BitBLAS does not support weight_bits = {self.weight_bits}. " f"Only weight_bits = {GPTQ_BITBLAS_SUPPORTED_NUM_BITS} " "are supported.") if self.is_sym not in GPTQ_BITBLAS_SUPPORTED_SYM: raise ValueError( f"BitBLAS does not support is_sym = {self.is_sym}. " f"Only sym = {GPTQ_BITBLAS_SUPPORTED_SYM} are supported.") self.storage_dtype = self.GPTQ_BITBLAS_STORAGE_DTYPE storage_nbit = int("".join(c for c in self.GPTQ_CKPT_STORAGE_DTYPE if c.isdigit())) # 4 Bits packed into 32 bit datatype. self.pack_factor = storage_nbit // weight_bits self.nbits = weight_bits # Zeros type for the quantized weights. self.zeros_mode = self.ZEROS_MODE if (weight_bits, is_sym) not in self.TYPE_MAP: raise ValueError("Unsupported quantization config: " f"bits={weight_bits}, sym={is_sym}") self.quant_type = self.TYPE_MAP[(weight_bits, is_sym)] def __repr__(self) -> str: return (f"GPTQBitBLASConfig(weight_bits={self.weight_bits}, " f"group_size={self.group_size}, " f"desc_act={self.desc_act})" f"is_sym={self.is_sym}, " f"quant_method={self.quant_method})") @classmethod def get_name(cls) -> QuantizationMethods: return "gptq_bitblas" @classmethod def get_supported_act_dtypes(cls) -> list[torch.dtype]: return [torch.half, torch.bfloat16] @classmethod def get_min_capability(cls) -> int: return 80 @classmethod def get_config_filenames(cls) -> list[str]: return ["quantize_config.json"] @classmethod def from_config(cls, config: dict[str, Any]) -> "GPTQBitBLASConfig": weight_bits = cls.get_from_keys(config, ["bits"]) group_size = cls.get_from_keys(config, ["group_size"]) desc_act = cls.get_from_keys(config, ["desc_act"]) is_sym = cls.get_from_keys(config, ["sym"]) quant_method = cls.get_from_keys(config, ["quant_method"]) lm_head_quantized = cls.get_from_keys_or(config, ["lm_head"], default=False) return cls(weight_bits, group_size, desc_act, is_sym, quant_method, lm_head_quantized) @classmethod def override_quantization_method( cls, hf_quant_cfg, user_quant) -> Optional[QuantizationMethods]: can_convert = cls.is_gptq_bitblas_compatible(hf_quant_cfg) is_valid_user_quant = (user_quant is None or user_quant == "bitblas" or user_quant == "gptq_bitblas") if can_convert and is_valid_user_quant: msg = ("The model is convertible to {} during runtime." " Using {} kernel.".format(cls.get_name(), cls.get_name())) logger.info(msg) return cls.get_name() if can_convert and user_quant == "gptq": logger.info("Detected that the model can run with gptq_bitblas" ", however you specified quantization=gptq explicitly," " so forcing gptq. Use quantization=gptq_bitblas for" " faster inference") return None def get_quant_method(self, layer: torch.nn.Module, prefix: str) -> Optional["GPTQBitBLASLinearMethod"]: if isinstance(layer, LinearBase) or (isinstance(layer, ParallelLMHead) and self.lm_head_quantized): return GPTQBitBLASLinearMethod(self) return None @property def torch_storage_dtype(self) -> torch.dtype: return self.TORCH_BITBLAS_STORAGE_DTYPE @classmethod def is_gptq_bitblas_compatible(cls, quant_config: dict[str, Any]): # Extract data from quant config. num_bits = quant_config.get("bits") group_size = quant_config.get("group_size") sym = quant_config.get("sym") desc_act = quant_config.get("desc_act") # temporarily disable on ROCm platform if not current_platform.is_cuda(): return False # If we cannot find the info needed in the config, cannot convert. if (num_bits is None or group_size is None or sym is None or desc_act is None): return False if (num_bits, sym) not in cls.TYPE_MAP: return False # If the capability of the device is too low, cannot convert. major, minor = torch.cuda.get_device_capability() device_capability = major * 10 + minor if device_capability < cls.get_min_capability(): return False # Otherwise, can convert if model satisfies bitblas constraints. return check_bitblas_supported(quant_type=cls.TYPE_MAP[(num_bits, sym)], group_size=group_size) class GPTQBitBLASLinearMethod(LinearMethodBase): """Linear method for GPTQ BitBLAS. Args: quant_config: The GPTQ BitBLAS quantization config. """ kernel_type = BitBLASLinearKernel _kernel_backends_being_used: set[str] = set() def __init__(self, quant_config: GPTQBitBLASConfig) -> None: self.quant_config = quant_config # Verify supported on platform. verify_bitblas_supported(quant_type=self.quant_config.quant_type, group_size=self.quant_config.group_size) 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, ) -> None: """Creates quantized weights for use in linear operations. The function initializes and returns a dictionary containing quantized weights, scales, and zeros for performing quantized matrix multiplication operations. Args: input_size_per_partition: The size of the input partition. output_partition_sizes: The size of the output partition. input_size: The total size of the input (unused). output_size: The total size of the output (unused). params_dtype: The data type of the parameters (expected to be torch.float16). Returns: A dictionary containing the quantized weights ('qweight'), scales ('scales'), and zeros ('zeros'). Raises: ValueError: If `params_dtype` is not `torch.float16` or if the input size per partition is not divisible by the group size in `quant_config`. """ if params_dtype != torch.float16: raise ValueError("Parameter data type must be torch.float16, " f"but got {params_dtype}") # Normalize group_size if self.quant_config.group_size != -1: group_size = self.quant_config.group_size else: group_size = input_size if input_size_per_partition % group_size != 0: raise ValueError( f"Input size per partition ({input_size_per_partition}) must " f"be divisible by group size ({self.quant_config.group_size})." ) kernel_type = self.kernel_type # Validate output_size_per_partition output_size_per_partition = sum(output_partition_sizes) is_row_parallel = input_size != input_size_per_partition weight_loader = extra_weight_attrs.get("weight_loader") mp_linear_kernel_config = MPLinearLayerConfig( full_weight_shape=(input_size, output_size), partition_weight_shape=\ (input_size_per_partition, output_size_per_partition), weight_type=self.quant_config.quant_type, act_type=params_dtype, group_size=self.quant_config.group_size, zero_points=False, has_g_idx=self.quant_config.desc_act ) if kernel_type.__name__ not in self._kernel_backends_being_used: logger.info("Using %s for GPTQBitBLASLinearMethod", kernel_type.__name__) self._kernel_backends_being_used.add(kernel_type.__name__) # Normalize group_size if self.quant_config.group_size != -1: group_size = self.quant_config.group_size else: group_size = input_size # Determine sharding if bitblas_repeat_scales_on_all_ranks(self.quant_config.desc_act, self.quant_config.group_size, is_row_parallel): # By setting scale_dim == None, weight_loader will # repeat the scales on each GPU in TP>1 case. scales_and_zp_input_dim = None scales_and_zp_size = input_size // group_size else: # By setting scale_dim == 0, weight_loader will # shard the scales in TP>1 case. scales_and_zp_input_dim = 0 scales_and_zp_size = input_size_per_partition // group_size # Init buffers # Quantized weights qweight = PackedvLLMParameter( data=torch.empty( input_size_per_partition // self.quant_config.pack_factor, output_size_per_partition, dtype=torch.int32, ), input_dim=0, output_dim=1, packed_dim=0, packed_factor=self.quant_config.pack_factor, weight_loader=weight_loader) # Activation order # Ignore warning from fused linear layers such as QKVParallelLinear. g_idx = RowvLLMParameter(data=torch.empty( input_size_per_partition, dtype=torch.int32, ), input_dim=0, weight_loader=weight_loader) # Scales scales = Parameter( torch.empty( scales_and_zp_size, output_size_per_partition, dtype=params_dtype, ), requires_grad=False, ) set_weight_attrs( scales, { **extra_weight_attrs, "input_dim": scales_and_zp_input_dim, "output_dim": 1, }, ) # Quantized zero-points qzeros_args = { "data": torch.empty( scales_and_zp_size, output_size_per_partition // self.quant_config.pack_factor, dtype=torch.int32, ), "weight_loader": weight_loader } weight_scale_args = { "data": torch.empty( scales_and_zp_size, output_size_per_partition, dtype=params_dtype, ), "weight_loader": weight_loader } if scales_and_zp_input_dim is None: scales = ChannelQuantScaleParameter(output_dim=1, **weight_scale_args) qzeros = PackedColumnParameter( output_dim=1, packed_dim=1, packed_factor=self.quant_config.pack_factor, **qzeros_args) else: scales = GroupQuantScaleParameter(output_dim=1, input_dim=0, **weight_scale_args) qzeros = PackedvLLMParameter( input_dim=0, output_dim=1, packed_dim=1, packed_factor=self.quant_config.pack_factor, **qzeros_args) layer.register_parameter("qweight", qweight) layer.register_parameter("g_idx", g_idx) layer.register_parameter("scales", scales) layer.register_parameter("qzeros", qzeros) self.kernel = kernel_type( mp_linear_kernel_config, w_q_param_name="qweight", w_s_param_name="scales", w_zp_param_name="qzeros", w_gidx_param_name="g_idx", bitblas_quant_config=self.quant_config, ) # Initialize or retrieve the BitBLAS matrix multiplication operator. self.kernel.configure_bitblas_matmul( input_size_per_partition, output_size_per_partition, params_dtype=params_dtype, bias=False, ) def process_weights_after_loading(self, layer: torch.nn.Module) -> None: self.kernel.process_weights_after_loading(layer) def apply( self, layer: torch.nn.Module, x: torch.Tensor, bias: Optional[torch.Tensor] = None, ) -> torch.Tensor: out = self.kernel.apply_gptq_bitblas_linear(layer, x) if bias is not None: out.add_(bias) return out