xc-llm-ascend/vllm_ascend/quantization/methods/base.py

#
# 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.
#
"""Abstract base classes for Ascend quantization schemes."""

from abc import ABC, abstractmethod
from enum import Enum
from typing import Any, Callable, Dict, Optional

import torch


class QuantType(Enum):
    """Quantization type enum for MoE schemes."""
    NONE = 0
    W8A8 = 1
    W4A8 = 2


class AscendLinearScheme(ABC):
    """Base class for all linear quantization schemes.
    
    Subclasses must implement get_weight() and apply() methods.
    Other methods have default implementations that return empty dicts
    or do nothing.
    """

    @abstractmethod
    def get_weight(self, input_size: int, output_size: int,
                   params_dtype: torch.dtype) -> Dict[str, Any]:
        """Return weight tensor specifications.
        
        Args:
            input_size: Input dimension of the linear layer.
            output_size: Output dimension of the linear layer.
            params_dtype: Data type for parameters.
            
        Returns:
            Dictionary mapping parameter names to empty tensors with
            the correct shape and dtype.
        """
        ...

    def get_pertensor_param(self, params_dtype: torch.dtype) -> Dict[str, Any]:
        """Return per-tensor parameter specifications (e.g., input_scale).
        
        Args:
            params_dtype: Data type for parameters.
            
        Returns:
            Dictionary mapping parameter names to empty tensors.
        """
        return {}

    def get_perchannel_param(self, output_size: int,
                             params_dtype: torch.dtype) -> Dict[str, Any]:
        """Return per-channel parameter specifications (e.g., weight_scale).
        
        Args:
            output_size: Output dimension of the linear layer.
            params_dtype: Data type for parameters.
            
        Returns:
            Dictionary mapping parameter names to empty tensors.
        """
        return {}

    def get_pergroup_param(self,
                           input_size: int,
                           output_size: int,
                           params_dtype: torch.dtype,
                           layer_type: Optional[str] = None) -> Dict[str, Any]:
        """Return per-group parameter specifications.
        
        Args:
            input_size: Input dimension of the linear layer.
            output_size: Output dimension of the linear layer.
            params_dtype: Data type for parameters.
            layer_type: Type of layer (e.g., "row" for RowParallelLinear).
            
        Returns:
            Dictionary mapping parameter names to empty tensors.
        """
        return {}

    @abstractmethod
    def apply(self,
              layer: torch.nn.Module,
              x: torch.Tensor,
              bias: Optional[torch.Tensor] = None,
              tp_rank: Optional[int] = 0) -> torch.Tensor:
        """Forward computation.
        
        Args:
            layer: The linear layer module.
            x: Input tensor.
            bias: Optional bias tensor.
            tp_rank: Tensor parallel rank.
            
        Returns:
            Output tensor after quantized linear operation.
        """
        ...

    def process_weights_after_loading(self, layer: torch.nn.Module) -> None:
        """Post-loading weight processing (transpose, format conversion, etc.).
        
        Args:
            layer: The linear layer module.
        """
        pass


class AscendAttentionScheme(ABC):
    """Base class for all attention quantization schemes.
    
    Subclasses must implement apply() method.
    Other methods have default implementations.
    """

    def create_weights(self, layer: torch.nn.Module) -> None:
        """Create weights for attention quantization.
        
        Args:
            layer: The attention layer module.
        """
        pass

    def process_weights_after_loading(self, layer: torch.nn.Module) -> None:
        """Post-loading weight processing for attention layer.
        
        Args:
            layer: The attention layer module.
        """
        pass

    @abstractmethod
    def apply(self, layer: torch.nn.Module, query: torch.Tensor,
              key: torch.Tensor, value: torch.Tensor, kv_cache, attn_metadata,
              attn_type, scale, output) -> torch.Tensor:
        """Forward computation for attention layer.
        
        Args:
            layer: The attention layer module.
            query: Query tensor.
            key: Key tensor.
            value: Value tensor.
            kv_cache: KV cache.
            attn_metadata: Attention metadata.
            attn_type: Attention type.
            scale: Scale factor.
            output: Output tensor.
            
        Returns:
            Output tensor after attention computation.
        """
        ...


class AscendMoEScheme(ABC):
    """Base class for all MoE quantization schemes.
    
    Subclasses must implement get_weight(), get_dynamic_quant_param(),
    and apply() methods.
    
    Attributes:
        quant_type: The quantization type for this scheme. Subclasses should
                   override this class attribute to declare their quant type.
    """

    # Default quant type - subclasses should override this
    quant_type: QuantType = QuantType.NONE

    @abstractmethod
    def get_weight(self, num_experts: int,
                   intermediate_size_per_partition: int, hidden_sizes: int,
                   params_dtype: torch.dtype) -> Dict[str, Any]:
        """Return weight tensor specifications for MoE layer.
        
        Args:
            num_experts: Number of experts.
            intermediate_size_per_partition: Intermediate size per partition.
            hidden_sizes: Hidden dimension size.
            params_dtype: Data type for parameters.
            
        Returns:
            Dictionary mapping parameter names to empty tensors.
        """
        ...

    @abstractmethod
    def get_dynamic_quant_param(self, num_experts: int,
                                intermediate_size_per_partition: int,
                                hidden_sizes: int,
                                params_dtype: torch.dtype) -> Dict[str, Any]:
        """Return dynamic quantization parameters for MoE layer.
        
        Args:
            num_experts: Number of experts.
            intermediate_size_per_partition: Intermediate size per partition.
            hidden_sizes: Hidden dimension size.
            params_dtype: Data type for parameters.
            
        Returns:
            Dictionary mapping parameter names to empty tensors.
        """
        ...

    @abstractmethod
    def apply(
        self,
        layer: torch.nn.Module,
        x: torch.Tensor,
        router_logits: torch.Tensor,
        top_k: int,
        renormalize: bool,
        use_grouped_topk: bool = False,
        global_num_experts: int = -1,
        expert_map: Optional[torch.Tensor] = None,
        topk_group: Optional[int] = None,
        num_expert_group: Optional[int] = None,
        custom_routing_function: Optional[Callable] = None,
        scoring_func: str = "softmax",
        routed_scaling_factor: float = 1.0,
        e_score_correction_bias: Optional[torch.Tensor] = None,
        is_prefill: bool = True,
        enable_force_load_balance: bool = False,
        log2phy: Optional[torch.Tensor] = None,
        global_redundant_expert_num: int = 0,
        **kwargs,
    ) -> torch.Tensor:
        """Forward computation for MoE layer.
        
        Args:
            layer: The MoE layer module.
            x: Input hidden states.
            router_logits: Router logits for expert selection.
            top_k: Number of experts to select per token.
            renormalize: Whether to renormalize expert weights.
            use_grouped_topk: Whether to use grouped top-k selection.
            global_num_experts: Total number of experts globally.
            expert_map: Mapping from local to global expert indices.
            topk_group: Group size for grouped top-k.
            num_expert_group: Number of expert groups.
            custom_routing_function: Custom routing function.
            scoring_func: Scoring function name.
            routed_scaling_factor: Scaling factor for routed experts.
            e_score_correction_bias: Expert score correction bias.
            is_prefill: Whether in prefill phase.
            enable_force_load_balance: Whether to force load balancing.
            log2phy: Logical to physical expert mapping.
            global_redundant_expert_num: Number of redundant experts.
            **kwargs: Additional keyword arguments.
            
        Returns:
            Output tensor after MoE computation.
        """
        ...

    def process_weights_after_loading(self, layer: torch.nn.Module) -> None:
        """Post-loading weight processing for MoE layer.
        
        Args:
            layer: The MoE layer module.
        """
        pass
[Refactor] Quantization Module Refactor (#5738) ### Summary This PR refactors the `vllm_ascend/quantization` module to improve code organization, maintainability, and extensibility. The refactoring introduces a clear separation of concerns with a registry-based scheme discovery pattern, abstract base classes for quantization schemes, and dedicated wrapper classes. ### Key Changes #### 1. Modular Directory Structure \| Before \| After \| \|--------\|-------\| \| Flat file structure with mixed responsibilities \| Organized into `methods/` subpackage for schemes \| \| Single `quant_config.py` (600+ lines) \| Separate config files: `modelslim_config.py`, `compressed_tensors_config.py` \| \| `utils.py` with scheme lookup logic \| `methods/registry.py` with decorator-based registration \| #### 2. Registry-Based Scheme Discovery Replaced hardcoded `ASCEND_QUANTIZATION_METHOD_MAP` dictionary with a decorator-based registry pattern: ```python # Before: Manual dictionary mapping ASCEND_QUANTIZATION_METHOD_MAP = { "W8A8_DYNAMIC": {"linear": AscendW8A8DynamicLinearMethod, ...}, ... } # After: Decorator-based registration @register_scheme("W8A8_DYNAMIC", "linear") class AscendW8A8DynamicLinearMethod(AscendLinearScheme): ... ``` #### 3. Abstract Base Classes Introduced three abstract base classes in `methods/base.py`: - `AscendLinearScheme` - Base for linear layer quantization - `AscendMoEScheme` - Base for MoE layer quantization - `AscendAttentionScheme` - Base for attention layer quantization #### 4. Separated Config and Wrapper Classes - Config classes (`AscendModelSlimConfig`, `AscendCompressedTensorsConfig`): Handle config parsing and scheme selection - Wrapper classes (`AscendLinearMethod`, `AscendFusedMoEMethod`, etc.): Implement vLLM interfaces and delegate to schemes #### 5. Cleaner Public API ```python # New clean module interface from vllm_ascend.quantization import ( AscendModelSlimConfig, AscendCompressedTensorsConfig, ) from vllm_ascend.quantization.methods import get_scheme_class ``` ### Architecture Diagram ```mermaid classDiagram direction TB class QuantizationConfig { <<vLLM Interface>> +get_quant_method() } class AscendModelSlimConfig { +quant_description +get_quant_method() -create_scheme_for_layer() } class AscendCompressedTensorsConfig { +target_scheme_map +get_quant_method() -_get_scheme_from_parts() } class AscendLinearMethod { <<Wrapper>> +quant_method: AscendLinearScheme +create_weights() +apply() } class AscendFusedMoEMethod { <<Wrapper>> +quant_method: AscendMoEScheme +create_weights() +apply() } class AscendLinearScheme { <<Abstract>> +get_weight()* +apply()* +get_pertensor_param() +get_perchannel_param() } class AscendMoEScheme { <<Abstract>> +get_weight()* +get_dynamic_quant_param()* +apply()* } class W8A8DynamicLinear { +get_weight() +apply() } class W8A8DynamicMoE { +get_weight() +apply() } QuantizationConfig <\|-- AscendModelSlimConfig QuantizationConfig <\|-- AscendCompressedTensorsConfig AscendModelSlimConfig ..> AscendLinearMethod : creates AscendModelSlimConfig ..> AscendFusedMoEMethod : creates AscendCompressedTensorsConfig ..> AscendLinearMethod : creates AscendCompressedTensorsConfig ..> AscendFusedMoEMethod : creates AscendLinearMethod o-- AscendLinearScheme : delegates to AscendFusedMoEMethod o-- AscendMoEScheme : delegates to AscendLinearScheme <\|-- W8A8DynamicLinear AscendMoEScheme <\|-- W8A8DynamicMoE ``` ### Scheme Registration Flow ```mermaid sequenceDiagram participant Module as Scheme Module participant Registry as _SCHEME_REGISTRY participant Config as QuantConfig participant Wrapper as Wrapper Class Note over Module: At import time Module->>Registry: @register_scheme("W8A8_DYNAMIC", "linear") Registry->>Registry: Store (quant_type, layer_type) -> Class Note over Config: At runtime Config->>Config: Determine quant_type from description Config->>Registry: get_scheme_class(quant_type, layer_type) Registry-->>Config: Return scheme class Config->>Config: scheme = scheme_cls() Config->>Wrapper: Create wrapper with scheme Wrapper-->>Config: Return wrapper instance ``` ### File Changes Summary \| Original Files \| Refactored Files \| \|----------------\|------------------\| \| `__init__.py` (empty) \| `__init__.py` (exports public API) \| \| `quant_config.py` \| `modelslim_config.py` + `wrappers.py` \| \| `compressed_tensors/` \| `compressed_tensors_config.py` \| \| `utils.py` \| `methods/registry.py` \| \| `w8a8_dynamic.py` \| `methods/w8a8_dynamic.py` \| \| `w8a8.py` \| `methods/w8a8_static.py` \| \| `w4a4_flatquant_dynamic.py` \| `methods/w4a4_flatquant.py` \| \| ... \| `methods/base.py` (new) \| ### Benefits 1. Extensibility: Adding new quantization schemes only requires implementing the base class and adding `@register_scheme` decorator 2. Maintainability: Clear separation between config parsing, wrapper logic, and scheme implementation 3. Testability: Abstract base classes enable easier unit testing and mocking 4. Discoverability: Registry pattern makes it easy to list all supported schemes 5. Reduced Coupling: Config classes no longer need to know about all scheme implementations ___ - vLLM version: v0.13.0 - vLLM main: https://github.com/vllm-project/vllm/commit/2f4e6548efec402b913ffddc8726230d9311948d --------- Signed-off-by: SlightwindSec <slightwindsec@gmail.com> 2026-01-23 14:13:47 +08:00			`#`
			`# 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.`
			`#`
			`"""Abstract base classes for Ascend quantization schemes."""`

			`from abc import ABC, abstractmethod`
			`from enum import Enum`
			`from typing import Any, Callable, Dict, Optional`

			`import torch`


			`class QuantType(Enum):`
			`"""Quantization type enum for MoE schemes."""`
			`NONE = 0`
			`W8A8 = 1`
			`W4A8 = 2`


			`class AscendLinearScheme(ABC):`
			`"""Base class for all linear quantization schemes.`

			`Subclasses must implement get_weight() and apply() methods.`
			`Other methods have default implementations that return empty dicts`
			`or do nothing.`
			`"""`

			`@abstractmethod`
			`def get_weight(self, input_size: int, output_size: int,`
			`params_dtype: torch.dtype) -> Dict[str, Any]:`
			`"""Return weight tensor specifications.`

			`Args:`
			`input_size: Input dimension of the linear layer.`
			`output_size: Output dimension of the linear layer.`
			`params_dtype: Data type for parameters.`

			`Returns:`
			`Dictionary mapping parameter names to empty tensors with`
			`the correct shape and dtype.`
			`"""`
			`...`

			`def get_pertensor_param(self, params_dtype: torch.dtype) -> Dict[str, Any]:`
			`"""Return per-tensor parameter specifications (e.g., input_scale).`

			`Args:`
			`params_dtype: Data type for parameters.`

			`Returns:`
			`Dictionary mapping parameter names to empty tensors.`
			`"""`
			`return {}`

			`def get_perchannel_param(self, output_size: int,`
			`params_dtype: torch.dtype) -> Dict[str, Any]:`
			`"""Return per-channel parameter specifications (e.g., weight_scale).`

			`Args:`
			`output_size: Output dimension of the linear layer.`
			`params_dtype: Data type for parameters.`

			`Returns:`
			`Dictionary mapping parameter names to empty tensors.`
			`"""`
			`return {}`

			`def get_pergroup_param(self,`
			`input_size: int,`
			`output_size: int,`
			`params_dtype: torch.dtype,`
			`layer_type: Optional[str] = None) -> Dict[str, Any]:`
			`"""Return per-group parameter specifications.`

			`Args:`
			`input_size: Input dimension of the linear layer.`
			`output_size: Output dimension of the linear layer.`
			`params_dtype: Data type for parameters.`
			`layer_type: Type of layer (e.g., "row" for RowParallelLinear).`

			`Returns:`
			`Dictionary mapping parameter names to empty tensors.`
			`"""`
			`return {}`

			`@abstractmethod`
			`def apply(self,`
			`layer: torch.nn.Module,`
			`x: torch.Tensor,`
			`bias: Optional[torch.Tensor] = None,`
			`tp_rank: Optional[int] = 0) -> torch.Tensor:`
			`"""Forward computation.`

			`Args:`
			`layer: The linear layer module.`
			`x: Input tensor.`
			`bias: Optional bias tensor.`
			`tp_rank: Tensor parallel rank.`

			`Returns:`
			`Output tensor after quantized linear operation.`
			`"""`
			`...`

			`def process_weights_after_loading(self, layer: torch.nn.Module) -> None:`
			`"""Post-loading weight processing (transpose, format conversion, etc.).`

			`Args:`
			`layer: The linear layer module.`
			`"""`
			`pass`


			`class AscendAttentionScheme(ABC):`
			`"""Base class for all attention quantization schemes.`

			`Subclasses must implement apply() method.`
			`Other methods have default implementations.`
			`"""`

			`def create_weights(self, layer: torch.nn.Module) -> None:`
			`"""Create weights for attention quantization.`

			`Args:`
			`layer: The attention layer module.`
			`"""`
			`pass`

			`def process_weights_after_loading(self, layer: torch.nn.Module) -> None:`
			`"""Post-loading weight processing for attention layer.`

			`Args:`
			`layer: The attention layer module.`
			`"""`
			`pass`

			`@abstractmethod`
			`def apply(self, layer: torch.nn.Module, query: torch.Tensor,`
			`key: torch.Tensor, value: torch.Tensor, kv_cache, attn_metadata,`
			`attn_type, scale, output) -> torch.Tensor:`
			`"""Forward computation for attention layer.`

			`Args:`
			`layer: The attention layer module.`
			`query: Query tensor.`
			`key: Key tensor.`
			`value: Value tensor.`
			`kv_cache: KV cache.`
			`attn_metadata: Attention metadata.`
			`attn_type: Attention type.`
			`scale: Scale factor.`
			`output: Output tensor.`

			`Returns:`
			`Output tensor after attention computation.`
			`"""`
			`...`


			`class AscendMoEScheme(ABC):`
			`"""Base class for all MoE quantization schemes.`

			`Subclasses must implement get_weight(), get_dynamic_quant_param(),`
			`and apply() methods.`

			`Attributes:`
			`quant_type: The quantization type for this scheme. Subclasses should`
			`override this class attribute to declare their quant type.`
			`"""`

			`# Default quant type - subclasses should override this`
			`quant_type: QuantType = QuantType.NONE`

			`@abstractmethod`
			`def get_weight(self, num_experts: int,`
			`intermediate_size_per_partition: int, hidden_sizes: int,`
			`params_dtype: torch.dtype) -> Dict[str, Any]:`
			`"""Return weight tensor specifications for MoE layer.`

			`Args:`
			`num_experts: Number of experts.`
			`intermediate_size_per_partition: Intermediate size per partition.`
			`hidden_sizes: Hidden dimension size.`
			`params_dtype: Data type for parameters.`

			`Returns:`
			`Dictionary mapping parameter names to empty tensors.`
			`"""`
			`...`

			`@abstractmethod`
			`def get_dynamic_quant_param(self, num_experts: int,`
			`intermediate_size_per_partition: int,`
			`hidden_sizes: int,`
			`params_dtype: torch.dtype) -> Dict[str, Any]:`
			`"""Return dynamic quantization parameters for MoE layer.`

			`Args:`
			`num_experts: Number of experts.`
			`intermediate_size_per_partition: Intermediate size per partition.`
			`hidden_sizes: Hidden dimension size.`
			`params_dtype: Data type for parameters.`

			`Returns:`
			`Dictionary mapping parameter names to empty tensors.`
			`"""`
			`...`

			`@abstractmethod`
			`def apply(`
			`self,`
			`layer: torch.nn.Module,`
			`x: torch.Tensor,`
			`router_logits: torch.Tensor,`
			`top_k: int,`
			`renormalize: bool,`
			`use_grouped_topk: bool = False,`
			`global_num_experts: int = -1,`
			`expert_map: Optional[torch.Tensor] = None,`
			`topk_group: Optional[int] = None,`
			`num_expert_group: Optional[int] = None,`
			`custom_routing_function: Optional[Callable] = None,`
			`scoring_func: str = "softmax",`
			`routed_scaling_factor: float = 1.0,`
			`e_score_correction_bias: Optional[torch.Tensor] = None,`
			`is_prefill: bool = True,`
			`enable_force_load_balance: bool = False,`
			`log2phy: Optional[torch.Tensor] = None,`
			`global_redundant_expert_num: int = 0,`
			`**kwargs,`
			`) -> torch.Tensor:`
			`"""Forward computation for MoE layer.`

			`Args:`
			`layer: The MoE layer module.`
			`x: Input hidden states.`
			`router_logits: Router logits for expert selection.`
			`top_k: Number of experts to select per token.`
			`renormalize: Whether to renormalize expert weights.`
			`use_grouped_topk: Whether to use grouped top-k selection.`
			`global_num_experts: Total number of experts globally.`
			`expert_map: Mapping from local to global expert indices.`
			`topk_group: Group size for grouped top-k.`
			`num_expert_group: Number of expert groups.`
			`custom_routing_function: Custom routing function.`
			`scoring_func: Scoring function name.`
			`routed_scaling_factor: Scaling factor for routed experts.`
			`e_score_correction_bias: Expert score correction bias.`
			`is_prefill: Whether in prefill phase.`
			`enable_force_load_balance: Whether to force load balancing.`
			`log2phy: Logical to physical expert mapping.`
			`global_redundant_expert_num: Number of redundant experts.`
			`**kwargs: Additional keyword arguments.`

			`Returns:`
			`Output tensor after MoE computation.`
			`"""`
			`...`

			`def process_weights_after_loading(self, layer: torch.nn.Module) -> None:`
			`"""Post-loading weight processing for MoE layer.`

			`Args:`
			`layer: The MoE layer module.`
			`"""`
			`pass`