# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project import torch import vllm.model_executor.layers.fused_moe.modular_kernel as mk from vllm.distributed import get_ep_group from vllm.model_executor.layers.fused_moe.config import FusedMoEQuantConfig from vllm.model_executor.layers.fused_moe.topk_weight_and_reduce import ( TopKWeightAndReduceContiguous, TopKWeightAndReduceDelegate, ) from vllm.model_executor.layers.fused_moe.utils import moe_kernel_quantize_input from vllm.utils.flashinfer import nvfp4_block_scale_interleave class MoEPrepareAndFinalizeNaiveEP(mk.FusedMoEPrepareAndFinalize): def __init__( self, is_sequence_parallel: bool = False, num_dispatchers: int = 1, ) -> None: super().__init__() self.is_sequence_parallel = is_sequence_parallel self._num_dispatchers = num_dispatchers @property def activation_format(self) -> mk.FusedMoEActivationFormat: return mk.FusedMoEActivationFormat.Standard def max_num_tokens_per_rank(self) -> int | None: return None def topk_indices_dtype(self) -> torch.dtype | None: return None def num_dispatchers(self) -> int: return self._num_dispatchers def output_is_reduced(self) -> bool: return False def prepare( self, a1: torch.Tensor, topk_weights: torch.Tensor, topk_ids: torch.Tensor, num_experts: int, expert_map: torch.Tensor | None, apply_router_weight_on_input: bool, quant_config: FusedMoEQuantConfig, defer_input_quant: bool = False, ) -> mk.PrepareResultType: if apply_router_weight_on_input: topk = topk_ids.size(1) assert topk == 1, ( "apply_router_weight_on_input is only implemented for topk=1" ) # Note: do not use inplace for shared experts overlap a1 = a1 * topk_weights.to(a1.dtype) # Defer input quantization to the MoE kernel. use_nvfp4 = quant_config.use_nvfp4_w4a4 if defer_input_quant: a1q = a1 a1q_scale = None else: a1q, a1q_scale = moe_kernel_quantize_input( a1, quant_config.a1_gscale if use_nvfp4 else quant_config.a1_scale, quant_config.quant_dtype, quant_config.per_act_token_quant, quant_config.block_shape, # NOTE: swizzling pads the scales to multiple of 128 # which makes the scales tensor different shape than # the hidden states, breaking the A2A kernel. So, we # delay the swizzling until after the A2A. is_fp4_scale_swizzled=False, ) # Skip gathering scales if we have static quantization # (the scale is a scalar, replicated on all ranks) or # if quantization is deferred. skip_gather_scales = a1q_scale is None or a1q_scale.ndim == 0 scales = None if skip_gather_scales else [a1q_scale] res = get_ep_group().dispatch( a1q, topk_weights, topk_ids, is_sequence_parallel=self.is_sequence_parallel, extra_tensors=scales, ) if skip_gather_scales: a1q, topk_weights, topk_ids = res else: a1q, topk_weights, topk_ids, scales = res assert scales is not None and len(scales) == 1 a1q_scale = scales[0] if quant_config.quant_dtype == "nvfp4": assert a1q_scale is not None if a1q_scale.element_size() == 1: a1q_scale = a1q_scale.view(torch.uint8) a1q_scale = nvfp4_block_scale_interleave(a1q_scale) return a1q, a1q_scale, None, topk_ids, topk_weights def finalize( self, output: torch.Tensor, fused_expert_output: torch.Tensor, topk_weights: torch.Tensor, topk_ids: torch.Tensor, apply_router_weight_on_input: bool, weight_and_reduce_impl: mk.TopKWeightAndReduce, ) -> None: if isinstance(weight_and_reduce_impl, TopKWeightAndReduceDelegate): weight_and_reduce_impl = TopKWeightAndReduceContiguous() out = weight_and_reduce_impl.apply( output=None, fused_expert_output=fused_expert_output, topk_weights=topk_weights, topk_ids=topk_ids, apply_router_weight_on_input=apply_router_weight_on_input, ) output.copy_( get_ep_group().combine(out, is_sequence_parallel=self.is_sequence_parallel) ) class MoEPrepareAndFinalizeNoEP(mk.FusedMoEPrepareAndFinalize): @property def activation_format(self) -> mk.FusedMoEActivationFormat: return mk.FusedMoEActivationFormat.Standard def max_num_tokens_per_rank(self) -> int | None: return None def topk_indices_dtype(self) -> torch.dtype | None: return None def num_dispatchers(self) -> int: return 1 def output_is_reduced(self) -> bool: return False def prepare( self, a1: torch.Tensor, topk_weights: torch.Tensor, topk_ids: torch.Tensor, num_experts: int, expert_map: torch.Tensor | None, apply_router_weight_on_input: bool, quant_config: FusedMoEQuantConfig, defer_input_quant: bool = False, ) -> mk.PrepareResultType: if apply_router_weight_on_input: topk = topk_ids.size(1) # TODO: this only works for topK=1, will need to update for topK>1 assert topk == 1, ( "apply_router_weight_on_input is only implemented for topk=1" ) # Note: do not use inplace for shared experts overlap a1 = a1 * topk_weights.to(a1.dtype) # Defer input quant to moe kernel for backends (e.g. AITER, FI) # which use a single kernel call for quant + experts. if defer_input_quant: return a1, None, None, None, None input_sf = ( quant_config.a1_gscale if quant_config.use_nvfp4_w4a4 else quant_config.a1_scale ) a1q, a1q_scale = moe_kernel_quantize_input( a1, input_sf, quant_config.quant_dtype, quant_config.per_act_token_quant, quant_config.block_shape, ) return a1q, a1q_scale, None, None, None def finalize( self, output: torch.Tensor, fused_expert_output: torch.Tensor, topk_weights: torch.Tensor, topk_ids: torch.Tensor, apply_router_weight_on_input: bool, weight_and_reduce_impl: mk.TopKWeightAndReduce, ) -> None: if isinstance(weight_and_reduce_impl, TopKWeightAndReduceDelegate): weight_and_reduce_impl = TopKWeightAndReduceContiguous() weight_and_reduce_impl.apply( output=output, fused_expert_output=fused_expert_output, topk_weights=topk_weights, topk_ids=topk_ids, apply_router_weight_on_input=apply_router_weight_on_input, )