# 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.model_executor.layers.fused_moe.config import ( FusedMoEConfig, FusedMoEQuantConfig, ) from vllm.model_executor.layers.fused_moe.topk_weight_and_reduce import ( TopKWeightAndReduceNoOP, ) class TrtLlmGenExperts(mk.FusedMoEPermuteExpertsUnpermute): def __init__( self, moe: FusedMoEConfig, quant_config: FusedMoEQuantConfig, gemm1_alpha, gemm1_beta, gemm1_clamp_limit, max_capture_size, ): super().__init__(quant_config) self.moe = moe self.gemm1_alpha = gemm1_alpha self.gemm1_beta = gemm1_beta self.gemm1_clamp_limit = gemm1_clamp_limit self.max_capture_size = max_capture_size @property def activation_formats( self, ) -> tuple[mk.FusedMoEActivationFormat, mk.FusedMoEActivationFormat]: return ( mk.FusedMoEActivationFormat.Standard, mk.FusedMoEActivationFormat.Standard, ) def supports_chunking(self) -> bool: return True def supports_expert_map(self) -> bool: return True def finalize_weight_and_reduce_impl(self) -> mk.TopKWeightAndReduce: return TopKWeightAndReduceNoOP() def workspace_shapes( self, M: int, N: int, K: int, topk: int, global_num_experts: int, local_num_experts: int, expert_tokens_meta: mk.ExpertTokensMetadata | None, ) -> tuple[tuple[int, ...], tuple[int, ...], tuple[int, ...]]: # The workspaces for this implementation are managed by flashinfer. workspace1 = (0,) workspace2 = (0,) output = (M, K) return (workspace1, workspace2, output) def apply( self, output: torch.Tensor, hidden_states: torch.Tensor, w1: torch.Tensor, w2: torch.Tensor, topk_weights: torch.Tensor, topk_ids: torch.Tensor, activation: str, global_num_experts: int, expert_map: torch.Tensor | None, a1q_scale: torch.Tensor | None, a2_scale: torch.Tensor | None, workspace13: torch.Tensor, workspace2: torch.Tensor, expert_tokens_meta: mk.ExpertTokensMetadata | None, apply_router_weight_on_input: bool, ): topk = topk_ids.size(-1) local_num_experts = w1.size(0) intermediate_size = w2.size(1) local_expert_offset = self.moe.ep_rank * local_num_experts x_quant = hidden_states x_scale = a1q_scale if x_scale is not None: x_scale = x_scale.view(torch.float8_e4m3fn).reshape(*x_quant.shape[:-1], -1) packed_tensor = (topk_ids.to(torch.int32) << 16) | topk_weights.to( torch.bfloat16 ).view(torch.int16) assert self.w1_scale is not None assert self.w2_scale is not None kwargs = { "topk_ids": packed_tensor, "routing_bias": None, "hidden_states": x_quant, "hidden_states_scale": x_scale, "gemm1_weights": w1, "gemm1_weights_scale": self.w1_scale, "gemm1_bias": self.w1_bias, "gemm1_alpha": self.gemm1_alpha, "gemm1_beta": self.gemm1_beta, "gemm1_clamp_limit": self.gemm1_clamp_limit, "gemm2_weights": w2, "gemm2_weights_scale": self.w2_scale, "gemm2_bias": self.w2_bias, "output1_scale_scalar": None, "output1_scale_gate_scalar": None, "output2_scale_scalar": None, "num_experts": global_num_experts, "top_k": topk, "n_group": None, "topk_group": None, "intermediate_size": intermediate_size, "local_expert_offset": local_expert_offset, "local_num_experts": local_num_experts, "routed_scaling_factor": None, "tile_tokens_dim": None, "routing_method_type": 1, "do_finalize": True, "output": output, "tune_max_num_tokens": max(self.max_capture_size, 1), } from flashinfer import trtllm_fp4_block_scale_routed_moe from vllm.utils.flashinfer import autotune with autotune(False): # Enable autotune when, # https://github.com/flashinfer-ai/flashinfer/issues/2023 is # resolved. trtllm_fp4_block_scale_routed_moe(**kwargs) return output