# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project import numpy as np import torch from vllm.model_executor.models.interfaces import SupportsMultiModal from vllm.multimodal.inputs import MultiModalFeatureSpec, MultiModalKwargsItem from vllm.multimodal.utils import group_mm_kwargs_by_modality from vllm.v1.worker.gpu.buffer_utils import UvaBufferPool from vllm.v1.worker.utils import sanity_check_mm_encoder_outputs class EncoderRunner: def __init__( self, max_num_tokens: int, hidden_size: int, dtype: torch.dtype, device: torch.device, ): self.max_num_tokens = max_num_tokens self.hidden_size = hidden_size self.dtype = dtype self.device = device self.inputs_embeds = torch.zeros( max_num_tokens, hidden_size, dtype=dtype, device=device, ) self.req_id_to_mm_features: dict[str, list[MultiModalFeatureSpec]] = {} self.encoder_cache: dict[str, torch.Tensor] = {} self.tmp_is_mm_embed = UvaBufferPool(max_num_tokens, torch.bool) def add_request(self, req_id: str, mm_features: list[MultiModalFeatureSpec]): self.req_id_to_mm_features[req_id] = mm_features def free_encoder_cache(self, mm_hash: str) -> None: self.encoder_cache.pop(mm_hash, None) def remove_request(self, req_id: str) -> None: self.req_id_to_mm_features.pop(req_id, None) def prepare_mm_inputs( self, scheduled_encoder_inputs: dict[str, list[int]], ) -> tuple[list[str], list[MultiModalKwargsItem]]: mm_hashes: list[str] = [] mm_kwargs: list[MultiModalKwargsItem] = [] for req_id, encoder_input_ids in scheduled_encoder_inputs.items(): mm_features = self.req_id_to_mm_features[req_id] for mm_input_id in encoder_input_ids: mm_feature = mm_features[mm_input_id] if mm_feature.data is None: continue mm_hashes.append(mm_feature.identifier) mm_kwargs.append(mm_feature.data) return mm_hashes, mm_kwargs @torch.inference_mode() def execute_mm_encoder( self, model: SupportsMultiModal, mm_hashes: list[str], mm_kwargs: list[MultiModalKwargsItem], ) -> list[torch.Tensor]: if not mm_hashes: return [] encoder_outputs: list[torch.Tensor] = [] for modality, num_items, mm_kwargs_group in group_mm_kwargs_by_modality( mm_kwargs, device=self.device, pin_memory=False, ): curr_group_outputs = model.embed_multimodal(**mm_kwargs_group) sanity_check_mm_encoder_outputs( curr_group_outputs, expected_num_items=num_items, ) encoder_outputs.extend(curr_group_outputs) # Cache the encoder outputs by mm_hash for mm_hash, output in zip(mm_hashes, encoder_outputs): self.encoder_cache[mm_hash] = output return encoder_outputs def gather_mm_embeddings( self, req_ids: list[str], total_num_scheduled_tokens: int, num_scheduled_tokens: np.ndarray, query_start_loc: np.ndarray, prefill_lens: np.ndarray, computed_prefill_lens: np.ndarray, ) -> tuple[list[torch.Tensor], torch.Tensor]: is_prefilling = (computed_prefill_lens < prefill_lens).tolist() all_decode = not any(is_prefilling) if all_decode: # All decode requests, so no need to gather any embeddings. return [], torch.zeros( total_num_scheduled_tokens, dtype=torch.bool, device=self.device, ) query_start = computed_prefill_lens.tolist() query_end = (computed_prefill_lens + num_scheduled_tokens).tolist() mm_embeds: list[torch.Tensor] = [] is_mm_embed = torch.zeros( total_num_scheduled_tokens, dtype=torch.bool, device="cpu", pin_memory=False, ) for i, req_id in enumerate(req_ids): if not is_prefilling[i]: # OPTIMIZATION: Skip decode requests. continue mm_features = self.req_id_to_mm_features[req_id] for mm_feature in mm_features: pos_info = mm_feature.mm_position start_pos = pos_info.offset num_encoder_tokens = pos_info.length if start_pos >= query_end[i]: # The encoder output is not needed in this step. break if start_pos + num_encoder_tokens <= query_start[i]: # The encoder output is already processed and stored # in the decoder's KV cache. continue start_idx = max(query_start[i] - start_pos, 0) end_idx = min(query_end[i] - start_pos, num_encoder_tokens) assert start_idx < end_idx curr_embeds_start, curr_embeds_end = ( pos_info.get_embeds_indices_in_range(start_idx, end_idx) ) # If there are no embeddings in the current range, we skip # gathering the embeddings. if curr_embeds_start == curr_embeds_end: continue mm_hash = mm_feature.identifier encoder_output = self.encoder_cache.get(mm_hash, None) assert encoder_output is not None, f"Encoder cache miss for {mm_hash}." if (is_embed := pos_info.is_embed) is not None: is_embed = is_embed[start_idx:end_idx] mm_embeds_item = encoder_output[curr_embeds_start:curr_embeds_end] else: mm_embeds_item = encoder_output[start_idx:end_idx] req_start_pos = query_start_loc[i] + start_pos - query_start[i] is_mm_embed[req_start_pos + start_idx : req_start_pos + end_idx] = ( True if is_embed is None else is_embed ) mm_embeds.append(mm_embeds_item) # Copy the is_mm_embed tensor to the GPU. is_mm_embed = self.tmp_is_mm_embed.copy_to_gpu(is_mm_embed) return mm_embeds, is_mm_embed @torch.inference_mode() def get_inputs_embeds( self, model: SupportsMultiModal, input_ids: torch.Tensor, mm_embeds: list[torch.Tensor], is_mm_embed: torch.Tensor, ) -> torch.Tensor: x = model.embed_input_ids( input_ids, multimodal_embeddings=mm_embeds, is_multimodal=is_mm_embed, ) # Copy to the pre-allocated buffer for CUDA graphs. self.inputs_embeds[: x.shape[0]] = x return self.inputs_embeds