# # 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. # from dataclasses import dataclass from typing import TYPE_CHECKING, Any, Dict, List, Optional, Tuple, Type import numpy as np import torch try: import torch_npu # noqa: F401 except ImportError: print("Failed to import torch_npu.") from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl, AttentionLayer, AttentionMetadata, AttentionType, MLAAttentionImpl) from vllm.attention.backends.utils import (CommonAttentionState, CommonMetadataBuilder, compute_slot_mapping, compute_slot_mapping_start_idx, is_block_tables_empty) from vllm.utils import async_tensor_h2d, make_tensor_with_pad if TYPE_CHECKING: from vllm_ascend.worker.model_runner import ModelInputForNPUBuilder def generate_attn_mask(max_seq_len: int, dtype=torch.float16): # Construct lower triangle matrix. mask_flag = torch.tril( torch.ones((max_seq_len, max_seq_len), dtype=torch.bool)).view(max_seq_len, max_seq_len) # Create upper triangle matrix used to mark mask positions. mask_flag = ~mask_flag # Currently for fp16 dtype, the mask value should be set to -inf. # TODO: Eliminate this part in the future. if dtype == torch.float16: mask_value = torch.finfo(torch.float32).min else: mask_value = 1 attn_mask = torch.masked_fill(torch.zeros(size=(max_seq_len, max_seq_len)), mask_flag, mask_value).to(dtype) return attn_mask class AttentionMaskBuilder: def __init__(self, attn_mask: torch.Tensor): self._seq_len_cached = attn_mask.shape[0] self.attn_mask_cache = attn_mask @classmethod def initialize_from_len(cls, max_seq_len: int, dtype: torch.dtype = torch.float16): return cls(generate_attn_mask(max_seq_len, dtype)) def update_attn_cache(self, seqlen: int, dtype: torch.dtype, device: torch.device): if seqlen > self._seq_len_cached or self.attn_mask_cache.dtype != dtype: self._seq_len_cached = seqlen self.attn_mask_cache = generate_attn_mask(seqlen, dtype) if self.attn_mask_cache.device != device: self.attn_mask_cache = self.attn_mask_cache.to(device) def get_attn_mask(self, max_seq_len: int, dtype: torch.dtype, device: torch.device): self.update_attn_cache(max_seq_len, dtype, device) return self.attn_mask_cache[:max_seq_len, :max_seq_len].contiguous() def get_decode_attn_mask( self, input_lengths: torch.tensor, max_s: int, dtype: torch.dtype, device: torch.device, ): self.update_attn_cache(max_s, dtype, device) return (self.attn_mask_cache.index_select( 0, input_lengths)[:, :max_s].view(-1, 1, max_s).contiguous()) class AscendAttentionBackend(AttentionBackend): @staticmethod def get_name() -> str: return "ASCEND" @staticmethod def get_impl_cls() -> Type["AscendAttentionBackendImpl"]: return AscendAttentionBackendImpl @staticmethod def get_metadata_cls() -> Type["AscendMetadata"]: return AscendMetadata @staticmethod def get_state_cls() -> Type["CommonAttentionState"]: return CommonAttentionState @staticmethod def get_kv_cache_shape( num_blocks: int, block_size: int, num_kv_heads: int, head_size: int, ) -> Tuple[int, ...]: return (2, num_blocks, block_size, num_kv_heads, head_size) @staticmethod def swap_blocks( src_kv_cache: List[torch.Tensor], dst_kv_cache: List[torch.Tensor], src_to_dst: torch.Tensor, ) -> None: src_key_cache, src_value_cache = src_kv_cache[0], src_kv_cache[1] dst_key_cache, dst_value_cache = dst_kv_cache[0], dst_kv_cache[1] src_indices = src_to_dst[:, 0] dst_indices = src_to_dst[:, 1] dst_key_cache[dst_indices] = src_key_cache[src_indices].to( dst_key_cache.device) dst_value_cache[dst_indices] = src_value_cache[src_indices].to( dst_key_cache.device) @staticmethod def copy_blocks( kv_caches: List[torch.Tensor], src_to_dists: torch.Tensor, ) -> None: src_indices = src_to_dists[:, 0] dst_indices = src_to_dists[:, 1] for kv_cache in kv_caches: key_caches = kv_cache[0] value_caches = kv_cache[1] key_caches[dst_indices] = key_caches[src_indices] value_caches[dst_indices] = value_caches[src_indices] @staticmethod def get_builder_cls() -> Type["AscendMetadataBuilder"]: return AscendMetadataBuilder @classmethod def make_metadata_builder(cls, *args, **kwargs) -> "AscendMetadataBuilder": return cls.get_builder_cls()(*args, **kwargs) class AscendMLAAttentionBackend(AscendAttentionBackend): @staticmethod def get_impl_cls() -> Type["AscendMLAAttentionBackendImpl"]: return AscendMLAAttentionBackendImpl @staticmethod def get_kv_cache_shape( num_blocks: int, block_size: int, num_kv_heads: int, head_size: int, ) -> Tuple[int, ...]: return (1, num_blocks, block_size, num_kv_heads * head_size) @dataclass class AscendMetadata(AttentionMetadata): """Metadata for Ascendbackend. * modified from XFormersbackend NOTE: Any python object stored here is not updated when it is cuda-graph replayed. If you have values that need to be changed dynamically, it should be stored in tensor. The tensor has to be updated from `CUDAGraphRunner.forward` API. """ # |---------- N-1 iteration --------| # |---------------- N iteration ---------------------| # |- tokenA -|......................|-- newTokens ---| # |---------- context_len ----------| # |-------------------- seq_len ----------------------| # |-- query_len ---| # FIXME: It is for flash attn. # Maximum sequence length among prefill batch. 0 if there are decoding # requests only. max_prefill_seq_len: int # Maximum sequence length among decode batch. 0 if there are prefill # requests only. max_decode_seq_len: int # (batch_size, max_blocks_per_seq). # Block addresses per sequence. (Seq id -> list of physical block) block_tables: Optional[torch.Tensor] # (batch_size,). The sequence length per sequence. Sequence length means # the computed tokens + new tokens None if it is a decoding. seq_lens: Optional[List[int]] = None # seq_lens stored as a tensor. seq_lens_tensor: Optional[torch.Tensor] = None # Maximum query length in the batch. None for decoding. max_query_len: Optional[int] = None # Self-attention prefill/decode metadata cache _cached_prefill_metadata: Optional["AscendMetadata"] = None _cached_decode_metadata: Optional["AscendMetadata"] = None # Begin encoder attn & enc/dec cross-attn fields... # Encoder sequence lengths representation encoder_seq_lens: Optional[List[int]] = None encoder_seq_lens_tensor: Optional[torch.Tensor] = None # Maximum sequence length among encoder sequences max_encoder_seq_len: Optional[int] = None # Number of tokens input to encoder num_encoder_tokens: Optional[int] = None attn_mask: Optional[torch.Tensor] = None # Cross-attention memory-mapping data structures: slot mapping # and block tables cross_slot_mapping: Optional[torch.Tensor] = None cross_block_tables: Optional[torch.Tensor] = None @property def prefill_metadata(self) -> Optional["AscendMetadata"]: if self.num_prefills == 0: return None if self._cached_prefill_metadata is not None: # Recover cached prefill-phase attention # metadata structure. return self._cached_prefill_metadata assert ((self.seq_lens is not None) or (self.encoder_seq_lens is not None)) # Compute some attn_metadata fields which default to None. slot_mapping = (None if self.slot_mapping is None else self.slot_mapping[:self.num_prefill_tokens]) seq_lens = (None if self.seq_lens is None else self.seq_lens[:self.num_prefills]) block_tables = (None if self.block_tables is None else self.block_tables[:self.num_prefills]) seq_lens_tensor = (None if self.seq_lens_tensor is None else self.seq_lens_tensor[:self.num_prefills]) # Construct & cache prefill-phase attention metadata structure. self._cached_prefill_metadata = AscendMetadata( num_prefills=self.num_prefills, num_prefill_tokens=self.num_prefill_tokens, num_decode_tokens=0, slot_mapping=slot_mapping, seq_lens=seq_lens, seq_lens_tensor=seq_lens_tensor, max_query_len=self.max_query_len, max_prefill_seq_len=self.max_prefill_seq_len, max_decode_seq_len=0, block_tables=block_tables, # Begin encoder & cross attn fields below... encoder_seq_lens=self.encoder_seq_lens, encoder_seq_lens_tensor=self.encoder_seq_lens_tensor, max_encoder_seq_len=self.max_encoder_seq_len, multi_modal_placeholder_index_maps=self. multi_modal_placeholder_index_maps, cross_slot_mapping=self.cross_slot_mapping, cross_block_tables=self.cross_block_tables, enable_kv_scales_calculation=False) return self._cached_prefill_metadata @property def decode_metadata(self) -> Optional["AscendMetadata"]: if self.num_decode_tokens == 0: return None if self._cached_decode_metadata is not None: # Recover cached decode-phase attention # metadata structure. return self._cached_decode_metadata # Compute some attn_metadata fields which default to None. slot_mapping = (None if self.slot_mapping is None else self.slot_mapping[self.num_prefill_tokens:]) seq_lens = (None if self.seq_lens is None else self.seq_lens[self.num_prefills:]) block_tables = (None if self.block_tables is None else self.block_tables[self.num_prefills:]) seq_lens_tensor = (None if self.seq_lens_tensor is None else self.seq_lens_tensor[self.num_prefills:]) # Construct & cache decode-phase attention metadata structure. self._cached_decode_metadata = AscendMetadata( num_prefills=0, num_prefill_tokens=0, num_decode_tokens=self.num_decode_tokens, slot_mapping=slot_mapping, seq_lens=seq_lens, seq_lens_tensor=seq_lens_tensor, max_prefill_seq_len=0, max_decode_seq_len=self.max_decode_seq_len, block_tables=block_tables, # Begin encoder & cross attn fields below... encoder_seq_lens=self.encoder_seq_lens, encoder_seq_lens_tensor=self.encoder_seq_lens_tensor, max_encoder_seq_len=self.max_encoder_seq_len, multi_modal_placeholder_index_maps=self. multi_modal_placeholder_index_maps, cross_slot_mapping=self.cross_slot_mapping, cross_block_tables=self.cross_block_tables, enable_kv_scales_calculation=False) return self._cached_decode_metadata class AscendMetadataBuilder(CommonMetadataBuilder[AscendMetadata]): _attn_mask_builder = None # noqa def __init__(self, input_builder: "ModelInputForNPUBuilder"): self.input_builder = input_builder self.runner = input_builder.runner self.sliding_window = input_builder.sliding_window self.block_size = input_builder.block_size self.attn_mask = None if AscendMetadataBuilder._attn_mask_builder is None: AscendMetadataBuilder._attn_mask_builder = AttentionMaskBuilder.initialize_from_len( 128, self.input_builder.runner.model_config.dtype) def _add_seq_group( self, inter_data: "ModelInputForNPUBuilder.InterDataForSeqGroup", chunked_prefill_enabled: bool): """Add a sequence group to the metadata. Specifically update/append 1. context length. 2. block table. 3. slot mapping. """ is_prompt = inter_data.is_prompt block_tables = inter_data.block_tables for (seq_id, token_len, seq_len, curr_seq_len, query_len, context_len, curr_sliding_window_block) in zip( inter_data.seq_ids, [len(t) for t in inter_data.input_tokens], inter_data.orig_seq_lens, inter_data.seq_lens, inter_data.query_lens, inter_data.context_lens, inter_data.curr_sliding_window_blocks): self.context_lens.append(context_len) if is_prompt: self.num_prefills += 1 self.num_prefill_tokens += token_len self.prefill_seq_lens.append(seq_len) else: assert query_len == 1, ( "seq_len: {}, context_len: {}, query_len: {}".format( seq_len, context_len, query_len)) self.num_decode_tokens += query_len self.curr_seq_lens.append(curr_seq_len) # Compute block table. # TODO(sang): Combine chunked prefill and prefix caching by # only allowing multiple of block_size chunk size. # NOTE: This only works for oooooooxxx style attention. block_table: List[int] = [] prefix_cache_hit = any([ inter_data.prefix_cache_hit for inter_data in self.input_builder.inter_data_list ]) if prefix_cache_hit: # NOTE(woosuk): For flash-attn, the block table should # include the entries for the incoming prefill tokens. if block_tables is not None: block_table = block_tables[seq_id] elif ((chunked_prefill_enabled or not is_prompt) and block_tables is not None): if curr_sliding_window_block == 0: block_table = block_tables[seq_id] else: block_table = block_tables[seq_id][ -curr_sliding_window_block:] self.block_tables.append(block_table) # Compute slot mapping. is_profile_run = is_block_tables_empty(block_tables) start_idx = compute_slot_mapping_start_idx(is_prompt, query_len, context_len, self.sliding_window) compute_slot_mapping( is_profile_run, self.slot_mapping, seq_id, seq_len, context_len, start_idx, self.block_size, inter_data.block_tables, ) def build( self, seq_lens: List[int], query_lens: List[int], ): """Build attention metadata with on-device tensors. Args: seq_lens: The maybe padded sequence lengths of the input sequences. query_lens: The query lengths of the input sequences. """ for inter_data in self.input_builder.inter_data_list: self._add_seq_group(inter_data, self.input_builder.chunked_prefill_enabled) device = self.runner.device max_query_len = max(query_lens) max_prefill_seq_len = max(self.prefill_seq_lens, default=0) max_decode_seq_len = max(self.curr_seq_lens, default=0) if self.num_prefills > 0: self.attn_mask = AscendMetadataBuilder._attn_mask_builder.get_attn_mask( # type: ignore max_prefill_seq_len, self.input_builder.runner.model_config.dtype, self.input_builder.runner.device) else: self.attn_mask = None block_tables = make_tensor_with_pad( self.block_tables, pad=0, dtype=torch.int32, device=device, ) assert max_query_len > 0, "query_lens: {}".format(query_lens) assert device is not None slot_mapping_tensor = async_tensor_h2d(self.slot_mapping, torch.int32, device, self.runner.pin_memory) placeholder_index_maps = { modality: placeholder_map.index_map() for modality, placeholder_map in self.multimodal_placeholder_maps.items() } seq_lens_tensor = torch.tensor(seq_lens, dtype=torch.long, device=device) return AscendMetadata( num_prefills=self.num_prefills, slot_mapping=slot_mapping_tensor, multi_modal_placeholder_index_maps=placeholder_index_maps, enable_kv_scales_calculation=False, num_prefill_tokens=self.num_prefill_tokens, num_decode_tokens=self.num_decode_tokens, seq_lens=seq_lens, seq_lens_tensor=seq_lens_tensor, max_query_len=max_query_len, max_prefill_seq_len=max_prefill_seq_len, max_decode_seq_len=max_decode_seq_len, block_tables=block_tables, attn_mask=self.attn_mask, ) class AscendAttentionBackendImpl(AttentionImpl): def __init__( self, num_heads: int, head_size: int, scale: float, num_kv_heads: int, alibi_slopes: Optional[List[float]], sliding_window: Optional[int], kv_cache_dtype: str, blocksparse_params: Optional[Dict[str, Any]] = None, logits_soft_cap: Optional[float] = None, attn_type: str = AttentionType.DECODER, ) -> None: self.num_heads = num_heads self.head_size = head_size self.scale = float(scale) self.num_kv_heads = num_heads if num_kv_heads is None else num_kv_heads self.hidden_size = self.num_heads * self.head_size self.kv_cache_dtype = kv_cache_dtype self.sliding_window = sliding_window if alibi_slopes is not None: alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32, device="npu") self.alibi_slopes = alibi_slopes self.attn_type = attn_type assert self.num_heads % self.num_kv_heads == 0 self.num_queries_per_kv = self.num_heads // self.num_kv_heads self.seq_len_cpu_tensor = None self.key_cache = None self.value_cache = None def forward( self, layer: AttentionLayer, query: torch.Tensor, key: torch.Tensor, value: torch.Tensor, kv_cache: torch.Tensor, attn_metadata: AscendMetadata, attn_type: str = AttentionType.DECODER, output: Optional[torch.Tensor] = None, ) -> torch.Tensor: """Forward pass with Ascend attention. Args: query: shape = [num_tokens, num_heads * head_size] num_tokens = batch_size * seq_len key: shape = [num_tokens, num_kv_heads * head_size] value: shape = [num_tokens, num_kv_heads * head_size] kv_cache: shape = [2, num_blocks, block_size, num_kv_heads * head_size] key_cache = [num_blocks, block_size, num_kv_heads * head_size] value_cache = [num_blocks, block_size, num_kv_heads * head_size] attn_metadata: Metadata for attention. Returns: shape = [batch_size, seq_len * num_heads * head_size] """ assert layer._k_scale_float == 1.0 and layer._v_scale_float == 1.0 # View q k v to BSH. num_tokens = query.shape[0] query = query.view(-1, self.num_heads, self.head_size) key = key.view(-1, self.num_kv_heads, self.head_size) value = value.view(-1, self.num_kv_heads, self.head_size) # TODO: Remove this contiguous in the future. value = value.contiguous() output = torch.empty(num_tokens, self.num_heads, self.head_size, dtype=query.dtype, device=query.device) if kv_cache.numel() > 0: if self.key_cache is None: self.key_cache, self.value_cache = kv_cache[0], kv_cache[1] slots = attn_metadata.slot_mapping if hasattr(layer, 'quant_method'): isPrefill = True if attn_metadata.num_prefills > 0 else False if isPrefill: assert attn_metadata.prefill_metadata is not None self.seq_lens_tensor_cpu = torch.from_numpy( np.array(attn_metadata.prefill_metadata.seq_lens).astype( np.int32)) else: assert attn_metadata.decode_metadata is not None self.seq_lens_tensor_cpu = torch.from_numpy( np.array(attn_metadata.decode_metadata.seq_lens).astype( np.int32)) block_tables = attn_metadata.decode_metadata.block_tables if attn_metadata.decode_metadata else None # Details of kv_cache arrangement in attention quantization # are implemented by quant_method. layer.quant_method.apply(layer, query, key, value, self.key_cache, self.value_cache, self.scale, self.seq_lens_tensor_cpu, block_tables, isPrefill, attn_metadata, output) else: if self.key_cache is not None: torch_npu._npu_reshape_and_cache(key=key, value=value, key_cache=self.key_cache, value_cache=self.value_cache, slot_indices=slots) if attn_metadata.num_prefills > 0: if (attn_metadata.block_tables is None or attn_metadata.block_tables.numel() == 0): assert attn_metadata.attn_mask is not None mask = attn_metadata.attn_mask assert attn_metadata.prefill_metadata is not None self.seq_lens_tensor_cpu = torch.from_numpy( np.array( attn_metadata.prefill_metadata.seq_lens).astype( np.int32)) torch_npu._npu_flash_attention( query=query, key=key, value=value, mask=mask, seq_len=self.seq_lens_tensor_cpu, scale_value=self.scale, num_heads=self.num_heads, num_kv_heads=self.num_kv_heads, out=output) else: # TODO: Will support prefix cache and chunked prefill soon. raise RuntimeError( "Prefix cache and chunked prefill are currently not supported." ) elif attn_metadata.decode_metadata: assert self.key_cache is not None self.seq_lens_tensor_cpu = torch.from_numpy( np.array(attn_metadata.decode_metadata.seq_lens).astype( np.int32)) block_tables = attn_metadata.decode_metadata.block_tables torch_npu._npu_paged_attention( query=query, key_cache=self.key_cache, value_cache=self.value_cache, num_kv_heads=self.num_kv_heads, num_heads=self.num_heads, scale_value=self.scale, block_table=block_tables, context_lens=self.seq_lens_tensor_cpu, out=output) return output.view(num_tokens, self.hidden_size) class AscendMLAAttentionBackendImpl(MLAAttentionImpl): def __init__( self, num_heads: int, head_size: int, scale: float, num_kv_heads: int, alibi_slopes: Optional[List[float]], sliding_window: Optional[int], kv_cache_dtype: str, blocksparse_params: Optional[Dict[str, Any]] = None, logits_soft_cap: Optional[float] = None, attn_type: str = AttentionType.DECODER, **extra_impl_args, ) -> None: self.num_heads = num_heads self.head_size = head_size self.scale = float(scale) self.num_kv_heads = num_heads if num_kv_heads is None else num_kv_heads self.hidden_size = self.num_heads * self.head_size self.kv_cache_dtype = kv_cache_dtype self.sliding_window = sliding_window if alibi_slopes is not None: alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32, device="npu") self.alibi_slopes = alibi_slopes self.attn_type = attn_type assert self.num_heads % self.num_kv_heads == 0 self.num_queries_per_kv = self.num_heads // self.num_kv_heads self.seq_len_cpu_tensor = None # MLA Args self.q_lora_rank = extra_impl_args['q_lora_rank'] self.kv_lora_rank = extra_impl_args['kv_lora_rank'] self.qk_nope_head_dim = extra_impl_args['qk_nope_head_dim'] self.qk_rope_head_dim = extra_impl_args['qk_rope_head_dim'] self.qk_head_dim = extra_impl_args['qk_head_dim'] self.v_head_dim = extra_impl_args['v_head_dim'] self.rotary_emb = extra_impl_args['rotary_emb'] self.q_proj = extra_impl_args['q_proj'] self.kv_b_proj = extra_impl_args['kv_b_proj'] self.o_proj = extra_impl_args['o_proj'] self.w_kc = None self.w_vc = None def forward( self, layer: AttentionLayer, hidden_states_or_q_c: torch.Tensor, kv_c_normed: torch.Tensor, k_pe: torch.Tensor, kv_cache: torch.Tensor, attn_metadata: AscendMetadata, attn_type: str = AttentionType.DECODER, output: Optional[torch.Tensor] = None, ) -> torch.Tensor: """Forward pass with Ascend attention. Args: hidden_states_or_q_c: shape = [num_tokens, num_heads * head_size] num_tokens = batch_size * seq_len kv_c_normed: shape = [num_tokens, num_kv_heads * head_size] k_pe: shape = [num_tokens, num_kv_heads * head_size] kv_cache: shape = [1, num_blocks, block_size, num_kv_heads * head_size] attn_metadata: Metadata for attention. Returns: shape = [batch_size, seq_len * num_heads * head_size] """ assert layer._k_scale_float == 1.0 and layer._v_scale_float == 1.0 attn_type = self.attn_type if attn_type != AttentionType.DECODER: raise NotImplementedError("Encoder self-attention and " "encoder/decoder cross-attention " "are not implemented for " "PallasAttentionBackendImpl") num_tokens = hidden_states_or_q_c.shape[0] q = self.q_proj(hidden_states_or_q_c)[0].view(-1, self.num_heads, self.qk_head_dim) q_nope, q_pe = q.split([self.qk_nope_head_dim, self.qk_rope_head_dim], dim=-1) k_pe = k_pe.view(num_tokens, self.num_kv_heads, -1) if self.rotary_emb.__class__.__name__ == 'RotaryEmbedding': ori_q_pe_shape, ori_k_pe_shape = q_pe.shape, k_pe.shape q_pe = q_pe.reshape(num_tokens, -1) k_pe = k_pe.reshape(num_tokens, -1) q_pe, k_pe = self.rotary_emb(attn_metadata.input_positions, q_pe, k_pe) q_pe = q_pe.view(ori_q_pe_shape) k_pe = k_pe.view(ori_k_pe_shape) else: q_pe, k_pe = self.rotary_emb(attn_metadata.input_positions, q_pe, k_pe) if self.w_kc is None or self.w_vc is None: kv_b_proj_weight = self.kv_b_proj.weight.reshape( self.num_heads, self.qk_nope_head_dim + self.v_head_dim, self.kv_lora_rank) self.w_kc = kv_b_proj_weight[:, :self. qk_nope_head_dim, :].contiguous() self.w_vc = kv_b_proj_weight[:, self.qk_nope_head_dim:, :].transpose( 1, 2).contiguous() if attn_metadata.num_prefills > 0: kv_heads_num = self.num_heads kv = self.kv_b_proj(kv_c_normed)[0].view(num_tokens, kv_heads_num, -1) k_nope, value = kv.split([self.qk_nope_head_dim, self.v_head_dim], dim=-1) k_cache = torch.cat( [kv_c_normed.view(num_tokens, self.num_kv_heads, -1), k_pe], dim=2) k_pe = k_pe.expand(-1, self.num_heads, -1) key = torch.cat([k_nope.view(num_tokens, kv_heads_num, -1), k_pe], dim=2) else: kv_heads_num = self.num_kv_heads q_nope_t = torch.transpose(q_nope, 0, 1) q_nope_out = torch.bmm(q_nope_t, self.w_kc) q_nope = torch.transpose(q_nope_out, 0, 1) k_cache = torch.cat( [kv_c_normed.view(num_tokens, self.num_kv_heads, -1), k_pe], dim=2) query = torch.cat([q_nope, q_pe], dim=-1).view(num_tokens, self.num_heads, -1) if kv_cache.numel() > 0: key_cache = kv_cache[0] num_blocks, block_size, _ = key_cache.shape key_cache = key_cache.view( num_blocks, block_size, self.num_kv_heads, self.qk_rope_head_dim + self.kv_lora_rank) slots = attn_metadata.slot_mapping torch_npu._npu_reshape_and_cache_siso(key=k_cache, key_cache=key_cache, slot_indices=slots) if attn_metadata.num_prefills > 0: attn_output = torch.empty(num_tokens, self.num_heads, self.v_head_dim, dtype=query.dtype, device="npu") if (attn_metadata.block_tables is None or attn_metadata.block_tables.numel() == 0): assert attn_metadata.attn_mask is not None mask = attn_metadata.attn_mask assert attn_metadata.prefill_metadata is not None assert attn_metadata.prefill_metadata.seq_lens is not None self.seq_lens_tensor_cpu = torch.from_numpy( np.array(attn_metadata.prefill_metadata.seq_lens).astype( np.int32)) torch_npu._npu_flash_attention( query=query, key=key, value=value, mask=mask, seq_len=self.seq_lens_tensor_cpu, scale_value=self.scale, num_heads=self.num_heads, num_kv_heads=self.num_heads, out=attn_output) else: # TODO: Will support prefix cache and chunked prefill soon. raise RuntimeError( "Prefix cache and chunked prefill are currently not supported." ) elif attn_metadata.decode_metadata: assert kv_cache is not None attn_output = torch.empty(num_tokens, self.num_heads, self.kv_lora_rank, dtype=query.dtype, device="npu") self.seq_lens_tensor_cpu = torch.from_numpy( np.array(attn_metadata.decode_metadata.seq_lens).astype( np.int32)) block_tables = attn_metadata.decode_metadata.block_tables torch_npu._npu_paged_attention_mla( query=query, key_cache=key_cache, num_kv_heads=self.num_kv_heads, num_heads=self.num_heads, scale_value=self.scale, block_table=block_tables, context_lens=self.seq_lens_tensor_cpu, mla_vheadsize=self.kv_lora_rank, out=attn_output) attn_output_t = torch.transpose(attn_output, 0, 1) attn_output_t = torch.bmm(attn_output_t, self.w_vc) attn_output = torch.transpose(attn_output_t, 0, 1) output, _ = self.o_proj(attn_output.reshape(num_tokens, -1)) return output