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Commit b9e12416 authored by zhuwenwen's avatar zhuwenwen
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merge v0.4.3

parents e5d707db e9d3aa04
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Showing with 2179 additions and 341 deletions
tests/worker/test_swap.py
View file @ b9e12416
......@@ -54,36 +54,36 @@ def test_swap() -> None:
a.cuda(), b.cuda(), rtol=0.0, atol=0.0)
# Test swap out.
blocks_to_swap_out = {3: 72, 56: 35, 84: 34}
blocks_to_swap_out = [(3, 72), (56, 35), (84, 34)]
execute_model_req = ExecuteModelRequest(
seq_group_metadata_list=[],
blocks_to_swap_in={},
blocks_to_swap_in=[],
blocks_to_swap_out=blocks_to_swap_out,
blocks_to_copy={},
blocks_to_copy=[],
)
worker.execute_model(execute_model_req=execute_model_req)
for i in range(num_layers):
gpu_key_cache, gpu_value_cache = gpu_cache[i]
cpu_key_cache, cpu_value_cache = cpu_cache[i]
for src, dst in blocks_to_swap_out.items():
for src, dst in blocks_to_swap_out:
assert allclose(gpu_key_cache[src], cpu_key_cache[dst])
assert allclose(gpu_value_cache[src], cpu_value_cache[dst])
# Test swap in.
execute_model_req.blocks_to_swap_out = {}
execute_model_req.blocks_to_swap_in = {
19: 45,
67: 23,
12: 78,
40: 99,
1: 71
}
execute_model_req.blocks_to_swap_out = []
execute_model_req.blocks_to_swap_in = [
(19, 45),
(67, 23),
(12, 78),
(40, 99),
(1, 71),
]
worker.execute_model(execute_model_req=execute_model_req)
for i in range(num_layers):
gpu_key_cache, gpu_value_cache = gpu_cache[i]
cpu_key_cache, cpu_value_cache = cpu_cache[i]
for src, dst in execute_model_req.blocks_to_swap_in.items():
for src, dst in execute_model_req.blocks_to_swap_in:
assert allclose(gpu_key_cache[dst], cpu_key_cache[src])
assert allclose(gpu_value_cache[dst], cpu_value_cache[src])
vllm/__init__.py
View file @ b9e12416
......@@ -5,22 +5,31 @@ from vllm.engine.async_llm_engine import AsyncLLMEngine
from vllm.engine.llm_engine import LLMEngine
from vllm.entrypoints.llm import LLM
from vllm.executor.ray_utils import initialize_ray_cluster
from vllm.inputs import PromptStrictInputs, TextPrompt, TokensPrompt
from vllm.model_executor.models import ModelRegistry
from vllm.outputs import CompletionOutput, RequestOutput
from vllm.outputs import (CompletionOutput, EmbeddingOutput,
EmbeddingRequestOutput, RequestOutput)
from vllm.pooling_params import PoolingParams
from vllm.sampling_params import SamplingParams
from vllm.version import __dcu_version__
__version__ = "0.4.2"
__version__ = "0.4.3"
__all__ = [
"LLM",
"ModelRegistry",
"PromptStrictInputs",
"TextPrompt",
"TokensPrompt",
"SamplingParams",
"RequestOutput",
"CompletionOutput",
"EmbeddingOutput",
"EmbeddingRequestOutput",
"LLMEngine",
"EngineArgs",
"AsyncLLMEngine",
"AsyncEngineArgs",
"initialize_ray_cluster",
"PoolingParams",
]
vllm/_custom_ops.py
View file @ b9e12416
from typing import Dict, Optional, Tuple
from typing import Optional, Tuple, Type
import torch
......@@ -45,11 +45,17 @@ def paged_attention_v1(
alibi_slopes: Optional[torch.Tensor],
kv_cache_dtype: str,
kv_scale: float,
tp_rank: int = 0,
blocksparse_local_blocks: int = 0,
blocksparse_vert_stride: int = 0,
blocksparse_block_size: int = 64,
blocksparse_head_sliding_step: int = 0,
) -> None:
vllm_ops.paged_attention_v1(out, query, key_cache, value_cache,
num_kv_heads, scale, block_tables, seq_lens,
block_size, max_seq_len, alibi_slopes,
kv_cache_dtype, kv_scale)
vllm_ops.paged_attention_v1(
out, query, key_cache, value_cache, num_kv_heads, scale, block_tables,
seq_lens, block_size, max_seq_len, alibi_slopes, kv_cache_dtype,
kv_scale, tp_rank, blocksparse_local_blocks, blocksparse_vert_stride,
blocksparse_block_size, blocksparse_head_sliding_step)
def paged_attention_v2(
......@@ -69,12 +75,18 @@ def paged_attention_v2(
alibi_slopes: Optional[torch.Tensor],
kv_cache_dtype: str,
kv_scale: float,
tp_rank: int = 0,
blocksparse_local_blocks: int = 0,
blocksparse_vert_stride: int = 0,
blocksparse_block_size: int = 64,
blocksparse_head_sliding_step: int = 0,
) -> None:
vllm_ops.paged_attention_v2(out, exp_sum, max_logits, tmp_out, query,
key_cache, value_cache, num_kv_heads, scale,
block_tables, seq_lens, block_size,
max_seq_len, alibi_slopes, kv_cache_dtype,
kv_scale)
vllm_ops.paged_attention_v2(
out, exp_sum, max_logits, tmp_out, query, key_cache, value_cache,
num_kv_heads, scale, block_tables, seq_lens, block_size, max_seq_len,
alibi_slopes, kv_cache_dtype, kv_scale, tp_rank,
blocksparse_local_blocks, blocksparse_vert_stride,
blocksparse_block_size, blocksparse_head_sliding_step)
# pos encoding ops
......@@ -153,6 +165,32 @@ def marlin_gemm(a: torch.Tensor, b_q_weight: torch.Tensor,
size_n, size_k)
# marlin_24
def gptq_marlin_24_gemm(a: torch.Tensor, b_q_weight: torch.Tensor,
b_meta: torch.Tensor, b_scales: torch.Tensor,
workspace: torch.Tensor, num_bits: int, size_m: int,
size_n: int, size_k: int) -> torch.Tensor:
return vllm_ops.gptq_marlin_24_gemm(a, b_q_weight, b_meta, b_scales,
workspace, num_bits, size_m, size_n,
size_k)
# cutlass
def cutlass_scaled_mm_dq(a: torch.Tensor, b: torch.Tensor,
a_scales: torch.Tensor, b_scales: torch.Tensor,
out_dtype: Type[torch.dtype]) -> torch.Tensor:
assert (b.shape[0] % 16 == 0 and b.shape[1] % 16 == 0)
assert (out_dtype is torch.bfloat16 or out_dtype is torch.float16)
m = a.shape[0]
n = b.shape[1]
out = torch.empty((m, n), dtype=out_dtype, device=a.device)
vllm_ops.cutlass_scaled_mm_dq(out, a, b, a_scales, b_scales)
return out
# aqlm
def aqlm_gemm(input: torch.Tensor, codes: torch.Tensor,
codebooks: torch.Tensor, scales: torch.Tensor,
......@@ -189,8 +227,34 @@ def gptq_marlin_gemm(a: torch.Tensor, b_q_weight: torch.Tensor,
# def scaled_fp8_quant(
# input: torch.Tensor,
# scale: Optional[torch.Tensor] = None,
# batch_dim_padding: Optional[int] = None,
# ) -> Tuple[torch.Tensor, torch.Tensor]:
# output = torch.empty_like(input, dtype=torch.float8_e4m3fn)
# """
# Quantize input tensor to FP8 and return quantized tensor and scale.
# This function supports both static and dynamic quantization: If you
# provide the scale, it will use static scaling and if you omit it,
# the scale will be determined dynamically. The function also allows
# optional padding of the output tensor for downstream kernels that
# will benefit from padding.
# Args:
# input: The input tensor to be quantized to FP8
# scale: Optional scaling factor for the FP8 quantization
# batch_dim_padding: If specified, pad the first dimension
# of the output to at least this value.
# Returns:
# Tuple[torch.Tensor, torch.Tensor]: The output tensor in FP8 and
# scaling factor.
# """
# if batch_dim_padding:
# shape = (max(batch_dim_padding, input.shape[0]), *input.shape[1:])
# output = torch.empty(shape,
# device=input.device,
# dtype=torch.float8_e4m3fn)
# else:
# output = torch.empty_like(input, dtype=torch.float8_e4m3fn)
# if scale is None:
# scale = torch.zeros(1, device=input.device, dtype=torch.float32)
# vllm_ops.dynamic_scaled_fp8_quant(output, input, scale)
......@@ -199,6 +263,24 @@ def gptq_marlin_gemm(a: torch.Tensor, b_q_weight: torch.Tensor,
# return output, scale
# int8
# def static_scaled_int8_quant(input: torch.Tensor,
# scale: float) -> torch.Tensor:
# """
# Quantize the input tensor to int8 and return the quantized tensor.
# Args:
# input: The input tensor to be quantized to int8.
# scale: Scaling factor for the int8 quantization.
# Returns:
# torch.Tensor: Output tensor in int8.
# """
# q = torch.empty_like(input, dtype=torch.int8)
# vllm_ops.static_scaled_int8_quant(q, input, scale)
# return q
# moe
def moe_align_block_size(topk_ids: torch.Tensor, num_experts: int,
block_size: int, sorted_token_ids: torch.Tensor,
......@@ -240,12 +322,15 @@ def copy_blocks(key_caches: torch.Tensor, value_caches: torch.Tensor,
def swap_blocks(src: torch.Tensor, dst: torch.Tensor,
block_mapping: Dict[int, int]) -> None:
block_mapping: torch.Tensor) -> None:
vllm_cache_ops.swap_blocks(src, dst, block_mapping)
def convert_fp8(output: torch.Tensor, input: torch.Tensor) -> None:
vllm_cache_ops.convert_fp8(output, input)
def convert_fp8(output: torch.Tensor,
input: torch.Tensor,
scale: float = 1.0,
kv_dtype: str = "fp8") -> None:
vllm_cache_ops.convert_fp8(output, input, scale, kv_dtype)
#TODO: cuda_utils, custom_ar
vllm/attention/__init__.py
View file @ b9e12416
from vllm.attention.backends.abstract import (AttentionBackend,
AttentionMetadata,
AttentionMetadataPerStage)
AttentionMetadata)
from vllm.attention.layer import Attention
from vllm.attention.selector import get_attn_backend
__all__ = [
"Attention",
"AttentionBackend",
"AttentionMetadata",
"Attention",
"get_attn_backend",
"AttentionMetadataPerStage",
]
vllm/attention/backends/abstract.py
View file @ b9e12416
......@@ -9,6 +9,11 @@ import torch
class AttentionBackend(ABC):
"""Abstract class for attention backends."""
@staticmethod
@abstractmethod
def get_name() -> str:
raise NotImplementedError
@staticmethod
@abstractmethod
def get_impl_cls() -> Type["AttentionImpl"]:
......@@ -16,7 +21,7 @@ class AttentionBackend(ABC):
@staticmethod
@abstractmethod
def make_metadata(*args, **kwargs) -> "AttentionMetadataPerStage":
def make_metadata(*args, **kwargs) -> "AttentionMetadata":
raise NotImplementedError
@staticmethod
......@@ -34,7 +39,7 @@ class AttentionBackend(ABC):
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
src_to_dst: torch.Tensor,
) -> None:
raise NotImplementedError
......@@ -42,14 +47,40 @@ class AttentionBackend(ABC):
@abstractmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
raise NotImplementedError
@dataclass
class AttentionMetadataPerStage:
"""Attention metadata for a specific stage. I.e., prefill or decode."""
class AttentionMetadata:
"""Attention metadata for prefill and decode batched together."""
# Total number of prefill requests.
num_prefills: int
# Number of prefill tokens.
num_prefill_tokens: int
# Number of decode tokens. Note that it is equivalent to the number of
# decode requests.
num_decode_tokens: int
# (num_tokens,). The indices of the token slots that input tokens will be
# stored into. E.g., if `slot_mapping` is [35, 2, 17] and the block size
# is 16, the three tokens are stored in the 3rd slot in block 2, 2nd slot
# in block 0, and 1st slot in block 1, respectively.
slot_mapping: torch.Tensor
@property
@abstractmethod
def prefill_metadata(self) -> Optional["AttentionMetadata"]:
"""Return the attention metadata that's required to run prefill
attention."""
pass
@property
@abstractmethod
def decode_metadata(self) -> Optional["AttentionMetadata"]:
"""Return the attention metadata that's required to run decode
attention."""
pass
def asdict_zerocopy(self,
skip_fields: Optional[Set[str]] = None
......@@ -65,42 +96,10 @@ class AttentionMetadataPerStage:
}
T = TypeVar("T", bound=AttentionMetadataPerStage)
@dataclass
class AttentionMetadata(Generic[T]):
"""Attention metadata for prefill and decode batched together."""
# Total number of prefill requests.
num_prefills: int
# Number of prefill tokens.
num_prefill_tokens: int
# Number of decode tokens. Note that it is equivalent to the number of
# decode requests.
num_decode_tokens: int
# The attention metadata for prefill requests in a batch.
# None if there's no prefill requests in a batch.
prefill_metadata: Optional[T]
# The attention metadata for decode requests in a batch.
# None if there's no decode requests in a batch.
decode_metadata: Optional[T]
# (num_tokens,). The indices of the token slots that input tokens will be
# stored into. E.g., if `slot_mapping` is [35, 2, 17] and the block size
# is 16, the three tokens are stored in the 3rd slot in block 2, 2nd slot
# in block 0, and 1st slot in block 1, respectively.
slot_mapping: torch.Tensor
# The kv cache's data type.
kv_cache_dtype: str
def __post_init__(self):
if self.num_prefill_tokens > 0:
assert self.num_prefills > 0
assert self.prefill_metadata is not None
if self.num_decode_tokens > 0:
assert self.decode_metadata is not None
T = TypeVar("T", bound=AttentionMetadata)
class AttentionImpl(ABC):
class AttentionImpl(ABC, Generic[T]):
@abstractmethod
def __init__(
......@@ -111,6 +110,8 @@ class AttentionImpl(ABC):
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
kv_cache_dtype: str = "auto",
blocksparse_params: Optional[Dict[str, Any]] = None,
) -> None:
raise NotImplementedError
......@@ -121,7 +122,7 @@ class AttentionImpl(ABC):
key: torch.Tensor,
value: torch.Tensor,
kv_cache: torch.Tensor,
attn_metadata: AttentionMetadata,
kv_scale: float,
attn_metadata: T,
kv_scale: float = 1.0,
) -> torch.Tensor:
raise NotImplementedError
vllm/attention/backends/blocksparse_attn.py 0 → 100644
View file @ b9e12416
from dataclasses import dataclass, field
from typing import Any, Dict, List, Optional, Tuple, Type
import torch
from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl,
AttentionMetadata)
from vllm.attention.ops.blocksparse_attention.interface import (
LocalStridedBlockSparseAttn, get_head_sliding_step)
from vllm.attention.ops.paged_attn import PagedAttention
from vllm.distributed import (get_tensor_model_parallel_rank,
get_tensor_model_parallel_world_size)
@dataclass
class BlocksparseParams:
max_seqlen: int
# Num q heads per tensor-parallel rank/partition
num_heads: int # per TP partition
# Num kv heads per tensor-parallel rank/partition
num_kv_heads: int
# block size used for blocksparse attention.
# This is the block_size used in `local_blocks`, `vert_stride`.
block_size: int
# Number of blocks for local attention, i.e., number of
# local attended tokens / `sparse_block_size`
local_blocks: int
# Attend to one block per every `vert_stride` blocks.
# Controlling the sparsity
vert_stride: int
"""
If to use the same vertical stride offset for all heads,
i.e., attend to the same block of tokens on all heads.
By default, it is False, i.e., attention on the non-local
blocks depends on the `head_idx`, that is on
blocks satisfying
`(block_idx + head_idx * head_sliding_step + 1) % vert_stride == 0`
where `head_sliding_step=max(1, int(vert_stride / num_total_heads))`,
`block_idx = position_id // sparse_block_size`.
See `..ops.blocksparse_attention.utils:get_sparse_attn_mask`
for more detail.
"""
homo_head: bool = False
# If within a group, the kv offsets that each q attends is the same or no.
homo_head_group: bool = False
# Decided by homo_head and homo_head group
head_sliding_step: int = field(init=False)
# range of q heads to for a TP rank
active_head_range: Tuple = field(init=False)
def __post_init__(self):
assert self.block_size > 0
assert self.local_blocks >= 0
assert self.vert_stride >= 1
assert self.num_heads % self.num_kv_heads == 0
tp_size = get_tensor_model_parallel_world_size()
tp_rank = get_tensor_model_parallel_rank()
total_heads = tp_size * self.num_heads
total_kv_heads = tp_size * self.num_kv_heads
if self.homo_head:
self.head_sliding_step = 0
elif self.homo_head_group:
head_sliding_step = get_head_sliding_step(total_kv_heads,
self.vert_stride)
# negative indicates sliding along kv heads, i.e., homo q group
self.head_sliding_step = -head_sliding_step
else:
self.head_sliding_step = get_head_sliding_step(
total_heads, self.vert_stride)
self.active_head_range = (
tp_rank * self.num_heads,
(tp_rank + 1) * self.num_heads,
)
class BlocksparseFlashAttentionBackend(AttentionBackend):
@staticmethod
def get_impl_cls() -> Type["BlocksparseFlashAttentionImpl"]:
return BlocksparseFlashAttentionImpl
@staticmethod
def make_metadata(*args, **kwargs) -> "BlocksparseFlashAttentionMetadata":
return BlocksparseFlashAttentionMetadata(*args, **kwargs)
@staticmethod
def get_kv_cache_shape(
num_blocks: int,
block_size: int,
num_kv_heads: int,
head_size: int,
) -> Tuple[int, ...]:
return PagedAttention.get_kv_cache_shape(num_blocks, block_size,
num_kv_heads, head_size)
@staticmethod
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
) -> None:
PagedAttention.swap_blocks(src_kv_cache, dst_kv_cache, src_to_dst)
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
) -> None:
PagedAttention.copy_blocks(kv_caches, src_to_dists)
@dataclass
class BlocksparseFlashAttentionMetadata(AttentionMetadata):
"""A copy of Metadata for FlashAttentionBackend,
to avoid having to install flash_attn.
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.
"""
# (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]]
# seq_lens stored as a tensor.
seq_lens_tensor: Optional[torch.Tensor]
# NOTE(sang): Definition of context_len, query_len, and seq_len.
# |---------- N-1 iteration --------|
# |---------------- N iteration ---------------------|
# |- tokenA -|......................|-- newTokens ---|
# |---------- context_len ----------|
# |-------------------- seq_len ----------------------|
# |-- query_len ---|
# Maximum query length in the batch. None for decoding.
max_query_len: Optional[int]
# 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 + 1,). The cumulative subquery lengths of the sequences in
# the batch, used to index into subquery. E.g., if the subquery length
# is [4, 6], it is [0, 4, 10].
query_start_loc: Optional[torch.Tensor]
# (batch_size + 1,). The cumulative sequence lengths of the sequences in
# the batch, used to index into sequence. E.g., if the sequence length is
# [4, 6], it is [0, 4, 10].
seq_start_loc: Optional[torch.Tensor]
# (batch_size,) A tensor of context lengths (tokens that are computed
# so far).
context_lens_tensor: Optional[torch.Tensor]
# (batch_size, max_blocks_per_seq).
# Block addresses per sequence. (Seq id -> list of physical block)
# E.g., [0, 1, 2] means tokens are stored in 0th, 1st, and 2nd blocks
# in the kv cache. Each block can contain up to block_size tokens.
# 2nd dimensions are padded up to max_blocks_per_seq if it is cuda-graph
# captured.
block_tables: Optional[torch.Tensor]
# Whether or not if cuda graph is enabled.
# Cuda-graph is currently enabled for decoding only.
# TODO(woosuk): Move `use_cuda_graph` out since it's unrelated to attention.
use_cuda_graph: bool
_cached_prefill_metadata: Optional[
"BlocksparseFlashAttentionMetadata"] = None
_cached_decode_metadata: Optional[
"BlocksparseFlashAttentionMetadata"] = None
@property
def prefill_metadata(
self) -> Optional["BlocksparseFlashAttentionMetadata"]:
if self.num_prefills == 0:
return None
if self._cached_prefill_metadata is not None:
return self._cached_prefill_metadata
assert self.seq_lens is not None
assert self.seq_lens_tensor is not None
assert self.query_start_loc is not None
assert self.context_lens_tensor is not None
assert self.block_tables is not None
assert self.seq_start_loc is not None
self._cached_prefill_metadata = BlocksparseFlashAttentionMetadata(
num_prefills=self.num_prefills,
num_prefill_tokens=self.num_prefill_tokens,
num_decode_tokens=0,
slot_mapping=self.slot_mapping[:self.num_prefill_tokens],
seq_lens=self.seq_lens[:self.num_prefills],
seq_lens_tensor=self.seq_lens_tensor[:self.num_prefills],
max_query_len=self.max_query_len,
max_prefill_seq_len=self.max_prefill_seq_len,
max_decode_seq_len=0,
query_start_loc=self.query_start_loc[:self.num_prefills + 1],
seq_start_loc=self.seq_start_loc[:self.num_prefills + 1],
context_lens_tensor=self.context_lens_tensor[:self.num_prefills],
block_tables=self.block_tables[:self.num_prefills],
use_cuda_graph=False,
)
return self._cached_prefill_metadata
@property
def decode_metadata(self) -> Optional["BlocksparseFlashAttentionMetadata"]:
if self.num_decode_tokens == 0:
return None
if self._cached_decode_metadata is not None:
return self._cached_decode_metadata
assert self.block_tables is not None
assert self.seq_lens_tensor is not None
self._cached_decode_metadata = BlocksparseFlashAttentionMetadata(
num_prefills=0,
num_prefill_tokens=0,
num_decode_tokens=self.num_decode_tokens,
slot_mapping=self.slot_mapping[self.num_prefill_tokens:],
seq_lens=None,
seq_lens_tensor=self.seq_lens_tensor[self.num_prefills:],
max_query_len=None,
max_prefill_seq_len=0,
max_decode_seq_len=self.max_decode_seq_len,
query_start_loc=None,
seq_start_loc=None,
context_lens_tensor=None,
block_tables=self.block_tables[self.num_prefills:],
use_cuda_graph=self.use_cuda_graph,
)
return self._cached_decode_metadata
class BlocksparseFlashAttentionImpl(AttentionImpl):
"""
If the input tensors contain prompt tokens, the layout is as follows:
|<--------------- num_prompt_tokens -------------->|
|<--prompt_0-->|<--prompt_1-->|...|<--prompt_N-1-->|
Otherwise, the layout is as follows:
|<------------------ num_generation_tokens (M) ----------------->|
|<--generation_0-->|..........|<--generation_M-1-->|<--padding-->|
Generation tokens can contain padding when cuda-graph is used.
Currently, prompt tokens don't contain any padding.
The prompts might have different lengths, while the generation tokens
always have length 1.
"""
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,
) -> None:
assert blocksparse_params is not None
assert alibi_slopes is None, ValueError(
"Alibi not support for blocksparse flash attention.")
assert sliding_window is None, ValueError(
"sliding_window is invalid for blocksparse attention.")
if "num_heads" not in blocksparse_params:
blocksparse_params["num_heads"] = num_heads
if "num_kv_heads" not in blocksparse_params:
blocksparse_params["num_kv_heads"] = num_kv_heads or num_heads
self.blocksparse_params = BlocksparseParams(**blocksparse_params)
self.kv_cache_dtype = kv_cache_dtype
self.num_heads = num_heads
self.head_size = head_size
self.scale = float(scale)
self.alibi_slopes = alibi_slopes
self.num_kv_heads = num_heads if num_kv_heads is None else num_kv_heads
assert self.num_heads % self.num_kv_heads == 0
self.num_queries_per_kv = self.num_heads // self.num_kv_heads
self.local_blocks = self.blocksparse_params.local_blocks
self.vert_stride = self.blocksparse_params.vert_stride
self.sparse_block_size = self.blocksparse_params.block_size
self.head_sliding_step = self.blocksparse_params.head_sliding_step
suppored_head_sizes = PagedAttention.get_supported_head_sizes()
if head_size not in suppored_head_sizes:
raise ValueError(
f"Head size {head_size} is not supported by PagedAttention. "
f"Supported head sizes are: {suppored_head_sizes}.")
self.tp_size = get_tensor_model_parallel_world_size()
self.tp_rank = get_tensor_model_parallel_rank()
total_num_heads = num_heads * self.tp_size
self.bs_attn = LocalStridedBlockSparseAttn(
total_num_heads,
self.blocksparse_params.max_seqlen,
self.blocksparse_params.local_blocks,
self.blocksparse_params.vert_stride,
self.blocksparse_params.block_size,
homo_head=self.blocksparse_params.homo_head,
active_head_range=self.blocksparse_params.active_head_range,
)
def forward(
self,
query: torch.Tensor,
key: torch.Tensor,
value: torch.Tensor,
kv_cache: torch.Tensor,
attn_metadata: BlocksparseFlashAttentionMetadata,
kv_scale: float = 1.0,
) -> torch.Tensor:
"""Forward pass with FlashAttention and PagedAttention.
Args:
query: shape = [num_tokens, num_heads * head_size]
key: shape = [num_tokens, num_kv_heads * head_size]
value: shape = [num_tokens, num_kv_heads * head_size]
kv_cache = [2, num_blocks, block_size * num_kv_heads * head_size]
attn_metadata: Metadata for attention.
Returns:
shape = [num_tokens, num_heads * head_size]
"""
num_tokens, hidden_size = query.shape
# Reshape the query, key, and value tensors.
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)
if kv_cache is not None:
key_cache, value_cache = PagedAttention.split_kv_cache(
kv_cache, self.num_kv_heads, self.head_size)
# Reshape the input keys and values and store them in the cache.
# If kv_cache is not provided, the new key and value tensors are
# not cached. This happens during the initial memory profiling run.
PagedAttention.write_to_paged_cache(
key,
value,
key_cache,
value_cache,
attn_metadata.slot_mapping,
self.kv_cache_dtype,
kv_scale,
)
if prefill_meta := attn_metadata.prefill_metadata:
# Prompt run.
# normal attention
# When block_tables are not filled, it means q and k are the
# prompt, and they have the same length.
assert kv_cache is None \
or prefill_meta.block_tables is None \
or prefill_meta.block_tables.numel() == 0, \
"Does not support prefix-enabled attention."
output = self.bs_attn(
q=query,
k=key,
v=value,
cu_seqlens_q=prefill_meta.seq_start_loc,
cu_seqlens_k=prefill_meta.seq_start_loc,
sm_scale=self.scale,
)
if decode_meta := attn_metadata.decode_metadata:
# Decoding run.
output = PagedAttention.forward_decode(
query,
key_cache,
value_cache,
decode_meta.block_tables,
decode_meta.seq_lens_tensor,
self.blocksparse_params.max_seqlen,
self.kv_cache_dtype,
self.num_kv_heads,
self.scale,
self.alibi_slopes,
kv_scale,
tp_rank=self.tp_rank,
blocksparse_local_blocks=self.local_blocks,
blocksparse_vert_stride=self.vert_stride,
blocksparse_block_size=self.sparse_block_size,
blocksparse_head_sliding_step=self.head_sliding_step,
)
# Reshape the output tensor.
return output.view(num_tokens, hidden_size)
vllm/attention/backends/flash_attn.py
View file @ b9e12416
"""Attention layer with Flash and PagedAttention.
NOTE(woosuk): At the moment, this file includes a lot of duplicated code from
XFormers backend. The duplicated code will be removed once we use flash-attn or
flashinfer for all the attention operations.
"""
"""Attention layer with FlashAttention."""
from dataclasses import dataclass
from typing import Dict, List, Optional, Tuple, Type
from typing import Any, Dict, List, Optional, Tuple, Type
import torch
from flash_attn import flash_attn_varlen_func
from vllm_flash_attn import flash_attn_varlen_func, flash_attn_with_kvcache
from vllm._C import cache_ops
from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl,
AttentionMetadata,
AttentionMetadataPerStage)
from vllm.attention.ops.paged_attn import (PagedAttention,
PagedAttentionMetadata)
AttentionMetadata)
class FlashAttentionBackend(AttentionBackend):
@staticmethod
def get_supported_head_sizes() -> List[int]:
return [32, 64, 96, 128, 160, 192, 224, 256]
@staticmethod
def get_name() -> str:
return "flash-attn"
@staticmethod
def get_impl_cls() -> Type["FlashAttentionImpl"]:
return FlashAttentionImpl
......@@ -34,28 +35,36 @@ class FlashAttentionBackend(AttentionBackend):
num_kv_heads: int,
head_size: int,
) -> Tuple[int, ...]:
return PagedAttention.get_kv_cache_shape(num_blocks, block_size,
num_kv_heads, head_size)
if block_size % 16 != 0:
raise ValueError("Block size must be a multiple of 16.")
return (2, num_blocks, block_size, num_kv_heads, head_size)
@staticmethod
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
src_to_dst: torch.Tensor,
) -> None:
PagedAttention.swap_blocks(src_kv_cache, dst_kv_cache, src_to_dst)
src_key_cache = src_kv_cache[0]
dst_key_cache = dst_kv_cache[0]
cache_ops.swap_blocks(src_key_cache, dst_key_cache, src_to_dst)
src_value_cache = src_kv_cache[1]
dst_value_cache = dst_kv_cache[1]
cache_ops.swap_blocks(src_value_cache, dst_value_cache, src_to_dst)
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
PagedAttention.copy_blocks(kv_caches, src_to_dists)
key_caches = [kv_cache[0] for kv_cache in kv_caches]
value_caches = [kv_cache[1] for kv_cache in kv_caches]
cache_ops.copy_blocks(key_caches, value_caches, src_to_dists)
@dataclass
class FlashAttentionMetadata(AttentionMetadataPerStage,
PagedAttentionMetadata):
class FlashAttentionMetadata(AttentionMetadata):
"""Metadata for FlashAttentionBackend.
NOTE: Any python object stored here is not updated when it is
......@@ -63,9 +72,6 @@ class FlashAttentionMetadata(AttentionMetadataPerStage,
dynamically, it should be stored in tensor. The tensor has to be
updated from `CUDAGraphRunner.forward` API.
"""
# Currently, input sequences can only contain all prompts
# or all decoding. True if all sequences are prompts.
is_prompt: bool
# (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]]
......@@ -80,14 +86,18 @@ class FlashAttentionMetadata(AttentionMetadataPerStage,
# |-------------------- seq_len ----------------------|
# |-- query_len ---|
# Maximum query length in the batch.
# Maximum query length in the batch. None for decoding.
max_query_len: Optional[int]
# Maximum sequence length in the batch.
max_seq_len: Optional[int]
# 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 + 1,). The cumulative subquery lengths of the sequences in
# the batch, used to index into subquery. E.g., if the subquery length
# is [4, 6], it is [0, 4, 10].
subquery_start_loc: Optional[torch.Tensor]
query_start_loc: Optional[torch.Tensor]
# (batch_size + 1,). The cumulative sequence lengths of the sequences in
# the batch, used to index into sequence. E.g., if the sequence length is
# [4, 6], it is [0, 4, 10].
......@@ -96,11 +106,83 @@ class FlashAttentionMetadata(AttentionMetadataPerStage,
# so far).
context_lens_tensor: Optional[torch.Tensor]
# (batch_size, max_blocks_per_seq).
# Block addresses per sequence. (Seq id -> list of physical block)
# E.g., [0, 1, 2] means tokens are stored in 0th, 1st, and 2nd blocks
# in the kv cache. Each block can contain up to block_size tokens.
# 2nd dimensions are padded up to max_blocks_per_seq if it is cuda-graph
# captured.
block_tables: Optional[torch.Tensor]
# Whether or not if cuda graph is enabled.
# Cuda-graph is currently enabled for decoding only.
# TODO(woosuk): Move `use_cuda_graph` out since it's unrelated to attention.
use_cuda_graph: bool
_cached_prefill_metadata: Optional["FlashAttentionMetadata"] = None
_cached_decode_metadata: Optional["FlashAttentionMetadata"] = None
@property
def prefill_metadata(self) -> Optional["FlashAttentionMetadata"]:
if self.num_prefills == 0:
return None
if self._cached_prefill_metadata is not None:
return self._cached_prefill_metadata
assert self.seq_lens is not None
assert self.seq_lens_tensor is not None
assert self.query_start_loc is not None
assert self.context_lens_tensor is not None
assert self.block_tables is not None
assert self.seq_start_loc is not None
self._cached_prefill_metadata = FlashAttentionMetadata(
num_prefills=self.num_prefills,
num_prefill_tokens=self.num_prefill_tokens,
num_decode_tokens=0,
slot_mapping=self.slot_mapping[:self.num_prefill_tokens],
seq_lens=self.seq_lens[:self.num_prefills],
seq_lens_tensor=self.seq_lens_tensor[:self.num_prefills],
max_query_len=self.max_query_len,
max_prefill_seq_len=self.max_prefill_seq_len,
max_decode_seq_len=0,
query_start_loc=self.query_start_loc[:self.num_prefills + 1],
seq_start_loc=self.seq_start_loc[:self.num_prefills + 1],
context_lens_tensor=self.context_lens_tensor[:self.num_prefills],
block_tables=self.block_tables[:self.num_prefills],
use_cuda_graph=False,
)
return self._cached_prefill_metadata
@property
def decode_metadata(self) -> Optional["FlashAttentionMetadata"]:
if self.num_decode_tokens == 0:
return None
if self._cached_decode_metadata is not None:
return self._cached_decode_metadata
assert self.block_tables is not None
assert self.seq_lens_tensor is not None
self._cached_decode_metadata = FlashAttentionMetadata(
num_prefills=0,
num_prefill_tokens=0,
num_decode_tokens=self.num_decode_tokens,
slot_mapping=self.slot_mapping[self.num_prefill_tokens:],
seq_lens=None,
seq_lens_tensor=self.seq_lens_tensor[self.num_prefills:],
max_query_len=None,
max_prefill_seq_len=0,
max_decode_seq_len=self.max_decode_seq_len,
query_start_loc=None,
seq_start_loc=None,
context_lens_tensor=None,
block_tables=self.block_tables[self.num_prefills:],
use_cuda_graph=self.use_cuda_graph,
)
return self._cached_decode_metadata
class FlashAttentionImpl(AttentionImpl):
"""
......@@ -133,28 +215,39 @@ class FlashAttentionImpl(AttentionImpl):
num_heads: int,
head_size: int,
scale: float,
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
num_kv_heads: int,
alibi_slopes: Optional[List[float]],
sliding_window: Optional[int],
kv_cache_dtype: str,
blocksparse_params: Optional[Dict[str, Any]] = None,
) -> None:
assert blocksparse_params is None, ValueError(
"FlashAttention does not support block-sparse attention.")
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.sliding_window = ((sliding_window, sliding_window)
if sliding_window is not None else (-1, -1))
self.num_kv_heads = num_kv_heads
if alibi_slopes is not None:
alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32)
self.alibi_slopes = alibi_slopes
self.sliding_window = ((sliding_window, sliding_window)
if sliding_window is not None else (-1, -1))
self.kv_cache_dtype = kv_cache_dtype
assert self.num_heads % self.num_kv_heads == 0
self.num_queries_per_kv = self.num_heads // self.num_kv_heads
suppored_head_sizes = PagedAttention.get_supported_head_sizes()
if head_size not in suppored_head_sizes:
if sliding_window is not None:
# NOTE(woosuk): flash-attn's sliding window does not work with
# paged KV cache.
raise ValueError(
f"Head size {head_size} is not supported by PagedAttention. "
f"Supported head sizes are: {suppored_head_sizes}.")
"Sliding window is not supported in FlashAttention.")
support_head_sizes = FlashAttentionBackend.get_supported_head_sizes()
if head_size not in support_head_sizes:
raise ValueError(
f"Head size {head_size} is not supported by FlashAttention. "
f"Supported head sizes are: {support_head_sizes}.")
def forward(
self,
......@@ -162,20 +255,23 @@ class FlashAttentionImpl(AttentionImpl):
key: torch.Tensor,
value: torch.Tensor,
kv_cache: torch.Tensor,
attn_metadata: AttentionMetadata[FlashAttentionMetadata],
kv_scale: float,
attn_metadata: FlashAttentionMetadata,
kv_scale: float = 1.0,
) -> torch.Tensor:
"""Forward pass with FlashAttention and PagedAttention.
"""Forward pass with FlashAttention.
Args:
query: shape = [num_tokens, num_heads * head_size]
key: shape = [num_tokens, num_kv_heads * head_size]
value: shape = [num_tokens, num_kv_heads * head_size]
kv_cache = [2, num_blocks, block_size * num_kv_heads * head_size]
kv_cache = [2, num_blocks, block_size, num_kv_heads, head_size]
attn_metadata: Metadata for attention.
Returns:
shape = [num_tokens, num_heads * head_size]
"""
# NOTE(woosuk): FlashAttention does not support FP8 KV cache.
assert kv_scale == 1.0, "kv_scale is not supported in FlashAttention."
num_tokens, hidden_size = query.shape
# Reshape the query, key, and value tensors.
query = query.view(-1, self.num_heads, self.head_size)
......@@ -183,17 +279,20 @@ class FlashAttentionImpl(AttentionImpl):
value = value.view(-1, self.num_kv_heads, self.head_size)
if kv_cache is not None:
key_cache, value_cache = PagedAttention.split_kv_cache(
kv_cache, self.num_kv_heads, self.head_size)
key_cache = kv_cache[0]
value_cache = kv_cache[1]
# Reshape the input keys and values and store them in the cache.
# If kv_cache is not provided, the new key and value tensors are
# not cached. This happens during the initial memory profiling run.
PagedAttention.write_to_paged_cache(key, value, key_cache,
value_cache,
attn_metadata.slot_mapping,
attn_metadata.kv_cache_dtype,
kv_scale)
cache_ops.reshape_and_cache_flash(
key,
value,
key_cache,
value_cache,
attn_metadata.slot_mapping.flatten(),
self.kv_cache_dtype,
)
num_prefill_tokens = attn_metadata.num_prefill_tokens
num_decode_tokens = attn_metadata.num_decode_tokens
......@@ -213,7 +312,8 @@ class FlashAttentionImpl(AttentionImpl):
if prefill_meta := attn_metadata.prefill_metadata:
# Prompt run.
if kv_cache is None or prefill_meta.block_tables.numel() == 0:
if (kv_cache is None or prefill_meta.block_tables is None
or prefill_meta.block_tables.numel() == 0):
# normal attention
# When block_tables are not filled, it means q and k are the
# prompt, and they have the same length.
......@@ -223,8 +323,8 @@ class FlashAttentionImpl(AttentionImpl):
v=value,
cu_seqlens_q=prefill_meta.seq_start_loc,
cu_seqlens_k=prefill_meta.seq_start_loc,
max_seqlen_q=prefill_meta.max_seq_len,
max_seqlen_k=prefill_meta.max_seq_len,
max_seqlen_q=prefill_meta.max_prefill_seq_len,
max_seqlen_k=prefill_meta.max_prefill_seq_len,
softmax_scale=self.scale,
causal=True,
window_size=self.sliding_window,
......@@ -234,38 +334,34 @@ class FlashAttentionImpl(AttentionImpl):
output[:num_prefill_tokens] = out
else:
# prefix-enabled attention
# TODO(Hai) this triton kernel has regression issue (broke) to
# deal with different data types between KV and FP8 KV cache,
# to be addressed separately.
output[:num_prefill_tokens] = PagedAttention.forward_prefix(
query,
key,
value,
key_cache,
value_cache,
prefill_meta.block_tables,
prefill_meta.subquery_start_loc,
prefill_meta.seq_lens_tensor,
prefill_meta.context_lens_tensor,
prefill_meta.max_query_len,
self.alibi_slopes,
self.sliding_window[0],
assert prefill_meta.seq_lens is not None
max_seq_len = max(prefill_meta.seq_lens)
output[:num_prefill_tokens] = flash_attn_varlen_func(
q=query,
k=key_cache,
v=value_cache,
cu_seqlens_q=prefill_meta.query_start_loc,
max_seqlen_q=prefill_meta.max_query_len,
cu_seqlens_k=prefill_meta.seq_start_loc,
max_seqlen_k=max_seq_len,
softmax_scale=self.scale,
causal=True,
alibi_slopes=self.alibi_slopes,
block_table=prefill_meta.block_tables,
)
if decode_meta := attn_metadata.decode_metadata:
# Decoding run.
output[num_prefill_tokens:] = PagedAttention.forward_decode(
decode_query,
output[num_prefill_tokens:] = flash_attn_with_kvcache(
decode_query.unsqueeze(1),
key_cache,
value_cache,
decode_meta.block_tables,
decode_meta.seq_lens_tensor,
decode_meta.max_seq_len,
attn_metadata.kv_cache_dtype,
self.num_kv_heads,
self.scale,
self.alibi_slopes,
kv_scale,
)
block_table=decode_meta.block_tables,
cache_seqlens=decode_meta.seq_lens_tensor,
softmax_scale=self.scale,
causal=True,
alibi_slopes=self.alibi_slopes,
).squeeze(1)
# Reshape the output tensor.
return output.view(num_tokens, hidden_size)
vllm/attention/backends/flashinfer.py
View file @ b9e12416
from dataclasses import dataclass
from typing import Any, Dict, List, Optional, Set, Tuple, Type
try:
import flashinfer
from flash_attn import flash_attn_varlen_func
from flashinfer import BatchDecodeWithPagedKVCacheWrapper
except ImportError:
flashinfer = None
flash_attn_varlen_func = None
BatchDecodeWithPagedKVCacheWrapper = None
import flashinfer
import torch
from flashinfer import BatchDecodeWithPagedKVCacheWrapper
from vllm_flash_attn import flash_attn_varlen_func
from vllm import _custom_ops as ops
from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl,
AttentionMetadata,
AttentionMetadataPerStage)
AttentionMetadata)
class FlashInferBackend(AttentionBackend):
@staticmethod
def get_name() -> str:
return "flashinfer"
@staticmethod
def get_impl_cls() -> Type["FlashInferImpl"]:
return FlashInferImpl
......@@ -41,14 +38,14 @@ class FlashInferBackend(AttentionBackend):
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
src_to_dst: torch.Tensor,
) -> None:
raise NotImplementedError
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
raise NotImplementedError
......@@ -58,9 +55,10 @@ class FlashInferBackend(AttentionBackend):
@dataclass
class FlashInferMetadata(AttentionMetadataPerStage):
is_prompt: bool
class FlashInferMetadata(AttentionMetadata):
# Maximum sequence length among prefill batch. 0 if there are decoding
# requests only.
max_prefill_seq_len: int
use_cuda_graph: bool = False
......@@ -69,7 +67,6 @@ class FlashInferMetadata(AttentionMetadataPerStage):
# Metadata for the prefill stage since we still
# use flash attention for prefill.
seq_start_loc: Optional[torch.Tensor] = None
max_seq_len: Optional[int] = None
block_tables: Optional[torch.Tensor] = None
# Metadata for the decode stage
......@@ -115,7 +112,8 @@ class FlashInferMetadata(AttentionMetadataPerStage):
# When using flashinfer, we are also creating the FlashInferMetadata,
# which will also call post_init by default, here we want to skip the
# post_init if it's the prefill phase.
if not self.is_prompt:
if self.num_prefills == 0:
assert self.num_decode_tokens > 0
self.decode_wrapper = flashinfer.BatchDecodeWithPagedKVCacheWrapper(
self.workspace_buffer, "NHD")
self.decode_wrapper.begin_forward(
......@@ -140,6 +138,24 @@ class FlashInferMetadata(AttentionMetadataPerStage):
skip_fields.add('decode_wrapper')
return super().asdict_zerocopy(skip_fields)
@property
def prefill_metadata(self) -> Optional["FlashInferMetadata"]:
# Currently chunked prefill is not supported
if self.num_decode_tokens == 0:
assert self.num_prefills > 0
return self
return None
@property
def decode_metadata(self) -> Optional["FlashInferMetadata"]:
# Currently chunked prefill is not supported
if self.num_prefills > 0:
assert self.num_decode_tokens == 0
return None
return self
class FlashInferImpl(AttentionImpl):
......@@ -148,23 +164,36 @@ class FlashInferImpl(AttentionImpl):
num_heads: int,
head_size: int,
scale: float,
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
num_kv_heads: int,
alibi_slopes: Optional[List[float]],
sliding_window: Optional[int],
kv_cache_dtype: str,
) -> None:
self.num_heads = num_heads
self.head_size = head_size
self.scale = float(scale)
self.num_kv_heads = num_kv_heads
if alibi_slopes is not None:
alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32)
self.alibi_slopes = alibi_slopes
if sliding_window is not None:
raise ValueError("Sliding window is not supported in FlashInfer.")
self.sliding_window = (-1, -1)
self.alibi_slopes = alibi_slopes
self.scale = scale
self.num_heads = num_heads
self.head_size = head_size
self.num_kv_heads = num_heads if num_kv_heads is None else num_kv_heads
self.kv_cache_dtype = kv_cache_dtype
def forward(self, query: torch.Tensor, key: torch.Tensor,
value: torch.Tensor, kv_cache: Optional[torch.Tensor],
attn_metadata: AttentionMetadata[FlashInferMetadata],
kv_scale: float):
assert self.num_heads % self.num_kv_heads == 0
self.num_queries_per_kv = self.num_heads // self.num_kv_heads
def forward(
self,
query: torch.Tensor,
key: torch.Tensor,
value: torch.Tensor,
kv_cache: Optional[torch.Tensor],
attn_metadata: FlashInferMetadata,
kv_scale: float = 1.0,
) -> torch.Tensor:
assert kv_scale == 1.0
num_tokens, hidden_size = query.shape
query = query.view(-1, self.num_heads, self.head_size)
key = key.view(-1, self.num_kv_heads, self.head_size)
......@@ -185,10 +214,11 @@ class FlashInferImpl(AttentionImpl):
kv_cache[:, 0],
kv_cache[:, 1],
attn_metadata.slot_mapping.flatten(),
attn_metadata.kv_cache_dtype,
self.kv_cache_dtype,
)
if prefill_meta := attn_metadata.prefill_metadata:
# Prompt run.
assert prefill_meta.block_tables is not None
if kv_cache is None or prefill_meta.block_tables.numel() == 0:
output = flash_attn_varlen_func(
......@@ -197,8 +227,8 @@ class FlashInferImpl(AttentionImpl):
v=value,
cu_seqlens_q=prefill_meta.seq_start_loc,
cu_seqlens_k=prefill_meta.seq_start_loc,
max_seqlen_q=prefill_meta.max_seq_len,
max_seqlen_k=prefill_meta.max_seq_len,
max_seqlen_q=prefill_meta.max_prefill_seq_len,
max_seqlen_k=prefill_meta.max_prefill_seq_len,
softmax_scale=self.scale,
causal=True,
window_size=self.sliding_window,
......
vllm/attention/backends/rocm_flash_attn.py
View file @ b9e12416
"""Attention layer ROCm GPUs."""
from dataclasses import dataclass
from typing import Dict, List, Optional, Tuple, Type
from typing import Any, Dict, List, Optional, Tuple, Type
import torch
import vllm.envs as envs
from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl,
AttentionMetadata,
AttentionMetadataPerStage)
AttentionMetadata)
from vllm.attention.ops.paged_attn import (PagedAttention,
PagedAttentionMetadata)
from vllm.logger import init_logger
......@@ -17,6 +16,10 @@ logger = init_logger(__name__)
class ROCmFlashAttentionBackend(AttentionBackend):
@staticmethod
def get_name() -> str:
return "rocm-flash-attn"
@staticmethod
def get_impl_cls() -> Type["ROCmFlashAttentionImpl"]:
return ROCmFlashAttentionImpl
......@@ -39,21 +42,20 @@ class ROCmFlashAttentionBackend(AttentionBackend):
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
src_to_dst: torch.Tensor,
) -> None:
PagedAttention.swap_blocks(src_kv_cache, dst_kv_cache, src_to_dst)
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
PagedAttention.copy_blocks(kv_caches, src_to_dists)
@dataclass
class ROCmFlashAttentionMetadata(AttentionMetadataPerStage,
PagedAttentionMetadata):
class ROCmFlashAttentionMetadata(AttentionMetadata, PagedAttentionMetadata):
"""Metadata for FlashAttentionBackend.
NOTE: Any python object stored here is not updated when it is
......@@ -61,9 +63,6 @@ class ROCmFlashAttentionMetadata(AttentionMetadataPerStage,
dynamically, it should be stored in tensor. The tensor has to be
updated from `CUDAGraphRunner.forward` API.
"""
# Currently, input sequences can only contain all prompts
# or all decoding. True if all sequences are prompts.
is_prompt: bool
# (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]]
......@@ -78,14 +77,18 @@ class ROCmFlashAttentionMetadata(AttentionMetadataPerStage,
# |-------------------- seq_len ----------------------|
# |-- query_len ---|
# Maximum query length in the batch.
# Maximum query length in the batch. None for decoding.
max_query_len: Optional[int]
# Maximum sequence length in the batch.
max_seq_len: Optional[int]
# 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 + 1,). The cumulative subquery lengths of the sequences in
# the batch, used to index into subquery. E.g., if the subquery length
# is [4, 6], it is [0, 4, 10].
subquery_start_loc: Optional[torch.Tensor]
query_start_loc: Optional[torch.Tensor]
# (batch_size + 1,). The cumulative sequence lengths of the sequences in
# the batch, used to index into sequence. E.g., if the sequence length is
# [4, 6], it is [0, 4, 10].
......@@ -98,6 +101,69 @@ class ROCmFlashAttentionMetadata(AttentionMetadataPerStage,
# (batch_size,) A tensor of context lengths (tokens that are computed
# so far).
context_lens_tensor: Optional[torch.Tensor]
_cached_prefill_metadata: Optional["ROCmFlashAttentionMetadata"] = None
_cached_decode_metadata: Optional["ROCmFlashAttentionMetadata"] = None
@property
def prefill_metadata(self) -> Optional["ROCmFlashAttentionMetadata"]:
if self.num_prefills == 0:
return None
if self._cached_prefill_metadata is not None:
return self._cached_prefill_metadata
assert self.seq_lens is not None
assert self.seq_lens_tensor is not None
assert self.query_start_loc is not None
assert self.context_lens_tensor is not None
assert self.block_tables is not None
assert self.seq_start_loc is not None
self._cached_prefill_metadata = ROCmFlashAttentionMetadata(
num_prefills=self.num_prefills,
num_prefill_tokens=self.num_prefill_tokens,
num_decode_tokens=0,
slot_mapping=self.slot_mapping[:self.num_prefill_tokens],
seq_lens=self.seq_lens[:self.num_prefills],
seq_lens_tensor=self.seq_lens_tensor[:self.num_prefills],
max_query_len=self.max_query_len,
max_prefill_seq_len=self.max_prefill_seq_len,
max_decode_seq_len=0,
query_start_loc=self.query_start_loc[:self.num_prefills + 1],
seq_start_loc=self.seq_start_loc[:self.num_prefills + 1],
context_lens_tensor=self.context_lens_tensor[:self.num_prefills],
block_tables=self.block_tables[:self.num_prefills],
use_cuda_graph=False,
)
return self._cached_prefill_metadata
@property
def decode_metadata(self) -> Optional["ROCmFlashAttentionMetadata"]:
if self.num_decode_tokens == 0:
return None
if self._cached_decode_metadata is not None:
return self._cached_decode_metadata
assert self.block_tables is not None
assert self.seq_lens_tensor is not None
self._cached_decode_metadata = ROCmFlashAttentionMetadata(
num_prefills=0,
num_prefill_tokens=0,
num_decode_tokens=self.num_decode_tokens,
slot_mapping=self.slot_mapping[self.num_prefill_tokens:],
seq_lens=None,
seq_lens_tensor=self.seq_lens_tensor[self.num_prefills:],
max_query_len=None,
max_prefill_seq_len=0,
max_decode_seq_len=self.max_decode_seq_len,
query_start_loc=None,
seq_start_loc=None,
context_lens_tensor=None,
block_tables=self.block_tables[self.num_prefills:],
use_cuda_graph=self.use_cuda_graph,
)
return self._cached_decode_metadata
class ROCmFlashAttentionImpl(AttentionImpl):
......@@ -131,28 +197,33 @@ class ROCmFlashAttentionImpl(AttentionImpl):
num_heads: int,
head_size: int,
scale: float,
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
num_kv_heads: int,
alibi_slopes: Optional[List[float]],
sliding_window: Optional[int],
kv_cache_dtype: str,
blocksparse_params: Optional[Dict[str, Any]] = None,
) -> None:
assert blocksparse_params is None, ValueError(
"ROCFlashAttention does not support blocksparse attention.")
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.sliding_window = ((sliding_window, sliding_window)
if sliding_window is not None else (-1, -1))
self.num_kv_heads = num_kv_heads
if alibi_slopes is not None:
alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32)
self.alibi_slopes = alibi_slopes
self.sliding_window = ((sliding_window, sliding_window)
if sliding_window is not None else (-1, -1))
self.kv_cache_dtype = kv_cache_dtype
assert self.num_heads % self.num_kv_heads == 0
self.num_queries_per_kv = self.num_heads // self.num_kv_heads
suppored_head_sizes = PagedAttention.get_supported_head_sizes()
if head_size not in suppored_head_sizes:
supported_head_sizes = PagedAttention.get_supported_head_sizes()
if head_size not in supported_head_sizes:
raise ValueError(
f"Head size {head_size} is not supported by PagedAttention. "
f"Supported head sizes are: {suppored_head_sizes}.")
f"Supported head sizes are: {supported_head_sizes}.")
self.use_naive_attn = False
# NOTE: Allow for switching between Triton and CK. Defaulting to triton.
......@@ -163,8 +234,9 @@ class ROCmFlashAttentionImpl(AttentionImpl):
self.attn_func = triton_attention
logger.debug("Using Triton FA in ROCmBackend")
else:
# if not using triton, navi3x not use flash-attn either
if torch.cuda.get_device_capability()[0] == 11:
# if not using triton, navi3x/navi21/navi10 do not use flash-attn
# either
if torch.cuda.get_device_capability()[0] != 9:
self.use_naive_attn = True
else:
try:
......@@ -192,7 +264,7 @@ class ROCmFlashAttentionImpl(AttentionImpl):
key: torch.Tensor,
value: torch.Tensor,
kv_cache: torch.Tensor,
attn_metadata: AttentionMetadata[ROCmFlashAttentionMetadata],
attn_metadata: ROCmFlashAttentionMetadata,
kv_scale: float = 1.0,
) -> torch.Tensor:
"""Forward pass with FlashAttention and PagedAttention.
......@@ -225,7 +297,7 @@ class ROCmFlashAttentionImpl(AttentionImpl):
key_cache,
value_cache,
attn_metadata.slot_mapping,
attn_metadata.kv_cache_dtype,
self.kv_cache_dtype,
kv_scale,
)
......@@ -260,8 +332,8 @@ class ROCmFlashAttentionImpl(AttentionImpl):
None,
prefill_meta.seq_start_loc,
prefill_meta.seq_start_loc,
prefill_meta.max_seq_len,
prefill_meta.max_seq_len,
prefill_meta.max_prefill_seq_len,
prefill_meta.max_prefill_seq_len,
True,
self.scale,
)
......@@ -284,8 +356,8 @@ class ROCmFlashAttentionImpl(AttentionImpl):
v=value,
cu_seqlens_q=prefill_meta.seq_start_loc,
cu_seqlens_k=prefill_meta.seq_start_loc,
max_seqlen_q=prefill_meta.max_seq_len,
max_seqlen_k=prefill_meta.max_seq_len,
max_seqlen_q=prefill_meta.max_prefill_seq_len,
max_seqlen_k=prefill_meta.max_prefill_seq_len,
softmax_scale=self.scale,
causal=True,
)
......@@ -302,7 +374,7 @@ class ROCmFlashAttentionImpl(AttentionImpl):
key_cache,
value_cache,
prefill_meta.block_tables,
prefill_meta.subquery_start_loc,
prefill_meta.query_start_loc,
prefill_meta.seq_lens_tensor,
prefill_meta.context_lens_tensor,
prefill_meta.max_query_len,
......@@ -318,8 +390,8 @@ class ROCmFlashAttentionImpl(AttentionImpl):
value_cache,
decode_meta.block_tables,
decode_meta.seq_lens_tensor,
decode_meta.max_seq_len,
attn_metadata.kv_cache_dtype,
decode_meta.max_decode_seq_len,
self.kv_cache_dtype,
self.num_kv_heads,
self.scale,
self.alibi_slopes,
......
vllm/attention/backends/torch_sdpa.py
View file @ b9e12416
""" Attention layer with torch scaled_dot_product_attention
and PagedAttention."""
from dataclasses import dataclass
from typing import Dict, List, Optional, Tuple, Type
from typing import Any, Dict, List, Optional, Tuple, Type
import torch
from torch.nn.functional import scaled_dot_product_attention
from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl,
AttentionMetadata,
AttentionMetadataPerStage)
AttentionMetadata)
from vllm.attention.ops.paged_attn import (PagedAttention,
PagedAttentionMetadata)
class TorchSDPABackend(AttentionBackend):
@staticmethod
def get_name() -> str:
return "torch-sdpa"
@staticmethod
def get_impl_cls() -> Type["TorchSDPABackendImpl"]:
return TorchSDPABackendImpl
......@@ -37,21 +40,20 @@ class TorchSDPABackend(AttentionBackend):
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
src_to_dst: torch.Tensor,
) -> None:
PagedAttention.swap_blocks(src_kv_cache, dst_kv_cache, src_to_dst)
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
PagedAttention.copy_blocks(kv_caches, src_to_dists)
@dataclass
class TorchSDPAMetadata(AttentionMetadata, PagedAttentionMetadata,
AttentionMetadataPerStage):
class TorchSDPAMetadata(AttentionMetadata, PagedAttentionMetadata):
"""Metadata for TorchSDPABackend.
"""
# Currently, input sequences can only contain all prompts
......@@ -68,37 +70,64 @@ class TorchSDPAMetadata(AttentionMetadata, PagedAttentionMetadata,
# will not appear in the __repr__ and __init__
self.attn_bias: Optional[List[torch.Tensor]] = None
@property
def prefill_metadata(self) -> Optional["TorchSDPAMetadata"]:
# Currently chunked prefill is not supported
if self.num_decode_tokens == 0:
assert self.num_prefills > 0
return self
return None
@property
def decode_metadata(self) -> Optional["TorchSDPAMetadata"]:
# Currently chunked prefill is not supported
if self.num_prefills > 0:
assert self.num_decode_tokens == 0
return None
class TorchSDPABackendImpl(AttentionImpl):
return self
class TorchSDPABackendImpl(AttentionImpl[TorchSDPAMetadata]):
def __init__(
self,
num_heads: int,
head_size: int,
scale: float,
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
num_kv_heads: int,
alibi_slopes: Optional[List[float]],
sliding_window: Optional[int],
kv_cache_dtype: str,
blocksparse_params: Optional[Dict[str, Any]] = None,
) -> None:
assert blocksparse_params is None, ValueError(
"Torch SPDA does not support block-sparse attention.")
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.sliding_window = sliding_window
self.num_kv_heads = num_kv_heads
if alibi_slopes is not None:
assert len(alibi_slopes) == num_heads
alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32)
self.alibi_slopes = alibi_slopes
self.need_mask = (self.alibi_slopes is not None
or self.sliding_window is not None)
self.sliding_window = sliding_window
self.kv_cache_dtype = kv_cache_dtype
assert self.num_heads % self.num_kv_heads == 0
self.num_queries_per_kv = self.num_heads // self.num_kv_heads
suppored_head_sizes = PagedAttention.get_supported_head_sizes()
if head_size not in suppored_head_sizes:
self.need_mask = (self.alibi_slopes is not None
or self.sliding_window is not None)
supported_head_sizes = PagedAttention.get_supported_head_sizes()
if head_size not in supported_head_sizes:
raise ValueError(
f"Head size {head_size} is not supported by PagedAttention. "
f"Supported head sizes are: {suppored_head_sizes}.")
f"Supported head sizes are: {supported_head_sizes}.")
if kv_cache_dtype != "auto":
raise NotImplementedError(
"Torch SDPA backend does not support FP8 KV cache. "
"Please use xFormers backend instead.")
def forward(
self,
......@@ -107,7 +136,7 @@ class TorchSDPABackendImpl(AttentionImpl):
value: torch.Tensor,
kv_cache: Optional[torch.Tensor],
attn_metadata: TorchSDPAMetadata, # type: ignore
kv_scale: float,
kv_scale: float = 1.0,
) -> torch.Tensor:
"""Forward pass with torch SDPA and PagedAttention.
......@@ -120,6 +149,7 @@ class TorchSDPABackendImpl(AttentionImpl):
Returns:
shape = [num_tokens, num_heads * head_size]
"""
assert kv_scale == 1.0
num_tokens, hidden_size = query.shape
# Reshape the query, key, and value tensors.
query = query.view(-1, self.num_heads, self.head_size)
......@@ -132,8 +162,7 @@ class TorchSDPABackendImpl(AttentionImpl):
PagedAttention.write_to_paged_cache(key, value, key_cache,
value_cache,
attn_metadata.slot_mapping,
attn_metadata.kv_cache_dtype,
kv_scale)
self.kv_cache_dtype, kv_scale)
if attn_metadata.is_prompt:
assert attn_metadata.seq_lens is not None
......@@ -190,8 +219,8 @@ class TorchSDPABackendImpl(AttentionImpl):
value_cache,
attn_metadata.block_tables,
attn_metadata.seq_lens_tensor,
attn_metadata.max_seq_len,
attn_metadata.kv_cache_dtype,
attn_metadata.max_decode_seq_len,
self.kv_cache_dtype,
self.num_kv_heads,
self.scale,
self.alibi_slopes,
......
vllm/attention/backends/xformers.py
View file @ b9e12416
"""Attention layer with xFormers and PagedAttention."""
from dataclasses import dataclass
from typing import Dict, List, Optional, Tuple, Type
from typing import Any, Dict, List, Optional, Tuple, Type
import torch
from xformers import ops as xops
......@@ -9,8 +9,7 @@ from xformers.ops.fmha.attn_bias import (AttentionBias,
LowerTriangularMaskWithTensorBias)
from vllm.attention.backends.abstract import (AttentionBackend, AttentionImpl,
AttentionMetadata,
AttentionMetadataPerStage)
AttentionMetadata)
from vllm.attention.ops.paged_attn import (PagedAttention,
PagedAttentionMetadata)
from vllm.logger import init_logger
......@@ -20,6 +19,10 @@ logger = init_logger(__name__)
class XFormersBackend(AttentionBackend):
@staticmethod
def get_name() -> str:
return "xformers"
@staticmethod
def get_impl_cls() -> Type["XFormersImpl"]:
return XFormersImpl
......@@ -49,13 +52,13 @@ class XFormersBackend(AttentionBackend):
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
PagedAttention.copy_blocks(kv_caches, src_to_dists)
@dataclass
class XFormersMetadata(AttentionMetadataPerStage, PagedAttentionMetadata):
class XFormersMetadata(AttentionMetadata, PagedAttentionMetadata):
"""Metadata for XFormersbackend.
NOTE: Any python object stored here is not updated when it is
......@@ -63,9 +66,6 @@ class XFormersMetadata(AttentionMetadataPerStage, PagedAttentionMetadata):
dynamically, it should be stored in tensor. The tensor has to be
updated from `CUDAGraphRunner.forward` API.
"""
# Currently, input sequences can only contain all prompts
# or all decoding. True if all sequences are prompts.
is_prompt: bool
# (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]]
......@@ -79,15 +79,19 @@ class XFormersMetadata(AttentionMetadataPerStage, PagedAttentionMetadata):
# |-------------------- seq_len ----------------------|
# |-- query_len ---|
# Maximum query length in the batch.
# Maximum query length in the batch. None for decoding.
max_query_len: Optional[int]
# FIXME: It is for flash attn.
# Maximum sequence length in the batch.
max_seq_len: Optional[int]
# 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 + 1,). The cumulative subquery lengths of the sequences in
# the batch, used to index into subquery. E.g., if the subquery length
# is [4, 6], it is [0, 4, 10].
subquery_start_loc: Optional[torch.Tensor]
query_start_loc: Optional[torch.Tensor]
# FIXME: It is for flash attn.
# (batch_size + 1,). The cumulative sequence lengths of the sequences in
# the batch, used to index into sequence. E.g., if the sequence length is
......@@ -101,6 +105,8 @@ class XFormersMetadata(AttentionMetadataPerStage, PagedAttentionMetadata):
# Cuda-graph is currently enabled for decoding only.
# TODO(woosuk): Move `use_cuda_graph` out since it's unrelated to attention.
use_cuda_graph: bool
_cached_prefill_metadata: Optional["XFormersMetadata"] = None
_cached_decode_metadata: Optional["XFormersMetadata"] = None
def __post_init__(self):
# Set during the execution of the first attention op.
......@@ -110,8 +116,68 @@ class XFormersMetadata(AttentionMetadataPerStage, PagedAttentionMetadata):
# will not appear in the __repr__ and __init__
self.attn_bias: Optional[List[AttentionBias]] = None
class XFormersImpl(AttentionImpl):
@property
def prefill_metadata(self) -> Optional["XFormersMetadata"]:
if self.num_prefills == 0:
return None
if self._cached_prefill_metadata is not None:
return self._cached_prefill_metadata
assert self.seq_lens is not None
assert self.seq_lens_tensor is not None
assert self.query_start_loc is not None
assert self.context_lens_tensor is not None
assert self.block_tables is not None
self._cached_prefill_metadata = XFormersMetadata(
num_prefills=self.num_prefills,
num_prefill_tokens=self.num_prefill_tokens,
num_decode_tokens=0,
slot_mapping=self.slot_mapping[:self.num_prefill_tokens],
seq_lens=self.seq_lens[:self.num_prefills],
seq_lens_tensor=self.seq_lens_tensor[:self.num_prefills],
max_query_len=self.max_query_len,
max_prefill_seq_len=self.max_prefill_seq_len,
max_decode_seq_len=0,
query_start_loc=self.query_start_loc[:self.num_prefills + 1],
seq_start_loc=None,
context_lens_tensor=self.context_lens_tensor[:self.num_prefills],
block_tables=self.block_tables[:self.num_prefills],
use_cuda_graph=False,
)
return self._cached_prefill_metadata
@property
def decode_metadata(self) -> Optional["XFormersMetadata"]:
if self.num_decode_tokens == 0:
return None
if self._cached_decode_metadata is not None:
return self._cached_decode_metadata
assert self.block_tables is not None
assert self.seq_lens_tensor is not None
self._cached_decode_metadata = XFormersMetadata(
num_prefills=0,
num_prefill_tokens=0,
num_decode_tokens=self.num_decode_tokens,
slot_mapping=self.slot_mapping[self.num_prefill_tokens:],
seq_lens=None,
seq_lens_tensor=self.seq_lens_tensor[self.num_prefills:],
max_query_len=None,
max_prefill_seq_len=0,
max_decode_seq_len=self.max_decode_seq_len,
query_start_loc=None,
seq_start_loc=None,
context_lens_tensor=None,
block_tables=self.block_tables[self.num_prefills:],
use_cuda_graph=self.use_cuda_graph,
)
return self._cached_decode_metadata
class XFormersImpl(AttentionImpl[XFormersMetadata]):
"""
If the input tensors contain prompt tokens, the layout is as follows:
|<--------------- num_prefill_tokens ----------------->|
......@@ -142,18 +208,23 @@ class XFormersImpl(AttentionImpl):
num_heads: int,
head_size: int,
scale: float,
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
num_kv_heads: int,
alibi_slopes: Optional[List[float]],
sliding_window: Optional[int],
kv_cache_dtype: str,
blocksparse_params: Optional[Dict[str, Any]] = None,
) -> None:
assert blocksparse_params is None, ValueError(
"XFormer does not support block-sparse attention.")
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.sliding_window = sliding_window
self.num_kv_heads = num_kv_heads
if alibi_slopes is not None:
alibi_slopes = torch.tensor(alibi_slopes, dtype=torch.float32)
self.alibi_slopes = alibi_slopes
self.sliding_window = sliding_window
self.kv_cache_dtype = kv_cache_dtype
assert self.num_heads % self.num_kv_heads == 0
self.num_queries_per_kv = self.num_heads // self.num_kv_heads
......@@ -170,8 +241,8 @@ class XFormersImpl(AttentionImpl):
key: torch.Tensor,
value: torch.Tensor,
kv_cache: Optional[torch.Tensor],
attn_metadata: AttentionMetadata[XFormersMetadata],
kv_scale: float,
attn_metadata: "XFormersMetadata",
kv_scale: float = 1.0,
) -> torch.Tensor:
"""Forward pass with xFormers and PagedAttention.
......@@ -184,7 +255,6 @@ class XFormersImpl(AttentionImpl):
Returns:
shape = [num_tokens, num_heads * head_size]
"""
num_tokens, hidden_size = query.shape
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)
......@@ -199,8 +269,7 @@ class XFormersImpl(AttentionImpl):
PagedAttention.write_to_paged_cache(key, value, key_cache,
value_cache,
attn_metadata.slot_mapping,
attn_metadata.kv_cache_dtype,
kv_scale)
self.kv_cache_dtype, kv_scale)
num_prefill_tokens = attn_metadata.num_prefill_tokens
num_decode_tokens = attn_metadata.num_decode_tokens
......@@ -240,7 +309,7 @@ class XFormersImpl(AttentionImpl):
key_cache,
value_cache,
prefill_meta.block_tables,
prefill_meta.subquery_start_loc,
prefill_meta.query_start_loc,
prefill_meta.seq_lens_tensor,
prefill_meta.context_lens_tensor,
prefill_meta.max_query_len,
......@@ -257,8 +326,8 @@ class XFormersImpl(AttentionImpl):
value_cache,
decode_meta.block_tables,
decode_meta.seq_lens_tensor,
decode_meta.max_seq_len,
attn_metadata.kv_cache_dtype,
decode_meta.max_decode_seq_len,
self.kv_cache_dtype,
self.num_kv_heads,
self.scale,
self.alibi_slopes,
......
vllm/attention/layer.py
View file @ b9e12416
"""Attention layer."""
from typing import List, Optional
from typing import Any, Dict, List, Optional
import torch
import torch.nn as nn
from vllm.attention.backends.abstract import (AttentionMetadata,
AttentionMetadataPerStage)
from vllm.attention.backends.abstract import AttentionMetadata
from vllm.attention.selector import get_attn_backend
from vllm.config import CacheConfig
from vllm.model_executor.layers.quantization.base_config import (
QuantizationConfig)
class Attention(nn.Module):
......@@ -28,13 +30,53 @@ class Attention(nn.Module):
scale: float,
num_kv_heads: Optional[int] = None,
alibi_slopes: Optional[List[float]] = None,
sliding_window: Optional[int] = None,
cache_config: Optional[CacheConfig] = None,
quant_config: Optional[QuantizationConfig] = None,
blocksparse_params: Optional[Dict[str, Any]] = None,
) -> None:
super().__init__()
self.backend = get_attn_backend(torch.get_default_dtype())
impl_cls = self.backend.get_impl_cls()
if cache_config is not None:
kv_cache_dtype = cache_config.cache_dtype
block_size = cache_config.block_size
sliding_window = cache_config.sliding_window
else:
kv_cache_dtype = "auto"
block_size = 16
sliding_window = None
if num_kv_heads is None:
num_kv_heads = num_heads
# The default kv_scale is set to 1.0. This is ignored
# when kv-cache is not fp8, and should be used with
# kv-cache in fp8_e5m2. For kv-cache in fp8_e4m3, we
# expect the pre-quantized kv_scale to be loaded along
# with the model weights.
self.kv_cache_dtype = kv_cache_dtype
self._kv_scale = 1.0
quant_method = quant_config.get_quant_method(
self) if quant_config else None
if quant_method is not None:
if self.kv_cache_dtype == "fp8_e5m2":
raise ValueError("fp8_e5m2 kv-cache is not supported with "
"fp8 checkpoints.")
# When FP8 quantization is enabled, we make a parameter
# "kv_scale" so that it can be loaded from FP8 checkpoint.
# The kv_scale will then be converted back
# to self._kv_scale in a native float32 value after weight loading.
self.quant_method = quant_method
self.quant_method.create_weights(self)
# During model initialization, the default dtype is set as the model
# weight and activation dtype.
dtype = torch.get_default_dtype()
attn_backend = get_attn_backend(num_heads, head_size, num_kv_heads,
sliding_window, dtype, kv_cache_dtype,
block_size, blocksparse_params
is not None)
impl_cls = attn_backend.get_impl_cls()
self.impl = impl_cls(num_heads, head_size, scale, num_kv_heads,
alibi_slopes, sliding_window)
alibi_slopes, sliding_window, kv_cache_dtype,
blocksparse_params)
def forward(
self,
......@@ -42,15 +84,15 @@ class Attention(nn.Module):
key: torch.Tensor,
value: torch.Tensor,
kv_cache: Optional[torch.Tensor],
attn_metadata: AttentionMetadata[AttentionMetadataPerStage],
kv_scale: float = 1.0,
attn_metadata: AttentionMetadata,
) -> torch.Tensor:
return self.impl.forward(query, key, value, kv_cache, attn_metadata,
kv_scale)
self._kv_scale)
def extra_repr(self) -> str:
s = f"head_size={self.impl.head_size}" # type: ignore
s += f", num_heads={self.impl.num_heads}" # type: ignore
s += f", num_kv_heads={self.impl.num_kv_heads}" # type: ignore
s += f", scale={self.impl.scale}" # type: ignore
s += f", backend={self.impl.__class__.__name__}"
return s
vllm/attention/ops/blocksparse_attention/blocksparse_attention_kernel.py 0 → 100644
View file @ b9e12416
import torch
import triton
import triton.language as tl
def blocksparse_flash_attn_varlen_fwd(
q,
k,
v, # (#tokens, n_heads, head_size)
cu_seqlens_k,
cu_seqlens_q,
sm_scale,
sparse_layout,
*,
block_size=64,
q_block_size=None,
max_seqlen=None):
# split q to blocks
assert isinstance(sparse_layout, (list, tuple))
_, n_heads, head_size = q.shape
batch_size = cu_seqlens_k.size(0) - 1
q_block_size = q_block_size or block_size
assert q.dim() == k.dim() == v.dim() == 3
assert q.size(1) % k.size(1) == 0
assert q.size(2) == k.size(2)
# TODO(linxihui): allow k, v to have different head_size
assert k.shape == v.shape
assert cu_seqlens_k.dim() == 1
q_k_ratio = q.size(1) // k.size(1)
if cu_seqlens_q is None:
if q.size(0) == batch_size: # decoding only
cu_seqlens_q = torch.arange(
0,
batch_size + 1,
dtype=cu_seqlens_k.dtype,
device=cu_seqlens_k.device,
)
elif q.size(0) == k.size(0):
cu_seqlens_q = cu_seqlens_k
else:
raise ValueError("cu_seqlens_q must be specified\
if it mix of prefilling and decoding.")
else:
assert cu_seqlens_k.size(0) == cu_seqlens_q.size(0)
# switch to use cpu to avoid too many kernel launches when iterated over
q_lens = (cu_seqlens_q[1:] - cu_seqlens_q[:-1]).cpu()
k_lens = (cu_seqlens_k[1:] - cu_seqlens_k[:-1]).cpu()
assert torch.logical_or(q_lens == 1, k_lens == q_lens).all(), (
"length of q should either be 1 (decoding) or same as k (prefilling).")
if max_seqlen:
assert k_lens.max() <= max_seqlen
n_blocks = (q_lens + q_block_size - 1) // q_block_size
q_batch_ids = torch.tensor(
[i for i, n in enumerate(n_blocks) for _ in range(n)],
dtype=cu_seqlens_q.dtype,
device=cu_seqlens_q.device,
)
q_start_sids = torch.tensor(
[i * q_block_size for n in n_blocks for i in range(n)],
dtype=cu_seqlens_q.dtype,
device=cu_seqlens_q.device,
)
out = q.new_empty(q.shape)
cu_seqlens_q = cu_seqlens_q.contiguous()
cu_seqlens_k = cu_seqlens_k.contiguous()
layout_crow_indices, layout_col_indices = sparse_layout
block_d = triton.next_power_of_2(head_size)
decoding_only = (q_lens == 1).all().item()
grid = (len(q_start_sids), n_heads, 1)
_fwd_kernel_batch_inference[grid](
q,
k,
v,
out,
sm_scale,
cu_seqlens_q[:-1],
cu_seqlens_q[1:],
cu_seqlens_k[:-1],
cu_seqlens_k[1:],
q_batch_ids,
q_start_sids,
0,
*q.stride(),
0,
*k.stride(),
0,
*v.stride(),
0,
*out.stride(),
layout_crow_indices,
layout_col_indices,
*layout_crow_indices.stride(),
*layout_col_indices.stride(),
q_k_ratio,
HAS_BATCH_DIM=False,
D_HEAD=head_size,
BLOCK_M=q_block_size,
BLOCK_N=block_size,
BLOCK_D=block_d,
BLOCK_M_LOADING=(16 if decoding_only else
q_block_size), # smaller for decoding
EVEN_D=block_d == head_size,
num_warps=1 if decoding_only else 4,
num_stages=3)
return out
@triton.jit
def _fwd_kernel_inner(
acc,
l_i,
m_i,
q,
Q,
k_block_col_idx,
layout_col_ptr,
layout_col_stride_h,
layout_col_stride_m,
k_ptrs,
v_ptrs,
off_h,
offs_m,
offs_n,
offs_d,
stride_kt,
stride_vt,
sm_scale,
k_seqlen,
past_len,
LAST_K_BLOCK: tl.constexpr,
BLOCK_M_LOADING: tl.constexpr,
BLOCK_N: tl.constexpr,
D_HEAD: tl.constexpr,
EVEN_D: tl.constexpr,
M_LT_N: tl.constexpr,
):
k_block_id = tl.load(layout_col_ptr + off_h * layout_col_stride_h +
k_block_col_idx * layout_col_stride_m).to(tl.int32)
start_n = k_block_id * BLOCK_N
if LAST_K_BLOCK:
if EVEN_D:
k = tl.load(
k_ptrs + start_n * stride_kt,
mask=offs_n[None, :] + start_n < k_seqlen,
)
else:
k = tl.load(
k_ptrs + start_n * stride_kt,
mask=(offs_n[None, :] + start_n < k_seqlen) &
(offs_d[:, None] < D_HEAD),
)
else:
if EVEN_D:
k = tl.load(k_ptrs + start_n * stride_kt)
else:
k = tl.load(k_ptrs + start_n * stride_kt,
mask=offs_d[:, None] < D_HEAD)
qk = tl.zeros([BLOCK_M_LOADING, BLOCK_N], dtype=tl.float32)
qk += tl.dot(q, k)
qk *= sm_scale
# the following is needed only when LAST_K_BLOCK or BLOCK_M < BLOCK_N
if LAST_K_BLOCK | M_LT_N:
qk += tl.where(
offs_m[:, None] + past_len >= (start_n + offs_n[None, :]),
0,
float("-inf"),
)
# flash-attn2
m_ij = tl.maximum(m_i, tl.max(qk, 1))
p = tl.math.exp2(qk - m_ij[:, None])
l_ij = tl.sum(p, 1)
alpha = tl.math.exp2(m_i - m_ij)
acc = acc * alpha[:, None]
# update m_i
m_i = m_ij
l_i = l_i * alpha + l_ij
p = p.to(Q.dtype.element_ty)
# update acc
if LAST_K_BLOCK:
if EVEN_D:
v = tl.load(
v_ptrs + start_n * stride_vt,
mask=offs_n[:, None] + start_n < k_seqlen,
)
else:
v = tl.load(
v_ptrs + start_n * stride_vt,
mask=(offs_n[:, None] + start_n < k_seqlen) &
(offs_d[None, :] < D_HEAD),
)
else:
if EVEN_D:
v = tl.load(v_ptrs + start_n * stride_vt)
else:
v = tl.load(v_ptrs + start_n * stride_vt,
mask=offs_d[None, :] < D_HEAD)
acc += tl.dot(p, v)
return acc, l_i, m_i
@triton.heuristics({
"M_LT_N":
lambda kwargs: kwargs["BLOCK_M"] < kwargs["BLOCK_N"],
})
@triton.jit
def _fwd_kernel_batch_inference(
Q,
K,
V,
Out,
sm_scale,
q_batch_starts,
q_batch_ends,
k_batch_starts,
k_batch_ends,
q_batch_ids,
q_start_sids,
stride_qb,
stride_qt,
stride_qh,
stride_qd,
stride_kb,
stride_kt,
stride_kh,
stride_kd,
stride_vb,
stride_vt,
stride_vh,
stride_vd,
stride_ob,
stride_ot,
stride_oh,
stride_od,
layout_crow_ptr,
layout_col_ptr,
layout_crow_stride_h,
layout_crow_stride_m,
layout_col_stride_h,
layout_col_stride_m,
q_k_ratio,
HAS_BATCH_DIM: tl.constexpr,
D_HEAD: tl.constexpr,
BLOCK_M: tl.constexpr,
BLOCK_N: tl.constexpr,
BLOCK_D: tl.constexpr,
BLOCK_M_LOADING: tl.constexpr,
EVEN_D: tl.constexpr,
M_LT_N: tl.constexpr,
):
"""
NOTATION:
pid: position id
sid: storage id
sbid: storage block id
pbid: position block id
offs_m, offs_n: storage offsets of m-dim(q, row) and n-dim(k, col)
TODO(linxihui):
Optimize grouped-attn
"""
off_zm = tl.program_id(0)
off_h = tl.program_id(1)
off_h_for_kv = off_h // q_k_ratio
if HAS_BATCH_DIM:
off_z = tl.program_id(2)
Q += off_z * stride_qb
K += off_z * stride_kb
V += off_z * stride_vb
Out += off_z * stride_ob
start_m = off_zm
q_start_sid = start_m * BLOCK_M # always 0 for decoding
else:
off_z = tl.load(q_batch_ids + off_zm).to(tl.int32) # [0, 0, 0, 1]
q_start_sid = tl.load(q_start_sids + off_zm)
start_m = q_start_sid // BLOCK_M # q_sbid
offs_m = start_m * BLOCK_M + tl.arange(0, BLOCK_M_LOADING)
offs_n = tl.arange(0, BLOCK_N)
offs_d = tl.arange(0, BLOCK_D)
q_cu_start = tl.load(q_batch_starts + off_z).to(tl.int32)
q_seqlen = tl.load(q_batch_ends + off_z).to(tl.int32) - q_cu_start
k_cu_start = tl.load(k_batch_starts + off_z).to(tl.int32)
k_seqlen = tl.load(k_batch_ends + off_z).to(tl.int32) - k_cu_start
past_len = k_seqlen - q_seqlen
Q += q_cu_start * stride_qt + off_h * stride_qh
K += k_cu_start * stride_kt + off_h_for_kv * stride_kh
V += k_cu_start * stride_vt + off_h_for_kv * stride_vh
Out += q_cu_start * stride_ot + off_h * stride_oh
q_pbid = (past_len + q_start_sid) // BLOCK_M
if EVEN_D:
q = tl.load(
Q + offs_m[:, None] * stride_qt + offs_d[None, :] * stride_qd,
mask=offs_m[:, None] < q_seqlen,
)
else:
q = tl.load(
Q + offs_m[:, None] * stride_qt + offs_d[None, :] * stride_qd,
mask=(offs_m[:, None] < q_seqlen) & (offs_d[None, :] < D_HEAD),
other=0,
)
sparse_crow_ptr = (layout_crow_ptr + off_h * layout_crow_stride_h +
q_pbid * layout_crow_stride_m)
# TODO(linxihui): load at once, with any Triton version
# that supports `tl.split`, e.g., Triton 3.0
k_block_start = tl.load(sparse_crow_ptr).to(tl.int32)
k_block_end = tl.load(sparse_crow_ptr + 1).to(tl.int32)
m_i = tl.zeros([BLOCK_M_LOADING], dtype=tl.float32) - float("inf")
l_i = tl.zeros([BLOCK_M_LOADING], dtype=tl.float32)
acc = tl.zeros([BLOCK_M_LOADING, BLOCK_D], dtype=tl.float32)
k_ptrs = K + offs_n[None, :] * stride_kt + offs_d[:, None] * stride_kd
v_ptrs = V + offs_n[:, None] * stride_vt + offs_d[None, :] * stride_vd
sm_scale *= (
1.44269504 # 1/log2 as we use base2 for exponential and logarithm
)
for k_block_col_idx in range(k_block_start, k_block_end - 1):
acc, l_i, m_i = _fwd_kernel_inner(
acc,
l_i,
m_i,
q,
Q,
k_block_col_idx,
layout_col_ptr,
layout_col_stride_h,
layout_col_stride_m,
k_ptrs,
v_ptrs,
off_h,
offs_m,
offs_n,
offs_d,
stride_kt,
stride_vt,
sm_scale,
k_seqlen,
past_len,
False,
BLOCK_M_LOADING,
BLOCK_N,
D_HEAD,
EVEN_D,
M_LT_N,
)
acc, l_i, m_i = _fwd_kernel_inner(
acc,
l_i,
m_i,
q,
Q,
k_block_end - 1,
layout_col_ptr,
layout_col_stride_h,
layout_col_stride_m,
k_ptrs,
v_ptrs,
off_h,
offs_m,
offs_n,
offs_d,
stride_kt,
stride_vt,
sm_scale,
k_seqlen,
past_len,
True,
BLOCK_M_LOADING,
BLOCK_N,
D_HEAD,
EVEN_D,
M_LT_N,
)
# flash-attn 2
m_i += tl.math.log2(l_i)
acc = acc / l_i[:, None]
# write output
if EVEN_D:
tl.store(
Out + offs_m[:, None] * stride_ot + offs_d[None, :] * stride_od,
acc,
mask=offs_m[:, None] < q_seqlen,
)
else:
tl.store(
Out + offs_m[:, None] * stride_ot + offs_d[None, :] * stride_od,
acc,
mask=(offs_m[:, None] < q_seqlen) & (offs_d[None, :] < D_HEAD),
)
vllm/attention/ops/blocksparse_attention/interface.py 0 → 100644
View file @ b9e12416
import math
import torch
from vllm.utils import is_cpu, is_hip
from .utils import (dense_to_crow_col, get_head_sliding_step,
get_sparse_attn_mask)
IS_COMPUTE_8_OR_ABOVE = (torch.cuda.is_available()
and torch.cuda.get_device_capability()[0] >= 8)
if IS_COMPUTE_8_OR_ABOVE:
from .blocksparse_attention_kernel import blocksparse_flash_attn_varlen_fwd
class LocalStridedBlockSparseAttn(torch.nn.Module):
def __init__(
self,
n_heads,
max_seqlen,
local_blocks,
vert_stride,
block_size,
device=None,
dtype=None,
homo_head=False,
active_head_range=None,
q_block_size=None,
use_spda=None,
):
super().__init__()
if use_spda is None:
use_spda = is_hip() or is_cpu() or not \
IS_COMPUTE_8_OR_ABOVE
device = device or (torch.cuda.current_device()
if torch.cuda.is_available() else "cpu")
device = torch.device(device)
# NOTE: vllm CPU backend support BF16 instead of FP16.
dtype = dtype or (torch.bfloat16 if IS_COMPUTE_8_OR_ABOVE
or device.type == "cpu" else torch.half)
self.n_heads = n_heads
self.max_seqlen = max_seqlen
self.local_blocks = local_blocks
self.vert_stride = vert_stride
self.use_spda = use_spda
self.dtype = dtype
self.device = device
self.block_size = block_size
self.q_block_size = q_block_size
self.homo_head = homo_head
self.active_head_range = active_head_range
self.head_sliding_step = get_head_sliding_step(n_heads, vert_stride,
homo_head)
sparse_layout, sparse_pattern, self.dense_attn_mask = (
self.get_attn_pattern(dtype, device))
if q_block_size is not None and q_block_size != block_size:
if q_block_size > block_size:
assert q_block_size % block_size == 0
blocks_to_merge = q_block_size // block_size
shape = sparse_pattern.shape
sparse_pattern = sparse_pattern.view(shape[0], -1,
blocks_to_merge,
shape[-1])
sparse_pattern = sparse_pattern.sum(2)
sparse_layout = dense_to_crow_col(sparse_pattern)
else:
raise ValueError(
"Does not support smaller q_block_size. It will be slower."
)
self.sparse_layout = sparse_layout
def get_attn_pattern(self, dtype, device):
sparse_layout, sparse_pattern, dense_attn_mask = get_sparse_attn_mask(
self.n_heads,
self.max_seqlen,
self.max_seqlen,
dtype,
device,
block_size=self.block_size,
local_blocks=self.local_blocks,
vert_stride=self.vert_stride,
homo_head=self.homo_head,
return_dense=self.use_spda,
dense_mask_type="bias",
)
if (not self.homo_head) and (self.active_head_range is not None):
assert isinstance(self.active_head_range, tuple)
assert (len(self.active_head_range) == 2)
h_start, h_end = self.active_head_range
sparse_layout = tuple(x[h_start:h_end] for x in sparse_layout)
if self.use_spda:
dense_attn_mask = dense_attn_mask[h_start:h_end]
return sparse_layout, sparse_pattern, dense_attn_mask
def varlen_attn(self,
q,
k,
v,
cu_seqlens_k,
cu_seqlens_q=None,
sm_scale=None):
"""
q, k, v: shape = (num_tokens, num_heads_q/kv, head_size).
Support grouped attention, with `q[:, i*r:(i*r + r)]`
is correspondent to `k[:, i]`, where `r` is the q/k ratio.
cu_seqlens_k: shape=(batch_size + 1,),
indicating segment of samples,
e.g., `k[cu_seqlen[i]:cu_seqlne[i+1]]` is q of sample i
cu_seqlens_q: shape=(batch_size + 1, ).
Default None: same as cu_seqlens_k for prefilling or
[0, 1, .., batch_size] for decoding.
The only case you need to specify is when q is a mix of
prefilling and decoding.
sm_scale: softmax scale, default to 1/sqrt(head_size).
return: tensor of shape as q.
"""
assert (
IS_COMPUTE_8_OR_ABOVE
), "Requires compute capability of 8 or above (Ampere or newer) to use \
Triton kernel."
sm_scale = sm_scale or 1.0 / math.sqrt(q.size(-1))
return blocksparse_flash_attn_varlen_fwd(
q,
k,
v,
cu_seqlens_k,
cu_seqlens_q,
sm_scale,
self.sparse_layout,
block_size=self.block_size,
q_block_size=self.q_block_size,
max_seqlen=self.max_seqlen,
)
@staticmethod
def transpose_and_pad(x, cu_seqlens, maxlen, head_repeats=1):
"""
:param x: (total_tokens, n_heads, head_size)
:return: (batch, n_heads, length, head_size)
"""
x_padded = x.new_empty(
len(cu_seqlens) - 1, x.size(1), head_repeats, maxlen, x.size(2))
cu_seqlens = cu_seqlens.cpu()
for i, (s, e) in enumerate(zip(cu_seqlens[:-1], cu_seqlens[1:])):
x_padded[i, :, :, :e - s].copy_(x[s:e].transpose(0,
1).unsqueeze(1))
return x_padded.flatten(1, 2)
@staticmethod
def transpose_and_unpad(x_padded, cu_seqlens):
"""
:param x_padded: (batch, n_heads, length, head_size)
:return: (total_tokens, n_heads, head_size)
"""
cu_seqlens = cu_seqlens.cpu()
total_n_tokens = cu_seqlens[-1]
x = x_padded.new_empty(total_n_tokens, x_padded.size(1),
x_padded.size(3))
for i, (s, e) in enumerate(zip(cu_seqlens[:-1], cu_seqlens[1:])):
x[s:e].copy_(x_padded[i, :, :e - s].transpose(0, 1))
return x
def spda(self, q, k, v, cu_seqlens_k, cu_seqlens_q=None, sm_scale=None):
"""For CPU, V100 or other older GPUs.
NOTE: torch SPDA supports nested tensor,
but seems extremely slow. Choose to pad instead.
"""
assert (cu_seqlens_q is None or
(cu_seqlens_q
== cu_seqlens_k).all()), "Can only handle prompt with SPDA."
assert q.size(0) == k.size(0), "can only handle prompt with SPDA."
assert q.size(1) % k.size(1) == 0
q_k_ratio = q.size(1) // k.size(1)
sm_scale = sm_scale or 1.0 / math.sqrt(q.size(-1))
cu_seqlens = cu_seqlens_k.cpu()
maxlen = (cu_seqlens[1:] - cu_seqlens[:-1]).max()
if (self.dense_attn_mask.dtype != q.dtype
or self.dense_attn_mask.device != q.device):
_, _, self.dense_attn_mask = self.get_attn_pattern(
q.dtype, q.device)
attn_mask = self.dense_attn_mask[None, :, :maxlen, :maxlen]
q2 = self.transpose_and_pad(q, cu_seqlens, maxlen, 1)
k2, v2 = [
self.transpose_and_pad(x, cu_seqlens, maxlen, q_k_ratio)
for x in [k, v]
]
spda_output = torch.nn.functional.scaled_dot_product_attention(
q2, k2, v2, attn_mask=attn_mask, scale=sm_scale)
return self.transpose_and_unpad(spda_output, cu_seqlens)
def forward(self, q, k, v, cu_seqlens_k, cu_seqlens_q=None, sm_scale=None):
"""Dispatch to `varlen_attn` (Ampere or newer) or
`self.spda`(cpu, Volta, Turing or older)based on
the type of device used and cuda compute capability.
q, k, v: shape = (num_tokens, num_heads_q/kv, head_size).
Support grouped attention, with `q[:, i*r:(i*r + r)]`
is correspondent to `k[:, i]`, where `r` is the q/k ratio.
cu_seqlens_k: shape=(batch_size + 1,), indicating segment of samples,
e.g., `k[cu_seqlen[i]:cu_seqlne[i+1]]` is q of sample i
cu_seqlens_q: shape=(batch_size + 1, ).
Default None: same as cu_seqlens_k for prefilling or
[0, 1, .., batch_size] for decoding.
The only case you need to specify
is when q is a mix of prefilling
and decoding.
sm_scale: softmax scale, default to 1/sqrt(head_size).
return: tensor of shape as q.
"""
assert k.dim() == 3
if self.use_spda:
return self.spda(
q,
k,
v,
cu_seqlens_k,
cu_seqlens_q=cu_seqlens_q,
sm_scale=sm_scale,
)
return self.varlen_attn(q,
k,
v,
cu_seqlens_k,
cu_seqlens_q=cu_seqlens_q,
sm_scale=sm_scale)
\ No newline at end of file
vllm/attention/ops/blocksparse_attention/utils.py 0 → 100644
View file @ b9e12416
# Helper functions for 3D sparse pattern
# These function are not optimized and very inefficient.
# Avoid calling them too frequent or use a cache mechanism.
from functools import lru_cache
import torch
import triton
from scipy import sparse
def dense_to_crow_col(x: torch.Tensor):
"""Turning a 2D/3D torch tensor (x) to CSR rows/cols indexing.
NOTE: col_indices padded -1
"""
device = x.device
pad = -1
dim = x.dim()
assert x.dim() in (2, 3)
if x.dim() == 2:
x = x[None]
x = [sparse.csr_matrix(xi.bool().cpu().numpy()) for xi in x]
crows = torch.vstack([torch.from_numpy(xi.indptr) for xi in x])
cols = [torch.from_numpy(xi.indices) for xi in x]
max_cols = max(len(xi) for xi in cols)
cols = [
torch.cat([xi, pad + xi.new_zeros(max_cols - xi.shape[0])])
for xi in cols
]
cols = torch.vstack(cols)
if dim == 2:
crows = crows[0]
cols = cols[0]
return crows.to(device), cols.to(device)
def crow_col_to_dense(crows: torch.Tensor,
cols: torch.Tensor,
dtype: torch.dtype = torch.float16):
dim = crows.dim()
if dim == 1:
crows = crows[None]
cols = cols[None]
device = crows.device
crows, cols = crows.cpu(), cols.cpu() # faster in cpu
shape = (crows.shape[0], crows.shape[1] - 1, cols.max() + 1)
x = torch.zeros(shape, dtype=dtype)
for i in range(shape[0]):
for j in range(shape[1]):
x[i, j, cols[i, crows[i, j]:crows[i, j + 1]]] = 1
if dim == 1:
x = x[0]
return x.to(device)
def dense_to_ccol_row(x: torch.Tensor):
"""Similar, but to CSC format"""
x = x.transpose(-2, -1)
return dense_to_crow_col(x)
def ccol_row_to_dense(ccol: torch.Tensor,
rows: torch.Tensor,
dtype: torch.dtype = torch.float16):
return crow_col_to_dense(ccol, rows, dtype).permute(0, 2, 1).contiguous()
def _get_sparse_attn_mask_homo_head(
q_len: int,
max_seqlen: int,
dtype: torch.dtype,
device: torch.device,
block_size: int = 128,
local_blocks: int = 4,
vert_stride: int = 4,
return_dense: bool = False,
):
"""
:return: a tuple of 3:
- tuple of crow_indices, col_indices representation
of CSR format.
- block dense mask
- all token dense mask (be aware that it can be
OOM if it is too big) if `return_dense==True`,
otherwise, None
"""
with torch.no_grad():
num_blocks = triton.cdiv(max_seqlen, block_size)
q_pos = torch.arange(num_blocks)[:, None]
k_pos = torch.arange(num_blocks)[None]
mask_vert_strided = (torch.arange(num_blocks) + 1) % vert_stride == 0
block_mask_dense = (((q_pos >= k_pos)
& ((q_pos - k_pos < local_blocks)
| mask_vert_strided)).to(device).to(dtype))
num_blocks_q = triton.cdiv(q_len, block_size)
block_mask_dense_output = (dense_to_crow_col(
block_mask_dense[-num_blocks_q:].contiguous()))
if return_dense:
mask_dense = torch.kron(
block_mask_dense,
block_mask_dense.new_ones((block_size, block_size)),
)
causal_mask = torch.tril(torch.ones(
max_seqlen, max_seqlen)).type_as(mask_dense)[-q_len:]
mask_dense = mask_dense[-q_len:, :max_seqlen] * causal_mask
return (
block_mask_dense_output,
block_mask_dense,
mask_dense,
)
else:
return (
block_mask_dense_output,
block_mask_dense,
None,
)
def binary_mask_to_bias(mask_dense: torch.Tensor):
mask_dense = 1 - mask_dense
mask_dense.masked_fill_(mask_dense.bool(), -torch.inf)
return mask_dense
def get_head_sliding_step(n_heads: int,
vert_stride: int,
homo_head: bool = False):
if homo_head:
return 0
return max(1, int(vert_stride / n_heads))
@lru_cache
def get_sparse_attn_mask(
n_heads: int,
q_len: int,
max_seqlen: int,
dtype: torch.dtype,
device: torch.device,
block_size: int = 64,
local_blocks: int = 4,
vert_stride: int = 4,
homo_head: bool = True,
return_dense: bool = False,
dense_mask_type: str = "binary",
):
"""
:param dense_mask_type: "binary" (0 for skip token, 1 for others)
or "bias" (-inf for skip token, 0 or others)
:return: a tuple of 3:
- tuple of crow_indices, col_indices representation
of CSR format.
- block dense mask
- all token dense mask (be aware that it can be OOM if it
is too big) if `return_dense==True`, otherwise, None
"""
assert dense_mask_type in ("binary", "bias")
if homo_head:
with torch.no_grad():
(crow, col), block_mask_dense, mask_dense = (
_get_sparse_attn_mask_homo_head(
q_len,
max_seqlen,
dtype,
device,
block_size,
local_blocks,
vert_stride,
return_dense,
))
crow = crow[None].expand(n_heads, crow.shape[0])
col = col[None].expand(n_heads, col.shape[0])
if return_dense:
mask_dense = mask_dense[None].expand(n_heads,
*mask_dense.shape)
if dense_mask_type == "bias":
mask_dense = binary_mask_to_bias(mask_dense)
return (crow, col), block_mask_dense, mask_dense
with torch.no_grad():
num_blocks = triton.cdiv(max_seqlen, block_size)
q_pos = torch.arange(num_blocks)[None, :, None]
k_pos = torch.arange(num_blocks)[None, None]
head_sliding_step = get_head_sliding_step(n_heads, vert_stride)
mask_vert_strided = [
(torch.arange(num_blocks) + h * head_sliding_step + 1) %
vert_stride == 0 for h in range(n_heads)
]
mask_vert_strided = torch.vstack(mask_vert_strided).unsqueeze(1)
block_mask_dense = (((q_pos >= k_pos)
& ((q_pos - k_pos < local_blocks)
| mask_vert_strided)).to(device).to(dtype))
num_blocks_q = triton.cdiv(q_len, block_size)
block_mask_dense_output = block_mask_dense[:, -num_blocks_q:]
if return_dense:
mask_dense = torch.kron(
block_mask_dense,
block_mask_dense.new_ones((block_size, block_size)),
)
causal_mask = torch.tril(torch.ones(
max_seqlen, max_seqlen)).type_as(mask_dense)[-q_len:]
mask_dense = mask_dense[..., -q_len:, :max_seqlen] * causal_mask[None]
if dense_mask_type == "bias":
mask_dense = binary_mask_to_bias(mask_dense)
return (
dense_to_crow_col(block_mask_dense_output),
block_mask_dense,
mask_dense,
)
else:
return (
dense_to_crow_col(block_mask_dense_output),
block_mask_dense,
None,
)
vllm/attention/ops/paged_attn.py
View file @ b9e12416
from dataclasses import dataclass
from typing import Dict, List, Optional, Tuple
from typing import List, Optional, Tuple
import torch
......@@ -16,8 +16,8 @@ class PagedAttentionMetadata:
# (batch_size,). The length of sequences (entire tokens seen so far) per
# sequence.
seq_lens_tensor: Optional[torch.Tensor]
# Maximum sequence length in the batch.
max_seq_len: Optional[int]
# Maximum sequence length in the batch. 0 if it is prefill-only batch.
max_decode_seq_len: int
# (batch_size, max_blocks_per_seq).
# Block addresses per sequence. (Seq id -> list of physical block)
# E.g., [0, 1, 2] means tokens are stored in 0th, 1st, and 2nd blocks
......@@ -31,7 +31,7 @@ class PagedAttention:
@staticmethod
def get_supported_head_sizes() -> List[int]:
return [64, 80, 96, 112, 128, 256]
return [64, 80, 96, 112, 128, 192, 256]
@staticmethod
def get_kv_cache_shape(
......@@ -91,9 +91,21 @@ class PagedAttention:
scale: float,
alibi_slopes: Optional[torch.Tensor],
kv_scale: float,
tp_rank: int = 0,
blocksparse_local_blocks: int = 0,
blocksparse_vert_stride: int = 0,
blocksparse_block_size: int = 64,
blocksparse_head_sliding_step: int = 0,
) -> torch.Tensor:
output = torch.empty_like(query)
if blocksparse_vert_stride is not None and blocksparse_vert_stride > 1:
# use blocksparse paged attention
block_size = value_cache.size(-1)
assert (blocksparse_block_size > 0 and
blocksparse_block_size % block_size == 0), \
(f"{blocksparse_block_size=} needs to be a multiple of"
f"{block_size=} used in block_tables.")
output = torch.empty_like(query)
block_size = value_cache.shape[3]
num_seqs, num_heads, head_size = query.shape
max_num_partitions = ((max_seq_len + _PARTITION_SIZE - 1) //
......@@ -107,6 +119,7 @@ class PagedAttention:
# For context len > 8192, use V2 kernel to avoid shared memory shortage.
use_v1 = (max_seq_len <= 8192
and (max_num_partitions == 1 or num_seqs * num_heads > 512))
if use_v1:
# Run PagedAttention V1.
ops.paged_attention_v1(
......@@ -123,6 +136,11 @@ class PagedAttention:
alibi_slopes,
kv_cache_dtype,
kv_scale,
tp_rank,
blocksparse_local_blocks,
blocksparse_vert_stride,
blocksparse_block_size,
blocksparse_head_sliding_step,
)
else:
# Run PagedAttention V2.
......@@ -155,6 +173,11 @@ class PagedAttention:
alibi_slopes,
kv_cache_dtype,
kv_scale,
tp_rank,
blocksparse_local_blocks,
blocksparse_vert_stride,
blocksparse_block_size,
blocksparse_head_sliding_step,
)
return output
......@@ -166,7 +189,7 @@ class PagedAttention:
key_cache: torch.Tensor,
value_cache: torch.Tensor,
block_tables: torch.Tensor,
subquery_start_loc: torch.Tensor,
query_start_loc: torch.Tensor,
seq_lens_tensor: torch.Tensor,
context_lens: torch.Tensor,
max_query_len: int,
......@@ -182,8 +205,8 @@ class PagedAttention:
key_cache,
value_cache,
block_tables,
# subquery_start_loc is (batch_size + 1,)
subquery_start_loc[:-1],
# query_start_loc is (batch_size + 1,)
query_start_loc[:-1],
seq_lens_tensor,
context_lens,
max_query_len,
......@@ -196,7 +219,7 @@ class PagedAttention:
def swap_blocks(
src_kv_cache: torch.Tensor,
dst_kv_cache: torch.Tensor,
src_to_dst: Dict[int, int],
src_to_dst: torch.Tensor,
) -> None:
src_key_cache = src_kv_cache[0]
dst_key_cache = dst_kv_cache[0]
......@@ -209,7 +232,7 @@ class PagedAttention:
@staticmethod
def copy_blocks(
kv_caches: List[torch.Tensor],
src_to_dists: Dict[int, List[int]],
src_to_dists: torch.Tensor,
) -> None:
key_caches = [kv_cache[0] for kv_cache in kv_caches]
value_caches = [kv_cache[1] for kv_cache in kv_caches]
......
vllm/attention/ops/prefix_prefill.py
View file @ b9e12416
......@@ -472,7 +472,8 @@ if triton.__version__ >= "2.1.0":
stride_v_cache_bl,
num_queries_per_kv: int,
BLOCK_M: tl.constexpr,
BLOCK_DMODEL: tl.constexpr,
BLOCK_DMODEL: tl.constexpr, # head size
BLOCK_DMODEL_PADDED: tl.constexpr, # head size padded to a power of 2
BLOCK_N: tl.constexpr,
):
# attn_bias[]
......@@ -493,21 +494,24 @@ if triton.__version__ >= "2.1.0":
# initialize offsets
offs_n = tl.arange(0, BLOCK_N)
offs_d = tl.arange(0, BLOCK_DMODEL)
offs_d = tl.arange(0, BLOCK_DMODEL_PADDED)
offs_m = start_m * BLOCK_M + tl.arange(0, BLOCK_M)
off_q = (
(cur_batch_in_all_start_index + offs_m[:, None]) * stride_qbs +
cur_head * stride_qh + offs_d[None, :] * stride_qd)
q = tl.load(
Q + off_q,
mask=offs_m[:, None] < cur_batch_seq_len - cur_batch_ctx_len,
other=0.0)
dim_mask = tl.where(
tl.arange(0, BLOCK_DMODEL_PADDED) < BLOCK_DMODEL, 1, 0).to(tl.int1)
q = tl.load(Q + off_q,
mask=dim_mask[None, :] &
(offs_m[:, None] < cur_batch_seq_len - cur_batch_ctx_len),
other=0.0)
# # initialize pointer to m and l
m_i = tl.zeros([BLOCK_M], dtype=tl.float32) - float("inf")
l_i = tl.zeros([BLOCK_M], dtype=tl.float32)
acc = tl.zeros([BLOCK_M, BLOCK_DMODEL], dtype=tl.float32)
acc = tl.zeros([BLOCK_M, BLOCK_DMODEL_PADDED], dtype=tl.float32)
alibi_slope = tl.load(Alibi_slopes + cur_head)
alibi_start_q = tl.arange(
......@@ -532,8 +536,9 @@ if triton.__version__ >= "2.1.0":
offs_d[None, :] * stride_v_cache_d +
(start_n + offs_n[:, None]) % block_size * stride_v_cache_bl)
k = tl.load(K_cache + off_k,
mask=(start_n + offs_n[None, :]) < cur_batch_ctx_len,
other=0.0)
mask=dim_mask[:, None] &
((start_n + offs_n[None, :]) < cur_batch_ctx_len),
other=0.0) # [D,N]
qk = tl.zeros([BLOCK_M, BLOCK_N], dtype=tl.float32)
qk += tl.dot(q, k)
......@@ -567,7 +572,8 @@ if triton.__version__ >= "2.1.0":
acc = acc * acc_scale[:, None]
# update acc
v = tl.load(V_cache + off_v,
mask=(start_n + offs_n[:, None]) < cur_batch_ctx_len,
mask=dim_mask[None, :] &
((start_n + offs_n[:, None]) < cur_batch_ctx_len),
other=0.0)
p = p.to(v.dtype)
......@@ -600,8 +606,9 @@ if triton.__version__ >= "2.1.0":
# -- compute qk ----
k = tl.load(k_ptrs +
(cur_batch_in_all_start_index + start_n) * stride_kbs,
mask=(start_n + offs_n[None, :]) <
cur_batch_seq_len - cur_batch_ctx_len,
mask=dim_mask[:, None] &
((start_n + offs_n[None, :]) <
cur_batch_seq_len - cur_batch_ctx_len),
other=0.0)
qk = tl.zeros([BLOCK_M, BLOCK_N], dtype=tl.float32)
......@@ -637,8 +644,9 @@ if triton.__version__ >= "2.1.0":
# update acc
v = tl.load(v_ptrs +
(cur_batch_in_all_start_index + start_n) * stride_vbs,
mask=(start_n + offs_n[:, None]) <
cur_batch_seq_len - cur_batch_ctx_len,
mask=dim_mask[None, :] &
((start_n + offs_n[:, None]) <
cur_batch_seq_len - cur_batch_ctx_len),
other=0.0)
p = p.to(v.dtype)
......@@ -656,7 +664,8 @@ if triton.__version__ >= "2.1.0":
out_ptrs = Out + off_o
tl.store(out_ptrs,
acc,
mask=offs_m[:, None] < cur_batch_seq_len - cur_batch_ctx_len)
mask=dim_mask[None, :] &
(offs_m[:, None] < cur_batch_seq_len - cur_batch_ctx_len))
return
@torch.inference_mode()
......@@ -688,9 +697,12 @@ if triton.__version__ >= "2.1.0":
grid = (batch, head, triton.cdiv(max_input_len, BLOCK)) # batch, head,
# 0 means "disable"
if sliding_window is None or sliding_window <= 0:
sliding_window = 0
num_warps = 8 if Lk <= 64 else 8
if alibi_slopes is not None:
assert Lk == Lk_padded
_fwd_kernel_alibi[grid](
q,
k,
......@@ -735,6 +747,7 @@ if triton.__version__ >= "2.1.0":
num_queries_per_kv=num_queries_per_kv,
BLOCK_M=BLOCK,
BLOCK_DMODEL=Lk,
BLOCK_DMODEL_PADDED=Lk_padded,
BLOCK_N=BLOCK,
num_warps=num_warps,
num_stages=1,
......@@ -785,7 +798,7 @@ if triton.__version__ >= "2.1.0":
BLOCK_DMODEL=Lk,
BLOCK_DMODEL_PADDED=Lk_padded,
BLOCK_N=BLOCK,
SLIDING_WINDOW=sliding_window if sliding_window is not None else 0,
SLIDING_WINDOW=sliding_window,
num_warps=num_warps,
num_stages=1,
)
......
vllm/attention/ops/triton_flash_attention.py
View file @ b9e12416
......@@ -239,6 +239,16 @@ def _attn_fwd_inner(
num_stages=1,
num_warps=8,
),
triton.Config(
{
"BLOCK_M": 128,
"BLOCK_N": 64,
"waves_per_eu": 1,
"PRE_LOAD_V": False,
},
num_stages=1,
num_warps=4,
),
triton.Config(
{
"BLOCK_M": 128,
......
vllm/attention/selector.py
View file @ b9e12416
import enum
from functools import lru_cache
from typing import Type
from typing import Optional, Type
import torch
......@@ -21,14 +21,33 @@ class _Backend(enum.Enum):
@lru_cache(maxsize=None)
def get_attn_backend(dtype: torch.dtype) -> Type[AttentionBackend]:
backend = _which_attn_to_use(dtype)
def get_attn_backend(
num_heads: int,
head_size: int,
num_kv_heads: int,
sliding_window: Optional[int],
dtype: torch.dtype,
kv_cache_dtype: Optional[str],
block_size: int,
is_blocksparse: bool = False,
) -> Type[AttentionBackend]:
if is_blocksparse:
logger.info("Using BlocksparseFlashAttention backend.")
from vllm.attention.backends.blocksparse_attn import (
BlocksparseFlashAttentionBackend)
return BlocksparseFlashAttentionBackend
"""Determine which attention backend to use and only import
the selected backend module.
"""
backend = which_attn_to_use(num_heads, head_size, num_kv_heads,
sliding_window, dtype, kv_cache_dtype,
block_size)
if backend == _Backend.FLASH_ATTN:
logger.info("Using FlashAttention-2 backend.")
from vllm.attention.backends.flash_attn import ( # noqa: F401
FlashAttentionBackend)
return FlashAttentionBackend
elif backend == _Backend.XFORMERS:
if backend == _Backend.XFORMERS:
logger.info("Using XFormers backend.")
from vllm.attention.backends.xformers import ( # noqa: F401
XFormersBackend)
......@@ -44,48 +63,102 @@ def get_attn_backend(dtype: torch.dtype) -> Type[AttentionBackend]:
return TorchSDPABackend
elif backend == _Backend.FLASHINFER:
logger.info("Using Flashinfer backend.")
logger.warning("Eager mode is enforced for the Flashinfer backend. ")
logger.warning("Eager mode is required for the Flashinfer backend. "
"Please make sure --enforce-eager is set.")
from vllm.attention.backends.flashinfer import FlashInferBackend
return FlashInferBackend
else:
raise ValueError("Invalid attention backend.")
def _which_attn_to_use(dtype: torch.dtype) -> _Backend:
def which_attn_to_use(
num_heads: int,
head_size: int,
num_kv_heads: int,
sliding_window: Optional[int],
dtype: torch.dtype,
kv_cache_dtype: Optional[str],
block_size: int,
) -> _Backend:
"""Returns which flash attention backend to use."""
# Default case.
selected_backend = _Backend.FLASH_ATTN
# Check the environment variable and override if specified
backend_by_env_var: Optional[str] = envs.VLLM_ATTENTION_BACKEND
if backend_by_env_var is not None:
backend_members = _Backend.__members__
if backend_by_env_var not in backend_members:
raise ValueError(
f"Invalid attention backend '{backend_by_env_var}'. "
f"Available backends: {', '.join(backend_members)} "
"(case-sensitive).")
selected_backend = _Backend[backend_by_env_var]
if is_cpu():
if selected_backend != _Backend.TORCH_SDPA:
logger.info("Cannot use %s backend on CPU.", selected_backend)
return _Backend.TORCH_SDPA
if is_hip():
# AMD GPUs.
if torch.cuda.get_device_capability()[0] != 9:
# not Instinct series GPUs.
logger.info("flash_atten is not supported on NAVI GPUs.")
selected_backend = (_Backend.ROCM_FLASH if selected_backend
== _Backend.FLASH_ATTN else selected_backend)
if selected_backend == _Backend.ROCM_FLASH:
if torch.cuda.get_device_capability()[0] != 9:
# not Instinct series GPUs.
logger.info("flash_attn is not supported on NAVI GPUs.")
else:
logger.info("%s is not supported in AMD GPUs.", selected_backend)
return _Backend.ROCM_FLASH
# NVIDIA GPUs.
if torch.cuda.get_device_capability()[0] < 8:
# Volta and Turing NVIDIA GPUs.
logger.info("Cannot use FlashAttention-2 backend for Volta and Turing "
"GPUs.")
return _Backend.XFORMERS
if dtype not in (torch.float16, torch.bfloat16):
logger.info("Cannot use FlashAttention-2 backend for dtype other than "
"torch.float16 or torch.bfloat16.")
return _Backend.XFORMERS
try:
import flash_attn # noqa: F401
except ImportError:
logger.info(
"Cannot use FlashAttention-2 backend because the flash_attn "
"package is not found. Please install it for better performance.")
return _Backend.XFORMERS
backend_by_env_var = envs.VLLM_ATTENTION_BACKEND
if backend_by_env_var is not None:
return _Backend[backend_by_env_var]
# FlashAttn in NVIDIA GPUs.
if selected_backend == _Backend.FLASH_ATTN:
if torch.cuda.get_device_capability()[0] < 8:
# Volta and Turing NVIDIA GPUs.
logger.info(
"Cannot use FlashAttention-2 backend for Volta and Turing "
"GPUs.")
selected_backend = _Backend.XFORMERS
elif dtype not in (torch.float16, torch.bfloat16):
logger.info(
"Cannot use FlashAttention-2 backend for dtype other than "
"torch.float16 or torch.bfloat16.")
selected_backend = _Backend.XFORMERS
elif kv_cache_dtype is not None and kv_cache_dtype.startswith("fp8"):
logger.info(
"Cannot use FlashAttention-2 backend for FP8 KV cache.")
selected_backend = _Backend.XFORMERS
elif block_size % 16 != 0:
logger.info(
"Cannot use FlashAttention-2 backend for block size not "
"divisible by 16.")
selected_backend = _Backend.XFORMERS
elif sliding_window is not None:
logger.info(
"Cannot use FlashAttention-2 backend due to sliding window.")
selected_backend = _Backend.XFORMERS
# Default case.
return _Backend.FLASH_ATTN
# FlashAttn is valid for the model, checking if the package is installed.
if selected_backend == _Backend.FLASH_ATTN:
try:
import vllm_flash_attn # noqa: F401
from vllm.attention.backends.flash_attn import ( # noqa: F401
FlashAttentionBackend)
supported_sizes = FlashAttentionBackend.get_supported_head_sizes()
if head_size not in supported_sizes:
logger.info(
"Cannot use FlashAttention-2 backend for head size %d.",
head_size)
selected_backend = _Backend.XFORMERS
except ImportError:
logger.info(
"Cannot use FlashAttention-2 backend because the "
"vllm_flash_attn package is not found. "
"`pip install vllm-flash-attn` for better performance.")
selected_backend = _Backend.XFORMERS
return selected_backend
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