Files
sglang/python/sglang/srt/mem_cache/memory_pool.py
zhangheng e4b708d3e9 [Spec V2] Support specV2 for mamba hybrid attention (#18808)
Co-authored-by: Yi Zhong <207368749+vincentzed@users.noreply.github.com>
Co-authored-by: yizhang2077 <1109276519@qq.com>
Co-authored-by: Hanming Lu <hanming@x.ai>
2026-02-27 00:36:01 +08:00

2031 lines
73 KiB
Python

"""
Copyright 2023-2024 SGLang Team
Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at
http://www.apache.org/licenses/LICENSE-2.0
Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License.
"""
from __future__ import annotations
"""
Memory pool.
SGLang has two levels of memory pool.
ReqToTokenPool maps a request to its token locations.
TokenToKVPoolAllocator manages the indices to kv cache data.
KVCache actually holds the physical kv cache.
"""
import abc
import dataclasses
import logging
from contextlib import contextmanager, nullcontext
from dataclasses import dataclass
from typing import TYPE_CHECKING, Any, List, Optional, Tuple, Union
import numpy as np
import torch
import triton
import triton.language as tl
from sglang.jit_kernel.kvcache import can_use_store_cache, store_cache
from sglang.srt.configs.mamba_utils import BaseLinearStateParams
from sglang.srt.constants import GPU_MEMORY_TYPE_KV_CACHE
from sglang.srt.environ import envs
from sglang.srt.layers.attention.nsa import index_buf_accessor
from sglang.srt.layers.attention.nsa.quant_k_cache import (
quantize_k_cache,
quantize_k_cache_separate,
)
from sglang.srt.layers.radix_attention import RadixAttention
from sglang.srt.mem_cache.utils import (
get_mla_kv_buffer_triton,
maybe_init_custom_mem_pool,
set_mla_kv_buffer_triton,
set_mla_kv_scale_buffer_triton,
)
from sglang.srt.utils import (
cpu_has_amx_support,
is_cpu,
is_cuda,
is_hip,
is_npu,
next_power_of_2,
)
from sglang.srt.utils.custom_op import register_custom_op
from sglang.srt.utils.torch_memory_saver_adapter import TorchMemorySaverAdapter
store_cache = register_custom_op(store_cache, mutates_args=["k_cache", "v_cache"])
if TYPE_CHECKING:
from sglang.srt.managers.cache_controller import LayerDoneCounter
from sglang.srt.managers.schedule_batch import Req
logger = logging.getLogger(__name__)
GB = 1024 * 1024 * 1024
_is_cuda = is_cuda()
_is_npu = is_npu()
_is_cpu = is_cpu()
_cpu_has_amx_support = cpu_has_amx_support()
_is_hip = is_hip()
def get_tensor_size_bytes(t: Union[torch.Tensor, List[torch.Tensor]]):
if isinstance(t, list):
return sum(get_tensor_size_bytes(x) for x in t)
return np.prod(t.shape) * t.dtype.itemsize
def _set_kv_buffer_impl(
k: torch.Tensor,
v: torch.Tensor,
k_cache: torch.Tensor,
v_cache: torch.Tensor,
indices: torch.Tensor,
row_dim: int, # head_num * head_dim
store_dtype: torch.dtype,
device_module: Any,
alt_stream: Optional[torch.cuda.Stream] = None,
same_kv_dim: bool = True,
) -> None:
row_bytes = row_dim * store_dtype.itemsize
if (_is_cuda or _is_hip) and same_kv_dim and can_use_store_cache(row_bytes):
return store_cache(
k.view(-1, row_dim),
v.view(-1, row_dim),
k_cache.view(-1, row_dim),
v_cache.view(-1, row_dim),
indices,
row_bytes=row_bytes,
)
from sglang.srt.model_executor.cuda_graph_runner import get_is_capture_mode
if get_is_capture_mode() and alt_stream is not None:
current_stream = device_module.current_stream()
alt_stream.wait_stream(current_stream)
k_cache[indices] = k
with device_module.stream(alt_stream):
v_cache[indices] = v
current_stream.wait_stream(alt_stream)
else: # fallback to naive implementation
k_cache[indices] = k
v_cache[indices] = v
class ReqToTokenPool:
"""A memory pool that maps a request to its token locations."""
def __init__(
self,
size: int,
max_context_len: int,
device: str,
enable_memory_saver: bool,
):
memory_saver_adapter = TorchMemorySaverAdapter.create(
enable=enable_memory_saver
)
self.size = size
self.max_context_len = max_context_len
self.device = device
with memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE):
self.req_to_token = torch.zeros(
(size, max_context_len), dtype=torch.int32, device=device
)
self.free_slots = list(range(size))
def write(self, indices, values):
self.req_to_token[indices] = values
def available_size(self):
return len(self.free_slots)
def alloc(self, reqs: list[Req]) -> Optional[List[int]]:
chunked = [i for i, r in enumerate(reqs) if r.req_pool_idx is not None]
if not any(r.is_dllm() for r in reqs):
assert (
len(chunked) <= 1
), "only one chunked request may reuse req_pool_idx in a batch"
assert all(
reqs[i].is_chunked > 0 or reqs[i].kv_committed_len > 0 for i in chunked
), "request has req_pool_idx but is not chunked"
need_size = len(reqs) - len(chunked)
if need_size > len(self.free_slots):
return None
select_index = self.free_slots[:need_size]
self.free_slots = self.free_slots[need_size:]
offset = 0
for r in reqs:
if r.req_pool_idx is None:
r.req_pool_idx = select_index[offset]
offset += 1
return [r.req_pool_idx for r in reqs]
def free(self, req: Req):
assert req.req_pool_idx is not None, "request must have req_pool_idx"
self.free_slots.append(req.req_pool_idx)
req.req_pool_idx = None
def clear(self):
self.free_slots = list(range(self.size))
class MambaPool:
@dataclass(frozen=True, kw_only=True)
class State:
conv: List[torch.Tensor]
temporal: torch.Tensor
def at_layer_idx(self, layer: int):
kwargs = {}
for k, v in vars(self).items():
if k == "conv" or k == "intermediate_conv_window":
kwargs[k] = [conv[layer] for conv in v]
else:
kwargs[k] = v[layer]
return type(self)(**kwargs)
def mem_usage_bytes(self):
return sum(
get_tensor_size_bytes(getattr(self, f.name))
for f in dataclasses.fields(self)
)
@dataclass(frozen=True, kw_only=True)
class SpeculativeState(State):
intermediate_ssm: torch.Tensor
intermediate_conv_window: List[torch.Tensor]
def __init__(
self,
*,
size: int,
spec_state_size: int,
cache_params: BaseLinearStateParams,
device: str,
enable_memory_saver: bool = False,
speculative_num_draft_tokens: Optional[int] = None,
):
conv_state_shape = cache_params.shape.conv
temporal_state_shape = cache_params.shape.temporal
conv_dtype = cache_params.dtype.conv
ssm_dtype = cache_params.dtype.temporal
self.memory_saver_adapter = TorchMemorySaverAdapter.create(
enable=enable_memory_saver
)
num_mamba_layers = len(cache_params.layers)
self.size = size
self.device = device
# for disagg with nvlink
self.enable_custom_mem_pool, self.custom_mem_pool, _ = (
maybe_init_custom_mem_pool(device=self.device)
)
with self.memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE), (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.enable_custom_mem_pool
else nullcontext()
):
conv_state = [
torch.zeros(
size=(num_mamba_layers, size + 1) + conv_shape,
dtype=conv_dtype,
device=device,
)
for conv_shape in conv_state_shape
]
if _is_cpu and _cpu_has_amx_support:
from sglang.srt.layers.amx_utils import _init_amx_conv_state
# CPU uses a different layout of conv_state for kernel optimization
conv_state = _init_amx_conv_state(conv_state)
temporal_state = torch.zeros(
size=(num_mamba_layers, size + 1) + temporal_state_shape,
dtype=ssm_dtype,
device=device,
)
if speculative_num_draft_tokens is not None:
# Cache intermediate SSM states per draft token during target verify
# Shape: [num_layers, size + 1, speculative_num_draft_tokens, HV, K, V]
intermediate_ssm_state_cache = torch.zeros(
size=(
num_mamba_layers,
spec_state_size + 1,
speculative_num_draft_tokens,
temporal_state_shape[0],
temporal_state_shape[1],
temporal_state_shape[2],
),
dtype=ssm_dtype,
device="cuda",
)
# Cache intermediate conv windows (last K-1 inputs) per draft token during target verify
# Shape: [num_layers, size + 1, speculative_num_draft_tokens, dim, K-1]
intermediate_conv_window_cache = [
torch.zeros(
size=(
num_mamba_layers,
spec_state_size + 1,
speculative_num_draft_tokens,
conv_shape[0],
conv_shape[1],
),
dtype=conv_dtype,
device="cuda",
)
for conv_shape in conv_state_shape
]
self.mamba_cache = self.SpeculativeState(
conv=conv_state,
temporal=temporal_state,
intermediate_ssm=intermediate_ssm_state_cache,
intermediate_conv_window=intermediate_conv_window_cache,
)
logger.info(
f"Mamba Cache is allocated. "
f"max_mamba_cache_size: {size}, "
f"conv_state size: {get_tensor_size_bytes(conv_state) / GB:.2f}GB, "
f"ssm_state size: {get_tensor_size_bytes(temporal_state) / GB:.2f}GB "
f"intermediate_ssm_state_cache size: {get_tensor_size_bytes(intermediate_ssm_state_cache) / GB:.2f}GB "
f"intermediate_conv_window_cache size: {get_tensor_size_bytes(intermediate_conv_window_cache) / GB:.2f}GB "
)
else:
self.mamba_cache = self.State(conv=conv_state, temporal=temporal_state)
logger.info(
f"Mamba Cache is allocated. "
f"max_mamba_cache_size: {size}, "
f"conv_state size: {get_tensor_size_bytes(conv_state) / GB:.2f}GB, "
f"ssm_state size: {get_tensor_size_bytes(temporal_state) / GB:.2f}GB "
)
# The padded slot 0 is used for writing dummy outputs from padded tokens.
self.free_slots = torch.arange(
1, self.size + 1, dtype=torch.int64, device=self.device
)
self.mem_usage = self.mamba_cache.mem_usage_bytes() / GB
self.num_mamba_layers = num_mamba_layers
def get_speculative_mamba2_params_all_layers(self) -> SpeculativeState:
assert isinstance(self.mamba_cache, self.SpeculativeState)
return self.mamba_cache
def mamba2_layer_cache(self, layer_id: int):
return self.mamba_cache.at_layer_idx(layer_id)
def available_size(self):
return len(self.free_slots)
def alloc(self, need_size: int) -> Optional[torch.Tensor]:
if need_size > len(self.free_slots):
return None
select_index = self.free_slots[:need_size]
self.free_slots = self.free_slots[need_size:]
# clear at alloc time, fill allocated slots with zeros
for i in range(len(self.mamba_cache.conv)):
self.mamba_cache.conv[i][:, select_index] = 0
self.mamba_cache.temporal[:, select_index] = 0
return select_index
def free(self, free_index: torch.Tensor):
if free_index.numel() == 0:
return
self.free_slots = torch.cat((self.free_slots, free_index))
def clear(self):
self.free_slots = torch.arange(
1, self.size + 1, dtype=torch.int64, device=self.device
)
def copy_from(self, src_index: torch.Tensor, dst_index: torch.Tensor):
for i in range(len(self.mamba_cache.conv)):
self.mamba_cache.conv[i][:, dst_index] = self.mamba_cache.conv[i][
:, src_index
]
self.mamba_cache.temporal[:, dst_index] = self.mamba_cache.temporal[
:, src_index
]
return
def fork_from(self, src_index: torch.Tensor) -> Optional[torch.Tensor]:
dst_index = self.alloc(1)
if dst_index == None:
return None
self.copy_from(src_index, dst_index)
return dst_index
def get_contiguous_buf_infos(self):
"""
Get buffer info for RDMA registration.
Only returns conv and temporal state buffers, excluding intermediate buffers
used for speculative decoding (intermediate_ssm, intermediate_conv_window).
"""
state_tensors = []
for field in vars(self.mamba_cache):
# Skip intermediate buffers used only for speculative decoding
# These buffers have different size (spec_state_size + 1) and should not be transferred
if field in ("intermediate_ssm", "intermediate_conv_window"):
continue
value = getattr(self.mamba_cache, field)
if isinstance(value, list):
state_tensors.extend(value)
else:
state_tensors.append(value)
data_ptrs, data_lens, item_lens = [], [], []
for _, state_tensor in enumerate(state_tensors):
data_ptrs += [
state_tensor[i].data_ptr() for i in range(self.num_mamba_layers)
]
data_lens += [state_tensor[i].nbytes for i in range(self.num_mamba_layers)]
item_lens += [
state_tensor[i][0].nbytes for i in range(self.num_mamba_layers)
]
return data_ptrs, data_lens, item_lens
def get_state_dim_per_tensor(self):
"""Get the sliceable dimension size for each state tensor.
For mamba state, the layout is:
- conv_state: [num_layers, size+1, conv_dim/tp, conv_kernel-1]
- temporal_state: [num_layers, size+1, num_heads/tp, head_dim, state_size]
The 3rd dimension (index 2) is the one that gets sliced by TP.
Returns the size of this dimension for each tensor (repeated for each layer).
"""
state_tensors = []
for field in vars(self.mamba_cache):
value = getattr(self.mamba_cache, field)
if isinstance(value, list):
state_tensors.extend(value)
else:
state_tensors.append(value)
dim_per_tensor = []
for state_tensor in state_tensors:
# state_tensor shape: [num_layers, size+1, sliceable_dim, ...]
# The sliceable dimension is at index 2 (after num_layers and size)
sliceable_dim = state_tensor.shape[2]
# Repeat for each layer since we have per-layer data_ptrs
dim_per_tensor += [sliceable_dim] * self.num_mamba_layers
return dim_per_tensor
class HybridReqToTokenPool(ReqToTokenPool):
"""A memory pool that maps a request to its token locations."""
def __init__(
self,
*,
size: int,
mamba_size: int,
mamba_spec_state_size: int,
max_context_len: int,
device: str,
enable_memory_saver: bool,
cache_params: BaseLinearStateParams,
enable_mamba_extra_buffer: bool,
speculative_num_draft_tokens: int = None,
enable_overlap_schedule: bool = True,
):
super().__init__(
size=size,
max_context_len=max_context_len,
device=device,
enable_memory_saver=enable_memory_saver,
)
if envs.SGLANG_ENABLE_SPEC_V2.get() and not enable_mamba_extra_buffer:
raise ValueError(
"Spec v2 requires mamba scheduler strategy `extra_buffer` for mamba models. "
"Please set `--mamba-scheduler-strategy extra_buffer`."
)
self.mamba_ping_pong_track_buffer_size = 2 if enable_overlap_schedule else 1
self.enable_mamba_extra_buffer = enable_mamba_extra_buffer
self.enable_memory_saver = enable_memory_saver
self._init_mamba_pool(
size=mamba_size,
mamba_spec_state_size=mamba_spec_state_size,
cache_params=cache_params,
device=device,
enable_mamba_extra_buffer=enable_mamba_extra_buffer,
speculative_num_draft_tokens=speculative_num_draft_tokens,
)
def _init_mamba_pool(
self,
size: int,
mamba_spec_state_size: int,
cache_params: BaseLinearStateParams,
device: str,
enable_mamba_extra_buffer: bool,
speculative_num_draft_tokens: int = None,
):
self.mamba_pool = MambaPool(
size=size,
spec_state_size=mamba_spec_state_size,
cache_params=cache_params,
device=device,
enable_memory_saver=self.enable_memory_saver,
speculative_num_draft_tokens=speculative_num_draft_tokens,
)
self.mamba_map = {layer_id: i for i, layer_id in enumerate(cache_params.layers)}
self.device = device
self.req_index_to_mamba_index_mapping: torch.Tensor = torch.zeros(
size, dtype=torch.int32, device=self.device
)
if enable_mamba_extra_buffer:
self.req_index_to_mamba_ping_pong_track_buffer_mapping: torch.Tensor = (
torch.zeros(
(size, self.mamba_ping_pong_track_buffer_size),
dtype=torch.int32,
device=self.device,
)
)
# For chunk prefill req, we do not need to allocate mamba cache,
# We could use allocated mamba cache instead.
def alloc(self, reqs: List["Req"]) -> Optional[List[int]]:
select_index = super().alloc(reqs)
if select_index is None:
return None
mamba_index = []
mamba_ping_pong_track_buffer_list = []
for req in reqs:
mid = None
if req.mamba_pool_idx is not None: # for radix cache
mid = req.mamba_pool_idx
else:
mid = self.mamba_pool.alloc(1)
assert (
mid is not None
), f"Not enough space for mamba cache, try to increase --mamba-full-memory-ratio or --max-mamba-cache-size. {mid=}, {self.mamba_pool.size=}, {self.mamba_pool.available_size()=}, {len(reqs)=}"
mid = mid[0]
req.mamba_pool_idx = mid
mamba_index.append(mid)
if self.enable_mamba_extra_buffer:
if req.mamba_ping_pong_track_buffer is None:
req.mamba_ping_pong_track_buffer = self.mamba_pool.alloc(
self.mamba_ping_pong_track_buffer_size
)
assert (
req.mamba_ping_pong_track_buffer is not None
), "Not enough space for mamba ping pong idx, try to increase --mamba-full-memory-ratio."
req.mamba_next_track_idx = 0
mamba_ping_pong_track_buffer_list.append(
req.mamba_ping_pong_track_buffer.tolist()
)
assert len(select_index) == len(
mamba_index
), f"Not enough space for mamba cache, try to increase --mamba-full-memory-ratio or --max-mamba-cache-size."
if self.enable_mamba_extra_buffer:
assert len(select_index) == len(
mamba_ping_pong_track_buffer_list
), f"Not enough space for mamba ping pong idx, try to increase --mamba-full-memory-ratio."
self.req_index_to_mamba_index_mapping[select_index] = torch.tensor(
mamba_index, dtype=torch.int32, device=self.device
)
if self.enable_mamba_extra_buffer:
self.req_index_to_mamba_ping_pong_track_buffer_mapping[select_index] = (
torch.tensor(
mamba_ping_pong_track_buffer_list,
dtype=torch.int32,
device=self.device,
)
)
return select_index
def get_mamba_indices(self, req_indices: torch.Tensor) -> torch.Tensor:
return self.req_index_to_mamba_index_mapping[req_indices]
def mamba2_layer_cache(self, layer_id: int):
assert layer_id in self.mamba_map
return self.mamba_pool.mamba2_layer_cache(self.mamba_map[layer_id])
def get_speculative_mamba2_params_all_layers(self) -> MambaPool.SpeculativeState:
return self.mamba_pool.get_speculative_mamba2_params_all_layers()
def get_mamba_ping_pong_other_idx(self, mamba_next_track_idx: int) -> int:
if self.mamba_ping_pong_track_buffer_size == 2:
return 1 - mamba_next_track_idx
else:
return mamba_next_track_idx
def free_mamba_cache(
self, req: "Req", mamba_ping_pong_track_buffer_to_keep: Optional[int] = None
):
mamba_index = req.mamba_pool_idx
assert mamba_index is not None, "double free? mamba_index is None"
self.mamba_pool.free(mamba_index.unsqueeze(0))
req.mamba_pool_idx = None
if self.enable_mamba_extra_buffer:
mamba_ping_pong_track_buffer_to_free = (
self.req_index_to_mamba_ping_pong_track_buffer_mapping[req.req_pool_idx]
)
if mamba_ping_pong_track_buffer_to_keep is not None:
assert mamba_ping_pong_track_buffer_to_keep in [
0,
1,
], f"mamba_ping_pong_track_buffer_to_keep must be 0 or 1, {mamba_ping_pong_track_buffer_to_keep=}"
idx_to_free = list(range(self.mamba_ping_pong_track_buffer_size))
idx_to_free.remove(mamba_ping_pong_track_buffer_to_keep)
mamba_ping_pong_track_buffer_to_free = (
mamba_ping_pong_track_buffer_to_free[idx_to_free]
)
self.mamba_pool.free(mamba_ping_pong_track_buffer_to_free)
def clear(self):
logger.info("Reset HybridReqToTokenPool")
super().clear()
self.mamba_pool.clear()
self.req_index_to_mamba_index_mapping.zero_()
if self.enable_mamba_extra_buffer:
self.req_index_to_mamba_ping_pong_track_buffer_mapping.zero_()
class KVCache(abc.ABC):
@abc.abstractmethod
def __init__(
self,
size: int,
page_size: int,
dtype: torch.dtype,
layer_num: int,
device: str,
enable_memory_saver: bool,
start_layer: Optional[int] = None,
end_layer: Optional[int] = None,
):
self.size = size
self.page_size = page_size
self.dtype = dtype
self.device = device
if dtype in (torch.float8_e5m2, torch.float8_e4m3fn):
# NOTE: Store as torch.uint8 because Tensor.index_put is not implemented for torch.float8_e5m2
self.store_dtype = torch.uint8
else:
self.store_dtype = dtype
self.layer_num = layer_num
self.start_layer = start_layer or 0
self.end_layer = end_layer or layer_num - 1
self.memory_saver_adapter = TorchMemorySaverAdapter.create(
enable=enable_memory_saver
)
self.mem_usage = 0
# used for chunked cpu-offloading
self.cpu_offloading_chunk_size = 8192
# default state for optional layer-wise transfer control
self.layer_transfer_counter = None
# for disagg with nvlink
self.enable_custom_mem_pool, self.custom_mem_pool, _ = (
maybe_init_custom_mem_pool(device=self.device)
)
def _finalize_allocation_log(self, num_tokens: int):
"""Common logging and mem_usage computation for KV cache allocation.
Supports both tuple (K, V) size returns and single KV size returns.
"""
kv_size_bytes = self.get_kv_size_bytes()
if isinstance(kv_size_bytes, tuple):
k_size, v_size = kv_size_bytes
k_size_GB = k_size / GB
v_size_GB = v_size / GB
logger.info(
f"KV Cache is allocated. #tokens: {num_tokens}, K size: {k_size_GB:.2f} GB, V size: {v_size_GB:.2f} GB"
)
self.mem_usage = k_size_GB + v_size_GB
else:
kv_size_GB = kv_size_bytes / GB
logger.info(
f"KV Cache is allocated. #tokens: {num_tokens}, KV size: {kv_size_GB:.2f} GB"
)
self.mem_usage = kv_size_GB
@abc.abstractmethod
def get_key_buffer(self, layer_id: int) -> torch.Tensor:
raise NotImplementedError()
@abc.abstractmethod
def get_value_buffer(self, layer_id: int) -> torch.Tensor:
raise NotImplementedError()
@abc.abstractmethod
def get_kv_buffer(self, layer_id: int) -> Tuple[torch.Tensor, torch.Tensor]:
raise NotImplementedError()
@abc.abstractmethod
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
) -> None:
raise NotImplementedError()
def register_layer_transfer_counter(self, layer_transfer_counter: LayerDoneCounter):
self.layer_transfer_counter = layer_transfer_counter
def get_cpu_copy(self, indices):
raise NotImplementedError()
def load_cpu_copy(self, kv_cache_cpu, indices):
raise NotImplementedError()
def maybe_get_custom_mem_pool(self):
return self.custom_mem_pool
class MHATokenToKVPool(KVCache):
def __init__(
self,
size: int,
page_size: int,
dtype: torch.dtype,
head_num: int,
head_dim: int,
layer_num: int,
device: str,
enable_memory_saver: bool,
v_head_dim: Optional[int] = None,
swa_head_num: Optional[int] = None,
swa_head_dim: Optional[int] = None,
swa_v_head_dim: Optional[int] = None,
start_layer: Optional[int] = None,
end_layer: Optional[int] = None,
enable_alt_stream: bool = True,
enable_kv_cache_copy: bool = False,
):
super().__init__(
size,
page_size,
dtype,
layer_num,
device,
enable_memory_saver,
start_layer,
end_layer,
)
self.head_num = swa_head_num if swa_head_num is not None else head_num
self.head_dim = swa_head_dim if swa_head_dim is not None else head_dim
self.v_head_dim = (
swa_v_head_dim
if swa_v_head_dim is not None
else v_head_dim if v_head_dim is not None else head_dim
)
self._create_buffers()
self.device_module = torch.get_device_module(self.device)
self.alt_stream = (
self.device_module.Stream() if _is_cuda and enable_alt_stream else None
)
if enable_kv_cache_copy:
self._init_kv_copy_and_warmup()
else:
self._kv_copy_config = None
self._finalize_allocation_log(size)
# for store_cache JIT kernel
self.row_dim = self.head_num * self.head_dim
self.same_kv_dim = self.head_dim == self.v_head_dim
def _init_kv_copy_and_warmup(self):
# Heuristics for KV copy tiling
_KV_COPY_STRIDE_THRESHOLD_LARGE = 8192
_KV_COPY_STRIDE_THRESHOLD_MEDIUM = 4096
_KV_COPY_TILE_SIZE_LARGE = 512
_KV_COPY_TILE_SIZE_MEDIUM = 256
_KV_COPY_TILE_SIZE_SMALL = 128
_KV_COPY_NUM_WARPS_LARGE_TILE = 8
_KV_COPY_NUM_WARPS_SMALL_TILE = 4
stride_bytes = int(self.data_strides[0].item())
if stride_bytes >= _KV_COPY_STRIDE_THRESHOLD_LARGE:
bytes_per_tile = _KV_COPY_TILE_SIZE_LARGE
elif stride_bytes >= _KV_COPY_STRIDE_THRESHOLD_MEDIUM:
bytes_per_tile = _KV_COPY_TILE_SIZE_MEDIUM
else:
bytes_per_tile = _KV_COPY_TILE_SIZE_SMALL
# Calculate num_locs_upper to avoid large Triton specialization (e.g. 8192)
chunk_upper = 128 if bytes_per_tile >= _KV_COPY_TILE_SIZE_LARGE else 256
self._kv_copy_config = {
"bytes_per_tile": bytes_per_tile,
"byte_tiles": (stride_bytes + bytes_per_tile - 1) // bytes_per_tile,
"num_warps": (
_KV_COPY_NUM_WARPS_SMALL_TILE
if bytes_per_tile <= _KV_COPY_TILE_SIZE_MEDIUM
else _KV_COPY_NUM_WARPS_LARGE_TILE
),
"num_locs_upper": chunk_upper,
}
dummy_loc = torch.zeros(chunk_upper, dtype=torch.int64, device=self.device)
grid = (self.data_ptrs.numel(), self._kv_copy_config["byte_tiles"])
copy_all_layer_kv_cache_tiled[grid](
self.data_ptrs,
self.data_strides,
dummy_loc,
dummy_loc,
1,
chunk_upper,
BYTES_PER_TILE=self._kv_copy_config["bytes_per_tile"],
num_warps=self._kv_copy_config["num_warps"],
num_stages=2,
)
def _create_buffers(self):
with self.memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE):
with (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.enable_custom_mem_pool
else nullcontext()
):
# [size, head_num, head_dim] for each layer
# The padded slot 0 is used for writing dummy outputs from padded tokens.
self.k_buffer = [
torch.zeros(
(self.size + self.page_size, self.head_num, self.head_dim),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
self.v_buffer = [
torch.zeros(
(self.size + self.page_size, self.head_num, self.v_head_dim),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
self.k_data_ptrs = torch.tensor(
[x.data_ptr() for x in self.k_buffer],
dtype=torch.uint64,
device=self.device,
)
self.v_data_ptrs = torch.tensor(
[x.data_ptr() for x in self.v_buffer],
dtype=torch.uint64,
device=self.device,
)
self.data_ptrs = torch.cat([self.k_data_ptrs, self.v_data_ptrs], dim=0)
self.data_strides = torch.tensor(
[
np.prod(x.shape[1:]) * x.dtype.itemsize
for x in self.k_buffer + self.v_buffer
],
device=self.device,
)
def _clear_buffers(self):
del self.k_buffer
del self.v_buffer
def get_kv_size_bytes(self):
assert hasattr(self, "k_buffer")
assert hasattr(self, "v_buffer")
k_size_bytes = 0
for k_cache in self.k_buffer:
k_size_bytes += get_tensor_size_bytes(k_cache)
v_size_bytes = 0
for v_cache in self.v_buffer:
v_size_bytes += get_tensor_size_bytes(v_cache)
return k_size_bytes, v_size_bytes
# for disagg
def get_contiguous_buf_infos(self):
# layer_num x [seq_len, head_num, head_dim]
# layer_num x [page_num, page_size, head_num, head_dim]
kv_data_ptrs = [
self._get_key_buffer(i).data_ptr()
for i in range(self.start_layer, self.start_layer + self.layer_num)
] + [
self._get_value_buffer(i).data_ptr()
for i in range(self.start_layer, self.start_layer + self.layer_num)
]
kv_data_lens = [
self._get_key_buffer(i).nbytes
for i in range(self.start_layer, self.start_layer + self.layer_num)
] + [
self._get_value_buffer(i).nbytes
for i in range(self.start_layer, self.start_layer + self.layer_num)
]
kv_item_lens = [
self._get_key_buffer(i)[0].nbytes * self.page_size
for i in range(self.start_layer, self.start_layer + self.layer_num)
] + [
self._get_value_buffer(i)[0].nbytes * self.page_size
for i in range(self.start_layer, self.start_layer + self.layer_num)
]
return kv_data_ptrs, kv_data_lens, kv_item_lens
def get_cpu_copy(self, indices):
torch.cuda.synchronize()
kv_cache_cpu = []
chunk_size = self.cpu_offloading_chunk_size
for layer_id in range(self.layer_num):
kv_cache_cpu.append([])
for i in range(0, len(indices), chunk_size):
chunk_indices = indices[i : i + chunk_size]
k_cpu = self.k_buffer[layer_id][chunk_indices].to(
"cpu", non_blocking=True
)
v_cpu = self.v_buffer[layer_id][chunk_indices].to(
"cpu", non_blocking=True
)
kv_cache_cpu[-1].append([k_cpu, v_cpu])
torch.cuda.synchronize()
return kv_cache_cpu
def load_cpu_copy(self, kv_cache_cpu, indices):
torch.cuda.synchronize()
chunk_size = self.cpu_offloading_chunk_size
for layer_id in range(self.layer_num):
for i in range(0, len(indices), chunk_size):
chunk_indices = indices[i : i + chunk_size]
k_cpu, v_cpu = (
kv_cache_cpu[layer_id][i // chunk_size][0],
kv_cache_cpu[layer_id][i // chunk_size][1],
)
assert k_cpu.shape[0] == v_cpu.shape[0] == len(chunk_indices)
k_chunk = k_cpu.to(self.k_buffer[0].device, non_blocking=True)
v_chunk = v_cpu.to(self.v_buffer[0].device, non_blocking=True)
self.k_buffer[layer_id][chunk_indices] = k_chunk
self.v_buffer[layer_id][chunk_indices] = v_chunk
torch.cuda.synchronize()
def _get_key_buffer(self, layer_id: int):
# for internal use of referencing
if self.store_dtype != self.dtype:
return self.k_buffer[layer_id - self.start_layer].view(self.dtype)
return self.k_buffer[layer_id - self.start_layer]
def get_key_buffer(self, layer_id: int):
# note: get_key_buffer is hooked with synchronization for layer-wise KV cache loading
# it is supposed to be used only by attention backend not for information purpose
# same applies to get_value_buffer and get_kv_buffer
if self.layer_transfer_counter is not None:
self.layer_transfer_counter.wait_until(layer_id - self.start_layer)
return self._get_key_buffer(layer_id)
def _get_value_buffer(self, layer_id: int):
# for internal use of referencing
if self.store_dtype != self.dtype:
return self.v_buffer[layer_id - self.start_layer].view(self.dtype)
return self.v_buffer[layer_id - self.start_layer]
def get_value_buffer(self, layer_id: int):
if self.layer_transfer_counter is not None:
self.layer_transfer_counter.wait_until(layer_id - self.start_layer)
return self._get_value_buffer(layer_id)
def get_kv_buffer(self, layer_id: int):
return self.get_key_buffer(layer_id), self.get_value_buffer(layer_id)
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
k_scale: Optional[float] = None,
v_scale: Optional[float] = None,
layer_id_override: Optional[int] = None,
):
if layer_id_override is not None:
layer_id = layer_id_override
else:
layer_id = layer.layer_id
if cache_k.dtype != self.dtype:
if k_scale is not None:
cache_k.div_(k_scale)
if v_scale is not None:
cache_v.div_(v_scale)
cache_k = cache_k.to(self.dtype)
cache_v = cache_v.to(self.dtype)
if self.store_dtype != self.dtype:
cache_k = cache_k.view(self.store_dtype)
cache_v = cache_v.view(self.store_dtype)
_set_kv_buffer_impl(
cache_k,
cache_v,
self.k_buffer[layer_id - self.start_layer],
self.v_buffer[layer_id - self.start_layer],
loc,
row_dim=self.row_dim,
store_dtype=self.store_dtype,
device_module=self.device_module,
alt_stream=self.alt_stream,
same_kv_dim=self.same_kv_dim,
)
def move_kv_cache(self, tgt_loc: torch.Tensor, src_loc: torch.Tensor):
if envs.SGLANG_NATIVE_MOVE_KV_CACHE.get():
move_kv_cache_native(self.k_buffer, self.v_buffer, tgt_loc, src_loc)
return
N = tgt_loc.numel()
if N == 0:
return
assert (
self._kv_copy_config is not None
), "KV copy not initialized. Set enable_kv_cache_copy=True in __init__"
cfg = self._kv_copy_config
cap = int(cfg.get("num_locs_upper", 256))
grid = (self.data_ptrs.numel(), cfg["byte_tiles"])
if N <= cap:
upper = next_power_of_2(N)
copy_all_layer_kv_cache_tiled[grid](
self.data_ptrs,
self.data_strides,
tgt_loc,
src_loc,
N,
upper,
BYTES_PER_TILE=cfg["bytes_per_tile"],
num_warps=cfg["num_warps"],
num_stages=2,
)
return
# Huge N: chunk, but each chunk's upper is still pow2(<= cap)
for start in range(0, N, cap):
end = min(start + cap, N)
chunk_len = end - start
upper = next_power_of_2(chunk_len)
copy_all_layer_kv_cache_tiled[grid](
self.data_ptrs,
self.data_strides,
tgt_loc[start:end],
src_loc[start:end],
chunk_len,
upper,
BYTES_PER_TILE=cfg["bytes_per_tile"],
num_warps=cfg["num_warps"],
num_stages=2,
)
class MHATokenToKVPoolFP4(MHATokenToKVPool):
def _create_buffers(self):
with self.memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE):
with (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.enable_custom_mem_pool
else nullcontext()
):
# [size, head_num, head_dim] for each layer
# The padded slot 0 is used for writing dummy outputs from padded tokens.
m = self.size + self.page_size
n = self.head_num
k = self.head_dim
scale_block_size = 16
self.store_dtype = torch.uint8
self.k_buffer = [
torch.zeros(
(m, n, k // 2),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
self.v_buffer = [
torch.zeros(
(m, n, k // 2),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
self.k_scale_buffer = [
torch.zeros(
(m, (n * k) // scale_block_size),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
self.v_scale_buffer = [
torch.zeros(
(m, (n * k) // scale_block_size),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
def _clear_buffers(self):
del self.k_buffer
del self.v_buffer
del self.k_scale_buffer
del self.v_scale_buffer
def _get_key_buffer(self, layer_id: int):
# for internal use of referencing
if self.store_dtype != self.dtype:
cache_k_nope_fp4 = self.k_buffer[layer_id - self.start_layer].view(
torch.uint8
)
cache_k_nope_fp4_sf = self.k_scale_buffer[layer_id - self.start_layer]
from sglang.srt.layers.quantization.kvfp4_tensor import KVFP4QuantizeUtil
cache_k_nope_fp4_dequant = KVFP4QuantizeUtil.batched_dequantize(
cache_k_nope_fp4, cache_k_nope_fp4_sf
)
return cache_k_nope_fp4_dequant
return self.k_buffer[layer_id - self.start_layer]
def _get_value_buffer(self, layer_id: int):
# for internal use of referencing
if self.store_dtype != self.dtype:
cache_v_nope_fp4 = self.v_buffer[layer_id - self.start_layer].view(
torch.uint8
)
cache_v_nope_fp4_sf = self.v_scale_buffer[layer_id - self.start_layer]
from sglang.srt.layers.quantization.kvfp4_tensor import KVFP4QuantizeUtil
cache_v_nope_fp4_dequant = KVFP4QuantizeUtil.batched_dequantize(
cache_v_nope_fp4, cache_v_nope_fp4_sf
)
return cache_v_nope_fp4_dequant
return self.v_buffer[layer_id - self.start_layer]
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
k_scale: Optional[float] = None,
v_scale: Optional[float] = None,
layer_id_override: Optional[int] = None,
):
from sglang.srt.model_executor.cuda_graph_runner import get_is_capture_mode
if layer_id_override is not None:
layer_id = layer_id_override
else:
layer_id = layer.layer_id
if cache_k.dtype != self.dtype:
if k_scale is not None:
cache_k.div_(k_scale)
if v_scale is not None:
cache_v.div_(v_scale)
from sglang.srt.layers.quantization.kvfp4_tensor import KVFP4QuantizeUtil
cache_k, cache_k_fp4_sf = KVFP4QuantizeUtil.batched_quantize(cache_k)
cache_v, cache_v_fp4_sf = KVFP4QuantizeUtil.batched_quantize(cache_v)
if self.store_dtype != self.dtype:
cache_k = cache_k.view(self.store_dtype)
cache_v = cache_v.view(self.store_dtype)
cache_k_fp4_sf = cache_k_fp4_sf.view(self.store_dtype)
cache_v_fp4_sf = cache_v_fp4_sf.view(self.store_dtype)
if get_is_capture_mode() and self.alt_stream is not None:
# Overlap the copy of K and V cache for small batch size
current_stream = self.device_module.current_stream()
self.alt_stream.wait_stream(current_stream)
self.k_buffer[layer_id - self.start_layer][loc] = cache_k
self.k_scale_buffer[layer_id - self.start_layer][loc] = cache_k_fp4_sf
with self.device_module.stream(self.alt_stream):
self.v_buffer[layer_id - self.start_layer][loc] = cache_v
self.v_scale_buffer[layer_id - self.start_layer][loc] = cache_v_fp4_sf
current_stream.wait_stream(self.alt_stream)
else:
self.k_buffer[layer_id - self.start_layer][loc] = cache_k
self.v_buffer[layer_id - self.start_layer][loc] = cache_v
self.k_scale_buffer[layer_id - self.start_layer][loc] = cache_k_fp4_sf
self.v_scale_buffer[layer_id - self.start_layer][loc] = cache_v_fp4_sf
class HybridLinearKVPool(KVCache):
"""KV cache with separate pools for full and linear attention layers."""
def __init__(
self,
size: int,
dtype: torch.dtype,
page_size: int,
head_num: int,
head_dim: int,
full_attention_layer_ids: List[int],
enable_kvcache_transpose: bool,
device: str,
mamba_pool: MambaPool,
enable_memory_saver: bool = False,
# TODO: refactor mla related args
use_mla: bool = False,
kv_lora_rank: int = None,
qk_rope_head_dim: int = None,
):
self.size = size
self.dtype = dtype
self.device = device
self.full_layer_nums = len(full_attention_layer_ids)
self.page_size = page_size
# TODO support pp?
self.start_layer = 0
self.head_num = head_num
self.head_dim = head_dim
self.mamba_pool = mamba_pool
# TODO MHATransposedTokenToKVPool if enable_kvcache_transpose is True
assert not enable_kvcache_transpose
self.use_mla = use_mla
if not use_mla:
TokenToKVPoolClass = MHATokenToKVPool
if _is_npu:
from sglang.srt.hardware_backend.npu.memory_pool_npu import (
NPUMHATokenToKVPool,
)
TokenToKVPoolClass = NPUMHATokenToKVPool
self.full_kv_pool = TokenToKVPoolClass(
size=size,
page_size=self.page_size,
dtype=dtype,
head_num=head_num,
head_dim=head_dim,
layer_num=self.full_layer_nums,
device=device,
enable_memory_saver=enable_memory_saver,
)
else:
TokenToKVPoolClass = MLATokenToKVPool
if _is_npu:
from sglang.srt.hardware_backend.npu.memory_pool_npu import (
NPUMLATokenToKVPool,
)
TokenToKVPoolClass = NPUMLATokenToKVPool
self.full_kv_pool = TokenToKVPoolClass(
size=size,
page_size=self.page_size,
dtype=dtype,
layer_num=self.full_layer_nums,
device=device,
kv_lora_rank=kv_lora_rank,
qk_rope_head_dim=qk_rope_head_dim,
enable_memory_saver=enable_memory_saver,
)
self.full_attention_layer_id_mapping = {
id: i for i, id in enumerate(full_attention_layer_ids)
}
if use_mla:
self.mem_usage = self.get_kv_size_bytes() / GB
else:
k_size, v_size = self.get_kv_size_bytes()
self.mem_usage = (k_size + v_size) / GB
def get_kv_size_bytes(self):
return self.full_kv_pool.get_kv_size_bytes()
def get_contiguous_buf_infos(self):
return self.full_kv_pool.get_contiguous_buf_infos()
def get_state_buf_infos(self):
mamba_data_ptrs, mamba_data_lens, mamba_item_lens = (
self.mamba_pool.get_contiguous_buf_infos()
)
return mamba_data_ptrs, mamba_data_lens, mamba_item_lens
def get_state_dim_per_tensor(self):
"""Get the sliceable dimension size for each mamba state tensor."""
return self.mamba_pool.get_state_dim_per_tensor()
def maybe_get_custom_mem_pool(self):
return self.full_kv_pool.maybe_get_custom_mem_pool()
def _transfer_full_attention_id(self, layer_id: int):
if layer_id not in self.full_attention_layer_id_mapping:
raise ValueError(
f"{layer_id=} not in full attention layers: {self.full_attention_layer_id_mapping.keys()}"
)
return self.full_attention_layer_id_mapping[layer_id]
def get_key_buffer(self, layer_id: int):
layer_id = self._transfer_full_attention_id(layer_id)
return self.full_kv_pool.get_key_buffer(layer_id)
def get_value_buffer(self, layer_id: int):
layer_id = self._transfer_full_attention_id(layer_id)
return self.full_kv_pool.get_value_buffer(layer_id)
def get_kv_buffer(self, layer_id: int):
layer_id = self._transfer_full_attention_id(layer_id)
return self.full_kv_pool.get_kv_buffer(layer_id)
@contextmanager
def _transfer_id_context(self, layer: RadixAttention):
@contextmanager
def _patch_layer_id(layer):
original_layer_id = layer.layer_id
layer.layer_id = self._transfer_full_attention_id(layer.layer_id)
try:
yield
finally:
layer.layer_id = original_layer_id
with _patch_layer_id(layer):
yield
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
k_scale: float = 1.0,
v_scale: float = 1.0,
):
layer_id = self._transfer_full_attention_id(layer.layer_id)
if not self.use_mla:
self.full_kv_pool.set_kv_buffer(
None,
loc,
cache_k,
cache_v,
k_scale,
v_scale,
layer_id_override=layer_id,
)
else:
with self._transfer_id_context(layer):
self.full_kv_pool.set_kv_buffer(
layer,
loc,
cache_k,
cache_v,
)
def move_kv_cache(self, tgt_loc: torch.Tensor, src_loc: torch.Tensor):
self.full_kv_pool.move_kv_cache(tgt_loc, src_loc)
def get_v_head_dim(self):
return self.full_kv_pool.get_value_buffer(0).shape[-1]
def set_mla_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k_nope: torch.Tensor,
cache_k_rope: torch.Tensor,
):
assert self.use_mla, "set_mla_kv_buffer called when use_mla is False"
with self._transfer_id_context(layer):
self.full_kv_pool.set_mla_kv_buffer(layer, loc, cache_k_nope, cache_k_rope)
def get_mla_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
dst_dtype: Optional[torch.dtype] = None,
):
assert self.use_mla, "get_mla_kv_buffer called when use_mla is False"
with self._transfer_id_context(layer):
return self.full_kv_pool.get_mla_kv_buffer(layer, loc, dst_dtype)
class MLATokenToKVPool(KVCache):
def __init__(
self,
size: int,
page_size: int,
dtype: torch.dtype,
kv_lora_rank: int,
qk_rope_head_dim: int,
layer_num: int,
device: str,
enable_memory_saver: bool,
start_layer: Optional[int] = None,
end_layer: Optional[int] = None,
use_nsa: bool = False,
override_kv_cache_dim: Optional[int] = None,
):
super().__init__(
size,
page_size,
dtype,
layer_num,
device,
enable_memory_saver,
start_layer,
end_layer,
)
self.kv_lora_rank = kv_lora_rank
self.qk_rope_head_dim = qk_rope_head_dim
self.use_nsa = use_nsa
self.nsa_kv_cache_store_fp8 = (
use_nsa
and dtype == torch.float8_e4m3fn
and override_kv_cache_dim is not None
)
# When override_kv_cache_dim is provided with nsa model, we assume the
# override kv cache dim is correct and use it directly.
self.kv_cache_dim = (
override_kv_cache_dim
if self.nsa_kv_cache_store_fp8
else (kv_lora_rank + qk_rope_head_dim)
)
self._create_buffers()
self.data_ptrs = torch.tensor(
[x.data_ptr() for x in self.kv_buffer],
dtype=torch.uint64,
device=self.device,
)
if not use_nsa:
# NSA will allocate indexer KV cache later and then log the total size
self._finalize_allocation_log(size)
def _create_buffers(self):
with self.memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE):
with (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.custom_mem_pool
else nullcontext()
):
# The padded slot 0 is used for writing dummy outputs from padded tokens.
self.kv_buffer = [
torch.zeros(
(self.size + self.page_size, 1, self.kv_cache_dim),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
def _clear_buffers(self):
del self.kv_buffer
def get_kv_size_bytes(self):
assert hasattr(self, "kv_buffer")
kv_size_bytes = 0
for kv_cache in self.kv_buffer:
kv_size_bytes += get_tensor_size_bytes(kv_cache)
return kv_size_bytes
# for disagg
def get_contiguous_buf_infos(self):
# MLA has only one kv_buffer, so only the information of this buffer needs to be returned.
kv_data_ptrs = [self.kv_buffer[i].data_ptr() for i in range(self.layer_num)]
kv_data_lens = [self.kv_buffer[i].nbytes for i in range(self.layer_num)]
kv_item_lens = [
self.kv_buffer[i][0].nbytes * self.page_size for i in range(self.layer_num)
]
return kv_data_ptrs, kv_data_lens, kv_item_lens
def get_key_buffer(self, layer_id: int):
if self.layer_transfer_counter is not None:
self.layer_transfer_counter.wait_until(layer_id - self.start_layer)
if self.store_dtype != self.dtype:
return self.kv_buffer[layer_id - self.start_layer].view(self.dtype)
return self.kv_buffer[layer_id - self.start_layer]
def get_value_buffer(self, layer_id: int):
if self.layer_transfer_counter is not None:
self.layer_transfer_counter.wait_until(layer_id - self.start_layer)
if self.store_dtype != self.dtype:
return self.kv_buffer[layer_id - self.start_layer][
..., : self.kv_lora_rank
].view(self.dtype)
return self.kv_buffer[layer_id - self.start_layer][..., : self.kv_lora_rank]
def get_kv_buffer(self, layer_id: int):
return self.get_key_buffer(layer_id), self.get_value_buffer(layer_id)
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
):
layer_id = layer.layer_id
assert not self.nsa_kv_cache_store_fp8
if cache_k.dtype != self.dtype:
cache_k = cache_k.to(self.dtype)
if self.store_dtype != self.dtype:
self.kv_buffer[layer_id - self.start_layer][loc] = cache_k.view(
self.store_dtype
)
else:
self.kv_buffer[layer_id - self.start_layer][loc] = cache_k
def set_mla_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k_nope: torch.Tensor,
cache_k_rope: torch.Tensor,
):
layer_id = layer.layer_id
if self.nsa_kv_cache_store_fp8:
# OPTIMIZATION: Quantize k_nope and k_rope separately to avoid concat overhead
# This also enables reuse of set_mla_kv_buffer_triton two-tensor write path
# quantize_k_cache_separate returns (nope_part, rope_part) as uint8 bytes
cache_k_nope_fp8, cache_k_rope_fp8 = quantize_k_cache_separate(
cache_k_nope, cache_k_rope
)
# Reuse existing two-tensor write kernel (works with FP8 byte layout)
# cache_k_nope_fp8: (num_tokens, 1, 528) uint8 [nope_fp8(512) | scales(16)]
# cache_k_rope_fp8: (num_tokens, 1, 128) uint8 [rope_bf16_bytes(128)]
set_mla_kv_buffer_triton(
self.kv_buffer[layer_id - self.start_layer],
loc,
cache_k_nope_fp8,
cache_k_rope_fp8,
)
else:
if cache_k_nope.dtype != self.dtype:
cache_k_nope = cache_k_nope.to(self.dtype)
cache_k_rope = cache_k_rope.to(self.dtype)
if self.store_dtype != self.dtype:
cache_k_nope = cache_k_nope.view(self.store_dtype)
cache_k_rope = cache_k_rope.view(self.store_dtype)
set_mla_kv_buffer_triton(
self.kv_buffer[layer_id - self.start_layer],
loc,
cache_k_nope,
cache_k_rope,
)
def get_mla_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
dst_dtype: Optional[torch.dtype] = None,
):
# get k nope and k rope from the kv buffer, and optionally cast them to dst_dtype.
layer_id = layer.layer_id
kv_buffer = self.get_key_buffer(layer_id)
dst_dtype = dst_dtype or self.dtype
cache_k_nope = torch.empty(
(loc.shape[0], 1, self.kv_lora_rank),
dtype=dst_dtype,
device=kv_buffer.device,
)
cache_k_rope = torch.empty(
(loc.shape[0], 1, self.qk_rope_head_dim),
dtype=dst_dtype,
device=kv_buffer.device,
)
get_mla_kv_buffer_triton(kv_buffer, loc, cache_k_nope, cache_k_rope)
return cache_k_nope, cache_k_rope
def get_cpu_copy(self, indices):
torch.cuda.synchronize()
kv_cache_cpu = []
chunk_size = self.cpu_offloading_chunk_size
for layer_id in range(self.layer_num):
kv_cache_cpu.append([])
for i in range(0, len(indices), chunk_size):
chunk_indices = indices[i : i + chunk_size]
kv_cpu = self.kv_buffer[layer_id][chunk_indices].to(
"cpu", non_blocking=True
)
kv_cache_cpu[-1].append(kv_cpu)
torch.cuda.synchronize()
return kv_cache_cpu
def load_cpu_copy(self, kv_cache_cpu, indices):
torch.cuda.synchronize()
chunk_size = self.cpu_offloading_chunk_size
for layer_id in range(self.layer_num):
for i in range(0, len(indices), chunk_size):
chunk_indices = indices[i : i + chunk_size]
kv_cpu = kv_cache_cpu[layer_id][i // chunk_size]
assert kv_cpu.shape[0] == len(chunk_indices)
kv_chunk = kv_cpu.to(self.kv_buffer[0].device, non_blocking=True)
self.kv_buffer[layer_id][chunk_indices] = kv_chunk
torch.cuda.synchronize()
class MLATokenToKVPoolFP4(MLATokenToKVPool):
def _create_buffers(self):
with self.memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE):
with (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.custom_mem_pool
else nullcontext()
):
# The padded slot 0 is used for writing dummy outputs from padded tokens.
m = self.size + self.page_size
n = 1 # head_num
k = self.kv_cache_dim # head_dim
scale_block_size = 16
self.store_dtype = torch.uint8
self.kv_buffer = [
torch.zeros(
(m, n, k // 2),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
self.kv_scale_buffer = [
torch.zeros(
(m, k // scale_block_size),
dtype=self.store_dtype,
device=self.device,
)
for _ in range(self.layer_num)
]
def _clear_buffers(self):
del self.kv_buffer
del self.kv_scale_buffer
def get_key_buffer(self, layer_id: int):
if self.layer_transfer_counter is not None:
self.layer_transfer_counter.wait_until(layer_id - self.start_layer)
if self.store_dtype != self.dtype:
cache_k_nope_fp4 = self.kv_buffer[layer_id - self.start_layer].view(
torch.uint8
)
cache_k_nope_fp4_sf = self.kv_scale_buffer[layer_id - self.start_layer]
from sglang.srt.layers.quantization.kvfp4_tensor import KVFP4QuantizeUtil
cache_k_nope_fp4_dequant = KVFP4QuantizeUtil.batched_dequantize(
cache_k_nope_fp4, cache_k_nope_fp4_sf
)
return cache_k_nope_fp4_dequant
return self.kv_buffer[layer_id - self.start_layer]
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
):
layer_id = layer.layer_id
assert not self.nsa_kv_cache_store_fp8
if cache_k.dtype != self.dtype:
from sglang.srt.layers.quantization.kvfp4_tensor import KVFP4QuantizeUtil
cache_k_fp4, cache_k_fp4_sf = KVFP4QuantizeUtil.batched_quantize(cache_k)
if self.store_dtype != self.dtype:
self.kv_buffer[layer_id - self.start_layer][loc] = cache_k_fp4.view(
self.store_dtype
)
self.kv_scale_buffer[layer_id - self.start_layer][loc] = (
cache_k_fp4_sf.view(self.store_dtype)
)
else:
self.kv_buffer[layer_id - self.start_layer][loc] = cache_k
def set_mla_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k_nope: torch.Tensor,
cache_k_rope: torch.Tensor,
):
layer_id = layer.layer_id
if self.nsa_kv_cache_store_fp8:
# original cache_k: (num_tokens, num_heads 1, hidden 576); we unsqueeze the page_size=1 dim here
# TODO no need to cat
cache_k = torch.cat([cache_k_nope, cache_k_rope], dim=-1)
cache_k = quantize_k_cache(cache_k.unsqueeze(1)).squeeze(1)
cache_k = cache_k.view(self.store_dtype)
self.kv_buffer[layer_id - self.start_layer][loc] = cache_k
else:
if cache_k_nope.dtype != self.dtype:
from sglang.srt.layers.quantization.kvfp4_tensor import (
KVFP4QuantizeUtil,
)
cache_k_nope_fp4, cache_k_nope_fp4_sf = (
KVFP4QuantizeUtil.batched_quantize(cache_k_nope)
)
cache_k_rope_fp4, cache_k_rope_fp4_sf = (
KVFP4QuantizeUtil.batched_quantize(cache_k_rope)
)
if self.store_dtype != self.dtype:
cache_k_nope = cache_k_nope.view(self.store_dtype)
cache_k_rope = cache_k_rope.view(self.store_dtype)
set_mla_kv_buffer_triton(
self.kv_buffer[layer_id - self.start_layer],
loc,
cache_k_nope_fp4,
cache_k_rope_fp4,
)
set_mla_kv_scale_buffer_triton(
self.kv_scale_buffer[layer_id - self.start_layer],
loc,
cache_k_nope_fp4_sf,
cache_k_rope_fp4_sf,
)
class NSATokenToKVPool(MLATokenToKVPool):
quant_block_size = 128
index_k_with_scale_buffer_dtype = torch.uint8
rope_storage_dtype = torch.bfloat16 # rope is always stored in bf16
def __init__(
self,
size: int,
page_size: int,
kv_lora_rank: int,
dtype: torch.dtype,
qk_rope_head_dim: int,
layer_num: int,
device: str,
index_head_dim: int,
enable_memory_saver: bool,
kv_cache_dim: int,
start_layer: Optional[int] = None,
end_layer: Optional[int] = None,
):
override_dim = (
kv_cache_dim if kv_cache_dim != kv_lora_rank + qk_rope_head_dim else None
)
super().__init__(
size,
page_size,
dtype,
kv_lora_rank,
qk_rope_head_dim,
layer_num,
device,
enable_memory_saver,
start_layer,
end_layer,
use_nsa=True,
override_kv_cache_dim=override_dim,
)
# self.index_k_dtype = torch.float8_e4m3fn
# self.index_k_scale_dtype = torch.float32
self.index_head_dim = index_head_dim
# num head == 1 and head dim == 128 for index_k in NSA
assert index_head_dim == 128
if _is_hip:
assert self.page_size == 1
else:
assert self.page_size == 64
with (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.custom_mem_pool
else nullcontext()
):
self.index_k_with_scale_buffer = [
torch.zeros(
# Layout:
# ref: test_attention.py :: kv_cache_cast_to_fp8
# shape: (num_pages, page_size 64 * head_dim 128 + page_size 64 * fp32_nbytes 4)
# data: for page i,
# * buf[i, :page_size * head_dim] for fp8 data
# * buf[i, page_size * head_dim:].view(float32) for scale
(
(size + page_size + 1) // self.page_size,
self.page_size
* (
index_head_dim + index_head_dim // self.quant_block_size * 4
),
),
dtype=self.index_k_with_scale_buffer_dtype,
device=device,
)
for _ in range(layer_num)
]
self._finalize_allocation_log(size)
def get_index_k_with_scale_buffer(self, layer_id: int) -> torch.Tensor:
if self.layer_transfer_counter is not None:
self.layer_transfer_counter.wait_until(layer_id - self.start_layer)
return self.index_k_with_scale_buffer[layer_id - self.start_layer]
def get_index_k_continuous(
self,
layer_id: int,
seq_len: int,
page_indices: torch.Tensor,
):
buf = self.index_k_with_scale_buffer[layer_id - self.start_layer]
return index_buf_accessor.GetK.execute(
self, buf, seq_len=seq_len, page_indices=page_indices
)
def get_index_k_scale_continuous(
self,
layer_id: int,
seq_len: int,
page_indices: torch.Tensor,
):
buf = self.index_k_with_scale_buffer[layer_id - self.start_layer]
return index_buf_accessor.GetS.execute(
self, buf, seq_len=seq_len, page_indices=page_indices
)
def get_index_k_scale_buffer(
self,
layer_id: int,
seq_len: int,
page_indices: torch.Tensor,
):
"""
Fused method to get both index K and scale data in a single call using Triton.
More efficient than calling get_index_k_continuous and get_index_k_scale_continuous separately.
:param layer_id: Layer index
:param seq_len: Sequence length
:param page_indices: Page indices tensor
:return: tuple of (k_fp8, k_scale) where
k_fp8: (seq_len, index_head_dim), uint8
k_scale: (seq_len, 4), uint8
"""
buf = self.index_k_with_scale_buffer[layer_id - self.start_layer]
return index_buf_accessor.GetKAndS.execute(
self, buf, seq_len=seq_len, page_indices=page_indices
)
def set_index_k_scale_buffer(
self,
layer_id: int,
loc: torch.Tensor,
index_k: torch.Tensor,
index_k_scale: torch.Tensor,
) -> None:
buf = self.index_k_with_scale_buffer[layer_id - self.start_layer]
index_buf_accessor.SetKAndS.execute(
pool=self, buf=buf, loc=loc, index_k=index_k, index_k_scale=index_k_scale
)
def get_state_buf_infos(self):
data_ptrs = [
self.index_k_with_scale_buffer[i].data_ptr() for i in range(self.layer_num)
]
data_lens = [
self.index_k_with_scale_buffer[i].nbytes for i in range(self.layer_num)
]
item_lens = [
self.index_k_with_scale_buffer[i][0].nbytes for i in range(self.layer_num)
]
return data_ptrs, data_lens, item_lens
def get_kv_size_bytes(self):
kv_size_bytes = super().get_kv_size_bytes()
for index_k_cache in self.index_k_with_scale_buffer:
kv_size_bytes += get_tensor_size_bytes(index_k_cache)
return kv_size_bytes
class DoubleSparseTokenToKVPool(KVCache):
def __init__(
self,
size: int,
page_size: int,
dtype: torch.dtype,
head_num: int,
head_dim: int,
layer_num: int,
device: str,
heavy_channel_num: int,
enable_memory_saver: bool,
start_layer: Optional[int] = None,
end_layer: Optional[int] = None,
):
super().__init__(
size,
page_size,
dtype,
layer_num,
device,
enable_memory_saver,
start_layer,
end_layer,
)
with self.memory_saver_adapter.region(GPU_MEMORY_TYPE_KV_CACHE):
with (
torch.cuda.use_mem_pool(self.custom_mem_pool)
if self.enable_custom_mem_pool
else nullcontext()
):
# [size, head_num, head_dim] for each layer
self.k_buffer = [
torch.zeros(
(size + page_size, head_num, head_dim),
dtype=dtype,
device=device,
)
for _ in range(layer_num)
]
self.v_buffer = [
torch.zeros(
(size + page_size, head_num, head_dim),
dtype=dtype,
device=device,
)
for _ in range(layer_num)
]
# [size, head_num, heavy_channel_num] for each layer
self.label_buffer = [
torch.zeros(
(size + 1, head_num, heavy_channel_num),
dtype=dtype,
device=device,
)
for _ in range(layer_num)
]
def get_key_buffer(self, layer_id: int):
return self.k_buffer[layer_id - self.start_layer]
def get_value_buffer(self, layer_id: int):
return self.v_buffer[layer_id - self.start_layer]
def get_label_buffer(self, layer_id: int):
return self.label_buffer[layer_id - self.start_layer]
def get_kv_buffer(self, layer_id: int):
return (
self.k_buffer[layer_id - self.start_layer],
self.v_buffer[layer_id - self.start_layer],
)
def set_kv_buffer(
self,
layer: RadixAttention,
loc: torch.Tensor,
cache_k: torch.Tensor,
cache_v: torch.Tensor,
cache_label: torch.Tensor,
):
# NOTE(Andy): ignore the dtype check
layer_id = layer.layer_id
self.k_buffer[layer_id - self.start_layer][loc] = cache_k
self.v_buffer[layer_id - self.start_layer][loc] = cache_v
self.label_buffer[layer_id - self.start_layer][loc] = cache_label
def move_kv_cache_native(
k_buffer: List[torch.Tensor],
v_buffer: List[torch.Tensor],
tgt_loc: torch.Tensor,
src_loc: torch.Tensor,
):
if tgt_loc.numel() == 0:
return
tgt_loc_flat = tgt_loc.view(-1).long()
src_loc_flat = src_loc.view(-1).long()
for k_cache, v_cache in zip(k_buffer, v_buffer):
k_cache[tgt_loc_flat] = k_cache[src_loc_flat]
v_cache[tgt_loc_flat] = v_cache[src_loc_flat]
@triton.jit
def copy_all_layer_kv_cache_tiled(
data_ptrs,
strides,
tgt_loc_ptr,
src_loc_ptr,
num_locs,
num_locs_upper: tl.constexpr,
BYTES_PER_TILE: tl.constexpr,
):
"""2D tiled kernel. Safe for in-place copy."""
bid = tl.program_id(0)
tid = tl.program_id(1)
stride = tl.load(strides + bid)
base_ptr = tl.load(data_ptrs + bid)
base_ptr = tl.cast(base_ptr, tl.pointer_type(tl.uint8))
byte_off = tid * BYTES_PER_TILE + tl.arange(0, BYTES_PER_TILE)
mask_byte = byte_off < stride
tl.multiple_of(byte_off, 16)
loc_idx = tl.arange(0, num_locs_upper)
mask_loc = loc_idx < num_locs
src = tl.load(src_loc_ptr + loc_idx, mask=mask_loc, other=0)
tgt = tl.load(tgt_loc_ptr + loc_idx, mask=mask_loc, other=0)
src_ptr = base_ptr + src[:, None] * stride + byte_off[None, :]
tgt_ptr = base_ptr + tgt[:, None] * stride + byte_off[None, :]
mask = mask_loc[:, None] & mask_byte[None, :]
vals = tl.load(src_ptr, mask=mask)
tl.store(tgt_ptr, vals, mask=mask)