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xc-llm-ascend/vllm_ascend/ops/triton/rope.py
Angazenn c0c2eb614e [Main][Ops] Make triton rope support index_selecting from cos_sin_cache (#5450) 
### What this PR does / why we need it?

This PR extends original `rope_triton_forward` and
`split_qkv_rmsnorm_rope` to support `cos_sin_cache` && `positions` as
inputs. This fully aligns to vLLM RoPE api interface. Compared with
earlier implementation for RoPE, the benefits are:

1. avoiding pre-computation of `cos` `sin` before model execution, which
helps to remove redundant codes.
2. allowing eagle3 draft model to have different rope parameters with
main model (see #6612 ). This help to recover accept rate && accuracy in
that case.

In addition, this kernel change only introduces very small performance
degradation. Those `index_select` or `chunk` operations are now changed
into simple memory access in triton kernel (For example,
https://github.com/vllm-project/vllm-ascend/pull/5450/changes#diff-a4c2d3071530df193b98f9bf38553874bc4d47571336711f116c26d019cfbb6aR77-R81).

**Highlights**

- **RoPE Cache Unification**: Replaced separate _sin and _cos global
tensors with a unified cos_sin_cache and explicit positions tensor for
Rotary Positional Embeddings (RoPE), streamlining data handling.
- **Triton Kernel Integration**: Updated Triton kernels
(split_qkv_rmsnorm_rope_kernel, _triton_rope) to directly consume the
cos_sin_cache and positions for more efficient and integrated RoPE
calculations.
- **Custom Operation Registration**: Registered `rope_forward_oot` as a
new custom operation, allowing its use in fused compilation passes and
providing a dedicated entry point for the new RoPE implementation.
- **Refactored RoPE Forward Pass**: Modified the rope_forward_oot
function to accept the new cos_sin_cache and positions arguments,
enabling a more flexible and integrated RoPE application within the
system.

### Does this PR introduce _any_ user-facing change?

No.

### How was this patch tested?

- vLLM version: v0.13.0
- vLLM main:
5326c89803

Additional test on Qwen3-235b accuracy:

| Aime2024 | GSM8K | Livecodebench |
| -------- | -------- | -------- |
| 83.33 | 96.26 | 70.23 |

---------

Signed-off-by: Angazenn <supperccell@163.com>
2026-02-11 21:20:53 +08:00

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#
# Copyright (c) 2025 Huawei Technologies Co., Ltd. All Rights Reserved.
#
# 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.
# This file is a part of the vllm-ascend project.
#
import torch
from vllm.triton_utils import tl, triton
from vllm_ascend.ops.triton.triton_utils import get_vectorcore_num
# TODO(whx-sjtu): Add tiling of n_q_head and n_kv_head to support more models.
# I only have tested this kernel on Deepseek V3.2 and Qwen3-Next.
# For models with larger n_q_head and n_kv_head such as GLM 4.6, this is not supported yet.
@triton.jit
def _triton_rope(
q_ptr,
q_row_stride,
k_ptr,
k_row_stride,
cos_ptr,
cos_row_stride,
sin_ptr,
sin_row_stride,
cos_sin_ptr,
cos_sin_row_stride,
pos_ptr,
num_tokens,
n_qh: tl.constexpr,
n_kh: tl.constexpr,
hd: tl.constexpr,
rope_dim: tl.constexpr,
pad_n_qh: tl.constexpr,
pad_n_kh: tl.constexpr,
pad_rope_dim: tl.constexpr,
BLOCK_SIZE: tl.constexpr,
IS_NEOX_STYLE: tl.constexpr,
USE_COS_SIN: tl.constexpr,
):
"""
This triton kernel applies rotary embedding on q and k.
It supports rope_dim != head_dim scenario.
It supports both neox style and non-neox style rope computation.
Input tensor layout assumptions:
q size: (num_tokens, num_q_heads, head_dim)
q stride: (num_q_heads * head_dim, head_dim, 1)
k size: (num_tokens, num_kv_heads, head_dim)
k stride: (num_kv_heads * head_dim, head_dim, 1)
cos/sin size: (num_tokens, rope_dim/2)
cos/sin stride: (rope_dim/2, 1)
Different compute pattern of IS_NEOX_STYLE:
if IS_NEOX_STYLE:
x1, x2 = torch.chunk(x, 2, dim=-1)
else:
x1 = x[..., ::2]
x2 = x[..., 1::2]
o1 = x1 * cos - x2 * sin
o2 = x2 * cos + x1 * sin
if IS_NEOX_STYLE:
return torch.cat((o1, o2), dim=-1)
else:
return torch.stack((o1, o2), dim=-1).flatten(-2)
"""
pid = tl.program_id(0).to(tl.int64)
row_block_size = tl.num_programs(0)
for row_idx in tl.range(pid, num_tokens, row_block_size):
q_start_ptr = q_ptr + row_idx * q_row_stride
k_start_ptr = k_ptr + row_idx * k_row_stride
# ####################################################################
# get the cos(mθ_{i...d/2}) and sin(mθ_{i...d/2}) for token position
# m of this program instance
# ####################################################################
cos_offsets = tl.arange(0, pad_rope_dim // 2)
sin_offsets = tl.arange(pad_rope_dim // 2, pad_rope_dim)
cos_mask = cos_offsets < (rope_dim // 2)
if USE_COS_SIN:
pos_idx = tl.load(pos_ptr + row_idx).to(tl.int64)
cos_start_ptr = cos_sin_ptr + pos_idx * cos_sin_row_stride
cos_row = tl.load(cos_start_ptr + cos_offsets, mask=cos_mask, other=0).to(tl.float32)
sin_row = tl.load(cos_start_ptr + sin_offsets, mask=cos_mask, other=0).to(tl.float32)
else:
cos_start_ptr = cos_ptr + row_idx * cos_row_stride
sin_start_ptr = sin_ptr + row_idx * sin_row_stride
cos_row = tl.load(cos_start_ptr + cos_offsets, mask=cos_mask, other=0).to(tl.float32)
sin_row = tl.load(sin_start_ptr + cos_offsets, mask=cos_mask, other=0).to(tl.float32)
# ####################################################################
# Load the left and right half of q and k for the current
# program instance (i.e. for the current token) separately
# ####################################################################
# left half of the head
if IS_NEOX_STYLE:
first_half_q_offsets = tl.arange(0, pad_n_qh)[:, None] * hd + tl.arange(0, pad_rope_dim // 2)[None, :]
first_half_k_offsets = tl.arange(0, pad_n_kh)[:, None] * hd + tl.arange(0, pad_rope_dim // 2)[None, :]
else:
first_half_q_offsets = tl.arange(0, pad_n_qh)[:, None] * hd + (2 * tl.arange(0, pad_rope_dim // 2)[None, :])
first_half_k_offsets = tl.arange(0, pad_n_kh)[:, None] * hd + (2 * tl.arange(0, pad_rope_dim // 2)[None, :])
first_q_mask = (tl.arange(0, pad_n_qh)[:, None] < n_qh) & (
tl.arange(0, pad_rope_dim // 2)[None, :] < (rope_dim // 2)
)
first_k_mask = (tl.arange(0, pad_n_kh)[:, None] < n_kh) & (
tl.arange(0, pad_rope_dim // 2)[None, :] < (rope_dim // 2)
)
q_tile_1 = tl.load(q_start_ptr + first_half_q_offsets, mask=first_q_mask, other=0).to(sin_row.dtype)
k_tile_1 = tl.load(k_start_ptr + first_half_k_offsets, mask=first_k_mask, other=0).to(sin_row.dtype)
# right half of the head
if IS_NEOX_STYLE:
second_half_q_offsets = first_half_q_offsets + (rope_dim // 2)
second_half_k_offsets = first_half_k_offsets + (rope_dim // 2)
else:
second_half_q_offsets = first_half_q_offsets + 1
second_half_k_offsets = first_half_k_offsets + 1
second_q_mask = first_q_mask
second_k_mask = first_k_mask
q_tile_2 = tl.load(q_start_ptr + second_half_q_offsets, mask=second_q_mask, other=0).to(sin_row.dtype)
k_tile_2 = tl.load(k_start_ptr + second_half_k_offsets, mask=second_k_mask, other=0).to(sin_row.dtype)
# y = [x1, x2] * [cos, cos] + [-x2, x1] * [sin, sin]
new_q_tile_1 = q_tile_1 * cos_row - q_tile_2 * sin_row
tl.store(q_start_ptr + first_half_q_offsets, new_q_tile_1, mask=first_q_mask)
new_q_tile_2 = q_tile_2 * cos_row + q_tile_1 * sin_row
tl.store(q_start_ptr + second_half_q_offsets, new_q_tile_2, mask=second_q_mask)
new_k_tile_1 = k_tile_1 * cos_row - k_tile_2 * sin_row
tl.store(k_start_ptr + first_half_k_offsets, new_k_tile_1, mask=first_k_mask)
new_k_tile_2 = k_tile_2 * cos_row + k_tile_1 * sin_row
tl.store(k_start_ptr + second_half_k_offsets, new_k_tile_2, mask=second_k_mask)
def rope_forward_triton(
q: torch.Tensor,
k: torch.Tensor,
cos: torch.Tensor = None,
sin: torch.Tensor = None,
cos_sin_cache: torch.Tensor = None,
positions: torch.Tensor = None,
rope_dim: int = -1,
is_neox_style: bool = True,
) -> tuple[torch.Tensor, torch.Tensor]:
if not q.is_contiguous():
q = q.contiguous()
if not k.is_contiguous():
k = k.contiguous()
num_tokens, n_q_head, head_dim = q.shape
n_kv_head = k.shape[1]
assert rope_dim <= head_dim
pad_rope_dim = triton.next_power_of_2(rope_dim)
pad_n_q_head = triton.next_power_of_2(n_q_head)
pad_n_kv_head = triton.next_power_of_2(n_kv_head)
BLOCK_SIZE = max(pad_n_q_head, pad_n_kv_head)
num_vectorcore = get_vectorcore_num()
n_row = min(num_tokens, num_vectorcore)
if cos_sin_cache is not None and positions is not None:
assert positions.shape[0] == num_tokens
_triton_rope[(n_row,)](
q,
q.stride(0),
k,
k.stride(0),
None,
None,
None,
None,
cos_sin_cache,
cos_sin_cache.stride(0),
positions,
num_tokens,
n_q_head,
n_kv_head,
head_dim,
rope_dim,
pad_n_q_head,
pad_n_kv_head,
pad_rope_dim,
BLOCK_SIZE=BLOCK_SIZE,
IS_NEOX_STYLE=is_neox_style,
USE_COS_SIN=True,
)
elif cos is not None and sin is not None:
assert cos.shape[0] == num_tokens and sin.shape[0] == num_tokens
cos = cos.view(num_tokens, -1)
sin = sin.view(num_tokens, -1)
if rope_dim == -1:
# If rope_dim is not specified, we assume that input cos/sin is not
# duplicated to rope_dim, which means rope_dim == cos.shape[-1] * 2
rope_dim = cos.shape[-1] * 2
_triton_rope[(n_row,)](
q,
q.stride(0),
k,
k.stride(0),
cos,
cos.stride(0),
sin,
sin.stride(0),
None,
None,
None,
num_tokens,
n_q_head,
n_kv_head,
head_dim,
rope_dim,
pad_n_q_head,
pad_n_kv_head,
pad_rope_dim,
BLOCK_SIZE=BLOCK_SIZE,
IS_NEOX_STYLE=is_neox_style,
USE_COS_SIN=False,
)
else:
raise ValueError(
"Currently, rope_forward_triton supports passing:\n"
"1. positions and original cos_sin_cache.\n"
"2. cos and sin which are already selected by positions\n"
"Please check whether you call rope_forward_triton correctly."
)
return q, k
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