| name | triton-ascend-case-reduction-amin-atomic |
| description | 原子操作归约(amin)优化:非reduce轴很小时将reduce轴映射多核,提供循环内/外两种原子操作方案(减少存储vs减少竞争),通过二次切分+计算重组提升性能,适用于M<<N(如16×262144)的极端shape比例场景 |
| category | case |
| version | 1.0.0 |
| metadata | {"backend":"ascend","dsl":"triton_ascend","hardware":"Atlas A2, Atlas A3"} |
Amin 归约原子操作优化案例
任务特征
- 数据尺寸:(16, 262144),非reduce轴很小,reduce轴很大
- 策略:将reduce轴映射到多核,通过原子操作实现跨线程块归约
优化 1:切分策略调整
grid = lambda meta: (triton.cdiv(M, meta['BLOCK_SIZE_M']),)
grid = lambda meta: (triton.cdiv(N, meta['BLOCK_SIZE_N']),)
for n_start in range(0, BLOCK_SIZE_N, SUB_BLOCK_SIZE_N):
n_offsets = pid * BLOCK_SIZE_N + n_start + tl.arange(0, SUB_BLOCK_SIZE_N)
优化内容
- 调整切分策略,由非reduce轴映射多核调整为reduce轴映射多核
- 为了不超过硬件缓存,kernel内对列进行二次切分
优化 2:计算重组
row_min = float('inf')
for n_start in range(0, BLOCK_SIZE_N, SUB_BLOCK_SIZE_N):
错误:curr_min = tl.min(data_block, 1)
row_min = tl.minimum(curr_min, row_min)
curr_min = tl.full((BLOCK_SIZE_M, SUB_BLOCK_SIZE_N), float('inf'), dtype=tl.float32)
for n_start in range(0, BLOCK_SIZE_N, SUB_BLOCK_SIZE_N):
curr_min = tl.minimum(data_block, curr_min)
row_min = tl.min(curr_min, 1)
优化内容
- 利用curr_min保持矩阵结构,维护中间结果
- 将多次归约合并为一次归约,减少归约次数
优化 3:原子操作(两种方案)
方案一:循环内进行原子操作
for m_start in range(0, M, BLOCK_SIZE_M):
m_offsets = m_start + tl.arange(0, BLOCK_SIZE_M)
mmask = m_offsets < M
curr_min = tl.full((BLOCK_SIZE_M, SUB_BLOCK_SIZE_N), float('inf'), dtype=tl.float32)
for n_start in range(0, BLOCK_SIZE_N, SUB_BLOCK_SIZE_N):
n_offsets = pid * BLOCK_SIZE_N + n_start + tl.arange(0, SUB_BLOCK_SIZE_N)
nmask = n_offsets < N
mask = (mmask[:, None]) & (nmask[None, :])
block_ptrs = in_ptr0 + m_offsets[:,None] * in_stride0 + n_offsets[None,:] * in_stride1
data_block = tl.load(block_ptrs, mask=mask, other=float('inf'))
curr_min = tl.minimum(data_block, curr_min)
row_min = tl.min(curr_min, 1)
output_ptrs = out_ptr0 + m_offsets * out_stride0
tl.atomic_min(output_ptrs, row_min, mask=mmask)
特点:
方案二:循环外进行原子操作
all_row_min = tl.full((M,), float('inf'), dtype=tl.float32)
for m_start in range(0, M, BLOCK_SIZE_M):
m_offsets = m_start + tl.arange(0, BLOCK_SIZE_M)
mmask = m_offsets < M
curr_min = tl.full((BLOCK_SIZE_M, SUB_BLOCK_SIZE_N), float('inf'), dtype=tl.float32)
for n_start in range(0, BLOCK_SIZE_N, SUB_BLOCK_SIZE_N):
n_offsets = pid * BLOCK_SIZE_N + n_start + tl.arange(0, SUB_BLOCK_SIZE_N)
nmask = n_offsets < N
mask = (mmask[:, None]) & (nmask[None, :])
block_ptrs = in_ptr0 + m_offsets[:,None] * in_stride0 + n_offsets[None,:] * in_stride1
data_block = tl.load(block_ptrs, mask=mask, other=float('inf'))
curr_min = tl.minimum(data_block, curr_min)
row_min = tl.min(curr_min, 1)
curr_block_size_m = tl.minimum(BLOCK_SIZE_M, M - m_start)
all_row_min = tl.insert_slice(all_row_min, row_min, [m_start], [curr_block_size_m], [1])
output_ptrs = out_ptr0 + tl.arange(0, M) * out_stride0
tl.atomic_min(output_ptrs, all_row_min)
特点:
- 通过集中执行原子操作减少了竞争
- 需要额外存储空间,适合大规模数据
优化 4:配置
@triton.autotune(
configs=[
triton.Config({'BLOCK_SIZE_M': 8, 'BLOCK_SIZE_N': 8192, 'SUB_BLOCK_SIZE_N': 1024}),
triton.Config({'BLOCK_SIZE_M': 16, 'BLOCK_SIZE_N': 8192, 'SUB_BLOCK_SIZE_N': 512}),
],
key=[...],
restore_value=['out_ptr0'],
)
优化内容
- 切分能被对应shape整除
- Grid数尽量大但不超过AI core(BLOCK_SIZE_N=8192,使grid=32)
- 在UB用满的前提下,进行kernel内切分大小调整
总结
- 非reduce轴很小、reduce轴很大时,将reduce轴映射到多核并结合原子操作
- 两种原子操作方案各有优劣:方案一减少存储但原子操作频繁,方案二集中原子操作但需额外空间
- 确定核数后,若超过硬件缓存,可以考虑二次切分
- 调整切分和核数配置,尽量保证在不超出UB的前提下尽量用满UB