Memcpy kernel for flash attention (#29)

* optimize * add benchmark * add assert * add test
2023-04-10 18:22:49 -07:00 · 2023-04-10 18:22:49 -07:00 · e3cec88aa5
commit e3cec88aa5
parent b9926f7f66
4 changed files with 293 additions and 0 deletions
--- a/benchmark/benchmark_cache.py
+++ b/benchmark/benchmark_cache.py
@ -0,0 +1,81 @@
 import functools
 import random
 import time
 import torch
 from cacheflow import cache_ops
 def benchmark(name, f, size: int, num_warmup = 10, num_iters = 100):
    for _ in range(num_warmup):
        f()
    torch.cuda.synchronize()
    start = time.time()
    for _ in range(num_iters):
        f()
    torch.cuda.synchronize()
    end = time.time()
    avg_time = (end - start) / num_iters
    print(f'[Latency] {name}: {avg_time * 1000:.3f} ms')
    print(f'[Throughput] {name}: {size / avg_time / 2 ** 30:.3f} GB/s')
@torch.inference_mode()
 def test_gather_cached_kv(
    num_tokens: int,
    num_heads: int,
    head_size: int,
    block_size: int,
    num_blocks: int,
    dtype: torch.dtype,
 ) -> None:
    print(f'num_tokens: {num_tokens}, num_heads: {num_heads}, '
          f'head_size: {head_size}, block_size: {block_size}, '
          f'num_blocks: {num_blocks}, dtype: {dtype}')
    num_slots = block_size * num_blocks
    slot_mapping = random.sample(range(num_slots), num_tokens)
    slot_mapping = torch.tensor(slot_mapping, dtype=torch.int, device='cuda')
    qkv = torch.randn(
        num_tokens, 3, num_heads, head_size, dtype=dtype, device='cuda')
    _, key, value = qkv.unbind(dim=1)
    x = 16 // torch.tensor([], dtype=dtype).element_size()
    key_cache_shape = (num_blocks, num_heads, head_size // x, block_size, x)
    key_cache = torch.randn(size=key_cache_shape, dtype=dtype, device='cuda')
    value_cache_shape = (num_blocks, num_heads, head_size, block_size)
    value_cache = torch.randn(
        size=value_cache_shape, dtype=dtype, device='cuda')
    # Run Flash attention.
    def run():
        cache_ops.gather_cached_kv(key, value, key_cache, value_cache, slot_mapping)
    benchmark('gather_cached_kv', run,
              size=num_tokens * num_heads * head_size * 2 * qkv.element_size())
 if __name__ == '__main__':
    BLOCK_SIZE = 8
    NUM_BLOCKS = 1024
    DTYPE = torch.half
    # LLaMA-13B and OPT-13B
    NUM_HEADS = 40
    HEAD_SIZE = 128
    run_benchmark = functools.partial(
        test_gather_cached_kv,
        num_heads=NUM_HEADS,
        head_size=HEAD_SIZE,
        block_size=BLOCK_SIZE,
        num_blocks=NUM_BLOCKS,
        dtype=DTYPE,
    )
    for i in range(6, 12):
        run_benchmark(num_tokens=2 ** i)
--- a/csrc/cache.cpp
+++ b/csrc/cache.cpp
@ -20,6 +20,13 @@ void reshape_and_cache(
  torch::Tensor& value_cache,
  torch::Tensor& slot_mapping);
 void gather_cached_kv(
  torch::Tensor& key,
  torch::Tensor& value,
  torch::Tensor& key_cache,
  torch::Tensor& value_cache,
  torch::Tensor& slot_mapping);
 PYBIND11_MODULE(TORCH_EXTENSION_NAME, m) {
  m.def(
    "swap_blocks",
@ -33,4 +40,8 @@ PYBIND11_MODULE(TORCH_EXTENSION_NAME, m) {
    "reshape_and_cache",
    &reshape_and_cache,
    "Reshape the key and value tensors and cache them");
  m.def(
    "gather_cached_kv",
    &gather_cached_kv,
    "Gather key and value from the cache into contiguous QKV tensors");
 }
--- a/csrc/cache_kernels.cu
+++ b/csrc/cache_kernels.cu
@ -176,6 +176,124 @@ __global__ void reshape_and_cache_kernel(
  }
 }
 // Grid: (num_blocks, block_size).
 template<typename scalar_t>
 __global__ void gather_cached_kv_kernel(
  scalar_t* __restrict__ key,             // [num_tokens, [stride], num_heads, head_size]
  scalar_t* __restrict__ value,           // [num_tokens, [stride], num_heads, head_size]
  const scalar_t* __restrict__ key_cache,   // [num_blocks, num_heads, head_size/x, block_size, x]
  const scalar_t* __restrict__ value_cache,   // [num_blocks, num_heads, head_size, block_size]
  const int* __restrict__ slot_mapping,   // [num_tokens]
  const int key_stride,
  const int value_stride,
  const int num_heads,
  const int head_size,
  const int block_size,
  const int x) {
    const int token_idx = blockIdx.x;
    const int slot_idx = slot_mapping[token_idx];
    const int block_idx = slot_idx / block_size;
    const int block_offset = slot_idx % block_size;
    const int num_tokens = num_heads * head_size;
    for (int i = threadIdx.x; i < num_tokens; i += blockDim.x) {
      const int tgt_key_idx = token_idx * key_stride + i;
      const int tgt_value_idx = token_idx * value_stride + i;
      const int head_idx = i / head_size;
      const int head_offset = i % head_size;
      const int x_idx = head_offset / x;  // the offset of the [head_size/x] dimension
      const int x_offset = head_offset % x;
      const int src_key_idx = block_idx * num_heads * (head_size / x) * block_size * x
                              + head_idx * (head_size / x) * block_size * x
                              + x_idx * block_size * x
                              + block_offset * x
                              + x_offset;
      const int src_value_idx = block_idx * num_heads * head_size * block_size
                                + head_idx * head_size * block_size
                                + head_offset * block_size
                                + block_offset;
      key[tgt_key_idx] = __ldg(&key_cache[src_key_idx]);
      value[tgt_value_idx] = __ldg(&value_cache[src_value_idx]);
    }
 }
 template <typename scalar_t>
 __global__ void gather_cached_kv_kernel_optimized(
    scalar_t *__restrict__ key,             // [num_tokens, [stride], num_heads, head_size]
    scalar_t *__restrict__ value,           // [num_tokens, [stride], num_heads, head_size]
    const scalar_t *__restrict__ key_cache, // [num_blocks, num_heads, head_size/x, block_size, x]
    const scalar_t *__restrict__ value_cache, // [num_blocks, num_heads, head_size, block_size]
    const int *__restrict__ slot_mapping,   // [num_tokens]
    const int key_stride,
    const int value_stride,
    const int num_heads,
    const int head_size,
    const int block_size,
    const int x)
 {
    const int token_idx = blockIdx.x;
    const int slot_idx = slot_mapping[token_idx];
    const int block_idx = slot_idx / block_size;
    const int block_offset = slot_idx % block_size;
    const int dim = num_heads * head_size;
    assert(dim % 4 == 0);  // this is true for known use cases
    const int unroll_factor = 4;
    const int unrolled_dim = dim / unroll_factor;
    for (int i = threadIdx.x; i < unrolled_dim; i += blockDim.x)
    {
        int tgt_key_indices[unroll_factor];
        int tgt_value_indices[unroll_factor];
        int src_key_indices[unroll_factor];
        int src_value_indices[unroll_factor];
        scalar_t keys_to_store[unroll_factor];
        scalar_t values_to_store[unroll_factor];
        #pragma unroll
        for (int j = 0; j < unroll_factor; ++j)
        {
            int index = i + j * unrolled_dim;
            const int tgt_key_idx = token_idx * key_stride + index;
            const int tgt_value_idx = token_idx * value_stride + index;
            const int head_idx = index / head_size;
            const int head_offset = index % head_size;
            const int x_idx = head_offset / x;
            const int x_offset = head_offset % x;
            const int src_key_idx = block_idx * num_heads * (head_size / x) * block_size * x
                                    + head_idx * (head_size / x) * block_size * x
                                    + x_idx * block_size * x
                                    + block_offset * x
                                    + x_offset;
            const int src_value_idx = block_idx * num_heads * head_size * block_size
                                      + head_idx * head_size * block_size
                                      + head_offset * block_size
                                      + block_offset;
            tgt_key_indices[j] = tgt_key_idx;
            tgt_value_indices[j] = tgt_value_idx;
            src_key_indices[j] = src_key_idx;
            src_value_indices[j] = src_value_idx;
            keys_to_store[j] = __ldg(&key_cache[src_key_idx]);
            values_to_store[j] = __ldg(&value_cache[src_value_idx]);
        }
        #pragma unroll
        for (int j = 0; j < unroll_factor; ++j)
        {
            key[tgt_key_indices[j]] = keys_to_store[j];
            value[tgt_value_indices[j]] = values_to_store[j];
        }
    }
 }
 } // namespace cacheflow
 void reshape_and_cache(
@ -215,3 +333,42 @@ void reshape_and_cache(
        x);
    });
 }
 void gather_cached_kv(
  torch::Tensor& key,           // [out] [num_tokens, num_heads, head_size]
  torch::Tensor& value,         // [out] [num_tokens, num_heads, head_size]
  torch::Tensor& key_cache,     // [in]  [num_blocks, num_heads, head_size/x, block_size, x]
  torch::Tensor& value_cache,   // [in]  [num_blocks, num_heads, head_size, block_size]
  torch::Tensor& slot_mapping)  // [in]  [num_tokens]
 {
  int num_tokens = key.size(0);
  int num_heads = key.size(1);
  int head_size = key.size(2);
  int block_size = key_cache.size(3);
  int x = key_cache.size(4);
  int key_stride = key.stride(0);
  int value_stride = value.stride(0);
  dim3 grid(num_tokens);
  dim3 block(std::min(num_heads * head_size, 512));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
  AT_DISPATCH_FLOATING_TYPES_AND_HALF(
    key.scalar_type(),
    "gather_cached_kv_kernel_optimized",
    [&] {
      cacheflow::gather_cached_kv_kernel_optimized<scalar_t><<<grid, block, 0, stream>>>(
        key.data_ptr<scalar_t>(),
        value.data_ptr<scalar_t>(),
        key_cache.data_ptr<scalar_t>(),
        value_cache.data_ptr<scalar_t>(),
        slot_mapping.data_ptr<int>(),
        key_stride,
        value_stride,
        num_heads,
        head_size,
        block_size,
        x);
    });
 }
--- a/tests/kernels/cache.py
+++ b/tests/kernels/cache.py
@ -99,6 +99,47 @@ def test_reshape_and_cache(
    assert torch.allclose(value_cache, cloned_value_cache)
 def test_gather_cached_kv(
    num_tokens: int,
    num_heads: int,
    head_size: int,
    block_size: int,
    num_blocks: int,
    dtype: torch.dtype,
 ) -> None:
    num_slots = block_size * num_blocks
    slot_mapping = random.sample(range(num_slots), num_tokens)
    slot_mapping = torch.tensor(slot_mapping, dtype=torch.int, device='cuda')
    qkv = torch.randn(
        num_tokens, 3, num_heads, head_size, dtype=dtype, device='cuda')
    _, key, value = qkv.unbind(dim=1)
    qkv_clone = qkv.clone()
    _, cloned_key, cloned_value = qkv_clone.unbind(dim=1)
    x = 16 // torch.tensor([], dtype=dtype).element_size()
    key_cache_shape = (num_blocks, num_heads, head_size // x, block_size, x)
    key_cache = torch.randn(size=key_cache_shape, dtype=dtype, device='cuda')
    value_cache_shape = (num_blocks, num_heads, head_size, block_size)
    value_cache = torch.randn(
        size=value_cache_shape, dtype=dtype, device='cuda')
    cache_ops.gather_cached_kv(key, value, key_cache, value_cache, slot_mapping)
    # Reference implementation.
    for i in range(num_tokens):
        reshaped_key = cloned_key.reshape(num_tokens, num_heads, head_size // x, x)
        block_idx = torch.div(slot_mapping[i], block_size, rounding_mode='floor')
        block_offset = slot_mapping[i] % block_size
        reshaped_key[i] = key_cache[block_idx, :, :, block_offset, :]
        cloned_value[i] = value_cache[block_idx, :, :, block_offset]
    assert torch.allclose(key, cloned_key)
    assert torch.allclose(value, cloned_value)
@torch.inference_mode()
 def test_cache() -> None:
    test_copy_blocks(
@ -107,6 +148,9 @@ def test_cache() -> None:
    test_reshape_and_cache(
        num_tokens=3, num_heads=2, head_size=16, block_size=8, num_blocks=2,
        dtype=torch.half)
    test_gather_cached_kv(
        num_tokens=3, num_heads=2, head_size=16, block_size=8, num_blocks=2,
        dtype=torch.half)
 if __name__ == '__main__':