mirror of
https://github.com/ggerganov/llama.cpp.git
synced 2024-10-31 23:28:51 +01:00
310 lines
11 KiB
Plaintext
310 lines
11 KiB
Plaintext
#include "common.cuh"
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#include "fattn-common.cuh"
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#include "fattn-tile-f32.cuh"
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#define FATTN_KQ_STRIDE_TILE_F32 32
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template<int D, int ncols, int nwarps, int parallel_blocks> // D == head size
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#if !(defined(GGML_USE_HIPBLAS) && defined(__HIP_PLATFORM_AMD__))
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__launch_bounds__(nwarps*WARP_SIZE, 1)
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#endif // !(defined(GGML_USE_HIPBLAS) && defined(__HIP_PLATFORM_AMD__))
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static __global__ void flash_attn_tile_ext_f32(
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const char * __restrict__ Q,
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const char * __restrict__ K,
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const char * __restrict__ V,
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const char * __restrict__ mask,
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float * __restrict__ dst,
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float2 * __restrict__ dst_meta,
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const float scale,
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const float max_bias,
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const float m0,
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const float m1,
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const uint32_t n_head_log2,
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const int ne00,
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const int ne01,
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const int ne02,
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const int ne03,
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const int ne10,
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const int ne11,
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const int ne12,
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const int ne13,
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const int ne31,
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const int nb31,
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const int nb01,
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const int nb02,
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const int nb03,
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const int nb11,
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const int nb12,
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const int nb13,
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const int ne0,
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const int ne1,
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const int ne2,
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const int ne3) {
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//In this kernel Q, K, V are matrices while i, j, k are matrix indices.
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const int ic0 = (blockIdx.x / parallel_blocks) * ncols; // Index of the Q/QKV column to work on.
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const int ip = blockIdx.x % parallel_blocks; // Index in group of blocks running for the same column in parallel.
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const int gqa_ratio = ne02 / ne12; // With grouped query attention there are > 1 Q matrices per K, V matrix.
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const float2 * Q_f2 = (const float2 *) (Q + nb02* blockIdx.y + nb01*ic0);
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const half2 * K_h2 = (const half2 *) (K + nb12*(blockIdx.y / gqa_ratio));
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const half2 * V_h2 = (const half2 *) (V + nb12*(blockIdx.y / gqa_ratio)); // K and V have same shape
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const half * maskh = (const half *) mask + ne11*ic0;
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const int stride_KV2 = nb11 / sizeof(half2);
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const float slope = get_alibi_slope(max_bias, blockIdx.y, n_head_log2, m0, m1);
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static_assert(D % (2*WARP_SIZE) == 0, "D not divisible by 2*WARP_SIZE == 64.");
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__shared__ float KQ[ncols*FATTN_KQ_STRIDE_TILE_F32];
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__shared__ float KV_tmp[FATTN_KQ_STRIDE_TILE_F32][D + 1]; // Pad D to avoid memory bank conflicts.
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float2 * KV_tmp2 = (float2 *) KV_tmp;
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float kqmax[ncols/nwarps];
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#pragma unroll
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for (int j0 = 0; j0 < ncols; j0 += nwarps) {
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kqmax[j0/nwarps] = -FLT_MAX/2.0f;
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}
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float kqsum[ncols/nwarps] = {0.0f};
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float2 VKQ[ncols/nwarps][(D/2)/WARP_SIZE] = {{{0.0f, 0.0f}}};
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// Convert Q to half2 and store in registers:
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__shared__ float Q_f[ncols][D];
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#pragma unroll
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for (int j0 = 0; j0 < ncols; j0 += nwarps) {
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const int j = j0 + threadIdx.y;
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#pragma unroll
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for (int i0 = 0; i0 < D; i0 += 2*WARP_SIZE) {
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float2 tmp = ic0 + j < ne01 ? Q_f2[j*(nb01/sizeof(float2)) + i0/2 + threadIdx.x] : make_float2(0.0f, 0.0f);
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Q_f[j][i0 + 0*WARP_SIZE + threadIdx.x] = tmp.x * scale;
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Q_f[j][i0 + 1*WARP_SIZE + threadIdx.x] = tmp.y * scale;
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}
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}
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__syncthreads();
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const int k_start = parallel_blocks == 1 ? 0 : ip*FATTN_KQ_STRIDE_TILE_F32;
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for (int k_VKQ_0 = k_start; k_VKQ_0 < ne11; k_VKQ_0 += parallel_blocks*FATTN_KQ_STRIDE_TILE_F32) {
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// Calculate KQ tile and keep track of new maximum KQ values:
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float kqmax_new[ncols/nwarps];
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#pragma unroll
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for (int j = 0; j < ncols/nwarps; ++j) {
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kqmax_new[j] = kqmax[j];
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}
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#pragma unroll
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for (int i_KQ_0 = 0; i_KQ_0 < FATTN_KQ_STRIDE_TILE_F32; i_KQ_0 += nwarps) {
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const int i_KQ = i_KQ_0 + threadIdx.y;
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#pragma unroll
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for (int k_KQ_0 = 0; k_KQ_0 < D; k_KQ_0 += 2*WARP_SIZE) {
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const half2 tmp = K_h2[(k_VKQ_0 + i_KQ)*stride_KV2 + k_KQ_0/2 + threadIdx.x];
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KV_tmp[i_KQ][k_KQ_0 + 0*WARP_SIZE + threadIdx.x] = __low2float(tmp);
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KV_tmp[i_KQ][k_KQ_0 + 1*WARP_SIZE + threadIdx.x] = __high2float(tmp);
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}
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}
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__syncthreads();
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float sum[FATTN_KQ_STRIDE_TILE_F32/WARP_SIZE][ncols/nwarps] = {{0.0f}};
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#pragma unroll
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for (int k_KQ = 0; k_KQ < D; ++k_KQ) {
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float K_k[FATTN_KQ_STRIDE_TILE_F32/WARP_SIZE];
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float Q_k[ncols/nwarps];
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#pragma unroll
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for (int i_KQ_0 = 0; i_KQ_0 < FATTN_KQ_STRIDE_TILE_F32; i_KQ_0 += WARP_SIZE) {
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const int i_KQ = i_KQ_0 + threadIdx.x;
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K_k[i_KQ_0/WARP_SIZE] = KV_tmp[i_KQ][k_KQ];
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}
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#pragma unroll
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for (int j_KQ_0 = 0; j_KQ_0 < ncols; j_KQ_0 += nwarps) {
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const int j_KQ = j_KQ_0 + threadIdx.y;
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Q_k[j_KQ_0/nwarps] = Q_f[j_KQ][k_KQ];
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}
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#pragma unroll
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for (int i_KQ_0 = 0; i_KQ_0 < FATTN_KQ_STRIDE_TILE_F32; i_KQ_0 += WARP_SIZE) {
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#pragma unroll
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for (int j_KQ_0 = 0; j_KQ_0 < ncols; j_KQ_0 += nwarps) {
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sum[i_KQ_0/WARP_SIZE][j_KQ_0/nwarps] += K_k[i_KQ_0/WARP_SIZE] * Q_k[j_KQ_0/nwarps];
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}
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}
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}
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#pragma unroll
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for (int i_KQ_0 = 0; i_KQ_0 < FATTN_KQ_STRIDE_TILE_F32; i_KQ_0 += WARP_SIZE) {
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const int i_KQ = i_KQ_0 + threadIdx.x;
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#pragma unroll
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for (int j_KQ_0 = 0; j_KQ_0 < ncols; j_KQ_0 += nwarps) {
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const int j_KQ = j_KQ_0 + threadIdx.y;
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sum[i_KQ_0/WARP_SIZE][j_KQ_0/nwarps] += mask ? slope*__half2float(maskh[j_KQ*ne11 + k_VKQ_0 + i_KQ]) : 0.0f;
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kqmax_new[j_KQ_0/nwarps] = fmaxf(kqmax_new[j_KQ_0/nwarps], sum[i_KQ_0/WARP_SIZE][j_KQ_0/nwarps]);
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KQ[j_KQ*FATTN_KQ_STRIDE_TILE_F32 + i_KQ] = sum[i_KQ_0/WARP_SIZE][j_KQ_0/nwarps];
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}
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}
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__syncthreads();
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#pragma unroll
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for (int j0 = 0; j0 < ncols; j0 += nwarps) {
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const int j = j0 + threadIdx.y;
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kqmax_new[j0/nwarps] = warp_reduce_max(kqmax_new[j0/nwarps]);
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const float KQ_max_scale = expf(kqmax[j0/nwarps] - kqmax_new[j0/nwarps]);
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kqmax[j0/nwarps] = kqmax_new[j0/nwarps];
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float kqsum_add = 0.0f;
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#pragma unroll
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for (int i0 = 0; i0 < FATTN_KQ_STRIDE_TILE_F32; i0 += WARP_SIZE) {
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const int i = i0 + threadIdx.x;
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const float diff = KQ[j*FATTN_KQ_STRIDE_TILE_F32 + i] - kqmax[j0/nwarps];
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const float val = expf(diff);
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kqsum_add += val;
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KQ[j*FATTN_KQ_STRIDE_TILE_F32 + i] = val;
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}
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kqsum[j0/nwarps] = kqsum[j0/nwarps]*KQ_max_scale + kqsum_add;
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#pragma unroll
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for (int i0 = 0; i0 < D/2; i0 += WARP_SIZE) {
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VKQ[j0/nwarps][i0/WARP_SIZE].x *= KQ_max_scale;
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VKQ[j0/nwarps][i0/WARP_SIZE].y *= KQ_max_scale;
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}
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}
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__syncthreads();
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#pragma unroll
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for (int k0 = 0; k0 < FATTN_KQ_STRIDE_TILE_F32; k0 += nwarps) {
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const int k = k0 + threadIdx.y;
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#pragma unroll
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for (int i0 = 0; i0 < D/2; i0 += WARP_SIZE) {
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const int i = i0 + threadIdx.x;
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KV_tmp2[k*(D/2) + i].x = __low2float(V_h2[(k_VKQ_0 + k)*stride_KV2 + i]);
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KV_tmp2[k*(D/2) + i].y = __high2float(V_h2[(k_VKQ_0 + k)*stride_KV2 + i]);
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}
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}
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__syncthreads();
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#pragma unroll
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for (int k = 0; k < FATTN_KQ_STRIDE_TILE_F32; ++k) {
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float2 V_k[(D/2)/WARP_SIZE];
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float KQ_k[ncols/nwarps];
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#pragma unroll
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for (int i0 = 0; i0 < D/2; i0 += WARP_SIZE) {
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const int i = i0 + threadIdx.x;
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V_k[i0/WARP_SIZE] = KV_tmp2[k*(D/2) + i];
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}
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#pragma unroll
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for (int j0 = 0; j0 < ncols; j0 += nwarps) {
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const int j = j0 + threadIdx.y;
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KQ_k[j0/nwarps] = KQ[j*FATTN_KQ_STRIDE_TILE_F32 + k];
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}
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#pragma unroll
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for (int i0 = 0; i0 < D/2; i0 += WARP_SIZE) {
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#pragma unroll
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for (int j0 = 0; j0 < ncols; j0 += nwarps) {
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VKQ[j0/nwarps][i0/WARP_SIZE].x += V_k[i0/WARP_SIZE].x*KQ_k[j0/nwarps];
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VKQ[j0/nwarps][i0/WARP_SIZE].y += V_k[i0/WARP_SIZE].y*KQ_k[j0/nwarps];
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}
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}
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}
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__syncthreads();
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}
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#pragma unroll
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for (int j_VKQ_0 = 0; j_VKQ_0 < ncols; j_VKQ_0 += nwarps) {
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const int j_VKQ = j_VKQ_0 + threadIdx.y;
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if (ic0 + j_VKQ >= ne01) {
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return;
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}
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float kqsum_j = kqsum[j_VKQ_0/nwarps];
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kqsum_j = warp_reduce_sum(kqsum_j);
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#pragma unroll
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for (int i00 = 0; i00 < D; i00 += 2*WARP_SIZE) {
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const int i0 = i00 + 2*threadIdx.x;
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float2 dst_val = VKQ[j_VKQ_0/nwarps][i0/(2*WARP_SIZE)];
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if (parallel_blocks == 1) {
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dst_val.x /= kqsum_j;
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dst_val.y /= kqsum_j;
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}
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const int j_dst = (ic0 + j_VKQ)*parallel_blocks + ip;
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dst[j_dst*D*gridDim.y + D*blockIdx.y + i0 + 0] = dst_val.x;
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dst[j_dst*D*gridDim.y + D*blockIdx.y + i0 + 1] = dst_val.y;
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}
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if (parallel_blocks != 1 && threadIdx.x == 0) {
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dst_meta[(ic0 + j_VKQ)*gridDim.y*parallel_blocks + blockIdx.y*parallel_blocks + ip] = make_float2(kqmax[j_VKQ_0/nwarps], kqsum_j);
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}
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}
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}
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template <int cols_per_block, int parallel_blocks>
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void launch_fattn_tile_f32_64_128(ggml_backend_cuda_context & ctx, ggml_tensor * dst) {
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const ggml_tensor * Q = dst->src[0];
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switch (Q->ne[0]) {
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case 64: {
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constexpr int D = 64;
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constexpr int nwarps = 8;
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fattn_kernel_t fattn_kernel = flash_attn_tile_ext_f32<D, cols_per_block, nwarps, parallel_blocks>;
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launch_fattn<D, parallel_blocks>(ctx, dst, fattn_kernel, nwarps, cols_per_block);
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} break;
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case 128: {
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constexpr int D = 128;
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constexpr int nwarps = 8;
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fattn_kernel_t fattn_kernel = flash_attn_tile_ext_f32<D, cols_per_block, nwarps, parallel_blocks>;
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launch_fattn<D, parallel_blocks>(ctx, dst, fattn_kernel, nwarps, cols_per_block);
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} break;
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default: {
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GGML_ASSERT(false && "FlashAttention without tensor cores only supports head sizes 64 and 128.");
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} break;
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}
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}
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void ggml_cuda_flash_attn_ext_tile_f32(ggml_backend_cuda_context & ctx, ggml_tensor * dst) {
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const ggml_tensor * Q = dst->src[0];
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if (Q->ne[1] <= 16) {
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constexpr int cols_per_block = 16;
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constexpr int parallel_blocks = 4;
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launch_fattn_tile_f32_64_128<cols_per_block, parallel_blocks>(ctx, dst);
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return;
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}
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if (Q->ne[1] <= 32) {
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constexpr int cols_per_block = 32;
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constexpr int parallel_blocks = 4;
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launch_fattn_tile_f32_64_128<cols_per_block, parallel_blocks>(ctx, dst);
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return;
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}
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constexpr int cols_per_block = 32;
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constexpr int parallel_blocks = 1;
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launch_fattn_tile_f32_64_128<cols_per_block, parallel_blocks>(ctx, dst);
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}
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