#include "common.cuh"
#include "fattn-common.cuh"
static int ggml_cuda_fattn_vec_get_nthreads_host(const int cc) {
return 128;
GGML_UNUSED(cc);
}
static constexpr __device__ int ggml_cuda_fattn_vec_get_nthreads_device() {
return 128;
}
// Currently llvm with the amdgcn target does not support unrolling loops
// that contain a break that can not be resolved at compile time.
#ifdef __clang__
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Wpass-failed"
#endif // __clang__
template<int D, int ncols, ggml_type type_K, ggml_type type_V, bool use_logit_softcap> // D == head size
__launch_bounds__(ggml_cuda_fattn_vec_get_nthreads_device(), 1)
static __global__ void flash_attn_ext_vec(
const char * __restrict__ Q,
const char * __restrict__ K,
const char * __restrict__ V,
const char * __restrict__ mask,
const char * __restrict__ sinks,
const int * __restrict__ KV_max,
float * __restrict__ dst,
float2 * __restrict__ dst_meta,
const float scale,
const float max_bias,
const float m0,
const float m1,
const uint32_t n_head_log2,
const float logit_softcap,
const int32_t ne00, const uint3 ne01, const int32_t ne02, const int32_t ne03,
const int32_t nb01, const int32_t nb02, const int32_t nb03,
const int32_t ne10, const int32_t ne11, const int32_t ne12, const int32_t ne13,
const int32_t nb11, const int32_t nb12, const int64_t nb13,
const int32_t nb21, const int32_t nb22, const int64_t nb23,
const int32_t ne31, const int32_t ne32, const int32_t ne33,
const int32_t nb31, const int32_t nb32, const int64_t nb33) {
#ifdef FLASH_ATTN_AVAILABLE
// Skip unused kernel variants for faster compilation:
if (use_logit_softcap && !(D == 128 || D == 256)) {
GGML_UNUSED_VARS(Q, K, V, mask, sinks, KV_max, dst, dst_meta, scale,
max_bias, m0, m1, n_head_log2, logit_softcap,
ne00, ne01, ne02, ne03,
nb01, nb02, nb03,
ne10, ne11, ne12, ne13,
nb11, nb12, nb13,
nb21, nb22, nb23,
ne31, ne32, ne33,
nb31, nb32, nb33);
NO_DEVICE_CODE;
return;
}
//In this kernel Q, K, V are matrices while i, j, k are matrix indices.
constexpr int cpy_nb = ggml_cuda_get_max_cpy_bytes();
constexpr int cpy_ne = cpy_nb / 4;
#ifdef GGML_USE_HIP
#ifdef RDNA
constexpr int nthreads_KQ_q = 2;
#else
constexpr int nthreads_KQ_q = 4;
#endif // RDNA
constexpr int nthreads_V_q = (D/4 < 32 ? D/4 : 32);
#else
constexpr int nthreads_KQ_q = (D/4 < 32 ? D/4 : 32);
constexpr int nthreads_V_q = (D/4 < 32 ? D/4 : 32);
#endif // GGML_USE_HIP
constexpr int nthreads = ggml_cuda_fattn_vec_get_nthreads_device();
constexpr int nthreads_KQ = (type_K == GGML_TYPE_F16 || type_K == GGML_TYPE_BF16) ? 128 / cpy_nb : nthreads_KQ_q;
constexpr int nthreads_V = (type_V == GGML_TYPE_F16 || type_V == GGML_TYPE_BF16) ? 128 / cpy_nb : nthreads_V_q;
static_assert(WARP_SIZE % nthreads_KQ == 0, "bad nthreads_K");
static_assert(WARP_SIZE % nthreads_V == 0, "bad nthreads_V");
constexpr int V_rows_per_thread = (type_V == GGML_TYPE_F16 || type_V == GGML_TYPE_BF16) ? 2*cpy_ne : 4;
constexpr int V_cols_per_iter = WARP_SIZE / nthreads_V;
constexpr vec_dot_KQ_t vec_dot_KQ = get_vec_dot_KQ<type_K, D, nthreads_KQ>();
constexpr bool Q_q8_1 = type_K != GGML_TYPE_F16 && type_K != GGML_TYPE_BF16;
#ifdef V_DOT2_F32_F16_AVAILABLE
constexpr dequantize_V_t dequantize_V = get_dequantize_V<type_V, half, V_rows_per_thread>();
#else
constexpr dequantize_V_t dequantize_V = get_dequantize_V<type_V, float, V_rows_per_thread>();
#endif // V_DOT2_F32_F16_AVAILABLE
const int ic0 = blockIdx.x * ncols; // Index of the Q/QKV column to work on.
const int sequence = blockIdx.z / ne02;
const int head = blockIdx.z - sequence*ne02;
const int gqa_ratio = ne02 / ne12; // With grouped query attention there are > 1 Q matrices per K, V matrix.
Q += nb03*sequence + nb02* head + nb01*ic0;
K += nb13*sequence + nb12*(head / gqa_ratio);
V += nb23*sequence + nb22*(head / gqa_ratio);
const half * maskh = (const half *) (mask + nb33*(sequence % ne33) + nb31*ic0);
const float slope = get_alibi_slope(max_bias, head, n_head_log2, m0, m1);
static_assert(D % (2*WARP_SIZE) == 0, "D not divisible by 2*WARP_SIZE == 64.");
constexpr int nwarps = nthreads / WARP_SIZE;
const int tid = WARP_SIZE*threadIdx.y + threadIdx.x;
__builtin_assume(tid < nthreads);
constexpr int ne_KQ = ncols*D;
constexpr int ne_combine = nwarps*V_cols_per_iter*D;
#ifdef V_DOT2_F32_F16_AVAILABLE
half2 VKQ[ncols][(D/2)/nthreads_V] = {{{0.0f, 0.0f}}};
__shared__ half KQ[ne_KQ > ne_combine ? ne_KQ : ne_combine];
#else
float2 VKQ[ncols][(D/2)/nthreads_V] = {{{0.0f, 0.0f}}};
__shared__ float KQ[ne_KQ > ne_combine ? ne_KQ : ne_combine];
#endif // V_DOT2_F32_F16_AVAILABLE
float KQ_max[ncols];
float KQ_sum[ncols];
#pragma unroll
for (int j = 0; j < ncols; ++j) {
KQ_max[j] = -FLT_MAX/2.0f;
KQ_sum[j] = 0.0f;
}
// Convert Q to float2 (f16 K) or q8_1 (quantized K) and store in registers:
#ifdef V_DOT2_F32_F16_AVAILABLE
half2 Q_reg[ncols][(D/2)/nthreads_KQ]; // Will be initialized completely.
#else
__align__(16) float2 Q_reg[ncols][(D/2)/nthreads_KQ] = {{{0.0f, 0.0f}}}; // May be only partially initialized.
#endif // V_DOT2_F32_F16_AVAILABLE
int Q_i32[ncols][1 > D/(sizeof(int)*nthreads_KQ) ? 1 : D/(sizeof(int)*nthreads_KQ)];
float2 Q_ds[ncols][1 > D/(sizeof(int)*nthreads_KQ) ? 1 : D/(sizeof(int)*nthreads_KQ)];
if constexpr (Q_q8_1) {
#pragma unroll
for (int j0 = 0; j0 < ncols; j0 += nwarps) {
const int j = j0 + threadIdx.y;
if (j0 + nwarps > ncols && j >= ncols) {
break;
}
// Reuse KQ as temporary storage for converting Q to q8_1:
int * tmp_q_i32 = (int *) &KQ[j*D];
float2 * tmp_q_ds = (float2 *) (tmp_q_i32 + D/sizeof(int));
// Set memory to zero if out of bounds:
if (ncols > 1 && ic0 + j >= int(ne01.z)) {
#pragma unroll
for (int i0 = 0; i0 < int(D/sizeof(int)); i0 += WARP_SIZE) {
const int i = i0 + threadIdx.x;
if (i0 + WARP_SIZE <= int(D/sizeof(int)) || i < int(D/sizeof(int))) {
tmp_q_i32[i] = 0;
}
}
if (threadIdx.x < D/QK8_1) {
tmp_q_ds[threadIdx.x] = make_float2(0.0f, 0.0f);
}
} else {
const float * Q_f = (const float *) (Q + j*nb01);
constexpr int nthreads_quantize = D/sizeof(int) < WARP_SIZE ? D/sizeof(int) : WARP_SIZE;
#pragma unroll
for (int i0 = 0; i0 < int(D/sizeof(int)); i0 += nthreads_quantize) {
quantize_q8_1_to_shared<float2, nthreads_quantize>
(Q_f + i0*sizeof(int), scale, tmp_q_i32 + i0, tmp_q_ds + i0/QI8_1);
}
}
}
__syncthreads();
#pragma unroll
for (int j = 0; j < ncols; ++j) {
int * tmp_q_i32 = (int *) &KQ[j*D];
float2 * tmp_q_ds = (float2 *) (tmp_q_i32 + D/sizeof(int));
#pragma unroll
for (int i0 = 0; i0 < int(D/sizeof(int)); i0 += nthreads_KQ) {
const int i = i0 + (nthreads_KQ == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_KQ);
Q_i32[j][i0/nthreads_KQ] = tmp_q_i32[i];
Q_ds[j][i0/nthreads_KQ] = tmp_q_ds[i/QI8_1];
}
}
__syncthreads();
} else {
#ifdef V_DOT2_F32_F16_AVAILABLE
const half2 scale_h2 = make_half2(scale, scale);
#pragma unroll
for (int j = 0; j < ncols; ++j) {
const float2 * Q_j = (const float2 *) (Q + j*nb01);
#pragma unroll
for (int i0 = 0; i0 < D/2; i0 += nthreads_KQ*cpy_ne) {
const int i = i0 + (nthreads_KQ == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_KQ)*cpy_ne;
__align__(16) float2 tmp[cpy_ne] = {{0.0f, 0.0f}};
if (ncols == 1 || ic0 + j < int(ne01.z)) {
ggml_cuda_memcpy_1<cpy_nb>(tmp, &Q_j[i]);
ggml_cuda_memcpy_1<cpy_nb>(tmp + cpy_ne/2, &Q_j[i + cpy_ne/2]);
}
#pragma unroll
for (int i1 = 0; i1 < cpy_ne; ++i1) {
Q_reg[j][i0/nthreads_KQ + i1] = make_half2(tmp[i1].x, tmp[i1].y);
}
}
#pragma unroll
for (int k = 0; k < (D/2)/nthreads_KQ; ++k) {
Q_reg[j][k] *= scale_h2;
}
}
#else
#pragma unroll
for (int j = 0; j < ncols; ++j) {
const float2 * Q_j = (const float2 *) (Q + j*nb01);
#pragma unroll
for (int i0 = 0; i0 < D/2; i0 += nthreads_KQ*cpy_ne) {
const int i = i0 + (nthreads_KQ == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_KQ)*cpy_ne;
if (ncols == 1 || ic0 + j < int(ne01.z)) {
ggml_cuda_memcpy_1<cpy_nb>(&Q_reg[j][i0/nthreads_KQ], &Q_j[i]);
ggml_cuda_memcpy_1<cpy_nb>(&Q_reg[j][i0/nthreads_KQ + cpy_ne/2], &Q_j[i + cpy_ne/2]);
}
}
#pragma unroll
for (int k = 0; k < (D/2)/nthreads_KQ; ++k) {
Q_reg[j][k].x *= scale;
Q_reg[j][k].y *= scale;
}
}
#endif // V_DOT2_F32_F16_AVAILABLE
}
const int k_VKQ_max = KV_max ? KV_max[sequence*gridDim.x + blockIdx.x] : ne11;
K += blockIdx.y*nthreads * nb11;
V += blockIdx.y*nthreads * nb21;
maskh += blockIdx.y*nthreads;
for (int k_VKQ_0 = blockIdx.y*nthreads; k_VKQ_0 < k_VKQ_max; k_VKQ_0 += gridDim.y*nthreads,
// Increment pointers after each loop:
K += gridDim.y*nthreads*nb11, V += gridDim.y*nthreads*nb21, maskh += gridDim.y*nthreads) {
// Calculate KQ tile and keep track of new maximum KQ values:
float KQ_reg[ncols]; // KQ in registers.
float KQ_max_new[ncols];
#pragma unroll
for (int j = 0; j < ncols; ++j) {
KQ_max_new[j] = KQ_max[j];
}
#pragma unroll
for (int i_KQ_0 = 0; i_KQ_0 < nthreads_KQ; ++i_KQ_0) {
const int i_KQ = threadIdx.y*WARP_SIZE + (nthreads_KQ == WARP_SIZE ? 0 : (threadIdx.x & ~(nthreads_KQ-1))) + i_KQ_0;
#pragma unroll
for (int j = 0; j < ncols; ++j) {
float sum = vec_dot_KQ(K + i_KQ*nb11, Q_reg[j], Q_i32[j], Q_ds[j]);
sum = warp_reduce_sum<nthreads_KQ>(sum);
if (use_logit_softcap) {
sum = logit_softcap*tanhf(sum);
}
if (mask && (ncols == 1 || ic0 + j < int(ne01.z))) {
sum += slope*__half2float(maskh[j*ne11 + i_KQ]);
}
KQ_max_new[j] = fmaxf(KQ_max_new[j], sum + FATTN_KQ_MAX_OFFSET);
if ((nthreads_KQ == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_KQ) == uint32_t(i_KQ_0)) {
KQ_reg[j] = sum;
}
}
}
#pragma unroll
for (int j = 0; j < ncols; ++j) {
#pragma unroll
for (int offset = nthreads_KQ; offset < WARP_SIZE; offset <<= 1) {
KQ_max_new[j] = fmaxf(KQ_max_new[j], __shfl_xor_sync(0xFFFFFFFF, KQ_max_new[j], offset, WARP_SIZE));
}
const float KQ_max_scale = expf(KQ_max[j] - KQ_max_new[j]);
KQ_max[j] = KQ_max_new[j];
KQ_reg[j] = expf(KQ_reg[j] - KQ_max[j]);
KQ_sum[j] = KQ_sum[j]*KQ_max_scale + KQ_reg[j];
KQ[j*nthreads + tid] = KQ_reg[j];
#ifdef V_DOT2_F32_F16_AVAILABLE
const half2 KQ_max_scale_h2 = make_half2(KQ_max_scale, KQ_max_scale);
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V) {
VKQ[j][i_VKQ_0/nthreads_V] *= KQ_max_scale_h2;
}
#else
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V) {
VKQ[j][i_VKQ_0/nthreads_V].x *= KQ_max_scale;
VKQ[j][i_VKQ_0/nthreads_V].y *= KQ_max_scale;
}
#endif // V_DOT2_F32_F16_AVAILABLE
}
#ifndef GGML_USE_HIP
__syncwarp();
#endif // GGML_USE_HIP
#pragma unroll
for (int k0 = 0; k0 < WARP_SIZE; k0 += V_cols_per_iter) {
const int k = threadIdx.y*WARP_SIZE + k0 + (nthreads_V == WARP_SIZE ? 0 : threadIdx.x / nthreads_V);
#ifdef V_DOT2_F32_F16_AVAILABLE
half2 KQ_k[ncols];
#pragma unroll
for (int j = 0; j < ncols; ++j) {
KQ_k[j] = __half2half2(KQ[j*nthreads + k]);
}
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V*V_rows_per_thread/2) {
half2 tmp[V_rows_per_thread/2];
if constexpr (type_V == GGML_TYPE_BF16) {
float2 tmp_f[V_rows_per_thread/2];
dequantize_V(V + k*nb21, tmp_f,
2*i_VKQ_0 + (nthreads_V == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_V)*V_rows_per_thread);
#pragma unroll
for (int i_VKQ_1 = 0; i_VKQ_1 < V_rows_per_thread/2; ++i_VKQ_1) {
tmp[i_VKQ_1] = __float22half2_rn(tmp_f[i_VKQ_1]);
}
} else {
dequantize_V(V + k*nb21, tmp,
2*i_VKQ_0 + (nthreads_V == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_V)*V_rows_per_thread);
}
#pragma unroll
for (int i_VKQ_1 = 0; i_VKQ_1 < V_rows_per_thread/2; ++i_VKQ_1) {
#pragma unroll
for (int j = 0; j < ncols; ++j) {
VKQ[j][i_VKQ_0/nthreads_V + i_VKQ_1] += tmp[i_VKQ_1]*KQ_k[j];
}
}
}
#else
float KQ_k[ncols];
#pragma unroll
for (int j = 0; j < ncols; ++j) {
KQ_k[j] = KQ[j*nthreads + k];
}
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V*V_rows_per_thread/2) {
float2 tmp[V_rows_per_thread/2];
dequantize_V(V + k*nb21, tmp,
2*i_VKQ_0 + (nthreads_V == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_V)*V_rows_per_thread);
#pragma unroll
for (int i_VKQ_1 = 0; i_VKQ_1 < V_rows_per_thread/2; ++i_VKQ_1) {
#pragma unroll
for (int j = 0; j < ncols; ++j) {
VKQ[j][i_VKQ_0/nthreads_V + i_VKQ_1].x += tmp[i_VKQ_1].x*KQ_k[j];
VKQ[j][i_VKQ_0/nthreads_V + i_VKQ_1].y += tmp[i_VKQ_1].y*KQ_k[j];
}
}
}
#endif // V_DOT2_F32_F16_AVAILABLE
}
}
if (sinks && blockIdx.y == 0) {
const float sink = ((const float *) sinks)[head];
#pragma unroll
for (int j0 = 0; j0 < ncols; j0 += nwarps) {
const int j = j0 + threadIdx.y;
if (j0 + nwarps > ncols && j >= ncols) {
break;
}
const float kqmax_new_j = fmaxf(sink, KQ_max[j]);
const float KQ_max_scale = expf(KQ_max[j] - kqmax_new_j);
KQ_max[j] = kqmax_new_j;
KQ_sum[j] = KQ_sum[j]*KQ_max_scale + (threadIdx.x == 0 ? expf(sink - KQ_max[j]) : 0.0f);
#ifdef V_DOT2_F32_F16_AVAILABLE
const half2 KQ_max_scale_h2 = make_half2(KQ_max_scale, KQ_max_scale);
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V) {
VKQ[j][i_VKQ_0/nthreads_V] *= KQ_max_scale_h2;
}
#else
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V) {
VKQ[j][i_VKQ_0/nthreads_V].x *= KQ_max_scale;
VKQ[j][i_VKQ_0/nthreads_V].y *= KQ_max_scale;
}
#endif // V_DOT2_F32_F16_AVAILABLE
}
}
__shared__ float KQ_max_shared[ncols][WARP_SIZE];
__shared__ float KQ_sum_shared[ncols][WARP_SIZE];
#pragma unroll
for (int j = 0; j < ncols; ++j) {
if (threadIdx.y == 0) {
KQ_max_shared[j][threadIdx.x] = -FLT_MAX/2.0f;
KQ_sum_shared[j][threadIdx.x] = 0.0f;
}
}
__syncthreads();
#pragma unroll
for (int j = 0; j < ncols; ++j) {
if (threadIdx.x == 0) {
KQ_max_shared[j][threadIdx.y] = KQ_max[j];
}
}
__syncthreads();
#pragma unroll
for (int j_VKQ = 0; j_VKQ < ncols; ++j_VKQ) {
if (ncols > 1 && ic0 + j_VKQ >= int(ne01.z)) {
break;
}
float kqmax_new = KQ_max_shared[j_VKQ][threadIdx.x];
kqmax_new = warp_reduce_max(kqmax_new);
const float kqmax_scale = expf(KQ_max[j_VKQ] - kqmax_new);
KQ_max[j_VKQ] = kqmax_new;
#ifdef V_DOT2_F32_F16_AVAILABLE
half2 * VKQ_tmp = (half2 *) KQ + threadIdx.y*(V_cols_per_iter*D/2)
+ (nthreads_V == WARP_SIZE ? 0 : threadIdx.x / nthreads_V)*(D/2);
const half2 kqmax_scale_h2 = make_half2(kqmax_scale, kqmax_scale);
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V) {
VKQ[j_VKQ][i_VKQ_0/nthreads_V] *= kqmax_scale_h2;
}
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V*V_rows_per_thread/2) {
const int i_VKQ = i_VKQ_0 + (nthreads_V == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_V)*(V_rows_per_thread/2);
ggml_cuda_memcpy_1<V_rows_per_thread*sizeof(half)>(VKQ_tmp + i_VKQ, &VKQ[j_VKQ][i_VKQ_0/nthreads_V]);
}
#else
float2 * VKQ_tmp = (float2 *) KQ + threadIdx.y*(V_cols_per_iter*D/2)
+ (nthreads_V == WARP_SIZE ? 0 : threadIdx.x / nthreads_V)*(D/2);
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V) {
VKQ[j_VKQ][i_VKQ_0/nthreads_V].x *= kqmax_scale;
VKQ[j_VKQ][i_VKQ_0/nthreads_V].y *= kqmax_scale;
}
#pragma unroll
for (int i_VKQ_0 = 0; i_VKQ_0 < D/2; i_VKQ_0 += nthreads_V*V_rows_per_thread/2) {
const int i_VKQ = i_VKQ_0 + (nthreads_V == WARP_SIZE ? threadIdx.x : threadIdx.x % nthreads_V)*(V_rows_per_thread/2);
ggml_cuda_memcpy_1<V_rows_per_thread/2*sizeof(float)>(VKQ_tmp + i_VKQ, &VKQ[j_VKQ][i_VKQ_0/nthreads_V]);
ggml_cuda_memcpy_1<V_rows_per_thread/2*sizeof(float)>(VKQ_tmp + i_VKQ + V_rows_per_thread/4, &VKQ[j_VKQ][i_VKQ_0/nthreads_V + V_rows_per_thread/4]);
}
#endif // V_DOT2_F32_F16_AVAILABLE
KQ_sum[j_VKQ] *= kqmax_scale;
KQ_sum[j_VKQ] = warp_reduce_sum(KQ_sum[j_VKQ]);
if (threadIdx.x == 0) {
KQ_sum_shared[j_VKQ][threadIdx.y] = KQ_sum[j_VKQ];
}
__syncthreads();
if (nthreads <= D || tid < D) {
KQ_sum[j_VKQ] = KQ_sum_shared[j_VKQ][threadIdx.x];
KQ_sum[j_VKQ] = warp_reduce_sum(KQ_sum[j_VKQ]);
#pragma unroll
for (int i0 = 0; i0 < D; i0 += nthreads) {
float dst_val = 0;
#pragma unroll
for (int w = 0; w < nwarps; ++w) {
#pragma unroll
for (int v = 0; v < V_cols_per_iter; ++v) {
dst_val += float(KQ[w*V_cols_per_iter*D + v*D + i0 + tid]);
}
}
if (gridDim.y == 1) {
dst_val /= KQ_sum[j_VKQ];
}
dst[(((sequence*int(ne01.z) + ic0 + j_VKQ)*ne02 + head)*gridDim.y + blockIdx.y)*D + i0 + tid] = dst_val;
}
}
if (j_VKQ < ncols-1) {
__syncthreads();
}
}
if (gridDim.y != 1 && tid < ncols && (ncols == 1 || ic0 + tid < int(ne01.z))) {
dst_meta[((sequence*int(ne01.z) + ic0 + tid)*ne02 + head)*gridDim.y + blockIdx.y] = make_float2(KQ_max[tid], KQ_sum[tid]);
}
#else
GGML_UNUSED_VARS(Q, K, V, mask, sinks, KV_max, dst, dst_meta, scale,
max_bias, m0, m1, n_head_log2, logit_softcap,
ne00, ne01, ne02, ne03,
nb01, nb02, nb03,
ne10, ne11, ne12, ne13,
nb11, nb12, nb13,
nb21, nb22, nb23,
ne31, ne32, ne33,
nb31, nb32, nb33);
NO_DEVICE_CODE;
#endif // FLASH_ATTN_AVAILABLE
}
#ifdef __clang__
#pragma clang diagnostic pop
#endif // __clang__
template <int D, int cols_per_block, ggml_type type_K, ggml_type type_V, bool use_logit_softcap>
void ggml_cuda_flash_attn_ext_vec_case_impl(ggml_backend_cuda_context & ctx, ggml_tensor * dst) {
const int cc = ggml_cuda_info().devices[ggml_cuda_get_device()].cc;
const int nthreads = ggml_cuda_fattn_vec_get_nthreads_host(cc);
const int nwarps = nthreads / WARP_SIZE;
fattn_kernel_t fattn_kernel = flash_attn_ext_vec<D, cols_per_block, type_K, type_V, use_logit_softcap>;
const bool need_f16_K = type_K == GGML_TYPE_F16;
const bool need_f16_V = type_V == GGML_TYPE_F16;
constexpr size_t nbytes_shared = 0;
launch_fattn<D, cols_per_block, 1>(ctx, dst, fattn_kernel, nwarps, nbytes_shared, D, need_f16_K, need_f16_V, false);
}
template <int D, ggml_type type_K, ggml_type type_V>
void ggml_cuda_flash_attn_ext_vec_case(ggml_backend_cuda_context & ctx, ggml_tensor * dst) {
const ggml_tensor * KQV = dst;
const ggml_tensor * Q = dst->src[0];
float logit_softcap;
memcpy(&logit_softcap, (const float *) KQV->op_params + 2, sizeof(float));
if (Q->ne[1] == 1) {
constexpr int cols_per_block = 1;
if (logit_softcap == 0.0f) {
constexpr bool use_logit_softcap = false;
ggml_cuda_flash_attn_ext_vec_case_impl<D, cols_per_block, type_K, type_V, use_logit_softcap>(ctx, dst);
} else {
constexpr bool use_logit_softcap = true;
ggml_cuda_flash_attn_ext_vec_case_impl<D, cols_per_block, type_K, type_V, use_logit_softcap>(ctx, dst);
}
return;
}
constexpr int cols_per_block = 2;
if (logit_softcap == 0.0f) {
constexpr bool use_logit_softcap = false;
ggml_cuda_flash_attn_ext_vec_case_impl<D, cols_per_block, type_K, type_V, use_logit_softcap>(ctx, dst);
} else {
constexpr bool use_logit_softcap = true;
ggml_cuda_flash_attn_ext_vec_case_impl<D, cols_per_block, type_K, type_V, use_logit_softcap>(ctx, dst);
}
}
#define DECL_FATTN_VEC_CASE(D, type_K, type_V) \
template void ggml_cuda_flash_attn_ext_vec_case \
<D, type_K, type_V>(ggml_backend_cuda_context & ctx, ggml_tensor * dst) \
#define EXTERN_DECL_FATTN_VEC_CASES(D, type_K) \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_F16); \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_Q4_0); \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_Q4_1); \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_Q5_0); \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_Q5_1); \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_Q8_0); \
extern DECL_FATTN_VEC_CASE(D, type_K, GGML_TYPE_BF16); \
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_F16)
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_Q4_0)
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_Q4_1)
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_Q5_0)
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_Q5_1)
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_Q8_0)
EXTERN_DECL_FATTN_VEC_CASES( 64, GGML_TYPE_BF16)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_F16)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_Q4_0)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_Q4_1)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_Q5_0)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_Q5_1)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_Q8_0)
EXTERN_DECL_FATTN_VEC_CASES(128, GGML_TYPE_BF16)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_F16)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_Q4_0)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_Q4_1)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_Q5_0)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_Q5_1)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_Q8_0)
EXTERN_DECL_FATTN_VEC_CASES(256, GGML_TYPE_BF16)