#pragma once #include "attn_common.cuh" constexpr int DC_CHUNK = 64; __device__ inline float warp_reduce_sum(float val) { for (int offset = 16; offset > 0; offset >>= 1) val += __shfl_xor_sync(0xFFFFFFFF, val, offset); return val; } __global__ void attn_decode_split_kv_kernel(AttentionParams p) { int batch = blockIdx.x / p.kv_head; int kv_head = blockIdx.x % p.kv_head; int split = blockIdx.z; int group_size = blockDim.y; int q_head = kv_head * group_size + threadIdx.y; int lane = threadIdx.x; int hd_per_thread = p.head_dim / 32; float q_reg[8]; int q_off = ((batch * p.q_head + q_head) * 1) * p.head_dim + lane * hd_per_thread; for (int i = 0; i < hd_per_thread; i++) q_reg[i] = __bfloat162float(p.q[q_off + i]); int kv_base = ((batch * p.kv_head + kv_head) * p.kv_len) * p.head_dim; int mask_base = batch * p.kv_len; float m = -FLT_MAX, d = 0.0f, acc_reg[8] = {0.0f}; extern __shared__ __align__(16) bf16 k_smem[]; // Split-KV: each split processes a contiguous subset of chunks int chunks_total = (p.kv_len + DC_CHUNK - 1) / DC_CHUNK; int chunks_per_split = (chunks_total + p.num_splits - 1) / p.num_splits; int ch_begin = split * chunks_per_split; int ch_end = min(chunks_total, ch_begin + chunks_per_split); for (int ci = ch_begin; ci < ch_end; ci++) { int chunk_start = ci * DC_CHUNK; int this_chunk = min(DC_CHUNK, p.kv_len - chunk_start); int total = this_chunk * p.head_dim; for (int i = threadIdx.y * 32 + lane; i < total; i += blockDim.x * blockDim.y) k_smem[i] = p.k[kv_base + chunk_start * p.head_dim + i]; __syncthreads(); for (int s = 0; s < this_chunk; s++) { float partial = 0.0f; for (int i = 0; i < hd_per_thread; i++) partial += q_reg[i] * __bfloat162float(k_smem[s * p.head_dim + lane * hd_per_thread + i]); partial = warp_reduce_sum(partial) * p.scale; if (p.use_mask && p.mask && !p.mask[mask_base + chunk_start + s]) partial = -FLT_MAX; if (p.is_causal && (chunk_start + s) > p.causal_offset) partial = -FLT_MAX; float new_m = fmaxf(m, partial); float alpha = expf(m - new_m); float beta = expf(partial - new_m); d = d * alpha + beta; int v_off = kv_base + (chunk_start + s) * p.head_dim + lane * hd_per_thread; for (int i = 0; i < hd_per_thread; i++) acc_reg[i] = acc_reg[i] * alpha + __bfloat162float(p.v[v_off + i]) * beta; m = new_m; } __syncthreads(); } // ---- write UN-normalised partials for this split ---- size_t bh = (size_t)batch * p.q_head + q_head; size_t slot = bh * p.num_splits + split; int d0 = lane * hd_per_thread; for (int i = 0; i < hd_per_thread; i++) { int dd = d0 + i; p.o_part[slot * p.head_dim + dd] = acc_reg[i]; } if (lane == 0) { p.ml_part[slot * 2] = m; p.ml_part[slot * 2 + 1] = d; } } // Reduce split-K partials into the final bf16 output. One block per (batch, // q_head); each thread folds across all splits with a single-pass // online-rescale reduction (expf + FMA counts halved vs 3-pass original). __global__ void attn_decode_combine_kernel(AttentionParams p) { int bh = blockIdx.x; int d = threadIdx.x; if (d >= p.head_dim) return; size_t split_base = (size_t)bh * p.num_splits; const float* mlp = p.ml_part + split_base * 2; const float* op = p.o_part + split_base * p.head_dim; float m = -FLT_MAX, l = 0.0f, acc = 0.0f; for (int s = 0; s < p.num_splits; s++) { float mi = mlp[s * 2]; if (mi <= -FLT_MAX) continue; float li = mlp[s * 2 + 1]; float nm = fmaxf(m, mi); float corr = __expf(m - nm); float e = __expf(mi - nm); acc = acc * corr + op[s * p.head_dim + d] * e; l = l * corr + li * e; m = nm; } float inv = (l > 1e-20f) ? (1.0f / l) : 0.0f; p.o[(size_t)bh * p.head_dim + d] = __float2bfloat16(acc * inv); }