mirror of
https://github.com/ggerganov/llama.cpp.git
synced 2024-12-26 03:14:35 +00:00
metal: minor q4 optimization and reduce code size (#2248)
* metal: use uint16_t instead of uint8_t. Apple GPU doesn't like uint8_t. For every operation on uint8_t the gpu need to copy the uint8_t to an empty 16 bit register, then it can issue other instructions. For the matrix-vector multiplication kernel only, we observed a 340~350 GB/s memory read speed on M1 Max after this commit, which is very close to the reported hardware limit. * metal: update rms_norm kernel This commit double the speed of rms_norm operations by using 512 threads per threadgroup, combining with SIMD primitives to minimize the need for thread group barriers. * metal: use template to reduce size Revert modifications on block_q4_0 and block_q4_1.
This commit is contained in:
parent
294f424554
commit
417a85a001
@ -792,7 +792,7 @@ void ggml_metal_graph_compute(
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const float eps = 1e-6f;
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const int nth = 256;
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const int nth = 512;
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[encoder setComputePipelineState:ctx->pipeline_rms_norm];
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[encoder setBuffer:id_src0 offset:offs_src0 atIndex:0];
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@ -800,7 +800,7 @@ void ggml_metal_graph_compute(
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[encoder setBytes:&ne00 length:sizeof( int64_t) atIndex:2];
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[encoder setBytes:&nb01 length:sizeof(uint64_t) atIndex:3];
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[encoder setBytes:&eps length:sizeof( float) atIndex:4];
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[encoder setThreadgroupMemoryLength:nth*sizeof(float) atIndex:0];
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[encoder setThreadgroupMemoryLength:nth/32*sizeof(float) atIndex:0];
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const int64_t nrows = ggml_nrows(src0);
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264
ggml-metal.metal
264
ggml-metal.metal
@ -331,26 +331,33 @@ kernel void kernel_rms_norm(
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threadgroup float * sum [[threadgroup(0)]],
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uint tgpig[[threadgroup_position_in_grid]],
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uint tpitg[[thread_position_in_threadgroup]],
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uint sgitg[[simdgroup_index_in_threadgroup]],
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uint tiisg[[thread_index_in_simdgroup]],
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uint ntg[[threads_per_threadgroup]]) {
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device const float * x = (device const float *) ((device const char *) src0 + tgpig*nb01);
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device const float4 * x = (device const float4 *) ((device const char *) src0 + tgpig*nb01);
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device const float * x_scalar = (device const float *) x;
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float4 sumf=0;
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float all_sum=0;
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// parallel sum
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sum[tpitg] = 0.0f;
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for (int i00 = tpitg; i00 < ne00; i00 += ntg) {
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sum[tpitg] += x[i00] * x[i00];
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for (int i00 = tpitg; i00 < ne00/4; i00 += ntg) {
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sumf += x[i00] * x[i00];
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}
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all_sum = sumf[0] + sumf[1] + sumf[2] + sumf[3];
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all_sum = simd_sum(all_sum);
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if (tiisg == 0) {
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sum[sgitg] = all_sum;
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}
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// reduce
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threadgroup_barrier(mem_flags::mem_threadgroup);
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for (uint i = ntg/2; i > 0; i /= 2) {
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// broadcast, simd group number is ntg / 32
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for (int i = ntg / 32 / 2; i > 0; i /= 2) {
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if (tpitg < i) {
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sum[tpitg] += sum[tpitg + i];
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}
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threadgroup_barrier(mem_flags::mem_threadgroup);
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}
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// broadcast
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if (tpitg == 0) {
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for (int i = 4 * (ne00 / 4); i < ne00; i++) {sum[0] += x_scalar[i];}
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sum[0] /= ne00;
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}
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@ -359,16 +366,101 @@ kernel void kernel_rms_norm(
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const float mean = sum[0];
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const float scale = 1.0f/sqrt(mean + eps);
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device float * y = dst + tgpig*ne00;
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for (int i00 = tpitg; i00 < ne00; i00 += ntg) {
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device float4 * y = (device float4 *) (dst + tgpig*ne00);
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device float * y_scalar = (device float *) y;
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for (int i00 = tpitg; i00 < ne00/4; i00 += ntg) {
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y[i00] = x[i00] * scale;
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}
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if (tpitg == 0) {
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for (int i00 = 4 * (ne00 / 4); i00 < ne00; i00++) {y_scalar[i00] = x_scalar[i00] * scale;}
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}
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}
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// function for calculate inner product between a q4_0 block and 32 floats (yl), sumy is SUM(yl[i])
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float block_q_n_dot_y(device const block_q4_0 * qb_curr, float sumy, thread float * yl) {
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float d = qb_curr->d;
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float4 acc = 0.f;
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device uint16_t * qs = ((device uint16_t *)qb_curr + 1);
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for (int i = 0; i < 16; i+=2) {
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acc[0] += yl[i] * (qs[i / 2] & 0x000F);
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acc[1] += yl[i + 16] * (qs[i / 2] & 0x00F0);
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acc[2] += yl[i + 1] * (qs[i / 2] & 0x0F00);
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acc[3] += yl[i + 17] * (qs[i / 2] & 0xF000);
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}
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return d * (sumy * -8.f + acc[0] + acc[1]/16.f + acc[2]/256.f + acc[3]/4096.f);
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}
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// function for calculate inner product between a q4_1 block and 32 floats (yl), sumy is SUM(yl[i])
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float block_q_n_dot_y(device const block_q4_1 * qb_curr, float sumy, thread float * yl) {
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float d = qb_curr->d;
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float m = qb_curr->m;
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float4 acc = 0.f;
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device uint16_t * qs = ((device uint16_t *)qb_curr + 2);
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for (int i = 0; i < 16; i+=2) {
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acc[0] += yl[i] * (qs[i / 2] & 0x000F);
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acc[1] += yl[i + 16] * (qs[i / 2] & 0x00F0);
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acc[2] += yl[i + 1] * (qs[i / 2] & 0x0F00);
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acc[3] += yl[i + 17] * (qs[i / 2] & 0xF000);
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}
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return d * (acc[0] + acc[1]/16.f + acc[2]/256.f + acc[3]/4096.f) + sumy * m;
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}
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// putting them in the kernel cause a significant performance penalty
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#define N_DST 4 // each SIMD group works on 4 rows
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#define N_SIMDGROUP 2 // number of SIMD groups in a thread group
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#define N_SIMDWIDTH 32 // assuming SIMD group size is 32
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template<typename block_q_type>
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void mul_vec_q_n_f32(device const void * src0, device const float * src1, device float * dst,
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int64_t ne00, int64_t ne10, int64_t ne0, int64_t ne01,
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uint2 tgpig, uint tiisg, uint sgitg) {
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const int nb = ne00/QK4_0;
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const int r0 = tgpig.x;
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const int r1 = tgpig.y;
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device const block_q_type * x = (device const block_q_type *) src0 + (r0 * N_SIMDGROUP + sgitg) * N_DST * nb;
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device const float * y = (device const float *) src1 + r1*ne10;
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float4 y_curr[8]; // src1 vector cache
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float sumf[N_DST]={0.f}, all_sum;
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thread float * yl=(thread float *)y_curr;
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// each thread in a SIMD group deals with 1 block.
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for (int column = 0; column < nb / N_SIMDWIDTH; column++) {
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float sumy = 0;
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for (int i = 0; i < QK4_0 / 4; i++) {
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y_curr[i] = *((device float4 *)(y + N_SIMDWIDTH * (tiisg + column * QK4_0)) + i);
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sumy += y_curr[i][0] + y_curr[i][1] + y_curr[i][2] + y_curr[i][3];
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}
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for (int row = 0; row < N_DST; row++) {
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sumf[row] += block_q_n_dot_y(x+(tiisg + row * nb + column * N_SIMDWIDTH), sumy, yl);
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}
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}
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// from now loads two rows every time and 16 blocks per row
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int ir = tiisg / (N_SIMDWIDTH / 2);
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int ib = tiisg % (N_SIMDWIDTH / 2);
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for (int ind = 0; ind < (nb % N_SIMDWIDTH + N_SIMDWIDTH / 2 - 1)/(N_SIMDWIDTH / 2); ind++) {
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int nb_start = (nb / N_SIMDWIDTH) * N_SIMDWIDTH + ind * (N_SIMDWIDTH / 2); //where the left blocks start
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float sumy = 0;
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for (int i = 0; i < QK4_0 / 4; i++) {
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y_curr[i] = *((device float4 *)(y + (nb_start + ib) * QK4_0) + i);
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sumy += y_curr[i][0] + y_curr[i][1] + y_curr[i][2] + y_curr[i][3];
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}
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for (int row = 0; row < N_DST; row+=2) {
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if (nb_start + ib < nb) {
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sumf[row + ir] += block_q_n_dot_y(x + (nb_start + ib + (row + ir) * nb), sumy, yl);
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}
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}
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}
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for (int row = 0; row < N_DST; ++row) {
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all_sum = simd_sum(sumf[row]);
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if (tiisg == 0 && ((r0 * N_SIMDGROUP + sgitg) * N_DST + row) < ne01) {
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dst[r1*ne0 + (r0 * N_SIMDGROUP + sgitg) * N_DST + row] = all_sum;
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}
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}
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}
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kernel void kernel_mul_mat_q4_0_f32(
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device const void * src0,
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device const float * src1,
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@ -380,80 +472,7 @@ kernel void kernel_mul_mat_q4_0_f32(
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uint2 tgpig[[threadgroup_position_in_grid]],
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uint tiisg[[thread_index_in_simdgroup]],
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uint sgitg[[simdgroup_index_in_threadgroup]]) {
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const int nb = ne00/QK4_0;
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const int r0 = tgpig.x;
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const int r1 = tgpig.y;
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device const block_q4_0 * x = (device const block_q4_0 *) src0 + (r0 * N_SIMDGROUP + sgitg) * N_DST * nb;
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device const float * y = (device const float *) src1 + r1*ne10;
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block_q4_0 qb_curr, qb_next;
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float4 y_curr[8]; // src1 vector cache
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float sumf[N_DST]={0.f}, all_sum;
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thread float * yl=(thread float *)y_curr;
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// bootstrap
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qb_curr = x[tiisg];
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// each thread in a SIMD group deals with 1 block.
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for (int column = 0; column < nb / N_SIMDWIDTH; column++) {
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float sumy = 0;
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for (int i = 0; i < QK4_0 / 4; i++) {
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y_curr[i] = *((device float4 *)(y + N_SIMDWIDTH * (tiisg + column * QK4_0) + 4 * i));
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sumy += y_curr[i][0] + y_curr[i][1] + y_curr[i][2] + y_curr[i][3];
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}
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sumy *= (-8.f);
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for (int row = 0; row < N_DST; row++) {
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// prefetch next x block
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qb_next = x[tiisg + ((row + 1) % N_DST) * nb + (column + ((row + 1) / N_DST)) * N_SIMDWIDTH];
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// calculate
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float d = qb_curr.d;
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float acc = sumy;
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for (int i = 0; i < 16; i++) {
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acc += yl[i] * (qb_curr.qs[i] & 0xF) + yl[i+16] * (qb_curr.qs[i] >> 4);
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}
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sumf[row] += d * acc;
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qb_curr = qb_next;
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}
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}
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if (nb % N_SIMDWIDTH == 0) {
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for (int row = 0; row < N_DST; ++row) {
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all_sum = simd_sum(sumf[row]);
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if (tiisg == 0 && ((r0 * N_SIMDGROUP + sgitg) * N_DST + row) < ne01) {
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dst[r1*ne0 + (r0 * N_SIMDGROUP + sgitg) * N_DST + row] = all_sum;
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}
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}
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} else {
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float sumy = 0;
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for (int i = 0; i < QK4_0 / 4; i++) {
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y_curr[i] = *((device float4 *)(y + N_SIMDWIDTH * (tiisg + (nb / N_SIMDWIDTH) * QK4_0) + 4 * i));
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sumy += y_curr[i][0] + y_curr[i][1] + y_curr[i][2] + y_curr[i][3];
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}
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sumy *= (-8.f);
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for (int row = 0; row < N_DST; row++) {
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// prefetch next x block
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qb_next = x[tiisg + ((row + 1) % N_DST) * nb + (nb / N_SIMDWIDTH + ((row + 1) / N_DST)) * N_SIMDWIDTH];
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// calculate
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float d = qb_curr.d;
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float acc = sumy;
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for (int i = 0; i < 16; i++) {
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acc += yl[i] * (qb_curr.qs[i] & 0xF) + yl[i+16] * (qb_curr.qs[i] >> 4);
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}
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if (tiisg < nb % N_SIMDWIDTH) {
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sumf[row] += d * acc;
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}
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qb_curr = qb_next;
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all_sum = simd_sum(sumf[row]);
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if (tiisg == 0 && ((r0 * N_SIMDGROUP + sgitg) * N_DST + row) < ne01) {
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dst[r1*ne0 + (r0 * N_SIMDGROUP + sgitg) * N_DST + row] = all_sum;
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}
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}
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}
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mul_vec_q_n_f32<block_q4_0>(src0,src1,dst,ne00,ne10,ne0,ne01,tgpig,tiisg,sgitg);
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}
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kernel void kernel_mul_mat_q4_1_f32(
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@ -467,80 +486,7 @@ kernel void kernel_mul_mat_q4_1_f32(
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uint2 tgpig[[threadgroup_position_in_grid]],
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uint tiisg[[thread_index_in_simdgroup]],
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uint sgitg[[simdgroup_index_in_threadgroup]]) {
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const int nb = ne00/QK4_0;
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const int r0 = tgpig.x;
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const int r1 = tgpig.y;
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device const block_q4_1 * x = (device const block_q4_1 *) src0 + (r0 * N_SIMDGROUP + sgitg) * N_DST * nb;
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device const float * y = (device const float *) src1 + r1*ne10;
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block_q4_1 qb_curr, qb_next;
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float4 y_curr[8]; // src1 vector cache
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float sumf[N_DST]={0.f}, all_sum;
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thread float * yl=(thread float *)y_curr;
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// bootstrap
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qb_curr = x[tiisg];
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// each thread in a SIMD group deals with 1 block.
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for (int column = 0; column < nb / N_SIMDWIDTH; column++) {
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float sumy = 0;
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for (int i = 0; i < QK4_0 / 4; i++) {
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y_curr[i] = *((device float4 *)(y + N_SIMDWIDTH * (tiisg + column * QK4_0) + 4 * i));
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sumy += y_curr[i][0] + y_curr[i][1] + y_curr[i][2] + y_curr[i][3];
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}
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for (int row = 0; row < N_DST; row++) {
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// prefetch next x block
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qb_next = x[tiisg + ((row + 1) % N_DST) * nb + (column + ((row + 1) / N_DST)) * N_SIMDWIDTH];
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// calculate
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const float d = qb_curr.d;
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const float m = qb_curr.m;
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float acc = 0.f;
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for (int i = 0; i < 16; i++) {
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acc += yl[i] * (qb_curr.qs[i] & 0xF) + yl[i+16] * (qb_curr.qs[i] >> 4);
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}
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sumf[row] += d * acc + m * sumy;
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qb_curr = qb_next;
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}
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}
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if (nb % N_SIMDWIDTH == 0) {
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for (int row = 0; row < N_DST; ++row) {
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all_sum = simd_sum(sumf[row]);
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if (tiisg == 0 && ((r0 * N_SIMDGROUP + sgitg) * N_DST + row) < ne01) {
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dst[r1*ne0 + (r0 * N_SIMDGROUP + sgitg) * N_DST + row] = all_sum;
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}
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}
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} else {
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float sumy = 0;
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for (int i = 0; i < QK4_0 / 4; i++) {
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y_curr[i] = *((device float4 *)(y + N_SIMDWIDTH * (tiisg + (nb / N_SIMDWIDTH) * QK4_0) + 4 * i));
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sumy += y_curr[i][0] + y_curr[i][1] + y_curr[i][2] + y_curr[i][3];
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}
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for (int row = 0; row < N_DST; row++) {
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// prefetch next x block
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qb_next = x[tiisg + ((row + 1) % N_DST) * nb + (nb / N_SIMDWIDTH + ((row + 1) / N_DST)) * N_SIMDWIDTH];
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// calculate
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const float d = qb_curr.d;
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const float m = qb_curr.m;
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float acc = 0.f;
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for (int i = 0; i < 16; i++) {
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acc += yl[i] * (qb_curr.qs[i] & 0xF) + yl[i+16] * (qb_curr.qs[i] >> 4);
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}
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if (tiisg < nb % N_SIMDWIDTH) {
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sumf[row] += d * acc + m * sumy;
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}
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qb_curr = qb_next;
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all_sum = simd_sum(sumf[row]);
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if (tiisg == 0 && ((r0 * N_SIMDGROUP + sgitg) * N_DST + row) < ne01) {
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dst[r1*ne0 + (r0 * N_SIMDGROUP + sgitg) * N_DST + row] = all_sum;
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}
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}
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}
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mul_vec_q_n_f32<block_q4_1>(src0,src1,dst,ne00,ne10,ne0,ne01,tgpig,tiisg,sgitg);
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}
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kernel void kernel_mul_mat_f16_f32(
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