#define GGML_COMMON_DECL_METAL #define GGML_COMMON_IMPL_METAL #if defined(GGML_METAL_EMBED_LIBRARY) __embed_ggml-common.h__ #else #include "ggml-common.h" #endif #include "ggml-metal-impl.h" #include #ifdef GGML_METAL_HAS_TENSOR #include #include #endif using namespace metal; #define MAX(x, y) ((x) > (y) ? (x) : (y)) #define MIN(x, y) ((x) < (y) ? (x) : (y)) #define SWAP(x, y) { auto tmp = (x); (x) = (y); (y) = tmp; } #define PAD2(x, n) (((x) + (n) - 1) & ~((n) - 1)) #define FOR_UNROLL(x) _Pragma("clang loop unroll(full)") for (x) #define N_SIMDWIDTH 32 // assuming SIMD group size is 32 // ref: https://developer.apple.com/metal/Metal-Shading-Language-Specification.pdf // // cmd: // .../usr/bin/metal -dM -E -c ggml/src/ggml-metal/ggml-metal.metal // .../usr/bin/metal -dM -E -c -target air64-apple-ios14.0 ggml/src/ggml-metal/ggml-metal.metal // #if __METAL_VERSION__ < 310 && defined(GGML_METAL_HAS_BF16) #undef GGML_METAL_HAS_BF16 #endif #if defined(GGML_METAL_HAS_BF16) typedef matrix bfloat4x4; typedef matrix bfloat2x4; #endif constexpr constant static float kvalues_iq4nl_f[16] = { -127.f, -104.f, -83.f, -65.f, -49.f, -35.f, -22.f, -10.f, 1.f, 13.f, 25.f, 38.f, 53.f, 69.f, 89.f, 113.f }; constexpr constant static float kvalues_mxfp4_f[16] = { 0, .5f, 1.f, 1.5f, 2.f, 3.f, 4.f, 6.f, -0, -.5f, -1.f, -1.5f, -2.f, -3.f, -4.f, -6.f }; static inline int best_index_int8(int n, constant float * val, float x) { if (x <= val[0]) return 0; if (x >= val[n-1]) return n-1; int ml = 0, mu = n-1; while (mu-ml > 1) { int mav = (ml+mu)/2; if (x < val[mav]) mu = mav; else ml = mav; } return x - val[mu-1] < val[mu] - x ? mu-1 : mu; } static inline float e8m0_to_fp32(uint8_t x) { uint32_t bits; if (x == 0) { bits = 0x00400000; } else { bits = (uint32_t) x << 23; } return as_type(bits); } static inline float dot(float x, float y) { return x*y; } // NOTE: this is not dequantizing - we are simply fitting the template template void dequantize_f32(device const float4x4 * src, short il, thread type4x4 & reg) { reg = (type4x4)(*src); } template void dequantize_f32_t4(device const float4 * src, short il, thread type4 & reg) { reg = (type4)(*src); } template void dequantize_f16(device const half4x4 * src, short il, thread type4x4 & reg) { reg = (type4x4)(*src); } template void dequantize_f16_t4(device const half4 * src, short il, thread type4 & reg) { reg = (type4)(*(src)); } #if defined(GGML_METAL_HAS_BF16) template void dequantize_bf16(device const bfloat4x4 * src, short il, thread type4x4 & reg) { reg = (type4x4)(*src); } template void dequantize_bf16_t4(device const bfloat4 * src, short il, thread type4 & reg) { reg = (type4)(*(src)); } #endif template void dequantize_q4_0(device const block_q4_0 * xb, short il, thread type4x4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 1); const float d1 = il ? (xb->d / 16.h) : xb->d; const float d2 = d1 / 256.f; const float md = -8.h * xb->d; const ushort mask0 = il ? 0x00F0 : 0x000F; const ushort mask1 = mask0 << 8; float4x4 reg_f; for (int i = 0; i < 8; i++) { reg_f[i/2][2*(i%2) + 0] = d1 * (qs[i] & mask0) + md; reg_f[i/2][2*(i%2) + 1] = d2 * (qs[i] & mask1) + md; } reg = (type4x4) reg_f; } template void dequantize_q4_0_t4(device const block_q4_0 * xb, short il, thread type4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 1); const float d1 = (il/4) ? (xb->d / 16.h) : xb->d; const float d2 = d1 / 256.f; const float md = -8.h * xb->d; const ushort mask0 = (il/4) ? 0x00F0 : 0x000F; const ushort mask1 = mask0 << 8; for (int i = 0; i < 2; i++) { reg[2*i + 0] = d1 * (qs[2*(il%4) + i] & mask0) + md; reg[2*i + 1] = d2 * (qs[2*(il%4) + i] & mask1) + md; } } void quantize_q4_0(device const float * src, device block_q4_0 & dst) { #pragma METAL fp math_mode(safe) float amax = 0.0f; // absolute max float max = 0.0f; for (int j = 0; j < QK4_0; j++) { const float v = src[j]; if (amax < fabs(v)) { amax = fabs(v); max = v; } } const float d = max / -8; const float id = d ? 1.0f/d : 0.0f; dst.d = d; for (int j = 0; j < QK4_0/2; ++j) { const float x0 = src[0 + j]*id; const float x1 = src[QK4_0/2 + j]*id; const uint8_t xi0 = MIN(15, (int8_t)(x0 + 8.5f)); const uint8_t xi1 = MIN(15, (int8_t)(x1 + 8.5f)); dst.qs[j] = xi0; dst.qs[j] |= xi1 << 4; } } void quantize_q4_1(device const float * src, device block_q4_1 & dst) { #pragma METAL fp math_mode(safe) float min = FLT_MAX; float max = -FLT_MAX; for (int j = 0; j < QK4_1; j++) { const float v = src[j]; if (min > v) min = v; if (max < v) max = v; } const float d = (max - min) / ((1 << 4) - 1); const float id = d ? 1.0f/d : 0.0f; dst.d = d; dst.m = min; for (int j = 0; j < QK4_1/2; ++j) { const float x0 = (src[0 + j] - min)*id; const float x1 = (src[QK4_1/2 + j] - min)*id; const uint8_t xi0 = MIN(15, (int8_t)(x0 + 0.5f)); const uint8_t xi1 = MIN(15, (int8_t)(x1 + 0.5f)); dst.qs[j] = xi0; dst.qs[j] |= xi1 << 4; } } void quantize_q5_0(device const float * src, device block_q5_0 & dst) { #pragma METAL fp math_mode(safe) float amax = 0.0f; // absolute max float max = 0.0f; for (int j = 0; j < QK5_0; j++) { const float v = src[j]; if (amax < fabs(v)) { amax = fabs(v); max = v; } } const float d = max / -16; const float id = d ? 1.0f/d : 0.0f; dst.d = d; uint32_t qh = 0; for (int j = 0; j < QK5_0/2; ++j) { const float x0 = src[0 + j]*id; const float x1 = src[QK5_0/2 + j]*id; const uint8_t xi0 = MIN(31, (int8_t)(x0 + 16.5f)); const uint8_t xi1 = MIN(31, (int8_t)(x1 + 16.5f)); dst.qs[j] = (xi0 & 0xf) | ((xi1 & 0xf) << 4); qh |= ((xi0 & 0x10u) >> 4) << (j + 0); qh |= ((xi1 & 0x10u) >> 4) << (j + QK5_0/2); } thread const uint8_t * qh8 = (thread const uint8_t *)&qh; for (int j = 0; j < 4; ++j) { dst.qh[j] = qh8[j]; } } void quantize_q5_1(device const float * src, device block_q5_1 & dst) { #pragma METAL fp math_mode(safe) float max = src[0]; float min = src[0]; for (int j = 1; j < QK5_1; j++) { const float v = src[j]; min = v < min ? v : min; max = v > max ? v : max; } const float d = (max - min) / 31; const float id = d ? 1.0f/d : 0.0f; dst.d = d; dst.m = min; uint32_t qh = 0; for (int j = 0; j < QK5_1/2; ++j) { const float x0 = (src[0 + j] - min)*id; const float x1 = (src[QK5_1/2 + j] - min)*id; const uint8_t xi0 = (uint8_t)(x0 + 0.5f); const uint8_t xi1 = (uint8_t)(x1 + 0.5f); dst.qs[j] = (xi0 & 0xf) | ((xi1 & 0xf) << 4); qh |= ((xi0 & 0x10u) >> 4) << (j + 0); qh |= ((xi1 & 0x10u) >> 4) << (j + QK5_1/2); } thread const uint8_t * qh8 = (thread const uint8_t *)&qh; for (int j = 0; j < 4; ++j) { dst.qh[j] = qh8[j]; } } void quantize_q8_0(device const float * src, device block_q8_0 & dst) { #pragma METAL fp math_mode(safe) float amax = 0.0f; // absolute max for (int j = 0; j < QK8_0; j++) { const float v = src[j]; amax = MAX(amax, fabs(v)); } const float d = amax / ((1 << 7) - 1); const float id = d ? 1.0f/d : 0.0f; dst.d = d; for (int j = 0; j < QK8_0; ++j) { const float x0 = src[j]*id; dst.qs[j] = round(x0); } } void quantize_iq4_nl(device const float * src, device block_iq4_nl & dst) { #pragma METAL fp math_mode(safe) float amax = 0.0f; // absolute max float max = 0.0f; for (int j = 0; j < QK4_NL; j++) { const float v = src[j]; if (amax < fabs(v)) { amax = fabs(v); max = v; } } const float d = max / kvalues_iq4nl_f[0]; const float id = d ? 1.0f/d : 0.0f; float sumqx = 0, sumq2 = 0; for (int j = 0; j < QK4_NL/2; ++j) { const float x0 = src[0 + j]*id; const float x1 = src[QK4_NL/2 + j]*id; const uint8_t xi0 = best_index_int8(16, kvalues_iq4nl_f, x0); const uint8_t xi1 = best_index_int8(16, kvalues_iq4nl_f, x1); dst.qs[j] = xi0 | (xi1 << 4); const float v0 = kvalues_iq4nl_f[xi0]; const float v1 = kvalues_iq4nl_f[xi1]; const float w0 = src[0 + j]*src[0 + j]; const float w1 = src[QK4_NL/2 + j]*src[QK4_NL/2 + j]; sumqx += w0*v0*src[j] + w1*v1*src[QK4_NL/2 + j]; sumq2 += w0*v0*v0 + w1*v1*v1; } dst.d = sumq2 > 0 ? sumqx/sumq2 : d; } template void dequantize_q4_1(device const block_q4_1 * xb, short il, thread type4x4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 2); const float d1 = il ? (xb->d / 16.h) : xb->d; const float d2 = d1 / 256.f; const float m = xb->m; const ushort mask0 = il ? 0x00F0 : 0x000F; const ushort mask1 = mask0 << 8; float4x4 reg_f; for (int i = 0; i < 8; i++) { reg_f[i/2][2*(i%2) + 0] = ((qs[i] & mask0) * d1) + m; reg_f[i/2][2*(i%2) + 1] = ((qs[i] & mask1) * d2) + m; } reg = (type4x4) reg_f; } template void dequantize_q4_1_t4(device const block_q4_1 * xb, short il, thread type4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 2); const float d1 = (il/4) ? (xb->d / 16.h) : xb->d; const float d2 = d1 / 256.f; const float m = xb->m; const ushort mask0 = (il/4) ? 0x00F0 : 0x000F; const ushort mask1 = mask0 << 8; for (int i = 0; i < 2; i++) { reg[2*i + 0] = d1 * (qs[2*(il%4) + i] & mask0) + m; reg[2*i + 1] = d2 * (qs[2*(il%4) + i] & mask1) + m; } } template void dequantize_q5_0(device const block_q5_0 * xb, short il, thread type4x4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 3); const float d = xb->d; const float md = -16.h * xb->d; const ushort mask = il ? 0x00F0 : 0x000F; const uint32_t qh = *((device const uint32_t *)xb->qh); const int x_mv = il ? 4 : 0; const int gh_mv = il ? 12 : 0; const int gh_bk = il ? 0 : 4; float4x4 reg_f; for (int i = 0; i < 8; i++) { // extract the 5-th bits for x0 and x1 const uint8_t xh_0 = ((qh >> (gh_mv + 2*i )) << gh_bk) & 0x10; const uint8_t xh_1 = ((qh >> (gh_mv + 2*i+1)) << gh_bk) & 0x10; // combine the 4-bits from qs with the 5th bit const int32_t x0 = ((((qs[i] ) & mask) >> x_mv) | xh_0); const int32_t x1 = ((((qs[i] >> 8) & mask) >> x_mv) | xh_1); reg_f[i/2][2*(i%2) + 0] = d * x0 + md; reg_f[i/2][2*(i%2) + 1] = d * x1 + md; } reg = (type4x4) reg_f; } template void dequantize_q5_0_t4(device const block_q5_0 * xb, short il, thread type4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 3); const float d = xb->d; const float md = -16.h * xb->d; const ushort mask = (il/4) ? 0x00F0 : 0x000F; const uint32_t qh = *((device const uint32_t *)xb->qh); const int x_mv = (il/4) ? 4 : 0; const int gh_mv = (il/4) ? 12 : 0; const int gh_bk = (il/4) ? 0 : 4; for (int ii = 0; ii < 2; ii++) { int i = 2*(il%4) + ii; // extract the 5-th bits for x0 and x1 const uint8_t xh_0 = ((qh >> (gh_mv + 2*i )) << gh_bk) & 0x10; const uint8_t xh_1 = ((qh >> (gh_mv + 2*i+1)) << gh_bk) & 0x10; // combine the 4-bits from qs with the 5th bit const int32_t x0 = ((((qs[i] ) & mask) >> x_mv) | xh_0); const int32_t x1 = ((((qs[i] >> 8) & mask) >> x_mv) | xh_1); reg[2*ii + 0] = d * x0 + md; reg[2*ii + 1] = d * x1 + md; } } template void dequantize_q5_1(device const block_q5_1 * xb, short il, thread type4x4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 4); const float d = xb->d; const float m = xb->m; const ushort mask = il ? 0x00F0 : 0x000F; const uint32_t qh = *((device const uint32_t *)xb->qh); const int x_mv = il ? 4 : 0; const int gh_mv = il ? 12 : 0; const int gh_bk = il ? 0 : 4; float4x4 reg_f; for (int i = 0; i < 8; i++) { // extract the 5-th bits for x0 and x1 const uint8_t xh_0 = ((qh >> (gh_mv + 2*i )) << gh_bk) & 0x10; const uint8_t xh_1 = ((qh >> (gh_mv + 2*i+1)) << gh_bk) & 0x10; // combine the 4-bits from qs with the 5th bit const int32_t x0 = ((((qs[i] ) & mask) >> x_mv) | xh_0); const int32_t x1 = ((((qs[i] >> 8) & mask) >> x_mv) | xh_1); reg_f[i/2][2*(i%2) + 0] = d * x0 + m; reg_f[i/2][2*(i%2) + 1] = d * x1 + m; } reg = (type4x4) reg_f; } template void dequantize_q5_1_t4(device const block_q5_1 * xb, short il, thread type4 & reg) { device const uint16_t * qs = ((device const uint16_t *)xb + 4); const float d = xb->d; const float m = xb->m; const ushort mask = (il/4) ? 0x00F0 : 0x000F; const uint32_t qh = *((device const uint32_t *)xb->qh); const int x_mv = (il/4) ? 4 : 0; const int gh_mv = (il/4) ? 12 : 0; const int gh_bk = (il/4) ? 0 : 4; for (int ii = 0; ii < 2; ii++) { int i = 2*(il%4) + ii; // extract the 5-th bits for x0 and x1 const uint8_t xh_0 = ((qh >> (gh_mv + 2*i )) << gh_bk) & 0x10; const uint8_t xh_1 = ((qh >> (gh_mv + 2*i+1)) << gh_bk) & 0x10; // combine the 4-bits from qs with the 5th bit const int32_t x0 = ((((qs[i] ) & mask) >> x_mv) | xh_0); const int32_t x1 = ((((qs[i] >> 8) & mask) >> x_mv) | xh_1); reg[2*ii + 0] = d * x0 + m; reg[2*ii + 1] = d * x1 + m; } } template void dequantize_q8_0(device const block_q8_0 *xb, short il, thread type4x4 & reg) { device const int8_t * qs = ((device const int8_t *)xb->qs); const float d = xb->d; float4x4 reg_f; for (int i = 0; i < 16; i++) { reg_f[i/4][i%4] = (qs[i + 16*il] * d); } reg = (type4x4) reg_f; } template void dequantize_q8_0_t4(device const block_q8_0 *xb, short il, thread type4 & reg) { device const int8_t * qs = ((device const int8_t *)xb->qs); const float d = xb->d; for (int i = 0; i < 4; i++) { reg[i] = (qs[4*(il%4) + i + 16*(il/4)] * d); } } template void dequantize_mxfp4(device const block_mxfp4 * xb, short il, thread type4x4 & reg) { device const uint8_t * q2 = (device const uint8_t *)xb->qs; const float d = e8m0_to_fp32(xb->e); const uint8_t shr = il >= 1 ? 4 : 0; for (int i = 0; i < 4; ++i) { reg[i][0] = d * kvalues_mxfp4_f[(q2[4*i + 0] >> shr) & 0x0F]; reg[i][1] = d * kvalues_mxfp4_f[(q2[4*i + 1] >> shr) & 0x0F]; reg[i][2] = d * kvalues_mxfp4_f[(q2[4*i + 2] >> shr) & 0x0F]; reg[i][3] = d * kvalues_mxfp4_f[(q2[4*i + 3] >> shr) & 0x0F]; } } template void dequantize_mxfp4_t4(device const block_mxfp4 * xb, short il, thread type4 & reg) { device const uint8_t * q2 = (device const uint8_t *)xb->qs; const float d = e8m0_to_fp32(xb->e); const short il4 = il%4; const uint8_t shr = il >= 4 ? 4 : 0; reg[0] = d * kvalues_mxfp4_f[(q2[4*il4 + 0] >> shr) & 0x0F]; reg[1] = d * kvalues_mxfp4_f[(q2[4*il4 + 1] >> shr) & 0x0F]; reg[2] = d * kvalues_mxfp4_f[(q2[4*il4 + 2] >> shr) & 0x0F]; reg[3] = d * kvalues_mxfp4_f[(q2[4*il4 + 3] >> shr) & 0x0F]; } template void dequantize_q2_K(device const block_q2_K *xb, short il, thread type4x4 & reg) { const float d = xb->d; const float min = xb->dmin; device const uint8_t * q = (device const uint8_t *)xb->qs; float dl, ml; uint8_t sc = xb->scales[il]; q = q + 32*(il/8) + 16*(il&1); il = (il/2)%4; half coef = il>1 ? (il>2 ? 1/64.h : 1/16.h) : (il>0 ? 1/4.h : 1.h); uchar mask = il>1 ? (il>2 ? 192 : 48) : (il>0 ? 12 : 3); dl = d * (sc & 0xF) * coef, ml = min * (sc >> 4); for (int i = 0; i < 16; ++i) { reg[i/4][i%4] = dl * (q[i] & mask) - ml; } } template void dequantize_q3_K(device const block_q3_K *xb, short il, thread type4x4 & reg) { const half d_all = xb->d; device const uint8_t * q = (device const uint8_t *)xb->qs; device const uint8_t * h = (device const uint8_t *)xb->hmask; device const int8_t * scales = (device const int8_t *)xb->scales; q = q + 32 * (il/8) + 16 * (il&1); h = h + 16 * (il&1); uint8_t m = 1 << (il/2); uint16_t kmask1 = (il/4)>1 ? ((il/4)>2 ? 192 : 48) : \ ((il/4)>0 ? 12 : 3); uint16_t kmask2 = il/8 ? 0xF0 : 0x0F; uint16_t scale_2 = scales[il%8], scale_1 = scales[8 + il%4]; int16_t dl_int = (il/4)&1 ? (scale_2&kmask2) | ((scale_1&kmask1) << 2) : (scale_2&kmask2) | ((scale_1&kmask1) << 4); float dl = il<8 ? d_all * (dl_int - 32.f) : d_all * (dl_int / 16.f - 32.f); const float ml = 4.f * dl; il = (il/2) & 3; const half coef = il>1 ? (il>2 ? 1/64.h : 1/16.h) : (il>0 ? 1/4.h : 1.h); const uint8_t mask = il>1 ? (il>2 ? 192 : 48) : (il>0 ? 12 : 3); dl *= coef; for (int i = 0; i < 16; ++i) { reg[i/4][i%4] = dl * (q[i] & mask) - (h[i] & m ? 0 : ml); } } static inline uchar2 get_scale_min_k4_just2(int j, int k, device const uchar * q) { return j < 4 ? uchar2{uchar(q[j+0+k] & 63), uchar(q[j+4+k] & 63)} : uchar2{uchar((q[j+4+k] & 0xF) | ((q[j-4+k] & 0xc0) >> 2)), uchar((q[j+4+k] >> 4) | ((q[j-0+k] & 0xc0) >> 2))}; } template void dequantize_q4_K(device const block_q4_K * xb, short il, thread type4x4 & reg) { device const uchar * q = xb->qs; short is = (il/4) * 2; q = q + (il/4) * 32 + 16 * (il&1); il = il & 3; const uchar2 sc = get_scale_min_k4_just2(is, il/2, xb->scales); const float d = il < 2 ? xb->d : xb->d / 16.h; const float min = xb->dmin; const float dl = d * sc[0]; const float ml = min * sc[1]; const ushort mask = il < 2 ? 0x0F : 0xF0; for (int i = 0; i < 16; ++i) { reg[i/4][i%4] = dl * (q[i] & mask) - ml; } } template void dequantize_q5_K(device const block_q5_K *xb, short il, thread type4x4 & reg) { device const uint8_t * q = xb->qs; device const uint8_t * qh = xb->qh; short is = (il/4) * 2; q = q + 32 * (il/4) + 16 * (il&1); qh = qh + 16 * (il&1); uint8_t ul = 1 << (il/2); il = il & 3; const uchar2 sc = get_scale_min_k4_just2(is, il/2, xb->scales); const float d = il < 2 ? xb->d : xb->d / 16.f; const float min = xb->dmin; const float dl = d * sc[0]; const float ml = min * sc[1]; const ushort mask = il<2 ? 0x0F : 0xF0; const float qh_val = il<2 ? 16.f : 256.f; for (int i = 0; i < 16; ++i) { reg[i/4][i%4] = dl * ((q[i] & mask) + (qh[i] & ul ? qh_val : 0)) - ml; } } template void dequantize_q6_K(device const block_q6_K *xb, short il, thread type4x4 & reg) { const half d_all = xb->d; device const uint16_t * ql = (device const uint16_t *)xb->ql; device const uint16_t * qh = (device const uint16_t *)xb->qh; device const int8_t * scales = (device const int8_t *)xb->scales; ql = ql + 32*(il/8) + 16*((il/2)&1) + 8*(il&1); qh = qh + 16*(il/8) + 8*(il&1); float sc = scales[(il%2) + 2 * ((il/2))]; il = (il/2) & 3; const uint32_t kmask1 = il>1 ? (il>2 ? 0xC0C0C0C0 : 0x30303030) : (il>0 ? 0x0C0C0C0C : 0x03030303); const uint32_t kmask2 = il>1 ? 0xF0F0F0F0 : 0x0F0F0F0F; const float ml = d_all * sc * 32.f; const float dl0 = d_all * sc; const float dl1 = dl0 / 256.f; const float dl2 = dl0 / (256.f * 256.f); const float dl3 = dl0 / (256.f * 256.f * 256.f); const uint8_t shr_h = il>2 ? 2 : 0; const uint8_t shl_h = il>1 ? 0 : (il>0 ? 2 : 4); const uint8_t shr_l = il>1 ? 4 : 0; for (int i = 0; i < 4; ++i) { const uint32_t low = (ql[2*i] | (uint32_t)(ql[2*i+1] << 16)) & kmask2; const uint32_t high = (qh[2*i] | (uint32_t)(qh[2*i+1] << 16)) & kmask1; const uint32_t q = ((high << shl_h) >> shr_h) | (low >> shr_l); reg[i][0] = dl0 * ((half)(q & 0xFF)) - ml; reg[i][1] = dl1 * ((float)(q & 0xFF00)) - ml; reg[i][2] = dl2 * ((float)(q & 0xFF0000)) - ml; reg[i][3] = dl3 * ((float)(q & 0xFF000000)) - ml; } } template void dequantize_iq2_xxs(device const block_iq2_xxs * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const float d = xb->d; const int ib32 = il/2; il = il%2; // il = 0 or 1. il = 0 processes the first 16 quants in a block of 32, il = 1 the second 16 // each block of 32 needs 2 uint32_t's for the quants & scale, so 4 uint16_t's. device const uint16_t * q2 = xb->qs + 4*ib32; const uint32_t aux32_g = q2[0] | (q2[1] << 16); const uint32_t aux32_s = q2[2] | (q2[3] << 16); thread const uint8_t * aux8 = (thread const uint8_t *)&aux32_g; const float dl = d * (0.5f + (aux32_s >> 28)) * 0.25f; constant uint8_t * grid = (constant uint8_t *)(iq2xxs_grid + aux8[2*il+0]); uint8_t signs = ksigns_iq2xs[(aux32_s >> 14*il) & 127]; for (int i = 0; i < 8; ++i) { reg[i/4][i%4] = dl * grid[i] * (signs & kmask_iq2xs[i] ? -1.f : 1.f); } grid = (constant uint8_t *)(iq2xxs_grid + aux8[2*il+1]); signs = ksigns_iq2xs[(aux32_s >> (14*il+7)) & 127]; for (int i = 0; i < 8; ++i) { reg[2+i/4][i%4] = dl * grid[i] * (signs & kmask_iq2xs[i] ? -1.f : 1.f); } } template void dequantize_iq2_xs(device const block_iq2_xs * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const float d = xb->d; const int ib32 = il/2; il = il%2; // il = 0 or 1. il = 0 processes the first 16 quants in a block of 32, il = 1 the second 16 device const uint16_t * q2 = xb->qs + 4*ib32; const float dl = d * (0.5f + ((xb->scales[ib32] >> 4*il) & 0xf)) * 0.25f; constant uint8_t * grid = (constant uint8_t *)(iq2xs_grid + (q2[2*il+0] & 511)); uint8_t signs = ksigns_iq2xs[q2[2*il+0] >> 9]; for (int i = 0; i < 8; ++i) { reg[i/4][i%4] = dl * grid[i] * (signs & kmask_iq2xs[i] ? -1.f : 1.f); } grid = (constant uint8_t *)(iq2xs_grid + (q2[2*il+1] & 511)); signs = ksigns_iq2xs[q2[2*il+1] >> 9]; for (int i = 0; i < 8; ++i) { reg[2+i/4][i%4] = dl * grid[i] * (signs & kmask_iq2xs[i] ? -1.f : 1.f); } } template void dequantize_iq3_xxs(device const block_iq3_xxs * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const float d = xb->d; const int ib32 = il/2; il = il%2; // il = 0 or 1. il = 0 processes the first 16 quants in a block of 32, il = 1 the second 16 device const uint8_t * q3 = xb->qs + 8*ib32; device const uint16_t * gas = (device const uint16_t *)(xb->qs + QK_K/4) + 2*ib32; const uint32_t aux32 = gas[0] | (gas[1] << 16); const float dl = d * (0.5f + (aux32 >> 28)) * 0.5f; constant uint8_t * grid1 = (constant uint8_t *)(iq3xxs_grid + q3[4*il+0]); constant uint8_t * grid2 = (constant uint8_t *)(iq3xxs_grid + q3[4*il+1]); uint8_t signs = ksigns_iq2xs[(aux32 >> 14*il) & 127]; for (int i = 0; i < 4; ++i) { reg[0][i] = dl * grid1[i] * (signs & kmask_iq2xs[i+0] ? -1.f : 1.f); reg[1][i] = dl * grid2[i] * (signs & kmask_iq2xs[i+4] ? -1.f : 1.f); } grid1 = (constant uint8_t *)(iq3xxs_grid + q3[4*il+2]); grid2 = (constant uint8_t *)(iq3xxs_grid + q3[4*il+3]); signs = ksigns_iq2xs[(aux32 >> (14*il+7)) & 127]; for (int i = 0; i < 4; ++i) { reg[2][i] = dl * grid1[i] * (signs & kmask_iq2xs[i+0] ? -1.f : 1.f); reg[3][i] = dl * grid2[i] * (signs & kmask_iq2xs[i+4] ? -1.f : 1.f); } } template void dequantize_iq3_s(device const block_iq3_s * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const float d = xb->d; const int ib32 = il/2; il = il%2; // il = 0 or 1. il = 0 processes the first 16 quants in a block of 32, il = 1 the second 16 device const uint8_t * qs = xb->qs + 8*ib32; device const uint8_t * signs = xb->signs + 4*ib32 + 2*il; const uint8_t qh = xb->qh[ib32] >> 4*il; const float dl = d * (1 + 2*((xb->scales[ib32/2] >> 4*(ib32%2)) & 0xf)); constant uint8_t * grid1 = (constant uint8_t *)(iq3s_grid + (qs[4*il+0] | ((qh << 8) & 256))); constant uint8_t * grid2 = (constant uint8_t *)(iq3s_grid + (qs[4*il+1] | ((qh << 7) & 256))); for (int i = 0; i < 4; ++i) { reg[0][i] = dl * grid1[i] * select(1, -1, signs[0] & kmask_iq2xs[i+0]); reg[1][i] = dl * grid2[i] * select(1, -1, signs[0] & kmask_iq2xs[i+4]); } grid1 = (constant uint8_t *)(iq3s_grid + (qs[4*il+2] | ((qh << 6) & 256))); grid2 = (constant uint8_t *)(iq3s_grid + (qs[4*il+3] | ((qh << 5) & 256))); for (int i = 0; i < 4; ++i) { reg[2][i] = dl * grid1[i] * select(1, -1, signs[1] & kmask_iq2xs[i+0]); reg[3][i] = dl * grid2[i] * select(1, -1, signs[1] & kmask_iq2xs[i+4]); } } template void dequantize_iq2_s(device const block_iq2_s * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const float d = xb->d; const int ib32 = il/2; il = il%2; // il = 0 or 1. il = 0 processes the first 16 quants in a block of 32, il = 1 the second 16 device const uint8_t * qs = xb->qs + 4*ib32 + 2*il; device const uint8_t * signs = qs + QK_K/8; const uint8_t qh = xb->qh[ib32] >> 4*il; const float dl = d * (0.5f + ((xb->scales[ib32] >> 4*il) & 0xf)) * 0.25f; constant uint8_t * grid1 = (constant uint8_t *)(iq2s_grid + (qs[0] | ((qh << 8) & 0x300))); constant uint8_t * grid2 = (constant uint8_t *)(iq2s_grid + (qs[1] | ((qh << 6) & 0x300))); for (int i = 0; i < 8; ++i) { reg[i/4+0][i%4] = dl * grid1[i] * select(1, -1, signs[0] & kmask_iq2xs[i]); reg[i/4+2][i%4] = dl * grid2[i] * select(1, -1, signs[1] & kmask_iq2xs[i]); } } template void dequantize_iq1_s(device const block_iq1_s * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const int ib32 = il/2; il = il%2; const float d = xb->d; device const uint8_t * qs = xb->qs + 4*ib32 + 2*il; device const uint16_t * qh = xb->qh; const float dl = d * (2*((qh[ib32] >> 12) & 7) + 1); const float ml = dl * (qh[ib32] & 0x8000 ? -1 - IQ1S_DELTA : -1 + IQ1S_DELTA); const uint16_t h = qh[ib32] >> 6*il; constant uint8_t * grid1 = (constant uint8_t *)(iq1s_grid_gpu + (qs[0] | ((h << 8) & 0x700))); constant uint8_t * grid2 = (constant uint8_t *)(iq1s_grid_gpu + (qs[1] | ((h << 5) & 0x700))); for (int i = 0; i < 4; ++i) { reg[0][i] = dl * (grid1[i] & 0xf) + ml; reg[1][i] = dl * (grid1[i] >> 4) + ml; reg[2][i] = dl * (grid2[i] & 0xf) + ml; reg[3][i] = dl * (grid2[i] >> 4) + ml; } } template void dequantize_iq1_m(device const block_iq1_m * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const int ib32 = il/2; il = il%2; device const uint16_t * sc = (device const uint16_t *)xb->scales; iq1m_scale_t scale; scale.u16 = (sc[0] >> 12) | ((sc[1] >> 8) & 0x00f0) | ((sc[2] >> 4) & 0x0f00) | (sc[3] & 0xf000); const float d = scale.f16; device const uint8_t * qs = xb->qs + 4*ib32 + 2*il; device const uint8_t * qh = xb->qh + 2*ib32 + il; const float dl = d * (2*((sc[ib32/2] >> (6*(ib32%2)+3*il)) & 7) + 1); const float ml1 = dl * (qh[0] & 0x08 ? -1 - IQ1M_DELTA : -1 + IQ1M_DELTA); const float ml2 = dl * (qh[0] & 0x80 ? -1 - IQ1M_DELTA : -1 + IQ1M_DELTA); constant uint8_t * grid1 = (constant uint8_t *)(iq1s_grid_gpu + (qs[0] | ((qh[0] << 8) & 0x700))); constant uint8_t * grid2 = (constant uint8_t *)(iq1s_grid_gpu + (qs[1] | ((qh[0] << 4) & 0x700))); for (int i = 0; i < 4; ++i) { reg[0][i] = dl * (grid1[i] & 0xf) + ml1; reg[1][i] = dl * (grid1[i] >> 4) + ml1; reg[2][i] = dl * (grid2[i] & 0xf) + ml2; reg[3][i] = dl * (grid2[i] >> 4) + ml2; } } template void dequantize_iq4_nl(device const block_iq4_nl * xb, short il, thread type4x4 & reg) { device const uint16_t * q4 = (device const uint16_t *)xb->qs; const float d = xb->d; uint32_t aux32; thread const uint8_t * q8 = (thread const uint8_t *)&aux32; for (int i = 0; i < 4; ++i) { aux32 = ((q4[2*i] | (q4[2*i+1] << 16)) >> 4*il) & 0x0f0f0f0f; reg[i][0] = d * kvalues_iq4nl_f[q8[0]]; reg[i][1] = d * kvalues_iq4nl_f[q8[1]]; reg[i][2] = d * kvalues_iq4nl_f[q8[2]]; reg[i][3] = d * kvalues_iq4nl_f[q8[3]]; } } template void dequantize_iq4_nl_t4(device const block_iq4_nl * xb, short il, thread type4 & reg) { device const uint16_t * q4 = (device const uint16_t *)xb->qs; const float d = xb->d; uint32_t aux32; thread const uint8_t * q8 = (thread const uint8_t *)&aux32; aux32 = ((q4[2*(il%4)] | (q4[2*(il%4)+1] << 16)) >> 4*(il/4)) & 0x0f0f0f0f; reg[0] = d * kvalues_iq4nl_f[q8[0]]; reg[1] = d * kvalues_iq4nl_f[q8[1]]; reg[2] = d * kvalues_iq4nl_f[q8[2]]; reg[3] = d * kvalues_iq4nl_f[q8[3]]; } template void dequantize_iq4_xs(device const block_iq4_xs * xb, short il, thread type4x4 & reg) { // il is 0...15 for QK_K = 256 => index of block of 32 is il/2 const int ib32 = il/2; il = il%2; // il = 0 or 1. il = 0 processes the first 16 quants in a block of 32, il = 1 the second 16 device const uint32_t * q4 = (device const uint32_t *)xb->qs + 4*ib32; const int ls = ((xb->scales_l[ib32/2] >> 4*(ib32%2)) & 0xf) | (((xb->scales_h >> 2*ib32) & 3) << 4); const float d = (float)xb->d * (ls - 32); uint32_t aux32; thread const uint8_t * q8 = (thread const uint8_t *)&aux32; for (int i = 0; i < 4; ++i) { aux32 = (q4[i] >> 4*il) & 0x0f0f0f0f; reg[i][0] = d * kvalues_iq4nl_f[q8[0]]; reg[i][1] = d * kvalues_iq4nl_f[q8[1]]; reg[i][2] = d * kvalues_iq4nl_f[q8[2]]; reg[i][3] = d * kvalues_iq4nl_f[q8[3]]; } } enum ggml_sort_order { GGML_SORT_ORDER_ASC, GGML_SORT_ORDER_DESC, }; constant float GELU_COEF_A = 0.044715f; constant float GELU_QUICK_COEF = -1.702f; constant float SQRT_2_OVER_PI = 0.79788456080286535587989211986876f; constant float SQRT_2_INV = 0.70710678118654752440084436210484f; // based on Abramowitz and Stegun formula 7.1.26 or similar Hastings' approximation // ref: https://www.johndcook.com/blog/python_erf/ constant float p_erf = 0.3275911f; constant float a1_erf = 0.254829592f; constant float a2_erf = -0.284496736f; constant float a3_erf = 1.421413741f; constant float a4_erf = -1.453152027f; constant float a5_erf = 1.061405429f; template inline T erf_approx(T x) { T sign_x = sign(x); x = fabs(x); T t = 1.0f / (1.0f + p_erf * x); T y = 1.0f - (((((a5_erf * t + a4_erf) * t) + a3_erf) * t + a2_erf) * t + a1_erf) * t * exp(-x * x); return sign_x * y; } template T elu_approx(T x); template<> inline float elu_approx(float x) { return (x > 0.f) ? x : (exp(x) - 1); } template<> inline float4 elu_approx(float4 x) { float4 res; res[0] = (x[0] > 0.0f) ? x[0] : (exp(x[0]) - 1.0f); res[1] = (x[1] > 0.0f) ? x[1] : (exp(x[1]) - 1.0f); res[2] = (x[2] > 0.0f) ? x[2] : (exp(x[2]) - 1.0f); res[3] = (x[3] > 0.0f) ? x[3] : (exp(x[3]) - 1.0f); return res; } constant short FC_unary_op [[function_constant(FC_UNARY + 0)]]; constant bool FC_unary_cnt[[function_constant(FC_UNARY + 1)]]; template kernel void kernel_unary_impl( constant ggml_metal_kargs_unary & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { #define FC_OP FC_unary_op #define FC_CNT FC_unary_cnt device const T0 * src0_ptr; device T * dst_ptr; int i0; if (FC_CNT) { i0 = tgpig.x; src0_ptr = (device const T0 *) (src0); dst_ptr = (device T *) (dst); } else { const int i03 = tgpig.z; const int i02 = tgpig.y; const int k0 = tgpig.x/args.ne01; const int i01 = tgpig.x - k0*args.ne01; i0 = k0*ntg.x + tpitg.x; src0_ptr = (device const T0 *) (src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01); dst_ptr = (device T *) (dst + i03*args.nb3 + i02*args.nb2 + i01*args.nb1 ); } { //threadgroup_barrier(mem_flags::mem_none); if (!FC_CNT) { if (i0 >= args.ne0) { return; } } const TC x = (TC) src0_ptr[i0]; if (FC_OP == OP_UNARY_NUM_SCALE) { dst_ptr[i0] = (T) (args.scale * x + args.bias); } if (FC_OP == OP_UNARY_NUM_FILL) { dst_ptr[i0] = (T) args.val; } if (FC_OP == OP_UNARY_NUM_CLAMP) { dst_ptr[i0] = (T) clamp(x, args.min, args.max); } if (FC_OP == OP_UNARY_NUM_SQR) { dst_ptr[i0] = (T) (x * x); } if (FC_OP == OP_UNARY_NUM_SQRT) { dst_ptr[i0] = (T) sqrt(x); } if (FC_OP == OP_UNARY_NUM_SIN) { dst_ptr[i0] = (T) sin(x); } if (FC_OP == OP_UNARY_NUM_COS) { dst_ptr[i0] = (T) cos(x); } if (FC_OP == OP_UNARY_NUM_LOG) { dst_ptr[i0] = (T) log(x); } if (FC_OP == OP_UNARY_NUM_LEAKY_RELU) { dst_ptr[i0] = (T) (TC(x > 0)*x + TC(x <= 0)*(x * args.slope)); } if (FC_OP == OP_UNARY_NUM_TANH) { dst_ptr[i0] = (T) precise::tanh(x); } if (FC_OP == OP_UNARY_NUM_RELU) { dst_ptr[i0] = (T) fmax(0, x); } if (FC_OP == OP_UNARY_NUM_SIGMOID) { dst_ptr[i0] = (T) (1 / (1 + exp(-x))); } if (FC_OP == OP_UNARY_NUM_GELU) { dst_ptr[i0] = (T) (0.5*x*(1 + precise::tanh(SQRT_2_OVER_PI*x*(1 + GELU_COEF_A*x*x)))); } if (FC_OP == OP_UNARY_NUM_GELU_ERF) { dst_ptr[i0] = (T) (0.5*x*(1 + erf_approx(SQRT_2_INV*x))); } if (FC_OP == OP_UNARY_NUM_GELU_QUICK) { dst_ptr[i0] = (T) (x * (1/(1 + exp(GELU_QUICK_COEF*x)))); } if (FC_OP == OP_UNARY_NUM_SILU) { dst_ptr[i0] = (T) (x / (1 + exp(-x))); } if (FC_OP == OP_UNARY_NUM_ELU) { dst_ptr[i0] = (T) elu_approx(x); } if (FC_OP == OP_UNARY_NUM_NEG) { dst_ptr[i0] = (T) -x; } if (FC_OP == OP_UNARY_NUM_ABS) { dst_ptr[i0] = (T) fabs(x); } if (FC_OP == OP_UNARY_NUM_SGN) { dst_ptr[i0] = T(x > 0) - T(x < 0); } if (FC_OP == OP_UNARY_NUM_STEP) { dst_ptr[i0] = T(x > 0); } if (FC_OP == OP_UNARY_NUM_HARDSWISH) { dst_ptr[i0] = (T) (x * fmax(0, fmin(1, x/6 + 0.5))); } if (FC_OP == OP_UNARY_NUM_HARDSIGMOID) { dst_ptr[i0] = (T) fmax(0, fmin(1, x/6 + 0.5)); } if (FC_OP == OP_UNARY_NUM_EXP) { dst_ptr[i0] = (T) exp(x); } if (FC_OP == OP_UNARY_NUM_SOFTPLUS) { dst_ptr[i0] = (T) select(log(1 + exp(x)), x, x > 20); } if (FC_OP == OP_UNARY_NUM_EXPM1) { // TODO: precise implementation dst_ptr[i0] = (T) (exp(x) - 1); } } #undef FC_OP #undef FC_CNT } typedef decltype(kernel_unary_impl) kernel_unary_t; template [[host_name("kernel_unary_f32_f32")]] kernel kernel_unary_t kernel_unary_impl; template [[host_name("kernel_unary_f32_f32_4")]] kernel kernel_unary_t kernel_unary_impl; template [[host_name("kernel_unary_f16_f16")]] kernel kernel_unary_t kernel_unary_impl; template [[host_name("kernel_unary_f16_f16_4")]] kernel kernel_unary_t kernel_unary_impl; // OP: 0 - add, 1 - sub, 2 - mul, 3 - div constant short FC_bin_op [[function_constant(FC_BIN + 0)]]; constant short FC_bin_f [[function_constant(FC_BIN + 1)]]; constant bool FC_bin_rb [[function_constant(FC_BIN + 2)]]; template kernel void kernel_bin_fuse_impl( constant ggml_metal_kargs_bin & args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { #define FC_OP FC_bin_op #define FC_F FC_bin_f #define FC_RB FC_bin_rb if (FC_RB) { // row broadcast const uint i0 = tgpig.x; const uint i1 = i0%args.ne10; device const T0 * src0_row = (device const T0 *) (src0); device T * dst_row = (device T *) (dst); if (FC_F == 1) { device const T1 * src1_row = (device const T1 *) (src1 + args.o1[0]); if (FC_OP == 0) { dst_row[i0] = src0_row[i0] + src1_row[i1]; } if (FC_OP == 1) { dst_row[i0] = src0_row[i0] - src1_row[i1]; } if (FC_OP == 2) { dst_row[i0] = src0_row[i0] * src1_row[i1]; } if (FC_OP == 3) { dst_row[i0] = src0_row[i0] / src1_row[i1]; } } else { T0 res = src0_row[i0]; if (FC_OP == 0) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res += ((device const T1 *) (src1 + args.o1[j]))[i1]; } } if (FC_OP == 1) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res -= ((device const T1 *) (src1 + args.o1[j]))[i1]; } } if (FC_OP == 2) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res *= ((device const T1 *) (src1 + args.o1[j]))[i1]; } } if (FC_OP == 3) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res /= ((device const T1 *) (src1 + args.o1[j]))[i1]; } } dst_row[i0] = res; } } else { const int i03 = tgpig.z; const int i02 = tgpig.y; const int i01 = tgpig.x; if (i01 >= args.ne01) { return; } const int i13 = i03%args.ne13; const int i12 = i02%args.ne12; const int i11 = i01%args.ne11; device const T0 * src0_ptr = (device const T0 *) (src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01 + args.offs); device T * dst_ptr = (device T *) (dst + i03*args.nb3 + i02*args.nb2 + i01*args.nb1 + args.offs); if (FC_F == 1) { device const T1 * src1_ptr = (device const T1 *) (src1 + args.o1[0] + i13*args.nb13 + i12*args.nb12 + i11*args.nb11); for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { const int i10 = i0%args.ne10; if (FC_OP == 0) { dst_ptr[i0] = src0_ptr[i0] + src1_ptr[i10]; } if (FC_OP == 1) { dst_ptr[i0] = src0_ptr[i0] - src1_ptr[i10]; } if (FC_OP == 2) { dst_ptr[i0] = src0_ptr[i0] * src1_ptr[i10]; } if (FC_OP == 3) { dst_ptr[i0] = src0_ptr[i0] / src1_ptr[i10]; } } } else { device const T1 * src1_ptr[8]; FOR_UNROLL (short j = 0; j < FC_F; ++j) { src1_ptr[j] = (device const T1 *) (src1 + args.o1[j] + i13*args.nb13 + i12*args.nb12 + i11*args.nb11); } for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { const int i10 = i0%args.ne10; T res = src0_ptr[i0]; if (FC_OP == 0) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res += src1_ptr[j][i10]; } } if (FC_OP == 1) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res -= src1_ptr[j][i10]; } } if (FC_OP == 2) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res *= src1_ptr[j][i10]; } } if (FC_OP == 3) { FOR_UNROLL (short j = 0; j < FC_F; ++j) { res /= src1_ptr[j][i10]; } } dst_ptr[i0] = res; } } } #undef FC_OP #undef FC_F #undef FC_RB } typedef decltype(kernel_bin_fuse_impl) kernel_bin_fuse_t; template [[host_name("kernel_bin_fuse_f32_f32_f32")]] kernel kernel_bin_fuse_t kernel_bin_fuse_impl; template [[host_name("kernel_bin_fuse_f32_f32_f32_4")]] kernel kernel_bin_fuse_t kernel_bin_fuse_impl; kernel void kernel_add_id( constant ggml_metal_kargs_add_id & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int i1 = tgpig.x; const int i2 = tgpig.y; const int i11 = *((device const int32_t *) (src2 + i1*sizeof(int32_t) + i2*args.nb21)); const size_t nb1 = args.ne0 * sizeof(float); const size_t nb2 = args.ne1 * nb1; device float * dst_row = (device float *)((device char *)dst + i1*nb1 + i2*nb2); device const float * src0_row = (device const float *)((device char *)src0 + i1*args.nb01 + i2*args.nb02); device const float * src1_row = (device const float *)((device char *)src1 + i11*args.nb11); for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { dst_row[i0] = src0_row[i0] + src1_row[i0]; } } template kernel void kernel_repeat( constant ggml_metal_kargs_repeat & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int i3 = tgpig.z; const int i2 = tgpig.y; const int i1 = tgpig.x; const int i03 = i3%args.ne03; const int i02 = i2%args.ne02; const int i01 = i1%args.ne01; device const char * src0_ptr = src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01; device char * dst_ptr = dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1; for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { const int i00 = i0%args.ne00; *((device T *)(dst_ptr + i0*args.nb0)) = *((device T *)(src0_ptr + i00*args.nb00)); } } typedef decltype(kernel_repeat) kernel_repeat_t; template [[host_name("kernel_repeat_f32")]] kernel kernel_repeat_t kernel_repeat; template [[host_name("kernel_repeat_f16")]] kernel kernel_repeat_t kernel_repeat; template [[host_name("kernel_repeat_i32")]] kernel kernel_repeat_t kernel_repeat; template [[host_name("kernel_repeat_i16")]] kernel kernel_repeat_t kernel_repeat; kernel void kernel_reglu_f32( constant ggml_metal_kargs_glu & args, device const char * src0, device const char * src1, device char * dst, uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * src0_row = (device const float *) ((device const char *) src0 + tgpig*args.nb01) + args.i00; device const float * src1_row = (device const float *) ((device const char *) src1 + tgpig*args.nb11) + args.i10; device float * dst_row = (device float *) ((device char *) dst + tgpig*args.nb1); for (int i0 = tpitg; i0 < args.ne0; i0 += ntg) { const float x0 = src0_row[i0]; const float x1 = src1_row[i0]; dst_row[i0] = x0*x1*(x0 > 0.0f); } } kernel void kernel_geglu_f32( constant ggml_metal_kargs_glu & args, device const char * src0, device const char * src1, device char * dst, uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * src0_row = (device const float *) ((device const char *) src0 + tgpig*args.nb01) + args.i00; device const float * src1_row = (device const float *) ((device const char *) src1 + tgpig*args.nb11) + args.i10; device float * dst_row = (device float *) ((device char *) dst + tgpig*args.nb1); for (int i0 = tpitg; i0 < args.ne0; i0 += ntg) { const float x0 = src0_row[i0]; const float x1 = src1_row[i0]; const float gelu = 0.5f*x0*(1.0f + precise::tanh(SQRT_2_OVER_PI*x0*(1.0f + GELU_COEF_A*x0*x0))); dst_row[i0] = gelu*x1; } } kernel void kernel_swiglu_f32( constant ggml_metal_kargs_glu & args, device const char * src0, device const char * src1, device char * dst, uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * src0_row = (device const float *) ((device const char *) src0 + tgpig*args.nb01) + args.i00; device const float * src1_row = (device const float *) ((device const char *) src1 + tgpig*args.nb11) + args.i10; device float * dst_row = (device float *) ((device char *) dst + tgpig*args.nb1); for (int i0 = tpitg; i0 < args.ne0; i0 += ntg) { const float x0 = src0_row[i0]; const float x1 = src1_row[i0]; const float silu = x0 / (1.0f + exp(-x0)); dst_row[i0] = silu*x1; } } kernel void kernel_swiglu_oai_f32( constant ggml_metal_kargs_glu & args, device const char * src0, device const char * src1, device char * dst, uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * src0_row = (device const float *) ((device const char *) src0 + tgpig*args.nb01) + args.i00; device const float * src1_row = (device const float *) ((device const char *) src1 + tgpig*args.nb11) + args.i10; device float * dst_row = (device float *) ((device char *) dst + tgpig*args.nb1); for (int i0 = tpitg; i0 < args.ne0; i0 += ntg) { float x0 = src0_row[i0]; float x1 = src1_row[i0]; x0 = min(x0, args.limit); x1 = max(min(x1, args.limit), -args.limit); float out_glu = x0 / (1.0f + exp(-x0 * args.alpha)); out_glu = out_glu * (1.0f + x1); dst_row[i0] = out_glu; } } kernel void kernel_geglu_erf_f32( constant ggml_metal_kargs_glu & args, device const char * src0, device const char * src1, device char * dst, uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * src0_row = (device const float *) ((device const char *) src0 + tgpig*args.nb01) + args.i00; device const float * src1_row = (device const float *) ((device const char *) src1 + tgpig*args.nb11) + args.i10; device float * dst_row = (device float *) ((device char *) dst + tgpig*args.nb1); for (int i0 = tpitg; i0 < args.ne0; i0 += ntg) { const float x0 = src0_row[i0]; const float x1 = src1_row[i0]; const float gelu_erf = 0.5f*x0*(1.0f+erf_approx(x0*SQRT_2_INV)); dst_row[i0] = gelu_erf*x1; } } kernel void kernel_geglu_quick_f32( constant ggml_metal_kargs_glu & args, device const char * src0, device const char * src1, device char * dst, uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * src0_row = (device const float *) ((device const char *) src0 + tgpig*args.nb01) + args.i00; device const float * src1_row = (device const float *) ((device const char *) src1 + tgpig*args.nb11) + args.i10; device float * dst_row = (device float *) ((device char *) dst + tgpig*args.nb1); for (int i0 = tpitg; i0 < args.ne0; i0 += ntg) { const float x0 = src0_row[i0]; const float x1 = src1_row[i0]; const float gelu_quick = x0*(1.0f/(1.0f+exp(GELU_QUICK_COEF*x0))); dst_row[i0] = gelu_quick*x1; } } kernel void kernel_op_sum_f32( constant ggml_metal_kargs_sum & args, device const float * src0, device float * dst, threadgroup float * shmem_f32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { if (args.np == 0) { return; } // TODO: become function constant const uint nsg = (ntg.x + 31) / 32; float sumf = 0; for (uint64_t i0 = tpitg.x; i0 < args.np; i0 += ntg.x) { sumf += src0[i0]; } sumf = simd_sum(sumf); if (tiisg == 0) { shmem_f32[sgitg] = sumf; } threadgroup_barrier(mem_flags::mem_threadgroup); float total = 0; if (sgitg == 0) { float v = 0; if (tpitg.x < nsg) { v = shmem_f32[tpitg.x]; } total = simd_sum(v); if (tpitg.x == 0) { dst[0] = total; } } } template kernel void kernel_sum_rows( constant ggml_metal_kargs_sum_rows & args, device const float * src0, device float * dst, threadgroup float * shmem_f32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { int64_t i3 = tgpig.z; int64_t i2 = tgpig.y; int64_t i1 = tgpig.x; if (i3 >= args.ne03 || i2 >= args.ne02 || i1 >= args.ne01) { return; } if (sgitg == 0) { shmem_f32[tiisg] = 0.0f; } device const float * src_row = (device const float *) ((device const char *) src0 + i1*args.nb01 + i2*args.nb02 + i3*args.nb03); device float * dst_row = (device float *) ((device char *) dst + i1*args.nb1 + i2*args.nb2 + i3*args.nb3); float sumf = 0; for (int64_t i0 = tpitg.x; i0 < args.ne00; i0 += ntg.x) { sumf += src_row[i0]; } sumf = simd_sum(sumf); threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { shmem_f32[sgitg] = sumf; } threadgroup_barrier(mem_flags::mem_threadgroup); sumf = shmem_f32[tiisg]; sumf = simd_sum(sumf); if (tpitg.x == 0) { dst_row[0] = norm ? sumf / args.ne00 : sumf; } } typedef decltype(kernel_sum_rows) kernel_sum_rows_t; template [[host_name("kernel_sum_rows_f32")]] kernel kernel_sum_rows_t kernel_sum_rows; template [[host_name("kernel_mean_f32")]] kernel kernel_sum_rows_t kernel_sum_rows; template kernel void kernel_cumsum_blk( constant ggml_metal_kargs_cumsum_blk & args, device const char * src0, device char * tmp, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int ib = tgpig[0]/args.ne01; const int i00 = ib*ntg.x; const int i01 = tgpig[0]%args.ne01; const int i02 = tgpig[1]; const int i03 = tgpig[2]; device const float * src0_row = (device const float *) (src0 + args.nb01*i01 + args.nb02*i02 + args.nb03*i03); threadgroup float * shmem_f32 = (threadgroup float *) shmem; float v = 0.0f; if (i00 + tpitg.x < args.ne00) { v = src0_row[i00 + tpitg.x]; } float s = simd_prefix_inclusive_sum(v); if (tiisg == N_SIMDWIDTH - 1) { shmem_f32[sgitg] = s; } threadgroup_barrier(mem_flags::mem_threadgroup); if (sgitg == 0) { shmem_f32[tiisg] = simd_prefix_exclusive_sum(shmem_f32[tiisg]); } threadgroup_barrier(mem_flags::mem_threadgroup); s += shmem_f32[sgitg]; device float * dst_row = (device float *) dst + args.ne00*i01 + args.ne00*args.ne01*i02 + args.ne00*args.ne01*args.ne02*i03; if (i00 + tpitg.x < args.ne00) { dst_row[i00 + tpitg.x] = s; } if (args.outb && tpitg.x == ntg.x - 1) { device float * tmp_row = (device float *) tmp + args.net0*i01 + args.net0*args.net1*i02 + args.net0*args.net1*args.net2*i03; tmp_row[ib] = s; } } typedef decltype(kernel_cumsum_blk) kernel_cumsum_blk_t; template [[host_name("kernel_cumsum_blk_f32")]] kernel kernel_cumsum_blk_t kernel_cumsum_blk; template kernel void kernel_cumsum_add( constant ggml_metal_kargs_cumsum_add & args, device const char * tmp, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int ib = tgpig[0]/args.ne01; if (ib == 0) { return; } const int i00 = ib*ntg.x; const int i01 = tgpig[0]%args.ne01; const int i02 = tgpig[1]; const int i03 = tgpig[2]; device const float * tmp_row = (device const float *) (tmp + args.nbt1*i01 + args.nbt2*i02 + args.nbt3*i03); device float * dst_row = (device float *) dst + args.ne00*i01 + args.ne00*args.ne01*i02 + args.ne00*args.ne01*args.ne02*i03; if (i00 + tpitg.x < args.ne00) { dst_row[i00 + tpitg.x] += tmp_row[ib - 1]; } } typedef decltype(kernel_cumsum_add) kernel_cumsum_add_t; template [[host_name("kernel_cumsum_add_f32")]] kernel kernel_cumsum_add_t kernel_cumsum_add; template bool _ggml_vec_tri_cmp(const int i, const int r); template<> bool _ggml_vec_tri_cmp(const int i, const int r) { return i < r; } template<> bool _ggml_vec_tri_cmp(const int i, const int r) { return i <= r; } template<> bool _ggml_vec_tri_cmp(const int i, const int r) { return i > r; } template<> bool _ggml_vec_tri_cmp(const int i, const int r) { return i >= r; } template kernel void kernel_tri( constant ggml_metal_kargs_tri & args, device const char * src0, device const char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int i3 = tgpig.z; const int i2 = tgpig.y; const int i1 = tgpig.x; if (i3 >= args.ne03 || i2 >= args.ne02 || i1 >= args.ne01) { return; } device const T * src_row = (device const T *) ((device const char *) src0 + i1*args.nb01 + i2*args.nb02 + i3*args.nb03); device T * dst_row = (device T *) ((device char *) dst + i1*args.nb1 + i2*args.nb2 + i3*args.nb3); // Each thread is a single element of the row if ne00 < max threads per // threadgroup, so this will loop once for each index that this thread is // responsible for for (int64_t i0 = tpitg.x; i0 < args.ne00; i0 += ntg.x) { // Use the comparison as a mask for branchless dst_row[i0] = static_cast(_ggml_vec_tri_cmp(i0, i1)) * src_row[i0]; } } typedef decltype(kernel_tri) kernel_tri_t; template [[host_name("kernel_tri_f32_0")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f32_1")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f32_2")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f32_3")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f16_0")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f16_1")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f16_2")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_f16_3")]] kernel kernel_tri_t kernel_tri; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_tri_bf16_0")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_bf16_1")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_bf16_2")]] kernel kernel_tri_t kernel_tri; template [[host_name("kernel_tri_bf16_3")]] kernel kernel_tri_t kernel_tri; #endif template kernel void kernel_soft_max( constant ggml_metal_kargs_soft_max & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, threadgroup float * buf [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint sgitg[[simdgroup_index_in_threadgroup]], uint tiisg[[thread_index_in_simdgroup]], uint3 tptg[[threads_per_threadgroup]]) { const int32_t i03 = tgpig.z; const int32_t i02 = tgpig.y; const int32_t i01 = tgpig.x; const int32_t i13 = i03%args.ne13; const int32_t i12 = i02%args.ne12; const int32_t i11 = i01; device const float * psrc0 = (device const float *) (src0 + i01*args.nb01 + i02*args.nb02 + i03*args.nb03); device const T * pmask = src1 != src0 ? (device const T * ) (src1 + i11*args.nb11 + i12*args.nb12 + i13*args.nb13) : nullptr; device const float * psrc2 = src2 != src0 ? (device const float *) (src2) : nullptr; device float * pdst = (device float *) (dst + i01*args.nb1 + i02*args.nb2 + i03*args.nb3); float slope = 1.0f; // ALiBi if (args.max_bias > 0.0f) { const int32_t h = i02; const float base = h < args.n_head_log2 ? args.m0 : args.m1; const int exp = h < args.n_head_log2 ? h + 1 : 2*(h - args.n_head_log2) + 1; slope = pow(base, exp); } // parallel max float lmax = psrc2 ? psrc2[i02] : -INFINITY; for (int i00 = tpitg.x; i00 < args.ne00; i00 += tptg.x) { lmax = MAX(lmax, psrc0[i00]*args.scale + (pmask ? slope*pmask[i00] : 0.0f)); } // find the max value in the block float max_val = simd_max(lmax); if (tptg.x > N_SIMDWIDTH) { if (sgitg == 0) { buf[tiisg] = -INFINITY; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { buf[sgitg] = max_val; } threadgroup_barrier(mem_flags::mem_threadgroup); max_val = buf[tiisg]; max_val = simd_max(max_val); } // parallel sum float lsum = 0.0f; for (int i00 = tpitg.x; i00 < args.ne00; i00 += tptg.x) { const float exp_psrc0 = exp((psrc0[i00]*args.scale + (pmask ? slope*pmask[i00] : 0.0f)) - max_val); lsum += exp_psrc0; pdst[i00] = exp_psrc0; } // This barrier fixes a failing test // ref: https://github.com/ggml-org/ggml/pull/621#discussion_r1425156335 threadgroup_barrier(mem_flags::mem_none); float sum = simd_sum(lsum); if (tptg.x > N_SIMDWIDTH) { if (sgitg == 0) { buf[tiisg] = 0.0f; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { buf[sgitg] = sum; } threadgroup_barrier(mem_flags::mem_threadgroup); sum = buf[tiisg]; sum = simd_sum(sum); } if (psrc2) { sum += exp(psrc2[i02] - max_val); } const float inv_sum = 1.0f/sum; for (int i00 = tpitg.x; i00 < args.ne00; i00 += tptg.x) { pdst[i00] *= inv_sum; } } template kernel void kernel_soft_max_4( constant ggml_metal_kargs_soft_max & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, threadgroup float * buf [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint sgitg[[simdgroup_index_in_threadgroup]], uint tiisg[[thread_index_in_simdgroup]], uint3 tptg[[threads_per_threadgroup]]) { const int32_t i03 = tgpig.z; const int32_t i02 = tgpig.y; const int32_t i01 = tgpig.x; const int32_t i13 = i03%args.ne13; const int32_t i12 = i02%args.ne12; const int32_t i11 = i01; device const float4 * psrc4 = (device const float4 *) (src0 + i01*args.nb01 + i02*args.nb02 + i03*args.nb03); device const T * pmask = src1 != src0 ? (device const T * ) (src1 + i11*args.nb11 + i12*args.nb12 + i13*args.nb13) : nullptr; device const float * psrc2 = src2 != src0 ? (device const float * ) (src2) : nullptr; device float4 * pdst4 = (device float4 *) (dst + i01*args.nb1 + i02*args.nb2 + i03*args.nb3); float slope = 1.0f; if (args.max_bias > 0.0f) { const int32_t h = i02; const float base = h < args.n_head_log2 ? args.m0 : args.m1; const int exp = h < args.n_head_log2 ? h + 1 : 2*(h - args.n_head_log2) + 1; slope = pow(base, exp); } // parallel max float4 lmax4 = psrc2 ? psrc2[i02] : -INFINITY; for (int i00 = tpitg.x; i00 < args.ne00/4; i00 += tptg.x) { lmax4 = fmax(lmax4, psrc4[i00]*args.scale + (float4)((pmask ? slope*pmask[i00] : 0.0f))); } const float lmax = MAX(MAX(lmax4[0], lmax4[1]), MAX(lmax4[2], lmax4[3])); float max_val = simd_max(lmax); if (tptg.x > N_SIMDWIDTH) { if (sgitg == 0) { buf[tiisg] = -INFINITY; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { buf[sgitg] = max_val; } threadgroup_barrier(mem_flags::mem_threadgroup); max_val = buf[tiisg]; max_val = simd_max(max_val); } // parallel sum float4 lsum4 = 0.0f; for (int i00 = tpitg.x; i00 < args.ne00/4; i00 += tptg.x) { const float4 exp_psrc4 = exp((psrc4[i00]*args.scale + (float4)((pmask ? slope*pmask[i00] : 0.0f))) - max_val); lsum4 += exp_psrc4; pdst4[i00] = exp_psrc4; } const float lsum = lsum4[0] + lsum4[1] + lsum4[2] + lsum4[3]; // This barrier fixes a failing test // ref: https://github.com/ggml-org/ggml/pull/621#discussion_r1425156335 threadgroup_barrier(mem_flags::mem_none); float sum = simd_sum(lsum); if (tptg.x > N_SIMDWIDTH) { if (sgitg == 0) { buf[tiisg] = 0.0f; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { buf[sgitg] = sum; } threadgroup_barrier(mem_flags::mem_threadgroup); sum = buf[tiisg]; sum = simd_sum(sum); } if (psrc2) { sum += exp(psrc2[i02] - max_val); } const float inv_sum = 1.0f/sum; for (int i00 = tpitg.x; i00 < args.ne00/4; i00 += tptg.x) { pdst4[i00] *= inv_sum; } } typedef decltype(kernel_soft_max) kernel_soft_max_t; typedef decltype(kernel_soft_max_4) kernel_soft_max_4_t; template [[host_name("kernel_soft_max_f16")]] kernel kernel_soft_max_t kernel_soft_max; template [[host_name("kernel_soft_max_f32")]] kernel kernel_soft_max_t kernel_soft_max; template [[host_name("kernel_soft_max_f16_4")]] kernel kernel_soft_max_4_t kernel_soft_max_4; template [[host_name("kernel_soft_max_f32_4")]] kernel kernel_soft_max_4_t kernel_soft_max_4; // ref: ggml.c:ggml_compute_forward_ssm_conv_f32 kernel void kernel_ssm_conv_f32_f32( constant ggml_metal_kargs_ssm_conv & args, device const void * src0, device const void * src1, device float * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const int64_t ir = tgpig.x; const int64_t i2 = tgpig.y; const int64_t i3 = tgpig.z; const int64_t nc = args.ne10; //const int64_t ncs = args.ne00; //const int64_t nr = args.ne01; //const int64_t n_t = args.ne1; //const int64_t n_s = args.ne2; device const float * s = (device const float *) ((device const char *) src0 + ir*args.nb01 + i2*args.nb00 + i3*args.nb02); device const float * c = (device const float *) ((device const char *) src1 + ir*args.nb11); device float * x = (device float *) ((device char *) dst + ir*args.nb0 + i2*args.nb1 + i3*args.nb2); float sumf = 0.0f; for (int64_t i0 = 0; i0 < nc; ++i0) { sumf += s[i0] * c[i0]; } x[0] = sumf; } kernel void kernel_ssm_conv_f32_f32_4( constant ggml_metal_kargs_ssm_conv & args, device const void * src0, device const void * src1, device float * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const int64_t ir = tgpig.x; const int64_t i2 = tgpig.y; const int64_t i3 = tgpig.z; const int64_t nc = args.ne10; //const int64_t ncs = args.ne00; //const int64_t nr = args.ne01; //const int64_t n_t = args.ne1; //const int64_t n_s = args.ne2; device const float4 * s = (device const float4 *) ((device const char *) src0 + ir*args.nb01 + i2*args.nb00 + i3*args.nb02); device const float4 * c = (device const float4 *) ((device const char *) src1 + ir*args.nb11); device float * x = (device float *) ((device char *) dst + ir*args.nb0 + i2*args.nb1 + i3*args.nb2); float sumf = 0.0f; for (int64_t i0 = 0; i0 < nc/4; ++i0) { sumf += dot(s[i0], c[i0]); } x[0] = sumf; } constant short FC_ssm_conv_bs [[function_constant(FC_SSM_CONV + 0)]]; // Batched version: each threadgroup processes multiple tokens for better efficiency // Thread layout: each thread handles one token, threadgroup covers BATCH_SIZE tokens kernel void kernel_ssm_conv_f32_f32_batched( constant ggml_metal_kargs_ssm_conv & args, device const void * src0, device const void * src1, device float * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { // tgpig.x = row index (ir) // tgpig.y = batch of tokens (i2_base / BATCH_SIZE) // tgpig.z = sequence index (i3) // tpitg.x = thread within batch (0..BATCH_SIZE-1) const short BATCH_SIZE = FC_ssm_conv_bs; const int64_t ir = tgpig.x; const int64_t i2_base = tgpig.y * BATCH_SIZE; const int64_t i3 = tgpig.z; const int64_t i2_off = tpitg.x; const int64_t i2 = i2_base + i2_off; const int64_t nc = args.ne10; // conv kernel size (typically 4) const int64_t n_t = args.ne1; // number of tokens // Bounds check for partial batches at the end if (i2 >= n_t) { return; } // Load conv weights (shared across all tokens for this row) device const float * c = (device const float *) ((device const char *) src1 + ir*args.nb11); // Load source for this specific token device const float * s = (device const float *) ((device const char *) src0 + ir*args.nb01 + i2*args.nb00 + i3*args.nb02); // Output location for this token device float * x = (device float *) ((device char *) dst + ir*args.nb0 + i2*args.nb1 + i3*args.nb2); float sumf = 0.0f; for (int64_t i0 = 0; i0 < nc; ++i0) { sumf += s[i0] * c[i0]; } x[0] = sumf; } kernel void kernel_ssm_conv_f32_f32_batched_4( constant ggml_metal_kargs_ssm_conv & args, device const void * src0, device const void * src1, device float * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { // tgpig.x = row index (ir) // tgpig.y = batch of tokens (i2_base / BATCH_SIZE) // tgpig.z = sequence index (i3) // tpitg.x = thread within batch (0..BATCH_SIZE-1) const short BATCH_SIZE = FC_ssm_conv_bs; const int64_t ir = tgpig.x; const int64_t i2_base = tgpig.y * BATCH_SIZE; const int64_t i3 = tgpig.z; const int64_t i2_off = tpitg.x; const int64_t i2 = i2_base + i2_off; const int64_t nc = args.ne10; // conv kernel size (typically 4) const int64_t n_t = args.ne1; // number of tokens // Bounds check for partial batches at the end if (i2 >= n_t) { return; } // Load conv weights (shared across all tokens for this row) device const float4 * c = (device const float4 *) ((device const char *) src1 + ir*args.nb11); // Load source for this specific token device const float4 * s = (device const float4 *) ((device const char *) src0 + ir*args.nb01 + i2*args.nb00 + i3*args.nb02); // Output location for this token device float * x = (device float *) ((device char *) dst + ir*args.nb0 + i2*args.nb1 + i3*args.nb2); float sumf = 0.0f; for (int64_t i0 = 0; i0 < nc/4; ++i0) { sumf += dot(s[i0], c[i0]); } x[0] = sumf; } // ref: ggml.c:ggml_compute_forward_ssm_scan_f32, Mamba-2 part // Optimized version: reduces redundant memory loads by having one thread load shared values kernel void kernel_ssm_scan_f32( constant ggml_metal_kargs_ssm_scan & args, device const void * src0, device const void * src1, device const void * src2, device const void * src3, device const void * src4, device const void * src5, device const void * src6, device float * dst, threadgroup float * shared [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgptg[[simdgroups_per_threadgroup]], uint3 tgpg[[threadgroups_per_grid]]) { constexpr short NW = N_SIMDWIDTH; // Shared memory layout: // [0..sgptg*NW-1]: partial sums for reduction (existing) // [sgptg*NW..sgptg*NW+sgptg-1]: pre-computed x_dt values for each token in batch // [sgptg*NW+sgptg..sgptg*NW+2*sgptg-1]: pre-computed dA values for each token in batch threadgroup float * shared_sums = shared; threadgroup float * shared_x_dt = shared + sgptg * NW; threadgroup float * shared_dA = shared + sgptg * NW + sgptg; shared_sums[tpitg.x] = 0.0f; const int32_t i0 = tpitg.x; const int32_t i1 = tgpig.x; const int32_t ir = tgpig.y; // current head const int32_t i3 = tgpig.z; // current seq const int32_t nc = args.d_state; const int32_t nr = args.d_inner; const int32_t nh = args.n_head; const int32_t ng = args.n_group; const int32_t n_t = args.n_seq_tokens; const int32_t s_off = args.s_off; device const int32_t * ids = (device const int32_t *) src6; device const float * s0_buff = (device const float *) ((device const char *) src0 + ir*args.nb02 + ids[i3]*args.nb03); device float * s_buff = (device float *) ((device char *) dst + ir*args.nb02 + i3*args.nb03 + s_off); const int32_t i = i0 + i1*nc; const int32_t g = ir / (nh / ng); // repeat_interleave float s0 = s0_buff[i]; float s = 0.0f; device const float * A = (device const float *) ((device const char *) src3 + ir*args.nb31); // {ne30, nh} const float A0 = A[i0%args.ne30]; device const float * x = (device const float *)((device const char *) src1 + i1*args.nb10 + ir*args.nb11 + i3*args.nb13); // {dim, nh, nt, ns} device const float * dt = (device const float *)((device const char *) src2 + ir*args.nb20 + i3*args.nb22); // {nh, nt, ns} device const float * B = (device const float *)((device const char *) src4 + g*args.nb41 + i3*args.nb43); // {d_state, ng, nt, ns} device const float * C = (device const float *)((device const char *) src5 + g*args.nb51 + i3*args.nb53); // {d_state, ng, nt, ns} device float * y = dst + (i1 + ir*(nr) + i3*(n_t*nh*nr)); // {dim, nh, nt, ns} for (int i2 = 0; i2 < n_t; i2 += sgptg) { threadgroup_barrier(mem_flags::mem_threadgroup); // Pre-compute x_dt and dA for this batch of tokens // Only first sgptg threads do the loads and expensive math if (i0 < sgptg && i2 + i0 < n_t) { // ns12 and ns21 are element strides (nb12/nb10, nb21/nb20) device const float * x_t = x + i0 * args.ns12; device const float * dt_t = dt + i0 * args.ns21; const float dt0 = dt_t[0]; const float dtsp = dt0 <= 20.0f ? log(1.0f + exp(dt0)) : dt0; shared_x_dt[i0] = x_t[0] * dtsp; shared_dA[i0] = dtsp; // Store dtsp, compute exp(dtsp * A0) per-thread since A0 varies } threadgroup_barrier(mem_flags::mem_threadgroup); for (int t = 0; t < sgptg && i2 + t < n_t; t++) { const float x_dt = shared_x_dt[t]; const float dA = exp(shared_dA[t] * A0); s = (s0 * dA) + (B[i0] * x_dt); const float sumf = simd_sum(s * C[i0]); if (tiisg == 0) { shared_sums[t*NW + sgitg] = sumf; } // recurse s0 = s; B += args.ns42; C += args.ns52; } // Advance pointers for next batch x += sgptg * args.ns12; dt += sgptg * args.ns21; threadgroup_barrier(mem_flags::mem_threadgroup); const float sumf = simd_sum(shared_sums[sgitg*NW + tiisg]); if (tiisg == 0 && i2 + sgitg < n_t) { y[sgitg*nh*nr] = sumf; } y += sgptg*nh*nr; } s_buff[i] = s; } kernel void kernel_rwkv_wkv6_f32( device const float * k, device const float * v, device const float * r, device const float * tf, device const float * td, device const float * state_in, device float * dst, constant uint & B, constant uint & T, constant uint & C, constant uint & H, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const uint head_size = 64; // TODO: support head_size = 128 const uint batch_id = tgpig.x / H; const uint head_id = tgpig.x % H; const uint tid = tpitg.x; if (batch_id >= B || head_id >= H) { return; } const uint state_size = C * head_size; const uint n_seq_tokens = T / B; threadgroup float _k[head_size]; threadgroup float _r[head_size]; threadgroup float _tf[head_size]; threadgroup float _td[head_size]; float state[head_size]; for (uint i = 0; i < head_size; i++) { state[i] = state_in[batch_id * state_size + head_id * head_size * head_size + i * head_size + tid]; } threadgroup_barrier(mem_flags::mem_threadgroup); _tf[tid] = tf[head_id * head_size + tid]; threadgroup_barrier(mem_flags::mem_threadgroup); const uint start_t = batch_id * n_seq_tokens * C + head_id * head_size + tid; const uint end_t = (batch_id + 1) * n_seq_tokens * C + head_id * head_size + tid; for (uint t = start_t; t < end_t; t += C) { threadgroup_barrier(mem_flags::mem_threadgroup); _k[tid] = k[t]; _r[tid] = r[t]; _td[tid] = td[t]; threadgroup_barrier(mem_flags::mem_threadgroup); const float v_val = v[t]; float y = 0.0; for (uint j = 0; j < head_size; j += 4) { float4 k_vec = float4(_k[j], _k[j+1], _k[j+2], _k[j+3]); float4 r_vec = float4(_r[j], _r[j+1], _r[j+2], _r[j+3]); float4 tf_vec = float4(_tf[j], _tf[j+1], _tf[j+2], _tf[j+3]); float4 td_vec = float4(_td[j], _td[j+1], _td[j+2], _td[j+3]); float4 s_vec = float4(state[j], state[j+1], state[j+2], state[j+3]); float4 kv = k_vec * v_val; float4 temp = tf_vec * kv + s_vec; y += dot(r_vec, temp); s_vec = s_vec * td_vec + kv; state[j] = s_vec[0]; state[j+1] = s_vec[1]; state[j+2] = s_vec[2]; state[j+3] = s_vec[3]; } dst[t] = y; } for (uint i = 0; i < head_size; i++) { dst[T * C + batch_id * state_size + head_id * head_size * head_size + i * head_size + tid] = state[i]; } } kernel void kernel_rwkv_wkv7_f32( device const float * r, device const float * w, device const float * k, device const float * v, device const float * a, device const float * b, device const float * state_in, device float * dst, constant uint & B, constant uint & T, constant uint & C, constant uint & H, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const uint head_size = 64; // TODO: support head_size = 128 const uint batch_id = tgpig.x / H; const uint head_id = tgpig.x % H; const uint tid = tpitg.x; if (batch_id >= B || head_id >= H) { return; } const uint state_size = C * head_size; const uint n_seq_tokens = T / B; threadgroup float _r[head_size]; threadgroup float _w[head_size]; threadgroup float _k[head_size]; threadgroup float _a[head_size]; threadgroup float _b[head_size]; float state[head_size]; for (uint i = 0; i < head_size; i++) { state[i] = state_in[batch_id * state_size + head_id * head_size * head_size + tid * head_size + i]; } const uint start_t = batch_id * n_seq_tokens * C + head_id * head_size + tid; const uint end_t = (batch_id + 1) * n_seq_tokens * C + head_id * head_size + tid; for (uint t = start_t; t < end_t; t += C) { threadgroup_barrier(mem_flags::mem_threadgroup); _r[tid] = r[t]; _w[tid] = w[t]; _k[tid] = k[t]; _a[tid] = a[t]; _b[tid] = b[t]; threadgroup_barrier(mem_flags::mem_threadgroup); const float v_val = v[t]; float y = 0.0, sa = 0.0; float4 sa_vec(0.0); for (uint j = 0; j < head_size; j += 4) { float4 a_vec = float4(_a[j], _a[j+1], _a[j+2], _a[j+3]); float4 s_vec = float4(state[j], state[j+1], state[j+2], state[j+3]); sa_vec += a_vec * s_vec; } sa = sa_vec[0] + sa_vec[1] + sa_vec[2] + sa_vec[3]; for (uint j = 0; j < head_size; j += 4) { float4 r_vec = float4(_r[j], _r[j+1], _r[j+2], _r[j+3]); float4 w_vec = float4(_w[j], _w[j+1], _w[j+2], _w[j+3]); float4 k_vec = float4(_k[j], _k[j+1], _k[j+2], _k[j+3]); float4 b_vec = float4(_b[j], _b[j+1], _b[j+2], _b[j+3]); float4 s_vec = float4(state[j], state[j+1], state[j+2], state[j+3]); float4 kv = k_vec * v_val; s_vec = s_vec * w_vec + kv + sa * b_vec; y += dot(s_vec, r_vec); state[j] = s_vec[0]; state[j+1] = s_vec[1]; state[j+2] = s_vec[2]; state[j+3] = s_vec[3]; } dst[t] = y; } for (uint i = 0; i < head_size; i++) { dst[T * C + batch_id * state_size + head_id * head_size * head_size + tid * head_size + i] = state[i]; } } constant short FC_solve_tri_nsg [[function_constant(FC_SOLVE_TRI + 0)]]; constant short FC_solve_tri_n [[function_constant(FC_SOLVE_TRI + 1)]]; constant short FC_solve_tri_k [[function_constant(FC_SOLVE_TRI + 2)]]; kernel void kernel_solve_tri_f32( constant ggml_metal_kargs_solve_tri & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], ushort3 tgpig[[threadgroup_position_in_grid]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { constexpr short NW = N_SIMDWIDTH; const short NSG = FC_solve_tri_nsg; const short N = FC_solve_tri_n; const short K = FC_solve_tri_k; const short NP = PAD2(N, NW); const int32_t ne02 = args.ne02; const int32_t ne03 = args.ne03; const int32_t i03 = tgpig.z; const int32_t i02 = tgpig.y; const int32_t i01 = tgpig.x*NSG + sgitg; threadgroup float * sh0 = (threadgroup float *) shmem; device const float * src0_ptr = (device const float *)(src0 + i02 * args.nb02 + i03 * args.nb03) + sgitg*N; device const float * src1_ptr = (device const float *)(src1 + i02 * args.nb12 + i03 * args.nb13) + i01; device float * dst_ptr = (device float *)(dst + i02 * args.nb2 + i03 * args.nb3) + i01; for (short rr = 0; rr < N; rr += NSG) { threadgroup_barrier(mem_flags::mem_threadgroup); { threadgroup float * sh0_cur = sh0 + sgitg*NP; for (short t = 0; t*NW < N; ++t) { const short idx = t*NW + tiisg; sh0_cur[idx] = src0_ptr[idx]; } src0_ptr += NSG*N; } threadgroup_barrier(mem_flags::mem_threadgroup); if (i01 >= args.ne10) { continue; } for (short ir = 0; ir < NSG && rr + ir < N; ++ir) { const short r = rr + ir; threadgroup float * sh0_cur = sh0 + ir*NP; float sum = 0.0f; for (short t = 0; t*NW < r; ++t) { const short idx = t*NW + tiisg; sum += sh0_cur[idx] * dst_ptr[idx*K] * (idx < r); } sum = simd_sum(sum); if (tiisg == 0) { const float diag = sh0_cur[r]; dst_ptr[r*K] = (src1_ptr[r*K] - sum) / diag; } } } } kernel void kernel_argmax_f32( constant ggml_metal_kargs_argmax & args, device const char * src0, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint sgitg[[simdgroup_index_in_threadgroup]], uint tiisg[[thread_index_in_simdgroup]], uint ntg[[threads_per_threadgroup]]) { device const float * x_row = (device const float *) ((device const char *) src0 + tgpig * args.nb01); float lmax = -INFINITY; int32_t larg = -1; for (int i00 = tpitg; i00 < args.ne00; i00 += ntg) { if (x_row[i00] > lmax) { lmax = x_row[i00]; larg = i00; } } // find the argmax value in the block float max_val = simd_max(lmax); int32_t arg_val = simd_max(select(-1, larg, lmax == max_val)); device int32_t * dst_i32 = (device int32_t *) dst; threadgroup float * shared_maxval = (threadgroup float *) shmem; threadgroup int32_t * shared_argmax = (threadgroup int32_t *) shmem + N_SIMDWIDTH; if (ntg > N_SIMDWIDTH) { if (sgitg == 0) { shared_maxval[tiisg] = -INFINITY; shared_argmax[tiisg] = -1; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { shared_maxval[sgitg] = max_val; shared_argmax[sgitg] = arg_val; } threadgroup_barrier(mem_flags::mem_threadgroup); max_val = shared_maxval[tiisg]; arg_val = shared_argmax[tiisg]; float max_val_reduced = simd_max(max_val); int32_t arg_val_reduced = simd_max(select(-1, arg_val, max_val == max_val_reduced)); dst_i32[tgpig] = arg_val_reduced; return; } dst_i32[tgpig] = arg_val; } // F == 1 : norm (no fuse) // F == 2 : norm + mul // F == 3 : norm + mul + add template kernel void kernel_norm_fuse_impl( constant ggml_metal_kargs_norm & args, device const char * src0, device const char * src1_0, device const char * src1_1, device char * dst, threadgroup float * shmem_f32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { if (sgitg == 0) { shmem_f32[tiisg] = 0.0f; } const int i01 = tgpig.x; const int i02 = tgpig.y; const int i03 = tgpig.z; device const T * x = (device const T *) (src0 + i03*args.nbf3[0] + i02*args.nbf2[0] + i01*args.nbf1[0]); device const T * f0 = (device const T *) (src1_0 + (i03%args.nef3[1])*args.nbf3[1] + (i02%args.nef2[1])*args.nbf2[1] + (i01%args.nef1[1])*args.nbf1[1]); device const T * f1 = (device const T *) (src1_1 + (i03%args.nef3[2])*args.nbf3[2] + (i02%args.nef2[2])*args.nbf2[2] + (i01%args.nef1[2])*args.nbf1[2]); T sumft(0.0f); float sumf = 0.0f; for (int i00 = tpitg.x; i00 < args.ne00_t; i00 += ntg.x) { sumft += x[i00]; } sumf = dot(sumft, T(1.0f)); sumf = simd_sum(sumf); threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { shmem_f32[sgitg] = sumf; } threadgroup_barrier(mem_flags::mem_threadgroup); sumf = shmem_f32[tiisg]; sumf = simd_sum(sumf); const float mean = sumf/args.ne00; device T * y = (device T *) (dst + i03*args.nb3 + i02*args.nb2 + i01*args.nb1); sumf = 0.0f; for (int i00 = tpitg.x; i00 < args.ne00_t; i00 += ntg.x) { y[i00] = x[i00] - mean; sumf += dot(y[i00], y[i00]); } sumf = simd_sum(sumf); threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { shmem_f32[sgitg] = sumf; } threadgroup_barrier(mem_flags::mem_threadgroup); sumf = shmem_f32[tiisg]; sumf = simd_sum(sumf); const float variance = sumf/args.ne00; const float scale = 1.0f/sqrt(variance + args.eps); for (int i00 = tpitg.x; i00 < args.ne00_t; i00 += ntg.x) { if (F == 1) { y[i00] = (y[i00]*scale); } if (F == 2) { y[i00] = (y[i00]*scale)*f0[i00]; } if (F == 3) { y[i00] = (y[i00]*scale)*f0[i00] + f1[i00]; } } } typedef decltype(kernel_norm_fuse_impl) kernel_norm_fuse_t; template [[host_name("kernel_norm_f32")]] kernel kernel_norm_fuse_t kernel_norm_fuse_impl; template [[host_name("kernel_norm_mul_f32")]] kernel kernel_norm_fuse_t kernel_norm_fuse_impl; template [[host_name("kernel_norm_mul_add_f32")]] kernel kernel_norm_fuse_t kernel_norm_fuse_impl; template [[host_name("kernel_norm_f32_4")]] kernel kernel_norm_fuse_t kernel_norm_fuse_impl; template [[host_name("kernel_norm_mul_f32_4")]] kernel kernel_norm_fuse_t kernel_norm_fuse_impl; template [[host_name("kernel_norm_mul_add_f32_4")]] kernel kernel_norm_fuse_t kernel_norm_fuse_impl; // F == 1 : rms_norm (no fuse) // F == 2 : rms_norm + mul // F == 3 : rms_norm + mul + add template kernel void kernel_rms_norm_fuse_impl( constant ggml_metal_kargs_norm & args, device const char * src0, device const char * src1_0, device const char * src1_1, device char * dst, threadgroup float * shmem_f32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { if (sgitg == 0) { shmem_f32[tiisg] = 0.0f; } const int i01 = tgpig.x; const int i02 = tgpig.y; const int i03 = tgpig.z; device const T * x = (device const T *) (src0 + i03*args.nbf3[0] + i02*args.nbf2[0] + i01*args.nbf1[0]); device const T * f0 = (device const T *) (src1_0 + (i03%args.nef3[1])*args.nbf3[1] + (i02%args.nef2[1])*args.nbf2[1] + (i01%args.nef1[1])*args.nbf1[1]); device const T * f1 = (device const T *) (src1_1 + (i03%args.nef3[2])*args.nbf3[2] + (i02%args.nef2[2])*args.nbf2[2] + (i01%args.nef1[2])*args.nbf1[2]); float sumf = 0.0f; // parallel sum for (int i00 = tpitg.x; i00 < args.ne00_t; i00 += ntg.x) { sumf += dot(x[i00], x[i00]); } sumf = simd_sum(sumf); threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { shmem_f32[sgitg] = sumf; } threadgroup_barrier(mem_flags::mem_threadgroup); sumf = shmem_f32[tiisg]; sumf = simd_sum(sumf); const float mean = sumf/args.ne00; const float scale = 1.0f/sqrt(mean + args.eps); device T * y = (device T *) (dst + i03*args.nb3 + i02*args.nb2 + i01*args.nb1); for (int i00 = tpitg.x; i00 < args.ne00_t; i00 += ntg.x) { if (F == 1) { y[i00] = (x[i00]*scale); } if (F == 2) { y[i00] = (x[i00]*scale)*f0[i00]; } if (F == 3) { y[i00] = (x[i00]*scale)*f0[i00] + f1[i00]; } } } typedef decltype(kernel_rms_norm_fuse_impl) kernel_rms_norm_fuse_t; template [[host_name("kernel_rms_norm_f32")]] kernel kernel_rms_norm_fuse_t kernel_rms_norm_fuse_impl; template [[host_name("kernel_rms_norm_mul_f32")]] kernel kernel_rms_norm_fuse_t kernel_rms_norm_fuse_impl; template [[host_name("kernel_rms_norm_mul_add_f32")]] kernel kernel_rms_norm_fuse_t kernel_rms_norm_fuse_impl; template [[host_name("kernel_rms_norm_f32_4")]] kernel kernel_rms_norm_fuse_t kernel_rms_norm_fuse_impl; template [[host_name("kernel_rms_norm_mul_f32_4")]] kernel kernel_rms_norm_fuse_t kernel_rms_norm_fuse_impl; template [[host_name("kernel_rms_norm_mul_add_f32_4")]] kernel kernel_rms_norm_fuse_t kernel_rms_norm_fuse_impl; template kernel void kernel_l2_norm_impl( constant ggml_metal_kargs_l2_norm & args, device const char * src0, device char * dst, threadgroup float * shmem_f32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]], ushort tiisg[[thread_index_in_simdgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int i03 = tgpig.z; const int i02 = tgpig.y; const int i01 = tgpig.x; if (sgitg == 0) { shmem_f32[tiisg] = 0.0f; } device const T0 * x = (device const T0 *) (src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01); device T * y = (device T *) (dst + i03*args.nb3 + i02*args.nb2 + i01*args.nb1); float sumf = 0.0f; // parallel sum for (int i00 = tpitg.x; i00 < args.ne00; i00 += ntg.x) { sumf += dot(x[i00], x[i00]); } sumf = simd_sum(sumf); threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { shmem_f32[sgitg] = sumf; } threadgroup_barrier(mem_flags::mem_threadgroup); sumf = shmem_f32[tiisg]; sumf = simd_sum(sumf); const float scale = 1.0f/sqrt(max(sumf, args.eps)); for (int i00 = tpitg.x; i00 < args.ne00; i00 += ntg.x) { y[i00] = x[i00] * scale; } } typedef decltype(kernel_l2_norm_impl) kernel_l2_norm_t; template [[host_name("kernel_l2_norm_f32_f32")]] kernel kernel_l2_norm_t kernel_l2_norm_impl; template [[host_name("kernel_l2_norm_f32_f32_4")]] kernel kernel_l2_norm_t kernel_l2_norm_impl; kernel void kernel_group_norm_f32( constant ggml_metal_kargs_group_norm & args, device const float * src0, device float * dst, threadgroup float * buf [[threadgroup(0)]], uint tgpig[[threadgroup_position_in_grid]], uint tpitg[[thread_position_in_threadgroup]], uint sgitg[[simdgroup_index_in_threadgroup]], uint tiisg[[thread_index_in_simdgroup]], uint ntg[[threads_per_threadgroup]]) { const int64_t ne = args.ne00*args.ne01*args.ne02; const int64_t gs = args.ne00*args.ne01*((args.ne02 + args.ngrp - 1) / args.ngrp); int start = tgpig * gs; int end = start + gs; start += tpitg; if (end >= ne) { end = ne; } float tmp = 0.0f; // partial sum for thread in warp for (int j = start; j < end; j += ntg) { tmp += src0[j]; } threadgroup_barrier(mem_flags::mem_threadgroup); tmp = simd_sum(tmp); if (ntg > N_SIMDWIDTH) { if (sgitg == 0) { buf[tiisg] = 0.0f; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { buf[sgitg] = tmp; } threadgroup_barrier(mem_flags::mem_threadgroup); tmp = buf[tiisg]; tmp = simd_sum(tmp); } const float mean = tmp / gs; tmp = 0.0f; for (int j = start; j < end; j += ntg) { float xi = src0[j] - mean; dst[j] = xi; tmp += xi * xi; } tmp = simd_sum(tmp); if (ntg > N_SIMDWIDTH) { if (sgitg == 0) { buf[tiisg] = 0.0f; } threadgroup_barrier(mem_flags::mem_threadgroup); if (tiisg == 0) { buf[sgitg] = tmp; } threadgroup_barrier(mem_flags::mem_threadgroup); tmp = buf[tiisg]; tmp = simd_sum(tmp); } const float variance = tmp / gs; const float scale = 1.0f/sqrt(variance + args.eps); for (int j = start; j < end; j += ntg) { dst[j] *= scale; } } // function for calculate inner product between half a q4_0 block and 16 floats (yl), sumy is SUM(yl[i]) // il indicates where the q4 quants begin (0 or QK4_0/4) // we assume that the yl's have been multiplied with the appropriate scale factor // that corresponds to the missing bit shifts (1, 1/16, 1/256, 1/4096) inline float block_q_n_dot_y(device const block_q4_0 * qb_curr, float sumy, thread float * yl, int il) { float d = qb_curr->d; float acc[4] = { 0.0f, 0.0f, 0.0f, 0.0f }; device const uint16_t * qs = ((device const uint16_t *) qb_curr + 1 + il/2); for (int i = 0; i < 8; i += 2) { acc[0] += yl[i + 0] * (qs[i / 2] & 0x000F); acc[1] += yl[i + 1] * (qs[i / 2] & 0x0F00); acc[2] += yl[i + 8] * (qs[i / 2] & 0x00F0); acc[3] += yl[i + 9] * (qs[i / 2] & 0xF000); } return d * (sumy * -8.f + acc[0] + acc[1] + acc[2] + acc[3]); } // function for calculate inner product between half a q4_1 block and 16 floats (yl), sumy is SUM(yl[i]) // il indicates where the q4 quants begin (0 or QK4_0/4) // we assume that the yl's have been multiplied with the appropriate scale factor // that corresponds to the missing bit shifts (1, 1/16, 1/256, 1/4096) inline float block_q_n_dot_y(device const block_q4_1 * qb_curr, float sumy, thread float * yl, int il) { float d = qb_curr->d; float m = qb_curr->m; float acc[4] = { 0.0f, 0.0f, 0.0f, 0.0f }; device const uint16_t * qs = ((device const uint16_t *) qb_curr + 2 + il/2); for (int i = 0; i < 8; i+=2) { acc[0] += yl[i + 0] * (qs[i / 2] & 0x000F); acc[1] += yl[i + 1] * (qs[i / 2] & 0x0F00); acc[2] += yl[i + 8] * (qs[i / 2] & 0x00F0); acc[3] += yl[i + 9] * (qs[i / 2] & 0xF000); } return d * (acc[0] + acc[1] + acc[2] + acc[3]) + sumy * m; } // function for calculate inner product between half a q5_0 block and 16 floats (yl), sumy is SUM(yl[i]) // il indicates where the q5 quants begin (0 or QK5_0/4) // we assume that the yl's have been multiplied with the appropriate scale factor // that corresponds to the missing bit shifts (1, 1/16, 1/256, 1/4096) inline float block_q_n_dot_y(device const block_q5_0 * qb_curr, float sumy, thread float * yl, int il) { float d = qb_curr->d; float acc[4] = { 0.0f, 0.0f, 0.0f, 0.0f }; device const uint16_t * qs = ((device const uint16_t *)qb_curr + 3 + il/2); const uint32_t qh = *((device const uint32_t *)qb_curr->qh); for (int i = 0; i < 8; i+=2) { acc[0] += yl[i + 0] * ((qs[i / 2] & 0x000F) | ((qh >> (i+0+il ) << 4 ) & 0x00010)); acc[1] += yl[i + 1] * ((qs[i / 2] & 0x0F00) | ((qh >> (i+1+il ) << 12) & 0x01000)); acc[2] += yl[i + 8] * ((qs[i / 2] & 0x00F0) | ((qh >> (i+0+il+QK5_0/2) << 8 ) & 0x00100)); acc[3] += yl[i + 9] * ((qs[i / 2] & 0xF000) | ((qh >> (i+1+il+QK5_0/2) << 16) & 0x10000)); } return d * (sumy * -16.f + acc[0] + acc[1] + acc[2] + acc[3]); } // function for calculate inner product between half a q5_1 block and 16 floats (yl), sumy is SUM(yl[i]) // il indicates where the q5 quants begin (0 or QK5_1/4) // we assume that the yl's have been multiplied with the appropriate scale factor // that corresponds to the missing bit shifts (1, 1/16, 1/256, 1/4096) inline float block_q_n_dot_y(device const block_q5_1 * qb_curr, float sumy, thread float * yl, int il) { float d = qb_curr->d; float m = qb_curr->m; float acc[4] = { 0.0f, 0.0f, 0.0f, 0.0f }; device const uint16_t * qs = ((device const uint16_t *)qb_curr + 4 + il/2); const uint32_t qh = *((device const uint32_t *)qb_curr->qh); for (int i = 0; i < 8; i+=2) { acc[0] += yl[i + 0] * ((qs[i / 2] & 0x000F) | ((qh >> (i+0+il ) << 4 ) & 0x00010)); acc[1] += yl[i + 1] * ((qs[i / 2] & 0x0F00) | ((qh >> (i+1+il ) << 12) & 0x01000)); acc[2] += yl[i + 8] * ((qs[i / 2] & 0x00F0) | ((qh >> (i+0+il+QK5_0/2) << 8 ) & 0x00100)); acc[3] += yl[i + 9] * ((qs[i / 2] & 0xF000) | ((qh >> (i+1+il+QK5_0/2) << 16) & 0x10000)); } return d * (acc[0] + acc[1] + acc[2] + acc[3]) + sumy * m; } template static inline void helper_mv_reduce_and_write( device float * dst_f32, float sumf[NR0], const int r0, const int ne01, ushort tiisg, ushort sgitg, threadgroup char * shmem) { constexpr short NW = N_SIMDWIDTH; threadgroup float * shmem_f32[NR0]; for (short row = 0; row < NR0; ++row) { shmem_f32[row] = (threadgroup float *) shmem + NW*row; if (sgitg == 0) { shmem_f32[row][tiisg] = 0.0f; } sumf[row] = simd_sum(sumf[row]); } threadgroup_barrier(mem_flags::mem_threadgroup); for (short row = 0; row < NR0; ++row) { if (tiisg == 0) { shmem_f32[row][sgitg] = sumf[row]; } } threadgroup_barrier(mem_flags::mem_threadgroup); for (short row = 0; row < NR0 && r0 + row < ne01; ++row) { float tot = simd_sum(shmem_f32[row][tiisg]); if (tiisg == 0 && sgitg == 0) { dst_f32[r0 + row] = tot; } } } constant short FC_mul_mv_nsg [[function_constant(FC_MUL_MV + 0)]]; constant short FC_mul_mv_nxpsg [[function_constant(FC_MUL_MV + 1)]]; template void mul_vec_q_n_f32_impl( args_t args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem, uint3 tgpig, ushort tiisg, ushort sgitg) { const short NSG = FC_mul_mv_nsg; constexpr short NW = N_SIMDWIDTH; constexpr short NQ = 16; const int nb = args.ne00/QK4_0; const int r0 = (tgpig.x*NSG + sgitg)*NR0; //const int r0 = tgpig.x*NR0; const int r1 = tgpig.y; const int im = tgpig.z; const uint i12 = im%args.ne12; const uint i13 = im/args.ne12; //const uint64_t offset0 = r0*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; const uint64_t offset1 = r1*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; //device const block_q_type * x = (device const block_q_type *) (src0 + offset0); device const float * y = (device const float *) (src1 + offset1); // pointers to src0 rows device const block_q_type * ax[NR0]; FOR_UNROLL (int row = 0; row < NR0; ++row) { const uint64_t offset0 = (r0 + row)*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; ax[row] = (device const block_q_type *) ((device char *) src0 + offset0); } float sumf[NR0] = {0.f}; const short ix = (tiisg/(NW/NQ)); const short il = (tiisg%(NW/NQ))*8; //const int ib0 = sgitg*NQ + ix; const int ib0 = ix; float yl[16]; // src1 vector cache //device const float * yb = y + ix*QK4_0 + il; device const float * yb = y + ib0*QK4_0 + il; // each thread in a SIMD group deals with half a block. //for (int ib = ib0; ib < nb; ib += NSG*NQ) { for (int ib = ib0; ib < nb; ib += NQ) { float sumy[2] = { 0.f, 0.f }; FOR_UNROLL (short i = 0; i < 8; i += 2) { sumy[0] += yb[i + 0] + yb[i + 1]; yl[i + 0] = yb[i + 0]; yl[i + 1] = yb[i + 1]/256.f; sumy[1] += yb[i + 16] + yb[i + 17]; yl[i + 8] = yb[i + 16]/16.f; yl[i + 9] = yb[i + 17]/4096.f; } FOR_UNROLL (short row = 0; row < NR0; row++) { sumf[row] += block_q_n_dot_y(ax[row] + ib, sumy[0] + sumy[1], yl, il); } yb += QK4_0 * 16; //yb += NSG*NQ*QK4_0; } device float * dst_f32 = (device float *) dst + im*args.ne0*args.ne1 + r1*args.ne0; //helper_mv_reduce_and_write(dst_f32, sumf, r0, args.ne01, tiisg, sgitg, shmem); for (int row = 0; row < NR0; ++row) { const float tot = simd_sum(sumf[row]); if (tiisg == 0 && r0 + row < args.ne01) { dst_f32[r0 + row] = tot; } } } kernel void kernel_mul_mv_q4_0_f32( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { mul_vec_q_n_f32_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } kernel void kernel_mul_mv_q4_1_f32( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { mul_vec_q_n_f32_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } kernel void kernel_mul_mv_q5_0_f32( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { mul_vec_q_n_f32_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } kernel void kernel_mul_mv_q5_1_f32( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { mul_vec_q_n_f32_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } template void kernel_mul_mv_q8_0_f32_impl( args_t args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem, uint3 tgpig, ushort tiisg, ushort sgitg) { const short NSG = FC_mul_mv_nsg; constexpr short NW = N_SIMDWIDTH; constexpr short NQ = 8; const int nb = args.ne00/QK8_0; const int r0 = tgpig.x*NR0; const int r1 = tgpig.y; const int im = tgpig.z; const uint i12 = im%args.ne12; const uint i13 = im/args.ne12; //const uint64_t offset0 = r0*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; const uint64_t offset1 = r1*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; //device const block_q8_0 * x = (device const block_q8_0 *) (src0 + offset0); device const float * y = (device const float *) (src1 + offset1); // pointers to src0 rows device const block_q8_0 * ax[NR0]; FOR_UNROLL (short row = 0; row < NR0; ++row) { const uint64_t offset0 = (r0 + row)*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; ax[row] = (device const block_q8_0 *) ((device char *) src0 + offset0); } float sumf[NR0] = { 0.f }; const short ix = tiisg/(NW/NQ); const short il = tiisg%(NW/NQ); const int ib0 = sgitg*NQ + ix; float yl[NQ]; device const float * yb = y + ib0*QK8_0 + il*NQ; // each thread in a SIMD group deals with NQ quants at a time for (int ib = ib0; ib < nb; ib += NSG*NQ) { for (short i = 0; i < NQ; ++i) { yl[i] = yb[i]; } for (short row = 0; row < NR0; row++) { device const int8_t * qs = ax[row][ib].qs + il*NQ; float sumq = 0.f; FOR_UNROLL (short i = 0; i < NQ; ++i) { sumq += qs[i] * yl[i]; } sumf[row] += sumq*ax[row][ib].d; } yb += NSG*NQ*QK8_0; } device float * dst_f32 = (device float *) dst + (uint64_t)im*args.ne0*args.ne1 + (uint64_t)r1*args.ne0; helper_mv_reduce_and_write(dst_f32, sumf, r0, args.ne01, tiisg, sgitg, shmem); } [[host_name("kernel_mul_mv_q8_0_f32")]] kernel void kernel_mul_mv_q8_0_f32( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { kernel_mul_mv_q8_0_f32_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } // mat-vec kernel processing in chunks of float4 // chpb - chunks per quantization block template void kernel_mul_mv_ext_q4_f32_impl( constant ggml_metal_kargs_mul_mv_ext & args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { const short NSG = FC_mul_mv_nsg; const short nxpsg = FC_mul_mv_nxpsg; const short chpt = 4; // chunks per thread //const short nxpsg = (32); const short nypsg = (32/nxpsg); const short tx = tiisg%nxpsg; const short ty = tiisg/nxpsg; const int i01 = tgpig.x*(nypsg*NSG) + nypsg*sgitg + ty; const int i11 = tgpig.y*r1ptg; const int i1m = tgpig.z; const int i12 = i1m%args.ne12; const int i13 = i1m/args.ne12; const uint64_t offset0 = i01*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; const uint64_t offset1 = i11*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; device const q_t * xq = (i01 < args.ne01) ? (device const q_t *) (src0 + offset0) + tx/chpb : (device const q_t *) src0; device const float4 * y4[r1ptg]; for (int ir1 = 0; ir1 < r1ptg; ++ir1) { y4[ir1] = (i11 + ir1 < args.ne11) ? (device const float4 *) (src1 + offset1 + ir1*args.nb11) + tx : (device const float4 *) src1; } float sumf[r1ptg] = { [ 0 ... r1ptg - 1 ] = 0.0f }; short cch = tx%chpb; // current chunk index for (int ich = tx; 4*ich < args.ne00; ich += chpt*nxpsg) { float4 lx[chpt]; #pragma unroll(chpt) for (short ch = 0; ch < chpt; ++ch) { deq_t4(xq, cch, lx[ch]); cch += nxpsg; if (cch >= chpb) { xq += cch/chpb; cch %= chpb; } } #pragma unroll(chpt) for (short ch = 0; ch < chpt; ++ch) { #pragma unroll(r1ptg) for (short ir1 = 0; ir1 < r1ptg; ++ir1) { sumf[ir1] += dot(lx[ch], y4[ir1][ch*nxpsg]); } } #pragma unroll(r1ptg) for (short ir1 = 0; ir1 < r1ptg; ++ir1) { y4[ir1] += chpt*nxpsg; } } // reduce only the threads in each row for (short ir1 = 0; ir1 < r1ptg; ++ir1) { if (nxpsg >= 32) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 16); } if (nxpsg >= 16) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 8); } if (nxpsg >= 8) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 4); } if (nxpsg >= 4) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 2); } if (nxpsg >= 2) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 1); } //sumf[ir1] = simd_sum(sumf[ir1]); } if (tx == 0) { for (short ir1 = 0; ir1 < r1ptg && i11 + ir1 < args.ne11; ++ir1) { device float * dst_f32 = (device float *) dst + (uint64_t)i1m*args.ne0*args.ne1 + (uint64_t)(i11 + ir1)*args.ne0; if (i01 < args.ne01) { dst_f32[i01] = sumf[ir1]; } } } } // mat-vec kernel processing in chunks of float4x4 template void kernel_mul_mv_ext_q4x4_f32_impl( constant ggml_metal_kargs_mul_mv_ext & args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { const short NSG = FC_mul_mv_nsg; const short nxpsg = FC_mul_mv_nxpsg; const short chpt = 1; //const short nxpsg = (32); const short nypsg = (32/nxpsg); const short tx = tiisg%nxpsg; const short ty = tiisg/nxpsg; const int i01 = tgpig.x*(nypsg*NSG) + nypsg*sgitg + ty; const int i11 = tgpig.y*r1ptg; const int i1m = tgpig.z; const int i12 = i1m%args.ne12; const int i13 = i1m/args.ne12; const uint64_t offset0 = i01*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; const uint64_t offset1 = i11*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; device const q_t * xq = (i01 < args.ne01) ? (device const q_t *) (src0 + offset0) + tx/chpb : (device const q_t *) src0; device const float4x4 * y4x4[r1ptg]; for (int ir1 = 0; ir1 < r1ptg; ++ir1) { y4x4[ir1] = (i11 + ir1 < args.ne11) ? (device const float4x4 *) (src1 + offset1 + ir1*args.nb11) + tx : (device const float4x4 *) src1; } float sumf[r1ptg] = { [ 0 ... r1ptg - 1 ] = 0.0f }; short cch = tx%chpb; for (int ich = tx; 16*ich < args.ne00; ich += chpt*nxpsg) { float4x4 lx[chpt]; #pragma unroll(chpt) for (short ch = 0; ch < chpt; ++ch) { deq_t4x4(xq, cch, lx[ch]); cch += nxpsg; if (cch >= chpb) { xq += cch/chpb; cch %= chpb; } } #pragma unroll(chpt) for (short ch = 0; ch < chpt; ++ch) { #pragma unroll(r1ptg) for (short ir1 = 0; ir1 < r1ptg; ++ir1) { sumf[ir1] += dot(lx[ch][0], y4x4[ir1][ch*nxpsg][0]) + dot(lx[ch][1], y4x4[ir1][ch*nxpsg][1]) + dot(lx[ch][2], y4x4[ir1][ch*nxpsg][2]) + dot(lx[ch][3], y4x4[ir1][ch*nxpsg][3]); } } #pragma unroll(r1ptg) for (short ir1 = 0; ir1 < r1ptg; ++ir1) { y4x4[ir1] += chpt*nxpsg; } } for (short ir1 = 0; ir1 < r1ptg; ++ir1) { if (nxpsg >= 32) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 16); } if (nxpsg >= 16) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 8); } if (nxpsg >= 8) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 4); } if (nxpsg >= 4) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 2); } if (nxpsg >= 2) { sumf[ir1] += simd_shuffle_down(sumf[ir1], 1); } //sumf[ir1] = simd_sum(sumf[ir1]); } if (tx == 0) { for (short ir1 = 0; ir1 < r1ptg && i11 + ir1 < args.ne11; ++ir1) { device float * dst_f32 = (device float *) dst + (uint64_t)i1m*args.ne0*args.ne1 + (uint64_t)(i11 + ir1)*args.ne0; if (i01 < args.ne01) { dst_f32[i01] = sumf[ir1]; } } } } // dispatchers needed for compile-time nxpsg // epb - elements per quantization block template kernel void kernel_mul_mv_ext_q4_f32_disp( constant ggml_metal_kargs_mul_mv_ext & args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { kernel_mul_mv_ext_q4_f32_impl(args, src0, src1, dst, tgpig, tiisg, sgitg); } template kernel void kernel_mul_mv_ext_q4x4_f32_disp( constant ggml_metal_kargs_mul_mv_ext & args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { kernel_mul_mv_ext_q4x4_f32_impl(args, src0, src1, dst, tgpig, tiisg, sgitg); } typedef decltype(kernel_mul_mv_ext_q4_f32_disp <2, block_q8_0, 32, dequantize_q8_0_t4>) mul_mv_ext_q4_f32_t; typedef decltype(kernel_mul_mv_ext_q4x4_f32_disp<2, block_q4_K, 256, dequantize_q4_K>) mul_mv_ext_q4x4_f32_t; template [[host_name("kernel_mul_mv_ext_f32_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, float4, 4, dequantize_f32_t4>; template [[host_name("kernel_mul_mv_ext_f32_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, float4, 4, dequantize_f32_t4>; template [[host_name("kernel_mul_mv_ext_f32_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, float4, 4, dequantize_f32_t4>; template [[host_name("kernel_mul_mv_ext_f32_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, float4, 4, dequantize_f32_t4>; template [[host_name("kernel_mul_mv_ext_f16_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, half4, 4, dequantize_f16_t4>; template [[host_name("kernel_mul_mv_ext_f16_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, half4, 4, dequantize_f16_t4>; template [[host_name("kernel_mul_mv_ext_f16_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, half4, 4, dequantize_f16_t4>; template [[host_name("kernel_mul_mv_ext_f16_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, half4, 4, dequantize_f16_t4>; template [[host_name("kernel_mul_mv_ext_q4_0_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_q4_0, 32, dequantize_q4_0_t4>; template [[host_name("kernel_mul_mv_ext_q4_0_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_q4_0, 32, dequantize_q4_0_t4>; template [[host_name("kernel_mul_mv_ext_q4_0_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_q4_0, 32, dequantize_q4_0_t4>; template [[host_name("kernel_mul_mv_ext_q4_0_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_q4_0, 32, dequantize_q4_0_t4>; template [[host_name("kernel_mul_mv_ext_q4_1_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_q4_1, 32, dequantize_q4_1_t4>; template [[host_name("kernel_mul_mv_ext_q4_1_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_q4_1, 32, dequantize_q4_1_t4>; template [[host_name("kernel_mul_mv_ext_q4_1_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_q4_1, 32, dequantize_q4_1_t4>; template [[host_name("kernel_mul_mv_ext_q4_1_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_q4_1, 32, dequantize_q4_1_t4>; template [[host_name("kernel_mul_mv_ext_q5_0_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_q5_0, 32, dequantize_q5_0_t4>; template [[host_name("kernel_mul_mv_ext_q5_0_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_q5_0, 32, dequantize_q5_0_t4>; template [[host_name("kernel_mul_mv_ext_q5_0_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_q5_0, 32, dequantize_q5_0_t4>; template [[host_name("kernel_mul_mv_ext_q5_0_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_q5_0, 32, dequantize_q5_0_t4>; template [[host_name("kernel_mul_mv_ext_q5_1_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_q5_1, 32, dequantize_q5_1_t4>; template [[host_name("kernel_mul_mv_ext_q5_1_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_q5_1, 32, dequantize_q5_1_t4>; template [[host_name("kernel_mul_mv_ext_q5_1_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_q5_1, 32, dequantize_q5_1_t4>; template [[host_name("kernel_mul_mv_ext_q5_1_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_q5_1, 32, dequantize_q5_1_t4>; template [[host_name("kernel_mul_mv_ext_q8_0_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_q8_0, 32, dequantize_q8_0_t4>; template [[host_name("kernel_mul_mv_ext_q8_0_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_q8_0, 32, dequantize_q8_0_t4>; template [[host_name("kernel_mul_mv_ext_q8_0_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_q8_0, 32, dequantize_q8_0_t4>; template [[host_name("kernel_mul_mv_ext_q8_0_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_q8_0, 32, dequantize_q8_0_t4>; template [[host_name("kernel_mul_mv_ext_mxfp4_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_mxfp4, 32, dequantize_mxfp4_t4>; template [[host_name("kernel_mul_mv_ext_mxfp4_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_mxfp4, 32, dequantize_mxfp4_t4>; template [[host_name("kernel_mul_mv_ext_mxfp4_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_mxfp4, 32, dequantize_mxfp4_t4>; template [[host_name("kernel_mul_mv_ext_mxfp4_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_mxfp4, 32, dequantize_mxfp4_t4>; template [[host_name("kernel_mul_mv_ext_iq4_nl_f32_r1_2")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<2, block_iq4_nl, 32, dequantize_iq4_nl_t4>; template [[host_name("kernel_mul_mv_ext_iq4_nl_f32_r1_3")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<3, block_iq4_nl, 32, dequantize_iq4_nl_t4>; template [[host_name("kernel_mul_mv_ext_iq4_nl_f32_r1_4")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<4, block_iq4_nl, 32, dequantize_iq4_nl_t4>; template [[host_name("kernel_mul_mv_ext_iq4_nl_f32_r1_5")]] kernel mul_mv_ext_q4_f32_t kernel_mul_mv_ext_q4_f32_disp<5, block_iq4_nl, 32, dequantize_iq4_nl_t4>; template [[host_name("kernel_mul_mv_ext_q4_K_f32_r1_2")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<2, block_q4_K, 256, dequantize_q4_K>; template [[host_name("kernel_mul_mv_ext_q4_K_f32_r1_3")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<3, block_q4_K, 256, dequantize_q4_K>; template [[host_name("kernel_mul_mv_ext_q4_K_f32_r1_4")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<4, block_q4_K, 256, dequantize_q4_K>; template [[host_name("kernel_mul_mv_ext_q4_K_f32_r1_5")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<5, block_q4_K, 256, dequantize_q4_K>; template [[host_name("kernel_mul_mv_ext_q5_K_f32_r1_2")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<2, block_q5_K, 256, dequantize_q5_K>; template [[host_name("kernel_mul_mv_ext_q5_K_f32_r1_3")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<3, block_q5_K, 256, dequantize_q5_K>; template [[host_name("kernel_mul_mv_ext_q5_K_f32_r1_4")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<4, block_q5_K, 256, dequantize_q5_K>; template [[host_name("kernel_mul_mv_ext_q5_K_f32_r1_5")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<5, block_q5_K, 256, dequantize_q5_K>; template [[host_name("kernel_mul_mv_ext_q6_K_f32_r1_2")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<2, block_q6_K, 256, dequantize_q6_K>; template [[host_name("kernel_mul_mv_ext_q6_K_f32_r1_3")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<3, block_q6_K, 256, dequantize_q6_K>; template [[host_name("kernel_mul_mv_ext_q6_K_f32_r1_4")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<4, block_q6_K, 256, dequantize_q6_K>; template [[host_name("kernel_mul_mv_ext_q6_K_f32_r1_5")]] kernel mul_mv_ext_q4x4_f32_t kernel_mul_mv_ext_q4x4_f32_disp<5, block_q6_K, 256, dequantize_q6_K>; template void kernel_mul_mv_t_t_impl( args_t args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem, uint3 tgpig, ushort tiisg, ushort sgitg) { const short NSG = FC_mul_mv_nsg; constexpr short NW = N_SIMDWIDTH; constexpr short NB = 32; constexpr short NF = 8; const int nb = args.ne00/NB; const int r0 = tgpig.x*NR0; const int r1 = tgpig.y; const int im = tgpig.z; const uint i12 = im%args.ne12; const uint i13 = im/args.ne12; //const uint64_t offset0 = r0*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; const uint64_t offset1 = r1*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; //device const T0 * x = (device const T0 *) (src0 + offset0); device const T1 * y = (device const T1 *) (src1 + offset1); // pointers to src0 rows device const T0 * ax [NR0]; FOR_UNROLL (short row = 0; row < NR0; ++row) { const uint64_t offset0 = (r0 + row)*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; ax[row] = (device const T0 *) ((device char *) src0 + offset0); } float sumf[NR0] = { 0.f }; const short ix = tiisg/(NW/NF); const short il = tiisg%(NW/NF); const int ib0 = sgitg*NF + ix; T1 yl[NF]; device const T1 * yb = y + (ib0*NB + il*NF); for (int ib = ib0; ib < nb; ib += NSG*NF) { for (short i = 0; i < NF; ++i) { yl[i] = yb[i]; } for (short row = 0; row < NR0; row++) { device const T0 * xb = ax[row] + (ib*NB + il*NF); float sumq = 0.f; FOR_UNROLL (short i = 0; i < NF; ++i) { sumq += xb[i] * yl[i]; } sumf[row] += sumq; } yb += NSG*NF*NW; } for (int i = nb*NB + sgitg*NW + tiisg; i < args.ne00; i += NW*NSG) { for (short row = 0; row < NR0; row++) { sumf[row] += ax[row][i] * y[i]; } } device float * dst_f32 = (device float *) dst + (uint64_t)im*args.ne0*args.ne1 + (uint64_t)r1*args.ne0; helper_mv_reduce_and_write(dst_f32, sumf, r0, args.ne01, tiisg, sgitg, shmem); } template void kernel_mul_mv_t_t_disp( args_t args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem, uint3 tgpig, ushort tiisg, ushort sgitg) { switch (args.nr0) { //case 1: kernel_mul_mv_t_t_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; case 2: kernel_mul_mv_t_t_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; //case 3: kernel_mul_mv_t_t_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; //case 4: kernel_mul_mv_t_t_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; } } template kernel void kernel_mul_mv_t_t( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { kernel_mul_mv_t_t_disp(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } typedef decltype(kernel_mul_mv_t_t) mul_mv_t_t; template [[host_name("kernel_mul_mv_f32_f32")]] kernel mul_mv_t_t kernel_mul_mv_t_t; template [[host_name("kernel_mul_mv_f16_f32")]] kernel mul_mv_t_t kernel_mul_mv_t_t; template [[host_name("kernel_mul_mv_f16_f16")]] kernel mul_mv_t_t kernel_mul_mv_t_t; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_mul_mv_bf16_f32")]] kernel mul_mv_t_t kernel_mul_mv_t_t; template [[host_name("kernel_mul_mv_bf16_bf16")]] kernel mul_mv_t_t kernel_mul_mv_t_t; #endif template void kernel_mul_mv_t_t_4_impl( args_t args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem, uint3 tgpig, ushort tiisg, ushort sgitg) { const short NSG = FC_mul_mv_nsg; constexpr short NW = N_SIMDWIDTH; constexpr short NB = 32; constexpr short NF = 16; constexpr short NF4 = NF/4; const int nb = args.ne00/NB; const int r0 = tgpig.x*NR0; const int r1 = tgpig.y; const int im = tgpig.z; const uint i12 = im%args.ne12; const uint i13 = im/args.ne12; //const uint64_t offset0 = r0*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; const uint64_t offset1 = r1*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; device const T1 * y = (device const T1 *) (src1 + offset1); device const T14 * y4 = (device const T14 *) (src1 + offset1); // pointers to src0 rows device const T0 * ax [NR0]; device const T04 * ax4[NR0]; FOR_UNROLL (short row = 0; row < NR0; ++row) { const uint64_t offset0 = (r0 + row)*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; ax [row] = (device const T0 *) ((device char *) src0 + offset0); ax4[row] = (device const T04 *) ((device char *) src0 + offset0); } float sumf[NR0] = { 0.f }; const short ix = tiisg/(NW/NF); const short il = tiisg%(NW/NF); const int ib0 = sgitg*NF + ix; T14 yl4[NF4]; device const T14 * yb4 = y4 + (ib0*NB + il*NF)/4; for (int ib = ib0; ib < nb; ib += NSG*NF) { for (short i = 0; i < NF4; ++i) { yl4[i] = yb4[i]; } for (short row = 0; row < NR0; row++) { device const T04 * xb4 = ax4[row] + (ib*NB + il*NF)/4; float sumq = 0.f; FOR_UNROLL (short i = 0; i < NF4; ++i) { sumq += dot(float4(xb4[i]), float4(yl4[i])); } sumf[row] += sumq; } yb4 += NSG*NF*NW/4; } for (int i = nb*NB + sgitg*NW + tiisg; i < args.ne00; i += NW*NSG) { for (short row = 0; row < NR0; row++) { sumf[row] += ax[row][i] * y[i]; } } device float * dst_f32 = (device float *) dst + (uint64_t)im*args.ne0*args.ne1 + (uint64_t)r1*args.ne0; helper_mv_reduce_and_write(dst_f32, sumf, r0, args.ne01, tiisg, sgitg, shmem); } template void kernel_mul_mv_t_t_4_disp( args_t args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem, uint3 tgpig, ushort tiisg, ushort sgitg) { switch (args.nr0) { //case 1: kernel_mul_mv_t_t_4_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; case 2: kernel_mul_mv_t_t_4_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; //case 3: kernel_mul_mv_t_t_4_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; //case 4: kernel_mul_mv_t_t_4_impl(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); break; }; } template kernel void kernel_mul_mv_t_t_4( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, threadgroup char * shmem [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { kernel_mul_mv_t_t_4_disp(args, src0, src1, dst, shmem, tgpig, tiisg, sgitg); } typedef decltype(kernel_mul_mv_t_t_4) mul_mv_t_t_4; template [[host_name("kernel_mul_mv_f32_f32_4")]] kernel mul_mv_t_t_4 kernel_mul_mv_t_t_4; template [[host_name("kernel_mul_mv_f16_f32_4")]] kernel mul_mv_t_t_4 kernel_mul_mv_t_t_4; template [[host_name("kernel_mul_mv_f16_f16_4")]] kernel mul_mv_t_t_4 kernel_mul_mv_t_t_4; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_mul_mv_bf16_f32_4")]] kernel mul_mv_t_t_4 kernel_mul_mv_t_t_4; template [[host_name("kernel_mul_mv_bf16_bf16_4")]] kernel mul_mv_t_t_4 kernel_mul_mv_t_t_4; #endif template void kernel_mul_mv_t_t_short_impl( args_t args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig, ushort tiisg) { const int r0 = tgpig.x*32 + tiisg; const int r1 = tgpig.y; const int im = tgpig.z; if (r0 >= args.ne01) { return; } const uint i12 = im%args.ne12; const uint i13 = im/args.ne12; const uint64_t offset0 = r0*args.nb01 + (i12/args.r2)*args.nb02 + (i13/args.r3)*args.nb03; device const T0 * x = (device const T0 *) (src0 + offset0); device float * dst_f32 = (device float *) dst + (uint64_t)im*args.ne0*args.ne1; const uint64_t offset1 = r1*args.nb11 + (i12 )*args.nb12 + (i13 )*args.nb13; device const T1 * y = (device const T1 *) (src1 + offset1); float res = 0.0f; for (int i = 0; i < args.ne00; ++i) { res += (float) x[i] * (float) y[i]; } dst_f32[(uint64_t)r1*args.ne0 + r0] = res; } template kernel void kernel_mul_mv_t_t_short( constant ggml_metal_kargs_mul_mv & args, device const char * src0, device const char * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]]) { kernel_mul_mv_t_t_short_impl( args, src0, src1, dst, tgpig, tiisg); } typedef decltype(kernel_mul_mv_t_t_short) mul_mv_t_t_short_t; template [[host_name("kernel_mul_mv_f32_f32_short")]] kernel mul_mv_t_t_short_t kernel_mul_mv_t_t_short; template [[host_name("kernel_mul_mv_f16_f32_short")]] kernel mul_mv_t_t_short_t kernel_mul_mv_t_t_short; template [[host_name("kernel_mul_mv_f16_f16_short")]] kernel mul_mv_t_t_short_t kernel_mul_mv_t_t_short; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_mul_mv_bf16_f32_short")]] kernel mul_mv_t_t_short_t kernel_mul_mv_t_t_short; template [[host_name("kernel_mul_mv_bf16_bf16_short")]] kernel mul_mv_t_t_short_t kernel_mul_mv_t_t_short; #endif constant bool FC_rope_is_imrope [[function_constant(FC_ROPE + 0)]]; static float rope_yarn_ramp(const float low, const float high, const int i0) { const float y = (i0 / 2 - low) / max(0.001f, high - low); return 1.0f - min(1.0f, max(0.0f, y)); } // YaRN algorithm based on LlamaYaRNScaledRotaryEmbedding.py from https://github.com/jquesnelle/yarn // MIT licensed. Copyright (c) 2023 Jeffrey Quesnelle and Bowen Peng. static void rope_yarn( float theta_extrap, float freq_scale, float corr_dims[2], int i0, float ext_factor, float mscale, thread float * cos_theta, thread float * sin_theta) { // Get n-d rotational scaling corrected for extrapolation float theta_interp = freq_scale * theta_extrap; float theta = theta_interp; if (ext_factor != 0.0f) { float ramp_mix = rope_yarn_ramp(corr_dims[0], corr_dims[1], i0) * ext_factor; theta = theta_interp * (1 - ramp_mix) + theta_extrap * ramp_mix; // Get n-d magnitude scaling corrected for interpolation mscale *= 1.0f + 0.1f * log(1.0f / freq_scale); } *cos_theta = cos(theta) * mscale; *sin_theta = sin(theta) * mscale; } // Apparently solving `n_rot = 2pi * x * base^((2 * max_pos_emb) / n_dims)` for x, we get // `corr_fac(n_rot) = n_dims * log(max_pos_emb / (n_rot * 2pi)) / (2 * log(base))` static float rope_yarn_corr_factor(int n_dims, int n_ctx_orig, float n_rot, float base) { return n_dims * log(n_ctx_orig / (n_rot * 2 * M_PI_F)) / (2 * log(base)); } static void rope_yarn_corr_dims( int n_dims, int n_ctx_orig, float freq_base, float beta_fast, float beta_slow, float dims[2] ) { // start and end correction dims dims[0] = max(0.0f, floor(rope_yarn_corr_factor(n_dims, n_ctx_orig, beta_fast, freq_base))); dims[1] = min(n_dims - 1.0f, ceil(rope_yarn_corr_factor(n_dims, n_ctx_orig, beta_slow, freq_base))); } template kernel void kernel_rope_norm( constant ggml_metal_kargs_rope & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, ushort tiitg[[thread_index_in_threadgroup]], ushort3 tptg [[threads_per_threadgroup]], uint3 tgpig[[threadgroup_position_in_grid]]) { const int i3 = tgpig[2]; const int i2 = tgpig[1]; const int i1 = tgpig[0]; float corr_dims[2]; rope_yarn_corr_dims(args.n_dims, args.n_ctx_orig, args.freq_base, args.beta_fast, args.beta_slow, corr_dims); device const int32_t * pos = (device const int32_t *) src1; const float theta_base = (float) pos[i2]; const float inv_ndims = -1.f/args.n_dims; float cos_theta; float sin_theta; for (int i0 = 2*tiitg; i0 < args.ne0; i0 += 2*tptg.x) { if (i0 < args.n_dims) { const int ic = i0/2; const float theta = theta_base * pow(args.freq_base, inv_ndims*i0); const float freq_factor = args.src2 ? ((device const float *) src2)[ic] : 1.0f; rope_yarn(theta/freq_factor, args.freq_scale, corr_dims, i0, args.ext_factor, args.attn_factor, &cos_theta, &sin_theta); device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + i0*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); const float x0 = src[0]; const float x1 = src[1]; dst_data[0] = x0*cos_theta - x1*sin_theta; dst_data[1] = x0*sin_theta + x1*cos_theta; } else { device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + i0*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); dst_data[0] = src[0]; dst_data[1] = src[1]; } } } template kernel void kernel_rope_neox( constant ggml_metal_kargs_rope & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, ushort tiitg[[thread_index_in_threadgroup]], ushort3 tptg [[threads_per_threadgroup]], uint3 tgpig[[threadgroup_position_in_grid]]) { const int i3 = tgpig[2]; const int i2 = tgpig[1]; const int i1 = tgpig[0]; float corr_dims[2]; rope_yarn_corr_dims(args.n_dims, args.n_ctx_orig, args.freq_base, args.beta_fast, args.beta_slow, corr_dims); device const int32_t * pos = (device const int32_t *) src1; const float theta_base = (float) pos[i2]; const float inv_ndims = -1.f/args.n_dims; float cos_theta; float sin_theta; for (int i0 = 2*tiitg; i0 < args.ne0; i0 += 2*tptg.x) { if (i0 < args.n_dims) { const int ic = i0/2; const float theta = theta_base * pow(args.freq_base, inv_ndims*i0); const float freq_factor = args.src2 ? ((device const float *) src2)[ic] : 1.0f; rope_yarn(theta/freq_factor, args.freq_scale, corr_dims, i0, args.ext_factor, args.attn_factor, &cos_theta, &sin_theta); device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + ic*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + ic*args.nb0); const float x0 = src[0]; const float x1 = src[args.n_dims/2]; dst_data[0] = x0*cos_theta - x1*sin_theta; dst_data[args.n_dims/2] = x0*sin_theta + x1*cos_theta; } else { device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + i0*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); dst_data[0] = src[0]; dst_data[1] = src[1]; } } } template kernel void kernel_rope_multi( constant ggml_metal_kargs_rope & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, ushort tiitg[[thread_index_in_threadgroup]], ushort3 tptg [[threads_per_threadgroup]], uint3 tgpig[[threadgroup_position_in_grid]]) { const int i3 = tgpig[2]; const int i2 = tgpig[1]; const int i1 = tgpig[0]; float corr_dims[2]; rope_yarn_corr_dims(args.n_dims, args.n_ctx_orig, args.freq_base, args.beta_fast, args.beta_slow, corr_dims); device const int32_t * pos = (device const int32_t *) src1; const float inv_ndims = -1.f/args.n_dims; float cos_theta; float sin_theta; for (int i0 = 2*tiitg; i0 < args.ne0; i0 += 2*tptg.x) { if (i0 < args.n_dims) { const int ic = i0/2; // mrope theta calculations // note: the rest is the same as kernel_rope_neox const int sect_dims = args.sect_0 + args.sect_1 + args.sect_2 + args.sect_3; const int sec_w01 = args.sect_0 + args.sect_1; // end of section 1 const int sec_w012 = args.sect_0 + args.sect_1 + args.sect_2; // end of section 2 const int sector = ic % sect_dims; float theta_base; if (FC_rope_is_imrope) { if (sector % 3 == 1 && sector < 3 * args.sect_1) { // h theta_base = (float) pos[i2 + args.ne02 * 1]; } else if (sector % 3 == 2 && sector < 3 * args.sect_2) { // w theta_base = (float) pos[i2 + args.ne02 * 2]; } else if (sector % 3 == 0 && sector < 3 * args.sect_0) { // t theta_base = (float) pos[i2 + args.ne02 * 0]; } else { // e theta_base = (float) pos[i2 + args.ne02 * 3]; } } else { if (sector < args.sect_0) { theta_base = (float) pos[i2]; } else if (sector < sec_w01) { theta_base = (float) pos[i2 + args.ne02 * 1]; } else if (sector < sec_w012) { theta_base = (float) pos[i2 + args.ne02 * 2]; } else { theta_base = (float) pos[i2 + args.ne02 * 3]; } } // end of mrope const float theta = theta_base * pow(args.freq_base, inv_ndims*i0); const float freq_factor = args.src2 ? ((device const float *) src2)[ic] : 1.0f; rope_yarn(theta/freq_factor, args.freq_scale, corr_dims, i0, args.ext_factor, args.attn_factor, &cos_theta, &sin_theta); device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + ic*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + ic*args.nb0); const float x0 = src[0]; const float x1 = src[args.n_dims/2]; dst_data[0] = x0*cos_theta - x1*sin_theta; dst_data[args.n_dims/2] = x0*sin_theta + x1*cos_theta; } else { device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + i0*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); dst_data[0] = src[0]; dst_data[1] = src[1]; } } } template kernel void kernel_rope_vision( constant ggml_metal_kargs_rope & args, device const char * src0, device const char * src1, device const char * src2, device char * dst, ushort tiitg[[thread_index_in_threadgroup]], ushort3 tptg [[threads_per_threadgroup]], uint3 tgpig[[threadgroup_position_in_grid]]) { const int i3 = tgpig[2]; const int i2 = tgpig[1]; const int i1 = tgpig[0]; float corr_dims[2]; rope_yarn_corr_dims(args.n_dims, args.n_ctx_orig, args.freq_base, args.beta_fast, args.beta_slow, corr_dims); device const int32_t * pos = (device const int32_t *) src1; const float inv_ndims = -1.f/args.n_dims; float cos_theta; float sin_theta; for (int i0 = 2*tiitg; i0 < args.ne0; i0 += 2*tptg.x) { if (i0 < 2*args.n_dims) { // different from kernel_rope_multi const int ic = i0/2; // mrope theta calculations (only support 2 dimensions) const int sect_dims = args.sect_0 + args.sect_1; const int sector = ic % sect_dims; float p; float theta_base; if (sector < args.sect_1) { p = (float) sector; theta_base = (float) pos[i2]; } else { p = (float) sector - args.sect_0; theta_base = (float) pos[i2 + args.ne02]; } const float theta = theta_base * pow(args.freq_base, 2.0f * inv_ndims * p); // end of mrope const float freq_factor = args.src2 ? ((device const float *) src2)[ic] : 1.0f; rope_yarn(theta/freq_factor, args.freq_scale, corr_dims, i0, args.ext_factor, args.attn_factor, &cos_theta, &sin_theta); device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + ic*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + ic*args.nb0); const float x0 = src[0]; const float x1 = src[args.n_dims]; // different from kernel_rope_multi dst_data[0] = x0*cos_theta - x1*sin_theta; dst_data[args.n_dims] = x0*sin_theta + x1*cos_theta; // different from kernel_rope_multi } else { device const T * const src = (device T *)(src0 + i3*args.nb03 + i2*args.nb02 + i1*args.nb01 + i0*args.nb00); device T * dst_data = (device T *)( dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); dst_data[0] = src[0]; dst_data[1] = src[1]; } } } typedef decltype(kernel_rope_norm) kernel_rope_norm_t; typedef decltype(kernel_rope_neox) kernel_rope_neox_t; typedef decltype(kernel_rope_multi) kernel_rope_multi_t; typedef decltype(kernel_rope_vision) kernel_rope_vision_t; template [[host_name("kernel_rope_norm_f32")]] kernel kernel_rope_norm_t kernel_rope_norm; template [[host_name("kernel_rope_norm_f16")]] kernel kernel_rope_norm_t kernel_rope_norm; template [[host_name("kernel_rope_neox_f32")]] kernel kernel_rope_neox_t kernel_rope_neox; template [[host_name("kernel_rope_neox_f16")]] kernel kernel_rope_neox_t kernel_rope_neox; template [[host_name("kernel_rope_multi_f32")]] kernel kernel_rope_multi_t kernel_rope_multi; template [[host_name("kernel_rope_multi_f16")]] kernel kernel_rope_multi_t kernel_rope_multi; template [[host_name("kernel_rope_vision_f32")]] kernel kernel_rope_vision_t kernel_rope_vision; template [[host_name("kernel_rope_vision_f16")]] kernel kernel_rope_vision_t kernel_rope_vision; typedef void (im2col_t)( constant ggml_metal_kargs_im2col & args, device const float * x, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]); template kernel void kernel_im2col( constant ggml_metal_kargs_im2col & args, device const float * x, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { // const int64_t IC = tgpg[0]; const int64_t OH = tgpg[1]; const int64_t OW = tgpg[2]; const int64_t KH = ntg[1]; const int64_t KW = ntg[2]; int64_t in = tpitg[0]; const int64_t ikh = tpitg[1]; const int64_t ikw = tpitg[2]; const int64_t iic = tgpig[0]; const int64_t ioh = tgpig[1]; const int64_t iow = tgpig[2]; const int64_t iiw = iow*args.s0 + ikw*args.d0 - args.p0; const int64_t iih = ioh*args.s1 + ikh*args.d1 - args.p1; int64_t offset_dst = (in*OH*OW + ioh*OW + iow)*args.CHW + (iic*(KH*KW) + ikh*KW + ikw); device T * pdst = (device T *) (dst); if (iih < 0 || iih >= args.IH || iiw < 0 || iiw >= args.IW) { while (in < args.N) { pdst[offset_dst] = 0.0f; offset_dst += ntg[0]*args.CHW*OH*OW; in += ntg[0]; } } else { int64_t offset_src = in*args.ofs0 + iic*args.ofs1 + iih*args.IW + iiw; while (in < args.N) { pdst[offset_dst] = x[offset_src]; offset_dst += ntg[0]*args.CHW*OH*OW; offset_src += ntg[0]*args.ofs0; in += ntg[0]; } } } template [[host_name("kernel_im2col_f32")]] kernel im2col_t kernel_im2col; template [[host_name("kernel_im2col_f16")]] kernel im2col_t kernel_im2col; // TODO: obolete -- remove //typedef void (im2col_ext_t)( // constant ggml_metal_kargs_im2col & args, // device const float * x, // device char * dst, // uint3 tgpig[[threadgroup_position_in_grid]], // uint3 tgpg[[threadgroups_per_grid]], // uint3 tpitg[[thread_position_in_threadgroup]], // uint3 ntg[[threads_per_threadgroup]]); // //template //kernel void kernel_im2col_ext( // constant ggml_metal_kargs_im2col & args, // device const float * x, // device char * dst, // uint3 tgpig[[threadgroup_position_in_grid]], // uint3 tgpg[[threadgroups_per_grid]], // tgpg[0] = D x IC x KH x KW, CHW = IC x KH x KW // uint3 tpitg[[thread_position_in_threadgroup]], // uint3 ntg[[threads_per_threadgroup]]) { // [M, 1, 1] // const int64_t KHW = (int64_t)args.KHW; // // const int64_t d = tgpig[0] / args.CHW; // const int64_t chw = tgpig[0] % args.CHW; // const int64_t tgpig_0 = chw / KHW; // 0 ~ (IC - 1) // const int64_t HW = tgpig[0] % KHW; // // const int64_t tpitg_0 = (d * ntg[0]) + tpitg[0]; // if (tpitg_0 >= args.N) { // return; // } // // const int64_t tpitg_1 = HW / args.KW; // const int64_t tpitg_2 = HW % args.KW; // // const int64_t iiw = tgpig[2] * args.s0 + tpitg_2 * args.d0 - args.p0; // const int64_t iih = tgpig[1] * args.s1 + tpitg_1 * args.d1 - args.p1; // // const int64_t offset_dst = // (tpitg_0 * tgpg[1] * tgpg[2] + tgpig[1] * tgpg[2] + tgpig[2]) * args.CHW + // (tgpig_0 * KHW + tpitg_1 * args.KW + tpitg_2); // // device T * pdst = (device T *) (dst); // // if (iih < 0 || iih >= args.IH || iiw < 0 || iiw >= args.IW) { // pdst[offset_dst] = 0.0f; // } else { // const int64_t offset_src = tpitg_0 * args.ofs0 + tgpig_0 * args.ofs1; // pdst[offset_dst] = x[offset_src + iih * args.IW + iiw]; // } //} // //template [[host_name("kernel_im2col_ext_f32")]] kernel im2col_ext_t kernel_im2col_ext; //template [[host_name("kernel_im2col_ext_f16")]] kernel im2col_ext_t kernel_im2col_ext; template kernel void kernel_conv_2d( constant ggml_metal_kargs_conv_2d & args, device const char * weights, device const char * src, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const uint threads_per_tg = ntg.x * ntg.y * ntg.z; const uint tg_index = (tgpig.z * tgpg.y + tgpig.y) * tgpg.x + tgpig.x; const uint local_thread = tpitg.z * (ntg.x * ntg.y) + tpitg.y * ntg.x + tpitg.x; const uint thread_index = tg_index * threads_per_tg + local_thread; const uint64_t total_threads = (uint64_t) threads_per_tg * tgpg.x * tgpg.y * tgpg.z; const uint64_t total_outputs = (uint64_t) args.N * args.OC * args.OH * args.OW; for (uint64_t index = thread_index; index < total_outputs; index += total_threads) { uint64_t tmp = index; const int32_t ow = tmp % args.OW; tmp /= args.OW; const int32_t oh = tmp % args.OH; tmp /= args.OH; const int32_t oc = tmp % args.OC; tmp /= args.OC; const int32_t n = tmp; float acc = 0.0f; const int32_t base_x = ow*args.s0 - args.p0; const int32_t base_y = oh*args.s1 - args.p1; int32_t ky_start = 0; if (base_y < 0) { ky_start = (-base_y + args.d1 - 1)/args.d1; } int32_t ky_end = args.KH; const int32_t y_max = args.IH - 1 - base_y; if (y_max < 0) { ky_end = ky_start; } else if (base_y + (args.KH - 1)*args.d1 >= args.IH) { ky_end = min(ky_end, y_max/args.d1 + 1); } int32_t kx_start = 0; if (base_x < 0) { kx_start = (-base_x + args.d0 - 1)/args.d0; } int32_t kx_end = args.KW; const int32_t x_max = args.IW - 1 - base_x; if (x_max < 0) { kx_end = kx_start; } else if (base_x + (args.KW - 1)*args.d0 >= args.IW) { kx_end = min(kx_end, x_max/args.d0 + 1); } if (ky_start < ky_end && kx_start < kx_end) { const uint64_t src_base_n = (uint64_t) n * args.nb13; const uint64_t w_base_oc = (uint64_t) oc * args.nb03; for (int32_t ic = 0; ic < args.IC; ++ic) { const uint64_t src_base_nc = src_base_n + (uint64_t) ic * args.nb12; const uint64_t w_base_ocic = w_base_oc + (uint64_t) ic * args.nb02; for (int32_t ky = ky_start; ky < ky_end; ++ky) { const int32_t iy = base_y + ky*args.d1; const uint64_t src_base_row = src_base_nc + (uint64_t) iy * args.nb11; const uint64_t w_base_row = w_base_ocic + (uint64_t) ky * args.nb01; for (int32_t kx = kx_start; kx < kx_end; ++kx) { const int32_t ix = base_x + kx*args.d0; const uint64_t src_offs = src_base_row + (uint64_t) ix * args.nb10; const uint64_t w_offs = w_base_row + (uint64_t) kx * args.nb00; const float x = *(device const float *)(src + src_offs); const float w = (float) (*(device const TK *)(weights + w_offs)); acc += x * w; } } } } const uint64_t dst_offs = (uint64_t) n * args.nb3 + (uint64_t) oc * args.nb2 + (uint64_t) oh * args.nb1 + (uint64_t) ow * args.nb0; *(device float *)(dst + dst_offs) = acc; } } template [[host_name("kernel_conv_2d_f32_f32")]] kernel void kernel_conv_2d( constant ggml_metal_kargs_conv_2d & args, device const char * weights, device const char * src, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]); template [[host_name("kernel_conv_2d_f16_f32")]] kernel void kernel_conv_2d( constant ggml_metal_kargs_conv_2d & args, device const char * weights, device const char * src, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]); typedef void (conv_transpose_1d_t)( constant ggml_metal_kargs_conv_transpose_1d & args, device const float * src0, device const float * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]]); template kernel void kernel_conv_transpose_1d( constant ggml_metal_kargs_conv_transpose_1d & args, device const T * src0, device const float * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]]) { float v = 0.0f; for (int64_t c = 0; c < args.IC; c++) { const int32_t kernel_offset = c * tgpg[1] * args.K + args.K * tgpig[1]; const int32_t input_offset = c * args.IL; for (int64_t i = 0; i < args.IL; i++) { if (tgpig[0] >= i * args.s0 && tgpig[0] < i * args.s0 + args.K) { v += src0[kernel_offset + tgpig[0] - i * args.s0] * src1[input_offset + i]; } } } device float * dst_ptr = (device float *) (dst + tgpig[0] * args.nb0 + tgpig[1] * args.nb1); dst_ptr[0] = v; } template [[host_name("kernel_conv_transpose_1d_f32_f32")]] kernel void kernel_conv_transpose_1d( constant ggml_metal_kargs_conv_transpose_1d & args, device const float * src0, device const float * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]]); template [[host_name("kernel_conv_transpose_1d_f16_f32")]] kernel void kernel_conv_transpose_1d( constant ggml_metal_kargs_conv_transpose_1d & args, device const half * src0, device const float * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]]); typedef void (conv_transpose_2d_t)( constant ggml_metal_kargs_conv_transpose_2d & args, device const float * src0, device const float * src1, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]]); template kernel void kernel_conv_transpose_2d( constant ggml_metal_kargs_conv_transpose_2d & args, device const T * src0, device const float * src1, device char * dst, threadgroup float * shared_sum [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const int64_t out_x = tgpig[0]; const int64_t out_y = tgpig[1]; const int64_t out_c = tgpig[2]; const int64_t kw = tpitg[0]; const int64_t kh = tpitg[1]; float v = 0.0f; for (int64_t in_c = 0; in_c < args.IC; in_c++) { int64_t in_y = out_y - kh; if (in_y < 0 || in_y % args.s0) continue; in_y /= args.s0; if (in_y >= args.IH) continue; int64_t in_x = out_x - kw; if (in_x < 0 || in_x % args.s0) continue; in_x /= args.s0; if (in_x >= args.IW) continue; const int64_t input_idx = (args.IW * args.IH) * in_c + (args.IW) * in_y + in_x; const int64_t kernel_idx = (args.KH * args.KW * args.OC) * in_c + (args.KH * args.KW) * out_c + (args.KW) * kh + kw; v += (float)src0[kernel_idx] * src1[input_idx]; } const uint tid = tpitg.y * ntg.x + tpitg.x; shared_sum[tid] = v; threadgroup_barrier(mem_flags::mem_threadgroup); if (tid == 0) { float total = 0.0f; const uint num_threads = ntg.x * ntg.y; for (uint i = 0; i < num_threads; i++) { total += shared_sum[i]; } device float * dst_ptr = (device float *) (dst + out_x*args.nb0 + out_y * args.nb1 + out_c*args.nb2); dst_ptr[0] = total; } } template [[host_name("kernel_conv_transpose_2d_f32_f32")]] kernel void kernel_conv_transpose_2d( constant ggml_metal_kargs_conv_transpose_2d & args, device const float * src0, device const float * src1, device char * dst, threadgroup float * shared_sum [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]); template [[host_name("kernel_conv_transpose_2d_f16_f32")]] kernel void kernel_conv_transpose_2d( constant ggml_metal_kargs_conv_transpose_2d & args, device const half * src0, device const float * src1, device char * dst, threadgroup float * shared_sum [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]); kernel void kernel_upscale_f32( constant ggml_metal_kargs_upscale & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const int64_t i3 = tgpig.z; const int64_t i2 = tgpig.y; const int64_t i1 = tgpig.x; const int64_t i03 = i3/args.sf3; const int64_t i02 = i2/args.sf2; const int64_t i01 = i1/args.sf1; for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { const int64_t i00 = i0/args.sf0; device const float * src0_ptr = (device const float *) (src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01 + i00*args.nb00); device float * dst_ptr = (device float *) (dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); dst_ptr[0] = src0_ptr[0]; } } kernel void kernel_pad_f32( constant ggml_metal_kargs_pad & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const int64_t i3 = tgpig.z; const int64_t i2 = tgpig.y; const int64_t i1 = tgpig.x; const int64_t i03 = i3; const int64_t i02 = i2; const int64_t i01 = i1; device const float * src0_ptr = (device const float *) (src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01); device float * dst_ptr = (device float *) (dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1); if (i1 < args.ne01 && i2 < args.ne02 && i3 < args.ne03) { for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { if (i0 < args.ne00) { dst_ptr[i0] = src0_ptr[i0]; } else { dst_ptr[i0] = 0.0f; } } return; } for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { dst_ptr[i0] = 0.0f; } } kernel void kernel_pad_reflect_1d_f32( constant ggml_metal_kargs_pad_reflect_1d & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tgpg[[threadgroups_per_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { const int64_t i3 = tgpig.z; const int64_t i2 = tgpig.y; const int64_t i1 = tgpig.x; const int64_t i03 = i3; const int64_t i02 = i2; const int64_t i01 = i1; device const float * src0_ptr = (device const float *) (src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01); device float * dst_ptr = (device float *) (dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1); if (i1 < args.ne01 && i2 < args.ne02 && i3 < args.ne03) { for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { if (i0 < args.p0) { dst_ptr[i0] = src0_ptr[args.p0 - i0]; } else if (i0 < args.ne0 - args.p1) { dst_ptr[i0] = src0_ptr[i0 - args.p0]; } else { dst_ptr[i0] = src0_ptr[(args.ne0 - args.p1 - args.p0) - (args.p1 + 1 - (args.ne0 - i0)) - 1]; } } } } kernel void kernel_arange_f32( constant ggml_metal_kargs_arange & args, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { device float * dst_ptr = (device float *) dst; for (int i0 = tpitg.x; i0 < args.ne0; i0 += ntg.x) { dst_ptr[i0] = args.start + args.step * i0; } } kernel void kernel_timestep_embedding_f32( constant ggml_metal_kargs_timestep_embedding & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], uint3 tpitg[[thread_position_in_threadgroup]], uint3 ntg[[threads_per_threadgroup]]) { int i = tgpig.x; device float * embed_data = (device float *)(dst + i*args.nb1); int half_ = args.dim / 2; for (int j = tpitg.x; j < half_; j += ntg.x) { float timestep = ((device float *)src0)[i]; float freq = (float)exp(-log((float)args.max_period) * j / half_); float arg = timestep * freq; embed_data[j ] = cos(arg); embed_data[j + half_] = sin(arg); } if (args.dim % 2 != 0 && tpitg.x == 0) { embed_data[2 * half_] = 0.f; } } // bitonic sort implementation following the CUDA kernels as reference typedef void (argsort_t)( constant ggml_metal_kargs_argsort & args, device const char * src0, device int32_t * dst, threadgroup int32_t * shmem_i32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]); template kernel void kernel_argsort_f32_i32( constant ggml_metal_kargs_argsort & args, device const char * src0, device int32_t * dst, threadgroup int32_t * shmem_i32 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { // bitonic sort const int col = tpitg[0]; const int ib = tgpig[0] / args.ne01; const int i00 = ib*ntg.x; const int i01 = tgpig[0] % args.ne01; const int i02 = tgpig[1]; const int i03 = tgpig[2]; device const float * src0_row = (device const float *) (src0 + args.nb01*i01 + args.nb02*i02 + args.nb03*i03); // initialize indices shmem_i32[col] = i00 + col; threadgroup_barrier(mem_flags::mem_threadgroup); for (int k = 2; k <= ntg.x; k *= 2) { for (int j = k / 2; j > 0; j /= 2) { int ixj = col ^ j; if (ixj > col) { if ((col & k) == 0) { if (shmem_i32[col] >= args.ne00 || (shmem_i32[ixj] < args.ne00 && (order == GGML_SORT_ORDER_ASC ? src0_row[shmem_i32[col]] > src0_row[shmem_i32[ixj]] : src0_row[shmem_i32[col]] < src0_row[shmem_i32[ixj]])) ) { SWAP(shmem_i32[col], shmem_i32[ixj]); } } else { if (shmem_i32[ixj] >= args.ne00 || (shmem_i32[col] < args.ne00 && (order == GGML_SORT_ORDER_ASC ? src0_row[shmem_i32[col]] < src0_row[shmem_i32[ixj]] : src0_row[shmem_i32[col]] > src0_row[shmem_i32[ixj]])) ) { SWAP(shmem_i32[col], shmem_i32[ixj]); } } } threadgroup_barrier(mem_flags::mem_threadgroup); } } const int64_t i0 = ib*args.top_k; // copy the result to dst without the padding if (i0 + col < args.ne0 && col < args.top_k) { dst += i0 + args.ne0*i01 + args.ne0*args.ne1*i02 + args.ne0*args.ne1*args.ne2*i03; dst[col] = shmem_i32[col]; } } template [[host_name("kernel_argsort_f32_i32_asc")]] kernel argsort_t kernel_argsort_f32_i32; template [[host_name("kernel_argsort_f32_i32_desc")]] kernel argsort_t kernel_argsort_f32_i32; typedef void (argsort_merge_t)( constant ggml_metal_kargs_argsort_merge & args, device const char * src0, device const int32_t * tmp, device int32_t * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]); template kernel void kernel_argsort_merge_f32_i32( constant ggml_metal_kargs_argsort_merge & args, device const char * src0, device const int32_t * tmp, device int32_t * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort3 tpitg[[thread_position_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int im = tgpig[0] / args.ne01; const int i01 = tgpig[0] % args.ne01; const int i02 = tgpig[1]; const int i03 = tgpig[2]; const int start = im * (2 * args.len); const int len0 = MIN(args.len, MAX(0, args.ne0 - (int)(start))); const int len1 = MIN(args.len, MAX(0, args.ne0 - (int)(start + args.len))); const int total = len0 + len1; device const int32_t * tmp0 = tmp + start + i01*args.ne0 + i02*args.ne0*args.ne01 + i03*args.ne0*args.ne01*args.ne02; device const int32_t * tmp1 = tmp0 + args.len; dst += start + i01*args.top_k + i02*args.top_k*args.ne01 + i03*args.top_k*args.ne01*args.ne02; device const float * src0_row = (device const float *)(src0 + args.nb01*i01 + args.nb02*i02 + args.nb03*i03); if (total == 0) { return; } const int chunk = (total + ntg.x - 1) / ntg.x; const int k0 = tpitg.x * chunk; const int k1 = MIN(MIN(k0 + chunk, total), args.top_k); if (k0 >= args.top_k) { return; } if (k0 >= total) { return; } int low = k0 > len1 ? k0 - len1 : 0; int high = MIN(k0, len0); // binary-search partition (i, j) such that i + j = k while (low < high) { const int mid = (low + high) >> 1; const int32_t idx0 = tmp0[mid]; const int32_t idx1 = tmp1[k0 - mid - 1]; const float val0 = src0_row[idx0]; const float val1 = src0_row[idx1]; bool take_left; if (order == GGML_SORT_ORDER_ASC) { take_left = (val0 <= val1); } else { take_left = (val0 >= val1); } if (take_left) { low = mid + 1; } else { high = mid; } } int i = low; int j = k0 - i; // keep the merge fronts into registers int32_t idx0 = 0; float val0 = 0.0f; if (i < len0) { idx0 = tmp0[i]; val0 = src0_row[idx0]; } int32_t idx1 = 0; float val1 = 0.0f; if (j < len1) { idx1 = tmp1[j]; val1 = src0_row[idx1]; } for (int k = k0; k < k1; ++k) { int32_t out_idx; if (i >= len0) { while (k < k1) { dst[k++] = tmp1[j++]; } break; } else if (j >= len1) { while (k < k1) { dst[k++] = tmp0[i++]; } break; } else { bool take_left; if (order == GGML_SORT_ORDER_ASC) { take_left = (val0 <= val1); } else { take_left = (val0 >= val1); } if (take_left) { out_idx = idx0; ++i; if (i < len0) { idx0 = tmp0[i]; val0 = src0_row[idx0]; } } else { out_idx = idx1; ++j; if (j < len1) { idx1 = tmp1[j]; val1 = src0_row[idx1]; } } } dst[k] = out_idx; } } template [[host_name("kernel_argsort_merge_f32_i32_asc")]] kernel argsort_merge_t kernel_argsort_merge_f32_i32; template [[host_name("kernel_argsort_merge_f32_i32_desc")]] kernel argsort_merge_t kernel_argsort_merge_f32_i32; constant bool FC_flash_attn_ext_pad_has_mask [[function_constant(FC_FLASH_ATTN_EXT_PAD + 0)]]; constant int32_t FC_flash_attn_ext_pad_ncpsg [[function_constant(FC_FLASH_ATTN_EXT_PAD + 25)]]; // pad the last chunk of C elements of k and v into a an extra pad buffer kernel void kernel_flash_attn_ext_pad( constant ggml_metal_kargs_flash_attn_ext_pad & args, device const char * k, device const char * v, device const char * mask, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiitg[[thread_index_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int32_t C = FC_flash_attn_ext_pad_ncpsg; device char * k_pad = dst; device char * v_pad = k_pad + args.nb11*C*args.ne_12_2*args.ne_12_3; device char * mask_pad = v_pad + args.nb21*C*args.ne_12_2*args.ne_12_3; const int32_t icp = args.ne11 % C; const int32_t ic0 = args.ne11 - icp; const int32_t i1 = tgpig[0]; const int32_t i2 = tgpig[1]; const int32_t i3 = tgpig[2]; if (i2 < args.ne_12_2 && i3 < args.ne_12_3) { device const char * k_src = k + args.nb11*(ic0 + i1) + args.nb12*i2 + args.nb13*i3; device const char * v_src = v + args.nb21*(ic0 + i1) + args.nb22*i2 + args.nb23*i3; device char * k_dst = k_pad + args.nb11*i1 + args.nb11*C*i2 + args.nb11*C*args.ne_12_2*i3; device char * v_dst = v_pad + args.nb21*i1 + args.nb21*C*i2 + args.nb21*C*args.ne_12_2*i3; if (i1 >= icp) { // here it is not important the exact value that will be used as we rely on masking out the scores in the attention for (uint64_t i = tiitg; i < args.nb11; i += ntg.x) { k_dst[i] = 0; } for (uint64_t i = tiitg; i < args.nb21; i += ntg.x) { v_dst[i] = 0; } } else { for (uint64_t i = tiitg; i < args.nb11; i += ntg.x) { k_dst[i] = k_src[i]; } for (uint64_t i = tiitg; i < args.nb21; i += ntg.x) { v_dst[i] = v_src[i]; } } } if (FC_flash_attn_ext_pad_has_mask) { if (i2 < args.ne32 && i3 < args.ne33) { for (int ib = i1; ib < args.ne31; ib += C) { device const half * mask_src = (device const half *)(mask + args.nb31*ib + args.nb32*i2 + args.nb33*i3) + ic0; device half * mask_dst = (device half *)(mask_pad) + C*ib + C*args.ne31*i2 + C*args.ne31*args.ne32*i3; for (int i = tiitg; i < C; i += ntg.x) { if (i >= icp) { mask_dst[i] = -MAXHALF; } else { mask_dst[i] = mask_src[i]; } } } } } } constant int32_t FC_flash_attn_ext_blk_nqptg [[function_constant(FC_FLASH_ATTN_EXT_BLK + 24)]]; constant int32_t FC_flash_attn_ext_blk_ncpsg [[function_constant(FC_FLASH_ATTN_EXT_BLK + 25)]]; // scan the blocks of the mask that are not masked // 0 - masked (i.e. full of -INF, skip) // 1 - not masked (i.e. at least one element of the mask is not -INF) // 2 - all zero kernel void kernel_flash_attn_ext_blk( constant ggml_metal_kargs_flash_attn_ext_blk & args, device const char * mask, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]]) { // block size C x Q const int32_t Q = FC_flash_attn_ext_blk_nqptg; const int32_t C = FC_flash_attn_ext_blk_ncpsg; constexpr short NW = N_SIMDWIDTH; const int32_t i3 = tgpig[2]/args.ne32; const int32_t i2 = tgpig[2]%args.ne32; const int32_t i1 = tgpig[1]; const int32_t i0 = tgpig[0]; char res = i0*C + C > args.ne30 ? 1 : 0; device const half * mask_src = (device const half *) (mask + (i1*Q)*args.nb31 + i2*args.nb32 + i3*args.nb33) + i0*C + tiisg; // detailed check of the elements of the block if ((C > NW || Q > 1) && res == 0) { half mmin = MAXHALF; half mmax = -MAXHALF; FOR_UNROLL (short j = 0; j < Q; ++j) { FOR_UNROLL (short ii = 0; ii < C/NW; ++ii) { mmin = min(mmin, mask_src[ii*NW]); mmax = max(mmax, mask_src[ii*NW]); } mask_src += args.nb31/2; } mmin = simd_min(mmin); mmax = simd_max(mmax); if (mmax > -MAXHALF) { if (mmin == 0.0 && mmax == 0.0) { res = 2; } else { res = 1; } } } const int32_t nblk1 = ((args.ne01 + Q - 1)/Q); const int32_t nblk0 = ((args.ne30 + C - 1)/C); if (tiisg == 0) { dst[((i3*args.ne32 + i2)*nblk1 + i1)*nblk0 + i0] = res; } } constant bool FC_flash_attn_ext_has_mask [[function_constant(FC_FLASH_ATTN_EXT + 0)]]; constant bool FC_flash_attn_ext_has_sinks [[function_constant(FC_FLASH_ATTN_EXT + 1)]]; constant bool FC_flash_attn_ext_has_bias [[function_constant(FC_FLASH_ATTN_EXT + 2)]]; constant bool FC_flash_attn_ext_has_scap [[function_constant(FC_FLASH_ATTN_EXT + 3)]]; constant bool FC_flash_attn_ext_has_kvpad [[function_constant(FC_FLASH_ATTN_EXT + 4)]]; constant bool FC_flash_attn_ext_bc_mask [[function_constant(FC_FLASH_ATTN_EXT + 10)]]; //constant float FC_flash_attn_ext_scale [[function_constant(FC_FLASH_ATTN_EXT + 10)]]; //constant float FC_flash_attn_ext_max_bias [[function_constant(FC_FLASH_ATTN_EXT + 11)]]; //constant float FC_flash_attn_ext_logit_softcap [[function_constant(FC_FLASH_ATTN_EXT + 12)]]; constant int32_t FC_flash_attn_ext_ns10 [[function_constant(FC_FLASH_ATTN_EXT + 20)]]; constant int32_t FC_flash_attn_ext_ns20 [[function_constant(FC_FLASH_ATTN_EXT + 21)]]; constant int32_t FC_flash_attn_ext_nsg [[function_constant(FC_FLASH_ATTN_EXT + 22)]]; // ref: https://arxiv.org/pdf/2307.08691.pdf template< typename q_t, // query types in shared memory typename q4_t, typename q8x8_t, typename k_t, // key types in shared memory typename k4x4_t, typename k8x8_t, typename v_t, // value types in shared memory typename v4x4_t, typename v8x8_t, typename qk_t, // Q*K types typename qk8x8_t, typename s_t, // soft-max types typename s2_t, typename s8x8_t, typename o_t, // attention accumulation types typename o4_t, typename o8x8_t, typename kd4x4_t, // key type in device memory short nl_k, void (*deq_k)(device const kd4x4_t *, short, thread k4x4_t &), typename vd4x4_t, // value type in device memory short nl_v, void (*deq_v)(device const vd4x4_t *, short, thread v4x4_t &), short DK, // K head size short DV, // V head size short Q, // queries per threadgroup short C, // cache items per threadgroup short NSG> // number of simd groups void kernel_flash_attn_ext_impl( constant ggml_metal_kargs_flash_attn_ext & args, device const char * q, device const char * k, device const char * v, device const char * mask, device const char * sinks, device const char * pad, device const char * blk, device char * dst, threadgroup half * shmem_f16, uint3 tgpig, ushort tiisg, ushort sgitg) { const ushort iq3 = tgpig[2]; const ushort iq2 = tgpig[1]; const ushort iq1 = tgpig[0]*Q; #define NS10 (FC_flash_attn_ext_ns10) #define NS20 (FC_flash_attn_ext_ns20) // note: I had some concerns that using this instead of the ugly macros above was affecting performance // need to re-check carefully and if no regressions are observerd - remove the macros // the concerns is that maybe using const variables requires extra registers? but not sure if the compiler // is clever enough to avoid this. unfortunately, using constexpr is not possible with FC //const short NS10 = FC_flash_attn_ext_ns10; //const short NS20 = FC_flash_attn_ext_ns20; constexpr short KV = 8; constexpr short DK4 = DK/4; constexpr short DK8 = DK/8; constexpr short DK16 = DK/16; constexpr short DV4 = DV/4; //constexpr short DV8 = DV/8; constexpr short DV16 = DV/16; constexpr short PV = PAD2(DV, 64); constexpr short PV4 = PV/4; constexpr short PV8 = PV/8; //constexpr short PV16 = PV/16; constexpr short NW = N_SIMDWIDTH; constexpr short NQ = Q/NSG; constexpr short SH = 2*C; // shared memory per simdgroup (s_t == float) constexpr short TS = 2*SH; constexpr short T = DK + 2*PV; // shared memory size per query in (half) threadgroup q_t * sq = (threadgroup q_t *) (shmem_f16 + 0*T); // holds the query data threadgroup q4_t * sq4 = (threadgroup q4_t *) (shmem_f16 + 0*T); // same as above but in q4_t threadgroup o_t * so = (threadgroup o_t *) (shmem_f16 + 0*T + Q*DK); // the result for all queries in 8x8 matrices (the O matrix from the paper) threadgroup o4_t * so4 = (threadgroup o4_t *) (shmem_f16 + 0*T + Q*DK); threadgroup s_t * ss = (threadgroup s_t *) (shmem_f16 + Q*T); // scratch buffer for attention, mask and diagonal matrix threadgroup s2_t * ss2 = (threadgroup s2_t *) (shmem_f16 + Q*T); // same as above but in s2_t threadgroup k_t * sk = (threadgroup k_t *) (shmem_f16 + sgitg*(4*16*KV) + Q*T + Q*TS); // scratch buffer to load K in shared memory threadgroup k4x4_t * sk4x4 = (threadgroup k4x4_t *) (shmem_f16 + sgitg*(4*16*KV) + Q*T + Q*TS); // same as above but in k4x4_t threadgroup v_t * sv = (threadgroup v_t *) (shmem_f16 + sgitg*(4*16*KV) + Q*T + Q*TS); // scratch buffer to load V in shared memory threadgroup v4x4_t * sv4x4 = (threadgroup v4x4_t *) (shmem_f16 + sgitg*(4*16*KV) + Q*T + Q*TS); // same as above but in v4x4_t // mask storage in shared mem threadgroup half2 * sm2 = (threadgroup half2 *) (shmem_f16 + Q*T + 2*C); // per-query mask pointers device const half2 * pm2[NQ]; FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; pm2[jj] = (device const half2 *) ((device const char *) mask + (iq1 + j)*args.nb31 + (iq2%args.ne32)*args.nb32 + (iq3%args.ne33)*args.nb33); } { const int32_t nblk1 = ((args.ne01 + Q - 1)/Q); const int32_t nblk0 = ((args.ne11 + C - 1)/C); blk += (((iq3%args.ne33)*args.ne32 + (iq2%args.ne32))*nblk1 + iq1/Q)*nblk0; } { q += iq1*args.nb01 + iq2*args.nb02 + iq3*args.nb03; const short ikv2 = iq2/(args.ne02/args.ne_12_2); const short ikv3 = iq3/(args.ne03/args.ne_12_3); k += ikv2*args.nb12 + ikv3*args.nb13; v += ikv2*args.nb22 + ikv3*args.nb23; } // load heads from Q to shared memory FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; device const float4 * q4 = (device const float4 *) ((device const char *) q + j*args.nb01); for (short i = tiisg; i < DK4; i += NW) { if (iq1 + j < args.ne01) { sq4[j*DK4 + i] = (q4_t) q4[i]; } else { sq4[j*DK4 + i] = 0; } } } // zero out FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; for (short i = tiisg; i < DV4; i += NW) { so4[j*PV4 + i] = 0; } for (short i = tiisg; i < SH; i += NW) { ss[j*SH + i] = 0.0f; } } threadgroup_barrier(mem_flags::mem_threadgroup); float S[NQ] = { [0 ... NQ-1] = 0.0f }; { float M[NQ] = { [0 ... NQ-1] = -FLT_MAX/2 }; float slope = 1.0f; // ALiBi if (FC_flash_attn_ext_has_bias) { const short h = iq2; const float base = h < args.n_head_log2 ? args.m0 : args.m1; const short exph = h < args.n_head_log2 ? h + 1 : 2*(h - args.n_head_log2) + 1; slope = pow(base, exph); } // loop over the KV cache // each simdgroup handles blocks of Q rows and C columns for (int ic0 = 0; ; ++ic0) { int ic = ic0*C; if (ic >= args.ne11) { break; } // the last partial chunk uses the pad buffer as source if (FC_flash_attn_ext_has_kvpad && ic + C > args.ne11) { k = pad; v = k + args.nb11*C*args.ne_12_2*args.ne_12_3; mask = v + args.nb21*C*args.ne_12_2*args.ne_12_3; const short ikv2 = iq2/(args.ne02/args.ne_12_2); const short ikv3 = iq3/(args.ne03/args.ne_12_3); k += (ikv2 + ikv3*args.ne_12_2)*args.nb11*C; v += (ikv2 + ikv3*args.ne_12_2)*args.nb21*C; if (!FC_flash_attn_ext_has_mask) { threadgroup half * sm = (threadgroup half *) (sm2); FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; for (short i = tiisg; i < C; i += NW) { if (ic + i >= args.ne11) { sm[2*j*SH + i] = -MAXHALF; } } } } else { FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; pm2[jj] = (device const half2 *) ((device const half *) mask + (iq1 + j)*C + (iq2%args.ne32)*(C*args.ne31) + (iq3%args.ne33)*(C*args.ne31*args.ne32)); } } ic = 0; } char blk_cur = 1; // read the mask into shared mem if (FC_flash_attn_ext_has_mask) { blk_cur = blk[ic0]; if (blk_cur == 0) { FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { pm2[jj] += NW; } continue; } if (blk_cur == 1) { FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; if (FC_flash_attn_ext_bc_mask) { sm2[j*SH + tiisg] = (iq1 + j) < args.ne31 ? pm2[jj][tiisg] : half2(-MAXHALF, -MAXHALF); } else { sm2[j*SH + tiisg] = pm2[jj][tiisg]; } pm2[jj] += NW; } } else if (blk_cur == 2) { FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { pm2[jj] += NW; } } #if 0 // note: old -INF block optimization - obsoleted by pre-computing non-masked blocks threadgroup_barrier(mem_flags::mem_threadgroup); // used to detect blocks full of -INF // skip only when the entire threadgroup is masked half2 smax2(-MAXHALF/2, -MAXHALF/2); FOR_UNROLL (short j = 0; j < Q; ++j) { smax2 = max(smax2, sm2[j*SH + tiisg]); } smax2 = simd_max(smax2); if (max(smax2[0], smax2[1]) <= -MAXHALF/2) { // this barrier is important threadgroup_barrier(mem_flags::mem_threadgroup); continue; } #endif } // Q*K^T // this is compile-time check, so it does not have runtime overhead if (is_same::value) { // we can read directly from global memory device const k_t * pk = (device const k_t *) (k + ic*args.nb11); threadgroup const q_t * pq = sq; threadgroup s_t * ps = ss; pk += sgitg*(8*NS10); ps += sgitg*(8*1); static_assert((C/8) % NSG == 0, ""); constexpr short NC = (C/8)/NSG; FOR_UNROLL (short cc = 0; cc < NC; ++cc) { qk8x8_t mqk = make_filled_simdgroup_matrix((qk_t) 0.0f); if (DK % 16 != 0) { k8x8_t mk; q8x8_t mq; FOR_UNROLL (short i = 0; i < DK8; ++i) { simdgroup_barrier(mem_flags::mem_none); simdgroup_load(mk, pk + 8*i, NS10, 0, true); simdgroup_load(mq, pq + 8*i, DK); simdgroup_barrier(mem_flags::mem_none); simdgroup_multiply_accumulate(mqk, mq, mk, mqk); } } else { k8x8_t mk[2]; q8x8_t mq[2]; // note: too much unroll can tank the performance for large heads #pragma unroll (MIN(DK8/2, 4*NSG)) for (short i = 0; i < DK8/2; ++i) { simdgroup_barrier(mem_flags::mem_none); simdgroup_load(mq[0], pq + 0*8 + 16*i, DK); simdgroup_load(mq[1], pq + 1*8 + 16*i, DK); simdgroup_load(mk[0], pk + 0*8 + 16*i, NS10, 0, true); simdgroup_load(mk[1], pk + 1*8 + 16*i, NS10, 0, true); simdgroup_barrier(mem_flags::mem_none); simdgroup_multiply_accumulate(mqk, mq[0], mk[0], mqk); simdgroup_multiply_accumulate(mqk, mq[1], mk[1], mqk); } } simdgroup_store(mqk, ps, SH, 0, false); pk += 8*(NSG*NS10); ps += 8*(NSG); } } else { // TODO: this is the quantized K cache branch - not optimized yet for (short ccc = 0; ccc < (C/8)/NSG; ++ccc) { const short cc = ccc*NSG + sgitg; const short tx = tiisg%4; const short ty = tiisg/4; qk8x8_t mqk = make_filled_simdgroup_matrix((qk_t) 0.0f); for (short ii = 0; ii < DK16; ii += 4) { device const kd4x4_t * pk4x4 = (device const kd4x4_t *) (k + ((ic + 8*cc + ty)*args.nb11)); if (DK16%4 == 0) { // the head is evenly divisible by 4*16 = 64, so no need for bound checks { k4x4_t tmp; deq_k(pk4x4 + (ii + tx)/nl_k, (ii + tx)%nl_k, tmp); sk4x4[4*ty + tx] = tmp; } simdgroup_barrier(mem_flags::mem_threadgroup); FOR_UNROLL (short k = 0; k < 4; ++k) { k8x8_t mk; q8x8_t mq; simdgroup_load(mk, sk + 16*k + 0*8, 4*16, 0, true); // transpose simdgroup_load(mq, sq + (2*(ii + k) + 0)*8, DK); simdgroup_multiply_accumulate(mqk, mq, mk, mqk); simdgroup_load(mk, sk + 16*k + 1*8, 4*16, 0, true); // transpose simdgroup_load(mq, sq + (2*(ii + k) + 1)*8, DK); simdgroup_multiply_accumulate(mqk, mq, mk, mqk); } } else { if (ii + tx < DK16) { k4x4_t tmp; deq_k(pk4x4 + (ii + tx)/nl_k, (ii + tx)%nl_k, tmp); sk4x4[4*ty + tx] = tmp; } simdgroup_barrier(mem_flags::mem_threadgroup); for (short k = 0; k < 4 && ii + k < DK16; ++k) { k8x8_t mk; q8x8_t mq; simdgroup_load(mk, sk + 16*k + 0*8, 4*16, 0, true); // transpose simdgroup_load(mq, sq + (2*(ii + k) + 0)*8, DK); simdgroup_multiply_accumulate(mqk, mq, mk, mqk); simdgroup_load(mk, sk + 16*k + 1*8, 4*16, 0, true); // transpose simdgroup_load(mq, sq + (2*(ii + k) + 1)*8, DK); simdgroup_multiply_accumulate(mqk, mq, mk, mqk); } } } simdgroup_store(mqk, ss + 8*cc, SH, 0, false); } } threadgroup_barrier(mem_flags::mem_threadgroup); // online softmax FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; const float m = M[jj]; // scale and apply the logitcap / mask float2 s2 = ss2[j*SH/2 + tiisg]*args.scale; if (FC_flash_attn_ext_has_scap) { s2 = args.logit_softcap*precise::tanh(s2); } // mqk = mqk + slope*mask if (blk_cur != 2) { if (FC_flash_attn_ext_has_bias) { s2 += s2_t(sm2[j*SH + tiisg])*slope; } else { s2 += s2_t(sm2[j*SH + tiisg]); } } M[jj] = simd_max(max(M[jj], max(s2[0], s2[1]))); const float ms = exp(m - M[jj]); const float2 vs2 = exp(s2 - M[jj]); S[jj] = S[jj]*ms + simd_sum(vs2[0] + vs2[1]); // the P matrix from the paper (Q rows, C columns) ss2[j*SH/2 + tiisg] = vs2; if (DV4 % NW == 0) { FOR_UNROLL (short ii = 0; ii < DV4/NW; ++ii) { const short i = ii*NW + tiisg; so4[j*PV4 + i] *= ms; } } else { for (short i = tiisg; i < DV4; i += NW) { so4[j*PV4 + i] *= ms; } } } threadgroup_barrier(mem_flags::mem_threadgroup); // O = O + (Q*K^T)*V { // we can read directly from global memory if (is_same::value) { static_assert(PV8 % NSG == 0, ""); constexpr short NO = PV8/NSG; o8x8_t lo[NO]; { auto sot = so + 8*sgitg; FOR_UNROLL (short ii = 0; ii < NO; ++ii) { simdgroup_load(lo[ii], sot, PV, 0, false); sot += 8*NSG; } } { device const v_t * pv = (device const v_t *) (v + ic*args.nb21); pv += 8*sgitg; if (DV <= 64) { FOR_UNROLL (short cc = 0; cc < C/8; ++cc) { s8x8_t vs; simdgroup_load(vs, ss + 8*cc, SH, 0, false); FOR_UNROLL (short ii = 0; ii < NO/2; ++ii) { v8x8_t mv[2]; simdgroup_load(mv[0], pv + 0*NSG + 16*ii*NSG, NS20, 0, false); simdgroup_load(mv[1], pv + 8*NSG + 16*ii*NSG, NS20, 0, false); simdgroup_multiply_accumulate(lo[2*ii + 0], vs, mv[0], lo[2*ii + 0]); simdgroup_multiply_accumulate(lo[2*ii + 1], vs, mv[1], lo[2*ii + 1]); } pv += 8*NS20; } } else { constexpr short NC = (C/8)/2; FOR_UNROLL (short cc = 0; cc < NC; ++cc) { s8x8_t vs[2]; simdgroup_load(vs[0], ss + 16*cc + 0, SH, 0, false); simdgroup_load(vs[1], ss + 16*cc + 8, SH, 0, false); FOR_UNROLL (short ii = 0; ii < NO/2; ++ii) { v8x8_t mv[4]; simdgroup_load(mv[0], pv + 0*NSG + 16*ii*NSG + 0*8*NS20, NS20, 0, false); simdgroup_load(mv[1], pv + 8*NSG + 16*ii*NSG + 0*8*NS20, NS20, 0, false); simdgroup_load(mv[2], pv + 0*NSG + 16*ii*NSG + 1*8*NS20, NS20, 0, false); simdgroup_load(mv[3], pv + 8*NSG + 16*ii*NSG + 1*8*NS20, NS20, 0, false); simdgroup_multiply_accumulate(lo[2*ii + 0], vs[0], mv[0], lo[2*ii + 0]); simdgroup_multiply_accumulate(lo[2*ii + 1], vs[0], mv[1], lo[2*ii + 1]); simdgroup_multiply_accumulate(lo[2*ii + 0], vs[1], mv[2], lo[2*ii + 0]); simdgroup_multiply_accumulate(lo[2*ii + 1], vs[1], mv[3], lo[2*ii + 1]); } pv += 2*8*NS20; } } } { auto sot = so + 8*sgitg; FOR_UNROLL (short ii = 0; ii < NO; ++ii) { simdgroup_store(lo[ii], sot, PV, 0, false); sot += 8*NSG; } } } else { // TODO: this is the quantized V cache branch - not optimized yet const short tx = tiisg%4; const short ty = tiisg/4; for (short cc = 0; cc < C/8; ++cc) { s8x8_t vs; simdgroup_load(vs, ss + 8*cc, SH, 0, false); for (short ii = 4*sgitg; ii < DV16; ii += 4*NSG) { device const vd4x4_t * pv4x4 = (device const vd4x4_t *) (v + ((ic + 8*cc + ty)*args.nb21)); if (DV16%4 == 0) { // no need for bound checks { v4x4_t tmp; deq_v(pv4x4 + (ii + tx)/nl_v, (ii + tx)%nl_v, tmp); sv4x4[4*ty + tx] = tmp; } simdgroup_barrier(mem_flags::mem_threadgroup); FOR_UNROLL (short k = 0; k < 4; ++k) { v8x8_t mv[2]; o8x8_t lo[2]; simdgroup_load(mv[0], sv + 16*k + 0*8, 4*16, 0, false); simdgroup_load(mv[1], sv + 16*k + 1*8, 4*16, 0, false); simdgroup_load(lo[0], so + 8*(2*(ii + k) + 0), PV, 0, false); simdgroup_load(lo[1], so + 8*(2*(ii + k) + 1), PV, 0, false); simdgroup_multiply_accumulate(lo[0], vs, mv[0], lo[0]); simdgroup_multiply_accumulate(lo[1], vs, mv[1], lo[1]); simdgroup_store(lo[0], so + 8*(2*(ii + k) + 0), PV, 0, false); simdgroup_store(lo[1], so + 8*(2*(ii + k) + 1), PV, 0, false); } } else { if (ii + tx < DV16) { v4x4_t tmp; deq_v(pv4x4 + (ii + tx)/nl_v, (ii + tx)%nl_v, tmp); sv4x4[4*ty + tx] = tmp; } simdgroup_barrier(mem_flags::mem_threadgroup); for (short k = 0; k < 4 && ii + k < DV16; ++k) { v8x8_t mv[2]; o8x8_t lo[2]; simdgroup_load(mv[0], sv + 16*k + 0*8, 4*16, 0, false); simdgroup_load(mv[1], sv + 16*k + 1*8, 4*16, 0, false); simdgroup_load(lo[0], so + 8*(2*(ii + k) + 0), PV, 0, false); simdgroup_load(lo[1], so + 8*(2*(ii + k) + 1), PV, 0, false); simdgroup_multiply_accumulate(lo[0], vs, mv[0], lo[0]); simdgroup_multiply_accumulate(lo[1], vs, mv[1], lo[1]); simdgroup_store(lo[0], so + 8*(2*(ii + k) + 0), PV, 0, false); simdgroup_store(lo[1], so + 8*(2*(ii + k) + 1), PV, 0, false); } } } } } } threadgroup_barrier(mem_flags::mem_threadgroup); } if (FC_flash_attn_ext_has_sinks) { FOR_UNROLL (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; const float m = M[jj]; const float s = tiisg == 0 ? ((device const float *) sinks)[iq2] : -FLT_MAX/2; M[jj] = simd_max(max(M[jj], s)); const float ms = exp(m - M[jj]); const float vs = exp(s - M[jj]); S[jj] = S[jj]*ms + simd_sum(vs); for (short i = tiisg; i < DV4; i += NW) { so4[j*PV4 + i] *= ms; } } } } // store to global memory for (short jj = 0; jj < NQ; ++jj) { const short j = jj*NSG + sgitg; if (iq1 + j >= args.ne01) { break; } device float4 * dst4 = (device float4 *) dst + ((uint64_t)iq3*args.ne2*args.ne1 + iq2 + (uint64_t)(iq1 + j)*args.ne1)*DV4; const float scale = S[jj] == 0.0 ? 0.0f : 1.0f/S[jj]; if (DV4 % NW == 0) { FOR_UNROLL (short ii = 0; ii < DV4/NW; ++ii) { const short i = ii*NW + tiisg; dst4[i] = (float4) so4[j*PV4 + i]*scale; } } else { for (short i = tiisg; i < DV4; i += NW) { dst4[i] = (float4) so4[j*PV4 + i]*scale; } } } #undef NS10 #undef NS20 } template< typename q_t, // query types in shared memory typename q4_t, typename q8x8_t, typename k_t, // key types in shared memory typename k4x4_t, typename k8x8_t, typename v_t, // value types in shared memory typename v4x4_t, typename v8x8_t, typename qk_t, // Q*K types typename qk8x8_t, typename s_t, // soft-max types typename s2_t, typename s8x8_t, typename o_t, // attention accumulation types typename o4_t, typename o8x8_t, typename kd4x4_t, // key type in device memory short nl_k, void (*deq_k)(device const kd4x4_t *, short, thread k4x4_t &), typename vd4x4_t, // value type in device memory short nl_v, void (*deq_v)(device const vd4x4_t *, short, thread v4x4_t &), short DK, // K head size short DV, // V head size short Q = OP_FLASH_ATTN_EXT_NQPSG, // queries per threadgroup short C = OP_FLASH_ATTN_EXT_NCPSG> // cache items per threadgroup kernel void kernel_flash_attn_ext( constant ggml_metal_kargs_flash_attn_ext & args, device const char * q, device const char * k, device const char * v, device const char * mask, device const char * sinks, device const char * pad, device const char * blk, device char * dst, threadgroup half * shmem_f16 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { #define FWD_TMPL q_t, q4_t, q8x8_t, k_t, k4x4_t, k8x8_t, v_t, v4x4_t, v8x8_t, qk_t, qk8x8_t, s_t, s2_t, s8x8_t, o_t, o4_t, o8x8_t, kd4x4_t, nl_k, deq_k, vd4x4_t, nl_v, deq_v, DK, DV, Q, C #define FWD_ARGS args, q, k, v, mask, sinks, pad, blk, dst, shmem_f16, tgpig, tiisg, sgitg switch (FC_flash_attn_ext_nsg) { // note: disabled cases to reduce library load time //case 1: kernel_flash_attn_ext_impl(FWD_ARGS); break; //case 2: kernel_flash_attn_ext_impl(FWD_ARGS); break; case 4: kernel_flash_attn_ext_impl(FWD_ARGS); break; case 8: kernel_flash_attn_ext_impl(FWD_ARGS); break; } #undef FWD_TMPL #undef FWD_ARGS } // TODO: this is quite ugly. in the future these types will be hardcoded in the kernel, but for now keep them as // template to be able to explore different combinations // #define FA_TYPES \ half, half4, simdgroup_half8x8, \ half, half4x4, simdgroup_half8x8, \ half, half4x4, simdgroup_half8x8, \ float, simdgroup_float8x8, \ float, float2, simdgroup_float8x8, \ float, float4, simdgroup_float8x8 //half, half4, simdgroup_half8x8 #define FA_TYPES_BF \ bfloat, bfloat4, simdgroup_bfloat8x8, \ bfloat, bfloat4x4, simdgroup_bfloat8x8, \ bfloat, bfloat4x4, simdgroup_bfloat8x8, \ float, simdgroup_float8x8, \ float, float2, simdgroup_float8x8, \ half, half4, simdgroup_half8x8 //float, float4, simdgroup_float8x8 #define FA_TYPES_F32 \ half, half4, simdgroup_half8x8, \ float, float4x4, simdgroup_float8x8, \ float, float4x4, simdgroup_float8x8, \ float, simdgroup_float8x8, \ float, float2, simdgroup_float8x8, \ float, float4, simdgroup_float8x8 //half, half4, simdgroup_half8x8 typedef decltype(kernel_flash_attn_ext) flash_attn_ext_t; template [[host_name("kernel_flash_attn_ext_f32_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f32_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_f16_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_bf16_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_bf16_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; #endif template [[host_name("kernel_flash_attn_ext_q4_0_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_0_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q4_1_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_0_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q5_1_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk32_dv32" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk40_dv40" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk48_dv48" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk64_dv64" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk72_dv72" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk80_dv80" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk96_dv96" )]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk112_dv112")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk128_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk192_dv192")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk192_dv128")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk256_dv256")]] kernel flash_attn_ext_t kernel_flash_attn_ext; template [[host_name("kernel_flash_attn_ext_q8_0_dk576_dv512")]] kernel flash_attn_ext_t kernel_flash_attn_ext; #undef FA_TYPES #undef FA_TYPES_BF #undef FA_TYPES_F32 constant bool FC_flash_attn_ext_vec_has_mask [[function_constant(FC_FLASH_ATTN_EXT_VEC + 0)]]; constant bool FC_flash_attn_ext_vec_has_sinks [[function_constant(FC_FLASH_ATTN_EXT_VEC + 1)]]; constant bool FC_flash_attn_ext_vec_has_bias [[function_constant(FC_FLASH_ATTN_EXT_VEC + 2)]]; constant bool FC_flash_attn_ext_vec_has_scap [[function_constant(FC_FLASH_ATTN_EXT_VEC + 3)]]; constant bool FC_flash_attn_ext_vec_has_kvpad [[function_constant(FC_FLASH_ATTN_EXT_VEC + 4)]]; //constant float FC_flash_attn_ext_vec_scale [[function_constant(FC_FLASH_ATTN_EXT_VEC + 10)]]; //constant float FC_flash_attn_ext_vec_max_bias [[function_constant(FC_FLASH_ATTN_EXT_VEC + 11)]]; //constant float FC_flash_attn_ext_vec_logit_softcap [[function_constant(FC_FLASH_ATTN_EXT_VEC + 12)]]; constant int32_t FC_flash_attn_ext_vec_ns10 [[function_constant(FC_FLASH_ATTN_EXT_VEC + 20)]]; constant int32_t FC_flash_attn_ext_vec_ns20 [[function_constant(FC_FLASH_ATTN_EXT_VEC + 21)]]; constant int32_t FC_flash_attn_ext_vec_nsg [[function_constant(FC_FLASH_ATTN_EXT_VEC + 22)]]; constant int32_t FC_flash_attn_ext_vec_nwg [[function_constant(FC_FLASH_ATTN_EXT_VEC + 23)]]; template< typename q4_t, // query types in shared memory typename k4_t, // key types in shared memory typename v4_t, // value types in shared memory typename qk_t, // Q*K types typename s_t, // soft-max types typename s4_t, typename o4_t, // attention accumulation types typename kd4_t, // key type in device memory short nl_k, void (*deq_k_t4)(device const kd4_t *, short, thread k4_t &), typename vd4_t, // value type in device memory short nl_v, void (*deq_v_t4)(device const vd4_t *, short, thread v4_t &), short DK, // K head size short DV, // V head size short NE = 4, // head elements per thread short Q = OP_FLASH_ATTN_EXT_VEC_NQPSG, // queries per threadgroup short C = OP_FLASH_ATTN_EXT_VEC_NCPSG> // cache items per threadgroup kernel void kernel_flash_attn_ext_vec( constant ggml_metal_kargs_flash_attn_ext_vec & args, device const char * q, device const char * k, device const char * v, device const char * mask, device const char * sinks, device const char * pad, device char * dst, threadgroup half * shmem_f16 [[threadgroup(0)]], uint3 tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { static_assert(DK % 32 == 0, "DK must be divisible by 32"); static_assert(DV % 32 == 0, "DV must be divisible by 32"); #define NWG (FC_flash_attn_ext_vec_nwg) #define NSG (FC_flash_attn_ext_vec_nsg) #define NS10 (FC_flash_attn_ext_vec_ns10) #define NS20 (FC_flash_attn_ext_vec_ns20) const short iwg = tgpig[2]%NWG; const ushort iq3 = tgpig[2]/NWG; const ushort iq2 = tgpig[1]; const ushort iq1 = tgpig[0]; constexpr short DK4 = DK/4; constexpr short DV4 = DV/4; constexpr short PK = PAD2(DK, 128); constexpr short PK4 = PK/4; constexpr short PV = PAD2(DV, 128); constexpr short PV4 = PV/4; constexpr short NW = N_SIMDWIDTH; constexpr short NL = NW/NE; // note: this can be adjusted to support different head sizes and simdgroup work loads constexpr short SH = 4*C; // shared memory per simdgroup static_assert(DK4 % NL == 0, "DK4 must be divisible by NL"); static_assert(DV4 % NL == 0, "DV4 must be divisible by NL"); const short T = PK + NSG*SH; // shared memory size per query in (half) //threadgroup q_t * sq = (threadgroup q_t *) (shmem_f16 + 0*PK); // holds the query data threadgroup q4_t * sq4 = (threadgroup q4_t *) (shmem_f16 + 0*PK); // same as above but in q4_t threadgroup s_t * ss = (threadgroup s_t *) (shmem_f16 + sgitg*SH + NSG*PK); // scratch buffer for attention threadgroup s4_t * ss4 = (threadgroup s4_t *) (shmem_f16 + sgitg*SH + NSG*PK); // same as above but in s4_t threadgroup half * sm = (threadgroup half *) (shmem_f16 + sgitg*SH + 2*C + NSG*PK); // scratch buffer for mask threadgroup o4_t * so4 = (threadgroup o4_t *) (shmem_f16 + 2*sgitg*PV + NSG*PK + NSG*SH); // scratch buffer for the results // store the result for all queries in shared memory (the O matrix from the paper) so4 += tiisg; { q += iq1*args.nb01 + iq2*args.nb02 + iq3*args.nb03; const short ikv2 = iq2/(args.ne02/args.ne_12_2); const short ikv3 = iq3/(args.ne03/args.ne_12_3); k += ikv2*args.nb12 + ikv3*args.nb13; v += ikv2*args.nb22 + ikv3*args.nb23; } // load heads from Q to shared memory device const float4 * q4 = (device const float4 *) ((device const char *) q); if (iq1 < args.ne01) { for (short i = tiisg; i < PK4; i += NW) { if (i < DK4) { sq4[i] = (q4_t) q4[i]; } else { sq4[i] = (q4_t) 0.0f; } } } // zero out so for (short i = 0; i < DV4/NL; ++i) { so4[i*NL] = (o4_t) 0.0f; } // zero out shared memory SH for (short i = tiisg; i < SH/4; i += NW) { ss4[i] = (s4_t) 0.0f; } threadgroup_barrier(mem_flags::mem_threadgroup); { float S = 0.0f; float M = -FLT_MAX/2; // thread indices inside the simdgroup const short tx = tiisg%NL; const short ty = tiisg/NL; // pointer to the mask device const half * pm = (device const half *) (mask + iq1*args.nb31 + (iq2%args.ne32)*args.nb32 + (iq3%args.ne33)*args.nb33); float slope = 1.0f; // ALiBi if (FC_flash_attn_ext_vec_has_bias) { const short h = iq2; const float base = h < args.n_head_log2 ? args.m0 : args.m1; const short exph = h < args.n_head_log2 ? h + 1 : 2*(h - args.n_head_log2) + 1; slope = pow(base, exph); } // loop over the KV cache // each simdgroup handles blocks of Q rows and C columns for (int ic0 = iwg*NSG + sgitg; ; ic0 += NWG*NSG) { int ic = ic0*C; if (ic >= args.ne11) { break; } // the last partial chunk uses the pad buffer as source if (FC_flash_attn_ext_vec_has_kvpad && ic + C > args.ne11) { k = pad; v = k + args.nb11*C*args.ne_12_2*args.ne_12_3; mask = v + args.nb21*C*args.ne_12_2*args.ne_12_3; const short ikv2 = iq2/(args.ne02/args.ne_12_2); const short ikv3 = iq3/(args.ne03/args.ne_12_3); k += (ikv2 + ikv3*args.ne_12_2)*args.nb11*C; v += (ikv2 + ikv3*args.ne_12_2)*args.nb21*C; if (!FC_flash_attn_ext_vec_has_mask) { if (ic + tiisg >= args.ne11) { sm[tiisg] = -MAXHALF; } } else { pm = (device const half *) (mask) + iq1*C + (iq2%args.ne32)*(C*args.ne31) + (iq3%args.ne33)*(C*args.ne31*args.ne32); } ic = 0; } if (FC_flash_attn_ext_vec_has_mask) { sm[tiisg] = pm[ic + tiisg]; } // skip -INF blocks if (simd_max(sm[tiisg]) <= -MAXHALF) { continue; } // Q*K^T { device const k4_t * pk4 = (device const k4_t *) (k + ic*args.nb11); threadgroup const q4_t * pq4 = sq4; pk4 += ty*NS10/4 + tx; pq4 += tx; qk_t mqk[C/NE] = { [ 0 ... C/NE - 1] = 0.0f }; // each simdgroup processes 1 query and NE (NW/NL) cache elements FOR_UNROLL (short cc = 0; cc < C/NE; ++cc) { if (is_same::value) { FOR_UNROLL (short ii = 0; ii < DK4/NL; ++ii) { mqk[cc] += dot((float4) pk4[cc*NE*NS10/4 + ii*NL], (float4) pq4[ii*NL]); } } else { device const kd4_t * pk = (device const kd4_t *) (k + ((ic + NE*cc + ty)*args.nb11)); k4_t mk; FOR_UNROLL (short ii = 0; ii < DK4/NL; ++ii) { const short i = ii*NL + tx; deq_k_t4(pk + i/nl_k, i%nl_k, mk); mqk[cc] += dot((float4) mk, (float4) sq4[i]); } } if (NE == 1) { mqk[cc] = simd_sum(mqk[cc]); } else { // simdgroup reduce (NE = 4) // [ 0 .. 7] -> [ 0] // [ 8 .. 15] -> [ 8] // [16 .. 23] -> [16] // [24 .. 31] -> [24] if (NE <= 1) { mqk[cc] += simd_shuffle_down(mqk[cc], 16); } if (NE <= 2) { mqk[cc] += simd_shuffle_down(mqk[cc], 8); } if (NE <= 4) { mqk[cc] += simd_shuffle_down(mqk[cc], 4); } if (NE <= 8) { mqk[cc] += simd_shuffle_down(mqk[cc], 2); } if (NE <= 16) { mqk[cc] += simd_shuffle_down(mqk[cc], 1); } // broadcast mqk[cc] = simd_shuffle(mqk[cc], NL*ty); } } if (FC_flash_attn_ext_vec_has_mask && !FC_flash_attn_ext_vec_has_scap && !FC_flash_attn_ext_vec_has_bias) { ss[NE*tx + ty] = fma(mqk[tx], args.scale, (qk_t) sm[NE*tx + ty]); } else { mqk[tx] *= args.scale; if (FC_flash_attn_ext_vec_has_scap) { mqk[tx] = args.logit_softcap*precise::tanh(mqk[tx]); } if (FC_flash_attn_ext_vec_has_bias) { mqk[tx] += (qk_t) sm[NE*tx + ty]*slope; } else { mqk[tx] += (qk_t) sm[NE*tx + ty]; } ss[NE*tx + ty] = mqk[tx]; } } simdgroup_barrier(mem_flags::mem_threadgroup); // online softmax { const float m = M; const float s = ss[tiisg]; M = simd_max(max(M, s)); const float ms = exp(m - M); const float vs = exp(s - M); S = S*ms + simd_sum(vs); // the P matrix from the paper (Q rows, C columns) ss[tiisg] = vs; // O = diag(ms)*O if ((DV4/NL % NW == 0) || ty == 0) { FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { so4[ii*NL] *= ms; } } } simdgroup_barrier(mem_flags::mem_threadgroup); // O = O + (Q*K^T)*V { o4_t lo[DV4/NL]; FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { lo[ii] = 0.0f; } if (is_same::value) { device const v4_t * pv4 = (device const v4_t *) (v + ic*args.nb21); pv4 += ty*NS20/4 + tx; const auto sst = ss + ty; FOR_UNROLL (short cc = 0; cc < C/NE; ++cc) { FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { lo[ii] += o4_t(float4(pv4[cc*NE*NS20/4 + ii*NL])*float4(sst[cc*NE])); } } } else { FOR_UNROLL (short cc = 0; cc < C/NE; ++cc) { device const vd4_t * pv4 = (device const vd4_t *) (v + ((ic + NE*cc + ty)*args.nb21)); FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { const short i = ii*NL + tx; v4_t mv; deq_v_t4(pv4 + i/nl_v, i%nl_v, mv); lo[ii] += o4_t(float4(mv)*float4(ss[NE*cc + ty])); } } } FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { if (NE > 1) { lo[ii][0] += simd_shuffle_down(lo[ii][0], 16); lo[ii][1] += simd_shuffle_down(lo[ii][1], 16); lo[ii][2] += simd_shuffle_down(lo[ii][2], 16); lo[ii][3] += simd_shuffle_down(lo[ii][3], 16); } if (NE > 2) { lo[ii][0] += simd_shuffle_down(lo[ii][0], 8); lo[ii][1] += simd_shuffle_down(lo[ii][1], 8); lo[ii][2] += simd_shuffle_down(lo[ii][2], 8); lo[ii][3] += simd_shuffle_down(lo[ii][3], 8); } if (NE > 4) { lo[ii][0] += simd_shuffle_down(lo[ii][0], 4); lo[ii][1] += simd_shuffle_down(lo[ii][1], 4); lo[ii][2] += simd_shuffle_down(lo[ii][2], 4); lo[ii][3] += simd_shuffle_down(lo[ii][3], 4); } if (NE > 8) { lo[ii][0] += simd_shuffle_down(lo[ii][0], 2); lo[ii][1] += simd_shuffle_down(lo[ii][1], 2); lo[ii][2] += simd_shuffle_down(lo[ii][2], 2); lo[ii][3] += simd_shuffle_down(lo[ii][3], 2); } if (NE > 16) { lo[ii][0] += simd_shuffle_down(lo[ii][0], 1); lo[ii][1] += simd_shuffle_down(lo[ii][1], 1); lo[ii][2] += simd_shuffle_down(lo[ii][2], 1); lo[ii][3] += simd_shuffle_down(lo[ii][3], 1); } } if ((DV4/NL % NW == 0) || ty == 0) { FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { so4[ii*NL] += lo[ii]; } } } } if (FC_flash_attn_ext_vec_has_sinks && sgitg == 0 && iwg == 0) { const float m = M; const float s = tiisg == 0 ? ((device const float *) sinks)[iq2] : -FLT_MAX/2; M = simd_max(max(M, s)); const float ms = exp(m - M); const float vs = exp(s - M); S = S*ms + simd_sum(vs); if ((DV4/NL % NW == 0) || ty == 0) { FOR_UNROLL (short ii = 0; ii < DV4/NL; ++ii) { so4[ii*NL] *= ms; } } } // these are needed for reducing the results from the simdgroups (reuse the ss buffer) if (tiisg == 0) { ss[0] = (s_t) S; ss[1] = (s_t) M; } } so4 -= tiisg; threadgroup_barrier(mem_flags::mem_threadgroup); // parallel reduce for (short r = NSG/2; r > 0; r >>= 1) { if (sgitg < r) { const float S0 = ss[ 0]; const float S1 = ss[r*(SH/2) + 0]; const float M0 = ss[ 1]; const float M1 = ss[r*(SH/2) + 1]; const float M = max(M0, M1); const float ms0 = exp(M0 - M); const float ms1 = exp(M1 - M); const float S = S0*ms0 + S1*ms1; if (tiisg == 0) { ss[0] = S; ss[1] = M; } // O_0 = diag(ms0)*O_0 + diag(ms1)*O_1 for (short i = tiisg; i < DV4; i += NW) { so4[i] = so4[i]*ms0 + so4[i + r*PV4]*ms1; } } threadgroup_barrier(mem_flags::mem_threadgroup); } // final rescale with 1/S and store to global memory if (sgitg == 0) { const int64_t nrows = args.ne3*args.ne2*args.ne1; const int64_t rid = iq3*args.ne2*args.ne1 + iq2 + iq1*args.ne1; device float4 * dst4 = (device float4 *) dst; device float * dst1 = (device float *) dst + nrows*DV*NWG; // the S and M are stored after the results const float S = NWG == 1 ? (ss[0] == 0.0f ? 0.0f : 1.0f/ss[0]) : 1.0f; // interleave the workgroup data for (short i = tiisg; i < DV4; i += NW) { dst4[rid*DV4*NWG + NWG*i + iwg] = (float4) so4[i]*S; } // store S and M if (NWG > 1) { if (tiisg == 0) { dst1[rid*(2*NWG) + 2*iwg + 0] = ss[0]; dst1[rid*(2*NWG) + 2*iwg + 1] = ss[1]; } } } #undef NWG #undef NSG #undef NS10 #undef NS20 } // note: I think the s_t can be half instead of float, because the Q*K scaling is done before storing to shared mem // in the other (non-vec) kernel, we need s_t to also be float because we scale during the soft_max // #define FA_TYPES \ half4, \ half4, \ half4, \ float, \ float, float4, \ float4 #define FA_TYPES_F32 \ half4, \ float4, \ float4, \ float, \ float, float4, \ float4 typedef decltype(kernel_flash_attn_ext_vec) flash_attn_ext_vec_t; template [[host_name("kernel_flash_attn_ext_vec_f32_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk32_dv32")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk64_dv64")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk96_dv96")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk128_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk192_dv192")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk192_dv128")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk256_dv256")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f32_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_f16_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_flash_attn_ext_vec_bf16_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #endif template [[host_name("kernel_flash_attn_ext_vec_q4_0_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q4_1_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_0_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q5_1_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; template [[host_name("kernel_flash_attn_ext_vec_q8_0_dk576_dv512")]] kernel flash_attn_ext_vec_t kernel_flash_attn_ext_vec; #undef FA_TYPES #undef FA_TYPES_F32 constant int32_t FC_flash_attn_ext_vec_reduce_DV [[function_constant(FC_FLASH_ATTN_EXT_VEC_REDUCE + 0)]]; constant int32_t FC_flash_attn_ext_vec_reduce_NWG [[function_constant(FC_FLASH_ATTN_EXT_VEC_REDUCE + 1)]]; kernel void kernel_flash_attn_ext_vec_reduce( constant ggml_metal_kargs_flash_attn_ext_vec_reduce & args, device const char * htmp, device char * dst, uint tgpig[[threadgroup_position_in_grid]], ushort tiisg[[thread_index_in_simdgroup]], ushort sgitg[[simdgroup_index_in_threadgroup]]) { #define NWG (FC_flash_attn_ext_vec_reduce_NWG) #define DV (FC_flash_attn_ext_vec_reduce_DV) const uint64_t rid = tgpig; const short iwg = tiisg; device const float * ss = (device const float *) htmp + (uint64_t)args.nrows*DV*NWG; float S = ss[rid*(2*NWG) + 2*iwg + 0]; float M = ss[rid*(2*NWG) + 2*iwg + 1]; const float m = simd_max(M); const float ms = exp(M - m); S = simd_sum(S*ms); S = S == 0.0f ? 0.0f : 1.0f/S; const short DV4 = DV/4; device const float4 * htmp4 = (device const float4 *) htmp + rid*DV4*NWG; device float4 * dst4 = (device float4 *) dst + rid*DV4; for (short i = sgitg; i < DV4; i += NWG) { const float4 v = simd_sum(htmp4[i*NWG + iwg]*ms); if (iwg == 0) { dst4[i] = v*S; } } #undef NWG #undef DV } template kernel void kernel_cpy_t_t( constant ggml_metal_kargs_cpy & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiitg[[thread_index_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int i03 = tgpig[2]; const int i02 = tgpig[1]; const int i01 = ntg[1] == 1 ? tgpig[0]%args.ne01 : tgpig[0]*ntg[1] + tiitg/ntg[0]; const int iw0 = ntg[1] == 1 ? tgpig[0]/args.ne01 : 0; const int64_t n = i03*args.ne02*args.ne01*args.ne00 + i02*args.ne01*args.ne00 + i01*args.ne00; const int64_t i3 = n/(args.ne2*args.ne1*args.ne0); const int64_t i2 = (n - i3*args.ne2*args.ne1*args.ne0)/(args.ne1*args.ne0); const int64_t i1 = (n - i3*args.ne2*args.ne1*args.ne0 - i2*args.ne1*args.ne0)/args.ne0; const int64_t i0 = (n - i3*args.ne2*args.ne1*args.ne0 - i2*args.ne1*args.ne0 - i1*args.ne0); device T1 * dst_data = (device T1 *) (dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); for (int64_t i00 = iw0*ntg[0] + tiitg%ntg[0]; i00 < args.ne00; ) { device const T0 * src = (device T0 *)(src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01 + i00*args.nb00); dst_data[i00] = (T1) src[0]; break; } } typedef decltype(kernel_cpy_t_t) kernel_cpy_t; template [[host_name("kernel_cpy_f32_f32")]] kernel kernel_cpy_t kernel_cpy_t_t; template [[host_name("kernel_cpy_f32_f16")]] kernel kernel_cpy_t kernel_cpy_t_t; template [[host_name("kernel_cpy_f32_i32")]] kernel kernel_cpy_t kernel_cpy_t_t; template [[host_name("kernel_cpy_i32_f32")]] kernel kernel_cpy_t kernel_cpy_t_t; template [[host_name("kernel_cpy_i32_i32")]] kernel kernel_cpy_t kernel_cpy_t_t; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_cpy_f32_bf16")]] kernel kernel_cpy_t kernel_cpy_t_t; #endif template [[host_name("kernel_cpy_f16_f32")]] kernel kernel_cpy_t kernel_cpy_t_t; template [[host_name("kernel_cpy_f16_f16")]] kernel kernel_cpy_t kernel_cpy_t_t; #if defined(GGML_METAL_HAS_BF16) template [[host_name("kernel_cpy_bf16_f32")]] kernel kernel_cpy_t kernel_cpy_t_t; template [[host_name("kernel_cpy_bf16_bf16")]] kernel kernel_cpy_t kernel_cpy_t_t; #endif template kernel void kernel_cpy_f32_q( constant ggml_metal_kargs_cpy & args, device const char * src0, device char * dst, uint3 tgpig[[threadgroup_position_in_grid]], ushort tiitg[[thread_index_in_threadgroup]], ushort3 ntg[[threads_per_threadgroup]]) { const int i03 = tgpig[2]; const int i02 = tgpig[1]; const int i01 = ntg[1] == 1 ? tgpig[0]%args.ne01 : tgpig[0]*ntg[1] + tiitg/ntg[0]; const int iw0 = ntg[1] == 1 ? tgpig[0]/args.ne01 : 0; const int64_t n = i03*args.ne02*args.ne01*args.ne00 + i02*args.ne01*args.ne00 + i01*args.ne00; const int64_t i3 = n / (args.ne2*args.ne1*args.ne0); const int64_t i2 = (n - i3*args.ne2*args.ne1*args.ne0) / (args.ne1*args.ne0); const int64_t i1 = (n - i3*args.ne2*args.ne1*args.ne0 - i2*args.ne1*args.ne0) / args.ne0; const int64_t i0 = (n - i3*args.ne2*args.ne1*args.ne0 - i2*args.ne1*args.ne0 - i1*args.ne0)/QK; device block_q * dst_data = (device block_q *)(dst + i3*args.nb3 + i2*args.nb2 + i1*args.nb1 + i0*args.nb0); for (int64_t i00 = iw0*ntg[0] + tiitg%ntg[0]; i00 < args.nk0; ) { device const float * src = (device const float *)(src0 + i03*args.nb03 + i02*args.nb02 + i01*args.nb01 + (i00*QK)*args.nb00); quantize_func(src, dst_data[i00]); break; } } typedef decltype(kernel_cpy_f32_q