diff options
Diffstat (limited to 'llama.cpp/ggml/src/ggml-vulkan/vulkan-shaders/mul_mat_vecq_funcs.glsl')
| -rw-r--r-- | llama.cpp/ggml/src/ggml-vulkan/vulkan-shaders/mul_mat_vecq_funcs.glsl | 494 |
1 files changed, 494 insertions, 0 deletions
diff --git a/llama.cpp/ggml/src/ggml-vulkan/vulkan-shaders/mul_mat_vecq_funcs.glsl b/llama.cpp/ggml/src/ggml-vulkan/vulkan-shaders/mul_mat_vecq_funcs.glsl new file mode 100644 index 0000000..6ddbed3 --- /dev/null +++ b/llama.cpp/ggml/src/ggml-vulkan/vulkan-shaders/mul_mat_vecq_funcs.glsl @@ -0,0 +1,494 @@ +#extension GL_EXT_shader_explicit_arithmetic_types_int32 : require +#extension GL_EXT_shader_explicit_arithmetic_types_int16 : require +#extension GL_EXT_shader_explicit_arithmetic_types_int8 : require + +#include "types.glsl" + +#if defined(DATA_A_Q4_0) || defined(DATA_A_Q5_0) || defined(DATA_A_Q8_0) || defined(DATA_A_IQ1_S) || defined(DATA_A_IQ2_XXS) || defined(DATA_A_IQ2_XS) || defined(DATA_A_IQ2_S) || defined(DATA_A_IQ3_XXS) || defined(DATA_A_IQ3_S) || defined(DATA_A_IQ4_XS) || defined(DATA_A_IQ4_NL) +FLOAT_TYPE get_dm(uint ib) { + return FLOAT_TYPE(data_a[ib].d); +} +#endif + +#if defined(DATA_A_Q4_1) || defined(DATA_A_Q5_1) +FLOAT_TYPE_VEC2 get_dm(uint ib) { + return FLOAT_TYPE_VEC2(data_a_packed32[ib].dm); +} +#endif + +#if defined(DATA_A_MXFP4) +FLOAT_TYPE get_dm(uint ib) { + return FLOAT_TYPE(e8m0_to_fp32(data_a[ib].e)); +} +#endif + +#if defined(DATA_A_Q2_K) +FLOAT_TYPE_VEC2 get_dm(uint ib) { + const uint ib_k = ib / 8; + return FLOAT_TYPE_VEC2(data_a_packed32[ib_k].dm); +} +#endif + +// Each iqs value maps to a 32-bit integer +#if defined(DATA_A_Q4_0) +// 2-byte loads for Q4_0 blocks (18 bytes) +i32vec2 repack(uint ib, uint iqs) { + const u16vec2 quants = u16vec2(data_a_packed16[ib].qs[iqs * 2 ], + data_a_packed16[ib].qs[iqs * 2 + 1]); + const uint32_t vui = pack32(quants); + return i32vec2( vui & 0x0F0F0F0F, + (vui >> 4) & 0x0F0F0F0F); +} + +FLOAT_TYPE mul_q8_1(const int32_t q_sum, const float da, const vec2 dsb, const int32_t sum_divisor) { + return FLOAT_TYPE(da * (float(q_sum) * dsb.x - (8 / sum_divisor) * dsb.y)); +} +#endif + +#if defined(DATA_A_Q4_1) +// 4-byte loads for Q4_1 blocks (20 bytes) +i32vec2 repack(uint ib, uint iqs) { + const uint32_t vui = data_a_packed32[ib].qs[iqs]; + return i32vec2( vui & 0x0F0F0F0F, + (vui >> 4) & 0x0F0F0F0F); +} + +FLOAT_TYPE mul_q8_1(const int32_t q_sum, const vec2 dma, const vec2 dsb, const int32_t sum_divisor) { + return FLOAT_TYPE(float(q_sum) * dma.x * dsb.x + dma.y * dsb.y / sum_divisor); +} +#endif + +#if defined(DATA_A_Q5_0) +// 2-byte loads for Q5_0 blocks (22 bytes) +i32vec2 repack(uint ib, uint iqs) { + const u16vec2 quants = u16vec2(data_a_packed16[ib].qs[iqs * 2 ], + data_a_packed16[ib].qs[iqs * 2 + 1]); + const uint32_t vui = pack32(quants); + const int32_t qh = int32_t((uint32_t(data_a_packed16[ib].qh[1]) << 16 | data_a_packed16[ib].qh[0]) >> (4 * iqs)); + const int32_t v0 = int32_t(vui & 0x0F0F0F0F) + | ((qh & 0xF) * 0x02040810) & 0x10101010; // (0,1,2,3) -> (4,12,20,28) + + const int32_t v1 = int32_t((vui >> 4) & 0x0F0F0F0F) + | (((qh >> 16) & 0xF) * 0x02040810) & 0x10101010; // (16,17,18,19) -> (4,12,20,28) + + return i32vec2(v0, v1); +} + +FLOAT_TYPE mul_q8_1(const int32_t q_sum, const float da, const vec2 dsb, const int32_t sum_divisor) { + return FLOAT_TYPE(da * (float(q_sum) * dsb.x - (16 / sum_divisor) * dsb.y)); +} +#endif + +#if defined(DATA_A_Q5_1) +// 4-byte loads for Q5_1 blocks (24 bytes) +i32vec2 repack(uint ib, uint iqs) { + const u16vec2 quants = u16vec2(data_a_packed16[ib].qs[iqs * 2 ], + data_a_packed16[ib].qs[iqs * 2 + 1]); + const uint32_t vui = pack32(quants); + const int32_t qh = int32_t(data_a_packed32[ib].qh >> (4 * iqs)); + const int32_t v0 = int32_t(vui & 0x0F0F0F0F) + | ((qh & 0xF) * 0x02040810) & 0x10101010; // (0,1,2,3) -> (4,12,20,28) + + const int32_t v1 = int32_t((vui >> 4) & 0x0F0F0F0F) + | (((qh >> 16) & 0xF) * 0x02040810) & 0x10101010; // (16,17,18,19) -> (4,12,20,28) + + return i32vec2(v0, v1); +} + +FLOAT_TYPE mul_q8_1(const int32_t q_sum, const vec2 dma, const vec2 dsb, const int32_t sum_divisor) { + return FLOAT_TYPE(float(q_sum) * dma.x * dsb.x + dma.y * dsb.y / sum_divisor); +} +#endif + +#if defined(DATA_A_Q8_0) +// 2-byte loads for Q8_0 blocks (34 bytes) +int32_t repack(uint ib, uint iqs) { + return pack32(i16vec2(data_a_packed16[ib].qs[iqs * 2 ], + data_a_packed16[ib].qs[iqs * 2 + 1])); +} + +FLOAT_TYPE mul_q8_1(const int32_t q_sum, const float da, const vec2 dsb, const int32_t sum_divisor) { + return FLOAT_TYPE(float(q_sum) * da * dsb.x); +} +#endif + +#if defined(DATA_A_MXFP4) +// 1-byte loads for mxfp4 blocks (17 bytes) +i32vec2 repack(uint ib, uint iqs) { + const uint32_t qs = pack32(u8vec4(data_a[ib].qs[iqs * 4 ], + data_a[ib].qs[iqs * 4 + 1], + data_a[ib].qs[iqs * 4 + 2], + data_a[ib].qs[iqs * 4 + 3])); + + const u8vec4 i_a0 = unpack8( qs & 0x0F0F0F0F); + const u8vec4 i_a1 = unpack8((qs >> 4) & 0x0F0F0F0F); + + return i32vec2(pack32(i8vec4(kvalues_mxfp4[i_a0.x], kvalues_mxfp4[i_a0.y], kvalues_mxfp4[i_a0.z], kvalues_mxfp4[i_a0.w])), + pack32(i8vec4(kvalues_mxfp4[i_a1.x], kvalues_mxfp4[i_a1.y], kvalues_mxfp4[i_a1.z], kvalues_mxfp4[i_a1.w]))); +} + +FLOAT_TYPE mul_q8_1(const int32_t q_sum, const float da, const vec2 dsb, const int32_t sum_divisor) { + return FLOAT_TYPE(da * dsb.x * float(q_sum) * 0.5); +} +#endif + +#if defined(DATA_A_QUANT_LEGACY) || defined(DATA_A_MXFP4) +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + int32_t q_sum = 0; +#if QUANT_R == 2 + const i32vec2 data_a_qs = repack(ib_a, iqs); + q_sum += dotPacked4x8EXT(data_a_qs.x, + cache_b_qs[0]); + q_sum += dotPacked4x8EXT(data_a_qs.y, + cache_b_qs[1]); +#else + int32_t data_a_qs = repack(ib_a, iqs * 2); + q_sum += dotPacked4x8EXT(data_a_qs, + cache_b_qs[0]); + data_a_qs = repack(ib_a, iqs * 2 + 1); + q_sum += dotPacked4x8EXT(data_a_qs, + cache_b_qs[1]); +#endif + + // 2 quants per call => divide sums by 8/2 = 4 + return mul_q8_1(q_sum, get_dm(ib_a), cache_b_ds, 4); +} +#endif + +#if defined(DATA_A_Q2_K) +// 4-byte loads for Q2_K blocks (84 bytes) +i32vec4 repack4(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + + const uint qs_idx = (iqs_k / 32) * 8 + (iqs_k % 8); + const uint qs_shift = ((iqs_k % 32) / 8) * 2; + + return i32vec4((data_a_packed32[ib_k].qs[qs_idx ] >> qs_shift) & 0x03030303, + (data_a_packed32[ib_k].qs[qs_idx + 1] >> qs_shift) & 0x03030303, + (data_a_packed32[ib_k].qs[qs_idx + 2] >> qs_shift) & 0x03030303, + (data_a_packed32[ib_k].qs[qs_idx + 3] >> qs_shift) & 0x03030303); +} + +uint8_t get_scale(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + + return data_a[ib_k].scales[iqs_k / 4]; +} + +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + int32_t sum_d = 0; + int32_t sum_m = 0; + + const i32vec4 qs_a = repack4(ib_a, iqs * 4); + const uint8_t scale = get_scale(ib_a, iqs * 4); + const vec2 dm = vec2(get_dm(ib_a)); + const int32_t scale_m = int32_t(scale >> 4) * 0x01010101; // Duplicate 8-bit value across 32-bits. + + sum_d += dotPacked4x8EXT(qs_a.x, cache_b_qs[0]) * (scale & 0xF); + sum_m += dotPacked4x8EXT(scale_m, cache_b_qs[0]); + + sum_d += dotPacked4x8EXT(qs_a.y, cache_b_qs[1]) * (scale & 0xF); + sum_m += dotPacked4x8EXT(scale_m, cache_b_qs[1]); + + sum_d += dotPacked4x8EXT(qs_a.z, cache_b_qs[2]) * (scale & 0xF); + sum_m += dotPacked4x8EXT(scale_m, cache_b_qs[2]); + + sum_d += dotPacked4x8EXT(qs_a.w, cache_b_qs[3]) * (scale & 0xF); + sum_m += dotPacked4x8EXT(scale_m, cache_b_qs[3]); + + return FLOAT_TYPE(float(cache_b_ds.x) * (float(dm.x) * float(sum_d) - float(dm.y) * float(sum_m))); +} +#endif + +#if defined(DATA_A_Q3_K) +// 2-byte loads for Q3_K blocks (110 bytes) +i32vec4 repack4(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + + const uint qs_idx = (iqs_k / 32) * 8 + (iqs_k % 8); + const uint qs_shift = ((iqs_k % 32) / 8) * 2; + const uint hm_shift = iqs_k / 8; + + // bitwise OR to add 4 if hmask is set, subtract later + const i8vec2 vals00 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 ] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 ] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals01 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 1] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 1] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals10 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 2] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 2] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals11 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 3] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 3] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals20 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 4] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 4] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals21 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 5] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 5] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals30 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 6] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 6] >> hm_shift) & uint16_t(0x0101)) << 2)); + const i8vec2 vals31 = unpack8(int16_t((data_a_packed16[ib_k].qs[qs_idx * 2 + 7] >> qs_shift) & uint16_t(0x0303))) | + unpack8(int16_t(((data_a_packed16[ib_k].hmask[iqs * 2 + 7] >> hm_shift) & uint16_t(0x0101)) << 2)); + + return i32vec4(pack32(i8vec4(vals00.x, vals00.y, vals01.x, vals01.y) - int8_t(4)), + pack32(i8vec4(vals10.x, vals10.y, vals11.x, vals11.y) - int8_t(4)), + pack32(i8vec4(vals20.x, vals20.y, vals21.x, vals21.y) - int8_t(4)), + pack32(i8vec4(vals30.x, vals30.y, vals31.x, vals31.y) - int8_t(4))); +} + +float get_d_scale(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + const uint is = iqs_k / 4; + + const int8_t scale = int8_t(((data_a[ib_k].scales[is % 8 ] >> (4 * (is / 8))) & 0x0F0F) | + (((data_a[ib_k].scales[8 + (is % 4)] >> (2 * (is / 4))) & 0x0303) << 4)); + return float(data_a[ib_k].d) * float(scale - 32); +} + +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + int32_t q_sum = 0; + + const i32vec4 qs_a = repack4(ib_a, iqs * 4); + const float d_scale = get_d_scale(ib_a, iqs * 4); + + q_sum += dotPacked4x8EXT(qs_a.x, cache_b_qs[0]); + q_sum += dotPacked4x8EXT(qs_a.y, cache_b_qs[1]); + q_sum += dotPacked4x8EXT(qs_a.z, cache_b_qs[2]); + q_sum += dotPacked4x8EXT(qs_a.w, cache_b_qs[3]); + + return FLOAT_TYPE(float(cache_b_ds.x) * d_scale * float(q_sum)); +} +#endif + +#if defined(DATA_A_Q4_K) || defined(DATA_A_Q5_K) +// 4-byte loads for Q4_K blocks (144 bytes) and Q5_K blocks (176 bytes) +i32vec4 repack4(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + + const uint qs_idx = (iqs_k / 16) * 8 + (iqs_k % 8); + const uint qs_shift = ((iqs_k % 16) / 8) * 4; + +#if defined(DATA_A_Q4_K) + const uint32_t vals0 = (data_a_packed32[ib_k].qs[qs_idx ] >> qs_shift) & 0x0F0F0F0F; + const uint32_t vals1 = (data_a_packed32[ib_k].qs[qs_idx + 1] >> qs_shift) & 0x0F0F0F0F; + const uint32_t vals2 = (data_a_packed32[ib_k].qs[qs_idx + 2] >> qs_shift) & 0x0F0F0F0F; + const uint32_t vals3 = (data_a_packed32[ib_k].qs[qs_idx + 3] >> qs_shift) & 0x0F0F0F0F; + + return i32vec4(vals0, vals1, vals2, vals3); +#else // defined(DATA_A_Q5_K) + const uint qh_idx = iqs; + const uint qh_shift = iqs_k / 8; + + return i32vec4(((data_a_packed32[ib_k].qs[qs_idx ] >> qs_shift) & 0x0F0F0F0F) | + (((data_a_packed32[ib_k].qh[qh_idx ] >> qh_shift) & 0x01010101) << 4), + ((data_a_packed32[ib_k].qs[qs_idx + 1] >> qs_shift) & 0x0F0F0F0F) | + (((data_a_packed32[ib_k].qh[qh_idx + 1] >> qh_shift) & 0x01010101) << 4), + ((data_a_packed32[ib_k].qs[qs_idx + 2] >> qs_shift) & 0x0F0F0F0F) | + (((data_a_packed32[ib_k].qh[qh_idx + 2] >> qh_shift) & 0x01010101) << 4), + ((data_a_packed32[ib_k].qs[qs_idx + 3] >> qs_shift) & 0x0F0F0F0F) | + (((data_a_packed32[ib_k].qh[qh_idx + 3] >> qh_shift) & 0x01010101) << 4)); +#endif +} + +vec2 get_dm_scale(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + const uint is = iqs_k / 8; + u8vec2 scale_dm; + if (is < 4) { + scale_dm = u8vec2(data_a[ib_k].scales[is] & 0x3F, data_a[ib_k].scales[is + 4] & 0x3F); + } else { + scale_dm = u8vec2((data_a[ib_k].scales[is+4] & 0xF) | ((data_a[ib_k].scales[is-4] & 0xC0) >> 2), + (data_a[ib_k].scales[is+4] >> 4) | ((data_a[ib_k].scales[is ] & 0xC0) >> 2)); + } + + return FLOAT_TYPE_VEC2(data_a_packed32[ib_k].dm) * FLOAT_TYPE_VEC2(scale_dm); +} + +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + int32_t q_sum = 0; + + const i32vec4 qs_a = repack4(ib_a, iqs * 4); + const vec2 dm_scale = get_dm_scale(ib_a, iqs * 4); + + q_sum += dotPacked4x8EXT(qs_a.x, cache_b_qs[0]); + q_sum += dotPacked4x8EXT(qs_a.y, cache_b_qs[1]); + q_sum += dotPacked4x8EXT(qs_a.z, cache_b_qs[2]); + q_sum += dotPacked4x8EXT(qs_a.w, cache_b_qs[3]); + + return FLOAT_TYPE(float(cache_b_ds.x) * float(dm_scale.x) * float(q_sum) - float(dm_scale.y) * float(cache_b_ds.y / 2)); +} +#endif + +#if defined(DATA_A_Q6_K) +// 2-byte loads for Q6_K blocks (210 bytes) +i32vec4 repack4(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + + const uint ql_idx = (iqs_k / 32) * 16 + iqs_k % 16; + const uint ql_shift = ((iqs_k % 32) / 16) * 4; + + const uint qh_idx = (iqs_k / 32) * 8 + iqs; + const uint qh_shift = ((iqs_k % 32) / 8) * 2; + + const i8vec2 vals00 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 ] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 ] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals01 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 1] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 1] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals10 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 2] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 2] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals11 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 3] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 3] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals20 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 4] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 4] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals21 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 5] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 5] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals30 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 6] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 6] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + const i8vec2 vals31 = (unpack8(int16_t((data_a_packed16[ib_k].ql[ql_idx * 2 + 7] >> ql_shift) & uint16_t(0x0F0F))) | + unpack8(int16_t(((data_a_packed16[ib_k].qh[qh_idx * 2 + 7] >> qh_shift) & uint16_t(0x0303)) << 4))) - int8_t(32); + + return i32vec4(pack32(i8vec4(vals00.x, vals00.y, vals01.x, vals01.y)), + pack32(i8vec4(vals10.x, vals10.y, vals11.x, vals11.y)), + pack32(i8vec4(vals20.x, vals20.y, vals21.x, vals21.y)), + pack32(i8vec4(vals30.x, vals30.y, vals31.x, vals31.y))); +} + +float get_d_scale(uint ib, uint iqs) { + const uint ib_k = ib / 8; + const uint iqs_k = (ib % 8) * 8 + iqs; + return float(data_a[ib_k].d) * float(data_a[ib_k].scales[iqs_k / 4]); +} + +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + int32_t q_sum = 0; + + const i32vec4 qs_a = repack4(ib_a, iqs * 4); + const float d_scale = get_d_scale(ib_a, iqs * 4); + + q_sum += dotPacked4x8EXT(qs_a.x, cache_b_qs[0]); + q_sum += dotPacked4x8EXT(qs_a.y, cache_b_qs[1]); + q_sum += dotPacked4x8EXT(qs_a.z, cache_b_qs[2]); + q_sum += dotPacked4x8EXT(qs_a.w, cache_b_qs[3]); + + return FLOAT_TYPE(float(cache_b_ds.x) * float(d_scale) * float(q_sum)); +} +#endif + +#if defined(DATA_A_IQ1_S) +void repack8(uint ib, uint iqs, out i32vec4 out0, out i32vec4 out1) { + const uint ib32 = iqs / 32; + + const uint qh = data_a[ib].qh[ib32]; + + const uint qs16_0 = data_a_packed16[ib].qs[(4 * ib32 + 0) / 2]; + const uint qs16_1 = data_a_packed16[ib].qs[(4 * ib32 + 2) / 2]; + + const uint qs0 = qs16_0 & 0xFF; + const uint qs1 = qs16_0 >> 8; + const uint qs2 = qs16_1 & 0xFF; + const uint qs3 = qs16_1 >> 8; + + const uint hi0 = bitfieldExtract(qh, 3 * int(0), 3); + const uint hi1 = bitfieldExtract(qh, 3 * int(1), 3); + const uint hi2 = bitfieldExtract(qh, 3 * int(2), 3); + const uint hi3 = bitfieldExtract(qh, 3 * int(3), 3); + + const int32_t grid0 = int32_t(iq1s_grid_gpu[qs0 | (hi0 << 8)]); + const int32_t grid1 = int32_t(iq1s_grid_gpu[qs1 | (hi1 << 8)]); + const int32_t grid2 = int32_t(iq1s_grid_gpu[qs2 | (hi2 << 8)]); + const int32_t grid3 = int32_t(iq1s_grid_gpu[qs3 | (hi3 << 8)]); + + out0 = i32vec4((grid0 >> 0) & 0x0F0F0F0F, + (grid0 >> 4) & 0x0F0F0F0F, + (grid1 >> 0) & 0x0F0F0F0F, + (grid1 >> 4) & 0x0F0F0F0F); + out1 = i32vec4((grid2 >> 0) & 0x0F0F0F0F, + (grid2 >> 4) & 0x0F0F0F0F, + (grid3 >> 0) & 0x0F0F0F0F, + (grid3 >> 4) & 0x0F0F0F0F); +} + +vec2 get_dm(uint ib, uint iqs) { + const uint ib32 = iqs / 32; + + const uint qh = data_a[ib].qh[ib32]; + const float delta = ((qh & 0x8000) != 0) ? -IQ1S_DELTA : IQ1S_DELTA; + + const float d = float(data_a[ib].d); + const float dl = d * float(2 * bitfieldExtract(qh, 12, 3) + 1); + + // the -1 cancels out the bias in iq1s_grid_gpu + return FLOAT_TYPE_VEC2(dl, dl * (delta - 1)); +} + +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + int32_t q_sum = 0; + + const uint ib_k = ib_a / 8; + const uint iqs_k = (ib_a % 8) * 32 + iqs * 32; + + i32vec4 qs_a0; + i32vec4 qs_a1; + repack8(ib_k, iqs_k, qs_a0, qs_a1); + + const vec2 dm = get_dm(ib_k, iqs_k); + + q_sum += dotPacked4x8EXT(qs_a0.x, cache_b_qs[0]); + q_sum += dotPacked4x8EXT(qs_a0.y, cache_b_qs[1]); + q_sum += dotPacked4x8EXT(qs_a0.z, cache_b_qs[2]); + q_sum += dotPacked4x8EXT(qs_a0.w, cache_b_qs[3]); + q_sum += dotPacked4x8EXT(qs_a1.x, cache_b_qs[4]); + q_sum += dotPacked4x8EXT(qs_a1.y, cache_b_qs[5]); + q_sum += dotPacked4x8EXT(qs_a1.z, cache_b_qs[6]); + q_sum += dotPacked4x8EXT(qs_a1.w, cache_b_qs[7]); + + return FLOAT_TYPE(float(cache_b_ds.x) * float(dm.x) * float(q_sum) + float(dm.y) * float(cache_b_ds.y)); +} +#endif + +#if defined(DATA_A_IQ1_M) +FLOAT_TYPE mmvq_dot_product(const uint ib_a, const uint iqs) { + const uint ib_k = ib_a / 8; + const uint iqs_k = (ib_a % 8) * 32 + iqs * 32; + + const uint ib32 = iqs_k / 32; + const uint ib64 = ib32 / 2; + + const uint16_t[4] scales = data_a[ib_k].scales; + const u16vec4 s = u16vec4(scales[0], scales[1], scales[2], scales[3]) >> 12; + const float d = float(unpackHalf2x16(s.x | (s.y << 4) | (s.z << 8) | (s.w << 12)).x); + + const uint qs32 = data_a_packed32[ib_k].qs[ib32]; + const uint qh16 = data_a_packed16[ib_k].qh[ib32]; + + float sum = 0; + const uint sc = data_a[ib_k].scales[ib64]; + [[unroll]] for (int l = 0; l < 4; ++l) { + const uint ib16 = 2 * ib32 + l / 2; + const float dl = d * (2 * bitfieldExtract(sc, 3 * int(ib16 & 3), 3) + 1); + const uint qh = qh16 >> (4 * l); + const uint qs = (qs32 >> (8 * l)) & 0xFF; + const float delta = ((qh & 8) != 0) ? -IQ1M_DELTA : IQ1M_DELTA; + + const int32_t grid = int32_t(iq1s_grid_gpu[qs | ((qh & 7) << 8)]); + + int32_t q_sum = 0; + q_sum += dotPacked4x8EXT((grid >> 0) & 0x0F0F0F0F, cache_b_qs[2 * l + 0]); + q_sum += dotPacked4x8EXT((grid >> 4) & 0x0F0F0F0F, cache_b_qs[2 * l + 1]); + + int32_t y_sum = 0; + y_sum += dotPacked4x8EXT(int(0x01010101), cache_b_qs[2 * l + 0]); + y_sum += dotPacked4x8EXT(int(0x01010101), cache_b_qs[2 * l + 1]); + + // the -1 cancels out the bias in iq1s_grid_gpu + sum += dl * (q_sum + y_sum * (delta - 1)); + } + sum *= float(cache_b_ds.x); + + return sum; +} +#endif |