llama.cpp/ggml/src/ggml-vulkan/vulkan-shaders/mul_mat_vec_iq3_s.comp

#version 450
#extension GL_EXT_shader_explicit_arithmetic_types_int32 : require

#include "mul_mat_vec_base.comp"

layout(local_size_x_id = 0, local_size_y = 1, local_size_z = 1) in;

FLOAT_TYPE temp[NUM_COLS][NUM_ROWS];

void calc_superblock(const uint a_offset, const uint b_offset, const uint ib32, const uint i, const uint num_blocks_per_row, const uint first_row, const uint num_rows) {
    const uint y_idx = i * QUANT_K + 32 * ib32;

    uint ibi = a_offset / QUANT_K + first_row * num_blocks_per_row + i;
    [[unroll]] for (uint n = 0; n < num_rows; ++n) {
        const float d = float(data_a[ibi].d);
        const uint scale = (data_a[ibi].scales[ib32/2] >> (4 * (ib32 & 1))) & 0xF;
        const float dscale = d * (1 + 2 * scale);
        const uint qh = data_a[ibi].qh[ib32];
        FLOAT_TYPE sum[NUM_COLS];
        [[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {
            sum[j] = 0.0;
        }
        [[unroll]] for (uint l = 0; l < 4; ++l) {
            const u8vec2 qs = unpack8(data_a_packed16[ibi].qs[4 * ib32 + l]);
            const uint sign = data_a[ibi].signs[4 * ib32 + l];
            const vec4 grid0 = vec4(unpack8(iq3s_grid[qs.x | ((qh << (8 - 2*l)) & 0x100)]));
            const vec4 grid1 = vec4(unpack8(iq3s_grid[qs.y | ((qh << (7 - 2*l)) & 0x100)]));

            [[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {
                const vec4 b0 = vec4(data_b_v4[(j*p.batch_stride_b + b_offset + y_idx) / 4 + 2*l + 0]);
                const vec4 b4 = vec4(data_b_v4[(j*p.batch_stride_b + b_offset + y_idx) / 4 + 2*l + 1]);

                sum[j] =
                      fma(FLOAT_TYPE(b0.x), FLOAT_TYPE((sign &   1) != 0 ? -grid0.x : grid0.x),
                      fma(FLOAT_TYPE(b0.y), FLOAT_TYPE((sign &   2) != 0 ? -grid0.y : grid0.y),
                      fma(FLOAT_TYPE(b0.z), FLOAT_TYPE((sign &   4) != 0 ? -grid0.z : grid0.z),
                      fma(FLOAT_TYPE(b0.w), FLOAT_TYPE((sign &   8) != 0 ? -grid0.w : grid0.w),
                      fma(FLOAT_TYPE(b4.x), FLOAT_TYPE((sign &  16) != 0 ? -grid1.x : grid1.x),
                      fma(FLOAT_TYPE(b4.y), FLOAT_TYPE((sign &  32) != 0 ? -grid1.y : grid1.y),
                      fma(FLOAT_TYPE(b4.z), FLOAT_TYPE((sign &  64) != 0 ? -grid1.z : grid1.z),
                      fma(FLOAT_TYPE(b4.w), FLOAT_TYPE((sign & 128) != 0 ? -grid1.w : grid1.w),
                      sum[j]))))))));
            }
        }
        [[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {
            temp[j][n] = fma(dscale, sum[j], temp[j][n]);
        }
        ibi += num_blocks_per_row;
    }
}

void compute_outputs(const uint32_t first_row, const uint32_t num_rows) {
    uint a_offset, b_offset, d_offset;
    get_offsets(a_offset, b_offset, d_offset);

    const uint num_blocks_per_row = p.ncols / QUANT_K;

    // 8 threads are used to process each block
    const uint blocks_per_wg = gl_WorkGroupSize.x/8;
    const uint tid = gl_LocalInvocationID.x;
    const uint itid = tid % 8;  // 0...7
    const uint ix = tid / 8;

    [[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {
        [[unroll]] for (uint i = 0; i < NUM_ROWS; ++i) {
            temp[j][i] = FLOAT_TYPE(0);
        }
    }

    [[unroll]] for (uint i = ix; i < num_blocks_per_row; i += blocks_per_wg)
        calc_superblock(a_offset, b_offset, itid, i, num_blocks_per_row, first_row, num_rows);

    reduce_result(temp, d_offset, first_row, num_rows, tid);
}

void main() {
    const uint first_row = NUM_ROWS * (gl_WorkGroupID.x + gl_NumWorkGroups.x * gl_WorkGroupID.z);

    init_iq_shmem(gl_WorkGroupSize);

    // do NUM_ROWS at a time, unless there aren't enough remaining rows
    if (first_row + NUM_ROWS <= p.stride_d) {
        compute_outputs(first_row, NUM_ROWS);
    } else {
        if (first_row >= p.stride_d) {
            return;
        }
        compute_outputs(first_row, p.stride_d - first_row);
    }
}
vulkan: add specific MMV kernels for IQ2 and IQ3 quants + optimizations (#11595) * vulkan: implement specialized MMV kernels for IQ2 quantizations * vulkan: add MMV kernels for IQ3 quants * vulkan: Increase MMV batch size and unroll IQ LUT setup * vulkan: fix init_iq_shmem for WG sizes larger than tables * vulkan: common batch size for all I-quants 2025-02-28 09:42:52 +01:00			`#version 450`
			`#extension GL_EXT_shader_explicit_arithmetic_types_int32 : require`

			`#include "mul_mat_vec_base.comp"`

			`layout(local_size_x_id = 0, local_size_y = 1, local_size_z = 1) in;`

			`FLOAT_TYPE temp[NUM_COLS][NUM_ROWS];`

			`void calc_superblock(const uint a_offset, const uint b_offset, const uint ib32, const uint i, const uint num_blocks_per_row, const uint first_row, const uint num_rows) {`
			`const uint y_idx = i * QUANT_K + 32 * ib32;`

			`uint ibi = a_offset / QUANT_K + first_row * num_blocks_per_row + i;`
			`[[unroll]] for (uint n = 0; n < num_rows; ++n) {`
			`const float d = float(data_a[ibi].d);`
			`const uint scale = (data_a[ibi].scales[ib32/2] >> (4 * (ib32 & 1))) & 0xF;`
			`const float dscale = d * (1 + 2 * scale);`
			`const uint qh = data_a[ibi].qh[ib32];`
			`FLOAT_TYPE sum[NUM_COLS];`
			`[[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {`
			`sum[j] = 0.0;`
			`}`
			`[[unroll]] for (uint l = 0; l < 4; ++l) {`
			`const u8vec2 qs = unpack8(data_a_packed16[ibi].qs[4 * ib32 + l]);`
			`const uint sign = data_a[ibi].signs[4 * ib32 + l];`
			`const vec4 grid0 = vec4(unpack8(iq3s_grid[qs.x \| ((qh << (8 - 2*l)) & 0x100)]));`
			`const vec4 grid1 = vec4(unpack8(iq3s_grid[qs.y \| ((qh << (7 - 2*l)) & 0x100)]));`

			`[[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {`
			`const vec4 b0 = vec4(data_b_v4[(jp.batch_stride_b + b_offset + y_idx) / 4 + 2l + 0]);`
			`const vec4 b4 = vec4(data_b_v4[(jp.batch_stride_b + b_offset + y_idx) / 4 + 2l + 1]);`

			`sum[j] =`
			`fma(FLOAT_TYPE(b0.x), FLOAT_TYPE((sign & 1) != 0 ? -grid0.x : grid0.x),`
			`fma(FLOAT_TYPE(b0.y), FLOAT_TYPE((sign & 2) != 0 ? -grid0.y : grid0.y),`
			`fma(FLOAT_TYPE(b0.z), FLOAT_TYPE((sign & 4) != 0 ? -grid0.z : grid0.z),`
			`fma(FLOAT_TYPE(b0.w), FLOAT_TYPE((sign & 8) != 0 ? -grid0.w : grid0.w),`
			`fma(FLOAT_TYPE(b4.x), FLOAT_TYPE((sign & 16) != 0 ? -grid1.x : grid1.x),`
			`fma(FLOAT_TYPE(b4.y), FLOAT_TYPE((sign & 32) != 0 ? -grid1.y : grid1.y),`
			`fma(FLOAT_TYPE(b4.z), FLOAT_TYPE((sign & 64) != 0 ? -grid1.z : grid1.z),`
			`fma(FLOAT_TYPE(b4.w), FLOAT_TYPE((sign & 128) != 0 ? -grid1.w : grid1.w),`
			`sum[j]))))))));`
			`}`
			`}`
			`[[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {`
			`temp[j][n] = fma(dscale, sum[j], temp[j][n]);`
			`}`
			`ibi += num_blocks_per_row;`
			`}`
			`}`

			`void compute_outputs(const uint32_t first_row, const uint32_t num_rows) {`
			`uint a_offset, b_offset, d_offset;`
			`get_offsets(a_offset, b_offset, d_offset);`

			`const uint num_blocks_per_row = p.ncols / QUANT_K;`

			`// 8 threads are used to process each block`
			`const uint blocks_per_wg = gl_WorkGroupSize.x/8;`
			`const uint tid = gl_LocalInvocationID.x;`
			`const uint itid = tid % 8; // 0...7`
			`const uint ix = tid / 8;`

			`[[unroll]] for (uint j = 0; j < NUM_COLS; ++j) {`
			`[[unroll]] for (uint i = 0; i < NUM_ROWS; ++i) {`
			`temp[j][i] = FLOAT_TYPE(0);`
			`}`
			`}`

			`[[unroll]] for (uint i = ix; i < num_blocks_per_row; i += blocks_per_wg)`
			`calc_superblock(a_offset, b_offset, itid, i, num_blocks_per_row, first_row, num_rows);`

			`reduce_result(temp, d_offset, first_row, num_rows, tid);`
			`}`

			`void main() {`
			`const uint first_row = NUM_ROWS * (gl_WorkGroupID.x + gl_NumWorkGroups.x * gl_WorkGroupID.z);`

			`init_iq_shmem(gl_WorkGroupSize);`

			`// do NUM_ROWS at a time, unless there aren't enough remaining rows`
			`if (first_row + NUM_ROWS <= p.stride_d) {`
			`compute_outputs(first_row, NUM_ROWS);`
			`} else {`
			`if (first_row >= p.stride_d) {`
			`return;`
			`}`
			`compute_outputs(first_row, p.stride_d - first_row);`
			`}`
			`}`