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kcpp-compiled-cuda-linux / ggml /src /ggml-vulkan /vulkan-shaders /dequant_funcs.comp

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	#if !defined(DATA_A_F32) && !defined(DATA_A_F16)
	#extension GL_EXT_shader_explicit_arithmetic_types_int8 : require
	#endif

	#include "types.comp"

	#if defined(A_TYPE_PACKED16)
	layout (binding = 0) readonly buffer A_PACKED16 {A_TYPE_PACKED16 data_a_packed16[];};
	#endif
	#if defined(A_TYPE_PACKED32)
	layout (binding = 0) readonly buffer A_PACKED32 {A_TYPE_PACKED32 data_a_packed32[];};
	#endif

	#if defined(DATA_A_F32)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	return vec2(data_a[a_offset + ib], data_a[a_offset + ib + 1]);
	}
	#endif

	#if defined(DATA_A_F16)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	return vec2(data_a[a_offset + ib], data_a[a_offset + ib + 1]);
	}
	#endif

	#if defined(DATA_A_Q4_0)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint vui = uint(data_a[a_offset + ib].qs[iqs]);
	return (vec2(vui & 0xF, vui >> 4) - 8.0f);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint vui = uint(data_a_packed16[a_offset + ib].qs[iqs/2]);
	return (vec4(vui & 0xF, (vui >> 4) & 0xF, (vui >> 8) & 0xF, vui >> 12) - 8.0f);
	}
	#endif

	#if defined(DATA_A_Q4_1)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint vui = uint(data_a[a_offset + ib].qs[iqs]);
	return vec2(vui & 0xF, vui >> 4);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint vui = uint(data_a_packed16[a_offset + ib].qs[iqs/2]);
	return vec4(vui & 0xF, (vui >> 4) & 0xF, (vui >> 8) & 0xF, vui >> 12);
	}
	#endif

	#if defined(DATA_A_Q5_0)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint uint_qh = uint(data_a[a_offset + ib].qh[1]) << 16 \| data_a[a_offset + ib].qh[0];
	const ivec2 qh = ivec2(((uint_qh >> iqs) << 4) & 0x10, (uint_qh >> (iqs + 12)) & 0x10);
	const uint vui = uint(data_a[a_offset + ib].qs[iqs]);
	return (vec2((vui & 0xF) \| qh.x, (vui >> 4) \| qh.y) - 16.0f);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint uint_qh = uint(data_a_packed16[a_offset + ib].qh[1]) << 16 \| data_a_packed16[a_offset + ib].qh[0];
	const ivec2 qh0 = ivec2(((uint_qh >> iqs) << 4) & 0x10, (uint_qh >> (iqs + 12)) & 0x10);
	const ivec2 qh1 = ivec2(((uint_qh >> (iqs + 1)) << 4) & 0x10, (uint_qh >> (iqs + 13)) & 0x10);
	const uint vui = uint(data_a_packed16[a_offset + ib].qs[iqs/2]);
	return (vec4((vui & 0xF) \| qh0.x, ((vui >> 4) & 0xF) \| qh0.y, ((vui >> 8) & 0xF) \| qh1.x, (vui >> 12) \| qh1.y) - 16.0f);
	}
	#endif

	#if defined(DATA_A_Q5_1)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint uint_qh = data_a[a_offset + ib].qh;
	const ivec2 qh = ivec2(((uint_qh >> iqs) << 4) & 0x10, (uint_qh >> (iqs + 12)) & 0x10);
	const uint vui = uint(data_a[a_offset + ib].qs[iqs]);
	return vec2((vui & 0xF) \| qh.x, (vui >> 4) \| qh.y);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint uint_qh = data_a_packed16[a_offset + ib].qh;
	const ivec2 qh0 = ivec2(((uint_qh >> iqs) << 4) & 0x10, (uint_qh >> (iqs + 12)) & 0x10);
	const ivec2 qh1 = ivec2(((uint_qh >> (iqs + 1)) << 4) & 0x10, (uint_qh >> (iqs + 13)) & 0x10);
	const uint vui = uint(data_a_packed16[a_offset + ib].qs[iqs/2]);
	return vec4((vui & 0xF) \| qh0.x, ((vui >> 4) & 0xF) \| qh0.y, ((vui >> 8) & 0xF) \| qh1.x, (vui >> 12) \| qh1.y);
	}
	#endif

	#if defined(DATA_A_Q8_0)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	return vec2(int(data_a[a_offset + ib].qs[iqs]), int(data_a[a_offset + ib].qs[iqs + 1]));
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	uint32_t v0 = data_a_packed16[a_offset + ib].qs[iqs/2];
	uint32_t v1 = data_a_packed16[a_offset + ib].qs[iqs/2 + 1];
	return vec4(int8_t(v0 & 0xFF), int8_t(v0 >> 8), int8_t(v1 & 0xFF), int8_t(v1 >> 8));
	}
	#endif

	#if defined(DATA_A_IQ1_S)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint ib8 = iqs / 8;
	const int i8 = int(iqs % 8);
	const uint qh = data_a[a_offset + ib].qh[ib32];
	const uint qs = data_a[a_offset + ib].qs[ib8];
	const float dl = float(2 * bitfieldExtract(qh, 12, 3) + 1);
	const float delta = ((qh & 0x8000) != 0) ? -IQ1S_DELTA : IQ1S_DELTA;
	const uint idxhi = bitfieldExtract(qh, 3 * int(ib8 & 3), 3);
	const int16_t grid = int16_t(iq1s_grid[qs \| (idxhi << 8)]);
	// Signed bitfield extract.
	const ivec2 gvec = ivec2(
	bitfieldExtract(grid, 2 * (i8), 2),
	bitfieldExtract(grid, 2 * (i8 + 1), 2)
	);
	return dl * (vec2(gvec) + delta);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint ib8 = iqs / 8;
	const int i8 = int(iqs % 8);
	const uint qh = data_a[a_offset + ib].qh[ib32];
	const uint qs = data_a[a_offset + ib].qs[ib8];
	const float dl = 2 * bitfieldExtract(qh, 12, 3) + 1;
	const float delta = ((qh & 0x8000) != 0) ? -IQ1S_DELTA : IQ1S_DELTA;
	const int16_t grid = int16_t(iq1s_grid[qs \| (bitfieldExtract(qh, 3 * int(ib8 & 3), 3) << 8)]);
	// Signed bitfield extract.
	const ivec4 gvec = ivec4(
	bitfieldExtract(grid, 2 * (i8), 2),
	bitfieldExtract(grid, 2 * (i8 + 1), 2),
	bitfieldExtract(grid, 2 * (i8 + 2), 2),
	bitfieldExtract(grid, 2 * (i8 + 3), 2)
	);
	return dl * (vec4(gvec) + delta);
	}
	#endif

	#if defined(DATA_A_IQ1_M)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint ib8 = iqs / 8;
	const uint ib16 = iqs / 16;
	const int i8 = int(iqs % 8);
	const uint sc = data_a[a_offset + ib].scales[iqs / 64];
	const uint qs = data_a[a_offset + ib].qs[ib8];
	const uint qh = data_a[a_offset + ib].qh[ib16] >> (4 * (ib8 & 1));
	const float dl = 2 * bitfieldExtract(sc, 3 * int(ib16 & 3), 3) + 1;
	const float delta = ((qh & 8) != 0) ? -IQ1M_DELTA : IQ1M_DELTA;
	const int16_t grid = int16_t(iq1s_grid[qs \| ((qh & 7) << 8)]);
	// Signed bitfield extract.
	const ivec2 gvec = ivec2(
	bitfieldExtract(grid, 2 * (i8), 2),
	bitfieldExtract(grid, 2 * (i8 + 1), 2)
	);
	return dl * (vec2(gvec) + delta);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib8 = iqs / 8;
	const uint ib16 = iqs / 16;
	const int i8 = int(iqs % 8);
	const uint sc = data_a[a_offset + ib].scales[iqs / 64];
	const uint qs = data_a[a_offset + ib].qs[ib8];
	const uint qh = data_a[a_offset + ib].qh[ib16] >> (4 * (ib8 & 1));
	const float dl = 2 * bitfieldExtract(sc, 3 * int(ib16 & 3), 3) + 1;
	const float delta = ((qh & 8) != 0) ? -IQ1M_DELTA : IQ1M_DELTA;
	const int16_t grid = int16_t(iq1s_grid[qs \| ((qh & 7) << 8)]);
	// Signed bitfield extract.
	const ivec4 gvec = ivec4(
	bitfieldExtract(grid, 2 * (i8), 2),
	bitfieldExtract(grid, 2 * (i8 + 1), 2),
	bitfieldExtract(grid, 2 * (i8 + 2), 2),
	bitfieldExtract(grid, 2 * (i8 + 3), 2)
	);
	return dl * (vec4(gvec) + delta);
	}
	#endif

	#if defined(DATA_A_IQ2_XXS)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint ib8 = (iqs / 8) % 4;
	const uint qs = data_a[a_offset + ib].qs[8 * ib32 + ib8];
	// Scales are stored as packed 7+7+7+7+4 bits (4 sign tuples and 1 int4 scale)
	const uint signs = pack32(u16vec2(data_a_packed16[a_offset + ib].qs[4 * ib32 + 2],
	data_a_packed16[a_offset + ib].qs[4 * ib32 + 3]));
	const float db = 0.25 * (0.5 + (signs >> 28));
	const uint sign7 = bitfieldExtract(signs, 7 * int(ib8), 7);
	// Add parity bit
	const uint sign8 = sign7 \| (bitCount(sign7) << 7);
	const uint sign = sign8 >> (iqs % 8);
	const u8vec4 grid = unpack8(iq2xxs_grid[qs][(iqs % 8) / 4] >> (8 * (iqs % 4)));
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	return db * vec2(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0)
	);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint ib8 = (iqs / 8) % 4;
	const uint qs = data_a[a_offset + ib].qs[8 * ib32 + ib8];
	// Scales are stored as packed 7+7+7+7+4 bits (4 sign tuples and 1 int4 scale)
	const uint signs = pack32(u16vec2(data_a_packed16[a_offset + ib].qs[4 * ib32 + 2],
	data_a_packed16[a_offset + ib].qs[4 * ib32 + 3]));
	const float db = 0.25 * (0.5 + (signs >> 28));
	const uint sign7 = bitfieldExtract(signs, 7 * int(ib8), 7);
	// Add parity bit
	const uint sign8 = sign7 \| (bitCount(sign7) << 7);
	const uint sign = sign8 >> (iqs % 8);
	const u8vec4 grid = unpack8(iq2xxs_grid[qs][(iqs % 8) / 4] >> (8 * (iqs % 4)));
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	bool sign2 = (sign & 4) != 0;
	bool sign3 = (sign & 8) != 0;
	return db * vec4(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0),
	grid.z * (sign2 ? -1.0 : 1.0),
	grid.w * (sign3 ? -1.0 : 1.0)
	);
	}
	#endif

	#if defined(DATA_A_IQ2_XS)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint scale = (data_a[a_offset + ib].scales[iqs / 32] >> (4 * ((iqs / 16) & 1))) & 0xf;
	const uint qs = data_a[a_offset + ib].qs[iqs / 8];
	const float db = 0.25 * (0.5 + scale);
	const uint sign7 = qs >> 9;
	// Add parity bit
	const uint sign8 = sign7 \| (bitCount(sign7) << 7);
	const uint sign = sign8 >> (iqs % 8);
	const u8vec4 grid = unpack8(iq2xs_grid[qs & 511][(iqs % 8) / 4] >> (8 * (iqs % 4)));
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	return db * vec2(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0)
	);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint scale = (data_a[a_offset + ib].scales[iqs / 32] >> (4 * ((iqs / 16) & 1))) & 0xf;
	const uint qs = data_a[a_offset + ib].qs[iqs / 8];
	const float db = 0.25 * (0.5 + scale);
	const uint sign7 = qs >> 9;
	// Add parity bit
	const uint sign8 = sign7 \| (bitCount(sign7) << 7);
	const uint sign = sign8 >> (iqs % 8);
	const u8vec4 grid = unpack8(iq2xs_grid[qs & 511][(iqs % 8) / 4] >> (8 * (iqs % 4)));
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	bool sign2 = (sign & 4) != 0;
	bool sign3 = (sign & 8) != 0;
	return db * vec4(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0),
	grid.z * (sign2 ? -1.0 : 1.0),
	grid.w * (sign3 ? -1.0 : 1.0)
	);
	}
	#endif

	#if defined(DATA_A_IQ2_S)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint ib8 = iqs / 8;

	const uint scale = (data_a[a_offset + ib].scales[ib32] >> (4 * ((iqs / 16) & 1))) & 0xf;
	const uint qs = data_a[a_offset + ib].qs[ib8];
	const uint qh = data_a[a_offset + ib].qh[ib32];
	const uint qhshift = 2 * (ib8 % 4);
	const uint sign = data_a[a_offset + ib].qs[QUANT_K / 8 + ib8] >> (iqs % 8);

	const float db = 0.25 * (0.5 + scale);
	const u8vec4 grid = unpack8(iq2s_grid[qs \| ((qh << (8 - qhshift)) & 0x300)][(iqs % 8) / 4]);
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	return db * vec2(
	grid[iqs % 4] * (sign0 ? -1.0 : 1.0),
	grid[(iqs % 4) + 1] * (sign1 ? -1.0 : 1.0)
	);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint ib8 = iqs / 8;

	const uint scale = (data_a[a_offset + ib].scales[ib32] >> (4 * ((iqs / 16) & 1))) & 0xf;
	const uint qs = data_a[a_offset + ib].qs[ib8];
	const uint qh = data_a[a_offset + ib].qh[ib32];
	const uint qhshift = 2 * (ib8 % 4);
	const uint sign = data_a[a_offset + ib].qs[QUANT_K / 8 + ib8] >> (iqs % 8);

	const float db = 0.25 * (0.5 + scale);
	const u8vec4 grid = unpack8(iq2s_grid[qs \| ((qh << (8 - qhshift)) & 0x300)][(iqs % 8) / 4]);
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	bool sign2 = (sign & 4) != 0;
	bool sign3 = (sign & 8) != 0;
	return db * vec4(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0),
	grid.z * (sign2 ? -1.0 : 1.0),
	grid.w * (sign3 ? -1.0 : 1.0)
	);
	}
	#endif

	#if defined(DATA_A_IQ3_XXS)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint ib4 = iqs / 4;
	const uint ib32 = iqs / 32;
	const uint is = QUANT_K / 4 + 4 * ib32;
	const uint qs = data_a[a_offset + ib].qs[ib4];
	// Scales are stored as packed 7+7+7+7+4 bits (4 sign tuples and 1 int4 scale)
	const uint signs = pack32(u16vec2(data_a_packed16[a_offset + ib].qs[is / 2],
	data_a_packed16[a_offset + ib].qs[is / 2 + 1]));
	const float db = 0.5 * (0.5 + (signs >> 28));
	const uint sign7 = bitfieldExtract(signs, 7 * (int(ib4 / 2) % 4), 7);
	// Add parity bit
	const uint sign8 = sign7 \| (bitCount(sign7) << 7);
	const uint sign = sign8 >> (iqs % 8);
	const u8vec4 grid = unpack8(iq3xxs_grid[qs] >> (8 * (iqs % 4)));
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	return db * vec2(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0)
	);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib4 = iqs / 4;
	const uint ib32 = iqs / 32;
	const uint is = QUANT_K / 4 + 4 * ib32;
	const uint qs = data_a[a_offset + ib].qs[ib4];
	const uint signs = pack32(u16vec2(data_a_packed16[a_offset + ib].qs[is / 2],
	data_a_packed16[a_offset + ib].qs[is / 2 + 1]));
	const float db = 0.5 * (0.5 + (signs >> 28));
	const uint sign7 = bitfieldExtract(signs, 7 * (int(ib4 / 2) % 4), 7);
	// Add parity bit
	const uint sign8 = sign7 \| (bitCount(sign7) << 7);
	const uint sign = sign8 >> (iqs % 8);
	const u8vec4 grid = unpack8(iq3xxs_grid[qs]);
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	bool sign2 = (sign & 4) != 0;
	bool sign3 = (sign & 8) != 0;
	return db * vec4(
	grid.x * (sign0 ? -1.0 : 1.0),
	grid.y * (sign1 ? -1.0 : 1.0),
	grid.z * (sign2 ? -1.0 : 1.0),
	grid.w * (sign3 ? -1.0 : 1.0)
	);
	}
	#endif

	#if defined(DATA_A_IQ3_S)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint qs = data_a[a_offset + ib].qs[iqs / 4];
	const uint qh = data_a[a_offset + ib].qh[iqs / 32];
	const uint sign = data_a[a_offset + ib].signs[iqs / 8] >> (iqs % 8);
	const uint scale = data_a[a_offset + ib].scales[iqs / 64];
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	const float db = 1 + 2 * ((scale >> (4 * ((iqs / 32) & 1))) & 0xf);
	const uint32_t grid = iq3s_grid[qs \| ((qh << (8 - ((iqs / 4) % 8))) & 256)] >> (8 * (iqs % 4));
	return db * vec2(
	int(grid & 0xFF) * (sign0 ? -1.0 : 1.0),
	int((grid >> 8) & 0xFF) * (sign1 ? -1.0 : 1.0)
	);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib4 = iqs / 4;
	const uint ib32 = iqs / 32;
	const uint qs = data_a[a_offset + ib].qs[ib4];
	const uint qh = data_a[a_offset + ib].qh[ib32];
	const uint sign = data_a[a_offset + ib].signs[iqs / 8] >> (iqs % 8);
	const uint scale = data_a[a_offset + ib].scales[ib32 / 2];
	bool sign0 = (sign & 1) != 0;
	bool sign1 = (sign & 2) != 0;
	bool sign2 = (sign & 4) != 0;
	bool sign3 = (sign & 8) != 0;
	const float db = 1 + 2 * ((scale >> (4 * (ib32 & 1))) & 0xf);
	const uint32_t grid = iq3s_grid[qs \| ((qh << (8 - ib4 % 8)) & 256)] >> (8 * (iqs % 4));
	return db * vec4(
	int(grid & 0xFF) * (sign0 ? -1.0 : 1.0),
	int((grid >> 8) & 0xFF) * (sign1 ? -1.0 : 1.0),
	int((grid >> 16) & 0xFF) * (sign2 ? -1.0 : 1.0),
	int((grid >> 24) & 0xFF) * (sign3 ? -1.0 : 1.0)
	);
	}
	#endif

	#if defined(DATA_A_IQ4_XS)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint iq = 16 * ib32 + (iqs % 16);

	const uint sl = (data_a[a_offset + ib].scales_l[ib32/2] >> (4 * (ib32 & 1))) & 0xF;
	const uint sh = (data_a[a_offset + ib].scales_h >> (2 * ib32)) & 3;
	const uint qshift = (iqs & 16) >> 2;
	u8vec2 qs = u8vec2(data_a[a_offset + ib].qs[iq], data_a[a_offset + ib].qs[iq + 1]);
	qs = (qs >> qshift) & uint8_t(0xF);

	const float dl = float(int(sl \| (sh << 4)) - 32);
	return dl * vec2(kvalues_iq4nl[qs.x], kvalues_iq4nl[qs.y]);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint ib32 = iqs / 32;
	const uint iq = 16 * ib32 + (iqs % 16);

	const uint sl = (data_a[a_offset + ib].scales_l[ib32/2] >> (4 * (ib32 & 1))) & 0xF;
	const uint sh = (data_a[a_offset + ib].scales_h >> (2 * ib32)) & 3;
	const uint qshift = (iqs & 16) >> 2;
	u8vec4 qs = u8vec4(
	data_a[a_offset + ib].qs[iq + 0],
	data_a[a_offset + ib].qs[iq + 1],
	data_a[a_offset + ib].qs[iq + 2],
	data_a[a_offset + ib].qs[iq + 3]
	);
	qs = (qs >> qshift) & uint8_t(0xF);

	const float dl = float(int(sl \| (sh << 4)) - 32);
	return dl * vec4(
	kvalues_iq4nl[qs.x], kvalues_iq4nl[qs.y],
	kvalues_iq4nl[qs.z], kvalues_iq4nl[qs.w]);
	}
	#endif

	#if defined(DATA_A_IQ4_NL)
	vec2 dequantize(uint ib, uint iqs, uint a_offset) {
	const uint vui = uint(data_a[a_offset + ib].qs[iqs]);
	return vec2(kvalues_iq4nl[vui & 0xF], kvalues_iq4nl[vui >> 4]);
	}
	vec4 dequantize4(uint ib, uint iqs, uint a_offset) {
	const uint vui = uint(data_a_packed16[a_offset + ib].qs[iqs/2]);
	return vec4(kvalues_iq4nl[vui & 0xF], kvalues_iq4nl[(vui >> 4) & 0xF], kvalues_iq4nl[(vui >> 8) & 0xF], kvalues_iq4nl[vui >> 12]);
	}
	#endif

	#if defined(DATA_A_F32) \|\| defined(DATA_A_F16)
	vec2 get_dm(uint ib, uint a_offset) {
	return vec2(0, 0);
	}
	#endif

	#if defined(DATA_A_IQ1_M)
	vec2 get_dm(uint ib, uint a_offset) {
	const uint16_t[4] scales = data_a[a_offset + ib].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);
	return vec2(d, 0);
	}
	#endif

	#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)
	vec2 get_dm(uint ib, uint a_offset) {
	return vec2(float(data_a[a_offset + ib].d), 0);
	}
	#endif

	#if defined(DATA_A_Q4_1) \|\| defined(DATA_A_Q5_1)
	vec2 get_dm(uint ib, uint a_offset) {
	return vec2(float(data_a[a_offset + ib].d), float(data_a[a_offset + ib].m));
	}
	#endif