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echodict
/

llama.cpp

	enable f16;

	#define DECLARE_BYTE_LOADERS_SRC0
	#include "common_decls.tmpl"


	#ifdef FLOAT
	const BLOCK_SIZE = 1u;

	#elif defined(Q4_0) \|\| defined(Q4_1) \|\| defined(Q5_0) \|\| defined(Q5_1) \|\| defined(Q8_0) \|\| defined(Q8_1) \|\| defined(IQ4_NL)
	const BLOCK_SIZE = 32u;

	#elif defined(Q2_K) \|\| defined(Q3_K) \|\| defined(Q4_K) \|\| defined(Q5_K) \|\| defined(Q6_K) \|\| defined(IQ2_XXS) \|\| defined(IQ2_XS) \|\| defined(IQ2_S) \|\| defined(IQ3_XXS) \|\| defined(IQ3_S) \|\| defined(IQ1_S) \|\| defined(IQ1_M) \|\| defined(IQ4_XS)
	const BLOCK_SIZE = 256u;
	#endif

	#ifdef FLOAT
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	return f32(src0[src0_idx_base + offset]) * f32(src1[src1_idx_base + offset]);
	}
	#endif

	#ifdef Q4_0
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 18; // Block stride: 18 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var sum: f32 = 0.0;
	for (var j: u32 = 0; j < 4; j++) {
	let q_byte_offset = block_byte_base + 2 + j * 4;
	let q_packed = load_u32_at_src0(q_byte_offset);
	for (var k: u32 = 0; k < 4; k++) {
	let q_byte = get_byte(q_packed, k);
	let q_hi = (f32((q_byte >> 4) & 0xF) - 8.0f) * d;
	let q_lo = (f32(q_byte & 0xF) - 8.0f) * d;
	let src1_offset = src1_idx_base + offset * 32 + j * 4 + k;
	sum += q_lo * f32(src1[src1_offset]);
	sum += q_hi * f32(src1[src1_offset + 16]);
	}
	}
	return sum;
	}
	#endif

	#ifdef Q4_1
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_q4_1 = src0[src0_idx_base + offset];
	let d = f32(block_q4_1.d);
	let m = f32(block_q4_1.m);
	var sum: f32 = 0.0;
	for (var j: u32 = 0; j < 4; j++) {
	let q_packed = block_q4_1.qs[j];
	for (var k: u32 = 0; k < 4; k++) {
	let q_byte = get_byte(q_packed, k);
	let q_hi = f32((q_byte >> 4) & 0xF) * d + m;
	let q_lo = f32(q_byte & 0xF) * d + m;
	let src1_offset = src1_idx_base + offset * 32 + j * 4 + k;
	sum += q_lo * f32(src1[src1_offset]);
	sum += q_hi * f32(src1[src1_offset + 16]);
	}
	}
	return sum;
	}
	#endif

	#ifdef Q5_0
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 22; // Block stride: 22 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var sum: f32 = 0.0;
	let qh_packed = load_u32_at_src0(block_byte_base + 2);
	for (var j: u32 = 0; j < 4; j++) {
	let q_byte_offset = block_byte_base + 6 + j * 4;
	let q_packed = load_u32_at_src0(q_byte_offset);
	for (var k: u32 = 0; k < 4; k++) {
	let q_byte = get_byte(q_packed, k);
	let qh_hi = (qh_packed >> (j * 4 + k + 12)) & 0x10;
	let q_hi = (f32(((q_byte >> 4) & 0xF) \| qh_hi) - 16.0) * d;
	let qh_lo = ((qh_packed >> (j * 4 + k)) << 4) & 0x10;
	let q_lo = (f32((q_byte & 0xF) \| qh_lo) - 16.0) * d;
	let src1_offset = src1_idx_base + offset * 32 + j * 4 + k;
	sum += q_lo * f32(src1[src1_offset]);
	sum += q_hi * f32(src1[src1_offset + 16]);
	}
	}
	return sum;
	}
	#endif

	#ifdef Q5_1
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_q5_1 = src0[src0_idx_base + offset];
	let d = f32(block_q5_1.d);
	let m = f32(block_q5_1.m);
	var sum: f32 = 0.0;
	for (var j: u32 = 0; j < 4; j++) {
	let q_packed = block_q5_1.qs[j];
	for (var k: u32 = 0; k < 4; k++) {
	let q_byte = get_byte(q_packed, k);
	let qh_hi = (block_q5_1.qh >> (j * 4 + k + 12)) & 0x10;
	let q_hi = f32(((q_byte >> 4) & 0xF) \| qh_hi) * d + m;
	let qh_lo = ((block_q5_1.qh >> (j * 4 + k)) << 4) & 0x10;
	let q_lo = f32((q_byte & 0xF) \| qh_lo) * d + m;
	let src1_offset = src1_idx_base + offset * 32 + j * 4 + k;
	sum += q_lo * f32(src1[src1_offset]);
	sum += q_hi * f32(src1[src1_offset + 16]);
	}
	}
	return sum;
	}
	#endif

	#ifdef Q8_0
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 34; // Block stride: 34 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var sum: f32 = 0.0;
	for (var j: u32 = 0; j < 8; j++) {
	let q_byte_offset = block_byte_base + 2 + j * 4;
	let q_packed = load_u32_at_src0(q_byte_offset);
	for (var k: u32 = 0u; k < 4u; k++) {
	let q_byte = get_byte_i32(q_packed, k);
	let q_val = f32(q_byte) * d;
	let src1_offset = src1_idx_base + offset * 32 + j * 4 + k;
	sum += q_val * f32(src1[src1_offset]);
	}
	}
	return sum;
	}
	#endif

	#ifdef Q8_1
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_q8_1 = src0[src0_idx_base + offset];
	let d = f32(block_q8_1.d);
	let m = f32(block_q8_1.m);
	var sum: f32 = 0.0;
	for (var j: u32 = 0; j < 8; j++) {
	let q_packed = block_q8_1.qs[j];
	for (var k: u32 = 0; k < 4; k++) {
	let q_byte = get_byte_i32(q_packed, k);
	let q_val = f32(q_byte) * d + m;
	let src1_offset = src1_idx_base + offset * 32 + j * 4 + k;
	sum += q_val * f32(src1[src1_offset]);
	}
	}
	return sum;
	}
	#endif

	#ifdef Q2_K
	// 16 blocks of 16 elements each
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block = src0[src0_idx_base + offset];
	let d = f32(block.d);
	let m = f32(block.dmin);
	var sum = 0.0;
	var src1_i = src1_idx_base + offset * 256;
	var is: u32 = 0;
	// 2 halves of the block (128 elements each)
	for (var q_b_idx: u32 = 0; q_b_idx < 64; q_b_idx += 32) {
	// 4 groups (each group has 2 blocks of 16 elements)
	for (var shift: u32 = 0; shift < 8; shift += 2) {
	// 2 blocks
	for (var k: u32 = 0; k < 32; k += 16) {
	let sc = get_byte(block.scales[is / 4], is % 4);
	is++;
	let dl = d * f32(sc & 0xF);
	let ml = m * f32(sc >> 4);
	for (var l: u32 = 0u; l < 16; l++) {
	let q_idx = q_b_idx + k + l;
	let q_byte = get_byte(block.qs[q_idx / 4], q_idx % 4);
	let qs_val = (q_byte >> shift) & 3;
	sum += (f32(qs_val) * dl - ml) * src1[src1_i];
	src1_i++;
	}
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef Q3_K
	// 16 blocks of 16 elements each
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 110; // Block stride: 110 bytes

	// Bytes 108-109: f16 scale 'd'
	let d = load_f16_as_f32_at_src0(block_byte_base + 108);

	// extract 6-bit scales, which consist of 4-bits from first 8 bytes of scale,
	// and 2-bits from the last 4 bytes
	// Bytes 96-107: 12 bytes of scales (3 u32s)
	let kmask1: u32 = 0x03030303;
	let kmask2: u32 = 0x0f0f0f0f;
	var scale_vals: array<u32, 4>;
	scale_vals[0] = load_u32_at_src0(block_byte_base + 96);
	scale_vals[1] = load_u32_at_src0(block_byte_base + 100);
	scale_vals[2] = load_u32_at_src0(block_byte_base + 104);

	var tmp: u32 = scale_vals[2];
	scale_vals[2] = ((scale_vals[0] >> 4) & kmask2) \| (((tmp >> 4) & kmask1) << 4);
	scale_vals[3] = ((scale_vals[1] >> 4) & kmask2) \| (((tmp >> 6) & kmask1) << 4);
	scale_vals[0] = (scale_vals[0] & kmask2) \| ((tmp & kmask1) << 4);
	scale_vals[1] = (scale_vals[1] & kmask2) \| (((tmp >> 2) & kmask1) << 4);

	// Bytes 0-31: 32 bytes of hmask (8 u32s)
	var hmask_vals: array<u32, 8>;
	for (var i: u32 = 0; i < 8; i++) {
	hmask_vals[i] = load_u32_at_src0(block_byte_base + i * 4);
	}

	// Bytes 32-95: 64 bytes of qs (16 u32s)
	var qs_vals: array<u32, 16>;
	for (var i: u32 = 0u; i < 16; i++) {
	qs_vals[i] = load_u32_at_src0(block_byte_base + 32 + i * 4);
	}

	var sum = 0.0;
	var src1_i = src1_idx_base + offset * 256;
	var is: u32 = 0;
	var m: u32 = 1;
	// 2 halves of the block (128 elements each)
	for (var q_b_idx: u32 = 0; q_b_idx < 64; q_b_idx += 32) {
	// 4 groups (each group has 2 blocks of 16 elements)
	for (var shift: u32 = 0; shift < 8; shift += 2) {
	// 2 blocks
	for (var k: u32 = 0; k < 32; k += 16) {
	let sc = get_byte(scale_vals[is / 4], is % 4);
	is++;
	let dl = d * (f32(sc) - 32.0);
	for (var l: u32 = 0u; l < 16u; l++) {
	let q_idx = q_b_idx + k + l;
	let hm_idx = k + l;
	let q_byte = get_byte(qs_vals[q_idx / 4], q_idx % 4);
	let hmask_byte = get_byte(hmask_vals[hm_idx / 4], hm_idx % 4);
	let hm = select(4.0, 0.0, (hmask_byte & m) != 0);
	let qs_val = (q_byte >> shift) & 3;
	sum += ((f32(qs_val) - hm) * dl) * src1[src1_i];
	src1_i++;
	}
	}
	m <<= 1;
	}
	}
	return sum;
	}
	#endif

	#ifdef Q4_K
	// 8 blocks of 32 elements each
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block = src0[src0_idx_base + offset];
	let d = f32(block.d);
	let m = f32(block.dmin);
	var sum = 0.0;
	var src1_i = src1_idx_base + offset * 256;
	var is: u32 = 0;
	// 2 blocks each iteration
	for (var q_b_idx: u32 = 0; q_b_idx < 128; q_b_idx += 32) {
	for (var shift: u32 = 0; shift < 8; shift += 4) {
	let scale_min = get_scale_min(is, block.scales);
	is++;
	let dl = d * scale_min.x;
	let ml = m * scale_min.y;
	for (var l: u32 = 0; l < 32; l++) {
	let q_idx = q_b_idx + l;
	let q_byte = get_byte(block.qs[q_idx / 4], q_idx % 4);
	let qs_val = (q_byte >> shift) & 0xF;
	sum += (f32(qs_val) * dl - ml) * src1[src1_i];
	src1_i++;
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef Q5_K
	// 8 blocks of 32 elements each
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block = src0[src0_idx_base + offset];
	let d = f32(block.d);
	let m = f32(block.dmin);
	var sum = 0.0;
	var src1_i = src1_idx_base + offset * 256;
	var is: u32 = 0;
	var u: u32 = 1;
	// 2 blocks each iteration
	for (var q_b_idx: u32 = 0; q_b_idx < 128; q_b_idx += 32) {
	for (var shift: u32 = 0; shift < 8; shift += 4) {
	let scale_min = get_scale_min(is, block.scales);
	is++;
	let dl = d * scale_min.x;
	let ml = m * scale_min.y;
	for (var l: u32 = 0; l < 32; l++) {
	let q_idx = q_b_idx + l;
	let q_byte = get_byte(block.qs[q_idx / 4], q_idx % 4);
	let qh_byte = get_byte(block.qh[l / 4], l % 4);
	let qs_val = (q_byte >> shift) & 0xF;
	let qh_val = select(0.0, 16.0, (qh_byte & u) != 0);
	sum += ((f32(qs_val) + qh_val) * dl - ml) * src1[src1_i];
	src1_i++;
	}
	u <<= 1;
	}
	}
	return sum;
	}
	#endif

	#ifdef Q6_K
	// 16 blocks of 16 elements each
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 210; // Block stride: 210 bytes

	// Bytes 208-209: f16 scale 'd'
	let d = load_f16_as_f32_at_src0(block_byte_base + 208);

	// Bytes 0-127: 128 bytes of ql (32 u32s)
	var ql_vals: array<u32, 32>;
	for (var i: u32 = 0; i < 32; i++) {
	ql_vals[i] = load_u32_at_src0(block_byte_base + i * 4);
	}

	// Bytes 128-191: 64 bytes of qh (16 u32s)
	var qh_vals: array<u32, 16>;
	for (var i: u32 = 0; i < 16; i++) {
	qh_vals[i] = load_u32_at_src0(block_byte_base + 128 + i * 4);
	}

	// Bytes 192-207: 16 bytes of scales (4 u32s)
	var scale_vals: array<u32, 4>;
	for (var i: u32 = 0; i < 4; i++) {
	scale_vals[i] = load_u32_at_src0(block_byte_base + 192 + i * 4);
	}

	var sum = 0.0;
	var src1_i = src1_idx_base + offset * 256;
	var qh_b_idx: u32 = 0;
	var sc_b_idx: u32 = 0;
	for (var ql_b_idx: u32 = 0; ql_b_idx < 128; ql_b_idx += 64) {
	for (var l: u32 = 0; l < 32; l++) {
	let ql13_b = get_byte(ql_vals[(ql_b_idx + l) / 4], (ql_b_idx + l) % 4);
	let ql24_b = get_byte(ql_vals[(ql_b_idx + l + 32) / 4], (ql_b_idx + l + 32) % 4);
	let qh_b = get_byte(qh_vals[(qh_b_idx + l) / 4], (qh_b_idx + l) % 4);

	let q1 = f32((ql13_b & 0xF) \| ((qh_b & 3) << 4)) - 32.0;
	let q2 = f32((ql24_b & 0xF) \| (((qh_b >> 2) & 3) << 4)) - 32.0;
	let q3 = f32((ql13_b >> 4) \| (((qh_b >> 4) & 3) << 4)) - 32.0;
	let q4 = f32((ql24_b >> 4) \| (((qh_b >> 6) & 3) << 4)) - 32.0;

	let is = l/16;
	let is1 = sc_b_idx + is;
	let sc1 = get_byte_i32(scale_vals[is1 / 4], is1 % 4);
	let is2 = sc_b_idx + is + 2;
	let sc2 = get_byte_i32(scale_vals[is2 / 4], is2 % 4);
	let is3 = sc_b_idx + is + 4;
	let sc3 = get_byte_i32(scale_vals[is3 / 4], is3 % 4);
	let is4 = sc_b_idx + is + 6;
	let sc4 = get_byte_i32(scale_vals[is4 / 4], is4 % 4);

	sum += d * f32(sc1) * q1 * src1[src1_i + l];
	sum += d * f32(sc2) * q2 * src1[src1_i + l + 32];
	sum += d * f32(sc3) * q3 * src1[src1_i + l + 64];
	sum += d * f32(sc4) * q4 * src1[src1_i + l + 96];
	}
	src1_i += 128;
	qh_b_idx += 32;
	sc_b_idx += 8;
	}
	return sum;
	}
	#endif

	#ifdef IQ2_XXS
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 66; // Block stride: 66 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 256;
	var sum = 0.0;
	for (var ib: u32 = 0; ib < 32; ib += 4) {
	let aux0_offset = block_byte_base + 2 + ib * 2;
	let aux1_offset = block_byte_base + 2 + (ib + 2) * 2;
	let aux0 = load_u32_at_src0(aux0_offset);
	let aux1 = load_u32_at_src0(aux1_offset);
	let db = d * (0.5 + f32(aux1 >> 28)) * 0.25;
	for (var l: u32 = 0; l < 4; l++) {
	let ig = get_byte(aux0, l) * 8;
	let is = (aux1 >> (7 * l)) & 127;
	let signs = get_byte(ksigns_iq2xs[is / 4], is % 4);
	for (var j: u32 = 0; j < 8; j++) {
	let g = get_byte(iq2xxs_grid[(ig + j) / 4], (ig + j) % 4);
	let m = select(1.0, -1.0, (get_byte(kmask_iq2xs[j / 4], j % 4) & signs) != 0);
	sum += db * f32(g) * m * src1[src1_i];
	src1_i++;
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef IQ2_XS
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 74; // Block stride: 74 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 256;

	var scale_vals = array<u32, 2>(
	load_u32_at_src0(block_byte_base + 66),
	load_u32_at_src0(block_byte_base + 70)
	);

	var sum = 0.0;
	for (var ib: u32 = 0; ib < 32; ib += 4) {
	let s = get_byte(scale_vals[ib / 16], (ib % 16) / 4);
	let db = array<f32, 2>(
	d * (0.5 + f32(s & 0xF)) * 0.25,
	d * (0.5 + f32(s >> 4)) * 0.25
	);
	for (var l: u32 = 0; l < 4; l++) {
	let qs_offset = block_byte_base + 2 + (ib + l) * 2;
	let qs_val = load_u32_at_src0(qs_offset) & 0xFFFF;
	let ig = (qs_val & 511) * 8;
	let is = qs_val >> 9;
	let signs = get_byte(ksigns_iq2xs[is / 4], is % 4);
	let dl = db[l/2];
	for (var j: u32 = 0; j < 8; j++) {
	let g = get_byte(iq2xs_grid[(ig + j) / 4], (ig + j) % 4);
	let m = select(1.0, -1.0, (get_byte(kmask_iq2xs[j / 4], j % 4) & signs) != 0);
	sum += dl * f32(g) * m * src1[src1_i];
	src1_i++;
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef IQ2_S
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 82; // Block stride: 82 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 256;

	var qs_vals : array<u32, 16>;
	for (var i: u32 = 0; i < 16; i++) {
	qs_vals[i] = load_u32_at_src0(block_byte_base + 2 + i * 4);
	}

	var qh_vals: array<u32, 2>;
	qh_vals[0] = load_u32_at_src0(block_byte_base + 66);
	qh_vals[1] = load_u32_at_src0(block_byte_base + 70);

	var scale_vals: array<u32, 2>;
	scale_vals[0] = load_u32_at_src0(block_byte_base + 74);
	scale_vals[1] = load_u32_at_src0(block_byte_base + 78);

	var sum = 0.0;
	for (var ib: u32 = 0; ib < 8; ib ++) {
	let s = get_byte(scale_vals[ib / 4], ib % 4);
	let db = array<f32, 2>(
	d * (0.5 + f32(s & 0xF)) * 0.25,
	d * (0.5 + f32(s >> 4)) * 0.25
	);
	let qs_w = qs_vals[ib];
	for (var l: u32 = 0; l < 4; l++) {
	let qh_b = (get_byte(qh_vals[ib / 4], ib % 4) << (8 - 2 * l)) & 0x300;
	let ig = (get_byte(qs_w, l) \| qh_b) * 8;
	let signs = get_byte(qs_vals[ib + 8], l);
	let dl = db[l/2];
	for (var j: u32 = 0; j < 8; j++) {
	let g = get_byte(iq2s_grid[(ig + j) / 4], (ig + j) % 4);
	let m = select(1.0, -1.0, (get_byte(kmask_iq2xs[j / 4], j % 4) & signs) != 0);
	sum += dl * f32(g) * m * src1[src1_i];
	src1_i++;
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef IQ3_XXS
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 98; // Block stride: 98 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 256;
	var sum = 0.0;
	for (var ib: u32 = 0; ib < 16; ib += 2) {
	let sc_sign_offset = block_byte_base + 2 + (ib + 32) * 2;
	let sc_sign = load_u32_at_src0(sc_sign_offset);
	let db = d * (0.5 + f32(sc_sign >> 28)) * 0.5;
	for (var l: u32 = 0; l < 4; l++) {
	let is = (sc_sign >> (7 * l)) & 127;
	let signs = get_byte(ksigns_iq2xs[is / 4], is % 4);
	let ig_val = load_u32_at_src0(block_byte_base + 2 + (ib * 2 + l) * 2) & 0xFFFF;
	let ig1 = get_byte(ig_val, 0);
	let ig2 = get_byte(ig_val, 1);
	for (var j: u32 = 0; j < 4; j++) {
	let g1 = get_byte(iq3xxs_grid[ig1], j);
	let g2 = get_byte(iq3xxs_grid[ig2], j);
	let m1 = select(1.0, -1.0, (get_byte(kmask_iq2xs[0], j) & signs) != 0);
	let m2 = select(1.0, -1.0, (get_byte(kmask_iq2xs[1], j) & signs) != 0);
	sum += db * f32(g1) * m1 * src1[src1_i];
	sum += db * f32(g2) * m2 * src1[src1_i + 4];
	src1_i++;
	}
	src1_i += 4;
	}
	}
	return sum;
	}
	#endif

	#ifdef IQ3_S
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 110; // Block stride: 110 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 256;

	var qh_vals = array<u32, 2>(
	load_u32_at_src0(block_byte_base + 66),
	load_u32_at_src0(block_byte_base + 70)
	);

	var sign_vals: array<u32, 8>;
	for (var i: u32 = 0; i < 8; i++) {
	sign_vals[i] = load_u32_at_src0(block_byte_base + 74 + i * 4);
	}

	var scale_vals = load_u32_at_src0(block_byte_base + 106);

	var sum = 0.0;
	for (var ib: u32 = 0; ib < 4; ib++) {
	let s = get_byte(scale_vals, ib);
	let db = array<f32, 2>(
	d * (1.0 + 2.0 * f32(s & 0xF)),
	d * (1.0 + 2.0 * f32(s >> 4))
	);
	for (var k: u32 = 0; k < 2; k++) {
	let dl = db[k];
	let qh_byte = get_byte(qh_vals[ib / 2], (ib % 2) * 2 + k);
	let sign_w = sign_vals[ib * 2 + k];
	for (var l: u32 = 0; l < 4; l++) {
	let signs = get_byte(sign_w, l);
	let ig_val = load_u32_at_src0(block_byte_base + 2 + (ib * 8 + k * 4 + l) * 2) & 0xFFFF;
	let ig1 = get_byte(ig_val, 0) \| ((qh_byte << ((8 - (2 * l)))) & 256);
	let ig2 = get_byte(ig_val, 1) \| ((qh_byte << ((7 - (2 * l)))) & 256);
	for (var j: u32 = 0; j < 4; j++) {
	let g1 = get_byte(iq3s_grid[ig1], j);
	let g2 = get_byte(iq3s_grid[ig2], j);
	let m1 = select(1.0, -1.0, (get_byte(kmask_iq2xs[0], j) & signs) != 0);
	let m2 = select(1.0, -1.0, (get_byte(kmask_iq2xs[1], j) & signs) != 0);
	sum += dl * f32(g1) * m1 * src1[src1_i];
	sum += dl * f32(g2) * m2 * src1[src1_i + 4];
	src1_i++;
	}
	src1_i += 4;
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef IQ1_S
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 50; // Block stride: 50 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 256;
	var sum = 0.0;
	for (var ib: u32 = 0; ib < 8; ib++) {
	let qh = load_u32_at_src0(block_byte_base + 34 + ib * 2) & 0xFFFF;
	let dl = d * (2.0 * f32((qh >> 12) & 7) + 1.0);
	let delta = select(IQ1_DELTA, -IQ1_DELTA, (qh & 0x8000) != 0);
	let qs_w = load_u32_at_src0(block_byte_base + 2 + ib * 4);
	for (var l: u32 = 0; l < 4; l++) {
	let ig = (get_byte(qs_w, l) \| (((qh >> (3 * l)) & 7) << 8)) * 8;
	for (var j: u32 = 0; j < 8; j++) {
	let gw = iq1_grid[(ig + j) / 16];
	let g = (gw >> (((ig + j) % 16) * 2)) & 3;
	let gs = bitcast<i32>(g << 30) >> 30;
	sum += dl * (f32(gs) + delta) * src1[src1_i];
	src1_i++;
	}
	}
	}
	return sum;
	}
	#endif


	#ifdef IQ1_M
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block = src0[src0_idx_base + offset];

	let scale = ((block.scales[0] >> 12) & 0xF) \| ((block.scales[0] >> 24) & 0x00F0) \| ((block.scales[1] >> 4) & 0x0F00) \| ((block.scales[1] >> 16) & 0xF000);
	let d = f32(bitcast<vec2<f16>>(scale).x);
	var src1_i = src1_idx_base + offset * 256;
	var sum = 0.0;
	for (var ib: u32 = 0; ib < 8; ib++) {
	let sw = (block.scales[ib / 4] >> (16 * ((ib / 2) % 2))) & 0xFFFF;
	let s1 : u32 = (sw >> (6 * (ib % 2))) & 0x7;
	let s2 : u32 = (sw >> (6 * (ib % 2) + 3)) & 0x7;
	var dl = array<f32, 2>(
	d * f32(2 * s1 + 1),
	d * f32(2 * s2 + 1)
	);

	let qh = block.qh[ib / 2] >> (16 * (ib % 2));
	var idx = array<u32, 4>(
	get_byte(block.qs[ib], 0) \| ((qh << 8) & 0x700),
	get_byte(block.qs[ib], 1) \| ((qh << 4) & 0x700),
	get_byte(block.qs[ib], 2) \| ((qh) & 0x700),
	get_byte(block.qs[ib], 3) \| ((qh >> 4) & 0x700)
	);
	var delta = array<f32, 4>(
	select(IQ1_DELTA, -IQ1_DELTA, (qh & 0x08) != 0),
	select(IQ1_DELTA, -IQ1_DELTA, (qh & 0x80) != 0),
	select(IQ1_DELTA, -IQ1_DELTA, ((qh >> 8) & 0x08) != 0),
	select(IQ1_DELTA, -IQ1_DELTA, ((qh >> 8) & 0x80) != 0)
	);
	for (var l: u32 = 0; l < 4; l++) {
	let ig = idx[l] * 8;
	for (var j: u32 = 0; j < 8; j++) {
	let gw = iq1_grid[(ig + j) / 16];
	let g = (gw >> (((ig + j) % 16) * 2)) & 3;
	let gs = bitcast<i32>(g << 30) >> 30;
	sum += dl[l/2] * (f32(gs) + delta[l]) * src1[src1_i];
	src1_i++;
	}
	}
	}
	return sum;
	}
	#endif

	#ifdef IQ4_NL
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block_byte_base = (src0_idx_base + offset) * 18; // Block stride: 18 bytes
	let d = load_f16_as_f32_at_src0(block_byte_base);
	var src1_i = src1_idx_base + offset * 32;
	var sum = 0.0;
	var qs: array<u32, 4>;
	for (var i: u32 = 0; i < 4; i++) {
	qs[i] = load_u32_at_src0(block_byte_base + 2 + i * 4);
	}
	for (var j: u32 = 0; j < 16; j++) {
	let qsb = get_byte(qs[j / 4], j % 4);
	sum += d * f32(kvalues_iq4nl[qsb & 0xF]) * src1[src1_i];
	sum += d * f32(kvalues_iq4nl[qsb >> 4]) * src1[src1_i + 16];
	src1_i++;
	}
	return sum;
	}
	#endif

	#ifdef IQ4_XS
	fn multiply_add(src0_idx_base: u32, src1_idx_base: u32, offset: u32) -> f32 {
	let block = src0[src0_idx_base + offset];
	let d = unpack2x16float(block.d_scales_h)[0];
	let scales_h = block.d_scales_h >> 16;
	var src1_i = src1_idx_base + offset * 256;
	var sum = 0.0;
	for (var ib: u32 = 0; ib < 8; ib++) {
	let ls = ((get_byte(block.scales_l, ib / 2) >> (4 * (ib % 2))) & 0xF) \| (((scales_h >> (2 * ib)) & 3) << 4);
	let dl = d * (f32(ls) - 32.0);
	for (var j: u32 = 0; j < 16; j++) {
	let iqs = ib * 16 + j;
	let qsb = get_byte(block.qs[iqs / 4], iqs % 4);
	sum += dl * f32(kvalues_iq4nl[qsb & 0xF]) * src1[src1_i];
	sum += dl * f32(kvalues_iq4nl[qsb >> 4]) * src1[src1_i + 16];
	src1_i++;
	}
	src1_i += 16;
	}
	return sum;
	}
	#endif

	struct MulMatParams {
	offset_src0: u32, // in elements/blocks
	offset_src1: u32, // in elements/blocks
	offset_dst: u32, // in elements/blocks
	m: u32,
	n: u32,
	k: u32,
	// all strides are in elements/blocks
	stride_01: u32,
	stride_11: u32,
	stride_02: u32,
	stride_12: u32,
	stride_03: u32,
	stride_13: u32,

	bs02: u32,
	bs03: u32,
	broadcast2: u32,
	broadcast3: u32
	};

	@group(0) @binding(0) var<storage, read_write> src0: array<SRC0_TYPE>; // M rows, K columns
	@group(0) @binding(1) var<storage, read_write> src1: array<SRC1_TYPE>; // K rows, N columns (transposed)
	@group(0) @binding(2) var<storage, read_write> dst: array<f32>; // M rows, N columns

	@group(0) @binding(3) var<uniform> params: MulMatParams;

	@compute @workgroup_size(256)
	fn main(@builtin(local_invocation_id) local_id: vec3<u32>,
	@builtin(workgroup_id) wg_id: vec3<u32>,
	@builtin(num_workgroups) num_wg: vec3<u32>) {
	let wg_linear = wg_id.y * num_wg.x + wg_id.x;
	let global_idx = wg_linear * 256u + local_id.x;

	let total = params.m * params.n * params.bs02 * params.broadcast2 * params.bs03 * params.broadcast3;
	if (global_idx >= total) {
	return;
	}

	let dst2_stride = params.m * params.n;
	let dst3_stride = dst2_stride * params.bs02 * params.broadcast2;

	let dst3_idx = global_idx / dst3_stride;
	let src03_idx = dst3_idx / params.broadcast3; // src0 may be broadcast along the third dimension
	let src13_idx = dst3_idx; // src1 is not broadcast
	let dst3_rem = global_idx % dst3_stride;

	let dst2_idx = dst3_rem / dst2_stride;
	let src02_idx = dst2_idx / params.broadcast2; // src0 may also be broadcast along the second dimension
	let src12_idx = dst2_idx; // src1 is not broadcast

	let dst2_rem = dst3_rem % dst2_stride;

	let row = dst2_rem / params.m; // output row
	let col = dst2_rem % params.m; // output column

	let src0_idx_base = params.offset_src0 + src03_idx * params.stride_03 + src02_idx * params.stride_02 + col * params.stride_01;
	let src1_idx_base = params.offset_src1 + src13_idx * params.stride_13 + src12_idx * params.stride_12 + row * params.stride_11;

	var sum = 0.0;
	for (var i: u32 = 0u; i < params.k/BLOCK_SIZE; i = i + 1u) {
	sum += multiply_add(src0_idx_base, src1_idx_base, i);
	}
	dst[params.offset_dst + dst3_idx * dst3_stride + dst2_idx * dst2_stride + row * params.m + col] = sum;
	}