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	/*
	* PACKED UNARY TRANSFORMER ENGINE - AVX-512 + OpenMP
	*
	* Instead of 7 fixed bitplanes (scanning 80% zeros),
	* store magnitude per weight directly. Kernel processes
	* groups of 16 weights, only loops to local max magnitude.
	*
	* Weight j with magnitude 3: adds x[j] THREE times (pure unary).
	* But only 3 passes for that group, not 7.
	*
	* Average magnitude = 1.374, so average ~1.4 passes per group
	* instead of always 7. That's the 5x speedup.
	*
	* Format per output row:
	* mags[in_dim] uint8 - magnitude 0-7 per weight
	* signs[chunks] uint64 - bitpacked sign (1=negative)
	* scale float - per-row scale
	*
	* (c) 2026 OpenTransformers Ltd / Scott Bisset
	*/

	#include <immintrin.h>
	#include <stdint.h>
	#include <stdlib.h>
	#include <string.h>
	#include <math.h>
	#include <stdio.h>
	#include <time.h>
	#include <omp.h>

	#define HIDDEN 1536
	#define INTER 8960
	#define N_HEADS 12
	#define N_KV_HEADS 2
	#define HEAD_DIM 128
	#define N_LAYERS 28
	#define VOCAB 151936
	#define RMS_EPS 1e-6f
	#define ROPE_THETA 1000000.0f
	#define MAX_SEQ 4096
	#define GQA_RATIO (N_HEADS / N_KV_HEADS)

	typedef struct {
	uint8_t mags; / [out_dim * in_dim] magnitude per weight */
	uint64_t sign_bits; / [out_dim * chunks] bitpacked signs */
	float scales; / [out_dim] per-row scale */
	float bias; / [out_dim] or NULL */
	int out_dim, in_dim;
	uint8_t row_maxmag; / [out_dim] max magnitude per row for early exit */
	} PL; /* Packed Linear */

	typedef struct { uint16_t *w; int od, id; } FL;

	typedef struct {
	PL qp, kp, vp, op, gp, up, dp;
	float in_norm, pn_norm;
	float qb, kb, *vb;
	} Lay;

	typedef struct {
	uint16_t *emb;
	Lay lay[N_LAYERS];
	float *fnorm;
	FL lmh;
	float kc, vc;
	float h, h2;
	float sq, sk, sv, ao;
	float sg, su, *sd;
	float lg, as;
	} M;

	/* ============================================================
	* PACKED UNARY MATVEC
	*
	* Process 16 weights at a time. For each group:
	* 1. Load 16 magnitudes (uint8)
	* 2. Find local max magnitude
	* 3. For m = 1 to local_max:
	* mask = (mag >= m)
	* pos_mask = mask & ~sign
	* neg_mask = mask & sign
	* acc += masked x (pos)
	* acc -= masked x (neg)
	*
	* Each pass = one unary "mark". Pure base-1.
	* Groups where all mags <= 1: ONE pass.
	* Groups where all mags == 0: ZERO passes. Skip entirely.
	* ============================================================ */
	static void pmv(const PL L, const float x, float *y) {
	const int od = L->out_dim, id = L->in_dim;
	const int chunks = (id + 63) / 64;
	const int id16 = (id + 15) & ~15;

	float xp = (float)aligned_alloc(64, id16 * sizeof(float));
	memcpy(xp, x, id * sizeof(float));
	if (id16 > id) memset(xp + id, 0, (id16 - id) * sizeof(float));

	#pragma omp parallel for schedule(dynamic, 64)
	for (int i = 0; i < od; i++) {
	const uint8_t row_mag = L->mags + (size_t)i id;
	const uint64_t row_sign = L->sign_bits + (size_t)i chunks;
	const int rmax = L->row_maxmag[i];

	__m512 acc = _mm512_setzero_ps();

	for (int j = 0; j < id; j += 16) {
	if (j >= id16) break;

	/* Load 16 magnitudes */
	__m128i mv = _mm_loadu_si128((__m128i*)(row_mag + j));

	/* Quick check: if all 16 mags are zero, skip entirely */
	if (_mm_testz_si128(mv, mv)) continue;

	__m512 xv = _mm512_load_ps(xp + j);

	/* Extract 16 sign bits from bitpacked array */
	int chunk_idx = j / 64;
	int bit_off = j % 64;
	uint64_t sbits = row_sign[chunk_idx];
	uint16_t signs = (uint16_t)((sbits >> bit_off) & 0xFFFF);

	/* Find max magnitude in this group of 16 */
	/* Use SSE horizontal max */
	__m128i mx = mv;
	mx = _mm_max_epu8(mx, _mm_srli_si128(mx, 8));
	mx = _mm_max_epu8(mx, _mm_srli_si128(mx, 4));
	mx = _mm_max_epu8(mx, _mm_srli_si128(mx, 2));
	mx = _mm_max_epu8(mx, _mm_srli_si128(mx, 1));
	int local_max = _mm_extract_epi8(mx, 0);

	/* Threshold vector for comparisons */
	for (int m = 1; m <= local_max; m++) {
	/* mask = (mag >= m) */
	__m128i thresh = _mm_set1_epi8((char)m);
	/* Compare: result is 0xFF where mag >= m, 0 otherwise */
	/* SSE doesn't have >= for uint8, use: NOT(max(thresh, mag) == thresh XOR mag == thresh) */
	/* Simpler: mag >= m iff mag - m doesn't underflow, i.e. saturating sub == 0 is false */
	/* Or: max(mag, thresh) == mag means mag >= thresh */
	__m128i cmp = _mm_cmpeq_epi8(_mm_max_epu8(mv, thresh), mv);
	uint16_t active = (uint16_t)_mm_movemask_epi8(cmp);

	__mmask16 pos = (__mmask16)(active & ~signs);
	__mmask16 neg = (__mmask16)(active & signs);

	acc = _mm512_mask_add_ps(acc, pos, acc, xv);
	acc = _mm512_mask_sub_ps(acc, neg, acc, xv);
	}
	}

	y[i] = _mm512_reduce_add_ps(acc) * L->scales[i];
	if (L->bias) y[i] += L->bias[i];
	}
	free(xp);
	}

	/* FP16 matvec for lm_head */
	static void fmv(const FL L, const float x, float *y) {
	#pragma omp parallel for schedule(dynamic, 256)
	for (int i = 0; i < L->od; i++) {
	__m512 acc = _mm512_setzero_ps();
	const uint16_t row = L->w + (size_t)i L->id;
	int j;
	for (j = 0; j + 16 <= L->id; j += 16) {
	__m256i h = _mm256_loadu_si256((__m256i*)(row + j));
	acc = _mm512_fmadd_ps(_mm512_cvtph_ps(h), _mm512_loadu_ps(x + j), acc);
	}
	float s = _mm512_reduce_add_ps(acc);
	for (; j < L->id; j++) {
	float wf; _mm_store_ss(&wf, _mm_cvtph_ps(_mm_set1_epi16(row[j])));
	s += wf * x[j];
	}
	y[i] = s;
	}
	}

	/* RMSNorm */
	static void rn(const float x, const float w, float *y, int d) {
	__m512 sq = _mm512_setzero_ps();
	int i;
	for (i = 0; i+16 <= d; i += 16) {
	__m512 v = _mm512_loadu_ps(x+i);
	sq = _mm512_fmadd_ps(v, v, sq);
	}
	float ss = _mm512_reduce_add_ps(sq);
	for (; i < d; i++) ss += x[i]*x[i];
	float r = 1.0f / sqrtf(ss/d + RMS_EPS);
	__m512 rv = _mm512_set1_ps(r);
	for (i = 0; i+16 <= d; i += 16)
	_mm512_storeu_ps(y+i, _mm512_mul_ps(_mm512_mul_ps(
	_mm512_loadu_ps(x+i), rv), _mm512_loadu_ps(w+i)));
	for (; i < d; i++) y[i] = x[i]rw[i];
	}

	static void silu(float *x, int n) {
	for (int i = 0; i < n; i++) x[i] /= (1.0f + expf(-x[i]));
	}
	static void emul(const float a, const float b, float *c, int n) {
	int i;
	for (i = 0; i+16 <= n; i += 16)
	_mm512_storeu_ps(c+i, _mm512_mul_ps(_mm512_loadu_ps(a+i), _mm512_loadu_ps(b+i)));
	for (; i < n; i++) c[i] = a[i]*b[i];
	}
	static void va(float y, const float x, int n) {
	int i;
	for (i = 0; i+16 <= n; i += 16)
	_mm512_storeu_ps(y+i, _mm512_add_ps(_mm512_loadu_ps(y+i), _mm512_loadu_ps(x+i)));
	for (; i < n; i++) y[i] += x[i];
	}
	static void rope(float *v, int pos, int d) {
	for (int i = 0; i < d; i += 2) {
	float f = 1.0f / powf(ROPE_THETA, (float)i/d);
	float a = pos*f, co = cosf(a), si = sinf(a);
	float v0 = v[i], v1 = v[i+1];
	v[i] = v0co - v1si; v[i+1] = v0si + v1co;
	}
	}
	static void sm(float *x, int n) {
	float mx = x[0];
	for (int i = 1; i < n; i++) if (x[i] > mx) mx = x[i];
	float s = 0;
	for (int i = 0; i < n; i++) { x[i] = expf(x[i]-mx); s += x[i]; }
	float iv = 1.0f/s;
	for (int i = 0; i < n; i++) x[i] *= iv;
	}
	static void etok(const M m, int t, float o) {
	const uint16_t r = m->emb + (size_t)t HIDDEN;
	int i;
	for (i = 0; i+16 <= HIDDEN; i += 16)
	_mm512_storeu_ps(o+i, _mm512_cvtph_ps(_mm256_loadu_si256((__m256i*)(r+i))));
	for (; i < HIDDEN; i++) _mm_store_ss(o+i, _mm_cvtph_ps(_mm_set1_epi16(r[i])));
	}
	static float* kvp(float *c, int l, int p, int h) {
	return c + ((size_t)lMAX_SEQN_KV_HEADS + (size_t)pN_KV_HEADS + h)HEAD_DIM;
	}

	static void do_attn(M *m, int l, int pos) {
	Lay *ly = &m->lay[l];
	pmv(&ly->qp, m->h2, m->sq);
	pmv(&ly->kp, m->h2, m->sk);
	pmv(&ly->vp, m->h2, m->sv);
	if (ly->qb) va(m->sq, ly->qb, N_HEADS*HEAD_DIM);
	if (ly->kb) va(m->sk, ly->kb, N_KV_HEADS*HEAD_DIM);
	if (ly->vb) va(m->sv, ly->vb, N_KV_HEADS*HEAD_DIM);
	for (int h = 0; h < N_HEADS; h++) rope(m->sq + h*HEAD_DIM, pos, HEAD_DIM);
	for (int h = 0; h < N_KV_HEADS; h++) rope(m->sk + h*HEAD_DIM, pos, HEAD_DIM);
	for (int h = 0; h < N_KV_HEADS; h++) {
	memcpy(kvp(m->kc,l,pos,h), m->sk+hHEAD_DIM, HEAD_DIM4);
	memcpy(kvp(m->vc,l,pos,h), m->sv+hHEAD_DIM, HEAD_DIM4);
	}
	float sc = 1.0f/sqrtf((float)HEAD_DIM);
	memset(m->ao, 0, N_HEADSHEAD_DIM4);
	for (int h = 0; h < N_HEADS; h++) {
	int kvh = h / GQA_RATIO;
	float qh = m->sq + hHEAD_DIM, oh = m->ao + hHEAD_DIM;
	for (int t = 0; t <= pos; t++) {
	float *kk = kvp(m->kc,l,t,kvh);
	__m512 a = _mm512_setzero_ps();
	int d;
	for (d = 0; d+16 <= HEAD_DIM; d += 16)
	a = _mm512_fmadd_ps(_mm512_loadu_ps(qh+d), _mm512_loadu_ps(kk+d), a);
	float dot = _mm512_reduce_add_ps(a);
	for (; d < HEAD_DIM; d++) dot += qh[d]*kk[d];
	m->as[t] = dot * sc;
	}
	sm(m->as, pos+1);
	for (int t = 0; t <= pos; t++) {
	float w = m->as[t];
	if (w < 1e-8f) continue;
	float *vv = kvp(m->vc,l,t,kvh);
	__m512 wv = _mm512_set1_ps(w);
	int d;
	for (d = 0; d+16 <= HEAD_DIM; d += 16)
	_mm512_storeu_ps(oh+d, _mm512_fmadd_ps(wv, _mm512_loadu_ps(vv+d), _mm512_loadu_ps(oh+d)));
	for (; d < HEAD_DIM; d++) oh[d] += w*vv[d];
	}
	}
	pmv(&ly->op, m->ao, m->h2);
	}

	static void do_mlp(M *m, int l) {
	Lay *ly = &m->lay[l];
	pmv(&ly->gp, m->h2, m->sg);
	pmv(&ly->up, m->h2, m->su);
	silu(m->sg, INTER);
	emul(m->sg, m->su, m->sd, INTER);
	pmv(&ly->dp, m->sd, m->h2);
	}

	float* forward_token(M *m, int tid, int pos) {
	etok(m, tid, m->h);
	for (int l = 0; l < N_LAYERS; l++) {
	rn(m->h, m->lay[l].in_norm, m->h2, HIDDEN);
	do_attn(m, l, pos);
	va(m->h, m->h2, HIDDEN);
	rn(m->h, m->lay[l].pn_norm, m->h2, HIDDEN);
	do_mlp(m, l);
	va(m->h, m->h2, HIDDEN);
	}
	rn(m->h, m->fnorm, m->h2, HIDDEN);
	fmv(&m->lmh, m->h2, m->lg);
	return m->lg;
	}

	static int samp(float *lg, int V, float T, float tp) {
	if (T > 0) { float it = 1.0f/T; for (int i = 0; i < V; i++) lg[i] *= it; }
	sm(lg, V);
	float pr = (float)malloc(V4); int ix = (int)malloc(V4);
	memcpy(pr, lg, V*4);
	for (int i = 0; i < V; i++) ix[i] = i;
	float cum = 0; int nk = 0;
	while (cum < tp && nk < V && nk < 50) {
	int b = nk;
	for (int i = nk+1; i < V; i++) if (pr[i] > pr[b]) b = i;
	float t = pr[nk]; pr[nk] = pr[b]; pr[b] = t;
	int ti = ix[nk]; ix[nk] = ix[b]; ix[b] = ti;
	cum += pr[nk]; nk++;
	}
	float s = 0; for (int i = 0; i < nk; i++) s += pr[i];
	float r = (float)rand()/RAND_MAX * s, ac = 0;
	int ch = ix[0];
	for (int i = 0; i < nk; i++) { ac += pr[i]; if (ac >= r) { ch = ix[i]; break; } }
	free(pr); free(ix);
	return ch;
	}

	int generate(M m, const int pr, int pl, int *out, int mx,
	float T, float tp, int eos) {
	srand(time(NULL));
	for (int i = 0; i < pl; i++) forward_token(m, pr[i], i);
	int pos = pl, gen = 0;
	for (int t = 0; t < mx; t++) {
	int nx;
	if (T <= 0) {
	nx = 0;
	for (int i = 1; i < VOCAB; i++) if (m->lg[i] > m->lg[nx]) nx = i;
	} else {
	nx = samp(m->lg, VOCAB, T, tp);
	}
	out[t] = nx; gen++;
	if (nx == eos) break;
	forward_token(m, nx, pos); pos++;
	}
	return gen;
	}

	M* model_alloc(void) {
	M m = (M)calloc(1, sizeof(M));
	size_t kv = (size_t)N_LAYERSMAX_SEQN_KV_HEADS*HEAD_DIM;
	m->kc = (float)calloc(kv,4); m->vc = (float)calloc(kv,4);
	m->h = (float)aligned_alloc(64,HIDDEN4);
	m->h2 = (float)aligned_alloc(64,HIDDEN4);
	m->sq = (float)aligned_alloc(64,N_HEADSHEAD_DIM*4);
	m->sk = (float)aligned_alloc(64,N_KV_HEADSHEAD_DIM*4);
	m->sv = (float)aligned_alloc(64,N_KV_HEADSHEAD_DIM*4);
	m->ao = (float)aligned_alloc(64,N_HEADSHEAD_DIM*4);
	m->sg = (float)aligned_alloc(64,INTER4);
	m->su = (float)aligned_alloc(64,INTER4);
	m->sd = (float)aligned_alloc(64,INTER4);
	m->lg = (float)aligned_alloc(64,VOCAB4);
	m->as = (float)aligned_alloc(64,MAX_SEQ4);
	m->fnorm = (float)aligned_alloc(64,HIDDEN4);
	printf("Alloc: KV=%zuMB\n", kv24/1024/1024);
	return m;
	}

	void model_set_embed(M m, uint16_t d) { m->emb = d; }
	void model_set_final_norm(M m, float d) { memcpy(m->fnorm, d, HIDDEN*4); }
	void model_set_lm_head(M m, uint16_t d, int o, int i) {
	m->lmh.w = d; m->lmh.od = o; m->lmh.id = i;
	}
	void layer_set_norms(M m, int l, float i, float *p) {
	m->lay[l].in_norm = i; m->lay[l].pn_norm = p;
	}
	void layer_set_bias(M m, int l, float q, float k, float v) {
	m->lay[l].qb = q; m->lay[l].kb = k; m->lay[l].vb = v;
	}
	void set_pl(PL p, uint8_t mags, uint64_t signs, float scales,
	uint8_t *rmm, int od, int id) {
	p->mags = mags; p->sign_bits = signs; p->scales = scales;
	p->row_maxmag = rmm; p->out_dim = od; p->in_dim = id; p->bias = NULL;
	}
	void layer_set_linears(M *m, int l,
	uint8_tqm,uint64_tqs,floatqc,uint8_tqx,int qo,int qi,
	uint8_tkm,uint64_tks,floatkc,uint8_tkx,int ko,int ki,
	uint8_tvm,uint64_tvs,floatvc,uint8_tvx,int vo,int vi,
	uint8_tom,uint64_tos_,floatoc,uint8_tox,int oo,int oi,
	uint8_tgm,uint64_tgs,floatgc,uint8_tgx,int go,int gi,
	uint8_tum,uint64_tus,floatuc,uint8_tux,int uo,int ui,
	uint8_tdm,uint64_tds,floatdc,uint8_tdx,int doo,int di) {
	set_pl(&m->lay[l].qp,qm,qs,qc,qx,qo,qi);
	set_pl(&m->lay[l].kp,km,ks,kc,kx,ko,ki);
	set_pl(&m->lay[l].vp,vm,vs,vc,vx,vo,vi);
	set_pl(&m->lay[l].op,om,os_,oc,ox,oo,oi);
	set_pl(&m->lay[l].gp,gm,gs,gc,gx,go,gi);
	set_pl(&m->lay[l].up,um,us,uc,ux,uo,ui);
	set_pl(&m->lay[l].dp,dm,ds,dc,dx,doo,di);
	}
	void model_reset_cache(M *m) {
	size_t kv=(size_t)N_LAYERSMAX_SEQN_KV_HEADS*HEAD_DIM;
	memset(m->kc,0,kv4); memset(m->vc,0,kv4);
	}
	void model_free(M *m) {
	free(m->kc);free(m->vc);free(m->h);free(m->h2);
	free(m->sq);free(m->sk);free(m->sv);free(m->ao);
	free(m->sg);free(m->su);free(m->sd);
	free(m->lg);free(m->as);free(m->fnorm);free(m);
	}