/* Motore GLM-5.2 (architettura glm_moe_dsa) in C puro. * Stadio B: replica fedele del forward di transformers (modeling_glm_moe_dsa.py): * - attenzione MLA (q/kv-LoRA, RoPE interleaved parziale) * - router sigmoid + noaux_tc (n_group=1) con routed_scaling_factor * - shared expert + expert routed in streaming dal disco (per-expert) * - primi first_k_dense_replace layer densi * Il DSA indexer e' un NO-OP per seq <= index_topk (seleziona tutte le key): qui si usa * attenzione causale densa -> output identico all'oracolo su prompt corti. * * QUANTIZZAZIONE: gli expert (streaming) e la parte DENSA residente (attenzione, lm_head, * embed, mlp densa, shared expert) sono tenuti in int8 per-riga + scala (dequant-on-use). * E' cio' che fa entrare GLM-5.2 nei 15 GB: ~17B param residenti a int4 ~= 8.7 GB. * Norme/router/bias restano f32 (piccoli e sensibili). * * Validazione: stessi token id di ref_glm.json (oracolo transformers, c/tools/make_glm_oracle.py). * build: make glm run: SNAP=./glm_tiny ./glm * TF=1 -> teacher-forcing (valida il prefill su tutta la sequenza) */ #define _GNU_SOURCE #include #include #include #include #include #include #include /* thread I/O del PILOTA */ #include /* PIPE ready-flags/job queue + PILOT_REAL cross-layer handshake */ #include /* sched_yield: PIPE spin / PILOT barrier */ #include #include #if defined(__APPLE__) || defined(__linux__) #include #include /* mlock: inchioda le pagine in RAM / wire pages into RAM */ #include /* fstat per mmap degli shard (COLI_MMAP) */ #endif #include "st.h" #include "tok.h" #include "tier.h" #include "grammar.h" /* metodo F: draft grammaticali (#48) */ #include "decode_batch.h" #ifdef _OPENMP #include /* scratch per-thread nell'attention */ #else static inline int omp_get_max_threads(void){ return 1; } static inline int omp_get_thread_num(void){ return 0; } #endif #ifdef COLI_CUDA #include "backend_cuda.h" #endif #ifdef COLI_METAL #include "backend_metal.h" #include static int g_metal_enabled; static int g_metal_gemm_min=16; /* COLI_METAL_GEMM_MIN: min rows to send a matmul_qt GEMM to GPU */ /* routing precalcolata dalla GPU (layer CB): moe() la usa e salta la FASE A */ static const int *g_pre_idx; static const float *g_pre_w; static const int *g_pre_keff; static const float *g_pre_sh; /* output dello shared expert gia' calcolato su GPU */ #endif #ifdef __AVX2__ #include static inline float hsum256(__m256 v){ /* somma orizzontale di 8 float */ __m128 lo=_mm256_castps256_ps128(v), hi=_mm256_extractf128_ps(v,1); lo=_mm_add_ps(lo,hi); __m128 sh=_mm_movehl_ps(lo,lo); lo=_mm_add_ps(lo,sh); sh=_mm_shuffle_ps(lo,lo,1); lo=_mm_add_ss(lo,sh); return _mm_cvtss_f32(lo); } #elif defined(__ARM_NEON) #include /* Apple Silicon / aarch64: kernel NEON */ #elif defined(__VSX__) #include /* POWER8+ (ppc64le): kernel VSX */ #undef vector /* igiene: si usano __vector/__bool espliciti */ #undef pixel #undef bool #endif #ifdef __APPLE__ #include /* host_statistics64: MemAvailable di macOS */ #endif typedef struct { int hidden, n_layers, n_heads, n_experts, topk, moe_inter, dense_inter; int first_dense, q_lora, kv_lora, qk_nope, qk_rope, qk_head, v_head, n_shared, vocab; int n_group, topk_group, norm_topk; int stop_ids[8], n_stop; /* eos_token_id dal config (GLM-5.2 ne ha 3!) */ int index_topk, index_nh, index_hd; /* DSA lightning indexer */ int8_t idx_type[128]; /* per layer: 1=full (calcola), 0=shared (riusa) */ float eps, theta, attn_scale, routed_scale; } Cfg; /* tensore [O,I] in uno di tre formati: * fmt=0 F32 -> qf * fmt=1 INT8 -> q8 (1 byte/param) + scala per riga * fmt=2 INT4 -> q4 (2 valori per byte, impacchettati) + scala per riga * INT4 e' cio' che fa stare la densa residente nei 15 GB (0.5 byte/param). */ /* fmt: 0 F32, 1 INT8, 2 INT4 (2/byte), 3 INT2 (4/byte). q4 ospita sia int4 che int2 packed. */ typedef struct { int fmt; float *qf; int8_t *q8; uint8_t *q4; float *s; int O, I; #ifdef COLI_CUDA ColiCudaTensor *cuda; #endif int cuda_eligible, cuda_failed, cuda_device; /* resident tensor, never a reused expert slot */ } QT; static int64_t qt_bytes(const QT *t){ /* byte residenti del tensore */ int64_t n=(int64_t)t->O*t->I; if(t->fmt==0) return n*4; if(t->fmt==1) return n + (int64_t)t->O*4; if(t->fmt==3) return (int64_t)t->O*((t->I+3)/4) + (int64_t)t->O*4; return (int64_t)t->O*((t->I+1)/2) + (int64_t)t->O*4; } typedef struct { float *in_ln, *post_ln; /* MLA (densa, quantizzata) */ QT q_a, q_b, kv_a, kv_b, o; float *q_a_ln, *kv_a_ln; int sparse; /* dense mlp (sparse==0) */ QT gate_proj, up_proj, down_proj; /* moe (sparse==1) */ float *router, *router_bias; /* router f32 (sensibile) */ QT sh_gate, sh_up, sh_down; /* shared expert */ } Layer; /* slot di un expert: pesi quantizzati + scale. Nel container pre-quantizzato g/u/d sono * VISTE dentro `slab` (una sola pread coalescente); nel fallback hanno buffer propri. * slab_cap/fslab_cap: capienza allocata — gli slot ws[] sono riusati TRA layer e gli * expert non hanno tutti la stessa taglia (layer MTP int8 = 2x i layer int4). */ typedef struct { int eid; QT g,u,d; uint8_t *slab; float *fslab; int64_t slab_cap, fslab_cap; uint64_t used; } ESlot; typedef struct { float **Lc, **Rc, **Ic; int *kv_start, max_t; int disk_nrec; char disk_path[2048]; } KVState; typedef struct { KVState *kv; int token, pos; } DecodeRow; typedef struct { Cfg c; shards S; int ebits, dbits; /* bit expert / bit densa */ QT embed, lm_head; float *final_norm; Layer *L; /* KV-cache MLA COMPRESSA: per token si tiene solo il latente normato [kv_lora] e * k_rot [qk_rope] (576 vs 32768 valori/token). k_nope e value si ricostruiscono al * volo con kv_b. E' cio' che rende gestibile il contesto su 15 GB (64 teste, no GQA). */ float **Lc, **Rc; int max_t; /* alias della KVState attiva */ int *kv_start; /* prima pos valida nella KV del layer (MTP: parziale) */ KVState *kv; ESlot **ecache; int *ecn; int ecap; /* LRU expert per-layer */ ESlot ws[64]; /* working set del layer corrente (load paralleli) */ ESlot **pin; int *npin; /* HOT-STORE: expert pinnati in RAM (mai evicted) */ uint32_t **eusage; /* contatori persistenti (per STATS/PIN) */ uint32_t **eheat; /* calore recente per promotion/demotion live */ uint32_t **elast, eaccess_clock; /* recency per LFRU session-local */ /* DSA lightning indexer (attivo solo se i pesi out-idx-* sono presenti) */ int has_dsa; QT *ix_wq, *ix_wk, *ix_wp; /* per layer FULL: wq_b, wk, weights_proj */ float **ix_knw, **ix_knb; /* k_norm (LayerNorm, eps 1e-6) */ float **Ic; /* alias KVState: cache indexer [max_t*hd] */ int *dsa_sel, *dsa_nsel; int dsa_scap; /* selezione per posizione del batch corrente */ /* testa MTP (layer n_layers, stile DeepSeek-V3): draft nativi ad alta acceptance */ int has_mtp; Layer mtpL; QT eh_proj; float *enorm, *hnorm, *mtp_norm; float *hlast, *h_all; /* hidden pre-norm: ultima pos / tutte le pos batch */ uint64_t mtp_prop, mtp_acc; /* statistica acceptance */ int **eroute; int *enr; /* metodo C: routing dell'ULTIMO token per layer */ uint64_t eclock, hits, miss, ereq; uint64_t gpu_expert_calls; int gpu_expert_count; int64_t gpu_expert_bytes; uint64_t n_fw, n_emit; /* metodo E: forward di decode / token emessi */ double t_edisk, t_ewait, t_emm, t_attn, t_kvb, t_head;/* profiling: dove va il tempo */ double t_aproj,t_acore,t_aout; /* attention breakdown */ int64_t resident_bytes; } Model; static void usage_save(Model *m); /* cache che impara: definita accanto a stats_dump */ #ifdef COLI_CUDA static int g_cuda_enabled; static double g_cuda_expert_gb; static int g_cuda_dense; static int g_cuda_release_host; static int g_cuda_devices[COLI_CUDA_MAX_DEVICES], g_cuda_ndev, g_cuda_rr; static int64_t g_cuda_dense_projected[COLI_CUDA_MAX_DEVICES]; static void qt_cuda_reset(QT *t){ if(t->cuda){ coli_cuda_tensor_free(t->cuda); t->cuda=NULL; } t->cuda_failed=0; } static int qt_cuda_upload(QT *t){ const void *weights = t->fmt==0 ? (const void*)t->qf : t->fmt==1 ? (const void*)t->q8 : (const void*)t->q4; return coli_cuda_tensor_upload(&t->cuda,weights,t->s,t->fmt,t->I,t->O,t->cuda_device); } static void cuda_stats_print(void){ size_t n=0,b=0; coli_cuda_stats(-1,&n,&b); fprintf(stderr,"[CUDA] resident set: %zu tensors, %.2f GB VRAM\n",n,b/1e9); if(g_cuda_ndev>1) for(int i=0;iINT_MAX||n>=COLI_CUDA_MAX_DEVICES) return 0; for(int i=0;i SIZE_MAX/sizeof(float)){ fprintf(stderr,"falloc: n=%lld is out of range\n",(long long)n); exit(1); } float *p=malloc((size_t)n*sizeof(float)); if(!p){fprintf(stderr,"OOM\n");exit(1);} return p; } /* y[S,O] = x[S,I] @ W^T, W[O,I] f32 */ static void matmul(float *y, const float *x, const float *W, int S, int I, int O){ #pragma omp parallel for schedule(static) for (int o=0;o>1))); /* 8 byte=16 nibble */ __m128i lo=_mm_and_si128(by,m4), hi=_mm_and_si128(_mm_srli_epi16(by,4),m4); __m128i nib=_mm_unpacklo_epi8(lo,hi); /* nibble in ordine */ __m256 w0=_mm256_cvtepi32_ps(_mm256_sub_epi32(_mm256_cvtepu8_epi32(nib),b8)); __m256 w1=_mm256_cvtepi32_ps(_mm256_sub_epi32(_mm256_cvtepu8_epi32(_mm_srli_si128(nib,8)),b8)); acc=_mm256_fmadd_ps(_mm256_loadu_ps(xs+i), w0, acc); acc=_mm256_fmadd_ps(_mm256_loadu_ps(xs+i+8), w1, acc); } a=hsum256(acc); #elif defined(__ARM_NEON) const uint8x8_t m4=vdup_n_u8(0x0F); const int8x8_t b8=vdup_n_s8(8); float32x4_t ac0=vdupq_n_f32(0), ac1=vdupq_n_f32(0); for(;i+16<=I;i+=16){ uint8x8_t by=vld1_u8(w+(i>>1)); /* 8 byte=16 nibble */ uint8x8x2_t z=vzip_u8(vand_u8(by,m4), vshr_n_u8(by,4)); /* nibble in ordine */ int16x8_t w0=vmovl_s8(vsub_s8(vreinterpret_s8_u8(z.val[0]),b8)); int16x8_t w1=vmovl_s8(vsub_s8(vreinterpret_s8_u8(z.val[1]),b8)); ac0=vfmaq_f32(ac0, vld1q_f32(xs+i), vcvtq_f32_s32(vmovl_s16(vget_low_s16(w0)))); ac1=vfmaq_f32(ac1, vld1q_f32(xs+i+4), vcvtq_f32_s32(vmovl_s16(vget_high_s16(w0)))); ac0=vfmaq_f32(ac0, vld1q_f32(xs+i+8), vcvtq_f32_s32(vmovl_s16(vget_low_s16(w1)))); ac1=vfmaq_f32(ac1, vld1q_f32(xs+i+12), vcvtq_f32_s32(vmovl_s16(vget_high_s16(w1)))); } a=vaddvq_f32(vaddq_f32(ac0,ac1)); #endif for(;i+1>1]; int lo=(int)(byte&0xF)-8, hi=(int)(byte>>4)-8; a += xs[i]*(float)lo + xs[i+1]*(float)hi; } if(i>1]; int lo=(int)(byte&0xF)-8; a += xs[i]*(float)lo; } y[(int64_t)s*O+o]=a*sc; } } } /* Decode hot path for gate+up: same exact q4 dot products as matmul_i4, but one * OpenMP dispatch covers both matrices. KTransformers uses persistent pools; * this keeps colibri dependency-free while removing one team launch/expert. */ static void matmul_i4_pair(float *yg, float *yu, const float *x, const uint8_t *qg, const float *sg, const uint8_t *qu, const float *su, int I, int O){ int rb=(I+1)/2; #pragma omp parallel for schedule(static) for(int z=0;z<2*O;z++){ int o=z>1))); __m128i lo=_mm_and_si128(by,m4),hi=_mm_and_si128(_mm_srli_epi16(by,4),m4); __m128i nib=_mm_unpacklo_epi8(lo,hi); __m256 w0=_mm256_cvtepi32_ps(_mm256_sub_epi32(_mm256_cvtepu8_epi32(nib),b8)); __m256 w1=_mm256_cvtepi32_ps(_mm256_sub_epi32(_mm256_cvtepu8_epi32(_mm_srli_si128(nib,8)),b8)); acc=_mm256_fmadd_ps(_mm256_loadu_ps(x+i),w0,acc); acc=_mm256_fmadd_ps(_mm256_loadu_ps(x+i+8),w1,acc); } a=hsum256(acc); #elif defined(__ARM_NEON) const uint8x8_t m4=vdup_n_u8(0x0F); const int8x8_t b8=vdup_n_s8(8); float32x4_t ac0=vdupq_n_f32(0),ac1=vdupq_n_f32(0); for(;i+16<=I;i+=16){ uint8x8_t by=vld1_u8(w+(i>>1)); uint8x8x2_t n=vzip_u8(vand_u8(by,m4),vshr_n_u8(by,4)); int16x8_t w0=vmovl_s8(vsub_s8(vreinterpret_s8_u8(n.val[0]),b8)); int16x8_t w1=vmovl_s8(vsub_s8(vreinterpret_s8_u8(n.val[1]),b8)); ac0=vfmaq_f32(ac0,vld1q_f32(x+i),vcvtq_f32_s32(vmovl_s16(vget_low_s16(w0)))); ac1=vfmaq_f32(ac1,vld1q_f32(x+i+4),vcvtq_f32_s32(vmovl_s16(vget_high_s16(w0)))); ac0=vfmaq_f32(ac0,vld1q_f32(x+i+8),vcvtq_f32_s32(vmovl_s16(vget_low_s16(w1)))); ac1=vfmaq_f32(ac1,vld1q_f32(x+i+12),vcvtq_f32_s32(vmovl_s16(vget_high_s16(w1)))); } a=vaddvq_f32(vaddq_f32(ac0,ac1)); #endif for(;i+1>1]; a+=x[i]*(float)((b&15)-8)+x[i+1]*(float)((b>>4)-8); } if(i>1]&15)-8); (zfmt==2&&wu->fmt==2&&wg->I==wu->I&&wg->O==wu->O) matmul_i4_pair(g,u,x,wg->q4,wg->s,wu->q4,wu->s,wg->I,wg->O); else { matmul_qt(g,x,wg,S); matmul_qt(u,x,wu,S); } } /* y[S,O] = x[S,I] @ W^T con W int2 impacchettato (4 valori/byte) + scala[O]. nibble 2-bit -> [-2,1]. */ static void matmul_i2(float *y, const float *x, const uint8_t *q2, const float *scale, int S, int I, int O){ int rb=(I+3)/4; #pragma omp parallel for schedule(static) for (int o=0;o>2))); /* 4 byte=16 valori */ __m128i p0=_mm_and_si128(by,m2), p1=_mm_and_si128(_mm_srli_epi16(by,2),m2); __m128i p2=_mm_and_si128(_mm_srli_epi16(by,4),m2), p3=_mm_and_si128(_mm_srli_epi16(by,6),m2); __m128i lo=_mm_unpacklo_epi8(p0,p1), hi=_mm_unpacklo_epi8(p2,p3); __m128i nib=_mm_unpacklo_epi16(lo,hi); /* 16 valori in ordine */ __m256 w0=_mm256_cvtepi32_ps(_mm256_sub_epi32(_mm256_cvtepu8_epi32(nib),b2)); __m256 w1=_mm256_cvtepi32_ps(_mm256_sub_epi32(_mm256_cvtepu8_epi32(_mm_srli_si128(nib,8)),b2)); acc=_mm256_fmadd_ps(_mm256_loadu_ps(xs+i), w0, acc); acc=_mm256_fmadd_ps(_mm256_loadu_ps(xs+i+8), w1, acc); } a=hsum256(acc); #elif defined(__ARM_NEON) const uint8x8_t m2v=vdup_n_u8(3); const int8x8_t b2v=vdup_n_s8(2); float32x4_t ac0=vdupq_n_f32(0), ac1=vdupq_n_f32(0); for(;i+16<=I;i+=16){ uint32_t wd; memcpy(&wd, w+(i>>2), 4); /* 4 byte=16 valori */ uint8x8_t by=vreinterpret_u8_u32(vdup_n_u32(wd)); uint8x8x2_t z01=vzip_u8(vand_u8(by,m2v), vand_u8(vshr_n_u8(by,2),m2v)); uint8x8x2_t z23=vzip_u8(vand_u8(vshr_n_u8(by,4),m2v), vshr_n_u8(by,6)); uint16x4x2_t zz=vzip_u16(vreinterpret_u16_u8(z01.val[0]), vreinterpret_u16_u8(z23.val[0])); int16x8_t w0=vmovl_s8(vsub_s8(vreinterpret_s8_u16(zz.val[0]),b2v)); /* 16 valori in ordine */ int16x8_t w1=vmovl_s8(vsub_s8(vreinterpret_s8_u16(zz.val[1]),b2v)); ac0=vfmaq_f32(ac0, vld1q_f32(xs+i), vcvtq_f32_s32(vmovl_s16(vget_low_s16(w0)))); ac1=vfmaq_f32(ac1, vld1q_f32(xs+i+4), vcvtq_f32_s32(vmovl_s16(vget_high_s16(w0)))); ac0=vfmaq_f32(ac0, vld1q_f32(xs+i+8), vcvtq_f32_s32(vmovl_s16(vget_low_s16(w1)))); ac1=vfmaq_f32(ac1, vld1q_f32(xs+i+12), vcvtq_f32_s32(vmovl_s16(vget_high_s16(w1)))); } a=vaddvq_f32(vaddq_f32(ac0,ac1)); #endif for(;i>2]; int sh=(i&3)*2; a += xs[i]*(float)((int)((byte>>sh)&3)-2); } y[(int64_t)s*O+o]=a*sc; } } } /* ---- KERNEL INTERI (IDOT): attivazioni quantizzate a int8 per riga (absmax/127, * stile Q8_0), prodotto scalare INTERO via maddubs/madd AVX2 — niente conversione * f32 dei pesi nel ciclo caldo. ~2-3x sui matmul quantizzati; errore aggiunto ~0.3% * RMS per matmul (attivazione int8), IDOT=0 torna al percorso f32 esatto. */ #if defined(__AVX512VNNI__) && defined(__AVX512BW__) #define IDOT_KERNEL "avx512-vnni" #elif defined(__AVX2__) #define IDOT_KERNEL "avx2" #elif defined(__ARM_NEON) #define IDOT_KERNEL "neon" #elif defined(__VSX__) #define IDOT_KERNEL "vsx" #else #define IDOT_KERNEL "scalar" #endif static int g_idot=1; #if defined(__ARM_NEON) && defined(__ARM_FEATURE_DOTPROD) static int g_i4s=1; /* SDOT presente: int4 IDOT conviene anche a S=1 (decode). Misurato * su Apple M-series: +14%%, expert-matmul -16%%. EN: with SDOT, int4 * IDOT pays even at S=1 (decode); measured on Apple M-series. */ #elif defined(__VSX__) static int g_i4s=1; /* POWER8 vec_msum: qui il fallback f32 e' SCALARE, quindi l'IDOT * int4 conviene anche a S=1. Misurato su POWER8 S824 (vedi PR). * EN: on VSX the f32 fallback is plain scalar C, so int4 IDOT * pays even at S=1. Measured on a POWER8 S824 (see PR). */ #else static int g_i4s=2; /* senza SDOT / altrove: soglia originale (misura AVX2 dell'autore). * EN: without SDOT / elsewhere: original threshold (author's AVX2). */ #endif static inline float qrow_i8(const float *x, int8_t *q, int I){ float amax=0; for(int i=0;iamax)amax=a; } float s=amax/127.f; if(s<1e-12f) s=1e-12f; float inv=1.f/s; for(int i=0;i s32 directly, 64 bytes/iter, no 16-bit intermediate. * AVX-512 has no vpsignb: |w| via abs, sign folded into x with a mask-negate * (w==0 -> product 0 either way). |x|<=127 (qrow_i8), |w|<=128 as u8: each * s32 lane adds <= 4*128*127, safe up to I=16384 like the AVX2 bound. */ __m512i acc=_mm512_setzero_si512(); for(;i+64<=I;i+=64){ __m512i wv=_mm512_loadu_si512((const void*)(w+i)); __m512i xv=_mm512_loadu_si512((const void*)(x+i)); __mmask64 neg=_mm512_movepi8_mask(wv); __m512i xs=_mm512_mask_sub_epi8(xv,neg,_mm512_setzero_si512(),xv); acc=_mm512_dpbusd_epi32(acc,_mm512_abs_epi8(wv),xs); } sum=_mm512_reduce_add_epi32(acc); #elif defined(__AVX2__) __m256i acc=_mm256_setzero_si256(); const __m256i ones=_mm256_set1_epi16(1); for(;i+32<=I;i+=32){ __m256i wv=_mm256_loadu_si256((const __m256i*)(w+i)); __m256i xv=_mm256_loadu_si256((const __m256i*)(x+i)); __m256i p=_mm256_maddubs_epi16(_mm256_sign_epi8(wv,wv),_mm256_sign_epi8(xv,wv)); acc=_mm256_add_epi32(acc,_mm256_madd_epi16(p,ones)); } sum=hsum256_i32(acc); #elif defined(__ARM_NEON) /* ARM: SDOT nativo se disponibile (Apple Silicon: sempre); altrimenti vmull/vpadal. * Stesso bound anti-overflow del trucco AVX2: coppie <= 128*127*2 = 32512 < 32767. */ int32x4_t acc=vdupq_n_s32(0); for(;i+16<=I;i+=16){ int8x16_t wv=vld1q_s8(w+i), xv=vld1q_s8(x+i); #if defined(__ARM_FEATURE_DOTPROD) acc=vdotq_s32(acc,wv,xv); #else int16x8_t p=vmull_s8(vget_low_s8(wv),vget_low_s8(xv)); p=vmlal_s8(p,vget_high_s8(wv),vget_high_s8(xv)); acc=vpadalq_s16(acc,p); #endif } sum=vaddvq_s32(acc); #elif defined(__VSX__) /* POWER8: vec_msum (s8 x u8 -> s32) somma i prodotti byte DIRETTAMENTE in lane * s32, 16 byte/iter: il bound anti-saturazione a 16 bit di maddubs qui non serve. * Stesso trucco del segno (|w| u8 per x*sign(w) s8), ma |w| via select+sub MODULO * e non vec_abs: -128 deve diventare 128 u8, non saturare a 127. * EN: vec_msum accumulates byte products straight into s32 lanes; |w| is built * with a modulo subtract select instead of vec_abs so w=-128 wraps to 128 (u8) * rather than saturating to 127. |x|<=127 from qrow_i8, so x negation is safe. */ __vector signed int acc=vec_splats(0); const __vector signed char vz=vec_splats((signed char)0); for(;i+16<=I;i+=16){ __vector signed char wv=vec_xl(0,(const signed char*)(w+i)); __vector signed char xv=vec_xl(0,(const signed char*)(x+i)); __vector __bool char neg=vec_cmplt(wv,vz); __vector signed char xs=vec_sel(xv,vec_sub(vz,xv),neg); __vector unsigned char wa=(__vector unsigned char)vec_sel(wv,vec_sub(vz,wv),neg); acc=vec_msum(xs,wa,acc); } sum=vec_extract(acc,0)+vec_extract(acc,1)+vec_extract(acc,2)+vec_extract(acc,3); #endif for(;i int8 [-8,7] al volo, poi stesso trucco */ static inline int32_t dot_i4i8(const uint8_t *w4, const int8_t *x, int I){ int32_t sum=0; int i=0; #if defined(__AVX512VNNI__) && defined(__AVX512BW__) /* 32 bytes = 64 nibbles -> int8 in [-8,7], one vpdpbusd per 64 values. * 256-bit unpack leaves values in per-128-lane order [0-15][32-47]/[16-31][48-63]; * dot pairing is order-invariant, so permute x's 128-bit blocks to match * instead of re-ordering w (one vpermq per iter, off the critical unpack path). */ const __m256i m4v=_mm256_set1_epi8(0x0F); const __m512i b8v=_mm512_set1_epi8(8); const __m512i xidx=_mm512_setr_epi64(0,1,4,5,2,3,6,7); __m512i acc=_mm512_setzero_si512(); for(;i+64<=I;i+=64){ __m256i by=_mm256_loadu_si256((const __m256i*)(w4+(i>>1))); __m256i lo=_mm256_and_si256(by,m4v), hi=_mm256_and_si256(_mm256_srli_epi16(by,4),m4v); __m256i z0=_mm256_unpacklo_epi8(lo,hi), z1=_mm256_unpackhi_epi8(lo,hi); __m512i wv=_mm512_sub_epi8(_mm512_inserti64x4(_mm512_castsi256_si512(z0),z1,1),b8v); __m512i xv=_mm512_permutexvar_epi64(xidx,_mm512_loadu_si512((const void*)(x+i))); __mmask64 neg=_mm512_movepi8_mask(wv); __m512i xs=_mm512_mask_sub_epi8(xv,neg,_mm512_setzero_si512(),xv); acc=_mm512_dpbusd_epi32(acc,_mm512_abs_epi8(wv),xs); } sum=_mm512_reduce_add_epi32(acc); #elif defined(__AVX2__) const __m128i m4=_mm_set1_epi8(0x0F); const __m256i b8=_mm256_set1_epi8(8); const __m256i ones=_mm256_set1_epi16(1); __m256i acc=_mm256_setzero_si256(); for(;i+32<=I;i+=32){ __m128i by=_mm_loadu_si128((const __m128i*)(w4+(i>>1))); /* 16 byte = 32 nibble */ __m128i lo=_mm_and_si128(by,m4), hi=_mm_and_si128(_mm_srli_epi16(by,4),m4); __m128i n0=_mm_unpacklo_epi8(lo,hi), n1=_mm_unpackhi_epi8(lo,hi); /* in ordine */ __m256i wv=_mm256_sub_epi8(_mm256_set_m128i(n1,n0),b8); __m256i xv=_mm256_loadu_si256((const __m256i*)(x+i)); __m256i p=_mm256_maddubs_epi16(_mm256_sign_epi8(wv,wv),_mm256_sign_epi8(xv,wv)); acc=_mm256_add_epi32(acc,_mm256_madd_epi16(p,ones)); } sum=hsum256_i32(acc); #elif defined(__ARM_NEON) const uint8x16_t m4q=vdupq_n_u8(0x0F); const int8x16_t b8q=vdupq_n_s8(8); int32x4_t acc=vdupq_n_s32(0); for(;i+32<=I;i+=32){ uint8x16_t by=vld1q_u8(w4+(i>>1)); /* 16 byte = 32 nibble */ uint8x16x2_t z=vzipq_u8(vandq_u8(by,m4q), vshrq_n_u8(by,4)); /* nibble in ordine */ int8x16_t w0=vsubq_s8(vreinterpretq_s8_u8(z.val[0]),b8q); int8x16_t w1=vsubq_s8(vreinterpretq_s8_u8(z.val[1]),b8q); int8x16_t x0=vld1q_s8(x+i), x1=vld1q_s8(x+i+16); #if defined(__ARM_FEATURE_DOTPROD) acc=vdotq_s32(acc,w0,x0); acc=vdotq_s32(acc,w1,x1); #else int16x8_t p=vmull_s8(vget_low_s8(w0),vget_low_s8(x0)); /* |w|<=8: nessun overflow */ p=vmlal_s8(p,vget_high_s8(w0),vget_high_s8(x0)); acc=vpadalq_s16(acc,p); p=vmull_s8(vget_low_s8(w1),vget_low_s8(x1)); p=vmlal_s8(p,vget_high_s8(w1),vget_high_s8(x1)); acc=vpadalq_s16(acc,p); #endif } sum=vaddvq_s32(acc); #elif defined(__VSX__) /* 16 byte = 32 nibble. vec_mergeh/vec_mergel su ppc64le (GCC) interallacciano come * unpacklo/unpackhi x86 (verificato empiricamente su POWER8): i nibble escono in * ordine di memoria. |w|<=8 dopo il -8, quindi stesso trucco del segno di dot_i8i8. * EN: vec_mergeh/l on ppc64le interleave like x86 unpacklo/hi (verified on POWER8), * so nibbles come out in memory order; then the same sign trick as dot_i8i8. */ const __vector unsigned char m4v=vec_splats((unsigned char)0x0F); const __vector unsigned char sh4=vec_splats((unsigned char)4); const __vector signed char b8v=vec_splats((signed char)8); const __vector signed char vz=vec_splats((signed char)0); __vector signed int acc=vec_splats(0); for(;i+32<=I;i+=32){ __vector unsigned char by=vec_xl(0,w4+(i>>1)); /* 16 byte = 32 nibble */ __vector unsigned char lo=vec_and(by,m4v), hi=vec_sr(by,sh4); __vector signed char w0=vec_sub((__vector signed char)vec_mergeh(lo,hi),b8v); __vector signed char w1=vec_sub((__vector signed char)vec_mergel(lo,hi),b8v); __vector signed char x0=vec_xl(0,(const signed char*)(x+i)); __vector signed char x1=vec_xl(0,(const signed char*)(x+i+16)); __vector __bool char n0=vec_cmplt(w0,vz), n1=vec_cmplt(w1,vz); acc=vec_msum(vec_sel(x0,vec_sub(vz,x0),n0), (__vector unsigned char)vec_sel(w0,vec_sub(vz,w0),n0),acc); acc=vec_msum(vec_sel(x1,vec_sub(vz,x1),n1), (__vector unsigned char)vec_sel(w1,vec_sub(vz,w1),n1),acc); } sum=vec_extract(acc,0)+vec_extract(acc,1)+vec_extract(acc,2)+vec_extract(acc,3); #endif for(;i+1>1]; sum+=((int)(b&0xF)-8)*x[i]+((int)(b>>4)-8)*x[i+1]; } if(i>1]; sum+=((int)(b&0xF)-8)*x[i]; } return sum; } static void matmul_q_idot(float *y, const int8_t *xq, const float *sx, const int8_t *q, const float *scale, int S, int I, int O){ #pragma omp parallel for schedule(static) for(int o=0;og_qscratch.xq_cap){ int8_t *p=realloc(g_qscratch.xq,xn); if(!p){ fprintf(stderr,"OOM quant scratch\n"); exit(1); } g_qscratch.xq=p; g_qscratch.xq_cap=xn; } if(sn>g_qscratch.sx_cap){ float *p=realloc(g_qscratch.sx,sn*sizeof(float)); if(!p){ fprintf(stderr,"OOM quant scales\n"); exit(1); } g_qscratch.sx=p; g_qscratch.sx_cap=sn; } *xq=g_qscratch.xq; *sx=g_qscratch.sx; } static void matmul_qt(float *y, const float *x, QT *w, int S){ #ifdef COLI_METAL /* Large row-batches (prefill: kv_b reconstruction, o_proj, dense MLP, step_all logits) * amortize Metal's ~5ms submit latency; small-S decode matmuls stay on CPU (NEON wins). * Weights must be registered (all dense QT allocs are, via qalloc). */ if(g_metal_enabled && S>=g_metal_gemm_min && (w->fmt==1||w->fmt==2) && !omp_in_parallel()){ const void *wp = w->fmt==1 ? (const void*)w->q8 : (const void*)w->q4; if(coli_metal_gemm(y,x,wp,w->s,w->fmt,S,w->I,w->O)) return; } #endif #ifdef COLI_CUDA /* The CUDA backend owns persistent copies only for model-resident tensors. * Streaming expert slots are reused for different IDs and must never enter * this cache. Nested OpenMP calls stay on CPU because each device context * intentionally owns one synchronous scratch stream in this stage. */ if(g_cuda_enabled && w->cuda_eligible && !w->cuda_failed && !omp_in_parallel()){ const void *weights = w->fmt==0 ? (const void*)w->qf : w->fmt==1 ? (const void*)w->q8 : (const void*)w->q4; if(coli_cuda_matmul(&w->cuda,y,x,weights,w->s,w->fmt,S,w->I,w->O,w->cuda_device)) return; w->cuda_failed=1; fprintf(stderr,"[CUDA] tensor [%d,%d] on device %d disabled after an error; falling back to CPU\n", w->O,w->I,w->cuda_device); } #endif if(w->fmt==0){ matmul(y,x,w->qf,S,w->I,w->O); return; } /* int8 IDOT vince sempre (1.4-2.5x). int4 IDOT: l'autore su AVX2 trovo' che a S=1 * non ripaga (soglia S>=2); ma su ARM/SDOT il singolo token CONVIENE (vedi g_i4s / * PR #9 per il gemello VNNI). Soglia configurabile con I4S. * EN: int8 IDOT always wins (1.4-2.5x). int4 IDOT: on AVX2 the author found S=1 didn't * pay (S>=2 gate); on ARM/SDOT single-token DOES pay (see g_i4s / PR #9 for the VNNI * twin). Threshold configurable via I4S. */ if(g_idot && (w->fmt==1 || (w->fmt==2 && S>=g_i4s))){ int I=w->I; int8_t *xq; float *sx; if(S<0 || I<0 || (size_t)S>SIZE_MAX/(size_t)(I?I:1)){ fprintf(stderr,"matmul_qt: shape overflow\n"); exit(1); } quant_scratch((size_t)S*I,(size_t)S,&xq,&sx); for(int s=0;sfmt==1) matmul_q_idot(y,xq,sx,w->q8,w->s,S,I,w->O); else matmul_i4_idot(y,xq,sx,w->q4,w->s,S,I,w->O); return; } if(w->fmt==1) matmul_q(y,x,w->q8,w->s,S,w->I,w->O); else if(w->fmt==3) matmul_i2(y,x,w->q4,w->s,S,w->I,w->O); else matmul_i4(y,x,w->q4,w->s,S,w->I,w->O); } /* quantizza w[O,I] f32 -> int8 q[O,I] + scala[O] simmetrica per riga */ static void quantize_rows(const float *w, int8_t *q, float *scale, int O, int I, int bits){ int qmax=(1<<(bits-1))-1; #pragma omp parallel for schedule(static) for(int o=0;oamax)amax=a; } float s=amax/qmax; if(s<1e-8f)s=1e-8f; scale[o]=s; int8_t *qr=q+(int64_t)o*I; for(int i=0;iqmax)v=qmax; if(v<-qmax-1)v=-qmax-1; qr[i]=(int8_t)v; } } } /* quantizza w[O,I] f32 -> int4 impacchettato (2/byte) + scala[O]. * bits<=4: valori in [-qmax-1,qmax] stanno in un nibble [-8,7]; memorizzati come v+8 (0..15). */ static void pack_int4(const float *w, uint8_t *q4, float *scale, int O, int I, int bits){ int qmax=(1<<(bits-1))-1, rb=(I+1)/2; #pragma omp parallel for schedule(static) for(int o=0;oamax)amax=a; } float s=amax/qmax; if(s<1e-8f)s=1e-8f; scale[o]=s; uint8_t *qr=q4+(int64_t)o*rb; for(int i=0;iqmax)v0=qmax; if(v0<-8)v0=-8; int v1=0; if(i+1qmax)v1=qmax; if(v1<-8)v1=-8; } qr[i>>1] = (uint8_t)((v0+8) | ((v1+8)<<4)); } } } /* quantizza w[O,I] f32 -> int2 impacchettato (4/byte) + scala[O]. valori nibble 2-bit in [-2,1]. */ static void pack_int2(const float *w, uint8_t *q2, float *scale, int O, int I, int bits){ int qmax=(1<<(bits-1))-1, rb=(I+3)/4; #pragma omp parallel for schedule(static) for(int o=0;oamax)amax=a; } float s=amax/qmax; if(s<1e-8f)s=1e-8f; scale[o]=s; uint8_t *qr=q2+(int64_t)o*rb; for(int i=0;iqmax)v=qmax; if(v<-2)v=-2; byte|=(uint8_t)((v+2)<<(k*2)); } qr[i>>2]=byte; } } } static int g_nopack=0; /* NOPACK=1 -> tiene i valori <=4bit in contenitore int8 (per validare il packing) */ static int g_drop=0; /* DROP=1 -> scarta le pagine expart dopo l'uso. Default 0: le lascia in * page-cache (buff/cache, NON RSS) come L2 gratuito -> sfrutta lo * sbilanciamento del routing MoE (pochi expert "caldi" riusati). */ static int g_prefetch=0; /* PREFETCH=1 -> riabilita il WILLNEED cross-layer (metodo C). Default * OFF: i load VERI in parallelo lo hanno reso superfluo, e sotto * pressione di memoria il readahead speculativo veniva rievictato. */ static int g_direct=0; /* DIRECT=1 -> O_DIRECT sugli slab expert. Default OFF: su questo host * (VHDX su NVMe DRAM-less, latenza serializzata ~60ms/req) il buffered * liscio e' risultato il migliore; su NVMe veri DIRECT=1 rende di piu'. */ static float g_temp=-1; /* TEMP: temperatura di sampling sui TOKEN. <0 = auto (1.0 in chat/testo, * 0=greedy in validazione). 0 = greedy puro. */ static float g_nuc=0.95f;/* NUCLEUS: top-p sul vocabolario (default dal generation_config GLM-5.2) */ static int g_topk=0; /* TOPK=n -> usa n expert/token invece di config (ricerca: meno disco) */ static float g_topp=0; /* TOPP=p (0..1) -> top-p adattivo: tieni gli expert fino a peso cumulato p */ static int g_spec=1; /* metodo C: SPEC=0 disabilita il prefetch speculativo cross-layer */ static int g_draft=0; /* metodo E: DRAFT=n token auto-speculati per forward via n-gram lookup * (0=off). LOSSLESS: verifica = output identico al greedy. Default OFF: * misurato sul run reale (2026-07-03) acceptance ~5% -> ogni draft * rifiutato paga comunque i suoi expert dal disco = ~3x piu' lento. * Opt-in (DRAFT=4) per testi ripetitivi dove l'acceptance e' alta. */ /* metodo F (#48): GRAMMAR= -> terza sorgente di draft, la grammatica stessa. * Nei workload a output vincolato (JSON/NDJSON, function calling) i byte FORZATI dalla * grammatica (chiavi, punteggiatura, valori enum) sono draft gratuiti ad acceptance ~1: * nessuna testa, nessuna lookup table, e si aggancia anche dove la testa MTP int4 non * parte (#8). MAI un vincolo sul sampling: solo proposte, la verifica batch-union * decide — grammatica sbagliata = draft rifiutati, output identico. * GRAMMAR_DRAFT=n (default 24) limita i token forzati per forward. */ static Grammar g_gram; static GrState g_gst; static Tok *g_gr_T=NULL; static int g_gr_on=0; /* grammatica caricata e walker vivo */ static int g_gr_armed=0; /* lazy: parte dal primo byte ammesso dalla radice (salta i preamboli) */ static int g_gr_max=24; static uint64_t g_gr_prop=0, g_gr_acc=0; static int g_looka=0; /* LOOKA=1: misura (solo contatori, zero effetti) quanto il routing MoE * e' predicibile IN ANTICIPO — la domanda che decide se un prefetch * pilotato dal router puo' riempire i tempi morti del disco. * [0] token precedente, stesso layer (cio' che usa gia' SPEC/PREFETCH) * [1] ingresso del layer -> routing dello STESSO layer (salta l'attention) * [2] post-attention del layer L -> routing di L+1 (un residuo MoE e * un'attention di anticipo: il punto dove il prefetch avrebbe * un intero giro di disco per lavorare in ombra). */ static int64_t la_hit[3], la_tot[3]; static int la_pred[2][130][16]; static signed char la_val[2][130]; static int g_pilot=0; /* PILOT=1: prefetch pilotato dal router (vedi pilot_prefetch) */ static int g_pilot_k=8; /* PILOT_K=k: prefetcha solo le prime k predizioni per posizione */ /* Aligned allocator for dense QT weights/scales: under METAL, page-align + register so the * GPU reads them zero-copy (no upload duplicate). Plain malloc otherwise. */ static void *qalloc(size_t n){ #ifdef COLI_METAL if(g_metal_enabled){ void *p; size_t r=(n+16383)&~(size_t)16383; if(posix_memalign(&p,16384,r)){fprintf(stderr,"OOM qalloc\n");exit(1);} coli_metal_register(p,r); return p; } #endif return malloc(n); } static float *qsalloc(int O){ return (float*)qalloc((size_t)O*sizeof(float)); } static int g_pilot_real=0;/* PILOT_REAL=1: il pilota fa LOAD VERI cross-layer dentro ecache[L+1] * (non il semplice WILLNEED). Implica PILOT=1. Default OFF: hint-only. */ /* Handshake main<->pilota per il load-vero cross-layer. Invariante di sicurezza in DUE parti: * 1) Percorso MATMUL (moe): il pilota scrive SOLO ecache[layer] con layer > g_cur_moe_layer; * il matmul in moe() legge SOLO ecache[layer]==g_cur_moe_layer, e la barriera a inizio moe() * aspetta l'eventuale load in volo su QUEL layer. Quindi NESSUNO slot mezzo-caricato viene * mai matmul-ato: il matmul e il pilota non toccano mai lo stesso layer contemporaneamente. * 2) Percorso SCAN (pilot_prefetch, anch'esso sul MAIN): la scansione di residenza gira sul * layer FUTURO (lnext = layer corrente + 1), esattamente il layer che il pilota sta scrivendo * -> QUI i due thread toccano davvero la stessa ecache. Percio' quella scansione prende * g_pilot_mx (lo stesso lock del worker): letture e pubblicazione degli slot sono serializzate, * niente torn read di ecn[]/eid. Il pilota non altera MAI il valore di un expert, solo QUALE * expert e' residente: con un load andato a buon fine l'output resta byte-identico all'OFF. */ static pthread_mutex_t g_pilot_mx=PTHREAD_MUTEX_INITIALIZER; static _Atomic int g_cur_moe_layer=-1; /* massimo layer moe in cui il MAIN e' entrato (per forward) */ static _Atomic int g_pilot_inflight=-1; /* layer che il worker sta REAL-caricando adesso (-1 = idle) */ static _Atomic long g_pilot_loads=0; /* load cross-layer VERI completati (banda spesa) */ static _Atomic long g_pilot_drops=0; /* predizioni scartate perche' il main possiede gia' il layer */ /* sceglie il formato da `bits`: >=16 f32, 5..8 int8, <=4 int4-packed */ static void qt_alloc(QT *t, int O, int I, int bits){ t->O=O; t->I=I; t->qf=NULL; t->q8=NULL; t->q4=NULL; t->s=NULL; if(bits>=16){ t->fmt=0; t->qf=falloc((int64_t)O*I); } else if(bits>=5 || g_nopack){ t->fmt=1; t->q8=qalloc((int64_t)O*I); t->s=qsalloc(O); } else if(bits>=3){ t->fmt=2; t->q4=qalloc((int64_t)O*((I+1)/2)); t->s=qsalloc(O); } else { t->fmt=3; t->q4=qalloc((int64_t)O*((I+3)/4)); t->s=qsalloc(O); } } static void qt_fill(QT *t, const float *w, int bits){ if(t->fmt==0) memcpy(t->qf, w, (int64_t)t->O*t->I*sizeof(float)); else if(t->fmt==1) quantize_rows(w, t->q8, t->s, t->O, t->I, bits); else if(t->fmt==3) pack_int2(w, t->q4, t->s, t->O, t->I, bits); else pack_int4(w, t->q4, t->s, t->O, t->I, bits); } static void rmsnorm(float *out, const float *x, const float *w, int D, float eps){ double ms=0; for(int i=0;im)m=x[i]; float s=0; for(int i=0;iqk_rope/2; float in[256]; memcpy(in,v,c->qk_rope*sizeof(float)); for(int j=0;jtheta, -2.0f*j/c->qk_rope); float ang = pos*inv, cs=cosf(ang), sn=sinf(ang); float a=in[2*j], b=in[2*j+1]; v[j] = a*cs - b*sn; v[half+j] = b*cs + a*sn; } } /* ---------- config ---------- */ static jval* cfg_root(const char *snap, char **arena){ char p[2048]; snprintf(p,sizeof(p),"%s/config.json",snap); FILE *f=fopen(p,"rb"); if(!f){perror(p);exit(1);} fseek(f,0,SEEK_END); long n=ftell(f); fseek(f,0,SEEK_SET); char *b=malloc(n+1); if(fread(b,1,n,f)!=(size_t)n){} b[n]=0; fclose(f); return json_parse(b,arena); } static int gi(jval*r,const char*k){ jval*v=json_get(r,k); return v?(int)v->num:0; } static void load_cfg(Cfg *c, const char *snap){ char *ar=NULL; jval *r=cfg_root(snap,&ar); c->hidden=gi(r,"hidden_size"); c->n_layers=gi(r,"num_hidden_layers"); c->n_heads=gi(r,"num_attention_heads"); c->n_experts=gi(r,"n_routed_experts"); c->topk=gi(r,"num_experts_per_tok"); c->moe_inter=gi(r,"moe_intermediate_size"); c->dense_inter=gi(r,"intermediate_size"); c->first_dense=gi(r,"first_k_dense_replace"); c->q_lora=gi(r,"q_lora_rank"); c->kv_lora=gi(r,"kv_lora_rank"); c->qk_nope=gi(r,"qk_nope_head_dim"); c->qk_rope=gi(r,"qk_rope_head_dim"); c->v_head=gi(r,"v_head_dim"); c->n_shared=gi(r,"n_shared_experts"); c->vocab=gi(r,"vocab_size"); c->n_group=gi(r,"n_group"); c->topk_group=gi(r,"topk_group"); jval *nt=json_get(r,"norm_topk_prob"); c->norm_topk=(nt&&nt->t==J_BOOL)?nt->boolean:0; jval *ep=json_get(r,"rms_norm_eps"); c->eps=ep?(float)ep->num:1e-5f; jval *rs=json_get(r,"routed_scaling_factor"); c->routed_scale=rs?(float)rs->num:1.f; jval *rp=json_get(r,"rope_parameters"); jval *th=rp?json_get(rp,"rope_theta"):NULL; c->theta = th?(float)th->num:10000.f; /* token di stop: GLM-5.2 ne ha TRE (endoftext, user, observation). Fermarsi solo sul * primo = generare spazzatura invisibile dopo la fine del turno (5-10x token sprecati). */ c->n_stop=0; jval *eo=json_get(r,"eos_token_id"); if(eo){ if(eo->t==J_NUM) c->stop_ids[c->n_stop++]=(int)eo->num; else if(eo->t==J_ARR) for(int i=0;ilen && c->n_stop<8;i++) c->stop_ids[c->n_stop++]=(int)eo->kids[i]->num; } /* DSA lightning indexer: parametri + tipo per-layer (lista esplicita o formula freq/offset) */ c->index_topk=gi(r,"index_topk"); c->index_nh=gi(r,"index_n_heads"); c->index_hd=gi(r,"index_head_dim"); { jval *it=json_get(r,"indexer_types"); int freq=gi(r,"index_topk_freq"); if(freq<1) freq=1; jval *of=json_get(r,"index_skip_topk_offset"); int off=of?(int)of->num:2; for(int i=0;in_layers && i<128;i++){ if(it && it->t==J_ARR && ilen && it->kids[i]->str) c->idx_type[i] = !strcmp(it->kids[i]->str,"full"); else { int v=i-off+1; if(v<0) v=0; c->idx_type[i] = (v%freq)==0; } } } c->qk_head=c->qk_nope+c->qk_rope; c->attn_scale = 1.f / sqrtf((float)c->qk_head); if(c->n_group!=1){ fprintf(stderr,"this engine requires n_group=1 (GLM-5.2)\n"); exit(1); } /* VALIDAZIONE (report PR #25): il config.json arriva da mirror non fidati — dimensioni * ostili non devono superare questo punto. Un solo choke point protegge ogni alloc a valle. */ #define CKR(name,v,lo,hi) if((v)<(lo)||(v)>(hi)){ \ fprintf(stderr,"config: %s=%d is outside [%d,%d]\n",name,(int)(v),(int)(lo),(int)(hi)); exit(1); } CKR("hidden_size",c->hidden,1,1<<20) CKR("num_hidden_layers",c->n_layers,1,128) CKR("num_attention_heads",c->n_heads,1,1024) CKR("n_routed_experts",c->n_experts,1,4096) CKR("num_experts_per_tok",c->topk,1,64) CKR("moe_intermediate_size",c->moe_inter,1,1<<20) CKR("intermediate_size",c->dense_inter,1,1<<24) CKR("first_k_dense_replace",c->first_dense,0,c->n_layers) CKR("q_lora_rank",c->q_lora,0,1<<20) CKR("kv_lora_rank",c->kv_lora,1,1<<20) CKR("qk_nope_head_dim",c->qk_nope,1,1<<16) CKR("qk_rope_head_dim",c->qk_rope,1,1<<16) CKR("v_head_dim",c->v_head,1,1<<16) CKR("n_shared_experts",c->n_shared,0,64) CKR("vocab_size",c->vocab,1,1<<24) CKR("index_topk",c->index_topk,0,1<<20) CKR("index_n_heads",c->index_nh,0,1024) CKR("index_head_dim",c->index_hd,0,1<<16) #undef CKR free(ar); } /* costruisce un QT [O,I] dal disco in `t` (buffer riusabili tra chiamate). * - se esiste `name.qs`: pesi GIA' quantizzati nel container (U8 qdata + F32 scala) -> letti diretti * - altrimenti: tensore pieno (f32/bf16) -> quantizzato a runtime a `bits` (oracolo tiny / pesi pieni) * drop=1 -> fadvise DONTNEED (streaming expert). */ static void qt_from_disk(Model *m, const char *name, int O, int I, int bits, int drop, QT *t){ char sn[300]; snprintf(sn,sizeof(sn),"%s.qs",name); if(st_has(&m->S,sn)){ int64_t nb=st_nbytes(&m->S,name); int fmt = (nb==(int64_t)O*I)?1 : (nb==(int64_t)O*((I+1)/2))?2 : 3; /* int8 / int4 / int2 dai byte */ if(fmt==1){ if(t->fmt!=1||!t->q8){ t->fmt=1; t->O=O; t->I=I; t->q8=qalloc(nb); t->s=qsalloc(O); } st_read_raw(&m->S,name,t->q8,drop); } else { if(t->fmt!=fmt||!t->q4){ t->fmt=fmt; t->O=O; t->I=I; t->q4=qalloc(nb); t->s=qsalloc(O); } st_read_raw(&m->S,name,t->q4,drop); } st_read_f32(&m->S,sn,t->s,drop); } else { if(!t->qf && !t->q8 && !t->q4) qt_alloc(t,O,I,bits); if(t->fmt==0) st_read_f32(&m->S,name,t->qf,drop); else { float *tmp=falloc((int64_t)O*I); st_read_f32(&m->S,name,tmp,drop); qt_fill(t,tmp,bits); free(tmp); } } } static QT qt_load(Model *m, const char *name, int O, int I, int bits){ QT t; memset(&t,0,sizeof(t)); qt_from_disk(m,name,O,I,bits,0,&t); #ifdef COLI_CUDA if(g_cuda_enabled&&g_cuda_dense){ t.cuda_eligible=1; int slot=g_cuda_rr++%g_cuda_ndev; t.cuda_device=g_cuda_devices[slot]; g_cuda_dense_projected[slot]+=qt_bytes(&t); } #endif return t; } static float *ld(Model *m, const char *name){ /* tensore 1D f32 residente (norme/bias) */ int64_t n=st_numel(&m->S,name); if(n<0){fprintf(stderr,"missing %s\n",name);exit(1);} float *p=(float*)qalloc((size_t)n*sizeof(float)); /* registrato per la GPU sotto METAL */ st_read_f32(&m->S,name,p,0); return p; } static void model_init(Model *m, const char *snap, int cap, int ebits, int dbits){ memset(m,0,sizeof(*m)); m->ebits=ebits; m->dbits=dbits; load_cfg(&m->c,snap); st_init(&m->S,snap); Cfg *c=&m->c; char nm[256]; int H=c->n_heads, D=c->hidden; /* embed e lm_head sono il confine I/O: tenerli ad alta precisione (come i quant dynamic * reali). A bf16 ~1.9GB su GLM reale: trascurabile. dbits>=8 -> qui f32; piu' basso -> dbits. */ int io_bits = dbits>=8 ? 16 : dbits; m->embed = qt_load(m,"model.embed_tokens.weight", c->vocab, D, io_bits); m->lm_head = qt_load(m,"lm_head.weight", c->vocab, D, io_bits); m->final_norm = ld(m,"model.norm.weight"); m->L=calloc(c->n_layers,sizeof(Layer)); int NR=c->n_layers+1; /* +1: riga del layer MTP */ m->ecap=cap; m->ecache=calloc(NR,sizeof(ESlot*)); m->ecn=calloc(NR,sizeof(int)); m->eroute=calloc(NR,sizeof(int*)); m->enr=calloc(NR,sizeof(int)); m->pin=calloc(NR,sizeof(ESlot*)); m->npin=calloc(NR,sizeof(int)); m->eusage=calloc(NR,sizeof(uint32_t*)); m->eheat=calloc(NR,sizeof(uint32_t*)); m->elast=calloc(NR,sizeof(uint32_t*)); m->kv=calloc(1,sizeof(KVState)); m->kv_start=m->kv->kv_start=calloc(NR,sizeof(int)); for(int i=0;in_layers;i++){ Layer *l=&m->L[i]; #define P(s) (snprintf(nm,sizeof(nm),"model.layers.%d." s,i),nm) l->in_ln=ld(m,P("input_layernorm.weight")); l->post_ln=ld(m,P("post_attention_layernorm.weight")); l->q_a = qt_load(m,P("self_attn.q_a_proj.weight"), c->q_lora, D, dbits); l->q_a_ln= ld(m,P("self_attn.q_a_layernorm.weight")); l->q_b = qt_load(m,P("self_attn.q_b_proj.weight"), H*c->qk_head, c->q_lora, dbits); l->kv_a = qt_load(m,P("self_attn.kv_a_proj_with_mqa.weight"), c->kv_lora+c->qk_rope, D, dbits); l->kv_a_ln= ld(m,P("self_attn.kv_a_layernorm.weight")); l->kv_b = qt_load(m,P("self_attn.kv_b_proj.weight"), H*(c->qk_nope+c->v_head), c->kv_lora, dbits); l->o = qt_load(m,P("self_attn.o_proj.weight"), D, H*c->v_head, dbits); l->sparse = (i >= c->first_dense); if(!l->sparse){ l->gate_proj = qt_load(m,P("mlp.gate_proj.weight"), c->dense_inter, D, dbits); l->up_proj = qt_load(m,P("mlp.up_proj.weight"), c->dense_inter, D, dbits); l->down_proj = qt_load(m,P("mlp.down_proj.weight"), D, c->dense_inter, dbits); } else { l->router=ld(m,P("mlp.gate.weight")); l->router_bias=ld(m,P("mlp.gate.e_score_correction_bias")); int sI=c->moe_inter*c->n_shared; l->sh_gate = qt_load(m,P("mlp.shared_experts.gate_proj.weight"), sI, D, dbits); l->sh_up = qt_load(m,P("mlp.shared_experts.up_proj.weight"), sI, D, dbits); l->sh_down = qt_load(m,P("mlp.shared_experts.down_proj.weight"), D, sI, dbits); m->ecache[i]=calloc(cap,sizeof(ESlot)); m->eroute[i]=calloc(c->topk,sizeof(int)); /* metodo C: ultimo routing del layer */ m->eusage[i]=calloc(c->n_experts,sizeof(uint32_t)); m->eheat[i]=calloc(c->n_experts,sizeof(uint32_t)); m->elast[i]=calloc(c->n_experts,sizeof(uint32_t)); } #undef P } /* testa MTP (layer n_layers): presente solo se convertita con --mtp */ { /* MTP attiva SOLO se il set e' COMPLETO (i tensori vivono su 3 shard: durante la * conversione parziale ne esiste solo una parte). MTP=0 la disabilita comunque. */ const char *req[]={"eh_proj.weight","enorm.weight","hnorm.weight","shared_head.norm.weight", "input_layernorm.weight","post_attention_layernorm.weight", "self_attn.q_a_proj.weight","self_attn.q_b_proj.weight","self_attn.kv_a_proj_with_mqa.weight", "self_attn.kv_b_proj.weight","self_attn.o_proj.weight","mlp.gate.weight", "mlp.shared_experts.gate_proj.weight","mlp.shared_experts.down_proj.weight", "mlp.experts.0.gate_proj.weight","mlp.experts.255.down_proj.weight"}; char mn[256]; m->has_mtp=1; for(unsigned q=0;qn_layers,req[q]); if(!st_has(&m->S,mn)){ m->has_mtp=0; break; } } if(getenv("MTP") && atoi(getenv("MTP"))==0) m->has_mtp=0; if(m->has_mtp){ int i=c->n_layers; Layer *l=&m->mtpL; #define PM(s) (snprintf(nm,sizeof(nm),"model.layers.%d." s,i),nm) l->in_ln=ld(m,PM("input_layernorm.weight")); l->post_ln=ld(m,PM("post_attention_layernorm.weight")); l->q_a = qt_load(m,PM("self_attn.q_a_proj.weight"), c->q_lora, D, dbits); l->q_a_ln= ld(m,PM("self_attn.q_a_layernorm.weight")); l->q_b = qt_load(m,PM("self_attn.q_b_proj.weight"), H*c->qk_head, c->q_lora, dbits); l->kv_a = qt_load(m,PM("self_attn.kv_a_proj_with_mqa.weight"), c->kv_lora+c->qk_rope, D, dbits); l->kv_a_ln= ld(m,PM("self_attn.kv_a_layernorm.weight")); l->kv_b = qt_load(m,PM("self_attn.kv_b_proj.weight"), H*(c->qk_nope+c->v_head), c->kv_lora, dbits); l->o = qt_load(m,PM("self_attn.o_proj.weight"), D, H*c->v_head, dbits); l->sparse=1; l->router=ld(m,PM("mlp.gate.weight")); l->router_bias=ld(m,PM("mlp.gate.e_score_correction_bias")); int sI=c->moe_inter*c->n_shared; l->sh_gate = qt_load(m,PM("mlp.shared_experts.gate_proj.weight"), sI, D, dbits); l->sh_up = qt_load(m,PM("mlp.shared_experts.up_proj.weight"), sI, D, dbits); l->sh_down = qt_load(m,PM("mlp.shared_experts.down_proj.weight"), D, sI, dbits); m->eh_proj = qt_load(m,PM("eh_proj.weight"), D, 2*D, dbits); m->enorm=ld(m,PM("enorm.weight")); m->hnorm=ld(m,PM("hnorm.weight")); m->mtp_norm=ld(m,PM("shared_head.norm.weight")); m->ecache[i]=calloc(cap,sizeof(ESlot)); m->eroute[i]=calloc(c->topk,sizeof(int)); m->eusage[i]=calloc(c->n_experts,sizeof(uint32_t)); m->eheat[i]=calloc(c->n_experts,sizeof(uint32_t)); m->elast[i]=calloc(c->n_experts,sizeof(uint32_t)); m->kv_start[i]=-1; /* KV MTP: parte dalla prima posizione di decode */ #undef PM } } /* DSA lightning indexer: attivo SOLO se i pesi (conversione --indexer) ci sono per * TUTTI i layer full. Auto-rilevamento come per MTP: niente flag, niente passi extra. */ { m->has_dsa = (c->index_topk>0 && c->index_nh>0 && c->index_hd>0 && c->index_hd<=256); char inm[300]; for(int i=0;in_layers && m->has_dsa;i++){ if(!c->idx_type[i]) continue; snprintf(inm,sizeof(inm),"model.layers.%d.self_attn.indexer.wq_b.weight",i); if(!st_has(&m->S,inm)) m->has_dsa=0; } if(getenv("DSA") && atoi(getenv("DSA"))==0) m->has_dsa=0; if(m->has_dsa){ m->ix_wq=calloc(c->n_layers,sizeof(QT)); m->ix_wk=calloc(c->n_layers,sizeof(QT)); m->ix_wp=calloc(c->n_layers,sizeof(QT)); m->ix_knw=calloc(c->n_layers,sizeof(float*)); m->ix_knb=calloc(c->n_layers,sizeof(float*)); for(int i=0;in_layers;i++){ if(!c->idx_type[i]) continue; #define PI(s) (snprintf(nm,sizeof(nm),"model.layers.%d.self_attn.indexer." s,i),nm) m->ix_wq[i]=qt_load(m,PI("wq_b.weight"), c->index_nh*c->index_hd, c->q_lora, dbits); m->ix_wk[i]=qt_load(m,PI("wk.weight"), c->index_hd, D, dbits); m->ix_wp[i]=qt_load(m,PI("weights_proj.weight"), c->index_nh, D, dbits); m->ix_knw[i]=ld(m,PI("k_norm.weight")); m->ix_knb[i]=ld(m,PI("k_norm.bias")); #undef PI } fprintf(stderr,"[DSA] indexer active: top-%d sparse attention beyond %d context tokens\n", c->index_topk, c->index_topk); } } m->hlast=falloc(D); m->h_all=falloc((int64_t)64*D); /* byte della parte DENSA residente (embed+lm_head+attn+mlp densa+shared+norme) */ int64_t rb=qt_bytes(&m->embed)+qt_bytes(&m->lm_head); for(int i=0;in_layers;i++){ Layer *l=&m->L[i]; rb+=qt_bytes(&l->q_a)+qt_bytes(&l->q_b)+qt_bytes(&l->kv_a)+qt_bytes(&l->kv_b)+qt_bytes(&l->o); if(!l->sparse) rb+=qt_bytes(&l->gate_proj)+qt_bytes(&l->up_proj)+qt_bytes(&l->down_proj); else rb+=qt_bytes(&l->sh_gate)+qt_bytes(&l->sh_up)+qt_bytes(&l->sh_down); } if(m->has_mtp){ Layer *l=&m->mtpL; rb+=qt_bytes(&l->q_a)+qt_bytes(&l->q_b)+qt_bytes(&l->kv_a)+qt_bytes(&l->kv_b)+qt_bytes(&l->o); rb+=qt_bytes(&l->sh_gate)+qt_bytes(&l->sh_up)+qt_bytes(&l->sh_down)+qt_bytes(&m->eh_proj); } if(m->has_dsa) for(int i=0;in_layers;i++) if(c->idx_type[i]) rb+=qt_bytes(&m->ix_wq[i])+qt_bytes(&m->ix_wk[i])+qt_bytes(&m->ix_wp[i]); m->resident_bytes=rb; } /* embed: dequantizza la riga del token (scala per-riga) in x[hidden] */ static void embed_row(Model *m, int tok, float *x){ int D=m->c.hidden; QT *e=&m->embed; if(e->fmt==0){ memcpy(x, e->qf+(int64_t)tok*D, D*sizeof(float)); return; } if(e->fmt==1){ const int8_t *q=e->q8+(int64_t)tok*D; float s=e->s[tok]; for(int i=0;ifmt==2){ const uint8_t *q=e->q4+(int64_t)tok*((D+1)/2); float s=e->s[tok]; /* int4 */ for(int i=0;i>1]; x[i]=(float)((int)(byte&0xF)-8)*s; if(i+1>4)-8)*s; } return; } const uint8_t *q=e->q4+(int64_t)tok*((D+3)/4); float s=e->s[tok]; /* int2 */ for(int i=0;i>2]; int sh=(i&3)*2; x[i]=(float)((int)((byte>>sh)&3)-2)*s; } } /* COLI_MMAP=1: gli expert diventano VISTE dentro mmap dei file safetensors (niente pread, * niente slab, niente copia: la page cache del kernel E' la cache). Le mappe sono * registrate con Metal (newBufferWithBytesNoCopy su pagine file-backed, come llama.cpp), * quindi la GPU legge gli stessi byte. Fallback allo slab path su disallineamento. */ static int g_mmap=0; static struct { int fd; void *base; size_t len; } g_maps[512]; static int g_nmaps; static pthread_mutex_t g_map_mtx = PTHREAD_MUTEX_INITIALIZER; /* expert_load e' OMP-parallel */ static void *map_of_fd(int fd){ pthread_mutex_lock(&g_map_mtx); for(int i=0;i UNA pread coalescente da ~19 MB dentro `slab` (+ le scale in fslab); i QT sono * viste dentro lo slab (zero copie). Fallback per modelli non quantizzati (oracolo tiny). * THREAD-SAFE su slot distinti (pread posizionale, st_find read-only). */ /* Load one expert's weights into slot `s`. Returns 0 on success, -1 on failure. * fatal=1 (all main / on-demand / REPIN / pin callers): preserve the original * exit-on-error contract byte-for-byte — any missing tensor, OOM, short read or * pread error aborts the process. fatal=0 (speculative pilot only): the same * errors instead abandon the load and return -1 without touching s->eid, so a * mispredicted cross-layer prefetch can never kill the server. */ static int expert_load(Model *m, int layer, int eid, ESlot *s, int fatal){ #ifdef COLI_CUDA /* A live REPIN may reuse a GPU-enabled pinned slot for a different expert. * Keep its tier assignment, but invalidate the old device weights. */ if(s->eid!=eid){ qt_cuda_reset(&s->g); qt_cuda_reset(&s->u); qt_cuda_reset(&s->d); } #endif Cfg *c=&m->c; int I=c->moe_inter, D=c->hidden, b=m->ebits; char nm[3][288]; const char *suf[3]={"gate_proj","up_proj","down_proj"}; for(int k=0;k<3;k++) snprintf(nm[k],sizeof(nm[k]),"model.layers.%d.mlp.experts.%d.%s.weight",layer,eid,suf[k]); char qn[300]; snprintf(qn,sizeof(qn),"%s.qs",nm[0]); if(!st_has(&m->S,qn)){ /* fallback: tensori pieni, quantizza a runtime. * Reachable ONLY for unquantized models (no .qs); * GLM always has .qs, so the pilot never hits it. */ qt_from_disk(m,nm[0],I,D,b,g_drop,&s->g); qt_from_disk(m,nm[1],I,D,b,g_drop,&s->u); qt_from_disk(m,nm[2],D,I,b,g_drop,&s->d); s->eid=eid; return 0; } st_tensor *tw[3], *tq[3]; for(int k=0;k<3;k++){ tw[k]=st_find(&m->S,nm[k]); snprintf(qn,sizeof(qn),"%s.qs",nm[k]); tq[k]=st_find(&m->S,qn); if(!tw[k]||!tq[k]){ fprintf(stderr,"missing %s\n",nm[k]); if(fatal) exit(1); return -1; } } if(g_mmap){ void *bw[3],*bq[3]; int okm=1; for(int k=0;k<3;k++){ bw[k]=map_of_fd(tw[k]->fd); bq[k]=map_of_fd(tq[k]->fd); if(!bw[k]||!bq[k]||((tw[k]->off)&3)||((tq[k]->off)&3)) okm=0; } if(okm){ QT *qt[3]={&s->g,&s->u,&s->d}; int OO[3]={I,I,D}, II[3]={D,D,I}; for(int k=0;k<3;k++){ int64_t nb=tw[k]->nbytes; int fmt=(nb==(int64_t)OO[k]*II[k])?1:(nb==(int64_t)OO[k]*((II[k]+1)/2))?2:3; qt[k]->fmt=fmt; qt[k]->O=OO[k]; qt[k]->I=II[k]; qt[k]->qf=NULL; qt[k]->q8=(int8_t*)((char*)bw[k]+tw[k]->off); qt[k]->q4=(uint8_t*)((char*)bw[k]+tw[k]->off); qt[k]->s=(float*)((char*)bq[k]+tq[k]->off); } /* CPU pre-touch: fault the pages in HERE (cheap, parallel, overlapped with the * resident-experts GPU submit) so the GPU never demand-faults file-backed pages * (measured catastrophic). madvise starts async readahead, the touch guarantees * residency. This is pread's I/O without the copy and without the slab. */ for(int k=0;k<3;k++){ char *p=(char*)bw[k]+tw[k]->off; size_t n=(size_t)tw[k]->nbytes; madvise((void*)((uintptr_t)p & ~16383UL), n+16384, MADV_WILLNEED); volatile char acc=0; for(size_t i=0;ioff; size_t nq=(size_t)tq[k]->nbytes; for(size_t i=0;ieid=eid; return 0; } } int64_t wtot=tw[0]->nbytes+tw[1]->nbytes+tw[2]->nbytes; int64_t ftot=(tq[0]->nbytes+tq[1]->nbytes+tq[2]->nbytes)/4; /* rialloca se lo slot (riusato tra layer) e' troppo piccolo per QUESTO expert: * pread oltre la mappatura = short-read o CORRUZIONE silenziosa dei vicini */ if(!s->slab || wtot+8192 > s->slab_cap){ #ifdef COLI_METAL /* page-align + zero-copy wrap: the GPU reads this slab in place (unified memory) */ if(s->slab && g_metal_enabled) coli_metal_unregister(s->slab); compat_aligned_free(s->slab); size_t need=((size_t)wtot+8192+16383)&~(size_t)16383; if(posix_memalign((void**)&s->slab,16384,need)){fprintf(stderr,"OOM slab\n"); if(fatal) exit(1); s->slab=NULL; s->slab_cap=0; return -1;} s->slab_cap=need; if(g_metal_enabled) coli_metal_register(s->slab,need); #else compat_aligned_free(s->slab); if(posix_memalign((void**)&s->slab,4096,wtot+8192)){fprintf(stderr,"OOM slab\n"); if(fatal) exit(1); s->slab=NULL; s->slab_cap=0; return -1;} s->slab_cap=wtot+8192; #endif } if(!s->fslab || ftot > s->fslab_cap){ #ifdef COLI_METAL /* page-align + register: the GPU reads the scales in place (unified memory). * Honours `fatal` exactly like the CPU arm below — a speculative pilot load * that hits OOM must unwind into a clean hidden slot, never exit(). */ if(s->fslab && g_metal_enabled) coli_metal_unregister(s->fslab); free(s->fslab); size_t fb=(((size_t)ftot*sizeof(float))+16383)&~(size_t)16383; if(ftot<0 || (uint64_t)ftot > SIZE_MAX/sizeof(float) || posix_memalign((void**)&s->fslab,16384,fb)){ fprintf(stderr,"OOM fslab\n"); if(fatal) exit(1); compat_aligned_free(s->slab); s->slab=NULL; s->slab_cap=0; /* clean, hidden slot (eid stays -1) */ s->fslab=NULL; s->fslab_cap=0; return -1; } s->fslab_cap=ftot; if(g_metal_enabled) coli_metal_register(s->fslab,fb); #else free(s->fslab); if(fatal){ s->fslab=falloc(ftot); } /* main path: byte-identical exit-on-OOM */ else { /* speculative pilot: checked alloc, never exit() */ /* replicate falloc's anti-wrap guard + malloc (no zeroing/alignment) */ if(ftot<0 || (uint64_t)ftot > SIZE_MAX/sizeof(float) || !(s->fslab=malloc((size_t)ftot*sizeof(float)))){ fprintf(stderr,"OOM fslab\n"); compat_aligned_free(s->slab); s->slab=NULL; s->slab_cap=0; /* leave a clean, hidden slot (eid stays -1) */ s->fslab=NULL; s->fslab_cap=0; return -1; } } s->fslab_cap=ftot; #endif } int ord[3]={0,1,2}; /* ordina per offset nel file */ for(int a=0;a<3;a++) for(int bb=a+1;bb<3;bb++) if(tw[ord[bb]]->offoff){ int t=ord[a]; ord[a]=ord[bb]; ord[bb]=t; } int contig = tw[ord[0]]->fd==tw[ord[1]]->fd && tw[ord[1]]->fd==tw[ord[2]]->fd && tw[ord[0]]->off+tw[ord[0]]->nbytes==tw[ord[1]]->off && tw[ord[1]]->off+tw[ord[1]]->nbytes==tw[ord[2]]->off; int64_t pos[3]; int done=0; if(contig){ int64_t off0=tw[ord[0]]->off; int dfd = g_direct ? st_direct_fd(&m->S, tw[ord[0]]->fd) : -1; if(dfd>=0){ /* O_DIRECT: offset/len allineati a 4K */ int64_t base=off0 & ~4095LL, need=(off0-base)+wtot; int64_t len=(need+4095)&~4095LL; ssize_t r=pread(dfd, s->slab, len, base); if(r>=need){ pos[ord[0]]=off0-base; pos[ord[1]]=pos[ord[0]]+tw[ord[0]]->nbytes; pos[ord[2]]=pos[ord[1]]+tw[ord[1]]->nbytes; done=1; } } if(!done){ /* fallback bufferizzato */ if(pread(tw[ord[0]]->fd, s->slab, wtot, off0)!=wtot){ perror("pread expert"); if(fatal) exit(1); return -1; } pos[ord[0]]=0; pos[ord[1]]=tw[ord[0]]->nbytes; pos[ord[2]]=tw[ord[0]]->nbytes+tw[ord[1]]->nbytes; done=1; } } if(!done){ /* non contigui: 3 pread bufferizzate */ int64_t o=0; for(int a=0;a<3;a++){ int k=ord[a]; if(pread(tw[k]->fd, s->slab+o, tw[k]->nbytes, tw[k]->off)!=tw[k]->nbytes){ perror("pread expert"); if(fatal) exit(1); return -1; } pos[k]=o; o+=tw[k]->nbytes; } } float *fp[3]; int64_t fo=0; /* scale (piccole) */ for(int k=0;k<3;k++){ if(pread(tq[k]->fd, (char*)(s->fslab+fo), tq[k]->nbytes, tq[k]->off)!=tq[k]->nbytes){ perror("pread qs"); if(fatal) exit(1); return -1; } fp[k]=s->fslab+fo; fo+=tq[k]->nbytes/4; } if(g_drop){ /* scarta subito le pagine: evita che la page * cache in pressione strangoli il throughput */ posix_fadvise(tw[ord[0]]->fd, tw[ord[0]]->off, wtot, POSIX_FADV_DONTNEED); for(int k=0;k<3;k++) posix_fadvise(tq[k]->fd, tq[k]->off, tq[k]->nbytes, POSIX_FADV_DONTNEED); } QT *qt[3]={&s->g,&s->u,&s->d}; int OO[3]={I,I,D}, II[3]={D,D,I}; for(int k=0;k<3;k++){ int64_t nb=tw[k]->nbytes; int fmt = (nb==(int64_t)OO[k]*II[k])?1 : (nb==(int64_t)OO[k]*((II[k]+1)/2))?2 : 3; qt[k]->fmt=fmt; qt[k]->O=OO[k]; qt[k]->I=II[k]; qt[k]->qf=NULL; qt[k]->q8=(int8_t*)(s->slab+pos[k]); qt[k]->q4=s->slab+pos[k]; qt[k]->s=fp[k]; } s->eid=eid; return 0; } /* ============================ PIPE: load ‖ matmul ============================ * Overlap NVMe expert-weight loads with expert matmul. A small persistent pool * of I/O worker pthreads runs the misses' pread (expert_load) into distinct * ws[] slabs and sets a per-slot `ready` flag; the MAIN thread walks the block's * experts in order, waiting on ready[q] only for the expert it needs right now, * and does all matmul_qt on itself (matmul_qt parallelises internally via OpenMP * and checks !omp_in_parallel() for GPU dispatch — so it must stay off the omp * team and off these I/O threads). * * Cross-generation safety is provided by a single generation-tagged, lock-free * cursor `cur = (gen<<8) | index`. The main thread is the sole writer of `gen` * (monotonic bump, so no ABA); workers grab jobs by CAS-advancing the low 8-bit * index. THE INVARIANT: a worker reads eids[i]/layer only AFTER its winning CAS, * and that CAS's comparand carries the generation — so if `cur`'s gen advanced * (a new batch was published), the CAS fails and the worker re-reads, seeing the * new generation. A straggler preempted anywhere (wake gap, post-cursor) can * therefore NEVER grab a wrong-generation job or read torn batch state: its * first act is a gen-checked CAS. dispatch publishes all batch state with * relaxed stores and then RELEASE-stores `cur`; each worker ACQUIRE-loads `cur`, * so the ready[] reset + eids[]/njobs/layer are visible before any worker acts. * The per-expert pipe_wait(ready[q]) in the matmul loop makes every grabbed job * complete before the block ends, so no grab outlives its generation — which is * why the old `active` counter AND the end-of-block drain barrier are gone (both * were redundant with those per-slot waits + the gen-tagged cursor). The mutex/ * condvar exist ONLY to park/wake idle workers, never for correctness. Gated * behind PIPE=1; OFF => the original blocking-load + serial-matmul path runs * byte-identically. */ static int g_pipe=0; /* PIPE=1: async expert-load pipeline (default OFF) */ static int g_pipe_nw=8; /* PIPE_WORKERS=n: I/O worker threads (disk-parallel reads) */ typedef struct { _Atomic uint64_t cur; /* (gen<<8)|index; gen main-only, index 0..njobs (≤64) */ _Atomic int njobs; /* current batch job count */ _Atomic int eids[64]; /* current batch expert ids */ _Atomic int layer; /* current batch layer */ _Atomic int ready[64]; /* per-slot load-done flag */ pthread_mutex_t mx; pthread_cond_t cv; /* ONLY for parking/waking idle workers */ Model *m; pthread_t th[16]; int nw; int started; } PipePool; static PipePool g_pp; static void *pipe_worker(void *arg){ (void)arg; PipePool *p=&g_pp; uint64_t seen=0; for(;;){ pthread_mutex_lock(&p->mx); while((atomic_load_explicit(&p->cur,memory_order_relaxed)>>8)==seen) pthread_cond_wait(&p->cv,&p->mx); pthread_mutex_unlock(&p->mx); for(;;){ uint64_t c=atomic_load_explicit(&p->cur,memory_order_acquire); seen=c>>8; uint32_t i=(uint32_t)(c & 0xFF); if(i >= (uint32_t)atomic_load_explicit(&p->njobs,memory_order_relaxed)) break; /* batch drained → re-park */ if(atomic_compare_exchange_weak_explicit(&p->cur,&c,c+1, memory_order_acq_rel,memory_order_relaxed)){ int L =atomic_load_explicit(&p->layer,memory_order_relaxed); int eid=atomic_load_explicit(&p->eids[i],memory_order_relaxed); /* AFTER winning CAS */ expert_load(p->m,L,eid,&p->m->ws[i],1); /* needed-now load: fatal on I/O error (matches serial path) */ atomic_store_explicit(&p->ready[i],1,memory_order_release); } /* CAS failed → another worker advanced index (or gen advanced): re-loop */ } } return NULL; } static void pipe_init(Model *m){ if(g_pp.started) return; g_pp.m=m; g_pp.nw=g_pipe_nw; if(g_pp.nw>16) g_pp.nw=16; if(g_pp.nw<1) g_pp.nw=1; atomic_store(&g_pp.cur,0); atomic_store(&g_pp.njobs,0); pthread_mutex_init(&g_pp.mx,NULL); pthread_cond_init(&g_pp.cv,NULL); for(int i=0;i>8)+1; atomic_store_explicit(&g_pp.cur,(g<<8),memory_order_release); /* PUBLISH */ pthread_mutex_lock(&g_pp.mx); pthread_cond_broadcast(&g_pp.cv); pthread_mutex_unlock(&g_pp.mx); } static inline void pipe_wait(int q){ while(!atomic_load_explicit(&g_pp.ready[q],memory_order_acquire)) sched_yield(); } #ifdef COLI_CUDA static void expert_host_release(Model *m, ESlot *s){ if(!s->slab&&!s->fslab) return; #if defined(__APPLE__) || defined(__linux__) if(s->slab) munlock(s->slab,(size_t)s->slab_cap); if(s->fslab) munlock(s->fslab,(size_t)s->fslab_cap*sizeof(float)); #endif int64_t bytes=qt_bytes(&s->g)+qt_bytes(&s->u)+qt_bytes(&s->d); free(s->slab); free(s->fslab); s->slab=NULL; s->fslab=NULL; s->slab_cap=s->fslab_cap=0; QT *q[3]={&s->g,&s->u,&s->d}; for(int k=0;k<3;k++){ q[k]->qf=NULL; q[k]->q8=NULL; q[k]->q4=NULL; q[k]->s=NULL; } m->resident_bytes-=bytes; if(m->resident_bytes<0) m->resident_bytes=0; } static void expert_host_ensure(Model *m, int layer, ESlot *s){ if(!s->slab) expert_load(m,layer,s->eid,s,1); } #endif /* prefetch asincrono dei pesi di un expert (e delle sue scale .qs): avvia il readahead * cosi' le letture sincrone successive trovano la page-cache calda. */ static void expert_prefetch(Model *m, int layer, int eid){ char nm[300]; const char *suf[3]={"gate_proj.weight","up_proj.weight","down_proj.weight"}; for(int k=0;k<3;k++){ snprintf(nm,sizeof(nm),"model.layers.%d.mlp.experts.%d.%s",layer,eid,suf[k]); st_prefetch(&m->S,nm); char qs[320]; snprintf(qs,sizeof(qs),"%s.qs",nm); st_prefetch(&m->S,qs); } } /* ---- helper per l'ABSORPTION: accesso per-riga ai QT quantizzati ---- */ /* acc[0..I) += coef * W[row,:] (dequant al volo) */ static void qt_addrow(const QT *t, int row, float coef, float *acc){ int I=t->I; if(t->fmt==0){ const float *w=t->qf+(int64_t)row*I; for(int i=0;is[row]; if(t->fmt==1){ const int8_t *w=t->q8+(int64_t)row*I; for(int i=0;ifmt==2){ const uint8_t *w=t->q4+(int64_t)row*((I+1)/2); for(int i=0;i+1>1]; acc[i]+=c*((int)(b&0xF)-8); acc[i+1]+=c*((int)(b>>4)-8); } if(I&1){ uint8_t b=w[I>>1]; acc[I-1]+=c*((int)(b&0xF)-8); } return; } const uint8_t *w=t->q4+(int64_t)row*((I+3)/4); for(int i=0;i>2]; acc[i]+=c*((int)((b>>((i&3)*2))&3)-2); } } /* y[0..n) = W[r0+j,:]·x (matvec su una FETTA di righe del QT) */ static void qt_matvec_rows(const QT *t, int r0, int n, const float *x, float *y){ int I=t->I; for(int j=0;jfmt==0){ const float *w=t->qf+(int64_t)row*I; for(int i=0;ifmt==1){ const int8_t *w=t->q8+(int64_t)row*I; float s=t->s[row]; float acc=0; for(int i=0;ifmt==2){ const uint8_t *w=t->q4+(int64_t)row*((I+1)/2); float s=t->s[row]; float acc=0; for(int i=0;i+1>1]; acc+=((int)(b&0xF)-8)*x[i]+((int)(b>>4)-8)*x[i+1]; } if(I&1){ uint8_t b=w[I>>1]; acc+=((int)(b&0xF)-8)*x[I-1]; } a=acc*s; } else { const uint8_t *w=t->q4+(int64_t)row*((I+3)/4); float s=t->s[row]; float acc=0; for(int i=0;i>2]; acc+=((int)((b>>((i&3)*2))&3)-2)*x[i]; } a=acc*s; } y[j]=(float)a; } } static int g_absorb=-1; /* ABSORB: -1 auto (decode S<=4), 0 mai, 1 sempre (test) */ static int g_dsa_force=0; /* DSA_FORCE=1: selezione sempre attiva (test: top-min(k,T)=denso) */ static int cmp_fdesc(const void *a,const void *b){ float x=*(const float*)a, y=*(const float*)b; return xy?-1:0; } /* attenzione MLA con KV-cache compressa, su token nuovi x[S,hidden], pos_base = pos del primo */ /* kvs/pos describe a ragged decode batch: each row may belong to a different * sequence. NULL keeps the original contiguous, currently-bound KV path. */ static void attention_rows(Model *m, Layer *l, int layer, float *x, int S, int pos_base, KVState *const *kvs, const int *positions, float *out){ Cfg *c=&m->c; int H=c->n_heads, D=c->hidden, qh=c->qk_head, vh=c->v_head; int kvb_dim=H*(c->qk_nope+vh), Tk=pos_base+S; double ta0=now_s(); #ifdef COLI_METAL /* Fused decode attention on GPU: whole layer in one command buffer (keeps the GPU hot). * S<=4 absorption path with st0==0, DSA selection inactive, and GLM-5.2 int4 dims. */ if(g_metal_enabled && S<=4 && (g_absorb==1||(g_absorb<0&&S<=4)) && m->kv_start[layer]==0 && D==6144 && H==64 && c->q_lora==2048 && c->kv_lora==512 && c->qk_nope==192 && c->qk_rope==64 && vh==256 && l->kv_b.fmt==2){ int sel_active = m->has_dsa && layern_layers && c->idx_type[layer] && (pos_base+S) > c->index_topk; if(!sel_active){ if(m->has_dsa && layern_layers && c->idx_type[layer]){ /* index keys for future selection */ for(int s=0;sIc[layer]+(int64_t)pos*c->index_hd; matmul_qt(kd, x+(int64_t)s*D, &m->ix_wk[layer], 1); layernorm(kd, m->ix_knw[layer], m->ix_knb[layer], c->index_hd, 1e-6f); rope_interleave(kd, pos, c); } } #define WP_(q) ((q).fmt==1?(const void*)(q).q8:(const void*)(q).q4) int ok = coli_metal_attn_decode(x, WP_(l->q_a), l->q_a.s, l->q_a.fmt, l->q_a_ln, WP_(l->q_b), l->q_b.s, l->q_b.fmt, WP_(l->kv_a), l->kv_a.s, l->kv_a.fmt, l->kv_a_ln, WP_(l->kv_b), l->kv_b.s, l->kv_b.fmt, WP_(l->o), l->o.s, l->o.fmt, m->Lc[layer], m->Rc[layer], S, pos_base, m->kv_start[layer], c->eps, c->theta, c->attn_scale, out); #undef WP_ if(ok){ m->t_attn += now_s()-ta0; return; } } } #endif float *ctx=falloc((int64_t)S*H*vh); float *Q=falloc((int64_t)S*H*qh); /* query (roped) dei token nuovi */ float *QR=falloc((int64_t)S*c->q_lora), *comp=falloc(c->kv_lora+c->qk_rope); /* 1) per ogni token nuovo: query roped + latente normato e k_rot roped -> in cache. * QR tiene il residuo q_a per TUTTE le posizioni: serve anche all'indexer DSA. */ for(int s=0;skv; const float *xs=x+(int64_t)s*D; int pos=positions?positions[s]:pos_base+s; float *qresid=QR+(int64_t)s*c->q_lora; matmul_qt(qresid, xs, &l->q_a, 1); rmsnorm(qresid, qresid, l->q_a_ln, c->q_lora, c->eps); float *qfull=Q+(int64_t)s*H*qh; matmul_qt(qfull, qresid, &l->q_b, 1); for(int h=0;hqk_nope, pos, c); matmul_qt(comp, xs, &l->kv_a, 1); float *Ldst=coli_kv_row(ks->Lc[layer],pos,c->kv_lora); float *Rdst=coli_kv_row(ks->Rc[layer],pos,c->qk_rope); memcpy(Ldst, comp, c->kv_lora*sizeof(float)); rmsnorm(Ldst, Ldst, l->kv_a_ln, c->kv_lora, c->eps); /* latente normato */ memcpy(Rdst, comp+c->kv_lora, c->qk_rope*sizeof(float)); rope_interleave(Rdst, pos, c); /* k_rot roped, condiviso fra teste */ } /* ---- DSA lightning indexer ---- * Layer FULL: k_idx dei token nuovi in cache + selezione top-k per query (riusata * dai layer SHARED successivi). Selezione attiva solo con contesto > index_topk * (o DSA_FORCE=1 per il test: selezionare TUTTO deve dare l'output denso esatto). */ const int *dsel=NULL, *dnsel=NULL; int dtopk=0; if(m->has_dsa && layern_layers && ((!kvs && m->kv_start[layer]==0) || kvs)){ int nh=c->index_nh, hd=c->index_hd; dtopk=c->index_topk; if(c->idx_type[layer]){ for(int s=0;skv; const float *xs=x+(int64_t)s*D; int pos=positions?positions[s]:pos_base+s; float *kd=coli_kv_row(ks->Ic[layer],pos,hd); matmul_qt(kd, xs, &m->ix_wk[layer], 1); layernorm(kd, m->ix_knw[layer], m->ix_knb[layer], hd, 1e-6f); rope_interleave(kd, pos, c); /* primi qk_rope dim, interleaved */ } if((int64_t)S*dtopk > m->dsa_scap){ free(m->dsa_sel); free(m->dsa_nsel); m->dsa_scap=(int64_t)S*dtopk; m->dsa_sel=malloc((size_t)m->dsa_scap*sizeof(int)); m->dsa_nsel=malloc((size_t)S*sizeof(int)); } #pragma omp parallel for schedule(dynamic,1) for(int s=0;skv; int pos=positions?positions[s]:pos_base+s, nk=pos+1; if(ks->kv_start[layer]!=0){ m->dsa_nsel[s]=0; continue; } if(nk<=dtopk && !g_dsa_force){ m->dsa_nsel[s]=0; continue; } int keep = nkq_lora, &m->ix_wq[layer], 1); for(int h=0;hix_wp[layer], 1); float wsc=1.f/sqrtf((float)nh), rs=1.f/sqrtf((float)hd); float *isc=falloc(nk); for(int t=0;tIc[layer],t,hd); float a=0; for(int h=0;h0) a+=w32[h]*d0; /* ReLU sullo score, poi peso */ } isc[t]=a*wsc; } /* top-keep: soglia via qsort desc, poi scan in ordine di posizione */ float *tmp=falloc(nk); memcpy(tmp,isc,nk*sizeof(float)); qsort(tmp,nk,sizeof(float),cmp_fdesc); float thr=tmp[keep-1]; int *dst=m->dsa_sel+(int64_t)s*dtopk, nd=0; for(int t=0;tthr) dst[nd++]=t; for(int t=0;tdsa_nsel[s]=nd; free(qi); free(w32); free(isc); free(tmp); } } if(m->dsa_nsel){ dsel=m->dsa_sel; dnsel=m->dsa_nsel; } } /* WEIGHT ABSORPTION (DeepSeek): per S piccoli (decode/verifica MTP) NON si ricostruisce * k/v per ogni token del contesto. Per linearita': * q·k_nope_t = (W_K^hT q_nope)·L_t ctx^h = W_V^h (Σ_t a_t L_t) * costo per step ~O(T·kv_lora) invece di O(T·H·(nope+vh)) del matmul kvb_all. */ int absorb = kvs || g_absorb==1 || (g_absorb<0 && S<=4); if(absorb && c->kv_lora<=512){ m->t_aproj+=now_s()-ta0; double tac=now_s(); int kvl=c->kv_lora, r0v=c->qk_nope; /* offset righe V dentro il blocco di testa */ /* punteggi per-thread sul HEAP (vedi dev): cap Tk+1 copre anche il kv_start * per-slot del percorso kvs (MTP: kv_start=-1 -> nt=Tk+1). */ int64_t sc_cap = (int64_t)Tk+1; float *sc_all = falloc((int64_t)omp_get_max_threads()*sc_cap); int cuda_core=0; #ifdef COLI_CUDA if(S<=4&&g_cuda_enabled&&getenv("COLI_CUDA_ATTN")&&atoi(getenv("COLI_CUDA_ATTN"))&& l->kv_b.cuda_eligible&&qt_cuda_upload(&l->kv_b)){ cuda_core=1; for(int s=0;skv;int pos=positions?positions[s]:pos_base+s; int st0=ks->kv_start[layer],nt=pos+1-st0; if(dnsel&&dnsel[s]>0){cuda_core=0;break;} cuda_core=coli_cuda_attention_absorb(l->kv_b.cuda,ctx+(int64_t)s*H*vh, Q+(int64_t)s*H*qh,coli_kv_row(ks->Lc[layer],st0,kvl), coli_kv_row(ks->Rc[layer],st0,c->qk_rope),H,c->qk_nope,c->qk_rope, vh,kvl,nt,c->attn_scale); } } #endif if(!cuda_core){ #pragma omp parallel for collapse(2) schedule(static) for(int s=0;skv; int pos=positions?positions[s]:pos_base+s; const float *qp=Q+(int64_t)s*H*qh+(int64_t)h*qh; const float *qr=qp+c->qk_nope; int rbase=h*(c->qk_nope+vh); float qabs[512]; memset(qabs,0,kvl*sizeof(float)); for(int d=0;dqk_nope;d++) qt_addrow(&l->kv_b, rbase+d, qp[d], qabs); float *sc = sc_all + (int64_t)omp_get_thread_num()*sc_cap; int st0=ks->kv_start[layer]; int ns = (dnsel && dnsel[s]>0) ? dnsel[s] : 0; /* DSA: lista top-k o range pieno */ const int *tlist = ns ? dsel+(int64_t)s*dtopk : NULL; int nt = ns ? ns : pos+1-st0; for(int jj=0;jjLc[layer],t,kvl); const float *kr=coli_kv_row(ks->Rc[layer],t,c->qk_rope); float a=0; for(int i=0;iqk_rope;d++) a+=qr[d]*kr[d]; sc[jj]=a*c->attn_scale; } softmax(sc,nt); float clat[512]; memset(clat,0,kvl*sizeof(float)); for(int jj=0;jjLc[layer],t,kvl); float a=sc[jj]; for(int i=0;ikv_b, rbase+r0v, vh, clat, ctx+((int64_t)s*H+h)*vh); } } m->t_acore+=now_s()-tac; double tao=now_s(); matmul_qt(out, ctx, &l->o, S); m->t_aout+=now_s()-tao; free(ctx); free(Q); free(QR); free(comp); free(sc_all); m->t_attn += now_s()-ta0; return; } /* 2) ricostruzione di k_nope+value per TUTTI i token 0..Tk-1 (un solo matmul su kv_b) */ m->t_aproj+=now_s()-ta0; double tk0=now_s(); int stL=m->kv_start[layer]; float *kvb_all=falloc((int64_t)Tk*kvb_dim); matmul_qt(kvb_all+(int64_t)stL*kvb_dim, m->Lc[layer]+(int64_t)stL*c->kv_lora, &l->kv_b, Tk-stL); m->t_kvb += now_s()-tk0; /* 3) attenzione causale: score = q_pass·k_nope + q_rot·k_rot * (punteggi sul heap, per-thread: vedi il commento nel ramo absorb) */ int64_t sc_cap = Tk - stL; float *sc_all = falloc((int64_t)omp_get_max_threads()*sc_cap); double tac=now_s(); #pragma omp parallel for collapse(2) schedule(static) for(int s=0;sqk_nope; float *sc = sc_all + (int64_t)omp_get_thread_num()*sc_cap; int st0=m->kv_start[layer]; int ns = (dnsel && dnsel[s]>0) ? dnsel[s] : 0; /* DSA: lista top-k o range pieno */ const int *tlist = ns ? dsel+(int64_t)s*dtopk : NULL; int nt = ns ? ns : pos+1-st0; for(int jj=0;jjqk_nope+vh); const float *kr=m->Rc[layer]+(int64_t)t*c->qk_rope; float a=0; for(int d=0;dqk_nope;d++) a+=qp[d]*kn[d]; for(int d=0;dqk_rope;d++) a+=qr[d]*kr[d]; sc[jj]=a*c->attn_scale; } softmax(sc,nt); float *cx=ctx+((int64_t)s*H+h)*vh; for(int d=0;dqk_nope+vh)+c->qk_nope; float a=sc[jj]; for(int d=0;dt_acore+=now_s()-tac; double tao=now_s(); matmul_qt(out, ctx, &l->o, S); m->t_aout+=now_s()-tao; free(ctx); free(Q); free(QR); free(comp); free(kvb_all); free(sc_all); m->t_attn += now_s()-ta0; } static void attention(Model *m, Layer *l, int layer, float *x, int S, int pos_base, float *out){ attention_rows(m,l,layer,x,S,pos_base,NULL,NULL,out); } /* MoE GLM su x[S,hidden] -> out (router sigmoid/noaux_tc, n_group=1, + shared expert). * BATCH-UNION: per S>1 (prefill, verifica MTP) ogni expert UNICO del batch viene caricato * una volta sola e moltiplicato per tutte le posizioni che lo usano (pesi letti 1 volta); * lo shared expert e' un unico matmul a S righe. Per posizione l'accumulo resta * nell'ordine (routed nel loro ordine di union, poi shared). */ static void moe(Model *m, Layer *l, int layer, float *x, int S, float *out){ if(g_pilot_real){ /* barriera cross-layer: prendi possesso di QUESTO layer e aspetta * l'eventuale load-pilota in volo sullo stesso layer (dopodiche' il * worker droppa ogni nuovo load <= layer -> ecache[layer] e' stabile * per tutto il resolve/matmul/promozione qui sotto). */ for(;;){ pthread_mutex_lock(&g_pilot_mx); atomic_store_explicit(&g_cur_moe_layer,layer,memory_order_release); int inf=atomic_load_explicit(&g_pilot_inflight,memory_order_acquire); pthread_mutex_unlock(&g_pilot_mx); if(inf!=layer) break; sched_yield(); } } Cfg *c=&m->c; int D=c->hidden, E=c->n_experts, K=c->topk, I=c->moe_inter; float *logit=falloc(E), *choice=falloc(E); int sI=c->moe_inter*c->n_shared; /* ---- FASE A: routing di tutte le S posizioni ---- */ int *idxs=malloc((size_t)S*K*sizeof(int)); float *ws=malloc((size_t)S*K*sizeof(float)); int *keff=malloc(S*sizeof(int)); #ifdef COLI_METAL if(g_pre_idx){ /* routing gia' calcolata dal layer CB (GPU) */ memcpy(idxs,g_pre_idx,(size_t)S*K*sizeof(int)); memcpy(ws,g_pre_w,(size_t)S*K*sizeof(float)); memcpy(keff,g_pre_keff,(size_t)S*sizeof(int)); for(int s=0;sereq+=keff[s]; for(int kk=0;kkeusage[layer][idxs[(int64_t)s*K+kk]]++; if(m->eheat[layer][idxs[(int64_t)s*K+kk]]eheat[layer][idxs[(int64_t)s*K+kk]]++; } for(int d=0;drouter, 1, D, E); for(int e=0;erouter_bias[e]; } int *idx=idxs+(int64_t)s*K; float *w=ws+(int64_t)s*K; int Ksel = g_topk>0 ? (g_topkbv){bv=choice[e];best=e;} } idx[kk]=best; w[kk]=logit[best]; } int Ke=Ksel; if(g_topp>0 && g_topp<1.f){ for(int a=1;a=0 && w[b]=g_topp*tot){ Ke=kk+1; break; } } } keff[s]=Ke; m->ereq+=Ke; for(int kk=0;kkeusage[layer][idx[kk]]++; if(m->eheat[layer][idx[kk]]eheat[layer][idx[kk]]++; m->elast[layer][idx[kk]]=++m->eaccess_clock; } if(c->norm_topk){ float sm=0; for(int kk=0;kkrouted_scale; for(int d=0;dn_layers){ int Ke=keff[0]; if(m->enr[layer]>0){ /* [0] vs routing del token precedente */ for(int kk=0;kkenr[layer];z++) if(m->eroute[layer][z]==idxs[kk]){ la_hit[0]++; break; } la_tot[0]+=Ke; } for(int kind=0;kind<2;kind++) if(la_val[kind][layer]){ /* [1]/[2] vs predizioni */ for(int kk=0;kkenr[layer]=keff[S-1]; for(int kk=0;kkeroute[layer][kk]=idxs[(int64_t)(S-1)*K+kk]; /* ---- FASE B: union degli expert del batch ---- */ int *uniq=malloc((size_t)E*sizeof(int)); int nu=0; unsigned char seen[E]; memset(seen,0,(size_t)E); for(int s=0;spin[layer]; for(int z=0;znpin[layer];z++) if(P[z].eid==eid){ m->hits++; use[j]=&P[z]; break; } if(!use[j]){ ESlot *Sl=m->ecache[layer]; int nn=m->ecn[layer]; for(int z=0;zhits++; Sl[z].used=(uint64_t)__atomic_add_fetch(&m->eclock,1,__ATOMIC_RELAXED); use[j]=&Sl[z]; break; } } if(!use[j]){ qof[j]=nmiss; use[j]=&m->ws[nmiss]; missk[nmiss++]=j; m->miss++; } } int metal_done=0; #ifdef COLI_METAL /* GPU/disk OVERLAP: submit the RESIDENT experts (pin/LRU hits, + shared expert on * the first block) to the GPU BEFORE loading the missed experts from disk, so the * preads run while the GPU computes; the missed subset follows in a second submit. * Per-subset CPU fallback on unresolved slab / bad fmt / GPU fault. */ int is_miss[64]={0}; ColiMetalMoeHandle *mh=NULL; int cpu_res=1, cpu_miss=1, mh_shared=0, nbb=0, Rtot=0, mfmt=-1, sh_in=0; const void *MG[65],*MU[65],*MD[65]; const float *MGS[65],*MUS[65],*MDS[65]; int xoffb[65],nrb[65]; float *mxg=NULL; int *mrows=NULL; float *mrw=NULL; /* subset builder: experts with is_miss==WANTMISS (+ shared expert when TRY_SH) */ #define MB_BUILD(WANTMISS, TRY_SH) do{ \ nbb=0; Rtot=0; mfmt=-1; sh_in=0; \ for(int j=0;jg.fmt; \ MG[nbb]=e->g.fmt==1?(const void*)e->g.q8:(const void*)e->g.q4; \ MU[nbb]=e->u.fmt==1?(const void*)e->u.q8:(const void*)e->u.q4; \ MD[nbb]=e->d.fmt==1?(const void*)e->d.q8:(const void*)e->d.q4; \ MGS[nbb]=e->g.s; MUS[nbb]=e->u.s; MDS[nbb]=e->d.s; \ xoffb[nbb]=Rtot; nrb[nbb]=cnt; Rtot+=cnt; nbb++; \ } \ if(TRY_SH){ int shf = mfmt<0 ? l->sh_gate.fmt : mfmt; \ if(c->n_shared==1 && sI==I && l->sh_gate.fmt==shf && l->sh_up.fmt==shf && l->sh_down.fmt==shf){ \ if(mfmt<0) mfmt=shf; \ MG[nbb]=shf==1?(const void*)l->sh_gate.q8:(const void*)l->sh_gate.q4; \ MU[nbb]=shf==1?(const void*)l->sh_up.q8 :(const void*)l->sh_up.q4; \ MD[nbb]=shf==1?(const void*)l->sh_down.q8:(const void*)l->sh_down.q4; \ MGS[nbb]=l->sh_gate.s; MUS[nbb]=l->sh_up.s; MDS[nbb]=l->sh_down.s; \ xoffb[nbb]=Rtot; nrb[nbb]=S; Rtot+=S; nbb++; sh_in=1; } } \ int p=0; \ for(int j=0;j0){ double t0=now_s(); mh=coli_metal_moe_block_begin(nbb,D,I,mfmt,MG,MU,MD,MGS,MUS,MDS,mxg,xoffb,nrb,mrows,mrw); m->t_emm += now_s()-t0; if(mh){ cpu_res=0; mh_shared=sh_in; } } else cpu_res=0; } #endif /* Expert loads run HERE, after the resident-experts GPU submit above: under METAL the * preads overlap the GPU compute (that submit is async). With METAL off the submit block * is a no-op / compiled out, so this sits exactly where dev put it and CPU behaviour is * unchanged. */ if(nmiss){ if(g_pipe){ /* PIPE: launch loads async, matmul overlaps them */ if(!g_pp.started) pipe_init(m); double t0=now_s(); int eids[64]; for(int q=0;qt_edisk += now_s()-t0; /* dispatch only; real reads hide behind matmul */ } else { double t0=now_s(); /* ORIGINALE: blocking parallel load */ #pragma omp parallel for schedule(dynamic,1) for(int q=0;qws[q],1); m->t_edisk += now_s()-t0; } } /* I/O ASINCRONO: readahead (WILLNEED) del blocco SUCCESSIVO mentre calcoliamo * questo — il kernel legge in background, le pread dopo trovano cache calda */ if(base+64pin[layer]; for(int z=0;znpin[layer] && !found;z++) if(P[z].eid==eid) found=1; ESlot *Sl=m->ecache[layer]; for(int z=0;zecn[layer] && !found;z++) if(Sl[z].eid==eid) found=1; if(!found) expert_prefetch(m,layer,eid); } } #ifdef COLI_CUDA ESlot *group_e[64]; int group_n[64]; int ngroup=0; #endif #ifdef COLI_METAL if(g_metal_enabled){ /* PIPE drain. Two reasons this barrier is mandatory here, and not optional: * 1) MB_BUILD(1) hands the missed experts' slabs straight to the GPU — a slot still * being pread by an I/O worker would be matmul-ed half-loaded. * 2) PIPE's only drain barrier is the per-expert pipe_wait() in the CPU matmul loop * below, which metal_done SKIPS ENTIRELY. Without this, a still-writing worker * would race the end-of-block LRU swap that recycles ws[]. * pipe_wait() is an idempotent spin on ready[q], so the per-expert waits below stay * correct (and free) when a subset falls back to the CPU. */ if(g_pipe && nmiss){ double tw=now_s(); for(int q=0;qt_edisk += now_s()-tw; } MB_BUILD(1, 0); /* missed experts, now loaded */ if(nbb>0){ double t0=now_s(); if(coli_metal_moe_block(nbb,D,I,mfmt,MG,MU,MD,MGS,MUS,MDS,mxg,xoffb,nrb,mrows,mrw,out,S)) cpu_miss=0; m->t_emm += now_s()-t0; } else cpu_miss=0; if(mh){ double t0=now_s(); if(coli_metal_moe_block_end(mh,out)){ if(mh_shared) shared_on_gpu=1; } else cpu_res=1; m->t_emm += now_s()-t0; mh=NULL; } metal_done = (!cpu_res && !cpu_miss); free(mxg); free(mrows); free(mrw); } #undef MB_BUILD #endif if(!metal_done) for(int j=0;j=1 routing invariant. * Stays ABOVE the METAL skip: a subset that fell back to the CPU still needs its * slot drained here, and under METAL the block-level drain above already ran (this * spin is then a no-op). */ if(g_pipe && qof[j]>=0){ double tw=now_s(); pipe_wait(qof[j]); m->t_edisk += now_s()-tw; } #ifdef COLI_METAL /* skip the subsets already computed on GPU */ if(g_metal_enabled && ((is_miss[j] && !cpu_miss) || (!is_miss[j] && !cpu_res))) continue; #endif int nr=0; /* righe (posizioni) che usano questo expert */ for(int s=0;sg.cuda_eligible) m->gpu_expert_calls++; if(group_enabled && g_cuda_enabled && e->g.cuda_eligible && e->u.cuda_eligible && e->d.cuda_eligible && !omp_in_parallel()){ group_e[ngroup]=e; group_n[ngroup]=nr; for(int r=0;rg.cuda_eligible && e->u.cuda_eligible && e->d.cuda_eligible && !omp_in_parallel() && coli_cuda_expert_mlp(e->g.cuda,e->u.cuda,e->d.cuda,hh,xg,nr)){ for(int r=0;rt_emm+=now_s()-t0; continue; } if(!e->slab) expert_host_ensure(m,layer,e); #endif expert_gate_up(gg,uu,xg,&e->g,&e->u,nr); for(int64_t z=0;z<(int64_t)nr*I;z++) gg[z]=siluf(gg[z])*uu[z]; matmul_qt(hh, gg, &e->d, nr); for(int r=0;rt_emm += now_s()-t0; } #ifdef COLI_CUDA ColiCudaTensor *dev_g[COLI_CUDA_MAX_DEVICES][64],*dev_u[COLI_CUDA_MAX_DEVICES][64]; ColiCudaTensor *dev_d[COLI_CUDA_MAX_DEVICES][64]; int dev_rows[COLI_CUDA_MAX_DEVICES][64],dev_which[COLI_CUDA_MAX_DEVICES][64]; int dev_nc[COLI_CUDA_MAX_DEVICES]={0},dev_total[COLI_CUDA_MAX_DEVICES]={0}; int dev_off[COLI_CUDA_MAX_DEVICES]={0},dev_ok[COLI_CUDA_MAX_DEVICES]={0}; for(int di=0;dig.cuda_device==g_cuda_devices[di]) dev_total[di]+=group_n[q]; for(int di=1;dig.cuda_device==device){ int nc=dev_nc[di]++; ESlot *e=group_e[q]; dev_g[di][nc]=e->g.cuda; dev_u[di][nc]=e->u.cuda; dev_d[di][nc]=e->d.cuda; dev_rows[di][nc]=group_n[q]; dev_which[di][nc]=q; for(int r=0;r1) schedule(static) for(int di=0;dig.cuda,e->u.cuda,e->d.cuda,hh,xg,nr)){ expert_host_ensure(m,layer,e); expert_gate_up(gg,uu,xg,&e->g,&e->u,nr); for(int64_t z=0;z<(int64_t)nr*I;z++) gg[z]=siluf(gg[z])*uu[z]; matmul_qt(hh,gg,&e->d,nr); } } float *src=dev_ok[di]?group_y+(int64_t)off*D:hh; for(int r=0;rt_emm+=now_s()-tg; #endif /* No drain barrier: the per-expert pipe_wait(qof[j]) above (issued for every * dispatched miss slot, before the nr==0 skip) already waited on all ws[] loads * for this block, so they are complete before the LRU swap — and the gen-tagged * cursor keeps any still-spinning worker off a wrong-generation slot. */ { ESlot *Sl=m->ecache[layer]; int *nn=&m->ecn[layer]; /* promozione LRU (swap buffer) */ int promo = nmissecap ? nmiss : m->ecap; for(int a=0;aecap) dst=&Sl[(*nn)++]; else { int lru=0; for(int z=1;z<*nn;z++) if(Sl[z].usedws[q]; m->ws[q]=tmp; dst->used=(uint64_t)__atomic_add_fetch(&m->eclock,1,__ATOMIC_RELAXED); } } } /* ---- FASE E: shared expert, un matmul a S righe (skipped se fuso nel blocco GPU) ---- */ float *sg=falloc((int64_t)S*sI), *su=falloc((int64_t)S*sI); #ifdef COLI_METAL if(g_pre_sh){ for(int64_t z=0;z<(int64_t)S*D;z++) out[z]+=g_pre_sh[z]; shared_on_gpu=1; } #endif if(!shared_on_gpu){ matmul_qt(sg, x, &l->sh_gate, S); matmul_qt(su, x, &l->sh_up, S); for(int64_t z=0;z<(int64_t)S*sI;z++) sg[z]=siluf(sg[z])*su[z]; matmul_qt(hh, sg, &l->sh_down, S); for(int64_t z=0;z<(int64_t)S*D;z++) out[z]+=hh[z]; } free(logit); free(choice); free(idxs); free(ws); free(keff); free(uniq); free(xg); free(gg); free(uu); free(hh); free(rows); free(rw); free(sg); free(su); #ifdef COLI_CUDA free(group_x); free(group_y); free(group_row); free(group_weight); #endif } static void dense_mlp(Layer *l, float *x, int S, int D, int I, float *out){ float *g=falloc((int64_t)S*I), *u=falloc((int64_t)S*I); matmul_qt(g, x, &l->gate_proj, S); matmul_qt(u, x, &l->up_proj, S); for(int64_t i=0;i<(int64_t)S*I;i++) g[i]=siluf(g[i])*u[i]; matmul_qt(out, g, &l->down_proj, S); free(g); free(u); } /* LOOKA: predice il top-K del router del layer `target` dallo stato h (residual stream), * usando la STESSA pipeline del routing vero (post_ln -> router -> sigmoid+bias, top-K). * kind 0 = stesso layer saltando l'attention, kind 1 = layer successivo. */ static void la_predict(Model *m, int target, const float *h, int kind){ Cfg *c=&m->c; Layer *l=&m->L[target]; int D=c->hidden, E=c->n_experts, K=c->topk; float *nrm=falloc(D), *ch=falloc(E); rmsnorm(nrm,h,l->post_ln,D,c->eps); matmul(ch,nrm,l->router,1,D,E); for(int e=0;erouter_bias[e]; int *pred=la_pred[kind][target]; for(int kk=0;kkbv){bv=ch[e];best=e;} } pred[kk]=best; } la_val[kind][target]=1; free(nrm); free(ch); } /* PILOTA: prefetch guidato dal router. Predice il top-K del layer L+1 dallo stato * post-attention di L (recall misurato 71.6% su GLM-5.2, vs 41.3% del token precedente) * e lancia il WILLNEED degli expert mancanti MENTRE il MoE di L legge i suoi: il disco * lavora nei tempi morti del calcolo invece di aspettare il routing vero. Con MTP attiva * predice per TUTTE le posizioni del draft: la speculazione pilota anche l'I/O. * PILOT_K limita alle prime k predizioni (la testa del ranking e' piu' affidabile * della coda: meno banda sprecata sulle predizioni sbagliate). * * I WILLNEED partono da un THREAD I/O dedicato: con la coda disco satura la submit * del fadvise BLOCCA (~0.5ms x 169k chiamate = +92s/48 token, misurato) — inline * il pilota costava piu' di quanto rendesse. Ring lock-free 1P/1C; pieno = scarta * (un hint perso non e' un errore). */ static struct { int l,e; } pilot_q[4096]; static volatile unsigned pilot_w=0, pilot_r=0; static Model *pilot_m=NULL; /* PILOT_REAL: load VERO dell'expert predetto dentro la LRU del layer FUTURO. Vedi * l'invariante di sicurezza accanto a g_pilot_real. Il pread (lento) gira FUORI dal lock; * il lock protegge solo la scelta/pubblicazione dello slot e l'handshake col main. */ static void pilot_realload(Model *m, int layer, int eid){ pthread_mutex_lock(&g_pilot_mx); if(layer <= atomic_load_explicit(&g_cur_moe_layer,memory_order_acquire)){ atomic_fetch_add_explicit(&g_pilot_drops,1,memory_order_relaxed); pthread_mutex_unlock(&g_pilot_mx); return; /* il main possiede gia' questo layer */ } ESlot *P=m->pin[layer]; /* gia' residente (pin o ecache)? skip */ for(int z=0;znpin[layer];z++) if(P[z].eid==eid){ pthread_mutex_unlock(&g_pilot_mx); return; } ESlot *Sl=m->ecache[layer]; int nn=m->ecn[layer]; for(int z=0;zecap){ slot=nn; isnew=1; } else { int lru=0; for(int z=1;zeid=-1; /* nascondi dagli scan-hint mentre carica */ atomic_store_explicit(&g_pilot_inflight,layer,memory_order_release); pthread_mutex_unlock(&g_pilot_mx); int rc=expert_load(m,layer,eid,dst,0); /* pread VERO — fuori dal lock, sovrapposto al compute; fatal=0: un errore su una speculazione NON deve uccidere il server */ pthread_mutex_lock(&g_pilot_mx); if(rc==0){ dst->used=(uint64_t)__atomic_add_fetch(&m->eclock,1,__ATOMIC_RELAXED); if(isnew) m->ecn[layer]=slot+1; /* pubblica lo slot SOLO ora che eid e' valido */ atomic_fetch_add_explicit(&g_pilot_loads,1,memory_order_relaxed); } else { atomic_fetch_add_explicit(&g_pilot_drops,1,memory_order_relaxed); /* load fallito: slot resta nascosto (eid=-1), mai pubblicato */ } atomic_store_explicit(&g_pilot_inflight,-1,memory_order_release); pthread_mutex_unlock(&g_pilot_mx); if(rc!=0) /* mai swallow silenzioso: logga (una riga) e prosegui */ fprintf(stderr,"[PILOT] load speculativo abbandonato: layer %d expert %d (I/O error/short read) — nessun impatto sull'output\n",layer,eid); } static void *pilot_worker(void *arg){ (void)arg; for(;;){ unsigned r=__atomic_load_n(&pilot_r,__ATOMIC_ACQUIRE); unsigned w=__atomic_load_n(&pilot_w,__ATOMIC_ACQUIRE); if(r==w){ usleep(200); continue; } if(g_pilot_real) pilot_realload(pilot_m, pilot_q[r&4095].l, pilot_q[r&4095].e); else expert_prefetch(pilot_m, pilot_q[r&4095].l, pilot_q[r&4095].e); __atomic_store_n(&pilot_r,r+1,__ATOMIC_RELEASE); } return NULL; } static void pilot_prefetch(Model *m, int lnext, const float *x, int S){ Cfg *c=&m->c; Layer *l=&m->L[lnext]; int D=c->hidden, E=c->n_experts; int K = g_pilot_ktopk ? g_pilot_k : c->topk; if(!pilot_m){ pilot_m=m; pthread_t t; pthread_create(&t,NULL,pilot_worker,NULL); } float *nrm=falloc(D), *ch=falloc(E); for(int s=0;spost_ln, D, c->eps); matmul(ch, nrm, l->router, 1, D, E); for(int e=0;erouter_bias[e]; for(int kk=0;kkch[best]) best=e; ch[best]=-2e30f; /* Residency scan of the FUTURE layer lnext under g_pilot_mx: with * PILOT_REAL=1 the pilot worker mutates ecache[lnext]/ecn[lnext] * concurrently, so read them under the same lock (Option A). Decide * under the lock, then enqueue AFTER unlocking — the pilot_q ring is * lock-free (pilot_w/pilot_r atomics, not g_pilot_mx) so there is no * re-entrant double-lock, and the worker re-checks residency under the * lock anyway, making a racing redundant enqueue harmless. */ int found=0; pthread_mutex_lock(&g_pilot_mx); ESlot *P=m->pin[lnext]; for(int z=0;znpin[lnext] && !found;z++) if(P[z].eid==best) found=1; ESlot *Sl=m->ecache[lnext]; for(int z=0;zecn[lnext] && !found;z++) if(Sl[z].eid==best) found=1; pthread_mutex_unlock(&g_pilot_mx); if(!found){ unsigned w=__atomic_load_n(&pilot_w,__ATOMIC_RELAXED); if(w-__atomic_load_n(&pilot_r,__ATOMIC_ACQUIRE)<4096){ pilot_q[w&4095].l=lnext; pilot_q[w&4095].e=best; __atomic_store_n(&pilot_w,w+1,__ATOMIC_RELEASE); } } } } free(nrm); free(ch); } /* forward di UN layer (usato dai 78 principali e dal layer MTP) */ static void layer_forward_rows(Model *m, Layer *l, int li, float *x, int S, int pos_base, KVState *const *kvs, const int *positions, float *nrm, float *tmp){ Cfg *c=&m->c; int D=c->hidden; if(g_spec && g_prefetch && l->sparse && m->enr[li]>0) for(int z=0;zenr[li];z++) expert_prefetch(m,li,m->eroute[li][z]); if(g_looka && S==1 && lin_layers && l->sparse) la_predict(m,li,x,0); #ifdef COLI_METAL /* FULL-LAYER CB: in_ln + attention + residuo + post_ln + shared expert + router/top-K * in un solo submit GPU; la CPU legge il routing e fa solo resolve/disk/expert-CB. * Fallback: qualsiasi condizione mancante -> percorso CPU intero qui sotto. */ if(g_metal_enabled && S<=4 && lin_layers && l->sparse && (g_absorb==1||(g_absorb<0&&S<=4)) && m->kv_start[li]==0 && D==6144 && c->n_heads==64 && c->q_lora==2048 && c->kv_lora==512 && c->qk_nope==192 && c->qk_rope==64 && c->v_head==256 && l->kv_b.fmt==2 && c->n_experts==256 && c->topk==8 && c->n_shared==1 && c->moe_inter==2048){ int sel_active = m->has_dsa && c->idx_type[li] && (pos_base+S) > c->index_topk; if(!sel_active){ static float *linrm,*lnrm,*lsh,*lw; static int *lidx,*lkeff; if(!linrm){ linrm=falloc(4*(int64_t)D); lnrm=falloc(4*(int64_t)D); lsh=falloc(4*(int64_t)D); lidx=malloc(4*8*sizeof(int)); lw=malloc(4*8*sizeof(float)); lkeff=malloc(4*sizeof(int)); } int Ksel = g_topk>0 ? (g_topk<8?g_topk:8) : 8; float tp = (g_topp>0 && g_topp<1.f) ? g_topp : 0.f; double ta0=now_s(); #define WP_(q) ((q).fmt==1?(const void*)(q).q8:(const void*)(q).q4) int ok = coli_metal_layer_decode(x, l->in_ln, l->post_ln, WP_(l->q_a), l->q_a.s, l->q_a.fmt, l->q_a_ln, WP_(l->q_b), l->q_b.s, l->q_b.fmt, WP_(l->kv_a), l->kv_a.s, l->kv_a.fmt, l->kv_a_ln, WP_(l->kv_b), l->kv_b.s, l->kv_b.fmt, WP_(l->o), l->o.s, l->o.fmt, WP_(l->sh_gate), l->sh_gate.s, l->sh_gate.fmt, WP_(l->sh_up), l->sh_up.s, l->sh_up.fmt, WP_(l->sh_down), l->sh_down.s, l->sh_down.fmt, l->router, l->router_bias, c->n_experts, c->topk, Ksel, tp, c->norm_topk, c->routed_scale, m->Lc[li], m->Rc[li], S, pos_base, m->kv_start[li], c->eps, c->theta, c->attn_scale, linrm, lnrm, lsh, lidx, lw, lkeff); #undef WP_ if(ok){ m->t_attn += now_s()-ta0; if(m->has_dsa && c->idx_type[li]){ /* index key per selezioni future */ for(int s=0;sIc[li]+(int64_t)pos*c->index_hd; matmul_qt(kd, linrm+(int64_t)s*D, &m->ix_wk[li], 1); layernorm(kd, m->ix_knw[li], m->ix_knb[li], c->index_hd, 1e-6f); rope_interleave(kd, pos, c); } } if(g_pilot && S<=8 && li+1n_layers && m->L[li+1].sparse) pilot_prefetch(m,li+1,x,S); if(g_looka && S==1 && li+1n_layers && m->L[li+1].sparse) la_predict(m,li+1,x,1); g_pre_idx=lidx; g_pre_w=lw; g_pre_keff=lkeff; g_pre_sh=lsh; moe(m,l,li,lnrm,S,tmp); g_pre_idx=NULL; g_pre_w=NULL; g_pre_keff=NULL; g_pre_sh=NULL; for(int64_t j=0;j<(int64_t)S*D;j++) x[j]+=tmp[j]; return; } } } #endif for(int s=0;sin_ln, D, c->eps); attention_rows(m,l,li,nrm,S,pos_base,kvs,positions,tmp); for(int64_t j=0;j<(int64_t)S*D;j++) x[j]+=tmp[j]; if(g_pilot && S<=8 && li+1n_layers && m->L[li+1].sparse) pilot_prefetch(m,li+1,x,S); if(g_looka && S==1 && li+1n_layers && m->L[li+1].sparse) la_predict(m,li+1,x,1); for(int s=0;spost_ln, D, c->eps); if(l->sparse) moe(m,l,li,nrm,S,tmp); else dense_mlp(l,nrm,S,D,c->dense_inter,tmp); for(int64_t j=0;j<(int64_t)S*D;j++) x[j]+=tmp[j]; } static void layer_forward(Model *m, Layer *l, int li, float *x, int S, int pos_base, float *nrm, float *tmp){ layer_forward_rows(m,l,li,x,S,pos_base,NULL,NULL,nrm,tmp); } static void layers_forward_rows(Model *m, float *x, int S, int pos_base, KVState *const *kvs, const int *positions){ Cfg *c=&m->c; int D=c->hidden; if(g_pilot_real){ /* nuovo forward: il possesso-layer riparte da -1 (i layer si rifanno da 0) */ pthread_mutex_lock(&g_pilot_mx); atomic_store_explicit(&g_cur_moe_layer,-1,memory_order_release); pthread_mutex_unlock(&g_pilot_mx); } float *nrm=falloc((int64_t)S*D), *tmp=falloc((int64_t)S*D); for(int i=0;in_layers;i++){ /* progresso su stderr per i batch grossi (prefill): il primo byte di risposta * puo' arrivare dopo MINUTI di streaming — al buio sembra un blocco. */ if(S>=8 && (i%4==0 || i==c->n_layers-1)) fprintf(stderr,"[prefill] layer %d/%d · %d token\n", i+1, c->n_layers, S); layer_forward_rows(m,&m->L[i],i,x,S,pos_base,kvs,positions,nrm,tmp); } free(nrm); free(tmp); } static void layers_forward(Model *m, float *x, int S, int pos_base){ layers_forward_rows(m,x,S,pos_base,NULL,NULL); } static void kv_alloc(Model *m, int max_t){ Cfg *c=&m->c; KVState *k=m->kv; if(k->Lc){ for(int i=0;in_layers+1;i++){ #ifdef COLI_METAL if(g_metal_enabled){ coli_metal_unregister(k->Lc[i]); coli_metal_unregister(k->Rc[i]); } #endif free(k->Lc[i]); free(k->Rc[i]); } free(k->Lc); free(k->Rc); } if(k->Ic){ for(int i=0;in_layers;i++) free(k->Ic[i]); free(k->Ic); k->Ic=NULL; } if(m->has_dsa){ k->Ic=calloc(c->n_layers,sizeof(float*)); for(int i=0;in_layers;i++) if(c->idx_type[i]) k->Ic[i]=falloc((int64_t)max_t*c->index_hd); } k->max_t=max_t; int NR=c->n_layers+1; /* riga extra: KV del layer MTP */ k->Lc=calloc(NR,sizeof(float*)); k->Rc=calloc(NR,sizeof(float*)); for(int i=0;iLc[i]=falloc((int64_t)max_t*c->kv_lora); k->Rc[i]=falloc((int64_t)max_t*c->qk_rope); #ifdef COLI_METAL /* page-align + register Lc/Rc for zero-copy GPU attention. falloc isn't 16K-aligned, * so re-allocate aligned and register the exact byte length. */ if(g_metal_enabled){ size_t lb=(((size_t)max_t*c->kv_lora*sizeof(float))+16383)&~(size_t)16383; size_t rb=(((size_t)max_t*c->qk_rope*sizeof(float))+16383)&~(size_t)16383; free(k->Lc[i]); free(k->Rc[i]); void *lp,*rp; if(posix_memalign(&lp,16384,lb)||posix_memalign(&rp,16384,rb)){fprintf(stderr,"OOM kv\n");exit(1);} k->Lc[i]=lp; k->Rc[i]=rp; coli_metal_register(k->Lc[i],lb); coli_metal_register(k->Rc[i],rb); } #endif } m->Lc=k->Lc; m->Rc=k->Rc; m->Ic=k->Ic; m->max_t=k->max_t; m->kv_start=k->kv_start; } static void kv_bind(Model *m, KVState *k){ m->kv=k; m->Lc=k->Lc; m->Rc=k->Rc; m->Ic=k->Ic; m->max_t=k->max_t; m->kv_start=k->kv_start; } static void mtp_absorb(Model *m, const int *next_ids, const float *x, int S, int pos_base); static float *step(Model *m, const int *ids, int S, int pos_base){ Cfg *c=&m->c; int D=c->hidden; float *x=falloc((int64_t)S*D); for(int s=0;shlast) memcpy(m->hlast, x+(int64_t)(S-1)*D, D*sizeof(float)); if(m->has_mtp && S>=2 && g_draft>0) mtp_absorb(m, ids+1, x, S-1, pos_base); float *last=falloc(D); rmsnorm(last, x+(int64_t)(S-1)*D, m->final_norm, D, c->eps); double th0=now_s(); float *logit=falloc(c->vocab); matmul_qt(logit,last,&m->lm_head,1); m->t_head += now_s()-th0; free(x); free(last); return logit; } /* come step(), ma ritorna i logits di TUTTE le S posizioni [S,vocab] (per la verifica spec) */ static float *step_all(Model *m, const int *ids, int S, int pos_base){ Cfg *c=&m->c; int D=c->hidden; float *x=falloc((int64_t)S*D); for(int s=0;sh_all) memcpy(m->h_all, x, (int64_t)S*D*sizeof(float)); /* hidden di TUTTE le pos (S<=64) */ if(m->hlast) memcpy(m->hlast, x+(int64_t)(S-1)*D, D*sizeof(float)); float *lo=falloc((int64_t)S*c->vocab), *row=falloc(D); for(int s=0;sfinal_norm, D, c->eps); matmul_qt(lo+(int64_t)s*c->vocab, row, &m->lm_head, 1); } free(x); free(row); return lo; } /* One decode token from each independent sequence, evaluated as a single MoE * batch. Prefill and speculative batches retain their contiguous-KV path. */ static float *step_decode_batch(Model *m, const DecodeRow *rows, int S){ Cfg *c=&m->c; int D=c->hidden; /* Ragged KV currently uses MLA absorption; the stack kernel is sized to 512. */ if(!rows || S<1 || S>64 || c->kv_lora>512) return NULL; KVState *kvs[64]; int positions[64]; float *x=falloc((int64_t)S*D); for(int s=0;sLc || !rows[s].kv->Rc || !rows[s].kv->kv_start || rows[s].token<0 || rows[s].token>=c->vocab || rows[s].pos<0 || rows[s].pos>=rows[s].kv->max_t){ free(x); return NULL; } for(int l=0;ln_layers;l++){ if(!rows[s].kv->Lc[l] || !rows[s].kv->Rc[l] || rows[s].kv->kv_start[l]<0 || rows[s].kv->kv_start[l]>rows[s].pos || (m->has_dsa && c->idx_type[l] && (!rows[s].kv->Ic || !rows[s].kv->Ic[l]))){ free(x); return NULL; } } for(int p=0;pfinal_norm,D,c->eps); double th0=now_s(); float *logit=falloc((int64_t)S*c->vocab); matmul_qt(logit,norm,&m->lm_head,S); m->t_head+=now_s()-th0; free(x); free(norm); return logit; } /* METODO E — prompt-lookup: cerca l'occorrenza piu' recente dell'ultimo bigramma nel * contesto e propone i token che la seguirono. Zero pesi extra, zero costo: e' solo * un'ipotesi che il modello verifichera'. */ static int ngram_draft(const int *ids, int len, int G, int *draft){ if(len<4 || G<1) return 0; int a=ids[len-2], b=ids[len-1]; for(int i=len-3;i>=1;i--) if(ids[i-1]==a && ids[i]==b){ int n=0; for(int j=i+1;jbv){bv=lo[i];b=i;} return b; } static int mtp_draft(Model *m, int next_tok, int kv, int G, int *draft){ Cfg *c=&m->c; int D=c->hidden, li=c->n_layers; int p=kv-1; if(p<0||G<1) return 0; if(m->kv_start[li]<0 || m->kv_start[li]>p) m->kv_start[li]=p; float *x=falloc(D), *cat=falloc(2*D), *hx=falloc(D), *nrm=falloc(D), *tmp=falloc(D); float *row=falloc(D), *logit=falloc(c->vocab), *h=falloc(D); memcpy(h, m->hlast, D*sizeof(float)); int tok=next_tok, n=0; int prenorm = getenv("MTP_PRENORM")!=NULL; for(int g=0; g=m->max_t) break; embed_row(m, tok, x); rmsnorm(x, x, m->enorm, D, c->eps); if(g==0 && !prenorm) rmsnorm(h, h, m->final_norm, D, c->eps); /* h vero: post model.norm */ rmsnorm(h, h, m->hnorm, D, c->eps); if(getenv("MTP_SWAP")){ memcpy(cat, h, D*sizeof(float)); memcpy(cat+D, x, D*sizeof(float)); } else { memcpy(cat, x, D*sizeof(float)); memcpy(cat+D, h, D*sizeof(float)); } matmul_qt(hx, cat, &m->eh_proj, 1); double n_eh=0; for(int d=0;d=2; int t_pre=-1; if(dbg){ rmsnorm(row, hx, m->mtp_norm, D, c->eps); matmul_qt(logit, row, &m->lm_head, 1); t_pre=mtp_argmax(logit, c->vocab); } layer_forward(m, &m->mtpL, li, hx, 1, pos, nrm, tmp); double n_post=0; for(int d=0;dmtp_norm, D, c->eps); matmul_qt(logit, row, &m->lm_head, 1); int t2=mtp_argmax(logit, c->vocab); if(dbg) fprintf(stderr,"[mtp2] pos=%d in_tok=%d ||eh||=%.1f ||post||=%.1f pre_blk=%d post_blk=%d\n", pos, tok, sqrt(n_eh), sqrt(n_post), t_pre, t2); draft[n++]=t2; tok=t2; memcpy(h, hx, D*sizeof(float)); } free(x); free(cat); free(hx); free(nrm); free(tmp); free(row); free(logit); free(h); return n; } /* assorbe nella KV della testa MTP le coppie VERIFICATE (emb(token@pos+1), h_vero@pos): * next_ids[i] = token alla posizione pos_base+i+1; x[i] = hidden VERO a pos_base+i. * Un solo passaggio batch del layer MTP (il batch-union rende economici gli expert). */ static void mtp_absorb(Model *m, const int *next_ids, const float *x, int S, int pos_base){ if(!m->has_mtp || S<1) return; Cfg *c=&m->c; int D=c->hidden, li=c->n_layers; if(m->kv_start[li]<0 || m->kv_start[li]>pos_base) m->kv_start[li]=pos_base; float *hx=falloc((int64_t)S*D), *cat=falloc(2*D), *e=falloc(D), *hn=falloc(D), *hf=falloc(D); int prenorm = getenv("MTP_PRENORM")!=NULL; for(int i=0;ienorm,D,c->eps); if(prenorm) rmsnorm(hn,x+(int64_t)i*D,m->hnorm,D,c->eps); else { rmsnorm(hf,x+(int64_t)i*D,m->final_norm,D,c->eps); /* vLLM: h POST model.norm */ rmsnorm(hn,hf,m->hnorm,D,c->eps); } if(getenv("MTP_SWAP")){ memcpy(cat,hn,D*sizeof(float)); memcpy(cat+D,e,D*sizeof(float)); } else { memcpy(cat,e,D*sizeof(float)); memcpy(cat+D,hn,D*sizeof(float)); } matmul_qt(hx+(int64_t)i*D, cat, &m->eh_proj, 1); } float *nrm=falloc((int64_t)S*D), *tmp=falloc((int64_t)S*D); layer_forward(m,&m->mtpL,li,hx,S,pos_base,nrm,tmp); free(hx); free(cat); free(e); free(hn); free(hf); free(nrm); free(tmp); } static inline int argmax_v(const float *lo, int V){ int b=0; float bv=lo[0]; for(int i=1;ibv){bv=lo[i];b=i;} return b; } /* ---- METODO F: draft grammaticale (#48) ---- * gr_feed consuma i byte di ogni token EMESSO e tiene il walker in sync con l'output; * grammar_draft propone lo span FORZATO successivo (un solo byte legale per posizione) * gia' tokenizzato. Il confine di tokenizzazione non e' garantito coincidere con quello * del modello: la verifica assorbe la differenza (al peggio l'ultimo draft e' rifiutato). */ static void grammar_setup(Tok *T){ const char *gf=getenv("GRAMMAR"); if(!gf||!*gf) return; FILE *f=fopen(gf,"rb"); if(!f){ fprintf(stderr,"[GRAMMAR] cannot open %s\n",gf); return; } fseek(f,0,SEEK_END); long n=ftell(f); fseek(f,0,SEEK_SET); char *txt=malloc((size_t)n+1); if(!txt || fread(txt,1,(size_t)n,f)!=(size_t)n){ fprintf(stderr,"[GRAMMAR] failed to read %s\n",gf); fclose(f); free(txt); return; } fclose(f); txt[n]=0; if(gr_parse(&g_gram,txt)){ fprintf(stderr,"[GRAMMAR] %s: %s\n",gf,g_gram.err); free(txt); return; } free(txt); gr_state_init(&g_gst,&g_gram); if(!g_gst.alive){ fprintf(stderr,"[GRAMMAR] %s: grammar cannot be evaluated (left recursion?)\n",gf); return; } if(getenv("GRAMMAR_DRAFT")) g_gr_max=atoi(getenv("GRAMMAR_DRAFT")); if(g_gr_max<1) g_gr_max=1; if(g_gr_max>48) g_gr_max=48; g_gr_T=T; g_gr_on=1; fprintf(stderr,"[GRAMMAR] %s: %d rules, forced span capped at %d tokens/forward\n",gf,g_gram.n,g_gr_max); } /* stato pulito all'inizio di ogni RISPOSTA (non tra i \x02MORE, che continuano) */ static void grammar_reset(void){ if(!g_gr_on) return; gr_state_init(&g_gst,&g_gram); g_gr_armed=0; if(!g_gst.alive) g_gr_on=0; } /* consuma i byte di un token emesso. Preambolo (prima dell'arming): ignorato. * Desync dopo l'arming: si riarma in attesa del prossimo inizio valido — al peggio * i draft vengono rifiutati dalla verifica, l'output non cambia MAI. */ static void gr_feed(int t){ if(!g_gr_on||!g_gr_T) return; char b[64]; int n=tok_decode(g_gr_T,&t,1,b,63); for(int i=0;i=32 && g_gr_acc*20?g:0; } /* ---- SAMPLING (temperatura + nucleus) con verifica speculativa LOSSLESS ---- * Il draft (MTP/n-gram) e' DETERMINISTICO (argmax della testa): q = massa puntuale. * Rejection sampling di Leviathan: accetta il draft x_d con prob p(x_d); al rifiuto * ricampiona da p con x_d azzerato e rinormalizzato. La distribuzione risultante e' * ESATTAMENTE p: la speculazione resta invisibile all'output anche col sampling. */ static uint64_t g_rng=0x9E3779B97F4A7C15ULL; static inline double rndu(void){ g_rng^=g_rng<<13; g_rng^=g_rng>>7; g_rng^=g_rng<<17; return (double)(g_rng>>11)*(1.0/9007199254740992.0); } static float *g_pbuf=NULL; static int *g_pidx=NULL; /* buffer riusati (decode single-thread) */ static int cmp_pdesc(const void *a,const void *b){ float pa=g_pbuf[*(const int*)a], pb=g_pbuf[*(const int*)b]; return papb ? -1 : 0; } /* costruisce in g_pbuf la distribuzione target: softmax(lo/temp) troncata a top-p g_nuc */ static void dist_build(const float *lo, int V){ if(!g_pbuf){ g_pbuf=falloc(V); g_pidx=malloc(V*sizeof(int)); } float mx=lo[0]; for(int i=1;imx) mx=lo[i]; double s=0; float invt=1.f/(g_temp>1e-4f?g_temp:1e-4f); for(int i=0;i0 && g_nuc<1.f){ for(int i=0;i=g_nuc){ keep=i+1; break; } } double s2=0; for(int i=keep;i=0 -> quel token e' escluso (rinormalizzando al volo) */ static int dist_sample(int V, int ban){ double z = 1.0 - (ban>=0 ? g_pbuf[ban] : 0.0); if(z<=1e-12) z=1e-12; double u = rndu()*z, cum=0; for(int i=0;i=u) return i; } for(int i=V-1;i>=0;i--) if(i!=ban && g_pbuf[i]>0) return i; return 0; } /* prossimo token dai logits: greedy se g_temp<=0, altrimenti sampling. * ban = token escluso perche' rifiutato dalla verifica speculativa precedente. */ static int pick_tok(const float *lo, int V, int ban){ if(g_temp<=0) return argmax_v(lo,V); dist_build(lo,V); return dist_sample(V,ban); } /* stop-set attivo (popolato da run_text/run_serve dal config; vuoto in validazione, * dove si genera un numero fisso di token da confrontare con l'oracolo) */ static int g_stop[9], g_nstop=0; static inline int is_stop(int t){ for(int i=0;in_stop;i++) g_stop[g_nstop++]=c->stop_ids[i]; if(tok_eos>=0 && !is_stop(tok_eos)) g_stop[g_nstop++]=tok_eos; fprintf(stderr,"[stop] %d stop tokens:",g_nstop); for(int i=0;i disco e banda RAM ammortizzati su piu' token. * all: storia token (capacita' >= kv+n_new+g_draft+2), kv = token gia' in KV. * logit = logits della posizione kv-1 (dal prefill); viene liberato qui. * emit(tok,ud) per ogni token emesso. Ritorna i token emessi; *kv_out = nuova kv. */ static int spec_decode(Model *m, int *all, int kv, int n_new, int eos, float *logit, void (*emit)(int,void*), void *ud, int *kv_out){ Cfg *c=&m->c; int V=c->vocab; int emitted=0, done=0; int draft[64]; if(g_draft>63) g_draft=63; int carry_ban=-1; /* token rifiutato dalla verifica: escluso dal resample */ while(emitted=0 && next==eos) || is_stop(next)) break; emit(next,ud); all[kv]=next; emitted++; m->n_emit++; gr_feed(next); /* il walker segue l'output emesso */ if(emitted>=n_new) break; /* l'ultimo token non serve forwardarlo */ int g = 0, gsrc = 0; /* sorgente: 1=grammatica 2=MTP/n-gram */ if(g_gr_on){ /* metodo F: prima la grammatica — dove * forza, l'acceptance e' ~1 (#48) */ g=grammar_draft(draft,g_gr_max); if(g>0) gsrc=1; } if(!g && g_draft>0){ /* auto-off adattivo: draft che non vengono mai accettati = solo tassa disco */ if(m->has_mtp && m->mtp_prop>=24 && m->mtp_acc*10 < m->mtp_prop){ g_draft=0; fprintf(stderr,"[MTP] %.0f%% acceptance after %llu proposals: drafts disabled\n", 100.0*m->mtp_acc/m->mtp_prop, (unsigned long long)m->mtp_prop); } } if(!g && g_draft>0){ if(m->has_mtp){ g=mtp_draft(m,next,kv,g_draft,draft); m->mtp_prop+=g; if(g)gsrc=2; } else { g=ngram_draft(all,kv+1,g_draft,draft); if(g)gsrc=2; } } if(g>n_new-emitted) g=n_new-emitted; if(kv+1+g+1>m->max_t) g=m->max_t-kv-2; if(g<0) g=0; if(gsrc==1) g_gr_prop+=(uint64_t)g; int S=1+g; int batch[64]; batch[0]=next; memcpy(batch+1,draft,g*sizeof(int)); float *lo=step_all(m,batch,S,kv); m->n_fw++; int k=0; /* verifica: accetta finche' coincide */ if(g>0 && getenv("MTP_DEBUG")){ int veri=argmax_v(lo,V); fprintf(stderr,"[mtpdbg] draft0=%d verified=%d %s\n", draft[0], veri, draft[0]==veri?"HIT":"miss"); } while(k0) carry_ban=draft[k]; break; } if((eos>=0 && draft[k]==eos) || is_stop(draft[k])){ done=1; break; } emit(draft[k],ud); all[kv+1+k]=draft[k]; emitted++; m->n_emit++; gr_feed(draft[k]); k++; } if(gsrc==1) g_gr_acc+=(uint64_t)k; else if(gsrc==2 && m->has_mtp) m->mtp_acc+=k; if(m->has_mtp && k>=1) mtp_absorb(m, all+kv+1, m->h_all, k, kv); /* KV MTP in sync coi verificati */ /* hlast deve corrispondere all'ultima posizione ACCETTATA (kv+k), non a fine batch */ if(m->h_all && khlast, m->h_all+(int64_t)k*m->c.hidden, m->c.hidden*sizeof(float)); kv += 1+k; /* KV oltre kv e' stantia: verra' sovrascritta */ logit=falloc(V); memcpy(logit, lo+(int64_t)k*V, V*sizeof(float)); free(lo); } if(logit) free(logit); if(kv_out) *kv_out=kv; return emitted; } /* emit callback: accumula in un array (validazione) */ typedef struct { int *dst; int n; } EmitStore; static void emit_store(int t, void *ud){ EmitStore *e=(EmitStore*)ud; e->dst[e->n++]=t; } /* emit callback: detokenizza e stampa in streaming (chat/run), con heartbeat */ typedef struct { Tok *T; Model *m; double t0; int count; int quiet; } EmitStream; static void emit_stream(int t, void *ud){ EmitStream *e=(EmitStream*)ud; char dec[64]; int dn=tok_decode(e->T,&t,1,dec,63); dec[dn]=0; fputs(dec,stdout); fflush(stdout); if(!e->quiet && ++e->count%16==0){ double tt=e->m->hits+e->m->miss; fprintf(stderr,"\n[t=%d RSS %.2f GB hit %.0f%% %.2f tok/s %.2f tok/fw]\n", e->count, rss_gb(), tt?100.0*e->m->hits/tt:0.0, e->count/(now_s()-e->t0), e->m->n_fw?(double)e->m->n_emit/e->m->n_fw:1.0); } } /* teacher-forcing: un solo forward su ids[S], argmax per posizione in pred[S] */ static void forward_all(Model *m, const int *ids, int S, int *pred){ Cfg *c=&m->c; int D=c->hidden; kv_alloc(m,S); float *x=falloc((int64_t)S*D); for(int s=0;svocab); for(int s=0;sfinal_norm, D, c->eps); matmul_qt(lo, row, &m->lm_head, 1); int best=0; float bv=lo[0]; for(int i=1;ivocab;i++) if(lo[i]>bv){bv=lo[i];best=i;} pred[s]=best; } free(x); free(lo); } /* log-prob (log-softmax) del token target dato il vettore di logit; *am=1 se e' l'argmax */ static double logprob_target(const float *lo, int V, int target, int *am){ float mx=lo[0]; int best=0; for(int i=1;imx){mx=lo[i];best=i;} } double se=0; for(int i=0;i .. " (T=ctxlen+contlen) * output: riga " " per richiesta. * Un solo forward per richiesta (teacher-forcing): niente generazione -> fattibile a bassa velocita'. */ static void run_score(Model *m, const char *path){ Cfg *c=&m->c; int D=c->hidden; FILE *f=fopen(path,"rb"); if(!f){perror(path);exit(1);} int maxT=1; { char *ln=NULL; size_t cp=0; while(getline(&ln,&cp,f)>0){ int a,b; if(sscanf(ln,"%d %d",&a,&b)==2 && a+b>maxT) maxT=a+b; } free(ln); } kv_alloc(m,maxT); float *x=falloc((int64_t)maxT*D), *lo=falloc(c->vocab), *row=falloc(D); int *ids=malloc(maxT*sizeof(int)); rewind(f); char *ln=NULL; size_t cp=0; int nreq=0; double t0=now_s(); while(getline(&ln,&cp,f)>0){ char *p=ln; int ctxlen=strtol(p,&p,10), contlen=strtol(p,&p,10), T=ctxlen+contlen; if(T<=0||ctxlen<1){ printf("0 0 0\n"); fflush(stdout); continue; } for(int i=0;ifinal_norm, D, c->eps); matmul_qt(lo,row,&m->lm_head,1); int am; lp += logprob_target(lo,c->vocab,ids[pos+1],&am); if(!am) greedy=0; } printf("%.6f %d %d\n", lp, contlen, greedy); fflush(stdout); if(++nreq%5==0) fprintf(stderr,"[score %d req | %.1fs | RSS %.2f GB | hit %.0f%%]\n", nreq, now_s()-t0, rss_gb(), (m->hits+m->miss)?100.0*m->hits/(m->hits+m->miss):0.0); } free(ln); free(ids); free(x); free(lo); free(row); fclose(f); } static void generate(Model *m, const int *prompt, int np, int n_new, int *out){ kv_alloc(m,np+n_new+g_draft+2); for(int i=0;it_ewait+m->t_emm+m->t_attn+m->t_head; printf("PROFILE: expert-disk %.3fs service / %.3fs wait | expert-matmul %.3fs | attention %.3fs " "(including kvb %.3fs) | lm_head %.3fs | other %.3fs\n", m->t_edisk,m->t_ewait,m->t_emm,m->t_attn,m->t_kvb,m->t_head,elapsed-accounted); printf("ATTENTION: projection/RoPE %.3fs | score-softmax-value %.3fs | output projection %.3fs\n", m->t_aproj,m->t_acore,m->t_aout); #ifdef COLI_METAL if(g_metal_enabled){ uint64_t ok=0,fb=0,ex=0; double su=0,gp=0,sc=0; coli_metal_moe_counts(&ok,&fb,&ex); coli_metal_moe_times(&su,&gp,&sc); { uint64_t aok=0; double aw=0,ak=0; coli_metal_attn_counts(&aok,&aw,&ak); if(aok){ double ks=0,gs=0; coli_metal_attn_lat(&ks,&gs); printf("METAL-ATTN: layer GPU %llu | gpu-wall %.2fs (kernel %.2fs | cpu-sched %.2fs gpu-sched %.2fs)\n",(unsigned long long)aok,aw,ak,ks,gs); } } printf("METAL: blocchi GPU %llu | fallback CPU %llu | expert su GPU %llu | setup %.2fs gpu-wall %.2fs (kernel %.2fs) scatter %.2fs\n", (unsigned long long)ok,(unsigned long long)fb,(unsigned long long)ex,su,gp,coli_metal_moe_kernel_time(),sc); } #endif } /* Fixed-token decode benchmark: prefill all but the prompt's last token, then * replay the oracle sequence one token at a time. CPU and CUDA therefore see * identical hidden-state inputs even if their argmax predictions differ. */ static void run_replay(Model *m, const int *full, int nfull, int np){ if(np<2||nfull<=np){ fprintf(stderr,"REPLAY requires a non-empty prompt and continuation\n"); return; } kv_alloc(m,nfull+2); float *logit=step(m,full,np-1,0); free(logit); m->hits=m->miss=m->ereq=m->gpu_expert_calls=0; m->t_edisk=m->t_ewait=m->t_emm=m->t_attn=m->t_kvb=m->t_head=0; m->t_aproj=m->t_acore=m->t_aout=0; double t0=now_s(); int steps=0; for(int i=np-1;ihits+m->miss; printf("REPLAY decode: %d tokens in %.3fs | %.2f tok/s | expert hit %.1f%%\n", steps,dt,steps/dt,tot?100.0*m->hits/tot:0.0); profile_print(m,dt); #ifdef COLI_CUDA if(m->gpu_expert_count) printf("CUDA expert tier: %d resident experts (%.2f GB) | %llu calls served from VRAM\n", m->gpu_expert_count,m->gpu_expert_bytes/1e9,(unsigned long long)m->gpu_expert_calls); if(g_cuda_enabled) cuda_stats_print(); #endif } /* generazione reale: tokenizza PROMPT, prefill + decode greedy con stop su EOS, * detokenizza e stampa il testo in streaming. */ static void run_text(Model *m, const char *snap, const char *prompt, int ngen){ Cfg *c=&m->c; char tkp[2048]; snprintf(tkp,sizeof(tkp),"%s/tokenizer.json",snap); Tok T; tok_load(&T,tkp); int eos=tok_id_of(&T,"<|endoftext|>"); stops_arm(&m->c, eos); grammar_setup(&T); /* metodo F: GRAMMAR=file.gbnf (#48) */ if(g_temp<0) g_temp=0.7f; /* auto: 0.7, NON l'1.0 ufficiale — la coda della * distribuzione int4 e' rumore di quantizzazione */ int cap=(int)strlen(prompt)+16; int *pids=malloc(cap*sizeof(int)); int np=tok_encode(&T,prompt,(int)strlen(prompt),pids,cap); if(np<1){ fprintf(stderr,"prompt is empty after tokenization\n"); return; } printf("prompt: %d tokens | generating up to %d (EOS stop=%d) | n-gram draft=%d\n", np, ngen, eos, g_draft); fputs(prompt,stdout); fflush(stdout); kv_alloc(m, np+ngen+g_draft+2); int *all=malloc((np+ngen+g_draft+2)*sizeof(int)); memcpy(all,pids,np*sizeof(int)); double t=now_s(); float *logit=step(m,pids,np,0); EmitStream es={&T,m,t,0,0}; grammar_reset(); int produced=spec_decode(m,all,np,ngen,eos,logit,emit_stream,&es,NULL); double dt=now_s()-t; double tot=m->hits+m->miss; int nsp=0; for(int i=0;in_layers;i++) if(m->L[i].sparse) nsp++; printf("\n---\n%d tokens in %.2fs (%.2f tok/s) | expert hit rate %.1f%% | RSS %.2f GB\n", produced, dt, produced/dt, tot?100.0*m->hits/tot:0.0, rss_gb()); printf("experts loaded/token: %.1f (per-layer %.2f across %d; baseline topk=%d) | TOPK=%d TOPP=%.2f\n", produced?(double)m->ereq/produced:0.0, (produced&&nsp)?(double)m->ereq/produced/nsp:0.0, nsp, c->topk, g_topk, g_topp); printf("speculation: %.2f tokens/forward (%llu forwards per %llu tokens) | MTP acceptance %.0f%% (%llu/%llu)\n", m->n_fw?(double)m->n_emit/m->n_fw:1.0, (unsigned long long)m->n_fw, (unsigned long long)m->n_emit, m->mtp_prop?100.0*m->mtp_acc/m->mtp_prop:0.0, (unsigned long long)m->mtp_acc, (unsigned long long)m->mtp_prop); if(g_gr_prop) printf("grammar: %.0f%% acceptance (%llu/%llu forced drafts)\n", 100.0*g_gr_acc/g_gr_prop, (unsigned long long)g_gr_acc, (unsigned long long)g_gr_prop); #ifdef COLI_CUDA if(m->gpu_expert_count) printf("CUDA expert tier: %d resident experts (%.2f GB) | %llu calls served from VRAM\n", m->gpu_expert_count,m->gpu_expert_bytes/1e9,(unsigned long long)m->gpu_expert_calls); if(g_cuda_enabled) cuda_stats_print(); #endif profile_print(m,dt); if(g_pilot_real) printf("PILOT_REAL: %ld load cross-layer completati, %ld scartati (main gia' sul layer) | PILOT_K=%d\n", (long)atomic_load_explicit(&g_pilot_loads,memory_order_relaxed), (long)atomic_load_explicit(&g_pilot_drops,memory_order_relaxed), g_pilot_k); if(g_looka){ const char *nm[3]={"previous token (=SPEC prefetch)","layer input, skip attention","next layer (one step ahead)"}; printf("LOOKAHEAD routing — recall of true experts in predicted top-8:\n"); for(int i=0;i<3;i++) printf(" %-38s %5.1f%% (%lld/%lld)\n", nm[i], la_tot[i]?100.0*la_hit[i]/la_tot[i]:0.0, (long long)la_hit[i], (long long)la_tot[i]); } free(pids); free(all); usage_save(m); } /* modalita' SERVE (per la CLI 'coli'): carica il modello UNA volta, poi CHAT conversazionale. * KV-cache PERSISTENTE tra i turni: la storia resta in cache, si fa il prefill solo dei * token NUOVI -> il modello RICORDA la conversazione e non ri-processa il passato (lossless, * piu' umano, piu' veloce). Template chat GLM con token speciali (CHAT_TEMPLATE=0 -> grezzo). * Protocollo: "\x01\x01" "READY" "\x01\x01\n" dopo il load; risposta in streaming; "\x01\x01" "END" "\x01\x01\n" a fine turno. * ":reset" (riga "\x02RESET") azzera la memoria. EOF -> esce. */ /* ---- RFC: RE-PIN A CALDO / LIVE RE-PIN (opt-in, REPIN=n, default OFF) ---- * Upstream fa AUTOPIN allo START (dalla storia .coli_usage). Questo aggiunge un re-pin * TRA I TURNI: nel punto sicuro dopo la risposta scambia i pin peggiori con i non-pinnati * piu' caldi, cosi' l'hot-store insegue il carico VIVO senza un profilo a parte. Isteresi * 25% (+4) contro il ping-pong; max 4 scambi/passata (~20 MB di disco l'uno). Una heat * map separata decade a ogni passata: la storia persistente .coli_usage resta intatta. * EN: upstream AUTOPINs at START (from .coli_usage). This adds a between-turns re-pin: at * the safe point after the reply, swap the worst pins for the hottest unpinned, so the * hot-store tracks the LIVE workload without a separate profile. 25% (+4) hysteresis vs * ping-pong; max 4 swaps/pass (~20 MB disk each). A separate decaying heat map keeps * persistent .coli_usage intact while adapting to the current workload. */ static int g_repin=0; static uint64_t g_last_repin=0; typedef struct { long gain; int l, slot, eid; } RepinCand; static int repin_pick(Model *m, RepinCand *out, int maxc){ Cfg *c=&m->c; int nb=0; for(int l=0;ln_layers;l++){ if(!m->npin || m->npin[l]<1 || !m->eheat[l]) continue; ESlot *P=m->pin[l]; int ids[4096], zp, eu; long g; int np=m->npin[l]; if(np>4096) np=4096; for(int z=0;zeheat[l],m->elast[l],m->eaccess_clock, c->n_experts,ids,np,&zp,&eu,&g)) continue; if(nbout[w].gain){ out[w].gain=g; out[w].l=l; out[w].slot=zp; out[w].eid=eu; } } } return nb; } static void repin_pass(Model *m){ if(g_repin<=0) return; if(m->n_emit - g_last_repin < (uint64_t)g_repin) return; g_last_repin = m->n_emit; RepinCand cd[4]; int nb=repin_pick(m,cd,4); for(int b=0;bpin[cd[b].l][cd[b].slot]; int old=s->eid; uint32_t old_heat=m->eheat[cd[b].l][old], new_heat=m->eheat[cd[b].l][cd[b].eid]; #ifdef COLI_CUDA int gpu=s->g.cuda_eligible; int64_t old_gpu=gpu ? (int64_t)coli_cuda_tensor_bytes(s->g.cuda) +(int64_t)coli_cuda_tensor_bytes(s->u.cuda) +(int64_t)coli_cuda_tensor_bytes(s->d.cuda) : 0; #endif double t0=now_s(); expert_load(m,cd[b].l,cd[b].eid,s,1); /* disk -> RAM, same resident slot */ const char *tier="RAM"; #ifdef COLI_CUDA if(gpu){ /* refresh the same VRAM slot now, not lazily */ if(qt_cuda_upload(&s->g) && qt_cuda_upload(&s->u) && qt_cuda_upload(&s->d)){ int64_t now_gpu=(int64_t)coli_cuda_tensor_bytes(s->g.cuda) +(int64_t)coli_cuda_tensor_bytes(s->u.cuda) +(int64_t)coli_cuda_tensor_bytes(s->d.cuda); m->gpu_expert_bytes+=now_gpu-old_gpu; tier="VRAM"; if(g_cuda_release_host) expert_host_release(m,s); } else { qt_cuda_reset(&s->g); qt_cuda_reset(&s->u); qt_cuda_reset(&s->d); s->g.cuda_eligible=s->u.cuda_eligible=s->d.cuda_eligible=0; m->gpu_expert_count--; m->gpu_expert_bytes-=old_gpu; fprintf(stderr,"[REPIN] VRAM upload failed; slot downgraded to RAM\n"); } } #endif fprintf(stderr,"[REPIN] %s layer %d: evict %d (heat=%u) <- admit %d (heat=%u) in %.0f ms\n", tier,cd[b].l,old,old_heat,cd[b].eid,new_heat,(now_s()-t0)*1e3); } for(int l=0;lc.n_layers;l++) if(m->eheat[l]) tier_decay(m->eheat[l],m->c.n_experts); } /* ---- KV SU DISCO: la conversazione si riapre CALDA (KVSAVE=0 disattiva) ---- * Il re-prefill di una chat riaperta costa ore su questo disco; la KV compressa MLA * costa ~182 KB/token. File /.coli_kv append-only: header (magic + dimensioni + * nrec) e un record per posizione [tok i32][Lc+Rc dei 78 layer][Ic DSA]. A fine turno * si appendono SOLO le posizioni nuove e si riscrive nrec per ultimo: un crash a meta' * append lascia nrec vecchio = file coerente. La riga KV del layer MTP non si salva: * al resume kv_start=-1 e la finestra di draft riparte da sola. */ static int g_kvsave=1; #define KV_MAGIC "COLIKV1\0" static void kv_hdr(Model *m, int32_t *h, int nrec){ Cfg *c=&m->c; int nic=0; for(int i=0;in_layers;i++) if(m->Ic && m->Ic[i]) nic++; h[0]=c->n_layers; h[1]=c->kv_lora; h[2]=c->qk_rope; h[3]=m->has_dsa?c->index_hd:0; h[4]=nic; h[5]=c->vocab; h[6]=nrec; h[7]=0; } static void kv_disk_truncate(Model *m, int nrec){ if(!g_kvsave) return; KVState *k=m->kv; FILE *f=fopen(k->disk_path,"r+b"); if(!f){ k->disk_nrec=0; return; } k->disk_nrec=nrec; int32_t nr=nrec; fseek(f,8+6*4,SEEK_SET); fwrite(&nr,4,1,f); fclose(f); } static void kv_disk_reset(Model *m){ kv_disk_truncate(m,0); } static void kv_disk_append(Model *m, const int *hist, int len){ KVState *k=m->kv; if(!g_kvsave || len<=k->disk_nrec) return; Cfg *c=&m->c; FILE *f=fopen(k->disk_path,"r+b"); if(!f){ f=fopen(k->disk_path,"wb"); if(!f) return; int32_t h[8]; kv_hdr(m,h,0); fwrite(KV_MAGIC,1,8,f); fwrite(h,4,8,f); } int64_t rec = 4 + (int64_t)c->n_layers*(c->kv_lora+c->qk_rope)*4; if(m->has_dsa) for(int i=0;in_layers;i++) if(m->Ic[i]) rec+=(int64_t)c->index_hd*4; fseek(f, 8+8*4 + (int64_t)k->disk_nrec*rec, SEEK_SET); for(int p=k->disk_nrec;pn_layers;i++){ fwrite(m->Lc[i]+(int64_t)p*c->kv_lora, 4, c->kv_lora, f); fwrite(m->Rc[i]+(int64_t)p*c->qk_rope, 4, c->qk_rope, f); } if(m->has_dsa) for(int i=0;in_layers;i++) if(m->Ic[i]) fwrite(m->Ic[i]+(int64_t)p*c->index_hd, 4, c->index_hd, f); } fflush(f); /* dati prima, contatore poi */ int32_t nr=len; fseek(f,8+6*4,SEEK_SET); fwrite(&nr,4,1,f); fclose(f); k->disk_nrec=len; } static int kv_disk_load(Model *m, int *hist, int maxctx){ if(!g_kvsave) return 0; KVState *k=m->kv; Cfg *c=&m->c; FILE *f=fopen(k->disk_path,"rb"); if(!f) return 0; char mg[8]; int32_t h[8], w[8]; kv_hdr(m,w,0); if(fread(mg,1,8,f)!=8 || memcmp(mg,KV_MAGIC,8) || fread(h,4,8,f)!=8 || h[0]!=w[0]||h[1]!=w[1]||h[2]!=w[2]||h[3]!=w[3]||h[4]!=w[4]||h[5]!=w[5]){ fprintf(stderr,"[KV] ignoring .coli_kv from a different model or version\n"); fclose(f); return 0; } int nrec=h[6]; if(nrec<1){ fclose(f); return 0; } if(nrec>=maxctx-8-g_draft){ fprintf(stderr,"[KV] saved conversation (%d tokens) exceeds the context: starting over\n",nrec); fclose(f); return 0; } double t0=now_s(); for(int p=0;pn_layers;i++){ if(fread(m->Lc[i]+(int64_t)p*c->kv_lora, 4, c->kv_lora, f)!=(size_t)c->kv_lora || fread(m->Rc[i]+(int64_t)p*c->qk_rope, 4, c->qk_rope, f)!=(size_t)c->qk_rope){ nrec=p; goto out; } } if(m->has_dsa) for(int i=0;in_layers;i++) if(m->Ic[i]) if(fread(m->Ic[i]+(int64_t)p*c->index_hd, 4, c->index_hd, f)!=(size_t)c->index_hd){ nrec=p; goto out; } } out: fclose(f); if(nrec>0){ if(m->has_mtp) m->kv_start[c->n_layers]=-1; /* la finestra MTP riparte da sola */ fprintf(stderr,"[KV] resumed conversation from disk: %d tokens in %.1fs (no re-prefill)\n", nrec, now_s()-t0); } k->disk_nrec=nrec; return nrec; } typedef struct { KVState kv; int *hist, len, first; } ServeCtx; static double kv_pool_bytes(Model *m, int max_ctx); static void serve_ctx_init(Model *m, ServeCtx *s, const char *snap, int slot, int maxctx){ s->kv.kv_start=calloc(m->c.n_layers+1,sizeof(int)); if(m->has_mtp) s->kv.kv_start[m->c.n_layers]=-1; kv_bind(m,&s->kv); kv_alloc(m,maxctx); s->hist=malloc(maxctx*sizeof(int)); s->first=1; if(slot==0) snprintf(s->kv.disk_path,sizeof(s->kv.disk_path),"%s/.coli_kv",snap); else snprintf(s->kv.disk_path,sizeof(s->kv.disk_path),"%s/.coli_kv.%d",snap,slot); s->len=kv_disk_load(m,s->hist,maxctx); if(s->len>0) s->first=0; } static void serve_ctx_free(Model *m, ServeCtx *s){ KVState *k=&s->kv; int NR=m->c.n_layers+1; if(k->Lc) for(int i=0;iLc[i]); free(k->Rc[i]); } if(k->Ic) for(int i=0;ic.n_layers;i++) free(k->Ic[i]); free(k->Lc); free(k->Rc); free(k->Ic); free(k->kv_start); free(s->hist); } typedef struct { int active, pending, emitted, maximum, prompt_tokens, length_limited; unsigned long long id; float temp, top_p; double started; uint64_t hits0, miss0; } ServeReq; static void mux_data(Tok *T, unsigned long long id, int token){ char out[256]; int n=tok_decode(T,&token,1,out,sizeof(out)); printf("DATA %llu %d\n",id,n); if(n>0) fwrite(out,1,(size_t)n,stdout); putchar('\n'); fflush(stdout); } static void mux_done(Model *m, ServeCtx *sc, ServeReq *r){ double dt=now_s()-r->started; if(dt<1e-6) dt=1e-6; double dh=(double)(m->hits-r->hits0), dm=(double)(m->miss-r->miss0); printf("DONE %llu STAT %d %.2f %.1f %.2f %d %d\n",r->id,r->emitted, r->emitted/dt,(dh+dm)>0?100.0*dh/(dh+dm):0.0,rss_gb(), r->prompt_tokens,r->length_limited); fflush(stdout); kv_bind(m,&sc->kv); kv_disk_append(m,sc->hist,sc->len); r->active=0; } /* Read and prefill one request. Returns -1 on EOF, 0 for a rejected frame and * 1 for an accepted request. Prefill deliberately remains serial: continuous * batching starts at decode, where every active slot contributes one row. */ static int mux_submit(Model *m, Tok *T, ServeCtx *ctx, ServeReq *req, int nctx, int maxctx, int eos){ char *line=NULL; size_t cap=0; ssize_t nr=getline(&line,&cap,stdin); if(nr<0){ free(line); return -1; } if(nr && line[nr-1]=='\n') line[--nr]=0; if(!strncmp(line,"CANCEL ",7)){ unsigned long long id=0; char tail; if(sscanf(line+7,"%llu %c",&id,&tail)!=1 || id==0){ printf("ERROR 0 BAD_REQUEST\n"); fflush(stdout); free(line); return 0; } for(int i=0;i=nctx || memchr(raw,0,(size_t)sub.bytes)){ printf("ERROR %llu BAD_REQUEST\n",sub.id); fflush(stdout); free(raw); free(line); return 0; } if(req[sub.slot].active){ printf("ERROR %llu SLOT_BUSY\n",sub.id); fflush(stdout); free(raw); free(line); return 0; } for(int i=0;ikv); int *tmp=malloc(maxctx*sizeof(int)); int nt=tok_encode(T,raw,(int)sub.bytes,tmp,maxctx-2); free(raw); free(line); if(nt<1){ free(tmp); printf("ERROR %llu EMPTY_PROMPT\n",sub.id); fflush(stdout); return 0; } int prefix=0; while(prefixlen && prefixhist[prefix]==tmp[prefix]) prefix++; if(prefixlen){ sc->len=prefix; if(m->has_mtp) m->kv_start[m->c.n_layers]=-1; kv_disk_truncate(m,sc->len); } int add=nt-sc->len; if(add>0) memcpy(sc->hist+sc->len,tmp+sc->len,(size_t)add*sizeof(int)); free(tmp); float *logit = add>0 ? step(m,sc->hist+sc->len,add,sc->len) : step(m,sc->hist+sc->len-1,1,sc->len-1); sc->len+=add; sc->first=0; ServeReq *r=&req[sub.slot]; memset(r,0,sizeof(*r)); r->id=sub.id; r->maximum=sub.max_tokens; r->temp=sub.temperature; r->top_p=sub.top_p; r->prompt_tokens=nt; r->started=now_s(); r->hits0=m->hits; r->miss0=m->miss; int room=maxctx-sc->len-1; if(r->maximum>room){r->maximum=room; r->length_limited=1;} g_temp=r->temp; g_nuc=r->top_p; int next=pick_tok(logit,m->c.vocab,-1); free(logit); if(r->maximum<=0 || next==eos || is_stop(next)){ mux_done(m,sc,r); return 1; } r->pending=next; r->emitted=1; r->active=1; sc->hist[sc->len]=next; m->n_emit++; mux_data(T,r->id,next); if(r->emitted>=r->maximum) mux_done(m,sc,r); return 1; } static void run_serve_mux(Model *m, const char *snap){ char tkp[2048]; snprintf(tkp,sizeof(tkp),"%s/tokenizer.json",snap); Tok T; tok_load(&T,tkp); int eos=tok_id_of(&T,"<|endoftext|>"); stops_arm(&m->c,eos); g_draft=0; /* one scheduler owns every forward; MTP/speculation is not ragged-safe */ int maxctx=getenv("CTX")?atoi(getenv("CTX")):4096; int nctx=getenv("KV_SLOTS")?atoi(getenv("KV_SLOTS")):1; if(nctx<1||nctx>16){fprintf(stderr,"KV_SLOTS deve essere tra 1 e 16\n");exit(2);} g_kvsave=getenv("KVSAVE")?atoi(getenv("KVSAVE")):1; KVState *initial=m->kv; free(initial->kv_start); free(initial); ServeCtx *ctx=calloc(nctx,sizeof(*ctx)); ServeReq *req=calloc(nctx,sizeof(*req)); for(int i=0;i0 && FD_ISSET(STDIN_FILENO,&rfds)) if(mux_submit(m,&T,ctx,req,nctx,maxctx,eos)<0) eof=1; active=0; for(int i=0;in_fw++; for(int s=0;slen++; g_temp=r->temp; g_nuc=r->top_p; int next=pick_tok(lo+(int64_t)s*m->c.vocab,m->c.vocab,-1); if(next==eos || is_stop(next)){mux_done(m,sc,r);continue;} r->pending=next; sc->hist[sc->len]=next; r->emitted++; m->n_emit++; mux_data(&T,r->id,next); if(r->emitted>=r->maximum) mux_done(m,sc,r); } free(lo); } usage_save(m); for(int i=0;ikv=NULL; m->Lc=m->Rc=m->Ic=NULL; m->kv_start=NULL; m->max_t=0; } static void run_serve(Model *m, const char *snap){ char tkp[2048]; snprintf(tkp,sizeof(tkp),"%s/tokenizer.json",snap); Tok T; tok_load(&T,tkp); int eos=tok_id_of(&T,"<|endoftext|>"); stops_arm(&m->c, eos); grammar_setup(&T); /* metodo F: GRAMMAR=file.gbnf (#48) */ if(g_temp<0) g_temp=0.7f; /* auto: 0.7, NON l'1.0 ufficiale — la coda della * distribuzione int4 e' rumore di quantizzazione */ int ngen=getenv("NGEN")?atoi(getenv("NGEN")):256; int maxctx=getenv("CTX")?atoi(getenv("CTX")):4096; int templ=getenv("CHAT_TEMPLATE")?atoi(getenv("CHAT_TEMPLATE")):1; g_kvsave = getenv("KVSAVE")?atoi(getenv("KVSAVE")):1; int nctx=getenv("KV_SLOTS")?atoi(getenv("KV_SLOTS")):1; if(nctx<1||nctx>16){ fprintf(stderr,"KV_SLOTS must be between 1 and 16\n"); exit(2); } KVState *initial=m->kv; free(initial->kv_start); free(initial); ServeCtx *ctx=calloc(nctx,sizeof(ServeCtx)); for(int i=0;ikv); fprintf(stderr,"[KV] context slots: %d x %d tokens, projected pool %.2f GB\n", nctx,maxctx,kv_pool_bytes(m,maxctx)/1e9); #define hist (sc->hist) #define len (sc->len) #define first (sc->first) char *line=NULL; size_t cap=0; ssize_t nr; char *buf=malloc(1<<16); printf("\x01\x01" "READY" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f\n", rss_gb()); fflush(stdout); while((nr=getline(&line,&cap,stdin))>0){ if(nr>0 && line[nr-1]=='\n') line[--nr]=0; if(!strcmp(line,"\x02RESET")){ len=0; first=1; if(m->has_mtp) m->kv_start[m->c.n_layers]=-1; kv_disk_reset(m); printf("\x01\x01" "END" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f\n", rss_gb()); fflush(stdout); continue; } if(!strcmp(line,"\x02MORE")){ /* continua la risposta troncata da NGEN: la storia e' gia' in KV, basta ri-forwardare l'ULTIMO token per riavere i logits */ if(len<1){ printf("\x01\x01" "END" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f\n", rss_gb()); fflush(stdout); continue; } int cur=ngen; if(len+cur+g_draft+2>=maxctx) cur=maxctx-len-g_draft-2; uint64_t h0=m->hits, ms0=m->miss; double tt0=now_s(); float *logit=step(m,hist+len-1,1,len-1); EmitStream es={&T,m,now_s(),0,1}; int prod=0; if(cur>0) prod=spec_decode(m,hist,len,cur,eos,logit,emit_stream,&es,&len); else free(logit); double tdt=now_s()-tt0; if(tdt<1e-6) tdt=1e-6; double dh=(double)(m->hits-h0), dm=(double)(m->miss-ms0); printf("\n\x01\x01" "END" "\x01\x01\n"); printf("STAT %d %.2f %.1f %.2f\n", prod, prod/tdt, (dh+dm)>0?100.0*dh/(dh+dm):0.0, rss_gb()); fflush(stdout); kv_disk_append(m,hist,len); repin_pass(m); continue; } /* RFC: re-pin a caldo tra i turni / live re-pin between turns */ if(nr<1){ printf("\x01\x01" "END" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f\n", rss_gb()); fflush(stdout); continue; } /* API mode: an exact, length-prefixed prompt. Unlike the interactive * line protocol this accepts newlines. The tokenized prompt is matched * against hist so the common KV prefix survives stateless HTTP turns. * Per-request generation controls follow the byte count: * \x02PROMPT [kv_slot]\n\n */ char *raw=NULL, *input=line; int input_n=(int)nr, raw_mode=0, req_ngen=ngen, prompt_tokens=0; float base_temp=g_temp, base_nuc=g_nuc; if(!strncmp(line,"\x02PROMPT ",8)){ unsigned long long nb=0; double rt=0, rp=0; int slot=0; int nf=sscanf(line+8,"%llu %d %lf %lf %d",&nb,&req_ngen,&rt,&rp,&slot); if(nf<4 || nb>(16u<<20) || req_ngen<1 || rt<0 || rt>2 || rp<=0 || rp>1 || slot<0 || slot>=nctx){ printf("\x01\x01" "END" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f 0 0\n",rss_gb()); fflush(stdout); continue; } active=slot; sc=&ctx[active]; kv_bind(m,&sc->kv); raw=malloc((size_t)nb+1); if(!raw){fprintf(stderr,"OOM raw prompt\n");exit(1);} if(fread(raw,1,(size_t)nb,stdin)!=(size_t)nb){free(raw);break;} int delim=fgetc(stdin); if(delim!='\n' && delim!=EOF) ungetc(delim,stdin); if(memchr(raw,0,(size_t)nb)){free(raw); printf("\x01\x01" "END" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f 0 0\n",rss_gb()); fflush(stdout); continue;} raw[nb]=0; input=raw; input_n=(int)nb; raw_mode=1; if(req_ngen>ngen) req_ngen=ngen; g_temp=(float)rt; g_nuc=(float)rp; } else { active=0; sc=&ctx[0]; kv_bind(m,&sc->kv); } int bl=0, k=0; /* costruisce/tokenizza il turno */ /* template UFFICIALE GLM-5.2 (chat_template.jinja): niente \n dopo i ruoli, e dopo * <|assistant|> serve SEMPRE il blocco think — lo DISATTIVA (nothink): * col template sbagliato il modello farfuglia e non emette mai lo stop. THINK=1 lo abilita. */ const char *tk = getenv("THINK")&&atoi(getenv("THINK"))? "" : ""; if(raw_mode){ int *tmp=malloc(maxctx*sizeof(int)); if(!tmp){fprintf(stderr,"OOM raw tokens\n");exit(1);} prompt_tokens=tok_encode(&T,input,input_n,tmp,maxctx-8-g_draft); int old_len=len, prefix=0; while(prefixhas_mtp) m->kv_start[m->c.n_layers]=-1; kv_disk_truncate(m,len); /* il prossimo append sovrascrive solo la coda */ } k=prompt_tokens-len; if(k>0) memcpy(hist+len,tmp+len,k*sizeof(int)); fprintf(stderr,"[API] KV slot %d prefix %d/%d token, prefill %d\n", active,len,prompt_tokens,k); free(tmp); } else { if(templ){ if(first) bl+=snprintf(buf+bl,(1<<16)-bl,"[gMASK]"); bl+=snprintf(buf+bl,(1<<16)-bl,"<|user|>%s<|assistant|>%s",input,tk); } else bl+=snprintf(buf+bl,(1<<16)-bl,"%s",input); k=tok_encode(&T,buf,bl,hist+len,maxctx-len); prompt_tokens=k; if(len+k+8+g_draft>=maxctx){ len=0; first=1; kv_disk_reset(m); bl=0; if(templ){ bl+=snprintf(buf+bl,(1<<16)-bl,"[gMASK]<|user|>%s<|assistant|>%s",input,tk); } else bl+=snprintf(buf+bl,(1<<16)-bl,"%s",input); k=tok_encode(&T,buf,bl,hist,maxctx); if(k>maxctx-8-g_draft) k=maxctx-8-g_draft; prompt_tokens=k; } } if(prompt_tokens<1){ free(raw); g_temp=base_temp; g_nuc=base_nuc; printf("\x01\x01" "END" "\x01\x01\n"); printf("STAT 0 0.00 0.0 %.2f 0 0\n", rss_gb()); fflush(stdout); continue; } first=0; int cur=req_ngen; if(len+k+cur+g_draft+2>=maxctx) cur=maxctx-len-k-g_draft-2; uint64_t h0=m->hits, ms0=m->miss; double tt0=now_s(); float *logit; if(k>0){ logit=step(m,hist+len,k,len); len+=k; } else logit=step(m,hist+len-1,1,len-1); /* prompt identico/prefisso: rigenera i logits */ EmitStream es={&T,m,now_s(),0,1}; int prod=0; grammar_reset(); /* nuova risposta = nuovo documento (MORE invece continua) */ if(cur>0) prod=spec_decode(m,hist,len,cur,eos,logit,emit_stream,&es,&len); else free(logit); double tdt=now_s()-tt0; if(tdt<1e-6) tdt=1e-6; double dh=(double)(m->hits-h0), dm=(double)(m->miss-ms0); printf("%s\x01\x01" "END" "\x01\x01\n",raw_mode?"":"\n"); printf("STAT %d %.2f %.1f %.2f %d %d\n", prod, prod/tdt, (dh+dm)>0?100.0*dh/(dh+dm):0.0, rss_gb(), prompt_tokens, prod>=cur); fflush(stdout); free(raw); g_temp=base_temp; g_nuc=base_nuc; usage_save(m); /* la cache che impara: storia aggiornata a ogni turno */ kv_disk_append(m,hist,len); /* KV su disco: il prossimo avvio riparte da qui */ repin_pass(m); /* safe request boundary: adapt session-local hot tier */ } free(line); free(buf); usage_save(m); #undef hist #undef len #undef first for(int i=0;ikv=NULL; m->Lc=m->Rc=m->Ic=NULL; m->kv_start=NULL; m->max_t=0; } static int *read_arr(jval*o,const char*k,int*n){ jval*a=json_get(o,k); int*r=malloc(a->len*sizeof(int)); for(int i=0;ilen;i++) r[i]=(int)a->kids[i]->num; *n=a->len; return r; } /* byte residenti di un tensore [O,I] al numero di bit dato (specchio di qt_bytes) */ static int64_t tbytes(int O,int I,int bits){ if(bits>=16) return (int64_t)O*I*4; if(bits>=5) return (int64_t)O*I + (int64_t)O*4; return (int64_t)O*((I+1)/2) + (int64_t)O*4; } /* byte VERI di un expert: dal container se pre-quantizzato, altrimenti stima da ebits */ static int64_t expert_bytes_probe(Model *m, int ebits){ Cfg *c=&m->c; int64_t eb=0; char nm[256]; snprintf(nm,sizeof(nm),"model.layers.%d.mlp.experts.0.gate_proj.weight",c->first_dense); if(st_nbytes(&m->S,nm)>0){ const char *suf[3]={"gate_proj","up_proj","down_proj"}; for(int k=0;k<3;k++){ snprintf(nm,sizeof(nm),"model.layers.%d.mlp.experts.0.%s.weight",c->first_dense,suf[k]); eb+=st_nbytes(&m->S,nm); snprintf(nm,sizeof(nm),"model.layers.%d.mlp.experts.0.%s.weight.qs",c->first_dense,suf[k]); int64_t q=st_nbytes(&m->S,nm); if(q>0) eb+=q; } } if(eb<=0) eb = tbytes(c->moe_inter,c->hidden,ebits)*2 + tbytes(c->hidden,c->moe_inter,ebits); return eb; } /* scarica su file l'istogramma d'uso degli expert: righe "layer eid count" (per PIN). * Include la riga MTP (layer n_layers). Scrittura atomica (tmp+rename): viene chiamata * anche a ogni turno di serve e il processo puo' morire in qualsiasi momento. */ static void stats_dump_q(Model *m, const char *path, int quiet){ char tmp[2100]; snprintf(tmp,sizeof(tmp),"%s.tmp",path); FILE *f=fopen(tmp,"w"); if(!f){ if(!quiet) perror(tmp); return; } Cfg *c=&m->c; int64_t tot=0, nz=0; for(int i=0;i<=c->n_layers;i++){ if(!m->eusage[i]) continue; for(int e=0;en_experts;e++) if(m->eusage[i][e]){ fprintf(f,"%d %d %u\n",i,e,m->eusage[i][e]); tot+=m->eusage[i][e]; nz++; } } fclose(f); rename(tmp,path); if(!quiet) fprintf(stderr,"[STATS] %lld selections across %lld distinct experts -> %s\n",(long long)tot,(long long)nz,path); } static void stats_dump(Model *m, const char *path){ stats_dump_q(m,path,0); } /* CACHE CHE IMPARA: istogramma d'uso PERSISTENTE in /.coli_usage. * Caricato all'avvio (i contatori ripartono dalla storia), salvato a ogni turno: * piu' usi colibri', meglio l'auto-pin conosce i TUOI expert caldi. */ static char g_usage_path[2100]=""; static int64_t usage_load(Model *m, const char *path){ FILE *f=fopen(path,"r"); if(!f) return 0; Cfg *c=&m->c; int l,e; uint32_t cnt; int64_t tot=0; while(fscanf(f,"%d %d %u",&l,&e,&cnt)==3) if(l>=0&&l<=c->n_layers&&e>=0&&en_experts&&m->eusage[l]){ m->eusage[l][e]+=cnt; tot+=cnt; } fclose(f); return tot; } static void usage_save(Model *m){ if(g_usage_path[0]) stats_dump_q(m,g_usage_path,1); } /* HOT-STORE ("il redis del colibri'"): carica in RAM, UNA VOLTA e per sempre, i top expert * per frequenza d'uso misurata (file STATS di un run precedente), entro un budget in GB. * Ogni hit evita una lettura dal disco lento. */ /* MLOCK: inchioda in RAM fisica gli expert pinnati cosi' il compressore di memoria di * macOS non li comprime/evacua (visto: RSS reale < residente previsto -> "hit" lenti). * -1 = auto (ON su macOS dove serve e RLIMIT_MEMLOCK e' permissivo; OFF altrove, dove * il limite e' spesso minuscolo e va alzato a mano), 0 = off, 1 = force. * EN: MLOCK: wire pinned experts into physical RAM so macOS's memory compressor can't * compress/evict them (we saw actual RSS < intended resident -> slow "hits"). -1 = auto * (ON on macOS where it matters and RLIMIT_MEMLOCK is permissive; OFF elsewhere, where the * limit is often tiny and must be raised by hand), 0 = off, 1 = force. */ static int g_mlock=-1; static int mem_should_wire(void){ if(g_mlock>=0) return g_mlock; #if defined(__APPLE__) return 1; /* macOS: default ON */ #else return 0; /* Linux/altri: opt-in via MLOCK=1 / opt-in */ #endif } /* Inchioda [addr,addr+len) in RAM fisica. No-op fuori da POSIX (Windows ecc.). * EN: wire [addr,addr+len) into physical RAM. No-op off POSIX (Windows, etc.). */ static int mem_wire(void *addr, size_t len){ #if defined(__APPLE__) || defined(__linux__) return mlock(addr, len); #else (void)addr; (void)len; return 0; #endif } /* Inchioda tutti gli slab degli expert pinnati (pesi + scale). Non fatale se fallisce. * EN: wire all pinned-expert slabs (weights + scales). Non-fatal on failure. */ static void pin_wire(Model *m){ if(!mem_should_wire()) return; Cfg *c=&m->c; double t0=now_s(); int64_t wired=0; long failed=0; for(int i=0;in_layers;i++) for(int z=0;znpin[i];z++){ ESlot *s=&m->pin[i][z]; if(s->slab){ if(mem_wire(s->slab, s->slab_cap)==0) wired+=s->slab_cap; else failed++; } if(s->fslab){ size_t fl=(size_t)s->fslab_cap*sizeof(float); if(mem_wire(s->fslab, fl)==0) wired+=fl; else failed++; } } if(failed) fprintf(stderr,"[PIN] mlock: %.1f GB wired, %ld allocations failed " "(raise the limit: ulimit -l unlimited) in %.0fs\n", wired/1e9, failed, now_s()-t0); else fprintf(stderr,"[PIN] mlock: %.1f GB wired in physical RAM " "(no compression) in %.0fs\n", wired/1e9, now_s()-t0); } typedef struct { int l,e; uint32_t c; } PinRec; static int pin_rec_cmp(const void *a,const void *b){ const PinRec *x=a,*y=b; return x->cc?1:x->c>y->c?-1:0; } static void pin_load(Model *m, const char *statspath, double gb){ FILE *f=fopen(statspath,"r"); if(!f){ perror(statspath); return; } Cfg *c=&m->c; int cap=(c->n_layers+1)*c->n_experts; PinRec *r=malloc((size_t)cap*sizeof(PinRec)); int n=0; unsigned char *seen=calloc((size_t)(c->n_layers+1)*c->n_experts,1); int l,e; uint32_t cnt; while(n=0 && e>=0 && en_experts && ((ln_layers && m->L[l].sparse) || (l==c->n_layers && m->has_mtp)); int64_t key=(int64_t)l*c->n_experts+e; if(ok&&!seen[key]){ r[n++]=(PinRec){l,e,cnt}; seen[key]=1; } } fclose(f); int fill=getenv("PIN_FILL")?atoi(getenv("PIN_FILL")):0; #ifdef COLI_CUDA if(!getenv("PIN_FILL")&&g_cuda_release_host) fill=1; #endif if(fill) for(int li=0;li<=c->n_layers;li++){ int sparse=(lin_layers&&m->L[li].sparse)||(li==c->n_layers&&m->has_mtp); if(sparse) for(int ei=0;ein_experts;ei++) if(!seen[(int64_t)li*c->n_experts+ei]) r[n++]=(PinRec){li,ei,0}; } free(seen); qsort(r,(size_t)n,sizeof(*r),pin_rec_cmp); int64_t eb=expert_bytes_probe(m,m->ebits); int npin=(int)(gb*1e9/eb); if(npin>n) npin=n; if(npin<1){ free(r); return; } int *cnt_l=calloc(c->n_layers+1,sizeof(int)); /* +1: riga MTP */ for(int a=0;an_layers;i++) if(cnt_l[i]) m->pin[i]=calloc(cnt_l[i],sizeof(ESlot)); int *slot_of=malloc((size_t)npin*sizeof(int)), *next=calloc(c->n_layers+1,sizeof(int)); for(int a=0;an_layers;i++) m->npin[i]=cnt_l[i]; double t0=now_s(); #ifdef COLI_CUDA double remaining[COLI_CUDA_MAX_DEVICES]={0}, placed_b[COLI_CUDA_MAX_DEVICES]={0}; int placed_n[COLI_CUDA_MAX_DEVICES]={0}, gpu_prefix=0; double budget=g_cuda_expert_gb*1e9, safe_total=0; if(g_cuda_enabled&&g_cuda_expert_gb>0) for(int i=0;isafe_total) budget=safe_total; if(g_cuda_enabled&&g_cuda_release_host&&budget>0){ gpu_prefix=(int)(budget/eb)+g_cuda_ndev; if(gpu_prefix>npin)gpu_prefix=npin; } #else int gpu_prefix=0; #endif /* Load the VRAM-ranked prefix first. Once uploaded its host backing is * released before the disjoint RAM-ranked suffix is allocated. */ #pragma omp parallel for schedule(dynamic,1) for(int a=0;a<(gpu_prefix?gpu_prefix:npin);a++) expert_load(m,r[a].l,r[a].e,&m->pin[r[a].l][slot_of[a]],1); m->resident_bytes+=(int64_t)(gpu_prefix?gpu_prefix:npin)*eb; #ifdef COLI_CUDA if(g_cuda_enabled && g_cuda_expert_gb>0){ int gpu_limit=gpu_prefix?gpu_prefix:npin; for(int a=0;agpu_expert_bytespin[li][slot_of[a]]; int64_t need=qt_bytes(&s->g)+qt_bytes(&s->u)+qt_bytes(&s->d); if(m->gpu_expert_bytes+need>budget) break; int tried[COLI_CUDA_MAX_DEVICES]={0}, placed=0; for(int attempt=0;attempt=need && (best<0||placed_b[i]g.cuda_device=s->u.cuda_device=s->d.cuda_device=g_cuda_devices[best]; s->g.cuda_eligible=s->u.cuda_eligible=s->d.cuda_eligible=1; if(qt_cuda_upload(&s->g) && qt_cuda_upload(&s->u) && qt_cuda_upload(&s->d)){ int64_t actual=(int64_t)coli_cuda_tensor_bytes(s->g.cuda) +(int64_t)coli_cuda_tensor_bytes(s->u.cuda) +(int64_t)coli_cuda_tensor_bytes(s->d.cuda); m->gpu_expert_count++; m->gpu_expert_bytes+=actual; remaining[best]-=actual; placed_b[best]+=actual; placed_n[best]++; if(g_cuda_release_host) expert_host_release(m,s); placed=1; } else { qt_cuda_reset(&s->g); qt_cuda_reset(&s->u); qt_cuda_reset(&s->d); s->g.cuda_eligible=s->u.cuda_eligible=s->d.cuda_eligible=0; remaining[best]=0; /* device rejected its projected capacity */ } } } } fprintf(stderr,"[CUDA] hot expert tier: %d/%d experts, VRAM %.2f GB (total budget %.1f GB)\n", m->gpu_expert_count,npin,m->gpu_expert_bytes/1e9,g_cuda_expert_gb); for(int i=0;i0&&gpu_prefixpin[r[a].l][slot_of[a]],1); m->resident_bytes+=(int64_t)(npin-gpu_prefix)*eb; } fprintf(stderr,"[PIN] placement: %d VRAM + %d RAM expert (%.1f GB warm) in %.0fs da %s\n", m->gpu_expert_count,npin-m->gpu_expert_count,(npin-m->gpu_expert_count)*eb/1e9,now_s()-t0,statspath); pin_wire(m); /* inchioda in RAM (no compressione) / wire in RAM (no compression) */ free(r); free(cnt_l); free(slot_of); free(next); } static double g_mem_avail_boot=0; /* MemAvailable all'avvio, prima di caricare il modello */ /* RAM disponibile ADESSO (GB): e' il tetto vero, non il totale. Linux: MemAvailable * da /proc/meminfo. macOS: pagine free+inactive+purgeable da host_statistics64 * (stessa semantica: recuperabili senza swap). Senza questo ramo il fallback * "assumo 8 GB" castrava la cache expert proprio sulle macchine con piu' RAM. */ static double mem_available_gb(void){ #ifdef __APPLE__ mach_msg_type_number_t cnt=HOST_VM_INFO64_COUNT; vm_statistics64_data_t vm; if(host_statistics64(mach_host_self(),HOST_VM_INFO64,(host_info64_t)&vm,&cnt)!=KERN_SUCCESS) return 0; return ((double)vm.free_count+(double)vm.inactive_count+(double)vm.purgeable_count) * (double)sysconf(_SC_PAGESIZE) / 1e9; #elif defined(_WIN32) double total, avail; compat_meminfo(&total, &avail); return avail; #else FILE *f=fopen("/proc/meminfo","r"); if(!f) return 0; char ln[256]; double kb=0; while(fgets(ln,sizeof(ln),f)) if(sscanf(ln,"MemAvailable: %lf",&kb)==1) break; fclose(f); return kb/1e6; #endif } static int kv_slot_count(void){ if(!getenv("SERVE")) return 1; return getenv("KV_SLOTS")?atoi(getenv("KV_SLOTS")):1; } static double kv_pool_bytes(Model *m, int max_ctx){ Cfg *c=&m->c; double one=(double)(c->n_layers+1)*max_ctx*(c->kv_lora+c->qk_rope)*4.0; if(m->has_dsa) for(int i=0;in_layers;i++) if(c->idx_type[i]) one+=(double)max_ctx*c->index_hd*4.0; int slots=kv_slot_count(); if(slots<1||slots>16) slots=1; return one*slots; } /* byte disponibili per gli expert (pin + LRU) nel budget — specchio del conto di cap_for_ram */ static double expert_avail(Model *m, double ram_gb, int ebits, int max_ctx){ Cfg *c=&m->c; int64_t eb=expert_bytes_probe(m,ebits); if(ram_gb<=0){ ram_gb=g_mem_avail_boot*0.88; if(ram_gb<4) ram_gb=8; } double slack = 1.2e9 + 2.5e9 + 64.0*(double)eb + kv_pool_bytes(m,max_ctx) + (double)max_ctx*c->n_heads*(c->qk_nope+c->v_head)*4.0; return ram_gb*1e9 - (double)m->resident_bytes - slack; } /* clampa la cache expert a un budget RAM (GB): cap t.c. residente + cache + slack <= budget. * ram_gb<=0 -> budget AUTO = 88% della RAM disponibile adesso (lascia respiro a OS+wrapper: * sforare = OOM-kill del kernel a meta' generazione, molto peggio di una cache piu' piccola). */ static void cap_for_ram(Model *m, double ram_gb, int ebits, int max_ctx){ Cfg *c=&m->c; int nsp=0; for(int i=0;in_layers;i++) if(m->L[i].sparse) nsp++; if(m->has_mtp) nsp+=2; /* riga cache MTP: conta ~doppia (expert int8 = 2x int4) */ int64_t eb=expert_bytes_probe(m,ebits); int auto_b = ram_gb<=0; if(auto_b){ ram_gb = g_mem_avail_boot*0.88; /* misurata PRIMA del load: il residente gia' * allocato viene sottratto sotto, non due volte */ if(ram_gb<4){ fprintf(stderr,"[RAM] MemAvailable is unreadable or too low; assuming 8 GB\n"); ram_gb=8; } } /* slack ONESTO, non forfettario (l'OOM del 2026-07-04 veniva da qui): * ws[64] slab del working-set (si materializzano TUTTI nel prefill batch-union), * KV cache a max_ctx, kvb_all della ricostruzione k/v in attention, * attivazioni+logits+overhead ~1.2 GB */ double ws_b = 64.0*(double)eb; double kv_b = kv_pool_bytes(m,max_ctx); double kvb_b = (double)max_ctx*c->n_heads*(c->qk_nope+c->v_head)*4.0; /* RISERVA PAGE-CACHE (misurato 2026-07-06): strangolarla fa crollare le pread * buffered da ~800 a ~180 MB/s — gli ultimi GB di LRU rendono MENO di quanto * costino in banda disco persa. 2.5 GB restano SEMPRE al kernel. */ double pc_b = 2.5e9; double slack = 1.2e9 + pc_b + ws_b + kv_b + kvb_b; double avail = ram_gb*1e9 - (double)m->resident_bytes - slack; int capmax = (avail>0 && nsp>0) ? (int)(avail/((double)nsp*eb)) : 0; if(capmax<1) capmax=1; if(capmax < m->ecap){ fprintf(stderr,"[RAM_GB=%.1f%s] resident %.1f GB + reserve %.1f GB (ws %.1f, KV %dx%d %.1f, kvb %.1f), " "experts %.1f MB x %d layers -> cap lowered %d->%d (projected peak %.1f GB)\n", ram_gb,auto_b?" auto":"",m->resident_bytes/1e9,slack/1e9,ws_b/1e9, kv_slot_count(),max_ctx,kv_b/1e9,kvb_b/1e9, eb/1e6, nsp, m->ecap, capmax, (m->resident_bytes + (double)capmax*nsp*eb + slack)/1e9); m->ecap=capmax; } else { /* AUTO-RAISE (issue #12): il budget consente PIU' cache di quella chiesta. * Senza questo, una macchina da 128 GB girava con la LRU di una da 16 * (cap=8 di default in coli): hit 23-28% con decine di GB inutilizzati. * Tetto a n_experts: oltre, ogni layer avrebbe slot che non puo' riempire. * CAP_RAISE=0 ripristina il comportamento fisso. */ int raise_on = getenv("CAP_RAISE")?atoi(getenv("CAP_RAISE")):1; int newcap = capmax>c->n_experts ? c->n_experts : capmax; if(raise_on && newcap>m->ecap){ for(int i=0;i<=c->n_layers;i++) if(m->ecache[i]){ m->ecache[i]=realloc(m->ecache[i],(size_t)newcap*sizeof(ESlot)); memset(m->ecache[i]+m->ecap,0,(size_t)(newcap-m->ecap)*sizeof(ESlot)); } fprintf(stderr,"[RAM_GB=%.1f%s] cap raised %d->%d: budget allows it " "(projected peak %.1f GB; set CAP_RAISE=0 to disable)\n", ram_gb, auto_b?" auto":"", m->ecap, newcap, (m->resident_bytes + (double)newcap*nsp*eb + slack)/1e9); m->ecap=newcap; } else fprintf(stderr,"[RAM_GB=%.1f%s] cap=%d ok (projected peak %.1f GB)\n", ram_gb, auto_b?" auto":"", m->ecap, (m->resident_bytes + (double)m->ecap*nsp*eb + slack)/1e9); } } int main(int argc, char **argv){ /* ---- Permanent OpenMP hot-thread tuning. The per-expert matmul regions are * tiny and back-to-back; with the default passive wait policy libgomp parks * the worker team between regions and the re-wake latency dominates. Keeping * the threads hot (active spin) collapses that overhead — measured matmul * time 66.9s -> 20.9s on the Zen5 build, with no change to numerical output. * * libgomp reads the OMP_ / GOMP_ vars in a CONSTRUCTOR that runs before * main(), so setenv() here and continuing would be too late (verified: * setenv-in-main is ignored by the already-initialised runtime). Instead, on * first entry seed the winning defaults — respecting anything the user * already set (overwrite=0) — then re-exec self once so a fresh libgomp * constructor picks them up. The COLI_OMP_TUNED sentinel guards the exec so * we re-exec at most once. Fully overridable: any explicit OMP_/GOMP_ env the * user sets wins (overwrite=0), pre-setting COLI_OMP_TUNED=1 skips the * re-exec entirely (runs with whatever policy the environment already has), * and COLI_NO_OMP_TUNE=1 is a documented kill-switch that disables the whole * re-exec + tuning path (distinct from the internal COLI_OMP_TUNED sentinel). * * Must remain the FIRST statement in main(): argv is passed verbatim to execv(). */ if(!getenv("COLI_OMP_TUNED") && !getenv("COLI_NO_OMP_TUNE")){ setenv("OMP_WAIT_POLICY","active",0); /* keep the team hot across the tiny per-expert matmul regions */ setenv("GOMP_SPINCOUNT","200000",0); /* spin briefly, then yield so long disk waits don't burn a core */ setenv("OMP_PROC_BIND","close",0); /* pack the team onto adjacent cores for cache locality */ setenv("OMP_DYNAMIC","FALSE",0); /* fixed team size: no per-region thread-count churn */ setenv("COLI_OMP_TUNED","1",1); #ifdef __linux__ fprintf(stderr,"[OMP] hot-thread tuning: re-exec once (COLI_NO_OMP_TUNE=1 to skip)\n"); execv("/proc/self/exe", argv); /* returns only on failure -> fall through and run untuned */ perror("[OMP] execv self-reexec failed, running untuned"); #endif } const char *snap=getenv("SNAP"); if(!snap){fprintf(stderr,"SNAP=\n");return 1;} g_nopack = getenv("NOPACK")?1:0; g_drop = getenv("DROP")?1:0; g_prefetch = getenv("PREFETCH")?atoi(getenv("PREFETCH")):0; g_mmap = getenv("COLI_MMAP")?atoi(getenv("COLI_MMAP")):0; if(g_mmap) fprintf(stderr,"[MMAP] expert = viste zero-copy nei file (page cache = cache)\n"); g_topk = getenv("TOPK")?atoi(getenv("TOPK")):0; g_topp = getenv("TOPP")?atof(getenv("TOPP")):0; const char *policy=getenv("COLI_POLICY"); if(!policy) policy="quality"; int experimental=!strcmp(policy,"experimental-fast"); if(strcmp(policy,"quality")&&strcmp(policy,"balanced")&&!experimental){ fprintf(stderr,"COLI_POLICY non valida: quality, balanced o experimental-fast\n"); return 2; } if(!experimental&&(g_topk>0||g_topp>0)){ fprintf(stderr,"[policy] --topp/--topk drop low-weight experts (~1.6x fewer reads, small quality cost)\n"); } g_mlock = getenv("MLOCK")?atoi(getenv("MLOCK")):-1; /* -1 auto (ON macOS), 0 off, 1 force / auto (ON macOS), 0 off, 1 force */ g_spec = getenv("SPEC")?atoi(getenv("SPEC")):1; g_draft = getenv("DRAFT")?atoi(getenv("DRAFT")):-1; /* -1 = auto: 3 se MTP, 0 senza */ g_looka = getenv("LOOKA")?atoi(getenv("LOOKA")):0; /* 1 = misura predicibilita' routing */ g_pilot = getenv("PILOT")?atoi(getenv("PILOT")):0; /* 1 = prefetch pilotato dal router */ g_pilot_real = getenv("PILOT_REAL")?atoi(getenv("PILOT_REAL")):0; /* default OFF: load VERI cross-layer (value-preserving prefetch); PILOT_REAL=1 opta in */ if(g_pilot_real) g_pilot=1; /* PILOT_REAL implica il pilota attivo */ /* Default K: hint-only PILOT keeps 8 (WILLNEED hints are free, no eviction). * Under PILOT_REAL the speculative loads are REAL and create LRU eviction * pressure, so at ~28% mispredict a large K thrashes the cache — default to 6 * (best-measured this session) unless the user set PILOT_K explicitly. */ g_pilot_k = getenv("PILOT_K")?atoi(getenv("PILOT_K")):(g_pilot_real?6:8); if(g_pilot_k<1) g_pilot_k=1; g_pipe = getenv("PIPE")?atoi(getenv("PIPE")):0; /* default OFF: overlap expert load ‖ matmul (byte-identical; reorders I/O). PIPE=1 opts in */ g_pipe_nw = getenv("PIPE_WORKERS")?atoi(getenv("PIPE_WORKERS")):8; /* I/O worker threads */ if(g_pipe_nw<1) g_pipe_nw=1; g_direct = getenv("DIRECT")?atoi(getenv("DIRECT")):0; g_idot = getenv("IDOT")?atoi(getenv("IDOT")):1; /* 0 = kernel f32 esatti (A/B) */ g_repin = getenv("REPIN")?atoi(getenv("REPIN")):0; /* RFC: re-pin ogni n token emessi (0=off) / live re-pin every n emitted tokens (0=off) */ g_absorb = getenv("ABSORB")?atoi(getenv("ABSORB")):-1; /* -1 auto: assorbita per S<=4 */ g_dsa_force = getenv("DSA_FORCE")?atoi(getenv("DSA_FORCE")):0; g_temp = getenv("TEMP")?atof(getenv("TEMP")):-1; /* -1 = auto (1.0 chat/testo, greedy altrove) */ g_nuc = getenv("NUCLEUS")?atof(getenv("NUCLEUS")):0.90f; /* piu' stretto dell'ufficiale 0.95: la coda int4 e' rumore */ if(getenv("SEED")) g_rng = (uint64_t)atoll(getenv("SEED"))*0x9E3779B97F4A7C15ULL+1; else { struct timespec ts; clock_gettime(CLOCK_MONOTONIC,&ts); g_rng ^= (uint64_t)ts.tv_nsec<<20 ^ (uint64_t)getpid(); } if(g_draft>63) g_draft=63; /* -1 = auto, risolto dopo model_init */ int cap = argc>1?atoi(argv[1]):64; int ebits= argc>2?atoi(argv[2]):8; int dbits= argc>3?atoi(argv[3]):ebits; if(getenv("SERVE") && (kv_slot_count()<1 || kv_slot_count()>16)){ fprintf(stderr,"KV_SLOTS must be between 1 and 16\n"); return 2; } #ifdef COLI_CUDA if(getenv("COLI_CUDA") && atoi(getenv("COLI_CUDA"))){ const char *one=getenv("COLI_GPU"), *many=getenv("COLI_GPUS"); if(one&&many){ fprintf(stderr,"use COLI_GPU or COLI_GPUS, not both\n"); return 2; } if(many) g_cuda_ndev=parse_cuda_devices(many,g_cuda_devices); else if(one) g_cuda_ndev=parse_cuda_devices(one,g_cuda_devices); else { g_cuda_ndev=1; g_cuda_devices[0]=0; } if(g_cuda_ndev<1){ fprintf(stderr,"invalid COLI_GPUS: use a list such as 0,1,2\n"); return 2; } g_cuda_enabled=coli_cuda_init(g_cuda_devices,g_cuda_ndev); if(!g_cuda_enabled){ fprintf(stderr,"[CUDA] requested backend is unavailable\n"); return 2; } } g_cuda_dense=getenv("CUDA_DENSE")?atoi(getenv("CUDA_DENSE")):0; g_cuda_expert_gb=getenv("CUDA_EXPERT_GB")?atof(getenv("CUDA_EXPERT_GB")):0; g_cuda_release_host=getenv("CUDA_RELEASE_HOST")?atoi(getenv("CUDA_RELEASE_HOST")):(g_cuda_ndev>1); if((getenv("COLI_GPU")||getenv("COLI_GPUS"))&&!g_cuda_enabled){ fprintf(stderr,"COLI_GPU(S) requires COLI_CUDA=1\n"); return 2; } if(g_cuda_dense&&!g_cuda_enabled){ fprintf(stderr,"CUDA_DENSE requires COLI_CUDA=1\n"); return 2; } if(g_cuda_expert_gb>0 && !g_cuda_enabled){ fprintf(stderr,"CUDA_EXPERT_GB requires COLI_CUDA=1\n"); return 2; } if(g_cuda_enabled) fprintf(stderr,"[CUDA] mode: routed experts%s%s\n", g_cuda_dense?" + resident dense tensors":" only (resident dense on CPU)", g_cuda_release_host?"; VRAM experts without host backing":""); #else if((getenv("COLI_CUDA") && atoi(getenv("COLI_CUDA"))) || getenv("COLI_GPU") || getenv("COLI_GPUS") || (getenv("CUDA_DENSE") && atoi(getenv("CUDA_DENSE"))) || (getenv("CUDA_EXPERT_GB") && atof(getenv("CUDA_EXPERT_GB"))>0)){ fprintf(stderr,"CUDA was requested, but this binary is CPU-only; rebuild with: make CUDA=1\n"); return 2; } #endif #ifdef COLI_METAL if(getenv("COLI_METAL") && atoi(getenv("COLI_METAL"))){ g_metal_enabled = coli_metal_init(); if(!g_metal_enabled){ fprintf(stderr,"[METAL] backend requested but not available\n"); return 2; } fprintf(stderr,"[METAL] mode: batched routed experts on GPU (unified-memory zero-copy)\n"); if(getenv("COLI_METAL_SPIN") && atoi(getenv("COLI_METAL_SPIN"))){ coli_metal_spin_start(); fprintf(stderr,"[METAL] keep-alive spinner ON\n"); } if(getenv("COLI_METAL_GEMM_MIN")) g_metal_gemm_min=atoi(getenv("COLI_METAL_GEMM_MIN")); } #else if(getenv("COLI_METAL") && atoi(getenv("COLI_METAL"))){ fprintf(stderr,"METAL was requested, but this binary has no Metal backend; rebuild with: make METAL=1\n"); return 2; } #endif printf("== GLM C engine (glm_moe_dsa), cache=%d experts/layer | experts@%d-bit dense@%d-bit | idot: " IDOT_KERNEL " ==\n", cap, ebits, dbits); g_mem_avail_boot = mem_available_gb(); Model m; double t0=now_s(); model_init(&m,snap,cap,ebits,dbits); if(g_draft<0){ #ifdef COLI_CUDA g_draft = (m.has_mtp&&!g_cuda_enabled) ? 3 : 0; #else g_draft = m.has_mtp ? 3 : 0; #endif } if(getenv("DSA_TOPK")) m.c.index_topk=atoi(getenv("DSA_TOPK")); /* override per test */ printf("loaded in %.2fs | resident dense: %.2f MB | layers=%d experts=%d | MTP %s (draft=%d)\n", now_s()-t0, m.resident_bytes/(1024.0*1024.0), m.c.n_layers, m.c.n_experts, m.has_mtp?"ACTIVE":"absent", g_draft); /* anche su stderr: e' il canale che le UI (coli) mostrano all'utente */ fprintf(stderr,"[MTP] %s (draft=%d)\n", m.has_mtp?"active: native speculative decoding":"absent", g_draft); if(!strncmp(snap,"/mnt/",5)) fprintf(stderr,"WARNING: the model is on %s (slow 9p/Windows filesystem; fadvise is ineffective).\n" " Keep it on ext4 (for example, /home/...) for memory efficiency and speed.\n", snap); /* HOT-STORE: PIN= [PIN_GB=g] -> top expert per frequenza fissi in RAM. * Va PRIMA di cap_for_ram: i pinnati contano nel residente. */ if(getenv("PIN")) pin_load(&m, getenv("PIN"), getenv("PIN_GB")?atof(getenv("PIN_GB")):10.0); /* CACHE CHE IMPARA: l'uso degli expert si accumula in /.coli_usage tra le sessioni; * all'avvio i piu' usati vengono auto-pinnati in RAM (meta' del budget expert: il pin * conosce la TUA storia, la LRU si adatta alla sessione). AUTOPIN=0 disattiva. */ { double ram_env = getenv("RAM_GB")?atof(getenv("RAM_GB")):0.0; int est_ctx = getenv("CTX")?atoi(getenv("CTX")):4096; /* stesso default di run_serve */ snprintf(g_usage_path,sizeof(g_usage_path),"%s/.coli_usage",snap); int64_t hist = usage_load(&m,g_usage_path); if(hist>0) fprintf(stderr,"[USAGE] expert history: %lld selections (%s)\n",(long long)hist,g_usage_path); int autopin = getenv("AUTOPIN")?atoi(getenv("AUTOPIN")):1; if(!getenv("PIN") && autopin && hist>=5000){ /* quota pin proporzionale alla FIDUCIA nella storia: con pochi dati il pin * sbaglia expert e ruba slot alla LRU adattiva; a regime (>=200k selezioni, * qualche ora di chat) arriva a meta' del budget expert. */ double conf = (double)hist/200000.0; if(conf>1) conf=1; double pin_gb = expert_avail(&m,ram_env,ebits,est_ctx)*0.5*conf/1e9; if(pin_gb>=0.5) pin_load(&m, g_usage_path, pin_gb); } /* SEMPRE: senza clamp la LRU cresce fino a cap*76 layer = decine di GB -> OOM-kill. * RAM_GB assente o <=0 = budget automatico da MemAvailable. */ cap_for_ram(&m, ram_env, ebits, est_ctx); } const char *stats=getenv("STATS"); /* STATS= -> istogramma uso expert a fine run */ /* modo scoring per benchmark: SCORE= -> log-likelihood per riga */ if(getenv("SCORE")){ run_score(&m, getenv("SCORE")); if(stats) stats_dump(&m,stats); return 0; } /* modo serve persistente per la CLI 'coli': SERVE=1 */ if(getenv("SERVE")){ if(getenv("SERVE_BATCH") && atoi(getenv("SERVE_BATCH"))) run_serve_mux(&m,snap); else run_serve(&m,snap); if(stats) stats_dump(&m,stats); return 0; } /* modo testo reale: PROMPT="..." [NGEN=n] -> tokenizza, genera, detokenizza */ if(getenv("PROMPT")){ int ngen=getenv("NGEN")?atoi(getenv("NGEN")):64; run_text(&m, snap, getenv("PROMPT"), ngen); if(stats) stats_dump(&m,stats); return 0; } /* altrimenti: validazione contro l'oracolo (ref_glm.json) */ const char *refpath=getenv("REF")?getenv("REF"):"ref_glm.json"; FILE *f=fopen(refpath,"rb"); if(!f){perror(refpath);return 1;} fseek(f,0,SEEK_END); long n=ftell(f); fseek(f,0,SEEK_SET); char *b=malloc(n+1); if(fread(b,1,n,f)!=(size_t)n){} b[n]=0; fclose(f); char *ar=NULL; jval *ref=json_parse(b,&ar); int np,nfull; int *prompt=read_arr(ref,"prompt_ids",&np); int *full=read_arr(ref,"full_ids",&nfull); int n_new=nfull-np; /* L'oracolo (ref_glm.json in repo) e' del modello TINY: contro il 744B da' 0/20 * garantito su OGNI piattaforma (prompt-token tiny = spazzatura per il modello vero). * Non e' un bug del motore — vedi #76. */ { int maxid=0; for(int i=0;imaxid) maxid=full[i]; if(m.c.vocab>1000 && maxid<1000 && !getenv("REF_FORCE")){ fprintf(stderr,"ERRORE: ref_glm.json e' l'oracolo del modello TINY (token max %d, ma il tuo vocab e' %d).\n" " Self-test motore: SNAP=./glm_tiny TF=1 ./glm 64 16 16 (atteso 32/32)\n" " Prova reale: PROMPT=\"Ciao\" NGEN=32 SNAP= ./glm 64\n" " REF_FORCE=1 per eseguire comunque il confronto (senza senso).\n", maxid, m.c.vocab); return 1; } } if(getenv("REPLAY")){ run_replay(&m,full,nfull,np); if(stats) stats_dump(&m,stats); return 0; } if(getenv("TF")){ int *tf=read_arr(ref,"tf_pred",&(int){0}); int *pred=malloc(nfull*sizeof(int)); double tt=now_s(); forward_all(&m, full, nfull, pred); double tdt=now_s()-tt; int ok=0; for(int i=0;i