12 KSTREAM_INIT(gzFile, gzread, 16384)
14 #define MC_MAX_EM_ITER 16
15 #define MC_EM_EPS 1e-5
16 #define MC_DEF_INDEL 0.15
18 unsigned char seq_nt4_table[256] = {
19 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
20 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
21 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4 /*'-'*/, 4, 4,
22 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
23 4, 0, 4, 1, 4, 4, 4, 2, 4, 4, 4, 4, 4, 4, 4, 4,
24 4, 4, 4, 4, 3, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
25 4, 0, 4, 1, 4, 4, 4, 2, 4, 4, 4, 4, 4, 4, 4, 4,
26 4, 4, 4, 4, 3, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
27 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
28 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
29 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
30 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
31 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
32 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
33 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
34 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4
37 struct __bcf_p1aux_t {
38 int n, M, n1, is_indel;
39 uint8_t *ploidy; // haploid or diploid ONLY
40 double *q2p, *pdg; // pdg -> P(D|g)
41 double *phi, *phi_indel;
42 double *z, *zswap; // aux for afs
43 double *z1, *z2, *phi1, *phi2; // only calculated when n1 is set
44 double **hg; // hypergeometric distribution
45 double *lf; // log factorial
47 double *afs, *afs1; // afs: accumulative AFS; afs1: site posterior distribution
48 const uint8_t *PL; // point to PL
52 void bcf_p1_indel_prior(bcf_p1aux_t *ma, double x)
55 for (i = 0; i < ma->M; ++i)
56 ma->phi_indel[i] = ma->phi[i] * x;
57 ma->phi_indel[ma->M] = 1. - ma->phi[ma->M] * x;
60 static void init_prior(int type, double theta, int M, double *phi)
63 if (type == MC_PTYPE_COND2) {
64 for (i = 0; i <= M; ++i)
65 phi[i] = 2. * (i + 1) / (M + 1) / (M + 2);
66 } else if (type == MC_PTYPE_FLAT) {
67 for (i = 0; i <= M; ++i)
68 phi[i] = 1. / (M + 1);
71 for (i = 0, sum = 0.; i < M; ++i)
72 sum += (phi[i] = theta / (M - i));
77 void bcf_p1_init_prior(bcf_p1aux_t *ma, int type, double theta)
79 init_prior(type, theta, ma->M, ma->phi);
80 bcf_p1_indel_prior(ma, MC_DEF_INDEL);
83 void bcf_p1_init_subprior(bcf_p1aux_t *ma, int type, double theta)
85 if (ma->n1 <= 0 || ma->n1 >= ma->M) return;
86 init_prior(type, theta, 2*ma->n1, ma->phi1);
87 init_prior(type, theta, 2*(ma->n - ma->n1), ma->phi2);
90 int bcf_p1_read_prior(bcf_p1aux_t *ma, const char *fn)
97 memset(&s, 0, sizeof(kstring_t));
98 fp = strcmp(fn, "-")? gzopen(fn, "r") : gzdopen(fileno(stdin), "r");
100 memset(ma->phi, 0, sizeof(double) * (ma->M + 1));
101 while (ks_getuntil(ks, '\n', &s, &dret) >= 0) {
102 if (strstr(s.s, "[afs] ") == s.s) {
104 for (k = 0; k <= ma->M; ++k) {
107 x = strtol(p, &p, 10);
108 if (x != k && (errno == EINVAL || errno == ERANGE)) return -1;
111 if (y == 0. && (errno == EINVAL || errno == ERANGE)) return -1;
112 ma->phi[ma->M - k] += y;
119 for (sum = 0., k = 0; k <= ma->M; ++k) sum += ma->phi[k];
120 fprintf(stderr, "[prior]");
121 for (k = 0; k <= ma->M; ++k) ma->phi[k] /= sum;
122 for (k = 0; k <= ma->M; ++k) fprintf(stderr, " %d:%.3lg", k, ma->phi[ma->M - k]);
124 for (sum = 0., k = 1; k < ma->M; ++k) sum += ma->phi[ma->M - k] * (2.* k * (ma->M - k) / ma->M / (ma->M - 1));
125 fprintf(stderr, "[%s] heterozygosity=%lf, ", __func__, (double)sum);
126 for (sum = 0., k = 1; k <= ma->M; ++k) sum += k * ma->phi[ma->M - k] / ma->M;
127 fprintf(stderr, "theta=%lf\n", (double)sum);
128 bcf_p1_indel_prior(ma, MC_DEF_INDEL);
132 bcf_p1aux_t *bcf_p1_init(int n, uint8_t *ploidy)
136 ma = calloc(1, sizeof(bcf_p1aux_t));
138 ma->n = n; ma->M = 2 * n;
140 ma->ploidy = malloc(n);
141 memcpy(ma->ploidy, ploidy, n);
142 for (i = 0, ma->M = 0; i < n; ++i) ma->M += ploidy[i];
143 if (ma->M == 2 * n) {
148 ma->q2p = calloc(256, sizeof(double));
149 ma->pdg = calloc(3 * ma->n, sizeof(double));
150 ma->phi = calloc(ma->M + 1, sizeof(double));
151 ma->phi_indel = calloc(ma->M + 1, sizeof(double));
152 ma->phi1 = calloc(ma->M + 1, sizeof(double));
153 ma->phi2 = calloc(ma->M + 1, sizeof(double));
154 ma->z = calloc(ma->M + 1, sizeof(double));
155 ma->zswap = calloc(ma->M + 1, sizeof(double));
156 ma->z1 = calloc(ma->M + 1, sizeof(double)); // actually we do not need this large
157 ma->z2 = calloc(ma->M + 1, sizeof(double));
158 ma->afs = calloc(ma->M + 1, sizeof(double));
159 ma->afs1 = calloc(ma->M + 1, sizeof(double));
160 ma->lf = calloc(ma->M + 1, sizeof(double));
161 for (i = 0; i < 256; ++i)
162 ma->q2p[i] = pow(10., -i / 10.);
163 for (i = 0; i <= ma->M; ++i) ma->lf[i] = lgamma(i + 1);
164 bcf_p1_init_prior(ma, MC_PTYPE_FULL, 1e-3); // the simplest prior
168 int bcf_p1_set_n1(bcf_p1aux_t *b, int n1)
170 if (n1 == 0 || n1 >= b->n) return -1;
171 if (b->M != b->n * 2) {
172 fprintf(stderr, "[%s] unable to set `n1' when there are haploid samples.\n", __func__);
179 void bcf_p1_set_ploidy(bcf1_t *b, bcf_p1aux_t *ma)
181 // bcf_p1aux_t fields are not visible outside of prob1.c, hence this wrapper.
182 // Ideally, this should set ploidy per site to allow pseudo-autosomal regions
183 b->ploidy = ma->ploidy;
186 void bcf_p1_destroy(bcf_p1aux_t *ma)
191 if (ma->hg && ma->n1 > 0) {
192 for (k = 0; k <= 2*ma->n1; ++k) free(ma->hg[k]);
195 free(ma->ploidy); free(ma->q2p); free(ma->pdg);
196 free(ma->phi); free(ma->phi_indel); free(ma->phi1); free(ma->phi2);
197 free(ma->z); free(ma->zswap); free(ma->z1); free(ma->z2);
198 free(ma->afs); free(ma->afs1);
203 extern double kf_gammap(double s, double z);
204 int test16(bcf1_t *b, anno16_t *a);
206 int call_multiallelic_gt(bcf1_t *b, bcf_p1aux_t *ma, double threshold)
210 for (p=b->alt; *p; p++)
212 if ( *p=='X' || p[0]=='.' ) break;
213 if ( p[0]==',' ) nals++;
215 if ( b->alt[0] && !*p ) nals++;
217 if ( nals==1 ) return 1;
221 if ( *b->ref=='N' ) return 0;
222 fprintf(stderr,"Not ready for this, more than 4 alleles at %d: %s, %s\n", b->pos+1, b->ref,b->alt);
226 // find PL and DP FORMAT indexes
230 for (i = 0; i < b->n_gi; ++i)
232 if (b->gi[i].fmt == bcf_str2int("PL", 2))
234 pl = (uint8_t*)b->gi[i].data;
237 if (b->gi[i].fmt == bcf_str2int("DP", 2)) idp=i;
239 if ( !pl ) return -1;
241 assert(ma->q2p[0] == 1);
244 int npdg = nals*(nals+1)/2;
246 _pdg = pdg = malloc(sizeof(double)*ma->n*npdg);
247 for (i=0; i<ma->n; i++)
251 for (j=0; j<npdg; j++)
253 //_pdg[j] = pow(10,-0.1*pl[j]);
254 _pdg[j] = ma->q2p[pl[j]];
258 for (j=0; j<npdg; j++) _pdg[j] /= sum;
263 if ((p = strstr(b->info, "QS=")) == 0) { fprintf(stderr,"INFO/QS is required with -m, exiting\n"); exit(1); }
265 if ( sscanf(p+3,"%lf,%lf,%lf,%lf",&qsum[0],&qsum[1],&qsum[2],&qsum[3])!=4 ) { fprintf(stderr,"Could not parse %s\n",p); exit(1); }
268 // Calculate the most likely combination of alleles
269 int ia,ib,ic, max_als=0, max_als2=0;
270 double ref_lk = 0, max_lk = INT_MIN, max_lk2 = INT_MIN, lk_sum = INT_MIN;
271 for (ia=0; ia<nals; ia++)
274 int iaa = (ia+1)*(ia+2)/2-1;
276 for (isample=0; isample<ma->n; isample++)
278 double *p = pdg + isample*npdg;
279 // assert( log(p[iaa]) <= 0 );
280 lk_tot += log(p[iaa]);
282 if ( ia==0 ) ref_lk = lk_tot;
283 if ( max_lk<lk_tot ) { max_lk2 = max_lk; max_als2 = max_als; max_lk = lk_tot; max_als = 1<<ia; }
284 else if ( max_lk2<lk_tot ) { max_lk2 = lk_tot; max_als2 = 1<<ia; }
285 lk_sum = lk_tot>lk_sum ? lk_tot + log(1+exp(lk_sum-lk_tot)) : lk_sum + log(1+exp(lk_tot-lk_sum));
289 for (ia=0; ia<nals; ia++)
291 if ( qsum[ia]==0 ) continue;
292 int iaa = (ia+1)*(ia+2)/2-1;
293 for (ib=0; ib<ia; ib++)
295 if ( qsum[ib]==0 ) continue;
297 double fa = qsum[ia]/(qsum[ia]+qsum[ib]);
298 double fb = qsum[ib]/(qsum[ia]+qsum[ib]);
299 double fab = 2*fa*fb; fa *= fa; fb *= fb;
300 int isample, ibb = (ib+1)*(ib+2)/2-1, iab = iaa - ia + ib;
301 for (isample=0; isample<ma->n; isample++)
303 if ( b->ploidy && b->ploidy[isample]==1 ) continue;
304 double *p = pdg + isample*npdg;
305 //assert( log(fa*p[iaa] + fb*p[ibb] + fab*p[iab]) <= 0 );
306 lk_tot += log(fa*p[iaa] + fb*p[ibb] + fab*p[iab]);
308 if ( max_lk<lk_tot ) { max_lk2 = max_lk; max_als2 = max_als; max_lk = lk_tot; max_als = 1<<ia|1<<ib; }
309 else if ( max_lk2<lk_tot ) { max_lk2 = lk_tot; max_als2 = 1<<ia|1<<ib; }
310 lk_sum = lk_tot>lk_sum ? lk_tot + log(1+exp(lk_sum-lk_tot)) : lk_sum + log(1+exp(lk_tot-lk_sum));
316 for (ia=0; ia<nals; ia++)
318 if ( qsum[ia]==0 ) continue;
319 int iaa = (ia+1)*(ia+2)/2-1;
320 for (ib=0; ib<ia; ib++)
322 if ( qsum[ib]==0 ) continue;
323 int ibb = (ib+1)*(ib+2)/2-1;
324 int iab = iaa - ia + ib;
325 for (ic=0; ic<ib; ic++)
327 if ( qsum[ic]==0 ) continue;
329 double fa = qsum[ia]/(qsum[ia]+qsum[ib]+qsum[ic]);
330 double fb = qsum[ib]/(qsum[ia]+qsum[ib]+qsum[ic]);
331 double fc = qsum[ic]/(qsum[ia]+qsum[ib]+qsum[ic]);
332 double fab = 2*fa*fb, fac = 2*fa*fc, fbc = 2*fb*fc; fa *= fa; fb *= fb; fc *= fc;
333 int isample, icc = (ic+1)*(ic+2)/2-1;
334 int iac = iaa - ia + ic, ibc = ibb - ib + ic;
335 for (isample=0; isample<ma->n; isample++)
337 if ( b->ploidy && b->ploidy[isample]==1 ) continue;
338 double *p = pdg + isample*npdg;
339 //assert( log(fa*p[iaa] + fb*p[ibb] + fc*p[icc] + fab*p[iab] + fac*p[iac] + fbc*p[ibc]) <= 0 );
340 lk_tot += log(fa*p[iaa] + fb*p[ibb] + fc*p[icc] + fab*p[iab] + fac*p[iac] + fbc*p[ibc]);
342 if ( max_lk<lk_tot ) { max_lk2 = max_lk; max_als2 = max_als; max_lk = lk_tot; max_als = 1<<ia|1<<ib|1<<ic; }
343 else if ( max_lk2<lk_tot ) { max_lk2 = lk_tot; max_als2 = 1<<ia|1<<ib|1<<ic; }
344 lk_sum = lk_tot>lk_sum ? lk_tot + log(1+exp(lk_sum-lk_tot)) : lk_sum + log(1+exp(lk_tot-lk_sum));
351 // Should we add another allele, does it increase the likelihood significantly?
353 for (i=0; i<nals; i++) if ( max_als&1<<i) n1++;
354 for (i=0; i<nals; i++) if ( max_als2&1<<i) n2++;
355 if ( n2<n1 && kf_gammap(1,2.0*(max_lk-max_lk2))<threshold )
361 // Get the BCF record ready for GT and GQ
363 int old_n_gi = b->n_gi;
364 s.m = b->m_str; s.l = b->l_str - 1; s.s = b->str;
365 kputs(":GT:GQ", &s); kputc('\0', &s);
366 b->m_str = s.m; b->l_str = s.l; b->str = s.s;
370 int isample, gts=0, ac[4] = {0,0,0,0};
371 for (isample = 0; isample < b->n_smpl; isample++)
373 int ploidy = b->ploidy ? b->ploidy[isample] : 2;
374 double *p = pdg + isample*npdg;
376 double lk = 0, lk_sum=0;
377 for (ia=0; ia<nals; ia++)
379 if ( !(max_als&1<<ia) ) continue;
380 int iaa = (ia+1)*(ia+2)/2-1;
381 double _lk = p[iaa]*qsum[ia]*qsum[ia];
382 if ( _lk > lk ) { lk = _lk; als = ia<<3 | ia; }
387 for (ia=0; ia<nals; ia++)
389 if ( !(max_als&1<<ia) ) continue;
390 int iaa = (ia+1)*(ia+2)/2-1;
391 for (ib=0; ib<ia; ib++)
393 if ( !(max_als&1<<ib) ) continue;
394 int iab = iaa - ia + ib;
395 double _lk = 2*qsum[ia]*qsum[ib]*p[iab];
396 if ( _lk > lk ) { lk = _lk; als = ib<<3 | ia; }
401 lk = -log(1-lk/lk_sum)/0.2302585;
402 if ( idp>=0 && ((uint16_t*)b->gi[idp].data)[isample]==0 )
404 ((uint8_t*)b->gi[old_n_gi].data)[isample] = als | 1<<7;
405 ((uint8_t*)b->gi[old_n_gi+1].data)[isample] = 0;
408 ((uint8_t*)b->gi[old_n_gi].data)[isample] = als;
409 ((uint8_t*)b->gi[old_n_gi+1].data)[isample] = lk<100 ? (int)lk : 99;
411 gts |= 1<<(als>>3&7) | 1<<(als&7);
415 bcf_fit_alt(b,max_als);
418 // Prepare BCF for output: ref, alt, filter, info, format
419 memset(&s, 0, sizeof(kstring_t)); kputc('\0', &s);
420 kputs(b->ref, &s); kputc('\0', &s);
421 kputs(b->alt, &s); kputc('\0', &s); kputc('\0', &s);
424 for (i=0; i<nals; i++)
427 if ( i>0 && ac[i] ) nalts++;
429 ksprintf(&s, "AN=%d;", an);
433 for (i=1; i<nals; i++)
435 if ( !(gts&1<<i) ) continue;
437 ksprintf(&s,"%d", ac[i]);
438 if ( nalts>0 ) kputc(',', &s);
444 int has_I16 = test16(b, &a) >= 0? 1 : 0;
447 if ( a.is_tested) ksprintf(&s, ";PV4=%.2g,%.2g,%.2g,%.2g", a.p[0], a.p[1], a.p[2], a.p[3]);
448 ksprintf(&s, ";DP4=%d,%d,%d,%d;MQ=%d", a.d[0], a.d[1], a.d[2], a.d[3], a.mq);
454 kputs(b->fmt, &s); kputc('\0', &s);
456 b->m_str = s.m; b->l_str = s.l; b->str = s.s;
457 b->qual = gts>1 ? -4.343*(ref_lk - lk_sum) : -4.343*(max_lk - lk_sum);
458 if ( b->qual>999 ) b->qual = 999;
466 static int cal_pdg(const bcf1_t *b, bcf_p1aux_t *ma)
470 p = alloca(b->n_alleles * sizeof(long));
471 memset(p, 0, sizeof(long) * b->n_alleles);
472 for (j = 0; j < ma->n; ++j) {
473 const uint8_t *pi = ma->PL + j * ma->PL_len;
474 double *pdg = ma->pdg + j * 3;
475 pdg[0] = ma->q2p[pi[2]]; pdg[1] = ma->q2p[pi[1]]; pdg[2] = ma->q2p[pi[0]];
476 for (i = 0; i < b->n_alleles; ++i)
477 p[i] += (int)pi[(i+1)*(i+2)/2-1];
479 for (i = 0; i < b->n_alleles; ++i) p[i] = p[i]<<4 | i;
480 for (i = 1; i < b->n_alleles; ++i) // insertion sort
481 for (j = i; j > 0 && p[j] < p[j-1]; --j)
482 tmp = p[j], p[j] = p[j-1], p[j-1] = tmp;
483 for (i = b->n_alleles - 1; i >= 0; --i)
484 if ((p[i]&0xf) == 0) break;
489 int bcf_p1_call_gt(const bcf_p1aux_t *ma, double f0, int k)
492 double max, f3[3], *pdg = ma->pdg + k * 3;
493 int q, i, max_i, ploidy;
494 ploidy = ma->ploidy? ma->ploidy[k] : 2;
496 f3[0] = (1.-f0)*(1.-f0); f3[1] = 2.*f0*(1.-f0); f3[2] = f0*f0;
498 f3[0] = 1. - f0; f3[1] = 0; f3[2] = f0;
500 for (i = 0, sum = 0.; i < 3; ++i)
501 sum += (g[i] = pdg[i] * f3[i]);
502 for (i = 0, max = -1., max_i = 0; i < 3; ++i) {
504 if (g[i] > max) max = g[i], max_i = i;
507 if (max < 1e-308) max = 1e-308;
508 q = (int)(-4.343 * log(max) + .499);
515 static void mc_cal_y_core(bcf_p1aux_t *ma, int beg)
517 double *z[2], *tmp, *pdg;
518 int _j, last_min, last_max;
519 assert(beg == 0 || ma->M == ma->n*2);
523 memset(z[0], 0, sizeof(double) * (ma->M + 1));
524 memset(z[1], 0, sizeof(double) * (ma->M + 1));
526 last_min = last_max = 0;
528 if (ma->M == ma->n * 2) {
530 for (_j = beg; _j < ma->n; ++_j) {
531 int k, j = _j - beg, _min = last_min, _max = last_max, M0;
534 pdg = ma->pdg + _j * 3;
535 p[0] = pdg[0]; p[1] = 2. * pdg[1]; p[2] = pdg[2];
536 for (; _min < _max && z[0][_min] < TINY; ++_min) z[0][_min] = z[1][_min] = 0.;
537 for (; _max > _min && z[0][_max] < TINY; --_max) z[0][_max] = z[1][_max] = 0.;
539 if (_min == 0) k = 0, z[1][k] = (M0-k+1) * (M0-k+2) * p[0] * z[0][k];
540 if (_min <= 1) k = 1, z[1][k] = (M0-k+1) * (M0-k+2) * p[0] * z[0][k] + k*(M0-k+2) * p[1] * z[0][k-1];
541 for (k = _min < 2? 2 : _min; k <= _max; ++k)
542 z[1][k] = (M0-k+1)*(M0-k+2) * p[0] * z[0][k] + k*(M0-k+2) * p[1] * z[0][k-1] + k*(k-1)* p[2] * z[0][k-2];
543 for (k = _min, sum = 0.; k <= _max; ++k) sum += z[1][k];
544 ma->t += log(sum / (M * (M - 1.)));
545 for (k = _min; k <= _max; ++k) z[1][k] /= sum;
546 if (_min >= 1) z[1][_min-1] = 0.;
547 if (_min >= 2) z[1][_min-2] = 0.;
548 if (j < ma->n - 1) z[1][_max+1] = z[1][_max+2] = 0.;
549 if (_j == ma->n1 - 1) { // set pop1; ma->n1==-1 when unset
551 memcpy(ma->z1, z[1], sizeof(double) * (ma->n1 * 2 + 1));
553 tmp = z[0]; z[0] = z[1]; z[1] = tmp;
554 last_min = _min; last_max = _max;
556 //for (_j = 0; _j < last_min; ++_j) z[0][_j] = 0.; // TODO: are these necessary?
557 //for (_j = last_max + 1; _j < ma->M; ++_j) z[0][_j] = 0.;
558 } else { // this block is very similar to the block above; these two might be merged in future
560 for (j = 0; j < ma->n; ++j) {
561 int k, M0, _min = last_min, _max = last_max;
563 pdg = ma->pdg + j * 3;
564 for (; _min < _max && z[0][_min] < TINY; ++_min) z[0][_min] = z[1][_min] = 0.;
565 for (; _max > _min && z[0][_max] < TINY; --_max) z[0][_max] = z[1][_max] = 0.;
568 if (ma->ploidy[j] == 1) {
569 p[0] = pdg[0]; p[1] = pdg[2];
571 if (_min == 0) k = 0, z[1][k] = (M0+1-k) * p[0] * z[0][k];
572 for (k = _min < 1? 1 : _min; k <= _max; ++k)
573 z[1][k] = (M0+1-k) * p[0] * z[0][k] + k * p[1] * z[0][k-1];
574 for (k = _min, sum = 0.; k <= _max; ++k) sum += z[1][k];
575 ma->t += log(sum / M);
576 for (k = _min; k <= _max; ++k) z[1][k] /= sum;
577 if (_min >= 1) z[1][_min-1] = 0.;
578 if (j < ma->n - 1) z[1][_max+1] = 0.;
579 } else if (ma->ploidy[j] == 2) {
580 p[0] = pdg[0]; p[1] = 2 * pdg[1]; p[2] = pdg[2];
582 if (_min == 0) k = 0, z[1][k] = (M0-k+1) * (M0-k+2) * p[0] * z[0][k];
583 if (_min <= 1) k = 1, z[1][k] = (M0-k+1) * (M0-k+2) * p[0] * z[0][k] + k*(M0-k+2) * p[1] * z[0][k-1];
584 for (k = _min < 2? 2 : _min; k <= _max; ++k)
585 z[1][k] = (M0-k+1)*(M0-k+2) * p[0] * z[0][k] + k*(M0-k+2) * p[1] * z[0][k-1] + k*(k-1)* p[2] * z[0][k-2];
586 for (k = _min, sum = 0.; k <= _max; ++k) sum += z[1][k];
587 ma->t += log(sum / (M * (M - 1.)));
588 for (k = _min; k <= _max; ++k) z[1][k] /= sum;
589 if (_min >= 1) z[1][_min-1] = 0.;
590 if (_min >= 2) z[1][_min-2] = 0.;
591 if (j < ma->n - 1) z[1][_max+1] = z[1][_max+2] = 0.;
593 tmp = z[0]; z[0] = z[1]; z[1] = tmp;
594 last_min = _min; last_max = _max;
597 if (z[0] != ma->z) memcpy(ma->z, z[0], sizeof(double) * (ma->M + 1));
600 static void mc_cal_y(bcf_p1aux_t *ma)
602 if (ma->n1 > 0 && ma->n1 < ma->n && ma->M == ma->n * 2) { // NB: ma->n1 is ineffective when there are haploid samples
605 memset(ma->z1, 0, sizeof(double) * (2 * ma->n1 + 1));
606 memset(ma->z2, 0, sizeof(double) * (2 * (ma->n - ma->n1) + 1));
607 ma->t1 = ma->t2 = 0.;
608 mc_cal_y_core(ma, ma->n1);
610 memcpy(ma->z2, ma->z, sizeof(double) * (2 * (ma->n - ma->n1) + 1));
611 mc_cal_y_core(ma, 0);
613 x = expl(ma->t - (ma->t1 + ma->t2));
614 for (k = 0; k <= ma->M; ++k) ma->z[k] *= x;
615 } else mc_cal_y_core(ma, 0);
618 #define CONTRAST_TINY 1e-30
620 extern double kf_gammaq(double s, double z); // incomplete gamma function for chi^2 test
622 static inline double chi2_test(int a, int b, int c, int d)
625 x = (double)(a+b) * (c+d) * (b+d) * (a+c);
626 if (x == 0.) return 1;
628 return kf_gammaq(.5, .5 * z * z * (a+b+c+d) / x);
631 // chi2=(a+b+c+d)(ad-bc)^2/[(a+b)(c+d)(a+c)(b+d)]
632 static inline double contrast2_aux(const bcf_p1aux_t *p1, double sum, int k1, int k2, double x[3])
634 double p = p1->phi[k1+k2] * p1->z1[k1] * p1->z2[k2] / sum * p1->hg[k1][k2];
635 int n1 = p1->n1, n2 = p1->n - p1->n1;
636 if (p < CONTRAST_TINY) return -1;
637 if (.5*k1/n1 < .5*k2/n2) x[1] += p;
638 else if (.5*k1/n1 > .5*k2/n2) x[2] += p;
640 return p * chi2_test(k1, k2, (n1<<1) - k1, (n2<<1) - k2);
643 static double contrast2(bcf_p1aux_t *p1, double ret[3])
645 int k, k1, k2, k10, k20, n1, n2;
648 n1 = p1->n1; n2 = p1->n - p1->n1;
649 if (n1 <= 0 || n2 <= 0) return 0.;
650 if (p1->hg == 0) { // initialize the hypergeometric distribution
651 /* NB: the hg matrix may take a lot of memory when there are many samples. There is a way
652 to avoid precomputing this matrix, but it is slower and quite intricate. The following
653 computation in this block can be accelerated with a similar strategy, but perhaps this
654 is not a serious concern for now. */
655 double tmp = lgamma(2*(n1+n2)+1) - (lgamma(2*n1+1) + lgamma(2*n2+1));
656 p1->hg = calloc(2*n1+1, sizeof(void*));
657 for (k1 = 0; k1 <= 2*n1; ++k1) {
658 p1->hg[k1] = calloc(2*n2+1, sizeof(double));
659 for (k2 = 0; k2 <= 2*n2; ++k2)
660 p1->hg[k1][k2] = exp(lgamma(k1+k2+1) + lgamma(p1->M-k1-k2+1) - (lgamma(k1+1) + lgamma(k2+1) + lgamma(2*n1-k1+1) + lgamma(2*n2-k2+1) + tmp));
664 long double suml = 0;
665 for (k = 0; k <= p1->M; ++k) suml += p1->phi[k] * p1->z[k];
668 { // get the max k1 and k2
671 for (k = 0, max = 0, max_k = -1; k <= 2*n1; ++k) {
672 double x = p1->phi1[k] * p1->z1[k];
673 if (x > max) max = x, max_k = k;
676 for (k = 0, max = 0, max_k = -1; k <= 2*n2; ++k) {
677 double x = p1->phi2[k] * p1->z2[k];
678 if (x > max) max = x, max_k = k;
682 { // We can do the following with one nested loop, but that is an O(N^2) thing. The following code block is much faster for large N.
684 long double z = 0., L[2];
685 x[0] = x[1] = x[2] = 0; L[0] = L[1] = 0;
686 for (k1 = k10; k1 >= 0; --k1) {
687 for (k2 = k20; k2 >= 0; --k2) {
688 if ((y = contrast2_aux(p1, sum, k1, k2, x)) < 0) break;
691 for (k2 = k20 + 1; k2 <= 2*n2; ++k2) {
692 if ((y = contrast2_aux(p1, sum, k1, k2, x)) < 0) break;
696 ret[0] = x[0]; ret[1] = x[1]; ret[2] = x[2];
697 x[0] = x[1] = x[2] = 0;
698 for (k1 = k10 + 1; k1 <= 2*n1; ++k1) {
699 for (k2 = k20; k2 >= 0; --k2) {
700 if ((y = contrast2_aux(p1, sum, k1, k2, x)) < 0) break;
703 for (k2 = k20 + 1; k2 <= 2*n2; ++k2) {
704 if ((y = contrast2_aux(p1, sum, k1, k2, x)) < 0) break;
708 ret[0] += x[0]; ret[1] += x[1]; ret[2] += x[2];
709 if (ret[0] + ret[1] + ret[2] < 0.95) { // in case of bad things happened
710 ret[0] = ret[1] = ret[2] = 0; L[0] = L[1] = 0;
711 for (k1 = 0, z = 0.; k1 <= 2*n1; ++k1)
712 for (k2 = 0; k2 <= 2*n2; ++k2)
713 if ((y = contrast2_aux(p1, sum, k1, k2, ret)) >= 0) z += y;
714 if (ret[0] + ret[1] + ret[2] < 0.95) // It seems that this may be caused by floating point errors. I do not really understand why...
715 z = 1.0, ret[0] = ret[1] = ret[2] = 1./3;
721 static double mc_cal_afs(bcf_p1aux_t *ma, double *p_ref_folded, double *p_var_folded)
724 long double sum = 0., sum2;
725 double *phi = ma->is_indel? ma->phi_indel : ma->phi;
726 memset(ma->afs1, 0, sizeof(double) * (ma->M + 1));
729 for (k = 0, sum = 0.; k <= ma->M; ++k)
730 sum += (long double)phi[k] * ma->z[k];
731 for (k = 0; k <= ma->M; ++k) {
732 ma->afs1[k] = phi[k] * ma->z[k] / sum;
733 if (isnan(ma->afs1[k]) || isinf(ma->afs1[k])) return -1.;
735 // compute folded variant probability
736 for (k = 0, sum = 0.; k <= ma->M; ++k)
737 sum += (long double)(phi[k] + phi[ma->M - k]) / 2. * ma->z[k];
738 for (k = 1, sum2 = 0.; k < ma->M; ++k)
739 sum2 += (long double)(phi[k] + phi[ma->M - k]) / 2. * ma->z[k];
740 *p_var_folded = sum2 / sum;
741 *p_ref_folded = (phi[k] + phi[ma->M - k]) / 2. * (ma->z[ma->M] + ma->z[0]) / sum;
742 // the expected frequency
743 for (k = 0, sum = 0.; k <= ma->M; ++k) {
744 ma->afs[k] += ma->afs1[k];
745 sum += k * ma->afs1[k];
750 int bcf_p1_cal(const bcf1_t *b, int do_contrast, bcf_p1aux_t *ma, bcf_p1rst_t *rst)
753 long double sum = 0.;
754 ma->is_indel = bcf_is_indel(b);
757 for (i = 0; i < b->n_gi; ++i) {
758 if (b->gi[i].fmt == bcf_str2int("PL", 2)) {
759 ma->PL = (uint8_t*)b->gi[i].data;
760 ma->PL_len = b->gi[i].len;
764 if (i == b->n_gi) return -1; // no PL
765 if (b->n_alleles < 2) return -1; // FIXME: find a better solution
767 rst->rank0 = cal_pdg(b, ma);
768 rst->f_exp = mc_cal_afs(ma, &rst->p_ref_folded, &rst->p_var_folded);
769 rst->p_ref = ma->afs1[ma->M];
770 for (k = 0, sum = 0.; k < ma->M; ++k)
772 rst->p_var = (double)sum;
773 { // compute the allele count
776 for (k = 0; k <= ma->M; ++k)
777 if (max < ma->z[k]) max = ma->z[k], rst->ac = k;
778 rst->ac = ma->M - rst->ac;
780 // calculate f_flat and f_em
781 for (k = 0, sum = 0.; k <= ma->M; ++k)
782 sum += (long double)ma->z[k];
784 for (k = 0; k <= ma->M; ++k) {
785 double p = ma->z[k] / sum;
786 rst->f_flat += k * p;
788 rst->f_flat /= ma->M;
789 { // estimate equal-tail credible interval (95% level)
792 for (i = 0, p = 0.; i <= ma->M; ++i)
793 if (p + ma->afs1[i] > 0.025) break;
794 else p += ma->afs1[i];
796 for (i = ma->M, p = 0.; i >= 0; --i)
797 if (p + ma->afs1[i] > 0.025) break;
798 else p += ma->afs1[i];
800 rst->cil = (double)(ma->M - h) / ma->M; rst->cih = (double)(ma->M - l) / ma->M;
802 if (ma->n1 > 0) { // compute LRT
803 double max0, max1, max2;
804 for (k = 0, max0 = -1; k <= ma->M; ++k)
805 if (max0 < ma->z[k]) max0 = ma->z[k];
806 for (k = 0, max1 = -1; k <= ma->n1 * 2; ++k)
807 if (max1 < ma->z1[k]) max1 = ma->z1[k];
808 for (k = 0, max2 = -1; k <= ma->M - ma->n1 * 2; ++k)
809 if (max2 < ma->z2[k]) max2 = ma->z2[k];
810 rst->lrt = log(max1 * max2 / max0);
811 rst->lrt = rst->lrt < 0? 1 : kf_gammaq(.5, rst->lrt);
812 } else rst->lrt = -1.0;
813 rst->cmp[0] = rst->cmp[1] = rst->cmp[2] = rst->p_chi2 = -1.0;
814 if (do_contrast && rst->p_var > 0.5) // skip contrast2() if the locus is a strong non-variant
815 rst->p_chi2 = contrast2(ma, rst->cmp);
819 void bcf_p1_dump_afs(bcf_p1aux_t *ma)
822 fprintf(stderr, "[afs]");
823 for (k = 0; k <= ma->M; ++k)
824 fprintf(stderr, " %d:%.3lf", k, ma->afs[ma->M - k]);
825 fprintf(stderr, "\n");
826 memset(ma->afs, 0, sizeof(double) * (ma->M + 1));