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view PsiCLASS-1.0.2/samtools-0.1.19/bcftools/call1.c @ 0:903fc43d6227 draft default tip
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| author | lsong10 |
|---|---|
| date | Fri, 26 Mar 2021 16:52:45 +0000 |
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#include <unistd.h> #include <stdlib.h> #include <math.h> #include <zlib.h> #include <errno.h> #include "bcf.h" #include "prob1.h" #include "kstring.h" #include "time.h" #ifdef _WIN32 #define srand48(x) srand(x) #define lrand48() rand() #endif #include "kseq.h" KSTREAM_INIT(gzFile, gzread, 16384) #define VC_NO_GENO 2 #define VC_BCFOUT 4 #define VC_CALL 8 #define VC_VARONLY 16 #define VC_VCFIN 32 #define VC_UNCOMP 64 #define VC_KEEPALT 256 #define VC_ACGT_ONLY 512 #define VC_QCALL 1024 #define VC_CALL_GT 2048 #define VC_ADJLD 4096 #define VC_NO_INDEL 8192 #define VC_ANNO_MAX 16384 #define VC_FIX_PL 32768 #define VC_EM 0x10000 #define VC_PAIRCALL 0x20000 #define VC_QCNT 0x40000 #define VC_INDEL_ONLY 0x80000 typedef struct { int flag, prior_type, n1, n_sub, *sublist, n_perm; uint32_t *trio_aux; char *prior_file, **subsam, *fn_dict; uint8_t *ploidy; double theta, pref, indel_frac, min_perm_p, min_smpl_frac, min_lrt, min_ma_lrt; void *bed; } viewconf_t; void *bed_read(const char *fn); void bed_destroy(void *_h); int bed_overlap(const void *_h, const char *chr, int beg, int end); static double ttest(int n1, int n2, int a[4]) { extern double kf_betai(double a, double b, double x); double t, v, u1, u2; if (n1 == 0 || n2 == 0 || n1 + n2 < 3) return 1.0; u1 = (double)a[0] / n1; u2 = (double)a[2] / n2; if (u1 <= u2) return 1.; t = (u1 - u2) / sqrt(((a[1] - n1 * u1 * u1) + (a[3] - n2 * u2 * u2)) / (n1 + n2 - 2) * (1./n1 + 1./n2)); v = n1 + n2 - 2; // printf("%d,%d,%d,%d,%lf,%lf,%lf\n", a[0], a[1], a[2], a[3], t, u1, u2); return t < 0.? 1. : .5 * kf_betai(.5*v, .5, v/(v+t*t)); } static int test16_core(int anno[16], anno16_t *a) { extern double kt_fisher_exact(int n11, int n12, int n21, int n22, double *_left, double *_right, double *two); double left, right; int i; a->p[0] = a->p[1] = a->p[2] = a->p[3] = 1.; memcpy(a->d, anno, 4 * sizeof(int)); a->depth = anno[0] + anno[1] + anno[2] + anno[3]; a->is_tested = (anno[0] + anno[1] > 0 && anno[2] + anno[3] > 0); if (a->depth == 0) return -1; a->mq = (int)(sqrt((anno[9] + anno[11]) / a->depth) + .499); kt_fisher_exact(anno[0], anno[1], anno[2], anno[3], &left, &right, &a->p[0]); for (i = 1; i < 4; ++i) a->p[i] = ttest(anno[0] + anno[1], anno[2] + anno[3], anno+4*i); return 0; } int test16(bcf1_t *b, anno16_t *a) { char *p; int i, anno[16]; a->p[0] = a->p[1] = a->p[2] = a->p[3] = 1.; a->d[0] = a->d[1] = a->d[2] = a->d[3] = 0.; a->mq = a->depth = a->is_tested = 0; if ((p = strstr(b->info, "I16=")) == 0) return -1; p += 4; for (i = 0; i < 16; ++i) { errno = 0; anno[i] = strtol(p, &p, 10); if (anno[i] == 0 && (errno == EINVAL || errno == ERANGE)) return -2; ++p; } return test16_core(anno, a); } static int update_bcf1(bcf1_t *b, const bcf_p1aux_t *pa, const bcf_p1rst_t *pr, double pref, int flag, double em[10], int cons_llr, int64_t cons_gt) { kstring_t s; int has_I16, is_var; double fq, r; anno16_t a; has_I16 = test16(b, &a) >= 0? 1 : 0; //rm_info(b, "I16="); // FIXME: probably this function has a bug. If I move it below, I16 will not be removed! memset(&s, 0, sizeof(kstring_t)); kputc('\0', &s); kputs(b->ref, &s); kputc('\0', &s); kputs(b->alt, &s); kputc('\0', &s); kputc('\0', &s); kputs(b->info, &s); if (b->info[0]) kputc(';', &s); { // print EM if (em[0] >= 0) ksprintf(&s, "AF1=%.4g", 1 - em[0]); if (em[4] >= 0 && em[4] <= 0.05) ksprintf(&s, ";G3=%.4g,%.4g,%.4g;HWE=%.3g", em[3], em[2], em[1], em[4]); if (em[5] >= 0 && em[6] >= 0) ksprintf(&s, ";AF2=%.4g,%.4g", 1 - em[5], 1 - em[6]); if (em[7] >= 0) ksprintf(&s, ";LRT=%.3g", em[7]); if (em[8] >= 0) ksprintf(&s, ";LRT2=%.3g", em[8]); } if (cons_llr > 0) { ksprintf(&s, ";CLR=%d", cons_llr); if (cons_gt > 0) ksprintf(&s, ";UGT=%c%c%c;CGT=%c%c%c", cons_gt&0xff, cons_gt>>8&0xff, cons_gt>>16&0xff, cons_gt>>32&0xff, cons_gt>>40&0xff, cons_gt>>48&0xff); } if (pr == 0) { // if pr is unset, return kputc('\0', &s); kputs(b->fmt, &s); kputc('\0', &s); free(b->str); b->m_str = s.m; b->l_str = s.l; b->str = s.s; bcf_sync(b); return 1; } is_var = (pr->p_ref < pref); r = is_var? pr->p_ref : pr->p_var; // ksprintf(&s, ";CI95=%.4g,%.4g", pr->cil, pr->cih); // FIXME: when EM is not used, ";" should be omitted! ksprintf(&s, ";AC1=%d", pr->ac); if (has_I16) ksprintf(&s, ";DP4=%d,%d,%d,%d;MQ=%d", a.d[0], a.d[1], a.d[2], a.d[3], a.mq); fq = pr->p_ref_folded < 0.5? -4.343 * log(pr->p_ref_folded) : 4.343 * log(pr->p_var_folded); if (fq < -999) fq = -999; if (fq > 999) fq = 999; ksprintf(&s, ";FQ=%.3g", fq); if (pr->cmp[0] >= 0.) { // two sample groups int i, q[3]; for (i = 1; i < 3; ++i) { double x = pr->cmp[i] + pr->cmp[0]/2.; q[i] = x == 0? 255 : (int)(-4.343 * log(x) + .499); if (q[i] > 255) q[i] = 255; } if (pr->perm_rank >= 0) ksprintf(&s, ";PR=%d", pr->perm_rank); // ksprintf(&s, ";LRT3=%.3g", pr->lrt); ksprintf(&s, ";PCHI2=%.3g;PC2=%d,%d", q[1], q[2], pr->p_chi2); } if (has_I16 && a.is_tested) ksprintf(&s, ";PV4=%.2g,%.2g,%.2g,%.2g", a.p[0], a.p[1], a.p[2], a.p[3]); kputc('\0', &s); rm_info(&s, "QS="); rm_info(&s, "I16="); kputs(b->fmt, &s); kputc('\0', &s); free(b->str); b->m_str = s.m; b->l_str = s.l; b->str = s.s; b->qual = r < 1e-100? 999 : -4.343 * log(r); if (b->qual > 999) b->qual = 999; bcf_sync(b); if (!is_var) bcf_shrink_alt(b, 1); else if (!(flag&VC_KEEPALT)) bcf_shrink_alt(b, pr->rank0 < 2? 2 : pr->rank0+1); if (is_var && (flag&VC_CALL_GT)) { // call individual genotype int i, x, old_n_gi = b->n_gi; s.m = b->m_str; s.l = b->l_str - 1; s.s = b->str; kputs(":GT:GQ", &s); kputc('\0', &s); b->m_str = s.m; b->l_str = s.l; b->str = s.s; bcf_sync(b); for (i = 0; i < b->n_smpl; ++i) { x = bcf_p1_call_gt(pa, pr->f_exp, i); ((uint8_t*)b->gi[old_n_gi].data)[i] = (x&3) == 0? 1<<3|1 : (x&3) == 1? 1 : 0; ((uint8_t*)b->gi[old_n_gi+1].data)[i] = x>>2; } } return is_var; } static char **read_samples(const char *fn, int *_n) { gzFile fp; kstream_t *ks; kstring_t s; int dret, n = 0, max = 0; char **sam = 0; *_n = 0; s.l = s.m = 0; s.s = 0; fp = gzopen(fn, "r"); if (fp == 0) { // interpret as sample names, not as a file name const char *t = fn, *p = t; while (*t) { t++; if ( *t==',' || !*t ) { sam = realloc(sam, sizeof(void*)*(n+1)); sam[n] = (char*) malloc(sizeof(char)*(t-p+2)); memcpy(sam[n], p, t-p); sam[n][t-p] = 0; sam[n][t-p+1] = 2; // assume diploid p = t+1; n++; } } *_n = n; return sam; // fail to open file } ks = ks_init(fp); while (ks_getuntil(ks, 0, &s, &dret) >= 0) { int l; if (max == n) { max = max? max<<1 : 4; sam = realloc(sam, sizeof(void*)*max); } l = s.l; sam[n] = malloc(s.l + 2); strcpy(sam[n], s.s); sam[n][l+1] = 2; // by default, diploid if (dret != '\n') { if (ks_getuntil(ks, 0, &s, &dret) >= 0) { // read ploidy, 1 or 2 int x = (int)s.s[0] - '0'; if (x == 1 || x == 2) sam[n][l+1] = x; else fprintf(stderr, "(%s) ploidy can only be 1 or 2; assume diploid\n", __func__); } if (dret != '\n') ks_getuntil(ks, '\n', &s, &dret); } ++n; } ks_destroy(ks); gzclose(fp); free(s.s); *_n = n; return sam; } static void write_header(bcf_hdr_t *h) { kstring_t str; str.l = h->l_txt? h->l_txt - 1 : 0; str.m = str.l + 1; str.s = h->txt; if (!strstr(str.s, "##INFO=<ID=DP,")) kputs("##INFO=<ID=DP,Number=1,Type=Integer,Description=\"Raw read depth\">\n", &str); if (!strstr(str.s, "##INFO=<ID=DP4,")) kputs("##INFO=<ID=DP4,Number=4,Type=Integer,Description=\"# high-quality ref-forward bases, ref-reverse, alt-forward and alt-reverse bases\">\n", &str); if (!strstr(str.s, "##INFO=<ID=MQ,")) kputs("##INFO=<ID=MQ,Number=1,Type=Integer,Description=\"Root-mean-square mapping quality of covering reads\">\n", &str); if (!strstr(str.s, "##INFO=<ID=FQ,")) kputs("##INFO=<ID=FQ,Number=1,Type=Float,Description=\"Phred probability of all samples being the same\">\n", &str); if (!strstr(str.s, "##INFO=<ID=AF1,")) kputs("##INFO=<ID=AF1,Number=1,Type=Float,Description=\"Max-likelihood estimate of the first ALT allele frequency (assuming HWE)\">\n", &str); if (!strstr(str.s, "##INFO=<ID=AC1,")) kputs("##INFO=<ID=AC1,Number=1,Type=Float,Description=\"Max-likelihood estimate of the first ALT allele count (no HWE assumption)\">\n", &str); if (!strstr(str.s, "##INFO=<ID=AN,")) kputs("##INFO=<ID=AN,Number=1,Type=Integer,Description=\"Total number of alleles in called genotypes\">\n", &str); if (!strstr(str.s, "##INFO=<ID=IS,")) kputs("##INFO=<ID=IS,Number=2,Type=Float,Description=\"Maximum number of reads supporting an indel and fraction of indel reads\">\n", &str); if (!strstr(str.s, "##INFO=<ID=AC,")) kputs("##INFO=<ID=AC,Number=A,Type=Integer,Description=\"Allele count in genotypes for each ALT allele, in the same order as listed\">\n", &str); if (!strstr(str.s, "##INFO=<ID=G3,")) kputs("##INFO=<ID=G3,Number=3,Type=Float,Description=\"ML estimate of genotype frequencies\">\n", &str); if (!strstr(str.s, "##INFO=<ID=HWE,")) kputs("##INFO=<ID=HWE,Number=1,Type=Float,Description=\"Chi^2 based HWE test P-value based on G3\">\n", &str); if (!strstr(str.s, "##INFO=<ID=CLR,")) kputs("##INFO=<ID=CLR,Number=1,Type=Integer,Description=\"Log ratio of genotype likelihoods with and without the constraint\">\n", &str); if (!strstr(str.s, "##INFO=<ID=UGT,")) kputs("##INFO=<ID=UGT,Number=1,Type=String,Description=\"The most probable unconstrained genotype configuration in the trio\">\n", &str); if (!strstr(str.s, "##INFO=<ID=CGT,")) kputs("##INFO=<ID=CGT,Number=1,Type=String,Description=\"The most probable constrained genotype configuration in the trio\">\n", &str); // if (!strstr(str.s, "##INFO=<ID=CI95,")) // kputs("##INFO=<ID=CI95,Number=2,Type=Float,Description=\"Equal-tail Bayesian credible interval of the site allele frequency at the 95% level\">\n", &str); if (!strstr(str.s, "##INFO=<ID=PV4,")) kputs("##INFO=<ID=PV4,Number=4,Type=Float,Description=\"P-values for strand bias, baseQ bias, mapQ bias and tail distance bias\">\n", &str); if (!strstr(str.s, "##INFO=<ID=INDEL,")) kputs("##INFO=<ID=INDEL,Number=0,Type=Flag,Description=\"Indicates that the variant is an INDEL.\">\n", &str); if (!strstr(str.s, "##INFO=<ID=PC2,")) kputs("##INFO=<ID=PC2,Number=2,Type=Integer,Description=\"Phred probability of the nonRef allele frequency in group1 samples being larger (,smaller) than in group2.\">\n", &str); if (!strstr(str.s, "##INFO=<ID=PCHI2,")) kputs("##INFO=<ID=PCHI2,Number=1,Type=Float,Description=\"Posterior weighted chi^2 P-value for testing the association between group1 and group2 samples.\">\n", &str); if (!strstr(str.s, "##INFO=<ID=QCHI2,")) kputs("##INFO=<ID=QCHI2,Number=1,Type=Integer,Description=\"Phred scaled PCHI2.\">\n", &str); if (!strstr(str.s, "##INFO=<ID=RP,")) kputs("##INFO=<ID=PR,Number=1,Type=Integer,Description=\"# permutations yielding a smaller PCHI2.\">\n", &str); if (!strstr(str.s, "##INFO=<ID=QBD,")) kputs("##INFO=<ID=QBD,Number=1,Type=Float,Description=\"Quality by Depth: QUAL/#reads\">\n", &str); //if (!strstr(str.s, "##INFO=<ID=RPS,")) // kputs("##INFO=<ID=RPS,Number=3,Type=Float,Description=\"Read Position Stats: depth, average, stddev\">\n", &str); if (!strstr(str.s, "##INFO=<ID=RPB,")) kputs("##INFO=<ID=RPB,Number=1,Type=Float,Description=\"Read Position Bias\">\n", &str); if (!strstr(str.s, "##INFO=<ID=MDV,")) kputs("##INFO=<ID=MDV,Number=1,Type=Integer,Description=\"Maximum number of high-quality nonRef reads in samples\">\n", &str); if (!strstr(str.s, "##INFO=<ID=VDB,")) kputs("##INFO=<ID=VDB,Number=1,Type=Float,Description=\"Variant Distance Bias (v2) for filtering splice-site artefacts in RNA-seq data. Note: this version may be broken.\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=GT,")) kputs("##FORMAT=<ID=GT,Number=1,Type=String,Description=\"Genotype\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=GQ,")) kputs("##FORMAT=<ID=GQ,Number=1,Type=Integer,Description=\"Genotype Quality\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=GL,")) kputs("##FORMAT=<ID=GL,Number=3,Type=Float,Description=\"Likelihoods for RR,RA,AA genotypes (R=ref,A=alt)\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=DP,")) kputs("##FORMAT=<ID=DP,Number=1,Type=Integer,Description=\"# high-quality bases\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=DV,")) kputs("##FORMAT=<ID=DV,Number=1,Type=Integer,Description=\"# high-quality non-reference bases\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=SP,")) kputs("##FORMAT=<ID=SP,Number=1,Type=Integer,Description=\"Phred-scaled strand bias P-value\">\n", &str); if (!strstr(str.s, "##FORMAT=<ID=PL,")) kputs("##FORMAT=<ID=PL,Number=G,Type=Integer,Description=\"List of Phred-scaled genotype likelihoods\">\n", &str); h->l_txt = str.l + 1; h->txt = str.s; } double bcf_pair_freq(const bcf1_t *b0, const bcf1_t *b1, double f[4]); int bcfview(int argc, char *argv[]) { extern int bcf_2qcall(bcf_hdr_t *h, bcf1_t *b); extern void bcf_p1_indel_prior(bcf_p1aux_t *ma, double x); extern int bcf_fix_gt(bcf1_t *b); extern int bcf_anno_max(bcf1_t *b); extern int bcf_shuffle(bcf1_t *b, int seed); extern uint32_t *bcf_trio_prep(int is_x, int is_son); extern int bcf_trio_call(uint32_t *prep, const bcf1_t *b, int *llr, int64_t *gt); extern int bcf_pair_call(const bcf1_t *b); extern int bcf_min_diff(const bcf1_t *b); extern int bcf_p1_get_M(bcf_p1aux_t *b); extern gzFile bcf_p1_fp_lk; bcf_t *bp, *bout = 0; bcf1_t *b, *blast; int c, *seeds = 0; uint64_t n_processed = 0, qcnt[256]; viewconf_t vc; bcf_p1aux_t *p1 = 0; bcf_hdr_t *hin, *hout; int tid, begin, end; char moder[4], modew[4]; tid = begin = end = -1; memset(&vc, 0, sizeof(viewconf_t)); vc.prior_type = vc.n1 = -1; vc.theta = 1e-3; vc.pref = 0.5; vc.indel_frac = -1.; vc.n_perm = 0; vc.min_perm_p = 0.01; vc.min_smpl_frac = 0; vc.min_lrt = 1; vc.min_ma_lrt = -1; memset(qcnt, 0, 8 * 256); while ((c = getopt(argc, argv, "FN1:l:cC:eHAGvbSuP:t:p:QgLi:IMs:D:U:X:d:T:Ywm:K:")) >= 0) { switch (c) { case '1': vc.n1 = atoi(optarg); break; case 'l': vc.bed = bed_read(optarg); if (!vc.bed) { fprintf(stderr,"Could not read \"%s\"\n", optarg); return 1; } break; case 'D': vc.fn_dict = strdup(optarg); break; case 'F': vc.flag |= VC_FIX_PL; break; case 'N': vc.flag |= VC_ACGT_ONLY; break; case 'G': vc.flag |= VC_NO_GENO; break; case 'A': vc.flag |= VC_KEEPALT; break; case 'b': vc.flag |= VC_BCFOUT; break; case 'S': vc.flag |= VC_VCFIN; break; case 'c': vc.flag |= VC_CALL; break; case 'e': vc.flag |= VC_EM; break; case 'v': vc.flag |= VC_VARONLY | VC_CALL; break; case 'u': vc.flag |= VC_UNCOMP | VC_BCFOUT; break; case 'g': vc.flag |= VC_CALL_GT | VC_CALL; break; case 'I': vc.flag |= VC_NO_INDEL; break; case 'w': vc.flag |= VC_INDEL_ONLY; break; case 'M': vc.flag |= VC_ANNO_MAX; break; case 'Y': vc.flag |= VC_QCNT; break; case 'm': vc.min_ma_lrt = atof(optarg); break; case 't': vc.theta = atof(optarg); break; case 'p': vc.pref = atof(optarg); break; case 'i': vc.indel_frac = atof(optarg); break; case 'Q': vc.flag |= VC_QCALL; break; case 'L': vc.flag |= VC_ADJLD; break; case 'U': vc.n_perm = atoi(optarg); break; case 'C': vc.min_lrt = atof(optarg); break; case 'X': vc.min_perm_p = atof(optarg); break; case 'd': vc.min_smpl_frac = atof(optarg); break; case 'K': bcf_p1_fp_lk = gzopen(optarg, "w"); break; case 's': vc.subsam = read_samples(optarg, &vc.n_sub); vc.ploidy = calloc(vc.n_sub + 1, 1); for (tid = 0; tid < vc.n_sub; ++tid) vc.ploidy[tid] = vc.subsam[tid][strlen(vc.subsam[tid]) + 1]; tid = -1; break; case 'T': if (strcmp(optarg, "trioauto") == 0) vc.trio_aux = bcf_trio_prep(0, 0); else if (strcmp(optarg, "trioxd") == 0) vc.trio_aux = bcf_trio_prep(1, 0); else if (strcmp(optarg, "trioxs") == 0) vc.trio_aux = bcf_trio_prep(1, 1); else if (strcmp(optarg, "pair") == 0) vc.flag |= VC_PAIRCALL; else { fprintf(stderr, "[%s] Option '-T' can only take value trioauto, trioxd or trioxs.\n", __func__); return 1; } break; case 'P': if (strcmp(optarg, "full") == 0) vc.prior_type = MC_PTYPE_FULL; else if (strcmp(optarg, "cond2") == 0) vc.prior_type = MC_PTYPE_COND2; else if (strcmp(optarg, "flat") == 0) vc.prior_type = MC_PTYPE_FLAT; else vc.prior_file = strdup(optarg); break; } } if (argc == optind) { fprintf(stderr, "\n"); fprintf(stderr, "Usage: bcftools view [options] <in.bcf> [reg]\n\n"); fprintf(stderr, "Input/output options:\n\n"); fprintf(stderr, " -A keep all possible alternate alleles at variant sites\n"); fprintf(stderr, " -b output BCF instead of VCF\n"); fprintf(stderr, " -D FILE sequence dictionary for VCF->BCF conversion [null]\n"); fprintf(stderr, " -F PL generated by r921 or before (which generate old ordering)\n"); fprintf(stderr, " -G suppress all individual genotype information\n"); fprintf(stderr, " -l FILE list of sites (chr pos) or regions (BED) to output [all sites]\n"); fprintf(stderr, " -L calculate LD for adjacent sites\n"); fprintf(stderr, " -N skip sites where REF is not A/C/G/T\n"); fprintf(stderr, " -Q output the QCALL likelihood format\n"); fprintf(stderr, " -s FILE list of samples to use [all samples]\n"); fprintf(stderr, " -S input is VCF\n"); fprintf(stderr, " -u uncompressed BCF output (force -b)\n"); fprintf(stderr, "\nConsensus/variant calling options:\n\n"); fprintf(stderr, " -c SNP calling (force -e)\n"); fprintf(stderr, " -d FLOAT skip loci where less than FLOAT fraction of samples covered [0]\n"); fprintf(stderr, " -e likelihood based analyses\n"); fprintf(stderr, " -g call genotypes at variant sites (force -c)\n"); fprintf(stderr, " -i FLOAT indel-to-substitution ratio [%.4g]\n", vc.indel_frac); fprintf(stderr, " -I skip indels\n"); fprintf(stderr, " -m FLOAT alternative model for multiallelic and rare-variant calling, include if P(chi^2)>=FLOAT\n"); fprintf(stderr, " -p FLOAT variant if P(ref|D)<FLOAT [%.3g]\n", vc.pref); fprintf(stderr, " -P STR type of prior: full, cond2, flat [full]\n"); fprintf(stderr, " -t FLOAT scaled substitution mutation rate [%.4g]\n", vc.theta); fprintf(stderr, " -T STR constrained calling; STR can be: pair, trioauto, trioxd and trioxs (see manual) [null]\n"); fprintf(stderr, " -v output potential variant sites only (force -c)\n"); fprintf(stderr, "\nContrast calling and association test options:\n\n"); fprintf(stderr, " -1 INT number of group-1 samples [0]\n"); fprintf(stderr, " -C FLOAT posterior constrast for LRT<FLOAT and P(ref|D)<0.5 [%g]\n", vc.min_lrt); fprintf(stderr, " -U INT number of permutations for association testing (effective with -1) [0]\n"); fprintf(stderr, " -X FLOAT only perform permutations for P(chi^2)<FLOAT [%g]\n", vc.min_perm_p); fprintf(stderr, "\n"); return 1; } if (vc.flag & VC_CALL) vc.flag |= VC_EM; if ((vc.flag & VC_VCFIN) && (vc.flag & VC_BCFOUT) && vc.fn_dict == 0) { fprintf(stderr, "[%s] For VCF->BCF conversion please specify the sequence dictionary with -D\n", __func__); return 1; } if (vc.n1 <= 0) vc.n_perm = 0; // TODO: give a warning here! if (vc.n_perm > 0) { seeds = malloc(vc.n_perm * sizeof(int)); srand48(time(0)); for (c = 0; c < vc.n_perm; ++c) seeds[c] = lrand48(); } b = calloc(1, sizeof(bcf1_t)); blast = calloc(1, sizeof(bcf1_t)); strcpy(moder, "r"); if (!(vc.flag & VC_VCFIN)) strcat(moder, "b"); strcpy(modew, "w"); if (vc.flag & VC_BCFOUT) strcat(modew, "b"); if (vc.flag & VC_UNCOMP) strcat(modew, "u"); bp = vcf_open(argv[optind], moder); hin = hout = vcf_hdr_read(bp); if (vc.fn_dict && (vc.flag & VC_VCFIN)) vcf_dictread(bp, hin, vc.fn_dict); bout = vcf_open("-", modew); if (!(vc.flag & VC_QCALL)) { if (vc.n_sub) { vc.sublist = calloc(vc.n_sub, sizeof(int)); hout = bcf_hdr_subsam(hin, vc.n_sub, vc.subsam, vc.sublist); } write_header(hout); // always print the header vcf_hdr_write(bout, hout); } if (vc.flag & VC_CALL) { p1 = bcf_p1_init(hout->n_smpl, vc.ploidy); if (vc.prior_file) { if (bcf_p1_read_prior(p1, vc.prior_file) < 0) { fprintf(stderr, "[%s] fail to read the prior AFS.\n", __func__); return 1; } } else bcf_p1_init_prior(p1, vc.prior_type, vc.theta); if (vc.n1 > 0 && vc.min_lrt > 0.) { // set n1 bcf_p1_set_n1(p1, vc.n1); bcf_p1_init_subprior(p1, vc.prior_type, vc.theta); } if (vc.indel_frac > 0.) bcf_p1_indel_prior(p1, vc.indel_frac); // otherwise use the default indel_frac } if (optind + 1 < argc && !(vc.flag&VC_VCFIN)) { void *str2id = bcf_build_refhash(hout); if (bcf_parse_region(str2id, argv[optind+1], &tid, &begin, &end) >= 0) { bcf_idx_t *idx; idx = bcf_idx_load(argv[optind]); if (idx) { uint64_t off; off = bcf_idx_query(idx, tid, begin); if (off == 0) { fprintf(stderr, "[%s] no records in the query region.\n", __func__); return 1; // FIXME: a lot of memory leaks... } bgzf_seek(bp->fp, off, SEEK_SET); bcf_idx_destroy(idx); } } } if (bcf_p1_fp_lk && p1) { int32_t M = bcf_p1_get_M(p1); gzwrite(bcf_p1_fp_lk, &M, 4); } while (vcf_read(bp, hin, b) > 0) { int is_indel, cons_llr = -1; int64_t cons_gt = -1; double em[10]; if ((vc.flag & VC_VARONLY) && strcmp(b->alt, "X") == 0) continue; if ((vc.flag & VC_VARONLY) && vc.min_smpl_frac > 0.) { extern int bcf_smpl_covered(const bcf1_t *b); int n = bcf_smpl_covered(b); if ((double)n / b->n_smpl < vc.min_smpl_frac) continue; } if (vc.n_sub) bcf_subsam(vc.n_sub, vc.sublist, b); if (vc.flag & VC_FIX_PL) bcf_fix_pl(b); is_indel = bcf_is_indel(b); if ((vc.flag & VC_NO_INDEL) && is_indel) continue; if ((vc.flag & VC_INDEL_ONLY) && !is_indel) continue; if ((vc.flag & VC_ACGT_ONLY) && !is_indel) { int x; if (b->ref[0] == 0 || b->ref[1] != 0) continue; x = toupper(b->ref[0]); if (x != 'A' && x != 'C' && x != 'G' && x != 'T') continue; } if (vc.bed && !bed_overlap(vc.bed, hin->ns[b->tid], b->pos, b->pos + strlen(b->ref))) continue; if (tid >= 0) { int l = strlen(b->ref); l = b->pos + (l > 0? l : 1); if (b->tid != tid || b->pos >= end) break; if (!(l > begin && end > b->pos)) continue; } ++n_processed; if ((vc.flag & VC_QCNT) && !is_indel) { // summarize the difference int x = bcf_min_diff(b); if (x > 255) x = 255; if (x >= 0) ++qcnt[x]; } if (vc.flag & VC_QCALL) { // output QCALL format; STOP here bcf_2qcall(hout, b); continue; } if (vc.trio_aux) // do trio calling bcf_trio_call(vc.trio_aux, b, &cons_llr, &cons_gt); else if (vc.flag & VC_PAIRCALL) cons_llr = bcf_pair_call(b); if (vc.flag & (VC_CALL|VC_ADJLD|VC_EM)) bcf_gl2pl(b); if (vc.flag & VC_EM) bcf_em1(b, vc.n1, 0x1ff, em); else { int i; for (i = 0; i < 9; ++i) em[i] = -1.; } if ( !(vc.flag&VC_KEEPALT) && (vc.flag&VC_CALL) && vc.min_ma_lrt>=0 ) { bcf_p1_set_ploidy(b, p1); // could be improved: do this per site to allow pseudo-autosomal regions int gts = call_multiallelic_gt(b, p1, vc.min_ma_lrt, vc.flag&VC_VARONLY); if ( gts<=1 && vc.flag & VC_VARONLY ) continue; } else if (vc.flag & VC_CALL) { // call variants bcf_p1rst_t pr; int calret; gzwrite(bcf_p1_fp_lk, &b->tid, 4); gzwrite(bcf_p1_fp_lk, &b->pos, 4); gzwrite(bcf_p1_fp_lk, &em[0], sizeof(double)); calret = bcf_p1_cal(b, (em[7] >= 0 && em[7] < vc.min_lrt), p1, &pr); if (n_processed % 100000 == 0) { fprintf(stderr, "[%s] %ld sites processed.\n", __func__, (long)n_processed); bcf_p1_dump_afs(p1); } if (pr.p_ref >= vc.pref && (vc.flag & VC_VARONLY)) continue; if (vc.n_perm && vc.n1 > 0 && pr.p_chi2 < vc.min_perm_p) { // permutation test bcf_p1rst_t r; int i, n = 0; for (i = 0; i < vc.n_perm; ++i) { #ifdef BCF_PERM_LRT // LRT based permutation is much faster but less robust to artifacts double x[10]; bcf_shuffle(b, seeds[i]); bcf_em1(b, vc.n1, 1<<7, x); if (x[7] < em[7]) ++n; #else bcf_shuffle(b, seeds[i]); bcf_p1_cal(b, 1, p1, &r); if (pr.p_chi2 >= r.p_chi2) ++n; #endif } pr.perm_rank = n; } if (calret >= 0) update_bcf1(b, p1, &pr, vc.pref, vc.flag, em, cons_llr, cons_gt); } else if (vc.flag & VC_EM) update_bcf1(b, 0, 0, 0, vc.flag, em, cons_llr, cons_gt); if (vc.flag & VC_ADJLD) { // compute LD double f[4], r2; if ((r2 = bcf_pair_freq(blast, b, f)) >= 0) { kstring_t s; s.m = s.l = 0; s.s = 0; if (*b->info) kputc(';', &s); ksprintf(&s, "NEIR=%.3f;NEIF4=%.3f,%.3f,%.3f,%.3f", r2, f[0], f[1], f[2], f[3]); bcf_append_info(b, s.s, s.l); free(s.s); } bcf_cpy(blast, b); } if (vc.flag & VC_ANNO_MAX) bcf_anno_max(b); if (vc.flag & VC_NO_GENO) { // do not output GENO fields b->n_gi = 0; b->fmt[0] = '\0'; b->l_str = b->fmt - b->str + 1; } else bcf_fix_gt(b); vcf_write(bout, hout, b); } if (bcf_p1_fp_lk) gzclose(bcf_p1_fp_lk); if (vc.prior_file) free(vc.prior_file); if (vc.flag & VC_CALL) bcf_p1_dump_afs(p1); if (hin != hout) bcf_hdr_destroy(hout); bcf_hdr_destroy(hin); bcf_destroy(b); bcf_destroy(blast); vcf_close(bp); vcf_close(bout); if (vc.fn_dict) free(vc.fn_dict); if (vc.ploidy) free(vc.ploidy); if (vc.trio_aux) free(vc.trio_aux); if (vc.n_sub) { int i; for (i = 0; i < vc.n_sub; ++i) free(vc.subsam[i]); free(vc.subsam); free(vc.sublist); } if (vc.bed) bed_destroy(vc.bed); if (vc.flag & VC_QCNT) for (c = 0; c < 256; ++c) fprintf(stderr, "QT\t%d\t%lld\n", c, (long long)qcnt[c]); if (seeds) free(seeds); if (p1) bcf_p1_destroy(p1); return 0; }