static int mpileup_reg(mplp_conf_t *conf, uint32_t beg, uint32_t end) { bam_hdr_t *hdr = conf->mplp_data[0]->h; // header of first file in input list int ret, i, tid, pos, ref_len; char *ref; while ( (ret=bam_mplp_auto(conf->iter, &tid, &pos, conf->n_plp, conf->plp)) > 0) { if ( end && (pos<beg || pos>end) ) continue; if ( conf->bed && tid >= 0 ) { int overlap = regidx_overlap(conf->bed, hdr->target_name[tid], pos, pos, NULL); if ( !conf->bed_logic ) overlap = overlap ? 0 : 1; if ( !overlap ) continue; } mplp_get_ref(conf->mplp_data[0], tid, &ref, &ref_len); int total_depth, _ref0, ref16; for (i = total_depth = 0; i < conf->nfiles; ++i) total_depth += conf->n_plp[i]; group_smpl(conf->gplp, conf->bsmpl, conf->nfiles, conf->n_plp, conf->plp); _ref0 = (ref && pos < ref_len)? ref[pos] : 'N'; ref16 = seq_nt16_table[_ref0]; bcf_callaux_clean(conf->bca, &conf->bc); for (i = 0; i < conf->gplp->n; ++i) bcf_call_glfgen(conf->gplp->n_plp[i], conf->gplp->plp[i], ref16, conf->bca, conf->bcr + i); conf->bc.tid = tid; conf->bc.pos = pos; bcf_call_combine(conf->gplp->n, conf->bcr, conf->bca, ref16, &conf->bc); bcf_clear1(conf->bcf_rec); bcf_call2bcf(&conf->bc, conf->bcf_rec, conf->bcr, conf->fmt_flag, 0, 0); flush_bcf_records(conf, conf->bcf_fp, conf->bcf_hdr, conf->bcf_rec); // call indels; todo: subsampling with total_depth>max_indel_depth instead of ignoring? // check me: rghash in bcf_call_gap_prep() should have no effect, reads mplp_func already excludes them if (!(conf->flag&MPLP_NO_INDEL) && total_depth < conf->max_indel_depth && bcf_call_gap_prep(conf->gplp->n, conf->gplp->n_plp, conf->gplp->plp, pos, conf->bca, ref) >= 0) { bcf_callaux_clean(conf->bca, &conf->bc); for (i = 0; i < conf->gplp->n; ++i) bcf_call_glfgen(conf->gplp->n_plp[i], conf->gplp->plp[i], -1, conf->bca, conf->bcr + i); if (bcf_call_combine(conf->gplp->n, conf->bcr, conf->bca, -1, &conf->bc) >= 0) { bcf_clear1(conf->bcf_rec); bcf_call2bcf(&conf->bc, conf->bcf_rec, conf->bcr, conf->fmt_flag, conf->bca, ref); flush_bcf_records(conf, conf->bcf_fp, conf->bcf_hdr, conf->bcf_rec); } } } return 0; }
static int mpileup(mplp_conf_t *conf, int n, char **fn) { extern void *bcf_call_add_rg(void *rghash, const char *hdtext, const char *list); extern void bcf_call_del_rghash(void *rghash); mplp_aux_t **data; int i, tid, pos, *n_plp, tid0 = -1, beg0 = 0, end0 = 1u<<29, ref_len, ref_tid = -1, max_depth, max_indel_depth; const bam_pileup1_t **plp; bam_mplp_t iter; bam_header_t *h = 0; char *ref; void *rghash = 0; bcf_callaux_t *bca = 0; bcf_callret1_t *bcr = 0; bcf_call_t bc; bcf_t *bp = 0; bcf_hdr_t *bh = 0; bam_sample_t *sm = 0; kstring_t buf; mplp_pileup_t gplp; memset(&gplp, 0, sizeof(mplp_pileup_t)); memset(&buf, 0, sizeof(kstring_t)); memset(&bc, 0, sizeof(bcf_call_t)); data = calloc(n, sizeof(void*)); plp = calloc(n, sizeof(void*)); n_plp = calloc(n, sizeof(int*)); sm = bam_smpl_init(); // read the header and initialize data for (i = 0; i < n; ++i) { bam_header_t *h_tmp; data[i] = calloc(1, sizeof(mplp_aux_t)); data[i]->fp = strcmp(fn[i], "-") == 0? bam_dopen(fileno(stdin), "r") : bam_open(fn[i], "r"); data[i]->conf = conf; h_tmp = bam_header_read(data[i]->fp); data[i]->h = i? h : h_tmp; // for i==0, "h" has not been set yet bam_smpl_add(sm, fn[i], (conf->flag&MPLP_IGNORE_RG)? 0 : h_tmp->text); rghash = bcf_call_add_rg(rghash, h_tmp->text, conf->pl_list); if (conf->reg) { int beg, end; bam_index_t *idx; idx = bam_index_load(fn[i]); if (idx == 0) { fprintf(stderr, "[%s] fail to load index for %d-th input.\n", __func__, i+1); exit(1); } if (bam_parse_region(h_tmp, conf->reg, &tid, &beg, &end) < 0) { fprintf(stderr, "[%s] malformatted region or wrong seqname for %d-th input.\n", __func__, i+1); exit(1); } if (i == 0) tid0 = tid, beg0 = beg, end0 = end; data[i]->iter = bam_iter_query(idx, tid, beg, end); bam_index_destroy(idx); } if (i == 0) h = h_tmp; else { // FIXME: to check consistency bam_header_destroy(h_tmp); } } gplp.n = sm->n; gplp.n_plp = calloc(sm->n, sizeof(int)); gplp.m_plp = calloc(sm->n, sizeof(int)); gplp.plp = calloc(sm->n, sizeof(void*)); fprintf(stderr, "[%s] %d samples in %d input files\n", __func__, sm->n, n); // write the VCF header if (conf->flag & MPLP_GLF) { kstring_t s; bh = calloc(1, sizeof(bcf_hdr_t)); s.l = s.m = 0; s.s = 0; bp = bcf_open("-", (conf->flag&MPLP_NO_COMP)? "wu" : "w"); for (i = 0; i < h->n_targets; ++i) { kputs(h->target_name[i], &s); kputc('\0', &s); } bh->l_nm = s.l; bh->name = malloc(s.l); memcpy(bh->name, s.s, s.l); s.l = 0; for (i = 0; i < sm->n; ++i) { kputs(sm->smpl[i], &s); kputc('\0', &s); } bh->l_smpl = s.l; bh->sname = malloc(s.l); memcpy(bh->sname, s.s, s.l); bh->txt = malloc(strlen(BAM_VERSION) + 64); bh->l_txt = 1 + sprintf(bh->txt, "##samtoolsVersion=%s\n", BAM_VERSION); free(s.s); bcf_hdr_sync(bh); bcf_hdr_write(bp, bh); bca = bcf_call_init(-1., conf->min_baseQ); bcr = calloc(sm->n, sizeof(bcf_callret1_t)); bca->rghash = rghash; bca->openQ = conf->openQ, bca->extQ = conf->extQ, bca->tandemQ = conf->tandemQ; bca->min_frac = conf->min_frac; bca->min_support = conf->min_support; } if (tid0 >= 0 && conf->fai) { // region is set ref = faidx_fetch_seq(conf->fai, h->target_name[tid0], 0, 0x7fffffff, &ref_len); ref_tid = tid0; for (i = 0; i < n; ++i) data[i]->ref = ref, data[i]->ref_id = tid0; } else ref_tid = -1, ref = 0; iter = bam_mplp_init(n, mplp_func, (void**)data); max_depth = conf->max_depth; if (max_depth * sm->n > 1<<20) fprintf(stderr, "(%s) Max depth is above 1M. Potential memory hog!\n", __func__); if (max_depth * sm->n < 8000) { max_depth = 8000 / sm->n; fprintf(stderr, "<%s> Set max per-file depth to %d\n", __func__, max_depth); } max_indel_depth = conf->max_indel_depth * sm->n; bam_mplp_set_maxcnt(iter, max_depth); while (bam_mplp_auto(iter, &tid, &pos, n_plp, plp) > 0) { if (conf->reg && (pos < beg0 || pos >= end0)) continue; // out of the region requested if (conf->bed && tid >= 0 && !bed_overlap(conf->bed, h->target_name[tid], pos, pos+1)) continue; if (tid != ref_tid) { free(ref); ref = 0; if (conf->fai) ref = faidx_fetch_seq(conf->fai, h->target_name[tid], 0, 0x7fffffff, &ref_len); for (i = 0; i < n; ++i) data[i]->ref = ref, data[i]->ref_id = tid; ref_tid = tid; } if (conf->flag & MPLP_GLF) { int total_depth, _ref0, ref16; bcf1_t *b = calloc(1, sizeof(bcf1_t)); for (i = total_depth = 0; i < n; ++i) total_depth += n_plp[i]; group_smpl(&gplp, sm, &buf, n, fn, n_plp, plp, conf->flag & MPLP_IGNORE_RG); _ref0 = (ref && pos < ref_len)? ref[pos] : 'N'; ref16 = bam_nt16_table[_ref0]; for (i = 0; i < gplp.n; ++i) bcf_call_glfgen(gplp.n_plp[i], gplp.plp[i], ref16, bca, bcr + i); bcf_call_combine(gplp.n, bcr, ref16, &bc); bcf_call2bcf(tid, pos, &bc, b, (conf->flag&(MPLP_FMT_DP|MPLP_FMT_SP))? bcr : 0, (conf->flag&MPLP_FMT_SP), 0, 0); bcf_write(bp, bh, b); bcf_destroy(b); // call indels if (!(conf->flag&MPLP_NO_INDEL) && total_depth < max_indel_depth && bcf_call_gap_prep(gplp.n, gplp.n_plp, gplp.plp, pos, bca, ref, rghash) >= 0) { for (i = 0; i < gplp.n; ++i) bcf_call_glfgen(gplp.n_plp[i], gplp.plp[i], -1, bca, bcr + i); if (bcf_call_combine(gplp.n, bcr, -1, &bc) >= 0) { b = calloc(1, sizeof(bcf1_t)); bcf_call2bcf(tid, pos, &bc, b, (conf->flag&(MPLP_FMT_DP|MPLP_FMT_SP))? bcr : 0, (conf->flag&MPLP_FMT_SP), bca, ref); bcf_write(bp, bh, b); bcf_destroy(b); } } } else { printf("%s\t%d\t%c", h->target_name[tid], pos + 1, (ref && pos < ref_len)? ref[pos] : 'N'); for (i = 0; i < n; ++i) { int j; printf("\t%d\t", n_plp[i]); if (n_plp[i] == 0) { printf("*\t*"); // FIXME: printf() is very slow... if (conf->flag & MPLP_PRINT_POS) printf("\t*"); } else { for (j = 0; j < n_plp[i]; ++j) pileup_seq(plp[i] + j, pos, ref_len, ref); putchar('\t'); for (j = 0; j < n_plp[i]; ++j) { const bam_pileup1_t *p = plp[i] + j; int c = bam1_qual(p->b)[p->qpos] + 33; if (c > 126) c = 126; putchar(c); } if (conf->flag & MPLP_PRINT_MAPQ) { putchar('\t'); for (j = 0; j < n_plp[i]; ++j) { int c = plp[i][j].b->core.qual + 33; if (c > 126) c = 126; putchar(c); } } if (conf->flag & MPLP_PRINT_POS) { putchar('\t'); for (j = 0; j < n_plp[i]; ++j) { if (j > 0) putchar(','); printf("%d", plp[i][j].qpos + 1); // FIXME: printf() is very slow... } } } } putchar('\n'); } } bcf_close(bp); bam_smpl_destroy(sm); free(buf.s); for (i = 0; i < gplp.n; ++i) free(gplp.plp[i]); free(gplp.plp); free(gplp.n_plp); free(gplp.m_plp); bcf_call_del_rghash(rghash); bcf_hdr_destroy(bh); bcf_call_destroy(bca); free(bc.PL); free(bcr); bam_mplp_destroy(iter); bam_header_destroy(h); for (i = 0; i < n; ++i) { bam_close(data[i]->fp); if (data[i]->iter) bam_iter_destroy(data[i]->iter); free(data[i]); } free(data); free(plp); free(ref); free(n_plp); return 0; }
/* * Performs pileup * @param conf configuration for this pileup * @param n number of files specified in fn * @param fn filenames */ static int mpileup(mplp_conf_t *conf, int n, char **fn) { extern void *bcf_call_add_rg(void *rghash, const char *hdtext, const char *list); extern void bcf_call_del_rghash(void *rghash); mplp_aux_t **data; int i, tid, pos, *n_plp, tid0 = -1, beg0 = 0, end0 = 1u<<29, ref_len, ref_tid = -1, max_depth, max_indel_depth; const bam_pileup1_t **plp; bam_mplp_t iter; bam_hdr_t *h = NULL; /* header of first file in input list */ char *ref; void *rghash = NULL; FILE *pileup_fp = NULL; bcf_callaux_t *bca = NULL; bcf_callret1_t *bcr = NULL; bcf_call_t bc; htsFile *bcf_fp = NULL; bcf_hdr_t *bcf_hdr = NULL; bam_sample_t *sm = NULL; kstring_t buf; mplp_pileup_t gplp; memset(&gplp, 0, sizeof(mplp_pileup_t)); memset(&buf, 0, sizeof(kstring_t)); memset(&bc, 0, sizeof(bcf_call_t)); data = calloc(n, sizeof(mplp_aux_t*)); plp = calloc(n, sizeof(bam_pileup1_t*)); n_plp = calloc(n, sizeof(int)); sm = bam_smpl_init(); if (n == 0) { fprintf(stderr,"[%s] no input file/data given\n", __func__); exit(1); } // read the header of each file in the list and initialize data for (i = 0; i < n; ++i) { bam_hdr_t *h_tmp; data[i] = calloc(1, sizeof(mplp_aux_t)); data[i]->fp = sam_open(fn[i], "rb"); if ( !data[i]->fp ) { fprintf(stderr, "[%s] failed to open %s: %s\n", __func__, fn[i], strerror(errno)); exit(1); } hts_set_fai_filename(data[i]->fp, conf->fai_fname); data[i]->conf = conf; h_tmp = sam_hdr_read(data[i]->fp); if ( !h_tmp ) { fprintf(stderr,"[%s] fail to read the header of %s\n", __func__, fn[i]); exit(1); } data[i]->h = i? h : h_tmp; // for i==0, "h" has not been set yet bam_smpl_add(sm, fn[i], (conf->flag&MPLP_IGNORE_RG)? 0 : h_tmp->text); // Collect read group IDs with PL (platform) listed in pl_list (note: fragile, strstr search) rghash = bcf_call_add_rg(rghash, h_tmp->text, conf->pl_list); if (conf->reg) { hts_idx_t *idx = sam_index_load(data[i]->fp, fn[i]); if (idx == 0) { fprintf(stderr, "[%s] fail to load index for %s\n", __func__, fn[i]); exit(1); } if ( (data[i]->iter=sam_itr_querys(idx, data[i]->h, conf->reg)) == 0) { fprintf(stderr, "[E::%s] fail to parse region '%s'\n", __func__, conf->reg); exit(1); } if (i == 0) tid0 = data[i]->iter->tid, beg0 = data[i]->iter->beg, end0 = data[i]->iter->end; hts_idx_destroy(idx); } if (i == 0) h = h_tmp; /* save the header of first file in list */ else { // FIXME: to check consistency bam_hdr_destroy(h_tmp); } } // allocate data storage proportionate to number of samples being studied sm->n gplp.n = sm->n; gplp.n_plp = calloc(sm->n, sizeof(int)); gplp.m_plp = calloc(sm->n, sizeof(int)); gplp.plp = calloc(sm->n, sizeof(bam_pileup1_t*)); fprintf(stderr, "[%s] %d samples in %d input files\n", __func__, sm->n, n); // write the VCF header if (conf->flag & MPLP_BCF) { const char *mode; if ( conf->flag & MPLP_VCF ) mode = (conf->flag&MPLP_NO_COMP)? "wu" : "wz"; // uncompressed VCF or compressed VCF else mode = (conf->flag&MPLP_NO_COMP)? "wub" : "wb"; // uncompressed BCF or compressed BCF bcf_fp = bcf_open(conf->output_fname? conf->output_fname : "-", mode); if (bcf_fp == NULL) { fprintf(stderr, "[%s] failed to write to %s: %s\n", __func__, conf->output_fname? conf->output_fname : "standard output", strerror(errno)); exit(1); } bcf_hdr = bcf_hdr_init("w"); kstring_t str = {0,0,0}; ksprintf(&str, "##samtoolsVersion=%s+htslib-%s\n",samtools_version(),hts_version()); bcf_hdr_append(bcf_hdr, str.s); str.l = 0; ksprintf(&str, "##samtoolsCommand=samtools mpileup"); for (i=1; i<conf->argc; i++) ksprintf(&str, " %s", conf->argv[i]); kputc('\n', &str); bcf_hdr_append(bcf_hdr, str.s); if (conf->fai_fname) { str.l = 0; ksprintf(&str, "##reference=file://%s\n", conf->fai_fname); bcf_hdr_append(bcf_hdr, str.s); } // todo: use/write new BAM header manipulation routines, fill also UR, M5 for (i=0; i<h->n_targets; i++) { str.l = 0; ksprintf(&str, "##contig=<ID=%s,length=%d>", h->target_name[i], h->target_len[i]); bcf_hdr_append(bcf_hdr, str.s); } free(str.s); bcf_hdr_append(bcf_hdr,"##ALT=<ID=X,Description=\"Represents allele(s) other than observed.\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=INDEL,Number=0,Type=Flag,Description=\"Indicates that the variant is an INDEL.\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=IDV,Number=1,Type=Integer,Description=\"Maximum number of reads supporting an indel\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=IMF,Number=1,Type=Float,Description=\"Maximum fraction of reads supporting an indel\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=DP,Number=1,Type=Integer,Description=\"Raw read depth\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=VDB,Number=1,Type=Float,Description=\"Variant Distance Bias for filtering splice-site artefacts in RNA-seq data (bigger is better)\",Version=\"3\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=RPB,Number=1,Type=Float,Description=\"Mann-Whitney U test of Read Position Bias (bigger is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=MQB,Number=1,Type=Float,Description=\"Mann-Whitney U test of Mapping Quality Bias (bigger is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=BQB,Number=1,Type=Float,Description=\"Mann-Whitney U test of Base Quality Bias (bigger is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=MQSB,Number=1,Type=Float,Description=\"Mann-Whitney U test of Mapping Quality vs Strand Bias (bigger is better)\">"); #if CDF_MWU_TESTS bcf_hdr_append(bcf_hdr,"##INFO=<ID=RPB2,Number=1,Type=Float,Description=\"Mann-Whitney U test of Read Position Bias [CDF] (bigger is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=MQB2,Number=1,Type=Float,Description=\"Mann-Whitney U test of Mapping Quality Bias [CDF] (bigger is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=BQB2,Number=1,Type=Float,Description=\"Mann-Whitney U test of Base Quality Bias [CDF] (bigger is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=MQSB2,Number=1,Type=Float,Description=\"Mann-Whitney U test of Mapping Quality vs Strand Bias [CDF] (bigger is better)\">"); #endif bcf_hdr_append(bcf_hdr,"##INFO=<ID=SGB,Number=1,Type=Float,Description=\"Segregation based metric.\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=MQ0F,Number=1,Type=Float,Description=\"Fraction of MQ0 reads (smaller is better)\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=I16,Number=16,Type=Float,Description=\"Auxiliary tag used for calling, see description of bcf_callret1_t in bam2bcf.h\">"); bcf_hdr_append(bcf_hdr,"##INFO=<ID=QS,Number=R,Type=Float,Description=\"Auxiliary tag used for calling\">"); bcf_hdr_append(bcf_hdr,"##FORMAT=<ID=PL,Number=G,Type=Integer,Description=\"List of Phred-scaled genotype likelihoods\">"); if ( conf->fmt_flag&B2B_FMT_DP ) bcf_hdr_append(bcf_hdr,"##FORMAT=<ID=DP,Number=1,Type=Integer,Description=\"Number of high-quality bases\">"); if ( conf->fmt_flag&B2B_FMT_DV ) bcf_hdr_append(bcf_hdr,"##FORMAT=<ID=DV,Number=1,Type=Integer,Description=\"Number of high-quality non-reference bases\">"); if ( conf->fmt_flag&B2B_FMT_DPR ) bcf_hdr_append(bcf_hdr,"##FORMAT=<ID=DPR,Number=R,Type=Integer,Description=\"Number of high-quality bases observed for each allele\">"); if ( conf->fmt_flag&B2B_INFO_DPR ) bcf_hdr_append(bcf_hdr,"##INFO=<ID=DPR,Number=R,Type=Integer,Description=\"Number of high-quality bases observed for each allele\">"); if ( conf->fmt_flag&B2B_FMT_DP4 ) bcf_hdr_append(bcf_hdr,"##FORMAT=<ID=DP4,Number=4,Type=Integer,Description=\"Number of high-quality ref-fwd, ref-reverse, alt-fwd and alt-reverse bases\">"); if ( conf->fmt_flag&B2B_FMT_SP ) bcf_hdr_append(bcf_hdr,"##FORMAT=<ID=SP,Number=1,Type=Integer,Description=\"Phred-scaled strand bias P-value\">"); for (i=0; i<sm->n; i++) bcf_hdr_add_sample(bcf_hdr, sm->smpl[i]); bcf_hdr_add_sample(bcf_hdr, NULL); bcf_hdr_write(bcf_fp, bcf_hdr); bca = bcf_call_init(-1., conf->min_baseQ); bcr = calloc(sm->n, sizeof(bcf_callret1_t)); bca->rghash = rghash; bca->openQ = conf->openQ, bca->extQ = conf->extQ, bca->tandemQ = conf->tandemQ; bca->min_frac = conf->min_frac; bca->min_support = conf->min_support; bca->per_sample_flt = conf->flag & MPLP_PER_SAMPLE; bc.bcf_hdr = bcf_hdr; bc.n = sm->n; bc.PL = malloc(15 * sm->n * sizeof(*bc.PL)); if (conf->fmt_flag) { assert( sizeof(float)==sizeof(int32_t) ); bc.DP4 = malloc(sm->n * sizeof(int32_t) * 4); bc.fmt_arr = malloc(sm->n * sizeof(float)); // all fmt_flag fields if ( conf->fmt_flag&(B2B_INFO_DPR|B2B_FMT_DPR) ) { // first B2B_MAX_ALLELES fields for total numbers, the rest per-sample bc.DPR = malloc((sm->n+1)*B2B_MAX_ALLELES*sizeof(int32_t)); for (i=0; i<sm->n; i++) bcr[i].DPR = bc.DPR + (i+1)*B2B_MAX_ALLELES; } } } else { pileup_fp = conf->output_fname? fopen(conf->output_fname, "w") : stdout; if (pileup_fp == NULL) { fprintf(stderr, "[%s] failed to write to %s: %s\n", __func__, conf->output_fname, strerror(errno)); exit(1); } } if (tid0 >= 0 && conf->fai) { // region is set ref = faidx_fetch_seq(conf->fai, h->target_name[tid0], 0, 0x7fffffff, &ref_len); ref_tid = tid0; for (i = 0; i < n; ++i) data[i]->ref = ref, data[i]->ref_id = tid0; } else ref_tid = -1, ref = 0; // begin pileup iter = bam_mplp_init(n, mplp_func, (void**)data); if ( conf->flag & MPLP_SMART_OVERLAPS ) bam_mplp_init_overlaps(iter); max_depth = conf->max_depth; if (max_depth * sm->n > 1<<20) fprintf(stderr, "(%s) Max depth is above 1M. Potential memory hog!\n", __func__); if (max_depth * sm->n < 8000) { max_depth = 8000 / sm->n; fprintf(stderr, "<%s> Set max per-file depth to %d\n", __func__, max_depth); } max_indel_depth = conf->max_indel_depth * sm->n; bam_mplp_set_maxcnt(iter, max_depth); bcf1_t *bcf_rec = bcf_init1(); int ret; while ( (ret=bam_mplp_auto(iter, &tid, &pos, n_plp, plp)) > 0) { if (conf->reg && (pos < beg0 || pos >= end0)) continue; // out of the region requested if (conf->bed && tid >= 0 && !bed_overlap(conf->bed, h->target_name[tid], pos, pos+1)) continue; if (tid != ref_tid) { free(ref); ref = 0; if (conf->fai) ref = faidx_fetch_seq(conf->fai, h->target_name[tid], 0, 0x7fffffff, &ref_len); for (i = 0; i < n; ++i) data[i]->ref = ref, data[i]->ref_id = tid; ref_tid = tid; } if (conf->flag & MPLP_BCF) { int total_depth, _ref0, ref16; for (i = total_depth = 0; i < n; ++i) total_depth += n_plp[i]; group_smpl(&gplp, sm, &buf, n, fn, n_plp, plp, conf->flag & MPLP_IGNORE_RG); _ref0 = (ref && pos < ref_len)? ref[pos] : 'N'; ref16 = seq_nt16_table[_ref0]; bcf_callaux_clean(bca, &bc); for (i = 0; i < gplp.n; ++i) bcf_call_glfgen(gplp.n_plp[i], gplp.plp[i], ref16, bca, bcr + i); bc.tid = tid; bc.pos = pos; bcf_call_combine(gplp.n, bcr, bca, ref16, &bc); bcf_clear1(bcf_rec); bcf_call2bcf(&bc, bcf_rec, bcr, conf->fmt_flag, 0, 0); bcf_write1(bcf_fp, bcf_hdr, bcf_rec); // call indels; todo: subsampling with total_depth>max_indel_depth instead of ignoring? if (!(conf->flag&MPLP_NO_INDEL) && total_depth < max_indel_depth && bcf_call_gap_prep(gplp.n, gplp.n_plp, gplp.plp, pos, bca, ref, rghash) >= 0) { bcf_callaux_clean(bca, &bc); for (i = 0; i < gplp.n; ++i) bcf_call_glfgen(gplp.n_plp[i], gplp.plp[i], -1, bca, bcr + i); if (bcf_call_combine(gplp.n, bcr, bca, -1, &bc) >= 0) { bcf_clear1(bcf_rec); bcf_call2bcf(&bc, bcf_rec, bcr, conf->fmt_flag, bca, ref); bcf_write1(bcf_fp, bcf_hdr, bcf_rec); } } } else { fprintf(pileup_fp, "%s\t%d\t%c", h->target_name[tid], pos + 1, (ref && pos < ref_len)? ref[pos] : 'N'); for (i = 0; i < n; ++i) { int j, cnt; for (j = cnt = 0; j < n_plp[i]; ++j) { const bam_pileup1_t *p = plp[i] + j; if (bam_get_qual(p->b)[p->qpos] >= conf->min_baseQ) ++cnt; } fprintf(pileup_fp, "\t%d\t", cnt); if (n_plp[i] == 0) { fputs("*\t*", pileup_fp); if (conf->flag & MPLP_PRINT_MAPQ) fputs("\t*", pileup_fp); if (conf->flag & MPLP_PRINT_POS) fputs("\t*", pileup_fp); } else { for (j = 0; j < n_plp[i]; ++j) { const bam_pileup1_t *p = plp[i] + j; if (bam_get_qual(p->b)[p->qpos] >= conf->min_baseQ) pileup_seq(pileup_fp, plp[i] + j, pos, ref_len, ref); } putc('\t', pileup_fp); for (j = 0; j < n_plp[i]; ++j) { const bam_pileup1_t *p = plp[i] + j; int c = bam_get_qual(p->b)[p->qpos]; if (c >= conf->min_baseQ) { c = c + 33 < 126? c + 33 : 126; putc(c, pileup_fp); } } if (conf->flag & MPLP_PRINT_MAPQ) { putc('\t', pileup_fp); for (j = 0; j < n_plp[i]; ++j) { const bam_pileup1_t *p = plp[i] + j; int c = bam_get_qual(p->b)[p->qpos]; if ( c < conf->min_baseQ ) continue; c = plp[i][j].b->core.qual + 33; if (c > 126) c = 126; putc(c, pileup_fp); } } if (conf->flag & MPLP_PRINT_POS) { putc('\t', pileup_fp); for (j = 0; j < n_plp[i]; ++j) { if (j > 0) putc(',', pileup_fp); fprintf(pileup_fp, "%d", plp[i][j].qpos + 1); // FIXME: printf() is very slow... } } } } putc('\n', pileup_fp); } } // clean up free(bc.tmp.s); bcf_destroy1(bcf_rec); if (bcf_fp) { hts_close(bcf_fp); bcf_hdr_destroy(bcf_hdr); bcf_call_destroy(bca); free(bc.PL); free(bc.DP4); free(bc.DPR); free(bc.fmt_arr); free(bcr); } if (pileup_fp && conf->output_fname) fclose(pileup_fp); bam_smpl_destroy(sm); free(buf.s); for (i = 0; i < gplp.n; ++i) free(gplp.plp[i]); free(gplp.plp); free(gplp.n_plp); free(gplp.m_plp); bcf_call_del_rghash(rghash); bam_mplp_destroy(iter); bam_hdr_destroy(h); for (i = 0; i < n; ++i) { sam_close(data[i]->fp); if (data[i]->iter) hts_itr_destroy(data[i]->iter); free(data[i]); } free(data); free(plp); free(ref); free(n_plp); return ret; }
static int mpileup(mplp_conf_t *conf, int n, char **fn) { extern void *bcf_call_add_rg(void *rghash, const char *hdtext, const char *list); extern void bcf_call_del_rghash(void *rghash); mplp_aux_t **data; int i, tid, pos, *n_plp, tid0 = -1, beg0 = 0, end0 = 1u<<29, ref_len, ref_tid = -1, max_depth, max_indel_depth; const bam_pileup1_t **plp; bam_mplp_t iter; bam_header_t *h = 0; char *ref; void *rghash = 0; bcf_callaux_t *bca = 0; bcf_callret1_t *bcr = 0; bcf_call_t bc; bcf_t *bp = 0; bcf_hdr_t *bh = 0; bam_sample_t *sm = 0; kstring_t buf; mplp_pileup_t gplp; memset(&gplp, 0, sizeof(mplp_pileup_t)); memset(&buf, 0, sizeof(kstring_t)); memset(&bc, 0, sizeof(bcf_call_t)); data = calloc(n, sizeof(void*)); plp = calloc(n, sizeof(void*)); n_plp = calloc(n, sizeof(int*)); sm = bam_smpl_init(); // read the header and initialize data for (i = 0; i < n; ++i) { bam_header_t *h_tmp; data[i] = calloc(1, sizeof(mplp_aux_t)); data[i]->fp = strcmp(fn[i], "-") == 0? bam_dopen(fileno(stdin), "r") : bam_open(fn[i], "r"); data[i]->conf = conf; h_tmp = bam_header_read(data[i]->fp); data[i]->h = i? h : h_tmp; // for i==0, "h" has not been set yet bam_smpl_add(sm, fn[i], (conf->flag&MPLP_IGNORE_RG)? 0 : h_tmp->text); rghash = bcf_call_add_rg(rghash, h_tmp->text, conf->pl_list); if (conf->reg) { int beg, end; bam_index_t *idx; idx = bam_index_load(fn[i]); if (idx == 0) { fprintf(stderr, "[%s] fail to load index for %d-th input.\n", __func__, i+1); exit(1); } if (bam_parse_region(h_tmp, conf->reg, &tid, &beg, &end) < 0) { fprintf(stderr, "[%s] malformatted region or wrong seqname for %d-th input.\n", __func__, i+1); exit(1); } if (i == 0) tid0 = tid, beg0 = beg, end0 = end; data[i]->iter = bam_iter_query(idx, tid, beg, end); bam_index_destroy(idx); } if (i == 0) h = h_tmp; else { // FIXME: to check consistency bam_header_destroy(h_tmp); } } gplp.n = sm->n; gplp.n_plp = calloc(sm->n, sizeof(int)); gplp.m_plp = calloc(sm->n, sizeof(int)); gplp.plp = calloc(sm->n, sizeof(void*)); fprintf(stderr, "[%s] %d samples in %d input files\n", __func__, sm->n, n); // write the VCF header if (conf->flag & MPLP_GLF) { kstring_t s; bh = calloc(1, sizeof(bcf_hdr_t)); s.l = s.m = 0; s.s = 0; bp = bcf_open("-", (conf->flag&MPLP_NO_COMP)? "wu" : "w"); for (i = 0; i < h->n_targets; ++i) { kputs(h->target_name[i], &s); kputc('\0', &s); } bh->l_nm = s.l; bh->name = malloc(s.l); memcpy(bh->name, s.s, s.l); s.l = 0; for (i = 0; i < sm->n; ++i) { kputs(sm->smpl[i], &s); kputc('\0', &s); } bh->l_smpl = s.l; bh->sname = malloc(s.l); memcpy(bh->sname, s.s, s.l); bh->txt = malloc(strlen(BAM_VERSION) + 64); bh->l_txt = 1 + sprintf(bh->txt, "##samtoolsVersion=%s\n", BAM_VERSION); free(s.s); bcf_hdr_sync(bh); bcf_hdr_write(bp, bh); bca = bcf_call_init(-1., conf->min_baseQ); bcr = calloc(sm->n, sizeof(bcf_callret1_t)); bca->rghash = rghash; bca->openQ = conf->openQ, bca->extQ = conf->extQ, bca->tandemQ = conf->tandemQ; bca->min_frac = conf->min_frac; bca->min_support = conf->min_support; } if (tid0 >= 0 && conf->fai) { // region is set ref = faidx_fetch_seq(conf->fai, h->target_name[tid0], 0, 0x7fffffff, &ref_len); ref_tid = tid0; for (i = 0; i < n; ++i) data[i]->ref = ref, data[i]->ref_id = tid0; } else ref_tid = -1, ref = 0; iter = bam_mplp_init(n, mplp_func, (void**)data); max_depth = conf->max_depth; if (max_depth * sm->n > 1<<20) fprintf(stderr, "(%s) Max depth is above 1M. Potential memory hog!\n", __func__); if (max_depth * sm->n < 8000) { max_depth = 8000 / sm->n; fprintf(stderr, "<%s> Set max per-file depth to %d\n", __func__, max_depth); } max_indel_depth = conf->max_indel_depth * sm->n; bam_mplp_set_maxcnt(iter, max_depth); int storeSize = 100; int delStore[2][100] = {{0},{0}}; typedef char * mstring; while (bam_mplp_auto(iter, &tid, &pos, n_plp, plp) > 0) { if (conf->reg && (pos < beg0 || pos >= end0)) continue; // out of the region requested if (conf->bed && tid >= 0 && !bed_overlap(conf->bed, h->target_name[tid], pos, pos+1)) continue; if (tid != ref_tid) { free(ref); ref = 0; if (conf->fai) ref = faidx_fetch_seq(conf->fai, h->target_name[tid], 0, 0x7fffffff, &ref_len); for (i = 0; i < n; ++i) data[i]->ref = ref, data[i]->ref_id = tid; ref_tid = tid; } if (conf->flag & MPLP_GLF) { int total_depth, _ref0, ref16; bcf1_t *b = calloc(1, sizeof(bcf1_t)); for (i = total_depth = 0; i < n; ++i) total_depth += n_plp[i]; group_smpl(&gplp, sm, &buf, n, fn, n_plp, plp, conf->flag & MPLP_IGNORE_RG); _ref0 = (ref && pos < ref_len)? ref[pos] : 'N'; ref16 = bam_nt16_table[_ref0]; for (i = 0; i < gplp.n; ++i) bcf_call_glfgen(gplp.n_plp[i], gplp.plp[i], ref16, bca, bcr + i); bcf_call_combine(gplp.n, bcr, ref16, &bc); bcf_call2bcf(tid, pos, &bc, b, (conf->flag&(MPLP_FMT_DP|MPLP_FMT_SP))? bcr : 0, (conf->flag&MPLP_FMT_SP), 0, 0); bcf_write(bp, bh, b); bcf_destroy(b); // call indels if (!(conf->flag&MPLP_NO_INDEL) && total_depth < max_indel_depth && bcf_call_gap_prep(gplp.n, gplp.n_plp, gplp.plp, pos, bca, ref, rghash) >= 0) { for (i = 0; i < gplp.n; ++i) bcf_call_glfgen(gplp.n_plp[i], gplp.plp[i], -1, bca, bcr + i); if (bcf_call_combine(gplp.n, bcr, -1, &bc) >= 0) { b = calloc(1, sizeof(bcf1_t)); bcf_call2bcf(tid, pos, &bc, b, (conf->flag&(MPLP_FMT_DP|MPLP_FMT_SP))? bcr : 0, (conf->flag&MPLP_FMT_SP), bca, ref); bcf_write(bp, bh, b); bcf_destroy(b); } } } else { printf("%s\t%d\t%c", h->target_name[tid], pos + 1, (ref && pos < ref_len)? ref[pos] : 'N'); for (i = 0; i < n; ++i) { int j; printf("\t%d\t", n_plp[i]); if (n_plp[i] == 0) { printf("*\t*"); // FIXME: printf() is very slow... if (conf->flag & MPLP_PRINT_POS) printf("\t*"); } else { //MDW start //for each position in the pileup column int charLen = 16; int countChars[ charLen ][2]; int countiChars[ charLen ][2]; int countGap[2]={0,0}; //double qvTotal=0; int numStruck=0; int numGood=0; int tti; int ttj; mstring insAllele[100]; int insAlleleCnt[100]; int sf=0; int flag=0; //typedef char * string; char insStr0[10000]; int iCnt0=0; char insStr1[10000]; int iCnt1=0; char delStr0[10000]; int dCnt0=0; char delStr1[10000]; int dCnt1=0; float qposP[10000]; int qposCnt=0; //initialize with zeros for(tti=0;tti<charLen;tti++){ countChars[tti][0]=0; countChars[tti][1]=0; } // define repeat length here; look back up to 10 prior positions // start one position away. int replC=0; // for(tti=1;tti<=15;tti++){ // check for greater than zero if(toupper(ref[pos-1])==toupper(ref[pos-tti])){ replC++; }else{ // breaks the chain at first non identical to current position not strict homopolymer break; } } int reprC=0; // for(tti=1;tti<=15;tti++){ // check for greater than zero if(toupper(ref[pos+1])==toupper(ref[pos+tti])){ reprC++; }else{ // breaks the chain at first non identical to current position not strict homopolymer break; } } int repT = replC; if(replC < reprC){ repT=reprC; } for (j = 0; j < n_plp[i]; ++j){ const bam_pileup1_t *p = plp[i] + j; /* SAME LOGIC AS pileup_seq() */ if(p->is_refskip){ // never count intron gaps in numStruck continue; } if(p->is_del){ // skip deletion gap, after first position which is the first aligned char continue; } if( p->b->core.qual < conf->min_mqToCount || // mapping quality conf->maxrepC < (repT) || // max homopolymer run, this will not (!p->is_del && bam1_qual(p->b)[p->qpos] < conf->min_baseQ) || // base quality for matches p->alignedQPosBeg <= (conf->trimEnd ) || p->alignedQPosEnd <= (conf->trimEnd ) || // trimEnd is 1-based p->zf == 1 || // fusion tag p->ih > conf->maxIH || // max hit index (p->nmd > conf->maxNM) || // max mismatch (conf->flagFilter == 1 && !(p->b->core.flag&BAM_FPROPER_PAIR)) || // optionally keep only proper pairs (conf->flagFilter == 2 && p->b->core.flag&BAM_FSECONDARY) || // optionally strike secondary (conf->flagFilter == 3 && p->b->core.flag&BAM_FDUP) || // optionally strike dup (conf->flagFilter == 4 && (p->b->core.flag&BAM_FDUP || p->b->core.flag&BAM_FSECONDARY)) || // optionally strike secondary or dup (conf->flagFilter == 5 && (p->b->core.flag&BAM_FDUP || p->b->core.flag&BAM_FSECONDARY || p->b->core.flag&BAM_FQCFAIL || !(p->b->core.flag&BAM_FPROPER_PAIR) )) // optionally strike secondary, dup and QCfail ){ numStruck++; continue; } //printf("repT=%d: %d %c %c %c %c \n",repT,p->indel,ref[pos],ref[pos-1],ref[pos-2],ref[pos-3]); if(!p->is_del && p->indel==0){ countChars[ bam1_seqi(bam1_seq(p->b), p->qpos) ][ bam1_strand(p->b) ] ++; numGood++; }else if(p->is_refskip){ countGap[ bam1_strand(p->b) ]++; } if(p->indel<0){ numGood++; if(bam1_strand(p->b) ==0){ for(tti=1;tti<= -p->indel; tti++) { // current spot, starting at 0 in store, because indel<0 refers to next position delStr0[dCnt0] = ref[pos+tti]; dCnt0++; } delStr0[dCnt0] = ','; dCnt0++; }else{ for(tti=1;tti<= -p->indel; tti++) { // current spot, starting at 0 in store, because indel<0 refers to next position delStr1[dCnt1] = ref[pos+tti]; dCnt1++; } delStr1[dCnt1] = ','; dCnt1++; } }else if(p->indel>0){ numGood++; if(bam1_strand(p->b) ==0){ for(tti=1;tti<= p->indel; tti++) { // current spot, starting at 0 in store, because indel<0 refers to next position insStr0[iCnt0] = bam_nt16_rev_table[bam1_seqi(bam1_seq(p->b), p->qpos + tti)]; iCnt0++; } insStr0[iCnt0] = ','; iCnt0++; }else{ for(tti=1;tti<= p->indel; tti++) { // current spot, starting at 0 in store, because indel<0 refers to next position insStr1[iCnt1] = bam_nt16_rev_table[bam1_seqi(bam1_seq(p->b), p->qpos + tti)]; iCnt1++; } insStr1[iCnt1] = ','; iCnt1++; } } //calculate position of variant within aligned read - no soft clips if( toupper(ref[pos]) != toupper(bam_nt16_rev_table[bam1_seqi(bam1_seq(p->b), p->qpos)]) || p->indel>0 || p->indel<0 ){ //distance to end; calculate distance to end of aligned read. removes soft clips. int distToEnd = (p->alignedQPosBeg < p->alignedQPosEnd) ? p->alignedQPosBeg : p->alignedQPosEnd; qposP[qposCnt] = distToEnd; qposCnt++; // printf("id=%s, pos=%d",bam1_qname(p->b),distToEnd); } } // //print A,C,G,T, by +/- printf("\t%d\t%d\t%d\t%d\t%d\t%d\t%d\t%d\t%d\t%d", countChars[1][0],countChars[1][1], countChars[2][0],countChars[2][1], countChars[4][0],countChars[4][1], countChars[8][0],countChars[8][1], countChars[7][0],countChars[7][1]); putchar('\t'); for(tti=0;tti<dCnt0;tti++){ putchar(delStr0[tti]); } putchar('\t'); for(tti=0;tti<dCnt1;tti++){ putchar(delStr1[tti]); } putchar('\t'); for(tti=0;tti<iCnt0;tti++){ putchar(insStr0[tti]); } putchar('\t'); for(tti=0;tti<iCnt1;tti++){ putchar(insStr1[tti]); } printf("\t%d\t%d",numGood,numStruck); // get non-ref qpos variation float medqpos = -1; float medAbsDev = -1; if(qposCnt>0){ medqpos = median(qposCnt,qposP); float absDev[qposCnt]; for(tti=0;tti<qposCnt;tti++){ absDev[tti] = abs(medqpos - qposP[tti]); } medAbsDev = median(qposCnt-1,absDev); } printf("\t%f",medAbsDev); ///END MDW } } putchar('\n'); } } bcf_close(bp); bam_smpl_destroy(sm); free(buf.s); for (i = 0; i < gplp.n; ++i) free(gplp.plp[i]); free(gplp.plp); free(gplp.n_plp); free(gplp.m_plp); bcf_call_del_rghash(rghash); bcf_hdr_destroy(bh); bcf_call_destroy(bca); free(bc.PL); free(bcr); bam_mplp_destroy(iter); bam_header_destroy(h); for (i = 0; i < n; ++i) { bam_close(data[i]->fp); if (data[i]->iter) bam_iter_destroy(data[i]->iter); free(data[i]); } free(data); free(plp); free(ref); free(n_plp); return 0; }