* negative if we are looking at an indel. */
int bcf_call_glfgen(int _n, const bam_pileup1_t *pl, int ref_base, bcf_callaux_t *bca, bcf_callret1_t *r)
{
+ static int *var_pos = NULL, nvar_pos = 0;
int i, n, ref4, is_indel, ori_depth = 0;
memset(r, 0, sizeof(bcf_callret1_t));
if (ref_base >= 0) {
r->depth = n; r->ori_depth = ori_depth;
// glfgen
errmod_cal(bca->e, n, 5, bca->bases, r->p);
+
+ // Calculate the Variant Distance Bias (make it optional?)
+ if ( nvar_pos < _n ) {
+ nvar_pos = _n;
+ var_pos = realloc(var_pos,sizeof(int)*nvar_pos);
+ }
+ int alt_dp=0, read_len=0;
+ for (i=0; i<_n; i++) {
+ const bam_pileup1_t *p = pl + i;
+ if ( bam1_seqi(bam1_seq(p->b),p->qpos) == ref_base )
+ continue;
+
+ var_pos[alt_dp] = p->qpos;
+ if ( (bam1_cigar(p->b)[0]&BAM_CIGAR_MASK)==4 )
+ var_pos[alt_dp] -= bam1_cigar(p->b)[0]>>BAM_CIGAR_SHIFT;
+
+ alt_dp++;
+ read_len += p->b->core.l_qseq;
+ }
+ float mvd=0;
+ int j;
+ n=0;
+ for (i=0; i<alt_dp; i++) {
+ for (j=0; j<i; j++) {
+ mvd += abs(var_pos[i] - var_pos[j]);
+ n++;
+ }
+ }
+ r->mvd[0] = n ? mvd/n : 0;
+ r->mvd[1] = alt_dp;
+ r->mvd[2] = alt_dp ? read_len/alt_dp : 0;
+
return r->depth;
}
+
+void calc_vdb(int n, const bcf_callret1_t *calls, bcf_call_t *call)
+{
+ // Variant distance bias. Samples merged by means of DP-weighted average.
+
+ float weight=0, tot_prob=0;
+
+ int i;
+ for (i=0; i<n; i++)
+ {
+ int mvd = calls[i].mvd[0];
+ int dp = calls[i].mvd[1];
+ int read_len = calls[i].mvd[2];
+
+ if ( dp<2 ) continue;
+
+ float prob = 0;
+ if ( dp==2 )
+ {
+ // Exact formula
+ prob = (mvd==0) ? 1.0/read_len : (read_len-mvd)*2.0/read_len/read_len;
+ }
+ else if ( dp==3 )
+ {
+ // Sin, quite accurate approximation
+ float mu = read_len/2.9;
+ prob = mvd>2*mu ? 0 : sin(mvd*3.14/2/mu) / (4*mu/3.14);
+ }
+ else
+ {
+ // Scaled gaussian curve, crude approximation, but behaves well. Using fixed depth for bigger depths.
+ if ( dp>5 )
+ dp = 5;
+ float sigma2 = (read_len/1.9/(dp+1)) * (read_len/1.9/(dp+1));
+ float norm = 1.125*sqrt(2*3.14*sigma2);
+ float mu = read_len/2.9;
+ if ( mvd < mu )
+ prob = exp(-(mvd-mu)*(mvd-mu)/2/sigma2)/norm;
+ else
+ prob = exp(-(mvd-mu)*(mvd-mu)/3.125/sigma2)/norm;
+ }
+
+ //fprintf(stderr,"dp=%d mvd=%d read_len=%d -> prob=%f\n", dp,mvd,read_len,prob);
+ tot_prob += prob*dp;
+ weight += dp;
+ }
+ tot_prob = weight ? tot_prob/weight : 1;
+ //fprintf(stderr,"prob=%f\n", tot_prob);
+ call->vdb = tot_prob;
+}
+
int bcf_call_combine(int n, const bcf_callret1_t *calls, int ref_base /*4-bit*/, bcf_call_t *call)
{
int ref4, i, j, qsum[4];
call->ori_depth += calls[i].ori_depth;
for (j = 0; j < 16; ++j) call->anno[j] += calls[i].anno[j];
}
+
+ calc_vdb(n, calls, call);
+
return 0;
}
if (i) kputc(',', &s);
kputw(bc->anno[i], &s);
}
+ if ( bc->vdb!=1 )
+ {
+ ksprintf(&s, ";VDB=%.4f", bc->vdb);
+ }
kputc('\0', &s);
// FMT
kputs("PL", &s);
memcpy(b->gi[0].data, bc->PL, b->gi[0].len * bc->n);
if (bcr) {
uint16_t *dp = (uint16_t*)b->gi[1].data;
- uint8_t *sp = is_SP? b->gi[2].data : 0;
+ int32_t *sp = is_SP? b->gi[2].data : 0;
for (i = 0; i < bc->n; ++i) {
bcf_callret1_t *p = bcr + i;
dp[i] = p->depth < 0xffff? p->depth : 0xffff;