#include "kseq.h"
KSTREAM_INIT(gzFile, gzread, 16384)
-#define MC_AVG_ERR 0.007
#define MC_MAX_EM_ITER 16
#define MC_EM_EPS 1e-4
+#define MC_DEF_INDEL 0.15
unsigned char seq_nt4_table[256] = {
4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4, 4,
};
struct __bcf_p1aux_t {
- int n, M, n1;
+ int n, M, n1, is_indel;
double *q2p, *pdg; // pdg -> P(D|g)
- double *phi;
+ double *phi, *phi_indel;
double *z, *zswap; // aux for afs
double *z1, *z2, *phi1, *phi2; // only calculated when n1 is set
double t, t1, t2;
int PL_len;
};
+void bcf_p1_indel_prior(bcf_p1aux_t *ma, double x)
+{
+ int i;
+ for (i = 0; i < ma->M; ++i)
+ ma->phi_indel[i] = ma->phi[i] * x;
+ ma->phi_indel[ma->M] = 1. - ma->phi[ma->M] * x;
+}
+
static void init_prior(int type, double theta, int M, double *phi)
{
int i;
void bcf_p1_init_prior(bcf_p1aux_t *ma, int type, double theta)
{
init_prior(type, theta, ma->M, ma->phi);
+ bcf_p1_indel_prior(ma, MC_DEF_INDEL);
}
void bcf_p1_init_subprior(bcf_p1aux_t *ma, int type, double theta)
fprintf(stderr, "[%s] heterozygosity=%lf, ", __func__, (double)sum);
for (sum = 0., k = 1; k <= ma->M; ++k) sum += k * ma->phi[ma->M - k] / ma->M;
fprintf(stderr, "theta=%lf\n", (double)sum);
+ bcf_p1_indel_prior(ma, MC_DEF_INDEL);
return 0;
}
ma->q2p = calloc(256, sizeof(double));
ma->pdg = calloc(3 * ma->n, sizeof(double));
ma->phi = calloc(ma->M + 1, sizeof(double));
+ ma->phi_indel = calloc(ma->M + 1, sizeof(double));
ma->phi1 = calloc(ma->M + 1, sizeof(double));
ma->phi2 = calloc(ma->M + 1, sizeof(double));
ma->z = calloc(2 * ma->n + 1, sizeof(double));
{
if (ma) {
free(ma->q2p); free(ma->pdg);
- free(ma->phi); free(ma->phi1); free(ma->phi2);
+ free(ma->phi); free(ma->phi_indel); free(ma->phi1); free(ma->phi2);
free(ma->z); free(ma->zswap); free(ma->z1); free(ma->z2);
free(ma->afs); free(ma->afs1);
free(ma);
}
}
-#define char2int(s) (((int)s[0])<<8|s[1])
-
static int cal_pdg(const bcf1_t *b, bcf_p1aux_t *ma)
{
- int i, j, k;
+ int i, j;
long *p, tmp;
p = alloca(b->n_alleles * sizeof(long));
memset(p, 0, sizeof(long) * b->n_alleles);
for (j = 0; j < ma->n; ++j) {
const uint8_t *pi = ma->PL + j * ma->PL_len;
double *pdg = ma->pdg + j * 3;
- pdg[0] = ma->q2p[pi[b->n_alleles]]; pdg[1] = ma->q2p[pi[1]]; pdg[2] = ma->q2p[pi[0]];
- for (i = k = 0; i < b->n_alleles; ++i) {
- p[i] += (int)pi[k];
- k += b->n_alleles - i;
- }
+ pdg[0] = ma->q2p[pi[2]]; pdg[1] = ma->q2p[pi[1]]; pdg[2] = ma->q2p[pi[0]];
+ for (i = 0; i < b->n_alleles; ++i)
+ p[i] += (int)pi[(i+1)*(i+2)/2-1];
}
for (i = 0; i < b->n_alleles; ++i) p[i] = p[i]<<4 | i;
for (i = 1; i < b->n_alleles; ++i) // insertion sort
{
int k, n1 = ma->n1, n2 = ma->n - ma->n1;
long double sum1, sum2;
- pc[0] = pc[1] = pc[2] = pc[3] = 0.;
+ pc[0] = pc[1] = pc[2] = pc[3] = -1.;
if (n1 <= 0 || n2 <= 0) return;
for (k = 0, sum1 = 0.; k <= 2*n1; ++k) sum1 += ma->phi1[k] * ma->z1[k];
for (k = 0, sum2 = 0.; k <= 2*n2; ++k) sum2 += ma->phi2[k] * ma->z2[k];
pc[1] = pc[1] == 1.? 99 : (int)(-4.343 * log(1. - pc[1]) + .499);
}
-static double mc_cal_afs(bcf_p1aux_t *ma)
+static double mc_cal_afs(bcf_p1aux_t *ma, double *p_ref_folded, double *p_var_folded)
{
int k;
- long double sum = 0.;
+ long double sum = 0., sum2;
+ double *phi = ma->is_indel? ma->phi_indel : ma->phi;
memset(ma->afs1, 0, sizeof(double) * (ma->M + 1));
mc_cal_y(ma);
+ // compute AFS
for (k = 0, sum = 0.; k <= ma->M; ++k)
- sum += (long double)ma->phi[k] * ma->z[k];
+ sum += (long double)phi[k] * ma->z[k];
for (k = 0; k <= ma->M; ++k) {
- ma->afs1[k] = ma->phi[k] * ma->z[k] / sum;
+ ma->afs1[k] = phi[k] * ma->z[k] / sum;
if (isnan(ma->afs1[k]) || isinf(ma->afs1[k])) return -1.;
}
+ // compute folded variant probability
+ for (k = 0, sum = 0.; k <= ma->M; ++k)
+ sum += (long double)(phi[k] + phi[ma->M - k]) / 2. * ma->z[k];
+ for (k = 1, sum2 = 0.; k < ma->M; ++k)
+ sum2 += (long double)(phi[k] + phi[ma->M - k]) / 2. * ma->z[k];
+ *p_var_folded = sum2 / sum;
+ *p_ref_folded = (phi[k] + phi[ma->M - k]) / 2. * (ma->z[ma->M] + ma->z[0]) / sum;
+ // the expected frequency
for (k = 0, sum = 0.; k <= ma->M; ++k) {
ma->afs[k] += ma->afs1[k];
sum += k * ma->afs1[k];
return pd;
}
-int bcf_p1_cal(bcf1_t *b, bcf_p1aux_t *ma, bcf_p1rst_t *rst)
+int bcf_p1_cal(const bcf1_t *b, bcf_p1aux_t *ma, bcf_p1rst_t *rst)
{
int i, k;
long double sum = 0.;
+ ma->is_indel = bcf_is_indel(b);
// set PL and PL_len
for (i = 0; i < b->n_gi; ++i) {
- if (b->gi[i].fmt == char2int("PL")) {
+ if (b->gi[i].fmt == bcf_str2int("PL", 2)) {
ma->PL = (uint8_t*)b->gi[i].data;
ma->PL_len = b->gi[i].len;
break;
if (b->n_alleles < 2) return -1; // FIXME: find a better solution
//
rst->rank0 = cal_pdg(b, ma);
- rst->f_exp = mc_cal_afs(ma);
+ rst->f_exp = mc_cal_afs(ma, &rst->p_ref_folded, &rst->p_var_folded);
rst->p_ref = ma->afs1[ma->M];
+ for (k = 0, sum = 0.; k < ma->M; ++k)
+ sum += ma->afs1[k];
+ rst->p_var = (double)sum;
// calculate f_flat and f_em
for (k = 0, sum = 0.; k <= ma->M; ++k)
sum += (long double)ma->z[k];
flast = rst->f_em;
}
}
+ { // estimate equal-tail credible interval (95% level)
+ int l, h;
+ double p;
+ for (i = 0, p = 0.; i < ma->M; ++i)
+ if (p + ma->afs1[i] > 0.025) break;
+ else p += ma->afs1[i];
+ l = i;
+ for (i = ma->M-1, p = 0.; i >= 0; --i)
+ if (p + ma->afs1[i] > 0.025) break;
+ else p += ma->afs1[i];
+ h = i;
+ rst->cil = (double)(ma->M - h) / ma->M; rst->cih = (double)(ma->M - l) / ma->M;
+ }
rst->g[0] = rst->g[1] = rst->g[2] = -1.;
contrast(ma, rst->pc);
return 0;