supposedly this is THE correct implementation, but more testing is needed

[samtools.git] / bam_mcns.c

diff --git a/bam_mcns.c b/bam_mcns.c
index 7859169c9ef8799b37878a6d1e19e7c1c5b8fcb0..b2edfe130bc9c32d5adbc9a8230edd122b8bdb73 100644 (file)
--- a/bam_mcns.c
+++ b/bam_mcns.c
@@ -1,16 +1,23 @@
 #include <math.h>
 #include <stdlib.h>
+#include <stdio.h>
 #include "bam_mcns.h"
 
 #define MC_MIN_QUAL 13
+#define MC_AVG_ERR 0.007
 #define MC_MAX_SUMQ 3000
 #define MC_MAX_SUMQP 1e-300
+#define MC_MAX_EM_ITER 16
+#define MC_EM_EPS 1e-4
 
 struct __mc_aux_t {
-       int n, N;
-       int ref, alt;
+       int n, M;
+       int ref, alt, alt2;
        double *q2p, *pdg; // pdg -> P(D|g)
-       double *alpha, *beta;
+       double *phi;
+       double *z, *zswap; // aux for afs
+       double *CMk; // \binom{M}{k}
+       double *afs, *afs1; // afs: accumulative AFS; afs1: site posterior distribution
        int *qsum, *bcnt;
 };
 
@@ -19,12 +26,15 @@ void mc_init_prior(mc_aux_t *ma, int type, double theta)
        int i;
        if (type == MC_PTYPE_COND2) {
                for (i = 0; i <= 2 * ma->n; ++i)
-                       ma->alpha[i] = 2. * (i + 1) / (2 * ma->n + 1) / (2 * ma->n + 2);
+                       ma->phi[i] = 2. * (i + 1) / (2 * ma->n + 1) / (2 * ma->n + 2);
+       } else if (type == MC_PTYPE_FLAT) {
+               for (i = 0; i <= ma->M; ++i)
+                       ma->phi[i] = 1. / (ma->M + 1);
        } else {
                double sum;
                for (i = 0, sum = 0.; i < 2 * ma->n; ++i)
-                       sum += (ma->alpha[i] = theta / (2 * ma->n - i));
-               ma->alpha[2 * ma->n] = 1. - sum;
+                       sum += (ma->phi[i] = theta / (2 * ma->n - i));
+               ma->phi[2 * ma->n] = 1. - sum;
        }
 }
 
@@ -33,22 +43,21 @@ mc_aux_t *mc_init(int n) // FIXME: assuming diploid
        mc_aux_t *ma;
        int i;
        ma = calloc(1, sizeof(mc_aux_t));
-       ma->n = n; ma->N = 2 * n;
+       ma->n = n; ma->M = 2 * n;
        ma->q2p = calloc(MC_MAX_SUMQ + 1, sizeof(double));
        ma->qsum = calloc(4 * ma->n, sizeof(int));
        ma->bcnt = calloc(4 * ma->n, sizeof(int));
        ma->pdg = calloc(3 * ma->n, sizeof(double));
-       ma->alpha = calloc(2 * ma->n + 1, sizeof(double));
-       ma->beta = calloc((2 * ma->n + 1) * 3, sizeof(double));
+       ma->phi = calloc(2 * ma->n + 1, sizeof(double));
+       ma->z = calloc(2 * ma->n + 1, sizeof(double));
+       ma->zswap = calloc(2 * ma->n + 1, sizeof(double));
+       ma->afs = calloc(2 * ma->n + 1, sizeof(double));
+       ma->afs1 = calloc(2 * ma->n + 1, sizeof(double));
+       ma->CMk = calloc(ma->M + 1, sizeof(double));
        for (i = 0; i <= MC_MAX_SUMQ; ++i)
                ma->q2p[i] = pow(10., -i / 10.);
-       for (i = 0; i <= 2 * ma->n; ++i) { // beta[k][g]=P(g|k/M)
-               double *bi = ma->beta + 3 * i;
-               double f = (double)i / (2 * ma->n);
-               bi[0] = (1. - f) * (1. - f);
-               bi[1] = 2 * f * (1. - f);
-               bi[2] = f * f;
-       }
+       for (i = 0; i <= ma->M; ++i)
+               ma->CMk[i] = exp(lgamma(ma->M+1) - lgamma(ma->M-i+1) - lgamma(i+1));
        mc_init_prior(ma, MC_PTYPE_FULL, 1e-3); // the simplest prior
        return ma;
 }
@@ -58,20 +67,23 @@ void mc_destroy(mc_aux_t *ma)
        if (ma) {
                free(ma->qsum); free(ma->bcnt);
                free(ma->q2p); free(ma->pdg);
-               free(ma->alpha); free(ma->beta);
+               free(ma->phi);
+               free(ma->z); free(ma->zswap);
+               free(ma->afs); free(ma->afs1);
+               free(ma->CMk);
                free(ma);
        }
 }
 
-static void sum_err(int *n, const bam_pileup1_t **plp, mc_aux_t *ma)
+static int sum_err(int *n, const bam_pileup1_t **plp, mc_aux_t *ma)
 {
-       int i, j;
+       int i, j, tot = 0;
        memset(ma->qsum, 0, sizeof(int) * 4 * ma->n);
        memset(ma->bcnt, 0, sizeof(int) * 4 * ma->n);
        for (j = 0; j < ma->n; ++j) {
-               int tmp, *qsum = ma->qsum + j * 4;
+               int *qsum = ma->qsum + j * 4;
                int *bcnt = ma->bcnt + j * 4;
-               for (i = tmp = 0; i < n[j]; ++i) {
+               for (i = 0; i < n[j]; ++i) {
                        const bam_pileup1_t *p = plp[j] + i;
                        int q, b;
                        if (p->is_del || (p->b->core.flag&BAM_FUNMAP)) continue;
@@ -82,9 +94,10 @@ static void sum_err(int *n, const bam_pileup1_t **plp, mc_aux_t *ma)
                        if (b > 3) continue; // N
                        qsum[b] += q;
                        ++bcnt[b];
-                       ++tmp;
+                       ++tot;
                }
        }
+       return tot;
 }
 
 static void set_allele(int ref, mc_aux_t *ma)
@@ -98,9 +111,13 @@ static void set_allele(int ref, mc_aux_t *ma)
        for (i = 1; i < 4; ++i) // insertion sort
                for (j = i; j > 0 && sum[j] < sum[j-1]; --j)
                        tmp = sum[j], sum[j] = sum[j-1], sum[j-1] = tmp;
-       ma->ref = sum[3]&3; ma->alt = sum[2]&3;
-       if (ref == ma->alt) tmp = ma->ref, ma->ref = ma->alt, ma->alt = tmp;
-       // note that ma->ref might not be ref in case of triallele
+       ma->ref = sum[3]&3; ma->alt = sum[2]&3; ma->alt2 = -1;
+       if (ma->ref != ref) { // the best base is not ref
+               if (ref >= 0 && ref <= 3) { // ref is not N
+                       if (ma->alt == ref) tmp = ma->ref, ma->ref = ma->alt, ma->alt = tmp; // then switch alt and ref
+                       else ma->alt2 = ma->alt, ma->alt = ma->ref, ma->ref = ref; // then set ref as ref
+               } else ma->alt2 = ma->alt, ma->alt = ma->ref, ma->ref = sum[0]&3; // then set the weakest as ref
+       }
 }
 
 static void cal_pdg(mc_aux_t *ma)
@@ -118,94 +135,49 @@ static void cal_pdg(mc_aux_t *ma)
                        pdg[i] = pi[i] > MC_MAX_SUMQ? MC_MAX_SUMQP : ma->q2p[pi[i]];
        }
 }
-// return the reference allele frequency
-double mc_freq0(int ref, int *n, const bam_pileup1_t **plp, mc_aux_t *ma, int *_ref, int *alt)
+// this calculates the naive allele frequency and Nielsen's frequency
+static double mc_freq0(const mc_aux_t *ma, double *_f)
 {
        int i, cnt;
-       double f;
-       sum_err(n, plp, ma);
-       set_allele(ref, ma);
-       cal_pdg(ma);
-       *_ref = ma->ref; *alt = ma->alt;
-       for (i = cnt = 0, f = 0.; i < ma->n; ++i) {
+       double f, f_nielsen, w_sum;
+       *_f = -1.;
+       for (i = cnt = 0, f = f_nielsen = w_sum = 0.; i < ma->n; ++i) {
                int *bcnt = ma->bcnt + i * 4;
                int x = bcnt[ma->ref] + bcnt[ma->alt];
                if (x) {
+                       double w, p;
                        ++cnt;
                        f += (double)bcnt[ma->ref] / x;
+                       p = (bcnt[ma->ref] - MC_AVG_ERR * x) / (1. - 2. * MC_AVG_ERR) / x;
+                       w = 2. * x / (1. + x);
+                       w_sum += w;
+                       f_nielsen += p * w;
                }
        }
-       return f / cnt;
+       if (cnt) {
+               f_nielsen /= w_sum;
+               if (f_nielsen < 0.) f_nielsen = 0.;
+               if (f_nielsen > 1.) f_nielsen = 1.;
+               *_f = f_nielsen;
+               return f / cnt;
+       } else return -1.;
 }
 // f0 is the reference allele frequency
-double mc_freq_iter(double f0, mc_aux_t *ma)
+static double mc_freq_iter(double f0, const mc_aux_t *ma)
 {
        double f, f3[3];
-       int i, j;
+       int i;
        f3[0] = (1.-f0)*(1.-f0); f3[1] = 2.*f0*(1.-f0); f3[2] = f0*f0;
        for (i = 0, f = 0.; i < ma->n; ++i) {
-               double up, dn, *pdg;
+               double *pdg;
                pdg = ma->pdg + i * 3;
-               for (j = 1, up = 0.; j < 3; ++j)
-                       up += j * pdg[j] * f3[j];
-               for (j = 0, dn = 0.; j < 3; ++j)
-                       dn += pdg[j] * f3[j];
-               f += up / dn;
+               f += (pdg[1] * f3[1] + 2. * pdg[2] * f3[2])
+                       / (pdg[0] * f3[0] + pdg[1] * f3[1] + pdg[2] * f3[2]);
        }
        f /= ma->n * 2.;
        return f;
 }
 
-double mc_freq_post(mc_aux_t *ma)
-{
-       int i, k;
-       long double f = 0.;
-       for (i = 0; i < ma->n; ++i) {
-               double *pdg = ma->pdg + i * 3;
-               long double y = 0., z = 0.;
-               for (k = 0; k <= ma->n * 2; ++k) {
-                       double *bk = ma->beta + k * 3;
-/*
-                       int g;
-                       double yk = 0., zk = 0.;
-                       for (g = 0; g < 3; ++g) {
-                               yk += g * pdg[g] * bk[g];
-                               zk += pdg[g] * bk[g];
-                       }
-                       y += yk * ma->alpha[k];
-                       z += zk * ma->alpha[k];
-*/
-                       y += (pdg[1] * bk[1] + 2. * pdg[2] * bk[2]) * ma->alpha[k];
-                       z += (pdg[0] * bk[0] + pdg[1] * bk[1] + pdg[2] * bk[2]) * ma->alpha[k];
-               }
-               f += y / z;
-       }
-       return f / ma->n / 2;
-}
-
-double mc_ref_prob(mc_aux_t *ma)
-{
-       int k, i;
-       long double PD = 0., Pref = 0.;
-       for (k = 0; k <= ma->n * 2; ++k) {
-               long double x = 1.;
-               double *bk = ma->beta + k * 3;
-               for (i = 0; i < ma->n; ++i) {
-                       double *pdg = ma->pdg + i * 3;
-//                     int g; double y=0.; for (g = 0; g < 3; ++g) y += pdg[g] * bk[g];
-                       x *= pdg[0] * bk[0] + pdg[1] * bk[1] + pdg[2] * bk[2];
-               }
-               PD += x * ma->alpha[k];
-       }
-       for (k = 0; k <= ma->n * 2; ++k) {
-               long double x = 1.0;
-               for (i = 0; i < ma->n; ++i)
-                       x *= ma->pdg[i * 3 + 2] * ma->beta[k * 3 + 2];
-               Pref += x * ma->alpha[k];
-       }
-       return Pref / PD;
-}
-
 int mc_call_gt(const mc_aux_t *ma, double f0, int k)
 {
        double sum, g[3];
@@ -218,10 +190,93 @@ int mc_call_gt(const mc_aux_t *ma, double f0, int k)
                g[i] /= sum;
                if (g[i] > max) max = g[i], max_i = i;
        }
-//     printf("***%lg,%lg,%lg,%lg,%lg,%lg\n", g[0], g[1], g[2], pdg[0], pdg[1], pdg[2]);
        max = 1. - max;
        if (max < 1e-308) max = 1e-308;
        q = (int)(-3.434 * log(max) + .499);
        if (q > 99) q = 99;
        return q<<2|max_i;
 }
+
+static void mc_cal_z(mc_aux_t *ma)
+{
+       double *z[2], *tmp, *pdg;
+       int i, j;
+       z[0] = ma->z;
+       z[1] = ma->zswap;
+       pdg = ma->pdg;
+       z[0][0] = 1.; z[0][1] = z[0][2] = 0.;
+       for (j = 0; j < ma->n; ++j) {
+               int max = (j + 1) * 2;
+               double p[3];
+               pdg = ma->pdg + j * 3;
+               p[0] = pdg[0]; p[1] = 2. * pdg[1]; p[2] = pdg[2];
+               z[1][0] = p[0] * z[0][0];
+               z[1][1] = p[0] * z[0][1] + p[1] * z[0][0];
+               for (i = 2; i <= max; ++i)
+                       z[1][i] = p[0] * z[0][i] + p[1] * z[0][i-1] + p[2] * z[0][i-2];
+               if (j < ma->n - 1) z[1][max+1] = z[1][max+2] = 0.;
+               tmp = z[0]; z[0] = z[1]; z[1] = tmp;
+       }
+       if (z[0] != ma->z) memcpy(ma->z, z[0], sizeof(double) * (2 * ma->n + 1));
+}
+
+static double mc_add_afs(mc_aux_t *ma)
+{
+       int k, l;
+       double sum = 0., avg = 0.;
+       memset(ma->afs1, 0, sizeof(double) * (ma->M + 1));
+       mc_cal_z(ma);
+       for (k = 0; k <= ma->M; ++k) {
+               for (l = 0, sum = 0.; l <= ma->M; ++l)
+                       sum += ma->phi[l] * ma->z[l];
+               ma->afs1[k] = ma->phi[k] * ma->z[k] / sum;
+       }
+       for (k = 0; k <= ma->M; ++k)
+               if (isnan(ma->afs1[k]) || isinf(ma->afs1[k])) return -1.;
+       for (k = 0, sum = avg = 0.; k <= ma->M; ++k) {
+               ma->afs[k] += ma->afs1[k];
+               sum += ma->afs1[k];
+               avg += k * ma->afs1[k];
+       }
+//     for (k = 0; k <= ma->M; ++k) printf("^%lg:%lg:%lg ", ma->z[k], ma->phi[k], ma->afs1[k]);
+       return avg / ma->M;
+}
+
+int mc_cal(int ref, int *n, const bam_pileup1_t **plp, mc_aux_t *ma, mc_rst_t *rst, int level)
+{
+       int i, tot;
+       memset(rst, 0, sizeof(mc_rst_t));
+       rst->f_em = rst->f_exp = -1.; rst->ref = rst->alt = -1;
+       // precalculation
+       tot = sum_err(n, plp, ma);
+       if (tot == 0) return 0; // no good bases
+       set_allele(ref, ma);
+       cal_pdg(ma);
+       // set ref/major allele
+       rst->ref = ma->ref; rst->alt = ma->alt; rst->alt2 = ma->alt2;
+       // calculate naive and Nielsen's freq
+       rst->f_naive = mc_freq0(ma, &rst->f_nielsen);
+       { // calculate f_em
+               double flast = rst->f_naive;
+               for (i = 0; i < MC_MAX_EM_ITER; ++i) {
+                       rst->f_em = mc_freq_iter(flast, ma);
+                       if (fabs(rst->f_em - flast) < MC_EM_EPS) break;
+                       flast = rst->f_em;
+               }
+       }
+       if (level >= 2) {
+               rst->f_exp = mc_add_afs(ma);
+               rst->p_ref = ma->afs1[ma->M];
+       }
+       return tot;
+}
+
+void mc_dump_afs(mc_aux_t *ma)
+{
+       int k;
+       fprintf(stderr, "[afs]");
+       for (k = 0; k <= ma->M; ++k)
+               fprintf(stderr, " %d:%.3lf", k, ma->afs[ma->M - k]);
+       fprintf(stderr, "\n");
+       memset(ma->afs, 0, sizeof(double) * (ma->M + 1));
+}