Mercurial > repos > siyuan > prada
view pyPRADA_1.2/tools/bwa-0.5.7-mh/cs2nt.c @ 3:f17965495ec9 draft default tip
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author | siyuan |
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date | Tue, 11 Mar 2014 12:14:01 -0400 |
parents | acc2ca1a3ba4 |
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#include <string.h> #include <stdint.h> #include <stdlib.h> #include "bwtaln.h" #include "stdaln.h" /* Here is a delicate example. ref_nt=ATTAAC(RBRBG), read_cs=RBBOG. If we decode as ATTGAC(RBGOG), there are one color change and one nt change; if we decode as ATTAAC(RBRBG), there are two color changes. In DP, if color quality is smaller than COLOR_MM, we will use COLOR_MM as the penalty; otherwise, we will use color quality as the penalty. This means we always prefer two consistent color changes over a nt change, but if a color has high quality, we may prefer one nt change. In the above example, the penalties of the two types of decoding are q(B)+25 and q(B)+q(O), respectively. If q(O)>25, we prefer the first; otherwise the second. Note that no matter what we choose, the fourth base will get a low nt quality. */ #define COLOR_MM 19 #define NUCL_MM 25 static const int nst_ntnt2cs_table[] = { 4, 0, 0, 1, 0, 2, 3, 4, 0, 3, 2, 4, 1, 4, 4, 4 }; /* {A,C,G,T,N} -> {0,1,2,3,4} nt_ref[0..size]: nucleotide reference: 0/1/2/3/4 cs_read[0..size-1]: color read+qual sequence: base<<6|qual; qual==63 for N nt_read[0..size]: nucleotide read sequence: 0/1/2/3 (returned) btarray[0..4*size]: backtrack array (working space) */ void cs2nt_DP(int size, const uint8_t *nt_ref, const uint8_t *cs_read, uint8_t *nt_read, uint8_t *btarray) { int h[8], curr, last; int x, y, xmin, hmin, k; // h[0..3] and h[4..7] are the current and last best score array, depending on curr and last // recursion: initial value if (nt_ref[0] >= 4) memset(h, 0, sizeof(int) << 2); else { for (x = 0; x != 4; ++x) h[x] = NUCL_MM; h[nt_ref[0]] = 0; } // recursion: main loop curr = 1; last = 0; for (k = 1; k <= size; ++k) { for (x = 0; x != 4; ++x) { int min = 0x7fffffff, ymin = 0; for (y = 0; y != 4; ++y) { int s = h[last<<2|y]; if ((cs_read[k-1]&0x3f) != 63 && cs_read[k-1]>>6 != nst_ntnt2cs_table[1<<x|1<<y]) s += ((cs_read[k-1]&0x3f) < COLOR_MM)? COLOR_MM : (cs_read[k-1]&0x3f); // color mismatch if (nt_ref[k] < 4 && nt_ref[k] != x) s += NUCL_MM; // nt mismatch if (s < min) { min = s; ymin = y; } } h[curr<<2|x] = min; btarray[k<<2|x] = ymin; } last = curr; curr = 1 - curr; // swap } // back trace hmin = 0x7fffffff; xmin = 0; for (x = 0; x != 4; ++x) { if (h[last<<2|x] < hmin) { hmin = h[last<<2|x]; xmin = x; } } nt_read[size] = xmin; for (k = size - 1; k >= 0; --k) nt_read[k] = btarray[(k+1)<<2 | nt_read[k+1]]; } /* nt_read[0..size]: nucleotide read sequence: 0/1/2/3 cs_read[0..size-1]: color read+qual sequence: base<<6|qual; qual==63 for N tarray[0..size*2-1]: temporary array */ uint8_t *cs2nt_nt_qual(int size, const uint8_t *nt_read, const uint8_t *cs_read, uint8_t *tarray) { int k, c1, c2; uint8_t *t2array = tarray + size; // get the color sequence of nt_read c1 = nt_read[0]; for (k = 1; k <= size; ++k) { c2 = nt_read[k]; // in principle, there is no 'N' in nt_read[]; just in case tarray[k-1] = (c1 >= 4 || c2 >= 4)? 4 : nst_ntnt2cs_table[1<<c1 | 1<<c2]; c1 = c2; } for (k = 1; k != size; ++k) { int q = 0; if (tarray[k-1] == cs_read[k-1]>>6 && tarray[k] == cs_read[k]>>6) { q = (int)(cs_read[k-1]&0x3f) + (int)(cs_read[k]&0x3f) + 10; } else if (tarray[k-1] == cs_read[k-1]>>6) { q = (int)(cs_read[k-1]&0x3f) - (int)(cs_read[k]&0x3f); } else if (tarray[k] == cs_read[k]>>6) { q = (int)(cs_read[k]&0x3f) - (int)(cs_read[k-1]&0x3f); } // else, q = 0 if (q < 0) q = 0; if (q > 60) q = 60; t2array[k] = nt_read[k]<<6 | q; if ((cs_read[k-1]&0x3f) == 63 || (cs_read[k]&0x3f) == 63) t2array[k] = 0; } return t2array + 1; // of size-2 } // this function will be called when p->seq has been reversed by refine_gapped() void bwa_cs2nt_core(bwa_seq_t *p, bwtint_t l_pac, ubyte_t *pac) { uint8_t *ta, *nt_read, *btarray, *tarray, *nt_ref, *cs_read, *new_nt_read; int i, len; uint8_t *seq; // set temporary arrays if (p->type == BWA_TYPE_NO_MATCH) return; len = p->len + p->n_gapo + p->n_gape + 100; // leave enough space ta = (uint8_t*)malloc(len * 7); nt_ref = ta; cs_read = nt_ref + len; nt_read = cs_read + len; btarray = nt_read + len; tarray = nt_read + len; #define __gen_csbase(_cs, _i, _seq) do { \ int q = p->qual[p->strand? p->len - 1 - (_i) : (_i)] - 33; \ if (q > 60) q = 60; \ if (_seq[_i] > 3) q = 63; \ (_cs) = _seq[_i]<<6 | q; \ } while (0) // generate len, nt_ref[] and cs_read seq = p->strand? p->rseq : p->seq; nt_ref[0] = p->pos? bns_pac(pac, p->pos-1) : 4; if (p->cigar == 0) { // no gap or clipping len = p->len; for (i = 0; i < p->len; ++i) { __gen_csbase(cs_read[i], i, seq); nt_ref[i+1] = bns_pac(pac, p->pos + i); } } else { int k, z; bwtint_t x, y; x = p->pos; y = 0; for (k = z = 0; k < p->n_cigar; ++k) { int l = __cigar_len(p->cigar[k]); if (__cigar_op(p->cigar[k]) == FROM_M) { for (i = 0; i < l; ++i, ++x, ++y) { __gen_csbase(cs_read[z], y, seq); nt_ref[z+1] = bns_pac(pac, x); ++z; } } else if (__cigar_op(p->cigar[k]) == FROM_I) { for (i = 0; i < l; ++i, ++y) { __gen_csbase(cs_read[z], y, seq); nt_ref[z+1] = 4; ++z; } } else if (__cigar_op(p->cigar[k]) == FROM_S) y += l; else x += l; } len = z; } cs2nt_DP(len, nt_ref, cs_read, nt_read, btarray); new_nt_read = cs2nt_nt_qual(len, nt_read, cs_read, tarray); // update p p->len = p->full_len = len - 1; for (i = 0; i < p->len; ++i) { if ((new_nt_read[i]&0x3f) == 63) { p->qual[i] = 33; seq[i] = 4; } else { p->qual[i] = (new_nt_read[i]&0x3f) + 33; seq[i] = new_nt_read[i]>>6; } } p->qual[p->len] = seq[p->len] = 0; if (p->strand) { memcpy(p->seq, seq, p->len); seq_reverse(p->len, p->seq, 1); seq_reverse(p->len, p->qual, 0); } else { memcpy(p->rseq, seq, p->len); seq_reverse(p->len, p->rseq, 1); } free(ta); }