/**
* Append a verbose, readable hit to the given output stream.
*/
void VerboseHitSink::append(
BTString& o,
const Hit& h,
const vector<string>* refnames,
bool fullRef,
int partition,
int offBase,
bool colorSeq,
bool colorQual,
bool cost,
const Bitset& suppress)
{
bool spill = false;
int spillAmt = 0;
uint32_t pdiv = 0xffffffff;
uint32_t pmod = 0xffffffff;
do {
bool dospill = false;
if(spill) {
// The read spilled over a partition boundary and so
// needs to be printed more than once
spill = false;
dospill = true;
spillAmt++;
}
assert(!spill);
size_t field = 0;
bool firstfield = true;
if(partition != 0) {
int pospart = abs(partition);
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
// Output a partitioning key
// First component of the key is the reference index
if(refnames != NULL && h.h.first < refnames->size()) {
printUptoWs(o, (*refnames)[h.h.first], !fullRef);
} else {
o << h.h.first;
}
}
// Next component of the key is the partition id
if(!dospill) {
pdiv = (h.h.second + offBase) / pospart;
pmod = (h.h.second + offBase) % pospart;
}
assert_neq(0xffffffff, pdiv);
assert_neq(0xffffffff, pmod);
if(dospill) assert_gt(spillAmt, 0);
if(partition > 0 &&
(pmod + h.length()) >= ((uint32_t)pospart * (spillAmt + 1))) {
// Spills into the next partition so we need to
// output another alignment for that partition
spill = true;
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) {
firstfield = false;
} else {
o << '\t';
}
// Print partition id with leading 0s so that Hadoop
// can do lexicographical sort (modern Hadoop versions
// seen to support numeric)
int padding = 10;
uint32_t part = (pdiv + (dospill ? spillAmt : 0));
uint32_t parttmp = part;
while(parttmp > 0) {
padding--;
parttmp /= 10;
}
assert_geq(padding, 0);
for(int i = 0; i < padding; i++) {
o << '0';
}
o << part;
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) {
firstfield = false;
} else {
o << '\t';
}
// Print offset with leading 0s
int padding = 9;
uint32_t off = h.h.second + offBase;
uint32_t offtmp = off;
while(offtmp > 0) {
padding--;
offtmp /= 10;
}
assert_geq(padding, 0);
for(int i = 0; i < padding; i++) {
o << '0';
}
o << off;
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << (h.fw? "+":"-");
}
// end if(partition != 0)
} else {
assert(!dospill);
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
for(size_t i = 0; i < seqan::length(h.patName); i++) {
o << (char)(h.patName[i]);
}
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << (h.fw? '+' : '-');
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
// .first is text id, .second is offset
if(refnames != NULL && h.h.first < refnames->size()) {
printUptoWs(o, (*refnames)[h.h.first], !fullRef);
} else {
o << h.h.first;
}
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << (h.h.second + offBase);
}
// end else clause of if(partition != 0)
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
const String<Dna5>* pat = &h.patSeq;
if(h.color && colorSeq) pat = &h.colSeq;
for(size_t i = 0; i < seqan::length(*pat); i++) {
o << (char)((*pat)[i]);
}
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
const String<char>* qual = &h.quals;
if(h.color && colorQual) qual = &h.colQuals;
for(size_t i = 0; i < seqan::length(*qual); i++) {
o << (char)((*qual)[i]);
}
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << h.oms;
}
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
const size_t len = length(h.patSeq);
// Output mismatch column
bool firstmm = true;
for (unsigned int i = 0; i < len; ++ i) {
if(h.mms.test(i)) {
// There's a mismatch at this position
if (!firstmm) {
o << ",";
}
o << i; // position
assert_gt(h.refcs.size(), i);
char refChar = toupper(h.refcs[i]);
char qryChar = (h.fw ? h.patSeq[i] : h.patSeq[length(h.patSeq)-i-1]);
assert_neq(refChar, qryChar);
o << ":" << refChar << ">" << qryChar;
firstmm = false;
}
}
if(partition != 0 && firstmm) o << '-';
}
if(partition != 0) {
// Fields addded as of Crossbow 0.1.4
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << (int)h.mate;
}
// Print label, or whole read name if label isn't found
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
int labelOff = -1;
// If LB: field is present, print its value
for(int i = 0; i < (int)seqan::length(h.patName)-3; i++) {
if(h.patName[i] == 'L' &&
h.patName[i+1] == 'B' &&
h.patName[i+2] == ':' &&
((i == 0) || h.patName[i-1] == ';'))
{
labelOff = i+3;
for(int j = labelOff; j < (int)seqan::length(h.patName); j++) {
if(h.patName[j] != ';') {
o << h.patName[j];
} else {
break;
}
}
}
}
// Otherwise, print the whole read name
if(labelOff == -1) {
for(size_t i = 0; i < seqan::length(h.patName); i++) {
o << (char)(h.patName[i]);
}
}
}
}
if(cost) {
// Stratum
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << (int)h.stratum;
}
// Cost
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << (int)h.cost;
}
}
if(showSeed) {
// Seed
if(!suppress.test((uint32_t)field++)) {
if(firstfield) firstfield = false;
else o << '\t';
o << h.seed;
}
}
o << '\n';
} while(spill);
}
/**
* Append a SAM output record for an unaligned read.
*/
void SAMHitSink::appendAligned(ostream& ss,
const Hit& h,
int mapq,
int xms, // value for XM:I field
const vector<string>* refnames,
ReferenceMap *rmap,
AnnotationMap *amap,
bool fullRef,
bool noQnameTrunc,
int offBase)
{
// QNAME
if(h.mate > 0) {
// truncate final 2 chars
for(int i = 0; i < (int)seqan::length(h.patName)-2; i++) {
if(!noQnameTrunc && isspace((int)h.patName[i])) break;
ss << h.patName[i];
}
} else {
for(int i = 0; i < (int)seqan::length(h.patName); i++) {
if(!noQnameTrunc && isspace((int)h.patName[i])) break;
ss << h.patName[i];
}
}
ss << '\t';
// FLAG
int flags = 0;
if(h.mate == 1) {
flags |= SAM_FLAG_PAIRED | SAM_FLAG_FIRST_IN_PAIR | SAM_FLAG_MAPPED_PAIRED;
} else if(h.mate == 2) {
flags |= SAM_FLAG_PAIRED | SAM_FLAG_SECOND_IN_PAIR | SAM_FLAG_MAPPED_PAIRED;
}
if(!h.fw) flags |= SAM_FLAG_QUERY_STRAND;
if(h.mate > 0 && !h.mfw) flags |= SAM_FLAG_MATE_STRAND;
ss << flags << "\t";
// RNAME
if(refnames != NULL && rmap != NULL) {
printUptoWs(ss, rmap->getName(h.h.first), !fullRef);
} else if(refnames != NULL && h.h.first < refnames->size()) {
printUptoWs(ss, (*refnames)[h.h.first], !fullRef);
} else {
ss << h.h.first;
}
// POS
ss << '\t' << (h.h.second + 1);
// MAPQ
ss << "\t" << mapq;
// CIGAR
ss << '\t' << h.length() << 'M';
// MRNM
if(h.mate > 0) {
ss << "\t=";
} else {
ss << "\t*";
}
// MPOS
if(h.mate > 0) {
ss << '\t' << (h.mh.second + 1);
} else {
ss << "\t0";
}
// ISIZE
ss << '\t';
if(h.mate > 0) {
assert_eq(h.h.first, h.mh.first);
int64_t inslen = 0;
if(h.h.second > h.mh.second) {
inslen = (int64_t)h.h.second - (int64_t)h.mh.second + (int64_t)h.length();
inslen = -inslen;
} else {
inslen = (int64_t)h.mh.second - (int64_t)h.h.second + (int64_t)h.mlen;
}
ss << inslen;
} else {
ss << '0';
}
// SEQ
ss << '\t' << h.patSeq;
// QUAL
ss << '\t' << h.quals;
//
// Optional fields
//
// Always output stratum
ss << "\tXA:i:" << (int)h.stratum;
// Always output cost
//ss << "\tXC:i:" << (int)h.cost;
// Look for SNP annotations falling within the alignment
// Output MD field
size_t len = length(h.patSeq);
int nm = 0;
int run = 0;
ss << "\tMD:Z:";
const FixedBitset<1024> *mms = &h.mms;
ASSERT_ONLY(const String<Dna5>* pat = &h.patSeq);
const vector<char>* refcs = &h.refcs;
if(h.color && false) {
// Disabled: print MD:Z string w/r/t to colors, not letters
mms = &h.cmms;
ASSERT_ONLY(pat = &h.colSeq);
assert_eq(length(h.colSeq), len+1);
len = length(h.colSeq);
refcs = &h.crefcs;
}
if(h.fw) {
for (int i = 0; i < (int)len; ++ i) {
if(mms->test(i)) {
nm++;
// There's a mismatch at this position
assert_gt((int)refcs->size(), i);
char refChar = toupper((*refcs)[i]);
ASSERT_ONLY(char qryChar = (h.fw ? (*pat)[i] : (*pat)[len-i-1]));
assert_neq(refChar, qryChar);
ss << run << refChar;
run = 0;
} else {
run++;
}
}
} else {
for (int i = len-1; i >= 0; -- i) {
if(mms->test(i)) {
nm++;
// There's a mismatch at this position
assert_gt((int)refcs->size(), i);
char refChar = toupper((*refcs)[i]);
ASSERT_ONLY(char qryChar = (h.fw ? (*pat)[i] : (*pat)[len-i-1]));
assert_neq(refChar, qryChar);
ss << run << refChar;
run = 0;
} else {
run++;
}
}
}
ss << run;
// Add optional edit distance field
ss << "\tNM:i:" << nm;
if(h.color) ss << "\tCM:i:" << h.cmms.count();
// Add optional fields reporting the primer base and the downstream color,
// which, if they were present, were clipped when the read was read in
if(h.color && gReportColorPrimer) {
if(h.primer != '?') {
ss << "\tZP:Z:" << h.primer;
assert(isprint(h.primer));
}
if(h.trimc != '?') {
ss << "\tZp:Z:" << h.trimc;
assert(isprint(h.trimc));
}
}
if(xms > 0) ss << "\tXM:i:" << xms;
ss << endl;
}
