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aln_sink.cpp
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aln_sink.cpp
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/*
* Copyright 2011, Ben Langmead <[email protected]>
*
* This file is part of Bowtie 2.
*
* Bowtie 2 is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Bowtie 2 is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Bowtie 2. If not, see <http://www.gnu.org/licenses/>.
*/
#include <iomanip>
#include <limits>
#include "aln_sink.h"
#include "aligner_seed.h"
#include "util.h"
using namespace std;
/**
* Initialize state machine with a new read. The state we start in depends
* on whether it's paired-end or unpaired.
*/
void ReportingState::nextRead(bool paired) {
paired_ = paired;
if(paired) {
state_ = CONCORDANT_PAIRS;
doneConcord_ = false;
doneDiscord_ = p_.discord ? false : true;
doneUnpair1_ = p_.mixed ? false : true;
doneUnpair2_ = p_.mixed ? false : true;
exitConcord_ = ReportingState::EXIT_DID_NOT_EXIT;
exitDiscord_ = p_.discord ?
ReportingState::EXIT_DID_NOT_EXIT :
ReportingState::EXIT_DID_NOT_ENTER;
exitUnpair1_ = p_.mixed ?
ReportingState::EXIT_DID_NOT_EXIT :
ReportingState::EXIT_DID_NOT_ENTER;
exitUnpair2_ = p_.mixed ?
ReportingState::EXIT_DID_NOT_EXIT :
ReportingState::EXIT_DID_NOT_ENTER;
} else {
// Unpaired
state_ = UNPAIRED;
doneConcord_ = true;
doneDiscord_ = true;
doneUnpair1_ = false;
doneUnpair2_ = true;
exitConcord_ = ReportingState::EXIT_DID_NOT_ENTER; // not relevant
exitDiscord_ = ReportingState::EXIT_DID_NOT_ENTER; // not relevant
exitUnpair1_ = ReportingState::EXIT_DID_NOT_EXIT;
exitUnpair2_ = ReportingState::EXIT_DID_NOT_ENTER; // not relevant
}
doneUnpair_ = doneUnpair1_ && doneUnpair2_;
done_ = false;
nconcord_ = ndiscord_ = nunpair1_ = nunpair2_ = 0;
}
/**
* Caller uses this member function to indicate that one additional
* concordant alignment has been found.
*/
bool ReportingState::foundConcordant() {
assert(paired_);
assert_geq(state_, ReportingState::CONCORDANT_PAIRS);
assert(!doneConcord_);
nconcord_++;
areDone(nconcord_, doneConcord_, exitConcord_);
// No need to search for discordant alignments if there are one or more
// concordant alignments.
doneDiscord_ = true;
exitDiscord_ = ReportingState::EXIT_SHORT_CIRCUIT_TRUMPED;
if(doneConcord_) {
// If we're finished looking for concordant alignments, do we have to
// continue on to search for unpaired alignments? Only if our exit
// from the concordant stage is EXIT_SHORT_CIRCUIT_M. If it's
// EXIT_SHORT_CIRCUIT_k or EXIT_WITH_ALIGNMENTS, we can skip unpaired.
assert_neq(ReportingState::EXIT_NO_ALIGNMENTS, exitConcord_);
if(exitConcord_ != ReportingState::EXIT_SHORT_CIRCUIT_M) {
if(!doneUnpair1_) {
doneUnpair1_ = true;
exitUnpair1_ = ReportingState::EXIT_SHORT_CIRCUIT_TRUMPED;
}
if(!doneUnpair2_) {
doneUnpair2_ = true;
exitUnpair2_ = ReportingState::EXIT_SHORT_CIRCUIT_TRUMPED;
}
}
}
updateDone();
return done();
}
/**
* Caller uses this member function to indicate that one additional unpaired
* mate alignment has been found for the specified mate.
*/
bool ReportingState::foundUnpaired(bool mate1) {
assert_gt(state_, ReportingState::NO_READ);
// Note: it's not right to assert !doneUnpair1_/!doneUnpair2_ here.
// Even if we're done with finding
if(mate1) {
nunpair1_++;
// Did we just finish with this mate?
if(!doneUnpair1_) {
areDone(nunpair1_, doneUnpair1_, exitUnpair1_);
if(doneUnpair1_) {
doneUnpair_ = doneUnpair1_ && doneUnpair2_;
updateDone();
}
}
if(nunpair1_ > 1) {
doneDiscord_ = true;
exitDiscord_ = ReportingState::EXIT_NO_ALIGNMENTS;
}
} else {
nunpair2_++;
// Did we just finish with this mate?
if(!doneUnpair2_) {
areDone(nunpair2_, doneUnpair2_, exitUnpair2_);
if(doneUnpair2_) {
doneUnpair_ = doneUnpair1_ && doneUnpair2_;
updateDone();
}
}
if(nunpair2_ > 1) {
doneDiscord_ = true;
exitDiscord_ = ReportingState::EXIT_NO_ALIGNMENTS;
}
}
return done();
}
/**
* Called to indicate that the aligner has finished searching for
* alignments. This gives us a chance to finalize our state.
*
* TODO: Keep track of short-circuiting information.
*/
void ReportingState::finish() {
if(!doneConcord_) {
doneConcord_ = true;
exitConcord_ =
((nconcord_ > 0) ?
ReportingState::EXIT_WITH_ALIGNMENTS :
ReportingState::EXIT_NO_ALIGNMENTS);
}
assert_gt(exitConcord_, EXIT_DID_NOT_EXIT);
if(!doneUnpair1_) {
doneUnpair1_ = true;
exitUnpair1_ =
((nunpair1_ > 0) ?
ReportingState::EXIT_WITH_ALIGNMENTS :
ReportingState::EXIT_NO_ALIGNMENTS);
}
assert_gt(exitUnpair1_, EXIT_DID_NOT_EXIT);
if(!doneUnpair2_) {
doneUnpair2_ = true;
exitUnpair2_ =
((nunpair2_ > 0) ?
ReportingState::EXIT_WITH_ALIGNMENTS :
ReportingState::EXIT_NO_ALIGNMENTS);
}
assert_gt(exitUnpair2_, EXIT_DID_NOT_EXIT);
if(!doneDiscord_) {
// Check if the unpaired alignments should be converted to a single
// discordant paired-end alignment.
assert_eq(0, ndiscord_);
if(nconcord_ == 0 && nunpair1_ == 1 && nunpair2_ == 1) {
convertUnpairedToDiscordant();
}
doneDiscord_ = true;
exitDiscord_ =
((ndiscord_ > 0) ?
ReportingState::EXIT_WITH_ALIGNMENTS :
ReportingState::EXIT_NO_ALIGNMENTS);
}
assert(!paired_ || exitDiscord_ > ReportingState::EXIT_DID_NOT_EXIT);
doneUnpair_ = done_ = true;
assert(done());
}
/**
* Populate given counters with the number of various kinds of alignments
* to report for this read. Concordant alignments are preferable to (and
* mutually exclusive with) discordant alignments, and paired-end
* alignments are preferable to unpaired alignments.
*
* The caller also needs some additional information for the case where a
* pair or unpaired read aligns repetitively. If the read is paired-end
* and the paired-end has repetitive concordant alignments, that should be
* reported, and 'pairMax' is set to true to indicate this. If the read is
* paired-end, does not have any conordant alignments, but does have
* repetitive alignments for one or both mates, then that should be
* reported, and 'unpair1Max' and 'unpair2Max' are set accordingly.
*
* Note that it's possible in the case of a paired-end read for the read to
* have repetitive concordant alignments, but for one mate to have a unique
* unpaired alignment.
*/
void ReportingState::getReport(
uint64_t& nconcordAln, // # concordant alignments to report
uint64_t& ndiscordAln, // # discordant alignments to report
uint64_t& nunpair1Aln, // # unpaired alignments for mate #1 to report
uint64_t& nunpair2Aln, // # unpaired alignments for mate #2 to report
bool& pairMax, // repetitive concordant alignments
bool& unpair1Max, // repetitive alignments for mate #1
bool& unpair2Max) // repetitive alignments for mate #2
const
{
nconcordAln = ndiscordAln = nunpair1Aln = nunpair2Aln = 0;
pairMax = unpair1Max = unpair2Max = false;
assert_gt(p_.khits, 0);
assert_gt(p_.mhits, 0);
if(paired_) {
// Do we have 1 or more concordant alignments to report?
if(exitConcord_ == ReportingState::EXIT_SHORT_CIRCUIT_k) {
// k at random
assert_geq(nconcord_, (uint64_t)p_.khits);
nconcordAln = p_.khits;
return;
} else if(exitConcord_ == ReportingState::EXIT_SHORT_CIRCUIT_M) {
assert(p_.msample);
assert_gt(nconcord_, 0);
pairMax = true; // repetitive concordant alignments
if(p_.mixed) {
unpair1Max = nunpair1_ > (uint64_t)p_.mhits;
unpair2Max = nunpair2_ > (uint64_t)p_.mhits;
}
// Not sure if this is OK
nconcordAln = 1; // 1 at random
return;
} else if(exitConcord_ == ReportingState::EXIT_WITH_ALIGNMENTS) {
assert_gt(nconcord_, 0);
// <= k at random
nconcordAln = min<uint64_t>(nconcord_, p_.khits);
return;
}
assert(!p_.mhitsSet() || nconcord_ <= (uint64_t)p_.mhits+1);
// Do we have a discordant alignment to report?
if(exitDiscord_ == ReportingState::EXIT_WITH_ALIGNMENTS) {
// Report discordant
assert(p_.discord);
ndiscordAln = 1;
return;
}
}
assert_neq(ReportingState::EXIT_SHORT_CIRCUIT_TRUMPED, exitUnpair1_);
assert_neq(ReportingState::EXIT_SHORT_CIRCUIT_TRUMPED, exitUnpair2_);
if((paired_ && !p_.mixed) || nunpair1_ + nunpair2_ == 0) {
// Unpaired alignments either not reportable or non-existant
return;
}
// Do we have 1 or more alignments for mate #1 to report?
if(exitUnpair1_ == ReportingState::EXIT_SHORT_CIRCUIT_k) {
// k at random
assert_geq(nunpair1_, (uint64_t)p_.khits);
nunpair1Aln = p_.khits;
} else if(exitUnpair1_ == ReportingState::EXIT_SHORT_CIRCUIT_M) {
assert(p_.msample);
assert_gt(nunpair1_, 0);
unpair1Max = true; // repetitive alignments for mate #1
nunpair1Aln = 1; // 1 at random
} else if(exitUnpair1_ == ReportingState::EXIT_WITH_ALIGNMENTS) {
assert_gt(nunpair1_, 0);
// <= k at random
nunpair1Aln = min<uint64_t>(nunpair1_, (uint64_t)p_.khits);
}
assert(!p_.mhitsSet() || paired_ || nunpair1_ <= (uint64_t)p_.mhits+1);
// Do we have 2 or more alignments for mate #2 to report?
if(exitUnpair2_ == ReportingState::EXIT_SHORT_CIRCUIT_k) {
// k at random
nunpair2Aln = p_.khits;
} else if(exitUnpair2_ == ReportingState::EXIT_SHORT_CIRCUIT_M) {
assert(p_.msample);
assert_gt(nunpair2_, 0);
unpair2Max = true; // repetitive alignments for mate #1
nunpair2Aln = 1; // 1 at random
} else if(exitUnpair2_ == ReportingState::EXIT_WITH_ALIGNMENTS) {
assert_gt(nunpair2_, 0);
// <= k at random
nunpair2Aln = min<uint64_t>(nunpair2_, (uint64_t)p_.khits);
}
assert(!p_.mhitsSet() || paired_ || nunpair2_ <= (uint64_t)p_.mhits+1);
}
/**
* Given the number of alignments in a category, check whether we
* short-circuited out of the category. Set the done and exit arguments to
* indicate whether and how we short-circuited.
*/
inline void ReportingState::areDone(
uint64_t cnt, // # alignments in category
bool& done, // out: whether we short-circuited out of category
int& exit) const // out: if done, how we short-circuited (-k? -m? etc)
{
assert(!done);
// Have we exceeded the -k limit?
assert_gt(p_.khits, 0);
assert_gt(p_.mhits, 0);
if(cnt >= (uint64_t)p_.khits && !p_.mhitsSet()) {
done = true;
exit = ReportingState::EXIT_SHORT_CIRCUIT_k;
}
// Have we exceeded the -m or -M limit?
else if(p_.mhitsSet() && cnt > (uint64_t)p_.mhits) {
done = true;
assert(p_.msample);
exit = ReportingState::EXIT_SHORT_CIRCUIT_M;
}
}
#ifdef ALN_SINK_MAIN
#include <iostream>
bool testDones(
const ReportingState& st,
bool done1,
bool done2,
bool done3,
bool done4,
bool done5,
bool done6)
{
assert(st.doneConcordant() == done1);
assert(st.doneDiscordant() == done2);
assert(st.doneUnpaired(true) == done3);
assert(st.doneUnpaired(false) == done4);
assert(st.doneUnpaired() == done5);
assert(st.done() == done6);
assert(st.repOk());
return true;
}
int main(void) {
cerr << "Case 1 (simple unpaired 1) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
2, // khits
0, // mhits
0, // pengap
false, // msample
false, // discord
false); // mixed
ReportingState st(rp);
st.nextRead(false); // unpaired read
assert(testDones(st, true, true, false, true, false, false));
st.foundUnpaired(true);
assert(testDones(st, true, true, false, true, false, false));
st.foundUnpaired(true);
assert(testDones(st, true, true, true, true, true, true));
st.finish();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(0, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(2, st.numUnpaired1());
assert_eq(0, st.numUnpaired2());
assert(st.repOk());
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(0, ndiscord);
assert_eq(2, nunpair1);
assert_eq(0, nunpair2);
assert(!pairMax);
assert(!unpair1Max);
assert(!unpair2Max);
}
cerr << "PASSED" << endl;
cerr << "Case 2 (simple unpaired 1) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
2, // khits
3, // mhits
0, // pengap
false, // msample
false, // discord
false); // mixed
ReportingState st(rp);
st.nextRead(false); // unpaired read
assert(testDones(st, true, true, false, true, false, false));
st.foundUnpaired(true);
assert(testDones(st, true, true, false, true, false, false));
st.foundUnpaired(true);
assert(testDones(st, true, true, false, true, false, false));
st.foundUnpaired(true);
assert(testDones(st, true, true, false, true, false, false));
st.foundUnpaired(true);
assert(testDones(st, true, true, true, true, true, true));
assert_eq(0, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(4, st.numUnpaired1());
assert_eq(0, st.numUnpaired2());
st.finish();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(0, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(4, st.numUnpaired1());
assert_eq(0, st.numUnpaired2());
assert(st.repOk());
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(!pairMax);
assert(unpair1Max);
assert(!unpair2Max);
}
cerr << "PASSED" << endl;
cerr << "Case 3 (simple paired 1) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
2, // khits
3, // mhits
0, // pengap
false, // msample
false, // discord
false); // mixed
ReportingState st(rp);
st.nextRead(true); // unpaired read
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, true, true, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(4, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(4, st.numUnpaired1());
assert_eq(4, st.numUnpaired2());
st.finish();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(4, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(4, st.numUnpaired1());
assert_eq(4, st.numUnpaired2());
assert(st.repOk());
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(pairMax);
assert(!unpair1Max); // because !mixed
assert(!unpair2Max); // because !mixed
}
cerr << "PASSED" << endl;
cerr << "Case 4 (simple paired 2) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
2, // khits
3, // mhits
0, // pengap
false, // msample
true, // discord
true); // mixed
ReportingState st(rp);
st.nextRead(true); // unpaired read
assert(testDones(st, false, false, false, false, false, false));
st.foundUnpaired(true);
assert(testDones(st, false, false, false, false, false, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, false, false, false, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, false, false, false, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, false, false, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, false, false, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, false, false, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, false, false, false));
st.foundUnpaired(false);
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, false, true, true, true, true, false));
st.foundConcordant();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(4, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(4, st.numUnpaired1());
assert_eq(4, st.numUnpaired2());
st.finish();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(4, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(4, st.numUnpaired1());
assert_eq(4, st.numUnpaired2());
assert(st.repOk());
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(pairMax);
assert(unpair1Max);
assert(unpair2Max);
}
cerr << "PASSED" << endl;
cerr << "Case 5 (potential discordant after concordant) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
2, // khits
3, // mhits
0, // pengap
false, // msample
true, // discord
true); // mixed
ReportingState st(rp);
st.nextRead(true);
assert(testDones(st, false, false, false, false, false, false));
st.foundUnpaired(true);
st.foundUnpaired(false);
st.foundConcordant();
assert(testDones(st, false, true, false, false, false, false));
st.finish();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(1, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(1, st.numUnpaired1());
assert_eq(1, st.numUnpaired2());
assert(st.repOk());
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(1, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(!pairMax);
assert(!unpair1Max);
assert(!unpair2Max);
}
cerr << "PASSED" << endl;
cerr << "Case 6 (true discordant) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
2, // khits
3, // mhits
0, // pengap
false, // msample
true, // discord
true); // mixed
ReportingState st(rp);
st.nextRead(true);
assert(testDones(st, false, false, false, false, false, false));
st.foundUnpaired(true);
st.foundUnpaired(false);
assert(testDones(st, false, false, false, false, false, false));
st.finish();
assert(testDones(st, true, true, true, true, true, true));
assert_eq(0, st.numConcordant());
assert_eq(1, st.numDiscordant());
assert_eq(0, st.numUnpaired1());
assert_eq(0, st.numUnpaired2());
assert(st.repOk());
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(1, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(!pairMax);
assert(!unpair1Max);
assert(!unpair2Max);
}
cerr << "PASSED" << endl;
cerr << "Case 7 (unaligned pair & uniquely aligned mate, mixed-mode) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
1, // khits
1, // mhits
0, // pengap
false, // msample
true, // discord
true); // mixed
ReportingState st(rp);
st.nextRead(true); // unpaired read
// assert(st.doneConcordant() == done1);
// assert(st.doneDiscordant() == done2);
// assert(st.doneUnpaired(true) == done3);
// assert(st.doneUnpaired(false) == done4);
// assert(st.doneUnpaired() == done5);
// assert(st.done() == done6);
st.foundUnpaired(true);
assert(testDones(st, false, false, false, false, false, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, false, false, false));
assert_eq(0, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(2, st.numUnpaired1());
assert_eq(0, st.numUnpaired2());
st.finish();
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(!pairMax);
assert(unpair1Max);
assert(!unpair2Max);
}
cerr << "PASSED" << endl;
cerr << "Case 8 (unaligned pair & uniquely aligned mate, NOT mixed-mode) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
1, // khits
1, // mhits
0, // pengap
false, // msample
true, // discord
false); // mixed
ReportingState st(rp);
st.nextRead(true); // unpaired read
// assert(st.doneConcordant() == done1);
// assert(st.doneDiscordant() == done2);
// assert(st.doneUnpaired(true) == done3);
// assert(st.doneUnpaired(false) == done4);
// assert(st.doneUnpaired() == done5);
// assert(st.done() == done6);
st.foundUnpaired(true);
assert(testDones(st, false, false, true, true, true, false));
st.foundUnpaired(true);
assert(testDones(st, false, true, true, true, true, false));
assert_eq(0, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(2, st.numUnpaired1());
assert_eq(0, st.numUnpaired2());
st.finish();
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(0, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(!pairMax);
assert(!unpair1Max); // not really relevant
assert(!unpair2Max); // not really relevant
}
cerr << "PASSED" << endl;
cerr << "Case 9 (repetitive pair, only one mate repetitive) ... ";
{
uint64_t nconcord = 0, ndiscord = 0, nunpair1 = 0, nunpair2 = 0;
bool pairMax = false, unpair1Max = false, unpair2Max = false;
ReportingParams rp(
1, // khits
1, // mhits
0, // pengap
true, // msample
true, // discord
true); // mixed
ReportingState st(rp);
st.nextRead(true); // unpaired read
// assert(st.doneConcordant() == done1);
// assert(st.doneDiscordant() == done2);
// assert(st.doneUnpaired(true) == done3);
// assert(st.doneUnpaired(false) == done4);
// assert(st.doneUnpaired() == done5);
// assert(st.done() == done6);
st.foundConcordant();
assert(st.repOk());
st.foundUnpaired(true);
assert(st.repOk());
st.foundUnpaired(false);
assert(st.repOk());
assert(testDones(st, false, true, false, false, false, false));
assert(st.repOk());
st.foundConcordant();
assert(st.repOk());
st.foundUnpaired(true);
assert(st.repOk());
assert(testDones(st, true, true, true, false, false, false));
assert_eq(2, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(2, st.numUnpaired1());
assert_eq(1, st.numUnpaired2());
st.foundUnpaired(false);
assert(st.repOk());
assert(testDones(st, true, true, true, true, true, true));
assert_eq(2, st.numConcordant());
assert_eq(0, st.numDiscordant());
assert_eq(2, st.numUnpaired1());
assert_eq(2, st.numUnpaired2());
st.finish();
st.getReport(nconcord, ndiscord, nunpair1, nunpair2,
pairMax, unpair1Max, unpair2Max);
assert_eq(1, nconcord);
assert_eq(0, ndiscord);
assert_eq(0, nunpair1);
assert_eq(0, nunpair2);
assert(pairMax);
assert(unpair1Max); // not really relevant
assert(unpair2Max); // not really relevant
}
cerr << "PASSED" << endl;
}
#endif /*def ALN_SINK_MAIN*/