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aligner_driver.h
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aligner_driver.h
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/*
* Copyright 2012, 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/>.
*/
/*
* aligner_driver.h
*
* REDUNDANT SEED HITS
*
* We say that two seed hits are redundant if they trigger identical
* seed-extend dynamic programming problems. Put another way, they both lie on
* the same diagonal of the overall read/reference dynamic programming matrix.
* Detecting redundant seed hits is simple when the seed hits are ungapped. We
* do this after offset resolution but before the offset is converted to genome
* coordinates (see uses of the seenDiags1_/seenDiags2_ fields for examples).
*
* REDUNDANT ALIGNMENTS
*
* In an unpaired context, we say that two alignments are redundant if they
* share any cells in the global DP table. Roughly speaking, this is like
* saying that two alignments are redundant if any read character aligns to the
* same reference character (same reference sequence, same strand, same offset)
* in both alignments.
*
* In a paired-end context, we say that two paired-end alignments are redundant
* if the mate #1s are redundant and the mate #2s are redundant.
*
* How do we enforce this? In the unpaired context, this is relatively simple:
* the cells from each alignment are checked against a set containing all cells
* from all previous alignments. Given a new alignment, for each cell in the
* new alignment we check whether it is in the set. If there is any overlap,
* the new alignment is rejected as redundant. Otherwise, the new alignment is
* accepted and its cells are added to the set.
*
* Enforcement in a paired context is a little trickier. Consider the
* following approaches:
*
* 1. Skip anchors that are redundant with any previous anchor or opposite
* alignment. This is sufficient to ensure no two concordant alignments
* found are redundant.
*
* 2. Same as scheme 1, but with a "transitive closure" scheme for finding all
* concordant pairs in the vicinity of an anchor. Consider the AB/AC
* scenario from the previous paragraph. If B is the anchor alignment, we
* will find AB but not AC. But under this scheme, once we find AB we then
* let B be a new anchor and immediately look for its opposites. Likewise,
* if we find any opposite, we make them anchors and continue searching. We
* don't stop searching until every opposite is used as an anchor.
*
* 3. Skip anchors that are redundant with any previous anchor alignment (but
* allow anchors that are redundant with previous opposite alignments).
* This isn't sufficient to avoid redundant concordant alignments. To avoid
* redundant concordants, we need an additional procedure that checks each
* new concordant alignment one-by-one against a list of previous concordant
* alignments to see if it is redundant.
*
* We take approach 1.
*/
#ifndef ALIGNER_DRIVER_H_
#define ALIGNER_DRIVER_H_
#include "aligner_seed2.h"
#include "simple_func.h"
#include "aln_sink.h"
/**
* Concrete subclass of DescentRootSelector. Puts a root every 'ival' chars,
* where 'ival' is determined by user-specified parameters. A root is filtered
* out if the end of the read is less than 'landing' positions away, in the
* direction of the search.
*/
class AlignerDriverRootSelector : public DescentRootSelector {
public:
AlignerDriverRootSelector(
double consExp,
const SimpleFunc& rootIval,
size_t landing)
{
consExp_ = consExp;
rootIval_ = rootIval;
landing_ = landing;
}
virtual ~AlignerDriverRootSelector() { }
virtual void select(
const Read& q, // read that we're selecting roots for
const Read* qo, // opposite mate, if applicable
bool nofw, // don't add roots for fw read
bool norc, // don't add roots for rc read
EList<DescentConfig>& confs, // put DescentConfigs here
EList<DescentRoot>& roots); // put DescentRoot here
protected:
double consExp_;
SimpleFunc rootIval_;
size_t landing_;
};
/**
* Return values from extendSeeds and extendSeedsPaired.
*/
enum {
// Candidates were examined exhaustively
ALDRIVER_EXHAUSTED_CANDIDATES = 1,
// The policy does not need us to look any further
ALDRIVER_POLICY_FULFILLED,
// We stopped because we ran up against a limit on how much work we should
// do for one set of seed ranges, e.g. the limit on number of consecutive
// unproductive DP extensions
ALDRIVER_EXCEEDED_LIMIT
};
/**
* This class is the glue between a DescentDriver and the dynamic programming
* implementations in Bowtie 2. The DescentDriver is used to find some very
* high-scoring alignments, but is additionally used to rank partial alignments
* so that they can be extended using dynamic programming.
*/
template <typename index_t>
class AlignerDriver {
public:
AlignerDriver(
double consExp,
const SimpleFunc& rootIval,
size_t landing,
bool veryVerbose,
const SimpleFunc& totsz,
const SimpleFunc& totfmops) :
sel_(consExp, rootIval, landing),
alsel_(),
dr1_(veryVerbose),
dr2_(veryVerbose)
{
totsz_ = totsz;
totfmops_ = totfmops;
}
/**
* Initialize driver with respect to a new read or pair.
*/
void initRead(
const Read& q1,
bool nofw,
bool norc,
TAlScore minsc,
TAlScore maxpen,
const Read* q2)
{
dr1_.initRead(q1, nofw, norc, minsc, maxpen, q2, &sel_);
red1_.init(q1.length());
paired_ = false;
if(q2 != NULL) {
dr2_.initRead(*q2, nofw, norc, minsc, maxpen, &q1, &sel_);
red2_.init(q2->length());
paired_ = true;
} else {
dr2_.reset();
}
size_t totsz = totsz_.f<size_t>(q1.length());
size_t totfmops = totfmops_.f<size_t>(q1.length());
stop_.init(
totsz,
0,
true,
totfmops);
}
/**
* Start the driver. The driver will begin by conducting a best-first,
* index-assisted search through the space of possible full and partial
* alignments. This search may be followed up with a dynamic programming
* extension step, taking a prioritized set of partial SA ranges found
* during the search and extending each with DP. The process might also be
* iterated, with the search being occasioanally halted so that DPs can be
* tried, then restarted, etc.
*/
int go(
const Scoring& sc,
const GFM<index_t>& gfmFw,
const GFM<index_t>& gfmBw,
const BitPairReference& ref,
DescentMetrics& met,
WalkMetrics& wlm,
PerReadMetrics& prm,
RandomSource& rnd,
AlnSinkWrap<index_t>& sink);
/**
* Reset state of all DescentDrivers.
*/
void reset() {
dr1_.reset();
dr2_.reset();
red1_.reset();
red2_.reset();
}
protected:
AlignerDriverRootSelector sel_; // selects where roots should go
DescentAlignmentSelector<index_t> alsel_; // one selector can deal with >1 drivers
DescentDriver<index_t> dr1_; // driver for mate 1/unpaired reads
DescentDriver<index_t> dr2_; // driver for paired-end reads
DescentStoppingConditions stop_; // when to pause index-assisted BFS
bool paired_; // current read is paired?
SimpleFunc totsz_; // memory limit on best-first search data
SimpleFunc totfmops_; // max # FM ops for best-first search
// For detecting redundant alignments
RedundantAlns red1_; // database of cells used for mate 1 alignments
RedundantAlns red2_; // database of cells used for mate 2 alignments
// For AlnRes::matchesRef
ASSERT_ONLY(SStringExpandable<char> raw_refbuf_);
ASSERT_ONLY(SStringExpandable<uint32_t> raw_destU32_);
ASSERT_ONLY(EList<bool> raw_matches_);
ASSERT_ONLY(BTDnaString tmp_rf_);
ASSERT_ONLY(BTDnaString tmp_rdseq_);
ASSERT_ONLY(BTString tmp_qseq_);
ASSERT_ONLY(EList<index_t> tmp_reflens_);
ASSERT_ONLY(EList<index_t> tmp_refoffs_);
};
#endif /* defined(ALIGNER_DRIVER_H_) */