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aligner_sw_driver.h
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aligner_sw_driver.h
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/*
* Copyright 2011, Ben Langmead <langmea@cs.jhu.edu>
*
* 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_sw_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_SW_DRIVER_H_
#define ALIGNER_SW_DRIVER_H_
#include <utility>
#include "ds.h"
#include "aligner_seed.h"
#include "aligner_sw.h"
#include "aligner_cache.h"
#include "reference.h"
#include "group_walk.h"
#include "bt2_idx.h"
#include "mem_ids.h"
#include "aln_sink.h"
#include "pe.h"
#include "ival_list.h"
#include "simple_func.h"
#include "random_util.h"
struct SeedPos {
SeedPos() : fw(false), offidx(0), rdoff(0), seedlen(0) { }
SeedPos(
bool fw_,
uint32_t offidx_,
uint32_t rdoff_,
uint32_t seedlen_)
{
init(fw_, offidx_, rdoff_, seedlen_);
}
void init(
bool fw_,
uint32_t offidx_,
uint32_t rdoff_,
uint32_t seedlen_)
{
fw = fw_;
offidx = offidx_;
rdoff = rdoff_;
seedlen = seedlen_;
}
bool operator<(const SeedPos& o) const {
if(offidx < o.offidx) return true;
if(offidx > o.offidx) return false;
if(rdoff < o.rdoff) return true;
if(rdoff > o.rdoff) return false;
if(seedlen < o.seedlen) return true;
if(seedlen > o.seedlen) return false;
if(fw && !o.fw) return true;
if(!fw && o.fw) return false;
return false;
}
bool operator>(const SeedPos& o) const {
if(offidx < o.offidx) return false;
if(offidx > o.offidx) return true;
if(rdoff < o.rdoff) return false;
if(rdoff > o.rdoff) return true;
if(seedlen < o.seedlen) return false;
if(seedlen > o.seedlen) return true;
if(fw && !o.fw) return false;
if(!fw && o.fw) return true;
return false;
}
bool operator==(const SeedPos& o) const {
return fw == o.fw && offidx == o.offidx &&
rdoff == o.rdoff && seedlen == o.seedlen;
}
bool fw;
uint32_t offidx;
uint32_t rdoff;
uint32_t seedlen;
};
/**
* An SATuple along with the associated seed position.
*/
struct SATupleAndPos {
SATuple sat; // result for this seed hit
SeedPos pos; // seed position that yielded the range this was taken from
size_t origSz; // size of range this was taken from
size_t nlex; // # position we can extend seed hit to left w/o edit
size_t nrex; // # position we can extend seed hit to right w/o edit
bool operator<(const SATupleAndPos& o) const {
if(sat < o.sat) return true;
if(sat > o.sat) return false;
return pos < o.pos;
}
bool operator==(const SATupleAndPos& o) const {
return sat == o.sat && pos == o.pos;
}
};
/**
* Encapsulates the weighted random sampling scheme we want to use to pick
* which seed hit range to sample a row from.
*/
class RowSampler {
public:
RowSampler(int cat = 0) : elim_(cat), masses_(cat) {
mass_ = 0.0f;
}
/**
* Initialze sampler with respect to a range of elements in a list of
* SATupleAndPos's.
*/
void init(
const EList<SATupleAndPos, 16>& salist,
size_t sai,
size_t saf,
bool lensq, // whether to square the numerator, which = extended length
bool szsq) // whether to square denominator, which =
{
assert_gt(saf, sai);
elim_.resize(saf - sai);
elim_.fill(false);
// Initialize mass
mass_ = 0.0f;
masses_.resize(saf - sai);
for(size_t i = sai; i < saf; i++) {
size_t len = salist[i].nlex + salist[i].nrex + 1; // + salist[i].sat.key.len;
double num = (double)len;
if(lensq) {
num *= num;
}
double denom = (double)salist[i].sat.size();
if(szsq) {
denom *= denom;
}
masses_[i - sai] = num / denom;
mass_ += masses_[i - sai];
}
}
/**
* Caller is indicating that the bin at index i is exhausted and we should
* exclude it from our sampling from now on.
*/
void finishedRange(size_t i) {
assert_lt(i, masses_.size());
elim_[i] = true;
mass_ -= masses_[i];
}
/**
* Sample randomly from the mass.
*/
size_t next(RandomSource& rnd) {
// Throw the dart
double rd = rnd.nextFloat() * mass_;
double mass_sofar = 0.0f;
size_t sz = masses_.size();
size_t last_unelim = std::numeric_limits<size_t>::max();
for(size_t i = 0; i < sz; i++) {
if(!elim_[i]) {
last_unelim = i;
mass_sofar += masses_[i];
if(rd < mass_sofar) {
// This is the one we hit
return i;
}
}
}
assert_neq(std::numeric_limits<size_t>::max(), last_unelim);
return last_unelim;
}
protected:
double mass_; // total probability mass to throw darts at
EList<bool> elim_; // whether the range is eliminated
EList<double> masses_; // mass of each range
};
/**
* Return values from extendSeeds and extendSeedsPaired.
*/
enum {
// All end-to-end and seed hits were examined
// The policy does not need us to look any further
EXTEND_EXHAUSTED_CANDIDATES = 1,
EXTEND_POLICY_FULFILLED,
// We stopped because we reached a point where the only remaining
// alignments of interest have perfect scores, but we already investigated
// perfect alignments
EXTEND_PERFECT_SCORE,
// 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
EXTEND_EXCEEDED_SOFT_LIMIT,
// We stopped because we ran up against a limit on how much work we should
// do for overall before giving up on a mate
EXTEND_EXCEEDED_HARD_LIMIT
};
/**
* Data structure encapsulating a range that's been extended out in two
* directions.
*/
struct ExtendRange {
void init(size_t off_, size_t len_, size_t sz_) {
off = off_; len = len_; sz = sz_;
}
size_t off; // offset of extended region
size_t len; // length between extremes of extended region
size_t sz; // # of elements in SA range
};
class SwDriver {
typedef PList<TIndexOffU, CACHE_PAGE_SZ> TSAList;
public:
SwDriver(size_t bytes) :
satups_(DP_CAT),
gws_(DP_CAT),
seenDiags1_(DP_CAT),
seenDiags2_(DP_CAT),
redAnchor_(DP_CAT),
redMate1_(DP_CAT),
redMate2_(DP_CAT),
pool_(bytes, CACHE_PAGE_SZ, DP_CAT),
salistEe_(DP_CAT),
gwstate_(GW_CAT) { }
/**
* Given a collection of SeedHits for a single read, extend seed alignments
* into full alignments. Where possible, try to avoid redundant offset
* lookups and dynamic programming problems. Optionally report alignments
* to a AlnSinkWrap object as they are discovered.
*
* If 'reportImmediately' is true, returns true iff a call to
* mhs->report() returned true (indicating that the reporting
* policy is satisfied and we can stop). Otherwise, returns false.
*/
int extendSeeds(
Read& rd, // read to align
bool mate1, // true iff rd is mate #1
SeedResults& sh, // seed hits to extend into full alignments
const Ebwt& ebwtFw, // BWT
const Ebwt* ebwtBw, // BWT'
const BitPairReference& ref, // Reference strings
SwAligner& swa, // dynamic programming aligner
const Scoring& sc, // scoring scheme
int seedmms, // # mismatches allowed in seed
int seedlen, // length of seed
int seedival, // interval between seeds
TAlScore& minsc, // minimum score for anchor
int nceil, // maximum # Ns permitted in ref portion
size_t maxhalf, // maximum width on one side of DP table
bool doUngapped, // do ungapped alignment
size_t maxIters, // stop after this many seed-extend loop iters
size_t maxUg, // max # ungapped extends
size_t maxDp, // max # DPs
size_t maxUgStreak, // stop after streak of this many ungap fails
size_t maxDpStreak, // stop after streak of this many dp fails
bool doExtend, // do seed extension
bool enable8, // use 8-bit SSE where possible
size_t cminlen, // use checkpointer if read longer than this
size_t cpow2, // interval between diagonals to checkpoint
bool doTri, // triangular mini-fills
int tighten, // -M score tightening mode
AlignmentCacheIface& ca, // alignment cache for seed hits
RandomSource& rnd, // pseudo-random source
WalkMetrics& wlm, // group walk left metrics
SwMetrics& swmSeed, // DP metrics for seed-extend
PerReadMetrics& prm, // per-read metrics
AlnSinkWrap* mhs, // HitSink for multiseed-style aligner
bool reportImmediately, // whether to report hits immediately to mhs
bool& exhaustive);
/**
* Given a collection of SeedHits for a read pair, extend seed
* alignments into full alignments and then look for the opposite
* mate using dynamic programming. Where possible, try to avoid
* redundant offset lookups. Optionally report alignments to a
* AlnSinkWrap object as they are discovered.
*
* If 'reportImmediately' is true, returns true iff a call to
* mhs->report() returned true (indicating that the reporting
* policy is satisfied and we can stop). Otherwise, returns false.
*/
int extendSeedsPaired(
Read& rd, // mate to align as anchor
Read& ord, // mate to align as opposite
bool anchor1, // true iff anchor mate is mate1
bool oppFilt, // true iff opposite mate was filtered out
SeedResults& sh, // seed hits for anchor
const Ebwt& ebwtFw, // BWT
const Ebwt* ebwtBw, // BWT'
const BitPairReference& ref, // Reference strings
SwAligner& swa, // dyn programming aligner for anchor
SwAligner& swao, // dyn programming aligner for opposite
const Scoring& sc, // scoring scheme
const PairedEndPolicy& pepol,// paired-end policy
int seedmms, // # mismatches allowed in seed
int seedlen, // length of seed
int seedival, // interval between seeds
TAlScore& minsc, // minimum score for anchor
TAlScore& ominsc, // minimum score for opposite
int nceil, // max # Ns permitted in ref for anchor
int onceil, // max # Ns permitted in ref for opposite
bool nofw, // don't align forward read
bool norc, // don't align revcomp read
size_t maxhalf, // maximum width on one side of DP table
bool doUngapped, // do ungapped alignment
size_t maxIters, // stop after this many seed-extend loop iters
size_t maxUg, // max # ungapped extends
size_t maxDp, // max # DPs
size_t maxEeStreak, // stop after streak of this many end-to-end fails
size_t maxUgStreak, // stop after streak of this many ungap fails
size_t maxDpStreak, // stop after streak of this many dp fails
size_t maxMateStreak, // stop seed range after N mate-find fails
bool doExtend, // do seed extension
bool enable8, // use 8-bit SSE where possible
size_t cminlen, // use checkpointer if read longer than this
size_t cpow2, // interval between diagonals to checkpoint
bool doTri, // triangular mini-fills
int tighten, // -M score tightening mode
AlignmentCacheIface& cs, // alignment cache for seed hits
RandomSource& rnd, // pseudo-random source
WalkMetrics& wlm, // group walk left metrics
SwMetrics& swmSeed, // DP metrics for seed-extend
SwMetrics& swmMate, // DP metrics for mate finidng
PerReadMetrics& prm, // per-read metrics for anchor
AlnSinkWrap* msink, // AlnSink wrapper for multiseed-style aligner
bool swMateImmediately, // whether to look for mate immediately
bool reportImmediately, // whether to report hits immediately to msink
bool discord, // look for discordant alignments?
bool mixed, // look for unpaired as well as paired alns?
bool& exhaustive);
/**
* Prepare for a new read.
*/
void nextRead(bool paired, size_t mate1len, size_t mate2len) {
redAnchor_.reset();
seenDiags1_.reset();
seenDiags2_.reset();
seedExRangeFw_[0].clear(); // mate 1 fw
seedExRangeFw_[1].clear(); // mate 2 fw
seedExRangeRc_[0].clear(); // mate 1 rc
seedExRangeRc_[1].clear(); // mate 2 rc
size_t maxlen = mate1len;
if(paired) {
redMate1_.reset();
redMate1_.init(mate1len);
redMate2_.reset();
redMate2_.init(mate2len);
if(mate2len > maxlen) {
maxlen = mate2len;
}
}
redAnchor_.init(maxlen);
}
protected:
bool eeSaTups(
const Read& rd, // read
SeedResults& sh, // seed hits to extend into full alignments
const Ebwt& ebwt, // BWT
const BitPairReference& ref, // Reference strings
RandomSource& rnd, // pseudo-random generator
WalkMetrics& wlm, // group walk left metrics
SwMetrics& swmSeed, // metrics for seed extensions
size_t& nelt_out, // out: # elements total
size_t maxelts, // max # elts to report
bool all); // report all hits?
void extend(
const Read& rd, // read
const Ebwt& ebwtFw, // Forward Bowtie index
const Ebwt* ebwtBw, // Backward Bowtie index
TIndexOffU topf, // top in fw index
TIndexOffU botf, // bot in fw index
TIndexOffU topb, // top in bw index
TIndexOffU botb, // bot in bw index
bool fw, // seed orientation
size_t off, // seed offset from 5' end
size_t len, // seed length
PerReadMetrics& prm, // per-read metrics
size_t& nlex, // # positions we can extend to left w/o edit
size_t& nrex); // # positions we can extend to right w/o edit
void prioritizeSATups(
const Read& rd, // read
SeedResults& sh, // seed hits to extend into full alignments
const Ebwt& ebwtFw, // BWT
const Ebwt* ebwtBw, // BWT'
const BitPairReference& ref, // Reference strings
int seedmms, // # seed mismatches allowed
size_t maxelt, // max elts we'll consider
bool doExtend, // extend out seeds
bool lensq, // square extended length
bool szsq, // square SA range size
size_t nsm, // if range as <= nsm elts, it's "small"
AlignmentCacheIface& ca, // alignment cache for seed hits
RandomSource& rnd, // pseudo-random generator
WalkMetrics& wlm, // group walk left metrics
PerReadMetrics& prm, // per-read metrics
size_t& nelt_out, // out: # elements total
bool all); // report all hits?
Random1toN rand_; // random number generators
EList<Random1toN, 16> rands_; // random number generators
EList<Random1toN, 16> rands2_; // random number generators
EList<EEHit, 16> eehits_; // holds end-to-end hits
EList<SATupleAndPos, 16> satpos_; // holds SATuple, SeedPos pairs
EList<SATupleAndPos, 16> satpos2_; // holds SATuple, SeedPos pairs
EList<SATuple, 16> satups_; // holds SATuples to explore elements from
EList<GroupWalk2S<TSlice, 16> > gws_; // list of GroupWalks; no particular order
EList<size_t> mateStreaks_; // mate-find fail streaks
RowSampler rowsamp_; // row sampler
// Ranges that we've extended through when extending seed hits
EList<ExtendRange> seedExRangeFw_[2];
EList<ExtendRange> seedExRangeRc_[2];
// Data structures encapsulating the diagonals that have already been used
// to seed alignment for mate 1 and mate 2.
EIvalMergeListBinned seenDiags1_;
EIvalMergeListBinned seenDiags2_;
// For weeding out redundant alignments
RedundantAlns redAnchor_; // database of cells used for anchor alignments
RedundantAlns redMate1_; // database of cells used for mate 1 alignments
RedundantAlns redMate2_; // database of cells used for mate 2 alignments
// For holding results for anchor (res_) and opposite (ores_) mates
SwResult resGap_; // temp holder for alignment result
SwResult oresGap_; // temp holder for alignment result, opp mate
SwResult resUngap_; // temp holder for ungapped alignment result
SwResult oresUngap_; // temp holder for ungap. aln. opp mate
SwResult resEe_; // temp holder for ungapped alignment result
SwResult oresEe_; // temp holder for ungap. aln. opp mate
Pool pool_; // memory pages for salistExact_
TSAList salistEe_; // PList for offsets for end-to-end hits
GroupWalkState gwstate_; // some per-thread state shared by all GroupWalks
// 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_);
};
#endif /*ALIGNER_SW_DRIVER_H_*/