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bt2_io.h
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bt2_io.h
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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/>.
*/
#ifndef EBWT_IO_H_
#define EBWT_IO_H_
#include <string>
#include <stdexcept>
#include <iostream>
#include <fstream>
#include <stdlib.h>
#include "bt2_idx.h"
using namespace std;
///////////////////////////////////////////////////////////////////////
//
// Functions for reading and writing Ebwts
//
///////////////////////////////////////////////////////////////////////
/**
* Read an Ebwt from file with given filename.
*/
template <typename index_t>
void Ebwt<index_t>::readIntoMemory(
int color,
int needEntireRev,
bool loadSASamp,
bool loadFtab,
bool loadRstarts,
bool justHeader,
EbwtParams<index_t> *params,
bool mmSweep,
bool loadNames,
bool startVerbose)
{
bool switchEndian; // dummy; caller doesn't care
#ifdef BOWTIE_MM
char *mmFile[] = { NULL, NULL };
#endif
if(_in1Str.length() > 0) {
if(_verbose || startVerbose) {
cerr << " About to open input files: ";
logTime(cerr);
}
// Initialize our primary and secondary input-stream fields
if(_in1 != NULL) fclose(_in1);
if(_verbose || startVerbose) cerr << "Opening \"" << _in1Str.c_str() << "\"" << endl;
if((_in1 = fopen(_in1Str.c_str(), "rb")) == NULL) {
cerr << "Could not open index file " << _in1Str.c_str() << endl;
}
if(loadSASamp) {
if(_in2 != NULL) fclose(_in2);
if(_verbose || startVerbose) cerr << "Opening \"" << _in2Str.c_str() << "\"" << endl;
if((_in2 = fopen(_in2Str.c_str(), "rb")) == NULL) {
cerr << "Could not open index file " << _in2Str.c_str() << endl;
}
}
if(_verbose || startVerbose) {
cerr << " Finished opening input files: ";
logTime(cerr);
}
#ifdef BOWTIE_MM
if(_useMm /*&& !justHeader*/) {
const char *names[] = {_in1Str.c_str(), _in2Str.c_str()};
int fds[] = { fileno(_in1), fileno(_in2) };
for(int i = 0; i < (loadSASamp ? 2 : 1); i++) {
if(_verbose || startVerbose) {
cerr << " Memory-mapping input file " << (i+1) << ": ";
logTime(cerr);
}
struct stat sbuf;
if (stat(names[i], &sbuf) == -1) {
perror("stat");
cerr << "Error: Could not stat index file " << names[i] << " prior to memory-mapping" << endl;
throw 1;
}
mmFile[i] = (char*)mmap((void *)0, (size_t)sbuf.st_size,
PROT_READ, MAP_SHARED, fds[(size_t)i], 0);
if(mmFile[i] == (void *)(-1)) {
perror("mmap");
cerr << "Error: Could not memory-map the index file " << names[i] << endl;
throw 1;
}
if(mmSweep) {
int sum = 0;
for(off_t j = 0; j < sbuf.st_size; j += 1024) {
sum += (int) mmFile[i][j];
}
if(startVerbose) {
cerr << " Swept the memory-mapped ebwt index file 1; checksum: " << sum << ": ";
logTime(cerr);
}
}
}
mmFile1_ = mmFile[0];
mmFile2_ = loadSASamp ? mmFile[1] : NULL;
}
#endif
}
#ifdef BOWTIE_MM
else if(_useMm && !justHeader) {
mmFile[0] = mmFile1_;
mmFile[1] = mmFile2_;
}
if(_useMm && !justHeader) {
assert(mmFile[0] == mmFile1_);
assert(mmFile[1] == mmFile2_);
}
#endif
if(_verbose || startVerbose) {
cerr << " Reading header: ";
logTime(cerr);
}
// Read endianness hints from both streams
size_t bytesRead = 0;
switchEndian = false;
uint32_t one = readU32(_in1, switchEndian); // 1st word of primary stream
bytesRead += 4;
if(loadSASamp) {
#ifndef NDEBUG
assert_eq(one, readU32(_in2, switchEndian)); // should match!
#else
readU32(_in2, switchEndian);
#endif
}
if(one != 1) {
assert_eq((1u<<24), one);
assert_eq(1, endianSwapU32(one));
switchEndian = true;
}
// Can't switch endianness and use memory-mapped files; in order to
// support this, someone has to modify the file to switch
// endiannesses appropriately, and we can't do this inside Bowtie
// or we might be setting up a race condition with other processes.
if(switchEndian && _useMm) {
cerr << "Error: Can't use memory-mapped files when the index is the opposite endianness" << endl;
throw 1;
}
// Reads header entries one by one from primary stream
index_t len = readIndex<index_t>(_in1, switchEndian);
bytesRead += sizeof(index_t);
int32_t lineRate = readI32(_in1, switchEndian);
bytesRead += 4;
/*int32_t linesPerSide =*/ readI32(_in1, switchEndian);
bytesRead += 4;
int32_t offRate = readI32(_in1, switchEndian);
bytesRead += 4;
// TODO: add isaRate to the actual file format (right now, the
// user has to tell us whether there's an ISA sample and what the
// sampling rate is.
int32_t ftabChars = readI32(_in1, switchEndian);
bytesRead += 4;
// chunkRate was deprecated in an earlier version of Bowtie; now
// we use it to hold flags.
int32_t flags = readI32(_in1, switchEndian);
bool entireRev = false;
if(flags < 0 && (((-flags) & EBWT_COLOR) != 0)) {
if(color != -1 && !color) {
cerr << "Error: -C was not specified when running bowtie, but index is in colorspace. If" << endl
<< "your reads are in colorspace, please use the -C option. If your reads are not" << endl
<< "in colorspace, please use a normal index (one built without specifying -C to" << endl
<< "bowtie-build)." << endl;
throw 1;
}
color = 1;
} else if(flags < 0) {
if(color != -1 && color) {
cerr << "Error: -C was specified when running bowtie, but index is not in colorspace. If" << endl
<< "your reads are in colorspace, please use a colorspace index (one built using" << endl
<< "bowtie-build -C). If your reads are not in colorspace, don't specify -C when" << endl
<< "running bowtie." << endl;
throw 1;
}
color = 0;
}
if(flags < 0 && (((-flags) & EBWT_ENTIRE_REV) == 0)) {
if(needEntireRev != -1 && needEntireRev != 0) {
cerr << "Error: This index is compatible with 0.* versions of Bowtie, but not with 2.*" << endl
<< "versions. Please build or download a version of the index that is compitble" << endl
<< "with Bowtie 2.* (i.e. built with bowtie-build 2.* or later)" << endl;
throw 1;
}
} else entireRev = true;
bytesRead += 4;
// Create a new EbwtParams from the entries read from primary stream
EbwtParams<index_t> *eh;
bool deleteEh = false;
if(params != NULL) {
params->init(len, lineRate, offRate, ftabChars, color, entireRev);
if(_verbose || startVerbose) params->print(cerr);
eh = params;
} else {
eh = new EbwtParams<index_t>(len, lineRate, offRate, ftabChars, color, entireRev);
deleteEh = true;
}
// Set up overridden suffix-array-sample parameters
index_t offsLen = eh->_offsLen;
// uint64_t offsSz = eh->_offsSz;
index_t offRateDiff = 0;
index_t offsLenSampled = offsLen;
if(_overrideOffRate > offRate) {
offRateDiff = _overrideOffRate - offRate;
}
if(offRateDiff > 0) {
offsLenSampled >>= offRateDiff;
if((offsLen & ~((index_t)OFF_MASK << offRateDiff)) != 0) {
offsLenSampled++;
}
}
// Can't override the offrate or isarate and use memory-mapped
// files; ultimately, all processes need to copy the sparser sample
// into their own memory spaces.
if(_useMm && (offRateDiff)) {
cerr << "Error: Can't use memory-mapped files when the offrate is overridden" << endl;
throw 1;
}
// Read nPat from primary stream
this->_nPat = readIndex<index_t>(_in1, switchEndian);
bytesRead += sizeof(index_t);
_plen.reset();
// Read plen from primary stream
if(_useMm) {
#ifdef BOWTIE_MM
_plen.init((index_t*)(mmFile[0] + bytesRead), _nPat, false);
bytesRead += _nPat*sizeof(index_t);
fseek(_in1, _nPat*sizeof(index_t), SEEK_CUR);
#endif
} else {
try {
if(_verbose || startVerbose) {
cerr << "Reading plen (" << this->_nPat << "): ";
logTime(cerr);
}
_plen.init(new index_t[_nPat], _nPat, true);
if(switchEndian) {
for(index_t i = 0; i < this->_nPat; i++) {
plen()[i] = readIndex<index_t>(_in1, switchEndian);
}
} else {
size_t r = MM_READ(_in1, (void*)(plen()), _nPat*sizeof(index_t));
if(r != (size_t)(_nPat*sizeof(index_t))) {
cerr << "Error reading _plen[] array: " << r << ", " << _nPat*sizeof(index_t) << endl;
throw 1;
}
}
} catch(bad_alloc& e) {
cerr << "Out of memory allocating plen[] in Ebwt::read()"
<< " at " << __FILE__ << ":" << __LINE__ << endl;
throw e;
}
}
bool shmemLeader;
// TODO: I'm not consistent on what "header" means. Here I'm using
// "header" to mean everything that would exist in memory if we
// started to build the Ebwt but stopped short of the build*() step
// (i.e. everything up to and including join()).
if(justHeader) goto done;
this->_nFrag = readIndex<index_t>(_in1, switchEndian);
bytesRead += sizeof(index_t);
if(_verbose || startVerbose) {
cerr << "Reading rstarts (" << this->_nFrag*3 << "): ";
logTime(cerr);
}
assert_geq(this->_nFrag, this->_nPat);
_rstarts.reset();
if(loadRstarts) {
if(_useMm) {
#ifdef BOWTIE_MM
_rstarts.init((index_t*)(mmFile[0] + bytesRead), _nFrag*3, false);
bytesRead += this->_nFrag*sizeof(index_t)*3;
fseek(_in1, this->_nFrag*sizeof(index_t)*3, SEEK_CUR);
#endif
} else {
_rstarts.init(new index_t[_nFrag*3], _nFrag*3, true);
if(switchEndian) {
for(size_t i = 0; i < (size_t)(this->_nFrag*3); i += 3) {
// fragment starting position in joined reference
// string, text id, and fragment offset within text
this->rstarts()[i] = readIndex<index_t>(_in1, switchEndian);
this->rstarts()[i+1] = readIndex<index_t>(_in1, switchEndian);
this->rstarts()[i+2] = readIndex<index_t>(_in1, switchEndian);
}
} else {
size_t r = MM_READ(_in1, (void *)rstarts(), this->_nFrag*sizeof(index_t)*3);
if(r != (size_t)(this->_nFrag*sizeof(index_t)*3)) {
cerr << "Error reading _rstarts[] array: " << r << ", " << (this->_nFrag*sizeof(index_t)*3) << endl;
throw 1;
}
}
}
} else {
// Skip em
assert(rstarts() == NULL);
bytesRead += this->_nFrag*sizeof(index_t)*3;
fseek(_in1, this->_nFrag*sizeof(index_t)*3, SEEK_CUR);
}
_ebwt.reset();
if(_useMm) {
#ifdef BOWTIE_MM
_ebwt.init((uint8_t*)(mmFile[0] + bytesRead), eh->_ebwtTotLen, false);
bytesRead += eh->_ebwtTotLen;
fseek(_in1, eh->_ebwtTotLen, SEEK_CUR);
#endif
} else {
// Allocate ebwt (big allocation)
if(_verbose || startVerbose) {
cerr << "Reading ebwt (" << eh->_ebwtTotLen << "): ";
logTime(cerr);
}
bool shmemLeader = true;
if(useShmem_) {
uint8_t *tmp = NULL;
shmemLeader = ALLOC_SHARED_U8(
(_in1Str + "[ebwt]"), eh->_ebwtTotLen, &tmp,
"ebwt[]", (_verbose || startVerbose));
assert(tmp != NULL);
_ebwt.init(tmp, eh->_ebwtTotLen, false);
if(_verbose || startVerbose) {
cerr << " shared-mem " << (shmemLeader ? "leader" : "follower") << endl;
}
} else {
try {
_ebwt.init(new uint8_t[eh->_ebwtTotLen], eh->_ebwtTotLen, true);
} catch(bad_alloc& e) {
cerr << "Out of memory allocating the ebwt[] array for the Bowtie index. Please try" << endl
<< "again on a computer with more memory." << endl;
throw 1;
}
}
if(shmemLeader) {
// Read ebwt from primary stream
uint64_t bytesLeft = eh->_ebwtTotLen;
char *pebwt = (char*)this->ebwt();
while (bytesLeft>0){
size_t r = MM_READ(this->_in1, (void *)pebwt, bytesLeft);
if(MM_IS_IO_ERR(this->_in1, r, bytesLeft)) {
cerr << "Error reading _ebwt[] array: " << r << ", "
<< bytesLeft << endl;
throw 1;
}
pebwt += r;
bytesLeft -= r;
}
if(switchEndian) {
uint8_t *side = this->ebwt();
for(size_t i = 0; i < eh->_numSides; i++) {
index_t *cums = reinterpret_cast<index_t*>(side + eh->_sideSz - sizeof(index_t)*2);
cums[0] = endianSwapIndex(cums[0]);
cums[1] = endianSwapIndex(cums[1]);
side += this->_eh._sideSz;
}
}
#ifdef BOWTIE_SHARED_MEM
if(useShmem_) NOTIFY_SHARED(ebwt(), eh->_ebwtTotLen);
#endif
} else {
// Seek past the data and wait until master is finished
fseek(_in1, eh->_ebwtTotLen, SEEK_CUR);
#ifdef BOWTIE_SHARED_MEM
if(useShmem_) WAIT_SHARED(ebwt(), eh->_ebwtTotLen);
#endif
}
}
// Read zOff from primary stream
_zOff = readIndex<index_t>(_in1, switchEndian);
bytesRead += sizeof(index_t);
assert_lt(_zOff, len);
try {
// Read fchr from primary stream
if(_verbose || startVerbose) cerr << "Reading fchr (5)" << endl;
_fchr.reset();
if(_useMm) {
#ifdef BOWTIE_MM
_fchr.init((index_t*)(mmFile[0] + bytesRead), 5, false);
bytesRead += 5*sizeof(index_t);
fseek(_in1, 5*sizeof(index_t), SEEK_CUR);
#endif
} else {
_fchr.init(new index_t[5], 5, true);
for(int i = 0; i < 5; i++) {
this->fchr()[i] = readIndex<index_t>(_in1, switchEndian);
assert_leq(this->fchr()[i], len);
assert(i <= 0 || this->fchr()[i] >= this->fchr()[i-1]);
}
}
assert_gt(this->fchr()[4], this->fchr()[0]);
// Read ftab from primary stream
if(_verbose || startVerbose) {
if(loadFtab) {
cerr << "Reading ftab (" << eh->_ftabLen << "): ";
logTime(cerr);
} else {
cerr << "Skipping ftab (" << eh->_ftabLen << "): ";
}
}
_ftab.reset();
if(loadFtab) {
if(_useMm) {
#ifdef BOWTIE_MM
_ftab.init((index_t*)(mmFile[0] + bytesRead), eh->_ftabLen, false);
bytesRead += eh->_ftabLen*sizeof(index_t);
fseek(_in1, eh->_ftabLen*sizeof(index_t), SEEK_CUR);
#endif
} else {
_ftab.init(new index_t[eh->_ftabLen], eh->_ftabLen, true);
if(switchEndian) {
for(size_t i = 0; i < eh->_ftabLen; i++)
this->ftab()[i] = readIndex<index_t>(_in1, switchEndian);
} else {
size_t r = MM_READ(_in1, (void *)ftab(), eh->_ftabLen*sizeof(index_t));
if(r != (size_t)(eh->_ftabLen*sizeof(index_t))) {
cerr << "Error reading _ftab[] array: " << r << ", " << (eh->_ftabLen*sizeof(index_t)) << endl;
throw 1;
}
}
}
// Read etab from primary stream
if(_verbose || startVerbose) {
if(loadFtab) {
cerr << "Reading eftab (" << eh->_eftabLen << "): ";
logTime(cerr);
} else {
cerr << "Skipping eftab (" << eh->_eftabLen << "): ";
}
}
_eftab.reset();
if(_useMm) {
#ifdef BOWTIE_MM
_eftab.init((index_t*)(mmFile[0] + bytesRead), eh->_eftabLen, false);
bytesRead += eh->_eftabLen*sizeof(index_t);
fseek(_in1, eh->_eftabLen*sizeof(index_t), SEEK_CUR);
#endif
} else {
_eftab.init(new index_t[eh->_eftabLen], eh->_eftabLen, true);
if(switchEndian) {
for(size_t i = 0; i < eh->_eftabLen; i++)
this->eftab()[i] = readIndex<index_t>(_in1, switchEndian);
} else {
size_t r = MM_READ(_in1, (void *)this->eftab(), eh->_eftabLen*sizeof(index_t));
if(r != (size_t)(eh->_eftabLen*sizeof(index_t))) {
cerr << "Error reading _eftab[] array: " << r << ", " << (eh->_eftabLen*sizeof(index_t)) << endl;
throw 1;
}
}
}
for(index_t i = 0; i < eh->_eftabLen; i++) {
if(i > 0 && this->eftab()[i] > 0) {
assert_geq(this->eftab()[i], this->eftab()[i-1]);
} else if(i > 0 && this->eftab()[i-1] == 0) {
assert_eq(0, this->eftab()[i]);
}
}
} else {
assert(ftab() == NULL);
assert(eftab() == NULL);
// Skip ftab
bytesRead += eh->_ftabLen*sizeof(index_t);
fseek(_in1, eh->_ftabLen*sizeof(index_t), SEEK_CUR);
// Skip eftab
bytesRead += eh->_eftabLen*sizeof(index_t);
fseek(_in1, eh->_eftabLen*sizeof(index_t), SEEK_CUR);
}
} catch(bad_alloc& e) {
cerr << "Out of memory allocating fchr[], ftab[] or eftab[] arrays for the Bowtie index." << endl
<< "Please try again on a computer with more memory." << endl;
throw 1;
}
// Read reference sequence names from primary index file (or not,
// if --refidx is specified)
if(loadNames) {
while(true) {
char c = '\0';
if(MM_READ(_in1, (void *)(&c), (size_t)1) != (size_t)1) break;
bytesRead++;
if(c == '\0') break;
else if(c == '\n') {
this->_refnames.push_back("");
} else {
if(this->_refnames.size() == 0) {
this->_refnames.push_back("");
}
this->_refnames.back().push_back(c);
}
}
}
_offs.reset();
if(loadSASamp) {
bytesRead = 4; // reset for secondary index file (already read 1-sentinel)
shmemLeader = true;
if(_verbose || startVerbose) {
cerr << "Reading offs (" << offsLenSampled << " " << std::setw(2) << sizeof(index_t)*8 << "-bit words): ";
logTime(cerr);
}
if(!_useMm) {
if(!useShmem_) {
// Allocate offs_
try {
#ifdef HISAT_CLASS
_offs.init(new uint16_t[offsLenSampled], offsLenSampled, true);
#else
_offs.init(new index_t[offsLenSampled], offsLenSampled, true);
#endif
} catch(bad_alloc& e) {
cerr << "Out of memory allocating the offs[] array for the Bowtie index." << endl
<< "Please try again on a computer with more memory." << endl;
throw 1;
}
} else {
#ifdef HISAT_CLASS
uint16_t *tmp = NULL;
shmemLeader = ALLOC_SHARED_U32(
(_in2Str + "[offs]"), offsLenSampled*sizeof(uint16_t), &tmp,
"offs", (_verbose || startVerbose));
_offs.init((uint16_t*)tmp, offsLenSampled, false);
#else
index_t *tmp = NULL;
shmemLeader = ALLOC_SHARED_U32(
(_in2Str + "[offs]"), offsLenSampled*sizeof(index_t), &tmp,
"offs", (_verbose || startVerbose));
_offs.init((index_t*)tmp, offsLenSampled, false);
#endif
}
}
if(_overrideOffRate < 32) {
if(shmemLeader) {
// Allocate offs (big allocation)
if(switchEndian || offRateDiff > 0) {
assert(!_useMm);
const index_t blockMaxSz = (index_t)(2 * 1024 * 1024); // 2 MB block size
#ifdef HISAT_CLASS
const index_t blockMaxSzU = (blockMaxSz / sizeof(uint16_t)); // # U32s per block
#else
const index_t blockMaxSzU = (blockMaxSz / sizeof(index_t)); // # U32s per block
#endif
char *buf;
try {
buf = new char[blockMaxSz];
} catch(std::bad_alloc& e) {
cerr << "Error: Out of memory allocating part of _offs array: '" << e.what() << "'" << endl;
throw e;
}
for(index_t i = 0; i < offsLen; i += blockMaxSzU) {
index_t block = min<index_t>((index_t)blockMaxSzU, (index_t)(offsLen - i));
#ifdef HISAT_CLASS
size_t r = MM_READ(_in2, (void *)buf, block * sizeof(uint16_t));
if(r != (size_t)(block * sizeof(uint16_t))) {
cerr << "Error reading block of _offs[] array: " << r << ", " << (block * sizeof(uint16_t)) << endl;
throw 1;
}
index_t idx = i >> 1;
for(index_t j = 0; j < block; j += 2) {
assert_lt(idx, offsLenSampled);
this->offs()[idx] = ((uint16_t*)buf)[j];
if(switchEndian) {
this->offs()[idx] = endianSwapIndex((uint16_t)this->offs()[idx]);
}
idx++;
}
#else
size_t r = MM_READ(_in2, (void *)buf, block * sizeof(index_t));
if(r != (size_t)(block * sizeof(index_t))) {
cerr << "Error reading block of _offs[] array: " << r << ", " << (block * sizeof(index_t)) << endl;
throw 1;
}
index_t idx = i >> offRateDiff;
for(index_t j = 0; j < block; j += (1 << offRateDiff)) {
assert_lt(idx, offsLenSampled);
this->offs()[idx] = ((index_t*)buf)[j];
if(switchEndian) {
this->offs()[idx] = endianSwapIndex(this->offs()[idx]);
}
idx++;
}
#endif
}
delete[] buf;
} else {
if(_useMm) {
#ifdef BOWTIE_MM
# ifdef HISAT_CLASS
# else
_offs.init((index_t*)(mmFile[1] + bytesRead), offsLen, false);
bytesRead += (offsLen * sizeof(index_t));
fseek(_in2, (offsLen * sizeof(index_t)), SEEK_CUR);
# endif
#endif
} else {
// Workaround for small-index mode where MM_READ may
// not be able to handle read amounts greater than 2^32
// bytes.
#ifdef HISAT_CLASS
uint64_t bytesLeft = (offsLen * sizeof(uint16_t));
#else
uint64_t bytesLeft = (offsLen * sizeof(index_t));
#endif
char *offs = (char *)this->offs();
while(bytesLeft > 0) {
size_t r = MM_READ(_in2, (void*)offs, bytesLeft);
if(MM_IS_IO_ERR(_in2,r,bytesLeft)) {
cerr << "Error reading block of _offs[] array: "
<< r << ", " << bytesLeft << gLastIOErrMsg << endl;
throw 1;
}
offs += r;
bytesLeft -= r;
}
}
}
#ifdef BOWTIE_SHARED_MEM
if(useShmem_) NOTIFY_SHARED(offs(), offsLenSampled*sizeof(index_t));
#endif
} else {
// Not the shmem leader
fseek(_in2, offsLenSampled*sizeof(index_t), SEEK_CUR);
#ifdef BOWTIE_SHARED_MEM
if(useShmem_) WAIT_SHARED(offs(), offsLenSampled*sizeof(index_t));
#endif
}
}
}
this->postReadInit(*eh); // Initialize fields of Ebwt not read from file
if(_verbose || startVerbose) print(cerr, *eh);
// The fact that _ebwt and friends actually point to something
// (other than NULL) now signals to other member functions that the
// Ebwt is loaded into memory.
done: // Exit hatch for both justHeader and !justHeader
// Be kind
if(deleteEh) delete eh;
#ifdef BOWTIE_MM
fseek(_in1, 0, SEEK_SET);
if(loadSASamp) fseek(_in2, 0, SEEK_SET);
#else
rewind(_in1);
if(loadSASamp) rewind(_in2);
#endif
}
/**
* Read reference names from an input stream 'in' for an Ebwt primary
* file and store them in 'refnames'.
*/
template <typename index_t>
void readEbwtRefnames(istream& in, EList<string>& refnames) {
// _in1 must already be open with the get cursor at the
// beginning and no error flags set.
assert(in.good());
assert_eq((streamoff)in.tellg(), ios::beg);
// Read endianness hints from both streams
bool switchEndian = false;
uint32_t one = readU32(in, switchEndian); // 1st word of primary stream
if(one != 1) {
assert_eq((1u<<24), one);
switchEndian = true;
}
// Reads header entries one by one from primary stream
index_t len = readIndex<index_t>(in, switchEndian);
int32_t lineRate = readI32(in, switchEndian);
/*int32_t linesPerSide =*/ readI32(in, switchEndian);
int32_t offRate = readI32(in, switchEndian);
int32_t ftabChars = readI32(in, switchEndian);
// BTL: chunkRate is now deprecated
int32_t flags = readI32(in, switchEndian);
bool color = false;
bool entireReverse = false;
if(flags < 0) {
color = (((-flags) & EBWT_COLOR) != 0);
entireReverse = (((-flags) & EBWT_ENTIRE_REV) != 0);
}
// Create a new EbwtParams from the entries read from primary stream
EbwtParams<index_t> eh(len, lineRate, offRate, ftabChars, color, entireReverse);
index_t nPat = readIndex<index_t>(in, switchEndian); // nPat
in.seekg(nPat*sizeof(index_t), ios_base::cur); // skip plen
// Skip rstarts
index_t nFrag = readIndex<index_t>(in, switchEndian);
in.seekg(nFrag*sizeof(index_t)*3, ios_base::cur);
// Skip ebwt
in.seekg(eh._ebwtTotLen, ios_base::cur);
// Skip zOff from primary stream
readIndex<index_t>(in, switchEndian);
// Skip fchr
in.seekg(5 * sizeof(index_t), ios_base::cur);
// Skip ftab
in.seekg(eh._ftabLen*sizeof(index_t), ios_base::cur);
// Skip eftab
in.seekg(eh._eftabLen*sizeof(index_t), ios_base::cur);
// Read reference sequence names from primary index file
while(true) {
char c = '\0';
in.read(&c, 1);
if(in.eof()) break;
if(c == '\0') break;
else if(c == '\n') {
refnames.push_back("");
} else {
if(refnames.size() == 0) {
refnames.push_back("");
}
refnames.back().push_back(c);
}
}
if(refnames.back().empty()) {
refnames.pop_back();
}
// Be kind
in.clear(); in.seekg(0, ios::beg);
assert(in.good());
}
/**
* Read reference names from the index with basename 'in' and store
* them in 'refnames'.
*/
template <typename index_t>
void readEbwtRefnames(const string& instr, EList<string>& refnames) {
ifstream in;
// Initialize our primary and secondary input-stream fields
in.open((instr + ".1." + gEbwt_ext).c_str(), ios_base::in | ios::binary);
if(!in.is_open()) {
throw EbwtFileOpenException("Cannot open file " + instr);
}
assert(in.is_open());
assert(in.good());
assert_eq((streamoff)in.tellg(), ios::beg);
readEbwtRefnames<index_t>(in, refnames);
}
/**
* Read just enough of the Ebwt's header to get its flags
*/
template <typename index_t>
int32_t Ebwt<index_t>::readFlags(const string& instr) {
ifstream in;
// Initialize our primary and secondary input-stream fields
in.open((instr + ".1." + gEbwt_ext).c_str(), ios_base::in | ios::binary);
if(!in.is_open()) {
throw EbwtFileOpenException("Cannot open file " + instr);
}
assert(in.is_open());
assert(in.good());
bool switchEndian = false;
uint32_t one = readU32(in, switchEndian); // 1st word of primary stream
if(one != 1) {
assert_eq((1u<<24), one);
assert_eq(1, endianSwapU32(one));
switchEndian = true;
}
readIndex<index_t>(in, switchEndian);
readI32(in, switchEndian);
readI32(in, switchEndian);
readI32(in, switchEndian);
readI32(in, switchEndian);
int32_t flags = readI32(in, switchEndian);
return flags;
}
/**
* Read just enough of the Ebwt's header to determine whether it's
* colorspace.
*/
bool
readEbwtColor(const string& instr) {
int32_t flags = Ebwt<>::readFlags(instr);
if(flags < 0 && (((-flags) & EBWT_COLOR) != 0)) {
return true;
} else {
return false;
}
}
/**
* Read just enough of the Ebwt's header to determine whether it's
* entirely reversed.
*/
bool
readEntireReverse(const string& instr) {
int32_t flags = Ebwt<>::readFlags(instr);
if(flags < 0 && (((-flags) & EBWT_ENTIRE_REV) != 0)) {
return true;
} else {
return false;
}
}
/**
* Write an extended Burrows-Wheeler transform to a pair of output
* streams.
*
* @param out1 output stream to primary file
* @param out2 output stream to secondary file
* @param be write in big endian?
*/
template <typename index_t>
void Ebwt<index_t>::writeFromMemory(bool justHeader,
ostream& out1,
ostream& out2) const
{
const EbwtParams<index_t>& eh = this->_eh;
assert(eh.repOk());
uint32_t be = this->toBe();
assert(out1.good());
assert(out2.good());
// When building an Ebwt, these header parameters are known
// "up-front", i.e., they can be written to disk immediately,
// before we join() or buildToDisk()
writeI32(out1, 1, be); // endian hint for priamry stream
writeI32(out2, 1, be); // endian hint for secondary stream
writeIndex<index_t>(out1, eh._len, be); // length of string (and bwt and suffix array)
writeI32(out1, eh._lineRate, be); // 2^lineRate = size in bytes of 1 line
writeI32(out1, 2, be); // not used
writeI32(out1, eh._offRate, be); // every 2^offRate chars is "marked"
writeI32(out1, eh._ftabChars, be); // number of 2-bit chars used to address ftab
int32_t flags = 1;
if(eh._color) flags |= EBWT_COLOR;
if(eh._entireReverse) flags |= EBWT_ENTIRE_REV;
writeI32(out1, -flags, be); // BTL: chunkRate is now deprecated
if(!justHeader) {
assert(rstarts() != NULL);
assert(offs() != NULL);
assert(ftab() != NULL);
assert(eftab() != NULL);
assert(isInMemory());
// These Ebwt parameters are known after the inputs strings have
// been joined() but before they have been built(). These can
// written to the disk next and then discarded from memory.
writeIndex<index_t>(out1, this->_nPat, be);
for(index_t i = 0; i < this->_nPat; i++)
writeIndex<index_t>(out1, this->plen()[i], be);
assert_geq(this->_nFrag, this->_nPat);
writeIndex<index_t>(out1, this->_nFrag, be);
for(size_t i = 0; i < this->_nFrag*3; i++)
writeIndex<index_t>(out1, this->rstarts()[i], be);
// These Ebwt parameters are discovered only as the Ebwt is being
// built (in buildToDisk()). Of these, only 'offs' and 'ebwt' are
// terribly large. 'ebwt' is written to the primary file and then
// discarded from memory as it is built; 'offs' is similarly
// written to the secondary file and discarded.
out1.write((const char *)this->ebwt(), eh._ebwtTotLen);
writeIndex<index_t>(out1, this->zOff(), be);
index_t offsLen = eh._offsLen;
for(index_t i = 0; i < offsLen; i++)
writeIndex<index_t>(out2, this->offs()[i], be);
// 'fchr', 'ftab' and 'eftab' are not fully determined until the
// loop is finished, so they are written to the primary file after
// all of 'ebwt' has already been written and only then discarded
// from memory.
for(int i = 0; i < 5; i++)
writeIndex<index_t>(out1, this->fchr()[i], be);
for(index_t i = 0; i < eh._ftabLen; i++)
writeIndex<index_t>(out1, this->ftab()[i], be);
for(index_t i = 0; i < eh._eftabLen; i++)
writeIndex<index_t>(out1, this->eftab()[i], be);
}
}
/**
* Given a pair of strings representing output filenames, and assuming
* this Ebwt object is currently in memory, write out this Ebwt to the
* specified files.
*
* If sanity-checking is enabled, then once the streams have been
* fully written and closed, we reopen them and read them into a
* (hopefully) exact copy of this Ebwt. We then assert that the
* current Ebwt and the copy match in all of their fields.
*/
template <typename index_t>
void Ebwt<index_t>::writeFromMemory(bool justHeader,
const string& out1,
const string& out2) const
{
ASSERT_ONLY(const EbwtParams<index_t>& eh = this->_eh);
assert(isInMemory());
assert(eh.repOk());
ofstream fout1(out1.c_str(), ios::binary);
ofstream fout2(out2.c_str(), ios::binary);
writeFromMemory(justHeader, fout1, fout2);
fout1.close();
fout2.close();
// Read the file back in and assert that all components match
if(_sanity) {
#if 0
if(_verbose)
cout << "Re-reading \"" << out1 << "\"/\"" << out2 << "\" for sanity check" << endl;
Ebwt copy(out1, out2, _verbose, _sanity);
assert(!isInMemory());
copy.loadIntoMemory(eh._color ? 1 : 0, true, false, false);
assert(isInMemory());
assert_eq(eh._lineRate, copy.eh()._lineRate);
assert_eq(eh._offRate, copy.eh()._offRate);
assert_eq(eh._ftabChars, copy.eh()._ftabChars);
assert_eq(eh._len, copy.eh()._len);
assert_eq(_zOff, copy.zOff());
assert_eq(_zEbwtBpOff, copy.zEbwtBpOff());
assert_eq(_zEbwtByteOff, copy.zEbwtByteOff());
assert_eq(_nPat, copy.nPat());
for(index_t i = 0; i < _nPat; i++)
assert_eq(this->_plen[i], copy.plen()[i]);
assert_eq(this->_nFrag, copy.nFrag());
for(size_t i = 0; i < this->nFrag*3; i++) {
assert_eq(this->_rstarts[i], copy.rstarts()[i]);
}
for(index_t i = 0; i < 5; i++)
assert_eq(this->_fchr[i], copy.fchr()[i]);
for(size_t i = 0; i < eh._ftabLen; i++)
assert_eq(this->ftab()[i], copy.ftab()[i]);
for(size_t i = 0; i < eh._eftabLen; i++)
assert_eq(this->eftab()[i], copy.eftab()[i]);
for(index_t i = 0; i < eh._offsLen; i++)
assert_eq(this->_offs[i], copy.offs()[i]);
for(index_t i = 0; i < eh._ebwtTotLen; i++)
assert_eq(this->ebwt()[i], copy.ebwt()[i]);
copy.sanityCheckAll();
if(_verbose)
cout << "Read-in check passed for \"" << out1 << "\"/\"" << out2 << "\"" << endl;
#endif
}
}
/**
* Write the rstarts array given the szs array for the reference.
*/
template <typename index_t>
void Ebwt<index_t>::szsToDisk(const EList<RefRecord>& szs, ostream& os, int reverse) {
#ifdef HISAT_CLASS
if(rstarts() == NULL) {
_rstarts.init(new index_t[this->_nFrag*3], this->_nFrag*3, true);
}
#endif
size_t seq = 0;
index_t off = 0;
index_t totlen = 0;
for(size_t i = 0; i < szs.size(); i++) {
if(szs[i].len == 0) continue;
if(szs[i].first) off = 0;
off += szs[i].off;
if(szs[i].first && szs[i].len > 0) seq++;
index_t seqm1 = seq-1;
assert_lt(seqm1, _nPat);