DiskLoc _repairExtent( Database* db , string ns, bool forward , DiskLoc eLoc ){
LogIndentLevel lil;
if ( eLoc.getOfs() <= 0 ){
error() << "invalid extent ofs: " << eLoc.getOfs() << endl;
return DiskLoc();
}
MongoDataFile * mdf = db->getFile( eLoc.a() );
Extent * e = mdf->debug_getExtent( eLoc );
if ( ! e->isOk() ){
warning() << "Extent not ok magic: " << e->magic << " going to try to continue" << endl;
}
log() << "length:" << e->length << endl;
LogIndentLevel lil2;
DiskLoc loc = forward ? e->firstRecord : e->lastRecord;
while ( ! loc.isNull() ){
if ( loc.getOfs() <= 0 ){
error() << "offset is 0 for record which should be impossible" << endl;
break;
}
log() << loc << endl;
Record* rec = loc.rec();
log() << loc.obj() << endl;
loc = forward ? rec->getNext( loc ) : rec->getPrev( loc );
}
return forward ? e->xnext : e->xprev;
}
/**
* analyzeDiskStorage helper which processes a single record.
*/
void processDeletedRecord(const DiskLoc& dl, const DeletedRecord* dr, const Extent* ex,
const AnalyzeParams& params, int bucketNum,
vector<DiskStorageData>& sliceData,
BSONArrayBuilder* deletedRecordsArrayBuilder) {
killCurrentOp.checkForInterrupt();
int extentOfs = ex->myLoc.getOfs();
if (! (dl.a() == ex->myLoc.a() &&
dl.getOfs() + dr->lengthWithHeaders() > extentOfs &&
dl.getOfs() < extentOfs + ex->length) ) {
return;
}
RecPos pos = RecPos::from(dl.getOfs(), dr->lengthWithHeaders(), extentOfs, params);
bool spansRequestedArea = false;
for (RecPos::SliceIterator it = pos.iterateSlices(); !it.end(); ++it) {
DiskStorageData& slice = sliceData[it->sliceNum];
slice.freeRecords[bucketNum] += it->ratioHere;
spansRequestedArea = true;
}
if (deletedRecordsArrayBuilder != NULL && spansRequestedArea) {
BSONObjBuilder(deletedRecordsArrayBuilder->subobjStart())
.append("ofs", dl.getOfs() - extentOfs)
.append("recBytes", dr->lengthWithHeaders());
}
}
bool NamespaceDetails::inCapExtent( const DiskLoc &dl ) const {
invariant( !dl.isNull() );
if ( dl.a() != _capExtent.a() )
return false;
if ( dl.getOfs() < _capExtent.getOfs() )
return false;
const Extent* e = theCapExtent();
int end = _capExtent.getOfs() + e->length;
return dl.getOfs() <= end;
}
DiskLoc ExtentManager::_createExtentInFile( int fileNo, DataFile* f,
int size, int maxFileNoForQuota ) {
size = ExtentManager::quantizeExtentSize( size );
if ( maxFileNoForQuota > 0 && fileNo - 1 >= maxFileNoForQuota ) {
if ( cc().hasWrittenThisPass() ) {
warning() << "quota exceeded, but can't assert" << endl;
}
else {
_quotaExceeded();
}
}
massert( 10358, "bad new extent size", size >= Extent::minSize() && size <= Extent::maxSize() );
DiskLoc loc = f->allocExtentArea( size );
loc.assertOk();
Extent *e = getExtent( loc, false );
verify( e );
getDur().writing(e)->init("", size, fileNo, loc.getOfs(), false);
return loc;
}
DiskLoc NamespaceDetails::__capAlloc( int len ) {
DiskLoc prev = cappedLastDelRecLastExtent();
DiskLoc i = cappedFirstDeletedInCurExtent();
DiskLoc ret;
for (; !i.isNull() && inCapExtent( i ); prev = i, i = i.drec()->nextDeleted() ) {
// We need to keep at least one DR per extent in cappedListOfAllDeletedRecords(),
// so make sure there's space to create a DR at the end.
if ( i.drec()->lengthWithHeaders() >= len + 24 ) {
ret = i;
break;
}
}
/* unlink ourself from the deleted list */
if ( !ret.isNull() ) {
if ( prev.isNull() )
cappedListOfAllDeletedRecords().writing() = ret.drec()->nextDeleted();
else
prev.drec()->nextDeleted().writing() = ret.drec()->nextDeleted();
ret.drec()->nextDeleted().writing().setInvalid(); // defensive.
verify( ret.drec()->extentOfs() < ret.getOfs() );
}
return ret;
}
// bypass standard alloc/insert routines to use the extent we want.
static DiskLoc insert( DiskLoc ext, int i ) {
BSONObjBuilder b;
b.append( "a", i );
BSONObj o = b.done();
int len = o.objsize();
Extent *e = ext.ext();
int ofs;
if ( e->lastRecord.isNull() )
ofs = ext.getOfs() + ( e->extentData - (char *)e );
else
ofs = e->lastRecord.getOfs() + e->lastRecord.rec()->lengthWithHeaders;
DiskLoc dl( ext.a(), ofs );
Record *r = dl.rec();
r->lengthWithHeaders = Record::HeaderSize + len;
r->extentOfs = e->myLoc.getOfs();
r->nextOfs = DiskLoc::NullOfs;
r->prevOfs = e->lastRecord.isNull() ? DiskLoc::NullOfs : e->lastRecord.getOfs();
memcpy( r->data, o.objdata(), len );
if ( e->firstRecord.isNull() )
e->firstRecord = dl;
else
e->lastRecord.rec()->nextOfs = ofs;
e->lastRecord = dl;
return dl;
}
Extent* ExtentManager::_createExtentInFile( int fileNo, DataFile* f,
const char* ns, int size, bool newCapped,
bool enforceQuota ) {
size = ExtentManager::quantizeExtentSize( size );
if ( enforceQuota ) {
if ( fileIndexExceedsQuota( ns, fileNo - 1 ) ) {
if ( cc().hasWrittenThisPass() ) {
warning() << "quota exceeded, but can't assert "
<< " going over quota for: " << ns << " " << fileNo << endl;
}
else {
_quotaExceeded();
}
}
}
massert( 10358, "bad new extent size", size >= Extent::minSize() && size <= Extent::maxSize() );
DiskLoc loc = f->allocExtentArea( size );
loc.assertOk();
Extent *e = getExtent( loc, false );
verify( e );
DiskLoc emptyLoc = getDur().writing(e)->init(ns, size, fileNo, loc.getOfs(), newCapped);
addNewExtentToNamespace(ns, e, loc, emptyLoc, newCapped);
LOG(1) << "ExtentManager: creating new extent for: " << ns << " in file: " << fileNo
<< " size: " << size << endl;
return e;
}
void touchNs( const std::string& ns ) {
std::vector< touch_location > ranges;
Client::ReadContext ctx(ns);
{
NamespaceDetails *nsd = nsdetails(ns.c_str());
uassert( 16154, "namespace does not exist", nsd );
for( DiskLoc L = nsd->firstExtent; !L.isNull(); L = L.ext()->xnext ) {
MongoDataFile* mdf = cc().database()->getFile( L.a() );
massert( 16238, "can't fetch extent file structure", mdf );
touch_location tl;
tl.fd = mdf->getFd();
tl.offset = L.getOfs();
tl.ext = L.ext();
tl.length = tl.ext->length;
ranges.push_back(tl);
}
}
LockMongoFilesShared lk;
Lock::TempRelease tr;
std::string progress_msg = "touch " + ns + " extents";
ProgressMeterHolder pm( cc().curop()->setMessage( progress_msg.c_str() , ranges.size() ) );
for ( std::vector< touch_location >::iterator it = ranges.begin(); it != ranges.end(); ++it ) {
touch_pages( it->fd, it->offset, it->length, it->ext );
pm.hit();
killCurrentOp.checkForInterrupt(false);
}
pm.finished();
}
/**
* analyzeDiskStorage helper which processes a single record.
*/
void processRecord(const DiskLoc& dl, const DiskLoc& prevDl, const Record* r, int extentOfs,
const AnalyzeParams& params, vector<DiskStorageData>& sliceData,
BSONArrayBuilder* recordsArrayBuilder) {
killCurrentOp.checkForInterrupt();
BSONObj obj = dl.obj();
int recBytes = r->lengthWithHeaders();
double characteristicFieldValue = 0;
bool hasCharacteristicField = extractCharacteristicFieldValue(obj, params,
characteristicFieldValue);
bool isLocatedBeforePrevious = dl.a() < prevDl.a();
RecPos pos = RecPos::from(dl.getOfs(), recBytes, extentOfs, params);
bool spansRequestedArea = false;
for (RecPos::SliceIterator it = pos.iterateSlices(); !it.end(); ++it) {
spansRequestedArea = true;
DiskStorageData& slice = sliceData[it->sliceNum];
slice.numEntries += it->ratioHere;
slice.recBytes += it->sizeHere;
slice.bsonBytes += static_cast<long long>(it->ratioHere * obj.objsize());
if (hasCharacteristicField) {
slice.characteristicCount += it->ratioHere;
slice.characteristicSum += it->ratioHere * characteristicFieldValue;
}
if (isLocatedBeforePrevious) {
slice.outOfOrderRecs += it->ratioHere;
}
}
if (recordsArrayBuilder != NULL && spansRequestedArea) {
DEV {
int startsAt = dl.getOfs() - extentOfs;
int endsAt = startsAt + recBytes;
verify((startsAt < params.startOfs && endsAt > params.startOfs) ||
(startsAt < params.endOfs && endsAt >= params.endOfs) ||
(startsAt >= params.startOfs && endsAt < params.endOfs));
}
BSONObjBuilder recordBuilder(recordsArrayBuilder->subobjStart());
recordBuilder.append("ofs", dl.getOfs() - extentOfs);
recordBuilder.append("recBytes", recBytes);
recordBuilder.append("bsonBytes", obj.objsize());
recordBuilder.append("_id", obj["_id"]);
if (hasCharacteristicField) {
recordBuilder.append("characteristic", characteristicFieldValue);
}
recordBuilder.doneFast();
}
/* combine adjacent deleted records *for the current extent* of the capped collection
this is O(n^2) but we call it for capped tables where typically n==1 or 2!
(or 3...there will be a little unused sliver at the end of the extent.)
*/
void NamespaceDetails::compact() {
DDD( "NamespaceDetails::compact enter" );
verify( isCapped() );
vector<DiskLoc> drecs;
// Pull out capExtent's DRs from deletedList
DiskLoc i = cappedFirstDeletedInCurExtent();
for (; !i.isNull() && inCapExtent( i ); i = i.drec()->nextDeleted() ) {
DDD( "\t" << i );
drecs.push_back( i );
}
getDur().writingDiskLoc( cappedFirstDeletedInCurExtent() ) = i;
std::sort( drecs.begin(), drecs.end() );
DDD( "\t drecs.size(): " << drecs.size() );
vector<DiskLoc>::const_iterator j = drecs.begin();
verify( j != drecs.end() );
DiskLoc a = *j;
while ( 1 ) {
j++;
if ( j == drecs.end() ) {
DDD( "\t compact adddelrec" );
addDeletedRec(a.drec(), a);
break;
}
DiskLoc b = *j;
while ( a.a() == b.a() && a.getOfs() + a.drec()->lengthWithHeaders() == b.getOfs() ) {
// a & b are adjacent. merge.
getDur().writingInt( a.drec()->lengthWithHeaders() ) += b.drec()->lengthWithHeaders();
j++;
if ( j == drecs.end() ) {
DDD( "\t compact adddelrec2" );
addDeletedRec(a.drec(), a);
return;
}
b = *j;
}
DDD( "\t compact adddelrec3" );
addDeletedRec(a.drec(), a);
a = b;
}
}
/* combine adjacent deleted records *for the current extent* of the capped collection
this is O(n^2) but we call it for capped tables where typically n==1 or 2!
(or 3...there will be a little unused sliver at the end of the extent.)
*/
void NamespaceDetails::compact() {
assert(capped);
list<DiskLoc> drecs;
// Pull out capExtent's DRs from deletedList
DiskLoc i = cappedFirstDeletedInCurExtent();
for (; !i.isNull() && inCapExtent( i ); i = i.drec()->nextDeleted )
drecs.push_back( i );
getDur().writingDiskLoc( cappedFirstDeletedInCurExtent() ) = i;
// This is the O(n^2) part.
drecs.sort();
list<DiskLoc>::iterator j = drecs.begin();
assert( j != drecs.end() );
DiskLoc a = *j;
while ( 1 ) {
j++;
if ( j == drecs.end() ) {
DEBUGGING out() << "TEMP: compact adddelrec\n";
addDeletedRec(a.drec(), a);
break;
}
DiskLoc b = *j;
while ( a.a() == b.a() && a.getOfs() + a.drec()->lengthWithHeaders == b.getOfs() ) {
// a & b are adjacent. merge.
getDur().writingInt( a.drec()->lengthWithHeaders ) += b.drec()->lengthWithHeaders;
j++;
if ( j == drecs.end() ) {
DEBUGGING out() << "temp: compact adddelrec2\n";
addDeletedRec(a.drec(), a);
return;
}
b = *j;
}
DEBUGGING out() << "temp: compact adddelrec3\n";
addDeletedRec(a.drec(), a);
a = b;
}
}
void DiskLoc56Bit::operator=(const DiskLoc& loc) {
ofs = loc.getOfs();
int la = loc.a();
invariant( la <= 0xffffff ); // must fit in 3 bytes
if( la < 0 ) {
if ( la != -1 ) {
log() << "btree diskloc isn't negative 1: " << la << std::endl;
invariant ( la == -1 );
}
la = 0;
ofs = OurNullOfs;
}
memcpy(_a, &la, 3); // endian
}
/** add a record to the end of the linked list chain within this extent.
require: you must have already declared write intent for the record header.
*/
void addRecordToRecListInExtent(Record *r, DiskLoc loc) {
dassert( loc.rec() == r );
Extent *e = r->myExtent(loc);
if ( e->lastRecord.isNull() ) {
Extent::FL *fl = getDur().writing(e->fl());
fl->firstRecord = fl->lastRecord = loc;
r->prevOfs() = r->nextOfs() = DiskLoc::NullOfs;
}
else {
Record *oldlast = e->lastRecord.rec();
r->prevOfs() = e->lastRecord.getOfs();
r->nextOfs() = DiskLoc::NullOfs;
getDur().writingInt(oldlast->nextOfs()) = loc.getOfs();
getDur().writingDiskLoc(e->lastRecord) = loc;
}
}
/* special version of insert for transaction logging -- streamlined a bit.
assumes ns is capped and no indexes
*/
Record* DataFileMgr::fast_oplog_insert(NamespaceDetails *d, const char *ns, int len) {
verify( d );
RARELY verify( d == nsdetails(ns) );
DEV verify( d == nsdetails(ns) );
massert( 16509,
str::stream()
<< "fast_oplog_insert requires a capped collection "
<< " but " << ns << " is not capped",
d->isCapped() );
//record timing on oplog inserts
boost::optional<TimerHolder> insertTimer;
//skip non-oplog collections
if (NamespaceString::oplog(ns)) {
insertTimer = boost::in_place(&oplogInsertStats);
oplogInsertBytesStats.increment(len); //record len of inserted records for oplog
}
int lenWHdr = len + Record::HeaderSize;
DiskLoc loc = d->alloc(ns, lenWHdr);
verify( !loc.isNull() );
Record *r = loc.rec();
verify( r->lengthWithHeaders() >= lenWHdr );
Extent *e = r->myExtent(loc);
if ( e->lastRecord.isNull() ) {
Extent::FL *fl = getDur().writing( e->fl() );
fl->firstRecord = fl->lastRecord = loc;
Record::NP *np = getDur().writing(r->np());
np->nextOfs = np->prevOfs = DiskLoc::NullOfs;
}
else {
Record *oldlast = e->lastRecord.rec();
Record::NP *np = getDur().writing(r->np());
np->prevOfs = e->lastRecord.getOfs();
np->nextOfs = DiskLoc::NullOfs;
getDur().writingInt( oldlast->nextOfs() ) = loc.getOfs();
e->lastRecord.writing() = loc;
}
d->incrementStats( r->netLength(), 1 );
return r;
}
void RecordStoreV1Base::_addRecordToRecListInExtent(OperationContext* txn,
Record *r,
DiskLoc loc) {
dassert( recordFor(loc) == r );
Extent *e = _getExtent( _getExtentLocForRecord( loc ) );
if ( e->lastRecord.isNull() ) {
*txn->recoveryUnit()->writing(&e->firstRecord) = loc;
*txn->recoveryUnit()->writing(&e->lastRecord) = loc;
r->prevOfs() = r->nextOfs() = DiskLoc::NullOfs;
}
else {
Record *oldlast = recordFor(e->lastRecord);
r->prevOfs() = e->lastRecord.getOfs();
r->nextOfs() = DiskLoc::NullOfs;
txn->recoveryUnit()->writingInt(oldlast->nextOfs()) = loc.getOfs();
*txn->recoveryUnit()->writing(&e->lastRecord) = loc;
}
}
void assertStateV1RS(const LocAndSize* records,
const LocAndSize* drecs,
const ExtentManager* em,
const DummyRecordStoreV1MetaData* md) {
invariant(records || drecs); // if both are NULL nothing is being asserted...
try {
if (records) {
long long dataSize = 0;
long long numRecs = 0;
int recIdx = 0;
DiskLoc extLoc = md->firstExtent();
while (!extLoc.isNull()) { // for each Extent
Extent* ext = em->getExtent(extLoc, true);
int expectedPrevOfs = DiskLoc::NullOfs;
DiskLoc actualLoc = ext->firstRecord;
while (!actualLoc.isNull()) { // for each Record in this Extent
const Record* actualRec = em->recordForV1(actualLoc);
const int actualSize = actualRec->lengthWithHeaders();
dataSize += actualSize - Record::HeaderSize;
numRecs += 1;
ASSERT_EQUALS(actualLoc, records[recIdx].loc);
ASSERT_EQUALS(actualSize, records[recIdx].size);
ASSERT_EQUALS(actualRec->extentOfs(), extLoc.getOfs());
ASSERT_EQUALS(actualRec->prevOfs(), expectedPrevOfs);
expectedPrevOfs = actualLoc.getOfs();
recIdx++;
const int nextOfs = actualRec->nextOfs();
actualLoc = (nextOfs == DiskLoc::NullOfs ? DiskLoc()
: DiskLoc(actualLoc.a(), nextOfs));
}
if (ext->xnext.isNull()) {
ASSERT_EQUALS(md->lastExtent(), extLoc);
}
extLoc = ext->xnext;
}
// both the expected and actual record lists must be done at this point
ASSERT_EQUALS(records[recIdx].loc, DiskLoc());
ASSERT_EQUALS(dataSize, md->dataSize());
ASSERT_EQUALS(numRecs, md->numRecords());
}
if (drecs) {
int drecIdx = 0;
for (int bucketIdx = 0; bucketIdx < RecordStoreV1Base::Buckets; bucketIdx++) {
DiskLoc actualLoc = md->deletedListEntry(bucketIdx);
if (md->isCapped() && bucketIdx == 1) {
// In capped collections, the 2nd bucket (index 1) points to the drec before
// the first drec in the capExtent. If the capExtent is the first Extent,
// it should be Null.
if (md->capExtent() == md->firstExtent()) {
ASSERT_EQUALS(actualLoc, DiskLoc());
}
else {
ASSERT_NOT_EQUALS(actualLoc.a(), md->capExtent().a());
const DeletedRecord* actualDrec =
&em->recordForV1(actualLoc)->asDeleted();
ASSERT_EQUALS(actualDrec->nextDeleted().a(), md->capExtent().a());
}
// Don't do normal checking of bucket 1 in capped collections. Checking
// other buckets to verify that they are Null.
continue;
}
while (!actualLoc.isNull()) {
const DeletedRecord* actualDrec = &em->recordForV1(actualLoc)->asDeleted();
const int actualSize = actualDrec->lengthWithHeaders();
ASSERT_EQUALS(actualLoc, drecs[drecIdx].loc);
ASSERT_EQUALS(actualSize, drecs[drecIdx].size);
// Make sure the drec is correct
ASSERT_EQUALS(actualDrec->extentOfs(), 0);
// in capped collections all drecs are linked into a single list in bucket 0
ASSERT_EQUALS(bucketIdx, md->isCapped()
? 0
: RecordStoreV1Base::bucket(actualSize));
drecIdx++;
actualLoc = actualDrec->nextDeleted();
}
}
// both the expected and actual deleted lists must be done at this point
ASSERT_EQUALS(drecs[drecIdx].loc, DiskLoc());
}
}
catch (...) {
// If a test fails, provide extra info to make debugging easier
printRecList(em, md);
printDRecList(em, md);
throw;
}
}
void initializeV1RS(OperationContext* txn,
const LocAndSize* records,
const LocAndSize* drecs,
DummyExtentManager* em,
DummyRecordStoreV1MetaData* md) {
invariant(records || drecs); // if both are NULL nothing is being created...
// Need to start with a blank slate
invariant(em->numFiles() == 0);
invariant(md->firstExtent().isNull());
// pre-allocate extents (even extents that aren't part of this RS)
{
typedef std::map<int, size_t> ExtentSizes;
ExtentSizes extentSizes;
accumulateExtentSizeRequirements(records, &extentSizes);
accumulateExtentSizeRequirements(drecs, &extentSizes);
invariant(!extentSizes.empty());
const int maxExtent = extentSizes.rbegin()->first;
for (int i = 0; i <= maxExtent; i++) {
const size_t size = extentSizes.count(i) ? extentSizes[i] : 0;
const DiskLoc loc = em->allocateExtent(txn, md->isCapped(), size, 0);
// This function and assertState depend on these details of DummyExtentManager
invariant(loc.a() == i);
invariant(loc.getOfs() == 0);
}
// link together extents that should be part of this RS
md->setFirstExtent(txn, DiskLoc(extentSizes.begin()->first, 0));
md->setLastExtent(txn, DiskLoc(extentSizes.rbegin()->first, 0));
for (ExtentSizes::iterator it = extentSizes.begin();
boost::next(it) != extentSizes.end(); /* ++it */ ) {
const int a = it->first;
++it;
const int b = it->first;
em->getExtent(DiskLoc(a, 0))->xnext = DiskLoc(b, 0);
em->getExtent(DiskLoc(b, 0))->xprev = DiskLoc(a, 0);
}
// This signals "done allocating new extents".
if (md->isCapped())
md->setDeletedListEntry(txn, 1, DiskLoc());
}
if (records && !records[0].loc.isNull()) {
int recIdx = 0;
DiskLoc extLoc = md->firstExtent();
while (!extLoc.isNull()) {
Extent* ext = em->getExtent(extLoc);
int prevOfs = DiskLoc::NullOfs;
while (extLoc.a() == records[recIdx].loc.a()) { // for all records in this extent
const DiskLoc loc = records[recIdx].loc;
const int size = records[recIdx].size;;
invariant(size >= Record::HeaderSize);
md->incrementStats(txn, size - Record::HeaderSize, 1);
if (ext->firstRecord.isNull())
ext->firstRecord = loc;
Record* rec = em->recordForV1(loc);
rec->lengthWithHeaders() = size;
rec->extentOfs() = 0;
rec->prevOfs() = prevOfs;
prevOfs = loc.getOfs();
const DiskLoc nextLoc = records[recIdx + 1].loc;
if (nextLoc.a() == loc.a()) { // if next is in same extent
rec->nextOfs() = nextLoc.getOfs();
}
else {
rec->nextOfs() = DiskLoc::NullOfs;
ext->lastRecord = loc;
}
recIdx++;
}
extLoc = ext->xnext;
}
invariant(records[recIdx].loc.isNull());
}
if (drecs && !drecs[0].loc.isNull()) {
int drecIdx = 0;
DiskLoc* prevNextPtr = NULL;
int lastBucket = -1;
while (!drecs[drecIdx].loc.isNull()) {
const DiskLoc loc = drecs[drecIdx].loc;
const int size = drecs[drecIdx].size;
invariant(size >= Record::HeaderSize);
const int bucket = RecordStoreV1Base::bucket(size);
if (md->isCapped()) {
// All drecs form a single list in bucket 0
if (prevNextPtr == NULL) {
md->setDeletedListEntry(txn, 0, loc);
}
else {
*prevNextPtr = loc;
}
if (loc.a() < md->capExtent().a()
&& drecs[drecIdx + 1].loc.a() == md->capExtent().a()) {
// Bucket 1 is known as cappedLastDelRecLastExtent
md->setDeletedListEntry(txn, 1, loc);
}
}
else if (bucket != lastBucket) {
invariant(bucket > lastBucket); // if this fails, drecs weren't sorted by bucket
md->setDeletedListEntry(txn, bucket, loc);
lastBucket = bucket;
}
else {
*prevNextPtr = loc;
}
DeletedRecord* drec = &em->recordForV1(loc)->asDeleted();
drec->lengthWithHeaders() = size;
drec->extentOfs() = 0;
drec->nextDeleted() = DiskLoc();
prevNextPtr = &drec->nextDeleted();
drecIdx++;
}
}
// Make sure we set everything up as requested.
assertStateV1RS(records, drecs, em, md);
}
DiskLoc SimpleRecordStoreV1::_allocFromExistingExtents(OperationContext* txn, int lenToAllocRaw) {
// Slowly drain the deletedListLegacyGrabBag by popping one record off and putting it in the
// correct deleted list each time we try to allocate a new record. This ensures we won't
// orphan any data when upgrading from old versions, without needing a long upgrade phase.
// This is done before we try to allocate the new record so we can take advantage of the new
// space immediately.
{
const DiskLoc head = _details->deletedListLegacyGrabBag();
if (!head.isNull()) {
_details->setDeletedListLegacyGrabBag(txn, drec(head)->nextDeleted());
addDeletedRec(txn, head);
}
}
// align size up to a multiple of 4
const int lenToAlloc = (lenToAllocRaw + (4 - 1)) & ~(4 - 1);
freelistAllocs.increment();
DiskLoc loc;
DeletedRecord* dr = NULL;
{
int myBucket;
for (myBucket = bucket(lenToAlloc); myBucket < Buckets; myBucket++) {
// Only look at the first entry in each bucket. This works because we are either
// quantizing or allocating fixed-size blocks.
const DiskLoc head = _details->deletedListEntry(myBucket);
if (head.isNull())
continue;
DeletedRecord* const candidate = drec(head);
if (candidate->lengthWithHeaders() >= lenToAlloc) {
loc = head;
dr = candidate;
break;
}
}
if (!dr)
return DiskLoc(); // no space
// Unlink ourself from the deleted list
_details->setDeletedListEntry(txn, myBucket, dr->nextDeleted());
*txn->recoveryUnit()->writing(&dr->nextDeleted()) = DiskLoc().setInvalid(); // defensive
}
invariant(dr->extentOfs() < loc.getOfs());
// Split the deleted record if it has at least as much left over space as our smallest
// allocation size. Otherwise, just take the whole DeletedRecord.
const int remainingLength = dr->lengthWithHeaders() - lenToAlloc;
if (remainingLength >= bucketSizes[0]) {
txn->recoveryUnit()->writingInt(dr->lengthWithHeaders()) = lenToAlloc;
const DiskLoc newDelLoc = DiskLoc(loc.a(), loc.getOfs() + lenToAlloc);
DeletedRecord* newDel = txn->recoveryUnit()->writing(drec(newDelLoc));
newDel->extentOfs() = dr->extentOfs();
newDel->lengthWithHeaders() = remainingLength;
newDel->nextDeleted().Null();
addDeletedRec(txn, newDelLoc);
}
return loc;
}
DiskLoc SimpleRecordStoreV1::_allocFromExistingExtents( OperationContext* txn,
int lenToAlloc ) {
// align size up to a multiple of 4
lenToAlloc = (lenToAlloc + (4-1)) & ~(4-1);
freelistAllocs.increment();
DiskLoc loc;
{
DiskLoc *prev = 0;
DiskLoc *bestprev = 0;
DiskLoc bestmatch;
int bestmatchlen = INT_MAX; // sentinel meaning we haven't found a record big enough
int b = bucket(lenToAlloc);
DiskLoc cur = _details->deletedListEntry(b);
int extra = 5; // look for a better fit, a little.
int chain = 0;
while ( 1 ) {
{ // defensive check
int fileNumber = cur.a();
int fileOffset = cur.getOfs();
if (fileNumber < -1 || fileNumber >= 100000 || fileOffset < 0) {
StringBuilder sb;
sb << "Deleted record list corrupted in collection " << _ns
<< ", bucket " << b
<< ", link number " << chain
<< ", invalid link is " << cur.toString()
<< ", throwing Fatal Assertion";
log() << sb.str() << endl;
fassertFailed(16469);
}
}
if ( cur.isNull() ) {
// move to next bucket. if we were doing "extra", just break
if ( bestmatchlen < INT_MAX )
break;
if ( chain > 0 ) {
// if we looked at things in the right bucket, but they were not suitable
freelistBucketExhausted.increment();
}
b++;
if ( b > MaxBucket ) {
// out of space. alloc a new extent.
freelistIterations.increment( 1 + chain );
return DiskLoc();
}
cur = _details->deletedListEntry(b);
prev = 0;
continue;
}
DeletedRecord *r = drec(cur);
if ( r->lengthWithHeaders() >= lenToAlloc &&
r->lengthWithHeaders() < bestmatchlen ) {
bestmatchlen = r->lengthWithHeaders();
bestmatch = cur;
bestprev = prev;
if (r->lengthWithHeaders() == lenToAlloc)
// exact match, stop searching
break;
}
if ( bestmatchlen < INT_MAX && --extra <= 0 )
break;
if ( ++chain > 30 && b <= MaxBucket ) {
// too slow, force move to next bucket to grab a big chunk
//b++;
freelistIterations.increment( chain );
chain = 0;
cur.Null();
}
else {
cur = r->nextDeleted();
prev = &r->nextDeleted();
}
}
// unlink ourself from the deleted list
DeletedRecord *bmr = drec(bestmatch);
if ( bestprev ) {
*txn->recoveryUnit()->writing(bestprev) = bmr->nextDeleted();
}
else {
// should be the front of a free-list
int myBucket = bucket(bmr->lengthWithHeaders());
invariant( _details->deletedListEntry(myBucket) == bestmatch );
_details->setDeletedListEntry(txn, myBucket, bmr->nextDeleted());
}
*txn->recoveryUnit()->writing(&bmr->nextDeleted()) = DiskLoc().setInvalid(); // defensive.
invariant(bmr->extentOfs() < bestmatch.getOfs());
freelistIterations.increment( 1 + chain );
loc = bestmatch;
}
if ( loc.isNull() )
return loc;
// determine if we should chop up
DeletedRecord *r = drec(loc);
/* note we want to grab from the front so our next pointers on disk tend
to go in a forward direction which is important for performance. */
int regionlen = r->lengthWithHeaders();
invariant( r->extentOfs() < loc.getOfs() );
int left = regionlen - lenToAlloc;
if ( left < 24 || left < (lenToAlloc / 8) ) {
// you get the whole thing.
return loc;
}
// don't quantize:
// - $ collections (indexes) as we already have those aligned the way we want SERVER-8425
if ( _normalCollection ) {
// we quantize here so that it only impacts newly sized records
// this prevents oddities with older records and space re-use SERVER-8435
lenToAlloc = std::min( r->lengthWithHeaders(),
quantizeAllocationSpace( lenToAlloc ) );
left = regionlen - lenToAlloc;
if ( left < 24 ) {
// you get the whole thing.
return loc;
}
}
/* split off some for further use. */
txn->recoveryUnit()->writingInt(r->lengthWithHeaders()) = lenToAlloc;
DiskLoc newDelLoc = loc;
newDelLoc.inc(lenToAlloc);
DeletedRecord* newDel = drec(newDelLoc);
DeletedRecord* newDelW = txn->recoveryUnit()->writing(newDel);
newDelW->extentOfs() = r->extentOfs();
newDelW->lengthWithHeaders() = left;
newDelW->nextDeleted().Null();
addDeletedRec( txn, newDelLoc );
return loc;
}
DiskLoc _repairExtent( Database* db , string ns, bool forward , DiskLoc eLoc , Writer& w ){
LogIndentLevel lil;
if ( eLoc.getOfs() <= 0 ){
toolError() << "invalid extent ofs: " << eLoc.getOfs() << std::endl;
return DiskLoc();
}
const ExtentManager& extentManager = db->getExtentManager();
Extent* e = extentManager.getExtent( eLoc, false );
if ( ! e->isOk() ){
toolError() << "Extent not ok magic: " << e->magic << " going to try to continue"
<< std::endl;
}
toolInfoLog() << "length:" << e->length << std::endl;
LogIndentLevel lil2;
set<DiskLoc> seen;
DiskLoc loc = forward ? e->firstRecord : e->lastRecord;
while ( ! loc.isNull() ){
if ( ! seen.insert( loc ).second ) {
toolError() << "infinite loop in extent, seen: " << loc << " before" << std::endl;
break;
}
if ( loc.getOfs() <= 0 ){
toolError() << "offset is 0 for record which should be impossible" << std::endl;
break;
}
if (logger::globalLogDomain()->shouldLog(logger::LogSeverity::Debug(1))) {
toolInfoLog() << loc << std::endl;
}
BSONObj obj;
try {
obj = loc.obj();
verify( obj.valid() );
if (logger::globalLogDomain()->shouldLog(logger::LogSeverity::Debug(1))) {
toolInfoLog() << obj << std::endl;
}
w( obj );
}
catch ( std::exception& e ) {
toolError() << "found invalid document @ " << loc << " " << e.what() << std::endl;
if ( ! obj.isEmpty() ) {
try {
BSONElement e = obj.firstElement();
stringstream ss;
ss << "first element: " << e;
toolError() << ss.str() << std::endl;
}
catch ( std::exception& ) {
toolError() << "unable to log invalid document @ " << loc << std::endl;
}
}
}
loc = forward ?
extentManager.getNextRecordInExtent( loc )
: extentManager.getPrevRecordInExtent( loc );
// break when new loc is outside current extent boundary
if ( loc.isNull() ) {
break;
}
}
toolInfoLog() << "wrote " << seen.size() << " documents" << std::endl;
return forward ? e->xnext : e->xprev;
}
DiskLoc _repairExtent( Database* db , string ns, bool forward , DiskLoc eLoc , Writer& w ){
LogIndentLevel lil;
if ( eLoc.getOfs() <= 0 ){
error() << "invalid extent ofs: " << eLoc.getOfs() << endl;
return DiskLoc();
}
MongoDataFile * mdf = db->getFile( eLoc.a() );
Extent * e = mdf->debug_getExtent( eLoc );
if ( ! e->isOk() ){
warning() << "Extent not ok magic: " << e->magic << " going to try to continue" << endl;
}
log() << "length:" << e->length << endl;
LogIndentLevel lil2;
set<DiskLoc> seen;
DiskLoc loc = forward ? e->firstRecord : e->lastRecord;
while ( ! loc.isNull() ){
if ( ! seen.insert( loc ).second ) {
error() << "infinite loop in extend, seen: " << loc << " before" << endl;
break;
}
if ( loc.getOfs() <= 0 ){
error() << "offset is 0 for record which should be impossible" << endl;
break;
}
log(1) << loc << endl;
Record* rec = loc.rec();
BSONObj obj;
try {
obj = loc.obj();
assert( obj.valid() );
LOG(1) << obj << endl;
w( obj );
}
catch ( std::exception& e ) {
log() << "found invalid document @ " << loc << " " << e.what() << endl;
if ( ! obj.isEmpty() ) {
try {
BSONElement e = obj.firstElement();
stringstream ss;
ss << "first element: " << e;
log() << ss.str();
}
catch ( std::exception& ) {
}
}
}
loc = forward ? rec->getNext( loc ) : rec->getPrev( loc );
}
return forward ? e->xnext : e->xprev;
}
/** @return number of skipped (invalid) documents */
unsigned compactExtent(const char *ns, NamespaceDetails *d, const DiskLoc diskloc, int n,
const scoped_array<IndexSpec> &indexSpecs,
scoped_array<SortPhaseOne>& phase1, int nidx, bool validate,
double pf, int pb)
{
log() << "compact begin extent #" << n << " for namespace " << ns << endl;
unsigned oldObjSize = 0; // we'll report what the old padding was
unsigned oldObjSizeWithPadding = 0;
Extent *e = diskloc.ext();
e->assertOk();
verify( e->validates() );
unsigned skipped = 0;
{
// the next/prev pointers within the extent might not be in order so we first page the whole thing in
// sequentially
log() << "compact paging in len=" << e->length/1000000.0 << "MB" << endl;
Timer t;
MongoDataFile* mdf = cc().database()->getFile( diskloc.a() );
HANDLE fd = mdf->getFd();
int offset = diskloc.getOfs();
Extent* ext = diskloc.ext();
size_t length = ext->length;
touch_pages(fd, offset, length, ext);
int ms = t.millis();
if( ms > 1000 )
log() << "compact end paging in " << ms << "ms " << e->length/1000000.0/ms << "MB/sec" << endl;
}
{
log() << "compact copying records" << endl;
long long datasize = 0;
long long nrecords = 0;
DiskLoc L = e->firstRecord;
if( !L.isNull() ) {
while( 1 ) {
Record *recOld = L.rec();
L = recOld->nextInExtent(L);
BSONObj objOld = BSONObj::make(recOld);
if( !validate || objOld.valid() ) {
nrecords++;
unsigned sz = objOld.objsize();
oldObjSize += sz;
oldObjSizeWithPadding += recOld->netLength();
unsigned lenWHdr = sz + Record::HeaderSize;
unsigned lenWPadding = lenWHdr;
{
lenWPadding = static_cast<unsigned>(pf*lenWPadding);
lenWPadding += pb;
lenWPadding = lenWPadding & quantizeMask(lenWPadding);
if( lenWPadding < lenWHdr || lenWPadding > BSONObjMaxUserSize / 2 ) {
lenWPadding = lenWHdr;
}
}
DiskLoc loc = allocateSpaceForANewRecord(ns, d, lenWPadding, false);
uassert(14024, "compact error out of space during compaction", !loc.isNull());
Record *recNew = loc.rec();
datasize += recNew->netLength();
recNew = (Record *) getDur().writingPtr(recNew, lenWHdr);
addRecordToRecListInExtent(recNew, loc);
memcpy(recNew->data(), objOld.objdata(), sz);
{
// extract keys for all indexes we will be rebuilding
for( int x = 0; x < nidx; x++ ) {
phase1[x].addKeys(indexSpecs[x], objOld, loc);
}
}
}
else {
if( ++skipped <= 10 )
log() << "compact skipping invalid object" << endl;
}
if( L.isNull() ) {
// we just did the very last record from the old extent. it's still pointed to
// by the old extent ext, but that will be fixed below after this loop
break;
}
// remove the old records (orphan them) periodically so our commit block doesn't get too large
bool stopping = false;
RARELY stopping = *killCurrentOp.checkForInterruptNoAssert() != 0;
if( stopping || getDur().aCommitIsNeeded() ) {
e->firstRecord.writing() = L;
Record *r = L.rec();
getDur().writingInt(r->prevOfs()) = DiskLoc::NullOfs;
getDur().commitIfNeeded();
killCurrentOp.checkForInterrupt(false);
}
}
} // if !L.isNull()
verify( d->firstExtent == diskloc );
verify( d->lastExtent != diskloc );
DiskLoc newFirst = e->xnext;
d->firstExtent.writing() = newFirst;
newFirst.ext()->xprev.writing().Null();
getDur().writing(e)->markEmpty();
freeExtents( diskloc, diskloc );
// update datasize/record count for this namespace's extent
{
NamespaceDetails::Stats *s = getDur().writing(&d->stats);
s->datasize += datasize;
s->nrecords += nrecords;
}
getDur().commitIfNeeded();
{
double op = 1.0;
if( oldObjSize )
op = static_cast<double>(oldObjSizeWithPadding)/oldObjSize;
log() << "compact finished extent #" << n << " containing " << nrecords << " documents (" << datasize/1000000.0 << "MB)"
<< " oldPadding: " << op << ' ' << static_cast<unsigned>(op*100.0)/100
<< endl;
}
}
return skipped;
}
