mongodb/db/btree.cpp

// btree.cpp

/**
*    Copyright (C) 2008 10gen Inc.
*
*    This program is free software: you can redistribute it and/or  modify
*    it under the terms of the GNU Affero General Public License, version 3,
*    as published by the Free Software Foundation.
*
*    This program 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 Affero General Public License for more details.
*
*    You should have received a copy of the GNU Affero General Public License
*    along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#include "stdafx.h"
#include "btree.h"
#include "pdfile.h"

/* it is easy to do custom sizes for a namespace - all the same for now */
const int BucketSize = 8192;
const int KeyMax = BucketSize / 10;

int ninserts = 0;
extern int otherTraceLevel;
int split_debug = 0;
int insert_debug = 0;

KeyNode::KeyNode(BucketBasics& bb, _KeyNode &k) :
        prevChildBucket(k.prevChildBucket),
        recordLoc(k.recordLoc), key(bb.data+k.keyDataOfs())
{ }

/* BucketBasics --------------------------------------------------- */

int BucketBasics::Size() const {
    assert( _Size == BucketSize );
    return _Size;
}
inline void BucketBasics::setNotPacked() {
    flags &= ~Packed;
}
inline void BucketBasics::setPacked() {
    flags |= Packed;
}

void BucketBasics::_shape(int level, stringstream& ss) {
    for ( int i = 0; i < level; i++ ) ss << ' ';
    ss << "*\n";
    for ( int i = 0; i < n; i++ )
        if ( !k(i).prevChildBucket.isNull() )
            k(i).prevChildBucket.btree()->_shape(level+1,ss);
    if ( !nextChild.isNull() )
        nextChild.btree()->_shape(level+1,ss);
}

int bt_fv=0;
int bt_dmp=0;

void BucketBasics::dumpTree(DiskLoc thisLoc) {
    bt_dmp=1;
    fullValidate(thisLoc);
    bt_dmp=0;
}

int BucketBasics::fullValidate(const DiskLoc& thisLoc) {
    assertValid(true);
//	if( bt_fv==0 )
//		return;

    if ( bt_dmp ) {
        cout << thisLoc.toString() << ' ';
        ((BtreeBucket *) this)->dump();
    }

    // keycount
    int kc = 0;

    for ( int i = 0; i < n; i++ ) {
        _KeyNode& kn = k(i);

        if ( kn.isUsed() ) kc++;
        if ( !kn.prevChildBucket.isNull() ) {
            DiskLoc left = kn.prevChildBucket;
            BtreeBucket *b = left.btree();
            wassert( b->parent == thisLoc );
            kc += b->fullValidate(kn.prevChildBucket);
        }
    }
    if ( !nextChild.isNull() ) {
        BtreeBucket *b = nextChild.btree();
        wassert( b->parent == thisLoc );
        kc += b->fullValidate(nextChild);
    }

    return kc;
}

int nDumped = 0;

void BucketBasics::assertValid(bool force) {
    if ( !debug && !force )
        return;
    wassert( n >= 0 && n < Size() );
    wassert( emptySize >= 0 && emptySize < BucketSize );
    wassert( topSize >= n && topSize <= BucketSize );
    DEV {
        // slow:
        for ( int i = 0; i < n-1; i++ ) {
            BSONObj k1 = keyNode(i).key;
            BSONObj k2 = keyNode(i+1).key;
            int z = k1.woCompare(k2); //OK
            if ( z > 0 ) {
                cout << "ERROR: btree key order corrupt.  Keys:" << endl;
                if ( ++nDumped < 5 ) {
                    for ( int j = 0; j < n; j++ ) {
                        cout << "  " << keyNode(j).key.toString() << endl;
                    }
                    ((BtreeBucket *) this)->dump();
                }
                wassert(false);
                break;
            }
            else if ( z == 0 ) {
                if ( !(k(i).recordLoc < k(i+1).recordLoc) ) {
                    cout << "ERROR: btree key order corrupt (recordloc's wrong).  Keys:" << endl;
                    cout << " k(" << i << "):" << keyNode(i).key.toString() << " RL:" << k(i).recordLoc.toString() << endl;
                    cout << " k(" << i+1 << "):" << keyNode(i+1).key.toString() << " RL:" << k(i+1).recordLoc.toString() << endl;
                    wassert( k(i).recordLoc < k(i+1).recordLoc );
                }
            }
        }
    }
    else {
        //faster:
        if ( n > 1 ) {
            BSONObj k1 = keyNode(0).key;
            BSONObj k2 = keyNode(n-1).key;
            int z = k1.woCompare(k2);
            //wassert( z <= 0 );
            if ( z > 0 ) {
                problem() << "btree keys out of order" << '\n';
                ONCE {
                    ((BtreeBucket *) this)->dump();
                }
                assert(false);
            }
        }
    }
}

inline void BucketBasics::markUnused(int keypos) {
    assert( keypos >= 0 && keypos < n );
    k(keypos).setUnused();
}

inline int BucketBasics::totalDataSize() const {
    return Size() - (data-(char*)this);
}

void BucketBasics::init() {
    parent.Null();
    nextChild.Null();
    _Size = BucketSize;
    flags = Packed;
    n = 0;
    emptySize = totalDataSize();
    topSize = 0;
    reserved = 0;
}

/* we allocate space from the end of the buffer for data.
   the keynodes grow from the front.
*/
inline int BucketBasics::_alloc(int bytes) {
    topSize += bytes;
    emptySize -= bytes;
    int ofs = totalDataSize() - topSize;
    assert( ofs > 0 );
    return ofs;
}

void BucketBasics::_delKeyAtPos(int keypos) {
    assert( keypos >= 0 && keypos <= n );
    assert( childForPos(keypos).isNull() );
    n--;
    assert( n > 0 || nextChild.isNull() );
    for ( int j = keypos; j < n; j++ )
        k(j) = k(j+1);
    emptySize += sizeof(_KeyNode);
    setNotPacked();
}

/* add a key.  must be > all existing.  be careful to set next ptr right. */
void BucketBasics::pushBack(const DiskLoc& recordLoc, BSONObj& key, DiskLoc prevChild) {
    int bytesNeeded = key.objsize() + sizeof(_KeyNode);
    assert( bytesNeeded <= emptySize );
    assert( n == 0 || keyNode(n-1).key.woCompare(key) <= 0 );
    emptySize -= sizeof(_KeyNode);
    _KeyNode& kn = k(n++);
    kn.prevChildBucket = prevChild;
    kn.recordLoc = recordLoc;
    kn.setKeyDataOfs( (short) _alloc(key.objsize()) );
    char *p = dataAt(kn.keyDataOfs());
    memcpy(p, key.objdata(), key.objsize());
}

bool BucketBasics::basicInsert(int keypos, const DiskLoc& recordLoc, BSONObj& key) {
    assert( keypos >= 0 && keypos <= n );
    int bytesNeeded = key.objsize() + sizeof(_KeyNode);
    if ( bytesNeeded > emptySize ) {
        pack();
        if ( bytesNeeded > emptySize )
            return false;
    }
    for ( int j = n; j > keypos; j-- ) // make room
        k(j) = k(j-1);
    n++;
    emptySize -= sizeof(_KeyNode);
    _KeyNode& kn = k(keypos);
    kn.prevChildBucket.Null();
    kn.recordLoc = recordLoc;
    kn.setKeyDataOfs((short) _alloc(key.objsize()) );
    char *p = dataAt(kn.keyDataOfs());
    memcpy(p, key.objdata(), key.objsize());
    return true;
}

/* when we delete things we just leave empty space until the node is
   full and then we repack it.
*/
void BucketBasics::pack() {
    if ( flags & Packed )
        return;

    int tdz = totalDataSize();
    char temp[BucketSize];
    int ofs = tdz;
    topSize = 0;
    for ( int j = 0; j < n; j++ ) {
        short ofsold = k(j).keyDataOfs();
        int sz = keyNode(j).key.objsize();
        ofs -= sz;
        topSize += sz;
        memcpy(temp+ofs, dataAt(ofsold), sz);
        k(j).setKeyDataOfsSavingUse( ofs );
    }
    int dataUsed = tdz - ofs;
    memcpy(data + ofs, temp + ofs, dataUsed);
    emptySize = tdz - dataUsed - n * sizeof(_KeyNode);
    assert( emptySize >= 0 );

    setPacked();
    assertValid();
}

inline void BucketBasics::truncateTo(int N) {
    n = N;
    setNotPacked();
    pack();
}

/* - BtreeBucket --------------------------------------------------- */

/* return largest key in the subtree. */
void BtreeBucket::findLargestKey(const DiskLoc& thisLoc, DiskLoc& largestLoc, int& largestKey) {
    DiskLoc loc = thisLoc;
    while ( 1 ) {
        BtreeBucket *b = loc.btree();
        if ( !b->nextChild.isNull() ) {
            loc = b->nextChild;
            continue;
        }

        assert(b->n>0);
        largestLoc = loc;
        largestKey = b->n-1;

        break;
    }
}

/* pos: for existing keys k0...kn-1.
   returns # it goes BEFORE.  so key[pos-1] < key < key[pos]
   returns n if it goes after the last existing key.
   note result might be Unused!
*/
bool BtreeBucket::find(BSONObj& key, DiskLoc recordLoc, int& pos) {
    /* binary search for this key */
    int l=0;
    int h=n-1;
    while ( l <= h ) {
        int m = (l+h)/2;
        KeyNode M = keyNode(m);
        int x = key.woCompare(M.key);
        if ( x == 0 )
            x = recordLoc.compare(M.recordLoc);
        if ( x < 0 ) // key < M.key
            h = m-1;
        else if ( x > 0 )
            l = m+1;
        else {
            // found it.  however, if dup keys are here, be careful we might have
            // found one in the middle.  we want find() to return the leftmost instance.
            /*
            			while( m >= 1 && keyNode(m-1).key.woEqual(key) )
            				m--;
            */

            pos = m;

            /*
            			DiskLoc ch = k(m).prevChildBucket;
            			if( !ch.isNull() ) {
            				// if dup keys, might be dups to the left.
            				DiskLoc largestLoc;
            				int largestKey;
            				ch.btree()->findLargestKey(ch, largestLoc, largestKey);
            				if( !largestLoc.isNull() ) {
            					if( largestLoc.btree()->keyAt(largestKey).woEqual(key) )
            						return false;
            				}
            			}
            */

            return true;
        }
//?		x = key.woCompare(M.key);
    }
    // not found
    pos = l;
    if ( pos != n ) {
        BSONObj keyatpos = keyNode(pos).key;
        wassert( key.woCompare(keyatpos) <= 0 );
        if ( pos > 0 ) {
            wassert( keyNode(pos-1).key.woCompare(key) <= 0 );
        }
    }

    return false;
}

void aboutToDeleteBucket(const DiskLoc&);
void BtreeBucket::delBucket(const DiskLoc& thisLoc, IndexDetails& id) {
    aboutToDeleteBucket(thisLoc);

    assert( !isHead() );

    BtreeBucket *p = parent.btree();
    if ( p->nextChild == thisLoc ) {
        p->nextChild.Null();
    }
    else {
        for ( int i = 0; i < p->n; i++ ) {
            if ( p->k(i).prevChildBucket == thisLoc ) {
                p->k(i).prevChildBucket.Null();
                goto found;
            }
        }
        cout << "ERROR: can't find ref to deleted bucket.\n";
        cout << "To delete:\n";
        dump();
        cout << "Parent:\n";
        p->dump();
        assert(false);
    }
found:
#if 1
    /* as a temporary defensive measure, we zap the whole bucket, AND don't truly delete
       it (meaning it is ineligible for reuse).  temporary to see if it helps with some
       issues.
       */
    memset(this, 0, Size());
#else
    //defensive:
    n = -1;
    parent.Null();
    theDataFileMgr.deleteRecord(id.indexNamespace().c_str(), thisLoc.rec(), thisLoc);
#endif
}

/* note: may delete the entire bucket!  this invalid upon return sometimes. */
void BtreeBucket::delKeyAtPos(const DiskLoc& thisLoc, IndexDetails& id, int p) {
    dassert( thisLoc.btree() == this );
    assert(n>0);
    DiskLoc left = childForPos(p);

    if ( n == 1 ) {
        if ( left.isNull() && nextChild.isNull() ) {
            if ( isHead() )
                _delKeyAtPos(p); // we don't delete the top bucket ever
            else
                delBucket(thisLoc, id);
            return;
        }
        markUnused(p);
        return;
    }

    if ( left.isNull() )
        _delKeyAtPos(p);
    else
        markUnused(p);
}

int qqq = 0;

bool BtreeBucket::unindex(const DiskLoc& thisLoc, IndexDetails& id, BSONObj& key, const DiskLoc& recordLoc ) {
    if ( key.objsize() > KeyMax ) {
        OCCASIONALLY problem() << "unindex: key too large to index, skipping " << id.indexNamespace() << /* ' ' << key.toString() << */ '\n';
        return false;
    }

    int pos;
    bool found;
    DiskLoc loc = locate(thisLoc, key, pos, found, recordLoc, 1);
    if ( found ) {
        loc.btree()->delKeyAtPos(loc, id, pos);
        return true;
    }
    return false;
}

BtreeBucket* BtreeBucket::allocTemp() {
    BtreeBucket *b = (BtreeBucket*) malloc(BucketSize);
    b->init();
    return b;
}

inline void fix(const DiskLoc& thisLoc, const DiskLoc& child) {
    if ( !child.isNull() ) {
        if ( insert_debug )
            cout << "      " << child.toString() << ".parent=" << thisLoc.toString() << endl;
        child.btree()->parent = thisLoc;
    }
}

/* this sucks.  maybe get rid of parent ptrs. */
void BtreeBucket::fixParentPtrs(const DiskLoc& thisLoc) {
    dassert( thisLoc.btree() == this );
    fix(thisLoc, nextChild);
    for ( int i = 0; i < n; i++ )
        fix(thisLoc, k(i).prevChildBucket);
}

/* keypos - where to insert the key i3n range 0..n.  0=make leftmost, n=make rightmost.
*/
void BtreeBucket::insertHere(DiskLoc thisLoc, int keypos,
                             DiskLoc recordLoc, BSONObj& key,
                             DiskLoc lchild, DiskLoc rchild, IndexDetails& idx)
{
    dassert( thisLoc.btree() == this );
    if ( insert_debug )
        cout << "   " << thisLoc.toString() << ".insertHere " << key.toString() << '/' << recordLoc.toString() << ' '
             << lchild.toString() << ' ' << rchild.toString() << " keypos:" << keypos << endl;

    DiskLoc oldLoc = thisLoc;

    if ( basicInsert(keypos, recordLoc, key) ) {
        _KeyNode& kn = k(keypos);
        if ( keypos+1 == n ) { // last key
            if ( nextChild != lchild ) {
                cout << "ERROR nextChild != lchild" << endl;
                cout << "  thisLoc: " << thisLoc.toString() << ' ' << idx.indexNamespace() << endl;
                cout << "  keyPos: " << keypos << " n:" << n << endl;
                cout << "  nextChild: " << nextChild.toString() << " lchild: " << lchild.toString() << endl;
                cout << "  recordLoc: " << recordLoc.toString() << " rchild: " << rchild.toString() << endl;
                cout << "  key: " << key.toString() << endl;
                dump();
#if defined(_WIN32)
                cout << "\n\nDUMPING FULL INDEX" << endl;
                bt_dmp=1;
                bt_fv=1;
                idx.head.btree()->fullValidate(idx.head);
#endif
                assert(false);
            }
            kn.prevChildBucket = nextChild;
            assert( kn.prevChildBucket == lchild );
            nextChild = rchild;
            if ( !rchild.isNull() )
                rchild.btree()->parent = thisLoc;
        }
        else {
            k(keypos).prevChildBucket = lchild;
            if ( k(keypos+1).prevChildBucket != lchild ) {
                cout << "ERROR k(keypos+1).prevChildBucket != lchild" << endl;
                cout << "  thisLoc: " << thisLoc.toString() << ' ' << idx.indexNamespace() << endl;
                cout << "  keyPos: " << keypos << " n:" << n << endl;
                cout << "  k(keypos+1).pcb: " << k(keypos+1).prevChildBucket.toString() << " lchild: " << lchild.toString() << endl;
                cout << "  recordLoc: " << recordLoc.toString() << " rchild: " << rchild.toString() << endl;
                cout << "  key: " << key.toString() << endl;
                dump();
#if defined(_WIN32)
                cout << "\n\nDUMPING FULL INDEX" << endl;
                bt_dmp=1;
                bt_fv=1;
                idx.head.btree()->fullValidate(idx.head);
#endif
                assert(false);
            }
            k(keypos+1).prevChildBucket = rchild;
            if ( !rchild.isNull() )
                rchild.btree()->parent = thisLoc;
        }
        return;
    }

    // split
    if ( split_debug )
        cout << "    " << thisLoc.toString() << ".split" << endl;

    int mid = n / 2;

    /* on duplicate key, we need to ensure that they all end up on the RHS */
    if ( 0 ) {
        assert(mid>0);
        while ( 1 ) {
            KeyNode mn = keyNode(mid);
            KeyNode left = keyNode(mid-1);
            if ( left.key < mn.key )
                break;
            mid--;
            if ( mid < 3 ) {
                problem() << "Assertion failure - mid<3: duplicate key bug not fixed yet" << endl;
                cout << "Assertion failure - mid<3: duplicate key bug not fixed yet" << endl;
                cout << "  ns:" << idx.indexNamespace() << endl;
                cout << "  key:" << mn.key.toString() << endl;
                break;
            }
        }
    }

    BtreeBucket *r = allocTemp();
    DiskLoc rLoc;

    if ( split_debug )
        cout << "     mid:" << mid << ' ' << keyNode(mid).key.toString() << " n:" << n << endl;
    for ( int i = mid+1; i < n; i++ ) {
        KeyNode kn = keyNode(i);
        r->pushBack(kn.recordLoc, kn.key, kn.prevChildBucket);
    }
    r->nextChild = nextChild;
    r->assertValid();
//r->dump();
    rLoc = theDataFileMgr.insert(idx.indexNamespace().c_str(), r, r->Size(), true);
    if ( split_debug )
        cout << "     new rLoc:" << rLoc.toString() << endl;
    free(r);
    r = 0;
    rLoc.btree()->fixParentPtrs(rLoc);

    {
        KeyNode middle = keyNode(mid);
        nextChild = middle.prevChildBucket; // middle key gets promoted, its children will be thisLoc (l) and rLoc (r)
        if ( split_debug ) {
            //rLoc.btree()->dump();
            cout << "    middle key:" << middle.key.toString() << endl;
        }

        // promote middle to a parent node
        if ( parent.isNull() ) {
            // make a new parent if we were the root
            BtreeBucket *p = allocTemp();
            p->pushBack(middle.recordLoc, middle.key, thisLoc);
            p->nextChild = rLoc;
            p->assertValid();
            parent = idx.head = theDataFileMgr.insert(idx.indexNamespace().c_str(), p, p->Size(), true);
            if ( split_debug )
                cout << "    we were root, making new root:" << hex << parent.getOfs() << dec << endl;
            free(p);
            rLoc.btree()->parent = parent;
        }
        else {
            /* set this before calling _insert - if it splits it will do fixParent() logic and fix the value,
               so we don't want to overwrite that if it happens.
            */
            rLoc.btree()->parent = parent;
            if ( split_debug )
                cout << "    promoting middle key " << middle.key.toString() << endl;
            parent.btree()->_insert(parent, middle.recordLoc, middle.key, false, thisLoc, rLoc, idx);
        }
//BtreeBucket *br = rLoc.btree();
//br->dump();

//parent.btree()->dump();
//idx.head.btree()->dump();

    }

    truncateTo(mid);  // note this may trash middle.key!  thus we had to promote it before finishing up here.

    // add our new key, there is room now
    {

//dump();

        if ( keypos <= mid ) {
//		if( keypos < mid ) {
            if ( split_debug )
                cout << "  keypos<mid, insertHere() the new key" << endl;
            insertHere(thisLoc, keypos, recordLoc, key, lchild, rchild, idx);
//dump();
        } else {
            int kp = keypos-mid-1;
            assert(kp>=0);
            rLoc.btree()->insertHere(rLoc, kp, recordLoc, key, lchild, rchild, idx);
// set a bp here.
//			if( !lchild.isNull() ) cout << lchild.btree()->parent.toString() << endl;
//			if( !rchild.isNull() ) cout << rchild.btree()->parent.toString() << endl;
        }
    }

    if ( split_debug )
        cout << "     split end " << hex << thisLoc.getOfs() << dec << endl;
}

/* start a new index off, empty */
DiskLoc BtreeBucket::addHead(IndexDetails& id) {
    BtreeBucket *p = allocTemp();
    DiskLoc loc = theDataFileMgr.insert(id.indexNamespace().c_str(), p, p->Size(), true);
    free(p);
    return loc;
}

DiskLoc BtreeBucket::getHead(const DiskLoc& thisLoc) {
    DiskLoc p = thisLoc;
    while ( !p.btree()->isHead() )
        p = p.btree()->parent;
    return p;
}

DiskLoc BtreeBucket::advance(const DiskLoc& thisLoc, int& keyOfs, int direction, const char *caller) {
    if ( keyOfs < 0 || keyOfs >= n ) {
        cout << "ASSERT failure BtreeBucket::advance, caller: " << caller << endl;
        cout << "  thisLoc: " << thisLoc.toString() << endl;
        cout << "  keyOfs: " << keyOfs << " n:" << n << " direction: " << direction << endl;
        cout << bucketSummary() << endl;
        assert(false);
    }
    int adj = direction < 0 ? 1 : 0;
    int ko = keyOfs + direction;
    DiskLoc nextDown = childForPos(ko+adj);
    if ( !nextDown.isNull() ) {
        while ( 1 ) {
            keyOfs = direction>0 ? 0 : nextDown.btree()->n - 1;
            DiskLoc loc= nextDown.btree()->childForPos(keyOfs + adj);
            if ( loc.isNull() )
                break;
            nextDown = loc;
        }
        return nextDown;
    }

    if ( ko < n && ko >= 0 ) {
        keyOfs = ko;
        return thisLoc;
    }

    // end of bucket.  traverse back up.
    DiskLoc childLoc = thisLoc;
    DiskLoc ancestor = parent;
    while ( 1 ) {
        if ( ancestor.isNull() )
            break;
        BtreeBucket *an = ancestor.btree();
        for ( int i = 0; i < an->n; i++ ) {
            if ( an->childForPos(i+adj) == childLoc ) {
                keyOfs = i;
                return ancestor;
            }
        }
        assert( direction<0 || an->nextChild == childLoc );
        // parent exhausted also, keep going up
        childLoc = ancestor;
        ancestor = an->parent;
    }

    return DiskLoc();
}

DiskLoc BtreeBucket::locate(const DiskLoc& thisLoc, BSONObj& key, int& pos, bool& found, DiskLoc recordLoc, int direction) {
    int p;
    found = find(key, recordLoc, p);
    if ( found ) {
        pos = p;
        return thisLoc;
    }

    DiskLoc child = childForPos(p);

    if ( !child.isNull() ) {
        DiskLoc l = child.btree()->locate(child, key, pos, found, recordLoc, direction);
        if ( !l.isNull() )
            return l;
    }

    pos = p;
    if ( direction < 0 )
        return --pos == -1 ? DiskLoc() /*theend*/ : thisLoc;
    else
        return pos == n ? DiskLoc() /*theend*/ : thisLoc;
}

/* thisloc is the location of this bucket object.  you must pass that in. */
int BtreeBucket::_insert(DiskLoc thisLoc, DiskLoc recordLoc,
                         BSONObj& key, bool dupsAllowed,
                         DiskLoc lChild, DiskLoc rChild, IndexDetails& idx) {
    if ( key.objsize() > KeyMax ) {
        problem() << "ERROR: key too large len:" << key.objsize() << " max:" << KeyMax << ' ' << idx.indexNamespace() << endl;
        return 2;
    }
    assert( key.objsize() > 0 );

    int pos;
    bool found = find(key, recordLoc, pos);
    if ( insert_debug ) {
        cout << "  " << thisLoc.toString() << '.' << "_insert " <<
             key.toString() << '/' << recordLoc.toString() <<
             " l:" << lChild.toString() << " r:" << rChild.toString() << endl;
        cout << "    found:" << found << " pos:" << pos << " n:" << n << endl;
    }

    if ( found ) {
        if ( k(pos).isUnused() ) {
            cout << "an unused already occupying keyslot, write more code.\n";
            cout << "  index may be corrupt (missing data) now.\n";
        }

        cout << "_insert(): key already exists in index\n";
        cout << "  " << idx.indexNamespace().c_str() << " thisLoc:" << thisLoc.toString() << '\n';
        cout << "  " << key.toString() << '\n';
        cout << "  " << "recordLoc:" << recordLoc.toString() << " pos:" << pos << endl;
        cout << "  old l r: " << childForPos(pos).toString() << ' ' << childForPos(pos+1).toString() << endl;
        cout << "  new l r: " << lChild.toString() << ' ' << rChild.toString() << endl;
        assert(false);

        // on a dup key always insert on the right or else you will be broken.
//		pos++;
        // on a promotion, find the right point to update if dup keys.
        /* not needed: we always insert right after the first key so we are ok with just pos++...
        if( !rChild.isNull() ) {
        	while( pos < n && k(pos).prevChildBucket != lchild ) {
        		pos++;
        		cout << "looking for the right dup key" << endl;
        	}
        }
        */
    }

    DEBUGGING cout << "TEMP: key: " << key.toString() << endl;
    DiskLoc& child = getChild(pos);
    if ( insert_debug )
        cout << "    getChild(" << pos << "): " << child.toString() << endl;
    if ( child.isNull() || !rChild.isNull() /* means an 'internal' insert */ ) {
        insertHere(thisLoc, pos, recordLoc, key, lChild, rChild, idx);
        return 0;
    }

    return child.btree()->insert(child, recordLoc, key, dupsAllowed, idx, false);
}

void BtreeBucket::dump() {
    cout << "DUMP btreebucket: ";
    cout << " parent:" << hex << parent.getOfs() << dec;
    for ( int i = 0; i < n; i++ ) {
        cout << '\n';
        KeyNode k = keyNode(i);
        cout << '\t' << i << '\t' << k.key.toString() << "\tleft:" << hex <<
             k.prevChildBucket.getOfs() << "\trec:" << k.recordLoc.getOfs() << dec;
        if ( this->k(i).isUnused() )
            cout << " UNUSED";
    }
    cout << " right:" << hex << nextChild.getOfs() << dec << endl;
}

/* todo: meaning of return code unclear clean up */
int BtreeBucket::insert(DiskLoc thisLoc, DiskLoc recordLoc,
                        BSONObj& key, bool dupsAllowed, IndexDetails& idx, bool toplevel)
{
    if ( toplevel ) {
        if ( key.objsize() > KeyMax ) {
            problem() << "Btree::insert: key too large to index, skipping " << idx.indexNamespace().c_str() << ' ' << key.toString() << '\n';
            return 3;
        }
        ++ninserts;
        /*
        if( ninserts % 1000 == 0 ) {
        	cout << "ninserts: " << ninserts << endl;
        	if( 0 && ninserts >= 127287 ) {
        		cout << "debug?" << endl;
        		split_debug = 1;
        	}
        }
        */
    }

    int x = _insert(thisLoc, recordLoc, key, dupsAllowed, DiskLoc(), DiskLoc(), idx);
    assertValid();

    return x;
}

void BtreeBucket::shape(stringstream& ss) {
    _shape(0, ss);
}