/** * Performs a wildcard search for the specified token. * * @param token token to look for * @return iterator */ private synchronized IndexIterator wc(final byte[] token) { final FTIndexIterator it = FTIndexIterator.FTEMPTY; final FTWildcard wc = new FTWildcard(token); if (!wc.parse()) return it; final IntList pr = new IntList(); final IntList ps = new IntList(); final byte[] pref = wc.prefix(); final int pl = pref.length, tl = tp.length; final int l = Math.min(tl - 1, wc.max()); for (int ti = pl; ti <= l; ti++) { int i = tp[ti]; if (i == -1) continue; int c = ti + 1; int e = -1; while (c < tl && e == -1) e = tp[c++]; i = find(pref, i, e, ti); while (i < e) { final byte[] t = inY.readBytes(i, ti); if (!startsWith(t, pref)) break; if (wc.match(t)) { inZ.cursor(pointer(i, ti)); final int s = size(i, ti); for (int d = 0; d < s; d++) { pr.add(inZ.readNum()); ps.add(inZ.readNum()); } } i += ti + ENTRY; } } return iter(new FTCache(pr, ps), token); }
/** * Returns an iterator for an index entry. * * @param off offset on entries * @param size number of id/pos entries * @param da data source * @param token index token * @return iterator */ private static FTIndexIterator iter( final long off, final int size, final DataAccess da, final byte[] token) { da.cursor(off); final IntList pr = new IntList(size); final IntList ps = new IntList(size); for (int c = 0; c < size; c++) { pr.add(da.readNum()); ps.add(da.readNum()); } return iter(new FTCache(pr, ps), token); }
/** * Returns pre values. * * @param ids unique node ids * @param off start offset * @param len number of ids * @return sorted pre values */ public final int[] pre(final int[] ids, final int off, final int len) { if (meta.updindex) return idmap.pre(ids, off, len); final IntList p = new IntList(ids.length); for (int i = off; i < len; ++i) p.add(preold(ids[i])); return p.sort().toArray(); }
@Override public IndexIterator iter(final IndexToken token) { final int id = values.id(token.get()); if (id == 0) return IndexIterator.EMPTY; final int len = lenList.get(id); final int[] ids = idsList.get(id), pres; if (data.meta.updindex) { final IntList tmp = new IntList(); for (int i = 0; i < len; ++i) tmp.add(data.pre(ids[i])); pres = tmp.sort().finish(); } else { pres = ids; } return new IndexIterator() { int p; @Override public boolean more() { return p < len; } @Override public int pre() { return pres[p++]; } @Override public int size() { return len; } }; }
/** * Inserts a data instance at the specified pre value. Note that the specified data instance must * differ from this instance. * * @param ipre value at which to insert new data * @param ipar parent pre value of node * @param clip data clip */ public final void insert(final int ipre, final int ipar, final DataClip clip) { meta.update(); // update value and document indexes if (meta.updindex) indexBegin(); resources.insert(ipre, clip); final int dsize = clip.size(); final int buf = Math.min(dsize, IO.BLOCKSIZE >> IO.NODEPOWER); // resize buffer to cache more entries buffer(buf); // find all namespaces in scope to avoid duplicate declarations final TokenMap nsScope = nspaces.scope(ipar, this); // loop through all entries final IntList preStack = new IntList(); final NSNode nsRoot = nspaces.current(); final HashSet<NSNode> newNodes = new HashSet<NSNode>(); final IntList flagPres = new IntList(); // indicates if database only contains a dummy node final Data data = clip.data; int c = 0; for (int dpre = clip.start; dpre < clip.end; ++dpre, ++c) { if (c != 0 && c % buf == 0) insert(ipre + c - buf); final int pre = ipre + c; final int dkind = data.kind(dpre); final int dpar = data.parent(dpre, dkind); // ipar < 0 if document nodes on top level are added final int dis = dpar >= 0 ? dpre - dpar : ipar >= 0 ? pre - ipar : 0; final int par = dis == 0 ? -1 : pre - dis; if (c == 0) nspaces.root(par, this); while (!preStack.isEmpty() && preStack.peek() > par) nspaces.close(preStack.pop()); switch (dkind) { case DOC: // add document nspaces.prepare(); final int s = data.size(dpre, dkind); doc(pre, s, data.text(dpre, true)); meta.ndocs++; preStack.push(pre); break; case ELEM: // add element nspaces.prepare(); boolean ne = false; if (data.nsFlag(dpre)) { final Atts at = data.ns(dpre); for (int a = 0; a < at.size(); ++a) { // see if prefix has been declared/ is part of current ns scope final byte[] old = nsScope.get(at.name(a)); if (old == null || !eq(old, at.value(a))) { // we have to keep track of all new NSNodes that are added // to the Namespace structure, as their pre values must not // be updated. I.e. if an NSNode N with pre value 3 existed // prior to inserting and two new nodes are inserted at // location pre == 3 we have to make sure N and only N gets // updated. newNodes.add(nspaces.add(at.name(a), at.value(a), pre)); ne = true; } } } byte[] nm = data.name(dpre, dkind); elem( dis, tagindex.index(nm, null, false), data.attSize(dpre, dkind), data.size(dpre, dkind), nspaces.uri(nm, true), ne); preStack.push(pre); break; case TEXT: case COMM: case PI: // add text text(pre, dis, data.text(dpre, true), dkind); break; case ATTR: // add attribute nm = data.name(dpre, dkind); // check if prefix already in nsScope or not final byte[] attPref = prefix(nm); // check if prefix of attribute has already been declared, otherwise // add declaration to parent node if (data.nsFlag(dpre) && nsScope.get(attPref) == null) { nspaces.add( par, preStack.isEmpty() ? -1 : preStack.peek(), attPref, data.nspaces.uri(data.uri(dpre, dkind)), this); // save pre value to set ns flag later for this node. can't be done // here as direct table access would interfere with the buffer flagPres.add(par); } attr( pre, dis, atnindex.index(nm, null, false), data.text(dpre, false), nspaces.uri(nm, false), false); break; } } // finalize and update namespace structure while (!preStack.isEmpty()) nspaces.close(preStack.pop()); nspaces.root(nsRoot); if (bp != 0) insert(ipre + c - 1 - (c - 1) % buf); // reset buffer to old size buffer(1); // set ns flags for (int f = 0; f < flagPres.size(); f++) { final int fl = flagPres.get(f); table.write2(fl, 1, name(fl) | 1 << 15); } // increase size of ancestors int p = ipar; while (p >= 0) { final int k = kind(p); size(p, k, size(p, k) + dsize); p = parent(p, k); } if (meta.updindex) { // add the entries to the ID -> PRE mapping: idmap.insert(ipre, id(ipre), dsize); indexEnd(); } if (!cache) updateDist(ipre + dsize, dsize); // propagate PRE value shifts to namespaces if (ipar != -1) nspaces.insert(ipre, dsize, newNodes); }