@Override public final Expr inline(final QueryContext ctx, final VarScope scp, final Var v, final Expr e) throws QueryException { final Value oldVal = ctx.value; try { ctx.value = root(ctx); final Expr rt = root == null ? null : root.inline(ctx, scp, v, e); if (rt != null) { setRoot(ctx, rt); ctx.value = oldVal; ctx.value = root(ctx); } boolean change = rt != null; for (int i = 0; i < steps.length; i++) { final Expr nw = steps[i].inline(ctx, scp, v, e); if (nw != null) { steps[i] = nw; change = true; } } return change ? optimize(ctx, scp) : null; } finally { ctx.value = oldVal; } }
/** * Checks if the predicates are successful for the specified item. * * @param it item to be checked * @param qc query context * @return result of check * @throws QueryException query exception */ protected final boolean preds(final Item it, final QueryContext qc) throws QueryException { if (preds.length == 0) return true; // set context value and position final Value cv = qc.value; try { if (qc.scoring) { double s = 0; for (final Expr p : preds) { qc.value = it; final Item i = p.test(qc, info); if (i == null) return false; s += i.score(); } it.score(Scoring.avg(s, preds.length)); } else { for (final Expr p : preds) { qc.value = it; if (p.test(qc, info) == null) return false; } } return true; } finally { qc.value = cv; } }
@Override public final Expr compile(final QueryContext qc, final VarScope scp) throws QueryException { if (root != null) root = root.compile(qc, scp); // no steps if (steps.length == 0) return root == null ? new Context(info) : root; final Value init = qc.value, cv = initial(qc); final boolean doc = cv != null && cv.type == NodeType.DOC; qc.value = cv; try { final int sl = steps.length; for (int s = 0; s < sl; s++) { Expr e = steps[s]; // axis step: if input is a document, its type is temporarily generalized final boolean as = e instanceof Step; if (as && s == 0 && doc) cv.type = NodeType.NOD; e = e.compile(qc, scp); if (e.isEmpty()) return optPre(qc); steps[s] = e; // no axis step: invalidate context value if (!as) qc.value = null; } } finally { if (doc) cv.type = NodeType.DOC; qc.value = init; } // optimize path return optimize(qc, scp); }
/** * Converts descendant to child steps. * * @param qc query context * @param rt root value * @return original or new expression */ private Expr children(final QueryContext qc, final Value rt) { // skip if index does not exist or is out-dated, or if several namespaces occur in the input final Data data = rt.data(); if (data == null || !data.meta.uptodate || data.nspaces.globalNS() == null) return this; Path path = this; final int sl = steps.length; for (int s = 0; s < sl; s++) { // don't allow predicates in preceding location steps final Step prev = s > 0 ? axisStep(s - 1) : null; if (prev != null && prev.preds.length != 0) break; // ignore axes other than descendant, or numeric predicates final Step curr = axisStep(s); if (curr == null || curr.axis != DESC || curr.has(Flag.FCS)) continue; // check if child steps can be retrieved for current step ArrayList<PathNode> nodes = pathNodes(data, s); if (nodes == null) continue; // cache child steps final ArrayList<QNm> qnm = new ArrayList<>(); while (nodes.get(0).parent != null) { QNm nm = new QNm(data.elemNames.key(nodes.get(0).name)); // skip children with prefixes if (nm.hasPrefix()) return this; for (final PathNode p : nodes) { if (nodes.get(0).name != p.name) nm = null; } qnm.add(nm); nodes = PathSummary.parent(nodes); } qc.compInfo(OPTCHILD, steps[s]); // build new steps int ts = qnm.size(); final Expr[] stps = new Expr[ts + sl - s - 1]; for (int t = 0; t < ts; t++) { final Expr[] preds = t == ts - 1 ? ((Preds) steps[s]).preds : new Expr[0]; final QNm nm = qnm.get(ts - t - 1); final NameTest nt = nm == null ? new NameTest(false) : new NameTest(nm, Kind.NAME, false, null); stps[t] = Step.get(info, CHILD, nt, preds); } while (++s < sl) stps[ts++] = steps[s]; path = get(info, root, stps); break; } // check if all steps yield results; if not, return empty sequence final ArrayList<PathNode> nodes = pathNodes(qc); if (nodes != null && nodes.isEmpty()) { qc.compInfo(OPTPATH, path); return Empty.SEQ; } return path; }
@Override public Expr optimize(final QueryContext qc, final VarScope scp) throws QueryException { // number of predicates may change in loop for (int p = 0; p < preds.length; p++) { final Expr pred = preds[p]; if (pred instanceof CmpG || pred instanceof CmpV) { final Cmp cmp = (Cmp) pred; if (cmp.exprs[0].isFunction(Function.POSITION)) { final Expr e2 = cmp.exprs[1]; final SeqType st2 = e2.seqType(); // position() = last() -> last() // position() = $n (numeric) -> $n if (e2.isFunction(Function.LAST) || st2.one() && st2.type.isNumber()) { if (cmp instanceof CmpG && ((CmpG) cmp).op == OpG.EQ || cmp instanceof CmpV && ((CmpV) cmp).op == OpV.EQ) { qc.compInfo(OPTWRITE, pred); preds[p] = e2; } } } } else if (pred instanceof And) { if (!pred.has(Flag.FCS)) { // replace AND expression with predicates (don't swap position tests) qc.compInfo(OPTPRED, pred); final Expr[] and = ((Arr) pred).exprs; final int m = and.length - 1; final ExprList el = new ExprList(preds.length + m); for (final Expr e : Arrays.asList(preds).subList(0, p)) el.add(e); for (final Expr a : and) { // wrap test with boolean() if the result is numeric el.add(Function.BOOLEAN.get(null, info, a).optimizeEbv(qc, scp)); } for (final Expr e : Arrays.asList(preds).subList(p + 1, preds.length)) el.add(e); preds = el.finish(); } } else if (pred instanceof ANum) { final ANum it = (ANum) pred; final long i = it.itr(); if (i == it.dbl()) { preds[p] = Pos.get(i, info); } else { qc.compInfo(OPTREMOVE, this, pred); return Empty.SEQ; } } else if (pred.isValue()) { if (pred.ebv(qc, info).bool(info)) { qc.compInfo(OPTREMOVE, this, pred); preds = Array.delete(preds, p--); } else { // handle statically known predicates qc.compInfo(OPTREMOVE, this, pred); return Empty.SEQ; } } } return this; }
@Override public final Expr compile(final QueryContext ctx, final VarScope scp) throws QueryException { if (root != null) setRoot(ctx, root.compile(ctx, scp)); final Value v = ctx.value; try { ctx.value = root(ctx); return compilePath(ctx, scp); } finally { ctx.value = v; } }
@Override public Expr compile(final QueryContext qc, final VarScope scp) throws QueryException { final Value init = qc.value; // never compile predicates with empty sequence as context value (#1016) if (init != null && init.isEmpty()) qc.value = null; try { final int pl = preds.length; for (int p = 0; p < pl; ++p) preds[p] = preds[p].compile(qc, scp).optimizeEbv(qc, scp); return this; } finally { qc.value = init; } }
/** * Optimizes descendant-or-self steps and static types. * * @param ctx query context */ void optSteps(final QueryContext ctx) { boolean opt = false; Expr[] st = steps; for (int l = 1; l < st.length; ++l) { if (!(st[l - 1] instanceof Step && st[l] instanceof Step)) continue; final Step prev = (Step) st[l - 1]; final Step curr = (Step) st[l]; if (!prev.simple(DESCORSELF, false)) continue; if (curr.axis == CHILD && !curr.has(Flag.FCS)) { // descendant-or-self::node()/child::X -> descendant::X final int sl = st.length; final Expr[] tmp = new Expr[sl - 1]; System.arraycopy(st, 0, tmp, 0, l - 1); System.arraycopy(st, l, tmp, l - 1, sl - l); st = tmp; curr.axis = DESC; opt = true; } else if (curr.axis == ATTR && !curr.has(Flag.FCS)) { // descendant-or-self::node()/@X -> descendant-or-self::*/@X prev.test = new NameTest(false); opt = true; } } if (opt) ctx.compInfo(OPTDESC); // set atomic type for single attribute steps to speedup predicate tests if (root == null && st.length == 1 && st[0] instanceof Step) { final Step curr = (Step) st[0]; if (curr.axis == ATTR && curr.test.mode == Mode.STD) curr.type = SeqType.NOD_ZO; } steps = st; }
/** * Sets a new root expression and eliminates a superfluous context item. * * @param ctx query context * @param rt root expression */ private void setRoot(final QueryContext ctx, final Expr rt) { root = rt; if (root instanceof Context) { ctx.compInfo(OPTREMCTX); root = null; } }
/** * Extracts entries from the archive. * * @param ctx query context * @return text entries * @throws QueryException query exception */ private TokenList extract(final QueryContext ctx) throws QueryException { final B64 archive = (B64) checkType(checkItem(expr[0], ctx), AtomType.B64); TokenSet hs = null; if (expr.length > 1) { // filter result to specified entries hs = new TokenSet(); final Iter names = ctx.iter(expr[1]); for (Item en; (en = names.next()) != null; ) { hs.add(checkElmStr(en).string(info)); } } final TokenList tl = new TokenList(); final ArchiveIn in = ArchiveIn.get(archive.input(info), info); try { while (in.more()) { final ZipEntry ze = in.entry(); if (ze.isDirectory()) continue; if (hs == null || hs.delete(token(ze.getName())) != 0) tl.add(in.read()); } } catch (final IOException ex) { Util.debug(ex); ARCH_FAIL.thrw(info, ex); } finally { in.close(); } return tl; }
/** * Performs the test-uris function. * * @param ctx query context * @return resulting value * @throws QueryException query exception */ private Item testUris(final QueryContext ctx) throws QueryException { checkCreate(ctx); final ArrayList<IO> inputs = new ArrayList<>(); final Iter ir = ctx.iter(expr[0]); for (Item it; (it = ir.next()) != null; ) inputs.add(checkPath(it, ctx)); return new Suite(ctx, info).test(inputs); }
/** * Returns the specified function literal. * * @param name function name * @param arity number of arguments * @param dyn dynamic invocation flag * @param ctx query context * @param ii input info * @return literal function expression * @throws QueryException query exception */ public static FItem get( final QNm name, final long arity, final boolean dyn, final QueryContext ctx, final InputInfo ii) throws QueryException { final Expr[] args = new Expr[(int) arity]; final Var[] vars = new Var[args.length]; for (int i = 0; i < args.length; i++) { vars[i] = ctx.uniqueVar(ii, null); args[i] = new VarRef(ii, vars[i]); } final TypedFunc f = get(name, args, dyn, ctx, ii); if (f == null) { if (!dyn) FUNCUNKNOWN.thrw(ii, name + "#" + arity); return null; } // compile the function if it hasn't been done statically if (dyn && f.fun instanceof UserFuncCall) { final UserFunc usf = ((UserFuncCall) f.fun).func(); if (usf != null && usf.declared) usf.compile(ctx); } final FuncType ft = f.type; return new FuncItem(name, vars, f.fun, ft, false); }
@Override Value[] evalArgs(final QueryContext ctx) throws QueryException { final int al = expr.length - 1; final Value[] args = new Value[al]; for (int a = 0; a < al; ++a) args[a] = ctx.value(expr[a]); return args; }
/** * Returns a serializer for the given output stream. Optional output declarations within the query * will be included in the serializer instance. * * @param os output stream * @return serializer instance * @throws IOException query exception * @throws QueryException query exception */ public Serializer getSerializer(final OutputStream os) throws IOException, QueryException { compile(); try { return Serializer.get(os, qc.serParams()); } catch (final QueryIOException ex) { throw ex.getCause(); } }
/** * Parses and returns an xquery expression. * * @param cmd referring command; if specified, the result must not be empty * @return path * @throws QueryException query exception */ private String xquery(final Cmd cmd) throws QueryException { consumeWS(); final StringBuilder sb = new StringBuilder(); if (!eoc()) { final QueryContext qc = new QueryContext(ctx); try { final QueryParser p = new QueryParser(parser.input, null, qc, null); p.pos = parser.pos; p.parseMain(); sb.append(parser.input.substring(parser.pos, p.pos)); parser.pos = p.pos; } finally { qc.close(); } } return finish(sb, cmd); }
/** * Performs the assert-equals function. * * @param ctx query context * @return resulting value * @throws QueryException query exception */ private Item assertEquals(final QueryContext ctx) throws QueryException { final byte[] str = expr.length < 3 ? null : checkStr(expr[2], ctx); final Iter iter1 = ctx.iter(expr[0]), iter2 = ctx.iter(expr[1]); final Compare comp = new Compare(info); Item it1, it2; int c = 1; while (true) { it1 = iter1.next(); it2 = iter2.next(); final boolean empty1 = it1 == null, empty2 = it2 == null; if (empty1 && empty2) return null; if (empty1 || empty2 || !comp.deep(it1.iter(), it2.iter())) break; c++; } if (str != null) throw UNIT_MESSAGE.get(info, str); throw new UnitException(info, UNIT_ASSERT_EQUALS, it1, it2, c); }
/** * Refreshes the view after a file has been saved. * * @param root root directory * @param ctx database context * @throws InterruptedException interruption */ void parse(final IOFile root, final Context ctx) throws InterruptedException { final long id = ++parseId; final HashSet<String> parsed = new HashSet<>(); final TreeMap<String, InputInfo> errs = new TreeMap<>(); // collect files to be parsed final ProjectCache pc = cache(root); final StringList mods = new StringList(), lmods = new StringList(); for (final String path : pc) { final IOFile file = new IOFile(path); if (file.hasSuffix(IO.XQSUFFIXES)) (file.hasSuffix(IO.XQMSUFFIX) ? lmods : mods).add(path); } mods.add(lmods); // parse modules for (final String path : mods) { if (id != parseId) throw new InterruptedException(); if (parsed.contains(path)) continue; final IOFile file = new IOFile(path); try (final TextInput ti = new TextInput(file)) { // parse query try (final QueryContext qc = new QueryContext(ctx)) { final String input = ti.cache().toString(); final boolean lib = QueryProcessor.isLibrary(input); qc.parse(input, lib, path, null); // parsing was successful: remember path parsed.add(path); for (final byte[] mod : qc.modParsed) parsed.add(Token.string(mod)); } catch (final QueryException ex) { // parsing failed: remember path final InputInfo ii = ex.info(); errs.put(path, ii); parsed.add(ii.path()); } } catch (final IOException ex) { // file may not be accessible Util.debug(ex); } } errors = errs; }
@Override public FuncValues getValues(QueryContext context, AtomicReaderContext readerContext) throws IOException { if (context.get(this) == null) { SolrRequestInfo requestInfo = SolrRequestInfo.getRequestInfo(); throw new SolrException( SolrException.ErrorCode.BAD_REQUEST, "testfunc: unweighted value source detected. delegate=" + source + " request=" + (requestInfo == null ? "null" : requestInfo.getReq())); } return source.getValues(context, readerContext); }
@Override public Expr optimize(final QueryContext ctx, final VarScope scp) throws QueryException { if (root instanceof Context) { ctx.compInfo(OPTREMCTX); root = null; } for (final Expr e : steps) { // check for empty steps if (e.isEmpty()) return optPre(null, ctx); } return this; }
/** * Performs the test function. * * @param ctx query context * @return resulting value * @throws QueryException query exception */ private Item test(final QueryContext ctx) throws QueryException { final Unit unit = new Unit(ctx, info); if (expr.length == 0) return unit.test(sc); final ArrayList<StaticFunc> funcs = new ArrayList<>(); final Iter ir = ctx.iter(expr[0]); for (Item it; (it = ir.next()) != null; ) { final FItem fi = checkFunc(it, ctx); if (fi.funcName() != null) { final StaticFunc sf = ctx.funcs.get(fi.funcName(), fi.arity(), null, true); if (sf != null) funcs.add(sf); } } return unit.test(sc, funcs); }
public FilterBindingsCursor( QueryContext context, Cursor input, int bindingPosition, int depth, List<? extends TPreparedExpression> expressions, ExpressionAdapter<TPreparedExpression, TEvaluatableExpression> expressionAdapter) { super(input, bindingPosition, depth); this.storeAdapter = context.getStore(); this.expressionAdapter = expressionAdapter; for (TPreparedExpression field : expressions) { TEvaluatableExpression eval = expressionAdapter.evaluate(field, context); fieldEvals.add(eval); } }
/** * Creates a new archive. * * @param ctx query context * @return archive * @throws QueryException query exception */ private B64 create(final QueryContext ctx) throws QueryException { final Iter entr = ctx.iter(expr[0]); final Iter cont = ctx.iter(expr[1]); final Item opt = expr.length > 2 ? expr[2].item(ctx, info) : null; final TokenMap map = new FuncParams(Q_OPTIONS, info).parse(opt); final byte[] f = map.get(FORMAT); final String format = f != null ? string(lc(f)) : "zip"; final ArchiveOut out = ArchiveOut.get(format, info); // check algorithm final byte[] alg = map.get(ALGORITHM); int level = ZipEntry.DEFLATED; if (alg != null) { if (format.equals("zip") && !eq(alg, STORED, DEFLATE) || format.equals("gzip") && !eq(alg, DEFLATE)) { ARCH_SUPP.thrw(info, ALGORITHM, alg); } if (eq(alg, STORED)) level = ZipEntry.STORED; else if (eq(alg, DEFLATE)) level = ZipEntry.DEFLATED; } out.level(level); try { int e = 0; int c = 0; Item en, cn; while (true) { en = entr.next(); cn = cont.next(); if (en == null || cn == null) break; if (out instanceof GZIPOut && c > 0) ARCH_ONE.thrw(info, format.toUpperCase(Locale.ENGLISH)); add(checkElmStr(en), cn, out, level); e++; c++; } // count remaining entries if (cn != null) do c++; while (cont.next() != null); if (en != null) do e++; while (entr.next() != null); if (e != c) throw ARCH_DIFF.thrw(info, e, c); } catch (final IOException ex) { Util.debug(ex); throw ARCH_FAIL.thrw(info, ex); } finally { out.close(); } return new B64(out.toArray()); }
/** * Merges expensive descendant-or-self::node() steps. * * @param qc query context * @return original or new expression */ private Expr mergeSteps(final QueryContext qc) { boolean opt = false; final int sl = steps.length; final ExprList stps = new ExprList(sl); for (int s = 0; s < sl; s++) { final Expr step = steps[s]; // check for simple descendants-or-self step with succeeding step if (s < sl - 1 && step instanceof Step) { final Step curr = (Step) step; if (curr.simple(DESCORSELF, false)) { // check succeeding step final Expr next = steps[s + 1]; // descendant-or-self::node()/child::X -> descendant::X if (simpleChild(next)) { ((Step) next).axis = DESC; opt = true; continue; } // descendant-or-self::node()/(X, Y) -> (descendant::X | descendant::Y) Expr e = mergeList(next); if (e != null) { steps[s + 1] = e; opt = true; continue; } // //(X, Y)[text()] -> (/descendant::X | /descendant::Y)[text()] if (next instanceof Filter && !next.has(Flag.FCS)) { final Filter f = (Filter) next; e = mergeList(f.root); if (e != null) { f.root = e; opt = true; continue; } } } } stps.add(step); } if (opt) { qc.compInfo(OPTDESC); return get(info, root, stps.finish()); } return this; }
/** * Updates an archive. * * @param ctx query context * @return updated archive * @throws QueryException query exception */ private B64 update(final QueryContext ctx) throws QueryException { final B64 archive = (B64) checkType(checkItem(expr[0], ctx), AtomType.B64); // entries to be updated final TokenObjMap<Item[]> hm = new TokenObjMap<Item[]>(); final Iter entr = ctx.iter(expr[1]); final Iter cont = ctx.iter(expr[2]); int e = 0; int c = 0; Item en, cn; while (true) { en = entr.next(); cn = cont.next(); if (en == null || cn == null) break; hm.add(checkElmStr(en).string(info), new Item[] {en, cn}); e++; c++; } // count remaining entries if (cn != null) do c++; while (cont.next() != null); if (en != null) do e++; while (entr.next() != null); if (e != c) ARCH_DIFF.thrw(info, e, c); final ArchiveIn in = ArchiveIn.get(archive.input(info), info); final ArchiveOut out = ArchiveOut.get(in.format(), info); try { if (in instanceof GZIPIn) ARCH_MODIFY.thrw(info, in.format().toUpperCase(Locale.ENGLISH)); // delete entries to be updated while (in.more()) if (!hm.contains(token(in.entry().getName()))) out.write(in); // add new and updated entries for (final byte[] h : hm) { if (h == null) continue; final Item[] it = hm.get(h); add(it[0], it[1], out, ZipEntry.DEFLATED); } } catch (final IOException ex) { Util.debug(ex); ARCH_FAIL.thrw(info, ex); } finally { in.close(); out.close(); } return new B64(out.toArray()); }
/** * Deletes files from an archive. * * @param ctx query context * @return updated archive * @throws QueryException query exception */ private B64 delete(final QueryContext ctx) throws QueryException { final B64 archive = (B64) checkType(checkItem(expr[0], ctx), AtomType.B64); // entries to be deleted final TokenObjMap<Item[]> hm = new TokenObjMap<Item[]>(); final Iter names = ctx.iter(expr[1]); for (Item en; (en = names.next()) != null; ) { hm.add(checkElmStr(en).string(info), null); } final ArchiveIn in = ArchiveIn.get(archive.input(info), info); final ArchiveOut out = ArchiveOut.get(in.format(), info); try { if (in instanceof GZIPIn) ARCH_MODIFY.thrw(info, in.format().toUpperCase(Locale.ENGLISH)); while (in.more()) if (!hm.contains(token(in.entry().getName()))) out.write(in); } catch (final IOException ex) { Util.debug(ex); ARCH_FAIL.thrw(info, ex); } finally { in.close(); out.close(); } return new B64(out.toArray()); }
@Override public B64 item(final QueryContext qc, final InputInfo ii) throws QueryException { checkCreate(qc); final IOFile root = new IOFile(toPath(0, qc).toString()); final ArchOptions opts = toOptions(1, Q_OPTIONS, new ArchOptions(), qc); final Iter entries; if (exprs.length > 2) { entries = qc.iter(exprs[2]); } else { final TokenList tl = new TokenList(); for (final String file : root.descendants()) tl.add(file); entries = StrSeq.get(tl).iter(); } final String format = opts.get(ArchOptions.FORMAT); final int level = level(opts); if (!root.isDir()) throw FILE_NO_DIR_X.get(info, root); try (final ArchiveOut out = ArchiveOut.get(format.toLowerCase(Locale.ENGLISH), info)) { out.level(level); try { while (true) { Item en = entries.next(); if (en == null) break; en = checkElemToken(en); final IOFile file = new IOFile(root, string(en.string(info))); if (!file.exists()) throw FILE_NOT_FOUND_X.get(info, file); if (file.isDir()) throw FILE_IS_DIR_X.get(info, file); add(en, new B64(file.read()), out, level, qc); } } catch (final IOException ex) { throw ARCH_FAIL_X.get(info, ex); } return new B64(out.finish()); } }
@Override public void createWeight(QueryContext context) throws IOException { context.put(this, this); }
/** * Returns an instance of a with the specified name and number of arguments, or {@code null}. * * @param name name of the function * @param args optional arguments * @param dyn compile-/run-time flag * @param ctx query context * @param ii input info * @return function instance * @throws QueryException query exception */ public static TypedFunc get( final QNm name, final Expr[] args, final boolean dyn, final QueryContext ctx, final InputInfo ii) throws QueryException { // get namespace and local name // parse data type constructors if (eq(name.uri(), XSURI)) { final byte[] ln = name.local(); final AtomType type = AtomType.find(name, false); if (type == null) { final Levenshtein ls = new Levenshtein(); for (final AtomType t : AtomType.values()) { if (t.par != null && t != AtomType.NOT && t != AtomType.AAT && t != AtomType.BIN && ls.similar(lc(ln), lc(t.string()), 0)) FUNSIMILAR.thrw(ii, name.string(), t.string()); } } // no constructor function found, or abstract type specified if (type == null || type == AtomType.NOT || type == AtomType.AAT) { FUNCUNKNOWN.thrw(ii, name.string()); } if (args.length != 1) FUNCTYPE.thrw(ii, name.string()); final SeqType to = SeqType.get(type, Occ.ZERO_ONE); return TypedFunc.constr(new Cast(ii, args[0], to), to); } // pre-defined functions final StandardFunc fun = Functions.get().get(name, args, ii); if (fun != null) { if (!ctx.sc.xquery3 && fun.xquery3()) FEATURE30.thrw(ii); for (final Function f : Function.UPDATING) { if (fun.sig == f) { ctx.updating(true); break; } } return new TypedFunc(fun, fun.sig.type(args.length)); } // user-defined function final TypedFunc tf = ctx.funcs.get(name, args, ii); if (tf != null) return tf; // Java function (only allowed with administrator permissions) final JavaMapping jf = JavaMapping.get(name, args, ctx, ii); if (jf != null) return TypedFunc.java(jf); // add user-defined function that has not been declared yet if (!dyn && FuncType.find(name) == null) return ctx.funcs.add(name, args, ii, ctx); // no function found return null; }
/** * Returns an equivalent expression which accesses an index. If the expression cannot be * rewritten, the original expression is returned. * * <p>The following types of queries can be rewritten (in the examples, the equality comparison is * used, which will be rewritten to {@link ValueAccess} instances): * * <pre> * 1. A[text() = '...'] -> IA('...') * 2. A[. = '...'] -> IA('...', A) * 3. text()[. = '...'] -> IA('...') * 4. A[B = '...'] -> IA('...', B)/parent::A * 1. A[B/text() = '...'] -> IA('...')/parent::B/parent::A * 2. A[B/C = '...'] -> IA('...', C)/parent::B/parent::A * 7. A[@a = '...'] -> IA('...', @a)/parent::A * 8. @a[. = '...'] -> IA('...', @a)</pre> * * Queries of type 1, 3, 5 will not yield any results if the string to be compared is empty. * * @param qc query context * @param rt root value * @return original or new expression * @throws QueryException query exception */ private Expr index(final QueryContext qc, final Value rt) throws QueryException { // only rewrite paths with data reference final Data data = rt.data(); if (data == null) return this; // cache index access costs IndexInfo index = null; // cheapest predicate and step int iPred = 0, iStep = 0; // check if path can be converted to an index access final int sl = steps.length; for (int s = 0; s < sl; s++) { // only accept descendant steps without positional predicates final Step step = axisStep(s); if (step == null || !step.axis.down || step.has(Flag.FCS)) break; // check if path is iterable (i.e., will be duplicate-free) final boolean iter = pathNodes(data, s) != null; final IndexContext ictx = new IndexContext(data, iter); // choose cheapest index access final int pl = step.preds.length; for (int p = 0; p < pl; p++) { final IndexInfo ii = new IndexInfo(ictx, qc, step); if (!step.preds[p].indexAccessible(ii)) continue; if (ii.costs == 0) { // no results... qc.compInfo(OPTNOINDEX, this); return Empty.SEQ; } if (index == null || index.costs > ii.costs) { index = ii; iPred = p; iStep = s; } } } // skip rewriting if no index access is possible, or if it is too expensive if (index == null || index.costs > data.meta.size) return this; // rewrite for index access qc.compInfo(index.info); // replace expressions for index access final Step indexStep = index.step; // collect remaining predicates final int pl = indexStep.preds.length; final ExprList newPreds = new ExprList(pl - 1); for (int p = 0; p < pl; p++) { if (p != iPred) newPreds.add(indexStep.preds[p]); } // invert steps that occur before index step and add them as predicate final Test test = InvDocTest.get(rt); final ExprList invSteps = new ExprList(); if (test != Test.DOC || !data.meta.uptodate || predSteps(data, iStep)) { for (int s = iStep; s >= 0; s--) { final Axis ax = axisStep(s).axis.invert(); if (s == 0) { // add document test for collections and axes other than ancestors if (test != Test.DOC || ax != Axis.ANC && ax != Axis.ANCORSELF) invSteps.add(Step.get(info, ax, test)); } else { final Step prev = axisStep(s - 1); invSteps.add(Step.get(info, ax, prev.test, prev.preds)); } } } if (!invSteps.isEmpty()) newPreds.add(get(info, null, invSteps.finish())); // create resulting expression final ExprList resultSteps = new ExprList(); final Expr resultRoot; if (index.expr instanceof Path) { final Path p = (Path) index.expr; resultRoot = p.root; resultSteps.add(p.steps); } else { resultRoot = index.expr; } if (!newPreds.isEmpty()) { int ls = resultSteps.size() - 1; Step step; if (ls < 0 || !(resultSteps.get(ls) instanceof Step)) { // add at least one self axis step step = Step.get(info, Axis.SELF, Test.NOD); ls++; } else { step = (Step) resultSteps.get(ls); } // add remaining predicates to last step resultSteps.set(ls, step.addPreds(newPreds.finish())); } // add remaining steps for (int s = iStep + 1; s < sl; s++) resultSteps.add(steps[s]); return get(info, resultRoot, resultSteps.finish()); }
/** * Returns a result value. * * @return result value * @throws QueryException query exception */ public Value value() throws QueryException { parse(); return qc.iter().value(); }