Esempio n. 1
0
  /**
   * Returns a new path instance. A path implementation is chosen that works fastest for the given
   * steps.
   *
   * @param info input info
   * @param root root expression; can be {@code null}
   * @param steps steps
   * @return path instance
   */
  public static Path get(final InputInfo info, final Expr root, final Expr... steps) {
    // new list with steps
    final ExprList stps = new ExprList(steps.length);

    // merge nested paths
    Expr rt = root;
    if (rt instanceof Path) {
      final Path path = (Path) rt;
      stps.add(path.steps);
      rt = path.root;
    }
    // remove redundant context reference
    if (rt instanceof Context) rt = null;

    // add steps of input array
    final int sl = steps.length;
    for (int s = 0; s < sl; s++) {
      Expr step = steps[s];
      if (step instanceof Context) {
        // remove redundant context references
        if (sl > 1) continue;
        // single step: rewrite to axis step (required to sort results of path)
        step = Step.get(((Context) step).info, SELF, Test.NOD);
      } else if (step instanceof Filter) {
        // rewrite to axis step (can be evaluated faster than filter expression)
        final Filter f = (Filter) step;
        if (f.root instanceof Context) step = Step.get(f.info, SELF, Test.NOD, f.preds);
      }
      stps.add(step);
    }

    // check if all steps are axis steps
    boolean axes = true;
    final Expr[] st = stps.finish();
    for (final Expr step : st) axes &= step instanceof Step;

    // choose best implementation
    return axes
        ? iterative(rt, st) ? new IterPath(info, rt, st) : new CachedPath(info, rt, st)
        : new MixedPath(info, rt, st);
  }
Esempio n. 2
0
  /**
   * 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;
  }
Esempio n. 3
0
  /**
   * 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());
  }