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[/] [openrisc/] [trunk/] [gnu-dev/] [or1k-gcc/] [libjava/] [classpath/] [gnu/] [xml/] [xpath/] [Selector.java] - Rev 769
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/* Selector.java -- Copyright (C) 2004,2006 Free Software Foundation, Inc. This file is part of GNU Classpath. GNU Classpath is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 2, or (at your option) any later version. GNU Classpath 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 General Public License for more details. You should have received a copy of the GNU General Public License along with GNU Classpath; see the file COPYING. If not, write to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. Linking this library statically or dynamically with other modules is making a combined work based on this library. Thus, the terms and conditions of the GNU General Public License cover the whole combination. As a special exception, the copyright holders of this library give you permission to link this library with independent modules to produce an executable, regardless of the license terms of these independent modules, and to copy and distribute the resulting executable under terms of your choice, provided that you also meet, for each linked independent module, the terms and conditions of the license of that module. An independent module is a module which is not derived from or based on this library. If you modify this library, you may extend this exception to your version of the library, but you are not obligated to do so. If you do not wish to do so, delete this exception statement from your version. */ package gnu.xml.xpath; import gnu.java.lang.CPStringBuilder; import java.util.ArrayList; import java.util.Collection; import java.util.Iterator; import java.util.LinkedHashSet; import java.util.List; import java.util.Set; import javax.xml.XMLConstants; import javax.xml.namespace.QName; import org.w3c.dom.Attr; import org.w3c.dom.NamedNodeMap; import org.w3c.dom.Node; /** * A single component of a location path. * * @author <a href='mailto:dog@gnu.org'>Chris Burdess</a> */ public final class Selector extends Path { public static final int ANCESTOR = 0; public static final int ANCESTOR_OR_SELF = 1; public static final int ATTRIBUTE = 2; public static final int CHILD = 3; public static final int DESCENDANT = 4; public static final int DESCENDANT_OR_SELF = 5; public static final int FOLLOWING = 6; public static final int FOLLOWING_SIBLING = 7; public static final int NAMESPACE = 8; public static final int PARENT = 9; public static final int PRECEDING = 10; public static final int PRECEDING_SIBLING = 11; public static final int SELF = 12; /** * Axis to select nodes in. */ final int axis; /** * List of tests to perform on candidates. */ final Test[] tests; public Selector(int axis, List<? extends Test> tests) { this.axis = axis; int len = tests.size(); this.tests = new Test[(len == 0) ? 1 : len]; if (len > 0) tests.toArray(this.tests); else this.tests[0] = new NodeTypeTest((short) 0); if (axis == NAMESPACE && this.tests[0] instanceof NameTest) { NameTest nt = (NameTest) this.tests[0]; this.tests[0] = new NamespaceTest(nt.qName, nt.anyLocalName, nt.any); } } /** * Returns the list of tests to perform on candidates. */ public Test[] getTests() { return tests; } public boolean matches(Node context) { // If called directly, selector is the top level of the path return matches(context, getContextPosition(context), getContextSize(context)); } boolean matches(Node context, int pos, int len) { short nodeType = context.getNodeType(); switch (axis) { case CHILD: if (nodeType == Node.ATTRIBUTE_NODE) return false; break; case ATTRIBUTE: case NAMESPACE: if (nodeType != Node.ATTRIBUTE_NODE) return false; break; case DESCENDANT_OR_SELF: return true; default: return false; } for (int j = 0; j < tests.length && len > 0; j++) { Test test = tests[j]; if (!test.matches(context, pos, len)) return false; } return true; } private int getContextPosition(Node ctx) { int pos = 1; for (ctx = ctx.getPreviousSibling(); ctx != null; ctx = ctx.getPreviousSibling()) { if (tests[0].matches(ctx, 1, 1)) pos++; } return pos; } private int getContextSize(Node ctx) { if (ctx.getNodeType() == Node.ATTRIBUTE_NODE) { Node owner = ((Attr) ctx).getOwnerElement(); return owner.getAttributes().getLength(); } int count = 1; Node sib = ctx.getPreviousSibling(); for (; sib != null; sib = sib.getPreviousSibling()) { if (tests[0].matches(ctx, 1, 1)) count++; } sib = ctx.getNextSibling(); for (; sib != null; sib = sib.getNextSibling()) { if (tests[0].matches(ctx, 1, 1)) count++; } return count; } @Override public Object evaluate(Node context, int pos, int len) { Set<Node> acc = new LinkedHashSet<Node>(); addCandidates(context, acc); List<Node> candidates = new ArrayList<Node>(acc); List<Node> ret = filterCandidates(candidates, false); return ret; } Collection<Node> evaluate(Node context, Collection<Node> ns) { Set<Node> acc = new LinkedHashSet<Node>(); for (Iterator<Node> i = ns.iterator(); i.hasNext(); ) addCandidates(i.next(), acc); List<Node> candidates = new ArrayList<Node>(acc); List<Node> ret = filterCandidates(candidates, true); return ret; } /** * Filter the given list of candidates according to the node tests. */ List<Node> filterCandidates(List<Node> candidates, boolean cascade) { int len = candidates.size(); int tlen = tests.length; if (tlen > 0 && len > 0) { // Present the result of each successful generation to the next test for (int j = 0; j < tlen && len > 0; j++) { Test test = tests[j]; List<Node> successful = new ArrayList<Node>(len); for (int i = 0; i < len; i++) { Node node = candidates.get(i); if (cascade) { // Documents and DocumentFragments should be considered // if part of a location path where the axis involves // the SELF concept short nodeType = node.getNodeType(); if ((nodeType == Node.DOCUMENT_NODE || nodeType == Node.DOCUMENT_FRAGMENT_NODE) && (axis == DESCENDANT_OR_SELF || axis == ANCESTOR_OR_SELF || axis == SELF) && (tests.length == 1 && tests[0] instanceof NodeTypeTest && ((NodeTypeTest) tests[0]).type == (short) 0)) { successful.add(node); continue; } } if (test.matches(node, i + 1, len)) successful.add(node); } candidates = successful; len = candidates.size(); } } return candidates; } void addCandidates(Node context, Collection<Node> candidates) { // Build list of candidates switch (axis) { case CHILD: addChildNodes(context, candidates, false); break; case DESCENDANT: addChildNodes(context, candidates, true); break; case DESCENDANT_OR_SELF: candidates.add (context); addChildNodes(context, candidates, true); break; case PARENT: addParentNode(context, candidates, false); break; case ANCESTOR: addParentNode(context, candidates, true); break; case ANCESTOR_OR_SELF: candidates.add(context); addParentNode(context, candidates, true); break; case FOLLOWING_SIBLING: addFollowingNodes(context, candidates, false); break; case PRECEDING_SIBLING: addPrecedingNodes(context, candidates, false); break; case FOLLOWING: addFollowingNodes(context, candidates, true); break; case PRECEDING: addPrecedingNodes(context, candidates, true); break; case ATTRIBUTE: addAttributes(context, candidates); break; case NAMESPACE: addNamespaceAttributes(context, candidates); break; case SELF: candidates.add(context); break; } } void addChildNodes(Node context, Collection<Node> acc, boolean recurse) { Node child = context.getFirstChild(); while (child != null) { acc.add(child); if (recurse) addChildNodes(child, acc, recurse); child = child.getNextSibling(); } } void addParentNode(Node context, Collection<Node> acc, boolean recurse) { Node parent = (context.getNodeType() == Node.ATTRIBUTE_NODE) ? ((Attr) context).getOwnerElement() : context.getParentNode(); if (parent != null) { acc.add(parent); if (recurse) addParentNode(parent, acc, recurse); } } void addFollowingNodes(Node context, Collection<Node> acc, boolean recurse) { if (context != null && recurse) addChildNodes(context, acc, true); Node cur = (context.getNodeType() == Node.ATTRIBUTE_NODE) ? null : context.getNextSibling(); while (cur != null) { acc.add(cur); if (recurse) addChildNodes(cur, acc, true); cur = cur.getNextSibling(); } if (recurse) { while (context != null) { context = (context.getNodeType() == Node.ATTRIBUTE_NODE) ? ((Attr) context).getOwnerElement() : context.getParentNode(); if (context != null) { cur = context.getNextSibling(); while (cur != null) { acc.add(cur); if (recurse) addChildNodes(cur, acc, true); cur = cur.getNextSibling(); } } } } } void addPrecedingNodes(Node context, Collection<Node> acc, boolean recurse) { Node cur = (context.getNodeType() == Node.ATTRIBUTE_NODE) ? null : context.getPreviousSibling(); while (cur != null) { acc.add(cur); if (recurse) addChildNodes(cur, acc, true); cur = cur.getPreviousSibling(); } if (recurse) { cur = context; cur = (cur.getNodeType() == Node.ATTRIBUTE_NODE) ? ((Attr) cur).getOwnerElement() : cur.getParentNode(); if (cur != null) addPrecedingNodes(cur, acc, recurse); } } void addAttributes(Node context, Collection<Node> acc) { NamedNodeMap attrs = context.getAttributes(); if (attrs != null) { int attrLen = attrs.getLength(); for (int i = 0; i < attrLen; i++) { Node attr = attrs.item(i); if (!isNamespaceAttribute(attr)) { acc.add(attr); } } } } void addNamespaceAttributes(Node context, Collection<Node> acc) { NamedNodeMap attrs = context.getAttributes(); if (attrs != null) { int attrLen = attrs.getLength(); for (int i = 0; i < attrLen; i++) { Node attr = attrs.item(i); if (isNamespaceAttribute(attr)) acc.add(attr); } } } final boolean isNamespaceAttribute(Node node) { String uri = node.getNamespaceURI(); return (XMLConstants.XMLNS_ATTRIBUTE_NS_URI.equals(uri) || XMLConstants.XMLNS_ATTRIBUTE.equals(node.getPrefix()) || XMLConstants.XMLNS_ATTRIBUTE.equals(node.getNodeName())); } public Expr clone(Object context) { int len = tests.length; List<Test> tests2 = new ArrayList<Test>(len); for (int i = 0; i < len; i++) tests2.add(tests[i].clone(context)); return new Selector(axis, tests2); } public boolean references(QName var) { for (int i = 0; i < tests.length; i++) { if (tests[i].references(var)) return true; } return false; } public String toString() { CPStringBuilder buf = new CPStringBuilder(); switch (axis) { case ANCESTOR: buf.append("ancestor::"); break; case ANCESTOR_OR_SELF: buf.append("ancestor-or-self::"); break; case ATTRIBUTE: if (tests.length == 0 || (tests[0] instanceof NameTest)) buf.append('@'); else buf.append("attribute::"); break; case CHILD: //buf.append("child::"); break; case DESCENDANT: buf.append("descendant::"); break; case DESCENDANT_OR_SELF: buf.append("descendant-or-self::"); break; case FOLLOWING: buf.append("following::"); break; case FOLLOWING_SIBLING: buf.append("following-sibling::"); break; case NAMESPACE: buf.append("namespace::"); break; case PARENT: if (tests.length == 0 || (tests[0] instanceof NodeTypeTest && ((NodeTypeTest) tests[0]).type == 0)) return ".."; buf.append("parent::"); break; case PRECEDING: buf.append("preceding::"); break; case PRECEDING_SIBLING: buf.append("preceding-sibling::"); break; case SELF: if (tests.length == 0 || (tests[0] instanceof NodeTypeTest && ((NodeTypeTest) tests[0]).type == 0)) return "."; buf.append("self::"); break; } if (tests.length == 0) buf.append("[error]"); else { for (int i = 0; i < tests.length; i++) buf.append(tests[i]); } return buf.toString(); } }