Examples of org.apache.bcel.generic.InstructionHandle

• org.apache.bcel.generic.InstructionHandle
  Instances of this class give users a handle to the instructions contained in an InstructionList. Instruction objects may be used more than once within a list, this is useful because it saves memory and may be much faster. Within an InstructionList an InstructionHandle object is wrapped around all instructions, i.e., it implements a cell in a doubly-linked list. From the outside only the next and the previous instruction (handle) are accessible. One can traverse the list via an Enumeration returned by InstructionList.elements(). @version $Id: InstructionHandle.java,v 1.1.1.1 2001/10/29 20:00:19 jvanzyl Exp $ @author M. Dahm @see Instruction @see BranchHandle @see InstructionList

      // Add a new local variable and store value
            boolean createLocal = _local == null;
      if (createLocal) {
                mapRegister(methodGen);
            }
      InstructionHandle storeInst =
                                  il.append(_type.STORE(_local.getIndex()));

            // If the local is just being created, mark the store as the start
            // of its live range.  Note that it might have been created by
            // initializeVariables already, which would have set the start of

     */
    public void translate(ClassGenerator classGen, MethodGenerator methodGen) {
  final InstructionList il = methodGen.getInstructionList();
  _test.translateDesynthesized(classGen, methodGen);
  // remember end of condition
  final InstructionHandle truec = il.getEnd();
  if (!_ignore) {
      translateContents(classGen, methodGen);
  }
  _test.backPatchFalseList(il.append(NOP));
  _test.backPatchTrueList(truec.getNext());
    }

  final BranchHandle ifBlock3 = il.append(new IFEQ(null));
  il.append(methodGen.loadHandler());
  name.setEnd(il.append(new ALOAD(name.getIndex())));
  il.append(methodGen.endElement());

  final InstructionHandle end = il.append(NOP);
  ifBlock1.setTarget(end);
  ifBlock3.setTarget(end);
  methodGen.removeLocalVariable(name);
  methodGen.removeLocalVariable(length);
    }

  // next element will hold a handle to the beginning of next
  // When/Otherwise if test on current When fails
  BranchHandle nextElement = null;
  List exitHandles = new ArrayList();
  InstructionHandle exit = null;

  Iterator whens = whenElements.iterator();
  while (whens.hasNext()) {
      final When when = (When)whens.next();
      final Expression test = when.getTest();

      InstructionHandle truec = il.getEnd();

      if (nextElement != null)
    nextElement.setTarget(il.append(NOP));
      test.translateDesynthesized(classGen, methodGen);

      if (test instanceof FunctionCall) {
    FunctionCall call = (FunctionCall)test;
    try {
        Type type = call.typeCheck(getParser().getSymbolTable());
        if (type != Type.Boolean) {
      test._falseList.add(il.append(new IFEQ(null)));
        }
    }
    catch (TypeCheckError e) {
        // handled later!
    }
      }
      // remember end of condition
      truec = il.getEnd();

      // The When object should be ignored completely in case it tests
      // for the support of a non-available element
      if (!when.ignore()) when.translateContents(classGen, methodGen);

      // goto exit after executing the body of when
      exitHandles.add(il.append(new GOTO(null)));
      if (whens.hasNext() || otherwise != null) {
    nextElement = il.append(new GOTO(null));
    test.backPatchFalseList(nextElement);
      }
      else
    test.backPatchFalseList(exit = il.append(NOP));
      test.backPatchTrueList(truec.getNext());
  }

  // Translate any <xsl:otherwise> element
  if (otherwise != null) {
      nextElement.setTarget(il.append(NOP));

              GET_PARENT_SIG);
  final int getType = cpg.addInterfaceMethodref(DOM_INTF,
                  "getExpandedTypeID",
                                                      "(I)I");

  InstructionHandle begin = il.append(methodGen.loadDOM());
  il.append(SWAP);
  il.append(new INVOKEINTERFACE(getParent, 2));
  if (_left instanceof AncestorPattern) {
      il.append(methodGen.loadDOM());
      il.append(SWAP);

  }
  return _right.typeCheck(stable);
    }

    public void translate(ClassGenerator classGen, MethodGenerator methodGen) {
  InstructionHandle parent;
  final ConstantPoolGen cpg = classGen.getConstantPool();
  final InstructionList il = methodGen.getInstructionList();

  /*
   * The scope of this local var must be the entire method since

  final int n = _elements.size();
  final Iterator oldIter = oldList.iterator();
  final Iterator newIter = newList.iterator();

  while (oldIter.hasNext()) {
      final InstructionHandle oldIh = (InstructionHandle) oldIter.next();
      final InstructionHandle newIh = (InstructionHandle) newIter.next();

      for (int i = 0; i < n; i++) {
    if (_elements.elementAt(i) == oldIh) {
        result.add(newIh);
    }

  // The body of this code can get very large - large than can be handled
  // by a single IFNE(body.getStart()) instruction - need workaround:
        final BranchHandle ifeq = ilLoop.append(new IFLT(null));
  final BranchHandle loop = ilLoop.append(new GOTO_W(null));
  ifeq.setTarget(ilLoop.append(RETURN));   // applyTemplates() ends here!
  final InstructionHandle ihLoop = ilLoop.getStart();

        current.setStart(mainIL.append(new GOTO_W(ihLoop)));

        // Live range of "current" ends at end of loop
        current.setEnd(loop);

  // Compile default handling of elements (traverse children)
  InstructionList ilRecurse =
      compileDefaultRecursion(classGen, methodGen, ihLoop);
  InstructionHandle ihRecurse = ilRecurse.getStart();

  // Compile default handling of text/attribute nodes (output text)
  InstructionList ilText =
      compileDefaultText(classGen, methodGen, ihLoop);
  InstructionHandle ihText = ilText.getStart();

  // Distinguish attribute/element/namespace tests for further processing
  final int[] types = new int[DTM.NTYPES + names.size()];
  for (int i = 0; i < types.length; i++) {
      types[i] = i;
  }

  // Initialize isAttribute[] and isNamespace[] arrays
  final boolean[] isAttribute = new boolean[types.length];
  final boolean[] isNamespace = new boolean[types.length];
  for (int i = 0; i < names.size(); i++) {
      final String name = (String)names.elementAt(i);
      isAttribute[i + DTM.NTYPES] = isAttributeName(name);
      isNamespace[i + DTM.NTYPES] = isNamespaceName(name);
  }

  // Compile all templates - regardless of pattern type
  compileTemplates(classGen, methodGen, ihLoop);

  // Handle template with explicit "*" pattern
  final TestSeq elemTest = _testSeq[DTM.ELEMENT_NODE];
  InstructionHandle ihElem = ihRecurse;
  if (elemTest != null)
      ihElem = elemTest.compile(classGen, methodGen, ihRecurse);

  // Handle template with explicit "@*" pattern
  final TestSeq attrTest = _testSeq[DTM.ATTRIBUTE_NODE];
  InstructionHandle ihAttr = ihText;
  if (attrTest != null)
      ihAttr = attrTest.compile(classGen, methodGen, ihAttr);

  // Do tests for id() and key() patterns first
  InstructionList ilKey = null;
  if (_idxTestSeq != null) {
      loop.setTarget(_idxTestSeq.compile(classGen, methodGen, body.getStart()));
      ilKey = _idxTestSeq.getInstructionList();
  }
  else {
      loop.setTarget(body.getStart());
  }

  // If there is a match on node() we need to replace ihElem
  // and ihText if the priority of node() is higher
  if (_childNodeTestSeq != null) {
      // Compare priorities of node() and "*"
      double nodePrio = _childNodeTestSeq.getPriority();
      int    nodePos  = _childNodeTestSeq.getPosition();
      double elemPrio = (0 - Double.MAX_VALUE);
      int    elemPos  = Integer.MIN_VALUE;

      if (elemTest != null) {
    elemPrio = elemTest.getPriority();
    elemPos  = elemTest.getPosition();
      }
      if (elemPrio == Double.NaN || elemPrio < nodePrio ||
    (elemPrio == nodePrio && elemPos < nodePos))
      {
    ihElem = _childNodeTestSeq.compile(classGen, methodGen, ihLoop);
      }

      // Compare priorities of node() and text()
      final TestSeq textTest = _testSeq[DTM.TEXT_NODE];
      double textPrio = (0 - Double.MAX_VALUE);
      int    textPos  = Integer.MIN_VALUE;

      if (textTest != null) {
    textPrio = textTest.getPriority();
    textPos  = textTest.getPosition();
      }
      if (textPrio == Double.NaN || textPrio < nodePrio ||
          (textPrio == nodePrio && textPos < nodePos))
      {
    ihText = _childNodeTestSeq.compile(classGen, methodGen, ihLoop);
    _testSeq[DTM.TEXT_NODE] = _childNodeTestSeq;
      }
  }

  // Handle templates with "ns:*" pattern
  InstructionHandle elemNamespaceHandle = ihElem;
  InstructionList nsElem = compileNamespaces(classGen, methodGen,
               isNamespace, isAttribute,
               false, ihElem);
  if (nsElem != null) elemNamespaceHandle = nsElem.getStart();

  // Handle templates with "ns:@*" pattern
  InstructionHandle attrNamespaceHandle = ihAttr;
  InstructionList nsAttr = compileNamespaces(classGen, methodGen,
               isNamespace, isAttribute,
               true, ihAttr);
  if (nsAttr != null) attrNamespaceHandle = nsAttr.getStart();

  // Handle templates with "ns:elem" or "ns:@attr" pattern
  final InstructionHandle[] targets = new InstructionHandle[types.length];
  for (int i = DTM.NTYPES; i < targets.length; i++) {
      final TestSeq testSeq = _testSeq[i];
      // Jump straight to namespace tests ?
      if (isNamespace[i]) {
    if (isAttribute[i])
        targets[i] = attrNamespaceHandle;
    else
        targets[i] = elemNamespaceHandle;
      }
      // Test first, then jump to namespace tests
      else if (testSeq != null) {
    if (isAttribute[i])
        targets[i] = testSeq.compile(classGen, methodGen,
             attrNamespaceHandle);
    else
        targets[i] = testSeq.compile(classGen, methodGen,
             elemNamespaceHandle);
      }
      else {
    targets[i] = ihLoop;
      }
  }


  // Handle pattern with match on root node - default: traverse children
  targets[DTM.ROOT_NODE] = _rootPattern != null
      ? getTemplateInstructionHandle(_rootPattern.getTemplate())
      : ihRecurse;

        // Handle pattern with match on root node - default: traverse children
  targets[DTM.DOCUMENT_NODE] = _rootPattern != null
      ? getTemplateInstructionHandle(_rootPattern.getTemplate())
      : ihRecurse;

  // Handle any pattern with match on text nodes - default: output text
  targets[DTM.TEXT_NODE] = _testSeq[DTM.TEXT_NODE] != null
      ? _testSeq[DTM.TEXT_NODE].compile(classGen, methodGen, ihText)
      : ihText;

  // This DOM-type is not in use - default: process next node
  targets[DTM.NAMESPACE_NODE] = ihLoop;

  // Match unknown element in DOM - default: check for namespace match
  targets[DTM.ELEMENT_NODE] = elemNamespaceHandle;

  // Match unknown attribute in DOM - default: check for namespace match
  targets[DTM.ATTRIBUTE_NODE] = attrNamespaceHandle;

  // Match on processing instruction - default: process next node
  InstructionHandle ihPI = ihLoop;
  if (_childNodeTestSeq != null) ihPI = ihElem;
  if (_testSeq[DTM.PROCESSING_INSTRUCTION_NODE] != null)
      targets[DTM.PROCESSING_INSTRUCTION_NODE] =
    _testSeq[DTM.PROCESSING_INSTRUCTION_NODE].
    compile(classGen, methodGen, ihPI);
  else
      targets[DTM.PROCESSING_INSTRUCTION_NODE] = ihPI;

  // Match on comments - default: process next node
  InstructionHandle ihComment = ihLoop;
  if (_childNodeTestSeq != null) ihComment = ihElem;
  targets[DTM.COMMENT_NODE] = _testSeq[DTM.COMMENT_NODE] != null
      ? _testSeq[DTM.COMMENT_NODE].compile(classGen, methodGen, ihComment)
      : ihComment;

      // This DOM-type is not in use - default: process next node
  targets[DTM.CDATA_SECTION_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.DOCUMENT_FRAGMENT_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.DOCUMENT_TYPE_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.ENTITY_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.ENTITY_REFERENCE_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.NOTATION_NODE] = ihLoop;


  // Now compile test sequences for various match patterns:
  for (int i = DTM.NTYPES; i < targets.length; i++) {
      final TestSeq testSeq = _testSeq[i];
      // Jump straight to namespace tests ?
      if ((testSeq == null) || (isNamespace[i])) {
    if (isAttribute[i])
        targets[i] = attrNamespaceHandle;
    else
        targets[i] = elemNamespaceHandle;
      }
      // Match on node type
      else {
    if (isAttribute[i])
        targets[i] = testSeq.compile(classGen, methodGen,
             attrNamespaceHandle);
    else
        targets[i] = testSeq.compile(classGen, methodGen,
             elemNamespaceHandle);
      }
  }

  if (ilKey != null) body.insert(ilKey);

  // Append first code in applyTemplates() - get type of current node
  final int getType = cpg.addInterfaceMethodref(DOM_INTF,
                  "getExpandedTypeID",
                                                      "(I)I");
  body.append(methodGen.loadDOM());
  body.append(new ILOAD(_currentIndex));
  body.append(new INVOKEINTERFACE(getType, 2));

  // Append switch() statement - main dispatch loop in applyTemplates()
  InstructionHandle disp = body.append(new SWITCH(types, targets, ihLoop));

  // Append all the "case:" statements
  appendTestSequences(body);
  // Append the actual template code
  appendTemplateCode(body);

  // Create an instruction list that contains the default next-node
  // iteration
  final InstructionList ilLoop = new InstructionList();
    ilLoop.append(RETURN);
  final InstructionHandle ihLoop = ilLoop.getStart();

  // Compile default handling of elements (traverse children)
  InstructionList ilRecurse =
      compileDefaultRecursion(classGen, methodGen, ihLoop);
  InstructionHandle ihRecurse = ilRecurse.getStart();

  // Compile default handling of text/attribute nodes (output text)
  InstructionList ilText =
      compileDefaultText(classGen, methodGen, ihLoop);
  InstructionHandle ihText = ilText.getStart();

  // Distinguish attribute/element/namespace tests for further processing
  final int[] types = new int[DTM.NTYPES + names.size()];
  for (int i = 0; i < types.length; i++) {
      types[i] = i;
  }

  final boolean[] isAttribute = new boolean[types.length];
  final boolean[] isNamespace = new boolean[types.length];
  for (int i = 0; i < names.size(); i++) {
      final String name = (String)names.elementAt(i);
      isAttribute[i+DTM.NTYPES] = isAttributeName(name);
      isNamespace[i+DTM.NTYPES] = isNamespaceName(name);
  }

  // Compile all templates - regardless of pattern type
  compileTemplateCalls(classGen, methodGen, ihLoop, min, max);

  // Handle template with explicit "*" pattern
  final TestSeq elemTest = _testSeq[DTM.ELEMENT_NODE];
  InstructionHandle ihElem = ihRecurse;
  if (elemTest != null) {
      ihElem = elemTest.compile(classGen, methodGen, ihLoop);
  }

  // Handle template with explicit "@*" pattern
  final TestSeq attrTest = _testSeq[DTM.ATTRIBUTE_NODE];
  InstructionHandle ihAttr = ihLoop;
  if (attrTest != null) {
      ihAttr = attrTest.compile(classGen, methodGen, ihAttr);
  }

  // Do tests for id() and key() patterns first
  InstructionList ilKey = null;
  if (_idxTestSeq != null) {
      ilKey = _idxTestSeq.getInstructionList();
  }

  // If there is a match on node() we need to replace ihElem
  // and ihText if the priority of node() is higher
  if (_childNodeTestSeq != null) {
      // Compare priorities of node() and "*"
      double nodePrio = _childNodeTestSeq.getPriority();
      int    nodePos  = _childNodeTestSeq.getPosition();
      double elemPrio = (0 - Double.MAX_VALUE);
      int    elemPos  = Integer.MIN_VALUE;

      if (elemTest != null) {
    elemPrio = elemTest.getPriority();
    elemPos  = elemTest.getPosition();
      }

      if (elemPrio == Double.NaN || elemPrio < nodePrio ||
    (elemPrio == nodePrio && elemPos < nodePos))
      {
    ihElem = _childNodeTestSeq.compile(classGen, methodGen, ihLoop);
      }

      // Compare priorities of node() and text()
      final TestSeq textTest = _testSeq[DTM.TEXT_NODE];
      double textPrio = (0 - Double.MAX_VALUE);
      int    textPos  = Integer.MIN_VALUE;

      if (textTest != null) {
    textPrio = textTest.getPriority();
    textPos  = textTest.getPosition();
      }

      if (textPrio == Double.NaN || textPrio < nodePrio ||
          (textPrio == nodePrio && textPos < nodePos))
      {
    ihText = _childNodeTestSeq.compile(classGen, methodGen, ihLoop);
    _testSeq[DTM.TEXT_NODE] = _childNodeTestSeq;
      }
  }

  // Handle templates with "ns:*" pattern
  InstructionHandle elemNamespaceHandle = ihElem;
  InstructionList nsElem = compileNamespaces(classGen, methodGen,
               isNamespace, isAttribute,
               false, ihElem);
  if (nsElem != null) elemNamespaceHandle = nsElem.getStart();

  // Handle templates with "ns:@*" pattern
  InstructionList nsAttr = compileNamespaces(classGen, methodGen,
               isNamespace, isAttribute,
               true, ihAttr);
  InstructionHandle attrNamespaceHandle = ihAttr;
  if (nsAttr != null) attrNamespaceHandle = nsAttr.getStart();

  // Handle templates with "ns:elem" or "ns:@attr" pattern
  final InstructionHandle[] targets = new InstructionHandle[types.length];
  for (int i = DTM.NTYPES; i < targets.length; i++) {
      final TestSeq testSeq = _testSeq[i];
      // Jump straight to namespace tests ?
      if (isNamespace[i]) {
    if (isAttribute[i])
        targets[i] = attrNamespaceHandle;
    else
        targets[i] = elemNamespaceHandle;
      }
      // Test first, then jump to namespace tests
      else if (testSeq != null) {
    if (isAttribute[i])
        targets[i] = testSeq.compile(classGen, methodGen,
             attrNamespaceHandle);
    else
        targets[i] = testSeq.compile(classGen, methodGen,
             elemNamespaceHandle);
      }
      else {
    targets[i] = ihLoop;
      }
  }

  // Handle pattern with match on root node - default: traverse children
  targets[DTM.ROOT_NODE] = _rootPattern != null
      ? getTemplateInstructionHandle(_rootPattern.getTemplate())
      : ihRecurse;
  // Handle pattern with match on root node - default: traverse children
  targets[DTM.DOCUMENT_NODE] = _rootPattern != null
      ? getTemplateInstructionHandle(_rootPattern.getTemplate())
      : ihRecurse;    // %HZ%:  Was ihLoop in XSLTC_DTM branch

  // Handle any pattern with match on text nodes - default: loop
  targets[DTM.TEXT_NODE] = _testSeq[DTM.TEXT_NODE] != null
      ? _testSeq[DTM.TEXT_NODE].compile(classGen, methodGen, ihText)
      : ihText;

  // This DOM-type is not in use - default: process next node
  targets[DTM.NAMESPACE_NODE] = ihLoop;

  // Match unknown element in DOM - default: check for namespace match
  targets[DTM.ELEMENT_NODE] = elemNamespaceHandle;

  // Match unknown attribute in DOM - default: check for namespace match
  targets[DTM.ATTRIBUTE_NODE] = attrNamespaceHandle;

  // Match on processing instruction - default: loop
  InstructionHandle ihPI = ihLoop;
  if (_childNodeTestSeq != null) ihPI = ihElem;
  if (_testSeq[DTM.PROCESSING_INSTRUCTION_NODE] != null) {
      targets[DTM.PROCESSING_INSTRUCTION_NODE] =
    _testSeq[DTM.PROCESSING_INSTRUCTION_NODE].
    compile(classGen, methodGen, ihPI);
  }
  else {
      targets[DTM.PROCESSING_INSTRUCTION_NODE] = ihPI;
  }

  // Match on comments - default: process next node
  InstructionHandle ihComment = ihLoop;
  if (_childNodeTestSeq != null) ihComment = ihElem;
  targets[DTM.COMMENT_NODE] = _testSeq[DTM.COMMENT_NODE] != null
      ? _testSeq[DTM.COMMENT_NODE].compile(classGen, methodGen, ihComment)
      : ihComment;

          // This DOM-type is not in use - default: process next node
  targets[DTM.CDATA_SECTION_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.DOCUMENT_FRAGMENT_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.DOCUMENT_TYPE_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.ENTITY_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.ENTITY_REFERENCE_NODE] = ihLoop;

  // This DOM-type is not in use - default: process next node
  targets[DTM.NOTATION_NODE] = ihLoop;



  // Now compile test sequences for various match patterns:
  for (int i = DTM.NTYPES; i < targets.length; i++) {
      final TestSeq testSeq = _testSeq[i];
      // Jump straight to namespace tests ?
      if ((testSeq == null) || (isNamespace[i])) {
    if (isAttribute[i])
        targets[i] = attrNamespaceHandle;
    else
        targets[i] = elemNamespaceHandle;
      }
      // Match on node type
      else {
    if (isAttribute[i])
        targets[i] = testSeq.compile(classGen, methodGen,
             attrNamespaceHandle);
    else
        targets[i] = testSeq.compile(classGen, methodGen,
             elemNamespaceHandle);
      }
  }

  if (ilKey != null) body.insert(ilKey);

  // Append first code in applyTemplates() - get type of current node
  final int getType = cpg.addInterfaceMethodref(DOM_INTF,
                  "getExpandedTypeID",
                                                      "(I)I");
  body.append(methodGen.loadDOM());
  body.append(new ILOAD(_currentIndex));
  body.append(new INVOKEINTERFACE(getType, 2));

  // Append switch() statement - main dispatch loop in applyTemplates()
  InstructionHandle disp = body.append(new SWITCH(types,targets,ihLoop));

  // Append all the "case:" statements
  appendTestSequences(body);
  // Append the actual template code
  appendTemplateCode(body);

      * Peephole optimization.
      */
    private void peepHoleOptimization(MethodGenerator methodGen) {
        InstructionList il = methodGen.getInstructionList();
        InstructionFinder find = new InstructionFinder(il);
  InstructionHandle ih;
  String pattern;

  // LoadInstruction, POP => (removed)
  pattern = "LoadInstruction POP";
  for (Iterator iter = find.search(pattern); iter.hasNext();) {