Package com.sun.org.apache.xalan.internal.xsltc.compiler.util

Examples of com.sun.org.apache.xalan.internal.xsltc.compiler.util.MethodGenerator$LocalVariableRegistry


     * Compiles a constructor for the class <tt>_className</tt> that
     * inherits from {Any,Single,Multiple}NodeCounter. This constructor
     * simply calls the same constructor in the super class.
     */
    private void compileConstructor(ClassGenerator classGen) {
        MethodGenerator cons;
        final InstructionList il = new InstructionList();
        final ConstantPoolGen cpg = classGen.getConstantPool();

        cons = new MethodGenerator(ACC_PUBLIC,
                                   com.sun.org.apache.bcel.internal.generic.Type.VOID,
                                   new com.sun.org.apache.bcel.internal.generic.Type[] {
                                       Util.getJCRefType(TRANSLET_INTF_SIG),
                                       Util.getJCRefType(DOM_INTF_SIG),
                                       Util.getJCRefType(NODE_ITERATOR_SIG),
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  argNames[5] = "lang";
  argNames[6] = "case_order";


        InstructionList il = new InstructionList();
        final MethodGenerator constructor =
            new MethodGenerator(ACC_PUBLIC,
                                com.sun.org.apache.bcel.internal.generic.Type.VOID,
                                argTypes, argNames, "<init>",
                                className, il, cpg);

        // Push all parameters onto the stack and called super.<init>()
        il.append(ALOAD_0);
        il.append(ALOAD_1);
        il.append(ALOAD_2);
        il.append(new ALOAD(3));
        il.append(new ALOAD(4));
        il.append(new ALOAD(5));
  il.append(new ALOAD(6));
  il.append(new ALOAD(7));
        il.append(new INVOKESPECIAL(cpg.addMethodref(NODE_SORT_FACTORY,
            "<init>",
            "(" + DOM_INTF_SIG
                + STRING_SIG
                + TRANSLET_INTF_SIG
                + "[" + STRING_SIG
    + "[" + STRING_SIG
    + "[" + STRING_SIG
                + "[" + STRING_SIG + ")V")));
        il.append(RETURN);

        // Override the definition of makeNodeSortRecord()
        il = new InstructionList();
        final MethodGenerator makeNodeSortRecord =
            new MethodGenerator(ACC_PUBLIC,
                Util.getJCRefType(NODE_SORT_RECORD_SIG),
                new com.sun.org.apache.bcel.internal.generic.Type[] {
                    com.sun.org.apache.bcel.internal.generic.Type.INT,
                    com.sun.org.apache.bcel.internal.generic.Type.INT },
                new String[] { "node", "last" }, "makeNodeSortRecord",
                className, il, cpg);

        il.append(ALOAD_0);
        il.append(ILOAD_1);
        il.append(ILOAD_2);
        il.append(new INVOKESPECIAL(cpg.addMethodref(NODE_SORT_FACTORY,
            "makeNodeSortRecord", "(II)" + NODE_SORT_RECORD_SIG)));
        il.append(DUP);
        il.append(new CHECKCAST(cpg.addClass(sortRecordClass)));

        // Initialize closure in record class
        final int ndups = dups.size();
        for (int i = 0; i < ndups; i++) {
            final VariableRefBase varRef = (VariableRefBase) dups.get(i);
            final VariableBase var = varRef.getVariable();
            final Type varType = var.getType();

            il.append(DUP);

            // Get field from factory class
            il.append(ALOAD_0);
            il.append(new GETFIELD(
                cpg.addFieldref(className,
                    var.getEscapedName(), varType.toSignature())));

            // Put field in record class
            il.append(new PUTFIELD(
                cpg.addFieldref(sortRecordClass,
                    var.getEscapedName(), varType.toSignature())));
        }
        il.append(POP);
        il.append(ARETURN);

        constructor.setMaxLocals();
        constructor.setMaxStack();
        sortRecordFactory.addMethod(constructor);
        makeNodeSortRecord.setMaxLocals();
        makeNodeSortRecord.setMaxStack();
        sortRecordFactory.addMethod(makeNodeSortRecord);
        xsltc.dumpClass(sortRecordFactory.getJavaClass());

        return className;
    }
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                                    null, cpg.getConstantPool()));
                dups.add(varRef);
            }
        }

        MethodGenerator init = compileInit(sortObjects, sortRecord,
                                         cpg, className);
        MethodGenerator extract = compileExtract(sortObjects, sortRecord,
                                        cpg, className);
        sortRecord.addMethod(init);
        sortRecord.addMethod(extract);

        xsltc.dumpClass(sortRecord.getJavaClass());
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                                           NodeSortRecordGenerator sortRecord,
                                           ConstantPoolGen cpg,
                                           String className)
    {
        final InstructionList il = new InstructionList();
        final MethodGenerator init =
            new MethodGenerator(ACC_PUBLIC,
                                com.sun.org.apache.bcel.internal.generic.Type.VOID,
                                null, null, "<init>", className,
                                il, cpg);

        // Call the constructor in the NodeSortRecord superclass
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        final ConstantPoolGen cpg = classGen.getConstantPool();
        final InstructionList il = new InstructionList();
        final XSLTC xsltc = classGen.getParser().getXSLTC();

        // private boolean Translet.stripSpace(int type) - cannot be static
        final MethodGenerator stripSpace =
            new MethodGenerator(ACC_PUBLIC | ACC_FINAL ,
                        com.sun.org.apache.bcel.internal.generic.Type.BOOLEAN,
                        new com.sun.org.apache.bcel.internal.generic.Type[] {
                            Util.getJCRefType(DOM_INTF_SIG),
                            com.sun.org.apache.bcel.internal.generic.Type.INT,
                            com.sun.org.apache.bcel.internal.generic.Type.INT
                        },
                        new String[] { "dom","node","type" },
                        "stripSpace",classGen.getClassName(),il,cpg);

        classGen.addInterface("com/sun/org/apache/xalan/internal/xsltc/StripFilter");

        final int paramDom = stripSpace.getLocalIndex("dom");
        final int paramCurrent = stripSpace.getLocalIndex("node");
        final int paramType = stripSpace.getLocalIndex("type");

        BranchHandle strip[] = new BranchHandle[rules.size()];
        BranchHandle preserve[] = new BranchHandle[rules.size()];
        int sCount = 0;
        int pCount = 0;
View Full Code Here

        final ConstantPoolGen cpg = classGen.getConstantPool();
        final InstructionList il = new InstructionList();
        final XSLTC xsltc = classGen.getParser().getXSLTC();

        // private boolean Translet.stripSpace(int type) - cannot be static
        final MethodGenerator stripSpace =
            new MethodGenerator(ACC_PUBLIC | ACC_FINAL ,
                        com.sun.org.apache.bcel.internal.generic.Type.BOOLEAN,
                        new com.sun.org.apache.bcel.internal.generic.Type[] {
                            Util.getJCRefType(DOM_INTF_SIG),
                            com.sun.org.apache.bcel.internal.generic.Type.INT,
                            com.sun.org.apache.bcel.internal.generic.Type.INT
View Full Code Here

        argNames[0] = DOCUMENT_PNAME;
        argNames[1] = ITERATOR_PNAME;
        argNames[2] = TRANSLET_OUTPUT_PNAME;

        final InstructionList mainIL = new InstructionList();
        final MethodGenerator methodGen =
            new MethodGenerator(ACC_PUBLIC | ACC_FINAL,
                                com.sun.org.apache.bcel.internal.generic.Type.VOID,
                                argTypes, argNames, functionName(),
                                getClassName(), mainIL,
                                classGen.getConstantPool());
        methodGen.addException("com.sun.org.apache.xalan.internal.xsltc.TransletException");
        // Insert an extra NOP just to keep "current" from appearing as if it
        // has a value before the start of the loop.
        mainIL.append(NOP);


        // Create a local variable to hold the current node
        final LocalVariableGen current;
        current = methodGen.addLocalVariable2("current",
                                              com.sun.org.apache.bcel.internal.generic.Type.INT,
                                              null);
        _currentIndex = current.getIndex();

        // Create the "body" instruction list that will eventually hold the
        // code for the entire method (other ILs will be appended).
        final InstructionList body = new InstructionList();
        body.append(NOP);

        // Create an instruction list that contains the default next-node
        // iteration
        final InstructionList ilLoop = new InstructionList();
        ilLoop.append(methodGen.loadIterator());
        ilLoop.append(methodGen.nextNode());
        ilLoop.append(DUP);
        ilLoop.append(new ISTORE(_currentIndex));

        // 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));
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        argNames[1] = ITERATOR_PNAME;
        argNames[2] = TRANSLET_OUTPUT_PNAME;
        argNames[3] = NODE_PNAME;

        final InstructionList mainIL = new InstructionList();
        final MethodGenerator methodGen =
            new MethodGenerator(ACC_PUBLIC | ACC_FINAL,
                                com.sun.org.apache.bcel.internal.generic.Type.VOID,
                                argTypes, argNames, functionName()+'_'+max,
                                getClassName(), mainIL,
                                classGen.getConstantPool());
        methodGen.addException("com.sun.org.apache.xalan.internal.xsltc.TransletException");

        // Create the local variable to hold the current node
        final LocalVariableGen current;
        current = methodGen.addLocalVariable2("current",
                                              com.sun.org.apache.bcel.internal.generic.Type.INT,
                                              null);
        _currentIndex = current.getIndex();

        mainIL.append(new ILOAD(methodGen.getLocalIndex(NODE_PNAME)));
        current.setStart(mainIL.append(new ISTORE(_currentIndex)));

        // Create the "body" instruction list that will eventually hold the
        // code for the entire method (other ILs will be appended).
        final InstructionList body = new InstructionList();
        body.append(NOP);

        // 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));
View Full Code Here

     * Compiles a constructor for the class <tt>_className</tt> that
     * inherits from {Any,Single,Multiple}NodeCounter. This constructor
     * simply calls the same constructor in the super class.
     */
    private void compileConstructor(ClassGenerator classGen) {
  MethodGenerator cons;
  final InstructionList il = new InstructionList();
  final ConstantPoolGen cpg = classGen.getConstantPool();

  cons = new MethodGenerator(ACC_PUBLIC,
           com.sun.org.apache.bcel.internal.generic.Type.VOID,
           new com.sun.org.apache.bcel.internal.generic.Type[] {
               Util.getJCRefType(TRANSLET_INTF_SIG),
               Util.getJCRefType(DOM_INTF_SIG),
               Util.getJCRefType(NODE_ITERATOR_SIG),
                                       com.sun.org.apache.bcel.internal.generic.Type.BOOLEAN
           },
           new String[] {
               "dom",
               "translet",
               "iterator",
                                       "hasFrom"
           },
           "<init>", _className, il, cpg);

  il.append(ALOAD_0);         // this
  il.append(ALOAD_1);         // translet
  il.append(ALOAD_2);         // DOM
  il.append(new ALOAD(3));    // iterator
        il.append(new ILOAD(4));    // hasFrom

  int index = cpg.addMethodref(ClassNames[_level],
             "<init>",
             "(" + TRANSLET_INTF_SIG
             + DOM_INTF_SIG
             + NODE_ITERATOR_SIG
             + "Z)V");
  il.append(new INVOKESPECIAL(index));
  il.append(RETURN);
 
  cons.stripAttributes(true);
  cons.setMaxLocals();
  cons.setMaxStack();
  classGen.addMethod(cons.getMethod());
    }
View Full Code Here

     */
    private void compileStaticInitializer(ClassGenerator classGen) {
        final ConstantPoolGen cpg = classGen.getConstantPool();
        final InstructionList il = new InstructionList();

        final MethodGenerator staticConst =
            new MethodGenerator(ACC_PUBLIC|ACC_STATIC,
                                com.sun.org.apache.bcel.internal.generic.Type.VOID,
                                null, null, "<clinit>",
                                _className, il, cpg);

        addStaticField(classGen, "[" + STRING_SIG, STATIC_NAMES_ARRAY_FIELD);
        addStaticField(classGen, "[" + STRING_SIG, STATIC_URIS_ARRAY_FIELD);
        addStaticField(classGen, "[I", STATIC_TYPES_ARRAY_FIELD);
        addStaticField(classGen, "[" + STRING_SIG, STATIC_NAMESPACE_ARRAY_FIELD);
        // Create fields of type char[] that will contain literal text from
        // the stylesheet.
        final int charDataFieldCount = getXSLTC().getCharacterDataCount();
        for (int i = 0; i < charDataFieldCount; i++) {
            addStaticField(classGen, STATIC_CHAR_DATA_FIELD_SIG,
                           STATIC_CHAR_DATA_FIELD+i);
        }

        // Put the names array into the translet - used for dom/translet mapping
        final Vector namesIndex = getXSLTC().getNamesIndex();
        int size = namesIndex.size();
        String[] namesArray = new String[size];
        String[] urisArray = new String[size];
        int[] typesArray = new int[size];

        int index;
        for (int i = 0; i < size; i++) {
            String encodedName = (String)namesIndex.elementAt(i);
            if ((index = encodedName.lastIndexOf(':')) > -1) {
                urisArray[i] = encodedName.substring(0, index);
            }

            index = index + 1;
            if (encodedName.charAt(index) == '@') {
                typesArray[i] = DTM.ATTRIBUTE_NODE;
                index++;
            } else if (encodedName.charAt(index) == '?') {
                typesArray[i] = DTM.NAMESPACE_NODE;
                index++;
            } else {
                typesArray[i] = DTM.ELEMENT_NODE;
            }

            if (index == 0) {
                namesArray[i] = encodedName;
            }
            else {
                namesArray[i] = encodedName.substring(index);
            }
        }

        il.append(new PUSH(cpg, size));
        il.append(new ANEWARRAY(cpg.addClass(STRING)));

        for (int i = 0; i < size; i++) {
            final String name = namesArray[i];
            il.append(DUP);
            il.append(new PUSH(cpg, i));
            il.append(new PUSH(cpg, name));
            il.append(AASTORE);
        }
        il.append(new PUTSTATIC(cpg.addFieldref(_className,
                                               STATIC_NAMES_ARRAY_FIELD,
                                               NAMES_INDEX_SIG)));

        il.append(new PUSH(cpg, size));
        il.append(new ANEWARRAY(cpg.addClass(STRING)));

        for (int i = 0; i < size; i++) {
            final String uri = urisArray[i];
            il.append(DUP);
            il.append(new PUSH(cpg, i));
            il.append(new PUSH(cpg, uri));
            il.append(AASTORE);
        }
        il.append(new PUTSTATIC(cpg.addFieldref(_className,
                                               STATIC_URIS_ARRAY_FIELD,
                                               URIS_INDEX_SIG)));

        il.append(new PUSH(cpg, size));
        il.append(new NEWARRAY(BasicType.INT));

        for (int i = 0; i < size; i++) {
            final int nodeType = typesArray[i];
            il.append(DUP);
            il.append(new PUSH(cpg, i));
            il.append(new PUSH(cpg, nodeType));
            il.append(IASTORE);
        }
        il.append(new PUTSTATIC(cpg.addFieldref(_className,
                                               STATIC_TYPES_ARRAY_FIELD,
                                               TYPES_INDEX_SIG)));

        // Put the namespace names array into the translet
        final Vector namespaces = getXSLTC().getNamespaceIndex();
        il.append(new PUSH(cpg, namespaces.size()));
        il.append(new ANEWARRAY(cpg.addClass(STRING)));

        for (int i = 0; i < namespaces.size(); i++) {
            final String ns = (String)namespaces.elementAt(i);
            il.append(DUP);
            il.append(new PUSH(cpg, i));
            il.append(new PUSH(cpg, ns));
            il.append(AASTORE);
        }
        il.append(new PUTSTATIC(cpg.addFieldref(_className,
                                               STATIC_NAMESPACE_ARRAY_FIELD,
                                               NAMESPACE_INDEX_SIG)));

        // Grab all the literal text in the stylesheet and put it in a char[]
        final int charDataCount = getXSLTC().getCharacterDataCount();
        final int toCharArray = cpg.addMethodref(STRING, "toCharArray", "()[C");
        for (int i = 0; i < charDataCount; i++) {
            il.append(new PUSH(cpg, getXSLTC().getCharacterData(i)));
            il.append(new INVOKEVIRTUAL(toCharArray));
            il.append(new PUTSTATIC(cpg.addFieldref(_className,
                                               STATIC_CHAR_DATA_FIELD+i,
                                               STATIC_CHAR_DATA_FIELD_SIG)));
        }

        il.append(RETURN);

        staticConst.stripAttributes(true);
        staticConst.setMaxLocals();
        staticConst.setMaxStack();
        classGen.addMethod(staticConst.getMethod());

    }
View Full Code Here

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