From e5b7380c874745c989d1816b8f552504f038e1bc Mon Sep 17 00:00:00 2001 From: lresende Date: Thu, 26 Sep 2013 20:33:20 +0000 Subject: 2.0 branch for possible maintenance release git-svn-id: http://svn.us.apache.org/repos/asf/tuscany@1526672 13f79535-47bb-0310-9956-ffa450edef68 --- .../sca/binding/ejb/corba/ClassLoadingUtil.java | 365 +++++++++++++++++++++ 1 file changed, 365 insertions(+) create mode 100644 sca-java-2.x/branches/2.0/modules/binding-ejb-runtime/src/main/java/org/apache/tuscany/sca/binding/ejb/corba/ClassLoadingUtil.java (limited to 'sca-java-2.x/branches/2.0/modules/binding-ejb-runtime/src/main/java/org/apache/tuscany/sca/binding/ejb/corba/ClassLoadingUtil.java') diff --git a/sca-java-2.x/branches/2.0/modules/binding-ejb-runtime/src/main/java/org/apache/tuscany/sca/binding/ejb/corba/ClassLoadingUtil.java b/sca-java-2.x/branches/2.0/modules/binding-ejb-runtime/src/main/java/org/apache/tuscany/sca/binding/ejb/corba/ClassLoadingUtil.java new file mode 100644 index 0000000000..c65868c23b --- /dev/null +++ b/sca-java-2.x/branches/2.0/modules/binding-ejb-runtime/src/main/java/org/apache/tuscany/sca/binding/ejb/corba/ClassLoadingUtil.java @@ -0,0 +1,365 @@ +/* + * Licensed to the Apache Software Foundation (ASF) under one + * or more contributor license agreements. See the NOTICE file + * distributed with this work for additional information + * regarding copyright ownership. The ASF licenses this file + * to you under the Apache License, Version 2.0 (the + * "License"); you may not use this file except in compliance + * with the License. You may obtain a copy of the License at + * + * http://www.apache.org/licenses/LICENSE-2.0 + * + * Unless required by applicable law or agreed to in writing, + * software distributed under the License is distributed on an + * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY + * KIND, either express or implied. See the License for the + * specific language governing permissions and limitations + * under the License. + */ + +package org.apache.tuscany.sca.binding.ejb.corba; + +import java.lang.reflect.Array; +import java.util.ArrayList; +import java.util.Arrays; +import java.util.HashMap; +import java.util.LinkedHashSet; +import java.util.LinkedList; +import java.util.List; +import java.util.Set; + +/** + * Utility class for loading classes by a variety of name variations. + *

+ * Supported names types are: + *

+ * 1) Fully qualified class name (e.g., "java.lang.String", "org.apache.geronimo.kernel.ClassLoading" + * 2) Method signature encoding ("Ljava.lang.String;", "J", "I", etc.) + * 3) Primitive type names ("int", "boolean", etc.) + * 4) Method array signature strings ("[I", "[Ljava.lang.String") + * 5) Arrays using Java code format ("int[]", "java.lang.String[][]") + *

+ * The classes are loaded using the provided class loader. For the basic types, the primitive + * reflection types are returned. + * + * @version $Rev$ $Date$ + */ +public class ClassLoadingUtil { + + /** + * Table for mapping primitive class names/signatures to the implementing + * class object + */ + private static final HashMap PRIMITIVE_CLASS_MAP = new HashMap(); + + /** + * Table for mapping primitive classes back to their name signature type, which + * allows a reverse mapping to be performed from a class object into a resolvable + * signature. + */ + private static final HashMap CLASS_TO_SIGNATURE_MAP = new HashMap(); + + + /** + * Setup the primitives map. We make any entry for each primitive class using both the + * human readable name and the method signature shorthand type. + */ + static { + PRIMITIVE_CLASS_MAP.put("boolean", boolean.class); + PRIMITIVE_CLASS_MAP.put("Z", boolean.class); + PRIMITIVE_CLASS_MAP.put("byte", byte.class); + PRIMITIVE_CLASS_MAP.put("B", byte.class); + PRIMITIVE_CLASS_MAP.put("char", char.class); + PRIMITIVE_CLASS_MAP.put("C", char.class); + PRIMITIVE_CLASS_MAP.put("short", short.class); + PRIMITIVE_CLASS_MAP.put("S", short.class); + PRIMITIVE_CLASS_MAP.put("int", int.class); + PRIMITIVE_CLASS_MAP.put("I", int.class); + PRIMITIVE_CLASS_MAP.put("long", long.class); + PRIMITIVE_CLASS_MAP.put("J", long.class); + PRIMITIVE_CLASS_MAP.put("float", float.class); + PRIMITIVE_CLASS_MAP.put("F", float.class); + PRIMITIVE_CLASS_MAP.put("double", double.class); + PRIMITIVE_CLASS_MAP.put("D", double.class); + PRIMITIVE_CLASS_MAP.put("void", void.class); + PRIMITIVE_CLASS_MAP.put("V", void.class); + + // Now build a reverse mapping table. The table above has a many-to-one mapping for + // class names. To do the reverse, we need to pick just one. As long as the + // returned name supports "round tripping" of the requests, this will work fine. + + CLASS_TO_SIGNATURE_MAP.put(boolean.class, "Z"); + CLASS_TO_SIGNATURE_MAP.put(byte.class, "B"); + CLASS_TO_SIGNATURE_MAP.put(char.class, "C"); + CLASS_TO_SIGNATURE_MAP.put(short.class, "S"); + CLASS_TO_SIGNATURE_MAP.put(int.class, "I"); + CLASS_TO_SIGNATURE_MAP.put(long.class, "J"); + CLASS_TO_SIGNATURE_MAP.put(float.class, "F"); + CLASS_TO_SIGNATURE_MAP.put(double.class, "D"); + CLASS_TO_SIGNATURE_MAP.put(void.class, "V"); + } + + + /** + * Load a class that matches the requested name, using the provided class loader context. + *

+ * The class name may be a standard class name, the name of a primitive type Java + * reflection class (e.g., "boolean" or "int"), or a type in method type signature + * encoding. Array classes in either encoding form are also processed. + * + * @param className The name of the required class. + * @param classLoader The class loader used to resolve the class object. + * @return The Class object resolved from "className". + * @throws ClassNotFoundException When unable to resolve the class object. + * @throws IllegalArgumentException If either argument is null. + */ + public static Class loadClass(String className, ClassLoader classLoader) throws ClassNotFoundException { + + // the tests require IllegalArgumentExceptions for null values on either of these. + if (className == null) { + throw new IllegalArgumentException("className is null"); + } + + if (classLoader == null) { + throw new IllegalArgumentException("classLoader is null"); + } + // The easiest case is a proper class name. We just have the class loader resolve this. + // If the class loader throws a ClassNotFoundException, then we need to check each of the + // special name encodings we support. + try { + return classLoader.loadClass(className); + } catch (ClassNotFoundException ignore) { + // if not found, continue on to the other name forms. + } + + + // The second easiest version to resolve is a direct map to a primitive type name + // or method signature. Check our name-to-class map for one of those. + Class resolvedClass = (Class) PRIMITIVE_CLASS_MAP.get(className); + if (resolvedClass != null) { + return resolvedClass; + } + + // Class names in method signature have the format "Lfully.resolved.name;", + // so if it ends in a semicolon and begins with an "L", this must be in + // this format. Have the class loader try to load this. There are no other + // options if this fails, so just allow the class loader to throw the + // ClassNotFoundException. + if (className.endsWith(";") && className.startsWith("L")) { + // pick out the name portion + String typeName = className.substring(1, className.length() - 1); + // and delegate the loading to the class loader. + return classLoader.loadClass(typeName); + } + + // All we have left now are the array types. Method signature array types + // have a series of leading "[" characters to specify the number of dimensions. + // The other array type we handle uses trailing "[]" for the dimensions, just + // like the Java language syntax. + + // first check for the signature form ([[[[type). + if (className.charAt(0) == '[') { + // we have at least one array marker, now count how many leading '['s we have + // to get the dimension count. + int count = 0; + int nameLen = className.length(); + + while (count < nameLen && className.charAt(count) == '[') { + count++; + } + + // pull of the name subtype, which is everything after the last '[' + String arrayTypeName = className.substring(count, className.length()); + // resolve the type using a recursive call, which will load any of the primitive signature + // types as well as class names. + Class arrayType = loadClass(arrayTypeName, classLoader); + + // Resolving array types require a little more work. The array classes are + // created dynamically when the first instance of a given dimension and type is + // created. We need to create one using reflection to do this. + return getArrayClass(arrayType, count); + } + + + // ok, last chance. Now check for an array specification in Java language + // syntax. This will be a type name followed by pairs of "[]" to indicate + // the number of dimensions. + if (className.endsWith("[]")) { + // get the base component class name and the arrayDimensions + int count = 0; + int position = className.length(); + + while (position > 1 && className.substring(position - 2, position).equals("[]")) { + // count this dimension + count++; + // and step back the probe position. + position -= 2; + } + + // position now points at the location of the last successful test. This makes it + // easy to pick off the class name. + + String typeName = className.substring(0, position); + + // load the base type, again, doing this recursively + Class arrayType = loadClass(typeName, classLoader); + // and turn this into the class object + return getArrayClass(arrayType, count); + } + + throw new ClassNotFoundException("Could not load class " + className + " from unknown classloader; " + classLoader); + } + + + /** + * Map a class object back to a class name. The returned class object + * must be "round trippable", which means + *

+ * type == ClassLoading.loadClass(ClassLoading.getClassName(type), classLoader) + *

+ * must be true. To ensure this, the class name is always returned in + * method signature format. + * + * @param type The class object we convert into name form. + * @return A string representation of the class name, in method signature + * format. + */ + public static String getClassName(Class type) { + StringBuffer name = new StringBuffer(); + + // we test these in reverse order from the resolution steps, + // first handling arrays, then primitive types, and finally + // "normal" class objects. + + // First handle arrays. If a class is an array, the type is + // element stored at that level. So, for a 2-dimensional array + // of ints, the top-level type will be "[I". We need to loop + // down the hierarchy until we hit a non-array type. + while (type.isArray()) { + // add another array indicator at the front of the name, + // and continue with the next type. + name.append('['); + type = type.getComponentType(); + } + + // we're down to the base type. If this is a primitive, then + // we poke in the single-character type specifier. + if (type.isPrimitive()) { + name.append((String) CLASS_TO_SIGNATURE_MAP.get(type)); + } + // a "normal" class. This gets expressing using the "Lmy.class.name;" syntax. + else { + name.append('L'); + name.append(type.getName()); + name.append(';'); + } + return name.toString(); + } + + private static Class getArrayClass(Class type, int dimension) { + // Array.newInstance() requires an array of the requested number of dimensions + // that gives the size for each dimension. We just request 0 in each of the + // dimensions, which is not unlike a black hole singularity. + int[] dimensions = new int[dimension]; + // create an instance and return the associated class object. + return Array.newInstance(type, dimensions).getClass(); + } + + public static Set getAllTypes(Class type) { + Set allTypes = new LinkedHashSet(); + allTypes.add(type); + allTypes.addAll(getAllSuperClasses(type)); + allTypes.addAll(getAllInterfaces(type)); + return allTypes; + } + + private static Set getAllSuperClasses(Class clazz) { + Set allSuperClasses = new LinkedHashSet(); + for (Class superClass = clazz.getSuperclass(); superClass != null; superClass = superClass.getSuperclass()) { + allSuperClasses.add(superClass); + } + return allSuperClasses; + } + + private static Set getAllInterfaces(Class clazz) { + Set allInterfaces = new LinkedHashSet(); + LinkedList stack = new LinkedList(); + stack.addAll(Arrays.asList(clazz.getInterfaces())); + while (!stack.isEmpty()) { + Class intf = (Class) stack.removeFirst(); + if (!allInterfaces.contains(intf)) { + allInterfaces.add(intf); + stack.addAll(Arrays.asList(intf.getInterfaces())); + } + } + return allInterfaces; + } + + public static Set reduceInterfaces(Set source) { + Class[] classes = (Class[]) source.toArray(new Class[source.size()]); + classes = reduceInterfaces(classes); + return new LinkedHashSet(Arrays.asList(classes)); + } + + /** + * If there are multiple interfaces, and some of them extend each other, + * eliminate the superclass in favor of the subclasses that extend them. + * + * If one of the entries is a class (not an interface), make sure it's + * the first one in the array. If more than one of the entries is a + * class, throws an IllegalArgumentException + * + * @param source the original list of interfaces + * @return the equal or smaller list of interfaces + */ + public static Class[] reduceInterfaces(Class[] source) { + // use a copy of the source array + source = (Class[]) source.clone(); + + for (int leftIndex = 0; leftIndex < source.length-1; leftIndex++) { + Class left = source[leftIndex]; + if(left == null) { + continue; + } + + for (int rightIndex = leftIndex +1; rightIndex < source.length; rightIndex++) { + Class right = source[rightIndex]; + if(right == null) { + continue; + } + + if(left == right || right.isAssignableFrom(left)) { + // right is the same as class or a sub class of left + source[rightIndex] = null; + } else if(left.isAssignableFrom(right)) { + // left is the same as class or a sub class of right + source[leftIndex] = null; + + // the left has been eliminated; move on to the next left + break; + } + } + } + + Class clazz = null; + for (int i = 0; i < source.length; i++) { + if (source[i] != null && !source[i].isInterface()) { + if (clazz != null) { + throw new IllegalArgumentException("Source contains two classes which are not subclasses of each other: " + clazz.getName() + ", " + source[i].getName()); + } + clazz = source[i]; + source[i] = null; + } + } + + List list = new ArrayList(source.length); + if (clazz != null) list.add(clazz); + for (int i = 0; i < source.length; i++) { + if(source[i] != null) { + list.add(source[i]); + } + } + return (Class[]) list.toArray(new Class[list.size()]); + } +} + -- cgit v1.2.3