/*
 * 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.
 */

/*
 * This is a modified version of the original Apache class.  It has had unused
 * members removed.
 */

package org.ehcache.impl.internal.classes.commonslang.reflect;

import org.ehcache.impl.internal.classes.commonslang.ClassUtils;

import java.lang.reflect.AccessibleObject;
import java.lang.reflect.Constructor;
import java.lang.reflect.Member;
import java.lang.reflect.Method;
import java.lang.reflect.Modifier;

Contains common code for working with Methods/Constructors, extracted and refactored from MethodUtils when it was imported from Commons BeanUtils.
Since:2.5
/** * Contains common code for working with {@link Method Methods}/{@link Constructor Constructors}, * extracted and refactored from {@link MethodUtils} when it was imported from Commons BeanUtils. * * @since 2.5 */
abstract class MemberUtils { // TODO extract an interface to implement compareParameterSets(...)? private static final int ACCESS_TEST = Modifier.PUBLIC | Modifier.PROTECTED | Modifier.PRIVATE;
Array of primitive number types ordered by "promotability"
/** Array of primitive number types ordered by "promotability" */
private static final Class<?>[] ORDERED_PRIMITIVE_TYPES = { Byte.TYPE, Short.TYPE, Character.TYPE, Integer.TYPE, Long.TYPE, Float.TYPE, Double.TYPE };
XXX Default access superclass workaround. When a public class has a default access superclass with public members, these members are accessible. Calling them from compiled code works fine. Unfortunately, on some JVMs, using reflection to invoke these members seems to (wrongly) prevent access even when the modifier is public. Calling setAccessible(true) solves the problem but will only work from sufficiently privileged code. Better workarounds would be gratefully accepted.
Params:
  • o – the AccessibleObject to set as accessible
Returns:a boolean indicating whether the accessibility of the object was set to true.
/** * XXX Default access superclass workaround. * * When a {@code public} class has a default access superclass with {@code public} members, * these members are accessible. Calling them from compiled code works fine. * Unfortunately, on some JVMs, using reflection to invoke these members * seems to (wrongly) prevent access even when the modifier is {@code public}. * Calling {@code setAccessible(true)} solves the problem but will only work from * sufficiently privileged code. Better workarounds would be gratefully * accepted. * @param o the AccessibleObject to set as accessible * @return a boolean indicating whether the accessibility of the object was set to true. */
static boolean setAccessibleWorkaround(final AccessibleObject o) { if (o == null || o.isAccessible()) { return false; } final Member m = (Member) o; if (!o.isAccessible() && Modifier.isPublic(m.getModifiers()) && isPackageAccess(m.getDeclaringClass().getModifiers())) { try { o.setAccessible(true); return true; } catch (final SecurityException e) { // NOPMD // ignore in favor of subsequent IllegalAccessException } } return false; }
Returns whether a given set of modifiers implies package access.
Params:
  • modifiers – to test
Returns:true unless package/protected/private modifier detected
/** * Returns whether a given set of modifiers implies package access. * @param modifiers to test * @return {@code true} unless {@code package}/{@code protected}/{@code private} modifier detected */
static boolean isPackageAccess(final int modifiers) { return (modifiers & ACCESS_TEST) == 0; }
Returns whether a Member is accessible.
Params:
  • m – Member to check
Returns:true if m is accessible
/** * Returns whether a {@link Member} is accessible. * @param m Member to check * @return {@code true} if <code>m</code> is accessible */
static boolean isAccessible(final Member m) { return m != null && Modifier.isPublic(m.getModifiers()) && !m.isSynthetic(); }
Compares the relative fitness of two Constructors in terms of how well they match a set of runtime parameter types, such that a list ordered by the results of the comparison would return the best match first (least).
Params:
  • left – the "left" Constructor
  • right – the "right" Constructor
  • actual – the runtime parameter types to match against left/right
Returns:int consistent with compare semantics
Since:3.5
/** * Compares the relative fitness of two Constructors in terms of how well they * match a set of runtime parameter types, such that a list ordered * by the results of the comparison would return the best match first * (least). * * @param left the "left" Constructor * @param right the "right" Constructor * @param actual the runtime parameter types to match against * {@code left}/{@code right} * @return int consistent with {@code compare} semantics * @since 3.5 */
static int compareConstructorFit(final Constructor<?> left, final Constructor<?> right, final Class<?>[] actual) { return compareParameterTypes(Executable.of(left), Executable.of(right), actual); }
Compares the relative fitness of two Executables in terms of how well they match a set of runtime parameter types, such that a list ordered by the results of the comparison would return the best match first (least).
Params:
  • left – the "left" Executable
  • right – the "right" Executable
  • actual – the runtime parameter types to match against left/right
Returns:int consistent with compare semantics
/** * Compares the relative fitness of two Executables in terms of how well they * match a set of runtime parameter types, such that a list ordered * by the results of the comparison would return the best match first * (least). * * @param left the "left" Executable * @param right the "right" Executable * @param actual the runtime parameter types to match against * {@code left}/{@code right} * @return int consistent with {@code compare} semantics */
private static int compareParameterTypes(final Executable left, final Executable right, final Class<?>[] actual) { final float leftCost = getTotalTransformationCost(actual, left); final float rightCost = getTotalTransformationCost(actual, right); return leftCost < rightCost ? -1 : rightCost < leftCost ? 1 : 0; }
Returns the sum of the object transformation cost for each class in the source argument list.
Params:
  • srcArgs – The source arguments
  • executable – The executable to calculate transformation costs for
Returns:The total transformation cost
/** * Returns the sum of the object transformation cost for each class in the * source argument list. * @param srcArgs The source arguments * @param executable The executable to calculate transformation costs for * @return The total transformation cost */
private static float getTotalTransformationCost(final Class<?>[] srcArgs, final Executable executable) { final Class<?>[] destArgs = executable.getParameterTypes(); final boolean isVarArgs = executable.isVarArgs(); // "source" and "destination" are the actual and declared args respectively. float totalCost = 0.0f; final long normalArgsLen = isVarArgs ? destArgs.length-1 : destArgs.length; if (srcArgs.length < normalArgsLen) { return Float.MAX_VALUE; } for (int i = 0; i < normalArgsLen; i++) { totalCost += getObjectTransformationCost(srcArgs[i], destArgs[i]); } if (isVarArgs) { // When isVarArgs is true, srcArgs and dstArgs may differ in length. // There are two special cases to consider: final boolean noVarArgsPassed = srcArgs.length < destArgs.length; final boolean explicitArrayForVarags = srcArgs.length == destArgs.length && srcArgs[srcArgs.length-1].isArray(); final float varArgsCost = 0.001f; final Class<?> destClass = destArgs[destArgs.length-1].getComponentType(); if (noVarArgsPassed) { // When no varargs passed, the best match is the most generic matching type, not the most specific. totalCost += getObjectTransformationCost(destClass, Object.class) + varArgsCost; } else if (explicitArrayForVarags) { final Class<?> sourceClass = srcArgs[srcArgs.length-1].getComponentType(); totalCost += getObjectTransformationCost(sourceClass, destClass) + varArgsCost; } else { // This is typical varargs case. for (int i = destArgs.length-1; i < srcArgs.length; i++) { final Class<?> srcClass = srcArgs[i]; totalCost += getObjectTransformationCost(srcClass, destClass) + varArgsCost; } } } return totalCost; }
Gets the number of steps required needed to turn the source class into the destination class. This represents the number of steps in the object hierarchy graph.
Params:
  • srcClass – The source class
  • destClass – The destination class
Returns:The cost of transforming an object
/** * Gets the number of steps required needed to turn the source class into * the destination class. This represents the number of steps in the object * hierarchy graph. * @param srcClass The source class * @param destClass The destination class * @return The cost of transforming an object */
private static float getObjectTransformationCost(Class<?> srcClass, final Class<?> destClass) { if (destClass.isPrimitive()) { return getPrimitivePromotionCost(srcClass, destClass); } float cost = 0.0f; while (srcClass != null && !destClass.equals(srcClass)) { if (destClass.isInterface() && ClassUtils.isAssignable(srcClass, destClass)) { // slight penalty for interface match. // we still want an exact match to override an interface match, // but // an interface match should override anything where we have to // get a superclass. cost += 0.25f; break; } cost++; srcClass = srcClass.getSuperclass(); } /* * If the destination class is null, we've traveled all the way up to * an Object match. We'll penalize this by adding 1.5 to the cost. */ if (srcClass == null) { cost += 1.5f; } return cost; }
Gets the number of steps required to promote a primitive number to another type.
Params:
  • srcClass – the (primitive) source class
  • destClass – the (primitive) destination class
Returns:The cost of promoting the primitive
/** * Gets the number of steps required to promote a primitive number to another * type. * @param srcClass the (primitive) source class * @param destClass the (primitive) destination class * @return The cost of promoting the primitive */
private static float getPrimitivePromotionCost(final Class<?> srcClass, final Class<?> destClass) { float cost = 0.0f; Class<?> cls = srcClass; if (!cls.isPrimitive()) { // slight unwrapping penalty cost += 0.1f; cls = ClassUtils.wrapperToPrimitive(cls); } for (int i = 0; cls != destClass && i < ORDERED_PRIMITIVE_TYPES.length; i++) { if (cls == ORDERED_PRIMITIVE_TYPES[i]) { cost += 0.1f; if (i < ORDERED_PRIMITIVE_TYPES.length - 1) { cls = ORDERED_PRIMITIVE_TYPES[i + 1]; } } } return cost; } static boolean isMatchingConstructor(final Constructor<?> method, final Class<?>[] parameterTypes) { return MemberUtils.isMatchingExecutable(Executable.of(method), parameterTypes); } private static boolean isMatchingExecutable(final Executable method, final Class<?>[] parameterTypes) { final Class<?>[] methodParameterTypes = method.getParameterTypes(); if (ClassUtils.isAssignable(parameterTypes, methodParameterTypes, true)) { return true; } if (method.isVarArgs()) { int i; for (i = 0; i < methodParameterTypes.length - 1 && i < parameterTypes.length; i++) { if (!ClassUtils.isAssignable(parameterTypes[i], methodParameterTypes[i], true)) { return false; } } final Class<?> varArgParameterType = methodParameterTypes[methodParameterTypes.length - 1].getComponentType(); for (; i < parameterTypes.length; i++) { if (!ClassUtils.isAssignable(parameterTypes[i], varArgParameterType, true)) { return false; } } return true; } return false; }

A class providing a subset of the API of java.lang.reflect.Executable in Java 1.8, providing a common representation for function signatures for Constructors and Methods.

/** * <p> A class providing a subset of the API of java.lang.reflect.Executable in Java 1.8, * providing a common representation for function signatures for Constructors and Methods.</p> */
private static final class Executable { private final Class<?>[] parameterTypes; private final boolean isVarArgs; private static Executable of(final Constructor<?> constructor) { return new Executable(constructor); } private Executable(final Constructor<?> constructor) { parameterTypes = constructor.getParameterTypes(); isVarArgs = constructor.isVarArgs(); } public Class<?>[] getParameterTypes() { return parameterTypes; } public boolean isVarArgs() { return isVarArgs; } } }