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/*
 * 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.calcite.util;

import org.apache.calcite.linq4j.function.Parameter;

import com.google.common.collect.ImmutableList;

import java.lang.annotation.Annotation;
import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.List;
import java.util.Map;

/**
 * Static utilities for Java reflection.
 */
public abstract class ReflectUtil {
  //~ Static fields/initializers ---------------------------------------------

  private static Map primitiveToBoxingMap;
  private static Map primitiveToByteBufferReadMethod;
  private static Map primitiveToByteBufferWriteMethod;

  static {
    primitiveToBoxingMap = new HashMap<>();
    primitiveToBoxingMap.put(Boolean.TYPE, Boolean.class);
    primitiveToBoxingMap.put(Byte.TYPE, Byte.class);
    primitiveToBoxingMap.put(Character.TYPE, Character.class);
    primitiveToBoxingMap.put(Double.TYPE, Double.class);
    primitiveToBoxingMap.put(Float.TYPE, Float.class);
    primitiveToBoxingMap.put(Integer.TYPE, Integer.class);
    primitiveToBoxingMap.put(Long.TYPE, Long.class);
    primitiveToBoxingMap.put(Short.TYPE, Short.class);

    primitiveToByteBufferReadMethod = new HashMap<>();
    primitiveToByteBufferWriteMethod = new HashMap<>();
    Method[] methods = ByteBuffer.class.getDeclaredMethods();
    for (Method method : methods) {
      Class[] paramTypes = method.getParameterTypes();
      if (method.getName().startsWith("get")) {
        if (!method.getReturnType().isPrimitive()) {
          continue;
        }
        if (paramTypes.length != 1) {
          continue;
        }
        primitiveToByteBufferReadMethod.put(
            method.getReturnType(), method);

        // special case for Boolean:  treat as byte
        if (method.getReturnType().equals(Byte.TYPE)) {
          primitiveToByteBufferReadMethod.put(Boolean.TYPE, method);
        }
      } else if (method.getName().startsWith("put")) {
        if (paramTypes.length != 2) {
          continue;
        }
        if (!paramTypes[1].isPrimitive()) {
          continue;
        }
        primitiveToByteBufferWriteMethod.put(paramTypes[1], method);

        // special case for Boolean:  treat as byte
        if (paramTypes[1].equals(Byte.TYPE)) {
          primitiveToByteBufferWriteMethod.put(Boolean.TYPE, method);
        }
      }
    }
  }

  //~ Methods ----------------------------------------------------------------

  /**
   * Uses reflection to find the correct java.nio.ByteBuffer "absolute get"
   * method for a given primitive type.
   *
   * @param clazz the Class object representing the primitive type
   * @return corresponding method
   */
  public static Method getByteBufferReadMethod(Class clazz) {
    assert clazz.isPrimitive();
    return primitiveToByteBufferReadMethod.get(clazz);
  }

  /**
   * Uses reflection to find the correct java.nio.ByteBuffer "absolute put"
   * method for a given primitive type.
   *
   * @param clazz the Class object representing the primitive type
   * @return corresponding method
   */
  public static Method getByteBufferWriteMethod(Class clazz) {
    assert clazz.isPrimitive();
    return primitiveToByteBufferWriteMethod.get(clazz);
  }

  /**
   * Gets the Java boxing class for a primitive class.
   *
   * @param primitiveClass representative class for primitive (e.g.
   *                       java.lang.Integer.TYPE)
   * @return corresponding boxing Class (e.g. java.lang.Integer)
   */
  public static Class getBoxingClass(Class primitiveClass) {
    assert primitiveClass.isPrimitive();
    return primitiveToBoxingMap.get(primitiveClass);
  }

  /**
   * Gets the name of a class with no package qualifiers; if it's an inner
   * class, it will still be qualified by the containing class (X$Y).
   *
   * @param c the class of interest
   * @return the unqualified name
   */
  public static String getUnqualifiedClassName(Class c) {
    String className = c.getName();
    int lastDot = className.lastIndexOf('.');
    if (lastDot < 0) {
      return className;
    }
    return className.substring(lastDot + 1);
  }

  /**
   * Composes a string representing a human-readable method name (with neither
   * exception nor return type information).
   *
   * @param declaringClass class on which method is defined
   * @param methodName     simple name of method without signature
   * @param paramTypes     method parameter types
   * @return unmangled method name
   */
  public static String getUnmangledMethodName(
      Class declaringClass,
      String methodName,
      Class[] paramTypes) {
    StringBuilder sb = new StringBuilder();
    sb.append(declaringClass.getName());
    sb.append(".");
    sb.append(methodName);
    sb.append("(");
    for (int i = 0; i < paramTypes.length; ++i) {
      if (i > 0) {
        sb.append(", ");
      }
      sb.append(paramTypes[i].getName());
    }
    sb.append(")");
    return sb.toString();
  }

  /**
   * Composes a string representing a human-readable method name (with neither
   * exception nor return type information).
   *
   * @param method method whose name is to be generated
   * @return unmangled method name
   */
  public static String getUnmangledMethodName(
      Method method) {
    return getUnmangledMethodName(
        method.getDeclaringClass(),
        method.getName(),
        method.getParameterTypes());
  }

  /**
   * Implements the {@link org.apache.calcite.util.Glossary#VISITOR_PATTERN} via
   * reflection. The basic technique is taken from a
   * Javaworld article. For an example of how to use it, see
   * {@code ReflectVisitorTest}.
   *
   * 

Visit method lookup follows the same rules as if * compile-time resolution for VisitorClass.visit(VisiteeClass) were * performed. An ambiguous match due to multiple interface inheritance * results in an IllegalArgumentException. A non-match is indicated by * returning false. * * @param visitor object whose visit method is to be invoked * @param visitee object to be passed as a parameter to the visit * method * @param hierarchyRoot if non-null, visitor method will only be invoked if * it takes a parameter whose type is a subtype of * hierarchyRoot * @param visitMethodName name of visit method, e.g. "visit" * @return true if a matching visit method was found and invoked */ public static boolean invokeVisitor( ReflectiveVisitor visitor, Object visitee, Class hierarchyRoot, String visitMethodName) { return invokeVisitorInternal( visitor, visitee, hierarchyRoot, visitMethodName); } /** * Shared implementation of the two forms of invokeVisitor. * * @param visitor object whose visit method is to be invoked * @param visitee object to be passed as a parameter to the visit * method * @param hierarchyRoot if non-null, visitor method will only be invoked if * it takes a parameter whose type is a subtype of * hierarchyRoot * @param visitMethodName name of visit method, e.g. "visit" * @return true if a matching visit method was found and invoked */ private static boolean invokeVisitorInternal( Object visitor, Object visitee, Class hierarchyRoot, String visitMethodName) { Class visitorClass = visitor.getClass(); Class visiteeClass = visitee.getClass(); Method method = lookupVisitMethod( visitorClass, visiteeClass, visitMethodName); if (method == null) { return false; } if (hierarchyRoot != null) { Class paramType = method.getParameterTypes()[0]; if (!hierarchyRoot.isAssignableFrom(paramType)) { return false; } } try { method.invoke( visitor, visitee); } catch (IllegalAccessException ex) { throw new RuntimeException(ex); } catch (InvocationTargetException ex) { // visit methods aren't allowed to have throws clauses, // so the only exceptions which should come // to us are RuntimeExceptions and Errors Util.throwIfUnchecked(ex.getTargetException()); throw new RuntimeException(ex.getTargetException()); } return true; } /** * Looks up a visit method. * * @param visitorClass class of object whose visit method is to be invoked * @param visiteeClass class of object to be passed as a parameter to the * visit method * @param visitMethodName name of visit method * @return method found, or null if none found */ public static Method lookupVisitMethod( Class visitorClass, Class visiteeClass, String visitMethodName) { return lookupVisitMethod( visitorClass, visiteeClass, visitMethodName, Collections.emptyList()); } /** * Looks up a visit method taking additional parameters beyond the * overloaded visitee type. * * @param visitorClass class of object whose visit method is to be * invoked * @param visiteeClass class of object to be passed as a parameter * to the visit method * @param visitMethodName name of visit method * @param additionalParameterTypes list of additional parameter types * @return method found, or null if none found * @see #createDispatcher(Class, Class) */ public static Method lookupVisitMethod( Class visitorClass, Class visiteeClass, String visitMethodName, List additionalParameterTypes) { // Prepare an array to re-use in recursive calls. The first argument // will have the visitee class substituted into it. Class[] paramTypes = new Class[1 + additionalParameterTypes.size()]; int iParam = 0; paramTypes[iParam++] = null; for (Class paramType : additionalParameterTypes) { paramTypes[iParam++] = paramType; } // Cache Class to candidate Methods, to optimize the case where // the original visiteeClass has a diamond-shaped interface inheritance // graph. (This is common, for example, in JMI.) The idea is to avoid // iterating over a single interface's method more than once in a call. Map, Method> cache = new HashMap<>(); return lookupVisitMethod( visitorClass, visiteeClass, visitMethodName, paramTypes, cache); } private static Method lookupVisitMethod( final Class visitorClass, final Class visiteeClass, final String visitMethodName, final Class[] paramTypes, final Map, Method> cache) { // Use containsKey since the result for a Class might be null. if (cache.containsKey(visiteeClass)) { return cache.get(visiteeClass); } Method candidateMethod = null; paramTypes[0] = visiteeClass; try { candidateMethod = visitorClass.getMethod( visitMethodName, paramTypes); cache.put(visiteeClass, candidateMethod); return candidateMethod; } catch (NoSuchMethodException ex) { // not found: carry on with lookup } Class superClass = visiteeClass.getSuperclass(); if (superClass != null) { candidateMethod = lookupVisitMethod( visitorClass, superClass, visitMethodName, paramTypes, cache); } Class[] interfaces = visiteeClass.getInterfaces(); for (Class anInterface : interfaces) { final Method method = lookupVisitMethod(visitorClass, anInterface, visitMethodName, paramTypes, cache); if (method != null) { if (candidateMethod != null) { if (!method.equals(candidateMethod)) { Class c1 = method.getParameterTypes()[0]; Class c2 = candidateMethod.getParameterTypes()[0]; if (c1.isAssignableFrom(c2)) { // c2 inherits from c1, so keep candidateMethod // (which is more specific than method) continue; } else if (c2.isAssignableFrom(c1)) { // c1 inherits from c2 (method is more specific // than candidate method), so fall through // to set candidateMethod = method } else { // c1 and c2 are not directly related throw new IllegalArgumentException("dispatch ambiguity between " + candidateMethod + " and " + method); } } } candidateMethod = method; } } cache.put(visiteeClass, candidateMethod); return candidateMethod; } /** * Creates a dispatcher for calls to {@link #lookupVisitMethod}. The * dispatcher caches methods between invocations. * * @param visitorBaseClazz Visitor base class * @param visiteeBaseClazz Visitee base class * @return cache of methods */ public static ReflectiveVisitDispatcher createDispatcher( final Class visitorBaseClazz, final Class visiteeBaseClazz) { assert ReflectiveVisitor.class.isAssignableFrom(visitorBaseClazz); assert Object.class.isAssignableFrom(visiteeBaseClazz); return new ReflectiveVisitDispatcher() { final Map, Method> map = new HashMap<>(); public Method lookupVisitMethod( Class visitorClass, Class visiteeClass, String visitMethodName) { return lookupVisitMethod( visitorClass, visiteeClass, visitMethodName, Collections.emptyList()); } public Method lookupVisitMethod( Class visitorClass, Class visiteeClass, String visitMethodName, List additionalParameterTypes) { final List key = ImmutableList.of( visitorClass, visiteeClass, visitMethodName, additionalParameterTypes); Method method = map.get(key); if (method == null) { if (map.containsKey(key)) { // We already looked for the method and found nothing. } else { method = ReflectUtil.lookupVisitMethod( visitorClass, visiteeClass, visitMethodName, additionalParameterTypes); map.put(key, method); } } return method; } public boolean invokeVisitor( R visitor, E visitee, String visitMethodName) { return ReflectUtil.invokeVisitor( visitor, visitee, visiteeBaseClazz, visitMethodName); } }; } /** * Creates a dispatcher for calls to a single multi-method on a particular * object. * *

Calls to that multi-method are resolved by looking for a method on * the runtime type of that object, with the required name, and with * the correct type or a subclass for the first argument, and precisely the * same types for other arguments. * *

For instance, a dispatcher created for the method * *

String foo(Vehicle, int, List)
* *

could be used to call the methods * *

String foo(Car, int, List)
* String foo(Bus, int, List)
* *

(because Car and Bus are subclasses of Vehicle, and they occur in the * polymorphic first argument) but not the method * *

String foo(Car, int, ArrayList)
* *

(only the first argument is polymorphic). * *

You must create an implementation of the method for the base class. * Otherwise throws {@link IllegalArgumentException}. * * @param returnClazz Return type of method * @param visitor Object on which to invoke the method * @param methodName Name of method * @param arg0Clazz Base type of argument zero * @param otherArgClasses Types of remaining arguments */ public static MethodDispatcher createMethodDispatcher( final Class returnClazz, final ReflectiveVisitor visitor, final String methodName, final Class arg0Clazz, final Class... otherArgClasses) { final List otherArgClassList = ImmutableList.copyOf(otherArgClasses); @SuppressWarnings({"unchecked" }) final ReflectiveVisitDispatcher dispatcher = createDispatcher( (Class) visitor.getClass(), arg0Clazz); return new MethodDispatcher() { public T invoke(Object... args) { Method method = lookupMethod(args[0]); try { final Object o = method.invoke(visitor, args); return returnClazz.cast(o); } catch (IllegalAccessException | InvocationTargetException e) { throw new RuntimeException("While invoking method '" + method + "'", e); } } private Method lookupMethod(final Object arg0) { if (!arg0Clazz.isInstance(arg0)) { throw new IllegalArgumentException(); } Method method = dispatcher.lookupVisitMethod( visitor.getClass(), (Class) arg0.getClass(), methodName, otherArgClassList); if (method == null) { List classList = new ArrayList<>(); classList.add(arg0Clazz); classList.addAll(otherArgClassList); throw new IllegalArgumentException("Method not found: " + methodName + "(" + classList + ")"); } return method; } }; } /** Derives the name of the {@code i}th parameter of a method. */ public static String getParameterName(Method method, int i) { for (Annotation annotation : method.getParameterAnnotations()[i]) { if (annotation.annotationType() == Parameter.class) { return ((Parameter) annotation).name(); } } return Compatible.INSTANCE.getParameterName(method, i); } /** Derives whether the {@code i}th parameter of a method is optional. */ public static boolean isParameterOptional(Method method, int i) { for (Annotation annotation : method.getParameterAnnotations()[i]) { if (annotation.annotationType() == Parameter.class) { return ((Parameter) annotation).optional(); } } return false; } //~ Inner Classes ---------------------------------------------------------- /** * Can invoke a method on an object of type E with return type T. * * @param Return type of method */ public interface MethodDispatcher { /** * Invokes method on an object with a given set of arguments. * * @param args Arguments to method * @return Return value of method */ T invoke(Object... args); } } // End ReflectUtil.java