安全风险 - 如何解决 setAccessible(true) 带来的安全风险?

可能每款成熟的金融app上架前都会经过层层安全检测才能执行上架,所以我隔三差五就能看到安全检测报告中提到的问题,根据问题的不同级别,处理的优先级也有所不同,此次讲的主要是一个 “轻度问题” ,个人认为属于那种可改不可改的状态

Tip因并未重新进行安全检测,尚不确定该方式是否能解决实际提到的问题

人生处处是课堂

    • 所遇问题
    • 自我求知
      • setAccessible
      • 反射原理
    • 解决过程
      • 第一阶段
      • 第二阶段
    • 最终方案
      • 解决方式
        • ReflectionUtils
        • ReflectionHelper
      • 使用方式
    • SecurityManager 相关思考
      • 如何规避 setAccessible 风险?
      • SecurityManager 如何给 setAccessible 授权?
      • SecurityManager 如何使用?

所遇问题

漏洞描述AccessibleObject 类 允许程序员绕过 由 Java 访问说明符提供的 访问控制(access control)检查,特别是他让程序员能够允许反射对象绕过 Java access control,并反过来更改私有字段或调用私有方法、行为,这些通常情况下都是不允许的 |

漏洞影响:不符合安全准则,绕过部分安全控制

解决建议:建议应用服务器或者应用程序使用 SecurityManager的。如果存在System.getSecurityManager则该方法会必须先经过它的同意才能调用(这条建议是安全中心给出的,然后我全局都搜索不到SecurityManagerSystem.getSecurityManager,起初先忽略了,回头看的时候在最后补充了相关内容)

触发安全风险的伪代码示例

在这里插入图片描述


自我求知

解决问题的第一步是明确问题的产生原因,然后针对于此进行逐步解决

结论先行:项目中存在类(对象)操作的相关代码

  • 当编译时,编译器会进行访问(权限)检查
  • 可以通过setAccessible方法屏蔽或者说禁用运行时访问检查

setAccessible

在安全中心给出的风险代码段中 ,核心风险代码为 setAccessible(true),那么有必要先了解一下此为何物

之前在 java setaccessible 用处 中看到一个简短描述,提示了可能存在潜在风险

在这里插入图片描述

按照我看源码的猜想,不论访问权限是(public、private)哪种,setAccessible 在底层中默认应该都是 false,意味着都需要接受权限检查,主要区别在于 public 可以通过检查,而 private 通不过

setAccessible(boolean flag) 方法是 AccessibleObject 类中的一个方法,它是 FieldMethodConstructor的公共父类。

在这里插入图片描述

通过反射Class类后,以下三种都是其内部可反射的范围,当触发这些场景将执行运行时访问检查:

  • Field(字段) 设置字段(set(Object obj, Object value))或获取字段(get(Object obj))
  • Method(方法) 调用方法(invoke(Object obj, Object… args))
  • Constructor(构造函数) 创建和初始化类的新实例(newInstance(Object… initargs))

反射原理

Java反射是一种强大的特性,它允许程序在运行时动态地获取和操作类的信息。通过反射,我们可以创建对象、调用方法和访问字段,而不需要提前知道类的具体定义。

Java反射的原理基于Java的运行时数据区域(Runtime Data Area)和类加载机制。当Java虚拟机加载一个类时,它将类的字节码文件加载到内存中,并在方法区创建一个Class对象来表示该类

因为Class对象包含了类的完整信息,包括类的构造函数、方法、字段等;所以可以通过反射提供的一系列方法在运行时来获取Class对象、获取构造函数、获取方法、获取字段等。


解决过程

起初看到这个问题,我认为是没必要解决,所以直接拒了需求方,然后因为工作态度就被上了一课,然后直接给我发了一个别人的处理方式 - field.setAccessible(true);代码扫描有安全漏洞,解决方案

第一阶段

AccessibleObject类是 FieldMethodConstructor对象的基类,能够允许反射对象修改访问权限修饰符,绕过由Java访问修饰符提供的访问控制检查。它让程序员能够更改私有字段或调用私有方法,这在通常情况下是不允许的!

例如:以下代码片段中,将Field将accessible标记设置为true。

 Class clazz = User.class;
 Field field = clazz.getField("name");
 field.setAccessible(true);

如果为false,则其中的私有字段不能够被访问到的,所以不可以注掉。

 ReflectionUtils.makeAccessible(field);

个人想法:起初不确定是用 ReflectionUtils.makeAccessible(field) 替换 field.setAccessible(true) ,还行是在尾端加入ReflectionUtils.makeAccessible(field) ,所以可以先看看源码(后续会提到该类详情),可以看出在源码中做了权限检查后才确定是否禁用权限检查

在这里插入图片描述

调用代码,类似如下

 Class clazz = User.class;
 Field field = clazz.getField("name");
 ReflectionUtils.makeAccessible(field);

第二阶段

因为这里并未提供 ReflectionUtils 工具类,所以自行搜索到了 ReflectionUtils反射工具:精要介绍与实战应用指南

作者说:org.springframework.util.ReflectionUtils 是 Spring 框架提供的一个反射工具类,它封装了 Java 反射 API 的一些常用操作,使得我们能够更加方便、简洁地使用反射功能…

这篇Blog内并不是一无所获,至少我们可以看到这款工具类的相关调用方式!

在这里插入图片描述
那么接了下来我们就去找一下 AndroidReflectionUtils 工具类


最终方案

经自我查证和同事推荐,主要找到俩种方法,处理方式应该是一样的,但是这种方法是否真的能解决问题?我目前对最终结果保持怀疑态度

解决方式

ReflectionUtils

找了半天在 Android反射机制简单理解,ReflectionUtils 反射工具类 看到一个类似的 ReflectionUtils(可直接copy)

package xxx;

import java.lang.reflect.Constructor;
import java.lang.reflect.Field;
import java.lang.reflect.InvocationTargetException;
import java.lang.reflect.Method;
import java.lang.reflect.Modifier;
import java.lang.reflect.UndeclaredThrowableException;
import java.sql.SQLException;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.List;
import java.util.regex.Pattern;

public class ReflectionUtils {
    /**
     * Pattern for detecting CGLIB-renamed methods.
     * @see #isCglibRenamedMethod
     */
    private static final Pattern CGLIB_RENAMED_METHOD_PATTERN = Pattern.compile("CGLIB\\$(.+)\\$\\d+");


    /**
     * Attempt to find a {@link Field field} on the supplied {@link Class} with the
     * supplied {@code name}. Searches all superclasses up to {@link Object}.
     * @param clazz the class to introspect
     * @param name the name of the field
     * @return the corresponding Field object, or {@code null} if not found
     */
    public static Field findField(Class<?> clazz, String name) {
        return findField(clazz, name, null);
    }

    /**
     * Attempt to find a {@link Field field} on the supplied {@link Class} with the
     * supplied {@code name} and/or {@link Class type}. Searches all superclasses
     * up to {@link Object}.
     * @param clazz the class to introspect
     * @param name the name of the field (may be {@code null} if type is specified)
     * @param type the type of the field (may be {@code null} if name is specified)
     * @return the corresponding Field object, or {@code null} if not found
     */
    public static Field findField(Class<?> clazz, String name, Class<?> type) {
        //Assert.notNull(clazz, "Class must not be null");
        //Assert.isTrue(name != null || type != null, "Either name or type of the field must be specified");
        Class<?> searchType = clazz;
        while (!Object.class.equals(searchType) && searchType != null) {
            Field[] fields = searchType.getDeclaredFields();
            for (Field field : fields) {
                if ((name == null || name.equals(field.getName())) && (type == null || type.equals(field.getType()))) {
                    return field;
                }
            }
            searchType = searchType.getSuperclass();
        }
        return null;
    }

    /**
     * Set the field represented by the supplied {@link Field field object} on the
     * specified {@link Object target object} to the specified {@code value}.
     * In accordance with {@link Field#set(Object, Object)} semantics, the new value
     * is automatically unwrapped if the underlying field has a primitive type.
     * <p>Thrown exceptions are handled via a call to {@link #handleReflectionException(Exception)}.
     * @param field the field to set
     * @param target the target object on which to set the field
     * @param value the value to set; may be {@code null}
     */
    public static void setField(Field field, Object target, Object value) {
        try {
            field.set(target, value);
        }
        catch (IllegalAccessException ex) {
            handleReflectionException(ex);
            throw new IllegalStateException(
                    "Unexpected reflection exception - " + ex.getClass().getName() + ": " + ex.getMessage());
        }
    }

    /**
     * Get the field represented by the supplied {@link Field field object} on the
     * specified {@link Object target object}. In accordance with {@link Field#get(Object)}
     * semantics, the returned value is automatically wrapped if the underlying field
     * has a primitive type.
     * <p>Thrown exceptions are handled via a call to {@link #handleReflectionException(Exception)}.
     * @param field the field to get
     * @param target the target object from which to get the field
     * @return the field's current value
     */
    public static Object getField(Field field, Object target) {
        try {
            return field.get(target);
        }
        catch (IllegalAccessException ex) {
            handleReflectionException(ex);
            throw new IllegalStateException(
                    "Unexpected reflection exception - " + ex.getClass().getName() + ": " + ex.getMessage());
        }
    }

    /**
     * Attempt to find a {@link Method} on the supplied class with the supplied name
     * and no parameters. Searches all superclasses up to {@code Object}.
     * <p>Returns {@code null} if no {@link Method} can be found.
     * @param clazz the class to introspect
     * @param name the name of the method
     * @return the Method object, or {@code null} if none found
     */
    public static Method findMethod(Class<?> clazz, String name) {
        return findMethod(clazz, name, new Class<?>[0]);
    }

    /**
     * Attempt to find a {@link Method} on the supplied class with the supplied name
     * and parameter types. Searches all superclasses up to {@code Object}.
     * <p>Returns {@code null} if no {@link Method} can be found.
     * @param clazz the class to introspect
     * @param name the name of the method
     * @param paramTypes the parameter types of the method
     * (may be {@code null} to indicate any signature)
     * @return the Method object, or {@code null} if none found
     */
    public static Method findMethod(Class<?> clazz, String name, Class<?>... paramTypes) {
        //Assert.notNull(clazz, "Class must not be null");
        //Assert.notNull(name, "Method name must not be null");
        Class<?> searchType = clazz;
        while (searchType != null) {
            Method[] methods = (searchType.isInterface() ? searchType.getMethods() : searchType.getDeclaredMethods());
            for (Method method : methods)
                if (name.equals(method.getName()) &&
                        (paramTypes == null || Arrays.equals(paramTypes, method.getParameterTypes()))) {
                    return method;
                }
            searchType = searchType.getSuperclass();
        }
        return null;
    }

    /**
     * Invoke the specified {@link Method} against the supplied target object with no arguments.
     * The target object can be {@code null} when invoking a static {@link Method}.
     * <p>Thrown exceptions are handled via a call to {@link #handleReflectionException}.
     * @param method the method to invoke
     * @param target the target object to invoke the method on
     * @return the invocation result, if any
     * @see #invokeMethod(Method, Object, Object[])
     */
    public static Object invokeMethod(Method method, Object target) {
        return invokeMethod(method, target, new Object[0]);
    }

    /**
     * Invoke the specified {@link Method} against the supplied target object with the
     * supplied arguments. The target object can be {@code null} when invoking a
     * static {@link Method}.
     * <p>Thrown exceptions are handled via a call to {@link #handleReflectionException}.
     * @param method the method to invoke
     * @param target the target object to invoke the method on
     * @param args the invocation arguments (may be {@code null})
     * @return the invocation result, if any
     */
    public static Object invokeMethod(Method method, Object target, Object... args) {
        try {
            return method.invoke(target, args);
        }
        catch (Exception ex) {
            handleReflectionException(ex);
        }
        throw new IllegalStateException("Should never get here");
    }

    /**
     * Invoke the specified JDBC API {@link Method} against the supplied target
     * object with no arguments.
     * @param method the method to invoke
     * @param target the target object to invoke the method on
     * @return the invocation result, if any
     * @throws SQLException the JDBC API SQLException to rethrow (if any)
     * @see #invokeJdbcMethod(Method, Object, Object[])
     */
    public static Object invokeJdbcMethod(Method method, Object target) throws SQLException {
        return invokeJdbcMethod(method, target, new Object[0]);
    }

    /**
     * Invoke the specified JDBC API {@link Method} against the supplied target
     * object with the supplied arguments.
     * @param method the method to invoke
     * @param target the target object to invoke the method on
     * @param args the invocation arguments (may be {@code null})
     * @return the invocation result, if any
     * @throws SQLException the JDBC API SQLException to rethrow (if any)
     * @see #invokeMethod(Method, Object, Object[])
     */
    public static Object invokeJdbcMethod(Method method, Object target, Object... args) throws SQLException {
        try {
            return method.invoke(target, args);
        }
        catch (IllegalAccessException ex) {
            handleReflectionException(ex);
        }
        catch (InvocationTargetException ex) {
            if (ex.getTargetException() instanceof SQLException) {
                throw (SQLException) ex.getTargetException();
            }
            handleInvocationTargetException(ex);
        }
        throw new IllegalStateException("Should never get here");
    }

    /**
     * Handle the given reflection exception. Should only be called if no
     * checked exception is expected to be thrown by the target method.
     * <p>Throws the underlying RuntimeException or Error in case of an
     * InvocationTargetException with such a root cause. Throws an
     * IllegalStateException with an appropriate message else.
     * @param ex the reflection exception to handle
     */
    public static void handleReflectionException(Exception ex) {
        if (ex instanceof NoSuchMethodException) {
            throw new IllegalStateException("Method not found: " + ex.getMessage());
        }
        if (ex instanceof IllegalAccessException) {
            throw new IllegalStateException("Could not access method: " + ex.getMessage());
        }
        if (ex instanceof InvocationTargetException) {
            handleInvocationTargetException((InvocationTargetException) ex);
        }
        if (ex instanceof RuntimeException) {
            throw (RuntimeException) ex;
        }
        throw new UndeclaredThrowableException(ex);
    }

    /**
     * Handle the given invocation target exception. Should only be called if no
     * checked exception is expected to be thrown by the target method.
     * <p>Throws the underlying RuntimeException or Error in case of such a root
     * cause. Throws an IllegalStateException else.
     * @param ex the invocation target exception to handle
     */
    public static void handleInvocationTargetException(InvocationTargetException ex) {
        rethrowRuntimeException(ex.getTargetException());
    }

    /**
     * Rethrow the given {@link Throwable exception}, which is presumably the
     * <em>target exception</em> of an {@link InvocationTargetException}. Should
     * only be called if no checked exception is expected to be thrown by the
     * target method.
     * <p>Rethrows the underlying exception cast to an {@link RuntimeException} or
     * {@link Error} if appropriate; otherwise, throws an
     * {@link IllegalStateException}.
     * @param ex the exception to rethrow
     * @throws RuntimeException the rethrown exception
     */
    public static void rethrowRuntimeException(Throwable ex) {
        if (ex instanceof RuntimeException) {
            throw (RuntimeException) ex;
        }
        if (ex instanceof Error) {
            throw (Error) ex;
        }
        throw new UndeclaredThrowableException(ex);
    }

    /**
     * Rethrow the given {@link Throwable exception}, which is presumably the
     * <em>target exception</em> of an {@link InvocationTargetException}. Should
     * only be called if no checked exception is expected to be thrown by the
     * target method.
     * <p>Rethrows the underlying exception cast to an {@link Exception} or
     * {@link Error} if appropriate; otherwise, throws an
     * {@link IllegalStateException}.
     * @param ex the exception to rethrow
     * @throws Exception the rethrown exception (in case of a checked exception)
     */
    public static void rethrowException(Throwable ex) throws Exception {
        if (ex instanceof Exception) {
            throw (Exception) ex;
        }
        if (ex instanceof Error) {
            throw (Error) ex;
        }
        throw new UndeclaredThrowableException(ex);
    }

    /**
     * Determine whether the given method explicitly declares the given
     * exception or one of its superclasses, which means that an exception of
     * that type can be propagated as-is within a reflective invocation.
     * @param method the declaring method
     * @param exceptionType the exception to throw
     * @return {@code true} if the exception can be thrown as-is;
     * {@code false} if it needs to be wrapped
     */
    public static boolean declaresException(Method method, Class<?> exceptionType) {
        //Assert.notNull(method, "Method must not be null");
        Class<?>[] declaredExceptions = method.getExceptionTypes();
        for (Class<?> declaredException : declaredExceptions) {
            if (declaredException.isAssignableFrom(exceptionType)) {
                return true;
            }
        }
        return false;
    }

    /**
     * Determine whether the given field is a "public static final" constant.
     * @param field the field to check
     */
    public static boolean isPublicStaticFinal(Field field) {
        int modifiers = field.getModifiers();
        return (Modifier.isPublic(modifiers) && Modifier.isStatic(modifiers) && Modifier.isFinal(modifiers));
    }

    /**
     * Determine whether the given method is an "equals" method.
     * @see Object#equals(Object)
     */
    public static boolean isEqualsMethod(Method method) {
        if (method == null || !method.getName().equals("equals")) {
            return false;
        }
        Class<?>[] paramTypes = method.getParameterTypes();
        return (paramTypes.length == 1 && paramTypes[0] == Object.class);
    }

    /**
     * Determine whether the given method is a "hashCode" method.
     * @see Object#hashCode()
     */
    public static boolean isHashCodeMethod(Method method) {
        return (method != null && method.getName().equals("hashCode") && method.getParameterTypes().length == 0);
    }

    /**
     * Determine whether the given method is a "toString" method.
     * @see Object#toString()
     */
    public static boolean isToStringMethod(Method method) {
        return (method != null && method.getName().equals("toString") && method.getParameterTypes().length == 0);
    }

    /**
     * Determine whether the given method is originally declared by {@link Object}.
     */
    public static boolean isObjectMethod(Method method) {
        if (method == null) {
            return false;
        }
        try {
            Object.class.getDeclaredMethod(method.getName(), method.getParameterTypes());
            return true;
        }
        catch (Exception ex) {
            return false;
        }
    }

    /**
     * Determine whether the given method is a CGLIB 'renamed' method,
     * following the pattern "CGLIB$methodName$0".
     * @param renamedMethod the method to check
     * @see //org.springframework.cglib.proxy.Enhancer#rename
     */
    public static boolean isCglibRenamedMethod(Method renamedMethod) {
        return CGLIB_RENAMED_METHOD_PATTERN.matcher(renamedMethod.getName()).matches();
    }

    /**
     * Make the given field accessible, explicitly setting it accessible if
     * necessary. The {@code setAccessible(true)} method is only called
     * when actually necessary, to avoid unnecessary conflicts with a JVM
     * SecurityManager (if active).
     * @param field the field to make accessible
     * @see Field#setAccessible
     */
    public static void makeAccessible(Field field) {
        if ((!Modifier.isPublic(field.getModifiers()) || !Modifier.isPublic(field.getDeclaringClass().getModifiers()) ||
                Modifier.isFinal(field.getModifiers())) && !field.isAccessible()) {
            field.setAccessible(true);
        }
    }

    /**
     * Make the given method accessible, explicitly setting it accessible if
     * necessary. The {@code setAccessible(true)} method is only called
     * when actually necessary, to avoid unnecessary conflicts with a JVM
     * SecurityManager (if active).
     * @param method the method to make accessible
     * @see Method#setAccessible
     */
    public static void makeAccessible(Method method) {
        if ((!Modifier.isPublic(method.getModifiers()) || !Modifier.isPublic(method.getDeclaringClass().getModifiers()))
                && !method.isAccessible()) {
            method.setAccessible(true);
        }
    }

    /**
     * Make the given constructor accessible, explicitly setting it accessible
     * if necessary. The {@code setAccessible(true)} method is only called
     * when actually necessary, to avoid unnecessary conflicts with a JVM
     * SecurityManager (if active).
     * @param ctor the constructor to make accessible
     * @see Constructor#setAccessible
     */
    public static void makeAccessible(Constructor<?> ctor) {
        if ((!Modifier.isPublic(ctor.getModifiers()) || !Modifier.isPublic(ctor.getDeclaringClass().getModifiers()))
                && !ctor.isAccessible()) {
            ctor.setAccessible(true);
        }
    }

    /**
     * Perform the given callback operation on all matching methods of the given
     * class and superclasses.
     * <p>The same named method occurring on subclass and superclass will appear
     * twice, unless excluded by a {@link MethodFilter}.
     * @param clazz class to start looking at
     * @param mc the callback to invoke for each method
     * @see #doWithMethods(Class, MethodCallback, MethodFilter)
     */
    public static void doWithMethods(Class<?> clazz, MethodCallback mc) throws IllegalArgumentException {
        doWithMethods(clazz, mc, null);
    }

    /**
     * Perform the given callback operation on all matching methods of the given
     * class and superclasses (or given interface and super-interfaces).
     * <p>The same named method occurring on subclass and superclass will appear
     * twice, unless excluded by the specified {@link MethodFilter}.
     * @param clazz class to start looking at
     * @param mc the callback to invoke for each method
     * @param mf the filter that determines the methods to apply the callback to
     */
    public static void doWithMethods(Class<?> clazz, MethodCallback mc, MethodFilter mf)
            throws IllegalArgumentException {

        // Keep backing up the inheritance hierarchy.
        Method[] methods = clazz.getDeclaredMethods();
        for (Method method : methods) {
            if (mf != null && !mf.matches(method)) {
                continue;
            }
            try {
                mc.doWith(method);
            }
            catch (IllegalAccessException ex) {
                throw new IllegalStateException("Shouldn't be illegal to access method '" + method.getName()
                        + "': " + ex);
            }
        }
        if (clazz.getSuperclass() != null) {
            doWithMethods(clazz.getSuperclass(), mc, mf);
        }
        else if (clazz.isInterface()) {
            for (Class<?> superIfc : clazz.getInterfaces()) {
                doWithMethods(superIfc, mc, mf);
            }
        }
    }

    /**
     * Get all declared methods on the leaf class and all superclasses. Leaf
     * class methods are included first.
     */
    public static Method[] getAllDeclaredMethods(Class<?> leafClass) throws IllegalArgumentException {
        final List<Method> methods = new ArrayList<Method>(32);
        doWithMethods(leafClass, new MethodCallback() {
            public void doWith(Method method) {
                methods.add(method);
            }
        });
        return methods.toArray(new Method[methods.size()]);
    }

    /**
     * Get the unique set of declared methods on the leaf class and all superclasses. Leaf
     * class methods are included first and while traversing the superclass hierarchy any methods found
     * with signatures matching a method already included are filtered out.
     */
    public static Method[] getUniqueDeclaredMethods(Class<?> leafClass) throws IllegalArgumentException {
        final List<Method> methods = new ArrayList<Method>(32);
        doWithMethods(leafClass, new MethodCallback() {
            public void doWith(Method method) {
                boolean knownSignature = false;
                Method methodBeingOverriddenWithCovariantReturnType = null;
                for (Method existingMethod : methods) {
                    if (method.getName().equals(existingMethod.getName()) &&
                            Arrays.equals(method.getParameterTypes(), existingMethod.getParameterTypes())) {
                        // Is this a covariant return type situation?
                        if (existingMethod.getReturnType() != method.getReturnType() &&
                                existingMethod.getReturnType().isAssignableFrom(method.getReturnType())) {
                            methodBeingOverriddenWithCovariantReturnType = existingMethod;
                        }
                        else {
                            knownSignature = true;
                        }
                        break;
                    }
                }
                if (methodBeingOverriddenWithCovariantReturnType != null) {
                    methods.remove(methodBeingOverriddenWithCovariantReturnType);
                }
                if (!knownSignature && !isCglibRenamedMethod(method)) {
                    methods.add(method);
                }
            }
        });
        return methods.toArray(new Method[methods.size()]);
    }

    /**
     * Invoke the given callback on all fields in the target class, going up the
     * class hierarchy to get all declared fields.
     * @param clazz the target class to analyze
     * @param fc the callback to invoke for each field
     */
    public static void doWithFields(Class<?> clazz, FieldCallback fc) throws IllegalArgumentException {
        doWithFields(clazz, fc, null);
    }

    /**
     * Invoke the given callback on all fields in the target class, going up the
     * class hierarchy to get all declared fields.
     * @param clazz the target class to analyze
     * @param fc the callback to invoke for each field
     * @param ff the filter that determines the fields to apply the callback to
     */
    public static void doWithFields(Class<?> clazz, FieldCallback fc, FieldFilter ff)
            throws IllegalArgumentException {

        // Keep backing up the inheritance hierarchy.
        Class<?> targetClass = clazz;
        do {
            Field[] fields = targetClass.getDeclaredFields();
            for (Field field : fields) {
                // Skip static and final fields.
                if (ff != null && !ff.matches(field)) {
                    continue;
                }
                try {
                    fc.doWith(field);
                }
                catch (IllegalAccessException ex) {
                    throw new IllegalStateException(
                            "Shouldn't be illegal to access field '" + field.getName() + "': " + ex);
                }
            }
            targetClass = targetClass.getSuperclass();
        }
        while (targetClass != null && targetClass != Object.class);
    }

    /**
     * Given the source object and the destination, which must be the same class
     * or a subclass, copy all fields, including inherited fields. Designed to
     * work on objects with public no-arg constructors.
     * @throws IllegalArgumentException if the arguments are incompatible
     */
    public static void shallowCopyFieldState(final Object src, final Object dest) throws IllegalArgumentException {
        if (src == null) {
            throw new IllegalArgumentException("Source for field copy cannot be null");
        }
        if (dest == null) {
            throw new IllegalArgumentException("Destination for field copy cannot be null");
        }
        if (!src.getClass().isAssignableFrom(dest.getClass())) {
            throw new IllegalArgumentException("Destination class [" + dest.getClass().getName()
                    + "] must be same or subclass as source class [" + src.getClass().getName() + "]");
        }
        doWithFields(src.getClass(), new FieldCallback() {
            public void doWith(Field field) throws IllegalArgumentException, IllegalAccessException {
                makeAccessible(field);
                Object srcValue = field.get(src);
                field.set(dest, srcValue);
            }
        }, COPYABLE_FIELDS);
    }


    /**
     * Action to take on each method.
     */
    public interface MethodCallback {

        /**
         * Perform an operation using the given method.
         * @param method the method to operate on
         */
        void doWith(Method method) throws IllegalArgumentException, IllegalAccessException;
    }


    /**
     * Callback optionally used to filter methods to be operated on by a method callback.
     */
    public interface MethodFilter {

        /**
         * Determine whether the given method matches.
         * @param method the method to check
         */
        boolean matches(Method method);
    }


    /**
     * Callback interface invoked on each field in the hierarchy.
     */
    public interface FieldCallback {

        /**
         * Perform an operation using the given field.
         * @param field the field to operate on
         */
        void doWith(Field field) throws IllegalArgumentException, IllegalAccessException;
    }


    /**
     * Callback optionally used to filter fields to be operated on by a field callback.
     */
    public interface FieldFilter {

        /**
         * Determine whether the given field matches.
         * @param field the field to check
         */
        boolean matches(Field field);
    }


    /**
     * Pre-built FieldFilter that matches all non-static, non-final fields.
     */
    public static FieldFilter COPYABLE_FIELDS = new FieldFilter() {

        public boolean matches(Field field) {
            return !(Modifier.isStatic(field.getModifiers()) || Modifier.isFinal(field.getModifiers()));
        }
    };


    /**
     * Pre-built MethodFilter that matches all non-bridge methods.
     */
    public static MethodFilter NON_BRIDGED_METHODS = new MethodFilter() {

        public boolean matches(Method method) {
            return !method.isBridge();
        }
    };


    /**
     * Pre-built MethodFilter that matches all non-bridge methods
     * which are not declared on {@code java.lang.Object}.
     */
    public static MethodFilter USER_DECLARED_METHODS = new MethodFilter() {

        public boolean matches(Method method) {
            return (!method.isBridge() && method.getDeclaringClass() != Object.class);
        }
    };
}
ReflectionHelper

ReflectionHelpergoogle.gson 提供的一个类,有需要的话可以引入 gson 依赖,不确定copy后是否可直接使用(如果有包内关联类的话,最好是引入依赖)

package com.google.gson.internal.reflect;

import com.google.gson.JsonIOException;
import com.google.gson.internal.GsonBuildConfig;
import java.lang.reflect.AccessibleObject;
import java.lang.reflect.Constructor;
import java.lang.reflect.Field;
import java.lang.reflect.Method;

public class ReflectionHelper {

  private static final RecordHelper RECORD_HELPER;

  static {
    RecordHelper instance;
    try {
      // Try to construct the RecordSupportedHelper, if this fails, records are not supported on this JVM.
      instance = new RecordSupportedHelper();
    } catch (NoSuchMethodException e) {
      instance = new RecordNotSupportedHelper();
    }
    RECORD_HELPER = instance;
  }

  private ReflectionHelper() {}

  /**
   * Internal implementation of making an {@link AccessibleObject} accessible.
   *
   * @param object the object that {@link AccessibleObject#setAccessible(boolean)} should be called on.
   * @throws JsonIOException if making the object accessible fails
   */
  public static void makeAccessible(AccessibleObject object) throws JsonIOException {
    try {
      object.setAccessible(true);
    } catch (Exception exception) {
      String description = getAccessibleObjectDescription(object, false);
      throw new JsonIOException("Failed making " + description + " accessible; either increase its visibility"
              + " or write a custom TypeAdapter for its declaring type.", exception);
    }
  }

  /**
   * Returns a short string describing the {@link AccessibleObject} in a human-readable way.
   * The result is normally shorter than {@link AccessibleObject#toString()} because it omits
   * modifiers (e.g. {@code final}) and uses simple names for constructor and method parameter
   * types.
   *
   * @param object object to describe
   * @param uppercaseFirstLetter whether the first letter of the description should be uppercased
   */
  public static String getAccessibleObjectDescription(AccessibleObject object, boolean uppercaseFirstLetter) {
    String description;

    if (object instanceof Field) {
      description = "field '" + fieldToString((Field) object) + "'";
    } else if (object instanceof Method) {
      Method method = (Method) object;

      StringBuilder methodSignatureBuilder = new StringBuilder(method.getName());
      appendExecutableParameters(method, methodSignatureBuilder);
      String methodSignature = methodSignatureBuilder.toString();

      description = "method '" + method.getDeclaringClass().getName() + "#" + methodSignature + "'";
    } else if (object instanceof Constructor) {
      description = "constructor '" + constructorToString((Constructor<?>) object) + "'";
    } else {
      description = "<unknown AccessibleObject> " + object.toString();
    }

    if (uppercaseFirstLetter && Character.isLowerCase(description.charAt(0))) {
      description = Character.toUpperCase(description.charAt(0)) + description.substring(1);
    }
    return description;
  }

  /**
   * Creates a string representation for a field, omitting modifiers and
   * the field type.
   */
  public static String fieldToString(Field field) {
    return field.getDeclaringClass().getName() + "#" + field.getName();
  }

  /**
   * Creates a string representation for a constructor.
   * E.g.: {@code java.lang.String(char[], int, int)}
   */
  public static String constructorToString(Constructor<?> constructor) {
    StringBuilder stringBuilder = new StringBuilder(constructor.getDeclaringClass().getName());
    appendExecutableParameters(constructor, stringBuilder);

    return stringBuilder.toString();
  }

  // Note: Ideally parameter type would be java.lang.reflect.Executable, but that was added in Java 8
  private static void appendExecutableParameters(AccessibleObject executable, StringBuilder stringBuilder) {
    stringBuilder.append('(');

    Class<?>[] parameters = (executable instanceof Method)
        ? ((Method) executable).getParameterTypes()
        : ((Constructor<?>) executable).getParameterTypes();
    for (int i = 0; i < parameters.length; i++) {
      if (i > 0) {
        stringBuilder.append(", ");
      }
      stringBuilder.append(parameters[i].getSimpleName());
    }

    stringBuilder.append(')');
  }

  /**
   * Tries making the constructor accessible, returning an exception message
   * if this fails.
   *
   * @param constructor constructor to make accessible
   * @return exception message; {@code null} if successful, non-{@code null} if
   *    unsuccessful
   */
  public static String tryMakeAccessible(Constructor<?> constructor) {
    try {
      constructor.setAccessible(true);
      return null;
    } catch (Exception exception) {
      return "Failed making constructor '" + constructorToString(constructor) + "' accessible;"
          + " either increase its visibility or write a custom InstanceCreator or TypeAdapter for"
          // Include the message since it might contain more detailed information
          + " its declaring type: " + exception.getMessage();
    }
  }

  /** If records are supported on the JVM, this is equivalent to a call to Class.isRecord() */
  public static boolean isRecord(Class<?> raw) {
    return RECORD_HELPER.isRecord(raw);
  }

  public static String[] getRecordComponentNames(Class<?> raw) {
    return RECORD_HELPER.getRecordComponentNames(raw);
  }

  /** Looks up the record accessor method that corresponds to the given record field */
  public static Method getAccessor(Class<?> raw, Field field) {
    return RECORD_HELPER.getAccessor(raw, field);
  }

  public static <T> Constructor<T> getCanonicalRecordConstructor(Class<T> raw) {
    return RECORD_HELPER.getCanonicalRecordConstructor(raw);
  }

  public static RuntimeException createExceptionForUnexpectedIllegalAccess(
      IllegalAccessException exception) {
    throw new RuntimeException("Unexpected IllegalAccessException occurred (Gson " + GsonBuildConfig.VERSION + ")."
        + " Certain ReflectionAccessFilter features require Java >= 9 to work correctly. If you are not using"
        + " ReflectionAccessFilter, report this to the Gson maintainers.",
        exception);
  }


  private static RuntimeException createExceptionForRecordReflectionException(
          ReflectiveOperationException exception) {
    throw new RuntimeException("Unexpected ReflectiveOperationException occurred"
            + " (Gson " + GsonBuildConfig.VERSION + ")."
            + " To support Java records, reflection is utilized to read out information"
            + " about records. All these invocations happens after it is established"
            + " that records exist in the JVM. This exception is unexpected behavior.",
            exception);
  }

  /**
   * Internal abstraction over reflection when Records are supported.
   */
  private abstract static class RecordHelper {
    abstract boolean isRecord(Class<?> clazz);

    abstract String[] getRecordComponentNames(Class<?> clazz);

    abstract <T> Constructor<T> getCanonicalRecordConstructor(Class<T> raw);

    public abstract Method getAccessor(Class<?> raw, Field field);
  }

  private static class RecordSupportedHelper extends RecordHelper {
    private final Method isRecord;
    private final Method getRecordComponents;
    private final Method getName;
    private final Method getType;

    private RecordSupportedHelper() throws NoSuchMethodException {
      isRecord = Class.class.getMethod("isRecord");
      getRecordComponents = Class.class.getMethod("getRecordComponents");
      // Class java.lang.reflect.RecordComponent
      Class<?> classRecordComponent = getRecordComponents.getReturnType().getComponentType();
      getName = classRecordComponent.getMethod("getName");
      getType = classRecordComponent.getMethod("getType");
    }

    @Override
    boolean isRecord(Class<?> raw) {
      try {
        return (boolean) isRecord.invoke(raw);
      } catch (ReflectiveOperationException e) {
        throw createExceptionForRecordReflectionException(e);
      }
    }

    @Override
    String[] getRecordComponentNames(Class<?> raw) {
      try {
        Object[] recordComponents = (Object[]) getRecordComponents.invoke(raw);
        String[] componentNames = new String[recordComponents.length];
        for (int i = 0; i < recordComponents.length; i++) {
          componentNames[i] = (String) getName.invoke(recordComponents[i]);
        }
        return componentNames;
      } catch (ReflectiveOperationException e) {
        throw createExceptionForRecordReflectionException(e);
      }
    }

    @Override
    public <T> Constructor<T> getCanonicalRecordConstructor(Class<T> raw) {
      try {
        Object[] recordComponents = (Object[]) getRecordComponents.invoke(raw);
        Class<?>[] recordComponentTypes = new Class<?>[recordComponents.length];
        for (int i = 0; i < recordComponents.length; i++) {
          recordComponentTypes[i] = (Class<?>) getType.invoke(recordComponents[i]);
        }
        // Uses getDeclaredConstructor because implicit constructor has same visibility as record and might
        // therefore not be public
        return raw.getDeclaredConstructor(recordComponentTypes);
      } catch (ReflectiveOperationException e) {
        throw createExceptionForRecordReflectionException(e);
      }
    }

    @Override
    public Method getAccessor(Class<?> raw, Field field) {
      try {
        // Records consists of record components, each with a unique name, a corresponding field and accessor method
        // with the same name. Ref.: https://docs.oracle.com/javase/specs/jls/se17/html/jls-8.html#jls-8.10.3
        return raw.getMethod(field.getName());
      } catch (ReflectiveOperationException e) {
        throw createExceptionForRecordReflectionException(e);
      }
    }
  }

  /**
   * Instance used when records are not supported
   */
  private static class RecordNotSupportedHelper extends RecordHelper {

    @Override
    boolean isRecord(Class<?> clazz) {
      return false;
    }

    @Override
    String[] getRecordComponentNames(Class<?> clazz) {
      throw new UnsupportedOperationException(
              "Records are not supported on this JVM, this method should not be called");
    }

    @Override
    <T> Constructor<T> getCanonicalRecordConstructor(Class<T> raw) {
      throw new UnsupportedOperationException(
              "Records are not supported on this JVM, this method should not be called");
    }

    @Override
    public Method getAccessor(Class<?> raw, Field field) {
      throw new UnsupportedOperationException(
              "Records are not supported on this JVM, this method should not be called");
    }
  }
}

使用方式

仅需在原 setAccessible(true) 处采用 ReflectionHelper.makeAccessible(xxx)ReflectionUtils.makeAccessible(xxx) 替换即可

在这里插入图片描述


SecurityManager 相关思考

在此之前我应该没了解过 SecurityManager ,这次应该是首次,以下主要是我的一些答疑

如何规避 setAccessible 风险?

Hint:伪代码其实就已经做了 try、catch 操作
在这里插入图片描述

SecurityManager 如何给 setAccessible 授权?

在这里插入图片描述

我理解的:根据结果来看就是不建议使用 setAccessible,如果要使用就用 SecurityManager 授权,但即使这样也不保证就能解决安全风险?

SecurityManager 如何使用?

在这里插入图片描述

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