记录一次压测中遇到的线程阻塞问题
java可以使用反射来执行方法调用,反射根据一个类名得到Class对象,再由对象名和给定的参数集拿到Method对象,就可以通过Method.invoke来执行
@CallerSensitive
public Object invoke(Object var1, Object... var2) throws IllegalAccessException, IllegalArgumentException, InvocationTargetException {
if(!this.override && !Reflection.quickCheckMemberAccess(this.clazz, this.modifiers)) {
Class var3 = Reflection.getCallerClass();
this.checkAccess(var3, this.clazz, var1, this.modifiers);
}
MethodAccessor var4 = this.methodAccessor;
if(var4 == null) {
var4 = this.acquireMethodAccessor();
}
return var4.invoke(var1, var2);
}由上面的代码可以看出来invoke是由MethodAccessor来执行的,MethodAccessor又是acquireMethodAccessor方法获取到的
private MethodAccessor acquireMethodAccessor() {
MethodAccessor var1 = null;
if(this.root != null) {
var1 = this.root.getMethodAccessor();
}
if(var1 != null) {
this.methodAccessor = var1;
} else {
var1 = reflectionFactory.newMethodAccessor(this);
this.setMethodAccessor(var1);
}
return var1;
}MethodAccessor是通过ReflectionFactory的newMethodAccessor获取的,代码如下:
public MethodAccessor newMethodAccessor(Method var1) {
checkInitted();
if(noInflation && !ReflectUtil.isVMAnonymousClass(var1.getDeclaringClass())) {
return (new MethodAccessorGenerator()).generateMethod(var1.getDeclaringClass(), var1.getName(), var1.getParameterTypes(), var1.getReturnType(), var1.getExceptionTypes(), var1.getModifiers());
} else {
NativeMethodAccessorImpl var2 = new NativeMethodAccessorImpl(var1);
DelegatingMethodAccessorImpl var3 = new DelegatingMethodAccessorImpl(var2);
var2.setParent(var3);
return var3;
}
}如果noInflation为true(不膨胀,当Java虚拟机从JNI存取器改为字节码存取器的行为被称为膨胀(Inflation)),创建MethodAccessorGenerator,否则NativeMethodAccessor。NativeMethodAccessorImpl中的invoke代码如下
public Object invoke(Object var1, Object[] var2) throws IllegalArgumentException, InvocationTargetException {
if(++this.numInvocations > ReflectionFactory.inflationThreshold() && !ReflectUtil.isVMAnonymousClass(this.method.getDeclaringClass())) {
MethodAccessorImpl var3 = (MethodAccessorImpl)(new MethodAccessorGenerator()).generateMethod(this.method.getDeclaringClass(), this.method.getName(), this.method.getParameterTypes(), this.method.getReturnType(), this.method.getExceptionTypes(), this.method.getModifiers());
this.parent.setDelegate(var3);//当这一步执行完之后,DelegatingMethodAccessorImpl中的delegate就是MethodAccessorImpl而不是NativeMethodAccessorImpl了
}
return invoke0(this.method, var1, var2);
}ReflectionFactory.inflationThreshold() 就是jvm的启动参数的-Dsun.reflect.inflationThreshold,默认值是15.
调用次数没有超过这个阈值的时候其实使用的还是NativeMethodAccessor.invoke),即没有if里面那些处理。超出阈值后执行if中的逻辑,native的就被搞成了MethodAccessorImpl。同时setDelegate
这个setDelegate 要回看上面DelegatingMethodAccessorImpl,有点像一个中间层,在native和java版之间转换
class DelegatingMethodAccessorImpl extends MethodAccessorImpl {
private MethodAccessorImpl delegate;
DelegatingMethodAccessorImpl(MethodAccessorImpl var1) {
this.setDelegate(var1);
}
public Object invoke(Object var1, Object[] var2) throws IllegalArgumentException, InvocationTargetException {
return this.delegate.invoke(var1, var2);
}
void setDelegate(MethodAccessorImpl var1) {
this.delegate = var1;
}
}据说java版的启动慢,但是执行快(编译器可以优化);native版的启动快,但是执行慢。所以hotspot的jdk做了个优化,调用次数少时用native版的,当发现调用次数多时,则调用MethodAccessorGenerator.generateMethod()来生成Java版的MethodAccessor的实现类,并且改变DelegatingMethodAccessorImpl所引用的MethodAccessor为Java版
sun.reflect.GeneratedMethodAccessor
默认这个优化是开启的且阈值是15,在前面少数调用时,调用的其实是native版的invoke0,超出阈值后,就开始使用MethodAccessorGenerator.generateMethod,这里面最终会调到一个genarateName方法
private static synchronized String generateName(boolean var0, boolean var1) {
int var2;
if(var0) {
if(var1) {
var2 = ++serializationConstructorSymnum;
return "sun/reflect/GeneratedSerializationConstructorAccessor" + var2;
} else {
var2 = ++constructorSymnum;
return "sun/reflect/GeneratedConstructorAccessor" + var2;
}
} else {
var2 = ++methodSymnum;
return "sun/reflect/GeneratedMethodAccessor" + var2;
}
}