In C++, I can write 2 template classes, like:

#include <stdio.h>
#include <vector>
template <typename T>
class Printer{
    static void print(T& v){
        printf("%d ",v.getValue());

template <typename T,typename Alloc>
class Printer<std::vector<T,Alloc> >{
    static void print(std::vector<T,Alloc>& v){
        for(T& e : v){

so that it can accept arbitrary custom object type and vector in vector in vector... (infinity nested vector):

class Student{
    int value;
    Student(int value){ this->value=value; }
    int getValue() const { return this->value; }

class Teacher{
    int value;
    Teacher(int value){ this->value=value; }
    int getValue() const { return this->value*10; }

int main(){
    std::vector<Student> v2 = {Student(10),Student(20)};
    Printer<std::vector<Student> >::print(v2);

    std::vector<std::vector<Teacher> > v3 = {{Teacher(30),Teacher(40)},{Teacher(50),Teacher(60),Teacher(70)}};
    Printer<std::vector<std::vector<Teacher> > >::print(v3);
    return 0;

provided the custom object Student and Teacher has getValue() function.

But in Java, how can I write something like above that accepts both

ArrayList<Student > v2;


ArrayList<ArrayList<Teacher> > v3;

(and also ArrayList in ArrayList in ArrayList in...) in generic way?

Few problems occurs when I tried to convert the code, first, the generic object method cannot compile:

public static void <T> print(T t){

and I don't know how to convert std::vector< T , Alloc > in to Java because ArrayList only accepts 1 template parameter.

Note: I want vector to be the specialized template because when I want to add support of int:

std::vector<int> v1={1,2};
Printer<std::vector<int> >::print(v1);

I can just add

template <>
class Printer<int>{
    static void print(int& v){
        printf("%d ",v);

to the code.

  • 1
    I don't see why you need two Printer classes instead of two overloaded functions? Or better yet, overload the operator<< function to handle the actual classes? – Some programmer dude May 24 '17 at 7:36
  • Sure it's possible. It may be ugly and it may be less generic than you think, but it's definitely possible. – Kayaman May 24 '17 at 7:43

You can do it with instanceof checks:

public static <T> void print(List<? extends T> list) {
    for (final T t : list) {
        if (t instanceof List) print((List) t);
        else System.out.println(t);

But of course you can not use a method T.getValue() if it is not defined anywhere in an interface or somewhere. If T is an interface

public interface T {
    String getValue();

then you have something like this

public static void print(List<? extends Object> list) {
    for (Object t : list) {
        if(t instanceof T) System.out.println(((T)t).getValue());
        else if (t instanceof List) print((List) t);
        else continue; // I don't know this type.

But it is then attached to your Interface T. The Problem is really that you can't access methods, which are not defined, at least not without Reflections. How does C++ do this anyway?

EDIT: This will of course not work, if you have an implementation of T which also implements the List interface.

  • The big difference to C++ is that in C++, the compiler creates specific code for template usages. Thats the thing: in java, there is only ONE list class - dealing with objects. In C++, each template usage leads to another binary output - built exactly for that use case. But I like your answer - it gives some specific advise that I left out in my answer. My vote for that! – GhostCat says Reinstate Monica May 24 '17 at 8:04

There is one simple, but very ugly solution: turn to raw types, or as that is super bad practice, go for ? extends Object.

You see, in the end, Java generics are simply not a match to modern day C++ templates. Generics are not templates - example: you can't use them for primitive types, such as int. You can only work with List<Integer> instead. Or some T extends Number when you need a list that takes Double, Float, ... objects as well.

The point is: in the end, at runtime, all of those "generics" are gone. All such lists simply contain Objects.

So, theoretically, if you really want a "solution", then you could go for

void foo(List<? extends Object> thingies) 

avoiding all type information ... and doing reflection magic at runtime to determine how to deal with the exact contents of that list.

A "more Java" solution requires you to step back. As said, Java isn't C++, so you simply should not expect the same level of "expressiveness" from Java.

Instead: learn how to properly make use of Java generics and the Java type system; and build a solution based on that knowledge*.

Or in other words: if you need a C++ solution, use C++. Java will never meet that requirement (at least not to 100%).

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