Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I'd love to be able to do this:

class myInt : public int


Why can't I?

Why would I want to? Stronger typing. For example, I could define two classes intA and intB, which let me do intA + intA or intB + intB, but not intA + intB.

"Ints aren't classes." So what?

"Ints don't have any member data." Yes they do, they have 32 bits, or whatever.

"Ints don't have any member functions." Well, they have a whole bunch of operators like + and -.

share|improve this question
Hey, this is not Ruby :) – Nikolai N Fetissov Jan 26 '10 at 22:10
Because the language was not designed that way. – anon Jan 26 '10 at 22:16
As for "Why would I want to? Stronger typing. For example, I could define two classes intA and intB, which let me do intA+intA or intB+intB, but not intA+intB", that's nonsense. You can implement those types without inheriting from int. Just define a new type from scratch, and define its operator+. I don't see the problem – jalf Jan 26 '10 at 22:45
If your syntax was legal, then intA+intB would compile, which was what you wanted to avoid. – jalf Jan 26 '10 at 22:51
This thread has lowered my IQ by at least 3 points, thanks a lot. – Ed S. Jan 27 '10 at 0:56

19 Answers 19

up vote 59 down vote accepted

Neil's comment is pretty accurate. Bjarne mentioned considering and rejecting this exact possibility1:

The initializer syntax used to be illegal for built-in types. To allow it, I introduced the notion that built-in types have constructors and destructors. For example:

int a(1);    // pre-2.1 error, now initializes a to 1

I considered extending this notion to allow derivation from built-in classes and explicit declaration of built-in operators for built-in types. However, I restrained myself.

Allowing derivation from an int doesn't actually give a C++ programmer anything significantly new compared to having an int member. This is primarily because int doesn't have any virtual functions for the derived class to override. More seriously though, the C conversion rules are so chaotic that pretending that int, short, etc., are well-behaved ordinary classes is not going to work. They are either C compatible, or they obey the relatively well-behaved C++ rules for classes, but not both.

As far as the comment the performance justifies not making int a class, it's (at least mostly) false. In Smalltalk all types are classes -- but nearly all implementations of Smalltalk have optimizations so the implementation can be essentially identical to how you'd make a non-class type work. For example, the smallInteger class is represents a 15-bit integer, and the '+' message is hard-coded into the virtual machine, so even though you can derive from smallInteger, it still gives performance similar to a built-in type (though Smalltalk is enough different from C++ that direct performance comparisons are difficult and unlikely to mean much).

Edit: the one bit that's "wasted" in the Smalltalk implementation of smallInteger probably wouldn't be needed in C or C++. Smalltalk is a bit like Java -- when you "define an object" you're really just defining a pointer to an object, and you have to dynamically allocate an object for it to point at. What you manipulate, pass to a function as a parameter, etc., is always just the pointer, not the object itself.

That's not how smallInteger is implemented though -- in its case, they put the integer value directly into what would normally be the pointer. To distinguish between a smallInteger and a pointer, they force all objects to be allocated at even byte boundaries, so the LSB is always clear. A smallInteger always has the LSB set.

Most of this is necessary, however, because Smalltalk is dynamically typed -- it has to be able to deduce the type by looking at the value itself, and smallInteger is basically using that LSB as a type-tag. Given that C++ is statically typed, there's never a need to deduce the type from the value, so you probably wouldn't need to waste that bit.

1 In The Design and Evolution of C++, §15.11.3.

share|improve this answer
Finally, someone comes up with the exact reason. +1 – sbi Jan 27 '10 at 6:08
I don't know the internal representation of integers in Smalltalk, but a 15-bit integer is not useful in a language trying to work with or extend C. It's too small to be a short, and I doubt it can be used to make compact bitfields. If the cost of being able to derive from raw integer types is one bit of overhead per integer, it's far too high for a language like C++. It's a valid approach in language design in general, but any language that does that will have compatibility issues with C. – David Thornley Jan 27 '10 at 14:43
@David Thornley:while it's true that 15 bits is on the small side, keep in mind that smallInteger was defined sometime before 1980. If I were implementing Smalltalk today, I'd probably make it 63 bits, adequate for all integer types except long long. – Jerry Coffin Jan 27 '10 at 16:25
Thanks, this is a good answer! – Rocketmagnet Jan 27 '10 at 21:55
Do you know if Smalltalk really requires the extra bit? A 63-bit integer is technically legal for int, but it's still going to have compatibility problems with C. – David Thornley Jan 28 '10 at 15:58

Int is an ordinal type, not a class. Why would you want to?

If you need to add functionality to "int", consider building an aggregate class which has an integer field, and methods that expose whatever additional capabilities that you require.


@OP "Ints aren't classes" so?

Inheritance, polymorphism and encapsulation are keystones of object oriented design. None of these things apply to ordinal types. You can't inherit from an int because it's just a bunch of bytes and has no code.

Ints, chars, and other ordinal types do not have method tables, so there's no way to add methods or override them, which is really the heart of inheritance.

share|improve this answer
+1 for proposing an alternate solution. – AJ. Jan 26 '10 at 22:12
All I'd like to know is why. Is there some fundamental reason this could not have been done within the design constraints of C++, or did they forget? – Rocketmagnet Jan 26 '10 at 22:45
Why did someone design the Honda Aztek to look so stupid? It was a design decision. That is the only reason. – snicker Jan 26 '10 at 22:51
@snicker this is quite OT, but the Aztec is by Pontiac, not Honda. – JAL Jan 27 '10 at 0:08
OK, @Soapbox, I'll pose the same question to you as I did to Neil in the comments to Mason's answer. If there's no benefit to inheriting from something without virtual functions, then why was C++ designed to allow that at all? C++ allows allows descending from class types that have no virtual functions, so int's lack of virtual functions cannot be the reason that C++ forbids descending from it. – Rob Kennedy Jan 27 '10 at 0:18

Why would I want to? Stronger typing. For example, I could define two classes intA and intB, which let me do intA+intA or intB+intB, but not intA+intB.

That makes no sense. You can do all that without inheriting from anything. (And on the other hand, I don't see how you could possibly achieve it using inheritance.) For example,

class SpecialInt {
SpecialInt operator+ (const SpecialInt& lhs, const SpecialInt& rhs) {

Fill in the blanks, and you have a type that solves your problem. You can do SpecialInt + SpecialInt or int + int, but SpecialInt + int won't compile, exactly as you wanted.

On the other hand, if we pretended that inheriting from int was legal, and our SpecialInt derived from int, then SpecialInt + int would compile. Inheriting would cause the exact problem you want to avoid. Not inheriting avoids the problem easily.

"Ints don't have any member functions." Well, they have a whole bunch of operators like + and -.

Those aren't member functions though.

share|improve this answer
+1 for addressing the real problem (operator overloading) – LiraNuna Jan 26 '10 at 23:17
"Inheriting would cause the exact problem you want to avoid." Only if you were to publicly inherit (as, admittedly, the initial question implied in the code section). Private inheritance would not cause this issue. – addaon Dec 21 '13 at 23:56
@addaon Yes, and private inheritance is a useful idiom when you need to override base class member functions without exposing the base class functionality. What would private inheritance of a concrete type without any virtual functions achieve? – curiousguy Aug 18 '15 at 14:50
+1 for the fact that + and - and such aren't member functions. It might be worth mentioning that even for full blown classes many overloaded operators need not be member functions. – YoungJohn 2 days ago

If the OP really wants to understand WHY C++ is the way it is, then he should get a hold of a copy of Stroustup's book "The Design and Evolution of C++". It explains the rationale for this and many other design decisions in the early days of C++.

share|improve this answer
I will do this. I have The C++ Programming Language, but not D&E. – Rocketmagnet Jan 27 '10 at 21:57

Because int is a native type and not a class

Edit: moving my comments into my answer.

It comes from the C heritage and what, exactly, primitives represent. A primitive in c++ is just a collection of bytes that have little meaning except to the compiler. A class, on the other hand, has a function table, and once you start going down the inheritance and virtual inheritance path, then you have a vtable. None of that is present in a primitive, and by making it present you would a) break a lot of c code that assumes an int is 8 bytes only and b) make programs take up a lot more memory.

Think about it another way. int/float/char don't have any data members or methods. Think of the primitives as quarks - they're the building blocks that you can't subdivide, you use them to make bigger things (apologies if my analogy is a little off, I don't know enough particle physics)

share|improve this answer
That's not an answer, just a restatement of the fact. – Rocketmagnet Jan 26 '10 at 22:31
OK, why is int not a class ? To me it makes sense to inherit from an int. It would be an object which behaves just like an int. – Rocketmagnet Jan 26 '10 at 22:40
If it would behave just like an int, why would you re-invent int? :] – GManNickG Jan 26 '10 at 22:43
It was a design decision when C++ was created that the builtin types would not be classes. Think about it another way. int/float/char don't have any data members or methods. Think of the primitives as quarks - they're the building blocks that you can't subdivide, you use them to make bigger things (apologies if my analogy is a little off, I don't know enough particle physics) – Mason Jan 26 '10 at 22:43
@GMan: I think you meant to say "Why would you re-invent int?" – snicker Jan 26 '10 at 22:45

strong typing of ints (and floats etc) in c++

Scott Meyer (Effective c++ has a very effective and powerful solution to your problem of doing strong typing of base types in c++, and it works like this:

Strong typing is a problem that can be addressed and evaluated at compile time, which means you can use the ordinals (weak typing) for multiple types at run-time in deployed apps, and use a special compile phase to iron out inappropriate combinations of types at compile time.

typedef time Time
typedef distance Distance
typedef velocity Velocity
typedef time float
typedef distance float
typedef velocity float

You then define your Time, Mass, Distance to be classes with all (and only) the appropriate operators overloaded to the appropriate operations. In pseudo-code:

class Time {
  float value;
  Time operator +(Time b) {self.value + b.value;}
  Time operator -(Time b) {self.value - b.value;}
  // don't define Time*Time, Time/Time etc.
  Time operator *(float b) {self.value * b;}
  Time operator /(float b) {self.value / b;}

class Distance {
  float value;
  Distance operator +(Distance b) {self.value + b.value;}
  // also -, but not * or /
  Velocity operator /(Time b) {Velocity( self.value / b.value )}

class Velocity {
  float value;
  // appropriate operators
  Velocity(float a) : value(a) {}

Once this is done, your compiler will tell you any places you have violated the rules encoded in the above classes.

I'll let you work out the rest of the details yourself, or buy the book.

share|improve this answer
Thanks Alex. This is roughly what I'm after. I just wondered if it would be possible to do this without having to re-specify all the operators every time. – Rocketmagnet Jan 27 '10 at 22:07
You reference Effective C++. What part do you mean? "Item 18: Make interfaces easy to use correctly and hard to use incorrectly", with its Date example? – Frank Kusters Dec 14 '12 at 13:44
Once you've implemented the strong type compile, why even leave weak typing as a compile option? – Wallacoloo Apr 16 '13 at 3:36
Performance, code density, icache usage, debuggability, handling platforms with incomplete/incompatible template implementations. – Alex Brown Apr 16 '13 at 18:50
"Performance, code density," : wouldn't a modern compiler completely inline such classes at high optimisation level ? I tried on and at -O3 it compiles to the exact same ASM instructions: – Jean-Michaël Celerier Jun 27 '15 at 10:47

What others have said is true... int is a primitive in C++ (much like C#). However, you can achieve what you wanted by just building a class around int:

class MyInt
   int mInt;

   explicit MyInt(int in) { mInt = in; }
   // Getters/setters etc

You can then inherit from that all you jolly want.

share|improve this answer
Ok, but you'll want to mark the constructor as explicit to prevent automatic conversion. – Steven Sudit Jan 26 '10 at 22:27
edited... thanks! – Polaris878 Jan 26 '10 at 22:32
But this class behaves nothing like an int. – Rocketmagnet Jan 26 '10 at 22:35
It's an example, to illustrate a point. – GManNickG Jan 26 '10 at 22:43
You have to go to the trouble of adding all the member operators abd typecasting functions to get it to act like an extended int type. But once you do, you can then make it a template type that takes min and max allowable values, and all of the member functions can do range checking. – David R Tribble Jan 27 '10 at 0:23

No one has mentioned that C++ was designed to have (mostly) backwards compatibility with C, so as to ease the upgrade path for C coders hence struct defaulting to all members public etc.

Having int as a base class that you could override would fundamentally complicate that rule no end and make the compiler implementation hellish which if you want existing coders and compiler vendors to support your fledgling language was probably not worth the effort.

share|improve this answer
I don’t see that as valid. The original int wouldn’t behave any different to the int form which you could inherit. And it’s not like C had a method to check whether a type is expected to be a class. – Debilski Jan 27 '10 at 0:46
@Debilski BS. If you're using pointer arithmetic to iterate through a malloc'd block of memory, increment by sizeof(int) should be by 2 or 4 bytes ( depending on the bandwidth of your system as defined in limits.h) not by the instance size of an Int, which will certainly be different. Go write a compiler and let us know how it goes. – David Lively Jan 27 '10 at 3:57
Why would the instance size be different? It doesn’t carry any information apart from the value of an int? I don’t need my own compiler to prove that. – Debilski Jan 27 '10 at 11:58
@David: From the point of view of language design, an Int class that has no ability to have virtual functions is very limited as a base class, and therefore arguably not worth having. From the point of view of implementation, a class with virtual functions needs one vtable pointer per instance. – David Thornley Jan 27 '10 at 14:52
@David: There would be no vtable, because there are no virtual functions. The derived int class would be the same size as the original int. – Rocketmagnet Jan 27 '10 at 21:59

In C++ the built-in types are not classes.

share|improve this answer

Well, you don’t really need to inherit anything which hasn’t got any virtual member functions. So even if int were a class, there would not be a plus over composition.

So to say, virtual inheritance is the only real reason you’d need inheritance for anyway; everything else is just saving you masses of typing time. And I don’t think an int class/type with virtual members would be the smartest thing to imagine in the C++ world. At least not for you every day int.

share|improve this answer

What does it mean to inherit from an int?

"int" has no member functions; it has no member data, it's a 32 (or 64) bit representation in memory. It doesn't have it's own vtable. All what it "has" (it doesn't really even own them) are some operators like +-/* that are really more global functions than member functions.

share|improve this answer
No, int is member data. – GManNickG Jan 26 '10 at 22:44
What difference does that make, @Chuck? An int holds data. A descendant of an int could hold that data just as easily, no? Why does it need to be called member data? – Rob Kennedy Jan 27 '10 at 0:24
Just because the base type doesn't "have members" doesn't mean a descendant couldn't add members. – Rob Kennedy Jan 27 '10 at 1:39
@sbi: And my point is that these questions often have no good answer. A lot of language design decisions are made for no particular reason, and aren't changed later because of compatibility. It happens that Jerry Coffin dug up Stroustrup's reasoning on this case, which is good. Sometimes "because" is the best answer, and it annoys me when people refuse to accept it. – David Thornley Jan 28 '10 at 15:54
@sbi: Sometimes "because" is the only answer. Why does Planck's constant have the value it does? Sometimes the only answer is that it seemed like a good idea at the time. If nobody provided an answer that wasn't certainly good, some questions about language features would go unanswered. Which, I must admit, might be an improvement. – David Thornley Jan 31 '10 at 22:05

As others I saying, can't be done since int is a primitive type.

I understand the motivation, though, if it is for stronger typing. It has even been proposed for C++0x that a special kind of typedef should be enough for that (but this has been rejected?).

Perhaps something could be achieved, if you provided the base wrapper yourself. E.g something like the following, which hopefully uses curiously recurring templates in a legal manner, and requires only deriving a class and providing a suitable constructor:

template <class Child, class T>
class Wrapper
    T n;
    Wrapper(T n = T()): n(n) {}
    T& value() { return n; }
    T value() const { return n; }
    Child operator+= (Wrapper other) { return Child(n += other.n); }
    //... many other operators

template <class Child, class T>
Child operator+(Wrapper<Child, T> lhv, Wrapper<Child, T> rhv)
    return Wrapper<Child, T>(lhv) += rhv;

//Make two different kinds of "int"'s

struct IntA : public Wrapper<IntA, int>
    IntA(int n = 0): Wrapper<IntA, int>(n) {}

struct IntB : public Wrapper<IntB, int>
    IntB(int n = 0): Wrapper<IntB, int>(n) {}

#include <iostream>

int main()
    IntA a1 = 1, a2 = 2, a3;
    IntB b1 = 1, b2 = 2, b3;
    a3 = a1 + a2;
    b3 = b1 + b2;
    //a1 + b1;  //bingo
    //a1 = b1; //bingo
    a1 += a2;

    std::cout << a1.value() << ' ' << b3.value() << '\n';

But if you take the advice that you should just define a new type and overload the operators, you might take a look at Boost.Operators

share|improve this answer
Thanks UncleBens. This is a useful answer. I think that a combination of Alex Brown's answer with Boost::Operators would be good. – Rocketmagnet Jan 27 '10 at 22:15

More general than the fact that "int is primitive" is this: int is a scalar type, while classes are aggregate types. A scalar is an atomic value, while an aggregate is something with members. Inheritance (at least as it exists in C++) only makes sense for an aggregate type, because you can't add members or methods to scalars — by definition, they don't have any members.

share|improve this answer
for some, class is syntax to express a type, and subclassing means restricting the domain. like naturals are a subtype of integers, which are a subtype of reals, etc. – just somebody Jan 27 '10 at 1:04
Guess what? Those "some" are living in la la land. You're talking about how you wish it were, not how it is. I deal in the real world. class is not a generic syntax to express the mathematical concept of type in C++. – Chuck Jan 27 '10 at 6:47
What you say is all well and good, except that the question wasn't "how is it?" but "why is it that way?" Neither your answer nor your (somewhat rude) comment answers the right question. – sbi Jan 28 '10 at 15:39
The question was "Why can't I do this?" The answer is "Because int is a scalar, and the C++ concept of subtyping is not meaningful for scalars." Integers weren't arbitrarily excluded — it's not possible to apply the concept as it exists to them. That is why. – Chuck Jan 28 '10 at 18:59
No that isn't why. That's just stating the facts without explaining why they are the way they are. There is a very good answer to these questions and, not surprisingly, it also is the accepted answer. – sbi Jan 31 '10 at 7:55

You can get what you want with strong typedefs. See BOOST_STRONG_TYPEDEF

share|improve this answer

This answer is an implementation of UncleBens answer

put in Primitive.hpp

#pragma once

template<typename T, typename Child>
class Primitive {
    T value;


    // we must type cast to child to so
    // a += 3 += 5 ... and etc.. work the same way
    // as on primitives
    Child &childRef(){
        return *((Child*)this);

    // you can overload to give a default value if you want
    explicit Primitive(T v):value(v){}

    T get(){
        return value;

    #define OP(op) Child &operator op(Child const &v){\
        value op v.value; \
        return childRef(); \

    // all with equals

    #undef OP

    #define OP(p) Child operator p(Child const &v){\
        Child other = childRef();\
        other p ## = v;\
        return other;\


    #undef OP

    #define OP(p) bool operator p(Child const &v){\
        return value p v.value;\


    #undef OP

    Child operator +(){return Child(value);}
    Child operator -(){return Child(-value);}
    Child &operator ++(){++value; return childRef();}
    Child operator ++(int){
        Child ret(value);
        return childRef();
    Child operator --(int){
        Child ret(value);
        return childRef();

    bool operator!(){return !value;}
    Child operator~(){return Child(~value);}



#include "Primitive.hpp"
#include <iostream>

using namespace std;
class Integer : public Primitive<int, Integer> {
    Integer(int a):Primitive<int, Integer>(a) {}

int main(){
    Integer a(3);
    Integer b(8);

    a += b;
    cout << a.get() << "\n";
    Integer c;

    c = a + b;
    cout << c.get() << "\n";

    cout << (a > b) << "\n";
    cout << (!b) << " " << (!!b) << "\n";

share|improve this answer
I wrote my answer before i saw your (we have difference 1.5 hours between our answers). But i'm not sure that your code looks complicated. Could you comment any issue from more simpler code: – Speakus Oct 2 '14 at 5:48
@Speakus I don't see your post the link you provided doesn't seem to go to a particular post. I've been coding in c++ so much everything here looks very simple to me. I'll be glad to explain my answer further, just let me know what you don't understand. – over_optimistic Oct 2 '14 at 23:00
my answer was deleted: so link i want to show here:… – Speakus Oct 2 '14 at 23:25
In your code you also implement for TT (another type other than T). This removes the strong typeness which is sought after. Also you return a Primitive<T> rather than the derived type.Thus again not being useful to the purpose of strong typeness. Try running UncleBens main() function using your class. That should shed light where you need to improve. – over_optimistic Oct 3 '14 at 0:29
i really miss strong typing request. Now it's supported in my code too:… - tested with UncleBens main() function :) – Speakus Oct 3 '14 at 1:25

Please, excuse me for my poor English.

There is a major difference between C++ correct construction like this:

struct Length { double l; operator =!?:%+-*/...(); };
struct Mass { double l; operator =!?:%+-*/...(); };

and the proposed extension

struct Length : public double ;
struct Mass   : public double ;

And this difference lies on the keyword this behavior. this is a pointer and using a pointer let few chances to use registers for computations, because in usuals processors registers does not have address. Worst, using pointer make the compiler suspicous about the fact that two pointers may designate the same memory.

This will put an extraordinary burden on the compiler to optimize trivials ops.

Another problem is on the number of bugs: reproducing exactly all the behavior of operators is absolutly error prone (for ex making constructor explicit does not forbid all implicits cases). Probability of error while building such an object is quite high. It is not equivalent to have the possibility to do something thru hard work or to have it already done.

Compiler implementors would introduce type checking code (with maybe some errors, but compiler exactness is much better than client code, because of any bug in compiler generate countless errors cases), but main behavior of operation will remain exactly the same, with as few errors than usual.

The proposed alternate solution (using structs during debug phase and real floats when optimized ones) is interesting but has drawbacks: it's raise the probability to have bugs only in optimized version. And debugging optimized application is much costly.

One may implement a good proposal for @Rocketmagnet initial demand for integers types using :

enum class MyIntA : long {}; 
auto operator=!?:%+-*/...(MyIntA);
MyIntA operator "" _A(long);

The bug level will be quite high, like using single member trick, but compiler will treat thoses types exactly like built-in integers (including register capability & optimisation), thanks for inlining.

But this trick can't be used (sadly) for floating numbers, and the nicest need is obviously real valued dimensions checking. One may not mix up apples and pears: adding length and area is a common error.

Stroustrup' invocation by @Jerry is irrelevant. Virtuality is meaningful mainly for public inheritance, and the need is here toward private inheritance. Consideration around 'chaotic' C conversion rules (Does C++14 have anything not chaotic?) of basic type are also not useful : the objective is to have no default conversion rules, not to follow standard ones.

share|improve this answer

If I remember, this was the main - or one of - the main reasons C++ was not considered a true object oriented language. Java people would say: "In Java, EVERYTHING is an object" ;)

share|improve this answer
Except that Java also has an int that can't be subclassed, so those people would be wrong :-) – paxdiablo Jan 26 '10 at 22:29
@Joe: Thankyou, someone who understands the question. – Rocketmagnet Jan 26 '10 at 22:33
Note that people have different definitions of object orientation, so it would be more accurate to say "some people considered C++ not a true O-O language" or specify who. – David Thornley Jan 26 '10 at 23:03
In C++ an int is an object. It isn't a class. And not all classes have virtual functions, not all classes are designed to serve as base classes. – curiousguy Aug 18 '15 at 15:05

This is related to how the items are stored in memory. An int in C++ is an integral type, as mentioned elsewhere, and is just 32 or 64 bits (a word) in memory. An object, however, is stored differently in memory. It is usually stored on the heap, and it has functionality related to polymorphism.

I don't know how to explain it any better. How would you inherit from the number 4?

share|improve this answer
Objects are usually stored on the heap in C++? Isn't that a bit of an overgeneralization? – Chuck Jan 26 '10 at 23:44
Also, number 4 isn't a type. It's a value that a variable of type int might hold. Also objects don't necessarily have to be polymorphic (see your STL). – UncleBens Jan 27 '10 at 0:06
Here are two variables: int x; struct { int i; } y; Erik, please describe how x and y are stored differently in memory. – Rob Kennedy Jan 27 '10 at 0:28
I don't want to inherit from the number 4, I want to inherit from int. – Rocketmagnet Jan 27 '10 at 22:15
@Eric, you seem to have no idea what you're talking about. In my previous comment, y is an instance of the anonymous struct defined right there. If it had a name (say, Y), you could also instantiate it like this: Y* z = new Y; The variables x, y, and now z, are all objects. (Check the standard for its definition of object; if you think it's "instance of a class," you're wrong.) You can store objects on the heap, but saying they're usually there is an overstatement. They're frequently on the stack, too. Integral types are stored the same as other types. – Rob Kennedy Feb 6 '10 at 23:34

Why can't you inherit from int, even though you might want to?


There's no functional reason why you shouldn't be able (in an arbitrary language) inherit from ordinal types such as int, or char, or char* etc. Some languages such as Java and Objective-C actually provide class/object (boxed) versions of the base type, in order to satisfy this need (as well as to deal with some other unpleasant consequences of ordinal types not being objects):

language     ordinal type boxed type, 
c++          int          ?
java         int          Integer
objective-c  int          NSNumber

But even Java and objective-c preserve their ordinal types for use... why?

The simple reasons are performance and memory consumption. An ordinal type can be typically be constructed, operated upon, and passed by value in just one or two X86 instructions, and only consumes a few bytes at worst. A class typically cannot - it often uses 2x or more as much memory, and manipulating its value may take many hundreds of cycles.

This means programmers who understand this will typically use the ordinal types to implement performance or memory usage sensitive code, and will demand that language developers support the base types.

It should be noted that quite a few languages do not have ordinal types, in particular the dynamic languages such as perl, which relies almost entirely on a variadic type, which is something else altogether, and shares some of the overhead of classes.

share|improve this answer
You can easily construct wrapper classes in C++ that adds semantics to primitive types but compiles down to the exact same assembly as using the primitive directly, (or calling a non-member function that operates on the primitive). A language need not go the Java way and provide you an Integer class that behaves differently than the primitive equivialent. – nos Jan 27 '10 at 0:08
yes, you are right, you can. But they aren't provided out of the box, hence the ? in the table. – Alex Brown Jan 27 '10 at 0:20
also, if there were provided out of the box, they would have virtual functions and be based upon a base class and have members in addition to their main value. count on it. For example, the Java Int type has a lock in it, as well as the int (and who knows what else?) – Alex Brown Jan 27 '10 at 0:21
Alex, I disagree. int has no virtual functions, therefore there will be no vtable. If I add no other members, then MyInt is exactly the same size as int, and should compile to identical code. The only difference will be compile time checking of my types. – Rocketmagnet Jan 27 '10 at 22:22

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.