Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I often find myself using Integers to represent values in different "spaces". For example...

int arrayIndex;
int usersAge;
int daysToChristmas;

Ideally, I'd like to have separate classes for each of these types "Index","Years" and "Days", which should prevent me accidentally mixing them up. Typedefs are a help from a documnentation perspective, but aren't type-safe enough.

I've tried wrapper classes, but end up with too much boilerplate for my liking. Is there a straightforward template-based solution, or maybe something ready-to-go in Boost?

EDIT: Several people have talked about bounds-checking in their answers. That maybe a handy side-effect, but is NOT a key requirement. In particular, I don't just want to prevent out-of-bound assignments, but assignments between "inappropriate" types.

share|improve this question

10 Answers 10

up vote 5 down vote accepted

You could try BOOST_STRONG_TYPEDEF. From boost/strong_typedef.hpp:

// macro used to implement a strong typedef.  strong typedef
// guarentees that two types are distinguised even though the
// share the same underlying implementation.  typedef does not create
// a new type.  BOOST_STRONG_TYPEDEF(T, D) creates a new type named D
// that operates as a type T.
share|improve this answer
That looks very much like the answer I need. Boost::units isn't supported in my version of boost, but this is. –  Roddy Dec 9 '08 at 15:56

Boost does in fact have a library specifically for this type of thing! Check out the Boost.Units library.

share|improve this answer
Having used boost::units in production code, I'd say it has only advantages. You have to make one include file which defines your unit system, and then everything works pretty much like you would like to. –  Alexandre C. Mar 25 '12 at 16:05

One funky "hack" you could use is a template non-type parameter to create wrapper types. This doesn't add any bounds but it does allow to treat them as different types with only one set of boilerplate template code. I.e.

template<unsigned i>
class t_integer_wrapper
    int m_value;
     // Constructors, accessors, operators, etc.

typedef t_integer_wrapper<1> ArrayIndex;
typedef t_integer_wrapper<2> UsersAge;

Extend the template with lower and upper bounds or other validation as you like. Not pretty by a long shot though.

share|improve this answer
Interesting solution. Would make me feel dirty. But using C++ always makes me feel dirty anyway, so +1. –  OregonGhost Dec 9 '08 at 10:48
Doesn't this fit into the "boilerplate code" category Roddy was talking about? –  OJ. Dec 9 '08 at 11:44
You only have to write this boilerplate once, instead of multiple times to get distinct C++ types - variation in the non-type parameter changes the type of the template instantiation. –  Joris Timmermans Dec 9 '08 at 12:24
neat solution. I'd try to throw in LINE__/__FILE somehow to make it simpler to select the unique template version for the typedef. –  Greg Rogers Dec 9 '08 at 14:25

I remember solving a similar problem with a simple template where you would specify the allowed range, i.e.

Int<0, 365> daysToChristmas;
Int<0, 150> usersAge;
Int<0, 6> dayOfWeek;

You get the point. Now you could just derive from such a template type, like

class DayOfYear: public Int<0, 365> {}

and you could no longer pass a user age to a function expecting a DayOfYear, and you wouldn't have to use the angled brackets.

share|improve this answer

This is a generic "StrongType" template that we use to wrap different types and contexts. The only significant difference to this answer is that we prefer to use a tag-type that gives a meaningful name to each specialized wrapper type:

template <typename ValueType, class Tag> class StrongType {
  inline StrongType() : m_value(){}
  inline explicit StrongType(ValueType const &val) : m_value(val) {}
  inline operator ValueType () const {return m_value; }
  inline StrongType & operator=(StrongType const &newVal) {
    m_value = newVal.m_value;
    return *this;
  // data
  ValueType m_value;

And a use of the template as follows:

class ArrayIndexTag;
typedef StringType<int, ArrayIndexTag> StrongArrayIndex;
StringArrayIndex arrayIndex;

Notice too, that all of the functions are 'inline', the intention being that the compiler can do its best to generate exactly the same code it would generated had the template not been used at all!

share|improve this answer
I don't thing you need the inline as these are templates. explicit StrongType(ValueType const &val) and StrongType & operator=(StrongType const &newVal) works better than mine I think. –  David Allan Finch Dec 9 '08 at 11:38
All functions defined in a class definition (including a class template) are implicitly inline. Of course inline is only a hint anyway, so there's no way to externally test whether a compiler always treats them the same whether they're marked inline or not, so there's no harm in spelling it out. –  Steve Jessop Dec 9 '08 at 11:46

In addition to the Boost Units library mentioned by Ryan Fox, there will be also the Boost Constrained Value library, which is currently under review.

Who knows when or if it will hit an official Boost release, but you can probably try it out anyway.

share|improve this answer

Adding in the operator int () will allow you to use the object where a normal int is required. You can also add in a operator = () to set it within range.

class DayType 
    static int const low = 1;
    static int const high = 365;

template<class TYPE>
class Int
    int m_value;
     operator int () { return m_value; }
     operator = ( int i ) { /* check and set*/ }

  Int<DayType> day;
  int d = day;
  day = 23;

I hope this helps.

share|improve this answer
That's a good addition to my proposal, though I thought it would be obvious to add those - it might be wise to make the operator int() explicit anyway. But it's fine this way too. –  OregonGhost Dec 9 '08 at 11:01
True, but it can be handy to use them as real built in types but it might be wise to stop the auto conversion from type to type. Not sure if you can put and explicit on a operator - naff if you can't ;) –  David Allan Finch Dec 9 '08 at 11:06
Not sure. It's just C++ does scary things with auto conversion regarding overloaded functions or pointer/int conversions. For a string type, for example, it seems to be good practice not to have implicit conversion because of these problems. You know, the things you can only do in C++. –  OregonGhost Dec 9 '08 at 11:19
I wouldn't do this without seriously testing it first - implicit conversions are going to bite you in the ass in surprising ways. –  Joris Timmermans Dec 9 '08 at 11:24
int arrayIndex;

This is what std::size_t is for.

int usersAge;

People can't have negative ages and it is not useful/easy to set a fixed upper bound for ages. So here you should just use unsigned int.

int daysToChristmas;

Days to Christmas requires special attention. The number of days until Christamas can range from 0-366. The simple solution is to write the following wherever needed:

assert( 0 < daysToChristmas && daysToChristmas < 366 )

If you feel you're going to duplicate that assert in too many places, then David Allan Finch proposes a neat solution for this case. Though I am partial to using the assert.

share|improve this answer
Ummm, you're missing the point. I can still say "arrayIndex = usersAge;" without any warning from the compiler that I'm fouling up. I'm looking for a strongly typed solution. –  Roddy Dec 9 '08 at 11:29
I just don't think the examples you gave warrant a non-trivial solution. There is only so much you can do to prevent undesired assignment, for example a template solution allows assignment between any two numbers which share the same domain. So daysToChristmas can be assigned to daysToBirtday. –  AlfaZulu Dec 9 '08 at 11:40
ok - maybe I need better examples! –  Roddy Dec 9 '08 at 12:24

For an array index I'd use size_t provided I didn't need negative values, because that's what it's there for. Of course that frequently is unsigned int, so won't give you any type safety at all. However, anything that did give you type safety (i.e. that stopped you assigning an unsigned int to an array index) would also stop you returning a size_t value into your type. That might be too much type safety anyway.

You could probably use an enum for bounded ranges:

enum YearDay {
    FirstJan = 0,
    LastDecInLeapYear = 365

You can assign YearDay to int, but you can't assign an int (or another enum type) to YearDay without an explicit cast. Any value between the least and greatest named value in an enum is a valid value for the enum. Assigning a value outside the range [0,365] results in undefined behaviour. Or possibly an unspecified or implementation-defined result, I can't remember.

Age is tricky, because it's almost bounded, but not quite. You could use 969 (age of Methuselah) in an enum, or a class wrapping an int with explicit conversions as described by others.

share|improve this answer
humm. Wouldn't LastDecInLeapYear be 366? –  EvilTeach Dec 9 '08 at 15:12
Well, I'm counting from 1stJan = 0. 366 days in the year, so last one is 365. It might be more sensible to count from 1stJan = 1, mind you, but I copied the meaning of tm_yday. And YearDay isn't the same thing as daystoXmas anyway, just a similar example, so the base doesn't affect the questioner. –  Steve Jessop Dec 9 '08 at 17:56

Check out this old CUJ article on this subject. IIRC the technique desribes how to make it work with all the fundamental operators

share|improve this answer

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.