21

I would like to populate an array of enum using constexpr. The content of the array follows a certain pattern.

I have an enum separating ASCII character set into four categories.

enum Type {
    Alphabet,
    Number,
    Symbol,
    Other,
};

constexpr Type table[128] = /* blah blah */;

I would like to have an array of 128 Type. They can be in a structure. The index of the array will be corresponding to the ASCII characters and the value will be the Type of each character.

So I can query this array to find out which category an ASCII character belongs to. Something like

char c = RandomFunction();
if (table[c] == Alphabet) 
    DoSomething();

I would like to know if this is possible without some lengthy macro hacks.

Currently, I initialize the table by doing the following.

constexpr bool IsAlphabet (char c) {
    return ((c >= 0x41 && c <= 0x5A) ||
            (c >= 0x61 && c <= 0x7A));
}

constexpr bool IsNumber (char c) { /* blah blah */ }

constexpr bool IsSymbol (char c) { /* blah blah */ }

constexpr Type whichCategory (char c) { /* blah blah */ }

constexpr Type table[128] = { INITIALIZE };

where INITIALIZE is the entry point of some very lengthy macro hacks. Something like

#define INITIALIZE INIT(0)
#define INIT(N) INIT_##N
#define INIT_0 whichCategory(0), INIT_1
#define INIT_1 whichCategory(1), INIT_2
//...
#define INIT_127 whichCategory(127)

I would like a way to populate this array or a structure containing the array without the need for this macro hack...

Maybe something like

struct Table {
    Type _[128];
};

constexpr Table table = MagicFunction();

So, the question is how to write this MagicFunction?

Note: I am aware of cctype and likes, this question is more of a Is this possible? rather than Is this the best way to do it?.

Any help would be appreciated.

Thanks,

  • 2
    You do know that ASCII only ranges [0 .. 127]? And that char's signedness is implementation defined? Your current approach is very dangerous. Oh, and last but not least, the C++ standard doesn't demand ASCII encoding at all. It might aswell be EBCDIC. – Xeo Nov 9 '12 at 19:36
  • The good news is that because arrays can be initialized with pack expansions, what you ask for is indeed feasible. You just need to invoke the function plenty of times :p – Matthieu M. Nov 9 '12 at 19:39
  • 1
    @DyP: ((c >= 0x41 && c <= 0x5A) || (c >= 0x61 && c <= 0x7A)) from IsAlphabet -- this assumes the decimal ordering that is present in ASCII. The signedness is important since OP passes literals > 127, which may map to negative chars. – Xeo Nov 9 '12 at 20:40
  • 1
    @BeyondSora: I'm sorry, I did not have the time to properly address this question yesterday. Thankfully Xeo did (despite his grumpiness :p). The indices generation combined with pack expansion is a great trick to generate all kind of initialization lists (as you can see here), and thus I was pointing out at the fact that since arrays accept initialization lists, you were golden. – Matthieu M. Nov 10 '12 at 11:33
  • 1
    @DyP: With EBCDIC, 0x41 isn't mapped to any symbol at all, and letters have a strange place in the codepage. Just see here. – Xeo Nov 12 '12 at 20:01
29

Ignoring ALL the issues, indices to the rescue:

template<unsigned... Is> struct seq{};
template<unsigned N, unsigned... Is>
struct gen_seq : gen_seq<N-1, N-1, Is...>{};
template<unsigned... Is>
struct gen_seq<0, Is...> : seq<Is...>{};

template<unsigned... Is>
constexpr Table MagicFunction(seq<Is...>){
  return {{ whichCategory(Is)... }};
}

constexpr Table MagicFunction(){
  return MagicFunction(gen_seq<128>{});
}

Live example.

  • 2
    @Steven: Added a link to the Lounge<C++> wiki entry. It basically builds a list [0 .. 127] and expands that, calling whichCategory(0), whichCategory(1), ..., whichCategory(127) and passes that as initializer arguments for list-initialization to Table._ (notice the double {} for initializing the inner array). – Xeo Nov 9 '12 at 21:02
  • 1
    I didn't know you can return something of this form { /*...*/ }, is this something new in C++11 or always there in the standard? – Jimmy Lu Nov 9 '12 at 21:09
  • 2
    @BeyondSora: New to C++11, called list-initialization (also less formal and more commonly known as uniform initialization). – Xeo Nov 9 '12 at 21:18
  • 2
    Why do you use double curly brackets? – Yola Oct 10 '16 at 18:44
  • 2
    This answer is obsolete in C++14 because C++14 allows you to build the whole array inside a constexpr function. – Omnifarious Jun 29 '17 at 22:05
12

In C++17 ::std::array has been updated to be more constexpr friendly and you can do the same as in C++14, but without some of the scary looking hacks to get around the lack of constexpr in crucial places. Here is what the code would look like there:

#include <array>

enum Type {
    Alphabet,
    Number,
    Symbol,
    Other,
};

constexpr ::std::array<Type, 128> MagicFunction()
{
   using result_t = ::std::array<Type, 128>;
   result_t result = {Other};
   result[65] = Alphabet;
   //....
   return result;
}

const ::std::array<Type, 128> table = MagicFunction();

Again MagicFunction still needs to obey the rather loose constexpr rules. Mainly, it may not modify any global variables or use new (which implies modifying global state, namely the heap) or other such things.

5

IMHO the best way to do this is simply write a tiny setup program that will generate table for you. And then you can either throw out the setup program, or check it in alongside the generated source code.

The tricky part of this question is just a duplicate of this other one: Is it possible to create and initialize an array of values using template metaprogramming?

The trick is, it's impossible to write anything like

Type table[256] = some_expression();

at file scope, because global arrays can be initialized only with literal (source-level) initializer-lists. You can't initialize a global array with the result of a constexpr function, even if you could somehow get that function to return a std::initializer_list, which you can't because its constructor isn't declared constexpr.

So what you have to do is get the compiler to generate the array for you, by making it a static const data member of a template class. After one or two levels of metaprogramming that I'm too confused to write out, you'll bottom out in a line that looks something like

template <int... Indices>
Type DummyStruct<Indices...>::table[] = { whichCategory(Indices)... };

where Indices is a parameter-pack that looks like 0,1,2,... 254,255. You construct that parameter-pack using a recursive helper template, or maybe just using something out of Boost. And then you can write

constexpr Type (&table)[] = IndexHelperTemplate<256>::table;

...But why would you do all that, when the table is only 256 entries that will never change unless ASCII itself changes? The right way is the simplest way: precompute all 256 entries and write out the table explicitly, with no templates, constexpr, or any other magic.

  • IMHO hardcode it is bad because its important to understand the logic on that values if that was complex (in a more generic case). If there is n pregenerated factorial values who ensure my that there is no copypaste mistake nor error on some value? – Isaac Pascual Mar 27 '19 at 17:49
  • If there are n lines of complicated metaprogramming to compute the values, who ensures that there is no copy-paste mistake or bug in that code? Our goal is always to reduce the possibility of error. For something like a three-line factorial function, maybe you'd minimize the possibility of error by writing code instead of data. For OP's actual problem — a 128-byte classification table — I still feel strongly that writing data instead of code is the best way to minimize the possibility of error. (But note that constexpr programming has gotten MUCH more powerful and natural since 2012.) – Quuxplusone Mar 27 '19 at 18:42
  • I prefer to see what is behind the data than hardcoded numbers. – Isaac Pascual Apr 1 '19 at 8:56
4

The way to do this in C++14 looks like this:

#include <array>

enum Type {
    Alphabet,
    Number,
    Symbol,
    Other,
};

constexpr ::std::array<Type, 128> MagicFunction()
{
   using result_t = ::std::array<Type, 128>;
   result_t result = {Other};
   const result_t &fake_const_result = result;
   const_cast<result_t::reference>(fake_const_result[65]) = Alphabet;
   //....
   return result;
}

const ::std::array<Type, 128> table = MagicFunction();

No clever template hackery required any longer. Though, because C++14 didn't really undergo a thorough enough review of what did and didn't have to be constexpr in the standard library, a horrible hack involving const_cast has to be used.

And, of course, MagicFunction had better not modify any global variables or otherwise violate the constexpr rules. But those rules are pretty liberal nowadays. You can, for example, modify all the local variables you want, though passing them by reference or taking their addresses may not work out so well.

See my other answer for C++17, which allows you to drop some of the ugly-looking hacks.

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