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I have:


I can call kLetters[n] to obtain the nth letter of the Keyboard alphabet in O(1) time. However I will have to iterate through kLetter (taking O(n) or at least O(log n) ) time for the reverse lookup.

I would like to create a reverse lookup table as a compile-time static lookup table using templates and was wondering if there is a ways of doing this.

EDIT - as mentioned in the comments, a reverse lookup would mean I supply 'E' and get back 2. Also my alphabet example was not the best example, I would like to make no assumptions about the order. For that reason I have change the alphabet to keyboard order.

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kLetters[n] obtains (n+1)th letter. – Nawaz Sep 14 '11 at 15:44
What is reverse lookup by the way? – Nawaz Sep 14 '11 at 15:46
@Nawaz: Presumably, a function that given e.g.'E' returns 4. – Oliver Charlesworth Sep 14 '11 at 15:47
What about 'A' + n and letter - 'A' for those lookups if you really want to look up English alphabet. – UncleBens Sep 14 '11 at 15:48
@Kerrek: No! It isn't the case for EBCDIC. There are two gaps in the alphabet in EBCDIC. EBCDIC is the classical example of why 'A' + n is not portable. – R. Martinho Fernandes Sep 14 '11 at 16:02

6 Answers 6

How about something like this? It lets you specify the range rather than a complete string.

#include <iostream>

template <int Start, int End, int N>
struct lookup {
        static_assert(Start != End, "Can't have 0 length lookup table");
        enum { value =  lookup<Start+(Start < End ? 1:-1),End,N-1>::value };

template <int Start, int End>
struct lookup<Start,End,0> {
        enum { value = Start };

template <int Start, int End, int V, int P=0>
struct reverse_lookup {
        static_assert(Start != End, "V isn't in the range Start, End");
        static_assert(Start != End || !P, "Can't have 0 length range");
        enum { value = reverse_lookup<Start+(Start < End ? 1:-1),End,V,P+1>::value };

template <int Start, int End, int P>
struct reverse_lookup<Start,End,Start,P> {
        enum { value = P };

int main() {
   std::cout << char(lookup<'A', 'Z', 3>::value) << std::endl;
   std::cout << char(lookup<'Z', 'A', 3>::value) << std::endl;
   std::cout << int(reverse_lookup<'A','Z','F'>::value) << std::endl;
share|improve this answer
Nice - I was going to accept the challenge and try something but looks like you beat me to it. – tenfour Sep 14 '11 at 16:00
Also, this solution means user has to know the letter at compile-time for which index has to be obtained! – Nawaz Sep 14 '11 at 16:10
fast, but doesn't work for EBCDIC, and only works on compile-time constants. – Mooing Duck Sep 14 '11 at 16:10
I don't see the point here. Either the letters are sorted like in the question, then you can simply add ('A'-1) for the lookup and subtract the same for the reverse lookup, otherwise, your approach doesn't work (because you use +1 to iterate to the next value). Also you really have a problem if you want to lookup a variable (as opposed to your constant 3). – bitmask Sep 14 '11 at 16:16
@Nawaz: If letters are in arbitrary order your solution won't work either :) – David Rodríguez - dribeas Sep 14 '11 at 16:22

Alright, after knowing what reverse lookup is, I think you can do this:


int get_index(char letter)
     return letter - 'A';

After all, the letter A is at index 0, B at 1, C at 2... and so on. That gives enough hint.

My O(1) solution


So far other solutions work for non-arbitrary sequence of letters, and @awoodland solution assumes that the letter whose index is to be obtainted is known at compile time which makes it less useful.

But this solution has attempted to solve both limitations; that is, it should work:

  • With arbitrary sequence of letters, such as

       const char Letters[] = "ZBADCEWFVGHIUXJTKSLYQMROPN";
  • And the letters may be unknown at compile time. The function that gets the index has this signature:

    int Index(char letter);

Here is the complete code which uses a technique described by @ David Rodríguez in his blog:

#include <iostream>


template<char L> int Index();

template<> int Index<'Z'>() { return 0; }
template<> int Index<'B'>() { return 1; }
template<> int Index<'A'>() { return 2; }
template<> int Index<'D'>() { return 3; }
template<> int Index<'C'>() { return 4; }
template<> int Index<'E'>() { return 5; }
template<> int Index<'W'>() { return 6; }
template<> int Index<'F'>() { return 7; }
template<> int Index<'V'>() { return 8; }
template<> int Index<'G'>() { return 9; }
template<> int Index<'H'>() { return 10; }
template<> int Index<'I'>() { return 11; }
template<> int Index<'U'>() { return 12; }
template<> int Index<'X'>() { return 13; }
template<> int Index<'J'>() { return 14; }
template<> int Index<'T'>() { return 15; }
template<> int Index<'K'>() { return 16; }
template<> int Index<'S'>() { return 17; }
template<> int Index<'L'>() { return 18; }
template<> int Index<'Y'>() { return 19; }
template<> int Index<'Q'>() { return 20; }
template<> int Index<'M'>() { return 21; }
template<> int Index<'R'>() { return 22; }
template<> int Index<'O'>() { return 23; }
template<> int Index<'P'>() { return 24; }
template<> int Index<'N'>() { return 25; }

typedef int (*fptr)();
const int limit = 26;
fptr indexLookup[ limit ];

template <char L>
struct init_indexLookup {
    static void init( fptr *indexLookup ) {
        indexLookup[ L - 'A' ] = &Index<L>;
        init_indexLookup<L-1>::init( indexLookup );

template <>
struct init_indexLookup<'A'> {
    static void init( fptr *indexLookup ) {
        indexLookup[ 0 ] = &Index<'A'>;

const int ignore = (init_indexLookup<'Z'>::init(indexLookup),0);

int Index(char letter)
    return indexLookup[letter-'A']();

And here is the test code:

int main()
    std::cout << Index('A') << std::endl;
    std::cout << Index('Z') << std::endl;
    std::cout << Index('B') << std::endl;
    std::cout << Index('K') << std::endl;



Online demo :

Well, that actually is two function calls: one to Index(), other to from one in the indexLookup. You can easily avoid first function call by writing (ideone):

int main()
    std::cout << indexLookup['A'-'A']() << std::endl;
    std::cout << indexLookup['Z'-'A']() << std::endl;
    std::cout << indexLookup['B'-'A']() << std::endl;
    std::cout << indexLookup['K'-'A']() << std::endl;

That looks cumbersome, but hey, we can make Index() inline:

inline int Index(char letter)
    return indexLookup[letter-'A']();

That looks fine, and most likely now compiler will make it equivalent to one function call!

Simple yet O(1) solution

Wait. I just realized that the whole solution reduces to a lookup table which is initialized as:

 const int indexLookup[] = {2,1,4,3,5,7,9,10,11,14,16,18,21,

 inline int Index(char letter)
       return indexLookup[letter-'A'];

which looks unbelievably simple!

share|improve this answer
... so long as it remains that string in that encoding – AJG85 Sep 14 '11 at 15:56
...but then I wonder what the point of the array is in the first place... – John Dibling Sep 14 '11 at 16:05
@John: I was also wondering about that. – Nawaz Sep 14 '11 at 16:06
@Mooing Duck: the code does not suppose characters are numbered contiguously, therefore should work with EBCDIC as well. – eudoxos Sep 14 '11 at 16:52
@Mooing: Now my template solution doesn't have that restriction, if at all it is. – Nawaz Sep 14 '11 at 16:54

If you can use Boost and only need compile-time lookups:

using namespace boost::mpl;
typedef vector_c<char, 'A', 'B', 'C', 'D'> Chars;   

// lookup by index:
std::cout << at_c<Chars, 1>::type::value << std::endl; // B 

// lookup by value:
typedef find<Chars, integral_c<char, 'C'> >::type Iter;
std::cout << Iter::pos::value << std::endl; // 2
share|improve this answer

This assumes that 'Z' > 'A', but does not assume letters are contiguous. (Though it takes less memory if they are) I was tempted to put in if (numrLetters>26) conditionals so a smart compiler could use addition rather than the tables for ASCII, but then decided I didn't want to slow the code in the case of less-smart compilers.

const int numLetters = sizeof(kLetters);
const char rkLetters['Z'-'A'] = {};
const int numrLetters = sizeof(rkLetters);
struct LetterInit {
    LetterInit() {
        for(int i=0; i<numLetters; ++i)
            rkLetters[kLetters[i]-'A'] = i;

char findChar(int index) {
    assert(index>=0 && index<numLetters);
    return kLetters[index];
int findIndex(char letter) { 
    assert(letter>='A' && letter<='Z');
    return rkLetters[letter-'A'];
share|improve this answer
If Z and A are far apart, the table can be large, but I know of no system where this is the case. – Mooing Duck Sep 14 '11 at 18:22
This does runtime initialization, what I am really after is Compile time initialization where the reverse array is loaded as const static data. – doron Sep 16 '11 at 12:25

As there are several solutions given that don't generate a table but still allow compile time lookup, here is another one

constexpr char kLetters[] = "ABCDEFGHIJKLMNOPQRSTUVWXYZ";
constexpr int get(char const x, int const i = 0) {
  return kLetters[i] == x ? i : get(x, i + 1);

Use at compile time

int x[get('F')];
static_assert(sizeof(x) == sizeof(int[5]), "");

Specifying a character that doesn't exist will result in an error. If you use the function at runtime, you will get undefined behavior if you specify a character that doesn't exist. Proper checking can be added for those cases.

It yields the index of the first character found. No error is given if a character appears twice in the haystack.

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If you can use c++0x (tested with gcc 4.5), this works:

constexpr int getLetterNumber(char a){ return std::map<char,int>({{'a',2},{'b',1},{'c',4}})[a]; }
int main(){
    const char ch='b';
    std::cout<<ch<<": "<<getLetterNumber(ch)<<std::endl;

constexpr enforces evaluation at compile-time.

EDIT: that solution is not correct, as pointed out. constexpr does not enfoce compile-time evaluation. This does does the lookup really at compile-time (similar to solutions posted meanwhile).

template<char C> int ch2Num();
#define CHR(c,i) template<> int ch2Num<c>(){ return i; }
CHR('a',2); CHR('b',1); /* ... */
#undef CHR
int main(void){
    const char ch='b';
    std::cout<<ch<<": "<<ch2Num<ch>()<<std::endl;
share|improve this answer
No, constexpr does not enforce evaluation at compile-time. It allows it. That nitpick aside, this code should not even compile. std::map does not have any constexpr constructor. – R. Martinho Fernandes Sep 14 '11 at 16:41
Just checked the disassembly, you're right. The function is called (or inlined with -O3, even if ch and the number are made constexpr as well :-(. – eudoxos Sep 14 '11 at 16:43

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