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What is a very efficient way of determining how many digits there are in an integer in C++?

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8  
In what base? 2? 10? –  Jacob Krall Sep 28 '09 at 23:20
    
I would like to do it in base 10 –  Seth Sep 28 '09 at 23:25
    
I once asked a related question: How can you get the first digit in an int? Many of the same methodologies as below were used in people's answers. Here's the link in case it's relevant to your task [stackoverflow.com/questions/701322/] –  Dinah Sep 28 '09 at 23:52
    
Does inline assembly qualify? –  György Andrasek Sep 29 '09 at 0:18
    
How would inline assembly help? –  Vitali Sep 29 '09 at 2:36

20 Answers 20

up vote 50 down vote accepted

Well, the most efficient way, presuming you know the size of the integer, would be a lookup. Should be faster than the much shorter logarithm based approach. If you don't care about counting the '-', remove the + 1.

// generic solution
template <class T>
int numDigits(T number)
{
    int digits = 0;
    if (number < 0) digits = 1; // remove this line if '-' counts as a digit
    while (number) {
        number /= 10;
        digits++;
    }
    return digits;
}

// partial specialization optimization for 32-bit numbers
template<>
int numDigits(int32_t x)
{
    if (x == MIN_INT) return 10 + 1;
    if (x < 0) return numDigits(-x) + 1;

    if (x >= 10000) {
        if (x >= 10000000) {
            if (x >= 100000000) {
                if (x >= 1000000000)
                    return 10;
                return 9;
            }
            return 8;
        }
        if (x >= 100000) {
            if (x >= 1000000)
                return 7;
            return 6;
        }
        return 5;
    }
    if (x >= 100) {
        if (x >= 1000)
            return 4;
        return 3;
    }
    if (x >= 10)
        return 2;
    return 1;
}

// partial-specialization optimization for 8-bit numbers
template <>
int numDigits(char n)
{
    // if you have the time, replace this with a static initialization to avoid
    // the initial overhead & unnecessary branch
    static char x[256] = {0};
    if (x[0] == 0) {
        for (char c = 1; c != 0; c++)
            x[c] = numDigits((int32_t)c);
        x[0] = 1;
    }
    return x[n];
}
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3  
Probably faster than my answer, well done. For added efficiency, if you know that your input numbers will be mostly small ones (I'm guessing less than 100,000), then reverse the tests: if (x < 10) return 1; if (x < 100) return 2; etc., so that the function will do less tests and exit faster. –  squelart Sep 28 '09 at 23:44
12  
Or perhaps reorder and nest the if statements, to do a binary search instead of a linear search. –  dave4420 Sep 28 '09 at 23:44
    
Yeah - that's even more clever. –  Vitali Sep 29 '09 at 0:51
3  
assuming a uniform distribution of numbers, the reverse linear search ( starting from max digits to 1 ) may be faster on average than the binary search as there are quite more numbers with N digits than with N-1 digits graphics.stanford.edu/~seander/… –  fa. Sep 29 '09 at 12:27
4  
I wouldn't worry very hard about 256 or 128 bit integers. Unless you need to count the number of electrons in the Universe (10^78 last time I did it), 64 bits will do pretty well. 32 bit machines lasted ~~15 years. I'd guess 64 bit machines will last a lot longer. For larger number, multiprecision arithmetic will be fine, and I doubt if efficiency of computing digit count will matter. –  Ira Baxter Sep 30 '09 at 9:26

The simplest way is to do:

unsigned GetNumberOfDigits (unsigned i)
{
    return i > 0 ? (int) log10 ((double) i) + 1 : 1;
}

log10 is defined in <cmath> or <math.h>. You'd need to profile this to see if it's faster than any of the others posted here. I'm not sure how robust this is with regards to float point precision. Also, the argument is unsigned as negative values and log don't really mix.

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2  
For 32 bit ints and 56 bit floats, this probably works. If the input is a long (64 bits), the 56 bits of double-precision log may cause this to produce the wrong answer in cases of values near large values of 10^n. Expect trouble above 2^50. –  Ira Baxter Sep 29 '09 at 10:07
    
There's also the question of how accurate the log functions are. I haven't checked how accurate they are in modern libraries, and wouldn't be comfortable blindly trusting them to be good to one part in a billion. –  David Thornley Sep 29 '09 at 13:49
1  
There's also the fact that you're returning a value from a function with a void return type. –  Lightness Races in Orbit Mar 1 '11 at 16:28
2  
@Tomalak: wow, nearly a year and half old and you're the first to see that. Fixed. –  Skizz Mar 2 '11 at 0:29
    
@DavidThornley: log or other math functions are perfectly precise unless specified on the compiler command line. some will be converted to x86 intrinsics at compile time. some don't exist and will expand into formulas of existing intrinsics. for example if using -fpfast you could see usage of SSE instrinsics rather than x87, which yields less guarantee on the precision IIRC. but by default no problem. –  v.oddou Nov 18 at 3:07
int digits = 0; while (number != 0) { number /= 10; digits++; }

Note: "0" will have 0 digits! If you need 0 to appear to have 1 digit, use:

int digits = 0; do { number /= 10; digits++; } while (number != 0);

(Thanks Kevin Fegan)

In the end, use a profiler to know which of all the answers here will be faster on your machine...

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2  
This may or may not be faster than the unrolled loop approach I took - you'd need to profile the difference (should be negligible in the long run). –  Vitali Sep 28 '09 at 23:43
    
Agreed, profiling is the only way to really know for sure! I updated my answer with that comment, as Ben S's ceil(log10()) answer has disappeared. –  squelart Sep 28 '09 at 23:49
1  
To return the correct length when (number == 0), just change the while loop to do...while. That way digits will be incremented once when (number == 0). –  Kevin Fegan Jan 11 at 13:16
    
Wow, how could I miss this? Thanks Kevin! –  squelart Jan 28 at 23:18

Perhaps I misunderstood the question but doesn't this do it?

int NumDigits(int x)  
{  
    x = abs(x);  
    return (x < 10 ? 1 :   
    	(x < 100 ? 2 :   
    	(x < 1000 ? 3 :   
    	(x < 10000 ? 4 :   
    	(x < 100000 ? 5 :   
    	(x < 1000000 ? 6 :   
    	(x < 10000000 ? 7 :  
    	(x < 100000000 ? 8 :  
    	(x < 1000000000 ? 9 :  
    	10)))))))));  
}
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And I wouldn't be surprised if this solution will be the fastest. –  VisioN Nov 14 at 15:10

See Bit Twiddling Hacks for a much shorter version of the answer you accepted. It also has the benefit of finding the answer sooner if your input is normally distributed, by checking the big constants first. (v >= 1000000000) catches 76% of the values, so checking that first will on average be faster.

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It's unclear if the bit-twiddling is actually faster. Even in the worst case, my modified approach requires 4 comparisons (might be able to take it down to 3 if I examined the partitioning further, although that looks unlikely). I seriously doubt that that is going to be beat by arithmetic operations + memory loads (although if accessed enough, those disappear into the CPU cache). Remember, in the example they give, they also hide the log base 2 as some abstract IntegerLogBase2 function (which itself is actually not cheap). –  Vitali Sep 29 '09 at 8:14
    
Just as a follow up, yes if the numbers are normally distributed, doing the in-order check is faster. However, it has the degenerate case of being twice as slow in the worst case. The partitioned approach by number of digits instead of input space means that the behaviour does not have a degenerate case and always performs optimally. Furthermore, remember you are making the assumption that the numbers will be uniformly distributed. In fact, they are more likely to follow some distribution related to <a href="en.wikipedia.org/wiki/…; would be my guess. –  Vitali Sep 29 '09 at 8:19
    
The bit twiddling hacks are not faster than the partition method above, but they are potentially interesting if you had a more general case like a float here. –  Corwin Joy Sep 30 '09 at 8:25
1  
The bit twiddling hacks suggests a way to get the int log10, given the int log2. It suggests several way to get int log2, mostly involving few compare/branches. (I think you're underestimating the cost of unpredictable branches, Vitali). If you can use inline x86 asm, the BSR instruction will give you the int log2 of a value (i.e. the bit index of a the most significant set bit). It's a bit slow on K8 (10 cycle latency), but fast on Core 2 (2 or 3 cycle latency). Even on K8, may well be faster than the comparisons. –  Peter Cordes Dec 6 '09 at 0:08
    
On K10, lzcnt counts leading zeros, so it's almost the same as bsr, but an input of 0 is no longer a special case with undefined results. Latencies: BSR: 4, LZCNT: 2. –  Peter Cordes Dec 6 '09 at 0:30

Practical joke: This is the most efficient way (number of digits is calculated at compile-time):

template <unsigned long long N, size_t base=10>
struct numberlength
{
    enum { value = 1 + numberlength<N/base, base>::value };
};

template <size_t base>
struct numberlength<0, base>
{
    enum { value = 0 };
};

May be useful to determine the width required for number field in formatting, input elements etc.

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First, your solution doesn't work for 0. Secondly your solution is inapplicable to the general case of a variable. Thirdly, if you are using a constant literal, you already know how many digits it has. –  Vitali Sep 29 '09 at 8:02
    
It works for 0 too. It also works for any base. The rest are valid points that I already outlined. –  blinnov.com Sep 29 '09 at 13:10
1  
I don't think it does actually. It fails on 0 and also fails on base 1 :) and gives divide by zero errors if the base is given as 0. It can be fixed though. Anyway I'm nitpicking over a very old post, so sorry, it's just that I think this needn't be a joke and could actually be useful. –  tjm Oct 7 '10 at 17:46

A previous poster suggested a loop that divides by 10. Since multiplies on modern machines are a lot faster, I'd recommend the following code instead:

 int digits = 1, pten=10; while ( pten <= number ) { digits++; pten*=10; }
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1  
the devil is in the details - what happens with say std::numeric_limits<int>::max == number - it might have a problem terminating –  pgast Sep 29 '09 at 2:53
2  
If you are worried about that case, you can add one additional IF to handle very large values. –  Ira Baxter Sep 29 '09 at 3:46
2  
I should observe that on x86 machines, a multiply by a constant 10 as used in this case can actually be implemented by the compiler as LEA R2,[8*R1+R1], ADD R1,R2 so it takes 2 clocks max. Multiplys by variables take tens of clocks, and divides are much worse. –  Ira Baxter Sep 29 '09 at 10:19
    
the advantage with the divide approach is that you dont need to worry about negative numbers. –  Johannes Schaub - litb Jan 14 '13 at 9:32
1  
I benchmarked the multipication approach (with a fabs to remove the sign issue) versus the division approach. On my machine the division approach is factor 2 slower than the multiplication approach. Whether this is premature optimization or not really depends on where and how this is called. –  Spacemoose Apr 8 at 7:58

The ppc architecture has a bit counting instruction. With that, you can determine the log base 2 of a positive integer in a single instruction. For example, 32 bit would be:

#define log_2_32_ppc(x) (31-__cntlzw(x))

If you can handle a small margin of error on large values you can convert that to log base 10 with another few instructions:

#define log_10_estimate_32_ppc(x) (9-(((__cntlzw(x)*1233)+1545)>>12))

This is platform specific and slightly inaccurate, but also involves no branches, division or conversion to floating point. All depends on what you need.

I only know the ppc instructions off hand, but other architectures should have similar instructions.

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This solution computes log2(15)= 4 bits and log2(9)=4 bits. But 15 and 9 require different numbers of decimal digits to print. So it doesn't work, unless you don't mind your numbers printing with too many digits sometimes. But in that case, you can always choose "10" as the answer for int. –  Ira Baxter Sep 29 '09 at 11:05
    
Wow, an approximate function. Nice. –  doug65536 Jan 25 '13 at 2:59

I like Ira Baxter's answer. Here is a template variant that handles the various sizes and deals with the maximum integer values (updated to hoist the upper bound check out of the loop):

#include <boost/integer_traits.hpp>

template<typename T> T max_decimal()
{
    T t = 1;

    for (unsigned i = boost::integer_traits<T>::digits10; i; --i)
        t *= 10;

    return t;
}

template<typename T>
unsigned digits(T v)
{
    if (v < 0) v = -v;

    if (max_decimal<T>() <= v)
        return boost::integer_traits<T>::digits10 + 1;

    unsigned digits = 1;
    T boundary = 10;

    while (boundary <= v) {
        boundary *= 10;
        ++digits;
    }

    return digits;
}

To actually get the improved performance from hoisting the additional test out of the loop, you need to specialise max_decimal() to return constants for each type on your platform. A sufficiently magic compiler could optimise the call to max_decimal() to a constant, but specialisation is better with most compilers today. As it stands, this version is probably slower because max_decimal costs more than the tests removed from the loop.

I'll leave all that as an exercise for the reader.

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You want to make the upper limit check a seperate conditional tested first so you don't check it on each loop iteration. –  Ira Baxter Sep 29 '09 at 10:24
    
You don't want to put 10 into that temp t. The compiler might consider multiplying by t to be multiplying by a real variable, and use a general purpose multiply instruction. If you instead wrote "result*=10;" the compiler will surely notice the multiply by constant 10 and implement that with a few shifts and adds, which is extremely fast. –  Ira Baxter Sep 30 '09 at 0:48
    
If the multiplication by t was always a multiplication by 10, then yes, the compiler could do strength reduction. However, t is not loop-invariant in this case (it is just a modification of an integer power function I had lying around). The correct optimisation is specialisation on type returning a constant. However, you are right that, in this case, the function is always raising 10 to a power, not an arbitrary integer to a power, and strength reduction gives a good win. So I made a change ... This time further changes really are left as an exercise! (Stack Overflow is a big time sink ...) –  janm Sep 30 '09 at 7:07

convert to string and then use built-in functions

unsigned int i;
cout<< to_string(i).length()<<endl;
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template <typename type>
class number_of_decimal_digits {   
    const powers_and_max<type> mPowersAndMax;
public:
    number_of_decimal_digits(){
    }   
    inline size_t ndigits( type i) const {
        if(i<0){
             i += (i == std::numeric_limits<type>::min());
             i=-i;
        }
        const type* begin = &*mPowersAndMax.begin();
        const type* end = begin+mPowersAndMax.size();
        return 1 + std::lower_bound(begin,end,i) - begin;
    }
    inline size_t string_ndigits(const type& i) const {
        return (i<0) + ndigits(i);
    }
    inline size_t operator[](const type& i) const {
       return string_ndigits(i);
    }
};

where in powers_and_max we have (10^n)-1 for all n such that

(10^n) < std::numeric_limits<type>::max()

and std::numeric_limits<type>::max() in an array:

template <typename type>
struct powers_and_max : protected std::vector<type>{
    typedef std::vector<type> super;
    using super::const_iterator;
    using super::size;
    type& operator[](size_t i)const{return super::operator[](i)};
    const_iterator begin()const {return super::begin();} 
    const_iterator end()const {return super::end();} 
    powers_and_max() {
       const int size = (int)(log10(double(std::numeric_limits<type>::max())));
       int j = 0;
       type i = 10;
       for( ; j<size ;++j){
           push_back(i-1);//9,99,999,9999 etc;
           i*=10;
       }
       ASSERT(back()<std::numeric_limits<type>::max());
       push_back(std::numeric_limits<type>::max());
   }
};

here's a simple test:

number_of_decimal_digits<int>  ndd;
ASSERT(ndd[0]==1);
ASSERT(ndd[9]==1);
ASSERT(ndd[10]==2);
ASSERT(ndd[-10]==3);
ASSERT(ndd[-1]==2);
ASSERT(ndd[-9]==2);
ASSERT(ndd[1000000000]==10);
ASSERT(ndd[0x7fffffff]==10);
ASSERT(ndd[-1000000000]==11);
ASSERT(ndd[0x80000000]==11);

Of course any other implementation of an ordered set might be used for powers_and_max and if there was knowledge that there would be clustering but no knowledge of where the cluster might be perhaps a self adjusting tree implementation might be best

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effective way

int num;
int count = 0;
while(num)
{
   num /= 10;
   ++count;
}


#include <iostream>

int main()
{
   int num;
   std::cin >> num;

   std::cout << "number of digits for " << num << ": ";

   int count = 0;
   while(num)
   {
      num /= 10;
      ++count;
   }

   std::cout << count << '\n';

   return 0;
}
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Yet another code snippet, doing basically the same as Vitali's but employs binary search. Powers array is lazy initialized once per unsigned type instance. Signed type overload takes care of minus sign.

#include <limits>
#include <type_traits>
#include <array>

template <class T> 
size_t NumberOfDecPositions ( T v, typename std::enable_if<std::is_unsigned<T>::value>::type* = 0 )
{
    typedef std::array<T,std::numeric_limits<T>::digits10+1> array_type;
    static array_type powers_of_10;
    if ( powers_of_10.front() == 0 )
    {
        T n = 1;
        for ( T& i: powers_of_10 )
        {
            i = n;
            n *= 10;
        }
    }

    size_t l = 0, r = powers_of_10.size(), p;
    while ( l+1 < r )
    {
        p = (l+r)/2;
        if ( powers_of_10[p] <= v )
            l = p;
        else
            r = p;
    }
    return l + 1;
};

template <class T> 
size_t NumberOfDecPositions ( T v, typename std::enable_if<std::is_signed<T>::value>::type* = 0 )
{
    typedef typename std::make_unsigned<T>::type unsigned_type;
    if ( v < 0 )
        return NumberOfDecPositions ( static_cast<unsigned_type>(-v) ) + 1;
    else
        return NumberOfDecPositions ( static_cast<unsigned_type>(v) );
}

If anybody cares of further optimization, please note that the first element of powers array is never used, and the l appears with +1 2 times.

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in case the number of digits AND the value of each digit position is needed use this:

int64_t = number, digitValue, digits = 0;    // or "int" for 32bit

while (number != 0) {
    digitValue = number % 10;
    digits ++;
    number /= 10;
}

digit gives you the value at the number postition which is currently processed in the loop. for example for the number 1776 the digit value is:
6 in the 1st loop
7 in the 2nd loop
7 in the 3rd loop
1 in the 4th loop

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C++11 update of preferred solution:

#include <limits>
#include <type_traits>
        template <typename T>
        typename std::enable_if<std::numeric_limits<T>::is_integer, unsigned int>::type
        numberDigits(T value) {
            unsigned int digits = 0;
            if (value < 0) digits = 1;
            while (value) {
                value /= 10;
                ++digits;
            }
            return digits;
        }

prevents template instantiation with double, et. al.

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int numberOfDigits(double number){
    if(number < 0){
        number*=-1;
    }
    int i=0;
        while(number > pow(10, i))
            i++;    
    cout << "This number has " << i << " digits" << endl;
    return i;
}
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// Meta-program to calculate number of digits in (unsigned) 'N'.    
template <unsigned long long N, unsigned base=10>
struct numberlength
{   // http://stackoverflow.com/questions/1489830/
    enum { value = ( 1<=N && N<base ? 1 : 1+numberlength<N/base, base>::value ) };
};

template <unsigned base>
struct numberlength<0, base>
{
    enum { value = 1 };
};

{
    assert( (1 == numberlength<0,10>::value) );
}
assert( (1 == numberlength<1,10>::value) );
assert( (1 == numberlength<5,10>::value) );
assert( (1 == numberlength<9,10>::value) );

assert( (4 == numberlength<1000,10>::value) );
assert( (4 == numberlength<5000,10>::value) );
assert( (4 == numberlength<9999,10>::value) );
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Correction for "Practical joke" from 'blinnov.com' above –  Adolfo Dec 22 at 11:50

You could always just convert the number to a string and then use the size() function to count the characters in your string.

#include <iostream>
#include <sstream>
#include <string>
using namespace std;

int main()
{
    int num = 10101010;
    ostringstream ostr;
    ostr << num;
    string numStr = ostr.str();

    int length = numStr.size();
    cout << length;
}
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Very Pythonic way.:-) –  quapka Nov 12 at 15:16

Use this simple thing?

#include <iostream>
using namespace std;

int main()
{
    int x = 1000;
    int answer;
    if (x < 10) {answer = 1;}
    else
    {
        int temp = 1;
        while (x >= 10)
        {
            x = x / 10;
            temp = temp + 1;
        }
            answer = temp;
    }
    return answer;
}
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Here's a different approach:

digits = sprintf(numArr, "%d", num);    // where numArr is a char array
if (num < 0)
    digits--;

This may not be efficient, just something different than what others suggested.

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3  
The request was for extremely efficient. This is the opposite. –  Ira Baxter Sep 30 '09 at 0:49

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