Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them, it only takes a minute:

I have used the following code to sort files in alphabetical order and it sorts the files as shown in the figure. `

for(int i = 0;i < maxcnt;i++) 
    for(int j = i+1;j < maxcnt;j++)
        if(strcmp(Array[i],Array[j]) > 0)

enter image description here . But I need to sort it as order seen in Windows explorer enter image description here. How to sort like this way? Please help

share|improve this question
When you compare, first extract the numbers from both strings, then compare the numbers. –  Wimmel Dec 13 '12 at 9:41
@Wimmel: This relies an all filenames having the same prefix, which I assume is not necessarily the case. It also relies on all filenames containing exactly one (not zero, not two) numeric component. –  NPE Dec 13 '12 at 9:42
Unrelated: why copy the strings for swapping? Just swap the pointers (and there is std::swap...). –  R. Martinho Fernandes Dec 13 '12 at 9:45
possible duplicate of How to get the sort order in Delphi as in Windows Explorer? - The answer to that question is not delphi specific. –  Wimmel Dec 13 '12 at 9:48
Not to bang too hard on my own drum, but this rather obscure old file manager contains the code to do this, and is written in plain C. It's GPL. –  unwind Dec 13 '12 at 10:14

5 Answers 5

up vote 4 down vote accepted

For a C answer, the following is a replacement for strcasecmp(). This function recurses to handle strings that contain alternating numeric and non-numeric substrings. You can use it with qsort():

int strcasecmp_withNumbers(const void *void_a, const void *void_b) {
   const char *a = void_a;
   const char *b = void_b;

   if (!a || !b) { // if one doesn't exist, other wins by default
      return a ? 1 : b ? -1 : 0;
   if (isdigit(*a) && isdigit(*b)) { // if both start with numbers
      char *remainderA;
      char *remainderB;
      long valA = strtol(a, &remainderA, 10);
      long valB = strtol(b, &remainderB, 10);
      if (valA != valB)
         return valA - valB;
      // if you wish 7 == 007, comment out the next two lines
      else if (remainderB - b != remainderA - a) // equal with diff lengths
         return (remainderB - b) - (remainderA - a); // set 007 before 7
      else // if numerical parts equal, recurse
         return strcasecmp_withNumbers(remainderA, remainderB);
   if (isdigit(*a) || isdigit(*b)) { // if just one is a number
      return isdigit(*a) ? -1 : 1; // numbers always come first
   while (*a && *b) { // non-numeric characters
      if (isdigit(*a) || isdigit(*b))
         return strcasecmp_withNumbers(a, b); // recurse
      if (tolower(*a) != tolower(*b))
         return tolower(*a) - tolower(*b);
   return *a ? 1 : *b ? -1 : 0;


  • Windows needs stricmp() rather than the Unix equivalent strcasecmp().
  • The above code will (obviously) give incorrect results if the numbers are really big.
  • Leading zeros are ignored here. In my area, this is a feature, not a bug: we usually want UAL0123 to match UAL123. But this may or may not be what you require.
  • See also Sort on a string that may contain a number and How to implement a natural sort algorithm in c++?, although the answers there, or in their links, are certainly long and rambling compared with the above code, by about a factor of at least four.
share|improve this answer
Thank u thank u very much Joseph!! –  indira Dec 13 '12 at 12:27

What you want to do is perform "Natural Sort". Here is a blog post about it, explaining implementation in python I believe. Here is a perl module that accomplishes it. There also seems to be a similar question at How to implement a natural sort algorithm in c++?

share|improve this answer

Natural sorting is the way that you must take here . I have a working code for my scenario. You probably can make use of it by altering it according to your needs :

    #include <string>
    int natural_compare(const char *a, const char *b);
    int natural_compare(const std::string& a, const std::string& b);
    #include <cctype>
    namespace {
      // Note: This is a convenience for the natural_compare 
      // function, it is *not* designed for general use
      class int_span {
        int _ws;
        int _zeros;
        const char *_value;
        const char *_end;
        int_span(const char *src)
          const char *start = src;
          // Save and skip leading whitespace
          while (std::isspace(*(unsigned char*)src)) ++src;
          _ws = src - start;
          // Save and skip leading zeros
          start = src;
          while (*src == '0') ++src;
          _zeros = src - start;
          // Save the edges of the value
          _value = src;
          while (std::isdigit(*(unsigned char*)src)) ++src;
          _end = src;
        bool is_int() const { return _value != _end; }
        const char *value() const { return _value; }
        int whitespace() const { return _ws; }
        int zeros() const { return _zeros; }
        int digits() const { return _end - _value; }
        int non_value() const { return whitespace() + zeros(); }
      inline int safe_compare(int a, int b)
        return a < b ? -1 : a > b;
    int natural_compare(const char *a, const char *b)
      int cmp = 0;
      while (cmp == 0 && *a != '\0' && *b != '\0') {
        int_span lhs(a), rhs(b);
        if (lhs.is_int() && rhs.is_int()) {
          if (lhs.digits() != rhs.digits()) {
            // For differing widths (excluding leading characters),
            // the value with fewer digits takes priority
            cmp = safe_compare(lhs.digits(), rhs.digits());
          else {
            int digits = lhs.digits();
            a = lhs.value();
            b = rhs.value();
            // For matching widths (excluding leading characters),
            // search from MSD to LSD for the larger value
            while (--digits >= 0 && cmp == 0)
              cmp = safe_compare(*a++, *b++);
          if (cmp == 0) {
            // If the values are equal, we need a tie   
            // breaker using leading whitespace and zeros
            if (lhs.non_value() != rhs.non_value()) {
              // For differing widths of combined whitespace and 
              // leading zeros, the smaller width takes priority
              cmp = safe_compare(lhs.non_value(), rhs.non_value());
            else {
              // For matching widths of combined whitespace 
              // and leading zeros, more whitespace takes priority
              cmp = safe_compare(rhs.whitespace(), lhs.whitespace());
        else {
          // No special logic unless both spans are integers
          cmp = safe_compare(*a++, *b++);
      // All else being equal so far, the shorter string takes priority
      return cmp == 0 ? safe_compare(*a, *b) : cmp;
    #include <string>
    int natural_compare(const std::string& a, const std::string& b)
      return natural_compare(a.c_str(), b.c_str());
share|improve this answer

Taking into account that this has a c++ tag, you could elaborate on @Joseph Quinsey's answer and create a natural_less function to be passed to the standard library.

using namespace std;

bool natural_less(const string& lhs, const string& rhs)
    return strcasecmp_withNumbers(lhs.c_str(), rhs.c_str()) < 0;

void example(vector<string>& data)
    std::sort(data.begin(), data.end(), natural_less);

I took the time to write some working code as an exercise

share|improve this answer

Your problem is that you have an interpretation behind parts of the file name.

In lexicographical order, Slide1 is before Slide10 which is before Slide5.

You expect Slide5 before Slide10 as you have an interpretation of the substrings 5 and 10 (as integers).

You will run into more problems, if you had the name of the month in the filename, and would expect them to be ordered by date (i.e. January comes before August). You will need to adjust your sorting to this interpretation (and the "natural" order will depend on your interpretation, there is no generic solution).

Another approach is to format the filenames in a way that your sorting and the lexicographical order agree. In your case, you would use leading zeroes and a fixed length for the number. So Slide1 becomes Slide01, and then you will see that sorting them lexicographically will yield the result you would like to have.

However, often you cannot influence the output of an application, and thus cannot enforce your format directly.

What I do in those cases: write a little script/function that renames the file to a proper format, and then use standard sorting algorithms to sort them. The advantage of this is that you do not need to adapt your sorting, and can use existing software for the sorting. On the downside, there are situations where this is not feasible (as filenames need to be fixed).

share|improve this answer
In my case, file names are fixed. –  indira Dec 13 '12 at 10:11

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.