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Recently, someone asked about an algorithm for reversing a string in place in C. Most of the proposed solutions had troubles when dealing with non single-byte strings. So, I was wondering what could be a good algorithm for dealing specifically with utf-8 strings.

I came up with some code, which I'm posting as an answer, but I'd be glad to see other people's ideas or suggestions. I preferred to use actual code, so I've chosen C#, as it seems to be one of the most popular language in this site, but I don't mind if your code is in another language, as long as it could be reasonably understood by anyone who is familiar with an imperative language. And, as this is intended to see how such an algorithm could be implemented at a low-level (by low-level I just mean dealing with bytes), the idea is to avoid using libraries for the core code.


I'm interested in the algorithm itself, its performance and how could it be optimized (I mean algorithm-level optimization, not replacing i++ with ++i and such; I'm not really interested in actual benchmarks either).

I don't mean to actually use it in production code or "reinventing the wheel". This is just out of curiosity and as an exercise.

I'm using C# byte arrays so I'm assuming you can get the length of the string without running though the string until you find a NUL. That is, I'm not accounting for the complexity of finding the length of the string. But if you're using C, for instance, you could factor that out by using strlen() before calling the core code.


As Mike F points out, my code (and other people's code posted here) is not dealing with composite characters. Some info about those here. I'm not familiar with the concept, but if that means that there are "combining characters", i.e., characters / code points that are only valid in combination with other "base" characters / code points, a look-up table of such characters could be used to preserve the order of the "global" character ("base" + "combining" characters) when reversing.

share|improve this question
This is a fun question, but in order to usefully reverse a Unicode string (UTF8 or otherwise) you have to worry about preserving the order of composite characters as well as juggling bytes. –  Mike F Oct 14 '08 at 0:17
Thanks for the heads up. I was not aware of composite characters. I'll look that up first. –  Juan Pablo Califano Oct 14 '08 at 0:30

5 Answers 5

up vote 9 down vote accepted

I'd make one pass reversing the bytes, then a second pass that reverses the bytes in any multibyte characters (which are easily detected in UTF8) back to their correct order.

You can definitely handle this in line in a single pass, but I wouldn't bother unless the routine became a bottleneck.

share|improve this answer
Yes, that's what I thought. Thanks. –  Juan Pablo Califano Oct 13 '08 at 22:36

Agree that your approach is the only sane way to do it in-place.

Personally I don't like revalidating UTF8 inside every function that deals with it, and generally only do what's needed to avoid crashes; it adds up to a lot less code. Dunno much C# so here it is in C:

(edited to eliminate strlen)

void reverse( char *start, char *end )
    while( start < end )
        char c = *start;
        *start++ = *end;
        *end-- = c;

char *reverse_char( char *start )
    char *end = start;
    while( (end[1] & 0xC0) == 0x80 ) end++;
    reverse( start, end );
    return( end+1 );

void reverse_string( char *string )
    char *end = string;
    while( *end ) end = reverse_char( end );
    reverse( string, end-1 );
share|improve this answer
Well, not validating there is OK if you're doing it up-front somewhere else. I just added the validation there, since I didn't assume it would be a valid string and I was checking the leading bytes anyway, so it was adding a few conditions. Not a C & pointers expert, but I get the idea. Thanks. –  Juan Pablo Califano Oct 13 '08 at 23:24
Nicely done, MikeF. BTW: you probably forgot a char *start= string; in the beginning of reverse_string. –  tzot Oct 13 '08 at 23:50
Ουπς...ευχαριστώ. –  Mike F Oct 13 '08 at 23:59
Compatriot or polyglot?-) –  tzot Oct 14 '08 at 0:09
Compatriot, but raised in the UK. BTW, I just noticed that properly reversing a Unicode string actually involves preserving the order of composite characters too :p –  Mike F Oct 14 '08 at 0:15

My initial approach could by summarized this way:

1) Reverse bytes naively

2) Run the string backwards and fix the utf8 sequences as you go.

Illegal sequences are dealt with in the second step and in the first step, we check if the string is in "sync" (that is, if it starts with a legal leading byte).

EDIT: improved validation for leading byte in Reverse()

class UTF8Utils {

    public static void Reverse(byte[] str) {
    	int len = str.Length;
    	int i	= 0;
    	int j	= len - 1;

    	//	first, check if the string is "synced", i.e., it starts
    	//	with a valid leading character. Will check for illegal 
    	//	sequences thru the whole string later.
    	byte leadChar = str[0];

    	//	if it starts with 10xx xxx, it's a trailing char...
    	//	if it starts with 1111 10xx or 1111 110x 
    	//	it's out of the 4 bytes range.
	//	EDIT: added validation for 7 bytes seq and 0xff
    	if( (leadChar & 0xc0) == 0x80 ||
    		(leadChar & 0xfc) == 0xf8 ||
    		(leadChar & 0xfe) == 0xfc ||
		(leadChar & 0xff) == 0xfe ||
		leadChar == 0xff) {

    		throw new Exception("Illegal UTF-8 sequence");


    	//	reverse bytes in-place naïvely
    	while(i < j) {
    		byte tmp = str[i];
    		str[i]	= str[j];
    		str[j]	= tmp;
    	//	now, run the string again to fix the multibyte sequences


    private static void ReverseMbSequences(byte[] str) {
    	int i = str.Length - 1;
    	byte leadChar = 0;
    	int nBytes	= 0;

    	//	loop backwards thru the reversed buffer
    	while(i >= 0) {
    		//	since the first byte in the unreversed buffer is assumed to be
    		//	the leading char of that byte, it seems safe to assume that the  
    		//	last byte is now the leading char. (Given that the string is
    		//	not out of sync -- we checked that out already)
    		leadChar = str[i];

    		//	check how many bytes this sequence takes and validate against
    		//	illegal sequences
    		if(leadChar < 0x80) {
    			nBytes = 1;
    		} else if((leadChar & 0xe0) == 0xc0) {
    			if((str[i-1] & 0xc0) != 0x80) {
    				throw new Exception("Illegal UTF-8 sequence");
    			nBytes = 2;
    		} else if ((leadChar & 0xf0) == 0xe0) {
    			if((str[i-1] & 0xc0) != 0x80 ||
    				(str[i-2] & 0xc0) != 0x80 ) {
    				throw new Exception("Illegal UTF-8 sequence");
    			nBytes = 3;
    		} else if ((leadChar & 0xf8) == 0xf0) {
    			if((str[i-1] & 0xc0) != 0x80 ||
    				(str[i-2] & 0xc0) != 0x80 ||
    				(str[i-3] & 0xc0) != 0x80  ) {
    				throw new Exception("Illegal UTF-8 sequence");
    			nBytes = 4;
    		} else {
    			throw new Exception("Illegal UTF-8 sequence");

    		//	now, reverse the current sequence and then continue
    		//	whith the next one
    		int back	= i;
    		int front	= back - nBytes + 1;

    		while(front < back) {
    			byte tmp = str[front];
    			str[front] = str[back];
    			str[back] = tmp;
    		i -= nBytes;
share|improve this answer

This code assumes that the input UTF-8 string is valid and well formed (i.e. at most 4 bytes per multibyte character):

#include "string.h"

void utf8rev(char *str)
    /* this assumes that str is valid UTF-8 */
    char    *scanl, *scanr, *scanr2, c;

    /* first reverse the string */
    for (scanl= str, scanr= str + strlen(str); scanl < scanr;)
        c= *scanl, *scanl++= *--scanr, *scanr= c;

    /* then scan all bytes and reverse each multibyte character */
    for (scanl= scanr= str; c= *scanr++;) {
        if ( (c & 0x80) == 0) // ASCII char
            scanl= scanr;
        else if ( (c & 0xc0) == 0xc0 ) { // start of multibyte
            scanr2= scanr;
            switch (scanr - scanl) {
                case 4: c= *scanl, *scanl++= *--scanr, *scanr= c; // fallthrough
                case 3: // fallthrough
                case 2: c= *scanl, *scanl++= *--scanr, *scanr= c;
            scanr= scanl= scanr2;

// quick and dirty main for testing purposes
#include "stdio.h"

int main(int argc, char* argv[])
    char buffer[256];
    buffer[sizeof(buffer)-1]= '\0';

    while (--argc > 0) {
        strncpy(buffer, argv[argc], sizeof(buffer)-1); // don't overwrite final null
        printf("%s → ", buffer);
        printf("%s\n", buffer);
    return 0;

If you compile this program (example name: so199260.c) and run it on a UTF-8 environment (a Linux installation in this case):

$ so199260 γεια και χαρά français АДЖИ a♠♡♢♣b
a♠♡♢♣b → b♣♢♡♠a
français → siaçnarf
χαρά → άραχ
και → ιακ
γεια → αιεγ

If the code is too cryptic, I will happily clarify.

share|improve this answer
Neat! But how does the 3-byte character case work? Also, I think it turns out simpler if you reverse the individual characters first. –  Mike F Oct 13 '08 at 23:57
The three byte character works with a single swap (bytes [0] and [2]), [1] does not need swapping. I'm sorry for the cryptic code, for years I code in Python and all C-code I write is for memory-constrained environments with not-so-clever compilers, so I tend to optimize code size a lot. –  tzot Oct 13 '08 at 23:58
Yes, your method is much simpler; in my code, if I reverse the string at the end (skipping the strlen call) then my character reversing process needs refactoring. –  tzot Oct 14 '08 at 0:06
Well, yeah, I scratched my head for a moment trying to figure out the switch argument (scanr - scanl) and what you were doing in each case, but now I get it. Thanks. –  Juan Pablo Califano Oct 14 '08 at 0:15

The best solution:

  1. Convert to a wide char string
  2. Reverse the new string

Never, never, never, never treat single bytes as characters.

share|improve this answer
I agree that it's probably the best solution in "real" code (that or using a decent library). But I'm interested in how would you do it, if you had to do it in place. –  Juan Pablo Califano Oct 13 '08 at 22:40
That doesn't work for many reasons. Even for the sake of this contrived problem, UTF-8 can represent characters that end up being more than two bytes in UTF-16. –  Jim Puls Oct 13 '08 at 22:49
Jim: look up <a href="kerneltrap.org/man/linux/man0p/stddef.h.0p">man stddef.h</a> -- not room for the definition of wchar_t in this comment, but I read it to mean that if the compiling enviroment supports a charset with e.g. 6 byte encoding, wchar_t must be >= 6 bytes. –  gnud Oct 13 '08 at 23:01
gnud, probably Jim is right, but anyway it's not that I need to write code for an actual task, I just would like to see how could one best solve this problems, given those constrains. It's just self-educational. –  Juan Pablo Califano Oct 13 '08 at 23:12
Yes, i understood your angele - eventually =). But equating UTF-16 with wchar_t is josta as wrong as equating a character with 8 bitt. On my system, wchar_t is 32 bits. And as I read the standard, each wchar_t is guaranteed to hold one character. –  gnud Oct 14 '08 at 9:28

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