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What is the fastest way to strip all non-printable characters from a String in Java?

So far I've tried and measured on 138-byte, 131-character String:

  • String's replaceAll() - slowest method
    • 517009 results / sec
  • Precompile a Pattern, then use Matcher's replaceAll()
    • 637836 results / sec
  • Use StringBuffer, get codepoints using codepointAt() one-by-one and append to StringBuffer
    • 711946 results / sec
  • Use StringBuffer, get chars using charAt() one-by-one and append to StringBuffer
    • 1052964 results / sec
  • Preallocate a char[] buffer, get chars using charAt() one-by-one and fill this buffer, then convert back to String
    • 2022653 results / sec
  • Preallocate 2 char[] buffers - old and new, get all chars for existing String at once using getChars(), iterate over old buffer one-by-one and fill new buffer, then convert new buffer to String - my own fastest version
    • 2502502 results / sec
  • Same stuff with 2 buffers - only using byte[], getBytes() and specifying encoding as "utf-8"
    • 857485 results / sec
  • Same stuff with 2 byte[] buffers, but specifying encoding as a constant Charset.forName("utf-8")
    • 791076 results / sec
  • Same stuff with 2 byte[] buffers, but specifying encoding as 1-byte local encoding (barely a sane thing to do)
    • 370164 results / sec

My best try was the following:

    char[] oldChars = new char[s.length()];
    s.getChars(0, s.length(), oldChars, 0);
    char[] newChars = new char[s.length()];
    int newLen = 0;
    for (int j = 0; j < s.length(); j++) {
        char ch = oldChars[j];
        if (ch >= ' ') {
            newChars[newLen] = ch;
    s = new String(newChars, 0, newLen);

Any thoughts on how to make it even faster?

Bonus points for answering a very strange question: why using "utf-8" charset name directly yields better performance than using pre-allocated static const Charset.forName("utf-8")?


  • Suggestion from ratchet freak yields impressive 3105590 results / sec performance, a +24% improvement!
  • Suggestion from Ed Staub yields yet another improvement - 3471017 results / sec, a +12% over previous best.

Update 2

I've tried my best to collected all the proposed solutions and its cross-mutations and published it as a small benchmarking framework at github. Currently it sports 17 algorithms. One of them is "special" - Voo1 algorithm (provided by SO user Voo) employs intricate reflection tricks thus achieving stellar speeds, but it messes up JVM strings' state, thus it's benchmarked separately.

You're welcome to check it out and run it to determine results on your box. Here's a summary of results I've got on mine. It's specs:

  • Debian sid
  • Linux 2.6.39-2-amd64 (x86_64)
  • Java installed from a package sun-java6-jdk-6.24-1, JVM identifies itself as
    • Java(TM) SE Runtime Environment (build 1.6.0_24-b07)
    • Java HotSpot(TM) 64-Bit Server VM (build 19.1-b02, mixed mode)

Different algorithms show ultimately different results given a different set of input data. I've ran a benchmark in 3 modes:

Same single string

This mode works on a same single string provided by StringSource class as a constant. The showdown is:

 Ops / s  │ Algorithm
6 535 947 │ Voo1
5 350 454 │ RatchetFreak2EdStaub1GreyCat1
5 249 343 │ EdStaub1
5 002 501 │ EdStaub1GreyCat1
4 859 086 │ ArrayOfCharFromStringCharAt
4 295 532 │ RatchetFreak1
4 045 307 │ ArrayOfCharFromArrayOfChar
2 790 178 │ RatchetFreak2EdStaub1GreyCat2
2 583 311 │ RatchetFreak2
1 274 859 │ StringBuilderChar
1 138 174 │ StringBuilderCodePoint
  994 727 │ ArrayOfByteUTF8String
  918 611 │ ArrayOfByteUTF8Const
  756 086 │ MatcherReplace
  598 945 │ StringReplaceAll
  460 045 │ ArrayOfByteWindows1251

In charted form: Same single string chart

Multiple strings, 100% of strings contain control characters

Source string provider pre-generated lots of random strings using (0..127) character set - thus almost all strings contained at least one control character. Algorithms received strings from this pre-generated array in round-robin fashion.

 Ops / s  │ Algorithm
2 123 142 │ Voo1
1 782 214 │ EdStaub1
1 776 199 │ EdStaub1GreyCat1
1 694 628 │ ArrayOfCharFromStringCharAt
1 481 481 │ ArrayOfCharFromArrayOfChar
1 460 067 │ RatchetFreak2EdStaub1GreyCat1
1 438 435 │ RatchetFreak2EdStaub1GreyCat2
1 366 494 │ RatchetFreak2
1 349 710 │ RatchetFreak1
  893 176 │ ArrayOfByteUTF8String
  817 127 │ ArrayOfByteUTF8Const
  778 089 │ StringBuilderChar
  734 754 │ StringBuilderCodePoint
  377 829 │ ArrayOfByteWindows1251
  224 140 │ MatcherReplace
  211 104 │ StringReplaceAll

In charted form: Multiple strings, 100% concentration

Multiple strings, 1% of strings contain control characters

Same as previous, but only 1% of strings was generated with control characters - other 99% was generated in using [32..127] character set, so they couldn't contain control characters at all. This synthetic load comes the closest to real world application of this algorithm at my place.

 Ops / s  │ Algorithm
3 711 952 │ Voo1
2 851 440 │ EdStaub1GreyCat1
2 455 796 │ EdStaub1
2 426 007 │ ArrayOfCharFromStringCharAt
2 347 969 │ RatchetFreak2EdStaub1GreyCat2
2 242 152 │ RatchetFreak1
2 171 553 │ ArrayOfCharFromArrayOfChar
1 922 707 │ RatchetFreak2EdStaub1GreyCat1
1 857 010 │ RatchetFreak2
1 023 751 │ ArrayOfByteUTF8String
  939 055 │ StringBuilderChar
  907 194 │ ArrayOfByteUTF8Const
  841 963 │ StringBuilderCodePoint
  606 465 │ MatcherReplace
  501 555 │ StringReplaceAll
  381 185 │ ArrayOfByteWindows1251

In charted form: Multiple strings, 1% concentration

It's very hard for me to decide on who provided the best answer, but given the real-world application best solution was given/inspired by Ed Staub, I guess it would be fair to mark his answer. Thanks for all who took part in this, your input was very helpful and invaluable. Feel free to run the test suite on your box and propose even better solutions (working JNI solution, anyone?).


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"This question shows research effort" - hmm... yeah, pass. +1 –  Gustav Carlson Aug 23 '11 at 13:15
StringBuilder will be marginally faster than StringBuffer as it is un-synchronized, I just mention this because you tagged this micro-optimization –  Jarrod Roberson Aug 23 '11 at 13:16
@Jarrod Roberson: ok, so let's make all read-only fields final and extract s.length() out of the for loop as well :-) –  home Aug 23 '11 at 13:24
Some characters below space are printable e.g. \t and \n. Many characters above 127 are non-printable in your character set. –  Peter Lawrey Aug 23 '11 at 13:25
did you init the string buffer with a capacity of s.length()? –  ratchet freak Aug 23 '11 at 13:28
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7 Answers

up vote 5 down vote accepted

If it is reasonable to embed this method in a class which is not shared across threads, then you can reuse the buffer:

char [] oldChars = new char[5];

String stripControlChars(String s)
    final int inputLen = s.length();
    if ( oldChars.length < inputLen )
        oldChars = new char[inputLen];
    s.getChars(0, inputLen, oldChars, 0);


This is a big win - 20% or so, as I understand the current best case.

If this is to be used on potentially large strings and the memory "leak" is a concern, a weak reference can be used.

share|improve this answer
Great idea! So far it brought the counts up to 3471017 strings per second - i.e. a +12% improvement over previous best version. –  GreyCat Aug 24 '11 at 4:29
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using 1 char array could work a bit better

int length = s.length();
char[] oldChars = new char[length];
s.getChars(0, length, oldChars, 0);
int newLen = 0;
for (int j = 0; j < length; j++) {
    char ch = oldChars[j];
    if (ch >= ' ') {
        oldChars[newLen] = ch;
s = new String(oldChars, 0, newLen);

and I avoided repeated calls to s.length();

another micro-optimization that might work is

int length = s.length();
char[] oldChars = new char[length+1];
s.getChars(0, length, oldChars, 0);
oldChars[length]='\0';//avoiding explicit bound check in while
int newLen=-1;
while(oldChars[++newLen]>=' ');//find first non-printable,
                       // if there are none it ends on the null char I appended
for (int  j = newLen; j < length; j++) {
    char ch = oldChars[j];
    if (ch >= ' ') {
        oldChars[newLen] = ch;//the while avoids repeated overwriting here when newLen==j
s = new String(oldChars, 0, newLen);
share|improve this answer
Thanks! Your version yields 3105590 strings / sec - a massive improvement! –  GreyCat Aug 23 '11 at 13:29
newLen++;: what about using preincrement ++newLen;? - (++j in the loop as well). Have a look here: stackoverflow.com/questions/1546981/… –  Thomas Aug 23 '11 at 13:33
Adding final to this algorithm and using oldChars[newLen++] (++newLen is an error - the whole string would be off by 1!) yields no measureable performance gains (i.e. I get ±2..3% differences, which are comparable to differences of different runs) –  GreyCat Aug 23 '11 at 13:43
@grey I made another version with some other optimizations –  ratchet freak Aug 23 '11 at 13:43
Hmm! That's a brilliant idea! 99.9% of strings in my production environment won't really require stripping - I can improve it further to eliminate even first char[] allocation and return the String as is, if no stripping happened. –  GreyCat Aug 23 '11 at 14:04
show 8 more comments

Well I've beaten the current best method (freak's solution with the preallocated array) by about 30% according to my measures. How? By selling my soul.

As I'm sure everyone that has followed the discussion so far knows this violates pretty much any basic programming principle, but oh well. Anyways the following only works if the used character array of the string isn't shared between other strings - if it does whoever has to debug this will have every right deciding to kill you (without calls to substring() and using this on literal strings this should work as I don't see why the JVM would intern unique strings read from an outside source). Though don't forget to make sure the benchmark code doesn't do it - that's extremely likely and would help the reflection solution obviously.

Anyways here we go:

    // Has to be done only once - so cache those! Prohibitively expensive otherwise
    private Field value;
    private Field offset;
    private Field count;
    private Field hash;
        try {
            value = String.class.getDeclaredField("value");
            offset = String.class.getDeclaredField("offset");
            count = String.class.getDeclaredField("count");
            hash = String.class.getDeclaredField("hash");
        catch (NoSuchFieldException e) {
            throw new RuntimeException();


    public String strip(final String old) {
        final int length = old.length();
        char[] chars = null;
        int off = 0;
        try {
            chars = (char[]) value.get(old);
            off = offset.getInt(old);
        catch(IllegalArgumentException e) {
            throw new RuntimeException(e);
        catch(IllegalAccessException e) {
            throw new RuntimeException(e);
        int newLen = off;
        for(int j = off; j < off + length; j++) {
            final char ch = chars[j];
            if (ch >= ' ') {
                chars[newLen] = ch;
        if (newLen - off != length) {
            // We changed the internal state of the string, so at least
            // be friendly enough to correct it.
            try {
                count.setInt(old, newLen - off);
                // Have to recompute hash later on
                hash.setInt(old, 0);
            catch(IllegalArgumentException e) {
            catch(IllegalAccessException e) {
        // Well we have to return something
        return old;

For my teststring that gets 3477148.18ops/s vs. 2616120.89ops/s for the old variant. I'm quite sure the only way to beat that could be to write it in C (probably not though) or some completely different approach nobody has thought about so far. Though I'm absolutely not sure if the timing is stable across different platforms - produces reliable results on my box (Java7, Win7 x64) at least.

share|improve this answer
Thanks for the solution, please check out question update - I've published my testing framework and added 3 test run results for 17 algorithms. Your algorithm is always on the top, but it changes internal state of Java String, thus breaking the "immutable String" contract => it would pretty hard to use it in real world application. Test-wise, yeah, it's the best result, but I guess I'll announce it as a separate nomination :) –  GreyCat Aug 28 '11 at 22:54
@GreyCat Yeah it has certainly some big strings attached and honestly I pretty much only wrote it up because I'm pretty sure there's no noticeable way to improve your current best solution further. There are situations where I'm certain that it'll work fine (no substring or intern calls before stripping it ), but that's because of knowledge about one current Hotspot version (ie afaik it won't intern strings read from IO - wouldn't be especially useful). It may be useful if one really needs those extra x%, but otherwise more a baseline to see how much you can still improve ;) –  Voo Aug 29 '11 at 0:47
Though I'm attempted to try a JNI version if I find time - never used it so far so that'd be interesting. But I'm pretty sure it'll be slower because of the additional calling overhead (strings are way too small) and the fact that the JIT shouldn't have such a hard time optimizing the functions. Just don't use new String() in case your string wasn't changed, but I think you got that already. –  Voo Aug 29 '11 at 0:51
I've already tried to do exactly the same thing in pure C - and, well, it doesn't really show much improvement over your reflection-based version. C version runs something like +5..10% faster, not really that great - I thought it would be at least like 1.5x-1.7x... –  GreyCat Aug 29 '11 at 1:47
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You could split the task into a several parallel subtasks, depending of processor's quantity.

share|improve this answer
Yeah, I thought of it too, but it won't yield any performance gains in my situation - this stripping algorithm would be called in already massively parallel system. –  GreyCat Aug 23 '11 at 13:38
And, besides, I might guess that forking off a few threads for processing per every 50-100 byte string would be a huge overkill. –  GreyCat Aug 23 '11 at 13:39
Yes, forking threads for every small string is not good idea. But load balancer could improve performance. BTW, did you test performance with StringBuilder instead of StringBuffer which has performance lacks because it synchronized. –  umbr Aug 23 '11 at 13:56
My production setup runs spawns several separate processes and utilizes as much parallel CPUs and cores as possible, so I can freely use StringBuilder everywhere without any issues at all. –  GreyCat Aug 23 '11 at 14:17
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IANA low-level java performance junkie, but have you tried unrolling your main loop? It appears that it could allow some CPU's to perform checks in parallel.

Also, this has some fun ideas for optimizations.

share|improve this answer
I doubt that any unrolling could be done here, as there are (a) dependencies on following steps of algorithm on previous steps, (b) I haven't even heard of anybody doing manual loop unrolling in Java producing any stellar results; JIT usually does a good job at unrolling whatever it sees fitting the task. Thanks for the suggestion and a link, though :) –  GreyCat Aug 24 '11 at 4:44
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I was so free and wrote a small benchmark for different algorithms. It's not perfect, but I take the minimum of 1000 runs of a given algorithm 10000 times over a random string (with about 32/200% non printables by default). That should take care of stuff like GC, initialization and so on - there's not so much overhead that any algorithm shouldn't have at least one run without much hindrance.

Not especially well documented, but oh well. Here we go - I included both of ratchet freak's algorithms and the basic version. At the moment I randomly initialize a 200 chars long string with uniformly distributed chars in the range [0, 200).

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+1 for the effort - but you should've asked me - I already have a similar benchmarking suite - that's where I was testing my algorithms ;) –  GreyCat Aug 24 '11 at 4:38
@GreyCat Well I could've, but just throwing that together (out of existing code anyways) was probably faster ;) –  Voo Aug 24 '11 at 13:13
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why using "utf-8" charset name directly yields better performance than using pre-allocated static const Charset.forName("utf-8")?

If you mean String#getBytes("utf-8") etc.: This shouldn't be faster - except for some better caching - since Charset.forName("utf-8") is used internally, if the charset is not cached.

One thing might be that you're using different charsets (or maybe some of your code does transparently) but the charset cached in StringCoding doesn't change.

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