I'm afraid I have a question on a detail of a rather oversaturated topic, I searched aroudn a lot, but couldn't find a clear answer to that specific obvious -imho- important, problem:

When converting byte[] to String using UTF-8, each byte (8bit) becomes a 8 bit character encoded by UTF-8, but each UTF-8 character is saved as a 16 bit character in java. Is that correct? If yes, this means, that each stupid java character only uses the first 8 bits, and consumes double the memory? Is that correct too? I wonder how this wasteful behaviour is acceptable..

Isn't there some trick to have a pseudo String that is 8 bit? Would that actually result in less memory consumption? Or maybe, is there a way to store >two< 8bit characters in one java 16bit character to avoid this memory waste?

thanks for any deconfusing answers...

EDIT: hi, thanks everybody for answering. I was aware of the variable-length property of UTF-8. However, since my source is byte which is 8 bit, I understood (apparently wrongly) that it needs only 8-bit UTF-8 words. Is UTF-8 conversion actually saving the strange symbols that you see when on the CLI you do "cat somebinary" ? I thought UTF-8 was just somehow used to map each of the possible 8bit words of byte to one particular 8 bit word of UTF-8. Wrong? I thought about using Base64 but it's bad because it uses only 7 bit..

questions reformulated: is there a smarter way to convert byte to something String? May favorite was to just cast byte[] to char[], but then I still have 16bit words.

additional use case info:

I'm adapting Jedis (java client for the NoSQL Redis) as the "primitive storage layer" for hypergraphDB. So, jedis is a database for another "database". My problem is that I have to feed jedis with byte[] data all the time, but internally, >Redis< (the actual server) is dealing only with "binary safe" Strings. Since Redis is written in C, a char is 8 bit long, AFAIK not ASCIII which is 7 bit. In Jedis however, java world, every character is 16 bit long internally. I don't understand this code (yet), but I suppose jedis then converts this java 16 bit strings to a Redis conforming 8 bit string (([here][3]). It says it extends FilterOutputStream. My hope is to bypass the byte[] <-> string conversion altogether and use that Filteroutputstream...? )

now I wonder: if I had to interconvert byte[] and String all the time, with datasizes ranging from very small to potentially very big, isn't there a huge waste of memory to have each 8 bit character passed around as 16bit within java?

  • 4
    You are aware that some UTF-8 characters are 2, 3, or 4 bytes, right? The whole world doesn't use ASCII. – Ernest Friedman-Hill Apr 12 '11 at 12:09
  • hi, thanks everybody for answering. I was aware of the variable-length property of UTF-8. However, since my source is byte which is 8 bit, I understood that it needs only 8-bit UTF-8 words. Isn't that so? Is UTF-8 conversion actually saving the strange symbols that you see when on the CLI you do "cat somebinary" ? I thought UTF-8 was just somehow used to map each of the possible 8bit words of byte to one 8 bit word of UTF-8. Wrong? I thought about using Base64 but it's bad because it uses only 7 bit.. – ib84 Apr 12 '11 at 13:06
  • UTF-16 is also a variable-width encoding, just like UTF-8. It just uses bigger code units. – tchrist Apr 12 '11 at 13:19
  • What would be bad about casting two bytes to one char ? – ib84 Apr 12 '11 at 13:27
  • 1
    You could Huffman‐encode it so that the most common code points occupy the fewest bits, and vice versa. Every document would thus require a different preambulatory lookup dictionary mapping bits to code points. This would be a false efficiency. – tchrist Apr 12 '11 at 14:27

Isn't there some trick to have a pseudo String that is 8 bit?

yes, make sure you have an up to date version of Java. ;)


-XX:+UseCompressedStrings Use a byte[] for Strings which can be represented as pure ASCII. (Introduced in Java 6 Update 21 Performance Release)

EDIT: This option doesn't work in Java 6 update 22 and is not on by default in Java 6 update 24. Note: it appears this option may slow performance by about 10%.

The following program

public static void main(String... args) throws IOException {
    StringBuilder sb = new StringBuilder();
    for (int i = 0; i < 10000; i++)

    for (int j = 0; j < 10; j++)
        test(sb, j >= 2);

private static void test(StringBuilder sb, boolean print) {
    List<String> strings = new ArrayList<String>();
    long free = Runtime.getRuntime().freeMemory();

    long size = 0;
    for (int i = 0; i < 100; i++) {
        final String s = "" + sb + i;
        size += s.length();
    long used = free - Runtime.getRuntime().freeMemory();
    if (print)
        System.out.println("Bytes per character is " + (double) used / size);

private static void forceGC() {
    try {
    } catch (InterruptedException e) {
        throw new AssertionError(e);

Prints this by default

Bytes per character is 2.0013668655941212
Bytes per character is 2.0013668655941212
Bytes per character is 2.0013606946433575
Bytes per character is 2.0013668655941212

with the option -XX:+UseCompressedStrings

Bytes per character is 1.0014671435440285
Bytes per character is 1.0014671435440285
Bytes per character is 1.0014609725932648
Bytes per character is 1.0014671435440285
  • Peter, that is very interesting, so thank you! I say this because I have long been frustrated by the um, finality, of Java’s String class, combined with how it is tied into String literals in the language. This makes it impossible to use proper OO techniques for any sort of improved or variant strings. You have just shown one such use; several of mine involve posit strings composed either of code point sequences, or also grapheme sequences. I did not know about -XX:+UseCompressedStrings; its existence suggests it might be possible to do other such, although perhaps not portably. – tchrist Apr 12 '11 at 14:51
  • very nice! if I save 50% of memory, having more memory should overcompensate a performance drop of 10%. thanks – ib84 Apr 12 '11 at 14:52
  • This shows another potential use for a user‐defined String datatype in the Java language. One could alter the underlying memory allocation from variable‐width UTF‐16 to variable‐width UTF‐8 or to fixed‐width UTF‐32, according to one’s purpose and code‐point distribution. These could be further compessed as an implementational detail — at a time–space trade‐off. All it’d take is to enhance the Java String definition to admit anything conforming to a “uniform code‐point interface”. String literals could be controlled by a lexically scoped compiler directive (pragma) per source unit. – tchrist Apr 12 '11 at 15:20
  • My long comment shows why ASCII is insufficient for even pure English text: I employed not merely 3 distinct types of quotation marks (\p{Quotation_Mark}), but also 4 distinct types of hyphens and dashes (\p{Dash}). You probably don’t even notice which are which, but that’s ok: they’re still needed to render everyday English correctly. – tchrist Apr 12 '11 at 15:26
  • @tchrist, In England, they use the £ in every day English. ;) – Peter Lawrey Apr 12 '11 at 15:35

Actually, you have the UTF-8 part wrong: UTF-8 is a variable-length multibyte encoding, so there are valid characters 1-4 bytes in length (in other words, some UTF-8 characters are 8-bit, some are 16-bit, some are 24-bit, and some are 32-bit). Although the 1-byte characters take up 8 bits, there are many more multibyte characters. If you only had 1-byte characters, it would only allow you to have 256 different characters in total (a.k.a. "Extended ASCII"); that may be sufficient for 90% of use in English (my naïve guesstimate), but would bite you in the ass as soon as you even think of anything beyond that subset (see the word naïve - English, yet can't be written just with ASCII).

So, although UTF-16 (which Java uses) looks wasteful, it's actually not. Anyway, unless you're on a very limited embedded system (in which case, what you're doing there with Java?), trying to trim down the strings is pointless microoptimization.

For a slightly longer introduction to character encodings, see e.g. this: http://www.joelonsoftware.com/articles/Unicode.html

  • +1: True, but I hadn't the courage to tell him he was wrong. – Martijn Courteaux Apr 12 '11 at 12:13
  • @Martijn Courteaux: [mouth drops, stunned silence] So you've shown him something else, which is wrong but appears to work, and which is very hard to unlearn? I'm shocked, shocked! – Piskvor Apr 12 '11 at 12:20
  • thanks piskvor for answering. I'm reading your link now.. I the 256 possible words of byte just get mapped to 256 "characters" of 8 bit only UTF-8. So now, I'm even more convinced that it's a really a stupid thing, this conversion between byte[] <--> string... there isn't a better way?? – ib84 Apr 12 '11 at 13:16
  • Java does not use UCS-2. It uses UTF-16. This is easily demonstrated: the regex engine treats any Unicode character as ., no matter how many code units it occupies. – tchrist Apr 12 '11 at 13:30
  • 1
    @Piskvor, no problem. Part of my de‑facto job involves educating my Java‐lingo’d co‐workers about differences between UCS‑2 and UTF‑16. Much of the problem stems from old documentation and “simplified versions of reality”. Java v1 debuted in ’95, Unicode v2 in ’96, but it was by then already deemed politically too late to fix the Java char bug. Other factors collude to continue the confusion (eg, interfaces deficient at handling code points), but none is worse than the cognitive dissonance resulting from a Java char or Character being too small to hold a Unicode code point. – tchrist Apr 12 '11 at 15:00

When converting byte[] to String using UTF-8, each byte (8bit) becomes a 8 bit character encoded by UTF-8

No. When converting byte[] to String using UTF-8, each UTF-8 sequence of 1-6 bytes is converted into a UTF-16 sequence of 1-2 16-bit characters.

In almost all cases, worldwide, this UTF-16 sequence contains a single character.

In Western Europe and North America, for most text, only 8 bits of this 16-bit character are used. However, if you have a Euro sign, you'll need more than 8 bits.

For more information, see Unicode. Or Joel Spolsky's article.

  • 1
    +1 Indeed. Just a minor nitpick: the above only holds if by "Western Europe" you mean "UK" and by "North America" you mean "USA". Otherwise, you'll get the French é, the Spanish Ñ, the German ß, which are all multibyte in UTF-8. – Piskvor Apr 12 '11 at 12:53
  • @Piskvor: Curly quotes and proper dashes and hyphens — both necessary for writing English properly — all take multiple code units in UTF-8. As for the UK, Welsh also uses letters outside the ASCII range. Plus anybody who writes resume on their résumé automatically flunks. – tchrist Apr 12 '11 at 13:20
  • @tchrist: Quite so - but 1) note that @Anon writes "for most text", and 2) these have been (unfairly) dismissed for years as "unnecessary nitpicking, why can't you just use - instead of your fancy e[mn] dashes, yada yada", so I wanted to present examples where the necessity is clear. – Piskvor Apr 12 '11 at 13:36
  • @Piskvor - I never said that they weren't. I did say that most western characters would occupy the lower 8 bits of a 16-bit Java character. And although I haven't checked, I believe that all the characters that you mention are ISO-8859-1, so this is true. The punctuation symbols that tchrist mentions, however, do not fit in that space. – Anon Apr 12 '11 at 14:05
  • 1
    ISO 8859‑15, sometimes called Latin‑9, works somewhat better for some Western languages than does the original ISO 8859‑1, Latin‑1, because it includes œ and Œ needed for properly writing such words as French œuf (U+153) and Œuvre de secours aux enfants (U+152) and the ᴀʟʟᴄᴀᴘs version of Pierre Louÿs, since LOUŸS requires Ÿ at U+178. However, it does such things at a cost that is unacceptable to certain other languages. No 8-bit repertoire suffices to write modern text, especially but only English. Unicode solves all those problems; please do not reinstantiate them. – tchrist Apr 12 '11 at 14:43

Java stores all it's "chars" internally as two bytes representations of the value. However, they aren't stored the same as UTF-8. For example, the max value supported is "\uFFFF" (hex FFFF, dec 65536), or 11111111 11111111 binary (two bytes) - but this would be a 3 byte Unicode character on disk.

The only possible wastage is for genuinely 'single' byte characters in memory (most ASCII 'language' characters actually fit in 7bits). When the characters are written to disk, they'll be in the specified encoding anyway (so UTF-8 single byte characters will only occupy one byte).

The only place it makes a difference is in the JVM heap. However, you'd have to have thousands and thousands of 8-bit characters to notice any real difference in Java heap usage - which would be far outweighed by all the extra (hacky) processing you've done.

A million-odd 8-bit characters in RAM is only 'wasting' about 1 MiB anyway...

  • +1, minor nitpick: There's no such thing as "stored Unicode", there are however several Unicode encodings (mapping between the somewhat abstract characters and their byte representations) – Piskvor Apr 12 '11 at 14:46
  • Yes, that should probably read "aren't stored the same as UTF-8". \uFFFF is 11101111 10111111 10111111 on disk (UTF-8). – Michael Apr 12 '11 at 14:53
  • thanks mikaveli. My only worry is JVM heap memory. I'm dealing with lots of byte[] which I have to pack in "Strings" in an memory efficient manner. – ib84 Apr 12 '11 at 14:58
  • That's understandable, but I wouldn't want to give up Java's native Unicode support - there are lots of other workarounds available to control the amount of byte[] / characters in memory (streams, persistence etc etc). – Michael Apr 12 '11 at 15:02
  • I wouldn’t want to “give up” Java’s “native Unicode support”; however, I’d want to make it actually work. It’s a bit begrudged and clunky right now, making it far too easy to do the wrong thing and too hard to do the right one. Unicode isn’t just assigning characters to ordinals; that’s UCS. Unicode is also a rich collection of behaviors, almost none of which Java is up to speed at. It doesn’t do full case mapping at all, and though it provides for UAX#15, it neglects UTS#10, UAX#14, UTS#18, UAX#11, UAX#29, and indeed most of the crucial UAX#44. Java supports Unicode poorly. – tchrist Apr 12 '11 at 15:54

Redis (the actual server) is dealing only with "binary safe" Strings.

I take this to mean that you can use arbitrary octet sequences for the keys/values. If you can use any C char sequence without thought to character encoding, then the equivalent in Java is the byte type.

Strings in Java are implicitly UTF-16. I mean, you could stick arbitrary numbers in there, but the intent of the class is to represent Unicode character data. Methods that do byte-to-char transformations perform transcoding operations from a known encoding to UTF-16.

If Jedis treats keys/values as UTF-8, then it will not support every value that Redis supports. Not every byte sequence is valid UTF-8, so the encoding can't be used for binary safe strings.

Whether UTF-8 or UTF-16 consumes more memory depends on the data - the euro symbol (€) for example consumes three bytes in UTF-8 and only two in UTF-16.


Just for the record, I wrote my own little implementation of a byte[] <-> String interconverter, that works by casting every 2 bytes in 1 char. It's roughly 30-40% faster and consumes (possibly less than) half the memory of the Java standard way: new String(somebyte) and someString.getBytes().

However, it is incompatible with existing string encoded bytes or byte encoded strings. Furthermore, it is not safe to call the method from different JVMs on shared data.



Maybe it is this what you want:

// Store them into the 16 bit datatype.
char c1_8bit = 'a';
char c2_8bit = 'h';
char two_chars = (c1_8bit << 8) + c2_8bit;

// extract them
char c1_8bit = two_chars >> 8;
char c2_8bit = two_chars & 0xFF;

Of course this trick only works with ASCII chars (chars in the range [0-255]). Why? Because you want to store your chars this way:
xxxx xxxx yyyy yyyy with x is char 1 and y is char 2. So this means you have only 8 bit per char. And what is the biggest integer you can make with 8 bit? Answer: 255

255 = 0000 0000 1111 1111 (8 bit). And when you are using a char > 255, then you will have this:
256 = 0000 0001 0000 0000 (more than 8 bit), which doesn't fit in the 8 bit you provide for 1 char.

Plus: Keep in mind Java is a language, developed by clever people. They knew what they where doing. Thrust the Java API

  • 1
    Seemingly clever, but try to do this with these two characters: çé. Oh, they're not 8-bit, are they? Congratulations, you now have a weird mess in two_chars with no way to extract the original characters. (Interesting how everyone thinks that ASCII should be enough for everyone, even when they meet characters outside ASCII, every day) – Piskvor Apr 12 '11 at 12:16
  • @Piskvor: I said I know it won't work with chars out of the range [0-255]. But if he knows what he is doing, and his application only uses ASCII chars, this is what he wants... – Martijn Courteaux Apr 12 '11 at 13:01
  • If the Java folks were so clever, why would they create a char datatype that isn’t big enough to hold a character? Remember: “int is the new char.” – tchrist Apr 12 '11 at 13:27
  • "if his application only uses ASCII chars" - that is possible but not very likely. In such case, yours would be a valid way to do it (although I'd still think that there are better ways to conserve space, such as Huffman coding). – Piskvor Apr 12 '11 at 14:54
  • thanks for that answer. I acually don't care at all about characters. I just want to pack byte in string efficiently. So yes, byte should be [0-255] maybe I have to use Shift operators as you did. Your hint remembered me that some peoples just casted byte to strings. So now I'm trying to cast two byte into one char. – ib84 Apr 12 '11 at 15:02

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