I have been reading about how Unicode code points have evolved over time, including this article by Joel Spolsky, which says:

Some people are under the misconception that Unicode is simply a 16-bit code where each character takes 16 bits and therefore there are 65,536 possible characters. This is not, actually, correct.

But despite all this reading, I couldn't find the real reason that Java uses UTF-16 for a char.

Isn't UTF-8 far more efficient than UTF-16? For example, if I had a string which contains 1024 letters of ASCII scoped characters, UTF-16 will take 1024 * 2 bytes (2KB) of memory.

But if Java used UTF-8, it would be just 1KB of data. Even if the string has a few character which needs to 2 bytes, it will still only take about a kilobyte. For example, suppose in addition to the 1024 characters, there were 10 characters of "字" (code-point U+5b57, UTF-8 encoding e5 ad 97). In UTF-8, this will still take only (1024 * 1 byte) + (10 * 3 bytes) = 1KB + 30 bytes.

So this doesn't answer my question. 1KB + 30 bytes for UTF-8 is clearly less memory than 2KB for UTF-16.

Of course it makes sense that Java doesn't use ASCII for a char, but why does it not use UTF-8, which has a clean mechanism for handling arbitrary multi-byte characters when they come up? UTF-16 looks like a waste of memory in any string which has lots of non-multibyte chars.

Is there some good reason for UTF-16 that I'm missing?

  • 4
    Suppose you want to access the 576th char of the string, and it's represented as an UTF8 encoded byte array. What is the cost of the operation?
    – JB Nizet
    Mar 26, 2016 at 14:32
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    Strings are immutable - it is possible (and it still would be possible to retrofit this without breaking existing Java code [it would probably break JNI]) to store strings with only codes 0-255 in an 8-bit encoding, and strings with other codes in 16-bit like it is now. But it seems that the need for this isn't very high (at least I haven't seen a big demand for this). Mar 26, 2016 at 15:05
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    @ErwinBolwidt it's actually scheduled for Java 9
    – Clashsoft
    Mar 26, 2016 at 17:20
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    It's safER to just go to the (576*2)th byte in a UTF16 string to find the 576th character. But UTF16 still allows for 32 bit characters (two 16-bit code points). afaik, java (and c# as well for that matter) just ignore this when accessing the Nth character in a string, meaning you could either end up at a different character than you expected to, or end up with half a character. May 19, 2016 at 20:33
  • 1
    @JBNizet your rhetorical question is misleading: UTF8 and UTF16 have the same performance in that case. Unless the JVM keeps track of whether the string has only BMP code points and optimizes for that case. Jul 17, 2017 at 18:03

2 Answers 2


Java used UCS-2 before transitioning over UTF-16 in 2004/2005. The reason for the original choice of UCS-2 is mainly historical:

Unicode was originally designed as a fixed-width 16-bit character encoding. The primitive data type char in the Java programming language was intended to take advantage of this design by providing a simple data type that could hold any character.

This, and the birth of UTF-16, is further explained by the Unicode FAQ page:

Originally, Unicode was designed as a pure 16-bit encoding, aimed at representing all modern scripts. (Ancient scripts were to be represented with private-use characters.) Over time, and especially after the addition of over 14,500 composite characters for compatibility with legacy sets, it became clear that 16-bits were not sufficient for the user community. Out of this arose UTF-16.

As @wero has already mentioned, random access cannot be done efficiently with UTF-8. So all things weighed up, UCS-2 was seemingly the best choice at the time, particularly as no supplementary characters had been allocated by that stage. This then left UTF-16 as the easiest natural progression beyond that.


Historically, one reason was the performance characteristics of random access or iterating over the characters of a String:

UTF-8 encoding uses a variable number (1-4) bytes to encode a Unicode character. Therefore accessing a character by index: String.charAt(i) would be way more complicated to implement and slower than the array access used by java.lang.String.

Even today, Python uses a fixed-width format for Strings internally, storing either 1, 2, or 4 bytes per character depending on the maximum size of a character in that string.

Of course, this is no longer a pure benefit in Java, since, as nj_ explains, Java no longer uses a fixed-with format. But at the time the language was developed, Unicode was a fixed-width format (now called UCS-2), and this would have been an advantage.

  • 8
    This was true for UCS-2, but UCS-2 ceased to be when Unicode expanded beyond the BMP (i.e. beyond the first 65536 characters); nowadays there's only UTF-16 and it is a variable length encoding exactly as UTF-8. You can put the head under the sand and think you are iterating over Unicode code points only until you find the first surrogate pair. See @nj_'s answer for the details. May 19, 2016 at 20:26
  • @MatteoItalia The question asks why Java does not use e.g. UTF-8 to store Strings in order to save memory compared to the current implementation. My answer gave a particular reason - namely performance of accessing characters by index - why UTF-8 night not be a good idea.
    – wero
    May 19, 2016 at 21:03
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    the point is that UTF-16 is too a variable length encoding. May 19, 2016 at 21:53
  • @MatteoItalia so you want Oracle to remove String.charAt because it allows people to put their head under the sand?
    – wero
    May 19, 2016 at 22:00
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    No, I want to point out that it's false that UTF-16 has any advantage over UTF-8 related to seeking at a given code point, because UTF-16, exactly as UTF-8, is a variable length encoding, which takes either 1 or 2 code units to encode a single code point. If you want O(1) seek to a given code point you want UTF-32, not UTF-16. For this reason, your answer is plain wrong - or actually, outdated of 21 years (IIRC it was in 1995 that Unicode was expanded beyond the BMP, killing the fixed-lenght UCS-2 encoding, which became the UTF-16 variable length encoding). May 19, 2016 at 23:04

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