What are the differences between UTF-8, UTF-16, and UTF-32?

I understand that they will all store Unicode, and that each uses a different number of bytes to represent a character. Is there an advantage to choosing one over the other?

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    Watch this video if you are interested in how Unicode works youtube.com/watch?v=MijmeoH9LT4 – Joe Sep 30 '13 at 17:04
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    The video focuses on UTF-8, and yes it explains well how variable length encoding works and is mostly compatible with computers reading or writing only fixed length ASCII. Unicode guys were smart when designing UTF-8 encoding. – mins Jul 2 '14 at 19:33
  • I've created an online tool for conversion and comparison. – Amit Kumar Gupta Nov 14 at 1:21

12 Answers 12

up vote 294 down vote accepted

UTF-8 has an advantage in the case where ASCII characters represent the majority of characters in a block of text, because UTF-8 encodes all characters into 8 bits (like ASCII). It is also advantageous in that a UTF-8 file containing only ASCII characters has the same encoding as an ASCII file.

UTF-16 is better where ASCII is not predominant, since it uses 2 bytes per character, primarily. UTF-8 will start to use 3 or more bytes for the higher order characters where UTF-16 remains at just 2 bytes for most characters.

UTF-32 will cover all possible characters in 4 bytes. This makes it pretty bloated. I can't think of any advantage to using it.

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    UTF-32 advantage: you don't need to decode stored data to the 32-bit Unicode code point for e.g. character by character handling. The code point is already available right there in your array/vector/string. – richq Jan 30 '09 at 17:48
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    It's also easier to parse if (heaven help you) you have to re-implement the wheel. – Paul McMillan Sep 29 '09 at 18:58
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    Well, UTF-8 has an advantage in network transfers - no need to worry about endianness since you're transfering data one byte at a time (as opposed to 4). – Tim Čas Dec 31 '11 at 14:20
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    @richq You can't do character-by-character handling in UTF-32, as code point does not always correspond to a character. – hamstergene Nov 13 '12 at 17:27
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    The statement "UTF-8 encodes all characters into 8 bits" is wrong. It does not encode "all" characters into 8 bits. It uses variable-length encoding, which is a multiple of 8-bits. So characters can take 8, 16, 24, up to 32 bits! – Nawaz Dec 25 '16 at 8:05

In short:

  • UTF-8: Variable-width encoding, backwards compatible with ASCII. ASCII characters (U+0000 to U+007F) take 1 byte, code points U+0080 to U+07FF take 2 bytes, code points U+0800 to U+FFFF take 3 bytes, code points U+10000 to U+10FFFF take 4 bytes. Good for English text, not so good for Asian text.
  • UTF-16: Variable-width encoding. Code points U+0000 to U+FFFF take 2 bytes, code points U+10000 to U+10FFFF take 4 bytes. Bad for English text, good for Asian text.
  • UTF-32: Fixed-width encoding. All code points take four bytes. An enormous memory hog, but fast to operate on. Rarely used.

In long: see Wikipedia: UTF-8, UTF-16, and UTF-32.

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    How is "UTF8 is not so good for Asian text"? This is false. UTF-8 is perfect for Japanese, for example. I run a Japanese web site and everything is encoded in UTF8 and all works fine. UTF-8 can encode any Unicode character. – PandaWood Aug 4 '09 at 12:25
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    @spurrymoses: I'm referring strictly to the amount of space taken up by the data bytes. UTF-8 requires 3 bytes per Asian character, while UTF-16 only requires 2 bytes per Asian character. This really isn't a major problem, since computers have tons of memory these days compared to the average amount of text stored in a program's memory. – Adam Rosenfield Aug 4 '09 at 14:19
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    UTF-32 isn't rarely used anymore... on osx and linux wchar_t defaults to 4 bytes. gcc has an option -fshort-wchar which reduces the size to 2 bytes, but breaks the binary compatibility with std libs. – vine'th Nov 14 '11 at 10:12
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    @UstamanSangat Yes, if this answer is restricted to only memory requirements, then I missed the point. However that point was never made within the answer (nor does the question require it). It appears then, that I missed a point that was never made but that you somehow were able to see without it even being said. When someone says that UTF-8 is "not so good for Asian text" - without restricting it to the context of memory requirements, then it is wrong. – PandaWood Dec 16 '11 at 7:08
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    If someone were to say UTF-8 is "not so good for Asian text" in the context of All Encoding Formats Including Those That Cannot Encode Unicode, they would of course be wrong. But that is not the context. The context of memory requirements comes from the fact that the question (and answer) is comparing UTF-8, UTF-16 and UTF-32, which will all encode Asian text but use differing amounts of memory/storage. It follows that their relative goodness would naturally be entirely in the context of memory requirements. "Not so good" != "not good". – Paul Gregory Jan 23 '13 at 11:39
  • UTF-8 is variable 1 to 4 bytes.

  • UTF-16 is variable 2 or 4 bytes.

  • UTF-32 is fixed 4 bytes.

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    UTF8 is actually 1 to 6 bytes. – Urkle Feb 24 '14 at 21:17
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    @Urkle is technically correct because mapping the full range of UTF32/LE/BE includes U-00200000 - U-7FFFFFFF even though Unicode v6.3 ends at U-0010FFFF inclusive. Here's a nice breakdown of how to enc/dec 5 and 6 byte utf8: lists.gnu.org/archive/html/help-flex/2005-01/msg00030.html – Barry May 13 '14 at 23:08
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    backing up these with relevant references parts and their sources? – n611x007 Jun 6 '14 at 15:15
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    @Urkle No, UTF-8 can not be 5 or 6 bytes. Unicode code points are limited to 21 bits, which limits UTF-8 to 4 bytes. (You could of course extend the principle of UTF-8 to encode arbitrary large integers, but it would not be Unicode.) See RFC 3629. – rdb Sep 20 '15 at 14:17
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    Quoting Wikipedia: In November 2003, UTF-8 was restricted by RFC 3629 to match the constraints of the UTF-16 character encoding: explicitly prohibiting code points corresponding to the high and low surrogate characters removed more than 3% of the three-byte sequences, and ending at U+10FFFF removed more than 48% of the four-byte sequences and all five- and six-byte sequences. – Adam Calvet Bohl Jan 20 '17 at 11:48

Unicode defines a single huge character set, assigning one unique integer value to every graphical symbol (that is a major simplification, and isn't actually true, but it's close enough for the purposes of this question). UTF-8/16/32 are simply different ways to encode this.

In brief, UTF-32 uses 32-bit values for each character. That allows them to use a fixed-width code for every character.

UTF-16 uses 16-bit by default, but that only gives you 65k possible characters, which is nowhere near enough for the full Unicode set. So some characters use pairs of 16-bit values.

And UTF-8 uses 8-bit values by default, which means that the 127 first values are fixed-width single-byte characters (the most significant bit is used to signify that this is the start of a multi-byte sequence, leaving 7 bits for the actual character value). All other characters are encoded as sequences of up to 4 bytes (if memory serves).

And that leads us to the advantages. Any ASCII-character is directly compatible with UTF-8, so for upgrading legacy apps, UTF-8 is a common and obvious choice. In almost all cases, it will also use the least memory. On the other hand, you can't make any guarantees about the width of a character. It may be 1, 2, 3 or 4 characters wide, which makes string manipulation difficult.

UTF-32 is opposite, it uses the most memory (each character is a fixed 4 bytes wide), but on the other hand, you know that every character has this precise length, so string manipulation becomes far simpler. You can compute the number of characters in a string simply from the length in bytes of the string. You can't do that with UTF-8.

UTF-16 is a compromise. It lets most characters fit into a fixed-width 16-bit value. So as long as you don't have Chinese symbols, musical notes or some others, you can assume that each character is 16 bits wide. It uses less memory than UTF-32. But it is in some ways "the worst of both worlds". It almost always uses more memory than UTF-8, and it still doesn't avoid the problem that plagues UTF-8 (variable-length characters).

Finally, it's often helpful to just go with what the platform supports. Windows uses UTF-16 internally, so on Windows, that is the obvious choice.

Linux varies a bit, but they generally use UTF-8 for everything that is Unicode-compliant.

So short answer: All three encodings can encode the same character set, but they represent each character as different byte sequences.

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    It is inaccurate to say that Unicode assigns a unique integer to each graphical symbol. It assigns such to each code point, but some code points are invisible control characters, and some graphical symbols require multiple code points to represent. – tchrist Mar 7 '12 at 1:58
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    @tchrist: yes, it's inaccurate. The problem is that to accurately explain Unicode, you need to write thousands of pages. I hoped to get the basic concept across to explain the difference between encodings – jalf Mar 7 '12 at 9:42
  • @jalf lol right so basically to explain Unicode you would have to write the Unicode Core Specification – Justin Ohms Jul 8 '16 at 18:07

Unicode is a standard and about UTF-x you can think as a technical implementation for some practical purposes:

  • UTF-8 - "size optimized": best suited for Latin character based data (or ASCII), it takes only 1 byte per character but the size grows accordingly symbol variety (and in worst case could grow up to 6 bytes per character)
  • UTF-16 - "balance": it takes minimum 2 bytes per character which is enough for existing set of the mainstream languages with having fixed size on it to ease character handling (but size is still variable and can grow up to 4 bytes per character)
  • UTF-32 - "performance": allows using of simple algorithms as result of fixed size characters (4 bytes) but with memory disadvantage
  • «mainstream languages» not that mainstream in a lot of parts of the world ^^ – tuxayo Jun 21 at 14:48
  • UTF-16 is actually size optimized for non ASCII chars. For it really depends with which languages it will be used. – tuxayo Jun 21 at 14:49
  • @tuxayo totally agree, it is worth noting sets of Hanzi and Kanji characters for Asian part of world. – rook Jun 22 at 12:49

I tried to give a simple explanation in my blogpost.


requires 32 bits (4 bytes) to encode any character. For example, in order to represent the "A" character code-point using this scheme, you'll need to write 65 in 32-bit binary number:

00000000 00000000 00000000 01000001 (Big Endian)

If you take a closer look, you'll note that the most-right seven bits are actually the same bits when using the ASCII scheme. But since UTF-32 is fixed width scheme, we must attach three additional bytes. Meaning that if we have two files that only contain the "A" character, one is ASCII-encoded and the other is UTF-32 encoded, their size will be 1 byte and 4 bytes correspondingly.


Many people think that as UTF-32 uses fixed width 32 bit to represent a code-point, UTF-16 is fixed width 16 bits. WRONG!

In UTF-16 the code point maybe represented either in 16 bits, OR 32 bits. So this scheme is variable length encoding system. What is the advantage over the UTF-32? At least for ASCII, the size of files won't be 4 times the original (but still twice), so we're still not ASCII backward compatible.

Since 7-bits are enough to represent the "A" character, we can now use 2 bytes instead of 4 like the UTF-32. It'll look like:

00000000 01000001


You guessed right.. In UTF-8 the code point maybe represented using either 32, 16, 24 or 8 bits, and as the UTF-16 system, this one is also variable length encoding system.

Finally we can represent "A" in the same way we represent it using ASCII encoding system:


A small example where UTF-16 is actually better than UTF-8:

Consider the Chinese letter "語" - its UTF-8 encoding is:

11101000 10101010 10011110

While its UTF-16 encoding is shorter:

10001010 10011110

In order to understand the representation and how it's interpreted, visit the original post.


  • has no concept of byte-order
  • uses between 1 and 4 bytes per character
  • ASCII is a compatible subset of encoding
  • completely self-synchronizing e.g. a dropped byte from anywhere in a stream will corrupt at most a single character
  • pretty much all European languages are encoded in two bytes or less per character


  • must be parsed with known byte-order or reading a byte-order-mark (BOM)
  • uses either 2 or 4 bytes per character


  • every character is 4 bytes
  • must be parsed with known byte-order or reading a byte-order-mark (BOM)

UTF-8 is going to be the most space efficient unless a majority of the characters are from the CJK (Chinese, Japanese, and Korean) character space.

UTF-32 is best for random access by character offset into a byte-array.

  • How does "self synchronizing" work in UTF-8? Can you give examples for 1 byte and 2 byte characters? – Koray Tugay Jul 8 '16 at 16:57
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    @KorayTugay Valid shorter byte strings are never used in longer characters. For instance, ASCII is in the range 0-127, meaning all one-byte characters have the form 0xxxxxxx in binary. All two-byte characters begin with 110xxxxx with a second byte of 10xxxxxx. So let's say the first character of a two-byte character is lost. As soon as you see 10xxxxxx without a preceding 110xxxxxx, you can determine for sure that a byte was lost or corrupted, and discard that character (or re-request it from a server or whatever), and move on until you see a valid first byte again. – Chris Aug 1 '17 at 23:38
  • if you have the offset to a character, you have the offset to that character -- utf8, utf16 or utf32 will work just the same in that case; i.e. they are all equally good at random access by character offset into a byte array. The idea that utf32 is better at counting characters than utf8 is also completely false. A codepoint (which is not the same as a character which again, is not the same as a grapheme.. sigh), is 32 bits wide in utf32 and between 8 and 32 bits in utf8, but a character may span multiple codepoints, which destroys the major advantage that people claim utf32 has over utf8. – Clearer Nov 25 '17 at 22:19

I made some tests to compare database performance between UTF-8 and UTF-16 in MySQL.

Update Speeds


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    It depends so much on the text you use... – kiwixz Feb 3 '15 at 16:23

In UTF-32 all of characters are coded with 32 bits. The advantage is that you can easily calculate the length of the string. The disadvantage is that for each ASCII characters you waste an extra three bytes.

In UTF-8 characters have variable length, ASCII characters are coded in one byte (eight bits), most western special characters are coded either in two bytes or three bytes (for example € is three bytes), and more exotic characters can take up to four bytes. Clear disadvantage is, that a priori you cannot calculate string's length. But it's takes lot less bytes to code Latin (English) alphabet text, compared to UTF-32.

UTF-16 is also variable length. Characters are coded either in two bytes or four bytes. I really don't see the point. It has disadvantage of being variable length, but hasn't got the advantage of saving as much space as UTF-8.

Of those three, clearly UTF-8 is the most widely spread.

  • Why would I want to calculate the length of the string while developing websites? Is there any advantage of choosing UTF-8/UTF-16 in web development? – Morfidon Sep 8 '17 at 8:07

Depending on your development environment you may not even have the choice what encoding your string data type will use internally.

But for storing and exchanging data I would always use UTF-8, if you have the choice. If you have mostly ASCII data this will give you the smallest amount of data to transfer, while still being able to encode everything. Optimizing for the least I/O is the way to go on modern machines.

  • Arguably, a lot more important than space requirements is the fact, that UTF-8 is immune to endianness. UTF-16 and UTF-32 will inevitably have to deal with endianness issues, where UTF-8 is simply a stream of octets. – IInspectable Sep 2 at 18:26

As mentioned, the difference is primarily the size of the underlying variables, which in each case get larger to allow more characters to be represented.

However, fonts, encoding and things are wickedly complicated (unnecessarily?), so a big link is needed to fill in more detail:


Don't expect to understand it all, but if you don't want to have problems later it's worth learning as much as you can, as early as you can (or just getting someone else to sort it out for you).


In short, the only reason to use UTF-16 or UTF-32 is to support non-English and ancient scripts respectively.

I was wondering why anyone would chose to have non-UTF-8 encoding when it is obviously more efficient for web/programming purposes.

A common misconception - the suffixed number is NOT an indication of its capability. They all support the complete Unicode, just that UTF-8 can handle ASCII with a single byte, so is MORE efficient/less corruptible to the CPU and over the internet.

Some good reading: http://www.personal.psu.edu/ejp10/blogs/gotunicode/2007/10/which_utf_do_i_use.html and http://utf8everywhere.org

  • I'm not sure, why you suggest, that using UTF-16 or UTF-32 were to support non-English text. UTF-8 can handle that just fine. And there are non-ASCII characters in English text, too. Like a zero-width non-joiner. Or an em dash. I'm afraid, this answer doesn't add much value. – IInspectable Sep 2 at 18:30

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