I have a university programming exam coming up, and one section is on unicode.

I have checked all over for answers to this, and my lecturer is useless so that’s no help, so this is a last resort for you guys to possibly help.

The question will be something like:

The string 'mЖ丽' has these unicode codepoints U+006D, U+0416 and U+4E3D, with answers written in hexadecimal, manually encode the string into UTF-8 and UTF-16.

Any help at all will be greatly appreciated as I am trying to get my head round this.

  • Did you try to write a program that converts a UTF-8 string to a UTF-16 string and then manually compare the output (UTF-16) and input (UTF-8)?
    – user142019
    Commented Jun 4, 2011 at 23:52
  • 1
    I have played around with several coded converters, but im still at a miss as to how i actually do it manually with a pen and paper, as thats all we will have in the exam.
    – RSM
    Commented Jun 4, 2011 at 23:55
  • Does this answer your question? How does UTF-8 "variable-width encoding" work? Commented Jul 24, 2023 at 1:12

3 Answers 3


Wow. On the one hand I'm thrilled to know that university courses are teaching to the reality that character encodings are hard work, but actually knowing the UTF-8 encoding rules sounds like expecting a lot. (Will it help students pass the Turkey test?)

The clearest description I've seen so far for the rules to encode UCS codepoints to UTF-8 are from the utf-8(7) manpage on many Linux systems:

   The following byte sequences are used to represent a
   character.  The sequence to be used depends on the UCS code
   number of the character:

   0x00000000 - 0x0000007F:

   0x00000080 - 0x000007FF:
       110xxxxx 10xxxxxx

   0x00000800 - 0x0000FFFF:
       1110xxxx 10xxxxxx 10xxxxxx

   0x00010000 - 0x001FFFFF:
       11110xxx 10xxxxxx 10xxxxxx 10xxxxxx

   [... removed obsolete five and six byte forms ...]

   The xxx bit positions are filled with the bits of the
   character code number in binary representation.  Only the
   shortest possible multibyte sequence which can represent the
   code number of the character can be used.

   The UCS code values 0xd800–0xdfff (UTF-16 surrogates) as well
   as 0xfffe and 0xffff (UCS noncharacters) should not appear in
   conforming UTF-8 streams.

It might be easier to remember a 'compressed' version of the chart:

Initial bytes starts of mangled codepoints start with a 1, and add padding 1+0. Subsequent bytes start 10.

0x80      5 bits, one byte
0x800     4 bits, two bytes
0x10000   3 bits, three bytes

You can derive the ranges by taking note of how much space you can fill with the bits allowed in the new representation:

2**(5+1*6) == 2048       == 0x800
2**(4+2*6) == 65536      == 0x10000
2**(3+3*6) == 2097152    == 0x200000

I know I could remember the rules to derive the chart easier than the chart itself. Here's hoping you're good at remembering rules too. :)


Once you have built the chart above, you can convert input Unicode codepoints to UTF-8 by finding their range, converting from hexadecimal to binary, inserting the bits according to the rules above, then converting back to hex:


This fits in the 0x00000800 - 0x0000FFFF range (0x4E3E < 0xFFFF), so the representation will be of the form:

   1110xxxx 10xxxxxx 10xxxxxx

0x4E3E is 100111000111110b. Drop the bits into the x above (start from the right, we'll fill in missing bits at the start with 0):

   1110x100 10111000 10111110

There is an x spot left over at the start, fill it in with 0:

   11100100 10111000 10111110

Convert from bits to hex:

   0xE4 0xB8 0xBE
  • Brilliant thanks for your help. The content on the course is good, cannot say the same for the lecturers teaching it tho. So for example. I have 'm' which is unicode codepoint 'u+006D' which i think lies in: 0x00000000 - 0x0000007F: 0xxxxxxx. Im still a little confused as where to go from here
    – RSM
    Commented Jun 5, 2011 at 0:32
  • @Ryan, the ascii range (0--127 aka 0x0--0x7F) is easy -- they self-represent. So your u+006D is just 01101101b. :) (Which I got with my calculator, because I'm lazy. Hex-to-bin by hand isn't horrible though, you can write a translation table by hand at the start of the test and re-use it each time you need it. :)
    – sarnold
    Commented Jun 5, 2011 at 0:36
  • @sarnold is it always 01101101 for everthing that lies between 0x0 - 0x7F? or was there more of a process to go from U+006D to 01101101b. Where did you get the b from?
    – RSM
    Commented Jun 5, 2011 at 0:41
  • @Ryan, sorry :) The 01101101b was specific to your input u+006D. That's just 0x6D in binary. (I included the b at the end to signify binary -- numbers starting with a leading 0 are sometimes meant to be octal.) Everything between 0 and 0x7F requires only seven bits to represent, so the leading 0 in the rules is just re-stating that the ascii range remains unchanged in UTF-8, one of its prime selling points.
    – sarnold
    Commented Jun 5, 2011 at 0:44
  • 1
    @MarcusJ, thanks for the reminder, I never got around to removing the obsolete data after Patryk notified me.
    – sarnold
    Commented Dec 12, 2017 at 1:45

The descriptions on Wikipedia for UTF-8 and UTF-16 are good:

Procedures for your example string:


UTF-8 uses up to 4 bytes to represent Unicode codepoints. For the 1-byte case, use the following pattern:

1-byte UTF-8 = 0xxxxxxxbin = 7 bits = 0-7Fhex

The initial byte of 2-, 3- and 4-byte UTF-8 start with 2, 3 or 4 one bits, followed by a zero bit. Follow on bytes always start with the two-bit pattern 10, leaving 6 bits for data:

2-byte UTF-8 = 110xxxxx 10xxxxxxbin = 5+6(11) bits = 80-7FFhex
3-byte UTF-8 = 1110xxxx 10xxxxxx 10xxxxxxbin = 4+6+6(16) bits = 800-FFFFhex
4-byte UTF-8 = 11110xxx 10xxxxxx 10xxxxxx 10xxxxxxbin = 3+6+6+6(21) bits = 10000-10FFFFhex

Unicode codepoints are undefined beyond 10FFFFhex.

Your codepoints are U+006D, U+0416 and U+4E3D requiring 1-, 2- and 3-byte UTF-8 sequences, respectively. Convert to binary and assign the bits:

U+006D = 1101101bin = 01101101bin = 6Dhex
U+0416 = 10000 010110bin = 11010000 10010110bin = D0 96hex
U+4E3D = 0100 111000 111101bin = 11100100 10111000 10111101bin = E4 B8 BDhex

Final byte sequence:

6D D0 96 E4 B8 BD

or if nul-terminated strings are desired:

6D D0 96 E4 B8 BD 00


UTF-16 uses 2 or 4 bytes to represent Unicode codepoints. Algorithm:

U+0000 to U+D7FF uses 2-byte 0000hex to D7FFhex
U+D800 to U+DFFF are invalid codepoints reserved for 4-byte UTF-16
U+E000 to U+FFFF uses 2-byte E000hex to FFFFhex

U+10000 to U+10FFFF uses 4-byte UTF-16 encoded as follows:

  1. Subtract 10000hex from the codepoint.
  2. Express result as 20-bit binary.
  3. Use the pattern 110110xxxxxxxxxx 110111xxxxxxxxxxbin to encode the upper- and lower- 10 bits into two 16-bit words.

Using your codepoints:

U+006D = 006Dhex
U+0416 = 0416hex
U+4E3D = 4E3Dhex

Now, we have one more issue. Some machines store the two bytes of a 16-bit word least significant byte first (so-called little-endian machines) and some store most significant byte first (big-endian machines). UTF-16 uses the codepoint U+FEFF (called the byte order mark or BOM) to help a machine determine if a byte stream contains big- or little-endian UTF-16:

big-endian = FE FF 00 6D 04 16 4E 3D
little-endian = FF FE 6D 00 16 04 3D 4E

With nul-termination, U+0000 = 0000hex:

big-endian = FE FF 00 6D 04 16 4E 3D 00 00
little-endian = FF FE 6D 00 16 04 3D 4E 00 00

Since your instructor didn't give a codepoint that required 4-byte UTF-16, here's one example:

U+1F031 = 1F031hex - 10000hex = F031hex = 0000111100 0000110001bin =
1101100000111100 1101110000110001bin = D83C DC31hex


The following program will do the necessary work. It may not be "manual" enough for your purposes, but at a minimum you can check your work.


use 5.012;
use strict;
use utf8;
use autodie;
use warnings;
use warnings    qw< FATAL utf8 >;
no warnings     qw< uninitialized >;
use open        qw< :std :utf8 >;
use charnames   qw< :full >;
use feature     qw< unicode_strings >;

use Encode              qw< encode decode >;
use Unicode::Normalize  qw< NFD NFC >;

my ($x) = "mЖ丽";

print U8 $x;
print U16 $x;
system("od -t x1 /tmp/utf8-out");
my $u8 = encode("utf-8",$x);
print "utf-8: 0x".unpack("H*",$u8)."\n";

system("od -t x1 /tmp/utf16-out");
my $u16 = encode("utf-16",$x);
print "utf-16: 0x".unpack("H*",$u16)."\n";
  • Clever; I hadn't heard Perl introduced >:encoding()-style support yet. Thanks!
    – sarnold
    Commented Jun 5, 2011 at 2:22

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