I'm using Python and Django, but I'm having a problem caused by a limitation of MySQL. According to the MySQL 5.1 documentation, their
utf8 implementation does not support 4-byte characters. MySQL 5.5 will support 4-byte characters using
utf8mb4; and, someday in future,
utf8 might support it as well.
But my server is not ready to upgrade to MySQL 5.5, and thus I'm limited to UTF-8 characters that take 3 bytes or less.
My question is: How to filter (or replace) unicode characters that would take more than 3 bytes?
I want to replace all 4-byte characters with the official
\ufffd (U+FFFD REPLACEMENT CHARACTER), or with
In other words, I want a behavior quite similar to Python's own
str.encode() method (when passing
'replace' parameter). Edit: I want a behavior similar to
encode(), but I don't want to actually encode the string. I want to still have an unicode string after filtering.
I DON'T want to escape the character before storing at the MySQL, because that would mean I would need to unescape all strings I get from the database, which is very annoying and unfeasible.
- "Incorrect string value" warning when saving some unicode characters to MySQL (at Django ticket system)
- ‘𠂉’ Not a valid unicode character, but in the unicode character set? (at Stack Overflow)
[EDIT] Added tests about the proposed solutions
So I got good answers so far. Thanks, people! Now, in order to choose one of them, I did a quick testing to find the simplest and fastest one.
#!/usr/bin/env python # -*- coding: utf-8 -*- # vi:ts=4 sw=4 et import cProfile import random import re # How many times to repeat each filtering repeat_count = 256 # Percentage of "normal" chars, when compared to "large" unicode chars normal_chars = 90 # Total number of characters in this string string_size = 8 * 1024 # Generating a random testing string test_string = u''.join( unichr(random.randrange(32, 0x10ffff if random.randrange(100) > normal_chars else 0x0fff )) for i in xrange(string_size) ) # RegEx to find invalid characters re_pattern = re.compile(u'[^\u0000-\uD7FF\uE000-\uFFFF]', re.UNICODE) def filter_using_re(unicode_string): return re_pattern.sub(u'\uFFFD', unicode_string) def filter_using_python(unicode_string): return u''.join( uc if uc < u'\ud800' or u'\ue000' <= uc <= u'\uffff' else u'\ufffd' for uc in unicode_string ) def repeat_test(func, unicode_string): for i in xrange(repeat_count): tmp = func(unicode_string) print '='*10 + ' filter_using_re() ' + '='*10 cProfile.run('repeat_test(filter_using_re, test_string)') print '='*10 + ' filter_using_python() ' + '='*10 cProfile.run('repeat_test(filter_using_python, test_string)') #print test_string.encode('utf8') #print filter_using_re(test_string).encode('utf8') #print filter_using_python(test_string).encode('utf8')
filter_using_re()did 515 function calls in 0.139 CPU seconds (0.138 CPU seconds at the
filter_using_python()did 2097923 function calls in 3.413 CPU seconds (1.511 CPU seconds at the
join()call and 1.900 CPU seconds evaluating the generator expression)
- I did no test using
itertoolsbecause... well... that solution, although interesting, was quite big and complex.
The RegEx solution was, by far, the fastest one.