Why does modern Perl avoid UTF-8 by default?

There are two stages to processing Unicode text. The first is "how can I input it and output it without losing information". The second is "how do I treat text according to local language conventions".

tchrist's post covers both, but the second part is where 99% of the text in his post comes from. Most programs don't even handle I/O correctly, so it's important to understand that before you even begin to worry about normalization and collation.

This post aims to solve that first problem

When you read data into Perl, it doesn't care what encoding it is. It allocates some memory and stashes the bytes away there. If you say print $str, it just blits those bytes out to your terminal, which is probably set to assume everything that is written to it is UTF-8, and your text shows up.

Marvelous.

Except, it's not. If you try to treat the data as text, you'll see that Something Bad is happening. You need go no further than length to see that what Perl thinks about your string and what you think about your string disagree. Write a one-liner like: perl -E 'while(<>){ chomp; say length }' and type in 文字化け and you get 12... not the correct answer, 4.

That's because Perl assumes your string is not text. You have to tell it that it's text before it will give you the right answer.

That's easy enough; the Encode module has the functions to do that. The generic entry point is Encode::decode (or use Encode qw(decode), of course). That function takes some string from the outside world (what we'll call "octets", a fancy of way of saying "8-bit bytes"), and turns it into some text that Perl will understand. The first argument is a character encoding name, like "UTF-8" or "ASCII" or "EUC-JP". The second argument is the string. The return value is the Perl scalar containing the text.

(There is also Encode::decode_utf8, which assumes UTF-8 for the encoding.)

If we rewrite our one-liner:

perl -MEncode=decode -E 'while(<>){ chomp; say length decode("UTF-8", $_) }'

We type in 文字化け and get "4" as the result. Success.

That, right there, is the solution to 99% of Unicode problems in Perl.

The key is, whenever any text comes into your program, you must decode it. The Internet cannot transmit characters. Files cannot store characters. There are no characters in your database. There are only octets, and you can't treat octets as characters in Perl. You must decode the encoded octets into Perl characters with the Encode module.

The other half of the problem is getting data out of your program. That's easy to; you just say use Encode qw(encode), decide what the encoding your data will be in (UTF-8 to terminals that understand UTF-8, UTF-16 for files on Windows, etc.), and then output the result of encode($encoding, $data) instead of just outputting $data.

This operation converts Perl's characters, which is what your program operates on, to octets that can be used by the outside world. It would be a lot easier if we could just send characters over the Internet or to our terminals, but we can't: octets only. So we have to convert characters to octets, otherwise the results are undefined.

To summarize: encode all outputs and decode all inputs.

Now we'll talk about three issues that make this a little challenging. The first is libraries. Do they handle text correctly? The answer is... they try. If you download a web page, LWP will give you your result back as text. If you call the right method on the result, that is (and that happens to be decoded_content, not content, which is just the octet stream that it got from the server.) Database drivers can be flaky; if you use DBD::SQLite with just Perl, it will work out, but if some other tool has put text stored as some encoding other than UTF-8 in your database... well... it's not going to be handled correctly until you write code to handle it correctly.

Outputting data is usually easier, but if you see "wide character in print", then you know you're messing up the encoding somewhere. That warning means "hey, you're trying to leak Perl characters to the outside world and that doesn't make any sense". Your program appears to work (because the other end usually handles the raw Perl characters correctly), but it is very broken and could stop working at any moment. Fix it with an explicit Encode::encode!

The second problem is UTF-8 encoded source code. Unless you say use utf8 at the top of each file, Perl will not assume that your source code is UTF-8. This means that each time you say something like my $var = 'ほげ', you're injecting garbage into your program that will totally break everything horribly. You don't have to "use utf8", but if you don't, you must not use any non-ASCII characters in your program.

The third problem is how Perl handles The Past. A long time ago, there was no such thing as Unicode, and Perl assumed that everything was Latin-1 text or binary. So when data comes into your program and you start treating it as text, Perl treats each octet as a Latin-1 character. That's why, when we asked for the length of "文字化け", we got 12. Perl assumed that we were operating on the Latin-1 string "æå­åã" (which is 12 characters, some of which are non-printing).

This is called an "implicit upgrade", and it's a perfectly reasonable thing to do, but it's not what you want if your text is not Latin-1. That's why it's critical to explicitly decode input: if you don't do it, Perl will, and it might do it wrong.

People run into trouble where half their data is a proper character string, and some is still binary. Perl will interpret the part that's still binary as though it's Latin-1 text and then combine it with the correct character data. This will make it look like handling your characters correctly broke your program, but in reality, you just haven't fixed it enough.

Here's an example: you have a program that reads a UTF-8-encoded text file, you tack on a Unicode PILE OF POO to each line, and you print it out. You write it like:

while(<>){
    chomp;
    say "$_ 💩";
}

And then run on some UTF-8 encoded data, like:

perl poo.pl input-data.txt

It prints the UTF-8 data with a poo at the end of each line. Perfect, my program works!

But nope, you're just doing binary concatenation. You're reading octets from the file, removing a \n with chomp, and then tacking on the bytes in the UTF-8 representation of the PILE OF POO character. When you revise your program to decode the data from the file and encode the output, you'll notice that you get garbage ("ð©") instead of the poo. This will lead you to believe that decoding the input file is the wrong thing to do. It's not.

The problem is that the poo is being implicitly upgraded as latin-1. If you use utf8 to make the literal text instead of binary, then it will work again!

(That's the number one problem I see when helping people with Unicode. They did part right and that broke their program. That's what's sad about undefined results: you can have a working program for a long time, but when you start to repair it, it breaks. Don't worry; if you are adding encode/decode statements to your program and it breaks, it just means you have more work to do. Next time, when you design with Unicode in mind from the beginning, it will be much easier!)

That's really all you need to know about Perl and Unicode. If you tell Perl what your data is, it has the best Unicode support among all popular programming languages. If you assume it will magically know what sort of text you are feeding it, though, then you're going to trash your data irrevocably. Just because your program works today on your UTF-8 terminal doesn't mean it will work tomorrow on a UTF-16 encoded file. So make it safe now, and save yourself the headache of trashing your users' data!

The easy part of handling Unicode is encoding output and decoding input. The hard part is finding all your input and output, and determining which encoding it is. But that's why you get the big bucks :)


𝙎𝙞𝙢𝙥𝙡𝙚𝙨𝙩 : 𝟕 𝘿𝙞𝙨𝙘𝙧𝙚𝙩𝙚 𝙍𝙚𝙘𝙤𝙢𝙢𝙚𝙣𝙙𝙖𝙩𝙞𝙤𝙣𝙨

  1. Set your PERL_UNICODE envariable to AS. This makes all Perl scripts decode @ARGV as UTF‑8 strings, and sets the encoding of all three of stdin, stdout, and stderr to UTF‑8. Both these are global effects, not lexical ones.

  2. At the top of your source file (program, module, library, dohickey), prominently assert that you are running perl version 5.12 or better via:

    use v5.12;  # minimal for unicode string feature
    use v5.14;  # optimal for unicode string feature
    
  3. Enable warnings, since the previous declaration only enables strictures and features, not warnings. I also suggest promoting Unicode warnings into exceptions, so use both these lines, not just one of them. Note however that under v5.14, the utf8 warning class comprises three other subwarnings which can all be separately enabled: nonchar, surrogate, and non_unicode. These you may wish to exert greater control over.

    use warnings;
    use warnings qw( FATAL utf8 );
    
  4. Declare that this source unit is encoded as UTF‑8. Although once upon a time this pragma did other things, it now serves this one singular purpose alone and no other:

    use utf8;
    
  5. Declare that anything that opens a filehandle within this lexical scope but not elsewhere is to assume that that stream is encoded in UTF‑8 unless you tell it otherwise. That way you do not affect other module’s or other program’s code.

    use open qw( :encoding(UTF-8) :std );
    
  6. Enable named characters via \N{CHARNAME}.

    use charnames qw( :full :short );
    
  7. If you have a DATA handle, you must explicitly set its encoding. If you want this to be UTF‑8, then say:

    binmode(DATA, ":encoding(UTF-8)");
    

There is of course no end of other matters with which you may eventually find yourself concerned, but these will suffice to approximate the state goal to “make everything just work with UTF‑8”, albeit for a somewhat weakened sense of those terms.

One other pragma, although it is not Unicode related, is:

      use autodie;

It is strongly recommended.

🌴 🐪🐫🐪 🌞 𝕲𝖔 𝕿𝖍𝖔𝖚 𝖆𝖓𝖉 𝕯𝖔 𝕷𝖎𝖐𝖊𝖜𝖎𝖘𝖊 🌞 🐪🐫🐪 🐁


🎁 🐪 𝕭𝖔𝖎𝖑𝖊𝖗⸗𝖕𝖑𝖆𝖙𝖊 𝖋𝖔𝖗 𝖀𝖓𝖎𝖈𝖔𝖉𝖊⸗𝕬𝖜𝖆𝖗𝖊 𝕮𝖔𝖉𝖊 🐪 🎁


My own boilerplate these days tends to look like this:

use 5.014;

use utf8;
use strict;
use autodie;
use warnings; 
use warnings    qw< FATAL  utf8     >;
use open        qw< :std  :utf8     >;
use charnames   qw< :full >;
use feature     qw< unicode_strings >;

use File::Basename      qw< basename >;
use Carp                qw< carp croak confess cluck >;
use Encode              qw< encode decode >;
use Unicode::Normalize  qw< NFD NFC >;

END { close STDOUT }

if (grep /\P{ASCII}/ => @ARGV) { 
   @ARGV = map { decode("UTF-8", $_) } @ARGV;
}

$0 = basename($0);  # shorter messages
$| = 1;

binmode(DATA, ":utf8");

# give a full stack dump on any untrapped exceptions
local $SIG{__DIE__} = sub {
    confess "Uncaught exception: @_" unless $^S;
};

# now promote run-time warnings into stack-dumped
#   exceptions *unless* we're in an try block, in
#   which case just cluck the stack dump instead
local $SIG{__WARN__} = sub {
    if ($^S) { cluck   "Trapped warning: @_" } 
    else     { confess "Deadly warning: @_"  }
};

while (<>)  {
    chomp;
    $_ = NFD($_);
    ...
} continue {
    say NFC($_);
}

__END__

🎅 𝕹 𝖔 𝕸 𝖆 𝖌 𝖎 𝖈 𝕭 𝖚 𝖑 𝖑 𝖊 𝖙 🎅


Saying that “Perl should [somehow!] enable Unicode by default” doesn’t even start to begin to think about getting around to saying enough to be even marginally useful in some sort of rare and isolated case. Unicode is much much more than just a larger character repertoire; it’s also how those characters all interact in many, many ways.

Even the simple-minded minimal measures that (some) people seem to think they want are guaranteed to miserably break millions of lines of code, code that has no chance to “upgrade” to your spiffy new Brave New World modernity.

It is way way way more complicated than people pretend. I’ve thought about this a huge, whole lot over the past few years. I would love to be shown that I am wrong. But I don’t think I am. Unicode is fundamentally more complex than the model that you would like to impose on it, and there is complexity here that you can never sweep under the carpet. If you try, you’ll break either your own code or somebody else’s. At some point, you simply have to break down and learn what Unicode is about. You cannot pretend it is something it is not.

🐪 goes out of its way to make Unicode easy, far more than anything else I’ve ever used. If you think this is bad, try something else for a while. Then come back to 🐪: either you will have returned to a better world, or else you will bring knowledge of the same with you so that we can make use of your new knowledge to make 🐪 better at these things.


💡 𝕴𝖉𝖊𝖆𝖘 𝖋𝖔𝖗 𝖆 𝖀𝖓𝖎𝖈𝖔𝖉𝖊 ⸗ 𝕬𝖜𝖆𝖗𝖊 🐪 𝕷𝖆𝖚𝖓𝖉𝖗𝖞 𝕷𝖎𝖘𝖙 💡


At a minimum, here are some things that would appear to be required for 🐪 to “enable Unicode by default”, as you put it:

  1. All 🐪 source code should be in UTF-8 by default. You can get that with use utf8 or export PERL5OPTS=-Mutf8.

  2. The 🐪 DATA handle should be UTF-8. You will have to do this on a per-package basis, as in binmode(DATA, ":encoding(UTF-8)").

  3. Program arguments to 🐪 scripts should be understood to be UTF-8 by default. export PERL_UNICODE=A, or perl -CA, or export PERL5OPTS=-CA.

  4. The standard input, output, and error streams should default to UTF-8. export PERL_UNICODE=S for all of them, or I, O, and/or E for just some of them. This is like perl -CS.

  5. Any other handles opened by 🐪 should be considered UTF-8 unless declared otherwise; export PERL_UNICODE=D or with i and o for particular ones of these; export PERL5OPTS=-CD would work. That makes -CSAD for all of them.

  6. Cover both bases plus all the streams you open with export PERL5OPTS=-Mopen=:utf8,:std. See uniquote.

  7. You don’t want to miss UTF-8 encoding errors. Try export PERL5OPTS=-Mwarnings=FATAL,utf8. And make sure your input streams are always binmoded to :encoding(UTF-8), not just to :utf8.

  8. Code points between 128–255 should be understood by 🐪 to be the corresponding Unicode code points, not just unpropertied binary values. use feature "unicode_strings" or export PERL5OPTS=-Mfeature=unicode_strings. That will make uc("\xDF") eq "SS" and "\xE9" =~ /\w/. A simple export PERL5OPTS=-Mv5.12 or better will also get that.

  9. Named Unicode characters are not by default enabled, so add export PERL5OPTS=-Mcharnames=:full,:short,latin,greek or some such. See uninames and tcgrep.

  10. You almost always need access to the functions from the standard Unicode::Normalize module various types of decompositions. export PERL5OPTS=-MUnicode::Normalize=NFD,NFKD,NFC,NFKD, and then always run incoming stuff through NFD and outbound stuff from NFC. There’s no I/O layer for these yet that I’m aware of, but see nfc, nfd, nfkd, and nfkc.

  11. String comparisons in 🐪 using eq, ne, lc, cmp, sort, &c&cc are always wrong. So instead of @a = sort @b, you need @a = Unicode::Collate->new->sort(@b). Might as well add that to your export PERL5OPTS=-MUnicode::Collate. You can cache the key for binary comparisons.

  12. 🐪 built-ins like printf and write do the wrong thing with Unicode data. You need to use the Unicode::GCString module for the former, and both that and also the Unicode::LineBreak module as well for the latter. See uwc and unifmt.

  13. If you want them to count as integers, then you are going to have to run your \d+ captures through the Unicode::UCD::num function because 🐪’s built-in atoi(3) isn’t currently clever enough.

  14. You are going to have filesystem issues on 👽 filesystems. Some filesystems silently enforce a conversion to NFC; others silently enforce a conversion to NFD. And others do something else still. Some even ignore the matter altogether, which leads to even greater problems. So you have to do your own NFC/NFD handling to keep sane.

  15. All your 🐪 code involving a-z or A-Z and such MUST BE CHANGED, including m//, s///, and tr///. It’s should stand out as a screaming red flag that your code is broken. But it is not clear how it must change. Getting the right properties, and understanding their casefolds, is harder than you might think. I use unichars and uniprops every single day.

  16. Code that uses \p{Lu} is almost as wrong as code that uses [A-Za-z]. You need to use \p{Upper} instead, and know the reason why. Yes, \p{Lowercase} and \p{Lower} are different from \p{Ll} and \p{Lowercase_Letter}.

  17. Code that uses [a-zA-Z] is even worse. And it can’t use \pL or \p{Letter}; it needs to use \p{Alphabetic}. Not all alphabetics are letters, you know!

  18. If you are looking for 🐪 variables with /[\$\@\%]\w+/, then you have a problem. You need to look for /[\$\@\%]\p{IDS}\p{IDC}*/, and even that isn’t thinking about the punctuation variables or package variables.

  19. If you are checking for whitespace, then you should choose between \h and \v, depending. And you should never use \s, since it DOES NOT MEAN [\h\v], contrary to popular belief.

  20. If you are using \n for a line boundary, or even \r\n, then you are doing it wrong. You have to use \R, which is not the same!

  21. If you don’t know when and whether to call Unicode::Stringprep, then you had better learn.

  22. Case-insensitive comparisons need to check for whether two things are the same letters no matter their diacritics and such. The easiest way to do that is with the standard Unicode::Collate module. Unicode::Collate->new(level => 1)->cmp($a, $b). There are also eq methods and such, and you should probably learn about the match and substr methods, too. These are have distinct advantages over the 🐪 built-ins.

  23. Sometimes that’s still not enough, and you need the Unicode::Collate::Locale module instead, as in Unicode::Collate::Locale->new(locale => "de__phonebook", level => 1)->cmp($a, $b) instead. Consider that Unicode::Collate::->new(level => 1)->eq("d", "ð") is true, but Unicode::Collate::Locale->new(locale=>"is",level => 1)->eq("d", " ð") is false. Similarly, "ae" and "æ" are eq if you don’t use locales, or if you use the English one, but they are different in the Icelandic locale. Now what? It’s tough, I tell you. You can play with ucsort to test some of these things out.

  24. Consider how to match the pattern CVCV (consonsant, vowel, consonant, vowel) in the string “niño”. Its NFD form — which you had darned well better have remembered to put it in — becomes “nin\x{303}o”. Now what are you going to do? Even pretending that a vowel is [aeiou] (which is wrong, by the way), you won’t be able to do something like (?=[aeiou])\X) either, because even in NFD a code point like ‘ø’ does not decompose! However, it will test equal to an ‘o’ using the UCA comparison I just showed you. You can’t rely on NFD, you have to rely on UCA.


💩 𝔸 𝕤 𝕤 𝕦 𝕞 𝕖 𝔹 𝕣 𝕠 𝕜 𝕖 𝕟 𝕟 𝕖 𝕤 𝕤 💩


And that’s not all. There are a million broken assumptions that people make about Unicode. Until they understand these things, their 🐪 code will be broken.

  1. Code that assumes it can open a text file without specifying the encoding is broken.

  2. Code that assumes the default encoding is some sort of native platform encoding is broken.

  3. Code that assumes that web pages in Japanese or Chinese take up less space in UTF‑16 than in UTF‑8 is wrong.

  4. Code that assumes Perl uses UTF‑8 internally is wrong.

  5. Code that assumes that encoding errors will always raise an exception is wrong.

  6. Code that assumes Perl code points are limited to 0x10_FFFF is wrong.

  7. Code that assumes you can set $/ to something that will work with any valid line separator is wrong.

  8. Code that assumes roundtrip equality on casefolding, like lc(uc($s)) eq $s or uc(lc($s)) eq $s, is completely broken and wrong. Consider that the uc("σ") and uc("ς") are both "Σ", but lc("Σ") cannot possibly return both of those.

  9. Code that assumes every lowercase code point has a distinct uppercase one, or vice versa, is broken. For example, "ª" is a lowercase letter with no uppercase; whereas both "ᵃ" and "ᴬ" are letters, but they are not lowercase letters; however, they are both lowercase code points without corresponding uppercase versions. Got that? They are not \p{Lowercase_Letter}, despite being both \p{Letter} and \p{Lowercase}.

  10. Code that assumes changing the case doesn’t change the length of the string is broken.

  11. Code that assumes there are only two cases is broken. There’s also titlecase.

  12. Code that assumes only letters have case is broken. Beyond just letters, it turns out that numbers, symbols, and even marks have case. In fact, changing the case can even make something change its main general category, like a \p{Mark} turning into a \p{Letter}. It can also make it switch from one script to another.

  13. Code that assumes that case is never locale-dependent is broken.

  14. Code that assumes Unicode gives a fig about POSIX locales is broken.

  15. Code that assumes you can remove diacritics to get at base ASCII letters is evil, still, broken, brain-damaged, wrong, and justification for capital punishment.

  16. Code that assumes that diacritics \p{Diacritic} and marks \p{Mark} are the same thing is broken.

  17. Code that assumes \p{GC=Dash_Punctuation} covers as much as \p{Dash} is broken.

  18. Code that assumes dash, hyphens, and minuses are the same thing as each other, or that there is only one of each, is broken and wrong.

  19. Code that assumes every code point takes up no more than one print column is broken.

  20. Code that assumes that all \p{Mark} characters take up zero print columns is broken.

  21. Code that assumes that characters which look alike are alike is broken.

  22. Code that assumes that characters which do not look alike are not alike is broken.

  23. Code that assumes there is a limit to the number of code points in a row that just one \X can match is wrong.

  24. Code that assumes \X can never start with a \p{Mark} character is wrong.

  25. Code that assumes that \X can never hold two non-\p{Mark} characters is wrong.

  26. Code that assumes that it cannot use "\x{FFFF}" is wrong.

  27. Code that assumes a non-BMP code point that requires two UTF-16 (surrogate) code units will encode to two separate UTF-8 characters, one per code unit, is wrong. It doesn’t: it encodes to single code point.

  28. Code that transcodes from UTF‐16 or UTF‐32 with leading BOMs into UTF‐8 is broken if it puts a BOM at the start of the resulting UTF-8. This is so stupid the engineer should have their eyelids removed.

  29. Code that assumes the CESU-8 is a valid UTF encoding is wrong. Likewise, code that thinks encoding U+0000 as "\xC0\x80" is UTF-8 is broken and wrong. These guys also deserve the eyelid treatment.

  30. Code that assumes characters like > always points to the right and < always points to the left are wrong — because they in fact do not.

  31. Code that assumes if you first output character X and then character Y, that those will show up as XY is wrong. Sometimes they don’t.

  32. Code that assumes that ASCII is good enough for writing English properly is stupid, shortsighted, illiterate, broken, evil, and wrong. Off with their heads! If that seems too extreme, we can compromise: henceforth they may type only with their big toe from one foot. (The rest will be duct taped.)

  33. Code that assumes that all \p{Math} code points are visible characters is wrong.

  34. Code that assumes \w contains only letters, digits, and underscores is wrong.

  35. Code that assumes that ^ and ~ are punctuation marks is wrong.

  36. Code that assumes that ü has an umlaut is wrong.

  37. Code that believes things like contain any letters in them is wrong.

  38. Code that believes \p{InLatin} is the same as \p{Latin} is heinously broken.

  39. Code that believe that \p{InLatin} is almost ever useful is almost certainly wrong.

  40. Code that believes that given $FIRST_LETTER as the first letter in some alphabet and $LAST_LETTER as the last letter in that same alphabet, that [${FIRST_LETTER}-${LAST_LETTER}] has any meaning whatsoever is almost always complete broken and wrong and meaningless.

  41. Code that believes someone’s name can only contain certain characters is stupid, offensive, and wrong.

  42. Code that tries to reduce Unicode to ASCII is not merely wrong, its perpetrator should never be allowed to work in programming again. Period. I’m not even positive they should even be allowed to see again, since it obviously hasn’t done them much good so far.

  43. Code that believes there’s some way to pretend textfile encodings don’t exist is broken and dangerous. Might as well poke the other eye out, too.

  44. Code that converts unknown characters to ? is broken, stupid, braindead, and runs contrary to the standard recommendation, which says NOT TO DO THAT! RTFM for why not.

  45. Code that believes it can reliably guess the encoding of an unmarked textfile is guilty of a fatal mélange of hubris and naïveté that only a lightning bolt from Zeus will fix.

  46. Code that believes you can use 🐪 printf widths to pad and justify Unicode data is broken and wrong.

  47. Code that believes once you successfully create a file by a given name, that when you run ls or readdir on its enclosing directory, you’ll actually find that file with the name you created it under is buggy, broken, and wrong. Stop being surprised by this!

  48. Code that believes UTF-16 is a fixed-width encoding is stupid, broken, and wrong. Revoke their programming licence.

  49. Code that treats code points from one plane one whit differently than those from any other plane is ipso facto broken and wrong. Go back to school.

  50. Code that believes that stuff like /s/i can only match "S" or "s" is broken and wrong. You’d be surprised.

  51. Code that uses \PM\pM* to find grapheme clusters instead of using \X is broken and wrong.

  52. People who want to go back to the ASCII world should be whole-heartedly encouraged to do so, and in honor of their glorious upgrade they should be provided gratis with a pre-electric manual typewriter for all their data-entry needs. Messages sent to them should be sent via an ᴀʟʟᴄᴀᴘs telegraph at 40 characters per line and hand-delivered by a courier. STOP.


😱 𝕾 𝖀 𝕸 𝕸 𝕬 𝕽 𝖄 😱


I don’t know how much more “default Unicode in 🐪” you can get than what I’ve written. Well, yes I do: you should be using Unicode::Collate and Unicode::LineBreak, too. And probably more.

As you see, there are far too many Unicode things that you really do have to worry about for there to ever exist any such thing as “default to Unicode”.

What you’re going to discover, just as we did back in 🐪 5.8, that it is simply impossible to impose all these things on code that hasn’t been designed right from the beginning to account for them. Your well-meaning selfishness just broke the entire world.

And even once you do, there are still critical issues that require a great deal of thought to get right. There is no switch you can flip. Nothing but brain, and I mean real brain, will suffice here. There’s a heck of a lot of stuff you have to learn. Modulo the retreat to the manual typewriter, you simply cannot hope to sneak by in ignorance. This is the 21ˢᵗ century, and you cannot wish Unicode away by willful ignorance.

You have to learn it. Period. It will never be so easy that “everything just works,” because that will guarantee that a lot of things don’t work — which invalidates the assumption that there can ever be a way to “make it all work.”

You may be able to get a few reasonable defaults for a very few and very limited operations, but not without thinking about things a whole lot more than I think you have.

As just one example, canonical ordering is going to cause some real headaches. 😭"\x{F5}" ‘õ’, "o\x{303}" ‘õ’, "o\x{303}\x{304}" ‘ȭ’, and "o\x{304}\x{303}" ‘ō̃’ should all match ‘õ’, but how in the world are you going to do that? This is harder than it looks, but it’s something you need to account for. 💣

If there’s one thing I know about Perl, it is what its Unicode bits do and do not do, and this thing I promise you: “ ̲ᴛ̲ʜ̲ᴇ̲ʀ̲ᴇ̲ ̲ɪ̲s̲ ̲ɴ̲ᴏ̲ ̲U̲ɴ̲ɪ̲ᴄ̲ᴏ̲ᴅ̲ᴇ̲ ̲ᴍ̲ᴀ̲ɢ̲ɪ̲ᴄ̲ ̲ʙ̲ᴜ̲ʟ̲ʟ̲ᴇ̲ᴛ̲ ̲ ” 😞

You cannot just change some defaults and get smooth sailing. It’s true that I run 🐪 with PERL_UNICODE set to "SA", but that’s all, and even that is mostly for command-line stuff. For real work, I go through all the many steps outlined above, and I do it very, ** very** carefully.


😈 ¡ƨdləɥ ƨᴉɥʇ ədoɥ puɐ ʻλɐp əɔᴉu ɐ əʌɐɥ ʻʞɔnl poo⅁ 😈


We're all in agreement that it is a difficult problem for many reasons, but that's precisely the reason to try to make it easier on everybody.

There is a recent module on CPAN, utf8::all, that attempts to "turn on Unicode. All of it".

As has been pointed out, you can't magically make the entire system (outside programs, external web requests, etc.) use Unicode as well, but we can work together to make sensible tools that make doing common problems easier. That's the reason that we're programmers.

If utf8::all doesn't do something you think it should, let's improve it to make it better. Or let's make additional tools that together can suit people's varying needs as well as possible.

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