Encoding issues for UTF8 CSV file when opening Excel and TextEdit

Excel likes Unicode in UTF-16 LE with BOM encoding. Output the correct BOM (FF FE), then convert all your data from UTF-8 to UTF-16 LE.

Windows uses UTF-16 LE internally, so some applications work better with UTF-16 than with UTF-8.

I haven't tried to do that in JS, but there're various scripts on the web to convert UTF-8 to UTF-16. Conversion between UTF variations is pretty easy and takes just a dozen of lines.


I ran into exactly this yesterday. I was developing a button that exports the contents of an HTML table as a CSV download. The functionality of the button itself is almost identical to yours – on click I read the text from the table and create a data URI with the CSV content.

When I tried to open the resulting file in Excel it was clear that the "£" symbol was getting read incorrectly. The 2 byte UTF-8 representation was being processed as ASCII resulting in an unwanted garbage character. Some Googling indicated this was a known issue with Excel.

I tried adding the byte order mark at the start of the string – Excel just interpreted it as ASCII data. I then tried various things to convert the UTF-8 string to ASCII (such as csvData.replace('\u00a3', '\xa3')) but I found that any time the data is coerced to a JavaScript string it will become UTF-8 again. The trick is to convert it to binary and then Base64 encode it without converting back to a string along the way.

I already had CryptoJS in my app (used for HMAC authentication against a REST API) and I was able to use that to create an ASCII encoded byte sequence from the original string then Base64 encode it and create a data URI. This worked and the resulting file when opened in Excel does not display any unwanted characters.

The essential bit of code that does the conversion is:

var csvHeader = 'data:text/csv;charset=iso-8859-1;base64,'
var encodedCsv =  CryptoJS.enc.Latin1.parse(csvData).toString(CryptoJS.enc.Base64)
var dataURI = csvHeader + encodedCsv

Where csvData is your CSV string.

There are probably ways to do the same thing without CryptoJS if you don't want to bring in that library but this at least shows it is possible.


As @jlarson updated with information that Mac was the biggest culprit we might get some further. Office for Mac has, at least 2011 and back, rather poor support for reading Unicode formats when importing files.

Support for UTF-8 seems to be close to non-existent, have read a tiny few comments about it working, whilst the majority say it does not. Unfortunately I do not have any Mac to test on. So again: The files themselves should be OK as UTF-8, but the import halts the process.

Wrote up a quick test in Javascript for exporting percent escaped UTF-16 little and big endian, with- / without BOM etc.

Code should probably be refactored but should be OK for testing. It might work better then UTF-8. Of course this also usually means bigger data transfers as any glyph is two or four bytes.

You can find a fiddle here:

Unicode export sample Fiddle

Note that it does not handle CSV in any particular way. It is mainly meant for pure conversion to data URL having UTF-8, UTF-16 big/little endian and +/- BOM. There is one option in the fiddle to replace commas with tabs, – but believe that would be rather hackish and fragile solution if it works.


Typically use like:

// Initiate
encoder = new DataEnc({
    mime   : 'text/csv',
    charset: 'UTF-16BE',
    bom    : true
});

// Convert data to percent escaped text
encoder.enc(data);

// Get result
var result = encoder.pay();

There is two result properties of the object:

1.) encoder.lead

This is the mime-type, charset etc. for data URL. Built from options passed to initializer, or one can also say .config({ ... new conf ...}).intro() to re-build.

data:[<MIME-type>][;charset=<encoding>][;base64]

You can specify base64, but there is no base64 conversion (at least not this far).

2.) encoder.buf

This is a string with the percent escaped data.

The .pay() function simply return 1.) and 2.) as one.


Main code:


function DataEnc(a) {
    this.config(a);
    this.intro();
}
/*
* http://www.iana.org/assignments/character-sets/character-sets.xhtml
* */
DataEnc._enctype = {
        u8    : ['u8', 'utf8'],
        // RFC-2781, Big endian should be presumed if none given
        u16be : ['u16', 'u16be', 'utf16', 'utf16be', 'ucs2', 'ucs2be'],
        u16le : ['u16le', 'utf16le', 'ucs2le']
};
DataEnc._BOM = {
        'none'     : '',
        'UTF-8'    : '%ef%bb%bf', // Discouraged
        'UTF-16BE' : '%fe%ff',
        'UTF-16LE' : '%ff%fe'
};
DataEnc.prototype = {
    // Basic setup
    config : function(a) {
        var opt = {
            charset: 'u8',
            mime   : 'text/csv',
            base64 : 0,
            bom    : 0
        };
        a = a || {};
        this.charset = typeof a.charset !== 'undefined' ?
                        a.charset : opt.charset;
        this.base64 = typeof a.base64 !== 'undefined' ? a.base64 : opt.base64;
        this.mime = typeof a.mime !== 'undefined' ? a.mime : opt.mime;
        this.bom = typeof a.bom !== 'undefined' ? a.bom : opt.bom;

        this.enc = this.utf8;
        this.buf = '';
        this.lead = '';
        return this;
    },
    // Create lead based on config
    // data:[<MIME-type>][;charset=<encoding>][;base64],<data>
    intro : function() {
        var
            g = [],
            c = this.charset || '',
            b = 'none'
        ;
        if (this.mime && this.mime !== '')
            g.push(this.mime);
        if (c !== '') {
            c = c.replace(/[-\s]/g, '').toLowerCase();
            if (DataEnc._enctype.u8.indexOf(c) > -1) {
                c = 'UTF-8';
                if (this.bom)
                    b = c;
                this.enc = this.utf8;
            } else if (DataEnc._enctype.u16be.indexOf(c) > -1) {
                c = 'UTF-16BE';
                if (this.bom)
                    b = c;
                this.enc = this.utf16be;
            } else if (DataEnc._enctype.u16le.indexOf(c) > -1) {
                c = 'UTF-16LE';
                if (this.bom)
                    b = c;
                this.enc = this.utf16le;
            } else {
                if (c === 'copy')
                    c = '';
                this.enc = this.copy;
            }
        }
        if (c !== '')
            g.push('charset=' + c);
        if (this.base64)
            g.push('base64');
        this.lead = 'data:' + g.join(';') + ',' + DataEnc._BOM[b];
        return this;
    },
    // Deliver
    pay : function() {
        return this.lead + this.buf;
    },
    // UTF-16BE
    utf16be : function(t) { // U+0500 => %05%00
        var i, c, buf = [];
        for (i = 0; i < t.length; ++i) {
            if ((c = t.charCodeAt(i)) > 0xff) {
                buf.push(('00' + (c >> 0x08).toString(16)).substr(-2));
                buf.push(('00' + (c  & 0xff).toString(16)).substr(-2));
            } else {
                buf.push('00');
                buf.push(('00' + (c  & 0xff).toString(16)).substr(-2));
            }
        }
        this.buf += '%' + buf.join('%');
        // Note the hex array is returned, not string with '%'
        // Might be useful if one want to loop over the data.
        return buf;
    },
    // UTF-16LE
    utf16le : function(t) { // U+0500 => %00%05
        var i, c, buf = [];
        for (i = 0; i < t.length; ++i) {
            if ((c = t.charCodeAt(i)) > 0xff) {
                buf.push(('00' + (c  & 0xff).toString(16)).substr(-2));
                buf.push(('00' + (c >> 0x08).toString(16)).substr(-2));
            } else {
                buf.push(('00' + (c  & 0xff).toString(16)).substr(-2));
                buf.push('00');
            }
        }
        this.buf += '%' + buf.join('%');
        // Note the hex array is returned, not string with '%'
        // Might be useful if one want to loop over the data.
        return buf;
    },
    // UTF-8
    utf8 : function(t) {
        this.buf += encodeURIComponent(t);
        return this;
    },
    // Direct copy
    copy : function(t) {
        this.buf += t;
        return this;
    }
};

Previous answer:


I do not have any setup to replicate yours, but if your case is the same as @jlarson then the resulting file should be correct.

This answer became somewhat long, (fun topic you say?), but discuss various aspects around the question, what is (likely) happening, and how to actually check what is going on in various ways.

TL;DR:

The text is likely imported as ISO-8859-1, Windows-1252, or the like, and not as UTF-8. Force application to read file as UTF-8 by using import or other means.


PS: The UniSearcher is a nice tool to have available on this journey.

The long way around

The "easiest" way to be 100% sure what we are looking at is to use a hex-editor on the result. Alternatively use hexdump, xxd or the like from command line to view the file. In this case the byte sequence should be that of UTF-8 as delivered from the script.

As an example if we take the script of jlarson it takes the data Array:

data = ['name', 'city', 'state'],
       ['\u0500\u05E1\u0E01\u1054', 'seattle', 'washington']

This one is merged into the string:

 name,city,state<newline>
 \u0500\u05E1\u0E01\u1054,seattle,washington<newline>

which translates by Unicode to:

 name,city,state<newline>
 Ԁסกၔ,seattle,washington<newline>

As UTF-8 uses ASCII as base (bytes with highest bit not set are the same as in ASCII) the only special sequence in the test data is "Ԁסกၔ" which in turn, is:

Code-point  Glyph      UTF-8
----------------------------
    U+0500    Ԁ        d4 80
    U+05E1    ס        d7 a1
    U+0E01    ก     e0 b8 81
    U+1054    ၔ     e1 81 94

Looking at the hex-dump of the downloaded file:

0000000: 6e61 6d65 2c63 6974 792c 7374 6174 650a  name,city,state.
0000010: d480 d7a1 e0b8 81e1 8194 2c73 6561 7474  ..........,seatt
0000020: 6c65 2c77 6173 6869 6e67 746f 6e0a       le,washington.

On second line we find d480 d7a1 e0b8 81e1 8194 which match up with the above:

0000010: d480  d7a1  e0b8 81  e1 8194 2c73 6561 7474  ..........,seatt
         |   | |   | |     |  |     |  | |  | |  | |
         +-+-+ +-+-+ +--+--+  +--+--+  | |  | |  | |
           |     |      |        |     | |  | |  | |
           Ԁ     ס      ก        ၔ     , s  e a  t t

None of the other characters is mangled either.

Do similar tests if you want. The result should be the similar.


By sample provided —, â€, “

We can also have a look at the sample provided in the question. It is likely to assume that the text is represented in Excel / TextEdit by code-page 1252.

To quote Wikipedia on Windows-1252:

Windows-1252 or CP-1252 is a character encoding of the Latin alphabet, used by default in the legacy components of Microsoft Windows in English and some other Western languages. It is one version within the group of Windows code pages. In LaTeX packages, it is referred to as "ansinew".

Retrieving the original bytes

To translate it back into it's original form we can look at the code page layout, from which we get:

Character:   <â>  <€>  <”>  <,>  < >  <â>  <€>  < >  <,>  < >  <â>  <€>  <œ>
U.Hex    :    e2 20ac 201d   2c   20   e2 20ac   9d   2c   20   e2 20ac  153
T.Hex    :    e2   80   94   2c   20   e2   80   9d*  2c   20   e2   80   9c
  • U is short for Unicode
  • T is short for Translated

For example:

â => Unicode 0xe2   => CP-1252 0xe2
” => Unicode 0x201d => CP-1252 0x94
€ => Unicode 0x20ac => CP-1252 0x80

Special cases like 9d does not have a corresponding code-point in CP-1252, these we simply copy directly.

Note: If one look at mangled string by copying the text to a file and doing a hex-dump, save the file with for example UTF-16 encoding to get the Unicode values as represented in the table. E.g. in Vim:

set fenc=utf-16
# Or
set fenc=ucs-2

Bytes to UTF-8

We then combine the result, the T.Hex line, into UTF-8. In UTF-8 sequences the bytes are represented by a leading byte telling us how many subsequent bytes make the glyph. For example if a byte has the binary value 110x xxxx we know that this byte and the next represent one code-point. A total of two. 1110 xxxx tells us it is three and so on. ASCII values does not have the high bit set, as such any byte matching 0xxx xxxx is a standalone. A total of one byte.

0xe2 = 1110 0010bin => 3 bytes => 0xe28094 (em-dash)  —
0x2c = 0010 1100bin => 1 byte  => 0x2c     (comma)    ,
0x2c = 0010 0000bin => 1 byte  => 0x20     (space)   
0xe2 = 1110 0010bin => 3 bytes => 0xe2809d (right-dq) ”
0x2c = 0010 1100bin => 1 byte  => 0x2c     (comma)    ,
0x2c = 0010 0000bin => 1 byte  => 0x20     (space)   
0xe2 = 1110 0010bin => 3 bytes => 0xe2809c (left-dq)  “

Conclusion; The original UTF-8 string was:

—, ”, “

Mangling it back

We can also do the reverse. The original string as bytes:

UTF-8: e2 80 94 2c 20 e2 80 9d 2c 20 e2 80 9c

Corresponding values in cp-1252:

e2 => â
80 => €
94 => ”
2c => ,
20 => <space>
...

and so on, result:

—, â€, “

Importing to MS Excel

In other words: The issue at hand could be how to import UTF-8 text files into MS Excel, and some other applications. In Excel this can be done in various ways.

  • Method one:

Do not save the file with an extension recognized by the application, like .csv, or .txt, but omit it completely or make something up.

As an example save the file as "testfile", with no extension. Then in Excel open the file, confirm that we actually want to open this file, and voilà we get served with the encoding option. Select UTF-8, and file should be correctly read.

  • Method two:

Use import data instead of open file. Something like:

Data -> Import External Data -> Import Data

Select encoding and proceed.

Check that Excel and selected font actually supports the glyph

We can also test the font support for the Unicode characters by using the, sometimes, friendlier clipboard. For example, copy text from this page into Excel:

  • page with code points U+0E00 to U+0EFF

If support for the code points exist, the text should render fine.


Linux

On Linux, which is primarily UTF-8 in userland this should not be an issue. Using Libre Office Calc, Vim, etc. show the files correctly rendered.


Why it works (or should)

encodeURI from the spec states, (also read sec-15.1.3):

The encodeURI function computes a new version of a URI in which each instance of certain characters is replaced by one, two, three, or four escape sequences representing the UTF-8 encoding of the character.

We can simply test this in our console by, for example saying:

>> encodeURI('Ԁסกၔ,seattle,washington')
<< "%D4%80%D7%A1%E0%B8%81%E1%81%94,seattle,washington"

As we register the escape sequences are equal to the ones in the hex dump above:

%D4%80%D7%A1%E0%B8%81%E1%81%94 (encodeURI in log)
 d4 80 d7 a1 e0 b8 81 e1 81 94 (hex-dump of file)

or, testing a 4-byte code:

>> encodeURI('󱀁')
<< "%F3%B1%80%81"

If this is does not comply

If nothing of this apply it could help if you added

  1. Sample of expected input vs mangled output, (copy paste).
  2. Sample hex-dump of original data vs result file.