Sign up ×
Stack Overflow is a community of 4.7 million programmers, just like you, helping each other. Join them; it only takes a minute:

A JSON string can contain the escape sequence: \u four-hex-digits, which are two octets.

After reading the four hex digits into c1, c2, c3, c4, the JSON Spirit C++ library returns a single character whose value is (hex_to_num (c1) << 12) + (hex_to_num (c2) << 8) + (hex_to_num (c3) << 4) + hex_to_num (c4).

Based on the simplicity of the decoding scheme, and based on having only 2 octets to decode, I conclude that JSON escape sequences support only UCS-2 encoding, which is text from the BMP U+0000 to U+FFFF encoded "as is" using the code point as the 16-bit code unit.

Since UTF-16 and UCS-2 encode valid code points in U+0000 to U+FFFF as single 16-bit code units that are numerically equal to the corresponding code points (wikipedia), one can simply pretend that the decoded UCS-2 character is a UTF-16 character.

The escape character varies from a normal unescaped JSON string, which can contain "any Unicode character except " or \ or control-character"(json spec). Since JSON is a subset of ECMAScript, which is assumed to be UTF-16 (ecma standard), I conclude that JSON supports UTF-16 encoding, which is broader than what the escape sequence provides.

Now having reduced all JSON strings to UTF-16, if one converts them from UTF-16 to UTF-8, my understanding is that it is possible to store the UTF-8 in a std::string on Linux, because during processing one can often ignore that several std::string characters are consumed to represent as long as a 6-byte long UTF-8 sequence.

If all the above assumptions and interpretations are correct, one can safely parse JSON and store it into a std::string on Linux. Can someone please verify?

share|improve this question
Your question is way to long-winded. If your JSON comes as a UTF-8 encoded string, then of course you can traverse it and replace every occurrence of \uXXXX by the corresponding UTF-8 byte sequence. (Don't forget error checking.) – Kerrek SB Dec 1 '11 at 0:32

1 Answer 1

up vote 1 down vote accepted

You are mistaken in several regards:

1) The \u escape values in JSON are UTF-16 code units, not UCS-2 code points, which despite the claims of wikipedia, are not (necessarily) the same as UCS-2 and UTF-16 are not 100% byte compatible (although they are for all characters which existed before UTF-16 was created in the Unicode 2.0 standard)

2) The JSON escape sequence can represent all of UTF-16 by using surrogate pairs of code units.

Your end assertion is still true - you can safely parse JSON and store it in a std::string, but the conversion can't be based on the assumptions you're making (and using std::string to essentially store a bundle of bytes likely isn't what you want anyhow).

share|improve this answer
"and using std::string to essentially store a bundle of bytes likely isn't what you want anyhow" Why not? That's what it's for, after all. std::vector doesn't allow useful features like small string optimization and such, which are good even for UTF-8 or UTF-16 strings. Obviously, the text searching and such is bad for general Unicode use, but std::basic_string still makes for a good data storage object for Unicode-encoded strings – Nicol Bolas Dec 1 '11 at 1:34
Also, Wikipedia pointed out exactly what you said: that they're not 100% byte compatible, and that it only counts codepoints that existed before UTF-16 came out. And no, I didn't just add that ;) It's the OP who misread the Wiki article. – Nicol Bolas Dec 1 '11 at 1:36
I totally missed the surrogate pair thing, which tripped me up thinking there was a two-octet limitation and wondering what that might mean. My UTF-8 parser of JSON can now handle the JSON string escape "\uD834\uDD1E" (the G clef character U+1D11E) by converting four octets of UTF-16 to UTF-8. – maxpolk Dec 2 '11 at 2:09

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.