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Having a variable length encoding is indirectly forbidden in the standard.

So I have several questions:

How is the following part of the standard handled? Wide-character sequences

A wide-character sequence is an array object (8.3.4) A that can be declared as T A[N], where T is type wchar_t (3.9.1), optionally qualified by any combination of const or volatile. The initial elements of the array have defined contents up to and including an element determined by some predicate. A character sequence can be designated by a pointer value S that designates its first element.

The length of an NTWCS is the number of elements that precede the terminating null wide character. An empty NTWCS has a length of zero.



  • How is operator[] implemented and what does it return?
    • standard: If pos < size(), returns data()[pos]. Otherwise, if pos == size(), the const version returns charT(). Otherwise, the behavior is undefined.
  • Does size() return the number of elements or the length of the string?
    • standard: Returns: a count of the number of char-like objects currently in the string.
  • How does resize() work?
    • unrelated to standard, just what does it do
  • How are the position in insert(), erase() and others handled?


  • Pretty much everything in here. How is the variable encoding handled?


  • getwchar() obviously can't return a whole platform-character, so how does this work?

Plus all the rest of the character function (the theme is the same).

Edit: I will be opening a bounty to get some confirmation. I want to get some clear answers or at least a clearer distribution of votes.

Edit: This is starting to get pointless. This is full of totally conflicting answers. Some of you talk about external encodings (I don't care about those, UTF-8 encoded will still be stored as UTF-16 once read into the string, the same for output), the rest simply contradicts each other. :-/

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Perhaps you could elaborate on what you mean by the "fact" that their UTF-16 support is a variable length encoding (eg: an example where a string is encoded into more than 2 bytes per character). As far as I am aware, UTF-16 is treated as a fixed-length encoding in MS docs/code, but I'm not an expert, so an example would probably help. –  Nick Oct 26 '10 at 16:03
A variable length encoding is by no means forbidden. wstring does keep track of the number of elements, as you said, which it must know for allocation purposes, and is completely independent of encoding. But elements != number of codepoints != number of glyphs, it's up to you to keep track of other measures of length. –  Ben Voigt Oct 26 '10 at 16:44
@Nick This is interesting, where did you read that? –  Let_Me_Be Oct 26 '10 at 17:27
@Let_Me_Be: Maybe you are mixing concepts. Where in the standard have you seen that the *length of a wchar_t sequence is defined as the number of elements preceeding the '\0'? Both string and wstring support strings containing null characters. –  David Rodríguez - dribeas Oct 26 '10 at 18:15
I think this question is sorta confusing the issue (perhaps a title/tag edit is in order). The STL's handling of wchar_t strings doesn't handle variable length encodings for UTF-16, it ignores them (as other people have said). However, this is not a Microsoft issue, or a "problem" with the implementation of STL which they distribute: STL (and C++ for that matter) doesn't have any handling for variable length encoded strings (UTF-16 or otherwise). Are you asking what Windows API's are available to do this, or is this just about STL? –  Nick Oct 27 '10 at 17:30

5 Answers 5

up vote 14 down vote accepted

Here's how Microsoft's STL implementation handles the variable-length encoding:

basic_string<wchar_t>::operator[])( can return a low or a high surrogate, in isolation.

basic_string<wchar_t>::size() returns the number of wchar_t objects. A surrogate pair (one Unicode character) uses two wchar_t's and therefore adds two to the size.

basic_string<wchar_t>::resize() can truncate a string in the middle of a surrogate pair.

basic_string<wchar_t>::insert() can insert in the middle of a surrogate pair.

basic_string<wchar_t>::erase() can erase either half of a surrogate pair.

In general, the pattern should be clear: the STL does not assume that a std::wstring is in UTF-16, nor enforce that it remains UTF-16.

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How do you determine the string length if size() returns number of wchar_t objects? How do you safely insert(), erase(), etc? The "C" part of the standard library isn't supported in Windows for wide characters? –  Let_Me_Be Oct 27 '10 at 10:20
@Let_Me_Be: If you consider the presence of combining marks in Unicode, you can only realize that the whole of Unicode is actually a variable-length encoding. What would you expect to happen if you have a string with the Unicode codepoints U+0041 U+0308 (LATIN CAPITAL LETTER A and COMBINING DIARESIS) and you try to insert the codepoint U+0030 (DIGIT ZERO) between them? Allog these codepoints are representable with a single element in UTF-16 and UCS-4. –  Bart van Ingen Schenau Oct 29 '10 at 11:25
@Let_Me_Be: No, I am talking about internal coding. Even if your internal coding is UCS-4, it remains a variable-length coding due to the presence of combining marks in Unicode. There is just no way to encode every character (as a non-programmer would define such a thing) in a single codepoint. –  Bart van Ingen Schenau Oct 29 '10 at 13:56
@Let_Me_Be: Then please enlighten me. What would the internal representation be for the character that is externally visible as an A with a line above it (LATIN CAPITAL A with COMBINING OVERLINE)? –  Bart van Ingen Schenau Oct 29 '10 at 14:11
@Let_Me_Be: And why would that make a difference for a user of a text-manipulation program? To the user it appears as a single glyph, so the program should treat it as a single character. –  Bart van Ingen Schenau Oct 29 '10 at 14:29

STL deals with strings as simply a wrapper for an array of characters therefore size() or length() on an STL string will tell you how many char or wchar_t elements it contains and not necessarily the number of printable characters it would be in a string.

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So, they have implemented basic_string in such way that it can handle variable encoding (I will check for the collision I mentioned and report back) and ignore raw strings? –  Let_Me_Be Oct 26 '10 at 17:18
The absolutely correct OO way to handle variable-character-length strings would be to have a class represent a variable-length character and then have a vector of them. That would be a horribly inefficient implementation though. A better implementation is to store the array of elements in its raw form and then if you need to have another array of offsets to each character so you can find the nth character in constant time once it has been parsed through once. You can make this a wrapper, with state, including a state that the string is actually one-element-per-character throughout. –  CashCow Oct 27 '10 at 8:41
I'm not really interested in the correct way. For me the correct way is to use variable encoding on input and output only. What I'm asking is how Microsoft handles the fact, that they actually have a variable length encoding for wchar_t and consequently for wstring. –  Let_Me_Be Oct 27 '10 at 10:22

Assuming that you're talking about the wstring type, there would be no handling of the encoding - it just deals with wchar_t elements without knowing anything about the encoding. It's just a sequence of wchar_t's. You'll need to deal with encoding issues using functionality of other functions.

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AFAIK this is right. Not sure whether UTF-16 offers multiple ways to encode the same code point, in the way UTF-8 does. Even if it does, as long as functions like wstring::operator== don't "unfold" the encoding, and in that case returns true if and only if the strings consist of the same sequence of wchar_t, the implementation is compliant. It's as if the encoding was UCS-2. The standard doesn't say anything about whether functions like fopen are allowed to treat "different" wide strings as representing the same file, so they're allowed to treat the name as variable-length encoded. –  Steve Jessop Oct 26 '10 at 16:22
You need to deal with the fact the wchar_t != one platform character. –  Let_Me_Be Oct 26 '10 at 17:20
@Steve Jessop: UTF-16 uses surrogate pairs (2 16 bit values) for any character outside the BMP (past U+10000). You're not allowed to use surrogate pairs for BMP characters. Essentially, it enforces a canonical representation in the same way as UTF-8 does, by mandating the shortest possible encoding. Besides, the strings used by fopen are open to platform interpretation anyway. C and C++ don't even specify whether they're case-sensitive. –  MSalters Oct 27 '10 at 10:01
@Let_Me_Be: deal with it how? As far as the C++ language is concerned, the execution wide character set is int16_t (or uint16_t, I can't remember whether MS's wchar_t is signed). Implementation-defined meanings of strings are a whole separate issue, and it's only here that MS comes in and says, "it's UTF-16". Can you give an example of some code which behaves differently with Microsoft's definition of a wide character, from what the standard allows? –  Steve Jessop Oct 27 '10 at 10:18
@Steve The standard actually doesn't care about he underlying type. What I'm searching for is what MSalters posted in his answer. If it's true, then I need to know how to walk around these semantics. –  Let_Me_Be Oct 27 '10 at 10:26

Two things:

  1. There is no "Microsoft STL implementation". The C++ Standard Library shipped with Visual C++ is licensed from Dinkumware.
  2. The current C++ Standard knows nothing about Unicode and its encoding forms. std::wstring is merely a container for wchar_t units which happen to be 16-bit on Windows. In practice, if you want to store a UTF-16 encoded string into a wstring, just take into account that you are really storing code units and not code points.
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There certainly is a Microsoft STL implementation. It may be licensed, but it's also modified, so it's not the original Dinkumware implementation anymore (and even if it was, it's still part of the Visual Studio product). Also, the current C++ standard does know something about Unicode: ISO 10646 is a normative reference, and universal character names are interpreted as Unicode. It's also reasonable to assume that C99's __STDC_ISO_10646__, if defined, has the same meaning in a C++ implementation (even though C++98 does not mention it). –  Martin v. Löwis Oct 31 '10 at 9:21

MSVC stores wchar_t in wstrings. These can be interpreted as unicode 16 bit words, or anything else really.

If you want to get access to unicode characters or glyphs, you'll have to process said raw string by the unicode standard. You probably also want to handle common corner cases without breaking.

Here is a sketch of such a library. It is about half as memory efficient as it could be, but it does give you in-place access to unicode glyphs in a std::string. It relies on having a decent array_view class, but you want to write one of those anyhow:

struct unicode_char : array_view<wchar_t const> {
  using array_view<wchar_t const>::array_view<wchar_t const>;

  uint32_t value() const {
    if (size()==1)
      return front();
    if (size()==2)
      wchar_t high = front()-0xD800;
      wchar_T low = back()-0xDC00;
      return (uint32_t(high)<<10) + uint32_t(low);
    return 0; // error
  static bool is_high_surrogate( wchar_t c ) {
    return (c >= 0xD800 && c <= 0xDBFF);
  static bool is_low_surrogate( wchar_t c ) {
    return (c >= 0xDC00 && c <= 0xDFFF);
  static unicode_char extract( array_view<wchar_t const> raw )
    if (raw.empty())
      return {};
    if (raw.size()==1)
      return raw;
    if (is_high_surrogate(raw.front()) && is_low_surrogate(*std::next(raw.begin())))
      return {raw.begin(), raw.begin()+2);
    return {raw.begin(), std::next(raw.begin())};
static std::vector<unicode_char> as_unicode_chars( array_view<wchar_t> raw )
  std::vector<unicode_char> retval;
  retval.reserve( raw.size() ); // usually 1:1
    retval.push_back( unicode_char::extract(raw) );
    Assert( retval.back().size() <= raw.size() );
    raw = {raw.begin() + retval.back().size(), raw.end()};
  return retval;
struct unicode_glyph {
  std::array< unicode_char, 3 > buff;
  std::size_t count=0;
  unicode_char const* begin() const {
    return buff.begin();
  unicode_char const* end() const {
    return buff.begin()+count;
  std::size_t size() const { return count; }
  bool empty() { return size()==0; }
  unicode_char const& front() const { return *begin(); }
  unicode_char const& back() const { return *std::prev(end()); }
  array_view< unicode_char const > chars() const { return {begin(), end()}; }
  array_view< wchar_t const > wchars() const {
    if (empty()) return {};
    return { front().begin(), back().end() };

  void append( unicode_char next ) {
    buff[count++] = next;
  unicode_glyph() {}

  static bool is_diacrit(unicode_char c) const {
    auto v = c.value();
    return is_diacrit(v);
  static bool is_diacrit(uint32_t v) const {
      ((v >= 0x0300) && (v <= 0x0360))
    || ((v >= 0x1AB0) && (v <= 0x1AFF))
    || ((v >= 0x1DC0) && (v <= 0x1DFF))
    || ((v >= 0x20D0) && (v <= 0x20FF))
    || ((v >= 0xFE20) && (v <= 0xFE2F));
  static size_t diacrit_count(unicode_char c) const {
    auto v = c.value();
    if (is_diacrit(v))
      return 1 + ((v >= 0x035C)&&(v<=0x0362));
      return 0;
  static unicode_glyph extract( array_view<const unicode_char> raw ) {
    unicode_glyph retval;
    if (raw.empty())
      return retval;
    if (raw.size()==1)
      return retval;
    retval.count = diacrit_count( *std::next(raw.begin()) )+1;
    std::copy( raw.begin(), raw.begin()+retval.count, retval.buff.begin() );
    return retval;
static std::vector<unicode_glyph> as_unicode_glyphs( array_view<unicode_char> raw )
  std::vector<unicode_glyph> retval;
  retval.reserve( raw.size() ); // usually 1:1
    retval.push_back( unicode_glyph::extract(raw) );
    Assert( retval.back().size() <= raw.size() );
    raw = {raw.begin() + retval.back().size(), raw.end()};
  return retval;
static std::vector<unicode_glyph> as_unicode_glyphs( array_view<wchar_t> raw )
  return as_unicode_glyphs( as_unicode_chars( raw ) );

a smarter bit of code would generate the unicode_chars and unicode_glyphs on the fly with a factory iterator of some kind. A more compact implementation would keep track of the fact that the end pointer of the previous and begin pointer of the next are always identical, and alias them together. Another optimization would be to use a small object optimization on glyph based off the assumption that most glyphs are one character, and use dynamic allocation if they are two.

Note that I treat CGJ as a standard diacrit, and the double-diacrits as a set of 3 characters that form one (unicode), but half-diacrits don't merge things into one glyph. These are all questionable choices.

This was written in a bout of insomnia. Hope it at least somewhat works.

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