///////////////////////////////////////////////////////////////////////////////
// Name: wx/stringops.h
// Purpose: implementation of wxString primitive operations
// Author: Vaclav Slavik
// Modified by:
// Created: 2007-04-16
// Copyright: (c) 2007 REA Elektronik GmbH
// Licence: wxWindows licence
///////////////////////////////////////////////////////////////////////////////
#ifndef _WX_WXSTRINGOPS_H__
#define _WX_WXSTRINGOPS_H__
#include "wx/chartype.h"
#include "wx/stringimpl.h"
#include "wx/unichar.h"
#include "wx/buffer.h"
// This header contains wxStringOperations "namespace" class that implements
// elementary operations on string data as static methods; wxString methods and
// iterators are implemented in terms of it. Two implementations are available,
// one for UTF-8 encoded char* string and one for "raw" wchar_t* strings (or
// char* in ANSI build).
// FIXME-UTF8: only wchar after we remove ANSI build
#if wxUSE_UNICODE_WCHAR || !wxUSE_UNICODE
struct WXDLLIMPEXP_BASE wxStringOperationsWchar
{
// moves the iterator to the next Unicode character
template <typename Iterator>
static void IncIter(Iterator& i) { ++i; }
// moves the iterator to the previous Unicode character
template <typename Iterator>
static void DecIter(Iterator& i) { --i; }
// moves the iterator by n Unicode characters
template <typename Iterator>
static Iterator AddToIter(const Iterator& i, ptrdiff_t n)
{ return i + n; }
// returns distance of the two iterators in Unicode characters
template <typename Iterator>
static ptrdiff_t DiffIters(const Iterator& i1, const Iterator& i2)
{ return i1 - i2; }
#if wxUSE_UNICODE_UTF16
// encodes the characters as UTF-16:
struct Utf16CharBuffer
{
// Notice that data is left uninitialized, it is filled by EncodeChar()
// which is the only function creating objects of this class.
wchar_t data[3];
operator const wchar_t*() const { return data; }
};
static Utf16CharBuffer EncodeChar(const wxUniChar& ch);
static wxWCharBuffer EncodeNChars(size_t n, const wxUniChar& ch);
static bool IsSingleCodeUnitCharacter(const wxUniChar& ch)
{ return !ch.IsSupplementary(); }
#else
// encodes the character to a form used to represent it in internal
// representation
struct SingleCharBuffer
{
wxChar data[2];
operator const wxChar*() const { return data; }
};
static SingleCharBuffer EncodeChar(const wxUniChar& ch)
{
SingleCharBuffer buf;
buf.data[0] = (wxChar)ch;
buf.data[1] = 0;
return buf;
}
static wxWxCharBuffer EncodeNChars(size_t n, const wxUniChar& ch);
static bool IsSingleCodeUnitCharacter(const wxUniChar&) { return true; }
#endif
static wxUniChar DecodeChar(const wxStringImpl::const_iterator& i)
{ return *i; }
};
#endif // wxUSE_UNICODE_WCHAR || !wxUSE_UNICODE
#if wxUSE_UNICODE_UTF8
struct WXDLLIMPEXP_BASE wxStringOperationsUtf8
{
// checks correctness of UTF-8 sequence
static bool IsValidUtf8String(const char *c,
size_t len = wxStringImpl::npos);
static bool IsValidUtf8LeadByte(unsigned char c)
{
return (c <= 0x7F) || (c >= 0xC2 && c <= 0xF4);
}
// returns offset to skip forward when iterating over UTF-8 sequence
static unsigned char GetUTF8IterOffset(unsigned char c);
template<typename Iterator>
static void IncIter(Iterator& i)
{
wxASSERT( IsValidUtf8LeadByte(*i) );
i += GetUTF8IterOffset(*i);
}
template<typename Iterator>
static void DecIter(Iterator& i)
{
// Non-lead bytes are all in the 0x80..0xBF range (i.e. 10xxxxxx in
// binary), so we just have to go back until we hit a byte that is
// either < 0x80 (i.e. 0xxxxxxx in binary) or 0xC0..0xFF (11xxxxxx in
// binary; this includes some invalid values, but we can ignore it
// here, because we assume valid UTF-8 input for the purpose of
// efficient implementation).
--i;
while ( ((*i) & 0xC0) == 0x80 /* 2 highest bits are '10' */ )
--i;
}
template<typename Iterator>
static Iterator AddToIter(const Iterator& i, ptrdiff_t n)
{
Iterator out(i);
if ( n > 0 )
{
for ( ptrdiff_t j = 0; j < n; ++j )
IncIter(out);
}
else if ( n < 0 )
{
for ( ptrdiff_t j = 0; j > n; --j )
DecIter(out);
}
return out;
}
template<typename Iterator>
static ptrdiff_t DiffIters(Iterator i1, Iterator i2)
{
ptrdiff_t dist = 0;
if ( i1 < i2 )
{
while ( i1 != i2 )
{
IncIter(i1);
dist--;
}
}
else if ( i2 < i1 )
{
while ( i2 != i1 )
{
IncIter(i2);
dist++;
}
}
return dist;
}
static bool IsSingleCodeUnitCharacter(const wxUniChar& ch)
{ return ch.IsAscii(); }
// encodes the character as UTF-8:
typedef wxUniChar::Utf8CharBuffer Utf8CharBuffer;
static Utf8CharBuffer EncodeChar(const wxUniChar& ch)
{ return ch.AsUTF8(); }
// returns n copies of ch encoded in UTF-8 string
static wxCharBuffer EncodeNChars(size_t n, const wxUniChar& ch);
// returns the length of UTF-8 encoding of the character with lead byte 'c'
static size_t GetUtf8CharLength(char c)
{
wxASSERT( IsValidUtf8LeadByte(c) );
return GetUTF8IterOffset(c);
}
// decodes single UTF-8 character from UTF-8 string
static wxUniChar DecodeChar(wxStringImpl::const_iterator i)
{
if ( (unsigned char)*i < 0x80 )
return (int)*i;
return DecodeNonAsciiChar(i);
}
private:
static wxUniChar DecodeNonAsciiChar(wxStringImpl::const_iterator i);
};
#endif // wxUSE_UNICODE_UTF8
#if wxUSE_UNICODE_UTF8
typedef wxStringOperationsUtf8 wxStringOperations;
#else
typedef wxStringOperationsWchar wxStringOperations;
#endif
#endif // _WX_WXSTRINGOPS_H_
