]> git.saurik.com Git - wxWidgets.git/blob - src/common/string.cpp
Fix wxTextEntryDialog::GetValue() when using SetTextValidator().
[wxWidgets.git] / src / common / string.cpp
1 /////////////////////////////////////////////////////////////////////////////
2 // Name: src/common/string.cpp
3 // Purpose: wxString class
4 // Author: Vadim Zeitlin, Ryan Norton
5 // Modified by:
6 // Created: 29/01/98
7 // RCS-ID: $Id$
8 // Copyright: (c) 1998 Vadim Zeitlin <zeitlin@dptmaths.ens-cachan.fr>
9 // (c) 2004 Ryan Norton <wxprojects@comcast.net>
10 // Licence: wxWindows licence
11 /////////////////////////////////////////////////////////////////////////////
12
13 // ===========================================================================
14 // headers, declarations, constants
15 // ===========================================================================
16
17 // For compilers that support precompilation, includes "wx.h".
18 #include "wx/wxprec.h"
19
20 #ifdef __BORLANDC__
21 #pragma hdrstop
22 #endif
23
24 #ifndef WX_PRECOMP
25 #include "wx/string.h"
26 #include "wx/wxcrtvararg.h"
27 #include "wx/intl.h"
28 #include "wx/log.h"
29 #endif
30
31 #include <ctype.h>
32
33 #ifndef __WXWINCE__
34 #include <errno.h>
35 #endif
36
37 #include <string.h>
38 #include <stdlib.h>
39
40 #include "wx/hashmap.h"
41 #include "wx/vector.h"
42 #include "wx/xlocale.h"
43
44 #ifdef __WINDOWS__
45 #include "wx/msw/wrapwin.h"
46 #endif // __WINDOWS__
47
48 #if wxUSE_STD_IOSTREAM
49 #include <sstream>
50 #endif
51
52 // string handling functions used by wxString:
53 #if wxUSE_UNICODE_UTF8
54 #define wxStringMemcpy memcpy
55 #define wxStringMemcmp memcmp
56 #define wxStringMemchr memchr
57 #define wxStringStrlen strlen
58 #else
59 #define wxStringMemcpy wxTmemcpy
60 #define wxStringMemcmp wxTmemcmp
61 #define wxStringMemchr wxTmemchr
62 #define wxStringStrlen wxStrlen
63 #endif
64
65 // define a function declared in wx/buffer.h here as we don't have buffer.cpp
66 // and don't want to add it just because of this simple function
67 namespace wxPrivate
68 {
69
70 // wxXXXBuffer classes can be (implicitly) used during global statics
71 // initialization so wrap the status UntypedBufferData variable in a function
72 // to make it safe to access it even before all global statics are initialized
73 UntypedBufferData *GetUntypedNullData()
74 {
75 static UntypedBufferData s_untypedNullData(NULL, 0);
76
77 return &s_untypedNullData;
78 }
79
80 } // namespace wxPrivate
81
82 // ---------------------------------------------------------------------------
83 // static class variables definition
84 // ---------------------------------------------------------------------------
85
86 //According to STL _must_ be a -1 size_t
87 const size_t wxString::npos = (size_t) -1;
88
89 #if wxUSE_STRING_POS_CACHE
90
91 #ifdef wxHAS_COMPILER_TLS
92
93 wxTLS_TYPE(wxString::Cache) wxString::ms_cache;
94
95 #else // !wxHAS_COMPILER_TLS
96
97 struct wxStrCacheInitializer
98 {
99 wxStrCacheInitializer()
100 {
101 // calling this function triggers s_cache initialization in it, and
102 // from now on it becomes safe to call from multiple threads
103 wxString::GetCache();
104 }
105 };
106
107 /*
108 wxString::Cache& wxString::GetCache()
109 {
110 static wxTLS_TYPE(Cache) s_cache;
111
112 return wxTLS_VALUE(s_cache);
113 }
114 */
115
116 static wxStrCacheInitializer gs_stringCacheInit;
117
118 #endif // wxHAS_COMPILER_TLS/!wxHAS_COMPILER_TLS
119
120 // gdb seems to be unable to display thread-local variables correctly, at least
121 // not my 6.4.98 version under amd64, so provide this debugging helper to do it
122 #if wxDEBUG_LEVEL >= 2
123
124 struct wxStrCacheDumper
125 {
126 static void ShowAll()
127 {
128 puts("*** wxString cache dump:");
129 for ( unsigned n = 0; n < wxString::Cache::SIZE; n++ )
130 {
131 const wxString::Cache::Element&
132 c = wxString::GetCacheBegin()[n];
133
134 printf("\t%u%s\t%p: pos=(%lu, %lu), len=%ld\n",
135 n,
136 n == wxString::LastUsedCacheElement() ? " [*]" : "",
137 c.str,
138 (unsigned long)c.pos,
139 (unsigned long)c.impl,
140 (long)c.len);
141 }
142 }
143 };
144
145 void wxDumpStrCache() { wxStrCacheDumper::ShowAll(); }
146
147 #endif // wxDEBUG_LEVEL >= 2
148
149 #ifdef wxPROFILE_STRING_CACHE
150
151 wxString::CacheStats wxString::ms_cacheStats;
152
153 struct wxStrCacheStatsDumper
154 {
155 ~wxStrCacheStatsDumper()
156 {
157 const wxString::CacheStats& stats = wxString::ms_cacheStats;
158
159 if ( stats.postot )
160 {
161 puts("*** wxString cache statistics:");
162 printf("\tTotal non-trivial calls to PosToImpl(): %u\n",
163 stats.postot);
164 printf("\tHits %u (of which %u not used) or %.2f%%\n",
165 stats.poshits,
166 stats.mishits,
167 100.*float(stats.poshits - stats.mishits)/stats.postot);
168 printf("\tAverage position requested: %.2f\n",
169 float(stats.sumpos) / stats.postot);
170 printf("\tAverage offset after cached hint: %.2f\n",
171 float(stats.sumofs) / stats.postot);
172 }
173
174 if ( stats.lentot )
175 {
176 printf("\tNumber of calls to length(): %u, hits=%.2f%%\n",
177 stats.lentot, 100.*float(stats.lenhits)/stats.lentot);
178 }
179 }
180 };
181
182 static wxStrCacheStatsDumper s_showCacheStats;
183
184 #endif // wxPROFILE_STRING_CACHE
185
186 #endif // wxUSE_STRING_POS_CACHE
187
188 // ----------------------------------------------------------------------------
189 // global functions
190 // ----------------------------------------------------------------------------
191
192 #if wxUSE_STD_IOSTREAM
193
194 #include <iostream>
195
196 wxSTD ostream& operator<<(wxSTD ostream& os, const wxCStrData& str)
197 {
198 #if wxUSE_UNICODE && !wxUSE_UNICODE_UTF8
199 const wxScopedCharBuffer buf(str.AsCharBuf());
200 if ( !buf )
201 os.clear(wxSTD ios_base::failbit);
202 else
203 os << buf.data();
204
205 return os;
206 #else
207 return os << str.AsInternal();
208 #endif
209 }
210
211 wxSTD ostream& operator<<(wxSTD ostream& os, const wxString& str)
212 {
213 return os << str.c_str();
214 }
215
216 wxSTD ostream& operator<<(wxSTD ostream& os, const wxScopedCharBuffer& str)
217 {
218 return os << str.data();
219 }
220
221 #ifndef __BORLANDC__
222 wxSTD ostream& operator<<(wxSTD ostream& os, const wxScopedWCharBuffer& str)
223 {
224 return os << str.data();
225 }
226 #endif
227
228 #if wxUSE_UNICODE && defined(HAVE_WOSTREAM)
229
230 wxSTD wostream& operator<<(wxSTD wostream& wos, const wxString& str)
231 {
232 return wos << str.wc_str();
233 }
234
235 wxSTD wostream& operator<<(wxSTD wostream& wos, const wxCStrData& str)
236 {
237 return wos << str.AsWChar();
238 }
239
240 wxSTD wostream& operator<<(wxSTD wostream& wos, const wxScopedWCharBuffer& str)
241 {
242 return wos << str.data();
243 }
244
245 #endif // wxUSE_UNICODE && defined(HAVE_WOSTREAM)
246
247 #endif // wxUSE_STD_IOSTREAM
248
249 // ===========================================================================
250 // wxString class core
251 // ===========================================================================
252
253 #if wxUSE_UNICODE_UTF8
254
255 void wxString::PosLenToImpl(size_t pos, size_t len,
256 size_t *implPos, size_t *implLen) const
257 {
258 if ( pos == npos )
259 {
260 *implPos = npos;
261 }
262 else // have valid start position
263 {
264 const const_iterator b = GetIterForNthChar(pos);
265 *implPos = wxStringImpl::const_iterator(b.impl()) - m_impl.begin();
266 if ( len == npos )
267 {
268 *implLen = npos;
269 }
270 else // have valid length too
271 {
272 // we need to handle the case of length specifying a substring
273 // going beyond the end of the string, just as std::string does
274 const const_iterator e(end());
275 const_iterator i(b);
276 while ( len && i <= e )
277 {
278 ++i;
279 --len;
280 }
281
282 *implLen = i.impl() - b.impl();
283 }
284 }
285 }
286
287 #endif // wxUSE_UNICODE_UTF8
288
289 // ----------------------------------------------------------------------------
290 // wxCStrData converted strings caching
291 // ----------------------------------------------------------------------------
292
293 // FIXME-UTF8: temporarily disabled because it doesn't work with global
294 // string objects; re-enable after fixing this bug and benchmarking
295 // performance to see if using a hash is a good idea at all
296 #if 0
297
298 // For backward compatibility reasons, it must be possible to assign the value
299 // returned by wxString::c_str() to a char* or wchar_t* variable and work with
300 // it. Returning wxCharBuffer from (const char*)c_str() wouldn't do the trick,
301 // because the memory would be freed immediately, but it has to be valid as long
302 // as the string is not modified, so that code like this still works:
303 //
304 // const wxChar *s = str.c_str();
305 // while ( s ) { ... }
306
307 // FIXME-UTF8: not thread safe!
308 // FIXME-UTF8: we currently clear the cached conversion only when the string is
309 // destroyed, but we should do it when the string is modified, to
310 // keep memory usage down
311 // FIXME-UTF8: we do the conversion every time As[W]Char() is called, but if we
312 // invalidated the cache on every change, we could keep the previous
313 // conversion
314 // FIXME-UTF8: add tracing of usage of these two methods - new code is supposed
315 // to use mb_str() or wc_str() instead of (const [w]char*)c_str()
316
317 template<typename T>
318 static inline void DeleteStringFromConversionCache(T& hash, const wxString *s)
319 {
320 typename T::iterator i = hash.find(wxConstCast(s, wxString));
321 if ( i != hash.end() )
322 {
323 free(i->second);
324 hash.erase(i);
325 }
326 }
327
328 #if wxUSE_UNICODE
329 // NB: non-STL implementation doesn't compile with "const wxString*" key type,
330 // so we have to use wxString* here and const-cast when used
331 WX_DECLARE_HASH_MAP(wxString*, char*, wxPointerHash, wxPointerEqual,
332 wxStringCharConversionCache);
333 static wxStringCharConversionCache gs_stringsCharCache;
334
335 const char* wxCStrData::AsChar() const
336 {
337 // remove previously cache value, if any (see FIXMEs above):
338 DeleteStringFromConversionCache(gs_stringsCharCache, m_str);
339
340 // convert the string and keep it:
341 const char *s = gs_stringsCharCache[wxConstCast(m_str, wxString)] =
342 m_str->mb_str().release();
343
344 return s + m_offset;
345 }
346 #endif // wxUSE_UNICODE
347
348 #if !wxUSE_UNICODE_WCHAR
349 WX_DECLARE_HASH_MAP(wxString*, wchar_t*, wxPointerHash, wxPointerEqual,
350 wxStringWCharConversionCache);
351 static wxStringWCharConversionCache gs_stringsWCharCache;
352
353 const wchar_t* wxCStrData::AsWChar() const
354 {
355 // remove previously cache value, if any (see FIXMEs above):
356 DeleteStringFromConversionCache(gs_stringsWCharCache, m_str);
357
358 // convert the string and keep it:
359 const wchar_t *s = gs_stringsWCharCache[wxConstCast(m_str, wxString)] =
360 m_str->wc_str().release();
361
362 return s + m_offset;
363 }
364 #endif // !wxUSE_UNICODE_WCHAR
365
366 wxString::~wxString()
367 {
368 #if wxUSE_UNICODE
369 // FIXME-UTF8: do this only if locale is not UTF8 if wxUSE_UNICODE_UTF8
370 DeleteStringFromConversionCache(gs_stringsCharCache, this);
371 #endif
372 #if !wxUSE_UNICODE_WCHAR
373 DeleteStringFromConversionCache(gs_stringsWCharCache, this);
374 #endif
375 }
376 #endif
377
378 // ===========================================================================
379 // wxString class core
380 // ===========================================================================
381
382 // ---------------------------------------------------------------------------
383 // construction and conversion
384 // ---------------------------------------------------------------------------
385
386 #if wxUSE_UNICODE_WCHAR
387 /* static */
388 wxString::SubstrBufFromMB wxString::ConvertStr(const char *psz, size_t nLength,
389 const wxMBConv& conv)
390 {
391 // anything to do?
392 if ( !psz || nLength == 0 )
393 return SubstrBufFromMB(wxWCharBuffer(L""), 0);
394
395 if ( nLength == npos )
396 nLength = wxNO_LEN;
397
398 size_t wcLen;
399 wxScopedWCharBuffer wcBuf(conv.cMB2WC(psz, nLength, &wcLen));
400 if ( !wcLen )
401 return SubstrBufFromMB(wxWCharBuffer(L""), 0);
402 else
403 return SubstrBufFromMB(wcBuf, wcLen);
404 }
405 #endif // wxUSE_UNICODE_WCHAR
406
407 #if wxUSE_UNICODE_UTF8
408 /* static */
409 wxString::SubstrBufFromMB wxString::ConvertStr(const char *psz, size_t nLength,
410 const wxMBConv& conv)
411 {
412 // anything to do?
413 if ( !psz || nLength == 0 )
414 return SubstrBufFromMB(wxCharBuffer(""), 0);
415
416 // if psz is already in UTF-8, we don't have to do the roundtrip to
417 // wchar_t* and back:
418 if ( conv.IsUTF8() )
419 {
420 // we need to validate the input because UTF8 iterators assume valid
421 // UTF-8 sequence and psz may be invalid:
422 if ( wxStringOperations::IsValidUtf8String(psz, nLength) )
423 {
424 // we must pass the real string length to SubstrBufFromMB ctor
425 if ( nLength == npos )
426 nLength = psz ? strlen(psz) : 0;
427 return SubstrBufFromMB(wxScopedCharBuffer::CreateNonOwned(psz, nLength),
428 nLength);
429 }
430 // else: do the roundtrip through wchar_t*
431 }
432
433 if ( nLength == npos )
434 nLength = wxNO_LEN;
435
436 // first convert to wide string:
437 size_t wcLen;
438 wxScopedWCharBuffer wcBuf(conv.cMB2WC(psz, nLength, &wcLen));
439 if ( !wcLen )
440 return SubstrBufFromMB(wxCharBuffer(""), 0);
441
442 // and then to UTF-8:
443 SubstrBufFromMB buf(ConvertStr(wcBuf, wcLen, wxMBConvStrictUTF8()));
444 // widechar -> UTF-8 conversion isn't supposed to ever fail:
445 wxASSERT_MSG( buf.data, wxT("conversion to UTF-8 failed") );
446
447 return buf;
448 }
449 #endif // wxUSE_UNICODE_UTF8
450
451 #if wxUSE_UNICODE_UTF8 || !wxUSE_UNICODE
452 /* static */
453 wxString::SubstrBufFromWC wxString::ConvertStr(const wchar_t *pwz, size_t nLength,
454 const wxMBConv& conv)
455 {
456 // anything to do?
457 if ( !pwz || nLength == 0 )
458 return SubstrBufFromWC(wxCharBuffer(""), 0);
459
460 if ( nLength == npos )
461 nLength = wxNO_LEN;
462
463 size_t mbLen;
464 wxScopedCharBuffer mbBuf(conv.cWC2MB(pwz, nLength, &mbLen));
465 if ( !mbLen )
466 return SubstrBufFromWC(wxCharBuffer(""), 0);
467 else
468 return SubstrBufFromWC(mbBuf, mbLen);
469 }
470 #endif // wxUSE_UNICODE_UTF8 || !wxUSE_UNICODE
471
472 // This std::string::c_str()-like method returns a wide char pointer to string
473 // contents. In wxUSE_UNICODE_WCHAR case it is trivial as it can simply return
474 // a pointer to the internal representation. Otherwise a conversion is required
475 // and it returns a temporary buffer.
476 //
477 // However for compatibility with c_str() and to avoid breaking existing code
478 // doing
479 //
480 // for ( const wchar_t *p = s.wc_str(); *p; p++ )
481 // ... use *p...
482 //
483 // we actually need to ensure that the returned buffer is _not_ temporary and
484 // so we use wxString::m_convertedToWChar to store the returned data
485 #if !wxUSE_UNICODE_WCHAR
486
487 const wchar_t *wxString::AsWChar(const wxMBConv& conv) const
488 {
489 const char * const strMB = m_impl.c_str();
490 const size_t lenMB = m_impl.length();
491
492 // find out the size of the buffer needed
493 const size_t lenWC = conv.ToWChar(NULL, 0, strMB, lenMB);
494 if ( lenWC == wxCONV_FAILED )
495 return NULL;
496
497 // keep the same buffer if the string size didn't change: this is not only
498 // an optimization but also ensure that code which modifies string
499 // character by character (without changing its length) can continue to use
500 // the pointer returned by a previous wc_str() call even after changing the
501 // string
502
503 // TODO-UTF8: we could check for ">" instead of "!=" here as this would
504 // allow to save on buffer reallocations but at the cost of
505 // consuming (even) more memory, we should benchmark this to
506 // determine if it's worth doing
507 if ( !m_convertedToWChar.m_str || lenWC != m_convertedToWChar.m_len )
508 {
509 if ( !const_cast<wxString *>(this)->m_convertedToWChar.Extend(lenWC) )
510 return NULL;
511 }
512
513 // finally do convert
514 m_convertedToWChar.m_str[lenWC] = L'\0';
515 if ( conv.ToWChar(m_convertedToWChar.m_str, lenWC,
516 strMB, lenMB) == wxCONV_FAILED )
517 return NULL;
518
519 return m_convertedToWChar.m_str;
520 }
521
522 #endif // !wxUSE_UNICODE_WCHAR
523
524
525 // Same thing for mb_str() which returns a normal char pointer to string
526 // contents: this always requires converting it to the specified encoding in
527 // non-ANSI build except if we need to convert to UTF-8 and this is what we
528 // already use internally.
529 #if wxUSE_UNICODE
530
531 const char *wxString::AsChar(const wxMBConv& conv) const
532 {
533 #if wxUSE_UNICODE_UTF8
534 if ( conv.IsUTF8() )
535 return m_impl.c_str();
536
537 const wchar_t * const strWC = AsWChar(wxMBConvStrictUTF8());
538 const size_t lenWC = m_convertedToWChar.m_len;
539 #else // wxUSE_UNICODE_WCHAR
540 const wchar_t * const strWC = m_impl.c_str();
541 const size_t lenWC = m_impl.length();
542 #endif // wxUSE_UNICODE_UTF8/wxUSE_UNICODE_WCHAR
543
544 const size_t lenMB = conv.FromWChar(NULL, 0, strWC, lenWC);
545 if ( lenMB == wxCONV_FAILED )
546 return NULL;
547
548 if ( !m_convertedToChar.m_str || lenMB != m_convertedToChar.m_len )
549 {
550 if ( !const_cast<wxString *>(this)->m_convertedToChar.Extend(lenMB) )
551 return NULL;
552 }
553
554 m_convertedToChar.m_str[lenMB] = '\0';
555 if ( conv.FromWChar(m_convertedToChar.m_str, lenMB,
556 strWC, lenWC) == wxCONV_FAILED )
557 return NULL;
558
559 return m_convertedToChar.m_str;
560 }
561
562 #endif // wxUSE_UNICODE
563
564 // shrink to minimal size (releasing extra memory)
565 bool wxString::Shrink()
566 {
567 wxString tmp(begin(), end());
568 swap(tmp);
569 return tmp.length() == length();
570 }
571
572 // deprecated compatibility code:
573 #if WXWIN_COMPATIBILITY_2_8 && !wxUSE_STL_BASED_WXSTRING && !wxUSE_UNICODE_UTF8
574 wxStringCharType *wxString::GetWriteBuf(size_t nLen)
575 {
576 return DoGetWriteBuf(nLen);
577 }
578
579 void wxString::UngetWriteBuf()
580 {
581 DoUngetWriteBuf();
582 }
583
584 void wxString::UngetWriteBuf(size_t nLen)
585 {
586 DoUngetWriteBuf(nLen);
587 }
588 #endif // WXWIN_COMPATIBILITY_2_8 && !wxUSE_STL_BASED_WXSTRING && !wxUSE_UNICODE_UTF8
589
590
591 // ---------------------------------------------------------------------------
592 // data access
593 // ---------------------------------------------------------------------------
594
595 // all functions are inline in string.h
596
597 // ---------------------------------------------------------------------------
598 // concatenation operators
599 // ---------------------------------------------------------------------------
600
601 /*
602 * concatenation functions come in 5 flavours:
603 * string + string
604 * char + string and string + char
605 * C str + string and string + C str
606 */
607
608 wxString operator+(const wxString& str1, const wxString& str2)
609 {
610 #if !wxUSE_STL_BASED_WXSTRING
611 wxASSERT( str1.IsValid() );
612 wxASSERT( str2.IsValid() );
613 #endif
614
615 wxString s = str1;
616 s += str2;
617
618 return s;
619 }
620
621 wxString operator+(const wxString& str, wxUniChar ch)
622 {
623 #if !wxUSE_STL_BASED_WXSTRING
624 wxASSERT( str.IsValid() );
625 #endif
626
627 wxString s = str;
628 s += ch;
629
630 return s;
631 }
632
633 wxString operator+(wxUniChar ch, const wxString& str)
634 {
635 #if !wxUSE_STL_BASED_WXSTRING
636 wxASSERT( str.IsValid() );
637 #endif
638
639 wxString s = ch;
640 s += str;
641
642 return s;
643 }
644
645 wxString operator+(const wxString& str, const char *psz)
646 {
647 #if !wxUSE_STL_BASED_WXSTRING
648 wxASSERT( str.IsValid() );
649 #endif
650
651 wxString s;
652 if ( !s.Alloc(strlen(psz) + str.length()) ) {
653 wxFAIL_MSG( wxT("out of memory in wxString::operator+") );
654 }
655 s += str;
656 s += psz;
657
658 return s;
659 }
660
661 wxString operator+(const wxString& str, const wchar_t *pwz)
662 {
663 #if !wxUSE_STL_BASED_WXSTRING
664 wxASSERT( str.IsValid() );
665 #endif
666
667 wxString s;
668 if ( !s.Alloc(wxWcslen(pwz) + str.length()) ) {
669 wxFAIL_MSG( wxT("out of memory in wxString::operator+") );
670 }
671 s += str;
672 s += pwz;
673
674 return s;
675 }
676
677 wxString operator+(const char *psz, const wxString& str)
678 {
679 #if !wxUSE_STL_BASED_WXSTRING
680 wxASSERT( str.IsValid() );
681 #endif
682
683 wxString s;
684 if ( !s.Alloc(strlen(psz) + str.length()) ) {
685 wxFAIL_MSG( wxT("out of memory in wxString::operator+") );
686 }
687 s = psz;
688 s += str;
689
690 return s;
691 }
692
693 wxString operator+(const wchar_t *pwz, const wxString& str)
694 {
695 #if !wxUSE_STL_BASED_WXSTRING
696 wxASSERT( str.IsValid() );
697 #endif
698
699 wxString s;
700 if ( !s.Alloc(wxWcslen(pwz) + str.length()) ) {
701 wxFAIL_MSG( wxT("out of memory in wxString::operator+") );
702 }
703 s = pwz;
704 s += str;
705
706 return s;
707 }
708
709 // ---------------------------------------------------------------------------
710 // string comparison
711 // ---------------------------------------------------------------------------
712
713 bool wxString::IsSameAs(wxUniChar c, bool compareWithCase) const
714 {
715 return (length() == 1) && (compareWithCase ? GetChar(0u) == c
716 : wxToupper(GetChar(0u)) == wxToupper(c));
717 }
718
719 #ifdef HAVE_STD_STRING_COMPARE
720
721 // NB: Comparison code (both if HAVE_STD_STRING_COMPARE and if not) works with
722 // UTF-8 encoded strings too, thanks to UTF-8's design which allows us to
723 // sort strings in characters code point order by sorting the byte sequence
724 // in byte values order (i.e. what strcmp() and memcmp() do).
725
726 int wxString::compare(const wxString& str) const
727 {
728 return m_impl.compare(str.m_impl);
729 }
730
731 int wxString::compare(size_t nStart, size_t nLen,
732 const wxString& str) const
733 {
734 size_t pos, len;
735 PosLenToImpl(nStart, nLen, &pos, &len);
736 return m_impl.compare(pos, len, str.m_impl);
737 }
738
739 int wxString::compare(size_t nStart, size_t nLen,
740 const wxString& str,
741 size_t nStart2, size_t nLen2) const
742 {
743 size_t pos, len;
744 PosLenToImpl(nStart, nLen, &pos, &len);
745
746 size_t pos2, len2;
747 str.PosLenToImpl(nStart2, nLen2, &pos2, &len2);
748
749 return m_impl.compare(pos, len, str.m_impl, pos2, len2);
750 }
751
752 int wxString::compare(const char* sz) const
753 {
754 return m_impl.compare(ImplStr(sz));
755 }
756
757 int wxString::compare(const wchar_t* sz) const
758 {
759 return m_impl.compare(ImplStr(sz));
760 }
761
762 int wxString::compare(size_t nStart, size_t nLen,
763 const char* sz, size_t nCount) const
764 {
765 size_t pos, len;
766 PosLenToImpl(nStart, nLen, &pos, &len);
767
768 SubstrBufFromMB str(ImplStr(sz, nCount));
769
770 return m_impl.compare(pos, len, str.data, str.len);
771 }
772
773 int wxString::compare(size_t nStart, size_t nLen,
774 const wchar_t* sz, size_t nCount) const
775 {
776 size_t pos, len;
777 PosLenToImpl(nStart, nLen, &pos, &len);
778
779 SubstrBufFromWC str(ImplStr(sz, nCount));
780
781 return m_impl.compare(pos, len, str.data, str.len);
782 }
783
784 #else // !HAVE_STD_STRING_COMPARE
785
786 static inline int wxDoCmp(const wxStringCharType* s1, size_t l1,
787 const wxStringCharType* s2, size_t l2)
788 {
789 if( l1 == l2 )
790 return wxStringMemcmp(s1, s2, l1);
791 else if( l1 < l2 )
792 {
793 int ret = wxStringMemcmp(s1, s2, l1);
794 return ret == 0 ? -1 : ret;
795 }
796 else
797 {
798 int ret = wxStringMemcmp(s1, s2, l2);
799 return ret == 0 ? +1 : ret;
800 }
801 }
802
803 int wxString::compare(const wxString& str) const
804 {
805 return ::wxDoCmp(m_impl.data(), m_impl.length(),
806 str.m_impl.data(), str.m_impl.length());
807 }
808
809 int wxString::compare(size_t nStart, size_t nLen,
810 const wxString& str) const
811 {
812 wxASSERT(nStart <= length());
813 size_type strLen = length() - nStart;
814 nLen = strLen < nLen ? strLen : nLen;
815
816 size_t pos, len;
817 PosLenToImpl(nStart, nLen, &pos, &len);
818
819 return ::wxDoCmp(m_impl.data() + pos, len,
820 str.m_impl.data(), str.m_impl.length());
821 }
822
823 int wxString::compare(size_t nStart, size_t nLen,
824 const wxString& str,
825 size_t nStart2, size_t nLen2) const
826 {
827 wxASSERT(nStart <= length());
828 wxASSERT(nStart2 <= str.length());
829 size_type strLen = length() - nStart,
830 strLen2 = str.length() - nStart2;
831 nLen = strLen < nLen ? strLen : nLen;
832 nLen2 = strLen2 < nLen2 ? strLen2 : nLen2;
833
834 size_t pos, len;
835 PosLenToImpl(nStart, nLen, &pos, &len);
836 size_t pos2, len2;
837 str.PosLenToImpl(nStart2, nLen2, &pos2, &len2);
838
839 return ::wxDoCmp(m_impl.data() + pos, len,
840 str.m_impl.data() + pos2, len2);
841 }
842
843 int wxString::compare(const char* sz) const
844 {
845 SubstrBufFromMB str(ImplStr(sz, npos));
846 if ( str.len == npos )
847 str.len = wxStringStrlen(str.data);
848 return ::wxDoCmp(m_impl.data(), m_impl.length(), str.data, str.len);
849 }
850
851 int wxString::compare(const wchar_t* sz) const
852 {
853 SubstrBufFromWC str(ImplStr(sz, npos));
854 if ( str.len == npos )
855 str.len = wxStringStrlen(str.data);
856 return ::wxDoCmp(m_impl.data(), m_impl.length(), str.data, str.len);
857 }
858
859 int wxString::compare(size_t nStart, size_t nLen,
860 const char* sz, size_t nCount) const
861 {
862 wxASSERT(nStart <= length());
863 size_type strLen = length() - nStart;
864 nLen = strLen < nLen ? strLen : nLen;
865
866 size_t pos, len;
867 PosLenToImpl(nStart, nLen, &pos, &len);
868
869 SubstrBufFromMB str(ImplStr(sz, nCount));
870 if ( str.len == npos )
871 str.len = wxStringStrlen(str.data);
872
873 return ::wxDoCmp(m_impl.data() + pos, len, str.data, str.len);
874 }
875
876 int wxString::compare(size_t nStart, size_t nLen,
877 const wchar_t* sz, size_t nCount) const
878 {
879 wxASSERT(nStart <= length());
880 size_type strLen = length() - nStart;
881 nLen = strLen < nLen ? strLen : nLen;
882
883 size_t pos, len;
884 PosLenToImpl(nStart, nLen, &pos, &len);
885
886 SubstrBufFromWC str(ImplStr(sz, nCount));
887 if ( str.len == npos )
888 str.len = wxStringStrlen(str.data);
889
890 return ::wxDoCmp(m_impl.data() + pos, len, str.data, str.len);
891 }
892
893 #endif // HAVE_STD_STRING_COMPARE/!HAVE_STD_STRING_COMPARE
894
895
896 // ---------------------------------------------------------------------------
897 // find_{first,last}_[not]_of functions
898 // ---------------------------------------------------------------------------
899
900 #if !wxUSE_STL_BASED_WXSTRING || wxUSE_UNICODE_UTF8
901
902 // NB: All these functions are implemented with the argument being wxChar*,
903 // i.e. widechar string in any Unicode build, even though native string
904 // representation is char* in the UTF-8 build. This is because we couldn't
905 // use memchr() to determine if a character is in a set encoded as UTF-8.
906
907 size_t wxString::find_first_of(const wxChar* sz, size_t nStart) const
908 {
909 return find_first_of(sz, nStart, wxStrlen(sz));
910 }
911
912 size_t wxString::find_first_not_of(const wxChar* sz, size_t nStart) const
913 {
914 return find_first_not_of(sz, nStart, wxStrlen(sz));
915 }
916
917 size_t wxString::find_first_of(const wxChar* sz, size_t nStart, size_t n) const
918 {
919 wxASSERT_MSG( nStart <= length(), wxT("invalid index") );
920
921 size_t idx = nStart;
922 for ( const_iterator i = begin() + nStart; i != end(); ++idx, ++i )
923 {
924 if ( wxTmemchr(sz, *i, n) )
925 return idx;
926 }
927
928 return npos;
929 }
930
931 size_t wxString::find_first_not_of(const wxChar* sz, size_t nStart, size_t n) const
932 {
933 wxASSERT_MSG( nStart <= length(), wxT("invalid index") );
934
935 size_t idx = nStart;
936 for ( const_iterator i = begin() + nStart; i != end(); ++idx, ++i )
937 {
938 if ( !wxTmemchr(sz, *i, n) )
939 return idx;
940 }
941
942 return npos;
943 }
944
945
946 size_t wxString::find_last_of(const wxChar* sz, size_t nStart) const
947 {
948 return find_last_of(sz, nStart, wxStrlen(sz));
949 }
950
951 size_t wxString::find_last_not_of(const wxChar* sz, size_t nStart) const
952 {
953 return find_last_not_of(sz, nStart, wxStrlen(sz));
954 }
955
956 size_t wxString::find_last_of(const wxChar* sz, size_t nStart, size_t n) const
957 {
958 size_t len = length();
959
960 if ( nStart == npos )
961 {
962 nStart = len - 1;
963 }
964 else
965 {
966 wxASSERT_MSG( nStart <= len, wxT("invalid index") );
967 }
968
969 size_t idx = nStart;
970 for ( const_reverse_iterator i = rbegin() + (len - nStart - 1);
971 i != rend(); --idx, ++i )
972 {
973 if ( wxTmemchr(sz, *i, n) )
974 return idx;
975 }
976
977 return npos;
978 }
979
980 size_t wxString::find_last_not_of(const wxChar* sz, size_t nStart, size_t n) const
981 {
982 size_t len = length();
983
984 if ( nStart == npos )
985 {
986 nStart = len - 1;
987 }
988 else
989 {
990 wxASSERT_MSG( nStart <= len, wxT("invalid index") );
991 }
992
993 size_t idx = nStart;
994 for ( const_reverse_iterator i = rbegin() + (len - nStart - 1);
995 i != rend(); --idx, ++i )
996 {
997 if ( !wxTmemchr(sz, *i, n) )
998 return idx;
999 }
1000
1001 return npos;
1002 }
1003
1004 size_t wxString::find_first_not_of(wxUniChar ch, size_t nStart) const
1005 {
1006 wxASSERT_MSG( nStart <= length(), wxT("invalid index") );
1007
1008 size_t idx = nStart;
1009 for ( const_iterator i = begin() + nStart; i != end(); ++idx, ++i )
1010 {
1011 if ( *i != ch )
1012 return idx;
1013 }
1014
1015 return npos;
1016 }
1017
1018 size_t wxString::find_last_not_of(wxUniChar ch, size_t nStart) const
1019 {
1020 size_t len = length();
1021
1022 if ( nStart == npos )
1023 {
1024 nStart = len - 1;
1025 }
1026 else
1027 {
1028 wxASSERT_MSG( nStart <= len, wxT("invalid index") );
1029 }
1030
1031 size_t idx = nStart;
1032 for ( const_reverse_iterator i = rbegin() + (len - nStart - 1);
1033 i != rend(); --idx, ++i )
1034 {
1035 if ( *i != ch )
1036 return idx;
1037 }
1038
1039 return npos;
1040 }
1041
1042 // the functions above were implemented for wchar_t* arguments in Unicode
1043 // build and char* in ANSI build; below are implementations for the other
1044 // version:
1045 #if wxUSE_UNICODE
1046 #define wxOtherCharType char
1047 #define STRCONV (const wxChar*)wxConvLibc.cMB2WC
1048 #else
1049 #define wxOtherCharType wchar_t
1050 #define STRCONV (const wxChar*)wxConvLibc.cWC2MB
1051 #endif
1052
1053 size_t wxString::find_first_of(const wxOtherCharType* sz, size_t nStart) const
1054 { return find_first_of(STRCONV(sz), nStart); }
1055
1056 size_t wxString::find_first_of(const wxOtherCharType* sz, size_t nStart,
1057 size_t n) const
1058 { return find_first_of(STRCONV(sz, n, NULL), nStart, n); }
1059 size_t wxString::find_last_of(const wxOtherCharType* sz, size_t nStart) const
1060 { return find_last_of(STRCONV(sz), nStart); }
1061 size_t wxString::find_last_of(const wxOtherCharType* sz, size_t nStart,
1062 size_t n) const
1063 { return find_last_of(STRCONV(sz, n, NULL), nStart, n); }
1064 size_t wxString::find_first_not_of(const wxOtherCharType* sz, size_t nStart) const
1065 { return find_first_not_of(STRCONV(sz), nStart); }
1066 size_t wxString::find_first_not_of(const wxOtherCharType* sz, size_t nStart,
1067 size_t n) const
1068 { return find_first_not_of(STRCONV(sz, n, NULL), nStart, n); }
1069 size_t wxString::find_last_not_of(const wxOtherCharType* sz, size_t nStart) const
1070 { return find_last_not_of(STRCONV(sz), nStart); }
1071 size_t wxString::find_last_not_of(const wxOtherCharType* sz, size_t nStart,
1072 size_t n) const
1073 { return find_last_not_of(STRCONV(sz, n, NULL), nStart, n); }
1074
1075 #undef wxOtherCharType
1076 #undef STRCONV
1077
1078 #endif // !wxUSE_STL_BASED_WXSTRING || wxUSE_UNICODE_UTF8
1079
1080 // ===========================================================================
1081 // other common string functions
1082 // ===========================================================================
1083
1084 int wxString::CmpNoCase(const wxString& s) const
1085 {
1086 #if !wxUSE_UNICODE_UTF8
1087 // We compare NUL-delimited chunks of the strings inside the loop. We will
1088 // do as many iterations as there are embedded NULs in the string, i.e.
1089 // usually we will run it just once.
1090
1091 typedef const wxStringImpl::value_type *pchar_type;
1092 const pchar_type thisBegin = m_impl.c_str();
1093 const pchar_type thatBegin = s.m_impl.c_str();
1094
1095 const pchar_type thisEnd = thisBegin + m_impl.length();
1096 const pchar_type thatEnd = thatBegin + s.m_impl.length();
1097
1098 pchar_type thisCur = thisBegin;
1099 pchar_type thatCur = thatBegin;
1100
1101 int rc;
1102 for ( ;; )
1103 {
1104 // Compare until the next NUL, if the strings differ this is the final
1105 // result.
1106 rc = wxStricmp(thisCur, thatCur);
1107 if ( rc )
1108 break;
1109
1110 const size_t lenChunk = wxStrlen(thisCur);
1111 thisCur += lenChunk;
1112 thatCur += lenChunk;
1113
1114 // Skip all the NULs as wxStricmp() doesn't handle them.
1115 for ( ; !*thisCur; thisCur++, thatCur++ )
1116 {
1117 // Check if we exhausted either of the strings.
1118 if ( thisCur == thisEnd )
1119 {
1120 // This one is exhausted, is the other one too?
1121 return thatCur == thatEnd ? 0 : -1;
1122 }
1123
1124 if ( thatCur == thatEnd )
1125 {
1126 // Because of the test above we know that this one is not
1127 // exhausted yet so it's greater than the other one that is.
1128 return 1;
1129 }
1130
1131 if ( *thatCur )
1132 {
1133 // Anything non-NUL is greater than NUL.
1134 return -1;
1135 }
1136 }
1137 }
1138
1139 return rc;
1140 #else // wxUSE_UNICODE_UTF8
1141 // CRT functions can't be used for case-insensitive comparison of UTF-8
1142 // strings so do it in the naive, simple and inefficient way.
1143
1144 // FIXME-UTF8: use wxUniChar::ToLower/ToUpper once added
1145 const_iterator i1 = begin();
1146 const_iterator end1 = end();
1147 const_iterator i2 = s.begin();
1148 const_iterator end2 = s.end();
1149
1150 for ( ; i1 != end1 && i2 != end2; ++i1, ++i2 )
1151 {
1152 wxUniChar lower1 = (wxChar)wxTolower(*i1);
1153 wxUniChar lower2 = (wxChar)wxTolower(*i2);
1154 if ( lower1 != lower2 )
1155 return lower1 < lower2 ? -1 : 1;
1156 }
1157
1158 size_t len1 = length();
1159 size_t len2 = s.length();
1160
1161 if ( len1 < len2 )
1162 return -1;
1163 else if ( len1 > len2 )
1164 return 1;
1165 return 0;
1166 #endif // !wxUSE_UNICODE_UTF8/wxUSE_UNICODE_UTF8
1167 }
1168
1169
1170 #if wxUSE_UNICODE
1171
1172 wxString wxString::FromAscii(const char *ascii, size_t len)
1173 {
1174 if (!ascii || len == 0)
1175 return wxEmptyString;
1176
1177 wxString res;
1178
1179 {
1180 wxStringInternalBuffer buf(res, len);
1181 wxStringCharType *dest = buf;
1182
1183 for ( ; len > 0; --len )
1184 {
1185 unsigned char c = (unsigned char)*ascii++;
1186 wxASSERT_MSG( c < 0x80,
1187 wxT("Non-ASCII value passed to FromAscii().") );
1188
1189 *dest++ = (wchar_t)c;
1190 }
1191 }
1192
1193 return res;
1194 }
1195
1196 wxString wxString::FromAscii(const char *ascii)
1197 {
1198 return FromAscii(ascii, wxStrlen(ascii));
1199 }
1200
1201 wxString wxString::FromAscii(char ascii)
1202 {
1203 // What do we do with '\0' ?
1204
1205 unsigned char c = (unsigned char)ascii;
1206
1207 wxASSERT_MSG( c < 0x80, wxT("Non-ASCII value passed to FromAscii().") );
1208
1209 // NB: the cast to wchar_t causes interpretation of 'ascii' as Latin1 value
1210 return wxString(wxUniChar((wchar_t)c));
1211 }
1212
1213 const wxScopedCharBuffer wxString::ToAscii() const
1214 {
1215 // this will allocate enough space for the terminating NUL too
1216 wxCharBuffer buffer(length());
1217 char *dest = buffer.data();
1218
1219 for ( const_iterator i = begin(); i != end(); ++i )
1220 {
1221 wxUniChar c(*i);
1222 // FIXME-UTF8: unify substituted char ('_') with wxUniChar ('?')
1223 *dest++ = c.IsAscii() ? (char)c : '_';
1224
1225 // the output string can't have embedded NULs anyhow, so we can safely
1226 // stop at first of them even if we do have any
1227 if ( !c )
1228 break;
1229 }
1230
1231 return buffer;
1232 }
1233
1234 #endif // wxUSE_UNICODE
1235
1236 // extract string of length nCount starting at nFirst
1237 wxString wxString::Mid(size_t nFirst, size_t nCount) const
1238 {
1239 size_t nLen = length();
1240
1241 // default value of nCount is npos and means "till the end"
1242 if ( nCount == npos )
1243 {
1244 nCount = nLen - nFirst;
1245 }
1246
1247 // out-of-bounds requests return sensible things
1248 if ( nFirst + nCount > nLen )
1249 {
1250 nCount = nLen - nFirst;
1251 }
1252
1253 if ( nFirst > nLen )
1254 {
1255 // AllocCopy() will return empty string
1256 return wxEmptyString;
1257 }
1258
1259 wxString dest(*this, nFirst, nCount);
1260 if ( dest.length() != nCount )
1261 {
1262 wxFAIL_MSG( wxT("out of memory in wxString::Mid") );
1263 }
1264
1265 return dest;
1266 }
1267
1268 // check that the string starts with prefix and return the rest of the string
1269 // in the provided pointer if it is not NULL, otherwise return false
1270 bool wxString::StartsWith(const wxString& prefix, wxString *rest) const
1271 {
1272 if ( compare(0, prefix.length(), prefix) != 0 )
1273 return false;
1274
1275 if ( rest )
1276 {
1277 // put the rest of the string into provided pointer
1278 rest->assign(*this, prefix.length(), npos);
1279 }
1280
1281 return true;
1282 }
1283
1284
1285 // check that the string ends with suffix and return the rest of it in the
1286 // provided pointer if it is not NULL, otherwise return false
1287 bool wxString::EndsWith(const wxString& suffix, wxString *rest) const
1288 {
1289 int start = length() - suffix.length();
1290
1291 if ( start < 0 || compare(start, npos, suffix) != 0 )
1292 return false;
1293
1294 if ( rest )
1295 {
1296 // put the rest of the string into provided pointer
1297 rest->assign(*this, 0, start);
1298 }
1299
1300 return true;
1301 }
1302
1303
1304 // extract nCount last (rightmost) characters
1305 wxString wxString::Right(size_t nCount) const
1306 {
1307 if ( nCount > length() )
1308 nCount = length();
1309
1310 wxString dest(*this, length() - nCount, nCount);
1311 if ( dest.length() != nCount ) {
1312 wxFAIL_MSG( wxT("out of memory in wxString::Right") );
1313 }
1314 return dest;
1315 }
1316
1317 // get all characters after the last occurrence of ch
1318 // (returns the whole string if ch not found)
1319 wxString wxString::AfterLast(wxUniChar ch) const
1320 {
1321 wxString str;
1322 int iPos = Find(ch, true);
1323 if ( iPos == wxNOT_FOUND )
1324 str = *this;
1325 else
1326 str.assign(*this, iPos + 1, npos);
1327
1328 return str;
1329 }
1330
1331 // extract nCount first (leftmost) characters
1332 wxString wxString::Left(size_t nCount) const
1333 {
1334 if ( nCount > length() )
1335 nCount = length();
1336
1337 wxString dest(*this, 0, nCount);
1338 if ( dest.length() != nCount ) {
1339 wxFAIL_MSG( wxT("out of memory in wxString::Left") );
1340 }
1341 return dest;
1342 }
1343
1344 // get all characters before the first occurrence of ch
1345 // (returns the whole string if ch not found)
1346 wxString wxString::BeforeFirst(wxUniChar ch, wxString *rest) const
1347 {
1348 int iPos = Find(ch);
1349 if ( iPos == wxNOT_FOUND )
1350 {
1351 iPos = length();
1352 if ( rest )
1353 rest->clear();
1354 }
1355 else
1356 {
1357 if ( rest )
1358 rest->assign(*this, iPos + 1, npos);
1359 }
1360
1361 return wxString(*this, 0, iPos);
1362 }
1363
1364 /// get all characters before the last occurrence of ch
1365 /// (returns empty string if ch not found)
1366 wxString wxString::BeforeLast(wxUniChar ch, wxString *rest) const
1367 {
1368 wxString str;
1369 int iPos = Find(ch, true);
1370 if ( iPos != wxNOT_FOUND )
1371 {
1372 if ( iPos != 0 )
1373 str.assign(*this, 0, iPos);
1374
1375 if ( rest )
1376 rest->assign(*this, iPos + 1, npos);
1377 }
1378 else
1379 {
1380 if ( rest )
1381 *rest = *this;
1382 }
1383
1384 return str;
1385 }
1386
1387 /// get all characters after the first occurrence of ch
1388 /// (returns empty string if ch not found)
1389 wxString wxString::AfterFirst(wxUniChar ch) const
1390 {
1391 wxString str;
1392 int iPos = Find(ch);
1393 if ( iPos != wxNOT_FOUND )
1394 str.assign(*this, iPos + 1, npos);
1395
1396 return str;
1397 }
1398
1399 // replace first (or all) occurrences of some substring with another one
1400 size_t wxString::Replace(const wxString& strOld,
1401 const wxString& strNew, bool bReplaceAll)
1402 {
1403 // if we tried to replace an empty string we'd enter an infinite loop below
1404 wxCHECK_MSG( !strOld.empty(), 0,
1405 wxT("wxString::Replace(): invalid parameter") );
1406
1407 wxSTRING_INVALIDATE_CACHE();
1408
1409 size_t uiCount = 0; // count of replacements made
1410
1411 // optimize the special common case: replacement of one character by
1412 // another one (in UTF-8 case we can only do this for ASCII characters)
1413 //
1414 // benchmarks show that this special version is around 3 times faster
1415 // (depending on the proportion of matching characters and UTF-8/wchar_t
1416 // build)
1417 if ( strOld.m_impl.length() == 1 && strNew.m_impl.length() == 1 )
1418 {
1419 const wxStringCharType chOld = strOld.m_impl[0],
1420 chNew = strNew.m_impl[0];
1421
1422 // this loop is the simplified version of the one below
1423 for ( size_t pos = 0; ; )
1424 {
1425 pos = m_impl.find(chOld, pos);
1426 if ( pos == npos )
1427 break;
1428
1429 m_impl[pos++] = chNew;
1430
1431 uiCount++;
1432
1433 if ( !bReplaceAll )
1434 break;
1435 }
1436 }
1437 else if ( !bReplaceAll)
1438 {
1439 size_t pos = m_impl.find(strOld.m_impl, 0);
1440 if ( pos != npos )
1441 {
1442 m_impl.replace(pos, strOld.m_impl.length(), strNew.m_impl);
1443 uiCount = 1;
1444 }
1445 }
1446 else // replace all occurrences
1447 {
1448 const size_t uiOldLen = strOld.m_impl.length();
1449 const size_t uiNewLen = strNew.m_impl.length();
1450
1451 // first scan the string to find all positions at which the replacement
1452 // should be made
1453 wxVector<size_t> replacePositions;
1454
1455 size_t pos;
1456 for ( pos = m_impl.find(strOld.m_impl, 0);
1457 pos != npos;
1458 pos = m_impl.find(strOld.m_impl, pos + uiOldLen))
1459 {
1460 replacePositions.push_back(pos);
1461 ++uiCount;
1462 }
1463
1464 if ( !uiCount )
1465 return 0;
1466
1467 // allocate enough memory for the whole new string
1468 wxString tmp;
1469 tmp.m_impl.reserve(m_impl.length() + uiCount*(uiNewLen - uiOldLen));
1470
1471 // copy this string to tmp doing replacements on the fly
1472 size_t replNum = 0;
1473 for ( pos = 0; replNum < uiCount; replNum++ )
1474 {
1475 const size_t nextReplPos = replacePositions[replNum];
1476
1477 if ( pos != nextReplPos )
1478 {
1479 tmp.m_impl.append(m_impl, pos, nextReplPos - pos);
1480 }
1481
1482 tmp.m_impl.append(strNew.m_impl);
1483 pos = nextReplPos + uiOldLen;
1484 }
1485
1486 if ( pos != m_impl.length() )
1487 {
1488 // append the rest of the string unchanged
1489 tmp.m_impl.append(m_impl, pos, m_impl.length() - pos);
1490 }
1491
1492 swap(tmp);
1493 }
1494
1495 return uiCount;
1496 }
1497
1498 bool wxString::IsAscii() const
1499 {
1500 for ( const_iterator i = begin(); i != end(); ++i )
1501 {
1502 if ( !(*i).IsAscii() )
1503 return false;
1504 }
1505
1506 return true;
1507 }
1508
1509 bool wxString::IsWord() const
1510 {
1511 for ( const_iterator i = begin(); i != end(); ++i )
1512 {
1513 if ( !wxIsalpha(*i) )
1514 return false;
1515 }
1516
1517 return true;
1518 }
1519
1520 bool wxString::IsNumber() const
1521 {
1522 if ( empty() )
1523 return true;
1524
1525 const_iterator i = begin();
1526
1527 if ( *i == wxT('-') || *i == wxT('+') )
1528 ++i;
1529
1530 for ( ; i != end(); ++i )
1531 {
1532 if ( !wxIsdigit(*i) )
1533 return false;
1534 }
1535
1536 return true;
1537 }
1538
1539 wxString wxString::Strip(stripType w) const
1540 {
1541 wxString s = *this;
1542 if ( w & leading ) s.Trim(false);
1543 if ( w & trailing ) s.Trim(true);
1544 return s;
1545 }
1546
1547 // ---------------------------------------------------------------------------
1548 // case conversion
1549 // ---------------------------------------------------------------------------
1550
1551 wxString& wxString::MakeUpper()
1552 {
1553 for ( iterator it = begin(), en = end(); it != en; ++it )
1554 *it = (wxChar)wxToupper(*it);
1555
1556 return *this;
1557 }
1558
1559 wxString& wxString::MakeLower()
1560 {
1561 for ( iterator it = begin(), en = end(); it != en; ++it )
1562 *it = (wxChar)wxTolower(*it);
1563
1564 return *this;
1565 }
1566
1567 wxString& wxString::MakeCapitalized()
1568 {
1569 const iterator en = end();
1570 iterator it = begin();
1571 if ( it != en )
1572 {
1573 *it = (wxChar)wxToupper(*it);
1574 for ( ++it; it != en; ++it )
1575 *it = (wxChar)wxTolower(*it);
1576 }
1577
1578 return *this;
1579 }
1580
1581 // ---------------------------------------------------------------------------
1582 // trimming and padding
1583 // ---------------------------------------------------------------------------
1584
1585 // some compilers (VC++ 6.0 not to name them) return true for a call to
1586 // isspace('\xEA') in the C locale which seems to be broken to me, but we have
1587 // to live with this by checking that the character is a 7 bit one - even if
1588 // this may fail to detect some spaces (I don't know if Unicode doesn't have
1589 // space-like symbols somewhere except in the first 128 chars), it is arguably
1590 // still better than trimming away accented letters
1591 inline int wxSafeIsspace(wxChar ch) { return (ch < 127) && wxIsspace(ch); }
1592
1593 // trims spaces (in the sense of isspace) from left or right side
1594 wxString& wxString::Trim(bool bFromRight)
1595 {
1596 // first check if we're going to modify the string at all
1597 if ( !empty() &&
1598 (
1599 (bFromRight && wxSafeIsspace(GetChar(length() - 1))) ||
1600 (!bFromRight && wxSafeIsspace(GetChar(0u)))
1601 )
1602 )
1603 {
1604 if ( bFromRight )
1605 {
1606 // find last non-space character
1607 reverse_iterator psz = rbegin();
1608 while ( (psz != rend()) && wxSafeIsspace(*psz) )
1609 ++psz;
1610
1611 // truncate at trailing space start
1612 erase(psz.base(), end());
1613 }
1614 else
1615 {
1616 // find first non-space character
1617 iterator psz = begin();
1618 while ( (psz != end()) && wxSafeIsspace(*psz) )
1619 ++psz;
1620
1621 // fix up data and length
1622 erase(begin(), psz);
1623 }
1624 }
1625
1626 return *this;
1627 }
1628
1629 // adds nCount characters chPad to the string from either side
1630 wxString& wxString::Pad(size_t nCount, wxUniChar chPad, bool bFromRight)
1631 {
1632 wxString s(chPad, nCount);
1633
1634 if ( bFromRight )
1635 *this += s;
1636 else
1637 {
1638 s += *this;
1639 swap(s);
1640 }
1641
1642 return *this;
1643 }
1644
1645 // truncate the string
1646 wxString& wxString::Truncate(size_t uiLen)
1647 {
1648 if ( uiLen < length() )
1649 {
1650 erase(begin() + uiLen, end());
1651 }
1652 //else: nothing to do, string is already short enough
1653
1654 return *this;
1655 }
1656
1657 // ---------------------------------------------------------------------------
1658 // finding (return wxNOT_FOUND if not found and index otherwise)
1659 // ---------------------------------------------------------------------------
1660
1661 // find a character
1662 int wxString::Find(wxUniChar ch, bool bFromEnd) const
1663 {
1664 size_type idx = bFromEnd ? find_last_of(ch) : find_first_of(ch);
1665
1666 return (idx == npos) ? wxNOT_FOUND : (int)idx;
1667 }
1668
1669 // ----------------------------------------------------------------------------
1670 // conversion to numbers
1671 // ----------------------------------------------------------------------------
1672
1673 // The implementation of all the functions below is exactly the same so factor
1674 // it out. Note that number extraction works correctly on UTF-8 strings, so
1675 // we can use wxStringCharType and wx_str() for maximum efficiency.
1676
1677 #ifndef __WXWINCE__
1678 #define DO_IF_NOT_WINCE(x) x
1679 #else
1680 #define DO_IF_NOT_WINCE(x)
1681 #endif
1682
1683 #define WX_STRING_TO_X_TYPE_START \
1684 wxCHECK_MSG( pVal, false, wxT("NULL output pointer") ); \
1685 DO_IF_NOT_WINCE( errno = 0; ) \
1686 const wxStringCharType *start = wx_str(); \
1687 wxStringCharType *end;
1688
1689 // notice that we return false without modifying the output parameter at all if
1690 // nothing could be parsed but we do modify it and return false then if we did
1691 // parse something successfully but not the entire string
1692 #define WX_STRING_TO_X_TYPE_END \
1693 if ( end == start DO_IF_NOT_WINCE(|| errno == ERANGE) ) \
1694 return false; \
1695 *pVal = val; \
1696 return !*end;
1697
1698 bool wxString::ToLong(long *pVal, int base) const
1699 {
1700 wxASSERT_MSG( !base || (base > 1 && base <= 36), wxT("invalid base") );
1701
1702 WX_STRING_TO_X_TYPE_START
1703 long val = wxStrtol(start, &end, base);
1704 WX_STRING_TO_X_TYPE_END
1705 }
1706
1707 bool wxString::ToULong(unsigned long *pVal, int base) const
1708 {
1709 wxASSERT_MSG( !base || (base > 1 && base <= 36), wxT("invalid base") );
1710
1711 WX_STRING_TO_X_TYPE_START
1712 unsigned long val = wxStrtoul(start, &end, base);
1713 WX_STRING_TO_X_TYPE_END
1714 }
1715
1716 bool wxString::ToLongLong(wxLongLong_t *pVal, int base) const
1717 {
1718 wxASSERT_MSG( !base || (base > 1 && base <= 36), wxT("invalid base") );
1719
1720 WX_STRING_TO_X_TYPE_START
1721 wxLongLong_t val = wxStrtoll(start, &end, base);
1722 WX_STRING_TO_X_TYPE_END
1723 }
1724
1725 bool wxString::ToULongLong(wxULongLong_t *pVal, int base) const
1726 {
1727 wxASSERT_MSG( !base || (base > 1 && base <= 36), wxT("invalid base") );
1728
1729 WX_STRING_TO_X_TYPE_START
1730 wxULongLong_t val = wxStrtoull(start, &end, base);
1731 WX_STRING_TO_X_TYPE_END
1732 }
1733
1734 bool wxString::ToDouble(double *pVal) const
1735 {
1736 WX_STRING_TO_X_TYPE_START
1737 double val = wxStrtod(start, &end);
1738 WX_STRING_TO_X_TYPE_END
1739 }
1740
1741 #if wxUSE_XLOCALE
1742
1743 bool wxString::ToCLong(long *pVal, int base) const
1744 {
1745 wxASSERT_MSG( !base || (base > 1 && base <= 36), wxT("invalid base") );
1746
1747 WX_STRING_TO_X_TYPE_START
1748 #if (wxUSE_UNICODE_UTF8 || !wxUSE_UNICODE) && defined(wxHAS_XLOCALE_SUPPORT)
1749 long val = wxStrtol_lA(start, &end, base, wxCLocale);
1750 #else
1751 long val = wxStrtol_l(start, &end, base, wxCLocale);
1752 #endif
1753 WX_STRING_TO_X_TYPE_END
1754 }
1755
1756 bool wxString::ToCULong(unsigned long *pVal, int base) const
1757 {
1758 wxASSERT_MSG( !base || (base > 1 && base <= 36), wxT("invalid base") );
1759
1760 WX_STRING_TO_X_TYPE_START
1761 #if (wxUSE_UNICODE_UTF8 || !wxUSE_UNICODE) && defined(wxHAS_XLOCALE_SUPPORT)
1762 unsigned long val = wxStrtoul_lA(start, &end, base, wxCLocale);
1763 #else
1764 unsigned long val = wxStrtoul_l(start, &end, base, wxCLocale);
1765 #endif
1766 WX_STRING_TO_X_TYPE_END
1767 }
1768
1769 bool wxString::ToCDouble(double *pVal) const
1770 {
1771 WX_STRING_TO_X_TYPE_START
1772 #if (wxUSE_UNICODE_UTF8 || !wxUSE_UNICODE) && defined(wxHAS_XLOCALE_SUPPORT)
1773 double val = wxStrtod_lA(start, &end, wxCLocale);
1774 #else
1775 double val = wxStrtod_l(start, &end, wxCLocale);
1776 #endif
1777 WX_STRING_TO_X_TYPE_END
1778 }
1779
1780 #else // wxUSE_XLOCALE
1781
1782 // Provide implementation of these functions even when wxUSE_XLOCALE is
1783 // disabled, we still need them in wxWidgets internal code.
1784
1785 // For integers we just assume the current locale uses the same number
1786 // representation as the C one as there is nothing else we can do.
1787 bool wxString::ToCLong(long *pVal, int base) const
1788 {
1789 return ToLong(pVal, base);
1790 }
1791
1792 bool wxString::ToCULong(unsigned long *pVal, int base) const
1793 {
1794 return ToULong(pVal, base);
1795 }
1796
1797 // For floating point numbers we have to handle the problem of the decimal
1798 // point which is different in different locales.
1799 bool wxString::ToCDouble(double *pVal) const
1800 {
1801 // Create a copy of this string using the decimal point instead of whatever
1802 // separator the current locale uses.
1803 #if wxUSE_INTL
1804 wxString sep = wxLocale::GetInfo(wxLOCALE_DECIMAL_POINT,
1805 wxLOCALE_CAT_NUMBER);
1806 if ( sep == "." )
1807 {
1808 // We can avoid an unnecessary string copy in this case.
1809 return ToDouble(pVal);
1810 }
1811 #else // !wxUSE_INTL
1812 // We don't know what the current separator is so it might even be a point
1813 // already, try to parse the string as a double:
1814 if ( ToDouble(pVal) )
1815 {
1816 // It must have been the point, nothing else to do.
1817 return true;
1818 }
1819
1820 // Try to guess the separator, using the most common alternative value.
1821 wxString sep(",");
1822 #endif // wxUSE_INTL/!wxUSE_INTL
1823 wxString cstr(*this);
1824 cstr.Replace(".", sep);
1825
1826 return cstr.ToDouble(pVal);
1827 }
1828
1829 #endif // wxUSE_XLOCALE/!wxUSE_XLOCALE
1830
1831 // ----------------------------------------------------------------------------
1832 // number to string conversion
1833 // ----------------------------------------------------------------------------
1834
1835 /* static */
1836 wxString wxString::FromDouble(double val, int precision)
1837 {
1838 wxCHECK_MSG( precision >= -1, wxString(), "Invalid negative precision" );
1839
1840 wxString format;
1841 if ( precision == -1 )
1842 {
1843 format = "%g";
1844 }
1845 else // Use fixed precision.
1846 {
1847 format.Printf("%%.%df", precision);
1848 }
1849
1850 return wxString::Format(format, val);
1851 }
1852
1853 /* static */
1854 wxString wxString::FromCDouble(double val, int precision)
1855 {
1856 wxCHECK_MSG( precision >= -1, wxString(), "Invalid negative precision" );
1857
1858 #if wxUSE_STD_IOSTREAM && wxUSE_STD_STRING
1859 // We assume that we can use the ostream and not wstream for numbers.
1860 wxSTD ostringstream os;
1861 if ( precision != -1 )
1862 {
1863 os.precision(precision);
1864 os.setf(std::ios::fixed, std::ios::floatfield);
1865 }
1866
1867 os << val;
1868 return os.str();
1869 #else // !wxUSE_STD_IOSTREAM
1870 // Can't use iostream locale support, fall back to the manual method
1871 // instead.
1872 wxString s = FromDouble(val, precision);
1873 #if wxUSE_INTL
1874 wxString sep = wxLocale::GetInfo(wxLOCALE_DECIMAL_POINT,
1875 wxLOCALE_CAT_NUMBER);
1876 #else // !wxUSE_INTL
1877 // As above, this is the most common alternative value. Notice that here it
1878 // doesn't matter if we guess wrongly and the current separator is already
1879 // ".": we'll just waste a call to Replace() in this case.
1880 wxString sep(",");
1881 #endif // wxUSE_INTL/!wxUSE_INTL
1882
1883 s.Replace(sep, ".");
1884 return s;
1885 #endif // wxUSE_STD_IOSTREAM/!wxUSE_STD_IOSTREAM
1886 }
1887
1888 // ---------------------------------------------------------------------------
1889 // formatted output
1890 // ---------------------------------------------------------------------------
1891
1892 #if !wxUSE_UTF8_LOCALE_ONLY
1893 /* static */
1894 #ifdef wxNEEDS_WXSTRING_PRINTF_MIXIN
1895 wxString wxStringPrintfMixinBase::DoFormatWchar(const wxChar *format, ...)
1896 #else
1897 wxString wxString::DoFormatWchar(const wxChar *format, ...)
1898 #endif
1899 {
1900 va_list argptr;
1901 va_start(argptr, format);
1902
1903 wxString s;
1904 s.PrintfV(format, argptr);
1905
1906 va_end(argptr);
1907
1908 return s;
1909 }
1910 #endif // !wxUSE_UTF8_LOCALE_ONLY
1911
1912 #if wxUSE_UNICODE_UTF8
1913 /* static */
1914 wxString wxString::DoFormatUtf8(const char *format, ...)
1915 {
1916 va_list argptr;
1917 va_start(argptr, format);
1918
1919 wxString s;
1920 s.PrintfV(format, argptr);
1921
1922 va_end(argptr);
1923
1924 return s;
1925 }
1926 #endif // wxUSE_UNICODE_UTF8
1927
1928 /* static */
1929 wxString wxString::FormatV(const wxString& format, va_list argptr)
1930 {
1931 wxString s;
1932 s.PrintfV(format, argptr);
1933 return s;
1934 }
1935
1936 #if !wxUSE_UTF8_LOCALE_ONLY
1937 #ifdef wxNEEDS_WXSTRING_PRINTF_MIXIN
1938 int wxStringPrintfMixinBase::DoPrintfWchar(const wxChar *format, ...)
1939 #else
1940 int wxString::DoPrintfWchar(const wxChar *format, ...)
1941 #endif
1942 {
1943 va_list argptr;
1944 va_start(argptr, format);
1945
1946 #ifdef wxNEEDS_WXSTRING_PRINTF_MIXIN
1947 // get a pointer to the wxString instance; we have to use dynamic_cast<>
1948 // because it's the only cast that works safely for downcasting when
1949 // multiple inheritance is used:
1950 wxString *str = static_cast<wxString*>(this);
1951 #else
1952 wxString *str = this;
1953 #endif
1954
1955 int iLen = str->PrintfV(format, argptr);
1956
1957 va_end(argptr);
1958
1959 return iLen;
1960 }
1961 #endif // !wxUSE_UTF8_LOCALE_ONLY
1962
1963 #if wxUSE_UNICODE_UTF8
1964 int wxString::DoPrintfUtf8(const char *format, ...)
1965 {
1966 va_list argptr;
1967 va_start(argptr, format);
1968
1969 int iLen = PrintfV(format, argptr);
1970
1971 va_end(argptr);
1972
1973 return iLen;
1974 }
1975 #endif // wxUSE_UNICODE_UTF8
1976
1977 /*
1978 Uses wxVsnprintf and places the result into the this string.
1979
1980 In ANSI build, wxVsnprintf is effectively vsnprintf but in Unicode build
1981 it is vswprintf. Due to a discrepancy between vsnprintf and vswprintf in
1982 the ISO C99 (and thus SUSv3) standard the return value for the case of
1983 an undersized buffer is inconsistent. For conforming vsnprintf
1984 implementations the function must return the number of characters that
1985 would have been printed had the buffer been large enough. For conforming
1986 vswprintf implementations the function must return a negative number
1987 and set errno.
1988
1989 What vswprintf sets errno to is undefined but Darwin seems to set it to
1990 EOVERFLOW. The only expected errno are EILSEQ and EINVAL. Both of
1991 those are defined in the standard and backed up by several conformance
1992 statements. Note that ENOMEM mentioned in the manual page does not
1993 apply to swprintf, only wprintf and fwprintf.
1994
1995 Official manual page:
1996 http://www.opengroup.org/onlinepubs/009695399/functions/swprintf.html
1997
1998 Some conformance statements (AIX, Solaris):
1999 http://www.opengroup.org/csq/view.mhtml?RID=ibm%2FSD1%2F3
2000 http://www.theopengroup.org/csq/view.mhtml?norationale=1&noreferences=1&RID=Fujitsu%2FSE2%2F10
2001
2002 Since EILSEQ and EINVAL are rather common but EOVERFLOW is not and since
2003 EILSEQ and EINVAL are specifically defined to mean the error is other than
2004 an undersized buffer and no other errno are defined we treat those two
2005 as meaning hard errors and everything else gets the old behaviour which
2006 is to keep looping and increasing buffer size until the function succeeds.
2007
2008 In practice it's impossible to determine before compilation which behaviour
2009 may be used. The vswprintf function may have vsnprintf-like behaviour or
2010 vice-versa. Behaviour detected on one release can theoretically change
2011 with an updated release. Not to mention that configure testing for it
2012 would require the test to be run on the host system, not the build system
2013 which makes cross compilation difficult. Therefore, we make no assumptions
2014 about behaviour and try our best to handle every known case, including the
2015 case where wxVsnprintf returns a negative number and fails to set errno.
2016
2017 There is yet one more non-standard implementation and that is our own.
2018 Fortunately, that can be detected at compile-time.
2019
2020 On top of all that, ISO C99 explicitly defines snprintf to write a null
2021 character to the last position of the specified buffer. That would be at
2022 at the given buffer size minus 1. It is supposed to do this even if it
2023 turns out that the buffer is sized too small.
2024
2025 Darwin (tested on 10.5) follows the C99 behaviour exactly.
2026
2027 Glibc 2.6 almost follows the C99 behaviour except vswprintf never sets
2028 errno even when it fails. However, it only seems to ever fail due
2029 to an undersized buffer.
2030 */
2031 #if wxUSE_UNICODE_UTF8
2032 template<typename BufferType>
2033 #else
2034 // we only need one version in non-UTF8 builds and at least two Windows
2035 // compilers have problems with this function template, so use just one
2036 // normal function here
2037 #endif
2038 static int DoStringPrintfV(wxString& str,
2039 const wxString& format, va_list argptr)
2040 {
2041 int size = 1024;
2042
2043 for ( ;; )
2044 {
2045 #if wxUSE_UNICODE_UTF8
2046 BufferType tmp(str, size + 1);
2047 typename BufferType::CharType *buf = tmp;
2048 #else
2049 wxStringBuffer tmp(str, size + 1);
2050 wxChar *buf = tmp;
2051 #endif
2052
2053 if ( !buf )
2054 {
2055 // out of memory
2056 return -1;
2057 }
2058
2059 // wxVsnprintf() may modify the original arg pointer, so pass it
2060 // only a copy
2061 va_list argptrcopy;
2062 wxVaCopy(argptrcopy, argptr);
2063
2064 #ifndef __WXWINCE__
2065 // Set errno to 0 to make it determinate if wxVsnprintf fails to set it.
2066 errno = 0;
2067 #endif
2068 int len = wxVsnprintf(buf, size, format, argptrcopy);
2069 va_end(argptrcopy);
2070
2071 // some implementations of vsnprintf() don't NUL terminate
2072 // the string if there is not enough space for it so
2073 // always do it manually
2074 // FIXME: This really seems to be the wrong and would be an off-by-one
2075 // bug except the code above allocates an extra character.
2076 buf[size] = wxT('\0');
2077
2078 // vsnprintf() may return either -1 (traditional Unix behaviour) or the
2079 // total number of characters which would have been written if the
2080 // buffer were large enough (newer standards such as Unix98)
2081 if ( len < 0 )
2082 {
2083 // NB: wxVsnprintf() may call either wxCRT_VsnprintfW or
2084 // wxCRT_VsnprintfA in UTF-8 build; wxUSE_WXVSNPRINTF
2085 // is true if *both* of them use our own implementation,
2086 // otherwise we can't be sure
2087 #if wxUSE_WXVSNPRINTF
2088 // we know that our own implementation of wxVsnprintf() returns -1
2089 // only for a format error - thus there's something wrong with
2090 // the user's format string
2091 buf[0] = '\0';
2092 return -1;
2093 #else // possibly using system version
2094 // assume it only returns error if there is not enough space, but
2095 // as we don't know how much we need, double the current size of
2096 // the buffer
2097 #ifndef __WXWINCE__
2098 if( (errno == EILSEQ) || (errno == EINVAL) )
2099 // If errno was set to one of the two well-known hard errors
2100 // then fail immediately to avoid an infinite loop.
2101 return -1;
2102 else
2103 #endif // __WXWINCE__
2104 // still not enough, as we don't know how much we need, double the
2105 // current size of the buffer
2106 size *= 2;
2107 #endif // wxUSE_WXVSNPRINTF/!wxUSE_WXVSNPRINTF
2108 }
2109 else if ( len >= size )
2110 {
2111 #if wxUSE_WXVSNPRINTF
2112 // we know that our own implementation of wxVsnprintf() returns
2113 // size+1 when there's not enough space but that's not the size
2114 // of the required buffer!
2115 size *= 2; // so we just double the current size of the buffer
2116 #else
2117 // some vsnprintf() implementations NUL-terminate the buffer and
2118 // some don't in len == size case, to be safe always add 1
2119 // FIXME: I don't quite understand this comment. The vsnprintf
2120 // function is specifically defined to return the number of
2121 // characters printed not including the null terminator.
2122 // So OF COURSE you need to add 1 to get the right buffer size.
2123 // The following line is definitely correct, no question.
2124 size = len + 1;
2125 #endif
2126 }
2127 else // ok, there was enough space
2128 {
2129 break;
2130 }
2131 }
2132
2133 // we could have overshot
2134 str.Shrink();
2135
2136 return str.length();
2137 }
2138
2139 int wxString::PrintfV(const wxString& format, va_list argptr)
2140 {
2141 #if wxUSE_UNICODE_UTF8
2142 #if wxUSE_STL_BASED_WXSTRING
2143 typedef wxStringTypeBuffer<char> Utf8Buffer;
2144 #else
2145 typedef wxStringInternalBuffer Utf8Buffer;
2146 #endif
2147 #endif
2148
2149 #if wxUSE_UTF8_LOCALE_ONLY
2150 return DoStringPrintfV<Utf8Buffer>(*this, format, argptr);
2151 #else
2152 #if wxUSE_UNICODE_UTF8
2153 if ( wxLocaleIsUtf8 )
2154 return DoStringPrintfV<Utf8Buffer>(*this, format, argptr);
2155 else
2156 // wxChar* version
2157 return DoStringPrintfV<wxStringBuffer>(*this, format, argptr);
2158 #else
2159 return DoStringPrintfV(*this, format, argptr);
2160 #endif // UTF8/WCHAR
2161 #endif
2162 }
2163
2164 // ----------------------------------------------------------------------------
2165 // misc other operations
2166 // ----------------------------------------------------------------------------
2167
2168 // returns true if the string matches the pattern which may contain '*' and
2169 // '?' metacharacters (as usual, '?' matches any character and '*' any number
2170 // of them)
2171 bool wxString::Matches(const wxString& mask) const
2172 {
2173 // I disable this code as it doesn't seem to be faster (in fact, it seems
2174 // to be much slower) than the old, hand-written code below and using it
2175 // here requires always linking with libregex even if the user code doesn't
2176 // use it
2177 #if 0 // wxUSE_REGEX
2178 // first translate the shell-like mask into a regex
2179 wxString pattern;
2180 pattern.reserve(wxStrlen(pszMask));
2181
2182 pattern += wxT('^');
2183 while ( *pszMask )
2184 {
2185 switch ( *pszMask )
2186 {
2187 case wxT('?'):
2188 pattern += wxT('.');
2189 break;
2190
2191 case wxT('*'):
2192 pattern += wxT(".*");
2193 break;
2194
2195 case wxT('^'):
2196 case wxT('.'):
2197 case wxT('$'):
2198 case wxT('('):
2199 case wxT(')'):
2200 case wxT('|'):
2201 case wxT('+'):
2202 case wxT('\\'):
2203 // these characters are special in a RE, quote them
2204 // (however note that we don't quote '[' and ']' to allow
2205 // using them for Unix shell like matching)
2206 pattern += wxT('\\');
2207 // fall through
2208
2209 default:
2210 pattern += *pszMask;
2211 }
2212
2213 pszMask++;
2214 }
2215 pattern += wxT('$');
2216
2217 // and now use it
2218 return wxRegEx(pattern, wxRE_NOSUB | wxRE_EXTENDED).Matches(c_str());
2219 #else // !wxUSE_REGEX
2220 // TODO: this is, of course, awfully inefficient...
2221
2222 // FIXME-UTF8: implement using iterators, remove #if
2223 #if wxUSE_UNICODE_UTF8
2224 const wxScopedWCharBuffer maskBuf = mask.wc_str();
2225 const wxScopedWCharBuffer txtBuf = wc_str();
2226 const wxChar *pszMask = maskBuf.data();
2227 const wxChar *pszTxt = txtBuf.data();
2228 #else
2229 const wxChar *pszMask = mask.wx_str();
2230 // the char currently being checked
2231 const wxChar *pszTxt = wx_str();
2232 #endif
2233
2234 // the last location where '*' matched
2235 const wxChar *pszLastStarInText = NULL;
2236 const wxChar *pszLastStarInMask = NULL;
2237
2238 match:
2239 for ( ; *pszMask != wxT('\0'); pszMask++, pszTxt++ ) {
2240 switch ( *pszMask ) {
2241 case wxT('?'):
2242 if ( *pszTxt == wxT('\0') )
2243 return false;
2244
2245 // pszTxt and pszMask will be incremented in the loop statement
2246
2247 break;
2248
2249 case wxT('*'):
2250 {
2251 // remember where we started to be able to backtrack later
2252 pszLastStarInText = pszTxt;
2253 pszLastStarInMask = pszMask;
2254
2255 // ignore special chars immediately following this one
2256 // (should this be an error?)
2257 while ( *pszMask == wxT('*') || *pszMask == wxT('?') )
2258 pszMask++;
2259
2260 // if there is nothing more, match
2261 if ( *pszMask == wxT('\0') )
2262 return true;
2263
2264 // are there any other metacharacters in the mask?
2265 size_t uiLenMask;
2266 const wxChar *pEndMask = wxStrpbrk(pszMask, wxT("*?"));
2267
2268 if ( pEndMask != NULL ) {
2269 // we have to match the string between two metachars
2270 uiLenMask = pEndMask - pszMask;
2271 }
2272 else {
2273 // we have to match the remainder of the string
2274 uiLenMask = wxStrlen(pszMask);
2275 }
2276
2277 wxString strToMatch(pszMask, uiLenMask);
2278 const wxChar* pMatch = wxStrstr(pszTxt, strToMatch);
2279 if ( pMatch == NULL )
2280 return false;
2281
2282 // -1 to compensate "++" in the loop
2283 pszTxt = pMatch + uiLenMask - 1;
2284 pszMask += uiLenMask - 1;
2285 }
2286 break;
2287
2288 default:
2289 if ( *pszMask != *pszTxt )
2290 return false;
2291 break;
2292 }
2293 }
2294
2295 // match only if nothing left
2296 if ( *pszTxt == wxT('\0') )
2297 return true;
2298
2299 // if we failed to match, backtrack if we can
2300 if ( pszLastStarInText ) {
2301 pszTxt = pszLastStarInText + 1;
2302 pszMask = pszLastStarInMask;
2303
2304 pszLastStarInText = NULL;
2305
2306 // don't bother resetting pszLastStarInMask, it's unnecessary
2307
2308 goto match;
2309 }
2310
2311 return false;
2312 #endif // wxUSE_REGEX/!wxUSE_REGEX
2313 }
2314
2315 // Count the number of chars
2316 int wxString::Freq(wxUniChar ch) const
2317 {
2318 int count = 0;
2319 for ( const_iterator i = begin(); i != end(); ++i )
2320 {
2321 if ( *i == ch )
2322 count ++;
2323 }
2324 return count;
2325 }
2326