///////////////////////////////////////////////////////////////////////////// // Name: src/common/arrstr.cpp // Purpose: wxArrayString class // Author: Vadim Zeitlin // Modified by: // Created: 29/01/98 // Copyright: (c) 1998 Vadim Zeitlin // Licence: wxWindows licence ///////////////////////////////////////////////////////////////////////////// // =========================================================================== // headers, declarations, constants // =========================================================================== // For compilers that support precompilation, includes "wx.h". #include "wx/wxprec.h" #ifdef __BORLANDC__ #pragma hdrstop #endif #include "wx/arrstr.h" #include "wx/scopedarray.h" #include "wx/beforestd.h" #include #include #include "wx/afterstd.h" // ============================================================================ // ArrayString // ============================================================================ wxArrayString::wxArrayString(size_t sz, const char** a) { #if !wxUSE_STD_CONTAINERS Init(false); #endif for (size_t i=0; i < sz; i++) Add(a[i]); } wxArrayString::wxArrayString(size_t sz, const wchar_t** a) { #if !wxUSE_STD_CONTAINERS Init(false); #endif for (size_t i=0; i < sz; i++) Add(a[i]); } wxArrayString::wxArrayString(size_t sz, const wxString* a) { #if !wxUSE_STD_CONTAINERS Init(false); #endif for (size_t i=0; i < sz; i++) Add(a[i]); } #if !wxUSE_STD_CONTAINERS // size increment = min(50% of current size, ARRAY_MAXSIZE_INCREMENT) #define ARRAY_MAXSIZE_INCREMENT 4096 #ifndef ARRAY_DEFAULT_INITIAL_SIZE // also defined in dynarray.h #define ARRAY_DEFAULT_INITIAL_SIZE (16) #endif // ctor void wxArrayString::Init(bool autoSort) { m_nSize = m_nCount = 0; m_pItems = NULL; m_autoSort = autoSort; } // copy ctor wxArrayString::wxArrayString(const wxArrayString& src) { Init(src.m_autoSort); *this = src; } // assignment operator wxArrayString& wxArrayString::operator=(const wxArrayString& src) { if ( m_nSize > 0 ) Clear(); Copy(src); m_autoSort = src.m_autoSort; return *this; } void wxArrayString::Copy(const wxArrayString& src) { if ( src.m_nCount > ARRAY_DEFAULT_INITIAL_SIZE ) Alloc(src.m_nCount); for ( size_t n = 0; n < src.m_nCount; n++ ) Add(src[n]); } // grow the array wxString *wxArrayString::Grow(size_t nIncrement) { if ( (m_nSize - m_nCount) >= nIncrement ) { // We already have enough space. return NULL; } // if ARRAY_DEFAULT_INITIAL_SIZE were set to 0, the initially empty would // be never resized! #if ARRAY_DEFAULT_INITIAL_SIZE == 0 #error "ARRAY_DEFAULT_INITIAL_SIZE must be > 0!" #endif if ( m_nSize == 0 ) { // was empty, alloc some memory m_nSize = ARRAY_DEFAULT_INITIAL_SIZE; if (m_nSize < nIncrement) m_nSize = nIncrement; m_pItems = new wxString[m_nSize]; // Nothing to free, we hadn't had any memory before. return NULL; } else { // otherwise when it's called for the first time, nIncrement would be 0 // and the array would never be expanded // add 50% but not too much size_t ndefIncrement = m_nSize < ARRAY_DEFAULT_INITIAL_SIZE ? ARRAY_DEFAULT_INITIAL_SIZE : m_nSize >> 1; if ( ndefIncrement > ARRAY_MAXSIZE_INCREMENT ) ndefIncrement = ARRAY_MAXSIZE_INCREMENT; if ( nIncrement < ndefIncrement ) nIncrement = ndefIncrement; m_nSize += nIncrement; wxString *pNew = new wxString[m_nSize]; // copy data to new location for ( size_t j = 0; j < m_nCount; j++ ) pNew[j] = m_pItems[j]; wxString* const pItemsOld = m_pItems; m_pItems = pNew; return pItemsOld; } } // deletes all the strings from the list void wxArrayString::Empty() { m_nCount = 0; } // as Empty, but also frees memory void wxArrayString::Clear() { m_nSize = m_nCount = 0; wxDELETEA(m_pItems); } // dtor wxArrayString::~wxArrayString() { delete [] m_pItems; } void wxArrayString::reserve(size_t nSize) { Alloc(nSize); } // pre-allocates memory (frees the previous data!) void wxArrayString::Alloc(size_t nSize) { // only if old buffer was not big enough if ( nSize > m_nSize ) { wxString *pNew = new wxString[nSize]; if ( !pNew ) return; for ( size_t j = 0; j < m_nCount; j++ ) pNew[j] = m_pItems[j]; delete [] m_pItems; m_pItems = pNew; m_nSize = nSize; } } // minimizes the memory usage by freeing unused memory void wxArrayString::Shrink() { // only do it if we have some memory to free if( m_nCount < m_nSize ) { // allocates exactly as much memory as we need wxString *pNew = new wxString[m_nCount]; // copy data to new location for ( size_t j = 0; j < m_nCount; j++ ) pNew[j] = m_pItems[j]; delete [] m_pItems; m_pItems = pNew; m_nSize = m_nCount; } } // searches the array for an item (forward or backwards) int wxArrayString::Index(const wxString& str, bool bCase, bool bFromEnd) const { if ( m_autoSort ) { // use binary search in the sorted array wxASSERT_MSG( bCase && !bFromEnd, wxT("search parameters ignored for auto sorted array") ); size_t i, lo = 0, hi = m_nCount; int res; while ( lo < hi ) { i = (lo + hi)/2; res = str.compare(m_pItems[i]); if ( res < 0 ) hi = i; else if ( res > 0 ) lo = i + 1; else return i; } return wxNOT_FOUND; } else { // use linear search in unsorted array if ( bFromEnd ) { if ( m_nCount > 0 ) { size_t ui = m_nCount; do { if ( m_pItems[--ui].IsSameAs(str, bCase) ) return ui; } while ( ui != 0 ); } } else { for( size_t ui = 0; ui < m_nCount; ui++ ) { if( m_pItems[ui].IsSameAs(str, bCase) ) return ui; } } } return wxNOT_FOUND; } // add item at the end size_t wxArrayString::Add(const wxString& str, size_t nInsert) { if ( m_autoSort ) { // insert the string at the correct position to keep the array sorted size_t i, lo = 0, hi = m_nCount; int res; while ( lo < hi ) { i = (lo + hi)/2; res = str.Cmp(m_pItems[i]); if ( res < 0 ) hi = i; else if ( res > 0 ) lo = i + 1; else { lo = hi = i; break; } } wxASSERT_MSG( lo == hi, wxT("binary search broken") ); Insert(str, lo, nInsert); return (size_t)lo; } else { // Now that we must postpone freeing the old memory until we don't need it // any more, i.e. don't reference "str" which could be a reference to one // of our own strings. wxScopedArray oldStrings(Grow(nInsert)); for (size_t i = 0; i < nInsert; i++) { // just append m_pItems[m_nCount + i] = str; } size_t ret = m_nCount; m_nCount += nInsert; return ret; } } // add item at the given position void wxArrayString::Insert(const wxString& str, size_t nIndex, size_t nInsert) { wxCHECK_RET( nIndex <= m_nCount, wxT("bad index in wxArrayString::Insert") ); wxCHECK_RET( m_nCount <= m_nCount + nInsert, wxT("array size overflow in wxArrayString::Insert") ); wxScopedArray oldStrings(Grow(nInsert)); for (int j = m_nCount - nIndex - 1; j >= 0; j--) m_pItems[nIndex + nInsert + j] = m_pItems[nIndex + j]; for (size_t i = 0; i < nInsert; i++) { m_pItems[nIndex + i] = str; } m_nCount += nInsert; } // range insert (STL 23.2.4.3) void wxArrayString::insert(iterator it, const_iterator first, const_iterator last) { const int idx = it - begin(); // grow it once wxScopedArray oldStrings(Grow(last - first)); // reset "it" since it can change inside Grow() it = begin() + idx; while ( first != last ) { it = insert(it, *first); // insert returns an iterator to the last element inserted but we need // insert the next after this one, that is before the next one ++it; ++first; } } void wxArrayString::resize(size_type n, value_type v) { if ( n < m_nCount ) m_nCount = n; else if ( n > m_nCount ) Add(v, n - m_nCount); } // expand the array void wxArrayString::SetCount(size_t count) { Alloc(count); wxString s; while ( m_nCount < count ) m_pItems[m_nCount++] = s; } // removes item from array (by index) void wxArrayString::RemoveAt(size_t nIndex, size_t nRemove) { wxCHECK_RET( nIndex < m_nCount, wxT("bad index in wxArrayString::Remove") ); wxCHECK_RET( nIndex + nRemove <= m_nCount, wxT("removing too many elements in wxArrayString::Remove") ); for ( size_t j = 0; j < m_nCount - nIndex -nRemove; j++) m_pItems[nIndex + j] = m_pItems[nIndex + nRemove + j]; m_nCount -= nRemove; } // removes item from array (by value) void wxArrayString::Remove(const wxString& sz) { int iIndex = Index(sz); wxCHECK_RET( iIndex != wxNOT_FOUND, wxT("removing inexistent element in wxArrayString::Remove") ); RemoveAt(iIndex); } // ---------------------------------------------------------------------------- // sorting // ---------------------------------------------------------------------------- // we need an adaptor as our predicates use qsort() convention and so return // negative, null or positive value depending on whether the first item is less // than, equal to or greater than the other one while we need a real boolean // predicate now that we use std::sort() struct wxSortPredicateAdaptor { wxSortPredicateAdaptor(wxArrayString::CompareFunction compareFunction) : m_compareFunction(compareFunction) { } bool operator()(const wxString& first, const wxString& second) const { return (*m_compareFunction)(first, second) < 0; } wxArrayString::CompareFunction m_compareFunction; }; void wxArrayString::Sort(CompareFunction compareFunction) { wxCHECK_RET( !m_autoSort, wxT("can't use this method with sorted arrays") ); std::sort(m_pItems, m_pItems + m_nCount, wxSortPredicateAdaptor(compareFunction)); } struct wxSortPredicateAdaptor2 { wxSortPredicateAdaptor2(wxArrayString::CompareFunction2 compareFunction) : m_compareFunction(compareFunction) { } bool operator()(const wxString& first, const wxString& second) const { return (*m_compareFunction)(const_cast(&first), const_cast(&second)) < 0; } wxArrayString::CompareFunction2 m_compareFunction; }; void wxArrayString::Sort(CompareFunction2 compareFunction) { std::sort(m_pItems, m_pItems + m_nCount, wxSortPredicateAdaptor2(compareFunction)); } void wxArrayString::Sort(bool reverseOrder) { if ( reverseOrder ) std::sort(m_pItems, m_pItems + m_nCount, std::greater()); else // normal sort std::sort(m_pItems, m_pItems + m_nCount); } bool wxArrayString::operator==(const wxArrayString& a) const { if ( m_nCount != a.m_nCount ) return false; for ( size_t n = 0; n < m_nCount; n++ ) { if ( Item(n) != a[n] ) return false; } return true; } #endif // !wxUSE_STD_CONTAINERS // =========================================================================== // wxJoin and wxSplit // =========================================================================== #include "wx/tokenzr.h" wxString wxJoin(const wxArrayString& arr, const wxChar sep, const wxChar escape) { size_t count = arr.size(); if ( count == 0 ) return wxEmptyString; wxString str; // pre-allocate memory using the estimation of the average length of the // strings in the given array: this is very imprecise, of course, but // better than nothing str.reserve(count*(arr[0].length() + arr[count-1].length()) / 2); if ( escape == wxT('\0') ) { // escaping is disabled: for ( size_t i = 0; i < count; i++ ) { if ( i ) str += sep; str += arr[i]; } } else // use escape character { for ( size_t n = 0; n < count; n++ ) { if ( n ) str += sep; for ( wxString::const_iterator i = arr[n].begin(), end = arr[n].end(); i != end; ++i ) { const wxChar ch = *i; if ( ch == sep ) str += escape; // escape this separator str += ch; } } } str.Shrink(); // release extra memory if we allocated too much return str; } wxArrayString wxSplit(const wxString& str, const wxChar sep, const wxChar escape) { if ( escape == wxT('\0') ) { // simple case: we don't need to honour the escape character return wxStringTokenize(str, sep, wxTOKEN_RET_EMPTY_ALL); } wxArrayString ret; wxString curr; wxChar prev = wxT('\0'); for ( wxString::const_iterator i = str.begin(), end = str.end(); i != end; ++i ) { const wxChar ch = *i; if ( ch == sep ) { if ( prev == escape ) { // remove the escape character and don't consider this // occurrence of 'sep' as a real separator *curr.rbegin() = sep; } else // real separator { ret.push_back(curr); curr.clear(); } } else // normal character { curr += ch; } prev = ch; } // add the last token if ( !curr.empty() || prev == sep ) ret.Add(curr); return ret; }