/**************************************************************************** ** ** ** Implementation of QGArray class ** ** Created : 930906 ** ** Copyright (C) 1992-2000 Trolltech AS. All rights reserved. ** ** This file is part of the tools module of the Qt GUI Toolkit. ** ** This file may be distributed under the terms of the Q Public License ** as defined by Trolltech AS of Norway and appearing in the file ** LICENSE.QPL included in the packaging of this file. ** ** This file may be distributed and/or modified under the terms of the ** GNU General Public License version 2 as published by the Free Software ** Foundation and appearing in the file LICENSE.GPL included in the ** packaging of this file. ** ** Licensees holding valid Qt Enterprise Edition or Qt Professional Edition ** licenses may use this file in accordance with the Qt Commercial License ** Agreement provided with the Software. ** ** This file is provided AS IS with NO WARRANTY OF ANY KIND, INCLUDING THE ** WARRANTY OF DESIGN, MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. ** ** See http://www.trolltech.com/pricing.html or email sales@trolltech.com for ** information about Qt Commercial License Agreements. ** See http://www.trolltech.com/qpl/ for QPL licensing information. ** See http://www.trolltech.com/gpl/ for GPL licensing information. ** ** Contact info@trolltech.com if any conditions of this licensing are ** not clear to you. ** **********************************************************************/ #define QGARRAY_CPP #include "qgarray.h" #include "qstring.h" #include #define USE_MALLOC // comment to use new/delete #undef NEW #undef DELETE #if defined(USE_MALLOC) #define NEW(type,size) ((type*)malloc(size*sizeof(type))) #define DELETE(array) (free((char*)array)) #else #define NEW(type,size) (new type[size]) #define DELETE(array) (delete[] array) #define DONT_USE_REALLOC // comment to use realloc() #endif // NOT REVISED /*! \class QShared qshared.h \brief The QShared struct is internally used for implementing shared classes. It only contains a reference count and member functions to increment and decrement it. Shared classes normally have internal classes that inherit QShared and add the shared data. \sa \link shclass.html Shared Classes\endlink */ /*! \class QGArray qgarray.h \brief The QGArray class is an internal class for implementing the QArray class. QGArray is a strictly internal class that acts as base class for the QArray template array. It contains an array of bytes and has no notion of an array element. */ /*! \internal Constructs a null array. */ QGArray::QGArray() { shd = newData(); CHECK_PTR( shd ); } /*! \internal Dummy constructor; does not allocate any data. This constructor does not initialize any array data so subclasses must do it. The intention is to make the code more efficient. */ QGArray::QGArray( int, int ) { } /*! \internal Constructs an array with room for \e size bytes. */ QGArray::QGArray( int size ) { if ( size < 0 ) { #if defined(CHECK_RANGE) qWarning( "QGArray: Cannot allocate array with negative length" ); #endif size = 0; } shd = newData(); CHECK_PTR( shd ); if ( size == 0 ) // zero length return; shd->data = NEW(char,size); CHECK_PTR( shd->data ); shd->len = size; } /*! \internal Constructs a shallow copy of \e a. */ QGArray::QGArray( const QGArray &a ) { shd = a.shd; shd->ref(); } /*! \internal Dereferences the array data and deletes it if this was the last reference. */ QGArray::~QGArray() { if ( shd && shd->deref() ) { // delete when last reference if ( shd->data ) // is lost DELETE(shd->data); deleteData( shd ); } } /*! \fn QGArray &QGArray::operator=( const QGArray &a ) \internal Assigns a shallow copy of \e a to this array and returns a reference to this array. Equivalent to assign(). */ /*! \fn void QGArray::detach() \internal Detaches this array from shared array data. */ /*! \fn char *QGArray::data() const \internal Returns a pointer to the actual array data. */ /*! \fn uint QGArray::nrefs() const \internal Returns the reference count. */ /*! \fn uint QGArray::size() const \internal Returns the size of the array, in bytes. */ /*! \internal Returns TRUE if this array is equal to \e a, otherwise FALSE. The comparison is bitwise, of course. */ bool QGArray::isEqual( const QGArray &a ) const { if ( size() != a.size() ) // different size return FALSE; if ( data() == a.data() ) // has same data return TRUE; return (size() ? memcmp( data(), a.data(), size() ) : 0) == 0; } /*! \internal Resizes the array to \e newsize bytes. */ bool QGArray::resize( uint newsize ) { if ( newsize == shd->len ) // nothing to do return TRUE; if ( newsize == 0 ) { // remove array duplicate( 0, 0 ); return TRUE; } if ( shd->data ) { // existing data #if defined(DONT_USE_REALLOC) char *newdata = NEW(char,newsize); // manual realloc memcpy( newdata, shd->data, QMIN(shd->len,newsize) ); DELETE(shd->data); shd->data = newdata; #else shd->data = (char *)realloc( shd->data, newsize ); #endif } else { shd->data = NEW(char,newsize); } CHECK_PTR( shd->data ); if ( !shd->data ) // no memory return FALSE; shd->len = newsize; return TRUE; } /*! \internal Fills the array with the repeated occurrences of \e d, which is \e sz bytes long. If \e len is specified as different from -1, then the array will be resized to \e len*sz before it is filled. Returns TRUE if successful, or FALSE if the memory cannot be allocated (only when \e len != -1). \sa resize() */ bool QGArray::fill( const char *d, int len, uint sz ) { if ( len < 0 ) len = shd->len/sz; // default: use array length else if ( !resize( len*sz ) ) return FALSE; if ( sz == 1 ) // 8 bit elements memset( data(), *d, len ); else if ( sz == 4 ) { // 32 bit elements register Q_INT32 *x = (Q_INT32*)data(); Q_INT32 v = *((Q_INT32*)d); while ( len-- ) *x++ = v; } else if ( sz == 2 ) { // 16 bit elements register Q_INT16 *x = (Q_INT16*)data(); Q_INT16 v = *((Q_INT16*)d); while ( len-- ) *x++ = v; } else { // any other size elements register char *x = data(); while ( len-- ) { // more complicated memcpy( x, d, sz ); x += sz; } } return TRUE; } /*! \internal Shallow copy. Dereference the current array and references the data contained in \e a instead. Returns a reference to this array. \sa operator=() */ QGArray &QGArray::assign( const QGArray &a ) { a.shd->ref(); // avoid 'a = a' if ( shd->deref() ) { // delete when last reference if ( shd->data ) // is lost DELETE(shd->data); deleteData( shd ); } shd = a.shd; return *this; } /*! \internal Shallow copy. Dereference the current array and references the array data \e d, which contains \e len bytes. Returns a reference to this array. Do not delete \e d later, because QGArray takes care of that. */ QGArray &QGArray::assign( const char *d, uint len ) { if ( shd->count > 1 ) { // disconnect this shd->count--; shd = newData(); CHECK_PTR( shd ); } else { if ( shd->data ) DELETE(shd->data); } shd->data = (char *)d; shd->len = len; return *this; } /*! \internal Deep copy. Dereference the current array and obtains a copy of the data contained in \e a instead. Returns a reference to this array. \sa assign(), operator=() */ QGArray &QGArray::duplicate( const QGArray &a ) { if ( a.shd == shd ) { // a.duplicate(a) ! if ( shd->count > 1 ) { shd->count--; register array_data *n = newData(); CHECK_PTR( n ); if ( (n->len=shd->len) ) { n->data = NEW(char,n->len); CHECK_PTR( n->data ); if ( n->data ) memcpy( n->data, shd->data, n->len ); } else { n->data = 0; } shd = n; } return *this; } char *oldptr = 0; if ( shd->count > 1 ) { // disconnect this shd->count--; shd = newData(); CHECK_PTR( shd ); } else { // delete after copy was made oldptr = shd->data; } if ( a.shd->len ) { // duplicate data shd->data = NEW(char,a.shd->len); CHECK_PTR( shd->data ); if ( shd->data ) memcpy( shd->data, a.shd->data, a.shd->len ); } else { shd->data = 0; } shd->len = a.shd->len; if ( oldptr ) DELETE(oldptr); return *this; } /*! \internal Deep copy. Dereferences the current array and obtains a copy of the array data \e d instead. Returns a reference to this array. \sa assign(), operator=() */ QGArray &QGArray::duplicate( const char *d, uint len ) { char *data; if ( d == 0 || len == 0 ) { data = 0; len = 0; } else { if ( shd->count == 1 && shd->len == len ) { memcpy( shd->data, d, len ); // use same buffer return *this; } data = NEW(char,len); CHECK_PTR( data ); memcpy( data, d, len ); } if ( shd->count > 1 ) { // detach shd->count--; shd = newData(); CHECK_PTR( shd ); } else { // just a single reference if ( shd->data ) DELETE(shd->data); } shd->data = data; shd->len = len; return *this; } /*! \internal Resizes this array to \e len bytes and copies the \e len bytes at address \e into it. \warning This function disregards the reference count mechanism. If other QGArrays reference the same data as this, all will be updated. */ void QGArray::store( const char *d, uint len ) { // store, but not deref resize( len ); memcpy( shd->data, d, len ); } /*! \fn array_data *QGArray::sharedBlock() const \internal Returns a pointer to the shared array block. \warning Do not use this function. Using it is begging for trouble. We dare not remove it, for fear of breaking code, but we \e strongly discourage new use of it. */ /*! \fn void QGArray::setSharedBlock( array_data *p ) \internal Sets the shared array block to \e p. \warning Do not use this function. Using it is begging for trouble. We dare not remove it, for fear of breaking code, but we \e strongly discourage new use of it. */ /*! \internal Sets raw data and returns a reference to the array. Dereferences the current array and sets the new array data to \e d and the new array size to \e len. Do not attempt to resize or re-assign the array data when raw data has been set. Call resetRawData(d,len) to reset the array. Setting raw data is useful because it set QArray data without allocating memory or copying data. Example of intended use: \code static uchar bindata[] = { 231, 1, 44, ... }; QByteArray a; a.setRawData( bindata, sizeof(bindata) ); // a points to bindata QDataStream s( a, IO_ReadOnly ); // open on a's data s >> ; // read raw bindata s.close(); a.resetRawData( bindata, sizeof(bindata) ); // finished \endcode Example of misuse (do not do this): \code static uchar bindata[] = { 231, 1, 44, ... }; QByteArray a, b; a.setRawData( bindata, sizeof(bindata) ); // a points to bindata a.resize( 8 ); // will crash b = a; // will crash a[2] = 123; // might crash // forget to resetRawData - will crash \endcode \warning If you do not call resetRawData(), QGArray will attempt to deallocate or reallocate the raw data, which might not be too good. Be careful. */ QGArray &QGArray::setRawData( const char *d, uint len ) { duplicate( 0, 0 ); // set null data shd->data = (char *)d; shd->len = len; return *this; } /*! \internal Resets raw data. The arguments must be the data and length that were passed to setRawData(). This is for consistency checking. */ void QGArray::resetRawData( const char *d, uint len ) { if ( d != shd->data || len != shd->len ) { #if defined(CHECK_STATE) qWarning( "QGArray::resetRawData: Inconsistent arguments" ); #endif return; } shd->data = 0; shd->len = 0; } /*! \internal Finds the first occurrence of \e d in the array from position \e index, where \e sz is the size of the \e d element. Note that \e index is given in units of \e sz, not bytes. This function only compares whole cells, not bytes. */ int QGArray::find( const char *d, uint index, uint sz ) const { index *= sz; if ( index >= shd->len ) { #if defined(CHECK_RANGE) qWarning( "QGArray::find: Index %d out of range", index/sz ); #endif return -1; } register uint i; uint ii; switch ( sz ) { case 1: { // 8 bit elements register char *x = data() + index; char v = *d; for ( i=index; ilen; i++ ) { if ( *x++ == v ) break; } ii = i; } break; case 2: { // 16 bit elements register Q_INT16 *x = (Q_INT16*)(data() + index); Q_INT16 v = *((Q_INT16*)d); for ( i=index; ilen; i+=2 ) { if ( *x++ == v ) break; } ii = i/2; } break; case 4: { // 32 bit elements register Q_INT32 *x = (Q_INT32*)(data() + index); Q_INT32 v = *((Q_INT32*)d); for ( i=index; ilen; i+=4 ) { if ( *x++ == v ) break; } ii = i/4; } break; default: { // any size elements for ( i=index; ilen; i+=sz ) { if ( memcmp( d, &shd->data[i], sz ) == 0 ) break; } ii = i/sz; } break; } return ilen ? (int)ii : -1; } /*! \internal Returns the number of occurrences of \e d in the array, where \e sz is the size of the \e d element. This function only compares whole cells, not bytes. */ int QGArray::contains( const char *d, uint sz ) const { register uint i = shd->len; int count = 0; switch ( sz ) { case 1: { // 8 bit elements register char *x = data(); char v = *d; while ( i-- ) { if ( *x++ == v ) count++; } } break; case 2: { // 16 bit elements register Q_INT16 *x = (Q_INT16*)data(); Q_INT16 v = *((Q_INT16*)d); i /= 2; while ( i-- ) { if ( *x++ == v ) count++; } } break; case 4: { // 32 bit elements register Q_INT32 *x = (Q_INT32*)data(); Q_INT32 v = *((Q_INT32*)d); i /= 4; while ( i-- ) { if ( *x++ == v ) count++; } } break; default: { // any size elements for ( i=0; ilen; i+=sz ) { if ( memcmp(d, &shd->data[i], sz) == 0 ) count++; } } break; } return count; } static int cmp_item_size = 0; #if defined(Q_C_CALLBACKS) extern "C" { #endif static int cmp_arr( const void *n1, const void *n2 ) { return ( n1 && n2 ) ? memcmp( n1, n2, cmp_item_size ) : (int)((intptr_t)n1 - (intptr_t)n2); // Qt 3.0: Add a virtual compareItems() method and call that instead } #if defined(Q_C_CALLBACKS) } #endif /*! \internal Sort the array. */ void QGArray::sort( uint sz ) { int numItems = size() / sz; if ( numItems < 2 ) return; cmp_item_size = sz; qsort( shd->data, numItems, sz, cmp_arr ); } /*! \internal Binary search; assumes sorted array */ int QGArray::bsearch( const char *d, uint sz ) const { int numItems = size() / sz; if ( !numItems ) return -1; cmp_item_size = sz; char* r = (char*)::bsearch( d, shd->data, numItems, sz, cmp_arr ); if ( !r ) return -1; while( (r >= shd->data + sz) && (cmp_arr( r - sz, d ) == 0) ) r -= sz; // search to first of equal elements; bsearch is undef return (int)(( r - shd->data ) / sz); } /*! \fn char *QGArray::at( uint index ) const \internal Returns a pointer to the byte at offset \e index in the array. */ /*! \internal Expand the array if necessary, and copies (the first part of) its contents from the \e index*zx bytes at \e d. Returns TRUE if the operation succeeds, FALSE if it runs out of memory. \warning This function disregards the reference count mechanism. If other QGArrays reference the same data as this, all will be changed. */ bool QGArray::setExpand( uint index, const char *d, uint sz ) { index *= sz; if ( index >= shd->len ) { if ( !resize( index+sz ) ) // no memory return FALSE; } memcpy( data() + index, d, sz ); return TRUE; } /*! \internal Prints a warning message if at() or [] is given a bad index. */ void QGArray::msg_index( uint index ) { #if defined(CHECK_RANGE) qWarning( "QGArray::at: Absolute index %d out of range", index ); #else Q_UNUSED( index ) #endif } /*! \internal Returns a new shared array block. */ QGArray::array_data * QGArray::newData() { return new array_data; } /*! \internal Deletes the shared array block. */ void QGArray::deleteData( array_data *p ) { delete p; p = 0; }