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****************************************************************************/
#ifndef QVECTOR_H
#define QVECTOR_H
#include <QtCore/qiterator.h>
#include <QtCore/qatomic.h>
#include <QtCore/qalgorithms.h>
#include <QtCore/qlist.h>
#ifndef QT_NO_STL
#include <iterator>
#include <vector>
#endif
#include <stdlib.h>
#include <string.h>
QT_BEGIN_HEADER
QT_BEGIN_NAMESPACE
QT_MODULE(Core)
struct Q_CORE_EXPORT QVectorData
{
QBasicAtomicInt ref;
int alloc;
int size;
#if defined(QT_ARCH_SPARC) && defined(Q_CC_GNU) && defined(__LP64__) && defined(QT_BOOTSTRAPPED)
// workaround for bug in gcc 3.4.2
uint sharable;
uint capacity;
uint reserved;
#else
uint sharable : 1;
uint capacity : 1;
uint reserved : 30;
#endif
static QVectorData shared_null;
// ### Qt 5: rename to 'allocate()'. The current name causes problems for
// some debugges when the QVector is member of a class within an unnamed namespace.
// ### Qt 5: can be removed completely. (Ralf)
static QVectorData *malloc(int sizeofTypedData, int size, int sizeofT, QVectorData *init);
static QVectorData *allocate(int size, int alignment);
static QVectorData *reallocate(QVectorData *old, int newsize, int oldsize, int alignment);
static void free(QVectorData *data, int alignment);
static int grow(int sizeofTypedData, int size, int sizeofT, bool excessive);
};
template <typename T>
struct QVectorTypedData : private QVectorData
{ // private inheritance as we must not access QVectorData member thought QVectorTypedData
// as this would break strict aliasing rules. (in the case of shared_null)
T array[1];
static inline void free(QVectorTypedData<T> *x, int alignment) { QVectorData::free(static_cast<QVectorData *>(x), alignment); }
};
class QRegion;
template <typename T>
class QVector
{
typedef QVectorTypedData<T> Data;
union {
QVectorData *d;
#if defined(Q_CC_SUN) && (__SUNPRO_CC <= 0x550)
QVectorTypedData<T> *p;
#else
Data *p;
#endif
};
public:
inline QVector() : d(&QVectorData::shared_null) { d->ref.ref(); }
explicit QVector(int size);
QVector(int size, const T &t);
inline QVector(const QVector<T> &v) : d(v.d) { d->ref.ref(); if (!d->sharable) detach_helper(); }
inline ~QVector() { if (!d) return; if (!d->ref.deref()) free(p); }
QVector<T> &operator=(const QVector<T> &v);
bool operator==(const QVector<T> &v) const;
inline bool operator!=(const QVector<T> &v) const { return !(*this == v); }
inline int size() const { return d->size; }
inline bool isEmpty() const { return d->size == 0; }
void resize(int size);
inline int capacity() const { return d->alloc; }
void reserve(int size);
inline void squeeze() { realloc(d->size, d->size); d->capacity = 0; }
inline void detach() { if (d->ref != 1) detach_helper(); }
inline bool isDetached() const { return d->ref == 1; }
inline void setSharable(bool sharable) { if (!sharable) detach(); d->sharable = sharable; }
inline T *data() { detach(); return p->array; }
inline const T *data() const { return p->array; }
inline const T *constData() const { return p->array; }
void clear();
const T &at(int i) const;
T &operator[](int i);
const T &operator[](int i) const;
void append(const T &t);
void prepend(const T &t);
void insert(int i, const T &t);
void insert(int i, int n, const T &t);
void replace(int i, const T &t);
void remove(int i);
void remove(int i, int n);
QVector<T> &fill(const T &t, int size = -1);
int indexOf(const T &t, int from = 0) const;
int lastIndexOf(const T &t, int from = -1) const;
bool contains(const T &t) const;
int count(const T &t) const;
#ifdef QT_STRICT_ITERATORS
class iterator {
public:
T *i;
typedef std::random_access_iterator_tag iterator_category;
typedef qptrdiff difference_type;
typedef T value_type;
typedef T *pointer;
typedef T &reference;
inline iterator() : i(0) {}
inline iterator(T *n) : i(n) {}
inline iterator(const iterator &o): i(o.i){}
inline T &operator*() const { return *i; }
inline T *operator->() const { return i; }
inline T &operator[](int j) const { return *(i + j); }
inline bool operator==(const iterator &o) const { return i == o.i; }
inline bool operator!=(const iterator &o) const { return i != o.i; }
inline bool operator<(const iterator& other) const { return i < other.i; }
inline bool operator<=(const iterator& other) const { return i <= other.i; }
inline bool operator>(const iterator& other) const { return i > other.i; }
inline bool operator>=(const iterator& other) const { return i >= other.i; }
inline iterator &operator++() { ++i; return *this; }
inline iterator operator++(int) { T *n = i; ++i; return n; }
inline iterator &operator--() { i--; return *this; }
inline iterator operator--(int) { T *n = i; i--; return n; }
inline iterator &operator+=(int j) { i+=j; return *this; }
inline iterator &operator-=(int j) { i-=j; return *this; }
inline iterator operator+(int j) const { return iterator(i+j); }
inline iterator operator-(int j) const { return iterator(i-j); }
inline int operator-(iterator j) const { return i - j.i; }
};
friend class iterator;
class const_iterator {
public:
T *i;
typedef std::random_access_iterator_tag iterator_category;
typedef qptrdiff difference_type;
typedef T value_type;
typedef const T *pointer;
typedef const T &reference;
inline const_iterator() : i(0) {}
inline const_iterator(T *n) : i(n) {}
inline const_iterator(const const_iterator &o): i(o.i) {}
inline explicit const_iterator(const iterator &o): i(o.i) {}
inline const T &operator*() const { return *i; }
inline const T *operator->() const { return i; }
inline const T &operator[](int j) const { return *(i + j); }
inline bool operator==(const const_iterator &o) const { return i == o.i; }
inline bool operator!=(const const_iterator &o) const { return i != o.i; }
inline bool operator<(const const_iterator& other) const { return i < other.i; }
inline bool operator<=(const const_iterator& other) const { return i <= other.i; }
inline bool operator>(const const_iterator& other) const { return i > other.i; }
inline bool operator>=(const const_iterator& other) const { return i >= other.i; }
inline const_iterator &operator++() { ++i; return *this; }
inline const_iterator operator++(int) { T *n = i; ++i; return n; }
inline const_iterator &operator--() { i--; return *this; }
inline const_iterator operator--(int) { T *n = i; i--; return n; }
inline const_iterator &operator+=(int j) { i+=j; return *this; }
inline const_iterator &operator-=(int j) { i-=j; return *this; }
inline const_iterator operator+(int j) const { return const_iterator(i+j); }
inline const_iterator operator-(int j) const { return const_iterator(i-j); }
inline int operator-(const_iterator j) const { return i - j.i; }
};
friend class const_iterator;
#else
// STL-style
typedef T* iterator;
typedef const T* const_iterator;
#endif
inline iterator begin() { detach(); return p->array; }
inline const_iterator begin() const { return p->array; }
inline const_iterator constBegin() const { return p->array; }
inline iterator end() { detach(); return p->array + d->size; }
inline const_iterator end() const { return p->array + d->size; }
inline const_iterator constEnd() const { return p->array + d->size; }
iterator insert(iterator before, int n, const T &x);
inline iterator insert(iterator before, const T &x) { return insert(before, 1, x); }
iterator erase(iterator begin, iterator end);
inline iterator erase(iterator pos) { return erase(pos, pos+1); }
// more Qt
inline int count() const { return d->size; }
inline T& first() { Q_ASSERT(!isEmpty()); return *begin(); }
inline const T &first() const { Q_ASSERT(!isEmpty()); return *begin(); }
inline T& last() { Q_ASSERT(!isEmpty()); return *(end()-1); }
inline const T &last() const { Q_ASSERT(!isEmpty()); return *(end()-1); }
inline bool startsWith(const T &t) const { return !isEmpty() && first() == t; }
inline bool endsWith(const T &t) const { return !isEmpty() && last() == t; }
QVector<T> mid(int pos, int length = -1) const;
T value(int i) const;
T value(int i, const T &defaultValue) const;
// STL compatibility
typedef T value_type;
typedef value_type* pointer;
typedef const value_type* const_pointer;
typedef value_type& reference;
typedef const value_type& const_reference;
typedef qptrdiff difference_type;
typedef iterator Iterator;
typedef const_iterator ConstIterator;
typedef int size_type;
inline void push_back(const T &t) { append(t); }
inline void push_front(const T &t) { prepend(t); }
void pop_back() { Q_ASSERT(!isEmpty()); erase(end()-1); }
void pop_front() { Q_ASSERT(!isEmpty()); erase(begin()); }
inline bool empty() const
{ return d->size == 0; }
inline T& front() { return first(); }
inline const_reference front() const { return first(); }
inline reference back() { return last(); }
inline const_reference back() const { return last(); }
// comfort
QVector<T> &operator+=(const QVector<T> &l);
inline QVector<T> operator+(const QVector<T> &l) const
{ QVector n = *this; n += l; return n; }
inline QVector<T> &operator+=(const T &t)
{ append(t); return *this; }
inline QVector<T> &operator<< (const T &t)
{ append(t); return *this; }
inline QVector<T> &operator<<(const QVector<T> &l)
{ *this += l; return *this; }
QList<T> toList() const;
static QVector<T> fromList(const QList<T> &list);
#ifndef QT_NO_STL
static inline QVector<T> fromStdVector(const std::vector<T> &vector)
{ QVector<T> tmp; qCopy(vector.begin(), vector.end(), std::back_inserter(tmp)); return tmp; }
inline std::vector<T> toStdVector() const
{ std::vector<T> tmp; qCopy(constBegin(), constEnd(), std::back_inserter(tmp)); return tmp; }
#endif
private:
friend class QRegion; // Optimization for QRegion::rects()
void detach_helper();
QVectorData *malloc(int alloc);
void realloc(int size, int alloc);
void free(Data *d);
int sizeOfTypedData() {
// this is more or less the same as sizeof(Data), except that it doesn't
// count the padding at the end
return reinterpret_cast<const char *>(&(reinterpret_cast<const Data *>(this))->array[1]) - reinterpret_cast<const char *>(this);
}
inline int alignOfTypedData() const
{
#ifdef Q_ALIGNOF
return qMax<int>(sizeof(void*), Q_ALIGNOF(Data));
#else
return 0;
#endif
}
};
template <typename T>
void QVector<T>::detach_helper()
{ realloc(d->size, d->alloc); }
template <typename T>
void QVector<T>::reserve(int asize)
{ if (asize > d->alloc) realloc(d->size, asize); if (d->ref == 1) d->capacity = 1; }
template <typename T>
void QVector<T>::resize(int asize)
{ realloc(asize, (asize > d->alloc || (!d->capacity && asize < d->size && asize < (d->alloc >> 1))) ?
QVectorData::grow(sizeOfTypedData(), asize, sizeof(T), QTypeInfo<T>::isStatic)
: d->alloc); }
template <typename T>
inline void QVector<T>::clear()
{ *this = QVector<T>(); }
template <typename T>
inline const T &QVector<T>::at(int i) const
{ Q_ASSERT_X(i >= 0 && i < d->size, "QVector<T>::at", "index out of range");
return p->array[i]; }
template <typename T>
inline const T &QVector<T>::operator[](int i) const
{ Q_ASSERT_X(i >= 0 && i < d->size, "QVector<T>::operator[]", "index out of range");
return p->array[i]; }
template <typename T>
inline T &QVector<T>::operator[](int i)
{ Q_ASSERT_X(i >= 0 && i < d->size, "QVector<T>::operator[]", "index out of range");
return data()[i]; }
template <typename T>
inline void QVector<T>::insert(int i, const T &t)
{ Q_ASSERT_X(i >= 0 && i <= d->size, "QVector<T>::insert", "index out of range");
insert(begin() + i, 1, t); }
template <typename T>
inline void QVector<T>::insert(int i, int n, const T &t)
{ Q_ASSERT_X(i >= 0 && i <= d->size, "QVector<T>::insert", "index out of range");
insert(begin() + i, n, t); }
template <typename T>
inline void QVector<T>::remove(int i, int n)
{ Q_ASSERT_X(i >= 0 && n >= 0 && i + n <= d->size, "QVector<T>::remove", "index out of range");
erase(begin() + i, begin() + i + n); }
template <typename T>
inline void QVector<T>::remove(int i)
{ Q_ASSERT_X(i >= 0 && i < d->size, "QVector<T>::remove", "index out of range");
erase(begin() + i, begin() + i + 1); }
template <typename T>
inline void QVector<T>::prepend(const T &t)
{ insert(begin(), 1, t); }
template <typename T>
inline void QVector<T>::replace(int i, const T &t)
{
Q_ASSERT_X(i >= 0 && i < d->size, "QVector<T>::replace", "index out of range");
const T copy(t);
data()[i] = copy;
}
template <typename T>
QVector<T> &QVector<T>::operator=(const QVector<T> &v)
{
v.d->ref.ref();
if (!d->ref.deref())
free(p);
d = v.d;
if (!d->sharable)
detach_helper();
return *this;
}
template <typename T>
inline QVectorData *QVector<T>::malloc(int aalloc)
{
QVectorData *vectordata = QVectorData::allocate(sizeOfTypedData() + (aalloc - 1) * sizeof(T), alignOfTypedData());
Q_CHECK_PTR(vectordata);
return vectordata;
}
template <typename T>
QVector<T>::QVector(int asize)
{
d = malloc(asize);
d->ref = 1;
d->alloc = d->size = asize;
d->sharable = true;
d->capacity = false;
if (QTypeInfo<T>::isComplex) {
T* b = p->array;
T* i = p->array + d->size;
while (i != b)
new (--i) T;
} else {
qMemSet(p->array, 0, asize * sizeof(T));
}
}
template <typename T>
QVector<T>::QVector(int asize, const T &t)
{
d = malloc(asize);
d->ref = 1;
d->alloc = d->size = asize;
d->sharable = true;
d->capacity = false;
T* i = p->array + d->size;
while (i != p->array)
new (--i) T(t);
}
template <typename T>
void QVector<T>::free(Data *x)
{
if (QTypeInfo<T>::isComplex) {
T* b = x->array;
union { QVectorData *d; Data *p; } u;
u.p = x;
T* i = b + u.d->size;
while (i-- != b)
i->~T();
}
x->free(x, alignOfTypedData());
}
template <typename T>
void QVector<T>::realloc(int asize, int aalloc)
{
Q_ASSERT(asize <= aalloc);
T *pOld;
T *pNew;
union { QVectorData *d; Data *p; } x;
x.d = d;
if (QTypeInfo<T>::isComplex && asize < d->size && d->ref == 1 ) {
// call the destructor on all objects that need to be
// destroyed when shrinking
pOld = p->array + d->size;
pNew = p->array + asize;
while (asize < d->size) {
(--pOld)->~T();
d->size--;
}
}
if (aalloc != d->alloc || d->ref != 1) {
// (re)allocate memory
if (QTypeInfo<T>::isStatic) {
x.d = malloc(aalloc);
Q_CHECK_PTR(x.p);
x.d->size = 0;
} else if (d->ref != 1) {
x.d = malloc(aalloc);
Q_CHECK_PTR(x.p);
if (QTypeInfo<T>::isComplex) {
x.d->size = 0;
} else {
::memcpy(x.p, p, sizeOfTypedData() + (qMin(aalloc, d->alloc) - 1) * sizeof(T));
x.d->size = d->size;
}
} else {
QT_TRY {
QVectorData *mem = QVectorData::reallocate(d, sizeOfTypedData() + (aalloc - 1) * sizeof(T),
sizeOfTypedData() + (d->alloc - 1) * sizeof(T), alignOfTypedData());
Q_CHECK_PTR(mem);
x.d = d = mem;
x.d->size = d->size;
} QT_CATCH (const std::bad_alloc &) {
if (aalloc > d->alloc) // ignore the error in case we are just shrinking.
QT_RETHROW;
}
}
x.d->ref = 1;
x.d->alloc = aalloc;
x.d->sharable = true;
x.d->capacity = d->capacity;
x.d->reserved = 0;
}
if (QTypeInfo<T>::isComplex) {
QT_TRY {
pOld = p->array + x.d->size;
pNew = x.p->array + x.d->size;
// copy objects from the old array into the new array
const int toMove = qMin(asize, d->size);
while (x.d->size < toMove) {
new (pNew++) T(*pOld++);
x.d->size++;
}
// construct all new objects when growing
while (x.d->size < asize) {
new (pNew++) T;
x.d->size++;
}
} QT_CATCH (...) {
free(x.p);
QT_RETHROW;
}
} else if (asize > x.d->size) {
// initialize newly allocated memory to 0
qMemSet(x.p->array + x.d->size, 0, (asize - x.d->size) * sizeof(T));
}
x.d->size = asize;
if (d != x.d) {
if (!d->ref.deref())
free(p);
d = x.d;
}
}
template<typename T>
Q_OUTOFLINE_TEMPLATE T QVector<T>::value(int i) const
{
if (i < 0 || i >= d->size) {
return T();
}
return p->array[i];
}
template<typename T>
Q_OUTOFLINE_TEMPLATE T QVector<T>::value(int i, const T &defaultValue) const
{
return ((i < 0 || i >= d->size) ? defaultValue : p->array[i]);
}
template <typename T>
void QVector<T>::append(const T &t)
{
if (d->ref != 1 || d->size + 1 > d->alloc) {
const T copy(t);
realloc(d->size, QVectorData::grow(sizeOfTypedData(), d->size + 1, sizeof(T),
QTypeInfo<T>::isStatic));
if (QTypeInfo<T>::isComplex)
new (p->array + d->size) T(copy);
else
p->array[d->size] = copy;
} else {
if (QTypeInfo<T>::isComplex)
new (p->array + d->size) T(t);
else
p->array[d->size] = t;
}
++d->size;
}
template <typename T>
Q_TYPENAME QVector<T>::iterator QVector<T>::insert(iterator before, size_type n, const T &t)
{
int offset = int(before - p->array);
if (n != 0) {
const T copy(t);
if (d->ref != 1 || d->size + n > d->alloc)
realloc(d->size, QVectorData::grow(sizeOfTypedData(), d->size + n, sizeof(T),
QTypeInfo<T>::isStatic));
if (QTypeInfo<T>::isStatic) {
T *b = p->array + d->size;
T *i = p->array + d->size + n;
while (i != b)
new (--i) T;
i = p->array + d->size;
T *j = i + n;
b = p->array + offset;
while (i != b)
*--j = *--i;
i = b+n;
while (i != b)
*--i = copy;
} else {
T *b = p->array + offset;
T *i = b + n;
memmove(i, b, (d->size - offset) * sizeof(T));
while (i != b)
new (--i) T(copy);
}
d->size += n;
}
return p->array + offset;
}
template <typename T>
Q_TYPENAME QVector<T>::iterator QVector<T>::erase(iterator abegin, iterator aend)
{
int f = int(abegin - p->array);
int l = int(aend - p->array);
int n = l - f;
detach();
if (QTypeInfo<T>::isComplex) {
qCopy(p->array+l, p->array+d->size, p->array+f);
T *i = p->array+d->size;
T* b = p->array+d->size-n;
while (i != b) {
--i;
i->~T();
}
} else {
memmove(p->array + f, p->array + l, (d->size-l)*sizeof(T));
}
d->size -= n;
return p->array + f;
}
template <typename T>
bool QVector<T>::operator==(const QVector<T> &v) const
{
if (d->size != v.d->size)
return false;
if (d == v.d)
return true;
T* b = p->array;
T* i = b + d->size;
T* j = v.p->array + d->size;
while (i != b)
if (!(*--i == *--j))
return false;
return true;
}
template <typename T>
QVector<T> &QVector<T>::fill(const T &from, int asize)
{
const T copy(from);
resize(asize < 0 ? d->size : asize);
if (d->size) {
T *i = p->array + d->size;
T *b = p->array;
while (i != b)
*--i = copy;
}
return *this;
}
template <typename T>
QVector<T> &QVector<T>::operator+=(const QVector &l)
{
int newSize = d->size + l.d->size;
realloc(d->size, newSize);
T *w = p->array + newSize;
T *i = l.p->array + l.d->size;
T *b = l.p->array;
while (i != b) {
if (QTypeInfo<T>::isComplex)
new (--w) T(*--i);
else
*--w = *--i;
}
d->size = newSize;
return *this;
}
template <typename T>
int QVector<T>::indexOf(const T &t, int from) const
{
if (from < 0)
from = qMax(from + d->size, 0);
if (from < d->size) {
T* n = p->array + from - 1;
T* e = p->array + d->size;
while (++n != e)
if (*n == t)
return n - p->array;
}
return -1;
}
template <typename T>
int QVector<T>::lastIndexOf(const T &t, int from) const
{
if (from < 0)
from += d->size;
else if (from >= d->size)
from = d->size-1;
if (from >= 0) {
T* b = p->array;
T* n = p->array + from + 1;
while (n != b) {
if (*--n == t)
return n - b;
}
}
return -1;
}
template <typename T>
bool QVector<T>::contains(const T &t) const
{
T* b = p->array;
T* i = p->array + d->size;
while (i != b)
if (*--i == t)
return true;
return false;
}
template <typename T>
int QVector<T>::count(const T &t) const
{
int c = 0;
T* b = p->array;
T* i = p->array + d->size;
while (i != b)
if (*--i == t)
++c;
return c;
}
template <typename T>
Q_OUTOFLINE_TEMPLATE QVector<T> QVector<T>::mid(int pos, int length) const
{
if (length < 0)
length = size() - pos;
if (pos == 0 && length == size())
return *this;
QVector<T> copy;
if (pos + length > size())
length = size() - pos;
for (int i = pos; i < pos + length; ++i)
copy += at(i);
return copy;
}
template <typename T>
Q_OUTOFLINE_TEMPLATE QList<T> QVector<T>::toList() const
{
QList<T> result;
for (int i = 0; i < size(); ++i)
result.append(at(i));
return result;
}
template <typename T>
Q_OUTOFLINE_TEMPLATE QVector<T> QList<T>::toVector() const
{
QVector<T> result(size());
for (int i = 0; i < size(); ++i)
result[i] = at(i);
return result;
}
template <typename T>
QVector<T> QVector<T>::fromList(const QList<T> &list)
{
return list.toVector();
}
template <typename T>
QList<T> QList<T>::fromVector(const QVector<T> &vector)
{
return vector.toList();
}
Q_DECLARE_SEQUENTIAL_ITERATOR(Vector)
Q_DECLARE_MUTABLE_SEQUENTIAL_ITERATOR(Vector)
/*
### Qt 5:
### This needs to be removed for next releases of Qt. It is a workaround for vc++ because
### Qt exports QPolygon and QPolygonF that inherit QVector<QPoint> and
### QVector<QPointF> respectively.
*/
#ifdef Q_CC_MSVC
QT_BEGIN_INCLUDE_NAMESPACE
#include <QtCore/QPointF>
#include <QtCore/QPoint>
QT_END_INCLUDE_NAMESPACE
#if defined(QT_BUILD_CORE_LIB)
#define Q_TEMPLATE_EXTERN
#else
#define Q_TEMPLATE_EXTERN extern
#endif
# pragma warning(push) /* MSVC 6.0 doesn't care about the disabling in qglobal.h (why?), so do it here */
# pragma warning(disable: 4231) /* nonstandard extension used : 'extern' before template explicit instantiation */
Q_TEMPLATE_EXTERN template class Q_CORE_EXPORT QVector<QPointF>;
Q_TEMPLATE_EXTERN template class Q_CORE_EXPORT QVector<QPoint>;
# pragma warning(pop)
#endif
QT_END_NAMESPACE
QT_END_HEADER
#endif // QVECTOR_H