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#include <QtTest/QtTest>
#include "q3valuevector.h"
#include <qiodevice.h>
#include <q3valuevector.h>
//TESTED_CLASS=
//TESTED_FILES=
class tst_Q3ValueVector : public QObject
{
Q_OBJECT
public:
tst_Q3ValueVector();
virtual ~tst_Q3ValueVector();
public slots:
void init();
void cleanup();
private slots:
void acc_01();
void operator_equalEqual();
void operator_assign();
// a test for assignment from a std::list has been omitted
void size();
void empty();
void capacity_data();
void capacity();
// ommiting test for const iterators (for begin() and end())
void begin();
void end();
// omitting test for const reference
void at();
// omitting test for const reference
void operator_index();
void front();
void back();
void push_back();
void pop_back();
void insert();
void reserve_data();
void reserve();
void resize();
void clear();
};
static QByteArray toBA( const Q3ValueVector<int> &vv )
{
QByteArray ba;
QDataStream ds( &ba, IO_ReadWrite );
(void)vv;
ds << vv;
return ba;
}
tst_Q3ValueVector::tst_Q3ValueVector()
{
}
tst_Q3ValueVector::~tst_Q3ValueVector()
{
}
void tst_Q3ValueVector::init()
{
// TODO: Add initialization code here.
// This will be executed immediately before each test is run.
}
void tst_Q3ValueVector::cleanup()
{
// TODO: Add cleanup code here.
// This will be executed immediately after each test is run.
}
void tst_Q3ValueVector::reserve_data()
{
capacity_data();
}
void tst_Q3ValueVector::capacity_data()
{
QTest::addColumn<QByteArray>("ba");
Q3ValueVector<int> a;
QTest::newRow( "data0" ) << toBA( a );
Q3ValueVector<int> b;
b.push_back( 1 );
b.push_back( 2 );
QTest::newRow( "data1" ) << toBA( b );
Q3ValueVector<int> c;
// let's try one that's rather large
for(int i = 0; i < 10000; i++)
c.push_back( i );
QTest::newRow( "data2" ) << toBA( c );
}
void tst_Q3ValueVector::acc_01()
{
// vectors
Q3ValueVector<int> v1;
QVERIFY( v1.empty() );
QVERIFY( v1.size() == 0 );
QVERIFY( v1.capacity() >= v1.size() );
Q3ValueVector<int> v2( v1 );
QVERIFY( v2.empty() );
QVERIFY( v2.size() == 0 );
QVERIFY( v2.capacity() >= v1.size() );
Q3ValueVector<int> v5( 5 );
QVERIFY( !v5.empty() );
QVERIFY( v5.size() == 5 );
QVERIFY( v5.capacity() >= 5 );
//operator=
Q3ValueVector<int> v4 = v2;
QVERIFY( v4.empty() );
QVERIFY( v4.size() == 0 );
QVERIFY( (int)v4.capacity() >= 0 );
// adding elements
v4.push_back( 1 );
v4.push_back( 2 );
v4.push_back( 3 );
QVERIFY( !v4.empty() );
QVERIFY( v2.empty() ); // should have detached
QVERIFY( v4.size() == 3 );
QVERIFY( v4.capacity() >= v4.size() );
v4.insert( v4.end(), 4 );
v4.insert( v4.begin(), 0 );
QVERIFY( !v4.empty() );
QVERIFY( v4.size() == 5 );
QVERIFY( v4.capacity() >= v4.size() );
QVERIFY( v4[0] == 0);
QVERIFY( v4[1] == 1);
QVERIFY( v4[2] == 2);
QVERIFY( v4[3] == 3);
QVERIFY( v4[4] == 4);
// swap
Q3ValueVector<int> tmp = v2;
v2 = v4;
v4 = tmp;
// v4.swap( v2 );
QVERIFY( v4.empty() );
QVERIFY( !v2.empty() );
QVERIFY( v2.size() == 5 );
QVERIFY( v2.capacity() >= v2.size() );
QVERIFY( v2[0] == 0);
QVERIFY( v2[1] == 1);
QVERIFY( v2[2] == 2);
QVERIFY( v2[3] == 3);
QVERIFY( v2[4] == 4);
// v2 Should contain 5 elements: 0,1,2,3,4
QVERIFY(v4.size() == 0); //Should contain no elements
// element access
Q3ValueVector<int> v3( 5 );
v3[0] = 0;
v3[1] = 1;
v3[2] = 2;
v3[3] = 3;
v3[4] = 4;
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3[4] == 4 );
bool ok = FALSE;
(void) v3.at( 1000, &ok );
QVERIFY( !ok );
int& j = v3.at( 2, &ok );
QVERIFY( ok );
QVERIFY( j == 2 );
// iterators
Q3ValueVector<int>::iterator it = v3.begin();
int k = 0;
for ( ; k < 5; ++k, ++it )
QVERIFY( *it == k );
QVERIFY( it == v3.end() );
--it;
for ( k = 4; k >= 0; --k, --it )
QVERIFY( *it == k );
QVERIFY( v3.front() == 0 );
QVERIFY( v3.back() == 4 );
// capacity stuff
v3.resize( 5 );
// Should contain 5 elements: 0,1,2,3,4
QVERIFY( v3.size() == 5 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3[4] == 4 );
v3.resize( 6 );
// Should now contain 6 elements: 0,1,2,3,4,0
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3[4] == 4 );
QVERIFY( v3[5] == 0 );
v3.reserve( 1000 );
QVERIFY( v3.size() == 6 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3[4] == 4 );
QVERIFY( v3.capacity() >= 1000 );
v3.back() = 5;
// Should contain 5 elements: 0,1,2,3,4
QVERIFY( v3.back() == 5 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3[4] == 4 );
v3.resize( 5 );
// Should contain 5 elements: 0,1,2,3,4
QVERIFY( v3.size() == 5 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3[4] == 4 );
QVERIFY( v3.capacity() >= 1000 );
it = v3.end();
v3.erase( --it );
// Should contain 4 elements: 0,1,2,3
QVERIFY( v3.size() == 4 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 1 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 3 );
QVERIFY( v3.capacity() >= 1000 );
it = v3.begin();
Q3ValueVector<int>::iterator it2 = v3.end();
v3.erase( ++it, --it2 );
// Should contain 2 elements: 0,3
QVERIFY( v3.size() == 2 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 3 );
QVERIFY( v3.capacity() >= 1000 );
it = v3.begin();
v3.insert( ++it, 9 );
// Should contain 3 elements: 0,9,3
QVERIFY( v3.size() == 3 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 9 );
QVERIFY( v3[2] == 3 );
QVERIFY( v3.capacity() >= 1000 );
it = v3.begin();
v3.insert( ++it, 4, 4 );
// Should contain 7 elements: 0,4,4,4,4,9,3
QVERIFY( v3.size() == 7 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 4 );
QVERIFY( v3[2] == 4 );
QVERIFY( v3[3] == 4 );
QVERIFY( v3[4] == 4 );
QVERIFY( v3[5] == 9 );
QVERIFY( v3[6] == 3 );
QVERIFY( v3.capacity() >= 1000 );
it = v3.begin();
v3.insert( ++it, 2000, 2 );
// Should contain 2007 elements: 0,2,2,...2,4,4,4,4,9,3
QVERIFY( v3.size() == 2007 );
it = qFind( v3.begin(), v3.end(), 3 );
it2 = v3.end();
QVERIFY( it == --it2 );
v3.resize( 4 );
// Should contain 4 elements: 0,2,2,2
QVERIFY( v3.size() == 4 );
QVERIFY( v3[0] == 0 );
QVERIFY( v3[1] == 2 );
QVERIFY( v3[2] == 2 );
QVERIFY( v3[3] == 2 );
QVERIFY( v3.capacity() >= 2007 );
it = v3.begin();
v3.insert( ++it, 2000, 2 );
v3.push_back( 9 );
v3.push_back( 3 );
it = v3.begin();
it2 = v3.end();
v3.erase( ++it, ----it2 );
// Should contain 3 elements: 0,9,3
QVERIFY( v3.size() == 3 );
v3.pop_back();
// Should contain 2 elements: 0,9
QVERIFY( v3.size() == 2 );
/*
// instantiate other member functions
Q3ValueVector<int>::const_iterator cit = v3.begin();
cit = v3.end();
Q3ValueVector<int>::size_type max_size = v3.max_size();
std::cout << "max size of vector:" << max_size << std::endl;
const int& ci = v3.at( 1 );
const int& ci2 = v3[1];
const int& ci3 = v3.front();
const int& ci4 = v3.back();
v3.clear();
QStringList l1, l2;
l1 << "Weis" << "Ettrich" << "Arnt" << "Sue";
l2 << "Torben" << "Matthias";
qCopy( l2.begin(), l2.end(), l1.begin() );
Q3ValueVector<QString> v( l1.size(), "Dave" );
qCopy( l2.begin(), l2.end(), v.begin() );
std::for_each( v.begin(), v.end(), qDebug );
std::vector<int> stdvec( 5, 100 );
Q3ValueVector<int> cvec( stdvec );
std::cout << "Should contain 5 elements: 100,100,100,100,100" << std::endl;
print( cvec );
Q3ValueVector<int> cvec2 = stdvec;
std::cout << "Should contain 5 elements: 100,100,100,100,100" << std::endl;
print( cvec2 );
QFile f( "file.dta" );
f.open( QIODevice::WriteOnly );
QDataStream s( &f );
s << cvec2;
f.close();
f.open( QIODevice::ReadOnly );
Q3ValueVector<int> in;
s >> in;
std::cout << "Should contain 5 elements: 100,100,100,100,100" << std::endl;
print( in );
*/
}
void tst_Q3ValueVector::operator_equalEqual()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 10 );
a.push_back( 100 );
Q3ValueVector<int> b;
b.push_back( 1 );
b.push_back( 10 );
b.push_back( 100 );
QVERIFY( a == b );
QVERIFY( b == a );
a.push_back( 1000 );
QVERIFY( !(a == b) );
QVERIFY( !(b == a) );
}
void tst_Q3ValueVector::operator_assign()
{
// test assignment using an int
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
Q3ValueVector<int> b = a;
QVERIFY( (a == b) );
}
void tst_Q3ValueVector::size()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
QCOMPARE( (int)a.size(), 2 );
}
void tst_Q3ValueVector::empty()
{
Q3ValueVector<int> a;
QVERIFY( a.empty() );
}
void tst_Q3ValueVector::capacity()
{
QFETCH( QByteArray, ba );
Q3ValueVector<int> vector;
QDataStream ds( &ba, IO_ReadWrite );
ds >> vector;
QVERIFY( vector.capacity() >= vector.size() );
}
void tst_Q3ValueVector::begin()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
Q3ValueVector<int>::iterator it_a = a.begin();
QCOMPARE( (*it_a), 1 );
// now try it for an empty vector; per the documentation begin() should equal end()
Q3ValueVector<int> b;
Q3ValueVector<int>::iterator it_b = b.begin();
QVERIFY( it_b == b.end() );
}
void tst_Q3ValueVector::end()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
Q3ValueVector<int>::iterator it_a = a.end();
QCOMPARE( (*(--it_a)), 2 );
Q3ValueVector<int> b;
Q3ValueVector<int>::iterator it_b = b.end();
QVERIFY( it_b == b.begin() );
}
void tst_Q3ValueVector::at()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
bool ok;
QVERIFY( a.at( 0, &ok ) == 1 && ok == true );
QVERIFY( a.at( 1, &ok ) == 2 && ok == true );
(void)a.at( 3, &ok );
QCOMPARE( ok, false );
}
void tst_Q3ValueVector::operator_index()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
QCOMPARE( a[0], 1 );
QCOMPARE( a[1], 2 );
}
void tst_Q3ValueVector::front()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
QCOMPARE(a.front(), 1 );
}
void tst_Q3ValueVector::back()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
QCOMPARE(a.back(), 2 );
}
void tst_Q3ValueVector::push_back()
{
Q3ValueVector<int> a;
a.push_back( 1 );
QVERIFY( a.back() == 1 && a.size() == 1 );
a.push_back( 2 );
QVERIFY( a.back() == 2 && a.size() == 2 );
}
void tst_Q3ValueVector::pop_back()
{
Q3ValueVector<int> a;
a.push_back( 1 );
a.push_back( 2 );
a.pop_back();
QVERIFY( a.back() == 1 && a.size() == 1 );
a.pop_back();
QVERIFY( a.empty() );
}
void tst_Q3ValueVector::insert()
{
// insert at the beginning
Q3ValueVector<int> a;
a.insert( a.begin(), 1 );
QCOMPARE( a[0], 1 );
// insert at the end
a.insert( a.end(), 2 );
QCOMPARE( a[1], 2 );
// insert in the middle
Q3ValueVector<int>::iterator it_a = a.begin();
a.insert( ++it_a, 3 );
QCOMPARE( a[1], 3 );
// now testing the overloaded insert() which takes an
// argument for the number of items to insert
// we'll insert two of each value
Q3ValueVector<int> b;
b.insert( b.begin(), 2, 1 );
QCOMPARE( b[0], 1 );
QCOMPARE( b[1], 1 );
// insert at the end
b.insert( b.end(), 2, 2 );
QCOMPARE( b[2], 2 );
QCOMPARE( b[3], 2 );
// insert in the middle
Q3ValueVector<int>::iterator it_b = b.begin();
b.insert( ++++it_b, 2, 3 );
QCOMPARE( b[2], 3 );
QCOMPARE( b[3], 3 );
}
void tst_Q3ValueVector::reserve()
{
QFETCH( QByteArray, ba );
Q3ValueVector<int> vector;
QDataStream ds( &ba, IO_ReadWrite );
ds >> vector;
Q3ValueVector<int>::size_type cap = vector.capacity();
// should do nothing
if( cap > 5 )
vector.reserve( vector.capacity() - 5 );
else
vector.reserve( 0 );
QVERIFY( vector.capacity() == cap );
// should make capacity() grow
vector.reserve( vector.capacity() + 5 );
QVERIFY( cap < vector.capacity() );
}
void tst_Q3ValueVector::resize()
{
Q3ValueVector<int> a;
a.resize( 2 );
QVERIFY( a.size() == 2 );
Q3ValueVector<int> b;
b.resize( 2, 42 );
QVERIFY( b.size() == 2 );
QCOMPARE( b[0], 42 );
QCOMPARE( b[1], 42 );
b.resize( 1 );
QVERIFY( b.size() == 1 );
b.resize( 4, 21 );
QCOMPARE( b[0], 42 );
QCOMPARE( b[1], 21 );
QCOMPARE( b[2], 21 );
QCOMPARE( b[3], 21 );
b.resize( 0 );
QVERIFY( b.empty() );
}
void tst_Q3ValueVector::clear()
{
Q3ValueVector<int> a;
a.clear();
QVERIFY( a.empty() );
a.push_back( 1 );
a.push_back( 2 );
a.clear();
QVERIFY( a.empty() );
}
QTEST_APPLESS_MAIN(tst_Q3ValueVector)
#include "tst_q3valuevector.moc"