void UT_array(const char* params)
{
Lumix::DefaultAllocator allocator;
Lumix::Array<int> array1(allocator);
LUMIX_EXPECT(array1.empty());
LUMIX_EXPECT(array1.size() == 0);
array1.reserve(128);
LUMIX_EXPECT(array1.size() == 0);
LUMIX_EXPECT(array1.capacity() == 128);
array1.reserve(256);
LUMIX_EXPECT(array1.capacity() == 256);
array1.reserve(64);
LUMIX_EXPECT(array1.capacity() >= 64);
LUMIX_EXPECT(array1.size() == 0);
for (int i = 0; i < 10; ++i)
{
array1.push(i * 2);
LUMIX_EXPECT(array1[i] == i * 2);
LUMIX_EXPECT(array1.back() == i * 2);
LUMIX_EXPECT(array1.indexOf(i*2) == i);
}
LUMIX_EXPECT(array1.size() == 10);
for (int i = 0; i < 10; ++i)
{
LUMIX_EXPECT(array1[i] == i * 2);
}
array1.clear();
LUMIX_EXPECT(array1.size() == 0);
LUMIX_EXPECT(array1.empty());
array1.resize(10);
LUMIX_EXPECT(array1.size() == 10);
array1.insert(0, 123);
LUMIX_EXPECT(array1.size() == 11);
LUMIX_EXPECT(array1[0] == 123);
Lumix::Array<int> array2(allocator);
array1.swap(array2);
LUMIX_EXPECT(array2.size() == 11);
LUMIX_EXPECT(array1.size() == 0);
}
int main(void){
//Stack allocated array raw1 and its stack allocated Base objects.
Base raw1[]={Base("one"),Base("two")};
//Heap allocated array raw2 and its heap allocated Base objects
Base* raw2=new Base[3];
std::cout<<"3 dtor calls will follow shortly."<<std::endl;
//forgetting to delete with [] operator will leak the all but raw2[0]
delete [] raw2;
std::cout<<"scoped_array init #1"<<std::endl;
boost::scoped_array<Base> array1(new Base[2]);
std::cout<<"scoped_array init #2"<<std::endl;
Base *raw3=new Base[2];
boost::scoped_array<Base> array2(raw3);
std::cout<<"exiting main..."<<std::endl;
return 0;
}
pilo::i32_t functional_test_construct(void* param)
{
M_UNUSED(param);
fixed_array<testing_pod_info,13> array;
if (array.size() != 0)
{
return -1;
}
testing_pod_info info[13];
for (int i = 0; i < 13; i++)
{
info[i].m_id = i;
}
fixed_array<testing_pod_info, 13> array1(info, 13, false);
if (array1.size() != 13)
{
return -20;
}
for (int i = 0; i < (int) array1.size(); i++)
{
if (array1[i].m_id != i)
{
return -1000 + i;
}
}
fixed_array<testing_pod_info, 12> array2(info, 13, true);
if (array2.size() != 12)
{
return -30;
}
for (int i = 0; i < (int) array2.size(); i++)
{
if (array2[i].m_id != i)
{
return -2000 + i;
}
}
return 0;
}
void
DynamicArrayTest::testCopyConstructor()
{
Container array(4, 123);
Container array2(array);
TEST_ASSERT_FALSE(array2.isEmpty());
TEST_ASSERT_EQUALS(array2.getSize(), 4U);
for (uint_fast16_t i = 0; i < array2.getSize(); ++i) {
TEST_ASSERT_EQUALS(array2[i], 123);
}
array[0] = 1;
TEST_ASSERT_EQUALS(array[0], 1);
TEST_ASSERT_EQUALS(array2[0], 123);
}
int main() {
RLIdentRegister* iregister = new RLIdentRegister();
RLType::setRegister(iregister);
RLArray array1(RLType::Number);
RLArray array2(RLType::Number);
array1.setElem(1,&RLNumber(100));
array1.setElem(2,&RLNumber(101));
array2.applyBinary(assign,&array1);
array1.getElem(1)->applyUnary(increment);
array1.print();
array2.print();
delete iregister;
}
void
MSVehicleContainer::addReplacing(const VehicleDepartureVector& x) {
if (isFull()) {
std::vector<VehicleDepartureVector> array2((array.size() - 1) * 2 + 1, VehicleDepartureVector());
for (int i = (int)array.size(); i-- > 0;) {
assert(i < (int)array2.size());
array2[i] = array[i];
}
array = array2;
}
// Percolate up
int hole = ++currentSize;
for (; hole > 1 && (x.first < array[ hole / 2 ].first); hole /= 2) {
assert(array.size() > (size_t) hole);
array[ hole ] = array[ hole / 2 ];
}
assert(array.size() > (size_t) hole);
array[ hole ] = x;
}
void testTransactionManager() {
printf("%s\n", "testTransactionManager");
// Insert a document in wal
BaseTransaction* wal = new BaseTransaction(_controller);
wal->dropNamespace("db", "mtx");
TransactionManager* manager = new TransactionManager(wal);
BSONObj testA;
testA.add("cod", 1);
testA.add("name", "William");
wal->insert("db", "mtx", &testA);
std::string* t1 = uuid();
StdTransaction* transaction = manager->getTransaction(*t1);
std::auto_ptr<BSONArrayObj> array(transaction->find("db", "mtx", "*", "$'cod' == 1"));
BSONObj* obj1up = array->get(0);
obj1up->add("lastName", "Shakespeare");
transaction->update("db", "mtx", obj1up);
std::auto_ptr<BSONArrayObj> array0(wal->find("db", "mtx", "*", "$'cod' == 1"));
BSONObj* origin1 = array0->get(0);
TEST_ASSERT(!origin1->has("lastName"));
std::auto_ptr<BSONArrayObj> array1(transaction->find("db", "mtx", "*", "$'cod' == 1"));
BSONObj* objtx1 = array1->get(0);
TEST_ASSERT(objtx1->has("lastName"));
transaction->commit();
manager->dropTransaction(*t1);
std::auto_ptr<BSONArrayObj> array2(wal->find("db", "mtx", "*", "$'cod' == 1"));
BSONObj* origin2 = array2->get(0);
TEST_ASSERT(origin2->has("lastName"));
delete t1;
delete manager;
printf("%s\n", "~testTransactionManager");
}
void Json_Parser::write_a_array(cocos2d::ValueVector &temp,rapidjson::Value &val2,rapidjson::Document::AllocatorType&allocator){
rapidjson::Value array2(rapidjson::kArrayType);
for (int i=0; i<temp.size(); i++) {
rapidjson::Value v;
if(temp.at(i).getType()==Value::Type::DOUBLE){
v.SetDouble(temp.at(i).asDouble());
val2.PushBack(v,allocator);
}
else if(temp.at(i).getType()==Value::Type::STRING){
v.SetString(temp.at(i).asString().c_str(),allocator);
val2.PushBack(v,allocator);
}
else if(temp.at(i).getType()==Value::Type::BOOLEAN){
v.SetBool(temp.at(i).asBool());
val2.PushBack(v,allocator);
}
else if(temp.at(i).getType()==Value::Type::INTEGER){
v.SetInt(temp.at(i).asInt());
val2.PushBack(v,allocator);
}
else if(temp.at(i).getType()==Value::Type::NONE){
v.SetNull();
val2.PushBack(v,allocator);
}
else if(temp.at(i).getType()==Value::Type::MAP){
ValueMap chmap=temp.at(i).asValueMap();
v.SetObject();
write_a_map(chmap,v,allocator);
val2.PushBack(v,allocator);
}
else if(temp.at(i).getType()==Value::Type::VECTOR){
ValueVector chvec=temp.at(i).asValueVector();
v.SetArray();
write_a_array(chvec, v, allocator);
val2.PushBack(v, allocator);
}
}
}
FX_BOOL color::equal(IFXJS_Context* cc, const CJS_Parameters& params, CJS_Value& vRet, CFX_WideString& sError)
{
v8::Isolate* isolate = GetIsolate(cc);
if (params.size() < 2) return FALSE;
CJS_Array array1(isolate), array2(isolate);
if (!params[0].ConvertToArray(array1)) return FALSE;
if (!params[1].ConvertToArray(array2)) return FALSE;
CPWL_Color color1;
CPWL_Color color2;
ConvertArrayToPWLColor(array1, color1);
ConvertArrayToPWLColor(array2, color2);
color1.ConvertColorType(color2.nColorType);
vRet = color1 == color2;
return TRUE;
}
void tst_QVectorArray::create4DArray()
{
QVector4DArray array;
QVERIFY(array.isEmpty());
array.append(1.0f, 2.0f, 3.0f, 4.0f);
array.append(3.0f, 4.0f, 5.0f, 6.0f);
array.append(QVector4D(5.0f, 6.0f, 7.0f, 8.0f));
QCOMPARE(array.size(), 3);
QVERIFY(array[0] == QVector4D(1.0f, 2.0f, 3.0f, 4.0f));
QVERIFY(array[1] == QVector4D(3.0f, 4.0f, 5.0f, 6.0f));
QVERIFY(array[2] == QVector4D(5.0f, 6.0f, 7.0f, 8.0f));
array.append(QVector4D(7.0f, 8.0f, 9.0f, 10.0f),
QVector4D(9.0f, 10.0f, 11.0f, 12.0f));
array.append(QVector4D(11.0f, 12.0f, 13.0f, 14.0f),
QVector4D(13.0f, 14.0f, 15.0f, 16.0f),
QVector4D(15.0f, 16.0f, 17.0f, 18.0f));
array.append(QVector4D(17.0f, 18.0f, 19.0f, 20.0f),
QVector4D(19.0f, 20.0f, 21.0f, 22.0f),
QVector4D(21.0f, 22.0f, 23.0f, 24.0f));
for (int index = 0; index < array.size(); ++index) {
QVERIFY(array[index] == QVector4D(index * 2 + 1,
index * 2 + 2,
index * 2 + 3,
index * 2 + 4));
}
QVector4DArray array2(34);
QCOMPARE(array2.size(), 34);
for (int index = 0; index < array2.size(); ++index)
QCOMPARE(array2[index], QVector4D(0.0f, 0.0f, 0.0f, 0.0f));
QVector4DArray array3(15, QVector4D(1.0f, 2.0f, 3.0f, 4.0f));
QCOMPARE(array3.size(), 15);
for (int index = 0; index < array3.size(); ++index)
QCOMPARE(array3[index], QVector4D(1.0f, 2.0f, 3.0f, 4.0f));
}
void tst_QVectorArray::create2DArray()
{
QVector2DArray array;
QVERIFY(array.isEmpty());
array.append(1.0f, 2.0f);
array.append(3.0f, 4.0f);
array.append(QVector2D(5.0f, 6.0f));
array.append(QPointF(7.0f, 8.0f));
array.append(QPoint(9, 10));
QCOMPARE(array.size(), 5);
QVERIFY(array[0] == QVector2D(1.0f, 2.0f));
QVERIFY(array[1] == QVector2D(3.0f, 4.0f));
QVERIFY(array[2] == QVector2D(5.0f, 6.0f));
QVERIFY(array[3] == QVector2D(7.0f, 8.0f));
QVERIFY(array[4] == QVector2D(9.0f, 10.0f));
array.append(QVector2D(11.0f, 12.0f), QVector2D(13.0f, 14.0f));
array.append(QVector2D(15.0f, 16.0f), QVector2D(17.0f, 18.0f),
QVector2D(19.0f, 20.0f));
array.append(QVector2D(21.0f, 22.0f), QVector2D(23.0f, 24.0f),
QVector2D(25.0f, 26.0f));
for (int index = 0; index < array.size(); ++index)
QVERIFY(array[index] == QVector2D(index * 2 + 1, index * 2 + 2));
QVector2DArray array2(34);
QCOMPARE(array2.size(), 34);
for (int index = 0; index < array2.size(); ++index)
QCOMPARE(array2[index], QVector2D(0.0f, 0.0f));
QVector2DArray array3(15, QVector2D(1.0f, 2.0f));
QCOMPARE(array3.size(), 15);
for (int index = 0; index < array3.size(); ++index)
QCOMPARE(array3[index], QVector2D(1.0f, 2.0f));
}
int main(int argc, char *argv[])
{
srand (time(NULL));
//kepek egyszeges meretenek beallitasa
int size = 25;
//a halo retegeinek es ezek mereteinek beallitasa
std::vector<int> array2(2);
array2[0] = size*size;
array2[1] = 43;
//az adatok betoltese
DataSet d = DataSet();
QString path = "../../TestLearning";
d.LoadData(size,path);
std::cout<< "Learning started" <<std::endl;
//a halo letrehozasa
Network net(array2);
//tanulas megkezdese
net.SGD(d,300,30,3,d);
std::cout<< "Learning finished" <<std::endl;
}
DEF_TEST(SkSLMemoryLayout430Test, r) {
SkSL::Context context;
SkSL::MemoryLayout layout(SkSL::MemoryLayout::k430_Standard);
// basic types
REPORTER_ASSERT(r, 4 == layout.size(*context.fFloat_Type));
REPORTER_ASSERT(r, 8 == layout.size(*context.fVec2_Type));
REPORTER_ASSERT(r, 12 == layout.size(*context.fVec3_Type));
REPORTER_ASSERT(r, 16 == layout.size(*context.fVec4_Type));
REPORTER_ASSERT(r, 4 == layout.size(*context.fInt_Type));
REPORTER_ASSERT(r, 8 == layout.size(*context.fIVec2_Type));
REPORTER_ASSERT(r, 12 == layout.size(*context.fIVec3_Type));
REPORTER_ASSERT(r, 16 == layout.size(*context.fIVec4_Type));
REPORTER_ASSERT(r, 1 == layout.size(*context.fBool_Type));
REPORTER_ASSERT(r, 2 == layout.size(*context.fBVec2_Type));
REPORTER_ASSERT(r, 3 == layout.size(*context.fBVec3_Type));
REPORTER_ASSERT(r, 4 == layout.size(*context.fBVec4_Type));
REPORTER_ASSERT(r, 16 == layout.size(*context.fMat2x2_Type));
REPORTER_ASSERT(r, 32 == layout.size(*context.fMat2x4_Type));
REPORTER_ASSERT(r, 48 == layout.size(*context.fMat3x3_Type));
REPORTER_ASSERT(r, 32 == layout.size(*context.fMat4x2_Type));
REPORTER_ASSERT(r, 64 == layout.size(*context.fMat4x4_Type));
REPORTER_ASSERT(r, 4 == layout.alignment(*context.fFloat_Type));
REPORTER_ASSERT(r, 8 == layout.alignment(*context.fVec2_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fVec3_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fVec4_Type));
REPORTER_ASSERT(r, 4 == layout.alignment(*context.fInt_Type));
REPORTER_ASSERT(r, 8 == layout.alignment(*context.fIVec2_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fIVec3_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fIVec4_Type));
REPORTER_ASSERT(r, 1 == layout.alignment(*context.fBool_Type));
REPORTER_ASSERT(r, 2 == layout.alignment(*context.fBVec2_Type));
REPORTER_ASSERT(r, 4 == layout.alignment(*context.fBVec3_Type));
REPORTER_ASSERT(r, 4 == layout.alignment(*context.fBVec4_Type));
REPORTER_ASSERT(r, 8 == layout.alignment(*context.fMat2x2_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fMat2x4_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fMat3x3_Type));
REPORTER_ASSERT(r, 8 == layout.alignment(*context.fMat4x2_Type));
REPORTER_ASSERT(r, 16 == layout.alignment(*context.fMat4x4_Type));
// struct 1
std::vector<SkSL::Type::Field> fields1;
fields1.emplace_back(SkSL::Modifiers(), SkString("a"), context.fVec3_Type.get());
SkSL::Type s1(SkSL::Position(), SkString("s1"), fields1);
REPORTER_ASSERT(r, 16 == layout.size(s1));
REPORTER_ASSERT(r, 16 == layout.alignment(s1));
fields1.emplace_back(SkSL::Modifiers(), SkString("b"), context.fFloat_Type.get());
SkSL::Type s2(SkSL::Position(), SkString("s2"), fields1);
REPORTER_ASSERT(r, 16 == layout.size(s2));
REPORTER_ASSERT(r, 16 == layout.alignment(s2));
fields1.emplace_back(SkSL::Modifiers(), SkString("c"), context.fBool_Type.get());
SkSL::Type s3(SkSL::Position(), SkString("s3"), fields1);
REPORTER_ASSERT(r, 32 == layout.size(s3));
REPORTER_ASSERT(r, 16 == layout.alignment(s3));
// struct 2
std::vector<SkSL::Type::Field> fields2;
fields2.emplace_back(SkSL::Modifiers(), SkString("a"), context.fInt_Type.get());
SkSL::Type s4(SkSL::Position(), SkString("s4"), fields2);
REPORTER_ASSERT(r, 4 == layout.size(s4));
REPORTER_ASSERT(r, 4 == layout.alignment(s4));
fields2.emplace_back(SkSL::Modifiers(), SkString("b"), context.fVec3_Type.get());
SkSL::Type s5(SkSL::Position(), SkString("s5"), fields2);
REPORTER_ASSERT(r, 32 == layout.size(s5));
REPORTER_ASSERT(r, 16 == layout.alignment(s5));
// arrays
SkSL::Type array1(SkString("float[4]"), SkSL::Type::kArray_Kind, *context.fFloat_Type, 4);
REPORTER_ASSERT(r, 16 == layout.size(array1));
REPORTER_ASSERT(r, 4 == layout.alignment(array1));
REPORTER_ASSERT(r, 4 == layout.stride(array1));
SkSL::Type array2(SkString("vec4[4]"), SkSL::Type::kArray_Kind, *context.fVec4_Type, 4);
REPORTER_ASSERT(r, 64 == layout.size(array2));
REPORTER_ASSERT(r, 16 == layout.alignment(array2));
REPORTER_ASSERT(r, 16 == layout.stride(array2));
}
int
run_main (int, ACE_TCHAR *[])
{
ACE_START_TEST (ACE_TEXT ("Collection_Test"));
deletion_func NO_DFUNC = (deletion_func)0;
DummyFunctor dummyfunc;
{
UNBOUNDED_SET unbounded_set;
unbounded_set.insert (UglyThing ((void*)&unbounded_set, NO_DFUNC));
unbounded_set.insert (UglyThing ((void*)&dummyfunc, NO_DFUNC));
{
for (UNBOUNDED_SET::iterator iterator = unbounded_set.begin ();
iterator != unbounded_set.end ();
++iterator)
{
ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("%x,%x\n"),
(*iterator).alloc_, (*iterator).dfunc_));
}
}
unbounded_set.insert (UglyThing (0, NO_DFUNC));
unbounded_set.remove (UglyThing ((void*)&dummyfunc, NO_DFUNC));
{
UNBOUNDED_SET_ITERATOR iterator (unbounded_set);
while (!iterator.done ())
{
DATA *data = 0;
iterator.next (data);
ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("%x,%x\n"),
data->alloc_, data->dfunc_));
iterator.advance ();
}
}
iterate_const (unbounded_set);
unbounded_set.reset ();
{
DATA *data;
UNBOUNDED_SET_ITERATOR i (unbounded_set);
while (i.next (data) != 0)
{
ACE_DEBUG ((LM_DEBUG, "%x,%x\n", data->alloc_, data->dfunc_));
i.advance ();
}
}
iterate_const (unbounded_set);
}
{
ARRAY array;
}
{
ARRAY array (0);
}
{
ARRAY array1;
array1.size (2);
array1[0] = 4;
array1[1] = 4;
ARRAY array2 (2, 4);
ARRAY array3 (array2);
ARRAY array4;
array4 = array2;
ACE_TEST_ASSERT (array1 == array2);
ACE_TEST_ASSERT (array1 == array3);
ACE_TEST_ASSERT (array1 == array4);
{
for (size_t i = 0;
i != array1.size ();
++i)
{
ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("%d\n"),
array1[i]));
ACE_TEST_ASSERT (array1[i] == 4);
}
}
{
ARRAY_ITERATOR iterator (array1);
while (!iterator.done ())
{
ARRAY_DATA *data = 0;
iterator.next (data);
ACE_DEBUG ((LM_DEBUG, ACE_TEXT ("%d\n"),
(*data)));
ACE_TEST_ASSERT (*data == 4);
iterator.advance ();
}
}
}
ACE_END_TEST;
return 0;
}
int main()
{
Cimage array;
Cimage darray[10];
Cimage array2("test.img");
int nDim1 = 1024;
short int *piInt;
int i;
int nWhere[2];
array.oHeader.nList();
array2.oHeader.nList();
// Test nGetPixel, nPutPixel;
(void) array2.nGetDimensions(&nWhere[0], &nWhere[1]);
nWhere[0] = nWhere[0] / 2;
nWhere[1] = nWhere[1] / 2;
short int iPixel;
(void) array2.nGetPixel(nWhere, &iPixel);
cout << "Pixel at " << nWhere[0] << ", " << nWhere[1] << " is "
<< iPixel << ".\n";
iPixel = 9999;
(void) array2.nSetPixel(nWhere, iPixel);
(void) array2.nGetPixel(nWhere, &iPixel);
cout << "Pixel at " << nWhere[0] << ", " << nWhere[1] << " is now "
<< iPixel << ".\n\n";
(void) array2.nSetNextPixel(nWhere);
for (i=0; i < 10; i++)
cout << "Next pixel is : " << array2.iGetNextPixel() << endl;
cout << endl;
(void) array2.nSetNextPixel(nWhere);
for (i=0; i < 10; i++) array2.vSetNextPixel(iPixel);
(void) array2.nSetNextPixel(nWhere);
for (i=0; i < 10; i++)
cout << "Next pixel is : " << array2.iGetNextPixel() << endl;
// for (i=0; i< 10; i++) {
// nDim1 = darray[i].nRead("test.img");
// cout << "Status from darray[i].nRead: " << nDim1 << ".\n";
// }
nDim1 = array.nRead("test.img");
cout << "Status from array.nRead: " << nDim1 << ".\n";
array.oHeader.nList();
cout << "Try a read without a file name!\n";
nDim1 = array2.nRead();
cout << "Status from array2.nRead: " << nDim1 << ".\n";
// Test Cimage::nList
int nRect[4];// = {200, 300, 5, 10}; // fast, slow start; fast, slow extents
do {
cout << "Input center, widths of rectangle to list: ";
cin >> nRect[0] >> nRect[1] >> nRect[2] >> nRect[3];
array2.nList(nRect);
} while (nRect[3] != 0);
// Test prfGetPixel
(void) array2.nGetDimensions(&nWhere[0], &nWhere[1]);
nWhere[0] = nWhere[0] / 2;
nWhere[1] = nWhere[1] / 2;
float fTemp = (array2.*array2.prfGetPixel)(nWhere[0]+i, nWhere[1]+i);
for (i = 0; i < 10; i++)
{
cout << "Pixel at " << nWhere[0]+i << ", " << nWhere[1]+i << " is "
<< (array2.*array2.prfGetPixel)(nWhere[0]+i, nWhere[1]+i) << ".\n\n";
}
// Test Cimage::nGetRect, 3rd ctor and nWrite
do {
cout << "Input origin and extents of subimage to copy to new image: ";
cin >> nRect[0] >> nRect[1] >> nRect[2] >> nRect[3];
// short int *piShort = new (short int) [nRect[2]*nRect[3]];
short *piShort = new short[nRect[2]*nRect[3]];
nDim1 = array2.nGetRect(nRect, (char **)&piShort);
if (nDim1 == 0) {
Cimage *image1 = new Cimage(nRect[2], nRect[3], eImage_I2, piShort);
cout << "\n\nListing of image1.oHeader\n"; image1->oHeader.nList();
nDim1 = image1->nWrite();
delete image1;
}
else
cout << "Error in nGetRect\n";
delete [] piShort;
} while (nRect[3] != 0);
{
Cimage *image2 = new Cimage("test.img");
cout << "\n\nListing of image2.oHeader\n"; image2->oHeader.nList();
delete image2;
}
{
Cimage *image3 = new Cimage("");
cout << "\n\nListing of image3.oHeader\n"; image3->oHeader.nList();
delete image3;
}
array2.oHeader.nList();
array.nWrite("writetest.img");
delete piInt;
short int* piData;
piData = array.The_Data.pi;
for (i = 0; i < array.nGetDimension(); i++)
*piData++ = 100;
array.nWrite();
return 0;
}
bool run ()
{
bool passed = true;
/* create vector with random numbers */
const size_t M = 10;
std::vector<atomic<size_t>> flattened;
typedef std::vector<std::vector<size_t>* > ArrayArray;
ArrayArray array2(M);
size_t K = 0;
for (size_t i=0; i<M; i++) {
const size_t N = rand() % 10;
K += N;
array2[i] = new std::vector<size_t>(N);
for (size_t j=0; j<N; j++)
(*array2[i])[j] = rand() % 10;
}
/* array to test global index */
std::vector<atomic<size_t>> verify_k(K);
for (size_t i=0; i<K; i++) verify_k[i].store(0);
ParallelForForPrefixSumState<size_t> state(array2,size_t(1));
/* dry run only counts */
size_t S = parallel_for_for_prefix_sum( state, array2, size_t(0), [&](std::vector<size_t>* v, const range<size_t>& r, size_t k, const size_t base) -> size_t
{
size_t s = 0;
for (size_t i=r.begin(); i<r.end(); i++) {
s += (*v)[i];
verify_k[k++]++;
}
return s;
}, [](size_t v0, size_t v1) { return v0+v1; });
/* create properly sized output array */
flattened.resize(S);
memset(flattened.data(),0,sizeof(atomic<size_t>)*S);
/* now we actually fill the flattened array */
parallel_for_for_prefix_sum( state, array2, size_t(0), [&](std::vector<size_t>* v, const range<size_t>& r, size_t k, const size_t base) -> size_t
{
size_t s = 0;
for (size_t i=r.begin(); i<r.end(); i++) {
for (size_t j=0; j<(*v)[i]; j++) {
flattened[base+s+j]++;
}
s += (*v)[i];
verify_k[k++]++;
}
return s;
}, [](size_t v0, size_t v1) { return v0+v1; });
/* check global index */
for (size_t i=0; i<K; i++)
passed &= (verify_k[i] == 2);
/* check if each element was assigned exactly once */
for (size_t i=0; i<flattened.size(); i++)
passed &= (flattened[i] == 1);
/* delete arrays again */
for (size_t i=0; i<array2.size(); i++)
delete array2[i];
return passed;
}
//==============================================================================
int checkSharedOwnership(Epetra_Comm& Comm, bool verbose) {
// check to make sure each function returns 1 when it should
// check to make sure each function doesn't return 1 when it shouldn't
int ierr = 0;
// initialize Map
const int NumMyElements = 10;
const long long IndexBase = 0;
Epetra_Map Map1((long long) -1, NumMyElements, IndexBase, Comm);
// initialize Graphs
const int NumIndicesPerRow = 5;
Epetra_CrsGraph SoleOwner(Copy, Map1, Map1, NumIndicesPerRow);
Epetra_CrsGraph SharedOrig(Copy, Map1, Map1, NumIndicesPerRow);
Epetra_CrsGraph SharedOwner(SharedOrig);
// arrays used by Insert & Remove
Epetra_IntSerialDenseVector array1(2);
array1[0] = NumIndicesPerRow / 2;
array1[1] = array1[0] + 1;
Epetra_LongLongSerialDenseVector array2(NumIndicesPerRow);
for(int i = 0; i < NumIndicesPerRow; i++)
array2[i] = i;
// output variables (declaring them here lets us comment out indiv. tests)
int soleOutput, sharedOutput;
// InsertMyIndices
if(verbose) cout << "InsertMyIndices..." << endl;
soleOutput = SoleOwner.InsertMyIndices(0, 2, array1.Values());
sharedOutput = SharedOwner.InsertMyIndices(0, 2, array1.Values());
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// SortIndices
//if(verbose) cout << "SortIndices..." << endl;
//soleOutput = SoleOwner.SortIndices();
//sharedOutput = SharedOwner.SortIndices();
//EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
//EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
//if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// RemoveRedundantIndices
//if(verbose) cout << "RemoveRedundantIndices..." << endl;
//SoleOwner.InsertGlobalIndices(0, 1, array1.Values());
//SharedOwner.InsertGlobalIndices(0, 1, array1.Values());
//soleOutput = SoleOwner.RemoveRedundantIndices();
//sharedOutput = SharedOwner.RemoveRedundantIndices();
//EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
//EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
//if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// FillComplete (#1)
if(verbose) cout << "FillComplete..." << endl;
soleOutput = SoleOwner.FillComplete();
sharedOutput = SharedOwner.FillComplete();
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// OptimizeStorage
if(verbose) cout << "OptimizeStorage..." << endl;
soleOutput = SoleOwner.OptimizeStorage();
sharedOutput = SharedOwner.OptimizeStorage();
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 0), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// RemoveMyIndices (#1)
if(verbose) cout << "RemoveMyIndices..." << endl;
soleOutput = SoleOwner.RemoveMyIndices(0, 1, &array1[1]);
sharedOutput = SharedOwner.RemoveMyIndices(0, 1, &array1[1]);
EPETRA_TEST_ERR(!(soleOutput == -1), ierr);
EPETRA_TEST_ERR(!(sharedOutput == -1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// RemoveMyIndices (#2)
if(verbose) cout << "RemoveMyIndices(#2)..." << endl;
soleOutput = SoleOwner.RemoveMyIndices(0);
sharedOutput = SharedOwner.RemoveMyIndices(0);
EPETRA_TEST_ERR(!(soleOutput == -1), ierr);
EPETRA_TEST_ERR(!(sharedOutput == -1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// FillComplete (#2)
if(verbose) cout << "FillComplete(#2)..." << endl;
soleOutput = SoleOwner.FillComplete(SoleOwner.DomainMap(), SoleOwner.RangeMap());
sharedOutput = SharedOwner.FillComplete(SharedOwner.DomainMap(), SharedOwner.RangeMap());
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
{
// make new Graphs so that we can insert Global instead of Local
// inside of new scope so that we can use same names
Epetra_CrsGraph SoleOwnerG(Copy, Map1, NumIndicesPerRow);
Epetra_CrsGraph SharedOrigG(Copy, Map1, NumIndicesPerRow);
Epetra_CrsGraph SharedOwnerG(SharedOrig);
long long GlobalRow = SoleOwnerG.GRID64(0);
// InsertGlobalIndices
if(verbose) cout << "InsertGlobalIndices..." << endl;
soleOutput = SoleOwnerG.InsertGlobalIndices(GlobalRow, 2, array2.Values());
sharedOutput = SharedOwnerG.InsertGlobalIndices(GlobalRow, 2, array2.Values());
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// RemoveGlobalIndices (#1)
if(verbose) cout << "RemoveGlobalIndices..." << endl;
soleOutput = SoleOwnerG.RemoveGlobalIndices(GlobalRow, 1, &array2[1]);
sharedOutput = SharedOwnerG.RemoveGlobalIndices(GlobalRow, 1, &array2[1]);
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
// RemoveGlobalIndices (#2)
if(verbose) cout << "RemoveGlobalIndices(#2)..." << endl;
soleOutput = SoleOwnerG.RemoveGlobalIndices(GlobalRow);
sharedOutput = SharedOwnerG.RemoveGlobalIndices(GlobalRow);
EPETRA_TEST_ERR(!(soleOutput == 0), ierr);
EPETRA_TEST_ERR(!(sharedOutput == 1), ierr);
if(verbose && ierr > 0) cout << "soleOutput = " << soleOutput << " sharedOutput = " << sharedOutput << endl;
}
// *PROT* InsertIndices
// *PROT* MakeIndicesLocal
return(ierr);
}
void UnitTestDynamicArray::DoTest()
{
UNIT_TEST_BLOCK_START();
Dia::Core::Containers::DynamicArray<int> array(3);
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array.At(0) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_POSITIVE(array.Capacity() == 3, "DynamicArray()");
UNIT_TEST_POSITIVE(array.Size() == 0, "DynamicArray()");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
UNIT_TEST_ASSERT_EXPECTED_START();
int* ptr = NULL;
Dia::Core::Containers::DynamicArray<int> array0(ptr, 3);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> array1(&cArray1[0], 3);
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
int cArray2[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> array2(&cArray2[0], 3);
UNIT_TEST_POSITIVE(array2.Capacity() == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.IsFull(), "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.Size() == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.At(1) == 2, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.At(2) == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
int cArray3[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> array3(&cArray3[0], 2);
UNIT_TEST_POSITIVE(array3.Capacity() == 2, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.IsFull(), "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Size() == 2, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(0) == 1, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(1) == 2, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array3.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 3);
Dia::Core::Containers::DynamicArray<int> array1(tempArray1);
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray(ConstReference data, unsigned int _size)");
int cArray3[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> tempArray3(cArray3, 2);
Dia::Core::Containers::DynamicArray<int> array3(tempArray3);
UNIT_TEST_POSITIVE(array3.IsFull(), "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Capacity() == 2, "DynamicArray(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Size() == 2, "DynamicArray(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(0) == 1, "DynamicArray(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(1) == 2, "DynamicArray(ConstReference data, unsigned int _size)");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array3.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1(tempArray1);
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.Capacity() == 5, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.Size() == 5, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(3) == 4, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(4) == 5, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray(cArray, 5);
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(tempArray, 2, 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(tempArray, 5, 2);
UNIT_TEST_ASSERT_EXPECTED_END();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1(tempArray1, 1, 3);
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements");
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.At(0) == 2, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.At(1) == 3, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.At(2) == 4, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
int cArray2[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 5);
Dia::Core::Containers::DynamicArray<int> array2(tempArray2, 1, 2);
UNIT_TEST_POSITIVE(array2.IsFull(), "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements");
UNIT_TEST_POSITIVE(array2.Capacity() == 2, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array2.At(0) == 2, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array2.At(1) == 3, "DynamicArray(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 3);
Dia::Core::Containers::DynamicArray<int>::ConstIterator iter1(tempArray1.Begin());
Dia::Core::Containers::DynamicArray<int> array1(3, iter1);
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray(Iterator begin)");
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray(Iterator begin)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
int cArray2[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 2);
Dia::Core::Containers::DynamicArray<int> array2(3, tempArray2.BeginConst());
UNIT_TEST_POSITIVE(!array2.IsFull(), "DynamicArray(Iterator begin)");
UNIT_TEST_POSITIVE(array2.Capacity() == 3, "DynamicArray(Iterator begin)");
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
UNIT_TEST_POSITIVE(array2.At(1) == 2, "DynamicArray<T, size>::DynamicArray ( Iterator begin )");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 3);
Dia::Core::Containers::DynamicArray<int> array1(3, tempArray1.EndConst());
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray(ConstReverseIterator begin)");
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray(ConstReverseIterator begin)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array1.At(0) == 3, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array1.At(2) == 1, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
int cArray2[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 2);
Dia::Core::Containers::DynamicArray<int> array2(3, tempArray2.EndConst());
UNIT_TEST_POSITIVE(!array2.IsFull(), "DynamicArray(ConstReverseIterator begin)");
UNIT_TEST_POSITIVE(array2.Capacity() == 3, "DynamicArray(ConstReverseIterator begin)");
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array2.At(0) == 2, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array2.At(1) == 1, "DynamicArray<T, size>::DynamicArray ( ConstReverseIterator iter begin )");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
class AboveTwoFilter
{
public:
bool Evaluate(const int& currentIter)const
{
return (currentIter > 2);
};
};
AboveTwoFilter filter1;
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1(5, tempArray1.BeginConst(), filter1);
UNIT_TEST_POSITIVE(!array1.IsFull(), "DynamicArray(ConstIterator& iter, const EvaluateFunctor& filter)");
UNIT_TEST_POSITIVE(array1.Capacity() == 5, "DynamicArray(ConstIterator& iter, const EvaluateFunctor& filter)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray<T, size>::DynamicArray ( ConstIterator& iter, const EvaluateFunctor& filter )");
UNIT_TEST_POSITIVE(array1.At(0) == 3, "DynamicArray<T, size>::DynamicArray ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_POSITIVE(array1.At(1) == 4, "DynamicArray<T, size>::DynamicArray ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_POSITIVE(array1.At(2) == 5, "DynamicArray<T, size>::DynamicArray ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array1.At(3) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array1.At(4) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
UNIT_TEST_ASSERT_EXPECTED_START();
int* ptr = NULL;
Dia::Core::Containers::DynamicArray<int> array0(3);
array0.Assign(ptr, 3);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(&cArray1[0], 10);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(&cArray1[0], 3);
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
int cArray2[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.Assign(&cArray2[0], 3);
UNIT_TEST_POSITIVE(array2.IsFull(), "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.Capacity() == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.Size() == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.At(1) == 2, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array2.At(2) == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
int cArray3[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> array3(3);
array3.Assign(&cArray3[0], 2);
UNIT_TEST_POSITIVE(!array3.IsFull(), "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Capacity() == 3, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Size() == 2, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(0) == 1, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(1) == 2, "DynamicArray.Assign(ConstPointer pData, unsigned int _size)");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array3.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(cArray1, 10);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> tempArray1;
tempArray1.Reserve(3);
tempArray1.Assign(cArray1, 3);
Dia::Core::Containers::DynamicArray<int> array1(tempArray1);
UNIT_TEST_POSITIVE(array1.IsFull(), "DynamicArray.Assign(ConstReference pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Capacity() == 3, "DynamicArray.Assign(ConstReference pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
int cArray3[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> tempArray3;
tempArray3.Reserve(3);
tempArray3.Assign(cArray3, 2);
Dia::Core::Containers::DynamicArray<int> array3(tempArray3);
UNIT_TEST_POSITIVE(!array3.IsFull(), "DynamicArray.Assign(ConstReference pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Capacity() == 3, "DynamicArray.Assign(ConstReference pData, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.Size() == 2, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(0) == 1, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
UNIT_TEST_POSITIVE(array3.At(1) == 2, "DynamicArray.Assign(ConstReference data, unsigned int _size)");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array3.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1;
array1.Reserve(5);
array1.Assign(tempArray1);
UNIT_TEST_POSITIVE(array1.Size() == 5, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(3) == 4, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array1.At(4) == 5, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
int cArray2[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 5);
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.Assign(tempArray2);
UNIT_TEST_POSITIVE(array2.Size() == 3, "DynamicArray(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array2.At(1) == 2, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_POSITIVE(array2.At(2) == 3, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs)");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray(cArray, 5);
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(tempArray, 2, 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(tempArray, 5, 2);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(tempArray, 2, 10);
UNIT_TEST_ASSERT_EXPECTED_END();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(tempArray1, 1, 3);
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.At(0) == 2, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.At(1) == 3, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array1.At(2) == 4, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
int cArray2[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 5);
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.Assign(tempArray2, 1, 2);
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array2.At(0) == 2, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_POSITIVE(array2.At(1) == 3, "DynamicArray.Assign(const DynamicArray<T,_size>& rhs, unsigned int startIndex, unsigned int numberElements)");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 3);
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(tempArray1.BeginConst());
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
int cArray2[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 2);
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.Assign(tempArray2.BeginConst());
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
UNIT_TEST_POSITIVE(array2.At(1) == 2, "DynamicArray<T, size>::DynamicArray.Assign ( Iterator begin )");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[3] = {1, 2, 3};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 3);
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Assign(tempArray1.EndConst());
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array1.At(0) == 3, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array1.At(2) == 1, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
int cArray2[2] = {1, 2};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 2);
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.Assign(tempArray2.EndConst());
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array2.At(0) == 2, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
UNIT_TEST_POSITIVE(array2.At(1) == 1, "DynamicArray<T, size>::DynamicArray.Assign ( ConstReverseIterator iter begin )");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
class AboveTwoFilter
{
public:
bool Evaluate(const int& currentIter)const
{
return (currentIter > 2);
};
};
AboveTwoFilter filter1;
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1(5);
array1.Assign(tempArray1.BeginConst(), filter1);
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray<T, size>::DynamicArray.Assign ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_POSITIVE(array1.At(0) == 3, "DynamicArray<T, size>::DynamicArray.Assign ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_POSITIVE(array1.At(1) == 4, "DynamicArray<T, size>::DynamicArray.Assign ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_POSITIVE(array1.At(2) == 5, "DynamicArray<T, size>::DynamicArray.Assign ( ConstIterator& iter, const EvaluateFunctor<T, bool>* filter )");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array1.At(3) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array1.At(4) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array1(5);
array1 = tempArray1;
UNIT_TEST_POSITIVE(array1.Size() == 5, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array1.At(1) == 2, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array1.At(2) == 3, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array1.At(3) == 4, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array1.At(4) == 5, "DynamicArray opertor=");
int cArray2[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> tempArray2(cArray2, 5);
Dia::Core::Containers::DynamicArray<int> array2(3);
array2 = tempArray2;
UNIT_TEST_POSITIVE(array2.Size() == 3, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array2.At(1) == 2, "DynamicArray opertor=");
UNIT_TEST_POSITIVE(array2.At(2) == 3, "DynamicArray opertor=");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array2(array1);
Dia::Core::Containers::DynamicArray<int> array3(array1, 1, 3);
UNIT_TEST_POSITIVE(array1 == array2, "DynamicArray opertor==");
UNIT_TEST_NEGATIVE(array1 == array3, "DynamicArray opertor==");
UNIT_TEST_POSITIVE(array1 != array3, "DynamicArray opertor!=");
UNIT_TEST_NEGATIVE(array1 != array2, "DynamicArray opertor!=");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 5);
UNIT_TEST_ASSERT_EXPECTED_START();
int temp = array1[-1];
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
int temp = array1[6];
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
int temp = array1.At(-1);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
int temp = array1.At(6);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_POSITIVE(array1[0] == array1.At(0), "DynamicArray opertor[]");
UNIT_TEST_POSITIVE(array1[1] == array1.At(1), "DynamicArray opertor[]");
UNIT_TEST_POSITIVE(array1[2] == array1.At(2), "DynamicArray opertor[]");
UNIT_TEST_POSITIVE(array1[3] == array1.At(3), "DynamicArray opertor[]");
UNIT_TEST_POSITIVE(array1[4] == array1.At(4), "DynamicArray opertor[]");
UNIT_TEST_POSITIVE(array1.Front() == array1.At(0), "DynamicArray Front");
UNIT_TEST_POSITIVE(array1.Back() == array1.At(4), "DynamicArray Back");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 5);
UNIT_TEST_POSITIVE(&array1[0] == array1.IteratorAt(0).Current(), "DynamicArray IteratorAt");
UNIT_TEST_POSITIVE(&array1[1] == array1.IteratorAt(1).Current(), "DynamicArray IteratorAt");
UNIT_TEST_POSITIVE(&array1[2] == array1.IteratorAt(2).Current(), "DynamicArray IteratorAt");
UNIT_TEST_POSITIVE(&array1[3] == array1.IteratorAt(3).Current(), "DynamicArray IteratorAt");
UNIT_TEST_POSITIVE(&array1[4] == array1.IteratorAt(4).Current(), "DynamicArray IteratorAt");
UNIT_TEST_POSITIVE(array1.Begin() == array1.IteratorAt(0), "DynamicArray Begin");
UNIT_TEST_POSITIVE(array1.BeginConst() == array1.IteratorAtConst(0), "DynamicArray BeginConst");
UNIT_TEST_POSITIVE(&array1[0] == array1.ReverseIteratorAt(0).Current(), "DynamicArray ReverseIteratorAt");
UNIT_TEST_POSITIVE(&array1[1] == array1.ReverseIteratorAt(1).Current(), "DynamicArray ReverseIteratorAt");
UNIT_TEST_POSITIVE(&array1[2] == array1.ReverseIteratorAt(2).Current(), "DynamicArray ReverseIteratorAt");
UNIT_TEST_POSITIVE(&array1[3] == array1.ReverseIteratorAt(3).Current(), "DynamicArray ReverseIteratorAt");
UNIT_TEST_POSITIVE(&array1[4] == array1.ReverseIteratorAt(4).Current(), "DynamicArray ReverseIteratorAt");
UNIT_TEST_POSITIVE(array1.End() == array1.ReverseIteratorAt(4), "DynamicArray End");
UNIT_TEST_POSITIVE(array1.EndConst() == array1.ReverseIteratorAtConst(4), "DynamicArray EndConst");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[10] = {1, 2, 3, 4, 5, 1, 3, 3, 3, 4};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 10);
UNIT_TEST_POSITIVE(array1.FrequencyOfElement(1) == 2, "DynamicArray FrequencyOfElement");
UNIT_TEST_POSITIVE(array1.FrequencyOfElement(2) == 1, "DynamicArray FrequencyOfElement");
UNIT_TEST_POSITIVE(array1.FrequencyOfElement(3) == 4, "DynamicArray FrequencyOfElement");
UNIT_TEST_POSITIVE(array1.FrequencyOfElement(4) == 2, "DynamicArray FrequencyOfElement");
UNIT_TEST_POSITIVE(array1.FrequencyOfElement(5) == 1, "DynamicArray FrequencyOfElement");
UNIT_TEST_POSITIVE(array1.FrequencyOfElement(6) == 0, "DynamicArray FrequencyOfElement");
Dia::Core::Containers::DynamicArray<int> arrayUnique(10);
array1.UniqueElements(arrayUnique);
UNIT_TEST_POSITIVE(arrayUnique.Size() == 5, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayUnique[0] == 1, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayUnique[1] == 2, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayUnique[2] == 3, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayUnique[3] == 4, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayUnique[4] == 5, "DynamicArray numberOfUniqueElements");
Dia::Core::Containers::DynamicArray<int> arrayFreqUnique(10);
Dia::Core::Containers::DynamicArray<int> arrayFreq(10);
array1.FrequencyUniqueElements(arrayFreqUnique, arrayFreq);
UNIT_TEST_POSITIVE(arrayFreqUnique.Size() == 5, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreqUnique[0] == 1, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreqUnique[1] == 2, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreqUnique[2] == 3, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreqUnique[3] == 4, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreqUnique[4] == 5, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreq[0] == 2, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreq[1] == 1, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreq[2] == 4, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreq[3] == 2, "DynamicArray numberOfUniqueElements");
UNIT_TEST_POSITIVE(arrayFreq[4] == 1, "DynamicArray numberOfUniqueElements");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
class IncreasingOrder
{
public:
bool GreaterThen(const int& object1, const int& object2)const
{
return (object1 > object2);
}
bool LessThen(const int& object1, const int& object2)const
{
return (object1 < object2);
}
bool Equal(const int& object1, const int& object2)const
{
return (object1 == object2);
}
};
IncreasingOrder order;
int cArray1[10] = {1, 2, 3, 4, 5, 1, 3, 3, 3, 4};
int cArray2[5] = {4, 2, 5, 1, 3};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 10);
Dia::Core::Containers::DynamicArray<int> array2(cArray2, 5);
Dia::Core::Containers::DynamicArray<int> array3(cArray1, 10);
Dia::Core::Containers::DynamicArray<int> array4(cArray2, 5);
array1.Sort(order);
UNIT_TEST_POSITIVE(array1[0] == 1, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[1] == 1, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[2] == 2, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[3] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[4] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[5] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[6] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[7] == 4, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[8] == 4, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1[9] == 5, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array1.IsSorted(order), "DynamicArray Sort");
array2.Sort(order);
UNIT_TEST_POSITIVE(array2[0] == 1, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array2[1] == 2, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array2[2] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array2[3] == 4, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array2[4] == 5, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array2.IsSorted(order), "DynamicArray Sort");
array3.Sort();
UNIT_TEST_POSITIVE(array3[0] == 1, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[1] == 1, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[2] == 2, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[3] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[4] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[5] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[6] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[7] == 4, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[8] == 4, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3[9] == 5, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array3.IsSorted(), "DynamicArray Sort");
array4.Sort();
UNIT_TEST_POSITIVE(array4[0] == 1, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array4[1] == 2, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array4[2] == 3, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array4[3] == 4, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array4[4] == 5, "DynamicArray Sort");
UNIT_TEST_POSITIVE(array4.IsSorted(), "DynamicArray Sort");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[5] = {1, 2, 3, 4, 5};
int cArray2[5] = {4, 2, 5, 1, 3};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 5);
Dia::Core::Containers::DynamicArray<int> array2(cArray2, 5);
array1.Swap(array2);
UNIT_TEST_POSITIVE(array1[0] == 4, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array1[1] == 2, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array1[2] == 5, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array1[3] == 1, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array1[4] == 3, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array2[0] == 1, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array2[1] == 2, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array2[2] == 3, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array2[3] == 4, "DynamicArray Swap");
UNIT_TEST_POSITIVE(array2[4] == 5, "DynamicArray Swap");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[10] = {1, 2, 3, 4, 5, 6, 3, 4, 5, 7};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 10);
class OneLess
{
public:
bool Equal(const int& object1, const int& object2)const
{
return (object1 == (object2 - 1));
}
};
OneLess oneLess;
UNIT_TEST_ASSERT_EXPECTED_START();
array1.FindBetweenIndex(5, -2, 3);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
array1.FindBetweenIndex(5, 3, 1);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
array1.FindBetweenIndex(5, 0, 17);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_POSITIVE(array1.FindIndex(5) == 4 , "DynamicArray FindIndex");
UNIT_TEST_POSITIVE(array1.FindIndex(7) == 9, "DynamicArray FindIndex");
UNIT_TEST_POSITIVE(array1.FindIndex(10) == -1, "DynamicArray FindIndex");
UNIT_TEST_POSITIVE(array1.FindBetweenIndex(5, 0, 7) == 4 , "DynamicArray FindBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindBetweenIndex(5, 6, 9) == 8, "DynamicArray FindBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindBetweenIndex(1, 6, 9) == -1, "DynamicArray FindBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindIndex(5, oneLess) == 3 , "DynamicArray FindIndex");
UNIT_TEST_POSITIVE(array1.FindIndex(7, oneLess) == 5, "DynamicArray FindIndex");
UNIT_TEST_POSITIVE(array1.FindIndex(10, oneLess) == -1, "DynamicArray FindIndex");
UNIT_TEST_POSITIVE(array1.FindBetweenIndex(5, oneLess, 0, 7) == 3 , "DynamicArray FindBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindBetweenIndex(5, oneLess, 6, 9) == 7, "DynamicArray FindBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindBetweenIndex(1, oneLess, 6, 9) == -1, "DynamicArray FindBetweenIndex");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[10] = {1, 2, 3, 4, 5, 6, 3, 4, 5, 7};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 10);
class OneLess
{
public:
bool Equal(const int& object1, const int& object2)const
{
return (object1 == (object2 - 1));
}
};
OneLess oneLess;
UNIT_TEST_ASSERT_EXPECTED_START();
array1.FindLastBetweenIndex(5, -2, 3);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
array1.FindLastBetweenIndex(5, 3, 1);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_ASSERT_EXPECTED_START();
array1.FindLastBetweenIndex(5, 0, 17);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_POSITIVE(array1.FindLastIndex(5) == 8 , "DynamicArray FindLastIndex");
UNIT_TEST_POSITIVE(array1.FindLastIndex(3) == 6, "DynamicArray FindLastIndex");
UNIT_TEST_POSITIVE(array1.FindLastIndex(10) == -1, "DynamicArray FindLastIndex");
UNIT_TEST_POSITIVE(array1.FindLastBetweenIndex(4, 0, 7) == 7 , "DynamicArray FindLastBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindLastBetweenIndex(5, 6, 9) == 8, "DynamicArray FindLastBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindLastBetweenIndex(1, 6, 9) == -1, "DynamicArray FindLastBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindLastIndex(5, oneLess) == 7 , "DynamicArray FindLastIndex");
UNIT_TEST_POSITIVE(array1.FindLastIndex(7, oneLess) == 5, "DynamicArray FindLastIndex");
UNIT_TEST_POSITIVE(array1.FindLastIndex(10, oneLess) == -1, "DynamicArray FindLastIndex");
UNIT_TEST_POSITIVE(array1.FindLastBetweenIndex(5, oneLess, 0, 7) == 7 , "DynamicArray FindLastBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindLastBetweenIndex(5, oneLess, 6, 9) == 7, "DynamicArray FindLastBetweenIndex");
UNIT_TEST_POSITIVE(array1.FindLastBetweenIndex(1, oneLess, 6, 9) == -1, "DynamicArray FindLastBetweenIndex");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
int cArray1[10] = {1, 2, 3, 4, 5, 6, 3, 4, 5, 7};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 10);
array1.Sort();
class Equality
{
public:
bool GreaterThen(const int& object1, const int& object2)const
{
return (object1 > object2);
}
bool LessThen(const int& object1, const int& object2)const
{
return (object1 < object2);
}
bool Equal(const int& object1, const int& object2)const
{
return (object1 == object2);
}
};
Equality equality;
UNIT_TEST_POSITIVE(array1.IsSorted(), "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindSortedIndex(5) == 6 , "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindSortedIndex(3) == 2, "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindSortedIndex(10) == -1, "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindLastSortedIndex(4) == 5 , "DynamicArray FindLastSortedIndex");
UNIT_TEST_POSITIVE(array1.FindLastSortedIndex(5) == 7, "DynamicArray FindLastSortedIndex");
UNIT_TEST_POSITIVE(array1.FindLastSortedIndex(10) == -1, "DynamicArray FindLastSortedIndex");
UNIT_TEST_POSITIVE(array1.FindSortedIndex(5, equality) == 6 , "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindSortedIndex(3, equality) == 2, "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindSortedIndex(10, equality) == -1, "DynamicArray FindSortedIndex");
UNIT_TEST_POSITIVE(array1.FindLastSortedIndex(4, equality) == 5 , "DynamicArray FindLastSortedIndex");
UNIT_TEST_POSITIVE(array1.FindLastSortedIndex(5, equality) == 7, "DynamicArray FindLastSortedIndex");
UNIT_TEST_POSITIVE(array1.FindLastSortedIndex(10, equality) == -1, "DynamicArray FindLastSortedIndex");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
class Eval
{
public:
float Evaluate(const int& object1)const
{
return static_cast<float>(object1);
};
};
Eval eval;
int cArray1[10] = {1, 2, 3, 9, 5, 6, 3, 4, 5, 7};
Dia::Core::Containers::DynamicArray<int> array1(cArray1, 10);
UNIT_TEST_POSITIVE(array1.HighestEvalutionIndex(eval) == 3, "DynamicArray HighestEvalutionIndex");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
class Foo
{
public:
Foo(): mSomeData(true), mMoreData(21.0f){}
bool SomeData(){return mSomeData;}
float MoreData(){return mMoreData;}
bool mSomeData;
float mMoreData;
};
Foo cArray1[3];
Dia::Core::Containers::DynamicArray<Foo> array1(cArray1, 3);
cArray1[0].mSomeData = false;
cArray1[0].mMoreData = 11.0f;
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray Test Non primitive");
UNIT_TEST_POSITIVE(array1.At(0).SomeData(), "DynamicArray Test Non primitive");
UNIT_TEST_POSITIVE(array1.At(1).SomeData(), "DynamicArray Test Non primitive");
UNIT_TEST_POSITIVE(array1.At(2).SomeData(), "DynamicArray Test Non primitive");
UNIT_TEST_POSITIVE(array1.At(0).MoreData() == 21.0f, "DynamicArray Test Non primitive");
UNIT_TEST_POSITIVE(array1.At(1).MoreData() == 21.0f, "DynamicArray Test Non primitive");
UNIT_TEST_POSITIVE(array1.At(2).MoreData() == 21.0f, "DynamicArray Test Non primitive");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Add(1);
array1.AddDefault();
array1.Add(2);
UNIT_TEST_POSITIVE(array1.Size() == 3, "DynamicArray Add");
UNIT_TEST_POSITIVE(array1.At(0) == 1, "DynamicArray Add");
UNIT_TEST_POSITIVE(array1.At(1) == 0, "DynamicArray AddDefault");
UNIT_TEST_POSITIVE(array1.At(2) == 2, "DynamicArray Add");
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.FillDefault();
UNIT_TEST_POSITIVE(array2.Size() == 3, "DynamicArray Add");
UNIT_TEST_POSITIVE(array2.At(0) == 0, "DynamicArray FillDefault");
UNIT_TEST_POSITIVE(array2.At(1) == 0, "DynamicArray FillDefault");
UNIT_TEST_POSITIVE(array2.At(2) == 0, "DynamicArray FillDefault");
Dia::Core::Containers::DynamicArray<int> array3(3);
array3.Fill(11);
UNIT_TEST_POSITIVE(array3.Size() == 3, "DynamicArray Add");
UNIT_TEST_POSITIVE(array3.At(0) == 11, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array3.At(1) == 11, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array3.At(2) == 11, "DynamicArray Fill");
Dia::Core::Containers::DynamicArray<int> array4(3);
array4.FillDefault();
UNIT_TEST_POSITIVE(array4.Size() == 3, "DynamicArray Add");
UNIT_TEST_POSITIVE(array4.At(0) == 0, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array4.At(1) == 0, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array4.At(2) == 0, "DynamicArray Fill");
Dia::Core::Containers::DynamicArray<int> array5(5);
array5.AddDefault();
array5.AddAt(1, 0);
array5.AddAt(2, 1);
array5.AddAt(3, 1);
array5.AddAt(4, 3);
UNIT_TEST_POSITIVE(array5.Size() == 5, "DynamicArray Add");
UNIT_TEST_POSITIVE(array5.At(0) == 1, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array5.At(1) == 3, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array5.At(2) == 2, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array5.At(3) == 4, "DynamicArray Fill");
UNIT_TEST_POSITIVE(array5.At(4) == 0, "DynamicArray Fill");
UNIT_TEST_BLOCK_END();
UNIT_TEST_BLOCK_START();
Dia::Core::Containers::DynamicArray<int> array1(3);
array1.Fill(11);
array1.Remove();
UNIT_TEST_POSITIVE(array1.Size() == 2, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array1.At(0) == 11, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array1.At(1) == 11, "DynamicArray Remove");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array1.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> array2(3);
array2.Add(1);
array2.Add(2);
array2.Add(3);
array2.RemoveAt(1);
UNIT_TEST_POSITIVE(array2.Size() == 2, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array2.At(0) == 1, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array2.At(1) == 3, "DynamicArray Remove");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array2.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> array3(3);
array3.Add(1);
array3.Add(2);
array3.Add(3);
array3.RemoveFirst(2);
UNIT_TEST_POSITIVE(array3.Size() == 2, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array3.At(0) == 1, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array3.At(1) == 3, "DynamicArray Remove");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array3.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> array4(3);
array4.Add(1);
array4.Add(2);
array4.Add(3);
array4.RemoveLast(2);
UNIT_TEST_POSITIVE(array4.Size() == 2, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array4.At(0) == 1, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array4.At(1) == 3, "DynamicArray Remove");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array4.At(2) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
Dia::Core::Containers::DynamicArray<int> array5(3);
array5.Add(1);
array5.Add(2);
array5.Add(3);
array5.RemoveAll();
UNIT_TEST_POSITIVE(array5.Size() == 0, "DynamicArray Remove");
Dia::Core::Containers::DynamicArray<int> array6(5);
array6.Add(1);
array6.Add(2);
array6.Add(3);
array6.Add(2);
array6.Add(3);
array6.RemoveAll(2);
UNIT_TEST_POSITIVE(array6.Size() == 3, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array6.At(0) == 1, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array6.At(1) == 3, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array6.At(2) == 3, "DynamicArray Remove");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array6.At(3) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
class Comparisson
{
public:
bool Evaluate(const int&a)const
{
return (a == 2);
};
};
Comparisson compare;
Dia::Core::Containers::DynamicArray<int> array7(5);
array7.Add(1);
array7.Add(2);
array7.Add(3);
array7.Add(2);
array7.Add(3);
array7.RemoveAll(compare);
UNIT_TEST_POSITIVE(array7.Size() == 3, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array7.At(0) == 1, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array7.At(1) == 3, "DynamicArray Remove");
UNIT_TEST_POSITIVE(array7.At(2) == 3, "DynamicArray Remove");
UNIT_TEST_ASSERT_EXPECTED_START();
bool test = (array7.At(3) == 0);
UNIT_TEST_ASSERT_EXPECTED_END();
UNIT_TEST_BLOCK_END();
mState = kFinished;
}
TEST(FixedArray,size_test){
FixedArray<int> array(7);
ASSERT_EQ(7,array.size());
FixedArray<int> array2(100);
ASSERT_EQ(100,array2.size());
}
// a utility function to compare two parameter arrays
::testing::AssertionResult compareParameterArrays(std::shared_ptr<Region> region1,
std::shared_ptr<Region> region2,
std::string parameter,
NTA_BasicType type) {
UInt32 *buf1;
UInt32 *buf2;
Real32 *buf3;
Real32 *buf4;
Real64 *buf5;
Real64 *buf6;
Byte *buf7;
Byte *buf8;
Array array1(type);
Array array2(type);
region1->getParameterArray(parameter, array1);
region2->getParameterArray(parameter, array2);
if (type != array1.getType())
return ::testing::AssertionFailure()
<< "Failure: Original Array1 for parameter '" << parameter
<< "' is not the expected type. expected: "
<< BasicType::getName(type) << ", found: "
<< BasicType::getName(array1.getType());
if (type != array2.getType())
return ::testing::AssertionFailure()
<< "Failure: Restored Array2 for parameter '" << parameter
<< "' is not the expected type. expected: "
<< BasicType::getName(type) << ", found: "
<< BasicType::getName(array1.getType());
size_t len1 = array1.getCount();
size_t len2 = array2.getCount();
if (len1 != len2) {
return ::testing::AssertionFailure()
<< "Failure: Arrays for parameter '" << parameter
<< "' are not the same length.";
}
switch (type) {
case NTA_BasicType_UInt32:
buf1 = (UInt32 *)array1.getBuffer();
buf2 = (UInt32 *)array2.getBuffer();
for (size_t i = 0; i < len1; i++) {
if (buf1[i] != buf2[i]) {
return ::testing::AssertionFailure()
<< "Failure: Array element for parameter '" << parameter << "["
<< i << "]' is not the same after restore.";
}
}
break;
case NTA_BasicType_Real32:
buf3 = (Real32 *)array1.getBuffer();
buf4 = (Real32 *)array2.getBuffer();
for (size_t i = 0; i < len1; i++) {
if (buf3[i] != buf4[i]) {
return ::testing::AssertionFailure()
<< "Failure: Array element for parameter '" << parameter << "["
<< i << "]' is not the same after restore.";
}
}
break;
case NTA_BasicType_Real64:
buf5 = (Real64 *)array1.getBuffer();
buf6 = (Real64 *)array2.getBuffer();
for (size_t i = 0; i < len1; i++) {
if (buf5[i] != buf6[i]) {
return ::testing::AssertionFailure()
<< "Failure: Array element for parameter '" << parameter << "["
<< i << "]' is not the same after restore.";
}
}
break;
case NTA_BasicType_Byte:
case NTA_BasicType_SDR:
buf7 = (Byte *)array1.getBuffer();
buf8 = (Byte *)array2.getBuffer();
for (size_t i = 0; i < len1; i++) {
if (buf7[i] != buf8[i]) {
return ::testing::AssertionFailure()
<< "Failure: Array element for parameter '" << parameter << "["
<< i << "]' is not the same after restore.";
}
}
break;
default:
break;
} // end switch
return ::testing::AssertionSuccess();
}
void tst_QCustomDataArray::create()
{
QCustomDataArray array1;
QVERIFY(array1.elementType() == QCustomDataArray::Float);
QVERIFY(array1.elementSize() == sizeof(float));
QCOMPARE(array1.size(), 0);
QCOMPARE(array1.count(), 0);
QVERIFY(array1.isEmpty());
array1.setElementType(QCustomDataArray::Vector3D);
QVERIFY(array1.elementType() == QCustomDataArray::Vector3D);
QVERIFY(array1.elementSize() == sizeof(QVector3D));
QCOMPARE(array1.size(), 0);
QCOMPARE(array1.count(), 0);
QVERIFY(array1.isEmpty());
QCustomDataArray array2(QCustomDataArray::Vector2D);
QVERIFY(array2.elementType() == QCustomDataArray::Vector2D);
QVERIFY(array2.elementSize() == sizeof(QVector2D));
QCOMPARE(array2.size(), 0);
QCOMPARE(array2.count(), 0);
QVERIFY(array2.isEmpty());
QCustomDataArray array3(QCustomDataArray::Vector3D, 20);
QVERIFY(array3.elementType() == QCustomDataArray::Vector3D);
QVERIFY(array3.elementSize() == sizeof(QVector3D));
QCOMPARE(array3.size(), 20);
QCOMPARE(array3.count(), 20);
QVERIFY(!array3.isEmpty());
QVERIFY(array3.capacity() >= 20);
QCustomDataArray array4(QCustomDataArray::Vector4D, 20);
QVERIFY(array4.elementType() == QCustomDataArray::Vector4D);
QVERIFY(array4.elementSize() == sizeof(QVector4D));
QCOMPARE(array4.size(), 20);
QCOMPARE(array4.count(), 20);
QVERIFY(!array4.isEmpty());
array4.append(QVector4D(1.0f, 2.0f, 3.0f, 4.0f));
QCustomDataArray array5(QCustomDataArray::Color, 10);
QVERIFY(array5.elementType() == QCustomDataArray::Color);
QVERIFY(array5.elementSize() == sizeof(QColor4ub));
QCOMPARE(array5.size(), 10);
QCOMPARE(array5.count(), 10);
QVERIFY(!array5.isEmpty());
array5.append(Qt::red);
array5.setAt(4, Qt::green);
QVERIFY(array5.colorAt(4) == Qt::green);
QCustomDataArray array6(array5);
QVERIFY(array6.elementType() == QCustomDataArray::Color);
QVERIFY(array6.elementSize() == sizeof(QColor4ub));
QCOMPARE(array6.size(), 11);
QCOMPARE(array6.count(), 11);
QVERIFY(!array6.isEmpty());
QVERIFY(array6.colorAt(10) == Qt::red);
// Changes element type from Color to Vector4D.
array6 = array4;
QVERIFY(array6.elementType() == QCustomDataArray::Vector4D);
QVERIFY(array6.elementSize() == sizeof(QVector4D));
QCOMPARE(array6.size(), 21);
QCOMPARE(array6.count(), 21);
QVERIFY(!array6.isEmpty());
QVERIFY(array6.vector4DAt(20) == QVector4D(1.0f, 2.0f, 3.0f, 4.0f));
array6.clear();
QVERIFY(array6.elementType() == QCustomDataArray::Vector4D);
QVERIFY(array6.elementSize() == sizeof(QVector4D));
QCOMPARE(array6.size(), 0);
QCOMPARE(array6.count(), 0);
QVERIFY(array6.isEmpty());
array6.setElementType(QCustomDataArray::Vector3D);
QVERIFY(array6.elementType() == QCustomDataArray::Vector3D);
QVERIFY(array6.elementSize() == sizeof(QVector3D));
QCOMPARE(array6.size(), 0);
QCOMPARE(array6.count(), 0);
QVERIFY(array6.isEmpty());
}
bool operator() ()
{
bool passed = true;
printf("%s::%s ... ",TOSTRING(isa),name);
fflush(stdout);
/* create vector with random numbers */
const size_t M = 10;
std::vector<atomic_t> flattened;
typedef std::vector<std::vector<size_t>* > ArrayArray;
ArrayArray array2(M);
size_t K = 0;
for (size_t i=0; i<M; i++) {
const size_t N = rand() % 10;
K += N;
array2[i] = new std::vector<size_t>(N);
for (size_t j=0; j<N; j++)
(*array2[i])[j] = rand() % 10;
}
/* array to test global index */
std::vector<atomic_t> verify_k(K);
for (size_t i=0; i<K; i++) verify_k[i] = 0;
ParallelForForPrefixSumState<size_t> state(array2,size_t(1));
/* dry run only counts */
size_t S = parallel_for_for_prefix_sum( state, array2, size_t(0), [&](std::vector<size_t>* v, const range<size_t>& r, size_t k, const size_t base) -> size_t
{
size_t s = 0;
for (size_t i=r.begin(); i<r.end(); i++) {
s += (*v)[i];
atomic_add(&verify_k[k++],1);
}
return s;
}, [](size_t v0, size_t v1) {
return v0+v1;
});
/* create properly sized output array */
flattened.resize(S);
memset(flattened.data(),0,sizeof(atomic_t)*S);
/* now we actually fill the flattened array */
parallel_for_for_prefix_sum( state, array2, size_t(0), [&](std::vector<size_t>* v, const range<size_t>& r, size_t k, const size_t base) -> size_t
{
size_t s = 0;
for (size_t i=r.begin(); i<r.end(); i++) {
for (size_t j=0; j<(*v)[i]; j++) {
atomic_add(&flattened[base+s+j],1);
}
s += (*v)[i];
atomic_add(&verify_k[k++],1);
}
return s;
}, [](size_t v0, size_t v1) {
return v0+v1;
});
/* check global index */
for (size_t i=0; i<K; i++)
passed &= (verify_k[i] == 2);
/* check if each element was assigned exactly once */
for (size_t i=0; i<flattened.size(); i++)
passed &= (flattened[i] == 1);
/* delete arrays again */
for (size_t i=0; i<array2.size(); i++)
delete array2[i];
/* output if test passed or not */
if (passed) printf("[passed]\n");
else printf("[failed]\n");
return passed;
}
