##// END OF EJS Templates
Updates unit tests
Alexandre Leroux -
r604:da7f81670868
parent child
Show More
@@ -10,6 +10,20
10 10 Q_DECLARE_METATYPE(std::shared_ptr<ScalarSeries>)
11 11 Q_DECLARE_METATYPE(std::shared_ptr<VectorSeries>)
12 12
13 namespace {
14
15 void validateRange(DataSeriesIterator first, DataSeriesIterator last, const QVector<double> &xData,
16 const QVector<double> &valuesData)
17 {
18 QVERIFY(std::equal(first, last, xData.cbegin(), xData.cend(),
19 [](const auto &it, const auto &expectedX) { return it.x() == expectedX; }));
20 QVERIFY(std::equal(
21 first, last, valuesData.cbegin(), valuesData.cend(),
22 [](const auto &it, const auto &expectedVal) { return it.value() == expectedVal; }));
23 }
24
25 } // namespace
26
13 27 class TestDataSeries : public QObject {
14 28 Q_OBJECT
15 29 private:
@@ -164,13 +178,7 void TestDataSeries::testCtor()
164 178 QFETCH(QVector<double>, expectedXAxisData);
165 179 QFETCH(QVector<double>, expectedValuesData);
166 180
167 auto seriesXAxisData = series->xAxisData()->data();
168 auto seriesValuesData = series->valuesData()->data();
169
170 QVERIFY(
171 std::equal(expectedXAxisData.cbegin(), expectedXAxisData.cend(), seriesXAxisData.cbegin()));
172 QVERIFY(std::equal(expectedValuesData.cbegin(), expectedValuesData.cend(),
173 seriesValuesData.cbegin()));
181 validateRange(series->cbegin(), series->cend(), expectedXAxisData, expectedValuesData);
174 182 }
175 183
176 184 namespace {
@@ -250,13 +258,7 void TestDataSeries::testMerge()
250 258 QFETCH(QVector<double>, expectedXAxisData);
251 259 QFETCH(QVector<double>, expectedValuesData);
252 260
253 auto seriesXAxisData = dataSeries->xAxisData()->data();
254 auto seriesValuesData = dataSeries->valuesData()->data();
255
256 QVERIFY(
257 std::equal(expectedXAxisData.cbegin(), expectedXAxisData.cend(), seriesXAxisData.cbegin()));
258 QVERIFY(std::equal(expectedValuesData.cbegin(), expectedValuesData.cend(),
259 seriesValuesData.cbegin()));
261 validateRange(dataSeries->cbegin(), dataSeries->cend(), expectedXAxisData, expectedValuesData);
260 262 }
261 263
262 264 void TestDataSeries::testMinXAxisData_data()
@@ -438,12 +440,7 void TestDataSeries::testXAxisRange()
438 440 QFETCH(QVector<double>, expectedValuesData);
439 441
440 442 auto bounds = dataSeries->xAxisRange(min, max);
441 QVERIFY(std::equal(bounds.first, bounds.second, expectedXAxisData.cbegin(),
442 expectedXAxisData.cend(),
443 [](const auto &it, const auto &expectedX) { return it.x() == expectedX; }));
444 QVERIFY(std::equal(
445 bounds.first, bounds.second, expectedValuesData.cbegin(), expectedValuesData.cend(),
446 [](const auto &it, const auto &expectedVal) { return it.value() == expectedVal; }));
443 validateRange(bounds.first, bounds.second, expectedXAxisData, expectedValuesData);
447 444 }
448 445
449 446 void TestDataSeries::testValuesBoundsScalar_data()
@@ -2,6 +2,17
2 2 #include <QObject>
3 3 #include <QtTest>
4 4
5 namespace {
6
7 void verifyArrayData(const ArrayData<1> &arrayData, const QVector<double> &expectedData)
8 {
9 QVERIFY(std::equal(
10 arrayData.cbegin(), arrayData.cend(), expectedData.cbegin(), expectedData.cend(),
11 [](const auto &it, const auto &expectedData) { return it.at(0) == expectedData; }));
12 }
13
14 } // namespace
15
5 16 class TestOneDimArrayData : public QObject {
6 17 Q_OBJECT
7 18 private slots:
@@ -9,10 +20,6 private slots:
9 20 void testData_data();
10 21 void testData();
11 22
12 /// Tests @sa ArrayData::data(int componentIndex)
13 void testDataByComponentIndex_data();
14 void testDataByComponentIndex();
15
16 23 /// Tests @sa ArrayData::add()
17 24 void testAdd_data();
18 25 void testAdd();
@@ -51,32 +58,7 void TestOneDimArrayData::testData()
51 58 QFETCH(QVector<double>, expectedData);
52 59
53 60 ArrayData<1> arrayData{inputData};
54 QVERIFY(arrayData.data() == expectedData);
55 }
56
57 void TestOneDimArrayData::testDataByComponentIndex_data()
58 {
59 // Test structure
60 QTest::addColumn<QVector<double> >("inputData"); // array data's input
61 QTest::addColumn<int>("componentIndex"); // component index to test
62 QTest::addColumn<QVector<double> >("expectedData"); // expected data
63
64 // Test cases
65 QTest::newRow("validIndex") << QVector<double>{1., 2., 3., 4., 5.} << 0
66 << QVector<double>{1., 2., 3., 4., 5.};
67 QTest::newRow("invalidIndex1") << QVector<double>{1., 2., 3., 4., 5.} << -1
68 << QVector<double>{};
69 QTest::newRow("invalidIndex2") << QVector<double>{1., 2., 3., 4., 5.} << 1 << QVector<double>{};
70 }
71
72 void TestOneDimArrayData::testDataByComponentIndex()
73 {
74 QFETCH(QVector<double>, inputData);
75 QFETCH(int, componentIndex);
76 QFETCH(QVector<double>, expectedData);
77
78 ArrayData<1> arrayData{inputData};
79 QVERIFY(arrayData.data(componentIndex) == expectedData);
61 verifyArrayData(arrayData, expectedData);
80 62 }
81 63
82 64 void TestOneDimArrayData::testAdd_data()
@@ -107,7 +89,7 void TestOneDimArrayData::testAdd()
107 89 ArrayData<1> other{otherData};
108 90
109 91 arrayData.add(other, prepend);
110 QVERIFY(arrayData.data() == expectedData);
92 verifyArrayData(arrayData, expectedData);
111 93 }
112 94
113 95 void TestOneDimArrayData::testAt_data()
@@ -147,7 +129,7 void TestOneDimArrayData::testClear()
147 129
148 130 ArrayData<1> arrayData{inputData};
149 131 arrayData.clear();
150 QVERIFY(arrayData.data() == QVector<double>{});
132 verifyArrayData(arrayData, QVector<double>{});
151 133 }
152 134
153 135 void TestOneDimArrayData::testSize_data()
@@ -192,7 +174,7 void TestOneDimArrayData::testSort()
192 174 ArrayData<1> arrayData{inputData};
193 175 auto sortedArrayData = arrayData.sort(sortPermutation);
194 176 QVERIFY(sortedArrayData != nullptr);
195 QVERIFY(sortedArrayData->data() == expectedData);
177 verifyArrayData(*sortedArrayData, expectedData);
196 178 }
197 179
198 180 QTEST_MAIN(TestOneDimArrayData)
@@ -2,15 +2,55
2 2 #include <QObject>
3 3 #include <QtTest>
4 4
5 using DataContainer = QVector<QVector<double> >;
5 using Container = QVector<QVector<double> >;
6 using InputData = QPair<QVector<double>, int>;
7
8 namespace {
9
10 InputData flatten(const Container &container)
11 {
12 if (container.isEmpty()) {
13 return {};
14 }
15
16 // We assume here that each component of the container have the same size
17 auto containerSize = container.size();
18 auto componentSize = container.first().size();
19
20 auto result = QVector<double>{};
21 result.reserve(componentSize * containerSize);
22
23 for (auto i = 0; i < componentSize; ++i) {
24 for (auto j = 0; j < containerSize; ++j) {
25 result.append(container.at(j).at(i));
26 }
27 }
28
29 return {result, containerSize};
30 }
31
32 void verifyArrayData(const ArrayData<2> &arrayData, const Container &expectedData)
33 {
34 auto verifyComponent = [&arrayData](const auto &componentData, const auto &equalFun) {
35 QVERIFY(std::equal(arrayData.cbegin(), arrayData.cend(), componentData.cbegin(),
36 componentData.cend(),
37 [&equalFun](const auto &dataSeriesIt, const auto &expectedValue) {
38 return equalFun(dataSeriesIt, expectedValue);
39 }));
40 };
41
42 for (auto i = 0; i < expectedData.size(); ++i) {
43 verifyComponent(expectedData.at(i), [i](const auto &seriesIt, const auto &value) {
44 return seriesIt.at(i) == value;
45 });
46 }
47 }
48
49 } // namespace
6 50
7 51 class TestTwoDimArrayData : public QObject {
8 52 Q_OBJECT
9 53 private slots:
10 /// Tests @sa ArrayData::data(int componentIndex)
11 void testDataByComponentIndex_data();
12 void testDataByComponentIndex();
13
14 54 /// Tests @sa ArrayData ctor
15 55 void testCtor_data();
16 56 void testCtor();
@@ -32,192 +72,167 private slots:
32 72 void testSort();
33 73 };
34 74
35 void TestTwoDimArrayData::testDataByComponentIndex_data()
36 {
37 // Test structure
38 QTest::addColumn<DataContainer>("inputData"); // array data's input
39 QTest::addColumn<int>("componentIndex"); // component index to test
40 QTest::addColumn<QVector<double> >("expectedData"); // expected data
41
42 // Test cases
43 auto inputData
44 = DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}};
45
46 QTest::newRow("validIndex1") << inputData << 0 << QVector<double>{1., 2., 3., 4., 5.};
47 QTest::newRow("validIndex2") << inputData << 1 << QVector<double>{6., 7., 8., 9., 10.};
48 QTest::newRow("validIndex3") << inputData << 2 << QVector<double>{11., 12., 13., 14., 15.};
49 QTest::newRow("invalidIndex1") << inputData << -1 << QVector<double>{};
50 QTest::newRow("invalidIndex2") << inputData << 3 << QVector<double>{};
51 }
52
53 void TestTwoDimArrayData::testDataByComponentIndex()
54 {
55 QFETCH(DataContainer, inputData);
56 QFETCH(int, componentIndex);
57 QFETCH(QVector<double>, expectedData);
58
59 ArrayData<2> arrayData{inputData};
60 QVERIFY(arrayData.data(componentIndex) == expectedData);
61 }
62
63 75 void TestTwoDimArrayData::testCtor_data()
64 76 {
65 77 // Test structure
66 QTest::addColumn<DataContainer>("inputData"); // array data's input
67 QTest::addColumn<bool>("success"); // array data has been successfully constructed
68 QTest::addColumn<DataContainer>("expectedData"); // expected array data (when success)
78 QTest::addColumn<InputData>("inputData"); // array data's input
79 QTest::addColumn<bool>("success"); // array data has been successfully constructed
80 QTest::addColumn<Container>("expectedData"); // expected array data (when success)
69 81
70 82 // Test cases
71 QTest::newRow("validInput")
72 << DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}}
73 << true
74 << DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}};
75 QTest::newRow("malformedInput (components of the array data haven't the same size")
76 << DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8.}, {11., 12.}} << true
77 << DataContainer{{}, {}, {}};
78 QTest::newRow("invalidInput (less than tow components") << DataContainer{{1., 2., 3., 4., 5.}}
79 << false << DataContainer{{}, {}, {}};
83 QTest::newRow("validInput") << flatten(Container{{1., 2., 3., 4., 5.},
84 {6., 7., 8., 9., 10.},
85 {11., 12., 13., 14., 15.}})
86 << true << Container{{1., 2., 3., 4., 5.},
87 {6., 7., 8., 9., 10.},
88 {11., 12., 13., 14., 15.}};
89 QTest::newRow("invalidInput (invalid data size")
90 << InputData{{1., 2., 3., 4., 5., 6., 7.}, 3} << false << Container{{}, {}, {}};
91 QTest::newRow("invalidInput (less than two components")
92 << flatten(Container{{1., 2., 3., 4., 5.}}) << false << Container{{}, {}, {}};
80 93 }
81 94
82 95 void TestTwoDimArrayData::testCtor()
83 96 {
84 QFETCH(DataContainer, inputData);
97 QFETCH(InputData, inputData);
85 98 QFETCH(bool, success);
86 99
87 100 if (success) {
88 QFETCH(DataContainer, expectedData);
89
90 ArrayData<2> arrayData{inputData};
101 QFETCH(Container, expectedData);
91 102
92 for (auto i = 0; i < expectedData.size(); ++i) {
93 QVERIFY(arrayData.data(i) == expectedData.at(i));
94 }
103 ArrayData<2> arrayData{inputData.first, inputData.second};
104 verifyArrayData(arrayData, expectedData);
95 105 }
96 106 else {
97 QVERIFY_EXCEPTION_THROWN(ArrayData<2> arrayData{inputData}, std::invalid_argument);
107 QVERIFY_EXCEPTION_THROWN(ArrayData<2>(inputData.first, inputData.second),
108 std::invalid_argument);
98 109 }
99 110 }
100 111
101 112 void TestTwoDimArrayData::testAdd_data()
102 113 {
103 114 // Test structure
104 QTest::addColumn<DataContainer>("inputData"); // array's data input
105 QTest::addColumn<DataContainer>("otherData"); // array data's input to merge with
106 QTest::addColumn<bool>("prepend"); // prepend or append merge
107 QTest::addColumn<DataContainer>("expectedData"); // expected data after merge
115 QTest::addColumn<InputData>("inputData"); // array's data input
116 QTest::addColumn<InputData>("otherData"); // array data's input to merge with
117 QTest::addColumn<bool>("prepend"); // prepend or append merge
118 QTest::addColumn<Container>("expectedData"); // expected data after merge
108 119
109 120 // Test cases
110 auto inputData
111 = DataContainer{{1., 2., 3., 4., 5.}, {11., 12., 13., 14., 15.}, {21., 22., 23., 24., 25.}};
121 auto inputData = flatten(
122 Container{{1., 2., 3., 4., 5.}, {11., 12., 13., 14., 15.}, {21., 22., 23., 24., 25.}});
112 123
113 auto vectorContainer = DataContainer{{6., 7., 8.}, {16., 17., 18.}, {26., 27., 28}};
114 auto tensorContainer = DataContainer{{6., 7., 8.}, {16., 17., 18.}, {26., 27., 28},
115 {36., 37., 38.}, {46., 47., 48.}, {56., 57., 58}};
124 auto vectorContainer = flatten(Container{{6., 7., 8.}, {16., 17., 18.}, {26., 27., 28}});
125 auto tensorContainer = flatten(Container{{6., 7., 8.},
126 {16., 17., 18.},
127 {26., 27., 28},
128 {36., 37., 38.},
129 {46., 47., 48.},
130 {56., 57., 58}});
116 131
117 132 QTest::newRow("appendMerge") << inputData << vectorContainer << false
118 << DataContainer{{1., 2., 3., 4., 5., 6., 7., 8.},
119 {11., 12., 13., 14., 15., 16., 17., 18.},
120 {21., 22., 23., 24., 25., 26., 27., 28}};
133 << Container{{1., 2., 3., 4., 5., 6., 7., 8.},
134 {11., 12., 13., 14., 15., 16., 17., 18.},
135 {21., 22., 23., 24., 25., 26., 27., 28}};
121 136 QTest::newRow("prependMerge") << inputData << vectorContainer << true
122 << DataContainer{{6., 7., 8., 1., 2., 3., 4., 5.},
123 {16., 17., 18., 11., 12., 13., 14., 15.},
124 {26., 27., 28, 21., 22., 23., 24., 25.}};
125 QTest::newRow("invalidMerge") << inputData << tensorContainer << false << inputData;
137 << Container{{6., 7., 8., 1., 2., 3., 4., 5.},
138 {16., 17., 18., 11., 12., 13., 14., 15.},
139 {26., 27., 28, 21., 22., 23., 24., 25.}};
140 QTest::newRow("invalidMerge") << inputData << tensorContainer << false
141 << Container{{1., 2., 3., 4., 5.},
142 {11., 12., 13., 14., 15.},
143 {21., 22., 23., 24., 25.}};
126 144 }
127 145
128 146 void TestTwoDimArrayData::testAdd()
129 147 {
130 QFETCH(DataContainer, inputData);
131 QFETCH(DataContainer, otherData);
148 QFETCH(InputData, inputData);
149 QFETCH(InputData, otherData);
132 150 QFETCH(bool, prepend);
133 QFETCH(DataContainer, expectedData);
151 QFETCH(Container, expectedData);
134 152
135 ArrayData<2> arrayData{inputData};
136 ArrayData<2> other{otherData};
153 ArrayData<2> arrayData{inputData.first, inputData.second};
154 ArrayData<2> other{otherData.first, otherData.second};
137 155
138 156 arrayData.add(other, prepend);
139 157
140 for (auto i = 0; i < expectedData.size(); ++i) {
141 QVERIFY(arrayData.data(i) == expectedData.at(i));
142 }
158 verifyArrayData(arrayData, expectedData);
143 159 }
144 160
145 161 void TestTwoDimArrayData::testClear_data()
146 162 {
147 163 // Test structure
148 QTest::addColumn<DataContainer>("inputData"); // array data's input
164 QTest::addColumn<InputData>("inputData"); // array data's input
149 165
150 166 // Test cases
151 QTest::newRow("data1") << DataContainer{
152 {1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}};
167 QTest::newRow("data1") << flatten(
168 Container{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}});
153 169 }
154 170
155 171 void TestTwoDimArrayData::testClear()
156 172 {
157 QFETCH(DataContainer, inputData);
173 QFETCH(InputData, inputData);
158 174
159 ArrayData<2> arrayData{inputData};
175 ArrayData<2> arrayData{inputData.first, inputData.second};
160 176 arrayData.clear();
161 177
162 for (auto i = 0; i < inputData.size(); ++i) {
163 QVERIFY(arrayData.data(i) == QVector<double>{});
164 }
178 auto emptyData = Container(inputData.second, QVector<double>{});
179 verifyArrayData(arrayData, emptyData);
165 180 }
166 181
167 182 void TestTwoDimArrayData::testSize_data()
168 183 {
169 184 // Test structure
170 QTest::addColumn<QVector<QVector<double> > >("inputData"); // array data's input
171 QTest::addColumn<int>("expectedSize"); // expected array data size
185 QTest::addColumn<InputData>("inputData"); // array data's input
186 QTest::addColumn<int>("expectedSize"); // expected array data size
172 187
173 188 // Test cases
174 QTest::newRow("data1") << DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}} << 5;
175 QTest::newRow("data2") << DataContainer{{1., 2., 3., 4., 5.},
176 {6., 7., 8., 9., 10.},
177 {11., 12., 13., 14., 15.}}
189 QTest::newRow("data1") << flatten(Container{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}}) << 5;
190 QTest::newRow("data2") << flatten(Container{{1., 2., 3., 4., 5.},
191 {6., 7., 8., 9., 10.},
192 {11., 12., 13., 14., 15.}})
178 193 << 5;
179 194 }
180 195
181 196 void TestTwoDimArrayData::testSize()
182 197 {
183 QFETCH(DataContainer, inputData);
198 QFETCH(InputData, inputData);
184 199 QFETCH(int, expectedSize);
185 200
186 ArrayData<2> arrayData{inputData};
201 ArrayData<2> arrayData{inputData.first, inputData.second};
187 202 QVERIFY(arrayData.size() == expectedSize);
188 203 }
189 204
190 205 void TestTwoDimArrayData::testSort_data()
191 206 {
192 207 // Test structure
193 QTest::addColumn<DataContainer>("inputData"); // array data's input
208 QTest::addColumn<InputData>("inputData"); // array data's input
194 209 QTest::addColumn<std::vector<int> >("sortPermutation"); // permutation used to sort data
195 QTest::addColumn<DataContainer>("expectedData"); // expected data after sorting
210 QTest::addColumn<Container>("expectedData"); // expected data after sorting
196 211
197 212 // Test cases
198 213 QTest::newRow("data1")
199 << DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}}
214 << flatten(
215 Container{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}})
200 216 << std::vector<int>{0, 2, 3, 1, 4}
201 << DataContainer{{1., 3., 4., 2., 5.}, {6., 8., 9., 7., 10.}, {11., 13., 14., 12., 15.}};
217 << Container{{1., 3., 4., 2., 5.}, {6., 8., 9., 7., 10.}, {11., 13., 14., 12., 15.}};
202 218 QTest::newRow("data2")
203 << DataContainer{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}}
219 << flatten(
220 Container{{1., 2., 3., 4., 5.}, {6., 7., 8., 9., 10.}, {11., 12., 13., 14., 15.}})
204 221 << std::vector<int>{2, 4, 3, 0, 1}
205 << DataContainer{{3., 5., 4., 1., 2.}, {8., 10., 9., 6., 7.}, {13., 15., 14., 11., 12.}};
222 << Container{{3., 5., 4., 1., 2.}, {8., 10., 9., 6., 7.}, {13., 15., 14., 11., 12.}};
206 223 }
207 224
208 225 void TestTwoDimArrayData::testSort()
209 226 {
210 QFETCH(DataContainer, inputData);
227 QFETCH(InputData, inputData);
211 228 QFETCH(std::vector<int>, sortPermutation);
212 QFETCH(DataContainer, expectedData);
229 QFETCH(Container, expectedData);
213 230
214 ArrayData<2> arrayData{inputData};
231 ArrayData<2> arrayData{inputData.first, inputData.second};
215 232 auto sortedArrayData = arrayData.sort(sortPermutation);
216 233 QVERIFY(sortedArrayData != nullptr);
217 234
218 for (auto i = 0; i < expectedData.size(); ++i) {
219 QVERIFY(sortedArrayData->data(i) == expectedData.at(i));
220 }
235 verifyArrayData(*sortedArrayData, expectedData);
221 236 }
222 237
223 238 QTEST_MAIN(TestTwoDimArrayData)
@@ -17,51 +17,6 QDateTime dateTime(int year, int month, int day, int hours, int minutes, int sec
17 17 return QDateTime{{year, month, day}, {hours, minutes, seconds}, Qt::UTC};
18 18 }
19 19
20 /// Compares two vectors that can potentially contain NaN values
21 bool compareVectors(const QVector<double> &v1, const QVector<double> &v2)
22 {
23 if (v1.size() != v2.size()) {
24 return false;
25 }
26
27 auto result = true;
28 auto v2It = v2.cbegin();
29 for (auto v1It = v1.cbegin(), v1End = v1.cend(); v1It != v1End && result; ++v1It, ++v2It) {
30 auto v1Value = *v1It;
31 auto v2Value = *v2It;
32
33 // If v1 is NaN, v2 has to be NaN too
34 result = std::isnan(v1Value) ? std::isnan(v2Value) : (v1Value == v2Value);
35 }
36
37 return result;
38 }
39
40 bool compareVectors(const QVector<QVector<double> > &v1, const QVector<QVector<double> > &v2)
41 {
42 if (v1.size() != v2.size()) {
43 return false;
44 }
45
46 auto result = true;
47 for (auto i = 0; i < v1.size() && result; ++i) {
48 result &= compareVectors(v1.at(i), v2.at(i));
49 }
50
51 return result;
52 }
53
54 QVector<QVector<double> > valuesData(const ArrayData<1> &arrayData)
55 {
56 return QVector<QVector<double> >{arrayData.data()};
57 }
58
59 QVector<QVector<double> > valuesData(const ArrayData<2> &arrayData)
60 {
61 return arrayData.data();
62 }
63
64
65 20 QString inputFilePath(const QString &inputFileName)
66 21 {
67 22 return QFileInfo{TESTS_RESOURCES_PATH, inputFileName}.absoluteFilePath();
@@ -106,10 +61,26 struct ExpectedResults {
106 61 QVERIFY(dataSeries->xAxisUnit() == m_XAxisUnit);
107 62 QVERIFY(dataSeries->valuesUnit() == m_ValuesUnit);
108 63
109 // Checks values : as the vectors can potentially contain NaN values, we must use a
110 // custom vector comparison method
111 QVERIFY(compareVectors(dataSeries->xAxisData()->data(), m_XAxisData));
112 QVERIFY(compareVectors(valuesData(*dataSeries->valuesData()), m_ValuesData));
64 auto verifyRange = [dataSeries](const auto &expectedData, const auto &equalFun) {
65 QVERIFY(std::equal(dataSeries->cbegin(), dataSeries->cend(), expectedData.cbegin(),
66 expectedData.cend(),
67 [&equalFun](const auto &dataSeriesIt, const auto &expectedX) {
68 return equalFun(dataSeriesIt, expectedX);
69 }));
70 };
71
72 // Checks x-axis data
73 verifyRange(m_XAxisData, [](const auto &seriesIt, const auto &value) {
74 return seriesIt.x() == value;
75 });
76
77 // Checks values data of each component
78 for (auto i = 0; i < m_ValuesData.size(); ++i) {
79 verifyRange(m_ValuesData.at(i), [i](const auto &seriesIt, const auto &value) {
80 auto itValue = seriesIt.value(i);
81 return (std::isnan(itValue) && std::isnan(value)) || seriesIt.value(i) == value;
82 });
83 }
113 84 }
114 85 else {
115 86 QVERIFY(results == nullptr);
General Comments 0
You need to be logged in to leave comments. Login now