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mlz
BornAgain
Commits
13f5052a
Commit
13f5052a
authored
10 months ago
by
Wuttke, Joachim
Browse files
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persistence tests: relax accuracy requirement in view of other architectures
parent
8cfee812
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1 merge request
!2530
persistence tests: relax accuracy requirement in view of other architectures (#952)
Pipeline
#141111
passed
10 months ago
Stage: build
Changes
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1 changed file
Tests/Suite/Common/TestSuite.h
+58
-56
58 additions, 56 deletions
Tests/Suite/Common/TestSuite.h
with
58 additions
and
56 deletions
Tests/Suite/Common/TestSuite.h
+
58
−
56
View file @
13f5052a
...
...
@@ -41,9 +41,11 @@
#define eps_direct_vs_python(eps_direct, eps_python) eps_python
#endif
static
const
double
eps1
=
9e-11
;
// typically 5e-13 on x86_64, looser for arm64
TEST
(
TESTNAME
,
FormFactors
)
{
const
double
eps
=
eps_direct_vs_python
(
2e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
// 2e-13 on x86_64
for
(
const
std
::
string
&
ffname
:
FormFactorComponents
().
keys
())
{
const
IFormFactor
*
ff
=
FormFactorComponents
().
getItem
(
ffname
)
->
clone
();
ASSERT
(
ff
);
...
...
@@ -57,7 +59,7 @@ TEST(TESTNAME, FormFactors)
TEST
(
TESTNAME
,
FormFactorsWithAbsorption
)
{
const
double
eps
=
eps_direct_vs_python
(
8e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
// 2e-13 on x86_64
for
(
const
std
::
string
&
ffname
:
FormFactorComponents
().
keys
())
{
const
IFormFactor
*
ff
=
FormFactorComponents
().
getItem
(
ffname
)
->
clone
();
ASSERT
(
ff
);
...
...
@@ -71,7 +73,7 @@ TEST(TESTNAME, FormFactorsWithAbsorption)
TEST
(
TESTNAME
,
GISASAbsorptiveSLDLayers
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createLayersWithAbsorptionBySLD
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"GISASAbsorptiveSLDLayers"
,
*
sim
,
eps
));
...
...
@@ -79,7 +81,7 @@ TEST(TESTNAME, GISASAbsorptiveSLDLayers)
TEST
(
TESTNAME
,
CylindersAndPrisms
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCylindersAndPrisms
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CylindersAndPrisms"
,
*
sim
,
eps
));
...
...
@@ -87,7 +89,7 @@ TEST(TESTNAME, CylindersAndPrisms)
TEST
(
TESTNAME
,
RadialParacrystal
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createRadialParacrystal
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"RadialParacrystal"
,
*
sim
,
eps
));
...
...
@@ -95,7 +97,7 @@ TEST(TESTNAME, RadialParacrystal)
TEST
(
TESTNAME
,
HardDisk
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createHardDisk
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"HardDisk"
,
*
sim
,
eps
));
...
...
@@ -103,7 +105,7 @@ TEST(TESTNAME, HardDisk)
TEST
(
TESTNAME
,
Basic2DParacrystal
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
for
(
const
std
::
string
&
pdfname
:
Profile2DComponents
().
keys
())
{
const
IProfile2D
*
pdf2
=
Profile2DComponents
().
getItem
(
pdfname
)
->
clone
();
ASSERT
(
pdf2
);
...
...
@@ -126,7 +128,7 @@ TEST(TESTNAME, HexParacrystal)
TEST
(
TESTNAME
,
Lattice1D
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createLattice1D
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"Lattice1D"
,
*
sim
,
eps
));
...
...
@@ -143,7 +145,7 @@ TEST(TESTNAME, RectParacrystal)
TEST
(
TESTNAME
,
CoreShellParticle
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCoreShellParticle
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CoreShellParticle"
,
*
sim
,
eps
));
...
...
@@ -151,7 +153,7 @@ TEST(TESTNAME, CoreShellParticle)
TEST
(
TESTNAME
,
CoreShellBoxRotateZandY
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCoreShellBoxRotateZandY
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CoreShellBoxRotateZandY"
,
*
sim
,
eps
));
...
...
@@ -159,7 +161,7 @@ TEST(TESTNAME, CoreShellBoxRotateZandY)
TEST
(
TESTNAME
,
MultiLayerWithRoughness
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMultiLayerWithRoughness
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"MultiLayerWithRoughness"
,
*
sim
,
eps
));
...
...
@@ -167,7 +169,7 @@ TEST(TESTNAME, MultiLayerWithRoughness)
TEST
(
TESTNAME
,
SquareLattice2D
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createSquareLattice2D
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"SquareLattice2D"
,
*
sim
,
eps
));
...
...
@@ -175,7 +177,7 @@ TEST(TESTNAME, SquareLattice2D)
TEST
(
TESTNAME
,
CenteredSquareLattice2D
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCenteredSquareLattice2D
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CenteredSquareLattice2D"
,
*
sim
,
eps
));
...
...
@@ -183,7 +185,7 @@ TEST(TESTNAME, CenteredSquareLattice2D)
TEST
(
TESTNAME
,
RotatedSquareLattice2D
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createRotatedSquareLattice2D
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"RotatedSquareLattice2D"
,
*
sim
,
eps
));
...
...
@@ -191,7 +193,7 @@ TEST(TESTNAME, RotatedSquareLattice2D)
TEST
(
TESTNAME
,
FiniteSquareLattice2D
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createFiniteSquareLattice2D
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"FiniteSquareLattice2D"
,
*
sim
,
eps
));
...
...
@@ -199,7 +201,7 @@ TEST(TESTNAME, FiniteSquareLattice2D)
TEST
(
TESTNAME
,
RotatedPyramids
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createRotatedPyramids
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"RotatedPyramids"
,
*
sim
,
eps
));
...
...
@@ -207,7 +209,7 @@ TEST(TESTNAME, RotatedPyramids)
TEST
(
TESTNAME
,
ThickAbsorptiveSampleWithRoughness
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-4
,
5e-4
);
// issue #817 (previously
5e-13
, 8e-9)
const
double
eps
=
eps_direct_vs_python
(
5e-4
,
5e-4
);
// issue #817 (previously
eps1
, 8e-9)
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createThickAbsorptiveSample
());
auto
sim
=
test
::
makeSimulation
::
ExtraLongWavelengthGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"ThickAbsorptiveSampleWithRoughness"
,
*
sim
,
eps
));
...
...
@@ -215,7 +217,7 @@ TEST(TESTNAME, ThickAbsorptiveSampleWithRoughness)
TEST
(
TESTNAME
,
Compound
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCompound
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"Compound"
,
*
sim
,
eps
));
...
...
@@ -223,7 +225,7 @@ TEST(TESTNAME, Compound)
TEST
(
TESTNAME
,
CompoundPlus
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCompoundPlus
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CompoundPlus"
,
*
sim
,
eps
));
...
...
@@ -231,7 +233,7 @@ TEST(TESTNAME, CompoundPlus)
TEST
(
TESTNAME
,
BoxCompositionRotateX
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createBoxCompositionRotateX
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BoxCompositionRotateX"
,
*
sim
,
eps
));
...
...
@@ -239,7 +241,7 @@ TEST(TESTNAME, BoxCompositionRotateX)
TEST
(
TESTNAME
,
BoxCompositionRotateY
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createBoxCompositionRotateY
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BoxCompositionRotateY"
,
*
sim
,
eps
));
...
...
@@ -247,7 +249,7 @@ TEST(TESTNAME, BoxCompositionRotateY)
TEST
(
TESTNAME
,
BoxCompositionRotateZ
)
{
const
double
eps
=
eps_direct_vs_python
(
6e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
// 2e-13 on x86_64
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createBoxCompositionRotateZ
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BoxCompositionRotateZ"
,
*
sim
,
eps
));
...
...
@@ -255,7 +257,7 @@ TEST(TESTNAME, BoxCompositionRotateZ)
TEST
(
TESTNAME
,
BoxCompositionRotateZandY
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createBoxCompositionRotateZandY
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BoxCompositionRotateZandY"
,
*
sim
,
eps
));
...
...
@@ -263,7 +265,7 @@ TEST(TESTNAME, BoxCompositionRotateZandY)
TEST
(
TESTNAME
,
BoxStackComposition
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createBoxStackComposition
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BoxStackComposition"
,
*
sim
,
eps
));
...
...
@@ -271,7 +273,7 @@ TEST(TESTNAME, BoxStackComposition)
TEST
(
TESTNAME
,
MultipleLayout
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMultipleLayout
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"MultipleLayout"
,
*
sim
,
eps
));
...
...
@@ -279,7 +281,7 @@ TEST(TESTNAME, MultipleLayout)
TEST
(
TESTNAME
,
ApproximationDA
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createSizeDistributionDAModel
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"ApproximationDA"
,
*
sim
,
eps
));
...
...
@@ -287,7 +289,7 @@ TEST(TESTNAME, ApproximationDA)
TEST
(
TESTNAME
,
ApproximationLMA
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createSizeDistributionLMAModel
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"ApproximationLMA"
,
*
sim
,
eps
));
...
...
@@ -295,7 +297,7 @@ TEST(TESTNAME, ApproximationLMA)
TEST
(
TESTNAME
,
ApproximationSSCA
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createSizeDistributionSSCAModel
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"ApproximationSSCA"
,
*
sim
,
eps
));
...
...
@@ -303,7 +305,7 @@ TEST(TESTNAME, ApproximationSSCA)
TEST
(
TESTNAME
,
CosineRipple
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCosineRipple
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CosineRipple"
,
*
sim
,
eps
));
...
...
@@ -311,7 +313,7 @@ TEST(TESTNAME, CosineRipple)
TEST
(
TESTNAME
,
TriangularRipple
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createTriangularRipple
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"TriangularRipple"
,
*
sim
,
eps
));
...
...
@@ -319,7 +321,7 @@ TEST(TESTNAME, TriangularRipple)
TEST
(
TESTNAME
,
AsymRipple
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createAsymRipple
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"AsymRipple"
,
*
sim
,
eps
));
...
...
@@ -327,7 +329,7 @@ TEST(TESTNAME, AsymRipple)
TEST
(
TESTNAME
,
Mesocrystal
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMesocrystal
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"Mesocrystal"
,
*
sim
,
eps
));
...
...
@@ -335,7 +337,7 @@ TEST(TESTNAME, Mesocrystal)
TEST
(
TESTNAME
,
MesocrystalPlus
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMesocrystalPlus
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"MesocrystalPlus"
,
*
sim
,
eps
));
...
...
@@ -343,7 +345,7 @@ TEST(TESTNAME, MesocrystalPlus)
TEST
(
TESTNAME
,
CustomMorphology
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCustomMorphology
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"CustomMorphology"
,
*
sim
,
eps
));
...
...
@@ -351,7 +353,7 @@ TEST(TESTNAME, CustomMorphology)
TEST
(
TESTNAME
,
TransformBox
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createTransformBox
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"TransformBox"
,
*
sim
,
eps
));
...
...
@@ -359,7 +361,7 @@ TEST(TESTNAME, TransformBox)
TEST
(
TESTNAME
,
MagneticParticleZeroField
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticParticleZeroField
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"MagneticParticleZeroField"
,
*
sim
,
eps
));
...
...
@@ -367,7 +369,7 @@ TEST(TESTNAME, MagneticParticleZeroField)
TEST
(
TESTNAME
,
SlicedComposition
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createSlicedComposition
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"SlicedComposition"
,
*
sim
,
eps
));
...
...
@@ -375,7 +377,7 @@ TEST(TESTNAME, SlicedComposition)
TEST
(
TESTNAME
,
MagneticSubstrateZeroField
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticSubstrateZeroField
());
auto
sim
=
test
::
makeSimulation
::
MiniZPolarizedGISAS
(
*
sample
,
"PP"
);
EXPECT_TRUE
(
runTest
(
"MagneticSubstrateZeroField"
,
*
sim
,
eps
));
...
...
@@ -383,7 +385,7 @@ TEST(TESTNAME, MagneticSubstrateZeroField)
TEST
(
TESTNAME
,
MagneticRotation
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticRotation
());
auto
sim
=
test
::
makeSimulation
::
MiniZPolarizedGISAS
(
*
sample
,
"PM"
);
EXPECT_TRUE
(
runTest
(
"MagneticRotationZPM"
,
*
sim
,
eps
));
...
...
@@ -391,7 +393,7 @@ TEST(TESTNAME, MagneticRotation)
TEST
(
TESTNAME
,
MagneticRotationUnpol
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticRotation
());
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"MagneticRotationUnpol"
,
*
sim
,
eps
));
...
...
@@ -399,7 +401,7 @@ TEST(TESTNAME, MagneticRotationUnpol)
TEST
(
TESTNAME
,
MagneticSpheres
)
{
const
double
eps
=
eps_direct_vs_python
(
4e-3
,
8e-9
);
// TODO mac-arm restore
5e-13
const
double
eps
=
eps_direct_vs_python
(
4e-3
,
8e-9
);
// TODO mac-arm restore
eps1
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticSpheres
());
auto
sim
=
test
::
makeSimulation
::
MiniZPolarizedGISAS
(
*
sample
,
"PM"
);
EXPECT_TRUE
(
runTest
(
"MagneticSpheres"
,
*
sim
,
eps
));
...
...
@@ -407,7 +409,7 @@ TEST(TESTNAME, MagneticSpheres)
TEST
(
TESTNAME
,
MagneticCylinders
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
for
(
const
std
::
string
polCase
:
{
"PP"
,
"MP"
,
"PM"
,
"MM"
})
{
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticCylinders
());
auto
sim
=
test
::
makeSimulation
::
MiniZPolarizedGISAS
(
*
sample
,
polCase
);
...
...
@@ -417,7 +419,7 @@ TEST(TESTNAME, MagneticCylinders)
TEST
(
TESTNAME
,
MagneticSpheresInMagLayer
)
{
const
double
eps
=
eps_direct_vs_python
(
4e-3
,
8e-9
);
// TODO mac-arm restore
5e-13
const
double
eps
=
eps_direct_vs_python
(
4e-3
,
8e-9
);
// TODO mac-arm restore
eps1
for
(
const
std
::
string
polCase
:
{
"PP"
,
"MP"
})
{
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createMagneticLayer
());
auto
sim
=
test
::
makeSimulation
::
MiniZPolarizedGISAS
(
*
sample
,
polCase
);
...
...
@@ -427,7 +429,7 @@ TEST(TESTNAME, MagneticSpheresInMagLayer)
TEST
(
TESTNAME
,
BeamDivergence
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCylindersInBA
());
auto
sim
=
test
::
makeSimulation
::
MiniGISASBeamDivergence
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BeamDivergence"
,
*
sim
,
eps
));
...
...
@@ -443,7 +445,7 @@ TEST(TESTNAME, DetectorResolution)
TEST
(
TESTNAME
,
SimulationWithMasks
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCylindersAndPrisms
());
auto
sim
=
test
::
makeSimulation
::
GISASWithMasks
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"SimulationWithMasks"
,
*
sim
,
eps
));
...
...
@@ -458,7 +460,7 @@ TEST(TESTNAME, LargeCylindersMonteCarlo)
TEST
(
TESTNAME
,
RectDetWithRoi
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCylindersAndPrisms
());
auto
sim
=
test
::
makeSimulation
::
RectDetWithRoi
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"RectDetWithRoi"
,
*
sim
,
eps
));
...
...
@@ -466,7 +468,7 @@ TEST(TESTNAME, RectDetWithRoi)
TEST
(
TESTNAME
,
BoxesWithSpecular
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createBoxesSquareLattice2D
());
auto
sim
=
test
::
makeSimulation
::
MiniGISASSpecularPeak
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"BoxesWithSpecular"
,
*
sim
,
eps
));
...
...
@@ -474,7 +476,7 @@ TEST(TESTNAME, BoxesWithSpecular)
TEST
(
TESTNAME
,
ConstantBackground
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createCylindersInBA
();
auto
sim
=
test
::
makeSimulation
::
MiniGISAS
(
*
sample
);
sim
->
setBackground
(
ConstantBackground
(
1e3
));
...
...
@@ -483,7 +485,7 @@ TEST(TESTNAME, ConstantBackground)
TEST
(
TESTNAME
,
HomogeneousTiNiSample
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createHomogeneousMultilayer
();
auto
sim
=
test
::
makeSimulation
::
BasicSpecular
(
*
sample
,
false
);
EXPECT_TRUE
(
runTest
(
"HomogeneousTiNiSample"
,
*
sim
,
eps
));
...
...
@@ -491,7 +493,7 @@ TEST(TESTNAME, HomogeneousTiNiSample)
TEST
(
TESTNAME
,
HomogeneousTiNiSampleWithAbsorption
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createPlainMultiLayerBySLD
();
auto
sim
=
test
::
makeSimulation
::
BasicSpecular
(
*
sample
,
false
);
EXPECT_TRUE
(
runTest
(
"HomogeneousTiNiSampleWithAbsorption"
,
*
sim
,
eps
));
...
...
@@ -506,7 +508,7 @@ TEST(TESTNAME, RoughnessInSpecular)
TEST
(
TESTNAME
,
GaussianBeamFootprint
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createHomogeneousMultilayer
();
auto
sim
=
test
::
makeSimulation
::
SpecularWithGaussianBeam
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"GaussianBeamFootprint"
,
*
sim
,
eps
));
...
...
@@ -514,7 +516,7 @@ TEST(TESTNAME, GaussianBeamFootprint)
TEST
(
TESTNAME
,
SquareBeamFootprint
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createHomogeneousMultilayer
();
auto
sim
=
test
::
makeSimulation
::
SpecularWithSquareBeam
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"SquareBeamFootprint"
,
*
sim
,
eps
));
...
...
@@ -522,7 +524,7 @@ TEST(TESTNAME, SquareBeamFootprint)
TEST
(
TESTNAME
,
SpecularDivergentBeam
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createHomogeneousMultilayer
();
auto
sim
=
test
::
makeSimulation
::
SpecularDivergentBeam
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"SpecularDivergentBeam"
,
*
sim
,
eps
));
...
...
@@ -536,7 +538,7 @@ TEST(TESTNAME, SpecularDivergentBeam)
TEST
(
TESTNAME
,
RelativeResolutionTOF
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createPlainMultiLayerBySLD
();
auto
sim
=
test
::
makeSimulation
::
TOFRWithRelativeResolution
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"RelativeResolutionTOF"
,
*
sim
,
eps
));
...
...
@@ -544,7 +546,7 @@ TEST(TESTNAME, RelativeResolutionTOF)
TEST
(
TESTNAME
,
SphericalDetWithRoi
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
std
::
unique_ptr
<
const
MultiLayer
>
sample
(
ExemplarySamples
::
createCylindersAndPrisms
());
auto
sim
=
test
::
makeSimulation
::
SphericalDetWithRoi
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"SphericalDetWithRoi"
,
*
sim
,
eps
));
...
...
@@ -575,7 +577,7 @@ TEST(TESTNAME, DepthprobeSimpleLayer)
TEST
(
TESTNAME
,
OffspecResonator
)
{
const
double
eps
=
eps_direct_vs_python
(
5e-13
,
8e-9
);
const
double
eps
=
eps_direct_vs_python
(
eps1
,
8e-9
);
auto
*
sample
=
ExemplarySamples
::
createResonator
();
auto
sim
=
test
::
makeSimulation
::
MiniOffspec
(
*
sample
);
EXPECT_TRUE
(
runTest
(
"OffspecResonator"
,
*
sim
,
eps
));
...
...
This diff is collapsed.
Click to expand it.
Wuttke, Joachim
@j.wuttke
mentioned in commit
ecdd00ba
·
10 months ago
mentioned in commit
ecdd00ba
mentioned in commit ecdd00ba1e5e1e7e3a2d3cb6dd1e46430bc17438
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