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/*************************************************************************/
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/* test_basis.h */
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/* Copyright (c) 2007-2022 Juan Linietsky, Ariel Manzur. */
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# ifndef TEST_BASIS_H
# define TEST_BASIS_H
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# include "core/math/basis.h"
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# include "core/math/random_number_generator.h"
# include "tests/test_macros.h"
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namespace TestBasis {
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Vector3 deg_to_rad ( const Vector3 & p_rotation ) {
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return p_rotation / 180.0 * Math_PI ;
}
Vector3 rad2deg ( const Vector3 & p_rotation ) {
return p_rotation / Math_PI * 180.0 ;
}
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String get_rot_order_name ( EulerOrder ro ) {
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switch ( ro ) {
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case EulerOrder : : XYZ :
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return " XYZ " ;
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case EulerOrder : : XZY :
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return " XZY " ;
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case EulerOrder : : YZX :
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return " YZX " ;
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case EulerOrder : : YXZ :
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return " YXZ " ;
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case EulerOrder : : ZXY :
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return " ZXY " ;
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case EulerOrder : : ZYX :
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return " ZYX " ;
default :
return " [Not supported] " ;
}
}
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void test_rotation ( Vector3 deg_original_euler , EulerOrder rot_order ) {
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// This test:
// 1. Converts the rotation vector from deg to rad.
// 2. Converts euler to basis.
// 3. Converts the above basis back into euler.
// 4. Converts the above euler into basis again.
// 5. Compares the basis obtained in step 2 with the basis of step 4
//
// The conversion "basis to euler", done in the step 3, may be different from
// the original euler, even if the final rotation are the same.
// This happens because there are more ways to represents the same rotation,
// both valid, using eulers.
// For this reason is necessary to convert that euler back to basis and finally
// compares it.
//
// In this way we can assert that both functions: basis to euler / euler to basis
// are correct.
// Euler to rotation
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const Vector3 original_euler = deg_to_rad ( deg_original_euler ) ;
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const Basis to_rotation = Basis : : from_euler ( original_euler , rot_order ) ;
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// Euler from rotation
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const Vector3 euler_from_rotation = to_rotation . get_euler ( rot_order ) ;
const Basis rotation_from_computed_euler = Basis : : from_euler ( euler_from_rotation , rot_order ) ;
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Basis res = to_rotation . inverse ( ) * rotation_from_computed_euler ;
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CHECK_MESSAGE ( ( res . get_column ( 0 ) - Vector3 ( 1.0 , 0.0 , 0.0 ) ) . length ( ) < = 0.1 , vformat ( " Fail due to X %s \n " , String ( res . get_column ( 0 ) ) ) . utf8 ( ) . ptr ( ) ) ;
CHECK_MESSAGE ( ( res . get_column ( 1 ) - Vector3 ( 0.0 , 1.0 , 0.0 ) ) . length ( ) < = 0.1 , vformat ( " Fail due to Y %s \n " , String ( res . get_column ( 1 ) ) ) . utf8 ( ) . ptr ( ) ) ;
CHECK_MESSAGE ( ( res . get_column ( 2 ) - Vector3 ( 0.0 , 0.0 , 1.0 ) ) . length ( ) < = 0.1 , vformat ( " Fail due to Z %s \n " , String ( res . get_column ( 2 ) ) ) . utf8 ( ) . ptr ( ) ) ;
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// Double check `to_rotation` decomposing with XYZ rotation order.
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const Vector3 euler_xyz_from_rotation = to_rotation . get_euler ( EulerOrder : : XYZ ) ;
Basis rotation_from_xyz_computed_euler = Basis : : from_euler ( euler_xyz_from_rotation , EulerOrder : : XYZ ) ;
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res = to_rotation . inverse ( ) * rotation_from_xyz_computed_euler ;
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CHECK_MESSAGE ( ( res . get_column ( 0 ) - Vector3 ( 1.0 , 0.0 , 0.0 ) ) . length ( ) < = 0.1 , vformat ( " Double check with XYZ rot order failed, due to X %s \n " , String ( res . get_column ( 0 ) ) ) . utf8 ( ) . ptr ( ) ) ;
CHECK_MESSAGE ( ( res . get_column ( 1 ) - Vector3 ( 0.0 , 1.0 , 0.0 ) ) . length ( ) < = 0.1 , vformat ( " Double check with XYZ rot order failed, due to Y %s \n " , String ( res . get_column ( 1 ) ) ) . utf8 ( ) . ptr ( ) ) ;
CHECK_MESSAGE ( ( res . get_column ( 2 ) - Vector3 ( 0.0 , 0.0 , 1.0 ) ) . length ( ) < = 0.1 , vformat ( " Double check with XYZ rot order failed, due to Z %s \n " , String ( res . get_column ( 2 ) ) ) . utf8 ( ) . ptr ( ) ) ;
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INFO ( vformat ( " Rotation order: %s \n . " , get_rot_order_name ( rot_order ) ) . utf8 ( ) . ptr ( ) ) ;
INFO ( vformat ( " Original Rotation: %s \n " , String ( deg_original_euler ) ) . utf8 ( ) . ptr ( ) ) ;
INFO ( vformat ( " Quaternion to rotation order: %s \n " , String ( rad2deg ( euler_from_rotation ) ) ) . utf8 ( ) . ptr ( ) ) ;
}
TEST_CASE ( " [Basis] Euler conversions " ) {
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Vector < EulerOrder > euler_order_to_test ;
euler_order_to_test . push_back ( EulerOrder : : XYZ ) ;
euler_order_to_test . push_back ( EulerOrder : : XZY ) ;
euler_order_to_test . push_back ( EulerOrder : : YZX ) ;
euler_order_to_test . push_back ( EulerOrder : : YXZ ) ;
euler_order_to_test . push_back ( EulerOrder : : ZXY ) ;
euler_order_to_test . push_back ( EulerOrder : : ZYX ) ;
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Vector < Vector3 > vectors_to_test ;
// Test the special cases.
vectors_to_test . push_back ( Vector3 ( 0.0 , 0.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.5 , 0.5 , 0.5 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 0.5 , - 0.5 , - 0.5 ) ) ;
vectors_to_test . push_back ( Vector3 ( 40.0 , 40.0 , 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 40.0 , - 40.0 , - 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , 0.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , - 90.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , 0.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , 0.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , 90.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , 0.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , 0.0 , - 30.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , - 30.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 30.0 , 0.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , 0.0 , 30.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.0 , 30.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 30.0 , 0.0 , 0.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.5 , 50.0 , 20.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 0.5 , - 50.0 , - 20.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.5 , 0.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 0.5 , 0.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 360.0 , 360.0 , 360.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 360.0 , - 360.0 , - 360.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , 60.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , 60.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , - 60.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , - 60.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , 60.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , 60.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , - 60.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , - 60.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 60.0 , 90.0 , - 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 60.0 , - 90.0 , - 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 60.0 , - 90.0 , - 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 60.0 , 90.0 , 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 60.0 , 90.0 , 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 60.0 , - 90.0 , 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 60.0 , - 90.0 , 40.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , 90.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , 90.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , - 90.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , - 90.0 , - 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 90.0 , 90.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , 90.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 90.0 , - 90.0 , 90.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 20.0 , 150.0 , 30.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 20.0 , - 150.0 , 30.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 120.0 , - 150.0 , 30.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( - 120.0 , - 150.0 , - 130.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 120.0 , - 150.0 , - 130.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 120.0 , 150.0 , - 130.0 ) ) ;
vectors_to_test . push_back ( Vector3 ( 120.0 , 150.0 , 130.0 ) ) ;
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for ( int h = 0 ; h < euler_order_to_test . size ( ) ; h + = 1 ) {
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for ( int i = 0 ; i < vectors_to_test . size ( ) ; i + = 1 ) {
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test_rotation ( vectors_to_test [ i ] , euler_order_to_test [ h ] ) ;
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}
}
}
TEST_CASE ( " [Stress][Basis] Euler conversions " ) {
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Vector < EulerOrder > euler_order_to_test ;
euler_order_to_test . push_back ( EulerOrder : : XYZ ) ;
euler_order_to_test . push_back ( EulerOrder : : XZY ) ;
euler_order_to_test . push_back ( EulerOrder : : YZX ) ;
euler_order_to_test . push_back ( EulerOrder : : YXZ ) ;
euler_order_to_test . push_back ( EulerOrder : : ZXY ) ;
euler_order_to_test . push_back ( EulerOrder : : ZYX ) ;
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Vector < Vector3 > vectors_to_test ;
// Add 1000 random vectors with weirds numbers.
RandomNumberGenerator rng ;
for ( int _ = 0 ; _ < 1000 ; _ + = 1 ) {
vectors_to_test . push_back ( Vector3 (
rng . randf_range ( - 1800 , 1800 ) ,
rng . randf_range ( - 1800 , 1800 ) ,
rng . randf_range ( - 1800 , 1800 ) ) ) ;
}
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for ( int h = 0 ; h < euler_order_to_test . size ( ) ; h + = 1 ) {
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for ( int i = 0 ; i < vectors_to_test . size ( ) ; i + = 1 ) {
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test_rotation ( vectors_to_test [ i ] , euler_order_to_test [ h ] ) ;
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}
}
}
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TEST_CASE ( " [Basis] Set axis angle " ) {
Vector3 axis ;
real_t angle ;
real_t pi = ( real_t ) Math_PI ;
// Testing the singularity when the angle is 0°.
Basis identity ( 1 , 0 , 0 , 0 , 1 , 0 , 0 , 0 , 1 ) ;
identity . get_axis_angle ( axis , angle ) ;
CHECK ( angle = = 0 ) ;
// Testing the singularity when the angle is 180°.
Basis singularityPi ( - 1 , 0 , 0 , 0 , 1 , 0 , 0 , 0 , - 1 ) ;
singularityPi . get_axis_angle ( axis , angle ) ;
CHECK ( Math : : is_equal_approx ( angle , pi ) ) ;
// Testing reversing the an axis (of an 30° angle).
float cos30deg = Math : : cos ( Math : : deg_to_rad ( ( real_t ) 30.0 ) ) ;
Basis z_positive ( cos30deg , - 0.5 , 0 , 0.5 , cos30deg , 0 , 0 , 0 , 1 ) ;
Basis z_negative ( cos30deg , 0.5 , 0 , - 0.5 , cos30deg , 0 , 0 , 0 , 1 ) ;
z_positive . get_axis_angle ( axis , angle ) ;
CHECK ( Math : : is_equal_approx ( angle , Math : : deg_to_rad ( ( real_t ) 30.0 ) ) ) ;
CHECK ( axis = = Vector3 ( 0 , 0 , 1 ) ) ;
z_negative . get_axis_angle ( axis , angle ) ;
CHECK ( Math : : is_equal_approx ( angle , Math : : deg_to_rad ( ( real_t ) 30.0 ) ) ) ;
CHECK ( axis = = Vector3 ( 0 , 0 , - 1 ) ) ;
// Testing a rotation of 90° on x-y-z.
Basis x90deg ( 1 , 0 , 0 , 0 , 0 , - 1 , 0 , 1 , 0 ) ;
x90deg . get_axis_angle ( axis , angle ) ;
CHECK ( Math : : is_equal_approx ( angle , pi / ( real_t ) 2 ) ) ;
CHECK ( axis = = Vector3 ( 1 , 0 , 0 ) ) ;
Basis y90deg ( 0 , 0 , 1 , 0 , 1 , 0 , - 1 , 0 , 0 ) ;
y90deg . get_axis_angle ( axis , angle ) ;
CHECK ( axis = = Vector3 ( 0 , 1 , 0 ) ) ;
Basis z90deg ( 0 , - 1 , 0 , 1 , 0 , 0 , 0 , 0 , 1 ) ;
z90deg . get_axis_angle ( axis , angle ) ;
CHECK ( axis = = Vector3 ( 0 , 0 , 1 ) ) ;
// Regression test: checks that the method returns a small angle (not 0).
Basis tiny ( 1 , 0 , 0 , 0 , 0.9999995 , - 0.001 , 0 , 001 , 0.9999995 ) ; // The min angle possible with float is 0.001rad.
tiny . get_axis_angle ( axis , angle ) ;
CHECK ( Math : : is_equal_approx ( angle , ( real_t ) 0.001 , ( real_t ) 0.0001 ) ) ;
// Regression test: checks that the method returns an angle which is a number (not NaN)
Basis bugNan ( 1.00000024 , 0 , 0.000100001693 , 0 , 1 , 0 , - 0.000100009143 , 0 , 1.00000024 ) ;
bugNan . get_axis_angle ( axis , angle ) ;
CHECK ( ! Math : : is_nan ( angle ) ) ;
}
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TEST_CASE ( " [Basis] Finite number checks " ) {
const Vector3 x ( 0 , 1 , 2 ) ;
const Vector3 infinite ( NAN , NAN , NAN ) ;
CHECK_MESSAGE (
Basis ( x , x , x ) . is_finite ( ) ,
" Basis with all components finite should be finite " ) ;
CHECK_FALSE_MESSAGE (
Basis ( infinite , x , x ) . is_finite ( ) ,
" Basis with one component infinite should not be finite. " ) ;
CHECK_FALSE_MESSAGE (
Basis ( x , infinite , x ) . is_finite ( ) ,
" Basis with one component infinite should not be finite. " ) ;
CHECK_FALSE_MESSAGE (
Basis ( x , x , infinite ) . is_finite ( ) ,
" Basis with one component infinite should not be finite. " ) ;
CHECK_FALSE_MESSAGE (
Basis ( infinite , infinite , x ) . is_finite ( ) ,
" Basis with two components infinite should not be finite. " ) ;
CHECK_FALSE_MESSAGE (
Basis ( infinite , x , infinite ) . is_finite ( ) ,
" Basis with two components infinite should not be finite. " ) ;
CHECK_FALSE_MESSAGE (
Basis ( x , infinite , infinite ) . is_finite ( ) ,
" Basis with two components infinite should not be finite. " ) ;
CHECK_FALSE_MESSAGE (
Basis ( infinite , infinite , infinite ) . is_finite ( ) ,
" Basis with three components infinite should not be finite. " ) ;
}
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} // namespace TestBasis
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# endif // TEST_BASIS_H