import pytest from supervision.geometry.core import Point, Position, Vector def test_position_list_returns_enum_values_in_definition_order() -> None: """Position.list returns stable string values for public option lists.""" assert Position.list() == [position.value for position in Position] @pytest.mark.parametrize( ("vector", "point", "expected_result"), [ (Vector(start=Point(x=0, y=0), end=Point(x=5, y=5)), Point(x=-1, y=1), 10.0), (Vector(start=Point(x=0, y=0), end=Point(x=5, y=5)), Point(x=6, y=6), 0.0), (Vector(start=Point(x=0, y=0), end=Point(x=5, y=5)), Point(x=3, y=6), 15.0), (Vector(start=Point(x=5, y=5), end=Point(x=0, y=0)), Point(x=-1, y=1), -10.0), (Vector(start=Point(x=5, y=5), end=Point(x=0, y=0)), Point(x=6, y=6), 0.0), (Vector(start=Point(x=5, y=5), end=Point(x=0, y=0)), Point(x=3, y=6), -15.0), (Vector(start=Point(x=0, y=0), end=Point(x=1, y=0)), Point(x=0, y=0), 0.0), (Vector(start=Point(x=0, y=0), end=Point(x=1, y=0)), Point(x=0, y=-1), -1.0), (Vector(start=Point(x=0, y=0), end=Point(x=1, y=0)), Point(x=0, y=1), 1.0), (Vector(start=Point(x=1, y=0), end=Point(x=0, y=0)), Point(x=0, y=0), 0.0), (Vector(start=Point(x=1, y=0), end=Point(x=0, y=0)), Point(x=0, y=-1), 1.0), (Vector(start=Point(x=1, y=0), end=Point(x=0, y=0)), Point(x=0, y=1), -1.0), (Vector(start=Point(x=1, y=1), end=Point(x=1, y=3)), Point(x=0, y=0), 2.0), (Vector(start=Point(x=1, y=1), end=Point(x=1, y=3)), Point(x=1, y=4), 0.0), (Vector(start=Point(x=1, y=1), end=Point(x=1, y=3)), Point(x=2, y=4), -2.0), (Vector(start=Point(x=1, y=3), end=Point(x=1, y=1)), Point(x=0, y=0), -2.0), (Vector(start=Point(x=1, y=3), end=Point(x=1, y=1)), Point(x=1, y=4), 0.0), (Vector(start=Point(x=1, y=3), end=Point(x=1, y=1)), Point(x=2, y=4), 2.0), ], ) def test_vector_cross_product( vector: Vector, point: Point, expected_result: float ) -> None: """ Verify that Vector.cross_product correctly calculates the scalar value. Scenario: Computing the cross product between a vector and a point. Expected: Correct scalar value is returned, which is used to determine which side of a line a point lies on (essential for line crossing counting). """ result = vector.cross_product(point=point) assert result == expected_result @pytest.mark.parametrize( ("vector", "expected_result"), [ (Vector(start=Point(x=0, y=0), end=Point(x=0, y=0)), 0.0), (Vector(start=Point(x=1, y=0), end=Point(x=0, y=0)), 1.0), (Vector(start=Point(x=0, y=1), end=Point(x=0, y=0)), 1.0), (Vector(start=Point(x=0, y=0), end=Point(x=1, y=0)), 1.0), (Vector(start=Point(x=0, y=0), end=Point(x=0, y=1)), 1.0), (Vector(start=Point(x=-1, y=0), end=Point(x=0, y=0)), 1.0), (Vector(start=Point(x=0, y=-1), end=Point(x=0, y=0)), 1.0), (Vector(start=Point(x=0, y=0), end=Point(x=-1, y=0)), 1.0), (Vector(start=Point(x=0, y=0), end=Point(x=0, y=-1)), 1.0), (Vector(start=Point(x=0, y=0), end=Point(x=3, y=4)), 5.0), (Vector(start=Point(x=0, y=0), end=Point(x=-3, y=4)), 5.0), (Vector(start=Point(x=0, y=0), end=Point(x=3, y=-4)), 5.0), (Vector(start=Point(x=0, y=0), end=Point(x=-3, y=-4)), 5.0), (Vector(start=Point(x=0, y=0), end=Point(x=4, y=3)), 5.0), (Vector(start=Point(x=3, y=4), end=Point(x=0, y=0)), 5.0), (Vector(start=Point(x=4, y=3), end=Point(x=0, y=0)), 5.0), ], ) def test_vector_magnitude(vector: Vector, expected_result: float) -> None: """ Verify that Vector.magnitude correctly calculates Euclidean distance. Scenario: Calculating the magnitude (length) of a vector. Expected: Correct Euclidean distance between start and end points is returned, fundamental for various spatial calculations. """ result = vector.magnitude assert result == expected_result