+{-# LANGUAGE BangPatterns #-}
-- | The Grid module just contains the Grid type and two constructors
-- for it. We hide the main Grid constructor because we don't want
-- to allow instantiation of a grid with h <= 0.
where
import qualified Data.Array.Repa as R
-import Test.HUnit
+import Test.HUnit (Assertion, assertEqual)
import Test.Framework (Test, testGroup)
import Test.Framework.Providers.HUnit (testCase)
import Test.Framework.Providers.QuickCheck2 (testProperty)
Positive(..),
Property,
choose)
-import Assertions
-import Comparisons
+import Assertions (assertAlmostEqual, assertTrue)
+import Comparisons ((~=))
import Cube (Cube(Cube),
find_containing_tetrahedron,
tetrahedra,
tetrahedron)
-import Examples
-import FunctionValues
-import Point (Point)
-import ScaleFactor
+import Examples (trilinear, trilinear9x9x9, zeros, naturals_1d)
+import FunctionValues (make_values, value_at)
+import Point (Point(..))
+import ScaleFactor (ScaleFactor)
import Tetrahedron (Tetrahedron, c, polynomial, v0, v1, v2, v3)
-import ThreeDimensional
+import ThreeDimensional (ThreeDimensional(..))
import Values (Values3D, dims, empty3d, zoom_shape)
-- another in each direction (x,y,z).
data Grid = Grid { h :: Double, -- MUST BE GREATER THAN ZERO!
function_values :: Values3D }
- deriving (Eq, Show)
+ deriving (Show)
instance Arbitrary Grid where
-- centered on that position. If there is no cube there (i.e. the
-- position is outside of the grid), it will throw an error.
cube_at :: Grid -> Int -> Int -> Int -> Cube
-cube_at g i j k
+cube_at !g !i !j !k
| i < 0 = error "i < 0 in cube_at"
| i >= xsize = error "i >= xsize in cube_at"
| j < 0 = error "j < 0 in cube_at"
-- Since our grid is rectangular, we can figure this out without having
-- to check every cube.
find_containing_cube :: Grid -> Point -> Cube
-find_containing_cube g p =
+find_containing_cube g (Point x y z) =
cube_at g i j k
where
- (x, y, z) = p
i = calculate_containing_cube_coordinate g x
j = calculate_containing_cube_coordinate g y
k = calculate_containing_cube_coordinate g z
-{-# INLINE zoom_lookup #-}
zoom_lookup :: Values3D -> ScaleFactor -> a -> (R.DIM3 -> Double)
zoom_lookup v3d scale_factor _ =
zoom_result v3d scale_factor
-{-# INLINE zoom_result #-}
zoom_result :: Values3D -> ScaleFactor -> R.DIM3 -> Double
zoom_result v3d (sfx, sfy, sfz) (R.Z R.:. m R.:. n R.:. o) =
f p
m' = (fromIntegral m) / (fromIntegral sfx) - offset
n' = (fromIntegral n) / (fromIntegral sfy) - offset
o' = (fromIntegral o) / (fromIntegral sfz) - offset
- p = (m', n', o') :: Point
+ p = Point m' n' o'
cube = find_containing_cube g p
t = find_containing_tetrahedron cube p
f = polynomial t
test_trilinear_f0_t0_v0 :: Assertion
test_trilinear_f0_t0_v0 =
- assertEqual "v0 is correct" (v0 t) (1, 1, 1)
+ assertEqual "v0 is correct" (v0 t) (Point 1 1 1)
test_trilinear_f0_t0_v1 :: Assertion
test_trilinear_f0_t0_v1 =
- assertEqual "v1 is correct" (v1 t) (0.5, 1, 1)
+ assertEqual "v1 is correct" (v1 t) (Point 0.5 1 1)
test_trilinear_f0_t0_v2 :: Assertion
test_trilinear_f0_t0_v2 =
- assertEqual "v2 is correct" (v2 t) (0.5, 0.5, 1.5)
+ assertEqual "v2 is correct" (v2 t) (Point 0.5 0.5 1.5)
test_trilinear_f0_t0_v3 :: Assertion
test_trilinear_f0_t0_v3 =
- assertClose "v3 is correct" (v3 t) (0.5, 1.5, 1.5)
+ assertEqual "v3 is correct" (v3 t) (Point 0.5 1.5 1.5)
test_trilinear_reproduced :: Assertion
test_trilinear_reproduced =
assertTrue "trilinears are reproduced correctly" $
- and [p (i', j', k') ~= value_at trilinear i j k
+ and [p (Point i' j' k') ~= value_at trilinear i j k
| i <- [0..2],
j <- [0..2],
k <- [0..2],
+ c0 <- cs,
t <- tetrahedra c0,
let p = polynomial t,
let i' = fromIntegral i,
let k' = fromIntegral k]
where
g = make_grid 1 trilinear
- c0 = cube_at g 1 1 1
+ cs = [ cube_at g ci cj ck | ci <- [0..2], cj <- [0..2], ck <- [0..2] ]
test_zeros_reproduced :: Assertion
test_zeros_reproduced =
assertTrue "the zero function is reproduced correctly" $
- and [p (i', j', k') ~= value_at zeros i j k
+ and [p (Point i' j' k') ~= value_at zeros i j k
| i <- [0..2],
j <- [0..2],
k <- [0..2],
let i' = fromIntegral i,
let j' = fromIntegral j,
- let k' = fromIntegral k]
+ let k' = fromIntegral k,
+ c0 <- cs,
+ t0 <- tetrahedra c0,
+ let p = polynomial t0 ]
where
g = make_grid 1 zeros
- c0 = cube_at g 1 1 1
- t0 = tetrahedron c0 0
- p = polynomial t0
+ cs = [ cube_at g ci cj ck | ci <- [0..2], cj <- [0..2], ck <- [0..2] ]
-- | Make sure we can reproduce a 9x9x9 trilinear from the 3x3x3 one.
test_trilinear9x9x9_reproduced :: Assertion
test_trilinear9x9x9_reproduced =
assertTrue "trilinear 9x9x9 is reproduced correctly" $
- and [p (i', j', k') ~= value_at trilinear9x9x9 i j k
+ and [p (Point i' j' k') ~= value_at trilinear9x9x9 i j k
| i <- [0..8],
j <- [0..8],
k <- [0..8],
where
g = make_grid 1 naturals_1d
cube = cube_at g 0 18 0
- p = (0, 17.5, 0.5) :: Point
+ p = Point 0 17.5 0.5
t20 = tetrahedron cube 20
trilinear_c0_t0_tests,
p80_29_properties,
testCase "tetrahedra collision test isn't too sensitive"
- test_tetrahedra_collision_sensitivity,
- testCase "trilinear reproduced" test_trilinear_reproduced,
- testCase "zeros reproduced" test_zeros_reproduced ]
+ test_tetrahedra_collision_sensitivity,
+ testProperty "cube indices within bounds"
+ prop_cube_indices_never_go_out_of_bounds ]
-- Do the slow tests last so we can stop paying attention.
slow_tests :: Test.Framework.Test
slow_tests =
testGroup "Slow Tests" [
- testProperty "cube indices within bounds"
- prop_cube_indices_never_go_out_of_bounds,
- testCase "trilinear9x9x9 reproduced" test_trilinear9x9x9_reproduced ]
+ testCase "trilinear reproduced" test_trilinear_reproduced,
+ testCase "trilinear9x9x9 reproduced" test_trilinear9x9x9_reproduced,
+ testCase "zeros reproduced" test_zeros_reproduced ]