1 -- | The Grid module just contains the Grid type and two constructors
2 -- for it. We hide the main Grid constructor because we don't want
3 -- to allow instantiation of a grid with h <= 0.
13 import Data.Array (Array, array, (!))
14 import qualified Data.Array.Repa as R
16 import Test.Framework (Test, testGroup)
17 import Test.Framework.Providers.HUnit (testCase)
18 import Test.Framework.Providers.QuickCheck2 (testProperty)
19 import Test.QuickCheck (Arbitrary(..), Gen, Positive(..), choose)
23 import Cube (Cube(Cube),
24 find_containing_tetrahedron,
31 import Tetrahedron (Tetrahedron, c, polynomial, v0, v1, v2, v3)
32 import ThreeDimensional
33 import Values (Values3D, dims, empty3d, zoom_shape)
36 type CubeGrid = Array (Int,Int,Int) Cube
39 -- | Our problem is defined on a Grid. The grid size is given by the
40 -- positive number h. The function values are the values of the
41 -- function at the grid points, which are distance h from one
42 -- another in each direction (x,y,z).
43 data Grid = Grid { h :: Double, -- MUST BE GREATER THAN ZERO!
44 function_values :: Values3D,
45 cube_grid :: CubeGrid }
49 instance Arbitrary Grid where
51 (Positive h') <- arbitrary :: Gen (Positive Double)
52 fvs <- arbitrary :: Gen Values3D
53 return (make_grid h' fvs)
56 -- | The constructor that we want people to use. If we're passed a
57 -- non-positive grid size, we throw an error.
58 make_grid :: Double -> Values3D -> Grid
59 make_grid grid_size values
60 | grid_size <= 0 = error "grid size must be positive"
61 | otherwise = Grid grid_size values (cubes grid_size values)
64 -- | Returns a three-dimensional array of cubes centered on the grid
65 -- points (h*i, h*j, h*k) with the appropriate 'FunctionValues'.
66 cubes :: Double -> Values3D -> CubeGrid
68 = array (lbounds, ubounds)
73 let tet_vol = (1/24)*(delta^(3::Int)),
75 Cube delta i j k (make_values fvs i j k) tet_vol]
81 ubounds = (xmax, ymax, zmax)
82 (xsize, ysize, zsize) = dims fvs
85 -- | Takes a grid and a position as an argument and returns the cube
86 -- centered on that position. If there is no cube there (i.e. the
87 -- position is outside of the grid), it will throw an error.
88 cube_at :: Grid -> Int -> Int -> Int -> Cube
90 | i < 0 = error "i < 0 in cube_at"
91 | i >= xsize = error "i >= xsize in cube_at"
92 | j < 0 = error "j < 0 in cube_at"
93 | j >= ysize = error "j >= ysize in cube_at"
94 | k < 0 = error "k < 0 in cube_at"
95 | k >= zsize = error "k >= zsize in cube_at"
96 | otherwise = (cube_grid g) ! (i,j,k)
98 fvs = function_values g
99 (xsize, ysize, zsize) = dims fvs
101 -- The first cube along any axis covers (-h/2, h/2). The second
102 -- covers (h/2, 3h/2). The third, (3h/2, 5h/2), and so on.
104 -- We translate the (x,y,z) coordinates forward by 'h/2' so that the
105 -- first covers (0, h), the second covers (h, 2h), etc. This makes
106 -- it easy to figure out which cube contains the given point.
107 calculate_containing_cube_coordinate :: Grid -> Double -> Int
108 calculate_containing_cube_coordinate g coord
109 -- Don't use a cube on the boundary if we can help it. This
110 -- returns cube #1 if we would have returned cube #0 and cube #1
113 | coord == offset && (xsize > 1 && ysize > 1 && zsize > 1) = 1
114 | otherwise = (ceiling ( (coord + offset) / cube_width )) - 1
116 (xsize, ysize, zsize) = dims (function_values g)
118 offset = cube_width / 2
121 -- | Takes a 'Grid', and returns a 'Cube' containing the given 'Point'.
122 -- Since our grid is rectangular, we can figure this out without having
123 -- to check every cube.
124 find_containing_cube :: Grid -> Point -> Cube
125 find_containing_cube g p =
129 i = calculate_containing_cube_coordinate g x
130 j = calculate_containing_cube_coordinate g y
131 k = calculate_containing_cube_coordinate g z
134 {-# INLINE zoom_lookup #-}
135 zoom_lookup :: Grid -> ScaleFactor -> a -> (R.DIM3 -> Double)
136 zoom_lookup g scale_factor _ =
137 zoom_result g scale_factor
140 {-# INLINE zoom_result #-}
141 zoom_result :: Grid -> ScaleFactor -> R.DIM3 -> Double
142 zoom_result g (sfx, sfy, sfz) (R.Z R.:. m R.:. n R.:. o) =
146 m' = (fromIntegral m) / (fromIntegral sfx) - offset
147 n' = (fromIntegral n) / (fromIntegral sfy) - offset
148 o' = (fromIntegral o) / (fromIntegral sfz) - offset
149 p = (m', n', o') :: Point
150 cube = find_containing_cube g p
151 t = find_containing_tetrahedron cube p
154 zoom :: Grid -> ScaleFactor -> Values3D
156 | xsize == 0 || ysize == 0 || zsize == 0 = empty3d
158 R.force $ R.unsafeTraverse arr transExtent (zoom_lookup g scale_factor)
160 arr = function_values g
161 (xsize, ysize, zsize) = dims arr
162 transExtent = zoom_shape scale_factor
167 -- | Check all coefficients of tetrahedron0 belonging to the cube
168 -- centered on (1,1,1) with a grid constructed from the trilinear
169 -- values. See example one in the paper.
171 -- We also verify that the four vertices on face0 of the cube are
172 -- in the correct location.
174 trilinear_c0_t0_tests :: Test.Framework.Test
175 trilinear_c0_t0_tests =
176 testGroup "trilinear c0 t0"
177 [testGroup "coefficients"
178 [testCase "c0030 is correct" test_trilinear_c0030,
179 testCase "c0003 is correct" test_trilinear_c0003,
180 testCase "c0021 is correct" test_trilinear_c0021,
181 testCase "c0012 is correct" test_trilinear_c0012,
182 testCase "c0120 is correct" test_trilinear_c0120,
183 testCase "c0102 is correct" test_trilinear_c0102,
184 testCase "c0111 is correct" test_trilinear_c0111,
185 testCase "c0210 is correct" test_trilinear_c0210,
186 testCase "c0201 is correct" test_trilinear_c0201,
187 testCase "c0300 is correct" test_trilinear_c0300,
188 testCase "c1020 is correct" test_trilinear_c1020,
189 testCase "c1002 is correct" test_trilinear_c1002,
190 testCase "c1011 is correct" test_trilinear_c1011,
191 testCase "c1110 is correct" test_trilinear_c1110,
192 testCase "c1101 is correct" test_trilinear_c1101,
193 testCase "c1200 is correct" test_trilinear_c1200,
194 testCase "c2010 is correct" test_trilinear_c2010,
195 testCase "c2001 is correct" test_trilinear_c2001,
196 testCase "c2100 is correct" test_trilinear_c2100,
197 testCase "c3000 is correct" test_trilinear_c3000],
199 testGroup "face0 vertices"
200 [testCase "v0 is correct" test_trilinear_f0_t0_v0,
201 testCase "v1 is correct" test_trilinear_f0_t0_v1,
202 testCase "v2 is correct" test_trilinear_f0_t0_v2,
203 testCase "v3 is correct" test_trilinear_f0_t0_v3]
206 g = make_grid 1 trilinear
207 cube = cube_at g 1 1 1
208 t = tetrahedron cube 0
210 test_trilinear_c0030 :: Assertion
211 test_trilinear_c0030 =
212 assertAlmostEqual "c0030 is correct" (c t 0 0 3 0) (17/8)
214 test_trilinear_c0003 :: Assertion
215 test_trilinear_c0003 =
216 assertAlmostEqual "c0003 is correct" (c t 0 0 0 3) (27/8)
218 test_trilinear_c0021 :: Assertion
219 test_trilinear_c0021 =
220 assertAlmostEqual "c0021 is correct" (c t 0 0 2 1) (61/24)
222 test_trilinear_c0012 :: Assertion
223 test_trilinear_c0012 =
224 assertAlmostEqual "c0012 is correct" (c t 0 0 1 2) (71/24)
226 test_trilinear_c0120 :: Assertion
227 test_trilinear_c0120 =
228 assertAlmostEqual "c0120 is correct" (c t 0 1 2 0) (55/24)
230 test_trilinear_c0102 :: Assertion
231 test_trilinear_c0102 =
232 assertAlmostEqual "c0102 is correct" (c t 0 1 0 2) (73/24)
234 test_trilinear_c0111 :: Assertion
235 test_trilinear_c0111 =
236 assertAlmostEqual "c0111 is correct" (c t 0 1 1 1) (8/3)
238 test_trilinear_c0210 :: Assertion
239 test_trilinear_c0210 =
240 assertAlmostEqual "c0210 is correct" (c t 0 2 1 0) (29/12)
242 test_trilinear_c0201 :: Assertion
243 test_trilinear_c0201 =
244 assertAlmostEqual "c0201 is correct" (c t 0 2 0 1) (11/4)
246 test_trilinear_c0300 :: Assertion
247 test_trilinear_c0300 =
248 assertAlmostEqual "c0300 is correct" (c t 0 3 0 0) (5/2)
250 test_trilinear_c1020 :: Assertion
251 test_trilinear_c1020 =
252 assertAlmostEqual "c1020 is correct" (c t 1 0 2 0) (8/3)
254 test_trilinear_c1002 :: Assertion
255 test_trilinear_c1002 =
256 assertAlmostEqual "c1002 is correct" (c t 1 0 0 2) (23/6)
258 test_trilinear_c1011 :: Assertion
259 test_trilinear_c1011 =
260 assertAlmostEqual "c1011 is correct" (c t 1 0 1 1) (13/4)
262 test_trilinear_c1110 :: Assertion
263 test_trilinear_c1110 =
264 assertAlmostEqual "c1110 is correct" (c t 1 1 1 0) (23/8)
266 test_trilinear_c1101 :: Assertion
267 test_trilinear_c1101 =
268 assertAlmostEqual "c1101 is correct" (c t 1 1 0 1) (27/8)
270 test_trilinear_c1200 :: Assertion
271 test_trilinear_c1200 =
272 assertAlmostEqual "c1200 is correct" (c t 1 2 0 0) 3
274 test_trilinear_c2010 :: Assertion
275 test_trilinear_c2010 =
276 assertAlmostEqual "c2010 is correct" (c t 2 0 1 0) (10/3)
278 test_trilinear_c2001 :: Assertion
279 test_trilinear_c2001 =
280 assertAlmostEqual "c2001 is correct" (c t 2 0 0 1) 4
282 test_trilinear_c2100 :: Assertion
283 test_trilinear_c2100 =
284 assertAlmostEqual "c2100 is correct" (c t 2 1 0 0) (7/2)
286 test_trilinear_c3000 :: Assertion
287 test_trilinear_c3000 =
288 assertAlmostEqual "c3000 is correct" (c t 3 0 0 0) 4
290 test_trilinear_f0_t0_v0 :: Assertion
291 test_trilinear_f0_t0_v0 =
292 assertEqual "v0 is correct" (v0 t) (1, 1, 1)
294 test_trilinear_f0_t0_v1 :: Assertion
295 test_trilinear_f0_t0_v1 =
296 assertEqual "v1 is correct" (v1 t) (0.5, 1, 1)
298 test_trilinear_f0_t0_v2 :: Assertion
299 test_trilinear_f0_t0_v2 =
300 assertEqual "v2 is correct" (v2 t) (0.5, 0.5, 1.5)
302 test_trilinear_f0_t0_v3 :: Assertion
303 test_trilinear_f0_t0_v3 =
304 assertClose "v3 is correct" (v3 t) (0.5, 1.5, 1.5)
307 test_trilinear_reproduced :: Assertion
308 test_trilinear_reproduced =
309 assertTrue "trilinears are reproduced correctly" $
310 and [p (i', j', k') ~= value_at trilinear i j k
315 let p = polynomial t,
316 let i' = fromIntegral i,
317 let j' = fromIntegral j,
318 let k' = fromIntegral k]
320 g = make_grid 1 trilinear
324 test_zeros_reproduced :: Assertion
325 test_zeros_reproduced =
326 assertTrue "the zero function is reproduced correctly" $
327 and [p (i', j', k') ~= value_at zeros i j k
331 let i' = fromIntegral i,
332 let j' = fromIntegral j,
333 let k' = fromIntegral k]
335 g = make_grid 1 zeros
337 t0 = tetrahedron c0 0
341 -- | Make sure we can reproduce a 9x9x9 trilinear from the 3x3x3 one.
342 test_trilinear9x9x9_reproduced :: Assertion
343 test_trilinear9x9x9_reproduced =
344 assertTrue "trilinear 9x9x9 is reproduced correctly" $
345 and [p (i', j', k') ~= value_at trilinear9x9x9 i j k
350 let p = polynomial t,
351 let i' = (fromIntegral i) * 0.5,
352 let j' = (fromIntegral j) * 0.5,
353 let k' = (fromIntegral k) * 0.5]
355 g = make_grid 1 trilinear
359 -- | The point 'p' in this test lies on the boundary of tetrahedra 12 and 15.
360 -- However, the 'contains_point' test fails due to some numerical innacuracy.
361 -- This bug should have been fixed by setting a positive tolerance level.
363 -- Example from before the fix:
365 -- b1 (tetrahedron c 20) (0, 17.5, 0.5)
368 test_tetrahedra_collision_sensitivity :: Assertion
369 test_tetrahedra_collision_sensitivity =
370 assertTrue "tetrahedron collision tests isn't too sensitive" $
373 g = make_grid 1 naturals_1d
374 cube = cube_at g 0 18 0
375 p = (0, 17.5, 0.5) :: Point
376 t20 = tetrahedron cube 20
379 prop_cube_indices_never_go_out_of_bounds :: Grid -> Gen Bool
380 prop_cube_indices_never_go_out_of_bounds g =
383 let coordmin = negate (delta/2)
385 let (xsize, ysize, zsize) = dims $ function_values g
386 let xmax = delta*(fromIntegral xsize) - (delta/2)
387 let ymax = delta*(fromIntegral ysize) - (delta/2)
388 let zmax = delta*(fromIntegral zsize) - (delta/2)
390 x <- choose (coordmin, xmax)
391 y <- choose (coordmin, ymax)
392 z <- choose (coordmin, zmax)
394 let idx_x = calculate_containing_cube_coordinate g x
395 let idx_y = calculate_containing_cube_coordinate g y
396 let idx_z = calculate_containing_cube_coordinate g z
400 idx_x <= xsize - 1 &&
402 idx_y <= ysize - 1 &&
408 grid_tests :: Test.Framework.Test
410 testGroup "Grid Tests" [
411 trilinear_c0_t0_tests,
412 testCase "tetrahedra collision test isn't too sensitive"
413 test_tetrahedra_collision_sensitivity,
414 testCase "trilinear reproduced" test_trilinear_reproduced,
415 testCase "zeros reproduced" test_zeros_reproduced ]
418 -- Do the slow tests last so we can stop paying attention.
419 slow_tests :: Test.Framework.Test
421 testGroup "Slow Tests" [
422 testProperty "cube indices within bounds"
423 prop_cube_indices_never_go_out_of_bounds,
424 testCase "trilinear9x9x9 reproduced" test_trilinear9x9x9_reproduced ]