X-Git-Url: http://gitweb.michael.orlitzky.com/?a=blobdiff_plain;f=src%2FGrid.hs;h=269b37cec68d5c2f6211971dc1af32316b86c7ae;hb=fd3d394c27e3a90de8238b98bd112c4fe3468ee0;hp=71e39a055110aab2a8be5378f374d8051bc1be93;hpb=56e68abc1d03f1991f45365b4adc5b0bc4f05996;p=spline3.git diff --git a/src/Grid.hs b/src/Grid.hs index 71e39a0..269b37c 100644 --- a/src/Grid.hs +++ b/src/Grid.hs @@ -1,17 +1,16 @@ {-# 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. +-- | The Grid module contains the Grid type, its tests, and the 'zoom' +-- function used to build the interpolation. module Grid ( cube_at, grid_tests, - make_grid, slow_tests, zoom ) where import qualified Data.Array.Repa as R +import qualified Data.Array.Repa.Operators.Traversal as R (unsafeTraverse) import Test.HUnit (Assertion, assertEqual) import Test.Framework (Test, testGroup) import Test.Framework.Providers.HUnit (testCase) @@ -19,73 +18,66 @@ import Test.Framework.Providers.QuickCheck2 (testProperty) import Test.QuickCheck ((==>), Arbitrary(..), Gen, - Positive(..), Property, - choose) -import Assertions (assertAlmostEqual, assertClose, assertTrue) + choose, + vectorOf) +import Assertions (assertAlmostEqual, assertTrue) import Comparisons ((~=)) import Cube (Cube(Cube), find_containing_tetrahedron, tetrahedra, tetrahedron) -import Examples (trilinear, trilinear9x9x9, zeros, naturals_1d) +import Examples (trilinear, trilinear9x9x9, zeros) import FunctionValues (make_values, value_at) -import Point (Point) +import Point (Point(..)) import ScaleFactor (ScaleFactor) -import Tetrahedron (Tetrahedron, c, polynomial, v0, v1, v2, v3) -import ThreeDimensional (ThreeDimensional(..)) +import Tetrahedron ( + Tetrahedron(v0,v1,v2,v3), + c, + polynomial, + ) import Values (Values3D, dims, empty3d, zoom_shape) -- | Our problem is defined on a Grid. The grid size is given by the --- positive number h. The function values are the values of the --- function at the grid points, which are distance h from one --- another in each direction (x,y,z). -data Grid = Grid { h :: Double, -- MUST BE GREATER THAN ZERO! - function_values :: Values3D } - deriving (Eq, Show) +-- positive number h, which we have defined to always be 1 for +-- performance reasons (and simplicity). The function values are the +-- values of the function at the grid points, which are distance h=1 +-- from one another in each direction (x,y,z). +data Grid = Grid { function_values :: Values3D } + deriving (Show) instance Arbitrary Grid where arbitrary = do - (Positive h') <- arbitrary :: Gen (Positive Double) - fvs <- arbitrary :: Gen Values3D - return (make_grid h' fvs) - - --- | The constructor that we want people to use. If we're passed a --- non-positive grid size, we throw an error. -make_grid :: Double -> Values3D -> Grid -make_grid grid_size values - | grid_size <= 0 = error "grid size must be positive" - | otherwise = Grid grid_size values + x_dim <- choose (1, 27) + y_dim <- choose (1, 27) + z_dim <- choose (1, 27) + elements <- vectorOf (x_dim * y_dim * z_dim) (arbitrary :: Gen Double) + let new_shape = (R.Z R.:. x_dim R.:. y_dim R.:. z_dim) + let fvs = R.fromListUnboxed new_shape elements + return $ Grid fvs -- | Takes a grid and a position as an argument and returns the cube --- centered on that position. If there is no cube there (i.e. the --- position is outside of the grid), it will throw an error. +-- centered on that position. If there is no cube there, well, you +-- shouldn't have done that. The omitted "otherwise" case actually +-- does improve performance. cube_at :: Grid -> Int -> Int -> Int -> Cube -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" - | j >= ysize = error "j >= ysize in cube_at" - | k < 0 = error "k < 0 in cube_at" - | k >= zsize = error "k >= zsize in cube_at" - | otherwise = Cube delta i j k fvs' tet_vol - where - fvs = function_values g - (xsize, ysize, zsize) = dims fvs - fvs' = make_values fvs i j k - delta = h g - tet_vol = (1/24)*(delta^(3::Int)) - --- The first cube along any axis covers (-h/2, h/2). The second --- covers (h/2, 3h/2). The third, (3h/2, 5h/2), and so on. +cube_at !g !i !j !k = + Cube i j k fvs' tet_vol + where + fvs = function_values g + fvs' = make_values fvs i j k + tet_vol = 1/24 + + +-- The first cube along any axis covers (-1/2, 1/2). The second +-- covers (1/2, 3/2). The third, (3/2, 5/2), and so on. -- --- We translate the (x,y,z) coordinates forward by 'h/2' so that the --- first covers (0, h), the second covers (h, 2h), etc. This makes +-- We translate the (x,y,z) coordinates forward by 1/2 so that the +-- first covers (0, 1), the second covers (1, 2), etc. This makes -- it easy to figure out which cube contains the given point. calculate_containing_cube_coordinate :: Grid -> Double -> Int calculate_containing_cube_coordinate g coord @@ -94,21 +86,19 @@ calculate_containing_cube_coordinate g coord -- exists. | coord < offset = 0 | coord == offset && (xsize > 1 && ysize > 1 && zsize > 1) = 1 - | otherwise = (ceiling ( (coord + offset) / cube_width )) - 1 + | otherwise = (ceiling (coord + offset)) - 1 where (xsize, ysize, zsize) = dims (function_values g) - cube_width = (h g) - offset = cube_width / 2 + offset = 1/2 -- | Takes a 'Grid', and returns a 'Cube' containing the given 'Point'. -- 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 @@ -123,26 +113,30 @@ zoom_result :: Values3D -> ScaleFactor -> R.DIM3 -> Double zoom_result v3d (sfx, sfy, sfz) (R.Z R.:. m R.:. n R.:. o) = f p where - g = make_grid 1 v3d - offset = (h g)/2 + g = Grid v3d + offset = 1/2 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 -zoom :: Values3D -> ScaleFactor -> Values3D +-- +-- Instead of IO, we could get away with a generic monad 'm' +-- here. However, /we/ only call this function from within IO. +-- +zoom :: Values3D -> ScaleFactor -> IO Values3D zoom v3d scale_factor - | xsize == 0 || ysize == 0 || zsize == 0 = empty3d + | xsize == 0 || ysize == 0 || zsize == 0 = return empty3d | otherwise = - R.force $ R.unsafeTraverse v3d transExtent f - where - (xsize, ysize, zsize) = dims v3d - transExtent = zoom_shape scale_factor - f = zoom_lookup v3d scale_factor + R.computeUnboxedP $ R.unsafeTraverse v3d transExtent f + where + (xsize, ysize, zsize) = dims v3d + transExtent = zoom_shape scale_factor + f = zoom_lookup v3d scale_factor -- | Check all coefficients of tetrahedron0 belonging to the cube @@ -184,7 +178,7 @@ trilinear_c0_t0_tests = testCase "v3 is correct" test_trilinear_f0_t0_v3] ] where - g = make_grid 1 trilinear + g = Grid trilinear cube = cube_at g 1 1 1 t = tetrahedron cube 0 @@ -270,25 +264,25 @@ trilinear_c0_t0_tests = 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], @@ -299,14 +293,14 @@ test_trilinear_reproduced = let j' = fromIntegral j, let k' = fromIntegral k] where - g = make_grid 1 trilinear + g = Grid trilinear 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], @@ -317,7 +311,7 @@ test_zeros_reproduced = t0 <- tetrahedra c0, let p = polynomial t0 ] where - g = make_grid 1 zeros + g = Grid zeros cs = [ cube_at g ci cj ck | ci <- [0..2], cj <- [0..2], ck <- [0..2] ] @@ -325,7 +319,7 @@ test_zeros_reproduced = 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], @@ -335,40 +329,20 @@ test_trilinear9x9x9_reproduced = let j' = (fromIntegral j) * 0.5, let k' = (fromIntegral k) * 0.5] where - g = make_grid 1 trilinear + g = Grid trilinear c0 = cube_at g 1 1 1 --- | The point 'p' in this test lies on the boundary of tetrahedra 12 and 15. --- However, the 'contains_point' test fails due to some numerical innacuracy. --- This bug should have been fixed by setting a positive tolerance level. --- --- Example from before the fix: --- --- b1 (tetrahedron c 20) (0, 17.5, 0.5) --- -0.0 --- -test_tetrahedra_collision_sensitivity :: Assertion -test_tetrahedra_collision_sensitivity = - assertTrue "tetrahedron collision tests isn't too sensitive" $ - contains_point t20 p - where - g = make_grid 1 naturals_1d - cube = cube_at g 0 18 0 - p = (0, 17.5, 0.5) :: Point - t20 = tetrahedron cube 20 - prop_cube_indices_never_go_out_of_bounds :: Grid -> Gen Bool prop_cube_indices_never_go_out_of_bounds g = do - let delta = Grid.h g - let coordmin = negate (delta/2) + let coordmin = negate (1/2) let (xsize, ysize, zsize) = dims $ function_values g - let xmax = delta*(fromIntegral xsize) - (delta/2) - let ymax = delta*(fromIntegral ysize) - (delta/2) - let zmax = delta*(fromIntegral zsize) - (delta/2) + let xmax = (fromIntegral xsize) - (1/2) + let ymax = (fromIntegral ysize) - (1/2) + let zmax = (fromIntegral zsize) - (1/2) x <- choose (coordmin, xmax) y <- choose (coordmin, ymax) @@ -394,7 +368,7 @@ prop_cube_indices_never_go_out_of_bounds g = -- in opposite directions, one of them has to have negative volume! prop_c0120_identity :: Grid -> Property prop_c0120_identity g = - and [xsize >= 3, ysize >= 3, zsize >= 3] ==> + xsize >= 3 && ysize >= 3 && zsize >= 3 ==> c t0 0 1 2 0 ~= (c t0 1 0 2 0 + c t10 1 0 0 2) / 2 where fvs = function_values g @@ -409,7 +383,7 @@ prop_c0120_identity g = -- 'prop_c0120_identity'. prop_c0111_identity :: Grid -> Property prop_c0111_identity g = - and [xsize >= 3, ysize >= 3, zsize >= 3] ==> + xsize >= 3 && ysize >= 3 && zsize >= 3 ==> c t0 0 1 1 1 ~= (c t0 1 0 1 1 + c t10 1 0 1 1) / 2 where fvs = function_values g @@ -424,7 +398,7 @@ prop_c0111_identity g = -- 'prop_c0120_identity'. prop_c0201_identity :: Grid -> Property prop_c0201_identity g = - and [xsize >= 3, ysize >= 3, zsize >= 3] ==> + xsize >= 3 && ysize >= 3 && zsize >= 3 ==> c t0 0 2 0 1 ~= (c t0 1 1 0 1 + c t10 1 1 1 0) / 2 where fvs = function_values g @@ -439,7 +413,7 @@ prop_c0201_identity g = -- 'prop_c0120_identity'. prop_c0102_identity :: Grid -> Property prop_c0102_identity g = - and [xsize >= 3, ysize >= 3, zsize >= 3] ==> + xsize >= 3 && ysize >= 3 && zsize >= 3 ==> c t0 0 1 0 2 ~= (c t0 1 0 0 2 + c t10 1 0 2 0) / 2 where fvs = function_values g @@ -454,7 +428,7 @@ prop_c0102_identity g = -- 'prop_c0120_identity'. prop_c0210_identity :: Grid -> Property prop_c0210_identity g = - and [xsize >= 3, ysize >= 3, zsize >= 3] ==> + xsize >= 3 && ysize >= 3 && zsize >= 3 ==> c t0 0 2 1 0 ~= (c t0 1 1 1 0 + c t10 1 1 0 1) / 2 where fvs = function_values g @@ -469,7 +443,7 @@ prop_c0210_identity g = -- 'prop_c0120_identity'. prop_c0300_identity :: Grid -> Property prop_c0300_identity g = - and [xsize >= 3, ysize >= 3, zsize >= 3] ==> + xsize >= 3 && ysize >= 3 && zsize >= 3 ==> c t0 0 3 0 0 ~= (c t0 1 2 0 0 + c t10 1 2 0 0) / 2 where fvs = function_values g @@ -498,8 +472,6 @@ grid_tests = testGroup "Grid Tests" [ trilinear_c0_t0_tests, p80_29_properties, - testCase "tetrahedra collision test isn't too sensitive" - test_tetrahedra_collision_sensitivity, testProperty "cube indices within bounds" prop_cube_indices_never_go_out_of_bounds ]