Очередная реализация fluid sim методом Эйлера, но в блокноте WL. Чернила. Часть 3

ClearAll[advect]; ClearAll[removeDivergence]; ClearAll[bilinearInterpolation];  advect[v_, u_, δt_:0.1] := With[{max = Length[v]}, With[{   take = Function[{array, x,y}, If[x >= 1 && x <= max && y >= 1 && y <= max, array[[x,y]], array[[1,1]] 0.]] },   Table[         With[{       v1 =  (*FB[*)((take[v, i-1, j] + take[v, i, j])(*,*)/(*,*)(2.0))(*]FB*).{1,0},       v2 =  (*FB[*)((take[v, i, j+1] + take[v, i, j])(*,*)/(*,*)(2.0))(*]FB*).{0,-1},       v3 =  (*FB[*)((take[v, i+1, j] + take[v, i, j])(*,*)/(*,*)(2.0))(*]FB*).{-1,0},       v4 =  (*FB[*)((take[v, i, j-1] + take[v, i, j])(*,*)/(*,*)(2.0))(*]FB*).{0,1},       org = u[[i,j]]     },        org + (                v1 (*TB[*)Piecewise[{{(*|*)take[u, i-1, j](*|*),(*|*)v1 > 0(*|*)},{(*|*)org(*|*),(*|*)True(*|*)}}](*|*)(*1:eJxTTMoPSmNkYGAo5gESAZmpyanlmcWpTvkVmUxAAQBzVQdd*)(*]TB*) + v3 (*TB[*)Piecewise[{{(*|*)take[u, i+1, j](*|*),(*|*)v3 > 0(*|*)},{(*|*)org(*|*),(*|*)True(*|*)}}](*|*)(*1:eJxTTMoPSmNkYGAo5gESAZmpyanlmcWpTvkVmUxAAQBzVQdd*)(*]TB*)  +                  v4 (*TB[*)Piecewise[{{(*|*)take[u, i, j-1](*|*),(*|*)v4 > 0(*|*)},{(*|*)org(*|*),(*|*)True(*|*)}}](*|*)(*1:eJxTTMoPSmNkYGAo5gESAZmpyanlmcWpTvkVmUxAAQBzVQdd*)(*]TB*) + v2 (*TB[*)Piecewise[{{(*|*)take[u, i, j+1](*|*),(*|*)v2 > 0(*|*)},{(*|*)org(*|*),(*|*)True(*|*)}}](*|*)(*1:eJxTTMoPSmNkYGAo5gESAZmpyanlmcWpTvkVmUxAAQBzVQdd*)(*]TB*)                ) δt     ]        , {i, max}, {j, max}] // Chop  ]]   removeDivergence[grid_] := With[{   (*BB[*)(*safety checks, which enforce closed boundaries*)(*,*)(*"1:eJxTTMoPSmNhYGAo5gcSAUX5ZZkpqSn+BSWZ+XnFaYwgCS4g4Zyfm5uaV+KUXxEMUqxsbm6exgSSBPGCSnNSg9mAjOCSosy8dLBYSFFpKpoKkDkeqYkpEFXBILO1sCgJSczMQVYCAOFrJEU="*)(*]BB*)   take = Function[{array, x,y}, If[x >= 1 && x <= Length[grid] && y >= 1 && y <= Length[grid], array[[x,y]], {0,0}]] },   MapIndexed[Function[{val, i},      val + (*FB[*)((1)(*,*)/(*,*)(8.0))(*]FB*) (       ((take[grid, i[[1]] - 1, i[[2]] - 1] + take[grid, i[[1]] + 1, i[[2]] + 1]).{1,1}){1,1} +        ((take[grid, i[[1]] - 1, i[[2]] + 1] + take[grid, i[[1]] + 1, i[[2]] - 1]).{1,-1}){1,-1} +        (take[grid, i[[1]]-1, i[[2]]] + take[grid, i[[1]]+1, i[[2]]] - take[grid, i[[1]], i[[2]]-1] - take[grid, i[[1]], i[[2]]+1]){2,-2} + take[grid, i[[1]], i[[2]]] (-4)      )   ], grid, {2}] ]  bilinearInterpolation[array_, {x0_, y0_}] := Module[   {rows, cols, x = y0, y = x0, x1, x2, y1, y2, fQ11, fQ12, fQ21, fQ22},      (* Get the dimensions of the array *)   {rows, cols} = Take[Dimensions[array], 2];      (* Clip points to the boundaries *)   x = Clip[x, {1, cols}];   y = Clip[y, {1, rows}];      (* Find the bounding indices *)   x1 = Floor[x];    x2 = Ceiling[x];   y1 = Floor[y];    y2 = Ceiling[y];      (* Get the values at the four corners *)   fQ11 = array[[y1, x1]];   fQ12 = array[[y2, x1]];   fQ21 = array[[y1, x2]];   fQ22 = array[[y2, x2]];      (* Perform bilinear interpolation *)   If[x2 == x1,     If[y2 == y1,       fQ11,       1/(2 (y2 - y1)) * (         fQ11 (y2 - y) +         fQ21 (y2 - y) +         fQ12 (y - y1) +         fQ22 (y - y1)       )     ],     If[y2 == y1,       1/(2 (x2 - x1)) * (         fQ11 (x2 - x) +         fQ21 (x - x1) +         fQ12 (x2 - x) +         fQ22 (x - x1)       ),       1/((x2 - x1) (y2 - y1)) * (         fQ11 (x2 - x) (y2 - y) +         fQ21 (x - x1) (y2 - y) +         fQ12 (x2 - x) (y - y1) +         fQ22 (x - x1) (y - y1)       )     ]   ] ]  advectParticles[v_, pts_, δt_:0.02] := Map[Function[p, p + δt (bilinearInterpolation[v, p])], pts]

advect = Compile[{{v, _Real, 3}, {u, _Real, 3}, {δt, _Real, 0}} , With[{max = Length[v]}, With[{   },   Table[         With[{       (*BB[*)(* here we add a lot of manual check for boundary condition *)(*,*)(*"1:eJxTTMoPSmNhYGAo5gcSAUX5ZZkpqSn+BSWZ+XnFaYwgCS4g4Zyfm5uaV+KUXxEMUqxsbm6exgSSBPGCSnNSg9mAjOCSosy8dLBYSFFpKpoKkDkeqYkpEFXBILO1sCgJSczMQVYCAOFrJEU="*)(*]BB*)       v1 = (*BB[*)( (*FB[*)((If[i-1 >= 1, v[[i-1, j]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*))(*,*)(*"1:eJxTTMoPSmNkYGAoZgESHvk5KRAeB5AILqnMSXXKr0hjgskHleakFnMBGU6JydnpRfmleSlpzDDlQe5Ozvk5+UVFDGDwwR6dwcAAAAHdFiw="*)(*]BB*).{1,0},       v2 =  (*FB[*)((If[j+1 <= max, v[[i, j+1]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{0,-1},       v3 =  (*FB[*)((If[i+1 <= max, v[[i+1, j]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{-1,0},       v4 =  (*FB[*)((If[j-1 >= 1, v[[i, j-1]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{0,1},       org = u[[i,j]]     },        org +  (         (*BB[*)(* here we add a lot of manual check for boundary condition *)(*,*)(*"1:eJxTTMoPSmNhYGAo5gcSAUX5ZZkpqSn+BSWZ+XnFaYwgCS4g4Zyfm5uaV+KUXxEMUqxsbm6exgSSBPGCSnNSg9mAjOCSosy8dLBYSFFpKpoKkDkeqYkpEFXBILO1sCgJSczMQVYCAOFrJEU="*)(*]BB*)                v1 (*BB[*)(If[v1 >0, If[i-1 >= 1, u[[i-1, j]], {0.,0.} ], org])(*,*)(*"1:eJxTTMoPSmNkYGAoZgESHvk5KRAeB5AILqnMSXXKr0hjgskHleakFnMBGU6JydnpRfmleSlpzDDlQe5Ozvk5+UVFDGDwwR6dwcAAAAHdFiw="*)(*]BB*)                    + v3 (*BB[*)(If[v3>0,If[i+1 <= max, u[[i+1, j]], {0.,0.} ], org])(*,*)(*"1:eJxTTMoPSmNkYGAoZgESHvk5KRAeB5AILqnMSXXKr0hjgskHleakFnMBGU6JydnpRfmleSlpzDDlQe5Ozvk5+UVFDGDwwR6dwcAAAAHdFiw="*)(*]BB*)+                  v4 If[v4 >0, If[j-1 >= 1, u[[i, j-1]], {0.,0.} ], org]                   + v2 If[v2>0, If[j+1 <= max, u[[i, j+1]], {0.,0.} ], org]                ) δt      ]        , {i, max}, {j, max}] // Chop  ]]];  removeDivergence = Compile[{{grid, _Real, 3}}, With[{   max = grid // Length },   MapIndexed[Function[{val, i},      val + (*FB[*)((1)(*,*)/(*,*)(8.0))(*]FB*) (       (         (           (*BB[*)(* here we add a lot of manual check for boundary condition *)(*,*)(*"1:eJxTTMoPSmNhYGAo5gcSAUX5ZZkpqSn+BSWZ+XnFaYwgCS4g4Zyfm5uaV+KUXxEMUqxsbm6exgSSBPGCSnNSg9mAjOCSosy8dLBYSFFpKpoKkDkeqYkpEFXBILO1sCgJSczMQVYCAOFrJEU="*)(*]BB*)           If[i[[1]] - 1 >= 1 && i[[1]] - 1 <= max && i[[2]] - 1 >= 1 && i[[2]] - 1 <= max, grid[[i[[1]] - 1, i[[2]] - 1]], {0.,0.}]                       + If[i[[1]] + 1 >=1 && i[[1]] + 1 <= max && i[[2]] + 1 >= 1 && i[[2]] + 1 <= max, grid[[i[[1]] + 1, i[[2]] + 1]], {0.,0.}]                  ).{1,1}                ){1,1} +        (         (           (*BB[*)(* here we add a lot of manual check for boundary condition *)(*,*)(*"1:eJxTTMoPSmNhYGAo5gcSAUX5ZZkpqSn+BSWZ+XnFaYwgCS4g4Zyfm5uaV+KUXxEMUqxsbm6exgSSBPGCSnNSg9mAjOCSosy8dLBYSFFpKpoKkDkeqYkpEFXBILO1sCgJSczMQVYCAOFrJEU="*)(*]BB*)           If[i[[1]] - 1 >= 1 && i[[1]] - 1 <= max && i[[2]] + 1 >= 1 && i[[2]] + 1 <= max, grid[[i[[1]] - 1, i[[2]] + 1]], {0.,0.}]                      + If[i[[1]] + 1 >= 1 && i[[1]] + 1 <= max && i[[2]] - 1 >= 1 && i[[2]] - 1 <= max, grid[[i[[1]] + 1, i[[2]] - 1]], {0.,0.}]                    ).{1,-1}                ){1,-1} +        (         (*BB[*)(If[i[[1]]-1 >= 1 && i[[1]]-1 <= max, grid[[i[[1]]-1, i[[2]] ]], {0.,0.}])(*,*)(*"1:eJxTTMoPSmNkYGAoZgESHvk5KRAeB5AILqnMSXXKr0hjgskHleakFnMBGU6JydnpRfmleSlpzDDlQe5Ozvk5+UVFDGDwwR6dwcAAAAHdFiw="*)(*]BB*)                  + If[i[[1]]+1 >= 1 && i[[1]]+1 <= max, grid[[ i[[1]]+1, i[[2]] ]], {0.,0.}]                  - If[i[[2]]-1 >= 1 && i[[2]]-1 <= max, grid[[ i[[1]], i[[2]]-1 ]], {0.,0.}]                  - If[i[[2]]+1 >= 1 && i[[2]]+1 <= max, grid[[i[[1]], i[[2]]+1]], {0.,0.}]                ){2,-2}                   + grid[[ i[[1]], i[[2]] ]] (-4)      )   ], grid, {2}] ]];  bilinearInterpolation = Compile[{{array, _Real, 3}, {v, _Real, 1}},  (*BB[*)(* no big changes here *)(*,*)(*"1:eJxTTMoPSmNhYGAo5gcSAUX5ZZkpqSn+BSWZ+XnFaYwgCS4g4Zyfm5uaV+KUXxEMUqxsbm6exgSSBPGCSnNSg9mAjOCSosy8dLBYSFFpKpoKkDkeqYkpEFXBILO1sCgJSczMQVYCAOFrJEU="*)(*]BB*) Module[   {rows, cols, x = v[[2]], y = v[[1]], x1, x2, y1, y2, fQ11, fQ12, fQ21, fQ22},      (* Get the dimensions of the array *)   {rows, cols} = {Length[array], Length[array]};      (* Clip points to the boundaries *)   x = Clip[x, {1, cols}];   y = Clip[y, {1, rows}];      (* Find the bounding indices *)   x1 = Floor[x];    x2 = Ceiling[x];   y1 = Floor[y];    y2 = Ceiling[y];      (* Get the values at the four corners *)   fQ11 = array[[y1, x1]];   fQ12 = array[[y2, x1]];   fQ21 = array[[y1, x2]];   fQ22 = array[[y2, x2]];      (* Perform bilinear interpolation *)   If[x2 == x1,     If[y2 == y1,       fQ11,       1/(2 (y2 - y1)) * (         fQ11 (y2 - y) +         fQ21 (y2 - y) +         fQ12 (y - y1) +         fQ22 (y - y1)       )     ],     If[y2 == y1,       1/(2 (x2 - x1)) * (         fQ11 (x2 - x) +         fQ21 (x - x1) +         fQ12 (x2 - x) +         fQ22 (x - x1)       ),       1/((x2 - x1) (y2 - y1)) * (         fQ11 (x2 - x) (y2 - y) +         fQ21 (x - x1) (y2 - y) +         fQ12 (x2 - x) (y - y1) +         fQ22 (x - x1) (y - y1)       )     ]   ] ]];    

advect = Compile[{{v, _Real, 3}, {u, _Real, 3}, {δt, _Real, 0}} , With[{max = Length[v]}, With[{   },   Table[         With[{       v1 =  (*FB[*)((If[i-1 >= 1, v[[i-1, j]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{1,0},       v2 =  (*FB[*)((If[j+1 <= max, v[[i, j+1]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{0,-1},       v3 =  (*FB[*)((If[i+1 <= max, v[[i+1, j]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{-1,0},       v4 =  (*FB[*)((If[j-1 >= 1, v[[i, j-1]], {0.,0.}] + v[[i, j]])(*,*)/(*,*)(2.0))(*]FB*).{0,1},       org = u[[i,j]]     },        org +  (                v1 If[v1 >0, If[i-1 >= 1, u[[i-1, j]], {0.,0.} ], org]  + v3 If[v3>0,If[i+1 <= max, u[[i+1, j]], {0.,0.} ], org]+                  v4 If[v4 >0, If[j-1 >= 1, u[[i, j-1]], {0.,0.} ], org] + v2 If[v2>0, If[j+1 <= max, u[[i, j+1]], {0.,0.} ], org]                ) δt      ]        , {i, max}, {j, max}] // Chop  ]] , CompilationOptions -> {"InlineExternalDefinitions" -> True},      "CompilationTarget" -> "C", "RuntimeOptions" -> "Speed"];  removeDivergence = Compile[{{grid, _Real, 3}}, With[{   max = grid // Length },   MapIndexed[Function[{val, i},      val + (*FB[*)((1)(*,*)/(*,*)(8.0))(*]FB*) (       (         (           If[i[[1]] - 1 >= 1 && i[[1]] - 1 <= max && i[[2]] - 1 >= 1 && i[[2]] - 1 <= max, grid[[i[[1]] - 1, i[[2]] - 1]], {0.,0.}]                       + If[i[[1]] + 1 >=1 && i[[1]] + 1 <= max && i[[2]] + 1 >= 1 && i[[2]] + 1 <= max, grid[[i[[1]] + 1, i[[2]] + 1]], {0.,0.}]                  ).{1,1}                ){1,1} +        (         (           If[i[[1]] - 1 >= 1 && i[[1]] - 1 <= max && i[[2]] + 1 >= 1 && i[[2]] + 1 <= max, grid[[i[[1]] - 1, i[[2]] + 1]], {0.,0.}]                      + If[i[[1]] + 1 >= 1 && i[[1]] + 1 <= max && i[[2]] - 1 >= 1 && i[[2]] - 1 <= max, grid[[i[[1]] + 1, i[[2]] - 1]], {0.,0.}]                    ).{1,-1}                ){1,-1} +        (         If[i[[1]]-1 >= 1 && i[[1]]-1 <= max, grid[[i[[1]]-1, i[[2]] ]], {0.,0.}]                  + If[i[[1]]+1 >= 1 && i[[1]]+1 <= max, grid[[ i[[1]]+1, i[[2]] ]], {0.,0.}]                  - If[i[[2]]-1 >= 1 && i[[2]]-1 <= max, grid[[ i[[1]], i[[2]]-1 ]], {0.,0.}]                  - If[i[[2]]+1 >= 1 && i[[2]]+1 <= max, grid[[i[[1]], i[[2]]+1]], {0.,0.}]                ){2,-2}                   + grid[[ i[[1]], i[[2]] ]] (-4)      )   ], grid, {2}] ], CompilationOptions -> {"InlineExternalDefinitions" -> True},      "CompilationTarget" -> "C",   "RuntimeOptions" -> "Speed"];   bilinearInterpolation = Compile[{{array, _Real, 3}, {v, _Real, 1}}, Module[   {rows, cols, x = v[[2]], y = v[[1]], x1, x2, y1, y2, fQ11, fQ12, fQ21, fQ22},      (* Get the dimensions of the array *)   {rows, cols} = {Length[array], Length[array]};      (* Clip points to the boundaries *)   x = Clip[x, {1, cols}];   y = Clip[y, {1, rows}];      (* Find the bounding indices *)   x1 = Floor[x];    x2 = Ceiling[x];   y1 = Floor[y];    y2 = Ceiling[y];      (* Get the values at the four corners *)   fQ11 = array[[y1, x1]];   fQ12 = array[[y2, x1]];   fQ21 = array[[y1, x2]];   fQ22 = array[[y2, x2]];      (* Perform bilinear interpolation *)   If[x2 == x1,     If[y2 == y1,       fQ11,       1/(2 (y2 - y1)) * (         fQ11 (y2 - y) +         fQ21 (y2 - y) +         fQ12 (y - y1) +         fQ22 (y - y1)       )     ],     If[y2 == y1,       1/(2 (x2 - x1)) * (         fQ11 (x2 - x) +         fQ21 (x - x1) +         fQ12 (x2 - x) +         fQ22 (x - x1)       ),       1/((x2 - x1) (y2 - y1)) * (         fQ11 (x2 - x) (y2 - y) +         fQ21 (x - x1) (y2 - y) +         fQ12 (x2 - x) (y - y1) +         fQ22 (x - x1) (y - y1)       )     ]   ] ] , CompilationOptions -> {"InlineExternalDefinitions" -> True},      "CompilationTarget" -> "C","RuntimeOptions" -> "Speed"];