# A* / Dijkstra's algorithm simple implementation (Pascal)

I'm trying to implement A* path finding algorithm (now it's Dijkstra's algorithm i.e without heuristic) using this article http://www.policyalmanac.org/games/aStarTutorial.htm. But I can't figure out what's wrong in this my code (it finds incorrect path).

where void body of begin ... end; it should be this step:

If it is on the open list already, check to see if this path to that square is better, using G cost as the measure. A lower G cost means that this is a better path. If so, change the parent of the square to the current square, and recalculate the G and F scores of the square.

but I think it is not important because there is no diagonal movement.

``````uses
crt;

const
MAXX = 20;
MAXY = 25;

type
TArr = array [0..MAXY, 0..MAXX] of integer;

TCell = record
x: integer;
y: integer;
end;

TListCell = record
x: integer;
y: integer;
G: integer;
parent: TCell;
end;

TListArr = array [1..10000] of TListCell;

TList = record
arr: TListArr;
len: integer;
end;

var
i, j, minind, ind, c: integer;
start, finish: TCell;
current: TListCell;
field: TArr;
opened, closed: TList;

procedure ShowField;
var
i, j: integer;
begin
textcolor(15);
for i := 0 to MAXX do
begin
for j := 0 to MAXY do
begin
case field[j, i] of
99: textcolor(8);  // not walkable
71: textcolor(14); // walkable
11: textcolor(10); // start
21: textcolor(12); // finish
15: textcolor(2);  // path
14: textcolor(5);
16: textcolor(6);
end;
write(field[j, i], ' ');
end;
writeln;
end;
textcolor(15);
end;

begin
closed.arr[closed.len + 1] := a;
inc(closed.len);
end;

begin
opened.arr[opened.len + 1].x := x;
opened.arr[opened.len + 1].y := y;
opened.arr[opened.len + 1].G := G;
inc(opened.len);
end;

procedure DelOpened(n: integer);
var
i: integer;
begin
for i := n to opened.len - 1 do
opened.arr[i] := opened.arr[i + 1];
dec(opened.len);
end;

procedure SetParent(var a: TListCell; parx, pary: integer);
begin
a.parent.x := parx;
a.parent.y := pary;
end;

function GetMin(var a: TList): integer;
var
i, min, mini: integer;
begin
min := MaxInt;
mini := 0;
for i := 1 to a.len do
if a.arr[i].G < min then
begin
min := a.arr[i].G;
mini := i;
end;

GetMin := mini;
end;

function FindCell(a: TList; x, y: integer): integer;
var
i: integer;
begin
FindCell := 0;
for i := 1 to a.len do
if (a.arr[i].x = x) and (a.arr[i].y = y) then
begin
FindCell := i;
break;
end;
end;

procedure ProcessNeighbourCell(x, y: integer);
begin
if (field[current.x + x, current.y + y] <> 99) then    // if walkable
if (FindCell(closed, current.x + x, current.y + y) <= 0) then // and not visited before
if (FindCell(opened, current.x + x, current.y + y) <= 0) then // and not added to list already
begin
AddOpened(current.x + x, current.y + y, current.G + 10);
SetParent(opened.arr[opened.len], current.x, current.y);
//  field[opened.arr[opened.len].x, opened.arr[opened.len].y]:=16;
end
else
begin

end;
end;

begin
randomize;
for i := 0 to MAXX do
for j := 0 to MAXY do
field[j, i] := 99;

for i := 1 to MAXX - 1 do
for j := 1 to MAXY - 1 do
if random(5) mod 5 = 0 then
field[j, i] := 99
else field[j, i] := 71;

// start and finish positions coordinates
start.x := 5;
start.y := 3;
finish.x := 19;
finish.y := 16;
field[start.x, start.y] := 11;
field[finish.x, finish.y] := 21;

ShowField;

writeln;

opened.len := 0;
closed.len := 0;
SetParent(opened.arr[opened.len], -1, -1);
current.x := start.x;
current.y := start.y;

repeat
minind := GetMin(opened);
current.x := opened.arr[minind].x;
current.y := opened.arr[minind].y;
current.G := opened.arr[minind].G;
DelOpened(minind);

ProcessNeighbourCell(1, 0);  // look at the cell to the right
ProcessNeighbourCell(-1, 0); // look at the cell to the left
ProcessNeighbourCell(0, 1);  // look at the cell above
ProcessNeighbourCell(0, -1); // look at the cell below

if (FindCell(opened, finish.x, finish.y) > 0) then
break;
until opened.len = 0;

// count and mark path
c := 0;
while ((current.x <> start.x) or (current.y <> start.y)) do
begin
field[current.x, current.y] := 15;
ind := FindCell(closed, current.x, current.y);
current.x := closed.arr[ind].parent.x;
current.y := closed.arr[ind].parent.y;
inc(c);
end;

ShowField;
writeln(c);
end.
``````
-

You should rewrite the program to use a loop instead of cut-and-paste to visit each neighbor. If you do that you will avoid bugs like the following:

``````if (field[current.x, current.y - 1] <> 99) then
if (FindCell(closed, current.x, current.y - 1) <= 0) then
if (FindCell(opened, current.x + 1, current.y) <= 0) then
``````

(See the inconsistent `current.x + 1, current.y` in the last line.)

With respect to the loop, I was thinking of something like this (pseudo-Python):

``````neighbor_offsets = [(0, 1), (0, -1), (1, 0), (-1, 0)]
for offset in neighbor_offsets:
neighbor = current + offset
if is_walkable(neighbor) and not is_visited(neighbor):
# Open 'neighbor' with 'current' as parent:
open(neighbor, current)

# Perhaps check if the goal is reached:
if neighbor == finish:
goal_reached = True
break
``````

If you don't write a loop but just refactor to

``````ProcessCell(x+1, y);
ProcessCell(x-1, y);
ProcessCell(x, y-1);
ProcessCell(x, y-1);
``````

then that's a great improvement too.

-
It's a good idea, thank you, I will rewrite it :) Although fixing this line didn't solve problem. But could you explain what means "a loop to visit each neighbor", is it something like ProcessCell(x+1, y); ProcessCell(X-1, y); ProcessCell(x, y-1); ProcessCell(x, y-1); instead of these? –  Alex11223 Jan 31 '12 at 19:30
@Alex11223 Beware that the `current.x + 1` inconsistency has to be fixed (at least) twice in the program. I've added some more discussion of the code structure. –  antonakos Jan 31 '12 at 23:30
updated code, also fixed path marking (there should be or instead and), looks like it works now :) –  Alex11223 Feb 1 '12 at 6:24

Youre posting quite a lot of code, have you tried narrow it down where it fails?

Have you compared your code with the pseudocode on wikipedia?

Also remember that dijkstra is just A* with a heuristic of 0.

Edit:

The article you linked (which I now realize is the very same I used to learn the A*, funny) contains illustrated steps. I would suggest that you recreate that map/grid and run your implementation on it. Then step through the images:

1. Are the eight initial neighbors added to the open list? Do they have the correct parent?
2. Is the correct open node picked as next to be scanned according to the heuristic?
3. Is the list of closed nodes correct?
4. And so on...
-
fails == crashes? Program works, but path is incorrect (for example screenshot above). I can't understand where is misstake in my implemenatation of this algorithm =\ Looks like somewhere in field/coordinates movement implementation. –  Alex11223 Jan 31 '12 at 14:40