I'm having trouble imagining you'll be happy with
cell/4, since you've got four pointers to the other directions, but what's going to be in those cells is just pointers to other cells, which are just pointers to other cells... I think probably you actually want
cell/5, which is more like some value plus the pointers in each direction.
In general, if you want a list of size N, you can use
length/2 to generate one for you like this:
?- length(L, 3).
L = [_772, _778, _784].
Then you can pass that list of variables around. Presumably you're making a maze or something and you want to pass your grid to some process that's going to place grues and walls or something in it, and that's why you want this grid. My comment above is meant to say that this structure, in an Mx1 arrangement, resembles a doubly-linked list:
| | Interconnect_1 | |
West_1 -+ West cell/2 East +----------------+ West cell/2 East +- East_1
| | | |
You can build this structure manually in a similar way:
?- West = cell(West_1, East), East = cell(West, East_1).
West = cell(West_1, cell(West, East_1)),
East = cell(West, East_1).
@false correctly points out this will be recursive, since West is equal to some structure with West inside it. I share his misgivings with it because infinite terms present interesting problems, and moreover, usually you can just hold onto the previous value during your traversal and avoid the problem. (In your case, that would be forming a grid with just East and South pointers, I guess, or some other combination of one latitudinal and one longitudinal direction instead of both of each).
In any event, you can build a doubly-linked list by following the example of
length/2 and passing in a length you want and constructing one node at a time:
generate(0, Prev, cell(Prev, _)).
generate(N, Prev, cell(Prev, Next)) :-
generate(N0, cell(Prev, Next), Next).
Here's the N=3 case:
?- generate(3, Start, X).
X = cell(Start, cell(_S1, cell(_S2, _S3))), % where
_S1 = cell(Start, cell(_S1, cell(_S2, _S3))),
_S2 = cell(_S1, cell(_S2, _S3)),
_S3 = cell(cell(_S2, _S3), _656)
Again, let me point out that a cons cell in a singly-linked list is going to be something like
cell/2 because there's a value and a next pointer, so we probably need to add a value slot to this and return
cell/3 structures instead.
So, returning to the grid, what you probably need to do to generate an NxN grid is something akin to generating a row at a time, holding onto the previous row you made each time and passing it to some kind of zip-up process that equates the previous row's
South pointers to the current row's
I have a solution for the singly-linked grid case here. I hope this turns out to be sufficient for what you need. It was a little tricky to come up with!
First, we will need to be able to generate a row:
generate_row(1, cell(_, nil, _)).
generate_row(N, cell(_, Next, _)) :-
The plan here is that we have a
cell(Value, NextRight, NextDown) structure. Both
NextDown are cells, which are the East and South directions in your grid respectively. I am using
nil to represent what the empty list does; it terminates our recursion and represents a null pointer. This turns out to be an important thing to have since otherwise my stitch-up procedure will have unbounded recursion.
Now that we have a row, let's worry about how we'll combine an upper and a lower row. All we're really doing here is walking both rows from left to right, equating the NextBelow of the upper one to the cell below it in the second list. This is a little weird to read, but it does work:
stitch(cell(_, NextAbove, Below), Below) :-
Below = cell(_, NextBelow, _),
stitch(cell(_, nil, Below), Below).
Because we need
Below to remain whole, we take it apart in the body rather than the head. I match
nil here to terminate the recursion.
Now we have all the pieces we need to generate a whole grid: we will generate a row, recursively generate the rest of the rows, and use
stitch/2 to place the new row on top of the recursively generated rows. Now we will also need a secondary parameter so we can count down rows.
generate_rows(2, N, Above) :-
generate_rows(M, N, Grid) :-
generate_rows(M0, N, Below),
I felt like my base case was a 2xM matrix; it probably could be made to work for 1xM with more careful coding but this is what I came up with.
Running it, it will not be immediately obvious that you have a useful result:
?- generate_rows(3, 3, X).
X = cell(_8940, cell(_8948, cell(_8956, nil, cell(_8980, nil, cell(_9004, nil, _9008))), cell(_8972, cell(_8980, nil, cell(_9004, nil, _9008)), cell(_8996, cell(_9004, nil, _9008), _9000))), cell(_8964, cell(_8972, cell(_8980, nil, cell(_9004, nil, _9008)), cell(_8996, cell(_9004, nil, _9008), _9000)), cell(_8988, cell(_8996, cell(_9004, nil, _9008), _9000), _8992))) ;
However, if you format it, it will start to make sense:
X = cell(_8940,
cell(_9004, nil, _9008))),
cell(_9004, nil, _9008)),
cell(_8996, cell(_9004, nil, _9008), _9000))),
cell(_9004, nil, _9008)),
cell(_8996, cell(_9004, nil, _9008), _9000)),
cell(_9004, nil, _9008),
OK, read all the variables in the first position until you are indented as far as you can go. Then read them in the first position from the second-leftmost cell, and repeat. You should get a table of 3x3 variables:
_8940 _8948 _8956
_8964 _8972 _8980
_8988 _8996 _9004
Now looking at that table, you should notice that _8940 should have two children: 8948 (East) and 8964 (South), and it does. You'll notice that 8972 should have two children: 8980 (East) and 8996 (South), and it does. There is a lot of repetition in the tree, but it is consistent.
Anyway, this isn't exactly a solution to your question. But I hope it is helpful to you. If you do still decide to doubly-link it, you will have to generalize this solution the way the doubly-linked list is generalized from
length/2. Hopefully, there is enough here for you to see what you'd have to do if you decide you have to do that, but this is as far as I am willing to take it for now.