Your remaining problem is in your `vecTimesMatrix`

predicate:

```
vecTimesMatrix([],[[]],[]).
vecTimesMatrix([List], [MH|Mtail],[N]):-
getDotProd(List, MH, N),
vecTimesMatrix(List, Mtail, N).
```

Issues:

- In the second clause, the first argument is given as
`[List]`

which would imply a list of a single element (`List`

). Subsequent calls to `getDotProd`

and `vecTimesMatrix`

in the clause indicate that this should simply be `List`

.
- In the second clause, the third argument is shown simply as a list of one argument:
`[N]`

. So the third argument never "builds" a list. Additionally, the recursive call to `vecTimesMatrix`

has `N`

as its third argument, and that argument had already been instantiated by the prior query to `getDotProd`

as the dot product of the vector `List`

and the vectory `MH`

. Logically, the recursive call should be saying that *the vector product of *`List`

with `Mtail`

is the tail of the final product.
- The base case assumes that the first argument reduces to
`[]`

, but this is not so. `List`

always remains as-is throughout the recursive process. So instead of `[]`

you should have `_`

(it will keep its value, but you don't care about it in the base case).
- The base case has as a second argument
`[[]]`

, but that's not the correct form for an empty list. That's actually a list consisting of one element, that element being the empty list. In reality, even though the second argument is a "list of lists", the empty list is still `[]`

.

Putting it all together (and renaming predicates per *de facto* conventions using underscores rather than camel case):

```
get_dot_prod([], [], 0.0). % Dot product of empty vectors is 0.0
% (Dot prod of vectors of unequal length
% is not defined and will fail)
get_dot_prod([H1|T1], [H2|T2], N) :- % N is dot product of [H1|T1] [H2|T2] if...
get_dot_prod(T1, T2, N1), % N1 is dot product of T1 T2, and
N is N1 + (H1 * H2). % N is N1 + (H1*H2) [evaluated]
vec_times_matrix(_, [], []). % Product of any vector with
% empty matrix is empty
vec_times_matrix(List, [MH|Mtail], [N|Ntail]):-
% [N|Ntail] is List x [MH|Mtail] if...
get_dot_prod(List, MH, N), % N is dot product of List and MH, and
vec_times_matrix(List, Mtail, Ntail). % Ntail is List x Mtail
```

This will yield:

```
| ?- vec_times_matrix([1,2],[[1,0],[0,1]], M).
M = [1.0,2.0] ? a
no
| ?- vec_times_matrix([1,2],[[1,0],[0,1],[1,1]], M).
M = [1.0,2.0,3.0] ? a
(1 ms) no
```

I added the comments in the code above to illustrate, in a simple way, how to think of the prolog predicate logic, which aids in defining them. As was pointed out already, the prolog "predicate" doesn't act as a "function". It describes a logical relation between entities which will either succeed or fail.

Once you learn to think how prolog thinks (relationally), you'll find it more enjoyable. :)

`N is getDotProd...`

, where you mean`getDotProd(List, MH, N)`

. The other is that your two rules for`getDotProd`

do not have the same arity: first one has four parameters and the second has three. – Daniel Lyons Mar 3 '14 at 20:06