Consider the code presented in my answer to related question "Finding the max in a list - Prolog".

The code in mentioned answer is based on the meta-predicate `foldl/4`

.

Here, I show how to do it with the meta-predicates `combine/3`

and `reduce/3`

. First, `combine/3`

:

```
:- meta_predicate combine(3,?,?).
combine( _ ,[] ,[]).
combine(P_3,[X|Xs],Ys) :-
list_prev_combined_(Xs,X,Ys,P_3).
:- meta_predicate list_combined_(?,?,3).
list_combined_([] ,[], _ ).
list_combined_([X|Xs],Ys,P_3) :-
list_prev_combined_(Xs,X,Ys,P_3).
:- meta_predicate list_prev_combined_(?,?,?,3).
list_prev_combined_([] ,X ,[X] , _ ).
list_prev_combined_([X1|Xs],X0,[Y|Ys],P_3) :-
call(P_3,X0,X1,Y),
list_combined_(Xs,Ys,P_3).
```

Building on `combine/3`

we can define `reduce/3`

as follows:

```
:- meta_predicate reduce(3,?,?).
reduce(P_3,[X|Xs],V) :-
list_aka_prev_reduced_(Xs,Xs,X,V,P_3).
:- meta_predicate list_aka_prev_reduced_(?,?,?,?,3).
list_aka_prev_reduced_([] ,_ ,V ,V, _ ).
list_aka_prev_reduced_([_|_],Xs,X0,V,P_3) :-
list_prev_combined_(Xs,X0,Ys,P_3),
reduce(P_3,Ys,V).
```

Regarding the shape of their respective proof trees, `foldl/4`

is similar to lists, while `combine/3`

and `reduce/3`

are similar to balanced binary trees.

Consider the following queries:

```
:- use_module(library(lambda)).
?- foldl(\X^Y^f(X,Y)^true, [1,2,3,4,5,6,7], 0,S).
S = f(7,f(6,f(5,f(4,f(3,f(2,f(1,0))))))).
?- combine(\X^Y^f(X,Y)^true, [1,2,3,4,5,6,7], S).
S = [f(1,2),f(3,4),f(5,6),7].
?- reduce(\X^Y^f(X,Y)^true, [1,2,3,4,5,6,7], S).
S = f(f(f(1,2),f(3,4)),f(f(5,6),7)).
```

`reduce/3`

is based on `combine/3`

and applies it until all items have been combined to one:

?- combine(\X^Y^f(X,Y)^true, [1,2,3,4,5,6,7], S).
S = [f(1,2),f(3,4),f(5,6),7].
?- combine(\X^Y^f(X,Y)^true, [f(1,2),f(3,4),f(5,6),7], S).
S = [f(f(1,2),f(3,4)),f(f(5,6),7)].
?- combine(\X^Y^f(X,Y)^true, [f(f(1,2),f(3,4)),f(f(5,6),7)], S).
S = [**f(f(f(1,2),f(3,4)),f(f(5,6),7))**].
?- reduce(\X^Y^f(X,Y)^true, [1,2,3,4,5,6,7], S).
S = **f(f(f(1,2),f(3,4)),f(f(5,6),7))**.

Let's use it for getting the maximum integer `Max`

in list `[1,5,2,4,3,8,7,2]`

:

:- use_module(library(clpfd)).
?- reduce(\X^Y^XY^(XY #= max(X,Y)), [1,5,2,4,3,8,7,2], Max).
Max = 8.
℅ If you can't use clpfd, simply use is/2 instead of (#=)/2:
?- reduce(\X^Y^XY^(XY **is** max(X,Y)), [1,5,2,4,3,8,7,2], Max).
Max = 8.

`Res`

isn't instantiated on a query to`max`

.`max`

and you can do this with an auxiliary predicate (which can just be`max/3`

versus`max/2`

). Here's a starter:`max([H|T], Max) :- max(T, H, Max).`

This says,. Now, you need to define`Max`

is the maximum value of list`[H|T]`

if`Max`

is the maximum of the highest value in list`T`

and the value`H`

(last max value seen)`max(List, MaxSeenSoFar, Max)`

and now you have`MaxSeenSoFar`

instantiated, so you can use your logical which compares`H`

from`[H|T]`

with`MaxSeenSoFar`

.