The following is based on the reification of term equality/inequality.

First, we first define `list_memberd_t/3`

, which behaves just like the `memberd_truth/3`

but has a different argument order:

```
list_memberd_t([] ,_,false).
list_memberd_t([Y|Ys],X,Truth) :-
if_(X=Y, Truth=true, list_memberd_t(Ys,X,Truth)).
list_memberd_truth(Xs,X,Truth) :- list_memberd_t(Xs,X,Truth).
```

For the sake of brevity, let's define `memberd_t/3`

based on `list_memberd_t/3`

:

```
memberd_t(X,Xs,Truth) :- list_memberd_t(Xs,X,Truth).
```

As a parallel to `library(apply)`

, let's define `tinclude/3`

:

```
:- meta_predicate tinclude(2,?,?).
tinclude(P_2,Xs,Zs) :-
list_tinclude_list(Xs,P_2,Zs).
list_tinclude_list([], _P_2,[]).
list_tinclude_list([E|Es],P_2,Fs0) :-
if_(call(P_2,E), Fs0 = [E|Fs], Fs0 = Fs),
list_tinclude_list(Es,P_2,Fs).
```

`tfilter/3`

is another name for `tinclude/3`

:

```
tfilter(P_2,As,Bs) :-
tinclude(P_2,As,Bs).
```

Next, we define the meta-predicate `texclude/3`

, the opposite of `tinclude/3`

:

```
:- meta_predicate texclude(2,?,?).
texclude(P_2,Xs,Zs) :-
list_texclude_list(Xs,P_2,Zs).
list_texclude_list([],_,[]).
list_texclude_list([E|Es],P_2,Fs0) :-
if_(call(P_2,E), Fs0 = Fs, Fs0 = [E|Fs]),
list_texclude_list(Es,P_2,Fs).
```

Now let's use them together!

```
?- texclude(list_memberd_truth([a,e,i,o,u]),
[d,e,l,e,t,e,' ',v,o,w,e,l,s,' ',i,n,' ',a,' ',l,i,s,t], Filtered).
Filtered = [d, l, t, ' ',v, w, l,s,' ', n,' ', ' ',l, s,t].
```

### Edit

As an alternative to using above `texclude/3`

, let's use `tinclude/3`

with an auxiliary predicate `not/3`

to flip the truth value:

```
:- meta_predicate not(2,?,?).
not(P_2,X,Truth) :-
call(P_2,X,Truth0),
truth_flipped(Truth0,Truth).
truth_flipped(true,false).
truth_flipped(false,true).
```

Sample query:

```
?- tinclude(not(list_memberd_truth([a,e,i,o,u])),
[d,e,l,e,t,e,' ',v,o,w,e,l,s,' ',i,n,' ',a,' ',l,i,s,t], Filtered).
Filtered = [d, l, t, ' ',v, w, l,s,' ', n,' ', ' ',l, s,t].
```