In Prolog's terms, `condA`

is *"soft cut"*, `*->`

, and `condU`

is *"committed choice"* – a combination of `once`

and a soft cut, so that `(once(A) *-> B ; false)`

expresses the *cut* in `(A, !, B)`

:

```
A *-> B ; C %% soft cut, condA
once(A) *-> B ; C %% committed choice, condU
```

In `condA`

, if the goal `A`

succeeds, all the solutions are passed through to the first clause `B`

and no alternative clauses `C`

are tried. `once/1`

allows its argument goal to succeed only once (keeps only one solution, if any).

`condE`

is a simple disjunction, and `condI`

is a disjunction which alternates between the solutions of its constituents.

Here's an attempt at faithfully translating the book's code, w/out logical variables and unification, into 18 lines of Haskell (where juxtaposition is curried function application, and `:`

means *cons*). See if this clarifies things:

- Sequential stream combination ("
`mplus`

" of the book):

```
(1) [] ++: ys = ys
(2) (x:xs) ++: ys = x:(xs ++: ys)
```

- Alternating stream combination ("
`mplusI`

"):

```
(3) [] ++/ ys = ys
(4) (x:xs) ++/ ys = x:(ys ++/ xs)
```

- Sequential feed ("
`bind`

"):

```
(5) [] >>: g = []
(6) (x:xs) >>: g = g x ++: (xs >>: g)
```

- Alternating feed ("
`bindI`

"):

```
(7) [] >>/ g = []
(8) (x:xs) >>/ g = g x ++/ (xs >>/ g)
```

- "
`OR`

" *goal* combination ("`condE`

"):

```
(9) (f ||: g) x = f x ++: g x
```

- "Alternating
`OR`

" goal combination ("`condI`

"):

```
(10) (f ||/ g) x = f x ++/ g x
```

- "
`AND`

" goal combination ("`all`

"):

```
(11) (f &&: g) x = f x >>: g
```

- "Alternating
`AND`

" goal combination ("`allI`

" of the book):

```
(12) (f &&/ g) x = f x >>/ g
```

```
(13) true x = [x] -- a sigleton list with the same solution repackaged
(14) false x = [] -- an empty list, meaning the solution is rejected
```

*Goals* produce streams (possibly empty) of (possibly updated) solutions, given a (possibly partial) solution to a problem.

Re-write rules for `all`

are:

```
(all) = true
(all g1) = g1
(all g1 g2 g3 ...) = (\x -> g1 x >>: (all g2 g3 ...))
=== g1 &&: (g2 &&: (g3 &&: ... ))
(allI g1 g2 g3 ...) = (\x -> g1 x >>/ (allI g2 g3 ...))
=== g1 &&/ (g2 &&/ (g3 &&/ ... ))
```

Re-write rules for `condX`

are:

```
(condX) = false
(condX (else g1 g2 ...)) = (all g1 g2 ...) === g1 &&: (g2 &&: (...))
(condX (g1 g2 ...)) = (all g1 g2 ...) === g1 &&: (g2 &&: (...))
(condX (g1 g2 ...) (h1 h2 ...) ...) =
(ifX g1 (all g2 ...) (ifX h1 (all h2 ...) (...) ))
```

To arrive at the final `condE`

and `condI`

's translation, there's no need to implement the book's `ifE`

and `ifI`

, since they reduce further to simple operator combinations, with all the operators considered to be *right-associative*:

```
(condE (g1 g2 ...) (h1 h2 ...) ...) =
(g1 &&: g2 &&: ... ) ||: (h1 &&: h2 &&: ...) ||: ...
(condI (g1 g2 ...) (h1 h2 ...) ...) =
(g1 &&: g2 &&: ... ) ||/ (h1 &&: h2 &&: ...) ||/ ...
```

So there's no need for any special "syntax" in Haskell, plain operators suffice. Any combination can be used, with `&&/`

instead of `&&:`

if needed. But OTOH `condI`

could also be implemented as a function to accept a collection (list, tree etc.) of goals to be fulfilled, that would use some smart strategy to pick of them one most likely or most needed etc, and not just simple binary alternation as in `||/`

operator (or `ifI`

of the book).

Next, the book's `condA`

can be modeled by two new operators, `~~>`

and `||~`

, working together. We can use them in a natural way as in e.g.

```
g1 ~~> g2 &&: ... ||~ h1 ~~> h2 &&: ... ||~ ... ||~ gelse
```

which can intuitively be read as "`IF g1 THEN g2 AND ... OR-ELSE IF h1 THEN ... OR-ELSE gelse`

".

- "
`IF-THEN`

" goal combination is to produce a "try" goal which must be called with a failure-continuation goal:

```
(15) (g ~~> h) f x = case g x of [] -> f x ; ys -> ys >>: h
```

- "
`OR-ELSE`

" goal combination of a "try" goal and a simple goal simply calls its "try" goal with a second, on-failure goal, so it's nothing more than a convenience syntax for automatic grouping of operands:

```
(16) (g ||~ f) x = g f x
```

If the `||~`

"`OR-ELSE`

" operator is given less binding power than the `~~>`

"`IF-THEN`

" operator and made right-associative too, and `~~>`

operator has still less binding power than `&&:`

and the like, sensible grouping of the above example is automatically produced as

```
(g1 ~~> (g2 &&: ...)) ||~ ( (h1 ~~> (h2 &&: ...)) ||~ (... ||~ gelse)...)
```

Last goal in an `||~`

chain must thus be a simple goal. That's no limitation really, since last clause of `condA`

form is equivalent anyway to simple "`AND`

"-combination of its goals (or simple `false`

can be used just as well).

That's all. We can even have more types of try-goals, represented by different kinds of "`IF`

" operators, if we want:

- use alternating feed in a successful clause (to model what could've been called
`condAI`

, if there were one in the book):

```
(17) (g ~~>/ h) f x = case g x of [] -> f x ; ys -> ys >>/ h
```

- use the successful solution stream only
*once* to produce the *cut* effect, to model `condU`

:

```
(18) (g ~~>! h) f x = case g x of [] -> f x ; (y:_) -> h y
```

So that, finally, the re-write rules for `condA`

and `condU`

of the book are simply:

```
(condA (g1 g2 ...) (h1 h2 ...) ...) =
g1 ~~> g2 &&: ... ||~ h1 ~~> h2 &&: ... ||~ ...
(condU (g1 g2 ...) (h1 h2 ...) ...) =
g1 ~~>! g2 &&: ... ||~ h1 ~~>! h2 &&: ... ||~ ...
```