# Has the notion of 'semidet' in Prolog been settled?

Being new to Prolog, I came across a very interesting discussion that happened in late 2012. What I noticed was that there were, at the time, two notions of 'semidet' in Prolog community, namely:

1. A computation that succeeds at most once.
2. A computation that, upon success, leaves no choice points open.

Clearly the second one implies the first, but not vice versa.

Reading the thread, I understood that the first one was Dr.Neumerkel's notion, and the second was Drs.Wielemaker, O'Keefe, and others'.

Googling around, I've seen some database researchers mean by 'semi-deterministic' a query that would answer at most one equivalence class, nearer to the first notion.

Dr. Neumerkel says (refering to the predicate called `call_semidet` there):

The implementation might be improved, but prior to optimizing and bechnmarking the actual meaning needs to be settled.

So, has the meaning been settled?

It seems customary to classify predicates according to their number of solutions. According to the SWI-Prolog's definition (see below), a 'det' can do fully nondeterministic (say parallel) computations, provided it commits to a solution which is now guaranteed to exist. So, by analogy I guess there may be two notions of 'det':

1. A computation which succeeds exactly once.
2. A computation which succeeds exactly once and which, upon success, leaves no choice points.

The first one is more logical but undecidable in general until the end of the computation. The second is easily decidable once a solution is found, but procedural and its meaning depends on the particular search strategy Prolog employs, i.e. the depth first search.

I wonder if there is not a community's consensus yet? Why not name these two different concepts differently?

Here's the excerpt from the SWI-Prolog's page above:

det [determinism]

Short for deterministic.

deterministic

A predicate is deterministic if it succeeds exactly one time without leaving a choice point.

semidet

Shorthand for semi deterministic.

semi deterministic

A predicate that is semi deterministic either fails or succeeds exactly once without a choice point. See also deterministic.

• "...the actual meaning needs to be settled." This quote actually referred to the user's programming process where we want to settle the meaning of a predicate. It was not meant to refer to settling the meaning of `call_semidet/1` which was already settled. Oct 1, 2016 at 12:08

That's a really excellent question!

From the Mercury determinism categories where this is also explained quite authoritatively:

## 6.1 Determinism categories

For each mode of a predicate or function, we categorise that mode according to how many times it can succeed, and whether or not it can fail before producing its first solution.

If all possible calls to a particular mode of a predicate or function which return to the caller (calls which terminate, do not throw an exception and do not cause a fatal runtime error)

• have exactly one solution, then that mode is deterministic (det);
• either have no solutions or have one solution, then that mode is semideterministic (semidet);
• have at least one solution but may have more, then that mode is multisolution (multi);
• have zero or more solutions, then that mode is nondeterministic (nondet);
• have exactly zero solutions, i.e, fail without producing a solution, then that mode has a determinism of failure (failure).

(emphases mine)

Note that whether or not a choice point is left is not even mentioned in this definition, nor in the whole section. Mercury is not the same as Prolog, but the point is that this definition is in principle 100% applicable also to Prolog. Clearly, it then corresponds to your variant (1).

In my opinion, this is right in this way: Whether or not a choice point is left is rather immaterial, and depends on—for example—how powerful and versatile your system's argument indexing is. A good indexing scheme may prevent the creation of choice points that other systems introduce. A notion that depends on particular idiosyncrasies of a specific Prolog system and may break from one version to the next (with the introduction of better argument indexing etc.) is not very robust, and not of much value.

It is true that we often say "the predicate is deterministic" when we mean: "the predicate is deterministic and no choice points are left", but even so the main point is almost always also in such cases that the predicate succeeds exactly once. Note that "deterministic" is a rather overloaded adjective with other meanings too. In the SWI documentation, this ambiguity carries over to semi deterministic. However, even SWI back-pedals a bit from this rather implementation-oriented definition in other places:

### 2.2.2 Testing semi-deterministic predicates

Semi-deterministic predicates are predicates that either fail or succeed exactly once and, for well behaved predicates, leave no choicepoints.

So a semi-deterministic predicate that is not well behaved (?) can also leave choice points...

In the discussion, note especially the following: Ulrich is here using the weaker and more robust notion to obtain a predicate that is applicable for both definitions.

So, no matter which variant you pick, `call_semidet/1` is useful! From this, the meaning of the quote becomes clearer. When Ulrich says:

(The implementation might be improved, but prior to optimizing and bechnmarking the actual meaning needs to be settled.)

it is evidently not meant that the meaning of "semidet" must be settled between the two variants, but that it should first be clear what `call_semidet/1` actually guarantees: It is a lot more useful than what people thought Ulrich posted. For example, the definition that Jan gives:

```call_semidet(Goal) :-
call_cleanup(Goal, Det=true),
(   Det == true
->  true
;   throw(error(mode_error(semidet,Goal),_))
).
```

works only with your second definition of "semidet".

• Note that in Mercury answer and solutions are notions that can be used almost interchangeably since Mercury's answers are ground answers only. Oct 1, 2016 at 12:10
• Thanks for your detailed answer! The issue with optimization was exactly what I had in mind, but my intent was that "aren't both definitions well-defined and useful, deserving their own terminologies?" Maybe I'll rewrite my question tomorrow to clarify what I mean by "well-defined". Oct 1, 2016 at 14:42
• @mnish: Maybe better write a new question. Oct 1, 2016 at 15:02
• I agree with false: it is best to file a new question, since changing the question would also require changes in existing answers.
– mat
Oct 1, 2016 at 16:46

The classification currently being used e.g. in SWI-Prolog is, as @mat mentioned, taken from Mercury. The mode names used (`det`, `semidet`, `multi`, and `nondet`) are very poor (and also insufficient) choices. They are not only abbreviations but require new users to lookup the documentation to understand their meaning! Ironically, the description of the meaning of each of these modes already suggests the best non-abbreviated and clear names. Remembering that we're talking about the number of solutions: `zero`, `one`, `zero_or_one`, `zero_or_more`, `one_or_more` (and possibly, due to its usefulness, `error`, which can be used to indicate that a given call mode results in an error). These are, btw, the mode names in use in Logtalk.

Mixing the specification of the number of solutions for a predicate (in a given mode) with issues with leftover choice-points is also a poor choice, ridden with ambiguity, as @mat also described. Code optimization issues are orthogonal to the specification of the number of solutions. Also, any mode other than `zero` may leave a spurious choice-point when the solutions are exhausted. Thus, this is more general than just a distinction between the poorly named `det` and `semidet` modes.

• `call_semidet/1` is about answers, not solutions. Oct 1, 2016 at 11:56
• @false Neither the question or my answer is about the `call_semidet/1` predicate. Moreover, although both the question and the answers so far talk about solutions, a distinction can be made between solutions, answers, and proofs. But that requires precise definitions for these terms and a public consensus about those definitions. Currently, these terms are often used in a liberal way. In that regard, Logtalk describes in fact the second argument in predicate `mode/2` directives as the number of proofs, which follows naturally from the way the inference engine works. Oct 1, 2016 at 13:38
• Thank you very much, your point taken, but I have another point regarding "ambiguity" of choicepoints. It seems to me that choicepoints are a well-defined ISO concept independent of particular implementation. But maybe I need to understand precisely what `call_cleanup/2` does. Oct 1, 2016 at 14:52
• @mnish: See this definition which is the best so far. For any questions, use a new SO-question. Oct 1, 2016 at 15:14
• @mnish: Again: For any questions, use a new SO-question. Oct 2, 2016 at 15:41