Common Lisp allows exception handling through conditions and restarts. In rough terms, when a function throws an exception, the "catcher" can decide how/whether the "thrower" should proceed. Does Prolog offer a similar system? If not, could one be built on top of existing predicates for walking and examining the call stack?
The ISO/IEC standard of Prolog provides only a very rudimentary exception and error handling mechanism which is - more or less - comparable to what Java offers and far away from Common Lisp's rich mechanism, but there are still some points worth noting. In particular, beside the actual signalling and handling mechanism, many systems provide a mechanism similar to
ISO throw/1, catch/3
An exception is raised/thrown with
Errors of built-in predicates are signaled by executing
There are many cases where handling an error locally would be of great benefit but it is deemed by many implementors to be too complex to implement.
The additional effort to make a Prolog processor handle each and every error locally is quite considerable and is much larger than in Common Lisp or other programming languages. This is due to the very nature of unification in Prolog. The local handling of an error would require to undo unifications performed during the execution of the built-in: An implementor has thus two possibilities to implement this:
Similar complexities are caused by exploiting WAM registers within built-ins. Again, one has the choice between a slow system or one with significant implementation overhead.
Many systems, however, provide internally better mechanisms, but few offer them consistently to the programmer. IF/Prolog provides
[user] ?- catch((arg(a,f(1),_); Z=ok), error(type_error(_,_),_), fail). no [user] ?- exception_handler((arg(a,f(1),_); Z=ok), error(type_error(_,_),_), fail). Z = ok yes
This built-in offered by quite a few systems. It is very similar to
All these mechanisms need to be provided by the system implementor, they cannot be built on top of ISO Prolog.
ISO prolog defines these predicates:
Regarding your note "If not, could one be built on top of existing predicates for walking and examining the call stack?" i don't think there is a general way to do this. Maybe look at the documentation of the prolog system you are using to see if there is some way to walk through the stack.
As false mentioned in his answer, ISO Prolog doesn't allow this. However, some experimentation shows that SWI-Prolog has provided a mechanism on which conditions and restarts could be built. A very rough proof of concept follows.
The "catcher" invokes
You can use hypothetical reasoning, to implement what you want. Lets say a Prolog system that allows hypothetical reasoning supports the following inference rule:
There are some Prolog systems that support this, for example lambda Prolog. You can now use hypothetical reasoning to implement for example restart/2 and signal_condition/3. Assume the hypothetical reasoning is done via (-:)/2, we could then have:
The solution will not for nothing traverse the whole stack trace, but directly query for a handler. But it begs the question whether I need a special Prolog or whether I can do hypothetical reasoning by myself. As a first approximation the (-:)/2 can be implemented as follows:
But the above will not work correctly if Goal issues a cut or an exception. So a better solution available for example in Jekejeke Minlog 0.6 would be:
The sys_unbind/1 predicate schedules an undo goal on the binding list. It corresponds to the undo/1 from SICStus. The binding list is resilient to cuts. The sys_atomic/1 assures that the undo goal is always schedule, even if an external signal happens during the execution, such as for example an end-user issued abort. It corresponds to how for example the first argument of setup_call_cleanup/3 is handled.
The advantage of using clause references here is that the clause is only compiled once, even if backtracking happens between the goal and the continuation after the (-:)/2. But otherwise the solution is most likely slower than putting a goal on the stack trace via calling it. But one could imagine further refinements of a Prolog system, for example (-:)/2 as a primitive and appropriate compile techniques.