Can someone provide a simple example of channelling constraints?
Channelling constraints are used to combine viewpoints of a constraint problem. Handbook of Constraint Programming gives a good explanation of how it works and why it can be useful:
The search variables can be the variables of one of the viewpoints, say X1 (this is discussed further below). As
search proceeds, propagating the constraints C1 removes values from the domains of the
variables in X1. The channelling constraints may then allow values to be removed from
the domains of the variables in X2. Propagating these value deletions using the constraints
of the second model, C2, may remove further values from these variables, and again these
removals can be translated back into the first viewpoint by the channelling constraints. The
net result can be that more values are removed within viewpoint V1 than by the constraints
C1 alone, leading to reduced search.
I do not understand how this is implemented. What are these constraints exactly, how do they look like in a real problem? A simple example would be very helpful.
As stated in Dual Viewpoint Heuristics for Binary Constraint Satisfaction Problems (P.A. Geelen):
Channelling constraints of two different models allows for the expression of a relationship between two sets of variables, one of each model.
This implies assignments in one of the viewpoints can be translated into assignments in the other and vice versa, as well as, when search initiates,
excluded values from one model can be excluded from the other as well.
Let me throw in an example I implemented a while ago while writing a Sudoku solver.
Classic viewpoint
Here we interpret the problem in the same way a human would: using the
integers between 1 and 9 and a definition that all rows, columns and blocks must contain every integer exactly once.
We can easily state this in ECLiPSe using something like:
% Domain
dim(Sudoku,[N,N]),
Sudoku[1..N,1..N] :: 1..N
% For X = rows, cols, blocks
alldifferent(X)
And this is yet sufficient to solve the Sudoku puzzle.
Binary boolean viewpoint
One could however choose to represent integers by their binary boolean arrays (shown in the answer by #jschimpf). In case it's not clear what this does, consider the small example below (this is built-in functionality!):
? ic_global:bool_channeling(Digit, [0,0,0,1,0], 1).
Digit = 4
Yes (0.00s cpu)
? ic_global:bool_channeling(Digit, [A,B,C,D], 1), C = 1.
Digit = 3
A = 0
B = 0
C = 1
D = 0
Yes (0.00s cpu)
If we use this model to represent a Sudoku, every number will be replaced by its binary boolean array and corresponding constraints can be written. Being trivial for this answer, I will not include all the code for the constraints, but a single sum constraint is yet enough to solve a Sudoku puzzle in its binary boolean representation.
Channelling
Having these two viewpoints with corresponding constrained models now gives the opportunity to channel between them and see if any improvements were made.
Since both models are still just an NxN board, no difference in dimension of representation exists and channelling becomes real easy.
Let me first give you a last example of what a block filled with integers 1..9 would look like in both of our models:
% Classic viewpoint
1 2 3
4 5 6
7 8 9
% Binary Boolean Viewpoint
[](1,0,0,0,0,0,0,0,0) [](0,1,0,0,0,0,0,0,0) [](0,0,1,0,0,0,0,0,0)
[](0,0,0,1,0,0,0,0,0) [](0,0,0,0,1,0,0,0,0) [](0,0,0,0,0,1,0,0,0)
[](0,0,0,0,0,0,1,0,0) [](0,0,0,0,0,0,0,1,0) [](0,0,0,0,0,0,0,0,1)
We now clearly see the link between the models and simply write the code to channel our decision variables. Using Sudoku and BinBools as our boards, the code would look something like:
( multifor([Row,Col],1,N), param(Sudoku,BinBools,N)
do
Value is Sudoku[Row,Col],
ValueBools is BinBools[Row,Col,1..N],
ic_global:bool_channeling(Value,ValueBools,1)
).
At this point, we have a channelled model where, during search, if values are pruned in one of the models, its impact will also occur in the other model. This can then of course lead to further overall constraint propagation.
Reasoning
To explain the usefulness of the binary boolean model for the Sudoku puzzle, we must first differentiate between some provided alldifferent/1 implementations by ECLiPSe:
What this means in practice can be shown as following:
? [A, B, C] :: [0..1], ic:alldifferent([A, B, C]).
A = A{[0, 1]}
B = B{[0, 1]}
C = C{[0, 1]}
There are 3 delayed goals.
Yes (0.00s cpu)
? [A, B, C] :: [0..1], ic_global:alldifferent([A, B, C]).
No (0.00s cpu)
As there has not yet occurred any assignment using the Forward Checking (ic library), the invalidity of the query is not yet detected, whereas the Bounds Consistent version immediately notices this. This behaviour can lead to considerable differences in constraint propagation while searching and backtracking through highly constrained models.
On top of these two libraries there is the ic_global_gac library intended for global constraints for which generalized arc consistency (also called hyper arc consistency or domain consistency) is maintained. This alldifferent/1 constraint provides even more pruning opportunities than the bounds consistent one, but preserving full domain consistency has its cost and using this library in highly constrained models generally leads to a loss in running performance.
Because of this, I found it interesting for the Sudoku puzzle to try and work with the bounds consistent (ic_global) implementation of alldifferent to maximise performance and subsequently try to approach domain consistency myself by channelling the binary boolean model.
Experiment results
Below are the backtrack results for the 'platinumblonde' Sudoku puzzle (referenced as being the hardest, most chaotic Sudoku puzzle to solve in The Chaos Within Sudoku, M. ErcseyRavasz and Z. Toroczkai) using respectively forward checking, bounds consistency, domain consistency, standalone binary boolean model and finally, the channelled model:
(ic) (ic_global) (ic_global_gac) (bin_bools) (channelled)
BT 6 582 43 29 143 30
As we can see, our channelled model (using bounds consistency (ic_global)) still needs one backtrack more than the domain consistent implementation, but it definitely performs better than the standalone bounds consistent version.
When we now take a look at the running times (results are the product of calculating an average over multiple executions, this to avoid extremes) excluding the forward checking implementation as it's proven to no longer be interesting for solving Sudoku puzzles:
(ic_global) (ic_global_gac) (bin_bools) (channelled)
Time(ms) 180ms 510ms 100ms 220ms
Looking at these results, I think we can successfully conclude the experiment (these results were confirmed by 20+ other Sudoku puzzle instances):
Channelling the binary boolean viewpoint to the bounds consistent standalone implementation produces a slightly less strong constraint propagation behaviour than that of the domain consistent standalone implementation, but with running times ranging from just as long to notably faster.
EDIT: attempt to clarify
Imagine some domain variable representing a cell on a Sudoku board has a remaining domain of 4..9. Using bounds consistency, it is guaranteed that for both value 4 and 9 other domain values can be found which satisfy all constraints and thus provides consistency. However, no consistency is explicitly guaranteed for other values in the domain (this is what 'domain consistency' is).
Using a binary boolean model, we define the following two sum constraints:
The sum of every binary boolean array is always equal to 1
The sum of every N'th element of every array in every row/col/block is always equal to 1
The extra constraint strength is enforced by the second constraint which, apart from constraining row, columns and blocks, also implicitly says: "every cell can only contain every digit once". This behaviour is not actively expressed when using just the bounds consistent alldifferent/1 constraint!
Conclusion
It is clear that channelling can be very useful to improve a standalone constrained model, however if the new model's constraint strengthness is weaker than that of the current model, obviously, no improvements will be made. Also note that having a more constrained model doesn't necesarilly also mean an overall better performance! Adding more constraints will in fact decrease amounts of backtracks required to solve a problem, but it might also increase the running times of your program if more constraint checks have to occur.
Channeling constraints are used when, in a model, aspects of a problem are represented in more than one way. They are then necessary to synchronize these multiple representations, even though they do not themselves model an aspect of the problem.
Typically, when modelling a problem with constraints, you have several ways of choosing your variables. For example, in a scheduling problem, you could choose to have
an integer variable for each job (indicating which machine does the job)
an integer variable for each machine (indicating which job it performs)
a matrix of Booleans (indicating which job runs on which machine)
or something more exotic
In a simple enough problem, you choose the representation that makes it easiest to formulate the constraints of the problem. However, in real life problems with many heterogeneous constraints it is often impossible to find such a single best representation: some constraints are best represented with one type of variable, others with another.
In such cases, you can use multiple sets of variables, and formulate each individual problem constraint over the most convenient variable set. Of course, you then end up with multiple independent subproblems, and solving these in isolation will not give you a solution for the whole problem. But by adding channeling constraints, the variable sets can be synchronized, and the subproblems thus re-connected. The result is then a valid model for the whole problem.
As hinted in the quote from the handbook, in such a formulation is is sufficient to perform search on only one of the variable sets ("viewpoints"), because the values of the others are implied by the channeling constraints.
Some common examples for channeling between two representations are:
Integer variable and Array of Booleans:
Consider an integer variable T indicating the time slot 1..N when an event takes place, and an array of Booleans Bs[N] such that Bs[T] = 1 iff an event takes place in time slot T. In ECLiPSe:
T #:: 1..N,
dim(Bs, [N]), Bs #:: 0..1,
Channeling between the two representations can then be set up with
( for(I,1,N), param(T,Bs) do Bs[I] #= (T#=I) )
which will propagate information both ways between T and Bs. Another way of implementing this channeling is the special purpose bool_channeling/3 constraint.
Start/End integer variables and Array of Booleans (timetable):
We have integer variables S,E indicating the start and end time of an activity. On the other side an array of Booleans Bs[N] such that Bs[T] = 1 iff the activity takes place at time T. In ECLiPSe:
[S,E] #:: 1..N,
dim(Bs, [N]), Bs #:: 0..1,
Channeling can be achieved via
( for(I,1,N), param(S,E,Bs) do Bs[I] #= (S#=<I and I#=<E) ).
Dual representation Job/Machine integer variables:
Here, Js[J] = M means that job J is executed on machine M, while the dual formulation Ms[M] = J means that machine M executes job J
dim(Js, [NJobs]), Js #:: 0..NMach,
dim(Ms, [NMach]), Ms #:: 1..NJobs,
And channeling is achieved via
( multifor([J,M],1,[NJobs,NMach]), param(Js,Ms) do
(Js[J] #= M) #= (Ms[M] #= J)
).
Set variable and Array of Booleans:
If you use a solver (such as library(ic_sets)) that can directly handle set-variables, these can be reflected into an array of booleans indicating membership of elements in the set. The library provides a dedicated constraint membership_booleans/2 for this purpose.
Here is a simple example, works in SWI-Prolog, but should
also work in ECLiPSe Prolog (in the later you have to use (::)/2 instead of (in)/2):
Constraint C1:
?- Y in 0..100.
Y in 0..100.
Constraint C2:
?- X in 0..100.
X in 0..100.
Channelling Constraint:
?- 2*X #= 3*Y+5.
2*X#=3*Y+5.
All together:
?- Y in 0..100, X in 0..100, 2*X #= 3*Y+5.
Y in 1..65,
2*X#=3*Y+5,
X in 4..100.
So the channel constraint works in both directions, it
reduces the domain of C1 as well as the domain of C2.
Some systems use iterative methods, with the result that this channelling
can take quite some time, here is an example which needs around
1 minute to compute in SWI-Prolog:
?- time(([U,V] ins 0..1_000_000_000, 36_641*U-24 #= 394_479_375*V)).
% 9,883,559 inferences, 53.616 CPU in 53.721 seconds
(100% CPU, 184341 Lips)
U in 346688814..741168189,
36641*U#=394479375*V+24,
V in 32202..68843.
On the other hand ECLiPSe Prolog does it in a blink:
[eclipse]: U::0..1000000000, V::0..1000000000,
36641*U-24 #= 394479375*V.
U = U{346688814 .. 741168189}
V = V{32202 .. 68843}
Delayed goals:
-394479375 * V{32202 .. 68843} +
36641 * U{346688814 .. 741168189} #= 24
Yes (0.11s cpu)
Bye
Related
The goal is to select shapes that don't touch each other using constraints (clpfd). Calling start(Pairs,4) would return Pairs = [1,3,5,7].
One problem I noticed is that if I print Final before labeling, it prints [1,3,5,7]. Which means labeling isn't doing anything.
What could I change/add to this code in order to fix that and also remove possible backtracking?
:-use_module(library(clpfd)).
:-use_module(library(lists)).
% init initialises Pairs and Max
% Pairs - The elements inside the Nth list in Pairs,
% represent the index of the shapes that shape N can touch
init([[3,5,6,7],[4,5,7],[1,4,5,7],[2,3,7],[1,2,3,7],[1],[1,2,3,4,5]],7).
start(Final, N):-
init(Pairs, Max),
length(Final, N),
domain(Final, 1, Max),
ascending(Final),
all_different(Final),
rules(Pairs,Final),
labeling([],Final).
rules(_,[]).
rules(Pairs,[H|T]):-
nth1(H,Pairs,PairH),
secondrule(PairH,T),
rules(Pairs,T).
secondrule(_, []).
secondrule(PairH, [H|T]):-
element(_,PairH,H),
secondrule(PairH, T).
ascending([_|[]]).
ascending([H|[T1|T2]]):-
H #< T1,
ascending([T1|T2]).
This is an Independent Set problem, which is an NP-hard problem. Therefore, it is unlikely that anybody will ever find a way to do it without search (backtracking) for general instances.
Regarding your code, labeling/2 does nothing, because your rules/2 is in fact a search procedure that returns the solution it it can find it. all_different/1 is useless too, because it is implied by ascending/1.
Presumably, your goal is a program that sets up constraints (without any search) and then searches for a solution with labeling/2. For that, you need to rethink your constraint model. Read up a bit on independent sets.
I am new to Prolog and now I have to implement a path consistency algorithm for RCC8 calculus/Allen Time Interval Algebra in Prolog.
I am struggling with basic problems. A small example of my Background Knowledge. It is all about a given transitivity table and computing the resulting constraints between regions:
tpp(a,b).
dc(b,c).
dc(A,C) :- dc(A,C).
dc(A,C) :- tpp(A,B), dc(B,C).
So the constraint dc(a,c). should be generated. The whole algorithm:
Input: A network T
Output: A path consisten network
repeat
S <- T
for k:=1 to n do
for i,j := 1 to n do begin
Cij <- Cij UNION Cik COMPOSITION Ckj
until S = T
where Cij is the constraint between the nodes i and j. In the case of the BK tpp(a,b) for example. So my qeustion is, I am struggeling writing a rule which computes the resulting constraint from the transitivity table. I want to start with something like this:
comp([tpp(a,b), dc(b,c)], X).
Which stores dc(a,c) in X and I get X = [dc(a,c)] back.
I don't know if it is the right approach. I want to have a rule to which I give a list of constraints and it computes all resulting constraints. I am used to program in Python and Java and now I am struggeling starting with the problem.
Thank you very much! :D
I #> 0, I #< 10, indomain(I).
The previous code obviously does the following:
I = 1 ;
I = 2 ;
I = 3 ;
I = 4 ;
I = 5 ;
I = 6 ;
I = 7 ;
I = 8 ;
I = 9.
The following code does not work (arguments are not sufficiently instantiated):
I #> 0, indomain(I).
Now I understand that there are in this case an infinite number of possible bindings for I, and that CLPFD works for finite domains as its name suggests.
However I don't understand why this limitation exists in this particular case. Isn't it possible to enumerate possible solutions from smallest to biggest norm, and get the following:
I = 1 ;
I = 2 ;
I = 3 ;
.
.
.
Even for problems where there are more than one variables, say:
0 #< I, I #< J, label([I,J]).
Why wouldn't it be possible to implement it such that the following behavior occurs:
I = 1,
J = 2 ;
I = 1,
J = 3 ;
I = 2,
J = 3 ;
I = 1,
J = 4 ;
.
.
.
In short: why doesn't CLPFD still work for infinite domains if those domains are easily countable using amplitude?
The reason for this is that CLP(FD) preserves the following important property:
If a predicate p(Vs) terminates universally, then ?- p(Vs), label(Vs). also terminates universally.
A goal G terminates universally iff ?- G, false. terminates.
Why is this so important? Because a CLP(FD) program typically consists of two parts:
posting all constraints
the search for solutions.
It is often easy to show, by simple inspection, that the modeling part (1) terminates universally. But (2) is the tough part that usually takes most of the computation time, and often we do not know a priori whether there even is a single solution. The search part may run for days, months or years without yielding results.
Many Prolog beginners describe a search task, run it, and after a few seconds complain that Prolog is slow. In reality, as it turns out, they often accidentally write programs that do not terminate, and can never find a solution.
For such reasons, it is encouraging that if you can only show (as you typically can, and also rather easily) that part (1) terminates, then your whole program—part (1) and part (2)—also terminates.
You are completely right that any countably infinite search space can be systematically covered to any finite extent in one of the ways you are describing. However, doing so would break this fundamental invariant. You must be able to count on the following property for the above reasoning to apply:
label/1, labeling/2 and indomain/1 always terminate.
In SWI-Prolog and YAP, this is ensured by design. In other systems it holds to varying degrees.
There is no reason to not allow infinite domains enumeration in CLP(FD). Since
as user:mat has correctly observed the constraints itself terminate, an infinite enumeration might find a solution if a solution exists.
So basically we have:
The constraints terminate universally, i.e. (#=)/2, (#=<)/2, etc.. give
true or false when completely instantiated, and don't diverge.
And we then observe:
The labeling of constraints terminates existentially, i.e. it finds
a solution to a problem after some time if we can also enumerate multiple
infinite domains in a fair way.
So the main problem is to enumerate multiple infinite domains in a fair way, since when we don't enumerate in a fair way, we might go astray in a subset of the domain and not find a solution even if there exists one. The following approaches to enumerate multiple infinite domains come to mind:
1) Unpair Function
Use a function unpair: N -> NxN, and enumerate the argument of this function only. This is an old Mathematica technique described here: An Elegant Pairing Function . Drawback you need to compute the square root each time.
2) Fair Conjunction
Use a fair conjunction to combine infinite enumerators. This is a technique applied in functional programming, see for example here: Backtracking, Interleaving, and Terminating Monad Transformers . Drawback the connective doesn't work in constant memory space, you spawn more and more instances of the right hand side enumerator.
3) Extra Variable
Use an extra variable H and an extra constraint for example H=abs(X1)+..+abs(Xn) for cantor pairing. You can then enumerate this variable and let the constraint solver do the rest of the work. Advantage for certain values you might have early pruning.
In Jekejeke Minlog we have recently opted for variant 3. Here is an example run to enumerate Pythagorean triples:
?- use_module(library(finite/clpfd)).
?- [X,Y,Z] ins 1..sup, X*X+Y*Y #= Z*Z, label([X,Y,Z]).
X = 3,
Y = 4,
Z = 5 ;
X = 4,
Y = 3,
Z = 5 ;
X = 6,
Y = 8,
Z = 10 ;
X = 8,
Y = 6,
Z = 10
In general when using infinite labeling one will attempt to solve a Diophantine Equation, which do not have always a solution and this is even not decidable, which we know after Hilbert's Tenth problem came up. So a guarantee of universal termination is even not possible.
On the other hand if there is a solution, you might find it after some time, provided the solution is not too big and will exceed the computer limitations in memory space and computation time. But this shouldn't crash your computer, a decent Prolog system implementation should gracefully return to the top-level. You can also interrupt the interpreter or stop demanding further solutions.
Bye
I'm in a bit of pickle in Prolog.
I have a collection of objects. These objects have a certain dimension, hence weight.
I want to split up these objects in 2 sets (which form the entire set together) in such a way that their difference in total weight is minimal.
The first thing I tried was the following (pseudo-code):
-> findall with predicate createSets(List, set(A, B))
-> iterate over results while
---> calculate weight of both
---> calculate difference
---> loop with current difference and compare to current difference
till end of list of sets
This is pretty straightforward. The issue here is that I have a list of +/- 30 objects. Creating all possible sets causes a stack overflow.
Helper predicates:
sublist([],[]).
sublist(X, [_ | RestY]) :-
sublist(X,RestY).
sublist([Item|RestX], [Item|RestY]) :-
sublist(RestX,RestY).
subtract([], _, []) :-
!.
subtract([Head|Tail],ToSubstractList,Result) :-
memberchk(Head,ToSubstractList),
!,
subtract(Tail, ToSubstractList, Result).
subtract([Head|Tail], ToSubstractList, [Head|ResultTail]) :-
!,
subtract(Tail,ToSubstractList,ResultTail).
generateAllPossibleSubsets(ListToSplit,sets(Sublist,SecondPart)) :-
sublist(Sublist,ListToSplit),
subtract(ListToSplit, Sublist, SecondPart).
These can then be used as follows:
:- findall(Set, generateAllPossibleSubsets(ObjectList,Set), ListOfSets ),
findMinimalDifference(ListOfSets,Set).
So because I think this is a wrong way to do it, I figured I'd try it in an iterative way. This is what I have so far:
totalWeightOfSet([],0).
totalWeightOfSet([Head|RestOfSet],Weight) :-
objectWeight(Head,HeadWeight),
totalWeightOfSet(RestOfSet, RestWeight),
Weight is HeadWeight + RestWeight.
findBestBalancedSet(ListOfObjects,Sets) :-
generateAllPossibleSubsets(ListOfObjects,sets(A,B)),
totalWeightOfSet(A,WeightA),
totalWeightOfSet(B,WeightB),
Temp is WeightA - WeightB,
abs(Temp, Difference),
betterSets(ListOfObjects, Difference, Sets).
betterSets(ListOfObjects,OriginalDifference,sets(A,B)) :-
generateAllPossibleSubsets(ListOfObjects,sets(A,B)),
totalWeightOfSet(A,WeightA),
totalWeightOfSet(B,WeightB),
Temp is WeightA - WeightB,
abs(Temp, Difference),
OriginalDifference > Difference,
!,
betterSets(ListOfObjects, Difference, sets(A, B)).
betterSets(_,Difference,sets(A,B)) :-
write_ln(Difference).
The issue here is that it returns a better result, but it hasn't traversed the entire solution tree. I have a feeling this is a default Prolog scheme I'm missing here.
So basically I want it to tell me "these two sets have the minimal difference".
Edit:
What are the pros and cons of using manual list iteration vs recursion through fail
This is a possible solution (the recursion through fail) except that it can not fail, since that won't return the best set.
I would generate the 30 objects list, sort it descending on weight, then pop objects off the sorted list one by one and put each into one or the other of the two sets, so that I get the minimal difference between the two sets on each step. Each time we add an element to a set, just add together their weights, to keep track of the set's weight. Start with two empty sets, each with a total weight of 0.
It won't be the best partition probably, but might come close to it.
A very straightforward implementation:
pair(A,B,A-B).
near_balanced_partition(L,S1,S2):-
maplist(weight,L,W), %// user-supplied predicate weight(+E,?W).
maplist(pair,W,L,WL),
keysort(WL,SL),
reverse(SL,SLR),
partition(SLR,0,[],0,[],S1,S2).
partition([],_,A,_,B,A,B).
partition([N-E|R],N1,L1,N2,L2,S1,S2):-
( abs(N2-N1-N) < abs(N1-N2-N)
-> N3 is N1+N,
partition(R,N3,[E|L1],N2,L2,S1,S2)
; N3 is N2+N,
partition(R,N1,L1,N3,[E|L2],S1,S2)
).
If you insist on finding the precise answer, you will have to generate all the partitions of your list into two sets. Then while generating, you'd keep the current best.
The most important thing left is to find the way to generate them iteratively.
A given object is either included in the first subset, or the second (you don't mention whether they're all different; let's assume they are). We thus have a 30-bit number that represents the partition. This allows us to enumerate them independently, so our state is minimal. For 30 objects there will be 2^30 ~= 10^9 generated partitions.
exact_partition(L,S1,S2):-
maplist(weight,L,W), %// user-supplied predicate weight(+E,?W).
maplist(pair,W,L,WL),
keysort(WL,SL), %// not necessary here except for the aesthetics
length(L,Len), length(Num,Len), maplist(=(0),Num),
.....
You will have to implement the binary arithmetics to add 1 to Num on each step, and generate the two subsets from SL according to the new Num, possibly in one fused operation. For each freshly generated subset, it's easy to calculate its weight (this calculation too can be fused into the same generating operation):
maplist(pair,Ws,_,Subset1),
sumlist(Ws,Weight1),
.....
This binary number, Num, is all that represents our current position in the search space, together with the unchanging list SL. Thus the search will be iterative, i.e. running in constant space.
Given a set of constraints, I would like to efficiently generate the set of values.
Suppose I have a few constraints on my Thungus[1]:
goodThungus(X) :-
X > 100,
X < 1000.
sin(X) = 0.
Now, I can check a Thungus by asking:
goodThungus(500).
I would like to generate all good Thungi. I'm not sure how to do that; I'm really not sure about how to do it efficiently.
Note: this of course has to be a computable generation.
[1] Arbitrary object selected for this example.
What you are asking for can't be done in the full general case: imagine doing f(X) = 0 where f is a function for which the roots cannot be analytically determined, for example. Or suppose f(X) is the function "does the program X halt?". No computer is going to solve that for you.
Your options are basically to either:
Limit the set of constraints to things that you can reason about. e.g. inequalities are good because you can identify ranges, then do intersections and unions on ranges efficiently etc.
Limit the set of values to a small enough number that you can test them individually against each of the constraints
UPDATE: For the kind of constraints stated in the question (ranges of real values and real-valued functions that can be analytically solved and have a finite number of solutions within any range) I would suggest the following approach:
Write a generating function that can iteratively return solutions for you function within a given range... this will need to be done analytically e.g. exploiting the fact that sin(X)=0 implies X=n*pi where n is any integer.
Do interval arithmetic and bounding on your range constraints to work out the range(s) that need to be scanned (in the example you would want the range 100 < X < 1000)
Apply your generating function to each of the target ranges in order to create all of the possible solutions.
I'll preface my suggestion by stating that I'm no expert in using numerical constraint logic programming systems, but here goes...
On the surface, I'd think that solving this kind of problem in PROLOG would be best suited to a numerical constraint logic programming system, perhaps such as CLP(R) (for reals) in SWI-PROLOG; unfortunately, the specific problem you've asked for is seeking to solve for a set of constraints including a non-linear constraint, which seems to be not well or widely supported amongst PROLOG implementations; instead, they seem to deal mainly with linear constraints and often have limited support for non-linear constraints such as X = sin(Y), for example.
Take SWI-PROLOG's CLP(R) library, and the following example program:
:- use_module(library(clpr)).
report_xsq_zeros :-
findall(X, {0 = (X * X) - 10}, Results),
write_ln(Results).
report_sin_zeros :-
findall(X, {0 = sin(X)}, Results),
write_ln(Results).
Now, executing report_xsq_zeros gives us:
?- report_xsq_zeros.
[3.16228, -3.16228]
true.
Here, the system correctly computed the zeros of the quadratic x^2 - 10, which are indeed approximately 3.16228 and -3.16228, where the range of X was unbounded. However, when we execute report_sin_zeros, we get:
?- report_sin_zeros.
[0.0]
true.
We see that the system only computed a single zero of the function sin(X), even though the range of X was indeed also unbounded. Perhaps this is because it is recognized that there are an infinite number of solutions here (though I'm only guessing...). If we were to program what you've asked for:
report_sin_zeros :-
findall(X, {X > 100, X < 1000, 0 = sin(X)}, Results),
write_ln(Results).
We get no results, as the underlying system only computed a single zero for sin(X) as shown earlier (i.e., binding X to 0.0 which lies outside the stated range):
?- report_sin_zeros.
[]
true.
I conclude that I've either not demonstrated proper usage of SWI-PL CLP(R) (I suggest you look into it yourself), or it won't solve your specific (non-linear) problem. Other CLP(R) implementations may behave differently to SWI-PROLOG CLP(R), but I don't have them installed so I can't check, but you could try SICSTUS CLP(R) or others; the syntax looks similar.
He is searching any X in [100..1000] for that sin(x) = 0. But this is a pure mathematical problem, and not meant for relational logical deduction / backtracking. simple Prolog is not suited for this?