really good csp problems
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Examples
Map coloring Problem Cryptarithmetic N-queens problem Magic sequence Magic square Zebra puzzle Uzbekian puzzle A tiny transportation problem Knapsack problem graceful labeling problem
Map Coloring Problem (MCP)
Given a map and given a set of colors, the problem is how to color the map so that the regions sharing a boundary line don’t have the same color.
Modeling MCP
MCP can be Modeled as a CSP: A set of variables representing the
color of each region The domain of the variables is the set
of the colors used. A set of constraints expressing the fact
that countries that share the same boundary are not colored with the same color.
Modeling (MCP)
Example - Australia Variables = {a,b,c,d,e,f,g} Domain = {red, blue, green} Constraints:
a!=b, a!=c b!=c, b!=d c!=e, c!=f e!=d, e!=f
a
b
c
d
f
e
g
Coding MCP
OPL studio - Ilog Solver: 54 solutions foundenum Country={a,b,c,d,e,f,g};enum Color = {red, green, blue};
var Color color[Country];
solve{ color[a]<>color[b];color[a]<>color[c]; color[b]<>color[c];color[b]<>color[d]; color[c]<>color[e];color[c]<>color[f]; color[e]<>color[d];color[e]<>color[f]; color[b]<>color[c];color[b]<>color[d];};
Coding MCP
ECLiPSe:- lib(fd).coloured(Countries) :- Countries=[A,B,C,D,E,F,G], Countries :: [red,green,blue], ne(A,B), ne(A,C), ne(B,C), ne(B,D), ne(C,E), ne(C,F), ne(E,D), ne(E,F), labeling(Countries).
ne(X,Y) :- X##Y.
Cryptarithmetic
The problem is to find the digits corresponding to the letters involved in the following puzzle:
SEND +
MORE
MONEY
Cryptarithmetic Modeling
A CSP model for Cryptarithmetic problem: Variables={S,E,N,D,M,O,R,Y} Domain={0,1,2,3,4,5,6,7,8,9} Constraints
The variables are all different S!=0, M!=0 S*103+E*102+N*10+D {SEND}
+ M*103+O*102+R*10+E {MORE}= M*104+O*103+N*102+E*10+Y {MONEY}
Coding Cryptarithmetic
OPL Studio - ILog Solver
enum letter = {S,E,N,D,M,O,R,Y};range Digit 0..9;var Digit value[letter];
solve{ alldifferent(value); value[S]<>0; value[M] <>0; value[S]*1000+value[E]*100+value[N]*10+value[D]+ value[M]*1000+value[O]*100+value[R]*10+value[E] = value[M]*10000+value[O]*1000+value[N]*100+value[E]*10+value[Y]};
Coding Cryptarithmetic
ECLiPSe :- lib(fd).
sendmore(Digits) :-
Digits = [S,E,N,D,M,O,R,Y],
Digits :: [0..9],
alldifferent(Digits),
S #\= 0,
M #\= 0,
1000*S + 100*E + 10*N + D
+ 1000*M + 100*O + 10*R + E
#= 10000*M + 1000*O + 100*N + 10*E + Y,
labeling(Digits).
N-Queens Problem
The problem is to put N queens on a board of NxN such that no queen attacks any other queen.
A queen moves vertically, horizontally and diagonally
Modeling N-Queens Problem
The queens problem can be modeling via the following CSP Variables={Q1,Q2,Q3,Q4,...,QN}. Domain={1,2,3,…,N} represents the column
in which the variables can be. Constraints
Queens not on the same row: already taken care off by the good modeling of the variables.
Queens not on the same column: Qi != Qj
Queens not on the same diagonal: |Qi-Qj| != |i-j|
Coding N-Queens Problem OPL Studio - ILog Solver
int n << "number of queens:"; range Domain 1..n;var Domain queens[Domain];solve { alldifferent(queens); forall(ordered i,j in Domain) { abs(queens[i]-queens[j])<> abs(i-j) ; };};
Coding N-Queens Problem ECLiPSe:-lib(fd).nqueens(N, Q):-
length(Q,N),Q::1..N,alldifferent(Q),( fromto(Q, [Q1|Cols], Cols, []) do
( foreach(Q2, Cols), param(Q1), count(Dist,1,_) do Q2 - Q1 #\= Dist, Q1 - Q2 #\= Dist
) ), search(Q).
search([]).search(Q):-
deleteff(Var,Q,R),indomain(Var), search(R).
Magic sequence problem
Given a finite integer n, the problem consists of finding a sequence S = (s0,s1,…,sn), such that si represents the number of occurrences of i in S.
Example: (2, 0, 2, 0) (1,2,1,0)
Modeling MSP
MSP can be modeled by the following CSP variables: s0,s1, …,sn-1
Domain:{0,1,…,n} constraints:
number of occurences of i in (s0,s1, …,sn-1) is si. Redundant constraints:
the sum of s0,s1, …,sn-1 is n the sum of i*Si, i in [0..n-1] is n
Coding MSP OPL - ILog Solver
int n << "Number of Variables:";
range Range 0..n-1;range Domain 0..n;
int value[i in Range ] = i;
var Domain s[Range];solve { distribute(s,value,s); //global constraint s[i]=sum(j in Range)(s[j]=i) sum(i in Range) s[i] = n; //redundant constraint sum(i in Range) s[i]*i = n; //redundant constraint};
Coding MSP
ECLiPSe:- lib(fd). :- lib(fd_global).:- lib(fd_search). solve(N, Sequence) :-
length(Sequence, N), Sequence :: 0..N-1, ( for(I,0,N-1),
foreach(Xi, Sequence), foreach(I, Range), param(Sequence) do
occurrences(I, Sequence, Xi) ), N #= sum(Sequence), % two redundant constraints N #= Sequence*Range, search(Sequence, 0, first_fail, indomain, complete, []).%search procedure
Magic square problem
A magic square of size N is an NxN square filled with the numbers from 1 to N2 such that the sums of each row, each column and the two main diagonals are equal.
Example:
Modeling Magic square pb Magic square problem can be viewed as a CSP with the following properties:
Variables: the elements of the matrix representing the square Domain: 1..N*N Constraints:
magic sum = sum of the columns = sum of the rows = sum of the down diagonal = sum of the up diagonal
Remove symmetries Redundant constraint:
magic sum = N(N2+1)/2
Coding Magic square pb
OPL Studio:int N << "The length of the square:";range Dimension 1..N;range Values 1..N*N;int msum = N*(N*N+1)/2; //magic sumvar Values square[1..N,1..N];
solve { //The elements of the square are all different alldifferent(square); //the sum of the diagonal is magic sum msum = sum(i in Dimension)square[i,i]; //the sum of the up diagonal is magic sum
Coding Magic square pb
msum = sum(i in Dimension)square[i,N-i+1]; //the sum of the rows and columns are all magic sum
forall(i in Dimension){ msum = sum(j in Dimension)square[i,j]; msum = sum(k in Dimension)square[k,i]; }; //remove symmetric behavior of the square square[N,1] < square[1,N]; square[1,1] < square[1,N]; square[1,1] < square[N,N]; square[1,1] < square[N,1];};
Coding Magic square pb
ECLiPSe: :- lib(fd).
magic(N) :-Max is N*N,Magicsum is N*(Max+1)//2,
dim(Square, [N,N]),Square[1..N,1..N] :: 1..Max,Rows is Square[1..N,1..N],flatten(Rows, Vars),alldifferent(Vars),
Coding Magic square pb%constraints on rows
( for(I,1,N), foreach(U,UpDiag), foreach(D,DownDiag), param(N,Square,Sum)do Magicsum #= sum(Square[I,1..N]), Magicsum #= sum(Square[1..N,I]), U is Square[I,I], D is Square[I,N+1-I]),%constraints on diagonalsMagicsum #= sum(UpDiag),Magicsum #= sum(DownDiag),
Coding Magic square pb%remove symmetry
Square[1,1] #< Square[1,N],Square[1,1] #< Square[N,N],Square[1,1] #< Square[N,1],Square[1,N] #< Square[N,1],
%searchlabeling(Vars),print(Square).
Unfortunately, ECLiPSe ran for a long time without providing any answer. ECLiPSe had also the same behavior for a similar code from ECLiPSe website.
A Tiny Transportation problem
How much should be shipped from several sources to several destinations
2222 2222
nnnn
aaaa 1111 bbbb1111 xxxx11111111 1111
aaaa 2222 bbbb 2222
:::: :::: :::: ::::aaaa mmmm bbbb nnnn
xxxx1n1n1n1n xxxx12121212
mmmm
11
Supply Supply cptycpty
Supply Supply cptycpty SourceSourceSourceSource Qty ShippedQty ShippedQty ShippedQty Shipped DestinationDestinationDestinationDestination
Demand Demand Qty Qty
Demand Demand Qty Qty
xxxx22222222xxxx2n2n2n2n
xxxx21212121
A Tiny Transportation problem
3 plants with known capacities, 4 clients with known demands and transport costs per unit between them.
2222 2222
4444
500500500500 1111 200200200200
3333
11
300300300300
4004004004003333
400400400400
300300300300
100100100100
Find qty shipped?Find qty shipped?Find qty shipped?Find qty shipped?
Modeling TTP
TTP can be modeled by a CSP with optimization as follows: Variables: A1,A2,A3,B1,B2,B3,C1, C2, C3,D1,D2,D3 Domain: 0.0..Inf constraints:
Demand constraints:A1+A2+A3=200; B1+B2+B3=400; C1+C2+C3=300; D1+D2+D3=100; Capacity constraints:A1+B1+C1+D1500; A2+B2+C2+D2300; A3+B3+C3+D3400;
Minimization of the objective function:10*A1 + 7*A2 + 11*A3 + 8*B1 + 5*B2 + 10*B3 +
5*C1 + 5*C2 + 8*C3 + 9*D1 + 3*D2 + 7*D3
Coding TTP OPL Studio - Cplex Solver
var float+ productA[Range];var float+ productB[Range];var float+ productC[Range]; var float+ productD[Range];minimize 10*productA[1] + 7*productA[2] + 11*productA[3] + 8*productB[1] + 5*productB[2] + 10*productB[3] + 5*productC[1] + 5*productC[2] + 8*productC[3] + 9*productD[1] + 3*productD[2] + 7*productD[3]subject to { productA[1] + productA[2] + productA[3] = 200; productB[1] + productB[2] + productB[3] = 400; productC[1] + productC[2] + productC[3] = 300; productD[1] + productD[2] + productD[3] = 100; productA[1] + productB[1] + productC[1] + productD[1]<=500 productA[2] + productB[2] + productC[2]+productC[2] <= 300; productA[3] + productB[3] + productC[3] + productD[3] <= 400; };
Coding TTP OPL Studio - Cplex Solver: Solution found
Optimal Solution with Objective Value: 6200.0000productA[1] = 100.0000productA[2] = 0.0000productA[3] = 100.0000
productB[1] = 100.0000productB[2] = 300.0000productB[3] = 0.0000
productC[1] = 300.0000productC[2] = 0.0000productC[3] = 0.0000
productD[1] = 0.0000productD[2] = 100.0000productD[3] = 0.0000
Coding TTP ECLiPSe
:- lib(eplex_cplex).
main1(Cost, Vars) :-
Vars = [A1, A2, A3, B1, B2, B3, C1, C2, C3, D1, D2, D3],
Vars :: 0.0..inf,
A1 + A2 + A3 $= 200, B1 + B2 + B3 $= 400,
C1 + C2 + C3 $= 300, D1 + D2 + D3 $= 100, A1 + B1 + C1 + D1 $=< 500, A2 + B2 + C2 + D2 $=< 300,
A3 + B3 + C3 + D3 $=< 400,optimize(min(10*A1 + 7*A2 + 11*A3 + 8*B1 + 5*B2 + 10*B3 +
5*C1 + 5*C2 + 8*C3 +9*D1 + 3*D2 + 7*D3), Cost).
It didn’t run! calling an undefined procedure cplex_prob_init(…)
Zebra puzzle Zebra is a well known puzzle in which five men with
different nationalities live in the first five house of a street. They practice five distinct professions, and each of them has a favorite animal and a favorite drink, all of them different. The five houses are painted in different colors. The puzzle is to find who owns Zebra.
Zebra puzzle has different statements. We’ll handle two.
This kind of Puzzle is usually treated as an instance of the class of tabular constraint satisfaction problems in which we express the problem using tables.
In this presentation we show how to solve it using CSP languages: OPL studio and ECLiPSe.
Modeling Zebra puzzle In crucial step in Modeling Zebra puzzle is finding the
decision variables. In our case, we consider: variables: persons, colors, pets, drinks, tobaccos. Domain: 1..5 (representing the five houses) Constraints:
Expressed directly from the statement of the puzzle.
Coding Zebra puzzle OPL Studio - ILog Solverenum people {Englishman, Spaniard, Ukrainian, Norwegian, Japanese};enum drinks {coffee, tea, milk, orange, water};enum pets {dog, fox, zebra, horse, snails};enum tabacco {winston, kools, chesterfields, luckyStrike, parliaments };enum colors {ivory, yellow, red , green, blue};range houses 1..5;//{first, second, third, fourth, fifth};
var houses hseClr[colors];var houses hsePple[people];var houses hsePts[pets];var houses hseDrks[drinks];var houses hseTaba[tabacco];
Coding Zebra puzzlesolve{ hsePple[Englishman] = hseClr[red]; hsePple[Spaniard]=hsePts[dog]; hseDrks[coffee] = hseClr[green]; hsePple[Ukrainian] = hseDrks[tea]; hseClr[green] = hseClr[ivory]+1; hseTaba[winston] = hsePts[snails]; hseTaba[kools]=hseClr[yellow]; hseDrks[milk]=3; hsePple[Norwegian] = 1; hseTaba[chesterfields]=hsePts[fox]+1 \/ hseTaba[chesterfields]=hsePts[fox]-
1; hseTaba[kools] = hsePts[horse]+1 \/ hseTaba[kools] = hsePts[horse]-1 ; hseTaba[ luckyStrike] = hseDrks[orange]; hsePple[ Japanese] = hseTaba[parliaments]; hsePple[Norwegian] = hseClr[blue]+1 \/ hsePple[Norwegian] = hseClr[blue]-1; //slient constraints-Global constraint alldifferent alldifferent(hsePple);//forall(ordered i,j in people) hsePple[i] <> hsePple[j]; alldifferent(hsePts);//forall(ordered i,j in pets) hsePts[i] <> hsePts[j]; alldifferent(hseClr);//forall(ordered i,j in colors) hseClr[i] <> hseClr[j]; alldifferent(hseDrks);//forall(ordered i,j in drinks) hseDrks[i] <> hseDrks[j]; alldifferent(hseTaba);//forall(ordered i,j in tabacco) hseTaba[i] <> hseTaba[j];
};
Coding Zebra puzzle% The Englishman lives in a red house.% The Spaniard owns a dog.% The Japanese is a painter.% The Italian drinks tea.% The Norwegian lives in the first house on the left.% The owner of the green house drinks coffee.% The green house is on the right of the white one.% The sculptor breeds snails.% The diplomat lives in the yellow house.% Milk is drunk in the middle house.% The Norwegian's house is next to the blue one.% The violinist drinks fruit juice.% The fox is in a house next to that of the doctor.% The horse is in a house next to that of the diplomat.% % Who owns a Zebra, and who drinks water?%
Coding Zebra puzzle:- lib(fd).
zebra :-
% we use 5 lists of 5 variables eachNat = [English, Spaniard, Japanese, Italian, Norwegian],Color = [Red, Green, White, Yellow, Blue],Profession = [Painter, Sculptor, Diplomat, Violinist, Doctor],Pet = [Dog, Snails, Fox, Horse, Zebra],Drink = [Tea, Coffee, Milk, Juice, Water],
% domains: all the variables range over house numbers 1 to 5Nat :: 1..5,Color :: 1..5,Profession :: 1..5,Pet :: 1..5,Drink :: 1..5,
Coding Zebra puzzle% the values in each list are exclusive
alldifferent(Nat),
alldifferent(Color),
alldifferent(Profession),
alldifferent(Pet),
alldifferent(Drink),
% and here follow the actual constraints
English = Red, Spaniard = Dog,
Japanese = Painter, Italian = Tea,
Norwegian = 1, Green = Coffee,
Green #= White + 1, Sculptor = Snails,
Diplomat = Yellow, Milk = 3,
Dist1 #= Norwegian - Blue, Dist1 :: [-1, 1],
Violinist = Juice,
Dist2 #= Fox - Doctor, Dist2 :: [-1, 1],
Dist3 #= Horse - Diplomat, Dist3 :: [-1, 1],
Coding Zebra puzzle% put all the variables in a single list
flatten([Nat, Color, Profession, Pet, Drink], List),
% search: label all variables with valueslabeling(List),
% print the answers: we need to do some decodingNatNames = [English-english, Spaniard-spaniard, Japanese-japanese,
Italian-italian, Norwegian-norwegian],memberchk(Zebra-ZebraNat, NatNames),memberchk(Water-WaterNat, NatNames),printf("The %w owns the zebra%n", [ZebraNat]),printf("The %w drinks water%n", [WaterNat]).
Answer from ECLiPSe after 0.02sThe japanese owns the zebraThe norwegian drinks water
Uzbekian Puzzle An uzbekian sales man met five traders who live in five
different cities. The five traders are: {Abdulhamid, Kurban,Ruza, Sharaf, Usman}
The five cities are : {Bukhara, Fergana, Kokand, Samarkand, Tashkent}
Find the order in which he visited the cities given the following information:
He met Ruza before Sharaf after visiting Samarkand, He reached Fergana after visiting Samarkand followed by other two
cities, The third trader he met was Tashkent, Immediately after his visit to Bukhara, he met Abdulhamid He reached Kokand after visiting the city of Kurban followed by other
two cities;
Modeling Uzbekian Puzzle
The uzbekian puzzle can formulated within the CSP framework as follows: Variables: order in which he visited each city and met each
trader Domain:1..5 constraints:
He met Ruza before Sharaf after visiting Samarkand, He reached Fergana after visiting Samarkand followed by other two
cities, The third trader he met was Tashkent, Immediately after his visit to Bukhara, he met Abdulhamid He reached Kokand after visiting the city of Kurban followed by
other two cities;
Coding Uzbekian Puzzle in OPL
enum cities {Bukhara, Fergana, Kokand, Samarkand, Tashkent};enum traders {Abdulhamid, Kurban, Ruza, Sharaf, Usman};range order 1..5;var order mtTrader[traders];var order vstCty[cities];solve{ mtTrader[Ruza] < mtTrader[Sharaf]; mtTrader[Ruza] > vstCty[Samarkand]; vstCty[Fergana] = vstCty[Samarkand] + 2; vstCty[Tashkent] = 3; mtTrader[Abdulhamid] = vstCty[Bukhara] + 1; vstCty[Kokand] = mtTrader[Kurban] + 2; alldifferent(mtTrader); alldifferent(vstCty);};
Solution [1]
mtTrader[Abdulhamid] = 2mtTrader[Kurban] = 3mtTrader[Ruza] = 4mtTrader[Sharaf] = 5mtTrader[Usman] = 1
vstCty[Bukhara] = 1vstCty[Fergana] = 4vstCty[Kokand] = 5vstCty[Samarkand] = 2vstCty[Tashkent] = 3
Knapsack problem We have a knapsack with a fixed capacity and a
number of items. Each item has a weight and a value. The problem consists of filling the knapsack without exceeding its capacity, while maximizing the overall value of its contents.
Knapsack problem is an example of Mixed integer programming.
Modeling Knapsack problem
A CSP model for knapsack problem is given by: Variables: For each item, we associate a variable that gives
the quantity of such an item we can put in the knapsack. Domain: 0..Capacity of the knapsack Constraints:
sum of the weights in the knapsack is less than the capacity
Objective function to maximize: sum of the values in the knapsack
Coding Knapsack Pb in OPL
range items 1..10;int MaxCapacity= 1000;int value[items] = [29,30,25,27, 28,21,23,19,18,17];int weight[items] =[30,32,33,31,34,40,45,44,39,35];var int take[items] in 0..MaxCapacity;
maximize sum(i in items) value[i] * take[i]subject to sum(i in items) weight[i] * take[i] <= MaxCapacity;
integer programming (CPLEX MIP)displaying solution ...
take[1] = 28 take[2] = 5 take[i] = 0, i=3..10
Graceful labeling problem Given a tree T with m+1 nodes, and m edges, find
the possible labels in {0,1,…,m} for the nodes such that the absolute value of the difference of the labels of the nodes related to each edge are all different.
Formally, let f be a function from V ----> {0,…,m}, where V is the set of the vertices of T. f is said to be a graceful labeling of T iff
|f(vi)-f(vj)| are all different for any edge vivj in T.
Modeling Graceful labeling Pb
Graceful labeling problem can be formulated into the following CSP: variables: labels to put on each node of T Domain: 0..m constraints:
the absolute value of the difference between the labels of any edge are all different
Coding Graceful labeling Pb
OPL program for graceful labeling problemint nbreOfNodes = ...;//set the range of the labels of the nodesrange nodes 0..nbreOfNodes-1; range indices 1..nbreOfNodes; int adjacencyMatrix[indices, indices] = ...;var nodes label[indices];solve { alldifferent(label); forall(ordered i, j in indices){ if(adjacencyMatrix[i,j] <> 0) then forall(ordered k, h in indices){ if(adjacencyMatrix[k,h] <> 0 & not(k=i & h=j)) then abs(label[i]-label[j])<>abs(label[h]-label[k]) endif; } endif; };};
Coding Graceful labeling Pb
Data filenbreOfNodes = 7;adjacencyMatrix = [[ 0, 1, 0, 0, 0, 0, 0], [ 1, 0, 1, 0, 0, 0, 0 ], [ 0, 1, 0, 1, 0, 1, 0 ], [ 0, 0, 1, 0, 1, 0, 0 ], [ 0, 0, 0, 1, 0, 0, 0 ], [ 0, 0, 1, 0, 0, 0, 1 ], [ 0, 0, 0, 0, 0, 1, 0 ]];
Solution Example:
label[1] = 0label[2] = 6label[3] = 1label[4] = 3label[5] = 4label[6] = 5label[7] = 2
1
3
75
4 6
2
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