A simple hybrid example
Consider the following knapsack problem with an additional non linear constraint: all-different
s.t. 3·x1 + 5·x2 + 2·x3 ≥ 30
all-different(x1, x2, x3)
xj ∈ {1,3,8,12} for j = 1,2,3
A pure and straightforward CP approach for formulating and solving this problem is shown below:
model "Knapsack with side constraints"
uses "kalis"
declarations
x1,x2,x3: cpvar ! Decision variables
benefit : cpvar ! The objective to minimize
end-declarations
! Enable output printing
setparam("kalis_verbose_level", 1)
! Setting name of variables for pretty printing
setname(x1,"x1"); setname(x2,"x2"); setname(x3,"x3")
setname(benefit,"benefit")
! Set initial domains for variables
setdomain(x1, {1,3,8,12})
setdomain(x2, {1,3,8,12})
setdomain(x3, {1,3,8,12})
! Knapsack constraint
3*x1 + 5*x2 + 2*x3 >= 30
! Additional global constraint
all_different({x1,x2,x3})
! Objective function
benefit = 5*x1 + 8*x2 + 4*x3
! Initial propagation
res := cp_propagate
! Display bounds on objective after constraint propagation
writeln("Constraints propagation objective ", benefit)
! Solve the problem
if (cp_minimize(benefit)) then
cp_show_sol ! Output optimal solution to screen
end-if
end-model
This model formulation can be augmented by the definition of a linear relaxation.
We start by getting an automatic relaxation of the problem by a call to the function cp_get_linrelax. The resulting relaxation can be displayed (printed to the standard output) with a call to the procedure cp_show_relax.
From the linear relaxation a linear relaxation solver is built with a call to the get_linrelax_solver method. Note that the KALIS_TOPNODE_RELAX_SOLVER argument passed to the method indicates that we just want to solve the linear relaxation at the top node of the CP search tree.
Having obtained the linear relaxation solver, we need to add it to the search process by a call to cp_add_linrelax_solver. Of course, Xpress Kalis is not limited to one relaxation so several solvers can be defined and added to the search process.
The model definition is completed by specifying a 'MIP style' branching scheme that branches first on the variables with largest reduced cost and tests first the values nearest to the optimal solution of the relaxation. The invocation ot the search and solution display remain the same as in the CP model.
This is the full hybrid model:
model "Knapsack with side constraints"
uses "kalis"
declarations
x1,x2,x3: cpvar ! Decision variables
benefit : cpvar ! The objective to minimize
end-declarations
! Enable output printing
setparam("kalis_verbose_level", 1)
! Setting name of variables for pretty printing
setname(x1,"x1"); setname(x2,"x2"); setname(x3,"x3")
setname(benefit,"benefit")
! Set initial domains for variables
setdomain(x1, {1,3,8,12})
setdomain(x2, {1,3,8,12})
setdomain(x3, {1,3,8,12})
! Knapsack constraint
3*x1 + 5*x2 + 2*x3 >= 30
! Additional global constraint
all_different({x1,x2,x3})
! Objective function
benefit = 5*x1 + 8*x2 + 4*x3
! Initial propagation
res := cp_propagate
! Display bounds on objective after constraint propagation
writeln("Constraints propagation objective ", benefit)
declarations
myrelaxall: cplinrelax
end-declarations
! Build an automatic 'LP' oriented linear relaxation
myrelaxall:= cp_get_linrelax(0)
! Output the relaxation to the screen
cp_show_relax(myrelaxall)
mysolver:= get_linrelax_solver(myrelaxall, benefit, KALIS_MINIMIZE,
KALIS_SOLVE_AS_MIP, KALIS_TOPNODE_RELAX_SOLVER)
! Define the linear relaxation
cp_add_linrelax_solver(mysolver)
! Define a 'MIP' style branching scheme using the solution of the
! optimal relaxation
cp_set_branching(assign_var(KALIS_LARGEST_REDUCED_COST(mysolver),
KALIS_NEAREST_RELAXED_VALUE(mysolver)))
! Solve the problem
if (cp_minimize(benefit)) then
cp_show_sol ! Output optimal solution to screen
end-if
end-model
You will find below the list of relaxation related functions and procedures defined within Xpress Kalis:
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Add a linear relaxation solver to the linear relaxation solver list
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Clear the linear relaxation solver list
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Returns an automatic relaxation of the cp problem
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Remove a linear relaxation solver from the linear relaxation solver list
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Pretty printing of a linear relaxation
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Export the linear relaxation in LP format
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Fix the continuous variables to their optimal value in the relaxation solver passed in argument
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Generate and add cuts to the relaxation passed in parameters
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Get an indicator variable for a given variable and a value.
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Get the linear relaxation for a constraint
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Returns a linear relaxation solver from a linear relaxation, an objective variables and some configuration parameters
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Get a reduced cost value from a linear relaxation solver
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Returns the optimal relaxed value for a variable in a relaxation
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Get a largest reduced cost variable selector from a linear relaxation solver
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Get a nearest relaxed value selector from a linear relaxation solver
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Launch LP/MIP solver without CP branching.
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Set integrality flag for a variable in a linear relaxation
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Parameter setting for a linear relaxation solver.
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Set the verbose level for a specific linear relaxation solver
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