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ortools-clone/ortools/linear_solver/linear_solver.h
Laurent Perron f282db4d48 fix crash on scip solve
2019-10-21 16:50:12 +02:00

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// Copyright 2010-2018 Google LLC
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
/**
* \file
* A C++ wrapper that provides a simple and unified interface to
* several linear programming and mixed integer programming solvers:
* GLOP, GLPK, CLP, CBC, and SCIP. The wrapper can also be used in Java, C#,
* and Python via SWIG.
*
* What is Linear Programming?
*
* In mathematics, linear programming (LP) is a technique for optimization of
* a linear objective function, subject to linear equality and linear
* inequality constraints. Informally, linear programming determines the way
* to achieve the best outcome (such as maximum profit or lowest cost) in a
* given mathematical model and given some list of requirements represented
* as linear equations.
*
* The most widely used technique for solving a linear program is the Simplex
* algorithm, devised by George Dantzig in 1947. It performs very well on
* most instances, for which its running time is polynomial. A lot of effort
* has been put into improving the algorithm and its implementation. As a
* byproduct, it has however been shown that one can always construct
* problems that take exponential time for the Simplex algorithm to solve.
* Research has thus focused on trying to find a polynomial algorithm for
* linear programming, or to prove that linear programming is indeed
* polynomial.
*
* Leonid Khachiyan first exhibited in 1979 a weakly polynomial algorithm for
* linear programming. "Weakly polynomial" means that the running time of the
* algorithm is in O(P(n) * 2^p) where P(n) is a polynomial of the size of the
* problem, and p is the precision of computations expressed in number of
* bits. With a fixed-precision, floating-point-based implementation, a weakly
* polynomial algorithm will thus run in polynomial time. No implementation
* of Khachiyan's algorithm has proved efficient, but a larger breakthrough in
* the field came in 1984 when Narendra Karmarkar introduced a new interior
* point method for solving linear programming problems. Interior point
* algorithms have proved efficient on very large linear programs.
*
* Check Wikipedia for more detail:
* http://en.wikipedia.org/wiki/Linear_programming
*
* -----------------------------------
*
* Example of a Linear Program
*
* maximize:
* 3x + y
* subject to:
* 1.5 x + 2 y <= 12
* 0 <= x <= 3
* 0 <= y <= 5
*
* A linear program has:
* 1) a linear objective function
* 2) linear constraints that can be equalities or inequalities
* 3) bounds on variables that can be positive, negative, finite or
* infinite.
*
* -----------------------------------
*
* What is Mixed Integer Programming?
*
* Here, the constraints and the objective are still linear but
* there are additional integrality requirements for variables. If
* all variables are required to take integer values, then the
* problem is called an integer program (IP). In most cases, only
* some variables are required to be integer and the rest of the
* variables are continuous: this is called a mixed integer program
* (MIP). IPs and MIPs are generally NP-hard.
*
* Integer variables can be used to model discrete decisions (build a
* datacenter in city A or city B), logical relationships (only
* place machines in datacenter A if we have decided to build
* datacenter A) and approximate non-linear functions with piecewise
* linear functions (for example, the cost of machines as a function
* of how many machines are bought, or the latency of a server as a
* function of its load).
*
* -----------------------------------
*
* How to use the wrapper
*
* The user builds the model and solves it through the MPSolver class,
* then queries the solution through the MPSolver, MPVariable and
* MPConstraint classes. To be able to query a solution, you need the
* following:
* - A solution exists: MPSolver::Solve has been called and a solution
* has been found.
* - The model has not been modified since the last time
* MPSolver::Solve was called. Otherwise, the solution obtained
* before the model modification may not longer be feasible or
* optimal.
*
* @see ../examples/linear_programming.cc for a simple LP example.
*
* @see ../examples/integer_programming.cc for a simple MIP example.
*
* All methods cannot be called successfully in all cases. For
* example: you cannot query a solution when no solution exists, you
* cannot query a reduced cost value (which makes sense only on
* continuous problems) on a discrete problem. When a method is
* called in an unsuitable context, it aborts with a
* LOG(FATAL).
* TODO(user): handle failures gracefully.
*
* -----------------------------------
*
* For developers: How the wrapper works
*
* MPSolver stores a representation of the model (variables,
* constraints and objective) in its own data structures and a
* pointer to a MPSolverInterface that wraps the underlying solver
* (GLOP, CBC, CLP, GLPK, or SCIP) that does the actual work. The
* underlying solver also keeps a representation of the model in its
* own data structures. The model representations in MPSolver and in
* the underlying solver are kept in sync by the 'extraction'
* mechanism: synchronously for some changes and asynchronously
* (when MPSolver::Solve is called) for others. Synchronicity
* depends on the modification applied and on the underlying solver.
*/
#ifndef OR_TOOLS_LINEAR_SOLVER_LINEAR_SOLVER_H_
#define OR_TOOLS_LINEAR_SOLVER_LINEAR_SOLVER_H_
#include <functional>
#include <limits>
#include <map>
#include <memory>
#include <string>
#include <utility>
#include <vector>
#include "absl/container/flat_hash_map.h"
#include "absl/strings/match.h"
#include "absl/strings/str_format.h"
#include "absl/types/optional.h"
#include "ortools/base/commandlineflags.h"
#include "ortools/base/integral_types.h"
#include "ortools/base/logging.h"
#include "ortools/base/macros.h"
#include "ortools/base/status.h"
#include "ortools/base/timer.h"
#include "ortools/linear_solver/linear_expr.h"
#include "ortools/linear_solver/linear_solver.pb.h"
#include "ortools/port/proto_utils.h"
namespace operations_research {
constexpr double kDefaultPrimalTolerance = 1e-07;
class MPConstraint;
class MPObjective;
class MPSolverInterface;
class MPSolverParameters;
class MPVariable;
/**
* This mathematical programming (MP) solver class is the main class
* though which users build and solve problems.
*/
class MPSolver {
public:
/**
* The type of problems (LP or MIP) that will be solved and the underlying
* solver (GLOP, GLPK, CLP, CBC or SCIP) that will solve them. This must
* remain consistent with MPModelRequest::OptimizationProblemType
* (take particular care of the open-source version).
*/
enum OptimizationProblemType {
#ifdef USE_CLP
/// Linear Programming solver using Coin CBC.
CLP_LINEAR_PROGRAMMING = 0,
#endif
#ifdef USE_GLPK
/// Linear Programming solver using GLPK.
GLPK_LINEAR_PROGRAMMING = 1,
#endif
/// Linear Programming solver using GLOP (Recommended solver).
GLOP_LINEAR_PROGRAMMING = 2,
#ifdef USE_GUROBI
/// Linear Programming solver using GUROBI.
GUROBI_LINEAR_PROGRAMMING = 6,
#endif
#ifdef USE_CPLEX
/// Linear Programming solver using CPLEX.
CPLEX_LINEAR_PROGRAMMING = 10,
#endif
// Integer programming problems.
#ifdef USE_SCIP
/// Mixed integer Programming Solver using SCIP.
SCIP_MIXED_INTEGER_PROGRAMMING = 3, // Recommended default value.
#endif
#ifdef USE_GLPK
/// Mixed integer Programming Solver using SCIP.
GLPK_MIXED_INTEGER_PROGRAMMING = 4,
#endif
#ifdef USE_CBC
/// Mixed integer Programming Solver using Coin CBC.
CBC_MIXED_INTEGER_PROGRAMMING = 5,
#endif
#if defined(USE_GUROBI)
/// Mixed integer Programming Solver using GUROBI.
GUROBI_MIXED_INTEGER_PROGRAMMING = 7,
#endif
#if defined(USE_CPLEX)
/// Mixed integer Programming Solver using CPLEX.
CPLEX_MIXED_INTEGER_PROGRAMMING = 11,
#endif
/// Linear Boolean Programming Solver.
BOP_INTEGER_PROGRAMMING = 12,
/// SAT based solver (requires only integer and Boolean variables).
/// If you pass it mixed integer problems, it will scale coefficients to
/// integer values, and solve continuous variables as integral variables.
SAT_INTEGER_PROGRAMMING = 14,
#if defined(USE_XPRESS)
XPRESS_LINEAR_PROGRAMMING = 101,
XPRESS_MIXED_INTEGER_PROGRAMMING = 102,
#endif
};
/// Create a solver with the given name and underlying solver backend.
MPSolver(const std::string& name, OptimizationProblemType problem_type);
virtual ~MPSolver();
/**
* Whether the given problem type is supported (this will depend on the
* targets that you linked).
*/
static bool SupportsProblemType(OptimizationProblemType problem_type);
/**
* Parses the name of the solver. Returns true if the solver type is
* successfully parsed as one of the OptimizationProblemType.
*/
static bool ParseSolverType(absl::string_view solver,
OptimizationProblemType* type);
bool IsMIP() const;
/// Returns the name of the model set at construction.
const std::string& Name() const {
return name_; // Set at construction.
}
/// Returns the optimization problem type set at construction.
virtual OptimizationProblemType ProblemType() const {
return problem_type_; // Set at construction.
}
/**
* Clears the objective (including the optimization direction), all variables
* and constraints. All the other properties of the MPSolver (like the time
* limit) are kept untouched.
*/
void Clear();
/// Returns the number of variables.
int NumVariables() const { return variables_.size(); }
/**
* Returns the array of variables handled by the MPSolver. (They are listed in
* the order in which they were created.)
*/
const std::vector<MPVariable*>& variables() const { return variables_; }
/**
* Looks up a variable by name, and returns nullptr if it does not exist. The
* first call has a O(n) complexity, as the variable name index is lazily
* created upon first use. Will crash if variable names are not unique.
*/
MPVariable* LookupVariableOrNull(const std::string& var_name) const;
/**
* Creates a variable with the given bounds, integrality requirement and
* name. Bounds can be finite or +/- MPSolver::infinity(). The MPSolver owns
* the variable (i.e. the returned pointer is borrowed). Variable names are
* optional. If you give an empty name, name() will auto-generate one for you
* upon request.
*/
MPVariable* MakeVar(double lb, double ub, bool integer,
const std::string& name);
/// Creates a continuous variable.
MPVariable* MakeNumVar(double lb, double ub, const std::string& name);
/// Creates an integer variable.
MPVariable* MakeIntVar(double lb, double ub, const std::string& name);
/// Creates a boolean variable.
MPVariable* MakeBoolVar(const std::string& name);
/**
* Creates an array of variables. All variables created have the same bounds
* and integrality requirement. If nb <= 0, no variables are created, the
* function crashes in non-opt mode.
*
* @param nb the number of variables to create.
* @param lb the lower bound of created variables
* @param ub the upper bound of created variables
* @param integer controls whether the created variables are continuous or
* integral.
* @param name_prefix the prefix of the variable names. Variables are named
* name_prefix0, name_prefix1, ...
* @param[out] vars the vector of variables to fill with variables.
*/
void MakeVarArray(int nb, double lb, double ub, bool integer,
const std::string& name_prefix,
std::vector<MPVariable*>* vars);
/// Creates an array of continuous variables.
void MakeNumVarArray(int nb, double lb, double ub, const std::string& name,
std::vector<MPVariable*>* vars);
/// Creates an array of integer variables.
void MakeIntVarArray(int nb, double lb, double ub, const std::string& name,
std::vector<MPVariable*>* vars);
/// Creates an array of boolean variables.
void MakeBoolVarArray(int nb, const std::string& name,
std::vector<MPVariable*>* vars);
/// Returns the number of constraints.
int NumConstraints() const { return constraints_.size(); }
/**
* Returns the array of constraints handled by the MPSolver.
*
* They are listed in the order in which they were created.
*/
const std::vector<MPConstraint*>& constraints() const { return constraints_; }
/**
* Looks up a constraint by name, and returns nullptr if it does not exist.
*
* The first call has a O(n) complexity, as the constraint name index is
* lazily created upon first use. Will crash if constraint names are not
* unique.
*/
MPConstraint* LookupConstraintOrNull(
const std::string& constraint_name) const;
/**
* Creates a linear constraint with given bounds.
*
* Bounds can be finite or +/- MPSolver::infinity(). The MPSolver class
* assumes ownership of the constraint.
*
* @return a pointer to the newly created constraint.
*/
MPConstraint* MakeRowConstraint(double lb, double ub);
/// Creates a constraint with -infinity and +infinity bounds.
MPConstraint* MakeRowConstraint();
/// Creates a named constraint with given bounds.
MPConstraint* MakeRowConstraint(double lb, double ub,
const std::string& name);
/// Creates a named constraint with -infinity and +infinity bounds.
MPConstraint* MakeRowConstraint(const std::string& name);
/**
* Creates a constraint owned by MPSolver enforcing:
* range.lower_bound() <= range.linear_expr() <= range.upper_bound()
*/
MPConstraint* MakeRowConstraint(const LinearRange& range);
/// As above, but also names the constraint.
MPConstraint* MakeRowConstraint(const LinearRange& range,
const std::string& name);
/**
* Returns the objective object.
*
* Note that the objective is owned by the solver, and is initialized to its
* default value (see the MPObjective class below) at construction.
*/
const MPObjective& Objective() const { return *objective_; }
/// Returns the mutable objective object.
MPObjective* MutableObjective() { return objective_.get(); }
/**
* The status of solving the problem. The straightforward translation to
* homonymous enum values of MPSolverResponseStatus (see
* ./linear_solver.proto) is guaranteed by ./enum_consistency_test.cc, you may
* rely on it.
*/
enum ResultStatus {
/// optimal.
OPTIMAL,
/// feasible, or stopped by limit.
FEASIBLE,
/// proven infeasible.
INFEASIBLE,
/// proven unbounded.
UNBOUNDED,
/// abnormal, i.e., error of some kind.
ABNORMAL,
/// the model is trivially invalid (NaN coefficients, etc).
MODEL_INVALID,
/// not been solved yet.
NOT_SOLVED = 6
};
/// Solves the problem using default parameter values.
ResultStatus Solve();
/// Solves the problem using the specified parameter values.
ResultStatus Solve(const MPSolverParameters& param);
/**
* Writes the model using the solver internal write function. Currently only
* available for Gurobi.
*/
void Write(const std::string& file_name);
/**
* Advanced usage: compute the "activities" of all constraints, which are the
* sums of their linear terms. The activities are returned in the same order
* as constraints(), which is the order in which constraints were added; but
* you can also use MPConstraint::index() to get a constraint's index.
*/
std::vector<double> ComputeConstraintActivities() const;
/**
* Advanced usage: Verifies the *correctness* of the solution.
*
* It verifies that all variables must be within their domains, all
* constraints must be satisfied, and the reported objective value must be
* accurate.
*
* Usage:
* - This can only be called after Solve() was called.
* - "tolerance" is interpreted as an absolute error threshold.
* - For the objective value only, if the absolute error is too large,
* the tolerance is interpreted as a relative error threshold instead.
* - If "log_errors" is true, every single violation will be logged.
* - If "tolerance" is negative, it will be set to infinity().
*
* Most users should just set the --verify_solution flag and not bother using
* this method directly.
*/
bool VerifySolution(double tolerance, bool log_errors) const;
/**
* Advanced usage: resets extracted model to solve from scratch.
*
* This won't reset the parameters that were set with
* SetSolverSpecificParametersAsString() or set_time_limit() or even clear the
* linear program. It will just make sure that next Solve() will be as if
* everything was reconstructed from scratch.
*/
void Reset();
/** Interrupts the Solve() execution to terminate processing if possible.
*
* If the underlying interface supports interruption; it does that and returns
* true regardless of whether there's an ongoing Solve() or not. The Solve()
* call may still linger for a while depending on the conditions. If
* interruption is not supported; returns false and does nothing.
*/
bool InterruptSolve();
/**
* Loads model from protocol buffer.
*
* Returns MPSOLVER_MODEL_IS_VALID if the model is valid, and another status
* otherwise (currently only MPSOLVER_MODEL_INVALID and MPSOLVER_INFEASIBLE).
* If the model isn't valid, populates "error_message".
*/
MPSolverResponseStatus LoadModelFromProto(const MPModelProto& input_model,
std::string* error_message);
/**
* Loads model from protocol buffer.
*
* The same as above, except that the loading keeps original variable and
* constraint names. Caller should make sure that all variable names and
* constraint names are unique, respectively.
*/
MPSolverResponseStatus LoadModelFromProtoWithUniqueNamesOrDie(
const MPModelProto& input_model, std::string* error_message);
/// Encodes the current solution in a solution response protocol buffer.
void FillSolutionResponseProto(MPSolutionResponse* response) const;
/**
* Solves the model encoded by a MPModelRequest protocol buffer and fills the
* solution encoded as a MPSolutionResponse.
*
* Note(user): This creates a temporary MPSolver and destroys it at the end.
* If you want to keep the MPSolver alive (for debugging, or for incremental
* solving), you should write another version of this function that creates
* the MPSolver object on the heap and returns it.
*/
static void SolveWithProto(const MPModelRequest& model_request,
MPSolutionResponse* response);
/// Exports model to protocol buffer.
void ExportModelToProto(MPModelProto* output_model) const;
/**
* Load a solution encoded in a protocol buffer onto this solver for easy
access via the MPSolver interface.
*
* IMPORTANT: This may only be used in conjunction with ExportModel(),
following this example:
*
\code
MPSolver my_solver;
... add variables and constraints ...
MPModelProto model_proto;
my_solver.ExportModelToProto(&model_proto);
MPSolutionResponse solver_response;
MPSolver::SolveWithProto(model_proto, &solver_response);
if (solver_response.result_status() == MPSolutionResponse::OPTIMAL) {
CHECK_OK(my_solver.LoadSolutionFromProto(solver_response));
... inspect the solution using the usual API: solution_value(), etc...
}
\endcode
*
* The response must be in OPTIMAL or FEASIBLE status.
*
* Returns a non-OK status if a problem arised (typically, if it wasn't used
* like it should be):
* - loading a solution whose variables don't correspond to the solver's
* current variables
* - loading a solution with a status other than OPTIMAL / FEASIBLE.
*
* Note: the objective value isn't checked. You can use VerifySolution() for
* that.
*/
util::Status LoadSolutionFromProto(
const MPSolutionResponse& response,
double tolerance = kDefaultPrimalTolerance);
/**
* Resets values of out of bound variables to the corresponding bound and
* returns an error if any of the variables have NaN value.
*/
util::Status ClampSolutionWithinBounds();
/**
* Shortcuts to the homonymous MPModelProtoExporter methods, via exporting to
* a MPModelProto with ExportModelToProto() (see above).
*
* Produces empty std::string on portable platforms (e.g. android, ios).
*/
bool ExportModelAsLpFormat(bool obfuscate, std::string* model_str) const;
bool ExportModelAsMpsFormat(bool fixed_format, bool obfuscate,
std::string* model_str) const;
/**
* Sets the number of threads to use by the underlying solver.
*
* Returns OkStatus if the operation was successful. num_threads must be equal
* to or greater than 1. Note that the behaviour of this call depends on the
* underlying solver. E.g., it may set the exact number of threads or the max
* number of threads (check the solver's interface implementation for
* details). Also, some solvers may not (yet) support this function, but still
* enable multi-threading via SetSolverSpecificParametersAsString().
*/
util::Status SetNumThreads(int num_threads);
/// Returns the number of threads to be used during solve.
int GetNumThreads() const { return num_threads_; }
/**
* Advanced usage: pass solver specific parameters in text format.
*
* The format is solver-specific and is the same as the corresponding solver
* configuration file format. Returns true if the operation was successful.
*/
bool SetSolverSpecificParametersAsString(const std::string& parameters);
std::string GetSolverSpecificParametersAsString() const {
return solver_specific_parameter_string_;
}
/**
* Sets a hint for solution.
*
* If a feasible or almost-feasible solution to the problem is already known,
* it may be helpful to pass it to the solver so that it can be used. A solver
* that supports this feature will try to use this information to create its
* initial feasible solution.
*
* Note: It may not always be faster to give a hint like this to the
* solver. There is also no guarantee that the solver will use this hint or
* try to return a solution "close" to this assignment in case of multiple
* optimal solutions.
*/
void SetHint(std::vector<std::pair<const MPVariable*, double> > hint);
/**
* Advanced usage: possible basis status values for a variable and the slack
* variable of a linear constraint.
*/
enum BasisStatus {
FREE = 0,
AT_LOWER_BOUND,
AT_UPPER_BOUND,
FIXED_VALUE,
BASIC
};
/**
* Advanced usage: Incrementality.
*
* This function takes a starting basis to be used in the next LP Solve()
* call. The statuses of a current solution can be retrieved via the
* basis_status() function of a MPVariable or a MPConstraint.
*
* WARNING: With Glop, you should disable presolve when using this because
* this information will not be modified in sync with the presolve and will
* likely not mean much on the presolved problem.
*/
void SetStartingLpBasis(
const std::vector<MPSolver::BasisStatus>& variable_statuses,
const std::vector<MPSolver::BasisStatus>& constraint_statuses);
/**
* Infinity.
*
* You can use -MPSolver::infinity() for negative infinity.
*/
static double infinity() { return std::numeric_limits<double>::infinity(); }
/**
* Controls (or queries) the amount of output produced by the underlying
* solver. The output can surface to LOGs, or to stdout or stderr, depending
* on the implementation. The amount of output will greatly vary with each
* implementation and each problem.
*
* Output is suppressed by default.
*/
bool OutputIsEnabled() const;
/// Enables solver logging.
void EnableOutput();
/// Suppresses solver logging.
void SuppressOutput();
absl::Duration TimeLimit() const { return time_limit_; }
void SetTimeLimit(absl::Duration time_limit) {
DCHECK_GE(time_limit, absl::ZeroDuration());
time_limit_ = time_limit;
}
absl::Duration DurationSinceConstruction() const {
return absl::Now() - construction_time_;
}
/// Returns the number of simplex iterations.
int64 iterations() const;
/**
* Returns the number of branch-and-bound nodes evaluated during the solve.
*
* Only available for discrete problems.
*/
int64 nodes() const;
/// Returns a std::string describing the underlying solver and its version.
std::string SolverVersion() const;
/**
* Advanced usage: returns the underlying solver.
*
* Returns the underlying solver so that the user can use solver-specific
* features or features that are not exposed in the simple API of MPSolver.
* This method is for advanced users, use at your own risk! In particular, if
* you modify the model or the solution by accessing the underlying solver
* directly, then the underlying solver will be out of sync with the
* information kept in the wrapper (MPSolver, MPVariable, MPConstraint,
* MPObjective). You need to cast the void* returned back to its original type
* that depends on the interface (CBC: OsiClpSolverInterface*, CLP:
* ClpSimplex*, GLPK: glp_prob*, SCIP: SCIP*).
*/
void* underlying_solver();
/** Advanced usage: computes the exact condition number of the current scaled
* basis: L1norm(B) * L1norm(inverse(B)), where B is the scaled basis.
*
* This method requires that a basis exists: it should be called after Solve.
* It is only available for continuous problems. It is implemented for GLPK
* but not CLP because CLP does not provide the API for doing it.
*
* The condition number measures how well the constraint matrix is conditioned
* and can be used to predict whether numerical issues will arise during the
* solve: the model is declared infeasible whereas it is feasible (or
* vice-versa), the solution obtained is not optimal or violates some
* constraints, the resolution is slow because of repeated singularities.
*
* The rule of thumb to interpret the condition number kappa is:
* - o kappa <= 1e7: virtually no chance of numerical issues
* - o 1e7 < kappa <= 1e10: small chance of numerical issues
* - o 1e10 < kappa <= 1e13: medium chance of numerical issues
* - o kappa > 1e13: high chance of numerical issues
*
* The computation of the condition number depends on the quality of the LU
* decomposition, so it is not very accurate when the matrix is ill
* conditioned.
*/
double ComputeExactConditionNumber() const;
/**
* Some solvers (MIP only, not LP) can produce multiple solutions to the
* problem. Returns true when another solution is available, and updates the
* MPVariable* objects to make the new solution queryable. Call only after
* calling solve.
*
* The optimality properties of the additional solutions found, and whether or
* not the solver computes them ahead of time or when NextSolution() is called
* is solver specific.
*
* As of 2018-08-09, only Gurobi supports NextSolution(), see
* linear_solver_underlying_gurobi_test for an example of how to configure
* Gurobi for this purpose. The other solvers return false unconditionally.
*/
ABSL_MUST_USE_RESULT bool NextSolution();
// DEPRECATED: Use TimeLimit() and SetTimeLimit(absl::Duration) instead.
// NOTE: These deprecated functions used the convention time_limit = 0 to mean
// "no limit", which now corresponds to time_limit_ = InfiniteDuration().
int64 time_limit() const {
return time_limit_ == absl::InfiniteDuration()
? 0
: absl::ToInt64Milliseconds(time_limit_);
}
void set_time_limit(int64 time_limit_milliseconds) {
SetTimeLimit(time_limit_milliseconds == 0
? absl::InfiniteDuration()
: absl::Milliseconds(time_limit_milliseconds));
}
double time_limit_in_secs() const {
return static_cast<double>(time_limit()) / 1000.0;
}
// DEPRECATED: Use DurationSinceConstruction() instead.
int64 wall_time() const {
return absl::ToInt64Milliseconds(DurationSinceConstruction());
}
friend class GLPKInterface;
friend class CLPInterface;
friend class CBCInterface;
friend class SCIPInterface;
friend class GurobiInterface;
friend class CplexInterface;
friend class XpressInterface;
friend class SLMInterface;
friend class MPSolverInterface;
friend class GLOPInterface;
friend class BopInterface;
friend class SatInterface;
friend class KnapsackInterface;
// Debugging: verify that the given MPVariable* belongs to this solver.
bool OwnsVariable(const MPVariable* var) const;
private:
// Computes the size of the constraint with the largest number of
// coefficients with index in [min_constraint_index,
// max_constraint_index)
int ComputeMaxConstraintSize(int min_constraint_index,
int max_constraint_index) const;
// Returns true if the model has constraints with lower bound > upper bound.
bool HasInfeasibleConstraints() const;
// Returns true if the model has at least 1 integer variable.
bool HasIntegerVariables() const;
// Generates the map from variable names to their indices.
void GenerateVariableNameIndex() const;
// Generates the map from constraint names to their indices.
void GenerateConstraintNameIndex() const;
// The name of the linear programming problem.
const std::string name_;
// The type of the linear programming problem.
const OptimizationProblemType problem_type_;
// The solver interface.
std::unique_ptr<MPSolverInterface> interface_;
// The vector of variables in the problem.
std::vector<MPVariable*> variables_;
// A map from a variable's name to its index in variables_.
mutable absl::optional<absl::flat_hash_map<std::string, int> >
variable_name_to_index_;
// Whether variables have been extracted to the underlying interface.
std::vector<bool> variable_is_extracted_;
// The vector of constraints in the problem.
std::vector<MPConstraint*> constraints_;
// A map from a constraint's name to its index in constraints_.
mutable absl::optional<absl::flat_hash_map<std::string, int> >
constraint_name_to_index_;
// Whether constraints have been extracted to the underlying interface.
std::vector<bool> constraint_is_extracted_;
// The linear objective function.
std::unique_ptr<MPObjective> objective_;
// Initial values for all or some of the problem variables that can be
// exploited as a starting hint by a solver.
//
// Note(user): as of 05/05/2015, we can't use >> because of some SWIG errors.
//
// TODO(user): replace by two vectors, a std::vector<bool> to indicate if a
// hint is provided and a std::vector<double> for the hint value.
std::vector<std::pair<const MPVariable*, double> > solution_hint_;
absl::Duration time_limit_ = absl::InfiniteDuration(); // Default = No limit.
const absl::Time construction_time_;
// Permanent storage for the number of threads.
int num_threads_ = 1;
// Permanent storage for SetSolverSpecificParametersAsString().
std::string solver_specific_parameter_string_;
MPSolverResponseStatus LoadModelFromProtoInternal(
const MPModelProto& input_model, bool clear_names,
bool check_model_validity, std::string* error_message);
DISALLOW_COPY_AND_ASSIGN(MPSolver);
};
const absl::string_view ToString(
MPSolver::OptimizationProblemType optimization_problem_type);
inline std::ostream& operator<<(
std::ostream& os,
MPSolver::OptimizationProblemType optimization_problem_type) {
return os << ToString(optimization_problem_type);
}
inline std::ostream& operator<<(std::ostream& os,
MPSolver::ResultStatus status) {
return os << ProtoEnumToString<MPSolverResponseStatus>(
static_cast<MPSolverResponseStatus>(status));
}
bool AbslParseFlag(absl::string_view text,
MPSolver::OptimizationProblemType* solver_type,
std::string* error);
inline std::string AbslUnparseFlag(
MPSolver::OptimizationProblemType solver_type) {
return std::string(ToString(solver_type));
}
/// A class to express a linear objective.
class MPObjective {
public:
/**
* Clears the offset, all variables and coefficients, and the optimization
* direction.
*/
void Clear();
/**
* Sets the coefficient of the variable in the objective.
*
* If the variable does not belong to the solver, the function just returns,
* or crashes in non-opt mode.
*/
void SetCoefficient(const MPVariable* const var, double coeff);
/**
* Gets the coefficient of a given variable in the objective
*
* It returns 0 if the variable does not appear in the objective).
*/
double GetCoefficient(const MPVariable* const var) const;
/**
* Returns a map from variables to their coefficients in the objective.
*
* If a variable is not present in the map, then its coefficient is zero.
*/
const absl::flat_hash_map<const MPVariable*, double>& terms() const {
return coefficients_;
}
/// Sets the constant term in the objective.
void SetOffset(double value);
/// Gets the constant term in the objective.
double offset() const { return offset_; }
/**
* Resets the current objective to take the value of linear_expr, and sets the
* objective direction to maximize if "is_maximize", otherwise minimizes.
*/
void OptimizeLinearExpr(const LinearExpr& linear_expr, bool is_maximization);
/// Resets the current objective to maximize linear_expr.
void MaximizeLinearExpr(const LinearExpr& linear_expr) {
OptimizeLinearExpr(linear_expr, true);
}
/// Resets the current objective to minimize linear_expr.
void MinimizeLinearExpr(const LinearExpr& linear_expr) {
OptimizeLinearExpr(linear_expr, false);
}
/// Adds linear_expr to the current objective, does not change the direction.
void AddLinearExpr(const LinearExpr& linear_expr);
/// Sets the optimization direction (maximize: true or minimize: false).
void SetOptimizationDirection(bool maximize);
/// Sets the optimization direction to minimize.
void SetMinimization() { SetOptimizationDirection(false); }
/// Sets the optimization direction to maximize.
void SetMaximization() { SetOptimizationDirection(true); }
/// Is the optimization direction set to maximize?
bool maximization() const;
/// Is the optimization direction set to minimize?
bool minimization() const;
/**
* Returns the objective value of the best solution found so far.
*
* It is the optimal objective value if the problem has been solved to
* optimality.
*
* Note: the objective value may be slightly different than what you could
* compute yourself using \c MPVariable::solution_value(); please use the
* --verify_solution flag to gain confidence about the numerical stability of
* your solution.
*/
double Value() const;
/**
* Returns the best objective bound.
*
* In case of minimization, it is a lower bound on the objective value of the
* optimal integer solution. Only available for discrete problems.
*/
double BestBound() const;
private:
friend class MPSolver;
friend class MPSolverInterface;
friend class CBCInterface;
friend class CLPInterface;
friend class GLPKInterface;
friend class SCIPInterface;
friend class SLMInterface;
friend class GurobiInterface;
friend class CplexInterface;
friend class XpressInterface;
friend class GLOPInterface;
friend class BopInterface;
friend class SatInterface;
friend class KnapsackInterface;
// Constructor. An objective points to a single MPSolverInterface
// that is specified in the constructor. An objective cannot belong
// to several models.
// At construction, an MPObjective has no terms (which is equivalent
// on having a coefficient of 0 for all variables), and an offset of 0.
explicit MPObjective(MPSolverInterface* const interface_in)
: interface_(interface_in), coefficients_(1), offset_(0.0) {}
MPSolverInterface* const interface_;
// Mapping var -> coefficient.
absl::flat_hash_map<const MPVariable*, double> coefficients_;
// Constant term.
double offset_;
DISALLOW_COPY_AND_ASSIGN(MPObjective);
};
/// The class for variables of a Mathematical Programming (MP) model.
class MPVariable {
public:
/// Returns the name of the variable.
const std::string& name() const { return name_; }
/// Sets the integrality requirement of the variable.
void SetInteger(bool integer);
/// Returns the integrality requirement of the variable.
bool integer() const { return integer_; }
/**
* Returns the value of the variable in the current solution.
*
* If the variable is integer, then the value will always be an integer (the
* underlying solver handles floating-point values only, but this function
* automatically rounds it to the nearest integer; see: man 3 round).
*/
double solution_value() const;
/// Returns the index of the variable in the MPSolver::variables_.
int index() const { return index_; }
/// Returns the lower bound.
double lb() const { return lb_; }
/// Returns the upper bound.
double ub() const { return ub_; }
/// Sets the lower bound.
void SetLB(double lb) { SetBounds(lb, ub_); }
/// Sets the upper bound.
void SetUB(double ub) { SetBounds(lb_, ub); }
/// Sets both the lower and upper bounds.
void SetBounds(double lb, double ub);
/**
* Advanced usage: unrounded solution value.
*
* The returned value won't be rounded to the nearest integer even if the
* variable is integer.
*/
double unrounded_solution_value() const;
/**
* Advanced usage: returns the reduced cost of the variable in the current
* solution (only available for continuous problems).
*/
double reduced_cost() const;
/**
* Advanced usage: returns the basis status of the variable in the current
* solution (only available for continuous problems).
*
* @see MPSolver::BasisStatus.
*/
MPSolver::BasisStatus basis_status() const;
/**
* Advanced usage: Certain MIP solvers (e.g. Gurobi or SCIP) allow you to set
* a per-variable priority for determining which variable to branch on.
*
* A value of 0 is treated as default, and is equivalent to not setting the
* branching priority. The solver looks first to branch on fractional
* variables in higher priority levels. As of 2019-05, only Gurobi and SCIP
* support setting branching priority; all other solvers will simply ignore
* this annotation.
*/
int branching_priority() const { return branching_priority_; }
void SetBranchingPriority(int priority);
protected:
friend class MPSolver;
friend class MPSolverInterface;
friend class CBCInterface;
friend class CLPInterface;
friend class GLPKInterface;
friend class SCIPInterface;
friend class SLMInterface;
friend class GurobiInterface;
friend class CplexInterface;
friend class XpressInterface;
friend class GLOPInterface;
friend class MPVariableSolutionValueTest;
friend class BopInterface;
friend class SatInterface;
friend class KnapsackInterface;
// Constructor. A variable points to a single MPSolverInterface that
// is specified in the constructor. A variable cannot belong to
// several models.
MPVariable(int index, double lb, double ub, bool integer,
const std::string& name, MPSolverInterface* const interface_in)
: index_(index),
lb_(lb),
ub_(ub),
name_(name.empty() ? absl::StrFormat("auto_v_%09d", index) : name),
solution_value_(0.0),
reduced_cost_(0.0),
interface_(interface_in),
integer_(integer){}
void set_solution_value(double value) { solution_value_ = value; }
void set_reduced_cost(double reduced_cost) { reduced_cost_ = reduced_cost; }
private:
const int index_;
int branching_priority_ = 0;
double lb_;
double ub_;
const std::string name_;
double solution_value_;
double reduced_cost_;
MPSolverInterface* const interface_;
bool integer_;
DISALLOW_COPY_AND_ASSIGN(MPVariable);
};
/**
* The class for constraints of a Mathematical Programming (MP) model.
*
* A constraint is represented as a linear equation or inequality.
*/
class MPConstraint {
public:
/// Returns the name of the constraint.
const std::string& name() const { return name_; }
/// Clears all variables and coefficients. Does not clear the bounds.
void Clear();
/**
* Sets the coefficient of the variable on the constraint.
*
* If the variable does not belong to the solver, the function just returns,
* or crashes in non-opt mode.
*/
void SetCoefficient(const MPVariable* const var, double coeff);
/**
* Gets the coefficient of a given variable on the constraint (which is 0 if
* the variable does not appear in the constraint).
*/
double GetCoefficient(const MPVariable* const var) const;
/**
* Returns a map from variables to their coefficients in the constraint.
*
* If a variable is not present in the map, then its coefficient is zero.
*/
const absl::flat_hash_map<const MPVariable*, double>& terms() const {
return coefficients_;
}
/// Returns the lower bound.
double lb() const { return lb_; }
/// Returns the upper bound.
double ub() const { return ub_; }
/// Sets the lower bound.
void SetLB(double lb) { SetBounds(lb, ub_); }
/// Sets the upper bound.
void SetUB(double ub) { SetBounds(lb_, ub); }
/// Sets both the lower and upper bounds.
void SetBounds(double lb, double ub);
/// Advanced usage: returns true if the constraint is "lazy" (see below).
bool is_lazy() const { return is_lazy_; }
/**
* Advanced usage: sets the constraint "laziness".
*
* <em>This is only supported for SCIP and has no effect on other
* solvers.</em>
*
* When \b laziness is true, the constraint is only considered by the Linear
* Programming solver if its current solution violates the constraint. In this
* case, the constraint is definitively added to the problem. This may be
* useful in some MIP problems, and may have a dramatic impact on performance.
*
* For more info see: http://tinyurl.com/lazy-constraints.
*/
void set_is_lazy(bool laziness) { is_lazy_ = laziness; }
const MPVariable* indicator_variable() const { return indicator_variable_; }
bool indicator_value() const { return indicator_value_; }
/// Returns the index of the constraint in the MPSolver::constraints_.
int index() const { return index_; }
/**
* Advanced usage: returns the dual value of the constraint in the current
* solution (only available for continuous problems).
*/
double dual_value() const;
/**
* Advanced usage: returns the basis status of the constraint.
*
* It is only available for continuous problems).
*
* Note that if a constraint "linear_expression in [lb, ub]" is transformed
* into "linear_expression + slack = 0" with slack in [-ub, -lb], then this
* status is the same as the status of the slack variable with AT_UPPER_BOUND
* and AT_LOWER_BOUND swapped.
*
* @see MPSolver::BasisStatus.
*/
MPSolver::BasisStatus basis_status() const;
protected:
friend class MPSolver;
friend class MPSolverInterface;
friend class CBCInterface;
friend class CLPInterface;
friend class GLPKInterface;
friend class SCIPInterface;
friend class SLMInterface;
friend class GurobiInterface;
friend class CplexInterface;
friend class XpressInterface;
friend class GLOPInterface;
friend class BopInterface;
friend class SatInterface;
friend class KnapsackInterface;
// Constructor. A constraint points to a single MPSolverInterface
// that is specified in the constructor. A constraint cannot belong
// to several models.
MPConstraint(int index, double lb, double ub, const std::string& name,
MPSolverInterface* const interface_in)
: coefficients_(1),
index_(index),
lb_(lb),
ub_(ub),
name_(name.empty() ? absl::StrFormat("auto_c_%09d", index) : name),
indicator_variable_(nullptr),
is_lazy_(false),
dual_value_(0.0),
interface_(interface_in) {}
void set_dual_value(double dual_value) { dual_value_ = dual_value; }
private:
// Returns true if the constraint contains variables that have not
// been extracted yet.
bool ContainsNewVariables();
// Mapping var -> coefficient.
absl::flat_hash_map<const MPVariable*, double> coefficients_;
const int index_; // See index().
// The lower bound for the linear constraint.
double lb_;
// The upper bound for the linear constraint.
double ub_;
// Name.
const std::string name_;
// If given, this constraint is only active if `indicator_variable_`'s value
// is equal to `indicator_value_`.
const MPVariable* indicator_variable_;
bool indicator_value_;
// True if the constraint is "lazy", i.e. the constraint is added to the
// underlying Linear Programming solver only if it is violated.
// By default this parameter is 'false'.
bool is_lazy_;
double dual_value_;
MPSolverInterface* const interface_;
DISALLOW_COPY_AND_ASSIGN(MPConstraint);
};
/**
* This class stores parameter settings for LP and MIP solvers. Some parameters
* are marked as advanced: do not change their values unless you know what you
* are doing!
*
* For developers: how to add a new parameter:
* - Add the new Foo parameter in the DoubleParam or IntegerParam enum.
* - If it is a categorical param, add a FooValues enum.
* - Decide if the wrapper should define a default value for it: yes
* if it controls the properties of the solution (example:
* tolerances) or if it consistently improves performance, no
* otherwise. If yes, define kDefaultFoo.
* - Add a foo_value_ member and, if no default value is defined, a
* foo_is_default_ member.
* - Add code to handle Foo in Set...Param, Reset...Param,
* Get...Param, Reset and the constructor.
* - In class MPSolverInterface, add a virtual method SetFoo, add it
* to SetCommonParameters or SetMIPParameters, and implement it for
* each solver. Sometimes, parameters need to be implemented
* differently, see for example the INCREMENTALITY implementation.
* - Add a test in linear_solver_test.cc.
*
* TODO(user): store the parameter values in a protocol buffer
* instead. We need to figure out how to deal with the subtleties of
* the default values.
*/
class MPSolverParameters {
public:
/// Enumeration of parameters that take continuous values.
enum DoubleParam {
/// Limit for relative MIP gap.
RELATIVE_MIP_GAP = 0,
/**
* Advanced usage: tolerance for primal feasibility of basic solutions.
*
* This does not control the integer feasibility tolerance of integer
* solutions for MIP or the tolerance used during presolve.
*/
PRIMAL_TOLERANCE = 1,
/// Advanced usage: tolerance for dual feasibility of basic solutions.
DUAL_TOLERANCE = 2
};
/// Enumeration of parameters that take integer or categorical values.
enum IntegerParam {
/// Advanced usage: presolve mode.
PRESOLVE = 1000,
/// Algorithm to solve linear programs.
LP_ALGORITHM = 1001,
/// Advanced usage: incrementality from one solve to the next.
INCREMENTALITY = 1002,
/// Advanced usage: enable or disable matrix scaling.
SCALING = 1003
};
/// For each categorical parameter, enumeration of possible values.
enum PresolveValues {
/// Presolve is off.
PRESOLVE_OFF = 0,
/// Presolve is on.
PRESOLVE_ON = 1
};
/// LP algorithm to use.
enum LpAlgorithmValues {
/// Dual simplex.
DUAL = 10,
/// Primal simplex.
PRIMAL = 11,
/// Barrier algorithm.
BARRIER = 12
};
/// Advanced usage: Incrementality options.
enum IncrementalityValues {
/// Start solve from scratch.
INCREMENTALITY_OFF = 0,
/**
* Reuse results from previous solve as much as the underlying solver
* allows.
*/
INCREMENTALITY_ON = 1
};
/// Advanced usage: Scaling options.
enum ScalingValues {
/// Scaling is off.
SCALING_OFF = 0,
/// Scaling is on.
SCALING_ON = 1
};
// Placeholder value to indicate that a parameter is set to
// the default value defined in the wrapper.
static const double kDefaultDoubleParamValue;
static const int kDefaultIntegerParamValue;
// Placeholder value to indicate that a parameter is unknown.
static const double kUnknownDoubleParamValue;
static const int kUnknownIntegerParamValue;
// Default values for parameters. Only parameters that define the
// properties of the solution returned need to have a default value
// (that is the same for all solvers). You can also define a default
// value for performance parameters when you are confident it is a
// good choice (example: always turn presolve on).
static const double kDefaultRelativeMipGap;
static const double kDefaultPrimalTolerance;
static const double kDefaultDualTolerance;
static const PresolveValues kDefaultPresolve;
static const IncrementalityValues kDefaultIncrementality;
/// The constructor sets all parameters to their default value.
MPSolverParameters();
/// Sets a double parameter to a specific value.
void SetDoubleParam(MPSolverParameters::DoubleParam param, double value);
/// Sets a integer parameter to a specific value.
void SetIntegerParam(MPSolverParameters::IntegerParam param, int value);
/**
* Sets a double parameter to its default value (default value defined in
* MPSolverParameters if it exists, otherwise the default value defined in
* the underlying solver).
*/
void ResetDoubleParam(MPSolverParameters::DoubleParam param);
/**
* Sets an integer parameter to its default value (default value defined in
* MPSolverParameters if it exists, otherwise the default value defined in
* the underlying solver).
*/
void ResetIntegerParam(MPSolverParameters::IntegerParam param);
/// Sets all parameters to their default value.
void Reset();
/// Returns the value of a double parameter.
double GetDoubleParam(MPSolverParameters::DoubleParam param) const;
/// Returns the value of an integer parameter.
int GetIntegerParam(MPSolverParameters::IntegerParam param) const;
private:
// Parameter value for each parameter.
// @see DoubleParam
// @see IntegerParam
double relative_mip_gap_value_;
double primal_tolerance_value_;
double dual_tolerance_value_;
int presolve_value_;
int scaling_value_;
int lp_algorithm_value_;
int incrementality_value_;
// Boolean value indicating whether each parameter is set to the
// solver's default value. Only parameters for which the wrapper
// does not define a default value need such an indicator.
bool lp_algorithm_is_default_;
DISALLOW_COPY_AND_ASSIGN(MPSolverParameters);
};
// This class wraps the actual mathematical programming solvers. Each
// solver (GLOP, CLP, CBC, GLPK, SCIP) has its own interface class that
// derives from this abstract class. This class is never directly
// accessed by the user.
// @see glop_interface.cc
// @see cbc_interface.cc
// @see clp_interface.cc
// @see glpk_interface.cc
// @see scip_interface.cc
class MPSolverInterface {
public:
enum SynchronizationStatus {
// The underlying solver (CLP, GLPK, ...) and MPSolver are not in
// sync for the model nor for the solution.
MUST_RELOAD,
// The underlying solver and MPSolver are in sync for the model
// but not for the solution: the model has changed since the
// solution was computed last.
MODEL_SYNCHRONIZED,
// The underlying solver and MPSolver are in sync for the model and
// the solution.
SOLUTION_SYNCHRONIZED
};
// When the underlying solver does not provide the number of simplex
// iterations.
static const int64 kUnknownNumberOfIterations = -1;
// When the underlying solver does not provide the number of
// branch-and-bound nodes.
static const int64 kUnknownNumberOfNodes = -1;
// Constructor. The user will access the MPSolverInterface through the
// MPSolver passed as argument.
explicit MPSolverInterface(MPSolver* const solver);
virtual ~MPSolverInterface();
// ----- Solve -----
// Solves problem with specified parameter values. Returns true if the
// solution is optimal.
virtual MPSolver::ResultStatus Solve(const MPSolverParameters& param) = 0;
// Directly solves a MPModelRequest, bypassing the MPSolver data structures
// entirely. Returns {} (eg. absl::nullopt) if the feature is not supported by
// the underlying solver.
virtual absl::optional<MPSolutionResponse> DirectlySolveProto(
const MPModelRequest& request) {
return absl::nullopt;
}
// Writes the model using the solver internal write function. Currently only
// available for GurobiInterface.
virtual void Write(const std::string& filename);
// ----- Model modifications and extraction -----
// Resets extracted model.
virtual void Reset() = 0;
// Sets the optimization direction (min/max).
virtual void SetOptimizationDirection(bool maximize) = 0;
// Modifies bounds of an extracted variable.
virtual void SetVariableBounds(int index, double lb, double ub) = 0;
// Modifies integrality of an extracted variable.
virtual void SetVariableInteger(int index, bool integer) = 0;
// Modify bounds of an extracted variable.
virtual void SetConstraintBounds(int index, double lb, double ub) = 0;
// Adds a linear constraint.
virtual void AddRowConstraint(MPConstraint* const ct) = 0;
// Adds an indicator constraint. Returns true if the feature is supported by
// the underlying solver.
virtual bool AddIndicatorConstraint(MPConstraint* const ct) {
LOG(ERROR) << "Solver doesn't support indicator constraints.";
return false;
}
// Add a variable.
virtual void AddVariable(MPVariable* const var) = 0;
// Changes a coefficient in a constraint.
virtual void SetCoefficient(MPConstraint* const constraint,
const MPVariable* const variable,
double new_value, double old_value) = 0;
// Clears a constraint from all its terms.
virtual void ClearConstraint(MPConstraint* const constraint) = 0;
// Changes a coefficient in the linear objective.
virtual void SetObjectiveCoefficient(const MPVariable* const variable,
double coefficient) = 0;
// Changes the constant term in the linear objective.
virtual void SetObjectiveOffset(double value) = 0;
// Clears the objective from all its terms.
virtual void ClearObjective() = 0;
virtual void BranchingPriorityChangedForVariable(int var_index) {}
// ------ Query statistics on the solution and the solve ------
// Returns the number of simplex iterations. The problem must be discrete,
// otherwise it crashes, or returns kUnknownNumberOfIterations in NDEBUG mode.
virtual int64 iterations() const = 0;
// Returns the number of branch-and-bound nodes. The problem must be discrete,
// otherwise it crashes, or returns kUnknownNumberOfNodes in NDEBUG mode.
virtual int64 nodes() const = 0;
// Returns the best objective bound. The problem must be discrete, otherwise
// it crashes, or returns trivial_worst_objective_bound() in NDEBUG mode.
virtual double best_objective_bound() const = 0;
// A trivial objective bound: the worst possible value of the objective,
// which will be +infinity if minimizing and -infinity if maximing.
double trivial_worst_objective_bound() const;
// Returns the objective value of the best solution found so far.
double objective_value() const;
// Returns the basis status of a row.
virtual MPSolver::BasisStatus row_status(int constraint_index) const = 0;
// Returns the basis status of a constraint.
virtual MPSolver::BasisStatus column_status(int variable_index) const = 0;
// Checks whether the solution is synchronized with the model, i.e. whether
// the model has changed since the solution was computed last.
// If it isn't, it crashes in NDEBUG, and returns false othwerwise.
bool CheckSolutionIsSynchronized() const;
// Checks whether a feasible solution exists. The behavior is similar to
// CheckSolutionIsSynchronized() above.
virtual bool CheckSolutionExists() const;
// Handy shortcut to do both checks above (it is often used).
bool CheckSolutionIsSynchronizedAndExists() const {
return CheckSolutionIsSynchronized() && CheckSolutionExists();
}
// Checks whether information on the best objective bound exists. The behavior
// is similar to CheckSolutionIsSynchronized() above.
virtual bool CheckBestObjectiveBoundExists() const;
// ----- Misc -----
// Queries problem type. For simplicity, the distinction between
// continuous and discrete is based on the declaration of the user
// when the solver is created (example: GLPK_LINEAR_PROGRAMMING
// vs. GLPK_MIXED_INTEGER_PROGRAMMING), not on the actual content of
// the model.
// Returns true if the problem is continuous.
virtual bool IsContinuous() const = 0;
// Returns true if the problem is continuous and linear.
virtual bool IsLP() const = 0;
// Returns true if the problem is discrete and linear.
virtual bool IsMIP() const = 0;
// Returns the index of the last variable extracted.
int last_variable_index() const { return last_variable_index_; }
bool variable_is_extracted(int var_index) const {
return solver_->variable_is_extracted_[var_index];
}
void set_variable_as_extracted(int var_index, bool extracted) {
solver_->variable_is_extracted_[var_index] = extracted;
}
bool constraint_is_extracted(int ct_index) const {
return solver_->constraint_is_extracted_[ct_index];
}
void set_constraint_as_extracted(int ct_index, bool extracted) {
solver_->constraint_is_extracted_[ct_index] = extracted;
}
// Returns the boolean indicating the verbosity of the solver output.
bool quiet() const { return quiet_; }
// Sets the boolean indicating the verbosity of the solver output.
void set_quiet(bool quiet_value) { quiet_ = quiet_value; }
// Returns the result status of the last solve.
MPSolver::ResultStatus result_status() const {
CheckSolutionIsSynchronized();
return result_status_;
}
// Returns a std::string describing the underlying solver and its version.
virtual std::string SolverVersion() const = 0;
// Returns the underlying solver.
virtual void* underlying_solver() = 0;
// Computes exact condition number. Only available for continuous
// problems and only implemented in GLPK.
virtual double ComputeExactConditionNumber() const;
// See MPSolver::SetStartingLpBasis().
virtual void SetStartingLpBasis(
const std::vector<MPSolver::BasisStatus>& variable_statuses,
const std::vector<MPSolver::BasisStatus>& constraint_statuses) {
LOG(FATAL) << "Not supported by this solver.";
}
virtual bool InterruptSolve() { return false; }
// See MPSolver::NextSolution() for contract.
virtual bool NextSolution() { return false; }
friend class MPSolver;
// To access the maximize_ bool and the MPSolver.
friend class MPConstraint;
friend class MPObjective;
protected:
MPSolver* const solver_;
// Indicates whether the model and the solution are synchronized.
SynchronizationStatus sync_status_;
// Indicates whether the solve has reached optimality,
// infeasibility, a limit, etc.
MPSolver::ResultStatus result_status_;
// Optimization direction.
bool maximize_;
// Index in MPSolver::variables_ of last constraint extracted.
int last_constraint_index_;
// Index in MPSolver::constraints_ of last variable extracted.
int last_variable_index_;
// The value of the objective function.
double objective_value_;
// Boolean indicator for the verbosity of the solver output.
bool quiet_;
// Index of dummy variable created for empty constraints or the
// objective offset.
static const int kDummyVariableIndex;
// Extracts model stored in MPSolver.
void ExtractModel();
// Extracts the variables that have not been extracted yet.
virtual void ExtractNewVariables() = 0;
// Extracts the constraints that have not been extracted yet.
virtual void ExtractNewConstraints() = 0;
// Extracts the objective.
virtual void ExtractObjective() = 0;
// Resets the extraction information.
void ResetExtractionInformation();
// Change synchronization status from SOLUTION_SYNCHRONIZED to
// MODEL_SYNCHRONIZED. To be used for model changes.
void InvalidateSolutionSynchronization();
// Sets parameters common to LP and MIP in the underlying solver.
void SetCommonParameters(const MPSolverParameters& param);
// Sets MIP specific parameters in the underlying solver.
void SetMIPParameters(const MPSolverParameters& param);
// Sets all parameters in the underlying solver.
virtual void SetParameters(const MPSolverParameters& param) = 0;
// Sets an unsupported double parameter.
void SetUnsupportedDoubleParam(MPSolverParameters::DoubleParam param);
// Sets an unsupported integer parameter.
virtual void SetUnsupportedIntegerParam(
MPSolverParameters::IntegerParam param);
// Sets a supported double parameter to an unsupported value.
void SetDoubleParamToUnsupportedValue(MPSolverParameters::DoubleParam param,
double value);
// Sets a supported integer parameter to an unsupported value.
virtual void SetIntegerParamToUnsupportedValue(
MPSolverParameters::IntegerParam param, int value);
// Sets each parameter in the underlying solver.
virtual void SetRelativeMipGap(double value) = 0;
virtual void SetPrimalTolerance(double value) = 0;
virtual void SetDualTolerance(double value) = 0;
virtual void SetPresolveMode(int value) = 0;
// Sets the number of threads to be used by the solver.
virtual util::Status SetNumThreads(int num_threads);
// Pass solver specific parameters in text format. The format is
// solver-specific and is the same as the corresponding solver configuration
// file format. Returns true if the operation was successful.
//
// The default implementation of this method stores the parameters in a
// temporary file and calls ReadParameterFile to import the parameter file
// into the solver. Solvers that support passing the parameters directly can
// override this method to skip the temporary file logic.
virtual bool SetSolverSpecificParametersAsString(
const std::string& parameters);
// Reads a solver-specific file of parameters and set them.
// Returns true if there was no errors.
virtual bool ReadParameterFile(const std::string& filename);
// Returns a file extension like ".tmp", this is needed because some solvers
// require a given extension for the ReadParameterFile() filename and we need
// to know it to generate a temporary parameter file.
virtual std::string ValidFileExtensionForParameterFile() const;
// Sets the scaling mode.
virtual void SetScalingMode(int value) = 0;
virtual void SetLpAlgorithm(int value) = 0;
};
} // namespace operations_research
#endif // OR_TOOLS_LINEAR_SOLVER_LINEAR_SOLVER_H_
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