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build2/epsilon-master/apps/solver/equation_store.h 4.46 KB
6663b6c9   adorian   projet complet av...
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  #ifndef SOLVER_EQUATION_STORE_H
  #define SOLVER_EQUATION_STORE_H
  
  #include "equation.h"
  #include "../shared/expression_model_store.h"
  #include <stdint.h>
  
  namespace Solver {
  
  class EquationStore : public Shared::ExpressionModelStore {
  public:
    enum class Type {
      LinearSystem,
      PolynomialMonovariable,
      Monovariable,
    };
    enum class Error : int16_t {
      NoError = 0,
      EquationUndefined = -1,
      TooManyVariables = -2,
      NonLinearSystem = -3,
      RequireApproximateSolution = -4
    };
    /* EquationStore */
    EquationStore();
    ~EquationStore();
    Equation * modelAtIndex(int i) override {
      assert(i>=0 && i<m_numberOfModels);
      return &m_equations[i];
    }
    Equation * definedModelAtIndex(int i) override { return static_cast<Equation *>(Shared::ExpressionModelStore::definedModelAtIndex(i)); }
    int maxNumberOfModels() const override { return k_maxNumberOfEquations; }
    Type type() const {
      return m_type;
    }
    char variableAtIndex(size_t i) {
      assert(i < strlen(m_variables));
      return m_variables[i];
    }
    int numberOfSolutions() const {
      return m_numberOfSolutions;
    }
    /* Exact resolution */
    Error exactSolve(Poincare::Context * context);
    /* The exact solutions are displayed in a table with 2 layouts: an exact
     * Layout and an approximate layout. For example, 'sqrt(2)' and '1.414213'.
     * The boolean exactLayout indicates if we want the exact layout or the
     * approximate one. */
    Poincare::ExpressionLayout * exactSolutionLayoutAtIndex(int i, bool exactLayout);
    /* Exact layout and approximate layout of an exact solution can be:
     * - identical: for instance, 5 and 5
     * - equal: for instance 1/2 and 0.5
     * - non-equal: for instance 1/3 and 0.333.
     */
    bool exactSolutionLayoutsAtIndexAreIdentical(int i) {
      assert(m_type != Type::Monovariable && i >= 0 && (i < m_numberOfSolutions || (i == m_numberOfSolutions && m_type == Type::PolynomialMonovariable)));
      return m_exactSolutionIdentity[i];
    }
    bool exactSolutionLayoutsAtIndexAreEqual(int i) {
      assert(m_type != Type::Monovariable && i >= 0 && (i < m_numberOfSolutions || (i == m_numberOfSolutions && m_type == Type::PolynomialMonovariable)));
      return m_exactSolutionEquality[i];
    }
    /* Approximate resolution */
    double intervalBound(int index) const;
    void setIntervalBound(int index, double value);
    double approximateSolutionAtIndex(int i);
    void approximateSolve(Poincare::Context * context);
    bool haveMoreApproximationSolutions(Poincare::Context * context);
  
    void tidy() override;
    static constexpr int k_maxNumberOfExactSolutions = Poincare::Expression::k_maxNumberOfVariables > Poincare::Expression::k_maxPolynomialDegree + 1? Poincare::Expression::k_maxNumberOfVariables : Poincare::Expression::k_maxPolynomialDegree + 1;
    static constexpr int k_maxNumberOfApproximateSolutions = 10;
    static constexpr int k_maxNumberOfSolutions = k_maxNumberOfExactSolutions > k_maxNumberOfApproximateSolutions ? k_maxNumberOfExactSolutions : k_maxNumberOfApproximateSolutions;
  private:
    static constexpr double k_precision = 0.01;
    static constexpr int k_maxNumberOfEquations = Poincare::Expression::k_maxNumberOfVariables; // Enable the same number of equations as the number of unknown variables
    Equation * emptyModel() override;
    Equation * nullModel() override {
      return emptyModel();
    }
    void setModelAtIndex(Shared::ExpressionModel * f, int i) override;
    Error resolveLinearSystem(Poincare::Expression * solutions[k_maxNumberOfExactSolutions], Poincare::Expression * coefficients[k_maxNumberOfEquations][Poincare::Expression::k_maxNumberOfVariables], Poincare::Expression * constants[k_maxNumberOfEquations], Poincare::Context * context);
    Error oneDimensialPolynomialSolve(Poincare::Expression * solutions[k_maxNumberOfExactSolutions], Poincare::Expression * polynomialCoefficients[Poincare::Expression::k_maxNumberOfPolynomialCoefficients], int degree, Poincare::Context * context);
    void tidySolution();
  
    Equation m_equations[k_maxNumberOfEquations];
    Type m_type;
    char m_variables[Poincare::Expression::k_maxNumberOfVariables+1];
    int m_numberOfSolutions;
    Poincare::ExpressionLayout * m_exactSolutionExactLayouts[k_maxNumberOfApproximateSolutions];
    Poincare::ExpressionLayout * m_exactSolutionApproximateLayouts[k_maxNumberOfExactSolutions];
    bool m_exactSolutionIdentity[k_maxNumberOfExactSolutions];
    bool m_exactSolutionEquality[k_maxNumberOfExactSolutions];
    double m_intervalApproximateSolutions[2];
    double m_approximateSolutions[k_maxNumberOfApproximateSolutions];
  };
  
  }
  
  #endif