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I have a weird access location error that only happens when I run the program outside the IDE (I use Code::Block wih GNU GCC compiler and GBD as debugger).

Unhandled exception at 0x77cd82ea in SFinGe.exe: 0xC0000005: Access violation reading location 0x69687065.

This happens when I try to add elements to a std::map. I know that this commonly happens when you have an unitialised variable, but I have been going through my code carefully and I cant find the problem and its driving me crazzy.

This is the class definition:

//==============================================================================
// CDirectionalMapGenerator prototypes.
//==============================================================================

#ifndef CDIRECTIONALMAPGENERATOR_H
#define CDIRECTIONALMAPGENERATOR_H

//==============================================================================

#include <complex.h>
#include <math.h>
#include <map>
#include <vector>
#include <CRandom.h>
#include <SFingerprintPattern.h>
#include <ESingularityType.h>

//==============================================================================

#define PI 3.14159265359

//==============================================================================

/** \brief
  * Generates a directional map using the orientation model proposed by Sherlock and Monro, this allows a consistent orientation image to be computed from
  * the knowledge of the position of the fingerprint singularities (core and deltas) alone. The image is located in the complex plane and the local ridge
  * orientation is the phase of the square root of a complex rational function whose singularities (poles and zeros) are located at the same place
  * as the fingerprint singularities.
 */
class CDirectionalMapGenerator
{
  public:

    /** \brief
     * Initializes a new instance of the CDirectionalMapGenerator class.
     *
     */
    CDirectionalMapGenerator();

    /** \brief
     * Destroy the CDirectionalMapGenerator object and all its reference safely.
     */
    virtual ~CDirectionalMapGenerator();

    /** \brief
     * Generates a directional map.
     * \param pattern CFingerprintPattern The fingerprint class and singularity types information.
     * \param witdh int The witdh of the map.
     * \param height int The height of the map.
     * \return std::vector<std::vector<double>> The directional map.
     */
    std::vector<std::vector<double> > generate(SFingerprintPattern& pattern, int width, int height);

  private:

    /** \brief
     * Gets the segment orientation.
     * \param z complex The complex number representing a point in the directional map.
     * \return double The segment orientation in radians.
     */
    double getSegmentOrientation(std::complex<double> z);

    /** \brief
     * Vizcaya and Gerhardt correction.
     * \param alpha double The angle to be corrected.
     * \param singularityType ESingularityType The singularity type.
     * \return double The angle corrected.
     */
    double correctOrientation(double alpha, ESingularityType singularityType);

    /** \brief
     * Gets the amount of angle correction for the given point. The directional map is uniformly divided between -PI and PI
     * in eight segments (45 degrees each segment), points in each region must be adjusted using a different piecewise linear function.
     * The variables 'v' and 'u' are angles defined at the beginning of the generation process, this angles are chosen depending on the
     * singularity type and fingerprint class.
     * \param q int Region of the point.
     * \param singularityType ESingularityType The singularity type.
     * \return double The amount of correction.
     */
    double getAmountOfCorrection(int q, ESingularityType singularityType);

    /** \brief
     *  Modification angles must be defined on the basis of position and number of singularities.
     * \return void
     *
     */
    void generateWeigths();

  private:
      static CRandom*                    m_sRandom;

      std::map<ESingularityType, double> m_v;
      std::map<ESingularityType, double> m_u;
      EFingerprintClass                  m_currentFingerprintClass;
      SFingerprintPattern                m_currentPattern;
      double                             m_nArchTypeFactors[3];
      int                                m_nCurrentWidth;
      int                                m_nCurrentHeight;
};


#endif // CDIRECTIONALMAPGENERATOR_H

and the implementation:

#include "CDirectionalMapGenerator.h"
//==============================================================================

// Static variable initialization.
CRandom* CDirectionalMapGenerator::m_sRandom = new CRandom(time(0));

//==============================================================================
CDirectionalMapGenerator::CDirectionalMapGenerator()
{
    m_currentFingerprintClass = ARCH;
    m_nCurrentWidth           = 0;
    m_nCurrentHeight          = 0;
    m_v                       = std::map<ESingularityType, double>();
    m_u                       = std::map<ESingularityType, double>();
}

//==============================================================================
CDirectionalMapGenerator::~CDirectionalMapGenerator()
{
    delete m_sRandom;

    m_u.clear();
    m_v.clear();
}

//==============================================================================
std::vector<std::vector<double> > CDirectionalMapGenerator::generate(SFingerprintPattern& pattern, int width, int height)
{
    std::vector<std::vector<double> > directionalMap;

    m_currentFingerprintClass = pattern.FingerprintClass;
    m_currentPattern          = pattern;
    m_nCurrentWidth           = width;
    m_nCurrentHeight          = height;

    // Clear weights from last generation.
    m_u.clear();
    m_v.clear();

    this->generateWeigths();

    for (int i = 0; i < m_nCurrentWidth; ++i)
    {
      std::vector<double> vLine;
      for (int j = 0; j < m_nCurrentHeight; ++j)
      {
        std::complex<double> z(i, j);

        vLine.push_back(this->getSegmentOrientation(z));
      }

      directionalMap.push_back(vLine);
    }

    return directionalMap;
}


//==============================================================================
double CDirectionalMapGenerator::getSegmentOrientation(std::complex<double> z)
{
      double segmentOrientation = 0;
      int    degrees            = 0;

      if (m_currentFingerprintClass == ARCH)
      {
        // Arch patterns that do not contain any singularity are not supported by the model, a sinusoidal function
        // must be use instead (The frequency and amplitude are tuned to control the arch curvature and aspect).
        segmentOrientation = atan(std::max(0.0, (m_nArchTypeFactors[2] - m_nArchTypeFactors[2] * z.imag() / (m_nCurrentHeight * m_nArchTypeFactors[1]))) * cos(z.real() * PI / (m_nCurrentWidth * m_nArchTypeFactors[0])));
      }
      else if (m_currentFingerprintClass == WHORL)
      {
        // Whorl have two cores and two deltas.

        // 1/2(g(arg(z - d1)) - g(arg(z - l1))) + 1/2(g(arg(z - d2)) - g(arg (z - l2)))
        segmentOrientation = (0.5 * (this->correctOrientation(arg((z - m_currentPattern.DeltaOne)), DELTA) - this->correctOrientation(arg((z - m_currentPattern.LoopOne)), CORE))) +
                             (0.5 * (this->correctOrientation(arg((z - m_currentPattern.DeltaTwo)), SECONDARY_DELTA) - this->correctOrientation(arg((z - m_currentPattern.LoopTwo)), SECONDARY_CORE)));
      }
      else
      {
        // 1/2(g(arg(z - d)) - g(arg (z - l)))
        segmentOrientation = 0.5 * (this->correctOrientation(arg((z - m_currentPattern.DeltaOne)), DELTA) - this->correctOrientation(arg((z - m_currentPattern.LoopOne)), CORE));
      }

      degrees = static_cast<int>(segmentOrientation * (180 / PI)); // From radiants to degrees.

      if(degrees < 0)
        degrees = -(((-1) * degrees) % (180)) + 180;

      segmentOrientation = degrees * (PI / 180); // From degrees to radiants.

      return segmentOrientation;
}

//==============================================================================
double CDirectionalMapGenerator::correctOrientation(double alpha, ESingularityType singularityType)
{
      int    q             = static_cast<int>(floor(4 * (PI + alpha) / PI));
      double alphaI        = -PI + (PI * q) / 4;
      double correctionOne = this->getAmountOfCorrection(q + 1, singularityType); //gk(alpha i)
      double correctionTwo = this->getAmountOfCorrection(q + 2, singularityType); //gk(alpha i + 1)

      return (correctionOne + ((4 * (alpha - alphaI)) / PI) * (correctionTwo - correctionOne));
}

//==============================================================================
double CDirectionalMapGenerator::getAmountOfCorrection(int q, ESingularityType singularityType)
{
      double amountOfCorrection = 0;
      switch (q)
      {
        case 1:
          amountOfCorrection = -PI + m_u[singularityType];
          break;
        case 2:
          amountOfCorrection = -3 * PI / 4 + m_u[singularityType];
          break;
        case 3:
          amountOfCorrection = -PI / 2;
          break;
        case 4:
          amountOfCorrection = -PI / 4 + m_v[singularityType];
          break;
        case 5:
          amountOfCorrection = m_v[singularityType];
          break;
        case 6:
          amountOfCorrection = PI / 4 + m_v[singularityType];
          break;
        case 7:
          amountOfCorrection = PI / 2;
          break;
        case 8:
          amountOfCorrection = 3 * PI / 4 + m_u[singularityType];
          break;
        default:
          amountOfCorrection = PI + m_u[singularityType];
          break;
      }

      return amountOfCorrection;
}

//==============================================================================
void CDirectionalMapGenerator::generateWeigths()
{
      switch (m_currentFingerprintClass)
      {
        case(ARCH):

          m_nArchTypeFactors[0] = (0.8 + 0.4 * m_sRandom->nextDouble());
          m_nArchTypeFactors[1] = (0.6 + 0.8 * m_sRandom->nextDouble());
          m_nArchTypeFactors[2] = (1.2 + m_sRandom->nextDouble() * 1.5);

        break;
      case (LEFT_LOOP):

          m_u[CORE] = -120 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);
          m_v[CORE] = 50 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

        break;
      case (RIGHT_LOOP):

          m_u[CORE] = -90 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);
          m_v[CORE] = 60 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

        break;
      case (TENTED_ARCH):

          m_u[CORE] = -90 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);
          m_v[CORE] = 45 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

        break;
      case (WHORL):

          // Whorl have two cores and two deltas.
          m_u[CORE] = -60 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);
          m_v[CORE] = 40 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);
          m_u[SECONDARY_CORE] = 10 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);
          m_v[SECONDARY_CORE] = 20 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);

        break;
      }
          m_u[DELTA] = 0;
          m_v[DELTA] = 0;
          m_u[SECONDARY_DELTA] = 0;
          m_v[SECONDARY_DELTA] = 0;
}

This is the method that is breaking:

void CDirectionalMapGenerator::generateWeigths()
{
      switch (m_currentFingerprintClass)
      {
        case(ARCH):

          m_nArchTypeFactors[0] = (0.8 + 0.4 * m_sRandom->nextDouble());
          m_nArchTypeFactors[1] = (0.6 + 0.8 * m_sRandom->nextDouble());
          m_nArchTypeFactors[2] = (1.2 + m_sRandom->nextDouble() * 1.5);

        break;
      case (LEFT_LOOP):

          m_u[CORE] = -120 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);
          m_v[CORE] = 50 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

        break;
      case (RIGHT_LOOP):

          m_u[CORE] = -90 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);
          m_v[CORE] = 60 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

        break;
      case (TENTED_ARCH):

          m_u[CORE] = -90 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);
          m_v[CORE] = 45 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

        break;
      case (WHORL):

          // Whorl have two cores and two deltas.
          m_u[CORE] = -60 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);
          m_v[CORE] = 40 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);
          m_u[SECONDARY_CORE] = 10 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);
          m_v[SECONDARY_CORE] = 20 * PI / 180.0 + m_sRandom->nextDouble() * (15 * PI / 180.0);

        break;
      }
          m_u[DELTA] = 0;
          m_v[DELTA] = 0;
          m_u[SECONDARY_DELTA] = 0;
          m_v[SECONDARY_DELTA] = 0;
}

When ever I try to assign a value to the map it blows:

m_u[CORE] = -90 * PI / 180.0 + m_sRandom->nextDouble() * (45 * PI / 180.0);

Im not sure whats worng, I initialized all the members that need it in the contructor, all the others are passed as parameters to the method "generate".

What can I be missing?

share|improve this question
    
std::map compares keys using the less-than (<) operator by default. Perhaps there is an issue with ESingularityType::operator< ? –  Alex Goldberg Dec 19 '12 at 1:35
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1 Answer

Do you use two CDirectionalMapGenerators in your program? Your static variable m_sRandom is only newed once at the beginning of the program, but is deleted whenever a CDirectionalMapGenerator is destroyed. If you create a second CDirectionalMapGenerator after the first is destroyed, whenever it accesses m_sRandom you will be dereferencing an invalid pointer.

Either make sure you don't delete the m_sRandom pointer until the end of your program or make it non-static so that each instance of CDirectionalMapGenerator has its own copy.

share|improve this answer
    
Oh good catch I didnt realised that, but there is only one instance of the CDirectionalMapGenerator and it only gets destroyed when the program ends, I will remove the delete from the deconstructor tho, thanks! –  AngelCastillo Dec 18 '12 at 23:23
    
Are you sure it's that line that does it then? Perhaps nextDouble is the offending function? –  Joseph Mansfield Dec 18 '12 at 23:27
    
I tested the random generator with a cout inside the method and its working fine, also when I try to assing a value like "4" to the map, it blows, so im pretty sure is something related to the map, but cant figure out what =( (Btw +1 for the tip on the static member being destroyed in the constructor :D). –  AngelCastillo Dec 18 '12 at 23:30
    
@AngelCastillo So you're saying a line like m_u[CORE] = 4.0; causes this problem? Are you certain this is where it comes from? If you put a std::cout << "Test"; at the end of the function, does nothing get outputted? –  Joseph Mansfield Dec 18 '12 at 23:35
    
Exactly, if I put 2 std::cout << "Test";, one before m_u[CORE] = 4.0; and one after, only one will be outputted, and yes a line like m_u[CORE] = 4.0 breaks the program. Thats why I think there is a problem with the map, It works fine in debug mode, so I thought maybe im no initializing the maps correctly? I honestly am clueless here. –  AngelCastillo Dec 18 '12 at 23:40
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