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I have a question regarding some memory management in C.

I have to allocate some memory to create multidimensional arrays so I use malloc. For example here:

par.prueba[0][0] = (int *)malloc( 4 * sizeof ( int ) );

Some of them I have to dynamically assign the memory inside a loop like this:

for(;j<=par.param1[0][0];j++){

 pj = -Np * cP + (j - 1) * cP; //aquí va de -NpcP hasta NpcP


 par.prueba[0][j-1][2] = floor((Cx + pj) * par.Bn + 0.5) + par.Bn/2; //xb

 if(j!=par.param1[0][0])
 par.prueba[0][j] = (int *)malloc( 4 * sizeof ( int ) );
}

I have several lines like this through my code. I also check if the allocation worked like this:

if(par.prueba[0][0]==NULL){
  printf("Fail\n");
  exit(2);
}

The thing is that sometimes malloc fails to allocate the requested memory so my program exits. It exists in different places everytime I compile and run again. If I don't check the allocated space my program runs with no problem but eventually crashes.

I used valgrind to try and find the problem but I get a lot of errors of this type:

5,080 bytes in 5 blocks are possibly lost in loss record 5,640 of 5,670

and the error normally traces back to a similar line like this

    par.prueba[0][0] = (int *)malloc( 4 * sizeof ( int ) );

In the end this is what valgrind tells me:

==13628== LEAK SUMMARY:
==13628==    definitely lost: 2,856 bytes in 10 blocks
==13628==    indirectly lost: 10,120 bytes in 505 blocks
==13628==      possibly lost: 614,134 bytes in 6,119 blocks
==13628==    still reachable: 497,948 bytes in 6,432 blocks
==13628==         suppressed: 0 bytes in 0 blocks

So I'm pretty sure I'm not running out of memory but I get a lot of memory leaks. My question is, what is it I'm doing wrong? Am I using malloc correctly? Is there a problem when using malloc so much and very frequently? Any tips to improve that part of the code?

Thanks in advance

EDIT

Thanks for the quick answers!

To answer George's questions

Maybe I should write more of my code here to make it clearer, the code is a little long so I obviate some of the things just to make it more clear.

prueba[0][0] is intialized before that loop. The thing is that I have several such loops across my code but I'm pretty sure I initialize all the values. This is the code

I first declare a struct like this

typedef struct parametros{
  int cT;
  float Bn;
  int **prueba[360];
  int param1[360][3];
  int ***pixels[360];
} 

struct parametros par;

Then I use it like this

par.param1[0][0] = 2*Np + 1; //Np is initialized before

par.prueba[0] = (int **)malloc( par.param1[0][0]* sizeof ( int * ) );

if(par.prueba[0]==NULL){
  printf("Fail\n");
  exit(2);
}

par.prueba[0][0] = (int *)malloc( 4 * sizeof ( int ) );

if(par.prueba[0][0]==NULL){
  printf("Fail\n");
  exit(2);
}

Then I assign some values to the array like this

par.prueba[0][0][1] = floor(Nhe/par.cT);//Nhe and par.cT are initialized before

par.prueba[0][0][0] = -par.prueba[0][0][1];

par.param1[0][1] = 0; 

par.param1[0][2] = par.cT * par.Bn; //par.Bn is also initialized before


par.prueba[0][0][3] = floor((Cy + par.prueba[0][0][0] * par.cT) * par.Bn + 0.5) + par.Bn/2; //Cy is initialized before

And then the loop

int j = 1;
for(;j<=par.param1[0][0];j++){

   pj = -Np * cP + (j - 1) * cP; //cP is initialized before and pj is declared before

   par.prueba[0][j-1][2] = floor((Cx + pj) * par.Bn + 0.5) + par.Bn/2; //xb

   if(j!=par.param1[0][0]){
  par.prueba[0][j] = (int *)malloc( 4 * sizeof ( int ) );

      if(par.prueba[0][j]==NULL){
    printf("Fail\n");
    exit(2);
      }
    }

}

I do similar things for all the 360 values of par.prueba

To answer PaulP.R.O.'s question.

No I don't free the memory. I did that before and it crashed when I tried to free it. I'll try again to see if something changes. I think my problem was trying to figure out when to free it.

To answer AoeAoe's

I think my code is equivalent to what you did right?

To answer Chris Lutz's question.

I don't necessarily want to exit for every failure I get but if I let the code run without exiting it runs fine but then it crashes randomly...

EDIT 2

I added the code to free memory after I finish using the "arrays" and same problem it exits because it fails to allocate some memory with malloc

for(y=0;y<360;y++){

   for(t=0;t<par.param1[y][0];t++){

   free(par.prueba[y][t]);

   }

   free(par.prueba[y]);

}

EDIT 3 -- Complete code

Ok here is the complete code, sorry if it is a little confusing. I will explain if I have to. Basically I need the multidimensional arrays to store some parameters I will afterwards use to calculate some things using the values of the pixels of some image. The code is not finished but I was trying to test how it worked with all the dynamically allocated memory. This code compiles without a problem and, at first runs without a problem if I don't check the memory allocations after using malloc. But once I start using the program it randomly crashes.

#include <stdio.h>
#include <gtk/gtk.h>
#include <glib.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>
#include <math.h>
#include <magick/MagickCore.h>

void ClickCallback(GtkWidget *widget, GdkEventButton *event, gpointer callback_data);
void computar_transformadas(GtkWidget *widget, GdkEventButton *event, gpointer callback_data);
void ext_parametros(GtkImage *img);
static void destroy_event(GtkWidget *widget, gpointer data);
static gboolean delete_event(GtkWidget *widget, GdkEvent *event, gpointer data);
void suma(int** trazo,int o,int entra);

GtkWidget *window, *caja, *button1, *button2, *file_selection_box;
GtkImage *imagen = NULL;
GdkPixbuf *pixbuf = NULL;
guchar *pixs = NULL;
guchar *p = NULL;
int rowstride, n_channels;

typedef struct parametros{
   int cT;
   float Bn;
   int **prueba[360];
   int param1[360][3];
   int ***pixels[360];
};

struct parametros par;

int main (int argc, char *argv[]){

  /*--  Initialize GTK --*/
  gtk_init (&argc, &argv);

  /*-- Create the new window --*/
  window = gtk_window_new(GTK_WINDOW_TOPLEVEL);
  button1 = gtk_button_new_with_label("Abrir.");
  button2 = gtk_button_new_with_label("Analizar.");

  caja = gtk_vbox_new(0,0);


  gtk_window_set_default_size(window,200,200);

  /*-- Agrega funcionalidad al botón -- */
  g_signal_connect(G_OBJECT(button1), "button_press_event", G_CALLBACK(ClickCallback), NULL);

  /*-- Agrega funcionalidad al botón -- */
  g_signal_connect(G_OBJECT(button2), "button_press_event", G_CALLBACK(computar_transformadas), NULL);


  /*-- Agrega el botón a la ventana -- */
  gtk_container_add(GTK_CONTAINER(window), caja);


  gtk_box_pack_end(caja,button1,FALSE,FALSE,1);
  gtk_box_pack_end(caja,button2,FALSE,FALSE,1);

  /*-- Display the window con el botón --*/
  gtk_widget_show_all(window);

  /*-- Start the GTK event loop --*/
  gtk_main();

  /* -- Cierra los eventos -- */
  g_signal_connect(G_OBJECT(window), "delete_event", G_CALLBACK(delete_event), NULL);
  g_signal_connect(G_OBJECT(window), "destroy", G_CALLBACK(destroy_event), NULL);


  /*-- Return 0 if exit is successful --*/
  return 0;

}


void open_file(char *file){


  if(imagen != NULL)
    gtk_image_clear(imagen);


  imagen = gtk_image_new_from_file(file);

  gtk_box_pack_end(caja,imagen,FALSE,FALSE,1);

  gtk_widget_show_all(window);

  ext_parametros(imagen);

}

void ext_parametros(GtkImage *img){


  pixbuf = gtk_image_get_pixbuf(img);

  n_channels = gdk_pixbuf_get_n_channels(pixbuf);
  pixs=gdk_pixbuf_get_pixels(pixbuf);
  p=gdk_pixbuf_get_pixels(pixbuf);
  rowstride=gdk_pixbuf_get_rowstride(pixbuf);

  int pT = 1;

  int pj;

  int M = gdk_pixbuf_get_width(pixbuf);
  int N = gdk_pixbuf_get_height(pixbuf);

  int cP = 1; //paso en P
  par.cT = 1;

  par.Bn = pow(2,12); //division de cada pixel

  float Cx = (float) (M-1)/2; //centro de la imagen eje x
  float Cy = (float) (N-1)/2; //centro de la imagen eje y

  float Mh = Cx + 0.5; //pixel central
  float Nh = Cy + 0.5; //pixel central

  double Pmax = pow((pow(Mh,2)+pow(Nh,2)),0.5)-0.001;

  double E = (1/(2*par.Bn))*(((2*Pmax)/pT)+1);

  double Mhe = Mh - E; //largo tomando en cuenta el error

  double Nhe = Nh - E; //ancho tomando en cuenta el error

  int MBn = M * par.Bn;

  int NBn = N * par.Bn;


  /*  φ = 0  */

  int Np = floor(Mhe/cP);

  par.param1[0][0] = 2*Np + 1; //NP

  par.prueba[0] = (int **)malloc( par.param1[0][0]* sizeof ( int * ) );

  if(par.prueba[0]==NULL){
  printf("¡Fallo al asignar memoria! 0\n");
  exit(2);
  }

  par.prueba[0][0] = (int *)malloc( 4 * sizeof ( int ) );

  if(par.prueba[0][0]==NULL){
  printf("¡Fallo al asignar memoria! 0\n");
  exit(2);
  }

  par.prueba[0][0][1] = floor(Nhe/par.cT);//tend
  par.prueba[0][0][0] = -par.prueba[0][0][1];//tbegin

  par.param1[0][1] = 0; //xinc

  par.param1[0][2] = par.cT * par.Bn; //yinc

  par.prueba[0][0][3] = floor((Cy + par.prueba[0][0][0] * par.cT) * par.Bn + 0.5) + par.Bn/2; //yb

  //------------ -NpcP < p < NpcP ----------------//


  int j = 1;
  for(;j<=par.param1[0][0];j++){

 pj = -Np * cP + (j - 1) * cP; //aquí va de -NpcP hasta NpcP

 par.prueba[0][j-1][2] = floor((Cx + pj) * par.Bn + 0.5) + par.Bn/2; //xb

 if(j!=par.param1[0][0]){
     par.prueba[0][j] = (int *)malloc( 4 * sizeof ( int ) );

     if(par.prueba[0][j]==NULL){
           printf("¡Fallo al asignar memoria! 0 %d\n",j);
       exit(2);
         }
 }

   }

   //----------- Precomputar y calcular 0 < φ < 90 --------------//

   int phi = 1;
   double t1x;
   double t1y;
   double t2x;
   double t2y;




   for(;phi<90;phi++){
  Pmax = Mhe * fabs(cos(phi)) + Nhe * fabs(sin(phi));

  Np = floor(Pmax/cP);

  par.param1[phi][0] = 2 * Np + 1; //NP

  par.prueba[phi] = (int **)malloc( par.param1[phi][0]* sizeof ( int * ) );

  if(par.prueba[phi]==NULL){
     printf("¡Fallo al asignar memoria! %d\n",phi);
     exit(2);
  }

  par.prueba[phi][0] = (int *)malloc( 4 * sizeof ( int ) );

  if(par.prueba[phi][0]==NULL){
      printf("¡Fallo al asignar memoria! %d\n",phi);
      exit(2);
  }


  par.param1[phi][1] = -par.cT*sin(phi)*par.Bn; //xinc
  par.param1[phi][2] = par.cT*cos(phi)*par.Bn; //yinc

  for(j=1;j<=par.param1[phi][0];j++){

      pj = -Np * cP + (j - 1) * cP;

      t1y = -((Mhe - (pj * cos(phi)))/sin(phi));
      t1x = -((Nhe + (pj * sin(phi)))/cos(phi));
      t2y = ((Mhe + (pj * cos(phi)))/sin(phi));
      t2x = ((Nhe - (pj * sin(phi)))/cos(phi));

      par.prueba[phi][j-1][0] = ceil(fmax(t1y,t1x)/par.cT); //tbegin
      par.prueba[phi][j-1][1] = floor(fmin(t2y,t2x)/par.cT); //tend

      par.prueba[phi][j-1][2] = floor((Cx + pj * cos(phi)) * par.Bn + 0.5 + (par.param1[phi][1] * par.prueba[phi][j-1][0])) + par.Bn/2; //xb
      par.prueba[phi][j-1][3] = floor((Cy + pj * sin(phi)) * par.Bn + 0.5 + (par.param1[phi][2] * par.prueba[phi][j-1][0])) + par.Bn/2; //yb

      if(j!=par.param1[phi][0]){
          par.prueba[phi][j] = (int *)malloc( 4 * sizeof ( int ) );

          if(par.prueba[phi][j]==NULL){
            printf("¡Fallo al asignar memoria! %d %d\n",phi,j);
            exit(2);
          }
      }

   }

    }

    //----------- Precomputar φ = 90 --------------//

    int tendbeg;

    Np = floor(Nhe/cP);

    par.param1[90][0] = 2 * Np + 1; //NP

    par.prueba[90] = (int **)malloc( par.param1[90][0]* sizeof ( int * ) );

    if(par.prueba[90]==NULL){
     printf("¡Fallo al asignar memoria! 90\n");
     exit(2);
    }

    par.prueba[90][0] = (int *)malloc( 4 * sizeof ( int ) );

    if(par.prueba[90][0]==NULL){
    printf("¡Fallo al asignar memoria! 90\n");
    exit(2);
    }


    par.prueba[90][0][1] = floor(Mhe/par.cT); //tend

    par.prueba[90][0][0] = -par.prueba[90][0][1]; //tbegin

    tendbeg = par.prueba[90][0][1] - par.prueba[90][0][0];

    par.param1[90][1] = -par.cT * par.Bn; //xinc

    par.param1[90][2] = 0; //yinc

    par.prueba[90][0][2] = floor(Cx * par.Bn + par.param1[90][1] * par.prueba[90][0][0] + 0.5) + par.param1[90][1] * par.Bn + par.Bn/2; //xb

    //----------- Calcular φ = 90 --------------//

    for(j=1;j<=par.param1[90][0];j++){

     pj = -Np * cP + (j - 1) * cP; //aquí va de -NpcP hasta NpcP

     par.prueba[90][j-1][3] = floor((Cy + pj) * par.Bn + 0.5) + par.Bn/2; //se guarda cada valor de cada línea //yb

     if(j!=par.param1[90][0]){
     par.prueba[90][j] = (int *)malloc( 4 * sizeof ( int ) );

     if(par.prueba[90][j]==NULL){
        printf("¡Fallo al asignar memoria! 90 %d\n",j);
        exit(2);
     }
      }

     }

     //----------- Precomputar y calcular 90 < φ < 180 --------------//

     phi = 91;

     for(;phi<180;phi++){
     Pmax = Mhe * fabs(cos(phi)) + Nhe * fabs(sin(phi));

     Np = floor(Pmax/cP);

     par.param1[phi][0] = 2 * Np + 1; //NP

     par.prueba[phi] = (int **)malloc( par.param1[phi][0]* sizeof ( int * ) );

     if(par.prueba[phi]==NULL){
    printf("¡Fallo al asignar memoria! %d\n",phi);
    exit(2);
     }

         par.prueba[phi][0] = (int *)malloc( 4 * sizeof ( int ) );

         if(par.prueba[phi][0]==NULL){
           printf("¡Fallo al asignar memoria! %d\n",phi);
           exit(2);
         }

     par.param1[phi][1] = -(par.cT*sin(phi)*par.Bn); //xinc
     par.param1[phi][2] = par.cT*cos(phi)*par.Bn; //yinc

     for(j=1;j<=par.param1[phi][0];j++){

      pj = -Np * cP + (j - 1) * cP;

      t1y = -((Mhe - (pj * cos(phi)))/sin(phi));
      t1x = ((Nhe - (pj * sin(phi)))/cos(phi));
      t2y = ((Mhe + (pj * cos(phi)))/sin(phi));
      t2x = -((Nhe + (pj * sin(phi)))/cos(phi));

      par.prueba[phi][j-1][0] = ceil(fmax(t1y,t1x)/par.cT); //tbegin
      par.prueba[phi][j-1][1] = floor(fmin(t2y,t2x)/par.cT); //tend

      par.prueba[phi][j-1][2] = floor((Cx + pj * cos(phi)) * par.Bn + 0.5 + (par.param1[phi-1][1] * par.prueba[phi][j-1][0])) + par.Bn/2; //xb
      par.prueba[phi][j-1][3] = floor((Cy + pj * sin(phi)) * par.Bn + 0.5 + (par.param1[phi-1][2] * par.prueba[phi][j-1][0])) + par.Bn/2; //yb

      if(j!=par.param1[phi][0]){
        par.prueba[phi][j] = (int *)malloc( 4 * sizeof ( int ) );

        if(par.prueba[phi][j]==NULL){
            printf("¡Fallo al asignar memoria! %d %d\n",phi,j);
            exit(2);
        }
      }


  }

    }

    //----------- Precomputar φ = 180 --------------//

    Np = floor(Mhe/cP);

    par.param1[180][0] = 2*Np + 1; //NP de 0 grados

    par.prueba[180] = (int **)malloc( par.param1[180][0]* sizeof ( int * ) );

    if(par.prueba[180]==NULL){
    printf("¡Fallo al asignar memoria! 180\n");
    exit(2);
    }

    par.prueba[180][0] = (int *)malloc( 4 * sizeof ( int ) );

    if(par.prueba[180][0]==NULL){
    printf("¡Fallo al asignar memoria! 180\n");
    exit(2);
    }

    par.prueba[180][0][0] = -floor(Nhe/par.cT); //tbegin  //-tend de 0 grados

    par.prueba[180][0][1] = -par.prueba[180][0][0]; //tend  //-tbegin de 0 grados

    par.param1[180][1] = 0; //xinc

    par.param1[180][2] = -(par.cT * par.Bn); //yinc

    par.prueba[180][0][3] = floor((Cy - par.prueba[180][0][0] * par.cT) * par.Bn + 0.5) + par.Bn/2; //yb

    //------------ Calcular φ = 180 ----------------//


    for(j=1;j<=par.param1[180][0];j++){

    pj = -Np * cP + (j - 1) * cP; //aquí va de -NpcP hasta NpcP

    par.prueba[180][j-1][2] = floor((Cx - pj) * par.Bn + 0.5) + par.Bn/2; //se guarda cada valor de cada línea //xb

    if(j!=par.param1[180][0]){
    par.prueba[180][j] = (int *)malloc( 4 * sizeof ( int ) );

    if(par.prueba[180][j]==NULL){
        printf("¡Fallo al asignar memoria! 180 %d\n",j);
        exit(2);
    }
    }
    }

    //----------- Precomputar y calcular 180 < φ < 270 --------------//

   phi = 181;

   for(;phi<270;phi++){
  Pmax = Mhe * fabs(cos(phi)) + Nhe * fabs(sin(phi));

  Np = floor(Pmax/cP);

  par.param1[phi][0] = 2 * Np + 1; //NP

  par.prueba[phi] = (int **)malloc( par.param1[phi][0]* sizeof ( int * ) );

  if(par.prueba[phi]==NULL){
    printf("¡Fallo al asignar memoria! %d\n",phi);
    exit(2);
  }

  par.prueba[phi][0] = (int *)malloc( 4 * sizeof ( int ) );

  if(par.prueba[phi][0]==NULL){
    printf("¡Fallo al asignar memoria! %d 0\n",phi);
    exit(2);
  }

  par.param1[phi][1] = -(par.cT*sin(phi)*par.Bn); //xinc
  par.param1[phi][2] = par.cT*cos(phi)*par.Bn; //yinc

  for(j=1;j<=par.param1[phi][0];j++){

      pj = -Np * cP + (j - 1) * cP;

      t1y = ((Mhe + (pj * cos(phi)))/sin(phi));
      t1x = ((Nhe - (pj * sin(phi)))/cos(phi));
      t2y = -((Mhe - (pj * cos(phi)))/sin(phi));
      t2x = -((Nhe + (pj * sin(phi)))/cos(phi));

      par.prueba[phi][j-1][0] = ceil(fmax(t1y,t1x)/par.cT); //tbegin
      par.prueba[phi][j-1][1] = floor(fmin(t2y,t2x)/par.cT); //tend

      par.prueba[phi][j-1][2] = floor((Cx + pj * cos(phi)) * par.Bn + 0.5 + (par.param1[phi-1][1] * par.prueba[phi][j-1][0])) + par.Bn/2; //xb
      par.prueba[phi][j-1][3] = floor((Cy + pj * sin(phi)) * par.Bn + 0.5 + (par.param1[phi-1][2] * par.prueba[phi][j-1][0])) + par.Bn/2; //yb

      if(j!=par.param1[phi][0]){
          par.prueba[phi][j] = (int *)malloc( 4 * sizeof ( int ) );

          if(par.prueba[phi][j]==NULL){
            printf("¡Fallo al asignar memoria! %d %d\n",phi,j);
            exit(2);
          }
      }


  }

   }

   //----------- Precomputar φ = 270 --------------//

   Np = floor(Nhe/cP);

   par.param1[270][0] = 2 * Np + 1; //NP //NP del angulo de 90 param1[90][0]

   par.prueba[270] = (int **)malloc( par.param1[270][0]* sizeof ( int * ) );

   if(par.prueba[270]==NULL){
printf("¡Fallo al asignar memoria! 270\n");
exit(2);
   }

   par.prueba[270][0] = (int *)malloc( 4 * sizeof ( int ) );

   if(par.prueba[270][0]==NULL){
 printf("¡Fallo al asignar memoria! 270\n");
 exit(2);
   }

   par.prueba[270][0][1] = floor(Mhe/par.cT); //tend //-tbegin del angulo de 90

   par.prueba[270][0][0] = -par.prueba[270][0][1]; //tbegin //-tend del angulo de 90

   par.param1[270][1] = par.cT * par.Bn; //xinc

   par.param1[270][2] = 0; //yinc

   par.prueba[270][0][2] = floor(Cx * par.Bn + par.param1[270][1] * par.prueba[270][0][0] + 0.5) + par.Bn/2; //xb

   //----------- Calcular φ = 270 --------------//

   for(j=1;j<=par.param1[270][0];j++){

   pj = -Np * cP + (j - 1) * cP; //aquí va de -NpcP hasta NpcP

   par.prueba[270][j-1][3] = floor((Cy - pj) * par.Bn + 0.5) + par.Bn/2; //se guarda cada valor de cada línea //yb

   if(j!=par.param1[270][0]){
     par.prueba[270][j] = (int *)malloc( 4 * sizeof ( int ) );

     if(par.prueba[270][j]==NULL){
        printf("¡Fallo al asignar memoria! 270 %d\n",j);
        exit(2);
     }
   }
   }


   //----------- Precomputar y calcular 270 < φ < 360 --------------//


   for(;phi<360;phi++){
   Pmax = Mhe * fabs(cos(phi)) + Nhe * fabs(sin(phi));

   Np = floor(Pmax/cP);

   par.param1[phi][0] = 2 * Np + 1; //NP

   par.prueba[phi] = (int **)malloc( par.param1[phi][0]* sizeof ( int * ) );

   if(par.prueba[phi]==NULL){
    printf("¡Fallo al asignar memoria! %d\n",phi);
    exit(2);
   }

   par.prueba[phi][0] = (int *)malloc( 4 * sizeof ( int ) );

   if(par.prueba[phi][0]==NULL){
    printf("¡Fallo al asignar memoria! %d\n",phi);
    exit(2);
   }


   par.param1[phi][1] = -(par.cT*sin(phi)*par.Bn); //xinc
   par.param1[phi][2] = par.cT*cos(phi)*par.Bn; //yinc

   for(j=1;j<=par.param1[phi][0];j++){

      pj = -Np * cP + (j - 1) * cP;

      t1y = (Mhe + (pj * cos(phi)))/sin(phi);
      t1x = -((Nhe + (pj * sin(phi)))/cos(phi));
      t2y = -((Mhe - (pj * cos(phi)))/sin(phi));
      t2x = (Nhe - (pj * sin(phi)))/cos(phi);

      par.prueba[phi][j-1][0] = ceil(fmax(t1y,t1x)/par.cT); //tbegin
      par.prueba[phi][j-1][1] = floor(fmin(t2y,t2x)/par.cT); //tend

      par.prueba[phi][j-1][2] = floor((Cx + pj * cos(phi)) * par.Bn + 0.5 + (par.param1[phi-1][1] * par.prueba[phi][j-1][0])) + par.Bn/2; //xb
      par.prueba[phi][j-1][3] = floor((Cy + pj * sin(phi)) * par.Bn + 0.5 + (par.param1[phi-1][2] * par.prueba[phi][j-1][0])) + par.Bn/2; //yb

      if(j!=par.param1[phi][0]){
          par.prueba[phi][j] = (int *)malloc( 4 * sizeof ( int ) );

          if(par.prueba[phi][j]==NULL){
            printf("¡Fallo al asignar memoria! %d %d\n",phi,j);
            exit(2);
          }
      }


  }

   }


 }

 void computar_transformadas(GtkWidget *widget, GdkEventButton *event, gpointer callback_data){

int tendbegin;
int xi;
int yi;
    int ti;
int phi;
int j;
int o;
int sale=0;//variable para salir del for de tendbegin en los casos especiales
int entra = 0;

for(phi = 0; phi < 360;phi++){ //todos los ángulos
    e = par.cT;

    sale = 0;

    par.pixels[phi] = (int ***)malloc( par.param1[phi][0]* sizeof ( int ** ) );

    if(par.pixels[phi]==NULL){
        printf("¡Fallo al asignar memoria! (pixels) %d\n",phi);
        exit(2);
    }


    for(j=0; (sale != 1); j++){  //todas las líneas

         tendbegin = par.prueba[phi][j][1]-par.prueba[phi][j][0];

             par.pixels[phi][j] = (int **)malloc( tendbegin * sizeof ( int * ) );

         if(par.pixels[phi][j]==NULL){
        printf("¡Fallo al asignar memoria! (pixels) %d %d\n",phi,j);
        exit(2);
         }


         if(phi==0 || phi==90 || phi==180 || phi==270 || phi==360 || j==(par.param1[phi][0]-1)){
          sale = 1;
         }

         entra=0;

         for(o=0; o < tendbegin;o++){ 

        par.pixels[phi][j][o] = (int *)malloc( 2 * sizeof ( int ) );

        if(par.pixels[phi][j][o]==NULL){
                printf("¡Fallo al asignar memoria! (pixels) %d %d %d\n",phi,j,o);
            exit(2);
        }

        ti = (par.prueba[phi][j][0] + o)*par.cT;

        xi = par.prueba[phi][j][2] + floor(o*par.param1[phi][1]);
        yi = par.prueba[phi][j][3] + floor(o*par.param1[phi][2]);

        par.pixels[phi][j][o][0] = floor(xi/par.Bn);//ii//para enviarlos a las funcionales se guardan en matriz
        par.pixels[phi][j][o][1] = floor(yi/par.Bn);//ji

        if(o == (tendbegin/2)){
          entra=1;
        }

        if(o==tendbegin-1){
          suma(par.pixels[phi][j],o, entra);

        }


         }


        }
   }


int y;
int t;
int p;

for(y=0;y<360;y++){

  for(t=0;t<par.param1[y][0];t++){


      free(par.prueba[y][t]);

      for(p=0;p<4;p++){
         free(par.pixels[y][t][p]);
      }


      free(par.pixels[y][t]);


  }

  free(par.prueba[y]);
  free(par.pixels[y]);

    }


gdk_pixbuf_save(pixbuf,"/path/to/image/prueba.png","png",NULL,NULL);



 }

 void suma(int** trazo,int o,int entra){

int i;
int gris;
int temp=0;

for(i=0;i<o;i++){

    p = pixs + trazo[i][1]/*y*/ * rowstride + trazo[i][0]/*x*/ * n_channels;//para colocarse en la imagen
    gris=0.2989 * p[0] + 0.5870 * p[1] + 0.1140 * p[2]; //para transofrmar de RGB a escala de gris

    if(entra ==1){
     p[0]=(guchar)50;
     p[1]=(guchar)0;
     p[2]=(guchar)0;
     }

     entra = 0;


     temp=rowstride;

     }

 }

  void ClickCallback(GtkWidget *widget, GdkEventButton *event, gpointer callback_data)
  {
/*-- Create the selector widget --*/
file_selection_box = gtk_file_chooser_dialog_new("Porfavor seleccione un archivo.",NULL,GTK_FILE_CHOOSER_ACTION_OPEN,GTK_STOCK_CANCEL, GTK_RESPONSE_CANCEL, GTK_STOCK_OPEN, GTK_RESPONSE_ACCEPT, NULL);


if (gtk_dialog_run (GTK_DIALOG (file_selection_box)) == GTK_RESPONSE_ACCEPT)
   {
     // char *filename;
      filename = gtk_file_chooser_get_filename (GTK_FILE_CHOOSER (file_selection_box));
      open_file(filename);
      g_free (filename);
}
gtk_widget_destroy (file_selection_box);
  }

  static void destroy_event(GtkWidget *widget, gpointer data)
  {
   gtk_main_quit();
  }

  static gboolean delete_event(GtkWidget *widget, GdkEvent *event, gpointer data)
  {
   return FALSE; // must return false to trigger destroy event for window
  }
share|improve this question
    
It's unclear how variables prueba and param1 are declared and initialized. Please share that code before we can help further. Until then, one thing that jumps out is that you're missing initial value for j in the loop. Is this done on purpose? If j never happens to be 0, then prueba[0][0] will never be initialized. –  George Skoptsov Mar 14 '12 at 17:58
    
Do you ever loop through par.preuba and free all the memory? You need a call to free for every call to malloc, so if you call malloc in a loop you need to call free in a loop/recursion that will definitely call it exactly the same number of times as malloc was called previously. –  Paulpro Mar 14 '12 at 18:01
    
Thanks! Ok I edited the OP to clarify somethings... –  Atirag Mar 14 '12 at 19:47
    
You have to free all dynamically allocated memory, otherwise it will leak. Only local/static arrays does not need free(). Please post your full code that can be compiled so we can actually see what are you trying to do. (your code samples are really confusing). For example: par.param1[0][0] = 2*Np + 1; //Np is initialized before par.prueba[0] = (int *)malloc( par.param1[0][0] sizeof ( int * ) ); This is really weird, you try to write into something and then malloc? Store size in some variable or use malloc((2*Np + 1)*sizeof(int*)); –  AoeAoe Mar 14 '12 at 20:10
    
I use the value of par.param1[0][0] which is (2*Np + 1) to set the size of par.prueba[0]. I'll try to post the whole code although it is pretty long. I also freed the memory like I show on the edit but it doesn't work. –  Atirag Mar 14 '12 at 20:18

1 Answer 1

up vote 1 down vote accepted

First you need to allocate array for pointers to arrays (char **), then you need alocate each "row" one by one.

int **array = malloc(nrows * sizeof(int *));
assert(array);
for (int i=0; i < nrows; i++)
{
    array[i]= malloc(nbars * sizeof(int));
    assert(array[i]);
}

To free you will need to do this backwards, eg free each line and then free array of pointers:

for (int i=0; i < nrows; i++)
    free(array[i]);

free(array);

Basically, these are not really "true arrays" (by C definition), but instead of having 2D array as whole, you got one array that holds it together (type **) and multiple (type *) arrays that holds informations stored in "row".

Heres example of 3x3 array, --> stands for (points to).

a[0] --> b[0],b[1],b[2]
a[1] --> c[0],c[1],c[2]
a[2] --> d[0],d[1],d[2]
share|improve this answer
    
It should be noted that your allocation code assumes all allocations succeed. Writing a failed-allocation-safe version either requires using xalloc (a common but nonstandard wrapper around malloc that is essentially void *p = malloc(size); if(p) return p; else exit(1);) or making the allocation logic significantly more complex. –  Chris Lutz Mar 14 '12 at 18:14
    
For simplicity sake I did asserts and thus on allocation error it would fail. I think xalloc is not in current C standard, thus I would not recommend using it (for learning purposes). –  AoeAoe Mar 14 '12 at 18:17
    
My bad, I totally missed the asserts (I'm not a huge fan of asserts myself). I don't normally recommend it but a lot of people like defining it for their projects, and in this case it makes the code significantly cleaner, especially if the OP is just going to exit on malloc failure anyway. –  Chris Lutz Mar 14 '12 at 18:19
    
I edited the OP to clarify the code more. I appreciate the help! –  Atirag Mar 14 '12 at 19:48
    
I checked where I was freeing memory and I was making a mistake. It's now working. So thx! –  Atirag Mar 16 '12 at 21:12

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