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Summary

Description
English: Julia set . Construction of polynomial (location) and precise description by Marc Meidlinger: "Cubic parabolic set with interior"[1] "The polynomial has been constructed to have a parabolic fix point at the origin (f`=1) and an attracting cycle at x=1."
Date
Source Own work
Author Adam majewski

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c source code

/*

  Adam Majewski
  adammaj1 aaattt o2 dot pl  // o like oxygen not 0 like zero 
  
  
  


"Cubic parabolic set with interior"

The polynomial f(z)=z+(1/2)*z^2−(1/2)*z^3 has been constructed to have a parabolic fix point at the origin (f`=1) and an attracting cycle at x=1. For this set, the TSA (after some modifications) can detect interior (see image below, immediate basin of the parabolic fix point in yellow).

https://fractalforums.org/fractal-mathematics-and-new-theories/28/parabolic-julia-sets/3091/msg23033#msg23033



coefficients read from input file cubic_parab.txt
	degree 3 coefficient = ( -0.5000000000000000 +0.0000000000000000*i) 
	degree 2 coefficient = ( +0.5000000000000000 +0.0000000000000000*i) 
	degree 1 coefficient = ( +1.0000000000000000 +0.0000000000000000*i) 

Input polynomial p(z)=(-0.5+0i)*z^3+(0.5+0i)*z^2+(1+0i)*z^1

2 critical points found

	cp#0: -0.54858377035486349804,3.0709403358457930956e-22 . It's critical orbit is bounded and enters cycle #0 length=1 and it's stability = |multiplier|=0.99992 =parabolic 
cycle = {
-7.9907621648727658256e-05,1.6594893104474807034e-45 ; }

	cp#1: 1.2152504370215302387,2.9560397788833490951e-23 . It's critical orbit is bounded and enters cycle #1 length=1 and it's stability = |multiplier|=0.5 =attractive 
cycle = {
1,0 ; }
  
  
  Structure of a program or how to analyze the program 
  
  
  ============== Image X ========================
  
  DrawImageOfX -> DrawPointOfX -> ComputeColorOfX 
  
  first 2 functions are identical for every X
  check only last function =  ComputeColorOfX
  which computes color of one pixel !
  
  

   
  ==========================================

  
  ---------------------------------
  indent d.c 
  default is gnu style 
  -------------------



  c console progam 
  
	export  OMP_DISPLAY_ENV="TRUE"	
  	gcc d.c -lm -Wall -march=native -fopenmp
  	time ./a.out > b.txt


  gcc d.c -lm -Wall -march=native -fopenmp


  time ./a.out

  time ./a.out >i.txt
  time ./a.out >e.txt
  
  
  
  
  
  
  convert -limit memory 1000mb -limit disk 1gb dd30010000_20_3_0.90.pgm -resize 2000x2000 10.png

  
  
  
*/

#include <stdio.h>
#include <stdlib.h>		// malloc
#include <string.h>		// strcat
#include <math.h>		// M_PI; needs -lm also
#include <complex.h>
#include <omp.h>		// OpenMP
#include <limits.h>		// Maximum value for an unsigned long long int



// https://sourceforge.net/p/predef/wiki/Standards/

#if defined(__STDC__)
#define PREDEF_STANDARD_C_1989
#if defined(__STDC_VERSION__)
#if (__STDC_VERSION__ >= 199409L)
#define PREDEF_STANDARD_C_1994
#endif
#if (__STDC_VERSION__ >= 199901L)
#define PREDEF_STANDARD_C_1999
#endif
#endif
#endif




/* --------------------------------- global variables and consts ------------------------------------------------------------ */



// virtual 2D array and integer ( screen) coordinate
// Indexes of array starts from 0 not 1 
//unsigned int ix, iy; // var
static unsigned int ixMin = 0;	// Indexes of array starts from 0 not 1
static unsigned int ixMax;	//
static unsigned int iWidth;	// horizontal dimension of array

static unsigned int iyMin = 0;	// Indexes of array starts from 0 not 1
static unsigned int iyMax;	//

static unsigned int iHeight = 5000;	//  
// The size of array has to be a positive constant integer 
static unsigned long long int iSize;	// = iWidth*iHeight; 

// memmory 1D array 
unsigned char *data;
unsigned char *edge;
//unsigned char *edge2;

// unsigned int i; // var = index of 1D array
//static unsigned int iMin = 0; // Indexes of array starts from 0 not 1
static unsigned int iMax;	// = i2Dsize-1  = 
// The size of array has to be a positive constant integer 
// unsigned int i1Dsize ; // = i2Dsize  = (iMax -iMin + 1) =  ;  1D array with the same size as 2D array


// dx = 2*dy compare setup : iWidth = iHeight*2;
static const double ZxMin = -2.2;	//-0.05;
static const double ZxMax = 2.6;	//0.75;
static const double ZyMin = -1.2;	//-0.1;
static const double ZyMax = 1.2;	//0.7;
static double PixelWidth;	// =(ZxMax-ZxMin)/ixMax;
static double PixelHeight;	// =(ZyMax-ZyMin)/iyMax;
static double ratio;


/*
ER = pow(10,ERe);
   AR = pow(10,-ARe);
 */
//int ARe ;			// increase ARe until black ( unknown) points disapear 
//int ERe ;
double ER;
double ER2;			//= 1e60;
double AR; // bigger values do not works
double AR2;
double AR12;



int IterMax = 100000;


/* colors = shades of gray from 0 to 255 

 unsigned char colorArray[2][2]={{255,231},    {123,99}};
 color = 245;  exterior 
*/
unsigned char iColorOfExterior = 245;
unsigned char iColorOfInterior1 = 99;
unsigned char iColorOfInterior2 = 183;
unsigned char iColorOfBoundary = 0;
unsigned char iColorOfUnknown = 5;

// pixel counters
unsigned long long int uUnknown = 0;
unsigned long long int uInterior = 0;
unsigned long long int uExterior = 0;



// periodic points = attractors
complex double zp=0.0;
complex double za= 1.0;

/* ------------------------------------------ functions -------------------------------------------------------------*/





//------------------complex numbers -----------------------------------------------------





// from screen to world coordinate ; linear mapping
// uses global cons
double
GiveZx (int ix)
{
  return (ZxMin + ix * PixelWidth);
}

// uses globaal cons
double
GiveZy (int iy)
{
  return (ZyMax - iy * PixelHeight);
}				// reverse y axis


complex double
GiveZ (int ix, int iy)
{
  double Zx = GiveZx (ix);
  double Zy = GiveZy (iy);

  return Zx + Zy * I;




}



double cabs2(complex double z){

	return creal(z)*creal(z)+cimag(z)*cimag(z);


}






// =====================
int IsPointInsideTrap1(complex double  z){

	
	 
	
	if ( cabs2(z+AR12)<AR2) {return 1;} // circle with prabolic point zp on it's boundary
	return 0; // outside



}



// =====================
int IsPointInsideTrap2(complex double  z){

	
	if (cabs2(z - za) <AR2) {return 1;} // circle around periodic point
	
	return 0; // outside



}









// ****************** DYNAMICS = trap tests ( target sets) ****************************


/* -----------  array functions = drawing -------------- */

/* gives position of 2D point (ix,iy) in 1D array  ; uses also global variable iWidth */
unsigned int
Give_i (unsigned int ix, unsigned int iy)
{
  return ix + iy * iWidth;
}



// f(z)=1+z−3z2−3.75z3+1.5z4+2.25z5
unsigned char
ComputeColor_Fatou (complex double z, int IterMax)
{



	complex double z2;
	complex double z3;
	double r2;


  	int i;			// number of iteration
  	for (i = 0; i < IterMax; ++i)
    	{


		z2 = z*z;
		z3 = z*z2;

      		z = z +0.5*z2 -0.5*z3;		// complex iteration =z+(1/2)*z^2−(1/2)*z^3 
		r2 =cabs2(z);
		
      		if (r2 > ER2) // esaping = exterior
		{
	  		uExterior += 1;
	  		return iColorOfExterior;
		}			
	
		if ( IsPointInsideTrap1(z)) {
			uInterior +=1;
			return iColorOfInterior1;}
	
		if (IsPointInsideTrap2(z)){
			uInterior +=1;
			return iColorOfInterior2;}




    	}

  	uUnknown += 1;
  	return iColorOfUnknown;


}





// plots raster point (ix,iy) 
int
DrawFatouPoint (unsigned char A[], int ix, int iy, int IterMax)
{
  int i;			/* index of 1D array */
  unsigned char iColor = 0;
  complex double z;


  i = Give_i (ix, iy);		/* compute index of 1D array from indices of 2D array */
  z = GiveZ (ix, iy);
  iColor = ComputeColor_Fatou (z, IterMax);
  A[i] = iColor;		// interior

  return 0;
}




// fill array 
// uses global var :  ...
// scanning complex plane 
int
DrawFatouImage (unsigned char A[], int IterMax)
{
  unsigned int ix, iy;		// pixel coordinate 

  fprintf (stdout, "compute Fatou image \n");
  // for all pixels of image 
#pragma omp parallel for schedule(dynamic) private(ix,iy) shared(A, ixMax , iyMax, uUnknown, uInterior, uExterior)
  for (iy = iyMin; iy <= iyMax; ++iy)
    {
      fprintf (stderr, " %d from %d \r", iy, iyMax);	//info 
      for (ix = ixMin; ix <= ixMax; ++ix)
	DrawFatouPoint (A, ix, iy, IterMax);	//  
    }

  return 0;
}


//=========



int IsInside (int x, int y, int xcenter, int ycenter, int r){

	
	double dx = x- xcenter;
	double dy = y - ycenter;
	double d = sqrt(dx*dx+dy*dy);
	if (d<r) 
		return 1;
	return 0;
	  

} 

int PlotBigPoint(complex double z, unsigned char A[]){

	
	unsigned int ix_seed = (creal(z)-ZxMin)/PixelWidth;
	unsigned int iy_seed = (ZyMax - cimag(z))/PixelHeight;
	unsigned int i;
	
	
	 /* mark seed point by big pixel */
  	int iSide =3.0*iWidth/2000.0 ; /* half of width or height of big pixel */
  	int iY;
  	int iX;
  	for(iY=iy_seed-iSide;iY<=iy_seed+iSide;++iY){ 
    		for(iX=ix_seed-iSide;iX<=ix_seed+iSide;++iX){ 
    			if (IsInside(iX, iY, ix_seed, iy_seed, iSide)) {
      			i= Give_i(iX,iY); /* index of _data array */
      			A[i]= 255-A[i];}}}
	
	
	return 0;
	
}


// fill array 
// uses global var :  ...
// scanning complex plane 
int MarkAttractors (unsigned char A[])
{
  
	
	
	
  	fprintf (stderr, "mark attractors \n");
  
  	PlotBigPoint(zp, A); // period 3 parabolic cycle
    	PlotBigPoint(za, A);	// period 3 attracting cycle
    		 
      	

  	return 0;
}


// =====================
int IsPointInsideTraps(unsigned int ix, unsigned int iy){

	
	complex double  z = GiveZ (ix, iy);
	
	if ( IsPointInsideTrap1(z)) {return 1;} // circle with prabolic point on it's boundary
	
	if (IsPointInsideTrap2(z)) {return 1;}
	
	return 0; // outside



}





int MarkTraps(unsigned char A[]){

	unsigned int ix, iy;		// pixel coordinate 
	unsigned int i;


  	fprintf (stderr, "Mark traps \n");
  	// for all pixels of image 
	#pragma omp parallel for schedule(dynamic) private(ix,iy) shared(A, ixMax , iyMax, uUnknown, uInterior, uExterior)
  	for (iy = iyMin; iy <= iyMax; ++iy)
    	{
      		fprintf (stderr, " %d from %d \r", iy, iyMax);	//info 
      		for (ix = ixMin; ix <= ixMax; ++ix){
			if (IsPointInsideTraps(ix, iy)) {
      				i= Give_i(ix,iy); /* index of _data array */
      				A[i]= 255-A[i]; // inverse color
      				}}}
  	return 0;
}






int PlotPoint(complex double z, unsigned char A[]){

	
	unsigned int ix = (creal(z)-ZxMin)/PixelWidth;
	unsigned int iy = (ZyMax - cimag(z))/PixelHeight;
	unsigned int i = Give_i(ix,iy); /* index of _data array */
	
	
	A[i]= 255-A[i]; // Mark point with inveres color
	
	
	return 0;
	
}




// ***********************************************************************************************
// ********************** edge detection usung Sobel filter ***************************************
// ***************************************************************************************************

// from Source to Destination
int ComputeBoundaries(unsigned char S[], unsigned char D[])
{
 
  unsigned int iX,iY; /* indices of 2D virtual array (image) = integer coordinate */
  unsigned int i; /* index of 1D array  */
  /* sobel filter */
  unsigned char G, Gh, Gv; 
  // boundaries are in D  array ( global var )
 
  // clear D array
  memset(D, iColorOfExterior, iSize*sizeof(*D)); // for heap-allocated arrays, where N is the number of elements = FillArrayWithColor(D , iColorOfExterior);
 
  // printf(" find boundaries in S array using  Sobel filter\n");   
#pragma omp parallel for schedule(dynamic) private(i,iY,iX,Gv,Gh,G) shared(iyMax,ixMax)
  for(iY=1;iY<iyMax-1;++iY){ 
    for(iX=1;iX<ixMax-1;++iX){ 
      Gv= S[Give_i(iX-1,iY+1)] + 2*S[Give_i(iX,iY+1)] + S[Give_i(iX-1,iY+1)] - S[Give_i(iX-1,iY-1)] - 2*S[Give_i(iX-1,iY)] - S[Give_i(iX+1,iY-1)];
      Gh= S[Give_i(iX+1,iY+1)] + 2*S[Give_i(iX+1,iY)] + S[Give_i(iX-1,iY-1)] - S[Give_i(iX+1,iY-1)] - 2*S[Give_i(iX-1,iY)] - S[Give_i(iX-1,iY-1)];
      G = sqrt(Gh*Gh + Gv*Gv);
      i= Give_i(iX,iY); /* compute index of 1D array from indices of 2D array */
      if (G==0) {D[i]=255;} /* background */
      else {D[i]=0;}  /* boundary */
    }
  }
 
   
 
  return 0;
}



// copy from Source to Destination
int CopyBoundaries(unsigned char S[],  unsigned char D[])
{
 
  unsigned int iX,iY; /* indices of 2D virtual array (image) = integer coordinate */
  unsigned int i; /* index of 1D array  */
 
 
  //printf("copy boundaries from S array to D array \n");
  for(iY=1;iY<iyMax-1;++iY)
    for(iX=1;iX<ixMax-1;++iX)
      {i= Give_i(iX,iY); if (S[i]==0) D[i]=0;}
 
 
 
  return 0;
}
















// *******************************************************************************************
// ********************************** save A array to pgm file ****************************
// *********************************************************************************************

int
SaveArray2PGMFile (unsigned char A[], int a, int b,  int c, char *comment)
{

  FILE *fp;
  const unsigned int MaxColorComponentValue = 255;	/* color component is coded from 0 to 255 ;  it is 8 bit color file */
  char name[100];		/* name of file */
  snprintf (name, sizeof name, "%d_%d_%d", a, b, c );	/*  */
  char *filename = strcat (name, ".pgm");
  char long_comment[200];
  sprintf (long_comment, "fc(z)= z+(1/2)*z^2−(1/2)*z^3  ; %s\tER = %e\tAR =%e", comment, ER, AR);





  // save image array to the pgm file 
  fp = fopen (filename, "wb");	// create new file,give it a name and open it in binary mode 
  fprintf (fp, "P5\n # %s\n %u %u\n %u\n", long_comment, iWidth, iHeight, MaxColorComponentValue);	// write header to the file
  fwrite (A, iSize, 1, fp);	// write array with image data bytes to the file in one step 
  fclose (fp);

  // info 
  printf ("File %s saved ", filename);
  if (long_comment == NULL || strlen (long_comment) == 0)
    printf ("\n");
  else
    printf (". Comment = %s \n", long_comment);

  return 0;
}




int
PrintCInfo ()
{

  printf ("gcc version: %d.%d.%d\n", __GNUC__, __GNUC_MINOR__, __GNUC_PATCHLEVEL__);	// https://stackoverflow.com/questions/20389193/how-do-i-check-my-gcc-c-compiler-version-for-my-eclipse
  // OpenMP version is displayed in the console : export  OMP_DISPLAY_ENV="TRUE"

  printf ("__STDC__ = %d\n", __STDC__);
  printf ("__STDC_VERSION__ = %ld\n", __STDC_VERSION__);
  printf ("c dialect = ");
  switch (__STDC_VERSION__)
    {				// the format YYYYMM 
    case 199409L:
      printf ("C94\n");
      break;
    case 199901L:
      printf ("C99\n");
      break;
    case 201112L:
      printf ("C11\n");
      break;
    case 201710L:
      printf ("C18\n");
      break;
      //default : /* Optional */

    }

  return 0;
}


int
PrintProgramInfo ()
{


  // display info messages
  printf ("Numerical approximation of Julia set for fc(z)= z+(1/2)*z^2−(1/2)*z^3  \n");
  //printf ("iPeriodParent = %d \n", iPeriodParent);
  //printf ("iPeriodOfChild  = %d \n", iPeriodChild);
  //printf ("parameter c = ( %.16f ; %.16f ) \n", creal (c), cimag (c));

  printf ("Image Width = %f in world coordinate\n", ZxMax - ZxMin);
  printf ("PixelWidth = %.16f \n", PixelWidth);
  printf ("AR = %.16f = %f *PixelWidth\n", AR, AR / PixelWidth);


  printf("pixel counters\n");
  printf ("uUnknown = %llu\n", uUnknown);
  printf ("uExterior = %llu\n", uExterior);
  printf ("uInterior = %llu\n", uInterior);
  printf ("Sum of pixels  = %llu\n", uInterior+uExterior + uUnknown);
  printf ("all pixels of the array = iSize = %llu\n", iSize);


  // image corners in world coordinate
  // center and radius
  // center and zoom
  // GradientRepetition
  printf ("Maximal number of iterations = iterMax = %d \n", IterMax);
  printf ("ratio of image  = %f ; it should be 1.000 ...\n", ratio);
  //




  return 0;
}






// *****************************************************************************
//;;;;;;;;;;;;;;;;;;;;;;  setup ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;
// **************************************************************************************

int
setup ()
{

  fprintf (stderr, "setup start\n");






  /* 2D array ranges */

  iWidth = iHeight*2;
  iSize = iWidth * iHeight;	// size = number of points in array 
  // iy
  iyMax = iHeight - 1;		// Indexes of array starts from 0 not 1 so the highest elements of an array is = array_name[size-1].
  //ix

  ixMax = iWidth - 1;

  /* 1D array ranges */
  // i1Dsize = i2Dsize; // 1D array with the same size as 2D array
  iMax = iSize - 1;		// Indexes of array starts from 0 not 1 so the highest elements of an array is = array_name[size-1].

  /* Pixel sizes */
  PixelWidth = (ZxMax - ZxMin) / ixMax;	//  ixMax = (iWidth-1)  step between pixels in world coordinate 
  PixelHeight = (ZyMax - ZyMin) / iyMax;
  ratio = ((ZxMax - ZxMin) / (ZyMax - ZyMin)) / ((double) iWidth / (double) iHeight);	// it should be 1.000 ...

  ER = 5.0; // it is bigger then 2  here !!!!!!
  ER2 = ER*ER;
  AR = PixelWidth*10.0*iWidth/2000.0 ; // 
  AR2 = AR * AR;
  AR12 = AR/2.0;



  	/* create dynamic 1D arrays for colors ( shades of gray ) */
  	data = malloc (iSize * sizeof (unsigned char));

	edge = malloc (iSize * sizeof (unsigned char));
  	if (data == NULL || edge == NULL)
    		{
      			fprintf (stderr, " Could not allocate memory");
      			return 1;
    		}





 


  fprintf (stderr, " end of setup \n");

  return 0;

}				// ;;;;;;;;;;;;;;;;;;;;;;;;; end of the setup ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;




int
end ()
{


  fprintf (stderr, " allways free memory (deallocate )  to avoid memory leaks \n");	// https://en.wikipedia.org/wiki/C_dynamic_memory_allocation
  free (data);
  free(edge);


  PrintProgramInfo ();
  PrintCInfo ();
  return 0;

}

// ********************************************************************************************************************
/* -----------------------------------------  main   -------------------------------------------------------------*/
// ********************************************************************************************************************

int
main ()
{
  	setup ();


  	DrawFatouImage (data, IterMax);	// first find Fatou
  	SaveArray2PGMFile (data, iWidth, IterMax, 0, "Fatou, name = iWidth_IterMax_n");
  
  	ComputeBoundaries(data,edge);
  	SaveArray2PGMFile (edge, iWidth, IterMax, 1, "Boundaries of Fatou; name = iWidth_IterMax_n"); 
  
  	CopyBoundaries(edge,data);
  	SaveArray2PGMFile (data, iWidth, IterMax, 2, "Fatou with boundaries; name = iWidth_IterMax_n"); 
  
  	//MarkAttractors(data);
  	MarkTraps(data);
  	SaveArray2PGMFile (data, iWidth, IterMax, 4, "Fatou with boundaries and traps; name = iWidth_IterMax_n"); 

  end ();

  return 0;
}


Text output

OPENMP DISPLAY ENVIRONMENT BEGIN
  _OPENMP = '201511'
  OMP_DYNAMIC = 'FALSE'
  OMP_NESTED = 'FALSE'
  OMP_NUM_THREADS = '8'
  OMP_SCHEDULE = 'DYNAMIC'
  OMP_PROC_BIND = 'FALSE'
  OMP_PLACES = ''
  OMP_STACKSIZE = '0'
  OMP_WAIT_POLICY = 'PASSIVE'
  OMP_THREAD_LIMIT = '4294967295'
  OMP_MAX_ACTIVE_LEVELS = '2147483647'
  OMP_CANCELLATION = 'FALSE'
  OMP_DEFAULT_DEVICE = '0'
  OMP_MAX_TASK_PRIORITY = '0'
  OMP_DISPLAY_AFFINITY = 'FALSE'
  OMP_AFFINITY_FORMAT = 'level %L thread %i affinity %A'
OPENMP DISPLAY ENVIRONMENT END


File 10000_100000_0.pgm saved . Comment = fc(z)= z+(1/2)*z^2−(1/2)*z^3  ; Fatou, name = iWidth_IterMax_n	ER = 5.000000e+00	AR =2.400240e-02 
File 10000_100000_1.pgm saved . Comment = fc(z)= z+(1/2)*z^2−(1/2)*z^3  ; Boundaries of Fatou; name = iWidth_IterMax_n	ER = 5.000000e+00	AR =2.400240e-02 
File 10000_100000_2.pgm saved . Comment = fc(z)= z+(1/2)*z^2−(1/2)*z^3  ; Fatou with boundaries; name = iWidth_IterMax_n	ER = 5.000000e+00	AR =2.400240e-02 
File 10000_100000_4.pgm saved . Comment = fc(z)= z+(1/2)*z^2−(1/2)*z^3  ; Fatou with boundaries and traps; name = iWidth_IterMax_n	ER = 5.000000e+00	AR =2.400240e-02 
Numerical approximation of Julia set for fc(z)= z+(1/2)*z^2−(1/2)*z^3  
Image Width = 4.800000 in world coordinate
PixelWidth = 0.0004800480048005 
AR = 0.0240024002400240 = 50.000000 *PixelWidth
pixel counters
uUnknown = 0
uExterior = 21913761
uInterior = 16793971
Sum of pixels  = 38707732
all pixels of the array = iSize = 50000000
Maximal number of iterations = iterMax = 100000 
ratio of image  = 1.000000 ; it should be 1.000 ...
gcc version: 9.3.0
__STDC__ = 1
__STDC_VERSION__ = 201710
c dialect = C18

real	0m4,655s
user	0m34,184s
sys	0m0,220s

  1. fractalforums.org : parabolic-julia-sets

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Julia set z+0.5z^2-0.5z^3

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