iBet uBet web content aggregator. Adding the entire web to your favor.
iBet uBet web content aggregator. Adding the entire web to your favor.



Link to original content: http://en.m.wikipedia.org/wiki/File:3D_RGB_profile_of_cubehelix_color_gradient.png
File:3D RGB profile of cubehelix color gradient.png - Wikipedia

File:3D RGB profile of cubehelix color gradient.png

3D_RGB_profile_of_cubehelix_color_gradient.png (640 × 480 pixels, file size: 28 KB, MIME type: image/png)

This graph image could be re-created using vector graphics as an SVG file. This has several advantages; see Commons:Media for cleanup for more information. If an SVG form of this image is available, please upload it and afterwards replace this template with {{vector version available|new image name}}.


It is recommended to name the SVG file “3D RGB profile of cubehelix color gradient.svg”—then the template Vector version available (or Vva) does not need the new image name parameter.

Summary

Description
English: 3D RGB profile of cubehelix color gradient[1]
Date
Source Own work
Author Adam majewski
Other versions

Licensing

I, the copyright holder of this work, hereby publish it under the following license:
w:en:Creative Commons
attribution share alike
This file is licensed under the Creative Commons Attribution-Share Alike 4.0 International license.
You are free:
  • to share – to copy, distribute and transmit the work
  • to remix – to adapt the work
Under the following conditions:
  • attribution – You must give appropriate credit, provide a link to the license, and indicate if changes were made. You may do so in any reasonable manner, but not in any way that suggests the licensor endorses you or your use.
  • share alike – If you remix, transform, or build upon the material, you must distribute your contributions under the same or compatible license as the original.

R src code

# Install the released version from CRAN:
install.packages("pals")
# Loading required package: pals
require(pals) 
# The palette is converted to RGB or LUV coordinates and plotted in a three-dimensional scatterplot. The LUV space is probably better, but it is easier to tweak colors by hand in RGB space.
pal.cube(cubehelix)
pal.cube(coolwarm)

c source code

/*
https://gitlab.com/adammajewski/color_gradient

  =============================
  gcc p.c -Wall -lm

  ./a.out 

  gnuplot plot.gp


  ===================
c program creates nMax ppm images and txt files
use ImageMagic convert program to convert ppm to png
use gnuplot to create png images from txt files 



*/

#include <stdio.h>
#include <string.h> // strncat
#include <stdlib.h> // malloc
#include <math.h> // log10

// color = RGB triplet = (thus three bytes per pixel) in the order red, green, then blue
// color = 3 bytes
// color component ( channel) = 1 byte =  number from 0 to 255 = unsigned char 


// size of virtual 2D array of pixels
// each piexel has a RGB color
int iWidth = 600;
int iHeight ; // 


// size of the dynamic 1D array 
unsigned char * data;
size_t ColorSize = 3; // RGB = number of color components = channels
size_t ArrayLength; // number of 1D array's elements = ENumber = iWidth*iHeight*ColorSize
size_t ElementSize; // size of array's element in bytes
size_t ArraySize; // size of array in bytes = ElementSize*ArrayLength 

// ppm P6 file
size_t HeaderSize ; // size of the P6 file  header in bytes
size_t FileSize; // = HeaderSize +ArraySize [bytes]







// gives position of 2D point (ix,iy) in 1D array  ; uses also global variables: iWidth , ColorSize
int Give_i ( int iX, int iY)
{
  return (iX + iY * iWidth) * ColorSize;  
}

/* 

   based on Delphi function by Witold J.Janik  
   https://commons.wikimedia.org/wiki/File:HSV-RGB-comparison.svg 

   input : position
   output: array c = RGB color 
*/
void GiveRainbowColor(double position, unsigned char c[])
{
  unsigned char nmax=6; /* number of color segments */
  double m=nmax* position;
  
  int n=(int)m; // integer of m
  
  double f=m-n;  // fraction of m
  unsigned char t=(int)(f*255);
  	
  /* if position > 1 then we have repetition of colors it maybe useful    */
      
  if (position>1.0){if (position-(int)position==0.0)position=1.0; else position=position-(int)position;}

  // gradient with 6 segments
  switch( n){
  case 0: { c[0] = 255; 		c[1] = t; 	c[2] = 0; 	break; };
  case 1: { c[0] = 255 -t;	c[1] = 255;	c[2] = 0; 	break; };
  case 2: { c[0] = 0;		c[1] = 255;	c[2] = t; 	break; };
  case 3: { c[0] = 0;		c[1] = 255 -t; 	c[2] = 255;	break; };
  case 4: { c[0] = t;		c[1] = 0;	c[2] = 255;	break; };
  case 5: { c[0] = 255;		c[1] = 0;	c[2] = 255 -t;	break; };
  default:{ c[0] = 255;		c[1] = 0;	c[2] = 0;	break; };
  }; // case
}




/*
  Your new colormap is different and ugly-ish. The line between red-and-yellow is much much worse than before.  the red-yellow discontinuity is ... confusing, annoying. .. to me, at least.
  https://gitlab.com/adammajewski/LinasArtGallery_MandelbrotSet
  http://linas.org/art-gallery/index.html

  http://linas.org/art-gallery/src/fractal/image/flo2mtv.c


  struct rgb {
  char r;
  char g;
  char b;
  };

  static struct rgb vlt[256];





  void make_cmap (void) {
  int i, j;
  struct rgb black;
  black.r = black.g = black.b = 0x0;
  for (i=0; i<256; i++) vlt[i] = black;

  // set up a default look up table 
  // ramp up to blue 
  for (i=0; i<60; i++) {
  vlt[i].r = 0;
  vlt[i].g = 0;
  vlt[i].b = (char) i*3;
  }
  // ramp down from blue, up to green 
  for (i=60; i<120; i++) {
  vlt[i].r = 0;
  vlt[i].g = (char) (i-60)*3;
  vlt[i].b = (char) (120-i)*3;
  }
  // ramp from green to yellow 
  for (i=120; i<180; i++) {
  // vlt[i].r = (char) (((i-120)*7) / 2); 
  vlt[i].r = (char) (210 - (7*(180-i)*(180-i)) / 120);
  vlt[i].g = (char) (210 -i/4);
  vlt[i].b = 0;
  }
  // ramp from yellow to red (pink) 
  for (i=180; i<240; i++) {
  vlt[i].r = (char) (210 + (3*(i-180))/4);
  vlt[i].g = (char) (510 - 2*i);
  vlt[i].b = (char) (i-180)/3;
  }
  }


*/


   
void GiveLinasColor(double position ,  unsigned char c[])
{
  /* based on the code by Linas Vepstas January 16 1994 : void make_cmap (void) */

   
  int i;
  int iMax = 239;
  i=(int)(iMax-1)*position;  
  c[0] = c[1] = c[2] = 0; /* set up a default look up table */
  
  
  // gradient with 4 segments 
  /* ramp from black to blue */
  if (i<60) {
    c[0] = 0;
    c[1] = 0;
    c[2] = (unsigned char) i*3;
  }
  /* ramp down from blue, up to green */
  if (i>=60 && i<120) {
    c[0] = 0;
    c[1] = (unsigned char) (i-60)*3;
    c[2] = (unsigned char) (120-i)*3;
  }
  /* ramp from green to yellow */
  if (i >=120 && i<180) {
    /* vlt[i].r = (char) (((i-120)*7) / 2); */
    c[0] = (unsigned char) (210 - (7*(180-i)*(180-i)) / 120);
    c[1] = (unsigned char) (210 -i/4);
    c[2] = 0;
  }
  /* ramp from yellow to red (pink) */
  if (i>=180 && i<iMax) {
    c[0] = (unsigned char) (210 + (3*(i-180))/4);
    c[1] = (unsigned char) (510 - 2*i);
    c[2] = (unsigned char) (i-180)/3;
  }
   
}

// https://github.com/Gnuplotting/gnuplot-palettes/blob/master/magma.pal
void GiveMagmaColor(double position, unsigned char c[]){
	
  double x, x2, x3, x4,x5,x6, x7, x8;
	
  double R, G, B;
	
  // 
  x = position;
  x2 = x*x;
  x3 = x*x2;
  x4 = x*x3;
  x5 = x*x4;
  x6 = x*x5;
  x7 = x*x6;
  x8 = x*x7;
	
  // found using https://arachnoid.com/polysolve/
  R = -2.1104070317295411e-002 +  1.0825531148278227e+000 * x -7.2556742716785472e-002 * x2 + 6.1700693562312701e+000 * x3 -1.1408475082678258e+001*x4 +  5.2341915705822935e+000*x5;
  if (R<0.0) R = 0.0; // small correction
	
  G = (-9.6293819919380796e-003 +  8.1951407027674095e-001 * x -2.9094991522336970e+000 * x2 + 5.4475501043849874e+000 * x3 -2.3446957347481536e+000*x4);
  if (G<0.0) G = 0.0;
	
  B = 3.4861713828180638e-002 -5.4531128070732215e-001*x + 4.9397985434515761e+001*x2 -3.4537272622690250e+002*x3 + 1.1644865375431577e+003*x4 -2.2241373781645634e+003*x5 + 2.4245808412415154e+003*x6 -1.3968425226952077e+003*x7 
    +3.2914755310075969e+002*x8;
	
  // change range 
  c[0] = (unsigned char) 255*R; //R
  c[1] = (unsigned char) 255*G; // G
  c[2] = (unsigned char) 255*B; // B	
	

}

void GiveGrayColorL(double position, unsigned char c[]){
	
	
  unsigned char X =  255- 255*position;
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}

void GiveGrayColorNL2(double position, unsigned char c[]){
	
	
  unsigned char X =  255- 255*(position*position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}


void GiveGrayColorNL3(double position, unsigned char c[]){
	
	
  unsigned char X =  255- 255*(position*position*position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}


void GiveGrayColorSqrt(double position, unsigned char c[]){
	
	
  unsigned char X =  255*sqrt(position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}



// from green to black = 
void GiveColorGreen(double position, unsigned char c[]){
	
	
  unsigned char X =  255- 255*(position*position*position);
  // change range 
  c[0] = 0; //R
  c[1] = X; // G
  c[2] = 0; // B	
	

}



void GiveLinas2Color(double position ,  unsigned char c[])
{
  /* based on the code by Linas Vepstas January 16 1994 : void make_cmap (void) */

   
   
  
  
  // gradient with 4 segments 0-0.25-0.5-0.75-1.0
  /* ramp from black to blue = (0.0 ; 0.25)) */
  if (position<0.25) {
    c[0] = 0;
    c[1] = 0;
    c[2] = 708*position;; // B
    return;
  }
  /* ramp down from blue, up to green = (0.25 ; 0.5)*/
  if (position<0.5) {
  	  
    c[0] = 0; //R
    c[1] =  -177+708*position; // G
    c[2] =  354 - 708* position;; // B
    return;
  }
  /* ramp from green to yellow  = (0.5 ; 0.75) */
  if (position<0.75) {
    	
    c[0] = -420+840*position; //R
    c[1] =  219-84*position; // G
    c[2] = 0;
    return;
  }
  /* position>0.75 :  ramp from yellow to red (pink) */
  	
  c[0] =  84+168*position; //R
  c[1] = 516-480*position; // G
  c[2] = -57 + 76*position; // B

    
   
}



// http://www.kennethmoreland.com/color-maps/
void GiveColorCoolWarm(double position, unsigned char c[]){
	
	
  double R,G,B;
  double x = position;
  double x2 = x*x;
  double x3 = x*x2;
  double x4 = x*x3;
  double x5 = x*x4;
  double x6 = x*x5;
	
	 
	
  R =  2.4070949725529692e-001 + 8.3340565013768031e-001*x + 2.6191922175556543e+000*x2 - 4.0994936709055061e+000*x3 + 1.1014553405733734e+000*x4;
  G =  2.8978300321243283e-001 + 2.2641158553110725e+000*x - 6.8483016873914799e+000*x2 + 3.0238558676188145e+001*x3 - 7.0431595279051223e+001*x4 + 6.8583306445298092e+001*x5 - 2.4054295028042432e+001*x6;
  B =  7.4391703318514535e-001 + 1.8345430120497781e+000*x - 3.1885763361607244e+000*x2 - 8.4015787106949880e-001*x3 + 1.6162754134259683e+000*x4;

  // change range 
  c[0] = (unsigned char) 255*R; //R
  c[1] = (unsigned char) 255*G; // G
  c[2] = (unsigned char) 255*B; // B	
	
	

}



void GiveGrayGammaColor(double position, unsigned char c[]){
  /*
    #from gnuplot
    gamma = 2.2
    color(gray) = gray**(1./gamma)
    set palette model RGB functions color(gray), color(gray), color(gray) # A gamma-corrected black and white palette
	
  */	double gamma = 2.2;
  double p = pow(position, 1.0/gamma);
  unsigned char X =  255*p;
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}


void GiveGrayColorNL3Wave2(double position, unsigned char c[]){
	
  int segments=2;
  position= segments*position;
  /* if position > 1 then we have repetition of colors it maybe useful    */
  if (position>1.0)
    {	int p = (int)position;
      position=position-p; // fractional part 
      if (p % 2)
	{position = 1.0-position;} // reverse gradient
    }
				 

  unsigned char X =  255- 255*(position*position*position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}




void GiveGrayColorNL3Wave10(double position, unsigned char c[]){
	
  int segments=10;
  position= segments*position;
  /* if position > 1 then we have repetition of colors it maybe useful    */
  if (position>1.0)
    {	int p = (int)position;
      position=position-p; // fractional part 
      if (p % 2)
	{position = 1.0-position;} // reverse gradient
    }
				 

  unsigned char X =  255- 255*(position*position*position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}



void GiveGrayColorSqrtWave(double position, unsigned char c[]){
  int segments=10;
  position= segments*position;
  /* if position > 1 then we have repetition of colors it maybe useful    */
  if (position>1.0)
    {	int p = (int)position;
      position=position-p; // fractional part 
      if (p % 2)
	{position = 1.0-position;} // reverse gradient
    }
				 

	
  unsigned char X =  255*sqrt(position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}





void GiveGrayColorLWave(double position, unsigned char c[]){
	
  int segments=10;
  position= segments*position;
  /* if position > 1 then we have repetition of colors it maybe useful    */
  if (position>1.0)
    {	int p = (int)position;
      position=position-p; // fractional part 
      			
    }
				 

  unsigned char X =  255- 255*position;
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}



void GiveGrayColorLWaveInverted(double position, unsigned char c[]){
	
  int segments=10;
  position= segments*position;
  /* if position > 1 then we have repetition of colors it maybe useful    */
  if (position>1.0)
    {	int p = (int)position;
      position=position-p; // fractional part 
      if (p % 2)
	{position = 1.0-position;} // reverse gradient
    }
				 

  unsigned char X =  255- 255*position;
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}




void GiveGrayColorNL3Wave5NonInv(double position, unsigned char c[]){
	
  int segments=5;
  position= segments*position;
  /* if position > 1 then we have repetition of colors it maybe useful    */
  if (position>1.0)
    {	int p = (int)position;
      position=position-p; // fractional part 
      			
    }
				 

  unsigned char X =  255- 255*(position*position*position);
  // change range 
  c[0] = X; //R
  c[1] = X; // G
  c[2] = X; // B	
	

}


// ----------------------------




/* 
 GNUPLOT - stdfn.h 
 Copyright 1986 - 1993, 1998, 2004   Thomas Williams, Colin Kelley 
*/
#ifndef clip_to_01
#define clip_to_01(val)	\
    ((val) < 0 ? 0 : (val) > 1 ? 1 : (val))
#endif

/*
 input : position
 output : c array ( rgb color)
 
the colour scheme spirals (as a squashed helix) around the diagonal of the RGB colour cube 

https://arxiv.org/abs/1108.5083
A colour scheme for the display of astronomical intensity images by D. A. Green 
*/
void GiveCubehelixColor(double position, unsigned char c[]){



	/* GNUPLOT - color.h 
	 * Petr Mikulik, December 1998 -- June 1999
	 * Copyright: open source as much as possible
	*/

	// t_sm_palette 
  	/* gamma for gray scale and cubehelix palettes only */
  	double gamma = 1.5;

  	/* control parameters for the cubehelix palette scheme */
  	//set palette cubehelix start 0.5 cycles -1.5 saturation 1
	//set palette gamma 1.5
  	double cubehelix_start = 0.5;	/* offset (radians) from colorwheel 0 */
  	double cubehelix_cycles = -1.5;	/* number of times round the colorwheel */
  	double cubehelix_saturation = 1.0;	/* color saturation */
	double r,g,b;
	double gray = position; 
 


	
	/*
 	 Petr Mikulik, December 1998 -- June 1999
 	* Copyright: open source as much as possible
 	*/
	// /* Map gray in [0,1] to color components according to colorMode */
	// function color_components_from_gray
	// from gnuplot/src/getcolor.c
	double phi, a;
	
	phi = 2. * M_PI * (cubehelix_start/3. +  gray * cubehelix_cycles);
	
	// gamma correction
	if (gamma != 1.0)    gray = pow(gray, 1./gamma);
	
	
	a = cubehelix_saturation * gray * (1.-gray) / 2.;
	
	// compute
	r = gray + a * (-0.14861 * cos(phi) + 1.78277 * sin(phi));
	g = gray + a * (-0.29227 * cos(phi) - 0.90649 * sin(phi));
	b = gray + a * ( 1.97294 * cos(phi));
	
	// normalize to [9,1] range
	r = clip_to_01(r);
	g = clip_to_01(g);
	b = clip_to_01(b);
	
	// change range to [0,255]
  	c[0] = (unsigned char) 255*r; //R
  	c[1] = (unsigned char) 255*g; // G
  	c[2] = (unsigned char) 255*b; // B	

}



/* 
   remember to update : 
   * nMax in main function
   * titles in plot.gp
   */

int GiveColor(double position, int n, unsigned char c[]){

  switch(n){
	
  case 0: {GiveRainbowColor(position, c); break;}
  case 1: {GiveLinasColor(position,c); break;}
  case 2: {GiveMagmaColor(position,c); break;}
  case 3: {GiveGrayColorL(position,c); break;}
  case 4: {GiveGrayColorNL2(position,c); break;}
  case 5: {GiveGrayColorNL3(position,c); break;}
  case 6: {GiveGrayColorSqrt(position,c); break;}
  case 7: {GiveColorGreen(position,c); break;}
  case 8: {GiveLinas2Color(position,c); break;}
  case 9: {GiveColorCoolWarm(position,c); break;}
  case 10: {GiveGrayGammaColor(position,c); break;}
  case 11: {GiveGrayColorNL3Wave2(position,c); break;}
  case 12: {GiveGrayColorNL3Wave10(position,c); break;}
  case 13: {GiveGrayColorSqrtWave(position,c); break;}
  case 14: {GiveGrayColorLWave(position,c); break;}
  case 15: {GiveGrayColorLWaveInverted(position,c); break;}
  case 16: {GiveGrayColorNL3Wave5NonInv(position,c); break;}
  case 17: {GiveCubehelixColor(position,c); break;}
  default:{GiveRainbowColor(position, c);}
  }
	
  return 0;


}


int PlotPoint(unsigned char A[], int i, unsigned char color[]){

  A[i]   = color[0]; /* Red*/
  A[i+1] = color[1]; /* Green */
  A[i+2] = color[2];  /* Blue */
  return 0;


}


void PrintColor( FILE *fp, double position, unsigned char color[]){
  // normalized to [0.0, 1.0] range RGB color channels
  double R = color[0]/255.0; 
  double G = color[1]/255.0;
  double B = color[2]/255.0;
  // [Relative luminance is formed as a weighted sum of linear RGB components](https://en.wikipedia.org/wiki/Luma_(video)) 
  // 
  //from function test_palette_subcommand from file gnuplot/src/command.c test_palette_subcommand
  //ntsc = 0.299 * rgb.r + 0.587 * rgb.g + 0.114 * rgb.b;
  double Y = 0.299*R + 0.587*G + 0.114*B;
	
  fprintf(fp, "%f\t %f\t%f\t%f \t %f \n", position, R,G,B,Y);

}



// --------------------
int FillArray (unsigned char A[] , int n){

  int iX;
  int iXmax = iWidth;
  int iY;
  int iYmax = iHeight;
  int i; //  index of 1D array  
  double position; // number form 0.0 to 1.0 used for color gradient
  unsigned char color[3]; // 
	
  // text file used by the gnuplot for creating images
  char name [100]; /* name of file */
  snprintf(name, sizeof name, "%d", n); /*  */
  char *filename =strncat(name,".txt", 4);
  FILE *fp = fopen(filename, "w");
  if (fp==NULL) {
    printf("Error opening text file!\n");
    return 1;
  }
  fprintf(fp, "# position \t\t R \t\t G \t\tB \t\tY\n"); // header of the text file
	
	
  //
  for(iX=0; iX<iXmax; ++iX){    
    position = (double) iX / iXmax;
    GiveColor(position, n, color);
    PrintColor(fp, position,color); // 
      		
    for(iY=0; iY<iYmax; ++iY){
      i = Give_i(iX, iY);
      PlotPoint(A, i , color);
    }
        		
         			
  }


  fclose(fp);
  return 0;
}





// --------------- save dynamic "A" array of uinsigned char to the binary ppm file ( P6 ) --------------------------------
int SaveArray2PPM (unsigned char A[], size_t ASize,   int k)
{

  FILE *fp;
  const unsigned char 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", k); /*  */
  char *filename =strncat(name,".ppm", 4);
  
  

  /* save image to the pgm file  */
  fp = fopen (filename, "wb");	/*create new file,give it a name and open it in binary mode  */
  if (fp == NULL) 
    {	printf("File open error"); 
      return 1;}
  else {
    fprintf (fp, "P6\n%u %u\n%u\n", iWidth, iHeight, MaxColorComponentValue);	/*write header to the file */
    fwrite (A, ASize, 1, fp);	// write dynamic A array to the binary file in one step  
 
    printf ("File %s saved. \n", filename);
    fclose (fp);
    return 0;}
  
}



// n = nummber of the gradient function
int MakeGradientImage(unsigned char A[],  int n){


  FillArray(data, n);
  SaveArray2PPM(data, ArraySize, n+iWidth);
  return 0;

}



int setup(){

  iHeight = iWidth/3; 
  // 1D array
  ArrayLength = iWidth*iHeight*ColorSize;
  ElementSize = sizeof(unsigned char);
  ArraySize = ElementSize*ArrayLength ; 
  HeaderSize = 11 + (size_t) (log10(iHeight) +log10(iWidth)); 
	
  FileSize = HeaderSize + ArraySize; 
	
  /* create dynamic 1D array for RGB colors  */
  data = malloc (ArraySize);
  if (data == NULL ){
    printf ( "Could not allocate memory for the array\n");
    return 1;}

	
  return 0;
}


void info(){

  printf("ppm (P6) header size = %zu bytes\n", HeaderSize);
  printf("Array Size  = %zu bytes\n", ArraySize);
  printf("PPM file size  = %zu bytes\n", FileSize);

	
}



int end(){


  printf (" allways free memory (deallocate )  to avoid memory leaks \n"); // https://en.wikipedia.org/wiki/C_dynamic_memory_allocation
  free (data);
  info();
  return 0;

}



// ================================== main ============================================

int main (){

  int n;
  int nMax = 18; // see GiveColor function, it should be one more then max n in GiveColor
  setup();
  //
  for (n = 0; n< nMax; ++n)
    MakeGradientImage(data, n);
	
  end();

  return 0;
}

Gnuplot source code

# save as a cubehelix.gp
# run : gnuplot cubehelix.gp
# https://gitlab.com/adammajewski/color_gradient



# Set the output file type
set terminal png

# list of gradient names;  update it maually
# gnuplot array is numbered from 1 to words(array), not like c arrays
# update list with order as in function GiveColor from p.c
titles = "Rainbow Linas Magma GrayL GrayNL2 GrayNL3 GraySqrt Green NewLinas CoolWarm GrayGamma GrayNL3Wave2 GrayNL3Wave10 GraySqrtWave ColorLWave ColorLWaveInverted NL3Wave5NonInv Cubehelix"
spaces = "RGB HSV"


# length of array spaces = nMax, but tex files are numbered from 0 to nMax-1 ( c style)
nMax = words(spaces)  


#  legend
set key inside bottom center horizontal
set key horizontal 
set key font ",8"

# remove upper and right axis
set border 3 back 
set xtics nomirror out
set ytics nomirror


set xlabel "gradient position"
set ylabel " intensity" 

# adjust y range to make a space for the legend 
set yrange [-0.2:1.1]


n=17
s=0 



	# Set the output file name
  	outfile = sprintf('%d.png',n)
  	set output outfile
  	
  	# Set the intput file name
  	infile = sprintf('%d.txt',n)

	# title of the image for the array of strings
	sTitle = sprintf(" 2D %s profiles of the %s colormap", word(spaces,s), word(titles,n+1) )
	set title sTitle
	
	
  	
  	
	# Now plot the data with lines and points
	plot infile using 1:2 with lines linecolor rgb 'red' title 'R', \
     	'' using 1:3 w lines linecolor rgb 'green' title 'G', \
     	'' using 1:4 w lines linecolor rgb 'blue' title 'B',\
     	'' using 1:5 w lines linecolor rgb 'black' title 'Y'
	
  
     	


     	
     	
     	



     	
# 3d plot of rgb profile

	
	
	
	set xlabel "R"
	set ylabel "G"
	set zlabel "B"

 	unset yrange
	set nokey	
	unset tics
	set xrange [0.0:1.0]
	set yrange [0.0:1.0]
	set zrange [0.0:1.0]
	set grid 
	set border 4095 ls 1 lc rgb "black" # Draw a complete box around a `splot`:
	
	set xzeroaxis
	set yzeroaxis
   	# set view <rot_x>{,{<rot_z>}{,{<scale>}{,<scale_z>}}}
   	# view is 60 rot_x, 30 rot_z, 1 scale, 1 scale_z
   	rot_x = 70
   	rot_z = 60
	set view rot_x,rot_z
	set view equal xyz # to get an orthographic projection with all of the axes scaled equally
	set xyplane at 0 # adjusts the position at which the xy plane is drawn in a 3D plot

	# Set the output file name
  	outfile = sprintf('%d_3d_%d_%d_v.png',n, rot_x, rot_z)
  	set output outfile
  	
  	

	# title of the image for the array of strings
	sTitle = sprintf("3D %s profile of the %s colormap", word(spaces,s), word(titles,n+1)  )
	set title sTitle
	
	# http://www.bersch.net/gnuplot-doc/linetypes,-colors,-and-styles.html
  	# There are several ways to specify color when one plots using gnuplot.
  	# Among them hex-string (like "#0000ff") and rgbvalue (like "256") 
  	# specification is very important.
  	# here rgb value is computed 
	rgb(r,g,b) = 65536*int(255*r) + 256*int(255*g) + int(255*b)
	
	
	
  	
	# Now plot the data with lines and points
	set label "(0,0,0)" at -0.1,0,0 right 
	#set label "0" at 1,-0.1,0 right
	#set label "1" at 1,+1.1,0 right 
	#set label "2" at 0,1.1,0 right 
	#set label "3" at 0,1,1 left 
	#set label "4" at 0,0,1 left 
	# set label "5" at 1,0,1 left 
	#set label "6" at 1,0,0 left 
	set label "(1,1,1)" at 1.1,1,1 left 
	splot 	infile using 1:1:1 with lines lw 3 lc rgb 'gray',\
		infile using 2:3:4:(rgb($2,$3,$4)) with points pt 7 ps 2 lc rgb variable ,\
		'-' w p pt 7 ps 2 lc rgb 'black'
		0 0 0
		1 1 1
		e
  1. gitlab repo of adam majewski: color_gradient

Captions

3D RGB profile of cubehelix color gradient

Items portrayed in this file

depicts

31 January 2020

image/png

e99a090466fc70e2603b4636cc22722cd26c4d01

28,813 byte

480 pixel

640 pixel

File history

Click on a date/time to view the file as it appeared at that time.

Date/TimeThumbnailDimensionsUserComment
current19:34, 31 January 2020Thumbnail for version as of 19:34, 31 January 2020640 × 480 (28 KB)Soul windsurferUser created page with UploadWizard

The following page uses this file:

Global file usage

The following other wikis use this file: