Function:ns2qvas
From S2PLOT
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| ==See Also== | ==See Also== | ||
| + | <table> | ||
| + | <tr><td>[[Function:ns2svas | ns2svas]]</td><td>Set alpha scaling mode. </td></tr> | ||
| + | <tr><td>[[Function:ns2sevas | ns2sevas]]</td><td>Explicitly set alpha scaling values. </td></tr> | ||
| + | <tr><td>[[Function:ns2cvr | ns2cvr ]]</td><td>Create a volume rendering object. </td></tr> | ||
| + | <tr><td>[[Function:ns2cvra| ns2cvra ]]</td><td>Render volume of objects. </td></tr> | ||
| + | </table> | ||
| ==Code Example== | ==Code Example== | ||
| <code><pre> | <code><pre> | ||
| - | </pre></code> | + | #include <stdio.h> |
| + | #include <stdlib.h> | ||
| + | #include <math.h> | ||
| + | #include <time.h> | ||
| + | #include "s2plot.h" | ||
| - | [[S2PLOT:Function List | Back]] to S2PLOT function list. | + | /* Global variables */ |
| + | int vid; /* ID for volume render object */ | ||
| + | float tr[12]; /* Transformation matrix */ | ||
| + | float ***volume; /* The data cube */ | ||
| + | int nx, ny, nz; /* Data grid dimensions */ | ||
| + | float ***initVolume(int nx, int ny, int nz) | ||
| + | /* Allocate memory and initialise a data cube */ | ||
| + | { | ||
| + | float ***volume; | ||
| + | int i, j, k; | ||
| + | volume = (float ***)malloc(nx * sizeof(float **)); | ||
| + | if (volume == NULL) { | ||
| + | fprintf(stderr,"Failed to allocate %ld bytes\n",(long)(nx*sizeof(float **))); | ||
| + | exit(-1); | ||
| + | } | ||
| + | for (i=0;i<nx;i++) { | ||
| + | volume[i] = (float **)malloc(ny * sizeof(float *)); | ||
| + | if (volume[i] == NULL) { | ||
| + | fprintf(stderr,"Failed to allocate %ld bytes\n",(long)(nx*sizeof(float *))); | ||
| + | exit(-1); | ||
| + | } | ||
| + | for (j=0;j<ny;j++) { | ||
| + | volume[i][j] = (float *)malloc(nz * sizeof(float)); | ||
| + | if (volume[i][j] == NULL) { | ||
| + | fprintf(stderr,"Failed to allocate %ld bytes\n",(long)(nx*sizeof(float))); | ||
| + | exit(-1); | ||
| + | } | ||
| + | for (k=0;k<nz;k++) { | ||
| + | volume[i][j][k] = 0.0; /* Initialise */ | ||
| + | } | ||
| + | } | ||
| + | } | ||
| - | __NOTOC__ | + | return volume; |
| - | __NOEDITSECTION__ | + | } |
| + | void cb(double *t, int *kc) | ||
| + | /* A dynamic callback */ | ||
| + | { | ||
| + | ns2svas(*kc%3); /* Set the alpha scaling mode */ | ||
| + | int qvas = ns2qvas(); /* Query the alpha scaling mode */ | ||
| + | char string[255]; | ||
| + | sprintf(string,"Alpha scaling mode: %d. Press <space> to toggle mode", | ||
| + | qvas); | ||
| + | s2lab("","","",string); | ||
| - | Back to [[Function:Template | template]] page. | + | ds2dvr(vid, 1); /* Draw the volume render object */ |
| + | } | ||
| + | |||
| + | int main(int argc, char *argv[]) | ||
| + | { | ||
| + | int i; /* Loop variable */ | ||
| + | float dmin, dmax, amin, amax; /* Min/max values */ | ||
| + | char trans; /* Transparency mode */ | ||
| + | float x1 = -1.0, x2 = +1.0; /* Data range along axes */ | ||
| + | float y1 = -1.0, y2 = +1.0; | ||
| + | float z1 = -1.0, z2 = +1.0; | ||
| + | int vi, vj, vk; /* Temporary variables */ | ||
| + | float dx, dy, dz; /* Temporary variables */ | ||
| + | COLOUR amb = {0.8, 0.8, 0.8}; /* Ambient light */ | ||
| + | |||
| + | srand48((long)time(NULL)); /* Seed random numbers */ | ||
| + | |||
| + | nx = 40; ny = 40; nz = 10; /* Dimensions of data cube */ | ||
| + | volume = initVolume(nx, ny, nz); /* Allocate memory */ | ||
| + | |||
| + | for (i=0;i<12;i++) { /* Set-up transfrom matrix */ | ||
| + | tr[i] = 0.0; | ||
| + | } | ||
| + | tr[ 0] = x1; /* Mapping from data cube */ | ||
| + | tr[ 1] = (x2-x1)/(float)(nx-1.0); /* to physical coordinates */ | ||
| + | tr[ 4] = y1; | ||
| + | tr[ 6] = (y2-y1)/(float)(ny-1.0); | ||
| + | tr[ 8] = z1; | ||
| + | tr[11] = (z2-z1)/(float)(nz-1.0); | ||
| + | |||
| + | dmin = 0.0; /* Mininum data value in volume to plot */ | ||
| + | dmax = 2.0; /* Maximum data value in volume to plot */ | ||
| + | amin = 0.0; /* Minimum alpha channel value */ | ||
| + | amax = 0.8; /* Maximum alpha channel value */ | ||
| + | trans = 't'; /* Transparency type */ | ||
| + | |||
| + | dx = tr[1]*0.5; /* Offsets for window - voxels are pixel */ | ||
| + | dy = tr[6]*0.5; /* centred */ | ||
| + | dz = tr[11]*0.5; | ||
| + | |||
| + | s2opend("/S2MONO",argc,argv); /* Open the display */ | ||
| + | s2swin(x1-dx,x2+dx, y1-dy,y2+dy, z1-dz,z2+dz); /* Set window coords */ | ||
| + | s2svp(-1,1,-1.5,1.5,-0.25,0.25); | ||
| + | s2box("BCDE",0,0,"BCDE",0,0,"BCDE",0,0); /* Draw coord box */ | ||
| + | |||
| + | long N = 5000; | ||
| + | |||
| + | for (i=0;i<N;i++) { /* Create N random (x,y,z) values */ | ||
| + | vi = (int)(drand48()*(nx)); | ||
| + | vj = (int)(drand48()*(ny)); | ||
| + | vk = (int)(drand48()*(nz)); | ||
| + | |||
| + | volume[vi][vj][vk]+=1.0-drand48()*drand48(); | ||
| + | /* Give a value to volume */ | ||
| + | } | ||
| + | |||
| + | s2scir(1000,2000); /* Set colour range */ | ||
| + | s2icm("mgreen",1000,2000); /* Install colour map */ | ||
| + | vid = ns2cvr(volume, nx, ny, nz, 0, nx-1, 0, ny-1, 0, nz-1, | ||
| + | tr, trans, dmin, dmax, amin, amax); | ||
| + | /* Create the volume render object */ | ||
| + | |||
| + | cs2scb(cb); /* Install a dynamic callback */ | ||
| + | |||
| + | ss2srm(SHADE_FLAT); /* Set shading type to FLAT */ | ||
| + | ss2sl(amb, 0, NULL, NULL, 0); /* Ambient lighting only */ | ||
| + | |||
| + | ss2sas(1); /* Start the cube spinning */ | ||
| + | |||
| + | s2show(1); /* Open the s2plot window */ | ||
| + | |||
| + | return 1; | ||
| + | } | ||
| + | </pre></code> | ||
| + | |||
| + | [[S2PLOT:Function List | Back]] to S2PLOT function list. | ||
| + | |||
| + | __NOTOC__ | ||
| + | __NOEDITSECTION__ | ||
Current revision
ns2qvas
Query alpha scaling mode.
Prototype
int ns2qvas(void);
Description
Query alpha scaling mode for volume rendering, and normal scaling mode for isosurfaces: 0 => none, 1 => scale by volume dimensions, 2 => scale by viewport dimensions.
See Also
| ns2svas | Set alpha scaling mode. |
| ns2sevas | Explicitly set alpha scaling values. |
| ns2cvr | Create a volume rendering object. |
| ns2cvra | Render volume of objects. |
Code Example
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <time.h>
#include "s2plot.h"
/* Global variables */
int vid; /* ID for volume render object */
float tr[12]; /* Transformation matrix */
float ***volume; /* The data cube */
int nx, ny, nz; /* Data grid dimensions */
float ***initVolume(int nx, int ny, int nz)
/* Allocate memory and initialise a data cube */
{
float ***volume;
int i, j, k;
volume = (float ***)malloc(nx * sizeof(float **));
if (volume == NULL) {
fprintf(stderr,"Failed to allocate %ld bytes\n",(long)(nx*sizeof(float **)));
exit(-1);
}
for (i=0;i<nx;i++) {
volume[i] = (float **)malloc(ny * sizeof(float *));
if (volume[i] == NULL) {
fprintf(stderr,"Failed to allocate %ld bytes\n",(long)(nx*sizeof(float *)));
exit(-1);
}
for (j=0;j<ny;j++) {
volume[i][j] = (float *)malloc(nz * sizeof(float));
if (volume[i][j] == NULL) {
fprintf(stderr,"Failed to allocate %ld bytes\n",(long)(nx*sizeof(float)));
exit(-1);
}
for (k=0;k<nz;k++) {
volume[i][j][k] = 0.0; /* Initialise */
}
}
}
return volume;
}
void cb(double *t, int *kc)
/* A dynamic callback */
{
ns2svas(*kc%3); /* Set the alpha scaling mode */
int qvas = ns2qvas(); /* Query the alpha scaling mode */
char string[255];
sprintf(string,"Alpha scaling mode: %d. Press <space> to toggle mode",
qvas);
s2lab("","","",string);
ds2dvr(vid, 1); /* Draw the volume render object */
}
int main(int argc, char *argv[])
{
int i; /* Loop variable */
float dmin, dmax, amin, amax; /* Min/max values */
char trans; /* Transparency mode */
float x1 = -1.0, x2 = +1.0; /* Data range along axes */
float y1 = -1.0, y2 = +1.0;
float z1 = -1.0, z2 = +1.0;
int vi, vj, vk; /* Temporary variables */
float dx, dy, dz; /* Temporary variables */
COLOUR amb = {0.8, 0.8, 0.8}; /* Ambient light */
srand48((long)time(NULL)); /* Seed random numbers */
nx = 40; ny = 40; nz = 10; /* Dimensions of data cube */
volume = initVolume(nx, ny, nz); /* Allocate memory */
for (i=0;i<12;i++) { /* Set-up transfrom matrix */
tr[i] = 0.0;
}
tr[ 0] = x1; /* Mapping from data cube */
tr[ 1] = (x2-x1)/(float)(nx-1.0); /* to physical coordinates */
tr[ 4] = y1;
tr[ 6] = (y2-y1)/(float)(ny-1.0);
tr[ 8] = z1;
tr[11] = (z2-z1)/(float)(nz-1.0);
dmin = 0.0; /* Mininum data value in volume to plot */
dmax = 2.0; /* Maximum data value in volume to plot */
amin = 0.0; /* Minimum alpha channel value */
amax = 0.8; /* Maximum alpha channel value */
trans = 't'; /* Transparency type */
dx = tr[1]*0.5; /* Offsets for window - voxels are pixel */
dy = tr[6]*0.5; /* centred */
dz = tr[11]*0.5;
s2opend("/S2MONO",argc,argv); /* Open the display */
s2swin(x1-dx,x2+dx, y1-dy,y2+dy, z1-dz,z2+dz); /* Set window coords */
s2svp(-1,1,-1.5,1.5,-0.25,0.25);
s2box("BCDE",0,0,"BCDE",0,0,"BCDE",0,0); /* Draw coord box */
long N = 5000;
for (i=0;i<N;i++) { /* Create N random (x,y,z) values */
vi = (int)(drand48()*(nx));
vj = (int)(drand48()*(ny));
vk = (int)(drand48()*(nz));
volume[vi][vj][vk]+=1.0-drand48()*drand48();
/* Give a value to volume */
}
s2scir(1000,2000); /* Set colour range */
s2icm("mgreen",1000,2000); /* Install colour map */
vid = ns2cvr(volume, nx, ny, nz, 0, nx-1, 0, ny-1, 0, nz-1,
tr, trans, dmin, dmax, amin, amax);
/* Create the volume render object */
cs2scb(cb); /* Install a dynamic callback */
ss2srm(SHADE_FLAT); /* Set shading type to FLAT */
ss2sl(amb, 0, NULL, NULL, 0); /* Ambient lighting only */
ss2sas(1); /* Start the cube spinning */
s2show(1); /* Open the s2plot window */
return 1;
}
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