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//vodafone call visualisation
//
//Tim Redfern Jan 2012
//
//scale of wall 10.57x2.8m - some parts are obscured
//
//416 x 110 in. ~ 62400x16500 ~ 1029 mpx ~ 2945 MB ram to open
//
//CousinMarriageWorld.svg, nominally 940 × 470 pixels, file size: 1.99 MB
//World_map_(Miller_cylindrical_projection,_blank).svg, nominally 634 × 477 pixels, file size: 1.84 MB
//wikimedia
//
//http://www.vectortemplates.com/vector-world-map.php
//requirements -
//must be able to transform points to a new projection
// maybe not through normal shape library
//must be able to find a random point within the shape
//
//250112 so far so good, can iterate children.
//safest thing is to establish that I can place a point as being inside or outside of a shape
//(are they closed properly!)
//If we can find points in them then we can start the main task:
//connecting parts of the SVG with rows in the spreadsheet
//maybe next first I should look at projections (to keep them happy)
//I have a map with rectangular coords,
//is easy to enough to play with the projection
// public boolean contains(RGeomElem shp)
// public geomerative.RRectangle getBounds()
// --> this is kind of hidden. why? anyway, it should be possible to use it
//another option is to use the OUTLINE of the country (as a purely geometric thing).
/*
http://en.wikipedia.org/wiki/3D_projection
a- the 3D position of a point A that is to be projected.
c- the 3D position of a point C representing the camera.
O- The orientation of the camera (represented, for instance, by Tait–Bryan angles).
e- the viewer's position relative to the display surface.[1]
*/
import processing.pdf.*;
import geomerative.*;
class pointMapper {
float xo,xs,yo,ys;
pointMapper(float _xo,float _xs,float _yo,float _ys) {
xo=_xo;
xs=_xs;
yo=_yo;
ys=_ys;
}
RPoint map(float _x,float _y) {
//formalise
float px=((_x-xo)/xs); //26)/736);
float py=((_y-yo)/ys); //90)/390);
//transform
px=(((px-0.5)*0.25)+.25); //front half of sphere
py=((py-0.5)*0.3)+0.5;
//map to 3D curve
float r=getHeight()*4;
float x=r*cos(px*PI*2)*(sin(py*PI)) *2;
float z=r*sin(px*PI*2)*(sin(py*PI))-985;
float y=r*cos(py*PI)+(getHeight()*0.5)-210;
//camera at 0,0,0
//screen plane at 0,0,100
//(dx-ex)(ez/dz)
//(dy-ey)(ez/dz)
//rotate camera
return new RPoint(x*(100/z),y*(100/z));
}
}
RShape shp;
pointMapper shpmap;
//RRectangle cb;
int whichChild,numChildren;
String mode;
void setup(){
println("vodaviz v0.11");
RG.init(this);
mode="PDF";
size(832,220); //,PDF, "testoutput.pdf"); //P3D); //832,220); //nb pdf is 800x600
smooth();
float m = millis();
shp = RG.loadShape("world_countries_outlines_culled.svg"); //test_drawing.svg"); //world_countries_outlines_split.svg");
shpmap = new pointMapper(26,736,90,390);
RG.ignoreStyles();
println("loaded svg in "+((millis()-m)*.001)+" seconds");
numChildren=shp.children.length;
whichChild=0;
}
void draw() {
background(0,0,0);
noFill();
stroke(255);
strokeWeight(.02);
//RG.shape(shp);
whichChild=(whichChild+1)%numChildren;
//println("child "+whichChild+" of "+numChildren);
//cb=shp.children[whichChild].getBounds();
float xWrap=1.0;
//plot shapes at points
for (int i=0;i<numChildren;i++) {
String cmd="";
for (int j=0;j<shp.children[i].paths.length;j++) { //
//shp.children[i].paths[j].draw();
//public boolean contains(RPoint p)
/*
//find a random point inside shape
RPoint tl=shp.children[i].getTopLeft();
RPoint br=shp.children[i].getBottomRight();
RPoint np;
boolean found =false;
while (!found) {
np=new RPoint(random(tl.x,br.x),random(tl.y,br.y));
found = shp.children[i].contains(np); //paths[j].
println(shp.children[i].name+"; trying "+np.x+","+np.y+" between "+tl.x+","+tl.y+" and "+br.x+","+br.y+" :"+found);
}
*/
beginShape();
for (int k=0;k<shp.children[i].paths[j].commands.length;k++) {
RPoint sp=shp.children[i].paths[j].commands[k].startPoint;
RPoint dp=shpmap.map(sp.x,sp.y);
vertex(dp.x+(getWidth()/2),dp.y+(getHeight()/2)); //,z); //z);
//if (i==0&&j==0) cmd+=(x+(getWidth()/2))+","+(y+(getHeight()/2))+","+z+" ";
}
endShape();
}
if (cmd!="") println(cmd);
}
noLoop();
if (mode=="PDF") exit();
}
void mousePressed() {
}
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