thermal particles

2020-10-20 14:50:26 +02:00 · 2020-10-20 14:50:26 +02:00 · dd459dc01b
commit dd459dc01b
parent 4a51d358bd
9 changed files with 103 additions and 415 deletions
--- a/zoneb/bin/data/shaders/particle.frag
+++ b/zoneb/bin/data/shaders/particle.frag
@ -1,177 +0,0 @@
 #ifdef GL_ES
 precision mediump float;
 #endif
 uniform sampler2D   u_depth;
 uniform sampler2D   u_world;
 uniform sampler2D   u_v4l2cam;
 uniform ivec2 uFrameSize;
 uniform ivec2 uDepthFrameSize;
 uniform sampler2D   u_buffer0;
 uniform sampler2D   u_buffer1;
 uniform vec2        u_resolution;
 uniform vec2        u_mouse;
 uniform float       u_time;
 uniform bool        u_init;
 varying vec2        v_texcoord;
 vec3 random3(vec3 c) {
 	float j = 4096.0*sin(dot(c,vec3(17.0, 59.4, 15.0)));
 	vec3 r;
 	r.z = fract(512.0*j);
 	j *= .125;
 	r.x = fract(512.0*j);
 	j *= .125;
 	r.y = fract(512.0*j);
 	return r-0.5;
 }
 /* skew constants for 3d simplex functions */
 const float F3 =  0.3333333;
 const float G3 =  0.1666667;
 /* 3d simplex noise */
 float simplex3d(vec3 p) {
 	 /* 1. find current tetrahedron T and it's four vertices */
 	 /* s, s+i1, s+i2, s+1.0 - absolute skewed (integer) coordinates of T vertices */
 	 /* x, x1, x2, x3 - unskewed coordinates of p relative to each of T vertices*/
 	 /* calculate s and x */
 	 vec3 s = floor(p + dot(p, vec3(F3)));
 	 vec3 x = p - s + dot(s, vec3(G3));
 	 /* calculate i1 and i2 */
 	 vec3 e = step(vec3(0.0), x - x.yzx);
 	 vec3 i1 = e*(1.0 - e.zxy);
 	 vec3 i2 = 1.0 - e.zxy*(1.0 - e);
 	 /* x1, x2, x3 */
 	 vec3 x1 = x - i1 + G3;
 	 vec3 x2 = x - i2 + 2.0*G3;
 	 vec3 x3 = x - 1.0 + 3.0*G3;
 	 /* 2. find four surflets and store them in d */
 	 vec4 w, d;
 	 /* calculate surflet weights */
 	 w.x = dot(x, x);
 	 w.y = dot(x1, x1);
 	 w.z = dot(x2, x2);
 	 w.w = dot(x3, x3);
 	 /* w fades from 0.6 at the center of the surflet to 0.0 at the margin */
 	 w = max(0.6 - w, 0.0);
 	 /* calculate surflet components */
 	 d.x = dot(random3(s), x);
 	 d.y = dot(random3(s + i1), x1);
 	 d.z = dot(random3(s + i2), x2);
 	 d.w = dot(random3(s + 1.0), x3);
 	 /* multiply d by w^4 */
 	 w *= w;
 	 w *= w;
 	 d *= w;
 	 /* 3. return the sum of the four surflets */
 	 return dot(d, vec4(52.0));
 }
 /* const matrices for 3d rotation */
 const mat3 rot1 = mat3(-0.37, 0.36, 0.85,-0.14,-0.93, 0.34,0.92, 0.01,0.4);
 const mat3 rot2 = mat3(-0.55,-0.39, 0.74, 0.33,-0.91,-0.24,0.77, 0.12,0.63);
 const mat3 rot3 = mat3(-0.71, 0.52,-0.47,-0.08,-0.72,-0.68,-0.7,-0.45,0.56);
 /* directional artifacts can be reduced by rotating each octave */
 float simplex3d_fractal(vec3 m) {
    return   0.5333333*simplex3d(m*rot1)
 			+0.2666667*simplex3d(2.0*m*rot2)
 			+0.1333333*simplex3d(4.0*m*rot3)
 			+0.0666667*simplex3d(8.0*m);
 }
 void main() {
  vec2 pixel = 1./u_resolution;
  vec2 st = v_texcoord;
  // st.y = 1.0 - st.y;
 #ifdef BUFFER_0
  // PING BUFFER
  //
  //  Note: Here is where most of the action happens. But need's to read
  //  te content of the previous pass, for that we are making another buffer
  //  BUFFER_1 (u_buffer1)
  vec4 color = vec4(0,0,0,1);
  float depth = texture2D(u_depth, v_texcoord).x;
  vec4 ray = texture2D(u_world, v_texcoord);
  float vValid = (depth != 0 && ray.x != 0 && ray.y != 0) ? 1 : 0;
  if(depth < 0.012) vValid = 0;
  if(depth > 0.04) vValid = 0;
  vec2 v4l2st = st;
  v4l2st /= 3;
  v4l2st -= vec2(0.5);
  v4l2st *= 1.45;
  v4l2st += vec2(0.5);
  v4l2st.s += 0.15;
  v4l2st.t += 0.16;
  float thermo = texture2D(u_v4l2cam, v4l2st).r;
  vec4 pos = texture2D(u_buffer1, st);
  float age = pos.w;//mod(pos.w, 100);
  float lastThermo = floor(pos.w / 100);
  if(vValid == 1 && mod(u_time * 3 + random3(vec3(v_texcoord, 0)).r, 1.0) < 0.5) {
    vec4 posWorld = vec4(1);
    posWorld.z = depth * 65535.0; // Remap to float range.
    posWorld.x = ray.x * posWorld.z;
    posWorld.y = ray.y * posWorld.z;
    // Flip X as OpenGL and K4A have different conventions on which direction is positive.
    posWorld.x *= -1;
    // float tmp = mix(texture2D(u_depth, st).r, texture2D(u_buffer1, st).r, 0.9);
    // color = vec4(vec3(tmp), 1.0);
    color.rgb = posWorld.rgb;
    // color.a = thermo * 100;//vValid;
    color.a = 0.1;
  }
  else {
    float th = 3.1415 * 4 * simplex3d_fractal(vec3(pos.xyz * 0.001 + vec3(0, 0, u_time * 0.01)));
    float phi = 3.1415 * simplex3d_fractal(pos.xyz * 0.002);
    pos.x += cos(th) * cos(phi) * 7;
    pos.y += sin(th) * cos(phi) * 7;
    pos.z += sin(phi) * 7;
    // age = min(1, age + 0.01);
    pos.w = age;
    color = pos;
  }
  gl_FragColor = color;
 #elif defined( BUFFER_1 )
  // PONG BUFFER
  //
  //  Note: Just copy the content of the BUFFER0 so it can be 
  //  read by it in the next frame
  //
  gl_FragColor = texture2D(u_buffer0, st);
 #else
  // Main Buffer
  vec4 buf1 = texture2D(u_buffer1, st);
  gl_FragColor = buf1;
 #endif
 }
--- a/zoneb/bin/data/shaders/particles/draw.frag
+++ b/zoneb/bin/data/shaders/particles/draw.frag
@ -8,10 +8,12 @@ uniform sampler2DRect   u_v4l2cam;
 uniform sampler2DRect   imageTexture;
 in vec2 texCoordVarying;
 in float vTemperature;
 void main()
 {
    fragColor = vec4(1);//vec4(texture(u_world, texCoordVarying.st).rgb,1);
    // fragColor = vec4(texCoordVarying.st/100,1.0,1.0);//vec4(texture(u_world, texCoordVarying.st).rgb,1);
-    // fragColor = vec4(texture(imageTexture, texCoordVarying.st).rgb,1);
+    // fragColor = vec4(texture(u_v4l2cam, texCoordVarying.st).rgb,1);
    fragColor = vec4(texture(imageTexture, vec2(vTemperature*1024, 0.5)).xyz,1);
 }
--- a/zoneb/bin/data/shaders/particles/draw.vert
+++ b/zoneb/bin/data/shaders/particles/draw.vert
@ -7,9 +7,11 @@ in vec4  position;
 in vec2  texcoord;
 out vec2 texCoordVarying;
 out float vTemperature;
 void main()
 {
    texCoordVarying = texcoord;
    vTemperature = texture(particles2, texCoordVarying).x;
    gl_Position = modelViewProjectionMatrix * vec4(texture(particles0, texCoordVarying).xyz, 1.0);
 }
--- a/zoneb/bin/data/shaders/particles/update.frag
+++ b/zoneb/bin/data/shaders/particles/update.frag
@ -22,8 +22,92 @@ layout(location = 0) out vec4 posOut;
 layout(location = 1) out vec4 velOut;
 layout(location = 2) out vec4 misOut;
 vec3 random3(vec3 c) {
 	float j = 4096.0*sin(dot(c,vec3(17.0, 59.4, 15.0)));
 	vec3 r;
 	r.z = fract(512.0*j);
 	j *= .125;
 	r.x = fract(512.0*j);
 	j *= .125;
 	r.y = fract(512.0*j);
 	return r-0.5;
 }
 /* skew constants for 3d simplex functions */
 const float F3 =  0.3333333;
 const float G3 =  0.1666667;
 /* 3d simplex noise */
 float simplex3d(vec3 p) {
 	 /* 1. find current tetrahedron T and it's four vertices */
 	 /* s, s+i1, s+i2, s+1.0 - absolute skewed (integer) coordinates of T vertices */
 	 /* x, x1, x2, x3 - unskewed coordinates of p relative to each of T vertices*/
 	 /* calculate s and x */
 	 vec3 s = floor(p + dot(p, vec3(F3)));
 	 vec3 x = p - s + dot(s, vec3(G3));
 	 /* calculate i1 and i2 */
 	 vec3 e = step(vec3(0.0), x - x.yzx);
 	 vec3 i1 = e*(1.0 - e.zxy);
 	 vec3 i2 = 1.0 - e.zxy*(1.0 - e);
 	 /* x1, x2, x3 */
 	 vec3 x1 = x - i1 + G3;
 	 vec3 x2 = x - i2 + 2.0*G3;
 	 vec3 x3 = x - 1.0 + 3.0*G3;
 	 /* 2. find four surflets and store them in d */
 	 vec4 w, d;
 	 /* calculate surflet weights */
 	 w.x = dot(x, x);
 	 w.y = dot(x1, x1);
 	 w.z = dot(x2, x2);
 	 w.w = dot(x3, x3);
 	 /* w fades from 0.6 at the center of the surflet to 0.0 at the margin */
 	 w = max(0.6 - w, 0.0);
 	 /* calculate surflet components */
 	 d.x = dot(random3(s), x);
 	 d.y = dot(random3(s + i1), x1);
 	 d.z = dot(random3(s + i2), x2);
 	 d.w = dot(random3(s + 1.0), x3);
 	 /* multiply d by w^4 */
 	 w *= w;
 	 w *= w;
 	 d *= w;
 	 /* 3. return the sum of the four surflets */
 	 return dot(d, vec4(52.0));
 }
 /* const matrices for 3d rotation */
 const mat3 rot1 = mat3(-0.37, 0.36, 0.85,-0.14,-0.93, 0.34,0.92, 0.01,0.4);
 const mat3 rot2 = mat3(-0.55,-0.39, 0.74, 0.33,-0.91,-0.24,0.77, 0.12,0.63);
 const mat3 rot3 = mat3(-0.71, 0.52,-0.47,-0.08,-0.72,-0.68,-0.7,-0.45,0.56);
 /* directional artifacts can be reduced by rotating each octave */
 float simplex3d_fractal(vec3 m) {
    return   0.5333333*simplex3d(m*rot1)
 			+0.2666667*simplex3d(2.0*m*rot2)
 			+0.1333333*simplex3d(4.0*m*rot3)
 			+0.0666667*simplex3d(8.0*m);
 }
 void main()
 {
  vec2 v4l2st = texCoordVarying.st;
  v4l2st /= 3;
  v4l2st -= vec2(0.5);
  v4l2st *= 1.65;
  v4l2st += vec2(0.5);
  v4l2st.s -= 35;
  v4l2st.t -= 60;
  float thermo = texture2D(u_v4l2cam, v4l2st).r;
  float depth = texture(u_depth, texCoordVarying.st).x;
  vec4 ray = texture(u_world, texCoordVarying.st);
@ -39,31 +123,28 @@ void main()
  posWorld.y = ray.y * posWorld.z;
  vec3 pos = texture(particles0, texCoordVarying.st).xyz;
-  pos = posWorld.xyz;
+  if(vValid == 1) {
    pos = posWorld.xyz;
  }
  vec3 vel = texture(particles1, texCoordVarying.st).xyz;
-  // mouse attraction
+  vec3 force = vec3(0,0,0);
-  vec3 direction = mouse - pos.xyz;
+  float th = 3.1415 * 4 * simplex3d_fractal(vec3(pos.xyz * 0.001));
-  float distSquared = dot(direction, direction);
+  float phi = 3.1415 * simplex3d_fractal(pos.xyz * 0.002);
-  float magnitude = 500.0 * (1.0 - distSquared / radiusSquared);
+  force.x += cos(th) * cos(phi);
-  vec3 force = step(distSquared, radiusSquared) * magnitude * normalize(direction);
+  force.y += sin(th) * cos(phi);
-
+  force.z += sin(phi);
-  // gravity
+  force *= 50;
  force += vec3(0.0, -0.5, 0.0);
  // accelerate
  vel += elapsed * force;
  // bounce off the sides
  vel.x *= step(abs(pos.x), 512.0) * 2.0 - 1.0;
  vel.y *= step(abs(pos.y), 384.0) * 2.0 - 1.0;
  // damping
-  vel *= 0.995;
+  vel *= 0.95;
  // move
  pos += elapsed * vel;
  posOut = vec4(pos, 1.0);
  velOut = vec4(vel, 0.0);
  misOut = vec4(thermo, 0, 0, 0);
 }
--- a/zoneb/bin/data/shaders/render.frag
+++ b/zoneb/bin/data/shaders/render.frag
@ -1,28 +0,0 @@
 #ifdef GL_ES
 precision mediump float;
 #endif
 // Custom attributes.
 uniform sampler2D uColorTex; // Sampler for the color registered data
 uniform sampler2D u_v4l2cam;
 uniform sampler2D u_gradient;
 uniform sampler2D u_particle;
 in vec2 gTexCoord;
 in float gTemperature;
 void main()
 {
    vec2 st = gTexCoord;
    st /= 3;
    st -= vec2(0.5);
    st *= 1.45;
    st += vec2(0.5);
    st.s += 0.15;
    st.t += 0.16;
    float thermo = gTemperature;//texture2D(u_v4l2cam, st).r;
    gl_FragColor = vec4(texture2D(u_gradient, vec2(thermo, 0.5)).rgb, 1);
    // gl_FragColor = texture2D(u_particle, gTexCoord);
    // gl_FragColor = vec4(1);
 }
--- a/zoneb/bin/data/shaders/render.geom
+++ b/zoneb/bin/data/shaders/render.geom
@ -1,47 +0,0 @@
 #ifdef GL_ES
 precision mediump float;
 #endif
 layout (points) in;
 layout (triangle_strip) out;
 layout (max_vertices = 4) out;
 // OF handled uniforms and attributes.
 uniform mat4 projectionMatrix;
 // App specific uniforms and attributes.
 uniform float uSpriteSize;
 in vec4 vPosition[];
 in vec2 vTexCoord[];
 flat in int vValid[];
 in float vTemperature[];
 out float gTemperature;
 out vec2 gTexCoord;
 void main()
 {
    if (vValid[0] == 0) return;
    gTexCoord = vTexCoord[0];
    gTemperature = vTemperature[0];
    for (int i = 0; i < gl_in.length(); ++i)
    {
        gl_Position = projectionMatrix * (vPosition[i] + vec4(1.0, -1.0, 0.0, 0.0) * uSpriteSize);
        EmitVertex();
        gl_Position = projectionMatrix * (vPosition[i] + vec4(1.0, 1.0, 0.0, 0.0) * uSpriteSize);
        EmitVertex();
        gl_Position = projectionMatrix * (vPosition[i] + vec4(-1.0, -1.0, 0.0, 0.0) * uSpriteSize);
        EmitVertex();
        gl_Position = projectionMatrix * (vPosition[i] + vec4(-1.0, 1.0, 0.0, 0.0) * uSpriteSize);
        EmitVertex();
        EndPrimitive();
    }
 }
--- a/zoneb/bin/data/shaders/render.vert
+++ b/zoneb/bin/data/shaders/render.vert
@ -1,52 +0,0 @@
 #ifdef GL_ES
 precision mediump float;
 #endif
 // OF built-in attributes.
 uniform mat4 modelViewMatrix;
 // Custom attributes.
 uniform sampler2D uDepthTex; // Sampler for the depth space data
 uniform sampler2D uWorldTex; // Transformation from kinect depth/color space to kinect world space
 uniform sampler2D u_particle;
 uniform ivec2 uFrameSize;
 uniform ivec2 uDepthFrameSize;
 uniform vec2 u_resolution;
 out vec4 vPosition;
 out vec2 vTexCoord;
 flat out int vValid;
 out float vTemperature;
 void main()
 {
    vTexCoord = vec2(gl_InstanceID % uFrameSize.x, gl_InstanceID / uFrameSize.x) / uDepthFrameSize;
    vValid = 1;
    // vValid = (depth != 0 && ray.x != 0 && ray.y != 0) ? 1 : 0;
    vec4 posWorld = texture2D(u_particle, vTexCoord);
    vTemperature = posWorld.w;
    posWorld.w = 1;
    // posWorld.xyz *= 65535;
    // // posWorld.xy = vTexCoord * 10000;
    // // posWorld.xy = posWorld.xz * 0.1;
    // // posWorld.z = 10;
    // vValid = posWorld.w > 0.0 ? 1 : 0;
    // posWorld.w = 1;
    // Flip X as OpenGL and K4A have different conventions on which direction is positive.
    // posWorld.x *= -1;
    vPosition = modelViewMatrix * posWorld;
 }
--- a/zoneb/src/ofApp.cpp
+++ b/zoneb/src/ofApp.cpp
@ -18,16 +18,6 @@ void ofApp::setupKinect()
    kinectSettings.updateVbo = false;
    kinectDevice.startCameras(kinectSettings);
  }
  // Load shader.
  shader.load("shaders/render.vert", "shaders/render.frag", "shaders/render.geom");
  // Setup vbo.
  std::vector<glm::vec3> verts(1);
  vbo.setVertexData(verts.data(), verts.size(), GL_STATIC_DRAW);
  pointSize = 2.0f;
  useColorSpace = false;
 }
 void ofApp::setupThermal()
@ -62,9 +52,6 @@ void ofApp::setup()
  setupKinect();
  setupThermal();
  particleShader.allocate(512, 512);
  particleShader.load("shaders/particle.frag");
  boundShader.allocate(ofGetWidth(), ofGetHeight());
  boundShader.load("shaders/bound.frag");
@ -77,7 +64,7 @@ void ofApp::setup()
  unsigned w = 512;
  unsigned h = 512;
-  particles.init(w, h);
+  particles.init(w, h, OF_PRIMITIVE_POINTS, false, 3);
  particles.loadShaders("shaders/particles/update", "shaders/particles/draw");
@ -98,6 +85,7 @@ void ofApp::setup()
  // initial velocities
  particles.zeroDataTexture(ofxGpuParticles::VELOCITY);
  particles.zeroDataTexture(ofxGpuParticles::MISC);
  particles.whateverImages.insert({"u_depth", kinectDevice.getDepthTex()});
  particles.whateverImages.insert({"u_world", kinectDevice.getDepthToWorldTex()});
@ -149,39 +137,6 @@ void ofApp::onParticlesDraw(ofxShader &shader)
 {
 }
 void ofApp::drawKinect()
 {
  ofClear(0);
  cam.begin();
  ofEnableDepthTest();
  // ofDrawAxis(100.0f);
  ofPushMatrix();
  ofRotateXDeg(180);
  shader.begin();
  shader.setUniform1f("uSpriteSize", pointSize);
  int numPoints;
  shader.setUniformTexture("uDepthTex", kinectDevice.getDepthTex(), 1);
  shader.setUniformTexture("uWorldTex", kinectDevice.getDepthToWorldTex(), 2);
  shader.setUniformTexture("uColorTex", kinectDevice.getColorInDepthTex(), 3);
  shader.setUniformTexture("u_v4l2cam", v4l2Tex, 4);
  shader.setUniformTexture("u_gradient", gradient, 5);
  shader.setUniformTexture("u_particle", particleShader, 6);
  shader.setUniform2i("uFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
  shader.setUniform2i("uDepthFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
  numPoints = kinectDevice.getDepthTex().getWidth() * kinectDevice.getDepthTex().getHeight();
  vbo.drawInstanced(GL_POINTS, 0, 1, numPoints);
  shader.end();
  ofPopMatrix();
  cam.end();
 }
 void ofApp::drawMain()
 {
  ofDisableDepthTest();
@ -207,38 +162,8 @@ void ofApp::drawDebug()
 void ofApp::draw()
 {
  ofBackground(0);
  // int i = 3;
  // auto dtex = kinectDevice.getDepthTex();
  // auto wtex = kinectDevice.getDepthToWorldTex();
  // particles.getUpdateShaderRef().setUniformTexture("u_depth", dtex, i++);
  // particles.getUpdateShaderRef().setUniformTexture("u_world", wtex, i++);
  // particles.getUpdateShaderRef().setUniformTexture("u_v4l2cam", v4l2Tex, i++);
  // particles.getUpdateShaderRef().setUniform2i("uFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
  // particles.getUpdateShaderRef().setUniform2i("uDepthFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
  // i = 3;
  // particles.getDrawShaderRef().setUniformTexture("u_depth", dtex, i++);
  // particles.getDrawShaderRef().setUniformTexture("u_world", wtex, i++);
  // particles.getDrawShaderRef().setUniformTexture("u_v4l2cam", v4l2Tex, i++);
  // particles.getDrawShaderRef().setUniform2i("uFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
  // particles.getDrawShaderRef().setUniform2i("uDepthFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
  if (kinectDevice.isStreaming())
  {
    //   auto dtex = kinectDevice.getDepthTex();
    //   auto wtex = kinectDevice.getDepthToWorldTex();
    //   particleShader.setUniformTexture("u_depth", dtex);
    //   particleShader.setUniformTexture("u_world", wtex);
    //   particleShader.setUniformTexture("u_v4l2cam", v4l2Tex);
    //   particleShader.setUniform2i("uFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
    //   particleShader.setUniform2i("uDepthFrameSize", kinectDevice.getDepthTex().getWidth(), kinectDevice.getDepthTex().getHeight());
    //   particleShader.render();
    //   fbos.at("ofcam").begin();
    //   drawKinect();
    //   fbos.at("ofcam").end();
    //   drawMain();
    //   boundShader.draw(0, 0);
    particles.whateverImages.at("u_depth") = kinectDevice.getDepthTex();
    particles.whateverImages.at("u_world") = kinectDevice.getDepthToWorldTex();
    particles.whateverImages.at("u_v4l2cam") = v4l2Tex;
@ -253,18 +178,6 @@ void ofApp::draw()
 void ofApp::keyPressed(int key)
 {
  if (key == 'w')
  {
    pointSize *= 2;
  }
  else if (key == 's')
  {
    pointSize /= 2;
  }
  else if (key == ' ')
  {
    useColorSpace ^= 1;
  }
 }
 void ofApp::keyReleased(int key)
--- a/zoneb/src/ofApp.h
+++ b/zoneb/src/ofApp.h
@ -21,7 +21,6 @@ public:
  void updateThermal();
  void update();
  void drawKinect();
  void drawMain();
  void drawDebug();
  void draw();
@ -43,15 +42,10 @@ public:
 private:
  ofxAzureKinect::Device kinectDevice;
  ofEasyCam cam;
  ofVbo vbo;
  ofxShader shader;
  ofxShaderFilter particleShader;
  ofxShaderFilter boundShader;
  std::map<string, ofFbo> fbos;
  float pointSize;
  bool useColorSpace;
  ofxV4L2 v4l2Cam;
  ofTexture v4l2Tex;