ofMatrix4x4 ParallelTransportFrames::normalMatrix() const
{
ofMatrix4x4 normalMatrix = ofMatrix4x4::getTransposedOf(const_cast<ofMatrix4x4&>(frames.back()).getInverse());
return ofMatrix4x4(normalMatrix(0, 0), normalMatrix(0, 1), normalMatrix(0, 2), 0.f,
normalMatrix(1, 0), normalMatrix(1, 1), normalMatrix(1, 2), 0.f,
normalMatrix(2, 0), normalMatrix(2, 1), normalMatrix(2, 2), 0.f,
0.f, 0.f, 0.f, 1.f);
}
virtual void redisplay ()
{
static GLuint buf [] = { 0, 0, 0, 0 };
static GLuint counters [4];
counterBuf.setData ( sizeof ( buf ), buf, GL_DYNAMIC_DRAW );
glClear ( GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT );
mat4 mv = mat4 :: rotateZ ( toRadians ( rot.z ) ) * mat4 :: rotateY ( toRadians ( rot.y ) ) * mat4 :: rotateX ( toRadians ( rot.x ) );
mat3 nm = normalMatrix ( mv );
program.bind ();
program.setUniformMatrix ( "mv", mv );
program.setUniformMatrix ( "nm", nm );
mesh -> render ();
program.unbind ();
glFinish ();
counterBuf.getSubData ( 0, sizeof ( buf ), counters );
printf ( "%4d %4d %d %d\n", counters [0], counters [1], counters [2], counters [3] );
}
void Node::Render(GLint texLoc, GLint matLoc, GLint normalMatLoc, glm::mat4 viewMat)
{
transform_global = transform_local;
if (m_Mesh != 0 && m_Texture != 0)
{
glm::mat3 normalMatrix(viewMat * transform_global);
glm::inverseTranspose(normalMatrix);
glUniformMatrix3fv(normalMatLoc, 1, GL_FALSE, glm::gtc::type_ptr::value_ptr(normalMatrix));
CheckOpenGLError("passing normalMat in root node");
glUniformMatrix4fv(matLoc, 1, GL_FALSE, glm::gtc::type_ptr::value_ptr(transform_global));
glUniform1i(texLoc, m_Texture->getUnit());
CheckOpenGLError("passing uniforms in root node");
glActiveTexture(GL_TEXTURE0 + m_Texture->getUnit());
glBindTexture(GL_TEXTURE_2D, m_Texture->getID());
glBindSampler(m_Texture->getUnit(), m_Texture->getSampler());
CheckOpenGLError("binding texture in root node");
m_Mesh->draw();
glBindTexture(GL_TEXTURE_2D, 0);
}
for (GLuint i = 0; i < m_children.size(); i++)
{
m_children[i]->Render(texLoc, matLoc, transform_global, normalMatLoc, viewMat);
CheckOpenGLError("render children in node");
}
}
Eigen::MatrixXd RMFE::getNormalMatrix() {
Eigen::MatrixXd normalMatrix(3, this->cloud_filtered_normals->points.size());
for (int i = 0; i < this->cloud_filtered_normals->points.size(); i++) {
normalMatrix.col(i) << this->cloud_filtered_normals->points[i].normal_x, this->cloud_filtered_normals->points[i].normal_y, this->cloud_filtered_normals->points[i].normal_z;
}
return normalMatrix;
}
UtilityMath::S_Matrix3x3<T> UtilityMath::S_Matrix3x3<T>::s_CreateNormal(const UtilityMath::S_Matrix4x4<T>& rMatrix)
{
S_Matrix3x3 normalMatrix(s_ConvertMatrix4x4ToMatrix3x3(rMatrix));
normalMatrix.Invert();
normalMatrix.Transpose();
return normalMatrix;
}
void Viewer::drawSphere(const QMatrix4x4& transform, bool picking) {
auto r = sceneRoot->get_transform() * puppetRotation * sceneRoot->get_inverse();
auto modelMatrix = puppetPosition * r * transform;
auto vp = getCameraMatrix();
auto mvMatrix = mTransformMatrix * modelMatrix;
mSphereBufferObject.bind();
sphereShaders.setAttributeBuffer("vert", GL_FLOAT, 0, 3);
mSphereNormalBuffer.bind();
sphereShaders.setAttributeBuffer("norm", GL_FLOAT, 0, 3);
sphereShaders.setUniformValue(mvpMatrixLoc, vp * modelMatrix);
sphereShaders.setUniformValue(mvMatrixLoc, mvMatrix);
sphereShaders.setUniformValue(normMatrixLoc, mvMatrix.normalMatrix());
// Whether or not we are picking (to do lighting or not)
sphereShaders.setUniformValue(flatLoc, picking);
// Light position shouldn't change: always on the eye
sphereShaders.setUniformValue(lightPositionLoc, mTransformMatrix * QVector3D());
glDrawArrays(GL_TRIANGLES, 0, numTriangles * 9);
}
void Node::Render(GLint texLoc, GLint matLoc, glm::mat4 const &transform, GLint normalMatLoc, glm::mat4 viewMat)
{
transform_global = transform * transform_local;
if (m_Mesh != 0 && m_Texture != 0)
{
glm::mat3 normalMatrix(viewMat * transform_global);
glm::inverseTranspose(normalMatrix);
glUniformMatrix3fv(normalMatLoc, 1, GL_FALSE, glm::gtc::type_ptr::value_ptr(normalMatrix));
CheckOpenGLError("passing normalMat in child node");
glUniformMatrix4fv(matLoc, 1, GL_FALSE, glm::value_ptr(transform_global));
glUniform1i(texLoc, m_Texture->getUnit());
CheckOpenGLError("passing uniform in child node");
glActiveTexture(GL_TEXTURE0 + m_Texture->getUnit());
glBindTexture(GL_TEXTURE_2D, m_Texture->getID());
m_Mesh->draw();
glBindTexture(GL_TEXTURE_2D, 0);
}
}
// Display function for GLUT
void display()
{
glViewport(0,0,WIN_WIDTH,WIN_HEIGHT);
glClear(GL_COLOR_BUFFER_BIT | GL_DEPTH_BUFFER_BIT);
// camera = crTrans * csTrans * ctTrans * camera;
mat4 modelCam = camera * modelView;
// Grab the normal matrix from the modelview matrix (upper 3x3 entries of
// modelview).
mat3 normalMatrix(modelCam);
normalMatrix = inverse(normalMatrix);
normalMatrix = transpose(normalMatrix);
// Tell OpenGL which shader program we want to use. In this case, we are only
// using one, but in general we might have many shader programs.
glUseProgram(shader->program);
// Pass the matrices and animation time to GPU
glUniformMatrix4fv(shader->modelViewLoc, 1, GL_FALSE, value_ptr(modelCam));
glUniformMatrix4fv(shader->projectionLoc, 1, GL_FALSE, value_ptr(projection));
glUniformMatrix3fv(shader->normalMatrixLoc, 1, GL_FALSE, value_ptr(normalMatrix));
glUniform3fv(shader->lightPosLoc, 1, value_ptr(lightPos));
glUniform3fv(shader->viewPosLoc, 1, value_ptr(viewPos));
// Buffer vertex data
glBindBuffer(GL_ARRAY_BUFFER, shader->vertexBuffer);
glBufferData(GL_ARRAY_BUFFER, verts.size() * sizeof(float), verts.data(), GL_DYNAMIC_DRAW);
// Enable vertex array
glEnableVertexAttribArray(shader->vertexLoc);
glVertexAttribPointer(shader->vertexLoc, 3, GL_FLOAT, GL_FALSE, 0, NULL);
// Buffer normal data
glBindBuffer(GL_ARRAY_BUFFER, shader->normalBuffer);
glBufferData(GL_ARRAY_BUFFER, norms.size() * sizeof(float), norms.data(), GL_DYNAMIC_DRAW);
// Enable normal array
glEnableVertexAttribArray(shader->normalLoc);
glVertexAttribPointer(shader->normalLoc, 3, GL_FLOAT, GL_FALSE, 0, NULL);
// Buffer color data
glBindBuffer(GL_ARRAY_BUFFER, shader->colorBuffer);
glBufferData(GL_ARRAY_BUFFER, color.size() * sizeof(float), color.data(), GL_DYNAMIC_DRAW);
// Enable color array
glEnableVertexAttribArray(shader->colorLoc);
glVertexAttribPointer(shader->colorLoc, 4, GL_FLOAT, GL_FALSE, 0, NULL);
//Bind element buffer
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, shader->indexBuffer);
for (int i = 0; i < (int) shapes.size(); i++)
{
glDrawArrays(GL_TRIANGLE_FAN, shapes[i]->startIndex / 3, shapes[i]->numVertices());
}
//----------------------------DRAW ARROW----------------------------//
if(ballMoving == false){
// Update arrow rotation
arrow->rotate(launchAngle);
modelCam = camera * arrow->getModelTransformMatrix();
//Pass the matrix
glUniformMatrix4fv(shader->modelViewLoc, 1, GL_FALSE, value_ptr(modelCam));
// Buffer vertex data
glBindBuffer(GL_ARRAY_BUFFER, shader->vertexBuffer);
glBufferData(GL_ARRAY_BUFFER, arrow->getVerts().size() * sizeof(glm::vec3), arrow->getVerts().data(), GL_DYNAMIC_DRAW);
// Enable vertex array
glEnableVertexAttribArray(shader->vertexLoc);
glVertexAttribPointer(shader->vertexLoc, 3, GL_FLOAT, GL_FALSE, 0, NULL);
// Disable normal array
glDisableVertexAttribArray(shader->normalLoc);
// Buffer color data
glBindBuffer(GL_ARRAY_BUFFER, shader->colorBuffer);
glBufferData(GL_ARRAY_BUFFER, arrow->getVertColors().size() * sizeof(glm::vec4), arrow->getVertColors().data(), GL_DYNAMIC_DRAW);
// Enable color array
glEnableVertexAttribArray(shader->colorLoc);
glVertexAttribPointer(shader->colorLoc, 4, GL_FLOAT, GL_FALSE, 0, NULL);
glDrawArrays(GL_LINES, 0, 6);
}
glutSwapBuffers();
}
ofVec3f ParallelTransportFrames::calcCurrentNormal() const
{
return getStartNormal() * normalMatrix();
}
//-----------------------------------------------------------------------------
// set standard variables for shader
void mgGL33Services::setShaderStdUniforms(
mgShaderHandle shader)
{
mgMatrix4 mvpMatrix(m_worldMatrix);
mvpMatrix.multiply(m_worldProjection);
GLint index;
GLfloat matrix[16];
CHECK_THREAD();
index = glGetUniformLocation(shader, "mgMVPMatrix");
if (index != -1)
{
matrix4toGL(mvpMatrix, matrix);
glUniformMatrix4fv(index, 1, GL_FALSE, matrix);
}
index = glGetUniformLocation(shader, "mgMVMatrix");
if (index != -1)
{
matrix4toGL(m_worldMatrix, matrix);
glUniformMatrix4fv(index, 1, GL_FALSE, matrix);
}
index = glGetUniformLocation(shader, "mgModelMatrix");
if (index != -1)
{
matrix4toGL(m_modelMatrix, matrix);
glUniformMatrix4fv(index, 1, GL_FALSE, matrix);
}
index = glGetUniformLocation(shader, "mgNormalMatrix");
if (index != -1)
{
normalMatrix(m_worldMatrix, matrix);
glUniformMatrix3fv(index, 1, GL_FALSE, matrix);
}
index = glGetUniformLocation(shader, "mgVPMatrix");
if (index != -1)
{
mgMatrix4 vpMatrix;
vpMatrix.translate(-m_eyePt.x, -m_eyePt.y, -m_eyePt.z);
vpMatrix.multiply(m_eyeMatrix);
vpMatrix.multiply(m_worldProjection);
matrix4toGL(vpMatrix, matrix);
glUniformMatrix4fv(index, 1, GL_FALSE, matrix);
}
index = glGetUniformLocation(shader, "mgEyePt");
if (index != -1)
{
glUniform3f(index, (GLfloat) m_eyePt.x, (GLfloat) m_eyePt.y, (GLfloat) m_eyePt.z);
}
// transform the light dir by eye matrix. negate, since we want vector from point to light
index = glGetUniformLocation(shader, "mgLightDir");
if (index != -1)
{
mgPoint3 eyeLightDir;
m_eyeMatrix.mapPt(m_lightDir, eyeLightDir);
glUniform3f(index, (GLfloat) eyeLightDir.x, (GLfloat) eyeLightDir.y, (GLfloat) eyeLightDir.z);
}
index = glGetUniformLocation(shader, "mgLightColor");
if (index != -1)
{
glUniform3f(index, (GLfloat) m_lightColor.x, (GLfloat) m_lightColor.y, (GLfloat) m_lightColor.z);
}
index = glGetUniformLocation(shader, "mgLightAmbient");
if (index != -1)
{
glUniform3f(index, (GLfloat) m_lightAmbient.x, (GLfloat) m_lightAmbient.y, (GLfloat) m_lightAmbient.z);
}
index = glGetUniformLocation(shader, "mgMatColor");
if (index != -1)
{
glUniform4f(index, (GLfloat) m_matColor.x, (GLfloat) m_matColor.y, (GLfloat) m_matColor.z, (GLfloat) m_matColor.w);
}
char varName[128];
for (int unit = 0; ; unit++)
{
sprintf(varName, "mgTextureUnit%d", unit);
index = glGetUniformLocation(shader, varName);
if (index != -1)
glUniform1i(index, unit);
else break;
}
// vars up to date
m_updateShaderVars = false;
}
void Earth::draw() const {
Camera* cam = static_cast<Camera*>(getGame()->getObjectByName("cam"));
// mat4f t = glm::scale(fullTransform, vec3f(radius));
// mat4f modelViewProjectionMatrix = cam->projection * cam->view * t;
// mat4f modelViewMatrix = t;
// mat4f normalMatrix( glm::transpose(glm::inverse(modelViewMatrix)));
// vec3f lightPos = vec3f(0,0,0); // parentObject->pos;
// Texture* earth_day = TextureManager::get("earth_daytime");
// earth_day->bind();
// sphere.program->uniform("sampler")->set(2);
// Texture* earth_night = TextureManager::get("earth_nighttime");
// earth_night->bind();
// sphere.program->uniform("EarthNight")->set(3);
// Texture* earth_cloud = TextureManager::get("earth_cloud");
// earth_cloud->bind();
// sphere.program->uniform("EarthCloudGloss")->set(4);
// Texture* earth_specular_map = TextureManager::get("earth_specular");
// earth_specular_map->bind();
// sphere.program->uniform("EarthSpecularMap")->set(5);
// sphere.program->uniform("LightPosition")->set(lightPos);
// sphere.program->uniform("MVPMatrix")->set(modelViewProjectionMatrix);
// sphere.program->uniform("MVMatrix")->set(modelViewMatrix);
// sphere.program->uniform("NormalMatrix")->set(normalMatrix);
mat4f projection = cam->projection;
mat4f view = cam->view;
mat4f model = glm::scale(fullTransform, getScale());
mat4f t = projection*view*model;
mat4f normalMatrix( glm::transpose(glm::inverse(model)));
vec3f lightPos = vec3f(0.0f);// - position;
float shininess = 10.0f;
vec3f emission = vec3f(0.0f);
//vec3f specular = vec3f(0.5f);
vec3f specular = vec3f(1.0f, 0.9255f, 0.698f)*0.3f;
vec3f lightAmbient = vec3f(0.0f);
vec3f lightDiffuse(1.0f);
vec3f lightSpecular(1.0f);
mat4f viewModel = glm::inverse(view*model);
vec4f camPos = viewModel[3];
mat4f iModel = ( (glm::inverse(model)));
vec3f cameraPos = vec3f(camPos); //(vec3f) (iModel*(vec4f(cam->getPosition(), 0)));//**** //vec3f(model*vec4f(cam->getPosition(),1.0));//
float Kr = 0.0025f;
float Km = 0.0010f;
float ESun = 2.f;
float fScale = 1.f/(outerRadius-innerRadius);
float fScaleDepth = 0.25f; //Must be 25%
float fCameraHeight = glm::length(cameraPos);
float g = -0.750f; // Mie aerosol scattering constant
float g2 = g*g;
vec3f wavelength = vec3f(0.650f, 0.570f, 0.475f);
vec3f v3InvWavelength = vec3f(1.0f / powf(wavelength.x, 4.0f), 1.0f / powf(wavelength.y, 4.0f), 1.0f / powf(wavelength.z, 4.0f));
vec3f lightPos_v2 = glm::normalize(mul4(iModel, -getPosition()));
// vec3f lightPos = vec3f(0.f);
sphere.program->uniform("v3CameraPos")->set(cameraPos); // The camera's current position
sphere.program->uniform("v3LightPos")->set(lightPos_v2); // The direction vector to the light source
sphere.program->uniform("v3InvWavelength")->set(v3InvWavelength); // 1 / pow(wavelength, 4) for the red, green, and blue channels
// sphere.program->uniform("fCameraHeight")->set(fCameraHeight); // The camera's current height
sphere.program->uniform("fCameraHeight2")->set(fCameraHeight*fCameraHeight); // fCameraHeight^2
sphere.program->uniform("fOuterRadius")->set(outerRadius); // The outer (spheresphere) radius
sphere.program->uniform("fOuterRadius2")->set(outerRadius*outerRadius); // fOuterRadius^2
sphere.program->uniform("fInnerRadius")->set(innerRadius); // The inner (planetary) radius
// sphere.program->uniform("fInnerRadius2")->set(innerRavec3f(0.0f);//******* //dius*innerRadius); // fInnerRadius^2
sphere.program->uniform("fKrESun")->set(Kr*ESun); // Kr * ESun
sphere.program->uniform("fKmESun")->set(Km*ESun); // Kr * ESun
sphere.program->uniform("fKr4PI")->set(Kr*4.f*PI); // Kr * 4 * PI
sphere.program->uniform("fKm4PI")->set(Km*4.f*PI); // Km * 4 * PI
sphere.program->uniform("fScale")->set(fScale); // 1 / (fOuterRadius - fInnerRadius)
sphere.program->uniform("fScaleDepth")->set(fScaleDepth); // The scale depth (i.e. the altitude at which the spheresphere's average density is found)
sphere.program->uniform("fScaleOverScaleDepth")->set(fScale / (fScaleDepth) ); // fScale / fScaleDepth
sphere.program->uniform("lightPos")->set(lightPos);
sphere.program->uniform("shininess")->set(shininess);
sphere.program->uniform("emission")->set(emission);
sphere.program->uniform("specular")->set(specular);
sphere.program->uniform("lightAmbient")->set(lightAmbient);
sphere.program->uniform("lightDiffuse")->set(lightDiffuse);
//sphere.program->uniform("lightSpecular")->set(lightSpecular);
Texture* tex;
tex = Textures.get("earth");
tex->bind();
sphere.program->uniform("sampler")->set((int)tex->getSlot());
tex = Textures.get("earthNight");
tex->bind();
sphere.program->uniform("samplerNight")->set((int)tex->getSlot());
tex = Textures.get("earthWater");
tex->bind();
sphere.program->uniform("samplerWater")->set((int)tex->getSlot());
tex = Textures.get("earthWaterTex");
tex->bind();
sphere.program->uniform("samplerWaterTex")->set((int)tex->getSlot());
tex = Textures.get("earthNormal");
tex->bind();
sphere.program->uniform("samplerNormal")->set((int)tex->getSlot());
tex = Textures.get("earthClouds");
tex->bind();
sphere.program->uniform("samplerCloud")->set((int)tex->getSlot());
sphere.program->uniform("modelViewProjectionMatrix")->set(t);
sphere.program->uniform("modelMatrix")->set(model);
sphere.program->uniform("viewMatrix")->set(view);
sphere.program->uniform("normalMatrix")->set(normalMatrix);
sphere.program->uniform("globaltime")->set(time);
//glDisable(GL_CULL_FACE);
//glDepthMask(GL_FALSE);
sphere.draw();
//glDepthMask(GL_TRUE);
//glEnable(GL_CULL_FACE);
}
