void PlaneMoon::init() {
// Material * skyDomeMat = new Template("Texture", QList<string>() << "uv");
QList<string> attributes = QList<string>() << "normal" << "uv";
initMaterials("Atmo/Space", attributes);
Texture * skyDomeMap = new TextureFile("Earth/StarsMap_2500x1250.jpg", "glow");
fromAtmosphere->addTexture(skyDomeMap);
fromSpace->addTexture(skyDomeMap);
// Mesh * skyDomeMesh = Geometry::sphere(attributes, 1000, 100, 50);
Mesh * skyDomeMesh = Geometry::sphere(attributes, 50, 100, 50);
// Mesh * skyDomeMesh = moonPlane(attributes);
node = new Node("space", QVector3D(0,0,0), 1, skyDomeMesh, fromAtmosphere);
// node->setRotation(QVector3D(-90, 0, 0));
// QList<string> attributes = QList<string>() << "normal" << "uv";
// initMaterials("Atmo/Space", attributes);
//
// Texture * glow = new TextureQImage(ProcTextures::makeGlow(QSize(512, 512), 40.0f, 0.1f), "glow");
// fromAtmosphere->addTexture(glow);
// fromSpace->addTexture(glow);
//
// node = new Node("space", planet->position, planet->getSize(), moonPlane(attributes), fromAtmosphere);
// setAtmoUniforms(fromAtmosphere->getShaderProgram());
// setAtmoUniforms(fromSpace->getShaderProgram());
}
void Object::loadObject( const std::string& filename )
{
Assimp::Importer Importer;
/* Import file
Options:
aiProcess_Triangulate -> translate models which are made from non-triangle polys
into triangle based meshes
aiProcess_GenSmoothNormals -> automatically generate normals, in case the model
doesn't already contain them
*/
const aiScene* pScene = Importer.ReadFile( filename.c_str(),
aiProcess_Triangulate | aiProcess_GenSmoothNormals | aiProcess_FlipUVs );
if( pScene )
{
initFromScene( pScene, filename );
initMaterials( pScene, filename );
}
else
{
std::cerr << "Could not load model\n";
}
}
void Sun::init(){
QList<string> attributes = QList<string>() << "normal" << "uv";
initMaterials("Atmo/Sun", attributes);
Texture * mars = new TextureFile("Planets/Mars.jpg","planet");
fromAtmosphere->addTexture(mars);
fromSpace->addTexture(mars);
node = new Node("sun", planet->position, planet->getSize(), Geometry::sphere(attributes, planet->innerRadius, 800, 400), fromAtmosphere);
node->setRotation(QVector3D(-90,0,180));
}
bool Mesh::initFromScene(const aiScene* pScene, const std::string &filename)
{
m_Entries.resize(pScene->mNumMeshes);
m_Textures.resize(pScene->mNumMaterials);
for(unsigned int i = 0; i < m_Entries.size(); i++)
{
const aiMesh* paiMesh = pScene->mMeshes[i];
initMesh(i, paiMesh);
}
return initMaterials(pScene, filename);
}
// ----------------------------------------------------------------------------
Terrain::Terrain(ISceneNode* parent, ISceneManager* mgr, s32 id,
float x, float z, u32 nx, u32 nz)
:ISceneNode(parent, mgr, id), m_nx(nx), m_nz(nz)
{
m_valid = true;
m_visible = true;
m_bounding_box = aabbox3d<f32>(0, 0, 0, x, 0, z);
setAutomaticCulling(EAC_OFF);
m_tile_num_x = 10;
m_tile_num_z = 10;
m_mesh.vertex_count = nx * nz;
m_mesh.vertices = new S3DVertex2TCoords[m_mesh.vertex_count];
m_mesh.quad_count = (nx - 1) * (nz - 1);
m_mesh.indices = new u16[m_mesh.quad_count * 6];
for (u32 j = 0; j < nz; j++)
for (u32 i = 0; i < nx; i++)
{
m_mesh.vertices[j * nx + i].Pos = vector3df(x / nx * i, 0, z / nz *j);
m_mesh.vertices[j * nx + i].Color = SColor(255, 255, 255, 255);
m_mesh.vertices[j * nx + i].TCoords =
vector2df(i / (float)nx * m_tile_num_x, j / (float)nz * m_tile_num_z);
m_mesh.vertices[j * nx + i].TCoords2 = vector2df(i / (float)nx, j / (float)nz);
}
createIndexList(m_mesh.indices, nx, nz);
m_x = x;
m_z = z;
recalculateNormals();
m_highlight_mesh.vertices = 0;
m_highlight_mesh.indices = 0;
initMaterials();
m_highlight_visible = false;
} // Terrain
void ThreeDimLife::initView() {
glClearColor(0,0,0,0);
glShadeModel(GL_SMOOTH);
glPolygonMode(GL_FRONT, GL_FILL);
glEnable(GL_POLYGON_OFFSET_FILL);
glEnable(GL_DEPTH_TEST);
zoomAmount=75;
rotateX = 45.0;
rotateY = 45.0;
rotateZ = 0.0;
initLights();
initMaterials();
}
bool Mesh::load(const std::string &filename){
Assimp::Importer importer;
const aiScene *pScene = importer.ReadFile(filename, aiProcess_Triangulate | aiProcess_GenSmoothNormals | aiProcess_FlipUVs);
if(pScene){
entries.resize(pScene->mNumMeshes);
textures.resize(pScene->mNumMaterials);
for(size_t i = 0; i < entries.size(); i++){
const aiMesh *pMesh = pScene->mMeshes[i];
initMesh(i,pMesh);
}
initMaterials(pScene,filename);
}
else{
printf("Error parsing '%s': '%s'\n",filename.c_str(),importer.GetErrorString());
return false;
}
return true;
}
void ThreeDimLife::reset() {
array.clear();
array.resize(height);
for (int i=0; i<height; ++i) {
array[i].resize(width);
for (int j=0;j<width; ++j) {
array[i][j].resize(depth, false);
}
}
int num = prob*width*height*depth;
for (int i=0;i<num; ++i) {
size_t ri = randUInt(0, height);
size_t rj = randUInt(0, width);
size_t rk = randUInt(0, depth);
array[ri][rj][rk] = true;
}
initMaterials();
initLights();
}
/*
Initialise des parametres OpenGL
*/
void initGL()
{
/*
** Initialisation
*/
initMaterials();
initLighting();
glFrontFace( GL_CCW );
glEnable( GL_NORMALIZE );
gCam.theta= 0.0;
gCam.phi = 89.0;
gCam.r = 500.0;
gCam.fovy = 45.0;
gCam.ratio = 1.0;
gCam.znear = 1.0;
gCam.zfar = 3000.0;
}
//============================================================================
void TestModel::init()
{
Renderer &rd = Engine::instance().getRenderer();
// Création de la caméra
// XXX mieux vaut ignorer le truc avec les entités
{
cameraEntity = Entity::create();
auto camera = cameraEntity->addComponent<Camera>();
cameraEntity->getTransform().move(glm::vec3(0, 0, -1));
cameraEntity->addComponent<FreeCameraController>();
}
// Création du buffer des paramètres à passer au shader
// TODO mieux vaut ignorer ça pour le moment, ça devrait pas être fait dans le main
frameData = rd.createConstantBuffer(
sizeof(PerFrameShaderParameters),
ResourceUsage::Dynamic,
nullptr);
initModel();
initMaterials();
}
bool Model::init(const char* fileName, const aiScene* scene){
//save our number of vertices so we know how many to draw later
numVertices = vertices.size();
//set up where geometry lives for GL to draw
glGenBuffers(1, &vbo_geometry);
glBindBuffer(GL_ARRAY_BUFFER, vbo_geometry);
glBufferData(GL_ARRAY_BUFFER, vertices.size() * sizeof(Vertex), &vertices[0], GL_STATIC_DRAW);
// --Geometry Done
//setup textures
initMaterials(fileName, scene); //mesh if our file name, scene is our aiScene
//set up our shaders
GLuint vertex_shader = glCreateShader(GL_VERTEX_SHADER);
GLuint fragment_shader = glCreateShader(GL_FRAGMENT_SHADER);
//Shader Sources
// --Shader loader completed, returns string with the shader file
// Note the added uniform!
std::string tempString1 = shaderLoader("assets/shaders/vertex-shader");
const char *vs = tempString1.c_str();
std::string tempString2 = shaderLoader("assets/shaders/fragment-shader");
const char *fs = tempString2.c_str();
//compile the shaders
GLint shader_status;
// Vertex shader first
glShaderSource(vertex_shader, 1, &vs, NULL);
glCompileShader(vertex_shader);
//check the compile status
glGetShaderiv(vertex_shader, GL_COMPILE_STATUS, &shader_status);
if(!shader_status)
{
std::cerr << "[F] FAILED TO COMPILE VERTEX SHADER!" << std::endl;
return false;
}
// Now the Fragment shader
glShaderSource(fragment_shader, 1, &fs, NULL);
glCompileShader(fragment_shader);
//check the compile status
glGetShaderiv(fragment_shader, GL_COMPILE_STATUS, &shader_status);
if(!shader_status)
{
std::cerr << "[F] FAILED TO COMPILE FRAGMENT SHADER!" << std::endl;
return false;
}
//Now we link the 2 shader objects into a program
//This program is what is run on the GPU
program = glCreateProgram();
glAttachShader(program, vertex_shader);
glAttachShader(program, fragment_shader);
glLinkProgram(program);
//check if everything linked ok
glGetProgramiv(program, GL_LINK_STATUS, &shader_status);
if(!shader_status){
std::cerr << "[F] THE SHADER PROGRAM FAILED TO LINK" << std::endl;
return false;
}
//Now we set the locations of the attributes and uniforms
//this allows us to access them easily while rendering
loc_position = glGetAttribLocation(program,
const_cast<const char*>("v_position"));
if(loc_position == -1){
std::cerr << "[F] POSITION NOT FOUND" << std::endl;
return false;
}
loc_color = glGetAttribLocation(program,
const_cast<const char*>("v_color"));
if(loc_color == -1){
std::cerr << "[F] V_COLOR NOT FOUND" << std::endl;
return false;
}
loc_normal = glGetAttribLocation(program,
const_cast<const char*>("v_normal"));
if (loc_normal == -1){
std::cerr << "[F] v_normal not found \n";
}
//add textures
loc_texture = glGetAttribLocation(program,
const_cast<const char*>("texcoord"));
if(loc_texture == -1){
std::cerr << "[F] texcoord NOT FOUND" << std::endl;
return false;
}
loc_mvpmat = glGetUniformLocation(program,
const_cast<const char*>("mvpMatrix"));
if(loc_mvpmat == -1){
std::cerr << "[F] MVPMATRIX NOT FOUND" << std::endl;
return false;
}
return true;
}
void iStatistics::init()
{
initMaterials();
_seconds = iTimer::getInstance().getSeconds();
}
void initGame(void)
{
lcdMainOnTop();
int oldv=getMemFree();
NOGBA("mem free : %dko (%do)",getMemFree()/1024,getMemFree());
NOGBA("initializing...");
videoSetMode(MODE_5_3D | DISPLAY_BG3_ACTIVE);
videoSetModeSub(MODE_5_2D | DISPLAY_BG3_ACTIVE);
glInit();
vramSetPrimaryBanks(VRAM_A_TEXTURE,VRAM_B_TEXTURE,VRAM_C_LCD,VRAM_D_MAIN_BG_0x06000000);
vramSetBankH(VRAM_H_SUB_BG);
vramSetBankI(VRAM_I_SUB_BG_0x06208000);
glEnable(GL_TEXTURE_2D);
// glEnable(GL_ANTIALIAS);
glDisable(GL_ANTIALIAS);
glEnable(GL_BLEND);
glEnable(GL_OUTLINE);
glSetOutlineColor(0,RGB15(0,0,0)); //TEMP?
glSetOutlineColor(1,RGB15(0,0,0)); //TEMP?
glSetOutlineColor(7,RGB15(31,0,0)); //TEMP?
glSetToonTableRange(0, 15, RGB15(8,8,8)); //TEMP?
glSetToonTableRange(16, 31, RGB15(24,24,24)); //TEMP?
glClearColor(31,31,0,31);
glClearPolyID(63);
glClearDepth(0x7FFF);
glViewport(0,0,255,191);
// initVramBanks(1);
initVramBanks(2);
initTextures();
initSound();
initCamera(NULL);
initPlayer(NULL);
initLights();
initParticles();
initMaterials();
loadMaterialSlices("slices.ini");
loadMaterials("materials.ini");
loadControlConfiguration("config.ini");
initElevators();
initWallDoors();
initTurrets();
initBigButtons();
initTimedButtons();
initEnergyBalls();
initPlatforms();
initCubes();
initEmancipation();
initDoors();
initSludge();
initPause();
initText();
NOGBA("lalala");
getPlayer()->currentRoom=&gameRoom;
currentBuffer=false;
getVramStatus();
fadeIn();
mainBG=bgInit(3, BgType_Bmp16, BgSize_B16_256x256, 0, 0);
bgSetPriority(mainBG, 0);
REG_BG0CNT=BG_PRIORITY(3);
#ifdef DEBUG_GAME
consoleInit(&bottomScreen, 3, BgType_Text4bpp, BgSize_T_256x256, 16, 0, false, true);
consoleSelect(&bottomScreen);
#endif
// glSetToonTableRange(0, 14, RGB15(16,16,16));
// glSetToonTableRange(15, 31, RGB15(26,26,26));
initPortals();
//PHYSICS
initPI9();
strcpy(&mapFilePath[strlen(mapFilePath)-3], "map");
newReadMap(mapFilePath, NULL, 255);
transferRectangles(&gameRoom);
makeGrid();
generateRoomGrid(&gameRoom);
gameRoom.displayList=generateRoomDisplayList(&gameRoom, vect(0,0,0), vect(0,0,0), false);
getVramStatus();
startPI();
NOGBA("START mem free : %dko (%do)",getMemFree()/1024,getMemFree());
NOGBA("vs mem free : %dko (%do)",oldv/1024,oldv);
levelInfoCounter=60;
}
/* openGL init */
void myInit() {
t = clock();
/* Enable a single OpenGL light. */
initLighting();
initMaterials();
glEnable(GL_LIGHT0);
glEnable(GL_LIGHTING);
initGroundTexture();
initSkyTexture();
initRailTexture();
initSpline();
calculateNormalsAndBinormals();
/* create the display list */
theSpline = glGenLists(1);
glNewList(theSpline, GL_COMPILE);
/* create cross sections */
glBegin(GL_LINES);
for (int i = 0; i < normals.numControlPoints; i++) {
glVertex3f(rollercoasterSpline.points[i].x, rollercoasterSpline.points[i].y, rollercoasterSpline.points[i].z);
glVertex3f(rollercoasterSpline.points[i].x + normals.points[i].x / 2,
rollercoasterSpline.points[i].y + normals.points[i].y / 2,
rollercoasterSpline.points[i].z + normals.points[i].z / 2);
}
glEnd();
/* create support beams */
glBegin(GL_LINES);
for (int i = 0; i < normals.numControlPoints; i++) {
if (i % 20 == 0) {
glVertex3f(rollercoasterSpline.points[i].x, rollercoasterSpline.points[i].y, rollercoasterSpline.points[i].z);
glVertex3f(rollercoasterSpline.points[i].x, rollercoasterSpline.points[i].y, 0);
glVertex3f(rollercoasterSpline.points[i].x + normals.points[i].x / 2,
rollercoasterSpline.points[i].y + normals.points[i].y / 2,
rollercoasterSpline.points[i].z + normals.points[i].z / 2);
glVertex3f(rollercoasterSpline.points[i].x + normals.points[i].x / 2,
rollercoasterSpline.points[i].y + normals.points[i].y / 2,
0);
}
}
glEnd();
// modulate texture with lighting
glTexEnvf(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_MODULATE);
glBindTexture(GL_TEXTURE_2D, railTexture);
// turn on texture mapping
glEnable(GL_TEXTURE_2D);
/* compute the spline */
glBegin(GL_QUADS);
double alpha = 0.05;
for (int i = 0; i < rollercoasterSpline.numControlPoints; i++) {
double pointX = rollercoasterSpline.points[i].x;
double pointY = rollercoasterSpline.points[i].y;
double pointZ = rollercoasterSpline.points[i].z;
double normX = normals.points[i].x;
double normY = normals.points[i].y;
double normZ = normals.points[i].z;
double binX = binormals.points[i].x;
double binY = binormals.points[i].y;
double binZ = binormals.points[i].z;
double pointX2 = rollercoasterSpline.points[i + 1].x;
double pointY2 = rollercoasterSpline.points[i + 1].y;
double pointZ2 = rollercoasterSpline.points[i + 1].z;
double normX2 = normals.points[i + 1].x;
double normY2 = normals.points[i + 1].y;
double normZ2 = normals.points[i + 1].z;
double binX2 = binormals.points[i + 1].x;
double binY2 = binormals.points[i + 1].y;
double binZ2 = binormals.points[i + 1].z;
double v0X = pointX - alpha*(normX - binX);
double v0Y = pointY - alpha*(normY - binY);
double v0Z = pointZ - alpha*(normZ - binZ);
double v1X = pointX + alpha*(normX + binX);
double v1Y = pointY + alpha*(normY + binY);
double v1Z = pointZ + alpha*(normZ + binZ);
double v2X = pointX + alpha*(normX - binX);
double v2Y = pointY + alpha*(normY - binY);
double v2Z = pointZ + alpha*(normZ - binZ);
double v3X = pointX - alpha*(normX + binX);
double v3Y = pointY - alpha*(normY + binY);
double v3Z = pointZ - alpha*(normZ + binZ);
double v4X = pointX2 - alpha*(normX2 - binX2);
double v4Y = pointY2 - alpha*(normY2 - binY2);
double v4Z = pointZ2 - alpha*(normZ2 - binZ2);
double v5X = pointX2 + alpha*(normX2 + binX2);
double v5Y = pointY2 + alpha*(normY2 + binY2);
double v5Z = pointZ2 + alpha*(normZ2 + binZ2);
double v6X = pointX2 + alpha*(normX2 - binX2);
double v6Y = pointY2 + alpha*(normY2 - binY2);
double v6Z = pointZ2 + alpha*(normZ2 - binZ2);
double v7X = pointX2 - alpha*(normX2 + binX2);
double v7Y = pointY2 - alpha*(normY2 + binY2);
double v7Z = pointZ2 - alpha*(normZ2 + binZ2);
// // // RAIL TWO // // //
double v0X2 = pointX - alpha*(-8 * normX - binX);
double v0Y2 = pointY - alpha*(-8 * normY - binY);
double v0Z2 = pointZ - alpha*(-8 * normZ - binZ);
double v1X2 = pointX + alpha*(10 * normX + binX);
double v1Y2 = pointY + alpha*(10 * normY + binY);
double v1Z2 = pointZ + alpha*(10 * normZ + binZ);
double v2X2 = pointX + alpha*(10 * normX - binX);
double v2Y2 = pointY + alpha*(10 * normY - binY);
double v2Z2 = pointZ + alpha*(10 * normZ - binZ);
double v3X2 = pointX - alpha*(-8 * normX + binX);
double v3Y2 = pointY - alpha*(-8 * normY + binY);
double v3Z2 = pointZ - alpha*(-8 * normZ + binZ);
double v4X2 = pointX2 - alpha*(-8 * normX2 - binX2);
double v4Y2 = pointY2 - alpha*(-8 * normY2 - binY2);
double v4Z2 = pointZ2 - alpha*(-8 * normZ2 - binZ2);
double v5X2 = pointX2 + alpha*(10 * normX2 + binX2);
double v5Y2 = pointY2 + alpha*(10 * normY2 + binY2);
double v5Z2 = pointZ2 + alpha*(10 * normZ2 + binZ2);
double v6X2 = pointX2 + alpha*(10 * normX2 - binX2);
double v6Y2 = pointY2 + alpha*(10 * normY2 - binY2);
double v6Z2 = pointZ2 + alpha*(10 * normZ2 - binZ2);
double v7X2 = pointX2 - alpha*(-8 * normX2 + binX2);
double v7Y2 = pointY2 - alpha*(-8 * normY2 + binY2);
double v7Z2 = pointZ2 - alpha*(-8 * normZ2 + binZ2);
// // // // // // // // //
glNormal3f(-normals.points[i].x, -normals.points[i].y, -normals.points[i].z);
// right side face
glTexCoord2f(1.0, 0.0);
glVertex3f(v0X, v0Y, v0Z);
glTexCoord2f(0.0, 0.0);
glVertex3f(v1X, v1Y, v1Z);
glTexCoord2f(0.0, 1.0);
glVertex3f(v5X, v5Y, v5Z);
glTexCoord2f(1.0, 1.0);
glVertex3f(v4X, v4Y, v4Z);
glNormal3f(-binormals.points[i].x, -binormals.points[i].y, -binormals.points[i].z);
// top face
glTexCoord2f(1.0, 0.0);
glVertex3f(v1X, v1Y, v1Z);
glTexCoord2f(0.0, 0.0);
glVertex3f(v2X, v2Y, v2Z);
glTexCoord2f(0.0, 1.0);
glVertex3f(v6X, v6Y, v6Z);
glTexCoord2f(1.0, 1.0);
glVertex3f(v5X, v5Y, v5Z);
glNormal3f(normals.points[i].x, normals.points[i].y, normals.points[i].z);
// left side face
glTexCoord2f(1.0, 0.0);
glVertex3f(v2X, v2Y, v2Z);
glTexCoord2f(0.0, 0.0);
glVertex3f(v3X, v3Y, v3Z);
glTexCoord2f(0.0, 1.0);
glVertex3f(v7X, v7Y, v7Z);
glTexCoord2f(1.0, 1.0);
glVertex3f(v6X, v6Y, v6Z);
glNormal3f(binormals.points[i].x, binormals.points[i].y, binormals.points[i].z);
// bottom face
glTexCoord2f(1.0, 0.0);
glVertex3f(v0X, v0Y, v0Z);
glTexCoord2f(0.0, 0.0);
glVertex3f(v3X, v3Y, v3Z);
glTexCoord2f(0.0, 1.0);
glVertex3f(v7X, v7Y, v7Z);
glTexCoord2f(1.0, 1.0);
glVertex3f(v4X, v4Y, v4Z);
// // // RAIL TWO // // //
// // // // // // // // //
glNormal3f(-normals.points[i].x, -normals.points[i].y, -normals.points[i].z);
// right side face
glTexCoord2f(1.0, 0.0);
glVertex3f(v0X2, v0Y2, v0Z2);
glTexCoord2f(0.0, 0.0);
glVertex3f(v1X2, v1Y2, v1Z2);
glTexCoord2f(0.0, 1.0);
glVertex3f(v5X2, v5Y2, v5Z2);
glTexCoord2f(1.0, 1.0);
glVertex3f(v4X2, v4Y2, v4Z2);
glNormal3f(-binormals.points[i].x, -binormals.points[i].y, -binormals.points[i].z);
// top face
glTexCoord2f(1.0, 0.0);
glVertex3f(v1X2, v1Y2, v1Z2);
glTexCoord2f(0.0, 0.0);
glVertex3f(v2X2, v2Y2, v2Z2);
glTexCoord2f(0.0, 1.0);
glVertex3f(v6X2, v6Y2, v6Z2);
glTexCoord2f(1.0, 1.0);
glVertex3f(v5X2, v5Y2, v5Z2);
glNormal3f(normals.points[i].x, normals.points[i].y, normals.points[i].z);
// left side face
glTexCoord2f(1.0, 0.0);
glVertex3f(v2X2, v2Y2, v2Z2);
glTexCoord2f(0.0, 0.0);
glVertex3f(v3X2, v3Y2, v3Z2);
glTexCoord2f(0.0, 1.0);
glVertex3f(v7X2, v7Y2, v7Z2);
glTexCoord2f(1.0, 1.0);
glVertex3f(v6X2, v6Y2, v6Z2);
glNormal3f(binormals.points[i].x, binormals.points[i].y, binormals.points[i].z);
// bottom face
glTexCoord2f(1.0, 0.0);
glVertex3f(v0X2, v0Y2, v0Z2);
glTexCoord2f(0.0, 0.0);
glVertex3f(v3X2, v3Y2, v3Z2);
glTexCoord2f(0.0, 1.0);
glVertex3f(v7X2, v7Y2, v7Z2);
glTexCoord2f(1.0, 1.0);
glVertex3f(v4X2, v4Y2, v4Z2);
}
glDisable(GL_TEXTURE_2D);
glEnd();
glEndList();
/* setup gl view here */
glClearColor(0.0, 0.0, 0.0, 0.0);
}
int main ( int argc, char* argv[] )
{
if ( argc != 2 )
{
cout << "usage : " << argv[0] << " SLCFileName" << endl;
cout << argv[0] << " will generate a slc file & idx files" << endl;
return 0;
}
initLC();
initMaterials();
// list<SLCNode*> nodes;
SLCSceneNode scene ( "test_scene");
scene.addChild ( gmat );
scene.addChild ( gmat1 );
scene.addChild ( gmatLine0 );
scene.addChild ( gmatLine );
scene.addChild ( gmatLine2 );
scene.addChild ( gmatLine3 );
{
SLCLayerNode* layer = new SLCLayerNode ( "background", gmat );
nodes.push_back ( layer );
SLCLODNode* lod = new SLCLODNode();
nodes.push_back ( lod );
SLCLODPageNode* lodpage = new SLCLODPageNode();
nodes.push_back ( lodpage );
lodpage->delayloading = false;
lodpage->kdtree = "background0.idx";
lodpage->imposter = true;
scene.addChild ( layer );
layer->addChild ( lod );
lod->addChild ( lodpage );
SLCTransformNode* t = new SLCTransformNode ();
// mat_rotatematrix ( t->mat, M_PI / 2, 2 );
mat_translatematrix ( t->mat, -100, -100, 0 );
nodes.push_back ( t );
lodpage->addChild ( t );
float w = 8900;
float h = 10800;
SLCRectNode* rc1 = new SLCRectNode ( gmat1 );
nodes.push_back ( rc1 );
rc1->pnts[0] = vec2f ( 0, 0 );
rc1->pnts[1] = vec2f ( w, 0 );
rc1->pnts[2] = vec2f ( w, h );
rc1->pnts[3] = vec2f ( 0, h );
rc1->z = -2;
// lodpage->addChild ( rc1 );
t->addChild ( rc1 );
}
{
SLCLayerNode* layer = new SLCLayerNode ( "global routing", gmat );
nodes.push_back ( layer );
SLCLODNode* lod = new SLCLODNode();
nodes.push_back ( lod );
SLCLODPageNode* lodpage = new SLCLODPageNode();
nodes.push_back ( lodpage );
lodpage->delayloading = false;
lodpage->kdtree = "globalrouting0.idx";
lodpage->imposter = true;
scene.addChild ( layer );
layer->addChild ( lod );
lod->addChild ( lodpage );
float w, h;
lodpage->addChild ( globalrouting_lod0(gmat, w, h) );
}
{
float w, h;
SLCLayerNode* layer = new SLCLayerNode ( "local routing", gmat );
nodes.push_back ( layer );
SLCLODNode* lod = new SLCLODNode();
nodes.push_back ( lod );
SLCLODPageNode* lodpage = new SLCLODPageNode();
nodes.push_back ( lodpage );
lodpage->delayloading = false;
lodpage->kdtree = "localrouting0.idx";
lodpage->imposter = true;
scene.addChild ( layer );
layer->addChild ( lod );
lodpage->addChild ( localrouting_lod0(gmat, w, h) );
SLCLODPageNode* lodpage1 = new SLCLODPageNode();
nodes.push_back ( lodpage1 );
lod->addChild ( lodpage1 );
lod->addChild ( lodpage );
lod->scales.push_back (0.00019);
}
{
float w, h;
SLCLayerNode* layer = new SLCLayerNode ( "logic", gmat );
nodes.push_back ( layer );
scene.addChild ( layer );
SLCLODNode* lod = new SLCLODNode();
nodes.push_back ( lod );
layer->addChild ( lod );
SLCLODPageNode* lodpage0 = new SLCLODPageNode();
nodes.push_back ( lodpage0 );
lodpage0->delayloading = false;
lodpage0->kdtree = "logic0.idx";
lodpage0->imposter = true;
lodpage0->addChild ( logic_lod0( gmat, w, h) );
SLCLODPageNode* lodpage1 = new SLCLODPageNode();
nodes.push_back ( lodpage1 );
lodpage1->delayloading = false;
lodpage1->kdtree = "logic1.idx";
lodpage1->imposter = true;
lodpage1->addChild ( logic_lod1( gmat, w, h) );
SLCLODPageNode* lodpage2 = new SLCLODPageNode();
nodes.push_back ( lodpage2 );
lodpage2->delayloading = false;
lodpage2->kdtree = "logic2.idx";
lodpage2->imposter = true;
lodpage2->addChild ( logic_lod2( gmat, w, h) );
lod->addChild ( lodpage0 );
lod->addChild ( lodpage1 );
lod->addChild ( lodpage2 );
lod->scales.push_back (0.00019);
lod->scales.push_back (0.00022);
}
{
float w, h;
SLCLayerNode* layer = new SLCLayerNode ( "port", gmat );
nodes.push_back ( layer );
SLCLODNode* lod = new SLCLODNode();
nodes.push_back ( lod );
SLCLODPageNode* lodpage = new SLCLODPageNode();
nodes.push_back ( lodpage );
lodpage->delayloading = false;
lodpage->kdtree = "port0.idx";
lodpage->imposter = true;
scene.addChild ( layer );
layer->addChild ( lod );
lodpage->addChild ( port_lod0( gmat, w, h) );
SLCLODPageNode* lodpage1 = new SLCLODPageNode();
nodes.push_back ( lodpage1 );
lod->addChild ( lodpage1 );
lod->addChild ( lodpage );
lod->scales.push_back (0.00026);
}
// ofstream o;
// o.open ("test.xml" );
// o << scene.toXML();
// o.close();
// ********************************************************************************
SLCNode2LC node2lc ( &scene );
node2lc.convert ( argv[1] );
for ( list<SLCNode*>::iterator pp=nodes.begin(); pp!=nodes.end(); ++pp )
delete *pp;
LC nlc;
clock_t t = clock();
nlc.load ( argv[1] );
cout << "parse finished, elapse " << clock() - t << "(ms), kdtreesize = " << nlc.kdtrees.size() << endl;
t = clock();
LCReport rpt ( nlc );
rpt.printCounter ();
cout << "traverse finished, elapse " << clock() - t << "(ms)" << endl;
t = clock();
nlc.free();
cout << "free LC finished, elapse " << clock() - t << "(ms)" << endl;
return 0;
}
// ----------------------------------------------------------------------------
Terrain::Terrain(ISceneNode* parent, ISceneManager* mgr, s32 id, FILE* fp)
:ISceneNode(parent, mgr, id)
{
m_visible = true;
m_valid = true;
setAutomaticCulling(EAC_OFF);
fread(&m_x, sizeof(f32), 1, fp);
fread(&m_z, sizeof(f32), 1, fp);
if (m_x < 1 || m_z < 1 || m_x > 500 || m_z > 500)
{
m_valid = false;
return;
}
fread(&m_nx, sizeof(u32), 1, fp);
fread(&m_nz, sizeof(u32), 1, fp);
if (m_nx > 400 || m_nz > 400)
{
m_valid = false;
return;
}
m_bounding_box = aabbox3d<f32>(0, 0, 0, m_x, 0, m_z);
m_tile_num_x = 10;
m_tile_num_z = 10;
m_mesh.vertex_count = m_nx * m_nz;
m_mesh.vertices = new S3DVertex2TCoords[m_mesh.vertex_count];
m_mesh.quad_count = (m_nx - 1) * (m_nz - 1);
m_mesh.indices = new u16[m_mesh.quad_count * 6];
for (u32 j = 0; j < m_nz; j++)
for (u32 i = 0; i < m_nx; i++)
{
m_mesh.vertices[j * m_nx + i].Pos =
vector3df(m_x / m_nx * i, 0, m_z / m_nz *j);
fread(&m_mesh.vertices[j * m_nx + i].Pos.Y, sizeof(f32), 1, fp);
m_mesh.vertices[j * m_nx + i].Color = SColor(255, 255, 255, 255);
m_mesh.vertices[j * m_nx + i].TCoords =
vector2df(i / (float)m_nx * m_tile_num_x, j / (float)m_nz * m_tile_num_z);
m_mesh.vertices[j * m_nx + i].TCoords2 =
vector2df(i / (float)m_nx, j / (float)m_nz);
}
createIndexList(m_mesh.indices, m_nx, m_nz);
recalculateNormals();
m_highlight_mesh.vertices = 0;
m_highlight_mesh.indices = 0;
initMaterials();
u32 x, y;
fread(&x, sizeof(u32), 1, fp);
fread(&y, sizeof(u32), 1, fp);
if (x != SPIMG_X || y != SPIMG_Y)
{
std::cerr << "Warning: splatting image size incorrect!\n";
}
fread(m_material.getTexture(1)->lock(ETLM_WRITE_ONLY), sizeof(u8),
4 * SPIMG_X*SPIMG_Y, fp);
m_material.getTexture(1)->unlock();
m_material.getTexture(1)->regenerateMipMapLevels();
m_highlight_visible = false;
ITexture* tex;
Editor::readTexSt(fp, &tex); m_material.setTexture(2,tex);
Editor::readTexSt(fp, &tex); m_material.setTexture(3, tex);
Editor::readTexSt(fp, &tex); m_material.setTexture(4, tex);
Editor::readTexSt(fp, &tex); m_material.setTexture(5, tex);
} // Terrain - fp
