Sat, 13 Jan 2018 00:04:54 +0200
moved matrix calculations, added inverted normals for BFC back sides
/* * LDForge: LDraw parts authoring CAD * Copyright (C) 2013 - 2017 Teemu Piippo * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see <http://www.gnu.org/licenses/>. */ #define GL_GLEXT_PROTOTYPES #include <GL/glu.h> #include <GL/glext.h> #include "glcompiler.h" #include "miscallenous.h" #include "guiutilities.h" #include "documentmanager.h" #include "grid.h" void checkGLError(HierarchyElement* element, QString file, int line) { struct ErrorInfo { GLenum value; QString text; }; static const ErrorInfo knownErrors[] = { { GL_NO_ERROR, "No error" }, { GL_INVALID_ENUM, "Unacceptable enumerator passed" }, { GL_INVALID_VALUE, "Numeric argument out of range" }, { GL_INVALID_OPERATION, "The operation is not allowed to be done in this state" }, { GL_INVALID_FRAMEBUFFER_OPERATION, "Framebuffer object is not complete"}, { GL_OUT_OF_MEMORY, "Out of memory" }, { GL_STACK_UNDERFLOW, "The operation would have caused an underflow" }, { GL_STACK_OVERFLOW, "The operation would have caused an overflow" }, }; GLenum errorNumber = glGetError(); if (errorNumber != GL_NO_ERROR) { QString errorMessage; for (const ErrorInfo& error : knownErrors) { if (error.value == errorNumber) { errorMessage = error.text; break; } } element->print("OpenGL ERROR: at %1:%2: %3", Basename(file), line, errorMessage); } } /* * Constructs a GL compiler. */ GLCompiler::GLCompiler (GLRenderer* renderer) : HierarchyElement (renderer), m_renderer (renderer) { connect(renderer->model(), SIGNAL(objectAdded(LDObject*)), this, SLOT(compileObject(LDObject*))); connect(renderer->model(), SIGNAL(objectModified(LDObject*)), this, SLOT(compileObject(LDObject*))); connect(renderer->model(), SIGNAL(aboutToRemoveObject(LDObject*)), this, SLOT(forgetObject(LDObject*)), Qt::DirectConnection); connect(renderer, SIGNAL(objectHighlightingChanged(LDObject*)), this, SLOT(compileObject(LDObject*))); connect(m_window, SIGNAL(gridChanged()), this, SLOT(recompile())); for (LDObject* object : renderer->model()->objects()) stageForCompilation(object); } /* * Initializes the VBOs after OpenGL is initialized. */ void GLCompiler::initialize() { initializeOpenGLFunctions(); glGenBuffers(countof(m_vbo), &m_vbo[0]); CHECK_GL_ERROR(); } /* * Destructs the VBOs when the compiler is deleted. */ GLCompiler::~GLCompiler() { glDeleteBuffers(countof(m_vbo), &m_vbo[0]); CHECK_GL_ERROR(); } /* * Returns an index color for the LDObject ID given. This color represents the object in the picking scene. */ QColor GLCompiler::indexColorForID (qint32 id) const { // Calculate a color based from this index. This method caters for // 16777216 objects. I don't think that will be exceeded anytime soon. :) int r = (id / 0x10000) % 0x100; int g = (id / 0x100) % 0x100; int b = id % 0x100; return {r, g, b}; } /* * Returns the suitable color for the polygon. * - polygon is the polygon to colorise. * - polygonOwner is the LDObject from which the polygon originated. * - subclass provides context for the polygon. */ QColor GLCompiler::getColorForPolygon(LDPolygon& polygon, LDObject* polygonOwner, VboSubclass subclass) { QColor color; switch (subclass) { case VboSubclass::Surfaces: case VboSubclass::Normals: case VboSubclass::_End: // Surface and normal VBOs contain vertex data, not colors. So we can't return anything meaningful. return {}; case VboSubclass::BfcFrontColors: // Use the constant green color for BFC front colors return {64, 192, 80}; case VboSubclass::BfcBackColors: // Use the constant red color for BFC back colors return {208, 64, 64}; case VboSubclass::PickColors: // For the picking scene, determine the color from the owner's ID. return indexColorForID(polygonOwner->id()); case VboSubclass::RandomColors: // For the random color scene, the owner object has rolled up a random color. Use that. color = polygonOwner->randomColor(); break; case VboSubclass::RegularColors: // For normal colors, use the polygon's color. if (polygon.color == MainColor) { // If it's the main color, use the polygon owner's color. if (polygonOwner->color() == MainColor) { // If that also is the main color, then we whatever the user has configured the main color to look like. color = guiUtilities()->mainColorRepresentation(); } else { color = polygonOwner->color().faceColor(); } } else if (polygon.color == EdgeColor) { // Edge color is black, unless we have a dark background, in which case lines need to be bright. color = luma(m_config->backgroundColor()) > 40 ? Qt::black : Qt::white; } else { // Not main or edge color, use the polygon's color as is. color = LDColor {polygon.color}.faceColor(); } break; } if (color.isValid()) { // We may wish to apply blending on the color to indicate selection or highlight. double blendAlpha = 0.0; if (polygonOwner->isSelected()) blendAlpha = 1.0; else if (polygonOwner == m_renderer->objectAtCursor()) blendAlpha = 0.5; if (blendAlpha != 0.0) { QColor selectedColor = m_config->selectColorBlend(); double denominator = blendAlpha + 1.0; color.setRed((color.red() + (selectedColor.red() * blendAlpha)) / denominator); color.setGreen((color.green() + (selectedColor.green() * blendAlpha)) / denominator); color.setBlue((color.blue() + (selectedColor.blue() * blendAlpha)) / denominator); } } else { // The color was unknown. Use main color to make the polygon at least not appear pitch-black. if (polygon.num != 2 and polygon.num != 5) color = guiUtilities()->mainColorRepresentation(); else color = Qt::black; // Warn about the unknown color, but only once. static QSet<int> warnedColors; if (not warnedColors.contains(polygon.color)) { print(tr("Unknown color %1!\n"), polygon.color); warnedColors.insert(polygon.color); } } return color; } /* * Tells the compiler that a merge of VBOs is required. */ void GLCompiler::needMerge() { for (int i = 0; i < countof (m_vboChanged); ++i) m_vboChanged[i] = true; } /* * Stages the given object for compilation. */ void GLCompiler::stageForCompilation(LDObject* obj) { m_staged << obj; } /* * Removes an object from the set of objects to be compiled. */ void GLCompiler::unstage(LDObject* obj) { m_staged.remove (obj); } /* * Compiles all staged objects. */ void GLCompiler::compileStaged() { for (LDObject* object : m_staged) compileObject(object); m_staged.clear(); } /* * Prepares a VBO for rendering. The VBO is merged if needed. */ void GLCompiler::prepareVBO (int vbonum) { // Compile anything that still awaits it compileStaged(); if (m_vboChanged[vbonum]) { // Merge the VBO into a vector of floats. QVector<GLfloat> vbodata; for (auto it = m_objectInfo.begin(); it != m_objectInfo.end();) { if (it.key() == nullptr) { it = m_objectInfo.erase(it); } else { if (not it.key()->isHidden()) vbodata += it->data[vbonum]; ++it; } } // Transfer the VBO to the graphics processor. glBindBuffer (GL_ARRAY_BUFFER, m_vbo[vbonum]); glBufferData (GL_ARRAY_BUFFER, countof(vbodata) * sizeof(GLfloat), vbodata.constData(), GL_STATIC_DRAW); glBindBuffer (GL_ARRAY_BUFFER, 0); CHECK_GL_ERROR(); m_vboChanged[vbonum] = false; m_vboSizes[vbonum] = countof(vbodata); } } /* * Removes the data related to the given object. */ void GLCompiler::dropObjectInfo(LDObject* object) { if (m_objectInfo.contains(object)) { // If we have data relating to this object, remove it. The VBOs have changed now and need to be merged. m_objectInfo.remove(object); needMerge(); } } /* * Makes the compiler forget about the given object completely. */ void GLCompiler::forgetObject(LDObject* object) { dropObjectInfo(object); unstage(object); } /* * Compiles a single object. */ void GLCompiler::compileObject(LDObject* object) { if (object == nullptr) return; ObjectVboData info; dropObjectInfo(object); switch (object->type()) { // Note: We cannot split quads into triangles here, it would mess up the wireframe view. // Quads must go into separate vbos. case LDObjectType::Triangle: case LDObjectType::Quadrilateral: case LDObjectType::EdgeLine: case LDObjectType::ConditionalEdge: { LDPolygon* poly = object->getPolygon(); poly->id = object->id(); compilePolygon (*poly, object, info); delete poly; break; } // TODO: try use interfaces to remove these special treatments? case LDObjectType::SubfileReference: { LDSubfileReference* subfileReference = static_cast<LDSubfileReference*>(object); auto data = subfileReference->inlinePolygons(); for (LDPolygon& poly : data) { poly.id = object->id(); compilePolygon (poly, object, info); } break; } case LDObjectType::BezierCurve: { LDBezierCurve* curve = static_cast<LDBezierCurve*>(object); for (LDPolygon& polygon : curve->rasterizePolygons(grid()->bezierCurveSegments())) { polygon.id = object->id(); compilePolygon (polygon, object, info); } } break; default: break; } m_objectInfo[object] = info; needMerge(); } /* * Inserts a single polygon into VBOs. */ void GLCompiler::compilePolygon(LDPolygon& poly, LDObject* polygonOwner, ObjectVboData& objectInfo) { VboClass surface; int vertexCount; switch (poly.num) { case 2: surface = VboClass::Lines; vertexCount = 2; break; case 3: surface = VboClass::Triangles; vertexCount = 3; break; case 4: surface = VboClass::Quads; vertexCount = 4; break; case 5: surface = VboClass::ConditionalLines; vertexCount = 2; break; default: return; } // Determine the normals for the polygon. Vertex normals[4]; auto vertexRing = ring(poly.vertices, vertexCount); for (int i = 0; i < vertexCount; ++i) { const Vertex& v1 = vertexRing[i - 1]; const Vertex& v2 = vertexRing[i]; const Vertex& v3 = vertexRing[i + 1]; normals[i] = Vertex::crossProduct(v3 - v2, v1 - v2).normalized(); } for (VboSubclass complement : iterateEnum<VboSubclass>()) { const int vbonum = vboNumber (surface, complement); QVector<GLfloat>& vbodata = objectInfo.data[vbonum]; const QColor color = getColorForPolygon (poly, polygonOwner, complement); for (int vert = 0; vert < vertexCount; ++vert) { if (complement == VboSubclass::Surfaces) { // Write coordinates. Apparently Z must be flipped too? vbodata << poly.vertices[vert].x() << -poly.vertices[vert].y() << -poly.vertices[vert].z(); } else if (complement == VboSubclass::Normals) { vbodata << normals[vert].x() << -normals[vert].y() << -normals[vert].z(); } else if (complement == VboSubclass::InvertedNormals) { vbodata << -normals[vert].x(); vbodata << +normals[vert].y(); vbodata << +normals[vert].z(); } else { vbodata << ((GLfloat) color.red()) / 255.0f << ((GLfloat) color.green()) / 255.0f << ((GLfloat) color.blue()) / 255.0f << ((GLfloat) color.alpha()) / 255.0f; } } } } int GLCompiler::vboNumber (VboClass surface, VboSubclass complement) { return (static_cast<int>(surface) * EnumLimits<VboSubclass>::Count) + static_cast<int>(complement); } GLuint GLCompiler::vbo (int vbonum) const { return m_vbo[vbonum]; } int GLCompiler::vboSize (int vbonum) const { return m_vboSizes[vbonum]; } /* * Recompiles the entire model. */ void GLCompiler::recompile() { for (LDObject* object : m_renderer->model()->objects()) compileObject(object); }