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OpenSpace/modules/digitaluniverse/rendering/renderablebillboardscloud.cpp
Alexander Bock cc178d03f3 Remove clang warnings 
Update SGCT repository
2017-12-29 19:47:33 +01:00

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/*****************************************************************************************
* *
* OpenSpace *
* *
* Copyright (c) 2014-2017 *
* *
* Permission is hereby granted, free of charge, to any person obtaining a copy of this *
* software and associated documentation files (the "Software"), to deal in the Software *
* without restriction, including without limitation the rights to use, copy, modify, *
* merge, publish, distribute, sublicense, and/or sell copies of the Software, and to *
* permit persons to whom the Software is furnished to do so, subject to the following *
* conditions: *
* *
* The above copyright notice and this permission notice shall be included in all copies *
* or substantial portions of the Software. *
* *
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, *
* INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A *
* PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT *
* HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF *
* CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE *
* OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. *
****************************************************************************************/
#include <modules/digitaluniverse/rendering/renderablebillboardscloud.h>
#include <openspace/documentation/documentation.h>
#include <openspace/documentation/verifier.h>
#include <openspace/util/updatestructures.h>
#include <openspace/engine/openspaceengine.h>
#include <openspace/rendering/renderengine.h>
#include <ghoul/filesystem/filesystem>
#include <ghoul/misc/templatefactory.h>
#include <ghoul/io/texture/texturereader.h>
#include <ghoul/opengl/programobject.h>
#include <ghoul/opengl/texture.h>
#include <ghoul/opengl/textureunit.h>
#include <ghoul/font/fontmanager.h>
#include <ghoul/font/fontrenderer.h>
#include <glm/gtx/string_cast.hpp>
#include <ghoul/glm.h>
#include <array>
#include <fstream>
#include <stdint.h>
#include <locale>
#include <string>
namespace {
constexpr const char* _loggerCat = "RenderableBillboardsCloud";
constexpr const char* KeyFile = "File";
constexpr const char* keyColor = "Color";
constexpr const char* keyUnit = "Unit";
constexpr const char* MeterUnit = "m";
constexpr const char* KilometerUnit = "Km";
constexpr const char* ParsecUnit = "pc";
constexpr const char* KiloparsecUnit = "Kpc";
constexpr const char* MegaparsecUnit = "Mpc";
constexpr const char* GigaparsecUnit = "Gpc";
constexpr const char* GigalightyearUnit = "Gly";
constexpr int8_t CurrentCacheVersion = 1;
constexpr double PARSEC = 0.308567756E17;
static const openspace::properties::Property::PropertyInfo SpriteTextureInfo = {
"Texture",
"Point Sprite Texture",
"The path to the texture that should be used as the point sprite."
};
static const openspace::properties::Property::PropertyInfo TransparencyInfo = {
"Transparency",
"Transparency",
"This value is a multiplicative factor that is applied to the transparency of "
"all points."
};
static const openspace::properties::Property::PropertyInfo ScaleFactorInfo = {
"ScaleFactor",
"Scale Factor",
"This value is used as a multiplicative factor that is applied to the apparent "
"size of each point."
};
static const openspace::properties::Property::PropertyInfo ColorInfo = {
"Color",
"Color",
"This value is used to define the color of the astronomical object."
};
static const openspace::properties::Property::PropertyInfo ColorMapInfo = {
"ColorMap",
"Color Map File",
"The path to the color map file of the astronomical object."
};
static const openspace::properties::Property::PropertyInfo PolygonSidesInfo = {
"PolygonSides",
"Polygon Sides",
"The number of sides for the polygon used to represent the astronomical object."
};
static const openspace::properties::Property::PropertyInfo TextColorInfo = {
"TextColor",
"Text Color",
"The text color for the astronomical object."
};
static const openspace::properties::Property::PropertyInfo TextSizeInfo = {
"TextSize",
"Text Size",
"The text size for the astronomical object labels."
};
static const openspace::properties::Property::PropertyInfo LabelFileInfo = {
"LabelFile",
"Label File",
"The path to the label file that contains information about the astronomical "
"objects being rendered."
};
static const openspace::properties::Property::PropertyInfo LabelMinSizeInfo = {
"TextMinSize",
"Text Min Size",
"The minimal size (in pixels) of the text for the labels for the astronomical "
"objects being rendered."
};
static const openspace::properties::Property::PropertyInfo LabelMaxSizeInfo = {
"TextMaxSize",
"Text Max Size",
"The maximum size (in pixels) of the text for the labels for the astronomical "
"objects being rendered."
};
static const openspace::properties::Property::PropertyInfo DrawElementsInfo = {
"DrawElements",
"Draw Elements",
"Enables/Disables the drawing of the astronomical objects."
};
static const openspace::properties::Property::PropertyInfo DrawLabelInfo = {
"DrawLabels",
"Draw Labels",
"Determines whether labels should be drawn or hidden."
};
static const openspace::properties::Property::PropertyInfo ColorOptionInfo = {
"ColorOption",
"Color Option",
"This value determines which paramenter is used default color of the "
"astronomical objects."
};
static const openspace::properties::Property::PropertyInfo ColorRangeInfo = {
"ColorRange",
"Color Range",
"This value determines the color ranges for the color parameter of the "
"astronomical objects."
};
static const openspace::properties::Property::PropertyInfo TransformationMatrixInfo =
{
"TransformationMatrix",
"Transformation Matrix",
"Transformation matrix to be applied to each astronomical object."
};
static const openspace::properties::Property::PropertyInfo RenderOptionInfo = {
"RenderOptionInfo",
"Render Option",
"Debug option for rendering of billboards and texts."
};
static const openspace::properties::Property::PropertyInfo FadeInDistancesInfo = {
"FadeInDistances",
"Fade-In Start and End Distances",
"These values determine the initial and final distances from the center of "
"our galaxy from which the astronomical object will start and end "
"fading-in."
};
static const openspace::properties::Property::PropertyInfo DisableFadeInInfo = {
"DisableFadeIn",
"Disable Fade-in effect",
"Enables/Disables the Fade-in effect."
};
static const openspace::properties::Property::PropertyInfo BillboardMaxSizeInfo = {
"BillboardMaxSize",
"Billboard Max Size in Pixels",
"The max size (in pixels) for the billboard representing the astronomical "
"object."
};
static const openspace::properties::Property::PropertyInfo BillboardMinSizeInfo = {
"BillboardMinSize",
"Billboard Min Size in Pixels",
"The min size (in pixels) for the billboard representing the astronomical "
"object."
};
} // namespace
namespace openspace {
documentation::Documentation RenderableBillboardsCloud::Documentation() {
using namespace documentation;
return {
"RenderableBillboardsCloud",
"digitaluniverse_RenderableBillboardsCloud",
{
{
"Type",
new StringEqualVerifier("RenderableBillboardsCloud"),
Optional::No
},
{
KeyFile,
new StringVerifier,
Optional::Yes,
"The path to the SPECK file that contains information about the "
"astronomical object being rendered."
},
{
keyColor,
new Vector3Verifier<float>,
Optional::No,
"Astronomical Object Color (r,g,b)."
},
{
SpriteTextureInfo.identifier,
new StringVerifier,
Optional::Yes,
SpriteTextureInfo.description
},
{
TransparencyInfo.identifier,
new DoubleVerifier,
Optional::No,
TransparencyInfo.description
},
{
ScaleFactorInfo.identifier,
new DoubleVerifier,
Optional::Yes,
ScaleFactorInfo.description
},
{
ColorMapInfo.identifier,
new StringVerifier,
Optional::Yes,
ColorMapInfo.description
},
{
PolygonSidesInfo.identifier,
new IntVerifier,
Optional::Yes,
PolygonSidesInfo.description
},
{
DrawLabelInfo.identifier,
new BoolVerifier,
Optional::Yes,
DrawLabelInfo.description
},
{
TextColorInfo.identifier,
new DoubleVector4Verifier,
Optional::Yes,
TextColorInfo.description
},
{
TextSizeInfo.identifier,
new DoubleVerifier,
Optional::Yes,
TextSizeInfo.description
},
{
LabelFileInfo.identifier,
new StringVerifier,
Optional::Yes,
LabelFileInfo.description
},
{
LabelMinSizeInfo.identifier,
new DoubleVerifier,
Optional::Yes,
LabelMinSizeInfo.description
},
{
LabelMaxSizeInfo.identifier,
new DoubleVerifier,
Optional::Yes,
LabelMaxSizeInfo.description
},
{
ColorOptionInfo.identifier,
new StringListVerifier,
Optional::Yes,
ColorOptionInfo.description
},
{
ColorRangeInfo.identifier,
new Vector2ListVerifier<float>,
Optional::Yes,
ColorRangeInfo.description
},
{
TransformationMatrixInfo.identifier,
new Matrix4x4Verifier<double>,
Optional::Yes,
TransformationMatrixInfo.description
},
{
FadeInDistancesInfo.identifier,
new Vector2Verifier<double>,
Optional::Yes,
FadeInDistancesInfo.description
},
{
DisableFadeInInfo.identifier,
new BoolVerifier,
Optional::Yes,
DisableFadeInInfo.description
},
{
BillboardMaxSizeInfo.identifier,
new DoubleVerifier,
Optional::Yes,
BillboardMaxSizeInfo.description
},
{
BillboardMinSizeInfo.identifier,
new DoubleVerifier,
Optional::Yes,
BillboardMinSizeInfo.description
}
}
};
}
RenderableBillboardsCloud::RenderableBillboardsCloud(const ghoul::Dictionary& dictionary)
: Renderable(dictionary)
, _hasSpeckFile(false)
, _dataIsDirty(true)
, _textColorIsDirty(true)
, _hasSpriteTexture(false)
, _spriteTextureIsDirty(true)
, _hasColorMapFile(false)
, _hasPolygon(false)
, _hasLabel(false)
, _labelDataIsDirty(true)
, _polygonSides(0)
, _pTexture(0)
, _alphaValue(TransparencyInfo, 1.f, 0.f, 1.f)
, _scaleFactor(ScaleFactorInfo, 1.f, 0.f, 600.f)
, _pointColor(
ColorInfo,
glm::vec3(1.f, 0.4f, 0.2f),
glm::vec3(0.f, 0.f, 0.f),
glm::vec3(1.0f, 1.0f, 1.0f)
)
, _spriteTexturePath(SpriteTextureInfo)
, _textColor(
TextColorInfo,
glm::vec4(1.0f, 1.0, 1.0f, 1.f),
glm::vec4(0.f),
glm::vec4(1.f)
)
, _textSize(TextSizeInfo, 8.0, 0.5, 24.0)
, _textMinSize(LabelMinSizeInfo, 8.0, 0.5, 24.0)
, _textMaxSize(LabelMaxSizeInfo, 500.0, 0.0, 1000.0)
, _drawElements(DrawElementsInfo, true)
, _drawLabels(DrawLabelInfo, false)
, _colorOption(ColorOptionInfo, properties::OptionProperty::DisplayType::Dropdown)
, _fadeInDistance(
FadeInDistancesInfo,
glm::vec2(0.0f),
glm::vec2(0.0),
glm::vec2(100.0)
)
, _disableFadeInDistance(DisableFadeInInfo, true)
, _billboardMaxSize(BillboardMaxSizeInfo, 400.0, 0.0, 1000.0)
, _billboardMinSize(BillboardMinSizeInfo, 0.0, 0.0, 100.0)
, _renderOption(RenderOptionInfo, properties::OptionProperty::DisplayType::Dropdown)
, _polygonTexture(nullptr)
, _spriteTexture(nullptr)
, _program(nullptr)
, _fontRenderer(nullptr)
, _font(nullptr)
, _speckFile("")
, _colorMapFile("")
, _labelFile("")
, _colorOptionString("")
, _unit(Parsec)
, _nValuesPerAstronomicalObject(0)
, _transformationMatrix(glm::dmat4(1.0))
, _vao(0)
, _vbo(0)
, _polygonVao(0)
, _polygonVbo(0)
{
using File = ghoul::filesystem::File;
documentation::testSpecificationAndThrow(
Documentation(),
dictionary,
"RenderableBillboardsCloud"
);
if (dictionary.hasKey(KeyFile)) {
_speckFile = absPath(dictionary.value<std::string>(KeyFile));
_hasSpeckFile = true;
_drawElements.onChange([&]() {
_hasSpeckFile = _hasSpeckFile == true? false : true; });
addProperty(_drawElements);
}
// DEBUG:
_renderOption.addOption(0, "Camera View Direction");
_renderOption.addOption(1, "Camera Position Normal");
_renderOption.addOption(2, "Screen center Position Normal");
addProperty(_renderOption);
if (dictionary.hasKey(keyUnit)) {
std::string unit = dictionary.value<std::string>(keyUnit);
if (unit == MeterUnit) {
_unit = Meter;
}
else if (unit == KilometerUnit) {
_unit = Kilometer;
}
else if (unit == ParsecUnit) {
_unit = Parsec;
}
else if (unit == KiloparsecUnit) {
_unit = Kiloparsec;
}
else if (unit == MegaparsecUnit) {
_unit = Megaparsec;
}
else if (unit == GigaparsecUnit) {
_unit = Gigaparsec;
}
else if (unit == GigalightyearUnit) {
_unit = GigalightYears;
}
else {
LWARNING(
"No unit given for RenderableBillboardsCloud. Using meters as units."
);
_unit = Meter;
}
}
if (dictionary.hasKey(SpriteTextureInfo.identifier)) {
_spriteTexturePath = absPath(dictionary.value<std::string>(
SpriteTextureInfo.identifier
));
_spriteTextureFile = std::make_unique<File>(_spriteTexturePath);
_spriteTexturePath.onChange([&] { _spriteTextureIsDirty = true; });
_spriteTextureFile->setCallback(
[&](const File&) { _spriteTextureIsDirty = true; }
);
addProperty(_spriteTexturePath);
_hasSpriteTexture = true;
}
if (dictionary.hasKey(ColorMapInfo.identifier)) {
_colorMapFile = absPath(dictionary.value<std::string>(
ColorMapInfo.identifier
));
_hasColorMapFile = true;
if (dictionary.hasKey(ColorOptionInfo.identifier)) {
ghoul::Dictionary colorOptionDataDic = dictionary.value<ghoul::Dictionary>(
ColorOptionInfo.identifier
);
for (int i = 0; i < static_cast<int>(colorOptionDataDic.size()); ++i) {
std::string colorMapInUseName(
colorOptionDataDic.value<std::string>(std::to_string(i + 1)));
_colorOption.addOption(i, colorMapInUseName);
_optionConversionMap.insert({i, colorMapInUseName});
_colorOptionString = colorMapInUseName;
}
}
_colorOption.onChange(
[&] {
_dataIsDirty = true;
_colorOptionString = _optionConversionMap[_colorOption.value()];
});
addProperty(_colorOption);
if (dictionary.hasKey(ColorRangeInfo.identifier)) {
ghoul::Dictionary rangeDataDict = dictionary.value<ghoul::Dictionary>(
ColorRangeInfo.identifier
);
for (size_t i = 0; i < rangeDataDict.size(); ++i) {
_colorRangeData.push_back(
rangeDataDict.value<glm::vec2>(std::to_string(i + 1)));
}
}
} else if (dictionary.hasKey(keyColor)) {
_pointColor = dictionary.value<glm::vec3>(keyColor);
addProperty(_pointColor);
}
if (dictionary.hasKey(TransparencyInfo.identifier)) {
_alphaValue = static_cast<float>(
dictionary.value<double>(TransparencyInfo.identifier)
);
}
addProperty(_alphaValue);
if (dictionary.hasKey(ScaleFactorInfo.identifier)) {
_scaleFactor = static_cast<float>(
dictionary.value<double>(ScaleFactorInfo.identifier)
);
}
addProperty(_scaleFactor);
if (dictionary.hasKey(PolygonSidesInfo.identifier)) {
_polygonSides = static_cast<float>(
dictionary.value<double>(PolygonSidesInfo.identifier)
);
_hasPolygon = true;
}
if (dictionary.hasKey(LabelFileInfo.identifier)) {
if (dictionary.hasKey(DrawLabelInfo.identifier)) {
_drawLabels = dictionary.value<bool>(DrawLabelInfo.identifier);
}
addProperty(_drawLabels);
_labelFile = absPath(dictionary.value<std::string>(
LabelFileInfo.identifier
));
_hasLabel = true;
if (dictionary.hasKey(TextColorInfo.identifier)) {
_textColor = dictionary.value<glm::vec4>(TextColorInfo.identifier);
_hasLabel = true;
}
_textColor.setViewOption(properties::Property::ViewOptions::Color);
addProperty(_textColor);
_textColor.onChange([&]() { _textColorIsDirty = true; });
if (dictionary.hasKey(TextSizeInfo.identifier)) {
_textSize = dictionary.value<double>(TextSizeInfo.identifier);
}
addProperty(_textSize);
if (dictionary.hasKey(LabelMinSizeInfo.identifier)) {
_textMinSize = static_cast<int>(
dictionary.value<float>(LabelMinSizeInfo.identifier)
);
}
addProperty(_textMinSize);
if (dictionary.hasKey(LabelMaxSizeInfo.identifier)) {
_textMaxSize = static_cast<int>(
dictionary.value<float>(LabelMaxSizeInfo.identifier)
);
}
addProperty(_textMaxSize);
}
if (dictionary.hasKey(TransformationMatrixInfo.identifier)) {
_transformationMatrix = dictionary.value<glm::dmat4>(
TransformationMatrixInfo.identifier
);
}
if (dictionary.hasKey(FadeInDistancesInfo.identifier)) {
glm::vec2 fadeInValue = dictionary.value<glm::vec2>(
FadeInDistancesInfo.identifier
);
_fadeInDistance.set(fadeInValue);
_disableFadeInDistance.set(false);
addProperty(_fadeInDistance);
addProperty(_disableFadeInDistance);
}
if (dictionary.hasKey(BillboardMaxSizeInfo.identifier)) {
_billboardMaxSize = static_cast<float>(
dictionary.value<double>(BillboardMaxSizeInfo.identifier)
);
addProperty(_billboardMaxSize);
}
if (dictionary.hasKey(BillboardMinSizeInfo.identifier)) {
_billboardMinSize = static_cast<float>(
dictionary.value<double>(BillboardMinSizeInfo.identifier)
);
addProperty(_billboardMinSize);
}
}
bool RenderableBillboardsCloud::isReady() const {
return ((_program != nullptr) && (!_fullData.empty())) || (!_labelData.empty());
}
void RenderableBillboardsCloud::initialize() {
bool success = loadData();
if (!success) {
throw ghoul::RuntimeError("Error loading data");
}
if (!_colorOptionString.empty()) {
// Following DU behavior here. The last colormap variable
// entry is the one selected by default.
_colorOption.setValue(static_cast<int>(_colorRangeData.size() - 1));
}
}
void RenderableBillboardsCloud::initializeGL() {
RenderEngine& renderEngine = OsEng.renderEngine();
_program = renderEngine.buildRenderProgram(
"RenderableBillboardsCloud",
absPath("${MODULE_DIGITALUNIVERSE}/shaders/billboard2_vs.glsl"),
absPath("${MODULE_DIGITALUNIVERSE}/shaders/billboard2_fs.glsl"),
absPath("${MODULE_DIGITALUNIVERSE}/shaders/billboard2_gs.glsl")
);
if (_hasPolygon) {
createPolygonTexture();
}
if (_hasLabel) {
if (_fontRenderer == nullptr)
_fontRenderer = std::unique_ptr<ghoul::fontrendering::FontRenderer>(
ghoul::fontrendering::FontRenderer::createProjectionSubjectText());
if (_font == nullptr) {
size_t _fontSize = 50;
_font = OsEng.fontManager().font(
"Mono",
static_cast<float>(_fontSize),
ghoul::fontrendering::FontManager::Outline::Yes,
ghoul::fontrendering::FontManager::LoadGlyphs::No
);
}
}
}
void RenderableBillboardsCloud::deinitializeGL() {
glDeleteBuffers(1, &_vbo);
_vbo = 0;
glDeleteVertexArrays(1, &_vao);
_vao = 0;
RenderEngine& renderEngine = OsEng.renderEngine();
if (_program) {
renderEngine.removeRenderProgram(_program);
_program = nullptr;
}
if (_hasSpriteTexture) {
_spriteTexture = nullptr;
}
if (_hasPolygon) {
_polygonTexture = nullptr;
glDeleteTextures(1, &_pTexture);
}
}
void RenderableBillboardsCloud::renderBillboards(const RenderData& data,
const glm::dmat4& modelViewMatrix,
const glm::dmat4& worldToModelTransform,
const glm::dvec3& orthoRight,
const glm::dvec3& orthoUp,
float fadeInVariable)
{
glDepthMask(false);
// Saving current OpenGL state
GLboolean blendEnabled = glIsEnabled(GL_BLEND);
GLenum blendEquationRGB;
GLenum blendEquationAlpha;
GLenum blendDestAlpha;
GLenum blendDestRGB;
GLenum blendSrcAlpha;
GLenum blendSrcRGB;
glGetIntegerv(GL_BLEND_EQUATION_RGB, &blendEquationRGB);
glGetIntegerv(GL_BLEND_EQUATION_ALPHA, &blendEquationAlpha);
glGetIntegerv(GL_BLEND_DST_ALPHA, &blendDestAlpha);
glGetIntegerv(GL_BLEND_DST_RGB, &blendDestRGB);
glGetIntegerv(GL_BLEND_SRC_ALPHA, &blendSrcAlpha);
glGetIntegerv(GL_BLEND_SRC_RGB, &blendSrcRGB);
glEnable(GL_BLEND);
glBlendFunc(GL_SRC_ALPHA, GL_ONE);
//glBlendFunc(GL_SRC_ALPHA, GL_ONE_MINUS_SRC_ALPHA);
_program->activate();
using IgnoreError = ghoul::opengl::ProgramObject::IgnoreError;
_program->setIgnoreUniformLocationError(IgnoreError::Yes);
glm::dmat4 projMatrix = glm::dmat4(data.camera.projectionMatrix());
_program->setUniform(
"screenSize",
glm::vec2(OsEng.renderEngine().renderingResolution())
);
_program->setUniform("projection", projMatrix);
_program->setUniform("modelViewTransform", modelViewMatrix);
_program->setUniform("modelViewProjectionTransform", projMatrix * modelViewMatrix);
_program->setUniform("cameraPosition", glm::dvec3(worldToModelTransform *
glm::dvec4(data.camera.positionVec3(), 1.0)));
_program->setUniform("cameraLookUp", glm::dvec3(worldToModelTransform *
glm::dvec4(data.camera.lookUpVectorWorldSpace(), 1.0)));
//_program->setUniform("cameraPosition", data.camera.positionVec3());
//_program->setUniform("cameraLookUp", data.camera.lookUpVectorWorldSpace());
_program->setUniform("renderOption", _renderOption.value());
glm::dvec4 centerScreenWorld = glm::inverse(data.camera.combinedViewMatrix()) *
glm::dvec4(0.0, 0.0, 0.0, 1.0);
_program->setUniform("centerScreenInWorldPosition", centerScreenWorld);
_program->setUniform("minBillboardSize", _billboardMinSize); // in pixels
_program->setUniform("maxBillboardSize", _billboardMaxSize); // in pixels
_program->setUniform("color", _pointColor);
_program->setUniform("sides", 4);
_program->setUniform("alphaValue", _alphaValue);
_program->setUniform("scaleFactor", _scaleFactor);
_program->setUniform("up", orthoUp);
_program->setUniform("right", orthoRight);
_program->setUniform("fadeInValue", fadeInVariable);
GLint viewport[4];
glGetIntegerv(GL_VIEWPORT, viewport);
_program->setUniform("screenSize", glm::vec2(viewport[2], viewport[3]));
ghoul::opengl::TextureUnit spriteTextureUnit;
if (_hasSpriteTexture) {
spriteTextureUnit.activate();
_spriteTexture->bind();
_program->setUniform("spriteTexture", spriteTextureUnit);
}
ghoul::opengl::TextureUnit polygonTextureUnit;
if (_hasPolygon) {
polygonTextureUnit.activate();
glBindTexture(GL_TEXTURE_2D, _pTexture);
_program->setUniform("polygonTexture", polygonTextureUnit);
_program->setUniform("hasPolygon", _hasPolygon);
}
if (_hasColorMapFile) {
_program->setUniform("hasColorMap", true);
}
else {
_program->setUniform("hasColorMap", false);
}
glBindVertexArray(_vao);
const GLsizei nAstronomicalObjects = static_cast<GLsizei>(_fullData.size() /
_nValuesPerAstronomicalObject);
glDrawArrays(GL_POINTS, 0, nAstronomicalObjects);
glBindVertexArray(0);
using IgnoreError = ghoul::opengl::ProgramObject::IgnoreError;
_program->setIgnoreUniformLocationError(IgnoreError::No);
_program->deactivate();
// Restores blending state
glBlendEquationSeparate(blendEquationRGB, blendEquationAlpha);
glBlendFuncSeparate(blendSrcRGB, blendDestRGB, blendSrcAlpha, blendDestAlpha);
if (!blendEnabled) {
glDisable(GL_BLEND);
}
glDepthMask(true);
}
void RenderableBillboardsCloud::renderLabels(const RenderData& data,
const glm::dmat4& modelViewProjectionMatrix,
const glm::dvec3& orthoRight,
const glm::dvec3& orthoUp,
float fadeInVariable)
{
RenderEngine& renderEngine = OsEng.renderEngine();
_fontRenderer->setFramebufferSize(renderEngine.renderingResolution());
float scale = 0.0;
switch (_unit) {
case Meter:
scale = 1.0;
break;
case Kilometer:
scale = 1e3;
break;
case Parsec:
scale = PARSEC;
break;
case Kiloparsec:
scale = 1e3 * PARSEC;
break;
case Megaparsec:
scale = 1e6 * PARSEC;
break;
case Gigaparsec:
scale = 1e9 * PARSEC;
break;
case GigalightYears:
scale = 306391534.73091 * PARSEC;
break;
}
glm::vec4 textColor = _textColor;
textColor.a *= fadeInVariable;
for (const std::pair<glm::vec3, std::string>& pair : _labelData) {
//glm::vec3 scaledPos(_transformationMatrix * glm::dvec4(pair.first, 1.0));
glm::vec3 scaledPos(pair.first);
scaledPos *= scale;
_fontRenderer->render(
*_font,
scaledPos,
textColor,
pow(10.0, _textSize.value()),
_textMinSize,
_textMaxSize,
modelViewProjectionMatrix,
orthoRight,
orthoUp,
data.camera.positionVec3(),
data.camera.lookUpVectorWorldSpace(),
_renderOption.value(),
"%s",
pair.second.c_str());
}
}
void RenderableBillboardsCloud::render(const RenderData& data, RendererTasks&) {
float scale = 0.0;
switch (_unit) {
case Meter:
scale = 1.0;
break;
case Kilometer:
scale = 1e3;
break;
case Parsec:
scale = PARSEC;
break;
case Kiloparsec:
scale = 1e3 * PARSEC;
break;
case Megaparsec:
scale = 1e6 * PARSEC;
break;
case Gigaparsec:
scale = 1e9 * PARSEC;
break;
case GigalightYears:
scale = 306391534.73091 * PARSEC;
break;
}
float fadeInVariable = 1.0f;
if (!_disableFadeInDistance) {
float distCamera = glm::length(data.camera.positionVec3());
/*
// Linear Fading
float funcValue = static_cast<float>(
(1.0 / double(_fadeInDistance*scale))*(distCamera)
);
fadeInVariable *= funcValue > 1.0 ? 1.0 : funcValue;
if (funcValue < 0.01) {
return;
}
*/
glm::vec2 fadeRange = _fadeInDistance;
float a = 1.0f / ((fadeRange.y - fadeRange.x) * scale);
float b = -(fadeRange.x / (fadeRange.y - fadeRange.x));
float funcValue = a * distCamera + b;
fadeInVariable *= funcValue > 1.0 ? 1.0 : funcValue;
if (funcValue < 0.01) {
return;
}
}
glm::dmat4 modelMatrix =
glm::translate(glm::dmat4(1.0), data.modelTransform.translation) * // Translation
glm::dmat4(data.modelTransform.rotation) * // Spice rotation
glm::scale(glm::dmat4(1.0), glm::dvec3(data.modelTransform.scale));
glm::dmat4 modelViewMatrix = data.camera.combinedViewMatrix() * modelMatrix;
// glm::mat4 viewMatrix = data.camera.viewMatrix();
glm::mat4 projectionMatrix = data.camera.projectionMatrix();
glm::dmat4 modelViewProjectionMatrix = glm::dmat4(projectionMatrix) *
modelViewMatrix;
glm::dmat4 worldToModelTransform = glm::inverse(modelMatrix);
/*glm::dmat4 internalCameraMatrix = data.camera.viewRotationMatrix() *
glm::inverse(glm::translate(glm::dmat4(1.0), data.camera.positionVec3()));
glm::dmat4 invInternalCameraMatrix = glm::inverse(internalCameraMatrix);
glm::vec3 lookup = worldToModelTransform * invInternalCameraMatrix * glm::dvec4(data.camera.lookUpVectorWorldSpace(), 0.0);
glm::vec3 viewDirection = worldToModelTransform * invInternalCameraMatrix * glm::dvec4(data.camera.viewDirectionWorldSpace(), 0.0);
glm::vec3 right = glm::cross(viewDirection, lookup);
glm::vec3 up = glm::cross(right, viewDirection);
glm::vec3 orthoRight = glm::normalize(right);
glm::vec3 orthoUp = glm::normalize(up);*/
/*
glm::dmat4 internalCameraMatrix = data.camera.viewRotationMatrix() *
glm::inverse(glm::translate(glm::dmat4(1.0), data.camera.positionVec3()));
glm::dmat4 invInternalCameraMatrix = glm::inverse(internalCameraMatrix);
glm::dvec4 lookup = worldToModelTransform * glm::dvec4(data.camera.lookUpVectorWorldSpace(), 0.0);
glm::dvec4 viewDirection = worldToModelTransform * glm::dvec4(data.camera.viewDirectionWorldSpace(), 0.0);
glm::vec3 right = glm::cross(glm::vec3(viewDirection), glm::vec3(lookup));
glm::vec3 up = glm::cross(right, glm::vec3(viewDirection));
glm::vec3 orthoRight = glm::normalize(right);
glm::vec3 orthoUp = glm::normalize(up);
*/
// Almost Working
glm::dmat4 invMVPParts = worldToModelTransform * glm::inverse(data.camera.combinedViewMatrix()) *
glm::inverse(glm::dmat4(projectionMatrix));
glm::dvec3 orthoRight = glm::dvec3(glm::normalize(glm::dvec3(invMVPParts * glm::dvec4(1.0, 0.0, 0.0, 0.0))));
glm::dvec3 orthoUp = glm::dvec3(glm::normalize(glm::dvec3(invMVPParts * glm::dvec4(0.0, 1.0, 0.0, 0.0))));
if (_hasSpeckFile) {
renderBillboards(
data,
modelViewMatrix,
worldToModelTransform,
orthoRight,
orthoUp,
fadeInVariable
);
}
if (_drawLabels && _hasLabel) {
renderLabels(
data,
modelViewProjectionMatrix,
orthoRight,
orthoUp,
fadeInVariable
);
}
}
void RenderableBillboardsCloud::update(const UpdateData&) {
if (_dataIsDirty && _hasSpeckFile) {
LDEBUG("Regenerating data");
createDataSlice();
int size = static_cast<int>(_slicedData.size());
if (_vao == 0) {
glGenVertexArrays(1, &_vao);
LDEBUG("Generating Vertex Array id '" << _vao << "'");
}
if (_vbo == 0) {
glGenBuffers(1, &_vbo);
LDEBUG("Generating Vertex Buffer Object id '" << _vbo << "'");
}
glBindVertexArray(_vao);
glBindBuffer(GL_ARRAY_BUFFER, _vbo);
glBufferData(
GL_ARRAY_BUFFER,
size * sizeof(float),
&_slicedData[0],
GL_STATIC_DRAW
);
GLint positionAttrib = _program->attributeLocation("in_position");
if (_hasColorMapFile) {
/*const size_t nAstronomicalObjects = _fullData.size() /
_nValuesPerAstronomicalObject;
const size_t nValues = _slicedData.size() / nAstronomicalObjects;
GLsizei stride = static_cast<GLsizei>(sizeof(float) * nValues);*/
glEnableVertexAttribArray(positionAttrib);
glVertexAttribPointer(
positionAttrib,
4,
GL_FLOAT,
GL_FALSE,
sizeof(float)*8,
nullptr
);
GLint colorMapAttrib = _program->attributeLocation("in_colormap");
glEnableVertexAttribArray(colorMapAttrib);
glVertexAttribPointer(
colorMapAttrib,
4,
GL_FLOAT,
GL_FALSE,
sizeof(float) * 8,
reinterpret_cast<void*>(sizeof(float)*4)
);
}
else {
glEnableVertexAttribArray(positionAttrib);
glVertexAttribPointer(
positionAttrib,
4,
GL_FLOAT,
GL_FALSE,
0,
nullptr
);
}
glBindVertexArray(0);
_dataIsDirty = false;
}
if (_hasSpriteTexture && _spriteTextureIsDirty) {
LDEBUG("Reloading Sprite Texture");
_spriteTexture = nullptr;
if (_spriteTexturePath.value() != "") {
_spriteTexture = ghoul::io::TextureReader::ref().loadTexture(
absPath(_spriteTexturePath)
);
if (_spriteTexture) {
LDEBUG("Loaded texture from '" << absPath(_spriteTexturePath) << "'");
_spriteTexture->uploadTexture();
}
_spriteTexture->setFilter(
ghoul::opengl::Texture::FilterMode::AnisotropicMipMap
);
_spriteTextureFile = std::make_unique<ghoul::filesystem::File>(
_spriteTexturePath);
_spriteTextureFile->setCallback(
[&](const ghoul::filesystem::File&) { _spriteTextureIsDirty = true; }
);
}
_spriteTextureIsDirty = false;
}
if (_hasLabel && _labelDataIsDirty) {
_labelDataIsDirty = false;
}
}
bool RenderableBillboardsCloud::loadData() {
bool success = false;
if (_hasSpeckFile) {
std::string _file = _speckFile;
// I disabled the cache as it didn't work on Mac --- abock
// std::string cachedFile = FileSys.cacheManager()->cachedFilename(
// _file,
// ghoul::filesystem::CacheManager::Persistent::Yes
// );
// bool hasCachedFile = FileSys.fileExists(cachedFile);
// if (hasCachedFile) {
// LINFO(
// "Cached file '" << cachedFile << "' used for Speck file '" <<
// _file << "'"
// );
// success = loadCachedFile(cachedFile);
// if (!success) {
// FileSys.cacheManager()->removeCacheFile(_file);
// // Intentional fall-through to the 'else' to generate the cache
// // file for the next run
// }
// }
// else
// {
// LINFO("Cache for Speck file '" << _file << "' not found");
LINFO("Loading Speck file '" << _file << "'");
success = readSpeckFile();
if (!success) {
return false;
}
// LINFO("Saving cache");
// success &= saveCachedFile(cachedFile);
// }
}
if (_hasColorMapFile) {
if (!_hasSpeckFile)
success = true;
success &= readColorMapFile();
}
std::string labelFile = _labelFile;
if (!labelFile.empty()) {
// I disabled the cache as it didn't work on Mac --- abock
// std::string cachedFile = FileSys.cacheManager()->cachedFilename(
// labelFile,
// ghoul::filesystem::CacheManager::Persistent::Yes
// );
if (!_hasSpeckFile && !_hasColorMapFile)
success = true;
//bool hasCachedFile = FileSys.fileExists(cachedFile);
//if (hasCachedFile) {
// LINFO(
// "Cached file '" << cachedFile << "' used for Label file '" <<
// labelFile << "'"
// );
//
// success &= loadCachedFile(cachedFile);
// if (!success) {
// FileSys.cacheManager()->removeCacheFile(labelFile);
// // Intentional fall-through to the 'else' to generate the cache
// // file for the next run
// }
//}
//else
// {
// LINFO("Cache for Label file '" << labelFile << "' not found");
LINFO("Loading Label file '" << labelFile << "'");
success &= readLabelFile();
if (!success) {
return false;
}
// }
}
return success;
}
bool RenderableBillboardsCloud::readSpeckFile() {
std::string _file = _speckFile;
std::ifstream file(_file);
if (!file.good()) {
LERROR("Failed to open Speck file '" << _file << "'");
return false;
}
_nValuesPerAstronomicalObject = 0;
// The beginning of the speck file has a header that either contains comments
// (signaled by a preceding '#') or information about the structure of the file
// (signaled by the keywords 'datavar', 'texturevar', and 'texture')
std::string line = "";
while (true) {
std::streampos position = file.tellg();
std::getline(file, line);
// Guard against wrong line endings (copying files from Windows to Mac) causes
// lines to have a final \r
if (!line.empty() && line.back() == '\r') {
line = line.substr(0, line.length() -1);
}
if (line.empty() || line[0] == '#') {
continue;
}
if (line.substr(0, 7) != "datavar" &&
line.substr(0, 10) != "texturevar" &&
line.substr(0, 7) != "texture" &&
line.substr(0, 10) != "polyorivar" &&
line.substr(0, 10) != "maxcomment")
{
// we read a line that doesn't belong to the header, so we have to jump back
// before the beginning of the current line
file.seekg(position);
break;
}
if (line.substr(0, 7) == "datavar") {
// datavar lines are structured as follows:
// datavar # description
// where # is the index of the data variable; so if we repeatedly overwrite
// the 'nValues' variable with the latest index, we will end up with the total
// number of values (+3 since X Y Z are not counted in the Speck file index)
std::stringstream str(line);
std::string dummy;
str >> dummy; // command
str >> _nValuesPerAstronomicalObject; // variable index
dummy.clear();
str >> dummy; // variable name
_variableDataPositionMap.insert({ dummy, _nValuesPerAstronomicalObject });
// We want the number, but the index is 0 based
_nValuesPerAstronomicalObject += 1;
}
}
_nValuesPerAstronomicalObject += 3; // X Y Z are not counted in the Speck file indices
do {
std::vector<float> values(_nValuesPerAstronomicalObject);
std::getline(file, line);
// Guard against wrong line endings (copying files from Windows to Mac) causes
// lines to have a final \r
if (!line.empty() && line.back() == '\r') {
line = line.substr(0, line.length() -1);
}
if (line.empty()) {
continue;
}
std::stringstream str(line);
for (int i = 0; i < _nValuesPerAstronomicalObject; ++i) {
str >> values[i];
}
_fullData.insert(_fullData.end(), values.begin(), values.end());
} while (!file.eof());
return true;
}
bool RenderableBillboardsCloud::readColorMapFile() {
std::string _file = _colorMapFile;
std::ifstream file(_file);
if (!file.good()) {
LERROR("Failed to open Color Map file '" << _file << "'");
return false;
}
std::size_t numberOfColors = 0;
// The beginning of the speck file has a header that either contains comments
// (signaled by a preceding '#') or information about the structure of the file
// (signaled by the keywords 'datavar', 'texturevar', and 'texture')
std::string line = "";
while (true) {
// std::streampos position = file.tellg();
std::getline(file, line);
if (line[0] == '#' || line.empty()) {
continue;
}
// Initial number of colors
std::locale loc;
if (std::isdigit(line[0], loc)) {
std::string::size_type sz;
numberOfColors = std::stoi(line, &sz);
break;
}
else if (file.eof()) {
return false;
}
}
for (size_t i = 0; i < numberOfColors; ++i) {
std::getline(file, line);
std::stringstream str(line);
glm::vec4 color;
for (int j = 0; j < 4; ++j) {
str >> color[j];
}
_colorMapData.push_back(color);
}
return true;
}
bool RenderableBillboardsCloud::readLabelFile() {
std::string _file = _labelFile;
std::ifstream file(_file);
if (!file.good()) {
LERROR("Failed to open Label file '" << _file << "'");
return false;
}
// The beginning of the speck file has a header that either contains comments
// (signaled by a preceding '#') or information about the structure of the file
// (signaled by the keywords 'datavar', 'texturevar', and 'texture')
std::string line = "";
while (true) {
std::streampos position = file.tellg();
std::getline(file, line);
// Guard against wrong line endings (copying files from Windows to Mac) causes
// lines to have a final \r
if (!line.empty() && line.back() == '\r') {
line = line.substr(0, line.length() -1);
}
if (line.empty() || line[0] == '#') {
continue;
}
if (line.substr(0, 9) != "textcolor") {
// we read a line that doesn't belong to the header, so we have to jump back
// before the beginning of the current line
file.seekg(position);
continue;
}
if (line.substr(0, 9) == "textcolor") {
// textcolor lines are structured as follows:
// textcolor # description
// where # is color text defined in configuration file
std::stringstream str(line);
// TODO: handle cases of labels with different colors
break;
}
}
do {
std::vector<float> values(_nValuesPerAstronomicalObject);
std::getline(file, line);
// Guard against wrong line endings (copying files from Windows to Mac) causes
// lines to have a final \r
if (!line.empty() && line.back() == '\r') {
line = line.substr(0, line.length() -1);
}
if (line.empty()) {
continue;
}
std::stringstream str(line);
glm::vec3 position;
for (auto j = 0; j < 3; ++j) {
str >> position[j];
}
std::string dummy;
str >> dummy; // text keyword
std::string label;
str >> label;
dummy.clear();
while (str >> dummy) {
if (dummy == "#") {
break;
}
label += " " + dummy;
dummy.clear();
}
glm::vec3 transformedPos = glm::vec3(
_transformationMatrix * glm::dvec4(position, 1.0)
);
_labelData.push_back(std::make_pair(transformedPos, label));
} while (!file.eof());
return true;
}
bool RenderableBillboardsCloud::loadCachedFile(const std::string& file) {
std::ifstream fileStream(file, std::ifstream::binary);
if (fileStream.good()) {
int8_t version = 0;
fileStream.read(reinterpret_cast<char*>(&version), sizeof(int8_t));
if (version != CurrentCacheVersion) {
LINFO("The format of the cached file has changed: deleting old cache");
fileStream.close();
FileSys.deleteFile(file);
return false;
}
int32_t nValues = 0;
fileStream.read(reinterpret_cast<char*>(&nValues), sizeof(int32_t));
fileStream.read(
reinterpret_cast<char*>(&_nValuesPerAstronomicalObject),
sizeof(int32_t)
);
_fullData.resize(nValues);
fileStream.read(reinterpret_cast<char*>(&_fullData[0]),
nValues * sizeof(_fullData[0]));
if (_hasColorMapFile) {
int32_t nItems = 0;
fileStream.read(reinterpret_cast<char*>(&nItems), sizeof(int32_t));
for (int i = 0; i < nItems; ++i) {
int32_t keySize = 0;
fileStream.read(reinterpret_cast<char*>(&keySize), sizeof(int32_t));
std::string key;
for (int c = 0; c < keySize; ++c) {
char t[2];
t[1] = '\0';
fileStream.read(reinterpret_cast<char*>(&t), sizeof(int32_t));
key.append(t);
}
int32_t value = 0;
fileStream.read(reinterpret_cast<char*>(&value), sizeof(int32_t));
_variableDataPositionMap.insert({ key, value });
}
}
bool success = fileStream.good();
return success;
}
else {
LERROR("Error opening file '" << file << "' for loading cache file");
return false;
}
}
bool RenderableBillboardsCloud::saveCachedFile(const std::string& file) const {
std::ofstream fileStream(file, std::ofstream::binary);
if (fileStream.good()) {
fileStream.write(reinterpret_cast<const char*>(&CurrentCacheVersion),
sizeof(int8_t));
int32_t nValues = static_cast<int32_t>(_fullData.size());
if (nValues == 0) {
LERROR("Error writing cache: No values were loaded");
return false;
}
fileStream.write(reinterpret_cast<const char*>(&nValues), sizeof(int32_t));
int32_t nValuesPerAstronomicalObject = static_cast<int32_t>(
_nValuesPerAstronomicalObject
);
fileStream.write(
reinterpret_cast<const char*>(&nValuesPerAstronomicalObject),
sizeof(int32_t)
);
size_t nBytes = nValues * sizeof(_fullData[0]);
fileStream.write(reinterpret_cast<const char*>(&_fullData[0]), nBytes);
if (_hasColorMapFile) {
int32_t nItems = static_cast<int32_t>(_variableDataPositionMap.size());
fileStream.write(reinterpret_cast<const char*>(&nItems), sizeof(int32_t));
for (auto pair : _variableDataPositionMap) {
int32_t keySize = static_cast<int32_t>(pair.first.size());
fileStream.write(
reinterpret_cast<const char*>(&keySize),
sizeof(int32_t)
);
for (size_t c = 0; c < pair.first.size(); ++c) {
int32_t keyChar = static_cast<int32_t>(pair.first[c]);
fileStream.write(
reinterpret_cast<const char*>(&keyChar),
sizeof(int32_t)
);
}
int32_t value = static_cast<int32_t>(pair.second);
fileStream.write(reinterpret_cast<const char*>(&value), sizeof(int32_t));
}
}
bool success = fileStream.good();
return success;
}
else {
LERROR("Error opening file '" << file << "' for save cache file");
return false;
}
}
void RenderableBillboardsCloud::createDataSlice() {
_slicedData.clear();
if (_hasColorMapFile) {
_slicedData.reserve(8 * (_fullData.size() / _nValuesPerAstronomicalObject));
}
else {
_slicedData.reserve(4 * (_fullData.size()/_nValuesPerAstronomicalObject));
}
// Generate the color bins for the colomap
int colorMapInUse = 0;
std::vector<float> colorBins;
if (_hasColorMapFile) {
colorMapInUse = _variableDataPositionMap[_colorOptionString];
glm::vec2 currentColorRange = _colorRangeData[_colorOption.value()];
float colorMapBinSize = (currentColorRange.y - currentColorRange.x) /
static_cast<float>(_colorMapData.size());
float bin = colorMapBinSize;
for (size_t i = 0; i < _colorMapData.size(); ++i) {
colorBins.push_back(bin);
bin += colorMapBinSize;
}
}
float biggestCoord = -1.0f;
for (size_t i = 0; i < _fullData.size(); i += _nValuesPerAstronomicalObject) {
glm::dvec4 transformedPos = _transformationMatrix * glm::dvec4(
_fullData[i + 0],
_fullData[i + 1],
_fullData[i + 2],
1.0
);
glm::vec4 position(glm::vec3(transformedPos), static_cast<float>(_unit));
if (_hasColorMapFile) {
for (auto j = 0; j < 4; ++j) {
_slicedData.push_back(position[j]);
biggestCoord = biggestCoord < position[j] ? position[j] : biggestCoord;
}
// Finds from which bin to get the color.
// Note: the first color in the colormap file
// is the outliers color.
glm::vec4 itemColor;
float variableColor = _fullData[i + 3 + colorMapInUse];
int c = static_cast<int>(colorBins.size() - 1);
while (variableColor < colorBins[c]) {
--c;
if (c == 0)
break;
}
int colorIndex =
c == static_cast<int>(colorBins.size() - 1) ?
0 :
c + 1;
for (auto j = 0; j < 4; ++j) {
_slicedData.push_back(_colorMapData[colorIndex][j]);
}
}
else {
for (auto j = 0; j < 4; ++j) {
_slicedData.push_back(position[j]);
}
}
}
_fadeInDistance.setMaxValue(glm::vec2(10.0f * biggestCoord));
}
void RenderableBillboardsCloud::createPolygonTexture() {
LDEBUG("Creating Polygon Texture");
glGenTextures(1, &_pTexture);
glBindTexture(GL_TEXTURE_2D, _pTexture);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
glTexParameteri(GL_TEXTURE_2D, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
// Stopped using a buffer object for GL_PIXEL_UNPACK_BUFFER
glBindBuffer(GL_PIXEL_UNPACK_BUFFER, 0);
glTexImage2D(GL_TEXTURE_2D, 0, GL_RGBA8, 256,
256, 0, GL_RGBA, GL_BYTE, nullptr);
renderToTexture(
std::bind(
&openspace::RenderableBillboardsCloud::loadPolygonGeometryForRendering,
this
),
std::bind(
&openspace::RenderableBillboardsCloud::renderPolygonGeometry,
this,
std::placeholders::_1
),
_pTexture,
256,
256
);
}
void RenderableBillboardsCloud::renderToTexture(
std::function<void(void)> geometryLoadingFunction,
std::function<void(GLuint)> renderFunction,
GLuint textureToRenderTo, GLuint textureWidth, GLuint textureHeight)
{
LDEBUG("Rendering to Texture");
// Saves initial Application's OpenGL State
GLint defaultFBO;
GLint viewport[4];
glGetIntegerv(GL_FRAMEBUFFER_BINDING, &defaultFBO);
glGetIntegerv(GL_VIEWPORT, viewport);
GLuint textureFBO;
glGenFramebuffers(1, &textureFBO);
glBindFramebuffer(GL_FRAMEBUFFER, textureFBO);
GLenum drawBuffers[1] = { GL_COLOR_ATTACHMENT0 };
glDrawBuffers(1, drawBuffers);
glFramebufferTexture(GL_FRAMEBUFFER, GL_COLOR_ATTACHMENT0, textureToRenderTo, 0);
glViewport(0, 0, textureWidth, textureHeight);
geometryLoadingFunction();
renderFunction(_polygonVao);
// Restores Applications' OpenGL State
glBindFramebuffer(GL_FRAMEBUFFER, defaultFBO);
glViewport(viewport[0], viewport[1], viewport[2], viewport[3]);
if (_polygonVbo) {
glDeleteBuffers(1, &_polygonVbo);
}
if (_polygonVao) {
glDeleteVertexArrays(1, &_polygonVao);
}
glDeleteFramebuffers(1, &textureFBO);
}
void RenderableBillboardsCloud::loadPolygonGeometryForRendering() {
glGenVertexArrays(1, &_polygonVao);
glGenBuffers(1, &_polygonVbo);
glBindVertexArray(_polygonVao);
glBindBuffer(GL_ARRAY_BUFFER, _polygonVbo);
const GLfloat vertex_data[] = {
// x y z w
0.0f, 0.0f, 0.0f, 1.0f,
};
glBufferData(GL_ARRAY_BUFFER, sizeof(vertex_data), vertex_data, GL_STATIC_DRAW);
glVertexAttribPointer(
0,
4,
GL_FLOAT,
GL_FALSE,
sizeof(GLfloat) * 4,
nullptr
);
glEnableVertexAttribArray(0);
glBindVertexArray(0);
}
void RenderableBillboardsCloud::renderPolygonGeometry(GLuint vao) {
std::unique_ptr<ghoul::opengl::ProgramObject> program =
ghoul::opengl::ProgramObject::Build("RenderableBillboardsCloud_Polygon",
absPath("${MODULE_DIGITALUNIVERSE}/shaders/billboardpolygon_vs.glsl"),
absPath("${MODULE_DIGITALUNIVERSE}/shaders/billboardpolygon_fs.glsl"),
absPath("${MODULE_DIGITALUNIVERSE}/shaders/billboardpolygon_gs.glsl")
);
program->activate();
static const float black[] = { 0.0f, 0.0f, 0.0f, 0.0f };
glClearBufferfv(GL_COLOR, 0, black);
program->setUniform("sides", _polygonSides);
program->setUniform("polygonColor", _pointColor);
glBindVertexArray(vao);
glDrawArrays(GL_POINTS, 0, 1);
glBindVertexArray(0);
program->deactivate();
}
} // namespace openspace
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