#include "objects.hpp"
#include <OgreSceneNode.h>
#include <OgreSceneManager.h>
#include <OgreEntity.h>
#include <OgreLight.h>
#include <OgreSubEntity.h>
#include <OgreStaticGeometry.h>
#include <components/nifogre/ogre_nif_loader.hpp>
#include <components/settings/settings.hpp>
#include "../mwworld/ptr.hpp"
#include "../mwworld/class.hpp"
#include "renderconst.hpp"
using namespace MWRender;
/// \todo Replace these, once fallback values from the ini file are available.
float Objects::lightLinearValue = 3;
float Objects::lightLinearRadiusMult = 1;
float Objects::lightQuadraticValue = 16;
float Objects::lightQuadraticRadiusMult = 1;
bool Objects::lightOutQuadInLin = true;
bool Objects::lightQuadratic = false;
int Objects::uniqueID = 0;
void Objects::clearSceneNode (Ogre::SceneNode *node)
{
for (int i=node->numAttachedObjects()-1; i>=0; --i)
{
Ogre::MovableObject *object = node->getAttachedObject (i);
node->detachObject (object);
mRenderer.getScene()->destroyMovableObject (object);
}
}
void Objects::setMwRoot(Ogre::SceneNode* root)
{
mMwRoot = root;
}
void Objects::insertBegin (const MWWorld::Ptr& ptr, bool enabled, bool static_)
{
Ogre::SceneNode* root = mMwRoot;
Ogre::SceneNode* cellnode;
if(mCellSceneNodes.find(ptr.getCell()) == mCellSceneNodes.end())
{
//Create the scenenode and put it in the map
cellnode = root->createChildSceneNode();
mCellSceneNodes[ptr.getCell()] = cellnode;
}
else
{
cellnode = mCellSceneNodes[ptr.getCell()];
}
Ogre::SceneNode* insert = cellnode->createChildSceneNode();
const float *f = ptr.getRefData().getPosition().pos;
insert->setPosition(f[0], f[1], f[2]);
insert->setScale(ptr.getCellRef().mScale, ptr.getCellRef().mScale, ptr.getCellRef().mScale);
// Convert MW rotation to a quaternion:
f = ptr.getCellRef().mPos.rot;
// Rotate around X axis
Ogre::Quaternion xr(Ogre::Radian(-f[0]), Ogre::Vector3::UNIT_X);
// Rotate around Y axis
Ogre::Quaternion yr(Ogre::Radian(-f[1]), Ogre::Vector3::UNIT_Y);
// Rotate around Z axis
Ogre::Quaternion zr(Ogre::Radian(-f[2]), Ogre::Vector3::UNIT_Z);
// Rotates first around z, then y, then x
insert->setOrientation(xr*yr*zr);
if (!enabled)
insert->setVisible (false);
ptr.getRefData().setBaseNode(insert);
mIsStatic = static_;
}
void Objects::insertMesh (const MWWorld::Ptr& ptr, const std::string& mesh)
{
Ogre::SceneNode* insert = ptr.getRefData().getBaseNode();
assert(insert);
Ogre::AxisAlignedBox bounds = Ogre::AxisAlignedBox::BOX_NULL;
NifOgre::EntityList entities = NifOgre::NIFLoader::createEntities(insert, NULL, mesh);
for(size_t i = 0;i < entities.mEntities.size();i++)
{
const Ogre::AxisAlignedBox &tmp = entities.mEntities[i]->getBoundingBox();
bounds.merge(Ogre::AxisAlignedBox(insert->_getDerivedPosition() + tmp.getMinimum(),
insert->_getDerivedPosition() + tmp.getMaximum())
);
}
Ogre::Vector3 extents = bounds.getSize();
extents *= insert->getScale();
float size = std::max(std::max(extents.x, extents.y), extents.z);
bool small = (size < Settings::Manager::getInt("small object size", "Viewing distance")) && Settings::Manager::getBool("limit small object distance", "Viewing distance");
// do not fade out doors. that will cause holes and look stupid
if (ptr.getTypeName().find("Door") != std::string::npos)
small = false;
if (mBounds.find(ptr.getCell()) == mBounds.end())
mBounds[ptr.getCell()] = Ogre::AxisAlignedBox::BOX_NULL;
mBounds[ptr.getCell()].merge(bounds);
bool transparent = false;
for(size_t i = 0;i < entities.mEntities.size();i++)
{
Ogre::Entity *ent = entities.mEntities[i];
for (unsigned int i=0; i<ent->getNumSubEntities(); ++i)
{
Ogre::MaterialPtr mat = ent->getSubEntity(i)->getMaterial();
Ogre::Material::TechniqueIterator techIt = mat->getTechniqueIterator();
while (techIt.hasMoreElements())
{
Ogre::Technique* tech = techIt.getNext();
Ogre::Technique::PassIterator passIt = tech->getPassIterator();
while (passIt.hasMoreElements())
{
Ogre::Pass* pass = passIt.getNext();
if (pass->getDepthWriteEnabled() == false)
transparent = true;
}
}
}
}
if(!mIsStatic || !Settings::Manager::getBool("use static geometry", "Objects") || transparent)
{
for(size_t i = 0;i < entities.mEntities.size();i++)
{
Ogre::Entity *ent = entities.mEntities[i];
ent->setRenderingDistance(small ? Settings::Manager::getInt("small object distance", "Viewing distance") : 0);
ent->setVisibilityFlags(mIsStatic ? (small ? RV_StaticsSmall : RV_Statics) : RV_Misc);
ent->setRenderQueueGroup(transparent ? RQG_Alpha : RQG_Main);
}
}
else
{
Ogre::StaticGeometry* sg = 0;
if (small)
{
if( mStaticGeometrySmall.find(ptr.getCell()) == mStaticGeometrySmall.end())
{
uniqueID = uniqueID +1;
sg = mRenderer.getScene()->createStaticGeometry( "sg" + Ogre::StringConverter::toString(uniqueID));
mStaticGeometrySmall[ptr.getCell()] = sg;
sg->setRenderingDistance(Settings::Manager::getInt("small object distance", "Viewing distance"));
}
else
sg = mStaticGeometrySmall[ptr.getCell()];
}
else
{
if( mStaticGeometry.find(ptr.getCell()) == mStaticGeometry.end())
{
uniqueID = uniqueID +1;
sg = mRenderer.getScene()->createStaticGeometry( "sg" + Ogre::StringConverter::toString(uniqueID));
mStaticGeometry[ptr.getCell()] = sg;
}
else
sg = mStaticGeometry[ptr.getCell()];
}
// This specifies the size of a single batch region.
// If it is set too high:
// - there will be problems choosing the correct lights
// - the culling will be more inefficient
// If it is set too low:
// - there will be too many batches.
sg->setRegionDimensions(Ogre::Vector3(2500,2500,2500));
sg->setVisibilityFlags(small ? RV_StaticsSmall : RV_Statics);
sg->setCastShadows(true);
sg->setRenderQueueGroup(transparent ? RQG_Alpha : RQG_Main);
for(size_t i = 0;i < entities.mEntities.size();i++)
{
Ogre::Entity *ent = entities.mEntities[i];
insert->detachObject(ent);
sg->addEntity(ent,insert->_getDerivedPosition(),insert->_getDerivedOrientation(),insert->_getDerivedScale());
mRenderer.getScene()->destroyEntity(ent);
}
}
}
void Objects::insertLight (const MWWorld::Ptr& ptr, float r, float g, float b, float radius)
{
Ogre::SceneNode* insert = mRenderer.getScene()->getSceneNode(ptr.getRefData().getHandle());
assert(insert);
Ogre::Light *light = mRenderer.getScene()->createLight();
light->setDiffuseColour (r, g, b);
MWWorld::LiveCellRef<ESM::Light> *ref = ptr.get<ESM::Light>();
LightInfo info;
info.name = light->getName();
info.radius = radius;
info.colour = Ogre::ColourValue(r, g, b);
if (ref->mBase->mData.mFlags & ESM::Light::Negative)
info.colour *= -1;
info.interior = !ptr.getCell()->mCell->isExterior();
if (ref->mBase->mData.mFlags & ESM::Light::Flicker)
info.type = LT_Flicker;
else if (ref->mBase->mData.mFlags & ESM::Light::FlickerSlow)
info.type = LT_FlickerSlow;
else if (ref->mBase->mData.mFlags & ESM::Light::Pulse)
info.type = LT_Pulse;
else if (ref->mBase->mData.mFlags & ESM::Light::PulseSlow)
info.type = LT_PulseSlow;
else
info.type = LT_Normal;
// randomize lights animations
info.time = Ogre::Math::RangeRandom(-500, +500);
info.phase = Ogre::Math::RangeRandom(-500, +500);
// adjust the lights depending if we're in an interior or exterior cell
// quadratic means the light intensity falls off quite fast, resulting in a
// dark, atmospheric environment (perfect for exteriors)
// for interiors, we want more "warm" lights, so use linear attenuation.
bool quadratic = false;
if (!lightOutQuadInLin)
quadratic = lightQuadratic;
else
{
quadratic = !info.interior;
}
if (!quadratic)
{
float r = radius * lightLinearRadiusMult;
float attenuation = lightLinearValue / r;
light->setAttenuation(r*10, 0, attenuation, 0);
}
else
{
float r = radius * lightQuadraticRadiusMult;
float attenuation = lightQuadraticValue / pow(r, 2);
light->setAttenuation(r*10, 0, 0, attenuation);
}
insert->attachObject(light);
mLights.push_back(info);
}
bool Objects::deleteObject (const MWWorld::Ptr& ptr)
{
if (Ogre::SceneNode *base = ptr.getRefData().getBaseNode())
{
Ogre::SceneNode *parent = base->getParentSceneNode();
for (std::map<MWWorld::Ptr::CellStore *, Ogre::SceneNode *>::const_iterator iter (
mCellSceneNodes.begin()); iter!=mCellSceneNodes.end(); ++iter)
if (iter->second==parent)
{
clearSceneNode (base);
base->removeAndDestroyAllChildren();
mRenderer.getScene()->destroySceneNode (base);
ptr.getRefData().setBaseNode (0);
return true;
}
return false;
}
return true;
}
void Objects::removeCell(MWWorld::Ptr::CellStore* store)
{
if(mCellSceneNodes.find(store) != mCellSceneNodes.end())
{
Ogre::SceneNode* base = mCellSceneNodes[store];
for (int i=0; i<base->numChildren(); ++i)
clearSceneNode (static_cast<Ogre::SceneNode *> (base->getChild (i)));
base->removeAndDestroyAllChildren();
mCellSceneNodes.erase(store);
mRenderer.getScene()->destroySceneNode(base);
base = 0;
}
if(mStaticGeometry.find(store) != mStaticGeometry.end())
{
Ogre::StaticGeometry* sg = mStaticGeometry[store];
mStaticGeometry.erase(store);
mRenderer.getScene()->destroyStaticGeometry (sg);
sg = 0;
}
if(mStaticGeometrySmall.find(store) != mStaticGeometrySmall.end())
{
Ogre::StaticGeometry* sg = mStaticGeometrySmall[store];
mStaticGeometrySmall.erase(store);
mRenderer.getScene()->destroyStaticGeometry (sg);
sg = 0;
}
if(mBounds.find(store) != mBounds.end())
mBounds.erase(store);
}
void Objects::buildStaticGeometry(MWWorld::Ptr::CellStore& cell)
{
if(mStaticGeometry.find(&cell) != mStaticGeometry.end())
{
Ogre::StaticGeometry* sg = mStaticGeometry[&cell];
sg->build();
}
if(mStaticGeometrySmall.find(&cell) != mStaticGeometrySmall.end())
{
Ogre::StaticGeometry* sg = mStaticGeometrySmall[&cell];
sg->build();
}
}
Ogre::AxisAlignedBox Objects::getDimensions(MWWorld::Ptr::CellStore* cell)
{
return mBounds[cell];
}
void Objects::enableLights()
{
std::vector<LightInfo>::iterator it = mLights.begin();
while (it != mLights.end())
{
if (mMwRoot->getCreator()->hasLight(it->name))
{
mMwRoot->getCreator()->getLight(it->name)->setVisible(true);
++it;
}
else
it = mLights.erase(it);
}
}
void Objects::disableLights()
{
std::vector<LightInfo>::iterator it = mLights.begin();
while (it != mLights.end())
{
if (mMwRoot->getCreator()->hasLight(it->name))
{
mMwRoot->getCreator()->getLight(it->name)->setVisible(false);
++it;
}
else
it = mLights.erase(it);
}
}
namespace MWRender
{
namespace Pulse
{
static float amplitude (float phase)
{
return sin (phase);
}
}
namespace Flicker
{
static const float fa = 0.785398f;
static const float fb = 1.17024f;
static const float tdo = 0.94f;
static const float tdm = 2.48f;
static const float f [3] = { 1.5708f, 4.18774f, 5.19934f };
static const float o [3] = { 0.804248f, 2.11115f, 3.46832f };
static const float m [3] = { 1.0f, 0.785f, 0.876f };
static const float s = 0.394f;
static const float phase_wavelength = 120.0f * 3.14159265359f / fa;
static float frequency (float x)
{
return tdo + tdm * sin (fa * x);
}
static float amplitude (float x)
{
float v = 0.0f;
for (int i = 0; i < 3; ++i)
v += sin (fb*x*f[i] + o[1])*m[i];
return v * s;
}
}
}
void Objects::update(const float dt)
{
std::vector<LightInfo>::iterator it = mLights.begin();
while (it != mLights.end())
{
if (mMwRoot->getCreator()->hasLight(it->name))
{
Ogre::Light* light = mMwRoot->getCreator()->getLight(it->name);
float brightness;
float cycle_time;
float time_distortion;
if ((it->type == LT_Pulse) && (it->type == LT_PulseSlow))
{
cycle_time = 2 * Ogre::Math::PI;
time_distortion = 20.0f;
}
else
{
cycle_time = 500.0f;
it->phase = fmod (it->phase + dt, Flicker::phase_wavelength);
time_distortion = Flicker::frequency (it->phase);
}
it->time += it->dir*dt*time_distortion;
if (it->dir > 0 && it->time > +cycle_time)
{
it->dir = -1.0f;
it->time = +2*cycle_time - it->time;
}
if (it->dir < 0 && it->time < -cycle_time)
{
it->dir = +1.0f;
it->time = -2*cycle_time - it->time;
}
static const float fast = 4.0f/1.0f;
static const float slow = 1.0f/1.0f;
// These formulas are just guesswork, but they work pretty well
if (it->type == LT_Normal)
{
// Less than 1/255 light modifier for a constant light:
brightness = (const float)(1.0 + Flicker::amplitude(it->time*slow) / 255.0 );
}
else if (it->type == LT_Flicker)
{
brightness = (const float)(0.75 + Flicker::amplitude(it->time*fast) * 0.25);
}
else if (it->type == LT_FlickerSlow)
{
brightness = (const float)(0.75 + Flicker::amplitude(it->time*slow) * 0.25);
}
else if (it->type == LT_Pulse)
{
brightness = (const float)(1.0 + Pulse::amplitude (it->time*fast) * 0.25);
}
else if (it->type == LT_PulseSlow)
{
brightness = (const float)(1.0 + Pulse::amplitude (it->time*slow) * 0.25);
}
else
assert(0 && "Invalid light type");
light->setDiffuseColour(it->colour * brightness);
++it;
}
else
it = mLights.erase(it);
}
}
void Objects::rebuildStaticGeometry()
{
for (std::map<MWWorld::CellStore *, Ogre::StaticGeometry*>::iterator it = mStaticGeometry.begin(); it != mStaticGeometry.end(); ++it)
{
it->second->destroy();
it->second->build();
}
for (std::map<MWWorld::CellStore *, Ogre::StaticGeometry*>::iterator it = mStaticGeometrySmall.begin(); it != mStaticGeometrySmall.end(); ++it)
{
it->second->destroy();
it->second->build();
}
}
void Objects::updateObjectCell(const MWWorld::Ptr &ptr)
{
Ogre::SceneNode *node;
MWWorld::CellStore *newCell = ptr.getCell();
if(mCellSceneNodes.find(newCell) == mCellSceneNodes.end()) {
node = mMwRoot->createChildSceneNode();
mCellSceneNodes[newCell] = node;
} else {
node = mCellSceneNodes[newCell];
}
node->addChild(ptr.getRefData().getBaseNode());
/// \note Still unaware how to move aabb and static w/o full rebuild,
/// moving static objects may cause problems
insertMesh(ptr, MWWorld::Class::get(ptr).getModel(ptr));
}