// ***************************************************************************
void CMaterial::flushTextures (IDriver &driver, uint selectedTexture)
{
// For each textures
for (uint tex=0; tex<IDRV_MAT_MAXTEXTURES; tex++)
{
// Texture exist ?
if (_Textures[tex])
{
// Select the good texture
_Textures[tex]->selectTexture (selectedTexture);
// Force setup texture
driver.setupTexture (*_Textures[tex]);
}
}
// If Lightmap material
if(_ShaderType==LightMap)
{
// For each lightmap
for (uint lmap=0; lmap<_LightMaps.size(); lmap++)
{
// Texture exist?
if(_LightMaps[lmap].Texture)
{
// Force setup texture
driver.setupTexture (*_LightMaps[lmap].Texture);
}
}
}
}
//***************************************************************************************************************
void CFlareShape::flushTextures (IDriver &driver, uint selectedTexture)
{
// Flush each texture
for (uint tex=0; tex<MaxFlareNum; tex++)
{
if (_Tex[tex] != NULL)
{
// Select the good texture
_Tex[tex]->selectTexture (selectedTexture);
// Flush texture
driver.setupTexture (*_Tex[tex]);
}
}
}
///===========================================================================
void CParticleSystemShape::flushTextures(IDriver &driver, uint selectedTexture)
{
// if textures are already flushed, no-op
if (!_CachedTex.empty()) return;
if (_SharedSystem)
{
_SharedSystem->enumTexs(_CachedTex, driver);
}
else
{
s_PSSMutex.enter();
// must create an instance just to flush the textures
CParticleSystem *myInstance = NULL;
#ifdef PS_FAST_ALLOC
nlassert(PSBlockAllocator == NULL);
NLMISC::CContiguousBlockAllocator blockAllocator;
PSBlockAllocator = &blockAllocator;
blockAllocator.init(300000); // we release memory just after, and we don't want to fragment the memory, so provide large enough mem
#endif
// serialize from the memory stream
if (!_ParticleSystemProto.isReading()) // we must be sure that we are reading the stream
{
_ParticleSystemProto.invert();
}
_ParticleSystemProto.resetPtrTable();
_ParticleSystemProto.seek(0, NLMISC::IStream::begin);
_ParticleSystemProto.serialPtr(myInstance); // instanciate the system
#ifdef PS_FAST_ALLOC
_NumBytesWanted = blockAllocator.getNumAllocatedBytes(); // next allocation will be fast because we know how much memory to allocate
#endif
myInstance->enumTexs(_CachedTex, driver);
// tmp
/*
#ifdef NL_DEBUG
for(uint k = 0; k < myInstance->getNbProcess(); ++k)
{
CPSLocated *loc = (CPSLocated *) myInstance->getProcess(k);
for(uint l = 0; l < loc->getNbBoundObjects(); ++l)
{
if (dynamic_cast<CPSCentralGravity *>(loc->getBoundObject(l)))
{
nlwarning("PS %s uses central gravity", myInstance->getName().c_str());
break;
}
}
}
#endif */
// sort the process inside the fx
myInstance->getSortingByEmitterPrecedence(_ProcessOrder);
delete myInstance;
#ifdef PS_FAST_ALLOC
PSBlockAllocator = NULL;
#endif
s_PSSMutex.leave();
}
for(uint k = 0; k < _CachedTex.size(); ++k)
{
//nlinfo(_CachedTex[k]->getShareName().c_str());
if (_CachedTex[k])
{
_CachedTex[k]->setTextureCategory(CPSTextureCategory::get());
driver.setupTexture(*_CachedTex[k]);
}
}
}
//*******************************************************************************
void CWaterEnvMap::init(uint cubeMapSize, uint projection2DSize, TGlobalAnimationTime updateTime, IDriver &driver)
{
// Allocate cube map
// a cubic texture with no sharing allowed
class CTextureCubeUnshared : public CTextureCube
{
public:
virtual bool supportSharing() const {return false;}
virtual uint32 getWidth(uint32 numMipMap = 0) const
{
nlassert(numMipMap == 0);
return Size;
}
virtual uint32 getHeight(uint32 numMipMap = 0) const
{
nlassert(numMipMap == 0);
return Size;
}
uint32 Size;
};
// a 2D testure
class CTexture2DUnshared : public CTextureBlank
{
public:
virtual bool supportSharing() const {return false;}
virtual uint32 getWidth(uint32 numMipMap = 0) const
{
nlassert(numMipMap == 0);
return Size;
}
virtual uint32 getHeight(uint32 numMipMap = 0) const
{
nlassert(numMipMap == 0);
return Size;
}
uint32 Size;
};
nlassert(cubeMapSize > 0);
nlassert(NLMISC::isPowerOf2(cubeMapSize));
nlassert(projection2DSize > 0);
nlassert(NLMISC::isPowerOf2(projection2DSize));
CTextureCubeUnshared *envCubic = new CTextureCubeUnshared;
_EnvCubic = envCubic;
_EnvCubic->setRenderTarget(true); // we will render to the texture
_EnvCubic->setWrapS(ITexture::Clamp);
_EnvCubic->setWrapT(ITexture::Clamp);
_EnvCubic->setFilterMode(ITexture::Linear, ITexture::LinearMipMapOff);
CTexture2DUnshared *tb = new CTexture2DUnshared;
tb->resize(cubeMapSize, cubeMapSize); // Unfortunately, must allocate memory in order for the driver to figure out the size
// that it needs to allocate for the texture, though its datas are never used (it is a render target)
tb->Size = cubeMapSize;
tb->setFilterMode(ITexture::Linear, ITexture::LinearMipMapOff);
for(uint k = 0; k < 6; ++k)
{
_EnvCubic->setTexture((CTextureCube::TFace) k, tb);
_EnvCubic->getTexture((CTextureCube::TFace) k)->setRenderTarget(true);
}
envCubic->Size = cubeMapSize;
// setup the texture to force the driver to allocate vram for it
driver.setupTexture(*_EnvCubic);
tb->reset();
// Allocate projection 2D map
CTexture2DUnshared *env2D = new CTexture2DUnshared;
_Env2D = env2D;
_Env2D->resize(projection2DSize, projection2DSize);
env2D->Size = projection2DSize;
_Env2D->setWrapS(ITexture::Clamp);
_Env2D->setWrapT(ITexture::Clamp);
_Env2D->setRenderTarget(true); // we will render to the texture
_Env2D->setFilterMode(ITexture::Linear, ITexture::LinearMipMapOff);
driver.setupTexture(*_Env2D); // allocate vram
_Env2D->reset();
_UpdateTime = updateTime;
_LastRenderTime = -1;
invalidate();
_NumRenderedFaces = 0;
_EnvCubicSize = cubeMapSize;
_Env2DSize = projection2DSize;
}
