Result::Name RegisterAsPlanarMirror( CCopyEntity& entity, BasicMesh& mesh, int subset_index )
{
const AABB3& aabb = mesh.GetAABB(subset_index);
EntityRenderManager& entity_render_mgr
= *(entity.GetStage()->GetEntitySet()->GetRenderManager());
// >>> TODO: support planes that are not axis-aligned or facing along the negative half-space
SPlane plane;
int plane_axis = 1;
if( aabb.vMax.x - aabb.vMin.x < 0.001f ) plane_axis = 0;
else if( aabb.vMax.y - aabb.vMin.y < 0.001f ) plane_axis = 1;
else if( aabb.vMax.z - aabb.vMin.z < 0.001f ) plane_axis = 2;
else plane_axis = 1;
plane.normal = Vector3(0,0,0);
plane.normal[plane_axis] = 1;
plane.dist = aabb.vMax[plane_axis];
Result::Name res = entity_render_mgr.AddPlanarReflector( EntityHandle<>( entity.Self() ), plane );
if( res != Result::SUCCESS )
return Result::UNKNOWN_ERROR;
entity.RaiseEntityFlags( BETYPE_PLANAR_REFLECTOR );
// Create shader variable loader for mirror
if( !entity.m_pMeshRenderMethod )
{
if( entity.pBaseEntity->MeshProperty().m_pMeshRenderMethod )
{
entity.m_pMeshRenderMethod
= entity.pBaseEntity->MeshProperty().m_pMeshRenderMethod->CreateCopy();
if( !entity.m_pMeshRenderMethod )
return Result::UNKNOWN_ERROR;
}
else
return Result::UNKNOWN_ERROR;
}
// create a planar reflection entity
// shared_ptr<MeshContainerRenderMethod> pMeshRenderMethodCopy
// = entity.m_pMeshRenderMethod->CreateCopy();
shared_ptr<MirroredSceneTextureParam> pTexParam;
pTexParam.reset( new MirroredSceneTextureParam( EntityHandle<>( entity.Self() ) ) );
pTexParam->m_fReflection = mesh.GetMaterial(subset_index).m_Mat.fReflection;
// pMeshRenderMethodCopy->SetShaderParamsLoaderToAllMeshRenderMethods( pTexParam );
// test - we assume that the entity's mesh is composed of polygons that belong to a single plane.
entity.m_pMeshRenderMethod->SetShaderParamsLoaderToAllMeshRenderMethods( pTexParam );
// Move the indices of the planar reflection subset(s)
// to the render method of the planar reflection entity
return Result::SUCCESS;
}
/// Update shader params loaders for the entity.
/// Shader params loaders are shared by entities, and need to be updated every time an entity is rendered.
void UpdateEntityForRendering( CCopyEntity& entity )
{
BaseEntity& base_entity = *(entity.pBaseEntity);
// light params writer
if( entity.GetEntityFlags() & BETYPE_LIGHTING )
{
UpdateLightInfo( entity );
if( base_entity.MeshProperty().m_pShaderLightParamsLoader )
{
// Set the entity to the light params loader, because a single light params loader
// is shared by all the entities of this base entity.
base_entity.MeshProperty().m_pShaderLightParamsLoader->SetEntity( entity.Self().lock() );
}
}
const float offset_world_transform_threshold = 150000.0f;
if( square(offset_world_transform_threshold) < Vec3LengthSq(entity.GetWorldPose().vPosition) )
{
Camera* pCam = entity.GetStage()->GetCurrentCamera();
if( pCam )
{
sg_pWorldTransLoader->SetActive( true );
sg_pWorldTransLoader->SetCameraPosition( pCam->GetPosition() );
}
else
sg_pWorldTransLoader->SetActive( false );
}
else
sg_pWorldTransLoader->SetActive( false );
}
EntityHandle<> CStage::LoadStaticGeometryFromFile( const std::string filename )
{
SafeDelete( m_pStaticGeometry );
m_pStaticGeometry = CreateStaticGeometry( this, filename );
if( !m_pStaticGeometry )
return EntityHandle<>();
// register the static geometry as an entity
// - the entity is used to render the static geometry
BaseEntityHandle baseentity_handle;
baseentity_handle.SetBaseEntityName( "StaticGeometry" );
CCopyEntityDesc desc;
desc.strName = filename;
desc.pBaseEntityHandle = &baseentity_handle;
desc.pUserData = m_pStaticGeometry;
CCopyEntity *pStaticGeometryEntity = CreateEntity( desc );
if( !pStaticGeometryEntity )
return EntityHandle<>();
// shared_ptr<CStaticGeometryEntity> pEntity( new CStaticGeometryEntity );
// pEntity->SetStaticGeometry( m_pStaticGeometry );
// EntityHandle<CStaticGeometryEntity> entity
// = CreateEntity( pEntity, baseentity_handle );
m_pEntitySet->WriteEntityTreeToFile( "debug/entity_tree - loaded static geometry.txt" );
// load the static geometry from file
this->PauseTimer();
bool loaded = m_pStaticGeometry->LoadFromFile( filename );
this->ResumeTimer();
return EntityHandle<>( pStaticGeometryEntity->Self() );
// return entity;
}
// sets the following shader params loaders to the render method of an entity
// - CEntityShaderLightParamsLoader
// - Set if the BETYPE_LIGHTING flag is on
// - BlendTransformsLoader
// - Set if pEntity->m_MeshHandle is a skeletal mesh
void InitMeshRenderMethod( CCopyEntity &entity, shared_ptr<BlendTransformsLoader> pBlendTransformsLoader )
{
if( !entity.m_pMeshRenderMethod )
{
entity.m_pMeshRenderMethod.reset( new MeshContainerRenderMethod );
// entity.m_pMeshRenderMethod->MeshRenderMethod().resize( 1 );
}
if( entity.GetEntityFlags() & BETYPE_LIGHTING )
{
shared_ptr<CEntityShaderLightParamsLoader> pLightParamsLoader( new CEntityShaderLightParamsLoader() );
pLightParamsLoader->SetEntity( entity.Self() );
entity.m_pMeshRenderMethod->SetShaderParamsLoaderToAllMeshRenderMethods( pLightParamsLoader );
}
// Not used now.
// Item entities set this in its own member function ItemEntity::InitMesh().
// Does any entity other than item entty need this?
if( pBlendTransformsLoader )
entity.m_pMeshRenderMethod->SetShaderParamsLoaderToAllMeshRenderMethods( pBlendTransformsLoader );
/*
shared_ptr<BasicMesh> pMesh = entity.m_MeshHandle.GetMesh();
if( pMesh && pMesh->GetMeshType() == MeshType::SKELETAL )
{
// shared_ptr<SkeletalMesh> pSkeletalMesh
// = boost::dynamic_pointer_cast<SkeletalMesh,BasicMesh>(pMesh);
if( !pBlendTransformsLoader )
pBlendTransformsLoader.reset( new BlendTransformsLoader() );
entity.m_pMeshRenderMethod->SetShaderParamsLoaderToAllMeshRenderMethods( pBlendTransformsLoader );
}*/
if( true /* world position of entity has large values */ )
{
entity.m_pMeshRenderMethod->SetShaderParamsLoaderToAllMeshRenderMethods( sg_pWorldTransLoader );
}
}
// Initializes CCopyEntity::m_pMeshRenderMethod
// - Initialize the mesh render method
// - Initialize shader parameter loaders
// - Create alpha entities
// - Creates a shader
void BaseEntity::InitEntityGraphics( CCopyEntity &entity,
ShaderHandle& shader,
ShaderTechniqueHandle& tech )
{
if( shader.IsLoaded()
&& tech.GetTechniqueName()
&& 0 < strlen(tech.GetTechniqueName()) )
{
CreateMeshRenderMethod( EntityHandle<>( entity.Self() ), shader, tech );
}
else
{
InitMeshRenderMethod( entity );
}
// create transparent parts of the model as separate entities
if( m_EntityFlag & BETYPE_SUPPORT_TRANSPARENT_PARTS )
{
// Remove any previous alpha entities
int next_child_index = 0;
while( next_child_index < entity.GetNumChildren() )
// for( int i=0; i<entity.GetNumChildren(); i++ )
{
shared_ptr<CCopyEntity> pChild = entity.m_aChild[next_child_index].Get();
if( IsValidEntity(pChild.get())
&& pChild->GetEntityTypeID() == CCopyEntityTypeID::ALPHA_ENTITY )
{
CCopyEntity *pChildRawPtr = pChild.get();
m_pStage->TerminateEntity( pChildRawPtr );
}
else
next_child_index += 1;
}
CreateAlphaEntities( &entity );
}
shared_ptr<BasicMesh> pMesh = entity.m_MeshHandle.GetMesh();
if( !pMesh )
return;
BasicMesh& mesh = *pMesh;
const int num_mesh_materials = mesh.GetNumMaterials();
std::vector<GenericShaderDesc> shader_descs;
shader_descs.resize( num_mesh_materials );
std::vector<int> mirror_subsets_indices;
// std::vector<int> non_mirror_subsets_indices;
if( m_MeshProperty.m_MeshDesc.IsValid() )
// if( true )
{
// The mesh is specified in the base entity
}
else
{
// base entity has no mesh
// - entity's mesh is individual
shader_descs.resize( num_mesh_materials );
for( int i=0; i<num_mesh_materials; i++ )
{
// Fill out the shader desc based on the parameter values of the material
// reflection
bool registered_as_mirror = RegisterAsMirrorIfReflective( entity, mesh, i, shader_descs[i] );
if( registered_as_mirror )
mirror_subsets_indices.push_back( i );
// specularity
if( 0.001f < mesh.GetMaterial(i).m_Mat.fSpecularity )
shader_descs[i].Specular = SpecularSource::UNIFORM;
else
shader_descs[i].Specular = SpecularSource::NONE;
}
vector< pair< GenericShaderDesc, vector<unsigned int> > > grouped_descs;
group_elements( shader_descs, grouped_descs );
// Do a NULL check just in case
// The mesh render method is initialized by InitMeshRenderMethod() above.
if( !entity.m_pMeshRenderMethod )
entity.m_pMeshRenderMethod.reset( new MeshContainerRenderMethod );
bool shader_loaded = false;
if( grouped_descs.size() == 1 )
{
SubsetRenderMethod& render_method = entity.m_pMeshRenderMethod->PrimaryMeshRenderMethod();
render_method.m_Technique.SetTechniqueName( "Default" );
render_method.m_ShaderDesc.pShaderGenerator.reset( new GenericShaderGenerator( grouped_descs[0].first ) );
// shader_loaded = render_method.Load();
shader_loaded = render_method.m_Shader.Load( render_method.m_ShaderDesc );
}
else
{
LOG_PRINT_WARNING( "Mesh materials need different shaders. This situation is not supported yet (the total number of materials: " + to_string(num_mesh_materials) + ")." );
}
}
}