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-----------------------------------------------------------------------------
This source file is part of OGRE
(Object-oriented Graphics Rendering Engine)
For the latest info, see http://www.ogre3d.org/
Copyright (c) 2000-2012 Torus Knot Software Ltd
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.
-----------------------------------------------------------------------------
*/
#ifndef __StaticGeometry_H__
#define __StaticGeometry_H__
#include "OgrePrerequisites.h"
#include "OgreMovableObject.h"
#include "OgreRenderable.h"
#include "OgreMesh.h"
#include "OgreLodStrategy.h"
namespace Ogre {
/** \addtogroup Core
* @{
*/
/** \addtogroup Scene
* @{
*/
/** Pre-transforms and batches up meshes for efficient use as static
geometry in a scene.
@remarks
Modern graphics cards (GPUs) prefer to receive geometry in large
batches. It is orders of magnitude faster to render 10 batches
of 10,000 triangles than it is to render 10,000 batches of 10
triangles, even though both result in the same number of on-screen
triangles.
@par
Therefore it is important when you are rendering a lot of geometry to
batch things up into as few rendering calls as possible. This
class allows you to build a batched object from a series of entities
in order to benefit from this behaviour.
Batching has implications of it's own though:
@li Batched geometry cannot be subdivided; that means that the whole
group will be displayed, or none of it will. This obivously has
culling issues.
@li A single world transform must apply to the entire batch. Therefore
once you have batched things, you can't move them around relative to
each other. That's why this class is most useful when dealing with
static geometry (hence the name). In addition, geometry is
effectively duplicated, so if you add 3 entities based on the same
mesh in different positions, they will use 3 times the geometry
space than the movable version (which re-uses the same geometry).
So you trade memory and flexibility of movement for pure speed when
using this class.
@li A single material must apply for each batch. In fact this class
allows you to use multiple materials, but you should be aware that
internally this means that there is one batch per material.
Therefore you won't gain as much benefit from the batching if you
use many different materials; try to keep the number down.
@par
In order to retain some sort of culling, this class will batch up
meshes in localised regions. The size and shape of these blocks is
controlled by the SceneManager which constructs this object, since it
makes sense to batch things up in the most appropriate way given the
existing partitioning of the scene.
@par
The LOD settings of both the Mesh and the Materials used in
constructing this static geometry will be respected. This means that
if you use meshes/materials which have LOD, batches in the distance
will have a lower polygon count or material detail to those in the
foreground. Since each mesh might have different LOD distances, during
build the furthest distance at each LOD level from all meshes
in that region is used. This means all the LOD levels change at the
same time, but at the furthest distance of any of them (so quality is
not degraded). Be aware that using Mesh LOD in this class will
further increase the memory required. Only generated LOD
is supported for meshes.
@par
There are 2 ways you can add geometry to this class; you can add
Entity objects directly with predetermined positions, scales and
orientations, or you can add an entire SceneNode and it's subtree,
including all the objects attached to it. Once you've added everything
you need to, you have to call build() the fix the geometry in place.
@note
This class is not a replacement for world geometry (@see
SceneManager::setWorldGeometry). The single most efficient way to
render large amounts of static geometry is to use a SceneManager which
is specialised for dealing with that particular world structure.
However, this class does provide you with a good 'halfway house'
between generalised movable geometry (Entity) which works with all
SceneManagers but isn't efficient when using very large numbers, and
highly specialised world geometry which is extremely fast but not
generic and typically requires custom world editors.
@par
You should not construct instances of this class directly; instead, cal
SceneManager::createStaticGeometry, which gives the SceneManager the
option of providing you with a specialised version of this class if it
wishes, and also handles the memory management for you like other
classes.
@note
Warning: this class only works with indexed triangle lists at the moment,
do not pass it triangle strips, fans or lines / points, or unindexed geometry.
*/
class _OgreExport StaticGeometry : public BatchedGeometryAlloc
{
public:
/** Struct holding geometry optimised per SubMesh / lod level, ready
for copying to instances.
@remarks
Since we're going to be duplicating geometry lots of times, it's
far more important that we don't have redundant vertex data. If a
SubMesh uses shared geometry, or we're looking at a lower LOD, not
all the vertices are being referenced by faces on that submesh.
Therefore to duplicate them, potentially hundreds or even thousands
of times, would be extremely wasteful. Therefore, if a SubMesh at
a given LOD has wastage, we create an optimised version of it's
geometry which is ready for copying with no wastage.
*/
class _OgrePrivate OptimisedSubMeshGeometry : public BatchedGeometryAlloc
{
public:
OptimisedSubMeshGeometry() :vertexData(0), indexData(0) {}
~OptimisedSubMeshGeometry()
{
OGRE_DELETE vertexData;
OGRE_DELETE indexData;
}
VertexData *vertexData;
IndexData *indexData;
};
typedef list<OptimisedSubMeshGeometry*>::type OptimisedSubMeshGeometryList;
/// Saved link between SubMesh at a LOD and vertex/index data
/// May point to original or optimised geometry
struct SubMeshLodGeometryLink
{
VertexData* vertexData;
IndexData* indexData;
};
typedef vector<SubMeshLodGeometryLink>::type SubMeshLodGeometryLinkList;
typedef map<SubMesh*, SubMeshLodGeometryLinkList*>::type SubMeshGeometryLookup;
/// Structure recording a queued submesh for the build
struct QueuedSubMesh : public BatchedGeometryAlloc
{
SubMesh* submesh;
/// Link to LOD list of geometry, potentially optimised
SubMeshLodGeometryLinkList* geometryLodList;
String materialName;
Vector3 position;
Quaternion orientation;
Vector3 scale;
/// Pre-transformed world AABB
AxisAlignedBox worldBounds;
};
typedef vector<QueuedSubMesh*>::type QueuedSubMeshList;
/// Structure recording a queued geometry for low level builds
struct QueuedGeometry : public BatchedGeometryAlloc
{
SubMeshLodGeometryLink* geometry;
Vector3 position;
Quaternion orientation;
Vector3 scale;
};
typedef vector<QueuedGeometry*>::type QueuedGeometryList;
// forward declarations
class LODBucket;
class MaterialBucket;
class Region;
/** A GeometryBucket is a the lowest level bucket where geometry with
the same vertex & index format is stored. It also acts as the
renderable.
*/
class _OgreExport GeometryBucket : public Renderable, public BatchedGeometryAlloc
{
protected:
/// Geometry which has been queued up pre-build (not for deallocation)
QueuedGeometryList mQueuedGeometry;
/// Pointer to parent bucket
MaterialBucket* mParent;
/// String identifying the vertex / index format
String mFormatString;
/// Vertex information, includes current number of vertices
/// committed to be a part of this bucket
VertexData* mVertexData;
/// Index information, includes index type which limits the max
/// number of vertices which are allowed in one bucket
IndexData* mIndexData;
/// Size of indexes
HardwareIndexBuffer::IndexType mIndexType;
/// Maximum vertex indexable
size_t mMaxVertexIndex;
template<typename T>
void copyIndexes(const T* src, T* dst, size_t count, size_t indexOffset)
{
if (indexOffset == 0)
{
memcpy(dst, src, sizeof(T) * count);
}
else
{
while(count--)
{
*dst++ = static_cast<T>(*src++ + indexOffset);
}
}
}
public:
GeometryBucket(MaterialBucket* parent, const String& formatString,
const VertexData* vData, const IndexData* iData);
virtual ~GeometryBucket();
MaterialBucket* getParent(void) { return mParent; }
/// Get the vertex data for this geometry
const VertexData* getVertexData(void) const { return mVertexData; }
/// Get the index data for this geometry
const IndexData* getIndexData(void) const { return mIndexData; }
/// @copydoc Renderable::getMaterial
const MaterialPtr& getMaterial(void) const;
Technique* getTechnique(void) const;
void getRenderOperation(RenderOperation& op);
void getWorldTransforms(Matrix4* xform) const;
Real getSquaredViewDepth(const Camera* cam) const;
const LightList& getLights(void) const;
bool getCastsShadows(void) const;
/** Try to assign geometry to this bucket.
@return false if there is no room left in this bucket
*/
bool assign(QueuedGeometry* qsm);
/// Build
void build(bool stencilShadows);
/// Dump contents for diagnostics
void dump(std::ofstream& of) const;
};
/** A MaterialBucket is a collection of smaller buckets with the same
Material (and implicitly the same LOD). */
class _OgreExport MaterialBucket : public BatchedGeometryAlloc
{
public:
/// list of Geometry Buckets in this region
typedef vector<GeometryBucket*>::type GeometryBucketList;
protected:
/// Pointer to parent LODBucket
LODBucket* mParent;
/// Material being used
String mMaterialName;
/// Pointer to material being used
MaterialPtr mMaterial;
/// Active technique
Technique* mTechnique;
/// list of Geometry Buckets in this region
GeometryBucketList mGeometryBucketList;
// index to current Geometry Buckets for a given geometry format
typedef map<String, GeometryBucket*>::type CurrentGeometryMap;
CurrentGeometryMap mCurrentGeometryMap;
/// Get a packed string identifying the geometry format
String getGeometryFormatString(SubMeshLodGeometryLink* geom);
public:
MaterialBucket(LODBucket* parent, const String& materialName);
virtual ~MaterialBucket();
LODBucket* getParent(void) { return mParent; }
/// Get the material name
const String& getMaterialName(void) const { return mMaterialName; }
/// Assign geometry to this bucket
void assign(QueuedGeometry* qsm);
/// Build
void build(bool stencilShadows);
/// Add children to the render queue
void addRenderables(RenderQueue* queue, uint8 group,
Real lodValue);
/// Get the material for this bucket
const MaterialPtr& getMaterial(void) const { return mMaterial; }
/// Iterator over geometry
typedef VectorIterator<GeometryBucketList> GeometryIterator;
/// Get an iterator over the contained geometry
GeometryIterator getGeometryIterator(void);
/// Get the current Technique
Technique* getCurrentTechnique(void) const { return mTechnique; }
/// Dump contents for diagnostics
void dump(std::ofstream& of) const;
void visitRenderables(Renderable::Visitor* visitor, bool debugRenderables);
};
/** A LODBucket is a collection of smaller buckets with the same LOD.
@remarks
LOD refers to Mesh LOD here. Material LOD can change separately
at the next bucket down from this.
*/
class _OgreExport LODBucket : public BatchedGeometryAlloc
{
public:
/// Lookup of Material Buckets in this region
typedef map<String, MaterialBucket*>::type MaterialBucketMap;
protected:
/** Nested class to allow shadows. */
class _OgreExport LODShadowRenderable : public ShadowRenderable
{
protected:
LODBucket* mParent;
// Shared link to position buffer
HardwareVertexBufferSharedPtr mPositionBuffer;
// Shared link to w-coord buffer (optional)
HardwareVertexBufferSharedPtr mWBuffer;
public:
LODShadowRenderable(LODBucket* parent,
HardwareIndexBufferSharedPtr* indexBuffer, const VertexData* vertexData,
bool createSeparateLightCap, bool isLightCap = false);
~LODShadowRenderable();
/// Overridden from ShadowRenderable
void getWorldTransforms(Matrix4* xform) const;
HardwareVertexBufferSharedPtr getPositionBuffer(void) { return mPositionBuffer; }
HardwareVertexBufferSharedPtr getWBuffer(void) { return mWBuffer; }
/// Overridden from ShadowRenderable
virtual void rebindIndexBuffer(const HardwareIndexBufferSharedPtr& indexBuffer);
};
/// Pointer to parent region
Region* mParent;
/// LOD level (0 == full LOD)
unsigned short mLod;
/// lod value at which this LOD starts to apply (squared)
Real mLodValue;
/// Lookup of Material Buckets in this region
MaterialBucketMap mMaterialBucketMap;
/// Geometry queued for a single LOD (deallocated here)
QueuedGeometryList mQueuedGeometryList;
/// Edge list, used if stencil shadow casting is enabled
EdgeData* mEdgeList;
/// Is a vertex program in use somewhere in this group?
bool mVertexProgramInUse;
/// List of shadow renderables
ShadowCaster::ShadowRenderableList mShadowRenderables;
public:
LODBucket(Region* parent, unsigned short lod, Real lodValue);
virtual ~LODBucket();
Region* getParent(void) { return mParent; }
/// Get the lod index
ushort getLod(void) const { return mLod; }
/// Get the lod value
Real getLodValue(void) const { return mLodValue; }
/// Assign a queued submesh to this bucket, using specified mesh LOD
void assign(QueuedSubMesh* qsm, ushort atLod);
/// Build
void build(bool stencilShadows);
/// Add children to the render queue
void addRenderables(RenderQueue* queue, uint8 group,
Real lodValue);
/// Iterator over the materials in this LOD
typedef MapIterator<MaterialBucketMap> MaterialIterator;
/// Get an iterator over the materials in this LOD
MaterialIterator getMaterialIterator(void);
/// Dump contents for diagnostics
void dump(std::ofstream& of) const;
void visitRenderables(Renderable::Visitor* visitor, bool debugRenderables);
EdgeData* getEdgeList() const { return mEdgeList; }
ShadowCaster::ShadowRenderableList& getShadowRenderableList() { return mShadowRenderables; }
bool isVertexProgramInUse() const { return mVertexProgramInUse; }
void updateShadowRenderables(
ShadowTechnique shadowTechnique, const Vector4& lightPos,
HardwareIndexBufferSharedPtr* indexBuffer,
bool extrudeVertices, Real extrusionDistance, unsigned long flags = 0 );
};
/** The details of a topological region which is the highest level of
partitioning for this class.
@remarks
The size & shape of regions entirely depends on the SceneManager
specific implementation. It is a MovableObject since it will be
attached to a node based on the local centre - in practice it
won't actually move (although in theory it could).
*/
class _OgreExport Region : public MovableObject
{
friend class MaterialBucket;
friend class GeometryBucket;
public:
/// list of LOD Buckets in this region
typedef vector<LODBucket*>::type LODBucketList;
protected:
/// Parent static geometry
StaticGeometry* mParent;
/// Scene manager link
SceneManager* mSceneMgr;
/// Scene node
SceneNode* mNode;
/// Local list of queued meshes (not used for deallocation)
QueuedSubMeshList mQueuedSubMeshes;
/// Unique identifier for the region
uint32 mRegionID;
/// Center of the region
Vector3 mCentre;
/// Lod values as built up - use the max at each level
Mesh::LodValueList mLodValues;
/// Local AABB relative to region centre
AxisAlignedBox mAABB;
/// Local bounding radius
Real mBoundingRadius;
/// The current lod level, as determined from the last camera
ushort mCurrentLod;
/// Current lod value, passed on to do material lod later
Real mLodValue;
/// List of LOD buckets
LODBucketList mLodBucketList;
/// List of lights for this region
mutable LightList mLightList;
/// The last frame that this light list was updated in
mutable ulong mLightListUpdated;
/// Lod strategy reference
const LodStrategy *mLodStrategy;
/// Current camera
Camera *mCamera;
/// Cached squared view depth value to avoid recalculation by GeometryBucket
Real mSquaredViewDepth;
public:
Region(StaticGeometry* parent, const String& name, SceneManager* mgr,
uint32 regionID, const Vector3& centre);
virtual ~Region();
// more fields can be added in subclasses
StaticGeometry* getParent(void) const { return mParent;}
/// Assign a queued mesh to this region, read for final build
void assign(QueuedSubMesh* qmesh);
/// Build this region
void build(bool stencilShadows);
/// Get the region ID of this region
uint32 getID(void) const { return mRegionID; }
/// Get the centre point of the region
const Vector3& getCentre(void) const { return mCentre; }
const String& getMovableType(void) const;
void _notifyCurrentCamera(Camera* cam);
const AxisAlignedBox& getBoundingBox(void) const;
Real getBoundingRadius(void) const;
void _updateRenderQueue(RenderQueue* queue);
/// @copydoc MovableObject::visitRenderables
void visitRenderables(Renderable::Visitor* visitor,
bool debugRenderables = false);
bool isVisible(void) const;
uint32 getTypeFlags(void) const;
typedef VectorIterator<LODBucketList> LODIterator;
/// Get an iterator over the LODs in this region
LODIterator getLODIterator(void);
/// @copydoc ShadowCaster::getShadowVolumeRenderableIterator
ShadowRenderableListIterator getShadowVolumeRenderableIterator(
ShadowTechnique shadowTechnique, const Light* light,
HardwareIndexBufferSharedPtr* indexBuffer,
bool extrudeVertices, Real extrusionDistance, unsigned long flags = 0 );
/// Overridden from MovableObject
EdgeData* getEdgeList(void);
/** Overridden member from ShadowCaster. */
bool hasEdgeList(void);
/// Dump contents for diagnostics
void dump(std::ofstream& of) const;
};
/** Indexed region map based on packed x/y/z region index, 10 bits for
each axis.
@remarks
Regions are indexed 0-1023 in all axes, where for example region
0 in the x axis begins at mOrigin.x + (mRegionDimensions.x * -512),
and region 1023 ends at mOrigin + (mRegionDimensions.x * 512).
*/
typedef map<uint32, Region*>::type RegionMap;
protected:
// General state & settings
SceneManager* mOwner;
String mName;
bool mBuilt;
Real mUpperDistance;
Real mSquaredUpperDistance;
bool mCastShadows;
Vector3 mRegionDimensions;
Vector3 mHalfRegionDimensions;
Vector3 mOrigin;
bool mVisible;
/// The render queue to use when rendering this object
uint8 mRenderQueueID;
/// Flags whether the RenderQueue's default should be used.
bool mRenderQueueIDSet;
/// Stores the visibility flags for the regions
uint32 mVisibilityFlags;
QueuedSubMeshList mQueuedSubMeshes;
/// List of geometry which has been optimised for SubMesh use
/// This is the primary storage used for cleaning up later
OptimisedSubMeshGeometryList mOptimisedSubMeshGeometryList;
/** Cached links from SubMeshes to (potentially optimised) geometry
This is not used for deletion since the lookup may reference
original vertex data
*/
SubMeshGeometryLookup mSubMeshGeometryLookup;
/// Map of regions
RegionMap mRegionMap;
/** Virtual method for getting a region most suitable for the
passed in bounds. Can be overridden by subclasses.
*/
virtual Region* getRegion(const AxisAlignedBox& bounds, bool autoCreate);
/** Get the region within which a point lies */
virtual Region* getRegion(const Vector3& point, bool autoCreate);
/** Get the region using indexes */
virtual Region* getRegion(ushort x, ushort y, ushort z, bool autoCreate);
/** Get the region using a packed index, returns null if it doesn't exist. */
virtual Region* getRegion(uint32 index);
/** Get the region indexes for a point.
*/
virtual void getRegionIndexes(const Vector3& point,
ushort& x, ushort& y, ushort& z);
/** Pack 3 indexes into a single index value
*/
virtual uint32 packIndex(ushort x, ushort y, ushort z);
/** Get the volume intersection for an indexed region with some bounds.
*/
virtual Real getVolumeIntersection(const AxisAlignedBox& box,
ushort x, ushort y, ushort z);
/** Get the bounds of an indexed region.
*/
virtual AxisAlignedBox getRegionBounds(ushort x, ushort y, ushort z);
/** Get the centre of an indexed region.
*/
virtual Vector3 getRegionCentre(ushort x, ushort y, ushort z);
/** Calculate world bounds from a set of vertex data. */
virtual AxisAlignedBox calculateBounds(VertexData* vertexData,
const Vector3& position, const Quaternion& orientation,
const Vector3& scale);
/** Look up or calculate the geometry data to use for this SubMesh */
SubMeshLodGeometryLinkList* determineGeometry(SubMesh* sm);
/** Split some shared geometry into dedicated geometry. */
void splitGeometry(VertexData* vd, IndexData* id,
SubMeshLodGeometryLink* targetGeomLink);
typedef map<size_t, size_t>::type IndexRemap;
/** Method for figuring out which vertices are used by an index buffer
and calculating a remap lookup for a vertex buffer just containing
those vertices.
*/
template <typename T>
void buildIndexRemap(T* pBuffer, size_t numIndexes, IndexRemap& remap)
{
remap.clear();
for (size_t i = 0; i < numIndexes; ++i)
{
// use insert since duplicates are silently discarded
remap.insert(IndexRemap::value_type(*pBuffer++, remap.size()));
// this will have mapped oldindex -> new index IF oldindex
// wasn't already there
}
}
/** Method for altering indexes based on a remap. */
template <typename T>
void remapIndexes(T* src, T* dst, const IndexRemap& remap,
size_t numIndexes)
{
for (size_t i = 0; i < numIndexes; ++i)
{
// look up original and map to target
IndexRemap::const_iterator ix = remap.find(*src++);
assert(ix != remap.end());
*dst++ = static_cast<T>(ix->second);
}
}
public:
/// Constructor; do not use directly (@see SceneManager::createStaticGeometry)
StaticGeometry(SceneManager* owner, const String& name);
/// Destructor
virtual ~StaticGeometry();
/// Get the name of this object
const String& getName(void) const { return mName; }
/** Adds an Entity to the static geometry.
@remarks
This method takes an existing Entity and adds its details to the
list of elements to include when building. Note that the Entity
itself is not copied or referenced in this method; an Entity is
passed simply so that you can change the materials of attached
SubEntity objects if you want. You can add the same Entity
instance multiple times with different material settings
completely safely, and destroy the Entity before destroying
this StaticGeometry if you like. The Entity passed in is simply
used as a definition.
@note Must be called before 'build'.
@param ent The Entity to use as a definition (the Mesh and Materials
referenced will be recorded for the build call).
@param position The world position at which to add this Entity
@param orientation The world orientation at which to add this Entity
@param scale The scale at which to add this entity
*/
virtual void addEntity(Entity* ent, const Vector3& position,
const Quaternion& orientation = Quaternion::IDENTITY,
const Vector3& scale = Vector3::UNIT_SCALE);
/** Adds all the Entity objects attached to a SceneNode and all it's
children to the static geometry.
@remarks
This method performs just like addEntity, except it adds all the
entities attached to an entire sub-tree to the geometry.
The position / orientation / scale parameters are taken from the
node structure instead of being specified manually.
@note
The SceneNode you pass in will not be automatically detached from
it's parent, so if you have this node already attached to the scene
graph, you will need to remove it if you wish to avoid the overhead
of rendering <i>both</i> the original objects and their new static
versions! We don't do this for you incase you are preparing this
in advance and so don't want the originals detached yet.
@note Must be called before 'build'.
@param node Pointer to the node to use to provide a set of Entity
templates
*/
virtual void addSceneNode(const SceneNode* node);
/** Build the geometry.
@remarks
Based on all the entities which have been added, and the batching
options which have been set, this method constructs the batched
geometry structures required. The batches are added to the scene
and will be rendered unless you specifically hide them.
@note
Once you have called this method, you can no longer add any more
entities.
*/
virtual void build(void);
/** Destroys all the built geometry state (reverse of build).
@remarks
You can call build() again after this and it will pick up all the
same entities / nodes you queued last time.
*/
virtual void destroy(void);
/** Clears any of the entities / nodes added to this geometry and
destroys anything which has already been built.
*/
virtual void reset(void);
/** Sets the distance at which batches are no longer rendered.
@remarks
This lets you turn off batches at a given distance. This can be
useful for things like detail meshes (grass, foliage etc) and could
be combined with a shader which fades the geometry out beforehand
to lessen the effect.
@param dist Distance beyond which the batches will not be rendered
(the default is 0, which means batches are always rendered).
*/
virtual void setRenderingDistance(Real dist) {
mUpperDistance = dist;
mSquaredUpperDistance = mUpperDistance * mUpperDistance;
}
/** Gets the distance at which batches are no longer rendered. */
virtual Real getRenderingDistance(void) const { return mUpperDistance; }
/** Gets the squared distance at which batches are no longer rendered. */
virtual Real getSquaredRenderingDistance(void) const
{ return mSquaredUpperDistance; }
/** Hides or shows all the batches. */
virtual void setVisible(bool visible);
/** Are the batches visible? */
virtual bool isVisible(void) const { return mVisible; }
/** Sets whether this geometry should cast shadows.
@remarks
No matter what the settings on the original entities,
the StaticGeometry class defaults to not casting shadows.
This is because, being static, unless you have moving lights
you'd be better to use precalculated shadows of some sort.
However, if you need them, you can enable them using this
method. If the SceneManager is set up to use stencil shadows,
edge lists will be copied from the underlying meshes on build.
It is essential that all meshes support stencil shadows in this
case.
@note If you intend to use stencil shadows, you must set this to
true before calling 'build' as well as making sure you set the
scene's shadow type (that should always be the first thing you do
anyway). You can turn shadows off temporarily but they can never
be turned on if they were not at the time of the build.
*/
virtual void setCastShadows(bool castShadows);
/// Will the geometry from this object cast shadows?
virtual bool getCastShadows(void) { return mCastShadows; }
/** Sets the size of a single region of geometry.
@remarks
This method allows you to configure the physical world size of
each region, so you can balance culling against batch size. Entities
will be fitted within the batch they most closely fit, and the
eventual bounds of each batch may well be slightly larger than this
if they overlap a little. The default is Vector3(1000, 1000, 1000).
@note Must be called before 'build'.
@param size Vector3 expressing the 3D size of each region.
*/
virtual void setRegionDimensions(const Vector3& size) {
mRegionDimensions = size;
mHalfRegionDimensions = size * 0.5;
}
/** Gets the size of a single batch of geometry. */
virtual const Vector3& getRegionDimensions(void) const { return mRegionDimensions; }
/** Sets the origin of the geometry.
@remarks
This method allows you to configure the world centre of the geometry,
thus the place which all regions surround. You probably don't need
to mess with this unless you have a seriously large world, since the
default set up can handle an area 1024 * mRegionDimensions, and
the sparseness of population is no issue when it comes to rendering.
The default is Vector3(0,0,0).
@note Must be called before 'build'.
@param size Vector3 expressing the 3D origin of the geometry.
*/
virtual void setOrigin(const Vector3& origin) { mOrigin = origin; }
/** Gets the origin of this geometry. */
virtual const Vector3& getOrigin(void) const { return mOrigin; }
/// Sets the visibility flags of all the regions at once
void setVisibilityFlags(uint32 flags);
/// Returns the visibility flags of the regions
uint32 getVisibilityFlags() const;
/** Sets the render queue group this object will be rendered through.
@remarks
Render queues are grouped to allow you to more tightly control the ordering
of rendered objects. If you do not call this method, all objects default
to the default queue (RenderQueue::getDefaultQueueGroup), which is fine for
most objects. You may want to alter this if you want to perform more complex
rendering.
@par
See RenderQueue for more details.
@param queueID Enumerated value of the queue group to use.
*/
virtual void setRenderQueueGroup(uint8 queueID);
/** Gets the queue group for this entity, see setRenderQueueGroup for full details. */
virtual uint8 getRenderQueueGroup(void) const;
/// @copydoc MovableObject::visitRenderables
void visitRenderables(Renderable::Visitor* visitor,
bool debugRenderables = false);
/// Iterator for iterating over contained regions
typedef MapIterator<RegionMap> RegionIterator;
/// Get an iterator over the regions in this geometry
RegionIterator getRegionIterator(void);
/** Dump the contents of this StaticGeometry to a file for diagnostic
purposes.
*/
virtual void dump(const String& filename) const;
};
/** @} */
/** @} */
}
#endif
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