/usr/include/OGRE/OgreSceneManager.h is in libogre-1.9-dev 1.9.0+dfsg1-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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This source file is a part of OGRE
(Object-oriented Graphics Rendering Engine)
For the latest info, see http://www.ogre3d.org/
Copyright (c) 2000-2013 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
You may alternatively use this source under the terms of a specific version of
the OGRE Unrestricted License provided you have obtained such a license from
Torus Knot Software Ltd.
-------------------------------------------------------------------------*/
#ifndef __SceneManager_H__
#define __SceneManager_H__
// Precompiler options
#include "OgrePrerequisites.h"
#include "OgreString.h"
#include "OgreSceneNode.h"
#include "OgrePlane.h"
#include "OgreQuaternion.h"
#include "OgreColourValue.h"
#include "OgreCommon.h"
#include "OgreSceneQuery.h"
#include "OgreAutoParamDataSource.h"
#include "OgreAnimationState.h"
#include "OgreRenderQueue.h"
#include "OgreRenderQueueSortingGrouping.h"
#include "OgreRectangle2D.h"
#include "OgrePixelFormat.h"
#include "OgreResourceGroupManager.h"
#include "OgreTexture.h"
#include "OgreShadowCameraSetup.h"
#include "OgreShadowTextureManager.h"
#include "OgreCamera.h"
#include "OgreInstancedGeometry.h"
#include "OgreLodListener.h"
#include "OgreInstanceManager.h"
#include "OgreRenderSystem.h"
#include "OgreHeaderPrefix.h"
#include "OgreNameGenerator.h"
namespace Ogre {
/** \addtogroup Core
* @{
*/
/** \addtogroup Scene
* @{
*/
/** Structure for holding a position & orientation pair. */
struct ViewPoint
{
Vector3 position;
Quaternion orientation;
};
// Forward declarations
class DefaultIntersectionSceneQuery;
class DefaultRaySceneQuery;
class DefaultSphereSceneQuery;
class DefaultAxisAlignedBoxSceneQuery;
class CompositorChain;
/** Structure collecting together information about the visible objects
that have been discovered in a scene.
*/
struct _OgreExport VisibleObjectsBoundsInfo
{
/// The axis-aligned bounds of the visible objects
AxisAlignedBox aabb;
/// The axis-aligned bounds of the visible shadow receiver objects
AxisAlignedBox receiverAabb;
/// The closest a visible object is to the camera
Real minDistance;
/// The farthest a visible objects is from the camera
Real maxDistance;
/// The closest a object in the frustum regardless of visibility / shadow caster flags
Real minDistanceInFrustum;
/// The farthest object in the frustum regardless of visibility / shadow caster flags
Real maxDistanceInFrustum;
VisibleObjectsBoundsInfo();
void reset();
void merge(const AxisAlignedBox& boxBounds, const Sphere& sphereBounds,
const Camera* cam, bool receiver=true);
/** Merge an object that is not being rendered because it's not a shadow caster,
but is a shadow receiver so should be included in the range.
*/
void mergeNonRenderedButInFrustum(const AxisAlignedBox& boxBounds,
const Sphere& sphereBounds, const Camera* cam);
};
/** Manages the organisation and rendering of a 'scene' i.e. a collection
of objects and potentially world geometry.
@remarks
This class defines the interface and the basic behaviour of a
'Scene Manager'. A SceneManager organises the culling and rendering of
the scene, in conjunction with the RenderQueue. This class is designed
to be extended through subclassing in order to provide more specialised
scene organisation structures for particular needs. The default
SceneManager culls based on a hierarchy of node bounding boxes, other
implementations can use an octree (@see OctreeSceneManager), a BSP
tree (@see BspSceneManager), and many other options. New SceneManager
implementations can be added at runtime by plugins, see
SceneManagerEnumerator for the interfaces for adding new SceneManager
types.
@par
There is a distinction between 'objects' (which subclass MovableObject,
and are movable, discrete objects in the world), and 'world geometry',
which is large, generally static geometry. World geometry tends to
influence the SceneManager organisational structure (e.g. lots of indoor
static geometry might result in a spatial tree structure) and as such
world geometry is generally tied to a given SceneManager implementation,
whilst MovableObject instances can be used with any SceneManager.
Subclasses are free to define world geometry however they please.
@par
Multiple SceneManager instances can exist at one time, each one with
a distinct scene. Which SceneManager is used to render a scene is
dependent on the Camera, which will always call back the SceneManager
which created it to render the scene.
*/
class _OgreExport SceneManager : public SceneMgtAlloc
{
public:
/// Query type mask which will be used for world geometry @see SceneQuery
static uint32 WORLD_GEOMETRY_TYPE_MASK;
/// Query type mask which will be used for entities @see SceneQuery
static uint32 ENTITY_TYPE_MASK;
/// Query type mask which will be used for effects like billboardsets / particle systems @see SceneQuery
static uint32 FX_TYPE_MASK;
/// Query type mask which will be used for StaticGeometry @see SceneQuery
static uint32 STATICGEOMETRY_TYPE_MASK;
/// Query type mask which will be used for lights @see SceneQuery
static uint32 LIGHT_TYPE_MASK;
/// Query type mask which will be used for frusta and cameras @see SceneQuery
static uint32 FRUSTUM_TYPE_MASK;
/// User type mask limit
static uint32 USER_TYPE_MASK_LIMIT;
/** Comparator for material map, for sorting materials into render order (e.g. transparent last).
*/
struct materialLess
{
_OgreExport bool operator()(const Material* x, const Material* y) const;
};
/// Comparator for sorting lights relative to a point
struct lightLess
{
_OgreExport bool operator()(const Light* a, const Light* b) const;
};
/// Describes the stage of rendering when performing complex illumination
enum IlluminationRenderStage
{
/// No special illumination stage
IRS_NONE,
/// Render to texture stage, used for texture based shadows
IRS_RENDER_TO_TEXTURE,
/// Render from shadow texture to receivers stage
IRS_RENDER_RECEIVER_PASS
};
/** Enumeration of the possible modes allowed for processing the special case
render queue list.
@see SceneManager::setSpecialCaseRenderQueueMode
*/
enum SpecialCaseRenderQueueMode
{
/// Render only the queues in the special case list
SCRQM_INCLUDE,
/// Render all except the queues in the special case list
SCRQM_EXCLUDE
};
struct SkyDomeGenParameters
{
Real skyDomeCurvature;
Real skyDomeTiling;
Real skyDomeDistance;
int skyDomeXSegments;
int skyDomeYSegments;
int skyDomeYSegments_keep;
};
struct SkyPlaneGenParameters
{
Real skyPlaneScale;
Real skyPlaneTiling;
Real skyPlaneBow;
int skyPlaneXSegments;
int skyPlaneYSegments;
};
struct SkyBoxGenParameters
{
Real skyBoxDistance;
};
/** Class that allows listening in on the various stages of SceneManager
processing, so that custom behaviour can be implemented from outside.
*/
class Listener
{
public:
Listener() {}
virtual ~Listener() {}
/** Called prior to updating the scene graph in this SceneManager.
@remarks
This is called before updating the scene graph for a camera.
@param source The SceneManager instance raising this event.
@param camera The camera being updated.
*/
virtual void preUpdateSceneGraph(SceneManager* source, Camera* camera)
{ (void)source; (void)camera; }
/** Called after updating the scene graph in this SceneManager.
@remarks
This is called after updating the scene graph for a camera.
@param source The SceneManager instance raising this event.
@param camera The camera being updated.
*/
virtual void postUpdateSceneGraph(SceneManager* source, Camera* camera)
{ (void)source; (void)camera; }
/** Called prior to searching for visible objects in this SceneManager.
@remarks
Note that the render queue at this stage will be full of the last
render's contents and will be cleared after this method is called.
@param source The SceneManager instance raising this event.
@param irs The stage of illumination being dealt with. IRS_NONE for
a regular render, IRS_RENDER_TO_TEXTURE for a shadow caster render.
@param v The viewport being updated. You can get the camera from here.
*/
virtual void preFindVisibleObjects(SceneManager* source,
IlluminationRenderStage irs, Viewport* v)
{ (void)source; (void)irs; (void)v; }
/** Called after searching for visible objects in this SceneManager.
@remarks
Note that the render queue at this stage will be full of the current
scenes contents, ready for rendering. You may manually add renderables
to this queue if you wish.
@param source The SceneManager instance raising this event.
@param irs The stage of illumination being dealt with. IRS_NONE for
a regular render, IRS_RENDER_TO_TEXTURE for a shadow caster render.
@param v The viewport being updated. You can get the camera from here.
*/
virtual void postFindVisibleObjects(SceneManager* source,
IlluminationRenderStage irs, Viewport* v)
{ (void)source; (void)irs; (void)v; }
/** Event raised after all shadow textures have been rendered into for
all queues / targets but before any other geometry has been rendered
(including main scene geometry and any additional shadow receiver
passes).
@remarks
This callback is useful for those that wish to perform some
additional processing on shadow textures before they are used to
render shadows. For example you could perform some filtering by
rendering the existing shadow textures into another alternative
shadow texture with a shader.]
@note
This event will only be fired when texture shadows are in use.
@param numberOfShadowTextures The number of shadow textures in use
*/
virtual void shadowTexturesUpdated(size_t numberOfShadowTextures)
{ (void)numberOfShadowTextures; }
/** This event occurs just before the view & projection matrices are
set for rendering into a shadow texture.
@remarks
You can use this event hook to perform some custom processing,
such as altering the camera being used for rendering the light's
view, including setting custom view & projection matrices if you
want to perform an advanced shadow technique.
@note
This event will only be fired when texture shadows are in use.
@param light Pointer to the light for which shadows are being rendered
@param camera Pointer to the camera being used to render
@param iteration For lights that use multiple shadow textures, the iteration number
*/
virtual void shadowTextureCasterPreViewProj(Light* light,
Camera* camera, size_t iteration)
{ (void)light; (void)camera; (void)iteration; }
/** This event occurs just before the view & projection matrices are
set for re-rendering a shadow receiver.
@remarks
You can use this event hook to perform some custom processing,
such as altering the projection frustum being used for rendering
the shadow onto the receiver to perform an advanced shadow
technique.
@note
This event will only be fired when texture shadows are in use.
@param light Pointer to the light for which shadows are being rendered
@param frustum Pointer to the projection frustum being used to project
the shadow texture
*/
virtual void shadowTextureReceiverPreViewProj(Light* light,
Frustum* frustum)
{ (void)light; (void)frustum; }
/** Hook to allow the listener to override the ordering of lights for
the entire frustum.
@remarks
Whilst ordinarily lights are sorted per rendered object
(@see MovableObject::queryLights), texture shadows adds another issue
in that, given there is a finite number of shadow textures, we must
choose which lights to render texture shadows from based on the entire
frustum. These lights should always be listed first in every objects
own list, followed by any other lights which will not cast texture
shadows (either because they have shadow casting off, or there aren't
enough shadow textures to service them).
@par
This hook allows you to override the detailed ordering of the lights
per frustum. The default ordering is shadow casters first (which you
must also respect if you override this method), and ordered
by distance from the camera within those 2 groups. Obviously the closest
lights with shadow casting enabled will be listed first. Only lights
within the range of the frustum will be in the list.
@param lightList The list of lights within range of the frustum which you
may sort.
@return true if you sorted the list, false otherwise.
*/
virtual bool sortLightsAffectingFrustum(LightList& lightList)
{ (void)lightList; return false; }
/** Event notifying the listener of the SceneManager's destruction. */
virtual void sceneManagerDestroyed(SceneManager* source)
{ (void)source; }
};
/** Inner helper class to implement the visitor pattern for rendering objects
in a queue.
*/
class _OgreExport SceneMgrQueuedRenderableVisitor : public QueuedRenderableVisitor
{
protected:
/// Pass that was actually used at the grouping level
const Pass* mUsedPass;
public:
SceneMgrQueuedRenderableVisitor()
:transparentShadowCastersMode(false) {}
~SceneMgrQueuedRenderableVisitor() {}
void visit(Renderable* r);
bool visit(const Pass* p);
void visit(RenderablePass* rp);
/// Target SM to send renderables to
SceneManager* targetSceneMgr;
/// Are we in transparent shadow caster mode?
bool transparentShadowCastersMode;
/// Automatic light handling?
bool autoLights;
/// Manual light list
const LightList* manualLightList;
/// Scissoring if requested?
bool scissoring;
};
/// Allow visitor helper to access protected methods
friend class SceneMgrQueuedRenderableVisitor;
protected:
/// Subclasses can override this to ensure their specialised SceneNode is used.
virtual SceneNode* createSceneNodeImpl(void);
/// Subclasses can override this to ensure their specialised SceneNode is used.
virtual SceneNode* createSceneNodeImpl(const String& name);
/// Instance name
String mName;
/// Queue of objects for rendering
RenderQueue* mRenderQueue;
bool mLastRenderQueueInvocationCustom;
/// Current ambient light, cached for RenderSystem
ColourValue mAmbientLight;
/// The rendering system to send the scene to
RenderSystem *mDestRenderSystem;
typedef map<String, Camera* >::type CameraList;
/** Central list of cameras - for easy memory management and lookup.
*/
CameraList mCameras;
typedef map<String, StaticGeometry* >::type StaticGeometryList;
StaticGeometryList mStaticGeometryList;
typedef map<String, InstancedGeometry* >::type InstancedGeometryList;
InstancedGeometryList mInstancedGeometryList;
typedef map<String, InstanceManager*>::type InstanceManagerMap;
InstanceManagerMap mInstanceManagerMap;
typedef map<String, SceneNode*>::type SceneNodeList;
/** Central list of SceneNodes - for easy memory management.
@note
Note that this list is used only for memory management; the structure of the scene
is held using the hierarchy of SceneNodes starting with the root node. However you
can look up nodes this way.
*/
SceneNodeList mSceneNodes;
/// Camera in progress
Camera* mCameraInProgress;
/// Current Viewport
Viewport* mCurrentViewport;
/// Root scene node
SceneNode* mSceneRoot;
/// Autotracking scene nodes
typedef set<SceneNode*>::type AutoTrackingSceneNodes;
AutoTrackingSceneNodes mAutoTrackingSceneNodes;
// Sky params
// Sky plane
Entity* mSkyPlaneEntity;
Entity* mSkyDomeEntity[5];
ManualObject* mSkyBoxObj;
SceneNode* mSkyPlaneNode;
SceneNode* mSkyDomeNode;
SceneNode* mSkyBoxNode;
// Sky plane
bool mSkyPlaneEnabled;
uint8 mSkyPlaneRenderQueue;
Plane mSkyPlane;
SkyPlaneGenParameters mSkyPlaneGenParameters;
// Sky box
bool mSkyBoxEnabled;
uint8 mSkyBoxRenderQueue;
Quaternion mSkyBoxOrientation;
SkyBoxGenParameters mSkyBoxGenParameters;
// Sky dome
bool mSkyDomeEnabled;
uint8 mSkyDomeRenderQueue;
Quaternion mSkyDomeOrientation;
SkyDomeGenParameters mSkyDomeGenParameters;
// Fog
FogMode mFogMode;
ColourValue mFogColour;
Real mFogStart;
Real mFogEnd;
Real mFogDensity;
typedef set<uint8>::type SpecialCaseRenderQueueList;
SpecialCaseRenderQueueList mSpecialCaseQueueList;
SpecialCaseRenderQueueMode mSpecialCaseQueueMode;
uint8 mWorldGeometryRenderQueue;
unsigned long mLastFrameNumber;
Matrix4 mTempXform[256];
bool mResetIdentityView;
bool mResetIdentityProj;
bool mNormaliseNormalsOnScale;
bool mFlipCullingOnNegativeScale;
CullingMode mPassCullingMode;
protected:
/** Visible objects bounding box list.
@remarks
Holds an ABB for each camera that contains the physical extends of the visible
scene elements by each camera. The map is crucial for shadow algorithms which
have a focus step to limit the shadow sample distribution to only valid visible
scene elements.
*/
typedef map< const Camera*, VisibleObjectsBoundsInfo>::type CamVisibleObjectsMap;
CamVisibleObjectsMap mCamVisibleObjectsMap;
/** ShadowCamera to light mapping */
typedef map< const Camera*, const Light* >::type ShadowCamLightMapping;
ShadowCamLightMapping mShadowCamLightMapping;
/// Array defining shadow count per light type.
size_t mShadowTextureCountPerType[3];
/// Array defining shadow texture index in light list.
vector<size_t>::type mShadowTextureIndexLightList;
/// Cached light information, used to tracking light's changes
struct _OgreExport LightInfo
{
Light* light; /// Just a pointer for comparison, the light might destroyed for some reason
int type; /// Use int instead of Light::LightTypes to avoid header file dependence
Real range; /// Sets to zero if directional light
Vector3 position; /// Sets to zero if directional light
uint32 lightMask; /// Light mask
bool operator== (const LightInfo& rhs) const
{
return light == rhs.light && type == rhs.type &&
range == rhs.range && position == rhs.position && lightMask == rhs.lightMask;
}
bool operator!= (const LightInfo& rhs) const
{
return !(*this == rhs);
}
};
typedef vector<LightInfo>::type LightInfoList;
LightList mLightsAffectingFrustum;
LightInfoList mCachedLightInfos;
LightInfoList mTestLightInfos; // potentially new list
ulong mLightsDirtyCounter;
LightList mShadowTextureCurrentCasterLightList;
typedef map<String, MovableObject*>::type MovableObjectMap;
/// Simple structure to hold MovableObject map and a mutex to go with it.
struct MovableObjectCollection
{
MovableObjectMap map;
OGRE_MUTEX(mutex);
};
typedef map<String, MovableObjectCollection*>::type MovableObjectCollectionMap;
MovableObjectCollectionMap mMovableObjectCollectionMap;
NameGenerator mMovableNameGenerator;
/** Gets the movable object collection for the given type name.
@remarks
This method create new collection if the collection does not exist.
*/
MovableObjectCollection* getMovableObjectCollection(const String& typeName);
/** Gets the movable object collection for the given type name.
@remarks
This method throw exception if the collection does not exist.
*/
const MovableObjectCollection* getMovableObjectCollection(const String& typeName) const;
/// Mutex over the collection of MovableObject types
OGRE_MUTEX(mMovableObjectCollectionMapMutex);
/** Internal method for initialising the render queue.
@remarks
Subclasses can use this to install their own RenderQueue implementation.
*/
virtual void initRenderQueue(void);
/// A pass designed to let us render shadow colour on white for texture shadows
Pass* mShadowCasterPlainBlackPass;
/// A pass designed to let us render shadow receivers for texture shadows
Pass* mShadowReceiverPass;
/** Internal method for turning a regular pass into a shadow caster pass.
@remarks
This is only used for texture shadows, basically we're trying to
ensure that objects are rendered solid black.
This method will usually return the standard solid black pass for
all fixed function passes, but will merge in a vertex program
and fudge the AutoParamDataSource to set black lighting for
passes with vertex programs.
*/
virtual const Pass* deriveShadowCasterPass(const Pass* pass);
/** Internal method for turning a regular pass into a shadow receiver pass.
@remarks
This is only used for texture shadows, basically we're trying to
ensure that objects are rendered with a projective texture.
This method will usually return a standard single-texture pass for
all fixed function passes, but will merge in a vertex program
for passes with vertex programs.
*/
virtual const Pass* deriveShadowReceiverPass(const Pass* pass);
/** Internal method to validate whether a Pass should be allowed to render.
@remarks
Called just before a pass is about to be used for rendering a group to
allow the SceneManager to omit it if required. A return value of false
skips this pass.
*/
virtual bool validatePassForRendering(const Pass* pass);
/** Internal method to validate whether a Renderable should be allowed to render.
@remarks
Called just before a pass is about to be used for rendering a Renderable to
allow the SceneManager to omit it if required. A return value of false
skips it.
*/
virtual bool validateRenderableForRendering(const Pass* pass, const Renderable* rend);
enum BoxPlane
{
BP_FRONT = 0,
BP_BACK = 1,
BP_LEFT = 2,
BP_RIGHT = 3,
BP_UP = 4,
BP_DOWN = 5
};
/* Internal utility method for creating the planes of a skybox.
*/
virtual MeshPtr createSkyboxPlane(
BoxPlane bp,
Real distance,
const Quaternion& orientation,
const String& groupName);
/* Internal utility method for creating the planes of a skydome.
*/
virtual MeshPtr createSkydomePlane(
BoxPlane bp,
Real curvature, Real tiling, Real distance,
const Quaternion& orientation,
int xsegments, int ysegments, int ySegmentsToKeep,
const String& groupName);
/// Flag indicating whether SceneNodes will be rendered as a set of 3 axes
bool mDisplayNodes;
/// Storage of animations, lookup by name
typedef map<String, Animation*>::type AnimationList;
AnimationList mAnimationsList;
OGRE_MUTEX(mAnimationsListMutex);
AnimationStateSet mAnimationStates;
/** Internal method used by _renderSingleObject to deal with renderables
which override the camera's own view / projection materices. */
virtual void useRenderableViewProjMode(const Renderable* pRend, bool fixedFunction);
/** Internal method used by _renderSingleObject to deal with renderables
which override the camera's own view / projection matrices. */
virtual void resetViewProjMode(bool fixedFunction);
typedef vector<RenderQueueListener*>::type RenderQueueListenerList;
RenderQueueListenerList mRenderQueueListeners;
typedef vector<RenderObjectListener*>::type RenderObjectListenerList;
RenderObjectListenerList mRenderObjectListeners;
typedef vector<Listener*>::type ListenerList;
ListenerList mListeners;
/// Internal method for firing the queue start event
virtual void firePreRenderQueues();
/// Internal method for firing the queue end event
virtual void firePostRenderQueues();
/// Internal method for firing the queue start event, returns true if queue is to be skipped
virtual bool fireRenderQueueStarted(uint8 id, const String& invocation);
/// Internal method for firing the queue end event, returns true if queue is to be repeated
virtual bool fireRenderQueueEnded(uint8 id, const String& invocation);
/// Internal method for firing when rendering a single object.
virtual void fireRenderSingleObject(Renderable* rend, const Pass* pass, const AutoParamDataSource* source,
const LightList* pLightList, bool suppressRenderStateChanges);
/// Internal method for firing the texture shadows updated event
virtual void fireShadowTexturesUpdated(size_t numberOfShadowTextures);
/// Internal method for firing the pre caster texture shadows event
virtual void fireShadowTexturesPreCaster(Light* light, Camera* camera, size_t iteration);
/// Internal method for firing the pre receiver texture shadows event
virtual void fireShadowTexturesPreReceiver(Light* light, Frustum* f);
/// Internal method for firing pre update scene graph event
virtual void firePreUpdateSceneGraph(Camera* camera);
/// Internal method for firing post update scene graph event
virtual void firePostUpdateSceneGraph(Camera* camera);
/// Internal method for firing find visible objects event
virtual void firePreFindVisibleObjects(Viewport* v);
/// Internal method for firing find visible objects event
virtual void firePostFindVisibleObjects(Viewport* v);
/// Internal method for firing destruction event
virtual void fireSceneManagerDestroyed();
/** Internal method for setting the destination viewport for the next render. */
virtual void setViewport(Viewport *vp);
/** Flag that indicates if all of the scene node's bounding boxes should be shown as a wireframe. */
bool mShowBoundingBoxes;
/** Internal method for rendering all objects using the default queue sequence. */
virtual void renderVisibleObjectsDefaultSequence(void);
/** Internal method for rendering all objects using a custom queue sequence. */
virtual void renderVisibleObjectsCustomSequence(RenderQueueInvocationSequence* s);
/** Internal method for preparing the render queue for use with each render. */
virtual void prepareRenderQueue(void);
/** Internal utility method for rendering a single object.
@remarks
Assumes that the pass has already been set up.
@param rend The renderable to issue to the pipeline
@param pass The pass which is being used
@param lightScissoringClipping If true, passes that have the getLightScissorEnabled
and/or getLightClipPlanesEnabled flags will cause calculation and setting of
scissor rectangle and user clip planes.
@param doLightIteration If true, this method will issue the renderable to
the pipeline possibly multiple times, if the pass indicates it should be
done once per light
@param manualLightList Only applicable if doLightIteration is false, this
method allows you to pass in a previously determined set of lights
which will be used for a single render of this object.
*/
virtual void renderSingleObject(Renderable* rend, const Pass* pass,
bool lightScissoringClipping, bool doLightIteration, const LightList* manualLightList = 0);
/** Internal method for creating the AutoParamDataSource instance. */
virtual AutoParamDataSource* createAutoParamDataSource(void) const
{
return OGRE_NEW AutoParamDataSource();
}
/// Utility class for calculating automatic parameters for gpu programs
AutoParamDataSource* mAutoParamDataSource;
CompositorChain* mActiveCompositorChain;
bool mLateMaterialResolving;
ShadowTechnique mShadowTechnique;
bool mDebugShadows;
ColourValue mShadowColour;
Pass* mShadowDebugPass;
Pass* mShadowStencilPass;
Pass* mShadowModulativePass;
bool mShadowMaterialInitDone;
HardwareIndexBufferSharedPtr mShadowIndexBuffer;
size_t mShadowIndexBufferSize;
size_t mShadowIndexBufferUsedSize;
Rectangle2D* mFullScreenQuad;
Real mShadowDirLightExtrudeDist;
IlluminationRenderStage mIlluminationStage;
ShadowTextureConfigList mShadowTextureConfigList;
bool mShadowTextureConfigDirty;
ShadowTextureList mShadowTextures;
TexturePtr mNullShadowTexture;
typedef vector<Camera*>::type ShadowTextureCameraList;
ShadowTextureCameraList mShadowTextureCameras;
Texture* mCurrentShadowTexture;
bool mShadowUseInfiniteFarPlane;
bool mShadowCasterRenderBackFaces;
bool mShadowAdditiveLightClip;
/// Struct for caching light clipping information for re-use in a frame
struct LightClippingInfo
{
RealRect scissorRect;
PlaneList clipPlanes;
bool scissorValid;
unsigned long clipPlanesValid;
LightClippingInfo() : scissorValid(false), clipPlanesValid(false) {}
};
typedef map<Light*, LightClippingInfo>::type LightClippingInfoMap;
LightClippingInfoMap mLightClippingInfoMap;
unsigned long mLightClippingInfoMapFrameNumber;
/// default shadow camera setup
ShadowCameraSetupPtr mDefaultShadowCameraSetup;
/** Default sorting routine which sorts lights which cast shadows
to the front of a list, sub-sorting by distance.
@remarks
Since shadow textures are generated from lights based on the
frustum rather than individual objects, a shadow and camera-wise sort is
required to pick the best lights near the start of the list. Up to
the number of shadow textures will be generated from this.
*/
struct lightsForShadowTextureLess
{
_OgreExport bool operator()(const Light* l1, const Light* l2) const;
};
/** Internal method for locating a list of lights which could be affecting the frustum.
@remarks
Custom scene managers are encouraged to override this method to make use of their
scene partitioning scheme to more efficiently locate lights, and to eliminate lights
which may be occluded by word geometry.
*/
virtual void findLightsAffectingFrustum(const Camera* camera);
/// Internal method for setting up materials for shadows
virtual void initShadowVolumeMaterials(void);
/// Internal method for creating shadow textures (texture-based shadows)
virtual void ensureShadowTexturesCreated();
/// Internal method for destroying shadow textures (texture-based shadows)
virtual void destroyShadowTextures(void);
typedef vector<InstanceManager*>::type InstanceManagerVec;
InstanceManagerVec mDirtyInstanceManagers;
InstanceManagerVec mDirtyInstanceMgrsTmp;
/** Updates all instance managaers with dirty instance batches. @see _addDirtyInstanceManager */
void updateDirtyInstanceManagers(void);
public:
/// Method for preparing shadow textures ready for use in a regular render
/// Do not call manually unless before frame start or rendering is paused
/// If lightList is not supplied, will render all lights in frustum
virtual void prepareShadowTextures(Camera* cam, Viewport* vp, const LightList* lightList = 0);
//A render context, used to store internal data for pausing/resuming rendering
struct RenderContext
{
RenderQueue* renderQueue;
Viewport* viewport;
Camera* camera;
CompositorChain* activeChain;
RenderSystem::RenderSystemContext* rsContext;
};
/** Pause rendering of the frame. This has to be called when inside a renderScene call
(Usually using a listener of some sort)
*/
virtual RenderContext* _pauseRendering();
/** Resume rendering of the frame. This has to be called after a _pauseRendering call
@param context The rendring context, as returned by the _pauseRendering call
*/
virtual void _resumeRendering(RenderContext* context);
protected:
/** Internal method for rendering all the objects for a given light into the
stencil buffer.
@param light The light source
@param cam The camera being viewed from
@param calcScissor Whether the method should set up any scissor state, or
false if that's already been done
*/
virtual void renderShadowVolumesToStencil(const Light* light, const Camera* cam,
bool calcScissor);
/** Internal utility method for setting stencil state for rendering shadow volumes.
@param secondpass Is this the second pass?
@param zfail Should we be using the zfail method?
@param twosided Should we use a 2-sided stencil?
*/
virtual void setShadowVolumeStencilState(bool secondpass, bool zfail, bool twosided);
/** Render a set of shadow renderables. */
void renderShadowVolumeObjects(ShadowCaster::ShadowRenderableListIterator iShadowRenderables,
Pass* pass, const LightList *manualLightList, unsigned long flags,
bool secondpass, bool zfail, bool twosided);
typedef vector<ShadowCaster*>::type ShadowCasterList;
ShadowCasterList mShadowCasterList;
SphereSceneQuery* mShadowCasterSphereQuery;
AxisAlignedBoxSceneQuery* mShadowCasterAABBQuery;
Real mDefaultShadowFarDist;
Real mDefaultShadowFarDistSquared;
Real mShadowTextureOffset; /// Proportion of texture offset in view direction e.g. 0.4
Real mShadowTextureFadeStart; /// As a proportion e.g. 0.6
Real mShadowTextureFadeEnd; /// As a proportion e.g. 0.9
bool mShadowTextureSelfShadow;
Pass* mShadowTextureCustomCasterPass;
Pass* mShadowTextureCustomReceiverPass;
String mShadowTextureCustomCasterVertexProgram;
String mShadowTextureCustomCasterFragmentProgram;
String mShadowTextureCustomReceiverVertexProgram;
String mShadowTextureCustomReceiverFragmentProgram;
GpuProgramParametersSharedPtr mShadowTextureCustomCasterVPParams;
GpuProgramParametersSharedPtr mShadowTextureCustomCasterFPParams;
GpuProgramParametersSharedPtr mShadowTextureCustomReceiverVPParams;
GpuProgramParametersSharedPtr mShadowTextureCustomReceiverFPParams;
/// Visibility mask used to show / hide objects
uint32 mVisibilityMask;
bool mFindVisibleObjects;
/// Suppress render state changes?
bool mSuppressRenderStateChanges;
/// Suppress shadows?
bool mSuppressShadows;
GpuProgramParametersSharedPtr mInfiniteExtrusionParams;
GpuProgramParametersSharedPtr mFiniteExtrusionParams;
/// Inner class to use as callback for shadow caster scene query
class _OgreExport ShadowCasterSceneQueryListener : public SceneQueryListener, public SceneMgtAlloc
{
protected:
SceneManager* mSceneMgr;
ShadowCasterList* mCasterList;
bool mIsLightInFrustum;
const PlaneBoundedVolumeList* mLightClipVolumeList;
const Camera* mCamera;
const Light* mLight;
Real mFarDistSquared;
public:
ShadowCasterSceneQueryListener(SceneManager* sm) : mSceneMgr(sm),
mCasterList(0), mIsLightInFrustum(false), mLightClipVolumeList(0),
mCamera(0) {}
// Prepare the listener for use with a set of parameters
void prepare(bool lightInFrustum,
const PlaneBoundedVolumeList* lightClipVolumes,
const Light* light, const Camera* cam, ShadowCasterList* casterList,
Real farDistSquared)
{
mCasterList = casterList;
mIsLightInFrustum = lightInFrustum;
mLightClipVolumeList = lightClipVolumes;
mCamera = cam;
mLight = light;
mFarDistSquared = farDistSquared;
}
bool queryResult(MovableObject* object);
bool queryResult(SceneQuery::WorldFragment* fragment);
};
ShadowCasterSceneQueryListener* mShadowCasterQueryListener;
/** Internal method for locating a list of shadow casters which
could be affecting the frustum for a given light.
@remarks
Custom scene managers are encouraged to override this method to add optimisations,
and to add their own custom shadow casters (perhaps for world geometry)
*/
virtual const ShadowCasterList& findShadowCastersForLight(const Light* light,
const Camera* camera);
/** Render a group in the ordinary way */
virtual void renderBasicQueueGroupObjects(RenderQueueGroup* pGroup,
QueuedRenderableCollection::OrganisationMode om);
/** Render a group with the added complexity of additive stencil shadows. */
virtual void renderAdditiveStencilShadowedQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Render a group with the added complexity of modulative stencil shadows. */
virtual void renderModulativeStencilShadowedQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Render a group rendering only shadow casters. */
virtual void renderTextureShadowCasterQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Render a group rendering only shadow receivers. */
virtual void renderTextureShadowReceiverQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Render a group with the added complexity of modulative texture shadows. */
virtual void renderModulativeTextureShadowedQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Render a group with additive texture shadows. */
virtual void renderAdditiveTextureShadowedQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Render a set of objects, see renderSingleObject for param definitions */
virtual void renderObjects(const QueuedRenderableCollection& objs,
QueuedRenderableCollection::OrganisationMode om, bool lightScissoringClipping,
bool doLightIteration, const LightList* manualLightList = 0);
/** Render those objects in the transparent pass list which have shadow casting forced on
@remarks
This function is intended to be used to render the shadows of transparent objects which have
transparency_casts_shadows set to 'on' in their material
*/
virtual void renderTransparentShadowCasterObjects(const QueuedRenderableCollection& objs,
QueuedRenderableCollection::OrganisationMode om, bool lightScissoringClipping,
bool doLightIteration, const LightList* manualLightList = 0);
/** Update the state of the global render queue splitting based on a shadow
option change. */
virtual void updateRenderQueueSplitOptions(void);
/** Update the state of the render queue group splitting based on a shadow
option change. */
virtual void updateRenderQueueGroupSplitOptions(RenderQueueGroup* group,
bool suppressShadows, bool suppressRenderState);
/// Set up a scissor rectangle from a group of lights
virtual ClipResult buildAndSetScissor(const LightList& ll, const Camera* cam);
/// Update a scissor rectangle from a single light
virtual void buildScissor(const Light* l, const Camera* cam, RealRect& rect);
virtual void resetScissor();
/// Build a set of user clip planes from a single non-directional light
virtual ClipResult buildAndSetLightClip(const LightList& ll);
virtual void buildLightClip(const Light* l, PlaneList& planes);
virtual void resetLightClip();
virtual void checkCachedLightClippingInfo();
/// The active renderable visitor class - subclasses could override this
SceneMgrQueuedRenderableVisitor* mActiveQueuedRenderableVisitor;
/// Storage for default renderable visitor
SceneMgrQueuedRenderableVisitor mDefaultQueuedRenderableVisitor;
/// Whether to use camera-relative rendering
bool mCameraRelativeRendering;
Matrix4 mCachedViewMatrix;
Vector3 mCameraRelativePosition;
/// Last light sets
uint32 mLastLightHash;
unsigned short mLastLightLimit;
uint32 mLastLightHashGpuProgram;
/// Gpu params that need rebinding (mask of GpuParamVariability)
uint16 mGpuParamsDirty;
virtual void useLights(const LightList& lights, unsigned short limit);
virtual void setViewMatrix(const Matrix4& m);
virtual void useLightsGpuProgram(const Pass* pass, const LightList* lights);
virtual void bindGpuProgram(GpuProgram* prog);
virtual void updateGpuProgramParameters(const Pass* p);
/// Set of registered LOD listeners
typedef set<LodListener*>::type LodListenerSet;
LodListenerSet mLodListeners;
/// List of movable object LOD changed events
typedef vector<MovableObjectLodChangedEvent>::type MovableObjectLodChangedEventList;
MovableObjectLodChangedEventList mMovableObjectLodChangedEvents;
/// List of entity mesh LOD changed events
typedef vector<EntityMeshLodChangedEvent>::type EntityMeshLodChangedEventList;
EntityMeshLodChangedEventList mEntityMeshLodChangedEvents;
/// List of entity material LOD changed events
typedef vector<EntityMaterialLodChangedEvent>::type EntityMaterialLodChangedEventList;
EntityMaterialLodChangedEventList mEntityMaterialLodChangedEvents;
public:
/** Constructor.
*/
SceneManager(const String& instanceName);
/** Default destructor.
*/
virtual ~SceneManager();
/** Mutex to protect the scene graph from simultaneous access from
multiple threads.
@remarks
If you are updating the scene in a separate thread from the rendering
thread, then you should lock this mutex before making any changes to
the scene graph - that means creating, modifying or deleting a
scene node, or attaching / detaching objects. It is <b>your</b>
responsibility to take out this lock, the detail methods on the nodes
will not do it for you (for the reasons discussed below).
@par
Note that locking this mutex will prevent the scene being rendered until
it is unlocked again. Therefore you should do this sparingly. Try
to create any objects you need separately and fully prepare them
before doing all your scene graph work in one go, thus keeping this
lock for the shortest time possible.
@note
A single global lock is used rather than a per-node lock since
it keeps the number of locks required during rendering down to a
minimum. Obtaining a lock, even if there is no contention, is not free
so for performance it is good to do it as little as possible.
Since modifying the scene in a separate thread is a fairly
rare occurrence (relative to rendering), it is better to keep the
locking required during rendering lower than to make update locks
more granular.
*/
OGRE_MUTEX(sceneGraphMutex);
/** Return the instance name of this SceneManager. */
const String& getName(void) const { return mName; }
/** Retrieve the type name of this scene manager.
@remarks
This method has to be implemented by subclasses. It should
return the type name of this SceneManager which agrees with
the type name of the SceneManagerFactory which created it.
*/
virtual const String& getTypeName(void) const = 0;
/** Creates a camera to be managed by this scene manager.
@remarks
This camera must be added to the scene at a later time using
the attachObject method of the SceneNode class.
@param
name Name to give the new camera.
*/
virtual Camera* createCamera(const String& name);
/** Retrieves a pointer to the named camera.
@note Throws an exception if the named instance does not exist
*/
virtual Camera* getCamera(const String& name) const;
/** Returns whether a camera with the given name exists.
*/
virtual bool hasCamera(const String& name) const;
/** Removes a camera from the scene.
@remarks
This method removes a previously added camera from the scene.
The camera is deleted so the caller must ensure no references
to it's previous instance (e.g. in a SceneNode) are used.
@param
cam Pointer to the camera to remove
*/
virtual void destroyCamera(Camera *cam);
/** Removes a camera from the scene.
@remarks
This method removes an camera from the scene based on the
camera's name rather than a pointer.
*/
virtual void destroyCamera(const String& name);
/** Removes (and destroys) all cameras from the scene.
@remarks
Some cameras are internal created to dealing with texture shadow,
their aren't supposed to destroy outside. So, while you are using
texture shadow, don't call this method, or you can set the shadow
technique other than texture-based, which will destroy all internal
created shadow cameras and textures.
*/
virtual void destroyAllCameras(void);
/** Creates a light for use in the scene.
@remarks
Lights can either be in a fixed position and independent of the
scene graph, or they can be attached to SceneNodes so they derive
their position from the parent node. Either way, they are created
using this method so that the SceneManager manages their
existence.
@param
name The name of the new light, to identify it later.
*/
virtual Light* createLight(const String& name);
/** Creates a light with a generated name. */
virtual Light* createLight();
/** Returns a pointer to the named Light which has previously been added to the scene.
@note Throws an exception if the named instance does not exist
*/
virtual Light* getLight(const String& name) const;
/** Returns whether a light with the given name exists.
*/
virtual bool hasLight(const String& name) const;
/** Retrieve a set of clipping planes for a given light.
*/
virtual const PlaneList& getLightClippingPlanes(Light* l);
/** Retrieve a scissor rectangle for a given light and camera.
*/
virtual const RealRect& getLightScissorRect(Light* l, const Camera* cam);
/** Removes the named light from the scene and destroys it.
@remarks
Any pointers held to this light after calling this method will be invalid.
*/
virtual void destroyLight(const String& name);
/** Removes the light from the scene and destroys it based on a pointer.
@remarks
Any pointers held to this light after calling this method will be invalid.
*/
virtual void destroyLight(Light* light);
/** Removes and destroys all lights in the scene.
*/
virtual void destroyAllLights(void);
/** Advance method to increase the lights dirty counter due lights changed.
@remarks
Scene manager tracking lights that affecting the frustum, if changes
detected (the changes includes light list itself and the light's position
and attenuation range), then increase the lights dirty counter.
@par
For some reason, you can call this method to force whole scene objects
re-populate their light list. But near in mind, call to this method
will harm performance, so should avoid if possible.
*/
virtual void _notifyLightsDirty(void);
/** Advance method to gets the lights dirty counter.
@remarks
Scene manager tracking lights that affecting the frustum, if changes
detected (the changes includes light list itself and the light's position
and attenuation range), then increase the lights dirty counter.
@par
When implementing customise lights finding algorithm relied on either
SceneManager::_getLightsAffectingFrustum or SceneManager::_populateLightList,
might check this value for sure that the light list are really need to
re-populate, otherwise, returns cached light list (if exists) for better
performance.
*/
ulong _getLightsDirtyCounter(void) const { return mLightsDirtyCounter; }
/** Get the list of lights which could be affecting the frustum.
@remarks
Note that default implementation of this method returns a cached light list,
which is populated when rendering the scene. So by default the list of lights
is only available during scene rendering.
*/
virtual const LightList& _getLightsAffectingFrustum(void) const;
/** Populate a light list with an ordered set of the lights which are closest
to the position specified.
@remarks
Note that since directional lights have no position, they are always considered
closer than any point lights and as such will always take precedence.
@par
Subclasses of the default SceneManager may wish to take into account other issues
such as possible visibility of the light if that information is included in their
data structures. This basic scenemanager simply orders by distance, eliminating
those lights which are out of range or could not be affecting the frustum (i.e.
only the lights returned by SceneManager::_getLightsAffectingFrustum are take into
account).
@par
The number of items in the list max exceed the maximum number of lights supported
by the renderer, but the extraneous ones will never be used. In fact the limit will
be imposed by Pass::getMaxSimultaneousLights.
@param position The position at which to evaluate the list of lights
@param radius The bounding radius to test
@param destList List to be populated with ordered set of lights; will be cleared by
this method before population.
@param lightMask The mask with which to include / exclude lights
*/
virtual void _populateLightList(const Vector3& position, Real radius, LightList& destList, uint32 lightMask = 0xFFFFFFFF);
/** Populates a light list with an ordered set of the lights which are closest
to the position of the SceneNode given.
@remarks
Note that since directional lights have no position, they are always considered
closer than any point lights and as such will always take precedence.
This overloaded version will take the SceneNode's position and use the second method
to populate the list.
@par
Subclasses of the default SceneManager may wish to take into account other issues
such as possible visibility of the light if that information is included in their
data structures. This basic scenemanager simply orders by distance, eliminating
those lights which are out of range or could not be affecting the frustum (i.e.
only the lights returned by SceneManager::_getLightsAffectingFrustum are take into
account).
@par
Also note that subclasses of the SceneNode might be used here to provide cached
scene related data, accelerating the list population (for example light lists for
SceneNodes could be cached inside subclassed SceneNode objects).
@par
The number of items in the list may exceed the maximum number of lights supported
by the renderer, but the extraneous ones will never be used. In fact the limit will
be imposed by Pass::getMaxSimultaneousLights.
@param sn The SceneNode for which to evaluate the list of lights
@param radius The bounding radius to test
@param destList List to be populated with ordered set of lights; will be cleared by
this method before population.
@param lightMask The mask with which to include / exclude lights
*/
virtual void _populateLightList(const SceneNode* sn, Real radius, LightList& destList, uint32 lightMask = 0xFFFFFFFF);
/** Creates an instance of a SceneNode.
@remarks
Note that this does not add the SceneNode to the scene hierarchy.
This method is for convenience, since it allows an instance to
be created for which the SceneManager is responsible for
allocating and releasing memory, which is convenient in complex
scenes.
@par
To include the returned SceneNode in the scene, use the addChild
method of the SceneNode which is to be it's parent.
@par
Note that this method takes no parameters, and the node created is unnamed (it is
actually given a generated name, which you can retrieve if you want).
If you wish to create a node with a specific name, call the alternative method
which takes a name parameter.
*/
virtual SceneNode* createSceneNode(void);
/** Creates an instance of a SceneNode with a given name.
@remarks
Note that this does not add the SceneNode to the scene hierarchy.
This method is for convenience, since it allows an instance to
be created for which the SceneManager is responsible for
allocating and releasing memory, which is convenient in complex
scenes.
@par
To include the returned SceneNode in the scene, use the addChild
method of the SceneNode which is to be it's parent.
@par
Note that this method takes a name parameter, which makes the node easier to
retrieve directly again later.
*/
virtual SceneNode* createSceneNode(const String& name);
/** Destroys a SceneNode with a given name.
@remarks
This allows you to physically delete an individual SceneNode if you want to.
Note that this is not normally recommended, it's better to allow SceneManager
to delete the nodes when the scene is cleared.
*/
virtual void destroySceneNode(const String& name);
/** Destroys a SceneNode.
@remarks
This allows you to physically delete an individual SceneNode if you want to.
Note that this is not normally recommended, it's better to allow SceneManager
to delete the nodes when the scene is cleared.
*/
virtual void destroySceneNode(SceneNode* sn);
/** Gets the SceneNode at the root of the scene hierarchy.
@remarks
The entire scene is held as a hierarchy of nodes, which
allows things like relative transforms, general changes in
rendering state etc (See the SceneNode class for more info).
In this basic SceneManager class, the application using
Ogre is free to structure this hierarchy however it likes,
since it has no real significance apart from making transforms
relative to each node (more specialised subclasses will
provide utility methods for building specific node structures
e.g. loading a BSP tree).
@par
However, in all cases there is only ever one root node of
the hierarchy, and this method returns a pointer to it.
*/
virtual SceneNode* getRootSceneNode(void);
/** Retrieves a named SceneNode from the scene graph.
@remarks
If you chose to name a SceneNode as you created it, or if you
happened to make a note of the generated name, you can look it
up wherever it is in the scene graph using this method.
@note Throws an exception if the named instance does not exist
*/
virtual SceneNode* getSceneNode(const String& name) const;
/** Returns whether a scene node with the given name exists.
*/
virtual bool hasSceneNode(const String& name) const;
/** Create an Entity (instance of a discrete mesh).
@param
entityName The name to be given to the entity (must be unique).
@param
meshName The name of the Mesh it is to be based on (e.g. 'knot.oof'). The
mesh will be loaded if it is not already.
*/
virtual Entity* createEntity(const String& entityName, const String& meshName, const String& groupName = ResourceGroupManager::AUTODETECT_RESOURCE_GROUP_NAME );
/** Create an Entity (instance of a discrete mesh).
@param
entityName The name to be given to the entity (must be unique).
@param
pMesh The pointer to the Mesh it is to be based on.
*/
virtual Entity* createEntity(const String& entityName, const MeshPtr& pMesh );
/** Create an Entity (instance of a discrete mesh) with an autogenerated name.
@param
meshName The name of the Mesh it is to be based on (e.g. 'knot.oof'). The
mesh will be loaded if it is not already.
*/
virtual Entity* createEntity(const String& meshName);
/** Create an Entity (instance of a discrete mesh) with an autogenerated name.
@param
pMesh The pointer to the Mesh it is to be based on.
*/
virtual Entity* createEntity(const MeshPtr& pMesh);
/** Prefab shapes available without loading a model.
@note
Minimal implementation at present.
@todo
Add more prefabs (teapots, teapots!!!)
*/
enum PrefabType {
PT_PLANE,
PT_CUBE,
PT_SPHERE
};
/** Create an Entity (instance of a discrete mesh) from a range of prefab shapes.
@param
entityName The name to be given to the entity (must be unique).
@param
ptype The prefab type.
*/
virtual Entity* createEntity(const String& entityName, PrefabType ptype);
/** Create an Entity (instance of a discrete mesh) from a range of prefab shapes, generating the name.
@param ptype The prefab type.
*/
virtual Entity* createEntity(PrefabType ptype);
/** Retrieves a pointer to the named Entity.
@note Throws an exception if the named instance does not exist
*/
virtual Entity* getEntity(const String& name) const;
/** Returns whether an entity with the given name exists.
*/
virtual bool hasEntity(const String& name) const;
/** Removes & destroys an Entity from the SceneManager.
@warning
Must only be done if the Entity is not attached
to a SceneNode. It may be safer to wait to clear the whole
scene if you are unsure use clearScene.
@see
SceneManager::clearScene
*/
virtual void destroyEntity(Entity* ent);
/** Removes & destroys an Entity from the SceneManager by name.
@warning
Must only be done if the Entity is not attached
to a SceneNode. It may be safer to wait to clear the whole
scene if you are unsure use clearScene.
@see
SceneManager::clearScene
*/
virtual void destroyEntity(const String& name);
/** Removes & destroys all Entities.
@warning
Again, use caution since no Entity must be referred to
elsewhere e.g. attached to a SceneNode otherwise a crash
is likely. Use clearScene if you are unsure (it clears SceneNode
entries too.)
@see
SceneManager::clearScene
*/
virtual void destroyAllEntities(void);
/** Create a ManualObject, an object which you populate with geometry
manually through a GL immediate-mode style interface.
@param
name The name to be given to the object (must be unique).
*/
virtual ManualObject* createManualObject(const String& name);
/** Create a ManualObject, an object which you populate with geometry
manually through a GL immediate-mode style interface, generating the name.
*/
virtual ManualObject* createManualObject();
/** Retrieves a pointer to the named ManualObject.
@note Throws an exception if the named instance does not exist
*/
virtual ManualObject* getManualObject(const String& name) const;
/** Returns whether a manual object with the given name exists.
*/
virtual bool hasManualObject(const String& name) const;
/** Removes & destroys a ManualObject from the SceneManager.
*/
virtual void destroyManualObject(ManualObject* obj);
/** Removes & destroys a ManualObject from the SceneManager.
*/
virtual void destroyManualObject(const String& name);
/** Removes & destroys all ManualObjects from the SceneManager.
*/
virtual void destroyAllManualObjects(void);
/** Create a BillboardChain, an object which you can use to render
a linked chain of billboards.
@param
name The name to be given to the object (must be unique).
*/
virtual BillboardChain* createBillboardChain(const String& name);
/** Create a BillboardChain, an object which you can use to render
a linked chain of billboards, with a generated name.
*/
virtual BillboardChain* createBillboardChain();
/** Retrieves a pointer to the named BillboardChain.
@note Throws an exception if the named instance does not exist
*/
virtual BillboardChain* getBillboardChain(const String& name) const;
/** Returns whether a billboard chain with the given name exists.
*/
virtual bool hasBillboardChain(const String& name) const;
/** Removes & destroys a BillboardChain from the SceneManager.
*/
virtual void destroyBillboardChain(BillboardChain* obj);
/** Removes & destroys a BillboardChain from the SceneManager.
*/
virtual void destroyBillboardChain(const String& name);
/** Removes & destroys all BillboardChains from the SceneManager.
*/
virtual void destroyAllBillboardChains(void);
/** Create a RibbonTrail, an object which you can use to render
a linked chain of billboards which follows one or more nodes.
@param
name The name to be given to the object (must be unique).
*/
virtual RibbonTrail* createRibbonTrail(const String& name);
/** Create a RibbonTrail, an object which you can use to render
a linked chain of billboards which follows one or more nodes, generating the name.
*/
virtual RibbonTrail* createRibbonTrail();
/** Retrieves a pointer to the named RibbonTrail.
@note Throws an exception if the named instance does not exist
*/
virtual RibbonTrail* getRibbonTrail(const String& name) const;
/** Returns whether a ribbon trail with the given name exists.
*/
virtual bool hasRibbonTrail(const String& name) const;
/** Removes & destroys a RibbonTrail from the SceneManager.
*/
virtual void destroyRibbonTrail(RibbonTrail* obj);
/** Removes & destroys a RibbonTrail from the SceneManager.
*/
virtual void destroyRibbonTrail(const String& name);
/** Removes & destroys all RibbonTrails from the SceneManager.
*/
virtual void destroyAllRibbonTrails(void);
/** Creates a particle system based on a template.
@remarks
This method creates a new ParticleSystem instance based on the named template
(defined through ParticleSystemManager::createTemplate) and returns a
pointer to the caller. The caller should not delete this object, it will be freed at system shutdown,
or can be released earlier using the destroyParticleSystem method.
@par
Each system created from a template takes the template's settings at the time of creation,
but is completely separate from the template from there on.
@par
Creating a particle system does not make it a part of the scene. As with other MovableObject
subclasses, a ParticleSystem is not rendered until it is attached to a SceneNode.
@par
This is probably the more useful particle system creation method since it does not require manual
setup of the system. Note that the initial quota is based on the template but may be changed later.
@param
name The name to give the new particle system instance.
@param
templateName The name of the template to base the new instance on.
*/
virtual ParticleSystem* createParticleSystem(const String& name,
const String& templateName);
/** Create a blank particle system.
@remarks
This method creates a new, blank ParticleSystem instance and returns a pointer to it.
The caller should not delete this object, it will be freed at system shutdown, or can
be released earlier using the destroyParticleSystem method.
@par
The instance returned from this method won't actually do anything because on creation a
particle system has no emitters. The caller should manipulate the instance through it's
ParticleSystem methods to actually create a real particle effect.
@par
Creating a particle system does not make it a part of the scene. As with other MovableObject
subclasses, a ParticleSystem is not rendered until it is attached to a SceneNode.
@param
name The name to give the ParticleSystem.
@param
quota The maximum number of particles to allow in this system.
@param
resourceGroup The resource group which will be used to load dependent resources
*/
virtual ParticleSystem* createParticleSystem(const String& name,
size_t quota = 500,
const String& resourceGroup = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Create a blank particle system with a generated name.
@remarks
This method creates a new, blank ParticleSystem instance and returns a pointer to it.
The caller should not delete this object, it will be freed at system shutdown, or can
be released earlier using the destroyParticleSystem method.
@par
The instance returned from this method won't actually do anything because on creation a
particle system has no emitters. The caller should manipulate the instance through it's
ParticleSystem methods to actually create a real particle effect.
@par
Creating a particle system does not make it a part of the scene. As with other MovableObject
subclasses, a ParticleSystem is not rendered until it is attached to a SceneNode.
@param
quota The maximum number of particles to allow in this system.
@param
resourceGroup The resource group which will be used to load dependent resources
*/
virtual ParticleSystem* createParticleSystem(size_t quota = 500,
const String& resourceGroup = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Retrieves a pointer to the named ParticleSystem.
@note Throws an exception if the named instance does not exist
*/
virtual ParticleSystem* getParticleSystem(const String& name) const;
/** Returns whether a particle system with the given name exists.
*/
virtual bool hasParticleSystem(const String& name) const;
/** Removes & destroys a ParticleSystem from the SceneManager.
*/
virtual void destroyParticleSystem(ParticleSystem* obj);
/** Removes & destroys a ParticleSystem from the SceneManager.
*/
virtual void destroyParticleSystem(const String& name);
/** Removes & destroys all ParticleSystems from the SceneManager.
*/
virtual void destroyAllParticleSystems(void);
/** Empties the entire scene, inluding all SceneNodes, Entities, Lights,
BillboardSets etc. Cameras are not deleted at this stage since
they are still referenced by viewports, which are not destroyed during
this process.
*/
virtual void clearScene(void);
/** Sets the ambient light level to be used for the scene.
@remarks
This sets the colour and intensity of the ambient light in the scene, i.e. the
light which is 'sourceless' and illuminates all objects equally.
The colour of an object is affected by a combination of the light in the scene,
and the amount of light that object reflects (in this case based on the Material::ambient
property).
@remarks
By default the ambient light in the scene is ColourValue::Black, i.e. no ambient light. This
means that any objects rendered with a Material which has lighting enabled (see Material::setLightingEnabled)
will not be visible unless you have some dynamic lights in your scene.
*/
void setAmbientLight(const ColourValue& colour);
/** Returns the ambient light level to be used for the scene.
*/
const ColourValue& getAmbientLight(void) const;
/** Sets the source of the 'world' geometry, i.e. the large, mainly static geometry
making up the world e.g. rooms, landscape etc.
This function can be called before setWorldGeometry in a background thread, do to
some slow tasks (e.g. IO) that do not involve the backend render system.
@remarks
Depending on the type of SceneManager (subclasses will be specialised
for particular world geometry types) you have requested via the Root or
SceneManagerEnumerator classes, you can pass a filename to this method and it
will attempt to load the world-level geometry for use. If you try to load
an inappropriate type of world data an exception will be thrown. The default
SceneManager cannot handle any sort of world geometry and so will always
throw an exception. However subclasses like BspSceneManager can load
particular types of world geometry e.g. "q3dm1.bsp".
*/
virtual void prepareWorldGeometry(const String& filename);
/** Sets the source of the 'world' geometry, i.e. the large, mainly
static geometry making up the world e.g. rooms, landscape etc.
This function can be called before setWorldGeometry in a background thread, do to
some slow tasks (e.g. IO) that do not involve the backend render system.
@remarks
Depending on the type of SceneManager (subclasses will be
specialised for particular world geometry types) you have
requested via the Root or SceneManagerEnumerator classes, you
can pass a stream to this method and it will attempt to load
the world-level geometry for use. If the manager can only
handle one input format the typeName parameter is not required.
The stream passed will be read (and it's state updated).
@param stream Data stream containing data to load
@param typeName String identifying the type of world geometry
contained in the stream - not required if this manager only
supports one type of world geometry.
*/
virtual void prepareWorldGeometry(DataStreamPtr& stream,
const String& typeName = StringUtil::BLANK);
/** Sets the source of the 'world' geometry, i.e. the large, mainly static geometry
making up the world e.g. rooms, landscape etc.
@remarks
Depending on the type of SceneManager (subclasses will be specialised
for particular world geometry types) you have requested via the Root or
SceneManagerEnumerator classes, you can pass a filename to this method and it
will attempt to load the world-level geometry for use. If you try to load
an inappropriate type of world data an exception will be thrown. The default
SceneManager cannot handle any sort of world geometry and so will always
throw an exception. However subclasses like BspSceneManager can load
particular types of world geometry e.g. "q3dm1.bsp".
*/
virtual void setWorldGeometry(const String& filename);
/** Sets the source of the 'world' geometry, i.e. the large, mainly
static geometry making up the world e.g. rooms, landscape etc.
@remarks
Depending on the type of SceneManager (subclasses will be
specialised for particular world geometry types) you have
requested via the Root or SceneManagerEnumerator classes, you
can pass a stream to this method and it will attempt to load
the world-level geometry for use. If the manager can only
handle one input format the typeName parameter is not required.
The stream passed will be read (and it's state updated).
@param stream Data stream containing data to load
@param typeName String identifying the type of world geometry
contained in the stream - not required if this manager only
supports one type of world geometry.
*/
virtual void setWorldGeometry(DataStreamPtr& stream,
const String& typeName = StringUtil::BLANK);
/** Estimate the number of loading stages required to load the named
world geometry.
@remarks
This method should be overridden by SceneManagers that provide
custom world geometry that can take some time to load. They should
return from this method a count of the number of stages of progress
they can report on whilst loading. During real loading (setWorldGeometry),
they should call ResourceGroupManager::_notifyWorldGeometryProgress exactly
that number of times when loading the geometry for real.
@note
The default is to return 0, ie to not report progress.
*/
virtual size_t estimateWorldGeometry(const String& filename)
{ (void)filename; return 0; }
/** Estimate the number of loading stages required to load the named
world geometry.
@remarks
Operates just like the version of this method which takes a
filename, but operates on a stream instead. Note that since the
stream is updated, you'll need to reset the stream or reopen it
when it comes to loading it for real.
@param stream Data stream containing data to load
@param typeName String identifying the type of world geometry
contained in the stream - not required if this manager only
supports one type of world geometry.
*/
virtual size_t estimateWorldGeometry(DataStreamPtr& stream,
const String& typeName = StringUtil::BLANK)
{ (void)stream; (void)typeName; return 0; }
/** Asks the SceneManager to provide a suggested viewpoint from which the scene should be viewed.
@remarks
Typically this method returns the origin unless a) world geometry has been loaded using
SceneManager::setWorldGeometry and b) that world geometry has suggested 'start' points.
If there is more than one viewpoint which the scene manager can suggest, it will always suggest
the first one unless the random parameter is true.
@param
random If true, and there is more than one possible suggestion, a random one will be used. If false
the same one will always be suggested.
@return
On success, true is returned.
@par
On failure, false is returned.
*/
virtual ViewPoint getSuggestedViewpoint(bool random = false);
/** Method for setting a specific option of the Scene Manager. These options are usually
specific for a certain implemntation of the Scene Manager class, and may (and probably
will) not exist across different implementations.
@param
strKey The name of the option to set
@param
pValue A pointer to the value - the size should be calculated by the scene manager
based on the key
@return
On success, true is returned.
@par
On failure, false is returned.
*/
virtual bool setOption( const String& strKey, const void* pValue )
{ (void)strKey; (void)pValue; return false; }
/** Method for getting the value of an implementation-specific Scene Manager option.
@param
strKey The name of the option
@param
pDestValue A pointer to a memory location where the value will
be copied. Currently, the memory will be allocated by the
scene manager, but this may change
@return
On success, true is returned and pDestValue points to the value of the given
option.
@par
On failure, false is returned and pDestValue is set to NULL.
*/
virtual bool getOption( const String& strKey, void* pDestValue )
{ (void)strKey; (void)pDestValue; return false; }
/** Method for verifying whether the scene manager has an implementation-specific
option.
@param
strKey The name of the option to check for.
@return
If the scene manager contains the given option, true is returned.
@remarks
If it does not, false is returned.
*/
virtual bool hasOption( const String& strKey ) const
{ (void)strKey; return false; }
/** Method for getting all possible values for a specific option. When this list is too large
(i.e. the option expects, for example, a float), the return value will be true, but the
list will contain just one element whose size will be set to 0.
Otherwise, the list will be filled with all the possible values the option can
accept.
@param
strKey The name of the option to get the values for.
@param
refValueList A reference to a list that will be filled with the available values.
@return
On success (the option exists), true is returned.
@par
On failure, false is returned.
*/
virtual bool getOptionValues( const String& strKey, StringVector& refValueList )
{ (void)strKey; (void)refValueList; return false; }
/** Method for getting all the implementation-specific options of the scene manager.
@param
refKeys A reference to a list that will be filled with all the available options.
@return
On success, true is returned. On failure, false is returned.
*/
virtual bool getOptionKeys( StringVector& refKeys )
{ (void)refKeys; return false; }
/** Internal method for updating the scene graph ie the tree of SceneNode instances managed by this class.
@remarks
This must be done before issuing objects to the rendering pipeline, since derived transformations from
parent nodes are not updated until required. This SceneManager is a basic implementation which simply
updates all nodes from the root. This ensures the scene is up to date but requires all the nodes
to be updated even if they are not visible. Subclasses could trim this such that only potentially visible
nodes are updated.
*/
virtual void _updateSceneGraph(Camera* cam);
/** Internal method which parses the scene to find visible objects to render.
@remarks
If you're implementing a custom scene manager, this is the most important method to
override since it's here you can apply your custom world partitioning scheme. Once you
have added the appropriate objects to the render queue, you can let the default
SceneManager objects _renderVisibleObjects handle the actual rendering of the objects
you pick.
@par
Any visible objects will be added to a rendering queue, which is indexed by material in order
to ensure objects with the same material are rendered together to minimise render state changes.
*/
virtual void _findVisibleObjects(Camera* cam, VisibleObjectsBoundsInfo* visibleBounds, bool onlyShadowCasters);
/** Internal method for applying animations to scene nodes.
@remarks
Uses the internally stored AnimationState objects to apply animation to SceneNodes.
*/
virtual void _applySceneAnimations(void);
/** Sends visible objects found in _findVisibleObjects to the rendering engine.
*/
virtual void _renderVisibleObjects(void);
/** Prompts the class to send its contents to the renderer.
@remarks
This method prompts the scene manager to send the
contents of the scene it manages to the rendering
pipeline, possibly preceded by some sorting, culling
or other scene management tasks. Note that this method is not normally called
directly by the user application; it is called automatically
by the Ogre rendering loop.
@param camera Pointer to a camera from whose viewpoint the scene is to
be rendered.
@param vp The target viewport
@param includeOverlays Whether or not overlay objects should be rendered
*/
virtual void _renderScene(Camera* camera, Viewport* vp, bool includeOverlays);
/** Internal method for queueing the sky objects with the params as
previously set through setSkyBox, setSkyPlane and setSkyDome.
*/
virtual void _queueSkiesForRendering(Camera* cam);
/** Notifies the scene manager of its destination render system
@remarks
Called automatically by RenderSystem::addSceneManager
this method simply notifies the manager of the render
system to which its output must be directed.
@param
sys Pointer to the RenderSystem subclass to be used as a render target.
*/
virtual void _setDestinationRenderSystem(RenderSystem* sys);
/** Enables / disables a 'sky plane' i.e. a plane at constant
distance from the camera representing the sky.
@remarks
You can create sky planes yourself using the standard mesh and
entity methods, but this creates a plane which the camera can
never get closer or further away from - it moves with the camera.
(NB you could create this effect by creating a world plane which
was attached to the same SceneNode as the Camera too, but this
would only apply to a single camera whereas this plane applies to
any camera using this scene manager).
@note
To apply scaling, scrolls etc to the sky texture(s) you
should use the TextureUnitState class methods.
@param
enable True to enable the plane, false to disable it
@param
plane Details of the plane, i.e. it's normal and it's
distance from the camera.
@param
materialName The name of the material the plane will use
@param
scale The scaling applied to the sky plane - higher values
mean a bigger sky plane - you may want to tweak this
depending on the size of plane.d and the other
characteristics of your scene
@param
tiling How many times to tile the texture across the sky.
Applies to all texture layers. If you need finer control use
the TextureUnitState texture coordinate transformation methods.
@param
drawFirst If true, the plane is drawn before all other
geometry in the scene, without updating the depth buffer.
This is the safest rendering method since all other objects
will always appear in front of the sky. However this is not
the most efficient way if most of the sky is often occluded
by other objects. If this is the case, you can set this
parameter to false meaning it draws <em>after</em> all other
geometry which can be an optimisation - however you must
ensure that the plane.d value is large enough that no objects
will 'poke through' the sky plane when it is rendered.
@param
bow If zero, the plane will be completely flat (like previous
versions. If above zero, the plane will be curved, allowing
the sky to appear below camera level. Curved sky planes are
simular to skydomes, but are more compatible with fog.
@param xsegments, ysegments
Determines the number of segments the plane will have to it. This
is most important when you are bowing the plane, but may also be useful
if you need tesselation on the plane to perform per-vertex effects.
@param groupName
The name of the resource group to which to assign the plane mesh.
*/
virtual void setSkyPlane(
bool enable,
const Plane& plane, const String& materialName, Real scale = 1000,
Real tiling = 10, bool drawFirst = true, Real bow = 0,
int xsegments = 1, int ysegments = 1,
const String& groupName = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Enables / disables a 'sky plane' i.e. a plane at constant
distance from the camera representing the sky.
@remarks
You can create sky planes yourself using the standard mesh and
entity methods, but this creates a plane which the camera can
never get closer or further away from - it moves with the camera.
(NB you could create this effect by creating a world plane which
was attached to the same SceneNode as the Camera too, but this
would only apply to a single camera whereas this plane applies to
any camera using this scene manager).
@note
To apply scaling, scrolls etc to the sky texture(s) you
should use the TextureUnitState class methods.
@param
enable True to enable the plane, false to disable it
@param
plane Details of the plane, i.e. it's normal and it's
distance from the camera.
@param
materialName The name of the material the plane will use
@param
scale The scaling applied to the sky plane - higher values
mean a bigger sky plane - you may want to tweak this
depending on the size of plane.d and the other
characteristics of your scene
@param
tiling How many times to tile the texture across the sky.
Applies to all texture layers. If you need finer control use
the TextureUnitState texture coordinate transformation methods.
@param
renderQueue The render queue to use when rendering this object
@param
bow If zero, the plane will be completely flat (like previous
versions. If above zero, the plane will be curved, allowing
the sky to appear below camera level. Curved sky planes are
simular to skydomes, but are more compatible with fog.
@param xsegments, ysegments
Determines the number of segments the plane will have to it. This
is most important when you are bowing the plane, but may also be useful
if you need tesselation on the plane to perform per-vertex effects.
@param groupName
The name of the resource group to which to assign the plane mesh.
*/
virtual void _setSkyPlane(
bool enable,
const Plane& plane, const String& materialName, Real scale = 1000,
Real tiling = 10, uint8 renderQueue = RENDER_QUEUE_SKIES_EARLY, Real bow = 0,
int xsegments = 1, int ysegments = 1,
const String& groupName = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Enables / disables a 'sky plane' */
virtual void setSkyPlaneEnabled(bool enable) { mSkyPlaneEnabled = enable; }
/** Return whether a key plane is enabled */
virtual bool isSkyPlaneEnabled(void) const { return mSkyPlaneEnabled; }
/** Get the sky plane node, if enabled. */
virtual SceneNode* getSkyPlaneNode(void) const { return mSkyPlaneNode; }
/** Get the parameters used to construct the SkyPlane, if any **/
virtual const SkyPlaneGenParameters& getSkyPlaneGenParameters(void) const { return mSkyPlaneGenParameters; }
/** Enables / disables a 'sky box' i.e. a 6-sided box at constant
distance from the camera representing the sky.
@remarks
You could create a sky box yourself using the standard mesh and
entity methods, but this creates a plane which the camera can
never get closer or further away from - it moves with the camera.
(NB you could create this effect by creating a world box which
was attached to the same SceneNode as the Camera too, but this
would only apply to a single camera whereas this skybox applies
to any camera using this scene manager).
@par
The material you use for the skybox can either contain layers
which are single textures, or they can be cubic textures, i.e.
made up of 6 images, one for each plane of the cube. See the
TextureUnitState class for more information.
@param
enable True to enable the skybox, false to disable it
@param
materialName The name of the material the box will use
@param
distance Distance in world coorinates from the camera to
each plane of the box. The default is normally OK.
@param
drawFirst If true, the box is drawn before all other
geometry in the scene, without updating the depth buffer.
This is the safest rendering method since all other objects
will always appear in front of the sky. However this is not
the most efficient way if most of the sky is often occluded
by other objects. If this is the case, you can set this
parameter to false meaning it draws <em>after</em> all other
geometry which can be an optimisation - however you must
ensure that the distance value is large enough that no
objects will 'poke through' the sky box when it is rendered.
@param
orientation Optional parameter to specify the orientation
of the box. By default the 'top' of the box is deemed to be
in the +y direction, and the 'front' at the -z direction.
You can use this parameter to rotate the sky if you want.
@param groupName
The name of the resource group to which to assign the plane mesh.
*/
virtual void setSkyBox(
bool enable, const String& materialName, Real distance = 5000,
bool drawFirst = true, const Quaternion& orientation = Quaternion::IDENTITY,
const String& groupName = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Enables / disables a 'sky box' i.e. a 6-sided box at constant
distance from the camera representing the sky.
@remarks
You could create a sky box yourself using the standard mesh and
entity methods, but this creates a plane which the camera can
never get closer or further away from - it moves with the camera.
(NB you could create this effect by creating a world box which
was attached to the same SceneNode as the Camera too, but this
would only apply to a single camera whereas this skybox applies
to any camera using this scene manager).
@par
The material you use for the skybox can either contain layers
which are single textures, or they can be cubic textures, i.e.
made up of 6 images, one for each plane of the cube. See the
TextureUnitState class for more information.
@param
enable True to enable the skybox, false to disable it
@param
materialName The name of the material the box will use
@param
distance Distance in world coorinates from the camera to
each plane of the box. The default is normally OK.
@param
renderQueue The render queue to use when rendering this object
@param
orientation Optional parameter to specify the orientation
of the box. By default the 'top' of the box is deemed to be
in the +y direction, and the 'front' at the -z direction.
You can use this parameter to rotate the sky if you want.
@param groupName
The name of the resource group to which to assign the plane mesh.
*/
virtual void _setSkyBox(
bool enable, const String& materialName, Real distance = 5000,
uint8 renderQueue = RENDER_QUEUE_SKIES_EARLY, const Quaternion& orientation = Quaternion::IDENTITY,
const String& groupName = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Enables / disables a 'sky box' */
virtual void setSkyBoxEnabled(bool enable) { mSkyBoxEnabled = enable; }
/** Return whether a skybox is enabled */
virtual bool isSkyBoxEnabled(void) const { return mSkyBoxEnabled; }
/** Get the skybox node, if enabled. */
virtual SceneNode* getSkyBoxNode(void) const { return mSkyBoxNode; }
/** Get the parameters used to generate the current SkyBox, if any */
virtual const SkyBoxGenParameters& getSkyBoxGenParameters(void) const { return mSkyBoxGenParameters; }
/** Enables / disables a 'sky dome' i.e. an illusion of a curved sky.
@remarks
A sky dome is actually formed by 5 sides of a cube, but with
texture coordinates generated such that the surface appears
curved like a dome. Sky domes are appropriate where you need a
realistic looking sky where the scene is not going to be
'fogged', and there is always a 'floor' of some sort to prevent
the viewer looking below the horizon (the distortion effect below
the horizon can be pretty horrible, and there is never anyhting
directly below the viewer). If you need a complete wrap-around
background, use the setSkyBox method instead. You can actually
combine a sky box and a sky dome if you want, to give a positional
backdrop with an overlayed curved cloud layer.
@par
Sky domes work well with 2D repeating textures like clouds. You
can change the apparent 'curvature' of the sky depending on how
your scene is viewed - lower curvatures are better for 'open'
scenes like landscapes, whilst higher curvatures are better for
say FPS levels where you don't see a lot of the sky at once and
the exaggerated curve looks good.
@param
enable True to enable the skydome, false to disable it
@param
materialName The name of the material the dome will use
@param
curvature The curvature of the dome. Good values are
between 2 and 65. Higher values are more curved leading to
a smoother effect, lower values are less curved meaning
more distortion at the horizons but a better distance effect.
@param
tiling How many times to tile the texture(s) across the
dome.
@param
distance Distance in world coorinates from the camera to
each plane of the box the dome is rendered on. The default
is normally OK.
@param
drawFirst If true, the dome is drawn before all other
geometry in the scene, without updating the depth buffer.
This is the safest rendering method since all other objects
will always appear in front of the sky. However this is not
the most efficient way if most of the sky is often occluded
by other objects. If this is the case, you can set this
parameter to false meaning it draws <em>after</em> all other
geometry which can be an optimisation - however you must
ensure that the distance value is large enough that no
objects will 'poke through' the sky when it is rendered.
@param
orientation Optional parameter to specify the orientation
of the dome. By default the 'top' of the dome is deemed to
be in the +y direction, and the 'front' at the -z direction.
You can use this parameter to rotate the sky if you want.
@param groupName
The name of the resource group to which to assign the plane mesh.
*/
virtual void setSkyDome(
bool enable, const String& materialName, Real curvature = 10,
Real tiling = 8, Real distance = 4000, bool drawFirst = true,
const Quaternion& orientation = Quaternion::IDENTITY,
int xsegments = 16, int ysegments = 16, int ysegments_keep = -1,
const String& groupName = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Enables / disables a 'sky dome' i.e. an illusion of a curved sky.
@remarks
A sky dome is actually formed by 5 sides of a cube, but with
texture coordinates generated such that the surface appears
curved like a dome. Sky domes are appropriate where you need a
realistic looking sky where the scene is not going to be
'fogged', and there is always a 'floor' of some sort to prevent
the viewer looking below the horizon (the distortion effect below
the horizon can be pretty horrible, and there is never anyhting
directly below the viewer). If you need a complete wrap-around
background, use the setSkyBox method instead. You can actually
combine a sky box and a sky dome if you want, to give a positional
backdrop with an overlayed curved cloud layer.
@par
Sky domes work well with 2D repeating textures like clouds. You
can change the apparent 'curvature' of the sky depending on how
your scene is viewed - lower curvatures are better for 'open'
scenes like landscapes, whilst higher curvatures are better for
say FPS levels where you don't see a lot of the sky at once and
the exaggerated curve looks good.
@param
enable True to enable the skydome, false to disable it
@param
materialName The name of the material the dome will use
@param
curvature The curvature of the dome. Good values are
between 2 and 65. Higher values are more curved leading to
a smoother effect, lower values are less curved meaning
more distortion at the horizons but a better distance effect.
@param
tiling How many times to tile the texture(s) across the
dome.
@param
distance Distance in world coorinates from the camera to
each plane of the box the dome is rendered on. The default
is normally OK.
@param
renderQueue The render queue to use when rendering this object
@param
orientation Optional parameter to specify the orientation
of the dome. By default the 'top' of the dome is deemed to
be in the +y direction, and the 'front' at the -z direction.
You can use this parameter to rotate the sky if you want.
@param groupName
The name of the resource group to which to assign the plane mesh.
*/
virtual void _setSkyDome(
bool enable, const String& materialName, Real curvature = 10,
Real tiling = 8, Real distance = 4000, uint8 renderQueue = RENDER_QUEUE_SKIES_EARLY,
const Quaternion& orientation = Quaternion::IDENTITY,
int xsegments = 16, int ysegments = 16, int ysegments_keep = -1,
const String& groupName = ResourceGroupManager::DEFAULT_RESOURCE_GROUP_NAME);
/** Enables / disables a 'sky dome' */
virtual void setSkyDomeEnabled(bool enable) { mSkyDomeEnabled = enable; }
/** Return whether a skydome is enabled */
virtual bool isSkyDomeEnabled(void) const { return mSkyDomeEnabled; }
/** Get the sky dome node, if enabled. */
virtual SceneNode* getSkyDomeNode(void) const { return mSkyDomeNode; }
/** Get the parameters used to generate the current SkyDome, if any */
virtual const SkyDomeGenParameters& getSkyDomeGenParameters(void) const { return mSkyDomeGenParameters; }
/** Sets the fogging mode applied to the scene.
@remarks
This method sets up the scene-wide fogging effect. These settings
apply to all geometry rendered, UNLESS the material with which it
is rendered has it's own fog settings (see Material::setFog).
@param
mode Set up the mode of fog as described in the FogMode
enum, or set to FOG_NONE to turn off.
@param
colour The colour of the fog. Either set this to the same
as your viewport background colour, or to blend in with a
skydome or skybox.
@param
expDensity The density of the fog in FOG_EXP or FOG_EXP2
mode, as a value between 0 and 1. The default is 0.001.
@param
linearStart Distance in world units at which linear fog starts to
encroach. Only applicable if mode is
FOG_LINEAR.
@param
linearEnd Distance in world units at which linear fog becomes completely
opaque. Only applicable if mode is
FOG_LINEAR.
*/
void setFog(
FogMode mode = FOG_NONE, const ColourValue& colour = ColourValue::White,
Real expDensity = 0.001, Real linearStart = 0.0, Real linearEnd = 1.0);
/** Returns the fog mode for the scene.
*/
virtual FogMode getFogMode(void) const;
/** Returns the fog colour for the scene.
*/
virtual const ColourValue& getFogColour(void) const;
/** Returns the fog start distance for the scene.
*/
virtual Real getFogStart(void) const;
/** Returns the fog end distance for the scene.
*/
virtual Real getFogEnd(void) const;
/** Returns the fog density for the scene.
*/
virtual Real getFogDensity(void) const;
/** Creates a new BillboardSet for use with this scene manager.
@remarks
This method creates a new BillboardSet which is registered with
the SceneManager. The SceneManager will destroy this object when
it shuts down or when the SceneManager::clearScene method is
called, so the caller does not have to worry about destroying
this object (in fact, it definitely should not do this).
@par
See the BillboardSet documentations for full details of the
returned class.
@param
name The name to give to this billboard set. Must be unique.
@param
poolSize The initial size of the pool of billboards (see BillboardSet for more information)
@see
BillboardSet
*/
virtual BillboardSet* createBillboardSet(const String& name, unsigned int poolSize = 20);
/** Creates a new BillboardSet for use with this scene manager, with a generated name.
@param
poolSize The initial size of the pool of billboards (see BillboardSet for more information)
@see
BillboardSet
*/
virtual BillboardSet* createBillboardSet(unsigned int poolSize = 20);
/** Retrieves a pointer to the named BillboardSet.
@note Throws an exception if the named instance does not exist
*/
virtual BillboardSet* getBillboardSet(const String& name) const;
/** Returns whether a billboardset with the given name exists.
*/
virtual bool hasBillboardSet(const String& name) const;
/** Removes & destroys an BillboardSet from the SceneManager.
@warning
Must only be done if the BillboardSet is not attached
to a SceneNode. It may be safer to wait to clear the whole
scene. If you are unsure, use clearScene.
*/
virtual void destroyBillboardSet(BillboardSet* set);
/** Removes & destroys an BillboardSet from the SceneManager by name.
@warning
Must only be done if the BillboardSet is not attached
to a SceneNode. It may be safer to wait to clear the whole
scene. If you are unsure, use clearScene.
*/
virtual void destroyBillboardSet(const String& name);
/** Removes & destroys all BillboardSets.
@warning
Again, use caution since no BillboardSet must be referred to
elsewhere e.g. attached to a SceneNode otherwise a crash
is likely. Use clearScene if you are unsure (it clears SceneNode
entries too.)
@see
SceneManager::clearScene
*/
virtual void destroyAllBillboardSets(void);
/** Tells the SceneManager whether it should render the SceneNodes which
make up the scene as well as the objects in the scene.
@remarks
This method is mainly for debugging purposes. If you set this to 'true',
each node will be rendered as a set of 3 axes to allow you to easily see
the orientation of the nodes.
*/
virtual void setDisplaySceneNodes(bool display);
/** Returns true if all scene nodes axis are to be displayed */
virtual bool getDisplaySceneNodes(void) const {return mDisplayNodes;}
/** Creates an animation which can be used to animate scene nodes.
@remarks
An animation is a collection of 'tracks' which over time change the position / orientation
of Node objects. In this case, the animation will likely have tracks to modify the position
/ orientation of SceneNode objects, e.g. to make objects move along a path.
@par
You don't need to use an Animation object to move objects around - you can do it yourself
using the methods of the Node in your FrameListener class. However, when you need relatively
complex scripted animation, this is the class to use since it will interpolate between
keyframes for you and generally make the whole process easier to manage.
@par
A single animation can affect multiple Node objects (each AnimationTrack affects a single Node).
In addition, through animation blending a single Node can be affected by multiple animations,
athough this is more useful when performing skeletal animation (see Skeleton::createAnimation).
@par
Note that whilst it uses the same classes, the animations created here are kept separate from the
skeletal animations of meshes (each Skeleton owns those animations).
@param name The name of the animation, must be unique within this SceneManager.
@param length The total length of the animation.
*/
virtual Animation* createAnimation(const String& name, Real length);
/** Looks up an Animation object previously created with createAnimation.
@note Throws an exception if the named instance does not exist
*/
virtual Animation* getAnimation(const String& name) const;
/** Returns whether an animation with the given name exists.
*/
virtual bool hasAnimation(const String& name) const;
/** Destroys an Animation.
@remarks
You should ensure that none of your code is referencing this animation objects since the
memory will be freed.
*/
virtual void destroyAnimation(const String& name);
/** Removes all animations created using this SceneManager. */
virtual void destroyAllAnimations(void);
/** Create an AnimationState object for managing application of animations.
@remarks
You can create Animation objects for animating SceneNode obejcts using the
createAnimation method. However, in order to actually apply those animations
you have to call methods on Node and Animation in a particular order (namely
Node::resetToInitialState and Animation::apply). To make this easier and to
help track the current time position of animations, the AnimationState object
is provided.
So if you don't want to control animation application manually, call this method,
update the returned object as you like every frame and let SceneManager apply
the animation state for you.
@par
Remember, AnimationState objects are disabled by default at creation time.
Turn them on when you want them using their setEnabled method.
@par
Note that any SceneNode affected by this automatic animation will have it's state
reset to it's initial position before application of the animation. Unless specifically
modified using Node::setInitialState the Node assumes it's initial state is at the
origin. If you want the base state of the SceneNode to be elsewhere, make your changes
to the node using the standard transform methods, then call setInitialState to
'bake' this reference position into the node.
@par
If the target of your animation is to be a generic AnimableValue, you
should ensure that it has a base value set (unlike nodes this has no
default). @see AnimableValue::setAsBaseValue.
@param animName The name of an animation created already with createAnimation.
*/
virtual AnimationState* createAnimationState(const String& animName);
/** Retrieves animation state as previously created using createAnimationState.
@note Throws an exception if the named instance does not exist
*/
virtual AnimationState* getAnimationState(const String& animName) const;
/** Returns whether an animation state with the given name exists.
*/
virtual bool hasAnimationState(const String& name) const;
/** Destroys an AnimationState.
@remarks
You should ensure that none of your code is referencing this animation
state object since the memory will be freed.
*/
virtual void destroyAnimationState(const String& name);
/** Removes all animation states created using this SceneManager. */
virtual void destroyAllAnimationStates(void);
/** Manual rendering method, for advanced users only.
@remarks
This method allows you to send rendering commands through the pipeline on
demand, bypassing OGRE's normal world processing. You should only use this if you
really know what you're doing; OGRE does lots of things for you that you really should
let it do. However, there are times where it may be useful to have this manual interface,
for example overlaying something on top of the scene rendered by OGRE.
@par
Because this is an instant rendering method, timing is important. The best
time to call it is from a RenderTargetListener event handler.
@par
Don't call this method a lot, it's designed for rare (1 or 2 times per frame) use.
Calling it regularly per frame will cause frame rate drops!
@param rend A RenderOperation object describing the rendering op
@param pass The Pass to use for this render
@param vp Pointer to the viewport to render to, or 0 to use the current viewport
@param worldMatrix The transform to apply from object to world space
@param viewMatrix The transform to apply from world to view space
@param projMatrix The transform to apply from view to screen space
@param doBeginEndFrame If true, beginFrame() and endFrame() are called,
otherwise not. You should leave this as false if you are calling
this within the main render loop.
*/
virtual void manualRender(RenderOperation* rend, Pass* pass, Viewport* vp,
const Matrix4& worldMatrix, const Matrix4& viewMatrix, const Matrix4& projMatrix,
bool doBeginEndFrame = false) ;
/** Manual rendering method for rendering a single object.
@param rend The renderable to issue to the pipeline
@param pass The pass to use
@param vp Pointer to the viewport to render to, or 0 to use the existing viewport
@param doBeginEndFrame If true, beginFrame() and endFrame() are called,
otherwise not. You should leave this as false if you are calling
this within the main render loop.
@param viewMatrix The transform to apply from world to view space
@param projMatrix The transform to apply from view to screen space
@param lightScissoringClipping If true, passes that have the getLightScissorEnabled
and/or getLightClipPlanesEnabled flags will cause calculation and setting of
scissor rectangle and user clip planes.
@param doLightIteration If true, this method will issue the renderable to
the pipeline possibly multiple times, if the pass indicates it should be
done once per light
@param manualLightList Only applicable if doLightIteration is false, this
method allows you to pass in a previously determined set of lights
which will be used for a single render of this object.
*/
virtual void manualRender(Renderable* rend, const Pass* pass, Viewport* vp,
const Matrix4& viewMatrix, const Matrix4& projMatrix, bool doBeginEndFrame = false, bool lightScissoringClipping = true,
bool doLightIteration = true, const LightList* manualLightList = 0);
/** Retrieves the internal render queue, for advanced users only.
@remarks
The render queue is mainly used internally to manage the scene object
rendering queue, it also exports some methods to allow advanced users
to configure the behavior of rendering process.
Most methods provided by RenderQueue are supposed to be used
internally only, you should reference to the RenderQueue API for
more information. Do not access this directly unless you know what
you are doing.
*/
virtual RenderQueue* getRenderQueue(void);
/** Registers a new RenderQueueListener which will be notified when render queues
are processed.
*/
virtual void addRenderQueueListener(RenderQueueListener* newListener);
/** Removes a listener previously added with addRenderQueueListener. */
virtual void removeRenderQueueListener(RenderQueueListener* delListener);
/** Registers a new Render Object Listener which will be notified when rendering an object.
*/
virtual void addRenderObjectListener(RenderObjectListener* newListener);
/** Removes a listener previously added with addRenderObjectListener. */
virtual void removeRenderObjectListener(RenderObjectListener* delListener);
/** Adds an item to the 'special case' render queue list.
@remarks
Normally all render queues are rendered, in their usual sequence,
only varying if a RenderQueueListener nominates for the queue to be
repeated or skipped. This method allows you to add a render queue to
a 'special case' list, which varies the behaviour. The effect of this
list depends on the 'mode' in which this list is in, which might be
to exclude these render queues, or to include them alone (excluding
all other queues). This allows you to perform broad selective
rendering without requiring a RenderQueueListener.
@param qid The identifier of the queue which should be added to the
special case list. Nothing happens if the queue is already in the list.
*/
virtual void addSpecialCaseRenderQueue(uint8 qid);
/** Removes an item to the 'special case' render queue list.
@see SceneManager::addSpecialCaseRenderQueue
@param qid The identifier of the queue which should be removed from the
special case list. Nothing happens if the queue is not in the list.
*/
virtual void removeSpecialCaseRenderQueue(uint8 qid);
/** Clears the 'special case' render queue list.
@see SceneManager::addSpecialCaseRenderQueue
*/
virtual void clearSpecialCaseRenderQueues(void);
/** Sets the way the special case render queue list is processed.
@see SceneManager::addSpecialCaseRenderQueue
@param mode The mode of processing
*/
virtual void setSpecialCaseRenderQueueMode(SpecialCaseRenderQueueMode mode);
/** Gets the way the special case render queue list is processed. */
virtual SpecialCaseRenderQueueMode getSpecialCaseRenderQueueMode(void);
/** Returns whether or not the named queue will be rendered based on the
current 'special case' render queue list and mode.
@see SceneManager::addSpecialCaseRenderQueue
@param qid The identifier of the queue which should be tested
@return true if the queue will be rendered, false otherwise
*/
virtual bool isRenderQueueToBeProcessed(uint8 qid);
/** Sets the render queue that the world geometry (if any) this SceneManager
renders will be associated with.
@remarks
SceneManagers which provide 'world geometry' should place it in a
specialised render queue in order to make it possible to enable /
disable it easily using the addSpecialCaseRenderQueue method. Even
if the SceneManager does not use the render queues to render the
world geometry, it should still pick a queue to represent it's manual
rendering, and check isRenderQueueToBeProcessed before rendering.
@note
Setting this may not affect the actual ordering of rendering the
world geometry, if the world geometry is being rendered manually
by the SceneManager. If the SceneManager feeds world geometry into
the queues, however, the ordering will be affected.
*/
virtual void setWorldGeometryRenderQueue(uint8 qid);
/** Gets the render queue that the world geometry (if any) this SceneManager
renders will be associated with.
@remarks
SceneManagers which provide 'world geometry' should place it in a
specialised render queue in order to make it possible to enable /
disable it easily using the addSpecialCaseRenderQueue method. Even
if the SceneManager does not use the render queues to render the
world geometry, it should still pick a queue to represent it's manual
rendering, and check isRenderQueueToBeProcessed before rendering.
*/
virtual uint8 getWorldGeometryRenderQueue(void);
/** Allows all bounding boxes of scene nodes to be displayed. */
virtual void showBoundingBoxes(bool bShow);
/** Returns if all bounding boxes of scene nodes are to be displayed */
virtual bool getShowBoundingBoxes() const;
/** Internal method for notifying the manager that a SceneNode is autotracking. */
virtual void _notifyAutotrackingSceneNode(SceneNode* node, bool autoTrack);
/** Creates an AxisAlignedBoxSceneQuery for this scene manager.
@remarks
This method creates a new instance of a query object for this scene manager,
for an axis aligned box region. See SceneQuery and AxisAlignedBoxSceneQuery
for full details.
@par
The instance returned from this method must be destroyed by calling
SceneManager::destroyQuery when it is no longer required.
@param box Details of the box which describes the region for this query.
@param mask The query mask to apply to this query; can be used to filter out
certain objects; see SceneQuery for details.
*/
virtual AxisAlignedBoxSceneQuery*
createAABBQuery(const AxisAlignedBox& box, uint32 mask = 0xFFFFFFFF);
/** Creates a SphereSceneQuery for this scene manager.
@remarks
This method creates a new instance of a query object for this scene manager,
for a spherical region. See SceneQuery and SphereSceneQuery
for full details.
@par
The instance returned from this method must be destroyed by calling
SceneManager::destroyQuery when it is no longer required.
@param sphere Details of the sphere which describes the region for this query.
@param mask The query mask to apply to this query; can be used to filter out
certain objects; see SceneQuery for details.
*/
virtual SphereSceneQuery*
createSphereQuery(const Sphere& sphere, uint32 mask = 0xFFFFFFFF);
/** Creates a PlaneBoundedVolumeListSceneQuery for this scene manager.
@remarks
This method creates a new instance of a query object for this scene manager,
for a region enclosed by a set of planes (normals pointing inwards).
See SceneQuery and PlaneBoundedVolumeListSceneQuery for full details.
@par
The instance returned from this method must be destroyed by calling
SceneManager::destroyQuery when it is no longer required.
@param volumes Details of the volumes which describe the region for this query.
@param mask The query mask to apply to this query; can be used to filter out
certain objects; see SceneQuery for details.
*/
virtual PlaneBoundedVolumeListSceneQuery*
createPlaneBoundedVolumeQuery(const PlaneBoundedVolumeList& volumes, uint32 mask = 0xFFFFFFFF);
/** Creates a RaySceneQuery for this scene manager.
@remarks
This method creates a new instance of a query object for this scene manager,
looking for objects which fall along a ray. See SceneQuery and RaySceneQuery
for full details.
@par
The instance returned from this method must be destroyed by calling
SceneManager::destroyQuery when it is no longer required.
@param ray Details of the ray which describes the region for this query.
@param mask The query mask to apply to this query; can be used to filter out
certain objects; see SceneQuery for details.
*/
virtual RaySceneQuery*
createRayQuery(const Ray& ray, uint32 mask = 0xFFFFFFFF);
//PyramidSceneQuery* createPyramidQuery(const Pyramid& p, unsigned long mask = 0xFFFFFFFF);
/** Creates an IntersectionSceneQuery for this scene manager.
@remarks
This method creates a new instance of a query object for locating
intersecting objects. See SceneQuery and IntersectionSceneQuery
for full details.
@par
The instance returned from this method must be destroyed by calling
SceneManager::destroyQuery when it is no longer required.
@param mask The query mask to apply to this query; can be used to filter out
certain objects; see SceneQuery for details.
*/
virtual IntersectionSceneQuery*
createIntersectionQuery(uint32 mask = 0xFFFFFFFF);
/** Destroys a scene query of any type. */
virtual void destroyQuery(SceneQuery* query);
typedef MapIterator<CameraList> CameraIterator;
typedef MapIterator<AnimationList> AnimationIterator;
/** Returns a specialised MapIterator over all cameras in the scene.
*/
CameraIterator getCameraIterator(void) {
return CameraIterator(mCameras.begin(), mCameras.end());
}
/** Returns a const version of the camera list.
*/
const CameraList& getCameras() const { return mCameras; }
/** Returns a specialised MapIterator over all animations in the scene. */
AnimationIterator getAnimationIterator(void) {
return AnimationIterator(mAnimationsList.begin(), mAnimationsList.end());
}
/** Returns a const version of the animation list.
*/
const AnimationList& getAnimations() const { return mAnimationsList; }
/** Returns a specialised MapIterator over all animation states in the scene. */
AnimationStateIterator getAnimationStateIterator(void) {
return mAnimationStates.getAnimationStateIterator();
}
/** Sets the general shadow technique to be used in this scene.
@remarks
There are multiple ways to generate shadows in a scene, and each has
strengths and weaknesses.
<ul><li>Stencil-based approaches can be used to
draw very long, extreme shadows without loss of precision and the 'additive'
version can correctly show the shadowing of complex effects like bump mapping
because they physically exclude the light from those areas. However, the edges
are very sharp and stencils cannot handle transparency, and they involve a
fair amount of CPU work in order to calculate the shadow volumes, especially
when animated objects are involved.</li>
<li>Texture-based approaches are good for handling transparency (they can, for
example, correctly shadow a mesh which uses alpha to represent holes), and they
require little CPU overhead, and can happily shadow geometry which is deformed
by a vertex program, unlike stencil shadows. However, they have a fixed precision
which can introduce 'jaggies' at long range and have fillrate issues of their own.</li>
</ul>
@par
We support 2 kinds of stencil shadows, and 2 kinds of texture-based shadows, and one
simple decal approach. The 2 stencil approaches differ in the amount of multipass work
that is required - the modulative approach simply 'darkens' areas in shadow after the
main render, which is the least expensive, whilst the additive approach has to perform
a render per light and adds the cumulative effect, which is more expensive but more
accurate. The texture based shadows both work in roughly the same way, the only difference is
that the shadowmap approach is slightly more accurate, but requires a more recent
graphics card.
@par
Note that because mixing many shadow techniques can cause problems, only one technique
is supported at once. Also, you should call this method at the start of the
scene setup.
@param technique The shadowing technique to use for the scene.
*/
virtual void setShadowTechnique(ShadowTechnique technique);
/** Gets the current shadow technique. */
virtual ShadowTechnique getShadowTechnique(void) const { return mShadowTechnique; }
/** Enables / disables the rendering of debug information for shadows. */
virtual void setShowDebugShadows(bool debug) { mDebugShadows = debug; }
/** Are debug shadows shown? */
virtual bool getShowDebugShadows(void ) const { return mDebugShadows; }
/** Set the colour used to modulate areas in shadow.
@remarks This is only applicable for shadow techniques which involve
darkening the area in shadow, as opposed to masking out the light.
This colour provided is used as a modulative value to darken the
areas.
*/
virtual void setShadowColour(const ColourValue& colour);
/** Get the colour used to modulate areas in shadow.
@remarks This is only applicable for shadow techniques which involve
darkening the area in shadow, as opposed to masking out the light.
This colour provided is used as a modulative value to darken the
areas.
*/
virtual const ColourValue& getShadowColour(void) const;
/** Sets the distance a shadow volume is extruded for a directional light.
@remarks
Although directional lights are essentially infinite, there are many
reasons to limit the shadow extrusion distance to a finite number,
not least of which is compatibility with older cards (which do not
support infinite positions), and shadow caster elimination.
@par
The default value is 10,000 world units. This does not apply to
point lights or spotlights, since they extrude up to their
attenuation range.
*/
virtual void setShadowDirectionalLightExtrusionDistance(Real dist);
/** Gets the distance a shadow volume is extruded for a directional light.
*/
virtual Real getShadowDirectionalLightExtrusionDistance(void) const;
/** Sets the default maximum distance away from the camera that shadows
will be visible. You have to call this function before you create lights
or the default distance of zero will be used.
@remarks
Shadow techniques can be expensive, therefore it is a good idea
to limit them to being rendered close to the camera if possible,
and to skip the expense of rendering shadows for distance objects.
This method allows you to set the distance at which shadows will no
longer be rendered.
@note
Each shadow technique can interpret this subtely differently.
For example, one technique may use this to eliminate casters,
another might use it to attenuate the shadows themselves.
You should tweak this value to suit your chosen shadow technique
and scene setup.
*/
virtual void setShadowFarDistance(Real distance);
/** Gets the default maximum distance away from the camera that shadows
will be visible.
*/
virtual Real getShadowFarDistance(void) const
{ return mDefaultShadowFarDist; }
virtual Real getShadowFarDistanceSquared(void) const
{ return mDefaultShadowFarDistSquared; }
/** Sets the maximum size of the index buffer used to render shadow
primitives.
@remarks
This method allows you to tweak the size of the index buffer used
to render shadow primitives (including stencil shadow volumes). The
default size is 51,200 entries, which is 100k of GPU memory, or
enough to render approximately 17,000 triangles. You can reduce this
as long as you do not have any models / world geometry chunks which
could require more than the amount you set.
@par
The maximum number of triangles required to render a single shadow
volume (including light and dark caps when needed) will be 3x the
number of edges on the light silhouette, plus the number of
light-facing triangles. On average, half the
triangles will be facing toward the light, but the number of
triangles in the silhouette entirely depends on the mesh -
angular meshes will have a higher silhouette tris/mesh tris
ratio than a smooth mesh. You can estimate the requirements for
your particular mesh by rendering it alone in a scene with shadows
enabled and a single light - rotate it or the light and make a note
of how high the triangle count goes (remembering to subtract the
mesh triangle count)
@param size The number of indexes; divide this by 3 to determine the
number of triangles.
*/
virtual void setShadowIndexBufferSize(size_t size);
/// Get the size of the shadow index buffer
virtual size_t getShadowIndexBufferSize(void) const
{ return mShadowIndexBufferSize; }
/** Set the size of the texture used for all texture-based shadows.
@remarks
The larger the shadow texture, the better the detail on
texture based shadows, but obviously this takes more memory.
The default size is 512. Sizes must be a power of 2.
@note This is the simple form, see setShadowTextureConfig for the more
complex form.
*/
virtual void setShadowTextureSize(unsigned short size);
/** Set the detailed configuration for a shadow texture.
@param shadowIndex The index of the texture to configure, must be < the
number of shadow textures setting
@param width The width of the texture
@param height The height of the texture
@param format The pixel format of the texture
@param fsaa The level of multisampling to use. Ignored if the device does not support it.
@param depthBufferPoolId The pool # it should query the depth buffers from
*/
virtual void setShadowTextureConfig(size_t shadowIndex, unsigned short width,
unsigned short height, PixelFormat format, unsigned short fsaa = 0, uint16 depthBufferPoolId=1);
/** Set the detailed configuration for a shadow texture.
@param shadowIndex The index of the texture to configure, must be < the
number of shadow textures setting
@param config Configuration structure
*/
virtual void setShadowTextureConfig(size_t shadowIndex,
const ShadowTextureConfig& config);
/** Get an iterator over the current shadow texture settings. */
ConstShadowTextureConfigIterator getShadowTextureConfigIterator() const;
/** Set the pixel format of the textures used for texture-based shadows.
@remarks
By default, a colour texture is used (PF_X8R8G8B8) for texture shadows,
but if you want to use more advanced texture shadow types you can
alter this. If you do, you will have to also call
setShadowTextureCasterMaterial and setShadowTextureReceiverMaterial
to provide shader-based materials to use these customised shadow
texture formats.
@note This is the simple form, see setShadowTextureConfig for the more
complex form.
*/
virtual void setShadowTexturePixelFormat(PixelFormat fmt);
/** Set the level of multisample AA of the textures used for texture-based shadows.
@remarks
By default, the level of multisample AA is zero.
@note This is the simple form, see setShadowTextureConfig for the more
complex form.
*/
virtual void setShadowTextureFSAA(unsigned short fsaa);
/** Set the number of textures allocated for texture-based shadows.
@remarks
The default number of textures assigned to deal with texture based
shadows is 1; however this means you can only have one light casting
shadows at the same time. You can increase this number in order to
make this more flexible, but be aware of the texture memory it will use.
*/
virtual void setShadowTextureCount(size_t count);
/// Get the number of the textures allocated for texture based shadows
size_t getShadowTextureCount(void) const {return mShadowTextureConfigList.size(); }
/** Set the number of shadow textures a light type uses.
@remarks
The default for all light types is 1. This means that each light uses only 1 shadow
texture. Call this if you need more than 1 shadow texture per light, E.G. PSSM.
@note
This feature only works with the Integrated shadow technique.
Also remember to increase the total number of shadow textures you request
appropriately (e.g. via setShadowTextureCount)!!
*/
void setShadowTextureCountPerLightType(Light::LightTypes type, size_t count)
{ mShadowTextureCountPerType[type] = count; }
/// Get the number of shadow textures is assigned for the given light type.
size_t getShadowTextureCountPerLightType(Light::LightTypes type) const
{return mShadowTextureCountPerType[type]; }
/** Sets the size and count of textures used in texture-based shadows.
@see setShadowTextureSize and setShadowTextureCount for details, this
method just allows you to change both at once, which can save on
reallocation if the textures have already been created.
@note This is the simple form, see setShadowTextureConfig for the more
complex form.
*/
virtual void setShadowTextureSettings(unsigned short size, unsigned short count,
PixelFormat fmt = PF_X8R8G8B8, unsigned short fsaa = 0, uint16 depthBufferPoolId=1);
/** Get a reference to the shadow texture currently in use at the given index.
@note
If you change shadow settings, this reference may no longer
be correct, so be sure not to hold the returned reference over
texture shadow configuration changes.
*/
virtual const TexturePtr& getShadowTexture(size_t shadowIndex);
/** Sets the proportional distance which a texture shadow which is generated from a
directional light will be offset into the camera view to make best use of texture space.
@remarks
When generating a shadow texture from a directional light, an approximation is used
since it is not possible to render the entire scene to one texture.
The texture is projected onto an area centred on the camera, and is
the shadow far distance * 2 in length (it is square). This wastes
a lot of texture space outside the frustum though, so this offset allows
you to move the texture in front of the camera more. However, be aware
that this can cause a little shadow 'jittering' during rotation, and
that if you move it too far then you'll start to get artefacts close
to the camera. The value is represented as a proportion of the shadow
far distance, and the default is 0.6.
*/
virtual void setShadowDirLightTextureOffset(Real offset) { mShadowTextureOffset = offset;}
/** Gets the proportional distance which a texture shadow which is generated from a
directional light will be offset into the camera view to make best use of texture space.
*/
virtual Real getShadowDirLightTextureOffset(void) const { return mShadowTextureOffset; }
/** Sets the proportional distance at which texture shadows begin to fade out.
@remarks
To hide the edges where texture shadows end (in directional lights)
Ogre will fade out the shadow in the distance. This value is a proportional
distance of the entire shadow visibility distance at which the shadow
begins to fade out. The default is 0.7
*/
virtual void setShadowTextureFadeStart(Real fadeStart)
{ mShadowTextureFadeStart = fadeStart; }
/** Sets the proportional distance at which texture shadows finish to fading out.
@remarks
To hide the edges where texture shadows end (in directional lights)
Ogre will fade out the shadow in the distance. This value is a proportional
distance of the entire shadow visibility distance at which the shadow
is completely invisible. The default is 0.9.
*/
virtual void setShadowTextureFadeEnd(Real fadeEnd)
{ mShadowTextureFadeEnd = fadeEnd; }
/** Sets whether or not texture shadows should attempt to self-shadow.
@remarks
The default implementation of texture shadows uses a fixed-function
colour texture projection approach for maximum compatibility, and
as such cannot support self-shadowing. However, if you decide to
implement a more complex shadowing technique using the
setShadowTextureCasterMaterial and setShadowTextureReceiverMaterial
there is a possibility you may be able to support
self-shadowing (e.g by implementing a shader-based shadow map). In
this case you might want to enable this option.
@param selfShadow Whether to attempt self-shadowing with texture shadows
*/
virtual void setShadowTextureSelfShadow(bool selfShadow);
/// Gets whether or not texture shadows attempt to self-shadow.
virtual bool getShadowTextureSelfShadow(void) const
{ return mShadowTextureSelfShadow; }
/** Sets the default material to use for rendering shadow casters.
@remarks
By default shadow casters are rendered into the shadow texture using
an automatically generated fixed-function pass. This allows basic
projective texture shadows, but it's possible to use more advanced
shadow techniques by overriding the caster and receiver materials, for
example providing vertex and fragment programs to implement shadow
maps.
@par
You can rely on the ambient light in the scene being set to the
requested texture shadow colour, if that's useful.
@note
Individual objects may also override the vertex program in
your default material if their materials include
shadow_caster_vertex_program_ref, shadow_receiver_vertex_program_ref
shadow_caster_material entries, so if you use both make sure they are compatible.
@note
Only a single pass is allowed in your material, although multiple
techniques may be used for hardware fallback.
*/
virtual void setShadowTextureCasterMaterial(const String& name);
/** Sets the default material to use for rendering shadow receivers.
@remarks
By default shadow receivers are rendered as a post-pass using basic
modulation. This allows basic projective texture shadows, but it's
possible to use more advanced shadow techniques by overriding the
caster and receiver materials, for example providing vertex and
fragment programs to implement shadow maps.
@par
You can rely on texture unit 0 containing the shadow texture, and
for the unit to be set to use projective texturing from the light
(only useful if you're using fixed-function, which is unlikely;
otherwise you should rely on the texture_viewproj_matrix auto binding)
@note
Individual objects may also override the vertex program in
your default material if their materials include
shadow_caster_vertex_program_ref shadow_receiver_vertex_program_ref
shadow_receiver_material entries, so if you use both make sure they are compatible.
@note
Only a single pass is allowed in your material, although multiple
techniques may be used for hardware fallback.
*/
virtual void setShadowTextureReceiverMaterial(const String& name);
/** Sets whether or not shadow casters should be rendered into shadow
textures using their back faces rather than their front faces.
@remarks
Rendering back faces rather than front faces into a shadow texture
can help minimise depth comparison issues, if you're using depth
shadowmapping. You will probably still need some biasing but you
won't need as much. For solid objects the result is the same anyway,
if you have objects with holes you may want to turn this option off.
The default is to enable this option.
*/
virtual void setShadowCasterRenderBackFaces(bool bf) { mShadowCasterRenderBackFaces = bf; }
/** Gets whether or not shadow casters should be rendered into shadow
textures using their back faces rather than their front faces.
*/
virtual bool getShadowCasterRenderBackFaces() const { return mShadowCasterRenderBackFaces; }
/** Set the shadow camera setup to use for all lights which don't have
their own shadow camera setup.
@see ShadowCameraSetup
*/
virtual void setShadowCameraSetup(const ShadowCameraSetupPtr& shadowSetup);
/** Get the shadow camera setup in use for all lights which don't have
their own shadow camera setup.
@see ShadowCameraSetup
*/
virtual const ShadowCameraSetupPtr& getShadowCameraSetup() const;
/** Sets whether we should use an inifinite camera far plane
when rendering stencil shadows.
@remarks
Stencil shadow coherency is very reliant on the shadow volume
not being clipped by the far plane. If this clipping happens, you
get a kind of 'negative' shadow effect. The best way to achieve
coherency is to move the far plane of the camera out to infinity,
thus preventing the far plane from clipping the shadow volumes.
When combined with vertex program extrusion of the volume to
infinity, which Ogre does when available, this results in very
robust shadow volumes. For this reason, when you enable stencil
shadows, Ogre automatically changes your camera settings to
project to infinity if the card supports it. You can disable this
behaviour if you like by calling this method; although you can
never enable infinite projection if the card does not support it.
@par
If you disable infinite projection, or it is not available,
you need to be far more careful with your light attenuation /
directional light extrusion distances to avoid clipping artefacts
at the far plane.
@note
Recent cards will generally support infinite far plane projection.
However, we have found some cases where they do not, especially
on Direct3D. There is no standard capability we can check to
validate this, so we use some heuristics based on experience:
<UL>
<LI>OpenGL always seems to support it no matter what the card</LI>
<LI>Direct3D on non-vertex program capable systems (including
vertex program capable cards on Direct3D7) does not
support it</LI>
<LI>Direct3D on GeForce3 and GeForce4 Ti does not seem to support
infinite projection<LI>
</UL>
Therefore in the RenderSystem implementation, we may veto the use
of an infinite far plane based on these heuristics.
*/
virtual void setShadowUseInfiniteFarPlane(bool enable) {
mShadowUseInfiniteFarPlane = enable; }
/** Is there a stencil shadow based shadowing technique in use? */
virtual bool isShadowTechniqueStencilBased(void) const
{ return (mShadowTechnique & SHADOWDETAILTYPE_STENCIL) != 0; }
/** Is there a texture shadow based shadowing technique in use? */
virtual bool isShadowTechniqueTextureBased(void) const
{ return (mShadowTechnique & SHADOWDETAILTYPE_TEXTURE) != 0; }
/** Is there a modulative shadowing technique in use? */
virtual bool isShadowTechniqueModulative(void) const
{ return (mShadowTechnique & SHADOWDETAILTYPE_MODULATIVE) != 0; }
/** Is there an additive shadowing technique in use? */
virtual bool isShadowTechniqueAdditive(void) const
{ return (mShadowTechnique & SHADOWDETAILTYPE_ADDITIVE) != 0; }
/** Is the shadow technique integrated into primary materials? */
virtual bool isShadowTechniqueIntegrated(void) const
{ return (mShadowTechnique & SHADOWDETAILTYPE_INTEGRATED) != 0; }
/** Is there any shadowing technique in use? */
virtual bool isShadowTechniqueInUse(void) const
{ return mShadowTechnique != SHADOWTYPE_NONE; }
/** Sets whether when using a built-in additive shadow mode, user clip
planes should be used to restrict light rendering.
*/
virtual void setShadowUseLightClipPlanes(bool enabled) { mShadowAdditiveLightClip = enabled; }
/** Gets whether when using a built-in additive shadow mode, user clip
planes should be used to restrict light rendering.
*/
virtual bool getShadowUseLightClipPlanes() const { return mShadowAdditiveLightClip; }
/** Sets the active compositor chain of the current scene being rendered.
@note CompositorChain does this automatically, no need to call manually.
*/
virtual void _setActiveCompositorChain(CompositorChain* chain) { mActiveCompositorChain = chain; }
/** Sets whether to use late material resolving or not. If set, materials will be resolved
from the materials at the pass-setting stage and not at the render queue building stage.
This is useful when the active material scheme during the render queue building stage
is different from the one during the rendering stage.
*/
virtual void setLateMaterialResolving(bool isLate) { mLateMaterialResolving = isLate; }
/** Gets whether using late material resolving or not.
@see setLateMaterialResolving */
virtual bool isLateMaterialResolving() const { return mLateMaterialResolving; }
/** Gets the active compositor chain of the current scene being rendered */
virtual CompositorChain* _getActiveCompositorChain() const { return mActiveCompositorChain; }
/** Add a listener which will get called back on scene manager events.
*/
virtual void addListener(Listener* s);
/** Remove a listener
*/
virtual void removeListener(Listener* s);
/** Creates a StaticGeometry instance suitable for use with this
SceneManager.
@remarks
StaticGeometry is a way of batching up geometry into a more
efficient form at the expense of being able to move it. Please
read the StaticGeometry class documentation for full information.
@param name The name to give the new object
@return The new StaticGeometry instance
*/
virtual StaticGeometry* createStaticGeometry(const String& name);
/** Retrieve a previously created StaticGeometry instance.
@note Throws an exception if the named instance does not exist
*/
virtual StaticGeometry* getStaticGeometry(const String& name) const;
/** Returns whether a static geometry instance with the given name exists. */
virtual bool hasStaticGeometry(const String& name) const;
/** Remove & destroy a StaticGeometry instance. */
virtual void destroyStaticGeometry(StaticGeometry* geom);
/** Remove & destroy a StaticGeometry instance. */
virtual void destroyStaticGeometry(const String& name);
/** Remove & destroy all StaticGeometry instances. */
virtual void destroyAllStaticGeometry(void);
/** Creates a InstancedGeometry instance suitable for use with this
SceneManager.
@remarks
InstancedGeometry is a way of batching up geometry into a more
efficient form, and still be able to move it. Please
read the InstancedGeometry class documentation for full information.
@param name The name to give the new object
@return The new InstancedGeometry instance
*/
virtual InstancedGeometry* createInstancedGeometry(const String& name);
/** Retrieve a previously created InstancedGeometry instance. */
virtual InstancedGeometry* getInstancedGeometry(const String& name) const;
/** Remove & destroy a InstancedGeometry instance. */
virtual void destroyInstancedGeometry(InstancedGeometry* geom);
/** Remove & destroy a InstancedGeometry instance. */
virtual void destroyInstancedGeometry(const String& name);
/** Remove & destroy all InstancedGeometry instances. */
virtual void destroyAllInstancedGeometry(void);
/** Creates an InstanceManager interface to create & manipulate instanced entities
You need to call this function at least once before start calling createInstancedEntity
to build up an instance based on the given mesh.
@remarks
Instancing is a way of batching up geometry into a much more
efficient form, but with some limitations, and still be able to move & animate it.
Please @see InstanceManager class documentation for full information.
@param customName Custom name for referencing. Must be unique
@param meshName The mesh name the instances will be based upon
@param groupName The resource name where the mesh lives
@param technique Technique to use, which may be shader based, or hardware based.
@param numInstancesPerBatch Suggested number of instances per batch. The actual number
may end up being lower if the technique doesn't support having so many. It can't be zero
@param flags Flags to pass to the InstanceManager @see InstanceManagerFlags
@param subMeshIdx InstanceManager only supports using one submesh from the base mesh. This parameter
says which submesh to pick (must be <= Mesh::getNumSubMeshes())
@return The new InstanceManager instance
*/
virtual InstanceManager* createInstanceManager( const String &customName, const String &meshName,
const String &groupName,
InstanceManager::InstancingTechnique technique,
size_t numInstancesPerBatch, uint16 flags=0,
unsigned short subMeshIdx=0 );
/** Retrieves an existing InstanceManager by it's name.
@note Throws an exception if the named InstanceManager does not exist
*/
virtual InstanceManager* getInstanceManager( const String &managerName ) const;
/** Returns whether an InstanceManager with the given name exists. */
virtual bool hasInstanceManager( const String &managerName ) const;
/** Destroys an InstanceManager <b>if</b> it was created with createInstanceManager()
@remarks
Be sure you don't have any InstancedEntity referenced somewhere which was created with
this manager, since it will become a dangling pointer.
@param name Name of the manager to remove
*/
virtual void destroyInstanceManager( const String &name );
virtual void destroyInstanceManager( InstanceManager *instanceManager );
virtual void destroyAllInstanceManagers(void);
/** @see InstanceManager::getMaxOrBestNumInstancesPerBatch
@remarks
If you've already created an InstanceManager, you can call it's
getMaxOrBestNumInstancesPerBatch() function directly.
Another (not recommended) way to know if the technique is unsupported is by creating
an InstanceManager and use createInstancedEntity, which will return null pointer.
The input parameter "numInstancesPerBatch" is a suggested value when using IM_VTFBESTFIT
flag (in that case it should be non-zero)
@return
The ideal (or maximum, depending on flags) number of instances per batch for
the given technique. Zero if technique is unsupported or errors were spotted
*/
virtual size_t getNumInstancesPerBatch( const String &meshName, const String &groupName,
const String &materialName,
InstanceManager::InstancingTechnique technique,
size_t numInstancesPerBatch, uint16 flags=0,
unsigned short subMeshIdx=0 );
/** Creates an InstancedEntity based on an existing InstanceManager (@see createInstanceManager)
@remarks
* Return value may be null if the InstanceManger technique isn't supported
* Try to keep the number of entities with different materials <b>to a minimum</b>
* For more information @see InstancedManager @see InstancedBatch, @see InstancedEntity
* Alternatively you can call InstancedManager::createInstanceEntity using the returned
pointer from createInstanceManager
@param materialName Material name
@param managerName Name of the instance manager
@return An InstancedEntity ready to be attached to a SceneNode
*/
virtual InstancedEntity* createInstancedEntity( const String &materialName,
const String &managerName );
/** Removes an InstancedEntity, @see SceneManager::createInstancedEntity &
@see InstanceBatch::removeInstancedEntity
@param instancedEntity Instance to remove
*/
virtual void destroyInstancedEntity( InstancedEntity *instancedEntity );
/** Called by an InstanceManager when it has at least one InstanceBatch that needs their bounds
to be updated for proper culling
@param dirtyManager The manager with dirty batches to update
*/
void _addDirtyInstanceManager( InstanceManager *dirtyManager );
/** Create a movable object of the type specified.
@remarks
This is the generalised form of MovableObject creation where you can
create a MovableObject of any specialised type generically, including
any new types registered using plugins.
@param name The name to give the object. Must be unique within type.
@param typeName The type of object to create
@param params Optional name/value pair list to give extra parameters to
the created object.
*/
virtual MovableObject* createMovableObject(const String& name,
const String& typeName, const NameValuePairList* params = 0);
/** Create a movable object of the type specified without a name.
@remarks
This is the generalised form of MovableObject creation where you can
create a MovableObject of any specialised type generically, including
any new types registered using plugins. The name is generated automatically.
@param typeName The type of object to create
@param params Optional name/value pair list to give extra parameters to
the created object.
*/
virtual MovableObject* createMovableObject(const String& typeName, const NameValuePairList* params = 0);
/** Destroys a MovableObject with the name specified, of the type specified.
@remarks
The MovableObject will automatically detach itself from any nodes
on destruction.
*/
virtual void destroyMovableObject(const String& name, const String& typeName);
/** Destroys a MovableObject.
@remarks
The MovableObject will automatically detach itself from any nodes
on destruction.
*/
virtual void destroyMovableObject(MovableObject* m);
/** Destroy all MovableObjects of a given type. */
virtual void destroyAllMovableObjectsByType(const String& typeName);
/** Destroy all MovableObjects. */
virtual void destroyAllMovableObjects(void);
/** Get a reference to a previously created MovableObject.
@note Throws an exception if the named instance does not exist
*/
virtual MovableObject* getMovableObject(const String& name, const String& typeName) const;
/** Returns whether a movable object instance with the given name exists. */
virtual bool hasMovableObject(const String& name, const String& typeName) const;
typedef MapIterator<MovableObjectMap> MovableObjectIterator;
/** Get an iterator over all MovableObect instances of a given type.
@note
The iterator returned from this method is not thread safe, do not use this
if you are creating or deleting objects of this type in another thread.
*/
virtual MovableObjectIterator getMovableObjectIterator(const String& typeName);
/** Inject a MovableObject instance created externally.
@remarks
This method 'injects' a MovableObject instance created externally into
the MovableObject instance registry held in the SceneManager. You
might want to use this if you have a MovableObject which you don't
want to register a factory for; for example a MovableObject which
cannot be generally constructed by clients.
@note
It is important that the MovableObject has a unique name for the type,
and that its getMovableType() method returns a proper type name.
*/
virtual void injectMovableObject(MovableObject* m);
/** Extract a previously injected MovableObject.
@remarks
Essentially this does the same as destroyMovableObject, but only
removes the instance from the internal lists, it does not attempt
to destroy it.
*/
virtual void extractMovableObject(const String& name, const String& typeName);
/** Extract a previously injected MovableObject.
@remarks
Essentially this does the same as destroyMovableObject, but only
removes the instance from the internal lists, it does not attempt
to destroy it.
*/
virtual void extractMovableObject(MovableObject* m);
/** Extract all injected MovableObjects of a given type.
@remarks
Essentially this does the same as destroyAllMovableObjectsByType,
but only removes the instances from the internal lists, it does not
attempt to destroy them.
*/
virtual void extractAllMovableObjectsByType(const String& typeName);
/** Sets a mask which is bitwise 'and'ed with objects own visibility masks
to determine if the object is visible.
@remarks
Note that this is combined with any per-viewport visibility mask
through an 'and' operation. @see Viewport::setVisibilityMask
*/
virtual void setVisibilityMask(uint32 vmask) { mVisibilityMask = vmask; }
/** Gets a mask which is bitwise 'and'ed with objects own visibility masks
to determine if the object is visible.
*/
virtual uint32 getVisibilityMask(void) { return mVisibilityMask; }
/** Internal method for getting the combination between the global visibility
mask and the per-viewport visibility mask.
*/
uint32 _getCombinedVisibilityMask(void) const;
/** Sets whether the SceneManager should search for visible objects, or
whether they are being manually handled.
@remarks
This is an advanced function, you should not use this unless you know
what you are doing.
*/
virtual void setFindVisibleObjects(bool find) { mFindVisibleObjects = find; }
/** Gets whether the SceneManager should search for visible objects, or
whether they are being manually handled.
*/
virtual bool getFindVisibleObjects(void) { return mFindVisibleObjects; }
/** Set whether to automatically normalise normals on objects whenever they
are scaled.
@remarks
Scaling can distort normals so the default behaviour is to compensate
for this, but it has a cost. If you would prefer to manually manage
this, set this option to 'false' and use Pass::setNormaliseNormals
only when needed.
*/
virtual void setNormaliseNormalsOnScale(bool n) { mNormaliseNormalsOnScale = n; }
/** Get whether to automatically normalise normals on objects whenever they
are scaled.
*/
virtual bool getNormaliseNormalsOnScale() const { return mNormaliseNormalsOnScale; }
/** Set whether to automatically flip the culling mode on objects whenever they
are negatively scaled.
@remarks
Negativelyl scaling an object has the effect of flipping the triangles,
so the culling mode should probably be inverted to deal with this.
If you would prefer to manually manage this, set this option to 'false'
and use different materials with Pass::setCullingMode set manually as needed.
*/
virtual void setFlipCullingOnNegativeScale(bool n) { mFlipCullingOnNegativeScale = n; }
/** Get whether to automatically flip the culling mode on objects whenever they
are negatively scaled.
*/
virtual bool getFlipCullingOnNegativeScale() const { return mFlipCullingOnNegativeScale; }
/** Render something as if it came from the current queue.
@param pass Material pass to use for setting up this quad.
@param rend Renderable to render
@param shadowDerivation Whether passes should be replaced with shadow caster / receiver passes
*/
virtual void _injectRenderWithPass(Pass *pass, Renderable *rend, bool shadowDerivation = true,
bool doLightIteration = false, const LightList* manualLightList = 0);
/** Indicates to the SceneManager whether it should suppress changing
the RenderSystem states when rendering objects.
@remarks
This method allows you to tell the SceneManager not to change any
RenderSystem state until you tell it to. This method is only
intended for advanced use, don't use it if you're unsure of the
effect. The only RenderSystems calls made are to set the world
matrix for each object (note - view an projection matrices are NOT
SET - they are under your control) and to render the object; it is up to
the caller to do everything else, including enabling any vertex /
fragment programs and updating their parameter state, and binding
parameters to the RenderSystem.
@note
Calling this implicitly disables shadow processing since no shadows
can be rendered without changing state.
@param suppress If true, no RenderSystem state changes will be issued
until this method is called again with a parameter of false.
*/
virtual void _suppressRenderStateChanges(bool suppress);
/** Are render state changes suppressed?
@see _suppressRenderStateChanges
*/
virtual bool _areRenderStateChangesSuppressed(void) const
{ return mSuppressRenderStateChanges; }
/** Internal method for setting up the renderstate for a rendering pass.
@param pass The Pass details to set.
@param evenIfSuppressed Sets the pass details even if render state
changes are suppressed; if you are using this to manually set state
when render state changes are suppressed, you should set this to
true.
@param shadowDerivation If false, disables the derivation of shadow
passes from original passes
@return
A Pass object that was used instead of the one passed in, can
happen when rendering shadow passes
*/
virtual const Pass* _setPass(const Pass* pass,
bool evenIfSuppressed = false, bool shadowDerivation = true);
/** Method to allow you to mark gpu parameters as dirty, causing them to
be updated according to the mask that you set when updateGpuProgramParameters is
next called. Only really useful if you're controlling parameter state in
inner rendering loop callbacks.
@param mask Some combination of GpuParamVariability which is bitwise OR'ed with the
current dirty state.
*/
virtual void _markGpuParamsDirty(uint16 mask);
/** Indicates to the SceneManager whether it should suppress the
active shadow rendering technique until told otherwise.
@remarks
This is a temporary alternative to setShadowTechnique to suppress
the rendering of shadows and forcing all processing down the
standard rendering path. This is intended for internal use only.
@param suppress If true, no shadow rendering will occur until this
method is called again with a parameter of false.
*/
virtual void _suppressShadows(bool suppress);
/** Are shadows suppressed?
@see _suppressShadows
*/
virtual bool _areShadowsSuppressed(void) const
{ return mSuppressShadows; }
/** Render the objects in a given queue group
@remarks You should only call this from a RenderQueueInvocation implementation
*/
virtual void _renderQueueGroupObjects(RenderQueueGroup* group,
QueuedRenderableCollection::OrganisationMode om);
/** Advanced method for supplying an alternative visitor, used for parsing the
render queues and sending the results to the renderer.
@remarks
You can use this method to insert your own implementation of the
QueuedRenderableVisitor interface, which receives calls as the queued
renderables are parsed in a given order (determined by RenderQueueInvocationSequence)
and are sent to the renderer. If you provide your own implementation of
this visitor, you are responsible for either calling the rendersystem,
or passing the calls on to the base class implementation.
@note
Ownership is not taken of this pointer, you are still required to
delete it yourself once you're finished.
@param visitor Your implementation of SceneMgrQueuedRenderableVisitor.
If you pass 0, the default implementation will be used.
*/
void setQueuedRenderableVisitor(SceneMgrQueuedRenderableVisitor* visitor);
/** Gets the current visitor object which processes queued renderables. */
SceneMgrQueuedRenderableVisitor* getQueuedRenderableVisitor(void) const;
/** Get the rendersystem subclass to which the output of this Scene Manager
gets sent
*/
RenderSystem *getDestinationRenderSystem();
/** Gets the current viewport being rendered (advanced use only, only
valid during viewport update. */
Viewport* getCurrentViewport(void) const { return mCurrentViewport; }
/** Returns a visibility boundary box for a specific camera. */
const VisibleObjectsBoundsInfo& getVisibleObjectsBoundsInfo(const Camera* cam) const;
/** Returns the shadow caster AAB for a specific light-camera combination */
const VisibleObjectsBoundsInfo& getShadowCasterBoundsInfo(const Light* light, size_t iteration = 0) const;
/** Set whether to use camera-relative co-ordinates when rendering, ie
to always place the camera at the origin and move the world around it.
@remarks
This is a technique to alleviate some of the precision issues associated with
rendering far from the origin, where single-precision floats as used in most
GPUs begin to lose their precision. Instead of including the camera
translation in the view matrix, it only includes the rotation, and
the world matrices of objects must be expressed relative to this.
@note
If you need this option, you will probably also need to enable double-precision
mode in Ogre (OGRE_DOUBLE_PRECISION), since even though this will
alleviate the rendering precision, the source camera and object positions will still
suffer from precision issues leading to jerky movement.
*/
virtual void setCameraRelativeRendering(bool rel) { mCameraRelativeRendering = rel; }
/** Get whether to use camera-relative co-ordinates when rendering, ie
to always place the camera at the origin and move the world around it.
*/
virtual bool getCameraRelativeRendering() const { return mCameraRelativeRendering; }
/** Add a level of detail listener. */
void addLodListener(LodListener *listener);
/**
Remove a level of detail listener.
@remarks
Do not call from inside an LodListener callback method.
*/
void removeLodListener(LodListener *listener);
/** Notify that a movable object LOD change event has occurred. */
void _notifyMovableObjectLodChanged(MovableObjectLodChangedEvent& evt);
/** Notify that an entity mesh LOD change event has occurred. */
void _notifyEntityMeshLodChanged(EntityMeshLodChangedEvent& evt);
/** Notify that an entity material LOD change event has occurred. */
void _notifyEntityMaterialLodChanged(EntityMaterialLodChangedEvent& evt);
/** Handle LOD events. */
void _handleLodEvents();
IlluminationRenderStage _getCurrentRenderStage() {return mIlluminationStage;}
};
/** Default implementation of IntersectionSceneQuery. */
class _OgreExport DefaultIntersectionSceneQuery :
public IntersectionSceneQuery
{
public:
DefaultIntersectionSceneQuery(SceneManager* creator);
~DefaultIntersectionSceneQuery();
/** See IntersectionSceneQuery. */
void execute(IntersectionSceneQueryListener* listener);
};
/** Default implementation of RaySceneQuery. */
class _OgreExport DefaultRaySceneQuery : public RaySceneQuery
{
public:
DefaultRaySceneQuery(SceneManager* creator);
~DefaultRaySceneQuery();
/** See RayScenQuery. */
void execute(RaySceneQueryListener* listener);
};
/** Default implementation of SphereSceneQuery. */
class _OgreExport DefaultSphereSceneQuery : public SphereSceneQuery
{
public:
DefaultSphereSceneQuery(SceneManager* creator);
~DefaultSphereSceneQuery();
/** See SceneQuery. */
void execute(SceneQueryListener* listener);
};
/** Default implementation of PlaneBoundedVolumeListSceneQuery. */
class _OgreExport DefaultPlaneBoundedVolumeListSceneQuery : public PlaneBoundedVolumeListSceneQuery
{
public:
DefaultPlaneBoundedVolumeListSceneQuery(SceneManager* creator);
~DefaultPlaneBoundedVolumeListSceneQuery();
/** See SceneQuery. */
void execute(SceneQueryListener* listener);
};
/** Default implementation of AxisAlignedBoxSceneQuery. */
class _OgreExport DefaultAxisAlignedBoxSceneQuery : public AxisAlignedBoxSceneQuery
{
public:
DefaultAxisAlignedBoxSceneQuery(SceneManager* creator);
~DefaultAxisAlignedBoxSceneQuery();
/** See RayScenQuery. */
void execute(SceneQueryListener* listener);
};
/// Bitmask containing scene types
typedef uint16 SceneTypeMask;
/** Classification of a scene to allow a decision of what type of
SceenManager to provide back to the application.
*/
enum SceneType
{
ST_GENERIC = 1,
ST_EXTERIOR_CLOSE = 2,
ST_EXTERIOR_FAR = 4,
ST_EXTERIOR_REAL_FAR = 8,
ST_INTERIOR = 16
};
/** Structure containing information about a scene manager. */
struct SceneManagerMetaData
{
/// A globally unique string identifying the scene manager type
String typeName;
/// A text description of the scene manager
String description;
/// A mask describing which sorts of scenes this manager can handle
SceneTypeMask sceneTypeMask;
/// Flag indicating whether world geometry is supported
bool worldGeometrySupported;
};
/** Class which will create instances of a given SceneManager. */
class _OgreExport SceneManagerFactory : public SceneMgtAlloc
{
protected:
mutable SceneManagerMetaData mMetaData;
mutable bool mMetaDataInit;
/// Internal method to initialise the metadata, must be implemented
virtual void initMetaData(void) const = 0;
public:
SceneManagerFactory() : mMetaDataInit(true) {}
virtual ~SceneManagerFactory() {}
/** Get information about the SceneManager type created by this factory. */
virtual const SceneManagerMetaData& getMetaData(void) const
{
if (mMetaDataInit)
{
initMetaData();
mMetaDataInit = false;
}
return mMetaData;
}
/** Create a new instance of a SceneManager.
@remarks
Don't call directly, use SceneManagerEnumerator::createSceneManager.
*/
virtual SceneManager* createInstance(const String& instanceName) = 0;
/** Destroy an instance of a SceneManager. */
virtual void destroyInstance(SceneManager* instance) = 0;
};
/** @} */
/** @} */
} // Namespace
#include "OgreHeaderSuffix.h"
#endif
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