stk-code_catmod/lib/irrlicht/include/ICameraSceneNode.h
hikerstk 974deca5e1 Added our own irrlicht version - not used atm.
git-svn-id: svn+ssh://svn.code.sf.net/p/supertuxkart/code/main/trunk@11846 178a84e3-b1eb-0310-8ba1-8eac791a3b58
2012-11-01 02:00:02 +00:00

208 lines
7.8 KiB
C++

// Copyright (C) 2002-2012 Nikolaus Gebhardt
// This file is part of the "Irrlicht Engine".
// For conditions of distribution and use, see copyright notice in irrlicht.h
#ifndef __I_CAMERA_SCENE_NODE_H_INCLUDED__
#define __I_CAMERA_SCENE_NODE_H_INCLUDED__
#include "ISceneNode.h"
#include "IEventReceiver.h"
namespace irr
{
namespace scene
{
struct SViewFrustum;
//! Scene Node which is a (controlable) camera.
/** The whole scene will be rendered from the cameras point of view.
Because the ICameraScenNode is a SceneNode, it can be attached to any
other scene node, and will follow its parents movement, rotation and so
on.
*/
class ICameraSceneNode : public ISceneNode, public IEventReceiver
{
public:
//! Constructor
ICameraSceneNode(ISceneNode* parent, ISceneManager* mgr, s32 id,
const core::vector3df& position = core::vector3df(0,0,0),
const core::vector3df& rotation = core::vector3df(0,0,0),
const core::vector3df& scale = core::vector3df(1.0f,1.0f,1.0f))
: ISceneNode(parent, mgr, id, position, rotation, scale), IsOrthogonal(false) {}
//! Sets the projection matrix of the camera.
/** The core::matrix4 class has some methods to build a
projection matrix. e.g:
core::matrix4::buildProjectionMatrixPerspectiveFovLH.
Note that the matrix will only stay as set by this method until
one of the following Methods are called: setNearValue,
setFarValue, setAspectRatio, setFOV.
\param projection The new projection matrix of the camera.
\param isOrthogonal Set this to true if the matrix is an
orthogonal one (e.g. from matrix4::buildProjectionMatrixOrtho).
*/
virtual void setProjectionMatrix(const core::matrix4& projection, bool isOrthogonal=false) =0;
//! Gets the current projection matrix of the camera.
/** \return The current projection matrix of the camera. */
virtual const core::matrix4& getProjectionMatrix() const =0;
//! Gets the current view matrix of the camera.
/** \return The current view matrix of the camera. */
virtual const core::matrix4& getViewMatrix() const =0;
//! Sets a custom view matrix affector.
/** The matrix passed here, will be multiplied with the view
matrix when it gets updated. This allows for custom camera
setups like, for example, a reflection camera.
\param affector The affector matrix. */
virtual void setViewMatrixAffector(const core::matrix4& affector) =0;
//! Get the custom view matrix affector.
/** \return The affector matrix. */
virtual const core::matrix4& getViewMatrixAffector() const =0;
//! It is possible to send mouse and key events to the camera.
/** Most cameras may ignore this input, but camera scene nodes
which are created for example with
ISceneManager::addCameraSceneNodeMaya or
ISceneManager::addCameraSceneNodeFPS, may want to get
this input for changing their position, look at target or
whatever. */
virtual bool OnEvent(const SEvent& event) =0;
//! Sets the look at target of the camera
/** If the camera's target and rotation are bound ( @see
bindTargetAndRotation() ) then calling this will also change
the camera's scene node rotation to match the target.
Note that setTarget uses the current absolute position
internally, so if you changed setPosition since last rendering you must
call updateAbsolutePosition before using this function.
\param pos Look at target of the camera, in world co-ordinates. */
virtual void setTarget(const core::vector3df& pos) =0;
//! Sets the rotation of the node.
/** This only modifies the relative rotation of the node.
If the camera's target and rotation are bound ( @see
bindTargetAndRotation() ) then calling this will also change
the camera's target to match the rotation.
\param rotation New rotation of the node in degrees. */
virtual void setRotation(const core::vector3df& rotation) =0;
//! Gets the current look at target of the camera
/** \return The current look at target of the camera, in world co-ordinates */
virtual const core::vector3df& getTarget() const =0;
//! Sets the up vector of the camera.
/** \param pos: New upvector of the camera. */
virtual void setUpVector(const core::vector3df& pos) =0;
//! Gets the up vector of the camera.
/** \return The up vector of the camera, in world space. */
virtual const core::vector3df& getUpVector() const =0;
//! Gets the value of the near plane of the camera.
/** \return The value of the near plane of the camera. */
virtual f32 getNearValue() const =0;
//! Gets the value of the far plane of the camera.
/** \return The value of the far plane of the camera. */
virtual f32 getFarValue() const =0;
//! Gets the aspect ratio of the camera.
/** \return The aspect ratio of the camera. */
virtual f32 getAspectRatio() const =0;
//! Gets the field of view of the camera.
/** \return The field of view of the camera in radians. */
virtual f32 getFOV() const =0;
//! Sets the value of the near clipping plane. (default: 1.0f)
/** \param zn: New z near value. */
virtual void setNearValue(f32 zn) =0;
//! Sets the value of the far clipping plane (default: 2000.0f)
/** \param zf: New z far value. */
virtual void setFarValue(f32 zf) =0;
//! Sets the aspect ratio (default: 4.0f / 3.0f)
/** \param aspect: New aspect ratio. */
virtual void setAspectRatio(f32 aspect) =0;
//! Sets the field of view (Default: PI / 2.5f)
/** \param fovy: New field of view in radians. */
virtual void setFOV(f32 fovy) =0;
//! Get the view frustum.
/** Needed sometimes by bspTree or LOD render nodes.
\return The current view frustum. */
virtual const SViewFrustum* getViewFrustum() const =0;
//! Disables or enables the camera to get key or mouse inputs.
/** If this is set to true, the camera will respond to key
inputs otherwise not. */
virtual void setInputReceiverEnabled(bool enabled) =0;
//! Checks if the input receiver of the camera is currently enabled.
virtual bool isInputReceiverEnabled() const =0;
//! Checks if a camera is orthogonal.
virtual bool isOrthogonal() const
{
_IRR_IMPLEMENT_MANAGED_MARSHALLING_BUGFIX;
return IsOrthogonal;
}
//! Binds the camera scene node's rotation to its target position and vice vera, or unbinds them.
/** When bound, calling setRotation() will update the camera's
target position to be along its +Z axis, and likewise calling
setTarget() will update its rotation so that its +Z axis will
point at the target point. FPS camera use this binding by
default; other cameras do not.
\param bound True to bind the camera's scene node rotation
and targetting, false to unbind them.
@see getTargetAndRotationBinding() */
virtual void bindTargetAndRotation(bool bound) =0;
//! Queries if the camera scene node's rotation and its target position are bound together.
/** @see bindTargetAndRotation() */
virtual bool getTargetAndRotationBinding(void) const =0;
//! Writes attributes of the camera node
virtual void serializeAttributes(io::IAttributes* out, io::SAttributeReadWriteOptions* options=0) const
{
ISceneNode::serializeAttributes(out, options);
if (!out)
return;
out->addBool ("IsOrthogonal", IsOrthogonal );
}
//! Reads attributes of the camera node
virtual void deserializeAttributes(io::IAttributes* in, io::SAttributeReadWriteOptions* options=0)
{
ISceneNode::deserializeAttributes(in, options);
if (!in)
return;
if ( in->findAttribute("IsOrthogonal") )
IsOrthogonal = in->getAttributeAsBool("IsOrthogonal");
}
protected:
void cloneMembers(ICameraSceneNode* toCopyFrom)
{
IsOrthogonal = toCopyFrom->IsOrthogonal;
}
bool IsOrthogonal;
};
} // end namespace scene
} // end namespace irr
#endif