/usr/include/OGRE/OgreTextureUnitState.h is in libogre-1.9-dev 1.9.0+dfsg1-7+b4.
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-----------------------------------------------------------------------------
This source file is part of OGRE
(Object-oriented Graphics Rendering Engine)
For the latest info, see http://www.ogre3d.org
Copyright (c) 2000-2013 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.
-----------------------------------------------------------------------------
*/
#ifndef __TextureUnitState_H__
#define __TextureUnitState_H__
#include "OgrePrerequisites.h"
#include "OgreCommon.h"
#include "OgreBlendMode.h"
#include "OgreMatrix4.h"
#include "OgreIteratorWrappers.h"
#include "OgreString.h"
#include "OgreTexture.h"
#include "OgreHeaderPrefix.h"
namespace Ogre {
/** \addtogroup Core
* @{
*/
/** \addtogroup Materials
* @{
*/
/** Class representing the state of a single texture unit during a Pass of a
Technique, of a Material.
@remarks
Texture units are pipelines for retrieving texture data for rendering onto
your objects in the world. Using them is common to both the fixed-function and
the programmable (vertex and fragment program) pipeline, but some of the
settings will only have an effect in the fixed-function pipeline (for example,
setting a texture rotation will have no effect if you use the programmable
pipeline, because this is overridden by the fragment program). The effect
of each setting as regards the 2 pipelines is commented in each setting.
@par
When I use the term 'fixed-function pipeline' I mean traditional rendering
where you do not use vertex or fragment programs (shaders). Programmable
pipeline means that for this pass you are using vertex or fragment programs.
*/
class _OgreExport TextureUnitState : public TextureUnitStateAlloc
{
friend class RenderSystem;
public:
/** Definition of the broad types of texture effect you can apply to a texture unit.
@note
Note that these have no effect when using the programmable pipeline, since their
effect is overridden by the vertex / fragment programs.
*/
enum TextureEffectType
{
/// Generate all texture coords based on angle between camera and vertex.
ET_ENVIRONMENT_MAP,
/// Generate texture coords based on a frustum.
ET_PROJECTIVE_TEXTURE,
/// Constant u/v scrolling effect.
ET_UVSCROLL,
/// Constant u scrolling effect.
ET_USCROLL,
/// Constant u/v scrolling effect.
ET_VSCROLL,
/// Constant rotation.
ET_ROTATE,
/// More complex transform.
ET_TRANSFORM
};
/** Enumeration to specify type of envmap.
@note
Note that these have no effect when using the programmable pipeline, since their
effect is overridden by the vertex / fragment programs.
*/
enum EnvMapType
{
/// Envmap based on vector from camera to vertex position, good for planar geometry.
ENV_PLANAR,
/// Envmap based on dot of vector from camera to vertex and vertex normal, good for curves.
ENV_CURVED,
/// Envmap intended to supply reflection vectors for cube mapping.
ENV_REFLECTION,
/// Envmap intended to supply normal vectors for cube mapping.
ENV_NORMAL
};
/** Useful enumeration when dealing with procedural transforms.
@note
Note that these have no effect when using the programmable pipeline, since their
effect is overridden by the vertex / fragment programs.
*/
enum TextureTransformType
{
TT_TRANSLATE_U,
TT_TRANSLATE_V,
TT_SCALE_U,
TT_SCALE_V,
TT_ROTATE
};
/** Texture addressing modes - default is TAM_WRAP.
@note
These settings are relevant in both the fixed-function and the
programmable pipeline.
*/
enum TextureAddressingMode
{
/// Texture wraps at values over 1.0.
TAM_WRAP,
/// Texture mirrors (flips) at joins over 1.0.
TAM_MIRROR,
/// Texture clamps at 1.0.
TAM_CLAMP,
/// Texture coordinates outside the range [0.0, 1.0] are set to the border colour.
TAM_BORDER,
/// Unknown
TAM_UNKNOWN = 99
};
/** Texture addressing mode for each texture coordinate. */
struct UVWAddressingMode
{
TextureAddressingMode u, v, w;
};
/** Enum identifying the frame indexes for faces of a cube map (not the composite 3D type.
*/
enum TextureCubeFace
{
CUBE_FRONT = 0,
CUBE_BACK = 1,
CUBE_LEFT = 2,
CUBE_RIGHT = 3,
CUBE_UP = 4,
CUBE_DOWN = 5
};
/** Internal structure defining a texture effect.
*/
struct TextureEffect {
TextureEffectType type;
int subtype;
Real arg1, arg2;
WaveformType waveType;
Real base;
Real frequency;
Real phase;
Real amplitude;
Controller<Real>* controller;
const Frustum* frustum;
};
/** Texture effects in a multimap paired array.
*/
typedef multimap<TextureEffectType, TextureEffect>::type EffectMap;
/** Default constructor.
*/
TextureUnitState(Pass* parent);
TextureUnitState(Pass* parent, const TextureUnitState& oth );
TextureUnitState & operator = ( const TextureUnitState& oth );
/** Default destructor.
*/
~TextureUnitState();
/** Name-based constructor.
@param texName
The basic name of the texture e.g. brickwall.jpg, stonefloor.png.
@param texCoordSet
The index of the texture coordinate set to use.
*/
TextureUnitState( Pass* parent, const String& texName, unsigned int texCoordSet = 0);
/** Get the name of current texture image for this layer.
@remarks
This will either always be a single name for this layer,
or will be the name of the current frame for an animated
or otherwise multi-frame texture.
@note
Applies to both fixed-function and programmable pipeline.
*/
const String& getTextureName(void) const;
/** Sets this texture layer to use a single texture, given the
name of the texture to use on this layer.
@note
Applies to both fixed-function and programmable pipeline.
*/
void setTextureName( const String& name, TextureType ttype = TEX_TYPE_2D);
/** Sets this texture layer to use a single texture, given the
pointer to the texture to use on this layer.
@note
Applies to both fixed-function and programmable pipeline.
*/
void setTexture( const TexturePtr& texPtr);
/** Sets this texture layer to use a combination of 6 texture maps, each one relating to a face of a cube.
@remarks
Cubic textures are made up of 6 separate texture images. Each one of these is an orthogonal view of the
world with a FOV of 90 degrees and an aspect ratio of 1:1. You can generate these from 3D Studio by
rendering a scene to a reflection map of a transparent cube and saving the output files.
@par
Cubic maps can be used either for skyboxes (complete wrap-around skies, like space) or as environment
maps to simulate reflections. The system deals with these 2 scenarios in different ways:
<ol>
<li>
<p>
for cubic environment maps, the 6 textures are combined into a single 'cubic' texture map which
is then addressed using 3D texture coordinates. This is required because you don't know what
face of the box you're going to need to address when you render an object, and typically you
need to reflect more than one face on the one object, so all 6 textures are needed to be
'active' at once. Cubic environment maps are enabled by calling this method with the forUVW
parameter set to true, and then calling setEnvironmentMap(true).
</p>
<p>
Note that not all cards support cubic environment mapping.
</p>
</li>
<li>
<p>
for skyboxes, the 6 textures are kept separate and used independently for each face of the skybox.
This is done because not all cards support 3D cubic maps and skyboxes do not need to use 3D
texture coordinates so it is simpler to render each face of the box with 2D coordinates, changing
texture between faces.
</p>
<p>
Skyboxes are created by calling SceneManager::setSkyBox.
</p>
</li>
</ol>
@note
Applies to both fixed-function and programmable pipeline.
@param name
The basic name of the texture e.g. brickwall.jpg, stonefloor.png. There must be 6 versions
of this texture with the suffixes _fr, _bk, _up, _dn, _lf, and _rt (before the extension) which
make up the 6 sides of the box. The textures must all be the same size and be powers of 2 in width & height.
If you can't make your texture names conform to this, use the alternative method of the same name which takes
an array of texture names instead.
@param forUVW
Set to @c true if you want a single 3D texture addressable with 3D texture coordinates rather than
6 separate textures. Useful for cubic environment mapping.
*/
void setCubicTextureName( const String& name, bool forUVW = false );
/** Sets this texture layer to use a combination of 6 texture maps, each one relating to a face of a cube.
@remarks
Cubic textures are made up of 6 separate texture images. Each one of these is an orthogonal view of the
world with a FOV of 90 degrees and an aspect ratio of 1:1. You can generate these from 3D Studio by
rendering a scene to a reflection map of a transparent cube and saving the output files.
@par
Cubic maps can be used either for skyboxes (complete wrap-around skies, like space) or as environment
maps to simulate reflections. The system deals with these 2 scenarios in different ways:
<ol>
<li>
<p>
For cubic environment maps, the 6 textures are combined into a single 'cubic' texture map which
is then addressed using 3D texture coordinates. This is required because you don't know what
face of the box you're going to need to address when you render an object, and typically you
need to reflect more than one face on the one object, so all 6 textures are needed to be
'active' at once. Cubic environment maps are enabled by calling this method with the forUVW
parameter set to @c true, and then calling setEnvironmentMap(true).
</p>
<p>
Note that not all cards support cubic environment mapping.
</p>
</li>
<li>
<p>
For skyboxes, the 6 textures are kept separate and used independently for each face of the skybox.
This is done because not all cards support 3D cubic maps and skyboxes do not need to use 3D
texture coordinates so it is simpler to render each face of the box with 2D coordinates, changing
texture between faces.
</p>
<p>
Skyboxes are created by calling SceneManager::setSkyBox.
</p>
</li>
</ol>
@note
Applies to both fixed-function and programmable pipeline.
@param names
The 6 names of the textures which make up the 6 sides of the box. The textures must all
be the same size and be powers of 2 in width & height.
Must be an Ogre::String array with a length of 6 unless forUVW is set to @c true.
@param forUVW
Set to @c true if you want a single 3D texture addressable with 3D texture coordinates rather than
6 separate textures. Useful for cubic environment mapping.
*/
void setCubicTextureName( const String* const names, bool forUVW = false );
/** Sets this texture layer to use a combination of 6 texture maps, each one relating to a face of a cube.
@remarks
Cubic textures are made up of 6 separate texture images. Each one of these is an orthogonal view of the
world with a FOV of 90 degrees and an aspect ratio of 1:1. You can generate these from 3D Studio by
rendering a scene to a reflection map of a transparent cube and saving the output files.
@par
Cubic maps can be used either for skyboxes (complete wrap-around skies, like space) or as environment
maps to simulate reflections. The system deals with these 2 scenarios in different ways:
<ol>
<li>
<p>
for cubic environment maps, the 6 textures are combined into a single 'cubic' texture map which
is then addressed using 3D texture coordinates. This is required because you don't know what
face of the box you're going to need to address when you render an object, and typically you
need to reflect more than one face on the one object, so all 6 textures are needed to be
'active' at once. Cubic environment maps are enabled by calling this method with the forUVW
parameter set to true, and then calling setEnvironmentMap(true).
</p>
<p>
Note that not all cards support cubic environment mapping.
</p>
</li>
<li>
<p>
for skyboxes, the 6 textures are kept separate and used independently for each face of the skybox.
This is done because not all cards support 3D cubic maps and skyboxes do not need to use 3D
texture coordinates so it is simpler to render each face of the box with 2D coordinates, changing
texture between faces.
</p>
<p>
Skyboxes are created by calling SceneManager::setSkyBox.
</p>
</li>
</ol>
@note
Applies to both fixed-function and programmable pipeline.
@param texPtrs
The 6 pointers to the textures which make up the 6 sides of the box. The textures must all
be the same size and be powers of 2 in width & height.
Must be an Ogre::TexturePtr array with a length of 6 unless forUVW is set to @c true.
@param forUVW
Set to @c true if you want a single 3D texture addressable with 3D texture coordinates rather than
6 separate textures. Useful for cubic environment mapping.
*/
void setCubicTexture( const TexturePtr* const texPtrs, bool forUVW = false );
/** Sets the names of the texture images for an animated texture.
@remarks
Animated textures are just a series of images making up the frames of the animation. All the images
must be the same size, and their names must have a frame number appended before the extension, e.g.
if you specify a name of "wall.jpg" with 3 frames, the image names must be "wall_0.jpg", "wall_1.jpg"
and "wall_2.jpg".
@par
You can change the active frame on a texture layer by calling the setCurrentFrame method.
@note
If you can't make your texture images conform to the naming standard laid out here, you
can call the alternative setAnimatedTextureName method which takes an array of names instead.
@note
Applies to both fixed-function and programmable pipeline.
@param name
The base name of the textures to use e.g. wall.jpg for frames wall_0.jpg, wall_1.jpg etc.
@param numFrames
The number of frames in the sequence.
@param duration
The length of time it takes to display the whole animation sequence, in seconds.
If 0, no automatic transition occurs.
*/
void setAnimatedTextureName( const String& name, unsigned int numFrames, Real duration = 0 );
/** Sets the names of the texture images for an animated texture.
@remarks
This an alternative method to the one where you specify a single name and let the system derive
the names of each frame, incase your images can't conform to this naming standard.
@par
Animated textures are just a series of images making up the frames of the animation. All the images
must be the same size, and you must provide their names as an array in the first parameter.
You can change the active frame on a texture layer by calling the setCurrentFrame method.
@note
If you can make your texture images conform to a naming standard of basicName_frame.ext, you
can call the alternative setAnimatedTextureName method which just takes a base name instead.
@note
Applies to both fixed-function and programmable pipeline.
@param names
Pointer to array of names of the textures to use, in frame order.
@param numFrames
The number of frames in the sequence.
@param duration
The length of time it takes to display the whole animation sequence, in seconds.
If 0, no automatic transition occurs.
*/
void setAnimatedTextureName( const String* const names, unsigned int numFrames, Real duration = 0 );
/** Returns the width and height of the texture in the given frame.
*/
std::pair< size_t, size_t > getTextureDimensions( unsigned int frame = 0 ) const;
/** Changes the active frame in an animated or multi-image texture.
@remarks
An animated texture (or a cubic texture where the images are not combined for 3D use) is made up of
a number of frames. This method sets the active frame.
@note
Applies to both fixed-function and programmable pipeline.
*/
void setCurrentFrame( unsigned int frameNumber );
/** Gets the active frame in an animated or multi-image texture layer.
@note
Applies to both fixed-function and programmable pipeline.
*/
unsigned int getCurrentFrame(void) const;
/** Gets the name of the texture associated with a frame number.
Throws an exception if frameNumber exceeds the number of stored frames.
@note
Applies to both fixed-function and programmable pipeline.
*/
const String& getFrameTextureName(unsigned int frameNumber) const;
/** Sets the name of the texture associated with a frame.
@param name
The name of the texture.
@param frameNumber
The frame the texture name is to be placed in.
@note
Throws an exception if frameNumber exceeds the number of stored frames.
Applies to both fixed-function and programmable pipeline.
*/
void setFrameTextureName(const String& name, unsigned int frameNumber);
/** Add a Texture name to the end of the frame container.
@param name
The name of the texture.
@note
Applies to both fixed-function and programmable pipeline.
*/
void addFrameTextureName(const String& name);
/** Deletes a specific texture frame. The texture used is not deleted but the
texture will no longer be used by the Texture Unit. An exception is raised
if the frame number exceeds the number of actual frames.
@param frameNumber
The frame number of the texture to be deleted.
@note
Applies to both fixed-function and programmable pipeline.
*/
void deleteFrameTextureName(const size_t frameNumber);
/** Gets the number of frames for a texture.
@note
Applies to both fixed-function and programmable pipeline.
*/
unsigned int getNumFrames(void) const;
/** The type of unit to bind the texture settings to. */
enum BindingType
{
/** Regular fragment processing unit - the default. */
BT_FRAGMENT = 0,
/** Vertex processing unit - indicates this unit will be used for
a vertex texture fetch.
*/
BT_VERTEX = 1,
/// Geometry processing unit
BT_GEOMETRY = 2,
/// Tesselation control processing unit
BT_TESSELATION_HULL = 3,
/// Tesselation evaluation processing unit
BT_TESSELATION_DOMAIN = 4,
/// Compute processing unit
BT_COMPUTE = 5
};
/** Enum identifying the type of content this texture unit contains.
*/
enum ContentType
{
/// Normal texture identified by name
CONTENT_NAMED = 0,
/// A shadow texture, automatically bound by engine
CONTENT_SHADOW = 1,
/// A compositor texture, automatically linked to active viewport's chain
CONTENT_COMPOSITOR = 2
};
/** Sets the type of unit these texture settings should be bound to.
@remarks
Some render systems, when implementing vertex texture fetch, separate
the binding of textures for use in the vertex program versus those
used in fragment programs. This setting allows you to target the
vertex processing unit with a texture binding, in those cases. For
rendersystems which have a unified binding for the vertex and fragment
units, this setting makes no difference.
*/
void setBindingType(BindingType bt);
/** Gets the type of unit these texture settings should be bound to.
*/
BindingType getBindingType(void) const;
/** Set the type of content this TextureUnitState references.
@remarks
The default is to reference a standard named texture, but this unit
can also reference automated content like a shadow texture.
*/
void setContentType(ContentType ct);
/** Get the type of content this TextureUnitState references. */
ContentType getContentType(void) const;
/** Returns true if this texture unit is either a series of 6 2D textures, each
in it's own frame, or is a full 3D cube map. You can tell which by checking
getTextureType.
@note
Applies to both fixed-function and programmable pipeline.
*/
bool isCubic(void) const;
/** Returns true if this texture layer uses a composite 3D cubic texture.
@note
Applies to both fixed-function and programmable pipeline.
*/
bool is3D(void) const;
/** Returns the type of this texture.
@note
Applies to both fixed-function and programmable pipeline.
*/
TextureType getTextureType(void) const;
/** Sets the desired pixel format when load the texture.
*/
void setDesiredFormat(PixelFormat desiredFormat);
/** Gets the desired pixel format when load the texture.
*/
PixelFormat getDesiredFormat(void) const;
/** Sets how many mipmaps have been requested for the texture.
*/
void setNumMipmaps(int numMipmaps);
/** Gets how many mipmaps have been requested for the texture.
*/
int getNumMipmaps(void) const;
/** Sets whether this texture is requested to be loaded as alpha if single channel
*/
void setIsAlpha(bool isAlpha);
/** Gets whether this texture is requested to be loaded as alpha if single channel
*/
bool getIsAlpha(void) const;
/// @copydoc Texture::getGamma
Real getGamma() const { return mGamma; }
/// @copydoc Texture::setGamma
void setGamma(Real gamma) { mGamma = gamma; }
/// @copydoc Texture::setHardwareGammaEnabled
void setHardwareGammaEnabled(bool enabled);
/// @copydoc Texture::isHardwareGammaEnabled
bool isHardwareGammaEnabled() const;
/** Gets the index of the set of texture co-ords this layer uses.
@note
Only applies to the fixed function pipeline and has no effect if a fragment program is used.
*/
unsigned int getTextureCoordSet(void) const;
/** Sets the index of the set of texture co-ords this layer uses.
@note
Default is 0 for all layers. Only change this if you have provided multiple texture co-ords per
vertex.
@note
Only applies to the fixed function pipeline and has no effect if a fragment program is used.
*/
void setTextureCoordSet(unsigned int set);
/** Sets a matrix used to transform any texture coordinates on this layer.
@remarks
Texture coordinates can be modified on a texture layer to create effects like scrolling
textures. A texture transform can either be applied to a layer which takes the source coordinates
from a fixed set in the geometry, or to one which generates them dynamically (e.g. environment mapping).
@par
It's obviously a bit impractical to create scrolling effects by calling this method manually since you
would have to call it every framw with a slight alteration each time, which is tedious. Instead
you can use the ControllerManager class to create a Controller object which will manage the
effect over time for you. See the ControllerManager::createTextureScroller and it's sibling methods for details.<BR>
In addition, if you want to set the individual texture transformations rather than concatenating them
yourself, use setTextureScroll, setTextureScale and setTextureRotate.
@note
Has no effect in the programmable pipeline.
*/
void setTextureTransform(const Matrix4& xform);
/** Gets the current texture transformation matrix.
@remarks
Causes a reclaculation of the matrix if any parameters have been changed via
setTextureScroll, setTextureScale and setTextureRotate.
@note
Has no effect in the programmable pipeline.
*/
const Matrix4& getTextureTransform(void) const;
/** Sets the translation offset of the texture, ie scrolls the texture.
@remarks
This method sets the translation element of the texture transformation, and is easier to use than setTextureTransform if
you are combining translation, scaling and rotation in your texture transformation. Again if you want
to animate these values you need to use a Controller
@note
Has no effect in the programmable pipeline.
@param u
The amount the texture should be moved horizontally (u direction).
@param v
The amount the texture should be moved vertically (v direction).
@see
ControllerManager, Controller
*/
void setTextureScroll(Real u, Real v);
/** As setTextureScroll, but sets only U value.
@note
Has no effect in the programmable pipeline.
*/
void setTextureUScroll(Real value);
/// Get texture uscroll value.
Real getTextureUScroll(void) const;
/** As setTextureScroll, but sets only V value.
@note
Has no effect in the programmable pipeline.
*/
void setTextureVScroll(Real value);
/// Get texture vscroll value.
Real getTextureVScroll(void) const;
/** As setTextureScale, but sets only U value.
@note
Has no effect in the programmable pipeline.
*/
void setTextureUScale(Real value);
/// Get texture uscale value.
Real getTextureUScale(void) const;
/** As setTextureScale, but sets only V value.
@note
Has no effect in the programmable pipeline.
*/
void setTextureVScale(Real value);
/// Get texture vscale value.
Real getTextureVScale(void) const;
/** Sets the scaling factor applied to texture coordinates.
@remarks
This method sets the scale element of the texture transformation, and is easier to use than
setTextureTransform if you are combining translation, scaling and rotation in your texture transformation. Again if you want
to animate these values you need to use a Controller (see ControllerManager and it's methods for
more information).
@note
Has no effect in the programmable pipeline.
@param uScale
The value by which the texture is to be scaled horizontally.
@param vScale
The value by which the texture is to be scaled vertically.
*/
void setTextureScale(Real uScale, Real vScale);
/** Sets the anticlockwise rotation factor applied to texture coordinates.
@remarks
This sets a fixed rotation angle - if you wish to animate this, see the
ControllerManager::createTextureRotater method.
@note
Has no effect in the programmable pipeline.
@param angle
The angle of rotation (anticlockwise).
*/
void setTextureRotate(const Radian& angle);
/// Get texture rotation effects angle value.
const Radian& getTextureRotate(void) const;
/** Gets the texture addressing mode for a given coordinate,
i.e. what happens at uv values above 1.0.
@note
The default is TAM_WRAP i.e. the texture repeats over values of 1.0.
*/
const UVWAddressingMode& getTextureAddressingMode(void) const;
/** Sets the texture addressing mode, i.e. what happens at uv values above 1.0.
@note
The default is TAM_WRAP i.e. the texture repeats over values of 1.0.
@note This is a shortcut method which sets the addressing mode for all
coordinates at once; you can also call the more specific method
to set the addressing mode per coordinate.
@note
This is a shortcut method which sets the addressing mode for all
coordinates at once; you can also call the more specific method
to set the addressing mode per coordinate.
@note
This applies for both the fixed-function and programmable pipelines.
*/
void setTextureAddressingMode( TextureAddressingMode tam);
/** Sets the texture addressing mode, i.e. what happens at uv values above 1.0.
@note
The default is TAM_WRAP i.e. the texture repeats over values of 1.0.
@note
This applies for both the fixed-function and programmable pipelines.
*/
void setTextureAddressingMode( TextureAddressingMode u,
TextureAddressingMode v, TextureAddressingMode w);
/** Sets the texture addressing mode, i.e. what happens at uv values above 1.0.
@note
The default is TAM_WRAP i.e. the texture repeats over values of 1.0.
@note
This applies for both the fixed-function and programmable pipelines.
*/
void setTextureAddressingMode( const UVWAddressingMode& uvw);
/** Sets the texture border colour.
@note
The default is ColourValue::Black, and this value only used when addressing mode
is TAM_BORDER.
@note
This applies for both the fixed-function and programmable pipelines.
*/
void setTextureBorderColour(const ColourValue& colour);
/** Sets the texture border colour.
@note
The default is ColourValue::Black, and this value only used when addressing mode
is TAM_BORDER.
*/
const ColourValue& getTextureBorderColour(void) const;
/** Setting advanced blending options.
@remarks
This is an extended version of the TextureUnitState::setColourOperation method which allows
extremely detailed control over the blending applied between this and earlier layers.
See the IMPORTANT note below about the issues between mulitpass and multitexturing that
using this method can create.
@par
Texture colour operations determine how the final colour of the surface appears when
rendered. Texture units are used to combine colour values from various sources (ie. the
diffuse colour of the surface from lighting calculations, combined with the colour of
the texture). This method allows you to specify the 'operation' to be used, ie. the
calculation such as adds or multiplies, and which values to use as arguments, such as
a fixed value or a value from a previous calculation.
@par
The defaults for each layer are:
<ul>
<li>op = LBX_MODULATE</li>
<li>source1 = LBS_TEXTURE</li>
<li>source2 = LBS_CURRENT</li>
</ul>
ie. each layer takes the colour results of the previous layer, and multiplies them
with the new texture being applied. Bear in mind that colours are RGB values from
0.0 - 1.0 so multiplying them together will result in values in the same range,
'tinted' by the multiply. Note however that a straight multiply normally has the
effect of darkening the textures - for this reason there are brightening operations
like LBO_MODULATE_X2. See the LayerBlendOperation and LayerBlendSource enumerated
types for full details.
@note
Because of the limitations on some underlying APIs (Direct3D included)
the LBS_TEXTURE argument can only be used as the first argument, not the second.
@par
The final 3 parameters are only required if you decide to pass values manually
into the operation, i.e. you want one or more of the inputs to the colour calculation
to come from a fixed value that you supply. Hence you only need to fill these in if
you supply LBS_MANUAL to the corresponding source, or use the LBX_BLEND_MANUAL
operation.
@warning
Ogre tries to use multitexturing hardware to blend texture layers
together. However, if it runs out of texturing units (e.g. 2 of a GeForce2, 4 on a
GeForce3) it has to fall back on multipass rendering, i.e. rendering the same object
multiple times with different textures. This is both less efficient and there is a smaller
range of blending operations which can be performed. For this reason, if you use this method
you MUST also call TextureUnitState::setColourOpMultipassFallback to specify which effect you
want to fall back on if sufficient hardware is not available.
@note
This has no effect in the programmable pipeline.
@par
If you wish to avoid having to do this, use the simpler TextureUnitState::setColourOperation method
which allows less flexible blending options but sets up the multipass fallback automatically,
since it only allows operations which have direct multipass equivalents.
@param op
The operation to be used, e.g. modulate (multiply), add, subtract.
@param source1
The source of the first colour to the operation e.g. texture colour.
@param source2
The source of the second colour to the operation e.g. current surface colour.
@param arg1
Manually supplied colour value (only required if source1 = LBS_MANUAL).
@param arg2
Manually supplied colour value (only required if source2 = LBS_MANUAL).
@param manualBlend
Manually supplied 'blend' value - only required for operations
which require manual blend e.g. LBX_BLEND_MANUAL.
*/
void setColourOperationEx(
LayerBlendOperationEx op,
LayerBlendSource source1 = LBS_TEXTURE,
LayerBlendSource source2 = LBS_CURRENT,
const ColourValue& arg1 = ColourValue::White,
const ColourValue& arg2 = ColourValue::White,
Real manualBlend = 0.0);
/** Determines how this texture layer is combined with the one below it (or the diffuse colour of
the geometry if this is layer 0).
@remarks
This method is the simplest way to blend tetxure layers, because it requires only one parameter,
gives you the most common blending types, and automatically sets up 2 blending methods: one for
if single-pass multitexturing hardware is available, and another for if it is not and the blending must
be achieved through multiple rendering passes. It is, however, quite limited and does not expose
the more flexible multitexturing operations, simply because these can't be automatically supported in
multipass fallback mode. If want to use the fancier options, use TextureUnitState::setColourOperationEx,
but you'll either have to be sure that enough multitexturing units will be available, or you should
explicitly set a fallback using TextureUnitState::setColourOpMultipassFallback.
@note
The default method is LBO_MODULATE for all layers.
@note
This option has no effect in the programmable pipeline.
@param op
One of the LayerBlendOperation enumerated blending types.
*/
void setColourOperation( const LayerBlendOperation op);
/** Sets the multipass fallback operation for this layer, if you used TextureUnitState::setColourOperationEx
and not enough multitexturing hardware is available.
@remarks
Because some effects exposed using TextureUnitState::setColourOperationEx are only supported under
multitexturing hardware, if the hardware is lacking the system must fallback on multipass rendering,
which unfortunately doesn't support as many effects. This method is for you to specify the fallback
operation which most suits you.
@par
You'll notice that the interface is the same as the Material::setSceneBlending method; this is
because multipass rendering IS effectively scene blending, since each layer is rendered on top
of the last using the same mechanism as making an object transparent, it's just being rendered
in the same place repeatedly to get the multitexture effect.
@par
If you use the simpler (and hence less flexible) TextureUnitState::setColourOperation method you
don't need to call this as the system sets up the fallback for you.
@note
This option has no effect in the programmable pipeline, because there is no multipass fallback
and multitexture blending is handled by the fragment shader.
*/
void setColourOpMultipassFallback( const SceneBlendFactor sourceFactor, const SceneBlendFactor destFactor);
/** Get multitexturing colour blending mode.
*/
const LayerBlendModeEx& getColourBlendMode(void) const;
/** Get multitexturing alpha blending mode.
*/
const LayerBlendModeEx& getAlphaBlendMode(void) const;
/** Get the multipass fallback for colour blending operation source factor.
*/
SceneBlendFactor getColourBlendFallbackSrc(void) const;
/** Get the multipass fallback for colour blending operation destination factor.
*/
SceneBlendFactor getColourBlendFallbackDest(void) const;
/** Sets the alpha operation to be applied to this texture.
@remarks
This works in exactly the same way as setColourOperation, except
that the effect is applied to the level of alpha (i.e. transparency)
of the texture rather than its colour. When the alpha of a texel (a pixel
on a texture) is 1.0, it is opaque, whereas it is fully transparent if the
alpha is 0.0. Please refer to the setColourOperation method for more info.
@param op
The operation to be used, e.g. modulate (multiply), add, subtract
@param source1
The source of the first alpha value to the operation e.g. texture alpha
@param source2
The source of the second alpha value to the operation e.g. current surface alpha
@param arg1
Manually supplied alpha value (only required if source1 = LBS_MANUAL)
@param arg2
Manually supplied alpha value (only required if source2 = LBS_MANUAL)
@param manualBlend
Manually supplied 'blend' value - only required for operations
which require manual blend e.g. LBX_BLEND_MANUAL
@see
setColourOperation
@note
This option has no effect in the programmable pipeline.
*/
void setAlphaOperation(LayerBlendOperationEx op,
LayerBlendSource source1 = LBS_TEXTURE,
LayerBlendSource source2 = LBS_CURRENT,
Real arg1 = 1.0,
Real arg2 = 1.0,
Real manualBlend = 0.0);
/** Generic method for setting up texture effects.
@remarks
Allows you to specify effects directly by using the TextureEffectType enumeration. The
arguments that go with it depend on the effect type. Only one effect of
each type can be applied to a texture layer.
@par
This method is used internally by Ogre but it is better generally for applications to use the
more intuitive specialised methods such as setEnvironmentMap and setScroll.
@note
This option has no effect in the programmable pipeline.
*/
void addEffect(TextureEffect& effect);
/** Turns on/off texture coordinate effect that makes this layer an environment map.
@remarks
Environment maps make an object look reflective by using the object's vertex normals relative
to the camera view to generate texture coordinates.
@par
The vectors generated can either be used to address a single 2D texture which
is a 'fish-eye' lens view of a scene, or a 3D cubic environment map which requires 6 textures
for each side of the inside of a cube. The type depends on what texture you set up - if you use the
setTextureName method then a 2D fisheye lens texture is required, whereas if you used setCubicTextureName
then a cubic environment map will be used.
@par
This effect works best if the object has lots of gradually changing normals. The texture also
has to be designed for this effect - see the example spheremap.png included with the sample
application for a 2D environment map; a cubic map can be generated by rendering 6 views of a
scene to each of the cube faces with orthogonal views.
@note
Enabling this disables any other texture coordinate generation effects.
However it can be combined with texture coordinate modification functions, which then operate on the
generated coordinates rather than static model texture coordinates.
@param enable
True to enable, false to disable
@param envMapType
The type of environment mapping to perform. Planar, curved, reflection or normal. @see EnvMapType
@note
This option has no effect in the programmable pipeline.
*/
void setEnvironmentMap(bool enable, EnvMapType envMapType = ENV_CURVED);
/** Sets up an animated scroll for the texture layer.
@note
Useful for creating constant scrolling effects on a texture layer (for varying scrolls, see setTransformAnimation).
@param uSpeed
The number of horizontal loops per second (+ve=moving right, -ve = moving left).
@param vSpeed
The number of vertical loops per second (+ve=moving up, -ve= moving down).
@note
This option has no effect in the programmable pipeline.
*/
void setScrollAnimation(Real uSpeed, Real vSpeed);
/** Sets up an animated texture rotation for this layer.
@note
Useful for constant rotations (for varying rotations, see setTransformAnimation).
@param speed
The number of complete anticlockwise revolutions per second (use -ve for clockwise)
@note
This option has no effect in the programmable pipeline.
*/
void setRotateAnimation(Real speed);
/** Sets up a general time-relative texture modification effect.
@note
This can be called multiple times for different values of ttype, but only the latest effect
applies if called multiple time for the same ttype.
@param ttype
The type of transform, either translate (scroll), scale (stretch) or rotate (spin).
@param waveType
The shape of the wave, see WaveformType enum for details.
@param base
The base value for the function (range of output = {base, base + amplitude}).
@param frequency
The speed of the wave in cycles per second.
@param phase
The offset of the start of the wave, e.g. 0.5 to start half-way through the wave.
@param amplitude
Scales the output so that instead of lying within 0..1 it lies within 0..1*amplitude for exaggerated effects.
@note
This option has no effect in the programmable pipeline.
*/
void setTransformAnimation( const TextureTransformType ttype,
const WaveformType waveType, Real base = 0, Real frequency = 1, Real phase = 0, Real amplitude = 1 );
/** Enables or disables projective texturing on this texture unit.
@remarks
Projective texturing allows you to generate texture coordinates
based on a Frustum, which gives the impression that a texture is
being projected onto the surface. Note that once you have called
this method, the texture unit continues to monitor the Frustum you
passed in and the projection will change if you can alter it. It also
means that you must ensure that the Frustum object you pass a pointer
to remains in existence for as long as this TextureUnitState does.
@par
This effect cannot be combined with other texture generation effects,
such as environment mapping. It also has no effect on passes which
have a vertex program enabled - projective texturing has to be done
in the vertex program instead.
@param enabled
Whether to enable / disable.
@param projectionSettings
The Frustum which will be used to derive the
projection parameters.
*/
void setProjectiveTexturing(bool enabled, const Frustum* projectionSettings = 0);
/** Removes all effects applied to this texture layer.
*/
void removeAllEffects(void);
/** Removes a single effect applied to this texture layer.
@note
Because you can only have 1 effect of each type (e.g. 1 texture coordinate generation) applied
to a layer, only the effect type is required.
*/
void removeEffect( const TextureEffectType type );
/** Determines if this texture layer is currently blank.
@note
This can happen if a texture fails to load or some other non-fatal error. Worth checking after
setting texture name.
*/
bool isBlank(void) const;
/** Sets this texture layer to be blank.
*/
void setBlank(void);
/** Tests if the texture associated with this unit has failed to load.
*/
bool isTextureLoadFailing() const { return mTextureLoadFailed; }
/** Tells the unit to retry loading the texture if it had failed to load.
*/
void retryTextureLoad() { mTextureLoadFailed = false; }
/// Get texture effects in a multimap paired array.
const EffectMap& getEffects(void) const;
/// Get the animated-texture animation duration.
Real getAnimationDuration(void) const;
/** Set the texture filtering for this unit, using the simplified interface.
@remarks
You also have the option of specifying the minification, magnification
and mip filter individually if you want more control over filtering
options. See the alternative setTextureFiltering methods for details.
@note
This option applies in both the fixed function and the programmable pipeline.
@param filterType
The high-level filter type to use.
*/
void setTextureFiltering(TextureFilterOptions filterType);
/** Set a single filtering option on this texture unit.
@param ftype
The filtering type to set.
@param opts
The filtering option to set.
*/
void setTextureFiltering(FilterType ftype, FilterOptions opts);
/** Set a the detailed filtering options on this texture unit.
@param minFilter
The filtering to use when reducing the size of the texture.
Can be FO_POINT, FO_LINEAR or FO_ANISOTROPIC.
@param magFilter
The filtering to use when increasing the size of the texture.
Can be FO_POINT, FO_LINEAR or FO_ANISOTROPIC.
@param mipFilter
The filtering to use between mip levels.
Can be FO_NONE (turns off mipmapping), FO_POINT or FO_LINEAR (trilinear filtering).
*/
void setTextureFiltering(FilterOptions minFilter, FilterOptions magFilter, FilterOptions mipFilter);
/// Get the texture filtering for the given type.
FilterOptions getTextureFiltering(FilterType ftpye) const;
void setTextureCompareEnabled(bool enabled);
bool getTextureCompareEnabled() const;
void setTextureCompareFunction(CompareFunction function);
CompareFunction getTextureCompareFunction() const;
/** Sets the anisotropy level to be used for this texture level.
@param maxAniso
The maximal anisotropy level, should be between 2 and the maximum
supported by hardware (1 is the default, ie. no anisotrophy).
@note
This option applies in both the fixed function and the programmable pipeline.
*/
void setTextureAnisotropy(unsigned int maxAniso);
/// Get this layer texture anisotropy level.
unsigned int getTextureAnisotropy() const;
/** Sets the bias value applied to the mipmap calculation.
@remarks
You can alter the mipmap calculation by biasing the result with a
single floating point value. After the mip level has been calculated,
this bias value is added to the result to give the final mip level.
Lower mip levels are larger (higher detail), so a negative bias will
force the larger mip levels to be used, and a positive bias
will cause smaller mip levels to be used. The bias values are in
mip levels, so a -1 bias will force mip levels one larger than by the
default calculation.
@param bias
The bias value as described above, can be positive or negative.
*/
void setTextureMipmapBias(float bias) { mMipmapBias = bias; }
/** Gets the bias value applied to the mipmap calculation.
@see TextureUnitState::setTextureMipmapBias
*/
float getTextureMipmapBias(void) const { return mMipmapBias; }
/** Set the compositor reference for this texture unit state.
@remarks
Only valid when content type is compositor.
@param compositorName
The name of the compositor to reference.
@param textureName
The name of the texture to reference.
@param mrtIndex
The index of the wanted texture, if referencing an MRT.
*/
void setCompositorReference(const String& compositorName, const String& textureName, size_t mrtIndex = 0);
/** Gets the name of the compositor that this texture referneces. */
const String& getReferencedCompositorName() const { return mCompositorRefName; }
/** Gets the name of the texture in the compositor that this texture references. */
const String& getReferencedTextureName() const { return mCompositorRefTexName; }
/** Gets the MRT index of the texture in the compositor that this texture references. */
size_t getReferencedMRTIndex() const { return mCompositorRefMrtIndex; }
/// Gets the parent Pass object.
Pass* getParent(void) const { return mParent; }
/** Internal method for preparing this object for load, as part of Material::prepare. */
void _prepare(void);
/** Internal method for undoing the preparation this object as part of Material::unprepare. */
void _unprepare(void);
/** Internal method for loading this object as part of Material::load. */
void _load(void);
/** Internal method for unloading this object as part of Material::unload. */
void _unload(void);
/// Returns whether this unit has texture coordinate generation that depends on the camera.
bool hasViewRelativeTextureCoordinateGeneration(void) const;
/// Is this loaded?
bool isLoaded(void) const;
/** Tells the class that it needs recompilation. */
void _notifyNeedsRecompile(void);
/** Set the name of the Texture Unit State.
@remarks
The name of the Texture Unit State is optional. Its useful in material scripts where a material could inherit
from another material and only want to modify a particalar Texture Unit State.
*/
void setName(const String& name);
/// Get the name of the Texture Unit State.
const String& getName(void) const { return mName; }
/** Set the alias name used for texture frame names.
@param name
Can be any sequence of characters and does not have to be unique.
*/
void setTextureNameAlias(const String& name);
/** Gets the Texture Name Alias of the Texture Unit.
*/
const String& getTextureNameAlias(void) const { return mTextureNameAlias;}
/** Applies texture names to Texture Unit State with matching texture name aliases.
If no matching aliases are found then the TUS state does not change.
@remarks
Cubic, 1d, 2d, and 3d textures are determined from current state of the Texture Unit.
Assumes animated frames are sequentially numbered in the name.
If matching texture aliases are found then true is returned.
@param aliasList
A map container of texture alias, texture name pairs.
@param apply
Set @c true to apply the texture aliases else just test to see if texture alias matches are found.
@return
True if matching texture aliases were found in the Texture Unit State.
*/
bool applyTextureAliases(const AliasTextureNamePairList& aliasList, const bool apply = true);
/** Notify this object that its parent has changed. */
void _notifyParent(Pass* parent);
/** Get the texture pointer for the current frame. */
const TexturePtr& _getTexturePtr(void) const;
/** Get the texture pointer for a given frame. */
const TexturePtr& _getTexturePtr(size_t frame) const;
/** Set the texture pointer for the current frame (internal use only!). */
void _setTexturePtr(const TexturePtr& texptr);
/** Set the texture pointer for a given frame (internal use only!). */
void _setTexturePtr(const TexturePtr& texptr, size_t frame);
size_t calculateSize(void) const;
/** Gets the animation controller (as created because of setAnimatedTexture)
if it exists.
*/
Controller<Real>* _getAnimController() const { return mAnimController; }
protected:
// State
/// The current animation frame.
unsigned int mCurrentFrame;
/// Duration of animation in seconds.
Real mAnimDuration;
bool mCubic; /// Is this a series of 6 2D textures to make up a cube?
TextureType mTextureType;
PixelFormat mDesiredFormat;
int mTextureSrcMipmaps; /// Request number of mipmaps.
unsigned int mTextureCoordSetIndex;
UVWAddressingMode mAddressMode;
ColourValue mBorderColour;
LayerBlendModeEx mColourBlendMode;
SceneBlendFactor mColourBlendFallbackSrc;
SceneBlendFactor mColourBlendFallbackDest;
LayerBlendModeEx mAlphaBlendMode;
mutable bool mTextureLoadFailed;
bool mIsAlpha;
bool mHwGamma;
Real mGamma;
mutable bool mRecalcTexMatrix;
Real mUMod, mVMod;
Real mUScale, mVScale;
Radian mRotate;
mutable Matrix4 mTexModMatrix;
/// Texture filtering - minification.
FilterOptions mMinFilter;
/// Texture filtering - magnification.
FilterOptions mMagFilter;
/// Texture filtering - mipmapping.
FilterOptions mMipFilter;
bool mCompareEnabled;
CompareFunction mCompareFunc;
/// Texture anisotropy.
unsigned int mMaxAniso;
/// Mipmap bias (always float, not Real).
float mMipmapBias;
bool mIsDefaultAniso;
bool mIsDefaultFiltering;
/// Binding type (fragment or vertex pipeline).
BindingType mBindingType;
/// Content type of texture (normal loaded texture, auto-texture).
ContentType mContentType;
/// The index of the referenced texture if referencing an MRT in a compositor.
size_t mCompositorRefMrtIndex;
//-----------------------------------------------------------------------------
// Complex members (those that can't be copied using memcpy) are at the end to
// allow for fast copying of the basic members.
//
vector<String>::type mFrames;
mutable vector<TexturePtr>::type mFramePtrs;
String mName; ///< Optional name for the TUS.
String mTextureNameAlias; ///< Optional alias for texture frames.
EffectMap mEffects;
/// The data that references the compositor.
String mCompositorRefName;
String mCompositorRefTexName;
//-----------------------------------------------------------------------------
//-----------------------------------------------------------------------------
// Pointer members (those that can't be copied using memcpy), and MUST
// preserving even if assign from others
//
Pass* mParent;
Controller<Real>* mAnimController;
//-----------------------------------------------------------------------------
/** Internal method for calculating texture matrix.
*/
void recalcTextureMatrix(void) const;
/** Internal method for creating animation controller.
*/
void createAnimController(void);
/** Internal method for creating texture effect controller.
*/
void createEffectController(TextureEffect& effect);
/** Internal method for ensuring the texture for a given frame is prepared. */
void ensurePrepared(size_t frame) const;
/** Internal method for ensuring the texture for a given frame is loaded. */
void ensureLoaded(size_t frame) const;
};
/** @} */
/** @} */
} // namespace Ogre
#include "OgreHeaderSuffix.h"
#endif // __TextureUnitState_H__
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