/usr/src/castle-game-engine-4.1.1/x3d/opengl/castlescene.pas is in castle-game-engine-src 4.1.1-1.
This file is owned by root:root, with mode 0o644.
The actual contents of the file can be viewed below.
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Copyright 2003-2013 Michalis Kamburelis.
This file is part of "Castle Game Engine".
"Castle Game Engine" is free software; see the file COPYING.txt,
included in this distribution, for details about the copyright.
"Castle Game Engine" is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.
----------------------------------------------------------------------------
}
{ VRML/X3D complete scene handling and OpenGL rendering (TCastleScene). }
unit CastleScene;
{$modeswitch nestedprocvars}{$H+}
interface
uses SysUtils, Classes, CastleVectors, CastleBoxes, X3DNodes, CastleClassUtils,
CastleUtils, CastleSceneCore, CastleRenderer, GL, GLU, GLExt, CastleBackground,
CastleGLUtils, CastleShapeOctree, CastleGLShadowVolumes, X3DFields, CastleTriangles,
CastleRendererLights, CastleShapes, CastleFrustum, Castle3D, CastleGLShaders, FGL,
CastleGenericLists;
{$define read_interface}
type
TGLShape = class;
TSceneRenderingAttributes = class;
TCastleSceneList = class;
TTestShapeVisibility = function (Shape: TGLShape): boolean of object;
{ Values for TSceneRenderingAttributes.WireframeEffect.
Generally, two other attributes may affect the way wireframe is rendered:
TSceneRenderingAttributes.WireframeColor and
TSceneRenderingAttributes.LineWidth, quite self-explanatory. }
TWireframeEffect = (
{ Default setting, model polygons are simply passed to OpenGL.
Whether this results in filled or wireframe look, depends on OpenGL
glPolygonMode setting, filled by default. }
weNormal,
{ The model is rendered in wireframe mode.
LineWidth is used as wireframe line width (regardless of
TSceneRenderingAttributes.Mode).
Depending on TSceneRenderingAttributes.Mode value:
@unorderedList(
@item(If <> rmFull then WireframeColor is used as wireframe
line color.)
@item(If rmFull, then lines are colored
and potentially lighted and textured just like their corresponding
triangles would be colored. So you can control lighting using
Lighting, UseSceneLights etc. attributes, and you
can control texturing by EnableTextures attribute.)
) }
weWireframeOnly,
{ The model is rendered as normal, with it's wireframe version visible
on top. This is most often called "solid wireframe", since the intention
is too see wireframe version of the model but still render shapes
solid (e.g. filled polygons with depth test).
WireframeColor and LineWidth are used as wireframe
line color/width (regardless of current scene
@link(TRenderingAttributes.Mode Attributes.Mode) value).
This usually gives best results when
@link(TRenderingAttributes.Mode Attributes.Mode) = rmPureGeometry.
Then current glColor sets the color of the solid model
(and, like said before, WireframeColor sets wireframe color). }
weSolidWireframe,
{ The model is rendered as normal, with silhouette outlined around it.
This works quite like weSolidWireframe, except that weSolidWireframe
makes the wireframe mesh slightly in front the model, while weSilhouette
makes the wireframe mesh slightly at the back of the model. This way
only the silhouette is visible from the wireframe rendering.
WireframeColor and LineWidth are used as silhouette
line color/width (regardless of current scene
@link(TRenderingAttributes.Mode Attributes.Mode) value).
This is sometimes sensible to use with
@link(TRenderingAttributes.Mode Attributes.Mode) = rmPureGeometry.
Then current glColor sets the color of the solid model
(and, like said before, WireframeColor sets wireframe color). }
weSilhouette);
TBeforeShapeRenderProc = procedure (Shape: TShape) of object;
TRenderingAttributesEvent = procedure (Attributes: TSceneRenderingAttributes) of object;
TSceneRenderingAttributes = class(TRenderingAttributes)
private
{ Scenes that use Renderer with this TSceneRenderingAttributes instance. }
FScenes: TCastleSceneList;
FBlending: boolean;
FBlendingSourceFactor: TGLenum;
FBlendingDestinationFactor: TGLenum;
FBlendingSort: boolean;
FControlBlending: boolean;
FWireframeColor: TVector3Single;
FWireframeEffect: TWireframeEffect;
FUseOcclusionQuery: boolean;
FUseHierarchicalOcclusionQuery: boolean;
FDebugHierOcclusionQueryResults: boolean;
{ Checks UseOcclusionQuery, existence of GL_ARB_occlusion_query,
and GLQueryCounterBits > 0. If @false, ARB_occlusion_query just cannot
be used.
Also, returns @false when UseHierarchicalOcclusionQuery is @true
--- because then UseHierarchicalOcclusionQuery should take precedence. }
function ReallyUseOcclusionQuery: boolean;
{ Checks UseHierarchicalOcclusionQuery, existence of GL_ARB_occlusion_query,
and GLQueryCounterBits > 0. If @false, ARB_occlusion_query just cannot
be used. }
function ReallyUseHierarchicalOcclusionQuery: boolean;
protected
procedure ReleaseCachedResources; override;
procedure SetBlending(const Value: boolean); virtual;
procedure SetBlendingSourceFactor(const Value: TGLenum); virtual;
procedure SetBlendingDestinationFactor(const Value: TGLenum); virtual;
procedure SetBlendingSort(const Value: boolean); virtual;
procedure SetControlBlending(const Value: boolean); virtual;
procedure SetUseOcclusionQuery(const Value: boolean); virtual;
procedure SetShaders(const Value: TShadersRendering); override;
public
const
{ }
DefaultBlendingSourceFactor = GL_SRC_ALPHA;
{ Default value of Attributes.BlendingDestinationFactor.
See TSceneRenderingAttributes.BlendingDestinationFactor.
Using ONE_MINUS_SRC_ALPHA is the standard value for 3D graphic stuff,
often producing best results. However, it causes troubles when
multiple transparent shapes are visible on the same screen pixel.
For closed convex 3D objects, using backface culling
(solid = TRUE for geometry) helps. For multiple transparent shapes,
sorting the transparent shapes helps,
see TSceneRenderingAttributes.BlendingSort.
Sometimes, no solution works for all camera angles.
Another disadvantage of ONE_MINUS_SRC_ALPHA may be that
the color of opaque shapes disappears too quickly from
resulting image (since GL_ONE_MINUS_SRC_ALPHA scales it down).
So the image may be darker than you like.
You can instead consider using GL_ONE, that doesn't require sorting
and never has problems with multiple transparent shapes.
On the other hand, it only adds to the color,
often making too bright results. }
DefaultBlendingDestinationFactor = GL_ONE_MINUS_SRC_ALPHA;
{ }
DefaultBlendingSort = false;
DefaultWireframeColor: TVector3Single = (0, 0, 0);
var
{ Adjust attributes of all loaded resources. }
OnCreate: TRenderingAttributesEvent; static;
constructor Create; override;
destructor Destroy; override;
procedure Assign(Source: TPersistent); override;
{ Render partially transparent objects.
More precisely: if this is @true, all shapes with
transparent materials or textures with non-trivial (not only yes/no)
alpha channel will be rendered using OpenGL blending
(with depth test off, like they should for OpenGL).
If this attribute is @false, everything will be rendered as opaque. }
property Blending: boolean
read FBlending write SetBlending default true;
{ Blending function parameters, used when @link(Blending).
See OpenGL documentation of glBlendFunc for possible values here.
See also DefaultBlendingDestinationFactor for comments about
GL_ONE and GL_ONE_MINUS_SRC_ALPHA.
Note that this is only a default, VRML/X3D model can override this
for specific shapes by using our extension BlendMode node.
See [http://castle-engine.sourceforge.net/x3d_extensions.php#section_ext_blending].
@groupBegin }
property BlendingSourceFactor: TGLenum
read FBlendingSourceFactor write SetBlendingSourceFactor
default DefaultBlendingSourceFactor;
property BlendingDestinationFactor: TGLenum
read FBlendingDestinationFactor write SetBlendingDestinationFactor
default DefaultBlendingDestinationFactor;
property BlendingSort: boolean
read FBlendingSort write SetBlendingSort
default DefaultBlendingSort;
{ @groupEnd }
{ Setting this to @false disables any modification of OpenGL
blending (and depth mask) state by TCastleScene.
This makes every other @link(Blending) setting ignored,
and is useful only if you set your own OpenGL blending parameters
when rendering this scene. }
property ControlBlending: boolean
read FControlBlending write SetControlBlending default true;
{ You can use this to turn on some effects related to rendering model
in special modes.
When this is weNormal (default), nothing special is
done, which means that model polygons are simply passed to OpenGL.
Whether this results in filled or wireframe, depends on OpenGL
glPolygonMode setting, filled by default.
How the wireframe effects work when Mode = rmDepth is undefined now.
Just don't use Mode = rmDepth if you're unsure.
See description of TWireframeEffect for what other modes do. }
property WireframeEffect: TWireframeEffect
read FWireframeEffect write FWireframeEffect default weNormal;
{ Wireframe color, used with some WireframeEffect values.
Default value is DefaultWireframeColor. }
property WireframeColor: TVector3Single
read FWireframeColor write FWireframeColor;
{ Should we use ARB_occlusion_query (if available) to avoid rendering
shapes that didn't pass occlusion test in previous frame.
Ignored if GPU doesn't support ARB_occlusion_query.
@true may give you a large speedup in some scenes.
OTOH, a lag of one frame may happen between an object should
be rendered and it actually appears.
When you render more than once the same instance of TCastleScene scene,
you should not activate it (as the occlusion query doesn't make sense
if each following render of the scene takes place at totally different
translation). Also, when rendering something more than just
one TCastleScene scene (maybe many times the same TCastleScene instance,
maybe many different TCastleScene instances, maybe some other
3D objects) you should try to sort rendering order
from the most to the least possible occluder (otherwise occlusion
query will not be as efficient at culling).
This is ignored if UseHierarchicalOcclusionQuery. }
property UseOcclusionQuery: boolean
read FUseOcclusionQuery write SetUseOcclusionQuery default false;
{ Should we use ARB_occlusion_query (if available) with
a hierarchical algorithm to avoid rendering
shapes that didn't pass occlusion test in previous frame.
Ignored if GPU doesn't support ARB_occlusion_query.
@true may give you a large speedup in some scenes.
This method doesn't impose any lag of one frame (like UseOcclusionQuery).
This requires the usage of TCastleSceneCore.OctreeRendering.
Also, it always does frustum culling (like fcBox for now),
regardless of TCastleScene.OctreeFrustumCulling setting.
The algorithm used underneath is "Coherent Hierarchical Culling",
described in detail in "GPU Gems 2",
Chapter 6: "Hardware Occlusion Queries Made Useful",
by Michael Wimmer and Jiri Bittner. Online on
[http://http.developer.nvidia.com/GPUGems2/gpugems2_chapter06.html]. }
property UseHierarchicalOcclusionQuery: boolean
read FUseHierarchicalOcclusionQuery
write FUseHierarchicalOcclusionQuery default false;
{ View only the shapes that were detected as visible by occlusion query
in last Render.
Use this only after render with UseHierarchicalOcclusionQuery.
TODO: for UseOcclusionQuery I would also like to make it work,
for now not done as frustum information is gone.
This will disable actual occlusion query,
instead reusing results from last occlusion
query done when this debug flag was @false.
Useful to quickly visualize the benefits of occlusion query. }
property DebugHierOcclusionQueryResults: boolean
read FDebugHierOcclusionQueryResults
write FDebugHierOcclusionQueryResults default false;
end;
{ TShape descendant for usage within TCastleScene.
Basically, this is just the same thing as TShape, with some
internal information needed by TCastleScene. }
TGLShape = class(TX3DRendererShape)
private
{ Keeps track if this shape was passed to Renderer.Prepare. }
PreparedForRenderer: boolean;
UseBlending: boolean;
{ Is UseBlending calculated and current. }
PreparedUseBlending: boolean;
procedure PrepareResources;
private
{ Private things only for RenderFrustumOctree ---------------------- }
RenderFrustumOctree_Visible: boolean;
{ ------------------------------------------------------------
Private things used only when Attributes.ReallyUseOcclusionQuery }
{ OcclusionQueryId is 0 if not initialized yet.
When it's 0, value of OcclusionQueryAsked doesn't matter,
OcclusionQueryAsked is always reset to @false when initializing
OcclusionQueryId. }
OcclusionQueryId: TGLint;
OcclusionQueryAsked: boolean;
{ For Hierarchical Occlusion Culling }
RenderedFrameId: Cardinal;
public
procedure Changed(const InactiveOnly: boolean;
const Changes: TX3DChanges); override;
end;
type
TPrepareResourcesOption = Castle3D.TPrepareResourcesOption;
TPrepareResourcesOptions = Castle3D.TPrepareResourcesOptions;
const
prRender = Castle3D.prRender;
prBackground = Castle3D.prBackground;
prBoundingBox = Castle3D.prBoundingBox;
prTrianglesListShadowCasters = Castle3D.prTrianglesListShadowCasters;
prManifoldAndBorderEdges = Castle3D.prManifoldAndBorderEdges;
type
{ Possible checks done while frustum culling.
This is used for TCastleScene.FrustumCulling (what checks
should be done when shapes octree is not available) and
TCastleScene.OctreeFrustumCulling (what checks
should be done when shapes octree is available).
In the second case, checks done by TFrustumCulling are applied
after octree traverse. That is, octree already eliminated some shapes,
and fully included some other shapes while traversing.
TFrustumCulling are used in this
case only as a "last resort", to check only the shapes in octree leaves
that are in "possibly-colliding" state with frustum.
Generally, more checks mean that more shapes may be eliminated but
also that we waste more time on checks themselves. What is optimal
depends on given 3D model, and how you expect the player to view it
(e.g. if player usually sees the whole model, then TFrustumCulling
checks may be useless waste of time; OTOH, if player stands inside
the model composed from many shapes then TFrustumCulling may help). }
TFrustumCulling = (
{ No checks.
Setting this as TCastleScene.FrustumCulling
turns off frustum culling entirely, which is usually not a wise thing
to do. Setting this as TCastleScene.OctreeFrustumCulling
means that frustum culling is only done during octree traversal
(we only visit octree nodes possibly colliding with frustum),
this is also not optimal. }
fcNone,
{ Check shape's bounding sphere for collision with frustum. }
fcSphere,
{ Check shape's bounding box for collision with frustum. }
fcBox,
{ Check shape's bounding sphere, and then box, for collision with frustum.
This is the most rigoristic check, but usually this is a waste of time:
in most cases, when bounding sphere collides, then bounding box
collides too. }
fcBoth
);
{ Basic non-abstact implementation of render params for calling T3D.Render.
@exclude
@bold(This is a hack, exposed here only to support some really weird
OpenGL tricks in engine example programs. Do not use this in your own code.)
To be used when you have to call T3D.Render, but you don't use scene manager.
Usually this should not be needed, and this class may be removed at some
point! You should always try to use TCastleSceneManager to manage and render
3D stuff in new programs, and then TCastleSceneManager will take care of creating
proper render params instance for you. }
TBasicRenderParams = class(TRenderParams)
public
FBaseLights: TLightInstancesList;
constructor Create;
destructor Destroy; override;
function BaseLights(Scene: T3D): TLightInstancesList; override;
end;
{ Complete handling and rendering of a 3D VRML/X3D scene.
This is a descendant of TCastleSceneCore that adds efficient rendering
using OpenGL.
This uses internal @link(TGLRenderer) instance,
adding some features and comfortable methods on top of it (like blending).
See @link(Render) method for some details.
This class also provides comfortable management for
@link(Background) instance to render the VRML/X3D background of this scene.
Calling methods PrepareResources, Render or Background connects this
class with current OpenGL context. Which means that all the following
calls should be done with the same OpenGL context set as current.
Calling GLContextClose or the destructor removes this connection. }
TCastleScene = class(TCastleSceneCore)
private
Renderer: TGLRenderer;
FReceiveShadowVolumes: boolean;
{ Cache used by this scene. Always initialized to non-nil by constructor. }
Cache: TGLRendererContextCache;
{ used by RenderScene }
FilteredShapes: TShapeList;
{ Render everything.
Calls Renderer.RenderBegin.
Then on all potentially visible Shapes[] calls RenderShape.
"Potentially visible" is decided by TestShapeVisibility
(shape is visible if TestShapeVisibility is @nil or returns
@true for this shape) and Params.Transparent value must include
given shape. At the end calls Renderer.RenderEnd.
Additionally this implements blending, looking at Attributes.Blending*,
setting appropriate OpenGL state and rendering partially transparent
shape before all opaque objects.
Updates Params.Statistics. }
procedure RenderScene(TestShapeVisibility: TTestShapeVisibility;
const Frustum: TFrustum;
const Params: TRenderParams);
{ Destroy any associations of Renderer with OpenGL context.
This also destroys associations with OpenGL context in this class
@italic(that were made using Renderer). This doesn't destroy other
associations, like Background.
This is useful to call when we change something in Attributes,
since changing most Attributes (besides color modulators ?)
requires that we disconnect Renderer from OpenGL context.
Other things, like Background, don't have to be destroyed in this case. }
procedure CloseGLRenderer;
private
FOwnsRenderer: boolean;
{ Fog for this shape. @nil if none. }
function ShapeFog(Shape: TShape): IAbstractFogObject;
private
{ Used by UpdateGeneratedTextures, to prevent rendering the shape
for which reflection texture is generated. (This wouldn't cause
recursive loop in our engine, but still it's bad --- rendering
from the inside of the object usually obscures the world around...). }
AvoidShapeRendering: TGLShape;
{ Used by UpdateGeneratedTextures, to prevent rendering non-shadow casters
for shadow maps. }
AvoidNonShadowCasterRendering: boolean;
PreparedShapesResouces, PreparedRender: boolean;
VarianceShadowMapsProgram: array [boolean] of TGLSLProgram;
{ Private things for RenderFrustum --------------------------------------- }
function FrustumCulling_None(Shape: TGLShape): boolean;
function FrustumCulling_Sphere(Shape: TGLShape): boolean;
function FrustumCulling_Box(Shape: TGLShape): boolean;
function FrustumCulling_Both(Shape: TGLShape): boolean;
private
FFrustumCulling: TFrustumCulling;
FOctreeFrustumCulling: TFrustumCulling;
procedure SetFrustumCulling(const Value: TFrustumCulling);
procedure SetOctreeFrustumCulling(const Value: TFrustumCulling);
private
FrustumCullingFunc: TTestShapeVisibility;
OctreeFrustumCullingFunc: TTestShapeVisibility;
RenderFrustum_Frustum: PFrustum;
function RenderFrustumOctree_TestShape(Shape: TGLShape): boolean;
procedure RenderFrustumOctree_EnumerateShapes(
ShapeIndex: Integer; CollidesForSure: boolean);
{ Turn off lights that are not supposed to light in the shadow.
This simply turns LightOn to @false if the light has
shadowVolumes = TRUE (see
[http://castle-engine.sourceforge.net/x3d_extensions.php#section_ext_shadows]).
It's useful to pass this as LightRenderEvent to @link(Render)
when you use shadow algorithm that requires
you to make a first pass rendering the scene all shadowed. }
class procedure LightRenderInShadow(const Light: TLightInstance;
var LightOn: boolean);
{ shadow things ---------------------------------------------------------- }
{ Rendering shadow volumes.
There are two algorithms here:
@orderedList(
@item(Rendering with silhouette optimization.
This renders shadow quads of silhouette edge. Edges from ManifoldEdges
list are used to find silhouette edge. Additionally edges from
BorderEdges always produce shadow quads, i.e. we treat them
like they would always be silhouette edges.
The very idea of this optimization is that most edges are in
ManifoldEdges and so only real silhouette edges produce shadow quads.
In other words, BorderEdges list should not contain too many items.
When BorderEdges contains all edges (ManifoldEdges is empty), then
this method degenerates to a naive rendering without silhouette
optimization. So you should try to make your models as much as
possible resembling nice 2-manifolds. Ideally, if your mesh
is a number of perfectly closed manifolds, and vertex ordering
is consistent, then BorderEdges is empty, and this works perfect.
Usually, most models are mostly 2-manifold (only the real border
edges are, well, in BorderEdges), and this works great.
See "VRML engine documentation" on
[http://castle-engine.sourceforge.net/engine_doc.php],
chapter "Shadows", for description and pictures of possible artifacts
when trying to use this on models that are not 2-manifold.)
@item(Without silhouette optimization.
This is the naive approach that just renders
3 shadow quads for each triangle.
It is so slow that there's no public way to actually
get this behavior, you have to edit source code and set
AllowSilhouetteOptimization constant to false if you really want this.
In all real uses, it's better to
fix your 3D model to be correct 2-manifold.)
)
LightCap and DarkCap say whether you want to cap your shadow volume.
LightCap is the cap at the caster position, DarkCap is the cap in infinity.
This is needed by z-fail method, you should set them both to @true.
To be more optimal, you can request LightCap only if z-fail @italic(and
the caster is inside camera frustum). For directional lights, DarkCap is
ignored, since the volume is always closed by a single point in infinity.
}
procedure RenderSilhouetteShadowVolume(
const LightPos: TVector4Single;
const TransformIsIdentity: boolean;
const Transform: TMatrix4Single;
const LightCap, DarkCap: boolean);
procedure RenderAllShadowVolume(
const LightPos: TVector4Single;
const TransformIsIdentity: boolean;
const Transform: TMatrix4Single;
LightCap, DarkCap: boolean);
private
{ For Hierarchical Occlusion Culling }
FrameId: Cardinal;
protected
function CreateShape(AGeometry: TAbstractGeometryNode;
AState: TX3DGraphTraverseState; ParentInfo: PTraversingInfo): TShape; override;
procedure InvalidateBackground; override;
public
constructor Create(AOwner: TComponent); override;
constructor CreateCustomCache(AOwner: TComponent; ACache: TGLRendererContextCache);
{ A very special constructor, that forces this class to use
provided ACustomRenderer. ACustomRenderer must be <> @nil.
Note that this renderer must be created with AttributesClass
= TSceneRenderingAttributes.
@italic(Don't use this unless you really know what you're doing!)
In all normal circumstances you should use normal @link(Create)
constructor, that will internally create and use internal renderer object.
If you use this constructor you will have to understand how internally
this class synchronizes itself with underlying Renderer object.
Once again, if you're not sure, then simply don't use this
constructor. It's for internal use --- namely it's internally used
by TCastlePrecalculatedAnimation, this way all scenes of the animation share
the same renderer which means that they also share the same
information about textures and images loaded into OpenGL.
And this is crucial for TCastlePrecalculatedAnimation, otherwise animation with
100 scenes would load the same texture to OpenGL 100 times. }
constructor CreateCustomRenderer(AOwner: TComponent;
ACustomRenderer: TGLRenderer);
destructor Destroy; override;
{ Destroy any associations of this object with current OpenGL context.
For example, release any allocated texture names.
Generally speaking, destroys everything that is allocated by
PrepareResources call. It's harmless to call this
method when there are already no associations with current OpenGL context.
This is called automatically from the destructor. }
procedure GLContextClose; override;
procedure PrepareResources(Options: TPrepareResourcesOptions;
ProgressStep: boolean; BaseLights: TAbstractLightInstancesList); override;
{ Render for OpenGL. The rendering parameters are configurable
by @link(Attributes), see TSceneRenderingAttributes and
TRenderingAttributes.
For more details about rendering, see @link(CastleRenderer) unit comments.
This method internally uses TGLRenderer instance, additionally
handling the blending:
@unorderedList(
@item(
OpenGL state of glDepthMask, glEnable/Disable(GL_BLEND), glBlendFunc
is controlled by this function. This function will unconditionally
change (and restore later to original value) this state,
to perform correct blending (transparency rendering).
To make a correct rendering, we always
render transparent shapes at the end (after all opaque),
and with depth-buffer in read-only mode.)
@item(Only a subset of shapes indicated by Params.Transparent is rendered.
This is necessary if you want to mix in one 3D world many scenes
(like TCastleScene instances), and each of them may have some opaque
and some transparent
parts. In such case, you want to render everything opaque
(from every scene) first, and only then render everything transparent.
For shadow volumes, this is even more complicated.)
@item(Note that when Attributes.Blending is @false then everything
is always opaque, so tgOpaque renders everything and tgTransparent
renders nothing.)
)
@param(TestShapeVisibility Filters which shapes are visible.
You can use this to optimize rendering. For example
you can reject shapes because their bounding volume
(bounding boxes or bounding spheres) doesn't intersect with frustum
or such. This is called frustum culling, and in fact is done
automatically by other overloaded Render methods in this class,
see FrustumCulling and OctreeFrustumCulling.
TestShapeVisibility callback may be used to implement frustum
culling, or some other visibility algorithm.) }
procedure Render(TestShapeVisibility: TTestShapeVisibility;
const Frustum: TFrustum;
const Params: TRenderParams);
procedure Render(const Frustum: TFrustum; const Params: TRenderParams); override;
procedure BeforeNodesFree(const InternalChangedAll: boolean = false); override;
{ Render shadow volume (sides and caps) of this scene, for shadow volume
algorithm. Checks ShadowVolumeRenderer.InitScene to know if the shadow
needs to be rendered at all.
It will calculate current bounding box (looking at ParentTransform,
ParentTransformIsIdentity and BoundingBox method).
It always uses silhouette optimization. This is the usual,
fast method of rendering shadow volumes.
Will not do anything (treat scene like not casting shadows,
like CastShadowVolumes = false) if the model is not perfect 2-manifold,
i.e. has some BorderEdges (although we could handle some BorderEdges
for some points of view, this was always inherently dangerous
and leading to rendering artifacts).
See RenderSilhouetteShadowVolume, RenderAllShadowVolume comments in code
for more explanation.
All shadow quads are generated from scene triangles transformed
by ParentTransform. We must be able to correctly detect front and
back facing triangles with respect to light position,
so ShadowVolumeRenderer.LightPosition and
"this scene transformed by ParentTransform" must be in the same coordinate system.
That's why explicit ParentTransform parameter is needed, you can't get away
with simply doing glPush/PopMatrix and glMultMatrix around RenderShadowVolume
call. If ParentTransformIsIdentity then ParentTransform value is ignored and
everything works like ParentTransform = identity matrix (and is a little
faster in this special case).
Uses TrianglesListShadowCasters and ManifoldEdges and BorderEdges
(so you may prefer to prepare it before, e.g. by calling PrepareResources
with prShadowVolume included).
We look at some Attributes, like Attributes.Blending, because transparent
triangles have to be handled a little differently, and when
Attributes.Blending = false then all triangles are forced to be opaque.
In other words, this takes Attributes into account, to cooperate with
our Render method.
ShadowVolumeRenderer.LightPosition is the light position.
ShadowVolumeRenderer.LightPosition[3] must be 1
(to indicate positional light) or 0 (a directional light).
It's expected that ShadowVolumeRenderer is already initialized by
ShadowVolumeRenderer.InitFrustumAndLight.
Faces (both shadow quads and caps) are rendered such that
CCW <=> you're looking at it from outside
(i.e. it's considered front face of this shadow volume).
All the commands passed to OpenGL by this methods are:
glBegin, sequence of glVertex, then glEnd. }
procedure RenderShadowVolume(
ShadowVolumeRenderer: TBaseShadowVolumeRenderer;
const ParentTransformIsIdentity: boolean;
const ParentTransform: TMatrix4Single); override;
{ Render silhouette edges.
Silhouette is determined from the ObserverPos.
Whole scene is transformed by Transform (before checking which
edges are silhouette and before rendering). In other words,
Transform must transform the scene to the same coord space where
given ObserverPos is. When they are in the same space, just use
IdentityMatrix4Single.
This implicitly creates and uses ManifoldEdges. In fact, one of the uses
of this is to visually see that ManifoldEdges are coorect. }
procedure RenderSilhouetteEdges(
const ObserverPos: TVector4Single;
const Transform: TMatrix4Single);
{ Render all border edges (the edges without neighbor).
This implicitly creates and uses BorderEdges. In fact, one of the uses
of this is to visually see that BorderEdges are coorect. }
procedure RenderBorderEdges(
const Transform: TMatrix4Single);
private
FBackgroundSkySphereRadius: Single;
{ Node for which FBackground is currently prepared. }
FBackgroundNode: TAbstractBindableNode;
{ Cached Background value }
FBackground: TBackground;
{ Is FBackground valid ? We can't use "nil" FBackground value to flag this
(bacause nil is valid value for Background function).
If not FBackgroundValid then FBackground must always be nil.
Never set FBackgroundValid to false directly - use InvalidateBackground,
this will automatically call FreeAndNil(FBackground) before setting
FBackgroundValid to false. }
FBackgroundValid: boolean;
procedure SetBackgroundSkySphereRadius(const Value: Single);
procedure PrepareBackground;
public
property BackgroundSkySphereRadius: Single
read FBackgroundSkySphereRadius write SetBackgroundSkySphereRadius
default 1;
{ TBackground instance to render current background. Current background
is the top node on the BackgroundStack of this scene, following VRML/X3D
specifications, and can be dynamic.
The scene manager should use this to render background.
We use the current value of BackgroundSkySphereRadius.
Returns @nil if there is no currently bound background node
in this scene, or if the bound background is not supported for now
(the latter case right now happens with TextureBakckground).
This instance is managed (automatically created/freed
and so on) by this TCastleScene instance. It is cached
(so that it's recreated only when relevant things change,
like VRML/X3D nodes affecting this background,
or changes to BackgroundSkySphereRadius, or OpenGL context is closed). }
function Background: TBackground;
{ Rendering attributes.
You are free to change them all at any time.
Although note that changing some attributes (the ones defined
in base TRenderingAttributes class) may be a costly operation
(next PrepareResources with prRender, or Render call, may need
to recalculate some things). }
function Attributes: TSceneRenderingAttributes;
procedure UpdateGeneratedTextures(
const RenderFunc: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
const OriginalViewportX, OriginalViewportY: LongInt;
const OriginalViewportWidth, OriginalViewportHeight: Cardinal); override;
procedure ViewChangedSuddenly; override;
procedure VisibleChangeNotification(const Changes: TVisibleChanges); override;
{ Screen effects information, used by TCastleAbstractViewport.ScreenEffects.
ScreenEffectsCount may actually prepare screen effects.
@groupBegin }
function ScreenEffects(Index: Integer): TGLSLProgram;
function ScreenEffectsCount: Integer;
function ScreenEffectsNeedDepth: boolean;
{ @groupEnd }
published
{ Fine-tune performance of @link(Render) when
OctreeRendering is @italic(not) available.
@link(Render) tests each Shape for collision with given Frustum
before rendering this Shape. It can use Shape.BoundingBox
or Shape.BoundingSphere or both.
See TFrustumCulling.
Shape.BoundingBox is (in a current implementation) always
a better approximation of shape geometry than Shape.BoundingSphere.
So advantage of using Shape.BoundingBox is that more Shapes
may be eliminated. Advantage of using Shape.BoundingSphere
is that checking for collision Frustum<->Sphere is faster,
so you don't waste so much time on testing for collisions between
frustum and Shape. }
property FrustumCulling: TFrustumCulling
read FFrustumCulling write SetFrustumCulling default fcBox;
{ Fine-tune performance of @link(Render) when
OctreeRendering @italic(is available).
See TFrustumCulling. }
property OctreeFrustumCulling: TFrustumCulling
read FOctreeFrustumCulling write SetOctreeFrustumCulling default fcBox;
property ReceiveShadowVolumes: boolean
read FReceiveShadowVolumes write FReceiveShadowVolumes default true;
end;
TCastleSceneList = class(specialize TFPGObjectList<TCastleScene>)
private
{ Just call InvalidateBackground or CloseGLRenderer on all items.
These methods are private, because corresponding methods in
TCastleScene are also private and we don't want to expose
them here. }
procedure InvalidateBackground;
procedure CloseGLRenderer;
public
{ Just call GLContextClose on all items. }
procedure GLContextClose;
{ Just call ViewChangedSuddenly on all items. }
procedure ViewChangedSuddenly;
end;
const
{ Options to pass to TCastleScene.PrepareResources to make
sure that rendering with shadow volumes is as fast as possible.
For now this actually could be equal to prManifoldEdges
(prTrianglesListShadowCasters has to be prepared while preparing
ManifoldEdges edges anyway). But for the future shadow volumes
optimizations, it's best to use this constant. }
prShadowVolume = [prTrianglesListShadowCasters, prManifoldAndBorderEdges];
type
TTriangle4SingleList = specialize TGenericStructList<TTriangle4Single>;
procedure Register;
var
{ Global OpenGL context cache.
This caches common things, like textures, shapes, and much more.
Our OpenGL resources are currently shared across all OpenGL contexts,
and they all automatically share this cache. }
GLContextCache: TGLRendererContextCache;
implementation
uses CastleGLVersion, CastleImages, CastleLog, CastleWarnings,
CastleStringUtils, CastleRenderingCamera;
var
TemporaryAttributeChange: Cardinal = 0;
procedure Register;
begin
RegisterComponents('Castle', [TCastleScene]);
end;
{ TGLShape --------------------------------------------------------------- }
procedure TGLShape.Changed(const InactiveOnly: boolean;
const Changes: TX3DChanges);
var
GLScene: TCastleScene;
begin
inherited;
GLScene := TCastleScene(ParentScene);
if Cache <> nil then
begin
{ Ignore changes that don't affect prepared arrays,
like transformation, clip planes and everything else that is applied
by renderer every time, and doesn't affect TGeometryArrays. }
if Changes * [chCoordinate] <> [] then
Cache.FreeArrays([vtCoordinate]) else
if Changes * [chVisibleVRML1State, chGeometryVRML1State,
chColorNode, chTextureCoordinate, chGeometry, chFontStyle] <> [] then
Cache.FreeArrays(AllVboTypes);
end;
if Changes * [chTextureImage, chTextureRendererProperties] <> [] then
begin
GLScene.Renderer.UnprepareTexture(State.Texture);
PreparedForRenderer := false;
PreparedUseBlending := false;
{ PreparedShapesResouces must be reset, otherwise scene will not even
call our PrepareResources next time. }
GLScene.PreparedShapesResouces := false;
end;
{ When Material.transparency changes, recalculate UseBlending. }
if chUseBlending in Changes then
begin
PreparedUseBlending := false;
{ PreparedShapesResouces must be reset, otherwise scene will not even
call our PrepareResources next time. }
GLScene.PreparedShapesResouces := false;
end;
end;
procedure TGLShape.PrepareResources;
var
GLScene: TCastleScene;
begin
GLScene := TCastleScene(ParentScene);
if not PreparedForRenderer then
begin
GLScene.Renderer.Prepare(State);
PreparedForRenderer := true;
end;
if not PreparedUseBlending then
begin
{ UseBlending is used by RenderScene to decide is Blending used for given
shape. }
UseBlending := Transparent;
PreparedUseBlending := true;
end;
if GLScene.Attributes.ReallyUseOcclusionQuery and
(OcclusionQueryId = 0) then
begin
glGenQueriesARB(1, @OcclusionQueryId);
OcclusionQueryAsked := false;
end;
end;
{ ShapesSplitBlending ---------------------------------------------------- }
{ Fill a TShapeList with only opaque (UseBlending = @false) or
only transparent shapes (UseBlending = @true). }
procedure ShapesFilterBlending(
Tree: TShapeTree;
const OnlyActive, OnlyVisible, OnlyCollidable: boolean;
TestShapeVisibility: TTestShapeVisibility;
const FilteredShapes: TShapeList; const UseBlending: boolean);
procedure AddToList(Shape: TShape);
begin
if TGLShape(Shape).UseBlending = UseBlending then
FilteredShapes.Add(Shape);
end;
procedure AddToListIfTested(Shape: TShape);
begin
if (TGLShape(Shape).UseBlending = UseBlending) and
TestShapeVisibility(TGLShape(Shape)) then
FilteredShapes.Add(Shape);
end;
var
Capacity: Integer;
begin
FilteredShapes.Clear;
{ Set Capacity to max value at the beginning, to speed adding items later. }
Capacity := Tree.ShapesCount(OnlyActive, OnlyVisible, OnlyCollidable);
FilteredShapes.Capacity := Capacity;
if Assigned(TestShapeVisibility) then
Tree.Traverse(@AddToListIfTested, OnlyActive, OnlyVisible, OnlyCollidable) else
Tree.Traverse(@AddToList, OnlyActive, OnlyVisible, OnlyCollidable);
end;
{ TBasicRenderParams --------------------------------------------------------- }
constructor TBasicRenderParams.Create;
begin
inherited;
FBaseLights := TLightInstancesList.Create;
InShadow := false;
{ Transparent and ShadowVolumesReceivers do not have good default values.
User of TBasicRenderParams should call Render method with
all 4 combinations of them, to really render everything correctly.
We just set them here to capture most 3D objects
(as using TBasicRenderParams for anything is a discouraged hack anyway). }
ShadowVolumesReceivers := true;
Transparent := false;
end;
destructor TBasicRenderParams.Destroy;
begin
FreeAndNil(FBaseLights);
inherited;
end;
function TBasicRenderParams.BaseLights(Scene: T3D): TLightInstancesList;
begin
Result := FBaseLights;
end;
{ TCastleScene ------------------------------------------------------------ }
constructor TCastleScene.Create(AOwner: TComponent);
begin
{ inherited Create *may* call some virtual things overriden here
(although right now it doesn't): it may bind new viewpoint which
may call ViewChangedSuddenly which is overridden here and uses Attributes.
That's why I have to initialize them *before* "inherited Create" }
{ Cache may be already assigned, when we came here from
CreateCustomRenderer or CreateCustomCache. }
if Cache = nil then
Cache := GLContextCache;
{ Renderer may be already assigned, when we came here from
CreateCustomRenderer. }
if Renderer = nil then
begin
FOwnsRenderer := true;
Renderer := TGLRenderer.Create(TSceneRenderingAttributes, Cache);
end;
Assert(Renderer.Attributes is TSceneRenderingAttributes);
{ Note that this calls Renderer.Attributes, so use this after
initializing Renderer. }
Attributes.FScenes.Add(Self);
inherited Create(AOwner);
FBackgroundSkySphereRadius := 1.0;
FBackgroundValid := false;
FBackgroundNode := nil;
FBackground := nil;
FFrustumCulling := fcBoth;
FrustumCulling := fcBox; { set through property setter }
FOctreeFrustumCulling := fcBoth;
OctreeFrustumCulling := fcBox; { set through property setter }
FReceiveShadowVolumes := true;
FilteredShapes := TShapeList.Create;
end;
constructor TCastleScene.CreateCustomCache(
AOwner: TComponent; ACache: TGLRendererContextCache);
begin
Assert(ACache <> nil);
Cache := ACache;
Create(AOwner);
end;
constructor TCastleScene.CreateCustomRenderer(
AOwner: TComponent; ACustomRenderer: TGLRenderer);
begin
FOwnsRenderer := false;
Renderer := ACustomRenderer;
CreateCustomCache(AOwner, ACustomRenderer.Cache);
end;
destructor TCastleScene.Destroy;
begin
FreeAndNil(FilteredShapes);
GLContextClose;
{ Note that this calls Renderer.Attributes, so use this before
deinitializing Renderer. }
if Renderer <> nil then
Attributes.FScenes.Remove(Self);
if FOwnsRenderer then
begin
{ We must release all connections between RootNode and Renderer first.
Reason: when freeing RootNode, image references (from texture nodes)
are decremented. So cache used when loading these images must be
available.
If we used custom renderer, then this is not
our problem: if OwnsRootNode then RootNode will be freed soon
by "inherited", if not OwnsRootNode then it's the using programmer
responsibility to free both RootNode and CustomRenderer
in exactly this order.
If we used our own renderer (actually, this is needed only if we used
own own cache, so caller didn't provide a renderer and didn't provide
a cache (ACache = nil for constructor), but we don't store this information
for now) : we must make sure that freeing RootNode is safe.
If OwnsRootNode then we know that inherited will free RootNode
and so the simpler solution, to just FreeAndNil(Renderer) after
inherited, would be possible. But it's not possible, since
OwnsRootNode may be false and then programmer may want to free
RootNode at undefined later time.
So we have to guarantee, *now*, that freeing RootNode is safe ---
no dangling references to Renderer.Cache. }
FreeResources([frTextureDataInNodes, frBackgroundImageInNodes]);
FreeAndNil(Renderer);
end else
Renderer := nil;
Cache := nil; // just for safety
inherited;
end;
function TCastleScene.CreateShape(AGeometry: TAbstractGeometryNode;
AState: TX3DGraphTraverseState; ParentInfo: PTraversingInfo): TShape;
begin
Result := TGLShape.Create(Self, AGeometry, AState, ParentInfo);
end;
procedure TCastleScene.CloseGLRenderer;
{ This must be coded carefully, because
- it's called by ChangedAll, and so may be called when our constructor
didn't do it's work yet.
- moreover it's called from destructor, so may be called if our
constructor terminated with exception.
This explains that we have to check Renderer <> nil, Shapes <> nil. }
procedure CloseGLScreenEffect(Node: TScreenEffectNode);
begin
{ The TGLSLProgram instance here will be released by Rendered.UnprepareAll,
that eventually calls GLSLRenderers.UnprepareAll,
that eventually calls Cache.GLSLProgram_DecReference on this shader,
that eventuallly destroys TGLSLProgram instance.
So below only set it to nil. }
Node.Shader := nil;
Node.ShaderLoaded := false;
end;
var
SI: TShapeTreeIterator;
S: TGLShape;
I: Integer;
Pass: TRenderingPass;
begin
PreparedRender := false;
PreparedShapesResouces := false;
{ Free Arrays and Vbo of all shapes. }
if (Renderer <> nil) and (Shapes <> nil) then
begin
{ Iterate even over non-visible shapes, for safety:
since this CloseGLRenderer may happen after some
"visibility" changed, that is you changed proxy
or such by event. }
SI := TShapeTreeIterator.Create(Shapes, false, false);
try
while SI.GetNext do
begin
S := TGLShape(SI.Current);
if S.Cache <> nil then
Renderer.Cache.Shape_DecReference(S.Cache);
for Pass := Low(Pass) to High(Pass) do
if S.ProgramCache[Pass] <> nil then
Renderer.Cache.Program_DecReference(S.ProgramCache[Pass]);
end;
finally FreeAndNil(SI) end;
end;
if ScreenEffectNodes <> nil then
for I := 0 to ScreenEffectNodes.Count - 1 do
CloseGLScreenEffect(TScreenEffectNode(ScreenEffectNodes[I]));
{ TODO: if FOwnsRenderer then we should do something more detailed
then just Renderer.UnprepareAll. It's not needed for TCastlePrecalculatedAnimation
right now, so it's not implemented. }
if Renderer <> nil then Renderer.UnprepareAll;
if Shapes <> nil then
begin
SI := TShapeTreeIterator.Create(Shapes, false, true);
try
while SI.GetNext do
begin
S := TGLShape(SI.Current);
S.PreparedForRenderer := false;
S.PreparedUseBlending := false;
if S.OcclusionQueryId <> 0 then
begin
glDeleteQueriesARB(1, @(S.OcclusionQueryId));
S.OcclusionQueryId := 0;
end;
end;
finally FreeAndNil(SI) end;
end;
if VarianceShadowMapsProgram[false] <> nil then
FreeAndNil(VarianceShadowMapsProgram[false]);
if VarianceShadowMapsProgram[true] <> nil then
FreeAndNil(VarianceShadowMapsProgram[true]);
end;
procedure TCastleScene.GLContextClose;
begin
inherited;
CloseGLRenderer;
InvalidateBackground;
end;
function TCastleScene.ShapeFog(Shape: TShape): IAbstractFogObject;
begin
Result := Shape.State.LocalFog;
if Result = nil then
Result := FogStack.Top;
end;
{ Given blending name (as defined by VRML BlendMode node spec,
http://www.instantreality.org/documentation/nodetype/BlendMode/),
returns @true and corresponding OpenGL constant as Factor.
Returns @false if S doesn't match any known name, or it's "none",
or it's not supported by current OpenGL implementation (some factors
may require newer OpenGL versions), or it's not for this kind
(which means it's not for source factor if Source = true,
or it's not for dest factor is Source = false).
If returns @true, then also updates NeedsConstXxx.
"Updates" means that always does something like
NeedsConstXxx := NeedsConstXxx or <this factor needs them>;
so can only change from false to true.
}
function BlendingFactorNameToStr(S: string;
out Factor: TGLEnum;
var NeedsConstColor, NeedsConstAlpha: boolean;
Source: boolean): boolean;
type
TBlendingFactor = record
Name: string;
GL: TGLEnum;
Source, Dest: boolean;
NeedsConstColor, NeedsConstAlpha: boolean;
end;
const
BlendingFactors: array [0..15] of TBlendingFactor =
(
{ Three most frequently used values are placed at the beginning of the list,
for speedup. }
(Name: 'src_alpha' ; GL: GL_SRC_ALPHA ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'one_minus_src_alpha' ; GL: GL_ONE_MINUS_SRC_ALPHA ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'one' ; GL: GL_ONE ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'none' ; GL: GL_NONE ; Source: false; Dest: false; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'zero' ; GL: GL_ZERO ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'dst_color' ; GL: GL_DST_COLOR ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'src_color' ; GL: GL_SRC_COLOR ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'one_minus_dst_color' ; GL: GL_ONE_MINUS_DST_COLOR ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'one_minus_src_color' ; GL: GL_ONE_MINUS_SRC_COLOR ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'dst_alpha' ; GL: GL_DST_ALPHA ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'one_minus_dst_alpha' ; GL: GL_ONE_MINUS_DST_ALPHA ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'src_alpha_saturate' ; GL: GL_SRC_ALPHA_SATURATE ; Source: true ; Dest: false; NeedsConstColor: false; NeedsConstAlpha: false),
(Name: 'constant_color' ; GL: GL_CONSTANT_COLOR ; Source: true ; Dest: true ; NeedsConstColor: true ; NeedsConstAlpha: false),
(Name: 'one_minus_constant_color'; GL: GL_ONE_MINUS_CONSTANT_COLOR; Source: true ; Dest: true ; NeedsConstColor: true ; NeedsConstAlpha: false),
(Name: 'constant_alpha' ; GL: GL_CONSTANT_ALPHA ; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: true ),
(Name: 'one_minus_constant_alpha'; GL: GL_ONE_MINUS_CONSTANT_ALPHA; Source: true ; Dest: true ; NeedsConstColor: false; NeedsConstAlpha: true )
);
SourceToStr: array [boolean] of string = ('destination', 'source');
var
I: Integer;
begin
Result := false;
S := LowerCase(S);
for I := Low(BlendingFactors) to High(BlendingFactors) do
if BlendingFactors[I].Name = S then
begin
if Source then
Result := BlendingFactors[I].Source else
Result := BlendingFactors[I].Dest;
if Result then
begin
Factor := BlendingFactors[I].GL;
{ check is GL version enough, or some GL extensions available
for more exotic factors. }
if BlendingFactors[I].NeedsConstColor or
BlendingFactors[I].NeedsConstAlpha then
begin
if not GLFeatures.BlendConstant then
begin
if Log then
WritelnLog('Blending', Format('Blending factor "%s" not available. It requires OpenGL >= 1.4 or ARB_imaging or OpenGL ES >= 2.0 extension, and is known to not work with fglrx (ATI Linux drivers)', [S]));
Exit(false);
end;
end;
if not GLFeatures.Version_1_4 then
begin
if ((Factor = GL_SRC_COLOR) or
(Factor = GL_ONE_MINUS_SRC_COLOR)) and Source then
begin
if Log then
WritelnLog('Blending', Format('Blending factor "%s" as "source" requires OpenGL 1.4', [S]));
Exit(false);
end;
if ((Factor = GL_DST_COLOR) or
(Factor = GL_ONE_MINUS_DST_COLOR)) and not Source then
begin
if Log then
WritelnLog('Blending', Format('Blending factor "%s" as "destination" requires OpenGL 1.4', [S]));
Exit(false);
end;
end;
NeedsConstColor := NeedsConstColor or BlendingFactors[I].NeedsConstColor;
NeedsConstAlpha := NeedsConstAlpha or BlendingFactors[I].NeedsConstAlpha;
end;
Break;
end;
if not Result then
OnWarning(wtMajor, 'VRML/X3D', Format('Unknown blending %s factor name "%s"',
[ SourceToStr[Source], S ]));
end;
type
TOcclusionQuery = class
public
constructor Create;
destructor Destroy; override;
public
Id: TGLuint;
Node: TShapeOctreeNode;
function Available: LongBool;
function GetResult: TGLuint;
end;
constructor TOcclusionQuery.Create;
begin
inherited;
glGenQueriesARB(1, @Id);
end;
destructor TOcclusionQuery.Destroy;
begin
glDeleteQueriesARB(1, @Id);
inherited;
end;
function TOcclusionQuery.Available: LongBool;
begin
Assert(SizeOf(LongBool) = SizeOf(TGLuint));
glGetQueryObjectuivARB(Id, GL_QUERY_RESULT_AVAILABLE_ARB, @Result);
end;
function TOcclusionQuery.GetResult: TGLuint;
begin
glGetQueryObjectuivARB(Id, GL_QUERY_RESULT_ARB, @Result);
end;
procedure TCastleScene.RenderScene(
TestShapeVisibility: TTestShapeVisibility;
const Frustum: TFrustum; const Params: TRenderParams);
var
OcclusionBoxState: boolean;
procedure OcclusionBoxStateBegin;
begin
if not OcclusionBoxState then
begin
glPushAttrib(GL_COLOR_BUFFER_BIT or GL_DEPTH_BUFFER_BIT or
GL_ENABLE_BIT or GL_LIGHTING_BIT);
glColorMask(GL_FALSE, GL_FALSE, GL_FALSE, GL_FALSE); { saved by GL_COLOR_BUFFER_BIT }
glDepthMask(GL_FALSE); { saved by GL_DEPTH_BUFFER_BIT }
{ A lot of state should be disabled. Remember that this is done
in the middle of TGLRenderer rendering, between
RenderBegin/End, and TGLRenderer doesn't need to
restore state after each shape render. So e.g. texturing
and alpha test may be enabled, which could lead to very
strange effects (box would be rendered with random texel,
possibly alpha tested and rejected...).
Also, some state should be disabled just to speed up
rendering. E.g. lighting is totally not needed here. }
glDisable(GL_LIGHTING); { saved by GL_ENABLE_BIT }
glDisable(GL_CULL_FACE); { saved by GL_ENABLE_BIT }
glDisable(GL_COLOR_MATERIAL); { saved by GL_ENABLE_BIT }
glDisable(GL_ALPHA_TEST); { saved by GL_ENABLE_BIT }
glDisable(GL_FOG); { saved by GL_ENABLE_BIT }
GLEnableTexture(etNone); { saved by GL_ENABLE_BIT }
glShadeModel(GL_FLAT); { saved by GL_LIGHTING_BIT }
glEnableClientState(GL_VERTEX_ARRAY);
OcclusionBoxState := true;
end;
end;
procedure OcclusionBoxStateEnd;
begin
if OcclusionBoxState then
begin
glDisableClientState(GL_VERTEX_ARRAY);
glPopAttrib;
OcclusionBoxState := false;
end;
end;
{ Call RenderShape if some tests succeed.
It assumes that test with TestShapeVisibility is already done. }
procedure RenderShape_SomeTests(Shape: TGLShape);
procedure DoRenderShape;
{ Renders Shape, by calling Renderer.RenderShape. }
procedure RenderShape(Shape: TGLShape);
begin
{ Optionally free Shape arrays data now, if they need to be regenerated. }
if (Assigned(Attributes.OnVertexColor) or
Assigned(Attributes.OnRadianceTransfer)) and
(Shape.Cache <> nil) then
Shape.Cache.FreeArrays([vtAttribute]);
Renderer.RenderShape(Shape, ShapeFog(Shape));
end;
begin
OcclusionBoxStateEnd;
if Params.Pass = 0 then Inc(Params.Statistics.ShapesRendered);
RenderShape(Shape);
end;
var
SampleCount: TGLuint;
begin
if (Shape <> AvoidShapeRendering) and
( (not AvoidNonShadowCasterRendering) or Shape.ShadowCaster) then
begin
{ We do not make occlusion query when rendering to something else
than screen (like shadow map or cube map environment for mirror).
Such views are drastically different from normal camera view,
so the whole idea that "what is visible in this frame is similar
to what was visible in previous frame" breaks down there.
TODO: In the future, this could be solved nicer, by having separate
occlusion query states for different views. But this isn't easy
to implement, as occlusion query state is part of TShape and
octree nodes (for hierarchical occ query), so all these things
should have a map "target->oq state" for various rendering targets. }
if Attributes.ReallyUseOcclusionQuery and
(RenderingCamera.Target = rtScreen) then
begin
Assert(Shape.OcclusionQueryId <> 0);
if Shape.OcclusionQueryAsked then
glGetQueryObjectuivARB(Shape.OcclusionQueryId, GL_QUERY_RESULT_ARB,
@SampleCount) else
SampleCount := 1; { if not asked, assume it's visible }
{ Do not do occlusion query (although still use results from previous
query) if we're within stencil test (like in InShadow = false pass
of shadow volumes). This would incorrectly mark some shapes
as non-visible (just because they don't pass stencil test on any pixel),
while in fact they should be visible in the very next
(with InShadow = true) render pass. }
if Params.StencilTest = 0 then
glBeginQueryARB(GL_SAMPLES_PASSED_ARB, Shape.OcclusionQueryId);
if SampleCount > 0 then
begin
DoRenderShape;
end else
begin
{ Object was not visible in the last frame.
In this frame, only render it's bounding box, to test
occlusion query. This is the speedup of using occlusion query:
we render only bbox. }
OcclusionBoxStateBegin;
glDrawBox3DSimple(Shape.BoundingBox);
if Params.Pass = 0 then Inc(Params.Statistics.BoxesOcclusionQueriedCount);
end;
if Params.StencilTest = 0 then
begin
glEndQueryARB(GL_SAMPLES_PASSED_ARB);
Shape.OcclusionQueryAsked := true;
end;
end else
if Attributes.DebugHierOcclusionQueryResults and
Attributes.UseHierarchicalOcclusionQuery then
begin
if Shape.RenderedFrameId = FrameId then
DoRenderShape;
end else
{ No occlusion query-related stuff. Just render the shape. }
DoRenderShape;
end;
end;
{ Call RenderShape if many tests, including TestShapeVisibility,
succeed. }
procedure RenderShape_AllTests(Shape: TShape);
begin
if ( (not Assigned(TestShapeVisibility)) or
TestShapeVisibility(TGLShape(Shape))) then
RenderShape_SomeTests(TGLShape(Shape));
end;
procedure RenderShape_AllTests_Opaque(Shape: TShape);
begin
if not TGLShape(Shape).UseBlending then RenderShape_AllTests(Shape);
end;
procedure RenderShape_AllTests_Transparent(Shape: TShape);
begin
if TGLShape(Shape).UseBlending then RenderShape_AllTests(Shape);
end;
procedure RenderAllAsOpaque;
begin
if not Params.Transparent then
Shapes.Traverse(@RenderShape_AllTests, true, true);
end;
{ Determine what blending source/destination factors to use for rendering Shape
(looking at Attributes.BlendingXxx and Appearance.blendMode of VRML node).
If different than currently set, then change BlendingXxxFactorSet and update
by glBlendFunc. This way, we avoid calling glBlendFunc (which is potentially costly,
since it changes GL state) too often. }
procedure AdjustBlendFunc(Shape: TShape;
var BlendingSourceFactorSet, BlendingDestinationFactorSet: TGLEnum);
var
B: TBlendModeNode;
NewSrc, NewDest: TGLEnum;
NeedsConstColor, NeedsConstAlpha: boolean;
begin
NeedsConstColor := false;
NeedsConstAlpha := false;
B := Shape.State.BlendMode;
if B <> nil then
begin
if not BlendingFactorNameToStr(B.FdSrcFactor.Value, NewSrc, NeedsConstColor, NeedsConstAlpha, true) then
NewSrc := Attributes.BlendingSourceFactor;
if not BlendingFactorNameToStr(B.FdDestFactor.Value, NewDest, NeedsConstColor, NeedsConstAlpha, false) then
NewDest := Attributes.BlendingDestinationFactor;
end else
begin
NewSrc := Attributes.BlendingSourceFactor;
NewDest := Attributes.BlendingDestinationFactor;
end;
if (BlendingSourceFactorSet <> NewSrc) or
(BlendingDestinationFactorSet <> NewDest) then
begin
BlendingSourceFactorSet := NewSrc;
BlendingDestinationFactorSet := NewDest;
glBlendFunc(BlendingSourceFactorSet, BlendingDestinationFactorSet);
end;
{ We track last source/dest factor, but we don't track last constant color/alpha.
So just set them always, if needed. }
if GLFeatures.BlendConstant then
begin
if NeedsConstColor then
begin
Assert(B <> nil);
glBlendColor(
B.FdColor.Value[0],
B.FdColor.Value[1],
B.FdColor.Value[2],
1 - B.FdColorTransparency.Value);
end else
if NeedsConstAlpha then
begin
Assert(B <> nil);
glBlendColor(0, 0, 0, 1 - B.FdColorTransparency.Value);
end;
end;
end;
procedure DoHierarchicalOcclusionQuery;
var
{ Stack of TShapeOctreeNode.
Although queue would also work not so bad, stack is better.
The idea is that it should try to keep front-to-back order,
assuming that Node.PushChildren* keeps this order.
Stack gives more chance to process front shapes first. }
TraversalStack: TCastleObjectStack;
procedure TraverseNode(Node: TShapeOctreeNode);
var
I: Integer;
Shape: TGLShape;
begin
if Node.IsLeaf then
begin
{ Render all shapes within this leaf, taking care to render
shape only once within this frame (FrameId is useful here). }
for I := 0 to Node.ItemsIndices.Count - 1 do
begin
Shape := TGLShape(OctreeRendering.ShapesList[Node.ItemsIndices.L[I]]);
if Shape.RenderedFrameId <> FrameId then
begin
RenderShape_SomeTests(Shape);
Shape.RenderedFrameId := FrameId;
end;
end;
end else
begin
{ Push Node children onto TraversalStack.
We want to Pop them front-first, to (since this is a stack)
we want to push back first. }
if CameraViewKnown then
Node.PushChildrenBackToFront(TraversalStack, CameraPosition) else
Node.PushChildren(TraversalStack);
end;
end;
procedure PullUpVisibility(Node: TShapeOctreeNode);
begin
while not Node.Visible do
begin
Node.Visible := true;
Node := Node.ParentNode;
if Node = nil then Break;
end;
end;
procedure RenderLeafNodeVolume(Node: TShapeOctreeNode);
var
I: Integer;
Shape: TGLShape;
Box: TBox3D;
begin
OcclusionBoxStateBegin;
{ How to render bounding volume of leaf for occlusion query?
- Simple version is just to render Node.Box. But this may be
much greater than actual box of shapes inside, Box of our
octree node is not adjusted to be tight.
- Another version is to render boxes of all shapes within this leaf.
This is much tighter than Node.Box, and results in much less
shapes quialified as visible. (See e.g. bzwgen city view behind
building 1 when trying to walk towards the city center.)
Unfortunately, this produces really a lot of boxes, so the
overhead of drawing glDrawBox3DSimple becomes large then.
- Compromise: calculate tight bounding box here, and use it.
Works best: number of both visible shapes and cull boxes
is small.
Note that we can render here boxes of only non-rendered shapes,
that's Ok and may actually speed up. }
Box := EmptyBox3D;
for I := 0 to Node.ItemsIndices.Count - 1 do
begin
Shape := TGLShape(OctreeRendering.ShapesList[Node.ItemsIndices.L[I]]);
if Shape.RenderedFrameId <> FrameId then
Box.Add(Shape.BoundingBox);
end;
glDrawBox3DSimple(Box);
if Params.Pass = 0 then Inc(Params.Statistics.BoxesOcclusionQueriedCount);
end;
const
VisibilityThreshold = 0;
{ $define VISIBILITY_KEEP_FRAMES}
{$ifdef VISIBILITY_KEEP_FRAMES}
VisibilityKeepFrames = 10;
{$endif}
var
{ queue of TOcclusionQuery }
QueryQueue: TCastleObjectQueue;
Q: TOcclusionQuery;
Node: TShapeOctreeNode;
WasVisible, LeafOrWasInvisible: boolean;
begin
{$include norqcheckbegin.inc}
Inc(FrameId);
{$include norqcheckend.inc}
TraversalStack := TCastleObjectStack.Create;
TraversalStack.Capacity := OctreeRendering.ShapesList.Count;
QueryQueue := TCastleObjectQueue.Create;
QueryQueue.Capacity := OctreeRendering.ShapesList.Count;
try
TraversalStack.Push(OctreeRendering.TreeRoot);
repeat
if (QueryQueue.Count <> 0) and
( (TOcclusionQuery(QueryQueue.Peek).Available) or
(TraversalStack.Count = 0) ) then
begin
Q := TOcclusionQuery(QueryQueue.Pop);
if Q.GetResult > VisibilityThreshold then
begin
PullUpVisibility(Q.Node);
TraverseNode(Q.Node);
end;
FreeAndNil(Q);
end;
if TraversalStack.Count <> 0 then
begin
Node := TShapeOctreeNode(TraversalStack.Pop);
if Node.FrustumCollisionPossible(RenderFrustum_Frustum^) then
begin
{$ifdef VISIBILITY_KEEP_FRAMES}
{ There was a resigned idea below (maybe useful later) to do
"or (Node.Depth >= 5)", to assume visible = true below some
octree depth. }
if (Node.Visible and (Node.LastVisitedFrameId >= FrameId - VisibilityKeepFrames)) then
begin
{ Visible somewhere during VisibilityKeepFrames.
Just assume it's still visible.
(This is the optimization described in 6.6.4
"Conservative Visibility Testing") }
TraverseNode(Node);
end else
{$endif VISIBILITY_KEEP_FRAMES}
begin
WasVisible := Node.Visible and (Node.LastVisitedFrameId = FrameId - 1);
LeafOrWasInvisible := (not WasVisible) or Node.IsLeaf;
Node.Visible := false;
Node.LastVisitedFrameId := FrameId;
{ Original logic goes like:
if LeafOrWasInvisible then
Add query with Node.Box;
if WasVisible then
TraverseNode(Node);
But this is not optimal: it would always query using bounding
boxes. Even for the case when we have a visible leaf,
then the above version would query using box of this leaf
and then render this leaf.
But in this case we can query using actual geometry.
So a modification is to do
if LeafOrWasInvisible then
begin
if Leaf and WasVisible then
Add query for Node and render the leaf else
Add query with Node.Box;
end else
if WasVisible then
TraverseNode(Node);
This exhausts all possibilities, since if
LeafOrWasInvisible and WasVisible then only leaf nodes
could satisfy this.
There's additional note about this:
rendering inside TraverseNode may render
only part of the leaf's items (or even none at all).
This is needed (although in original paper they write
about rendering single shape there, unline my many-shapes-in-leaf
approach, but still they have to safeguard against rendering
the same node many times, since visible leaf confirmed to
be visible may be passed twice to Render).
But this means that object may be classified as invisible
(because it didn't have any unrendered shapes), while in fact
it's visible. That's not a problem, since we check our
query in the next frame, and the object will be found
then visible again (or again invisible if other leafs
will render it's shapes, but then it's not a problem). }
if LeafOrWasInvisible then
begin
Q := TOcclusionQuery.Create;
Q.Node := Node;
glBeginQueryARB(GL_SAMPLES_PASSED_ARB, Q.Id);
if Node.IsLeaf and WasVisible then
TraverseNode(Node) else
if Node.IsLeaf then
{ Leaf nodes have optimized version of rendering their
bounding volume for occlusion query. }
RenderLeafNodeVolume(Node) else
begin
OcclusionBoxStateBegin;
glDrawBox3DSimple(Node.Box);
if Params.Pass = 0 then Inc(Params.Statistics.BoxesOcclusionQueriedCount);
end;
glEndQueryARB(GL_SAMPLES_PASSED_ARB);
QueryQueue.Push(Q);
end else
if WasVisible then
TraverseNode(Node);
end;
end;
end;
until (TraversalStack.Count = 0) and (QueryQueue.Count = 0);
finally
FreeAndNil(TraversalStack);
FreeAndNil(QueryQueue);
end;
end;
procedure UpdateVisibilitySensors;
var
I, J: Integer;
Instances: TVisibilitySensorInstanceList;
NewActive: boolean;
begin
{ optimize for common case: exit early if nothing to do }
if VisibilitySensors.Count = 0 then Exit;
if ProcessEvents then
begin
BeginChangesSchedule;
try
for I := 0 to VisibilitySensors.Count - 1 do
if VisibilitySensors.Keys[I].FdEnabled.Value then
begin
{ increment timestamp for each VisibilitySensor,
otherwise sensors_environmental/visibility_sensor.x3dv
has a problem at initialization, when multiple sensors
send isActive = TRUE, and X3D mechanism to avoid loops
kicks in. }
IncreaseTimeTick;
{ calculate NewActive }
NewActive := false;
Instances := VisibilitySensors.Data[I];
for J := 0 to Instances.Count - 1 do
if Frustum.Box3DCollisionPossibleSimple(Instances[J].Box) then
begin
NewActive := true;
Break;
end;
VisibilitySensors.Keys[I].SetIsActive(NewActive, Time);
end;
finally EndChangesSchedule; end;
end;
end;
var
BlendingSourceFactorSet, BlendingDestinationFactorSet: TGLEnum;
I: Integer;
LightRenderEvent: TVRMLLightRenderEvent;
begin
{ We update ShapesVisible only for one value of Params.Transparent.
Otherwise, we would increase it twice.
This method is always called first with Params.Transparent = false,
then Params.Transparent = true during a single frame. }
if (not Params.Transparent) and (Params.Pass = 0) then
begin
Params.Statistics.ShapesVisible += ShapesActiveVisibleCount;
{ also do this only once per frame }
UpdateVisibilitySensors;
end;
OcclusionBoxState := false;
if Params.InShadow then
LightRenderEvent := @LightRenderInShadow else
LightRenderEvent := nil;
if not Params.RenderTransformIdentity then
begin
glPushMatrix;
glMultMatrix(Params.RenderTransform);
end;
Renderer.RenderBegin(Params.BaseLights(Self) as TLightInstancesList,
LightRenderEvent, Params.Pass);
try
if Attributes.Mode <> rmFull then
begin
{ When not rmFull, we don't want to do anything with glDepthMask
or GL_BLEND enable state. Just render everything. }
RenderAllAsOpaque;
{ Each RenderShape_SomeTests inside could set OcclusionBoxState }
OcclusionBoxStateEnd;
end else
if Attributes.ReallyUseHierarchicalOcclusionQuery and
(not Attributes.DebugHierOcclusionQueryResults) and
(RenderingCamera.Target = rtScreen) and
(OctreeRendering <> nil) then
begin
DoHierarchicalOcclusionQuery;
{ Inside we could set OcclusionBoxState }
OcclusionBoxStateEnd;
end else
begin
glPushAttrib(GL_COLOR_BUFFER_BIT or GL_DEPTH_BUFFER_BIT);
try
if Attributes.ControlBlending and Attributes.Blending then
begin
if not Params.Transparent then
begin
{ draw fully opaque objects }
glDepthMask(GL_TRUE);
glDisable(GL_BLEND);
if CameraViewKnown and Attributes.ReallyUseOcclusionQuery then
begin
ShapesFilterBlending(Shapes, true, true, false,
TestShapeVisibility, FilteredShapes, false);
{ ShapesSplitBlending already filtered shapes through
TestShapeVisibility callback, so later we can render them
with RenderShape_SomeTests to skip checking TestShapeVisibility
twice. This is a good thing: it means that sorting below has
much less shapes to consider. }
FilteredShapes.SortFrontToBack(CameraPosition);
for I := 0 to FilteredShapes.Count - 1 do
RenderShape_SomeTests(TGLShape(FilteredShapes[I]));
end else
Shapes.Traverse(@RenderShape_AllTests_Opaque, true, true, false);
end else
{ this means Params.Transparent = true }
begin
{ draw partially transparent objects }
glDepthMask(GL_FALSE);
glEnable(GL_BLEND);
{ Set glBlendFunc using Attributes.BlendingXxxFactor }
BlendingSourceFactorSet := Attributes.BlendingSourceFactor;
BlendingDestinationFactorSet := Attributes.BlendingDestinationFactor;
glBlendFunc(BlendingSourceFactorSet, BlendingDestinationFactorSet);
if CameraViewKnown and Attributes.BlendingSort then
begin
ShapesFilterBlending(Shapes, true, true, false,
TestShapeVisibility, FilteredShapes, true);
FilteredShapes.SortBackToFront(CameraPosition);
for I := 0 to FilteredShapes.Count - 1 do
begin
AdjustBlendFunc(TGLShape(FilteredShapes[I]),
BlendingSourceFactorSet, BlendingDestinationFactorSet);
RenderShape_SomeTests(TGLShape(FilteredShapes[I]));
end;
end else
Shapes.Traverse(@RenderShape_AllTests_Transparent, true, true, false);
end;
end else
begin
if Attributes.ControlBlending then
begin
glDepthMask(GL_TRUE);
glDisable(GL_BLEND);
end;
RenderAllAsOpaque;
end;
{ Each RenderShape_SomeTests inside could set OcclusionBoxState.
Finish it now, before following glPopAttrib. }
OcclusionBoxStateEnd;
finally glPopAttrib end;
end;
finally Renderer.RenderEnd end;
if not Params.RenderTransformIdentity then
glPopMatrix;
end;
procedure TCastleScene.PrepareResources(
Options: TPrepareResourcesOptions; ProgressStep: boolean;
BaseLights: TAbstractLightInstancesList);
procedure PrepareShapesResouces;
var
SI: TShapeTreeIterator;
begin
SI := TShapeTreeIterator.Create(Shapes, false, false);
try
while SI.GetNext do
TGLShape(SI.Current).PrepareResources;
finally FreeAndNil(SI) end;
end;
procedure PrepareRenderShapes;
var
SI: TShapeTreeIterator;
Shape: TGLShape;
begin
if Log and LogRenderer then
WritelnLog('Renderer', 'Preparing rendering of all shapes');
{ Note: we prepare also not visible shapes, in case they become visible. }
SI := TShapeTreeIterator.Create(Shapes, false, false);
try
Inc(Renderer.PrepareRenderShape);
try
Renderer.RenderBegin(BaseLights as TLightInstancesList, nil, 0);
while SI.GetNext do
begin
Shape := TGLShape(SI.Current);
Renderer.RenderShape(Shape, ShapeFog(Shape));
end;
Renderer.RenderEnd;
finally Dec(Renderer.PrepareRenderShape) end;
finally FreeAndNil(SI) end;
end;
var
I: Integer;
begin
inherited;
if Dirty <> 0 then Exit;
{ When preparing resources, files (like textures) may get loaded,
causing progress bar (for example from CastleDownload).
Right now we're not ready to display the (partially loaded) scene
during this time, so we use Dirty to prevent it.
Test http://svn.code.sf.net/p/castle-engine/code/trunk/demo_models/navigation/transition_multiple_viewpoints.x3dv
Most probably problems are caused because shapes are initially
without a texture, so their arrays (including VBOs) are generated
without texture coordinates, and we do not mark them to be prepared
correctly later. Correct fix is unsure:
- Marking relevant shapes to be prepared again seems easiest,
but this means that potentially everything is prepared 2 times
--- once before resources (like textures) are ready, 2nd time with.
- It would be best to pas texture coordinates even when no texture is loaded?
Ideally, the renderer operations should be the same regardless if texture
is loaded or not.
It remains to carefully see whether it's possible in all cases.
}
Inc(Dirty);
try
if not PreparedShapesResouces then
begin
{ Use PreparedShapesResouces to avoid expensive (for large scenes)
iteration over all shapes in every TCastleScene.PrepareResources call. }
PreparedShapesResouces := true;
PrepareShapesResouces;
end;
if (prRender in Options) and not PreparedRender then
begin
{ We use PreparedRender to avoid potentially expensive iteration
over shapes and expensive Renderer.RenderBegin/End. }
PreparedRender := true;
{ Do not prepare when OnVertexColor or OnRadianceTransfer used,
as we can only call these callbacks during render (otherwise they
may be unprepared, like no texture for dynamic_ambient_occlusion.lpr). }
if not
(Assigned(Attributes.OnVertexColor) or
Assigned(Attributes.OnRadianceTransfer)) then
PrepareRenderShapes;
end;
if prBackground in Options then
PrepareBackground;
if prScreenEffects in Options then
begin
for I := 0 to ScreenEffectNodes.Count - 1 do
Renderer.PrepareScreenEffect(ScreenEffectNodes[I] as TScreenEffectNode);
end;
finally Dec(Dirty) end;
end;
procedure TCastleScene.Render(
TestShapeVisibility: TTestShapeVisibility;
const Frustum: TFrustum; const Params: TRenderParams);
procedure RenderNormal;
begin
RenderScene(TestShapeVisibility, Frustum, Params);
end;
procedure RenderWireframe(UseWireframeColor: boolean);
var
SavedMode: TRenderingMode;
begin
glPushAttrib(GL_POLYGON_BIT or GL_CURRENT_BIT or GL_ENABLE_BIT);
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE); { saved by GL_POLYGON_BIT }
if UseWireframeColor then
begin
glColorv(Attributes.WireframeColor); { saved by GL_CURRENT_BIT }
glDisable(GL_TEXTURE_2D); { saved by GL_CURRENT_BIT }
glDisable(GL_LIGHTING); { saved by GL_CURRENT_BIT }
SavedMode := Attributes.Mode;
Attributes.Mode := rmPureGeometry;
end;
RenderNormal;
if UseWireframeColor then
Attributes.Mode := SavedMode;
glPopAttrib;
end;
{ Render taking Attributes.WireframeEffect into account. }
procedure RenderWithWireframeEffect;
begin
case Attributes.WireframeEffect of
weNormal: RenderNormal;
weWireframeOnly: RenderWireframe(Attributes.Mode = rmPureGeometry);
weSolidWireframe:
begin
glPushAttrib(GL_POLYGON_BIT);
{ enable polygon offset for everything (whole scene) }
glEnable(GL_POLYGON_OFFSET_FILL); { saved by GL_POLYGON_BIT }
glEnable(GL_POLYGON_OFFSET_LINE); { saved by GL_POLYGON_BIT }
glEnable(GL_POLYGON_OFFSET_POINT); { saved by GL_POLYGON_BIT }
glPolygonOffset(1, 1); { saved by GL_POLYGON_BIT }
RenderNormal;
glPopAttrib;
RenderWireframe(true);
end;
weSilhouette:
begin
RenderNormal;
glPushAttrib(GL_POLYGON_BIT);
glEnable(GL_POLYGON_OFFSET_LINE); { saved by GL_POLYGON_BIT }
glPolygonOffset(5, 5); { saved by GL_POLYGON_BIT }
{ rmPureGeometry still does backface culling.
This is very good in this case. When rmPureGeometry and weSilhouette,
and objects are solid (so backface culling is used) we can
significantly improve the effect by reverting glFrontFace,
this way we will cull *front* faces. This will not be noticed
in case of rmPureGeometry will single solid color, and it will
improve the silhouette look, since front-face edges will not be
rendered at all (no need to even hide them by glPolygonOffset,
which is somewhat sloppy). }
if Attributes.Mode = rmPureGeometry then
glFrontFace(GL_CW); { saved by GL_POLYGON_BIT }
RenderWireframe(true);
glPopAttrib;
end;
else raise EInternalError.Create('Render: Attributes.WireframeEffect ?');
end;
end;
{ Render, doing some special tricks when rendering to shadow maps. }
procedure RenderWithShadowMaps;
var
SavedMode: TRenderingMode;
SavedCustomShader, SavedCustomShaderAlphaTest: TGLSLProgram;
begin
{ For shadow maps, speed up rendering by using only features that affect
depth output. This also disables user shaders (for both classic
and VSM shadow maps, consistently). }
if RenderingCamera.Target in [rtVarianceShadowMap, rtShadowMap] then
begin
SavedMode := Attributes.Mode;
Attributes.Mode := rmDepth;
end;
{ When rendering to Variance Shadow Map, we need special shader. }
if RenderingCamera.Target = rtVarianceShadowMap then
begin
{ create VarianceShadowMapsProgram if needed }
if VarianceShadowMapsProgram[false] = nil then
begin
VarianceShadowMapsProgram[false] := TGLSLProgram.Create;
VarianceShadowMapsProgram[false].AttachFragmentShader({$I variance_shadow_map_generate.fs.inc});
VarianceShadowMapsProgram[false].Link(true);
end;
if VarianceShadowMapsProgram[true] = nil then
begin
VarianceShadowMapsProgram[true] := TGLSLProgram.Create;
VarianceShadowMapsProgram[true].AttachFragmentShader(
'#define ALPHA_TEST' + NL + {$I variance_shadow_map_generate.fs.inc});
VarianceShadowMapsProgram[true].Link(true);
end;
SavedCustomShader := Attributes.CustomShader;
SavedCustomShaderAlphaTest := Attributes.CustomShaderAlphaTest;
Attributes.CustomShader := VarianceShadowMapsProgram[false];
Attributes.CustomShaderAlphaTest := VarianceShadowMapsProgram[true];
end;
RenderWithWireframeEffect;
if RenderingCamera.Target in [rtVarianceShadowMap, rtShadowMap] then
Attributes.Mode := SavedMode;
if RenderingCamera.Target = rtVarianceShadowMap then
begin
Attributes.CustomShader := SavedCustomShader;
Attributes.CustomShaderAlphaTest := SavedCustomShaderAlphaTest;
end;
end;
begin
{ This is usually called by Render(Frustum, Params) that probably
already did tests below. But it may also be called directly,
so do the checks below anyway. (The checks are trivial, so no speed harm.) }
if GetExists and (Dirty = 0) and
(ReceiveShadowVolumes = Params.ShadowVolumesReceivers) then
begin
{ I used to make here more complex "prepare" mechanism, that was trying
to prepare for particular shapes only right before they are rendered
(so instead of calling PrepareResources below, I was calling PrepareShape
at the beginning of each RenderShape and such).
After a while, it turns out this was a useless complication of code
logic. There are many things that *have* to be prepared before whole
rendering, for example
- UseBlending must be calculated for all shapes.
- Occlusion query id must be generated (as we may start occlusion query
before actually rendering the shape).
It's much simpler to just call PrepareResources at the beginning. }
PrepareResources([prRender], false, Params.BaseLights(Self));
RenderWithShadowMaps;
end;
end;
class procedure TCastleScene.LightRenderInShadow(const Light: TLightInstance;
var LightOn: boolean);
begin
if Light.Node.FdShadowVolumes.Value then
LightOn := false;
end;
procedure TCastleScene.BeforeNodesFree(const InternalChangedAll: boolean);
begin
{ Release all associations with OpenGL context before freeing the nodes.
This means vrml nodes are still valid during GLRenderer unprepare
calls.
Although we don't really want to lose our connection with OpenGL
context, in fact that's the only sensible thing to do now: since
everything possibly changed, we have to unprepare all now.
This is done before inherited, as inherited may clear Shapes tree
(clearing per-shape information about referenced vbos etc.). }
GLContextClose;
inherited;
end;
{ shadow quads --------------------------------------------------------------- }
{ This returns vertex Original extruded into infinity, as seen from light
at position LightPos.
This is designed to work only with LightPos[3] = 1. In the future, when
need arises, this may be improved to work with any LightPos[3] <> 0.
For LightPos[3] = 0, i.e. directional light,
don't use this, and there's no need to do it,
since then the extruded point is just LightPos (for any vertex).
RenderXxxShadowVolume want to treat it specially anyway (to optimize
drawing, since then quads degenerate to triangles). }
function ExtrudeVertex(
const Original: TVector3Single;
const LightPos: TVector4Single): TVector4Single;
var
LightPos3: TVector3Single absolute LightPos;
begin
{ Below is the moment when we require that
if LightPos[3] <> 0 then LightPos[3] = 1 (not any other non-zero value).
Otherwise we would have to divide here LightPos3 by LightPos[3].
Maybe in the future this requirement will be removed and we'll work
for any LightPos in homogeneous coordinates, for now it's not really
needed. }
Result[0] := Original[0] - LightPos3[0];
Result[1] := Original[1] - LightPos3[1];
Result[2] := Original[2] - LightPos3[2];
Result[3] := 0;
end;
procedure TCastleScene.RenderAllShadowVolume(
const LightPos: TVector4Single;
const TransformIsIdentity: boolean;
const Transform: TMatrix4Single;
LightCap, DarkCap: boolean);
var
TrianglesForLightCap: TTriangle3SingleList;
TrianglesForDarkCap: TTriangle4SingleList;
procedure RenderShadowQuad(
const P0, P1: TVector3Single;
const PExtruded0, PExtruded1: TVector4Single); overload;
begin
//glNormalv(TriangleNormal(P0, P1, PExtruded1));
glVertexv(P0);
glVertexv(P1);
glVertexv(PExtruded1);
glVertexv(PExtruded0);
end;
procedure RenderShadowQuad(
const P0, P1: TVector3Single;
const PExtruded: TVector4Single); overload;
begin
glVertexv(P0);
glVertexv(P1);
glVertexv(PExtruded);
end;
procedure HandleTriangle(const T: TTriangle3Single);
var
TExtruded: TTriangle4Single;
Plane: TVector4Single;
PlaneSide: Single;
begin
{ We want to have consistent CCW orientation of shadow quads faces,
so that face is oriented CCW <=> you're looking at it from outside
(i.e. it's considered front face of this shadow quad).
This is needed, since user of this method may want to do culling
to eliminate back or front faces.
If TriangleDir(T) indicates direction that goes from CCW triangle side.
If TriangleDir(T) points in the same direction as LightPos then
1st quad should be T1, T0, TExtruded0, TExtruded1.
If TriangleDir(T) points in the opposite direction as LightPos then
1st quad should be T0, T1, TExtruded1, TExtruded0.
And so on.
Note that this works for any LightPos[3].
- For LightPos[3] = 1 this is normal check.
- For other LightPos[3] > 0 this is equivalent to normal check.
- For LightPos[3] = 0, this calculates dot between light direction
and plane direction. Plane direction points outwards, so PlaneSide > 0
indicates that light is from the outside. So it matches results for
LightPos[3] = 1.
- For LightPos[3] < 0, is seems that the test has to be reversed !
I.e. add "if LightPos[3] < 0 then PlaneSide := -PlaneSide;".
This will be done when we'll have to do accept any homogeneous
coords for LightPos, right now it's not needed.
}
Plane := TrianglePlane(T);
PlaneSide := Plane[0] * LightPos[0] +
Plane[1] * LightPos[1] +
Plane[2] * LightPos[2] +
Plane[3] * LightPos[3];
{ Don't render quads on caps if LightPos lies on the Plane
(which means that PlaneSide = 0) }
if PlaneSide = 0 then
Exit;
if LightPos[3] <> 0 then
begin
TExtruded[0] := ExtrudeVertex(T[0], LightPos);
TExtruded[1] := ExtrudeVertex(T[1], LightPos);
TExtruded[2] := ExtrudeVertex(T[2], LightPos);
if PlaneSide > 0 then
begin
RenderShadowQuad(T[1], T[0], TExtruded[1], TExtruded[0]);
RenderShadowQuad(T[0], T[2], TExtruded[0], TExtruded[2]);
RenderShadowQuad(T[2], T[1], TExtruded[2], TExtruded[1]);
end else
begin
RenderShadowQuad(T[0], T[1], TExtruded[0], TExtruded[1]);
RenderShadowQuad(T[1], T[2], TExtruded[1], TExtruded[2]);
RenderShadowQuad(T[2], T[0], TExtruded[2], TExtruded[0]);
end;
if DarkCap then
begin
{ reverse TExtruded dir, we want to render caps CCW outside always.
Note that the test for reversing here is "PlaneSide > 0", while
test for reversing LightCaps is "PlaneSide < 0": that's as it should
be, as DarkCap triangle should always be in reversed direction
than corresponding LightCap triangle (since they both should be
CCW outside). }
if PlaneSide > 0 then
SwapValues(TExtruded[0], TExtruded[2]);
TrianglesForDarkCap.Add(TExtruded);
end;
end else
begin
{ For directional lights, this gets a little simpler, since
all extruded points are the same and equal just LightPos. }
if PlaneSide > 0 then
begin
RenderShadowQuad(T[1], T[0], LightPos);
RenderShadowQuad(T[0], T[2], LightPos);
RenderShadowQuad(T[2], T[1], LightPos);
end else
begin
RenderShadowQuad(T[0], T[1], LightPos);
RenderShadowQuad(T[1], T[2], LightPos);
RenderShadowQuad(T[2], T[0], LightPos);
end;
end;
if LightCap then
begin
{ reverse T dir, we want to render caps CCW outside always }
if PlaneSide < 0 then
TrianglesForLightCap.Add(Triangle3Single(T[2], T[1], T[0])) else
TrianglesForLightCap.Add(T);
end;
end;
procedure RenderTriangle3Single(const T: TTriangle3Single);
begin
glVertexv(T[0]);
glVertexv(T[1]);
glVertexv(T[2]);
end;
procedure RenderTriangle4Single(const T: TTriangle4Single);
begin
glVertexv(T[0]);
glVertexv(T[1]);
glVertexv(T[2]);
end;
var
I: Integer;
Triangles: TTriangle3SingleList;
TransformedTri: TTriangle3Single;
TPtr: PTriangle3Single;
T4Ptr: PTriangle4Single;
begin
TrianglesForLightCap := nil;
TrianglesForDarkCap := nil;
{ Note that we require that all triangles on Triangles list are valid
(have non-zero area). That's Ok, TrianglesListShadowCasters guarantees it.
Otherwise, degenerate triangles could cause artifacts --- image a degenerate
triangle on the silhouette edge, it will cause two shadow quads (with all
it's neighboring triangles) where there should be one. }
Triangles := TrianglesListShadowCasters;
{ If light is directional, no need to render dark cap }
DarkCap := DarkCap and (LightPos[3] <> 0);
{ It's a not nice that we have to create a structure in memory
to hold TrianglesForLight/DarkCap. But that's because they have to be rendered
after rendering normal shadow quads (because shadow quads may be
quads or triangles, caps are only triangles, and are rendered in
glDepthFunc(GL_NEVER) mode. }
if LightCap then
begin
TrianglesForLightCap := TTriangle3SingleList.Create;
TrianglesForLightCap.Capacity := Triangles.Count;
end;
if DarkCap then
begin
TrianglesForDarkCap := TTriangle4SingleList.Create;
TrianglesForDarkCap.Capacity := Triangles.Count;
end;
try
if LightPos[3] <> 0 then
glBegin(GL_QUADS) else
glBegin(GL_TRIANGLES);
TPtr := PTriangle3Single(Triangles.List);
if TransformIsIdentity then
begin
for I := 0 to Triangles.Count - 1 do
begin
HandleTriangle(TPtr^);
Inc(TPtr);
end;
end else
begin
for I := 0 to Triangles.Count - 1 do
begin
{ calculate TransformedTri := Triangles[I] transformed by Transform }
TransformedTri[0] := MatrixMultPoint(Transform, TPtr^[0]);
TransformedTri[1] := MatrixMultPoint(Transform, TPtr^[1]);
TransformedTri[2] := MatrixMultPoint(Transform, TPtr^[2]);
HandleTriangle(TransformedTri);
Inc(TPtr);
end;
end;
glEnd;
if LightCap or DarkCap then
begin
{ See RenderSilhouetteShadowVolume for explanation why caps
should be rendered with glDepthFunc(GL_NEVER). }
glPushAttrib(GL_DEPTH_BUFFER_BIT); { to save glDepthFunc call below }
glDepthFunc(GL_NEVER);
glBegin(GL_TRIANGLES);
if LightCap then
begin
TPtr := PTriangle3Single(TrianglesForLightCap.List);
for I := 0 to TrianglesForLightCap.Count - 1 do
begin
RenderTriangle3Single(TPtr^);
Inc(TPtr);
end;
end;
if DarkCap then
begin
T4Ptr := PTriangle4Single(TrianglesForDarkCap.List);
for I := 0 to TrianglesForDarkCap.Count - 1 do
begin
RenderTriangle4Single(T4Ptr^);
Inc(T4Ptr);
end;
end;
glEnd;
glPopAttrib;
end;
finally
FreeAndNil(TrianglesForLightCap);
FreeAndNil(TrianglesForDarkCap);
end;
end;
procedure TCastleScene.RenderSilhouetteShadowVolume(
const LightPos: TVector4Single;
const TransformIsIdentity: boolean;
const Transform: TMatrix4Single;
const LightCap, DarkCap: boolean);
{ Is it worth preparing ManifoldEdges list: yes.
At the beginning we used here the simple algorithm from
[http://www.gamedev.net/reference/articles/article1873.asp].
For each triangle with dot > 0, add it to the Edges list
--- unless it's already there, in which case remove it.
This way, at the end Edges contain all edges that have on one
side triangle with dot > 0 and on the other side triangle with dot <= 0.
In other words, all sihouette edges.
(This is all assuming that model is 2-manifold,
so each edge has exactly 2 neighbor triangles).
But this algorithm proved to be unacceptably slow for many cases.
While it generated much less shadow quads than naive
RenderAllShadowVolume, the time spent in detecting the silhouette edges
made the total time even worse than RenderAllShadowVolume.
Obviously, that's because we started from the list of triangles,
without any explicit information about the edges.
The time of this algorithm was n*m, if n is the number of triangles
and m the number of edges, and on 2-manifold n*3/2 = m so
the time is n^2. Terrible, if you take complicated shadow caster.
To make this faster, we have to know the connections inside the model:
that's what ManifoldEdges list is all about. It allows us to
implement this in time proportional to the number of edges.
}
var
Triangles: TTrianglesShadowCastersList;
procedure RenderShadowQuad(EdgePtr: PManifoldEdge;
const P0Index, P1Index: Cardinal); overload;
var
V0, V1: TVector3Single;
EdgeV0, EdgeV1: PVector3Single;
TrianglePtr: PTriangle3Single;
begin
TrianglePtr := Addr(Triangles.L[EdgePtr^.Triangles[0]]);
EdgeV0 := @TrianglePtr^[(EdgePtr^.VertexIndex + P0Index) mod 3];
EdgeV1 := @TrianglePtr^[(EdgePtr^.VertexIndex + P1Index) mod 3];
if TransformIsIdentity then
begin
V0 := EdgeV0^;
V1 := EdgeV1^;
end else
begin
V0 := MatrixMultPoint(Transform, EdgeV0^);
V1 := MatrixMultPoint(Transform, EdgeV1^);
end;
glVertexv(V0);
glVertexv(V1);
if LightPos[3] <> 0 then
begin
glVertexv(ExtrudeVertex(V1, LightPos));
glVertexv(ExtrudeVertex(V0, LightPos));
end else
glVertexv(LightPos);
end;
procedure RenderShadowQuad(EdgePtr: PBorderEdge;
const P0Index, P1Index: Cardinal); overload;
var
V0, V1: TVector3Single;
EdgeV0, EdgeV1: PVector3Single;
TrianglePtr: PTriangle3Single;
begin
TrianglePtr := Addr(Triangles.L[EdgePtr^.TriangleIndex]);
EdgeV0 := @TrianglePtr^[(EdgePtr^.VertexIndex + P0Index) mod 3];
EdgeV1 := @TrianglePtr^[(EdgePtr^.VertexIndex + P1Index) mod 3];
if TransformIsIdentity then
begin
V0 := EdgeV0^;
V1 := EdgeV1^;
end else
begin
V0 := MatrixMultPoint(Transform, EdgeV0^);
V1 := MatrixMultPoint(Transform, EdgeV1^);
end;
glVertexv(V0);
glVertexv(V1);
if LightPos[3] <> 0 then
begin
glVertexv(ExtrudeVertex(V1, LightPos));
glVertexv(ExtrudeVertex(V0, LightPos));
end else
glVertexv(LightPos);
end;
{ We initialize TrianglesPlaneSide and render caps in one step,
this way we have to iterate over Triangles only once, and in case
of PlaneSide_NotIdentity and rendering caps --- we have to transform
each triangle only once. }
procedure InitializeTrianglesPlaneSideAndRenderCaps(
TrianglesPlaneSide: TBooleanList;
LightCap, DarkCap: boolean);
procedure RenderCaps(const T: TTriangle3Single);
begin
if LightCap then
begin
glVertexv(T[0]);
glVertexv(T[1]);
glVertexv(T[2]);
end;
if DarkCap then
begin
glVertexv(ExtrudeVertex(T[2], LightPos));
glVertexv(ExtrudeVertex(T[1], LightPos));
glVertexv(ExtrudeVertex(T[0], LightPos));
end;
end;
function PlaneSide_Identity(const T: TTriangle3Single): boolean;
var
Plane: TVector4Single;
begin
Plane := TrianglePlane(T);
Result := (Plane[0] * LightPos[0] +
Plane[1] * LightPos[1] +
Plane[2] * LightPos[2] +
Plane[3] * LightPos[3]) > 0;
if Result then RenderCaps(T);
end;
function PlaneSide_NotIdentity(const T: TTriangle3Single): boolean;
var
Plane: TVector4Single;
TriangleTransformed: TTriangle3Single;
begin
TriangleTransformed[0] := MatrixMultPoint(Transform, T[0]);
TriangleTransformed[1] := MatrixMultPoint(Transform, T[1]);
TriangleTransformed[2] := MatrixMultPoint(Transform, T[2]);
Plane := TrianglePlane(TriangleTransformed);
Result := (Plane[0] * LightPos[0] +
Plane[1] * LightPos[1] +
Plane[2] * LightPos[2] +
Plane[3] * LightPos[3]) > 0;
if Result then RenderCaps(TriangleTransformed);
end;
{ Comments for Opaque/TransparentTrianglesBegin/End:
It's crucial to set glDepthFunc(GL_NEVER) for LightCap.
This way we get proper self-shadowing. Otherwise, LightCap would
collide in z buffer with the object itself.
Setting glDepthFunc(GL_NEVER) for DarkCap also is harmless and OK.
Proof: if there's anything on this pixel, then indeed the depth test
would fail. If the pixel is empty (nothing was rasterized there),
then the depth test wouldn't fail... but also, in this case value in
stencil buffer will not matter, it doesn't matter if this pixel
is in shadow or not because there's simply nothing there.
And it allows us to render both LightCap and DarkCap in one
GL_TRIANGLES pass, in one iteration over Triangles list, which is
good for speed.
Some papers propose other solution:
glEnable(GL_POLYGON_OFFSET_FILL);
glPolygonOffset(1, 1);
but this is no good for use, because it cannot be applied
to DarkCap (otherwise DarkCap in infinity (as done by ExtrudeVertex)
would go outside of depth range (even for infinite projection,
as glPolygonOffset works already after the vertex is transformed
by projection), and this would make DarkCap not rendered
(outside of depth range)).
If you consider that some shadow casters and receivers may
be partially transparent (that is, rendered without writing
to depth buffer) then the above reasoning is not so simple:
- There's no way to handle transparent
objects (that are not recorded in depth buffer) as shadow receivers.
Rendering them twice with blending would result in wrong blending
modes applied anyway. So TGLShadowVolumeRenderer.Render renders them
at the end, as last pass.
This means that "glDepthFunc(GL_NEVER) for DarkCap" is still
Ok: if on some pixel there was only transparent object visible,
then stencil value of this pixel is wrong, but transparent object
will never be rendered in shadowed state --- so it will not
look at stencil value.
For LightCap, situation is worse. Even if the transparent
object is only shadow caster (not receiver), still problems
may arise due to glDepthFunc(GL_NEVER): imagine you have
a transparent object casting shadow on non-transparent object
(see e.g. demo_models/shadow_volumes/ghost_shadow.wrl).
This means that you can look through the shadow casting
(transp) object and see shadow receiving (opaque) object,
that may or may not be in shadow on speciic pixel.
Which means that glDepthFunc(GL_NEVER) is wrong for LightCap:
the transparent object doesn't hide the shadow on the screen,
and the depth test shouldn't fail. Which means that for transparent
objects, we cannot do glDepthFunc(GL_NEVER).
- What to do?
The trick
glEnable(GL_POLYGON_OFFSET_FILL);
glPolygonOffset(1, 1);
makes light cap rendering working for both transparent and opaque
objects, but it's not applicable to dark cap. Moreover,
using glPolygonOffset always feels dirty.
Solution: we decide to handle transparent objects separately.
We note that for transparent shadow casters
actually no tweaks to caps rendering should be done.
No glPolygonOffset, no glDepthFunc(GL_NEVER) needed: light cap
should be tested as usual. (Since transparent object is not written
to depth buffer, it will not collide in depth buffer with it's
light cap).
This means that is we'll just split triangles list into
transparent and opaque ones, then the only complication needed
is to switch glDepthFunc(GL_NEVER) trick *off* for transparent
triangles. And all works fast.
- There's actually one more note: for transparent objects,
caps are always needed (even with zpass).
Note that this means that whole 2-manifold part must have
caps.
This also means that joining one 2-manifold path from some transparent
and some opaque triangles will not work. (as then some parts
may have caps (like transparent ones) and some note
(like opaque ones with zpass)).
TODO: implement above. We'll need triangles sorted by transparency,
with some marker TrianglesOpaqueCount.
}
procedure OpaqueTrianglesBegin;
begin
if LightCap or DarkCap then
begin
glPushAttrib(GL_DEPTH_BUFFER_BIT); { to save glDepthFunc call below }
glDepthFunc(GL_NEVER);
glBegin(GL_TRIANGLES);
end;
end;
procedure OpaqueTrianglesEnd;
begin
if LightCap or DarkCap then
begin
glEnd;
glPopAttrib;
end;
end;
procedure TransparentTrianglesBegin;
begin
{ Caps are always needed, doesn't depend on zpass/zfail.
Well, for dark cap we can avoid them if the light is directional. }
LightCap := true;
DarkCap := LightPos[3] <> 0;
glBegin(GL_TRIANGLES);
end;
procedure TransparentTrianglesEnd;
begin
glEnd;
end;
var
TrianglePtr: PTriangle3Single;
I: Integer;
OpaqueCount: Cardinal;
begin
TrianglesPlaneSide.Count := Triangles.Count;
TrianglePtr := PTriangle3Single(Triangles.List);
{ If light is directional, no need to render dark cap }
DarkCap := DarkCap and (LightPos[3] <> 0);
if Attributes.ControlBlending and
Attributes.Blending and
(Attributes.Mode = rmFull) then
OpaqueCount := Triangles.OpaqueCount else
OpaqueCount := Triangles.Count; { everything is opaque in this case }
if TransformIsIdentity then
begin
OpaqueTrianglesBegin;
for I := 0 to Integer(OpaqueCount) - 1 do
begin
TrianglesPlaneSide.L[I] := PlaneSide_Identity(TrianglePtr^);
Inc(TrianglePtr);
end;
OpaqueTrianglesEnd;
TransparentTrianglesBegin;
for I := OpaqueCount to Triangles.Count - 1 do
begin
TrianglesPlaneSide.L[I] := PlaneSide_Identity(TrianglePtr^);
Inc(TrianglePtr);
end;
TransparentTrianglesEnd;
end else
begin
OpaqueTrianglesBegin;
for I := 0 to Integer(OpaqueCount) - 1 do
begin
TrianglesPlaneSide.L[I] := PlaneSide_NotIdentity(TrianglePtr^);
Inc(TrianglePtr);
end;
OpaqueTrianglesEnd;
TransparentTrianglesBegin;
for I := OpaqueCount to Triangles.Count - 1 do
begin
TrianglesPlaneSide.L[I] := PlaneSide_NotIdentity(TrianglePtr^);
Inc(TrianglePtr);
end;
TransparentTrianglesEnd;
end;
end;
var
I: Integer;
PlaneSide0, PlaneSide1: boolean;
TrianglesPlaneSide: TBooleanList;
ManifoldEdgesNow: TManifoldEdgeList;
ManifoldEdgePtr: PManifoldEdge;
BorderEdgesNow: TBorderEdgeList;
BorderEdgePtr: PBorderEdge;
begin
Assert(ManifoldEdges <> nil);
{ if the model is not perfect 2-manifold, do not render it's shadow volumes.
We still have here some code to handle BorderEdges, but in practice:
this just has no chance to work 100% reliably with BorderEdges.
See demo_models/shadow_volumes/not_manifold/README.txt }
if BorderEdges.Count <> 0 then Exit;
Triangles := TrianglesListShadowCasters;
TrianglesPlaneSide := TBooleanList.Create;
try
InitializeTrianglesPlaneSideAndRenderCaps(TrianglesPlaneSide,
LightCap, DarkCap);
if LightPos[3] <> 0 then
glBegin(GL_QUADS) else
glBegin(GL_TRIANGLES);
{ for each 2-manifold edge, possibly render it's shadow quad }
ManifoldEdgesNow := ManifoldEdges;
ManifoldEdgePtr := PManifoldEdge(ManifoldEdgesNow.List);
for I := 0 to ManifoldEdgesNow.Count - 1 do
begin
PlaneSide0 := TrianglesPlaneSide.L[ManifoldEdgePtr^.Triangles[0]];
PlaneSide1 := TrianglesPlaneSide.L[ManifoldEdgePtr^.Triangles[1]];
{ Only if PlaneSide0 <> PlaneSide1 it's a silhouette edge,
so only then render it's shadow quad.
We want to have consistent CCW orientation of shadow quads faces,
so that face is oriented CCW <=> you're looking at it from outside
(i.e. it's considered front face of this shadow quad).
This is needed, since user of this method may want to do culling
to eliminate back or front faces.
TriangleDir(T) indicates direction that goes from CCW triangle side
(that's guaranteed by the way TriangleDir calculates plane dir).
So PlaneSideX is @true if LightPos is on CCW side of appropriate
triangle. So if PlaneSide0 the shadow quad is extended
in reversed Triangles[0] order, i.e. like 1, 0, Extruded0, Extruded1.
Otherwise, in normal Triangles[0], i.e. 0, 1, Extruded1, Extruded0.
Just draw it, the triangle corners numbered with 0,1,2 in CCW and
imagine that you want the shadow quad to be also CCW on the outside,
it will make sense then :) }
if PlaneSide0 and not PlaneSide1 then
RenderShadowQuad(ManifoldEdgePtr, 1, 0) else
if PlaneSide1 and not PlaneSide0 then
RenderShadowQuad(ManifoldEdgePtr, 0, 1);
Inc(ManifoldEdgePtr);
end;
{ For each border edge, always render it's shadow quad.
THIS CODE IS NEVER USED NOW (at the beginning of this method,
we exit if BorderEdges.Count <> 0). That's because rendering
the shadow quads from border edges doesn't solve the problem fully:
artifacts are still possible.
See http://http.developer.nvidia.com/GPUGems3/gpugems3_ch11.html
for more involved approach. Rendering shadow quads from border edges,
like below, is only part of the solution. }
BorderEdgesNow := BorderEdges;
BorderEdgePtr := PBorderEdge(BorderEdgesNow.List);
for I := 0 to BorderEdgesNow.Count - 1 do
begin
PlaneSide0 := TrianglesPlaneSide.L[BorderEdgePtr^.TriangleIndex];
{ We want to have consistent CCW orientation of shadow quads faces,
so that face is oriented CCW <=> you're looking at it from outside
(i.e. it's considered front face of this shadow quad).
This is needed, since user of this method may want to do culling
to eliminate back or front faces.
TriangleDir(T) indicates direction that goes from CCW triangle side
(that's guaranteed by the way TriangleDir calculates plane dir).
So PlaneSide0 is true if LightPos is on CCW side of appropriate
triangle. So if PlaneSide0, the shadow quad is extended
in the direction of TriangleIndex, like 1, 0, Extruded0, Extruded1. }
if PlaneSide0 then
RenderShadowQuad(BorderEdgePtr, 1, 0) else
RenderShadowQuad(BorderEdgePtr, 0, 1);
Inc(BorderEdgePtr);
end;
glEnd;
finally FreeAndNil(TrianglesPlaneSide) end;
end;
procedure TCastleScene.RenderShadowVolume(
ShadowVolumeRenderer: TBaseShadowVolumeRenderer;
const ParentTransformIsIdentity: boolean;
const ParentTransform: TMatrix4Single);
var
Box: TBox3D;
SVRenderer: TGLShadowVolumeRenderer;
const
AllowSilhouetteOptimization = true;
begin
if GetExists and CastShadowVolumes then
begin
{ calculate Box }
Box := BoundingBox;
if not ParentTransformIsIdentity then
Box := Box.Transform(ParentTransform);
SVRenderer := ShadowVolumeRenderer as TGLShadowVolumeRenderer;
SVRenderer.InitScene(Box);
if SVRenderer.SceneShadowPossiblyVisible then
begin
if AllowSilhouetteOptimization then
RenderSilhouetteShadowVolume(
SVRenderer.LightPosition, ParentTransformIsIdentity, ParentTransform,
SVRenderer.ZFailAndLightCap,
SVRenderer.ZFail) else
{$warnings off}
{ Do not warn that this code is not reachable because
AllowSilhouetteOptimization is constant. }
RenderAllShadowVolume(
SVRenderer.LightPosition, ParentTransformIsIdentity, ParentTransform,
SVRenderer.ZFailAndLightCap,
SVRenderer.ZFail);
{$warnings on}
end;
end;
end;
procedure TCastleScene.RenderSilhouetteEdges(
const ObserverPos: TVector4Single;
const Transform: TMatrix4Single);
{ This is actually a modified implementation of
TCastleScene.RenderSilhouetteShadowQuads: instead of rendering
shadow quad for each silhouette edge, the edge is simply rendered
as OpenGL line. }
var
Triangles: TTriangle3SingleList;
EdgePtr: PManifoldEdge;
procedure RenderEdge(
const P0Index, P1Index: Cardinal);
var
V0, V1: TVector3Single;
EdgeV0, EdgeV1: PVector3Single;
TrianglePtr: PTriangle3Single;
begin
TrianglePtr := Addr(Triangles.L[EdgePtr^.Triangles[0]]);
EdgeV0 := @TrianglePtr^[(EdgePtr^.VertexIndex + P0Index) mod 3];
EdgeV1 := @TrianglePtr^[(EdgePtr^.VertexIndex + P1Index) mod 3];
V0 := MatrixMultPoint(Transform, EdgeV0^);
V1 := MatrixMultPoint(Transform, EdgeV1^);
glVertexv(V0);
glVertexv(V1);
end;
function PlaneSide(const T: TTriangle3Single): boolean;
var
Plane: TVector4Single;
begin
Plane := TrianglePlane(
MatrixMultPoint(Transform, T[0]),
MatrixMultPoint(Transform, T[1]),
MatrixMultPoint(Transform, T[2]));
Result := (Plane[0] * ObserverPos[0] +
Plane[1] * ObserverPos[1] +
Plane[2] * ObserverPos[2] +
Plane[3] * ObserverPos[3]) > 0;
end;
var
I: Integer;
TrianglePtr: PTriangle3Single;
PlaneSide0, PlaneSide1: boolean;
TrianglesPlaneSide: TBooleanList;
Edges: TManifoldEdgeList;
begin
glBegin(GL_LINES);
Triangles := TrianglesListShadowCasters;
Edges := ManifoldEdges;
TrianglesPlaneSide := TBooleanList.Create;
try
{ calculate TrianglesPlaneSide array }
TrianglesPlaneSide.Count := Triangles.Count;
TrianglePtr := PTriangle3Single(Triangles.List);
for I := 0 to Triangles.Count - 1 do
begin
TrianglesPlaneSide.L[I] := PlaneSide(TrianglePtr^);
Inc(TrianglePtr);
end;
{ for each edge, possibly render it's shadow quad }
EdgePtr := PManifoldEdge(Edges.List);
for I := 0 to Edges.Count - 1 do
begin
PlaneSide0 := TrianglesPlaneSide.L[EdgePtr^.Triangles[0]];
PlaneSide1 := TrianglesPlaneSide.L[EdgePtr^.Triangles[1]];
if PlaneSide0 <> PlaneSide1 then
RenderEdge(0, 1);
Inc(EdgePtr);
end;
finally FreeAndNil(TrianglesPlaneSide) end;
glEnd;
end;
procedure TCastleScene.RenderBorderEdges(
const Transform: TMatrix4Single);
var
Triangles: TTriangle3SingleList;
EdgePtr: PBorderEdge;
procedure RenderEdge;
var
V0, V1: TVector3Single;
EdgeV0, EdgeV1: PVector3Single;
TrianglePtr: PTriangle3Single;
begin
TrianglePtr := Addr(Triangles.L[EdgePtr^.TriangleIndex]);
EdgeV0 := @TrianglePtr^[(EdgePtr^.VertexIndex + 0) mod 3];
EdgeV1 := @TrianglePtr^[(EdgePtr^.VertexIndex + 1) mod 3];
V0 := MatrixMultPoint(Transform, EdgeV0^);
V1 := MatrixMultPoint(Transform, EdgeV1^);
glVertexv(V0);
glVertexv(V1);
end;
var
I: Integer;
Edges: TBorderEdgeList;
begin
glBegin(GL_LINES);
Triangles := TrianglesListShadowCasters;
Edges := BorderEdges;
{ for each edge, render it }
EdgePtr := PBorderEdge(Edges.List);
for I := 0 to Edges.Count - 1 do
begin
RenderEdge;
Inc(EdgePtr);
end;
glEnd;
end;
{ Frustum culling ------------------------------------------------------------ }
function TCastleScene.FrustumCulling_None(Shape: TGLShape): boolean;
begin
Result := true;
end;
function TCastleScene.FrustumCulling_Sphere(Shape: TGLShape): boolean;
begin
Result := Shape.FrustumBoundingSphereCollisionPossibleSimple(
RenderFrustum_Frustum^);
end;
function TCastleScene.FrustumCulling_Box(Shape: TGLShape): boolean;
begin
Result := RenderFrustum_Frustum^.Box3DCollisionPossibleSimple(
Shape.BoundingBox);
end;
function TCastleScene.FrustumCulling_Both(Shape: TGLShape): boolean;
begin
Result :=
Shape.FrustumBoundingSphereCollisionPossibleSimple(
RenderFrustum_Frustum^) and
RenderFrustum_Frustum^.Box3DCollisionPossibleSimple(
Shape.BoundingBox);
end;
procedure TCastleScene.SetFrustumCulling(const Value: TFrustumCulling);
begin
if Value <> FFrustumCulling then
begin
FFrustumCulling := Value;
case Value of
{ FrustumCullingFunc may be @nil (unlike OctreeFrustumCullingFunc). }
fcNone : FrustumCullingFunc := nil;
fcSphere: FrustumCullingFunc := @FrustumCulling_Sphere;
fcBox : FrustumCullingFunc := @FrustumCulling_Box;
fcBoth : FrustumCullingFunc := @FrustumCulling_Both;
else raise EInternalError.Create('SetFrustumCulling?');
end;
end;
end;
procedure TCastleScene.SetOctreeFrustumCulling(const Value: TFrustumCulling);
begin
if Value <> FOctreeFrustumCulling then
begin
FOctreeFrustumCulling := Value;
case Value of
fcNone : OctreeFrustumCullingFunc := @FrustumCulling_None;
fcSphere: OctreeFrustumCullingFunc := @FrustumCulling_Sphere;
fcBox : OctreeFrustumCullingFunc := @FrustumCulling_Box;
fcBoth : OctreeFrustumCullingFunc := @FrustumCulling_Both;
else raise EInternalError.Create('SetOctreeFrustumCulling?');
end;
end;
end;
{ Render --------------------------------------------------------------------- }
function TCastleScene.RenderFrustumOctree_TestShape(
Shape: TGLShape): boolean;
begin
Result := Shape.RenderFrustumOctree_Visible;
end;
procedure TCastleScene.RenderFrustumOctree_EnumerateShapes(
ShapeIndex: Integer; CollidesForSure: boolean);
var
Shape: TGLShape;
begin
Shape := TGLShape(OctreeRendering.ShapesList[ShapeIndex]);
if (not Shape.RenderFrustumOctree_Visible) and
( CollidesForSure or
OctreeFrustumCullingFunc(Shape) ) then
Shape.RenderFrustumOctree_Visible := true;
end;
procedure TCastleScene.Render(const Frustum: TFrustum; const Params: TRenderParams);
{ Call Render with explicit TTestShapeVisibility function.
That is, choose test function suitable for our Frustum,
octrees and some settings.
If OctreeRendering is initialized (so be sure to include
ssRendering in @link(Spatial)), this octree will be used to quickly
find visible Shape. Otherwise, we will just enumerate all
Shapes (which may be slower if you really have a lot of Shapes). }
procedure RenderFrustumOctree(Octree: TShapeOctree);
procedure ResetShapeVisible(Shape: TShape);
begin
TGLShape(Shape).RenderFrustumOctree_Visible := false;
end;
begin
Shapes.Traverse(@ResetShapeVisible, false, true);
Octree.EnumerateCollidingOctreeItems(Frustum,
@RenderFrustumOctree_EnumerateShapes);
Render(@RenderFrustumOctree_TestShape, Frustum, Params);
end;
begin
if GetExists and (Dirty = 0) and
(ReceiveShadowVolumes = Params.ShadowVolumesReceivers) then
begin
RenderFrustum_Frustum := @Frustum;
if OctreeRendering <> nil then
RenderFrustumOctree(OctreeRendering) else
Render(FrustumCullingFunc, Frustum, Params);
end;
end;
{ Background-related things -------------------------------------------------- }
procedure TCastleScene.InvalidateBackground;
begin
FreeAndNil(FBackground);
FBackgroundNode := nil;
FBackgroundValid := false;
end;
procedure TCastleScene.SetBackgroundSkySphereRadius(const Value: Single);
begin
if Value <> FBackgroundSkySphereRadius then
begin
InvalidateBackground;
FBackgroundSkySphereRadius := Value;
end;
end;
procedure TCastleScene.PrepareBackground;
{ After PrepareBackground assertion FBackgroundValid is valid }
var
BgNode: TBackgroundNode;
SkyAngleCount: Integer;
SkyColorCount: Integer;
GroundAngleCount: Integer;
GroundColorCount: Integer;
begin
if FBackgroundValid and (BackgroundStack.Top = FBackgroundNode) then
Exit;
{ Background is created, but not suitable for current
BackgroundStack.Top. So destroy it. }
if FBackgroundValid then
InvalidateBackground;
if (BackgroundStack.Top <> nil) and
(BackgroundStack.Top is TBackgroundNode) then
begin
if Log then
WritelnLog('Background', Format('OpenGL background recreated, with radius %f',
[BackgroundSkySphereRadius]));
BgNode := TBackgroundNode(BackgroundStack.Top);
SkyAngleCount := BgNode.FdSkyAngle.Count;
SkyColorCount := BgNode.FdSkyColor.Count;
if SkyColorCount <= 0 then
begin
OnWarning(wtMajor, 'VRML/X3D', 'Background node incorrect: ' +
'Sky must have at least one color');
FBackground := nil;
end else
begin
if SkyAngleCount + 1 <> SkyColorCount then
begin
OnWarning(wtMajor, 'VRML/X3D', 'Background node incorrect: ' +
'Sky must have exactly one more Color than Angles');
{ We know now that SkyColorCount >= 1 and
SkyAngleCount >= 0 (since SkyAngleCount is a count of an array).
So we correct one of them to be smaller. }
if SkyAngleCount + 1 > SkyColorCount then
SkyAngleCount := SkyColorCount - 1 else
SkyColorCount := SkyAngleCount + 1;
end;
GroundAngleCount := BgNode.FdGroundAngle.Count;
GroundColorCount := BgNode.FdGroundColor.Count;
if (GroundAngleCount <> 0) and
(GroundAngleCount + 1 <> GroundColorCount) then
begin
OnWarning(wtMajor, 'VRML/X3D', 'Background node incorrect: ' +
'Ground must have exactly one more Color than Angles');
{ We know now that GroundColorCount >= 1 and
GroundAngleCount >= 0 (since GroundAngleCount is a count of an array).
So we correct one of them to be smaller. }
if GroundAngleCount + 1 > GroundColorCount then
GroundAngleCount := GroundColorCount - 1 else
GroundColorCount := GroundAngleCount + 1;
end;
FBackground := TBackground.Create(
PArray_Single(BgNode.FdGroundAngle.Items.List), GroundAngleCount,
PArray_Vector3Single(BgNode.FdGroundColor.Items.List), GroundColorCount,
BgNode.Textures,
PArray_Single(BgNode.FdSkyAngle.Items.List), SkyAngleCount,
PArray_Vector3Single(BgNode.FdSkyColor.Items.List), SkyColorCount,
BackgroundSkySphereRadius);
end;
end else
FBackground := nil;
FBackgroundNode := BackgroundStack.Top;
FBackgroundValid := true;
end;
function TCastleScene.Background: TBackground;
var
BackgroundNode: TAbstractBackgroundNode;
begin
PrepareBackground;
Result := FBackground;
BackgroundNode := BackgroundStack.Top;
if (BackgroundNode <> nil) and
{ We have to still check Result, since not every TAbstractBackgroundNode
is supported now, so for some background nodes we still have
Result = nil. }
(Result <> nil) then
begin
Result.Transform := BackgroundNode.TransformRotation;
end;
end;
function TCastleScene.Attributes: TSceneRenderingAttributes;
begin
Result := Renderer.Attributes as TSceneRenderingAttributes;
end;
procedure TCastleScene.UpdateGeneratedTextures(
const RenderFunc: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
const OriginalViewportX, OriginalViewportY: LongInt;
const OriginalViewportWidth, OriginalViewportHeight: Cardinal);
var
I: Integer;
NeedsRestoreViewport: boolean;
Shape: TGLShape;
TextureNode: TAbstractTextureNode;
begin
NeedsRestoreViewport := false;
for I := 0 to GeneratedTextures.Count - 1 do
begin
Shape := TGLShape(GeneratedTextures.L[I].Shape);
TextureNode := GeneratedTextures.L[I].TextureNode;
if TextureNode is TGeneratedCubeMapTextureNode then
AvoidShapeRendering := Shape else
if TextureNode is TGeneratedShadowMapNode then
AvoidNonShadowCasterRendering := true;
Renderer.UpdateGeneratedTextures(Shape, TextureNode,
RenderFunc, ProjectionNear, ProjectionFar, NeedsRestoreViewport,
ViewpointStack.Top,
CameraViewKnown, CameraPosition, CameraDirection, CameraUp);
AvoidShapeRendering := nil;
AvoidNonShadowCasterRendering := false;
end;
if NeedsRestoreViewport then
glViewport(OriginalViewportX, OriginalViewportY,
OriginalViewportWidth, OriginalViewportHeight);
end;
procedure TCastleScene.ViewChangedSuddenly;
var
SI: TShapeTreeIterator;
begin
inherited;
if Attributes.ReallyUseOcclusionQuery then
begin
if Log then
WritelnLog('Occlusion query', 'View changed suddenly');
{ Set OcclusionQueryAsked := false for all shapes. }
SI := TShapeTreeIterator.Create(Shapes, false, false, false);
try
while SI.GetNext do
TGLShape(SI.Current).OcclusionQueryAsked := false;
finally FreeAndNil(SI) end;
end;
end;
procedure TCastleScene.VisibleChangeNotification(const Changes: TVisibleChanges);
var
I: Integer;
begin
inherited;
{ set UpdateNeeded := true before calling inherited (with VisibleChange
and OnVisibleChange callback), because inside OnVisibleChange callback
we'll actually initialize regenerating the textures. }
if Changes <> [] then
begin
for I := 0 to GeneratedTextures.Count - 1 do
begin
if GeneratedTextures.L[I].TextureNode is TGeneratedCubeMapTextureNode then
begin
if [vcVisibleGeometry, vcVisibleNonGeometry] * Changes <> [] then
GeneratedTextures.L[I].Handler.UpdateNeeded := true;
end else
if GeneratedTextures.L[I].TextureNode is TGeneratedShadowMapNode then
begin
if vcVisibleGeometry in Changes then
GeneratedTextures.L[I].Handler.UpdateNeeded := true;
end else
{ Even mere vcCamera causes regenerate of RenderedTexture,
as RenderedTexture with viewpoint = NULL uses current camera.
So any Changes <> [] causes regeneration of RenderedTexture.
Also, for other than RenderedTexture nodes, default is to regenerate
(safer). }
GeneratedTextures.L[I].Handler.UpdateNeeded := true;
end;
end;
end;
function TCastleScene.ScreenEffectsCount: Integer;
var
I: Integer;
SE: TScreenEffectNode;
begin
Result := 0;
if Attributes.Shaders <> srDisable then
for I := 0 to ScreenEffectNodes.Count - 1 do
begin
SE := TScreenEffectNode(ScreenEffectNodes[I]);
Renderer.PrepareScreenEffect(SE);
if SE.Shader <> nil then
Inc(Result);
end;
end;
function TCastleScene.ScreenEffects(Index: Integer): TGLSLProgram;
var
I: Integer;
SE: TScreenEffectNode;
begin
{ No need for PrepareScreenEffect here, ScreenEffectsCount (that does
PrepareScreenEffect) is always called first, otherwise the caller
would not know that this Index is valid. }
for I := 0 to ScreenEffectNodes.Count - 1 do
begin
SE := TScreenEffectNode(ScreenEffectNodes[I]);
if SE.Shader <> nil then
if Index = 0 then
Exit(TGLSLProgram(SE.Shader)) else
Dec(Index);
end;
raise EInternalError.Create('TCastleScene.ScreenEffects: Invalid index');
end;
function TCastleScene.ScreenEffectsNeedDepth: boolean;
var
I: Integer;
begin
{ For now: No need for PrepareScreenEffect here, ScreenEffectsCount
is always called first. But actually for some scenarios we should do
here PrepareScreenEffect? }
for I := 0 to ScreenEffectNodes.Count - 1 do
if (TScreenEffectNode(ScreenEffectNodes[I]).Shader <> nil) and
TScreenEffectNode(ScreenEffectNodes[I]).FdNeedsDepth.Value then
Exit(true);
Exit(false);
end;
{ TSceneRenderingAttributes ---------------------------------------------- }
constructor TSceneRenderingAttributes.Create;
begin
inherited;
FBlending := true;
FBlendingSourceFactor := DefaultBlendingSourceFactor;
FBlendingDestinationFactor := DefaultBlendingDestinationFactor;
FBlendingSort := DefaultBlendingSort;
FControlBlending := true;
FWireframeEffect := weNormal;
FWireframeColor := DefaultWireframeColor;
FScenes := TCastleSceneList.Create(false);
if Assigned(OnCreate) then
OnCreate(Self);
end;
destructor TSceneRenderingAttributes.Destroy;
begin
FreeAndNil(FScenes);
inherited;
end;
procedure TSceneRenderingAttributes.Assign(Source: TPersistent);
var
S: TSceneRenderingAttributes;
begin
if Source is TSceneRenderingAttributes then
begin
S := TSceneRenderingAttributes(Source);
Blending := S.Blending;
BlendingSourceFactor := S.BlendingSourceFactor;
BlendingDestinationFactor := S.BlendingDestinationFactor;
BlendingSort := S.BlendingSort;
ControlBlending := S.ControlBlending;
UseOcclusionQuery := S.UseOcclusionQuery;
UseHierarchicalOcclusionQuery := S.UseHierarchicalOcclusionQuery;
inherited;
end else
inherited;
end;
procedure TSceneRenderingAttributes.ReleaseCachedResources;
begin
inherited;
{ We have to do at least Renderer.UnprepareAll.
Actually, we have to do more: TCastleScene must also be disconnected
from OpenGL, to release screen effects (referencing renderer shaders)
and such. So full CloseGLRenderer is needed. }
if TemporaryAttributeChange = 0 then
FScenes.CloseGLRenderer;
end;
procedure TSceneRenderingAttributes.SetBlending(const Value: boolean);
begin
FBlending := Value;
end;
procedure TSceneRenderingAttributes.SetBlendingSourceFactor(
const Value: TGLenum);
begin
FBlendingSourceFactor := Value;
end;
procedure TSceneRenderingAttributes.SetBlendingDestinationFactor(
const Value: TGLenum);
begin
FBlendingDestinationFactor := Value;
end;
procedure TSceneRenderingAttributes.SetBlendingSort(const Value: boolean);
begin
FBlendingSort := Value;
end;
procedure TSceneRenderingAttributes.SetControlBlending(const Value: boolean);
begin
FControlBlending := Value;
end;
procedure TSceneRenderingAttributes.SetUseOcclusionQuery(const Value: boolean);
var
I: Integer;
begin
if UseOcclusionQuery <> Value then
begin
FUseOcclusionQuery := Value;
if UseOcclusionQuery then
begin
{ If you switch UseOcclusionQuery on, then off, then move around the scene
a lot, then switch UseOcclusionQuery back on --- you don't want to use
results from previous query that was done many frames ago. }
FScenes.ViewChangedSuddenly;
{ Make PrepareShapesResouces again, to cause TGLShape.PrepareResources
that initializes OcclusionQueryId for each shape }
if TemporaryAttributeChange = 0 then
for I := 0 to FScenes.Count - 1 do
if FScenes[I] <> nil then
FScenes[I].PreparedShapesResouces := false;
end;
end;
end;
function TSceneRenderingAttributes.ReallyUseOcclusionQuery: boolean;
begin
Result := UseOcclusionQuery and (not UseHierarchicalOcclusionQuery) and
GLFeatures.ARB_occlusion_query and (GLFeatures.QueryCounterBits > 0);
end;
function TSceneRenderingAttributes.
ReallyUseHierarchicalOcclusionQuery: boolean;
begin
Result := UseHierarchicalOcclusionQuery and GLFeatures.ARB_occlusion_query and
(GLFeatures.QueryCounterBits > 0);
end;
procedure TSceneRenderingAttributes.SetShaders(const Value: TShadersRendering);
var
I: Integer;
begin
if Shaders <> Value then
begin
inherited;
{ When switching to a higher TShadersRendering value
(that uses more shaders), we want to force generating necessary
shaders at the next PrepareResources call. Otherwise shaders would
be prepared only when shapes come into view, which means that navigating
awfully stutters for some time after changing this property. }
if TemporaryAttributeChange = 0 then
for I := 0 to FScenes.Count - 1 do
if FScenes[I] <> nil then
FScenes[I].PreparedRender := false;
end;
end;
{ TCastleSceneList ------------------------------------------------------ }
procedure TCastleSceneList.GLContextClose;
{ This may be called from various destructors,
so we are extra careful here and check Items[I] <> nil. }
var
I: Integer;
begin
for I := 0 to Count - 1 do
if Items[I] <> nil then
Items[I].GLContextClose;
end;
procedure TCastleSceneList.InvalidateBackground;
{ This may be called from various destructors,
so we are extra careful here and check Items[I] <> nil. }
var
I: Integer;
begin
for I := 0 to Count - 1 do
if Items[I] <> nil then
Items[I].InvalidateBackground;
end;
procedure TCastleSceneList.CloseGLRenderer;
{ This may be called from various destructors,
so we are extra careful here and check Items[I] <> nil. }
var
I: Integer;
begin
for I := 0 to Count - 1 do
if Items[I] <> nil then
Items[I].CloseGLRenderer;
end;
procedure TCastleSceneList.ViewChangedSuddenly;
var
I: Integer;
begin
for I := 0 to Count - 1 do
if Items[I] <> nil then
Items[I].ViewChangedSuddenly;
end;
initialization
GLContextCache := TGLRendererContextCache.Create;
finalization
FreeAndNil(GLContextCache);
end.
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