/usr/src/castle-game-engine-4.1.1/opengl/castleglcubemaps.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 2008-2013 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.
----------------------------------------------------------------------------
}
{ OpenGL utilities for cube (environment) maps. }
unit CastleGLCubeMaps;
interface
uses CastleVectors, CastleCubeMaps, CastleImages, CastleDDS, GL, GLU, CastleGLUtils,
CastleRenderingCamera, CastleGLImages, Castle3D;
type
TCubeMapRenderSimpleFunction = procedure (ForCubeMap: boolean);
{ Calculate spherical harmonics basis describing environment rendered
by OpenGL. Environment is rendered by
Render(true) callback, from the
CapturePoint. It's rendered to color buffer, and captured as grayscale.
Captured pixel value is just assumed to be the value of spherical function
at this direction. It's also scaled by ScaleColor (since rendering
to OpenGL catches values in 0..1 range, but SH vector can express
values from any range).
This changes glViewport, so be sure to reset glViewport to something
normal after calling this.
The maps will be drawn in the color buffer (from positions MapScreenX, Y),
so will actually be visible (call this before glClear or such if you
want to hide them). }
procedure SHVectorGLCapture(
var SHVector: array of Single;
const CapturePoint: TVector3Single;
const Render: TCubeMapRenderSimpleFunction;
const MapScreenX, MapScreenY: Integer;
const ScaleColor: Single);
type
TCubeMapImages = array [TCubeMapSide] of TCastleImage;
{ Capture cube map by rendering environment from CapturePoint.
Environment is rendered by Render callback
that must honour camera described in RenderingCamera object.
RenderingCamera.Target will be set to rtCubeMapEnvironment.
RenderingCamera camera will be set to appropriate views
from the CapturePoint. You should at least load RenderingCamera.Matrix
to OpenGL modelview matrix before rendering your 3D scene.
Scene is rendered to color buffer, captured as appropriate
for Images classes (e.g. TGrayscaleImage, or TRGBImage).
Cube map is recorded in six images provided in Images parameter.
These must be already created TCastleImage instances with the exact same size.
(But we do not require here the images to be square, or have power-of-two
size, or honor GL_MAX_CUBE_MAP_TEXTURE_SIZE_ARB limit,
as we do not initialize actual OpenGL cube map here.
You can use generated images for any purpose.)
This changes glViewport, so be sure to reset glViewport to something
normal after calling this.
ProjectionNear, ProjectionFar parameters will be used to set GL
projection matrix. ProjectionFar may be equal to ZFarInfinity,
as always.
@param(MapsOverlap
If @false then the six maps will be drawn on non-overlapping
locations in the color buffer, and will be shifted by MapScreenX, Y.
This has two benefits: you can actually show the generated maps then
(useful for debug purposes). And, more important, you can sometimes
get away then with only one glClear before GLCaptureCubeMapImages
(avoiding doing glClear in each Render).
Otherwise (when NiceMapsLayout = @false),
then MapScreenX, Y will be ignored, and all images will be simply
drawn in screen lower-left corner starting from (0, 0).
The benefit is that this has the most chance of fitting into
your window size.) }
procedure GLCaptureCubeMapImages(
const Images: TCubeMapImages;
const CapturePoint: TVector3Single;
const Render: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
const MapsOverlap: boolean;
const MapScreenX, MapScreenY: Integer);
{ Capture cube map to DDS image by rendering environment from CapturePoint.
See GLCaptureCubeMapImages for documentation, this works the same,
but it creates TDDSImage instance containing all six images (oriented
as appropriate for DDS). }
function GLCaptureCubeMapDDS(
const Size: Cardinal;
const CapturePoint: TVector3Single;
const Render: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
const MapsOverlap: boolean;
const MapScreenX, MapScreenY: Integer): TDDSImage;
{ Capture cube map to OpenGL cube map texture by rendering environment
from CapturePoint.
See GLCaptureCubeMapImages for documentation, this works the same,
but it captures images to given OpenGL texture name Tex.
Tex must already be created cube map texture (with OpenGL
size and internal formats set), with square images of Size.
This also means that Size must be a valid OpenGL cube map texture size,
you can check it by GLImages.IsCubeMapTextureSized.
This captures the cube map images to "zero" texture level.
If you use mipmaps, it's your problem how to generate other texture levels
--- in the simplest case, call GenerateMipmap(GL_TEXTURE_CUBE_MAP).
It uses RenderToTexture to render to the texture, so it will use
framebuffer if available, and it's fast. }
procedure GLCaptureCubeMapTexture(
const Tex: TGLuint;
const Size: Cardinal;
const CapturePoint: TVector3Single;
const Render: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
RenderToTexture: TGLRenderToTexture);
implementation
uses SysUtils, CastleSphericalHarmonics, GLExt;
procedure SHVectorGLCapture(
var SHVector: array of Single;
const CapturePoint: TVector3Single;
const Render: TCubeMapRenderSimpleFunction;
const MapScreenX, MapScreenY: Integer;
const ScaleColor: Single);
procedure DrawMap(Side: TCubeMapSide);
var
Map: TGrayscaleImage;
I, SHBasis, ScreenX, ScreenY: Integer;
begin
ScreenX := CubeMapInfo[Side].ScreenX * CubeMapSize + MapScreenX;
ScreenY := CubeMapInfo[Side].ScreenY * CubeMapSize + MapScreenY;
{ We have to clear the buffer first. Clearing with glClear is fast,
but it must be clipped with scissor (glViewport does not clip glClear).
Later: actually, clearing is not needed now, since we call DrawLightMap
at the beginning, right after clearing the whole screen.
glScissor(ScreenX, ScreenY, CubeMapSize, CubeMapSize);
glEnable(GL_SCISSOR_TEST);
glClear(GL_COLOR_BUFFER_BIT);
glDisable(GL_SCISSOR_TEST);
}
glViewport(ScreenX, ScreenY, CubeMapSize, CubeMapSize);
glMatrixMode(GL_PROJECTION);
glPushMatrix;
glLoadIdentity;
glMultMatrix(PerspectiveProjMatrixDeg(90, 1, 0.01, 100));
glMatrixMode(GL_MODELVIEW);
glPushMatrix;
glLoadMatrix(LookDirMatrix(CapturePoint, CubeMapInfo[Side].Dir, CubeMapInfo[Side].Up));
Render(true);
glPopMatrix;
glMatrixMode(GL_PROJECTION);
glPopMatrix;
glMatrixMode(GL_MODELVIEW);
Map := TGrayscaleImage(SaveScreen_noflush(TGrayscaleImage,
ScreenX, ScreenY, CubeMapSize, CubeMapSize, GL_BACK));
try
{ Use the Map to calculate SHVector[SHBasis] (this is the actual
purpose of drawing the Render). SHVector[SHBasis] is just a dot product
for all directions (for all pixels, in this case) of
light intensity values * SH basis values. }
for I := 0 to Sqr(CubeMapSize) - 1 do
for SHBasis := 0 to High(SHVector) do
SHVector[SHBasis] += (Map.GrayscalePixels[I]/255) *
ScaleColor *
SHBasisMap[SHBasis, Side, I];
finally FreeAndNil(Map) end;
end;
var
SHBasis: Integer;
Side: TCubeMapSide;
begin
InitializeSHBasisMap;
{ Call all DrawMap. This wil draw maps, get them,
and calculate SHVector describing them. }
for SHBasis := 0 to High(SHVector) do
SHVector[SHBasis] := 0;
for Side := Low(TCubeMapSide) to High(TCubeMapSide) do
DrawMap(Side);
for SHBasis := 0 to High(SHVector) do
begin
{ Each SHVector[SHBasis] is now calculated for all sphere points.
We want this to be integral over a sphere, so normalize now.
Since SHBasisMap contains result of SH function * solid angle of pixel
(on cube map, pixels have different solid angles),
so below we divide by 4*Pi (sphere area, sum of solid angles for every
pixel). }
SHVector[SHBasis] /= 4 * Pi;
end;
end;
procedure SetRenderingCamera(
const CapturePoint: TVector3Single;
const Side: TCubeMapSide;
const ProjectionMatrix: TMatrix4Single);
begin
RenderingCamera.FromMatrix(
LookDirMatrix(CapturePoint, CubeMapInfo[Side].Dir, CubeMapInfo[Side].Up),
FastLookDirMatrix(CubeMapInfo[Side].Dir, CubeMapInfo[Side].Up),
ProjectionMatrix, nil);
end;
procedure GLCaptureCubeMapImages(
const Images: TCubeMapImages;
const CapturePoint: TVector3Single;
const Render: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
const MapsOverlap: boolean;
const MapScreenX, MapScreenY: Integer);
var
Width, Height: Cardinal;
procedure DrawMap(Side: TCubeMapSide);
var
ScreenX, ScreenY: Integer;
ProjectionMatrix: TMatrix4Single;
begin
if MapsOverlap then
begin
ScreenX := 0;
ScreenY := 0;
end else
begin
ScreenX := CubeMapInfo[Side].ScreenX * Integer(Width ) + MapScreenX;
ScreenY := CubeMapInfo[Side].ScreenY * Integer(Height) + MapScreenY;
end;
glViewport(ScreenX, ScreenY, Width, Height);
glMatrixMode(GL_PROJECTION);
glPushMatrix;
ProjectionMatrix := PerspectiveProjMatrixDeg(90, 1, ProjectionNear, ProjectionFar);
glLoadMatrix(ProjectionMatrix);
glMatrixMode(GL_MODELVIEW);
RenderingCamera.Target := rtCubeMapEnvironment;
SetRenderingCamera(CapturePoint, Side, ProjectionMatrix);
Render;
glMatrixMode(GL_PROJECTION);
glPopMatrix;
glMatrixMode(GL_MODELVIEW);
SaveScreen_noflush(Images[Side], ScreenX, ScreenY, GL_BACK);
end;
var
Side: TCubeMapSide;
begin
Width := Images[csPositiveX].Width ;
Height := Images[csPositiveX].Height;
for Side := Low(TCubeMapSide) to High(TCubeMapSide) do
DrawMap(Side);
end;
function GLCaptureCubeMapDDS(
const Size: Cardinal;
const CapturePoint: TVector3Single;
const Render: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
const MapsOverlap: boolean;
const MapScreenX, MapScreenY: Integer): TDDSImage;
var
Images: TCubeMapImages;
Side: TCubeMapSide;
begin
for Side := Low(Side) to High(Side) do
Images[Side] := TRGBImage.Create(Size, Size);
GLCaptureCubeMapImages(Images, CapturePoint, Render,
ProjectionNear, ProjectionFar,
MapsOverlap, MapScreenX, MapScreenY);
Result := TDDSImage.Create;
Result.Width := Size;
Result.Height := Size;
Result.DDSType := dtCubeMap;
Result.CubeMapSides := AllDDSCubeMapSides;
Result.Mipmaps := false;
Result.MipmapsCount := 1;
Result.Images.Count := 6;
Result.Images[Ord(dcsPositiveX)] := Images[csPositiveX];
Result.Images[Ord(dcsNegativeX)] := Images[csNegativeX];
{ For DDS positive/negative Y must be swapped (Direct X has left-handed
coord system). }
Result.Images[Ord(dcsNegativeY)] := Images[csPositiveY];
Result.Images[Ord(dcsPositiveY)] := Images[csNegativeY];
Result.Images[Ord(dcsPositiveZ)] := Images[csPositiveZ];
Result.Images[Ord(dcsNegativeZ)] := Images[csNegativeZ];
end;
procedure GLCaptureCubeMapTexture(
const Tex: TGLuint;
const Size: Cardinal;
const CapturePoint: TVector3Single;
const Render: TRenderFromViewFunction;
const ProjectionNear, ProjectionFar: Single;
RenderToTexture: TGLRenderToTexture);
procedure DrawMap(Side: TCubeMapSide);
var
ProjectionMatrix: TMatrix4Single;
begin
{ I used to implement here MapsOverlap, MapScreenX, MapScreenY,
but removed (since inherently conflicting with framebuffer possibility
inside TGLRenderToTexture).
if MapsOverlap then
begin
ScreenX := 0;
ScreenY := 0;
end else
begin
ScreenX := CubeMapInfo[Side].ScreenX * Integer(Size) + MapScreenX;
ScreenY := CubeMapInfo[Side].ScreenY * Integer(Size) + MapScreenY;
end;
}
RenderToTexture.RenderBegin;
RenderToTexture.SetTexture(Tex, GL_TEXTURE_CUBE_MAP_POSITIVE_X_ARB + Ord(Side));
glViewport(0, 0, Size, Size);
glMatrixMode(GL_PROJECTION);
glPushMatrix;
ProjectionMatrix := PerspectiveProjMatrixDeg(90, 1, ProjectionNear, ProjectionFar);
glLoadMatrix(ProjectionMatrix);
glMatrixMode(GL_MODELVIEW);
RenderingCamera.Target := rtCubeMapEnvironment;
SetRenderingCamera(CapturePoint, Side, ProjectionMatrix);
Render;
glMatrixMode(GL_PROJECTION);
glPopMatrix;
glMatrixMode(GL_MODELVIEW);
RenderToTexture.RenderEnd(Side < High(Side));
end;
var
Side: TCubeMapSide;
begin
RenderToTexture.CompleteTextureTarget := GL_TEXTURE_CUBE_MAP_ARB;
for Side := Low(TCubeMapSide) to High(TCubeMapSide) do
DrawMap(Side);
end;
end.
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