/*
===========================================================================
Doom 3 BFG Edition GPL Source Code
Copyright (C) 1993-2012 id Software LLC, a ZeniMax Media company.
This file is part of the Doom 3 BFG Edition GPL Source Code ("Doom 3 BFG Edition Source Code").
Doom 3 BFG Edition Source Code is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Doom 3 BFG Edition Source Code 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. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Doom 3 BFG Edition Source Code. If not, see <http://www.gnu.org/licenses/>.
In addition, the Doom 3 BFG Edition Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 BFG Edition Source Code. If not, please request a copy in writing from id Software at the address below.
If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA.
===========================================================================
*/
#ifndef __RENDERER_H__
#define __RENDERER_H__
/*
===============================================================================
idRenderSystem is responsible for managing the screen, which can have
multiple idRenderWorld and 2D drawing done on it.
===============================================================================
*/
enum stereo3DMode_t
{
STEREO3D_OFF,
// half-resolution, non-square pixel views
STEREO3D_SIDE_BY_SIDE_COMPRESSED,
STEREO3D_TOP_AND_BOTTOM_COMPRESSED,
// two full resolution views side by side, as for a dual cable display
STEREO3D_SIDE_BY_SIDE,
STEREO3D_INTERLACED,
// OpenGL quad buffer
STEREO3D_QUAD_BUFFER,
// two full resolution views stacked with a 30 pixel guard band
// On the PC this can be configured as a custom video timing, but
// it definitely isn't a consumer level task. The quad_buffer
// support can handle 720P-3D with apropriate driver support.
STEREO3D_HDMI_720
};
typedef enum
{
AUTORENDER_DEFAULTICON = 0,
AUTORENDER_HELLICON,
AUTORENDER_DIALOGICON,
AUTORENDER_MAX
} autoRenderIconType_t ;
enum stereoDepthType_t
{
STEREO_DEPTH_TYPE_NONE,
STEREO_DEPTH_TYPE_NEAR,
STEREO_DEPTH_TYPE_MID,
STEREO_DEPTH_TYPE_FAR
};
enum graphicsVendor_t
{
VENDOR_NVIDIA,
VENDOR_AMD,
VENDOR_INTEL
};
// Contains variables specific to the OpenGL configuration being run right now.
// These are constant once the OpenGL subsystem is initialized.
struct glconfig_t
{
const char* renderer_string;
const char* vendor_string;
const char* version_string;
const char* extensions_string;
const char* wgl_extensions_string;
const char* shading_language_string;
float glVersion; // atof( version_string )
graphicsVendor_t vendor;
int maxTextureSize; // queried from GL
int maxTextureCoords;
int maxTextureImageUnits;
int uniformBufferOffsetAlignment;
float maxTextureAnisotropy;
int colorBits;
int depthBits;
int stencilBits;
bool multitextureAvailable;
bool directStateAccess;
bool textureCompressionAvailable;
bool anisotropicFilterAvailable;
bool textureLODBiasAvailable;
bool seamlessCubeMapAvailable;
bool sRGBFramebufferAvailable;
bool vertexBufferObjectAvailable;
bool mapBufferRangeAvailable;
bool vertexArrayObjectAvailable;
bool drawElementsBaseVertexAvailable;
bool fragmentProgramAvailable;
bool glslAvailable;
bool uniformBufferAvailable;
bool twoSidedStencilAvailable;
bool depthBoundsTestAvailable;
bool syncAvailable;
bool timerQueryAvailable;
bool occlusionQueryAvailable;
bool debugOutputAvailable;
bool swapControlTearAvailable;
stereo3DMode_t stereo3Dmode;
int nativeScreenWidth; // this is the native screen width resolution of the renderer
int nativeScreenHeight; // this is the native screen height resolution of the renderer
int displayFrequency;
int isFullscreen; // monitor number
bool isStereoPixelFormat;
bool stereoPixelFormatAvailable;
int multisamples;
// Screen separation for stereoscopic rendering is set based on this.
// PC vid code sets this, converting from diagonals / inches / whatever as needed.
// If the value can't be determined, set something reasonable, like 50cm.
float physicalScreenWidthInCentimeters;
float pixelAspect;
GLuint global_vao;
};
struct emptyCommand_t;
bool R_IsInitialized();
const int SMALLCHAR_WIDTH = 8;
const int SMALLCHAR_HEIGHT = 16;
const int BIGCHAR_WIDTH = 16;
const int BIGCHAR_HEIGHT = 16;
// all drawing is done to a 640 x 480 virtual screen size
// and will be automatically scaled to the real resolution
const int SCREEN_WIDTH = 640;
const int SCREEN_HEIGHT = 480;
const int TITLESAFE_LEFT = 32;
const int TITLESAFE_RIGHT = 608;
const int TITLESAFE_TOP = 24;
const int TITLESAFE_BOTTOM = 456;
const int TITLESAFE_WIDTH = TITLESAFE_RIGHT - TITLESAFE_LEFT;
const int TITLESAFE_HEIGHT = TITLESAFE_BOTTOM - TITLESAFE_TOP;
class idRenderWorld;
class idRenderSystem
{
public:
virtual ~idRenderSystem() {}
// set up cvars and basic data structures, but don't
// init OpenGL, so it can also be used for dedicated servers
virtual void Init() = 0;
// only called before quitting
virtual void Shutdown() = 0;
virtual void ResetGuiModels() = 0;
virtual void InitOpenGL() = 0;
virtual void ShutdownOpenGL() = 0;
virtual bool IsOpenGLRunning() const = 0;
virtual bool IsFullScreen() const = 0;
virtual int GetWidth() const = 0;
virtual int GetHeight() const = 0;
// return w/h of a single pixel. This will be 1.0 for normal cases.
// A side-by-side stereo 3D frame will have a pixel aspect of 0.5.
// A top-and-bottom stereo 3D frame will have a pixel aspect of 2.0
virtual float GetPixelAspect() const = 0;
// This is used to calculate stereoscopic screen offset for a given interocular distance.
virtual float GetPhysicalScreenWidthInCentimeters() const = 0;
// GetWidth() / GetHeight() return the size of a single eye
// view, which may be replicated twice in a stereo display
virtual stereo3DMode_t GetStereo3DMode() const = 0;
virtual bool IsStereoScopicRenderingSupported() const = 0;
virtual stereo3DMode_t GetStereoScopicRenderingMode() const = 0;
virtual void EnableStereoScopicRendering( const stereo3DMode_t mode ) const = 0;
virtual bool HasQuadBufferSupport() const = 0;
// allocate a renderWorld to be used for drawing
virtual idRenderWorld* AllocRenderWorld() = 0;
virtual void FreeRenderWorld( idRenderWorld* rw ) = 0;
// All data that will be used in a level should be
// registered before rendering any frames to prevent disk hits,
// but they can still be registered at a later time
// if necessary.
virtual void BeginLevelLoad() = 0;
virtual void EndLevelLoad() = 0;
virtual void Preload( const idPreloadManifest& manifest, const char* mapName ) = 0;
virtual void LoadLevelImages() = 0;
virtual void BeginAutomaticBackgroundSwaps( autoRenderIconType_t icon = AUTORENDER_DEFAULTICON ) = 0;
virtual void EndAutomaticBackgroundSwaps() = 0;
virtual bool AreAutomaticBackgroundSwapsRunning( autoRenderIconType_t* icon = NULL ) const = 0;
// font support
virtual class idFont* RegisterFont( const char* fontName ) = 0;
virtual void ResetFonts() = 0;
virtual void SetColor( const idVec4& rgba ) = 0;
virtual void SetColor4( float r, float g, float b, float a )
{
SetColor( idVec4( r, g, b, a ) );
}
virtual uint32 GetColor() = 0;
virtual void SetGLState( const uint64 glState ) = 0;
virtual void DrawFilled( const idVec4& color, float x, float y, float w, float h ) = 0;
virtual void DrawStretchPic( float x, float y, float w, float h, float s1, float t1, float s2, float t2, const idMaterial* material ) = 0;
void DrawStretchPic( const idVec4& rect, const idVec4& st, const idMaterial* material )
{
DrawStretchPic( rect.x, rect.y, rect.z, rect.w, st.x, st.y, st.z, st.w, material );
}
virtual void DrawStretchPic( const idVec4& topLeft, const idVec4& topRight, const idVec4& bottomRight, const idVec4& bottomLeft, const idMaterial* material ) = 0;
virtual void DrawStretchTri( const idVec2& p1, const idVec2& p2, const idVec2& p3, const idVec2& t1, const idVec2& t2, const idVec2& t3, const idMaterial* material ) = 0;
virtual idDrawVert* AllocTris( int numVerts, const triIndex_t* indexes, int numIndexes, const idMaterial* material, const stereoDepthType_t stereoType = STEREO_DEPTH_TYPE_NONE ) = 0;
virtual void PrintMemInfo( MemInfo_t* mi ) = 0;
virtual void DrawSmallChar( int x, int y, int ch ) = 0;
virtual void DrawSmallStringExt( int x, int y, const char* string, const idVec4& setColor, bool forceColor ) = 0;
virtual void DrawBigChar( int x, int y, int ch ) = 0;
virtual void DrawBigStringExt( int x, int y, const char* string, const idVec4& setColor, bool forceColor ) = 0;
// dump all 2D drawing so far this frame to the demo file
virtual void WriteDemoPics() = 0;
// draw the 2D pics that were saved out with the current demo frame
virtual void DrawDemoPics() = 0;
// Performs final closeout of any gui models being defined.
//
// Waits for the previous GPU rendering to complete and vsync.
//
// Returns the head of the linked command list that was just closed off.
//
// Returns timing information from the previous frame.
//
// After this is called, new command buffers can be built up in parallel
// with the rendering of the closed off command buffers by RenderCommandBuffers()
virtual const emptyCommand_t* SwapCommandBuffers( uint64* frontEndMicroSec, uint64* backEndMicroSec, uint64* shadowMicroSec, uint64* gpuMicroSec ) = 0;
// SwapCommandBuffers operation can be split in two parts for non-smp rendering
// where the GPU is idled intentionally for minimal latency.
virtual void SwapCommandBuffers_FinishRendering( uint64* frontEndMicroSec, uint64* backEndMicroSec, uint64* shadowMicroSec, uint64* gpuMicroSec ) = 0;
virtual const emptyCommand_t* SwapCommandBuffers_FinishCommandBuffers() = 0;
// issues GPU commands to render a built up list of command buffers returned
// by SwapCommandBuffers(). No references should be made to the current frameData,
// so new scenes and GUIs can be built up in parallel with the rendering.
virtual void RenderCommandBuffers( const emptyCommand_t* commandBuffers ) = 0;
// aviDemo uses this.
// Will automatically tile render large screen shots if necessary
// Samples is the number of jittered frames for anti-aliasing
// If ref == NULL, common->UpdateScreen will be used
// This will perform swapbuffers, so it is NOT an approppriate way to
// generate image files that happen during gameplay, as for savegame
// markers. Use WriteRender() instead.
virtual void TakeScreenshot( int width, int height, const char* fileName, int samples, struct renderView_s* ref ) = 0;
// the render output can be cropped down to a subset of the real screen, as
// for save-game reviews and split-screen multiplayer. Users of the renderer
// will not know the actual pixel size of the area they are rendering to
// the x,y,width,height values are in virtual SCREEN_WIDTH / SCREEN_HEIGHT coordinates
// to render to a texture, first set the crop size with makePowerOfTwo = true,
// then perform all desired rendering, then capture to an image
// if the specified physical dimensions are larger than the current cropped region, they will be cut down to fit
virtual void CropRenderSize( int width, int height ) = 0;
virtual void CaptureRenderToImage( const char* imageName, bool clearColorAfterCopy = false ) = 0;
// fixAlpha will set all the alpha channel values to 0xff, which allows screen captures
// to use the default tga loading code without having dimmed down areas in many places
virtual void CaptureRenderToFile( const char* fileName, bool fixAlpha = false ) = 0;
virtual void UnCrop() = 0;
// the image has to be already loaded ( most straightforward way would be through a FindMaterial )
// texture filter / mipmapping / repeat won't be modified by the upload
// returns false if the image wasn't found
virtual bool UploadImage( const char* imageName, const byte* data, int width, int height ) = 0;
// consoles switch stereo 3D eye views each 60 hz frame
virtual int GetFrameCount() const = 0;
};
extern idRenderSystem* renderSystem;
//
// functions mainly intended for editor and dmap integration
//
// for use by dmap to do the carving-on-light-boundaries and for the editor for display
void R_LightProjectionMatrix( const idVec3& origin, const idPlane& rearPlane, idVec4 mat[4] );
// used by the view shot taker
void R_ScreenshotFilename( int& lastNumber, const char* base, idStr& fileName );
#endif /* !__RENDERER_H__ */