/* * Mesa 3-D graphics library * Version: 3.3 * * Copyright (C) 1999 Brian Paul All Rights Reserved. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * BRIAN PAUL BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN * AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN * CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #ifndef DD_INCLUDED #define DD_INCLUDED #include "macros.h" struct gl_pixelstore_attrib; struct vertex_buffer; struct immediate; struct gl_pipeline_stage; /* THIS FILE ONLY INCLUDED BY types.h !!!!! */ /* * Device Driver (DD) interface * * * All device driver functions are accessed through pointers in the * dd_function_table struct (defined below) which is stored in the GLcontext * struct. Since the device driver is strictly accessed trough a table of * function pointers we can: * 1. switch between a number of different device drivers at runtime. * 2. use optimized functions dependant on current rendering state or * frame buffer configuration. * * The function pointers in the dd_function_table struct are divided into * two groups: mandatory and optional. * Mandatory functions have to be implemented by every device driver. * Optional functions may or may not be implemented by the device driver. * The optional functions provide ways to take advantage of special hardware * or optimized algorithms. * * The function pointers in the dd_function_table struct should first be * initialized in the driver's "MakeCurrent" function. The "MakeCurrent" * function is a little different in each device driver. See the X/Mesa, * GLX, or OS/Mesa drivers for examples. * * Later, Mesa may call the dd_function_table's UpdateState() function. * This function should initialize the dd_function_table's pointers again. * The UpdateState() function is called whenever the core (GL) rendering * state is changed in a way which may effect rasterization. For example, * the TriangleFunc() pointer may have to point to different functions * depending on whether smooth or flat shading is enabled. * * Note that the first argument to every device driver function is a * GLcontext *. In turn, the GLcontext->DriverCtx pointer points to * the driver-specific context struct. See the X/Mesa or OS/Mesa interface * for an example. * * For more information about writing a device driver see the ddsample.c * file and other device drivers (X/xmesa[1234].c, OSMesa/osmesa.c, etc) * for examples. * * * Look below in the dd_function_table struct definition for descriptions * of each device driver function. * * * In the future more function pointers may be added for glReadPixels * glCopyPixels, etc. * * * Notes: * ------ * RGBA = red/green/blue/alpha * CI = color index (color mapped mode) * mono = all pixels have the same color or index * * The write_ functions all take an array of mask flags which indicate * whether or not the pixel should be written. One special case exists * in the write_color_span function: if the mask array is NULL, then * draw all pixels. This is an optimization used for glDrawPixels(). * * IN ALL CASES: * X coordinates start at 0 at the left and increase to the right * Y coordinates start at 0 at the bottom and increase upward * */ /* Used by the GetParameteri device driver function */ #define DD_HAVE_HARDWARE_FOG 3 /* Mask bits sent to the driver Clear() function */ #define DD_FRONT_LEFT_BIT FRONT_LEFT_BIT /* 1 */ #define DD_FRONT_RIGHT_BIT FRONT_RIGHT_BIT /* 2 */ #define DD_BACK_LEFT_BIT BACK_LEFT_BIT /* 4 */ #define DD_BACK_RIGHT_BIT BACK_RIGHT_BIT /* 8 */ #define DD_DEPTH_BIT GL_DEPTH_BUFFER_BIT /* 0x00000100 */ #define DD_STENCIL_BIT GL_STENCIL_BUFFER_BIT /* 0x00000400 */ #define DD_ACCUM_BIT GL_ACCUM_BUFFER_BIT /* 0x00000200 */ /* * Device Driver function table. */ struct dd_function_table { /********************************************************************** *** Mandatory functions: these functions must be implemented by *** *** every device driver. *** **********************************************************************/ const char * (*RendererString)(void); /* * Return a string which uniquely identifies this device driver. * The string should contain no whitespace. Examples: "X11", "OffScreen", * "MSWindows", "SVGA". * NOTE: This function will be obsolete in favor of GetString in the future! */ void (*UpdateState)( GLcontext *ctx ); /* * UpdateState() is called whenver Mesa thinks the device driver should * update its state and/or the other pointers (such as PointsFunc, * LineFunc, or TriangleFunc). */ void (*ClearIndex)( GLcontext *ctx, GLuint index ); /* * Called whenever glClearIndex() is called. Set the index for clearing * the color buffer when in color index mode. */ void (*ClearColor)( GLcontext *ctx, GLubyte red, GLubyte green, GLubyte blue, GLubyte alpha ); /* * Called whenever glClearColor() is called. Set the color for clearing * the color buffer when in RGBA mode. */ GLbitfield (*Clear)( GLcontext *ctx, GLbitfield mask, GLboolean all, GLint x, GLint y, GLint width, GLint height ); /* Clear the color/depth/stencil/accum buffer(s). * 'mask' is a bitmask of the DD_*_BIT values defined above that indicates * which buffers need to be cleared. The driver should clear those * buffers then return a new bitmask indicating which buffers should be * cleared by software Mesa. * If 'all' is true then the clear the whole buffer, else clear only the * region defined by (x,y,width,height). * This function must obey the glColorMask, glIndexMask and glStencilMask * settings! Software Mesa can do masked clears if the device driver can't. */ void (*Index)( GLcontext *ctx, GLuint index ); /* * Sets current color index for drawing flat-shaded primitives. * This index should also be used in the "mono" drawing functions. */ void (*Color)( GLcontext *ctx, GLubyte red, GLubyte green, GLubyte glue, GLubyte alpha ); /* * Sets current color for drawing flat-shaded primitives. * This color should also be used in the "mono" drawing functions. */ GLboolean (*SetDrawBuffer)( GLcontext *ctx, GLenum buffer ); /* * Specifies the current buffer for writing. * The following values must be accepted when applicable: * GL_FRONT_LEFT - this buffer always exists * GL_BACK_LEFT - when double buffering * GL_FRONT_RIGHT - when using stereo * GL_BACK_RIGHT - when using stereo and double buffering * The folowing values may optionally be accepted. Return GL_TRUE * if accepted, GL_FALSE if not accepted. In practice, only drivers * which can write to multiple color buffers at once should accept * these values. * GL_FRONT - write to front left and front right if it exists * GL_BACK - write to back left and back right if it exists * GL_LEFT - write to front left and back left if it exists * GL_RIGHT - write to right left and back right if they exist * GL_FRONT_AND_BACK - write to all four buffers if they exist * GL_NONE - disable buffer write in device driver. */ void (*SetReadBuffer)( GLcontext *ctx, GLframebuffer *colorBuffer, GLenum buffer ); /* * Specifies the current buffer for reading. * colorBuffer will be one of: * GL_FRONT_LEFT - this buffer always exists * GL_BACK_LEFT - when double buffering * GL_FRONT_RIGHT - when using stereo * GL_BACK_RIGHT - when using stereo and double buffering */ void (*GetBufferSize)( GLcontext *ctx, GLuint *width, GLuint *height ); /* * Returns the width and height of the current color buffer. */ /*** *** Functions for writing pixels to the frame buffer: ***/ void (*WriteRGBASpan)( const GLcontext *ctx, GLuint n, GLint x, GLint y, CONST GLubyte rgba[][4], const GLubyte mask[] ); void (*WriteRGBSpan)( const GLcontext *ctx, GLuint n, GLint x, GLint y, CONST GLubyte rgb[][3], const GLubyte mask[] ); /* Write a horizontal run of RGBA or RGB pixels. * If mask is NULL, draw all pixels. * If mask is not null, only draw pixel [i] when mask [i] is true. */ void (*WriteMonoRGBASpan)( const GLcontext *ctx, GLuint n, GLint x, GLint y, const GLubyte mask[] ); /* Write a horizontal run of RGBA pixels all with the color last * specified by the Color function. */ void (*WriteRGBAPixels)( const GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], CONST GLubyte rgba[][4], const GLubyte mask[] ); /* Write array of RGBA pixels at random locations. */ void (*WriteMonoRGBAPixels)( const GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], const GLubyte mask[] ); /* Write an array of mono-RGBA pixels at random locations. */ void (*WriteCI32Span)( const GLcontext *ctx, GLuint n, GLint x, GLint y, const GLuint index[], const GLubyte mask[] ); void (*WriteCI8Span)( const GLcontext *ctx, GLuint n, GLint x, GLint y, const GLubyte index[], const GLubyte mask[] ); /* Write a horizontal run of CI pixels. One function is for 32bpp * indexes and the other for 8bpp pixels (the common case). You mus * implement both for color index mode. */ void (*WriteMonoCISpan)( const GLcontext *ctx, GLuint n, GLint x, GLint y, const GLubyte mask[] ); /* Write a horizontal run of color index pixels using the color index * last specified by the Index() function. */ void (*WriteCI32Pixels)( const GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], const GLuint index[], const GLubyte mask[] ); /* * Write a random array of CI pixels. */ void (*WriteMonoCIPixels)( const GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], const GLubyte mask[] ); /* Write a random array of color index pixels using the color index * last specified by the Index() function. */ /*** *** Functions to read pixels from frame buffer: ***/ void (*ReadCI32Span)( const GLcontext *ctx, GLuint n, GLint x, GLint y, GLuint index[] ); /* Read a horizontal run of color index pixels. */ void (*ReadRGBASpan)( const GLcontext *ctx, GLuint n, GLint x, GLint y, GLubyte rgba[][4] ); /* Read a horizontal run of RGBA pixels. */ void (*ReadCI32Pixels)( const GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], GLuint indx[], const GLubyte mask[] ); /* Read a random array of CI pixels. */ void (*ReadRGBAPixels)( const GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], GLubyte rgba[][4], const GLubyte mask[] ); /* Read a random array of RGBA pixels. */ /********************************************************************** *** Optional functions: these functions may or may not be *** *** implemented by the device driver. If the device driver *** *** doesn't implement them it should never touch these pointers *** *** since Mesa will either set them to NULL or point them at a *** *** fall-back function. *** **********************************************************************/ const char * (*ExtensionString)( GLcontext *ctx ); /* Return a space-separated list of extensions for this driver. * NOTE: This function will be obsolete in favor of GetString in the future! */ const GLubyte * (*GetString)( GLcontext *ctx, GLenum name ); /* Return a string as needed by glGetString(). * NOTE: This will replace the ExtensionString and RendererString * functions in the future! */ void (*Finish)( GLcontext *ctx ); /* * This is called whenever glFinish() is called. */ void (*Flush)( GLcontext *ctx ); /* * This is called whenever glFlush() is called. */ GLboolean (*IndexMask)( GLcontext *ctx, GLuint mask ); /* * Implements glIndexMask() if possible, else return GL_FALSE. */ GLboolean (*ColorMask)( GLcontext *ctx, GLboolean rmask, GLboolean gmask, GLboolean bmask, GLboolean amask ); /* * Implements glColorMask() if possible, else return GL_FALSE. */ GLboolean (*LogicOp)( GLcontext *ctx, GLenum op ); /* * Implements glLogicOp() if possible, else return GL_FALSE. */ void (*Dither)( GLcontext *ctx, GLboolean enable ); /* * Enable/disable dithering. * NOTE: This function will be removed in the future in favor * of the "Enable" driver function. */ void (*Error)( GLcontext *ctx ); /* * Called whenever an error is generated. ctx->ErrorValue contains * the error value. */ void (*NearFar)( GLcontext *ctx, GLfloat nearVal, GLfloat farVal ); /* * Called from glFrustum and glOrtho to tell device driver the * near and far clipping plane Z values. The 3Dfx driver, for example, * uses this. */ GLint (*GetParameteri)( const GLcontext *ctx, GLint param ); /* Query the device driver to get an integer parameter. * Current parameters: * DD_MAX_TEXTURE_SIZE return maximum texture size * * DD_MAX_TEXTURES number of texture sets/stages, usually 1 * * DD_HAVE_HARDWARE_FOG the driver should return 1 (0 otherwise) * when the hardware support per fragment * fog for free (like the Voodoo Graphics) * so the Mesa core will start to ever use * per fragment fog */ /*** *** For supporting hardware Z buffers: *** Either ALL or NONE of these functions must be implemented! ***/ void (*WriteDepthSpan)( GLcontext *ctx, GLuint n, GLint x, GLint y, const GLdepth depth[], const GLubyte mask[] ); /* Write a horizontal span of values into the depth buffer. Only write * depth[i] value if mask[i] is nonzero. */ void (*ReadDepthSpan)( GLcontext *ctx, GLuint n, GLint x, GLint y, GLdepth depth[] ); /* Read a horizontal span of values from the depth buffer. */ void (*WriteDepthPixels)( GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], const GLdepth depth[], const GLubyte mask[] ); /* Write an array of randomly positioned depth values into the * depth buffer. Only write depth[i] value if mask[i] is nonzero. */ void (*ReadDepthPixels)( GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], GLdepth depth[] ); /* Read an array of randomly positioned depth values from the depth buffer. */ /*** *** For supporting hardware stencil buffers: *** Either ALL or NONE of these functions must be implemented! ***/ void (*WriteStencilSpan)( GLcontext *ctx, GLuint n, GLint x, GLint y, const GLstencil stencil[], const GLubyte mask[] ); /* Write a horizontal span of stencil values into the stencil buffer. * If mask is NULL, write all stencil values. * Else, only write stencil[i] if mask[i] is non-zero. */ void (*ReadStencilSpan)( GLcontext *ctx, GLuint n, GLint x, GLint y, GLstencil stencil[] ); /* Read a horizontal span of stencil values from the stencil buffer. */ void (*WriteStencilPixels)( GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], const GLstencil stencil[], const GLubyte mask[] ); /* Write an array of stencil values into the stencil buffer. * If mask is NULL, write all stencil values. * Else, only write stencil[i] if mask[i] is non-zero. */ void (*ReadStencilPixels)( GLcontext *ctx, GLuint n, const GLint x[], const GLint y[], GLstencil stencil[] ); /* Read an array of stencil values from the stencil buffer. */ /*** *** Accelerated point, line, polygon, glDrawPixels and glBitmap functions: ***/ points_func PointsFunc; line_func LineFunc; triangle_func TriangleFunc; quad_func QuadFunc; rect_func RectFunc; GLboolean (*DrawPixels)( GLcontext *ctx, GLint x, GLint y, GLsizei width, GLsizei height, GLenum format, GLenum type, const struct gl_pixelstore_attrib *unpack, const GLvoid *pixels ); /* This is called by glDrawPixels. * 'unpack' describes how to unpack the source image data. * Return GL_TRUE if the driver succeeds, return GL_FALSE if core Mesa * must do the job. */ GLboolean (*Bitmap)( GLcontext *ctx, GLint x, GLint y, GLsizei width, GLsizei height, const struct gl_pixelstore_attrib *unpack, const GLubyte *bitmap ); /* This is called by glBitmap. Works the same as DrawPixels, above. */ void (*RenderStart)( GLcontext *ctx ); void (*RenderFinish)( GLcontext *ctx ); /* KW: These replace Begin and End, and have more relaxed semantics. * They are called prior-to and after one or more vb flush, and are * thus decoupled from the gl_begin/gl_end pairs, which are possibly * more frequent. If a begin/end pair covers >1 vertex buffer, these * are called at most once for the pair. (a bit broken at present) */ void (*RasterSetup)( struct vertex_buffer *VB, GLuint start, GLuint end ); /* This function, if not NULL, is called whenever new window coordinates * are put in the vertex buffer. The vertices in question are those n * such that start <= n < end. * The device driver can convert the window coords to its own specialized * format. The 3Dfx driver uses this. * * Note: Deprecated in favour of RegisterPipelineStages, below. */ render_func *RenderVBClippedTab; render_func *RenderVBCulledTab; render_func *RenderVBRawTab; /* These function tables allow the device driver to rasterize an * entire begin/end group of primitives at once. See the * gl_render_vb() function in vbrender.c for more details. */ void (*ReducedPrimitiveChange)( GLcontext *ctx, GLenum primitive ); /* If registered, this will be called when rendering transitions between * points, lines and triangles. It is not called on transitions between * primtives such as GL_TRIANGLES and GL_TRIANGLE_STRIPS, or between * triangles and quads or triangles and polygons. */ GLuint TriangleCaps; /* Holds a list of the reasons why we might normally want to call * render_triangle, but which are in fact implemented by the * driver. The FX driver sets this to DD_TRI_CULL, and will soon * implement DD_TRI_OFFSET. */ GLboolean (*MultipassFunc)( struct vertex_buffer *VB, GLuint passno ); /* Driver may request additional render passes by returning GL_TRUE * when this function is called. This function will be called * after the first pass, and passes will be made until the function * returns GL_FALSE. If no function is registered, only one pass * is made. * * This function will be first invoked with passno == 1. */ /*** *** Texture mapping functions: ***/ void (*TexEnv)( GLcontext *ctx, GLenum pname, const GLfloat *param ); /* * Called whenever glTexEnv*() is called. * Pname will be one of GL_TEXTURE_ENV_MODE or GL_TEXTURE_ENV_COLOR. * If pname is GL_TEXTURE_ENV_MODE then param will be one * of GL_MODULATE, GL_BLEND, GL_DECAL, or GL_REPLACE. */ void (*TexImage)( GLcontext *ctx, GLenum target, struct gl_texture_object *tObj, GLint level, GLint internalFormat, const struct gl_texture_image *image ); /* * Called whenever a texture object's image is changed. * texObject is the number of the texture object being changed. * level indicates the mipmap level. * internalFormat is the format in which the texture is to be stored. * image is a pointer to a gl_texture_image struct which contains * the actual image data. */ void (*TexSubImage)( GLcontext *ctx, GLenum target, struct gl_texture_object *tObj, GLint level, GLint xoffset, GLint yoffset, GLsizei width, GLsizei height, GLint internalFormat, const struct gl_texture_image *image ); /* * Called from glTexSubImage() to define a sub-region of a texture. */ void (*TexParameter)( GLcontext *ctx, GLenum target, struct gl_texture_object *tObj, GLenum pname, const GLfloat *params ); /* * Called whenever glTexParameter*() is called. * target is GL_TEXTURE_1D or GL_TEXTURE_2D * texObject is the texture object to modify * pname is one of GL_TEXTURE_MIN_FILTER, GL_TEXTURE_MAG_FILTER, * GL_TEXTURE_WRAP_S, GL_TEXTURE_WRAP_T, or GL_TEXTURE_BORDER_COLOR. * params is dependant on pname. See man glTexParameter. */ void (*BindTexture)( GLcontext *ctx, GLenum target, struct gl_texture_object *tObj ); /* * Called whenever glBindTexture() is called. This specifies which * texture is to be the current one. No dirty flags will be set. */ void (*DeleteTexture)( GLcontext *ctx, struct gl_texture_object *tObj ); /* * Called when a texture object is about to be deallocated. Driver * should free anything attached to the DriverData pointers. */ void (*UpdateTexturePalette)( GLcontext *ctx, struct gl_texture_object *tObj ); /* * Called when the texture's color lookup table is changed. * If tObj is NULL then the shared texture palette ctx->Texture.Palette * was changed. */ void (*UseGlobalTexturePalette)( GLcontext *ctx, GLboolean state ); /* * Called via glEnable/Disable(GL_SHARED_TEXTURE_PALETTE_EXT) */ void (*ActiveTexture)( GLcontext *ctx, GLuint texUnitNumber ); /* * Called by glActiveTextureARB to set current texture unit. */ GLboolean (*IsTextureResident)( GLcontext *ctx, struct gl_texture_object *t ); /* * Allows the driver to implement the AreTexturesResident tests without * knowing about Mesa's internal hash tables for textures. */ void (*PrioritizeTexture)( GLcontext *ctx, struct gl_texture_object *t, GLclampf priority ); /* * Notify driver of priority change for a texture. */ /*** *** NEW in Mesa 3.x ***/ void (*RegisterVB)( struct vertex_buffer *VB ); void (*UnregisterVB)( struct vertex_buffer *VB ); /* Do any processing (eg allocate memory) required to set up a new * vertex_buffer. */ void (*ResetVB)( struct vertex_buffer *VB ); void (*ResetCvaVB)( struct vertex_buffer *VB, GLuint stages ); /* Do any reset operations necessary to the driver data associated * with these vertex buffers. */ GLuint RenderVectorFlags; /* What do the render tables require of the vectors they deal * with? */ GLuint (*RegisterPipelineStages)( struct gl_pipeline_stage *out, const struct gl_pipeline_stage *in, GLuint nr ); /* Register new pipeline stages, or modify existing ones. See also * the OptimizePipeline() functions. */ GLboolean (*BuildPrecalcPipeline)( GLcontext *ctx ); GLboolean (*BuildEltPipeline)( GLcontext *ctx ); /* Perform the full pipeline build, or return false. */ void (*OptimizePrecalcPipeline)( GLcontext *ctx, struct gl_pipeline *pipe ); void (*OptimizeImmediatePipeline)( GLcontext *ctx, struct gl_pipeline *pipe); /* Check to see if a fast path exists for this combination of stages * in the precalc and immediate (elt) pipelines. */ /* * State-changing functions (drawing functions are above) * * These functions are called by their corresponding OpenGL API functions. * They're ALSO called by the gl_PopAttrib() function!!! * May add more functions like these to the device driver in the future. * This should reduce the amount of state checking that * the driver's UpdateState() function must do. */ void (*AlphaFunc)(GLcontext *ctx, GLenum func, GLclampf ref); void (*BlendEquation)(GLcontext *ctx, GLenum mode); void (*BlendFunc)(GLcontext *ctx, GLenum sfactor, GLenum dfactor); void (*BlendFuncSeparate)( GLcontext *ctx, GLenum sfactorRGB, GLenum dfactorRGB, GLenum sfactorA, GLenum dfactorA ); void (*ClearDepth)(GLcontext *ctx, GLclampd d); void (*CullFace)(GLcontext *ctx, GLenum mode); void (*FrontFace)(GLcontext *ctx, GLenum mode); void (*DepthFunc)(GLcontext *ctx, GLenum func); void (*DepthMask)(GLcontext *ctx, GLboolean flag); void (*DepthRange)(GLcontext *ctx, GLclampd nearval, GLclampd farval); void (*Enable)(GLcontext* ctx, GLenum cap, GLboolean state); void (*Fogfv)(GLcontext *ctx, GLenum pname, const GLfloat *params); void (*Hint)(GLcontext *ctx, GLenum target, GLenum mode); void (*Lightfv)(GLcontext *ctx, GLenum light, GLenum pname, const GLfloat *params, GLint nparams ); void (*LightModelfv)(GLcontext *ctx, GLenum pname, const GLfloat *params); void (*PolygonMode)(GLcontext *ctx, GLenum face, GLenum mode); void (*Scissor)(GLcontext *ctx, GLint x, GLint y, GLsizei w, GLsizei h); void (*ShadeModel)(GLcontext *ctx, GLenum mode); void (*ClearStencil)(GLcontext *ctx, GLint s); void (*StencilFunc)(GLcontext *ctx, GLenum func, GLint ref, GLuint mask); void (*StencilMask)(GLcontext *ctx, GLuint mask); void (*StencilOp)(GLcontext *ctx, GLenum fail, GLenum zfail, GLenum zpass); void (*Viewport)(GLcontext *ctx, GLint x, GLint y, GLsizei w, GLsizei h); }; #endif