Source code of Windows XP (NT5)
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#ifndef __glbuffers_h_
#define __glbuffers_h_
/*
** Copyright 1991, Silicon Graphics, Inc.
** All Rights Reserved.
**
** This is UNPUBLISHED PROPRIETARY SOURCE CODE of Silicon Graphics, Inc.;
** the contents of this file may not be disclosed to third parties, copied or
** duplicated in any form, in whole or in part, without the prior written
** permission of Silicon Graphics, Inc.
**
** RESTRICTED RIGHTS LEGEND:
** Use, duplication or disclosure by the Government is subject to restrictions
** as set forth in subdivision (c)(1)(ii) of the Rights in Technical Data
** and Computer Software clause at DFARS 252.227-7013, and/or in similar or
** successor clauses in the FAR, DOD or NASA FAR Supplement. Unpublished -
** rights reserved under the Copyright Laws of the United States.
*/
#include "render.h"
#include "parray.h"
#include "procs.h"
typedef struct __GLbufferMachineRec {
/*
** GL_TRUE if store procs need to call gc->front->store and
** gc->back->store in order to store one fragment (only TRUE if
** drawBuffer is GL_FRONT_AND_BACK). This is needed because many
** frame buffers can draw to both front and back under some conditions
** (like when not blending), but not under other conditions.
*/
GLboolean doubleStore;
} __GLbufferMachine;
/************************************************************************/
/*
** Generic buffer description. This description is used for software
** and hardware buffers of all kinds.
*/
struct __GLbufferRec {
/*
** Which context is using this buffer.
*/
__GLcontext *gc;
/*
** Dimensions of the buffer.
*/
GLint width, height, depth;
/*
** Base of framebuffer.
*/
void* base;
/*
** Number of bytes consumed by the framebuffer.
*/
GLuint size;
/*
** Size of each element in the framebuffer.
*/
GLuint elementSize;
/*
** If this buffer is part of a larger (say full screen) buffer
** then this is the size of that larger buffer. Otherwise it is
** just a copy of width.
*/
GLint outerWidth;
/*
** If this buffer is part of a larger (say full screen) buffer
** then these are the location of this buffer in the larger
** buffer.
*/
GLint xOrigin, yOrigin;
/*
** Flags.
*/
GLuint flags;
};
/*
** Generic address macro for a buffer. Coded to assume that
** the buffer is not part of a larger buffer.
** The input coordinates x,y are biased by the x & y viewport
** adjusts in gc->transform, and thus they need to be de-adjusted
** here.
*/
#define __GL_FB_ADDRESS(fb,cast,x,y) \
((cast (fb)->buf.base) \
+ ((y) - (fb)->buf.gc->constants.viewportYAdjust) \
* (fb)->buf.outerWidth \
+ (x) - (fb)->buf.gc->constants.viewportXAdjust)
extern void __glResizeBuffer(__GLGENbuffers *buffers, __GLbuffer *buf,
GLint w, GLint h);
extern void FASTCALL __glInitGenericCB(__GLcontext *gc, __GLcolorBuffer *cfb);
/************************************************************************/
struct __GLalphaBufferRec {
__GLbuffer buf;
__GLfloat alphaScale;
void (FASTCALL *store)
(__GLalphaBuffer *afb, GLint x, GLint y, const __GLcolor *color);
void (FASTCALL *storeSpan) (__GLalphaBuffer *afb);
void (FASTCALL *storeSpan2)
(__GLalphaBuffer *afb, GLint x, GLint y, GLint w, __GLcolor *colors );
void (FASTCALL *fetch)
(__GLalphaBuffer *afb, GLint x, GLint y, __GLcolor *result);
void (FASTCALL *readSpan)
(__GLalphaBuffer *afb, GLint x, GLint y, GLint w, __GLcolor *results);
void (FASTCALL *clear)(__GLalphaBuffer *afb);
};
/************************************************************************/
struct __GLcolorBufferRec {
__GLbuffer buf;
__GLalphaBuffer alphaBuf;
GLint redMax;
GLint greenMax;
GLint blueMax;
GLint alphaMax; // XXX not used, just here for consistency with rgb
/*
** Color component scale factors. Given a component value between
** zero and one, this scales the component into a zero-N value
** which is suitable for usage in the color buffer. Note that these
** values are not necessarily the same as the max values above,
** which define precise bit ranges for the buffer. These values
** are never zero, for instance.
**/
__GLfloat redScale;
__GLfloat greenScale;
__GLfloat blueScale;
/* Integer versions of above */
GLint iRedScale;
GLint iGreenScale;
GLint iBlueScale;
/* Used primarily by pixmap code */
GLint redShift;
GLint greenShift;
GLint blueShift;
GLint alphaShift;
#ifdef NT
GLuint allShifts;
#endif
/*
** Alpha is treated a little bit differently. alphaScale and
** iAlphaScale are used to define a range of alpha values that are
** generated during various rendering steps. These values will then
** be used as indices into a lookup table to see if the alpha test
** passes or not. Because of this, the number should be fairly large
** (e.g., one is not good enough).
*/
__GLfloat alphaScale;
GLint iAlphaScale;
__GLfloat oneOverRedScale;
__GLfloat oneOverGreenScale;
__GLfloat oneOverBlueScale;
__GLfloat oneOverAlphaScale;
/*
** Color mask state for the buffer. When writemasking is enabled
** the source and dest mask will contain depth depedent masking.
*/
GLuint sourceMask, destMask;
/*
** This function updates the internal procedure pointers based
** on a state change in the context.
*/
void (FASTCALL *pick)(__GLcontext *gc, __GLcolorBuffer *cfb);
/*
** When the buffer needs resizing this procedure should be called.
*/
void (*resize)(__GLGENbuffers *buffers, __GLcolorBuffer *cfb,
GLint w, GLint h);
/*
** Store a fragment into the buffer. For color buffers, the
** procedure will optionally dither, writemask, blend and logic op
** the fragment before final storage.
*/
void (FASTCALL *store)(__GLcolorBuffer *cfb, const __GLfragment *frag);
/*
** Fetch a color from the buffer. This returns the r, g, b and a
** values for an RGB buffer. For an index buffer the "r" value
** returned is the index.
*/
void (*fetch)(__GLcolorBuffer *cfb, GLint x, GLint y,
__GLcolor *result);
/*
** Similar to fetch, except that the data is always read from
** the current read buffer, not from the current draw buffer.
*/
void (*readColor)(__GLcolorBuffer *cfb, GLint x, GLint y,
__GLcolor *result);
void (*readSpan)(__GLcolorBuffer *cfb, GLint x, GLint y,
__GLcolor *results, GLint w);
/*
** Return a span of data from the accumulation buffer into the
** color buffer(s), multiplying by "scale" before storage.
*/
void (*returnSpan)(__GLcolorBuffer *cfb, GLint x, GLint y,
const __GLaccumCell *acbuf, __GLfloat scale, GLint w);
/*
** Store a span (line) of colors into the color buffer. A minimal
** implementation need only copy the values directly into
** the framebuffer, assuming that the PickSpanProcs is providing
** software implementations of all of the modes.
*/
__GLspanFunc storeSpan;
__GLstippledSpanFunc storeStippledSpan;
__GLspanFunc storeLine;
__GLstippledSpanFunc storeStippledLine;
/*
** Read a span (line) of colors from the color buffer. The returned
** format is in the same format used for storage.
*/
__GLspanFunc fetchSpan;
__GLstippledSpanFunc fetchStippledSpan;
__GLspanFunc fetchLine;
__GLstippledSpanFunc fetchStippledLine;
/*
** Clear the scissor area of the color buffer, clipped to
** the window size. Apply dithering if enabled.
*/
void (FASTCALL *clear)(__GLcolorBuffer *cfb);
/*
** Pointer to bitmap information.
*/
struct __GLGENbitmapRec *bitmap;
};
/* generic span read routine */
extern GLboolean __glReadSpan(__GLcolorBuffer *cfb, GLint x, GLint y,
__GLcolor *results, GLint w);
/* generic accum return span routine */
extern void __glReturnSpan(__GLcolorBuffer *cfb, GLint x, GLint y,
const __GLaccumCell *ac, __GLfloat scale,
GLint w);
/* generic span fetch routine */
extern GLboolean FASTCALL __glFetchSpan(__GLcontext *gc);
/************************************************************************/
struct __GLdepthBufferRec {
__GLbuffer buf;
GLuint writeMask;
/*
** Scale factor used to convert users ZValues (0.0 to 1.0, inclusive)
** into this depth buffers range.
*/
GLuint scale;
/*
** This function updates the internal procedure pointers based
** on a state change in the context.
*/
void (FASTCALL *pick)(__GLcontext *gc, __GLdepthBuffer *dfb, GLint depthIndex );
/*
** Attempt to update the depth buffer using z. If the depth function
** passes then the depth buffer is updated and True is returned,
** otherwise False is returned. The caller is responsible for
** updating the stencil buffer.
*/
GLboolean (*store)(__GLdepthBuffer *dfb, GLint x, GLint y, __GLzValue z);
/*
** Clear the scissor area of the buffer clipped to the window
** area. No other modes apply.
*/
void (FASTCALL *clear)(__GLdepthBuffer *dfb);
/*
** Direct access routines used by ReadPixels(), WritePixels(),
** CopyPixels().
*/
GLboolean (*store2)(__GLdepthBuffer *dfb, GLint x, GLint y, __GLzValue z);
__GLzValue (FASTCALL *fetch)(__GLdepthBuffer *dfb, GLint x, GLint y);
/*
** When using MCD, depth values are passed to the MCD driver via a
** 32-bit depth scanline buffer. The normal store proc, for 16-bit
** MCD depth buffers, will translate an incoming 16-bit depth value
** into a 32-bit value before copying it into the scanline buffer.
**
** However, some code paths (such as the generic MCD line code)
** already do all computations in 32-bit no matter what the MCD
** depth buffer size. These code paths need a proc to write their
** values untranslated.
**
** The storeRaw proc will store the incoming z value without any
** translation.
*/
GLboolean (*storeRaw)(__GLdepthBuffer *dfb, GLint x, GLint y, __GLzValue z);
};
#define __GL_DEPTH_ADDR(a,b,c,d) __GL_FB_ADDRESS(a,b,c,d)
/************************************************************************/
struct __GLstencilBufferRec {
__GLbuffer buf;
/*
** Stencil test lookup table. The stencil buffer value is masked
** against the stencil mask and then used as an index into this
** table which contains either GL_TRUE or GL_FALSE for the
** index.
*/
GLboolean *testFuncTable;
/*
** Stencil op tables. These tables contain the new stencil buffer
** value given the old stencil buffer value as an index.
*/
__GLstencilCell *failOpTable;
__GLstencilCell *depthFailOpTable;
__GLstencilCell *depthPassOpTable;
/*
** This function updates the internal procedure pointers based
** on a state change in the context.
*/
void (FASTCALL *pick)(__GLcontext *gc, __GLstencilBuffer *sfb);
/*
** Store a fragment into the buffer.
*/
void (*store)(__GLstencilBuffer *sfb, GLint x, GLint y,
GLint value);
/*
** Fetch a value.
*/
GLint (FASTCALL *fetch)(__GLstencilBuffer *sfb, GLint x, GLint y);
/*
** Return GL_TRUE if the stencil test passes.
*/
GLboolean (FASTCALL *testFunc)(__GLstencilBuffer *sfb, GLint x, GLint y);
/*
** Apply the stencil ops to this position.
*/
void (FASTCALL *failOp)(__GLstencilBuffer *sfb, GLint x, GLint y);
void (FASTCALL *passDepthFailOp)(__GLstencilBuffer *sfb, GLint x, GLint y);
void (FASTCALL *depthPassOp)(__GLstencilBuffer *sfb, GLint x, GLint y);
/*
** Clear the scissor area of the buffer clipped to the window
** area. No other modes apply.
*/
void (FASTCALL *clear)(__GLstencilBuffer *sfb);
};
#define __GL_STENCIL_ADDR(a,b,c,d) __GL_FB_ADDRESS(a,b,c,d)
/************************************************************************/
struct __GLaccumBufferRec {
__GLbuffer buf;
/*
** Scaling factors to convert from color buffer values to accum
** buffer values.
*/
__GLfloat redScale;
__GLfloat greenScale;
__GLfloat blueScale;
__GLfloat alphaScale;
__GLfloat oneOverRedScale;
__GLfloat oneOverGreenScale;
__GLfloat oneOverBlueScale;
__GLfloat oneOverAlphaScale;
__GLuicolor shift, mask, sign; // Cache of commonly used values
__GLcolor *colors; // Temporary scanline buffer ptr
/*
** This function updates the internal procedure pointers based
** on a state change in the context.
*/
void (FASTCALL *pick)(__GLcontext *gc, __GLaccumBuffer *afb);
/*
** Clear a rectangular region in the buffer. The scissor area is
** cleared.
*/
void (FASTCALL *clear)(__GLaccumBuffer *afb);
/*
** Accumulate data into the accum buffer.
*/
void (*accumulate)(__GLaccumBuffer *afb, __GLfloat value);
/*
** Load data into the accum buffer.
*/
void (*load)(__GLaccumBuffer *afb, __GLfloat value);
/*
** Return data from the accum buffer to the current framebuffer.
*/
void (*ret)(__GLaccumBuffer *afb, __GLfloat value);
/*
** Multiply the accum buffer by the value.
*/
void (*mult)(__GLaccumBuffer *afb, __GLfloat value);
/*
** Add the value to the accum buffer.
*/
void (*add)(__GLaccumBuffer *afb, __GLfloat value);
};
#define __GL_ACCUM_ADDRESS(a,b,c,d) __GL_FB_ADDRESS(a,b,c,d)
/************************************************************************/
extern void FASTCALL __glInitAccum64(__GLcontext *gc, __GLaccumBuffer *afb);
extern void FASTCALL __glFreeAccum64(__GLcontext *gc, __GLaccumBuffer *afb);
extern void FASTCALL __glInitAccum32(__GLcontext *gc, __GLaccumBuffer *afb);
extern void FASTCALL __glInitCI4(__GLcontext *gc, __GLcolorBuffer *cfb);
extern void FASTCALL __glInitCI8(__GLcontext *gc, __GLcolorBuffer *cfb);
extern void FASTCALL __glInitCI16(__GLcontext *gc, __GLcolorBuffer *cfb);
extern void FASTCALL __glInitStencil8(__GLcontext *gc, __GLstencilBuffer *sfb);
extern void FASTCALL __glInitAlpha(__GLcontext *gc, __GLcolorBuffer *cfb);
extern void FASTCALL __glFreeStencil8(__GLcontext *gc, __GLstencilBuffer *sfb);
#ifdef NT
extern void FASTCALL __glInitDepth16(__GLcontext *gc, __GLdepthBuffer *dfb);
#endif
extern void FASTCALL __glInitDepth32(__GLcontext *gc, __GLdepthBuffer *dfb);
extern void FASTCALL __glFreeDepth32(__GLcontext *gc, __GLdepthBuffer *dfb);
extern void FASTCALL __glClearBuffers(__GLcontext *gc, GLuint mask);
#endif /* __glbuffers_h_ */