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|
/* -*- mode: c; c-basic-offset: 3 -*-
*
* Copyright 2000 VA Linux Systems Inc., Fremont, California.
*
* 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 (including the next
* paragraph) 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
* VA LINUX SYSTEMS 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.
*/
/* $XFree86: xc/lib/GL/mesa/src/drv/tdfx/tdfx_span.c,v 1.7 2002/10/30 12:52:00 alanh Exp $ */
/*
* Original rewrite:
* Gareth Hughes <gareth@valinux.com>, 29 Sep - 1 Oct 2000
*
* Authors:
* Gareth Hughes <gareth@valinux.com>
* Brian Paul <brianp@valinux.com>
* Keith Whitwell <keith@tungstengraphics.com>
*
*/
#include "tdfx_context.h"
#include "tdfx_lock.h"
#include "tdfx_span.h"
#include "tdfx_render.h"
#include "swrast/swrast.h"
#define DBG 0
#define LOCAL_VARS \
__DRIdrawablePrivate *dPriv = fxMesa->driDrawable; \
tdfxScreenPrivate *fxPriv = fxMesa->fxScreen; \
GLuint pitch = (fxMesa->glCtx->Color.DrawBuffer[0] == GL_FRONT) \
? (fxMesa->screen_width * BYTESPERPIXEL) : \
(info.strideInBytes); \
GLuint height = fxMesa->height; \
char *buf = (char *)((char *)info.lfbPtr + \
dPriv->x * fxPriv->cpp + \
dPriv->y * pitch); \
GLuint p; \
(void) buf; (void) p;
#define CLIPPIXEL( _x, _y ) ( _x >= minx && _x < maxx && \
_y >= miny && _y < maxy )
#define CLIPSPAN( _x, _y, _n, _x1, _n1, _i ) \
if ( _y < miny || _y >= maxy ) { \
_n1 = 0, _x1 = x; \
} else { \
_n1 = _n; \
_x1 = _x; \
if ( _x1 < minx ) _i += (minx-_x1), n1 -= (minx-_x1), _x1 = minx; \
if ( _x1 + _n1 >= maxx ) n1 -= (_x1 + n1 - maxx); \
}
#define Y_FLIP(_y) (height - _y - 1)
#define HW_WRITE_LOCK() \
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx); \
GrLfbInfo_t info; \
FLUSH_BATCH( fxMesa ); \
UNLOCK_HARDWARE( fxMesa ); \
LOCK_HARDWARE( fxMesa ); \
info.size = sizeof(GrLfbInfo_t); \
if ( fxMesa->Glide.grLfbLock( GR_LFB_WRITE_ONLY, \
fxMesa->DrawBuffer, LFB_MODE, \
GR_ORIGIN_UPPER_LEFT, FXFALSE, &info ) ) \
{
#define HW_WRITE_UNLOCK() \
fxMesa->Glide.grLfbUnlock( GR_LFB_WRITE_ONLY, fxMesa->DrawBuffer );\
}
#define HW_READ_LOCK() \
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx); \
GrLfbInfo_t info; \
FLUSH_BATCH( fxMesa ); \
UNLOCK_HARDWARE( fxMesa ); \
LOCK_HARDWARE( fxMesa ); \
info.size = sizeof(GrLfbInfo_t); \
if ( fxMesa->Glide.grLfbLock( GR_LFB_READ_ONLY, fxMesa->ReadBuffer, \
LFB_MODE, GR_ORIGIN_UPPER_LEFT, FXFALSE, &info ) ) \
{
#define HW_READ_UNLOCK() \
fxMesa->Glide.grLfbUnlock( GR_LFB_READ_ONLY, fxMesa->ReadBuffer );\
}
#define HW_WRITE_CLIPLOOP() \
do { \
int _nc = fxMesa->numClipRects; \
while (_nc--) { \
int minx = fxMesa->pClipRects[_nc].x1 - fxMesa->x_offset; \
int miny = fxMesa->pClipRects[_nc].y1 - fxMesa->y_offset; \
int maxx = fxMesa->pClipRects[_nc].x2 - fxMesa->x_offset; \
int maxy = fxMesa->pClipRects[_nc].y2 - fxMesa->y_offset;
#define HW_READ_CLIPLOOP() \
do { \
const __DRIdrawablePrivate *dPriv = fxMesa->driDrawable; \
drm_clip_rect_t *rect = dPriv->pClipRects; \
int _nc = dPriv->numClipRects; \
while (_nc--) { \
const int minx = rect->x1 - fxMesa->x_offset; \
const int miny = rect->y1 - fxMesa->y_offset; \
const int maxx = rect->x2 - fxMesa->x_offset; \
const int maxy = rect->y2 - fxMesa->y_offset; \
rect++;
#define HW_ENDCLIPLOOP() \
} \
} while (0)
#define LFB_MODE GR_LFBWRITEMODE_565
/* 16 bit, RGB565 color spanline and pixel functions */ \
#undef INIT_MONO_PIXEL
#define INIT_MONO_PIXEL(p, color) \
p = TDFXPACKCOLOR565( color[0], color[1], color[2] )
#define WRITE_RGBA( _x, _y, r, g, b, a ) \
*(GLushort *)(buf + _x*2 + _y*pitch) = ((((int)r & 0xf8) << 8) | \
(((int)g & 0xfc) << 3) | \
(((int)b & 0xf8) >> 3))
#define WRITE_PIXEL( _x, _y, p ) \
*(GLushort *)(buf + _x*2 + _y*pitch) = p
#define READ_RGBA( rgba, _x, _y ) \
do { \
GLushort p = *(GLushort *)(buf + _x*2 + _y*pitch); \
rgba[0] = (((p >> 11) & 0x1f) * 255) / 31; \
rgba[1] = (((p >> 5) & 0x3f) * 255) / 63; \
rgba[2] = (((p >> 0) & 0x1f) * 255) / 31; \
rgba[3] = 0xff; \
} while (0)
#define TAG(x) tdfx##x##_RGB565
#define BYTESPERPIXEL 2
#include "spantmp.h"
#undef BYTESPERPIXEL
/* 16 bit, BGR565 color spanline and pixel functions */ \
#if 0
#define WRITE_RGBA( _x, _y, r, g, b, a ) \
*(GLushort *)(buf + _x*2 + _y*pitch) = ((((int)b & 0xf8) << 8) | \
(((int)g & 0xfc) << 3) | \
(((int)r & 0xf8) >> 3))
#define WRITE_PIXEL( _x, _y, p ) \
*(GLushort *)(buf + _x*2 + _y*pitch) = p
#define READ_RGBA( rgba, _x, _y ) \
do { \
GLushort p = *(GLushort *)(buf + _x*2 + _y*pitch); \
rgba[0] = (p << 3) & 0xf8; \
rgba[1] = (p >> 3) & 0xfc; \
rgba[2] = (p >> 8) & 0xf8; \
rgba[3] = 0xff; \
} while (0)
#define TAG(x) tdfx##x##_BGR565
#define BYTESPERPIXEL 2
#include "spantmp.h"
#undef BYTESPERPIXEL
#endif
#undef LFB_MODE
#define LFB_MODE GR_LFBWRITEMODE_888
/* 24 bit, RGB888 color spanline and pixel functions */
#undef INIT_MONO_PIXEL
#define INIT_MONO_PIXEL(p, color) \
p = TDFXPACKCOLOR888( color[0], color[1], color[2] )
#define WRITE_RGBA( _x, _y, r, g, b, a ) \
*(GLuint *)(buf + _x*3 + _y*pitch) = ((b << 0) | \
(g << 8) | \
(r << 16))
#define WRITE_PIXEL( _x, _y, p ) \
*(GLuint *)(buf + _x*3 + _y*pitch) = p
#define READ_RGBA( rgba, _x, _y ) \
do { \
GLuint p = *(GLuint *)(buf + _x*3 + _y*pitch); \
rgba[0] = (p >> 16) & 0xff; \
rgba[1] = (p >> 8) & 0xff; \
rgba[2] = (p >> 0) & 0xff; \
rgba[3] = 0xff; \
} while (0)
#define TAG(x) tdfx##x##_RGB888
#define BYTESPERPIXEL 4
#include "spantmp.h"
#undef BYTESPERPIXEL
#undef LFB_MODE
#define LFB_MODE GR_LFBWRITEMODE_8888
/* 32 bit, ARGB8888 color spanline and pixel functions */
#undef INIT_MONO_PIXEL
#define INIT_MONO_PIXEL(p, color) \
p = TDFXPACKCOLOR8888( color[0], color[1], color[2], color[3] )
#define WRITE_RGBA( _x, _y, r, g, b, a ) \
*(GLuint *)(buf + _x*4 + _y*pitch) = ((b << 0) | \
(g << 8) | \
(r << 16) | \
(a << 24) )
#define WRITE_PIXEL( _x, _y, p ) \
*(GLuint *)(buf + _x*4 + _y*pitch) = p
#define READ_RGBA( rgba, _x, _y ) \
do { \
GLuint p = *(GLuint *)(buf + _x*4 + _y*pitch); \
rgba[0] = (p >> 16) & 0xff; \
rgba[1] = (p >> 8) & 0xff; \
rgba[2] = (p >> 0) & 0xff; \
rgba[3] = (p >> 24) & 0xff; \
} while (0)
#define TAG(x) tdfx##x##_ARGB8888
#define BYTESPERPIXEL 4
#include "spantmp.h"
#undef BYTESPERPIXEL
/* ================================================================
* Old span functions below...
*/
/*
* Examine the cliprects to generate an array of flags to indicate
* which pixels in a span are visible. Note: (x,y) is a screen
* coordinate.
*/
static void
generate_vismask(const tdfxContextPtr fxMesa, GLint x, GLint y, GLint n,
GLubyte vismask[])
{
GLboolean initialized = GL_FALSE;
GLint i, j;
/* Ensure we clear the visual mask */
MEMSET(vismask, 0, n);
/* turn on flags for all visible pixels */
for (i = 0; i < fxMesa->numClipRects; i++) {
const drm_clip_rect_t *rect = &fxMesa->pClipRects[i];
if (y >= rect->y1 && y < rect->y2) {
if (x >= rect->x1 && x + n <= rect->x2) {
/* common case, whole span inside cliprect */
MEMSET(vismask, 1, n);
return;
}
if (x < rect->x2 && x + n >= rect->x1) {
/* some of the span is inside the rect */
GLint start, end;
if (!initialized) {
MEMSET(vismask, 0, n);
initialized = GL_TRUE;
}
if (x < rect->x1)
start = rect->x1 - x;
else
start = 0;
if (x + n > rect->x2)
end = rect->x2 - x;
else
end = n;
assert(start >= 0);
assert(end <= n);
for (j = start; j < end; j++)
vismask[j] = 1;
}
}
}
}
/*
* Examine cliprects and determine if the given screen pixel is visible.
*/
static GLboolean
visible_pixel(const tdfxContextPtr fxMesa, int scrX, int scrY)
{
int i;
for (i = 0; i < fxMesa->numClipRects; i++) {
const drm_clip_rect_t *rect = &fxMesa->pClipRects[i];
if (scrX >= rect->x1 &&
scrX < rect->x2 &&
scrY >= rect->y1 && scrY < rect->y2) return GL_TRUE;
}
return GL_FALSE;
}
/*
* Depth buffer read/write functions.
*/
/*
* To read the frame buffer, we need to lock and unlock it. The
* four macros {READ,WRITE}_FB_SPAN_{LOCK,UNLOCK}
* do this for us.
*
* Note that the lock must be matched with an unlock. These
* macros include a spare curly brace, so they must
* be syntactically matched.
*
* Note, also, that you can't lock a buffer twice with different
* modes. That is to say, you can't lock a buffer in both read
* and write modes. The strideInBytes and LFB pointer will be
* the same with read and write locks, so you can use either.
* o The HW has different state for reads and writes, so
* locking it twice may give screwy results.
* o The DRM won't let you lock twice. It hangs. This is probably
* because of the LOCK_HARDWARE IN THE *_FB_SPAN_LOCK macros,
* and could be eliminated with nonlocking lock routines. But
* what's the point after all.
*/
#define READ_FB_SPAN_LOCK(fxMesa, info, target_buffer) \
UNLOCK_HARDWARE(fxMesa); \
LOCK_HARDWARE(fxMesa); \
(info).size=sizeof(info); \
if (fxMesa->Glide.grLfbLock(GR_LFB_READ_ONLY, \
target_buffer, \
GR_LFBWRITEMODE_ANY, \
GR_ORIGIN_UPPER_LEFT, \
FXFALSE, \
&(info))) {
#define READ_FB_SPAN_UNLOCK(fxMesa, target_buffer) \
fxMesa->Glide.grLfbUnlock(GR_LFB_READ_ONLY, target_buffer); \
} else { \
fprintf(stderr, "tdfxDriver: Can't get %s (%d) read lock\n", \
(target_buffer == GR_BUFFER_BACKBUFFER) \
? "back buffer" \
: ((target_buffer == GR_BUFFER_AUXBUFFER) \
? "depth buffer" \
: "unknown buffer"), \
target_buffer); \
}
#define WRITE_FB_SPAN_LOCK(fxMesa, info, target_buffer, write_mode) \
UNLOCK_HARDWARE(fxMesa); \
LOCK_HARDWARE(fxMesa); \
info.size=sizeof(info); \
if (fxMesa->Glide.grLfbLock(GR_LFB_WRITE_ONLY, \
target_buffer, \
write_mode, \
GR_ORIGIN_UPPER_LEFT, \
FXFALSE, \
&info)) {
#define WRITE_FB_SPAN_UNLOCK(fxMesa, target_buffer) \
fxMesa->Glide.grLfbUnlock(GR_LFB_WRITE_ONLY, target_buffer); \
} else { \
fprintf(stderr, "tdfxDriver: Can't get %s (%d) write lock\n", \
(target_buffer == GR_BUFFER_BACKBUFFER) \
? "back buffer" \
: ((target_buffer == GR_BUFFER_AUXBUFFER) \
? "depth buffer" \
: "unknown buffer"), \
target_buffer); \
}
/*
* Because the Linear Frame Buffer is not necessarily aligned
* with the depth buffer, we have to do some fiddling
* around to get the right addresses.
*
* Perhaps a picture is in order. The Linear Frame Buffer
* looks like this:
*
* |<----------------------info.strideInBytes------------->|
* |<-----physicalStrideInBytes------->|
* +-----------------------------------+xxxxxxxxxxxxxxxxxxx+
* | | |
* | Legal Memory | Forbidden Zone |
* | | |
* +-----------------------------------+xxxxxxxxxxxxxxxxxxx+
*
* You can only reliably read and write legal locations. Reads
* and writes from the Forbidden Zone will return undefined values,
* and may cause segmentation faults.
*
* Now, the depth buffer may not end up in a location such each
* scan line is an LFB line. For example, the depth buffer may
* look like this:
*
* wrapped ordinary.
* +-----------------------------------+xxxxxxxxxxxxxxxxxxx+
* |0000000000000000000000 | | back
* |1111111111111111111111 | | buffer
* |2222222222222222222222 | |
* |4096b align. padxx00000000000000000| Forbidden Zone | depth
* |0000 11111111111111111| | buffer
* |1111 22222222222222222| |
* |2222 | |
* +-----------------------------------+xxxxxxxxxxxxxxxxxxx+
* where each number is the scan line number. We know it will
* be aligned on 128 byte boundaries, at least. Aligning this
* on a scanline boundary causes the back and depth buffers to
* thrash in the SST1 cache. (Note that the back buffer is always
* allocated at the beginning of LFB memory, and so it is always
* properly aligned with the LFB stride.)
*
* We call the beginning of the line (which is the rightmost
* part of the depth line in the picture above) the *ordinary* part
* of the scanline, and the end of the line (which is the
* leftmost part, one line below) the *wrapped* part of the scanline.
* a.) We need to know what x value to subtract from the screen
* x coordinate to index into the wrapped part.
* b.) We also need to figure out if we need to read from the ordinary
* part scan line, or from the wrapped part of the scan line.
*
* [ad a]
* The first wrapped x coordinate is that coordinate such that
* depthBufferOffset&(info.strideInBytes) + x*elmentSize {*}
* > physicalStrideInBytes
* where depthBufferOffset is the LFB distance in bytes
* from the back buffer to the depth buffer. The expression
* depthBufferOffset&(info.strideInBytes)
* is then the offset (in bytes) from the beginining of (any)
* depth buffer line to first element in the line.
* Simplifying inequation {*} above we see that x is the smallest
* value such that
* x*elementSize > physicalStrideInBytes {**}
* - depthBufferOffset&(info.strideInBytes)
* Now, we know that both the summands on the right are multiples of
* 128, and elementSize <= 4, so if equality holds in {**}, x would
* be a multiple of 32. Thus we can set x to
* xwrapped = (physicalStrideInBytes
* - depthBufferOffset&(info.strideInBytes))/elementSize
* + 1
*
* [ad b]
* Question b is now simple. We read from the wrapped scan line if
* x is greater than xwrapped.
*/
#define TILE_WIDTH_IN_BYTES 128
#define TILE_WIDTH_IN_ZOXELS(bpz) (TILE_WIDTH_IN_BYTES/(bpz))
#define TILE_HEIGHT_IN_LINES 32
typedef struct
{
void *lfbPtr;
void *lfbWrapPtr;
FxU32 LFBStrideInElts;
GLint firstWrappedX;
}
LFBParameters;
/*
* We need information about the back buffer. Note that
* this function *cannot be called* while the aux buffer
* is locked, or the caller will hang.
*
* Only Glide knows the LFB address of the back and depth
* offsets. The upper levels of Mesa know the depth offset,
* but that is not in LFB space, it is tiled memory space,
* and is not useable for us.
*/
static void
GetBackBufferInfo(tdfxContextPtr fxMesa, GrLfbInfo_t * backBufferInfo)
{
READ_FB_SPAN_LOCK(fxMesa, *backBufferInfo, GR_BUFFER_BACKBUFFER);
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_BACKBUFFER);
}
static void
GetFbParams(tdfxContextPtr fxMesa,
GrLfbInfo_t * info,
GrLfbInfo_t * backBufferInfo,
LFBParameters * ReadParamsp, FxU32 elementSize)
{
FxU32 physicalStrideInBytes, bufferOffset;
FxU32 strideInBytes = info->strideInBytes;
char *lfbPtr = (char *) (info->lfbPtr); /* For arithmetic, use char * */
/*
* These two come directly from the info structure.
*/
ReadParamsp->lfbPtr = (void *) lfbPtr;
ReadParamsp->LFBStrideInElts = strideInBytes / elementSize;
/*
* Now, calculate the value of firstWrappedX.
*
* The physical stride is the screen width in bytes rounded up to
* the next highest multiple of 128 bytes. Note that this fails
* when TILE_WIDTH_IN_BYTES is not a power of two.
*
* The buffer Offset is the distance between the beginning of
* the LFB space, which is the beginning of the back buffer,
* and the buffer we are gathering information about.
* We want to make this routine usable for operations on the
* back buffer, though we don't actually use it on the back
* buffer. Note, then, that if bufferOffset == 0, the firstWrappedX
* is in the forbidden zone, and is therefore never reached.
*
* Note that if
* physicalStrideInBytes
* < bufferOffset&(info->strideInBytes-1)
* the buffer begins in the forbidden zone. We assert for this.
*/
bufferOffset = (FxU32)(lfbPtr - (char *) backBufferInfo->lfbPtr);
physicalStrideInBytes
= (fxMesa->screen_width * elementSize + TILE_WIDTH_IN_BYTES - 1)
& ~(TILE_WIDTH_IN_BYTES - 1);
assert(physicalStrideInBytes > (bufferOffset & (strideInBytes - 1)));
ReadParamsp->firstWrappedX
= (physicalStrideInBytes
- (bufferOffset & (strideInBytes - 1))) / elementSize;
/*
* This is the address of the next physical line.
*/
ReadParamsp->lfbWrapPtr
= (void *) ((char *) backBufferInfo->lfbPtr
+ (bufferOffset & ~(strideInBytes - 1))
+ (TILE_HEIGHT_IN_LINES) * strideInBytes);
}
/*
* These macros fetch data from the frame buffer. The type is
* the type of data we want to fetch. It should match the type
* whose size was used with GetFbParams to fill in the structure
* in *ReadParamsp. We have a macro to read the ordinary
* part, a second macro to read the wrapped part, and one which
* will do either. When we are reading a span, we will know
* when the ordinary part ends, so there's no need to test for
* it. However, when reading and writing pixels, we don't
* necessarily know. I suppose it's a matter of taste whether
* it's better in the macro or in the call.
*
* Recall that x and y are screen coordinates.
*/
#define GET_ORDINARY_FB_DATA(ReadParamsp, type, x, y) \
(((type *)((ReadParamsp)->lfbPtr)) \
[(y) * ((ReadParamsp)->LFBStrideInElts) \
+ (x)])
#define GET_WRAPPED_FB_DATA(ReadParamsp, type, x, y) \
(((type *)((ReadParamsp)->lfbWrapPtr)) \
[((y)) * ((ReadParamsp)->LFBStrideInElts) \
+ ((x) - (ReadParamsp)->firstWrappedX)])
#define GET_FB_DATA(ReadParamsp, type, x, y) \
(((x) < (ReadParamsp)->firstWrappedX) \
? GET_ORDINARY_FB_DATA(ReadParamsp, type, x, y) \
: GET_WRAPPED_FB_DATA(ReadParamsp, type, x, y))
#define PUT_ORDINARY_FB_DATA(ReadParamsp, type, x, y, value) \
(GET_ORDINARY_FB_DATA(ReadParamsp, type, x, y) = (type)(value))
#define PUT_WRAPPED_FB_DATA(ReadParamsp, type, x, y, value) \
(GET_WRAPPED_FB_DATA(ReadParamsp, type, x, y) = (type)(value))
#define PUT_FB_DATA(ReadParamsp, type, x, y, value) \
do { \
if ((x) < (ReadParamsp)->firstWrappedX) \
PUT_ORDINARY_FB_DATA(ReadParamsp, type, x, y, value); \
else \
PUT_WRAPPED_FB_DATA(ReadParamsp, type, x, y, value); \
} while (0)
static void
tdfxDDWriteDepthSpan(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, GLint x, GLint y, const void *values,
const GLubyte mask[])
{
const GLuint *depth = (const GLuint *) values;
tdfxContextPtr fxMesa = (tdfxContextPtr) ctx->DriverCtx;
GLint bottom = fxMesa->y_offset + fxMesa->height - 1;
GLuint depth_size = fxMesa->glCtx->Visual.depthBits;
GLuint stencil_size = fxMesa->glCtx->Visual.stencilBits;
GrLfbInfo_t info;
GLubyte visMask[MAX_WIDTH];
if (MESA_VERBOSE & VERBOSE_DRIVER) {
fprintf(stderr, "tdfxmesa: tdfxDDWriteDepthSpan(...)\n");
}
assert((depth_size == 16) || (depth_size == 24) || (depth_size == 32));
/*
* Convert x and y to screen coordinates.
*/
x += fxMesa->x_offset;
y = bottom - y;
if (mask) {
GLint i;
GLushort d16;
GrLfbInfo_t backBufferInfo;
switch (depth_size) {
case 16:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER,
GR_LFBWRITEMODE_ANY);
generate_vismask(fxMesa, x, y, n, visMask);
{
LFBParameters ReadParams;
int wrappedPartStart;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLushort));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
for (i = 0; i < wrappedPartStart; i++) {
if (mask[i] && visMask[i]) {
d16 = depth[i];
PUT_ORDINARY_FB_DATA(&ReadParams, GLushort, x + i, y, d16);
}
}
for (; i < n; i++) {
if (mask[i] && visMask[i]) {
d16 = depth[i];
PUT_WRAPPED_FB_DATA(&ReadParams, GLushort, x + i, y, d16);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
case 24:
case 32:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER,
GR_LFBWRITEMODE_ANY);
generate_vismask(fxMesa, x, y, n, visMask);
{
LFBParameters ReadParams;
int wrappedPartStart;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLuint));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
for (i = 0; i < wrappedPartStart; i++) {
GLuint d32;
if (mask[i] && visMask[i]) {
if (stencil_size > 0) {
d32 =
GET_ORDINARY_FB_DATA(&ReadParams, GLuint,
x + i, y);
d32 =
(d32 & 0xFF000000) | (depth[i] & 0x00FFFFFF);
}
else {
d32 = depth[i];
}
PUT_ORDINARY_FB_DATA(&ReadParams, GLuint, x + i, y, d32);
}
}
for (; i < n; i++) {
GLuint d32;
if (mask[i] && visMask[i]) {
if (stencil_size > 0) {
d32 =
GET_WRAPPED_FB_DATA(&ReadParams, GLuint,
x + i, y);
d32 =
(d32 & 0xFF000000) | (depth[i] & 0x00FFFFFF);
}
else {
d32 = depth[i];
}
PUT_WRAPPED_FB_DATA(&ReadParams, GLuint, x + i, y, d32);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
}
}
else {
GLint i;
GLuint d32;
GLushort d16;
GrLfbInfo_t backBufferInfo;
switch (depth_size) {
case 16:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info,
GR_BUFFER_AUXBUFFER, GR_LFBWRITEMODE_ANY);
generate_vismask(fxMesa, x, y, n, visMask);
{
LFBParameters ReadParams;
GLuint wrappedPartStart;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLushort));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
for (i = 0; i < wrappedPartStart; i++) {
if (visMask[i]) {
d16 = depth[i];
PUT_ORDINARY_FB_DATA(&ReadParams,
GLushort,
x + i, y,
d16);
}
}
for (; i < n; i++) {
if (visMask[i]) {
d16 = depth[i];
PUT_WRAPPED_FB_DATA(&ReadParams,
GLushort,
x + i, y,
d16);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
case 24:
case 32:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info,
GR_BUFFER_AUXBUFFER, GR_LFBWRITEMODE_ANY);
generate_vismask(fxMesa, x, y, n, visMask);
{
LFBParameters ReadParams;
GLuint wrappedPartStart;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLuint));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
for (i = 0; i < wrappedPartStart; i++) {
if (visMask[i]) {
if (stencil_size > 0) {
d32 = GET_ORDINARY_FB_DATA(&ReadParams, GLuint, x + i, y);
d32 =
(d32 & 0xFF000000) | (depth[i] & 0x00FFFFFF);
}
else {
d32 = depth[i];
}
PUT_ORDINARY_FB_DATA(&ReadParams, GLuint, x + i, y, d32);
}
}
for (; i < n; i++) {
if (visMask[i]) {
if (stencil_size > 0) {
d32 = GET_WRAPPED_FB_DATA(&ReadParams, GLuint, x + i, y);
d32 =
(d32 & 0xFF000000) | (depth[i] & 0x00FFFFFF);
}
else {
d32 = depth[i];
}
PUT_WRAPPED_FB_DATA(&ReadParams, GLuint, x + i, y, d32);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
}
}
}
static void
tdfxDDWriteMonoDepthSpan(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, GLint x, GLint y, const void *value,
const GLubyte mask[])
{
GLuint depthVal = *((GLuint *) value);
GLuint depths[MAX_WIDTH];
GLuint i;
for (i = 0; i < n; i++)
depths[i] = depthVal;
tdfxDDWriteDepthSpan(ctx, rb, n, x, y, depths, mask);
}
static void
tdfxDDReadDepthSpan(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, GLint x, GLint y, void *values)
{
GLuint *depth = (GLuint *) values;
tdfxContextPtr fxMesa = (tdfxContextPtr) ctx->DriverCtx;
GLint bottom = fxMesa->height + fxMesa->y_offset - 1;
GLuint i;
GLuint depth_size = fxMesa->glCtx->Visual.depthBits;
GrLfbInfo_t info;
if (MESA_VERBOSE & VERBOSE_DRIVER) {
fprintf(stderr, "tdfxmesa: tdfxDDReadDepthSpan(...)\n");
}
/*
* Convert to screen coordinates.
*/
x += fxMesa->x_offset;
y = bottom - y;
switch (depth_size) {
case 16:
{
LFBParameters ReadParams;
GrLfbInfo_t backBufferInfo;
int wrappedPartStart;
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
READ_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER);
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLushort));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
/*
* Read the line.
*/
for (i = 0; i < wrappedPartStart; i++) {
depth[i] =
GET_ORDINARY_FB_DATA(&ReadParams, GLushort, x + i, y);
}
for (; i < n; i++) {
depth[i] = GET_WRAPPED_FB_DATA(&ReadParams, GLushort,
x + i, y);
}
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
}
case 24:
case 32:
{
LFBParameters ReadParams;
GrLfbInfo_t backBufferInfo;
int wrappedPartStart;
GLuint stencil_size = fxMesa->glCtx->Visual.stencilBits;
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
READ_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER);
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLuint));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
/*
* Read the line.
*/
for (i = 0; i < wrappedPartStart; i++) {
const GLuint mask =
(stencil_size > 0) ? 0x00FFFFFF : 0xFFFFFFFF;
depth[i] =
GET_ORDINARY_FB_DATA(&ReadParams, GLuint, x + i, y);
depth[i] &= mask;
}
for (; i < n; i++) {
const GLuint mask =
(stencil_size > 0) ? 0x00FFFFFF : 0xFFFFFFFF;
depth[i] = GET_WRAPPED_FB_DATA(&ReadParams, GLuint, x + i, y);
depth[i] &= mask;
}
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
}
}
}
static void
tdfxDDWriteDepthPixels(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, const GLint x[], const GLint y[],
const void *values, const GLubyte mask[])
{
const GLuint *depth = (const GLuint *) values;
tdfxContextPtr fxMesa = (tdfxContextPtr) ctx->DriverCtx;
GLint bottom = fxMesa->height + fxMesa->y_offset - 1;
GLuint i;
GLushort d16;
GLuint d32;
GLuint depth_size = fxMesa->glCtx->Visual.depthBits;
GLuint stencil_size = fxMesa->glCtx->Visual.stencilBits;
GrLfbInfo_t info;
int xpos;
int ypos;
GrLfbInfo_t backBufferInfo;
if (MESA_VERBOSE & VERBOSE_DRIVER) {
fprintf(stderr, "tdfxmesa: tdfxDDWriteDepthPixels(...)\n");
}
switch (depth_size) {
case 16:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info,
GR_BUFFER_AUXBUFFER, GR_LFBWRITEMODE_ANY);
{
LFBParameters ReadParams;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLushort));
for (i = 0; i < n; i++) {
if (mask[i] && visible_pixel(fxMesa, x[i], y[i])) {
xpos = x[i] + fxMesa->x_offset;
ypos = bottom - y[i];
d16 = depth[i];
PUT_FB_DATA(&ReadParams, GLushort, xpos, ypos, d16);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
case 24:
case 32:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info,
GR_BUFFER_AUXBUFFER, GR_LFBWRITEMODE_ANY);
{
LFBParameters ReadParams;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLuint));
for (i = 0; i < n; i++) {
if (mask[i]) {
if (visible_pixel(fxMesa, x[i], y[i])) {
xpos = x[i] + fxMesa->x_offset;
ypos = bottom - y[i];
if (stencil_size > 0) {
d32 =
GET_FB_DATA(&ReadParams, GLuint, xpos, ypos);
d32 = (d32 & 0xFF000000) | (depth[i] & 0xFFFFFF);
}
else {
d32 = depth[i];
}
PUT_FB_DATA(&ReadParams, GLuint, xpos, ypos, d32);
}
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
}
}
static void
tdfxDDReadDepthPixels(GLcontext * ctx, struct gl_renderbuffer *rb, GLuint n,
const GLint x[], const GLint y[], void *values)
{
GLuint *depth = (GLuint *) values;
tdfxContextPtr fxMesa = (tdfxContextPtr) ctx->DriverCtx;
GLint bottom = fxMesa->height + fxMesa->y_offset - 1;
GLuint i;
GLuint depth_size = fxMesa->glCtx->Visual.depthBits;
GLushort d16;
int xpos;
int ypos;
GrLfbInfo_t info;
GLuint stencil_size;
GrLfbInfo_t backBufferInfo;
if (MESA_VERBOSE & VERBOSE_DRIVER) {
fprintf(stderr, "tdfxmesa: tdfxDDReadDepthPixels(...)\n");
}
assert((depth_size == 16) || (depth_size == 24) || (depth_size == 32));
switch (depth_size) {
case 16:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
READ_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER);
{
LFBParameters ReadParams;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLushort));
for (i = 0; i < n; i++) {
/*
* Convert to screen coordinates.
*/
xpos = x[i] + fxMesa->x_offset;
ypos = bottom - y[i];
d16 = GET_FB_DATA(&ReadParams, GLushort, xpos, ypos);
depth[i] = d16;
}
}
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
case 24:
case 32:
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
READ_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER);
stencil_size = fxMesa->glCtx->Visual.stencilBits;
{
LFBParameters ReadParams;
GetFbParams(fxMesa, &info, &backBufferInfo,
&ReadParams, sizeof(GLuint));
for (i = 0; i < n; i++) {
GLuint d32;
/*
* Convert to screen coordinates.
*/
xpos = x[i] + fxMesa->x_offset;
ypos = bottom - y[i];
d32 = GET_FB_DATA(&ReadParams, GLuint, xpos, ypos);
if (stencil_size > 0) {
d32 &= 0x00FFFFFF;
}
depth[i] = d32;
}
}
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
break;
default:
assert(0);
}
}
/*
* Stencil buffer read/write functions.
*/
#define EXTRACT_S_FROM_ZS(zs) (((zs) >> 24) & 0xFF)
#define EXTRACT_Z_FROM_ZS(zs) ((zs) & 0xffffff)
#define BUILD_ZS(z, s) (((s) << 24) | (z))
static void
write_stencil_span(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, GLint x, GLint y,
const void *values, const GLubyte mask[])
{
const GLubyte *stencil = (const GLubyte *) values;
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
GrLfbInfo_t info;
GrLfbInfo_t backBufferInfo;
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER, GR_LFBWRITEMODE_ANY);
{
const GLint winY = fxMesa->y_offset + fxMesa->height - 1;
const GLint winX = fxMesa->x_offset;
const GLint scrX = winX + x;
const GLint scrY = winY - y;
LFBParameters ReadParams;
GLubyte visMask[MAX_WIDTH];
GLuint i;
int wrappedPartStart;
GetFbParams(fxMesa, &info, &backBufferInfo, &ReadParams,
sizeof(GLuint));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
generate_vismask(fxMesa, scrX, scrY, n, visMask);
for (i = 0; i < wrappedPartStart; i++) {
if (visMask[i] && (!mask || mask[i])) {
GLuint z = GET_ORDINARY_FB_DATA(&ReadParams, GLuint,
scrX + i, scrY) & 0x00FFFFFF;
z |= (stencil[i] & 0xFF) << 24;
PUT_ORDINARY_FB_DATA(&ReadParams, GLuint, scrX + i, scrY, z);
}
}
for (; i < n; i++) {
if (visMask[i] && (!mask || mask[i])) {
GLuint z = GET_WRAPPED_FB_DATA(&ReadParams, GLuint,
scrX + i, scrY) & 0x00FFFFFF;
z |= (stencil[i] & 0xFF) << 24;
PUT_WRAPPED_FB_DATA(&ReadParams, GLuint, scrX + i, scrY, z);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
}
static void
write_mono_stencil_span(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, GLint x, GLint y,
const void *value, const GLubyte mask[])
{
GLbyte stencilVal = *((GLbyte *) value);
GLbyte stencils[MAX_WIDTH];
GLuint i;
for (i = 0; i < n; i++)
stencils[i] = stencilVal;
write_stencil_span(ctx, rb, n, x, y, stencils, mask);
}
static void
read_stencil_span(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, GLint x, GLint y,
void *values)
{
GLubyte *stencil = (GLubyte *) values;
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
GrLfbInfo_t info;
GrLfbInfo_t backBufferInfo;
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
READ_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER);
{
const GLint winY = fxMesa->y_offset + fxMesa->height - 1;
const GLint winX = fxMesa->x_offset;
GLuint i;
LFBParameters ReadParams;
int wrappedPartStart;
/*
* Convert to screen coordinates.
*/
x += winX;
y = winY - y;
GetFbParams(fxMesa, &info, &backBufferInfo, &ReadParams,
sizeof(GLuint));
if (ReadParams.firstWrappedX <= x) {
wrappedPartStart = 0;
}
else if (n <= (ReadParams.firstWrappedX - x)) {
wrappedPartStart = n;
}
else {
wrappedPartStart = (ReadParams.firstWrappedX - x);
}
for (i = 0; i < wrappedPartStart; i++) {
stencil[i] = (GET_ORDINARY_FB_DATA(&ReadParams, GLuint,
x + i, y) >> 24) & 0xFF;
}
for (; i < n; i++) {
stencil[i] = (GET_WRAPPED_FB_DATA(&ReadParams, GLuint,
x + i, y) >> 24) & 0xFF;
}
}
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
}
static void
write_stencil_pixels(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, const GLint x[], const GLint y[],
const void *values, const GLubyte mask[])
{
const GLubyte *stencil = (const GLubyte *) values;
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
GrLfbInfo_t info;
GrLfbInfo_t backBufferInfo;
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
WRITE_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER, GR_LFBWRITEMODE_ANY);
{
const GLint winY = fxMesa->y_offset + fxMesa->height - 1;
const GLint winX = fxMesa->x_offset;
LFBParameters ReadParams;
GLuint i;
GetFbParams(fxMesa, &info, &backBufferInfo, &ReadParams,
sizeof(GLuint));
for (i = 0; i < n; i++) {
const GLint scrX = winX + x[i];
const GLint scrY = winY - y[i];
if ((!mask || mask[i]) && visible_pixel(fxMesa, scrX, scrY)) {
GLuint z =
GET_FB_DATA(&ReadParams, GLuint, scrX, scrY) & 0x00FFFFFF;
z |= (stencil[i] & 0xFF) << 24;
PUT_FB_DATA(&ReadParams, GLuint, scrX, scrY, z);
}
}
}
WRITE_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
}
static void
read_stencil_pixels(GLcontext * ctx, struct gl_renderbuffer *rb,
GLuint n, const GLint x[], const GLint y[],
void *values)
{
GLubyte *stencil = (GLubyte *) values;
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
GrLfbInfo_t info;
GrLfbInfo_t backBufferInfo;
GetBackBufferInfo(fxMesa, &backBufferInfo);
/*
* Note that the _LOCK macro adds a curly brace,
* and the UNLOCK macro removes it.
*/
READ_FB_SPAN_LOCK(fxMesa, info, GR_BUFFER_AUXBUFFER);
{
const GLint winY = fxMesa->y_offset + fxMesa->height - 1;
const GLint winX = fxMesa->x_offset;
GLuint i;
LFBParameters ReadParams;
GetFbParams(fxMesa, &info, &backBufferInfo, &ReadParams,
sizeof(GLuint));
for (i = 0; i < n; i++) {
const GLint scrX = winX + x[i];
const GLint scrY = winY - y[i];
stencil[i] =
(GET_FB_DATA(&ReadParams, GLuint, scrX, scrY) >> 24) & 0xFF;
}
}
READ_FB_SPAN_UNLOCK(fxMesa, GR_BUFFER_AUXBUFFER);
}
#define VISUAL_EQUALS_RGBA(vis, r, g, b, a) \
((vis.redBits == r) && \
(vis.greenBits == g) && \
(vis.blueBits == b) && \
(vis.alphaBits == a))
/**********************************************************************/
/* Locking for swrast */
/**********************************************************************/
static void tdfxSpanRenderStart( GLcontext *ctx )
{
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
LOCK_HARDWARE(fxMesa);
}
static void tdfxSpanRenderFinish( GLcontext *ctx )
{
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
_swrast_flush( ctx );
UNLOCK_HARDWARE(fxMesa);
}
/* Set the buffer used for reading */
static void tdfxDDSetBuffer( GLcontext *ctx,
GLframebuffer *buffer, GLuint bufferBit )
{
tdfxContextPtr fxMesa = TDFX_CONTEXT(ctx);
(void) buffer;
switch ( bufferBit ) {
case BUFFER_BIT_FRONT_LEFT:
fxMesa->DrawBuffer = fxMesa->ReadBuffer = GR_BUFFER_FRONTBUFFER;
break;
case BUFFER_BIT_BACK_LEFT:
fxMesa->DrawBuffer = fxMesa->ReadBuffer = GR_BUFFER_BACKBUFFER;
break;
default:
break;
}
}
/**********************************************************************/
/* Initialize swrast device driver */
/**********************************************************************/
void tdfxDDInitSpanFuncs( GLcontext *ctx )
{
struct swrast_device_driver *swdd = _swrast_GetDeviceDriverReference( ctx );
swdd->SetBuffer = tdfxDDSetBuffer;
swdd->SpanRenderStart = tdfxSpanRenderStart;
swdd->SpanRenderFinish = tdfxSpanRenderFinish;
}
/**
* Plug in the Get/Put routines for the given driRenderbuffer.
*/
void
tdfxSetSpanFunctions(driRenderbuffer *drb, const GLvisual *vis)
{
if (drb->Base.InternalFormat == GL_RGBA) {
if (vis->redBits == 5 && vis->greenBits == 6 && vis->blueBits == 5) {
drb->Base.GetRow = tdfxReadRGBASpan_RGB565;
drb->Base.GetValues = tdfxReadRGBAPixels_RGB565;
drb->Base.PutRow = tdfxWriteRGBASpan_RGB565;
drb->Base.PutRowRGB = tdfxWriteRGBSpan_RGB565;
drb->Base.PutMonoRow = tdfxWriteMonoRGBASpan_RGB565;
drb->Base.PutValues = tdfxWriteRGBAPixels_RGB565;
drb->Base.PutMonoValues = tdfxWriteMonoRGBAPixels_RGB565;
}
else if (vis->redBits == 8 && vis->greenBits == 8
&& vis->blueBits == 8 && vis->alphaBits == 0) {
drb->Base.GetRow = tdfxReadRGBASpan_RGB888;
drb->Base.GetValues = tdfxReadRGBAPixels_RGB888;
drb->Base.PutRow = tdfxWriteRGBASpan_RGB888;
drb->Base.PutRowRGB = tdfxWriteRGBSpan_RGB888;
drb->Base.PutMonoRow = tdfxWriteMonoRGBASpan_RGB888;
drb->Base.PutValues = tdfxWriteRGBAPixels_RGB888;
drb->Base.PutMonoValues = tdfxWriteMonoRGBAPixels_RGB888;
}
else if (vis->redBits == 8 && vis->greenBits == 8
&& vis->blueBits == 8 && vis->alphaBits == 8) {
drb->Base.GetRow = tdfxReadRGBASpan_ARGB8888;
drb->Base.GetValues = tdfxReadRGBAPixels_ARGB8888;
drb->Base.PutRow = tdfxWriteRGBASpan_ARGB8888;
drb->Base.PutRowRGB = tdfxWriteRGBSpan_ARGB8888;
drb->Base.PutMonoRow = tdfxWriteMonoRGBASpan_ARGB8888;
drb->Base.PutValues = tdfxWriteRGBAPixels_ARGB8888;
drb->Base.PutMonoValues = tdfxWriteMonoRGBAPixels_ARGB8888;
}
else {
_mesa_problem(NULL, "problem in tdfxSetSpanFunctions");
}
}
else if (drb->Base.InternalFormat == GL_DEPTH_COMPONENT16 ||
drb->Base.InternalFormat == GL_DEPTH_COMPONENT24) {
drb->Base.GetRow = tdfxDDReadDepthSpan;
drb->Base.GetValues = tdfxDDReadDepthPixels;
drb->Base.PutRow = tdfxDDWriteDepthSpan;
drb->Base.PutMonoRow = tdfxDDWriteMonoDepthSpan;
drb->Base.PutValues = tdfxDDWriteDepthPixels;
drb->Base.PutMonoValues = NULL;
}
else if (drb->Base.InternalFormat == GL_STENCIL_INDEX8_EXT) {
drb->Base.GetRow = read_stencil_span;
drb->Base.GetValues = read_stencil_pixels;
drb->Base.PutRow = write_stencil_span;
drb->Base.PutMonoRow = write_mono_stencil_span;
drb->Base.PutValues = write_stencil_pixels;
drb->Base.PutMonoValues = NULL;
}
}
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