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xserver-multidpi/hw/xfree86/ramdac/xf86HWCurs.c
Michael Thayer 901fbfbbbd Add a return value to load_cursor_argb() to allow it to report failure 
load_cursor_argb() may need to be able to fail and have the server fall back
to a software cursor in at least the following circumstances.
1) The hardware can only support some ARGB cursors and this does not just
depend on cursor size.
2) Virtual hardware may not wish to pass through a cursor to the host at a
particular time but may wish to accept the same cursor at another time.
This patch adds a return value to the API and makes the server do the
software fall-back on failure.

Signed-off-by: Michael Thayer <michael.thayer@oracle.com>
Reviewed-by: Dave Airlie <airlied@redhat.com>
Signed-off-by: Keith Packard <keithp@keithp.com>
2014-04-03 16:46:55 -07:00

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#ifdef HAVE_XORG_CONFIG_H
#include <xorg-config.h>
#endif
#include <string.h>
#include "misc.h"
#include "xf86.h"
#include "xf86_OSproc.h"
#include <X11/X.h>
#include "scrnintstr.h"
#include "pixmapstr.h"
#include "windowstr.h"
#include "xf86str.h"
#include "cursorstr.h"
#include "mi.h"
#include "mipointer.h"
#include "xf86CursorPriv.h"
#include "servermd.h"
static CARD32
xf86ReverseBitOrder(CARD32 v)
{
return (((0x01010101 & v) << 7) | ((0x02020202 & v) << 5) |
((0x04040404 & v) << 3) | ((0x08080808 & v) << 1) |
((0x10101010 & v) >> 1) | ((0x20202020 & v) >> 3) |
((0x40404040 & v) >> 5) | ((0x80808080 & v) >> 7));
}
#if BITMAP_SCANLINE_PAD == 64
#if 1
/* Cursors might be only 32 wide. Give'em a chance */
#define SCANLINE CARD32
#define CUR_BITMAP_SCANLINE_PAD 32
#define CUR_LOG2_BITMAP_PAD 5
#define REVERSE_BIT_ORDER(w) xf86ReverseBitOrder(w)
#else
#define SCANLINE CARD64
#define CUR_BITMAP_SCANLINE_PAD BITMAP_SCANLINE_PAD
#define CUR_LOG2_BITMAP_PAD LOG2_BITMAP_PAD
#define REVERSE_BIT_ORDER(w) xf86CARD64ReverseBits(w)
static CARD64 xf86CARD64ReverseBits(CARD64 w);
static CARD64
xf86CARD64ReverseBits(CARD64 w)
{
unsigned char *p = (unsigned char *) &w;
p[0] = byte_reversed[p[0]];
p[1] = byte_reversed[p[1]];
p[2] = byte_reversed[p[2]];
p[3] = byte_reversed[p[3]];
p[4] = byte_reversed[p[4]];
p[5] = byte_reversed[p[5]];
p[6] = byte_reversed[p[6]];
p[7] = byte_reversed[p[7]];
return w;
}
#endif
#else
#define SCANLINE CARD32
#define CUR_BITMAP_SCANLINE_PAD BITMAP_SCANLINE_PAD
#define CUR_LOG2_BITMAP_PAD LOG2_BITMAP_PAD
#define REVERSE_BIT_ORDER(w) xf86ReverseBitOrder(w)
#endif /* BITMAP_SCANLINE_PAD == 64 */
static unsigned char *RealizeCursorInterleave0(xf86CursorInfoPtr, CursorPtr);
static unsigned char *RealizeCursorInterleave1(xf86CursorInfoPtr, CursorPtr);
static unsigned char *RealizeCursorInterleave8(xf86CursorInfoPtr, CursorPtr);
static unsigned char *RealizeCursorInterleave16(xf86CursorInfoPtr, CursorPtr);
static unsigned char *RealizeCursorInterleave32(xf86CursorInfoPtr, CursorPtr);
static unsigned char *RealizeCursorInterleave64(xf86CursorInfoPtr, CursorPtr);
Bool
xf86InitHardwareCursor(ScreenPtr pScreen, xf86CursorInfoPtr infoPtr)
{
if ((infoPtr->MaxWidth <= 0) || (infoPtr->MaxHeight <= 0))
return FALSE;
/* These are required for now */
if (!infoPtr->SetCursorPosition ||
!infoPtr->LoadCursorImage ||
!infoPtr->HideCursor ||
!infoPtr->ShowCursor || !infoPtr->SetCursorColors)
return FALSE;
if (infoPtr->RealizeCursor) {
/* Don't overwrite a driver provided Realize Cursor function */
}
else if (HARDWARE_CURSOR_SOURCE_MASK_INTERLEAVE_1 & infoPtr->Flags) {
infoPtr->RealizeCursor = RealizeCursorInterleave1;
}
else if (HARDWARE_CURSOR_SOURCE_MASK_INTERLEAVE_8 & infoPtr->Flags) {
infoPtr->RealizeCursor = RealizeCursorInterleave8;
}
else if (HARDWARE_CURSOR_SOURCE_MASK_INTERLEAVE_16 & infoPtr->Flags) {
infoPtr->RealizeCursor = RealizeCursorInterleave16;
}
else if (HARDWARE_CURSOR_SOURCE_MASK_INTERLEAVE_32 & infoPtr->Flags) {
infoPtr->RealizeCursor = RealizeCursorInterleave32;
}
else if (HARDWARE_CURSOR_SOURCE_MASK_INTERLEAVE_64 & infoPtr->Flags) {
infoPtr->RealizeCursor = RealizeCursorInterleave64;
}
else { /* not interleaved */
infoPtr->RealizeCursor = RealizeCursorInterleave0;
}
infoPtr->pScrn = xf86ScreenToScrn(pScreen);
return TRUE;
}
Bool
xf86SetCursor(ScreenPtr pScreen, CursorPtr pCurs, int x, int y)
{
xf86CursorScreenPtr ScreenPriv =
(xf86CursorScreenPtr) dixLookupPrivate(&pScreen->devPrivates,
xf86CursorScreenKey);
xf86CursorInfoPtr infoPtr = ScreenPriv->CursorInfoPtr;
unsigned char *bits;
if (pCurs == NullCursor) {
(*infoPtr->HideCursor) (infoPtr->pScrn);
return TRUE;
}
bits =
dixLookupScreenPrivate(&pCurs->devPrivates, CursorScreenKey, pScreen);
x -= infoPtr->pScrn->frameX0 + ScreenPriv->HotX;
y -= infoPtr->pScrn->frameY0 + ScreenPriv->HotY;
#ifdef ARGB_CURSOR
if (!pCurs->bits->argb || !infoPtr->LoadCursorARGB)
#endif
if (!bits) {
bits = (*infoPtr->RealizeCursor) (infoPtr, pCurs);
dixSetScreenPrivate(&pCurs->devPrivates, CursorScreenKey, pScreen,
bits);
}
if (!(infoPtr->Flags & HARDWARE_CURSOR_UPDATE_UNHIDDEN))
(*infoPtr->HideCursor) (infoPtr->pScrn);
#ifdef ARGB_CURSOR
if (pCurs->bits->argb && infoPtr->LoadCursorARGB) {
if (!(*infoPtr->LoadCursorARGB) (infoPtr->pScrn, pCurs))
return FALSE;
} else
#endif
if (bits)
if (!(*infoPtr->LoadCursorImage) (infoPtr->pScrn, bits))
return FALSE;
xf86RecolorCursor(pScreen, pCurs, 1);
(*infoPtr->SetCursorPosition) (infoPtr->pScrn, x, y);
(*infoPtr->ShowCursor) (infoPtr->pScrn);
return TRUE;
}
void
xf86SetTransparentCursor(ScreenPtr pScreen)
{
xf86CursorScreenPtr ScreenPriv =
(xf86CursorScreenPtr) dixLookupPrivate(&pScreen->devPrivates,
xf86CursorScreenKey);
xf86CursorInfoPtr infoPtr = ScreenPriv->CursorInfoPtr;
if (!ScreenPriv->transparentData)
ScreenPriv->transparentData =
(*infoPtr->RealizeCursor) (infoPtr, NullCursor);
if (!(infoPtr->Flags & HARDWARE_CURSOR_UPDATE_UNHIDDEN))
(*infoPtr->HideCursor) (infoPtr->pScrn);
if (ScreenPriv->transparentData)
(*infoPtr->LoadCursorImage) (infoPtr->pScrn,
ScreenPriv->transparentData);
(*infoPtr->ShowCursor) (infoPtr->pScrn);
}
void
xf86MoveCursor(ScreenPtr pScreen, int x, int y)
{
xf86CursorScreenPtr ScreenPriv =
(xf86CursorScreenPtr) dixLookupPrivate(&pScreen->devPrivates,
xf86CursorScreenKey);
xf86CursorInfoPtr infoPtr = ScreenPriv->CursorInfoPtr;
x -= infoPtr->pScrn->frameX0 + ScreenPriv->HotX;
y -= infoPtr->pScrn->frameY0 + ScreenPriv->HotY;
(*infoPtr->SetCursorPosition) (infoPtr->pScrn, x, y);
}
void
xf86RecolorCursor(ScreenPtr pScreen, CursorPtr pCurs, Bool displayed)
{
xf86CursorScreenPtr ScreenPriv =
(xf86CursorScreenPtr) dixLookupPrivate(&pScreen->devPrivates,
xf86CursorScreenKey);
xf86CursorInfoPtr infoPtr = ScreenPriv->CursorInfoPtr;
#ifdef ARGB_CURSOR
/* recoloring isn't applicable to ARGB cursors and drivers
shouldn't have to ignore SetCursorColors requests */
if (pCurs->bits->argb)
return;
#endif
if (ScreenPriv->PalettedCursor) {
xColorItem sourceColor, maskColor;
ColormapPtr pmap = ScreenPriv->pInstalledMap;
if (!pmap)
return;
sourceColor.red = pCurs->foreRed;
sourceColor.green = pCurs->foreGreen;
sourceColor.blue = pCurs->foreBlue;
FakeAllocColor(pmap, &sourceColor);
maskColor.red = pCurs->backRed;
maskColor.green = pCurs->backGreen;
maskColor.blue = pCurs->backBlue;
FakeAllocColor(pmap, &maskColor);
FakeFreeColor(pmap, sourceColor.pixel);
FakeFreeColor(pmap, maskColor.pixel);
(*infoPtr->SetCursorColors) (infoPtr->pScrn,
maskColor.pixel, sourceColor.pixel);
}
else { /* Pass colors in 8-8-8 RGB format */
(*infoPtr->SetCursorColors) (infoPtr->pScrn,
(pCurs->backBlue >> 8) |
((pCurs->backGreen >> 8) << 8) |
((pCurs->backRed >> 8) << 16),
(pCurs->foreBlue >> 8) |
((pCurs->foreGreen >> 8) << 8) |
((pCurs->foreRed >> 8) << 16)
);
}
}
/* These functions assume that MaxWidth is a multiple of 32 */
static unsigned char *
RealizeCursorInterleave0(xf86CursorInfoPtr infoPtr, CursorPtr pCurs)
{
SCANLINE *SrcS, *SrcM, *DstS, *DstM;
SCANLINE *pSrc, *pMsk;
unsigned char *mem;
int size = (infoPtr->MaxWidth * infoPtr->MaxHeight) >> 2;
int SrcPitch, DstPitch, Pitch, y, x;
/* how many words are in the source or mask */
int words = size / (CUR_BITMAP_SCANLINE_PAD / 4);
if (!(mem = calloc(1, size)))
return NULL;
if (pCurs == NullCursor) {
if (infoPtr->Flags & HARDWARE_CURSOR_INVERT_MASK) {
DstM = (SCANLINE *) mem;
if (!(infoPtr->Flags & HARDWARE_CURSOR_SWAP_SOURCE_AND_MASK))
DstM += words;
memset(DstM, -1, words * sizeof(SCANLINE));
}
return mem;
}
/* SrcPitch == the number of scanlines wide the cursor image is */
SrcPitch = (pCurs->bits->width + (BITMAP_SCANLINE_PAD - 1)) >>
CUR_LOG2_BITMAP_PAD;
/* DstPitch is the width of the hw cursor in scanlines */
DstPitch = infoPtr->MaxWidth >> CUR_LOG2_BITMAP_PAD;
Pitch = SrcPitch < DstPitch ? SrcPitch : DstPitch;
SrcS = (SCANLINE *) pCurs->bits->source;
SrcM = (SCANLINE *) pCurs->bits->mask;
DstS = (SCANLINE *) mem;
DstM = DstS + words;
if (infoPtr->Flags & HARDWARE_CURSOR_SWAP_SOURCE_AND_MASK) {
SCANLINE *tmp;
tmp = DstS;
DstS = DstM;
DstM = tmp;
}
if (infoPtr->Flags & HARDWARE_CURSOR_AND_SOURCE_WITH_MASK) {
for (y = pCurs->bits->height, pSrc = DstS, pMsk = DstM;
y--;
pSrc += DstPitch, pMsk += DstPitch, SrcS += SrcPitch, SrcM +=
SrcPitch) {
for (x = 0; x < Pitch; x++) {
pSrc[x] = SrcS[x] & SrcM[x];
pMsk[x] = SrcM[x];
}
}
}
else {
for (y = pCurs->bits->height, pSrc = DstS, pMsk = DstM;
y--;
pSrc += DstPitch, pMsk += DstPitch, SrcS += SrcPitch, SrcM +=
SrcPitch) {
for (x = 0; x < Pitch; x++) {
pSrc[x] = SrcS[x];
pMsk[x] = SrcM[x];
}
}
}
if (infoPtr->Flags & HARDWARE_CURSOR_NIBBLE_SWAPPED) {
int count = size;
unsigned char *pntr1 = (unsigned char *) DstS;
unsigned char *pntr2 = (unsigned char *) DstM;
unsigned char a, b;
while (count) {
a = *pntr1;
b = *pntr2;
*pntr1 = ((a & 0xF0) >> 4) | ((a & 0x0F) << 4);
*pntr2 = ((b & 0xF0) >> 4) | ((b & 0x0F) << 4);
pntr1++;
pntr2++;
count -= 2;
}
}
/*
* Must be _after_ HARDWARE_CURSOR_AND_SOURCE_WITH_MASK to avoid wiping
* out entire source mask.
*/
if (infoPtr->Flags & HARDWARE_CURSOR_INVERT_MASK) {
int count = words;
SCANLINE *pntr = DstM;
while (count--) {
*pntr = ~(*pntr);
pntr++;
}
}
if (infoPtr->Flags & HARDWARE_CURSOR_BIT_ORDER_MSBFIRST) {
for (y = pCurs->bits->height, pSrc = DstS, pMsk = DstM;
y--; pSrc += DstPitch, pMsk += DstPitch) {
for (x = 0; x < Pitch; x++) {
pSrc[x] = REVERSE_BIT_ORDER(pSrc[x]);
pMsk[x] = REVERSE_BIT_ORDER(pMsk[x]);
}
}
}
return mem;
}
static unsigned char *
RealizeCursorInterleave1(xf86CursorInfoPtr infoPtr, CursorPtr pCurs)
{
unsigned char *DstS, *DstM;
unsigned char *pntr;
unsigned char *mem, *mem2;
int count;
int size = (infoPtr->MaxWidth * infoPtr->MaxHeight) >> 2;
/* Realize the cursor without interleaving */
if (!(mem2 = RealizeCursorInterleave0(infoPtr, pCurs)))
return NULL;
if (!(mem = calloc(1, size))) {
free(mem2);
return NULL;
}
/* 1 bit interleave */
DstS = mem2;
DstM = DstS + (size >> 1);
pntr = mem;
count = size;
while (count) {
*pntr++ = ((*DstS & 0x01)) | ((*DstM & 0x01) << 1) |
((*DstS & 0x02) << 1) | ((*DstM & 0x02) << 2) |
((*DstS & 0x04) << 2) | ((*DstM & 0x04) << 3) |
((*DstS & 0x08) << 3) | ((*DstM & 0x08) << 4);
*pntr++ = ((*DstS & 0x10) >> 4) | ((*DstM & 0x10) >> 3) |
((*DstS & 0x20) >> 3) | ((*DstM & 0x20) >> 2) |
((*DstS & 0x40) >> 2) | ((*DstM & 0x40) >> 1) |
((*DstS & 0x80) >> 1) | ((*DstM & 0x80));
DstS++;
DstM++;
count -= 2;
}
/* Free the uninterleaved cursor */
free(mem2);
return mem;
}
static unsigned char *
RealizeCursorInterleave8(xf86CursorInfoPtr infoPtr, CursorPtr pCurs)
{
unsigned char *DstS, *DstM;
unsigned char *pntr;
unsigned char *mem, *mem2;
int count;
int size = (infoPtr->MaxWidth * infoPtr->MaxHeight) >> 2;
/* Realize the cursor without interleaving */
if (!(mem2 = RealizeCursorInterleave0(infoPtr, pCurs)))
return NULL;
if (!(mem = calloc(1, size))) {
free(mem2);
return NULL;
}
/* 8 bit interleave */
DstS = mem2;
DstM = DstS + (size >> 1);
pntr = mem;
count = size;
while (count) {
*pntr++ = *DstS++;
*pntr++ = *DstM++;
count -= 2;
}
/* Free the uninterleaved cursor */
free(mem2);
return mem;
}
static unsigned char *
RealizeCursorInterleave16(xf86CursorInfoPtr infoPtr, CursorPtr pCurs)
{
unsigned short *DstS, *DstM;
unsigned short *pntr;
unsigned char *mem, *mem2;
int count;
int size = (infoPtr->MaxWidth * infoPtr->MaxHeight) >> 2;
/* Realize the cursor without interleaving */
if (!(mem2 = RealizeCursorInterleave0(infoPtr, pCurs)))
return NULL;
if (!(mem = calloc(1, size))) {
free(mem2);
return NULL;
}
/* 16 bit interleave */
DstS = (void *) mem2;
DstM = DstS + (size >> 2);
pntr = (void *) mem;
count = (size >> 1);
while (count) {
*pntr++ = *DstS++;
*pntr++ = *DstM++;
count -= 2;
}
/* Free the uninterleaved cursor */
free(mem2);
return mem;
}
static unsigned char *
RealizeCursorInterleave32(xf86CursorInfoPtr infoPtr, CursorPtr pCurs)
{
CARD32 *DstS, *DstM;
CARD32 *pntr;
unsigned char *mem, *mem2;
int count;
int size = (infoPtr->MaxWidth * infoPtr->MaxHeight) >> 2;
/* Realize the cursor without interleaving */
if (!(mem2 = RealizeCursorInterleave0(infoPtr, pCurs)))
return NULL;
if (!(mem = calloc(1, size))) {
free(mem2);
return NULL;
}
/* 32 bit interleave */
DstS = (void *) mem2;
DstM = DstS + (size >> 3);
pntr = (void *) mem;
count = (size >> 2);
while (count) {
*pntr++ = *DstS++;
*pntr++ = *DstM++;
count -= 2;
}
/* Free the uninterleaved cursor */
free(mem2);
return mem;
}
static unsigned char *
RealizeCursorInterleave64(xf86CursorInfoPtr infoPtr, CursorPtr pCurs)
{
CARD32 *DstS, *DstM;
CARD32 *pntr;
unsigned char *mem, *mem2;
int count;
int size = (infoPtr->MaxWidth * infoPtr->MaxHeight) >> 2;
/* Realize the cursor without interleaving */
if (!(mem2 = RealizeCursorInterleave0(infoPtr, pCurs)))
return NULL;
if (!(mem = calloc(1, size))) {
free(mem2);
return NULL;
}
/* 64 bit interleave */
DstS = (void *) mem2;
DstM = DstS + (size >> 3);
pntr = (void *) mem;
count = (size >> 2);
while (count) {
*pntr++ = *DstS++;
*pntr++ = *DstS++;
*pntr++ = *DstM++;
*pntr++ = *DstM++;
count -= 4;
}
/* Free the uninterleaved cursor */
free(mem2);
return mem;
}
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