#ifdef HAVE_XORG_CONFIG_H #include #endif #include #include "misc.h" #include "xf86.h" #include "xf86_OSproc.h" #include #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" #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 = xf86Screens[pScreen->myNum]; return TRUE; } void xf86SetCursor(ScreenPtr pScreen, CursorPtr pCurs, int x, int y) { xf86CursorScreenPtr ScreenPriv = pScreen->devPrivates[xf86CursorScreenIndex].ptr; xf86CursorInfoPtr infoPtr = ScreenPriv->CursorInfoPtr; unsigned char *bits; if (pCurs == NullCursor) { (*infoPtr->HideCursor)(infoPtr->pScrn); return; } bits = pCurs->devPriv[pScreen->myNum]; 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); pCurs->devPriv[pScreen->myNum] = bits; } if (!(infoPtr->Flags & HARDWARE_CURSOR_UPDATE_UNHIDDEN)) (*infoPtr->HideCursor)(infoPtr->pScrn); #ifdef ARGB_CURSOR if (pCurs->bits->argb && infoPtr->LoadCursorARGB) (*infoPtr->LoadCursorARGB) (infoPtr->pScrn, pCurs); else #endif if (bits) (*infoPtr->LoadCursorImage)(infoPtr->pScrn, bits); xf86RecolorCursor(pScreen, pCurs, 1); (*infoPtr->SetCursorPosition)(infoPtr->pScrn, x, y); (*infoPtr->ShowCursor)(infoPtr->pScrn); } void xf86SetTransparentCursor(ScreenPtr pScreen) { xf86CursorScreenPtr ScreenPriv = pScreen->devPrivates[xf86CursorScreenIndex].ptr; 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 = pScreen->devPrivates[xf86CursorScreenIndex].ptr; 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 = pScreen->devPrivates[xf86CursorScreenIndex].ptr; 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 = xcalloc(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; (void)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 = xcalloc(1, size))) { xfree(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 */ xfree(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 = xcalloc(1, size))) { xfree(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 */ xfree(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 = xcalloc(1, size))) { xfree(mem2); return NULL; } /* 16 bit interleave */ DstS = (pointer)mem2; DstM = DstS + (size >> 2); pntr = (pointer)mem; count = (size >> 1); while (count) { *pntr++ = *DstS++; *pntr++ = *DstM++; count-=2; } /* Free the uninterleaved cursor */ xfree(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 = xcalloc(1, size))) { xfree(mem2); return NULL; } /* 32 bit interleave */ DstS = (pointer)mem2; DstM = DstS + (size >> 3); pntr = (pointer)mem; count = (size >> 2); while (count) { *pntr++ = *DstS++; *pntr++ = *DstM++; count-=2; } /* Free the uninterleaved cursor */ xfree(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 = xcalloc(1, size))) { xfree(mem2); return NULL; } /* 64 bit interleave */ DstS = (pointer)mem2; DstM = DstS + (size >> 3); pntr = (pointer)mem; count = (size >> 2); while (count) { *pntr++ = *DstS++; *pntr++ = *DstS++; *pntr++ = *DstM++; *pntr++ = *DstM++; count-=4; } /* Free the uninterleaved cursor */ xfree(mem2); return mem; }