/* * Copyright 1997-2001 by Alan Hourihane * * Permission to use, copy, modify, distribute, and sell this software and its * documentation for any purpose is hereby granted without fee, provided that * the above copyright notice appear in all copies and that both that * copyright notice and this permission notice appear in supporting * documentation, and that the name of Alan Hourihane not be used in * advertising or publicity pertaining to distribution of the software without * specific, written prior permission. Alan Hourihane makes no representations * about the suitability of this software for any purpose. It is provided * "as is" without express or implied warranty. * * ALAN HOURIHANE DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO * EVENT SHALL ALAN HOURIHANE BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, * DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. * * Authors: Alan Hourihane, * Dirk Hohndel, * Stefan Dirsch, * Helmut Fahrion, * * this work is sponsored by S.u.S.E. GmbH, Fuerth, Elsa GmbH, Aachen and * Siemens Nixdorf Informationssysteme */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include "xf86.h" #include "xf86_OSproc.h" #include "xf86Pci.h" #include "glint_regs.h" #include "glint.h" static unsigned long PM2VDAC_CalculateClock ( unsigned long reqclock, /* In kHz units */ unsigned long refclock, /* In kHz units */ unsigned char *prescale, /* ClkPreScale */ unsigned char *feedback, /* ClkFeedBackScale */ unsigned char *postscale /* ClkPostScale */ ) { int f, pre, post; unsigned long freq; long freqerr = 1000; unsigned long actualclock = 0; unsigned char divide[5] = { 1, 2, 4, 8, 16 }; for (f=1;f<256;f++) { for (pre=1;pre<256;pre++) { for (post=0;post<2;post++) { freq = ((refclock * f) / (pre * (1 << divide[post]))); if ((reqclock > freq - freqerr)&&(reqclock < freq + freqerr)){ freqerr = (reqclock > freq) ? reqclock - freq : freq - reqclock; *feedback = f; *prescale = pre; *postscale = post; actualclock = freq; } } } } return(actualclock); } static void Permedia2VPreInitSecondary(ScrnInfoPtr pScrn) { GLINTPtr pGlint = GLINTPTR(pScrn); /* disable MCLK */ Permedia2vOutIndReg(pScrn, PM2VDACRDMClkControl, 0x00, 0); /* boot new mclk values */ Permedia2vOutIndReg(pScrn, PM2VDACRDMClkPreScale, 0x00, 0x09); Permedia2vOutIndReg(pScrn, PM2VDACRDMClkFeedbackScale, 0x00, 0x58); Permedia2vOutIndReg(pScrn, PM2VDACRDMClkPostScale, 0x00, 0x01); /* re-enable MCLK */ Permedia2vOutIndReg(pScrn, PM2VDACRDMClkControl, 0x00, 1); /* spin until locked MCLK */ while ( (Permedia2vInIndReg(pScrn, PM2VDACRDMClkControl) & 0x2) == 0); /* Now re-boot the SGRAM's */ GLINT_SLOW_WRITE_REG(0xe6002021,PMMemConfig); GLINT_SLOW_WRITE_REG(0x00000020,PMBootAddress); } void Permedia2VPreInit(ScrnInfoPtr pScrn) { GLINTPtr pGlint = GLINTPTR(pScrn); if (IS_JPRO) { /* Appian Jeronimo Pro 4x8mb (pm2v version) */ /* BIOS doesn't initialize the secondary heads, so we need to */ xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Appian Jeronimo Pro 4x8mb board detected and initialized.\n"); Permedia2VPreInitSecondary(pScrn); } #if defined(__alpha__) /* * On Alpha, we have to init secondary PM2V cards, since * int10 cannot be run on the OEMed cards with VGA disable * jumpers. */ if (!xf86IsPrimaryPci(pGlint->PciInfo)) { if ( IS_QPM2V ) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "PM2V secondary: initializing\n"); Permedia2VPreInitSecondary(pScrn); } } #endif /* __alpha__ */ } Bool Permedia2VInit(ScrnInfoPtr pScrn, DisplayModePtr mode) { GLINTPtr pGlint = GLINTPTR(pScrn); GLINTRegPtr pReg = &pGlint->ModeReg[0]; CARD32 temp1, temp2, temp3, temp4; temp1 = 0; temp2 = 0; #if X_BYTE_ORDER == X_BIG_ENDIAN switch (pGlint->HwBpp) { case 8: case 24: temp1 = 0x00; temp2 = 0x00; break; case 15: case 16: temp1 = 0x02; temp2 = 0x02; break; case 32: temp1 = 0x01; temp2 = 0x01; break; default: break; }; #endif /* BIG_ENDIAN */ pReg->glintRegs[Aperture0 >> 3] = temp1; pReg->glintRegs[Aperture1 >> 3] = temp2; pReg->glintRegs[PMFramebufferWriteMask >> 3] = 0xFFFFFFFF; pReg->glintRegs[PMBypassWriteMask >> 3] = 0xFFFFFFFF; pReg->glintRegs[DFIFODis >> 3] = 0; pReg->glintRegs[FIFODis >> 3] = 1; if (pGlint->UseBlockWrite) pReg->glintRegs[PMMemConfig >> 3] = GLINT_READ_REG(PMMemConfig) | 1<<21; temp1 = mode->CrtcHSyncStart - mode->CrtcHDisplay; temp2 = mode->CrtcVSyncStart - mode->CrtcVDisplay; temp3 = mode->CrtcHSyncEnd - mode->CrtcHSyncStart; temp4 = mode->CrtcVSyncEnd - mode->CrtcVSyncStart; pReg->glintRegs[PMHTotal >> 3] = Shiftbpp(pScrn,mode->CrtcHTotal); pReg->glintRegs[PMHsEnd >> 3] = Shiftbpp(pScrn, temp1 + temp3); pReg->glintRegs[PMHsStart >> 3] = Shiftbpp(pScrn, temp1); pReg->glintRegs[PMHbEnd >> 3] = Shiftbpp(pScrn,mode->CrtcHTotal-mode->CrtcHDisplay); pReg->glintRegs[PMScreenStride >> 3] = Shiftbpp(pScrn,pScrn->displayWidth>>1); pReg->glintRegs[PMVTotal >> 3] = mode->CrtcVTotal; pReg->glintRegs[PMVsEnd >> 3] = temp2 + temp4; pReg->glintRegs[PMVsStart >> 3] = temp2; pReg->glintRegs[PMVbEnd >> 3] = mode->CrtcVTotal - mode->CrtcVDisplay; /* The hw cursor needs /VSYNC to recognize vert retrace. We'll stick both sync lines to active low here and if needed invert them using the RAMDAC's RDSyncControl below. */ pReg->glintRegs[PMVideoControl >> 3] = (1 << 5) | (1 << 3) | 1; /* We stick the RAMDAC into 64bit mode */ /* And reduce the horizontal timings and clock by half */ pReg->glintRegs[PMVideoControl >> 3] |= 1<<16; pReg->glintRegs[PMHTotal >> 3] >>= 1; pReg->glintRegs[PMHsEnd >> 3] >>= 1; pReg->glintRegs[PMHsStart >> 3] >>= 1; pReg->glintRegs[PMHbEnd >> 3] >>= 1; pReg->glintRegs[VClkCtl >> 3] = (GLINT_READ_REG(VClkCtl) & 0xFFFFFFFC); pReg->glintRegs[PMScreenBase >> 3] = 0; pReg->glintRegs[PMHTotal >> 3] -= 1; pReg->glintRegs[PMHsStart >> 3] -= 1; /* PMHsStart */ pReg->glintRegs[PMVTotal >> 3] -= 1; /* PMVTotal */ pReg->glintRegs[ChipConfig >> 3] = GLINT_READ_REG(ChipConfig) & 0xFFFFFFDD; pReg->DacRegs[PM2VDACRDDACControl] = 0x00; { /* Get the programmable clock values */ unsigned char m,n,p; (void) PM2VDAC_CalculateClock(mode->Clock/2,pGlint->RefClock, &m,&n,&p); pReg->DacRegs[PM2VDACRDDClk0PreScale] = m; pReg->DacRegs[PM2VDACRDDClk0FeedbackScale] = n; pReg->DacRegs[PM2VDACRDDClk0PostScale] = p; } pReg->glintRegs[PM2VDACRDIndexControl >> 3] = 0x00; if (pScrn->rgbBits == 8) pReg->DacRegs[PM2VDACRDMiscControl] = 0x01; /* 8bit DAC */ else pReg->DacRegs[PM2VDACRDMiscControl] = 0x00; /* 6bit DAC */ pReg->DacRegs[PM2VDACRDSyncControl] = 0x00; if (mode->Flags & V_PHSYNC) pReg->DacRegs[PM2VDACRDSyncControl] |= 0x01; /* invert hsync */ if (mode->Flags & V_PVSYNC) pReg->DacRegs[PM2VDACRDSyncControl] |= 0x08; /* invert vsync */ switch (pScrn->bitsPerPixel) { case 8: pReg->DacRegs[PM2VDACRDPixelSize] = 0x00; pReg->DacRegs[PM2VDACRDColorFormat] = 0x2E; break; case 16: pReg->DacRegs[PM2VDACRDMiscControl] |= 0x08; pReg->DacRegs[PM2VDACRDPixelSize] = 0x01; if (pScrn->depth == 15) pReg->DacRegs[PM2VDACRDColorFormat] = 0x61; else pReg->DacRegs[PM2VDACRDColorFormat] = 0x70; break; case 24: pReg->DacRegs[PM2VDACRDMiscControl] |= 0x08; pReg->DacRegs[PM2VDACRDPixelSize] = 0x04; pReg->DacRegs[PM2VDACRDColorFormat] = 0x60; break; case 32: pReg->DacRegs[PM2VDACRDMiscControl] |= 0x08; pReg->DacRegs[PM2VDACRDPixelSize] = 0x02; pReg->DacRegs[PM2VDACRDColorFormat] = 0x20; if (pScrn->overlayFlags & OVERLAY_8_32_PLANAR) { pReg->DacRegs[PM2VDACRDMiscControl] |= 0x18; pReg->DacRegs[PM2VDACRDOverlayKey] = pScrn->colorKey; } break; } return(TRUE); } void Permedia2VSave(ScrnInfoPtr pScrn, GLINTRegPtr glintReg) { GLINTPtr pGlint = GLINTPTR(pScrn); int i; /* We can't rely on the vgahw layer copying the font information * back properly, due to problems with MMIO access to VGA space * so we memcpy the information */ memcpy((CARD8*)pGlint->VGAdata,(CARD8*)pGlint->FbBase, 65536); glintReg->glintRegs[ChipConfig >> 3] = GLINT_READ_REG(ChipConfig); glintReg->glintRegs[Aperture0 >> 3] = GLINT_READ_REG(Aperture0); glintReg->glintRegs[Aperture1 >> 3] = GLINT_READ_REG(Aperture1); glintReg->glintRegs[PMFramebufferWriteMask >> 3] = GLINT_READ_REG(PMFramebufferWriteMask); glintReg->glintRegs[PMBypassWriteMask >> 3] = GLINT_READ_REG(PMBypassWriteMask); glintReg->glintRegs[DFIFODis >> 3] = GLINT_READ_REG(DFIFODis); glintReg->glintRegs[FIFODis >> 3] = GLINT_READ_REG(FIFODis); /* We only muck about with PMMemConfig, if user wants to */ if (pGlint->UseBlockWrite) glintReg->glintRegs[PMMemConfig >> 3] = GLINT_READ_REG(PMMemConfig); glintReg->glintRegs[PMHTotal >> 3] = GLINT_READ_REG(PMHTotal); glintReg->glintRegs[PMHbEnd >> 3] = GLINT_READ_REG(PMHbEnd); glintReg->glintRegs[PMHbEnd >> 3] = GLINT_READ_REG(PMHgEnd); glintReg->glintRegs[PMScreenStride >> 3] = GLINT_READ_REG(PMScreenStride); glintReg->glintRegs[PMHsStart >> 3] = GLINT_READ_REG(PMHsStart); glintReg->glintRegs[PMHsEnd >> 3] = GLINT_READ_REG(PMHsEnd); glintReg->glintRegs[PMVTotal >> 3] = GLINT_READ_REG(PMVTotal); glintReg->glintRegs[PMVbEnd >> 3] = GLINT_READ_REG(PMVbEnd); glintReg->glintRegs[PMVsStart >> 3] = GLINT_READ_REG(PMVsStart); glintReg->glintRegs[PMVsEnd >> 3] = GLINT_READ_REG(PMVsEnd); glintReg->glintRegs[PMScreenBase >> 3] = GLINT_READ_REG(PMScreenBase); glintReg->glintRegs[PMVideoControl >> 3] = GLINT_READ_REG(PMVideoControl); glintReg->glintRegs[VClkCtl >> 3] = GLINT_READ_REG(VClkCtl); for (i=0;i<768;i++) { Permedia2ReadAddress(pScrn, i); glintReg->cmap[i] = Permedia2ReadData(pScrn); } glintReg->glintRegs[PM2VDACRDIndexControl >> 3] = GLINT_READ_REG(PM2VDACRDIndexControl); glintReg->DacRegs[PM2VDACRDOverlayKey] = Permedia2vInIndReg(pScrn, PM2VDACRDOverlayKey); glintReg->DacRegs[PM2VDACRDSyncControl] = Permedia2vInIndReg(pScrn, PM2VDACRDSyncControl); glintReg->DacRegs[PM2VDACRDMiscControl] = Permedia2vInIndReg(pScrn, PM2VDACRDMiscControl); glintReg->DacRegs[PM2VDACRDDACControl] = Permedia2vInIndReg(pScrn, PM2VDACRDDACControl); glintReg->DacRegs[PM2VDACRDPixelSize] = Permedia2vInIndReg(pScrn, PM2VDACRDPixelSize); glintReg->DacRegs[PM2VDACRDColorFormat] = Permedia2vInIndReg(pScrn, PM2VDACRDColorFormat); glintReg->DacRegs[PM2VDACRDDClk0PreScale] = Permedia2vInIndReg(pScrn, PM2VDACRDDClk0PreScale); glintReg->DacRegs[PM2VDACRDDClk0FeedbackScale] = Permedia2vInIndReg(pScrn, PM2VDACRDDClk0FeedbackScale); glintReg->DacRegs[PM2VDACRDDClk0PostScale] = Permedia2vInIndReg(pScrn, PM2VDACRDDClk0PostScale); } void Permedia2VRestore(ScrnInfoPtr pScrn, GLINTRegPtr glintReg) { GLINTPtr pGlint = GLINTPTR(pScrn); CARD32 temp; int i; /* We can't rely on the vgahw layer copying the font information * back properly, due to problems with MMIO access to VGA space * so we memcpy the information */ if (pGlint->STATE) memcpy((CARD8*)pGlint->FbBase,(CARD8*)pGlint->VGAdata, 65536); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[ChipConfig >> 3], ChipConfig); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[Aperture0 >> 3], Aperture0); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[Aperture1 >> 3], Aperture1); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMFramebufferWriteMask >> 3], PMFramebufferWriteMask); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMBypassWriteMask >> 3], PMBypassWriteMask); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[DFIFODis >> 3], DFIFODis); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[FIFODis >> 3], FIFODis); /* We only muck about with PMMemConfig, if user wants to */ if (pGlint->UseBlockWrite) GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMMemConfig >> 3],PMMemConfig); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMVideoControl >> 3], PMVideoControl); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMHbEnd >> 3], PMHgEnd); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMScreenBase >> 3], PMScreenBase); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[VClkCtl >> 3], VClkCtl); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMScreenStride >> 3], PMScreenStride); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMHTotal >> 3], PMHTotal); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMHbEnd >> 3], PMHbEnd); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMHsStart >> 3], PMHsStart); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMHsEnd >> 3], PMHsEnd); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMVTotal >> 3], PMVTotal); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMVbEnd >> 3], PMVbEnd); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMVsStart >> 3], PMVsStart); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PMVsEnd >> 3], PMVsEnd); GLINT_SLOW_WRITE_REG(glintReg->glintRegs[PM2VDACRDIndexControl >> 3], PM2VDACRDIndexControl); Permedia2vOutIndReg(pScrn, PM2VDACRDOverlayKey, 0x00, glintReg->DacRegs[PM2VDACRDOverlayKey]); Permedia2vOutIndReg(pScrn, PM2VDACRDSyncControl, 0x00, glintReg->DacRegs[PM2VDACRDSyncControl]); Permedia2vOutIndReg(pScrn, PM2VDACRDMiscControl, 0x00, glintReg->DacRegs[PM2VDACRDMiscControl]); Permedia2vOutIndReg(pScrn, PM2VDACRDDACControl, 0x00, glintReg->DacRegs[PM2VDACRDDACControl]); Permedia2vOutIndReg(pScrn, PM2VDACRDPixelSize, 0x00, glintReg->DacRegs[PM2VDACRDPixelSize]); Permedia2vOutIndReg(pScrn, PM2VDACRDColorFormat, 0x00, glintReg->DacRegs[PM2VDACRDColorFormat]); for (i=0;i<768;i++) { Permedia2WriteAddress(pScrn, i); Permedia2WriteData(pScrn, glintReg->cmap[i]); } temp = Permedia2vInIndReg(pScrn, PM2VDACIndexClockControl) & 0xFC; Permedia2vOutIndReg(pScrn, PM2VDACRDDClk0PreScale, 0x00, glintReg->DacRegs[PM2VDACRDDClk0PreScale]); Permedia2vOutIndReg(pScrn, PM2VDACRDDClk0FeedbackScale, 0x00, glintReg->DacRegs[PM2VDACRDDClk0FeedbackScale]); Permedia2vOutIndReg(pScrn, PM2VDACRDDClk0PostScale, 0x00, glintReg->DacRegs[PM2VDACRDDClk0PostScale]); Permedia2vOutIndReg(pScrn, PM2VDACIndexClockControl, 0x00, temp|0x03); } static void Permedia2vShowCursor(ScrnInfoPtr pScrn) { /* Enable cursor - X11 mode */ Permedia2vOutIndReg(pScrn, PM2VDACRDCursorMode, 0x00, 0x11); } static void Permedia2vLoadCursorCallback(ScrnInfoPtr pScrn); static void Permedia2vHideCursor(ScrnInfoPtr pScrn) { GLINTPtr pGlint = GLINTPTR(pScrn); /* Disable cursor - X11 mode */ Permedia2vOutIndReg(pScrn, PM2VDACRDCursorMode, 0x00, 0x10); /* * For some reason, we need to clear the image as well as disable * the cursor on PM2V, but not on PM3. The problem is noticeable * only when running multi-head, as you can see the cursor get * "left behind" on the screen it is leaving... */ if (pGlint->Chipset == PCI_VENDOR_3DLABS_CHIP_PERMEDIA2V) { memset(pGlint->HardwareCursorPattern, 0, 1024); pGlint->LoadCursorCallback = Permedia2vLoadCursorCallback; } } static void Permedia2vLoadCursorCallback( ScrnInfoPtr pScrn ) { GLINTPtr pGlint = GLINTPTR(pScrn); int i; for (i=0; i<1024; i++) Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPattern+i, 0x00, pGlint->HardwareCursorPattern[i]); pGlint->LoadCursorCallback = NULL; } static void Permedia2vLoadCursorImage( ScrnInfoPtr pScrn, unsigned char *src ) { GLINTPtr pGlint = GLINTPTR(pScrn); int i; for (i=0; i<1024; i++) pGlint->HardwareCursorPattern[i] = *(src++); pGlint->LoadCursorCallback = Permedia2vLoadCursorCallback; } static void Permedia2vSetCursorPosition( ScrnInfoPtr pScrn, int x, int y ) { x += 64; y += 64; /* Output position - "only" 11 bits of location documented */ Permedia2vOutIndReg(pScrn, PM2VDACRDCursorHotSpotX, 0x00, 0x3f); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorHotSpotY, 0x00, 0x3f); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorXLow, 0x00, x & 0xFF); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorXHigh, 0x00, (x>>8) & 0x0F); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorYLow, 0x00, y & 0xFF); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorYHigh, 0x00, (y>>8) & 0x0F); Permedia2vOutIndReg(pScrn, PM2DACCursorControl, 0x00, 0x00); } static void Permedia2vCursorColorCallback( ScrnInfoPtr pScrn ) { GLINTPtr pGlint = GLINTPTR(pScrn); int fg = pGlint->FGCursor; int bg = pGlint->BGCursor; if ((pGlint->Chipset == PCI_VENDOR_3DLABS_CHIP_PERMEDIA3) || ((pGlint->Chipset == PCI_VENDOR_3DLABS_CHIP_GAMMA) && (pGlint->MultiChip == PCI_CHIP_3DLABS_PERMEDIA3)) ) { /* PM3 uses last 2 indexes into hardware cursor palette fg first...*/ Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+39, 0x00, (fg>>16)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+40, 0x00, (fg>>8)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+41, 0x00, fg & 0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+42, 0x00, (bg>>16)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+43, 0x00, (bg>>8)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+44, 0x00, bg & 0xff); } else { /* PM2v uses first 2 indexes into hardware cursor palette bg first...*/ Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+0, 0x00, (bg>>16)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+1, 0x00, (bg>>8)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+2, 0x00, bg & 0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+3, 0x00, (fg>>16)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+4, 0x00, (fg>>8)&0xff); Permedia2vOutIndReg(pScrn, PM2VDACRDCursorPalette+5, 0x00, fg & 0xff); } pGlint->CursorColorCallback = NULL; } static void Permedia2vSetCursorColors( ScrnInfoPtr pScrn, int bg, int fg ) { GLINTPtr pGlint = GLINTPTR(pScrn); pGlint->FGCursor = fg; pGlint->BGCursor = bg; pGlint->CursorColorCallback = Permedia2vCursorColorCallback; } static Bool Permedia2vUseHWCursor(ScreenPtr pScr, CursorPtr pCurs) { return TRUE; } Bool Permedia2vHWCursorInit(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86ScreenToScrn(pScreen); GLINTPtr pGlint = GLINTPTR(pScrn); xf86CursorInfoPtr infoPtr; infoPtr = xf86CreateCursorInfoRec(); if(!infoPtr) return FALSE; pGlint->CursorInfoRec = infoPtr; infoPtr->MaxWidth = 64; infoPtr->MaxHeight = 64; infoPtr->Flags = HARDWARE_CURSOR_TRUECOLOR_AT_8BPP | #if X_BYTE_ORDER == X_BIG_ENDIAN HARDWARE_CURSOR_BIT_ORDER_MSBFIRST | #endif HARDWARE_CURSOR_SOURCE_MASK_INTERLEAVE_1; infoPtr->SetCursorColors = Permedia2vSetCursorColors; infoPtr->SetCursorPosition = Permedia2vSetCursorPosition; infoPtr->LoadCursorImage = Permedia2vLoadCursorImage; infoPtr->HideCursor = Permedia2vHideCursor; infoPtr->ShowCursor = Permedia2vShowCursor; infoPtr->UseHWCursor = Permedia2vUseHWCursor; return(xf86InitCursor(pScreen, infoPtr)); }