/* * Created 1998 by David Bateman * * 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 the authors not be used in * advertising or publicity pertaining to distribution of the software without * specific, written prior permission. The authors makes no representations * about the suitability of this software for any purpose. It is provided * "as is" without express or implied warranty. * * THE AUTHORS DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS, IN NO * EVENT SHALL THE AUTHORS 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. */ /* $XFree86: xc/programs/Xserver/hw/xfree86/drivers/chips/ct_regs.c,v 1.8 2002/01/25 21:56:00 tsi Exp $ */ /* * The functions in this file are used to read/write the C&T extension register * and supply MMIO replacements of the VGA register access functions in * vgaHW.c for chips that support MMIO access (eg 69000). Unlike the MGA * chips, for instance, the C&T chipsets don't have a direct mapping between * the MMIO mapped vga registers and the PIO versions. * * In General, these are the ONLY supported way of access the video processors * registers. Exception are * * 1) chipsFindIsaDevice, where we don't know the chipset and so we don't know * if the chipset supports MMIO access to its VGA registers, and we don't * know the chips MemBase address and so can't map the VGA registers even * if the chip did support MMIO. This effectively limits the use of non-PCI * MMIO and multihead to a single card accessing 0x3D6/0x3D7. I.E. You can * only have a single C&T card in a non-PCI multihead arrangement. Also as * ISA has no method to disable I/O access to a card ISA multihead will * never be supported. * * 2) ct_Blitter.h, ct_BlitMM.h and ct_BltHiQV.h, where speed is crucial and * we know exactly whether we are using MMIO or PIO. * * 3) The 6554x 32bit DRxx in ct_cursor.c where the choice between MMIO and * PIO is made explicitly */ /* All drivers should typically include these */ #include "xf86.h" #include "xf86_OSproc.h" #include "xf86_ansic.h" /* Everything using inb/outb, etc needs "compiler.h" */ #include "compiler.h" /* Drivers for PCI hardware need this */ #include "xf86PciInfo.h" /* Drivers that need to access the PCI config space directly need this */ #include "xf86Pci.h" /* This is used for module versioning */ #include "xf86Version.h" /* Driver specific headers */ #include "ct_driver.h" #define CHIPS_MONO_STAT_1 0x3BA #define CHIPS_STAT_0 0x3BA #define CHIPS_MSS 0x3CB #define CHIPS_IOSS 0x3CD #define CHIPS_FR_INDEX 0x3D0 #define CHIPS_FR_DATA 0x3D1 #define CHIPS_MR_INDEX 0x3D2 #define CHIPS_MR_DATA 0x3D3 #define CHIPS_XR_INDEX 0x3D6 #define CHIPS_XR_DATA 0x3D7 #define CHIPS_COLOR_STAT_1 0x3DA #define CHIPS_MMIO_MONO_CRTC_INDEX 0x768 #define CHIPS_MMIO_MONO_CRTC_DATA 0x769 #define CHIPS_MMIO_MONO_STAT_1 0x774 #define CHIPS_MMIO_ATTR_INDEX 0x780 #define CHIPS_MMIO_ATTR_DATA_W 0x780 #define CHIPS_MMIO_ATTR_DATA_R 0x781 #define CHIPS_MMIO_STAT_0 0x784 #define CHIPS_MMIO_MISC_OUT_W 0x784 #define CHIPS_MMIO_SEQ_INDEX 0x788 #define CHIPS_MMIO_SEQ_DATA 0x789 #define CHIPS_MMIO_DAC_MASK 0x78C #define CHIPS_MMIO_DAC_READ_ADDR 0x78D #define CHIPS_MMIO_DAC_WRITE_ADDR 0x790 #define CHIPS_MMIO_DAC_DATA 0x791 #define CHIPS_MMIO_FEATURE_R 0x794 #define CHIPS_MMIO_MSS 0x795 #define CHIPS_MMIO_MISC_OUT_R 0x798 #define CHIPS_MMIO_IOSS 0x799 #define CHIPS_MMIO_GRAPH_INDEX 0x79C #define CHIPS_MMIO_GRAPH_DATA 0x79D #define CHIPS_MMIO_FR_INDEX 0x7A0 #define CHIPS_MMIO_FR_DATA 0x7A1 #define CHIPS_MMIO_MR_INDEX 0x7A4 #define CHIPS_MMIO_MR_DATA 0x7A5 #define CHIPS_MMIO_COLOR_CRTC_INDEX 0x7A8 #define CHIPS_MMIO_COLOR_CRTC_DATA 0x7A9 #define CHIPS_MMIO_XR_INDEX 0x7AC #define CHIPS_MMIO_XR_DATA 0x7AD #define CHIPS_MMIO_COLOR_STAT_1 0x7B4 /* * PIO Access to the C&T extension registers */ void chipsStdWriteXR(CHIPSPtr cPtr, CARD8 index, CARD8 value) { outb(cPtr->PIOBase + CHIPS_XR_INDEX, index); outb(cPtr->PIOBase + CHIPS_XR_DATA, value); } static CARD8 chipsStdReadXR(CHIPSPtr cPtr, CARD8 index) { outb(cPtr->PIOBase + CHIPS_XR_INDEX, index); return inb(cPtr->PIOBase + CHIPS_XR_DATA); } static void chipsStdWriteFR(CHIPSPtr cPtr, CARD8 index, CARD8 value) { outb(cPtr->PIOBase + CHIPS_FR_INDEX, index); outb(cPtr->PIOBase + CHIPS_FR_DATA, value); } static CARD8 chipsStdReadFR(CHIPSPtr cPtr, CARD8 index) { outb(cPtr->PIOBase + CHIPS_FR_INDEX, index); return inb(cPtr->PIOBase + CHIPS_FR_DATA); } static void chipsStdWriteMR(CHIPSPtr cPtr, CARD8 index, CARD8 value) { outb(cPtr->PIOBase + CHIPS_MR_INDEX, index); outb(cPtr->PIOBase + CHIPS_MR_DATA, value); } static CARD8 chipsStdReadMR(CHIPSPtr cPtr, CARD8 index) { outb(cPtr->PIOBase + CHIPS_MR_INDEX, index); return inb(cPtr->PIOBase + CHIPS_MR_DATA); } static void chipsStdWriteMSS(CHIPSPtr cPtr, vgaHWPtr hwp, CARD8 value) { outb(cPtr->PIOBase + CHIPS_MSS, value); } static CARD8 chipsStdReadMSS(CHIPSPtr cPtr) { return inb(cPtr->PIOBase + CHIPS_MSS); } static void chipsStdWriteIOSS(CHIPSPtr cPtr, CARD8 value) { outb(cPtr->PIOBase + CHIPS_IOSS, value); } static CARD8 chipsStdReadIOSS(CHIPSPtr cPtr) { return inb(cPtr->PIOBase + CHIPS_IOSS); } void CHIPSSetStdExtFuncs(CHIPSPtr cPtr) { cPtr->writeFR = chipsStdWriteFR; cPtr->readFR = chipsStdReadFR; cPtr->writeMR = chipsStdWriteMR; cPtr->readMR = chipsStdReadMR; cPtr->writeXR = chipsStdWriteXR; cPtr->readXR = chipsStdReadXR; cPtr->writeMSS = chipsStdWriteMSS; cPtr->readMSS = chipsStdReadMSS; cPtr->writeIOSS = chipsStdWriteIOSS; cPtr->readIOSS = chipsStdReadIOSS; } /* * MMIO Access to the C&T extension registers */ #define chipsminb(p) MMIO_IN8(cPtr->MMIOBaseVGA, (p)) #define chipsmoutb(p,v) MMIO_OUT8(cPtr->MMIOBaseVGA, (p),(v)) static void chipsMmioWriteXR(CHIPSPtr cPtr, CARD8 index, CARD8 value) { chipsmoutb(CHIPS_MMIO_XR_INDEX, index); chipsmoutb(CHIPS_MMIO_XR_DATA, value); } static CARD8 chipsMmioReadXR(CHIPSPtr cPtr, CARD8 index) { chipsmoutb(CHIPS_MMIO_XR_INDEX, index); return chipsminb(CHIPS_MMIO_XR_DATA); } static void chipsMmioWriteFR(CHIPSPtr cPtr, CARD8 index, CARD8 value) { chipsmoutb(CHIPS_MMIO_FR_INDEX, index); chipsmoutb(CHIPS_MMIO_FR_DATA, value); } static CARD8 chipsMmioReadFR(CHIPSPtr cPtr, CARD8 index) { chipsmoutb(CHIPS_MMIO_FR_INDEX, index); return chipsminb(CHIPS_MMIO_FR_DATA); } static void chipsMmioWriteMR(CHIPSPtr cPtr, CARD8 index, CARD8 value) { chipsmoutb(CHIPS_MMIO_MR_INDEX, index); chipsmoutb(CHIPS_MMIO_MR_DATA, value); } static CARD8 chipsMmioReadMR(CHIPSPtr cPtr, CARD8 index) { chipsmoutb(CHIPS_MMIO_MR_INDEX, index); return chipsminb(CHIPS_MMIO_MR_DATA); } static void chipsMmioWriteMSS(CHIPSPtr cPtr, vgaHWPtr hwp, CARD8 value) { /* 69030 MMIO Fix. * * determines which MMIOBase to use; either * Pipe A or Pipe B. -GHB */ if ((value & MSS_SHADOW) == MSS_PIPE_B) cPtr->MMIOBaseVGA = cPtr->MMIOBasePipeB; else cPtr->MMIOBaseVGA = cPtr->MMIOBasePipeA; hwp->MMIOBase = cPtr->MMIOBaseVGA; /* Since our Pipe constants don't set bit 3 of MSS, the value * written here has no effect on the hardware's behavior. It * does allow us to use the value returned by readMSS() to key * the above logic, though. -GHB */ chipsmoutb(CHIPS_MMIO_MSS, value); } static CARD8 chipsMmioReadMSS(CHIPSPtr cPtr) { return chipsminb(CHIPS_MMIO_MSS); } static void chipsMmioWriteIOSS(CHIPSPtr cPtr, CARD8 value) { chipsmoutb(CHIPS_MMIO_IOSS, value); } static CARD8 chipsMmioReadIOSS(CHIPSPtr cPtr) { return chipsminb(CHIPS_MMIO_IOSS); } void CHIPSSetMmioExtFuncs(CHIPSPtr cPtr) { cPtr->writeFR = chipsMmioWriteFR; cPtr->readFR = chipsMmioReadFR; cPtr->writeMR = chipsMmioWriteMR; cPtr->readMR = chipsMmioReadMR; cPtr->writeXR = chipsMmioWriteXR; cPtr->readXR = chipsMmioReadXR; cPtr->writeMSS = chipsMmioWriteMSS; cPtr->readMSS = chipsMmioReadMSS; cPtr->writeIOSS = chipsMmioWriteIOSS; cPtr->readIOSS = chipsMmioReadIOSS; } /* * MMIO versions of the VGA register access functions. */ #define minb(p) MMIO_IN8(hwp->MMIOBase, (p)) #define moutb(p,v) MMIO_OUT8(hwp->MMIOBase, (p),(v)) static void chipsMmioWriteCrtc(vgaHWPtr hwp, CARD8 index, CARD8 value) { if (hwp->IOBase == VGA_IOBASE_MONO) { moutb(CHIPS_MMIO_MONO_CRTC_INDEX, index); moutb(CHIPS_MMIO_MONO_CRTC_DATA, value); } else { moutb(CHIPS_MMIO_COLOR_CRTC_INDEX, index); moutb(CHIPS_MMIO_COLOR_CRTC_DATA, value); } } static CARD8 chipsMmioReadCrtc(vgaHWPtr hwp, CARD8 index) { if (hwp->IOBase == VGA_IOBASE_MONO) { moutb(CHIPS_MMIO_MONO_CRTC_INDEX, index); return minb(CHIPS_MMIO_MONO_CRTC_DATA); } else { moutb(CHIPS_MMIO_COLOR_CRTC_INDEX, index); return minb(CHIPS_MMIO_COLOR_CRTC_DATA); } } static void chipsMmioWriteGr(vgaHWPtr hwp, CARD8 index, CARD8 value) { moutb(CHIPS_MMIO_GRAPH_INDEX, index); moutb(CHIPS_MMIO_GRAPH_DATA, value); } static CARD8 chipsMmioReadGr(vgaHWPtr hwp, CARD8 index) { moutb(CHIPS_MMIO_GRAPH_INDEX, index); return minb(CHIPS_MMIO_GRAPH_DATA); } static void chipsMmioWriteSeq(vgaHWPtr hwp, CARD8 index, CARD8 value) { moutb(CHIPS_MMIO_SEQ_INDEX, index); moutb(CHIPS_MMIO_SEQ_DATA, value); } static CARD8 chipsMmioReadSeq(vgaHWPtr hwp, CARD8 index) { moutb(CHIPS_MMIO_SEQ_INDEX, index); return minb(CHIPS_MMIO_SEQ_DATA); } static void chipsMmioWriteAttr(vgaHWPtr hwp, CARD8 index, CARD8 value) { CARD8 tmp; if (hwp->paletteEnabled) index &= ~0x20; else index |= 0x20; if (hwp->IOBase == VGA_IOBASE_MONO) tmp = minb(CHIPS_MMIO_MONO_STAT_1); else tmp = minb(CHIPS_MMIO_COLOR_STAT_1); moutb(CHIPS_MMIO_ATTR_INDEX, index); moutb(CHIPS_MMIO_ATTR_DATA_W, value); } static CARD8 chipsMmioReadAttr(vgaHWPtr hwp, CARD8 index) { CARD8 tmp; if (hwp->paletteEnabled) index &= ~0x20; else index |= 0x20; if (hwp->IOBase == VGA_IOBASE_MONO) tmp = minb(CHIPS_MMIO_MONO_STAT_1); else tmp = minb(CHIPS_MMIO_COLOR_STAT_1); moutb(CHIPS_MMIO_ATTR_INDEX, index); return minb(CHIPS_MMIO_ATTR_DATA_R); } static void chipsMmioWriteMiscOut(vgaHWPtr hwp, CARD8 value) { moutb(CHIPS_MMIO_MISC_OUT_W, value); } static CARD8 chipsMmioReadMiscOut(vgaHWPtr hwp) { return minb(CHIPS_MMIO_MISC_OUT_R); } static void chipsMmioEnablePalette(vgaHWPtr hwp) { CARD8 tmp; if (hwp->IOBase == VGA_IOBASE_MONO) tmp = minb(CHIPS_MMIO_MONO_STAT_1); else tmp = minb(CHIPS_MMIO_COLOR_STAT_1); moutb(CHIPS_MMIO_ATTR_INDEX, 0x00); hwp->paletteEnabled = TRUE; } static void chipsMmioDisablePalette(vgaHWPtr hwp) { CARD8 tmp; if (hwp->IOBase == VGA_IOBASE_MONO) tmp = minb(CHIPS_MMIO_MONO_STAT_1); else tmp = minb(CHIPS_MMIO_COLOR_STAT_1); moutb(CHIPS_MMIO_ATTR_INDEX, 0x20); hwp->paletteEnabled = FALSE; } static void chipsMmioWriteDacMask(vgaHWPtr hwp, CARD8 value) { moutb(CHIPS_MMIO_DAC_MASK, value); } static CARD8 chipsMmioReadDacMask(vgaHWPtr hwp) { return minb(CHIPS_MMIO_DAC_MASK); } static void chipsMmioWriteDacReadAddr(vgaHWPtr hwp, CARD8 value) { moutb(CHIPS_MMIO_DAC_READ_ADDR, value); } static void chipsMmioWriteDacWriteAddr(vgaHWPtr hwp, CARD8 value) { moutb(CHIPS_MMIO_DAC_WRITE_ADDR, value); } static void chipsMmioWriteDacData(vgaHWPtr hwp, CARD8 value) { moutb(CHIPS_MMIO_DAC_DATA, value); } static CARD8 chipsMmioReadDacData(vgaHWPtr hwp) { return minb(CHIPS_MMIO_DAC_DATA); } static CARD8 chipsMmioReadST00(vgaHWPtr hwp) { return minb(CHIPS_MMIO_STAT_0); } static CARD8 chipsMmioReadST01(vgaHWPtr hwp) { if (hwp->IOBase == VGA_IOBASE_MONO) return minb(CHIPS_MMIO_MONO_STAT_1); else return minb(CHIPS_MMIO_COLOR_STAT_1); } static CARD8 chipsMmioReadFCR(vgaHWPtr hwp) { return minb(CHIPS_MMIO_FEATURE_R); } static void chipsMmioWriteFCR(vgaHWPtr hwp, CARD8 value) { if (hwp->IOBase == VGA_IOBASE_MONO) { moutb(CHIPS_MMIO_MONO_STAT_1, value); } else { moutb(CHIPS_MMIO_COLOR_STAT_1, value); } } void CHIPSHWSetMmioFuncs(ScrnInfoPtr pScrn, CARD8 *base, int offset) { vgaHWPtr hwp = VGAHWPTR(pScrn); hwp->writeCrtc = chipsMmioWriteCrtc; hwp->readCrtc = chipsMmioReadCrtc; hwp->writeGr = chipsMmioWriteGr; hwp->readGr = chipsMmioReadGr; hwp->writeAttr = chipsMmioWriteAttr; hwp->readAttr = chipsMmioReadAttr; hwp->writeSeq = chipsMmioWriteSeq; hwp->readSeq = chipsMmioReadSeq; hwp->writeMiscOut = chipsMmioWriteMiscOut; hwp->readMiscOut = chipsMmioReadMiscOut; hwp->enablePalette = chipsMmioEnablePalette; hwp->disablePalette = chipsMmioDisablePalette; hwp->writeDacMask = chipsMmioWriteDacMask; hwp->readDacMask = chipsMmioReadDacMask; hwp->writeDacWriteAddr = chipsMmioWriteDacWriteAddr; hwp->writeDacReadAddr = chipsMmioWriteDacReadAddr; hwp->writeDacData = chipsMmioWriteDacData; hwp->readDacData = chipsMmioReadDacData; hwp->readST00 = chipsMmioReadST00; hwp->readST01 = chipsMmioReadST01; hwp->readFCR = chipsMmioReadFCR; hwp->writeFCR = chipsMmioWriteFCR; hwp->MMIOBase = base; hwp->MMIOOffset = offset; }