/* $XConsortium: mga_driver.c /main/12 1996/10/28 05:13:26 kaleb $ */ /* * MGA Millennium (MGA2064W) with Ti3026 RAMDAC driver v.1.1 * * The driver is written without any chip documentation. All extended ports * and registers come from tracing the VESA-ROM functions. * The BitBlt Engine comes from tracing the windows BitBlt function. * * Author: Radoslaw Kapitan, Tarnow, Poland * kapitan@student.uci.agh.edu.pl * original source * * Now that MATROX has released documentation to the public, enhancing * this driver has become much easier. Nevertheless, this work continues * to be based on Radoslaw's original source * * Contributors: * Andrew van der Stock * ajv@greebo.net * additions, corrections, cleanups * * Dirk Hohndel * hohndel@XFree86.Org * integrated into XFree86-3.1.2Gg * fixed some problems with PCI probing and mapping * * David Dawes * dawes@XFree86.Org * some cleanups, and fixed some problems * * Andrew E. Mileski * aem@ott.hookup.net * RAMDAC timing, and BIOS stuff * * Leonard N. Zubkoff * lnz@dandelion.com * Support for 8MB boards, RGB Sync-on-Green, and DPMS. * Guy DESBIEF * g.desbief@aix.pacwan.net * RAMDAC MGA1064 timing, * Doug Merritt * doug@netcom.com * Fixed 32bpp hires 8MB horizontal line glitch at middle right * Niels Gram Jeppesen * Added digital screen option for first head */ /* $XFree86: xc/programs/Xserver/hw/xfree86/drivers/mga/mga_driver.c,v 1.244tsi Exp $ */ #ifdef HAVE_CONFIG_H #include "config.h" #endif /* All drivers should typically include these */ #include "xf86.h" #include "xf86_OSproc.h" #include "xf86Resources.h" /* All drivers need this */ #include "compiler.h" /* Drivers for PCI hardware need this */ #include "xf86PciInfo.h" /* All drivers initialising the SW cursor need this */ #include "mipointer.h" /* All drivers implementing backing store need this */ #include "mibstore.h" #include "micmap.h" #include "xf86DDC.h" #include "xf86RAC.h" #include "vbe.h" #include "fb.h" #include "dixstruct.h" #include "mga_reg.h" #include "mga.h" #include "mga_macros.h" #include "mga_maven.h" #ifdef USE_XAA #include "xaa.h" #endif #include "xf86cmap.h" #include "shadowfb.h" #include "fbdevhw.h" #include "cfb8_32.h" #ifdef XF86DRI #include "dri.h" #endif #include /* * Forward definitions for the functions that make up the driver. */ /* Mandatory functions */ static const OptionInfoRec * MGAAvailableOptions(int chipid, int busid); static void MGAIdentify(int flags); static Bool MGAPciProbe(DriverPtr drv, int entity_num, struct pci_device * dev, intptr_t match_data); static Bool MGAPreInit(ScrnInfoPtr pScrn, int flags); static Bool MGAScreenInit(int Index, ScreenPtr pScreen, int argc, char **argv); static Bool MGAEnterVT(int scrnIndex, int flags); static Bool MGAEnterVTFBDev(int scrnIndex, int flags); static void MGALeaveVT(int scrnIndex, int flags); static Bool MGACloseScreen(int scrnIndex, ScreenPtr pScreen); static Bool MGASaveScreen(ScreenPtr pScreen, int mode); static Bool MGASaveScreenCrtc2(ScreenPtr pScreen, int mode); /* This shouldn't be needed since RAC will disable all I/O for MGA cards. */ #ifdef DISABLE_VGA_IO static void VgaIOSave(int i, void *arg); static void VgaIORestore(int i, void *arg); #endif /* Optional functions */ static void MGAFreeScreen(int scrnIndex, int flags); static ModeStatus MGAValidMode(int scrnIndex, DisplayModePtr mode, Bool verbose, int flags); /* Internally used functions */ static Bool MGAMapMem(ScrnInfoPtr pScrn); static Bool MGAUnmapMem(ScrnInfoPtr pScrn); static void MGASave(ScrnInfoPtr pScrn); static void MGARestore(ScrnInfoPtr pScrn); static Bool MGAModeInit(ScrnInfoPtr pScrn, DisplayModePtr mode); static void MGABlockHandler(int, pointer, pointer, pointer); static void MGAG100BlackMagic(ScrnInfoPtr pScrn); static int MGAEntityIndex = -1; #include "mga_merge.h" static const struct mga_device_attributes attribs[8] = { /* 2064 */ [0] = { 1, 0, 0, 1, 0, 0, 0, 0, old_BARs, (BLK_OPAQUE_EXPANSION | FASTBLT_BUG | USE_LINEAR_EXPANSION) }, /* 1064 */ [1] = { 0, 1, 0, 0, 1, 0, 0, 0, probe_BARs, (USE_LINEAR_EXPANSION) }, /* 2164, 2164 AGP */ [2] = { 1, 0, 0, 1, 0, 0, 0, 0, new_BARs, (BLK_OPAQUE_EXPANSION | TRANSC_SOLID_FILL | USE_RECTS_FOR_LINES | USE_LINEAR_EXPANSION) }, /* G100 */ [3] = { 0, 1, 0, 0, 1, 0, 0, 0, new_BARs, (MGA_NO_PLANEMASK | USE_LINEAR_EXPANSION) }, /* G200 */ [4] = { 0, 1, 0, 0, 1, 1, 1, 1, new_BARs, (TRANSC_SOLID_FILL | TWO_PASS_COLOR_EXPAND | USE_LINEAR_EXPANSION) }, /* G400 / G450 */ [5] = { 0, 1, 1, 0, 1, 1, 2, 1, new_BARs, (TRANSC_SOLID_FILL | TWO_PASS_COLOR_EXPAND | USE_LINEAR_EXPANSION) }, /* G550 */ [6] = { 0, 1, 1, 0, 1, 1, 2, 1, new_BARs, (TRANSC_SOLID_FILL | TWO_PASS_COLOR_EXPAND | USE_LINEAR_EXPANSION) }, /* G200SE */ [7] = { 0, 1, 0, 0, 1, 0, 0, 1, new_BARs, (TRANSC_SOLID_FILL | TWO_PASS_COLOR_EXPAND | USE_LINEAR_EXPANSION) }, }; #define MGA_DEVICE_MATCH(d, i) \ { 0x102B, (d), PCI_MATCH_ANY, PCI_MATCH_ANY, 0, 0, (i) } #define MGA_SUBDEVICE_MATCH(d, s, i) \ { 0x102B, (d), 0x102B, (s), 0, 0, (i) } static const struct pci_id_match mga_device_match[] = { MGA_DEVICE_MATCH( PCI_CHIP_MGA2064, 0 ), MGA_DEVICE_MATCH( PCI_CHIP_MGA1064, 1 ), MGA_DEVICE_MATCH( PCI_CHIP_MGA2164, 2 ), MGA_DEVICE_MATCH( PCI_CHIP_MGA2164_AGP, 2 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG100, 3 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG100_PCI, 3 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG200, 4 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG200_PCI, 4 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG400, 5 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG550, 6 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG200_SE_A_PCI, 7 ), MGA_DEVICE_MATCH( PCI_CHIP_MGAG200_SE_B_PCI, 7 ), { 0, 0, 0 }, }; /* Supported chipsets */ static SymTabRec MGAChipsets[] = { { PCI_CHIP_MGA2064, "mga2064w" }, { PCI_CHIP_MGA1064, "mga1064sg" }, { PCI_CHIP_MGA2164, "mga2164w" }, { PCI_CHIP_MGA2164_AGP, "mga2164w AGP" }, { PCI_CHIP_MGAG100, "mgag100" }, { PCI_CHIP_MGAG100_PCI, "mgag100 PCI" }, { PCI_CHIP_MGAG200, "mgag200" }, { PCI_CHIP_MGAG200_PCI, "mgag200 PCI" }, { PCI_CHIP_MGAG200_SE_A_PCI, "mgag200 SE A PCI" }, { PCI_CHIP_MGAG200_SE_B_PCI, "mgag200 SE B PCI" }, { PCI_CHIP_MGAG400, "mgag400" }, { PCI_CHIP_MGAG550, "mgag550" }, {-1, NULL } }; static PciChipsets MGAPciChipsets[] = { { PCI_CHIP_MGA2064, PCI_CHIP_MGA2064, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGA1064, PCI_CHIP_MGA1064, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGA2164, PCI_CHIP_MGA2164, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGA2164_AGP, PCI_CHIP_MGA2164_AGP,(resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG100, PCI_CHIP_MGAG100, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG100_PCI, PCI_CHIP_MGAG100_PCI,(resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG200, PCI_CHIP_MGAG200, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG200_PCI, PCI_CHIP_MGAG200_PCI,(resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG200_SE_B_PCI, PCI_CHIP_MGAG200_SE_B_PCI, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG200_SE_A_PCI, PCI_CHIP_MGAG200_SE_A_PCI, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG400, PCI_CHIP_MGAG400, (resRange*)RES_SHARED_VGA }, { PCI_CHIP_MGAG550, PCI_CHIP_MGAG550, (resRange*)RES_SHARED_VGA }, { -1, -1, (resRange*)RES_UNDEFINED } }; /* * This contains the functions needed by the server after loading the * driver module. It must be supplied, and gets added the driver list by * the Module Setup funtion in the dynamic case. In the static case a * reference to this is compiled in, and this requires that the name of * this DriverRec be an upper-case version of the driver name. */ _X_EXPORT DriverRec MGA_C_NAME = { MGA_VERSION, MGA_DRIVER_NAME, MGAIdentify, NULL, MGAAvailableOptions, NULL, 0, NULL, mga_device_match, MGAPciProbe }; static const OptionInfoRec MGAOptions[] = { { OPTION_SW_CURSOR, "SWcursor", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_HW_CURSOR, "HWcursor", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_PCI_RETRY, "PciRetry", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_SYNC_ON_GREEN, "SyncOnGreen", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_NOACCEL, "NoAccel", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_SHOWCACHE, "ShowCache", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_OVERLAY, "Overlay", OPTV_ANYSTR, {0}, FALSE }, { OPTION_MGA_SDRAM, "MGASDRAM", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_SHADOW_FB, "ShadowFB", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_FBDEV, "UseFBDev", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_COLOR_KEY, "ColorKey", OPTV_INTEGER, {0}, FALSE }, { OPTION_SET_MCLK, "SetMclk", OPTV_FREQ, {0}, FALSE }, { OPTION_OVERCLOCK_MEM, "OverclockMem", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_VIDEO_KEY, "VideoKey", OPTV_INTEGER, {0}, FALSE }, { OPTION_ROTATE, "Rotate", OPTV_ANYSTR, {0}, FALSE }, { OPTION_TEXTURED_VIDEO, "TexturedVideo",OPTV_BOOLEAN, {0}, FALSE }, { OPTION_CRTC2HALF, "Crtc2Half", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_CRTC2RAM, "Crtc2Ram", OPTV_INTEGER, {0}, FALSE }, { OPTION_INT10, "Int10", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_AGP_MODE, "AGPMode", OPTV_INTEGER, {0}, FALSE }, { OPTION_AGP_SIZE, "AGPSize", OPTV_INTEGER, {0}, FALSE }, { OPTION_DIGITAL1, "DigitalScreen1",OPTV_BOOLEAN, {0}, FALSE }, { OPTION_DIGITAL2, "DigitalScreen2",OPTV_BOOLEAN, {0}, FALSE }, { OPTION_TV, "TV", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_TVSTANDARD, "TVStandard", OPTV_ANYSTR, {0}, FALSE }, { OPTION_CABLETYPE, "CableType", OPTV_ANYSTR, {0}, FALSE }, { OPTION_NOHAL, "NoHal", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_SWAPPED_HEAD, "SwappedHead", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_DRI, "DRI", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_MERGEDFB, "MergedFB", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_HSYNC2, "Monitor2HSync", OPTV_ANYSTR, {0}, FALSE }, { OPTION_VREFRESH2, "Monitor2VRefresh", OPTV_ANYSTR, {0}, FALSE }, { OPTION_MONITOR2POS, "Monitor2Position", OPTV_ANYSTR, {0}, FALSE }, { OPTION_METAMODES, "MetaModes", OPTV_ANYSTR, {0}, FALSE }, { OPTION_OLDDMA, "OldDmaInit", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_PCIDMA, "ForcePciDma", OPTV_BOOLEAN, {0}, FALSE }, { OPTION_ACCELMETHOD, "AccelMethod", OPTV_ANYSTR, {0}, FALSE }, { -1, NULL, OPTV_NONE, {0}, FALSE } }; /* * List of symbols from other modules that this module references. This * list is used to tell the loader that it is OK for symbols here to be * unresolved providing that it hasn't been told that they haven't been * told that they are essential via a call to xf86LoaderReqSymbols() or * xf86LoaderReqSymLists(). The purpose is this is to avoid warnings about * unresolved symbols that are not required. */ static const char *vgahwSymbols[] = { "vgaHWFreeHWRec", "vgaHWGetHWRec", "vgaHWGetIOBase", "vgaHWGetIndex", "vgaHWInit", "vgaHWLock", "vgaHWMapMem", "vgaHWProtect", "vgaHWRestore", "vgaHWSave", "vgaHWSaveScreen", "vgaHWSetMmioFuncs", "vgaHWUnlock", "vgaHWUnmapMem", "vgaHWddc1SetSpeedWeak", NULL }; static const char *fbSymbols[] = { "fbPictureInit", "fbScreenInit", NULL }; static const char *xf8_32bppSymbols[] = { "cfb8_32ScreenInit", "xf86Overlay8Plus32Init", NULL }; #ifdef USE_EXA static const char *exaSymbols[] = { "exaDriverInit", "exaDriverFini", "exaGetPixmapOffset", "exaGetVersion", NULL }; #endif #ifdef USE_XAA static const char *xaaSymbols[] = { "XAACachePlanarMonoStipple", "XAACreateInfoRec", "XAADestroyInfoRec", "XAAGetFallbackOps", "XAAInit", "XAAMoveDWORDS", "XAA_888_plus_PICT_a8_to_8888", NULL }; #endif static const char *ramdacSymbols[] = { "xf86CreateCursorInfoRec", "xf86DestroyCursorInfoRec", "xf86InitCursor", NULL }; #ifdef XF86DRI static const char *drmSymbols[] = { "drmAddBufs", "drmAddMap", "drmAgpAcquire", "drmAgpAlloc", "drmAgpBind", "drmAgpDeviceId", "drmAgpEnable", "drmAgpFree", "drmAgpGetMode", "drmAgpRelease", "drmAgpUnbind", "drmAgpVendorId", "drmCommandNone", "drmCommandWrite", "drmCtlInstHandler", "drmCtlUninstHandler", "drmFreeVersion", "drmGetInterruptFromBusID", "drmGetLibVersion", "drmGetVersion", "drmMap", "drmMapBufs", "drmUnmap", "drmUnmapBufs", NULL }; static const char *driSymbols[] = { "DRICloseScreen", "DRICreateInfoRec", "DRIDestroyInfoRec", "DRIFinishScreenInit", "DRIGetDeviceInfo", "DRILock", "DRIQueryVersion", "DRIScreenInit", "DRIUnlock", "GlxSetVisualConfigs", "DRICreatePCIBusID", NULL }; #endif #define MGAuseI2C 1 static const char *ddcSymbols[] = { "xf86DoEDID_DDC1", #if MGAuseI2C "xf86DoEDID_DDC2", #endif "xf86PrintEDID", "xf86SetDDCproperties", NULL }; static const char *i2cSymbols[] = { "xf86CreateI2CBusRec", "xf86I2CBusInit", NULL }; static const char *shadowSymbols[] = { "ShadowFBInit", NULL }; #ifdef XFree86LOADER static const char *vbeSymbols[] = { "VBEInit", "vbeDoEDID", "vbeFree", NULL }; #endif static const char *int10Symbols[] = { "xf86FreeInt10", "xf86InitInt10", NULL }; static const char *fbdevHWSymbols[] = { "fbdevHWAdjustFrameWeak", "fbdevHWEnterVT", "fbdevHWGetVidmem", "fbdevHWInit", "fbdevHWLeaveVTWeak", "fbdevHWLoadPaletteWeak", "fbdevHWMapMMIO", "fbdevHWMapVidmem", "fbdevHWModeInit", "fbdevHWRestore", "fbdevHWSave", "fbdevHWSwitchModeWeak", "fbdevHWUnmapMMIO", "fbdevHWUnmapVidmem", "fbdevHWUseBuildinMode", "fbdevHWValidModeWeak", NULL }; #ifdef USEMGAHAL static const char *halSymbols[] = { "MGACloseLibrary", "MGAGetBOARDHANDLESize", "MGAGetHardwareInfo", "MGAOpenLibrary", "MGARestoreVgaState", "MGASaveVgaState", "MGASetMode", "MGASetVgaMode", "MGAValidateMode", "MGAValidateVideoParameters", "HALSetDisplayStart", NULL }; #endif #ifdef XFree86LOADER static MODULESETUPPROTO(mgaSetup); static XF86ModuleVersionInfo mgaVersRec = { MGA_DRIVER_NAME, MODULEVENDORSTRING, MODINFOSTRING1, MODINFOSTRING2, XORG_VERSION_CURRENT, MGA_MAJOR_VERSION, MGA_MINOR_VERSION, MGA_PATCHLEVEL, ABI_CLASS_VIDEODRV, /* This is a video driver */ ABI_VIDEODRV_VERSION, MOD_CLASS_VIDEODRV, {0,0,0,0} }; _X_EXPORT XF86ModuleData MGA_MODULE_DATA = { &mgaVersRec, mgaSetup, NULL }; static pointer mgaSetup(pointer module, pointer opts, int *errmaj, int *errmin) { static Bool setupDone = FALSE; /* This module should be loaded only once, but check to be sure. */ if (!setupDone) { setupDone = TRUE; xf86AddDriver(&MGA_C_NAME, module, 1); /* * Modules that this driver always requires may be loaded here * by calling LoadSubModule(). */ /* * Tell the loader about symbols from other modules that this module * might refer to. */ LoaderRefSymLists(vgahwSymbols, #ifdef USE_XAA xaaSymbols, #endif #ifdef USE_EXA exaSymbols, #endif xf8_32bppSymbols, ramdacSymbols, ddcSymbols, i2cSymbols, shadowSymbols, fbdevHWSymbols, vbeSymbols, fbSymbols, int10Symbols, #ifdef XF86DRI drmSymbols, driSymbols, #endif #ifdef USEMGAHAL halSymbols, #endif NULL); /* * The return value must be non-NULL on success even though there * is no TearDownProc. */ return (pointer)1; } else { if (errmaj) *errmaj = LDR_ONCEONLY; return NULL; } } #endif /* XFree86LOADER */ /* * ramdac info structure initialization */ static MGARamdacRec DacInit = { FALSE, 0, 0, 0, 0, NULL, NULL, NULL, NULL, NULL, NULL, 90000, /* maxPixelClock */ 0, X_DEFAULT, X_DEFAULT, FALSE }; Bool MGAGetRec(ScrnInfoPtr pScrn) { /* * Allocate an MGARec, and hook it into pScrn->driverPrivate. * pScrn->driverPrivate is initialised to NULL, so we can check if * the allocation has already been done. */ if (pScrn->driverPrivate != NULL) return TRUE; pScrn->driverPrivate = xnfcalloc(sizeof(MGARec), 1); /* Initialise it */ MGAPTR(pScrn)->Dac = DacInit; return TRUE; } void MGAFreeRec(ScrnInfoPtr pScrn) { if (pScrn->driverPrivate == NULL) return; xfree(pScrn->driverPrivate); pScrn->driverPrivate = NULL; } static const OptionInfoRec * MGAAvailableOptions(int chipid, int busid) { return MGAOptions; } /* Mandatory */ static void MGAIdentify(int flags) { xf86PrintChipsets(MGA_NAME, "driver for Matrox chipsets", MGAChipsets); } Bool MGAPciProbe(DriverPtr drv, int entity_num, struct pci_device * dev, intptr_t match_data) { ScrnInfoPtr pScrn = NULL; EntityInfoPtr pEnt; MGAPtr pMga; #ifdef DISABLE_VGA_IO MgaSavePtr smga; smga = xnfalloc(sizeof(MgaSave)); smga->pvp = dev; #endif /* Allocate a ScrnInfoRec and claim the slot */ pScrn = xf86ConfigPciEntity(pScrn, 0, entity_num, MGAPciChipsets, NULL, #ifndef DISABLE_VGA_IO NULL, NULL, NULL, NULL #else VgaIOSave, VgaIOSave, VgaIORestore, smga #endif ); if (pScrn != NULL) { /* Fill in what we can of the ScrnInfoRec */ pScrn->driverVersion = MGA_VERSION; pScrn->driverName = MGA_DRIVER_NAME; pScrn->name = MGA_NAME; pScrn->Probe = NULL; pScrn->PreInit = MGAPreInit; pScrn->ScreenInit = MGAScreenInit; pScrn->SwitchMode = MGASwitchMode; pScrn->AdjustFrame = MGAAdjustFrame; pScrn->EnterVT = MGAEnterVT; pScrn->LeaveVT = MGALeaveVT; pScrn->FreeScreen = MGAFreeScreen; pScrn->ValidMode = MGAValidMode; /* Allocate the MGARec driverPrivate */ if (!MGAGetRec(pScrn)) { return FALSE; } pMga = MGAPTR(pScrn); pMga->chip_attribs = & attribs[ match_data ]; pMga->PciInfo = dev; /* * For cards that can do dual head per entity, mark the entity * as sharable. */ pEnt = xf86GetEntityInfo(entity_num); if (pMga->chip_attribs->dual_head_possible) { MGAEntPtr pMgaEnt = NULL; DevUnion *pPriv; xf86SetEntitySharable(entity_num); /* Allocate an entity private if necessary */ if (MGAEntityIndex < 0) MGAEntityIndex = xf86AllocateEntityPrivateIndex(); pPriv = xf86GetEntityPrivate(pScrn->entityList[0], MGAEntityIndex); if (!pPriv->ptr) { pPriv->ptr = xnfcalloc(sizeof(MGAEntRec), 1); pMgaEnt = pPriv->ptr; pMgaEnt->lastInstance = -1; } else { pMgaEnt = pPriv->ptr; } /* * Set the entity instance for this instance of the driver. For * dual head per card, instance 0 is the "master" instance, driving * the primary head, and instance 1 is the "slave". */ pMgaEnt->lastInstance++; xf86SetEntityInstanceForScreen(pScrn, pScrn->entityList[0], pMgaEnt->lastInstance); } } return (pScrn != NULL); } /* * MGASoftReset -- * * Resets drawing engine */ void MGASoftReset(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); pMga->FbMapSize = 8192 * 1024; MGAMapMem(pScrn); /* set soft reset bit */ OUTREG(MGAREG_Reset, 1); usleep(200); OUTREG(MGAREG_Reset, 0); /* reset memory */ OUTREG(MGAREG_MACCESS, 1<<15); usleep(10); #if 0 /* This will hang if the PLLs aren't on */ /* wait until drawing engine is ready */ while ( MGAISBUSY() ) usleep(1000); /* flush FIFO */ i = 32; WAITFIFO(i); while ( i-- ) OUTREG(MGAREG_SHIFT, 0); #endif MGAUnmapMem(pScrn); } /* * MGACountRAM -- * * Counts amount of installed RAM */ static int MGACountRam(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); int ProbeSize = 8192; int SizeFound = 2048; CARD32 biosInfo = 0; #if 0 /* This isn't correct. It looks like this can have arbitrary data for the memconfig even when the bios has initialized it. At least, my cards don't advertise the documented values (my 8 and 16 Meg G200s have the same values) */ if (pMga->Primary) { /* can only trust this for primary cards */ pci_device_cfg_read_u32(pMga->PciInfo, & biosInfo, PCI_OPTION_REG); } #endif switch(pMga->Chipset) { case PCI_CHIP_MGA2164: case PCI_CHIP_MGA2164_AGP: xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "Unable to probe memory amount due to hardware bug. " "Assuming 4096 KB\n"); return 4096; case PCI_CHIP_MGAG400: case PCI_CHIP_MGAG550: if(biosInfo) { switch((biosInfo >> 10) & 0x07) { case 0: return (biosInfo & (1 << 14)) ? 32768 : 16384; case 1: case 2: return 16384; case 3: case 5: return 65536; case 4: return 32768; } } ProbeSize = 32768; break; case PCI_CHIP_MGAG200_SE_A_PCI: case PCI_CHIP_MGAG200_SE_B_PCI: ProbeSize = 4096; break; case PCI_CHIP_MGAG200: case PCI_CHIP_MGAG200_PCI: if(biosInfo) { switch((biosInfo >> 11) & 0x03) { case 0: return 8192; default: return 16384; } } ProbeSize = 8192; break; case PCI_CHIP_MGAG100: case PCI_CHIP_MGAG100_PCI: if(biosInfo) /* I'm not sure if the docs are correct */ return (biosInfo & (1 << 12)) ? 16384 : 8192; case PCI_CHIP_MGA1064: case PCI_CHIP_MGA2064: ProbeSize = 8192; break; default: break; } if (pMga->FbAddress) { volatile unsigned char* base; unsigned char tmp; int i; pMga->FbMapSize = ProbeSize * 1024; MGAMapMem(pScrn); base = pMga->FbBase; /* turn MGA mode on - enable linear frame buffer (CRTCEXT3) */ OUTREG8(MGAREG_CRTCEXT_INDEX, 3); tmp = INREG8(MGAREG_CRTCEXT_DATA); OUTREG8(MGAREG_CRTCEXT_DATA, tmp | 0x80); /* apparently the G200SE doesn't have a BIOS to read */ if (pMga->is_G200SE) { CARD32 MemoryAt0, MemoryAt1, Offset; CARD32 FirstMemoryVal1, FirstMemoryVal2; CARD32 SecondMemoryVal1, SecondMemoryVal2; CARD32 TestMemoryLocA, TestMemoryLocB; CARD32 TestMemoryLoc0, TestMemoryLoc1; CARD32 TestA, TestB; MemoryAt0 = base[0]; MemoryAt1 = base[1]; base[0] = 0; base[1] = 0; for (Offset = 0x100000; Offset < (ProbeSize * 1024); Offset += 0x1000) { FirstMemoryVal1 = base[Offset]; FirstMemoryVal2 = base[Offset+1]; SecondMemoryVal1 = base[Offset+0x100]; SecondMemoryVal2 = base[Offset+0x101]; base[Offset] = 0x55; base[Offset+1] = 0xaa; base[Offset+0x100] = 0x55; base[Offset+0x101] = 0xaa; OUTREG(MGAREG_CRTC_INDEX, 0); usleep(8); TestMemoryLocA = base[Offset]; TestMemoryLocB = base[Offset+1]; TestMemoryLoc0 = base[0]; TestMemoryLoc1 = base[1]; base[Offset] = FirstMemoryVal1; base[Offset+1] = FirstMemoryVal2; base[Offset+0x100] = SecondMemoryVal1; base[Offset+0x101] = SecondMemoryVal2; TestA = ((TestMemoryLocB << 8) + TestMemoryLocA); TestB = ((TestMemoryLoc1 << 8) + TestMemoryLoc0); if ((TestA != 0xAA55) || (TestB)) { break; } } base[0] = MemoryAt0; base[1] = MemoryAt1; SizeFound = (Offset / 1024) - 64; } else { /* write, read and compare method split into two loops to make it more reliable on RS/6k -ReneR */ for(i = ProbeSize; i > 2048; i -= 2048) { base[(i * 1024) - 1] = 0xAA; } OUTREG8(MGAREG_CRTC_INDEX, 0); /* flush the cache */ usleep(4); /* twart write combination */ for(i = ProbeSize; i > 2048; i -= 2048) { if(base[(i * 1024) - 1] == 0xAA) { SizeFound = i; break; } } } /* restore CRTCEXT3 state */ OUTREG8(MGAREG_CRTCEXT_INDEX, 3); OUTREG8(MGAREG_CRTCEXT_DATA, tmp); MGAUnmapMem(pScrn); } return SizeFound; } static xf86MonPtr MGAdoDDC(ScrnInfoPtr pScrn) { vgaHWPtr hwp; MGAPtr pMga; xf86MonPtr MonInfo = NULL; hwp = VGAHWPTR(pScrn); pMga = MGAPTR(pScrn); /* Load DDC if we have the code to use it */ /* This gives us DDC1 */ if (pMga->ddc1Read || pMga->i2cInit) { if (xf86LoadSubModule(pScrn, "ddc")) { xf86LoaderReqSymLists(ddcSymbols, NULL); } else { /* ddc module not found, we can do without it */ pMga->ddc1Read = NULL; pMga->DDC_Bus1 = NULL; pMga->DDC_Bus2 = NULL; return NULL; } } else return NULL; #if MGAuseI2C /* - DDC can use I2C bus */ /* Load I2C if we have the code to use it */ if (pMga->i2cInit) { if ( xf86LoadSubModule(pScrn, "i2c") ) { xf86LoaderReqSymLists(i2cSymbols,NULL); } else { /* i2c module not found, we can do without it */ pMga->i2cInit = NULL; pMga->DDC_Bus1 = NULL; pMga->DDC_Bus2 = NULL; } } #endif /* MGAuseI2C */ /* Map the MGA memory and MMIO areas */ if (!MGAMapMem(pScrn)) return NULL; /* Initialise the MMIO vgahw functions */ vgaHWSetMmioFuncs(hwp, pMga->IOBase, PORT_OFFSET); vgaHWGetIOBase(hwp); /* Map the VGA memory when the primary video */ if (pMga->Primary) { hwp->MapSize = 0x10000; if (!vgaHWMapMem(pScrn)) return NULL; } else { /* XXX Need to write an MGA mode ddc1SetSpeed */ if (pMga->DDC1SetSpeed == vgaHWddc1SetSpeedWeak()) { pMga->DDC1SetSpeed = NULL; xf86DrvMsgVerb(pScrn->scrnIndex, X_INFO, 2, "DDC1 disabled - chip not in VGA mode\n"); } } /* Save the current state */ MGASave(pScrn); /* It is now safe to talk to the card */ #if MGAuseI2C /* Initialize I2C buses - used by DDC if available */ if (pMga->i2cInit) { pMga->i2cInit(pScrn); } /* DDC for second head... */ if (pMga->SecondCrtc && pMga->DDC_Bus2) { MonInfo = xf86DoEDID_DDC2(pScrn->scrnIndex,pMga->DDC_Bus2); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "I2C Monitor info: %p\n", (void *)MonInfo); xf86PrintEDID(MonInfo); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "end of I2C Monitor info\n"); xf86SetDDCproperties(pScrn, MonInfo); return MonInfo; } else { /* Its the first head... */ if (pMga->DDC_Bus1) { MonInfo = xf86DoEDID_DDC2(pScrn->scrnIndex,pMga->DDC_Bus1); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "I2C Monitor info: %p\n", (void *) MonInfo); xf86PrintEDID(MonInfo); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "end of I2C Monitor info\n"); } if (!MonInfo) #endif /* MGAuseI2C */ /* Read and output monitor info using DDC1 */ if (pMga->ddc1Read && pMga->DDC1SetSpeed) { MonInfo = xf86DoEDID_DDC1(pScrn->scrnIndex, pMga->DDC1SetSpeed, pMga->ddc1Read ) ; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "DDC Monitor info: %p\n", (void *) MonInfo); xf86PrintEDID( MonInfo ); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "end of DDC Monitor info\n"); } if (!MonInfo){ vbeInfoPtr pVbe; if (xf86LoadSubModule(pScrn, "vbe")) { pVbe = VBEInit(NULL,pMga->pEnt->index); MonInfo = vbeDoEDID(pVbe, NULL); vbeFree(pVbe); if (MonInfo){ xf86DrvMsg(pScrn->scrnIndex, X_INFO, "VBE DDC Monitor info: %p\n", (void *) MonInfo); xf86PrintEDID( MonInfo ); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "end of VBE DDC Monitor info\n\n"); } } } #if MGAuseI2C } #endif /* Restore previous state and unmap MGA memory and MMIO areas */ MGARestore(pScrn); MGAUnmapMem(pScrn); /* Unmap vga memory if we mapped it */ if (xf86IsPrimaryPci(pMga->PciInfo) && !pMga->FBDev) { vgaHWUnmapMem(pScrn); } xf86SetDDCproperties(pScrn, MonInfo); return MonInfo; } #ifdef DISABLE_VGA_IO static void VgaIOSave(int i, void *arg) { MgaSavePtr sMga = arg; uint32_t temp; #ifdef DEBUG ErrorF("mga: VgaIOSave: %d:%d:%d\n", sMga->pvp->bus, sMga->pvp->device, sMga->pvp->func); #endif pci_device_cfg_read_u32(pMga->PciInfo, & temp, PCI_OPTION_REG); sMga->enable = (temp & 0x100) != 0; } static void VgaIORestore(int i, void *arg) { MgaSavePtr sMga = arg; PCITAG tag = pciTag(sMga->pvp->bus,sMga->pvp->device,sMga->pvp->func); #ifdef DEBUG ErrorF("mga: VgaIORestore: %d:%d:%d\n", sMga->pvp->bus, sMga->pvp->device, sMga->pvp->func); #endif pci_device_cfg_write_bits(pMga->PciInfo, 0x00000100, sMga->enable, PCI_OPTION_REG); } static void VgaIODisable(void *arg) { MGAPtr pMga = arg; #ifdef DEBUG ErrorF("mga: VgaIODisable: %d:%d:%d, %s, xf86ResAccessEnter is %s\n", pMga->PciInfo->bus, pMga->PciInfo->device, pMga->PciInfo->func, pMga->Primary ? "primary" : "secondary", BOOLTOSTRING(xf86ResAccessEnter)); #endif /* Turn off the vgaioen bit. */ pci_device_cfg_write_bits(pMga->PciInfo, 0x00000100, 0x00000000, PCI_OPTION_REG); } static void VgaIOEnable(void *arg) { MGAPtr pMga = arg; #ifdef DEBUG ErrorF("mga: VgaIOEnable: %d:%d:%d, %s, xf86ResAccessEnter is %s\n", pMga->PciInfo->bus, pMga->PciInfo->device, pMga->PciInfo->func, pMga->Primary ? "primary" : "secondary", BOOLTOSTRING(xf86ResAccessEnter)); #endif /* Turn on the vgaioen bit. */ if (pMga->Primary) { pci_device_cfg_write_bits(pMga->PciInfo, 0x00000100, 0x00000100, PCI_OPTION_REG); } } #endif /* DISABLE_VGA_IO */ void MGAProbeDDC(ScrnInfoPtr pScrn, int index) { vbeInfoPtr pVbe; if (xf86LoadSubModule(pScrn, "vbe")) { pVbe = VBEInit(NULL,index); ConfiguredMonitor = vbeDoEDID(pVbe, NULL); vbeFree(pVbe); } } Bool MGAMavenRead(ScrnInfoPtr pScrn, I2CByte reg, I2CByte *val) { MGAPtr pMga = MGAPTR(pScrn); if (!pMga->Maven) return FALSE; /* FIXME: Using private interfaces for the moment until a more * flexible xf86I2CWriteRead() variant shows up for us * * MAVEN does _not_ like a start bit in the middle of its transaction * MAVEN does _not_ like ACK at the end of the transaction */ if (!pMga->Maven_Bus->I2CStart(pMga->Maven_Bus, pMga->Maven->ByteTimeout)) return FALSE; if (!pMga->Maven_Bus->I2CPutByte(pMga->Maven, MAVEN_READ)) return FALSE; if (!pMga->Maven_Bus->I2CPutByte(pMga->Maven, reg)) return FALSE; pMga->Maven_Bus->I2CStop(pMga->Maven); if (!pMga->Maven_Bus->I2CGetByte(pMga->Maven, val, 0)) return FALSE; pMga->Maven_Bus->I2CStop(pMga->Maven); return TRUE; } /* Mandatory */ static Bool MGAPreInit(ScrnInfoPtr pScrn, int flags) { MGAPtr pMga; MessageType from; int i; double real; int bytesPerPixel; ClockRangePtr clockRanges; const char *s; int flags24; MGAEntPtr pMgaEnt = NULL; Bool Default; #ifdef USEMGAHAL ULONG status; CARD8 MiscCtlReg; #endif /* * Note: This function is only called once at server startup, and * not at the start of each server generation. This means that * only things that are persistent across server generations can * be initialised here. xf86Screens[] is (pScrn is a pointer to one * of these). Privates allocated using xf86AllocateScrnInfoPrivateIndex() * are too, and should be used for data that must persist across * server generations. * * Per-generation data should be allocated with * AllocateScreenPrivateIndex() from the ScreenInit() function. */ /* Check the number of entities, and fail if it isn't one. */ if (pScrn->numEntities != 1) return FALSE; pMga = MGAPTR(pScrn); /* Set here until dri is enabled */ #ifdef XF86DRI pMga->haveQuiescense = 1; #endif /* Get the entity, and make sure it is PCI. */ pMga->pEnt = xf86GetEntityInfo(pScrn->entityList[0]); if (pMga->pEnt->location.type != BUS_PCI) return FALSE; /* Allocate an entity private if necessary */ if (xf86IsEntityShared(pScrn->entityList[0])) { pMgaEnt = xf86GetEntityPrivate(pScrn->entityList[0], MGAEntityIndex)->ptr; pMga->entityPrivate = pMgaEnt; } /* Set pMga->device to the relevant Device section */ pMga->device = xf86GetDevFromEntity(pScrn->entityList[0], pScrn->entityInstanceList[0]); if (flags & PROBE_DETECT) { MGAProbeDDC(pScrn, pMga->pEnt->index); return TRUE; } /* The vgahw module should be loaded here when needed */ if (!xf86LoadSubModule(pScrn, "vgahw")) return FALSE; xf86LoaderReqSymLists(vgahwSymbols, NULL); /* * Allocate a vgaHWRec */ if (!vgaHWGetHWRec(pScrn)) return FALSE; pMga->Primary = xf86IsPrimaryPci(pMga->PciInfo); #ifndef DISABLE_VGA_IO xf86SetOperatingState(resVgaIo, pMga->pEnt->index, ResUnusedOpr); xf86SetOperatingState(resVgaMem, pMga->pEnt->index, ResDisableOpr); #else /* * Set our own access functions, which control the vgaioen bit. */ pMga->Access.AccessDisable = VgaIODisable; pMga->Access.AccessEnable = VgaIOEnable; pMga->Access.arg = pMga; xf86SetAccessFuncs(pMga->pEnt, &pMga->Access, &pMga->Access); #endif /* Set pScrn->monitor */ pScrn->monitor = pScrn->confScreen->monitor; /* * Set the Chipset and ChipRev, allowing config file entries to * override. */ if (pMga->device->chipset && *pMga->device->chipset) { pScrn->chipset = pMga->device->chipset; pMga->Chipset = xf86StringToToken(MGAChipsets, pScrn->chipset); from = X_CONFIG; } else if (pMga->device->chipID >= 0) { pMga->Chipset = pMga->device->chipID; pScrn->chipset = (char *)xf86TokenToString(MGAChipsets, pMga->Chipset); from = X_CONFIG; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "ChipID override: 0x%04X\n", pMga->Chipset); } else { from = X_PROBED; pMga->Chipset = pMga->PciInfo->device_id; pScrn->chipset = (char *)xf86TokenToString(MGAChipsets, pMga->Chipset); } if (pMga->device->chipRev >= 0) { pMga->ChipRev = pMga->device->chipRev; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "ChipRev override: %d\n", pMga->ChipRev); } else { pMga->ChipRev = pMga->PciInfo->revision; } /* * This shouldn't happen because such problems should be caught in * MGAProbe(), but check it just in case. */ if (pScrn->chipset == NULL) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "ChipID 0x%04X is not recognised\n", pMga->Chipset); return FALSE; } if (pMga->Chipset < 0) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Chipset \"%s\" is not recognised\n", pScrn->chipset); return FALSE; } xf86DrvMsg(pScrn->scrnIndex, from, "Chipset: \"%s\"", pScrn->chipset); if (pMga->Chipset == PCI_CHIP_MGAG400) { if (pMga->ChipRev >= 0x80) xf86ErrorF(" (G450)\n"); else xf86ErrorF(" (G400)\n"); } else { xf86ErrorF("\n"); } pMga->is_Gx50 = ((pMga->Chipset == PCI_CHIP_MGAG400) && (pMga->ChipRev >= 0x80)) || (pMga->Chipset == PCI_CHIP_MGAG550); pMga->is_G200SE = (pMga->Chipset == PCI_CHIP_MGAG200_SE_A_PCI) || (pMga->Chipset == PCI_CHIP_MGAG200_SE_B_PCI); #ifdef USEMGAHAL if (pMga->chip_attribs->HAL_chipset) { Bool loadHal = TRUE; from = X_DEFAULT; if (xf86FindOption(pMga->device->options, "NoHal")) { loadHal = !xf86SetBoolOption(pMga->device->options, "NoHal", !loadHal); from = X_CONFIG; } else if (xf86FindOption(pMga->device->options, "Hal")) { loadHal = xf86SetBoolOption(pMga->device->options, "Hal", loadHal); from = X_CONFIG; } if (loadHal && xf86LoadSubModule(pScrn, "mga_hal")) { xf86LoaderReqSymLists(halSymbols, NULL); xf86DrvMsg(pScrn->scrnIndex, from,"Matrox HAL module used\n"); pMga->HALLoaded = TRUE; } else { xf86DrvMsg(pScrn->scrnIndex, from, "Matrox HAL module not loaded " "- using builtin mode setup instead\n"); pMga->HALLoaded = FALSE; } } #endif pMga->DualHeadEnabled = FALSE; if (xf86IsEntityShared(pScrn->entityList[0])) {/* dual-head mode requested*/ if ( #ifdef USEMGAHAL pMga->HALLoaded || #endif !MGA_DH_NEEDS_HAL(pMga)) { pMga->DualHeadEnabled = TRUE; } else if (xf86IsPrimInitDone(pScrn->entityList[0])) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "This card requires the \"mga_hal\" module for dual-head operation\n" "\tIt can be found at the Matrox web site \n"); } } /* * In case of DualHead, we need to determine if we are the 'master' head * or the 'slave' head. In order to do that, at the end of the first * initialisation, PrimInit is set as DONE to the shared entity. So that * the second initialisation knows that something has been done before it. * This always assume that the first device initialised is the master * head, and the second the slave. * */ if (xf86IsEntityShared(pScrn->entityList[0])) { /* dual-head mode */ if (!xf86IsPrimInitDone(pScrn->entityList[0])) { /* Is it the first initialisation? */ /* First CRTC */ pMga->SecondCrtc = FALSE; pMga->HWCursor = TRUE; pMgaEnt->pScrn_1 = pScrn; } else if (pMga->DualHeadEnabled) { /* Second CRTC */ pMga->SecondCrtc = TRUE; pMga->HWCursor = FALSE; pMgaEnt->pScrn_2 = pScrn; pScrn->AdjustFrame = MGAAdjustFrameCrtc2; /* * Fail initialization of second head if we are in MergeFB mode, * since we do it ourselfs. */ if(pMgaEnt->pScrn_1 && MGAPTR(pMgaEnt->pScrn_1)->MergedFB) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Primary head in Merged framebuffer mode. \n" "Don't let Xfree try to manage the second head.\n" "Remove the second screen in the \"ServerLayout\"\n" "Section of the config file."); return FALSE; } } else { return FALSE; } } if (pMga->DualHeadEnabled) { #ifdef XF86DRI pMga->GetQuiescence = MGAGetQuiescenceShared; #endif } else { /* single-head mode */ pMga->SecondCrtc = FALSE; pMga->HWCursor = TRUE; #ifdef XF86DRI pMga->GetQuiescence = MGAGetQuiescence; #endif } /* * The first thing we should figure out is the depth, bpp, etc. * Our default depth is 8, so pass it to the helper function. * We support both 24bpp and 32bpp layouts, so indicate that. */ /* Prefer 24bpp fb unless the Overlay option is set, or DRI is * supported. */ flags24 = Support24bppFb | Support32bppFb | SupportConvert32to24; s = xf86TokenToOptName(MGAOptions, OPTION_OVERLAY); #ifndef XF86DRI if (!(xf86FindOption(pScrn->confScreen->options, s) || xf86FindOption(pMga->device->options, s))) { flags24 |= PreferConvert32to24; } #endif if (pMga->SecondCrtc) flags24 = Support32bppFb; if (!xf86SetDepthBpp(pScrn, 0, 0, 0, flags24)) { return FALSE; } else { /* Check that the returned depth is one we support */ switch (pScrn->depth) { case 8: case 15: case 16: case 24: /* OK */ break; default: xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Given depth (%d) is not supported by this driver\n", pScrn->depth); return FALSE; } } xf86PrintDepthBpp(pScrn); /* * This must happen after pScrn->display has been set because * xf86SetWeight references it. */ if (pScrn->depth > 8) { /* The defaults are OK for us */ rgb zeros = {0, 0, 0}; if (!xf86SetWeight(pScrn, zeros, zeros)) { return FALSE; } else { /* XXX check that weight returned is supported */ ; } } bytesPerPixel = pScrn->bitsPerPixel / 8; /* We use a programmable clock */ pScrn->progClock = TRUE; /* Collect all of the relevant option flags (fill in pScrn->options) */ xf86CollectOptions(pScrn, NULL); /* Process the options */ if (!(pMga->Options = xalloc(sizeof(MGAOptions)))) return FALSE; memcpy(pMga->Options, MGAOptions, sizeof(MGAOptions)); xf86ProcessOptions(pScrn->scrnIndex, pScrn->options, pMga->Options); #if !defined(__powerpc__) pMga->softbooted = FALSE; Default = (pMga->chip_attribs->dual_head_possible && !pMga->Primary && !pMga->SecondCrtc); if (xf86ReturnOptValBool(pMga->Options, OPTION_INT10, Default) && xf86LoadSubModule(pScrn, "int10")) { xf86Int10InfoPtr pInt; xf86LoaderReqSymLists(int10Symbols, NULL); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Initializing int10\n"); pInt = xf86InitInt10(pMga->pEnt->index); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Done initializing int10\n"); if (pInt) pMga->softbooted = TRUE; xf86FreeInt10(pInt); } #endif /* Set the bits per RGB for 8bpp mode */ if (pScrn->depth == 8) pScrn->rgbBits = 8; #ifdef XF86DRI from = X_DEFAULT; pMga->agpMode = MGA_DEFAULT_AGP_MODE; if (xf86GetOptValInteger(pMga->Options, OPTION_AGP_MODE, &(pMga->agpMode))) { if (pMga->agpMode < 1) { pMga->agpMode = 1; } if (pMga->agpMode > MGA_MAX_AGP_MODE) { pMga->agpMode = MGA_MAX_AGP_MODE; } from = X_CONFIG; } if (xf86GetOptValInteger(pMga->Options, OPTION_AGP_SIZE, &(pMga->agpSize))) { /* check later */ xf86DrvMsg(pScrn->scrnIndex, from, "Using %d MB of AGP memory\n", pMga->agpSize); } xf86DrvMsg(pScrn->scrnIndex, from, "Using AGP %dx mode\n", pMga->agpMode); if (xf86ReturnOptValBool(pMga->Options, OPTION_OLDDMA, FALSE)) { pMga->useOldDmaInit = TRUE; } if (xf86ReturnOptValBool(pMga->Options, OPTION_PCIDMA, FALSE)) { pMga->forcePciDma = TRUE; } #endif from = X_DEFAULT; /* * The preferred method is to use the "hw cursor" option as a tri-state * option, with the default set above. */ if (xf86GetOptValBool(pMga->Options, OPTION_HW_CURSOR, &pMga->HWCursor)) { from = X_CONFIG; } /* For compatibility, accept this too (as an override) */ if (xf86ReturnOptValBool(pMga->Options, OPTION_NOACCEL, FALSE)) { pMga->NoAccel = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Acceleration disabled\n"); } else { int from = X_DEFAULT; #ifdef USE_EXA char *s = xf86GetOptValString(pMga->Options, OPTION_ACCELMETHOD); #endif pMga->NoAccel = FALSE; pMga->Exa = FALSE; #ifdef USE_EXA if (!xf86NameCmp(s, "EXA")) { pMga->Exa = TRUE; from = X_CONFIG; } #endif xf86DrvMsg(pScrn->scrnIndex, from, "Using %s acceleration\n", pMga->Exa ? "EXA" : "XAA"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_PCI_RETRY, FALSE)) { pMga->UsePCIRetry = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "PCI retry enabled\n"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_SYNC_ON_GREEN, FALSE)) { pMga->SyncOnGreen = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Sync-on-Green enabled\n"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_SHOWCACHE, FALSE)) { pMga->ShowCache = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "ShowCache enabled\n"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_MGA_SDRAM, FALSE)) { pMga->HasSDRAM = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Has SDRAM\n"); } if (xf86GetOptValFreq(pMga->Options, OPTION_SET_MCLK, OPTUNITS_MHZ, &real)) { pMga->MemClk = (int)(real * 1000.0); } if ((s = xf86GetOptValString(pMga->Options, OPTION_OVERLAY))) { if (!*s || !xf86NameCmp(s, "8,24") || !xf86NameCmp(s, "24,8")) { if(pScrn->bitsPerPixel == 32 && pMga->SecondCrtc == FALSE) { pMga->Overlay8Plus24 = TRUE; if(!xf86GetOptValInteger( pMga->Options, OPTION_COLOR_KEY,&(pMga->colorKey))) pMga->colorKey = TRANSPARENCY_KEY; pScrn->colorKey = pMga->colorKey; pScrn->overlayFlags = OVERLAY_8_32_PLANAR; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "PseudoColor overlay enabled\n"); } else { xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Option \"Overlay\" is only supported in 32 bits per pixel on" "the first CRTC\n"); } } else { xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "\"%s\" is not a valid value for Option \"Overlay\"\n", s); } } if(xf86GetOptValInteger(pMga->Options, OPTION_VIDEO_KEY, &(pMga->videoKey))) { xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "video key set to 0x%x\n", pMga->videoKey); } else { pMga->videoKey = (1 << pScrn->offset.red) | (1 << pScrn->offset.green) | (((pScrn->mask.blue >> pScrn->offset.blue) - 1) << pScrn->offset.blue); } if (xf86ReturnOptValBool(pMga->Options, OPTION_SHADOW_FB, FALSE)) { pMga->ShadowFB = TRUE; pMga->NoAccel = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Using \"Shadow Framebuffer\" - acceleration disabled\n"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_FBDEV, FALSE)) { pMga->FBDev = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Using framebuffer device\n"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_OVERCLOCK_MEM, FALSE)) { pMga->OverclockMem = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Overclocking memory\n"); } if (xf86ReturnOptValBool(pMga->Options, OPTION_TEXTURED_VIDEO, FALSE)) { pMga->TexturedVideo = TRUE; } if (xf86ReturnOptValBool(pMga->Options, OPTION_MERGEDFB, FALSE)) { if(!MGAISGx50(pMga)) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "\"Merged Framebuffer\" mode only supported on G450 and G550 boards.\n"); } else { #ifdef USEMGAHAL if(pMga->HALLoaded) { pMga->MergedFB = TRUE; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Using \"Merged Framebuffer\" mode.\n"); /* * a few options that won't work well together */ if(pMga->HWCursor) /*Should we give the choice? */ xf86DrvMsg(pScrn->scrnIndex, X_ERROR, " -- Hardware Cursor disabled.\n"); pMga->HWCursor = FALSE; if(pMga->ShadowFB) xf86DrvMsg(pScrn->scrnIndex, X_ERROR, " -- Shadow Framebuffer disabled.\n"); pMga->ShadowFB = FALSE; if(pMga->FBDev) xf86DrvMsg(pScrn->scrnIndex, X_ERROR, " -- Framebuffer device disabled.\n"); pMga->FBDev = FALSE; } /* MGA_HAL */ else #endif { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "HALLib not loaded! NOT using \"Merged Framebuffer\" mode.\n"); } /* MGA_NOT_HAL */ } /* ISMGAGx50() */ } if (pMga->FBDev) { /* check for linux framebuffer device */ if (!xf86LoadSubModule(pScrn, "fbdevhw")) return FALSE; xf86LoaderReqSymLists(fbdevHWSymbols, NULL); if (!fbdevHWInit(pScrn, pMga->PciInfo, NULL)) return FALSE; pScrn->SwitchMode = fbdevHWSwitchModeWeak(); pScrn->AdjustFrame = fbdevHWAdjustFrameWeak(); pScrn->EnterVT = MGAEnterVTFBDev; pScrn->LeaveVT = fbdevHWLeaveVTWeak(); pScrn->ValidMode = fbdevHWValidModeWeak(); } pMga->Rotate = 0; if ((s = xf86GetOptValString(pMga->Options, OPTION_ROTATE))) { if(!pMga->MergedFB) { if(!xf86NameCmp(s, "CW")) { pMga->ShadowFB = TRUE; pMga->NoAccel = TRUE; pMga->HWCursor = FALSE; pMga->Rotate = 1; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Rotating screen clockwise - acceleration disabled\n"); } else if(!xf86NameCmp(s, "CCW")) { pMga->ShadowFB = TRUE; pMga->NoAccel = TRUE; pMga->HWCursor = FALSE; pMga->Rotate = -1; xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Rotating screen counter clockwise - acceleration disabled\n"); } else { xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "\"%s\" is not a valid value for Option \"Rotate\"\n", s); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Valid options are \"CW\" or \"CCW\"\n"); } } else { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, " -- Rotation disabled.\n"); } } switch (pMga->Chipset) { case PCI_CHIP_MGA2064: case PCI_CHIP_MGA2164: case PCI_CHIP_MGA2164_AGP: MGA2064SetupFuncs(pScrn); break; case PCI_CHIP_MGA1064: case PCI_CHIP_MGAG100: case PCI_CHIP_MGAG100_PCI: case PCI_CHIP_MGAG200: case PCI_CHIP_MGAG200_PCI: case PCI_CHIP_MGAG200_SE_A_PCI: case PCI_CHIP_MGAG200_SE_B_PCI: case PCI_CHIP_MGAG400: case PCI_CHIP_MGAG550: MGAGSetupFuncs(pScrn); break; } /* ajv changes to reflect actual values. see sdk pp 3-2. */ /* these masks just get rid of the crap in the lower bits */ /* For the 2064 and older rev 1064, base0 is the MMIO and base1 is * the framebuffer. */ switch (pMga->chip_attribs->BARs) { case old_BARs: pMga->framebuffer_bar = 1; pMga->io_bar = 0; pMga->iload_bar = -1; break; case probe_BARs: if (pMga->ChipRev < 3) { pMga->framebuffer_bar = 1; pMga->io_bar = 0; pMga->iload_bar = 2; break; } /* FALLTHROUGH */ case new_BARs: pMga->framebuffer_bar = 0; pMga->io_bar = 1; pMga->iload_bar = 2; break; } pMga->FbAddress = pMga->PciInfo->regions[ pMga->framebuffer_bar ].base_addr; xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Linear framebuffer at 0x%lX\n", (unsigned long) pMga->PciInfo->regions[ pMga->framebuffer_bar ].base_addr ); xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "MMIO registers at 0x%lX\n", (unsigned long) pMga->PciInfo->regions[ pMga->io_bar ].base_addr ); if (pMga->iload_bar != -1) { xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Pseudo-DMA transfer window at 0x%lX\n", (unsigned long) pMga->PciInfo->regions[ pMga->iload_bar ].base_addr ); } if (xf86RegisterResources(pMga->pEnt->index, NULL, ResExclusive)) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "xf86RegisterResources() found resource conflicts\n"); MGAFreeRec(pScrn); return FALSE; } /* * Read the BIOS data struct */ mga_read_and_process_bios( pScrn ); /* Since the BIOS can swap DACs during the initialisation of G550, we need to * store which DAC this instance of the driver is taking care of. This is done * by checking a flag stored in the ROM by the BIOS at a fixed address. */ if (!pMga->SecondCrtc) pMga->SecondOutput = FALSE; else pMga->SecondOutput = TRUE; if (pMga->Chipset == PCI_CHIP_MGAG550) { if (!pMga->SecondCrtc) { pMga->SecondOutput = (pMga->BiosOutputMode & 0x1) ? TRUE : FALSE; } else { pMga->SecondOutput = (pMga->BiosOutputMode & 0x1) ? FALSE : TRUE; } } /* HW bpp matches reported bpp */ pMga->HwBpp = pScrn->bitsPerPixel; /* * Reset card if it isn't primary one */ if ( (!pMga->Primary && !pMga->FBDev) || xf86IsPc98() ) MGASoftReset(pScrn); /* * If the user has specified the amount of memory in the XF86Config * file, we respect that setting. */ from = X_PROBED; if (pMga->device->videoRam != 0) { pScrn->videoRam = pMga->device->videoRam; from = X_CONFIG; } else if (pMga->FBDev) { pScrn->videoRam = fbdevHWGetVidmem(pScrn)/1024; } else { pScrn->videoRam = MGACountRam(pScrn); } if (pMga->DualHeadEnabled) { /* This takes gives either half or 8 meg to the second head * whichever is less. */ if(pMga->SecondCrtc == FALSE) { Bool UseHalf = FALSE; int adjust; xf86GetOptValBool(pMga->Options, OPTION_CRTC2HALF, &UseHalf); adjust = pScrn->videoRam / 2; if (UseHalf == TRUE || xf86GetOptValInteger(pMga->Options, OPTION_CRTC2RAM, &adjust)) { xf86DrvMsg(pScrn->scrnIndex, X_CONFIG, "Crtc2 will use %dK of VideoRam\n", adjust); } else { adjust = min(adjust, 8192); xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Crtc2 will use %dK of VideoRam\n", adjust); } pMgaEnt->mastervideoRam = pScrn->videoRam - adjust; pScrn->videoRam = pMgaEnt->mastervideoRam; pMgaEnt->slavevideoRam = adjust; pMgaEnt->masterFbAddress = pMga->FbAddress; pMga->FbMapSize = pMgaEnt->masterFbMapSize = pScrn->videoRam * 1024; pMgaEnt->slaveFbAddress = pMga->FbAddress + pMgaEnt->masterFbMapSize; pMgaEnt->slaveFbMapSize = pMgaEnt->slavevideoRam * 1024; pMga->realSrcOrg = pMga->SrcOrg = 0; pMga->DstOrg = 0; } else { pMga->FbAddress = pMgaEnt->slaveFbAddress; pMga->FbMapSize = pMgaEnt->slaveFbMapSize; pScrn->videoRam = pMgaEnt->slavevideoRam; pMga->DstOrg = pMga->realSrcOrg = pMgaEnt->slaveFbAddress - pMgaEnt->masterFbAddress; pMga->SrcOrg = 0; /* This is not stored in hw format!! */ } pMgaEnt->refCount++; } else { /* Normal Handling of video ram etc */ pMga->FbMapSize = pScrn->videoRam * 1024; switch(pMga->Chipset) { case PCI_CHIP_MGAG550: case PCI_CHIP_MGAG400: case PCI_CHIP_MGAG200: case PCI_CHIP_MGAG200_PCI: case PCI_CHIP_MGAG200_SE_A_PCI: case PCI_CHIP_MGAG200_SE_B_PCI: pMga->SrcOrg = 0; pMga->DstOrg = 0; break; default: break; } } xf86DrvMsg(pScrn->scrnIndex, from, "VideoRAM: %d kByte\n", pScrn->videoRam); /* Set the bpp shift value */ pMga->BppShifts[0] = 0; pMga->BppShifts[1] = 1; pMga->BppShifts[2] = 0; pMga->BppShifts[3] = 2; /* * fill MGAdac struct * Warning: currently, it should be after RAM counting */ (*pMga->PreInit)(pScrn); #if !defined(__powerpc__) /* Read and print the Monitor DDC info */ pScrn->monitor->DDC = MGAdoDDC(pScrn); #endif /* !__powerpc__ */ /* * If the driver can do gamma correction, it should call xf86SetGamma() * here. */ { Gamma zeros = {0.0, 0.0, 0.0}; if (!xf86SetGamma(pScrn, zeros)) { return FALSE; } } /* XXX Set HW cursor use */ /* Set the min pixel clock */ pMga->MinClock = 12000; /* XXX Guess, need to check this */ xf86DrvMsg(pScrn->scrnIndex, X_DEFAULT, "Min pixel clock is %d MHz\n", pMga->MinClock / 1000); /* * If the user has specified ramdac speed in the XF86Config * file, we respect that setting. */ if (pMga->device->dacSpeeds[0]) { int speed = 0; switch (pScrn->bitsPerPixel) { case 8: speed = pMga->device->dacSpeeds[DAC_BPP8]; break; case 16: speed = pMga->device->dacSpeeds[DAC_BPP16]; break; case 24: speed = pMga->device->dacSpeeds[DAC_BPP24]; break; case 32: speed = pMga->device->dacSpeeds[DAC_BPP32]; break; } if (speed == 0) pMga->MaxClock = pMga->device->dacSpeeds[0]; else pMga->MaxClock = speed; from = X_CONFIG; } else { pMga->MaxClock = pMga->Dac.maxPixelClock; from = pMga->Dac.ClockFrom; } if(pMga->SecondCrtc == TRUE) { /* Override on 2nd crtc */ if ((pMga->ChipRev >= 0x80) || (pMga->Chipset == PCI_CHIP_MGAG550)) { /* G450, G550 */ pMga->MaxClock = 234000; } else { pMga->MaxClock = 135000; } } xf86DrvMsg(pScrn->scrnIndex, from, "Max pixel clock is %d MHz\n", pMga->MaxClock / 1000); /* * Setup the ClockRanges, which describe what clock ranges are available, * and what sort of modes they can be used for. */ clockRanges = xnfcalloc(sizeof(ClockRange), 1); clockRanges->next = NULL; clockRanges->minClock = pMga->MinClock; clockRanges->maxClock = pMga->MaxClock; clockRanges->clockIndex = -1; /* programmable */ clockRanges->interlaceAllowed = TRUE; clockRanges->doubleScanAllowed = TRUE; #ifdef USEMGAHAL MGA_HAL(clockRanges->interlaceAllowed = FALSE); MGA_HAL(clockRanges->doubleScanAllowed = FALSE); #endif if (pMga->SecondCrtc == TRUE) clockRanges->interlaceAllowed = FALSE; clockRanges->ClockMulFactor = 1; clockRanges->ClockDivFactor = 1; /* Only set MemClk if appropriate for the ramdac */ if (pMga->Dac.SetMemClk) { if (pMga->MemClk == 0) { pMga->MemClk = pMga->Dac.MemoryClock; from = pMga->Dac.MemClkFrom; } else from = X_CONFIG; xf86DrvMsg(pScrn->scrnIndex, from, "MCLK used is %.1f MHz\n", pMga->MemClk / 1000.0); } /* * xf86ValidateModes will check that the mode HTotal and VTotal values * don't exceed the chipset's limit if pScrn->maxHValue and * pScrn->maxVValue are set. Since our MGAValidMode() already takes * care of this, we don't worry about setting them here. */ { int Pitches1[] = {640, 768, 800, 960, 1024, 1152, 1280, 1600, 1920, 2048, 0}; int Pitches2[] = {512, 640, 768, 800, 832, 960, 1024, 1152, 1280, 1600, 1664, 1920, 2048, 0}; int *linePitches = NULL; int minPitch = 256; int maxPitch = 2048; switch(pMga->Chipset) { case PCI_CHIP_MGA2064: if (!pMga->NoAccel) { linePitches = xalloc(sizeof(Pitches1)); memcpy(linePitches, Pitches1, sizeof(Pitches1)); minPitch = maxPitch = 0; } break; case PCI_CHIP_MGA2164: case PCI_CHIP_MGA2164_AGP: case PCI_CHIP_MGA1064: if (!pMga->NoAccel) { linePitches = xalloc(sizeof(Pitches2)); memcpy(linePitches, Pitches2, sizeof(Pitches2)); minPitch = maxPitch = 0; } break; case PCI_CHIP_MGAG100: case PCI_CHIP_MGAG100_PCI: maxPitch = 2048; break; case PCI_CHIP_MGAG200: case PCI_CHIP_MGAG200_PCI: case PCI_CHIP_MGAG200_SE_A_PCI: case PCI_CHIP_MGAG200_SE_B_PCI: case PCI_CHIP_MGAG400: case PCI_CHIP_MGAG550: maxPitch = 4096; break; } i = xf86ValidateModes(pScrn, pScrn->monitor->Modes, pScrn->display->modes, clockRanges, linePitches, minPitch, maxPitch, pMga->Roundings[(pScrn->bitsPerPixel >> 3) - 1] * pScrn->bitsPerPixel, 128, 2048, pScrn->display->virtualX, pScrn->display->virtualY, pMga->FbMapSize, LOOKUP_BEST_REFRESH); if (linePitches) xfree(linePitches); } if (i < 1 && pMga->FBDev) { fbdevHWUseBuildinMode(pScrn); pScrn->displayWidth = pScrn->virtualX; /* FIXME: might be wrong */ i = 1; } if (i == -1) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Validate Modes Failed\n"); MGAFreeRec(pScrn); return FALSE; } /* Prune the modes marked as invalid */ xf86PruneDriverModes(pScrn); if (i == 0 || pScrn->modes == NULL) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "No valid modes found\n"); MGAFreeRec(pScrn); return FALSE; } #ifdef USEMGAHAL MGA_HAL( if(pMga->SecondCrtc == FALSE) { pMga->pBoard = xalloc(sizeof(CLIENTDATA) + MGAGetBOARDHANDLESize()); pMga->pClientStruct = xalloc(sizeof(CLIENTDATA)); pMga->pClientStruct->pMga = (MGAPtr) pMga; MGAMapMem(pScrn); /* * For some reason the MGAOPM_DMA_BLIT bit needs to be set * on G200 before opening the HALlib. I don't know why. * MATROX: hint, hint. */ /*if (pMga->Chipset == PCI_CHIP_MGAG200 || pMga->Chipset == PCI_CHIP_MGAG200_PCI) */{ CARD32 opmode; opmode = INREG(MGAREG_OPMODE); OUTREG(MGAREG_OPMODE, MGAOPM_DMA_BLIT | opmode); } /* wrapping OpenLibrary to fix broken registers. MATROX: hint, hint. */ MiscCtlReg = inMGAdac(MGA1064_MISC_CTL); MGAOpenLibrary(pMga->pBoard,pMga->pClientStruct,sizeof(CLIENTDATA)); outMGAdac(MGA1064_MISC_CTL,MiscCtlReg); MGAUnmapMem(pScrn); pMga->pMgaHwInfo = xalloc(sizeof(MGAHWINFO)); MGAGetHardwareInfo(pMga->pBoard,pMga->pMgaHwInfo); /* copy the board handles */ if (pMga->DualHeadEnabled) { pMgaEnt->pClientStruct = pMga->pClientStruct; pMgaEnt->pBoard = pMga->pBoard; pMgaEnt->pMgaHwInfo = pMga->pMgaHwInfo; } } else { /* Second CRTC && entity is shared */ pMga->pBoard = pMgaEnt->pBoard; pMga->pClientStruct = pMgaEnt->pClientStruct; pMga->pMgaHwInfo = pMgaEnt->pMgaHwInfo; } MGAFillModeInfoStruct(pScrn,NULL); /* Fields usually handled by MGAFillModeInfoStruct, but are unavailable * because no mode is given */ pMga->pMgaModeInfo->ulDispWidth = pScrn->virtualX; pMga->pMgaModeInfo->ulDispHeight = pScrn->virtualY; if (ISDIGITAL1(pMga)) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Digital screen detected on first head.\n"); if (ISTV1(pMga)) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "TV detected on first head.\n"); if (ISDIGITAL2(pMga)) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Digital screen detected on second head.\n"); if (ISTV2(pMga)) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "TV detected on second head.\n"); if((status = MGAValidateMode(pMga->pBoard,pMga->pMgaModeInfo)) != 0) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "MGAValidateMode from HALlib found the mode to be invalid.\n" "\tError: 0x%lx\n", status); return FALSE; } pScrn->displayWidth = pMga->pMgaModeInfo->ulFBPitch; ); /* MGA_HAL */ #endif /* If the Device section explicitly set HasSDRAM, don't bother checking. */ if (!pMga->HasSDRAM) { if ((pMga->softbooted || pMga->Primary) && pMga->chip_attribs->probe_for_sdram) { uint32_t option_reg; pci_device_cfg_read_u32(pMga->PciInfo, & option_reg, PCI_OPTION_REG); pMga->HasSDRAM = ((option_reg & (1 << 14)) == 0); } else { pMga->HasSDRAM = pMga->chip_attribs->has_sdram; } if (pMga->HasSDRAM) { xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Has SDRAM\n"); } } /* * Set the CRTC parameters for all of the modes based on the type * of mode, and the chipset's interlace requirements. * * Calling this is required if the mode->Crtc* values are used by the * driver and if the driver doesn't provide code to set them. They * are not pre-initialised at all. */ #ifdef USEMGAHAL MGA_HAL(xf86SetCrtcForModes(pScrn, 0)); #endif MGA_NOT_HAL(xf86SetCrtcForModes(pScrn, INTERLACE_HALVE_V)); /* Set the current mode to the first in the list */ pScrn->currentMode = pScrn->modes; /* Print the list of modes being used */ xf86PrintModes(pScrn); /* Set display resolution */ xf86SetDpi(pScrn, 0, 0); /* * Compute the byte offset into the linear frame buffer where the * frame buffer data should actually begin. According to DDK misc.c * line 1023, if more than 4MB is to be displayed, YDSTORG must be set * appropriately to align memory bank switching, and this requires a * corresponding offset on linear frame buffer access. * This is only needed for WRAM. */ pMga->YDstOrg = 0; if (pMga->chip_attribs->fb_4mb_quirk && (pScrn->virtualX * pScrn->virtualY * bytesPerPixel > 4*1024*1024)) { int offset; int offset_modulo = (pScrn->bitsPerPixel == 24) ? 12 : 4; int ydstorg_modulo = 64; if (pMga->Interleave) { offset_modulo <<= 1; ydstorg_modulo <<= 1; } offset = (4*1024*1024) % (pScrn->displayWidth * bytesPerPixel); pMga->YDstOrg = offset / bytesPerPixel; /* * When this was unconditional, it caused a line of horizontal garbage * at the middle right of the screen at the 4Meg boundary in 32bpp * (and presumably any other modes that use more than 4M). But it's * essential for 24bpp (it may not matter either way for 8bpp & 16bpp, * I'm not sure; I didn't notice problems when I checked with and * without.) * DRM Doug Merritt 12/97, submitted to XFree86 6/98 (oops) */ if (bytesPerPixel < 4) { while ((offset % offset_modulo) != 0 || (pMga->YDstOrg % ydstorg_modulo) != 0) { offset++; pMga->YDstOrg = offset / bytesPerPixel; } } } xf86DrvMsgVerb(pScrn->scrnIndex, X_INFO, 2, "YDstOrg is set to %d\n", pMga->YDstOrg); if(pMga->DualHeadEnabled) { if(pMga->SecondCrtc == FALSE) { pMga->FbUsableSize = pMgaEnt->masterFbMapSize; /* Allocate HW cursor buffer at the end of video ram */ if( pMga->HWCursor && pMga->Dac.CursorOffscreenMemSize ) { if( pScrn->virtualY * pScrn->displayWidth * pScrn->bitsPerPixel / 8 <= pMga->FbUsableSize - pMga->Dac.CursorOffscreenMemSize ) { pMga->FbUsableSize -= pMga->Dac.CursorOffscreenMemSize; pMga->FbCursorOffset = pMgaEnt->masterFbMapSize - pMga->Dac.CursorOffscreenMemSize; } else { pMga->HWCursor = FALSE; xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Too little offscreen memory for HW cursor; " "using SW cursor\n"); } } } else { /* Second CRTC */ pMga->FbUsableSize = pMgaEnt->slaveFbMapSize; pMga->HWCursor = FALSE; } } else { pMga->FbUsableSize = pMga->FbMapSize - pMga->YDstOrg * bytesPerPixel; /* Allocate HW cursor buffer at the end of video ram */ if( pMga->HWCursor && pMga->Dac.CursorOffscreenMemSize ) { if( pScrn->virtualY * pScrn->displayWidth * pScrn->bitsPerPixel / 8 <= pMga->FbUsableSize - pMga->Dac.CursorOffscreenMemSize ) { pMga->FbUsableSize -= pMga->Dac.CursorOffscreenMemSize; pMga->FbCursorOffset = pMga->FbMapSize - pMga->Dac.CursorOffscreenMemSize; } else { pMga->HWCursor = FALSE; xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Too little offscreen memory for HW cursor; " "using SW cursor\n"); } } } /* * XXX This should be taken into account in some way in the mode valdation * section. */ /* Load the required framebuffer */ if (pMga->Overlay8Plus24) { if (!xf86LoadSubModule(pScrn, "xf8_32bpp")) { MGAFreeRec(pScrn); return FALSE; } xf86LoaderReqSymLists(xf8_32bppSymbols, NULL); } else { if (!xf86LoadSubModule(pScrn, "fb")) { MGAFreeRec(pScrn); return FALSE; } xf86LoaderReqSymLists(fbSymbols, NULL); } /* Load XAA if needed */ if (!pMga->NoAccel) { #ifdef USE_EXA if (pMga->Exa) { if (!xf86LoadSubModule(pScrn, "exa")) { MGAFreeRec(pScrn); return FALSE; } else xf86LoaderReqSymLists(exaSymbols, NULL); } else { #endif #ifdef USE_XAA if (!xf86LoadSubModule(pScrn, "xaa")) { MGAFreeRec(pScrn); return FALSE; } else xf86LoaderReqSymLists(xaaSymbols, NULL); #endif #ifdef USE_EXA } #endif } /* Load ramdac if needed */ if (pMga->HWCursor) { if (!xf86LoadSubModule(pScrn, "ramdac")) { MGAFreeRec(pScrn); return FALSE; } xf86LoaderReqSymLists(ramdacSymbols, NULL); } /* Load shadowfb if needed */ if (pMga->ShadowFB) { if (!xf86LoadSubModule(pScrn, "shadowfb")) { MGAFreeRec(pScrn); return FALSE; } xf86LoaderReqSymLists(shadowSymbols, NULL); } #ifdef XF86DRI /* Load the dri module if requested. */ if (xf86ReturnOptValBool(pMga->Options, OPTION_DRI, FALSE)) { if (xf86LoadSubModule(pScrn, "dri")) { xf86LoaderReqSymLists(driSymbols, drmSymbols, NULL); } } #endif pMga->CurrentLayout.bitsPerPixel = pScrn->bitsPerPixel; pMga->CurrentLayout.depth = pScrn->depth; pMga->CurrentLayout.displayWidth = pScrn->displayWidth; pMga->CurrentLayout.weight.red = pScrn->weight.red; pMga->CurrentLayout.weight.green = pScrn->weight.green; pMga->CurrentLayout.weight.blue = pScrn->weight.blue; pMga->CurrentLayout.Overlay8Plus24 = pMga->Overlay8Plus24; pMga->CurrentLayout.mode = pScrn->currentMode; if(pMga->MergedFB) { MGAPreInitMergedFB(pScrn,flags); }; #ifdef USEMGAHAL MGA_HAL( /* Close the library after preinit */ /* This needs to only happen after this board has completed preinit * both times */ if(pMga->DualHeadEnabled) { /* Entity is shared make sure refcount == 2 */ /* If ref count is 2 then reset it to 0 */ if(pMgaEnt->refCount == 2) { /* Both boards have done there initialization */ MGACloseLibrary(pMga->pBoard); if (pMga->pBoard) xfree(pMga->pBoard); if (pMga->pClientStruct) xfree(pMga->pClientStruct); if (pMga->pMgaModeInfo) xfree(pMga->pMgaModeInfo); if (pMga->pMgaHwInfo) xfree(pMga->pMgaHwInfo); pMgaEnt->refCount = 0; } } else { MGACloseLibrary(pMga->pBoard); if (pMga->pBoard) xfree(pMga->pBoard); if (pMga->pClientStruct) xfree(pMga->pClientStruct); if (pMga->pMgaModeInfo) xfree(pMga->pMgaModeInfo); if (pMga->pMgaHwInfo) xfree(pMga->pMgaHwInfo); } ); /* MGA_HAL */ #endif xf86SetPrimInitDone(pScrn->entityList[0]); return TRUE; } /* * Map the framebuffer and MMIO memory. */ static Bool MGAMapMem(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); struct pci_device * const dev = pMga->PciInfo; int err; err = pci_device_map_region(dev, 0, TRUE); if (err) { return FALSE; } err = pci_device_map_region(dev, 1, TRUE); if (err) { return FALSE; } pMga->IOBase = dev->regions[ pMga->io_bar ].memory; pMga->FbBase = dev->regions[ pMga->framebuffer_bar ].memory; pMga->ILOADBase = NULL; if (pMga->iload_bar != -1) { err = pci_device_map_region(dev, 2, TRUE); if (err) { return FALSE; } pMga->ILOADBase = dev->regions[ pMga->iload_bar ].memory; } return TRUE; } static Bool MGAMapMemFBDev(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); struct pci_device * const dev = pMga->PciInfo; int err; pMga->FbBase = fbdevHWMapVidmem(pScrn); if (pMga->FbBase == NULL) return FALSE; pMga->IOBase = fbdevHWMapMMIO(pScrn); if (pMga->IOBase == NULL) return FALSE; pMga->FbStart = pMga->FbBase + pMga->YDstOrg * (pScrn->bitsPerPixel / 8); /* Can't ask matroxfb for a mapping of the ILOAD window. */ pMga->ILOADBase = NULL; if (pMga->iload_bar != -1) { err = pci_device_map_region(dev, 2, TRUE); if (err) { return FALSE; } pMga->ILOADBase = dev->regions[ pMga->iload_bar ].memory; } return TRUE; } /* * Unmap the framebuffer and MMIO memory. */ static Bool MGAUnmapMem(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); struct pci_device * const dev = pMga->PciInfo; unsigned i; for (i = 0 ; i < 6 ; i++) { if (dev->regions[i].memory != NULL) { pci_device_unmap_region(dev, i); } } pMga->IOBase = NULL; pMga->FbBase = NULL; pMga->FbStart = NULL; pMga->ILOADBase = NULL; return TRUE; } static Bool MGAUnmapMemFBDev(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); struct pci_device * const dev = pMga->PciInfo; fbdevHWUnmapVidmem(pScrn); fbdevHWUnmapMMIO(pScrn); if ((pMga->iload_bar != -1) && (dev->regions[ pMga->iload_bar ].memory != NULL)) { pci_device_unmap_region(dev, pMga->iload_bar); } pMga->FbBase = NULL; pMga->FbStart = NULL; pMga->IOBase = NULL; pMga->ILOADBase = NULL; return TRUE; } /* * This function saves the video state. */ static void MGASave(ScrnInfoPtr pScrn) { vgaHWPtr hwp = VGAHWPTR(pScrn); vgaRegPtr vgaReg = &hwp->SavedReg; MGAPtr pMga = MGAPTR(pScrn); MGARegPtr mgaReg = &pMga->SavedReg; if(pMga->SecondCrtc == TRUE) return; #ifdef USEMGAHAL MGA_HAL(if (pMga->pBoard != NULL) MGASaveVgaState(pMga->pBoard)); #endif /* I need to save the registers for the second head also */ /* Save the register for 0x80 to 0xa0 */ /* Could call it dac2Saved */ /* Only save text mode fonts/text for the primary card */ (*pMga->Save)(pScrn, vgaReg, mgaReg, pMga->Primary); } #ifdef USEMGAHAL /* Convert DisplayModeRec parameters in MGAMODEINFO parameters. * mode parameter optionnal. */ void MGAFillModeInfoStruct(ScrnInfoPtr pScrn, DisplayModePtr mode) { const char *s; MGAPtr pMga = MGAPTR(pScrn); Bool digital1 = FALSE; Bool digital2 = FALSE; Bool tv1 = FALSE; Bool tv2 = FALSE; Bool swap_head = xf86ReturnOptValBool(pMga->Options, OPTION_SWAPPED_HEAD, FALSE); if(pMga->MergedFB && mode && mode->Private && (mode->PrivSize == 0)) { mode = pMga->SecondCrtc ? ((MergedDisplayModePtr)mode->Private)->Monitor2 : ((MergedDisplayModePtr)mode->Private)->Monitor1; } if (pMga->pMgaHwInfo) { digital1 = ISDIGITAL1(pMga); digital2 = ISDIGITAL2(pMga); tv1 = ISTV1(pMga); tv2 = ISTV2(pMga); } /*FIXME: causes segfault elsewhere if not commented*/ /*if(!pMga->pMgaModeInfo)*/ pMga->pMgaModeInfo = xalloc(sizeof(MGAMODEINFO)); pMga->pMgaModeInfo->flOutput = 0; pMga->pMgaModeInfo->ulDeskWidth = pScrn->virtualX; pMga->pMgaModeInfo->ulDeskHeight = pScrn->virtualY; pMga->pMgaModeInfo->ulFBPitch = 0; pMga->pMgaModeInfo->ulBpp = pScrn->bitsPerPixel; pMga->pMgaModeInfo->ulZoom = 1; pMga->pMgaModeInfo->flSignalMode = 0x10; /* Set TV standard */ if ((s = xf86GetOptValString(pMga->Options, OPTION_TVSTANDARD))) { if (!xf86NameCmp(s, "PAL")) { pMga->pMgaModeInfo->flSignalMode = 0x00; pMga->pMgaModeInfo->ulRefreshRate = 50; pMga->pMgaModeInfo->ulTVStandard = TV_PAL; } else { pMga->pMgaModeInfo->ulRefreshRate = 60; pMga->pMgaModeInfo->ulTVStandard = TV_NTSC; } } else { pMga->pMgaModeInfo->ulRefreshRate = 0; pMga->pMgaModeInfo->ulTVStandard = TV_NTSC; } /* Set Cable Type */ if ((s = xf86GetOptValString(pMga->Options, OPTION_CABLETYPE))) { if (!xf86NameCmp(s, "SCART_RGB")) { pMga->pMgaModeInfo->ulCableType = TV_SCART_RGB; } else if (!xf86NameCmp(s, "SCART_COMPOSITE")) { pMga->pMgaModeInfo->ulCableType = TV_SCART_COMPOSITE; } else if (!xf86NameCmp(s, "SCART_TYPE2")) { pMga->pMgaModeInfo->ulCableType = TV_SCART_TYPE2; } else { pMga->pMgaModeInfo->ulCableType = TV_YC_COMPOSITE; } } else { pMga->pMgaModeInfo->ulCableType = TV_YC_COMPOSITE; } if(mode) { pMga->pMgaModeInfo->ulHorizRate = 0; pMga->pMgaModeInfo->ulDispWidth = mode->HDisplay; pMga->pMgaModeInfo->ulDispHeight = mode->VDisplay; pMga->pMgaModeInfo->ulPixClock = mode->Clock; pMga->pMgaModeInfo->ulHFPorch = mode->HSyncStart - mode->HDisplay; pMga->pMgaModeInfo->ulHSync = mode->HSyncEnd - mode->HSyncStart; pMga->pMgaModeInfo->ulHBPorch = mode->HTotal - mode->HSyncEnd; pMga->pMgaModeInfo->ulVFPorch = mode->VSyncStart - mode->VDisplay; pMga->pMgaModeInfo->ulVSync = mode->VSyncEnd - mode->VSyncStart; pMga->pMgaModeInfo->ulVBPorch = mode->VTotal - mode->VSyncEnd; } /* Use DstOrg directly */ /* This is an offset in pixels not memory */ pMga->pMgaModeInfo->ulDstOrg = pMga->DstOrg / (pScrn->bitsPerPixel / 8); pMga->pMgaModeInfo->ulDisplayOrg = pMga->DstOrg / (pScrn->bitsPerPixel / 8); pMga->pMgaModeInfo->ulPanXGran = 0; pMga->pMgaModeInfo->ulPanYGran = 0; if(pMga->SecondCrtc == TRUE) { pMga->pMgaModeInfo->flOutput = MGAMODEINFO_SECOND_CRTC | MGAMODEINFO_FORCE_PITCH | MGAMODEINFO_FORCE_DISPLAYORG; if (digital2) { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_DIGITAL2; } else if (tv2) { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_TV; } else { if (!swap_head) { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_ANALOG2; } else { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_ANALOG1; } } } else { pMga->pMgaModeInfo->flOutput = MGAMODEINFO_FORCE_PITCH; if (digital1) { if ((pMga->Chipset == PCI_CHIP_MGAG200) || (pMga->Chipset == PCI_CHIP_MGAG200_PCI)) { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_FLATPANEL1; pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_DIGITAL2; } else { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_DIGITAL1; } } else if (tv1) { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_TV; } else { if (!swap_head) { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_ANALOG1; } else { pMga->pMgaModeInfo->flOutput |= MGAMODEINFO_ANALOG2; } } } pMga->pMgaModeInfo->ulFBPitch = pScrn->displayWidth; } #endif /* * Initialise a new mode. This is currently still using the old * "initialise struct, restore/write struct to HW" model. That could * be changed. */ static Bool MGAModeInit(ScrnInfoPtr pScrn, DisplayModePtr mode) { vgaHWPtr hwp = VGAHWPTR(pScrn); vgaRegPtr vgaReg; MGAPtr pMga = MGAPTR(pScrn); MGARegPtr mgaReg; #ifdef USEMGAHAL ULONG status; #endif vgaHWUnlock(hwp); /* if(pMga->MergedFB && mode && mode->Private && (mode->PrivSize == 0)) { mode = (DisplayModePtr)mode->Private; }*/ /* Initialise the ModeReg values */ if (!vgaHWInit(pScrn, mode)) return FALSE; pScrn->vtSema = TRUE; if (!(*pMga->ModeInit)(pScrn, mode)) return FALSE; /* Program the registers */ vgaHWProtect(pScrn, TRUE); vgaReg = &hwp->ModeReg; mgaReg = &pMga->ModeReg; #ifdef USEMGAHAL MGA_HAL( MGAFillModeInfoStruct(pScrn,mode); /* Validate the parameters */ if ((status = MGAValidateMode(pMga->pBoard, pMga->pMgaModeInfo)) != 0) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "MGAValidateMode from HALlib found the mode to be invalid.\n" "\tError: %lx\n", status); return FALSE; } /* * Find mode for second head. */ if(pMga->MergedFB) { MGAFillModeInfoStruct(pMga->pScrn2,mode); /* Validates the Video parameters */ if ((status = MGAValidateVideoParameters(pMga->pBoard, MGAPTR(pMga->pScrn2)->pMgaModeInfo)) != 0) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "MGAValidateVideoParameters from HALlib found the mode to be invalid.\n\tError: %lx\n", status); return FALSE; } } ); /*MGA_HAL */ #endif #ifdef USEMGAHAL MGA_HAL( /*************************** ESC *****************************/ TmpMgaModeInfo[0] = *pMga->pMgaModeInfo; if(pMga->SecondCrtc == TRUE) pMgaModeInfo[1] = pMga->pMgaModeInfo; else pMgaModeInfo[0] = pMga->pMgaModeInfo; TmpMgaModeInfo[0].ulDispWidth = 0; if(!pMga->MergedFB) /* FIXME: Must deal with this once PowerDesk & MergedFB compatibility will exist */ MGAFillDisplayModeStruct(mode, pMga->pMgaModeInfo); /*************************************************************/ ); /* MGA_HAL */ #endif #ifdef XF86DRI if (pMga->directRenderingEnabled) { DRILock(screenInfo.screens[pScrn->scrnIndex], 0); } #endif #ifdef USEMGAHAL MGA_HAL( /* Initialize the board */ if(MGASetMode(pMga->pBoard,pMga->pMgaModeInfo) != 0) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "MGASetMode returned an error." " Make sure to validate the mode before.\n"); return FALSE; } if(pMga->MergedFB && MGASetMode(pMga->pBoard,MGAPTR(pMga->pScrn2)->pMgaModeInfo) != 0) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "MGASetMode returned an error." " Make sure to validate the mode before.\n"); } ); /* MGA_HAL */ /* getting around bugs in the HAL lib. MATROX: hint, hint. */ MGA_HAL( if (pMga->chip_attribs->hwcursor_1064) { if(pMga->SecondCrtc == FALSE && pMga->HWCursor == TRUE) { outMGAdac(MGA1064_CURSOR_BASE_ADR_LOW, pMga->FbCursorOffset >> 10); outMGAdac(MGA1064_CURSOR_BASE_ADR_HI, pMga->FbCursorOffset >> 18); outMGAdac(MGA1064_CURSOR_CTL, 0x00); } if (pMga->Overlay8Plus24 == TRUE) { outMGAdac(MGA1064_MUL_CTL, MGA1064_MUL_CTL_32bits); outMGAdac(MGA1064_COL_KEY_MSK_LSB,0xFF); outMGAdac(MGA1064_COL_KEY_LSB,pMga->colorKey); outMGAdac(MGA1064_COL_KEY_MSK_MSB,0xFF); outMGAdac(MGA1064_COL_KEY_MSB,0xFF); } } ); /* MGA_HAL */ #endif MGA_NOT_HAL((*pMga->Restore)(pScrn, vgaReg, mgaReg, FALSE)); MGAStormSync(pScrn); MGAStormEngineInit(pScrn); vgaHWProtect(pScrn, FALSE); if (xf86IsPc98()) { if (pMga->Chipset == PCI_CHIP_MGA2064) outb(0xfac, 0x01); else outb(0xfac, 0x02); } pMga->CurrentLayout.mode = mode; if(pMga->MergedFB && mode->Private && (mode->PrivSize == 0)) { pMga->M1currentMode = (DisplayModePtr)mode->Private; } #ifdef XF86DRI if (pMga->directRenderingEnabled) DRIUnlock(screenInfo.screens[pScrn->scrnIndex]); #endif #ifdef DEBUG MGAG450PrintPLL(pScrn); #endif return TRUE; } static void MGARestoreSecondCrtc(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); if (MGAISGx50(pMga)) { /* Force to return in clone mode */ if (pMga->SecondOutput && (xf86IsEntityShared(pScrn->entityList[0]) || pMga->SecondCrtc) && !pMga->MergedFB) { /* Do this branch if * SecondOutput * and not Unshared Primary * and not Merged Mode (usualy means Unshared Primary) */ CARD8 ucXDispCtrl = inMGAdac(MGA1064_DISP_CTL); ucXDispCtrl &= ~0x0c; /* dac2outsel mask */ ucXDispCtrl |= 0x04; /* dac2 -> crtc1 */ outMGAdac(MGA1064_DISP_CTL, ucXDispCtrl); } else { CARD8 ucXDispCtrl = inMGAdac(MGA1064_DISP_CTL); CARD32 ulC2CTL = INREG(MGAREG_C2CTL); ucXDispCtrl &= ~0x0c; /* dac2outsel mask */ ucXDispCtrl |= 0x5; /* dac1outsel -> crtcdacsel, dac2 -> crtc1 */ ulC2CTL &= ~0x00100000; /* crtcdacsel -> crtc1 */ outMGAdac(MGA1064_DISP_CTL, ucXDispCtrl); OUTREG(MGAREG_C2CTL, ulC2CTL); } } else { /* Force to close second crtc */ CARD32 ulC2CTL = INREG(MGAREG_C2CTL); ulC2CTL &= ~0x1; /* crtc2 disabled */ OUTREG(MGAREG_C2CTL, ulC2CTL); } return; } /* * Restore the initial (text) mode. */ static void MGARestore(ScrnInfoPtr pScrn) { vgaHWPtr hwp = VGAHWPTR(pScrn); vgaRegPtr vgaReg = &hwp->SavedReg; MGAPtr pMga = MGAPTR(pScrn); MGARegPtr mgaReg = &pMga->SavedReg; if (pScrn->pScreen != NULL) MGAStormSync(pScrn); /* * Restore the second crtc if: * first and only driver entity * second entity * Merged Framebuffer mode (first and only driver entity) */ if((!xf86IsEntityShared(pScrn->entityList[0]) && !pMga->SecondCrtc) || pMga->SecondCrtc || pMga->MergedFB) { /* if(pMga->MergedFB) { if(pMga->pScrn2) MGARestoreSecondCrtc(pMga->pScrn2); } else*/ MGARestoreSecondCrtc(pScrn); /* if we are second instance of driver, we've done our job, exit */ if(pMga->SecondCrtc) return; } /* Only restore text mode fonts/text for the primary card */ vgaHWProtect(pScrn, TRUE); if (pMga->Primary) { #ifdef USEMGAHAL MGA_HAL( if(pMga->pBoard != NULL) { MGASetVgaMode(pMga->pBoard); MGARestoreVgaState(pMga->pBoard); } ); /* MGA_HAL */ #endif (*pMga->Restore)(pScrn, vgaReg, mgaReg, TRUE); } else { vgaHWRestore(pScrn, vgaReg, VGA_SR_MODE); } vgaHWProtect(pScrn, FALSE); } /* Workaround for a G400 CRTC2 display problem */ static void MGACrtc2FillStrip(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); if (pMga->NoAccel) { /* Clears the whole screen, but ... */ bzero(pMga->FbStart, (pScrn->bitsPerPixel >> 3) * pScrn->displayWidth * pScrn->virtualY); } else { xf86SetLastScrnFlag(pScrn->entityList[0], pScrn->scrnIndex); pMga->RestoreAccelState(pScrn); pMga->SetupForSolidFill(pScrn, 0, GXcopy, 0xFFFFFFFF); pMga->SubsequentSolidFillRect(pScrn, pScrn->virtualX, 0, pScrn->displayWidth - pScrn->virtualX, pScrn->virtualY); MGAStormSync(pScrn); } } /* Mandatory */ /* This gets called at the start of each server generation */ static Bool MGAScreenInit(int scrnIndex, ScreenPtr pScreen, int argc, char **argv) { ScrnInfoPtr pScrn; vgaHWPtr hwp; MGAPtr pMga; MGARamdacPtr MGAdac; int ret; VisualPtr visual; unsigned char *FBStart; int width, height, displayWidth; MGAEntPtr pMgaEnt = NULL; int f; CARD32 VRTemp, FBTemp; #ifdef XF86DRI MessageType driFrom = X_DEFAULT; #endif /* * First get the ScrnInfoRec */ pScrn = xf86Screens[pScreen->myNum]; hwp = VGAHWPTR(pScrn); pMga = MGAPTR(pScrn); MGAdac = &pMga->Dac; if (pMga->is_G200SE) { VRTemp = pScrn->videoRam; FBTemp = pMga->FbMapSize; pScrn->videoRam = 4096; pMga->FbMapSize = pScrn->videoRam * 1024; } /* Map the MGA memory and MMIO areas */ if (pMga->FBDev) { if (!MGAMapMemFBDev(pScrn)) return FALSE; } else { if (!MGAMapMem(pScrn)) return FALSE; } if ((pMga->Chipset == PCI_CHIP_MGAG100) || (pMga->Chipset == PCI_CHIP_MGAG100_PCI)) MGAG100BlackMagic(pScrn); if (pMga->DualHeadEnabled) { DevUnion *pPriv; pPriv = xf86GetEntityPrivate(pScrn->entityList[0], MGAEntityIndex); pMgaEnt = pPriv->ptr; pMgaEnt->refCount++; #ifdef USEMGAHAL MGA_HAL( if(pMgaEnt->refCount == 1) { CARD8 MiscCtlReg; pMga->pBoard = xalloc(sizeof(CLIENTDATA) + MGAGetBOARDHANDLESize()); pMga->pClientStruct = xalloc(sizeof(CLIENTDATA)); pMga->pClientStruct->pMga = (MGAPtr) pMga; /* wrapping OpenLibrary to fix broken registers. MATROX: hint,hint.*/ MiscCtlReg = inMGAdac(MGA1064_MISC_CTL); MGAOpenLibrary(pMga->pBoard,pMga->pClientStruct,sizeof(CLIENTDATA)); outMGAdac(MGA1064_MISC_CTL,MiscCtlReg); pMga->pMgaHwInfo = xalloc(sizeof(MGAHWINFO)); MGAGetHardwareInfo(pMga->pBoard,pMga->pMgaHwInfo); /* Detecting for type of display */ if (pMga->pMgaHwInfo->ulCapsSecondOutput & MGAHWINFOCAPS_OUTPUT_TV) { xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "TV detected\n"); } if (pMga->pMgaHwInfo->ulCapsFirstOutput & MGAHWINFOCAPS_OUTPUT_DIGITAL) { xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Digital Screen detected\n"); } if (pMga->pMgaHwInfo->ulCapsSecondOutput & MGAHWINFOCAPS_OUTPUT_DIGITAL) { xf86DrvMsg(pScrn->scrnIndex, X_PROBED, "Digital Screen detected\n"); } /* Now copy these to the entitystructure */ pMgaEnt->pClientStruct = pMga->pClientStruct; pMgaEnt->pBoard = pMga->pBoard; pMgaEnt->pMgaHwInfo = pMga->pMgaHwInfo; } else { /* Ref count is 2 */ pMga->pClientStruct = pMgaEnt->pClientStruct; pMga->pBoard = pMgaEnt->pBoard; pMga->pMgaHwInfo = pMgaEnt->pMgaHwInfo; } ); /* MGA_HAL */ #endif } else { #ifdef USEMGAHAL CARD8 MiscCtlReg; MGA_HAL( pMga->pBoard = xalloc(sizeof(CLIENTDATA) + MGAGetBOARDHANDLESize()); pMga->pClientStruct = xalloc(sizeof(CLIENTDATA)); pMga->pClientStruct->pMga = (MGAPtr) pMga; MiscCtlReg = inMGAdac(MGA1064_MISC_CTL); /* wrapping OpenLibrary to fix broken registers. MATROX: hint,hint.*/ MGAOpenLibrary(pMga->pBoard,pMga->pClientStruct,sizeof(CLIENTDATA)); outMGAdac(MGA1064_MISC_CTL,MiscCtlReg); pMga->pMgaHwInfo = xalloc(sizeof(MGAHWINFO)); MGAGetHardwareInfo(pMga->pBoard,pMga->pMgaHwInfo); ); /* MGA_HAL */ #endif } if (pMga->is_G200SE) { pScrn->videoRam = VRTemp; pMga->FbMapSize = FBTemp; } #ifdef USEMGAHAL MGA_HAL( /* There is a problem in the HALlib: set soft reset bit */ /* MATROX: hint, hint. */ if (!pMga->Primary && !pMga->FBDev && (pMga->PciInfo->subdevice_id == PCI_CARD_MILL_G200_SG) ) { OUTREG(MGAREG_Reset, 1); usleep(200); OUTREG(MGAREG_Reset, 0); } ); /* MGA_HAL */ #endif /* Initialise the MMIO vgahw functions */ vgaHWSetMmioFuncs(hwp, pMga->IOBase, PORT_OFFSET); vgaHWGetIOBase(hwp); /* Map the VGA memory when the primary video */ if (pMga->Primary && !pMga->FBDev) { hwp->MapSize = 0x10000; if (!vgaHWMapMem(pScrn)) return FALSE; } if (pMga->FBDev) { fbdevHWSave(pScrn); /* Disable VGA core, and leave memory access on */ pci_device_cfg_write_bits(pMga->PciInfo, 0x00000100, 0x00000000, PCI_OPTION_REG); if (!fbdevHWModeInit(pScrn, pScrn->currentMode)) return FALSE; if (!pMga->SecondCrtc && pMga->HWCursor && pMga->chip_attribs->hwcursor_1064) { outMGAdac(MGA1064_CURSOR_BASE_ADR_LOW, pMga->FbCursorOffset >> 10); outMGAdac(MGA1064_CURSOR_BASE_ADR_HI, pMga->FbCursorOffset >> 18); } MGAStormEngineInit(pScrn); } else { /* Save the current state */ MGASave(pScrn); /* Initialise the first mode */ if (!MGAModeInit(pScrn, pScrn->currentMode)) return FALSE; } /* Darken the screen for aesthetic reasons and set the viewport */ if (pMga->SecondCrtc == TRUE && !pMga->MergedFB) { MGASaveScreenCrtc2(pScreen, SCREEN_SAVER_ON); } if (pMga->SecondCrtc == FALSE && !pMga->MergedFB) { MGASaveScreen(pScreen, SCREEN_SAVER_ON); } if( pMga->MergedFB ) { MGASaveScreenMerged( pScreen, SCREEN_SAVER_ON ); } pScrn->AdjustFrame(scrnIndex, pScrn->frameX0, pScrn->frameY0, 0); /* * The next step is to setup the screen's visuals, and initialise the * framebuffer code. In cases where the framebuffer's default * choices for things like visual layouts and bits per RGB are OK, * this may be as simple as calling the framebuffer's ScreenInit() * function. If not, the visuals will need to be setup before calling * a fb ScreenInit() function and fixed up after. * * For most PC hardware at depths >= 8, the defaults that cfb uses * are not appropriate. In this driver, we fixup the visuals after. */ /* * Reset the visual list. */ miClearVisualTypes(); /* Setup the visuals we support. */ /* All MGA support DirectColor and can do overlays in 32bpp */ if(pMga->Overlay8Plus24 && (pScrn->bitsPerPixel == 32)) { if (!miSetVisualTypes(8, PseudoColorMask | GrayScaleMask, pScrn->rgbBits, PseudoColor)) return FALSE; if (!miSetVisualTypes(24, TrueColorMask, pScrn->rgbBits, TrueColor)) return FALSE; } else if (pMga->SecondCrtc) { /* No DirectColor on the second head */ if (!miSetVisualTypes(pScrn->depth, TrueColorMask, pScrn->rgbBits, TrueColor)) return FALSE; if (!miSetPixmapDepths ()) return FALSE; } else { if (!xf86SetDefaultVisual(pScrn, -1)) return FALSE; if (!miSetVisualTypes(pScrn->depth, miGetDefaultVisualMask(pScrn->depth), pScrn->rgbBits, pScrn->defaultVisual)) return FALSE; if (!miSetPixmapDepths ()) return FALSE; } /* * Call the framebuffer layer's ScreenInit function, and fill in other * pScreen fields. */ width = pScrn->virtualX; height = pScrn->virtualY; displayWidth = pScrn->displayWidth; if(pMga->Rotate) { height = pScrn->virtualX; width = pScrn->virtualY; } if(pMga->ShadowFB) { pMga->ShadowPitch = BitmapBytePad(pScrn->bitsPerPixel * width); pMga->ShadowPtr = xalloc(pMga->ShadowPitch * height); displayWidth = pMga->ShadowPitch / (pScrn->bitsPerPixel >> 3); FBStart = pMga->ShadowPtr; } else { pMga->ShadowPtr = NULL; FBStart = pMga->FbStart; } #ifdef XF86DRI /* * Setup DRI after visuals have been established, but before cfbScreenInit * is called. cfbScreenInit will eventually call into the drivers * InitGLXVisuals call back. * The DRI does not work when textured video is enabled at this time. */ if ((pMga->Chipset == PCI_CHIP_MGAG200_SE_A_PCI) || (pMga->Chipset == PCI_CHIP_MGAG200_SE_B_PCI)) { xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "Not supported by hardware, not initializing the DRI\n"); pMga->directRenderingEnabled = FALSE; driFrom = X_PROBED; } else if (!xf86ReturnOptValBool(pMga->Options, OPTION_DRI, TRUE)) { driFrom = X_CONFIG; } else if ( pMga->NoAccel ) { xf86DrvMsg( pScrn->scrnIndex, X_ERROR, "Acceleration disabled, not initializing the DRI\n" ); pMga->directRenderingEnabled = FALSE; driFrom = X_CONFIG; } else if ( pMga->TexturedVideo == TRUE ) { xf86DrvMsg( pScrn->scrnIndex, X_ERROR, "Textured video enabled, not initializing the DRI\n" ); pMga->directRenderingEnabled = FALSE; driFrom = X_CONFIG; } else if (pMga->SecondCrtc == TRUE) { xf86DrvMsg( pScrn->scrnIndex, X_ERROR, "Not initializing the DRI on the second head\n" ); pMga->directRenderingEnabled = FALSE; } else if ((pMga->FbMapSize / (width * (pScrn->bitsPerPixel >> 3))) <= height * 3) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Static buffer allocation failed, not initializing the DRI\n"); xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Need at least %d kB video memory at this resolution, bit depth\n", (3 * displayWidth * height * (pScrn->bitsPerPixel >> 3)) / 1024 ); pMga->directRenderingEnabled = FALSE; driFrom = X_PROBED; } else { pMga->directRenderingEnabled = MGADRIScreenInit(pScreen); } #endif if (pMga->Overlay8Plus24) { ret = cfb8_32ScreenInit(pScreen, FBStart, width, height, pScrn->xDpi, pScrn->yDpi, displayWidth); } else { ret = fbScreenInit(pScreen, FBStart, width, height, pScrn->xDpi, pScrn->yDpi, displayWidth, pScrn->bitsPerPixel); } if (!ret) return FALSE; if (pScrn->bitsPerPixel > 8) { /* Fixup RGB ordering */ visual = pScreen->visuals + pScreen->numVisuals; while (--visual >= pScreen->visuals) { if ((visual->class | DynamicClass) == DirectColor) { visual->offsetRed = pScrn->offset.red; visual->offsetGreen = pScrn->offset.green; visual->offsetBlue = pScrn->offset.blue; visual->redMask = pScrn->mask.red; visual->greenMask = pScrn->mask.green; visual->blueMask = pScrn->mask.blue; } } } /* must be after RGB ordering fixed */ if (!pMga->Overlay8Plus24) fbPictureInit (pScreen, 0, 0); xf86SetBlackWhitePixels(pScreen); pMga->BlockHandler = pScreen->BlockHandler; pScreen->BlockHandler = MGABlockHandler; if(!pMga->ShadowFB) /* hardware cursor needs to wrap this layer */ MGADGAInit(pScreen); if (!pMga->NoAccel) { #ifdef USE_EXA if (pMga->Exa) mgaExaInit(pScreen); else #endif #ifdef USE_XAA MGAStormAccelInit(pScreen); #endif } miInitializeBackingStore(pScreen); xf86SetBackingStore(pScreen); xf86SetSilkenMouse(pScreen); /* Initialize software cursor. Must precede creation of the default colormap */ miDCInitialize(pScreen, xf86GetPointerScreenFuncs()); /* Initialize HW cursor layer. Must follow software cursor initialization*/ if (pMga->HWCursor) { if(!MGAHWCursorInit(pScreen)) xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Hardware cursor initialization failed\n"); } if(pMga->MergedFB) { /* Rotate and MergedFB are mutiualy exclusive, so we can use this * variable. */ if (!pMga->PointerMoved) pMga->PointerMoved = pScrn->PointerMoved; pScrn->PointerMoved = MGAMergePointerMoved; } /* Initialise default colourmap */ if (!miCreateDefColormap(pScreen)) return FALSE; /* Initialize colormap layer. Must follow initialization of the default colormap */ if (!pMga->SecondCrtc) f = CMAP_PALETTED_TRUECOLOR | CMAP_RELOAD_ON_MODE_SWITCH; else f = CMAP_RELOAD_ON_MODE_SWITCH; if(!xf86HandleColormaps(pScreen, 256, 8, pMga->FBDev ? fbdevHWLoadPaletteWeak() : MGAdac->LoadPalette, NULL, f)) return FALSE; if(pMga->Overlay8Plus24) { /* Must come after colormap initialization */ if(!xf86Overlay8Plus32Init(pScreen)) return FALSE; } if(pMga->ShadowFB) { RefreshAreaFuncPtr refreshArea = MGARefreshArea; if(pMga->Rotate) { if (!pMga->PointerMoved) { pMga->PointerMoved = pScrn->PointerMoved; pScrn->PointerMoved = MGAPointerMoved; } switch(pScrn->bitsPerPixel) { case 8: refreshArea = MGARefreshArea8; break; case 16: refreshArea = MGARefreshArea16; break; case 24: refreshArea = MGARefreshArea24; break; case 32: refreshArea = MGARefreshArea32; break; } } ShadowFBInit(pScreen, refreshArea); } if(pMga->SecondCrtc == TRUE && !pMga->MergedFB) { xf86DPMSInit(pScreen, MGADisplayPowerManagementSetCrtc2, 0); } if(pMga->SecondCrtc == FALSE && !pMga->MergedFB) { xf86DPMSInit(pScreen, MGADisplayPowerManagementSet, 0); } if(pMga->MergedFB) { xf86DPMSInit(pScreen, MGADisplayPowerManagementSetMerged, 0); } pScrn->memPhysBase = pMga->FbAddress; pScrn->fbOffset = pMga->YDstOrg * (pScrn->bitsPerPixel / 8); if(!pMga->MergedFB) { if(pMga->SecondCrtc == TRUE) { pScreen->SaveScreen = MGASaveScreenCrtc2; } else { pScreen->SaveScreen = MGASaveScreen; } } else { /* Merged FB */ pScreen->SaveScreen = MGASaveScreenMerged; } MGAInitVideo(pScreen); #ifdef XF86DRI if (pMga->directRenderingEnabled) { /* Now that mi, cfb, drm and others have done their thing, * complete the DRI setup. */ pMga->directRenderingEnabled = MGADRIFinishScreenInit(pScreen); } if (pMga->directRenderingEnabled) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Direct rendering enabled\n"); } else { xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "Direct rendering disabled\n"); } if (pMga->DualHeadEnabled && pMga->SecondCrtc == FALSE) pMgaEnt->directRenderingEnabled = pMga->directRenderingEnabled; pMga->haveQuiescense = 1; #endif /* Wrap the current CloseScreen function */ pMga->CloseScreen = pScreen->CloseScreen; pScreen->CloseScreen = MGACloseScreen; /* Report any unused options (only for the first generation) */ if (serverGeneration == 1) { xf86ShowUnusedOptions(pScrn->scrnIndex, pScrn->options); } /* For the second head, work around display problem. */ if (!pMga->MergedFB && pMga->SecondCrtc) { MGACrtc2FillStrip(pScrn); } /* Done */ return TRUE; } /* Usually mandatory */ Bool MGASwitchMode(int scrnIndex, DisplayModePtr mode, int flags) { #ifdef USEMGAHAL char sCmdIn[256]; char sCmdOut[256]; FILE* fdIn; # ifdef MATROX_WRITEBACK FILE* fdOut; # endif #endif if (mode->Flags & 0x80000000) { #ifdef USEMGAHAL # ifdef MATROX_WRITEBACK # define MWB(x) { x; } # define MWB_COND(x) x # else # define MWB(x) # define MWB_COND(x) 1 # endif ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; MGA_HAL( fdIn = fopen("/tmp/mgaDriverIn", "rt"); MWB(fdOut = fopen("/tmp/mgaDriverOut", "wt")) if(fdIn && MWB_COND(fdOut)) { fgets(sCmdIn, 255, fdIn); if(sCmdIn) { MGAExecuteEscCmd(xf86Screens[scrnIndex], sCmdIn, sCmdOut, mode); /* Remove file and close file descriptor */ remove("/tmp/mgaDriverIn"); fclose(fdIn); MWB( /* Write output data to output file for calling application */ fputs(sCmdOut, fdOut); fclose(fdOut); ) mode->Flags &= 0x7FFFFFFF; return TRUE; } else { mode->Flags &= 0x7FFFFFFF; return FALSE; } } else { mode->Flags &= 0x7FFFFFFF; return FALSE; } ) #endif return FALSE; } else return MGAModeInit(xf86Screens[scrnIndex], mode); } /* Adjusts coordinates to match Panning granularity. * does nothing if the HALlib is not loaded */ void MGAAdjustGranularity(ScrnInfoPtr pScrn, int* x, int* y) { #ifdef USEMGAHAL MGA_HAL( MGAPtr pMga = MGAPTR(pScrn); MGAPtr pMga2; int xg = 1; int yg = 1; if(pMga->pMgaModeInfo && pMga->pMgaModeInfo->ulPanXGran && pMga->pMgaModeInfo->ulPanYGran) { xg = pMga->pMgaModeInfo->ulPanXGran; yg = pMga->pMgaModeInfo->ulPanYGran; } if(pMga->pScrn2 && (pMga2 = MGAPTR(pMga->pScrn2)) ) { if(pMga2->pMgaModeInfo && pMga2->pMgaModeInfo->ulPanXGran && pMga2->pMgaModeInfo->ulPanYGran) { xg = max(xg,pMga2->pMgaModeInfo->ulPanXGran); yg = max(yg,pMga2->pMgaModeInfo->ulPanYGran); } } xg=16; /*ncoder: temporary */ *x -= *x % xg; *y -= *y % yg; ); #endif } /* * This function is used to initialize the Start Address - the first * displayed location in the video memory. */ /* Usually mandatory */ void MGAAdjustFrame(int scrnIndex, int x, int y, int flags) { ScrnInfoPtr pScrn; int Base, tmp, count; MGAFBLayout *pLayout; MGAPtr pMga; pScrn = xf86Screens[scrnIndex]; pMga = MGAPTR(pScrn); pLayout = &pMga->CurrentLayout; /* wanted to improve panning granularity problems without risking * compatibility issues. Existing code looked hardware dependent. */ #ifdef USEMGAHAL MGA_HAL( pMga->HALGranularityOffX = x; pMga->HALGranularityOffY = y; MGAAdjustGranularity(pScrn,&x,&y); pMga->HALGranularityOffX = pMga->HALGranularityOffX - x; pMga->HALGranularityOffY = pMga->HALGranularityOffY - y; HALSetDisplayStart(pMga->pBoard,x,y,0); ); #endif MGA_NOT_HAL( if(pMga->ShowCache && y && pScrn->vtSema) y += pScrn->virtualY - 1; Base = (y * pLayout->displayWidth + x + pMga->YDstOrg) >> (3 - pMga->BppShifts[(pLayout->bitsPerPixel >> 3) - 1]); if (pLayout->bitsPerPixel == 24) { if (pMga->Chipset == PCI_CHIP_MGAG400 || pMga->Chipset == PCI_CHIP_MGAG550) Base &= ~1; /*1 Not sure why */ Base *= 3; } /* find start of retrace */ while (INREG8(0x1FDA) & 0x08); while (!(INREG8(0x1FDA) & 0x08)); /* wait until we're past the start (fixseg.c in the DDK) */ count = INREG(MGAREG_VCOUNT) + 2; while(INREG(MGAREG_VCOUNT) < count); OUTREG16(MGAREG_CRTC_INDEX, (Base & 0x00FF00) | 0x0C); OUTREG16(MGAREG_CRTC_INDEX, ((Base & 0x0000FF) << 8) | 0x0D); OUTREG8(MGAREG_CRTCEXT_INDEX, 0x00); tmp = INREG8(MGAREG_CRTCEXT_DATA); OUTREG8(MGAREG_CRTCEXT_DATA, (tmp & 0xF0) | ((Base & 0x0F0000) >> 16)); ); } #define C2STARTADD0 0x3C28 void MGAAdjustFrameCrtc2(int scrnIndex, int x, int y, int flags) { ScrnInfoPtr pScrn; int Base; MGAFBLayout *pLayout; MGAPtr pMga; pScrn = xf86Screens[scrnIndex]; pMga = MGAPTR(pScrn); pLayout = &pMga->CurrentLayout; #ifdef USEMGAHAL MGA_HAL( MGAAdjustGranularity(pScrn,&x,&y); HALSetDisplayStart(pMga->pBoard,x,y,1); ); #endif MGA_NOT_HAL( if(pMga->ShowCache && y && pScrn->vtSema) y += pScrn->virtualY - 1; /* 3-85 c2offset * 3-93 c2startadd0 * 3-96 c2vcount */ Base = (y * pLayout->displayWidth + x) * pLayout->bitsPerPixel >> 3; Base += pMga->DstOrg; Base &= 0x01ffffc0; OUTREG(C2STARTADD0, Base); ); } /* * This is called when VT switching back to the X server. Its job is * to reinitialise the video mode. * * We may wish to unmap video/MMIO memory too. */ /* Mandatory */ static Bool MGAEnterVT(int scrnIndex, int flags) { ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; MGAPtr pMga; pMga = MGAPTR(pScrn); #ifdef XF86DRI if (pMga->directRenderingEnabled) { if (pMga->irq) { /* Need to make sure interrupts are enabled */ OUTREG(MGAREG_IEN, pMga->reg_ien); } DRIUnlock(screenInfo.screens[scrnIndex]); } #endif if (!MGAModeInit(pScrn, pScrn->currentMode)) return FALSE; pScrn->AdjustFrame(scrnIndex, pScrn->frameX0, pScrn->frameY0, 0); /* For the second head, work around display problem. */ if (pMga->SecondCrtc) { MGACrtc2FillStrip(pScrn); } return TRUE; } static Bool MGAEnterVTFBDev(int scrnIndex, int flags) { ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; #ifdef XF86DRI ScreenPtr pScreen; MGAPtr pMga; pMga = MGAPTR(pScrn); if (pMga->directRenderingEnabled) { pScreen = screenInfo.screens[scrnIndex]; DRIUnlock(pScreen); } #endif fbdevHWEnterVT(scrnIndex,flags); MGAStormEngineInit(pScrn); return TRUE; } #define RESTORE_TEXTMODE_ON_DVI(x) \ if (MGAISGx50(x) && \ (ISDIGITAL1(x) || ISDIGITAL2(x))) { \ /* Reset DUALDVI register */ \ outMGAdac(MGA1064_DVI_PIPE_CTL, 0x0); \ /* Set Panel mode between 20 and 54 MHz */ \ outMGAdac(MGA1064_PAN_CTL, 0x7); \ } /* * This is called when VT switching away from the X server. Its job is * to restore the previous (text) mode. * * We may wish to remap video/MMIO memory too. */ /* Mandatory */ static void MGALeaveVT(int scrnIndex, int flags) { ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; vgaHWPtr hwp = VGAHWPTR(pScrn); #ifdef XF86DRI MGAPtr pMga = MGAPTR(pScrn); ScreenPtr pScreen; #endif MGARestore(pScrn); vgaHWLock(hwp); if (xf86IsPc98()) outb(0xfac, 0x00); #ifdef XF86DRI if (pMga->directRenderingEnabled) { pScreen = screenInfo.screens[scrnIndex]; DRILock(pScreen, 0); } #endif #ifdef USEMGAHAL MGA_HAL( RESTORE_TEXTMODE_ON_DVI(pMga); ); #endif } /* * This is called at the end of each server generation. It restores the * original (text) mode. It should also unmap the video memory, and free * any per-generation data allocated by the driver. It should finish * by unwrapping and calling the saved CloseScreen function. */ /* Mandatory */ static Bool MGACloseScreen(int scrnIndex, ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; vgaHWPtr hwp = VGAHWPTR(pScrn); MGAPtr pMga = MGAPTR(pScrn); MGAEntPtr pMgaEnt = NULL; #ifdef USEMGAHAL MGA_HAL( RESTORE_TEXTMODE_ON_DVI(pMga); ); #endif if (pMga->MergedFB) MGACloseScreenMerged(scrnIndex, pScreen); if (pScrn->vtSema) { if (pMga->FBDev) { fbdevHWRestore(pScrn); MGAUnmapMemFBDev(pScrn); } else { MGARestore(pScrn); vgaHWLock(hwp); MGAUnmapMem(pScrn); vgaHWUnmapMem(pScrn); } } #ifdef XF86DRI if (pMga->directRenderingEnabled) { MGADRICloseScreen(pScreen); pMga->directRenderingEnabled=FALSE; } #endif if (pMga->DualHeadEnabled) { DevUnion *pPriv; pPriv = xf86GetEntityPrivate(pScrn->entityList[0], MGAEntityIndex); pMgaEnt = pPriv->ptr; pMgaEnt->refCount--; } #ifdef USEMGAHAL MGA_HAL( if(pMga->DualHeadEnabled) { if(pMgaEnt->refCount == 0) { /* Both boards have closed there screen */ MGACloseLibrary(pMga->pBoard); if (pMga->pBoard) xfree(pMga->pBoard); if (pMga->pClientStruct) xfree(pMga->pClientStruct); if (pMga->pMgaModeInfo) xfree(pMga->pMgaModeInfo); if (pMga->pMgaHwInfo) xfree(pMga->pMgaHwInfo); } } else { MGACloseLibrary(pMga->pBoard); if (pMga->pBoard) xfree(pMga->pBoard); if (pMga->pClientStruct) xfree(pMga->pClientStruct); if (pMga->pMgaModeInfo) xfree(pMga->pMgaModeInfo); if (pMga->pMgaHwInfo) xfree(pMga->pMgaHwInfo); } ); /* MGA_HAL */ #endif #ifdef USE_XAA if (pMga->AccelInfoRec) XAADestroyInfoRec(pMga->AccelInfoRec); #endif #ifdef USE_EXA if (pMga->ExaDriver) { exaDriverFini(pScreen); xfree(pMga->ExaDriver); } #endif if (pMga->CursorInfoRec) xf86DestroyCursorInfoRec(pMga->CursorInfoRec); if (pMga->ShadowPtr) xfree(pMga->ShadowPtr); if (pMga->DGAModes) xfree(pMga->DGAModes); if (pMga->adaptor) xfree(pMga->adaptor); if (pMga->portPrivate) xfree(pMga->portPrivate); if (pMga->ScratchBuffer) xfree(pMga->ScratchBuffer); pScrn->vtSema = FALSE; if (xf86IsPc98()) outb(0xfac, 0x00); xf86ClearPrimInitDone(pScrn->entityList[0]); if(pMga->BlockHandler) pScreen->BlockHandler = pMga->BlockHandler; pScreen->CloseScreen = pMga->CloseScreen; return (*pScreen->CloseScreen)(scrnIndex, pScreen); } /* Free up any persistent data structures */ /* Optional */ static void MGAFreeScreen(int scrnIndex, int flags) { /* * This only gets called when a screen is being deleted. It does not * get called routinely at the end of a server generation. */ if (xf86LoaderCheckSymbol("vgaHWFreeHWRec")) vgaHWFreeHWRec(xf86Screens[scrnIndex]); MGAFreeRec(xf86Screens[scrnIndex]); } /* Checks if a mode is suitable for the selected chipset. */ /* Optional */ static ModeStatus MGAValidMode(int scrnIndex, DisplayModePtr mode, Bool verbose, int flags) { int lace; ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; MGAPtr pMga = MGAPTR(pScrn); lace = 1 + ((mode->Flags & V_INTERLACE) != 0); if ((mode->CrtcHDisplay <= 2048) && (mode->CrtcHSyncStart <= 4096) && (mode->CrtcHSyncEnd <= 4096) && (mode->CrtcHTotal <= 4096) && (mode->CrtcVDisplay <= 2048 * lace) && (mode->CrtcVSyncStart <= 4096 * lace) && (mode->CrtcVSyncEnd <= 4096 * lace) && (mode->CrtcVTotal <= 4096 * lace)) { /* Can't have horizontal panning for second head of G400 */ if (pMga->SecondCrtc) { if (flags == MODECHECK_FINAL) { if (pMga->allowedWidth == 0) pMga->allowedWidth = pScrn->virtualX; if (mode->HDisplay != pMga->allowedWidth) return(MODE_ONE_WIDTH); } } return(MODE_OK); } else { return(MODE_BAD); } } /* * This routine is required but since we can't easily blank the * second display without risking powering off the monitor, return * FALSE and let the X server do something generic. */ static Bool MGASaveScreenCrtc2(ScreenPtr pScreen, int mode) { return FALSE; } /* Do screen blanking */ static Bool MGASaveScreen(ScreenPtr pScreen, int mode) { return vgaHWSaveScreen(pScreen, mode); } /* * MGADisplayPowerManagementSet -- * * Sets VESA Display Power Management Signaling (DPMS) Mode. * * XXX This needs fixing for sync-on-green! */ void MGADisplayPowerManagementSet(ScrnInfoPtr pScrn, int PowerManagementMode, int flags) { MGAPtr pMga = MGAPTR(pScrn); unsigned char seq1 = 0, crtcext1 = 0; switch (PowerManagementMode) { case DPMSModeOn: /* Screen: On; HSync: On, VSync: On */ seq1 = 0x00; crtcext1 = 0x00; break; case DPMSModeStandby: /* Screen: Off; HSync: Off, VSync: On */ seq1 = 0x20; crtcext1 = 0x10; break; case DPMSModeSuspend: /* Screen: Off; HSync: On, VSync: Off */ seq1 = 0x20; crtcext1 = 0x20; break; case DPMSModeOff: /* Screen: Off; HSync: Off, VSync: Off */ seq1 = 0x20; crtcext1 = 0x30; break; } /* XXX Prefer an implementation that doesn't depend on VGA specifics */ OUTREG8(MGAREG_SEQ_INDEX, 0x01); /* Select SEQ1 */ seq1 |= INREG8(MGAREG_SEQ_DATA) & ~0x20; OUTREG8(MGAREG_SEQ_DATA, seq1); OUTREG8(MGAREG_CRTCEXT_INDEX, 0x01); /* Select CRTCEXT1 */ crtcext1 |= INREG8(MGAREG_CRTCEXT_DATA) & ~0x30; OUTREG8(MGAREG_CRTCEXT_DATA, crtcext1); } void MGADisplayPowerManagementSetCrtc2(ScrnInfoPtr pScrn, int PowerManagementMode, int flags) { MGAPtr pMga = MGAPTR(pScrn); CARD32 val = INREG(MGAREG_C2CTL); if (PowerManagementMode==DPMSModeOn) { /* Enable CRTC2 */ val |= 0x1; val &= ~(0x8); OUTREG(MGAREG_C2CTL, val); /* Restore normal MAVEN values */ if (pMga->Maven) { /* if TV MODE -- for later implementation MAVW(MONEN, 0xb3); MAVW(MONSET, 0x20); MAVW(OUTMODE, 0x08); output: SVideo/Composite MAVW(STABLE, 0x02); makes picture stable? fixme? linux uses 0x14... MAVW(TEST, (MAVR(TEST) & 0x10)); */ /* else monitor mode */ xf86I2CWriteByte(pMga->Maven, MGAMAV_MONEN, 0xb2); /* must be set to this in monitor mode */ xf86I2CWriteByte(pMga->Maven, MGAMAV_MONSET, 0x20); /* output: monitor mode */ xf86I2CWriteByte(pMga->Maven, MGAMAV_OUTMODE, 0x03); /* makes picture stable? */ xf86I2CWriteByte(pMga->Maven, MGAMAV_STABLE, 0x22); /* turn off test signal */ xf86I2CWriteByte(pMga->Maven, MGAMAV_TEST, 0x00); } } else { /* Disable CRTC2 video */ val |= 0x8; val &= ~(0x1); OUTREG(MGAREG_C2CTL, val); /* Disable MAVEN display */ if (pMga->Maven) { /* In order to blank the 2nd display, we must set some MAVEN registers. * It seems that not always the same values work on different hardware so * we try a few different (possibly redundant) ones. */ /* xf86I2CWriteByte(pMga->Maven, MGAMAV_STABLE, 0x6a); */ /* xf86I2CWriteByte(pMga->Maven, MGAMAV_TEST, 0x03); */ /* xf86I2CWriteByte(pMga->Maven, MGAMAV_TEST, 0x10); */ xf86I2CWriteByte(pMga->Maven, MGAMAV_OUTMODE, 0x80); } } } static void MGABlockHandler ( int i, pointer blockData, pointer pTimeout, pointer pReadmask ){ ScreenPtr pScreen = screenInfo.screens[i]; ScrnInfoPtr pScrn = xf86Screens[i]; MGAPtr pMga = MGAPTR(pScrn); if(pMga->PaletteLoadCallback) (*pMga->PaletteLoadCallback)(pScrn); pScreen->BlockHandler = pMga->BlockHandler; (*pScreen->BlockHandler) (i, blockData, pTimeout, pReadmask); pScreen->BlockHandler = MGABlockHandler; if(pMga->VideoTimerCallback) { UpdateCurrentTime(); (*pMga->VideoTimerCallback)(pScrn, currentTime.milliseconds); } if(pMga->RenderCallback) (*pMga->RenderCallback)(pScrn); } #if defined (EXTRADEBUG) /* * some functions to track input/output in the server */ CARD8 MGAdbg_inreg8(ScrnInfoPtr pScrn,int addr,int verbose, char* func) { CARD8 ret; ret = MMIO_IN8(MGAPTR(pScrn)->IOBase,addr); if(verbose) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "inreg8 : %s: 0x%8x = 0x%x\n",func, addr,ret); return ret; } CARD16 MGAdbg_inreg16(ScrnInfoPtr pScrn,int addr,int verbose, char* func) { CARD16 ret; ret = MMIO_IN16(MGAPTR(pScrn)->IOBase,addr); if(verbose) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "inreg16: %s: 0x%8x = 0x%x\n",func, addr,ret); return ret; } CARD32 MGAdbg_inreg32(ScrnInfoPtr pScrn,int addr,int verbose, char* func) { CARD32 ret; ret = MMIO_IN32(MGAPTR(pScrn)->IOBase,addr); if(verbose) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "inreg32: %s: 0x%8x = 0x%x\n",func, addr,ret); return ret; } void MGAdbg_outreg8(ScrnInfoPtr pScrn,int addr,int val, char* func) { CARD8 ret; #if 0 if( addr = MGAREG_CRTCEXT_DATA ) return; #endif if( addr != 0x3c00 ) { ret = MGAdbg_inreg8(pScrn,addr,0,func); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "outreg8 : %s: 0x%8x = 0x%x was 0x%x\n", func,addr,val,ret); } else { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "outreg8 : %s: index 0x%x\n", func,val); } MMIO_OUT8(MGAPTR(pScrn)->IOBase,addr,val); } void MGAdbg_outreg16(ScrnInfoPtr pScrn,int addr,int val, char* func) { CARD16 ret; #if 0 if (addr == MGAREG_CRTCEXT_INDEX) return; #endif ret = MGAdbg_inreg16(pScrn,addr,0, func); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "outreg16: %s: 0x%8x = 0x%x was 0x%x\n", func,addr,val,ret); MMIO_OUT16(MGAPTR(pScrn)->IOBase,addr,val); } void MGAdbg_outreg32(ScrnInfoPtr pScrn,int addr,int val, char* func) { CARD32 ret; if (((addr & 0xff00) == 0x1c00) && (addr != 0x1c04) /* && (addr != 0x1c1c) */ && (addr != 0x1c20) && (addr != 0x1c24) && (addr != 0x1c80) && (addr != 0x1c8c) && (addr != 0x1c94) && (addr != 0x1c98) && (addr != 0x1c9c) ) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "%s: refused address 0x%x\n", func,addr); return; } ret = MGAdbg_inreg32(pScrn,addr,0, func); xf86DrvMsg(pScrn->scrnIndex, X_INFO, "outreg32: %s: 0x%8x = 0x%x was 0x%x\n", func,addr,val,ret); MMIO_OUT32(MGAPTR(pScrn)->IOBase,addr,val); } #endif /* DEBUG */ static void MGAG100BlackMagic(ScrnInfoPtr pScrn) { MGAPtr pMga = MGAPTR(pScrn); OUTREG(MGAREG_PLNWT, ~(CARD32)0x0); /* reset memory */ OUTREG(MGAREG_MACCESS, 1<<15); usleep(10); }