/* * Copyright (c) 1997-2003 by The XFree86 Project, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included in * all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE COPYRIGHT HOLDER(S) OR AUTHOR(S) BE LIABLE FOR ANY CLAIM, DAMAGES OR * OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, * ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR * OTHER DEALINGS IN THE SOFTWARE. * * Except as contained in this notice, the name of the copyright holder(s) * and author(s) shall not be used in advertising or otherwise to promote * the sale, use or other dealings in this Software without prior written * authorization from the copyright holder(s) and author(s). */ /* * Authors: Dirk Hohndel * David Dawes * ... and others * * This file includes the helper functions that the server provides for * different drivers. */ #ifdef HAVE_XORG_CONFIG_H #include #endif #include #include "Pci.h" #include #include "os.h" #include "servermd.h" #include "pixmapstr.h" #include "windowstr.h" #include "propertyst.h" #include "gcstruct.h" #include "loaderProcs.h" #include "xf86.h" #include "xf86Priv.h" #include "xf86_OSlib.h" #include "micmap.h" #include "xf86PciInfo.h" #include "xf86DDC.h" #include "xf86Xinput.h" #include "xf86InPriv.h" #include "mivalidate.h" #include "xf86RAC.h" #include "xf86Bus.h" #include "xf86Version.h" /* For xf86GetClocks */ #if defined(CSRG_BASED) || defined(__GNU__) #define HAS_SETPRIORITY #include #endif static int xf86ScrnInfoPrivateCount = 0; /* Add a pointer to a new DriverRec to xf86DriverList */ _X_EXPORT void xf86AddDriver(DriverPtr driver, pointer module, int flags) { /* Don't add null entries */ if (!driver) return; if (xf86DriverList == NULL) xf86NumDrivers = 0; xf86NumDrivers++; xf86DriverList = xnfrealloc(xf86DriverList, xf86NumDrivers * sizeof(DriverPtr)); xf86DriverList[xf86NumDrivers - 1] = xnfalloc(sizeof(DriverRec)); if (flags & HaveDriverFuncs) *xf86DriverList[xf86NumDrivers - 1] = *driver; else { (void) memset( xf86DriverList[xf86NumDrivers - 1], 0, sizeof( DriverRec ) ); (void) memcpy( xf86DriverList[xf86NumDrivers - 1], driver, sizeof(DriverRec1)); } xf86DriverList[xf86NumDrivers - 1]->module = module; xf86DriverList[xf86NumDrivers - 1]->refCount = 0; } _X_EXPORT void xf86DeleteDriver(int drvIndex) { if (xf86DriverList[drvIndex] && (!xf86DriverHasEntities(xf86DriverList[drvIndex]))) { if (xf86DriverList[drvIndex]->module) UnloadModule(xf86DriverList[drvIndex]->module); xfree(xf86DriverList[drvIndex]); xf86DriverList[drvIndex] = NULL; } } /* Add a pointer to a new InputDriverRec to xf86InputDriverList */ _X_EXPORT void xf86AddInputDriver(InputDriverPtr driver, pointer module, int flags) { /* Don't add null entries */ if (!driver) return; if (xf86InputDriverList == NULL) xf86NumInputDrivers = 0; xf86NumInputDrivers++; xf86InputDriverList = xnfrealloc(xf86InputDriverList, xf86NumInputDrivers * sizeof(InputDriverPtr)); xf86InputDriverList[xf86NumInputDrivers - 1] = xnfalloc(sizeof(InputDriverRec)); *xf86InputDriverList[xf86NumInputDrivers - 1] = *driver; xf86InputDriverList[xf86NumInputDrivers - 1]->module = module; xf86InputDriverList[xf86NumInputDrivers - 1]->refCount = 0; } void xf86DeleteInputDriver(int drvIndex) { if (xf86InputDriverList[drvIndex] && xf86InputDriverList[drvIndex]->module) UnloadModule(xf86InputDriverList[drvIndex]->module); xfree(xf86InputDriverList[drvIndex]); xf86InputDriverList[drvIndex] = NULL; } InputDriverPtr xf86LookupInputDriver(const char *name) { int i; for (i = 0; i < xf86NumInputDrivers; i++) { if (xf86InputDriverList[i] && xf86InputDriverList[i]->driverName && xf86NameCmp(name, xf86InputDriverList[i]->driverName) == 0) return xf86InputDriverList[i]; } return NULL; } InputInfoPtr xf86LookupInput(const char *name) { InputInfoPtr p; for (p = xf86InputDevs; p != NULL; p = p->next) { if (strcmp(name, p->name) == 0) return p; } return NULL; } /* ABI stubs of despair */ _X_EXPORT void xf86AddModuleInfo(pointer info, pointer module) { } _X_EXPORT void xf86DeleteModuleInfo(int idx) { } /* Allocate a new ScrnInfoRec in xf86Screens */ _X_EXPORT ScrnInfoPtr xf86AllocateScreen(DriverPtr drv, int flags) { int i; if (xf86Screens == NULL) xf86NumScreens = 0; i = xf86NumScreens++; xf86Screens = xnfrealloc(xf86Screens, xf86NumScreens * sizeof(ScrnInfoPtr)); xf86Screens[i] = xnfcalloc(sizeof(ScrnInfoRec), 1); xf86Screens[i]->scrnIndex = i; /* Changes when a screen is removed */ xf86Screens[i]->origIndex = i; /* This never changes */ xf86Screens[i]->privates = xnfcalloc(sizeof(DevUnion), xf86ScrnInfoPrivateCount); /* * EnableDisableFBAccess now gets initialized in InitOutput() * xf86Screens[i]->EnableDisableFBAccess = xf86EnableDisableFBAccess; */ xf86Screens[i]->drv = drv; drv->refCount++; xf86Screens[i]->module = DuplicateModule(drv->module, NULL); /* * set the initial access state. This will be modified after PreInit. * XXX Or should we do it some other place? */ xf86Screens[i]->CurrentAccess = &xf86CurrentAccess; xf86Screens[i]->resourceType = MEM_IO; #ifdef DEBUG /* OOps -- What's this ? */ ErrorF("xf86AllocateScreen - xf86Screens[%d]->pScreen = %p\n", i, xf86Screens[i]->pScreen ); if ( NULL != xf86Screens[i]->pScreen ) { ErrorF("xf86Screens[%d]->pScreen->CreateWindow = %p\n", i, xf86Screens[i]->pScreen->CreateWindow ); } #endif xf86Screens[i]->DriverFunc = drv->driverFunc; return xf86Screens[i]; } /* * Remove an entry from xf86Screens. Ideally it should free all allocated * data. To do this properly may require a driver hook. */ _X_EXPORT void xf86DeleteScreen(int scrnIndex, int flags) { ScrnInfoPtr pScrn; int i; /* First check if the screen is valid */ if (xf86NumScreens == 0 || xf86Screens == NULL) return; if (scrnIndex > xf86NumScreens - 1) return; if (!(pScrn = xf86Screens[scrnIndex])) return; /* If a FreeScreen function is defined, call it here */ if (pScrn->FreeScreen != NULL) pScrn->FreeScreen(scrnIndex, 0); while (pScrn->modes) xf86DeleteMode(&pScrn->modes, pScrn->modes); while (pScrn->modePool) xf86DeleteMode(&pScrn->modePool, pScrn->modePool); xf86OptionListFree(pScrn->options); if (pScrn->module) UnloadModule(pScrn->module); if (pScrn->drv) pScrn->drv->refCount--; if (pScrn->privates) xfree(pScrn->privates); xf86ClearEntityListForScreen(scrnIndex); xfree(pScrn); /* Move the other entries down, updating their scrnIndex fields */ xf86NumScreens--; for (i = scrnIndex; i < xf86NumScreens; i++) { xf86Screens[i] = xf86Screens[i + 1]; xf86Screens[i]->scrnIndex = i; /* Also need to take care of the screen layout settings */ } } /* * Allocate a private in ScrnInfoRec. */ _X_EXPORT int xf86AllocateScrnInfoPrivateIndex(void) { int idx, i; ScrnInfoPtr pScr; DevUnion *nprivs; idx = xf86ScrnInfoPrivateCount++; for (i = 0; i < xf86NumScreens; i++) { pScr = xf86Screens[i]; nprivs = xnfrealloc(pScr->privates, xf86ScrnInfoPrivateCount * sizeof(DevUnion)); /* Zero the new private */ bzero(&nprivs[idx], sizeof(DevUnion)); pScr->privates = nprivs; } return idx; } /* Allocate a new InputInfoRec and append it to the tail of xf86InputDevs. */ _X_EXPORT InputInfoPtr xf86AllocateInput(InputDriverPtr drv, int flags) { InputInfoPtr new, *prev = NULL; if (!(new = xcalloc(sizeof(InputInfoRec), 1))) return NULL; new->drv = drv; drv->refCount++; new->module = DuplicateModule(drv->module, NULL); for (prev = &xf86InputDevs; *prev; prev = &(*prev)->next) ; *prev = new; new->next = NULL; return new; } /* * Remove an entry from xf86InputDevs. Ideally it should free all allocated * data. To do this properly may require a driver hook. */ _X_EXPORT void xf86DeleteInput(InputInfoPtr pInp, int flags) { InputInfoPtr p; /* First check if the inputdev is valid. */ if (pInp == NULL) return; #if 0 /* If a free function is defined, call it here. */ if (pInp->free) pInp->free(pInp, 0); #endif if (pInp->module) UnloadModule(pInp->module); if (pInp->drv) pInp->drv->refCount--; /* This should *really* be handled in drv->UnInit(dev) call instead */ #if 0 if (pInp->private) xfree(pInp->private); #endif /* Remove the entry from the list. */ if (pInp == xf86InputDevs) xf86InputDevs = pInp->next; else { p = xf86InputDevs; while (p && p->next != pInp) p = p->next; if (p) p->next = pInp->next; /* Else the entry wasn't in the xf86InputDevs list (ignore this). */ } xfree(pInp); } _X_EXPORT Bool xf86AddPixFormat(ScrnInfoPtr pScrn, int depth, int bpp, int pad) { int i; if (pScrn->numFormats >= MAXFORMATS) return FALSE; if (bpp <= 0) { if (depth == 1) bpp = 1; else if (depth <= 8) bpp = 8; else if (depth <= 16) bpp = 16; else if (depth <= 32) bpp = 32; else return FALSE; } if (pad <= 0) pad = BITMAP_SCANLINE_PAD; i = pScrn->numFormats++; pScrn->formats[i].depth = depth; pScrn->formats[i].bitsPerPixel = bpp; pScrn->formats[i].scanlinePad = pad; return TRUE; } /* * Set the depth we are using based on (in the following order of preference): * - values given on the command line * - values given in the config file * - values provided by the driver * - an overall default when nothing else is given * * Also find a Display subsection matching the depth/bpp found. * * Sets the following ScrnInfoRec fields: * bitsPerPixel, pixmap24, depth, display, imageByteOrder, * bitmapScanlinePad, bitmapScanlineUnit, bitmapBitOrder, numFormats, * formats, fbFormat. */ /* Can the screen handle 24 bpp pixmaps */ #define DO_PIX24(f) ((f & Support24bppFb) || \ ((f & Support32bppFb) && (f & SupportConvert24to32))) /* Can the screen handle 32 bpp pixmaps */ #define DO_PIX32(f) ((f & Support32bppFb) || \ ((f & Support24bppFb) && (f & SupportConvert32to24))) /* Does the screen prefer 32bpp fb for 24bpp pixmaps */ #define CHOOSE32FOR24(f) ((f & Support32bppFb) && (f & SupportConvert24to32) \ && (f & PreferConvert24to32)) /* Does the screen prefer 24bpp fb for 32bpp pixmaps */ #define CHOOSE24FOR32(f) ((f & Support24bppFb) && (f & SupportConvert32to24) \ && (f & PreferConvert32to24)) /* Can the screen handle 32bpp pixmaps for 24bpp fb */ #define DO_PIX32FOR24(f) ((f & Support24bppFb) && (f & SupportConvert32to24)) /* Can the screen handle 24bpp pixmaps for 32bpp fb */ #define DO_PIX24FOR32(f) ((f & Support32bppFb) && (f & SupportConvert24to32)) #ifndef GLOBAL_DEFAULT_DEPTH #define GLOBAL_DEFAULT_DEPTH 24 #endif _X_EXPORT Bool xf86SetDepthBpp(ScrnInfoPtr scrp, int depth, int dummy, int fbbpp, int depth24flags) { int i; DispPtr disp; Pix24Flags pix24 = xf86Info.pixmap24; Bool nomatch = FALSE; scrp->bitsPerPixel = -1; scrp->depth = -1; scrp->pixmap24 = Pix24DontCare; scrp->bitsPerPixelFrom = X_DEFAULT; scrp->depthFrom = X_DEFAULT; if (xf86FbBpp > 0) { scrp->bitsPerPixel = xf86FbBpp; scrp->bitsPerPixelFrom = X_CMDLINE; } if (xf86Depth > 0) { scrp->depth = xf86Depth; scrp->depthFrom = X_CMDLINE; } if (xf86FbBpp < 0 && xf86Depth < 0) { if (scrp->confScreen->defaultfbbpp > 0) { scrp->bitsPerPixel = scrp->confScreen->defaultfbbpp; scrp->bitsPerPixelFrom = X_CONFIG; } if (scrp->confScreen->defaultdepth > 0) { scrp->depth = scrp->confScreen->defaultdepth; scrp->depthFrom = X_CONFIG; } if (scrp->confScreen->defaultfbbpp <= 0 && scrp->confScreen->defaultdepth <= 0) { /* * Check for DefaultDepth and DefaultFbBpp options in the * Device sections. */ int i; GDevPtr device; Bool found = FALSE; for (i = 0; i < scrp->numEntities; i++) { device = xf86GetDevFromEntity(scrp->entityList[i], scrp->entityInstanceList[i]); if (device && device->options) { if (xf86FindOption(device->options, "DefaultDepth")) { scrp->depth = xf86SetIntOption(device->options, "DefaultDepth", -1); scrp->depthFrom = X_CONFIG; found = TRUE; } if (xf86FindOption(device->options, "DefaultFbBpp")) { scrp->bitsPerPixel = xf86SetIntOption(device->options, "DefaultFbBpp", -1); scrp->bitsPerPixelFrom = X_CONFIG; found = TRUE; } } if (found) break; } } } /* If none of these is set, pick a default */ if (scrp->bitsPerPixel < 0 && scrp->depth < 0) { if (fbbpp > 0 || depth > 0) { if (fbbpp > 0) scrp->bitsPerPixel = fbbpp; if (depth > 0) scrp->depth = depth; } else { scrp->depth = GLOBAL_DEFAULT_DEPTH; } } /* If any are not given, determine a default for the others */ if (scrp->bitsPerPixel < 0) { /* The depth must be set */ if (scrp->depth > -1) { if (scrp->depth == 1) scrp->bitsPerPixel = 1; else if (scrp->depth <= 4) scrp->bitsPerPixel = 4; else if (scrp->depth <= 8) scrp->bitsPerPixel = 8; else if (scrp->depth <= 16) scrp->bitsPerPixel = 16; else if (scrp->depth <= 24) { /* * Figure out if a choice is possible based on the depth24 * and pix24 flags. */ /* Check pix24 first */ if (pix24 != Pix24DontCare) { if (pix24 == Pix24Use32) { if (DO_PIX32(depth24flags)) { if (CHOOSE24FOR32(depth24flags)) scrp->bitsPerPixel = 24; else scrp->bitsPerPixel = 32; } else { nomatch = TRUE; } } else if (pix24 == Pix24Use24) { if (DO_PIX24(depth24flags)) { if (CHOOSE32FOR24(depth24flags)) scrp->bitsPerPixel = 32; else scrp->bitsPerPixel = 24; } else { nomatch = TRUE; } } } else { if (DO_PIX32(depth24flags)) { if (CHOOSE24FOR32(depth24flags)) scrp->bitsPerPixel = 24; else scrp->bitsPerPixel = 32; } else if (DO_PIX24(depth24flags)) { if (CHOOSE32FOR24(depth24flags)) scrp->bitsPerPixel = 32; else scrp->bitsPerPixel = 24; } } } else if (scrp->depth <= 32) scrp->bitsPerPixel = 32; else { xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Specified depth (%d) is greater than 32\n", scrp->depth); return FALSE; } } else { xf86DrvMsg(scrp->scrnIndex, X_ERROR, "xf86SetDepthBpp: internal error: depth and fbbpp" " are both not set\n"); return FALSE; } if (scrp->bitsPerPixel < 0) { if (nomatch) xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Driver can't support depth 24 pixmap format (%d)\n", PIX24TOBPP(pix24)); else if ((depth24flags & (Support24bppFb | Support32bppFb)) == NoDepth24Support) xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Driver can't support depth 24\n"); else xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Can't find fbbpp for depth 24\n"); return FALSE; } scrp->bitsPerPixelFrom = X_PROBED; } if (scrp->depth <= 0) { /* bitsPerPixel is already set */ switch (scrp->bitsPerPixel) { case 32: scrp->depth = 24; break; default: /* 1, 4, 8, 16 and 24 */ scrp->depth = scrp->bitsPerPixel; break; } scrp->depthFrom = X_PROBED; } /* Sanity checks */ if (scrp->depth < 1 || scrp->depth > 32) { xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Specified depth (%d) is not in the range 1-32\n", scrp->depth); return FALSE; } switch (scrp->bitsPerPixel) { case 1: case 4: case 8: case 16: case 24: case 32: break; default: xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Specified fbbpp (%d) is not a permitted value\n", scrp->bitsPerPixel); return FALSE; } if (scrp->depth > scrp->bitsPerPixel) { xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Specified depth (%d) is greater than the fbbpp (%d)\n", scrp->depth, scrp->bitsPerPixel); return FALSE; } /* set scrp->pixmap24 if the driver isn't flexible */ if (scrp->bitsPerPixel == 24 && !DO_PIX32FOR24(depth24flags)) { scrp->pixmap24 = Pix24Use24; } if (scrp->bitsPerPixel == 32 && !DO_PIX24FOR32(depth24flags)) { scrp->pixmap24 = Pix24Use32; } /* * Find the Display subsection matching the depth/fbbpp and initialise * scrp->display with it. */ for (i = 0, disp = scrp->confScreen->displays; i < scrp->confScreen->numdisplays; i++, disp++) { if ((disp->depth == scrp->depth && disp->fbbpp == scrp->bitsPerPixel) || (disp->depth == scrp->depth && disp->fbbpp <= 0) || (disp->fbbpp == scrp->bitsPerPixel && disp->depth <= 0)) { scrp->display = disp; break; } } /* * If an exact match can't be found, see if there is one with no * depth or fbbpp specified. */ if (i == scrp->confScreen->numdisplays) { for (i = 0, disp = scrp->confScreen->displays; i < scrp->confScreen->numdisplays; i++, disp++) { if (disp->depth <= 0 && disp->fbbpp <= 0) { scrp->display = disp; break; } } } /* * If all else fails, create a default one. */ if (i == scrp->confScreen->numdisplays) { scrp->confScreen->numdisplays++; scrp->confScreen->displays = xnfrealloc(scrp->confScreen->displays, scrp->confScreen->numdisplays * sizeof(DispRec)); xf86DrvMsg(scrp->scrnIndex, X_INFO, "Creating default Display subsection in Screen section\n" "\t\"%s\" for depth/fbbpp %d/%d\n", scrp->confScreen->id, scrp->depth, scrp->bitsPerPixel); memset(&scrp->confScreen->displays[i], 0, sizeof(DispRec)); scrp->confScreen->displays[i].blackColour.red = -1; scrp->confScreen->displays[i].blackColour.green = -1; scrp->confScreen->displays[i].blackColour.blue = -1; scrp->confScreen->displays[i].whiteColour.red = -1; scrp->confScreen->displays[i].whiteColour.green = -1; scrp->confScreen->displays[i].whiteColour.blue = -1; scrp->confScreen->displays[i].defaultVisual = -1; scrp->confScreen->displays[i].modes = xnfalloc(sizeof(char *)); scrp->confScreen->displays[i].modes[0] = NULL; scrp->confScreen->displays[i].depth = depth; scrp->confScreen->displays[i].fbbpp = fbbpp; scrp->display = &scrp->confScreen->displays[i]; } /* * Setup defaults for the display-wide attributes the framebuffer will * need. These defaults should eventually be set globally, and not * dependent on the screens. */ scrp->imageByteOrder = IMAGE_BYTE_ORDER; scrp->bitmapScanlinePad = BITMAP_SCANLINE_PAD; if (scrp->depth < 8) { /* Planar modes need these settings */ scrp->bitmapScanlineUnit = 8; scrp->bitmapBitOrder = MSBFirst; } else { scrp->bitmapScanlineUnit = BITMAP_SCANLINE_UNIT; scrp->bitmapBitOrder = BITMAP_BIT_ORDER; } /* * If an unusual depth is required, add it to scrp->formats. The formats * for the common depths are handled globally in InitOutput */ switch (scrp->depth) { case 1: case 4: case 8: case 15: case 16: case 24: /* Common depths. Nothing to do for them */ break; default: if (!xf86AddPixFormat(scrp, scrp->depth, 0, 0)) { xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Can't add pixmap format for depth %d\n", scrp->depth); return FALSE; } } /* Initialise the framebuffer format for this screen */ scrp->fbFormat.depth = scrp->depth; scrp->fbFormat.bitsPerPixel = scrp->bitsPerPixel; scrp->fbFormat.scanlinePad = BITMAP_SCANLINE_PAD; return TRUE; } /* * Print out the selected depth and bpp. */ _X_EXPORT void xf86PrintDepthBpp(ScrnInfoPtr scrp) { xf86DrvMsg(scrp->scrnIndex, scrp->depthFrom, "Depth %d, ", scrp->depth); xf86Msg(scrp->bitsPerPixelFrom, "framebuffer bpp %d\n", scrp->bitsPerPixel); } /* * xf86SetWeight sets scrp->weight, scrp->mask, scrp->offset, and for depths * greater than MAX_PSEUDO_DEPTH also scrp->rgbBits. */ _X_EXPORT Bool xf86SetWeight(ScrnInfoPtr scrp, rgb weight, rgb mask) { MessageType weightFrom = X_DEFAULT; scrp->weight.red = 0; scrp->weight.green = 0; scrp->weight.blue = 0; if (xf86Weight.red > 0 && xf86Weight.green > 0 && xf86Weight.blue > 0) { scrp->weight = xf86Weight; weightFrom = X_CMDLINE; } else if (scrp->display->weight.red > 0 && scrp->display->weight.green > 0 && scrp->display->weight.blue > 0) { scrp->weight = scrp->display->weight; weightFrom = X_CONFIG; } else if (weight.red > 0 && weight.green > 0 && weight.blue > 0) { scrp->weight = weight; } else { switch (scrp->depth) { case 1: case 4: case 8: scrp->weight.red = scrp->weight.green = scrp->weight.blue = scrp->rgbBits; break; case 15: scrp->weight.red = scrp->weight.green = scrp->weight.blue = 5; break; case 16: scrp->weight.red = scrp->weight.blue = 5; scrp->weight.green = 6; break; case 24: scrp->weight.red = scrp->weight.green = scrp->weight.blue = 8; break; case 30: scrp->weight.red = scrp->weight.green = scrp->weight.blue = 10; break; } } if (scrp->weight.red) xf86DrvMsg(scrp->scrnIndex, weightFrom, "RGB weight %d%d%d\n", (int)scrp->weight.red, (int)scrp->weight.green, (int)scrp->weight.blue); if (scrp->depth > MAX_PSEUDO_DEPTH && (scrp->depth != scrp->weight.red + scrp->weight.green + scrp->weight.blue)) { xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Weight given (%d%d%d) is inconsistent with the " "depth (%d)\n", (int)scrp->weight.red, (int)scrp->weight.green, (int)scrp->weight.blue, scrp->depth); return FALSE; } if (scrp->depth > MAX_PSEUDO_DEPTH && scrp->weight.red) { /* * XXX Does this even mean anything for TrueColor visuals? * If not, we shouldn't even be setting it here. However, this * matches the behaviour of 3.x versions of XFree86. */ scrp->rgbBits = scrp->weight.red; if (scrp->weight.green > scrp->rgbBits) scrp->rgbBits = scrp->weight.green; if (scrp->weight.blue > scrp->rgbBits) scrp->rgbBits = scrp->weight.blue; } /* Set the mask and offsets */ if (mask.red == 0 || mask.green == 0 || mask.blue == 0) { /* Default to a setting common to PC hardware */ scrp->offset.red = scrp->weight.green + scrp->weight.blue; scrp->offset.green = scrp->weight.blue; scrp->offset.blue = 0; scrp->mask.red = ((1 << scrp->weight.red) - 1) << scrp->offset.red; scrp->mask.green = ((1 << scrp->weight.green) - 1) << scrp->offset.green; scrp->mask.blue = (1 << scrp->weight.blue) - 1; } else { /* Initialise to the values passed */ scrp->mask.red = mask.red; scrp->mask.green = mask.green; scrp->mask.blue = mask.blue; scrp->offset.red = ffs(mask.red); scrp->offset.green = ffs(mask.green); scrp->offset.blue = ffs(mask.blue); } return TRUE; } _X_EXPORT Bool xf86SetDefaultVisual(ScrnInfoPtr scrp, int visual) { MessageType visualFrom = X_DEFAULT; if (defaultColorVisualClass >= 0) { scrp->defaultVisual = defaultColorVisualClass; visualFrom = X_CMDLINE; } else if (scrp->display->defaultVisual >= 0) { scrp->defaultVisual = scrp->display->defaultVisual; visualFrom = X_CONFIG; } else if (visual >= 0) { scrp->defaultVisual = visual; } else { if (scrp->depth == 1) scrp->defaultVisual = StaticGray; else if (scrp->depth == 4) scrp->defaultVisual = StaticColor; else if (scrp->depth <= MAX_PSEUDO_DEPTH) scrp->defaultVisual = PseudoColor; else scrp->defaultVisual = TrueColor; } switch (scrp->defaultVisual) { case StaticGray: case GrayScale: case StaticColor: case PseudoColor: case TrueColor: case DirectColor: xf86DrvMsg(scrp->scrnIndex, visualFrom, "Default visual is %s\n", xf86VisualNames[scrp->defaultVisual]); return TRUE; default: xf86DrvMsg(scrp->scrnIndex, X_ERROR, "Invalid default visual class (%d)\n", scrp->defaultVisual); return FALSE; } } #define TEST_GAMMA(g) \ (g).red > GAMMA_ZERO || (g).green > GAMMA_ZERO || (g).blue > GAMMA_ZERO #define SET_GAMMA(g) \ (g) > GAMMA_ZERO ? (g) : 1.0 _X_EXPORT Bool xf86SetGamma(ScrnInfoPtr scrp, Gamma gamma) { MessageType from = X_DEFAULT; #if 0 xf86MonPtr DDC = (xf86MonPtr)(scrp->monitor->DDC); #endif if (TEST_GAMMA(xf86Gamma)) { from = X_CMDLINE; scrp->gamma.red = SET_GAMMA(xf86Gamma.red); scrp->gamma.green = SET_GAMMA(xf86Gamma.green); scrp->gamma.blue = SET_GAMMA(xf86Gamma.blue); } else if (TEST_GAMMA(scrp->monitor->gamma)) { from = X_CONFIG; scrp->gamma.red = SET_GAMMA(scrp->monitor->gamma.red); scrp->gamma.green = SET_GAMMA(scrp->monitor->gamma.green); scrp->gamma.blue = SET_GAMMA(scrp->monitor->gamma.blue); #if 0 } else if ( DDC && DDC->features.gamma > GAMMA_ZERO ) { from = X_PROBED; scrp->gamma.red = SET_GAMMA(DDC->features.gamma); scrp->gamma.green = SET_GAMMA(DDC->features.gamma); scrp->gamma.blue = SET_GAMMA(DDC->features.gamma); /* EDID structure version 2 gives optional seperate red, green & blue gamma values * in bytes 0x57-0x59 */ #endif } else if (TEST_GAMMA(gamma)) { scrp->gamma.red = SET_GAMMA(gamma.red); scrp->gamma.green = SET_GAMMA(gamma.green); scrp->gamma.blue = SET_GAMMA(gamma.blue); } else { scrp->gamma.red = 1.0; scrp->gamma.green = 1.0; scrp->gamma.blue = 1.0; } xf86DrvMsg(scrp->scrnIndex, from, "Using gamma correction (%.1f, %.1f, %.1f)\n", scrp->gamma.red, scrp->gamma.green, scrp->gamma.blue); return TRUE; } #undef TEST_GAMMA #undef SET_GAMMA /* * Set the DPI from the command line option. XXX should allow it to be * calculated from the widthmm/heightmm values. */ #undef MMPERINCH #define MMPERINCH 25.4 _X_EXPORT void xf86SetDpi(ScrnInfoPtr pScrn, int x, int y) { MessageType from = X_DEFAULT; xf86MonPtr DDC = (xf86MonPtr)(pScrn->monitor->DDC); int ddcWidthmm, ddcHeightmm; int widthErr, heightErr; /* XXX Maybe there is no need for widthmm/heightmm in ScrnInfoRec */ pScrn->widthmm = pScrn->monitor->widthmm; pScrn->heightmm = pScrn->monitor->heightmm; if (DDC && (DDC->features.hsize > 0 && DDC->features.vsize > 0) ) { /* DDC gives display size in mm for individual modes, * but cm for monitor */ ddcWidthmm = DDC->features.hsize * 10; /* 10mm in 1cm */ ddcHeightmm = DDC->features.vsize * 10; /* 10mm in 1cm */ } else { ddcWidthmm = ddcHeightmm = 0; } if (monitorResolution > 0) { pScrn->xDpi = monitorResolution; pScrn->yDpi = monitorResolution; from = X_CMDLINE; } else if (pScrn->widthmm > 0 || pScrn->heightmm > 0) { from = X_CONFIG; if (pScrn->widthmm > 0) { pScrn->xDpi = (int)((double)pScrn->virtualX * MMPERINCH / pScrn->widthmm); } if (pScrn->heightmm > 0) { pScrn->yDpi = (int)((double)pScrn->virtualY * MMPERINCH / pScrn->heightmm); } if (pScrn->xDpi > 0 && pScrn->yDpi <= 0) pScrn->yDpi = pScrn->xDpi; if (pScrn->yDpi > 0 && pScrn->xDpi <= 0) pScrn->xDpi = pScrn->yDpi; xf86DrvMsg(pScrn->scrnIndex, from, "Display dimensions: (%d, %d) mm\n", pScrn->widthmm, pScrn->heightmm); /* Warn if config and probe disagree about display size */ if ( ddcWidthmm && ddcHeightmm ) { if (pScrn->widthmm > 0) { widthErr = abs(ddcWidthmm - pScrn->widthmm); } else { widthErr = 0; } if (pScrn->heightmm > 0) { heightErr = abs(ddcHeightmm - pScrn->heightmm); } else { heightErr = 0; } if (widthErr>10 || heightErr>10) { /* Should include config file name for monitor here */ xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "Probed monitor is %dx%d mm, using Displaysize %dx%d mm\n", ddcWidthmm,ddcHeightmm, pScrn->widthmm,pScrn->heightmm); } } } else if ( ddcWidthmm && ddcHeightmm ) { from = X_PROBED; xf86DrvMsg(pScrn->scrnIndex, from, "Display dimensions: (%d, %d) mm\n", ddcWidthmm, ddcHeightmm ); pScrn->widthmm = ddcWidthmm; pScrn->heightmm = ddcHeightmm; if (pScrn->widthmm > 0) { pScrn->xDpi = (int)((double)pScrn->virtualX * MMPERINCH / pScrn->widthmm); } if (pScrn->heightmm > 0) { pScrn->yDpi = (int)((double)pScrn->virtualY * MMPERINCH / pScrn->heightmm); } if (pScrn->xDpi > 0 && pScrn->yDpi <= 0) pScrn->yDpi = pScrn->xDpi; if (pScrn->yDpi > 0 && pScrn->xDpi <= 0) pScrn->xDpi = pScrn->yDpi; } else { if (x > 0) pScrn->xDpi = x; else pScrn->xDpi = DEFAULT_DPI; if (y > 0) pScrn->yDpi = y; else pScrn->yDpi = DEFAULT_DPI; } xf86DrvMsg(pScrn->scrnIndex, from, "DPI set to (%d, %d)\n", pScrn->xDpi, pScrn->yDpi); } #undef MMPERINCH _X_EXPORT void xf86SetBlackWhitePixels(ScreenPtr pScreen) { if (xf86FlipPixels) { pScreen->whitePixel = 0; pScreen->blackPixel = 1; } else { pScreen->whitePixel = 1; pScreen->blackPixel = 0; } } /* * xf86SetRootClip -- * Enable or disable rendering to the screen by * setting the root clip list and revalidating * all of the windows */ static void xf86SetRootClip (ScreenPtr pScreen, Bool enable) { WindowPtr pWin = WindowTable[pScreen->myNum]; WindowPtr pChild; Bool WasViewable = (Bool)(pWin->viewable); Bool anyMarked = FALSE; #ifdef DO_SAVE_UNDERS Bool dosave = FALSE; #endif WindowPtr pLayerWin; BoxRec box; if (WasViewable) { for (pChild = pWin->firstChild; pChild; pChild = pChild->nextSib) { (void) (*pScreen->MarkOverlappedWindows)(pChild, pChild, &pLayerWin); } (*pScreen->MarkWindow) (pWin); anyMarked = TRUE; if (pWin->valdata) { if (HasBorder (pWin)) { RegionPtr borderVisible; borderVisible = REGION_CREATE(pScreen, NullBox, 1); REGION_SUBTRACT(pScreen, borderVisible, &pWin->borderClip, &pWin->winSize); pWin->valdata->before.borderVisible = borderVisible; } pWin->valdata->before.resized = TRUE; } } /* * Use REGION_BREAK to avoid optimizations in ValidateTree * that assume the root borderClip can't change well, normally * it doesn't...) */ if (enable) { box.x1 = 0; box.y1 = 0; box.x2 = pScreen->width; box.y2 = pScreen->height; REGION_INIT (pScreen, &pWin->winSize, &box, 1); REGION_INIT (pScreen, &pWin->borderSize, &box, 1); if (WasViewable) REGION_RESET(pScreen, &pWin->borderClip, &box); pWin->drawable.width = pScreen->width; pWin->drawable.height = pScreen->height; REGION_BREAK (pWin->drawable.pScreen, &pWin->clipList); } else { REGION_EMPTY(pScreen, &pWin->borderClip); REGION_BREAK (pWin->drawable.pScreen, &pWin->clipList); } ResizeChildrenWinSize (pWin, 0, 0, 0, 0); if (WasViewable) { if (pWin->firstChild) { anyMarked |= (*pScreen->MarkOverlappedWindows)(pWin->firstChild, pWin->firstChild, (WindowPtr *)NULL); } else { (*pScreen->MarkWindow) (pWin); anyMarked = TRUE; } #ifdef DO_SAVE_UNDERS if (DO_SAVE_UNDERS(pWin)) { dosave = (*pScreen->ChangeSaveUnder)(pLayerWin, pLayerWin); } #endif /* DO_SAVE_UNDERS */ if (anyMarked) (*pScreen->ValidateTree)(pWin, NullWindow, VTOther); } if (WasViewable) { if (anyMarked) (*pScreen->HandleExposures)(pWin); #ifdef DO_SAVE_UNDERS if (dosave) (*pScreen->PostChangeSaveUnder)(pLayerWin, pLayerWin); #endif /* DO_SAVE_UNDERS */ if (anyMarked && pScreen->PostValidateTree) (*pScreen->PostValidateTree)(pWin, NullWindow, VTOther); } if (pWin->realized) WindowsRestructured (); FlushAllOutput (); } /* * Function to enable/disable access to the frame buffer * * This is used when VT switching and when entering/leaving DGA direct mode. * * This has been rewritten again to eliminate the saved pixmap. The * devPrivate field in the screen pixmap is set to NULL to catch code * accidentally referencing the frame buffer while the X server is not * supposed to touch it. * * Here, we exchange the pixmap private data, rather than the pixmaps * themselves to avoid having to find and change any references to the screen * pixmap such as GC's, window privates etc. This also means that this code * does not need to know exactly how the pixmap pixels are accessed. Further, * this exchange is >not< done through the screen's ModifyPixmapHeader() * vector. This means the called frame buffer code layers can determine * whether they are switched in or out by keeping track of the root pixmap's * private data, and therefore don't need to access pScrnInfo->vtSema. */ _X_EXPORT void xf86EnableDisableFBAccess(int scrnIndex, Bool enable) { ScrnInfoPtr pScrnInfo = xf86Screens[scrnIndex]; ScreenPtr pScreen = pScrnInfo->pScreen; PixmapPtr pspix; pspix = (*pScreen->GetScreenPixmap) (pScreen); if (enable) { /* * Restore the screen pixmap devPrivate field */ pspix->devPrivate = pScrnInfo->pixmapPrivate; /* * Restore all of the clip lists on the screen */ if (!xf86Resetting) xf86SetRootClip (pScreen, TRUE); } else { /* * Empty all of the clip lists on the screen */ xf86SetRootClip (pScreen, FALSE); /* * save the screen pixmap devPrivate field and * replace it with NULL so accidental references * to the frame buffer are caught */ pScrnInfo->pixmapPrivate = pspix->devPrivate; pspix->devPrivate.ptr = NULL; } } /* Print driver messages in the standard format */ #undef PREFIX_SIZE #define PREFIX_SIZE 14 _X_EXPORT void xf86VDrvMsgVerb(int scrnIndex, MessageType type, int verb, const char *format, va_list args) { char *tmpFormat; /* Prefix the scrnIndex name to the format string. */ if (scrnIndex >= 0 && scrnIndex < xf86NumScreens && xf86Screens[scrnIndex]->name) { tmpFormat = xalloc(strlen(format) + strlen(xf86Screens[scrnIndex]->name) + PREFIX_SIZE + 1); if (!tmpFormat) return; snprintf(tmpFormat, PREFIX_SIZE + 1, "%s(%d): ", xf86Screens[scrnIndex]->name, scrnIndex); strcat(tmpFormat, format); LogVMessageVerb(type, verb, tmpFormat, args); xfree(tmpFormat); } else LogVMessageVerb(type, verb, format, args); } #undef PREFIX_SIZE /* Print driver messages, with verbose level specified directly */ _X_EXPORT void xf86DrvMsgVerb(int scrnIndex, MessageType type, int verb, const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(scrnIndex, type, verb, format, ap); va_end(ap); } /* Print driver messages, with verbose level of 1 (default) */ _X_EXPORT void xf86DrvMsg(int scrnIndex, MessageType type, const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(scrnIndex, type, 1, format, ap); va_end(ap); } /* Print non-driver messages with verbose level specified directly */ _X_EXPORT void xf86MsgVerb(MessageType type, int verb, const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(-1, type, verb, format, ap); va_end(ap); } /* Print non-driver messages with verbose level of 1 (default) */ _X_EXPORT void xf86Msg(MessageType type, const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(-1, type, 1, format, ap); va_end(ap); } /* Just like ErrorF, but with the verbose level checked */ _X_EXPORT void xf86ErrorFVerb(int verb, const char *format, ...) { va_list ap; va_start(ap, format); if (xf86Verbose >= verb || xf86LogVerbose >= verb) LogVWrite(verb, format, ap); va_end(ap); } /* Like xf86ErrorFVerb, but with an implied verbose level of 1 */ _X_EXPORT void xf86ErrorF(const char *format, ...) { va_list ap; va_start(ap, format); if (xf86Verbose >= 1 || xf86LogVerbose >= 1) LogVWrite(1, format, ap); va_end(ap); } void xf86LogInit() { char *lf = NULL; #define LOGSUFFIX ".log" #define LOGOLDSUFFIX ".old" /* Get the log file name */ if (xf86LogFileFrom == X_DEFAULT) { /* Append the display number and ".log" */ lf = malloc(strlen(xf86LogFile) + strlen("%s") + strlen(LOGSUFFIX) + 1); if (!lf) FatalError("Cannot allocate space for the log file name\n"); sprintf(lf, "%s%%s" LOGSUFFIX, xf86LogFile); xf86LogFile = lf; } xf86LogFile = LogInit(xf86LogFile, LOGOLDSUFFIX); xf86LogFileWasOpened = TRUE; xf86SetVerbosity(xf86Verbose); xf86SetLogVerbosity(xf86LogVerbose); #undef LOGSUFFIX #undef LOGOLDSUFFIX free(lf); } void xf86CloseLog() { LogClose(); } /* * Drivers can use these for using their own SymTabRecs. */ _X_EXPORT const char * xf86TokenToString(SymTabPtr table, int token) { int i; for (i = 0; table[i].token >= 0 && table[i].token != token; i++) ; if (table[i].token < 0) return NULL; else return(table[i].name); } _X_EXPORT int xf86StringToToken(SymTabPtr table, const char *string) { int i; if (string == NULL) return -1; for (i = 0; table[i].token >= 0 && xf86NameCmp(string, table[i].name); i++) ; return(table[i].token); } /* * helper to display the clocks found on a card */ _X_EXPORT void xf86ShowClocks(ScrnInfoPtr scrp, MessageType from) { int j; xf86DrvMsg(scrp->scrnIndex, from, "Pixel clocks available:"); for (j=0; j < scrp->numClocks; j++) { if ((j % 4) == 0) { xf86ErrorF("\n"); xf86DrvMsg(scrp->scrnIndex, from, "pixel clocks:"); } xf86ErrorF(" %7.3f", (double)scrp->clock[j] / 1000.0); } xf86ErrorF("\n"); } /* * This prints out the driver identify message, including the names of * the supported chipsets. * * XXX This makes assumptions about the line width, etc. Maybe we could * use a more general "pretty print" function for messages. */ _X_EXPORT void xf86PrintChipsets(const char *drvname, const char *drvmsg, SymTabPtr chips) { int len, i; len = 6 + strlen(drvname) + 2 + strlen(drvmsg) + 2; xf86Msg(X_INFO, "%s: %s:", drvname, drvmsg); for (i = 0; chips[i].name != NULL; i++) { if (i != 0) { xf86ErrorF(","); len++; } if (len + 2 + strlen(chips[i].name) < 78) { xf86ErrorF(" "); len++; } else { xf86ErrorF("\n\t"); len = 8; } xf86ErrorF("%s", chips[i].name); len += strlen(chips[i].name); } xf86ErrorF("\n"); } _X_EXPORT int xf86MatchDevice(const char *drivername, GDevPtr **sectlist) { GDevPtr gdp, *pgdp = NULL; confScreenPtr screensecptr; int i,j; if (sectlist) *sectlist = NULL; if (xf86DoModalias) return 0; if (xf86DoProbe) return 1; if (xf86DoConfigure && xf86DoConfigurePass1) return 1; /* * This is a very important function that matches the device sections * as they show up in the config file with the drivers that the server * loads at run time. * * ChipProbe can call * int xf86MatchDevice(char * drivername, GDevPtr ** sectlist) * with its driver name. The function allocates an array of GDevPtr and * returns this via sectlist and returns the number of elements in * this list as return value. 0 means none found, -1 means fatal error. * * It can figure out which of the Device sections to use for which card * (using things like the Card statement, etc). For single headed servers * there will of course be just one such Device section. */ i = 0; /* * first we need to loop over all the Screens sections to get to all * 'active' device sections */ for (j=0; xf86ConfigLayout.screens[j].screen != NULL; j++) { screensecptr = xf86ConfigLayout.screens[j].screen; if ((screensecptr->device->driver != NULL) && (xf86NameCmp( screensecptr->device->driver,drivername) == 0) && (! screensecptr->device->claimed)) { /* * we have a matching driver that wasn't claimed, yet */ pgdp = xnfrealloc(pgdp, (i + 2) * sizeof(GDevPtr)); pgdp[i++] = screensecptr->device; } } /* Then handle the inactive devices */ j = 0; while (xf86ConfigLayout.inactives[j].identifier) { gdp = &xf86ConfigLayout.inactives[j]; if (gdp->driver && !gdp->claimed && !xf86NameCmp(gdp->driver,drivername)) { /* we have a matching driver that wasn't claimed yet */ pgdp = xnfrealloc(pgdp, (i + 2) * sizeof(GDevPtr)); pgdp[i++] = gdp; } j++; } /* * make the array NULL terminated and return its address */ if (i) pgdp[i] = NULL; if (sectlist) *sectlist = pgdp; else xfree(pgdp); return i; } struct Inst { struct pci_device * pci; GDevPtr dev; Bool foundHW; /* PCIid in list of supported chipsets */ Bool claimed; /* BusID matches with a device section */ int chip; int screen; }; /** * Find set of unclaimed devices matching a given vendor ID. * * Used by drivers to find as yet unclaimed devices matching the specified * vendor ID. * * \param driverName Name of the driver. This is used to find Device * sections in the config file. * \param vendorID PCI vendor ID of associated devices. If zero, then * the true vendor ID must be encoded in the \c PCIid * fields of the \c PCIchipsets entries. * \param chipsets Symbol table used to associate chipset names with * PCI IDs. * \param devList List of Device sections parsed from the config file. * \param numDevs Number of entries in \c devList. * \param drvp Pointer the driver's control structure. * \param foundEntities Returned list of entity indicies associated with the * driver. * * \returns * The number of elements in returned in \c foundEntities on success or zero * on failure. * * \todo * This function does a bit more than short description says. Fill in some * more of the details of its operation. * * \todo * The \c driverName parameter is redundant. It is the same as * \c DriverRec::driverName. In a future version of this function, remove * that parameter. */ _X_EXPORT int xf86MatchPciInstances(const char *driverName, int vendorID, SymTabPtr chipsets, PciChipsets *PCIchipsets, GDevPtr *devList, int numDevs, DriverPtr drvp, int **foundEntities) { int i,j; struct pci_device * pPci; struct pci_device_iterator *iter; struct Inst *instances = NULL; int numClaimedInstances = 0; int allocatedInstances = 0; int numFound = 0; SymTabRec *c; PciChipsets *id; int *retEntities = NULL; *foundEntities = NULL; /* Each PCI device will contribute at least one entry. Each device * section can contribute at most one entry. The sum of the two is * guaranteed to be larger than the maximum possible number of entries. * Do this calculation and memory allocation once now to eliminate the * need for realloc calls inside the loop. */ if ( !xf86DoProbe && !(xf86DoConfigure && xf86DoConfigurePass1) ) { unsigned max_entries = numDevs; iter = pci_slot_match_iterator_create(NULL); while ((pPci = pci_device_next(iter)) != NULL) { max_entries++; } pci_iterator_destroy(iter); instances = xnfalloc(max_entries * sizeof(struct Inst)); } iter = pci_slot_match_iterator_create(NULL); while ((pPci = pci_device_next(iter)) != NULL) { unsigned device_class = pPci->device_class; Bool foundVendor = FALSE; /* Convert the pre-PCI 2.0 device class for a VGA adapter to the * 2.0 version of the same class. */ if ( device_class == 0x00000101 ) { device_class = 0x00030000; } /* Find PCI devices that match the given vendor ID. The vendor ID is * either specified explicitly as a parameter to the function or * implicitly encoded in the high bits of id->PCIid. * * The first device with a matching vendor is recorded, even if the * device ID doesn't match. This is done because the Device section * in the xorg.conf file can over-ride the device ID. A matching PCI * ID might not be found now, but after the device ID over-ride is * applied there /might/ be a match. */ for (id = PCIchipsets; id->PCIid != -1; id++) { const unsigned vendor_id = ((id->PCIid & 0xFFFF0000) >> 16) | vendorID; const unsigned device_id = (id->PCIid & 0x0000FFFF); const unsigned match_class = 0x00030000 | id->PCIid; if ((vendor_id == pPci->vendor_id) || ((vendorID == PCI_VENDOR_GENERIC) && (match_class == device_class))) { if (!foundVendor && (instances != NULL)) { ++allocatedInstances; instances[allocatedInstances - 1].pci = pPci; instances[allocatedInstances - 1].dev = NULL; instances[allocatedInstances - 1].claimed = FALSE; instances[allocatedInstances - 1].foundHW = FALSE; instances[allocatedInstances - 1].screen = 0; } foundVendor = TRUE; if ( (device_id == pPci->device_id) || ((vendorID == PCI_VENDOR_GENERIC) && (match_class == device_class)) ) { if ( instances != NULL ) { instances[allocatedInstances - 1].foundHW = TRUE; instances[allocatedInstances - 1].chip = id->numChipset; } if ( xf86DoConfigure && xf86DoConfigurePass1 ) { if (xf86CheckPciSlot(pPci)) { GDevPtr pGDev = xf86AddDeviceToConfigure(drvp->driverName, pPci, -1); if (pGDev) { /* After configure pass 1, chipID and chipRev * are treated as over-rides, so clobber them * here. */ pGDev->chipID = -1; pGDev->chipRev = -1; } numFound++; } } else { numFound++; } break; } } } } pci_iterator_destroy(iter); /* In "probe only" or "configure" mode (signaled by instances being NULL), * our work is done. Return the number of detected devices. */ if ( instances == NULL ) { return numFound; } /* * This may be debatable, but if no PCI devices with a matching vendor * type is found, return zero now. It is probably not desirable to * allow the config file to override this. */ if (allocatedInstances <= 0) { xfree(instances); return 0; } #ifdef DEBUG ErrorF("%s instances found: %d\n", driverName, allocatedInstances); #endif /* * Check for devices that need duplicated instances. This is required * when there is more than one screen per entity. * * XXX This currently doesn't work for cases where the BusID isn't * specified explicitly in the config file. */ for (j = 0; j < numDevs; j++) { if (devList[j]->screen > 0 && devList[j]->busID && *devList[j]->busID) { for (i = 0; i < allocatedInstances; i++) { pPci = instances[i].pci; if (xf86ComparePciBusString(devList[j]->busID, PCI_MAKE_BUS( pPci->domain, pPci->bus ), pPci->dev, pPci->func)) { allocatedInstances++; instances[allocatedInstances - 1] = instances[i]; instances[allocatedInstances - 1].screen = devList[j]->screen; numFound++; break; } } } } for (i = 0; i < allocatedInstances; i++) { GDevPtr dev = NULL; GDevPtr devBus = NULL; pPci = instances[i].pci; for (j = 0; j < numDevs; j++) { if (devList[j]->busID && *devList[j]->busID) { if (xf86ComparePciBusString(devList[j]->busID, PCI_MAKE_BUS( pPci->domain, pPci->bus ), pPci->dev, pPci->func) && devList[j]->screen == instances[i].screen) { if (devBus) xf86MsgVerb(X_WARNING,0, "%s: More than one matching Device section for " "instances\n\t(BusID: %s) found: %s\n", driverName, devList[j]->busID, devList[j]->identifier); else devBus = devList[j]; } } else { /* * if device section without BusID is found * only assign to it to the primary device. */ if (xf86IsPrimaryPci(pPci)) { xf86Msg(X_PROBED, "Assigning device section with no busID" " to primary device\n"); if (dev || devBus) xf86MsgVerb(X_WARNING, 0, "%s: More than one matching Device section " "found: %s\n", driverName, devList[j]->identifier); else dev = devList[j]; } } } if (devBus) dev = devBus; /* busID preferred */ if (!dev) { if ( xf86CheckPciSlot( pPci ) ) { xf86MsgVerb(X_WARNING, 0, "%s: No matching Device section " "for instance (BusID PCI:%u@%u:%u:%u) found\n", driverName, pPci->domain, pPci->bus, pPci->dev, pPci->func); } } else { numClaimedInstances++; instances[i].claimed = TRUE; instances[i].dev = dev; } } #ifdef DEBUG ErrorF("%s instances found: %d\n", driverName, numClaimedInstances); #endif /* * Now check that a chipset or chipID override in the device section * is valid. Chipset has precedence over chipID. * If chipset is not valid ignore BusSlot completely. */ for (i = 0; i < allocatedInstances && numClaimedInstances > 0; i++) { MessageType from = X_PROBED; if (!instances[i].claimed) { continue; } if (instances[i].dev->chipset) { for (c = chipsets; c->token >= 0; c++) { if (xf86NameCmp(c->name, instances[i].dev->chipset) == 0) break; } if (c->token == -1) { instances[i].claimed = FALSE; numClaimedInstances--; xf86MsgVerb(X_WARNING, 0, "%s: Chipset \"%s\" in Device " "section \"%s\" isn't valid for this driver\n", driverName, instances[i].dev->chipset, instances[i].dev->identifier); } else { instances[i].chip = c->token; for (id = PCIchipsets; id->numChipset >= 0; id++) { if (id->numChipset == instances[i].chip) break; } if(id->numChipset >=0){ xf86Msg(X_CONFIG,"Chipset override: %s\n", instances[i].dev->chipset); from = X_CONFIG; } else { instances[i].claimed = FALSE; numClaimedInstances--; xf86MsgVerb(X_WARNING, 0, "%s: Chipset \"%s\" in Device " "section \"%s\" isn't a valid PCI chipset\n", driverName, instances[i].dev->chipset, instances[i].dev->identifier); } } } else if (instances[i].dev->chipID > 0) { for (id = PCIchipsets; id->numChipset >= 0; id++) { if (id->PCIid == instances[i].dev->chipID) break; } if (id->numChipset == -1) { instances[i].claimed = FALSE; numClaimedInstances--; xf86MsgVerb(X_WARNING, 0, "%s: ChipID 0x%04X in Device " "section \"%s\" isn't valid for this driver\n", driverName, instances[i].dev->chipID, instances[i].dev->identifier); } else { instances[i].chip = id->numChipset; xf86Msg( X_CONFIG,"ChipID override: 0x%04X\n", instances[i].dev->chipID); from = X_CONFIG; } } else if (!instances[i].foundHW) { /* * This means that there was no override and the PCI chipType * doesn't match one that is supported */ instances[i].claimed = FALSE; numClaimedInstances--; } if (instances[i].claimed == TRUE){ for (c = chipsets; c->token >= 0; c++) { if (c->token == instances[i].chip) break; } xf86Msg(from,"Chipset %s found\n", c->name); } } /* * Of the claimed instances, check that another driver hasn't already * claimed its slot. */ numFound = 0; for (i = 0; i < allocatedInstances && numClaimedInstances > 0; i++) { if (!instances[i].claimed) continue; pPci = instances[i].pci; /* * Allow the same entity to be used more than once for devices with * multiple screens per entity. This assumes implicitly that there * will be a screen == 0 instance. * * XXX Need to make sure that two different drivers don't claim * the same screen > 0 instance. */ if (instances[i].screen == 0 && !xf86CheckPciSlot( pPci )) continue; #ifdef DEBUG ErrorF("%s: card at %d:%d:%d is claimed by a Device section\n", driverName, pPci->bus, pPci->dev, pPci->func); #endif /* Allocate an entry in the lists to be returned */ numFound++; retEntities = xnfrealloc(retEntities, numFound * sizeof(int)); retEntities[numFound - 1] = xf86ClaimPciSlot( pPci, drvp, instances[i].chip, instances[i].dev, instances[i].dev->active); if (retEntities[numFound - 1] == -1 && instances[i].screen > 0) { for (j = 0; j < xf86NumEntities; j++) { EntityPtr pEnt = xf86Entities[j]; if (pEnt->bus.type != BUS_PCI) continue; if (pEnt->bus.id.pci == pPci) { retEntities[numFound - 1] = j; xf86AddDevToEntity(j, instances[i].dev); break; } } } } xfree(instances); if (numFound > 0) { *foundEntities = retEntities; } return numFound; } _X_EXPORT int xf86MatchIsaInstances(const char *driverName, SymTabPtr chipsets, IsaChipsets *ISAchipsets, DriverPtr drvp, FindIsaDevProc FindIsaDevice, GDevPtr *devList, int numDevs, int **foundEntities) { SymTabRec *c; IsaChipsets *Chips; int i; int numFound = 0; int foundChip = -1; int *retEntities = NULL; *foundEntities = NULL; #if defined(__sparc__) || defined(__powerpc__) FindIsaDevice = NULL; /* Temporary */ #endif if (xf86DoProbe || (xf86DoConfigure && xf86DoConfigurePass1)) { if (FindIsaDevice && ((foundChip = (*FindIsaDevice)(NULL)) != -1)) { xf86AddDeviceToConfigure(drvp->driverName, NULL, foundChip); return 1; } return 0; } for (i = 0; i < numDevs; i++) { MessageType from = X_CONFIG; GDevPtr dev = NULL; GDevPtr devBus = NULL; if (devList[i]->busID && *devList[i]->busID) { if (xf86ParseIsaBusString(devList[i]->busID)) { if (devBus) xf86MsgVerb(X_WARNING,0, "%s: More than one matching Device " "section for ISA-Bus found: %s\n", driverName,devList[i]->identifier); else devBus = devList[i]; } } else { if (xf86IsPrimaryIsa()) { if (dev) xf86MsgVerb(X_WARNING,0, "%s: More than one matching " "Device section found: %s\n", driverName,devList[i]->identifier); else dev = devList[i]; } } if (devBus) dev = devBus; if (dev) { if (dev->chipset) { for (c = chipsets; c->token >= 0; c++) { if (xf86NameCmp(c->name, dev->chipset) == 0) break; } if (c->token == -1) { xf86MsgVerb(X_WARNING, 0, "%s: Chipset \"%s\" in Device " "section \"%s\" isn't valid for this driver\n", driverName, dev->chipset, dev->identifier); } else foundChip = c->token; } else { if (FindIsaDevice) foundChip = (*FindIsaDevice)(dev); /* Probe it */ from = X_PROBED; } } /* Check if the chip type is listed in the chipset table - for sanity*/ if (foundChip >= 0){ for (Chips = ISAchipsets; Chips->numChipset >= 0; Chips++) { if (Chips->numChipset == foundChip) break; } if (Chips->numChipset == -1){ foundChip = -1; xf86MsgVerb(X_WARNING,0, "%s: Driver detected unknown ISA-Bus Chipset\n", driverName); } } if (foundChip != -1) { numFound++; retEntities = xnfrealloc(retEntities,numFound * sizeof(int)); retEntities[numFound - 1] = xf86ClaimIsaSlot(drvp,foundChip,dev, dev->active ? TRUE : FALSE); for (c = chipsets; c->token >= 0; c++) { if (c->token == foundChip) break; } xf86Msg(from, "Chipset %s found\n", c->name); } } *foundEntities = retEntities; return numFound; } /* * xf86GetClocks -- get the dot-clocks via a BIG BAD hack ... */ _X_EXPORT void xf86GetClocks(ScrnInfoPtr pScrn, int num, Bool (*ClockFunc)(ScrnInfoPtr, int), void (*ProtectRegs)(ScrnInfoPtr, Bool), void (*BlankScreen)(ScrnInfoPtr, Bool), IOADDRESS vertsyncreg, int maskval, int knownclkindex, int knownclkvalue) { register int status = vertsyncreg; unsigned long i, cnt, rcnt, sync; /* First save registers that get written on */ (*ClockFunc)(pScrn, CLK_REG_SAVE); xf86SetPriority(TRUE); if (num > MAXCLOCKS) num = MAXCLOCKS; for (i = 0; i < num; i++) { if (ProtectRegs) (*ProtectRegs)(pScrn, TRUE); if (!(*ClockFunc)(pScrn, i)) { pScrn->clock[i] = -1; continue; } if (ProtectRegs) (*ProtectRegs)(pScrn, FALSE); if (BlankScreen) (*BlankScreen)(pScrn, FALSE); usleep(50000); /* let VCO stabilise */ cnt = 0; sync = 200000; /* XXX How critical is this? */ if (!xf86DisableInterrupts()) { (*ClockFunc)(pScrn, CLK_REG_RESTORE); ErrorF("Failed to disable interrupts during clock probe. If\n"); ErrorF("your OS does not support disabling interrupts, then you\n"); FatalError("must specify a Clocks line in the XF86Config file.\n"); } while ((inb(status) & maskval) == 0x00) if (sync-- == 0) goto finish; /* Something appears to be happening, so reset sync count */ sync = 200000; while ((inb(status) & maskval) == maskval) if (sync-- == 0) goto finish; /* Something appears to be happening, so reset sync count */ sync = 200000; while ((inb(status) & maskval) == 0x00) if (sync-- == 0) goto finish; for (rcnt = 0; rcnt < 5; rcnt++) { while (!(inb(status) & maskval)) cnt++; while ((inb(status) & maskval)) cnt++; } finish: xf86EnableInterrupts(); pScrn->clock[i] = cnt ? cnt : -1; if (BlankScreen) (*BlankScreen)(pScrn, TRUE); } xf86SetPriority(FALSE); for (i = 0; i < num; i++) { if (i != knownclkindex) { if (pScrn->clock[i] == -1) { pScrn->clock[i] = 0; } else { pScrn->clock[i] = (int)(0.5 + (((float)knownclkvalue) * pScrn->clock[knownclkindex]) / (pScrn->clock[i])); /* Round to nearest 10KHz */ pScrn->clock[i] += 5; pScrn->clock[i] /= 10; pScrn->clock[i] *= 10; } } } pScrn->clock[knownclkindex] = knownclkvalue; pScrn->numClocks = num; /* Restore registers that were written on */ (*ClockFunc)(pScrn, CLK_REG_RESTORE); } _X_EXPORT void xf86SetPriority(Bool up) { static int saved_nice; if (up) { #ifdef HAS_SETPRIORITY saved_nice = getpriority(PRIO_PROCESS, 0); setpriority(PRIO_PROCESS, 0, -20); #endif #if defined(SYSV) || defined(SVR4) || defined(linux) saved_nice = nice(0); nice(-20 - saved_nice); #endif } else { #ifdef HAS_SETPRIORITY setpriority(PRIO_PROCESS, 0, saved_nice); #endif #if defined(SYSV) || defined(SVR4) || defined(linux) nice(20 + saved_nice); #endif } } _X_EXPORT const char * xf86GetVisualName(int visual) { if (visual < 0 || visual > DirectColor) return NULL; return xf86VisualNames[visual]; } _X_EXPORT int xf86GetVerbosity() { return max(xf86Verbose, xf86LogVerbose); } _X_EXPORT Pix24Flags xf86GetPix24() { return xf86Info.pixmap24; } _X_EXPORT int xf86GetDepth() { return xf86Depth; } _X_EXPORT rgb xf86GetWeight() { return xf86Weight; } _X_EXPORT Gamma xf86GetGamma() { return xf86Gamma; } _X_EXPORT Bool xf86GetFlipPixels() { return xf86FlipPixels; } _X_EXPORT const char * xf86GetServerName() { return xf86ServerName; } _X_EXPORT Bool xf86ServerIsExiting() { return (dispatchException & DE_TERMINATE) == DE_TERMINATE; } _X_EXPORT Bool xf86ServerIsResetting() { return xf86Resetting; } Bool xf86ServerIsInitialising() { return xf86Initialising; } _X_EXPORT Bool xf86ServerIsOnlyDetecting(void) { return xf86DoProbe || xf86DoConfigure; } _X_EXPORT Bool xf86ServerIsOnlyProbing(void) { return xf86ProbeOnly; } _X_EXPORT Bool xf86CaughtSignal() { return xf86Info.caughtSignal; } _X_EXPORT Bool xf86GetVidModeAllowNonLocal() { return xf86Info.vidModeAllowNonLocal; } _X_EXPORT Bool xf86GetVidModeEnabled() { return xf86Info.vidModeEnabled; } _X_EXPORT Bool xf86GetModInDevAllowNonLocal() { return xf86Info.miscModInDevAllowNonLocal; } _X_EXPORT Bool xf86GetModInDevEnabled() { return xf86Info.miscModInDevEnabled; } _X_EXPORT Bool xf86GetAllowMouseOpenFail() { return xf86Info.allowMouseOpenFail; } _X_EXPORT Bool xf86IsPc98() { #ifdef __i386__ return xf86Info.pc98; #else return FALSE; #endif } _X_EXPORT void xf86DisableRandR() { xf86Info.disableRandR = TRUE; xf86Info.randRFrom = X_PROBED; } _X_EXPORT CARD32 xf86GetVersion() { return XF86_VERSION_CURRENT; } _X_EXPORT CARD32 xf86GetModuleVersion(pointer module) { return (CARD32)LoaderGetModuleVersion(module); } _X_EXPORT pointer xf86LoadDrvSubModule(DriverPtr drv, const char *name) { pointer ret; int errmaj = 0, errmin = 0; ret = LoadSubModule(drv->module, name, NULL, NULL, NULL, NULL, &errmaj, &errmin); if (!ret) LoaderErrorMsg(NULL, name, errmaj, errmin); return ret; } _X_EXPORT pointer xf86LoadSubModule(ScrnInfoPtr pScrn, const char *name) { pointer ret; int errmaj = 0, errmin = 0; ret = LoadSubModule(pScrn->module, name, NULL, NULL, NULL, NULL, &errmaj, &errmin); if (!ret) LoaderErrorMsg(pScrn->name, name, errmaj, errmin); return ret; } /* * xf86LoadOneModule loads a single module. */ _X_EXPORT pointer xf86LoadOneModule(char *name, pointer opt) { int errmaj, errmin; char *Name; pointer mod; if (!name) return NULL; /* Normalise the module name */ Name = xf86NormalizeName(name); /* Skip empty names */ if (Name == NULL) return NULL; if (*Name == '\0') { xfree(Name); return NULL; } mod = LoadModule(Name, NULL, NULL, NULL, opt, NULL, &errmaj, &errmin); if (!mod) LoaderErrorMsg(NULL, Name, errmaj, errmin); xfree(Name); return mod; } _X_EXPORT void xf86UnloadSubModule(pointer mod) { /* * This is disabled for now. The loader isn't smart enough yet to undo * relocations. */ #if 0 UnloadSubModule(mod); #endif } _X_EXPORT Bool xf86LoaderCheckSymbol(const char *name) { return LoaderSymbol(name) != NULL; } /* These two are just ABI stubs, they don't do anything in dlloader world */ _X_EXPORT void xf86LoaderReqSymLists(const char **list0, ...) { } _X_EXPORT void xf86LoaderReqSymbols(const char *sym0, ...) { } _X_EXPORT void xf86LoaderRefSymLists(const char **list0, ...) { } _X_EXPORT void xf86LoaderRefSymbols(const char *sym0, ...) { } typedef enum { OPTION_BACKING_STORE } BSOpts; static const OptionInfoRec BSOptions[] = { { OPTION_BACKING_STORE, "BackingStore", OPTV_BOOLEAN, {0}, FALSE }, { -1, NULL, OPTV_NONE, {0}, FALSE } }; _X_EXPORT void xf86SetBackingStore(ScreenPtr pScreen) { Bool useBS = FALSE; MessageType from = X_DEFAULT; ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; OptionInfoPtr options; options = xnfalloc(sizeof(BSOptions)); (void)memcpy(options, BSOptions, sizeof(BSOptions)); xf86ProcessOptions(pScrn->scrnIndex, pScrn->options, options); /* check for commandline option here */ if (xf86bsEnableFlag) { from = X_CMDLINE; useBS = TRUE; } else if (xf86bsDisableFlag) { from = X_CMDLINE; useBS = FALSE; } else { if (xf86GetOptValBool(options, OPTION_BACKING_STORE, &useBS)) from = X_CONFIG; } xfree(options); pScreen->backingStoreSupport = useBS ? Always : NotUseful; if (serverGeneration == 1) xf86DrvMsg(pScreen->myNum, from, "Backing store %s\n", useBS ? "enabled" : "disabled"); } typedef enum { OPTION_SILKEN_MOUSE } SMOpts; static const OptionInfoRec SMOptions[] = { { OPTION_SILKEN_MOUSE, "SilkenMouse", OPTV_BOOLEAN, {0}, FALSE }, { -1, NULL, OPTV_NONE, {0}, FALSE } }; _X_EXPORT void xf86SetSilkenMouse (ScreenPtr pScreen) { Bool useSM = TRUE; MessageType from = X_DEFAULT; ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; OptionInfoPtr options; options = xnfalloc(sizeof(SMOptions)); (void)memcpy(options, SMOptions, sizeof(SMOptions)); xf86ProcessOptions(pScrn->scrnIndex, pScrn->options, options); /* check for commandline option here */ /* disable if screen shares resources */ if (((pScrn->racMemFlags & RAC_CURSOR) && !xf86NoSharedResources(pScrn->scrnIndex,MEM)) || ((pScrn->racIoFlags & RAC_CURSOR) && !xf86NoSharedResources(pScrn->scrnIndex,IO))) { useSM = FALSE; from = X_PROBED; } else if (xf86silkenMouseDisableFlag) { from = X_CMDLINE; useSM = FALSE; } else { if (xf86GetOptValBool(options, OPTION_SILKEN_MOUSE, &useSM)) from = X_CONFIG; } xfree(options); /* * XXX quick hack to report correctly for OSs that can't do SilkenMouse * yet. Should handle this differently so that alternate async methods * work correctly with this too. */ pScrn->silkenMouse = useSM && xf86SIGIOSupported(); if (serverGeneration == 1) xf86DrvMsg(pScreen->myNum, from, "Silken mouse %s\n", pScrn->silkenMouse ? "enabled" : "disabled"); } /* Wrote this function for the PM2 Xv driver, preliminary. */ _X_EXPORT pointer xf86FindXvOptions(int scrnIndex, int adaptor_index, char *port_name, char **adaptor_name, pointer *adaptor_options) { ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; confXvAdaptorPtr adaptor; int i; if (adaptor_index >= pScrn->confScreen->numxvadaptors) { if (adaptor_name) *adaptor_name = NULL; if (adaptor_options) *adaptor_options = NULL; return NULL; } adaptor = &pScrn->confScreen->xvadaptors[adaptor_index]; if (adaptor_name) *adaptor_name = adaptor->identifier; if (adaptor_options) *adaptor_options = adaptor->options; for (i = 0; i < adaptor->numports; i++) if (!xf86NameCmp(adaptor->ports[i].identifier, port_name)) return adaptor->ports[i].options; return NULL; } /* Rather than duplicate loader's get OS function, just include it directly */ #define LoaderGetOS xf86GetOS #include "loader/os.c" /* new RAC */ /* * xf86ConfigIsa/PciEntity() -- These helper functions assign an * active entity to a screen, registers its fixed resources, assign * special enter/leave functions and their private scratch area to * this entity, take the dog for a walk... */ _X_EXPORT ScrnInfoPtr xf86ConfigIsaEntity(ScrnInfoPtr pScrn, int scrnFlag, int entityIndex, IsaChipsets *i_chip, resList res, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { IsaChipsets *i_id; EntityInfoPtr pEnt = xf86GetEntityInfo(entityIndex); if (!pEnt) return pScrn; if (!(pEnt->location.type == BUS_ISA)) { xfree(pEnt); return pScrn; } if (!pEnt->active) { xf86ConfigIsaEntityInactive(pEnt, i_chip, res, init, enter, leave, private); xfree(pEnt); return pScrn; } if (!pScrn) pScrn = xf86AllocateScreen(pEnt->driver,scrnFlag); xf86AddEntityToScreen(pScrn,entityIndex); if (i_chip) { for (i_id = i_chip; i_id->numChipset != -1; i_id++) { if (pEnt->chipset == i_id->numChipset) break; } xf86ClaimFixedResources(i_id->resList,entityIndex); } xfree(pEnt); xf86ClaimFixedResources(res,entityIndex); xf86SetEntityFuncs(entityIndex,init,enter,leave,private); return pScrn; } _X_EXPORT ScrnInfoPtr xf86ConfigPciEntity(ScrnInfoPtr pScrn, int scrnFlag, int entityIndex, PciChipsets *p_chip, resList res, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { PciChipsets *p_id; EntityInfoPtr pEnt = xf86GetEntityInfo(entityIndex); if (!pEnt) return pScrn; if (!(pEnt->location.type == BUS_PCI) || !xf86GetPciInfoForEntity(entityIndex)) { xfree(pEnt); return pScrn; } if (!pEnt->active) { xf86ConfigPciEntityInactive(pEnt, p_chip, res, init, enter, leave, private); xfree(pEnt); return pScrn; } if (!pScrn) pScrn = xf86AllocateScreen(pEnt->driver,scrnFlag); if (xf86IsEntitySharable(entityIndex)) { xf86SetEntityShared(entityIndex); } xf86AddEntityToScreen(pScrn,entityIndex); if (xf86IsEntityShared(entityIndex)) { return pScrn; } if (p_chip) { for (p_id = p_chip; p_id->numChipset != -1; p_id++) { if (pEnt->chipset == p_id->numChipset) break; } xf86ClaimFixedResources(p_id->resList,entityIndex); } xfree(pEnt); xf86ClaimFixedResources(res,entityIndex); xf86SetEntityFuncs(entityIndex,init,enter,leave,private); return pScrn; } _X_EXPORT ScrnInfoPtr xf86ConfigFbEntity(ScrnInfoPtr pScrn, int scrnFlag, int entityIndex, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { EntityInfoPtr pEnt = xf86GetEntityInfo(entityIndex); if (!pEnt) return pScrn; if (!(pEnt->location.type == BUS_NONE)) { xfree(pEnt); return pScrn; } if (!pEnt->active) { xf86ConfigFbEntityInactive(pEnt, init, enter, leave, private); xfree(pEnt); return pScrn; } if (!pScrn) pScrn = xf86AllocateScreen(pEnt->driver,scrnFlag); xf86AddEntityToScreen(pScrn,entityIndex); xf86SetEntityFuncs(entityIndex,init,enter,leave,private); return pScrn; } /* * * OBSOLETE ! xf86ConfigActiveIsaEntity() and xf86ConfigActivePciEntity() * are obsolete functions. They the are likely to be removed * Don't use! */ _X_EXPORT Bool xf86ConfigActiveIsaEntity(ScrnInfoPtr pScrn, int entityIndex, IsaChipsets *i_chip, resList res, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { IsaChipsets *i_id; EntityInfoPtr pEnt = xf86GetEntityInfo(entityIndex); if (!pEnt) return FALSE; if (!pEnt->active || !(pEnt->location.type == BUS_ISA)) { xfree(pEnt); return FALSE; } xf86AddEntityToScreen(pScrn,entityIndex); if (i_chip) { for (i_id = i_chip; i_id->numChipset != -1; i_id++) { if (pEnt->chipset == i_id->numChipset) break; } xf86ClaimFixedResources(i_id->resList,entityIndex); } xfree(pEnt); xf86ClaimFixedResources(res,entityIndex); if (!xf86SetEntityFuncs(entityIndex,init,enter,leave,private)) return FALSE; return TRUE; } _X_EXPORT Bool xf86ConfigActivePciEntity(ScrnInfoPtr pScrn, int entityIndex, PciChipsets *p_chip, resList res, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { PciChipsets *p_id; EntityInfoPtr pEnt = xf86GetEntityInfo(entityIndex); if (!pEnt) return FALSE; if (!pEnt->active || !(pEnt->location.type == BUS_PCI)) { xfree(pEnt); return FALSE; } xf86AddEntityToScreen(pScrn,entityIndex); if (p_chip) { for (p_id = p_chip; p_id->numChipset != -1; p_id++) { if (pEnt->chipset == p_id->numChipset) break; } xf86ClaimFixedResources(p_id->resList,entityIndex); } xfree(pEnt); xf86ClaimFixedResources(res,entityIndex); if (!xf86SetEntityFuncs(entityIndex,init,enter,leave,private)) return FALSE; return TRUE; } /* * xf86ConfigPci/IsaEntityInactive() -- These functions can be used * to configure an inactive entity as well as to reconfigure an * previously active entity inactive. If the entity has been * assigned to a screen before it will be removed. If p_pci(p_isa) is * non-NULL all static resources listed there will be registered. */ _X_EXPORT void xf86ConfigPciEntityInactive(EntityInfoPtr pEnt, PciChipsets *p_chip, resList res, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { PciChipsets *p_id; ScrnInfoPtr pScrn; if ((pScrn = xf86FindScreenForEntity(pEnt->index))) xf86RemoveEntityFromScreen(pScrn,pEnt->index); else if (p_chip) { for (p_id = p_chip; p_id->numChipset != -1; p_id++) { if (pEnt->chipset == p_id->numChipset) break; } xf86ClaimFixedResources(p_id->resList,pEnt->index); } xf86ClaimFixedResources(res,pEnt->index); /* shared resources are only needed when entity is active: remove */ xf86DeallocateResourcesForEntity(pEnt->index, ResShared); xf86SetEntityFuncs(pEnt->index,init,enter,leave,private); } _X_EXPORT void xf86ConfigIsaEntityInactive(EntityInfoPtr pEnt, IsaChipsets *i_chip, resList res, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { IsaChipsets *i_id; ScrnInfoPtr pScrn; if ((pScrn = xf86FindScreenForEntity(pEnt->index))) xf86RemoveEntityFromScreen(pScrn,pEnt->index); else if (i_chip) { for (i_id = i_chip; i_id->numChipset != -1; i_id++) { if (pEnt->chipset == i_id->numChipset) break; } xf86ClaimFixedResources(i_id->resList,pEnt->index); } xf86ClaimFixedResources(res,pEnt->index); /* shared resources are only needed when entity is active: remove */ xf86DeallocateResourcesForEntity(pEnt->index, ResShared); xf86SetEntityFuncs(pEnt->index,init,enter,leave,private); } void xf86ConfigFbEntityInactive(EntityInfoPtr pEnt, EntityProc init, EntityProc enter, EntityProc leave, pointer private) { ScrnInfoPtr pScrn; if ((pScrn = xf86FindScreenForEntity(pEnt->index))) xf86RemoveEntityFromScreen(pScrn,pEnt->index); xf86SetEntityFuncs(pEnt->index,init,enter,leave,private); } _X_EXPORT Bool xf86IsScreenPrimary(int scrnIndex) { ScrnInfoPtr pScrn = xf86Screens[scrnIndex]; int i; for (i=0 ; i < pScrn->numEntities; i++) { if (xf86IsEntityPrimary(i)) return TRUE; } return FALSE; } _X_EXPORT int xf86RegisterRootWindowProperty(int ScrnIndex, Atom property, Atom type, int format, unsigned long len, pointer value ) { RootWinPropPtr pNewProp = NULL, pRegProp; int i; Bool existing = FALSE; #ifdef DEBUG ErrorF("xf86RegisterRootWindowProperty(%d, %ld, %ld, %d, %ld, %p)\n", ScrnIndex, property, type, format, len, value); #endif if (ScrnIndex<0 || ScrnIndex>=xf86NumScreens) { return(BadMatch); } if (xf86RegisteredPropertiesTable && xf86RegisteredPropertiesTable[ScrnIndex]) { for (pNewProp = xf86RegisteredPropertiesTable[ScrnIndex]; pNewProp; pNewProp = pNewProp->next) { if (strcmp(pNewProp->name, NameForAtom(property)) == 0) break; } } if (!pNewProp) { if ((pNewProp = (RootWinPropPtr)xalloc(sizeof(RootWinProp))) == NULL) { return(BadAlloc); } /* * We will put this property at the end of the list so that * the changes are made in the order they were requested. */ pNewProp->next = NULL; } else { if (pNewProp->name) xfree(pNewProp->name); existing = TRUE; } pNewProp->name = xnfstrdup(NameForAtom(property)); pNewProp->type = type; pNewProp->format = format; pNewProp->size = len; pNewProp->data = value; #ifdef DEBUG ErrorF("new property filled\n"); #endif if (NULL==xf86RegisteredPropertiesTable) { #ifdef DEBUG ErrorF("creating xf86RegisteredPropertiesTable[] size %d\n", xf86NumScreens); #endif if ( NULL==(xf86RegisteredPropertiesTable=(RootWinPropPtr*)xnfcalloc(sizeof(RootWinProp),xf86NumScreens) )) { return(BadAlloc); } for (i=0; inext != NULL) { #ifdef DEBUG ErrorF("- next %p\n", (void *)pRegProp); #endif pRegProp = pRegProp->next; } pRegProp->next = pNewProp; } } #ifdef DEBUG ErrorF("xf86RegisterRootWindowProperty succeeded\n"); #endif return(Success); } _X_EXPORT Bool xf86IsUnblank(int mode) { switch(mode) { case SCREEN_SAVER_OFF: case SCREEN_SAVER_FORCER: return TRUE; case SCREEN_SAVER_ON: case SCREEN_SAVER_CYCLE: return FALSE; default: xf86MsgVerb(X_WARNING, 0, "Unexpected save screen mode: %d\n", mode); return TRUE; } } _X_EXPORT void xf86MotionHistoryAllocate(LocalDevicePtr local) { AllocateMotionHistory(local->dev); } _X_EXPORT int xf86GetMotionEvents(DeviceIntPtr pDev, xTimecoord *buff, unsigned long start, unsigned long stop, ScreenPtr pScreen) { return GetMotionHistory(pDev, buff, start, stop, pScreen); } _X_EXPORT void xf86getsecs(long * secs, long * usecs) { struct timeval tv; X_GETTIMEOFDAY(&tv); if (secs) *secs = tv.tv_sec; if (usecs) *usecs= tv.tv_usec; return; }