/* $XFree86: xc/programs/Xserver/hw/xfree86/drivers/ati/radeon_dri.c,v 1.39 2003/11/06 18:38:00 tsi Exp $ */ /* * Copyright 2000 ATI Technologies Inc., Markham, Ontario, * VA Linux Systems Inc., Fremont, California. * * All Rights Reserved. * * 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 on 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 (including the * next paragraph) 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 * NON-INFRINGEMENT. IN NO EVENT SHALL ATI, VA LINUX SYSTEMS AND/OR * THEIR SUPPLIERS 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. */ /* * Authors: * Kevin E. Martin * Rickard E. Faith * Gareth Hughes * */ /* Driver data structures */ #include "radeon.h" #include "radeon_macros.h" #include "radeon_dri.h" #include "radeon_reg.h" #include "radeon_version.h" /* X and server generic header files */ #include "xf86.h" #include "xf86PciInfo.h" #include "windowstr.h" #include "shadowfb.h" /* GLX/DRI/DRM definitions */ #define _XF86DRI_SERVER_ #include "GL/glxtokens.h" #include "sarea.h" #include "radeon_sarea.h" static size_t radeon_drm_page_size; static Bool RADEONDRICloseFullScreen(ScreenPtr pScreen); static Bool RADEONDRIOpenFullScreen(ScreenPtr pScreen); static void RADEONDRITransitionTo2d(ScreenPtr pScreen); static void RADEONDRITransitionTo3d(ScreenPtr pScreen); static void RADEONDRITransitionMultiToSingle3d(ScreenPtr pScreen); static void RADEONDRITransitionSingleToMulti3d(ScreenPtr pScreen); static void RADEONDRIRefreshArea(ScrnInfoPtr pScrn, int num, BoxPtr pbox); /* Initialize the visual configs that are supported by the hardware. * These are combined with the visual configs that the indirect * rendering core supports, and the intersection is exported to the * client. */ static Bool RADEONInitVisualConfigs(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); int numConfigs = 0; __GLXvisualConfig *pConfigs = 0; RADEONConfigPrivPtr pRADEONConfigs = 0; RADEONConfigPrivPtr *pRADEONConfigPtrs = 0; int i, accum, stencil, db, use_db; use_db = !info->noBackBuffer ? 1 : 0; switch (info->CurrentLayout.pixel_code) { case 8: /* 8bpp mode is not support */ case 15: /* FIXME */ case 24: /* FIXME */ xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] RADEONInitVisualConfigs failed " "(depth %d not supported). " "Disabling DRI.\n", info->CurrentLayout.pixel_code); return FALSE; #define RADEON_USE_ACCUM 1 #define RADEON_USE_STENCIL 1 case 16: numConfigs = 1; if (RADEON_USE_ACCUM) numConfigs *= 2; if (RADEON_USE_STENCIL) numConfigs *= 2; if (use_db) numConfigs *= 2; if (!(pConfigs = (__GLXvisualConfig *)xcalloc(sizeof(__GLXvisualConfig), numConfigs))) { return FALSE; } if (!(pRADEONConfigs = (RADEONConfigPrivPtr)xcalloc(sizeof(RADEONConfigPrivRec), numConfigs))) { xfree(pConfigs); return FALSE; } if (!(pRADEONConfigPtrs = (RADEONConfigPrivPtr *)xcalloc(sizeof(RADEONConfigPrivPtr), numConfigs))) { xfree(pConfigs); xfree(pRADEONConfigs); return FALSE; } i = 0; for (db = 0; db <= use_db; db++) { for (accum = 0; accum <= RADEON_USE_ACCUM; accum++) { for (stencil = 0; stencil <= RADEON_USE_STENCIL; stencil++) { pRADEONConfigPtrs[i] = &pRADEONConfigs[i]; pConfigs[i].vid = (VisualID)(-1); pConfigs[i].class = -1; pConfigs[i].rgba = TRUE; pConfigs[i].redSize = 5; pConfigs[i].greenSize = 6; pConfigs[i].blueSize = 5; pConfigs[i].alphaSize = 0; pConfigs[i].redMask = 0x0000F800; pConfigs[i].greenMask = 0x000007E0; pConfigs[i].blueMask = 0x0000001F; pConfigs[i].alphaMask = 0x00000000; if (accum) { /* Simulated in software */ pConfigs[i].accumRedSize = 16; pConfigs[i].accumGreenSize = 16; pConfigs[i].accumBlueSize = 16; pConfigs[i].accumAlphaSize = 0; } else { pConfigs[i].accumRedSize = 0; pConfigs[i].accumGreenSize = 0; pConfigs[i].accumBlueSize = 0; pConfigs[i].accumAlphaSize = 0; } if (db) pConfigs[i].doubleBuffer = TRUE; else pConfigs[i].doubleBuffer = FALSE; pConfigs[i].stereo = FALSE; pConfigs[i].bufferSize = 16; pConfigs[i].depthSize = 16; if (stencil) pConfigs[i].stencilSize = 8; else pConfigs[i].stencilSize = 0; pConfigs[i].auxBuffers = 0; pConfigs[i].level = 0; if (accum || stencil) { pConfigs[i].visualRating = GLX_SLOW_CONFIG; } else { pConfigs[i].visualRating = GLX_NONE; } pConfigs[i].transparentPixel = GLX_NONE; pConfigs[i].transparentRed = 0; pConfigs[i].transparentGreen = 0; pConfigs[i].transparentBlue = 0; pConfigs[i].transparentAlpha = 0; pConfigs[i].transparentIndex = 0; i++; } } } break; case 32: numConfigs = 1; if (RADEON_USE_ACCUM) numConfigs *= 2; if (RADEON_USE_STENCIL) numConfigs *= 2; if (use_db) numConfigs *= 2; if (!(pConfigs = (__GLXvisualConfig *)xcalloc(sizeof(__GLXvisualConfig), numConfigs))) { return FALSE; } if (!(pRADEONConfigs = (RADEONConfigPrivPtr)xcalloc(sizeof(RADEONConfigPrivRec), numConfigs))) { xfree(pConfigs); return FALSE; } if (!(pRADEONConfigPtrs = (RADEONConfigPrivPtr *)xcalloc(sizeof(RADEONConfigPrivPtr), numConfigs))) { xfree(pConfigs); xfree(pRADEONConfigs); return FALSE; } i = 0; for (db = 0; db <= use_db; db++) { for (accum = 0; accum <= RADEON_USE_ACCUM; accum++) { for (stencil = 0; stencil <= RADEON_USE_STENCIL; stencil++) { pRADEONConfigPtrs[i] = &pRADEONConfigs[i]; pConfigs[i].vid = (VisualID)(-1); pConfigs[i].class = -1; pConfigs[i].rgba = TRUE; pConfigs[i].redSize = 8; pConfigs[i].greenSize = 8; pConfigs[i].blueSize = 8; pConfigs[i].alphaSize = 8; pConfigs[i].redMask = 0x00FF0000; pConfigs[i].greenMask = 0x0000FF00; pConfigs[i].blueMask = 0x000000FF; pConfigs[i].alphaMask = 0xFF000000; if (accum) { /* Simulated in software */ pConfigs[i].accumRedSize = 16; pConfigs[i].accumGreenSize = 16; pConfigs[i].accumBlueSize = 16; pConfigs[i].accumAlphaSize = 16; } else { pConfigs[i].accumRedSize = 0; pConfigs[i].accumGreenSize = 0; pConfigs[i].accumBlueSize = 0; pConfigs[i].accumAlphaSize = 0; } if (db) pConfigs[i].doubleBuffer = TRUE; else pConfigs[i].doubleBuffer = FALSE; pConfigs[i].stereo = FALSE; pConfigs[i].bufferSize = 32; if (stencil) { pConfigs[i].depthSize = 24; pConfigs[i].stencilSize = 8; } else { pConfigs[i].depthSize = 24; pConfigs[i].stencilSize = 0; } pConfigs[i].auxBuffers = 0; pConfigs[i].level = 0; if (accum) { pConfigs[i].visualRating = GLX_SLOW_CONFIG; } else { pConfigs[i].visualRating = GLX_NONE; } pConfigs[i].transparentPixel = GLX_NONE; pConfigs[i].transparentRed = 0; pConfigs[i].transparentGreen = 0; pConfigs[i].transparentBlue = 0; pConfigs[i].transparentAlpha = 0; pConfigs[i].transparentIndex = 0; i++; } } } break; } info->numVisualConfigs = numConfigs; info->pVisualConfigs = pConfigs; info->pVisualConfigsPriv = pRADEONConfigs; GlxSetVisualConfigs(numConfigs, pConfigs, (void**)pRADEONConfigPtrs); return TRUE; } /* Create the Radeon-specific context information */ static Bool RADEONCreateContext(ScreenPtr pScreen, VisualPtr visual, drm_context_t hwContext, void *pVisualConfigPriv, DRIContextType contextStore) { #ifdef PER_CONTEXT_SAREA ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); RADEONDRIContextPtr ctx_info; ctx_info = (RADEONDRIContextPtr)contextStore; if (!ctx_info) return FALSE; if (drmAddMap(info->drmFD, 0, info->perctx_sarea_size, DRM_SHM, DRM_REMOVABLE, &ctx_info->sarea_handle) < 0) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "[dri] could not create private sarea for ctx id (%d)\n", (int)hwContext); return FALSE; } if (drmAddContextPrivateMapping(info->drmFD, hwContext, ctx_info->sarea_handle) < 0) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "[dri] could not associate private sarea to ctx id (%d)\n", (int)hwContext); drmRmMap(info->drmFD, ctx_info->sarea_handle); return FALSE; } ctx_info->ctx_id = hwContext; #endif return TRUE; } /* Destroy the Radeon-specific context information */ static void RADEONDestroyContext(ScreenPtr pScreen, drm_context_t hwContext, DRIContextType contextStore) { #ifdef PER_CONTEXT_SAREA ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); RADEONDRIContextPtr ctx_info; ctx_info = (RADEONDRIContextPtr)contextStore; if (!ctx_info) return; if (drmRmMap(info->drmFD, ctx_info->sarea_handle) < 0) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "[dri] could not remove private sarea for ctx id (%d)\n", (int)hwContext); } #endif } /* Called when the X server is woken up to allow the last client's * context to be saved and the X server's context to be loaded. This is * not necessary for the Radeon since the client detects when it's * context is not currently loaded and then load's it itself. Since the * registers to start and stop the CP are privileged, only the X server * can start/stop the engine. */ static void RADEONEnterServer(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); if (info->accel) info->accel->NeedToSync = TRUE; } /* Called when the X server goes to sleep to allow the X server's * context to be saved and the last client's context to be loaded. This * is not necessary for the Radeon since the client detects when it's * context is not currently loaded and then load's it itself. Since the * registers to start and stop the CP are privileged, only the X server * can start/stop the engine. */ static void RADEONLeaveServer(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); RING_LOCALS; /* The CP is always running, but if we've generated any CP commands * we must flush them to the kernel module now. */ if (info->CPInUse) { RADEON_FLUSH_CACHE(); RADEON_WAIT_UNTIL_IDLE(); RADEONCPReleaseIndirect(pScrn); info->CPInUse = FALSE; } } /* Contexts can be swapped by the X server if necessary. This callback * is currently only used to perform any functions necessary when * entering or leaving the X server, and in the future might not be * necessary. */ static void RADEONDRISwapContext(ScreenPtr pScreen, DRISyncType syncType, DRIContextType oldContextType, void *oldContext, DRIContextType newContextType, void *newContext) { if ((syncType==DRI_3D_SYNC) && (oldContextType==DRI_2D_CONTEXT) && (newContextType==DRI_2D_CONTEXT)) { /* Entering from Wakeup */ RADEONEnterServer(pScreen); } if ((syncType==DRI_2D_SYNC) && (oldContextType==DRI_NO_CONTEXT) && (newContextType==DRI_2D_CONTEXT)) { /* Exiting from Block Handler */ RADEONLeaveServer(pScreen); } } /* The Radeon has depth tiling on all the time, so we have to convert * the x,y coordinates into the memory bus address (mba) in the same * manner as the engine. In each case, the linear block address (ba) * is calculated, and then wired with x and y to produce the final * memory address. */ static CARD32 radeon_mba_z16(RADEONInfoPtr info, int x, int y) { CARD32 pitch = info->frontPitch; CARD32 address = 0; /* a[0] = 0 */ CARD32 ba; ba = (y / 16) * (pitch / 32) + (x / 32); address |= (x & 0x7) << 1; /* a[1..3] = x[0..2] */ address |= (y & 0x7) << 4; /* a[4..6] = y[0..2] */ address |= (x & 0x8) << 4; /* a[7] = x[3] */ address |= (ba & 0x3) << 8; /* a[8..9] = ba[0..1] */ address |= (y & 0x8) << 7; /* a[10] = y[3] */ address |= ((x & 0x10) ^ (y & 0x10)) << 7; /* a[11] = x[4] ^ y[4] */ address |= (ba & ~0x3u) << 10; /* a[12..] = ba[2..] */ return address; } static CARD32 radeon_mba_z32(RADEONInfoPtr info, int x, int y) { CARD32 pitch = info->frontPitch; CARD32 address = 0; /* a[0..1] = 0 */ CARD32 ba; ba = (y / 16) * (pitch / 16) + (x / 16); address |= (x & 0x7) << 2; /* a[2..4] = x[0..2] */ address |= (y & 0x3) << 5; /* a[5..6] = y[0..1] */ address |= (((x & 0x10) >> 2) ^ (y & 0x4)) << 5; /* a[7] = x[4] ^ y[2] */ address |= (ba & 0x3) << 8; /* a[8..9] = ba[0..1] */ address |= (y & 0x8) << 7; /* a[10] = y[3] */ address |= (((x & 0x8) << 1) ^ (y & 0x10)) << 7; /* a[11] = x[3] ^ y[4] */ address |= (ba & ~0x3u) << 10; /* a[12..] = ba[2..] */ return address; } /* 16-bit depth buffer functions */ #define WRITE_DEPTH16(_x, _y, d) \ *(CARD16 *)(pointer)(buf + radeon_mba_z16(info, (_x), (_y))) = (d) #define READ_DEPTH16(d, _x, _y) \ (d) = *(CARD16 *)(pointer)(buf + radeon_mba_z16(info, (_x), (_y))) /* 24 bit depth, 8 bit stencil depthbuffer functions */ #define WRITE_DEPTH32(_x, _y, d) \ do { \ CARD32 tmp = \ *(CARD32 *)(pointer)(buf + radeon_mba_z32(info, (_x), (_y))); \ tmp &= 0xff000000; \ tmp |= ((d) & 0x00ffffff); \ *(CARD32 *)(pointer)(buf + radeon_mba_z32(info, (_x), (_y))) = tmp; \ } while (0) #define READ_DEPTH32(d, _x, _y) \ d = (*(CARD32 *)(pointer)(buf + radeon_mba_z32(info, (_x), (_y))) \ & 0x00ffffff) /* Screen to screen copy of data in the depth buffer */ static void RADEONScreenToScreenCopyDepth(ScrnInfoPtr pScrn, int xa, int ya, int xb, int yb, int w, int h) { RADEONInfoPtr info = RADEONPTR(pScrn); unsigned char *buf = info->FB + info->depthOffset; int xstart, xend, xdir; int ystart, yend, ydir; int x, y, d; if (xa < xb) xdir = -1, xstart = w-1, xend = 0; else xdir = 1, xstart = 0, xend = w-1; if (ya < yb) ydir = -1, ystart = h-1, yend = 0; else ydir = 1, ystart = 0, yend = h-1; switch (pScrn->bitsPerPixel) { case 16: for (x = xstart; x != xend; x += xdir) { for (y = ystart; y != yend; y += ydir) { READ_DEPTH16(d, xa+x, ya+y); WRITE_DEPTH16(xb+x, yb+y, d); } } break; case 32: for (x = xstart; x != xend; x += xdir) { for (y = ystart; y != yend; y += ydir) { READ_DEPTH32(d, xa+x, ya+y); WRITE_DEPTH32(xb+x, yb+y, d); } } break; default: break; } } /* Initialize the state of the back and depth buffers */ static void RADEONDRIInitBuffers(WindowPtr pWin, RegionPtr prgn, CARD32 indx) { /* NOOP. There's no need for the 2d driver to be clearing buffers * for the 3d client. It knows how to do that on its own. */ } /* Copy the back and depth buffers when the X server moves a window. * * This routine is a modified form of XAADoBitBlt with the calls to * ScreenToScreenBitBlt built in. My routine has the prgnSrc as source * instead of destination. My origin is upside down so the ydir cases * are reversed. */ static void RADEONDRIMoveBuffers(WindowPtr pParent, DDXPointRec ptOldOrg, RegionPtr prgnSrc, CARD32 indx) { ScreenPtr pScreen = pParent->drawable.pScreen; ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); BoxPtr pboxTmp, pboxNext, pboxBase; DDXPointPtr pptTmp; int xdir, ydir; int screenwidth = pScrn->virtualX; int screenheight = pScrn->virtualY; BoxPtr pbox = REGION_RECTS(prgnSrc); int nbox = REGION_NUM_RECTS(prgnSrc); BoxPtr pboxNew1 = NULL; BoxPtr pboxNew2 = NULL; DDXPointPtr pptNew1 = NULL; DDXPointPtr pptNew2 = NULL; DDXPointPtr pptSrc = &ptOldOrg; int dx = pParent->drawable.x - ptOldOrg.x; int dy = pParent->drawable.y - ptOldOrg.y; /* If the copy will overlap in Y, reverse the order */ if (dy > 0) { ydir = -1; if (nbox > 1) { /* Keep ordering in each band, reverse order of bands */ pboxNew1 = (BoxPtr)ALLOCATE_LOCAL(sizeof(BoxRec)*nbox); if (!pboxNew1) return; pptNew1 = (DDXPointPtr)ALLOCATE_LOCAL(sizeof(DDXPointRec)*nbox); if (!pptNew1) { DEALLOCATE_LOCAL(pboxNew1); return; } pboxBase = pboxNext = pbox+nbox-1; while (pboxBase >= pbox) { while ((pboxNext >= pbox) && (pboxBase->y1 == pboxNext->y1)) pboxNext--; pboxTmp = pboxNext+1; pptTmp = pptSrc + (pboxTmp - pbox); while (pboxTmp <= pboxBase) { *pboxNew1++ = *pboxTmp++; *pptNew1++ = *pptTmp++; } pboxBase = pboxNext; } pboxNew1 -= nbox; pbox = pboxNew1; pptNew1 -= nbox; pptSrc = pptNew1; } } else { /* No changes required */ ydir = 1; } /* If the regions will overlap in X, reverse the order */ if (dx > 0) { xdir = -1; if (nbox > 1) { /* reverse order of rects in each band */ pboxNew2 = (BoxPtr)ALLOCATE_LOCAL(sizeof(BoxRec)*nbox); pptNew2 = (DDXPointPtr)ALLOCATE_LOCAL(sizeof(DDXPointRec)*nbox); if (!pboxNew2 || !pptNew2) { DEALLOCATE_LOCAL(pptNew2); DEALLOCATE_LOCAL(pboxNew2); DEALLOCATE_LOCAL(pptNew1); DEALLOCATE_LOCAL(pboxNew1); return; } pboxBase = pboxNext = pbox; while (pboxBase < pbox+nbox) { while ((pboxNext < pbox+nbox) && (pboxNext->y1 == pboxBase->y1)) pboxNext++; pboxTmp = pboxNext; pptTmp = pptSrc + (pboxTmp - pbox); while (pboxTmp != pboxBase) { *pboxNew2++ = *--pboxTmp; *pptNew2++ = *--pptTmp; } pboxBase = pboxNext; } pboxNew2 -= nbox; pbox = pboxNew2; pptNew2 -= nbox; pptSrc = pptNew2; } } else { /* No changes are needed */ xdir = 1; } (*info->accel->SetupForScreenToScreenCopy)(pScrn, xdir, ydir, GXcopy, (CARD32)(-1), -1); for (; nbox-- ; pbox++) { int xa = pbox->x1; int ya = pbox->y1; int destx = xa + dx; int desty = ya + dy; int w = pbox->x2 - xa + 1; int h = pbox->y2 - ya + 1; if (destx < 0) xa -= destx, w += destx, destx = 0; if (desty < 0) ya -= desty, h += desty, desty = 0; if (destx + w > screenwidth) w = screenwidth - destx; if (desty + h > screenheight) h = screenheight - desty; if (w <= 0) continue; if (h <= 0) continue; RADEONSelectBuffer(pScrn, RADEON_BACK); (*info->accel->SubsequentScreenToScreenCopy)(pScrn, xa, ya, destx, desty, w, h); if (info->depthMoves) { RADEONSelectBuffer(pScrn, RADEON_DEPTH); RADEONScreenToScreenCopyDepth(pScrn, xa, ya, destx, desty, w, h); } } RADEONSelectBuffer(pScrn, RADEON_FRONT); DEALLOCATE_LOCAL(pptNew2); DEALLOCATE_LOCAL(pboxNew2); DEALLOCATE_LOCAL(pptNew1); DEALLOCATE_LOCAL(pboxNew1); info->accel->NeedToSync = TRUE; } static void RADEONDRIInitGARTValues(RADEONInfoPtr info) { int s, l; info->gartOffset = 0; /* Initialize the CP ring buffer data */ info->ringStart = info->gartOffset; info->ringMapSize = info->ringSize*1024*1024 + radeon_drm_page_size; info->ringSizeLog2QW = RADEONMinBits(info->ringSize*1024*1024/8)-1; info->ringReadOffset = info->ringStart + info->ringMapSize; info->ringReadMapSize = radeon_drm_page_size; /* Reserve space for vertex/indirect buffers */ info->bufStart = info->ringReadOffset + info->ringReadMapSize; info->bufMapSize = info->bufSize*1024*1024; /* Reserve the rest for GART textures */ info->gartTexStart = info->bufStart + info->bufMapSize; s = (info->gartSize*1024*1024 - info->gartTexStart); l = RADEONMinBits((s-1) / RADEON_NR_TEX_REGIONS); if (l < RADEON_LOG_TEX_GRANULARITY) l = RADEON_LOG_TEX_GRANULARITY; info->gartTexMapSize = (s >> l) << l; info->log2GARTTexGran = l; } /* Set AGP transfer mode according to requests and constraints */ static Bool RADEONSetAgpMode(RADEONInfoPtr info, ScreenPtr pScreen) { unsigned char *RADEONMMIO = info->MMIO; unsigned long mode = drmAgpGetMode(info->drmFD); /* Default mode */ unsigned int vendor = drmAgpVendorId(info->drmFD); unsigned int device = drmAgpDeviceId(info->drmFD); mode &= ~RADEON_AGP_MODE_MASK; switch (info->agpMode) { case 4: mode |= RADEON_AGP_4X_MODE; case 2: mode |= RADEON_AGP_2X_MODE; case 1: default: mode |= RADEON_AGP_1X_MODE; } if (info->agpFastWrite) mode |= RADEON_AGP_FW_MODE; if ((vendor == PCI_VENDOR_AMD) && (device == PCI_CHIP_AMD761)) { /* Disable fast write for AMD 761 chipset, since they cause * lockups when enabled. */ mode &= ~0x10; /* FIXME: Magic number */ } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] Mode 0x%08lx [AGP 0x%04x/0x%04x; Card 0x%04x/0x%04x]\n", mode, vendor, device, info->PciInfo->vendor, info->PciInfo->chipType); if (drmAgpEnable(info->drmFD, mode) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] AGP not enabled\n"); drmAgpRelease(info->drmFD); return FALSE; } /* Workaround for some hardware bugs */ if (info->ChipFamily < CHIP_FAMILY_R200) OUTREG(RADEON_AGP_CNTL, INREG(RADEON_AGP_CNTL) | 0x000e0000); /* Modify the mode if the default mode * is not appropriate for this * particular combination of graphics * card and AGP chipset. */ return TRUE; } /* Initialize Radeon's AGP registers */ static void RADEONSetAgpBase(RADEONInfoPtr info) { unsigned char *RADEONMMIO = info->MMIO; OUTREG(RADEON_AGP_BASE, drmAgpBase(info->drmFD)); } /* Initialize the AGP state. Request memory for use in AGP space, and * initialize the Radeon registers to point to that memory. */ static Bool RADEONDRIAgpInit(RADEONInfoPtr info, ScreenPtr pScreen) { int ret; if (drmAgpAcquire(info->drmFD) < 0) { xf86DrvMsg(pScreen->myNum, X_WARNING, "[agp] AGP not available\n"); return FALSE; } if (!RADEONSetAgpMode(info, pScreen)) return FALSE; RADEONDRIInitGARTValues(info); if ((ret = drmAgpAlloc(info->drmFD, info->gartSize*1024*1024, 0, NULL, &info->agpMemHandle)) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Out of memory (%d)\n", ret); drmAgpRelease(info->drmFD); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] %d kB allocated with handle 0x%08lx\n", info->gartSize*1024, info->agpMemHandle); if (drmAgpBind(info->drmFD, info->agpMemHandle, info->gartOffset) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not bind\n"); drmAgpFree(info->drmFD, info->agpMemHandle); drmAgpRelease(info->drmFD); return FALSE; } if (drmAddMap(info->drmFD, info->ringStart, info->ringMapSize, DRM_AGP, DRM_READ_ONLY, &info->ringHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not add ring mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] ring handle = 0x%08lx\n", info->ringHandle); if (drmMap(info->drmFD, info->ringHandle, info->ringMapSize, (drmAddressPtr)&info->ring) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not map ring\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] Ring mapped at 0x%08lx\n", (unsigned long)info->ring); if (drmAddMap(info->drmFD, info->ringReadOffset, info->ringReadMapSize, DRM_AGP, DRM_READ_ONLY, &info->ringReadPtrHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not add ring read ptr mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] ring read ptr handle = 0x%08lx\n", info->ringReadPtrHandle); if (drmMap(info->drmFD, info->ringReadPtrHandle, info->ringReadMapSize, (drmAddressPtr)&info->ringReadPtr) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not map ring read ptr\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] Ring read ptr mapped at 0x%08lx\n", (unsigned long)info->ringReadPtr); if (drmAddMap(info->drmFD, info->bufStart, info->bufMapSize, DRM_AGP, 0, &info->bufHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not add vertex/indirect buffers mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] vertex/indirect buffers handle = 0x%08lx\n", info->bufHandle); if (drmMap(info->drmFD, info->bufHandle, info->bufMapSize, (drmAddressPtr)&info->buf) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not map vertex/indirect buffers\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] Vertex/indirect buffers mapped at 0x%08lx\n", (unsigned long)info->buf); if (drmAddMap(info->drmFD, info->gartTexStart, info->gartTexMapSize, DRM_AGP, 0, &info->gartTexHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not add GART texture map mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] GART texture map handle = 0x%08lx\n", info->gartTexHandle); if (drmMap(info->drmFD, info->gartTexHandle, info->gartTexMapSize, (drmAddressPtr)&info->gartTex) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] Could not map GART texture map\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] GART Texture map mapped at 0x%08lx\n", (unsigned long)info->gartTex); RADEONSetAgpBase(info); return TRUE; } /* Initialize the PCI GART state. Request memory for use in PCI space, * and initialize the Radeon registers to point to that memory. */ static Bool RADEONDRIPciInit(RADEONInfoPtr info, ScreenPtr pScreen) { int ret; int flags = DRM_READ_ONLY | DRM_LOCKED | DRM_KERNEL; ret = drmScatterGatherAlloc(info->drmFD, info->gartSize*1024*1024, &info->pciMemHandle); if (ret < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Out of memory (%d)\n", ret); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] %d kB allocated with handle 0x%08lx\n", info->gartSize*1024, info->pciMemHandle); RADEONDRIInitGARTValues(info); if (drmAddMap(info->drmFD, info->ringStart, info->ringMapSize, DRM_SCATTER_GATHER, flags, &info->ringHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not add ring mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] ring handle = 0x%08lx\n", info->ringHandle); if (drmMap(info->drmFD, info->ringHandle, info->ringMapSize, (drmAddressPtr)&info->ring) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not map ring\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] Ring mapped at 0x%08lx\n", (unsigned long)info->ring); xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] Ring contents 0x%08lx\n", *(unsigned long *)(pointer)info->ring); if (drmAddMap(info->drmFD, info->ringReadOffset, info->ringReadMapSize, DRM_SCATTER_GATHER, flags, &info->ringReadPtrHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not add ring read ptr mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] ring read ptr handle = 0x%08lx\n", info->ringReadPtrHandle); if (drmMap(info->drmFD, info->ringReadPtrHandle, info->ringReadMapSize, (drmAddressPtr)&info->ringReadPtr) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not map ring read ptr\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] Ring read ptr mapped at 0x%08lx\n", (unsigned long)info->ringReadPtr); xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] Ring read ptr contents 0x%08lx\n", *(unsigned long *)(pointer)info->ringReadPtr); if (drmAddMap(info->drmFD, info->bufStart, info->bufMapSize, DRM_SCATTER_GATHER, 0, &info->bufHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not add vertex/indirect buffers mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] vertex/indirect buffers handle = 0x%08lx\n", info->bufHandle); if (drmMap(info->drmFD, info->bufHandle, info->bufMapSize, (drmAddressPtr)&info->buf) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not map vertex/indirect buffers\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] Vertex/indirect buffers mapped at 0x%08lx\n", (unsigned long)info->buf); xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] Vertex/indirect buffers contents 0x%08lx\n", *(unsigned long *)(pointer)info->buf); if (drmAddMap(info->drmFD, info->gartTexStart, info->gartTexMapSize, DRM_SCATTER_GATHER, 0, &info->gartTexHandle) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not add GART texture map mapping\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] GART texture map handle = 0x%08lx\n", info->gartTexHandle); if (drmMap(info->drmFD, info->gartTexHandle, info->gartTexMapSize, (drmAddressPtr)&info->gartTex) < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] Could not map GART texture map\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[pci] GART Texture map mapped at 0x%08lx\n", (unsigned long)info->gartTex); return TRUE; } /* Add a map for the MMIO registers that will be accessed by any * DRI-based clients. */ static Bool RADEONDRIMapInit(RADEONInfoPtr info, ScreenPtr pScreen) { /* Map registers */ info->registerSize = RADEON_MMIOSIZE; if (drmAddMap(info->drmFD, info->MMIOAddr, info->registerSize, DRM_REGISTERS, DRM_READ_ONLY, &info->registerHandle) < 0) { return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[drm] register handle = 0x%08lx\n", info->registerHandle); return TRUE; } /* Initialize the kernel data structures */ static int RADEONDRIKernelInit(RADEONInfoPtr info, ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; int cpp = info->CurrentLayout.pixel_bytes; drmRadeonInit drmInfo; memset(&drmInfo, 0, sizeof(drmRadeonInit)); if ( info->ChipFamily >= CHIP_FAMILY_R200 ) drmInfo.func = DRM_RADEON_INIT_R200_CP; else drmInfo.func = DRM_RADEON_INIT_CP; drmInfo.sarea_priv_offset = sizeof(XF86DRISAREARec); drmInfo.is_pci = info->IsPCI; drmInfo.cp_mode = info->CPMode; drmInfo.gart_size = info->gartSize*1024*1024; drmInfo.ring_size = info->ringSize*1024*1024; drmInfo.usec_timeout = info->CPusecTimeout; drmInfo.fb_bpp = info->CurrentLayout.pixel_code; drmInfo.depth_bpp = info->CurrentLayout.pixel_code; drmInfo.front_offset = info->frontOffset; drmInfo.front_pitch = info->frontPitch * cpp; drmInfo.back_offset = info->backOffset; drmInfo.back_pitch = info->backPitch * cpp; drmInfo.depth_offset = info->depthOffset; drmInfo.depth_pitch = info->depthPitch * cpp; drmInfo.fb_offset = info->fbHandle; drmInfo.mmio_offset = info->registerHandle; drmInfo.ring_offset = info->ringHandle; drmInfo.ring_rptr_offset = info->ringReadPtrHandle; drmInfo.buffers_offset = info->bufHandle; drmInfo.gart_textures_offset= info->gartTexHandle; if (drmCommandWrite(info->drmFD, DRM_RADEON_CP_INIT, &drmInfo, sizeof(drmRadeonInit)) < 0) return FALSE; /* DRM_RADEON_CP_INIT does an engine reset, which resets some engine * registers back to their default values, so we need to restore * those engine register here. */ RADEONEngineRestore(pScrn); return TRUE; } static void RADEONDRIGartHeapInit(RADEONInfoPtr info, ScreenPtr pScreen) { drmRadeonMemInitHeap drmHeap; /* Start up the simple memory manager for GART space */ if (info->drmMinor >= 6) { drmHeap.region = RADEON_MEM_REGION_GART; drmHeap.start = 0; drmHeap.size = info->gartTexMapSize; if (drmCommandWrite(info->drmFD, DRM_RADEON_INIT_HEAP, &drmHeap, sizeof(drmHeap))) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[drm] Failed to initialize GART heap manager\n"); } else { xf86DrvMsg(pScreen->myNum, X_INFO, "[drm] Initialized kernel GART heap manager, %d\n", info->gartTexMapSize); } } else { xf86DrvMsg(pScreen->myNum, X_INFO, "[drm] Kernel module too old (1.%d) for GART heap manager\n", info->drmMinor); } } /* Add a map for the vertex buffers that will be accessed by any * DRI-based clients. */ static Bool RADEONDRIBufInit(RADEONInfoPtr info, ScreenPtr pScreen) { /* Initialize vertex buffers */ info->bufNumBufs = drmAddBufs(info->drmFD, info->bufMapSize / RADEON_BUFFER_SIZE, RADEON_BUFFER_SIZE, info->IsPCI ? DRM_SG_BUFFER : DRM_AGP_BUFFER, info->bufStart); if (info->bufNumBufs <= 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[drm] Could not create vertex/indirect buffers list\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[drm] Added %d %d byte vertex/indirect buffers\n", info->bufNumBufs, RADEON_BUFFER_SIZE); if (!(info->buffers = drmMapBufs(info->drmFD))) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[drm] Failed to map vertex/indirect buffers list\n"); return FALSE; } xf86DrvMsg(pScreen->myNum, X_INFO, "[drm] Mapped %d vertex/indirect buffers\n", info->buffers->count); return TRUE; } static void RADEONDRIIrqInit(RADEONInfoPtr info, ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; if (!info->irq) { info->irq = drmGetInterruptFromBusID( info->drmFD, ((pciConfigPtr)info->PciInfo->thisCard)->busnum, ((pciConfigPtr)info->PciInfo->thisCard)->devnum, ((pciConfigPtr)info->PciInfo->thisCard)->funcnum); if ((drmCtlInstHandler(info->drmFD, info->irq)) != 0) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "[drm] failure adding irq handler, " "there is a device already using that irq\n" "[drm] falling back to irq-free operation\n"); info->irq = 0; } else { unsigned char *RADEONMMIO = info->MMIO; info->ModeReg.gen_int_cntl = INREG( RADEON_GEN_INT_CNTL ); } } if (info->irq) xf86DrvMsg(pScrn->scrnIndex, X_INFO, "[drm] dma control initialized, using IRQ %d\n", info->irq); } /* Initialize the CP state, and start the CP (if used by the X server) */ static void RADEONDRICPInit(ScrnInfoPtr pScrn) { RADEONInfoPtr info = RADEONPTR(pScrn); /* Turn on bus mastering */ info->BusCntl &= ~RADEON_BUS_MASTER_DIS; /* Make sure the CP is on for the X server */ RADEONCP_START(pScrn, info); RADEONSelectBuffer(pScrn, RADEON_FRONT); } /* Initialize the screen-specific data structures for the DRI and the * Radeon. This is the main entry point to the device-specific * initialization code. It calls device-independent DRI functions to * create the DRI data structures and initialize the DRI state. */ Bool RADEONDRIScreenInit(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); DRIInfoPtr pDRIInfo; RADEONDRIPtr pRADEONDRI; int major, minor, patch; drmVersionPtr version; /* Check that the GLX, DRI, and DRM modules have been loaded by testing * for known symbols in each module. */ if (!xf86LoaderCheckSymbol("GlxSetVisualConfigs")) return FALSE; if (!xf86LoaderCheckSymbol("DRIScreenInit")) return FALSE; if (!xf86LoaderCheckSymbol("drmAvailable")) return FALSE; if (!xf86LoaderCheckSymbol("DRIQueryVersion")) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] RADEONDRIScreenInit failed (libdri.a too old)\n"); return FALSE; } /* Check the DRI version */ DRIQueryVersion(&major, &minor, &patch); if (major != 4 || minor < 0) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] RADEONDRIScreenInit failed because of a version " "mismatch.\n" "[dri] libDRI version is %d.%d.%d but version 4.0.x is " "needed.\n" "[dri] Disabling DRI.\n", major, minor, patch); return FALSE; } switch (info->CurrentLayout.pixel_code) { case 8: case 15: case 24: /* These modes are not supported (yet). */ xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] RADEONInitVisualConfigs failed " "(depth %d not supported). " "Disabling DRI.\n", info->CurrentLayout.pixel_code); return FALSE; /* Only 16 and 32 color depths are supports currently. */ case 16: case 32: break; } radeon_drm_page_size = getpagesize(); /* Create the DRI data structure, and fill it in before calling the * DRIScreenInit(). */ if (!(pDRIInfo = DRICreateInfoRec())) return FALSE; info->pDRIInfo = pDRIInfo; pDRIInfo->drmDriverName = RADEON_DRIVER_NAME; if ( info->ChipFamily >= CHIP_FAMILY_R200 ) pDRIInfo->clientDriverName = R200_DRIVER_NAME; else pDRIInfo->clientDriverName = RADEON_DRIVER_NAME; if (xf86LoaderCheckSymbol("DRICreatePCIBusID")) { pDRIInfo->busIdString = DRICreatePCIBusID(info->PciInfo); } else { pDRIInfo->busIdString = xalloc(64); sprintf(pDRIInfo->busIdString, "PCI:%d:%d:%d", info->PciInfo->bus, info->PciInfo->device, info->PciInfo->func); } pDRIInfo->ddxDriverMajorVersion = RADEON_VERSION_MAJOR; pDRIInfo->ddxDriverMinorVersion = RADEON_VERSION_MINOR; pDRIInfo->ddxDriverPatchVersion = RADEON_VERSION_PATCH; pDRIInfo->frameBufferPhysicalAddress = info->LinearAddr; pDRIInfo->frameBufferSize = info->FbMapSize; pDRIInfo->frameBufferStride = (pScrn->displayWidth * info->CurrentLayout.pixel_bytes); pDRIInfo->ddxDrawableTableEntry = RADEON_MAX_DRAWABLES; pDRIInfo->maxDrawableTableEntry = (SAREA_MAX_DRAWABLES < RADEON_MAX_DRAWABLES ? SAREA_MAX_DRAWABLES : RADEON_MAX_DRAWABLES); #ifdef PER_CONTEXT_SAREA /* This is only here for testing per-context SAREAs. When used, the magic number below would be properly defined in a header file. */ info->perctx_sarea_size = 64 * 1024; #endif #ifdef NOT_DONE /* FIXME: Need to extend DRI protocol to pass this size back to * client for SAREA mapping that includes a device private record */ pDRIInfo->SAREASize = ((sizeof(XF86DRISAREARec) + 0xfff) & 0x1000); /* round to page */ /* + shared memory device private rec */ #else /* For now the mapping works by using a fixed size defined * in the SAREA header */ if (sizeof(XF86DRISAREARec)+sizeof(RADEONSAREAPriv) > SAREA_MAX) { ErrorF("Data does not fit in SAREA\n"); return FALSE; } pDRIInfo->SAREASize = SAREA_MAX; #endif if (!(pRADEONDRI = (RADEONDRIPtr)xcalloc(sizeof(RADEONDRIRec),1))) { DRIDestroyInfoRec(info->pDRIInfo); info->pDRIInfo = NULL; return FALSE; } pDRIInfo->devPrivate = pRADEONDRI; pDRIInfo->devPrivateSize = sizeof(RADEONDRIRec); pDRIInfo->contextSize = sizeof(RADEONDRIContextRec); pDRIInfo->CreateContext = RADEONCreateContext; pDRIInfo->DestroyContext = RADEONDestroyContext; pDRIInfo->SwapContext = RADEONDRISwapContext; pDRIInfo->InitBuffers = RADEONDRIInitBuffers; pDRIInfo->MoveBuffers = RADEONDRIMoveBuffers; pDRIInfo->bufferRequests = DRI_ALL_WINDOWS; pDRIInfo->OpenFullScreen = RADEONDRIOpenFullScreen; pDRIInfo->CloseFullScreen = RADEONDRICloseFullScreen; pDRIInfo->TransitionTo2d = RADEONDRITransitionTo2d; pDRIInfo->TransitionTo3d = RADEONDRITransitionTo3d; pDRIInfo->TransitionSingleToMulti3D = RADEONDRITransitionSingleToMulti3d; pDRIInfo->TransitionMultiToSingle3D = RADEONDRITransitionMultiToSingle3d; pDRIInfo->createDummyCtx = TRUE; pDRIInfo->createDummyCtxPriv = FALSE; if (!DRIScreenInit(pScreen, pDRIInfo, &info->drmFD)) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] DRIScreenInit failed. Disabling DRI.\n"); xfree(pDRIInfo->devPrivate); pDRIInfo->devPrivate = NULL; DRIDestroyInfoRec(pDRIInfo); pDRIInfo = NULL; return FALSE; } /* Check the DRM lib version. * drmGetLibVersion was not supported in version 1.0, so check for * symbol first to avoid possible crash or hang. */ if (xf86LoaderCheckSymbol("drmGetLibVersion")) { version = drmGetLibVersion(info->drmFD); } else { /* drmlib version 1.0.0 didn't have the drmGetLibVersion * entry point. Fake it by allocating a version record * via drmGetVersion and changing it to version 1.0.0. */ version = drmGetVersion(info->drmFD); version->version_major = 1; version->version_minor = 0; version->version_patchlevel = 0; } if (version) { if (version->version_major != 1 || version->version_minor < 1) { /* incompatible drm library version */ xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] RADEONDRIScreenInit failed because of a " "version mismatch.\n" "[dri] libdrm.a module version is %d.%d.%d but " "version 1.1.x is needed.\n" "[dri] Disabling DRI.\n", version->version_major, version->version_minor, version->version_patchlevel); drmFreeVersion(version); RADEONDRICloseScreen(pScreen); return FALSE; } drmFreeVersion(version); } /* Check the radeon DRM version */ version = drmGetVersion(info->drmFD); if (version) { int req_minor, req_patch; if (info->IsIGP) { req_minor = 10; req_patch = 0; } else if (info->ChipFamily >= CHIP_FAMILY_R200) { req_minor = 5; req_patch = 0; } else { #if X_BYTE_ORDER == X_LITTLE_ENDIAN req_minor = 1; req_patch = 0; #else req_minor = 2; req_patch = 1; #endif } if (version->version_major != 1 || version->version_minor < req_minor || (version->version_minor == req_minor && version->version_patchlevel < req_patch)) { /* Incompatible drm version */ xf86DrvMsg(pScreen->myNum, X_ERROR, "[dri] RADEONDRIScreenInit failed because of a version " "mismatch.\n" "[dri] radeon.o kernel module version is %d.%d.%d " "but version 1.%d.%d or newer is needed.\n" "[dri] Disabling DRI.\n", version->version_major, version->version_minor, version->version_patchlevel, req_minor, req_patch); drmFreeVersion(version); RADEONDRICloseScreen(pScreen); return FALSE; } if (version->version_minor < 3) { xf86DrvMsg(pScreen->myNum, X_WARNING, "[dri] Some DRI features disabled because of version " "mismatch.\n" "[dri] radeon.o kernel module version is %d.%d.%d but " "1.3.1 or later is preferred.\n", version->version_major, version->version_minor, version->version_patchlevel); } info->drmMinor = version->version_minor; drmFreeVersion(version); } /* Initialize AGP */ if (!info->IsPCI && !RADEONDRIAgpInit(info, pScreen)) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[agp] AGP failed to initialize. Disabling the DRI.\n" ); xf86DrvMsg(pScreen->myNum, X_INFO, "[agp] You may want to make sure the agpgart kernel " "module\nis loaded before the radeon kernel module.\n"); RADEONDRICloseScreen(pScreen); return FALSE; } /* Initialize PCI */ if (info->IsPCI && !RADEONDRIPciInit(info, pScreen)) { xf86DrvMsg(pScreen->myNum, X_ERROR, "[pci] PCI failed to initialize. Disabling the DRI.\n" ); RADEONDRICloseScreen(pScreen); return FALSE; } /* DRIScreenInit doesn't add all the * common mappings. Add additional * mappings here. */ if (!RADEONDRIMapInit(info, pScreen)) { RADEONDRICloseScreen(pScreen); return FALSE; } /* DRIScreenInit adds the frame buffer map, but we need it as well */ { void *scratch_ptr; int scratch_int; DRIGetDeviceInfo(pScreen, &info->fbHandle, &scratch_int, &scratch_int, &scratch_int, &scratch_int, &scratch_ptr); } /* FIXME: When are these mappings unmapped? */ if (!RADEONInitVisualConfigs(pScreen)) { RADEONDRICloseScreen(pScreen); return FALSE; } xf86DrvMsg(pScrn->scrnIndex, X_INFO, "[dri] Visual configs initialized\n"); return TRUE; } /* Finish initializing the device-dependent DRI state, and call * DRIFinishScreenInit() to complete the device-independent DRI * initialization. */ Bool RADEONDRIFinishScreenInit(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); RADEONSAREAPrivPtr pSAREAPriv; RADEONDRIPtr pRADEONDRI; info->pDRIInfo->driverSwapMethod = DRI_HIDE_X_CONTEXT; /* info->pDRIInfo->driverSwapMethod = DRI_SERVER_SWAP; */ /* NOTE: DRIFinishScreenInit must be called before *DRIKernelInit * because *DRIKernelInit requires that the hardware lock is held by * the X server, and the first time the hardware lock is grabbed is * in DRIFinishScreenInit. */ if (!DRIFinishScreenInit(pScreen)) { RADEONDRICloseScreen(pScreen); return FALSE; } /* Initialize the kernel data structures */ if (!RADEONDRIKernelInit(info, pScreen)) { RADEONDRICloseScreen(pScreen); return FALSE; } /* Initialize the vertex buffers list */ if (!RADEONDRIBufInit(info, pScreen)) { RADEONDRICloseScreen(pScreen); return FALSE; } /* Initialize IRQ */ RADEONDRIIrqInit(info, pScreen); /* Initialize kernel GART memory manager */ RADEONDRIGartHeapInit(info, pScreen); /* Initialize and start the CP if required */ RADEONDRICPInit(pScrn); /* Initialize the SAREA private data structure */ pSAREAPriv = (RADEONSAREAPrivPtr)DRIGetSAREAPrivate(pScreen); memset(pSAREAPriv, 0, sizeof(*pSAREAPriv)); pRADEONDRI = (RADEONDRIPtr)info->pDRIInfo->devPrivate; pRADEONDRI->deviceID = info->Chipset; pRADEONDRI->width = pScrn->virtualX; pRADEONDRI->height = pScrn->virtualY; pRADEONDRI->depth = pScrn->depth; pRADEONDRI->bpp = pScrn->bitsPerPixel; pRADEONDRI->IsPCI = info->IsPCI; pRADEONDRI->AGPMode = info->agpMode; pRADEONDRI->frontOffset = info->frontOffset; pRADEONDRI->frontPitch = info->frontPitch; pRADEONDRI->backOffset = info->backOffset; pRADEONDRI->backPitch = info->backPitch; pRADEONDRI->depthOffset = info->depthOffset; pRADEONDRI->depthPitch = info->depthPitch; pRADEONDRI->textureOffset = info->textureOffset; pRADEONDRI->textureSize = info->textureSize; pRADEONDRI->log2TexGran = info->log2TexGran; pRADEONDRI->registerHandle = info->registerHandle; pRADEONDRI->registerSize = info->registerSize; pRADEONDRI->statusHandle = info->ringReadPtrHandle; pRADEONDRI->statusSize = info->ringReadMapSize; pRADEONDRI->gartTexHandle = info->gartTexHandle; pRADEONDRI->gartTexMapSize = info->gartTexMapSize; pRADEONDRI->log2GARTTexGran = info->log2GARTTexGran; pRADEONDRI->gartTexOffset = info->gartTexStart; pRADEONDRI->sarea_priv_offset = sizeof(XF86DRISAREARec); #ifdef PER_CONTEXT_SAREA /* Set per-context SAREA size */ pRADEONDRI->perctx_sarea_size = info->perctx_sarea_size; #endif /* Have shadowfb run only while there is 3d active. */ if (info->allowPageFlip /* && info->drmMinor >= 3 */) { ShadowFBInit( pScreen, RADEONDRIRefreshArea ); } else { info->allowPageFlip = 0; } return TRUE; } /** * This function will attempt to get the Radeon hardware back into shape * after a resume from disc. * * Charl P. Botha */ void RADEONDRIResume(ScreenPtr pScreen) { int _ret; ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); if (info->drmMinor >= 9) { xf86DrvMsg(pScreen->myNum, X_INFO, "[RESUME] Attempting to re-init Radeon hardware.\n"); } else { xf86DrvMsg(pScreen->myNum, X_WARNING, "[RESUME] Cannot re-init Radeon hardware, DRM too old\n" "(need 1.9.0 or newer)\n"); return; } if (!info->IsPCI) { if (!RADEONSetAgpMode(info, pScreen)) return; RADEONSetAgpBase(info); } _ret = drmCommandNone(info->drmFD, DRM_RADEON_CP_RESUME); if (_ret) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "%s: CP resume %d\n", __FUNCTION__, _ret); /* FIXME: return? */ } RADEONEngineRestore(pScrn); RADEONDRICPInit(pScrn); } /* The screen is being closed, so clean up any state and free any * resources used by the DRI. */ void RADEONDRICloseScreen(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); drmRadeonInit drmInfo; RING_LOCALS; /* Stop the CP */ if (info->directRenderingEnabled) { /* If we've generated any CP commands, we must flush them to the * kernel module now. */ if (info->CPInUse) { RADEON_FLUSH_CACHE(); RADEON_WAIT_UNTIL_IDLE(); RADEONCPReleaseIndirect(pScrn); info->CPInUse = FALSE; } RADEONCP_STOP(pScrn, info); } if (info->irq) { drmCtlUninstHandler(info->drmFD); info->irq = 0; info->ModeReg.gen_int_cntl = 0; } /* De-allocate vertex buffers */ if (info->buffers) { drmUnmapBufs(info->buffers); info->buffers = NULL; } /* De-allocate all kernel resources */ memset(&drmInfo, 0, sizeof(drmRadeonInit)); drmInfo.func = DRM_RADEON_CLEANUP_CP; drmCommandWrite(info->drmFD, DRM_RADEON_CP_INIT, &drmInfo, sizeof(drmRadeonInit)); /* De-allocate all GART resources */ if (info->gartTex) { drmUnmap(info->gartTex, info->gartTexMapSize); info->gartTex = NULL; } if (info->buf) { drmUnmap(info->buf, info->bufMapSize); info->buf = NULL; } if (info->ringReadPtr) { drmUnmap(info->ringReadPtr, info->ringReadMapSize); info->ringReadPtr = NULL; } if (info->ring) { drmUnmap(info->ring, info->ringMapSize); info->ring = NULL; } if (info->agpMemHandle != DRM_AGP_NO_HANDLE) { drmAgpUnbind(info->drmFD, info->agpMemHandle); drmAgpFree(info->drmFD, info->agpMemHandle); info->agpMemHandle = DRM_AGP_NO_HANDLE; drmAgpRelease(info->drmFD); } if (info->pciMemHandle) { drmScatterGatherFree(info->drmFD, info->pciMemHandle); info->pciMemHandle = 0; } /* De-allocate all DRI resources */ DRICloseScreen(pScreen); /* De-allocate all DRI data structures */ if (info->pDRIInfo) { if (info->pDRIInfo->devPrivate) { xfree(info->pDRIInfo->devPrivate); info->pDRIInfo->devPrivate = NULL; } DRIDestroyInfoRec(info->pDRIInfo); info->pDRIInfo = NULL; } if (info->pVisualConfigs) { xfree(info->pVisualConfigs); info->pVisualConfigs = NULL; } if (info->pVisualConfigsPriv) { xfree(info->pVisualConfigsPriv); info->pVisualConfigsPriv = NULL; } } /* Fullscreen hooks. The DRI fullscreen mode can probably be removed as * it adds little or nothing above the mechanism below (and isn't widely * used). */ static Bool RADEONDRIOpenFullScreen(ScreenPtr pScreen) { return TRUE; } static Bool RADEONDRICloseFullScreen(ScreenPtr pScreen) { return TRUE; } /* Use callbacks from dri.c to support pageflipping mode for a single * 3d context without need for any specific full-screen extension. * * Also use these callbacks to allocate and free 3d-specific memory on * demand. */ /* Use the shadowfb module to maintain a list of dirty rectangles. * These are blitted to the back buffer to keep both buffers clean * during page-flipping when the 3d application isn't fullscreen. * * Unlike most use of the shadowfb code, both buffers are in video memory. * * An alternative to this would be to organize for all on-screen drawing * operations to be duplicated for the two buffers. That might be * faster, but seems like a lot more work... */ static void RADEONDRIRefreshArea(ScrnInfoPtr pScrn, int num, BoxPtr pbox) { RADEONInfoPtr info = RADEONPTR(pScrn); int i; RADEONSAREAPrivPtr pSAREAPriv = DRIGetSAREAPrivate(pScrn->pScreen); /* Don't want to do this when no 3d is active and pages are * right-way-round */ if (!pSAREAPriv->pfAllowPageFlip && pSAREAPriv->pfCurrentPage == 0) return; (*info->accel->SetupForScreenToScreenCopy)(pScrn, 1, 1, GXcopy, (CARD32)(-1), -1); for (i = 0 ; i < num ; i++, pbox++) { int xa = max(pbox->x1, 0), xb = min(pbox->x2, pScrn->virtualX-1); int ya = max(pbox->y1, 0), yb = min(pbox->y2, pScrn->virtualY-1); if (xa <= xb && ya <= yb) { (*info->accel->SubsequentScreenToScreenCopy)(pScrn, xa, ya, xa + info->backX, ya + info->backY, xb - xa + 1, yb - ya + 1); } } } static void RADEONEnablePageFlip(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); RADEONSAREAPrivPtr pSAREAPriv = DRIGetSAREAPrivate(pScreen); if (info->allowPageFlip) { /* Duplicate the frontbuffer to the backbuffer */ (*info->accel->SetupForScreenToScreenCopy)(pScrn, 1, 1, GXcopy, (CARD32)(-1), -1); (*info->accel->SubsequentScreenToScreenCopy)(pScrn, 0, 0, info->backX, info->backY, pScrn->virtualX, pScrn->virtualY); pSAREAPriv->pfAllowPageFlip = 1; } } static void RADEONDisablePageFlip(ScreenPtr pScreen) { /* Tell the clients not to pageflip. How? * -- Field in sarea, plus bumping the window counters. * -- DRM needs to cope with Front-to-Back swapbuffers. */ RADEONSAREAPrivPtr pSAREAPriv = DRIGetSAREAPrivate(pScreen); pSAREAPriv->pfAllowPageFlip = 0; } static void RADEONDRITransitionSingleToMulti3d(ScreenPtr pScreen) { RADEONDisablePageFlip(pScreen); } static void RADEONDRITransitionMultiToSingle3d(ScreenPtr pScreen) { /* Let the remaining 3d app start page flipping again */ RADEONEnablePageFlip(pScreen); } static void RADEONDRITransitionTo3d(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); FBAreaPtr fbarea; int width, height; /* reserve offscreen area for back and depth buffers and textures */ /* If we still have an area for the back buffer reserved, free it * first so we always start with all free offscreen memory, except * maybe for Xv */ if (info->backArea) { xf86FreeOffscreenArea(info->backArea); info->backArea = NULL; } xf86PurgeUnlockedOffscreenAreas(pScreen); xf86QueryLargestOffscreenArea(pScreen, &width, &height, 0, 0, 0); /* Free Xv linear offscreen memory if necessary */ if (height < (info->depthTexLines + info->backLines)) { xf86FreeOffscreenLinear(info->videoLinear); info->videoLinear = NULL; xf86QueryLargestOffscreenArea(pScreen, &width, &height, 0, 0, 0); } /* Reserve placeholder area so the other areas will match the * pre-calculated offsets */ fbarea = xf86AllocateOffscreenArea(pScreen, pScrn->displayWidth, height - info->depthTexLines - info->backLines, pScrn->displayWidth, NULL, NULL, NULL); if (!fbarea) xf86DrvMsg(pScreen->myNum, X_ERROR, "Unable to reserve placeholder " "offscreen area, you might experience screen corruption\n"); info->backArea = xf86AllocateOffscreenArea(pScreen, pScrn->displayWidth, info->backLines, pScrn->displayWidth, NULL, NULL, NULL); if (!info->backArea) xf86DrvMsg(pScreen->myNum, X_ERROR, "Unable to reserve offscreen " "area for back buffer, you might experience screen " "corruption\n"); info->depthTexArea = xf86AllocateOffscreenArea(pScreen, pScrn->displayWidth, info->depthTexLines, pScrn->displayWidth, NULL, NULL, NULL); if (!info->depthTexArea) xf86DrvMsg(pScreen->myNum, X_ERROR, "Unable to reserve offscreen " "area for depth buffer and textures, you might " "experience screen corruption\n"); xf86FreeOffscreenArea(fbarea); RADEONEnablePageFlip(pScreen); info->have3DWindows = 1; if (info->cursor_start) xf86ForceHWCursor (pScreen, TRUE); } static void RADEONDRITransitionTo2d(ScreenPtr pScreen) { ScrnInfoPtr pScrn = xf86Screens[pScreen->myNum]; RADEONInfoPtr info = RADEONPTR(pScrn); RADEONSAREAPrivPtr pSAREAPriv = DRIGetSAREAPrivate(pScreen); /* Try flipping back to the front page if necessary */ if (pSAREAPriv->pfCurrentPage == 1) drmCommandNone(info->drmFD, DRM_RADEON_FLIP); /* Shut down shadowing if we've made it back to the front page */ if (pSAREAPriv->pfCurrentPage == 0) { RADEONDisablePageFlip(pScreen); xf86FreeOffscreenArea(info->backArea); info->backArea = NULL; } else { xf86DrvMsg(pScreen->myNum, X_WARNING, "[dri] RADEONDRITransitionTo2d: " "kernel failed to unflip buffers.\n"); } xf86FreeOffscreenArea(info->depthTexArea); info->have3DWindows = 0; if (info->cursor_start) xf86ForceHWCursor (pScreen, FALSE); }