/* * Copyright 2000 through 2004 by Marc Aurele La France (TSI @ UQV), tsi@xfree86.org * * Permission to use, copy, modify, distribute, and sell this software and its * documentation for any purpose is hereby granted without fee, provided that * the above copyright notice appear in all copies and that both that copyright * notice and this permission notice appear in supporting documentation, and * that the name of Marc Aurele La France not be used in advertising or * publicity pertaining to distribution of the software without specific, * written prior permission. Marc Aurele La France makes no representations * about the suitability of this software for any purpose. It is provided * "as-is" without express or implied warranty. * * MARC AURELE LA FRANCE DISCLAIMS ALL WARRANTIES WITH REGARD TO THIS SOFTWARE, * INCLUDING ALL IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS. IN NO * EVENT SHALL MARC AURELE LA FRANCE BE LIABLE FOR ANY SPECIAL, INDIRECT OR * CONSEQUENTIAL DAMAGES OR ANY DAMAGES WHATSOEVER RESULTING FROM LOSS OF USE, * DATA OR PROFITS, WHETHER IN AN ACTION OF CONTRACT, NEGLIGENCE OR OTHER * TORTIOUS ACTION, ARISING OUT OF OR IN CONNECTION WITH THE USE OR * PERFORMANCE OF THIS SOFTWARE. * * DRI support by: * Manuel Teira * Leif Delgass */ #ifndef ___ATIMACH64IO_H___ #if !defined(___ATI_H___) && defined(XFree86Module) # error Missing #include "ati.h" before #include "atimach64io.h" # undef XFree86Module #endif #define ___ATIMACH64IO_H___ 1 #include "atiio.h" #include "atistruct.h" /* * A few important notes on some of the I/O statements provided: * * inl/outl 32-bit R/W through PIO space. The register is specified as the * actual PIO address. These are actually defined in compiler.h. * * inw/outw 16-bit counterparts to inl/outl. Not used for Mach64 support. * * inb/outb 8-bit counterparts to inl/outl. * * inm/outm 32-bit R/W through MMIO space. The register is specified as * the actual MMIO offset (with Block 1 following Block 0), which, * in this case, is equivalent to the register's IOPortTag from * atiregs.h. Can be used for those few non-FIFO'ed registers * outside of Block 0's first 256 bytes. inm() can also be used * for FIFO'ed registers if, and only if, it can be guaranteed to * not have been previously FIFO'ed (e.g. when the engine is * idle). pATI->pBlock array elements must have been previously * set up by ATIMapApertures(). * * outf 32-bit write through MMIO cache. Identical to outm() but * intended for FIFO'ed registers. There is no inf() provided. * * inr/outr 32-bit R/W through PIO or MMIO. Which one depends on the * machine architecture. The register is specified as a IOPortTag * from atiregs.h. Can only be used for registers in the first * 256 bytes of MMIO space (in Block 0). Note that all of these * registers are non-FIFO'ed. * * in8/out8 8-bit counterparts to inr/outr. * * For portability reasons, inr/outr/in8/out8 should be used in preference to * inl/outl/inb/outb to/from any register space starting with CRTC_H_TOTAL_DISP * but before DST_OFF_PITCH (in the order defined by atiregs.h). None of * inm/outm/outf should ever be used for these registers. * * outf()'s should be grouped together as much as possible, while respecting * any ordering constraints the engine might impose. Groups larger than 16 * outf()'s should be split up into two or more groups as needed (but not * necessarily wanted). The outf() groups that result should be immediately * preceeded by an ATIMach64WaitForFIFO(n) call, where "n" is the number of * outf()'s in the group with the exception that groups containing a single * outf() should not be thus preceeded. This means "n" should not be less than * 2, nor larger than 16. */ /* * Cave canem (or it WILL bite you): All Mach64 non-VGA registers are * ================================ little-endian, no matter how they are * accessed (nor by what). */ #define inm(_Register) \ MMIO_IN32(pATI->pBlock[GetBits(_Register, BLOCK_SELECT)], \ (_Register) & MM_IO_SELECT) #define outm(_Register, _Value) \ MMIO_OUT32(pATI->pBlock[GetBits(_Register, BLOCK_SELECT)], \ (_Register) & MM_IO_SELECT, _Value) #ifdef AVOID_CPIO # define inr(_Register) \ MMIO_IN32(pATI->pBlock[0], (_Register) & MM_IO_SELECT) # define outr(_Register, _Value) \ MMIO_OUT32(pATI->pBlock[0], (_Register) & MM_IO_SELECT, _Value) # define in8(_Register) \ MMIO_IN8(pATI->pBlock[0], \ (_Register) & (MM_IO_SELECT | IO_BYTE_SELECT)) # define out8(_Register, _Value) \ MMIO_OUT8(pATI->pBlock[0], \ (_Register) & (MM_IO_SELECT | IO_BYTE_SELECT), _Value) /* Cause a cpp syntax error if any of these are used */ #undef inb #undef inw #undef inl #undef outb #undef outw #undef outl #define inb() /* Nothing */ #define inw() /* Nothing */ #define inl() /* Nothing */ #define outb() /* Nothing */ #define outw() /* Nothing */ #define outl() /* Nothing */ #else /* AVOID_CPIO */ # define ATIIOPort(_PortTag) \ (((pATI->CPIODecoding == SPARSE_IO) ? \ ((_PortTag) & (SPARSE_IO_SELECT | IO_BYTE_SELECT)) : \ ((_PortTag) & (BLOCK_IO_SELECT | IO_BYTE_SELECT))) | \ pATI->CPIOBase) # define inr(_Register) \ inl(ATIIOPort(_Register)) # define outr(_Register, _Value) \ outl(ATIIOPort(_Register), _Value) # define in8(_Register) \ inb(ATIIOPort(_Register)) # define out8(_Register, _Value) \ outb(ATIIOPort(_Register), _Value) #endif /* AVOID_CPIO */ extern void ATIMach64PollEngineStatus(ATIPtr); /* * MMIO cache definitions. * * Many FIFO'ed registers can be cached by the driver. Registers that qualify * for caching must not contain values that can change without driver * intervention. Thus registers that contain hardware counters, strobe lines, * etc., cannot be cached. This caching is intended to minimise FIFO use. * There is therefore not much point to enable it for non-FIFO'ed registers. * * The cache for a particular 32-bit register is enabled by coding a * CacheRegister() line for that register in the ATIMach64Set() function. The * integrity of the cache for a particular register should be verified by the * ATIMach64Sync() function. This code should be kept in register order, as * defined in atiregs.h. */ #define CacheByte(___Register) pATI->MMIOCached[CacheSlotOf(___Register) >> 3] #define CacheBit(___Register) (0x80U >> (CacheSlotOf(___Register) & 0x07U)) #define RegisterIsCached(__Register) \ (CacheByte(__Register) & CacheBit(__Register)) #define CacheSlot(__Register) pATI->MMIOCache[CacheSlotOf(__Register)] #define CacheRegister(__Register) \ CacheByte(__Register) |= CacheBit(__Register) #define UncacheRegister(__Register) \ CacheByte(__Register) &= ~CacheBit(__Register) /* This would be quite a bit slower as a function */ #define outf(_Register, _Value) \ do \ { \ CARD32 _IOValue = (_Value); \ \ if (!RegisterIsCached(_Register) || \ (_IOValue != CacheSlot(_Register))) \ { \ while (!pATI->nAvailableFIFOEntries--) \ ATIMach64PollEngineStatus(pATI); \ MMIO_OUT32(pATI->pBlock[GetBits(_Register, BLOCK_SELECT)], \ (_Register) & MM_IO_SELECT, _IOValue); \ CacheSlot(_Register) = _IOValue; \ pATI->EngineIsBusy = TRUE; \ } \ } while (0) /* * This is no longer as critical, especially for _n == 1. However, * there is still a need to ensure _n <= pATI->nFIFOEntries. */ #define ATIMach64WaitForFIFO(_pATI, _n) \ while ((_pATI)->nAvailableFIFOEntries < (_n)) \ ATIMach64PollEngineStatus(_pATI) #define ATIMach64WaitForIdle(_pATI) \ while ((_pATI)->EngineIsBusy) \ ATIMach64PollEngineStatus(_pATI) #ifdef XF86DRI_DEVEL /* * DRI Sync and Lock definitions. */ #define ATIDRIWaitForIdle(_pATI) \ do { \ ATIDRIServerInfoPtr pATIDRIServer = _pATI->pDRIServerInfo; \ int ret; \ \ if (pATIDRIServer && pATI->directRenderingEnabled) { \ /* Wait for DMA to complete */ \ ret = drmCommandNone(_pATI->drmFD, DRM_MACH64_IDLE); \ if (ret) { \ drmCommandNone(_pATI->drmFD, DRM_MACH64_RESET); \ } \ \ /* Force updating of FIFO entry counters */ \ pATI->EngineIsBusy = TRUE; \ ATIMach64PollEngineStatus(_pATI); \ } else { \ ATIMach64WaitForIdle(_pATI); \ } \ } while (0) /* * Set upon DRISwapContext and when DRI accesses the GPU engine * from within the server, see DRIInitBuffers/DRIMoveBuffers. * * Forces the EXA/XAA software paths to sync before accessing the FB memory. */ static __inline__ void ATIDRIMarkSyncInt(ScrnInfoPtr _pScrInfo) { ATIPtr _pATI=ATIPTR(_pScrInfo); #ifdef USE_EXA if (_pATI->useEXA) exaMarkSync(_pScrInfo->pScreen); #endif #ifdef USE_XAA if (!_pATI->useEXA) SET_SYNC_FLAG(_pATI->pXAAInfo); /* NeedToSync = TRUE */ #endif } /* * Set upon DRISwapContext and when the server acquires the DRI lock. * * Forces the EXA/XAA accelerated paths to sync before accessing the GPU engine. */ static __inline__ void ATIDRIMarkSyncExt(ScrnInfoPtr _pScrInfo) { ATIPtr _pATI=ATIPTR(_pScrInfo); _pATI->NeedDRISync = TRUE; } static __inline__ void ATIDRISync(ScrnInfoPtr _pScrInfo) { ATIPtr _pATI=ATIPTR(_pScrInfo); #ifdef USE_EXA if (_pATI->directRenderingEnabled && _pATI->pExa) { if (_pATI->NeedDRISync) exaWaitSync(_pScrInfo->pScreen); } #endif #ifdef USE_XAA if (_pATI->directRenderingEnabled && _pATI->pXAAInfo) { if (_pATI->NeedDRISync) (*_pATI->pXAAInfo->Sync)(_pScrInfo); } #endif } #define ATIDRILock(_pScrInfo) \ do \ { \ ATIPtr _pATI=ATIPTR(_pScrInfo); \ if (_pATI->directRenderingEnabled) \ { \ DRILock(_pScrInfo->pScreen, 0); \ ATIDRIMarkSyncExt(_pScrInfo); \ } \ } while (0) #define ATIDRIUnlock(_pScrInfo) \ do \ { \ ATIPtr _pATI=ATIPTR(_pScrInfo); \ if (_pATI->directRenderingEnabled) \ { \ DRIUnlock(_pScrInfo->pScreen); \ } \ } while (0) #else /* XF86DRI_DEVEL */ #define ATIDRIWaitForIdle(_pATI) #define ATIDRILock(_pScrInfo) #define ATIDRIUnlock(_pScrInfo) #define ATIDRISync(_pScrInfo) #endif /* XF86DRI_DEVEL */ /* * An outf() variant to write two registers such that the second register is * is always written whenever either is to be changed. */ #define outq(_Register1, _Register2, _Value1, _Value2) \ do \ { \ CARD32 _IOValue1 = (_Value1), \ _IOValue2 = (_Value2); \ \ if (!RegisterIsCached(_Register1) || \ (_IOValue1 != CacheSlot(_Register1))) \ { \ ATIMach64WaitForFIFO(pATI, 2); \ pATI->nAvailableFIFOEntries -= 2; \ MMIO_OUT32(pATI->pBlock[GetBits(_Register1, BLOCK_SELECT)], \ (_Register1) & MM_IO_SELECT, _IOValue1); \ MMIO_OUT32(pATI->pBlock[GetBits(_Register2, BLOCK_SELECT)], \ (_Register2) & MM_IO_SELECT, _IOValue2); \ CacheSlot(_Register1) = _IOValue1; \ CacheSlot(_Register2) = _IOValue2; \ pATI->EngineIsBusy = TRUE; \ } \ else if (!RegisterIsCached(_Register2) || \ (_IOValue2 != CacheSlot(_Register2))) \ { \ while (!pATI->nAvailableFIFOEntries--) \ ATIMach64PollEngineStatus(pATI); \ MMIO_OUT32(pATI->pBlock[GetBits(_Register2, BLOCK_SELECT)], \ (_Register2) & MM_IO_SELECT, _IOValue2); \ CacheSlot(_Register2) = _IOValue2; \ pATI->EngineIsBusy = TRUE; \ } \ } while (0) extern void ATIMach64AccessPLLReg(ATIPtr, const CARD8, const Bool); #define ATIMach64GetPLLReg(_Index) \ ( \ ATIMach64AccessPLLReg(pATI, _Index, FALSE), \ in8(CLOCK_CNTL + 2) \ ) #define ATIMach64PutPLLReg(_Index, _Value) \ do \ { \ ATIMach64AccessPLLReg(pATI, _Index, TRUE); \ out8(CLOCK_CNTL + 2, _Value); \ } while (0) #define ATIMach64GetLCDReg(_Index) \ ( \ out8(LCD_INDEX, SetBits(_Index, LCD_REG_INDEX)), \ inr(LCD_DATA) \ ) #define ATIMach64PutLCDReg(_Index, _Value) \ do \ { \ out8(LCD_INDEX, SetBits(_Index, LCD_REG_INDEX)); \ outr(LCD_DATA, _Value); \ } while (0) #define ATIMach64GetTVReg(_Index) \ ( \ out8(TV_OUT_INDEX, SetBits(_Index, TV_REG_INDEX)), \ inr(TV_OUT_DATA) \ ) #define ATIMach64PutTVReg(_Index, _Value) \ do \ { \ out8(TV_OUT_INDEX, SetBits(_Index, TV_REG_INDEX)); \ outr(TV_OUT_DATA, _Value); \ } while (0) /* * Block transfer definitions. */ #if defined(GCCUSESGAS) && \ (defined(i386) || defined(__i386) || defined(__i386__)) #define ATIMove32(_pDst, _pSrc, _nCount) \ do \ { \ long d0, d1, d2; \ __asm__ __volatile__ \ ( \ "cld\n\t" \ "rep ; movsl" \ : "=&c" (d0), \ "=&D" (d1), \ "=&S" (d2) \ : "0" (_nCount), \ "1" (_pDst), \ "2" (_pSrc) \ : "memory" \ ); \ } while (0) #endif /* * Return the MMIO address of register, used for HOST_DATA_X only. */ #define ATIHostDataAddr(_Register) \ ((CARD8 *)pATI->pBlock[GetBits(_Register, BLOCK_SELECT)] + \ ((_Register) & MM_IO_SELECT)) #endif /* ___ATIMACH64IO_H___ */