/* * Copyright 2007 Egbert Eich * Copyright 2007 Luc Verhaegen * Copyright 2007 Matthias Hopf * Copyright 2007 Advanced Micro Devices, 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. */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include "xf86.h" #include "xf86_OSproc.h" #include "radeon.h" #include "radeon_atombios.h" #include "radeon_atomwrapper.h" #include "radeon_probe.h" #include "radeon_macros.h" #include "xorg-server.h" /* only for testing now */ #include "xf86DDC.h" typedef AtomBiosResult (*AtomBiosRequestFunc)(atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data); typedef struct rhdConnectorInfo *rhdConnectorInfoPtr; static AtomBiosResult rhdAtomInit(atomBiosHandlePtr unused1, AtomBiosRequestID unused2, AtomBiosArgPtr data); static AtomBiosResult rhdAtomTearDown(atomBiosHandlePtr handle, AtomBiosRequestID unused1, AtomBiosArgPtr unused2); static AtomBiosResult rhdAtomVramInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); static AtomBiosResult rhdAtomTmdsInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); static AtomBiosResult rhdAtomAllocateFbScratch(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); static AtomBiosResult rhdAtomLvdsGetTimings(atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data); static AtomBiosResult rhdAtomCVGetTimings(atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data); static AtomBiosResult rhdAtomLvdsInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); static AtomBiosResult rhdAtomGPIOI2CInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); static AtomBiosResult rhdAtomFirmwareInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); /*static AtomBiosResult rhdAtomConnectorInfo(atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data);*/ # ifdef ATOM_BIOS_PARSER static AtomBiosResult rhdAtomExec(atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data); # endif static AtomBiosResult rhdAtomCompassionateDataQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data); enum msgDataFormat { MSG_FORMAT_NONE, MSG_FORMAT_HEX, MSG_FORMAT_DEC }; struct atomBIOSRequests { AtomBiosRequestID id; AtomBiosRequestFunc request; char *message; enum msgDataFormat message_format; } AtomBiosRequestList [] = { {ATOMBIOS_INIT, rhdAtomInit, "AtomBIOS Init", MSG_FORMAT_NONE}, {ATOMBIOS_TEARDOWN, rhdAtomTearDown, "AtomBIOS Teardown", MSG_FORMAT_NONE}, # ifdef ATOM_BIOS_PARSER {ATOMBIOS_EXEC, rhdAtomExec, "AtomBIOS Exec", MSG_FORMAT_NONE}, #endif {ATOMBIOS_ALLOCATE_FB_SCRATCH, rhdAtomAllocateFbScratch, "AtomBIOS Set FB Space", MSG_FORMAT_NONE}, /*{ATOMBIOS_GET_CONNECTORS, rhdAtomConnectorInfo, "AtomBIOS Get Connectors", MSG_FORMAT_NONE},*/ {ATOMBIOS_GET_PANEL_MODE, rhdAtomLvdsGetTimings, "AtomBIOS Get Panel Mode", MSG_FORMAT_NONE}, {ATOMBIOS_GET_PANEL_EDID, rhdAtomLvdsGetTimings, "AtomBIOS Get Panel EDID", MSG_FORMAT_NONE}, {GET_DEFAULT_ENGINE_CLOCK, rhdAtomFirmwareInfoQuery, "Default Engine Clock", MSG_FORMAT_DEC}, {GET_DEFAULT_MEMORY_CLOCK, rhdAtomFirmwareInfoQuery, "Default Memory Clock", MSG_FORMAT_DEC}, {GET_MAX_PIXEL_CLOCK_PLL_OUTPUT, rhdAtomFirmwareInfoQuery, "Maximum Pixel ClockPLL Frequency Output", MSG_FORMAT_DEC}, {GET_MIN_PIXEL_CLOCK_PLL_OUTPUT, rhdAtomFirmwareInfoQuery, "Minimum Pixel ClockPLL Frequency Output", MSG_FORMAT_DEC}, {GET_MAX_PIXEL_CLOCK_PLL_INPUT, rhdAtomFirmwareInfoQuery, "Maximum Pixel ClockPLL Frequency Input", MSG_FORMAT_DEC}, {GET_MIN_PIXEL_CLOCK_PLL_INPUT, rhdAtomFirmwareInfoQuery, "Minimum Pixel ClockPLL Frequency Input", MSG_FORMAT_DEC}, {GET_MAX_PIXEL_CLK, rhdAtomFirmwareInfoQuery, "Maximum Pixel Clock", MSG_FORMAT_DEC}, {GET_REF_CLOCK, rhdAtomFirmwareInfoQuery, "Reference Clock", MSG_FORMAT_DEC}, {GET_FW_FB_START, rhdAtomVramInfoQuery, "Start of VRAM area used by Firmware", MSG_FORMAT_HEX}, {GET_FW_FB_SIZE, rhdAtomVramInfoQuery, "Framebuffer space used by Firmware (kb)", MSG_FORMAT_DEC}, {ATOM_TMDS_FREQUENCY, rhdAtomTmdsInfoQuery, "TMDS Frequency", MSG_FORMAT_DEC}, {ATOM_TMDS_PLL_CHARGE_PUMP, rhdAtomTmdsInfoQuery, "TMDS PLL ChargePump", MSG_FORMAT_DEC}, {ATOM_TMDS_PLL_DUTY_CYCLE, rhdAtomTmdsInfoQuery, "TMDS PLL DutyCycle", MSG_FORMAT_DEC}, {ATOM_TMDS_PLL_VCO_GAIN, rhdAtomTmdsInfoQuery, "TMDS PLL VCO Gain", MSG_FORMAT_DEC}, {ATOM_TMDS_PLL_VOLTAGE_SWING, rhdAtomTmdsInfoQuery, "TMDS PLL VoltageSwing", MSG_FORMAT_DEC}, {ATOM_LVDS_SUPPORTED_REFRESH_RATE, rhdAtomLvdsInfoQuery, "LVDS Supported Refresh Rate", MSG_FORMAT_DEC}, {ATOM_LVDS_OFF_DELAY, rhdAtomLvdsInfoQuery, "LVDS Off Delay", MSG_FORMAT_DEC}, {ATOM_LVDS_SEQ_DIG_ONTO_DE, rhdAtomLvdsInfoQuery, "LVDS SEQ Dig onto DE", MSG_FORMAT_DEC}, {ATOM_LVDS_SEQ_DE_TO_BL, rhdAtomLvdsInfoQuery, "LVDS SEQ DE to BL", MSG_FORMAT_DEC}, {ATOM_LVDS_DITHER, rhdAtomLvdsInfoQuery, "LVDS Ditherc", MSG_FORMAT_HEX}, {ATOM_LVDS_DUALLINK, rhdAtomLvdsInfoQuery, "LVDS Duallink", MSG_FORMAT_HEX}, {ATOM_LVDS_GREYLVL, rhdAtomLvdsInfoQuery, "LVDS Grey Level", MSG_FORMAT_HEX}, {ATOM_LVDS_FPDI, rhdAtomLvdsInfoQuery, "LVDS FPDI", MSG_FORMAT_HEX}, {ATOM_LVDS_24BIT, rhdAtomLvdsInfoQuery, "LVDS 24Bit", MSG_FORMAT_HEX}, {ATOM_GPIO_I2C_CLK_MASK, rhdAtomGPIOI2CInfoQuery, "GPIO_I2C_Clk_Mask", MSG_FORMAT_HEX}, {ATOM_DAC1_BG_ADJ, rhdAtomCompassionateDataQuery, "DAC1 BG Adjustment", MSG_FORMAT_HEX}, {ATOM_DAC1_DAC_ADJ, rhdAtomCompassionateDataQuery, "DAC1 DAC Adjustment", MSG_FORMAT_HEX}, {ATOM_DAC1_FORCE, rhdAtomCompassionateDataQuery, "DAC1 Force Data", MSG_FORMAT_HEX}, {ATOM_DAC2_CRTC2_BG_ADJ, rhdAtomCompassionateDataQuery, "DAC2_CRTC2 BG Adjustment", MSG_FORMAT_HEX}, {ATOM_DAC2_CRTC2_DAC_ADJ, rhdAtomCompassionateDataQuery, "DAC2_CRTC2 DAC Adjustment", MSG_FORMAT_HEX}, {ATOM_DAC2_CRTC2_FORCE, rhdAtomCompassionateDataQuery, "DAC2_CRTC2 Force", MSG_FORMAT_HEX}, {ATOM_DAC2_CRTC2_MUX_REG_IND,rhdAtomCompassionateDataQuery, "DAC2_CRTC2 Mux Register Index", MSG_FORMAT_HEX}, {ATOM_DAC2_CRTC2_MUX_REG_INFO,rhdAtomCompassionateDataQuery, "DAC2_CRTC2 Mux Register Info", MSG_FORMAT_HEX}, {ATOMBIOS_GET_CV_MODES, rhdAtomCVGetTimings, "AtomBIOS Get CV Mode", MSG_FORMAT_NONE}, {FUNC_END, NULL, NULL, MSG_FORMAT_NONE} }; enum { legacyBIOSLocation = 0xC0000, legacyBIOSMax = 0x10000 }; #define DEBUGP(x) {x;} #define LOG_DEBUG 7 # ifdef ATOM_BIOS_PARSER # define LOG_CAIL LOG_DEBUG + 1 #if 0 static void RHDDebug(int scrnIndex, const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(scrnIndex, X_INFO, LOG_DEBUG, format, ap); va_end(ap); } static void RHDDebugCont(const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(-1, X_NONE, LOG_DEBUG, format, ap); va_end(ap); } #endif static void CailDebug(int scrnIndex, const char *format, ...) { va_list ap; va_start(ap, format); xf86VDrvMsgVerb(scrnIndex, X_INFO, LOG_CAIL, format, ap); va_end(ap); } # define CAILFUNC(ptr) \ CailDebug(((atomBiosHandlePtr)(ptr))->scrnIndex, "CAIL: %s\n", __func__) # endif static int rhdAtomAnalyzeCommonHdr(ATOM_COMMON_TABLE_HEADER *hdr) { if (hdr->usStructureSize == 0xaa55) return FALSE; return TRUE; } static int rhdAtomAnalyzeRomHdr(unsigned char *rombase, ATOM_ROM_HEADER *hdr, unsigned int *data_offset, unsigned int *command_offset) { if (!rhdAtomAnalyzeCommonHdr(&hdr->sHeader)) { return FALSE; } xf86DrvMsg(-1,X_NONE,"\tSubsystemVendorID: 0x%4.4x SubsystemID: 0x%4.4x\n", hdr->usSubsystemVendorID,hdr->usSubsystemID); xf86DrvMsg(-1,X_NONE,"\tIOBaseAddress: 0x%4.4x\n",hdr->usIoBaseAddress); xf86DrvMsgVerb(-1,X_NONE,3,"\tFilename: %s\n",rombase + hdr->usConfigFilenameOffset); xf86DrvMsgVerb(-1,X_NONE,3,"\tBIOS Bootup Message: %s\n", rombase + hdr->usBIOS_BootupMessageOffset); *data_offset = hdr->usMasterDataTableOffset; *command_offset = hdr->usMasterCommandTableOffset; return TRUE; } static int rhdAtomAnalyzeRomDataTable(unsigned char *base, int offset, void *ptr,unsigned short *size) { ATOM_COMMON_TABLE_HEADER *table = (ATOM_COMMON_TABLE_HEADER *) (base + offset); if (!*size || !rhdAtomAnalyzeCommonHdr(table)) { if (*size) *size -= 2; *(void **)ptr = NULL; return FALSE; } *size -= 2; *(void **)ptr = (void *)(table); return TRUE; } Bool rhdAtomGetTableRevisionAndSize(ATOM_COMMON_TABLE_HEADER *hdr, CARD8 *contentRev, CARD8 *formatRev, unsigned short *size) { if (!hdr) return FALSE; if (contentRev) *contentRev = hdr->ucTableContentRevision; if (formatRev) *formatRev = hdr->ucTableFormatRevision; if (size) *size = (short)hdr->usStructureSize - sizeof(ATOM_COMMON_TABLE_HEADER); return TRUE; } static Bool rhdAtomAnalyzeMasterDataTable(unsigned char *base, ATOM_MASTER_DATA_TABLE *table, atomDataTablesPtr data) { ATOM_MASTER_LIST_OF_DATA_TABLES *data_table = &table->ListOfDataTables; unsigned short size; if (!rhdAtomAnalyzeCommonHdr(&table->sHeader)) return FALSE; if (!rhdAtomGetTableRevisionAndSize(&table->sHeader,NULL,NULL, &size)) return FALSE; # define SET_DATA_TABLE(x) {\ rhdAtomAnalyzeRomDataTable(base,data_table->x,(void *)(&(data->x)),&size); \ } # define SET_DATA_TABLE_VERS(x) {\ rhdAtomAnalyzeRomDataTable(base,data_table->x,&(data->x.base),&size); \ } SET_DATA_TABLE(UtilityPipeLine); SET_DATA_TABLE(MultimediaCapabilityInfo); SET_DATA_TABLE(MultimediaConfigInfo); SET_DATA_TABLE(StandardVESA_Timing); SET_DATA_TABLE_VERS(FirmwareInfo); SET_DATA_TABLE(DAC_Info); SET_DATA_TABLE_VERS(LVDS_Info); SET_DATA_TABLE(TMDS_Info); SET_DATA_TABLE(AnalogTV_Info); SET_DATA_TABLE_VERS(SupportedDevicesInfo); SET_DATA_TABLE(GPIO_I2C_Info); SET_DATA_TABLE(VRAM_UsageByFirmware); SET_DATA_TABLE(GPIO_Pin_LUT); SET_DATA_TABLE(VESA_ToInternalModeLUT); SET_DATA_TABLE_VERS(ComponentVideoInfo); SET_DATA_TABLE(PowerPlayInfo); SET_DATA_TABLE(CompassionateData); SET_DATA_TABLE(SaveRestoreInfo); SET_DATA_TABLE(PPLL_SS_Info); SET_DATA_TABLE(OemInfo); SET_DATA_TABLE(XTMDS_Info); SET_DATA_TABLE(MclkSS_Info); SET_DATA_TABLE(Object_Header); SET_DATA_TABLE(IndirectIOAccess); SET_DATA_TABLE(MC_InitParameter); SET_DATA_TABLE(ASIC_VDDC_Info); SET_DATA_TABLE(ASIC_InternalSS_Info); SET_DATA_TABLE(TV_VideoMode); SET_DATA_TABLE_VERS(VRAM_Info); SET_DATA_TABLE(MemoryTrainingInfo); SET_DATA_TABLE_VERS(IntegratedSystemInfo); SET_DATA_TABLE(ASIC_ProfilingInfo); SET_DATA_TABLE(VoltageObjectInfo); SET_DATA_TABLE(PowerSourceInfo); # undef SET_DATA_TABLE return TRUE; } static Bool rhdAtomGetDataTable(int scrnIndex, unsigned char *base, atomDataTables *atomDataPtr, unsigned int *cmd_offset, unsigned int BIOSImageSize) { unsigned int data_offset; unsigned int atom_romhdr_off = *(unsigned short*) (base + OFFSET_TO_POINTER_TO_ATOM_ROM_HEADER); ATOM_ROM_HEADER *atom_rom_hdr = (ATOM_ROM_HEADER *)(base + atom_romhdr_off); //RHDFUNCI(scrnIndex); if (atom_romhdr_off + sizeof(ATOM_ROM_HEADER) > BIOSImageSize) { xf86DrvMsg(scrnIndex,X_ERROR, "%s: AtomROM header extends beyond BIOS image\n",__func__); return FALSE; } if (memcmp("ATOM",&atom_rom_hdr->uaFirmWareSignature,4)) { xf86DrvMsg(scrnIndex,X_ERROR,"%s: No AtomBios signature found\n", __func__); return FALSE; } xf86DrvMsg(scrnIndex, X_INFO, "ATOM BIOS Rom: \n"); if (!rhdAtomAnalyzeRomHdr(base, atom_rom_hdr, &data_offset, cmd_offset)) { xf86DrvMsg(scrnIndex, X_ERROR, "RomHeader invalid\n"); return FALSE; } if (data_offset + sizeof (ATOM_MASTER_DATA_TABLE) > BIOSImageSize) { xf86DrvMsg(scrnIndex,X_ERROR,"%s: Atom data table outside of BIOS\n", __func__); } if (*cmd_offset + sizeof (ATOM_MASTER_COMMAND_TABLE) > BIOSImageSize) { xf86DrvMsg(scrnIndex,X_ERROR,"%s: Atom command table outside of BIOS\n", __func__); } if (!rhdAtomAnalyzeMasterDataTable(base, (ATOM_MASTER_DATA_TABLE *) (base + data_offset), atomDataPtr)) { xf86DrvMsg(scrnIndex, X_ERROR, "%s: ROM Master Table invalid\n", __func__); return FALSE; } return TRUE; } static Bool rhdAtomGetFbBaseAndSize(atomBiosHandlePtr handle, unsigned int *base, unsigned int *size) { AtomBiosArgRec data; if (RHDAtomBiosFunc(handle->scrnIndex, handle, GET_FW_FB_SIZE, &data) == ATOM_SUCCESS) { if (data.val == 0) { xf86DrvMsg(handle->scrnIndex, X_WARNING, "%s: AtomBIOS specified VRAM " "scratch space size invalid\n", __func__); return FALSE; } if (size) *size = (int)data.val; } else return FALSE; if (RHDAtomBiosFunc(handle->scrnIndex, handle, GET_FW_FB_START, &data) == ATOM_SUCCESS) { if (data.val == 0) return FALSE; if (base) *base = (int)data.val; } return TRUE; } /* * Uses videoRam form ScrnInfoRec. */ static AtomBiosResult rhdAtomAllocateFbScratch(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { unsigned int fb_base = 0; unsigned int fb_size = 0; unsigned int start = data->fb.start; unsigned int size = data->fb.size; handle->scratchBase = NULL; handle->fbBase = 0; if (rhdAtomGetFbBaseAndSize(handle, &fb_base, &fb_size)) { xf86DrvMsg(handle->scrnIndex, X_INFO, "AtomBIOS requests %ikB" " of VRAM scratch space\n",fb_size); fb_size *= 1024; /* convert to bytes */ xf86DrvMsg(handle->scrnIndex, X_INFO, "AtomBIOS VRAM scratch base: 0x%x\n", fb_base); } else { fb_size = 20 * 1024; xf86DrvMsg(handle->scrnIndex, X_INFO, " default to: %i\n",fb_size); } if (fb_base && fb_size && size) { /* 4k align */ fb_size = (fb_size & ~(CARD32)0xfff) + ((fb_size & 0xfff) ? 1 : 0); if ((fb_base + fb_size) > (start + size)) { xf86DrvMsg(handle->scrnIndex, X_WARNING, "%s: FW FB scratch area %i (size: %i)" " extends beyond available framebuffer size %i\n", __func__, fb_base, fb_size, size); } else if ((fb_base + fb_size) < (start + size)) { xf86DrvMsg(handle->scrnIndex, X_WARNING, "%s: FW FB scratch area not located " "at the end of VRAM. Scratch End: " "0x%x VRAM End: 0x%x\n", __func__, (unsigned int)(fb_base + fb_size), size); } else if (fb_base < start) { xf86DrvMsg(handle->scrnIndex, X_WARNING, "%s: FW FB scratch area extends below " "the base of the free VRAM: 0x%x Base: 0x%x\n", __func__, (unsigned int)(fb_base), start); } else { size -= fb_size; handle->fbBase = fb_base; return ATOM_SUCCESS; } } if (!handle->fbBase) { xf86DrvMsg(handle->scrnIndex, X_INFO, "Cannot get VRAM scratch space. " "Allocating in main memory instead\n"); handle->scratchBase = xcalloc(fb_size,1); return ATOM_SUCCESS; } return ATOM_FAILED; } # ifdef ATOM_BIOS_PARSER static Bool rhdAtomASICInit(atomBiosHandlePtr handle) { ASIC_INIT_PS_ALLOCATION asicInit; AtomBiosArgRec data; RHDAtomBiosFunc(handle->scrnIndex, handle, GET_DEFAULT_ENGINE_CLOCK, &data); asicInit.sASICInitClocks.ulDefaultEngineClock = data.val / 10;/*in 10 Khz*/ RHDAtomBiosFunc(handle->scrnIndex, handle, GET_DEFAULT_MEMORY_CLOCK, &data); asicInit.sASICInitClocks.ulDefaultMemoryClock = data.val / 10;/*in 10 Khz*/ data.exec.dataSpace = NULL; data.exec.index = 0x0; data.exec.pspace = &asicInit; xf86DrvMsg(handle->scrnIndex, X_INFO, "Calling ASIC Init\n"); if (RHDAtomBiosFunc(handle->scrnIndex, handle, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { xf86DrvMsg(handle->scrnIndex, X_INFO, "ASIC_INIT Successful\n"); return TRUE; } xf86DrvMsg(handle->scrnIndex, X_INFO, "ASIC_INIT Failed\n"); return FALSE; } Bool rhdAtomSetScaler(atomBiosHandlePtr handle, unsigned char scalerID, int setting) { ENABLE_SCALER_PARAMETERS scaler; AtomBiosArgRec data; scaler.ucScaler = scalerID; scaler.ucEnable = setting; data.exec.dataSpace = NULL; data.exec.index = 0x21; data.exec.pspace = &scaler; xf86DrvMsg(handle->scrnIndex, X_INFO, "Calling EnableScaler\n"); if (RHDAtomBiosFunc(handle->scrnIndex, handle, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { xf86DrvMsg(handle->scrnIndex, X_INFO, "EnableScaler Successful\n"); return TRUE; } xf86DrvMsg(handle->scrnIndex, X_INFO, "EableScaler Failed\n"); return FALSE; } # endif static AtomBiosResult rhdAtomInit(atomBiosHandlePtr unused1, AtomBiosRequestID unused2, AtomBiosArgPtr data) { int scrnIndex = data->val; RADEONInfoPtr info = RADEONPTR(xf86Screens[scrnIndex]); unsigned char *ptr; atomDataTablesPtr atomDataPtr; unsigned int cmd_offset; atomBiosHandlePtr handle = NULL; unsigned int BIOSImageSize = 0; data->atomhandle = NULL; //RHDFUNCI(scrnIndex); /*if (info->BIOSCopy) { xf86DrvMsg(scrnIndex,X_INFO,"Getting BIOS copy from INT10\n"); ptr = info->BIOSCopy; info->BIOSCopy = NULL; BIOSImageSize = ptr[2] * 512; if (BIOSImageSize > legacyBIOSMax) { xf86DrvMsg(scrnIndex,X_ERROR,"Invalid BIOS length field\n"); return ATOM_FAILED; } } else*/ { /*if (!xf86IsEntityPrimary(info->entityIndex)) { if (!(BIOSImageSize = RHDReadPCIBios(info, &ptr))) return ATOM_FAILED; } else*/ { int read_len; unsigned char tmp[32]; xf86DrvMsg(scrnIndex,X_INFO,"Getting BIOS copy from legacy VBIOS location\n"); if (xf86ReadBIOS(legacyBIOSLocation, 0, tmp, 32) < 0) { xf86DrvMsg(scrnIndex,X_ERROR, "Cannot obtain POSTed BIOS header\n"); return ATOM_FAILED; } BIOSImageSize = tmp[2] * 512; if (BIOSImageSize > legacyBIOSMax) { xf86DrvMsg(scrnIndex,X_ERROR,"Invalid BIOS length field\n"); return ATOM_FAILED; } if (!(ptr = xcalloc(1,BIOSImageSize))) { xf86DrvMsg(scrnIndex,X_ERROR, "Cannot allocate %i bytes of memory " "for BIOS image\n",BIOSImageSize); return ATOM_FAILED; } if ((read_len = xf86ReadBIOS(legacyBIOSLocation, 0, ptr, BIOSImageSize) < 0)) { xf86DrvMsg(scrnIndex,X_ERROR,"Cannot read POSTed BIOS\n"); goto error; } } } if (!(atomDataPtr = xcalloc(1, sizeof(atomDataTables)))) { xf86DrvMsg(scrnIndex,X_ERROR,"Cannot allocate memory for " "ATOM BIOS data tabes\n"); goto error; } if (!rhdAtomGetDataTable(scrnIndex, ptr, atomDataPtr, &cmd_offset, BIOSImageSize)) goto error1; if (!(handle = xcalloc(1, sizeof(atomBiosHandleRec)))) { xf86DrvMsg(scrnIndex,X_ERROR,"Cannot allocate memory\n"); goto error1; } handle->BIOSBase = ptr; handle->atomDataPtr = atomDataPtr; handle->cmd_offset = cmd_offset; handle->scrnIndex = scrnIndex; #if XSERVER_LIBPCIACCESS handle->device = info->PciInfo; #else handle->PciTag = info->PciTag; #endif handle->BIOSImageSize = BIOSImageSize; # if ATOM_BIOS_PARSER /* Try to find out if BIOS has been posted (either by system or int10 */ if (!rhdAtomGetFbBaseAndSize(handle, NULL, NULL)) { /* run AsicInit */ if (!rhdAtomASICInit(handle)) xf86DrvMsg(scrnIndex, X_WARNING, "%s: AsicInit failed. Won't be able to obtain in VRAM " "FB scratch space\n",__func__); } # endif data->atomhandle = handle; return ATOM_SUCCESS; error1: xfree(atomDataPtr); error: xfree(ptr); return ATOM_FAILED; } static AtomBiosResult rhdAtomTearDown(atomBiosHandlePtr handle, AtomBiosRequestID unused1, AtomBiosArgPtr unused2) { //RHDFUNC(handle); xfree(handle->BIOSBase); xfree(handle->atomDataPtr); if (handle->scratchBase) xfree(handle->scratchBase); xfree(handle); return ATOM_SUCCESS; } static AtomBiosResult rhdAtomVramInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD32 *val = &data->val; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; switch (func) { case GET_FW_FB_START: *val = atomDataPtr->VRAM_UsageByFirmware ->asFirmwareVramReserveInfo[0].ulStartAddrUsedByFirmware; break; case GET_FW_FB_SIZE: *val = atomDataPtr->VRAM_UsageByFirmware ->asFirmwareVramReserveInfo[0].usFirmwareUseInKb; break; default: return ATOM_NOT_IMPLEMENTED; } return ATOM_SUCCESS; } static AtomBiosResult rhdAtomTmdsInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD32 *val = &data->val; int idx = *val; atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->TMDS_Info), NULL,NULL,NULL)) { return ATOM_FAILED; } //RHDFUNC(handle); switch (func) { case ATOM_TMDS_FREQUENCY: *val = atomDataPtr->TMDS_Info->asMiscInfo[idx].usFrequency; break; case ATOM_TMDS_PLL_CHARGE_PUMP: *val = atomDataPtr->TMDS_Info->asMiscInfo[idx].ucPLL_ChargePump; break; case ATOM_TMDS_PLL_DUTY_CYCLE: *val = atomDataPtr->TMDS_Info->asMiscInfo[idx].ucPLL_DutyCycle; break; case ATOM_TMDS_PLL_VCO_GAIN: *val = atomDataPtr->TMDS_Info->asMiscInfo[idx].ucPLL_VCO_Gain; break; case ATOM_TMDS_PLL_VOLTAGE_SWING: *val = atomDataPtr->TMDS_Info->asMiscInfo[idx].ucPLL_VoltageSwing; break; default: return ATOM_NOT_IMPLEMENTED; } return ATOM_SUCCESS; } static DisplayModePtr rhdAtomDTDTimings(atomBiosHandlePtr handle, ATOM_DTD_FORMAT *dtd) { DisplayModePtr mode; #define NAME_LEN 16 char name[NAME_LEN]; //RHDFUNC(handle); if (!dtd->usHActive || !dtd->usVActive) return NULL; if (!(mode = (DisplayModePtr)xcalloc(1,sizeof(DisplayModeRec)))) return NULL; mode->CrtcHDisplay = mode->HDisplay = dtd->usHActive; mode->CrtcVDisplay = mode->VDisplay = dtd->usVActive; mode->CrtcHBlankStart = dtd->usHActive + dtd->ucHBorder; mode->CrtcHBlankEnd = mode->CrtcHBlankStart + dtd->usHBlanking_Time; mode->CrtcHTotal = mode->HTotal = mode->CrtcHBlankEnd + dtd->ucHBorder; mode->CrtcVBlankStart = dtd->usVActive + dtd->ucVBorder; mode->CrtcVBlankEnd = mode->CrtcVBlankStart + dtd->usVBlanking_Time; mode->CrtcVTotal = mode->VTotal = mode->CrtcVBlankEnd + dtd->ucVBorder; mode->CrtcHSyncStart = mode->HSyncStart = dtd->usHActive + dtd->usHSyncOffset; mode->CrtcHSyncEnd = mode->HSyncEnd = mode->HSyncStart + dtd->usHSyncWidth; mode->CrtcVSyncStart = mode->VSyncStart = dtd->usVActive + dtd->usVSyncOffset; mode->CrtcVSyncEnd = mode->VSyncEnd = mode->VSyncStart + dtd->usVSyncWidth; mode->SynthClock = mode->Clock = dtd->usPixClk * 10; mode->HSync = ((float) mode->Clock) / ((float)mode->HTotal); mode->VRefresh = (1000.0 * ((float) mode->Clock)) / ((float)(((float)mode->HTotal) * ((float)mode->VTotal))); if (dtd->susModeMiscInfo.sbfAccess.CompositeSync) mode->Flags |= V_CSYNC; if (dtd->susModeMiscInfo.sbfAccess.Interlace) mode->Flags |= V_INTERLACE; if (dtd->susModeMiscInfo.sbfAccess.DoubleClock) mode->Flags |= V_DBLSCAN; if (dtd->susModeMiscInfo.sbfAccess.VSyncPolarity) mode->Flags |= V_NVSYNC; if (dtd->susModeMiscInfo.sbfAccess.HSyncPolarity) mode->Flags |= V_NHSYNC; snprintf(name, NAME_LEN, "%dx%d", mode->HDisplay, mode->VDisplay); mode->name = xstrdup(name); ErrorF("DTD Modeline: %s " "%2.d %i (%i) %i %i (%i) %i %i (%i) %i %i (%i) %i flags: 0x%x\n", mode->name, mode->Clock, mode->HDisplay, mode->CrtcHBlankStart, mode->HSyncStart, mode->CrtcHSyncEnd, mode->CrtcHBlankEnd, mode->HTotal, mode->VDisplay, mode->CrtcVBlankStart, mode->VSyncStart, mode->VSyncEnd, mode->CrtcVBlankEnd, mode->VTotal, mode->Flags); return mode; } static unsigned char* rhdAtomLvdsDDC(atomBiosHandlePtr handle, CARD32 offset, unsigned char *record) { unsigned char *EDIDBlock; //RHDFUNC(handle); while (*record != ATOM_RECORD_END_TYPE) { switch (*record) { case LCD_MODE_PATCH_RECORD_MODE_TYPE: offset += sizeof(ATOM_PATCH_RECORD_MODE); if (offset > handle->BIOSImageSize) break; record += sizeof(ATOM_PATCH_RECORD_MODE); break; case LCD_RTS_RECORD_TYPE: offset += sizeof(ATOM_LCD_RTS_RECORD); if (offset > handle->BIOSImageSize) break; record += sizeof(ATOM_LCD_RTS_RECORD); break; case LCD_CAP_RECORD_TYPE: offset += sizeof(ATOM_LCD_MODE_CONTROL_CAP); if (offset > handle->BIOSImageSize) break; record += sizeof(ATOM_LCD_MODE_CONTROL_CAP); break; case LCD_FAKE_EDID_PATCH_RECORD_TYPE: offset += sizeof(ATOM_FAKE_EDID_PATCH_RECORD); /* check if the structure still fully lives in the BIOS image */ if (offset > handle->BIOSImageSize) break; offset += ((ATOM_FAKE_EDID_PATCH_RECORD*)record)->ucFakeEDIDLength - sizeof(UCHAR); if (offset > handle->BIOSImageSize) break; /* dup string as we free it later */ if (!(EDIDBlock = (unsigned char *)xalloc( ((ATOM_FAKE_EDID_PATCH_RECORD*)record)->ucFakeEDIDLength))) return NULL; memcpy(EDIDBlock,&((ATOM_FAKE_EDID_PATCH_RECORD*)record)->ucFakeEDIDString, ((ATOM_FAKE_EDID_PATCH_RECORD*)record)->ucFakeEDIDLength); /* for testing */ { xf86MonPtr mon = xf86InterpretEDID(handle->scrnIndex,EDIDBlock); xf86PrintEDID(mon); xfree(mon); } return EDIDBlock; case LCD_PANEL_RESOLUTION_RECORD_TYPE: offset += sizeof(ATOM_PANEL_RESOLUTION_PATCH_RECORD); if (offset > handle->BIOSImageSize) break; record += sizeof(ATOM_PANEL_RESOLUTION_PATCH_RECORD); break; default: xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: unknown record type: %x\n",__func__,*record); return NULL; } } return NULL; } static AtomBiosResult rhdAtomCVGetTimings(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; DisplayModePtr last = NULL; DisplayModePtr new = NULL; DisplayModePtr first = NULL; int i; data->modes = NULL; atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->ComponentVideoInfo.base), &frev,&crev,NULL)) { return ATOM_FAILED; } switch (frev) { case 1: switch (func) { case ATOMBIOS_GET_CV_MODES: for (i = 0; i < MAX_SUPPORTED_CV_STANDARDS; i++) { new = rhdAtomDTDTimings(handle, &atomDataPtr->ComponentVideoInfo .ComponentVideoInfo->aModeTimings[i]); if (!new) continue; new->type |= M_T_DRIVER; new->next = NULL; new->prev = last; if (last) last->next = new; last = new; if (!first) first = new; } if (last) { last->next = NULL; //first; first->prev = NULL; //last; data->modes = first; } if (data->modes) return ATOM_SUCCESS; default: return ATOM_FAILED; } case 2: switch (func) { case ATOMBIOS_GET_CV_MODES: for (i = 0; i < MAX_SUPPORTED_CV_STANDARDS; i++) { new = rhdAtomDTDTimings(handle, &atomDataPtr->ComponentVideoInfo .ComponentVideoInfo_v21->aModeTimings[i]); if (!new) continue; new->type |= M_T_DRIVER; new->next = NULL; new->prev = last; if (last) last->next = new; last = new; if (!first) first = new; } if (last) { last->next = NULL; //first; first->prev = NULL; //last; data->modes = first; } if (data->modes) return ATOM_SUCCESS; return ATOM_FAILED; default: return ATOM_FAILED; } default: return ATOM_NOT_IMPLEMENTED; } /*NOTREACHED*/ } static AtomBiosResult rhdAtomLvdsGetTimings(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; unsigned long offset; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->LVDS_Info.base), &frev,&crev,NULL)) { return ATOM_FAILED; } switch (crev) { case 1: switch (func) { case ATOMBIOS_GET_PANEL_MODE: data->modes = rhdAtomDTDTimings(handle, &atomDataPtr->LVDS_Info .LVDS_Info->sLCDTiming); if (data->modes) return ATOM_SUCCESS; default: return ATOM_FAILED; } case 2: switch (func) { case ATOMBIOS_GET_PANEL_MODE: data->modes = rhdAtomDTDTimings(handle, &atomDataPtr->LVDS_Info .LVDS_Info_v12->sLCDTiming); if (data->modes) return ATOM_SUCCESS; return ATOM_FAILED; case ATOMBIOS_GET_PANEL_EDID: offset = (unsigned long)&atomDataPtr->LVDS_Info.base - (unsigned long)handle->BIOSBase + atomDataPtr->LVDS_Info .LVDS_Info_v12->usExtInfoTableOffset; data->EDIDBlock = rhdAtomLvdsDDC(handle, offset, (unsigned char *) &atomDataPtr->LVDS_Info.base + atomDataPtr->LVDS_Info .LVDS_Info_v12->usExtInfoTableOffset); if (data->EDIDBlock) return ATOM_SUCCESS; default: return ATOM_FAILED; } default: return ATOM_NOT_IMPLEMENTED; } /*NOTREACHED*/ } static AtomBiosResult rhdAtomLvdsInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; CARD32 *val = &data->val; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->LVDS_Info.base), &frev,&crev,NULL)) { return ATOM_FAILED; } switch (crev) { case 1: switch (func) { case ATOM_LVDS_SUPPORTED_REFRESH_RATE: *val = atomDataPtr->LVDS_Info .LVDS_Info->usSupportedRefreshRate; break; case ATOM_LVDS_OFF_DELAY: *val = atomDataPtr->LVDS_Info .LVDS_Info->usOffDelayInMs; break; case ATOM_LVDS_SEQ_DIG_ONTO_DE: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucPowerSequenceDigOntoDEin10Ms * 10; break; case ATOM_LVDS_SEQ_DE_TO_BL: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucPowerSequenceDEtoBLOnin10Ms * 10; break; case ATOM_LVDS_DITHER: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucLVDS_Misc & 0x40; break; case ATOM_LVDS_DUALLINK: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucLVDS_Misc & 0x01; break; case ATOM_LVDS_24BIT: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucLVDS_Misc & 0x02; break; case ATOM_LVDS_GREYLVL: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucLVDS_Misc & 0x0C; break; case ATOM_LVDS_FPDI: *val = atomDataPtr->LVDS_Info .LVDS_Info->ucLVDS_Misc * 0x10; break; default: return ATOM_NOT_IMPLEMENTED; } break; case 2: switch (func) { case ATOM_LVDS_SUPPORTED_REFRESH_RATE: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->usSupportedRefreshRate; break; case ATOM_LVDS_OFF_DELAY: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->usOffDelayInMs; break; case ATOM_LVDS_SEQ_DIG_ONTO_DE: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucPowerSequenceDigOntoDEin10Ms * 10; break; case ATOM_LVDS_SEQ_DE_TO_BL: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucPowerSequenceDEtoBLOnin10Ms * 10; break; case ATOM_LVDS_DITHER: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucLVDS_Misc & 0x40; break; case ATOM_LVDS_DUALLINK: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucLVDS_Misc & 0x01; break; case ATOM_LVDS_24BIT: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucLVDS_Misc & 0x02; break; case ATOM_LVDS_GREYLVL: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucLVDS_Misc & 0x0C; break; case ATOM_LVDS_FPDI: *val = atomDataPtr->LVDS_Info .LVDS_Info_v12->ucLVDS_Misc * 0x10; break; default: return ATOM_NOT_IMPLEMENTED; } break; default: return ATOM_NOT_IMPLEMENTED; } return ATOM_SUCCESS; } static AtomBiosResult rhdAtomCompassionateDataQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; CARD32 *val = &data->val; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->CompassionateData), &frev,&crev,NULL)) { return ATOM_FAILED; } switch (func) { case ATOM_DAC1_BG_ADJ: *val = atomDataPtr->CompassionateData-> ucDAC1_BG_Adjustment; break; case ATOM_DAC1_DAC_ADJ: *val = atomDataPtr->CompassionateData-> ucDAC1_DAC_Adjustment; break; case ATOM_DAC1_FORCE: *val = atomDataPtr->CompassionateData-> usDAC1_FORCE_Data; break; case ATOM_DAC2_CRTC2_BG_ADJ: *val = atomDataPtr->CompassionateData-> ucDAC2_CRT2_BG_Adjustment; break; case ATOM_DAC2_CRTC2_DAC_ADJ: *val = atomDataPtr->CompassionateData-> ucDAC2_CRT2_DAC_Adjustment; break; case ATOM_DAC2_CRTC2_FORCE: *val = atomDataPtr->CompassionateData-> usDAC2_CRT2_FORCE_Data; break; case ATOM_DAC2_CRTC2_MUX_REG_IND: *val = atomDataPtr->CompassionateData-> usDAC2_CRT2_MUX_RegisterIndex; break; case ATOM_DAC2_CRTC2_MUX_REG_INFO: *val = atomDataPtr->CompassionateData-> ucDAC2_CRT2_MUX_RegisterInfo; break; default: return ATOM_NOT_IMPLEMENTED; } return ATOM_SUCCESS; } static AtomBiosResult rhdAtomGPIOI2CInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; CARD32 *val = &data->val; unsigned short size; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->GPIO_I2C_Info), &frev,&crev,&size)) { return ATOM_FAILED; } switch (func) { case ATOM_GPIO_I2C_CLK_MASK: if ((sizeof(ATOM_COMMON_TABLE_HEADER) + (*val * sizeof(ATOM_GPIO_I2C_ASSIGMENT))) > size) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: GPIO_I2C Device " "num %lu exeeds table size %u\n",__func__, (unsigned long)val, size); return ATOM_FAILED; } *val = atomDataPtr->GPIO_I2C_Info->asGPIO_Info[*val] .usClkMaskRegisterIndex; break; default: return ATOM_NOT_IMPLEMENTED; } return ATOM_SUCCESS; } static AtomBiosResult rhdAtomFirmwareInfoQuery(atomBiosHandlePtr handle, AtomBiosRequestID func, AtomBiosArgPtr data) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; CARD32 *val = &data->val; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( (ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->FirmwareInfo.base), &crev,&frev,NULL)) { return ATOM_FAILED; } switch (crev) { case 1: switch (func) { case GET_DEFAULT_ENGINE_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->ulDefaultEngineClock * 10; break; case GET_DEFAULT_MEMORY_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->ulDefaultMemoryClock * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->ulMaxPixelClockPLL_Output * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->usMinPixelClockPLL_Output * 10; case GET_MAX_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->usMaxPixelClockPLL_Input * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->usMinPixelClockPLL_Input * 10; break; case GET_MAX_PIXEL_CLK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->usMaxPixelClock * 10; break; case GET_REF_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo->usReferenceClock * 10; break; default: return ATOM_NOT_IMPLEMENTED; } case 2: switch (func) { case GET_DEFAULT_ENGINE_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->ulDefaultEngineClock * 10; break; case GET_DEFAULT_MEMORY_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->ulDefaultMemoryClock * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->ulMaxPixelClockPLL_Output * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->usMinPixelClockPLL_Output * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->usMaxPixelClockPLL_Input * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->usMinPixelClockPLL_Input * 10; break; case GET_MAX_PIXEL_CLK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->usMaxPixelClock * 10; break; case GET_REF_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_2->usReferenceClock * 10; break; default: return ATOM_NOT_IMPLEMENTED; } break; case 3: switch (func) { case GET_DEFAULT_ENGINE_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->ulDefaultEngineClock * 10; break; case GET_DEFAULT_MEMORY_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->ulDefaultMemoryClock * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->ulMaxPixelClockPLL_Output * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->usMinPixelClockPLL_Output * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->usMaxPixelClockPLL_Input * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->usMinPixelClockPLL_Input * 10; break; case GET_MAX_PIXEL_CLK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->usMaxPixelClock * 10; break; case GET_REF_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_3->usReferenceClock * 10; break; default: return ATOM_NOT_IMPLEMENTED; } break; case 4: switch (func) { case GET_DEFAULT_ENGINE_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->ulDefaultEngineClock * 10; break; case GET_DEFAULT_MEMORY_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->ulDefaultMemoryClock * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->usMaxPixelClockPLL_Input * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_INPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->usMinPixelClockPLL_Input * 10; break; case GET_MAX_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->ulMaxPixelClockPLL_Output * 10; break; case GET_MIN_PIXEL_CLOCK_PLL_OUTPUT: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->usMinPixelClockPLL_Output * 10; break; case GET_MAX_PIXEL_CLK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->usMaxPixelClock * 10; break; case GET_REF_CLOCK: *val = atomDataPtr->FirmwareInfo .FirmwareInfo_V_1_4->usReferenceClock * 10; break; default: return ATOM_NOT_IMPLEMENTED; } break; default: return ATOM_NOT_IMPLEMENTED; } return ATOM_SUCCESS; } const int object_connector_convert[] = { CONNECTOR_NONE, CONNECTOR_DVI_I, CONNECTOR_DVI_I, CONNECTOR_DVI_D, CONNECTOR_DVI_D, CONNECTOR_VGA, CONNECTOR_CTV, CONNECTOR_STV, CONNECTOR_NONE, CONNECTOR_DIN, CONNECTOR_SCART, CONNECTOR_HDMI_TYPE_A, CONNECTOR_HDMI_TYPE_B, CONNECTOR_HDMI_TYPE_B, CONNECTOR_LVDS, CONNECTOR_DIN, CONNECTOR_NONE, CONNECTOR_NONE, CONNECTOR_NONE, CONNECTOR_NONE, }; static void rhdAtomParseI2CRecord(atomBiosHandlePtr handle, ATOM_I2C_RECORD *Record, CARD32 *ddc_line) { ErrorF(" %s: I2C Record: %s[%x] EngineID: %x I2CAddr: %x\n", __func__, Record->sucI2cId.bfHW_Capable ? "HW_Line" : "GPIO_ID", Record->sucI2cId.bfI2C_LineMux, Record->sucI2cId.bfHW_EngineID, Record->ucI2CAddr); if (!*(unsigned char *)&(Record->sucI2cId)) *ddc_line = 0; else { if (Record->ucI2CAddr != 0) return; if (Record->sucI2cId.bfHW_Capable) { switch(Record->sucI2cId.bfI2C_LineMux) { case 0: *ddc_line = 0x7e40; break; case 1: *ddc_line = 0x7e50; break; case 2: *ddc_line = 0x7e30; break; default: break; } return; } else { /* add GPIO pin parsing */ } } } static CARD32 RADEONLookupGPIOLineForDDC(ScrnInfoPtr pScrn, CARD8 id) { RADEONInfoPtr info = RADEONPTR (pScrn); atomDataTablesPtr atomDataPtr; ATOM_GPIO_I2C_ASSIGMENT gpio; CARD32 ret = 0; CARD8 crev, frev; atomDataPtr = info->atomBIOS->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( &(atomDataPtr->GPIO_I2C_Info->sHeader), &crev,&frev,NULL)) { xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "No GPIO Info Table found!\n"); return ret; } /* note clk and data regs can be different! * gpio.usClkMaskRegisterIndex and gpio.usDataMaskRegisterIndex */ gpio = atomDataPtr->GPIO_I2C_Info->asGPIO_Info[id]; ret = gpio.usClkMaskRegisterIndex * 4; return ret; } Bool RADEONGetATOMConnectorInfoFromBIOSObject (ScrnInfoPtr pScrn) { RADEONInfoPtr info = RADEONPTR (pScrn); CARD8 crev, frev; unsigned short size; atomDataTablesPtr atomDataPtr; ATOM_CONNECTOR_OBJECT_TABLE *con_obj; int i, j; atomDataPtr = info->atomBIOS->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize((ATOM_COMMON_TABLE_HEADER *)(atomDataPtr->Object_Header), &crev, &frev, &size)) return FALSE; if (crev < 2) return FALSE; con_obj = (ATOM_CONNECTOR_OBJECT_TABLE *) ((char *)&atomDataPtr->Object_Header->sHeader + atomDataPtr->Object_Header->usConnectorObjectTableOffset); for (i = 0; i < con_obj->ucNumberOfObjects; i++) { ATOM_SRC_DST_TABLE_FOR_ONE_OBJECT *SrcDstTable; ATOM_COMMON_RECORD_HEADER *Record; CARD8 obj_id, num, obj_type; int record_base; obj_id = (con_obj->asObjects[i].usObjectID & OBJECT_ID_MASK) >> OBJECT_ID_SHIFT; num = (con_obj->asObjects[i].usObjectID & ENUM_ID_MASK) >> ENUM_ID_SHIFT; obj_type = (con_obj->asObjects[i].usObjectID & OBJECT_TYPE_MASK) >> OBJECT_TYPE_SHIFT; if (obj_type != GRAPH_OBJECT_TYPE_CONNECTOR) continue; SrcDstTable = (ATOM_SRC_DST_TABLE_FOR_ONE_OBJECT *) ((char *)&atomDataPtr->Object_Header->sHeader + con_obj->asObjects[i].usSrcDstTableOffset); ErrorF("object id %04x %02x\n", obj_id, SrcDstTable->ucNumberOfSrc); info->BiosConnector[i].ConnectorType = object_connector_convert[obj_id]; info->BiosConnector[i].valid = TRUE; info->BiosConnector[i].devices = 0; for (j = 0; j < SrcDstTable->ucNumberOfSrc; j++) { CARD8 sobj_id; sobj_id = (SrcDstTable->usSrcObjectID[j] & OBJECT_ID_MASK) >> OBJECT_ID_SHIFT; ErrorF("src object id %04x %d\n", SrcDstTable->usSrcObjectID[j], sobj_id); switch(sobj_id) { case ENCODER_OBJECT_ID_INTERNAL_LVDS: info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_LCD1_INDEX); break; case ENCODER_OBJECT_ID_INTERNAL_TMDS1: info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_DFP1_INDEX); info->BiosConnector[i].TMDSType = TMDS_INT; break; case ENCODER_OBJECT_ID_INTERNAL_TMDS2: info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_DFP2_INDEX); info->BiosConnector[i].TMDSType = TMDS_EXT; break; case ENCODER_OBJECT_ID_INTERNAL_LVTM1: info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_DFP3_INDEX); info->BiosConnector[i].TMDSType = TMDS_EXT; break; case ENCODER_OBJECT_ID_INTERNAL_DAC1: case ENCODER_OBJECT_ID_INTERNAL_KLDSCP_DAC1: info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_CRT1_INDEX); info->BiosConnector[i].DACType = DAC_PRIMARY; break; case ENCODER_OBJECT_ID_INTERNAL_DAC2: case ENCODER_OBJECT_ID_INTERNAL_KLDSCP_DAC2: if (info->BiosConnector[i].ConnectorType == CONNECTOR_DIN || info->BiosConnector[i].ConnectorType == CONNECTOR_STV || info->BiosConnector[i].ConnectorType == CONNECTOR_CTV) info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_TV1_INDEX); else info->BiosConnector[i].devices |= (1 << ATOM_DEVICE_CRT2_INDEX); info->BiosConnector[i].DACType = DAC_TVDAC; break; } } Record = (ATOM_COMMON_RECORD_HEADER *) ((char *)&atomDataPtr->Object_Header->sHeader + con_obj->asObjects[i].usRecordOffset); record_base = con_obj->asObjects[i].usRecordOffset; while (Record->ucRecordType > 0 && Record->ucRecordType <= ATOM_MAX_OBJECT_RECORD_NUMBER ) { ErrorF("record type %d\n", Record->ucRecordType); switch (Record->ucRecordType) { case ATOM_I2C_RECORD_TYPE: rhdAtomParseI2CRecord(info->atomBIOS, (ATOM_I2C_RECORD *)Record, &info->BiosConnector[i].ddc_line); break; case ATOM_HPD_INT_RECORD_TYPE: break; case ATOM_CONNECTOR_DEVICE_TAG_RECORD_TYPE: break; } Record = (ATOM_COMMON_RECORD_HEADER*) ((char *)Record + Record->ucRecordSize); } } return TRUE; } Bool RADEONGetATOMTVInfo(xf86OutputPtr output) { ScrnInfoPtr pScrn = output->scrn; RADEONInfoPtr info = RADEONPTR(pScrn); RADEONOutputPrivatePtr radeon_output = output->driver_private; ATOM_ANALOG_TV_INFO *tv_info; tv_info = info->atomBIOS->atomDataPtr->AnalogTV_Info; if (!tv_info) return FALSE; switch(tv_info->ucTV_BootUpDefaultStandard) { case NTSC_SUPPORT: radeon_output->default_tvStd = TV_STD_NTSC; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Default TV standard: NTSC\n"); break; case NTSCJ_SUPPORT: radeon_output->default_tvStd = TV_STD_NTSC_J; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Default TV standard: NTSC-J\n"); break; case PAL_SUPPORT: radeon_output->default_tvStd = TV_STD_PAL; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Default TV standard: PAL\n"); break; case PALM_SUPPORT: radeon_output->default_tvStd = TV_STD_PAL_M; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Default TV standard: PAL-M\n"); break; case PAL60_SUPPORT: radeon_output->default_tvStd = TV_STD_PAL_60; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Default TV standard: PAL-60\n"); break; } radeon_output->tvStd = radeon_output->default_tvStd; xf86DrvMsg(pScrn->scrnIndex, X_INFO, "TV standards supported by chip: "); radeon_output->SupportedTVStds = radeon_output->default_tvStd; if (tv_info->ucTV_SupportedStandard & NTSC_SUPPORT) { ErrorF("NTSC "); radeon_output->SupportedTVStds |= TV_STD_NTSC; } if (tv_info->ucTV_SupportedStandard & NTSCJ_SUPPORT) { ErrorF("NTSC-J "); radeon_output->SupportedTVStds |= TV_STD_NTSC_J; } if (tv_info->ucTV_SupportedStandard & PAL_SUPPORT) { ErrorF("PAL "); radeon_output->SupportedTVStds |= TV_STD_PAL; } if (tv_info->ucTV_SupportedStandard & PALM_SUPPORT) { ErrorF("PAL-M "); radeon_output->SupportedTVStds |= TV_STD_PAL_M; } if (tv_info->ucTV_SupportedStandard & PAL60_SUPPORT) { ErrorF("PAL-60 "); radeon_output->SupportedTVStds |= TV_STD_PAL_60; } ErrorF("\n"); if (tv_info->ucExt_TV_ASIC_ID) { xf86DrvMsg(pScrn->scrnIndex, X_ERROR, "Unknown external TV ASIC\n"); return FALSE; } return TRUE; } Bool RADEONATOMGetTVTimings(ScrnInfoPtr pScrn, int index, SET_CRTC_TIMING_PARAMETERS_PS_ALLOCATION *crtc_timing, int32_t *pixel_clock) { RADEONInfoPtr info = RADEONPTR(pScrn); ATOM_ANALOG_TV_INFO *tv_info; tv_info = info->atomBIOS->atomDataPtr->AnalogTV_Info; if (index > MAX_SUPPORTED_TV_TIMING) return FALSE; crtc_timing->usH_Total = tv_info->aModeTimings[index].usCRTC_H_Total; crtc_timing->usH_Disp = tv_info->aModeTimings[index].usCRTC_H_Disp; crtc_timing->usH_SyncStart = tv_info->aModeTimings[index].usCRTC_H_SyncStart; crtc_timing->usH_SyncWidth = tv_info->aModeTimings[index].usCRTC_H_SyncWidth; crtc_timing->usV_Total = tv_info->aModeTimings[index].usCRTC_V_Total; crtc_timing->usV_Disp = tv_info->aModeTimings[index].usCRTC_V_Disp; crtc_timing->usV_SyncStart = tv_info->aModeTimings[index].usCRTC_V_SyncStart; crtc_timing->usV_SyncWidth = tv_info->aModeTimings[index].usCRTC_V_SyncWidth; crtc_timing->susModeMiscInfo = tv_info->aModeTimings[index].susModeMiscInfo; crtc_timing->ucOverscanRight = tv_info->aModeTimings[index].usCRTC_OverscanRight; crtc_timing->ucOverscanLeft = tv_info->aModeTimings[index].usCRTC_OverscanLeft; crtc_timing->ucOverscanBottom = tv_info->aModeTimings[index].usCRTC_OverscanBottom; crtc_timing->ucOverscanTop = tv_info->aModeTimings[index].usCRTC_OverscanTop; *pixel_clock = tv_info->aModeTimings[index].usPixelClock * 10; return TRUE; } Bool RADEONGetATOMConnectorInfoFromBIOSConnectorTable (ScrnInfoPtr pScrn) { RADEONInfoPtr info = RADEONPTR (pScrn); atomDataTablesPtr atomDataPtr; CARD8 crev, frev; int i, j; atomDataPtr = info->atomBIOS->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( &(atomDataPtr->SupportedDevicesInfo.SupportedDevicesInfo->sHeader), &crev,&frev,NULL)) { xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "No Device Info Table found!\n"); return FALSE; } for (i = 0; i < ATOM_MAX_SUPPORTED_DEVICE; i++) { ATOM_CONNECTOR_INFO_I2C ci = atomDataPtr->SupportedDevicesInfo.SupportedDevicesInfo->asConnInfo[i]; if (!(atomDataPtr->SupportedDevicesInfo .SupportedDevicesInfo->usDeviceSupport & (1 << i))) { info->BiosConnector[i].valid = FALSE; continue; } #if 1 if (i == ATOM_DEVICE_CV_INDEX) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Skipping Component Video\n"); info->BiosConnector[i].valid = FALSE; continue; } #endif info->BiosConnector[i].valid = TRUE; info->BiosConnector[i].output_id = ci.sucI2cId.sbfAccess.bfI2C_LineMux; info->BiosConnector[i].devices = (1 << i); info->BiosConnector[i].ConnectorType = ci.sucConnectorInfo.sbfAccess.bfConnectorType; info->BiosConnector[i].DACType = ci.sucConnectorInfo.sbfAccess.bfAssociatedDAC - 1; if (ci.sucI2cId.sbfAccess.bfHW_Capable) { /* don't assign a gpio for tv */ if ((i == ATOM_DEVICE_TV1_INDEX) || (i == ATOM_DEVICE_TV2_INDEX) || (i == ATOM_DEVICE_CV_INDEX)) info->BiosConnector[i].ddc_line = 0; else info->BiosConnector[i].ddc_line = RADEONLookupGPIOLineForDDC(pScrn, ci.sucI2cId.sbfAccess.bfI2C_LineMux); } else if (ci.sucI2cId.sbfAccess.bfI2C_LineMux) { /* add support for GPIO line */ ErrorF("Unsupported SW GPIO - device %d: gpio line: 0x%x\n", i, (unsigned int)RADEONLookupGPIOLineForDDC(pScrn, ci.sucI2cId.sbfAccess.bfI2C_LineMux)); info->BiosConnector[i].ddc_line = 0; } else { info->BiosConnector[i].ddc_line = 0; } if (i == ATOM_DEVICE_DFP1_INDEX) info->BiosConnector[i].TMDSType = TMDS_INT; else if (i == ATOM_DEVICE_DFP2_INDEX) info->BiosConnector[i].TMDSType = TMDS_EXT; else if (i == ATOM_DEVICE_DFP3_INDEX) info->BiosConnector[i].TMDSType = TMDS_EXT; else info->BiosConnector[i].TMDSType = TMDS_UNKNOWN; /* Always set the connector type to VGA for CRT1/CRT2. if they are * shared with a DVI port, we'll pick up the DVI connector below when we * merge the outputs */ if ((i == ATOM_DEVICE_CRT1_INDEX || i == ATOM_DEVICE_CRT2_INDEX) && (info->BiosConnector[i].ConnectorType == CONNECTOR_DVI_I || info->BiosConnector[i].ConnectorType == CONNECTOR_DVI_D || info->BiosConnector[i].ConnectorType == CONNECTOR_DVI_A)) { info->BiosConnector[i].ConnectorType = CONNECTOR_VGA; } if (crev > 1) { ATOM_CONNECTOR_INC_SRC_BITMAP isb = atomDataPtr->SupportedDevicesInfo .SupportedDevicesInfo_HD->asIntSrcInfo[i]; switch (isb.ucIntSrcBitmap) { case 0x4: info->BiosConnector[i].hpd_mask = 0x00000001; break; case 0xa: info->BiosConnector[i].hpd_mask = 0x00000100; break; default: info->BiosConnector[i].hpd_mask = 0; break; } } else { info->BiosConnector[i].hpd_mask = 0; } } /* CRTs/DFPs may share a port */ for (i = 0; i < ATOM_MAX_SUPPORTED_DEVICE; i++) { if (info->BiosConnector[i].valid) { for (j = 0; j < ATOM_MAX_SUPPORTED_DEVICE; j++) { if (info->BiosConnector[j].valid && (i != j) ) { if (info->BiosConnector[i].output_id == info->BiosConnector[j].output_id) { if (((i == ATOM_DEVICE_DFP1_INDEX) || (i == ATOM_DEVICE_DFP2_INDEX) || (i == ATOM_DEVICE_DFP3_INDEX)) && ((j == ATOM_DEVICE_CRT1_INDEX) || (j == ATOM_DEVICE_CRT2_INDEX))) { info->BiosConnector[i].DACType = info->BiosConnector[j].DACType; info->BiosConnector[i].devices |= info->BiosConnector[j].devices; info->BiosConnector[j].valid = FALSE; } else if (((j == ATOM_DEVICE_DFP1_INDEX) || (j == ATOM_DEVICE_DFP2_INDEX) || (j == ATOM_DEVICE_DFP3_INDEX)) && ((i == ATOM_DEVICE_CRT1_INDEX) || (i == ATOM_DEVICE_CRT2_INDEX))) { info->BiosConnector[j].DACType = info->BiosConnector[i].DACType; info->BiosConnector[j].devices |= info->BiosConnector[i].devices; info->BiosConnector[i].valid = FALSE; } /* other possible combos? */ } } } } } xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Bios Connector table: \n"); for (i = 0; i < ATOM_MAX_SUPPORTED_DEVICE; i++) { if (info->BiosConnector[i].valid) { xf86DrvMsg(pScrn->scrnIndex, X_INFO, "Port%d: DDCType-0x%x, DACType-%d, TMDSType-%d, ConnectorType-%d, hpd_mask-0x%x\n", i, (unsigned int)info->BiosConnector[i].ddc_line, info->BiosConnector[i].DACType, info->BiosConnector[i].TMDSType, info->BiosConnector[i].ConnectorType, info->BiosConnector[i].hpd_mask); } } return TRUE; } #if 0 #define RHD_CONNECTORS_MAX 4 #define MAX_OUTPUTS_PER_CONNECTOR 2 #define Limit(n,max,name) ((n >= max) ? ( \ xf86DrvMsg(handle->scrnIndex,X_ERROR,"%s: %s %i exceeds maximum %i\n", \ __func__,name,n,max), TRUE) : FALSE) static const struct _rhd_connector_objs { char *name; RADEONConnectorTypeATOM con; } rhd_connector_objs[] = { { "NONE", CONNECTOR_NONE_ATOM }, { "SINGLE_LINK_DVI_I", CONNECTOR_DVI_I_ATOM }, { "DUAL_LINK_DVI_I", CONNECTOR_DVI_I_ATOM }, { "SINGLE_LINK_DVI_D", CONNECTOR_DVI_D_ATOM }, { "DUAL_LINK_DVI_D", CONNECTOR_DVI_D_ATOM }, { "VGA", CONNECTOR_VGA_ATOM }, { "COMPOSITE", CONNECTOR_CTV_ATOM }, { "SVIDEO", CONNECTOR_STV_ATOM }, { "D_CONNECTOR", CONNECTOR_NONE_ATOM }, { "9PIN_DIN", CONNECTOR_NONE_ATOM }, { "SCART", CONNECTOR_SCART_ATOM }, { "HDMI_TYPE_A", CONNECTOR_HDMI_TYPE_A_ATOM }, { "HDMI_TYPE_B", CONNECTOR_HDMI_TYPE_B_ATOM }, { "HDMI_TYPE_B", CONNECTOR_HDMI_TYPE_B_ATOM }, { "LVDS", CONNECTOR_LVDS_ATOM }, { "7PIN_DIN", CONNECTOR_STV_ATOM }, { "PCIE_CONNECTOR", CONNECTOR_NONE_ATOM }, { "CROSSFIRE", CONNECTOR_NONE_ATOM }, { "HARDCODE_DVI", CONNECTOR_NONE_ATOM }, { "DISPLAYPORT", CONNECTOR_DISPLAY_PORT_ATOM } }; static const int n_rhd_connector_objs = sizeof (rhd_connector_objs) / sizeof(struct _rhd_connector_objs); static const struct _rhd_encoders { char *name; RADEONOutputTypeATOM ot; } rhd_encoders[] = { { "NONE", OUTPUT_NONE_ATOM }, { "INTERNAL_LVDS", OUTPUT_LVDS_ATOM }, { "INTERNAL_TMDS1", OUTPUT_TMDSA_ATOM }, { "INTERNAL_TMDS2", OUTPUT_TMDSB_ATOM }, { "INTERNAL_DAC1", OUTPUT_DACA_ATOM }, { "INTERNAL_DAC2", OUTPUT_DACB_ATOM }, { "INTERNAL_SDVOA", OUTPUT_NONE_ATOM }, { "INTERNAL_SDVOB", OUTPUT_NONE_ATOM }, { "SI170B", OUTPUT_NONE_ATOM }, { "CH7303", OUTPUT_NONE_ATOM }, { "CH7301", OUTPUT_NONE_ATOM }, { "INTERNAL_DVO1", OUTPUT_NONE_ATOM }, { "EXTERNAL_SDVOA", OUTPUT_NONE_ATOM }, { "EXTERNAL_SDVOB", OUTPUT_NONE_ATOM }, { "TITFP513", OUTPUT_NONE_ATOM }, { "INTERNAL_LVTM1", OUTPUT_LVTMA_ATOM }, { "VT1623", OUTPUT_NONE_ATOM }, { "HDMI_SI1930", OUTPUT_NONE_ATOM }, { "HDMI_INTERNAL", OUTPUT_NONE_ATOM }, { "INTERNAL_KLDSCP_TMDS1", OUTPUT_TMDSA_ATOM }, { "INTERNAL_KLSCP_DVO1", OUTPUT_NONE_ATOM }, { "INTERNAL_KLDSCP_DAC1", OUTPUT_DACA_ATOM }, { "INTERNAL_KLDSCP_DAC2", OUTPUT_DACB_ATOM }, { "SI178", OUTPUT_NONE_ATOM }, { "MVPU_FPGA", OUTPUT_NONE_ATOM }, { "INTERNAL_DDI", OUTPUT_NONE_ATOM }, { "VT1625", OUTPUT_NONE_ATOM }, { "HDMI_SI1932", OUTPUT_NONE_ATOM }, { "AN9801", OUTPUT_NONE_ATOM }, { "DP501", OUTPUT_NONE_ATOM }, }; static const int n_rhd_encoders = sizeof (rhd_encoders) / sizeof(struct _rhd_encoders); static const struct _rhd_connectors { char *name; RADEONConnectorTypeATOM con; Bool dual; } rhd_connectors[] = { {"NONE", CONNECTOR_NONE_ATOM, FALSE }, {"VGA", CONNECTOR_VGA_ATOM, FALSE }, {"DVI-I", CONNECTOR_DVI_I_ATOM, TRUE }, {"DVI-D", CONNECTOR_DVI_D_ATOM, FALSE }, {"DVI-A", CONNECTOR_DVI_A_ATOM, FALSE }, {"SVIDEO", CONNECTOR_STV_ATOM, FALSE }, {"COMPOSITE", CONNECTOR_CTV_ATOM, FALSE }, {"PANEL", CONNECTOR_LVDS_ATOM, FALSE }, {"DIGITAL_LINK", CONNECTOR_DIGITAL_ATOM, FALSE }, {"SCART", CONNECTOR_SCART_ATOM, FALSE }, {"HDMI Type A", CONNECTOR_HDMI_TYPE_A_ATOM, FALSE }, {"HDMI Type B", CONNECTOR_HDMI_TYPE_B_ATOM, FALSE }, {"UNKNOWN", CONNECTOR_NONE_ATOM, FALSE }, {"UNKNOWN", CONNECTOR_NONE_ATOM, FALSE }, {"DVI+DIN", CONNECTOR_NONE_ATOM, FALSE } }; static const int n_rhd_connectors = sizeof(rhd_connectors) / sizeof(struct _rhd_connectors); static const struct _rhd_devices { char *name; RADEONOutputTypeATOM ot; } rhd_devices[] = { {" CRT1", OUTPUT_NONE_ATOM }, {" LCD1", OUTPUT_LVTMA_ATOM }, {" TV1", OUTPUT_NONE_ATOM }, {" DFP1", OUTPUT_TMDSA_ATOM }, {" CRT2", OUTPUT_NONE_ATOM }, {" LCD2", OUTPUT_LVTMA_ATOM }, {" TV2", OUTPUT_NONE_ATOM }, {" DFP2", OUTPUT_LVTMA_ATOM }, {" CV", OUTPUT_NONE_ATOM }, {" DFP3", OUTPUT_LVTMA_ATOM } }; static const int n_rhd_devices = sizeof(rhd_devices) / sizeof(struct _rhd_devices); static const rhdDDC hwddc[] = { RHD_DDC_0, RHD_DDC_1, RHD_DDC_2, RHD_DDC_3 }; static const int n_hwddc = sizeof(hwddc) / sizeof(rhdDDC); static const rhdOutputType acc_dac[] = { OUTPUT_NONE_ATOM, OUTPUT_DACA_ATOM, OUTPUT_DACB_ATOM, OUTPUT_DAC_EXTERNAL_ATOM }; static const int n_acc_dac = sizeof(acc_dac) / sizeof (rhdOutputType); /* * */ static Bool rhdAtomInterpretObjectID(atomBiosHandlePtr handle, CARD16 id, CARD8 *obj_type, CARD8 *obj_id, CARD8 *num, char **name) { *obj_id = (id & OBJECT_ID_MASK) >> OBJECT_ID_SHIFT; *num = (id & ENUM_ID_MASK) >> ENUM_ID_SHIFT; *obj_type = (id & OBJECT_TYPE_MASK) >> OBJECT_TYPE_SHIFT; *name = NULL; switch (*obj_type) { case GRAPH_OBJECT_TYPE_CONNECTOR: if (!Limit(*obj_id, n_rhd_connector_objs, "obj_id")) *name = rhd_connector_objs[*obj_id].name; break; case GRAPH_OBJECT_TYPE_ENCODER: if (!Limit(*obj_id, n_rhd_encoders, "obj_id")) *name = rhd_encoders[*obj_id].name; break; default: break; } return TRUE; } /* * */ static void rhdAtomDDCFromI2CRecord(atomBiosHandlePtr handle, ATOM_I2C_RECORD *Record, rhdDDC *DDC) { RHDDebug(handle->scrnIndex, " %s: I2C Record: %s[%x] EngineID: %x I2CAddr: %x\n", __func__, Record->sucI2cId.bfHW_Capable ? "HW_Line" : "GPIO_ID", Record->sucI2cId.bfI2C_LineMux, Record->sucI2cId.bfHW_EngineID, Record->ucI2CAddr); if (!*(unsigned char *)&(Record->sucI2cId)) *DDC = RHD_DDC_NONE; else { if (Record->ucI2CAddr != 0) return; if (Record->sucI2cId.bfHW_Capable) { *DDC = (rhdDDC)Record->sucI2cId.bfI2C_LineMux; if (*DDC >= RHD_DDC_MAX) *DDC = RHD_DDC_NONE; } else { *DDC = RHD_DDC_GPIO; /* add GPIO pin parsing */ } } } /* * */ static void rhdAtomParseGPIOLutForHPD(atomBiosHandlePtr handle, CARD8 pinID, rhdHPD *HPD) { atomDataTablesPtr atomDataPtr; ATOM_GPIO_PIN_LUT *gpio_pin_lut; unsigned short size; int i = 0; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; *HPD = RHD_HPD_NONE; if (!rhdAtomGetTableRevisionAndSize( &atomDataPtr->GPIO_Pin_LUT->sHeader, NULL, NULL, &size)) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: No valid GPIO pin LUT in AtomBIOS\n",__func__); return; } gpio_pin_lut = atomDataPtr->GPIO_Pin_LUT; while (1) { if (gpio_pin_lut->asGPIO_Pin[i].ucGPIO_ID == pinID) { if ((sizeof(ATOM_COMMON_TABLE_HEADER) + (i * sizeof(ATOM_GPIO_PIN_ASSIGNMENT))) > size) return; RHDDebug(handle->scrnIndex, " %s: GPIO PinID: %i Index: %x Shift: %i\n", __func__, pinID, gpio_pin_lut->asGPIO_Pin[i].usGpioPin_AIndex, gpio_pin_lut->asGPIO_Pin[i].ucGpioPinBitShift); /* grr... map backwards: register indices -> line numbers */ if (gpio_pin_lut->asGPIO_Pin[i].usGpioPin_AIndex == (DC_GPIO_HPD_A >> 2)) { switch (gpio_pin_lut->asGPIO_Pin[i].ucGpioPinBitShift) { case 0: *HPD = RHD_HPD_0; return; case 8: *HPD = RHD_HPD_1; return; case 16: *HPD = RHD_HPD_2; return; } } } i++; } } /* * */ static void rhdAtomHPDFromRecord(atomBiosHandlePtr handle, ATOM_HPD_INT_RECORD *Record, rhdHPD *HPD) { RHDDebug(handle->scrnIndex, " %s: HPD Record: GPIO ID: %x Plugged_PinState: %x\n", __func__, Record->ucHPDIntGPIOID, Record->ucPluggged_PinState); rhdAtomParseGPIOLutForHPD(handle, Record->ucHPDIntGPIOID, HPD); } /* * */ static char * rhdAtomDeviceTagsFromRecord(atomBiosHandlePtr handle, ATOM_CONNECTOR_DEVICE_TAG_RECORD *Record) { int i, j, k; char *devices; //RHDFUNC(handle); RHDDebug(handle->scrnIndex," NumberOfDevice: %i\n", Record->ucNumberOfDevice); if (!Record->ucNumberOfDevice) return NULL; devices = (char *)xcalloc(Record->ucNumberOfDevice * 4 + 1,1); for (i = 0; i < Record->ucNumberOfDevice; i++) { k = 0; j = Record->asDeviceTag[i].usDeviceID; while (!(j & 0x1)) { j >>= 1; k++; }; if (!Limit(k,n_rhd_devices,"usDeviceID")) strcat(devices, rhd_devices[k].name); } RHDDebug(handle->scrnIndex," Devices:%s\n",devices); return devices; } /* * */ static AtomBiosResult rhdAtomConnectorInfoFromObjectHeader(atomBiosHandlePtr handle, rhdConnectorInfoPtr *ptr) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; ATOM_CONNECTOR_OBJECT_TABLE *con_obj; rhdConnectorInfoPtr cp; unsigned long object_header_end; int ncon = 0; int i,j; unsigned short object_header_size; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( &atomDataPtr->Object_Header->sHeader, &crev,&frev,&object_header_size)) { return ATOM_NOT_IMPLEMENTED; } if (crev < 2) /* don't bother with anything below rev 2 */ return ATOM_NOT_IMPLEMENTED; if (!(cp = (rhdConnectorInfoPtr)xcalloc(sizeof(struct rhdConnectorInfo), RHD_CONNECTORS_MAX))) return ATOM_FAILED; object_header_end = atomDataPtr->Object_Header->usConnectorObjectTableOffset + object_header_size; RHDDebug(handle->scrnIndex,"ObjectTable - size: %u, BIOS - size: %u " "TableOffset: %u object_header_end: %u\n", object_header_size, handle->BIOSImageSize, atomDataPtr->Object_Header->usConnectorObjectTableOffset, object_header_end); if ((object_header_size > handle->BIOSImageSize) || (atomDataPtr->Object_Header->usConnectorObjectTableOffset > handle->BIOSImageSize) || object_header_end > handle->BIOSImageSize) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: Object table information is bogus\n",__func__); return ATOM_FAILED; } if (((unsigned long)&atomDataPtr->Object_Header->sHeader + object_header_end) > ((unsigned long)handle->BIOSBase + handle->BIOSImageSize)) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: Object table extends beyond BIOS Image\n",__func__); return ATOM_FAILED; } con_obj = (ATOM_CONNECTOR_OBJECT_TABLE *) ((char *)&atomDataPtr->Object_Header->sHeader + atomDataPtr->Object_Header->usConnectorObjectTableOffset); for (i = 0; i < con_obj->ucNumberOfObjects; i++) { ATOM_SRC_DST_TABLE_FOR_ONE_OBJECT *SrcDstTable; ATOM_COMMON_RECORD_HEADER *Record; int record_base; CARD8 obj_type, obj_id, num; char *name; int nout = 0; rhdAtomInterpretObjectID(handle, con_obj->asObjects[i].usObjectID, &obj_type, &obj_id, &num, &name); RHDDebug(handle->scrnIndex, "Object: ID: %x name: %s type: %x id: %x\n", con_obj->asObjects[i].usObjectID, name ? name : "", obj_type, obj_id); if (obj_type != GRAPH_OBJECT_TYPE_CONNECTOR) continue; SrcDstTable = (ATOM_SRC_DST_TABLE_FOR_ONE_OBJECT *) ((char *)&atomDataPtr->Object_Header->sHeader + con_obj->asObjects[i].usSrcDstTableOffset); if (con_obj->asObjects[i].usSrcDstTableOffset + (SrcDstTable->ucNumberOfSrc * sizeof(ATOM_SRC_DST_TABLE_FOR_ONE_OBJECT)) > handle->BIOSImageSize) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: SrcDstTable[%i] extends " "beyond Object_Header table\n",__func__,i); continue; } cp[ncon].Type = rhd_connector_objs[obj_id].con; cp[ncon].Name = RhdAppendString(cp[ncon].Name,name); for (j = 0; j < SrcDstTable->ucNumberOfSrc; j++) { CARD8 stype, sobj_id, snum; char *sname; rhdAtomInterpretObjectID(handle, SrcDstTable->usSrcObjectID[j], &stype, &sobj_id, &snum, &sname); RHDDebug(handle->scrnIndex, " * SrcObject: ID: %x name: %s\n", SrcDstTable->usSrcObjectID[j], sname); cp[ncon].Output[nout] = rhd_encoders[sobj_id].ot; if (++nout >= MAX_OUTPUTS_PER_CONNECTOR) break; } Record = (ATOM_COMMON_RECORD_HEADER *) ((char *)&atomDataPtr->Object_Header->sHeader + con_obj->asObjects[i].usRecordOffset); record_base = con_obj->asObjects[i].usRecordOffset; while (Record->ucRecordType > 0 && Record->ucRecordType <= ATOM_MAX_OBJECT_RECORD_NUMBER ) { char *taglist; if ((record_base += Record->ucRecordSize) > object_header_size) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: Object Records extend beyond Object Table\n", __func__); break; } RHDDebug(handle->scrnIndex, " - Record Type: %x\n", Record->ucRecordType); switch (Record->ucRecordType) { case ATOM_I2C_RECORD_TYPE: rhdAtomDDCFromI2CRecord(handle, (ATOM_I2C_RECORD *)Record, &cp[ncon].DDC); break; case ATOM_HPD_INT_RECORD_TYPE: rhdAtomHPDFromRecord(handle, (ATOM_HPD_INT_RECORD *)Record, &cp[ncon].HPD); break; case ATOM_CONNECTOR_DEVICE_TAG_RECORD_TYPE: taglist = rhdAtomDeviceTagsFromRecord(handle, (ATOM_CONNECTOR_DEVICE_TAG_RECORD *)Record); if (taglist) { cp[ncon].Name = RhdAppendString(cp[ncon].Name,taglist); xfree(taglist); } break; default: break; } Record = (ATOM_COMMON_RECORD_HEADER*) ((char *)Record + Record->ucRecordSize); } if ((++ncon) == RHD_CONNECTORS_MAX) break; } *ptr = cp; RhdPrintConnectorInfo(handle->scrnIndex, cp); return ATOM_SUCCESS; } /* * */ static AtomBiosResult rhdAtomConnectorInfoFromSupportedDevices(atomBiosHandlePtr handle, rhdConnectorInfoPtr *ptr) { atomDataTablesPtr atomDataPtr; CARD8 crev, frev; rhdConnectorInfoPtr cp; struct { rhdOutputType ot; rhdConnectorType con; rhdDDC ddc; rhdHPD hpd; Bool dual; char *name; char *outputName; } devices[ATOM_MAX_SUPPORTED_DEVICE]; int ncon = 0; int n; //RHDFUNC(handle); atomDataPtr = handle->atomDataPtr; if (!rhdAtomGetTableRevisionAndSize( &(atomDataPtr->SupportedDevicesInfo.SupportedDevicesInfo->sHeader), &crev,&frev,NULL)) { return ATOM_NOT_IMPLEMENTED; } if (!(cp = (rhdConnectorInfoPtr)xcalloc(RHD_CONNECTORS_MAX, sizeof(struct rhdConnectorInfo)))) return ATOM_FAILED; for (n = 0; n < ATOM_MAX_SUPPORTED_DEVICE; n++) { ATOM_CONNECTOR_INFO_I2C ci = atomDataPtr->SupportedDevicesInfo.SupportedDevicesInfo->asConnInfo[n]; devices[n].ot = OUTPUT_NONE_ATOM; if (!(atomDataPtr->SupportedDevicesInfo .SupportedDevicesInfo->usDeviceSupport & (1 << n))) continue; if (Limit(ci.sucConnectorInfo.sbfAccess.bfConnectorType, n_rhd_connectors, "bfConnectorType")) continue; devices[n].con = rhd_connectors[ci.sucConnectorInfo.sbfAccess.bfConnectorType].con; if (devices[n].con == RHD_CONNECTOR_NONE) continue; devices[n].dual = rhd_connectors[ci.sucConnectorInfo.sbfAccess.bfConnectorType].dual; devices[n].name = rhd_connectors[ci.sucConnectorInfo.sbfAccess.bfConnectorType].name; RHDDebug(handle->scrnIndex,"AtomBIOS Connector[%i]: %s Device:%s ",n, rhd_connectors[ci.sucConnectorInfo .sbfAccess.bfConnectorType].name, rhd_devices[n].name); devices[n].outputName = rhd_devices[n].name; if (!Limit(ci.sucConnectorInfo.sbfAccess.bfAssociatedDAC, n_acc_dac, "bfAssociatedDAC")) { if ((devices[n].ot = acc_dac[ci.sucConnectorInfo.sbfAccess.bfAssociatedDAC]) == OUTPUT_NONE_ATOM) { devices[n].ot = rhd_devices[n].ot; } } else devices[n].ot = OUTPUT_NONE_ATOM; RHDDebugCont("Output: %x ",devices[n].ot); if (ci.sucI2cId.sbfAccess.bfHW_Capable) { RHDDebugCont("HW DDC %i ", ci.sucI2cId.sbfAccess.bfI2C_LineMux); if (Limit(ci.sucI2cId.sbfAccess.bfI2C_LineMux, n_hwddc, "bfI2C_LineMux")) devices[n].ddc = RHD_DDC_NONE; else devices[n].ddc = hwddc[ci.sucI2cId.sbfAccess.bfI2C_LineMux]; } else if (ci.sucI2cId.sbfAccess.bfI2C_LineMux) { RHDDebugCont("GPIO DDC "); devices[n].ddc = RHD_DDC_GPIO; /* add support for GPIO line */ } else { RHDDebugCont("NO DDC "); devices[n].ddc = RHD_DDC_NONE; } if (crev > 1) { ATOM_CONNECTOR_INC_SRC_BITMAP isb = atomDataPtr->SupportedDevicesInfo .SupportedDevicesInfo_HD->asIntSrcInfo[n]; switch (isb.ucIntSrcBitmap) { case 0x4: RHDDebugCont("HPD 0\n"); devices[n].hpd = RHD_HPD_0; break; case 0xa: RHDDebugCont("HPD 1\n"); devices[n].hpd = RHD_HPD_1; break; default: RHDDebugCont("NO HPD\n"); devices[n].hpd = RHD_HPD_NONE; break; } } else { RHDDebugCont("NO HPD\n"); devices[n].hpd = RHD_HPD_NONE; } } /* sort devices for connectors */ for (n = 0; n < ATOM_MAX_SUPPORTED_DEVICE; n++) { int i; if (devices[n].ot == OUTPUT_NONE_ATOM) continue; if (devices[n].con == CONNECTOR_NONE_ATOM) continue; cp[ncon].DDC = devices[n].ddc; cp[ncon].HPD = devices[n].hpd; cp[ncon].Output[0] = devices[n].ot; cp[ncon].Output[1] = OUTPUT_NONE_ATOM; cp[ncon].Type = devices[n].con; cp[ncon].Name = xf86strdup(devices[n].name); cp[ncon].Name = RhdAppendString(cp[ncon].Name, devices[n].outputName); if (devices[n].dual) { if (devices[n].ddc == RHD_DDC_NONE) xf86DrvMsg(handle->scrnIndex, X_ERROR, "No DDC channel for device %s found." " Cannot find matching device.\n",devices[n].name); else { for (i = n + 1; i < ATOM_MAX_SUPPORTED_DEVICE; i++) { if (!devices[i].dual) continue; if (devices[n].ddc != devices[i].ddc) continue; if (((devices[n].ot == OUTPUT_DACA_ATOM || devices[n].ot == OUTPUT_DACB_ATOM) && (devices[i].ot == OUTPUT_LVTMA_ATOM || devices[i].ot == OUTPUT_TMDSA_ATOM)) || ((devices[i].ot == OUTPUT_DACA_ATOM || devices[i].ot == OUTPUT_DACB_ATOM) && (devices[n].ot == OUTPUT_LVTMA_ATOM || devices[n].ot == OUTPUT_TMDSA_ATOM))) { cp[ncon].Output[1] = devices[i].ot; if (cp[ncon].HPD == RHD_HPD_NONE) cp[ncon].HPD = devices[i].hpd; cp[ncon].Name = RhdAppendString(cp[ncon].Name, devices[i].outputName); devices[i].ot = OUTPUT_NONE_ATOM; /* zero the device */ } } } } if ((++ncon) == RHD_CONNECTORS_MAX) break; } *ptr = cp; RhdPrintConnectorInfo(handle->scrnIndex, cp); return ATOM_SUCCESS; } /* * */ static AtomBiosResult rhdAtomConnectorInfo(atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data) { data->connectorInfo = NULL; if (rhdAtomConnectorInfoFromObjectHeader(handle,&data->connectorInfo) == ATOM_SUCCESS) return ATOM_SUCCESS; else return rhdAtomConnectorInfoFromSupportedDevices(handle, &data->connectorInfo); } #endif # ifdef ATOM_BIOS_PARSER static AtomBiosResult rhdAtomExec (atomBiosHandlePtr handle, AtomBiosRequestID unused, AtomBiosArgPtr data) { RADEONInfoPtr info = RADEONPTR (xf86Screens[handle->scrnIndex]); Bool ret = FALSE; char *msg; int idx = data->exec.index; void *pspace = data->exec.pspace; pointer *dataSpace = data->exec.dataSpace; //RHDFUNCI(handle->scrnIndex); if (dataSpace) { if (!handle->fbBase && !handle->scratchBase) return ATOM_FAILED; if (handle->fbBase) { if (!info->FB) { xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s: " "Cannot exec AtomBIOS: framebuffer not mapped\n", __func__); return ATOM_FAILED; } *dataSpace = (CARD8*)info->FB + handle->fbBase; } else *dataSpace = (CARD8*)handle->scratchBase; } ret = ParseTableWrapper(pspace, idx, handle, handle->BIOSBase, &msg); if (!ret) xf86DrvMsg(handle->scrnIndex, X_ERROR, "%s\n",msg); else xf86DrvMsgVerb(handle->scrnIndex, X_INFO, 5, "%s\n",msg); return (ret) ? ATOM_SUCCESS : ATOM_FAILED; } # endif AtomBiosResult RHDAtomBiosFunc(int scrnIndex, atomBiosHandlePtr handle, AtomBiosRequestID id, AtomBiosArgPtr data) { AtomBiosResult ret = ATOM_FAILED; int i; char *msg = NULL; enum msgDataFormat msg_f = MSG_FORMAT_NONE; AtomBiosRequestFunc req_func = NULL; //RHDFUNCI(scrnIndex); for (i = 0; AtomBiosRequestList[i].id != FUNC_END; i++) { if (id == AtomBiosRequestList[i].id) { req_func = AtomBiosRequestList[i].request; msg = AtomBiosRequestList[i].message; msg_f = AtomBiosRequestList[i].message_format; break; } } if (req_func == NULL) { xf86DrvMsg(scrnIndex, X_ERROR, "Unknown AtomBIOS request: %i\n",id); return ATOM_NOT_IMPLEMENTED; } /* Hack for now */ if (id == ATOMBIOS_INIT) data->val = scrnIndex; if (id == ATOMBIOS_INIT || handle) ret = req_func(handle, id, data); if (ret == ATOM_SUCCESS) { switch (msg_f) { case MSG_FORMAT_DEC: xf86DrvMsg(scrnIndex,X_INFO,"%s: %li\n", msg, (unsigned long) data->val); break; case MSG_FORMAT_HEX: xf86DrvMsg(scrnIndex,X_INFO,"%s: 0x%lx\n",msg , (unsigned long) data->val); break; case MSG_FORMAT_NONE: xf86DrvMsgVerb(scrnIndex, 7, X_INFO, "Call to %s succeeded\n", msg); break; } } else { char *result = (ret == ATOM_FAILED) ? "failed" : "not implemented"; switch (msg_f) { case MSG_FORMAT_DEC: case MSG_FORMAT_HEX: xf86DrvMsgVerb(scrnIndex, 1, X_WARNING, "Call to %s %s\n", msg, result); break; case MSG_FORMAT_NONE: xf86DrvMsg(scrnIndex,X_INFO,"Query for %s: %s\n", msg, result); break; } } return ret; } # ifdef ATOM_BIOS_PARSER VOID* CailAllocateMemory(VOID *CAIL,UINT16 size) { CAILFUNC(CAIL); return malloc(size); } VOID CailReleaseMemory(VOID *CAIL, VOID *addr) { CAILFUNC(CAIL); free(addr); } VOID CailDelayMicroSeconds(VOID *CAIL, UINT32 delay) { CAILFUNC(CAIL); usleep(delay); DEBUGP(xf86DrvMsg(((atomBiosHandlePtr)CAIL)->scrnIndex,X_INFO,"Delay %i usec\n",delay)); } UINT32 CailReadATIRegister(VOID* CAIL, UINT32 idx) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; RADEONInfoPtr info = RADEONPTR(pScrn); unsigned char *RADEONMMIO = info->MMIO; UINT32 ret; CAILFUNC(CAIL); ret = INREG(idx << 2); DEBUGP(ErrorF("%s(%x) = %x\n",__func__,idx << 2,ret)); return ret; } VOID CailWriteATIRegister(VOID *CAIL, UINT32 idx, UINT32 data) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; RADEONInfoPtr info = RADEONPTR(pScrn); unsigned char *RADEONMMIO = info->MMIO; CAILFUNC(CAIL); OUTREG(idx << 2,data); DEBUGP(ErrorF("%s(%x,%x)\n",__func__,idx << 2,data)); } UINT32 CailReadFBData(VOID* CAIL, UINT32 idx) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; RADEONInfoPtr info = RADEONPTR(pScrn); UINT32 ret; CAILFUNC(CAIL); if (((atomBiosHandlePtr)CAIL)->fbBase) { CARD8 *FBBase = (CARD8*)info->FB; ret = *((CARD32*)(FBBase + (((atomBiosHandlePtr)CAIL)->fbBase) + idx)); DEBUGP(ErrorF("%s(%x) = %x\n",__func__,idx,ret)); } else if (((atomBiosHandlePtr)CAIL)->scratchBase) { ret = *(CARD32*)((CARD8*)(((atomBiosHandlePtr)CAIL)->scratchBase) + idx); DEBUGP(ErrorF("%s(%x) = %x\n",__func__,idx,ret)); } else { xf86DrvMsg(((atomBiosHandlePtr)CAIL)->scrnIndex,X_ERROR, "%s: no fbbase set\n",__func__); return 0; } return ret; } VOID CailWriteFBData(VOID *CAIL, UINT32 idx, UINT32 data) { CAILFUNC(CAIL); DEBUGP(ErrorF("%s(%x,%x)\n",__func__,idx,data)); if (((atomBiosHandlePtr)CAIL)->fbBase) { CARD8 *FBBase = (CARD8*) RADEONPTR(xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex])->FB; *((CARD32*)(FBBase + (((atomBiosHandlePtr)CAIL)->fbBase) + idx)) = data; } else if (((atomBiosHandlePtr)CAIL)->scratchBase) { *(CARD32*)((CARD8*)(((atomBiosHandlePtr)CAIL)->scratchBase) + idx) = data; } else xf86DrvMsg(((atomBiosHandlePtr)CAIL)->scrnIndex,X_ERROR, "%s: no fbbase set\n",__func__); } ULONG CailReadMC(VOID *CAIL, ULONG Address) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; ULONG ret; CAILFUNC(CAIL); ret = INMC(pScrn, Address); DEBUGP(ErrorF("%s(%x) = %x\n",__func__,Address,ret)); return ret; } VOID CailWriteMC(VOID *CAIL, ULONG Address, ULONG data) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; CAILFUNC(CAIL); DEBUGP(ErrorF("%s(%x,%x)\n",__func__,Address,data)); OUTMC(pScrn, Address, data); } #ifdef XSERVER_LIBPCIACCESS VOID CailReadPCIConfigData(VOID*CAIL, VOID* ret, UINT32 idx,UINT16 size) { pci_device_cfg_read(RADEONPTR(xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex])->PciInfo, ret,idx << 2 , size >> 3, NULL); } VOID CailWritePCIConfigData(VOID*CAIL,VOID*src,UINT32 idx,UINT16 size) { pci_device_cfg_write(RADEONPTR(xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex])->PciInfo, src, idx << 2, size >> 3, NULL); } #else VOID CailReadPCIConfigData(VOID*CAIL, VOID* ret, UINT32 idx,UINT16 size) { PCITAG tag = ((atomBiosHandlePtr)CAIL)->PciTag; CAILFUNC(CAIL); switch (size) { case 8: *(CARD8*)ret = pciReadByte(tag,idx << 2); break; case 16: *(CARD16*)ret = pciReadWord(tag,idx << 2); break; case 32: *(CARD32*)ret = pciReadLong(tag,idx << 2); break; default: xf86DrvMsg(((atomBiosHandlePtr)CAIL)->scrnIndex, X_ERROR,"%s: Unsupported size: %i\n", __func__,(int)size); return; break; } DEBUGP(ErrorF("%s(%x) = %x\n",__func__,idx,*(unsigned int*)ret)); } VOID CailWritePCIConfigData(VOID*CAIL,VOID*src,UINT32 idx,UINT16 size) { PCITAG tag = ((atomBiosHandlePtr)CAIL)->PciTag; CAILFUNC(CAIL); DEBUGP(ErrorF("%s(%x,%x)\n",__func__,idx,(*(unsigned int*)src))); switch (size) { case 8: pciWriteByte(tag,idx << 2,*(CARD8*)src); break; case 16: pciWriteWord(tag,idx << 2,*(CARD16*)src); break; case 32: pciWriteLong(tag,idx << 2,*(CARD32*)src); break; default: xf86DrvMsg(((atomBiosHandlePtr)CAIL)->scrnIndex,X_ERROR, "%s: Unsupported size: %i\n",__func__,(int)size); break; } } #endif ULONG CailReadPLL(VOID *CAIL, ULONG Address) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; ULONG ret; CAILFUNC(CAIL); ret = RADEONINPLL(pScrn, Address); DEBUGP(ErrorF("%s(%x) = %x\n",__func__,Address,ret)); return ret; } VOID CailWritePLL(VOID *CAIL, ULONG Address,ULONG Data) { ScrnInfoPtr pScrn = xf86Screens[((atomBiosHandlePtr)CAIL)->scrnIndex]; CAILFUNC(CAIL); DEBUGP(ErrorF("%s(%x,%x)\n",__func__,Address,Data)); RADEONOUTPLL(pScrn, Address, Data); } void atombios_get_command_table_version(atomBiosHandlePtr atomBIOS, int index, int *major, int *minor) { ATOM_MASTER_COMMAND_TABLE *cmd_table = (void *)(atomBIOS->BIOSBase + atomBIOS->cmd_offset); ATOM_MASTER_LIST_OF_COMMAND_TABLES *table_start; ATOM_COMMON_ROM_COMMAND_TABLE_HEADER *table_hdr; //unsigned short *ptr; unsigned short offset; table_start = &cmd_table->ListOfCommandTables; offset = *(((unsigned short *)table_start) + index); table_hdr = (ATOM_COMMON_ROM_COMMAND_TABLE_HEADER *)(atomBIOS->BIOSBase + offset); *major = table_hdr->CommonHeader.ucTableFormatRevision; *minor = table_hdr->CommonHeader.ucTableContentRevision; } #endif /* ATOM_BIOS */