/* * Copyright © 2007 Red Hat, Inc. * 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 (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 NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS 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: * Dave Airlie * Alex Deucher * */ /* * avivo crtc handling functions. */ #ifdef HAVE_CONFIG_H #include "config.h" #endif /* DPMS */ #define DPMS_SERVER #include #include "radeon.h" #include "radeon_reg.h" #include "radeon_macros.h" #include "radeon_atombios.h" #ifdef XF86DRI #define _XF86DRI_SERVER_ #include "radeon_drm.h" #include "sarea.h" #endif extern int atombios_get_encoder_mode(xf86OutputPtr output); AtomBiosResult atombios_lock_crtc(atomBiosHandlePtr atomBIOS, int crtc, int lock) { ENABLE_CRTC_PS_ALLOCATION crtc_data; AtomBiosArgRec data; unsigned char *space; crtc_data.ucCRTC = crtc; crtc_data.ucEnable = lock; data.exec.index = GetIndexIntoMasterTable(COMMAND, UpdateCRTC_DoubleBufferRegisters); data.exec.dataSpace = (void *)&space; data.exec.pspace = &crtc_data; if (RHDAtomBiosFunc(atomBIOS->scrnIndex, atomBIOS, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { ErrorF("%s CRTC %d success\n", lock? "Lock":"Unlock", crtc); return ATOM_SUCCESS ; } ErrorF("Lock CRTC failed\n"); return ATOM_NOT_IMPLEMENTED; } static AtomBiosResult atombios_enable_crtc(atomBiosHandlePtr atomBIOS, int crtc, int state) { ENABLE_CRTC_PS_ALLOCATION crtc_data; AtomBiosArgRec data; unsigned char *space; crtc_data.ucCRTC = crtc; crtc_data.ucEnable = state; data.exec.index = GetIndexIntoMasterTable(COMMAND, EnableCRTC); data.exec.dataSpace = (void *)&space; data.exec.pspace = &crtc_data; if (RHDAtomBiosFunc(atomBIOS->scrnIndex, atomBIOS, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { ErrorF("%s CRTC %d success\n", state? "Enable":"Disable", crtc); return ATOM_SUCCESS ; } ErrorF("Enable CRTC failed\n"); return ATOM_NOT_IMPLEMENTED; } static AtomBiosResult atombios_enable_crtc_memreq(atomBiosHandlePtr atomBIOS, int crtc, int state) { ENABLE_CRTC_PS_ALLOCATION crtc_data; AtomBiosArgRec data; unsigned char *space; crtc_data.ucCRTC = crtc; crtc_data.ucEnable = state; data.exec.index = GetIndexIntoMasterTable(COMMAND, EnableCRTCMemReq); data.exec.dataSpace = (void *)&space; data.exec.pspace = &crtc_data; if (RHDAtomBiosFunc(atomBIOS->scrnIndex, atomBIOS, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { ErrorF("%s CRTC memreq %d success\n", state? "Enable":"Disable", crtc); return ATOM_SUCCESS ; } ErrorF("Enable CRTC memreq failed\n"); return ATOM_NOT_IMPLEMENTED; } static AtomBiosResult atombios_blank_crtc(atomBiosHandlePtr atomBIOS, int crtc, int state) { BLANK_CRTC_PS_ALLOCATION crtc_data; unsigned char *space; AtomBiosArgRec data; memset(&crtc_data, 0, sizeof(crtc_data)); crtc_data.ucCRTC = crtc; crtc_data.ucBlanking = state; data.exec.index = GetIndexIntoMasterTable(COMMAND, BlankCRTC); data.exec.dataSpace = (void *)&space; data.exec.pspace = &crtc_data; if (RHDAtomBiosFunc(atomBIOS->scrnIndex, atomBIOS, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { ErrorF("%s CRTC %d success\n", state? "Blank":"Unblank", crtc); return ATOM_SUCCESS ; } ErrorF("Blank CRTC failed\n"); return ATOM_NOT_IMPLEMENTED; } void atombios_crtc_dpms(xf86CrtcPtr crtc, int mode) { RADEONCrtcPrivatePtr radeon_crtc = crtc->driver_private; RADEONInfoPtr info = RADEONPTR(crtc->scrn); switch (mode) { case DPMSModeOn: case DPMSModeStandby: case DPMSModeSuspend: if (IS_DCE3_VARIANT) atombios_enable_crtc_memreq(info->atomBIOS, radeon_crtc->crtc_id, 1); atombios_enable_crtc(info->atomBIOS, radeon_crtc->crtc_id, 1); atombios_blank_crtc(info->atomBIOS, radeon_crtc->crtc_id, 0); break; case DPMSModeOff: atombios_blank_crtc(info->atomBIOS, radeon_crtc->crtc_id, 1); atombios_enable_crtc(info->atomBIOS, radeon_crtc->crtc_id, 0); if (IS_DCE3_VARIANT) atombios_enable_crtc_memreq(info->atomBIOS, radeon_crtc->crtc_id, 0); break; } } static AtomBiosResult atombios_set_crtc_timing(atomBiosHandlePtr atomBIOS, SET_CRTC_TIMING_PARAMETERS_PS_ALLOCATION *crtc_param) { AtomBiosArgRec data; unsigned char *space; SET_CRTC_TIMING_PARAMETERS_PS_ALLOCATION conv_param; conv_param.usH_Total = cpu_to_le16(crtc_param->usH_Total); conv_param.usH_Disp = cpu_to_le16(crtc_param->usH_Disp); conv_param.usH_SyncStart = cpu_to_le16(crtc_param->usH_SyncStart); conv_param.usH_SyncWidth = cpu_to_le16(crtc_param->usH_SyncWidth); conv_param.usV_Total = cpu_to_le16(crtc_param->usV_Total); conv_param.usV_Disp = cpu_to_le16(crtc_param->usV_Disp); conv_param.usV_SyncStart = cpu_to_le16(crtc_param->usV_SyncStart); conv_param.usV_SyncWidth = cpu_to_le16(crtc_param->usV_SyncWidth); conv_param.susModeMiscInfo.usAccess = cpu_to_le16(crtc_param->susModeMiscInfo.usAccess); conv_param.ucCRTC = crtc_param->ucCRTC; conv_param.ucOverscanRight = crtc_param->ucOverscanRight; conv_param.ucOverscanLeft = crtc_param->ucOverscanLeft; conv_param.ucOverscanBottom = crtc_param->ucOverscanBottom; conv_param.ucOverscanTop = crtc_param->ucOverscanTop; conv_param.ucReserved = crtc_param->ucReserved; data.exec.index = GetIndexIntoMasterTable(COMMAND, SetCRTC_Timing); data.exec.dataSpace = (void *)&space; data.exec.pspace = &conv_param; if (RHDAtomBiosFunc(atomBIOS->scrnIndex, atomBIOS, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { ErrorF("Set CRTC Timing success\n"); return ATOM_SUCCESS ; } ErrorF("Set CRTC Timing failed\n"); return ATOM_NOT_IMPLEMENTED; } void atombios_crtc_set_pll(xf86CrtcPtr crtc, DisplayModePtr mode, int pll_flags) { RADEONCrtcPrivatePtr radeon_crtc = crtc->driver_private; RADEONInfoPtr info = RADEONPTR(crtc->scrn); xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(crtc->scrn); unsigned char *RADEONMMIO = info->MMIO; int index = GetIndexIntoMasterTable(COMMAND, SetPixelClock); uint32_t sclock = mode->Clock; uint32_t ref_div = 0, fb_div = 0, post_div = 0; int major, minor, i; SET_PIXEL_CLOCK_PS_ALLOCATION spc_param; PIXEL_CLOCK_PARAMETERS_V2 *spc2_ptr; PIXEL_CLOCK_PARAMETERS_V3 *spc3_ptr; xf86OutputPtr output; RADEONOutputPrivatePtr radeon_output = NULL; radeon_encoder_ptr radeon_encoder = NULL; void *ptr; AtomBiosArgRec data; unsigned char *space; RADEONSavePtr save = info->ModeReg; memset(&spc_param, 0, sizeof(spc_param)); if (IS_AVIVO_VARIANT) { uint32_t temp; if (IS_DCE3_VARIANT && mode->Clock > 200000) /* range limits??? */ pll_flags |= RADEON_PLL_PREFER_HIGH_FB_DIV; else pll_flags |= RADEON_PLL_PREFER_LOW_REF_DIV; RADEONComputePLL(&info->pll, mode->Clock, &temp, &fb_div, &ref_div, &post_div, pll_flags); sclock = temp; /* disable spread spectrum clocking for now -- thanks Hedy Lamarr */ if (radeon_crtc->crtc_id == 0) { temp = INREG(AVIVO_P1PLL_INT_SS_CNTL); OUTREG(AVIVO_P1PLL_INT_SS_CNTL, temp & ~1); } else { temp = INREG(AVIVO_P2PLL_INT_SS_CNTL); OUTREG(AVIVO_P2PLL_INT_SS_CNTL, temp & ~1); } } else { sclock = save->dot_clock_freq; fb_div = save->feedback_div; post_div = save->post_div; ref_div = save->ppll_ref_div; } xf86DrvMsg(crtc->scrn->scrnIndex, X_INFO, "crtc(%d) Clock: mode %d, PLL %lu\n", radeon_crtc->crtc_id, mode->Clock, (long unsigned int)sclock * 10); xf86DrvMsg(crtc->scrn->scrnIndex, X_INFO, "crtc(%d) PLL : refdiv %u, fbdiv 0x%X(%u), pdiv %u\n", radeon_crtc->crtc_id, (unsigned int)ref_div, (unsigned int)fb_div, (unsigned int)fb_div, (unsigned int)post_div); /* Can't really do cloning easily on DCE3 cards */ for (i = 0; i < xf86_config->num_output; i++) { output = xf86_config->output[i]; if (output->crtc == crtc) { radeon_output = output->driver_private; radeon_encoder = radeon_get_encoder(output); break; } } if (radeon_output == NULL) { xf86DrvMsg(crtc->scrn->scrnIndex, X_ERROR, "No output assigned to crtc!\n"); return; } if (radeon_encoder == NULL) { xf86DrvMsg(crtc->scrn->scrnIndex, X_ERROR, "No encoder assigned to output!\n"); return; } atombios_get_command_table_version(info->atomBIOS, index, &major, &minor); /*ErrorF("table is %d %d\n", major, minor);*/ switch(major) { case 1: switch(minor) { case 1: case 2: spc2_ptr = (PIXEL_CLOCK_PARAMETERS_V2*)&spc_param.sPCLKInput; spc2_ptr->usPixelClock = cpu_to_le16(sclock); spc2_ptr->usRefDiv = cpu_to_le16(ref_div); spc2_ptr->usFbDiv = cpu_to_le16(fb_div); spc2_ptr->ucPostDiv = post_div; spc2_ptr->ucPpll = radeon_crtc->crtc_id ? ATOM_PPLL2 : ATOM_PPLL1; spc2_ptr->ucCRTC = radeon_crtc->crtc_id; spc2_ptr->ucRefDivSrc = 1; ptr = &spc_param; break; case 3: spc3_ptr = (PIXEL_CLOCK_PARAMETERS_V3*)&spc_param.sPCLKInput; spc3_ptr->usPixelClock = cpu_to_le16(sclock); spc3_ptr->usRefDiv = cpu_to_le16(ref_div); spc3_ptr->usFbDiv = cpu_to_le16(fb_div); spc3_ptr->ucPostDiv = post_div; spc3_ptr->ucPpll = radeon_crtc->crtc_id ? ATOM_PPLL2 : ATOM_PPLL1; spc3_ptr->ucMiscInfo = (radeon_crtc->crtc_id << 2); spc3_ptr->ucTransmitterId = radeon_encoder->encoder_id; spc3_ptr->ucEncoderMode = atombios_get_encoder_mode(output); ptr = &spc_param; break; default: ErrorF("Unknown table version\n"); exit(-1); } break; default: ErrorF("Unknown table version\n"); exit(-1); } data.exec.index = GetIndexIntoMasterTable(COMMAND, SetPixelClock); data.exec.dataSpace = (void *)&space; data.exec.pspace = ptr; if (RHDAtomBiosFunc(info->atomBIOS->scrnIndex, info->atomBIOS, ATOMBIOS_EXEC, &data) == ATOM_SUCCESS) { ErrorF("Set CRTC %d PLL success\n", radeon_crtc->crtc_id); return; } ErrorF("Set CRTC %d PLL failed\n", radeon_crtc->crtc_id); return; } void atombios_crtc_mode_set(xf86CrtcPtr crtc, DisplayModePtr mode, DisplayModePtr adjusted_mode, int x, int y) { ScrnInfoPtr pScrn = crtc->scrn; RADEONCrtcPrivatePtr radeon_crtc = crtc->driver_private; RADEONInfoPtr info = RADEONPTR(pScrn); xf86CrtcConfigPtr xf86_config = XF86_CRTC_CONFIG_PTR(pScrn); unsigned char *RADEONMMIO = info->MMIO; unsigned long fb_location = crtc->scrn->fbOffset + info->fbLocation; int need_tv_timings = 0; int i, ret; SET_CRTC_TIMING_PARAMETERS_PS_ALLOCATION crtc_timing; Bool tilingChanged = FALSE; int pll_flags = 0; memset(&crtc_timing, 0, sizeof(crtc_timing)); if (info->allowColorTiling) { radeon_crtc->can_tile = (adjusted_mode->Flags & (V_DBLSCAN | V_INTERLACE)) ? FALSE : TRUE; tilingChanged = RADEONSetTiling(pScrn); } for (i = 0; i < xf86_config->num_output; i++) { xf86OutputPtr output = xf86_config->output[i]; RADEONOutputPrivatePtr radeon_output = output->driver_private; radeon_tvout_ptr tvout = &radeon_output->tvout; if (output->crtc == crtc) { if (radeon_output->MonType == MT_STV || radeon_output->MonType == MT_CTV) { if (tvout->tvStd == TV_STD_NTSC || tvout->tvStd == TV_STD_NTSC_J || tvout->tvStd == TV_STD_PAL_M) need_tv_timings = 1; else need_tv_timings = 2; } if (radeon_output->MonType == MT_LCD) pll_flags |= RADEON_PLL_USE_REF_DIV; } } crtc_timing.ucCRTC = radeon_crtc->crtc_id; if (need_tv_timings) { ret = RADEONATOMGetTVTimings(pScrn, need_tv_timings - 1, &crtc_timing, &adjusted_mode->Clock); if (ret == FALSE) { need_tv_timings = 0; } } if (!need_tv_timings) { crtc_timing.usH_Total = adjusted_mode->CrtcHTotal; crtc_timing.usH_Disp = adjusted_mode->CrtcHDisplay; crtc_timing.usH_SyncStart = adjusted_mode->CrtcHSyncStart; crtc_timing.usH_SyncWidth = adjusted_mode->CrtcHSyncEnd - adjusted_mode->CrtcHSyncStart; crtc_timing.usV_Total = adjusted_mode->CrtcVTotal; crtc_timing.usV_Disp = adjusted_mode->CrtcVDisplay; crtc_timing.usV_SyncStart = adjusted_mode->CrtcVSyncStart; crtc_timing.usV_SyncWidth = adjusted_mode->CrtcVSyncEnd - adjusted_mode->CrtcVSyncStart; if (adjusted_mode->Flags & V_NVSYNC) crtc_timing.susModeMiscInfo.usAccess |= ATOM_VSYNC_POLARITY; if (adjusted_mode->Flags & V_NHSYNC) crtc_timing.susModeMiscInfo.usAccess |= ATOM_HSYNC_POLARITY; if (adjusted_mode->Flags & V_CSYNC) crtc_timing.susModeMiscInfo.usAccess |= ATOM_COMPOSITESYNC; if (adjusted_mode->Flags & V_INTERLACE) crtc_timing.susModeMiscInfo.usAccess |= ATOM_INTERLACE; if (adjusted_mode->Flags & V_DBLSCAN) crtc_timing.susModeMiscInfo.usAccess |= ATOM_DOUBLE_CLOCK_MODE; } ErrorF("Mode %dx%d - %d %d %d\n", adjusted_mode->CrtcHDisplay, adjusted_mode->CrtcVDisplay, adjusted_mode->CrtcHTotal, adjusted_mode->CrtcVTotal, adjusted_mode->Flags); RADEONInitMemMapRegisters(pScrn, info->ModeReg, info); RADEONRestoreMemMapRegisters(pScrn, info->ModeReg); if (IS_AVIVO_VARIANT) { uint32_t fb_format; switch (crtc->scrn->bitsPerPixel) { case 15: fb_format = AVIVO_D1GRPH_CONTROL_DEPTH_16BPP | AVIVO_D1GRPH_CONTROL_16BPP_ARGB1555; break; case 16: fb_format = AVIVO_D1GRPH_CONTROL_DEPTH_16BPP | AVIVO_D1GRPH_CONTROL_16BPP_RGB565; break; case 24: case 32: fb_format = AVIVO_D1GRPH_CONTROL_DEPTH_32BPP | AVIVO_D1GRPH_CONTROL_32BPP_ARGB8888; break; default: FatalError("Unsupported screen depth: %d\n", xf86GetDepth()); } if (info->tilingEnabled && (crtc->rotatedData == NULL)) { fb_format |= AVIVO_D1GRPH_MACRO_ADDRESS_MODE; } if (radeon_crtc->crtc_id == 0) OUTREG(AVIVO_D1VGA_CONTROL, 0); else OUTREG(AVIVO_D2VGA_CONTROL, 0); /* setup fb format and location */ if (crtc->rotatedData != NULL) { /* x/y offset is already included */ x = 0; y = 0; fb_location = fb_location + (char *)crtc->rotatedData - (char *)info->FB; } OUTREG(AVIVO_D1GRPH_PRIMARY_SURFACE_ADDRESS + radeon_crtc->crtc_offset, fb_location); OUTREG(AVIVO_D1GRPH_SECONDARY_SURFACE_ADDRESS + radeon_crtc->crtc_offset, fb_location); OUTREG(AVIVO_D1GRPH_CONTROL + radeon_crtc->crtc_offset, fb_format); OUTREG(AVIVO_D1GRPH_SURFACE_OFFSET_X + radeon_crtc->crtc_offset, 0); OUTREG(AVIVO_D1GRPH_SURFACE_OFFSET_Y + radeon_crtc->crtc_offset, 0); OUTREG(AVIVO_D1GRPH_X_START + radeon_crtc->crtc_offset, 0); OUTREG(AVIVO_D1GRPH_Y_START + radeon_crtc->crtc_offset, 0); OUTREG(AVIVO_D1GRPH_X_END + radeon_crtc->crtc_offset, info->virtualX); OUTREG(AVIVO_D1GRPH_Y_END + radeon_crtc->crtc_offset, info->virtualY); OUTREG(AVIVO_D1GRPH_PITCH + radeon_crtc->crtc_offset, crtc->scrn->displayWidth); OUTREG(AVIVO_D1GRPH_ENABLE + radeon_crtc->crtc_offset, 1); OUTREG(AVIVO_D1MODE_DESKTOP_HEIGHT + radeon_crtc->crtc_offset, mode->VDisplay); OUTREG(AVIVO_D1MODE_VIEWPORT_START + radeon_crtc->crtc_offset, (x << 16) | y); OUTREG(AVIVO_D1MODE_VIEWPORT_SIZE + radeon_crtc->crtc_offset, (mode->HDisplay << 16) | mode->VDisplay); if (adjusted_mode->Flags & V_INTERLACE) OUTREG(AVIVO_D1MODE_DATA_FORMAT + radeon_crtc->crtc_offset, AVIVO_D1MODE_INTERLEAVE_EN); else OUTREG(AVIVO_D1MODE_DATA_FORMAT + radeon_crtc->crtc_offset, 0); } atombios_crtc_set_pll(crtc, adjusted_mode, pll_flags); atombios_set_crtc_timing(info->atomBIOS, &crtc_timing); if (info->DispPriority) RADEONInitDispBandwidth(pScrn); radeon_crtc->initialized = TRUE; if (tilingChanged) { /* need to redraw front buffer, I guess this can be considered a hack ? */ /* if this is called during ScreenInit() we don't have pScrn->pScreen yet */ if (pScrn->pScreen) xf86EnableDisableFBAccess(pScrn->scrnIndex, FALSE); RADEONChangeSurfaces(pScrn); if (pScrn->pScreen) xf86EnableDisableFBAccess(pScrn->scrnIndex, TRUE); /* xf86SetRootClip would do, but can't access that here */ } } /* Calculate display buffer watermark to prevent buffer underflow */ void RADEONInitDispBandwidthAVIVO(ScrnInfoPtr pScrn, DisplayModePtr mode1, int pixel_bytes1, DisplayModePtr mode2, int pixel_bytes2) { RADEONInfoPtr info = RADEONPTR(pScrn); RADEONEntPtr pRADEONEnt = RADEONEntPriv(pScrn); unsigned char *RADEONMMIO = info->MMIO; uint32_t dc_lb_memory_split; float mem_bw, peak_disp_bw; float min_mem_eff = 0.8; /* XXX: taken from legacy method */ float pix_clk, pix_clk2; /* in MHz */ /* * Set display0/1 priority up in the memory controller for * modes if the user specifies HIGH for displaypriority * option. */ if (info->DispPriority == 2) { uint32_t mc_init_misc_lat_timer = 0; if (info->ChipFamily == CHIP_FAMILY_RV515) mc_init_misc_lat_timer = INMC(pScrn, RV515_MC_INIT_MISC_LAT_TIMER); else if (info->ChipFamily == CHIP_FAMILY_RS690) mc_init_misc_lat_timer = INMC(pScrn, RS690_MC_INIT_MISC_LAT_TIMER); mc_init_misc_lat_timer &= ~(R300_MC_DISP1R_INIT_LAT_MASK << R300_MC_DISP1R_INIT_LAT_SHIFT); mc_init_misc_lat_timer &= ~(R300_MC_DISP0R_INIT_LAT_MASK << R300_MC_DISP0R_INIT_LAT_SHIFT); if (pRADEONEnt->pCrtc[1]->enabled) mc_init_misc_lat_timer |= (1 << R300_MC_DISP1R_INIT_LAT_SHIFT); /* display 1 */ if (pRADEONEnt->pCrtc[0]->enabled) mc_init_misc_lat_timer |= (1 << R300_MC_DISP0R_INIT_LAT_SHIFT); /* display 0 */ if (info->ChipFamily == CHIP_FAMILY_RV515) OUTMC(pScrn, RV515_MC_INIT_MISC_LAT_TIMER, mc_init_misc_lat_timer); else if (info->ChipFamily == CHIP_FAMILY_RS690) OUTMC(pScrn, RS690_MC_INIT_MISC_LAT_TIMER, mc_init_misc_lat_timer); } /* XXX: fix me for AVIVO * Determine if there is enough bandwidth for current display mode */ mem_bw = info->mclk * (info->RamWidth / 8) * (info->IsDDR ? 2 : 1); pix_clk = 0; pix_clk2 = 0; peak_disp_bw = 0; if (mode1) { pix_clk = mode1->Clock/1000.0; peak_disp_bw += (pix_clk * pixel_bytes1); } if (mode2) { pix_clk2 = mode2->Clock/1000.0; peak_disp_bw += (pix_clk2 * pixel_bytes2); } if (peak_disp_bw >= mem_bw * min_mem_eff) { xf86DrvMsg(pScrn->scrnIndex, X_WARNING, "You may not have enough display bandwidth for current mode\n" "If you have flickering problem, try to lower resolution, refresh rate, or color depth\n"); } /* * Line Buffer Setup * There is a single line buffer shared by both display controllers. * DC_LB_MEMORY_SPLIT controls how that line buffer is shared between the display * controllers. The paritioning can either be done manually or via one of four * preset allocations specified in bits 1:0: * 0 - line buffer is divided in half and shared between each display controller * 1 - D1 gets 3/4 of the line buffer, D2 gets 1/4 * 2 - D1 gets the whole buffer * 3 - D1 gets 1/4 of the line buffer, D2 gets 3/4 * Setting bit 2 of DC_LB_MEMORY_SPLIT controls switches to manual allocation mode. * In manual allocation mode, D1 always starts at 0, D1 end/2 is specified in bits * 14:4; D2 allocation follows D1. */ /* is auto or manual better ? */ dc_lb_memory_split = INREG(AVIVO_DC_LB_MEMORY_SPLIT) & ~AVIVO_DC_LB_MEMORY_SPLIT_MASK; dc_lb_memory_split &= ~AVIVO_DC_LB_MEMORY_SPLIT_SHIFT_MODE; #if 1 /* auto */ if (mode1 && mode2) { if (mode1->HDisplay > mode2->HDisplay) { if (mode1->HDisplay > 2560) dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1_3Q_D2_1Q; else dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1HALF_D2HALF; } else if (mode2->HDisplay > mode1->HDisplay) { if (mode2->HDisplay > 2560) dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1_1Q_D2_3Q; else dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1HALF_D2HALF; } else dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1HALF_D2HALF; } else if (mode1) { dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1_ONLY; } else if (mode2) { dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_D1_1Q_D2_3Q; } #else /* manual */ dc_lb_memory_split |= AVIVO_DC_LB_MEMORY_SPLIT_SHIFT_MODE; dc_lb_memory_split &= ~(AVIVO_DC_LB_DISP1_END_ADR_MASK << AVIVO_DC_LB_DISP1_END_ADR_SHIFT); if (mode1) { dc_lb_memory_split |= ((((mode1->HDisplay / 2) + 64 /*???*/) & AVIVO_DC_LB_DISP1_END_ADR_MASK) << AVIVO_DC_LB_DISP1_END_ADR_SHIFT); } else if (mode2) { dc_lb_memory_split |= (0 << AVIVO_DC_LB_DISP1_END_ADR_SHIFT); } OUTREG(AVIVO_DC_LB_MEMORY_SPLIT, dc_lb_memory_split); #endif /* * Watermark setup * TODO... * Unforunately, I haven't been able to dig up the avivo watermark programming * guide yet. -AGD */ }