From 5c044c732fc28b09eb58956a85b141af194f2b94 Mon Sep 17 00:00:00 2001 From: Uwe Hermann Date: Wed, 27 May 2009 17:06:54 +0000 Subject: Make directory hierarchy flat to match the same layout we use for other chipsets, as suggested on IRC. Signed-off-by: Uwe Hermann Acked-by: Uwe Hermann git-svn-id: svn://svn.coreboot.org/coreboot/trunk@4317 2b7e53f0-3cfb-0310-b3e9-8179ed1497e1 --- src/northbridge/via/vx800/clk_ctrl.c | 312 +++++ src/northbridge/via/vx800/ddr2init/dram_init.c | 86 -- src/northbridge/via/vx800/ddr2init/dram_init.h | 263 ---- src/northbridge/via/vx800/ddr2init/dram_util.c | 249 ---- src/northbridge/via/vx800/ddr2init/dram_util.h | 47 - .../via/vx800/ddr2init/translator_ddr2_init.c | 34 - .../via/vx800/ddr2init/vx800/clk_ctrl.c | 312 ----- .../via/vx800/ddr2init/vx800/detection.c | 192 --- .../via/vx800/ddr2init/vx800/dev_init.c | 1318 -------------------- .../via/vx800/ddr2init/vx800/dqs_search.c | 98 -- src/northbridge/via/vx800/ddr2init/vx800/drdy_bl.c | 600 --------- .../via/vx800/ddr2init/vx800/driving_setting.c | 396 ------ .../via/vx800/ddr2init/vx800/final_setting.c | 129 -- .../via/vx800/ddr2init/vx800/freq_setting.c | 235 ---- .../via/vx800/ddr2init/vx800/rank_map.c | 363 ------ .../via/vx800/ddr2init/vx800/timing_setting.c | 492 -------- .../via/vx800/ddr2init/vx800/uma_ram_setting.c | 445 ------- src/northbridge/via/vx800/detection.c | 192 +++ src/northbridge/via/vx800/dev_init.c | 1318 ++++++++++++++++++++ src/northbridge/via/vx800/dqs_search.c | 98 ++ src/northbridge/via/vx800/dram_init.c | 86 ++ src/northbridge/via/vx800/dram_init.h | 263 ++++ src/northbridge/via/vx800/dram_util.c | 249 ++++ src/northbridge/via/vx800/dram_util.h | 47 + src/northbridge/via/vx800/drdy_bl.c | 600 +++++++++ src/northbridge/via/vx800/driving_setting.c | 396 ++++++ src/northbridge/via/vx800/final_setting.c | 129 ++ src/northbridge/via/vx800/freq_setting.c | 235 ++++ src/northbridge/via/vx800/raminit.c | 32 +- src/northbridge/via/vx800/rank_map.c | 363 ++++++ src/northbridge/via/vx800/timing_setting.c | 492 ++++++++ src/northbridge/via/vx800/translator_ddr2_init.c | 34 + src/northbridge/via/vx800/uma_ram_setting.c | 445 +++++++ 33 files changed, 5275 insertions(+), 5275 deletions(-) create mode 100644 src/northbridge/via/vx800/clk_ctrl.c delete mode 100644 src/northbridge/via/vx800/ddr2init/dram_init.c delete mode 100644 src/northbridge/via/vx800/ddr2init/dram_init.h delete mode 100644 src/northbridge/via/vx800/ddr2init/dram_util.c delete mode 100644 src/northbridge/via/vx800/ddr2init/dram_util.h delete mode 100644 src/northbridge/via/vx800/ddr2init/translator_ddr2_init.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/clk_ctrl.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/detection.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/dev_init.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/dqs_search.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/drdy_bl.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/driving_setting.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/final_setting.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/freq_setting.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/rank_map.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/timing_setting.c delete mode 100644 src/northbridge/via/vx800/ddr2init/vx800/uma_ram_setting.c create mode 100644 src/northbridge/via/vx800/detection.c create mode 100644 src/northbridge/via/vx800/dev_init.c create mode 100644 src/northbridge/via/vx800/dqs_search.c create mode 100644 src/northbridge/via/vx800/dram_init.c create mode 100644 src/northbridge/via/vx800/dram_init.h create mode 100644 src/northbridge/via/vx800/dram_util.c create mode 100644 src/northbridge/via/vx800/dram_util.h create mode 100644 src/northbridge/via/vx800/drdy_bl.c create mode 100644 src/northbridge/via/vx800/driving_setting.c create mode 100644 src/northbridge/via/vx800/final_setting.c create mode 100644 src/northbridge/via/vx800/freq_setting.c create mode 100644 src/northbridge/via/vx800/rank_map.c create mode 100644 src/northbridge/via/vx800/timing_setting.c create mode 100644 src/northbridge/via/vx800/translator_ddr2_init.c create mode 100644 src/northbridge/via/vx800/uma_ram_setting.c (limited to 'src/northbridge/via') diff --git a/src/northbridge/via/vx800/clk_ctrl.c b/src/northbridge/via/vx800/clk_ctrl.c new file mode 100644 index 0000000000..13edc1f996 --- /dev/null +++ b/src/northbridge/via/vx800/clk_ctrl.c @@ -0,0 +1,312 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +void DutyCycleCtrl(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 FreqId; + u8 i; + + if (DIMMFREQ_800 == DramAttr->DramFreq) + FreqId = 2; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + FreqId = 3; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + FreqId = 4; + else if (DIMMFREQ_400 == DramAttr->DramFreq) + FreqId = 5; + else + FreqId = 5; + + if (DramAttr->RankNumChA > 0) { // 1 rank + for (i = 0; i < DUTY_CYCLE_REG_NUM; i++) { + Data = + pci_read_config8(MEMCTRL, + ChA_Duty_Control_DDR2[i][0]); + Data &= ChA_Duty_Control_DDR2[i][1]; /*Mask */ + Data |= ChA_Duty_Control_DDR2[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + ChA_Duty_Control_DDR2[i][0], + Data); + } + } + if (1 == ENABLE_CHC) { // 1 rank + for (i = 0; i < DUTY_CYCLE_REG_NUM; i++) { + Data = + pci_read_config8(MEMCTRL, + ChB_Duty_Control_DDR2[i][0]); + Data &= ChB_Duty_Control_DDR2[i][1]; /*Mask */ + Data |= ChB_Duty_Control_DDR2[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + ChB_Duty_Control_DDR2[i][0], + Data); + } + } + +} + +/* +DRAM clock phase and delay control +*/ +//sub routine list +void ClkPhsCtrlFBMDDR2(DRAM_SYS_ATTR * DramAttr); + +void WrtDataPhsCtrl(DRAM_SYS_ATTR * DramAttr); + +void DQDQSOutputDlyCtrl(DRAM_SYS_ATTR * DramAttr); + +void DQSInputCaptureCtrl(DRAM_SYS_ATTR * DramAttr); + +void DCLKPhsCtrl(DRAM_SYS_ATTR * DramAttr); + + +void DRAMClkCtrl(DRAM_SYS_ATTR * DramAttr) +{ + /*write data clock phase control */ + WrtDataPhsCtrl(DramAttr); + /*clock phase control */ + ClkPhsCtrlFBMDDR2(DramAttr); + /**/ DQDQSOutputDlyCtrl(DramAttr); + /**/ DQSInputCaptureCtrl(DramAttr); + DCLKPhsCtrl(DramAttr); +} + +void ClkPhsCtrlFBMDDR2(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + + u8 FreqId, i; + + if (DramAttr->DramFreq == DIMMFREQ_800) + FreqId = 2; + else if (DramAttr->DramFreq == DIMMFREQ_667) + FreqId = 3; + else if (DramAttr->DramFreq == DIMMFREQ_533) + FreqId = 4; + else if (DramAttr->DramFreq == DIMMFREQ_400) + FreqId = 5; + else + FreqId = 5; + /*channel A */// 2~4 Rank + if (DramAttr->RankNumChA == 1) { // 1 rank + for (i = 0; i < 3; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChA_Clk_Phase_Table_1R[i] + [0]); + Data &= DDR2_ChA_Clk_Phase_Table_1R[i][1]; /*Mask */ + Data |= DDR2_ChA_Clk_Phase_Table_1R[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChA_Clk_Phase_Table_1R[i] + [0], Data); + } + } else if (DramAttr->RankNumChA > 1) { // 2~4 Rank + for (i = 0; i < 3; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChA_Clk_Phase_Table_2R[i] + [0]); + Data &= DDR2_ChA_Clk_Phase_Table_2R[i][1]; /*Mask */ + Data |= DDR2_ChA_Clk_Phase_Table_2R[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChA_Clk_Phase_Table_2R[i] + [0], Data); + } + } +#if ENABLE_CHB + if (DramAttr->RankNumChB > 0) { // 1 rank + for (i = 0; i < 3; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChB_Clk_Phase_Table_1R[i] + [0]); + Data &= DDR2_ChB_Clk_Phase_Table_1R[i][1]; /*Mask */ + Data |= DDR2_ChB_Clk_Phase_Table_1R[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChB_Clk_Phase_Table_1R[i] + [0], Data); + } + } +#endif +} + +void WrtDataPhsCtrl(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 FreqId, i; + + + if (DIMMFREQ_800 == DramAttr->DramFreq) + FreqId = 2; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + FreqId = 3; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + FreqId = 4; + else if (DIMMFREQ_400 == DramAttr->DramFreq) + FreqId = 5; + else + FreqId = 5; + + if (DramAttr->RankNumChA > 0) { // 1 rank + for (i = 0; i < WrtData_REG_NUM; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChA_WrtData_Phase_Table + [i][0]); + Data &= DDR2_ChA_WrtData_Phase_Table[i][1]; /*Mask */ + Data |= DDR2_ChA_WrtData_Phase_Table[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChA_WrtData_Phase_Table[i] + [0], Data); + } + } +#if ENABLE_CHB + if (DramAttr->RankNumChB > 0) { // 1 rank + for (i = 0; i < WrtData_REG_NUM; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChB_WrtData_Phase_Table + [i][0]); + Data &= DDR2_ChB_WrtData_Phase_Table[i][1]; /*Mask */ + Data |= DDR2_ChB_WrtData_Phase_Table[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChB_WrtData_Phase_Table[i] + [0], Data); + } + } +#endif + Data = pci_read_config8(MEMCTRL, 0x8C); + Data &= 0xFC; + Data |= 0x03; + pci_write_config8(MEMCTRL, 0x8C, Data); +} + +void DQDQSOutputDlyCtrl(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 FreqId; + + if (DIMMFREQ_400 == DramAttr->DramFreq) + FreqId = 0; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + FreqId = 1; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + FreqId = 2; + else if (DIMMFREQ_800 == DramAttr->DramFreq) + FreqId = 2; + else + FreqId = 0; + if (DramAttr->RankNumChA > 0) { + Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][0]; + pci_write_config8(MEMCTRL, 0xf0, Data); + + Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][1]; + pci_write_config8(MEMCTRL, 0xf1, Data); + + Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][2]; + pci_write_config8(MEMCTRL, 0xf2, Data); + + Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][3]; + pci_write_config8(MEMCTRL, 0xf3, Data); + } +#if ENABLE_CHB + if (DramAttr->RankNumChB > 0) { + Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][0]; + pci_write_config8(MEMCTRL, 0xf4, Data); + + Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][1]; + pci_write_config8(MEMCTRL, 0xf5, Data); + + Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][2]; + pci_write_config8(MEMCTRL, 0xf6, Data); + + Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][3]; + pci_write_config8(MEMCTRL, 0xf7, Data); + } +#endif +} + +void DQSInputCaptureCtrl(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 FreqId, i; + + if (DIMMFREQ_800 == DramAttr->DramFreq) + FreqId = 2; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + FreqId = 3; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + FreqId = 4; + else if (DIMMFREQ_400 == DramAttr->DramFreq) + FreqId = 5; + else + FreqId = 2; + + Data = 0x8A; + pci_write_config8(MEMCTRL, 0x77, Data); + + if (DramAttr->RankNumChA > 0) { // 1 rank + for (i = 0; i < DQS_INPUT_CAPTURE_REG_NUM; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChA_DQS_Input_Capture_Tbl + [i][0]); + Data &= DDR2_ChA_DQS_Input_Capture_Tbl[i][1]; /*Mask */ + Data |= DDR2_ChA_DQS_Input_Capture_Tbl[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChA_DQS_Input_Capture_Tbl[i] + [0], Data); + } + } +#if ENABLE_CHB + if (DramAttr->RankNumChB > 0) { // 1 rank + for (i = 0; i < DQS_INPUT_CAPTURE_REG_NUM; i++) { + Data = + pci_read_config8(MEMCTRL, + DDR2_ChB_DQS_Input_Capture_Tbl + [i][0]); + Data &= DDR2_ChB_DQS_Input_Capture_Tbl[i][1]; /*Mask */ + Data |= DDR2_ChB_DQS_Input_Capture_Tbl[i][FreqId]; /*set Value */ + pci_write_config8(MEMCTRL, + DDR2_ChB_DQS_Input_Capture_Tbl[i] + [0], Data); + } + } +#endif +} + +//This is very important, if you don't set it correctly, dram will be unreliable +//set DCLK Phase control(Reg99H[6:1]) according the DDRII in the dimm +void DCLKPhsCtrl(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + + Data = 0; + Data = pci_read_config8(MEMCTRL, 0x99); + Data &= 0xE1; + //DDR in Dimm1, MCLKOA[4,3,0] will output MCLK + if (DramAttr->RankPresentMap & 0x03) + Data |= 0x09 << 1; + //DDR in Dimm2, MCLKOA[5,2,1] will output MCLK + if (DramAttr->RankPresentMap & 0x0C) + Data |= 0x06 << 1; + + pci_write_config8(MEMCTRL, 0x99, Data); + +} diff --git a/src/northbridge/via/vx800/ddr2init/dram_init.c b/src/northbridge/via/vx800/ddr2init/dram_init.c deleted file mode 100644 index ad4d721cbd..0000000000 --- a/src/northbridge/via/vx800/ddr2init/dram_init.c +++ /dev/null @@ -1,86 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; either version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -#include "lib/memset.c" -CB_STATUS DDR2_DRAM_INIT() -{ - CB_STATUS Status; - u8 i; - u32 RamSize; - BOOLEAN bTest; - DRAM_SYS_ATTR DramAttr; - - PRINT_DEBUG_MEM("DRAM_INIT \r"); - - memset(&DramAttr, 0, sizeof(DRAM_SYS_ATTR)); - /*Step1 DRAM Detection; DDR1 or DDR2; Get SPD Data; Rank Presence;64 or 128bit; Unbuffered or registered; 1T or 2T */ - DRAMDetect(&DramAttr); - - //Step2 set Frequency; calculate CL and Frequncy from SPD data; set the Frequency - DRAMFreqSetting(&DramAttr); - //Step3 Set DRAM Timing; CL, tRP, tRCD, tRAS, tRFC, tRRD, tWR, tWTR, tRTP - DRAMTimingSetting(&DramAttr); - //Step4 DRDY - DRAMDRDYSetting(&DramAttr); - //Step5 Burst length - DRAMBurstLength(&DramAttr); - //Step6 DRAM Driving Adjustment - DRAMDriving(&DramAttr); - //Step7 duty cycle control - DutyCycleCtrl(&DramAttr); - //Step8 DRAM clock phase and delay control - DRAMClkCtrl(&DramAttr); - //Step9 set register before init DRAM device - DRAMRegInitValue(&DramAttr); - //Step10 DDR and DDR2 initialize process - DRAMInitializeProc(&DramAttr); - - //Step13 Interleave function in rankmap.c - DRAMBankInterleave(&DramAttr); - //Step14 Sizing - DRAMSizingMATypeM(&DramAttr); - - //Step11 Search DQS and DQ output delay - DRAMDQSOutputSearch(&DramAttr); - //Step12 Search DQS input delay - DRAMDQSInputSearch(&DramAttr); - - //Step15 DDR fresh counter setting - DRAMRefreshCounter(&DramAttr); - //Step16 Final register setting for improve performance - DRAMRegFinalValue(&DramAttr); - - RamSize = 0; - for (i = 0; i < MAX_RANKS; i++) { - if (DramAttr.RankSize[i] == 0) { - continue; - } - RamSize += DramAttr.RankSize[i]; - } - PRINT_DEBUG_MEM("RamSize="); - PRINT_DEBUG_MEM_HEX32(RamSize); - PRINT_DEBUG_MEM("\r"); - DumpRegisters(0, 3); - //bTest = DramBaseTest( M1, RamSize - M1 * 2,SPARE, FALSE); - /* the memory can not correct work, this is because the user set the incorrect memory - parameter from setup interface.so we must set the boot mode to recovery mode, let - the system to reset and use the spd value to initialize the memory */ - SetUMARam(); - return CB_SUCCESS; -} diff --git a/src/northbridge/via/vx800/ddr2init/dram_init.h b/src/northbridge/via/vx800/ddr2init/dram_init.h deleted file mode 100644 index e7f5e72d50..0000000000 --- a/src/northbridge/via/vx800/ddr2init/dram_init.h +++ /dev/null @@ -1,263 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; either version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -#ifndef __DRAMINIT_H_ -#define __DRAMINIT_H_ - -//Dram Size -#define M (1024*1024) -#define M1 (1*M) -#define M64 (64*M) -#define M128 (128*M) -#define M256 (256*M) -#define M384 (384*M) -#define M512 (512*M) - -// UMA size -#define UMASIZE M64 - -#define ENABLE_CHC 0 //CHC enable, how ever, this CHC,used some reg define in CHB -#define ENABLE_CHB 0 //CHB enable , CHB is VX800's, VX855 no this CHB. -//Dram Freq -#define DIMMFREQ_800 400 -#define DIMMFREQ_667 333 -//#define DIMMFREQ_600 300 -#define DIMMFREQ_533 266 -#define DIMMFREQ_400 200 -#define DIMMFREQ_333 166 -#define DIMMFREQ_266 133 -#define DIMMFREQ_200 100 - -//Dram Type -#define RAMTYPE_FPMDRAM 1 -#define RAMTYPE_EDO 2 -#define RAMTYPE_PipelinedNibble 3 -#define RAMTYPE_SDRAM 4 -#define RAMTYPE_ROM 5 -#define RAMTYPE_SGRAMDDR 6 -#define RAMTYPE_SDRAMDDR 7 -#define RAMTYPE_SDRAMDDR2 8 - -/* CAS latency constant */ -#define CASLAN_15 15 -#define CASLAN_2 20 -#define CASLAN_25 25 -#define CASLAN_3 30 -#define CASLAN_35 35 -#define CASLAN_4 40 -#define CASLAN_45 45 -#define CASLAN_5 50 -#define CASLAN_NULL 00 - -//Burst length -#define BURSTLENGTH8 8 -#define BURSTLENGTH4 4 - -//Data Width -//#define DATAWIDTHX16 16 -//#define DATAWIDTHX8 8 -//#define DATAWIDTHX4 4 - - -#define SPD_MEMORY_TYPE 2 /*Memory type FPM,EDO,SDRAM,DDR,DDR2 */ -#define SPD_SDRAM_ROW_ADDR 3 /*Number of row addresses on this assembly */ -#define SPD_SDRAM_COL_ADDR 4 /*Number of column addresses on this assembly */ -#define SPD_SDRAM_DIMM_RANKS 5 /*Number of RANKS on this assembly */ -#define SPD_SDRAM_MOD_DATA_WIDTH 6 /*Data width of this assembly */ -#define SPD_SDRAM_TCLK_X 9 /*Cycle time at Maximum supported CAS latency (CL=X) */ -#define SPD_SDRAM_TAC_X 10 /*Access time for highest CL */ -#define SPD_SDRAM_CONFIG_TYPE 11 /*Non-parity , Parity or ECC */ -#define SPD_SDRAM_REFRESH 12 /*Refresh rate/type */ -#define SPD_SDRAM_WIDTH 13 /*Primary sdram width */ -#define SPD_SDRAM_MIN_CLK_DLY 15 /*Minimum clock delay */ -#define SPD_SDRAM_BURSTLENGTH 16 /*Burst Lengths supported */ -#define SPD_SDRAM_NO_OF_BANKS 17 /*Number of banks on this assembly */ -#define SPD_SDRAM_CAS_LATENCY 18 /*CAS latency */ -#define SPD_SDRAM_DIMM_TYPE_DDR2 20 /*DIMM type information; identifies the DDR2 memory module type */ -#define SPD_SDRAM_DEV_ATTR_DDR1 20 /*WE latency */ -#define SPD_SDRAM_MODULES_ATTR 21 /*This byte depicts various aspects of the modules; DDR DDR2 have different aspects */ -#define SPD_SDRAM_DEV_ATTR_GEN 22 /*General device attributes */ -#define SPD_SDRAM_TCLK_X_1 23 /*Minimum clock cycle time at Reduced CL, DDR: X-0.5 DDR2: X-1 */ -#define SPD_SDRAM_TAC_X_1 24 /*Maximum Data Access time from Clock at reduced CL,DDR: X-0.5 DDR2: X-1 */ -#define SPD_SDRAM_TCLK_X_2 25 /*Minimum clock cycle time at reduced CL, DDR: X-1 DDR2: X-2 */ -#define SPD_SDRAM_TAC_X_2 26 /*Maximum Data Access time from Clock at reduced CL, DDR: X-1 DDR2: X-2 */ -#define SPD_SDRAM_TRP 27 /*minimum row precharge time */ -#define SPD_SDRAM_TRRD 28 /*minimum row active to row active delay */ -#define SPD_SDRAM_TRCD 29 /*minimum RAS to CAS delay */ -#define SPD_SDRAM_TRAS 30 /*minimum active to precharge time */ -#define SPD_SDRAM_TWR 36 /*write recovery time, only DDR2 use it */ -#define SPD_SDRAM_TWTR 37 /*internal write to read command delay, only DDR2 use it */ -#define SPD_SDRAM_TRTP 38 /*internal read to prechange command delay, only DDR2 use it */ -#define SPD_SDRAM_TRFC2 40 /*extension of byte 41 tRC and byte 42 tRFC, only DDR2 use it */ -#define SPC_SDRAM_TRC 41 /*minimum active to active/refresh time */ -#define SPD_SDRAM_TRFC 42 /*minimum refresh to active / refresh command period */ - -#define SPD_DATA_SIZE 44 -//Dram cofig are -/*the most number of socket*/ -//#define MAX_RAM_SLOTS 2 -#define MAX_SOCKETS MAX_RAM_SLOTS -#define MAX_DIMMS MAX_SOCKETS /*every sockets can plug one DIMM */ -/*the most number of RANKs on a DIMM*/ -#define MAX_RANKS MAX_SOCKETS*2 - -struct mem_controller { - u8 channel0[MAX_DIMMS]; -}; - -static const struct mem_controller ctrl = { - .channel0 = {0x50, 0x51}, -}; - -typedef struct _DRAM_CONFIG_DATA { - u8 DramClk; - u8 DramTiming; - u8 CasLatency; - u8 BankIntlv; - u8 Trp; - u8 Tras; - u8 Trcd; - u8 Trfc; - u8 Trrd; - u8 Trtp; - u8 Twtr; - u8 Twr; - - u8 CmdRate; - u8 DualEn; - //u8 IntLv0; - //u8 IntLv1; - //u8 Ba0Sel; - //u8 Ba1Sel; - //u8 Ba2Sel; - u8 BaScmb; - u8 DrdyTiming; - //u8 Above4G; - //u8 RdsaitMode; - //u8 Rdsait; - //u8 TopPerf; - - u16 UMASize; -} DRAM_CONFIG_DATA; - -/*DIMM(assembly) information*/ -typedef struct _DIMM_INFO_tag { - u8 bPresence; - u8 SPDDataBuf[SPD_DATA_SIZE]; /*get all information from spd data */ -} DIMM_INFO; - -typedef struct _DRAM_SYS_ATTR_tag { - DIMM_INFO DimmInfo[MAX_DIMMS]; - - u8 RankPresentMap; /*bit0,1 Rank0,1 on DIMM0, bit2,3 Rank2,3 on DIMM1, - bit4,5 Rank4,5 on DIMM2, bit6,7 Rank6,7 on DIMM3 */ - u8 DimmNumChA; /*Dimm number */ - u8 DimmNumChB; - u8 RankNumChA; /*the number of Ranks on the mortherbaord */ - u8 RankNumChB; - u8 LoadNumChA; /*the number of chips on all DIMM */ - u8 LoadNumChB; - - u8 DramType; /*DDR1 or DDR2 */ - u16 DramFreq; - u16 DramCyc; /*10ns, 7.5ns, 6ns, 5ns, 3.75ns, 3ns, 2.5ns =1/SysFreq, unit: 100*ns. */ - - //u16 HFreq; /*100, 133, 166, 200, 266, 333, 400*/ - - u8 CL; /* CAS lantency */ - u8 CmdRate; /*1T or 2T */ - - u32 RankSize[MAX_RANKS]; - u8 Dual_Channel; - DRAM_CONFIG_DATA ConfigData; - u8 reserved[4]; - -} DRAM_SYS_ATTR; - -typedef struct _DRAM_SIZE_INFO { - u32 RankLength[MAX_RANKS]; -} DRAM_SIZE_INFO; - -//detection.c -/*Step1 detect DRAM type, Read SPD data,command rate*/ -CB_STATUS DRAMDetect(DRAM_SYS_ATTR * DramAttr); -//freq_setting.c -/*Step2 set Frequency, calculate CAL*/ -void DRAMFreqSetting(DRAM_SYS_ATTR * DramAttr); -//timing_setting.c -/*Step3 Set DRAM Timing*/ -void DRAMTimingSetting(DRAM_SYS_ATTR * DramAttr); -//drdy_bl.c -/*Step4 DRDY*/ -void DRAMDRDYSetting(DRAM_SYS_ATTR * DramAttr); -//drdy_bl.c -/*Step5 Burst Length*/ -void DRAMBurstLength(DRAM_SYS_ATTR * DramAttr); -//driving_setting.c -/*Step6 DRAM Driving Adjustment*/ -void DRAMDriving(DRAM_SYS_ATTR * DramAttr); - -//clk_ctrl.c -/*Step7 duty cycle control*/ -void DutyCycleCtrl(DRAM_SYS_ATTR * DramAttr); -//clk_ctrl.c -/*Step8 DRAM clock phase and delay control*/ -void DRAMClkCtrl(DRAM_SYS_ATTR * DramAttr); - -//dev_init.c -/*Step9 set register before init DRAM device*/ -void DRAMRegInitValue(DRAM_SYS_ATTR * DramAttr); - -//dev_init.c -/*Step10 DDR and DDR2 initialize process*/ -void DRAMInitializeProc(DRAM_SYS_ATTR * DramAttr); - -//dqs_search.c -/*Step11 Search DQS and DQ output delay*/ -void DRAMDQSOutputSearch(DRAM_SYS_ATTR * DramAttr); - -//dqs_search.c -/*Step12 Search DQS input delay*/ -void DRAMDQSInputSearch(DRAM_SYS_ATTR * DramAttr); - -//rank_map.c -/*Step13 Interleav function in rankmap.c*/ -void DRAMBankInterleave(DRAM_SYS_ATTR * DramAttr); - -//rank_map.c -/*Step14 Sizing*/ -void DRAMSizingMATypeM(DRAM_SYS_ATTR * DramAttr); - - -//final_setting.c -/*Step15 DDR fresh counter setting*/ -void DRAMRefreshCounter(DRAM_SYS_ATTR * DramAttr); - -//final_setting.c -/*Step16 Final register setting for improve performance*/ -void DRAMRegFinalValue(DRAM_SYS_ATTR * DramAttr); - - -/*set UMA*/ -void SetUMARam(); - -CB_STATUS InstallMemory(DRAM_SYS_ATTR * DramAttr, u32 RamSize); -CB_STATUS DDR2_DRAM_INIT(); - -#endif diff --git a/src/northbridge/via/vx800/ddr2init/dram_util.c b/src/northbridge/via/vx800/ddr2init/dram_util.c deleted file mode 100644 index d09acdaf6f..0000000000 --- a/src/northbridge/via/vx800/ddr2init/dram_util.c +++ /dev/null @@ -1,249 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -void WaitMicroSec(UINTN MicroSeconds) -{ - u32 i; - - for (i = 0; i < 1024 * MicroSeconds; i++) { - __asm__ volatile ("nop\n\t"); - } - - return; -} - -/*=================================================================== -Function : via_write_phys() -Precondition : -Input : addr - value -Output : void -Purpose : -Reference : None -===================================================================*/ - -void via_write_phys(volatile u32 addr, volatile u32 value) -{ - volatile u32 *ptr; - ptr = (volatile u32 *) addr; - *ptr = (volatile u32) value; -} - -/*=================================================================== -Function : via_read_phys() -Precondition : -Input : addr -Output : u32 -Purpose : -Reference : None -===================================================================*/ - -u32 via_read_phys(volatile u32 addr) -{ - volatile u32 *ptr; - volatile u32 y; -// ptr = (volatile u32 *)addr; - y = *(volatile u32 *) addr; -// return *ptr; - return y; -} - - -/*=================================================================== -Function : DimmRead() -Precondition : -Input : x -Output : u32 -Purpose : -Reference : None -===================================================================*/ - -u32 DimmRead(volatile u32 x) -{ // volatile u32 z; - volatile u32 y; - y = *(volatile u32 *) x; - - return y; -} - - -/*=================================================================== -Function : DramBaseTest() -Precondition : this function used to verify memory -Input : - BaseAdd, - length, - mode -Output : u32 -Purpose :write into and read out to verify if dram is correct -Reference : None -===================================================================*/ -BOOLEAN DramBaseTest(u32 BaseAdd, u32 Length, - DRAM_TEST_MODE Mode, BOOLEAN PrintFlag) -{ - u32 TestSpan; - u32 Data, Address, Address2; - u8 i, TestCount; - - //decide the test mode is continous or step - if (Mode == EXTENSIVE) { - //the test mode is continuos and must test each unit - TestSpan = 4; - TestCount = 1; - } else if (Mode == SPARE) { - // the test mode is step and test some unit - TestSpan = STEPSPAN; - TestCount = TESTCOUNT; - } else { - PRINT_DEBUG_MEM("the test mode is error\r"); - return FALSE; - } - - //write each test unit the value with TEST_PATTERN - for (Address = BaseAdd; Address < BaseAdd + Length; - Address += TestSpan) { - for (i = 0; i < TestCount; i++) - via_write_phys(Address + i * 4, TEST_PATTERN); - if (PrintFlag) { - if ((u32) Address % 0x10000000 == 0) { - PRINT_DEBUG_MEM("Write in Addr ="); - PRINT_DEBUG_MEM_HEX32(Address); - PRINT_DEBUG_MEM("\r"); - } - } - } - - //compare each test unit with the value of TEST_PATTERN - //and write it with compliment of TEST_PATTERN - for (Address = BaseAdd; Address < BaseAdd + Length; - Address += TestSpan) { - for (i = 0; i < TestCount; i++) { - Data = via_read_phys(Address + i * 4); - via_write_phys(Address + i * 4, - (u32) (~TEST_PATTERN)); - if (Data != TEST_PATTERN) { - PRINT_DEBUG_MEM - ("TEST_PATTERN ERROR !!!!! "); - Address2 = Address + i * 4; - PRINT_DEBUG_MEM_HEX32(Address2); - PRINT_DEBUG_MEM(" : "); - PRINT_DEBUG_MEM_HEX32(Data); - PRINT_DEBUG_MEM(" \r"); - return FALSE; - } - } - if (PrintFlag) { - if ((u32) Address % 0x10000000 == 0) { - PRINT_DEBUG_MEM("Write in Addr ="); - PRINT_DEBUG_MEM_HEX32(Address); - PRINT_DEBUG_MEM("\r"); - } - } - } - - - //compare each test unit with the value of ~TEST_PATTERN - for (Address = BaseAdd; Address < BaseAdd + Length; - Address += TestSpan) { - for (i = (u8) (TestCount); i > 0; i--) { - Data = via_read_phys(Address + (i - 1) * 4); - if (Data != ~TEST_PATTERN) { - - PRINT_DEBUG_MEM - ("~TEST_PATTERN ERROR !!!!! "); - Address2 = Address + (i - 1) * 4; - PRINT_DEBUG_MEM_HEX32(Address2); - PRINT_DEBUG_MEM(" : "); - PRINT_DEBUG_MEM_HEX32(Data); - PRINT_DEBUG_MEM(" \r"); - return FALSE; - } - } - } - - return TRUE; -} - -/*=================================================================== -Function : DumpRegisters() -Precondition : -Input : - pPCIPPI, - DevNum, - FuncNum -Output : Void -Purpose : -Reference : None -===================================================================*/ - -void DumpRegisters(INTN DevNum, INTN FuncNum) -{ - INTN i, j; - u8 ByteVal; - - ByteVal = 0; - //pci_write_config8(PCI_DEV(0, DevNum, FuncNum), 0xA1, ByteVal); - PRINT_DEBUG_MEM("\rDev %02x Fun %02x\r"); - PRINT_DEBUG_MEM - ("\r 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f\r"); - PRINT_DEBUG_MEM - ("---------------------------------------------------\r"); - for (i = 0; i < 0x10; i++) { - PRINT_DEBUG_MEM_HEX32(i); - for (j = 0; j < 0x10; j++) { - ByteVal = - pci_read_config8(PCI_DEV(0, DevNum, FuncNum), - i * 0x10 + j); - PRINT_DEBUG_MEM_HEX8(ByteVal); - PRINT_DEBUG_MEM(" "); - - } - PRINT_DEBUG_MEM("\r"); - } - return; -} - - -/*=================================================================== -Function : dumpnorth() -Precondition : -Input : - pPCIPPI, - Func -Output : Void -Purpose : -Reference : None -===================================================================*/ - -void dumpnorth(u8 Func) -{ - u16 r, c; - u8 ByteVal; - PRINT_DEBUG_MEM("Dump North!!!\r"); - for (r = 0; r < 32; r++) { - for (c = (u16) (r << 3); c < (r << 3) + 8; c++) { - ByteVal = 0; - ByteVal = pci_read_config8(PCI_DEV(0, 0, Func), c); - PRINT_DEBUG_MEM_HEX16(c); - PRINT_DEBUG_MEM("= "); - PRINT_DEBUG_MEM_HEX8(ByteVal); - } - PRINT_DEBUG_MEM("\r"); - } -} diff --git a/src/northbridge/via/vx800/ddr2init/dram_util.h b/src/northbridge/via/vx800/ddr2init/dram_util.h deleted file mode 100644 index 725fd670fc..0000000000 --- a/src/northbridge/via/vx800/ddr2init/dram_util.h +++ /dev/null @@ -1,47 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -#ifndef __DRAM_UTIL_H__ -#define __DRAM_UTIL_H__ - -#define STEPSPAN 0x1000 //the span when test memory in spare mode -#define TESTCOUNT 0x4 // the test count in each range when test memory in spare mode -#define TEST_PATTERN 0x5A5A5A5A //the test pattern - -typedef enum __DRAM_TEST_MODE { - EXTENSIVE, - SPARE, - MAXMODE -} DRAM_TEST_MODE; - -void WaitMicroSec(UINTN MicroSeconds); - -void via_write_phys(u32 addr, u32 value); - -u32 via_read_phys(u32 addr); - -u32 DimmRead(u32 x); - -BOOLEAN DramBaseTest(u32 BaseAdd, u32 Length, - DRAM_TEST_MODE mode, BOOLEAN PrintFlag); - -void DumpRegisters(INTN DevNum, INTN FuncNum); - -void dumpnorth(u8 Func); -#endif diff --git a/src/northbridge/via/vx800/ddr2init/translator_ddr2_init.c b/src/northbridge/via/vx800/ddr2init/translator_ddr2_init.c deleted file mode 100644 index cb54aba1af..0000000000 --- a/src/northbridge/via/vx800/ddr2init/translator_ddr2_init.c +++ /dev/null @@ -1,34 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -#define CB_SUCCESS 0x0 -#define CB_INVALID_PARAMETER 0x2 -#define CB_NOT_READY 0x6 -#define CB_DEVICE_ERROR 0x7 -#define TRUE 1 -#define FALSE 0 - - -typedef int8_t INT8; -typedef unsigned long uintn_t; -typedef uintn_t UINTN; -typedef long intn_t; -typedef intn_t INTN; -typedef UINTN CB_STATUS; -typedef uint8_t BOOLEAN; diff --git a/src/northbridge/via/vx800/ddr2init/vx800/clk_ctrl.c b/src/northbridge/via/vx800/ddr2init/vx800/clk_ctrl.c deleted file mode 100644 index 13edc1f996..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/clk_ctrl.c +++ /dev/null @@ -1,312 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -void DutyCycleCtrl(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 FreqId; - u8 i; - - if (DIMMFREQ_800 == DramAttr->DramFreq) - FreqId = 2; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - FreqId = 3; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - FreqId = 4; - else if (DIMMFREQ_400 == DramAttr->DramFreq) - FreqId = 5; - else - FreqId = 5; - - if (DramAttr->RankNumChA > 0) { // 1 rank - for (i = 0; i < DUTY_CYCLE_REG_NUM; i++) { - Data = - pci_read_config8(MEMCTRL, - ChA_Duty_Control_DDR2[i][0]); - Data &= ChA_Duty_Control_DDR2[i][1]; /*Mask */ - Data |= ChA_Duty_Control_DDR2[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - ChA_Duty_Control_DDR2[i][0], - Data); - } - } - if (1 == ENABLE_CHC) { // 1 rank - for (i = 0; i < DUTY_CYCLE_REG_NUM; i++) { - Data = - pci_read_config8(MEMCTRL, - ChB_Duty_Control_DDR2[i][0]); - Data &= ChB_Duty_Control_DDR2[i][1]; /*Mask */ - Data |= ChB_Duty_Control_DDR2[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - ChB_Duty_Control_DDR2[i][0], - Data); - } - } - -} - -/* -DRAM clock phase and delay control -*/ -//sub routine list -void ClkPhsCtrlFBMDDR2(DRAM_SYS_ATTR * DramAttr); - -void WrtDataPhsCtrl(DRAM_SYS_ATTR * DramAttr); - -void DQDQSOutputDlyCtrl(DRAM_SYS_ATTR * DramAttr); - -void DQSInputCaptureCtrl(DRAM_SYS_ATTR * DramAttr); - -void DCLKPhsCtrl(DRAM_SYS_ATTR * DramAttr); - - -void DRAMClkCtrl(DRAM_SYS_ATTR * DramAttr) -{ - /*write data clock phase control */ - WrtDataPhsCtrl(DramAttr); - /*clock phase control */ - ClkPhsCtrlFBMDDR2(DramAttr); - /**/ DQDQSOutputDlyCtrl(DramAttr); - /**/ DQSInputCaptureCtrl(DramAttr); - DCLKPhsCtrl(DramAttr); -} - -void ClkPhsCtrlFBMDDR2(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - - u8 FreqId, i; - - if (DramAttr->DramFreq == DIMMFREQ_800) - FreqId = 2; - else if (DramAttr->DramFreq == DIMMFREQ_667) - FreqId = 3; - else if (DramAttr->DramFreq == DIMMFREQ_533) - FreqId = 4; - else if (DramAttr->DramFreq == DIMMFREQ_400) - FreqId = 5; - else - FreqId = 5; - /*channel A */// 2~4 Rank - if (DramAttr->RankNumChA == 1) { // 1 rank - for (i = 0; i < 3; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChA_Clk_Phase_Table_1R[i] - [0]); - Data &= DDR2_ChA_Clk_Phase_Table_1R[i][1]; /*Mask */ - Data |= DDR2_ChA_Clk_Phase_Table_1R[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChA_Clk_Phase_Table_1R[i] - [0], Data); - } - } else if (DramAttr->RankNumChA > 1) { // 2~4 Rank - for (i = 0; i < 3; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChA_Clk_Phase_Table_2R[i] - [0]); - Data &= DDR2_ChA_Clk_Phase_Table_2R[i][1]; /*Mask */ - Data |= DDR2_ChA_Clk_Phase_Table_2R[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChA_Clk_Phase_Table_2R[i] - [0], Data); - } - } -#if ENABLE_CHB - if (DramAttr->RankNumChB > 0) { // 1 rank - for (i = 0; i < 3; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChB_Clk_Phase_Table_1R[i] - [0]); - Data &= DDR2_ChB_Clk_Phase_Table_1R[i][1]; /*Mask */ - Data |= DDR2_ChB_Clk_Phase_Table_1R[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChB_Clk_Phase_Table_1R[i] - [0], Data); - } - } -#endif -} - -void WrtDataPhsCtrl(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 FreqId, i; - - - if (DIMMFREQ_800 == DramAttr->DramFreq) - FreqId = 2; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - FreqId = 3; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - FreqId = 4; - else if (DIMMFREQ_400 == DramAttr->DramFreq) - FreqId = 5; - else - FreqId = 5; - - if (DramAttr->RankNumChA > 0) { // 1 rank - for (i = 0; i < WrtData_REG_NUM; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChA_WrtData_Phase_Table - [i][0]); - Data &= DDR2_ChA_WrtData_Phase_Table[i][1]; /*Mask */ - Data |= DDR2_ChA_WrtData_Phase_Table[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChA_WrtData_Phase_Table[i] - [0], Data); - } - } -#if ENABLE_CHB - if (DramAttr->RankNumChB > 0) { // 1 rank - for (i = 0; i < WrtData_REG_NUM; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChB_WrtData_Phase_Table - [i][0]); - Data &= DDR2_ChB_WrtData_Phase_Table[i][1]; /*Mask */ - Data |= DDR2_ChB_WrtData_Phase_Table[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChB_WrtData_Phase_Table[i] - [0], Data); - } - } -#endif - Data = pci_read_config8(MEMCTRL, 0x8C); - Data &= 0xFC; - Data |= 0x03; - pci_write_config8(MEMCTRL, 0x8C, Data); -} - -void DQDQSOutputDlyCtrl(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 FreqId; - - if (DIMMFREQ_400 == DramAttr->DramFreq) - FreqId = 0; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - FreqId = 1; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - FreqId = 2; - else if (DIMMFREQ_800 == DramAttr->DramFreq) - FreqId = 2; - else - FreqId = 0; - if (DramAttr->RankNumChA > 0) { - Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][0]; - pci_write_config8(MEMCTRL, 0xf0, Data); - - Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][1]; - pci_write_config8(MEMCTRL, 0xf1, Data); - - Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][2]; - pci_write_config8(MEMCTRL, 0xf2, Data); - - Data = DDR2_CHA_DQ_DQS_Delay_Table[FreqId][3]; - pci_write_config8(MEMCTRL, 0xf3, Data); - } -#if ENABLE_CHB - if (DramAttr->RankNumChB > 0) { - Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][0]; - pci_write_config8(MEMCTRL, 0xf4, Data); - - Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][1]; - pci_write_config8(MEMCTRL, 0xf5, Data); - - Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][2]; - pci_write_config8(MEMCTRL, 0xf6, Data); - - Data = DDR2_CHB_DQ_DQS_Delay_Table[FreqId][3]; - pci_write_config8(MEMCTRL, 0xf7, Data); - } -#endif -} - -void DQSInputCaptureCtrl(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 FreqId, i; - - if (DIMMFREQ_800 == DramAttr->DramFreq) - FreqId = 2; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - FreqId = 3; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - FreqId = 4; - else if (DIMMFREQ_400 == DramAttr->DramFreq) - FreqId = 5; - else - FreqId = 2; - - Data = 0x8A; - pci_write_config8(MEMCTRL, 0x77, Data); - - if (DramAttr->RankNumChA > 0) { // 1 rank - for (i = 0; i < DQS_INPUT_CAPTURE_REG_NUM; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChA_DQS_Input_Capture_Tbl - [i][0]); - Data &= DDR2_ChA_DQS_Input_Capture_Tbl[i][1]; /*Mask */ - Data |= DDR2_ChA_DQS_Input_Capture_Tbl[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChA_DQS_Input_Capture_Tbl[i] - [0], Data); - } - } -#if ENABLE_CHB - if (DramAttr->RankNumChB > 0) { // 1 rank - for (i = 0; i < DQS_INPUT_CAPTURE_REG_NUM; i++) { - Data = - pci_read_config8(MEMCTRL, - DDR2_ChB_DQS_Input_Capture_Tbl - [i][0]); - Data &= DDR2_ChB_DQS_Input_Capture_Tbl[i][1]; /*Mask */ - Data |= DDR2_ChB_DQS_Input_Capture_Tbl[i][FreqId]; /*set Value */ - pci_write_config8(MEMCTRL, - DDR2_ChB_DQS_Input_Capture_Tbl[i] - [0], Data); - } - } -#endif -} - -//This is very important, if you don't set it correctly, dram will be unreliable -//set DCLK Phase control(Reg99H[6:1]) according the DDRII in the dimm -void DCLKPhsCtrl(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - - Data = 0; - Data = pci_read_config8(MEMCTRL, 0x99); - Data &= 0xE1; - //DDR in Dimm1, MCLKOA[4,3,0] will output MCLK - if (DramAttr->RankPresentMap & 0x03) - Data |= 0x09 << 1; - //DDR in Dimm2, MCLKOA[5,2,1] will output MCLK - if (DramAttr->RankPresentMap & 0x0C) - Data |= 0x06 << 1; - - pci_write_config8(MEMCTRL, 0x99, Data); - -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/detection.c b/src/northbridge/via/vx800/ddr2init/vx800/detection.c deleted file mode 100644 index 63fc56b845..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/detection.c +++ /dev/null @@ -1,192 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -#define SMBUS_ADDR_CH_A_1 0xA0 // Dimmx -#define SMBUS_ADDR_CH_A_2 0xA2 // Dimmx -#define SMBUS_ADDR_CH_B_1 0xA4 // Dimmx -#define SMBUS_ADDR_CH_B_2 0xA6 // Dimmx - -/*read data*/ -CB_STATUS GetSPDData(u8 Slot, u8 Length, u8 * Buf); - -void DRAMCmdRate(DRAM_SYS_ATTR * DramAttr); - - - -CB_STATUS GetInfoFromSPD(DRAM_SYS_ATTR * DramAttr); - -CB_STATUS GetSPDData(u8 Slot, u8 Length, u8 * Buf) -{ - // CB_STATUS Status = CB_NOT_READY; - u8 Val; - u8 i; - - if (1 > Length || NULL == Buf) - return CB_INVALID_PARAMETER; - - for (i = 0; i < Length; i++) { - Val = get_spd_data(ctrl.channel0[Slot], i); - *(Buf + i) = Val; - } - return CB_SUCCESS; -} - -CB_STATUS DRAMDetect(DRAM_SYS_ATTR * DramAttr) -{ - CB_STATUS Status = CB_SUCCESS; - - PRINT_DEBUG_MEM("Dram Detection \r"); - - /*Read D0F3Rx6C , detect memory type DDR1 or DDR2 */ - // 353 supports DDR2 only - DramAttr->DramType = RAMTYPE_SDRAMDDR2; - /*get information for SPD */ - Status = GetInfoFromSPD(DramAttr); - if (CB_SUCCESS == Status) { - /*64bit or 128Bit */ - // - // if (RAMTYPE_SDRAMDDR == DramAttr->DramType) - - /*select command rate */ - DRAMCmdRate(DramAttr); - } - return Status; -} - - -// Determine 1T or 2T Command Rate: -// To enable 1T command Rate, the system will satisfy the following 3 conditions: -// 1. Each DRAM channel may have 1 or 2 ranks of DIMM. 3/4 ranks can not support 1T command rate -// It's for loading issue. 1T can supports (a). only one socket with two ranks OR -// (b). two sockets each with 1 rank. -// 2. User wishes to enable 1T command rate mode and turn on by Setup menu -// 3. If 1T command rate can be enabled, just set EBP bit here. -void DRAMCmdRate(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - - // 5.1t/2t command rate, use the stable set - //offset50 - DramAttr->CmdRate = 2; - Data = pci_read_config8(MEMCTRL, 0x50); - Data = (u8) (Data & 0xEE); - pci_write_config8(MEMCTRL, 0x50, Data); -} - -/*get SPD data and set RANK presence map*/ -/* -Sockets0,1 is Channel A / Sockets2,3 is Channel B -socket0 SPD device address 0x50 / socket1 SPD device address 0x51 -socket2 SPD device address 0x52 / socket3 SPD device address 0x53 -*/ -CB_STATUS GetInfoFromSPD(DRAM_SYS_ATTR * DramAttr) -{ - CB_STATUS Status; - u8 *pSPDDataBuf; - u8 ModuleDataWidth; - u8 ChipWidth; - u8 RankNum; - u8 LoadNum; - u8 Sockets, i; - BOOLEAN bFind; - bFind = FALSE; - Status = CB_DEVICE_ERROR; - - for (Sockets = 0; Sockets < MAX_SOCKETS; Sockets++) { - pSPDDataBuf = DramAttr->DimmInfo[Sockets].SPDDataBuf; - pSPDDataBuf[SPD_MEMORY_TYPE] = - get_spd_data(ctrl.channel0[Sockets], SPD_MEMORY_TYPE); - if (pSPDDataBuf[SPD_MEMORY_TYPE] == 0) { - Status = CB_NOT_READY; - } else { - Status = - GetSPDData(Sockets, SPD_DATA_SIZE, - pSPDDataBuf); - PRINT_DEBUG_MEM("SPD : \r"); - for (i = 0; i < SPD_DATA_SIZE; i++) { - PRINT_DEBUG_MEM(" "); - PRINT_DEBUG_MEM_HEX8(pSPDDataBuf[i]); - } - } - if (CB_SUCCESS == Status) { - /*if Dram Controller detected type not same as the type got from SPD, There are ERROR */ - if (pSPDDataBuf[SPD_MEMORY_TYPE] != - DramAttr->DramType) { - Status = CB_DEVICE_ERROR; /*Memory int error */ - PRINT_DEBUG_MEM - ("Memory Device ERROR: Dram Controller detected type != type got from SPD \r"); - break; - } - DramAttr->DimmInfo[Sockets].bPresence = TRUE; - /*calculate load number (chips number) */ - ModuleDataWidth = - (u8) (DramAttr->DimmInfo[Sockets]. - SPDDataBuf[SPD_SDRAM_MOD_DATA_WIDTH + - 1]); - ModuleDataWidth = (u8) (ModuleDataWidth << 8); - ModuleDataWidth |= - (u8) (DramAttr->DimmInfo[Sockets]. - SPDDataBuf[SPD_SDRAM_MOD_DATA_WIDTH]); - ChipWidth = - (u8) ((DramAttr->DimmInfo[Sockets]. - SPDDataBuf[SPD_SDRAM_WIDTH]) & 0x7F); - LoadNum = (u8) (ModuleDataWidth / ChipWidth); - - /*set the RANK map */ - RankNum = (u8) (pSPDDataBuf[SPD_SDRAM_DIMM_RANKS] & 0x3); /*get bit0,1, the Most number of supported RANK is 2 */ - if (RAMTYPE_SDRAMDDR2 == DramAttr->DramType) - RankNum++; /*for DDR bit[0,1] 01->1 RANK 10->2 RANK; for DDR2 bit[0,1] = 00 -> 1 RANK 01 -> 2 RANK */ - if (RankNum != 2 && RankNum != 1) { /*every DIMM have 1 or 2 ranks */ - Status = CB_DEVICE_ERROR; - PRINT_DEBUG_MEM - ("Memory Device ERROR: the number of RANK not support!\r"); - break; - } - - if (Sockets < 2) { /*sockets0,1 is channel A */ - DramAttr->RankNumChA = - (u8) (DramAttr->RankNumChA + RankNum); - DramAttr->DimmNumChA++; - DramAttr->LoadNumChA = - (u8) (DramAttr->LoadNumChA * LoadNum * - RankNum); - } else { /*sockets2,3 is channel B */ - - DramAttr->RankNumChB = - (u8) (DramAttr->RankNumChB + RankNum); - DramAttr->DimmNumChB++; - DramAttr->LoadNumChB = - (u8) (DramAttr->LoadNumChB * LoadNum * - RankNum);; - } - RankNum |= 1; /*set rank map */ - DramAttr->RankPresentMap |= - (RankNum << (Sockets * 2)); - bFind = TRUE; - } - } - PRINT_DEBUG_MEM("Rank Present Map:"); - PRINT_DEBUG_MEM_HEX8(DramAttr->RankPresentMap); - PRINT_DEBUG_MEM("\r"); - - if (bFind) - Status = CB_SUCCESS; - - return Status; -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/dev_init.c b/src/northbridge/via/vx800/ddr2init/vx800/dev_init.c deleted file mode 100644 index bb0232589d..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/dev_init.c +++ /dev/null @@ -1,1318 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -void DRAMSetVRNum(DRAM_SYS_ATTR * DramAttr, u8 PhyRank, // Physical Rank - u8 VirRank, // Virtual Rank - BOOLEAN Enable); - -void SetEndingAddr(DRAM_SYS_ATTR * DramAttr, u8 VirRank, // Ending address register number indicator (INDEX - INT8 Value // (value) add or subtract value to this and after banks - ); - -void InitDDR2CHA(DRAM_SYS_ATTR * DramAttr); - -void InitDDR2CHB(DRAM_SYS_ATTR * DramAttr); - -void InitDDR2CHC(DRAM_SYS_ATTR * DramAttr); - -CB_STATUS VerifyChc(); -/*=================================================================== -Function : DRAMRegInitValue() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : Set necessary register before DRAM initialize -===================================================================*/ - -static const u8 DramRegTbl[][3] = { - //Register AND OR - {0x50, 0x11, 0xEE}, // DDR default MA7 for DRAM init - {0x51, 0x11, 0x60}, // DDR default MA3 for CHB init - {0x52, 0x00, 0x33}, // DDR use BA0=M17, BA1=M18, - {0x53, 0x00, 0x3F}, // DDR BA2=M19 - - {0x54, 0x00, 0x00}, // default PR0=VR0; PR1=VR1 - {0x55, 0x00, 0x00}, // default PR2=VR2; PR3=VR3 - {0x56, 0x00, 0x00}, // default PR4=VR4; PR5=VR5 - {0x57, 0x00, 0x00}, // default PR4=VR4; PR5=VR5 - - {0x60, 0x00, 0x00}, // disable fast turn-around - {0x65, 0x00, 0xD9}, // AGP timer = 0XD; Host timer = 8; - {0x66, 0x00, 0x88}, //DRAMC Queue Size = 4; park at the last bus owner,Priority promotion timer = 8 - {0x68, 0x00, 0x0C}, - {0x69, 0xF0, 0x04}, // set RX69[3:0]=0000b - {0x6A, 0x00, 0x00}, // refresh counter - {0x6E, 0xF8, 0x80}, //must set 6E[7],or else DDR2 probe test will fail - // In here, we not set RX70~RX74, because we just init DRAM but no need R/W DRAM, - // when we check DQS input/output delay, then we need R/W DRAM. - - //{0x79, 0x00, 0x8F }, - {0x85, 0x00, 0x00}, - // {0x90, 0x87, 0x78 }, - // {0x91, 0x00, 0x46 }, - {0x40, 0x00, 0x00}, - {0, 0, 0} -}; - -void DRAMRegInitValue(DRAM_SYS_ATTR * DramAttr) -{ - u8 Idx, CL; - u8 Data; - - for (Idx = 0; DramRegTbl[Idx][0] != 0; Idx++) { - Data = pci_read_config8(MEMCTRL, DramRegTbl[Idx][0]); - Data &= DramRegTbl[Idx][1]; - Data |= DramRegTbl[Idx][2]; - pci_write_config8(MEMCTRL, DramRegTbl[Idx][0], Data); - } - - Data = 0x80; - pci_write_config8(PCI_DEV(0, 0, 4), 0xa3, Data); - - //set Dram Controllor mode - Data = pci_read_config8(MEMCTRL, 0x6c); - Data &= 0xFB; - if (ENABLE_CHC == 0) { - Data |= 0x4; //only CHA 64 bit mode - pci_write_config8(MEMCTRL, 0x6c, Data); - } else { - Data |= 0x0; //CHA + CHC - pci_write_config8(MEMCTRL, 0x6c, Data); - - //Data = 0xAA; - //pci_write_config8(MEMCTRL, 0xb1, Data); - - //set CHB DQSB input delay, or else will meet error which is some byte is right - //but another bit is error - Data = pci_read_config8(MEMCTRL, 0xff); - Data = (Data & 0x03) | 0x3D; - pci_write_config8(MEMCTRL, 0xff, Data); - - //enable CHC RXDB[7] - //Data=pci_read_config8(MEMCTRL, 0xdb); - // Data = (Data & 0x7F) | 0x80; - //pci_write_config8(MEMCTRL, 0xdb, Data); - - //rx62[2:0],CHA and CHB CL - Data = pci_read_config8(MEMCTRL, 0x62); - CL = Data & 0x07; - - //if CL = 6 , so I set CHB CL = 5 default - if (CL >= 4) - CL = 3; - - // set CHC Read CL rxDC[6:7] - Data = pci_read_config8(MEMCTRL, 0xdc); - Data = (Data & 0x3F) | (CL << 6); - pci_write_config8(MEMCTRL, 0xdc, Data); - // set CHC write CL rxDF[6:7] - Data = pci_read_config8(MEMCTRL, 0xdf); - Data = (Data & 0x3F) | (CL << 6); - pci_write_config8(MEMCTRL, 0xdf, Data); - // set CHC ODT RxDC[5:0] - Data = pci_read_config8(MEMCTRL, 0xdc); - Data = (Data & 0xC0) | 0x03; - pci_write_config8(MEMCTRL, 0xdc, Data); - - //set column type RXDD[6] and enable ODT PAD RXDD[7] - Data = pci_read_config8(MEMCTRL, 0xdd); - Data |= 0x80; - Idx = DramAttr->DimmInfo[2].SPDDataBuf[SPD_SDRAM_COL_ADDR]; - if ((Idx & 0x0F) == 10) - Data |= 0x40; //MA9~MA0 - else - Data &= 0xBF; //MA8~MA0 - pci_write_config8(MEMCTRL, 0xdd, Data); - } - - // Disable read DRAM fast ready ;Rx51[7] - // Disable Read Around Write ;Rx51[6] - - // Disable Consecutive Read ;RX52[1:0] - // disable speculative read - -} - -/*=================================================================== -Function : DRAMInitializeProc() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : DRAM initialize according to the bios porting guid -===================================================================*/ - -#define EXIST_TEST_PATTERN 0x55555555 -#define NOT_EXIST_TEST_PATTERN 0xAAAAAAAA -BOOLEAN ChkForExistLowBank() -{ - u32 *Address, data32; - - // Check Pattern - - Address = (u32 *) 8; - *Address = EXIST_TEST_PATTERN; - Address = (u32 *) 4; - *Address = EXIST_TEST_PATTERN; - -// _asm {WBINVD} - WaitMicroSec(100); - Address = (u32 *) 8; - data32 = *Address; - if (data32 != EXIST_TEST_PATTERN) - return FALSE; - Address = (u32 *) 4; - data32 = *Address; - if (data32 != EXIST_TEST_PATTERN) - return FALSE; - - // Check not Pattern - Address = (u32 *) 8; - *Address = NOT_EXIST_TEST_PATTERN; - Address = (u32 *) 4; - *Address = NOT_EXIST_TEST_PATTERN; - //_asm {WBINVD} - WaitMicroSec(100); - - - Address = (u32 *) 8; - data32 = *Address; - if (data32 != (u32) (NOT_EXIST_TEST_PATTERN)) - return FALSE; - Address = (u32 *) 4; - data32 = *Address; - if (data32 != (u32) (NOT_EXIST_TEST_PATTERN)) - return FALSE; - - return TRUE; -} - -void InitDDR2CHC(DRAM_SYS_ATTR * DramAttr); -void InitDDR2CHB(DRAM_SYS_ATTR * DramAttr); -void DRAMInitializeProc(DRAM_SYS_ATTR * DramAttr) -{ - u8 shift, idx; - BOOLEAN Status; - - shift = 1; - for (idx = 0; idx < MAX_RANKS; idx++) { - if ((DramAttr->RankPresentMap & shift) != 0) { - // Set VR# to physical rank indicated = PR + physical rank enable bit - DRAMSetVRNum(DramAttr, idx, idx, TRUE); - SetEndingAddr(DramAttr, idx, 0x10); // assume 1G size - if (idx < 4) //CHA init - InitDDR2CHA(DramAttr); //temp wjb 2007/1 only for compiling - // in the function InitDDR2,the parameter is no need - Status = ChkForExistLowBank(); - if (Status == TRUE) { - PRINT_DEBUG_MEM(" S\r"); - } else { - PRINT_DEBUG_MEM(" F\r"); - } - // Set VR# to physical rank indicated = 00h + physical rank enable bit - DRAMSetVRNum(DramAttr, idx, 0, FALSE); - SetEndingAddr(DramAttr, idx, -16); - } - shift <<= 1; - } - if (ENABLE_CHC) - InitDDR2CHC(DramAttr); - -} - - -/*=================================================================== -Function : DRAMSetVRNUM() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard - PhyRank: Physical Rank number - VirRank: Virtual Rank number - Enable: Enable/Disable Physical Rank -Output : Void -Purpose : Set virtual rank number for physical rank - Program the specific physical rank with specific virtual rank number - Program when necessary, otherwise don't touch the pr-vr-mapping registers -===================================================================*/ - -void DRAMSetVRNum(DRAM_SYS_ATTR * DramAttr, u8 PhyRank, // Physical Rank - u8 VirRank, // Virtual Rank - BOOLEAN Enable) -{ - u8 Data; - u8 AndData, OrData; - Data = pci_read_config8(MEMCTRL, (0x54 + (PhyRank >> 1))); - - OrData = 0; - if (Enable) - OrData |= 0x08; - OrData |= VirRank; - if ((PhyRank & 0x01) == 0x00) { - AndData = 0x0F; // keep the value of odd rank on PR # is even(keep 1,3,5,7) - OrData <<= 4; // VR #, value to be set - } else { - AndData = 0xF0; // keep the value of even rank on PR # is odd(keep 0,2,4,6) - } - Data &= AndData; - Data |= OrData; - pci_write_config8(MEMCTRL, (0x54 + (PhyRank >> 1)), Data); -} - - -/*=================================================================== -Function : SetEndingAddr() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard - VirRank: Virtual Rank number - Value: (value) add or subtract value to this and after banks -Output : Void -Purpose : Set ending address of virtual rank specified by VirRank -===================================================================*/ - -void SetEndingAddr(DRAM_SYS_ATTR * DramAttr, u8 VirRank, // Ending address register number indicator (INDEX - INT8 Value // (value) add or subtract value to this and after banks - ) { - u8 Data; - - // Read register,Rx40-Rx47(0,1,2,3,4,5,6,7) and set the ending address - Data = pci_read_config8(MEMCTRL, 0x40 + VirRank); - Data = (u8) (Data + Value); - pci_write_config8(MEMCTRL, 0x40 + VirRank, Data); - - //program the virank's begining address to zero - Data = 0x00; - pci_write_config8(MEMCTRL, 0x48 + VirRank, Data); -} - -/*=================================================================== -Function : InitDDR2() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : Initialize DDR2 by standard sequence -===================================================================*/ - -// DLL: Enable Reset -static const u32 CHA_MRS_DLL_150[2] = { 0x00020200, 0x00000800 }; // with 150 ohm (A17=1, A9=1), (A11=1)(cpu address) -static const u32 CHA_MRS_DLL_75[2] = { 0x00020020, 0x00000800 }; // with 75 ohm (A17=1, A5=1), (A11=1)(cpu address) - -// CPU(DRAM) -// { DLL: Enable. A17(BA0)=1 and A3(MA0)=0 } -// { DLL: reset. A11(MA8)=1 } -// -// DDR2 CL=2 CL=3 CL=4 CL=5 CL=6(Burst type=interleave)(WR fine tune in code) -static const u16 CHA_DDR2_MRS_table[5] = { 0x0150, 0x01D0, 0x0250, 0x02D0, 0x350 }; // BL=4 ;Use 1X-bandwidth MA table to init DRAM - -// MA11 MA10(AP) MA9 -#define CHA_MRS_DDR2_TWR2 (0 << 13) + (0 << 20) + (1 << 12) // Value = 001000h -#define CHA_MRS_DDR2_TWR3 (0 << 13) + (1 << 20) + (0 << 12) // Value = 100000h -#define CHA_MRS_DDR2_TWR4 (0 << 13) + (1 << 20) + (1 << 12) // Value = 101000h -#define CHA_MRS_DDR2_TWR5 (1 << 13) + (0 << 20) + (0 << 12) // Value = 002000h -#define CHA_MRS_DDR2_TWR6 (1 << 13) + (0 << 20) + (1 << 12) // Value = 003000h - -// DDR2 Twr=2 Twr=3 Twr=4 Twr=5 -static const u32 CHA_DDR2_Twr_table[5] = - { CHA_MRS_DDR2_TWR2, CHA_MRS_DDR2_TWR3, CHA_MRS_DDR2_TWR4, -CHA_MRS_DDR2_TWR5, CHA_MRS_DDR2_TWR6 }; - -#define CHA_OCD_Exit_150ohm 0x20200 // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=1,MA2=0 (DRAM bus address) -// A17=1, A12=A11=A10=0,A9=1 ,A5=0 (CPU address) -#define CHA_OCD_Default_150ohm 0x21E00 // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=1,MA2=0 (DRAM bus address) -// A17=1, A12=A11=A10=1,A9=1 ,A5=0 (CPU address) -#define CHA_OCD_Exit_75ohm 0x20020 // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=0,MA2=1 (DRAM bus address) -// A17=1, A12=A11=A10=0,A9=0 ,A5=1 (CPU address) -#define CHA_OCD_Default_75ohm 0x21C20 // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=0,MA2=1 (DRAM bus address) -// A17=1, A12=A11=A10=1,A9=0 ,A5=1 (CPU address) - -void InitDDR2CHA(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 Reg6BVal; - u8 Idx, CL, BL, Twr; - u32 AccessAddr; - u8 DimmNum; - - // step2. - //disable bank paging and multi page - Data = pci_read_config8(MEMCTRL, 0x69); - Data &= ~0x03; - pci_write_config8(MEMCTRL, 0x69, Data); - - Reg6BVal = pci_read_config8(MEMCTRL, 0x6b); - Reg6BVal &= ~0x07; - // Step 3. - // At least one NOP cycle will be issued after the 1m sec device deselect. - Data = Reg6BVal | 0x01; - pci_write_config8(MEMCTRL, 0x6b, Data); - - // step4. - //Read a double word from any address of the DIMM - DimmRead(0x0); - - // Step 5. - // A minimum pause of 200u sec will be provided after the NOP. - // - <<< reduce BOOT UP time >>> - - // Loop 200us - for (Idx = 0; Idx < 0x10; Idx++) - WaitMicroSec(100); - - // Step 6. - // Precharge all (PALL) will be issued to the DDR. - Data = Reg6BVal | 0x02; - pci_write_config8(MEMCTRL, 0x6b, Data); - - // Step7. - //Read a double word from any address of the DIMM - DimmRead(0x0); - - // Step 8. - // MSR Eable will be issued to the DDR - Data = Reg6BVal | 0x03; - pci_write_config8(MEMCTRL, 0x6b, Data); - - - // Step 9,10. check ODT value for EMRS(1) command - // according to ODTLookUp_TBL in driving_setting.c if there is one dimm in MB's one channel , the DDR2's ODT is 150ohm - // if there is two dimm in MB's one channel, the DDR2's ODT is 75 ohm - DimmNum = DramAttr->DimmNumChA; - - if (DimmNum == 1) //DDR's ODT is 150ohm - { - AccessAddr = (u32) CHA_MRS_DLL_150[0]; - DimmRead(AccessAddr); //issue EMRS DLL Enable - PRINT_DEBUG_MEM("Step 9 Address "); - PRINT_DEBUG_MEM_HEX32(AccessAddr); - PRINT_DEBUG_MEM("\r"); - - AccessAddr = (u32) CHA_MRS_DLL_150[1]; - DimmRead(AccessAddr); //issue MRS DLL Reset - PRINT_DEBUG_MEM("Step 10 Address "); - PRINT_DEBUG_MEM_HEX32(AccessAddr); - PRINT_DEBUG_MEM("\r"); - } else if (DimmNum == 2) //DDR's ODT is 75ohm - { - AccessAddr = (u32) CHA_MRS_DLL_75[0]; - DimmRead(AccessAddr); //issue EMRS DLL Enable - AccessAddr = (u32) CHA_MRS_DLL_75[1]; - DimmRead(AccessAddr); //issue MRS DLL Reset - } else { - PRINT_DEBUG_MEM("Dimm NUM ERROR:"); - PRINT_DEBUG_MEM_HEX8(DimmNum); - PRINT_DEBUG_MEM("\r"); - } - - // Step 11. - // Precharge all (PALL) will be issued to the DDR. - Data = Reg6BVal | 0x02; - pci_write_config8(MEMCTRL, 0x6b, Data); - - // Step12. - //Read a double word from any address of the DIMM - DimmRead(0x0); - - // Step 13. - // Execute 8 CBR refresh - Data = Reg6BVal | 0x04; - pci_write_config8(MEMCTRL, 0x6b, Data); - - // issue 14,15 , 16 - //reads and wait 100us between each read - for (Idx = 0; Idx < 8; Idx++) { - DimmRead(0x0); - WaitMicroSec(100); - } - - // Step 17. - // enable MRS for MAA - Data = Reg6BVal | 0x03; - pci_write_config8(MEMCTRL, 0x6b, Data); - - //Step 18 - //the SDRAM parameters.(Burst Length, CAS# Latency , Write recovery etc.) - //------------------------------------------------------------- - //Burst Length : really offset Rx6c[3] - Data = pci_read_config8(MEMCTRL, 0x6c); - BL = (Data & 0x08) >> 3; - - // CL = really offset RX62[2:0] - Data = pci_read_config8(MEMCTRL, 0x62); - CL = Data & 0x03; - - AccessAddr = (u32) (CHA_DDR2_MRS_table[CL]); - if (BL) { - AccessAddr += 8; - } - //Write recovery : really offset Rx63[7-5] - Data = pci_read_config8(MEMCTRL, 0x63); - Twr = (Data & 0xE0) >> 5; - - AccessAddr += CHA_DDR2_Twr_table[Twr]; - // AccessAddr = 0x1012D8; - DimmRead(AccessAddr); // Set MRS command - PRINT_DEBUG_MEM("Step 18 Address"); - PRINT_DEBUG_MEM_HEX32(AccessAddr); - PRINT_DEBUG_MEM("\r"); - - //Step 19,20 - if (DimmNum == 1) //DDR's ODT is 150ohm - { - AccessAddr = (u32) CHA_OCD_Default_150ohm; - DimmRead(AccessAddr); //issue EMRS OCD Default - PRINT_DEBUG_MEM("Step 19 Address "); - PRINT_DEBUG_MEM_HEX32(AccessAddr); - PRINT_DEBUG_MEM("\r"); - - AccessAddr = (u32) CHA_OCD_Exit_150ohm; - DimmRead(AccessAddr); //issue EMRS OCD Calibration Mode Exit - PRINT_DEBUG_MEM("Step 20 Address "); - PRINT_DEBUG_MEM_HEX32(AccessAddr); - PRINT_DEBUG_MEM("\r"); - } else if (DimmNum == 2) //DDR's ODT is 75ohm - { - AccessAddr = (u32) CHA_OCD_Default_75ohm; - DimmRead(AccessAddr); //issue EMRS OCD Default - AccessAddr = (u32) CHA_OCD_Exit_75ohm; - DimmRead(AccessAddr); //issue EMRS OCD Calibration Mode Exit - } else { - PRINT_DEBUG_MEM("Dimm NUM ERROR: "); - PRINT_DEBUG_MEM_HEX8(DimmNum); - PRINT_DEBUG_MEM("\r"); - } - - //Step 21 - //After MRS the device should be ready for full functionality within 3 clocks - // after Tmrd is met. - Data = Reg6BVal; - pci_write_config8(MEMCTRL, 0x6b, Data); - - // Enable bank paging and multi page - Data = pci_read_config8(MEMCTRL, 0x69); - Data |= 0x03; - pci_write_config8(MEMCTRL, 0x69, Data); -} - -/*=================================================================== -Function : InitDDR2_CHB() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : Initialize DDR2 of CHB by standard sequence -Reference : -===================================================================*/ -/*// DLL: Enable Reset -static const u32 CHB_MRS_DLL_150[2] = { 0x00020200 | (1 << 20), 0x00000800 }; // with 150 ohm (A17=1, A9=1), (A11=1)(cpu address) -//u32 CHB_MRS_DLL_75[2] = { 0x00020020 | (1 << 20), 0x00000800 }; // with 75 ohm (A17=1, A5=1), (A11=1)(cpu address) -// CPU(DRAM) -// { DLL: Enable. A17(BA0)=1 and A3(MA0)=0 } -// { DLL: reset. A11(MA8)=1 } -// -// DDR2 CL=2 CL=3 CL=4 CL=5 (Burst type=interleave)(WR fine tune in code) -static const u16 CHB_DDR2_MRS_table[4] ={ 0x0150, 0x01D0, 0x0250, 0x02D0 }; // BL=4 ;Use 1X-bandwidth MA table to init DRAM - -// MA11 MA10(AP) MA9 -#define CHB_MRS_DDR2_TWR2 (0 << 13) + (0 << 20) + (1 << 12) // Value = 001000h -#define CHB_MRS_DDR2_TWR3 (0 << 13) + (1 << 20) + (0 << 12) // Value = 100000h -#define CHB_MRS_DDR2_TWR4 (0 << 13) + (1 << 20) + (1 << 12) // Value = 101000h -#define CHB_MRS_DDR2_TWR5 (1 << 13) + (0 << 20) + (0 << 12) // Value = 002000h -#define CHB_MRS_DDR2_TWR6 (1 << 13) + (0 << 20) + (1 << 12) // Value = 003000h - -// DDR2 Twr=2 Twr=3 Twr=4 Twr=5 -static const u32 CHB_DDR2_Twr_table[5] = { CHB_MRS_DDR2_TWR2, CHB_MRS_DDR2_TWR3, CHB_MRS_DDR2_TWR4, CHB_MRS_DDR2_TWR5, CHB_MRS_DDR2_TWR6 }; - -#define CHB_OCD_Exit_150ohm 0x20200 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=1,MA2=0 (DRAM bus address) -// A17=1, A12=A11=A10=0,A9=1 ,A5=0 (CPU address) -#define CHB_OCD_Default_150ohm 0x21E00 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=1,MA2=0 (DRAM bus address) -// A17=1, A12=A11=A10=1,A9=1 ,A5=0 (CPU address) -//#define CHB_OCD_Exit_75ohm 0x20020 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=0,MA2=1 (DRAM bus address) -// A17=1, A12=A11=A10=0,A9=0 ,A5=1 (CPU address) -//#define CHB_OCD_Default_75ohm 0x21C20 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=0,MA2=1 (DRAM bus address) -// A17=1, A12=A11=A10=1,A9=0 ,A5=1 (CPU address) -void InitDDR2CHB( - DRAM_SYS_ATTR *DramAttr - ) - -{ - u8 Data; - u8 Idx, CL, BL, Twr; - u32 AccessAddr; - - Data = 0x80; - pci_write_config8(MEMCTRL, 0x54, Data); - - // step3. - //disable bank paging and multi page - Data=pci_read_config8(MEMCTRL, 0x69); - Data &= ~0x03; - pci_write_config8(MEMCTRL, 0x69, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step 4. Initialize CHB begin - Data=pci_read_config8(MEMCTRL, 0xd3); - Data |= 0x40; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //Step 5. NOP command enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x08; - pci_write_config8(MEMCTRL, 0xd7, Data); - - //Step 6. issue a nop cycle,RegD3[7] 0 -> 1 - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - - // Step 7. - // A minimum pause of 200u sec will be provided after the NOP. - // - <<< reduce BOOT UP time >>> - - // Loop 200us - for (Idx = 0; Idx < 0x10; Idx++) - WaitMicroSec(10); - - // Step 8. - // all banks precharge command enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x10; - pci_write_config8(MEMCTRL, 0xd7, Data); - - //step 9. issue a precharge all cycle,RegD3[7] 0 -> 1 - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step10. EMRS enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x18; - pci_write_config8(MEMCTRL, 0xd7, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xC7; - Data |= 0x08; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step11. EMRS DLL Enable and Disable DQS - AccessAddr = CHB_MRS_DLL_150[0] >> 3; - Data =(u8) (AccessAddr & 0xff); - pci_write_config8(MEMCTRL, 0xd9, Data); - - Data = (u8)((AccessAddr & 0xff00) >> 8); - pci_write_config8(MEMCTRL, 0xda, Data); - - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xF9; - Data |= (u8)((AccessAddr & 0x30000) >> 15); - pci_write_config8(MEMCTRL, 0xd7, Data); - - //step12. issue EMRS cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step13. MSR enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x18; - pci_write_config8(MEMCTRL, 0xd7, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xC7; - Data |= 0x00; - pci_write_config8(MEMCTRL, 0xd3, Data); - - - //step 14. MSR DLL Reset - AccessAddr = CHB_MRS_DLL_150[1] >> 3; - Data =(u8) (AccessAddr & 0xff); - pci_write_config8(MEMCTRL, 0xd9, Data); - - Data = (u8)((AccessAddr & 0xff00) >> 8); - pci_write_config8(MEMCTRL, 0xda, Data); - - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xF9; - Data |= (u8)((AccessAddr & 0x30000) >> 15); - pci_write_config8(MEMCTRL, 0xd7, Data); - - //step15. issue MRS cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //clear the address - Data = 0x00; - pci_write_config8(MEMCTRL, 0xda, Data); - - //step16. all banks precharge command enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x10; - pci_write_config8(MEMCTRL, 0xd7, Data); - - - // step17. issue precharge all cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step18. CBR cycle enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x20; - pci_write_config8(MEMCTRL, 0xd7, Data); - - //step 19.20.21 - //repeat issue 8 CBR cycle, between each cycle stop 100us - for (Idx = 0; Idx < 8; Idx++) - { - // issue CBR cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - WaitMicroSec(200); - } - - //step22. MSR enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x18; - pci_write_config8(MEMCTRL, 0xd7, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xC7; - Data |= 0x00; - pci_write_config8(MEMCTRL, 0xd3, Data); - - - - //the SDRAM parameters.(Burst Length, CAS# Latency , Write recovery etc.) - //------------------------------------------------------------- - //Burst Length : really offset Rx6c[1] - Data=pci_read_config8(MEMCTRL, 0x6C); - BL = (Data & 0x02) >> 1; - - // CL = really offset RX62[2:0] - Data=pci_read_config8(MEMCTRL, 0x62); - CL = Data & 0x03; - - - AccessAddr = (u32)(CHB_DDR2_MRS_table[CL]); - if (BL) - { - AccessAddr += 8; - } - - //Write recovery : really offset Rx63[7:5] - Data=pci_read_config8(MEMCTRL, 0x63); - Twr = (Data & 0xE0) >> 5; - - AccessAddr += CHB_DDR2_Twr_table[Twr]; - //MSR Address use addr[20:3] - AccessAddr >>= 3; - - //step 23. MSR command - Data = (u8)(AccessAddr & 0xFF); - pci_write_config8(MEMCTRL, 0xD9, Data); - - Data = (u8)((AccessAddr & 0xFF00) >> 8); - pci_write_config8(MEMCTRL, 0xda, Data); - - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xF9; - Data |= (u8)(((AccessAddr & 0x30000)>>16) << 1); - pci_write_config8(MEMCTRL, 0xd7, Data); - - //step 24. issue MRS cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step 25. EMRS enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x18; - pci_write_config8(MEMCTRL, 0xd7, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xC7; - Data |= 0x08; - pci_write_config8(MEMCTRL, 0xd3, Data); - - - //step 26. OCD default - AccessAddr = (CHB_OCD_Default_150ohm) >> 3; - Data =(u8) (AccessAddr & 0xff); - pci_write_config8(MEMCTRL, 0xd9, Data); - - Data = (u8)((AccessAddr & 0xff00) >> 8); - pci_write_config8(MEMCTRL, 0xda, Data); - - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xF9; - Data |= (u8)((AccessAddr & 0x30000) >> 15); - pci_write_config8(MEMCTRL, 0xd7, Data); - - - //step 27. issue EMRS cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step 25. EMRS enable - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x18; - pci_write_config8(MEMCTRL, 0xd7, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xC7; - Data |= 0x08; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step 28. OCD Exit - AccessAddr = (CHB_OCD_Exit_150ohm) >> 3; - Data =(u8) (AccessAddr & 0xff); - pci_write_config8(MEMCTRL, 0xd9, Data); - - Data = (u8)((AccessAddr & 0xff00) >> 8); - pci_write_config8(MEMCTRL, 0xda, Data); - - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xF9; - Data |= (u8)((AccessAddr & 0x30000) >> 15); - pci_write_config8(MEMCTRL, 0xd7, Data); - - //step 29. issue EMRS cycle - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0x7F; - pci_write_config8(MEMCTRL, 0xd3, Data); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //clear all the address - Data = 0x00; - pci_write_config8(MEMCTRL, 0xd9, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xda, Data); - - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xF9; - pci_write_config8(MEMCTRL, 0xd7, Data); - - - //step 30. normal SDRAM Mode - Data=pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xC7; - Data |= 0x00; - pci_write_config8(MEMCTRL, 0xd7, Data); - - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xC7; - Data |= 0x00; - pci_write_config8(MEMCTRL, 0xd3, Data); - - //step 31. exit the initialization mode - Data=pci_read_config8(MEMCTRL, 0xd3); - Data &= 0xBF; - pci_write_config8(MEMCTRL, 0xd3, Data); - - - //step 32. Enable bank paging and multi page - Data=pci_read_config8(MEMCTRL, 0x69); - Data |= 0x03; - pci_write_config8(MEMCTRL, 0x69, Data); -} -*/ -/*=================================================================== -Function : InitDDR2CHC() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : Initialize DDR2 of CHC by standard sequence -Reference : -===================================================================*/ -// DDR2 CL=2 CL=3 CL=4 CL=5 (Burst type=interleave)(WR fine tune in code) -static const u16 CHC_MRS_table[4] = { 0x22B, 0x23B, 0x24B, 0x25B }; // Use 1X-bandwidth MA table to init DRAM - -void InitDDR2CHC(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 Idx, CL, Twr; - u32 AccessAddr; - CB_STATUS Status; - - // step3. - //clear RxDF[2] to disable Tri-state output - Data = pci_read_config8(MEMCTRL, 0xdf); - Data &= 0xFB; - pci_write_config8(MEMCTRL, 0xdf, Data); - - - - //step 4. Enable the initialization mode of DRAM Controller C with NB's PLL clock - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x60; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //Step 5. NOP command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x00; - pci_write_config8(MEMCTRL, 0xdb, Data); - - - //Step 6. issue a nop cycle,RegDB[1] 0 -> 1 - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - - // Step 7. - // A minimum pause of 200u sec will be provided after the NOP. - // - <<< reduce BOOT UP time >>> - - // Loop 200us - for (Idx = 0; Idx < 0x10; Idx++) - WaitMicroSec(100); - - // Step 8. - // signal bank precharge command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x14; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //set MA10 =1, precharge all bank - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - - Data = 0x04; - pci_write_config8(MEMCTRL, 0xf9, Data); - - //step 9. issue a precharge all cycle,RegD3[7] 0 -> 1 - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step10. MRS enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x1C; - pci_write_config8(MEMCTRL, 0xdb, Data); - - - //step11. EMRS DLL enable and Disable DQS - Data = 0x40; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x24; - pci_write_config8(MEMCTRL, 0xf9, Data); - - //step12. issue EMRS cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step13. MSR enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x1C; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step 14. MSR DLL Reset - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x01; - pci_write_config8(MEMCTRL, 0xf9, Data); - - //step15. issue MRS cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step16. signal banks precharge command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x14; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //set MA10 =1, precharge all bank - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x04; - pci_write_config8(MEMCTRL, 0xf9, Data); - - // step17. issue precharge all cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step18. CBR cycle enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x18; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf9, Data); - - //step 19.20.21 - //repeat issue 8 CBR cycle, between each cycle stop 100us - for (Idx = 0; Idx < 8; Idx++) { - // issue CBR cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - WaitMicroSec(100); - } - - //the SDRAM parameters.(, CAS# Latency , Write recovery etc.) - //------------------------------------------------------------ - - // CL = really offset RXDC[7:6] - Data = pci_read_config8(MEMCTRL, 0xdc); - CL = (Data & 0xC0) >> 6; - - AccessAddr = (u32) (CHC_MRS_table[CL]); - - //Write recovery : really offset Rx63[7:5] - Data = pci_read_config8(MEMCTRL, 0x63); - Twr = (Data & 0xE0) >> 5; - - AccessAddr += Twr * 0x200; - - //step22. MSR enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x1C; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step 23. MSR command - Data = (u8) (AccessAddr & 0xFF); - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = (u8) ((AccessAddr & 0xFF00) >> 8); - pci_write_config8(MEMCTRL, 0xf9, Data); - - //step 24. issue MRS cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step 25. EMRS enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x1C; - pci_write_config8(MEMCTRL, 0xdb, Data); - - - //step 26. OCD default - Data = 0xC0; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x27; - pci_write_config8(MEMCTRL, 0xf9, Data); - - //step 27. issue EMRS cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //step 28. OCD Exit - Data = 0x40; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x24; - pci_write_config8(MEMCTRL, 0xf9, Data); - - - //step 29. issue EMRS cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Status = VerifyChc(); - if (Status != CB_SUCCESS) - PRINT_DEBUG_MEM("Error!!!!CHC init error!\r"); - //step 31. exit the initialization mode - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0x9F; - pci_write_config8(MEMCTRL, 0xdb, Data); -} - -CB_STATUS VerifyChc() -{ - u8 Data, ByteVal, Index, pad; - u16 row; - - //first write the pad to all the address - - //the row bits is 13 and rank bit is 2, so the address bits is 15 and the value is 0x7fff - //verify each MA[0:12],BA[0:1] - pad = 1; - for (row = 0; row < 0x8000; row++) { - //set the write value; - //verify each MD[15:0] - for (Data = pad, Index = 0; Index < 16; Index++) { - Data <<= 1; - if (Data == 0) - Data = 1; - pci_write_config8(PCI_DEV(0, 0, 7), 0xC0 + Index, - Data); - - } - - //issue the bank active command - // bank active command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x10; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = (u8) (row && 0xFF); - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = (u8) ((row && 0xFF) >> 8); - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue active cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //issue ready/completion for read/write - // read/completion command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x04; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue read/completion cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //issue write command - // write command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x0C; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = (u8) ((row & 0x60) << 5); - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue write cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - ////issue ready/completion for read/write - // read/completion command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x04; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue read/completion cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //issue the bank active command - // bank active command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x10; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = (u8) (row && 0xFF); - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = (u8) ((row && 0xFF) >> 8); - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue active cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - ////issue ready/completion for read/write - // read/completion command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x04; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue read/completion cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - ////issue read command - // read/completion command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x08; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = (u8) ((row & 0x60) << 5); - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue read cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - ////issue ready/completion for read/write - // read/completion command enable - Data = pci_read_config8(MEMCTRL, 0xdb); - Data &= 0xE3; - Data |= 0x04; - pci_write_config8(MEMCTRL, 0xdb, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf8, Data); - - Data = 0x00; - pci_write_config8(MEMCTRL, 0xf9, Data); - - // issue read/completion cycle - Data = pci_read_config8(MEMCTRL, 0xdb); - Data |= 0x2; - pci_write_config8(MEMCTRL, 0xdb, Data); - Data &= 0xFD; - pci_write_config8(MEMCTRL, 0xdb, Data); - - //verify the value; - for (ByteVal = pad, Index = 0; Index < 16; Index++) { - Data = - pci_read_config8(PCI_DEV(0, 0, 7), - 0xD0 + Index); - if (ByteVal != Data) { - PRINT_DEBUG_MEM - ("error!!!! row = %x,Index =%x,Data = %x,ByteVal=%x\r"); - } - ByteVal <<= 1; - if (ByteVal == 0) - ByteVal = 1; - } - pad <<= 1; - if (pad == 0) - pad = 1; - } - - return CB_SUCCESS; -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/dqs_search.c b/src/northbridge/via/vx800/ddr2init/vx800/dqs_search.c deleted file mode 100644 index 80749f8597..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/dqs_search.c +++ /dev/null @@ -1,98 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -void SetDQSOutputCHA(DRAM_SYS_ATTR * DramAttr); -void SetDQSOutputCHB(DRAM_SYS_ATTR * DramAttr); - -/*=================================================================== -Function : DRAMDQSOutputSearchCHA() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : set DQS output delay register reg70 and DQ output delay register reg71 -===================================================================*/ - -#define CH_A 0 -#define CH_B 1 -void DRAMDQSOutputSearch(DRAM_SYS_ATTR * DramAttr) -{ - if (DramAttr->RankNumChA > 0) - SetDQSOutputCHA(DramAttr); -} - -/*=================================================================== -Function : SetDQSOutputCHA() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : according the frequence set CHA DQS output -===================================================================*/ -void SetDQSOutputCHA(DRAM_SYS_ATTR * DramAttr) -{ - u8 Reg70, Reg71; - u8 Index; - - if (DramAttr->DramFreq == DIMMFREQ_400) - Index = 3; - else if (DramAttr->DramFreq == DIMMFREQ_533) - Index = 2; - else if (DramAttr->DramFreq == DIMMFREQ_667) - Index = 1; - else if (DramAttr->DramFreq == DIMMFREQ_800) - Index = 0; - else - Index = 3; - - if (DramAttr->RankNumChA > 2) { - Reg70 = Fixed_DQSA_3_4_Rank_Table[Index][0]; - Reg71 = Fixed_DQSA_3_4_Rank_Table[Index][1]; - } else { - Reg70 = Fixed_DQSA_1_2_Rank_Table[Index][0]; - Reg71 = Fixed_DQSA_1_2_Rank_Table[Index][1]; - } - pci_write_config8(MEMCTRL, 0x70, Reg70); - pci_write_config8(MEMCTRL, 0x71, Reg71); -} - - -//################ -// STEP 12 # -//################ - -/*=================================================================== -Function : DRAMDQSInputSearch() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : search DQS input delay for CHA/CHB -===================================================================*/ - -void DRAMDQSInputSearch(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - //auto mode - Data = 0x0; - pci_write_config8(MEMCTRL, 0x77, Data); -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/drdy_bl.c b/src/northbridge/via/vx800/ddr2init/vx800/drdy_bl.c deleted file mode 100644 index b5a78f1a7d..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/drdy_bl.c +++ /dev/null @@ -1,600 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -// Set P6IF DRDY Timing -// Because there are 1.5T & 2.5T CAS latency in DDR1 mode, we need to use RDELAYMD-0 -// -// Entry: -// EBP[29:25] = DRAM Speed, Dual_Channel -// VIA_NB2HOST_REG54[7:5] Host Frequency -// VIA_NB3DRAM_REG62[2:0] CAS Latency -// -// Modify NB_Reg: -// VIA_NB2HOST_REG54[3,1] -// VIA_NB2HOST_REG55[1] -// VIA_NB2HOST_REG60 -// VIA_NB2HOST_REG61 -// VIA_NB2HOST_REG62[3:0] -// VIA_NB2HOST_REG63 -// VIA_NB2HOST_REG64 -// VIA_NB2HOST_REG65[3:0] -// VIA_NB2HOST_REG66 -// VIA_NB2HOST_REG67[5:4] -// -// Processing: -//-------------------------------------------------------------------------- -// P6IF DRDY Timing Control: -// *Following algorithm to set DRDY timing -// Set P6IF DRDY Timing by the following 3 conditions: -// 1. RDELAYMD -// a.RDRPH(MD input internal timing control) -// b.CAS Latency -// RDELAYMD(1bit) = bit0 of (CL + RDRPH) -// for example: RDRPH=10b, CL3 -> F3_Rx56[5:4]=11b, 10b + 11b = 101b, RDELAYMD=1 (bit0) -// RDRPH=00b, CL2.5 -> F3_Rx56[5:4]=10b, 00b + 10b = 010b, RDELAYMD=0 (bit0) -// 2. CPU Frequency -// 3. DRAM Frequency -// -// According to above conditions, we create different tables: -// 1. RDELAYMD=0 : for integer CAS latency(ex. CL=3) -// 2. RDELAYMD=1 : for non-integer CAS latency(ex. CL=2.5) -// 3. Normal performance -// 4. Top performance : -// Using phase0 to a case has better performance. -// -// Note: The setting are related to performance and maybe affect DRAM initialize. -// Turn OFF(F2_Rx51[7]=0) this feature at csDRAMRegInitValueJ procedure. -// Turn ON(F2_Rx51[7]=1) this feature at csDRAMRegFinalValueJ procedure. -// -// If F2_Rx51[7]=0, then CPU always wait 8QW, a slower but most stable way -// If F2_Rx51[7]=1, then the timing will refer to F2_Rx60 ~ F2_Rx67, -// a fast way but may cause the system to be unstable. -// -// Coding: -// 1. RDELAYMD and user's option for performance can determine which table -// 2. CPU Frequency can get block offset of table -// 3. DRAM Frequency can get row offset of block -// 4. Set value -// -// PS: Fun2 Rx62, Rx65, Rx67 are don't care bits in 3296, CPU 266MHz doesn't be supported by 3296, -// but I still keep these bits in table to avoid the usage in future -// and do the fewest modification for code. -// - -// Early 3T -// Early 3T -#define P6IF_Misc_RFASTH 0x08 -#define P6IF_Misc2_RRRDYH3E 0x10 -#define P6IF_Misc2_RHTSEL 0x02 - -#define Rx54E3T P6IF_Misc_RFASTH -#define Rx55E3T P6IF_Misc2_RRRDYH3E - -// Early 2T -#define Rx54E2T 0x00 -#define Rx55E2T P6IF_Misc2_RRRDYH3E - -// Early 1T -#define Rx54E1T 0x00 -#define Rx55E1T 0x00 - -// Early 0T -#define Rx54E0T P6IF_Misc_RFASTH -#define Rx55E0T P6IF_Misc2_RRRDYH3E + P6IF_Misc2_RHTSEL - -// Latter 1T -#define Rx54L1T P6IF_Misc_RFASTH -#define Rx55L1T P6IF_Misc2_RHTSEL - - -#define PH0_0_0_0 0x00 -#define PH0_0_0_1 0x01 -#define PH0_0_0_2 0x02 -#define PH0_0_0_3 0x03 -#define PH0_0_1_0 0x04 -#define PH0_0_1_1 0x05 -#define PH0_0_1_2 0x06 -#define PH0_0_2_1 0x09 -#define PH0_0_2_2 0x0a -#define PH0_0_2_3 0x0b -#define PH0_0_3_2 0x0e -#define PH0_0_3_3 0x0f -#define PH0_1_1_0 0x14 -#define PH0_1_1_1 0x15 -#define PH0_2_1_2 0x26 -#define PH0_2_2_1 0x29 -#define PH0_2_2_2 0x2a -#define PH0_2_2_3 0x2b -#define PH0_2_3_2 0x2e -#define PH0_2_3_3 0x2f -#define PH0_3_2_2 0x3a -#define PH0_3_3_3 0x3f -#define PH1_0_0_0 0x40 -#define PH1_0_0_1 0x41 -#define PH1_0_1_1 0x45 -#define PH1_1_1_1 0x55 -#define PH1_2_1_1 0x65 -#define PH1_2_2_1 0x69 -#define PH2_1_1_1 0x95 -#define PH2_1_2_1 0x99 -#define PH2_1_2_2 0x9a -#define PH2_2_1_2 0xa6 -#define PH2_2_2_1 0xa9 -#define PH2_2_2_2 0xaa -#define PH2_2_3_2 0xae -#define PH2_2_3_3 0xaf -#define PH2_3_2_2 0xba -#define PH2_3_2_3 0xbb -#define PH2_3_3_2 0xbe -#define PH3_2_2_3 0xeb -#define PH3_2_3_2 0xee -#define PH3_2_3_3 0xef -#define PH3_3_3_3 0xff - -#define PT894_RDRDY_TBL_Width 10 -#define PT894_RDRDY_TBL_Block 60 - -static const u8 PT894_128bit_DELAYMD0_RCONV0[6][6][PT894_RDRDY_TBL_Width] = -// ----------------------------------------------------------------------------------------------------------------- -// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM -// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E -// RCONV RHTSEL -// ----------------------------------------------------------------------------------------------------------------- -{ -// cpu100 - { - {PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/100 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/133 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 - }, -// cpu133 - { - {PH0_2_2_1, PH0_0_0_0, PH0_0_0_0, PH0_2_2_1, PH0_0_0_0, PH0_0_0_0, 0x01, 0x00, Rx54E3T, Rx55E3T}, // 133/100 - {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/133 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 - }, -// cpu200 - { - {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E2T, Rx55E2T}, // 200/100 - {PH2_3_2_3, PH0_0_0_0, PH0_0_0_0, PH2_3_2_3, PH0_0_0_0, PH0_0_0_0, 0x0a, 0x00, Rx54E3T, Rx55E3T}, // 200/133 - {PH1_2_2_1, PH0_0_0_1, PH0_0_0_0, PH1_2_2_1, PH0_0_0_1, PH0_0_0_0, 0x01, 0x00, Rx54E3T, Rx55E3T}, // 200/166 - {PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 - }, -// cpu166 - { - {PH0_2_3_3, PH0_0_0_0, PH0_0_0_0, PH0_2_2_3, PH0_0_0_0, PH0_0_0_0, 0x05, 0x00, Rx54E3T, Rx55E3T}, // 166/100 - {PH1_2_2_1, PH0_0_0_0, PH0_0_0_0, PH1_2_2_1, PH0_0_0_0, PH0_0_0_0, 0x01, 0x00, Rx54E3T, Rx55E3T}, // 166/133 - {PH1_1_1_1, PH0_0_0_1, PH0_0_0_0, PH1_1_1_1, PH0_0_0_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 - }, -// cpu266 - { - {PH0_2_2_3, PH0_0_0_0, PH0_0_0_0, PH0_0_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 266/100 - {PH3_3_3_3, PH0_0_0_0, PH0_0_0_0, PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E2T, Rx55E2T}, // 266/133 - {PH3_2_3_3, PH0_0_0_3, PH0_0_0_0, PH3_2_3_3, PH0_0_0_2, PH0_0_0_0, 0x0d, 0x00, Rx54E3T, Rx55E3T}, // 266/166 - {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH2_1_2_2, PH0_0_1_2, PH0_0_0_0, 0x12, 0x00, Rx54E3T, Rx55E3T}, // 266/200 - {PH1_1_1_1, PH1_1_1_1, PH0_0_0_0, PH1_1_1_1, PH1_1_1_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 266/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 266/333 - }, -// cpu333 - { - {PH0_1_1_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 333/100 - {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 333/133 - {PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, 0x1f, 0x00, Rx54E2T, Rx55E2T}, // 333/166 - {PH2_2_1_2, PH0_0_2_1, PH0_0_0_0, PH1_2_1_1, PH0_0_2_1, PH0_0_0_0, 0x36, 0x00, Rx54E2T, Rx55E2T}, // 333/200 - {PH2_1_1_1, PH2_1_1_1, PH0_0_0_0, PH2_1_1_1, PH2_1_1_1, PH0_0_0_0, 0x44, 0x00, Rx54E3T, Rx55E3T}, // 333/266 - {PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0x00, 0x00, Rx54E3T, Rx55E3T} // 333/333 - } -}; - -static const u8 PT894_128bit_DELAYMD1_RCONV0[6][6][PT894_RDRDY_TBL_Width] = -// ----------------------------------------------------------------------------------------------------------------- -// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM -// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E -// RCONV RHTSEL -// ----------------------------------------------------------------------------------------------------------------- -{ -// cpu100 - { - {PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/100 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/133 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 - }, -// cpu133 - { - {PH0_3_2_2, PH0_0_0_0, PH0_0_0_0, PH0_3_2_2, PH0_0_0_0, PH0_0_0_0, 0x02, 0x00, Rx54E3T, Rx55E3T}, // 133/100 - {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/133 - {PH1_0_0_0, PH0_0_0_0, PH0_0_0_0, PH1_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 - }, -// cpu200 - { - {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 200/100 - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH2_1_2_1, PH0_0_0_0, PH0_0_0_0, 0x0a, 0x00, Rx54E2T, Rx55E2T}, // 200/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x04, 0x00, Rx54E3T, Rx55E3T}, // 200/166 - {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 - }, -// cpu166 - { - {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_2_1_2, PH0_0_0_0, PH0_0_0_0, 0x05, 0x00, Rx54E2T, Rx55E2T}, // 166/100 - {PH2_3_2_2, PH0_0_0_0, PH0_0_0_0, PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, 0x02, 0x00, Rx54E3T, Rx55E3T}, // 166/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/166 - {PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 - }, -// cpu266 - { - {PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 266/100 - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 266/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_1_2, PH0_0_0_2, PH0_0_0_0, 0x15, 0x00, Rx54E2T, Rx55E2T}, // 266/166 - {PH3_2_3_3, PH0_0_2_3, PH0_0_0_0, PH2_2_3_2, PH0_0_2_3, PH0_0_0_0, 0x24, 0x00, Rx54E3T, Rx55E3T}, // 266/200 - {PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 266/266 - {PH0_0_0_1, PH0_0_1_1, PH0_0_1_0, PH0_0_0_1, PH0_0_1_1, PH0_0_1_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 266/333 - }, -// cpu333 - { - {PH0_3_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 333/100 - {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E0T, Rx55E0T}, // 333/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x1f, 0x00, Rx54E1T, Rx55E1T}, // 333/166 - {PH2_3_2_2, PH0_0_3_2, PH0_0_0_0, PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, 0x1b, 0x00, Rx54E2T, Rx55E2T}, // 333/200 - {PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, PH2_2_2_1, PH2_2_2_1, PH0_0_0_0, 0x88, 0x00, Rx54E3T, Rx55E3T}, // 333/266 - {PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0x00, 0x00, Rx54E3T, Rx55E3T} // 333/333 - } -}; - - -static const u8 PT894_64bit_DELAYMD0_RCONV0[6][6][PT894_RDRDY_TBL_Width] = -// ----------------------------------------------------------------------------------------------------------------- -// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM -// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E -// RCONV RHTSEL -// ----------------------------------------------------------------------------------------------------------------- -{ -// cpu100 - { - {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E3T, Rx55E3T}, // 100/100 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x09, 0x00, Rx54E3T, Rx55E3T}, // 100/133 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 - }, -// cpu133 - { - {PH0_2_3_2, PH0_0_0_0, PH0_0_0_0, PH0_0_1_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E2T, Rx55E2T}, // 133/100 - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E3T, Rx55E3T}, // 133/133 - {PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E3T, Rx55E3T}, // 133/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 - }, -// cpu200 - { - {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 200/100 - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 200/133 - {PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, PH1_2_2_1, PH0_0_0_1, PH0_0_0_0, 0x1f, 0x00, Rx54E3T, Rx55E3T}, // 200/166 - {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, 0x3f, 0x00, Rx54E3T, Rx55E3T}, // 200/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E1T, Rx55E1T}, // 200/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 -// DDR2 Both E3T and E2T Fail, need set to E1T, db PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 00110011b, 00000000b, Rx54E3T, Rx55E3T ;200/266 - }, -// cpu166 - { - {PH0_2_3_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 166/100 - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_1_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E2T, Rx55E2T}, // 166/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH1_1_1_1, PH0_0_0_1, PH0_0_0_0, 0x1f, 0x00, Rx54E3T, Rx55E3T}, // 166/166 - {PH1_0_0_1, PH0_0_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1e, 0x00, Rx54E3T, Rx55E3T}, // 166/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 - }, -// cpu266 - { - {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54L1T, Rx55L1T}, // 266/100 - {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 266/133 - {PH3_2_3_2, PH0_0_0_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54E1T, Rx55E1T}, // 266/166 - {PH3_2_2_3, PH0_0_2_2, PH0_0_0_0, PH1_0_0_1, PH0_0_0_0, PH0_0_0_0, 0x3f, 0x00, Rx54E2T, Rx55E2T}, // 266/200 - {PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, PH1_1_1_1, PH1_1_1_1, PH0_0_0_0, 0xff, 0x00, Rx54E3T, Rx55E3T}, // 266/266 - {PH0_0_1_1, PH0_1_1_1, PH0_0_1_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x9c, 0x03, Rx54E3T, Rx55E3T} // 266/333 - }, -// cpu333 - { - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54L1T, Rx55L1T}, // 333/100 ;DO NOT Support - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 333/133 - {PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54E0T, Rx55E0T}, // 333/166 - {PH2_3_3_2, PH0_0_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x3f, 0x00, Rx54E1T, Rx55E1T}, // 333/200 - {PH3_3_3_3, PH3_3_3_3, PH0_0_0_0, PH2_1_1_1, PH2_1_1_1, PH0_0_0_0, 0xff, 0x00, Rx54E3T, Rx55E3T}, // 333/266 - {PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0xff, 0x03, Rx54E3T, Rx55E3T} // 333/333 - } -}; - - -static const u8 PT894_64bit_DELAYMD1_RCONV0[6][6][PT894_RDRDY_TBL_Width] = -// ----------------------------------------------------------------------------------------------------------------- -// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM -// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E -// RCONV RHTSEL -// ----------------------------------------------------------------------------------------------------------------- -{ -// cpu100 - { - {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E3T, Rx55E3T}, // 100/100 - {PH1_0_0_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x06, 0x00, Rx54E3T, Rx55E3T}, // 100/133 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // ;100/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 - }, -// cpu133 - { - {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E2T, Rx55E2T}, // 133/100 - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E3T, Rx55E3T}, // 133/133 - {PH1_0_1_1, PH0_0_0_1, PH0_0_0_0, PH1_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1c, 0x00, Rx54E3T, Rx55E3T}, // 133/166 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x09, 0x00, Rx54E3T, Rx55E3T}, // 133/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 - }, -// cpu200 - { - {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54L1T, Rx55L1T}, // 200/100 - {PH3_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 200/133 - {PH2_2_3_3, PH0_0_0_2, PH0_0_0_0, PH1_0_1_1, PH0_0_0_1, PH0_0_0_0, 0x1f, 0x00, Rx54E2T, Rx55E2T}, // 200/166 - {PH3_3_3_3, PH0_0_3_3, PH0_0_0_0, PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, 0x3f, 0x00, Rx54E3T, Rx55E3T}, // 200/200 - {PH0_0_1_1, PH0_0_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0xcc, 0x00, Rx54E3T, Rx55E3T}, // 200/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 - }, -// cpu166 - { - {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 166/100 - {PH2_2_3_3, PH0_0_0_0, PH0_0_0_0, PH1_0_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E2T, Rx55E2T}, // 166/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x1f, 0x00, Rx54E3T, Rx55E3T}, // 166/166 - {PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, 0x39, 0x00, Rx54E3T, Rx55E3T}, // 166/200 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 - }, -// cpu266 - { - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54L1T, Rx55L1T}, // 266/100 ;DO NOT Support - {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 266/133 - {PH2_2_1_2, PH0_0_0_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54E0T, Rx55E0T}, // 266/166 - {PH3_3_3_3, PH0_0_3_3, PH0_0_0_0, PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, 0x3f, 0x00, Rx54E2T, Rx55E2T}, // 266/200 - {PH3_3_3_3, PH3_3_3_3, PH0_0_0_0, PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, 0xff, 0x00, Rx54E3T, Rx55E3T}, // 266/266 - {PH1_1_1_1, PH1_1_1_1, PH0_0_1_1, PH0_0_0_1, PH0_0_1_1, PH0_0_1_0, 0x73, 0x02, Rx54E3T, Rx55E3T} // 266/333 - }, -// cpu333 - { - {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54L1T, Rx55L1T}, // 333/100 ;DO NOT Support - {PH3_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 333/133 - {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54L1T, Rx55L1T}, // 333/166 - {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x3f, 0x00, Rx54E1T, Rx55E1T}, // 333/200 - {PH2_3_2_2, PH2_3_2_2, PH0_0_0_0, PH0_1_1_0, PH0_1_1_0, PH0_0_0_0, 0xff, 0x00, Rx54E2T, Rx55E2T}, // 333/266 - {PH3_3_3_3, PH3_3_3_3, PH0_0_3_3, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0xff, 0x03, Rx54E3T, Rx55E3T} // 333/333 - } -}; - -void DRAMDRDYSetting(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data, CL, RDRPH; - u8 CpuFreq, DramFreq; - u8 ProgData[PT894_RDRDY_TBL_Width]; - u8 DelayMode; - u8 DrdyMode; - u8 Index; - - /* - this function has 3 switchs, correspond to 3 level of Drdy setting. - 0:Slowest, 1:Default, 2:Optimize - you can only open one switch - */ -#if 1 //this is slowest - // 0 -> Slowest - //Write slowest value to register - - Data = 0xAA; - pci_write_config8(PCI_DEV(0, 0, 2), 0x60, Data); - - Data = 0x0A; - pci_write_config8(PCI_DEV(0, 0, 2), 0x61, Data); - - Data = 0x00; - pci_write_config8(PCI_DEV(0, 0, 2), 0x62, Data); - - Data = 0xAA; - pci_write_config8(PCI_DEV(0, 0, 2), 0x63, Data); - - Data = 0x0A; - pci_write_config8(PCI_DEV(0, 0, 2), 0x64, Data); - - Data = 0x00; - pci_write_config8(PCI_DEV(0, 0, 2), 0x65, Data); - - Data = 0x00; - pci_write_config8(PCI_DEV(0, 0, 2), 0x66, Data); - - Data = 0x00; - pci_write_config8(PCI_DEV(0, 0, 2), 0x67, Data); - - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x54); - Data = Data & 0xF5; - Data |= 0x08; - pci_write_config8(PCI_DEV(0, 0, 2), 0x54, Data); - - //Data=pci_read_config8(PCI_DEV(0,0,2), 0x55); - //Data = Data & (~0x20); - //pci_write_config8(PCI_DEV(0,0,2), 0x55, Data); - - //enable drdy timing - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x51); - Data = Data | 0x80; - pci_write_config8(PCI_DEV(0, 0, 2), 0x51, Data); -#endif -#if 0 //default - { - //disable drdy timing - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x51); - Data = Data & 0x7F; - pci_write_config8(PCI_DEV(0, 0, 2), 0x51, Data); - } -#endif -#if 0 // 2:Optimize - //CL :reg6x[2:0] - Data = pci_read_config8(MEMCTRL, 0x62); - CL = Data & 0x07; - - //RDRPH: reg7B[6:4] - Data = pci_read_config8(MEMCTRL, 0x7B); - RDRPH = (Data & 0x70) >> 4; - - //CpuFreq: F2Reg54[7:5] - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x54); - CpuFreq = (Data & 0xE0) >> 5; - - //DramFreq:F3Reg90[2:0] - Data = pci_read_config8(MEMCTRL, 0x90); - DramFreq = Data & 0x07; - - DelayMode = CL + RDRPH; // RDELAYMD = bit0 of (CAS Latency + RDRPH) - DelayMode &= 0x01; - - //In 364, there is no 128 bit - if (DelayMode == 1) { // DelayMode 1 - for (Index = 0; Index < PT894_RDRDY_TBL_Width; Index++) - ProgData[Index] = - PT894_64bit_DELAYMD1_RCONV0[CpuFreq][DramFreq] - [Index]; - } else { // DelayMode 0 - for (Index = 0; Index < PT894_RDRDY_TBL_Width; Index++) - ProgData[Index] = - PT894_64bit_DELAYMD0_RCONV0[CpuFreq][DramFreq] - [Index]; - } - - Data = ProgData[0]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x60, Data); - - Data = ProgData[1]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x61, Data); - - Data = ProgData[2]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x62, Data); - - Data = ProgData[3]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x63, Data); - - Data = ProgData[4]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x64, Data); - - Data = ProgData[5]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x65, Data); - - Data = ProgData[6]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x66, Data); - - Data = ProgData[7]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x67, Data); - - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x54); - Data = (Data & 0xF5) | ProgData[8]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x54, Data); - - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x55); - Data = Data & (~0x22) | ProgData[9]; - pci_write_config8(PCI_DEV(0, 0, 2), 0x62, Data); - - //enable drdy timing - Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x51); - Data = Data | 0x80; - pci_write_config8(PCI_DEV(0, 0, 2), 0x51, Data); -#endif -} - - -/*This routine process the ability for North Bridge side burst functionality -There are 3 variances that are valid: - 1. DIMM BL=8, chipset BL=8 - 2. DIMM BL=4, chipset BL=4 - 3. DIMM BL=4, chipset BL=8 (only happened on Dual channel) - Device 0 function 2 HOST:REG54[4] must be 1 when 128-bit mode. -Since DIMM will be initialized in each rank individually, - 1.If all DIMM BL=4, DIMM will initialize BL=4 first, - then check dual_channel flag to enable VIA_NB2HOST_REG54[4]. - 2.If all DIMM BL=8, DIMM will initialize BL=8 first, - then check dual_channel flag for re-initialize DIMM BL=4. - also VIA_NB2HOST_REG54[4] need to be enabled. -Chipset_BL8==>chipset side can set burst length=8 -two register need to set - 1. Device 0 function 2 HOST:REG54[4] - 2. Device 0 function 3 DRAM:REG6C[3] -*/ -void DRAMBurstLength(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data, BL; - u8 Sockets; - /*SPD byte16 bit3,2 describes the burst length supported. bit3=1 support BL=8 bit2=1 support BL=4 */ - BL = 0x0c; - for (Sockets = 0; Sockets < 2; Sockets++) { - if (DramAttr->DimmInfo[Sockets].bPresence) { - BL &= - (DramAttr->DimmInfo[Sockets]. - SPDDataBuf[SPD_SDRAM_BURSTLENGTH]); - } - } - - /*D0F3Rx6c bit3 CHA SDRAM effective burst length, for 64bit mode ranks =0 BL=4 ; =1 BL=8 */ - - if (BL & 0x08) /*All Assembly support BL=8 */ - BL = 0x8; /*set bit3 */ - else - BL = 0x00; /*clear bit3 */ - - Data = pci_read_config8(MEMCTRL, 0x6c); - Data = (u8) ((Data & 0xf7) | BL); - -#if ENABLE_CHB - if (DramAttr->RankNumChB > 0) { - BL = DramAttr->DimmInfo[2]. - SPDDataBuf[SPD_SDRAM_BURSTLENGTH]; - //Rx6c[1], CHB burst length - if (BL & 0x08) /*CHB support BL=8 */ - BL = 0x2; /*set bit1 */ - else - BL = 0x00; /*clear bit1 */ - - Data = (Data & 0xFD) | BL; - } -#endif - pci_write_config8(MEMCTRL, 0x6c, Data); -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/driving_setting.c b/src/northbridge/via/vx800/ddr2init/vx800/driving_setting.c deleted file mode 100644 index 3bdfdf391f..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/driving_setting.c +++ /dev/null @@ -1,396 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -/* - Driving setting: ODT/DQS/DQ/CS/MAA/MAB/DCLK - */ - -void DrivingODT(DRAM_SYS_ATTR * DramAttr); - -void DrivingDQS(DRAM_SYS_ATTR * DramAttr); - -void DrivingDQ(DRAM_SYS_ATTR * DramAttr); - -void DrivingCS(DRAM_SYS_ATTR * DramAttr); - -void DrivingMA(DRAM_SYS_ATTR * DramAttr); - -void DrivingDCLK(DRAM_SYS_ATTR * DramAttr); - -/* DRAM Driving Adjustment*/ -void DRAMDriving(DRAM_SYS_ATTR * DramAttr) -{ - PRINT_DEBUG_MEM("set ODT!\r"); - DrivingODT(DramAttr); - - PRINT_DEBUG_MEM("set DQS!\r"); - DrivingDQS(DramAttr); - - PRINT_DEBUG_MEM(("set DQ!\r")); - DrivingDQ(DramAttr); - - PRINT_DEBUG_MEM("set CS!\r"); - DrivingCS(DramAttr); - - PRINT_DEBUG_MEM("set MAA!\r"); - DrivingMA(DramAttr); - - PRINT_DEBUG_MEM("set DCLK!\r"); - DrivingDCLK(DramAttr); -} - - -/* -ODT Control for DQ/DQS/CKE/SCMD/DCLKO in ChA & ChB -which include driving enable/range and strong/weak selection - -Processing: According to DRAM frequency to ODT control bits. - Because function enable bit must be the last one to be set. - So the register VIA_NB3DRAM_REGD4 and VIA_NB3DRAM_REGD3 should be - the last register to be programmed. -*/ -//------------------------------------------------------------------------------- -// ODT Lookup Table -//------------------------------------------------------------------------------- -#define Rank0_ODT 0 -#define Rank1_ODT 1 -#define Rank2_ODT 2 -#define Rank3_ODT 3 -#define NA_ODT 0 -#define NB_ODT_75ohm 0 -#define NB_ODT_150ohm 1 - -#define DDR2_ODT_75ohm 0x20 -#define DDR2_ODT_150ohm 0x40 - -// Setting of ODT Lookup TBL -// RankMAP , Rank 3 Rank 2 Rank 1 Rank 0 , DRAM & NB ODT setting -// db 0000b , Reserved -#define ODTLookup_Tbl_count 8 -static const u8 ODTLookup_TBL[ODTLookup_Tbl_count][3] = { - // 0001b - {0x01, - (Rank3_ODT << 6) + (Rank2_ODT << 4) + (Rank1_ODT << 2) + - Rank0_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, - // 0010b , Reserved - // 0011b - {0x03, - (Rank3_ODT << 6) + (Rank2_ODT << 4) + (Rank0_ODT << 2) + - Rank1_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, - // 0100b - {0x04, - (Rank3_ODT << 6) + (Rank2_ODT << 4) + (Rank1_ODT << 2) + - Rank0_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, - // 0101b - {0x05, - (Rank3_ODT << 6) + (Rank0_ODT << 4) + (Rank1_ODT << 2) + - Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm}, - // 0110b , Reserved - // 0111b - {0x07, - (Rank3_ODT << 6) + (Rank0_ODT << 4) + (Rank2_ODT << 2) + - Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm}, - // 1000b , Reserved - // 1001b , Reserved - // 1010b , Reserved - // 1011b , Reserved - // 1100b - {0x0c, - (Rank2_ODT << 6) + (Rank3_ODT << 4) + (Rank1_ODT << 2) + - Rank0_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, - // 1101b - {0x0d, - (Rank0_ODT << 6) + (Rank0_ODT << 4) + (Rank1_ODT << 2) + - Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm}, - // 1110b , Reserved - // 1111b - {0x0f, - (Rank0_ODT << 6) + (Rank0_ODT << 4) + (Rank2_ODT << 2) + - Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm} -}; - -#define ODT_Table_Width_DDR2 4 -// RxD6 RxD3 -static const u8 ODT_Control_DDR2[ODT_Table_Width_DDR2] = { 0xFC, 0x01 }; - -void DrivingODT(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 i; - BOOLEAN bFound; - - pci_write_config8(MEMCTRL, 0xD0, 0x88); - - Data = ODT_Control_DDR2[0]; - pci_write_config8(MEMCTRL, 0xd6, Data); - - Data = ODT_Control_DDR2[1]; - pci_write_config8(MEMCTRL, 0xd3, Data); - - Data = pci_read_config8(MEMCTRL, 0x9e); - //set MD turn_around wait state - Data &= 0xCF; /*clear bit4,5 */ - if (DIMMFREQ_400 == DramAttr->DramFreq) - Data |= 0x0; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - Data |= 0x10; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - Data |= 0x20; - else if (DIMMFREQ_800 == DramAttr->DramFreq) - Data |= 0x20; - else - Data |= 0; - pci_write_config8(MEMCTRL, 0x9e, Data); - - - if (DIMMFREQ_400 == DramAttr->DramFreq) - Data = 0x0; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - Data = 0x11; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - Data = 0x11; - else if (DIMMFREQ_800 == DramAttr->DramFreq) - Data = 0x11; - else - Data = 0; - pci_write_config8(MEMCTRL, 0x9f, Data); - - - /*channel A ODT select */ - if (DramAttr->DimmNumChA > 0) { - Data = pci_read_config8(MEMCTRL, 0xd5); - Data &= 0x5F; /*clear bit7,5 */ - if (DramAttr->RankNumChA > 2) - Data |= 0xA0; /*if rank number > 2 (3or4), set bit7,5 */ - else - Data |= 0x00; /*if rank number is 1or2, clear bit5 */ - pci_write_config8(MEMCTRL, 0xd5, Data); - - Data = pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xEF; /*clear bit7 */ - if (DramAttr->RankNumChA > 2) - Data |= 0x80; /*if rank number > 2 (3or4), set bit7 */ - else - Data |= 0x00; /*if rank number is 1or2, clear bit7 */ - pci_write_config8(MEMCTRL, 0xd7, Data); - - - /*channel A */ - Data = pci_read_config8(MEMCTRL, 0xd5); - Data &= 0xF3; //bit2,3 - if (DramAttr->DimmNumChA == 2) /*2 Dimm, 3or4 Ranks */ - Data |= 0x00; - else if (DramAttr->DimmNumChA == 1) - Data |= 0x04; - pci_write_config8(MEMCTRL, 0xd5, Data); - - if ((DramAttr->RankPresentMap & 0x0F) != 0) { /*channel A */ - // MAA ODT Lookup Table - bFound = FALSE; - for (i = 0; i < ODTLookup_Tbl_count; i++) { - if ((DramAttr->RankPresentMap & 0x0F) == - ODTLookup_TBL[i][0]) { - Data = ODTLookup_TBL[i][1]; - bFound = TRUE; - } - } - if (!bFound) { /*set default value */ - Data = - ODTLookup_TBL[ODTLookup_Tbl_count - - 1][1]; - } - pci_write_config8(MEMCTRL, 0x9c, Data); - - - //set CHA MD ODT control State Dynamic-on - Data = pci_read_config8(MEMCTRL, 0xD4); - Data &= 0xC9; - Data |= 0x30; - pci_write_config8(MEMCTRL, 0xD4, Data); - - Data = pci_read_config8(MEMCTRL, 0x9e); - Data |= 0x01; - pci_write_config8(MEMCTRL, 0x9e, Data); - } - - } - /*channel B */ - if (1 == ENABLE_CHC) { - //CHB has not auto compensation mode ,so must set it manual,or else CHB initialization will not successful - // Data =0x88; - //pci_write_config8(MEMCTRL, 0xd0, Data); - - Data = pci_read_config8(MEMCTRL, 0xd5); - Data &= 0xAF; - if (DramAttr->RankNumChB > 2) /*rank number 3 or 4 */ - Data |= 0x50; - else - Data |= 0x00; - pci_write_config8(MEMCTRL, 0xd5, Data); - - Data = pci_read_config8(MEMCTRL, 0xd7); - Data &= 0xBF; /*clear bit6 */ - if (DramAttr->RankNumChB > 2) - Data |= 0x40; /*if rank number > 2 (3or4), set bit7 */ - else - Data |= 0x00; /*if rank number is 1or2, clear bit7 */ - pci_write_config8(MEMCTRL, 0xd7, Data); - - - Data = pci_read_config8(MEMCTRL, 0xd5); - Data &= 0xFC; - if (DramAttr->DimmNumChB == 2) /*2 Dimm, 3or4 Ranks */ - Data |= 0x00; // 2 dimm RxD5[2,0]=0,0b - else if (DramAttr->DimmNumChB == 1) - Data |= 0x01; // 1 dimm RxD5[2,0]=1,1b - pci_write_config8(MEMCTRL, 0xd5, Data); - - //set CHB MD ODT control State Dynamic-on - Data = pci_read_config8(MEMCTRL, 0xD4); - Data &= 0xF6; - Data |= 0x08; - pci_write_config8(MEMCTRL, 0xD4, Data); - - - //enable CHB differential DQS input - Data = pci_read_config8(MEMCTRL, 0x9E); - Data |= 0x02; - pci_write_config8(MEMCTRL, 0x9E, Data); - } - //enable ODT Control - Data = pci_read_config8(MEMCTRL, 0x9e); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0x9e, Data); -} - -void DrivingDQS(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - - /*channel A */ - if (DramAttr->RankNumChA > 0) { - Data = DDR2_DQSA_Driving_Table[DramAttr->RankNumChA - 1]; - pci_write_config8(MEMCTRL, 0xe0, Data); - } - - /*channel B */ - if (1 == ENABLE_CHC) { - Data = DDR2_DQSB_Driving_Table[DramAttr->RankNumChB - 1]; - pci_write_config8(MEMCTRL, 0xe1, Data); - } - -} - -void DrivingDQ(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - - /*channel A */ - if (DramAttr->RankNumChA > 0) { - Data = DDR2_DQA_Driving_Table[DramAttr->RankNumChA - 1]; - pci_write_config8(MEMCTRL, 0xe2, Data); - - } - /*channel B */ - if (1 == ENABLE_CHC) { - Data = DDR2_DQB_Driving_Table[DramAttr->RankNumChB - 1]; - pci_write_config8(MEMCTRL, 0xe3, Data); - } -} - -void DrivingCS(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - /*Channel A */ - if (DramAttr->RankNumChA > 0) { - Data = DDR2_CSA_Driving_Table_x8[DramAttr->RankNumChA - 1]; - pci_write_config8(MEMCTRL, 0xe4, Data); - } - /*channel B */ - if (1 == ENABLE_CHC) { - Data = DDR2_CSB_Driving_Table_x8[DramAttr->RankNumChB - 1]; - pci_write_config8(MEMCTRL, 0xe5, Data); - } -} - -void DrivingMA(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 i, FreqId; - - if (DramAttr->RankNumChA > 0) { - if (DIMMFREQ_400 == DramAttr->DramFreq) - FreqId = 1; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - FreqId = 2; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - FreqId = 3; - else if (DIMMFREQ_800 == DramAttr->DramFreq) - FreqId = 4; - else - FreqId = 1; - for (i = 0; i < MA_Table; i++) { - if (DramAttr->LoadNumChA <= - DDR2_MAA_Driving_Table[i][0]) { - Data = DDR2_MAA_Driving_Table[i][FreqId]; - break; - } - } - pci_write_config8(MEMCTRL, 0xe8, Data); - } - if (1 == ENABLE_CHC) { - for (i = 0; i < MA_Table; i++) { - if (DramAttr->LoadNumChA <= - DDR2_MAB_Driving_Table[i][0]) { - Data = DDR2_MAB_Driving_Table[i][1]; - break; - } - } - pci_write_config8(MEMCTRL, 0xe9, Data); - } -} - -void DrivingDCLK(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 FreqId; - - if (DIMMFREQ_400 == DramAttr->DramFreq) - FreqId = 0; - else if (DIMMFREQ_533 == DramAttr->DramFreq) - FreqId = 1; - else if (DIMMFREQ_667 == DramAttr->DramFreq) - FreqId = 2; - else if (DIMMFREQ_800 == DramAttr->DramFreq) - FreqId = 4; - else - FreqId = 0; - - /*channel A */ - if (DramAttr->RankNumChA > 0) { - Data = DDR2_DCLKA_Driving_Table[FreqId]; - pci_write_config8(MEMCTRL, 0xe6, Data); - } - /*channel B */ - if (1 == ENABLE_CHC) { - Data = DDR2_DCLKB_Driving_Table[FreqId]; - pci_write_config8(MEMCTRL, 0xe7, Data); - } - -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/final_setting.c b/src/northbridge/via/vx800/ddr2init/vx800/final_setting.c deleted file mode 100644 index 165c887d8a..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/final_setting.c +++ /dev/null @@ -1,129 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -static const u8 RefreshCounter[7][2] = { - //Non_256Mbit, 256Mbit - {0xCA, 0xA8}, // DRAM400 - {0xCA, 0xA8}, // DRAM333 - {0xCA, 0x86}, // DRAM266 - {0xCA, 0x65}, // DRAM200 - {0xA8, 0x54}, // DRAM166 - {0x86, 0x43}, // DRAM133 - {0x65, 0x32} // DRAM100 -}; - -void DRAMRefreshCounter(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 Freq = 5, i, Dram_256_Mb; - if (DramAttr->DramFreq == DIMMFREQ_800) - Freq = 0; - else if (DramAttr->DramFreq == DIMMFREQ_667) - Freq = 1; - else if (DramAttr->DramFreq == DIMMFREQ_533) - Freq = 2; - else if (DramAttr->DramFreq == DIMMFREQ_400) - Freq = 3; - else if (DramAttr->DramFreq == DIMMFREQ_333) - Freq = 4; - else if (DramAttr->DramFreq == DIMMFREQ_266) - Freq = 5; - else if (DramAttr->DramFreq == DIMMFREQ_200) - Freq = 6; - else - Freq = 6; - - Dram_256_Mb = 0; - for (i = 0; i < MAX_SOCKETS; i++) { - if (DramAttr->DimmInfo[i].SPDDataBuf[SPD_SDRAM_ROW_ADDR] == - 13) { - Dram_256_Mb = 1; - break; - } - } - - Data = RefreshCounter[Freq][Dram_256_Mb]; - - pci_write_config8(MEMCTRL, 0x6a, Data); -} - - -/*=================================================================== -Function : DRAMRegFinalValue() -Precondition : -Input : - DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information - in MotherBoard -Output : Void -Purpose : Chipset Performance UP and other setting after DRAM Sizing - Turn on register directly to promote performance -===================================================================*/ - -//-------------------------------------------------------------------------- -// register AND OR -//-------------------------------------------------------------------------- -#define DRAM_table_item 9 -static const u8 DRAM_table[DRAM_table_item][3] = { - {0x60, 0xff, 0xD0}, - {0x66, 0xcf, 0x80}, // DRAMC queue > 2 - {0x69, 0xff, 0x07}, // Enable multiple page - {0x95, 0x00, 0x0D}, - {0x96, 0x0F, 0xA0}, - {0xFB, 0x00, 0x3E}, - {0xFD, 0x00, 0xA9}, - {0xFE, 0x00, 0x0f}, - {0xFF, 0x00, 0x3D} -}; - -#define PM_table_item 5 -static const u8 PM_table[PM_table_item][3] = { - {0xA0, 0x0F, 0xF0}, - {0xA1, 0x1F, 0xE0}, - {0xA2, 0x00, 0xFE}, - {0xA3, 0x7F, 0x80}, - {0xA5, 0x7E, 0x81}, -}; - -void DRAMRegFinalValue(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 i; - - for (i = 0; i < DRAM_table_item; i++) { - Data = pci_read_config8(MEMCTRL, DRAM_table[i][0]); - Data = (u8) ((Data & DRAM_table[i][1]) | DRAM_table[i][2]); - pci_write_config8(MEMCTRL, DRAM_table[i][0], Data); - } - - //enable dram By-Rank self refresh - Data = pci_read_config8(MEMCTRL, 0x96); - Data &= 0xF0; - for (i = 0x01; i < 0x10; i = i << 1) { - if ((DramAttr->RankPresentMap & i) != 0x00) - Data |= i; - } - pci_write_config8(MEMCTRL, 0x96, Data); - - for (i = 0; i < PM_table_item; i++) { - Data = pci_read_config8(PCI_DEV(0, 0, 4), PM_table[i][0]); - Data = (u8) ((Data & PM_table[i][1]) | PM_table[i][2]); - pci_write_config8(PCI_DEV(0, 0, 4), PM_table[i][0], Data); - } - -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/freq_setting.c b/src/northbridge/via/vx800/ddr2init/vx800/freq_setting.c deleted file mode 100644 index ed4184ec77..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/freq_setting.c +++ /dev/null @@ -1,235 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -void CalcCLAndFreq(DRAM_SYS_ATTR * DramAttr); - -/* - Set DRAM Frequency -*/ -void DRAMFreqSetting(DRAM_SYS_ATTR * DramAttr) -{ - - u8 Data = 0; - - PRINT_DEBUG_MEM("Dram Frequency setting \r"); - - //calculate dram frequency using SPD data - CalcCLAndFreq(DramAttr); - - //init some Dramc control by Simon Chu slide - //Must use "CPU delay" to make sure VLINK is dis-connect - Data = pci_read_config8(PCI_DEV(0, 0, 7), 0x47); - Data = (u8) (Data | 0x04); - pci_write_config8(PCI_DEV(0, 0, 7), 0x47, Data); - - //in order to make sure NB command buffer don`t have pending request(C2P cycle) - //CPU DELAY - WaitMicroSec(20); - - //Before Set Dram Frequency, we must set 111 by Simon Chu slide. - Data = pci_read_config8(MEMCTRL, 0x90); - Data = (u8) ((Data & 0xf8) | 7); - pci_write_config8(MEMCTRL, 0x90, Data); - - WaitMicroSec(20); - - //Set Dram Frequency. - Data = pci_read_config8(MEMCTRL, 0x90); - switch (DramAttr->DramFreq) { - case DIMMFREQ_400: - Data = (u8) ((Data & 0xf8) | 3); - break; - case DIMMFREQ_533: - Data = (u8) ((Data & 0xf8) | 4); - break; - case DIMMFREQ_667: - Data = (u8) ((Data & 0xf8) | 5); - break; - case DIMMFREQ_800: - Data = (u8) ((Data & 0xf8) | 6); - break; - default: - Data = (u8) ((Data & 0xf8) | 1);; - } - pci_write_config8(MEMCTRL, 0x90, Data); - - //CPU Delay - WaitMicroSec(20); - - // Manual reset and adjust DLL when DRAM change frequency - Data = pci_read_config8(MEMCTRL, 0x6B); - Data = (u8) ((Data & 0x2f) | 0xC0); - pci_write_config8(MEMCTRL, 0x6B, Data); - - //CPU Delay - WaitMicroSec(20); - - Data = pci_read_config8(MEMCTRL, 0x6B); - Data = (u8) (Data | 0x10); - pci_write_config8(MEMCTRL, 0x6B, Data); - - //CPU Delay - WaitMicroSec(20); - - Data = pci_read_config8(MEMCTRL, 0x6B); - Data = (u8) (Data & 0x3f); - pci_write_config8(MEMCTRL, 0x6B, Data); - - //disable V_LINK Auto-Disconnect, or else program may stopped at some place and - //we cannot find the reason - Data = pci_read_config8(PCI_DEV(0, 0, 7), 0x47); - Data = (u8) (Data & 0xFB); - pci_write_config8(PCI_DEV(0, 0, 7), 0x47, Data); - -} - - -/* - calculate CL and dram freq - DDR1 - +---+---+---+---+---+---+---+---+ - | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 | - +---+---+---+---+---+---+---+---+ - |TBD| 4 |3.5| 3 |2.5| 2 |1.5| 1 | - +---+---+---+---+---+---+---+---+ - DDR2 - +---+---+---+---+---+---+---+---+ - | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 | - +---+---+---+---+---+---+---+---+ - |TBD| 6 | 5 | 4 | 3 | 2 |TBD|TBD| - +---+---+---+---+---+---+---+---+ -*/ -static const u8 CL_DDR1[7] = { 10, 15, 20, 25, 30, 35, 40 }; -static const u8 CL_DDR2[7] = { 0, 0, 20, 30, 40, 50, 60 }; - -void CalcCLAndFreq(DRAM_SYS_ATTR * DramAttr) -{ - u8 AllDimmSupportedCL, Tmp; - u8 CLMask, tmpMask, IndexDelta; - u8 SckId, BitId, TmpId; - u16 CycTime, TmpCycTime; - - /*1.list the CL value that all DIMM supported */ - AllDimmSupportedCL = 0xFF; - if (RAMTYPE_SDRAMDDR2 == DramAttr->DramType) - AllDimmSupportedCL &= 0x7C; /*bit2,3,4,5,6 */ - else /*DDR1 */ - AllDimmSupportedCL &= 0x7F; /*bit0,1,2,3,4,5,6 */ - for (SckId = 0; SckId < MAX_SOCKETS; SckId++) { - if (DramAttr->DimmInfo[SckId].bPresence) { /*all DIMM supported CL */ - AllDimmSupportedCL &= - (DramAttr->DimmInfo[SckId]. - SPDDataBuf[SPD_SDRAM_CAS_LATENCY]); - } - } - if (!AllDimmSupportedCL) { /*if equal 0, no supported CL */ - PRINT_DEBUG_MEM("SPD Data Error, Can not get CL !!!! \r"); - for (;;); - } - - /*Get CL Value */ - CLMask = 0x40; /*from Bit6 */ - - for (BitId = 7; BitId > 0; BitId--) { - if ((AllDimmSupportedCL & CLMask) == CLMask) { /*find the first bit */ - if (RAMTYPE_SDRAMDDR2 == DramAttr->DramType) - DramAttr->CL = CL_DDR2[BitId - 1]; - else /*DDR1 */ - DramAttr->CL = CL_DDR1[BitId - 1]; - break; - } - CLMask >>= 1; - } - - /*according the CL value calculate the cycle time, for X or X-1 or X-2 */ - CycTime = 0; - TmpCycTime = 0; - - for (SckId = 0; SckId < MAX_SOCKETS; SckId++) { - if (DramAttr->DimmInfo[SckId].bPresence) { - Tmp = - (DramAttr->DimmInfo[SckId]. - SPDDataBuf[SPD_SDRAM_CAS_LATENCY]); - tmpMask = 0x40; - for (TmpId = 7; TmpId > 0; TmpId--) { - if ((Tmp & tmpMask) == tmpMask) - break; - tmpMask >>= 1; - } - if (TmpId - BitId == 0) { /*get Cycle time for X, SPD BYTE9 */ - TmpCycTime = - DramAttr->DimmInfo[SckId]. - SPDDataBuf[SPD_SDRAM_TCLK_X]; - } else if (TmpId - BitId == 1) { /*get Cycle time for X-1, SPD BYTE23 */ - TmpCycTime = - DramAttr->DimmInfo[SckId]. - SPDDataBuf[SPD_SDRAM_TCLK_X_1]; - } else if (TmpId - BitId == 2) { /*get cycle time for X-2, SPD BYTE25 */ - TmpCycTime = - DramAttr->DimmInfo[SckId]. - SPDDataBuf[SPD_SDRAM_TCLK_X_2]; - } else { - //error!!! - } - if (TmpCycTime > CycTime) /*get the most cycle time,there is some problem! */ - CycTime = TmpCycTime; - } - } - - if (CycTime <= 0) { - //error! - for (;;); - } - - /* cycle time value - 0x25-->2.5ns Freq=400 DDR800 - 0x30-->3.0ns Freq=333 DDR667 - 0x3D-->3.75ns Freq=266 DDR533 - 0x50-->5.0ns Freq=200 DDR400 - 0x60-->6.0ns Freq=166 DDR333 - 0x75-->7.5ns Freq=133 DDR266 - 0xA0-->10.0ns Freq=100 DDR200 - */ - if (CycTime <= 0x25) { - DramAttr->DramFreq = DIMMFREQ_800; - DramAttr->DramCyc = 250; - } else if (CycTime <= 0x30) { - DramAttr->DramFreq = DIMMFREQ_667; - DramAttr->DramCyc = 300; - } else if (CycTime <= 0x3d) { - DramAttr->DramFreq = DIMMFREQ_533; - DramAttr->DramCyc = 375; - } else if (CycTime <= 0x50) { - DramAttr->DramFreq = DIMMFREQ_400; - DramAttr->DramCyc = 500; - } else if (CycTime <= 0x60) { - DramAttr->DramFreq = DIMMFREQ_333; - DramAttr->DramCyc = 600; - } else if (CycTime <= 0x75) { - DramAttr->DramFreq = DIMMFREQ_266; - DramAttr->DramCyc = 750; - } else if (CycTime <= 0xA0) { - DramAttr->DramFreq = DIMMFREQ_200; - DramAttr->DramCyc = 1000; - } - //if set the frequence mannul - PRINT_DEBUG_MEM("Dram Frequency:"); - PRINT_DEBUG_MEM_HEX16(DramAttr->DramFreq); - PRINT_DEBUG_MEM(" \r"); -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/rank_map.c b/src/northbridge/via/vx800/ddr2init/vx800/rank_map.c deleted file mode 100644 index f86a3648d3..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/rank_map.c +++ /dev/null @@ -1,363 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -extern void DRAMSetVRNum(DRAM_SYS_ATTR * DramAttr, - u8 PhyRank, u8 VirRank, BOOLEAN Enable); - -extern void SetEndingAddr(DRAM_SYS_ATTR * DramAttr, u8 VirRank, // Ending address register number indicator (INDEX - INT8 Value); // (value) add or subtract value to this and after banks - - -void DRAMClearEndingAddress(DRAM_SYS_ATTR * DramAttr); - -void DRAMSizingEachRank(DRAM_SYS_ATTR * DramAttr); - -BOOLEAN DoDynamicSizing1XM(DRAM_SYS_ATTR * DramAttr, - u8 * nRA, u8 * nCA, u8 * nBS, u8 PhyRank); - -void DRAMSetRankMAType(DRAM_SYS_ATTR * DramAttr); - -void DRAMSetEndingAddress(DRAM_SYS_ATTR * DramAttr); - -void DRAMPRToVRMapping(DRAM_SYS_ATTR * DramAttr); - -/*=================================================================== -Function : DRAMBankInterleave() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void -Purpose : STEP 13 Set Bank Interleave VIANB3DRAMREG69[7:6] 00:No Interleave 01:2 Bank 10:4 Bank 11:8 Bank - Scan all DIMMs on board to find out the lowest Bank Interleave among these DIMMs and set register. -===================================================================*/ -void DRAMBankInterleave(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data, SpdBAData; - DIMM_INFO *CurrentDimminfo; - u8 Bank = 3, Shift, RankNO, Count; - Shift = 1; - for (RankNO = 0; RankNO < 4; RankNO += 2) //all_even 0 RankNO 4 6 - { - if ((DramAttr->RankPresentMap & Shift) != 0) { - CurrentDimminfo = &(DramAttr->DimmInfo[RankNO >> 1]); //this Rank in a dimm - SpdBAData = - (u8) (CurrentDimminfo-> - SPDDataBuf[SPD_SDRAM_NO_OF_BANKS]); - if (SpdBAData == 4) - Count = 2; - else if (SpdBAData == 8) - Count = 3; - else - Count = 0; - if (Count < Bank) - Bank = Count; - } - Shift <<= 2; - } - - Data = pci_read_config8(MEMCTRL, 0x69); - Data &= ~0xc0; - Data |= (Bank << 6); - pci_write_config8(MEMCTRL, 0x69, Data); - - - if (DramAttr->DimmNumChB > 0) { - CurrentDimminfo = &(DramAttr->DimmInfo[3]); //this Rank in a dimm - SpdBAData = - (u8) (CurrentDimminfo-> - SPDDataBuf[SPD_SDRAM_NO_OF_BANKS]); - if (SpdBAData == 4) - Bank = 2; - else if (SpdBAData == 2) - Bank = 1; - else - Bank = 0; - pci_write_config8(MEMCTRL, 0x87, Bank); - } -} - -/*=================================================================== -Function : DRAMSizingMATypeM() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void - Purpose : STEP 14 1 DRAM Sizing 2 Fill MA type 3 Prank to vrankMapping -===================================================================*/ -void DRAMSizingMATypeM(DRAM_SYS_ATTR * DramAttr) -{ - DRAMClearEndingAddress(DramAttr); - DRAMSizingEachRank(DramAttr); - //DRAMReInitDIMMBL (DramAttr); - DRAMSetRankMAType(DramAttr); - DRAMSetEndingAddress(DramAttr); - DRAMPRToVRMapping(DramAttr); -} - -/*=================================================================== -Function : DRAMClearEndingAddress() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void -Purpose : clear Ending and Start adress from 0x40-4f to zero -===================================================================*/ -void DRAMClearEndingAddress(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data, Reg; - Data = 0; - for (Reg = 0x40; Reg <= 0x4f; Reg++) { - pci_write_config8(MEMCTRL, Reg, Data); - } -} - -/*=================================================================== -Function : DRAMSizingEachRank() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void -Purpose : Sizing each Rank invidually, by number of rows column banks pins, be care about 128bit -===================================================================*/ -void DRAMSizingEachRank(DRAM_SYS_ATTR * DramAttr) -{ - u8 Slot, RankIndex, Rows, Columns, Banks; - u32 Size; - BOOLEAN HasThreeBitBA; - u8 Data; - u32 Address; - - HasThreeBitBA = FALSE; - for (Slot = 0; Slot < 2; Slot++) { - if (!DramAttr->DimmInfo[Slot].bPresence) - continue; - Rows = - DramAttr->DimmInfo[Slot]. - SPDDataBuf[SPD_SDRAM_ROW_ADDR]; - Columns = - DramAttr->DimmInfo[Slot]. - SPDDataBuf[SPD_SDRAM_COL_ADDR]; - Banks = DramAttr->DimmInfo[Slot].SPDDataBuf[SPD_SDRAM_NO_OF_BANKS]; //this is Bank number not Bank address bit - if (Banks == 4) - Banks = 2; - else if (Banks == 8) - Banks = 3; - else - Banks = 0; - Size = (u32) (1 << (Rows + Columns + Banks + 3)); - RankIndex = 2 * Slot; - DramAttr->RankSize[RankIndex] = Size; - //if this module have two ranks - if ((DramAttr->DimmInfo[Slot]. - SPDDataBuf[SPD_SDRAM_DIMM_RANKS] & 0x07) == 0x01) { - RankIndex++; - DramAttr->RankSize[RankIndex] = Size; - } - - PRINT_DEBUG_MEM("rows: "); - PRINT_DEBUG_MEM_HEX8(Rows); - PRINT_DEBUG_MEM(", columns:"); - PRINT_DEBUG_MEM_HEX8(Columns); - PRINT_DEBUG_MEM(", banks:"); - PRINT_DEBUG_MEM_HEX8(Banks); - PRINT_DEBUG_MEM("\r"); - - if (Banks == 3) - HasThreeBitBA = TRUE; - } - - //must set BA2 enable if any 8-bank device exists - if (HasThreeBitBA) { - Data = pci_read_config8(MEMCTRL, 0x53); - Data |= 0x80; - pci_write_config8(MEMCTRL, 0x53, Data); - } -#if 1 - for (RankIndex = 0; DramAttr->RankSize[RankIndex] != 0; - RankIndex++) { - PRINT_DEBUG_MEM("Rank:"); - PRINT_DEBUG_MEM_HEX8(RankIndex); - PRINT_DEBUG_MEM(", Size:"); - PRINT_DEBUG_MEM_HEX32(DramAttr->RankSize[RankIndex] >> 20); - PRINT_DEBUG_MEM("\r"); - } -#endif -} - -/*=================================================================== -Function : DRAMSetRankMAType() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void -Purpose : set the matype Reg by MAMapTypeTbl, which the rule can be found in memoryinit -===================================================================*/ -void DRAMSetRankMAType(DRAM_SYS_ATTR * DramAttr) -{ - u8 SlotNum, Data, j, Reg, or, and; - u8 ShiftBits[] = { 5, 1, 5, 1 }; /* Rank 0/1 MA Map Type is 7:5, Rank 2/3 MA Map Type is 3:1. See Fun3Rx50. */ - u8 MAMapTypeTbl[] = { /* Table 12 of P4M800 Pro DataSheet. */ - 2, 9, 0, /* Bank Address Bits, Column Address Bits, Rank MA Map Type */ - 2, 10, 1, - 2, 11, 2, - 2, 12, 3, - 3, 10, 5, - 3, 11, 6, - 3, 12, 7, - 0, 0, 0 - }; - Data = pci_read_config8(MEMCTRL, 0x50); - Data &= 0x1; - pci_write_config8(MEMCTRL, 0x50, Data); - // disable MA32/16 MA33/17 swap in memory init it has this Reg fill - Data = pci_read_config8(MEMCTRL, 0x6b); - Data &= ~0x08; - pci_write_config8(MEMCTRL, 0x6b, Data); - - Data = 0x00; - for (SlotNum = 0; SlotNum < MAX_DIMMS; SlotNum++) { - if (DramAttr->DimmInfo[SlotNum].bPresence) { - for (j = 0; MAMapTypeTbl[j] != 0; j += 3) { - if ((1 << MAMapTypeTbl[j]) == - DramAttr->DimmInfo[SlotNum]. - SPDDataBuf[SPD_SDRAM_NO_OF_BANKS] - && MAMapTypeTbl[j + 1] == - DramAttr->DimmInfo[SlotNum]. - SPDDataBuf[SPD_SDRAM_COL_ADDR]) { - break; - } - } - if (0 == MAMapTypeTbl[j]) { - PRINT_DEBUG_MEM - ("UNSUPPORTED Bank, Row and Column Addr Bits!\r"); - return; - } - or = MAMapTypeTbl[j + 2] << ShiftBits[SlotNum]; - if (DramAttr->CmdRate == 1) - or |= 0x01 << (ShiftBits[SlotNum] - 1); - - Reg = SlotNum / 2; - if ((SlotNum & 0x01) == 0x01) { - and = 0xf1; // BUGBUG: it should be 0xf0 - } else { - and = 0x1f; // BUGBUG: it should be 0x0f - } - Data = pci_read_config8(MEMCTRL, 0x50 + Reg); - Data &= and; - Data |= or; - pci_write_config8(MEMCTRL, 0x50 + Reg, Data); - } - } - //may have some Reg filling at add 3-52 11 and 3-53 in his function -} - -/*=================================================================== -Function : DRAMSetEndingAddress() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void -Purpose : realize the Vrank 40...Reg (Start and Ending Regs). Vrank have same order with phy Rank, Size is actual Size -===================================================================*/ -void DRAMSetEndingAddress(DRAM_SYS_ATTR * DramAttr) -{ - u8 Shift = 1, Data, RankNO, Size, Start = 0, End = 0, Vrank; - for (RankNO = 0; RankNO < 4; RankNO++) { - if ((DramAttr->RankPresentMap & Shift) != 0) { - Size = (u8) (DramAttr->RankSize[RankNO] >> 26); // current Size in the unit of 64M - if (Size != 0) { - - End = End + Size; // calculate current ending address, add the current Size to ending - Vrank = RankNO; // get virtual Rank - Data = End; // set begin/End address register to correspondig virtual Rank # - pci_write_config8(MEMCTRL, 0x40 + Vrank, - Data); - Data = Start; - pci_write_config8(MEMCTRL, 0x48 + Vrank, - Data); - PRINT_DEBUG_MEM("Rank: "); - PRINT_DEBUG_MEM_HEX8(Vrank); - PRINT_DEBUG_MEM(", Start:"); - PRINT_DEBUG_MEM_HEX8(Start); - PRINT_DEBUG_MEM(", End:"); - PRINT_DEBUG_MEM_HEX8(End); - PRINT_DEBUG_MEM("\r"); - - Start = End; - } - } - Shift <<= 1; - } - - if (DramAttr->RankNumChB > 0) { - //this is a bug,fixed is to 2,so the max LL size is 128M - Data = 0x02; - pci_write_config8(MEMCTRL, 0x44, Data); - } - Data = End * 4; - pci_write_config8(PCI_DEV(0, 17, 7), 0x60, Data); - // We should directly write to south Bridge, not in north bridge - // program LOW TOP Address - Data = pci_read_config8(MEMCTRL, 0x88); - pci_write_config8(MEMCTRL, 0x85, Data); - - // also program vlink mirror - // We should directly write to south Bridge, not in north bridge - pci_write_config8(PCI_DEV(0, 17, 7), 0xe5, Data); -} - -/*=================================================================== -Function : DRAMPRToVRMapping() -Precondition : -Input : - DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard -Output : Void -Purpose : set the Vrank-prank map with the same order -===================================================================*/ -void DRAMPRToVRMapping(DRAM_SYS_ATTR * DramAttr) -{ - u8 Shift, Data, and, or, DimmNO = 0, PhyRankNO, Reg; - - for (Reg = 0x54; Reg <= 0x57; Reg++) //clear the map-reg - { - Data = 0; - pci_write_config8(MEMCTRL, Reg, Data); - } - - Shift = 1; - for (PhyRankNO = 0; PhyRankNO < MAX_RANKS; PhyRankNO++) { - if ((DramAttr->RankPresentMap & Shift) != 0) { - or = PhyRankNO; // get virtual Rank ,same with PhyRank - or |= 0x08; - - if ((PhyRankNO & 0x01) == 0x01) // get mask for register - and = 0xf0; - else { - and = 0x0f; - or <<= 4; - } - DimmNO = (PhyRankNO >> 1); - Data = pci_read_config8(MEMCTRL, 0x54 + DimmNO); - Data &= and; - Data |= or; - pci_write_config8(MEMCTRL, 0x54 + DimmNO, Data); - } - Shift <<= 1; - } -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/timing_setting.c b/src/northbridge/via/vx800/ddr2init/vx800/timing_setting.c deleted file mode 100644 index 5e1847800a..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/timing_setting.c +++ /dev/null @@ -1,492 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - - /* - Set Dram Timing functions - */ - -void SetCL(DRAM_SYS_ATTR * DramAttr); - -void SetTrp(DRAM_SYS_ATTR * DramAttr); - -void SetTrcd(DRAM_SYS_ATTR * DramAttr); - -void SetTras(DRAM_SYS_ATTR * DramAttr); - -void SetTrfc(DRAM_SYS_ATTR * DramAttr); - -void SetTrrd(DRAM_SYS_ATTR * DramAttr); - -void SetTwr(DRAM_SYS_ATTR * DramAttr); - -void SetTwtr(DRAM_SYS_ATTR * DramAttr); - -void SetTrtp(DRAM_SYS_ATTR * DramAttr); - -/* Set DRAM Timing*/ -void DRAMTimingSetting(DRAM_SYS_ATTR * DramAttr) -{ - PRINT_DEBUG_MEM("Set CAS latency value!"); - SetCL(DramAttr); - - PRINT_DEBUG_MEM("Set tRP value!"); - SetTrp(DramAttr); - - PRINT_DEBUG_MEM("Set tRCD value!"); - SetTrcd(DramAttr); - - PRINT_DEBUG_MEM("Set tRAS value!"); - SetTras(DramAttr); - - PRINT_DEBUG_MEM("Set tRFC value!"); - SetTrfc(DramAttr); - - PRINT_DEBUG_MEM("Set tRRD value!"); - SetTrrd(DramAttr); - - PRINT_DEBUG_MEM("Set tWR value!"); - SetTwr(DramAttr); - - PRINT_DEBUG_MEM("Set tWTR value!"); - SetTwtr(DramAttr); - - PRINT_DEBUG_MEM("Set tRTP value!"); - SetTrtp(DramAttr); -} - - -/* -Set DRAM Timing: CAS Latency for DDR1 -D0F3RX62 bit[0:2] for CAS Latency; -*/ -void SetCL(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u8 CL; - - /*DDR2 CL Value: 20, 30, 40, 50 -> 2, 3, 4, 5 */ - CL = (u8) ((DramAttr->CL - 20) / 10); //000,001,010,011 - - PRINT_DEBUG_MEM("CAS = "); - PRINT_DEBUG_MEM_HEX8(CL); - PRINT_DEBUG_MEM("\n"); - Data = pci_read_config8(MEMCTRL, 0x62); - Data = (u8) ((Data & 0xf8) | CL); - pci_write_config8(MEMCTRL, 0x62, Data); -} - - -/* - Minimum row precharge time, Trp for DDR1/DDR2 - D0F3Rx64[3:2] for Trp 2T~5T -*/ -#define MAX_TRP 6 -#define MIN_TRP 2 - -void SetTrp(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - - /*get the max Trp value from SPD data - SPD Byte27, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRP]); - if (Tmp > Max) - Max = Tmp; - } - /*Calculate clock,this value should be 2T,3T,4T,5T */ - } - Tmp = - (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - - 1) / ((DramAttr->DramCyc) << 2)); - PRINT_DEBUG_MEM("Trp = "); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - if (Tmp > MAX_TRP) - Tmp = MAX_TRP; - else if (Tmp < MIN_TRP) - Tmp = MIN_TRP; - - Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T - Tmp <<= 1; //bit1,2,3 - - Data = pci_read_config8(MEMCTRL, 0x64); - Data = (u8) ((Data & 0xf1) | (u8) Tmp); - pci_write_config8(MEMCTRL, 0x64, Data); - - //enable DDR2 8-Bank Device Timing Constraint - Data = pci_read_config8(MEMCTRL, 0x62); - Data = (u8) ((Data & 0xf7) | 0x08); - pci_write_config8(MEMCTRL, 0x62, Data); -} - - -/* -Minimum RAS to CAS dely,Trcd for DDR1/DDR2 -D0F3Rx64[7:6] for Trcd -*/ -#define MAX_TRCD 6 -#define MIN_TRCD 2 - -void SetTrcd(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - - /*get the max Trcd value from SPD data - SPD Byte29, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRCD]); - if (Tmp > Max) - Max = Tmp; - } - } - /*Calculate clock,this value should be 2T,3T,4T,5T */ - Tmp = - (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - - 1) / ((DramAttr->DramCyc) << 2)); - PRINT_DEBUG_MEM("Trcd ="); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - if (Tmp > MAX_TRCD) - Tmp = MAX_TRCD; - else if (Tmp < MIN_TRCD) - Tmp = MIN_TRCD; - Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T - Tmp <<= 5; //bit5,6,7 - - Data = pci_read_config8(MEMCTRL, 0x64); - Data = (u8) ((Data & 0x1f) | (u8) Tmp); - pci_write_config8(MEMCTRL, 0x64, Data); - -} - -/* - minimum active to precharge time,Tras for DDR1/DDR2 - D0F3Rx62[7:4] Tras -*/ -#define MAX_TRAS 20 //20T -#define MIN_TRAS 5 //5T -void SetTras(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - - /*get the max Tras value from SPD data - SPD byte30: bit0:7 1ns~255ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRAS]); - if (Tmp > Max) - Max = Tmp; - } - } - - /*Calculate clock,value range 5T-20T */ - Tmp = - (u16) ((Max * 100 + DramAttr->DramCyc - - 1) / (DramAttr->DramCyc)); - PRINT_DEBUG_MEM("Tras ="); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - if (Tmp > MAX_TRAS) - Tmp = MAX_TRAS; - else if (Tmp < MIN_TRAS) - Tmp = MIN_TRAS; - Tmp -= 5; //0->5T ... 1111->20T - Tmp <<= 4; //bit4:7 - - Data = pci_read_config8(MEMCTRL, 0x62); - Data = (u8) ((Data & 0x0f) | (u8) Tmp); - pci_write_config8(MEMCTRL, 0x62, Data); -} - -/* -Minimum refresh to activate/refresh command period Trfc for DDR1/DDR2 -D0F3Rx61[5:0] for Trfc -*/ - -#define MAX_TRFC 71 // Max supported,71T -#define MIN_TRFC 8 // Min supported,8T - -void SetTrfc(DRAM_SYS_ATTR * DramAttr) -{ - - u8 Data; - u32 Max, Tmp; - u8 Byte40; - u8 Socket; - - /*get the max Trfc value from SPD data */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u32) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRFC]) * 100; - /*only DDR2 need to add byte 40 bit[7:4] */ - Byte40 = - (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRFC2]); - /*if bit0 = 1, byte42(RFC)+256ns, SPD spec JEDEC standard No.21.c */ - if (Byte40 & 0x01) - Tmp += (256 * 100); - /*bit1,2,3 000->0ns+byte42; 001->0.25ns+byte42; 010->0.33ns+byte42; 011->0.5ns+byte42;100-> 0.75ns+byte42 */ - switch ((Byte40 >> 1) & 0x07) { /*bit1,2,3 */ - case 1: - Tmp += 25; - break; - case 2: - Tmp += 33; - break; - case 3: - Tmp += 50; - break; - case 4: - Tmp += 66; - break; - case 5: - Tmp += 75; - break; - case 6: //what is FRU??? - default: - break; - } - if (Tmp > Max) - Max = Tmp; - } - } - - /*Calculate clock,value range 8T-71T */ - Tmp = (u16) ((Max + DramAttr->DramCyc - 1) / (DramAttr->DramCyc)); - PRINT_DEBUG_MEM("Trfc = "); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - if (Tmp > MAX_TRFC) - Tmp = MAX_TRFC; - else if (Tmp < MIN_TRFC) { - // return; - Tmp = 0x40; - } - /*D0F3Rx61 bit[0:5] 0->8T ... 63->71T */ - Tmp -= 8; - - Data = pci_read_config8(MEMCTRL, 0x61); - Data = (u8) ((Data & 0xc0) | ((u8) Tmp & 0x3f)); - pci_write_config8(MEMCTRL, 0x61, Data); -} - - -/* -Minimum row active to row active delay: Trrd for DDR1/DDR2 -D0F3Rx61[7:6]:Trrd 00->2T, 01->3T, 10->4T, 11->5T -*/ -#define MAX_TRRD 5 -#define MIN_TRRD 2 - -void SetTrrd(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - - /*get the max Trrd value from SPD data - SPD Byte28, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRRD]); - if (Tmp > Max) - Max = Tmp; - } - } - - /*Calculate clock,this value should be 2T,3T,4T,5T */ - Tmp = - (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - - 1) / ((DramAttr->DramCyc) << 2)); - PRINT_DEBUG_MEM("Trrd ="); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - if (Tmp > MAX_TRRD) - Tmp = MAX_TRRD; - else if (Tmp < MIN_TRRD) - Tmp = MIN_TRRD; - Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T - Tmp <<= 6; - - Data = pci_read_config8(MEMCTRL, 0x61); - Data = (u8) ((Data & 0x3f) | (u8) Tmp); - pci_write_config8(MEMCTRL, 0x61, Data); -} - - -/* -Write recovery time: Twr for DDR1/DDR2 -Device 0 Function 3:REG63[7:5]:Twr 00->2T 01->3T 10->4T 11->5T -*/ -#define MAX_TWR 6 -#define MIN_TWR 2 - -void SetTwr(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - /*get the max Trtp value from SPD data - SPD Byte36, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TWR]); - if (Tmp > Max) - Max = Tmp; - } - } - /*Calculate clock */ - Tmp = (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - 1) / ((DramAttr->DramCyc) << 2)); //this value should be 2T,3T,4T,5T - PRINT_DEBUG_MEM("Twr = "); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - if (Tmp > MAX_TWR) - Tmp = MAX_TWR; - else if (Tmp < MIN_TWR) - Tmp = MIN_TWR; - Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T - Tmp <<= 5; - - Data = pci_read_config8(MEMCTRL, 0x63); - Data = (u8) ((Data & 0x1f) | (u8) Tmp); - pci_write_config8(MEMCTRL, 0x63, Data); -} - - -/* -Internal write to read command delay: Twtr for DDR1/DDR2 -Device 0 Function 3:REG63[1,0]:Twtr DDR: 1T or 2T; DDR2 2T or 3T -*/ -#define MAX_TWTR 5 //5T -#define MIN_TWTR 2 //2T - -void SetTwtr(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - /*get the max Trtp value from SPD data - SPD Byte37, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TWTR]); - if (Tmp > Max) - Max = Tmp; - } - } - /*Calculate clock */ - Tmp = (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - 1) / ((DramAttr->DramCyc) << 2)); //this value should be 2T or 3T - - PRINT_DEBUG_MEM("Twtr ="); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - if (Tmp > MAX_TWR) - Tmp = MAX_TWTR; - else if (Tmp < MIN_TWR) - Tmp = MIN_TWTR; - Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T - Data = pci_read_config8(MEMCTRL, 0x63); - Data = (u8) ((Data & 0xFC) | Tmp); - pci_write_config8(MEMCTRL, 0x63, Data); -} - - -/* -Internal read to precharge command delay, Trtp for DDR1/DDR2 -Device 0 Function 3:REG63[3]:Trtp 2T or 3T -*/ -#define MAX_TRTP 3 //3T -#define MIN_TRTP 2 //2T - -void SetTrtp(DRAM_SYS_ATTR * DramAttr) -{ - u8 Data; - u16 Max, Tmp; - u8 Socket; - - - /*get the max Trtp value from SPD data - SPD Byte38, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ - Max = 0; - for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { - if (DramAttr->DimmInfo[Socket].bPresence) { - Tmp = - (u16) (DramAttr->DimmInfo[Socket]. - SPDDataBuf[SPD_SDRAM_TRTP]); - if (Tmp > Max) - Max = Tmp; - } - } - /*Calculate clock */ - Tmp = (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - 1) / ((DramAttr->DramCyc) << 2)); //this value should be 2T or 3T - - PRINT_DEBUG_MEM("Trtp ="); - PRINT_DEBUG_MEM_HEX16(Tmp); - PRINT_DEBUG_MEM("\r"); - - Data = pci_read_config8(MEMCTRL, 0x63); - if (Tmp > MIN_TRTP) - Data = (u8) (Data | 0x08); /*set bit3, set 3T */ - else - Data = (u8) (Data & 0xf7); /*clear bit3, set 2T */ - - pci_write_config8(MEMCTRL, 0x63, Data); -} diff --git a/src/northbridge/via/vx800/ddr2init/vx800/uma_ram_setting.c b/src/northbridge/via/vx800/ddr2init/vx800/uma_ram_setting.c deleted file mode 100644 index f8aaf74eef..0000000000 --- a/src/northbridge/via/vx800/ddr2init/vx800/uma_ram_setting.c +++ /dev/null @@ -1,445 +0,0 @@ -/* - * This file is part of the coreboot project. - * - * Copyright (C) 2009 One Laptop per Child, Association, Inc. - * - * This program is free software; you can redistribute it and/or modify - * it under the terms of the GNU General Public License as published by - * the Free Software Foundation; version 2 of the License. - * - * This program is distributed in the hope that it will be useful, - * but WITHOUT ANY WARRANTY; without even the implied warranty of - * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the - * GNU General Public License for more details. - * - * You should have received a copy of the GNU General Public License - * along with this program; if not, write to the Free Software - * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA - */ - -typedef struct __UMA_RAM_tag { - u16 DramSize; - u8 D0F3Val; - u8 D1F0Val; - u8 VgaPortVal; -} UMARAM; -#define UMARAM_512M 7 -#define UMARAM_256M 6 -#define UMARAM_128M 5 -#define UMARAM_64M 4 -#define UMARAM_32M 3 -#define UMARAM_16M 2 -#define UMARAM_8M 1 -#define UMARAM_0M 0 - - -#define FB_512M 0 -#define FB_256M 0x40 -#define FB_128M 0x60 -#define FB_64M 0x70 -#define FB_32M 0x78 -#define FB_16M 0x7c -#define FB_8M 0x7E -#define FB_4M 0x7F - -#define VGA_PORT_512M 0x00 -#define VGA_PORT_256M 0x80 -#define VGA_PORT_128M 0xC0 -#define VGA_PORT_64M 0xE0 -#define VGA_PORT_32M 0xF0 -#define VGA_PORT_16M 0xF8 - -static const UMARAM UMARamArr[] = { - {0, UMARAM_0M, FB_4M, 0xFE}, - {8, UMARAM_8M, FB_8M, 0xFC}, - {16, UMARAM_16M, FB_16M, VGA_PORT_16M}, - {32, UMARAM_32M, FB_32M, VGA_PORT_32M}, - {64, UMARAM_64M, FB_64M, VGA_PORT_64M}, - {128, UMARAM_128M, FB_128M, VGA_PORT_128M}, - {256, UMARAM_256M, FB_256M, VGA_PORT_256M}, - {512, UMARAM_512M, FB_512M, VGA_PORT_512M}, - {0xffff, 0xff, 0xff, 0xFF} -}; - -void SetUMARam(void) -{ -#if 1 - u8 ramregs[] = { 0x43, 0x42, 0x41, 0x40 }; - device_t vga_dev = PCI_DEV(0, 1, 0), d0f0_dev = PCI_DEV(0, 0, 0); - u8 ByteVal, temp; - UMARAM *pUMARamTable; - u16 UmaSize; - u8 SLD0F3Val, SLD1F0Val, VgaPortVal; - u32 RamSize, SLBase, Tmp; - u8 i; - PRINT_DEBUG_MEM("Entering vx800 SetUMARam.\n"); - SLD0F3Val = 0; - SLD1F0Val = 0; - VgaPortVal = 0; - - - ByteVal = pci_read_config8(MEMCTRL, 0xa1); - ByteVal |= 0x80; - pci_write_config8(MEMCTRL, 0xa1, ByteVal); - - //set VGA Timer - pci_write_config8(MEMCTRL, 0xa2, 0xee); - - //set agp misc - //GFX Data Delay to Sync with Clock - pci_write_config8(MEMCTRL, 0xa4, 0x01); - - //page register life timer - pci_write_config8(MEMCTRL, 0xa6, 0x76); - - //GMINT and GFX relatate - //note Bit 3 VGA Enable - pci_write_config8(MEMCTRL, 0xa7, 0x8c); - // ByteVal = 0x4c; - - //GMINT Misc.1 - //pci_write_config8(MEMCTRL, 0xb0, 0x80); - - //pci_write_config8(MEMCTRL, 0xb1, 0xaa); - - //AGPCINT MISC - //pci_write_config8(MEMCTRL, 0xb2, 0x82); - //ByteVal = 0x8A; - - //GMINT MISC.2 - //disable read pass write - pci_write_config8(MEMCTRL, 0xb3, 0x9A); - - //EPLL Register - //pci_write_config8(MEMCTRL, 0xb4, 0x04); - - //enable CHA and CHB merge mode - pci_write_config8(MEMCTRL, 0xde, 0x06); - - //if can get the value from setup interface, so get the value - //else use the default value - UmaSize = CONFIG_VIDEO_MB; - - for (pUMARamTable = UMARamArr; pUMARamTable->DramSize != 0xffff; - pUMARamTable++) { - if (UmaSize == pUMARamTable->DramSize) { - SLD0F3Val = pUMARamTable->D0F3Val; - SLD1F0Val = pUMARamTable->D1F0Val; - VgaPortVal = pUMARamTable->VgaPortVal; - } - } - //set SL size - //Fill in Fun3_RXA1[6:4] with the Frame Buffer size for the Integrated Graphic Device. - ByteVal = pci_read_config8(MEMCTRL, 0xa1); - ByteVal = (ByteVal & 0x8f) | (SLD0F3Val << 4); - pci_write_config8(MEMCTRL, 0xa1, ByteVal); - - -// vga_dev = dev_find_device(PCI_VENDOR_ID_VIA, PCI_DEVICE_ID_VIA_VX855_VGA, 0); - - //RxB2 may be for S.L. and RxB1 may be for L. L. - // It is different from Spec. - ByteVal = SLD1F0Val; - pci_write_config8(vga_dev, 0xb2, ByteVal); - - - //set M1 size - //ByteVal=pci_read_config8(MEMCTRL, 0xa3); - //ByteVal = 0x02; - //pci_write_config8(MEMCTRL, 0xa3, ByteVal); - - PRINT_DEBUG_MEM("UMA setting - 3\n"); - - - - - //Enable p2p IO/mem - ByteVal = 0x07; - pci_write_config8(vga_dev, 0x04, ByteVal); - - - - - //must set SL and MMIO base, or else when enable GFX memory space, system will hang - //set S.L base - Tmp = pci_read_config32(vga_dev, 0x10); - Tmp = 0xfffffff8; - pci_write_config32(vga_dev, 0x10, Tmp); - Tmp = pci_read_config32(vga_dev, 0x10); - Tmp = VIACONFIG_VGA_PCI_10; - pci_write_config32(vga_dev, 0x10, Tmp); - - //set MMIO base - Tmp = pci_read_config32(vga_dev, 0x14); - Tmp = 0xfffffffC; - pci_write_config32(vga_dev, 0x14, Tmp); - Tmp = pci_read_config32(vga_dev, 0x14); - Tmp = VIACONFIG_VGA_PCI_14; - pci_write_config32(vga_dev, 0x14, Tmp); - - -//enable direct cpu frame buffer access - i = pci_rawread_config8(PCI_RAWDEV(0, 0, 3), 0xa1); - i = (i & 0xf0) | (VIACONFIG_VGA_PCI_10 >> 28); - pci_rawwrite_config8(PCI_RAWDEV(0, 0, 3), 0xa1, i); - pci_rawwrite_config8(PCI_RAWDEV(0, 0, 3), 0xa0, 0x01); - - - //enable GFx memory space access control for S.L and mmio - ByteVal = pci_read_config8(d0f0_dev, 0xD4); - ByteVal |= 0x03; - //ByteVal |= 0x01; - pci_write_config8(d0f0_dev, 0xD4, ByteVal); - - - //enable Base VGA 16 Bits Decode - ByteVal = pci_read_config8(d0f0_dev, 0xfe); - ByteVal |= 0x10; - pci_write_config8(d0f0_dev, 0xfe, ByteVal); - - - //disable CHB L.L - //set VGA memory selection - ByteVal = pci_read_config8(vga_dev, 0xb0); - ByteVal &= 0xF8; - //ByteVal |= 0x01; - ByteVal |= 0x03; - pci_write_config8(vga_dev, 0xb0, ByteVal); - - //set LL size - - //enable memory access to SL,MMIO,LL and IO to 3B0~3BB,3C0 ~3DF - //ByteVal = 0x03; - //pci_write_config8(d0f0_dev, 0xc0, ByteVal); - - //Turn on Graphic chip IO port port access - ByteVal = inb(0x03C3); - ByteVal |= 0x01; - outb(ByteVal, 0x03C3); - - //Turn off Graphic chip Register protection - outb(0x10, 0x03C4); - - ByteVal = inb(0x03C5); - ByteVal |= 0x01; - outb(ByteVal, 0x03C5); - - //set VGA memory Frequence - //direct IO port 0x3DX to vga io space 0x3C2[0] - ByteVal = inb(0x03CC); - ByteVal |= 0x03; - outb(ByteVal, 0x03C2); - // ByteVal=inb(0x03C2); - // ByteVal |= 0x01; - // outb(ByteVal,0x03C2); - - -#if 1 //bios porting guide has no this two defination: 3d on 3d4/3d5 and 39 on 3c4/3c5 - //set frequence 0x3D5.3d[7:4] - outb(0x3d, 0x03d4); - - temp = pci_read_config8(MEMCTRL, 0x90); - temp = (u8) (temp & 0x07); - ByteVal = inb(0x03d5); - switch (temp) { - case 0: //DIMMFREQ_200: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x30); - break; - case 1: //DIMMFREQ_266: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x40); - break; - case 3: //DIMMFREQ_400: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x60); - break; - case 4: //DIMMFREQ_533: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x70); - break; - case 5: //DIMMFREQ_667: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x80); - break; - case 6: //DIMMFREQ_800: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x90); - break; - default: - ByteVal = (u8) ((ByteVal & 0x0F) | 0x70); - break; - } - outb(ByteVal, 0x03d5); - - // Set frame buffer size - outb(0x39, 0x03c4); - outb(1 << SLD0F3Val, 0x03c5); - -#endif - // Set S.L. size in GFX's register - outb(0x68, 0x03c4); - outb(VgaPortVal, 0x03c5); - - // ECLK Selection (00:166Mhz, 01:185Mhz, 10:250Mhz, 11:275Mhz) - // set 3C5.5A[0]=1, address maps to secondary resgiters - outb(0x5a, 0x03c4); - ByteVal = inb(0x03c5); - ByteVal |= 0x01; - outb(ByteVal, 0x03c5); - - // Set 3D5.4C[7:6] (00:166Mhz, 01:185Mhz, 10:250Mhz, 11:275Mhz) - outb(0x4c, 0x03d4); - ByteVal = inb(0x03d5); - ByteVal = (ByteVal & 0x3F) | 0x80; - outb(ByteVal, 0x03d5); - - // set 3C5.5A[0]=0, address maps to first resgiters - outb(0x5a, 0x03c4); - ByteVal = inb(0x03c5); - ByteVal &= 0xFE; - outb(ByteVal, 0x03c5); - - // Set S.L. Address in System Memory - //calculate dram size - for (RamSize = 0, i = 0; i < ARRAY_SIZE(ramregs); i++) { - RamSize = pci_read_config8(MEMCTRL, ramregs[i]); - if (RamSize != 0) - break; - } - //calculate SL Base Address - SLBase = (RamSize << 26) - (UmaSize << 20); - - - outb(0x6D, 0x03c4); - //SL Base[28:21] - outb((u8) ((SLBase >> 21) & 0xFF), 0x03c5); - - outb(0x6e, 0x03c4); - //SL Base[36:29] - outb((u8) ((SLBase >> 29) & 0xFF), 0x03c5); - - outb(0x6f, 0x03c4); - outb(0x00, 0x03c5); - - // Set SVID high byte - outb(0x36, 0x03c4); - outb(0x11, 0x03c5); - - // Set SVID Low byte - outb(0x35, 0x03c4); - outb(0x06, 0x03c5); - - // Set SID high byte - outb(0x38, 0x03c4); - outb(0x51, 0x03c5); - - // Set SID Low byte - outb(0x37, 0x03c4); - outb(0x22, 0x03c5); - - //start : For enable snapshot mode control - // program 3C5 for SNAPSHOT Mode control, set RxF3h=1Ah - outb(0xf3, 0x03c4); - ByteVal = inb(0x03c5); - ByteVal = (ByteVal & 0xE5) | 0x1A; - outb(ByteVal, 0x03c5); - - - outb(0xf3, 0x03d4); - ByteVal = inb(0x03d5); - ByteVal = (ByteVal & 0xE5) | 0x1A; - outb(ByteVal, 0x03d5); - - u8 table3c43c5[0x70] = { - 0x03, 0x01, 0x0F, 0x00, 0x06, 0x00, 0x00, 0x00, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0x01, 0x78, 0x00, 0x00, 0x00, 0xBE, 0x20, 0x7F, - 0x60, 0x7F, 0x08, 0x31, 0xCC, 0x00, 0x01, 0x00, - 0x00, 0x18, 0x10, 0x00, 0x00, 0x00, 0x3D, 0x00, - 0x00, 0x00, 0x00, 0x00, 0x04, 0xF3, 0xFF, 0xFC, - 0xF8, 0x0C, 0x00, 0x00, 0x40, 0x06, 0x11, 0x22, - 0x51, 0x10, 0x00, 0x01, 0x19, 0x0C, 0x00, 0xFF, - 0x38, 0x40, 0x30, 0xFF, 0x70, 0x8C, 0x85, 0x9D, - 0x80, 0x05, 0x54, 0x90, 0x03, 0x30, 0x00, 0x5F, - 0x1F, 0x00, 0x00, 0xFF, 0x00, 0x00, 0xFF, 0x00, - 0x06, 0xDF, 0x00, 0x20, 0x20, 0x00, 0x00, 0x00, - 0x00, 0x00, 0x00, 0x40, 0x20, 0x00, 0x20, 0x20, - 0xE0, 0x20, 0xD0, 0x3F, 0x00, 0xE0, 0x00, 0x00 - }; - u8 table3d43d5[0x88] = { - 0x7F, 0x63, 0x63, 0x83, 0x69, 0x19, 0x72, 0xE0, - 0x00, 0x60, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0x58, 0x9C, 0x57, 0x90, 0x00, 0x57, 0x73, 0xE3, - 0x57, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0x0C, 0x00, 0x11, 0x06, 0x00, 0x20, 0x01, 0x34, - 0xEE, 0x74, 0x01, 0x01, 0x08, 0x84, 0x00, 0x00, - 0x00, 0xF3, 0x40, 0x90, 0x00, 0x00, 0x00, 0x01, - 0x00, 0x12, 0x00, 0x02, 0x00, 0x00, 0x10, 0x00, - 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, - 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x9D, 0x9D, 0x10, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x9D, 0x9D, 0x9D, - 0x9D, 0x9D, 0x9D, 0x9D, 0x00, 0x9D, 0x1D, 0x00, - 0x00, 0x00, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, - 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, - }; - - - u8 table3c0space[0xc0] = { - 0x11, 0x00, 0x10, 0x01, 0x26, 0x3D, 0xFF, 0x00, - 0x10, 0x3F, 0x00, 0x00, 0x2F, 0x00, 0x22, 0x00, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x50, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, - }; -#if 0 -//for(i=0;i<0xc0;i++) - for (i = 0; i < 0x40; i++) // - { - outb(table3c0space[i], 0x03c0 + i); - } - - - for (i = 0; i < 0x70; i++) { - outb(i, 0x03c4); - outb(table3c43c5[i], 0x03c5); - } - for (i = 0; i < 0x88; i++) { - outb(i, 0x03d4); - outb(table3d43d5[i], 0x03d5); - } - outb(0x92, 0x03d4); - outb(0x80, 0x03d5); - - outb(0xa3, 0x03d4); - outb(0x00, 0x03d5); - - outb(0xe8, 0x03d4); - outb(0x40, 0x03d5); -#endif -//3d4 3d freq -//IO Port / Index: 3X5.3D -//Scratch Pad Register 4 - -// outb(0x39,0x03c4);// - //outb(1 << SLD0F3Val ,0x03c5); -// -#endif - -} diff --git a/src/northbridge/via/vx800/detection.c b/src/northbridge/via/vx800/detection.c new file mode 100644 index 0000000000..63fc56b845 --- /dev/null +++ b/src/northbridge/via/vx800/detection.c @@ -0,0 +1,192 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +#define SMBUS_ADDR_CH_A_1 0xA0 // Dimmx +#define SMBUS_ADDR_CH_A_2 0xA2 // Dimmx +#define SMBUS_ADDR_CH_B_1 0xA4 // Dimmx +#define SMBUS_ADDR_CH_B_2 0xA6 // Dimmx + +/*read data*/ +CB_STATUS GetSPDData(u8 Slot, u8 Length, u8 * Buf); + +void DRAMCmdRate(DRAM_SYS_ATTR * DramAttr); + + + +CB_STATUS GetInfoFromSPD(DRAM_SYS_ATTR * DramAttr); + +CB_STATUS GetSPDData(u8 Slot, u8 Length, u8 * Buf) +{ + // CB_STATUS Status = CB_NOT_READY; + u8 Val; + u8 i; + + if (1 > Length || NULL == Buf) + return CB_INVALID_PARAMETER; + + for (i = 0; i < Length; i++) { + Val = get_spd_data(ctrl.channel0[Slot], i); + *(Buf + i) = Val; + } + return CB_SUCCESS; +} + +CB_STATUS DRAMDetect(DRAM_SYS_ATTR * DramAttr) +{ + CB_STATUS Status = CB_SUCCESS; + + PRINT_DEBUG_MEM("Dram Detection \r"); + + /*Read D0F3Rx6C , detect memory type DDR1 or DDR2 */ + // 353 supports DDR2 only + DramAttr->DramType = RAMTYPE_SDRAMDDR2; + /*get information for SPD */ + Status = GetInfoFromSPD(DramAttr); + if (CB_SUCCESS == Status) { + /*64bit or 128Bit */ + // + // if (RAMTYPE_SDRAMDDR == DramAttr->DramType) + + /*select command rate */ + DRAMCmdRate(DramAttr); + } + return Status; +} + + +// Determine 1T or 2T Command Rate: +// To enable 1T command Rate, the system will satisfy the following 3 conditions: +// 1. Each DRAM channel may have 1 or 2 ranks of DIMM. 3/4 ranks can not support 1T command rate +// It's for loading issue. 1T can supports (a). only one socket with two ranks OR +// (b). two sockets each with 1 rank. +// 2. User wishes to enable 1T command rate mode and turn on by Setup menu +// 3. If 1T command rate can be enabled, just set EBP bit here. +void DRAMCmdRate(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + + // 5.1t/2t command rate, use the stable set + //offset50 + DramAttr->CmdRate = 2; + Data = pci_read_config8(MEMCTRL, 0x50); + Data = (u8) (Data & 0xEE); + pci_write_config8(MEMCTRL, 0x50, Data); +} + +/*get SPD data and set RANK presence map*/ +/* +Sockets0,1 is Channel A / Sockets2,3 is Channel B +socket0 SPD device address 0x50 / socket1 SPD device address 0x51 +socket2 SPD device address 0x52 / socket3 SPD device address 0x53 +*/ +CB_STATUS GetInfoFromSPD(DRAM_SYS_ATTR * DramAttr) +{ + CB_STATUS Status; + u8 *pSPDDataBuf; + u8 ModuleDataWidth; + u8 ChipWidth; + u8 RankNum; + u8 LoadNum; + u8 Sockets, i; + BOOLEAN bFind; + bFind = FALSE; + Status = CB_DEVICE_ERROR; + + for (Sockets = 0; Sockets < MAX_SOCKETS; Sockets++) { + pSPDDataBuf = DramAttr->DimmInfo[Sockets].SPDDataBuf; + pSPDDataBuf[SPD_MEMORY_TYPE] = + get_spd_data(ctrl.channel0[Sockets], SPD_MEMORY_TYPE); + if (pSPDDataBuf[SPD_MEMORY_TYPE] == 0) { + Status = CB_NOT_READY; + } else { + Status = + GetSPDData(Sockets, SPD_DATA_SIZE, + pSPDDataBuf); + PRINT_DEBUG_MEM("SPD : \r"); + for (i = 0; i < SPD_DATA_SIZE; i++) { + PRINT_DEBUG_MEM(" "); + PRINT_DEBUG_MEM_HEX8(pSPDDataBuf[i]); + } + } + if (CB_SUCCESS == Status) { + /*if Dram Controller detected type not same as the type got from SPD, There are ERROR */ + if (pSPDDataBuf[SPD_MEMORY_TYPE] != + DramAttr->DramType) { + Status = CB_DEVICE_ERROR; /*Memory int error */ + PRINT_DEBUG_MEM + ("Memory Device ERROR: Dram Controller detected type != type got from SPD \r"); + break; + } + DramAttr->DimmInfo[Sockets].bPresence = TRUE; + /*calculate load number (chips number) */ + ModuleDataWidth = + (u8) (DramAttr->DimmInfo[Sockets]. + SPDDataBuf[SPD_SDRAM_MOD_DATA_WIDTH + + 1]); + ModuleDataWidth = (u8) (ModuleDataWidth << 8); + ModuleDataWidth |= + (u8) (DramAttr->DimmInfo[Sockets]. + SPDDataBuf[SPD_SDRAM_MOD_DATA_WIDTH]); + ChipWidth = + (u8) ((DramAttr->DimmInfo[Sockets]. + SPDDataBuf[SPD_SDRAM_WIDTH]) & 0x7F); + LoadNum = (u8) (ModuleDataWidth / ChipWidth); + + /*set the RANK map */ + RankNum = (u8) (pSPDDataBuf[SPD_SDRAM_DIMM_RANKS] & 0x3); /*get bit0,1, the Most number of supported RANK is 2 */ + if (RAMTYPE_SDRAMDDR2 == DramAttr->DramType) + RankNum++; /*for DDR bit[0,1] 01->1 RANK 10->2 RANK; for DDR2 bit[0,1] = 00 -> 1 RANK 01 -> 2 RANK */ + if (RankNum != 2 && RankNum != 1) { /*every DIMM have 1 or 2 ranks */ + Status = CB_DEVICE_ERROR; + PRINT_DEBUG_MEM + ("Memory Device ERROR: the number of RANK not support!\r"); + break; + } + + if (Sockets < 2) { /*sockets0,1 is channel A */ + DramAttr->RankNumChA = + (u8) (DramAttr->RankNumChA + RankNum); + DramAttr->DimmNumChA++; + DramAttr->LoadNumChA = + (u8) (DramAttr->LoadNumChA * LoadNum * + RankNum); + } else { /*sockets2,3 is channel B */ + + DramAttr->RankNumChB = + (u8) (DramAttr->RankNumChB + RankNum); + DramAttr->DimmNumChB++; + DramAttr->LoadNumChB = + (u8) (DramAttr->LoadNumChB * LoadNum * + RankNum);; + } + RankNum |= 1; /*set rank map */ + DramAttr->RankPresentMap |= + (RankNum << (Sockets * 2)); + bFind = TRUE; + } + } + PRINT_DEBUG_MEM("Rank Present Map:"); + PRINT_DEBUG_MEM_HEX8(DramAttr->RankPresentMap); + PRINT_DEBUG_MEM("\r"); + + if (bFind) + Status = CB_SUCCESS; + + return Status; +} diff --git a/src/northbridge/via/vx800/dev_init.c b/src/northbridge/via/vx800/dev_init.c new file mode 100644 index 0000000000..bb0232589d --- /dev/null +++ b/src/northbridge/via/vx800/dev_init.c @@ -0,0 +1,1318 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +void DRAMSetVRNum(DRAM_SYS_ATTR * DramAttr, u8 PhyRank, // Physical Rank + u8 VirRank, // Virtual Rank + BOOLEAN Enable); + +void SetEndingAddr(DRAM_SYS_ATTR * DramAttr, u8 VirRank, // Ending address register number indicator (INDEX + INT8 Value // (value) add or subtract value to this and after banks + ); + +void InitDDR2CHA(DRAM_SYS_ATTR * DramAttr); + +void InitDDR2CHB(DRAM_SYS_ATTR * DramAttr); + +void InitDDR2CHC(DRAM_SYS_ATTR * DramAttr); + +CB_STATUS VerifyChc(); +/*=================================================================== +Function : DRAMRegInitValue() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : Set necessary register before DRAM initialize +===================================================================*/ + +static const u8 DramRegTbl[][3] = { + //Register AND OR + {0x50, 0x11, 0xEE}, // DDR default MA7 for DRAM init + {0x51, 0x11, 0x60}, // DDR default MA3 for CHB init + {0x52, 0x00, 0x33}, // DDR use BA0=M17, BA1=M18, + {0x53, 0x00, 0x3F}, // DDR BA2=M19 + + {0x54, 0x00, 0x00}, // default PR0=VR0; PR1=VR1 + {0x55, 0x00, 0x00}, // default PR2=VR2; PR3=VR3 + {0x56, 0x00, 0x00}, // default PR4=VR4; PR5=VR5 + {0x57, 0x00, 0x00}, // default PR4=VR4; PR5=VR5 + + {0x60, 0x00, 0x00}, // disable fast turn-around + {0x65, 0x00, 0xD9}, // AGP timer = 0XD; Host timer = 8; + {0x66, 0x00, 0x88}, //DRAMC Queue Size = 4; park at the last bus owner,Priority promotion timer = 8 + {0x68, 0x00, 0x0C}, + {0x69, 0xF0, 0x04}, // set RX69[3:0]=0000b + {0x6A, 0x00, 0x00}, // refresh counter + {0x6E, 0xF8, 0x80}, //must set 6E[7],or else DDR2 probe test will fail + // In here, we not set RX70~RX74, because we just init DRAM but no need R/W DRAM, + // when we check DQS input/output delay, then we need R/W DRAM. + + //{0x79, 0x00, 0x8F }, + {0x85, 0x00, 0x00}, + // {0x90, 0x87, 0x78 }, + // {0x91, 0x00, 0x46 }, + {0x40, 0x00, 0x00}, + {0, 0, 0} +}; + +void DRAMRegInitValue(DRAM_SYS_ATTR * DramAttr) +{ + u8 Idx, CL; + u8 Data; + + for (Idx = 0; DramRegTbl[Idx][0] != 0; Idx++) { + Data = pci_read_config8(MEMCTRL, DramRegTbl[Idx][0]); + Data &= DramRegTbl[Idx][1]; + Data |= DramRegTbl[Idx][2]; + pci_write_config8(MEMCTRL, DramRegTbl[Idx][0], Data); + } + + Data = 0x80; + pci_write_config8(PCI_DEV(0, 0, 4), 0xa3, Data); + + //set Dram Controllor mode + Data = pci_read_config8(MEMCTRL, 0x6c); + Data &= 0xFB; + if (ENABLE_CHC == 0) { + Data |= 0x4; //only CHA 64 bit mode + pci_write_config8(MEMCTRL, 0x6c, Data); + } else { + Data |= 0x0; //CHA + CHC + pci_write_config8(MEMCTRL, 0x6c, Data); + + //Data = 0xAA; + //pci_write_config8(MEMCTRL, 0xb1, Data); + + //set CHB DQSB input delay, or else will meet error which is some byte is right + //but another bit is error + Data = pci_read_config8(MEMCTRL, 0xff); + Data = (Data & 0x03) | 0x3D; + pci_write_config8(MEMCTRL, 0xff, Data); + + //enable CHC RXDB[7] + //Data=pci_read_config8(MEMCTRL, 0xdb); + // Data = (Data & 0x7F) | 0x80; + //pci_write_config8(MEMCTRL, 0xdb, Data); + + //rx62[2:0],CHA and CHB CL + Data = pci_read_config8(MEMCTRL, 0x62); + CL = Data & 0x07; + + //if CL = 6 , so I set CHB CL = 5 default + if (CL >= 4) + CL = 3; + + // set CHC Read CL rxDC[6:7] + Data = pci_read_config8(MEMCTRL, 0xdc); + Data = (Data & 0x3F) | (CL << 6); + pci_write_config8(MEMCTRL, 0xdc, Data); + // set CHC write CL rxDF[6:7] + Data = pci_read_config8(MEMCTRL, 0xdf); + Data = (Data & 0x3F) | (CL << 6); + pci_write_config8(MEMCTRL, 0xdf, Data); + // set CHC ODT RxDC[5:0] + Data = pci_read_config8(MEMCTRL, 0xdc); + Data = (Data & 0xC0) | 0x03; + pci_write_config8(MEMCTRL, 0xdc, Data); + + //set column type RXDD[6] and enable ODT PAD RXDD[7] + Data = pci_read_config8(MEMCTRL, 0xdd); + Data |= 0x80; + Idx = DramAttr->DimmInfo[2].SPDDataBuf[SPD_SDRAM_COL_ADDR]; + if ((Idx & 0x0F) == 10) + Data |= 0x40; //MA9~MA0 + else + Data &= 0xBF; //MA8~MA0 + pci_write_config8(MEMCTRL, 0xdd, Data); + } + + // Disable read DRAM fast ready ;Rx51[7] + // Disable Read Around Write ;Rx51[6] + + // Disable Consecutive Read ;RX52[1:0] + // disable speculative read + +} + +/*=================================================================== +Function : DRAMInitializeProc() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : DRAM initialize according to the bios porting guid +===================================================================*/ + +#define EXIST_TEST_PATTERN 0x55555555 +#define NOT_EXIST_TEST_PATTERN 0xAAAAAAAA +BOOLEAN ChkForExistLowBank() +{ + u32 *Address, data32; + + // Check Pattern + + Address = (u32 *) 8; + *Address = EXIST_TEST_PATTERN; + Address = (u32 *) 4; + *Address = EXIST_TEST_PATTERN; + +// _asm {WBINVD} + WaitMicroSec(100); + Address = (u32 *) 8; + data32 = *Address; + if (data32 != EXIST_TEST_PATTERN) + return FALSE; + Address = (u32 *) 4; + data32 = *Address; + if (data32 != EXIST_TEST_PATTERN) + return FALSE; + + // Check not Pattern + Address = (u32 *) 8; + *Address = NOT_EXIST_TEST_PATTERN; + Address = (u32 *) 4; + *Address = NOT_EXIST_TEST_PATTERN; + //_asm {WBINVD} + WaitMicroSec(100); + + + Address = (u32 *) 8; + data32 = *Address; + if (data32 != (u32) (NOT_EXIST_TEST_PATTERN)) + return FALSE; + Address = (u32 *) 4; + data32 = *Address; + if (data32 != (u32) (NOT_EXIST_TEST_PATTERN)) + return FALSE; + + return TRUE; +} + +void InitDDR2CHC(DRAM_SYS_ATTR * DramAttr); +void InitDDR2CHB(DRAM_SYS_ATTR * DramAttr); +void DRAMInitializeProc(DRAM_SYS_ATTR * DramAttr) +{ + u8 shift, idx; + BOOLEAN Status; + + shift = 1; + for (idx = 0; idx < MAX_RANKS; idx++) { + if ((DramAttr->RankPresentMap & shift) != 0) { + // Set VR# to physical rank indicated = PR + physical rank enable bit + DRAMSetVRNum(DramAttr, idx, idx, TRUE); + SetEndingAddr(DramAttr, idx, 0x10); // assume 1G size + if (idx < 4) //CHA init + InitDDR2CHA(DramAttr); //temp wjb 2007/1 only for compiling + // in the function InitDDR2,the parameter is no need + Status = ChkForExistLowBank(); + if (Status == TRUE) { + PRINT_DEBUG_MEM(" S\r"); + } else { + PRINT_DEBUG_MEM(" F\r"); + } + // Set VR# to physical rank indicated = 00h + physical rank enable bit + DRAMSetVRNum(DramAttr, idx, 0, FALSE); + SetEndingAddr(DramAttr, idx, -16); + } + shift <<= 1; + } + if (ENABLE_CHC) + InitDDR2CHC(DramAttr); + +} + + +/*=================================================================== +Function : DRAMSetVRNUM() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard + PhyRank: Physical Rank number + VirRank: Virtual Rank number + Enable: Enable/Disable Physical Rank +Output : Void +Purpose : Set virtual rank number for physical rank + Program the specific physical rank with specific virtual rank number + Program when necessary, otherwise don't touch the pr-vr-mapping registers +===================================================================*/ + +void DRAMSetVRNum(DRAM_SYS_ATTR * DramAttr, u8 PhyRank, // Physical Rank + u8 VirRank, // Virtual Rank + BOOLEAN Enable) +{ + u8 Data; + u8 AndData, OrData; + Data = pci_read_config8(MEMCTRL, (0x54 + (PhyRank >> 1))); + + OrData = 0; + if (Enable) + OrData |= 0x08; + OrData |= VirRank; + if ((PhyRank & 0x01) == 0x00) { + AndData = 0x0F; // keep the value of odd rank on PR # is even(keep 1,3,5,7) + OrData <<= 4; // VR #, value to be set + } else { + AndData = 0xF0; // keep the value of even rank on PR # is odd(keep 0,2,4,6) + } + Data &= AndData; + Data |= OrData; + pci_write_config8(MEMCTRL, (0x54 + (PhyRank >> 1)), Data); +} + + +/*=================================================================== +Function : SetEndingAddr() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard + VirRank: Virtual Rank number + Value: (value) add or subtract value to this and after banks +Output : Void +Purpose : Set ending address of virtual rank specified by VirRank +===================================================================*/ + +void SetEndingAddr(DRAM_SYS_ATTR * DramAttr, u8 VirRank, // Ending address register number indicator (INDEX + INT8 Value // (value) add or subtract value to this and after banks + ) { + u8 Data; + + // Read register,Rx40-Rx47(0,1,2,3,4,5,6,7) and set the ending address + Data = pci_read_config8(MEMCTRL, 0x40 + VirRank); + Data = (u8) (Data + Value); + pci_write_config8(MEMCTRL, 0x40 + VirRank, Data); + + //program the virank's begining address to zero + Data = 0x00; + pci_write_config8(MEMCTRL, 0x48 + VirRank, Data); +} + +/*=================================================================== +Function : InitDDR2() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : Initialize DDR2 by standard sequence +===================================================================*/ + +// DLL: Enable Reset +static const u32 CHA_MRS_DLL_150[2] = { 0x00020200, 0x00000800 }; // with 150 ohm (A17=1, A9=1), (A11=1)(cpu address) +static const u32 CHA_MRS_DLL_75[2] = { 0x00020020, 0x00000800 }; // with 75 ohm (A17=1, A5=1), (A11=1)(cpu address) + +// CPU(DRAM) +// { DLL: Enable. A17(BA0)=1 and A3(MA0)=0 } +// { DLL: reset. A11(MA8)=1 } +// +// DDR2 CL=2 CL=3 CL=4 CL=5 CL=6(Burst type=interleave)(WR fine tune in code) +static const u16 CHA_DDR2_MRS_table[5] = { 0x0150, 0x01D0, 0x0250, 0x02D0, 0x350 }; // BL=4 ;Use 1X-bandwidth MA table to init DRAM + +// MA11 MA10(AP) MA9 +#define CHA_MRS_DDR2_TWR2 (0 << 13) + (0 << 20) + (1 << 12) // Value = 001000h +#define CHA_MRS_DDR2_TWR3 (0 << 13) + (1 << 20) + (0 << 12) // Value = 100000h +#define CHA_MRS_DDR2_TWR4 (0 << 13) + (1 << 20) + (1 << 12) // Value = 101000h +#define CHA_MRS_DDR2_TWR5 (1 << 13) + (0 << 20) + (0 << 12) // Value = 002000h +#define CHA_MRS_DDR2_TWR6 (1 << 13) + (0 << 20) + (1 << 12) // Value = 003000h + +// DDR2 Twr=2 Twr=3 Twr=4 Twr=5 +static const u32 CHA_DDR2_Twr_table[5] = + { CHA_MRS_DDR2_TWR2, CHA_MRS_DDR2_TWR3, CHA_MRS_DDR2_TWR4, +CHA_MRS_DDR2_TWR5, CHA_MRS_DDR2_TWR6 }; + +#define CHA_OCD_Exit_150ohm 0x20200 // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=1,MA2=0 (DRAM bus address) +// A17=1, A12=A11=A10=0,A9=1 ,A5=0 (CPU address) +#define CHA_OCD_Default_150ohm 0x21E00 // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=1,MA2=0 (DRAM bus address) +// A17=1, A12=A11=A10=1,A9=1 ,A5=0 (CPU address) +#define CHA_OCD_Exit_75ohm 0x20020 // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=0,MA2=1 (DRAM bus address) +// A17=1, A12=A11=A10=0,A9=0 ,A5=1 (CPU address) +#define CHA_OCD_Default_75ohm 0x21C20 // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=0,MA2=1 (DRAM bus address) +// A17=1, A12=A11=A10=1,A9=0 ,A5=1 (CPU address) + +void InitDDR2CHA(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 Reg6BVal; + u8 Idx, CL, BL, Twr; + u32 AccessAddr; + u8 DimmNum; + + // step2. + //disable bank paging and multi page + Data = pci_read_config8(MEMCTRL, 0x69); + Data &= ~0x03; + pci_write_config8(MEMCTRL, 0x69, Data); + + Reg6BVal = pci_read_config8(MEMCTRL, 0x6b); + Reg6BVal &= ~0x07; + // Step 3. + // At least one NOP cycle will be issued after the 1m sec device deselect. + Data = Reg6BVal | 0x01; + pci_write_config8(MEMCTRL, 0x6b, Data); + + // step4. + //Read a double word from any address of the DIMM + DimmRead(0x0); + + // Step 5. + // A minimum pause of 200u sec will be provided after the NOP. + // - <<< reduce BOOT UP time >>> - + // Loop 200us + for (Idx = 0; Idx < 0x10; Idx++) + WaitMicroSec(100); + + // Step 6. + // Precharge all (PALL) will be issued to the DDR. + Data = Reg6BVal | 0x02; + pci_write_config8(MEMCTRL, 0x6b, Data); + + // Step7. + //Read a double word from any address of the DIMM + DimmRead(0x0); + + // Step 8. + // MSR Eable will be issued to the DDR + Data = Reg6BVal | 0x03; + pci_write_config8(MEMCTRL, 0x6b, Data); + + + // Step 9,10. check ODT value for EMRS(1) command + // according to ODTLookUp_TBL in driving_setting.c if there is one dimm in MB's one channel , the DDR2's ODT is 150ohm + // if there is two dimm in MB's one channel, the DDR2's ODT is 75 ohm + DimmNum = DramAttr->DimmNumChA; + + if (DimmNum == 1) //DDR's ODT is 150ohm + { + AccessAddr = (u32) CHA_MRS_DLL_150[0]; + DimmRead(AccessAddr); //issue EMRS DLL Enable + PRINT_DEBUG_MEM("Step 9 Address "); + PRINT_DEBUG_MEM_HEX32(AccessAddr); + PRINT_DEBUG_MEM("\r"); + + AccessAddr = (u32) CHA_MRS_DLL_150[1]; + DimmRead(AccessAddr); //issue MRS DLL Reset + PRINT_DEBUG_MEM("Step 10 Address "); + PRINT_DEBUG_MEM_HEX32(AccessAddr); + PRINT_DEBUG_MEM("\r"); + } else if (DimmNum == 2) //DDR's ODT is 75ohm + { + AccessAddr = (u32) CHA_MRS_DLL_75[0]; + DimmRead(AccessAddr); //issue EMRS DLL Enable + AccessAddr = (u32) CHA_MRS_DLL_75[1]; + DimmRead(AccessAddr); //issue MRS DLL Reset + } else { + PRINT_DEBUG_MEM("Dimm NUM ERROR:"); + PRINT_DEBUG_MEM_HEX8(DimmNum); + PRINT_DEBUG_MEM("\r"); + } + + // Step 11. + // Precharge all (PALL) will be issued to the DDR. + Data = Reg6BVal | 0x02; + pci_write_config8(MEMCTRL, 0x6b, Data); + + // Step12. + //Read a double word from any address of the DIMM + DimmRead(0x0); + + // Step 13. + // Execute 8 CBR refresh + Data = Reg6BVal | 0x04; + pci_write_config8(MEMCTRL, 0x6b, Data); + + // issue 14,15 , 16 + //reads and wait 100us between each read + for (Idx = 0; Idx < 8; Idx++) { + DimmRead(0x0); + WaitMicroSec(100); + } + + // Step 17. + // enable MRS for MAA + Data = Reg6BVal | 0x03; + pci_write_config8(MEMCTRL, 0x6b, Data); + + //Step 18 + //the SDRAM parameters.(Burst Length, CAS# Latency , Write recovery etc.) + //------------------------------------------------------------- + //Burst Length : really offset Rx6c[3] + Data = pci_read_config8(MEMCTRL, 0x6c); + BL = (Data & 0x08) >> 3; + + // CL = really offset RX62[2:0] + Data = pci_read_config8(MEMCTRL, 0x62); + CL = Data & 0x03; + + AccessAddr = (u32) (CHA_DDR2_MRS_table[CL]); + if (BL) { + AccessAddr += 8; + } + //Write recovery : really offset Rx63[7-5] + Data = pci_read_config8(MEMCTRL, 0x63); + Twr = (Data & 0xE0) >> 5; + + AccessAddr += CHA_DDR2_Twr_table[Twr]; + // AccessAddr = 0x1012D8; + DimmRead(AccessAddr); // Set MRS command + PRINT_DEBUG_MEM("Step 18 Address"); + PRINT_DEBUG_MEM_HEX32(AccessAddr); + PRINT_DEBUG_MEM("\r"); + + //Step 19,20 + if (DimmNum == 1) //DDR's ODT is 150ohm + { + AccessAddr = (u32) CHA_OCD_Default_150ohm; + DimmRead(AccessAddr); //issue EMRS OCD Default + PRINT_DEBUG_MEM("Step 19 Address "); + PRINT_DEBUG_MEM_HEX32(AccessAddr); + PRINT_DEBUG_MEM("\r"); + + AccessAddr = (u32) CHA_OCD_Exit_150ohm; + DimmRead(AccessAddr); //issue EMRS OCD Calibration Mode Exit + PRINT_DEBUG_MEM("Step 20 Address "); + PRINT_DEBUG_MEM_HEX32(AccessAddr); + PRINT_DEBUG_MEM("\r"); + } else if (DimmNum == 2) //DDR's ODT is 75ohm + { + AccessAddr = (u32) CHA_OCD_Default_75ohm; + DimmRead(AccessAddr); //issue EMRS OCD Default + AccessAddr = (u32) CHA_OCD_Exit_75ohm; + DimmRead(AccessAddr); //issue EMRS OCD Calibration Mode Exit + } else { + PRINT_DEBUG_MEM("Dimm NUM ERROR: "); + PRINT_DEBUG_MEM_HEX8(DimmNum); + PRINT_DEBUG_MEM("\r"); + } + + //Step 21 + //After MRS the device should be ready for full functionality within 3 clocks + // after Tmrd is met. + Data = Reg6BVal; + pci_write_config8(MEMCTRL, 0x6b, Data); + + // Enable bank paging and multi page + Data = pci_read_config8(MEMCTRL, 0x69); + Data |= 0x03; + pci_write_config8(MEMCTRL, 0x69, Data); +} + +/*=================================================================== +Function : InitDDR2_CHB() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : Initialize DDR2 of CHB by standard sequence +Reference : +===================================================================*/ +/*// DLL: Enable Reset +static const u32 CHB_MRS_DLL_150[2] = { 0x00020200 | (1 << 20), 0x00000800 }; // with 150 ohm (A17=1, A9=1), (A11=1)(cpu address) +//u32 CHB_MRS_DLL_75[2] = { 0x00020020 | (1 << 20), 0x00000800 }; // with 75 ohm (A17=1, A5=1), (A11=1)(cpu address) +// CPU(DRAM) +// { DLL: Enable. A17(BA0)=1 and A3(MA0)=0 } +// { DLL: reset. A11(MA8)=1 } +// +// DDR2 CL=2 CL=3 CL=4 CL=5 (Burst type=interleave)(WR fine tune in code) +static const u16 CHB_DDR2_MRS_table[4] ={ 0x0150, 0x01D0, 0x0250, 0x02D0 }; // BL=4 ;Use 1X-bandwidth MA table to init DRAM + +// MA11 MA10(AP) MA9 +#define CHB_MRS_DDR2_TWR2 (0 << 13) + (0 << 20) + (1 << 12) // Value = 001000h +#define CHB_MRS_DDR2_TWR3 (0 << 13) + (1 << 20) + (0 << 12) // Value = 100000h +#define CHB_MRS_DDR2_TWR4 (0 << 13) + (1 << 20) + (1 << 12) // Value = 101000h +#define CHB_MRS_DDR2_TWR5 (1 << 13) + (0 << 20) + (0 << 12) // Value = 002000h +#define CHB_MRS_DDR2_TWR6 (1 << 13) + (0 << 20) + (1 << 12) // Value = 003000h + +// DDR2 Twr=2 Twr=3 Twr=4 Twr=5 +static const u32 CHB_DDR2_Twr_table[5] = { CHB_MRS_DDR2_TWR2, CHB_MRS_DDR2_TWR3, CHB_MRS_DDR2_TWR4, CHB_MRS_DDR2_TWR5, CHB_MRS_DDR2_TWR6 }; + +#define CHB_OCD_Exit_150ohm 0x20200 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=1,MA2=0 (DRAM bus address) +// A17=1, A12=A11=A10=0,A9=1 ,A5=0 (CPU address) +#define CHB_OCD_Default_150ohm 0x21E00 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=1,MA2=0 (DRAM bus address) +// A17=1, A12=A11=A10=1,A9=1 ,A5=0 (CPU address) +//#define CHB_OCD_Exit_75ohm 0x20020 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=0,MA6=0,MA2=1 (DRAM bus address) +// A17=1, A12=A11=A10=0,A9=0 ,A5=1 (CPU address) +//#define CHB_OCD_Default_75ohm 0x21C20 | (1 << 20) // EMRS(1), BA0=1, MA9=MA8=MA7=1,MA6=0,MA2=1 (DRAM bus address) +// A17=1, A12=A11=A10=1,A9=0 ,A5=1 (CPU address) +void InitDDR2CHB( + DRAM_SYS_ATTR *DramAttr + ) + +{ + u8 Data; + u8 Idx, CL, BL, Twr; + u32 AccessAddr; + + Data = 0x80; + pci_write_config8(MEMCTRL, 0x54, Data); + + // step3. + //disable bank paging and multi page + Data=pci_read_config8(MEMCTRL, 0x69); + Data &= ~0x03; + pci_write_config8(MEMCTRL, 0x69, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step 4. Initialize CHB begin + Data=pci_read_config8(MEMCTRL, 0xd3); + Data |= 0x40; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //Step 5. NOP command enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x08; + pci_write_config8(MEMCTRL, 0xd7, Data); + + //Step 6. issue a nop cycle,RegD3[7] 0 -> 1 + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + + // Step 7. + // A minimum pause of 200u sec will be provided after the NOP. + // - <<< reduce BOOT UP time >>> - + // Loop 200us + for (Idx = 0; Idx < 0x10; Idx++) + WaitMicroSec(10); + + // Step 8. + // all banks precharge command enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x10; + pci_write_config8(MEMCTRL, 0xd7, Data); + + //step 9. issue a precharge all cycle,RegD3[7] 0 -> 1 + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step10. EMRS enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x18; + pci_write_config8(MEMCTRL, 0xd7, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xC7; + Data |= 0x08; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step11. EMRS DLL Enable and Disable DQS + AccessAddr = CHB_MRS_DLL_150[0] >> 3; + Data =(u8) (AccessAddr & 0xff); + pci_write_config8(MEMCTRL, 0xd9, Data); + + Data = (u8)((AccessAddr & 0xff00) >> 8); + pci_write_config8(MEMCTRL, 0xda, Data); + + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xF9; + Data |= (u8)((AccessAddr & 0x30000) >> 15); + pci_write_config8(MEMCTRL, 0xd7, Data); + + //step12. issue EMRS cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step13. MSR enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x18; + pci_write_config8(MEMCTRL, 0xd7, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xC7; + Data |= 0x00; + pci_write_config8(MEMCTRL, 0xd3, Data); + + + //step 14. MSR DLL Reset + AccessAddr = CHB_MRS_DLL_150[1] >> 3; + Data =(u8) (AccessAddr & 0xff); + pci_write_config8(MEMCTRL, 0xd9, Data); + + Data = (u8)((AccessAddr & 0xff00) >> 8); + pci_write_config8(MEMCTRL, 0xda, Data); + + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xF9; + Data |= (u8)((AccessAddr & 0x30000) >> 15); + pci_write_config8(MEMCTRL, 0xd7, Data); + + //step15. issue MRS cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //clear the address + Data = 0x00; + pci_write_config8(MEMCTRL, 0xda, Data); + + //step16. all banks precharge command enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x10; + pci_write_config8(MEMCTRL, 0xd7, Data); + + + // step17. issue precharge all cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step18. CBR cycle enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x20; + pci_write_config8(MEMCTRL, 0xd7, Data); + + //step 19.20.21 + //repeat issue 8 CBR cycle, between each cycle stop 100us + for (Idx = 0; Idx < 8; Idx++) + { + // issue CBR cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + WaitMicroSec(200); + } + + //step22. MSR enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x18; + pci_write_config8(MEMCTRL, 0xd7, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xC7; + Data |= 0x00; + pci_write_config8(MEMCTRL, 0xd3, Data); + + + + //the SDRAM parameters.(Burst Length, CAS# Latency , Write recovery etc.) + //------------------------------------------------------------- + //Burst Length : really offset Rx6c[1] + Data=pci_read_config8(MEMCTRL, 0x6C); + BL = (Data & 0x02) >> 1; + + // CL = really offset RX62[2:0] + Data=pci_read_config8(MEMCTRL, 0x62); + CL = Data & 0x03; + + + AccessAddr = (u32)(CHB_DDR2_MRS_table[CL]); + if (BL) + { + AccessAddr += 8; + } + + //Write recovery : really offset Rx63[7:5] + Data=pci_read_config8(MEMCTRL, 0x63); + Twr = (Data & 0xE0) >> 5; + + AccessAddr += CHB_DDR2_Twr_table[Twr]; + //MSR Address use addr[20:3] + AccessAddr >>= 3; + + //step 23. MSR command + Data = (u8)(AccessAddr & 0xFF); + pci_write_config8(MEMCTRL, 0xD9, Data); + + Data = (u8)((AccessAddr & 0xFF00) >> 8); + pci_write_config8(MEMCTRL, 0xda, Data); + + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xF9; + Data |= (u8)(((AccessAddr & 0x30000)>>16) << 1); + pci_write_config8(MEMCTRL, 0xd7, Data); + + //step 24. issue MRS cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step 25. EMRS enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x18; + pci_write_config8(MEMCTRL, 0xd7, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xC7; + Data |= 0x08; + pci_write_config8(MEMCTRL, 0xd3, Data); + + + //step 26. OCD default + AccessAddr = (CHB_OCD_Default_150ohm) >> 3; + Data =(u8) (AccessAddr & 0xff); + pci_write_config8(MEMCTRL, 0xd9, Data); + + Data = (u8)((AccessAddr & 0xff00) >> 8); + pci_write_config8(MEMCTRL, 0xda, Data); + + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xF9; + Data |= (u8)((AccessAddr & 0x30000) >> 15); + pci_write_config8(MEMCTRL, 0xd7, Data); + + + //step 27. issue EMRS cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step 25. EMRS enable + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x18; + pci_write_config8(MEMCTRL, 0xd7, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xC7; + Data |= 0x08; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step 28. OCD Exit + AccessAddr = (CHB_OCD_Exit_150ohm) >> 3; + Data =(u8) (AccessAddr & 0xff); + pci_write_config8(MEMCTRL, 0xd9, Data); + + Data = (u8)((AccessAddr & 0xff00) >> 8); + pci_write_config8(MEMCTRL, 0xda, Data); + + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xF9; + Data |= (u8)((AccessAddr & 0x30000) >> 15); + pci_write_config8(MEMCTRL, 0xd7, Data); + + //step 29. issue EMRS cycle + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0x7F; + pci_write_config8(MEMCTRL, 0xd3, Data); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //clear all the address + Data = 0x00; + pci_write_config8(MEMCTRL, 0xd9, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xda, Data); + + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xF9; + pci_write_config8(MEMCTRL, 0xd7, Data); + + + //step 30. normal SDRAM Mode + Data=pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xC7; + Data |= 0x00; + pci_write_config8(MEMCTRL, 0xd7, Data); + + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xC7; + Data |= 0x00; + pci_write_config8(MEMCTRL, 0xd3, Data); + + //step 31. exit the initialization mode + Data=pci_read_config8(MEMCTRL, 0xd3); + Data &= 0xBF; + pci_write_config8(MEMCTRL, 0xd3, Data); + + + //step 32. Enable bank paging and multi page + Data=pci_read_config8(MEMCTRL, 0x69); + Data |= 0x03; + pci_write_config8(MEMCTRL, 0x69, Data); +} +*/ +/*=================================================================== +Function : InitDDR2CHC() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : Initialize DDR2 of CHC by standard sequence +Reference : +===================================================================*/ +// DDR2 CL=2 CL=3 CL=4 CL=5 (Burst type=interleave)(WR fine tune in code) +static const u16 CHC_MRS_table[4] = { 0x22B, 0x23B, 0x24B, 0x25B }; // Use 1X-bandwidth MA table to init DRAM + +void InitDDR2CHC(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 Idx, CL, Twr; + u32 AccessAddr; + CB_STATUS Status; + + // step3. + //clear RxDF[2] to disable Tri-state output + Data = pci_read_config8(MEMCTRL, 0xdf); + Data &= 0xFB; + pci_write_config8(MEMCTRL, 0xdf, Data); + + + + //step 4. Enable the initialization mode of DRAM Controller C with NB's PLL clock + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x60; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //Step 5. NOP command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x00; + pci_write_config8(MEMCTRL, 0xdb, Data); + + + //Step 6. issue a nop cycle,RegDB[1] 0 -> 1 + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + + // Step 7. + // A minimum pause of 200u sec will be provided after the NOP. + // - <<< reduce BOOT UP time >>> - + // Loop 200us + for (Idx = 0; Idx < 0x10; Idx++) + WaitMicroSec(100); + + // Step 8. + // signal bank precharge command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x14; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //set MA10 =1, precharge all bank + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + + Data = 0x04; + pci_write_config8(MEMCTRL, 0xf9, Data); + + //step 9. issue a precharge all cycle,RegD3[7] 0 -> 1 + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step10. MRS enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x1C; + pci_write_config8(MEMCTRL, 0xdb, Data); + + + //step11. EMRS DLL enable and Disable DQS + Data = 0x40; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x24; + pci_write_config8(MEMCTRL, 0xf9, Data); + + //step12. issue EMRS cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step13. MSR enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x1C; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step 14. MSR DLL Reset + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x01; + pci_write_config8(MEMCTRL, 0xf9, Data); + + //step15. issue MRS cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step16. signal banks precharge command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x14; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //set MA10 =1, precharge all bank + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x04; + pci_write_config8(MEMCTRL, 0xf9, Data); + + // step17. issue precharge all cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step18. CBR cycle enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x18; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf9, Data); + + //step 19.20.21 + //repeat issue 8 CBR cycle, between each cycle stop 100us + for (Idx = 0; Idx < 8; Idx++) { + // issue CBR cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + WaitMicroSec(100); + } + + //the SDRAM parameters.(, CAS# Latency , Write recovery etc.) + //------------------------------------------------------------ + + // CL = really offset RXDC[7:6] + Data = pci_read_config8(MEMCTRL, 0xdc); + CL = (Data & 0xC0) >> 6; + + AccessAddr = (u32) (CHC_MRS_table[CL]); + + //Write recovery : really offset Rx63[7:5] + Data = pci_read_config8(MEMCTRL, 0x63); + Twr = (Data & 0xE0) >> 5; + + AccessAddr += Twr * 0x200; + + //step22. MSR enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x1C; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step 23. MSR command + Data = (u8) (AccessAddr & 0xFF); + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = (u8) ((AccessAddr & 0xFF00) >> 8); + pci_write_config8(MEMCTRL, 0xf9, Data); + + //step 24. issue MRS cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step 25. EMRS enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x1C; + pci_write_config8(MEMCTRL, 0xdb, Data); + + + //step 26. OCD default + Data = 0xC0; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x27; + pci_write_config8(MEMCTRL, 0xf9, Data); + + //step 27. issue EMRS cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //step 28. OCD Exit + Data = 0x40; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x24; + pci_write_config8(MEMCTRL, 0xf9, Data); + + + //step 29. issue EMRS cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Status = VerifyChc(); + if (Status != CB_SUCCESS) + PRINT_DEBUG_MEM("Error!!!!CHC init error!\r"); + //step 31. exit the initialization mode + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0x9F; + pci_write_config8(MEMCTRL, 0xdb, Data); +} + +CB_STATUS VerifyChc() +{ + u8 Data, ByteVal, Index, pad; + u16 row; + + //first write the pad to all the address + + //the row bits is 13 and rank bit is 2, so the address bits is 15 and the value is 0x7fff + //verify each MA[0:12],BA[0:1] + pad = 1; + for (row = 0; row < 0x8000; row++) { + //set the write value; + //verify each MD[15:0] + for (Data = pad, Index = 0; Index < 16; Index++) { + Data <<= 1; + if (Data == 0) + Data = 1; + pci_write_config8(PCI_DEV(0, 0, 7), 0xC0 + Index, + Data); + + } + + //issue the bank active command + // bank active command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x10; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = (u8) (row && 0xFF); + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = (u8) ((row && 0xFF) >> 8); + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue active cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //issue ready/completion for read/write + // read/completion command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x04; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue read/completion cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //issue write command + // write command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x0C; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = (u8) ((row & 0x60) << 5); + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue write cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + ////issue ready/completion for read/write + // read/completion command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x04; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue read/completion cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //issue the bank active command + // bank active command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x10; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = (u8) (row && 0xFF); + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = (u8) ((row && 0xFF) >> 8); + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue active cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + ////issue ready/completion for read/write + // read/completion command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x04; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue read/completion cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + ////issue read command + // read/completion command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x08; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = (u8) ((row & 0x60) << 5); + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue read cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + ////issue ready/completion for read/write + // read/completion command enable + Data = pci_read_config8(MEMCTRL, 0xdb); + Data &= 0xE3; + Data |= 0x04; + pci_write_config8(MEMCTRL, 0xdb, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf8, Data); + + Data = 0x00; + pci_write_config8(MEMCTRL, 0xf9, Data); + + // issue read/completion cycle + Data = pci_read_config8(MEMCTRL, 0xdb); + Data |= 0x2; + pci_write_config8(MEMCTRL, 0xdb, Data); + Data &= 0xFD; + pci_write_config8(MEMCTRL, 0xdb, Data); + + //verify the value; + for (ByteVal = pad, Index = 0; Index < 16; Index++) { + Data = + pci_read_config8(PCI_DEV(0, 0, 7), + 0xD0 + Index); + if (ByteVal != Data) { + PRINT_DEBUG_MEM + ("error!!!! row = %x,Index =%x,Data = %x,ByteVal=%x\r"); + } + ByteVal <<= 1; + if (ByteVal == 0) + ByteVal = 1; + } + pad <<= 1; + if (pad == 0) + pad = 1; + } + + return CB_SUCCESS; +} diff --git a/src/northbridge/via/vx800/dqs_search.c b/src/northbridge/via/vx800/dqs_search.c new file mode 100644 index 0000000000..80749f8597 --- /dev/null +++ b/src/northbridge/via/vx800/dqs_search.c @@ -0,0 +1,98 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +void SetDQSOutputCHA(DRAM_SYS_ATTR * DramAttr); +void SetDQSOutputCHB(DRAM_SYS_ATTR * DramAttr); + +/*=================================================================== +Function : DRAMDQSOutputSearchCHA() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : set DQS output delay register reg70 and DQ output delay register reg71 +===================================================================*/ + +#define CH_A 0 +#define CH_B 1 +void DRAMDQSOutputSearch(DRAM_SYS_ATTR * DramAttr) +{ + if (DramAttr->RankNumChA > 0) + SetDQSOutputCHA(DramAttr); +} + +/*=================================================================== +Function : SetDQSOutputCHA() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : according the frequence set CHA DQS output +===================================================================*/ +void SetDQSOutputCHA(DRAM_SYS_ATTR * DramAttr) +{ + u8 Reg70, Reg71; + u8 Index; + + if (DramAttr->DramFreq == DIMMFREQ_400) + Index = 3; + else if (DramAttr->DramFreq == DIMMFREQ_533) + Index = 2; + else if (DramAttr->DramFreq == DIMMFREQ_667) + Index = 1; + else if (DramAttr->DramFreq == DIMMFREQ_800) + Index = 0; + else + Index = 3; + + if (DramAttr->RankNumChA > 2) { + Reg70 = Fixed_DQSA_3_4_Rank_Table[Index][0]; + Reg71 = Fixed_DQSA_3_4_Rank_Table[Index][1]; + } else { + Reg70 = Fixed_DQSA_1_2_Rank_Table[Index][0]; + Reg71 = Fixed_DQSA_1_2_Rank_Table[Index][1]; + } + pci_write_config8(MEMCTRL, 0x70, Reg70); + pci_write_config8(MEMCTRL, 0x71, Reg71); +} + + +//################ +// STEP 12 # +//################ + +/*=================================================================== +Function : DRAMDQSInputSearch() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : search DQS input delay for CHA/CHB +===================================================================*/ + +void DRAMDQSInputSearch(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + //auto mode + Data = 0x0; + pci_write_config8(MEMCTRL, 0x77, Data); +} diff --git a/src/northbridge/via/vx800/dram_init.c b/src/northbridge/via/vx800/dram_init.c new file mode 100644 index 0000000000..ad4d721cbd --- /dev/null +++ b/src/northbridge/via/vx800/dram_init.c @@ -0,0 +1,86 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; either version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +#include "lib/memset.c" +CB_STATUS DDR2_DRAM_INIT() +{ + CB_STATUS Status; + u8 i; + u32 RamSize; + BOOLEAN bTest; + DRAM_SYS_ATTR DramAttr; + + PRINT_DEBUG_MEM("DRAM_INIT \r"); + + memset(&DramAttr, 0, sizeof(DRAM_SYS_ATTR)); + /*Step1 DRAM Detection; DDR1 or DDR2; Get SPD Data; Rank Presence;64 or 128bit; Unbuffered or registered; 1T or 2T */ + DRAMDetect(&DramAttr); + + //Step2 set Frequency; calculate CL and Frequncy from SPD data; set the Frequency + DRAMFreqSetting(&DramAttr); + //Step3 Set DRAM Timing; CL, tRP, tRCD, tRAS, tRFC, tRRD, tWR, tWTR, tRTP + DRAMTimingSetting(&DramAttr); + //Step4 DRDY + DRAMDRDYSetting(&DramAttr); + //Step5 Burst length + DRAMBurstLength(&DramAttr); + //Step6 DRAM Driving Adjustment + DRAMDriving(&DramAttr); + //Step7 duty cycle control + DutyCycleCtrl(&DramAttr); + //Step8 DRAM clock phase and delay control + DRAMClkCtrl(&DramAttr); + //Step9 set register before init DRAM device + DRAMRegInitValue(&DramAttr); + //Step10 DDR and DDR2 initialize process + DRAMInitializeProc(&DramAttr); + + //Step13 Interleave function in rankmap.c + DRAMBankInterleave(&DramAttr); + //Step14 Sizing + DRAMSizingMATypeM(&DramAttr); + + //Step11 Search DQS and DQ output delay + DRAMDQSOutputSearch(&DramAttr); + //Step12 Search DQS input delay + DRAMDQSInputSearch(&DramAttr); + + //Step15 DDR fresh counter setting + DRAMRefreshCounter(&DramAttr); + //Step16 Final register setting for improve performance + DRAMRegFinalValue(&DramAttr); + + RamSize = 0; + for (i = 0; i < MAX_RANKS; i++) { + if (DramAttr.RankSize[i] == 0) { + continue; + } + RamSize += DramAttr.RankSize[i]; + } + PRINT_DEBUG_MEM("RamSize="); + PRINT_DEBUG_MEM_HEX32(RamSize); + PRINT_DEBUG_MEM("\r"); + DumpRegisters(0, 3); + //bTest = DramBaseTest( M1, RamSize - M1 * 2,SPARE, FALSE); + /* the memory can not correct work, this is because the user set the incorrect memory + parameter from setup interface.so we must set the boot mode to recovery mode, let + the system to reset and use the spd value to initialize the memory */ + SetUMARam(); + return CB_SUCCESS; +} diff --git a/src/northbridge/via/vx800/dram_init.h b/src/northbridge/via/vx800/dram_init.h new file mode 100644 index 0000000000..e7f5e72d50 --- /dev/null +++ b/src/northbridge/via/vx800/dram_init.h @@ -0,0 +1,263 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; either version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +#ifndef __DRAMINIT_H_ +#define __DRAMINIT_H_ + +//Dram Size +#define M (1024*1024) +#define M1 (1*M) +#define M64 (64*M) +#define M128 (128*M) +#define M256 (256*M) +#define M384 (384*M) +#define M512 (512*M) + +// UMA size +#define UMASIZE M64 + +#define ENABLE_CHC 0 //CHC enable, how ever, this CHC,used some reg define in CHB +#define ENABLE_CHB 0 //CHB enable , CHB is VX800's, VX855 no this CHB. +//Dram Freq +#define DIMMFREQ_800 400 +#define DIMMFREQ_667 333 +//#define DIMMFREQ_600 300 +#define DIMMFREQ_533 266 +#define DIMMFREQ_400 200 +#define DIMMFREQ_333 166 +#define DIMMFREQ_266 133 +#define DIMMFREQ_200 100 + +//Dram Type +#define RAMTYPE_FPMDRAM 1 +#define RAMTYPE_EDO 2 +#define RAMTYPE_PipelinedNibble 3 +#define RAMTYPE_SDRAM 4 +#define RAMTYPE_ROM 5 +#define RAMTYPE_SGRAMDDR 6 +#define RAMTYPE_SDRAMDDR 7 +#define RAMTYPE_SDRAMDDR2 8 + +/* CAS latency constant */ +#define CASLAN_15 15 +#define CASLAN_2 20 +#define CASLAN_25 25 +#define CASLAN_3 30 +#define CASLAN_35 35 +#define CASLAN_4 40 +#define CASLAN_45 45 +#define CASLAN_5 50 +#define CASLAN_NULL 00 + +//Burst length +#define BURSTLENGTH8 8 +#define BURSTLENGTH4 4 + +//Data Width +//#define DATAWIDTHX16 16 +//#define DATAWIDTHX8 8 +//#define DATAWIDTHX4 4 + + +#define SPD_MEMORY_TYPE 2 /*Memory type FPM,EDO,SDRAM,DDR,DDR2 */ +#define SPD_SDRAM_ROW_ADDR 3 /*Number of row addresses on this assembly */ +#define SPD_SDRAM_COL_ADDR 4 /*Number of column addresses on this assembly */ +#define SPD_SDRAM_DIMM_RANKS 5 /*Number of RANKS on this assembly */ +#define SPD_SDRAM_MOD_DATA_WIDTH 6 /*Data width of this assembly */ +#define SPD_SDRAM_TCLK_X 9 /*Cycle time at Maximum supported CAS latency (CL=X) */ +#define SPD_SDRAM_TAC_X 10 /*Access time for highest CL */ +#define SPD_SDRAM_CONFIG_TYPE 11 /*Non-parity , Parity or ECC */ +#define SPD_SDRAM_REFRESH 12 /*Refresh rate/type */ +#define SPD_SDRAM_WIDTH 13 /*Primary sdram width */ +#define SPD_SDRAM_MIN_CLK_DLY 15 /*Minimum clock delay */ +#define SPD_SDRAM_BURSTLENGTH 16 /*Burst Lengths supported */ +#define SPD_SDRAM_NO_OF_BANKS 17 /*Number of banks on this assembly */ +#define SPD_SDRAM_CAS_LATENCY 18 /*CAS latency */ +#define SPD_SDRAM_DIMM_TYPE_DDR2 20 /*DIMM type information; identifies the DDR2 memory module type */ +#define SPD_SDRAM_DEV_ATTR_DDR1 20 /*WE latency */ +#define SPD_SDRAM_MODULES_ATTR 21 /*This byte depicts various aspects of the modules; DDR DDR2 have different aspects */ +#define SPD_SDRAM_DEV_ATTR_GEN 22 /*General device attributes */ +#define SPD_SDRAM_TCLK_X_1 23 /*Minimum clock cycle time at Reduced CL, DDR: X-0.5 DDR2: X-1 */ +#define SPD_SDRAM_TAC_X_1 24 /*Maximum Data Access time from Clock at reduced CL,DDR: X-0.5 DDR2: X-1 */ +#define SPD_SDRAM_TCLK_X_2 25 /*Minimum clock cycle time at reduced CL, DDR: X-1 DDR2: X-2 */ +#define SPD_SDRAM_TAC_X_2 26 /*Maximum Data Access time from Clock at reduced CL, DDR: X-1 DDR2: X-2 */ +#define SPD_SDRAM_TRP 27 /*minimum row precharge time */ +#define SPD_SDRAM_TRRD 28 /*minimum row active to row active delay */ +#define SPD_SDRAM_TRCD 29 /*minimum RAS to CAS delay */ +#define SPD_SDRAM_TRAS 30 /*minimum active to precharge time */ +#define SPD_SDRAM_TWR 36 /*write recovery time, only DDR2 use it */ +#define SPD_SDRAM_TWTR 37 /*internal write to read command delay, only DDR2 use it */ +#define SPD_SDRAM_TRTP 38 /*internal read to prechange command delay, only DDR2 use it */ +#define SPD_SDRAM_TRFC2 40 /*extension of byte 41 tRC and byte 42 tRFC, only DDR2 use it */ +#define SPC_SDRAM_TRC 41 /*minimum active to active/refresh time */ +#define SPD_SDRAM_TRFC 42 /*minimum refresh to active / refresh command period */ + +#define SPD_DATA_SIZE 44 +//Dram cofig are +/*the most number of socket*/ +//#define MAX_RAM_SLOTS 2 +#define MAX_SOCKETS MAX_RAM_SLOTS +#define MAX_DIMMS MAX_SOCKETS /*every sockets can plug one DIMM */ +/*the most number of RANKs on a DIMM*/ +#define MAX_RANKS MAX_SOCKETS*2 + +struct mem_controller { + u8 channel0[MAX_DIMMS]; +}; + +static const struct mem_controller ctrl = { + .channel0 = {0x50, 0x51}, +}; + +typedef struct _DRAM_CONFIG_DATA { + u8 DramClk; + u8 DramTiming; + u8 CasLatency; + u8 BankIntlv; + u8 Trp; + u8 Tras; + u8 Trcd; + u8 Trfc; + u8 Trrd; + u8 Trtp; + u8 Twtr; + u8 Twr; + + u8 CmdRate; + u8 DualEn; + //u8 IntLv0; + //u8 IntLv1; + //u8 Ba0Sel; + //u8 Ba1Sel; + //u8 Ba2Sel; + u8 BaScmb; + u8 DrdyTiming; + //u8 Above4G; + //u8 RdsaitMode; + //u8 Rdsait; + //u8 TopPerf; + + u16 UMASize; +} DRAM_CONFIG_DATA; + +/*DIMM(assembly) information*/ +typedef struct _DIMM_INFO_tag { + u8 bPresence; + u8 SPDDataBuf[SPD_DATA_SIZE]; /*get all information from spd data */ +} DIMM_INFO; + +typedef struct _DRAM_SYS_ATTR_tag { + DIMM_INFO DimmInfo[MAX_DIMMS]; + + u8 RankPresentMap; /*bit0,1 Rank0,1 on DIMM0, bit2,3 Rank2,3 on DIMM1, + bit4,5 Rank4,5 on DIMM2, bit6,7 Rank6,7 on DIMM3 */ + u8 DimmNumChA; /*Dimm number */ + u8 DimmNumChB; + u8 RankNumChA; /*the number of Ranks on the mortherbaord */ + u8 RankNumChB; + u8 LoadNumChA; /*the number of chips on all DIMM */ + u8 LoadNumChB; + + u8 DramType; /*DDR1 or DDR2 */ + u16 DramFreq; + u16 DramCyc; /*10ns, 7.5ns, 6ns, 5ns, 3.75ns, 3ns, 2.5ns =1/SysFreq, unit: 100*ns. */ + + //u16 HFreq; /*100, 133, 166, 200, 266, 333, 400*/ + + u8 CL; /* CAS lantency */ + u8 CmdRate; /*1T or 2T */ + + u32 RankSize[MAX_RANKS]; + u8 Dual_Channel; + DRAM_CONFIG_DATA ConfigData; + u8 reserved[4]; + +} DRAM_SYS_ATTR; + +typedef struct _DRAM_SIZE_INFO { + u32 RankLength[MAX_RANKS]; +} DRAM_SIZE_INFO; + +//detection.c +/*Step1 detect DRAM type, Read SPD data,command rate*/ +CB_STATUS DRAMDetect(DRAM_SYS_ATTR * DramAttr); +//freq_setting.c +/*Step2 set Frequency, calculate CAL*/ +void DRAMFreqSetting(DRAM_SYS_ATTR * DramAttr); +//timing_setting.c +/*Step3 Set DRAM Timing*/ +void DRAMTimingSetting(DRAM_SYS_ATTR * DramAttr); +//drdy_bl.c +/*Step4 DRDY*/ +void DRAMDRDYSetting(DRAM_SYS_ATTR * DramAttr); +//drdy_bl.c +/*Step5 Burst Length*/ +void DRAMBurstLength(DRAM_SYS_ATTR * DramAttr); +//driving_setting.c +/*Step6 DRAM Driving Adjustment*/ +void DRAMDriving(DRAM_SYS_ATTR * DramAttr); + +//clk_ctrl.c +/*Step7 duty cycle control*/ +void DutyCycleCtrl(DRAM_SYS_ATTR * DramAttr); +//clk_ctrl.c +/*Step8 DRAM clock phase and delay control*/ +void DRAMClkCtrl(DRAM_SYS_ATTR * DramAttr); + +//dev_init.c +/*Step9 set register before init DRAM device*/ +void DRAMRegInitValue(DRAM_SYS_ATTR * DramAttr); + +//dev_init.c +/*Step10 DDR and DDR2 initialize process*/ +void DRAMInitializeProc(DRAM_SYS_ATTR * DramAttr); + +//dqs_search.c +/*Step11 Search DQS and DQ output delay*/ +void DRAMDQSOutputSearch(DRAM_SYS_ATTR * DramAttr); + +//dqs_search.c +/*Step12 Search DQS input delay*/ +void DRAMDQSInputSearch(DRAM_SYS_ATTR * DramAttr); + +//rank_map.c +/*Step13 Interleav function in rankmap.c*/ +void DRAMBankInterleave(DRAM_SYS_ATTR * DramAttr); + +//rank_map.c +/*Step14 Sizing*/ +void DRAMSizingMATypeM(DRAM_SYS_ATTR * DramAttr); + + +//final_setting.c +/*Step15 DDR fresh counter setting*/ +void DRAMRefreshCounter(DRAM_SYS_ATTR * DramAttr); + +//final_setting.c +/*Step16 Final register setting for improve performance*/ +void DRAMRegFinalValue(DRAM_SYS_ATTR * DramAttr); + + +/*set UMA*/ +void SetUMARam(); + +CB_STATUS InstallMemory(DRAM_SYS_ATTR * DramAttr, u32 RamSize); +CB_STATUS DDR2_DRAM_INIT(); + +#endif diff --git a/src/northbridge/via/vx800/dram_util.c b/src/northbridge/via/vx800/dram_util.c new file mode 100644 index 0000000000..d09acdaf6f --- /dev/null +++ b/src/northbridge/via/vx800/dram_util.c @@ -0,0 +1,249 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +void WaitMicroSec(UINTN MicroSeconds) +{ + u32 i; + + for (i = 0; i < 1024 * MicroSeconds; i++) { + __asm__ volatile ("nop\n\t"); + } + + return; +} + +/*=================================================================== +Function : via_write_phys() +Precondition : +Input : addr + value +Output : void +Purpose : +Reference : None +===================================================================*/ + +void via_write_phys(volatile u32 addr, volatile u32 value) +{ + volatile u32 *ptr; + ptr = (volatile u32 *) addr; + *ptr = (volatile u32) value; +} + +/*=================================================================== +Function : via_read_phys() +Precondition : +Input : addr +Output : u32 +Purpose : +Reference : None +===================================================================*/ + +u32 via_read_phys(volatile u32 addr) +{ + volatile u32 *ptr; + volatile u32 y; +// ptr = (volatile u32 *)addr; + y = *(volatile u32 *) addr; +// return *ptr; + return y; +} + + +/*=================================================================== +Function : DimmRead() +Precondition : +Input : x +Output : u32 +Purpose : +Reference : None +===================================================================*/ + +u32 DimmRead(volatile u32 x) +{ // volatile u32 z; + volatile u32 y; + y = *(volatile u32 *) x; + + return y; +} + + +/*=================================================================== +Function : DramBaseTest() +Precondition : this function used to verify memory +Input : + BaseAdd, + length, + mode +Output : u32 +Purpose :write into and read out to verify if dram is correct +Reference : None +===================================================================*/ +BOOLEAN DramBaseTest(u32 BaseAdd, u32 Length, + DRAM_TEST_MODE Mode, BOOLEAN PrintFlag) +{ + u32 TestSpan; + u32 Data, Address, Address2; + u8 i, TestCount; + + //decide the test mode is continous or step + if (Mode == EXTENSIVE) { + //the test mode is continuos and must test each unit + TestSpan = 4; + TestCount = 1; + } else if (Mode == SPARE) { + // the test mode is step and test some unit + TestSpan = STEPSPAN; + TestCount = TESTCOUNT; + } else { + PRINT_DEBUG_MEM("the test mode is error\r"); + return FALSE; + } + + //write each test unit the value with TEST_PATTERN + for (Address = BaseAdd; Address < BaseAdd + Length; + Address += TestSpan) { + for (i = 0; i < TestCount; i++) + via_write_phys(Address + i * 4, TEST_PATTERN); + if (PrintFlag) { + if ((u32) Address % 0x10000000 == 0) { + PRINT_DEBUG_MEM("Write in Addr ="); + PRINT_DEBUG_MEM_HEX32(Address); + PRINT_DEBUG_MEM("\r"); + } + } + } + + //compare each test unit with the value of TEST_PATTERN + //and write it with compliment of TEST_PATTERN + for (Address = BaseAdd; Address < BaseAdd + Length; + Address += TestSpan) { + for (i = 0; i < TestCount; i++) { + Data = via_read_phys(Address + i * 4); + via_write_phys(Address + i * 4, + (u32) (~TEST_PATTERN)); + if (Data != TEST_PATTERN) { + PRINT_DEBUG_MEM + ("TEST_PATTERN ERROR !!!!! "); + Address2 = Address + i * 4; + PRINT_DEBUG_MEM_HEX32(Address2); + PRINT_DEBUG_MEM(" : "); + PRINT_DEBUG_MEM_HEX32(Data); + PRINT_DEBUG_MEM(" \r"); + return FALSE; + } + } + if (PrintFlag) { + if ((u32) Address % 0x10000000 == 0) { + PRINT_DEBUG_MEM("Write in Addr ="); + PRINT_DEBUG_MEM_HEX32(Address); + PRINT_DEBUG_MEM("\r"); + } + } + } + + + //compare each test unit with the value of ~TEST_PATTERN + for (Address = BaseAdd; Address < BaseAdd + Length; + Address += TestSpan) { + for (i = (u8) (TestCount); i > 0; i--) { + Data = via_read_phys(Address + (i - 1) * 4); + if (Data != ~TEST_PATTERN) { + + PRINT_DEBUG_MEM + ("~TEST_PATTERN ERROR !!!!! "); + Address2 = Address + (i - 1) * 4; + PRINT_DEBUG_MEM_HEX32(Address2); + PRINT_DEBUG_MEM(" : "); + PRINT_DEBUG_MEM_HEX32(Data); + PRINT_DEBUG_MEM(" \r"); + return FALSE; + } + } + } + + return TRUE; +} + +/*=================================================================== +Function : DumpRegisters() +Precondition : +Input : + pPCIPPI, + DevNum, + FuncNum +Output : Void +Purpose : +Reference : None +===================================================================*/ + +void DumpRegisters(INTN DevNum, INTN FuncNum) +{ + INTN i, j; + u8 ByteVal; + + ByteVal = 0; + //pci_write_config8(PCI_DEV(0, DevNum, FuncNum), 0xA1, ByteVal); + PRINT_DEBUG_MEM("\rDev %02x Fun %02x\r"); + PRINT_DEBUG_MEM + ("\r 00 01 02 03 04 05 06 07 08 09 0a 0b 0c 0d 0e 0f\r"); + PRINT_DEBUG_MEM + ("---------------------------------------------------\r"); + for (i = 0; i < 0x10; i++) { + PRINT_DEBUG_MEM_HEX32(i); + for (j = 0; j < 0x10; j++) { + ByteVal = + pci_read_config8(PCI_DEV(0, DevNum, FuncNum), + i * 0x10 + j); + PRINT_DEBUG_MEM_HEX8(ByteVal); + PRINT_DEBUG_MEM(" "); + + } + PRINT_DEBUG_MEM("\r"); + } + return; +} + + +/*=================================================================== +Function : dumpnorth() +Precondition : +Input : + pPCIPPI, + Func +Output : Void +Purpose : +Reference : None +===================================================================*/ + +void dumpnorth(u8 Func) +{ + u16 r, c; + u8 ByteVal; + PRINT_DEBUG_MEM("Dump North!!!\r"); + for (r = 0; r < 32; r++) { + for (c = (u16) (r << 3); c < (r << 3) + 8; c++) { + ByteVal = 0; + ByteVal = pci_read_config8(PCI_DEV(0, 0, Func), c); + PRINT_DEBUG_MEM_HEX16(c); + PRINT_DEBUG_MEM("= "); + PRINT_DEBUG_MEM_HEX8(ByteVal); + } + PRINT_DEBUG_MEM("\r"); + } +} diff --git a/src/northbridge/via/vx800/dram_util.h b/src/northbridge/via/vx800/dram_util.h new file mode 100644 index 0000000000..725fd670fc --- /dev/null +++ b/src/northbridge/via/vx800/dram_util.h @@ -0,0 +1,47 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +#ifndef __DRAM_UTIL_H__ +#define __DRAM_UTIL_H__ + +#define STEPSPAN 0x1000 //the span when test memory in spare mode +#define TESTCOUNT 0x4 // the test count in each range when test memory in spare mode +#define TEST_PATTERN 0x5A5A5A5A //the test pattern + +typedef enum __DRAM_TEST_MODE { + EXTENSIVE, + SPARE, + MAXMODE +} DRAM_TEST_MODE; + +void WaitMicroSec(UINTN MicroSeconds); + +void via_write_phys(u32 addr, u32 value); + +u32 via_read_phys(u32 addr); + +u32 DimmRead(u32 x); + +BOOLEAN DramBaseTest(u32 BaseAdd, u32 Length, + DRAM_TEST_MODE mode, BOOLEAN PrintFlag); + +void DumpRegisters(INTN DevNum, INTN FuncNum); + +void dumpnorth(u8 Func); +#endif diff --git a/src/northbridge/via/vx800/drdy_bl.c b/src/northbridge/via/vx800/drdy_bl.c new file mode 100644 index 0000000000..b5a78f1a7d --- /dev/null +++ b/src/northbridge/via/vx800/drdy_bl.c @@ -0,0 +1,600 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +// Set P6IF DRDY Timing +// Because there are 1.5T & 2.5T CAS latency in DDR1 mode, we need to use RDELAYMD-0 +// +// Entry: +// EBP[29:25] = DRAM Speed, Dual_Channel +// VIA_NB2HOST_REG54[7:5] Host Frequency +// VIA_NB3DRAM_REG62[2:0] CAS Latency +// +// Modify NB_Reg: +// VIA_NB2HOST_REG54[3,1] +// VIA_NB2HOST_REG55[1] +// VIA_NB2HOST_REG60 +// VIA_NB2HOST_REG61 +// VIA_NB2HOST_REG62[3:0] +// VIA_NB2HOST_REG63 +// VIA_NB2HOST_REG64 +// VIA_NB2HOST_REG65[3:0] +// VIA_NB2HOST_REG66 +// VIA_NB2HOST_REG67[5:4] +// +// Processing: +//-------------------------------------------------------------------------- +// P6IF DRDY Timing Control: +// *Following algorithm to set DRDY timing +// Set P6IF DRDY Timing by the following 3 conditions: +// 1. RDELAYMD +// a.RDRPH(MD input internal timing control) +// b.CAS Latency +// RDELAYMD(1bit) = bit0 of (CL + RDRPH) +// for example: RDRPH=10b, CL3 -> F3_Rx56[5:4]=11b, 10b + 11b = 101b, RDELAYMD=1 (bit0) +// RDRPH=00b, CL2.5 -> F3_Rx56[5:4]=10b, 00b + 10b = 010b, RDELAYMD=0 (bit0) +// 2. CPU Frequency +// 3. DRAM Frequency +// +// According to above conditions, we create different tables: +// 1. RDELAYMD=0 : for integer CAS latency(ex. CL=3) +// 2. RDELAYMD=1 : for non-integer CAS latency(ex. CL=2.5) +// 3. Normal performance +// 4. Top performance : +// Using phase0 to a case has better performance. +// +// Note: The setting are related to performance and maybe affect DRAM initialize. +// Turn OFF(F2_Rx51[7]=0) this feature at csDRAMRegInitValueJ procedure. +// Turn ON(F2_Rx51[7]=1) this feature at csDRAMRegFinalValueJ procedure. +// +// If F2_Rx51[7]=0, then CPU always wait 8QW, a slower but most stable way +// If F2_Rx51[7]=1, then the timing will refer to F2_Rx60 ~ F2_Rx67, +// a fast way but may cause the system to be unstable. +// +// Coding: +// 1. RDELAYMD and user's option for performance can determine which table +// 2. CPU Frequency can get block offset of table +// 3. DRAM Frequency can get row offset of block +// 4. Set value +// +// PS: Fun2 Rx62, Rx65, Rx67 are don't care bits in 3296, CPU 266MHz doesn't be supported by 3296, +// but I still keep these bits in table to avoid the usage in future +// and do the fewest modification for code. +// + +// Early 3T +// Early 3T +#define P6IF_Misc_RFASTH 0x08 +#define P6IF_Misc2_RRRDYH3E 0x10 +#define P6IF_Misc2_RHTSEL 0x02 + +#define Rx54E3T P6IF_Misc_RFASTH +#define Rx55E3T P6IF_Misc2_RRRDYH3E + +// Early 2T +#define Rx54E2T 0x00 +#define Rx55E2T P6IF_Misc2_RRRDYH3E + +// Early 1T +#define Rx54E1T 0x00 +#define Rx55E1T 0x00 + +// Early 0T +#define Rx54E0T P6IF_Misc_RFASTH +#define Rx55E0T P6IF_Misc2_RRRDYH3E + P6IF_Misc2_RHTSEL + +// Latter 1T +#define Rx54L1T P6IF_Misc_RFASTH +#define Rx55L1T P6IF_Misc2_RHTSEL + + +#define PH0_0_0_0 0x00 +#define PH0_0_0_1 0x01 +#define PH0_0_0_2 0x02 +#define PH0_0_0_3 0x03 +#define PH0_0_1_0 0x04 +#define PH0_0_1_1 0x05 +#define PH0_0_1_2 0x06 +#define PH0_0_2_1 0x09 +#define PH0_0_2_2 0x0a +#define PH0_0_2_3 0x0b +#define PH0_0_3_2 0x0e +#define PH0_0_3_3 0x0f +#define PH0_1_1_0 0x14 +#define PH0_1_1_1 0x15 +#define PH0_2_1_2 0x26 +#define PH0_2_2_1 0x29 +#define PH0_2_2_2 0x2a +#define PH0_2_2_3 0x2b +#define PH0_2_3_2 0x2e +#define PH0_2_3_3 0x2f +#define PH0_3_2_2 0x3a +#define PH0_3_3_3 0x3f +#define PH1_0_0_0 0x40 +#define PH1_0_0_1 0x41 +#define PH1_0_1_1 0x45 +#define PH1_1_1_1 0x55 +#define PH1_2_1_1 0x65 +#define PH1_2_2_1 0x69 +#define PH2_1_1_1 0x95 +#define PH2_1_2_1 0x99 +#define PH2_1_2_2 0x9a +#define PH2_2_1_2 0xa6 +#define PH2_2_2_1 0xa9 +#define PH2_2_2_2 0xaa +#define PH2_2_3_2 0xae +#define PH2_2_3_3 0xaf +#define PH2_3_2_2 0xba +#define PH2_3_2_3 0xbb +#define PH2_3_3_2 0xbe +#define PH3_2_2_3 0xeb +#define PH3_2_3_2 0xee +#define PH3_2_3_3 0xef +#define PH3_3_3_3 0xff + +#define PT894_RDRDY_TBL_Width 10 +#define PT894_RDRDY_TBL_Block 60 + +static const u8 PT894_128bit_DELAYMD0_RCONV0[6][6][PT894_RDRDY_TBL_Width] = +// ----------------------------------------------------------------------------------------------------------------- +// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM +// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E +// RCONV RHTSEL +// ----------------------------------------------------------------------------------------------------------------- +{ +// cpu100 + { + {PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/100 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/133 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 + }, +// cpu133 + { + {PH0_2_2_1, PH0_0_0_0, PH0_0_0_0, PH0_2_2_1, PH0_0_0_0, PH0_0_0_0, 0x01, 0x00, Rx54E3T, Rx55E3T}, // 133/100 + {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/133 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 + }, +// cpu200 + { + {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E2T, Rx55E2T}, // 200/100 + {PH2_3_2_3, PH0_0_0_0, PH0_0_0_0, PH2_3_2_3, PH0_0_0_0, PH0_0_0_0, 0x0a, 0x00, Rx54E3T, Rx55E3T}, // 200/133 + {PH1_2_2_1, PH0_0_0_1, PH0_0_0_0, PH1_2_2_1, PH0_0_0_1, PH0_0_0_0, 0x01, 0x00, Rx54E3T, Rx55E3T}, // 200/166 + {PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 + }, +// cpu166 + { + {PH0_2_3_3, PH0_0_0_0, PH0_0_0_0, PH0_2_2_3, PH0_0_0_0, PH0_0_0_0, 0x05, 0x00, Rx54E3T, Rx55E3T}, // 166/100 + {PH1_2_2_1, PH0_0_0_0, PH0_0_0_0, PH1_2_2_1, PH0_0_0_0, PH0_0_0_0, 0x01, 0x00, Rx54E3T, Rx55E3T}, // 166/133 + {PH1_1_1_1, PH0_0_0_1, PH0_0_0_0, PH1_1_1_1, PH0_0_0_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 + }, +// cpu266 + { + {PH0_2_2_3, PH0_0_0_0, PH0_0_0_0, PH0_0_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 266/100 + {PH3_3_3_3, PH0_0_0_0, PH0_0_0_0, PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E2T, Rx55E2T}, // 266/133 + {PH3_2_3_3, PH0_0_0_3, PH0_0_0_0, PH3_2_3_3, PH0_0_0_2, PH0_0_0_0, 0x0d, 0x00, Rx54E3T, Rx55E3T}, // 266/166 + {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH2_1_2_2, PH0_0_1_2, PH0_0_0_0, 0x12, 0x00, Rx54E3T, Rx55E3T}, // 266/200 + {PH1_1_1_1, PH1_1_1_1, PH0_0_0_0, PH1_1_1_1, PH1_1_1_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 266/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 266/333 + }, +// cpu333 + { + {PH0_1_1_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 333/100 + {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 333/133 + {PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, 0x1f, 0x00, Rx54E2T, Rx55E2T}, // 333/166 + {PH2_2_1_2, PH0_0_2_1, PH0_0_0_0, PH1_2_1_1, PH0_0_2_1, PH0_0_0_0, 0x36, 0x00, Rx54E2T, Rx55E2T}, // 333/200 + {PH2_1_1_1, PH2_1_1_1, PH0_0_0_0, PH2_1_1_1, PH2_1_1_1, PH0_0_0_0, 0x44, 0x00, Rx54E3T, Rx55E3T}, // 333/266 + {PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0x00, 0x00, Rx54E3T, Rx55E3T} // 333/333 + } +}; + +static const u8 PT894_128bit_DELAYMD1_RCONV0[6][6][PT894_RDRDY_TBL_Width] = +// ----------------------------------------------------------------------------------------------------------------- +// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM +// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E +// RCONV RHTSEL +// ----------------------------------------------------------------------------------------------------------------- +{ +// cpu100 + { + {PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/100 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/133 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 + }, +// cpu133 + { + {PH0_3_2_2, PH0_0_0_0, PH0_0_0_0, PH0_3_2_2, PH0_0_0_0, PH0_0_0_0, 0x02, 0x00, Rx54E3T, Rx55E3T}, // 133/100 + {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/133 + {PH1_0_0_0, PH0_0_0_0, PH0_0_0_0, PH1_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 + }, +// cpu200 + { + {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 200/100 + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH2_1_2_1, PH0_0_0_0, PH0_0_0_0, 0x0a, 0x00, Rx54E2T, Rx55E2T}, // 200/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x04, 0x00, Rx54E3T, Rx55E3T}, // 200/166 + {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 200/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 + }, +// cpu166 + { + {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_2_1_2, PH0_0_0_0, PH0_0_0_0, 0x05, 0x00, Rx54E2T, Rx55E2T}, // 166/100 + {PH2_3_2_2, PH0_0_0_0, PH0_0_0_0, PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, 0x02, 0x00, Rx54E3T, Rx55E3T}, // 166/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/166 + {PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 + }, +// cpu266 + { + {PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 266/100 + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 266/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_1_2, PH0_0_0_2, PH0_0_0_0, 0x15, 0x00, Rx54E2T, Rx55E2T}, // 266/166 + {PH3_2_3_3, PH0_0_2_3, PH0_0_0_0, PH2_2_3_2, PH0_0_2_3, PH0_0_0_0, 0x24, 0x00, Rx54E3T, Rx55E3T}, // 266/200 + {PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 266/266 + {PH0_0_0_1, PH0_0_1_1, PH0_0_1_0, PH0_0_0_1, PH0_0_1_1, PH0_0_1_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 266/333 + }, +// cpu333 + { + {PH0_3_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 333/100 + {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E0T, Rx55E0T}, // 333/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x1f, 0x00, Rx54E1T, Rx55E1T}, // 333/166 + {PH2_3_2_2, PH0_0_3_2, PH0_0_0_0, PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, 0x1b, 0x00, Rx54E2T, Rx55E2T}, // 333/200 + {PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, PH2_2_2_1, PH2_2_2_1, PH0_0_0_0, 0x88, 0x00, Rx54E3T, Rx55E3T}, // 333/266 + {PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0x00, 0x00, Rx54E3T, Rx55E3T} // 333/333 + } +}; + + +static const u8 PT894_64bit_DELAYMD0_RCONV0[6][6][PT894_RDRDY_TBL_Width] = +// ----------------------------------------------------------------------------------------------------------------- +// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM +// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E +// RCONV RHTSEL +// ----------------------------------------------------------------------------------------------------------------- +{ +// cpu100 + { + {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E3T, Rx55E3T}, // 100/100 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x09, 0x00, Rx54E3T, Rx55E3T}, // 100/133 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 + }, +// cpu133 + { + {PH0_2_3_2, PH0_0_0_0, PH0_0_0_0, PH0_0_1_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E2T, Rx55E2T}, // 133/100 + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E3T, Rx55E3T}, // 133/133 + {PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E3T, Rx55E3T}, // 133/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 + }, +// cpu200 + { + {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E0T, Rx55E0T}, // 200/100 + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 200/133 + {PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, PH1_2_2_1, PH0_0_0_1, PH0_0_0_0, 0x1f, 0x00, Rx54E3T, Rx55E3T}, // 200/166 + {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, 0x3f, 0x00, Rx54E3T, Rx55E3T}, // 200/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E1T, Rx55E1T}, // 200/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 +// DDR2 Both E3T and E2T Fail, need set to E1T, db PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 00110011b, 00000000b, Rx54E3T, Rx55E3T ;200/266 + }, +// cpu166 + { + {PH0_2_3_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 166/100 + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_1_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E2T, Rx55E2T}, // 166/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH1_1_1_1, PH0_0_0_1, PH0_0_0_0, 0x1f, 0x00, Rx54E3T, Rx55E3T}, // 166/166 + {PH1_0_0_1, PH0_0_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1e, 0x00, Rx54E3T, Rx55E3T}, // 166/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 + }, +// cpu266 + { + {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54L1T, Rx55L1T}, // 266/100 + {PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 266/133 + {PH3_2_3_2, PH0_0_0_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54E1T, Rx55E1T}, // 266/166 + {PH3_2_2_3, PH0_0_2_2, PH0_0_0_0, PH1_0_0_1, PH0_0_0_0, PH0_0_0_0, 0x3f, 0x00, Rx54E2T, Rx55E2T}, // 266/200 + {PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, PH1_1_1_1, PH1_1_1_1, PH0_0_0_0, 0xff, 0x00, Rx54E3T, Rx55E3T}, // 266/266 + {PH0_0_1_1, PH0_1_1_1, PH0_0_1_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x9c, 0x03, Rx54E3T, Rx55E3T} // 266/333 + }, +// cpu333 + { + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54L1T, Rx55L1T}, // 333/100 ;DO NOT Support + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 333/133 + {PH3_3_3_3, PH0_0_0_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54E0T, Rx55E0T}, // 333/166 + {PH2_3_3_2, PH0_0_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x3f, 0x00, Rx54E1T, Rx55E1T}, // 333/200 + {PH3_3_3_3, PH3_3_3_3, PH0_0_0_0, PH2_1_1_1, PH2_1_1_1, PH0_0_0_0, 0xff, 0x00, Rx54E3T, Rx55E3T}, // 333/266 + {PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0xff, 0x03, Rx54E3T, Rx55E3T} // 333/333 + } +}; + + +static const u8 PT894_64bit_DELAYMD1_RCONV0[6][6][PT894_RDRDY_TBL_Width] = +// ----------------------------------------------------------------------------------------------------------------- +// RX60 RX61 RX62 RX63 RX64 RX65 RX66 RX67 RX54[3,1] RX55[3,1] CPU/DRAM +// LN4:1 LN8:5 LN10:9 QW4:1 QW8:5 QW10:9 WS8:1 WS10:9 RFASTH RRRDYH3E +// RCONV RHTSEL +// ----------------------------------------------------------------------------------------------------------------- +{ +// cpu100 + { + {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E3T, Rx55E3T}, // 100/100 + {PH1_0_0_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x06, 0x00, Rx54E3T, Rx55E3T}, // 100/133 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 100/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // ;100/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 100/333 + }, +// cpu133 + { + {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E2T, Rx55E2T}, // 133/100 + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH1_1_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E3T, Rx55E3T}, // 133/133 + {PH1_0_1_1, PH0_0_0_1, PH0_0_0_0, PH1_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1c, 0x00, Rx54E3T, Rx55E3T}, // 133/166 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x09, 0x00, Rx54E3T, Rx55E3T}, // 133/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 133/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 133/333 + }, +// cpu200 + { + {PH0_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54L1T, Rx55L1T}, // 200/100 + {PH3_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E1T, Rx55E1T}, // 200/133 + {PH2_2_3_3, PH0_0_0_2, PH0_0_0_0, PH1_0_1_1, PH0_0_0_1, PH0_0_0_0, 0x1f, 0x00, Rx54E2T, Rx55E2T}, // 200/166 + {PH3_3_3_3, PH0_0_3_3, PH0_0_0_0, PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, 0x3f, 0x00, Rx54E3T, Rx55E3T}, // 200/200 + {PH0_0_1_1, PH0_0_1_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0xcc, 0x00, Rx54E3T, Rx55E3T}, // 200/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 200/333 + }, +// cpu166 + { + {PH0_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x07, 0x00, Rx54E1T, Rx55E1T}, // 166/100 + {PH2_2_3_3, PH0_0_0_0, PH0_0_0_0, PH1_0_1_1, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54E2T, Rx55E2T}, // 166/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, 0x1f, 0x00, Rx54E3T, Rx55E3T}, // 166/166 + {PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, PH1_0_0_0, PH0_0_0_1, PH0_0_0_0, 0x39, 0x00, Rx54E3T, Rx55E3T}, // 166/200 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T}, // 166/266 + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54E3T, Rx55E3T} // 166/333 + }, +// cpu266 + { + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54L1T, Rx55L1T}, // 266/100 ;DO NOT Support + {PH2_2_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 266/133 + {PH2_2_1_2, PH0_0_0_1, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54E0T, Rx55E0T}, // 266/166 + {PH3_3_3_3, PH0_0_3_3, PH0_0_0_0, PH1_1_1_1, PH0_0_1_1, PH0_0_0_0, 0x3f, 0x00, Rx54E2T, Rx55E2T}, // 266/200 + {PH3_3_3_3, PH3_3_3_3, PH0_0_0_0, PH2_2_2_2, PH2_2_2_2, PH0_0_0_0, 0xff, 0x00, Rx54E3T, Rx55E3T}, // 266/266 + {PH1_1_1_1, PH1_1_1_1, PH0_0_1_1, PH0_0_0_1, PH0_0_1_1, PH0_0_1_0, 0x73, 0x02, Rx54E3T, Rx55E3T} // 266/333 + }, +// cpu333 + { + {PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x00, 0x00, Rx54L1T, Rx55L1T}, // 333/100 ;DO NOT Support + {PH3_3_3_3, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x0f, 0x00, Rx54L1T, Rx55L1T}, // 333/133 + {PH2_2_2_2, PH0_0_0_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x1f, 0x00, Rx54L1T, Rx55L1T}, // 333/166 + {PH2_2_2_2, PH0_0_2_2, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, PH0_0_0_0, 0x3f, 0x00, Rx54E1T, Rx55E1T}, // 333/200 + {PH2_3_2_2, PH2_3_2_2, PH0_0_0_0, PH0_1_1_0, PH0_1_1_0, PH0_0_0_0, 0xff, 0x00, Rx54E2T, Rx55E2T}, // 333/266 + {PH3_3_3_3, PH3_3_3_3, PH0_0_3_3, PH2_2_2_2, PH2_2_2_2, PH0_0_2_2, 0xff, 0x03, Rx54E3T, Rx55E3T} // 333/333 + } +}; + +void DRAMDRDYSetting(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data, CL, RDRPH; + u8 CpuFreq, DramFreq; + u8 ProgData[PT894_RDRDY_TBL_Width]; + u8 DelayMode; + u8 DrdyMode; + u8 Index; + + /* + this function has 3 switchs, correspond to 3 level of Drdy setting. + 0:Slowest, 1:Default, 2:Optimize + you can only open one switch + */ +#if 1 //this is slowest + // 0 -> Slowest + //Write slowest value to register + + Data = 0xAA; + pci_write_config8(PCI_DEV(0, 0, 2), 0x60, Data); + + Data = 0x0A; + pci_write_config8(PCI_DEV(0, 0, 2), 0x61, Data); + + Data = 0x00; + pci_write_config8(PCI_DEV(0, 0, 2), 0x62, Data); + + Data = 0xAA; + pci_write_config8(PCI_DEV(0, 0, 2), 0x63, Data); + + Data = 0x0A; + pci_write_config8(PCI_DEV(0, 0, 2), 0x64, Data); + + Data = 0x00; + pci_write_config8(PCI_DEV(0, 0, 2), 0x65, Data); + + Data = 0x00; + pci_write_config8(PCI_DEV(0, 0, 2), 0x66, Data); + + Data = 0x00; + pci_write_config8(PCI_DEV(0, 0, 2), 0x67, Data); + + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x54); + Data = Data & 0xF5; + Data |= 0x08; + pci_write_config8(PCI_DEV(0, 0, 2), 0x54, Data); + + //Data=pci_read_config8(PCI_DEV(0,0,2), 0x55); + //Data = Data & (~0x20); + //pci_write_config8(PCI_DEV(0,0,2), 0x55, Data); + + //enable drdy timing + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x51); + Data = Data | 0x80; + pci_write_config8(PCI_DEV(0, 0, 2), 0x51, Data); +#endif +#if 0 //default + { + //disable drdy timing + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x51); + Data = Data & 0x7F; + pci_write_config8(PCI_DEV(0, 0, 2), 0x51, Data); + } +#endif +#if 0 // 2:Optimize + //CL :reg6x[2:0] + Data = pci_read_config8(MEMCTRL, 0x62); + CL = Data & 0x07; + + //RDRPH: reg7B[6:4] + Data = pci_read_config8(MEMCTRL, 0x7B); + RDRPH = (Data & 0x70) >> 4; + + //CpuFreq: F2Reg54[7:5] + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x54); + CpuFreq = (Data & 0xE0) >> 5; + + //DramFreq:F3Reg90[2:0] + Data = pci_read_config8(MEMCTRL, 0x90); + DramFreq = Data & 0x07; + + DelayMode = CL + RDRPH; // RDELAYMD = bit0 of (CAS Latency + RDRPH) + DelayMode &= 0x01; + + //In 364, there is no 128 bit + if (DelayMode == 1) { // DelayMode 1 + for (Index = 0; Index < PT894_RDRDY_TBL_Width; Index++) + ProgData[Index] = + PT894_64bit_DELAYMD1_RCONV0[CpuFreq][DramFreq] + [Index]; + } else { // DelayMode 0 + for (Index = 0; Index < PT894_RDRDY_TBL_Width; Index++) + ProgData[Index] = + PT894_64bit_DELAYMD0_RCONV0[CpuFreq][DramFreq] + [Index]; + } + + Data = ProgData[0]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x60, Data); + + Data = ProgData[1]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x61, Data); + + Data = ProgData[2]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x62, Data); + + Data = ProgData[3]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x63, Data); + + Data = ProgData[4]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x64, Data); + + Data = ProgData[5]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x65, Data); + + Data = ProgData[6]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x66, Data); + + Data = ProgData[7]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x67, Data); + + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x54); + Data = (Data & 0xF5) | ProgData[8]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x54, Data); + + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x55); + Data = Data & (~0x22) | ProgData[9]; + pci_write_config8(PCI_DEV(0, 0, 2), 0x62, Data); + + //enable drdy timing + Data = pci_read_config8(PCI_DEV(0, 0, 2), 0x51); + Data = Data | 0x80; + pci_write_config8(PCI_DEV(0, 0, 2), 0x51, Data); +#endif +} + + +/*This routine process the ability for North Bridge side burst functionality +There are 3 variances that are valid: + 1. DIMM BL=8, chipset BL=8 + 2. DIMM BL=4, chipset BL=4 + 3. DIMM BL=4, chipset BL=8 (only happened on Dual channel) + Device 0 function 2 HOST:REG54[4] must be 1 when 128-bit mode. +Since DIMM will be initialized in each rank individually, + 1.If all DIMM BL=4, DIMM will initialize BL=4 first, + then check dual_channel flag to enable VIA_NB2HOST_REG54[4]. + 2.If all DIMM BL=8, DIMM will initialize BL=8 first, + then check dual_channel flag for re-initialize DIMM BL=4. + also VIA_NB2HOST_REG54[4] need to be enabled. +Chipset_BL8==>chipset side can set burst length=8 +two register need to set + 1. Device 0 function 2 HOST:REG54[4] + 2. Device 0 function 3 DRAM:REG6C[3] +*/ +void DRAMBurstLength(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data, BL; + u8 Sockets; + /*SPD byte16 bit3,2 describes the burst length supported. bit3=1 support BL=8 bit2=1 support BL=4 */ + BL = 0x0c; + for (Sockets = 0; Sockets < 2; Sockets++) { + if (DramAttr->DimmInfo[Sockets].bPresence) { + BL &= + (DramAttr->DimmInfo[Sockets]. + SPDDataBuf[SPD_SDRAM_BURSTLENGTH]); + } + } + + /*D0F3Rx6c bit3 CHA SDRAM effective burst length, for 64bit mode ranks =0 BL=4 ; =1 BL=8 */ + + if (BL & 0x08) /*All Assembly support BL=8 */ + BL = 0x8; /*set bit3 */ + else + BL = 0x00; /*clear bit3 */ + + Data = pci_read_config8(MEMCTRL, 0x6c); + Data = (u8) ((Data & 0xf7) | BL); + +#if ENABLE_CHB + if (DramAttr->RankNumChB > 0) { + BL = DramAttr->DimmInfo[2]. + SPDDataBuf[SPD_SDRAM_BURSTLENGTH]; + //Rx6c[1], CHB burst length + if (BL & 0x08) /*CHB support BL=8 */ + BL = 0x2; /*set bit1 */ + else + BL = 0x00; /*clear bit1 */ + + Data = (Data & 0xFD) | BL; + } +#endif + pci_write_config8(MEMCTRL, 0x6c, Data); +} diff --git a/src/northbridge/via/vx800/driving_setting.c b/src/northbridge/via/vx800/driving_setting.c new file mode 100644 index 0000000000..3bdfdf391f --- /dev/null +++ b/src/northbridge/via/vx800/driving_setting.c @@ -0,0 +1,396 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +/* + Driving setting: ODT/DQS/DQ/CS/MAA/MAB/DCLK + */ + +void DrivingODT(DRAM_SYS_ATTR * DramAttr); + +void DrivingDQS(DRAM_SYS_ATTR * DramAttr); + +void DrivingDQ(DRAM_SYS_ATTR * DramAttr); + +void DrivingCS(DRAM_SYS_ATTR * DramAttr); + +void DrivingMA(DRAM_SYS_ATTR * DramAttr); + +void DrivingDCLK(DRAM_SYS_ATTR * DramAttr); + +/* DRAM Driving Adjustment*/ +void DRAMDriving(DRAM_SYS_ATTR * DramAttr) +{ + PRINT_DEBUG_MEM("set ODT!\r"); + DrivingODT(DramAttr); + + PRINT_DEBUG_MEM("set DQS!\r"); + DrivingDQS(DramAttr); + + PRINT_DEBUG_MEM(("set DQ!\r")); + DrivingDQ(DramAttr); + + PRINT_DEBUG_MEM("set CS!\r"); + DrivingCS(DramAttr); + + PRINT_DEBUG_MEM("set MAA!\r"); + DrivingMA(DramAttr); + + PRINT_DEBUG_MEM("set DCLK!\r"); + DrivingDCLK(DramAttr); +} + + +/* +ODT Control for DQ/DQS/CKE/SCMD/DCLKO in ChA & ChB +which include driving enable/range and strong/weak selection + +Processing: According to DRAM frequency to ODT control bits. + Because function enable bit must be the last one to be set. + So the register VIA_NB3DRAM_REGD4 and VIA_NB3DRAM_REGD3 should be + the last register to be programmed. +*/ +//------------------------------------------------------------------------------- +// ODT Lookup Table +//------------------------------------------------------------------------------- +#define Rank0_ODT 0 +#define Rank1_ODT 1 +#define Rank2_ODT 2 +#define Rank3_ODT 3 +#define NA_ODT 0 +#define NB_ODT_75ohm 0 +#define NB_ODT_150ohm 1 + +#define DDR2_ODT_75ohm 0x20 +#define DDR2_ODT_150ohm 0x40 + +// Setting of ODT Lookup TBL +// RankMAP , Rank 3 Rank 2 Rank 1 Rank 0 , DRAM & NB ODT setting +// db 0000b , Reserved +#define ODTLookup_Tbl_count 8 +static const u8 ODTLookup_TBL[ODTLookup_Tbl_count][3] = { + // 0001b + {0x01, + (Rank3_ODT << 6) + (Rank2_ODT << 4) + (Rank1_ODT << 2) + + Rank0_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, + // 0010b , Reserved + // 0011b + {0x03, + (Rank3_ODT << 6) + (Rank2_ODT << 4) + (Rank0_ODT << 2) + + Rank1_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, + // 0100b + {0x04, + (Rank3_ODT << 6) + (Rank2_ODT << 4) + (Rank1_ODT << 2) + + Rank0_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, + // 0101b + {0x05, + (Rank3_ODT << 6) + (Rank0_ODT << 4) + (Rank1_ODT << 2) + + Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm}, + // 0110b , Reserved + // 0111b + {0x07, + (Rank3_ODT << 6) + (Rank0_ODT << 4) + (Rank2_ODT << 2) + + Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm}, + // 1000b , Reserved + // 1001b , Reserved + // 1010b , Reserved + // 1011b , Reserved + // 1100b + {0x0c, + (Rank2_ODT << 6) + (Rank3_ODT << 4) + (Rank1_ODT << 2) + + Rank0_ODT, DDR2_ODT_150ohm + NB_ODT_75ohm}, + // 1101b + {0x0d, + (Rank0_ODT << 6) + (Rank0_ODT << 4) + (Rank1_ODT << 2) + + Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm}, + // 1110b , Reserved + // 1111b + {0x0f, + (Rank0_ODT << 6) + (Rank0_ODT << 4) + (Rank2_ODT << 2) + + Rank2_ODT, DDR2_ODT_75ohm + NB_ODT_150ohm} +}; + +#define ODT_Table_Width_DDR2 4 +// RxD6 RxD3 +static const u8 ODT_Control_DDR2[ODT_Table_Width_DDR2] = { 0xFC, 0x01 }; + +void DrivingODT(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 i; + BOOLEAN bFound; + + pci_write_config8(MEMCTRL, 0xD0, 0x88); + + Data = ODT_Control_DDR2[0]; + pci_write_config8(MEMCTRL, 0xd6, Data); + + Data = ODT_Control_DDR2[1]; + pci_write_config8(MEMCTRL, 0xd3, Data); + + Data = pci_read_config8(MEMCTRL, 0x9e); + //set MD turn_around wait state + Data &= 0xCF; /*clear bit4,5 */ + if (DIMMFREQ_400 == DramAttr->DramFreq) + Data |= 0x0; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + Data |= 0x10; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + Data |= 0x20; + else if (DIMMFREQ_800 == DramAttr->DramFreq) + Data |= 0x20; + else + Data |= 0; + pci_write_config8(MEMCTRL, 0x9e, Data); + + + if (DIMMFREQ_400 == DramAttr->DramFreq) + Data = 0x0; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + Data = 0x11; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + Data = 0x11; + else if (DIMMFREQ_800 == DramAttr->DramFreq) + Data = 0x11; + else + Data = 0; + pci_write_config8(MEMCTRL, 0x9f, Data); + + + /*channel A ODT select */ + if (DramAttr->DimmNumChA > 0) { + Data = pci_read_config8(MEMCTRL, 0xd5); + Data &= 0x5F; /*clear bit7,5 */ + if (DramAttr->RankNumChA > 2) + Data |= 0xA0; /*if rank number > 2 (3or4), set bit7,5 */ + else + Data |= 0x00; /*if rank number is 1or2, clear bit5 */ + pci_write_config8(MEMCTRL, 0xd5, Data); + + Data = pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xEF; /*clear bit7 */ + if (DramAttr->RankNumChA > 2) + Data |= 0x80; /*if rank number > 2 (3or4), set bit7 */ + else + Data |= 0x00; /*if rank number is 1or2, clear bit7 */ + pci_write_config8(MEMCTRL, 0xd7, Data); + + + /*channel A */ + Data = pci_read_config8(MEMCTRL, 0xd5); + Data &= 0xF3; //bit2,3 + if (DramAttr->DimmNumChA == 2) /*2 Dimm, 3or4 Ranks */ + Data |= 0x00; + else if (DramAttr->DimmNumChA == 1) + Data |= 0x04; + pci_write_config8(MEMCTRL, 0xd5, Data); + + if ((DramAttr->RankPresentMap & 0x0F) != 0) { /*channel A */ + // MAA ODT Lookup Table + bFound = FALSE; + for (i = 0; i < ODTLookup_Tbl_count; i++) { + if ((DramAttr->RankPresentMap & 0x0F) == + ODTLookup_TBL[i][0]) { + Data = ODTLookup_TBL[i][1]; + bFound = TRUE; + } + } + if (!bFound) { /*set default value */ + Data = + ODTLookup_TBL[ODTLookup_Tbl_count - + 1][1]; + } + pci_write_config8(MEMCTRL, 0x9c, Data); + + + //set CHA MD ODT control State Dynamic-on + Data = pci_read_config8(MEMCTRL, 0xD4); + Data &= 0xC9; + Data |= 0x30; + pci_write_config8(MEMCTRL, 0xD4, Data); + + Data = pci_read_config8(MEMCTRL, 0x9e); + Data |= 0x01; + pci_write_config8(MEMCTRL, 0x9e, Data); + } + + } + /*channel B */ + if (1 == ENABLE_CHC) { + //CHB has not auto compensation mode ,so must set it manual,or else CHB initialization will not successful + // Data =0x88; + //pci_write_config8(MEMCTRL, 0xd0, Data); + + Data = pci_read_config8(MEMCTRL, 0xd5); + Data &= 0xAF; + if (DramAttr->RankNumChB > 2) /*rank number 3 or 4 */ + Data |= 0x50; + else + Data |= 0x00; + pci_write_config8(MEMCTRL, 0xd5, Data); + + Data = pci_read_config8(MEMCTRL, 0xd7); + Data &= 0xBF; /*clear bit6 */ + if (DramAttr->RankNumChB > 2) + Data |= 0x40; /*if rank number > 2 (3or4), set bit7 */ + else + Data |= 0x00; /*if rank number is 1or2, clear bit7 */ + pci_write_config8(MEMCTRL, 0xd7, Data); + + + Data = pci_read_config8(MEMCTRL, 0xd5); + Data &= 0xFC; + if (DramAttr->DimmNumChB == 2) /*2 Dimm, 3or4 Ranks */ + Data |= 0x00; // 2 dimm RxD5[2,0]=0,0b + else if (DramAttr->DimmNumChB == 1) + Data |= 0x01; // 1 dimm RxD5[2,0]=1,1b + pci_write_config8(MEMCTRL, 0xd5, Data); + + //set CHB MD ODT control State Dynamic-on + Data = pci_read_config8(MEMCTRL, 0xD4); + Data &= 0xF6; + Data |= 0x08; + pci_write_config8(MEMCTRL, 0xD4, Data); + + + //enable CHB differential DQS input + Data = pci_read_config8(MEMCTRL, 0x9E); + Data |= 0x02; + pci_write_config8(MEMCTRL, 0x9E, Data); + } + //enable ODT Control + Data = pci_read_config8(MEMCTRL, 0x9e); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0x9e, Data); +} + +void DrivingDQS(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + + /*channel A */ + if (DramAttr->RankNumChA > 0) { + Data = DDR2_DQSA_Driving_Table[DramAttr->RankNumChA - 1]; + pci_write_config8(MEMCTRL, 0xe0, Data); + } + + /*channel B */ + if (1 == ENABLE_CHC) { + Data = DDR2_DQSB_Driving_Table[DramAttr->RankNumChB - 1]; + pci_write_config8(MEMCTRL, 0xe1, Data); + } + +} + +void DrivingDQ(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + + /*channel A */ + if (DramAttr->RankNumChA > 0) { + Data = DDR2_DQA_Driving_Table[DramAttr->RankNumChA - 1]; + pci_write_config8(MEMCTRL, 0xe2, Data); + + } + /*channel B */ + if (1 == ENABLE_CHC) { + Data = DDR2_DQB_Driving_Table[DramAttr->RankNumChB - 1]; + pci_write_config8(MEMCTRL, 0xe3, Data); + } +} + +void DrivingCS(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + /*Channel A */ + if (DramAttr->RankNumChA > 0) { + Data = DDR2_CSA_Driving_Table_x8[DramAttr->RankNumChA - 1]; + pci_write_config8(MEMCTRL, 0xe4, Data); + } + /*channel B */ + if (1 == ENABLE_CHC) { + Data = DDR2_CSB_Driving_Table_x8[DramAttr->RankNumChB - 1]; + pci_write_config8(MEMCTRL, 0xe5, Data); + } +} + +void DrivingMA(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 i, FreqId; + + if (DramAttr->RankNumChA > 0) { + if (DIMMFREQ_400 == DramAttr->DramFreq) + FreqId = 1; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + FreqId = 2; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + FreqId = 3; + else if (DIMMFREQ_800 == DramAttr->DramFreq) + FreqId = 4; + else + FreqId = 1; + for (i = 0; i < MA_Table; i++) { + if (DramAttr->LoadNumChA <= + DDR2_MAA_Driving_Table[i][0]) { + Data = DDR2_MAA_Driving_Table[i][FreqId]; + break; + } + } + pci_write_config8(MEMCTRL, 0xe8, Data); + } + if (1 == ENABLE_CHC) { + for (i = 0; i < MA_Table; i++) { + if (DramAttr->LoadNumChA <= + DDR2_MAB_Driving_Table[i][0]) { + Data = DDR2_MAB_Driving_Table[i][1]; + break; + } + } + pci_write_config8(MEMCTRL, 0xe9, Data); + } +} + +void DrivingDCLK(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 FreqId; + + if (DIMMFREQ_400 == DramAttr->DramFreq) + FreqId = 0; + else if (DIMMFREQ_533 == DramAttr->DramFreq) + FreqId = 1; + else if (DIMMFREQ_667 == DramAttr->DramFreq) + FreqId = 2; + else if (DIMMFREQ_800 == DramAttr->DramFreq) + FreqId = 4; + else + FreqId = 0; + + /*channel A */ + if (DramAttr->RankNumChA > 0) { + Data = DDR2_DCLKA_Driving_Table[FreqId]; + pci_write_config8(MEMCTRL, 0xe6, Data); + } + /*channel B */ + if (1 == ENABLE_CHC) { + Data = DDR2_DCLKB_Driving_Table[FreqId]; + pci_write_config8(MEMCTRL, 0xe7, Data); + } + +} diff --git a/src/northbridge/via/vx800/final_setting.c b/src/northbridge/via/vx800/final_setting.c new file mode 100644 index 0000000000..165c887d8a --- /dev/null +++ b/src/northbridge/via/vx800/final_setting.c @@ -0,0 +1,129 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +static const u8 RefreshCounter[7][2] = { + //Non_256Mbit, 256Mbit + {0xCA, 0xA8}, // DRAM400 + {0xCA, 0xA8}, // DRAM333 + {0xCA, 0x86}, // DRAM266 + {0xCA, 0x65}, // DRAM200 + {0xA8, 0x54}, // DRAM166 + {0x86, 0x43}, // DRAM133 + {0x65, 0x32} // DRAM100 +}; + +void DRAMRefreshCounter(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 Freq = 5, i, Dram_256_Mb; + if (DramAttr->DramFreq == DIMMFREQ_800) + Freq = 0; + else if (DramAttr->DramFreq == DIMMFREQ_667) + Freq = 1; + else if (DramAttr->DramFreq == DIMMFREQ_533) + Freq = 2; + else if (DramAttr->DramFreq == DIMMFREQ_400) + Freq = 3; + else if (DramAttr->DramFreq == DIMMFREQ_333) + Freq = 4; + else if (DramAttr->DramFreq == DIMMFREQ_266) + Freq = 5; + else if (DramAttr->DramFreq == DIMMFREQ_200) + Freq = 6; + else + Freq = 6; + + Dram_256_Mb = 0; + for (i = 0; i < MAX_SOCKETS; i++) { + if (DramAttr->DimmInfo[i].SPDDataBuf[SPD_SDRAM_ROW_ADDR] == + 13) { + Dram_256_Mb = 1; + break; + } + } + + Data = RefreshCounter[Freq][Dram_256_Mb]; + + pci_write_config8(MEMCTRL, 0x6a, Data); +} + + +/*=================================================================== +Function : DRAMRegFinalValue() +Precondition : +Input : + DramAttr: pointer point to DRAM_SYS_ATTR which consist the DDR and Dimm information + in MotherBoard +Output : Void +Purpose : Chipset Performance UP and other setting after DRAM Sizing + Turn on register directly to promote performance +===================================================================*/ + +//-------------------------------------------------------------------------- +// register AND OR +//-------------------------------------------------------------------------- +#define DRAM_table_item 9 +static const u8 DRAM_table[DRAM_table_item][3] = { + {0x60, 0xff, 0xD0}, + {0x66, 0xcf, 0x80}, // DRAMC queue > 2 + {0x69, 0xff, 0x07}, // Enable multiple page + {0x95, 0x00, 0x0D}, + {0x96, 0x0F, 0xA0}, + {0xFB, 0x00, 0x3E}, + {0xFD, 0x00, 0xA9}, + {0xFE, 0x00, 0x0f}, + {0xFF, 0x00, 0x3D} +}; + +#define PM_table_item 5 +static const u8 PM_table[PM_table_item][3] = { + {0xA0, 0x0F, 0xF0}, + {0xA1, 0x1F, 0xE0}, + {0xA2, 0x00, 0xFE}, + {0xA3, 0x7F, 0x80}, + {0xA5, 0x7E, 0x81}, +}; + +void DRAMRegFinalValue(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 i; + + for (i = 0; i < DRAM_table_item; i++) { + Data = pci_read_config8(MEMCTRL, DRAM_table[i][0]); + Data = (u8) ((Data & DRAM_table[i][1]) | DRAM_table[i][2]); + pci_write_config8(MEMCTRL, DRAM_table[i][0], Data); + } + + //enable dram By-Rank self refresh + Data = pci_read_config8(MEMCTRL, 0x96); + Data &= 0xF0; + for (i = 0x01; i < 0x10; i = i << 1) { + if ((DramAttr->RankPresentMap & i) != 0x00) + Data |= i; + } + pci_write_config8(MEMCTRL, 0x96, Data); + + for (i = 0; i < PM_table_item; i++) { + Data = pci_read_config8(PCI_DEV(0, 0, 4), PM_table[i][0]); + Data = (u8) ((Data & PM_table[i][1]) | PM_table[i][2]); + pci_write_config8(PCI_DEV(0, 0, 4), PM_table[i][0], Data); + } + +} diff --git a/src/northbridge/via/vx800/freq_setting.c b/src/northbridge/via/vx800/freq_setting.c new file mode 100644 index 0000000000..ed4184ec77 --- /dev/null +++ b/src/northbridge/via/vx800/freq_setting.c @@ -0,0 +1,235 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +void CalcCLAndFreq(DRAM_SYS_ATTR * DramAttr); + +/* + Set DRAM Frequency +*/ +void DRAMFreqSetting(DRAM_SYS_ATTR * DramAttr) +{ + + u8 Data = 0; + + PRINT_DEBUG_MEM("Dram Frequency setting \r"); + + //calculate dram frequency using SPD data + CalcCLAndFreq(DramAttr); + + //init some Dramc control by Simon Chu slide + //Must use "CPU delay" to make sure VLINK is dis-connect + Data = pci_read_config8(PCI_DEV(0, 0, 7), 0x47); + Data = (u8) (Data | 0x04); + pci_write_config8(PCI_DEV(0, 0, 7), 0x47, Data); + + //in order to make sure NB command buffer don`t have pending request(C2P cycle) + //CPU DELAY + WaitMicroSec(20); + + //Before Set Dram Frequency, we must set 111 by Simon Chu slide. + Data = pci_read_config8(MEMCTRL, 0x90); + Data = (u8) ((Data & 0xf8) | 7); + pci_write_config8(MEMCTRL, 0x90, Data); + + WaitMicroSec(20); + + //Set Dram Frequency. + Data = pci_read_config8(MEMCTRL, 0x90); + switch (DramAttr->DramFreq) { + case DIMMFREQ_400: + Data = (u8) ((Data & 0xf8) | 3); + break; + case DIMMFREQ_533: + Data = (u8) ((Data & 0xf8) | 4); + break; + case DIMMFREQ_667: + Data = (u8) ((Data & 0xf8) | 5); + break; + case DIMMFREQ_800: + Data = (u8) ((Data & 0xf8) | 6); + break; + default: + Data = (u8) ((Data & 0xf8) | 1);; + } + pci_write_config8(MEMCTRL, 0x90, Data); + + //CPU Delay + WaitMicroSec(20); + + // Manual reset and adjust DLL when DRAM change frequency + Data = pci_read_config8(MEMCTRL, 0x6B); + Data = (u8) ((Data & 0x2f) | 0xC0); + pci_write_config8(MEMCTRL, 0x6B, Data); + + //CPU Delay + WaitMicroSec(20); + + Data = pci_read_config8(MEMCTRL, 0x6B); + Data = (u8) (Data | 0x10); + pci_write_config8(MEMCTRL, 0x6B, Data); + + //CPU Delay + WaitMicroSec(20); + + Data = pci_read_config8(MEMCTRL, 0x6B); + Data = (u8) (Data & 0x3f); + pci_write_config8(MEMCTRL, 0x6B, Data); + + //disable V_LINK Auto-Disconnect, or else program may stopped at some place and + //we cannot find the reason + Data = pci_read_config8(PCI_DEV(0, 0, 7), 0x47); + Data = (u8) (Data & 0xFB); + pci_write_config8(PCI_DEV(0, 0, 7), 0x47, Data); + +} + + +/* + calculate CL and dram freq + DDR1 + +---+---+---+---+---+---+---+---+ + | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 | + +---+---+---+---+---+---+---+---+ + |TBD| 4 |3.5| 3 |2.5| 2 |1.5| 1 | + +---+---+---+---+---+---+---+---+ + DDR2 + +---+---+---+---+---+---+---+---+ + | 7 | 6 | 5 | 4 | 3 | 2 | 1 | 0 | + +---+---+---+---+---+---+---+---+ + |TBD| 6 | 5 | 4 | 3 | 2 |TBD|TBD| + +---+---+---+---+---+---+---+---+ +*/ +static const u8 CL_DDR1[7] = { 10, 15, 20, 25, 30, 35, 40 }; +static const u8 CL_DDR2[7] = { 0, 0, 20, 30, 40, 50, 60 }; + +void CalcCLAndFreq(DRAM_SYS_ATTR * DramAttr) +{ + u8 AllDimmSupportedCL, Tmp; + u8 CLMask, tmpMask, IndexDelta; + u8 SckId, BitId, TmpId; + u16 CycTime, TmpCycTime; + + /*1.list the CL value that all DIMM supported */ + AllDimmSupportedCL = 0xFF; + if (RAMTYPE_SDRAMDDR2 == DramAttr->DramType) + AllDimmSupportedCL &= 0x7C; /*bit2,3,4,5,6 */ + else /*DDR1 */ + AllDimmSupportedCL &= 0x7F; /*bit0,1,2,3,4,5,6 */ + for (SckId = 0; SckId < MAX_SOCKETS; SckId++) { + if (DramAttr->DimmInfo[SckId].bPresence) { /*all DIMM supported CL */ + AllDimmSupportedCL &= + (DramAttr->DimmInfo[SckId]. + SPDDataBuf[SPD_SDRAM_CAS_LATENCY]); + } + } + if (!AllDimmSupportedCL) { /*if equal 0, no supported CL */ + PRINT_DEBUG_MEM("SPD Data Error, Can not get CL !!!! \r"); + for (;;); + } + + /*Get CL Value */ + CLMask = 0x40; /*from Bit6 */ + + for (BitId = 7; BitId > 0; BitId--) { + if ((AllDimmSupportedCL & CLMask) == CLMask) { /*find the first bit */ + if (RAMTYPE_SDRAMDDR2 == DramAttr->DramType) + DramAttr->CL = CL_DDR2[BitId - 1]; + else /*DDR1 */ + DramAttr->CL = CL_DDR1[BitId - 1]; + break; + } + CLMask >>= 1; + } + + /*according the CL value calculate the cycle time, for X or X-1 or X-2 */ + CycTime = 0; + TmpCycTime = 0; + + for (SckId = 0; SckId < MAX_SOCKETS; SckId++) { + if (DramAttr->DimmInfo[SckId].bPresence) { + Tmp = + (DramAttr->DimmInfo[SckId]. + SPDDataBuf[SPD_SDRAM_CAS_LATENCY]); + tmpMask = 0x40; + for (TmpId = 7; TmpId > 0; TmpId--) { + if ((Tmp & tmpMask) == tmpMask) + break; + tmpMask >>= 1; + } + if (TmpId - BitId == 0) { /*get Cycle time for X, SPD BYTE9 */ + TmpCycTime = + DramAttr->DimmInfo[SckId]. + SPDDataBuf[SPD_SDRAM_TCLK_X]; + } else if (TmpId - BitId == 1) { /*get Cycle time for X-1, SPD BYTE23 */ + TmpCycTime = + DramAttr->DimmInfo[SckId]. + SPDDataBuf[SPD_SDRAM_TCLK_X_1]; + } else if (TmpId - BitId == 2) { /*get cycle time for X-2, SPD BYTE25 */ + TmpCycTime = + DramAttr->DimmInfo[SckId]. + SPDDataBuf[SPD_SDRAM_TCLK_X_2]; + } else { + //error!!! + } + if (TmpCycTime > CycTime) /*get the most cycle time,there is some problem! */ + CycTime = TmpCycTime; + } + } + + if (CycTime <= 0) { + //error! + for (;;); + } + + /* cycle time value + 0x25-->2.5ns Freq=400 DDR800 + 0x30-->3.0ns Freq=333 DDR667 + 0x3D-->3.75ns Freq=266 DDR533 + 0x50-->5.0ns Freq=200 DDR400 + 0x60-->6.0ns Freq=166 DDR333 + 0x75-->7.5ns Freq=133 DDR266 + 0xA0-->10.0ns Freq=100 DDR200 + */ + if (CycTime <= 0x25) { + DramAttr->DramFreq = DIMMFREQ_800; + DramAttr->DramCyc = 250; + } else if (CycTime <= 0x30) { + DramAttr->DramFreq = DIMMFREQ_667; + DramAttr->DramCyc = 300; + } else if (CycTime <= 0x3d) { + DramAttr->DramFreq = DIMMFREQ_533; + DramAttr->DramCyc = 375; + } else if (CycTime <= 0x50) { + DramAttr->DramFreq = DIMMFREQ_400; + DramAttr->DramCyc = 500; + } else if (CycTime <= 0x60) { + DramAttr->DramFreq = DIMMFREQ_333; + DramAttr->DramCyc = 600; + } else if (CycTime <= 0x75) { + DramAttr->DramFreq = DIMMFREQ_266; + DramAttr->DramCyc = 750; + } else if (CycTime <= 0xA0) { + DramAttr->DramFreq = DIMMFREQ_200; + DramAttr->DramCyc = 1000; + } + //if set the frequence mannul + PRINT_DEBUG_MEM("Dram Frequency:"); + PRINT_DEBUG_MEM_HEX16(DramAttr->DramFreq); + PRINT_DEBUG_MEM(" \r"); +} diff --git a/src/northbridge/via/vx800/raminit.c b/src/northbridge/via/vx800/raminit.c index cd8cf2f3f8..8af9e74967 100644 --- a/src/northbridge/via/vx800/raminit.c +++ b/src/northbridge/via/vx800/raminit.c @@ -38,24 +38,24 @@ #define PRINT_DEBUG_MEM_HEX32(x) #define DUMPNORTH() #endif -#include "northbridge/via/vx800/ddr2init/translator_ddr2_init.c" -#include "northbridge/via/vx800/ddr2init/dram_init.h" +#include "northbridge/via/vx800/translator_ddr2_init.c" +#include "northbridge/via/vx800/dram_init.h" #include "northbridge/via/vx800/vx800_early_smbus.c" #include "northbridge/via/vx800/vx800_early_serial.c" -#include "northbridge/via/vx800/ddr2init/dram_util.h" -#include "northbridge/via/vx800/ddr2init/dram_util.c" -#include "northbridge/via/vx800/ddr2init/vx800/detection.c" -#include "northbridge/via/vx800/ddr2init/vx800/freq_setting.c" -#include "northbridge/via/vx800/ddr2init/vx800/timing_setting.c" -#include "northbridge/via/vx800/ddr2init/vx800/drdy_bl.c" -#include "northbridge/via/vx800/ddr2init/vx800/driving_setting.c" -#include "northbridge/via/vx800/ddr2init/vx800/clk_ctrl.c" -#include "northbridge/via/vx800/ddr2init/vx800/dev_init.c" -#include "northbridge/via/vx800/ddr2init/vx800/rank_map.c" -#include "northbridge/via/vx800/ddr2init/vx800/dqs_search.c" -#include "northbridge/via/vx800/ddr2init/vx800/final_setting.c" -#include "northbridge/via/vx800/ddr2init/vx800/uma_ram_setting.c" -#include "northbridge/via/vx800/ddr2init/dram_init.c" +#include "northbridge/via/vx800/dram_util.h" +#include "northbridge/via/vx800/dram_util.c" +#include "northbridge/via/vx800/detection.c" +#include "northbridge/via/vx800/freq_setting.c" +#include "northbridge/via/vx800/timing_setting.c" +#include "northbridge/via/vx800/drdy_bl.c" +#include "northbridge/via/vx800/driving_setting.c" +#include "northbridge/via/vx800/clk_ctrl.c" +#include "northbridge/via/vx800/dev_init.c" +#include "northbridge/via/vx800/rank_map.c" +#include "northbridge/via/vx800/dqs_search.c" +#include "northbridge/via/vx800/final_setting.c" +#include "northbridge/via/vx800/uma_ram_setting.c" +#include "northbridge/via/vx800/dram_init.c" /* * Support one dimm with up to 2 ranks */ diff --git a/src/northbridge/via/vx800/rank_map.c b/src/northbridge/via/vx800/rank_map.c new file mode 100644 index 0000000000..f86a3648d3 --- /dev/null +++ b/src/northbridge/via/vx800/rank_map.c @@ -0,0 +1,363 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +extern void DRAMSetVRNum(DRAM_SYS_ATTR * DramAttr, + u8 PhyRank, u8 VirRank, BOOLEAN Enable); + +extern void SetEndingAddr(DRAM_SYS_ATTR * DramAttr, u8 VirRank, // Ending address register number indicator (INDEX + INT8 Value); // (value) add or subtract value to this and after banks + + +void DRAMClearEndingAddress(DRAM_SYS_ATTR * DramAttr); + +void DRAMSizingEachRank(DRAM_SYS_ATTR * DramAttr); + +BOOLEAN DoDynamicSizing1XM(DRAM_SYS_ATTR * DramAttr, + u8 * nRA, u8 * nCA, u8 * nBS, u8 PhyRank); + +void DRAMSetRankMAType(DRAM_SYS_ATTR * DramAttr); + +void DRAMSetEndingAddress(DRAM_SYS_ATTR * DramAttr); + +void DRAMPRToVRMapping(DRAM_SYS_ATTR * DramAttr); + +/*=================================================================== +Function : DRAMBankInterleave() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void +Purpose : STEP 13 Set Bank Interleave VIANB3DRAMREG69[7:6] 00:No Interleave 01:2 Bank 10:4 Bank 11:8 Bank + Scan all DIMMs on board to find out the lowest Bank Interleave among these DIMMs and set register. +===================================================================*/ +void DRAMBankInterleave(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data, SpdBAData; + DIMM_INFO *CurrentDimminfo; + u8 Bank = 3, Shift, RankNO, Count; + Shift = 1; + for (RankNO = 0; RankNO < 4; RankNO += 2) //all_even 0 RankNO 4 6 + { + if ((DramAttr->RankPresentMap & Shift) != 0) { + CurrentDimminfo = &(DramAttr->DimmInfo[RankNO >> 1]); //this Rank in a dimm + SpdBAData = + (u8) (CurrentDimminfo-> + SPDDataBuf[SPD_SDRAM_NO_OF_BANKS]); + if (SpdBAData == 4) + Count = 2; + else if (SpdBAData == 8) + Count = 3; + else + Count = 0; + if (Count < Bank) + Bank = Count; + } + Shift <<= 2; + } + + Data = pci_read_config8(MEMCTRL, 0x69); + Data &= ~0xc0; + Data |= (Bank << 6); + pci_write_config8(MEMCTRL, 0x69, Data); + + + if (DramAttr->DimmNumChB > 0) { + CurrentDimminfo = &(DramAttr->DimmInfo[3]); //this Rank in a dimm + SpdBAData = + (u8) (CurrentDimminfo-> + SPDDataBuf[SPD_SDRAM_NO_OF_BANKS]); + if (SpdBAData == 4) + Bank = 2; + else if (SpdBAData == 2) + Bank = 1; + else + Bank = 0; + pci_write_config8(MEMCTRL, 0x87, Bank); + } +} + +/*=================================================================== +Function : DRAMSizingMATypeM() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void + Purpose : STEP 14 1 DRAM Sizing 2 Fill MA type 3 Prank to vrankMapping +===================================================================*/ +void DRAMSizingMATypeM(DRAM_SYS_ATTR * DramAttr) +{ + DRAMClearEndingAddress(DramAttr); + DRAMSizingEachRank(DramAttr); + //DRAMReInitDIMMBL (DramAttr); + DRAMSetRankMAType(DramAttr); + DRAMSetEndingAddress(DramAttr); + DRAMPRToVRMapping(DramAttr); +} + +/*=================================================================== +Function : DRAMClearEndingAddress() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void +Purpose : clear Ending and Start adress from 0x40-4f to zero +===================================================================*/ +void DRAMClearEndingAddress(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data, Reg; + Data = 0; + for (Reg = 0x40; Reg <= 0x4f; Reg++) { + pci_write_config8(MEMCTRL, Reg, Data); + } +} + +/*=================================================================== +Function : DRAMSizingEachRank() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void +Purpose : Sizing each Rank invidually, by number of rows column banks pins, be care about 128bit +===================================================================*/ +void DRAMSizingEachRank(DRAM_SYS_ATTR * DramAttr) +{ + u8 Slot, RankIndex, Rows, Columns, Banks; + u32 Size; + BOOLEAN HasThreeBitBA; + u8 Data; + u32 Address; + + HasThreeBitBA = FALSE; + for (Slot = 0; Slot < 2; Slot++) { + if (!DramAttr->DimmInfo[Slot].bPresence) + continue; + Rows = + DramAttr->DimmInfo[Slot]. + SPDDataBuf[SPD_SDRAM_ROW_ADDR]; + Columns = + DramAttr->DimmInfo[Slot]. + SPDDataBuf[SPD_SDRAM_COL_ADDR]; + Banks = DramAttr->DimmInfo[Slot].SPDDataBuf[SPD_SDRAM_NO_OF_BANKS]; //this is Bank number not Bank address bit + if (Banks == 4) + Banks = 2; + else if (Banks == 8) + Banks = 3; + else + Banks = 0; + Size = (u32) (1 << (Rows + Columns + Banks + 3)); + RankIndex = 2 * Slot; + DramAttr->RankSize[RankIndex] = Size; + //if this module have two ranks + if ((DramAttr->DimmInfo[Slot]. + SPDDataBuf[SPD_SDRAM_DIMM_RANKS] & 0x07) == 0x01) { + RankIndex++; + DramAttr->RankSize[RankIndex] = Size; + } + + PRINT_DEBUG_MEM("rows: "); + PRINT_DEBUG_MEM_HEX8(Rows); + PRINT_DEBUG_MEM(", columns:"); + PRINT_DEBUG_MEM_HEX8(Columns); + PRINT_DEBUG_MEM(", banks:"); + PRINT_DEBUG_MEM_HEX8(Banks); + PRINT_DEBUG_MEM("\r"); + + if (Banks == 3) + HasThreeBitBA = TRUE; + } + + //must set BA2 enable if any 8-bank device exists + if (HasThreeBitBA) { + Data = pci_read_config8(MEMCTRL, 0x53); + Data |= 0x80; + pci_write_config8(MEMCTRL, 0x53, Data); + } +#if 1 + for (RankIndex = 0; DramAttr->RankSize[RankIndex] != 0; + RankIndex++) { + PRINT_DEBUG_MEM("Rank:"); + PRINT_DEBUG_MEM_HEX8(RankIndex); + PRINT_DEBUG_MEM(", Size:"); + PRINT_DEBUG_MEM_HEX32(DramAttr->RankSize[RankIndex] >> 20); + PRINT_DEBUG_MEM("\r"); + } +#endif +} + +/*=================================================================== +Function : DRAMSetRankMAType() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void +Purpose : set the matype Reg by MAMapTypeTbl, which the rule can be found in memoryinit +===================================================================*/ +void DRAMSetRankMAType(DRAM_SYS_ATTR * DramAttr) +{ + u8 SlotNum, Data, j, Reg, or, and; + u8 ShiftBits[] = { 5, 1, 5, 1 }; /* Rank 0/1 MA Map Type is 7:5, Rank 2/3 MA Map Type is 3:1. See Fun3Rx50. */ + u8 MAMapTypeTbl[] = { /* Table 12 of P4M800 Pro DataSheet. */ + 2, 9, 0, /* Bank Address Bits, Column Address Bits, Rank MA Map Type */ + 2, 10, 1, + 2, 11, 2, + 2, 12, 3, + 3, 10, 5, + 3, 11, 6, + 3, 12, 7, + 0, 0, 0 + }; + Data = pci_read_config8(MEMCTRL, 0x50); + Data &= 0x1; + pci_write_config8(MEMCTRL, 0x50, Data); + // disable MA32/16 MA33/17 swap in memory init it has this Reg fill + Data = pci_read_config8(MEMCTRL, 0x6b); + Data &= ~0x08; + pci_write_config8(MEMCTRL, 0x6b, Data); + + Data = 0x00; + for (SlotNum = 0; SlotNum < MAX_DIMMS; SlotNum++) { + if (DramAttr->DimmInfo[SlotNum].bPresence) { + for (j = 0; MAMapTypeTbl[j] != 0; j += 3) { + if ((1 << MAMapTypeTbl[j]) == + DramAttr->DimmInfo[SlotNum]. + SPDDataBuf[SPD_SDRAM_NO_OF_BANKS] + && MAMapTypeTbl[j + 1] == + DramAttr->DimmInfo[SlotNum]. + SPDDataBuf[SPD_SDRAM_COL_ADDR]) { + break; + } + } + if (0 == MAMapTypeTbl[j]) { + PRINT_DEBUG_MEM + ("UNSUPPORTED Bank, Row and Column Addr Bits!\r"); + return; + } + or = MAMapTypeTbl[j + 2] << ShiftBits[SlotNum]; + if (DramAttr->CmdRate == 1) + or |= 0x01 << (ShiftBits[SlotNum] - 1); + + Reg = SlotNum / 2; + if ((SlotNum & 0x01) == 0x01) { + and = 0xf1; // BUGBUG: it should be 0xf0 + } else { + and = 0x1f; // BUGBUG: it should be 0x0f + } + Data = pci_read_config8(MEMCTRL, 0x50 + Reg); + Data &= and; + Data |= or; + pci_write_config8(MEMCTRL, 0x50 + Reg, Data); + } + } + //may have some Reg filling at add 3-52 11 and 3-53 in his function +} + +/*=================================================================== +Function : DRAMSetEndingAddress() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void +Purpose : realize the Vrank 40...Reg (Start and Ending Regs). Vrank have same order with phy Rank, Size is actual Size +===================================================================*/ +void DRAMSetEndingAddress(DRAM_SYS_ATTR * DramAttr) +{ + u8 Shift = 1, Data, RankNO, Size, Start = 0, End = 0, Vrank; + for (RankNO = 0; RankNO < 4; RankNO++) { + if ((DramAttr->RankPresentMap & Shift) != 0) { + Size = (u8) (DramAttr->RankSize[RankNO] >> 26); // current Size in the unit of 64M + if (Size != 0) { + + End = End + Size; // calculate current ending address, add the current Size to ending + Vrank = RankNO; // get virtual Rank + Data = End; // set begin/End address register to correspondig virtual Rank # + pci_write_config8(MEMCTRL, 0x40 + Vrank, + Data); + Data = Start; + pci_write_config8(MEMCTRL, 0x48 + Vrank, + Data); + PRINT_DEBUG_MEM("Rank: "); + PRINT_DEBUG_MEM_HEX8(Vrank); + PRINT_DEBUG_MEM(", Start:"); + PRINT_DEBUG_MEM_HEX8(Start); + PRINT_DEBUG_MEM(", End:"); + PRINT_DEBUG_MEM_HEX8(End); + PRINT_DEBUG_MEM("\r"); + + Start = End; + } + } + Shift <<= 1; + } + + if (DramAttr->RankNumChB > 0) { + //this is a bug,fixed is to 2,so the max LL size is 128M + Data = 0x02; + pci_write_config8(MEMCTRL, 0x44, Data); + } + Data = End * 4; + pci_write_config8(PCI_DEV(0, 17, 7), 0x60, Data); + // We should directly write to south Bridge, not in north bridge + // program LOW TOP Address + Data = pci_read_config8(MEMCTRL, 0x88); + pci_write_config8(MEMCTRL, 0x85, Data); + + // also program vlink mirror + // We should directly write to south Bridge, not in north bridge + pci_write_config8(PCI_DEV(0, 17, 7), 0xe5, Data); +} + +/*=================================================================== +Function : DRAMPRToVRMapping() +Precondition : +Input : + DramAttr: pointer point to DRAMSYSATTR which consist the DDR and Dimm information in MotherBoard +Output : Void +Purpose : set the Vrank-prank map with the same order +===================================================================*/ +void DRAMPRToVRMapping(DRAM_SYS_ATTR * DramAttr) +{ + u8 Shift, Data, and, or, DimmNO = 0, PhyRankNO, Reg; + + for (Reg = 0x54; Reg <= 0x57; Reg++) //clear the map-reg + { + Data = 0; + pci_write_config8(MEMCTRL, Reg, Data); + } + + Shift = 1; + for (PhyRankNO = 0; PhyRankNO < MAX_RANKS; PhyRankNO++) { + if ((DramAttr->RankPresentMap & Shift) != 0) { + or = PhyRankNO; // get virtual Rank ,same with PhyRank + or |= 0x08; + + if ((PhyRankNO & 0x01) == 0x01) // get mask for register + and = 0xf0; + else { + and = 0x0f; + or <<= 4; + } + DimmNO = (PhyRankNO >> 1); + Data = pci_read_config8(MEMCTRL, 0x54 + DimmNO); + Data &= and; + Data |= or; + pci_write_config8(MEMCTRL, 0x54 + DimmNO, Data); + } + Shift <<= 1; + } +} diff --git a/src/northbridge/via/vx800/timing_setting.c b/src/northbridge/via/vx800/timing_setting.c new file mode 100644 index 0000000000..5e1847800a --- /dev/null +++ b/src/northbridge/via/vx800/timing_setting.c @@ -0,0 +1,492 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + + /* + Set Dram Timing functions + */ + +void SetCL(DRAM_SYS_ATTR * DramAttr); + +void SetTrp(DRAM_SYS_ATTR * DramAttr); + +void SetTrcd(DRAM_SYS_ATTR * DramAttr); + +void SetTras(DRAM_SYS_ATTR * DramAttr); + +void SetTrfc(DRAM_SYS_ATTR * DramAttr); + +void SetTrrd(DRAM_SYS_ATTR * DramAttr); + +void SetTwr(DRAM_SYS_ATTR * DramAttr); + +void SetTwtr(DRAM_SYS_ATTR * DramAttr); + +void SetTrtp(DRAM_SYS_ATTR * DramAttr); + +/* Set DRAM Timing*/ +void DRAMTimingSetting(DRAM_SYS_ATTR * DramAttr) +{ + PRINT_DEBUG_MEM("Set CAS latency value!"); + SetCL(DramAttr); + + PRINT_DEBUG_MEM("Set tRP value!"); + SetTrp(DramAttr); + + PRINT_DEBUG_MEM("Set tRCD value!"); + SetTrcd(DramAttr); + + PRINT_DEBUG_MEM("Set tRAS value!"); + SetTras(DramAttr); + + PRINT_DEBUG_MEM("Set tRFC value!"); + SetTrfc(DramAttr); + + PRINT_DEBUG_MEM("Set tRRD value!"); + SetTrrd(DramAttr); + + PRINT_DEBUG_MEM("Set tWR value!"); + SetTwr(DramAttr); + + PRINT_DEBUG_MEM("Set tWTR value!"); + SetTwtr(DramAttr); + + PRINT_DEBUG_MEM("Set tRTP value!"); + SetTrtp(DramAttr); +} + + +/* +Set DRAM Timing: CAS Latency for DDR1 +D0F3RX62 bit[0:2] for CAS Latency; +*/ +void SetCL(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u8 CL; + + /*DDR2 CL Value: 20, 30, 40, 50 -> 2, 3, 4, 5 */ + CL = (u8) ((DramAttr->CL - 20) / 10); //000,001,010,011 + + PRINT_DEBUG_MEM("CAS = "); + PRINT_DEBUG_MEM_HEX8(CL); + PRINT_DEBUG_MEM("\n"); + Data = pci_read_config8(MEMCTRL, 0x62); + Data = (u8) ((Data & 0xf8) | CL); + pci_write_config8(MEMCTRL, 0x62, Data); +} + + +/* + Minimum row precharge time, Trp for DDR1/DDR2 + D0F3Rx64[3:2] for Trp 2T~5T +*/ +#define MAX_TRP 6 +#define MIN_TRP 2 + +void SetTrp(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + + /*get the max Trp value from SPD data + SPD Byte27, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRP]); + if (Tmp > Max) + Max = Tmp; + } + /*Calculate clock,this value should be 2T,3T,4T,5T */ + } + Tmp = + (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - + 1) / ((DramAttr->DramCyc) << 2)); + PRINT_DEBUG_MEM("Trp = "); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + if (Tmp > MAX_TRP) + Tmp = MAX_TRP; + else if (Tmp < MIN_TRP) + Tmp = MIN_TRP; + + Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T + Tmp <<= 1; //bit1,2,3 + + Data = pci_read_config8(MEMCTRL, 0x64); + Data = (u8) ((Data & 0xf1) | (u8) Tmp); + pci_write_config8(MEMCTRL, 0x64, Data); + + //enable DDR2 8-Bank Device Timing Constraint + Data = pci_read_config8(MEMCTRL, 0x62); + Data = (u8) ((Data & 0xf7) | 0x08); + pci_write_config8(MEMCTRL, 0x62, Data); +} + + +/* +Minimum RAS to CAS dely,Trcd for DDR1/DDR2 +D0F3Rx64[7:6] for Trcd +*/ +#define MAX_TRCD 6 +#define MIN_TRCD 2 + +void SetTrcd(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + + /*get the max Trcd value from SPD data + SPD Byte29, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRCD]); + if (Tmp > Max) + Max = Tmp; + } + } + /*Calculate clock,this value should be 2T,3T,4T,5T */ + Tmp = + (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - + 1) / ((DramAttr->DramCyc) << 2)); + PRINT_DEBUG_MEM("Trcd ="); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + if (Tmp > MAX_TRCD) + Tmp = MAX_TRCD; + else if (Tmp < MIN_TRCD) + Tmp = MIN_TRCD; + Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T + Tmp <<= 5; //bit5,6,7 + + Data = pci_read_config8(MEMCTRL, 0x64); + Data = (u8) ((Data & 0x1f) | (u8) Tmp); + pci_write_config8(MEMCTRL, 0x64, Data); + +} + +/* + minimum active to precharge time,Tras for DDR1/DDR2 + D0F3Rx62[7:4] Tras +*/ +#define MAX_TRAS 20 //20T +#define MIN_TRAS 5 //5T +void SetTras(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + + /*get the max Tras value from SPD data + SPD byte30: bit0:7 1ns~255ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRAS]); + if (Tmp > Max) + Max = Tmp; + } + } + + /*Calculate clock,value range 5T-20T */ + Tmp = + (u16) ((Max * 100 + DramAttr->DramCyc - + 1) / (DramAttr->DramCyc)); + PRINT_DEBUG_MEM("Tras ="); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + if (Tmp > MAX_TRAS) + Tmp = MAX_TRAS; + else if (Tmp < MIN_TRAS) + Tmp = MIN_TRAS; + Tmp -= 5; //0->5T ... 1111->20T + Tmp <<= 4; //bit4:7 + + Data = pci_read_config8(MEMCTRL, 0x62); + Data = (u8) ((Data & 0x0f) | (u8) Tmp); + pci_write_config8(MEMCTRL, 0x62, Data); +} + +/* +Minimum refresh to activate/refresh command period Trfc for DDR1/DDR2 +D0F3Rx61[5:0] for Trfc +*/ + +#define MAX_TRFC 71 // Max supported,71T +#define MIN_TRFC 8 // Min supported,8T + +void SetTrfc(DRAM_SYS_ATTR * DramAttr) +{ + + u8 Data; + u32 Max, Tmp; + u8 Byte40; + u8 Socket; + + /*get the max Trfc value from SPD data */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u32) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRFC]) * 100; + /*only DDR2 need to add byte 40 bit[7:4] */ + Byte40 = + (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRFC2]); + /*if bit0 = 1, byte42(RFC)+256ns, SPD spec JEDEC standard No.21.c */ + if (Byte40 & 0x01) + Tmp += (256 * 100); + /*bit1,2,3 000->0ns+byte42; 001->0.25ns+byte42; 010->0.33ns+byte42; 011->0.5ns+byte42;100-> 0.75ns+byte42 */ + switch ((Byte40 >> 1) & 0x07) { /*bit1,2,3 */ + case 1: + Tmp += 25; + break; + case 2: + Tmp += 33; + break; + case 3: + Tmp += 50; + break; + case 4: + Tmp += 66; + break; + case 5: + Tmp += 75; + break; + case 6: //what is FRU??? + default: + break; + } + if (Tmp > Max) + Max = Tmp; + } + } + + /*Calculate clock,value range 8T-71T */ + Tmp = (u16) ((Max + DramAttr->DramCyc - 1) / (DramAttr->DramCyc)); + PRINT_DEBUG_MEM("Trfc = "); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + if (Tmp > MAX_TRFC) + Tmp = MAX_TRFC; + else if (Tmp < MIN_TRFC) { + // return; + Tmp = 0x40; + } + /*D0F3Rx61 bit[0:5] 0->8T ... 63->71T */ + Tmp -= 8; + + Data = pci_read_config8(MEMCTRL, 0x61); + Data = (u8) ((Data & 0xc0) | ((u8) Tmp & 0x3f)); + pci_write_config8(MEMCTRL, 0x61, Data); +} + + +/* +Minimum row active to row active delay: Trrd for DDR1/DDR2 +D0F3Rx61[7:6]:Trrd 00->2T, 01->3T, 10->4T, 11->5T +*/ +#define MAX_TRRD 5 +#define MIN_TRRD 2 + +void SetTrrd(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + + /*get the max Trrd value from SPD data + SPD Byte28, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRRD]); + if (Tmp > Max) + Max = Tmp; + } + } + + /*Calculate clock,this value should be 2T,3T,4T,5T */ + Tmp = + (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - + 1) / ((DramAttr->DramCyc) << 2)); + PRINT_DEBUG_MEM("Trrd ="); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + if (Tmp > MAX_TRRD) + Tmp = MAX_TRRD; + else if (Tmp < MIN_TRRD) + Tmp = MIN_TRRD; + Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T + Tmp <<= 6; + + Data = pci_read_config8(MEMCTRL, 0x61); + Data = (u8) ((Data & 0x3f) | (u8) Tmp); + pci_write_config8(MEMCTRL, 0x61, Data); +} + + +/* +Write recovery time: Twr for DDR1/DDR2 +Device 0 Function 3:REG63[7:5]:Twr 00->2T 01->3T 10->4T 11->5T +*/ +#define MAX_TWR 6 +#define MIN_TWR 2 + +void SetTwr(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + /*get the max Trtp value from SPD data + SPD Byte36, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TWR]); + if (Tmp > Max) + Max = Tmp; + } + } + /*Calculate clock */ + Tmp = (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - 1) / ((DramAttr->DramCyc) << 2)); //this value should be 2T,3T,4T,5T + PRINT_DEBUG_MEM("Twr = "); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + if (Tmp > MAX_TWR) + Tmp = MAX_TWR; + else if (Tmp < MIN_TWR) + Tmp = MIN_TWR; + Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T + Tmp <<= 5; + + Data = pci_read_config8(MEMCTRL, 0x63); + Data = (u8) ((Data & 0x1f) | (u8) Tmp); + pci_write_config8(MEMCTRL, 0x63, Data); +} + + +/* +Internal write to read command delay: Twtr for DDR1/DDR2 +Device 0 Function 3:REG63[1,0]:Twtr DDR: 1T or 2T; DDR2 2T or 3T +*/ +#define MAX_TWTR 5 //5T +#define MIN_TWTR 2 //2T + +void SetTwtr(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + /*get the max Trtp value from SPD data + SPD Byte37, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TWTR]); + if (Tmp > Max) + Max = Tmp; + } + } + /*Calculate clock */ + Tmp = (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - 1) / ((DramAttr->DramCyc) << 2)); //this value should be 2T or 3T + + PRINT_DEBUG_MEM("Twtr ="); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + if (Tmp > MAX_TWR) + Tmp = MAX_TWTR; + else if (Tmp < MIN_TWR) + Tmp = MIN_TWTR; + Tmp -= 2; //00->2T, 01->3T, 10->4T, 11->5T + Data = pci_read_config8(MEMCTRL, 0x63); + Data = (u8) ((Data & 0xFC) | Tmp); + pci_write_config8(MEMCTRL, 0x63, Data); +} + + +/* +Internal read to precharge command delay, Trtp for DDR1/DDR2 +Device 0 Function 3:REG63[3]:Trtp 2T or 3T +*/ +#define MAX_TRTP 3 //3T +#define MIN_TRTP 2 //2T + +void SetTrtp(DRAM_SYS_ATTR * DramAttr) +{ + u8 Data; + u16 Max, Tmp; + u8 Socket; + + + /*get the max Trtp value from SPD data + SPD Byte38, Bit7:2->1ns~63ns, Bit1:0->0ns, 0.25ns, 0.50ns, 0.75ns */ + Max = 0; + for (Socket = 0; Socket < MAX_SOCKETS; Socket++) { + if (DramAttr->DimmInfo[Socket].bPresence) { + Tmp = + (u16) (DramAttr->DimmInfo[Socket]. + SPDDataBuf[SPD_SDRAM_TRTP]); + if (Tmp > Max) + Max = Tmp; + } + } + /*Calculate clock */ + Tmp = (u16) ((Max * 100 + ((DramAttr->DramCyc) << 2) - 1) / ((DramAttr->DramCyc) << 2)); //this value should be 2T or 3T + + PRINT_DEBUG_MEM("Trtp ="); + PRINT_DEBUG_MEM_HEX16(Tmp); + PRINT_DEBUG_MEM("\r"); + + Data = pci_read_config8(MEMCTRL, 0x63); + if (Tmp > MIN_TRTP) + Data = (u8) (Data | 0x08); /*set bit3, set 3T */ + else + Data = (u8) (Data & 0xf7); /*clear bit3, set 2T */ + + pci_write_config8(MEMCTRL, 0x63, Data); +} diff --git a/src/northbridge/via/vx800/translator_ddr2_init.c b/src/northbridge/via/vx800/translator_ddr2_init.c new file mode 100644 index 0000000000..cb54aba1af --- /dev/null +++ b/src/northbridge/via/vx800/translator_ddr2_init.c @@ -0,0 +1,34 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +#define CB_SUCCESS 0x0 +#define CB_INVALID_PARAMETER 0x2 +#define CB_NOT_READY 0x6 +#define CB_DEVICE_ERROR 0x7 +#define TRUE 1 +#define FALSE 0 + + +typedef int8_t INT8; +typedef unsigned long uintn_t; +typedef uintn_t UINTN; +typedef long intn_t; +typedef intn_t INTN; +typedef UINTN CB_STATUS; +typedef uint8_t BOOLEAN; diff --git a/src/northbridge/via/vx800/uma_ram_setting.c b/src/northbridge/via/vx800/uma_ram_setting.c new file mode 100644 index 0000000000..f8aaf74eef --- /dev/null +++ b/src/northbridge/via/vx800/uma_ram_setting.c @@ -0,0 +1,445 @@ +/* + * This file is part of the coreboot project. + * + * Copyright (C) 2009 One Laptop per Child, Association, Inc. + * + * This program is free software; you can redistribute it and/or modify + * it under the terms of the GNU General Public License as published by + * the Free Software Foundation; version 2 of the License. + * + * This program is distributed in the hope that it will be useful, + * but WITHOUT ANY WARRANTY; without even the implied warranty of + * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the + * GNU General Public License for more details. + * + * You should have received a copy of the GNU General Public License + * along with this program; if not, write to the Free Software + * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA + */ + +typedef struct __UMA_RAM_tag { + u16 DramSize; + u8 D0F3Val; + u8 D1F0Val; + u8 VgaPortVal; +} UMARAM; +#define UMARAM_512M 7 +#define UMARAM_256M 6 +#define UMARAM_128M 5 +#define UMARAM_64M 4 +#define UMARAM_32M 3 +#define UMARAM_16M 2 +#define UMARAM_8M 1 +#define UMARAM_0M 0 + + +#define FB_512M 0 +#define FB_256M 0x40 +#define FB_128M 0x60 +#define FB_64M 0x70 +#define FB_32M 0x78 +#define FB_16M 0x7c +#define FB_8M 0x7E +#define FB_4M 0x7F + +#define VGA_PORT_512M 0x00 +#define VGA_PORT_256M 0x80 +#define VGA_PORT_128M 0xC0 +#define VGA_PORT_64M 0xE0 +#define VGA_PORT_32M 0xF0 +#define VGA_PORT_16M 0xF8 + +static const UMARAM UMARamArr[] = { + {0, UMARAM_0M, FB_4M, 0xFE}, + {8, UMARAM_8M, FB_8M, 0xFC}, + {16, UMARAM_16M, FB_16M, VGA_PORT_16M}, + {32, UMARAM_32M, FB_32M, VGA_PORT_32M}, + {64, UMARAM_64M, FB_64M, VGA_PORT_64M}, + {128, UMARAM_128M, FB_128M, VGA_PORT_128M}, + {256, UMARAM_256M, FB_256M, VGA_PORT_256M}, + {512, UMARAM_512M, FB_512M, VGA_PORT_512M}, + {0xffff, 0xff, 0xff, 0xFF} +}; + +void SetUMARam(void) +{ +#if 1 + u8 ramregs[] = { 0x43, 0x42, 0x41, 0x40 }; + device_t vga_dev = PCI_DEV(0, 1, 0), d0f0_dev = PCI_DEV(0, 0, 0); + u8 ByteVal, temp; + UMARAM *pUMARamTable; + u16 UmaSize; + u8 SLD0F3Val, SLD1F0Val, VgaPortVal; + u32 RamSize, SLBase, Tmp; + u8 i; + PRINT_DEBUG_MEM("Entering vx800 SetUMARam.\n"); + SLD0F3Val = 0; + SLD1F0Val = 0; + VgaPortVal = 0; + + + ByteVal = pci_read_config8(MEMCTRL, 0xa1); + ByteVal |= 0x80; + pci_write_config8(MEMCTRL, 0xa1, ByteVal); + + //set VGA Timer + pci_write_config8(MEMCTRL, 0xa2, 0xee); + + //set agp misc + //GFX Data Delay to Sync with Clock + pci_write_config8(MEMCTRL, 0xa4, 0x01); + + //page register life timer + pci_write_config8(MEMCTRL, 0xa6, 0x76); + + //GMINT and GFX relatate + //note Bit 3 VGA Enable + pci_write_config8(MEMCTRL, 0xa7, 0x8c); + // ByteVal = 0x4c; + + //GMINT Misc.1 + //pci_write_config8(MEMCTRL, 0xb0, 0x80); + + //pci_write_config8(MEMCTRL, 0xb1, 0xaa); + + //AGPCINT MISC + //pci_write_config8(MEMCTRL, 0xb2, 0x82); + //ByteVal = 0x8A; + + //GMINT MISC.2 + //disable read pass write + pci_write_config8(MEMCTRL, 0xb3, 0x9A); + + //EPLL Register + //pci_write_config8(MEMCTRL, 0xb4, 0x04); + + //enable CHA and CHB merge mode + pci_write_config8(MEMCTRL, 0xde, 0x06); + + //if can get the value from setup interface, so get the value + //else use the default value + UmaSize = CONFIG_VIDEO_MB; + + for (pUMARamTable = UMARamArr; pUMARamTable->DramSize != 0xffff; + pUMARamTable++) { + if (UmaSize == pUMARamTable->DramSize) { + SLD0F3Val = pUMARamTable->D0F3Val; + SLD1F0Val = pUMARamTable->D1F0Val; + VgaPortVal = pUMARamTable->VgaPortVal; + } + } + //set SL size + //Fill in Fun3_RXA1[6:4] with the Frame Buffer size for the Integrated Graphic Device. + ByteVal = pci_read_config8(MEMCTRL, 0xa1); + ByteVal = (ByteVal & 0x8f) | (SLD0F3Val << 4); + pci_write_config8(MEMCTRL, 0xa1, ByteVal); + + +// vga_dev = dev_find_device(PCI_VENDOR_ID_VIA, PCI_DEVICE_ID_VIA_VX855_VGA, 0); + + //RxB2 may be for S.L. and RxB1 may be for L. L. + // It is different from Spec. + ByteVal = SLD1F0Val; + pci_write_config8(vga_dev, 0xb2, ByteVal); + + + //set M1 size + //ByteVal=pci_read_config8(MEMCTRL, 0xa3); + //ByteVal = 0x02; + //pci_write_config8(MEMCTRL, 0xa3, ByteVal); + + PRINT_DEBUG_MEM("UMA setting - 3\n"); + + + + + //Enable p2p IO/mem + ByteVal = 0x07; + pci_write_config8(vga_dev, 0x04, ByteVal); + + + + + //must set SL and MMIO base, or else when enable GFX memory space, system will hang + //set S.L base + Tmp = pci_read_config32(vga_dev, 0x10); + Tmp = 0xfffffff8; + pci_write_config32(vga_dev, 0x10, Tmp); + Tmp = pci_read_config32(vga_dev, 0x10); + Tmp = VIACONFIG_VGA_PCI_10; + pci_write_config32(vga_dev, 0x10, Tmp); + + //set MMIO base + Tmp = pci_read_config32(vga_dev, 0x14); + Tmp = 0xfffffffC; + pci_write_config32(vga_dev, 0x14, Tmp); + Tmp = pci_read_config32(vga_dev, 0x14); + Tmp = VIACONFIG_VGA_PCI_14; + pci_write_config32(vga_dev, 0x14, Tmp); + + +//enable direct cpu frame buffer access + i = pci_rawread_config8(PCI_RAWDEV(0, 0, 3), 0xa1); + i = (i & 0xf0) | (VIACONFIG_VGA_PCI_10 >> 28); + pci_rawwrite_config8(PCI_RAWDEV(0, 0, 3), 0xa1, i); + pci_rawwrite_config8(PCI_RAWDEV(0, 0, 3), 0xa0, 0x01); + + + //enable GFx memory space access control for S.L and mmio + ByteVal = pci_read_config8(d0f0_dev, 0xD4); + ByteVal |= 0x03; + //ByteVal |= 0x01; + pci_write_config8(d0f0_dev, 0xD4, ByteVal); + + + //enable Base VGA 16 Bits Decode + ByteVal = pci_read_config8(d0f0_dev, 0xfe); + ByteVal |= 0x10; + pci_write_config8(d0f0_dev, 0xfe, ByteVal); + + + //disable CHB L.L + //set VGA memory selection + ByteVal = pci_read_config8(vga_dev, 0xb0); + ByteVal &= 0xF8; + //ByteVal |= 0x01; + ByteVal |= 0x03; + pci_write_config8(vga_dev, 0xb0, ByteVal); + + //set LL size + + //enable memory access to SL,MMIO,LL and IO to 3B0~3BB,3C0 ~3DF + //ByteVal = 0x03; + //pci_write_config8(d0f0_dev, 0xc0, ByteVal); + + //Turn on Graphic chip IO port port access + ByteVal = inb(0x03C3); + ByteVal |= 0x01; + outb(ByteVal, 0x03C3); + + //Turn off Graphic chip Register protection + outb(0x10, 0x03C4); + + ByteVal = inb(0x03C5); + ByteVal |= 0x01; + outb(ByteVal, 0x03C5); + + //set VGA memory Frequence + //direct IO port 0x3DX to vga io space 0x3C2[0] + ByteVal = inb(0x03CC); + ByteVal |= 0x03; + outb(ByteVal, 0x03C2); + // ByteVal=inb(0x03C2); + // ByteVal |= 0x01; + // outb(ByteVal,0x03C2); + + +#if 1 //bios porting guide has no this two defination: 3d on 3d4/3d5 and 39 on 3c4/3c5 + //set frequence 0x3D5.3d[7:4] + outb(0x3d, 0x03d4); + + temp = pci_read_config8(MEMCTRL, 0x90); + temp = (u8) (temp & 0x07); + ByteVal = inb(0x03d5); + switch (temp) { + case 0: //DIMMFREQ_200: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x30); + break; + case 1: //DIMMFREQ_266: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x40); + break; + case 3: //DIMMFREQ_400: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x60); + break; + case 4: //DIMMFREQ_533: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x70); + break; + case 5: //DIMMFREQ_667: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x80); + break; + case 6: //DIMMFREQ_800: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x90); + break; + default: + ByteVal = (u8) ((ByteVal & 0x0F) | 0x70); + break; + } + outb(ByteVal, 0x03d5); + + // Set frame buffer size + outb(0x39, 0x03c4); + outb(1 << SLD0F3Val, 0x03c5); + +#endif + // Set S.L. size in GFX's register + outb(0x68, 0x03c4); + outb(VgaPortVal, 0x03c5); + + // ECLK Selection (00:166Mhz, 01:185Mhz, 10:250Mhz, 11:275Mhz) + // set 3C5.5A[0]=1, address maps to secondary resgiters + outb(0x5a, 0x03c4); + ByteVal = inb(0x03c5); + ByteVal |= 0x01; + outb(ByteVal, 0x03c5); + + // Set 3D5.4C[7:6] (00:166Mhz, 01:185Mhz, 10:250Mhz, 11:275Mhz) + outb(0x4c, 0x03d4); + ByteVal = inb(0x03d5); + ByteVal = (ByteVal & 0x3F) | 0x80; + outb(ByteVal, 0x03d5); + + // set 3C5.5A[0]=0, address maps to first resgiters + outb(0x5a, 0x03c4); + ByteVal = inb(0x03c5); + ByteVal &= 0xFE; + outb(ByteVal, 0x03c5); + + // Set S.L. Address in System Memory + //calculate dram size + for (RamSize = 0, i = 0; i < ARRAY_SIZE(ramregs); i++) { + RamSize = pci_read_config8(MEMCTRL, ramregs[i]); + if (RamSize != 0) + break; + } + //calculate SL Base Address + SLBase = (RamSize << 26) - (UmaSize << 20); + + + outb(0x6D, 0x03c4); + //SL Base[28:21] + outb((u8) ((SLBase >> 21) & 0xFF), 0x03c5); + + outb(0x6e, 0x03c4); + //SL Base[36:29] + outb((u8) ((SLBase >> 29) & 0xFF), 0x03c5); + + outb(0x6f, 0x03c4); + outb(0x00, 0x03c5); + + // Set SVID high byte + outb(0x36, 0x03c4); + outb(0x11, 0x03c5); + + // Set SVID Low byte + outb(0x35, 0x03c4); + outb(0x06, 0x03c5); + + // Set SID high byte + outb(0x38, 0x03c4); + outb(0x51, 0x03c5); + + // Set SID Low byte + outb(0x37, 0x03c4); + outb(0x22, 0x03c5); + + //start : For enable snapshot mode control + // program 3C5 for SNAPSHOT Mode control, set RxF3h=1Ah + outb(0xf3, 0x03c4); + ByteVal = inb(0x03c5); + ByteVal = (ByteVal & 0xE5) | 0x1A; + outb(ByteVal, 0x03c5); + + + outb(0xf3, 0x03d4); + ByteVal = inb(0x03d5); + ByteVal = (ByteVal & 0xE5) | 0x1A; + outb(ByteVal, 0x03d5); + + u8 table3c43c5[0x70] = { + 0x03, 0x01, 0x0F, 0x00, 0x06, 0x00, 0x00, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x01, 0x78, 0x00, 0x00, 0x00, 0xBE, 0x20, 0x7F, + 0x60, 0x7F, 0x08, 0x31, 0xCC, 0x00, 0x01, 0x00, + 0x00, 0x18, 0x10, 0x00, 0x00, 0x00, 0x3D, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x04, 0xF3, 0xFF, 0xFC, + 0xF8, 0x0C, 0x00, 0x00, 0x40, 0x06, 0x11, 0x22, + 0x51, 0x10, 0x00, 0x01, 0x19, 0x0C, 0x00, 0xFF, + 0x38, 0x40, 0x30, 0xFF, 0x70, 0x8C, 0x85, 0x9D, + 0x80, 0x05, 0x54, 0x90, 0x03, 0x30, 0x00, 0x5F, + 0x1F, 0x00, 0x00, 0xFF, 0x00, 0x00, 0xFF, 0x00, + 0x06, 0xDF, 0x00, 0x20, 0x20, 0x00, 0x00, 0x00, + 0x00, 0x00, 0x00, 0x40, 0x20, 0x00, 0x20, 0x20, + 0xE0, 0x20, 0xD0, 0x3F, 0x00, 0xE0, 0x00, 0x00 + }; + u8 table3d43d5[0x88] = { + 0x7F, 0x63, 0x63, 0x83, 0x69, 0x19, 0x72, 0xE0, + 0x00, 0x60, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x58, 0x9C, 0x57, 0x90, 0x00, 0x57, 0x73, 0xE3, + 0x57, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x0C, 0x00, 0x11, 0x06, 0x00, 0x20, 0x01, 0x34, + 0xEE, 0x74, 0x01, 0x01, 0x08, 0x84, 0x00, 0x00, + 0x00, 0xF3, 0x40, 0x90, 0x00, 0x00, 0x00, 0x01, + 0x00, 0x12, 0x00, 0x02, 0x00, 0x00, 0x10, 0x00, + 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, + 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, 0x9D, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x9D, 0x9D, 0x10, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x9D, 0x9D, 0x9D, + 0x9D, 0x9D, 0x9D, 0x9D, 0x00, 0x9D, 0x1D, 0x00, + 0x00, 0x00, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, + 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, 0x1D, + }; + + + u8 table3c0space[0xc0] = { + 0x11, 0x00, 0x10, 0x01, 0x26, 0x3D, 0xFF, 0x00, + 0x10, 0x3F, 0x00, 0x00, 0x2F, 0x00, 0x22, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0x50, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0x00, 0x00, 0x00, 0x00, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, + }; +#if 0 +//for(i=0;i<0xc0;i++) + for (i = 0; i < 0x40; i++) // + { + outb(table3c0space[i], 0x03c0 + i); + } + + + for (i = 0; i < 0x70; i++) { + outb(i, 0x03c4); + outb(table3c43c5[i], 0x03c5); + } + for (i = 0; i < 0x88; i++) { + outb(i, 0x03d4); + outb(table3d43d5[i], 0x03d5); + } + outb(0x92, 0x03d4); + outb(0x80, 0x03d5); + + outb(0xa3, 0x03d4); + outb(0x00, 0x03d5); + + outb(0xe8, 0x03d4); + outb(0x40, 0x03d5); +#endif +//3d4 3d freq +//IO Port / Index: 3X5.3D +//Scratch Pad Register 4 + +// outb(0x39,0x03c4);// + //outb(1 << SLD0F3Val ,0x03c5); +// +#endif + +} -- cgit v1.2.3