X-Git-Url: https://git.archive.openwrt.org/?p=15.05%2Fopenwrt.git;a=blobdiff_plain;f=target%2Flinux%2Fgeneric%2Ffiles%2Fcrypto%2Focf%2Fkirkwood%2FmvHal%2Fmv_hal%2Fddr2%2FmvDramIf.c;fp=target%2Flinux%2Fgeneric%2Ffiles%2Fcrypto%2Focf%2Fkirkwood%2FmvHal%2Fmv_hal%2Fddr2%2FmvDramIf.c;h=a214c95cd1acc90a05b82cc09a9640482897065e;hp=0000000000000000000000000000000000000000;hb=a082943b09f4f707990ad0ac6326df8480507f02;hpb=67fbcc7bd42cc07b1f3c6b5c9f2db37647178f25 diff --git a/target/linux/generic/files/crypto/ocf/kirkwood/mvHal/mv_hal/ddr2/mvDramIf.c b/target/linux/generic/files/crypto/ocf/kirkwood/mvHal/mv_hal/ddr2/mvDramIf.c new file mode 100644 index 0000000000..a214c95cd1 --- /dev/null +++ b/target/linux/generic/files/crypto/ocf/kirkwood/mvHal/mv_hal/ddr2/mvDramIf.c @@ -0,0 +1,1855 @@ +/******************************************************************************* +Copyright (C) Marvell International Ltd. and its affiliates + +This software file (the "File") is owned and distributed by Marvell +International Ltd. and/or its affiliates ("Marvell") under the following +alternative licensing terms. Once you have made an election to distribute the +File under one of the following license alternatives, please (i) delete this +introductory statement regarding license alternatives, (ii) delete the two +license alternatives that you have not elected to use and (iii) preserve the +Marvell copyright notice above. + +******************************************************************************** +Marvell Commercial License Option + +If you received this File from Marvell and you have entered into a commercial +license agreement (a "Commercial License") with Marvell, the File is licensed +to you under the terms of the applicable Commercial License. + +******************************************************************************** +Marvell GPL License Option + +If you received this File from Marvell, you may opt to use, redistribute and/or +modify this File in accordance with the terms and conditions of the General +Public License Version 2, June 1991 (the "GPL License"), a copy of which is +available along with the File in the license.txt file or by writing to the Free +Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 or +on the worldwide web at http://www.gnu.org/licenses/gpl.txt. + +THE FILE IS DISTRIBUTED AS-IS, WITHOUT WARRANTY OF ANY KIND, AND THE IMPLIED +WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE ARE EXPRESSLY +DISCLAIMED. The GPL License provides additional details about this warranty +disclaimer. +******************************************************************************** +Marvell BSD License Option + +If you received this File from Marvell, you may opt to use, redistribute and/or +modify this File under the following licensing terms. +Redistribution and use in source and binary forms, with or without modification, +are permitted provided that the following conditions are met: + + * Redistributions of source code must retain the above copyright notice, + this list of conditions and the following disclaimer. + + * Redistributions in binary form must reproduce the above copyright + notice, this list of conditions and the following disclaimer in the + documentation and/or other materials provided with the distribution. + + * Neither the name of Marvell nor the names of its contributors may be + used to endorse or promote products derived from this software without + specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND +ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED +WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE +DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR +ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES +(INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; +LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON +ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS +SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. + +*******************************************************************************/ + + +/* includes */ +#include "ddr2/mvDramIf.h" +#include "ctrlEnv/sys/mvCpuIf.h" + +#include "ddr2/mvDramIfStaticInit.h" + +/* #define MV_DEBUG */ +#ifdef MV_DEBUG +#define DB(x) x +#else +#define DB(x) +#endif + +/* DRAM bank presence encoding */ +#define BANK_PRESENT_CS0 0x1 +#define BANK_PRESENT_CS0_CS1 0x3 +#define BANK_PRESENT_CS0_CS2 0x5 +#define BANK_PRESENT_CS0_CS1_CS2 0x7 +#define BANK_PRESENT_CS0_CS2_CS3 0xd +#define BANK_PRESENT_CS0_CS2_CS3_CS4 0xf + +/* locals */ +#ifndef MV_STATIC_DRAM_ON_BOARD +static void sdramDDr2OdtConfig(MV_DRAM_BANK_INFO *pBankInfo); +static MV_U32 dunitCtrlLowRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 minCas, MV_U32 busClk, MV_STATUS TTmode ); +static MV_U32 dunitCtrlHighRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 busClk); +static MV_U32 sdramModeRegCalc(MV_U32 minCas); +static MV_U32 sdramExtModeRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 busClk); +static MV_U32 sdramAddrCtrlRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_DRAM_BANK_INFO *pBankInfoDIMM1); +static MV_U32 sdramConfigRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_DRAM_BANK_INFO *pBankInfo2, MV_U32 busClk); +static MV_U32 minCasCalc(MV_DRAM_BANK_INFO *pBankInfo,MV_DRAM_BANK_INFO *pBankInfo2, MV_U32 busClk, MV_U32 forcedCl); +static MV_U32 sdramTimeCtrlLowRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 minCas, MV_U32 busClk); +static MV_U32 sdramTimeCtrlHighRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 busClk); +static MV_U32 sdramDdr2TimeLoRegCalc(MV_U32 minCas); +static MV_U32 sdramDdr2TimeHiRegCalc(MV_U32 minCas); +#endif +MV_32 DRAM_CS_Order[MV_DRAM_MAX_CS] = {N_A + +#ifdef MV_INCLUDE_SDRAM_CS1 + ,N_A +#endif +#ifdef MV_INCLUDE_SDRAM_CS2 + ,N_A +#endif +#ifdef MV_INCLUDE_SDRAM_CS3 + ,N_A +#endif + }; +/* Get DRAM size of CS num */ +MV_U32 mvDramCsSizeGet(MV_U32 csNum) +{ + MV_DRAM_BANK_INFO bankInfo; + MV_U32 size, deviceW, dimmW; +#ifdef MV78XX0 + MV_U32 temp; +#endif + + if(MV_OK == mvDramBankInfoGet(csNum, &bankInfo)) + { + if (0 == bankInfo.size) + return 0; + + /* Note that the Dimm width might be different then the device DRAM width */ +#ifdef MV78XX0 + temp = MV_REG_READ(SDRAM_CONFIG_REG); + deviceW = ((temp & SDRAM_DWIDTH_MASK) == SDRAM_DWIDTH_32BIT )? 32 : 64; +#else + deviceW = 16 /* KW family */; +#endif + dimmW = bankInfo.dataWidth - (bankInfo.dataWidth % 16); + size = ((bankInfo.size << 20) / (dimmW/deviceW)); + return size; + } + else + return 0; +} +/******************************************************************************* +* mvDramIfDetect - Prepare DRAM interface configuration values. +* +* DESCRIPTION: +* This function implements the full DRAM detection and timing +* configuration for best system performance. +* Since this routine runs from a ROM device (Boot Flash), its stack +* resides on RAM, that might be the system DRAM. Changing DRAM +* configuration values while keeping vital data in DRAM is risky. That +* is why the function does not preform the configuration setting but +* prepare those in predefined 32bit registers (in this case IDMA +* registers are used) for other routine to perform the settings. +* The function will call for board DRAM SPD information for each DRAM +* chip select. The function will then analyze those SPD parameters of +* all DRAM banks in order to decide on DRAM configuration compatible +* for all DRAM banks. +* The function will set the CPU DRAM address decode registers. +* Note: This routine prepares values that will overide configuration of +* mvDramBasicAsmInit(). +* +* INPUT: +* forcedCl - Forced CAL Latency. If equal to zero, do not force. +* eccDisable - Force down the ECC. +* +* OUTPUT: +* None. +* +* RETURN: +* None. +* +*******************************************************************************/ +MV_STATUS mvDramIfDetect(MV_U32 forcedCl, MV_BOOL eccDisable) +{ + MV_32 MV_DRAM_CS_order[MV_DRAM_MAX_CS] = { + SDRAM_CS0 +#ifdef MV_INCLUDE_SDRAM_CS1 + ,SDRAM_CS1 +#endif +#ifdef MV_INCLUDE_SDRAM_CS2 + ,SDRAM_CS2 +#endif +#ifdef MV_INCLUDE_SDRAM_CS3 + ,SDRAM_CS3 +#endif + }; + MV_U32 busClk, deviceW, dimmW; + MV_U32 numOfAllDevices = 0; + MV_STATUS TTMode; +#ifndef MV_STATIC_DRAM_ON_BOARD + MV_DRAM_BANK_INFO bankInfo[MV_DRAM_MAX_CS]; + MV_U32 size, base = 0, i, j, temp, busClkPs; + MV_U8 minCas; + MV_CPU_DEC_WIN dramDecWin; + dramDecWin.addrWin.baseHigh = 0; +#endif + + busClk = mvBoardSysClkGet(); + + if (0 == busClk) + { + mvOsPrintf("Dram: ERR. Can't detect system clock! \n"); + return MV_ERROR; + } + +#ifndef MV_STATIC_DRAM_ON_BOARD + + busClkPs = 1000000000 / (busClk / 1000); /* in ps units */ + /* we will use bank 0 as the representative of the all the DRAM banks, */ + /* since bank 0 must exist. */ + for(i = 0; i < MV_DRAM_MAX_CS; i++) + { + /* if Bank exist */ + if(MV_OK == mvDramBankInfoGet(i, &bankInfo[i])) + { + DB(mvOsPrintf("Dram: Find bank %d\n", i)); + /* check it isn't SDRAM */ + if(bankInfo[i].memoryType != MEM_TYPE_DDR2) + { + mvOsOutput("Dram: ERR. SDRAM type not supported !!!\n"); + return MV_ERROR; + } + + /* All banks must support the Mclk freqency */ + if(bankInfo[i].minCycleTimeAtMaxCasLatPs > busClkPs) + { + mvOsOutput("Dram: ERR. Bank %d doesn't support memory clock!!!\n", i); + return MV_ERROR; + } + + /* All banks must support registry in order to activate it */ + if(bankInfo[i].registeredAddrAndControlInputs != + bankInfo[0].registeredAddrAndControlInputs) + { + mvOsOutput("Dram: ERR. different Registered settings !!!\n"); + return MV_ERROR; + } + + /* All banks must support same ECC mode */ + if(bankInfo[i].errorCheckType != + bankInfo[0].errorCheckType) + { + mvOsOutput("Dram: ERR. different ECC settings !!!\n"); + return MV_ERROR; + } + + } + else + { + if( i == 0 ) /* bank 0 doesn't exist */ + { + mvOsOutput("Dram: ERR. Fail to detect bank 0 !!!\n"); + return MV_ERROR; + } + else + { + DB(mvOsPrintf("Dram: Could not find bank %d\n", i)); + bankInfo[i].size = 0; /* Mark this bank as non exist */ + } + } + } + +#ifdef MV_INCLUDE_SDRAM_CS2 + if (bankInfo[SDRAM_CS0].size < bankInfo[SDRAM_CS2].size) + { + MV_DRAM_CS_order[0] = SDRAM_CS2; + MV_DRAM_CS_order[1] = SDRAM_CS3; + MV_DRAM_CS_order[2] = SDRAM_CS0; + MV_DRAM_CS_order[3] = SDRAM_CS1; + DRAM_CS_Order[0] = SDRAM_CS2; + DRAM_CS_Order[1] = SDRAM_CS3; + DRAM_CS_Order[2] = SDRAM_CS0; + DRAM_CS_Order[3] = SDRAM_CS1; + + } + else +#endif + { + MV_DRAM_CS_order[0] = SDRAM_CS0; + MV_DRAM_CS_order[1] = SDRAM_CS1; + DRAM_CS_Order[0] = SDRAM_CS0; + DRAM_CS_Order[1] = SDRAM_CS1; +#ifdef MV_INCLUDE_SDRAM_CS2 + MV_DRAM_CS_order[2] = SDRAM_CS2; + MV_DRAM_CS_order[3] = SDRAM_CS3; + DRAM_CS_Order[2] = SDRAM_CS2; + DRAM_CS_Order[3] = SDRAM_CS3; +#endif + } + + for(j = 0; j < MV_DRAM_MAX_CS; j++) + { + i = MV_DRAM_CS_order[j]; + + if (0 == bankInfo[i].size) + continue; + + /* Init the CPU window decode */ + /* Note that the Dimm width might be different then the device DRAM width */ +#ifdef MV78XX0 + temp = MV_REG_READ(SDRAM_CONFIG_REG); + deviceW = ((temp & SDRAM_DWIDTH_MASK) == SDRAM_DWIDTH_32BIT )? 32 : 64; +#else + deviceW = 16 /* KW family */; +#endif + dimmW = bankInfo[0].dataWidth - (bankInfo[0].dataWidth % 16); + size = ((bankInfo[i].size << 20) / (dimmW/deviceW)); + + /* We can not change DRAM window settings while excecuting */ + /* code from it. That is why we skip the DRAM CS[0], saving */ + /* it to the ROM configuration routine */ + + numOfAllDevices += bankInfo[i].numberOfDevices; + if (i == MV_DRAM_CS_order[0]) + { + MV_U32 sizeToReg; + /* Translate the given window size to register format */ + sizeToReg = ctrlSizeToReg(size, SCSR_SIZE_ALIGNMENT); + /* Size parameter validity check. */ + if (-1 == sizeToReg) + { + mvOsOutput("DRAM: mvCtrlAddrDecToReg: ERR. Win %d size invalid.\n" + ,i); + return MV_BAD_PARAM; + } + + DB(mvOsPrintf("Dram: Bank 0 Size - %x\n",sizeToReg);) + sizeToReg = (sizeToReg << SCSR_SIZE_OFFS); + sizeToReg |= SCSR_WIN_EN; + MV_REG_WRITE(DRAM_BUF_REG0, sizeToReg); + } + else + { + dramDecWin.addrWin.baseLow = base; + dramDecWin.addrWin.size = size; + dramDecWin.enable = MV_TRUE; + DB(mvOsPrintf("Dram: Enable window %d base 0x%x, size=0x%x\n",i, base, size)); + + /* Check if the DRAM size is more then 3GByte */ + if (base < 0xC0000000) + { + DB(mvOsPrintf("Dram: Enable window %d base 0x%x, size=0x%x\n",i, base, size)); + if (MV_OK != mvCpuIfTargetWinSet(i, &dramDecWin)) + { + mvOsPrintf("Dram: ERR. Fail to set bank %d!!!\n", SDRAM_CS0 + i); + return MV_ERROR; + } + } + } + + base += size; + + /* update the suportedCasLatencies mask */ + bankInfo[0].suportedCasLatencies &= bankInfo[i].suportedCasLatencies; + } + + /* calculate minimum CAS */ + minCas = minCasCalc(&bankInfo[0], &bankInfo[2], busClk, forcedCl); + if (0 == minCas) + { + mvOsOutput("Dram: Warn: Could not find CAS compatible to SysClk %dMhz\n", + (busClk / 1000000)); + + minCas = DDR2_CL_4; /* Continue with this CAS */ + mvOsOutput("Set default CAS latency 4\n"); + } + + /* calc SDRAM_CONFIG_REG and save it to temp register */ + temp = sdramConfigRegCalc(&bankInfo[0],&bankInfo[2], busClk); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramConfigRegCalc failed !!!\n"); + return MV_ERROR; + } + + /* check if ECC is enabled by the user */ + if(eccDisable) + { + /* turn off ECC*/ + temp &= ~BIT18; + } + DB(mvOsPrintf("Dram: sdramConfigRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG1, temp); + + /* calc SDRAM_MODE_REG and save it to temp register */ + temp = sdramModeRegCalc(minCas); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramModeRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramModeRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG2, temp); + + /* calc SDRAM_EXTENDED_MODE_REG and save it to temp register */ + temp = sdramExtModeRegCalc(&bankInfo[0], busClk); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramExtModeRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramExtModeRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG10, temp); + + /* calc D_UNIT_CONTROL_LOW and save it to temp register */ + TTMode = MV_FALSE; + DB(mvOsPrintf("Dram: numOfAllDevices = %x\n",numOfAllDevices);) + if( (numOfAllDevices > 9) && (bankInfo[0].registeredAddrAndControlInputs == MV_FALSE) ) + { + if ( ( (numOfAllDevices > 9) && (busClk > MV_BOARD_SYSCLK_200MHZ) ) || + (numOfAllDevices > 18) ) + { + mvOsOutput("Enable 2T "); + TTMode = MV_TRUE; + } + } + + temp = dunitCtrlLowRegCalc(&bankInfo[0], minCas, busClk, TTMode ); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. dunitCtrlLowRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: dunitCtrlLowRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG3, temp); + + /* calc D_UNIT_CONTROL_HIGH and save it to temp register */ + temp = dunitCtrlHighRegCalc(&bankInfo[0], busClk); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. dunitCtrlHighRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: dunitCtrlHighRegCalc - %x\n",temp);) + /* check if ECC is enabled by the user */ + if(eccDisable) + { + /* turn off sample stage if no ecc */ + temp &= ~SDRAM__D2P_EN;; + } + MV_REG_WRITE(DRAM_BUF_REG13, temp); + + /* calc SDRAM_ADDR_CTRL_REG and save it to temp register */ + temp = sdramAddrCtrlRegCalc(&bankInfo[0],&bankInfo[2]); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramAddrCtrlRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramAddrCtrlRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG4, temp); + + /* calc SDRAM_TIMING_CTRL_LOW_REG and save it to temp register */ + temp = sdramTimeCtrlLowRegCalc(&bankInfo[0], minCas, busClk); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramTimeCtrlLowRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramTimeCtrlLowRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG5, temp); + + /* calc SDRAM_TIMING_CTRL_HIGH_REG and save it to temp register */ + temp = sdramTimeCtrlHighRegCalc(&bankInfo[0], busClk); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramTimeCtrlHighRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramTimeCtrlHighRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG6, temp); + + sdramDDr2OdtConfig(bankInfo); + + /* calc DDR2_SDRAM_TIMING_LOW_REG and save it to temp register */ + temp = sdramDdr2TimeLoRegCalc(minCas); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramDdr2TimeLoRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramDdr2TimeLoRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG11, temp); + + /* calc DDR2_SDRAM_TIMING_HIGH_REG and save it to temp register */ + temp = sdramDdr2TimeHiRegCalc(minCas); + if(-1 == temp) + { + mvOsOutput("Dram: ERR. sdramDdr2TimeHiRegCalc failed !!!\n"); + return MV_ERROR; + } + DB(mvOsPrintf("Dram: sdramDdr2TimeHiRegCalc - %x\n",temp);) + MV_REG_WRITE(DRAM_BUF_REG12, temp); +#endif + + /* Note that DDR SDRAM Address/Control and Data pad calibration */ + /* settings is done in mvSdramIfConfig.s */ + + return MV_OK; +} + + +/******************************************************************************* +* mvDramIfBankBaseGet - Get DRAM interface bank base. +* +* DESCRIPTION: +* This function returns the 32 bit base address of a given DRAM bank. +* +* INPUT: +* bankNum - Bank number. +* +* OUTPUT: +* None. +* +* RETURN: +* DRAM bank size. If bank is disabled or paramter is invalid, the +* function returns -1. +* +*******************************************************************************/ +MV_U32 mvDramIfBankBaseGet(MV_U32 bankNum) +{ + DB(mvOsPrintf("Dram: mvDramIfBankBaseGet Bank %d base addr is %x \n", + bankNum, mvCpuIfTargetWinBaseLowGet(SDRAM_CS0 + bankNum))); + return mvCpuIfTargetWinBaseLowGet(SDRAM_CS0 + bankNum); +} + +/******************************************************************************* +* mvDramIfBankSizeGet - Get DRAM interface bank size. +* +* DESCRIPTION: +* This function returns the size of a given DRAM bank. +* +* INPUT: +* bankNum - Bank number. +* +* OUTPUT: +* None. +* +* RETURN: +* DRAM bank size. If bank is disabled the function return '0'. In case +* or paramter is invalid, the function returns -1. +* +*******************************************************************************/ +MV_U32 mvDramIfBankSizeGet(MV_U32 bankNum) +{ + DB(mvOsPrintf("Dram: mvDramIfBankSizeGet Bank %d size is %x \n", + bankNum, mvCpuIfTargetWinSizeGet(SDRAM_CS0 + bankNum))); + return mvCpuIfTargetWinSizeGet(SDRAM_CS0 + bankNum); +} + + +/******************************************************************************* +* mvDramIfSizeGet - Get DRAM interface total size. +* +* DESCRIPTION: +* This function get the DRAM total size. +* +* INPUT: +* None. +* +* OUTPUT: +* None. +* +* RETURN: +* DRAM total size. In case or paramter is invalid, the function +* returns -1. +* +*******************************************************************************/ +MV_U32 mvDramIfSizeGet(MV_VOID) +{ + MV_U32 size = 0, i; + + for(i = 0; i < MV_DRAM_MAX_CS; i++) + size += mvDramIfBankSizeGet(i); + + DB(mvOsPrintf("Dram: mvDramIfSizeGet size is %x \n",size)); + return size; +} + +/******************************************************************************* +* mvDramIfSingleBitErrThresholdSet - Set single bit ECC threshold. +* +* DESCRIPTION: +* The ECC single bit error threshold is the number of single bit +* errors to happen before the Dunit generates an interrupt. +* This function set single bit ECC threshold. +* +* INPUT: +* threshold - threshold. +* +* OUTPUT: +* None. +* +* RETURN: +* MV_BAD_PARAM if threshold is to big, MV_OK otherwise. +* +*******************************************************************************/ +MV_STATUS mvDramIfSingleBitErrThresholdSet(MV_U32 threshold) +{ + MV_U32 regVal; + + if (threshold > SECR_THRECC_MAX) + { + return MV_BAD_PARAM; + } + + regVal = MV_REG_READ(SDRAM_ECC_CONTROL_REG); + regVal &= ~SECR_THRECC_MASK; + regVal |= ((SECR_THRECC(threshold) & SECR_THRECC_MASK)); + MV_REG_WRITE(SDRAM_ECC_CONTROL_REG, regVal); + + return MV_OK; +} + +#ifndef MV_STATIC_DRAM_ON_BOARD +/******************************************************************************* +* minCasCalc - Calculate the Minimum CAS latency which can be used. +* +* DESCRIPTION: +* Calculate the minimum CAS latency that can be used, base on the DRAM +* parameters and the SDRAM bus Clock freq. +* +* INPUT: +* busClk - the DRAM bus Clock. +* pBankInfo - bank info parameters. +* forcedCl - Forced CAS Latency multiplied by 10. If equal to zero, do not force. +* +* OUTPUT: +* None +* +* RETURN: +* The minimum CAS Latency. The function returns 0 if max CAS latency +* supported by banks is incompatible with system bus clock frequancy. +* +*******************************************************************************/ + +static MV_U32 minCasCalc(MV_DRAM_BANK_INFO *pBankInfo,MV_DRAM_BANK_INFO *pBankInfo2, MV_U32 busClk, MV_U32 forcedCl) +{ + MV_U32 count = 1, j; + MV_U32 busClkPs = 1000000000 / (busClk / 1000); /* in ps units */ + MV_U32 startBit, stopBit; + MV_U32 minCas0 = 0, minCas2 = 0; + + + /* DDR 2: + *******-******-******-******-******-******-******-******* + * bit7 | bit6 | bit5 | bit4 | bit3 | bit2 | bit1 | bit0 * + *******-******-******-******-******-******-******-******* + CAS = * TBD | TBD | 5 | 4 | 3 | 2 | TBD | TBD * + Disco VI= * TBD | TBD | 5 | 4 | 3 | TBD | TBD | TBD * + Disco Duo= * TBD | 6 | 5 | 4 | 3 | TBD | TBD | TBD * + *********************************************************/ + + + /* If we are asked to use the forced CAL we change the suported CAL to be forcedCl only */ + if (forcedCl) + { + mvOsOutput("DRAM: Using forced CL %d.%d\n", (forcedCl / 10), (forcedCl % 10)); + + if (forcedCl == 30) + pBankInfo->suportedCasLatencies = 0x08; + else if (forcedCl == 40) + pBankInfo->suportedCasLatencies = 0x10; + else if (forcedCl == 50) + pBankInfo->suportedCasLatencies = 0x20; + else if (forcedCl == 60) + pBankInfo->suportedCasLatencies = 0x40; + else + { + mvOsPrintf("Forced CL %d.%d not supported. Set default CL 4\n", + (forcedCl / 10), (forcedCl % 10)); + pBankInfo->suportedCasLatencies = 0x10; + } + + return pBankInfo->suportedCasLatencies; + } + + /* go over the supported cas mask from Max Cas down and check if the */ + /* SysClk stands in its time requirments. */ + + DB(mvOsPrintf("Dram: minCasCalc supported mask = %x busClkPs = %x \n", + pBankInfo->suportedCasLatencies,busClkPs )); + count = 1; + for(j = 7; j > 0; j--) + { + if((pBankInfo->suportedCasLatencies >> j) & BIT0 ) + { + /* Reset the bits for CL incompatible for the sysClk */ + switch (count) + { + case 1: + if (pBankInfo->minCycleTimeAtMaxCasLatPs > busClkPs) + pBankInfo->suportedCasLatencies &= ~(BIT0 << j); + count++; + break; + case 2: + if (pBankInfo->minCycleTimeAtMaxCasLatMinus1Ps > busClkPs) + pBankInfo->suportedCasLatencies &= ~(BIT0 << j); + count++; + break; + case 3: + if (pBankInfo->minCycleTimeAtMaxCasLatMinus2Ps > busClkPs) + pBankInfo->suportedCasLatencies &= ~(BIT0 << j); + count++; + break; + default: + pBankInfo->suportedCasLatencies &= ~(BIT0 << j); + break; + } + } + } + + DB(mvOsPrintf("Dram: minCasCalc support = %x (after SysCC calc)\n", + pBankInfo->suportedCasLatencies )); + + count = 1; + DB(mvOsPrintf("Dram2: minCasCalc supported mask = %x busClkPs = %x \n", + pBankInfo2->suportedCasLatencies,busClkPs )); + for(j = 7; j > 0; j--) + { + if((pBankInfo2->suportedCasLatencies >> j) & BIT0 ) + { + /* Reset the bits for CL incompatible for the sysClk */ + switch (count) + { + case 1: + if (pBankInfo2->minCycleTimeAtMaxCasLatPs > busClkPs) + pBankInfo2->suportedCasLatencies &= ~(BIT0 << j); + count++; + break; + case 2: + if (pBankInfo2->minCycleTimeAtMaxCasLatMinus1Ps > busClkPs) + pBankInfo2->suportedCasLatencies &= ~(BIT0 << j); + count++; + break; + case 3: + if (pBankInfo2->minCycleTimeAtMaxCasLatMinus2Ps > busClkPs) + pBankInfo2->suportedCasLatencies &= ~(BIT0 << j); + count++; + break; + default: + pBankInfo2->suportedCasLatencies &= ~(BIT0 << j); + break; + } + } + } + + DB(mvOsPrintf("Dram2: minCasCalc support = %x (after SysCC calc)\n", + pBankInfo2->suportedCasLatencies )); + + startBit = 3; /* DDR2 support CL start with CL3 (bit 3) */ + stopBit = 6; /* DDR2 support CL stops with CL6 (bit 6) */ + + for(j = startBit; j <= stopBit ; j++) + { + if((pBankInfo->suportedCasLatencies >> j) & BIT0 ) + { + DB(mvOsPrintf("Dram: minCasCalc choose CAS %x \n",(BIT0 << j))); + minCas0 = (BIT0 << j); + break; + } + } + + for(j = startBit; j <= stopBit ; j++) + { + if((pBankInfo2->suportedCasLatencies >> j) & BIT0 ) + { + DB(mvOsPrintf("Dram: minCasCalc choose CAS %x \n",(BIT0 << j))); + minCas2 = (BIT0 << j); + break; + } + } + + if (minCas2 > minCas0) + return minCas2; + else + return minCas0; + + return 0; +} + +/******************************************************************************* +* sdramConfigRegCalc - Calculate sdram config register +* +* DESCRIPTION: Calculate sdram config register optimized value based +* on the bank info parameters. +* +* INPUT: +* busClk - the DRAM bus Clock. +* pBankInfo - sdram bank parameters +* +* OUTPUT: +* None +* +* RETURN: +* sdram config reg value. +* +*******************************************************************************/ +static MV_U32 sdramConfigRegCalc(MV_DRAM_BANK_INFO *pBankInfo,MV_DRAM_BANK_INFO *pBankInfo2, MV_U32 busClk) +{ + MV_U32 sdramConfig = 0; + MV_U32 refreshPeriod; + + busClk /= 1000000; /* we work with busClk in MHz */ + + sdramConfig = MV_REG_READ(SDRAM_CONFIG_REG); + + /* figure out the memory refresh internal */ + switch (pBankInfo->refreshInterval & 0xf) + { + case 0x0: /* refresh period is 15.625 usec */ + refreshPeriod = 15625; + break; + case 0x1: /* refresh period is 3.9 usec */ + refreshPeriod = 3900; + break; + case 0x2: /* refresh period is 7.8 usec */ + refreshPeriod = 7800; + break; + case 0x3: /* refresh period is 31.3 usec */ + refreshPeriod = 31300; + break; + case 0x4: /* refresh period is 62.5 usec */ + refreshPeriod = 62500; + break; + case 0x5: /* refresh period is 125 usec */ + refreshPeriod = 125000; + break; + default: /* refresh period undefined */ + mvOsPrintf("Dram: ERR. DRAM refresh period is unknown!\n"); + return -1; + } + + /* Now the refreshPeriod is in register format value */ + refreshPeriod = (busClk * refreshPeriod) / 1000; + + DB(mvOsPrintf("Dram: sdramConfigRegCalc calculated refresh interval %0x\n", + refreshPeriod)); + + /* make sure the refresh value is only 14 bits */ + if(refreshPeriod > SDRAM_REFRESH_MAX) + { + refreshPeriod = SDRAM_REFRESH_MAX; + DB(mvOsPrintf("Dram: sdramConfigRegCalc adjusted refresh interval %0x\n", + refreshPeriod)); + } + + /* Clear the refresh field */ + sdramConfig &= ~SDRAM_REFRESH_MASK; + + /* Set new value to refresh field */ + sdramConfig |= (refreshPeriod & SDRAM_REFRESH_MASK); + + /* registered DRAM ? */ + if ( pBankInfo->registeredAddrAndControlInputs ) + { + /* it's registered DRAM, so set the reg. DRAM bit */ + sdramConfig |= SDRAM_REGISTERED; + DB(mvOsPrintf("DRAM Attribute: Registered address and control inputs.\n");) + } + + /* ECC and IERR support */ + sdramConfig &= ~SDRAM_ECC_MASK; /* Clear ECC field */ + sdramConfig &= ~SDRAM_IERR_MASK; /* Clear IErr field */ + + if ( pBankInfo->errorCheckType ) + { + sdramConfig |= SDRAM_ECC_EN; + sdramConfig |= SDRAM_IERR_REPORTE; + DB(mvOsPrintf("Dram: mvDramIfDetect Enabling ECC\n")); + } + else + { + sdramConfig |= SDRAM_ECC_DIS; + sdramConfig |= SDRAM_IERR_IGNORE; + DB(mvOsPrintf("Dram: mvDramIfDetect Disabling ECC!\n")); + } + /* Set static default settings */ + sdramConfig |= SDRAM_CONFIG_DV; + + DB(mvOsPrintf("Dram: sdramConfigRegCalc set sdramConfig to 0x%x\n", + sdramConfig)); + + return sdramConfig; +} + +/******************************************************************************* +* sdramModeRegCalc - Calculate sdram mode register +* +* DESCRIPTION: Calculate sdram mode register optimized value based +* on the bank info parameters and the minCas. +* +* INPUT: +* minCas - minimum CAS supported. +* +* OUTPUT: +* None +* +* RETURN: +* sdram mode reg value. +* +*******************************************************************************/ +static MV_U32 sdramModeRegCalc(MV_U32 minCas) +{ + MV_U32 sdramMode; + + sdramMode = MV_REG_READ(SDRAM_MODE_REG); + + /* Clear CAS Latency field */ + sdramMode &= ~SDRAM_CL_MASK; + + DB(mvOsPrintf("DRAM CAS Latency ");) + + switch (minCas) + { + case DDR2_CL_3: + sdramMode |= SDRAM_DDR2_CL_3; + DB(mvOsPrintf("3.\n");) + break; + case DDR2_CL_4: + sdramMode |= SDRAM_DDR2_CL_4; + DB(mvOsPrintf("4.\n");) + break; + case DDR2_CL_5: + sdramMode |= SDRAM_DDR2_CL_5; + DB(mvOsPrintf("5.\n");) + break; + case DDR2_CL_6: + sdramMode |= SDRAM_DDR2_CL_6; + DB(mvOsPrintf("6.\n");) + break; + default: + mvOsOutput("\nsdramModeRegCalc ERROR: Max. CL out of range\n"); + return -1; + } + + DB(mvOsPrintf("\nsdramModeRegCalc register 0x%x\n", sdramMode )); + + return sdramMode; +} +/******************************************************************************* +* sdramExtModeRegCalc - Calculate sdram Extended mode register +* +* DESCRIPTION: +* Return sdram Extended mode register value based +* on the bank info parameters and bank presence. +* +* INPUT: +* pBankInfo - sdram bank parameters +* busClk - DRAM frequency +* +* OUTPUT: +* None +* +* RETURN: +* sdram Extended mode reg value. +* +*******************************************************************************/ +static MV_U32 sdramExtModeRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 busClk) +{ + MV_U32 populateBanks = 0; + int bankNum; + + /* Represent the populate banks in binary form */ + for(bankNum = 0; bankNum < MV_DRAM_MAX_CS; bankNum++) + { + if (0 != pBankInfo[bankNum].size) + { + populateBanks |= (1 << bankNum); + } + } + + switch(populateBanks) + { + case(BANK_PRESENT_CS0): + case(BANK_PRESENT_CS0_CS1): + return DDR_SDRAM_EXT_MODE_CS0_CS1_DV; + + case(BANK_PRESENT_CS0_CS2): + case(BANK_PRESENT_CS0_CS1_CS2): + case(BANK_PRESENT_CS0_CS2_CS3): + case(BANK_PRESENT_CS0_CS2_CS3_CS4): + if (busClk >= MV_BOARD_SYSCLK_267MHZ) + return DDR_SDRAM_EXT_MODE_FAST_CS0_CS1_CS2_CS3_DV; + else + return DDR_SDRAM_EXT_MODE_CS0_CS1_CS2_CS3_DV; + + default: + mvOsOutput("sdramExtModeRegCalc: Invalid DRAM bank presence\n"); + return -1; + } + return 0; +} + +/******************************************************************************* +* dunitCtrlLowRegCalc - Calculate sdram dunit control low register +* +* DESCRIPTION: Calculate sdram dunit control low register optimized value based +* on the bank info parameters and the minCas. +* +* INPUT: +* pBankInfo - sdram bank parameters +* minCas - minimum CAS supported. +* +* OUTPUT: +* None +* +* RETURN: +* sdram dunit control low reg value. +* +*******************************************************************************/ +static MV_U32 dunitCtrlLowRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 minCas, MV_U32 busClk, MV_STATUS TTMode) +{ + MV_U32 dunitCtrlLow, cl; + MV_U32 sbOutR[4]={3,5,7,9} ; + MV_U32 sbOutU[4]={1,3,5,7} ; + + dunitCtrlLow = MV_REG_READ(SDRAM_DUNIT_CTRL_REG); + + DB(mvOsPrintf("Dram: dunitCtrlLowRegCalc\n")); + + /* Clear StBurstOutDel field */ + dunitCtrlLow &= ~SDRAM_SB_OUT_MASK; + + /* Clear StBurstInDel field */ + dunitCtrlLow &= ~SDRAM_SB_IN_MASK; + + /* Clear CtrlPos field */ + dunitCtrlLow &= ~SDRAM_CTRL_POS_MASK; + + /* Clear 2T field */ + dunitCtrlLow &= ~SDRAM_2T_MASK; + if (TTMode == MV_TRUE) + { + dunitCtrlLow |= SDRAM_2T_MODE; + } + + /* For proper sample of read data set the Dunit Control register's */ + /* stBurstInDel bits [27:24] */ + /* 200MHz - 267MHz None reg = CL + 1 */ + /* 200MHz - 267MHz reg = CL + 2 */ + /* > 267MHz None reg = CL + 2 */ + /* > 267MHz reg = CL + 3 */ + + /* For proper sample of read data set the Dunit Control register's */ + /* stBurstOutDel bits [23:20] */ + /********-********-********-********- + * CL=3 | CL=4 | CL=5 | CL=6 | + *********-********-********-********- + Not Reg. * 0001 | 0011 | 0101 | 0111 | + *********-********-********-********- + Registered * 0011 | 0101 | 0111 | 1001 | + *********-********-********-********/ + + /* Set Dunit Control low default value */ + dunitCtrlLow |= SDRAM_DUNIT_CTRL_LOW_DDR2_DV; + + switch (minCas) + { + case DDR2_CL_3: cl = 3; break; + case DDR2_CL_4: cl = 4; break; + case DDR2_CL_5: cl = 5; break; + case DDR2_CL_6: cl = 6; break; + default: + mvOsOutput("Dram: dunitCtrlLowRegCalc Max. CL out of range %d\n", minCas); + return -1; + } + + /* registerd DDR SDRAM? */ + if (pBankInfo->registeredAddrAndControlInputs == MV_TRUE) + { + dunitCtrlLow |= (sbOutR[cl-3]) << SDRAM_SB_OUT_DEL_OFFS; + } + else + { + dunitCtrlLow |= (sbOutU[cl-3]) << SDRAM_SB_OUT_DEL_OFFS; + } + + DB(mvOsPrintf("\n\ndunitCtrlLowRegCalc: CL = %d, frequencies=%d\n", cl, busClk)); + + if (busClk <= MV_BOARD_SYSCLK_267MHZ) + { + if (pBankInfo->registeredAddrAndControlInputs == MV_TRUE) + cl = cl + 2; + else + cl = cl + 1; + } + else + { + if (pBankInfo->registeredAddrAndControlInputs == MV_TRUE) + cl = cl + 3; + else + cl = cl + 2; + } + + DB(mvOsPrintf("dunitCtrlLowRegCalc: SDRAM_SB_IN_DEL_OFFS = %d \n", cl)); + dunitCtrlLow |= cl << SDRAM_SB_IN_DEL_OFFS; + + DB(mvOsPrintf("Dram: Reg dunit control low = %x\n", dunitCtrlLow )); + + return dunitCtrlLow; +} + +/******************************************************************************* +* dunitCtrlHighRegCalc - Calculate sdram dunit control high register +* +* DESCRIPTION: Calculate sdram dunit control high register optimized value based +* on the bus clock. +* +* INPUT: +* busClk - DRAM frequency. +* +* OUTPUT: +* None +* +* RETURN: +* sdram dunit control high reg value. +* +*******************************************************************************/ +static MV_U32 dunitCtrlHighRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 busClk) +{ + MV_U32 dunitCtrlHigh; + dunitCtrlHigh = MV_REG_READ(SDRAM_DUNIT_CTRL_HI_REG); + if(busClk > MV_BOARD_SYSCLK_300MHZ) + dunitCtrlHigh |= SDRAM__P2D_EN; + else + dunitCtrlHigh &= ~SDRAM__P2D_EN; + + if(busClk > MV_BOARD_SYSCLK_267MHZ) + dunitCtrlHigh |= (SDRAM__WR_MESH_DELAY_EN | SDRAM__PUP_ZERO_SKEW_EN | SDRAM__ADD_HALF_FCC_EN); + + /* If ECC support we turn on D2P sample */ + dunitCtrlHigh &= ~SDRAM__D2P_EN; /* Clear D2P bit */ + if (( pBankInfo->errorCheckType ) && (busClk > MV_BOARD_SYSCLK_267MHZ)) + dunitCtrlHigh |= SDRAM__D2P_EN; + + return dunitCtrlHigh; +} + +/******************************************************************************* +* sdramAddrCtrlRegCalc - Calculate sdram address control register +* +* DESCRIPTION: Calculate sdram address control register optimized value based +* on the bank info parameters and the minCas. +* +* INPUT: +* pBankInfo - sdram bank parameters +* +* OUTPUT: +* None +* +* RETURN: +* sdram address control reg value. +* +*******************************************************************************/ +static MV_U32 sdramAddrCtrlRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_DRAM_BANK_INFO *pBankInfoDIMM1) +{ + MV_U32 addrCtrl = 0; + + if (pBankInfoDIMM1->size) + { + switch (pBankInfoDIMM1->sdramWidth) + { + case 4: /* memory is x4 */ + mvOsOutput("sdramAddrCtrlRegCalc: Error - x4 not supported!\n"); + return -1; + break; + case 8: /* memory is x8 */ + addrCtrl |= SDRAM_ADDRSEL_X8(2) | SDRAM_ADDRSEL_X8(3); + DB(mvOsPrintf("sdramAddrCtrlRegCalc: sdramAddrCtrlRegCalc SDRAM device DIMM2 width x8\n")); + break; + case 16: + addrCtrl |= SDRAM_ADDRSEL_X16(2) | SDRAM_ADDRSEL_X16(3); + DB(mvOsPrintf("sdramAddrCtrlRegCalc: sdramAddrCtrlRegCalc SDRAM device DIMM2 width x16\n")); + break; + default: /* memory width unsupported */ + mvOsOutput("sdramAddrCtrlRegCalc: ERR. DRAM chip width is unknown!\n"); + return -1; + } + } + + switch (pBankInfo->sdramWidth) + { + case 4: /* memory is x4 */ + mvOsOutput("sdramAddrCtrlRegCalc: Error - x4 not supported!\n"); + return -1; + break; + case 8: /* memory is x8 */ + addrCtrl |= SDRAM_ADDRSEL_X8(0) | SDRAM_ADDRSEL_X8(1); + DB(mvOsPrintf("sdramAddrCtrlRegCalc: sdramAddrCtrlRegCalc SDRAM device width x8\n")); + break; + case 16: + addrCtrl |= SDRAM_ADDRSEL_X16(0) | SDRAM_ADDRSEL_X16(1); + DB(mvOsPrintf("sdramAddrCtrlRegCalc: sdramAddrCtrlRegCalc SDRAM device width x16\n")); + break; + default: /* memory width unsupported */ + mvOsOutput("sdramAddrCtrlRegCalc: ERR. DRAM chip width is unknown!\n"); + return -1; + } + + /* Note that density is in MB units */ + switch (pBankInfo->deviceDensity) + { + case 256: /* 256 Mbit */ + DB(mvOsPrintf("DRAM Device Density 256Mbit\n")); + addrCtrl |= SDRAM_DSIZE_256Mb(0) | SDRAM_DSIZE_256Mb(1); + break; + case 512: /* 512 Mbit */ + DB(mvOsPrintf("DRAM Device Density 512Mbit\n")); + addrCtrl |= SDRAM_DSIZE_512Mb(0) | SDRAM_DSIZE_512Mb(1); + break; + case 1024: /* 1 Gbit */ + DB(mvOsPrintf("DRAM Device Density 1Gbit\n")); + addrCtrl |= SDRAM_DSIZE_1Gb(0) | SDRAM_DSIZE_1Gb(1); + break; + case 2048: /* 2 Gbit */ + DB(mvOsPrintf("DRAM Device Density 2Gbit\n")); + addrCtrl |= SDRAM_DSIZE_2Gb(0) | SDRAM_DSIZE_2Gb(1); + break; + default: + mvOsOutput("Dram: sdramAddrCtrl unsupported RAM-Device size %d\n", + pBankInfo->deviceDensity); + return -1; + } + + if (pBankInfoDIMM1->size) + { + switch (pBankInfoDIMM1->deviceDensity) + { + case 256: /* 256 Mbit */ + DB(mvOsPrintf("DIMM2: DRAM Device Density 256Mbit\n")); + addrCtrl |= SDRAM_DSIZE_256Mb(2) | SDRAM_DSIZE_256Mb(3); + break; + case 512: /* 512 Mbit */ + DB(mvOsPrintf("DIMM2: DRAM Device Density 512Mbit\n")); + addrCtrl |= SDRAM_DSIZE_512Mb(2) | SDRAM_DSIZE_512Mb(3); + break; + case 1024: /* 1 Gbit */ + DB(mvOsPrintf("DIMM2: DRAM Device Density 1Gbit\n")); + addrCtrl |= SDRAM_DSIZE_1Gb(2) | SDRAM_DSIZE_1Gb(3); + break; + case 2048: /* 2 Gbit */ + DB(mvOsPrintf("DIMM2: DRAM Device Density 2Gbit\n")); + addrCtrl |= SDRAM_DSIZE_2Gb(2) | SDRAM_DSIZE_2Gb(3); + break; + default: + mvOsOutput("DIMM2: Dram: sdramAddrCtrl unsupported RAM-Device size %d\n", + pBankInfoDIMM1->deviceDensity); + return -1; + } + } + /* SDRAM address control */ + DB(mvOsPrintf("Dram: setting sdram address control with: %x \n", addrCtrl)); + + return addrCtrl; +} + +/******************************************************************************* +* sdramTimeCtrlLowRegCalc - Calculate sdram timing control low register +* +* DESCRIPTION: +* This function calculates sdram timing control low register +* optimized value based on the bank info parameters and the minCas. +* +* INPUT: +* pBankInfo - sdram bank parameters +* minCas - minimum CAS supported. +* busClk - Bus clock +* +* OUTPUT: +* None +* +* RETURN: +* sdram timing control low reg value. +* +*******************************************************************************/ +static MV_U32 sdramTimeCtrlLowRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 minCas, MV_U32 busClk) +{ + MV_U32 tRp = 0; + MV_U32 tRrd = 0; + MV_U32 tRcd = 0; + MV_U32 tRas = 0; + MV_U32 tWr = 0; + MV_U32 tWtr = 0; + MV_U32 tRtp = 0; + MV_U32 timeCtrlLow = 0; + + MV_U32 bankNum; + + busClk = busClk / 1000000; /* In MHz */ + + /* Scan all DRAM banks to find maximum timing values */ + for (bankNum = 0; bankNum < MV_DRAM_MAX_CS; bankNum++) + { + tRp = MV_MAX(tRp, pBankInfo[bankNum].minRowPrechargeTime); + tRrd = MV_MAX(tRrd, pBankInfo[bankNum].minRowActiveToRowActive); + tRcd = MV_MAX(tRcd, pBankInfo[bankNum].minRasToCasDelay); + tRas = MV_MAX(tRas, pBankInfo[bankNum].minRasPulseWidth); + } + + /* Extract timing (in ns) from SPD value. We ignore the tenth ns part. */ + /* by shifting the data two bits right. */ + tRp = tRp >> 2; /* For example 0x50 -> 20ns */ + tRrd = tRrd >> 2; + tRcd = tRcd >> 2; + + /* Extract clock cycles from time parameter. We need to round up */ + tRp = ((busClk * tRp) / 1000) + (((busClk * tRp) % 1000) ? 1 : 0); + DB(mvOsPrintf("Dram Timing Low: tRp = %d ", tRp)); + tRrd = ((busClk * tRrd) / 1000) + (((busClk * tRrd) % 1000) ? 1 : 0); + /* JEDEC min reqeirments tRrd = 2 */ + if (tRrd < 2) + tRrd = 2; + DB(mvOsPrintf("tRrd = %d ", tRrd)); + tRcd = ((busClk * tRcd) / 1000) + (((busClk * tRcd) % 1000) ? 1 : 0); + DB(mvOsPrintf("tRcd = %d ", tRcd)); + tRas = ((busClk * tRas) / 1000) + (((busClk * tRas) % 1000) ? 1 : 0); + DB(mvOsPrintf("tRas = %d ", tRas)); + + /* tWr and tWtr is different for DDR1 and DDR2. tRtp is only for DDR2 */ + /* Scan all DRAM banks to find maximum timing values */ + for (bankNum = 0; bankNum < MV_DRAM_MAX_CS; bankNum++) + { + tWr = MV_MAX(tWr, pBankInfo[bankNum].minWriteRecoveryTime); + tWtr = MV_MAX(tWtr, pBankInfo[bankNum].minWriteToReadCmdDelay); + tRtp = MV_MAX(tRtp, pBankInfo[bankNum].minReadToPrechCmdDelay); + } + + /* Extract timing (in ns) from SPD value. We ignore the tenth ns */ + /* part by shifting the data two bits right. */ + tWr = tWr >> 2; /* For example 0x50 -> 20ns */ + tWtr = tWtr >> 2; + tRtp = tRtp >> 2; + /* Extract clock cycles from time parameter. We need to round up */ + tWr = ((busClk * tWr) / 1000) + (((busClk * tWr) % 1000) ? 1 : 0); + DB(mvOsPrintf("tWr = %d ", tWr)); + tWtr = ((busClk * tWtr) / 1000) + (((busClk * tWtr) % 1000) ? 1 : 0); + /* JEDEC min reqeirments tWtr = 2 */ + if (tWtr < 2) + tWtr = 2; + DB(mvOsPrintf("tWtr = %d ", tWtr)); + tRtp = ((busClk * tRtp) / 1000) + (((busClk * tRtp) % 1000) ? 1 : 0); + /* JEDEC min reqeirments tRtp = 2 */ + if (tRtp < 2) + tRtp = 2; + DB(mvOsPrintf("tRtp = %d ", tRtp)); + + /* Note: value of 0 in register means one cycle, 1 means two and so on */ + timeCtrlLow = (((tRp - 1) << SDRAM_TRP_OFFS) | + ((tRrd - 1) << SDRAM_TRRD_OFFS) | + ((tRcd - 1) << SDRAM_TRCD_OFFS) | + (((tRas - 1) << SDRAM_TRAS_OFFS) & SDRAM_TRAS_MASK)| + ((tWr - 1) << SDRAM_TWR_OFFS) | + ((tWtr - 1) << SDRAM_TWTR_OFFS) | + ((tRtp - 1) << SDRAM_TRTP_OFFS)); + + /* Check extended tRas bit */ + if ((tRas - 1) & BIT4) + timeCtrlLow |= (1 << SDRAM_EXT_TRAS_OFFS); + + return timeCtrlLow; +} + +/******************************************************************************* +* sdramTimeCtrlHighRegCalc - Calculate sdram timing control high register +* +* DESCRIPTION: +* This function calculates sdram timing control high register +* optimized value based on the bank info parameters and the bus clock. +* +* INPUT: +* pBankInfo - sdram bank parameters +* busClk - Bus clock +* +* OUTPUT: +* None +* +* RETURN: +* sdram timing control high reg value. +* +*******************************************************************************/ +static MV_U32 sdramTimeCtrlHighRegCalc(MV_DRAM_BANK_INFO *pBankInfo, MV_U32 busClk) +{ + MV_U32 tRfc; + MV_U32 timingHigh; + MV_U32 timeNs = 0; + MV_U32 bankNum; + + busClk = busClk / 1000000; /* In MHz */ + + /* Set DDR timing high register static configuration bits */ + timingHigh = MV_REG_READ(SDRAM_TIMING_CTRL_HIGH_REG); + + /* Set DDR timing high register default value */ + timingHigh |= SDRAM_TIMING_CTRL_HIGH_REG_DV; + + /* Clear tRfc field */ + timingHigh &= ~SDRAM_TRFC_MASK; + + /* Scan all DRAM banks to find maximum timing values */ + for (bankNum = 0; bankNum < MV_DRAM_MAX_CS; bankNum++) + { + timeNs = MV_MAX(timeNs, pBankInfo[bankNum].minRefreshToActiveCmd); + DB(mvOsPrintf("Dram: Timing High: minRefreshToActiveCmd = %d\n", + pBankInfo[bankNum].minRefreshToActiveCmd)); + } + if(busClk >= 333 && mvCtrlModelGet() == MV_78XX0_A1_REV) + { + timingHigh |= 0x1 << SDRAM_TR2W_W2R_OFFS; + } + + tRfc = ((busClk * timeNs) / 1000) + (((busClk * timeNs) % 1000) ? 1 : 0); + /* Note: value of 0 in register means one cycle, 1 means two and so on */ + DB(mvOsPrintf("Dram: Timing High: tRfc = %d\n", tRfc)); + timingHigh |= (((tRfc - 1) & SDRAM_TRFC_MASK) << SDRAM_TRFC_OFFS); + DB(mvOsPrintf("Dram: Timing High: tRfc = %d\n", tRfc)); + + /* SDRAM timing high */ + DB(mvOsPrintf("Dram: setting timing high with: %x \n", timingHigh)); + + return timingHigh; +} +/******************************************************************************* +* sdramDDr2OdtConfig - Set DRAM DDR2 On Die Termination registers. +* +* DESCRIPTION: +* This function config DDR2 On Die Termination (ODT) registers. +* +* INPUT: +* pBankInfo - bank info parameters. +* +* OUTPUT: +* None +* +* RETURN: +* None +*******************************************************************************/ +static void sdramDDr2OdtConfig(MV_DRAM_BANK_INFO *pBankInfo) +{ + MV_U32 populateBanks = 0; + MV_U32 odtCtrlLow, odtCtrlHigh, dunitOdtCtrl; + int bankNum; + + /* Represent the populate banks in binary form */ + for(bankNum = 0; bankNum < MV_DRAM_MAX_CS; bankNum++) + { + if (0 != pBankInfo[bankNum].size) + { + populateBanks |= (1 << bankNum); + } + } + + switch(populateBanks) + { + case(BANK_PRESENT_CS0): + case(BANK_PRESENT_CS0_CS1): + odtCtrlLow = DDR2_ODT_CTRL_LOW_CS0_CS1_DV; + odtCtrlHigh = DDR2_ODT_CTRL_HIGH_CS0_CS1_DV; + dunitOdtCtrl = DDR2_DUNIT_ODT_CTRL_CS0_CS1_DV; + break; + case(BANK_PRESENT_CS0_CS2): + case(BANK_PRESENT_CS0_CS1_CS2): + case(BANK_PRESENT_CS0_CS2_CS3): + case(BANK_PRESENT_CS0_CS2_CS3_CS4): + odtCtrlLow = DDR2_ODT_CTRL_LOW_CS0_CS1_CS2_CS3_DV; + odtCtrlHigh = DDR2_ODT_CTRL_HIGH_CS0_CS1_CS2_CS3_DV; + dunitOdtCtrl = DDR2_DUNIT_ODT_CTRL_CS0_CS1_CS2_CS3_DV; + break; + default: + DB(mvOsPrintf("sdramDDr2OdtConfig: Invalid DRAM bank presence\n")); + return; + } + /* DDR2 SDRAM ODT ctrl low */ + DB(mvOsPrintf("Dram: DDR2 setting ODT ctrl low with: %x \n", odtCtrlLow)); + MV_REG_WRITE(DRAM_BUF_REG7, odtCtrlLow); + + /* DDR2 SDRAM ODT ctrl high */ + DB(mvOsPrintf("Dram: DDR2 setting ODT ctrl high with: %x \n", odtCtrlHigh)); + MV_REG_WRITE(DRAM_BUF_REG8, odtCtrlHigh); + + /* DDR2 DUNIT ODT ctrl */ + if ( ((mvCtrlModelGet() == MV_78XX0_DEV_ID) && (mvCtrlRevGet() == MV_78XX0_Y0_REV)) || + (mvCtrlModelGet() == MV_76100_DEV_ID) || + (mvCtrlModelGet() == MV_78100_DEV_ID) || + (mvCtrlModelGet() == MV_78200_DEV_ID) ) + dunitOdtCtrl &= ~(BIT9|BIT8); /* Clear ODT always on */ + + DB(mvOsPrintf("DUNIT: DDR2 setting ODT ctrl with: %x \n", dunitOdtCtrl)); + MV_REG_WRITE(DRAM_BUF_REG9, dunitOdtCtrl); + return; +} +/******************************************************************************* +* sdramDdr2TimeLoRegCalc - Set DDR2 DRAM Timing Low registers. +* +* DESCRIPTION: +* This function config DDR2 DRAM Timing low registers. +* +* INPUT: +* minCas - minimum CAS supported. +* +* OUTPUT: +* None +* +* RETURN: +* DDR2 sdram timing low reg value. +*******************************************************************************/ +static MV_U32 sdramDdr2TimeLoRegCalc(MV_U32 minCas) +{ + MV_U8 cl = -1; + MV_U32 ddr2TimeLoReg; + + /* read and clear the feilds we are going to set */ + ddr2TimeLoReg = MV_REG_READ(SDRAM_DDR2_TIMING_LO_REG); + ddr2TimeLoReg &= ~(SD2TLR_TODT_ON_RD_MASK | + SD2TLR_TODT_OFF_RD_MASK | + SD2TLR_TODT_ON_CTRL_RD_MASK | + SD2TLR_TODT_OFF_CTRL_RD_MASK); + + if( minCas == DDR2_CL_3 ) + { + cl = 3; + } + else if( minCas == DDR2_CL_4 ) + { + cl = 4; + } + else if( minCas == DDR2_CL_5 ) + { + cl = 5; + } + else if( minCas == DDR2_CL_6 ) + { + cl = 6; + } + else + { + DB(mvOsPrintf("sdramDdr2TimeLoRegCalc: CAS latency %d unsupported. using CAS latency 4\n", + minCas)); + cl = 4; + } + + ddr2TimeLoReg |= ((cl-3) << SD2TLR_TODT_ON_RD_OFFS); + ddr2TimeLoReg |= ( cl << SD2TLR_TODT_OFF_RD_OFFS); + ddr2TimeLoReg |= ( cl << SD2TLR_TODT_ON_CTRL_RD_OFFS); + ddr2TimeLoReg |= ((cl+3) << SD2TLR_TODT_OFF_CTRL_RD_OFFS); + + /* DDR2 SDRAM timing low */ + DB(mvOsPrintf("Dram: DDR2 setting timing low with: %x \n", ddr2TimeLoReg)); + + return ddr2TimeLoReg; +} + +/******************************************************************************* +* sdramDdr2TimeHiRegCalc - Set DDR2 DRAM Timing High registers. +* +* DESCRIPTION: +* This function config DDR2 DRAM Timing high registers. +* +* INPUT: +* minCas - minimum CAS supported. +* +* OUTPUT: +* None +* +* RETURN: +* DDR2 sdram timing high reg value. +*******************************************************************************/ +static MV_U32 sdramDdr2TimeHiRegCalc(MV_U32 minCas) +{ + MV_U8 cl = -1; + MV_U32 ddr2TimeHiReg; + + /* read and clear the feilds we are going to set */ + ddr2TimeHiReg = MV_REG_READ(SDRAM_DDR2_TIMING_HI_REG); + ddr2TimeHiReg &= ~(SD2THR_TODT_ON_WR_MASK | + SD2THR_TODT_OFF_WR_MASK | + SD2THR_TODT_ON_CTRL_WR_MASK | + SD2THR_TODT_OFF_CTRL_WR_MASK); + + if( minCas == DDR2_CL_3 ) + { + cl = 3; + } + else if( minCas == DDR2_CL_4 ) + { + cl = 4; + } + else if( minCas == DDR2_CL_5 ) + { + cl = 5; + } + else if( minCas == DDR2_CL_6 ) + { + cl = 6; + } + else + { + mvOsOutput("sdramDdr2TimeHiRegCalc: CAS latency %d unsupported. using CAS latency 4\n", + minCas); + cl = 4; + } + + ddr2TimeHiReg |= ((cl-3) << SD2THR_TODT_ON_WR_OFFS); + ddr2TimeHiReg |= ( cl << SD2THR_TODT_OFF_WR_OFFS); + ddr2TimeHiReg |= ( cl << SD2THR_TODT_ON_CTRL_WR_OFFS); + ddr2TimeHiReg |= ((cl+3) << SD2THR_TODT_OFF_CTRL_WR_OFFS); + + /* DDR2 SDRAM timin high */ + DB(mvOsPrintf("Dram: DDR2 setting timing high with: %x \n", ddr2TimeHiReg)); + + return ddr2TimeHiReg; +} +#endif + +/******************************************************************************* +* mvDramIfCalGet - Get CAS Latency +* +* DESCRIPTION: +* This function get the CAS Latency. +* +* INPUT: +* None +* +* OUTPUT: +* None +* +* RETURN: +* CAS latency times 10 (to avoid using floating point). +* +*******************************************************************************/ +MV_U32 mvDramIfCalGet(void) +{ + MV_U32 sdramCasLat, casLatMask; + + casLatMask = (MV_REG_READ(SDRAM_MODE_REG) & SDRAM_CL_MASK); + + switch (casLatMask) + { + case SDRAM_DDR2_CL_3: + sdramCasLat = 30; + break; + case SDRAM_DDR2_CL_4: + sdramCasLat = 40; + break; + case SDRAM_DDR2_CL_5: + sdramCasLat = 50; + break; + case SDRAM_DDR2_CL_6: + sdramCasLat = 60; + break; + default: + mvOsOutput("mvDramIfCalGet: Err, unknown DDR2 CAL\n"); + return -1; + } + + return sdramCasLat; +} + + +/******************************************************************************* +* mvDramIfSelfRefreshSet - Put the dram in self refresh mode - +* +* DESCRIPTION: +* add support in power management. +* +* +* INPUT: +* None +* +* OUTPUT: +* None +* +* RETURN: +* None +* +*******************************************************************************/ + +MV_VOID mvDramIfSelfRefreshSet() +{ + MV_U32 operReg; + + operReg = MV_REG_READ(SDRAM_OPERATION_REG); + MV_REG_WRITE(SDRAM_OPERATION_REG ,operReg |SDRAM_CMD_SLF_RFRSH); + /* Read until register is reset to 0 */ + while(MV_REG_READ(SDRAM_OPERATION_REG)); +} +/******************************************************************************* +* mvDramIfDimGetSPDversion - return DIMM SPD version. +* +* DESCRIPTION: +* This function prints the DRAM controller information. +* +* INPUT: +* None. +* +* OUTPUT: +* None. +* +* RETURN: +* None. +* +*******************************************************************************/ +static void mvDramIfDimGetSPDversion(MV_U32 *pMajor, MV_U32 *pMinor, MV_U32 bankNum) +{ + MV_DIMM_INFO dimmInfo; + if (bankNum >= MV_DRAM_MAX_CS ) + { + DB(mvOsPrintf("Dram: mvDramIfDimGetSPDversion bad params \n")); + return ; + } + memset(&dimmInfo,0,sizeof(dimmInfo)); + if ( MV_OK != dimmSpdGet((MV_U32)(bankNum/2), &dimmInfo)) + { + DB(mvOsPrintf("Dram: ERR dimmSpdGet failed to get dimm info \n")); + return ; + } + *pMajor = dimmInfo.spdRawData[DIMM_SPD_VERSION]/10; + *pMinor = dimmInfo.spdRawData[DIMM_SPD_VERSION]%10; +} +/******************************************************************************* +* mvDramIfShow - Show DRAM controller information. +* +* DESCRIPTION: +* This function prints the DRAM controller information. +* +* INPUT: +* None. +* +* OUTPUT: +* None. +* +* RETURN: +* None. +* +*******************************************************************************/ +void mvDramIfShow(void) +{ + int i, sdramCasLat, sdramCsSize; + MV_U32 Major=0, Minor=0; + + mvOsOutput("DRAM Controller info:\n"); + + mvOsOutput("Total DRAM "); + mvSizePrint(mvDramIfSizeGet()); + mvOsOutput("\n"); + + for(i = 0; i < MV_DRAM_MAX_CS; i++) + { + sdramCsSize = mvDramIfBankSizeGet(i); + if (sdramCsSize) + { + if (0 == (i & 1)) + { + mvDramIfDimGetSPDversion(&Major, &Minor,i); + mvOsOutput("DIMM %d version %d.%d\n", i/2, Major, Minor); + } + mvOsOutput("\tDRAM CS[%d] ", i); + mvSizePrint(sdramCsSize); + mvOsOutput("\n"); + } + } + sdramCasLat = mvDramIfCalGet(); + + if (MV_REG_READ(SDRAM_CONFIG_REG) & SDRAM_ECC_EN) + { + mvOsOutput("ECC enabled, "); + } + else + { + mvOsOutput("ECC Disabled, "); + } + + if (MV_REG_READ(SDRAM_CONFIG_REG) & SDRAM_REGISTERED) + { + mvOsOutput("Registered DIMM\n"); + } + else + { + mvOsOutput("Non registered DIMM\n"); + } + + mvOsOutput("Configured CAS Latency %d.%d\n", sdramCasLat/10, sdramCasLat%10); +} +/******************************************************************************* +* mvDramIfGetFirstCS - find the DRAM bank on the lower address +* +* +* DESCRIPTION: +* This function return the fisrt CS on address 0 +* +* INPUT: +* None. +* +* OUTPUT: +* None. +* +* RETURN: +* SDRAM_CS0 or SDRAM_CS2 +* +*******************************************************************************/ +MV_U32 mvDramIfGetFirstCS(void) +{ + MV_DRAM_BANK_INFO bankInfo[MV_DRAM_MAX_CS]; + + if (DRAM_CS_Order[0] == N_A) + { + mvDramBankInfoGet(SDRAM_CS0, &bankInfo[SDRAM_CS0]); +#ifdef MV_INCLUDE_SDRAM_CS2 + mvDramBankInfoGet(SDRAM_CS2, &bankInfo[SDRAM_CS2]); +#endif + +#ifdef MV_INCLUDE_SDRAM_CS2 + if (bankInfo[SDRAM_CS0].size < bankInfo[SDRAM_CS2].size) + { + DRAM_CS_Order[0] = SDRAM_CS2; + DRAM_CS_Order[1] = SDRAM_CS3; + DRAM_CS_Order[2] = SDRAM_CS0; + DRAM_CS_Order[3] = SDRAM_CS1; + + return SDRAM_CS2; + } +#endif + DRAM_CS_Order[0] = SDRAM_CS0; + DRAM_CS_Order[1] = SDRAM_CS1; +#ifdef MV_INCLUDE_SDRAM_CS2 + DRAM_CS_Order[2] = SDRAM_CS2; + DRAM_CS_Order[3] = SDRAM_CS3; +#endif + return SDRAM_CS0; + } + return DRAM_CS_Order[0]; +} +/******************************************************************************* +* mvDramIfGetCSorder - +* +* +* DESCRIPTION: +* This function return the fisrt CS on address 0 +* +* INPUT: +* CS number. +* +* OUTPUT: +* CS order. +* +* RETURN: +* SDRAM_CS0 or SDRAM_CS2 +* +* NOTE: mvDramIfGetFirstCS must be caled before this subroutine +*******************************************************************************/ +MV_U32 mvDramIfGetCSorder(MV_U32 csOrder ) +{ + return DRAM_CS_Order[csOrder]; +} +