diff options
Diffstat (limited to 'src/vendorcode/amd/agesa/f10/Proc/Mem/NB/mndct.c')
-rwxr-xr-x | src/vendorcode/amd/agesa/f10/Proc/Mem/NB/mndct.c | 2053 |
1 files changed, 2053 insertions, 0 deletions
diff --git a/src/vendorcode/amd/agesa/f10/Proc/Mem/NB/mndct.c b/src/vendorcode/amd/agesa/f10/Proc/Mem/NB/mndct.c new file mode 100755 index 0000000000..76712ff0e2 --- /dev/null +++ b/src/vendorcode/amd/agesa/f10/Proc/Mem/NB/mndct.c @@ -0,0 +1,2053 @@ +/** + * @file + * + * mndct.c + * + * Common Northbridge DCT support + * + * @xrefitem bom "File Content Label" "Release Content" + * @e project: AGESA + * @e sub-project: (Mem/NB) + * @e \$Revision: 11758 $ @e \$Date: 2009-04-03 10:58:22 -0500 (Fri, 03 Apr 2009) $ + * + **/ +/***************************************************************************** +* +* Copyright (c) 2011, Advanced Micro Devices, Inc. +* All rights reserved. +* +* 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 Advanced Micro Devices, Inc. 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 ADVANCED MICRO DEVICES, INC. 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. +* +* *************************************************************************** +* +*/ + + +/* + *---------------------------------------------------------------------------- + * MODULES USED + * + *---------------------------------------------------------------------------- + */ + + + +#include "AGESA.h" +#include "amdlib.h" +#include "Ids.h" +#include "mport.h" +#include "mm.h" +#include "mn.h" +#include "mt.h" +#include "mu.h" +#include "mftds.h" +#include "merrhdl.h" +#include "OptionMemory.h" +#include "PlatformMemoryConfiguration.h" +#include "Filecode.h" +#define FILECODE PROC_MEM_NB_MNDCT_FILECODE +/*---------------------------------------------------------------------------- + * DEFINITIONS AND MACROS + * + *---------------------------------------------------------------------------- + */ +#define UNUSED_CLK 4 + +/*---------------------------------------------------------------------------- + * TYPEDEFS AND STRUCTURES + * + *---------------------------------------------------------------------------- + */ + +/*---------------------------------------------------------------------------- + * PROTOTYPES OF LOCAL FUNCTIONS + * + *---------------------------------------------------------------------------- + */ + +VOID +STATIC +MemNAfterStitchMemNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ); + +UINT8 +MemNGet1KTFawTkNb ( + IN UINT8 k + ); + +UINT8 +MemNGet2KTFawTkNb ( + IN UINT8 k + ); + +VOID +STATIC +MemNQuarterMemClk2NClkNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN OUT UINT16 *SubTotalPtr + ); + +/*---------------------------------------------------------------------------- + * EXPORTED FUNCTIONS + * + *---------------------------------------------------------------------------- + */ + +extern BUILD_OPT_CFG UserOptions; + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function combines all the memory into a contiguous map. + * Requires that Mask values for each bank be programmed first and that + * the chip-select population indicator is correctly set. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return TRUE - An Error value lower than AGESA_FATAL may have occurred + * @return FALSE - An Error value greater than or equal to AGESA_FATAL may have occurred + */ + +BOOLEAN +MemNStitchMemoryNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + BOOLEAN DSpareEn; + UINT32 NxtCSBase; + UINT32 CurCSBase; + UINT32 CsSize; + UINT32 BiggestBank; + UINT8 p; + UINT8 q; + UINT8 BiggestDimm; + MEM_PARAMETER_STRUCT *RefPtr; + DIE_STRUCT *MCTPtr; + DCT_STRUCT *DCTPtr; + RefPtr = NBPtr->RefPtr; + MCTPtr = NBPtr->MCTPtr; + DCTPtr = NBPtr->DCTPtr; + DSpareEn = FALSE; + if (NBPtr->IsSupported[SetSpareEn]) { + DSpareEn = FALSE; + if (RefPtr->GStatus[GsbEnDIMMSpareNW]) { + DSpareEn = TRUE; + } + } + + DCTPtr->Timings.CsEnabled = 0; + NxtCSBase = 0; + for (p = 0; p < MAX_CS_PER_CHANNEL; p++) { + BiggestBank = 0; + BiggestDimm = 0; + for (q = 0; q < MAX_CS_PER_CHANNEL; q++) { + if (((DCTPtr->Timings.CsPresent & ~DCTPtr->Timings.CsTestFail) & ((UINT16)1 << q)) != 0) { + if ((MemNGetBitFieldNb (NBPtr, BFCSBaseAddr0Reg + q) & 7) == 0) { + // (CSEnable|Spare==1)bank is not enabled yet + CsSize = MemNGetBitFieldNb (NBPtr, BFCSMask0Reg + (q >> 1)); + if (CsSize != 0) { + CsSize += ((UINT32)1 << 19); + CsSize &= 0xFFF80000; + } + if (CsSize > BiggestBank) { + BiggestBank = CsSize; + BiggestDimm = q; + } + } + } + } + + if (BiggestBank != 0) { + CurCSBase = NxtCSBase; + if (NBPtr->IsSupported[CheckSpareEn]) { + if (DSpareEn) { + CurCSBase = ((UINT32)1 << BFSpare); + DSpareEn = FALSE; + } else { + CurCSBase |= ((UINT32)1 << BFCSEnable); + NxtCSBase += BiggestBank; + } + } else { + CurCSBase |= ((UINT32)1 << BFCSEnable); + NxtCSBase += BiggestBank; + } + if ((BiggestDimm & 1) != 0) { + if ((DCTPtr->Timings.DimmMirrorPresent & (1 << (BiggestDimm >> 1))) != 0) { + CurCSBase |= ((UINT32)1 << BFOnDimmMirror); + } + } + MemNSetBitFieldNb (NBPtr, BFCSBaseAddr0Reg + BiggestDimm, CurCSBase); + DCTPtr->Timings.CsEnabled |= (1 << BiggestDimm); + } + if ((DCTPtr->Timings.CsTestFail & ((UINT16)1 << p)) != 0) { + MemNSetBitFieldNb (NBPtr, (BFCSBaseAddr0Reg + p), (UINT32)1 << BFTestFail); + } + } + + if (NxtCSBase != 0) { + DCTPtr->Timings.DctMemSize = NxtCSBase >> 8; // Scale base address from [39:8] to [47:16] + MemNAfterStitchMemNb (NBPtr); + } + + return (BOOLEAN) (MCTPtr->ErrCode < AGESA_FATAL); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets platform specific config/timing values from the interface layer and + * programs them into DCT. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return TRUE - An Error value lower than AGESA_FATAL may have occurred + * @return FALSE - An Error value greater than or equal to AGESA_FATAL may have occurred + */ + +BOOLEAN +MemNPlatformSpecNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + CONST BIT_FIELD_NAME ChipletPDRegs[] = { + BFPhyClkConfig0, + BFPhyClkConfig3, + BFPhyClkConfig1, + BFPhyClkConfig2 + }; + CONST UINT8 ChipletPDClkDisMap[][2] = { + //F2[1, 0]x9C_x0D0F2030 -> F2x[1, 0]88[MemClkDis[1:0]] + {0, 1}, + //F2[1, 0]x9C_x0D0F2330 -> F2x[1, 0]88[MemClkDis[7:6]] + {6, 7}, + //F2x09C_x0D0F2130 -> F2x88[MemClkDis[5:4]] + {4, 5}, + //F2x09C_x0D0F2230 -> F2x88[MemClkDis[3:2]] + {2, 3}, + //F2x19C_x0D0F2130 -> F2x188[MemClkDis[5:2]] + {2, 5}, + //F2x19C_x0D0F2230 -> F2x188[MemClkDis[4:3]] + {3, 4} + }; + + UINT8 MemClkDis; + UINT8 i; + UINT8 MemoryAllClocks; + UINT8 *MemClkDisMap; + UINT16 CsPresent; + UINT8 RegIndex; + UINT8 Cs1; + UINT8 Cs2; + + if (!MemNGetPlatformCfgNb (NBPtr)) { + IDS_ERROR_TRAP; + } + + MemNProgramPlatformSpecNb (NBPtr); + if (!NBPtr->PsPtr->MemPDoPs (NBPtr)) { + IDS_ERROR_TRAP; + } + + MemProcessConditionalOverrides (NBPtr->RefPtr->PlatformMemoryConfiguration, NBPtr, PSO_ACTION_ODT, ALL_DIMMS); + + if (NBPtr->MCTPtr->GangedMode) { + MemNSwitchDCTNb (NBPtr, 1); + if (!MemNGetPlatformCfgNb (NBPtr)) { + IDS_ERROR_TRAP; + } + MemNProgramPlatformSpecNb (NBPtr); + MemNSwitchDCTNb (NBPtr, 0); + } + + //====================================================================== + // Disable unused MemClk to save power + //====================================================================== + // + MemClkDis = 0; + MemoryAllClocks = UserOptions.CfgMemoryAllClocksOn; + IDS_OPTION_HOOK (IDS_ALL_MEMORY_CLOCK, &MemoryAllClocks, &(NBPtr->MemPtr->StdHeader)); + if (!MemoryAllClocks) { + // Special Jedec SPD diagnostic bit - "enable all clocks" + if (!NBPtr->MCTPtr->Status[SbDiagClks]) { + MemClkDisMap = FindPSOverrideEntry (NBPtr->RefPtr->PlatformMemoryConfiguration, PSO_MEMCLK_DIS, NBPtr->MCTPtr->SocketId, MemNGetSocketRelativeChannelNb (NBPtr, NBPtr->Dct, 0)); + if (MemClkDisMap == NULL) { + MemClkDisMap = NBPtr->ChannelPtr->MemClkDisMap; + } + + // Turn off the unused CS clocks + CsPresent = NBPtr->DCTPtr->Timings.CsPresent; + + if (NBPtr->IsSupported[CheckMemClkCSPresent]) { + if (NBPtr->ChannelPtr->RegDimmPresent != 0) { + // All DDR3 RDIMM use only one MEMCLOCK from edge finger to the register + // regardless of how many Ranks are on the DIMM (Single, Dual or Quad) + CsPresent = (CsPresent | (CsPresent >> 1)) & 0x5555; + } + } + for (i = 0; i < 8; i++) { + if ((CsPresent & MemClkDisMap[i]) == 0) { + MemClkDis |= (UINT8) (1 << i); + } + } + //Chiplet power down + for (RegIndex = 0; RegIndex < GET_SIZE_OF (ChipletPDRegs); RegIndex++) { + if ((NBPtr->Dct == 1) && (RegIndex >= 2)) { + Cs1 = MemClkDisMap[ChipletPDClkDisMap[RegIndex + 2][0]]; + Cs2 = MemClkDisMap[ChipletPDClkDisMap[RegIndex + 2][1]]; + } else { + Cs1 = MemClkDisMap[ChipletPDClkDisMap[RegIndex][0]]; + Cs2 = MemClkDisMap[ChipletPDClkDisMap[RegIndex][1]]; + } + if ((CsPresent & (UINT16) (Cs1 | Cs2)) == 0) { + MemNSetBitFieldNb (NBPtr, ChipletPDRegs[RegIndex], (MemNGetBitFieldNb (NBPtr, ChipletPDRegs[RegIndex]) | 0x10)); + } + } + } + } + MemNSetBitFieldNb (NBPtr, BFMemClkDis, MemClkDis); + + AGESA_TESTPOINT (TPProcMemPhyCompensation, &(NBPtr->MemPtr->StdHeader)); + NBPtr->MemNInitPhyComp (NBPtr); + + MemProcessConditionalOverrides (NBPtr->RefPtr->PlatformMemoryConfiguration, NBPtr, PSO_ACTION_SLEWRATE, ALL_DIMMS); + + if (NBPtr->IsSupported[CheckDynamicDramTerm]) { + // Program DramTerm for DDR2 + if ((MemNGetBitFieldNb (NBPtr, BFDdr3Mode)) == 0) { + MemNSetBitFieldNb (NBPtr, BFDramTerm, NBPtr->PsPtr->DramTerm); + } else { + // Dynamic Dynamic DramTerm for DDR3 + // Dram Term for DDR3 may vary based on chip selects + MemNSetBitFieldNb (NBPtr, BFDramTermDyn, NBPtr->PsPtr->DynamicDramTerm); + } + } + // Program DramTerm for DDR2 + if ((MemNGetBitFieldNb (NBPtr, BFDdr3Mode)) == 0) { + MemNSetBitFieldNb (NBPtr, BFDramTerm, NBPtr->PsPtr->DramTerm); + } else { + // Dynamic Dynamic DramTerm for DDR3 + // Dram Term for DDR3 may vary based on chip selects + MemNSetBitFieldNb (NBPtr, BFDramTermDyn, NBPtr->PsPtr->DynamicDramTerm); + } + + MemFInitTableDrive (NBPtr, MTAfterPlatformSpec); + + return (BOOLEAN) (NBPtr->MCTPtr->ErrCode < AGESA_FATAL); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets platform specific config/timing values from the interface layer and + * programs them into DCT. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return TRUE - An Error value lower than AGESA_FATAL may have occurred + * @return FALSE - An Error value greater than or equal to AGESA_FATAL may have occurred + */ + +BOOLEAN +MemNPlatformSpecClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 MemClkDis; + UINT8 i; + UINT8 MemoryAllClocks; + UINT8 *MemClkDisMap; + UINT16 CsPresent; + + if (!MemNGetPlatformCfgNb (NBPtr)) { + IDS_ERROR_TRAP; + } + + MemNProgramPlatformSpecNb (NBPtr); + if (!NBPtr->PsPtr->MemPDoPs (NBPtr)) { + IDS_ERROR_TRAP; + } + + //====================================================================== + // Disable unused MemClk to save power + //====================================================================== + // + MemClkDis = 0; + MemoryAllClocks = UserOptions.CfgMemoryAllClocksOn; + IDS_OPTION_HOOK (IDS_ALL_MEMORY_CLOCK, &MemoryAllClocks, &(NBPtr->MemPtr->StdHeader)); + if (!MemoryAllClocks) { + // Special Jedec SPD diagnostic bit - "enable all clocks" + if (!NBPtr->MCTPtr->Status[SbDiagClks]) { + MemClkDisMap = FindPSOverrideEntry (NBPtr->RefPtr->PlatformMemoryConfiguration, PSO_MEMCLK_DIS, NBPtr->MCTPtr->SocketId, NBPtr->Dct); + if (MemClkDisMap == NULL) { + MemClkDisMap = NBPtr->ChannelPtr->MemClkDisMap; + } + + // Turn off unused clocks + CsPresent = NBPtr->DCTPtr->Timings.CsPresent; + + for (i = 0; i < 8; i++) { + if ((CsPresent & MemClkDisMap[i]) == 0) { + MemClkDis |= (UINT8) (1 << i); + } + } + + // Turn off unused chiplets + if ((MemClkDis & 0x3) == 0x3) { + MemNSetBitFieldNb (NBPtr, BFPhyClkConfig0, 0x0010); + } + if ((MemClkDis & 0xC) == 0xC) { + MemNSetBitFieldNb (NBPtr, BFPhyClkConfig1, 0x0010); + } + } + } + MemNSetBitFieldNb (NBPtr, BFMemClkDis, MemClkDis); + MemFInitTableDrive (NBPtr, MTAfterPlatformSpec); + + return (BOOLEAN) (NBPtr->MCTPtr->ErrCode < AGESA_FATAL); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function disables the DCT and mem clock + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNDisableDCTNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + MemNSetBitFieldNb (NBPtr, BFCKETri, 0x03); + MemNSetBitFieldNb (NBPtr, BFODTTri, 0x0F); + MemNSetBitFieldNb (NBPtr, BFChipSelTri, 0xFF); + + // To maximize power savings when DisDramInterface=1b, + // all of the MemClkDis bits should also be set. + // + MemNSetBitFieldNb (NBPtr, BFMemClkDis, 0xFF); + + MemNSetBitFieldNb (NBPtr, BFDisDramInterface, 1); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function disables the DCT and mem clock for client NB + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNDisableDCTClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + MemNSetBitFieldNb (NBPtr, BFCKETri, 0x03); + MemNSetBitFieldNb (NBPtr, BFODTTri, 0x0F); + MemNSetBitFieldNb (NBPtr, BFChipSelTri, 0xFF); + + //Wait for 24 MEMCLKs + MemUWait10ns (6, NBPtr->MemPtr); + + // To maximize power savings when DisDramInterface=1b, + // all of the MemClkDis bits should also be set. + // + MemNSetBitFieldNb (NBPtr, BFMemClkDis, 0xFF); + + MemNSetBitFieldNb (NBPtr, BFDramPhyStatusReg, 0x80800000); + + MemNSetBitFieldNb (NBPtr, BFDisDramInterface, 1); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function initializes the DRAM devices on all DCTs at the same time + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNStartupDCTNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + // 1. Ensure F2x[1, 0]9C_x08[DisAutoComp] = 1. + // 2. BIOS waits 5 us for the disabling of the compensation engine to complete. + // DisAutoComp is still being set since InitPhyComp + + if (NBPtr->MCTPtr->NodeMemSize != 0) { + // Init MemClk frequency + MemNBrdcstSetNb (NBPtr, BFMemClkFreqVal, 1); + + + AGESA_TESTPOINT (TpProcMemBeforeDramInit, &(NBPtr->MemPtr->StdHeader)); + NBPtr->MemNBeforeDramInitNb (NBPtr); + + AGESA_TESTPOINT (TpProcMemDramInit, &(NBPtr->MemPtr->StdHeader)); + NBPtr->FeatPtr->DramInit (NBPtr->TechPtr); + } + + // 7. Program F2x[1, 0]9C_x08[DisAutoComp] = 0. + // 8. BIOS must wait 750 us for the phy compensation engine + // to reinitialize. + // DisAutoComp will be cleared after DramEnabled turns to 1 + +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function initializes the DRAM devices on all DCTs at the same time + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNStartupDCTClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 Dct; + + // Update NB frequency for startup DDR speed + NBPtr->ChangeNbFrequency (NBPtr); + + // Program D18F2x[1,0]9C_x0000_000B = 80000000h. #109999. + MemNBrdcstSetNb (NBPtr, BFDramPhyStatusReg, 0x80000000); + + // Program D18F2x[1,0]9C_x0D0F_E013[PllRegWaitTime] = 0118h. #193770. + MemNBrdcstSetNb (NBPtr, BFPllRegWaitTime, 0x118); + + // Phy Voltage Level Programming + MemNPhyVoltageLevelClientNb (NBPtr); + + // Run frequency change sequence + MemNBrdcstSetNb (NBPtr, BFPllLockTime, NBPtr->FreqChangeParam->PllLockTimeDefault); + MemNBrdcstSetNb (NBPtr, BFMemClkFreq, NBPtr->GetMemClkFreqId (NBPtr, NBPtr->DCTPtr->Timings.Speed)); + MemNProgramNbPstateDependentRegistersClientNb (NBPtr); + MemNBrdcstSetNb (NBPtr, BFMemClkFreqVal, 1); + MemNBrdcstSetNb (NBPtr, BFPllLockTime, 0x000F); + + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + IDS_HDT_CONSOLE ("!\tDct %d\n", Dct); + + // Phy fence programming + AGESA_TESTPOINT (TpProcMemPhyFenceTraining, &(NBPtr->MemPtr->StdHeader)); + NBPtr->PhyFenceTraining (NBPtr); + + // Phy compensation initialization + AGESA_TESTPOINT (TPProcMemPhyCompensation, &(NBPtr->MemPtr->StdHeader)); + NBPtr->MemNInitPhyComp (NBPtr); + } + } + + // Run DramInit sequence + AGESA_TESTPOINT (TpProcMemDramInit, &(NBPtr->MemPtr->StdHeader)); + NBPtr->FeatPtr->DramInit (NBPtr->TechPtr); + +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * MemNChangeFrequencyHy: + * + * This function change MemClk frequency to the value that is specified by DCTPtr->Timings.Speed + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNChangeFrequencyNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + MEM_TECH_BLOCK *TechPtr; + UINT8 Dct; + UINT8 ChipSel; + UINT32 Dummy; + + TechPtr = NBPtr->TechPtr; + if (NBPtr->IsSupported[CheckDisDllShutdownSR] && !(NBPtr->IsSupported[SetDllShutDown])) { + // #107421 + MemNBrdcstSetNb (NBPtr, BFDisDllShutdownSR, 1); + } + + //Program F2x[1,0]90[EnterSelfRefresh]=1. + //Wait until the hardware resets F2x[1,0]90[EnterSelfRefresh]=0. + MemNBrdcstSetNb (NBPtr, BFEnterSelfRef, 1); + MemNPollBitFieldNb (NBPtr, BFEnterSelfRef, 0, PCI_ACCESS_TIMEOUT, TRUE); + + //Program F2x9C_x08[DisAutoComp]=1 + MemNSwitchDCTNb (NBPtr, 0); + MemNSetBitFieldNb (NBPtr, BFDisAutoComp, 1); + + //Program F2x[1, 0]94[MemClkFreqVal] = 0. + MemNBrdcstSetNb (NBPtr, BFMemClkFreqVal, 0); + + //Program F2x[1, 0]94[MemClkFreq] to specify the target MEMCLK frequency. + MemNBrdcstSetNb (NBPtr, BFMemClkFreq, NBPtr->GetMemClkFreqId (NBPtr, NBPtr->DCTPtr->Timings.Speed)); + + //Program F2x[1, 0]94[MemClkFreqVal] = 1. + MemNBrdcstSetNb (NBPtr, BFMemClkFreqVal, 1); + + //Wait until F2x[1, 0]94[FreqChgInProg]=0. + MemNPollBitFieldNb (NBPtr, BFFreqChgInProg, 0, PCI_ACCESS_TIMEOUT, TRUE); + + if (NBPtr->IsSupported[CheckPhyFenceTraining]) { + //Perform Phy Fence retraining after frequency changed + AGESA_TESTPOINT (TpProcMemPhyFenceTraining, &(NBPtr->MemPtr->StdHeader)); + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + IDS_HDT_CONSOLE ("!\tDct %d\n", Dct); + AGESA_TESTPOINT (TpProcMemPhyFenceTraining, &(NBPtr->MemPtr->StdHeader)); + MemNPhyFenceTrainingNb (NBPtr); + } + } + } + + //Program F2x9C_x08[DisAutoComp]=0 + MemNSwitchDCTNb (NBPtr, 0); + MemNSetBitFieldNb (NBPtr, BFDisAutoComp, 0); + + //Program F2x[1,0]90[ExitSelfRef]=1 for both DCTs. + //Wait until the hardware resets F2x[1, 0]90[ExitSelfRef]=0. + MemNBrdcstSetNb (NBPtr, BFExitSelfRef, 1); + MemNPollBitFieldNb (NBPtr, BFExitSelfRef, 0, PCI_ACCESS_TIMEOUT, TRUE); + + if (NBPtr->MCTPtr->Status[SbRegistered]) { + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + TechPtr->FreqChgCtrlWrd (TechPtr); + } + } + } + + //wait for 500 MCLKs after ExitSelfRef, 500*2.5ns=1250ns + MemUWait10ns (125, NBPtr->MemPtr); + + if (NBPtr->IsSupported[CheckDisDllShutdownSR] && !(NBPtr->IsSupported[SetDllShutDown])) { + // #107421 + MemNBrdcstSetNb (NBPtr, BFDisDllShutdownSR, 0); + } + + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + IDS_HDT_CONSOLE ("!\tDct %d\n", Dct); + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + + //9.Configure the DCT to send initialization MR commands: + // BIOS must reprogram Twr, Tcwl, and Tcl based on the new MEMCLK frequency. + // Program F2x[1, 0]7C similar to step #2 in Pass 1 above for the new Dimm values. + TechPtr->AutoCycTiming (TechPtr); + if (!MemNPlatformSpecNb (NBPtr)) { + IDS_ERROR_TRAP; + } + + for (ChipSel = 0; ChipSel < MAX_CS_PER_CHANNEL; ChipSel++) { + if (NBPtr->IsSupported[CheckGetMCTSysAddr]) { + if (MemNGetMCTSysAddrNb (NBPtr, ChipSel, &Dummy)) { + // if chip select present + TechPtr->SendAllMRCmds (TechPtr, ChipSel); + // NOTE: wait 512 clocks for DLL-relock + MemUWait10ns (50000, NBPtr->MemPtr); // wait 500us + } + } + if (NBPtr->IsSupported[CheckSendAllMRCmds]) { + if (MemNGetMCTSysAddrNb (NBPtr, ChipSel, &Dummy)) { + // if chip select present + TechPtr->SendAllMRCmds (TechPtr, ChipSel); + } + } + } + if ((NBPtr->DCTPtr->Timings.Speed == DDR1600_FREQUENCY) && (NBPtr->IsSupported[CheckDllSpeedUp])) { + MemNSetBitFieldNb (NBPtr, BFPhy0x0D080F11, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D080F11) | 0x2000)); + MemNSetBitFieldNb (NBPtr, BFPhy0x0D080F10, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D080F10) | 0x2000)); + MemNSetBitFieldNb (NBPtr, BFPhy0x0D088F30, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D088F30) | 0x2000)); + MemNSetBitFieldNb (NBPtr, BFPhy0x0D08C030, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D08C030) | 0x2000)); + if (Dct == 0) { + MemNSetBitFieldNb (NBPtr, BFPhy0x0D082F30, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D082F30) | 0x2000)); + } + // NOTE: wait 512 clocks for DLL-relock + MemUWait10ns (50000, NBPtr->MemPtr); // wait 500us + } + } + } + // Re-enable phy compensation since it had been disabled during InitPhyComp + MemNSwitchDCTNb (NBPtr, 0); + MemNSetBitFieldNb (NBPtr, BFDisAutoComp, 0); +} + + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function ramp up frequency the next level if it have not reached + * its TargetSpeed yet. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return TRUE - No fatal error occurs. + * @return FALSE - Fatal error occurs. + */ + +BOOLEAN +MemNRampUpFrequencyNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + CONST UINT16 FreqList[] = { + DDR400_FREQUENCY, + DDR533_FREQUENCY, + DDR667_FREQUENCY, + DDR800_FREQUENCY, + DDR1066_FREQUENCY, + DDR1333_FREQUENCY, + DDR1600_FREQUENCY, + DDR1866_FREQUENCY + }; + UINT8 Dct; + UINT8 i; + UINT16 NewSpeed; + DIE_STRUCT *MCTPtr; + + MCTPtr = NBPtr->MCTPtr; + + // Do not change frequency when it is already at TargetSpeed + if (NBPtr->DCTPtr->Timings.Speed == NBPtr->DCTPtr->Timings.TargetSpeed) { + return TRUE; + } + + // Find the next supported frequency level + NewSpeed = NBPtr->DCTPtr->Timings.TargetSpeed; + for (i = 0; i < (GET_SIZE_OF (FreqList) - 1); i++) { + if (NBPtr->DCTPtr->Timings.Speed == FreqList[i]) { + NewSpeed = FreqList[i + 1]; + break; + } + } + ASSERT (i < (GET_SIZE_OF (FreqList) - 1)); + ASSERT (NewSpeed <= NBPtr->DCTPtr->Timings.TargetSpeed); + + // BIOS must program both DCTs to the same frequency. + IDS_HDT_CONSOLE ("\nMemClkFreq changed: %d MHz", NBPtr->DCTPtr->Timings.Speed); + for (Dct = 0; Dct < MCTPtr->DctCount; Dct++) { + NBPtr->SwitchDCT (NBPtr, Dct); + NBPtr->DCTPtr->Timings.Speed = NewSpeed; + } + IDS_HDT_CONSOLE (" -> %d MHz", NewSpeed); + + IDS_OPTION_HOOK (IDS_BEFORE_MEM_FREQ_CHG, NBPtr, &(NBPtr->MemPtr->StdHeader)); + NBPtr->ChangeFrequency (NBPtr); + + return (BOOLEAN) (MCTPtr->ErrCode < AGESA_FATAL); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function uses calculated values from DCT.Timings structure to + * program its registers. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNProgramCycTimingsNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + CONST CTENTRY TmgAdjTab[] = { + // BitField, Min, Max, Bias, Ratio_x2 + {BFTcl, 4, 12, 4, 2}, + {BFTrcd, 5, 12, 5, 2}, + {BFTrp, 5, 12, 5, 2}, + {BFTrtp, 4, 7, 4, 2}, + {BFTras, 15, 30, 15, 2}, + {BFTrc, 11, 42, 11, 2}, + {BFTwrDDR3, 5, 12, 4, 2}, + {BFTrrd, 4, 7, 4, 2}, + {BFTwtr, 4, 7, 4, 2}, + {BFFourActWindow, 16, 32, 14, 1} + }; + + DCT_STRUCT *DCTPtr; + UINT8 *MiniMaxTmg; + UINT8 *MiniMaxTrfc; + UINT8 Value8; + UINT8 j; + BIT_FIELD_NAME BitField; + + DCTPtr = NBPtr->DCTPtr; + + //====================================================================== + // Program turnaround timings to their max during DRAM init and training + //====================================================================== + // + MemNSetBitFieldNb (NBPtr, BFNonSPD, 0x28FF); + + MemNSetBitFieldNb (NBPtr, BFNonSPDHi, 0x2A); + + //====================================================================== + // Program DRAM Timing values + //====================================================================== + // + MiniMaxTmg = &DCTPtr->Timings.CasL; + for (j = 0; j < GET_SIZE_OF (TmgAdjTab); j++) { + BitField = TmgAdjTab[j].BitField; + + if (MiniMaxTmg[j] < TmgAdjTab[j].Min) { + MiniMaxTmg[j] = TmgAdjTab[j].Min; + } else if (MiniMaxTmg[j] > TmgAdjTab[j].Max) { + MiniMaxTmg[j] = TmgAdjTab[j].Max; + } + + Value8 = (UINT8) MiniMaxTmg[j]; + + if (BitField == BFTwrDDR3) { + Value8 = (Value8 == 10) ? 9 : (Value8 == 12) ? 10 : Value8; + } else if (BitField == BFTrtp) { + Value8 = (DCTPtr->Timings.Speed <= DDR1066_FREQUENCY) ? 4 : (DCTPtr->Timings.Speed == DDR1333_FREQUENCY) ? 5 : 6; + } + + Value8 = Value8 - TmgAdjTab[j].Bias; + Value8 = (Value8 * TmgAdjTab[j].Ratio_x2) >> 1; + + MemNSetBitFieldNb (NBPtr, BitField, Value8); + } + + MiniMaxTrfc = &DCTPtr->Timings.Trfc0; + for (j = 0; j < 4; j++) { + MemNSetBitFieldNb (NBPtr, BFTrfc0 + j, MiniMaxTrfc[j]); + } + + MemNSetBitFieldNb (NBPtr, BFTcwl, ((DCTPtr->Timings.Speed >= DDR800_FREQUENCY) ? + (NBPtr->GetMemClkFreqId (NBPtr, DCTPtr->Timings.Speed) - 3) : 0)); + + MemNSetBitFieldNb (NBPtr, BFTref, 2); // 7.8 us + + //====================================================================== + // DRAM MRS Register, set ODT + //====================================================================== + // + // DrvImpCtrl: drive impedance control.01b(34 ohm driver; Ron34 = Rzq/7) + MemNSetBitFieldNb (NBPtr, BFDrvImpCtrl, 1); + + // burst length control + if (NBPtr->MCTPtr->Status[Sb128bitmode]) { + MemNSetBitFieldNb (NBPtr, BFBurstCtrl, 2); + } + + // ASR=1, auto self refresh; SRT=0 + MemNSetBitFieldNb (NBPtr, BFASR, 1); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function uses calculated values from DCT.Timings structure to + * program its registers. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNProgramCycTimingsClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + CONST CTENTRY TmgAdjTab[] = { + // BitField, Min, Max, Bias, Ratio_x2 + {BFTcl, 5, 14, 4, 2}, + {BFTrcd, 5, 14, 5, 2}, + {BFTrp, 5, 14, 5, 2}, + {BFTrtp, 4, 8, 4, 2}, + {BFTras, 15, 36, 15, 2}, + {BFTrc, 20, 49, 11, 2}, + {BFTwrDDR3, 5, 16, 4, 2}, + {BFTrrd, 4, 8, 4, 2}, + {BFTwtr, 4, 8, 4, 2}, + {BFFourActWindow, 16, 40, 14, 1} + }; + + DCT_STRUCT *DCTPtr; + UINT8 *MiniMaxTmg; + UINT8 *MiniMaxTrfc; + UINT8 Value8; + UINT8 j; + UINT8 Tcwl; + BIT_FIELD_NAME BitField; + + DCTPtr = NBPtr->DCTPtr; + + //====================================================================== + // Program DRAM Timing values + //====================================================================== + // + MiniMaxTmg = &DCTPtr->Timings.CasL; + for (j = 0; j < GET_SIZE_OF (TmgAdjTab); j++) { + BitField = TmgAdjTab[j].BitField; + + if (MiniMaxTmg[j] < TmgAdjTab[j].Min) { + MiniMaxTmg[j] = TmgAdjTab[j].Min; + } else if (MiniMaxTmg[j] > TmgAdjTab[j].Max) { + MiniMaxTmg[j] = TmgAdjTab[j].Max; + } + + Value8 = (UINT8) MiniMaxTmg[j]; + + if (BitField == BFTwrDDR3) { + Value8 = (Value8 >= 10) ? (((Value8 + 1) / 2) + 4) : Value8; + } + + Value8 = Value8 - TmgAdjTab[j].Bias; + Value8 = (Value8 * TmgAdjTab[j].Ratio_x2) >> 1; + + MemNSetBitFieldNb (NBPtr, BitField, Value8); + } + + MiniMaxTrfc = &DCTPtr->Timings.Trfc0; + for (j = 0; j < 4; j++) { + MemNSetBitFieldNb (NBPtr, BFTrfc0 + j, MiniMaxTrfc[j]); + } + + Tcwl = (UINT8) (DCTPtr->Timings.Speed / 133) + 2; + MemNSetBitFieldNb (NBPtr, BFTcwl, ((Tcwl > 5) ? (Tcwl - 5) : 0)); + + MemNSetBitFieldNb (NBPtr, BFTref, 2); // Tref = 7.8 us + + MemNSetBitFieldNb (NBPtr, BFDbeSkidBufDis, (DCTPtr->Timings.Trcd > 10) ? 0 : 1); + + MemNSetBitFieldNb (NBPtr, BFRdOdtTrnOnDly, (DCTPtr->Timings.CasL > Tcwl) ? (DCTPtr->Timings.CasL - Tcwl) : 0); + + // Set ProcOdtAdv + if (DCTPtr->Timings.Speed <= DDR1333_FREQUENCY) { + MemNSetBitFieldNb (NBPtr, BFPhy0x0D0F0F13, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D0F0F13) & 0xBFFF)); + } else { + MemNSetBitFieldNb (NBPtr, BFPhy0x0D0F0F13, (MemNGetBitFieldNb (NBPtr, BFPhy0x0D0F0F13) | 0x4000)); + } +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets platform specific settings for the current channel + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return TRUE - All platform types defined have initialized successfully + * @return FALSE - At least one of the platform types gave not been initialized successfully + */ + +BOOLEAN +MemNGetPlatformCfgNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 p; + + for (p = 0; p < MAX_PLATFORM_TYPES; p++) { + ASSERT (NBPtr->MemPtr->GetPlatformCfg[p] != NULL); + if (NBPtr->MemPtr->GetPlatformCfg[p] (NBPtr->MemPtr, NBPtr->MCTPtr->SocketId, NBPtr->ChannelPtr) == AGESA_SUCCESS) { + break; + } + } + return (p < MAX_PLATFORM_TYPES); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function retrieves the Max latency parameters + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @param[in] *MinDlyPtr - Pointer to variable to store the Minimum Delay value + * @param[in] *MaxDlyPtr - Pointer to variable to store the Maximum Delay value + * @param[in] *DlyBiasPtr - Pointer to variable to store Delay Bias value + * @param[in] MaxRcvEnDly - Maximum receiver enable delay value + */ + +VOID +MemNGetMaxLatParamsNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT16 MaxRcvEnDly, + IN OUT UINT16 *MinDlyPtr, + IN OUT UINT16 *MaxDlyPtr, + IN OUT UINT16 *DlyBiasPtr + ) +{ + *MinDlyPtr = (MemNTotalSyncComponentsNb (NBPtr) + (MaxRcvEnDly >> 5)) * 2; + MemNQuarterMemClk2NClkNb (NBPtr, MinDlyPtr); + + *MaxDlyPtr = 0x3FF; + + *DlyBiasPtr = 4; + MemNQuarterMemClk2NClkNb (NBPtr, DlyBiasPtr); // 1 MEMCLK Margin + + *DlyBiasPtr += 1; // add 1 NCLK +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function retrieves the Max latency parameters + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @param[in] *MinDlyPtr - Pointer to variable to store the Minimum Delay value + * @param[in] *MaxDlyPtr - Pointer to variable to store the Maximum Delay value + * @param[in] *DlyBiasPtr - Pointer to variable to store Delay Bias value + * @param[in] MaxDlyForMaxRdLat - Maximum receiver enable delay value + * + */ + +VOID +MemNGetMaxLatParamsClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT16 MaxDlyForMaxRdLat, + IN OUT UINT16 *MinDlyPtr, + IN OUT UINT16 *MaxDlyPtr, + IN OUT UINT16 *DlyBiasPtr + ) +{ + UINT32 P; + UINT32 T; + UINT32 MemClkPeriod; + + T = MemNTotalSyncComponentsClientNb (NBPtr); + + // P = P + CEIL(MAX (total delay in DqsRcvEn + RdDqsTime)) + P = (MaxDlyForMaxRdLat + 31) / 32; + + MemClkPeriod = 1000000 / NBPtr->DCTPtr->Timings.Speed; + + *MinDlyPtr = (UINT16) (((((P * MemClkPeriod + 1) / 2) + T) * NBPtr->NBClkFreq + 999999) / 1000000); + + *MinDlyPtr += 4; + + *MaxDlyPtr = 0x50; + + *DlyBiasPtr = 3; + + // Need to set ForceCasToSlot0=1 before MaxRdLatency training + MemNSetBitFieldNb (NBPtr, BFForceCasToSlot0, 1); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function sets the maximum round-trip latency in the system from the processor to the DRAM + * devices and back. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] MaxRcvEnDly - Maximum receiver enable delay value + * + */ + +VOID +MemNSetMaxLatencyNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT16 MaxRcvEnDly + ) +{ + UINT16 SubTotal; + + AGESA_TESTPOINT (TpProcMemRcvrCalcLatency, &(NBPtr->MemPtr->StdHeader)); + + SubTotal = 0xC8; // init value for MaxRdLat used in training + + + if (MaxRcvEnDly != 0xFFFF) { + // Get all sync components BKDG steps 1-5 + SubTotal = MemNTotalSyncComponentsNb (NBPtr); + + // Add the maximum (worst case) delay value of DqsRcvEnGrossDelay + // that exists across all DIMMs and byte lanes. + // + SubTotal += MaxRcvEnDly >> 5; + + + // Add 14.5 to the sub-total. 14.5 represents part of the processor + // specific constant delay value in the DRAM clock domain. + // + SubTotal <<= 1; // scale 1/2 MemClk to 1/4 MemClk + SubTotal += 29; // add 14.5 1/2 MemClk + + // Convert the sub-total (in 1/2 MEMCLKs) to northbridge clocks (NCLKs) + // as follows (assuming DDR400 and assuming that no P-state or link speed + // changes have occurred). + // + MemNQuarterMemClk2NClkNb (NBPtr, &SubTotal); + + // Add 2 NCLKs to the sub-total. 2 represents part of the processor + // specific constant value in the northbridge clock domain. + // + SubTotal += 2; + } + + NBPtr->DCTPtr->Timings.MaxRdLat = SubTotal; + // Program the F2x[1, 0]78[MaxRdLatency] register with the total delay value + IDS_HDT_CONSOLE ("\t\tMaxRdLat: %03x\n", SubTotal); + MemNSetBitFieldNb (NBPtr, BFMaxLatency, SubTotal); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function sends the ZQCL command + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNSendZQCmdNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + // 1.Program MrsAddress[10]=1 + MemNSetBitFieldNb (NBPtr, BFMrsAddress, (UINT32)1 << 10); + + // 2.Set SendZQCmd=1 + MemNSetBitFieldNb (NBPtr, BFSendZQCmd, 1); + + // 3.Wait for SendZQCmd=0 + MemNPollBitFieldNb (NBPtr, BFSendZQCmd, 0, PCI_ACCESS_TIMEOUT, FALSE); + + // 4.Wait 512 MEMCLKs + MemUWait10ns (128, NBPtr->MemPtr); // 512*2.5ns=1280, wait 1280ns +} + + +/*---------------------------------------------------------------------------- + * LOCAL FUNCTIONS + * + *---------------------------------------------------------------------------- + */ + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function is used to create the DRAM map + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + */ + +VOID +STATIC +MemNAfterStitchMemNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + if (NBPtr->MCTPtr->GangedMode) { + NBPtr->MCTPtr->NodeMemSize = NBPtr->DCTPtr->Timings.DctMemSize; + NBPtr->MCTPtr->NodeSysLimit = NBPtr->MCTPtr->NodeMemSize - 1; + NBPtr->MCTPtr->DctData[1].Timings.CsPresent = NBPtr->DCTPtr->Timings.CsPresent; + NBPtr->MCTPtr->DctData[1].Timings.CsEnabled = NBPtr->DCTPtr->Timings.CsEnabled; + NBPtr->MCTPtr->DctData[1].Timings.DctMemSize = NBPtr->DCTPtr->Timings.DctMemSize; + } else { + // In unganged mode, add DCT0 and DCT1 to NodeMemSize + NBPtr->MCTPtr->NodeMemSize += NBPtr->DCTPtr->Timings.DctMemSize; + NBPtr->MCTPtr->NodeSysLimit = NBPtr->MCTPtr->NodeMemSize - 1; + } +} + + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function Return the binary value of tfaw associated with + * the index k + * + * @param[in] k value + * + * @return F[k], in Binary MHz. + */ + +UINT8 +MemNGet1KTFawTkNb ( + IN UINT8 k + ) +{ + CONST UINT8 Tab1KTfawTK[] = {0, 8, 10, 13, 14, 19}; + ASSERT (k <= 5); + return Tab1KTfawTK[k]; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function Return the binary value of the 2KTFaw associated with + * the index k + * + * @param[in] k value + * + * @return 2KTFaw converted based on k. + */ + +UINT8 +MemNGet2KTFawTkNb ( + IN UINT8 k + ) +{ + CONST UINT8 Tab2KTfawTK[] = {0, 10, 14, 17, 18, 24}; + ASSERT (k <= 5); + return Tab2KTfawTK[k]; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function converts the sub-total (in 1/4 MEMCLKs) to northbridge clocks (NCLKs) + * (assuming DDR400 and assuming that no P-state or link speed + * changes have occurred). + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in,out] *SubTotalPtr - pointer to Sub-Total + */ + +VOID +STATIC +MemNQuarterMemClk2NClkNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN OUT UINT16 *SubTotalPtr + ) +{ + UINT32 NBFreq; + UINT32 MemFreq; + + // Multiply SubTotal by NB COF + NBFreq = (MemNGetBitFieldNb (NBPtr, BFNbFid) + 4) * 200; + // Divide SubTotal by 4 times current MemClk frequency + MemFreq = NBPtr->DCTPtr->Timings.Speed * 4; + *SubTotalPtr = (UINT16) (((NBFreq * (*SubTotalPtr)) + MemFreq - 1) / MemFreq); // round up +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the total of sync components for Max Read Latency calculation + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return Total in 1/2 MEMCLKs + */ + +UINT16 +MemNTotalSyncComponentsNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT16 SubTotal; + + // Multiply the CAS Latency by two to get a number of 1/2 MEMCLKs UINTs. + SubTotal = (UINT16) MemNGetBitFieldNb (NBPtr, BFTcl) + 1; + if ((MemNGetBitFieldNb (NBPtr, BFDdr3Mode)) != 0) { + SubTotal += 3; + } + SubTotal *= 2; + + // If registered DIMMs are being used then add 1 MEMCLK to the sub-total. + if ((MemNGetBitFieldNb (NBPtr, BFUnBuffDimm)) == 0) { + SubTotal += 2; + } + + // If (F2x[1, 0]9C_x04[AddrCmdSetup] and F2x[1, 0]9C_x04[CsOdtSetup] and F2x[1, 0]9C_x04[Cke-Setup] = 0) then K = K + 1 + // If (F2x[1, 0]9C_x04[AddrCmdSetup] or F2x[1, 0]9C_x04[CsOdtSetup] or F2x[1, 0]9C_x04[CkeSetup] = 1) then K = K + 2 + if ((MemNGetBitFieldNb (NBPtr, BFAddrTmgControl) & 0x0202020) == 0) { + SubTotal += 1; + } else { + SubTotal += 2; + } + + // If the F2x[1, 0]78[RdPtrInit] field is 4, 5, 6 or 7 MEMCLKs, + // then add 4, 3, 2, or 1 MEMCLKs, respectively to the sub-total. + // + SubTotal = SubTotal + (8 - (UINT16) MemNGetBitFieldNb (NBPtr, BFRdPtrInit)); + + return SubTotal; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function swaps bits for OnDimmMirror support + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNSwapBitsNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 ChipSel; + UINT32 MRSReg; + + ChipSel = (UINT8) MemNGetBitFieldNb (NBPtr, BFMrsChipSel); + if ((ChipSel & 1) != 0) { + MRSReg = MemNGetBitFieldNb (NBPtr, BFDramInitRegReg); + if ((NBPtr->DCTPtr->Timings.DimmMirrorPresent & (1 << (ChipSel >> 1))) != 0) { + MRSReg = (MRSReg & 0xFFFCFE07) | ((MRSReg&0x100A8) << 1) | ((MRSReg&0x20150) >> 1); + MemNSetBitFieldNb (NBPtr, BFDramInitRegReg, MRSReg); + } + } +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * Programs Address/command timings, driver strengths, and tri-state fields. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ +VOID +MemNProgramPlatformSpecNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + CONST UINT8 PinType[3] = {PSO_CKE_TRI, PSO_ODT_TRI, PSO_CS_TRI}; + CONST UINT8 TabSize[3] = { 2, 4, 8}; + CONST BIT_FIELD_NAME BitField[3] = { BFCKETri, BFODTTri, BFChipSelTri}; + UINT8 *TabPtr; + UINT8 i; + UINT8 k; + UINT8 Value; + //=================================================================== + // Tristate unused CKE, ODT and chip select to save power + //=================================================================== + // + TabPtr = NULL; + for (k = 0; k < sizeof (PinType); k++) { + if (NBPtr->IsSupported[CheckFindPSOverideWithSocket]) { + TabPtr = FindPSOverrideEntry (NBPtr->RefPtr->PlatformMemoryConfiguration, PinType[k], NBPtr->MCTPtr->SocketId, MemNGetSocketRelativeChannelNb (NBPtr, NBPtr->Dct, 0)); + } + if (NBPtr->IsSupported[CheckFindPSDct]) { + TabPtr = FindPSOverrideEntry (NBPtr->RefPtr->PlatformMemoryConfiguration, PinType[k], NBPtr->MCTPtr->SocketId, NBPtr->Dct); + } + if (TabPtr == NULL) { + switch (k) { + case 0: + TabPtr = NBPtr->ChannelPtr->CKETriMap; + break; + case 1: + TabPtr = NBPtr->ChannelPtr->ODTTriMap; + break; + case 2: + TabPtr = NBPtr->ChannelPtr->ChipSelTriMap; + break; + default: + IDS_ERROR_TRAP; + } + } + ASSERT (TabPtr != NULL); + + Value = 0; + for (i = 0; i < TabSize[k]; i++) { + if ((NBPtr->DCTPtr->Timings.CsPresent & TabPtr[i]) == 0) { + Value |= (UINT8) (1 << i); + } + } + MemNSetBitFieldNb (NBPtr, BitField[k], Value); + } + NBPtr->MemNBeforePlatformSpecNb (NBPtr); + + //=================================================================== + // Program Address/Command timings and driver strength + //=================================================================== + // + MemProcessConditionalOverrides (NBPtr->RefPtr->PlatformMemoryConfiguration, NBPtr, PSO_ACTION_ADDRTMG, ALL_DIMMS); + MemProcessConditionalOverrides (NBPtr->RefPtr->PlatformMemoryConfiguration, NBPtr, PSO_ACTION_ODCCONTROL, ALL_DIMMS); + + MemNSetBitFieldNb (NBPtr, BFSlowAccessMode, (NBPtr->ChannelPtr->SlowMode) ? 1 : 0); + MemNSetBitFieldNb (NBPtr, BFODCControl, NBPtr->ChannelPtr->DctOdcCtl); + MemNSetBitFieldNb (NBPtr, BFAddrTmgControl, NBPtr->ChannelPtr->DctAddrTmg); + + if (NBPtr->IsSupported[CheckODTControls]) { + MemNSetBitFieldNb (NBPtr, BFPhyRODTCSLow, NBPtr->ChannelPtr->PhyRODTCSLow); + MemNSetBitFieldNb (NBPtr, BFPhyRODTCSHigh, NBPtr->ChannelPtr->PhyRODTCSHigh); + MemNSetBitFieldNb (NBPtr, BFPhyWODTCSLow, NBPtr->ChannelPtr->PhyWODTCSLow); + MemNSetBitFieldNb (NBPtr, BFPhyWODTCSHigh, NBPtr->ChannelPtr->PhyWODTCSHigh); + } +} +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the Trdrd value + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return Trdrd value + */ + +UINT8 +MemNGetTrdrdNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + DCT_STRUCT *DCTPtr; + INT8 Cgdd; + + DCTPtr = NBPtr->DCTPtr; + + // BIOS calculates Trdrd (in MEMCLKs) = CGDD / 2 + 3 clocks and programs F2x[1, 0]8C[Trdrd] with the + // converted field value. BIOS rounds fractional values down. + // The Critical Gross Delay Difference (CGDD) for Trdrd on any given byte lane is the largest F2x[1, + // 0]9C_x[3:0][2B:10][DqsRcvEnGrossDelay] delay of any DIMM minus the F2x[1, + // 0]9C_x[3:0][2B:10][DqsRcvEnGrossDelay] delay of any other DIMM. + + Cgdd = MemNGetOptimalCGDDNb (NBPtr, AccessRcvEnDly, AccessRcvEnDly); + DCTPtr->Timings.Trdrd = (Cgdd / 2) + 3; + + // Transfer clk to reg definition, 2T is 00b, etc. + DCTPtr->Timings.Trdrd -= 2; + if (DCTPtr->Timings.Trdrd > 8) { + DCTPtr->Timings.Trdrd = 8; + } + + return DCTPtr->Timings.Trdrd; +} + + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the Twrwr value + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return Twrwr value + */ + +UINT8 +MemNGetTwrwrNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + DCT_STRUCT *DCTPtr; + INT8 Cgdd; + + DCTPtr = NBPtr->DCTPtr; + + // Twrwr (in MEMCLKs) = CGDD / 2 + 3 clocks and programs F2x[1, 0]8C[Twrwr] with the + // converted field value. BIOS rounds fractional values down. + // On any given byte lane, the largest F2x[1, 0]9C_x[3:0][A, 7, 6, 0][2:1]:F2x[1, 0]9C_x[3:0][A, 7, 6, + // 0]3[WrDatGrossDlyByte] delay of any DIMM minus the F2x[1, 0]9C_x[3:0][A, 7, 6, 0][2:1]:F2x[1, + // 0]9C_x[3:0][A, 7, 6, 0]3[WrDatGrossDlyByte] delay of any other DIMM is equal to the Critical Gross + // Delay Difference (CGDD) for Twrwr. + + Cgdd = MemNGetOptimalCGDDNb (NBPtr, AccessWrDatDly, AccessWrDatDly); + DCTPtr->Timings.Twrwr = (Cgdd / 2) + 3; + NBPtr->TechPtr->AdjustTwrwr (NBPtr->TechPtr); + + return DCTPtr->Timings.Twrwr; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the Twrrd value. BIOS calculates Twrrd (in MEMCLKs) = CGDD / 2 - LD + 3 clocks and programs + * F2x[1, 0]8C[Twrrd] with the converted field value. BIOS rounds fractional + * values down. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return Value to be programmed to Twrrd field + * pDCT->Timings.Twrrd updated + */ + +UINT8 +MemNGetTwrrdNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + INT8 Cgdd; + INT8 Ld; + INT8 Twrrd; + DCT_STRUCT *DCTPtr; + + DCTPtr = NBPtr->DCTPtr; + + // + // For DDR3, BIOS calculates the latency difference (Ld) as equal to read CAS latency minus write CAS + // latency, in MEMCLKs (see F2x[1, 0]88[Tcl] and F2x[1, 0]84[Tcwl]) which can be a negative or positive + // value. + // For DDR2, LD is always one clock (For DDR2, Tcwl is always Tcl minus 1). + // + Ld = NBPtr->TechPtr->GetLD (NBPtr->TechPtr); + + // On any given byte lane, the largest WrDatGrossDlyByte delay of any DIMM + // minus the DqsRcvEnGrossDelay delay of any other DIMM is + // equal to the Critical Gross Delay Difference (CGDD) for Twrrd. + Cgdd = MemNGetOptimalCGDDNb (NBPtr, AccessWrDatDly, AccessRcvEnDly); + Twrrd = (Cgdd / 2) - Ld + 3; + DCTPtr->Timings.Twrrd = (UINT8) ((Twrrd >= 0) ? Twrrd : 0); + NBPtr->TechPtr->AdjustTwrrd (NBPtr->TechPtr); + + return DCTPtr->Timings.Twrrd; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the TrwtTO value + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return pDCT->Timings.TrwtTO updated + */ + +UINT8 +MemNGetTrwtTONb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + INT8 Cgdd; + INT8 Ld; + INT8 TrwtTO; + DCT_STRUCT *DCTPtr; + + DCTPtr = NBPtr->DCTPtr; + // + // For DDR3, BIOS calculates the latency difference (Ld) as equal to read CAS latency minus write CAS + // latency, in MEMCLKs (see F2x[1, 0]88[Tcl] and F2x[1, 0]84[Tcwl]) which can be a negative or positive + // value. + // For DDR2, LD is always one clock (For DDR2, Tcwl is always Tcl minus 1). + // + Ld = NBPtr->TechPtr->GetLD (NBPtr->TechPtr); + + // On any byte lane, the largest DqsRcvEnGrossDelay delay of any DIMM minus + // the WrDatGrossDlyByte delay of any other DIMM is equal to the Critical Gross + // Delay Difference (CGDD) for TrwtTO. + Cgdd = MemNGetOptimalCGDDNb (NBPtr, AccessRcvEnDly, AccessWrDatDly); + TrwtTO = (Cgdd / 2) + Ld + 3; + TrwtTO -= 2; + DCTPtr->Timings.TrwtTO = (UINT8) ((TrwtTO > 1) ? TrwtTO : 1); + + return DCTPtr->Timings.TrwtTO; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the TrwtWB value + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return TrwtWB value + */ +UINT8 +MemNGetTrwtWBNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + DCT_STRUCT *DCTPtr; + + DCTPtr = NBPtr->DCTPtr; + + // TrwtWB ensures read-to-write data-bus turnaround. + // This value should be one more than the programmed TrwtTO. + return DCTPtr->Timings.TrwtWB = DCTPtr->Timings.TrwtTO; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function converts MemClk frequency in MHz to MemClkFreq value + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] Speed - MemClk frequency in MHz + * + * @return MemClkFreq value + */ +UINT8 +MemNGetMemClkFreqIdNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT16 Speed + ) +{ + return (UINT8) ((Speed < DDR800_FREQUENCY) ? ((Speed / 66) - 3) : (Speed / 133)); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function enables swapping interleaved region feature. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] Base - Swap interleaved region base [47:27] + * @param[in] Limit - Swap interleaved region limit [47:27] + * + */ +VOID +MemNEnableSwapIntlvRgnNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT32 Base, + IN UINT32 Limit + ) +{ + UINT32 Size; + UINT32 SizeOfAlign; + + // Swapped interleaving region must be below 16G + if (Limit < (1 << (34 - 27))) { + // Adjust Base and Size to meet : + // 1. The size of the swapped region must be less than or equal to the alignment of F2x10C[IntLvRegionBase]. + // 2. Entire UMA region is swapped with interleaving region. + Size = Limit - Base; + SizeOfAlign = (UINT32) 1 << LibAmdBitScanForward (Base); + while (SizeOfAlign <= Size) { + // In case of SizeOfAlign <= Size, UmaBase -= 128MB, SizeOfIntlvrgn += 128MB. + Base -= 1; + Size += 1; + SizeOfAlign = (UINT32) 1 << LibAmdBitScanForward (Base); + } + MemNSetBitFieldNb (NBPtr, BFIntLvRgnBaseAddr, Base); + MemNSetBitFieldNb (NBPtr, BFIntLvRgnLmtAddr, (Limit - 1)); + MemNSetBitFieldNb (NBPtr, BFIntLvRgnSize, Size); + MemNSetBitFieldNb (NBPtr, BFIntLvRgnSwapEn, 1); + } +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function converts MemClk frequency in MHz to MemClkFreq value + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] Speed - MemClk frequency in MHz + * + * @return MemClkFreq value + */ +UINT8 +MemNGetMemClkFreqIdClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT16 Speed + ) +{ + return (UINT8) ((Speed > DDR400_FREQUENCY) ? ((Speed / 33) - 6) : ((Speed == DDR400_FREQUENCY) ? 2 : (Speed / 55))); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function change MemClk frequency to the value that is specified by DCTPtr->Timings.Speed + * for client NB. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNChangeFrequencyClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + MEM_TECH_BLOCK *TechPtr; + UINT8 Dct; + UINT8 ChipSel; + UINT32 Dummy; + BOOLEAN FrequencyChangeSuccess; + + TechPtr = NBPtr->TechPtr; + + // 1. Program D18F2x[1,0]9C_x0D0F_E006[PllLockTime] = 0190h for Llano + // 1. Program D18F2x9C_x0D0F_E006[PllLockTime] = 1838h for Ontario + MemNBrdcstSetNb (NBPtr, BFPllLockTime, NBPtr->FreqChangeParam->PllLockTimeDefault); + MemNBrdcstSetNb (NBPtr, BFDisDllShutdownSR, 1); + + //Program F2x[1,0]90[EnterSelfRefresh]=1. + //Wait until the hardware resets F2x[1,0]90[EnterSelfRefresh]=0. + MemNBrdcstSetNb (NBPtr, BFEnterSelfRef, 1); + MemNPollBitFieldNb (NBPtr, BFEnterSelfRef, 0, PCI_ACCESS_TIMEOUT, TRUE); + + if (NBPtr->ChangeNbFrequency (NBPtr)) { + // 2. Program D18F2x[1,0]94[MemClkFreqVal] = 0. + MemNBrdcstSetNb (NBPtr, BFMemClkFreqVal, 0); + + // 3. Program D18F2x[1,0]94[MemClkFreq] to the desired DRAM frequency. + MemNBrdcstSetNb (NBPtr, BFMemClkFreq, NBPtr->GetMemClkFreqId (NBPtr, NBPtr->DCTPtr->Timings.Speed)); + + // 4. Program D18F2x[1,0]F4_x30[DbeGskFifoNumerator] and D18F2x[1,0]F4_x31[DbeGskFifoDenominator]. + // 5. Program D18F2x[1,0]F4_x32[DataTxFifoSchedDlyNegSlot1, DataTxFifoSchedDlySlot1, + // DataTxFifoSchedDlyNegSlot0, DataTxFifoSchedDlySlot0]. See 2.10.3.2.2.1 [DCT Transmit Fifo Schedule + // Delay Programming]. + // 6. D18F2x[1,0]78[RdPtrInit] = IF (D18F2x[1,0]94[MemClkFreq] >= 667 MHz) THEN 7 ELSE 8 ENDIF (Llano) + // THEN 2 ELSE 3 ENDIF (Ontario) + MemNProgramNbPstateDependentRegistersClientNb (NBPtr); + + // 7. Program D18F2x[1,0]94[MemClkFreqVal] = 1. + MemNBrdcstSetNb (NBPtr, BFMemClkFreqVal, 1); + + FrequencyChangeSuccess = TRUE; + } else { + // If NB frequency cannot be updated, use the current speed as the target speed + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + NBPtr->DCTPtr->Timings.Speed = NBPtr->TechPtr->PrevSpeed; + NBPtr->DCTPtr->Timings.TargetSpeed = NBPtr->TechPtr->PrevSpeed; + } + FrequencyChangeSuccess = FALSE; + } + + //Program F2x[1,0]90[ExitSelfRef]=1 for both DCTs. + //Wait until the hardware resets F2x[1, 0]90[ExitSelfRef]=0. + MemNBrdcstSetNb (NBPtr, BFExitSelfRef, 1); + MemNPollBitFieldNb (NBPtr, BFExitSelfRef, 0, PCI_ACCESS_TIMEOUT, TRUE); + MemNBrdcstSetNb (NBPtr, BFDisDllShutdownSR, 0); + + // 8. IF (D18F2x[1,0]9C_x0D0F_E00A[CsrPhySrPllPdMode]==0) THEN program + // D18F2x[1,0]9C_x0D0F_E006[PllLockTime] = 0Fh. + // (CsrPhySrPllPdMode is kept 0 before training) + MemNBrdcstSetNb (NBPtr, BFPllLockTime, 0x000F); + + if (FrequencyChangeSuccess) { + // Perform Phy Fence training and Phy comp init after frequency change + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + IDS_HDT_CONSOLE ("!\tDct %d\n", Dct); + + // Phy fence programming + AGESA_TESTPOINT (TpProcMemPhyFenceTraining, &(NBPtr->MemPtr->StdHeader)); + NBPtr->PhyFenceTraining (NBPtr); + + // Phy compensation initialization + AGESA_TESTPOINT (TPProcMemPhyCompensation, &(NBPtr->MemPtr->StdHeader)); + NBPtr->MemNInitPhyComp (NBPtr); + } + } + + //====================================================================== + // Calculate and program DRAM Timings at new frequency + //====================================================================== + // + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + IDS_HDT_CONSOLE ("!\tDct %d\n", Dct); + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + + //9.Configure the DCT to send initialization MR commands: + // BIOS must reprogram Twr, Tcwl, and Tcl based on the new MEMCLK frequency. + TechPtr->AutoCycTiming (TechPtr); + if (!MemNPlatformSpecNb (NBPtr)) { + IDS_ERROR_TRAP; + } + + for (ChipSel = 0; ChipSel < MAX_CS_PER_CHANNEL; ChipSel++) { + if (MemNGetMCTSysAddrNb (NBPtr, ChipSel, &Dummy)) { + // if chip select present + TechPtr->SendAllMRCmds (TechPtr, ChipSel); + } + } + // Wait 512 clocks for DLL-relock + MemUWait10ns (50000, NBPtr->MemPtr); // wait 500us + } + } + } +} + + +/* -----------------------------------------------------------------------------*/ +CONST UINT16 PllDivTab[10] = {1, 2, 4, 8, 16, 128, 256, 1, 3, 6}; + +/** + * + * This function calculates and programs NB P-state dependent registers + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNProgramNbPstateDependentRegistersClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 i; + UINT8 Dct; + UINT8 NclkFid; + UINT16 MemClkDid; + UINT8 PllMult; + UINT8 NclkDiv; + UINT8 RdPtrInitMin; + UINT8 RdPtrInit; + UINT32 NclkPeriod; + UINT32 MemClkPeriod; + INT32 PartialSum2x; + INT32 PartialSumSlotI2x; + + NclkFid = (UINT8) (MemNGetBitFieldNb (NBPtr, BFMainPllOpFreqId) + 10); + ASSERT (MemNGetBitFieldNb (NBPtr, BFPllDiv) < 10); + MemClkDid = PllDivTab[MemNGetBitFieldNb (NBPtr, BFPllDiv)]; + PllMult = (UINT8) MemNGetBitFieldNb (NBPtr, BFPllMult); + if (MemNGetBitFieldNb (NBPtr, BFNbPs1Act) == 1) { + NclkDiv = (UINT8) MemNGetBitFieldNb (NBPtr, BFNbPs1NclkDiv); + IDS_HDT_CONSOLE ("\n\tNB P1"); + } else { + NclkDiv = (UINT8) MemNGetBitFieldNb (NBPtr, BFNbPs0NclkDiv); + IDS_HDT_CONSOLE ("\n\tNB P0"); + } + NclkPeriod = (2500 * NclkDiv) / NclkFid; + MemClkPeriod = 1000000 / NBPtr->DCTPtr->Timings.Speed; + RdPtrInitMin = RdPtrInit = (NBPtr->DCTPtr->Timings.Speed >= DDR1333_FREQUENCY) ? NBPtr->FreqChangeParam->RdPtrInit667orHigher : NBPtr->FreqChangeParam->RdPtrInitLower667; + ASSERT (NBPtr->NBClkFreq == (((UINT32) NclkFid * 400) / NclkDiv)); + + IDS_HDT_CONSOLE (" Freq: %lxMHz\n", NBPtr->NBClkFreq); + IDS_HDT_CONSOLE ("\tMemClk Freq: %dMHz\n", NBPtr->DCTPtr->Timings.Speed); + // D18F2x[1,0]78[RdPtrInit] = IF (D18F2x[1,0]94[MemClkFreq] >= 667 MHz) THEN 7 ELSE 8 ENDIF (Llano) + // THEN 2 ELSE 3 ENDIF (Ontario) + MemNBrdcstSetNb (NBPtr, BFRdPtrInit, RdPtrInit); + IDS_HDT_CONSOLE ("\t\tRdPtr: %d\n", RdPtrInit); + + // Program D18F2x[1,0]F4_x30[DbeGskFifoNumerator] and D18F2x[1,0]F4_x31[DbeGskFifoDenominator]. + MemNBrdcstSetNb (NBPtr, BFDbeGskFifoNumerator, NclkFid * MemClkDid * 16); + MemNBrdcstSetNb (NBPtr, BFDbeGskFifoDenominator, PllMult * NclkDiv); + IDS_HDT_CONSOLE ("\t\tDbeGskFifoNumerator: %d\n", NclkFid * MemClkDid * 16); + IDS_HDT_CONSOLE ("\t\tDbeGskFifoDenominator: %d\n", PllMult * NclkDiv); + + // Program D18F2x[1,0]F4_x32[DataTxFifoSchedDlyNegSlot1, DataTxFifoSchedDlySlot1, + // DataTxFifoSchedDlyNegSlot0, DataTxFifoSchedDlySlot0]. + // PartialSum = ((7 * NclkPeriod) + (1.5 * MemClkPeriod) + 520ps)*MemClkFrequency - tCWL - + // CmdSetup - PtrSeparation - 1. (Llano) + // PartialSum = ((5 * NclkPeriod) + MemClkPeriod) + 520ps)*MemClkFrequency - tCWL - + // CmdSetup - PtrSeparation - 1. (Ontario) + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + PartialSum2x = NBPtr->FreqChangeParam->NclkPeriodMul2x * NclkPeriod; + PartialSum2x += NBPtr->FreqChangeParam->MemClkPeriodMul2x * MemClkPeriod; + PartialSum2x += 520 * 2; + PartialSum2x = (PartialSum2x + MemClkPeriod - 1) / MemClkPeriod; // round-up here + PartialSum2x -= 2 * (MemNGetBitFieldNb (NBPtr, BFTcwl) + 5); + if ((MemNGetBitFieldNb (NBPtr, BFAddrTmgControl) & 0x0202020) == 0) { + PartialSum2x -= 1; + } else { + PartialSum2x -= 2; + } + PartialSum2x -= ((16 + RdPtrInitMin - RdPtrInit) % 16); + PartialSum2x -= 2; + + // If PartialSumSlotN is positive: + // DataTxFifoSchedDlySlotN=CEIL(PartialSumSlotN). + // DataTxFifoSchedDlyNegSlotN=0. + // Else if PartialSumSlotN is negative: + // DataTxFifoSchedDlySlotN=ABS(CEIL(PartialSumSlotN*MemClkPeriod/NclkPeriod)). + // DataTxFifoSchedDlyNegSlotN=1. + for (i = 0; i < 2; i++) { + PartialSumSlotI2x = PartialSum2x; + if ((i == 0) && (MemNGetBitFieldNb (NBPtr, BFSlowAccessMode) == 0)) { + PartialSumSlotI2x += 2; + } + if (PartialSumSlotI2x > 0) { + ASSERT ((i != 0) && (PartialSumSlotI2x <= 2)); // Real system constrain + MemNSetBitFieldNb (NBPtr, BFDataTxFifoSchedDlyNegSlot0 + i, 0); + MemNSetBitFieldNb (NBPtr, BFDataTxFifoSchedDlySlot0 + i, (PartialSumSlotI2x + 1) / 2); + IDS_HDT_CONSOLE ("\t\tDataTxFifoSchedDlySlot%d: %lx\n", i, (PartialSumSlotI2x + 1) / 2); + } else { + MemNSetBitFieldNb (NBPtr, BFDataTxFifoSchedDlyNegSlot0 + i, 1); + PartialSumSlotI2x = (((-PartialSumSlotI2x) * MemClkPeriod) + (2 * NclkPeriod - 1)) / (2 * NclkPeriod); + MemNSetBitFieldNb (NBPtr, BFDataTxFifoSchedDlySlot0 + i, PartialSumSlotI2x); + IDS_HDT_CONSOLE ("\t\tDataTxFifoSchedDlySlot%d: -%lx\n", i, PartialSumSlotI2x); + } + } + } + } + + MemFInitTableDrive (NBPtr, MTAfterNbPstateChange); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets the total of sync components for Max Read Latency calculation + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return Total in 1/2 MEMCLKs + */ + +UINT32 +MemNTotalSyncComponentsClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT32 P; + UINT32 T; + UINT8 RdPtrInitMin; + UINT8 RdPtrInit; + UINT32 AddrTmgCtl; + UINT8 DbeGskMemClkAlignMode; + UINT32 MemClkPeriod; + + // P = P + ((16 + RdPtrInitMin - D18F2x[1,0]78[RdPtrInit]) MOD 16) + RdPtrInitMin = (NBPtr->DCTPtr->Timings.Speed >= DDR1333_FREQUENCY) ? NBPtr->FreqChangeParam->RdPtrInit667orHigher : NBPtr->FreqChangeParam->RdPtrInitLower667; + RdPtrInit = (UINT8) MemNGetBitFieldNb (NBPtr, BFRdPtrInit); + P = (16 + RdPtrInitMin - RdPtrInit) % 16; + + // IF (AddrCmdSetup != CkeSetup) THEN P = P + 1 + AddrTmgCtl = MemNGetBitFieldNb (NBPtr, BFAddrTmgControl); + if (((AddrTmgCtl >> 16) & 0x20) != (AddrTmgCtl & 0x20)) { + P += 1; + } + + // IF (DbeGskMemClkAlignMode==01b || (DbeGskMemClkAlignMode==00b && !(AddrCmdSetup==CsOdtSetup==CkeSetup))) + // THEN P = P + 1 + DbeGskMemClkAlignMode = 2; // from BKDG recommendation. + if ((DbeGskMemClkAlignMode == 1) || ((DbeGskMemClkAlignMode == 0) && + !((((AddrTmgCtl >> 16) & 0x20) == (AddrTmgCtl & 0x20)) && (((AddrTmgCtl >> 8) & 0x20) == (AddrTmgCtl & 0x20))))) { + P += 1; + } + + // IF (SlowAccessMode==1) THEN P = P + 2 + if (MemNGetBitFieldNb (NBPtr, BFSlowAccessMode) == 1) { + P += 2; + } + + // IF (D18F2x[1,0]94[MemClkFreq] >= 667 MHz) + // THEN T = T + MemClkPeriod - 786 ps + // ELSE T = T + (0.5 * MemClkPeriod) - 786 ps + MemClkPeriod = 1000000 / NBPtr->DCTPtr->Timings.Speed; + if (NBPtr->DCTPtr->Timings.Speed >= DDR1333_FREQUENCY) { + T = MemClkPeriod - 786; + } else { + T = (MemClkPeriod / 2) - 786; + } + + // If (AddrCmdSetup==0 && CsOdtSetup==0 && CkeSetup==0) + // then P = P + 1 + // else P = P + 2 + if ((AddrTmgCtl & 0x0202020) == 0) { + P += 1; + } else { + P += 2; + } + + // P = P + (2 * (D18F2x[1,0]88[Tcl] clocks - 1)) + P += 2 * (NBPtr->DCTPtr->Timings.CasL - 1); + + // If (DisCutThroughMode==0) + // then P = P + 3 + // else P = P + 7 + if (MemNGetBitFieldNb (NBPtr, BFDisCutThroughMode) == 0) { + P += 3; + } else { + P += 7; + } + + return (((P * MemClkPeriod + 1) / 2) + T); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function sets up phy power saving for client NB + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ +VOID +MemNPhyPowerSavingClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + // 4. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]13[DllDisEarlyU] = 1b. + // 5. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]13[DllDisEarlyL] = 1b. + // 6. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]13[7:4] = 1010b. + MemNSetBitFieldNb (NBPtr, BFPhy0x0D0F0F13Bit0to7, 0xA3); + // 7. Program D18F2x[1,0]9C_x0D0F_812F[7, 5, 0] = {1b, 1b, 1b} to disable unused PAR and A[17:16] pins. + MemNSetBitFieldNb (NBPtr, BFAddrCmdTri, 0xA1); + // 8. Program D18F2x[1,0]9C_x0D0F_C000[LowPowerDrvStrengthEn] = 1. + MemNSetBitFieldNb (NBPtr, BFLowPowerDrvStrengthEn, 0x100); + // 9. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]10[EnRxPadStandby]= IF (D18F2x[1,0]94[MemClkFreq] <= + // 800 MHz) THEN 1 ELSE 0 ENDIF. + MemNSetBitFieldNb (NBPtr, BFEnRxPadStandby, (NBPtr->DCTPtr->Timings.Speed <= DDR1600_FREQUENCY) ? 0x1000 : 0); + // 10. Program D18F2x[1,0]9C_x0000_000D as follows: + // TxMaxDurDllNoLock/RxMaxDurDllNoLock = 9h. + MemNSetBitFieldNb (NBPtr, BFRxMaxDurDllNoLock, 9); + MemNSetBitFieldNb (NBPtr, BFTxMaxDurDllNoLock, 9); + // TxCPUpdPeriod/RxCPUpdPeriod = 000b. + MemNSetBitFieldNb (NBPtr, BFTxCPUpdPeriod, 0); + MemNSetBitFieldNb (NBPtr, BFRxCPUpdPeriod, 0); + // TxDLLWakeupTime/RxDLLWakeupTime = 11b. + MemNSetBitFieldNb (NBPtr, BFTxDLLWakeupTime, 3); + MemNSetBitFieldNb (NBPtr, BFRxDLLWakeupTime, 3); +}
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