diff options
author | efdesign98 <efdesign98@gmail.com> | 2011-06-20 18:12:43 -0700 |
---|---|---|
committer | Marc Jones <marcj303@gmail.com> | 2011-06-22 01:35:45 +0200 |
commit | 621ca384a7a5efb2cc7597504dc17b741cd2df10 (patch) | |
tree | 01871adc6d39f48916b5625b3aa1a4b6d5ab9c92 /src/vendorcode/amd/agesa/f14/Proc/Mem/NB/mnphy.c | |
parent | 05a89ab922473f375820a3bd68691bb085c62448 (diff) | |
download | coreboot-621ca384a7a5efb2cc7597504dc17b741cd2df10.tar.xz |
Move existing AMD Ffamily14 code to f14 folder
This change moves the AMD Family14 cpu Agesa code to
the vendorcode/amd/agesa/f14 folder to complete the
transition to the family oriented folder structure.
Change-Id: I211e80ee04574cc713f38b4cc1b767dbb2bfaa59
Signed-off-by: Frank Vibrans <frank.vibrans@amd.com>
Signed-off-by: efdesign98 <efdesign98@gmail.com>
Reviewed-on: http://review.coreboot.org/52
Tested-by: build bot (Jenkins)
Reviewed-by: Marc Jones <marcj303@gmail.com>
Diffstat (limited to 'src/vendorcode/amd/agesa/f14/Proc/Mem/NB/mnphy.c')
-rw-r--r-- | src/vendorcode/amd/agesa/f14/Proc/Mem/NB/mnphy.c | 1377 |
1 files changed, 1377 insertions, 0 deletions
diff --git a/src/vendorcode/amd/agesa/f14/Proc/Mem/NB/mnphy.c b/src/vendorcode/amd/agesa/f14/Proc/Mem/NB/mnphy.c new file mode 100644 index 0000000000..bcf2f6e4c1 --- /dev/null +++ b/src/vendorcode/amd/agesa/f14/Proc/Mem/NB/mnphy.c @@ -0,0 +1,1377 @@ +/* $NoKeywords:$ */ +/** + * @file + * + * mnphy.c + * + * Common Northbridge Phy support + * + * @xrefitem bom "File Content Label" "Release Content" + * @e project: AGESA + * @e sub-project: (Mem/NB) + * @e \$Revision: 38306 $ @e \$Date: 2010-09-22 01:51:51 +0800 (Wed, 22 Sep 2010) $ + * + **/ +/* + ***************************************************************************** + * + * 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 "PlatformMemoryConfiguration.h" +#include "heapManager.h" +#include "merrhdl.h" +#include "Filecode.h" +CODE_GROUP (G1_PEICC) +RDATA_GROUP (G1_PEICC) +#define FILECODE PROC_MEM_NB_MNPHY_FILECODE +/*---------------------------------------------------------------------------- + * DEFINITIONS AND MACROS + * + *---------------------------------------------------------------------------- + */ +#define UNUSED_CLK 4 + +/*---------------------------------------------------------------------------- + * TYPEDEFS AND STRUCTURES + * + *---------------------------------------------------------------------------- + */ +/// Type of an entry for processing phy init compensation for client NB +typedef struct { + BIT_FIELD_NAME IndexBitField; ///< Bit field on which the value is decided + BIT_FIELD_NAME StartTargetBitField; ///< First bit field to be modified + BIT_FIELD_NAME EndTargetBitField; ///< Last bit field to be modified + UINT16 ExtraValue; ///< Extra value needed to be written to bit field + CONST UINT16 (*TxPrePN)[3][5]; ///< Pointer to slew rate table +} PHY_COMP_INIT_CLIENTNB; + +/*---------------------------------------------------------------------------- + * PROTOTYPES OF LOCAL FUNCTIONS + * + *---------------------------------------------------------------------------- + */ + + + +/*---------------------------------------------------------------------------- + * EXPORTED FUNCTIONS + * + *---------------------------------------------------------------------------- + */ +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets a delay value a PCI register during training + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] TrnDly - type of delay to be set + * @param[in] DrbnVar - encoding of Dimm-Rank-Byte-Nibble to be accessed + * (use either DIMM_BYTE_ACCESS(dimm,byte) or CS_NBBL_ACCESS(cs,nibble) to use this encoding + * + * @return Value read + */ + +UINT32 +MemNGetTrainDlyNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN TRN_DLY_TYPE TrnDly, + IN DRBN DrbnVar + ) +{ + return NBPtr->MemNcmnGetSetTrainDly (NBPtr, 0, TrnDly, DrbnVar, 0); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function sets a delay value a PCI register during training + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] TrnDly - type of delay to be set + * @param[in] DrbnVar - encoding of Dimm-Rank-Byte-Nibble to be accessed + * (use either DIMM_BYTE_ACCESS(dimm,byte) or CS_NBBL_ACCESS(cs,nibble) to use this encoding + * @param[in] Field - Value to be programmed + * + */ + +VOID +MemNSetTrainDlyNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN TRN_DLY_TYPE TrnDly, + IN DRBN DrbnVar, + IN UINT16 Field + ) +{ + NBPtr->MemNcmnGetSetTrainDly (NBPtr, 1, TrnDly, DrbnVar, Field); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function executes prototypical Phy fence training function. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNPhyFenceTrainingNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + NBPtr->MemPPhyFenceTrainingNb (NBPtr); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function executes prototypical Phy fence training function. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNPhyFenceTrainingUnb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 FenceThresholdTxDll; + UINT8 FenceThresholdRxDll; + UINT8 FenceThresholdTxPad; + UINT16 Fence2Data; + + // 1. Program D18F2x[1,0]9C_x0000_0008[FenceTrSel]=10b. + // 2. Perform phy fence training. + // 3. Write the calculated fence value to D18F2x[1,0]9C_x0000_000C[FenceThresholdTxDll]. + MemNSetBitFieldNb (NBPtr, BFFenceTrSel, 2); + MAKE_TSEFO (NBPtr->NBRegTable, DCT_PHY_ACCESS, 0x0C, 30, 26, BFPhyFence); + IDS_HDT_CONSOLE (MEM_FLOW, "\t\tFenceThresholdTxDll\n"); + MemNTrainPhyFenceNb (NBPtr); + FenceThresholdTxDll = (UINT8) MemNGetBitFieldNb (NBPtr, BFPhyFence); + NBPtr->FamilySpecificHook[DetectMemPllError] (NBPtr, &FenceThresholdTxDll); + + // 4. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]0F[AlwaysEnDllClks]=001b. + MemNSetBitFieldNb (NBPtr, BFAlwaysEnDllClks, 0x1000); + + // 5. Program D18F2x[1,0]9C_x0000_0008[FenceTrSel]=01b. + // 6. Perform phy fence training. + // 7. Write the calculated fence value to D18F2x[1,0]9C_x0000_000C[FenceThresholdRxDll]. + MemNSetBitFieldNb (NBPtr, BFFenceTrSel, 1); + MAKE_TSEFO (NBPtr->NBRegTable, DCT_PHY_ACCESS, 0x0C, 25, 21, BFPhyFence); + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\tFenceThresholdRxDll\n"); + MemNTrainPhyFenceNb (NBPtr); + FenceThresholdRxDll = (UINT8) MemNGetBitFieldNb (NBPtr, BFPhyFence); + NBPtr->FamilySpecificHook[DetectMemPllError] (NBPtr, &FenceThresholdRxDll); + + // 8. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]0F[AlwaysEnDllClks]=000b. + MemNSetBitFieldNb (NBPtr, BFAlwaysEnDllClks, 0x0000); + + // 9. Program D18F2x[1,0]9C_x0000_0008[FenceTrSel]=11b. + // 10. Perform phy fence training. + // 11. Write the calculated fence value to D18F2x[1,0]9C_x0000_000C[FenceThresholdTxPad]. + MemNSetBitFieldNb (NBPtr, BFFenceTrSel, 3); + MAKE_TSEFO (NBPtr->NBRegTable, DCT_PHY_ACCESS, 0x0C, 20, 16, BFPhyFence); + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\tFenceThresholdTxPad\n"); + MemNTrainPhyFenceNb (NBPtr); + FenceThresholdTxPad = (UINT8) MemNGetBitFieldNb (NBPtr, BFPhyFence); + NBPtr->FamilySpecificHook[DetectMemPllError] (NBPtr, &FenceThresholdTxPad); + + // Program Fence2 threshold for Clk, Cmd, and Addr + if (FenceThresholdTxPad < 16) { + MemNSetBitFieldNb (NBPtr, BFClkFence2, FenceThresholdTxPad | 0x10); + MemNSetBitFieldNb (NBPtr, BFCmdFence2, FenceThresholdTxPad | 0x10); + MemNSetBitFieldNb (NBPtr, BFAddrFence2, FenceThresholdTxPad | 0x10); + } else { + MemNSetBitFieldNb (NBPtr, BFClkFence2, 0); + MemNSetBitFieldNb (NBPtr, BFCmdFence2, 0); + MemNSetBitFieldNb (NBPtr, BFAddrFence2, 0); + } + + // Program Fence2 threshold for data + Fence2Data = 0; + if (FenceThresholdTxPad < 16) { + Fence2Data |= FenceThresholdTxPad | 0x10; + } + if (FenceThresholdRxDll < 16) { + Fence2Data |= (FenceThresholdRxDll | 0x10) << 10; + } + if (FenceThresholdTxDll < 16) { + Fence2Data |= (FenceThresholdTxDll | 0x10) << 5; + } + MemNSetBitFieldNb (NBPtr, BFDataFence2, Fence2Data); + + if (NBPtr->MCTPtr->Status[SbLrdimms]) { + // 18. If motherboard routing requires CS[7:6] to adopt address timings, e.g. 3 LRDIMMs/ch with CS[7:6] + // routed across all DIMM sockets, BIOS performs the following: + if (FindPSOverrideEntry (NBPtr->RefPtr->PlatformMemoryConfiguration, PSO_NO_LRDIMM_CS67_ROUTING, NBPtr->MCTPtr->SocketId, NBPtr->ChannelPtr->ChannelID) != NULL) { + // A. Program D18F2xA8_dct[1:0][CSTimingMux67] = 1. + MemNSetBitFieldNb (NBPtr, BFCSTimingMux67, 1); + // B. Program D18F2x9C_x0D0F_8021_dct[1:0]: + // - DiffTimingEn = 1. + // - IF (D18F2x9C_x0000_0004_dct[1:0][AddrCmdFineDelay] >= + // D18F2x9C_x0D0F_E008_dct[1:0][FenceValue]) THEN Fence = 1 ELSE Fence = 0. + // - Delay = D18F2x9C_x0000_0004_dct[1:0][AddrCmdFineDelay]. + // + MemNSetBitFieldNb (NBPtr, BFDiffTimingEn, 1); + MemNSetBitFieldNb (NBPtr, BFFence, (MemNGetBitFieldNb (NBPtr, BFAddrCmdFineDelay) >= MemNGetBitFieldNb (NBPtr, BFFenceValue)) ? 1 : 0); + MemNSetBitFieldNb (NBPtr, BFDelay, (MemNGetBitFieldNb (NBPtr, BFAddrCmdFineDelay))); + } + } + + // 19. Reprogram F2x9C_04. + MemNSetBitFieldNb (NBPtr, BFAddrTmgControl, MemNGetBitFieldNb (NBPtr, BFAddrTmgControl)); + +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function executes Phy fence training + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNTrainPhyFenceNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 Byte; + UINT16 Avg; + UINT8 PREvalue; + + if (MemNGetBitFieldNb (NBPtr, BFDisDramInterface)) { + return; + } + + // 1. BIOS first programs a seed value to the phase recovery + // engine registers. + // + IDS_HDT_CONSOLE (MEM_FLOW, "\t\tSeeds: "); + for (Byte = 0; Byte < MAX_BYTELANES_PER_CHANNEL; Byte++) { + // This includes ECC as byte 8 + MemNSetTrainDlyNb (NBPtr, AccessPhRecDly, DIMM_BYTE_ACCESS (0, Byte), 19); + IDS_HDT_CONSOLE (MEM_FLOW, "%02x ", 19); + } + + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\tPhyFenceTrEn = 1"); + // 2. Set F2x[1, 0]9C_x08[PhyFenceTrEn]=1. + MemNSetBitFieldNb (NBPtr, BFPhyFenceTrEn, 1); + + if (!NBPtr->IsSupported[UnifiedNbFence]) { + // 3. Wait 200 MEMCLKs. + MemNWaitXMemClksNb (NBPtr, 200); + } else { + // 3. Wait 2000 MEMCLKs. + MemNWaitXMemClksNb (NBPtr, 2000); + } + + // 4. Clear F2x[1, 0]9C_x08[PhyFenceTrEn]=0. + MemNSetBitFieldNb (NBPtr, BFPhyFenceTrEn, 0); + + // 5. BIOS reads the phase recovery engine registers + // F2x[1, 0]9C_x[51:50] and F2x[1, 0]9C_x52. + // 6. Calculate the average value of the fine delay and subtract 8. + // + Avg = 0; + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\t PRE: "); + for (Byte = 0; Byte < MAX_BYTELANES_PER_CHANNEL; Byte++) { + // + // This includes ECC as byte 8. ECC Byte lane (8) is ignored by MemNGetTrainDlyNb function where + // ECC is not supported. + // + PREvalue = (UINT8) (0x1F & MemNGetTrainDlyNb (NBPtr, AccessPhRecDly, DIMM_BYTE_ACCESS (0, Byte))); + Avg = Avg + ((UINT16) PREvalue); + IDS_HDT_CONSOLE (MEM_FLOW, "%02x ", PREvalue); + } + Avg = ((Avg + 8) / 9); // round up + + Avg -= 8; + NBPtr->MemNPFenceAdjustNb (NBPtr, &Avg); + + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\tFence: %02x\n", Avg); + + // 7. Write the value to F2x[1, 0]9C_x0C[PhyFence]. + MemNSetBitFieldNb (NBPtr, BFPhyFence, Avg); + + // 8. BIOS rewrites F2x[1, 0]9C_x04, DRAM Address/Command Timing Control + // Register delays for both channels. This forces the phy to recompute + // the fence. + // + MemNSetBitFieldNb (NBPtr, BFAddrTmgControl, MemNGetBitFieldNb (NBPtr, BFAddrTmgControl)); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function initializes the DDR phy compensation logic + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNInitPhyCompNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + CONST UINT8 TableCompRiseSlew20x[] = {7, 3, 2, 2}; + CONST UINT8 TableCompRiseSlew15x[] = {7, 7, 3, 2}; + CONST UINT8 TableCompFallSlew20x[] = {7, 5, 3, 2}; + CONST UINT8 TableCompFallSlew15x[] = {7, 7, 5, 3}; + UINT8 i; + UINT8 j; + UINT8 CurrDct; + UINT8 CurrChannel; + BOOLEAN MarginImprv; + MarginImprv = FALSE; + CurrDct = NBPtr->Dct; + CurrChannel = NBPtr->Channel; + if (NBPtr->IsSupported[CheckSlewWithMarginImprv]) { + if (NBPtr->MCTPtr->GangedMode == FALSE) { + for (i = 0; i < NBPtr->DctCount; i++) { + MemNSwitchDCTNb (NBPtr, i); + for (j = 0; j < NBPtr->ChannelCount; j++) { + NBPtr->SwitchChannel (NBPtr, j); + if ((NBPtr->ChannelPtr->Dimms == 4) && ((NBPtr->DCTPtr->Timings.Speed == DDR533_FREQUENCY) || (NBPtr->DCTPtr->Timings.Speed == DDR667_FREQUENCY))) { + MarginImprv = TRUE; + } + } + } + MemNSwitchDCTNb (NBPtr, CurrDct); + NBPtr->SwitchChannel (NBPtr, CurrChannel); + } + } + + // 1. BIOS disables the phy compensation register by programming F2x9C_x08[DisAutoComp]=1 + // 2. BIOS waits 5 us for the disabling of the compensation engine to complete. + // DisAutoComp will be cleared after Dram init has completed + // + MemNSwitchDCTNb (NBPtr, 0); + MemNSetBitFieldNb (NBPtr, BFDisAutoComp, 1); + MemUWait10ns (500, NBPtr->MemPtr); + MemNSwitchDCTNb (NBPtr, CurrDct); + + // 3. For each normalized driver strength code read from + // F2x[1, 0]9C_x00[AddrCmdDrvStren], program the + // corresponding 3 bit predriver code in F2x9C_x0A[D3Cmp1NCal, D3Cmp1PCal]. + // + // 4. For each normalized driver strength code read from + // F2x[1, 0]9C_x00[DataDrvStren], program the corresponding + // 3 bit predriver code in F2x9C_x0A[D3Cmp0NCal, D3Cmp0PCal, D3Cmp2NCal, + // D3Cmp2PCal]. + // + j = (UINT8) MemNGetBitFieldNb (NBPtr, BFAddrCmdDrvStren); + i = (UINT8) MemNGetBitFieldNb (NBPtr, BFDataDrvStren); + + MemNSwitchDCTNb (NBPtr, 0); + MemNSetBitFieldNb (NBPtr, BFD3Cmp1NCal, TableCompRiseSlew20x[j]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp1PCal, TableCompFallSlew20x[j]); + + if (NBPtr->IsSupported[CheckSlewWithMarginImprv]) { + MemNSetBitFieldNb (NBPtr, BFD3Cmp0NCal, (MarginImprv) ? 0 : TableCompRiseSlew15x[i]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp0PCal, (MarginImprv) ? 0 : TableCompFallSlew15x[i]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp2NCal, (MarginImprv) ? 0 : TableCompRiseSlew15x[i]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp2PCal, (MarginImprv) ? 0 : TableCompFallSlew15x[i]); + } + if (NBPtr->IsSupported[CheckSlewWithoutMarginImprv]) { + ASSERT (i <= 3); + MemNSetBitFieldNb (NBPtr, BFD3Cmp0NCal, TableCompRiseSlew15x[i]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp0PCal, TableCompFallSlew15x[i]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp2NCal, TableCompRiseSlew15x[i]); + MemNSetBitFieldNb (NBPtr, BFD3Cmp2PCal, TableCompFallSlew15x[i]); + } + MemNSwitchDCTNb (NBPtr, CurrDct); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This is a general purpose function that executes before DRAM training + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNBeforeDQSTrainingNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + UINT8 Dct; + UINT8 ChipSel; + UINT32 TestAddrRJ16; + UINT32 RealAddr; + + MemTBeginTraining (NBPtr->TechPtr); + + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + MemNSwitchDCTNb (NBPtr, Dct); + if (NBPtr->DCTPtr->Timings.DctMemSize != 0) { + for (ChipSel = 0; ChipSel < MAX_CS_PER_CHANNEL; ChipSel += 2) { + if (MemNGetMCTSysAddrNb (NBPtr, ChipSel, &TestAddrRJ16)) { + + RealAddr = MemUSetUpperFSbase (TestAddrRJ16, NBPtr->MemPtr); + + MemUDummyCLRead (RealAddr); + + MemNSetBitFieldNb (NBPtr, BFErr350, 0x8000); + MemUWait10ns (60, NBPtr->MemPtr); // Wait 300ns + MemNSetBitFieldNb (NBPtr, BFErr350, 0x0000); + MemUWait10ns (400, NBPtr->MemPtr); // Wait 2us + MemUProcIOClFlush (TestAddrRJ16, 1, NBPtr->MemPtr); + break; + } + } + } + if (NBPtr->IsSupported[CheckEccDLLPwrDnConfig]) { + if (!NBPtr->MCTPtr->Status[SbEccDimms]) { + MemNSetBitFieldNb (NBPtr, BFEccDLLPwrDnConf, 0x0010); + } + if (NBPtr->DCTPtr->Timings.Dimmx4Present == 0) { + MemNSetBitFieldNb (NBPtr, BFEccDLLConf, 0x0080); + } + } + } + + MemTEndTraining (NBPtr->TechPtr); +} + +/*-----------------------------------------------------------------------------*/ +/** + * + * Returns the parameters for a requested delay value to be used in training + * The correct Min, Max and Mask are determined based on the type of Delay, + * and the frequency + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] TrnDly - Type of delay + * @param[in,out] *Parms - Pointer to the TRN_DLY-PARMS struct + * + */ + +VOID +MemNGetTrainDlyParmsNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN TRN_DLY_TYPE TrnDly, + IN OUT TRN_DLY_PARMS *Parms + ) +{ + Parms->Min = 0; + + if (TrnDly == AccessWrDatDly) { + Parms->Max = 0x1F; + Parms->Mask = 0x01F; + } else if (TrnDly == AccessRdDqsDly) { + if ( (NBPtr->IsSupported[CheckMaxRdDqsDlyPtr]) && (NBPtr->DCTPtr->Timings.Speed > DDR667_FREQUENCY) ) { + Parms->Max = 0x3E; + Parms->Mask = 0x03E; + } else { + Parms->Max = 0x1F; + Parms->Mask = 0x01F; + } + } +} + +/*-----------------------------------------------------------------------------*/ +/** + * + * Returns the parameters for a requested delay value to be used in training + * The correct Min, Max and Mask are determined based on the type of Delay, + * and the frequency + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] TrnDly - Type of delay + * @param[in,out] *Parms - Pointer to the TRN_DLY-PARMS struct + * + */ + +VOID +MemNGetTrainDlyParmsClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN TRN_DLY_TYPE TrnDly, + IN OUT TRN_DLY_PARMS *Parms + ) +{ + Parms->Min = 0; + + if (TrnDly == AccessWrDatDly) { + Parms->Max = 0x1F; + Parms->Mask = 0x01F; + } else if (TrnDly == AccessRdDqsDly) { + Parms->Max = 0x3E; + Parms->Mask = 0x03E; + } +} +/*-----------------------------------------------------------------------------*/ +/** + * + * Returns the parameters for a requested delay value to be used in training + * The correct Min, Max and Mask are determined based on the type of Delay, + * and the frequency + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] TrnDly - Type of delay + * @param[in,out] *Parms - Pointer to the TRN_DLY-PARMS struct + * + */ + +VOID +MemNGetTrainDlyParmsUnb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN TRN_DLY_TYPE TrnDly, + IN OUT TRN_DLY_PARMS *Parms + ) +{ + Parms->Min = 0; + + if (TrnDly == AccessWrDatDly) { + Parms->Max = 0x1F; + Parms->Mask = 0x01F; + } else if (TrnDly == AccessRdDqsDly) { + Parms->Max = 0x1F; + Parms->Mask = 0x01F; + } +} +/*---------------------------------------------------------------------------- + * LOCAL FUNCTIONS + * + *---------------------------------------------------------------------------- + */ +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function gets or set DQS timing during training. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] TrnDly - type of delay to be set + * @param[in] DrbnVar - encoding of Dimm-Rank-Byte-Nibble to be accessed + * (use either DIMM_BYTE_ACCESS(dimm,byte) or CS_NBBL_ACCESS(cs,nibble) to use this encoding + * @param[in] Field - Value to be programmed + * @param[in] IsSet - Indicates if the function will set or get + * + * @return value read, if the function is used as a "get" + */ + +UINT32 +MemNcmnGetSetTrainDlyNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT8 IsSet, + IN TRN_DLY_TYPE TrnDly, + IN DRBN DrbnVar, + IN UINT16 Field + ) +{ + UINT16 Index; + UINT16 Offset; + UINT32 Value; + UINT32 Address; + UINT8 Dimm; + UINT8 Rank; + UINT8 Byte; + UINT8 Nibble; + + Dimm = DRBN_DIMM (DrbnVar); + Rank = DRBN_RANK (DrbnVar); + Byte = DRBN_BYTE (DrbnVar); + Nibble = DRBN_NBBL (DrbnVar); + + ASSERT (Dimm < 4); + ASSERT (Byte <= ECC_DLY); + + switch (TrnDly) { + case AccessRcvEnDly: + Index = 0x10; + break; + case AccessWrDqsDly: + Index = 0x30; + break; + case AccessWrDatDly: + Index = 0x01; + break; + case AccessRdDqsDly: + Index = 0x05; + break; + case AccessPhRecDly: + Index = 0x50; + break; + default: + Index = 0; + IDS_ERROR_TRAP; + } + + switch (TrnDly) { + case AccessRcvEnDly: + case AccessWrDqsDly: + Index += (Dimm * 3); + if (Byte & 0x04) { + // if byte 4,5,6,7 + Index += 0x10; + } + if (Byte & 0x02) { + // if byte 2,3,6,7 + Index++; + } + if (Byte > 7) { + Index += 2; + } + Offset = 16 * (Byte % 2); + Index |= (Rank << 8); + Index |= (Nibble << 9); + break; + + case AccessRdDqsDly: + case AccessWrDatDly: + + if (NBPtr->IsSupported[DimmBasedOnSpeed]) { + if (NBPtr->DCTPtr->Timings.Speed < DDR800_FREQUENCY) { + // if DDR speed is below 800, use DIMM 0 delays for all DIMMs. + Dimm = 0; + } + } + + Index += (Dimm * 0x100); + if (Nibble) { + if (Rank) { + Index += 0xA0; + } else { + Index += 0x70; + } + } else if (Rank) { + Index += 0x60; + } + // break is not being used here because AccessRdDqsDly and AccessWrDatDly also need + // to run AccessPhRecDly sequence. + case AccessPhRecDly: + Index += (Byte / 4); + Offset = 8 * (Byte % 4); + break; + default: + Offset = 0; + IDS_ERROR_TRAP; + } + + Address = Index; + MemNSetBitFieldNb (NBPtr, BFDctAddlOffsetReg, Address); + MemNPollBitFieldNb (NBPtr, BFDctAccessDone, 1, PCI_ACCESS_TIMEOUT, FALSE); + Value = MemNGetBitFieldNb (NBPtr, BFDctAddlDataReg); + + if (TrnDly == AccessRdDqsDly) { + NBPtr->FamilySpecificHook[AdjustRdDqsDlyOffset] (NBPtr, &Offset); + } + + if (IsSet) { + if (TrnDly == AccessPhRecDly) { + Value = NBPtr->DctCachePtr->PhRecReg[Index & 0x03]; + } + + Value = ((UINT32)Field << Offset) | (Value & (~((UINT32) ((TrnDly == AccessRcvEnDly) ? 0x1FF : 0xFF) << Offset))); + MemNSetBitFieldNb (NBPtr, BFDctAddlDataReg, Value); + Address |= DCT_ACCESS_WRITE; + MemNSetBitFieldNb (NBPtr, BFDctAddlOffsetReg, Address); + MemNPollBitFieldNb (NBPtr, BFDctAccessDone, 1, PCI_ACCESS_TIMEOUT, FALSE); + + if (TrnDly == AccessPhRecDly) { + NBPtr->DctCachePtr->PhRecReg[Index & 0x03] = Value; + } + } else { + Value = (Value >> Offset) & (UINT32) ((TrnDly == AccessRcvEnDly) ? 0x1FF : 0xFF); + } + + return Value; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function gets or set DQS timing during training. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] IsSet - Indicates if the function will set or get + * @param[in] TrnDly - type of delay to be set + * @param[in] DrbnVar - encoding of Dimm-Rank-Byte-Nibble to be accessed + * (use either DIMM_BYTE_ACCESS(dimm,byte) or CS_NBBL_ACCESS(cs,nibble) to use this encoding + * @param[in] Field - Value to be programmed + * + * @return value read, if the function is used as a "get" + */ +UINT32 +MemNcmnGetSetTrainDlyClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT8 IsSet, + IN TRN_DLY_TYPE TrnDly, + IN DRBN DrbnVar, + IN UINT16 Field + ) +{ + UINT16 Index; + UINT16 Offset; + UINT32 Value; + UINT32 Address; + UINT8 Dimm; + UINT8 Byte; + + Dimm = DRBN_DIMM (DrbnVar); + Byte = DRBN_BYTE (DrbnVar); + + ASSERT (Dimm < 2); + ASSERT (Byte <= ECC_DLY); + + if ((Byte > 7)) { + // Llano does not support ECC delay, so: + if (IsSet) { + // On write, ignore + return 0; + } else { + // On read, redirect to byte 0 to correct fence averaging + Byte = 0; + } + } + + switch (TrnDly) { + case AccessRcvEnDly: + Index = 0x10; + break; + case AccessWrDqsDly: + Index = 0x30; + break; + case AccessWrDatDly: + Index = 0x01; + break; + case AccessRdDqsDly: + Index = 0x05; + break; + case AccessPhRecDly: + Index = 0x50; + break; + default: + Index = 0; + IDS_ERROR_TRAP; + } + + switch (TrnDly) { + case AccessRcvEnDly: + case AccessWrDqsDly: + Index += (Dimm * 3); + if (Byte & 0x04) { + // if byte 4,5,6,7 + Index += 0x10; + } + if (Byte & 0x02) { + // if byte 2,3,6,7 + Index++; + } + Offset = 16 * (Byte % 2); + break; + + case AccessRdDqsDly: + case AccessWrDatDly: + Index += (Dimm * 0x100); + // break is not being used here because AccessRdDqsDly and AccessWrDatDly also need + // to run AccessPhRecDly sequence. + case AccessPhRecDly: + Index += (Byte / 4); + Offset = 8 * (Byte % 4); + break; + default: + Offset = 0; + IDS_ERROR_TRAP; + } + + Address = Index; + MemNSetBitFieldNb (NBPtr, BFDctAddlOffsetReg, Address); + Value = MemNGetBitFieldNb (NBPtr, BFDctAddlDataReg); + + if (IsSet) { + if (TrnDly == AccessPhRecDly) { + Value = NBPtr->DctCachePtr->PhRecReg[Index & 0x03]; + } + + Value = ((UINT32)Field << Offset) | (Value & (~((UINT32) ((TrnDly == AccessRcvEnDly) ? 0x1FF : 0xFF) << Offset))); + MemNSetBitFieldNb (NBPtr, BFDctAddlDataReg, Value); + Address |= DCT_ACCESS_WRITE; + MemNSetBitFieldNb (NBPtr, BFDctAddlOffsetReg, Address); + + if (TrnDly == AccessPhRecDly) { + NBPtr->DctCachePtr->PhRecReg[Index & 0x03] = Value; + } + // Gross WrDatDly and WrDqsDly cannot be larger than 4 + ASSERT (((TrnDly == AccessWrDatDly) || (TrnDly == AccessWrDqsDly)) ? (Field < 0xA0) : TRUE); + } else { + Value = (Value >> Offset) & (UINT32) ((TrnDly == AccessRcvEnDly) ? 0x1FF : 0xFF); + } + + return Value; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function initializes the training pattern. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return AGESA_STATUS - Result + * AGESA_SUCCESS - Training pattern is ready to use + * AGESA_ERROR - Unable to initialize the pattern. + */ + +AGESA_STATUS +MemNTrainingPatternInitNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + MEM_TECH_BLOCK *TechPtr; + ALLOCATE_HEAP_PARAMS AllocHeapParams; + TRAIN_PATTERN TrainPattern; + AGESA_STATUS Status; + + TechPtr = NBPtr->TechPtr; + TrainPattern = 0; + // + // Check the training type + // + if (TechPtr->TrainingType == TRN_DQS_POSITION) { + // + // DQS Position Training + // + if (NBPtr->PosTrnPattern == POS_PATTERN_256B) { + // + // 256 Bit pattern + // + if (NBPtr->MCTPtr->Status[Sb128bitmode]) { + TrainPattern = TestPatternJD256B; + TechPtr->PatternLength = 64; + } else { + TrainPattern = TestPatternJD256A; + TechPtr->PatternLength = 32; + } + } else { + // + // 72 bit pattern will be used if PosTrnPattern is not specified + // + if (NBPtr->MCTPtr->Status[Sb128bitmode]) { + TrainPattern = TestPatternJD1B; + TechPtr->PatternLength = 18; + } else { + TrainPattern = TestPatternJD1A; + TechPtr->PatternLength = 9; + } + } + } else if (TechPtr->TrainingType == TRN_MAX_READ_LATENCY) { + // + // Max Read Latency Training + // + TrainPattern = TestPatternML; + TechPtr->PatternLength = (NBPtr->MCTPtr->Status[Sb128bitmode]) ? 6 : 3; + } else { + // + // Error - TechPtr->Training Type must be set to one of the types handled in this function + // + ASSERT (FALSE); + } + // + // Allocate training buffer + // + AllocHeapParams.RequestedBufferSize = (TechPtr->PatternLength * 64 * 2) + 16; + AllocHeapParams.BufferHandle = AMD_MEM_TRAIN_BUFFER_HANDLE; + AllocHeapParams.Persist = HEAP_LOCAL_CACHE; + Status = HeapAllocateBuffer (&AllocHeapParams, &NBPtr->MemPtr->StdHeader); + ASSERT (Status == AGESA_SUCCESS); + if (Status != AGESA_SUCCESS) { + return Status; + } + TechPtr->PatternBufPtr = AllocHeapParams.BufferPtr; + AlignPointerTo16Byte (&TechPtr->PatternBufPtr); + TechPtr->TestBufPtr = TechPtr->PatternBufPtr + (TechPtr->PatternLength * 64); + + // Prepare training pattern + MemUFillTrainPattern (TrainPattern, TechPtr->PatternBufPtr, TechPtr->PatternLength * 64); + + return Status; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function determined the settings for the Reliable Read/Write engine + * for each specific type of training + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] *OptParam - Pointer to an Enum of TRAINING_TYPE + * + * @return TRUE + */ + +BOOLEAN +MemNSetupHwTrainingEngineUnb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN VOID *OptParam + ) +{ + TRAINING_TYPE TrnType; + RRW_SETTINGS *Rrw; + + TrnType = *(TRAINING_TYPE*) OptParam; + Rrw = &NBPtr->RrwSettings; + // + // Common Settings + // + Rrw->TgtBankAddressA = CPG_BANK_ADDRESS_A; + Rrw->TgtRowAddressA = CPG_ROW_ADDRESS_A; + Rrw->TgtColAddressA = CPG_COL_ADDRESS_A; + Rrw->TgtBankAddressB = CPG_BANK_ADDRESS_B; + Rrw->TgtRowAddressB = CPG_ROW_ADDRESS_B; + Rrw->TgtColAddressB = CPG_COL_ADDRESS_B; + Rrw->CompareMaskHigh = CPG_COMPARE_MASK_HI; + Rrw->CompareMaskLow = CPG_COMPARE_MASK_LOW; + Rrw->CompareMaskEcc = CPG_COMPARE_MASK_ECC; + + switch (TrnType) { + case TRN_RCVR_ENABLE: + // + // Receiver Enable Training + // + NBPtr->TechPtr->PatternLength = 192; + break; + case TRN_MAX_READ_LATENCY: + // + // Max Read Latency Training + // + Rrw->CmdTgt = CMD_TGT_A; + NBPtr->TechPtr->PatternLength = 32; + Rrw->DataPrbsSeed = PRBS_SEED_32; + break; + case TRN_DQS_POSITION: + // + // Read/Write DQS Position training + // + Rrw->CmdTgt = CMD_TGT_AB; + NBPtr->TechPtr->PatternLength = 256; + Rrw->DataPrbsSeed = PRBS_SEED_256; + break; + default: + ASSERT (FALSE); + } + return TRUE; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function finalizes the training pattern. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in] Index - Index of Write Data Delay Value + * @param[in,out] *Value - Write Data Delay Value + * @return BOOLEAN - TRUE - Use the value returned. + * FALSE - No more values in table. + */ + +BOOLEAN +MemNGetApproximateWriteDatDelayNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN UINT8 Index, + IN OUT UINT8 *Value + ) +{ + CONST UINT8 WriteDatDelayValue[] = {0x10, 0x4, 0x8, 0xC, 0x14, 0x18, 0x1C, 0x1F}; + if (Index < GET_SIZE_OF (WriteDatDelayValue)) { + *Value = WriteDatDelayValue[Index]; + return TRUE; + } + return FALSE; +} + + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function finalizes the training pattern. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return AGESA_STATUS - Result + * AGESA_SUCCESS - Training pattern has been finalized. + * AGESA_ERROR - Unable to initialize the pattern. + */ + +AGESA_STATUS +MemNTrainingPatternFinalizeNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + AGESA_STATUS Status; + // + // Deallocate training buffer + // + Status = HeapDeallocateBuffer (AMD_MEM_TRAIN_BUFFER_HANDLE, &NBPtr->MemPtr->StdHeader); + ASSERT (Status == AGESA_SUCCESS); + return Status; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function returns the number of chipselects per channel. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return + */ + +UINT8 +MemNCSPerChannelNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + return MAX_CS_PER_CHANNEL; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function returns the number of Chipselects controlled by each set + * of Delay registers under current conditions. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return + */ + +UINT8 +MemNCSPerDelayNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + return MAX_CS_PER_DELAY; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function returns the minimum data eye width in 32nds of a UI for + * the type of data eye(Rd/Wr) that is being trained. This value will + * be the minimum number of consecutive delays that yield valid data. + * Uses TechPtr->Direction to determine read or write. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + * @return + */ + +UINT8 +MemNMinDataEyeWidthNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + if (NBPtr->TechPtr->Direction == DQS_READ_DIR) { + return MIN_RD_DATAEYE_WIDTH_NB; + } else { + return MIN_WR_DATAEYE_WIDTH_NB; + } +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function programs the phy registers according to the desired phy VDDIO voltage level + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNPhyVoltageLevelNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + BIT_FIELD_NAME BitField; + UINT16 Value; + + Value = (UINT16) NBPtr->RefPtr->DDR3Voltage << 3; + + for (BitField = BFDataRxVioLvl; BitField <= BFCmpVioLvl; BitField++) { + if (BitField == BFCmpVioLvl) { + Value <<= (14 - 3); + } + MemNBrdcstSetNb (NBPtr, BitField, Value); + } +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function adjusts Avg PRE value of Phy fence training according to specific CPU family. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in,out] *Value16 - Pointer to the value that we want to adjust + * + */ +VOID +MemNPFenceAdjustUnb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN OUT UINT16 *Value16 + ) +{ + *Value16 += 2; //for LN,ON,and OR, the Avg PRE value is subtracted by 6 only. +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * + * This function initializes the DDR phy compensation logic + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * + */ + +VOID +MemNInitPhyCompClientNb ( + IN OUT MEM_NB_BLOCK *NBPtr + ) +{ + // Slew rate table array [x][y][z] + // array[0]: slew rate for VDDIO 1.5V + // array[1]: slew rate for VDDIO 1.35V + // array[x][y]: slew rate for a certain frequency + // array[x][y][0]: frequency mask for current entry + CONST STATIC UINT16 TxPrePNDataDqs[2][3][5] = { + {{ (UINT16) DDR800, 0x924, 0x924, 0x924, 0x924}, + { (UINT16) (DDR1066 + DDR1333), 0xFF6, 0xFF6, 0xFF6, 0xFF6}, + { (UINT16) (DDR1600 + DDR1866), 0xFF6, 0xFF6, 0xFF6, 0xFF6}}, + {{ (UINT16) DDR800, 0xFF6, 0xB6D, 0xB6D, 0x924}, + { (UINT16) (DDR1066 + DDR1333), 0xFF6, 0xFF6, 0xFF6, 0xFF6}, + { (UINT16) (DDR1600 + DDR1866), 0xFF6, 0xFF6, 0xFF6, 0xFF6}} + }; + CONST STATIC UINT16 TxPrePNCmdAddr[2][3][5] = { + {{ (UINT16) DDR800, 0x492, 0x492, 0x492, 0x492}, + { (UINT16) (DDR1066 + DDR1333), 0x6DB, 0x6DB, 0x6DB, 0x6DB}, + { (UINT16) (DDR1600 + DDR1866), 0xB6D, 0xB6D, 0xB6D, 0xB6D}}, + {{ (UINT16) DDR800, 0x492, 0x492, 0x492, 0x492}, + { (UINT16) (DDR1066 + DDR1333), 0x924, 0x6DB, 0x6DB, 0x6DB}, + { (UINT16) (DDR1600 + DDR1866), 0xB6D, 0xB6D, 0x924, 0x924}} + }; + CONST STATIC UINT16 TxPrePNClock[2][3][5] = { + {{ (UINT16) DDR800, 0x924, 0x924, 0x924, 0x924}, + { (UINT16) (DDR1066 + DDR1333), 0xFF6, 0xFF6, 0xFF6, 0xB6D}, + { (UINT16) (DDR1600 + DDR1866), 0xFF6, 0xFF6, 0xFF6, 0xFF6}}, + {{ (UINT16) DDR800, 0xDAD, 0xDAD, 0x924, 0x924}, + { (UINT16) (DDR1066 + DDR1333), 0xFF6, 0xFF6, 0xFF6, 0xDAD}, + { (UINT16) (DDR1600 + DDR1866), 0xFF6, 0xFF6, 0xFF6, 0xDAD}} + }; + + CONST PHY_COMP_INIT_CLIENTNB PhyCompInitBitField[] = { + // 3. Program TxPreP/TxPreN for Data and DQS according toTable 14 if VDDIO is 1.5V or Table 15 if 1.35V. + // A. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]0[A,6]={0000b, TxPreP, TxPreN}. + // B. Program D18F2x[1,0]9C_x0D0F_0[F,7:0]02={1000b, TxPreP, TxPreN}. + {BFDqsDrvStren, BFDataByteTxPreDriverCal2Pad1, BFDataByteTxPreDriverCal2Pad1, 0, TxPrePNDataDqs}, + {BFDataDrvStren, BFDataByteTxPreDriverCal2Pad2, BFDataByteTxPreDriverCal2Pad2, 0, TxPrePNDataDqs}, + {BFDataDrvStren, BFDataByteTxPreDriverCal, BFDataByteTxPreDriverCal, 8, TxPrePNDataDqs}, + // 4. Program TxPreP/TxPreN for Cmd/Addr according toTable 16 if VDDIO is 1.5V or Table 17 if 1.35V. + // A. Program D18F2x[1,0]9C_x0D0F_[C,8][1:0][12,0E,0A,06]={0000b, TxPreP, TxPreN}. + // B. Program D18F2x[1,0]9C_x0D0F_[C,8][1:0]02={1000b, TxPreP, TxPreN}. + {BFCsOdtDrvStren, BFCmdAddr0TxPreDriverCal2Pad1, BFCmdAddr0TxPreDriverCal2Pad2, 0, TxPrePNCmdAddr}, + {BFAddrCmdDrvStren, BFCmdAddr1TxPreDriverCal2Pad1, BFAddrTxPreDriverCal2Pad4, 0, TxPrePNCmdAddr}, + {BFCsOdtDrvStren, BFCmdAddr0TxPreDriverCalPad0, BFCmdAddr0TxPreDriverCalPad0, 8, TxPrePNCmdAddr}, + {BFCkeDrvStren, BFAddrTxPreDriverCalPad0, BFAddrTxPreDriverCalPad0, 8, TxPrePNCmdAddr}, + {BFAddrCmdDrvStren, BFCmdAddr1TxPreDriverCalPad0, BFCmdAddr1TxPreDriverCalPad0, 8, TxPrePNCmdAddr}, + // 5. Program TxPreP/TxPreN for Clock according toTable 18 if VDDIO is 1.5V or Table 19 if 1.35V. + // A. Program D18F2x[1,0]9C_x0D0F_2[1:0]02={1000b, TxPreP, TxPreN}. + {BFClkDrvStren, BFClock0TxPreDriverCalPad0, BFClock1TxPreDriverCalPad0, 8, TxPrePNClock} + }; + + BIT_FIELD_NAME CurrentBitField; + UINT16 SpeedMask; + CONST UINT16 (*TxPrePNArray)[5]; + UINT8 Voltage; + UINT8 i; + UINT8 j; + UINT8 k; + UINT8 Dct; + + Dct = NBPtr->Dct; + NBPtr->SwitchDCT (NBPtr, 0); + // 1. Program D18F2x[1,0]9C_x0D0F_E003[DisAutoComp, DisablePreDriverCal] = {1b, 1b}. + MemNSetBitFieldNb (NBPtr, BFDisablePredriverCal, 0x6000); + NBPtr->SwitchDCT (NBPtr, Dct); + + SpeedMask = (UINT16) 1 << (NBPtr->DCTPtr->Timings.Speed / 66); + Voltage = (UINT8) NBPtr->RefPtr->DDR3Voltage; + + for (j = 0; j < GET_SIZE_OF (PhyCompInitBitField); j ++) { + i = (UINT8) MemNGetBitFieldNb (NBPtr, PhyCompInitBitField[j].IndexBitField); + TxPrePNArray = PhyCompInitBitField[j].TxPrePN[Voltage]; + for (k = 0; k < 3; k ++) { + if ((TxPrePNArray[k][0] & SpeedMask) != 0) { + for (CurrentBitField = PhyCompInitBitField[j].StartTargetBitField; CurrentBitField <= PhyCompInitBitField[j].EndTargetBitField; CurrentBitField ++) { + MemNSetBitFieldNb (NBPtr, CurrentBitField, ((PhyCompInitBitField[j].ExtraValue << 12) | TxPrePNArray[k][i + 1])); + } + break; + } + } + ASSERT (k < 3); + } + + NBPtr->FamilySpecificHook[ForceAutoComp] (NBPtr, NBPtr); +} + +/*----------------------------------------------------------------------------- + * + * + * This function re-enable phy compensation. + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in,out] OptParam - Optional parameter + * + * @return TRUE + * ---------------------------------------------------------------------------- + */ +BOOLEAN +MemNReEnablePhyCompNb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN OUT VOID *OptParam + ) +{ + UINT8 Dct; + + Dct = NBPtr->Dct; + + NBPtr->SwitchDCT (NBPtr, 0); + // Clear DisableCal and set DisablePredriverCal + MemNSetBitFieldNb (NBPtr, BFDisablePredriverCal, 0x2000); + NBPtr->SwitchDCT (NBPtr, Dct); + + return TRUE; +} + +/*----------------------------------------------------------------------------- + * + * + * This function calculates the value of WrDqDqsEarly and programs it into + * the DCT and adds it to the WrDqsGrossDelay of each byte lane on each + * DIMM of the channel. + * + * + * @param[in,out] *NBPtr - Pointer to the MEM_NB_BLOCK + * @param[in,out] OptParam - Optional parameter + * + * @return TRUE + * ---------------------------------------------------------------------------- + */ +BOOLEAN +MemNCalcWrDqDqsEarlyUnb ( + IN OUT MEM_NB_BLOCK *NBPtr, + IN OUT VOID *OptParam + ) +{ + MEM_TECH_BLOCK *TechPtr; + DCT_STRUCT *DCTPtr; + CH_DEF_STRUCT *ChannelPtr; + UINT8 Dimm; + UINT8 ByteLane; + UINT8 *WrDqsDlysPtr; + UINT8 WrDqDqsEarly; + + ASSERT ((NBPtr->IsSupported[WLSeedAdjust]) && (NBPtr->IsSupported[WLNegativeDelay])); + + TechPtr = NBPtr->TechPtr; + ChannelPtr = NBPtr->ChannelPtr; + DCTPtr = NBPtr->DCTPtr; + + ASSERT (NBPtr != NULL); + ASSERT (ChannelPtr != NULL); + ASSERT (DCTPtr != NULL); + // + // For each DIMM: + // - The Critical Gross Delay (CGD) is the minimum GrossDly of all byte lanes and all DIMMs. + // - If (CGD < 0) Then + // - D18F2xA8_dct[1:0][WrDqDqsEarly] = ABS(CGD) + // - WrDqsGrossDly = GrossDly + WrDqDqsEarly + // - Else + // - D18F2xA8_dct[1:0][WrDqDqsEarly] = 0. + // - WrDqsGrossDly = GrossDly + // + WrDqDqsEarly = 0; + if (TechPtr->WLCriticalDelay < 0) { + IDS_HDT_CONSOLE(MEM_FLOW, "\t\tCalculating WrDqDqsEarly, adjusting WrDqs.\n"); + // We've saved the entire negative delay value, so take the ABS and convert to GrossDly. + WrDqDqsEarly = (UINT8) (0x00FF &((((ABS (TechPtr->WLCriticalDelay)) + 0x1F) / 0x20))); + // + // Loop through All WrDqsDlys on all DIMMs + // + for (Dimm = 0; Dimm < MAX_DIMMS_PER_CHANNEL; Dimm++) { + if ((DCTPtr->Timings.CsEnabled & ((UINT16)3 << (Dimm << 1))) != 0) { + IDS_HDT_CONSOLE(MEM_FLOW, "\t\t\tDimm %x:",Dimm); + WrDqsDlysPtr = &(ChannelPtr->WrDqsDlys[(Dimm * TechPtr->DlyTableWidth ())]); + for (ByteLane = 0; ByteLane < TechPtr->DlyTableWidth (); ByteLane++) { + WrDqsDlysPtr[ByteLane] += (WrDqDqsEarly << 5); + NBPtr->SetTrainDly (NBPtr, AccessWrDqsDly, DIMM_BYTE_ACCESS (Dimm, ByteLane), WrDqsDlysPtr[ByteLane]); + IDS_HDT_CONSOLE(MEM_FLOW, " %02x",WrDqsDlysPtr[ByteLane]); + } + IDS_HDT_CONSOLE(MEM_FLOW, "\n"); + } + } + } + MemNSetBitFieldNb (NBPtr, BFWrDqDqsEarly, WrDqDqsEarly); + IDS_HDT_CONSOLE(MEM_FLOW, "\t\tWrDqDqsEarly : %02x\n",WrDqDqsEarly); + return TRUE; +} |