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Diffstat (limited to 'src/vendorcode/amd/agesa/f12/Proc/Mem/Tech/mttEdgeDetect.c')
-rwxr-xr-x | src/vendorcode/amd/agesa/f12/Proc/Mem/Tech/mttEdgeDetect.c | 910 |
1 files changed, 910 insertions, 0 deletions
diff --git a/src/vendorcode/amd/agesa/f12/Proc/Mem/Tech/mttEdgeDetect.c b/src/vendorcode/amd/agesa/f12/Proc/Mem/Tech/mttEdgeDetect.c new file mode 100755 index 0000000000..861549e2bb --- /dev/null +++ b/src/vendorcode/amd/agesa/f12/Proc/Mem/Tech/mttEdgeDetect.c @@ -0,0 +1,910 @@ +/* $NoKeywords:$ */ +/** + * @file + * + * mttEdgeDetect.c + * + * DQS R/W position training utilizing Data Eye Edge Detection for optimization + * + * @xrefitem bom "File Content Label" "Release Content" + * @e project: AGESA + * @e sub-project: (Mem/Tech) + * @e \$Revision: 49045 $ @e \$Date: 2011-03-16 13:16:58 +0800 (Wed, 16 Mar 2011) $ + * + **/ +/***************************************************************************** +* +* 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 "AdvancedApi.h" +#include "GeneralServices.h" +#include "Ids.h" +#include "heapManager.h" +#include "mm.h" +#include "mn.h" +#include "mu.h" +#include "mt.h" +#include "mport.h" +#include "mttEdgeDetect.h" +#include "OptionMemory.h" +#include "merrhdl.h" +#include "Filecode.h" +CODE_GROUP (G1_PEICC) +RDATA_GROUP (G1_PEICC) + +#define FILECODE PROC_MEM_TECH_MTTEDGEDETECT_FILECODE +/*---------------------------------------------------------------------------- + * DEFINITIONS AND MACROS + * + *---------------------------------------------------------------------------- + */ + + +#define LAST_DELAY (-128) +#define INC_DELAY 1 +#define DEC_DELAY 0 + + + +/*---------------------------------------------------------------------------- + * TYPEDEFS AND STRUCTURES + * + *---------------------------------------------------------------------------- + */ + +/*---------------------------------------------------------------------------- + * PROTOTYPES OF LOCAL FUNCTIONS + * + *---------------------------------------------------------------------------- + */ + +/** + * Sweep Table For Byte Training without insertion delay + * +*/ +DQS_POS_SWEEP_TABLE SweepTableByte[] = +{ + // Begin End Inc/Dec Step EndResult Edge + { 0x00, 0x1F, INC_DELAY, 4, 0xFFFF, LEFT_EDGE}, /// For Left Edge, start from 0 and Increment to 0x1F by 4 until all PASS + { LAST_DELAY, 0x00, DEC_DELAY, -1, 0xFE00, LEFT_EDGE}, /// Then go back down to 0x00 by 1 until all FAIL + { 0x1F, 0x00, DEC_DELAY, -4, 0xFFFF, RIGHT_EDGE}, /// For Right Edge, start from 0x1F down to 0 until all PASS. + { LAST_DELAY, 0x1F, INC_DELAY, 1, 0xFE00, RIGHT_EDGE} /// Then go back up by 1 until all FAIL. +}; +/** + * Sweep Table For Byte Training with insertion delay + * +*/ +DQS_POS_SWEEP_TABLE InsSweepTableByte[] = +{ + // Begin End Inc/Dec Step EndResult Edge + { 0x00, -0x20, DEC_DELAY, -4, 0xFE00, LEFT_EDGE}, /// For Left Edge, start from 0 and Decrement to -0x20 by -4 until all FAIL + { LAST_DELAY, 0x1F, INC_DELAY, 1, 0xFFFF, LEFT_EDGE}, /// Then go back up to 0x1F by 1 until all PASS + { 0x1F, 0x00, DEC_DELAY, -4, 0xFFFF, RIGHT_EDGE}, /// For Right Edge, start from 0x1F down to 0 until all PASS. + { LAST_DELAY, 0x1F, INC_DELAY, 1, 0xFE00, RIGHT_EDGE} /// Then go back up by 1 until all FAIL. +}; + +BOOLEAN +STATIC +MemTTrainDQSRdWrEdgeDetect ( + IN OUT MEM_TECH_BLOCK *TechPtr + ); + +BOOLEAN +STATIC +MemTInitTestPatternAddress ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr + ); + +BOOLEAN +STATIC +MemTContinueSweep ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr + ); + +BOOLEAN +STATIC +MemTSetNextDelay ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr + ); + +UINT8 +STATIC +MemTScaleDelayVal ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN INT8 Delay + ); + +BOOLEAN +STATIC +MemTDataEyeSave ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr, + IN UINT8 ByteLane + ); + +/*---------------------------------------------------------------------------- + * EXPORTED FUNCTIONS + * + *---------------------------------------------------------------------------- + */ +extern MEM_FEAT_TRAIN_SEQ memTrainSequenceDDR3[]; +/* -----------------------------------------------------------------------------*/ +/** + * + * This function executes DQS position training for all a Memory channel using + * the Edge Detection algorithm. + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * + */ + +BOOLEAN +MemTTrainDQSEdgeDetectSw ( + IN OUT MEM_TECH_BLOCK *TechPtr + ) +{ + MEM_NB_BLOCK *NBPtr; + BOOLEAN Status; + + Status = FALSE; + NBPtr = TechPtr->NBPtr; + TechPtr->TrainingType = TRN_DQS_POSITION; + // + // Initialize the Pattern + // + if (AGESA_SUCCESS == NBPtr->TrainingPatternInit (NBPtr)) { + // + // Setup hardware training engine (if applicable) + // + NBPtr->FamilySpecificHook[SetupHwTrainingEngine] (NBPtr, &TechPtr->TrainingType); + // + // Start Edge Detection + // + Status |= MemTTrainDQSRdWrEdgeDetect (TechPtr); + // + // Finalize the Pattern + // + Status &= (AGESA_SUCCESS == NBPtr->TrainingPatternFinalize (NBPtr)); + } + return Status; +} + +/*---------------------------------------------------------------------------- + * LOCAL FUNCTIONS + * + *---------------------------------------------------------------------------- + */ + +/* -----------------------------------------------------------------------------*/ +/** + * + * This Executes Read DQS and Write Data Position training on a chip select pair + * using the Edge Detection algorithm. + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * + * @return TRUE - No Errors occurred + * @return FALSE - Errors occurred + + */ + +BOOLEAN +STATIC +MemTTrainDQSRdWrEdgeDetect ( + IN OUT MEM_TECH_BLOCK *TechPtr + ) +{ + MEM_DATA_STRUCT *MemPtr; + MEM_NB_BLOCK *NBPtr; + UINT8 WrDqDelay; + UINT8 Dct; + UINT8 CSPerChannel; + UINT8 CsPerDelay; + UINT8 ChipSel; + UINT8 i; + BOOLEAN Status; + UINT8 TimesFail; + UINT8 TimesRetrain; + + NBPtr = TechPtr->NBPtr; + MemPtr = NBPtr->MemPtr; + TimesRetrain = DEFAULT_TRAINING_TIMES; + IDS_OPTION_HOOK (IDS_MEM_RETRAIN_TIMES, &TimesRetrain, &MemPtr->StdHeader); + // + // Set environment settings before training + // + IDS_HDT_CONSOLE (MEM_STATUS, "\nStart Read/Write Data Eye Edge Detection.\n"); + MemTBeginTraining (TechPtr); + // + // Do Rd DQS /Wr Data Position training for all Dcts/Chipselects + // + for (Dct = 0; Dct < NBPtr->DctCount; Dct++) { + IDS_HDT_CONSOLE (MEM_STATUS, "\tDct %d\n", Dct); + NBPtr->SwitchDCT (NBPtr, Dct); + // + // Chip Select Loop + // + CSPerChannel = NBPtr->CSPerChannel (NBPtr); + CsPerDelay = NBPtr->CSPerDelay (NBPtr); + for (ChipSel = 0; ChipSel < CSPerChannel; ChipSel = ChipSel + CsPerDelay ) { + // + // Init Bit Error Masks + // + LibAmdMemFill (&NBPtr->ChannelPtr->FailingBitMask[ (ChipSel * MAX_BYTELANES_PER_CHANNEL) ], + 0xFF, + (MAX_BYTELANES_PER_CHANNEL * CsPerDelay), + &MemPtr->StdHeader); + if ((NBPtr->DCTPtr->Timings.CsEnabled & ((UINT16) 1 << ChipSel)) != 0) { + TechPtr->ChipSel = ChipSel; + IDS_HDT_CONSOLE (MEM_STATUS, "\t\tCS %d\n", ChipSel); + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t\tIncrease WrDat, Train RdDqs:\n"); + + TechPtr->DqsRdWrPosSaved = 0; + // + // Use a list of Approximate Write Data delay values and train Read DQS Position for + // each until a valid Data eye is found. + // + Status = FALSE; + TimesFail = 0; + NBPtr->FamilySpecificHook[InitializeRxEnSeedlessTraining] (NBPtr, NBPtr); + ERROR_HANDLE_RETRAIN_BEGIN (TimesFail, TimesRetrain) { + i = 0; + while (NBPtr->GetApproximateWriteDatDelay (NBPtr, i, &WrDqDelay)) { + TechPtr->SmallDqsPosWindow = FALSE; + // + // Set Write Delay approximation + // + TechPtr->Direction = DQS_WRITE_DIR; + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\t\tWrite Delay: %02x", WrDqDelay); + MemTSetDQSDelayAllCSR (TechPtr, WrDqDelay); + // + // Attempt Read Training + // + TechPtr->Direction = DQS_READ_DIR; + Status = memTrainSequenceDDR3[NBPtr->TrainingSequenceIndex].MemTechFeatBlock->RdPosTraining (TechPtr); + if (Status) { + // + // If Read DQS Training was successful, Train Write Data (DQ) Position + // + TechPtr->DqsRdWrPosSaved = 0; + IDS_HDT_CONSOLE (MEM_FLOW, "\n\t\t\tTrain WrDat:\n\n"); + TechPtr->Direction = DQS_WRITE_DIR; + if (NBPtr->FamilySpecificHook[BeforeWrDatTrn] (NBPtr, &ChipSel)) { + Status = MemTTrainDQSEdgeDetect (TechPtr); + } + break; + } + i++; + } + ERROR_HANDLE_RETRAIN_END ((Status == FALSE), TimesFail) + } + + // + // If we went through the table, Fail. + // + if (Status == FALSE) { + // On training failure, check and record whether training fails due to small window or no window + if (TechPtr->SmallDqsPosWindow) { + NBPtr->MCTPtr->ErrStatus[EsbSmallDqs] = TRUE; + } else { + NBPtr->MCTPtr->ErrStatus[EsbNoDqsPos] = TRUE; + } + + SetMemError (AGESA_ERROR, NBPtr->MCTPtr); + if (TechPtr->Direction == DQS_READ_DIR) { + PutEventLog (AGESA_ERROR, MEM_ERROR_NO_DQS_POS_RD_WINDOW, NBPtr->Node, NBPtr->Dct, NBPtr->Channel, 0, &NBPtr->MemPtr->StdHeader); + } else { + PutEventLog (AGESA_ERROR, MEM_ERROR_NO_DQS_POS_WR_WINDOW, NBPtr->Node, NBPtr->Dct, NBPtr->Channel, 0, &NBPtr->MemPtr->StdHeader); + } + NBPtr->DCTPtr->Timings.CsTrainFail |= (UINT16)1 << ChipSel; + // If the even chip select failed training always fail the odd, if present. + if ((ChipSel & 0x01) == 0) { + if (NBPtr->DCTPtr->Timings.CsPresent & ((UINT16)1 << (ChipSel + 1))) { + NBPtr->DCTPtr->Timings.CsTrainFail |= (UINT16)1 << (ChipSel + 1); + } + } + NBPtr->MemPtr->ErrorHandling (NBPtr->MCTPtr, NBPtr->Dct, NBPtr->DCTPtr->Timings.CsTrainFail, &NBPtr->MemPtr->StdHeader); + } + } else { + // + // Clear Bit Error Masks if these CS will not be trained. + // + LibAmdMemFill (&NBPtr->ChannelPtr->FailingBitMask[ (ChipSel * MAX_BYTELANES_PER_CHANNEL) ], + 0x00, + (MAX_BYTELANES_PER_CHANNEL * CsPerDelay), + &NBPtr->MemPtr->StdHeader); + } + } + } + // + // Restore environment settings after training + // + MemTEndTraining (TechPtr); + IDS_HDT_CONSOLE (MEM_FLOW, "End Read/Write Data Eye Edge Detection\n\n"); + return (BOOLEAN) (NBPtr->MCTPtr->ErrCode < AGESA_FATAL); +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function executes DQS position training for both read and write, using + * the Edge Detection Algorithm. This method searches for the beginning and end + * of the Data Eye with out scanning every DSQ delay value. The following is a + * detailed description of the algorithm: + * + * Four-Stage Data Eye Sweep + * + * -Search starts at Delay value of 0. + * -Search left in steps of 4/32UI looking for all Byte lanes Passing. Left from zero rolls over to a negative value. + * -Negative values are translated to the high end of the delay range, but using Insertion delay comparison. + * -For each passing byte lane, freeze delay at first passing value, but set mask so next steps will not compare for byte lanes that previously passed + * -Switch to search right in steps of 1/32UI looking for fail. + * -For each lane, starting delay for 1/32 sweep right is first passing delay from 4/32 sweep left. + * -For each failing byte lane, freeze delay at first failing value, but set mask so next steps will not compare for byte lanes that previously failed + * -Search right until all byte lanes have failed + * -For each lane, right edge used by BIOS will be first failing delay value minus 1/32 + + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * + * @return TRUE - All bytelanes pass + * @return FALSE - Some bytelanes fail +*/ +BOOLEAN +MemTTrainDQSEdgeDetect ( + IN OUT MEM_TECH_BLOCK *TechPtr + ) +{ + MEM_NB_BLOCK *NBPtr; + DIE_STRUCT *MCTPtr; + DQS_POS_SWEEP_TABLE *SweepTablePtr; + UINT8 SweepTableSize; + SWEEP_INFO SweepData; + BOOLEAN Status; + UINT16 CurrentResult; + UINT16 AlignedResult; + UINT16 OffsetResult; + UINT8 StageIndex; + UINT8 CsIndex; + UINT8 CsPerDelay; + UINT8 i; + + Status = TRUE; + // + // Initialize Object Pointers + // + NBPtr = TechPtr->NBPtr; + MCTPtr = NBPtr->MCTPtr; + // + // Initialize stack variables + // + LibAmdMemFill (&SweepData, 0, sizeof (SWEEP_INFO), &NBPtr->MemPtr->StdHeader); + // + /// Get Pointer to Sweep Table + // + if (TechPtr->Direction == DQS_READ_DIR) { + SweepTablePtr = InsSweepTableByte; + SweepTableSize = GET_SIZE_OF (InsSweepTableByte); + } else { + SweepTablePtr = SweepTableByte; + SweepTableSize = GET_SIZE_OF (SweepTableByte); + } + // + // Get number of CS to train + // + CsPerDelay = NBPtr->CSPerDelay (NBPtr); + // + /// Set up the test Pattern, exit if no Memory + // + if (MemTInitTestPatternAddress (TechPtr, &SweepData) == FALSE) { + LibAmdMemFill (&NBPtr->ChannelPtr->FailingBitMask[ (TechPtr->ChipSel * MAX_BYTELANES_PER_CHANNEL) ], + 0, + (MAX_BYTELANES_PER_CHANNEL * CsPerDelay), + &NBPtr->MemPtr->StdHeader); + return FALSE; + } + // + // Clear Error Flag + // + SweepData.Error = FALSE; + NBPtr->FamilySpecificHook[InitialzeRxEnSeedlessByteLaneError] (NBPtr, NBPtr); + // + /// Process Sweep table, using entries from the table to determine Starting and Ending Delays + /// as well as the Step size and criteria for evaluating whether the correct result is found. + /// + /// Delay values at this level are an abstract range of values which gets scaled to the actual value + /// before it is written to the hardware. This allows NB specific code to handle the scaling as a + /// function of frequency or other conditions. + // + for (StageIndex = 0; (StageIndex < SweepTableSize) && (SweepData.Error == FALSE); StageIndex++) { + + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t\tSTAGE: %d\t", StageIndex); + // + /// Initialize SweepData variables + // + SweepData.BeginDelay = SweepTablePtr->BeginDelay; + SweepData.EndDelay = SweepTablePtr->EndDelay; + SweepData.Step = 0; /// Step Value will be 0 to start. + SweepData.EndResult = SweepTablePtr->EndResult; + if (!(MCTPtr->Status[SbEccDimms] && NBPtr->IsSupported[EccByteTraining])) { + SweepData.EndResult |= 0x0100; + } + SweepData.Edge = SweepTablePtr->MinMax; + SweepData.InsertionDelayMsk = 0; + SweepData.ResultFound = 0x0000; + // + // Set Training Delays Pointer. + // + if (TechPtr->Direction == DQS_READ_DIR) { + SweepData.TrnDelays = (INT8 *) ((SweepData.Edge == RIGHT_EDGE) ? NBPtr->ChannelPtr->RdDqsMaxDlys : NBPtr->ChannelPtr->RdDqsMinDlys); + } else { + SweepData.TrnDelays = (INT8 *) ((SweepData.Edge == RIGHT_EDGE) ? NBPtr->ChannelPtr->WrDatMaxDlys : NBPtr->ChannelPtr->WrDatMinDlys); + }; + // + /// Set initial TrnDelay Values if necessary + // + IDS_HDT_CONSOLE (MEM_FLOW, "Sweeping %s DQS, %s from ", (TechPtr->Direction == DQS_READ_DIR) ?"Read":"Write", (SweepTablePtr->ScanDir == INC_DELAY) ? "incrementing":"decrementing"); + if (SweepData.BeginDelay != LAST_DELAY) { + IDS_HDT_CONSOLE (MEM_FLOW, "%02x", (UINT16) MemTScaleDelayVal (TechPtr, SweepData.BeginDelay)); + for (i = 0; i < ((MCTPtr->Status[SbEccDimms] && NBPtr->IsSupported[EccByteTraining]) ? 9 : 8); i++) { + SweepData.TrnDelays[i] = SweepData.BeginDelay; + } + } else { + IDS_HDT_CONSOLE (MEM_FLOW, "Current Delay"); + SweepData.Step = SweepTablePtr->Step; + } + IDS_HDT_CONSOLE (MEM_FLOW, " by %02x, until all bytelanes %s.\n\n", (UINT16) MemTScaleDelayVal (TechPtr, ABS (SweepTablePtr->Step)), (SweepData.EndResult == 0xFFFF)?"PASS":"FAIL"); + + //------------------------------------------------------------------- + // Sweep DQS Delays + // MemTContinueSweep function returns false to break out of loop. + // There are no other breaks out of this loop. + //------------------------------------------------------------------- + while (MemTContinueSweep (TechPtr, &SweepData)) { + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t\t\tByte Lane : 08 07 06 05 04 03 02 01 00\n"); + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t\t\tDQS Delays : %02x %02x %02x %02x %02x %02x %02x %02x %02x\n", + (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[8]), + (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[7]), (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[6]), + (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[5]), (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[4]), + (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[3]), (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[2]), + (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[1]), (UINT16) MemTScaleDelayVal (TechPtr, SweepData.TrnDelays[0]) + ); + // + /// Set Step Value + // + SweepData.Step = SweepTablePtr->Step; + CurrentResult = 0xFFFF; + // + /// Chip Select Loop: Test the Pattern for all populated CS that are controlled by the current delay registers + // + for (CsIndex = 0; CsIndex < CsPerDelay ; CsIndex++, TechPtr->ChipSel++) { + ASSERT (CsIndex < MAX_CS_PER_CHANNEL); + ASSERT (TechPtr->ChipSel < MAX_CS_PER_CHANNEL); + if (SweepData.CsAddrValid[CsIndex] == TRUE) { + // + /// If this is a Write Dqs sweep, Write the pattern now. + // + if (TechPtr->Direction == DQS_WRITE_DIR) { + NBPtr->WritePattern (NBPtr, SweepData.TestAddrRJ16[CsIndex], TechPtr->PatternBufPtr, TechPtr->PatternLength); + } + // + /// Read the Pattern Back + // + NBPtr->ReadPattern (NBPtr, TechPtr->TestBufPtr, SweepData.TestAddrRJ16[CsIndex], TechPtr->PatternLength); + // + /// Compare the Pattern and Merge the results using InsertionDelayMsk + // + AlignedResult = NBPtr->CompareTestPattern (NBPtr, TechPtr->TestBufPtr, TechPtr->PatternBufPtr, TechPtr->PatternLength * 64); + CurrentResult &= AlignedResult | SweepData.InsertionDelayMsk; + if (SweepData.InsertionDelayMsk != 0) { + OffsetResult = NBPtr->InsDlyCompareTestPattern (NBPtr, TechPtr->TestBufPtr, TechPtr->PatternBufPtr, TechPtr->PatternLength * 64); + CurrentResult &= (OffsetResult | (~SweepData.InsertionDelayMsk)); + } + // + /// Flush the Test Pattern + // + NBPtr->FlushPattern (NBPtr, SweepData.TestAddrRJ16[CsIndex], TechPtr->PatternLength); + NBPtr->FamilySpecificHook[ResetRxFifoPtr] (NBPtr, NBPtr); + } + } /// End Chip Select Loop + TechPtr->ChipSel = TechPtr->ChipSel - CsIndex; + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t\t\tResult : %c %c %c %c %c %c %c %c %c \n", + (SweepData.ResultFound & ((UINT16) 1 << (8))) ? ' ':(CurrentResult & ((UINT16) 1 << (8))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (7))) ? ' ':(CurrentResult & ((UINT16) 1 << (7))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (6))) ? ' ':(CurrentResult & ((UINT16) 1 << (6))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (5))) ? ' ':(CurrentResult & ((UINT16) 1 << (5))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (4))) ? ' ':(CurrentResult & ((UINT16) 1 << (4))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (3))) ? ' ':(CurrentResult & ((UINT16) 1 << (3))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (2))) ? ' ':(CurrentResult & ((UINT16) 1 << (2))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (1))) ? ' ':(CurrentResult & ((UINT16) 1 << (1))) ? 'P':'.', + (SweepData.ResultFound & ((UINT16) 1 << (0))) ? ' ':(CurrentResult & ((UINT16) 1 << (0))) ? 'P':'.' + ); + // + /// Merge current result into cumulative result and make it positive. + // + SweepData.ResultFound |= ~(CurrentResult ^ SweepData.EndResult); + + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t\t\tResultFound : %c %c %c %c %c %c %c %c %c \n\n", + (SweepData.ResultFound & ((UINT16) 1 << (8))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (7))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (6))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (5))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (4))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (3))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (2))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (1))) ? 'Y':' ', + (SweepData.ResultFound & ((UINT16) 1 << (0))) ? 'Y':' ' + ); + } /// End of Delay Sweep + // + /// Place Final delay values at last passing delay. + // + if (SweepData.ResultFound == 0xFFFF) { + if ( ABS (SweepData.Step) == 1) { + for (i = 0; i < ((MCTPtr->Status[SbEccDimms] && NBPtr->IsSupported[EccByteTraining]) ? 9 : 8) ; i++) { + if ((SweepData.EndResult & ((UINT16) (1 << i))) == 0) { + SweepData.TrnDelays[i] = SweepData.TrnDelays[i] - SweepData.Step; + } + } + } + } + // + // Update Pointer to Sweep Table + // + SweepTablePtr++; + }///End of Edge Detect loop + // + /// If No Errors are detected, Calculate Data Eye Width and Center + // + if (SweepData.Error == FALSE) { + IDS_HDT_CONSOLE (MEM_FLOW, "\t\tData Eye Results:\n\n"); + IDS_HDT_CONSOLE (MEM_FLOW, "\t\tByte Left Right\n"); + IDS_HDT_CONSOLE (MEM_FLOW, "\t\tLane Edge Edge Width Center\n"); + for (i = 0; i < ((MCTPtr->Status[SbEccDimms] && NBPtr->IsSupported[EccByteTraining]) ? 9 : 8) ; i++) { + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t %0d", i); + TechPtr->Bytelane = i; + if (!MemTDataEyeSave (TechPtr, &SweepData, i)) { + break; + } + IDS_HDT_CONSOLE (MEM_FLOW, "\n"); + if (SweepData.Error == TRUE) { + Status = FALSE; + } + NBPtr->FamilySpecificHook[TrackRxEnSeedlessRdWrSmallWindBLError] (NBPtr, &SweepData); + } + } else { + Status = FALSE; + IDS_HDT_CONSOLE (MEM_FLOW, "\t\t--DATA EYE NOT FOUND--\n\n"); + NBPtr->FamilySpecificHook[TrackRxEnSeedlessRdWrNoWindBLError] (NBPtr, &SweepData); + } + return Status; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * Initialize the Test Pattern Address for two chip selects and, if this + * is a Write Data Eye, write the initial test pattern. + * + * Test Address is stored in the Sweep info struct. If Memory is not present + * then return with False. + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * @param[in,out] *SweepPtr - Pointer to SWEEP_INFO structure. + * + * @return BOOLEAN + * TRUE - Memory is present + * FALSE - No memory present on this Chip Select pair. + * +** + */ +BOOLEAN +STATIC +MemTInitTestPatternAddress ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr + ) +{ + MEM_NB_BLOCK *NBPtr; + UINT8 ChipSel; + UINT8 CsPerDelay; + UINT8 CsIndex; + BOOLEAN BanksPresent; + + NBPtr = TechPtr->NBPtr; + BanksPresent = FALSE; + CsPerDelay = NBPtr->CSPerDelay (NBPtr); + ChipSel = TechPtr->ChipSel; + for (CsIndex = 0; CsIndex < CsPerDelay; ChipSel++, CsIndex++, TechPtr->ChipSel++) { + ASSERT (CsIndex < MAX_CS_PER_CHANNEL); + ASSERT (ChipSel < MAX_CS_PER_CHANNEL); + ASSERT (TechPtr->ChipSel < MAX_CS_PER_CHANNEL); + // + /// If memory is present on this cs, get the test addr + // + if (NBPtr->GetSysAddr (NBPtr, ChipSel, &(SweepPtr->TestAddrRJ16[CsIndex]))) { + if (!(NBPtr->MCTPtr->Status[SbLrdimms]) || ((NBPtr->ChannelPtr->LrDimmPresent & ((UINT8) 1 << (ChipSel >> 1))) != 0)) { + BanksPresent = TRUE; + SweepPtr->CsAddrValid[CsIndex] = TRUE; + // + /// If this is a Read Dqs sweep, Write the pattern now. + // + if (TechPtr->Direction == DQS_READ_DIR) { + IDS_HDT_CONSOLE (MEM_FLOW, "\tTestAddr: %x0000\n", SweepPtr->TestAddrRJ16[CsIndex]); + NBPtr->WritePattern (NBPtr, SweepPtr->TestAddrRJ16[CsIndex], TechPtr->PatternBufPtr, TechPtr->PatternLength); + } + } + } else { + SweepPtr->CsAddrValid[CsIndex] = FALSE; + } + } /// End Chip Select Loop + TechPtr->ChipSel = TechPtr->ChipSel - CsIndex; + // + /// return FALSE if no ChipSelects present. + // + return BanksPresent; +} + +/* -----------------------------------------------------------------------------*/ +/** + * Test Conditions for exiting the training loop, set the next delay value, + * and return status + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * @param[in,out] *SweepPtr - Pointer to SWEEP_INFO structure. + * + * @return BOOLEAN + * TRUE - Continue to test with next delay setting + * FALSE - Exit training loop. Either the result has been found or + * end of delay range has been reached. +*/ +BOOLEAN +STATIC +MemTContinueSweep ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr + ) +{ + BOOLEAN Status; + Status = FALSE; + if (SweepPtr->ResultFound != 0xFFFF) { + Status = MemTSetNextDelay (TechPtr, SweepPtr); + } + return Status; +} + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function sets the next delay value for each bytelane that needs to + * be advanced. It checks the bounds of the delay to see if we are at the + * end of the range. If we are to close to advance a whole step value, but + * not at the boundary, then we set the delay to the boundary. + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * @param[in,out] *SweepPtr - Pointer to SWEEP_INFO structure. + * + */ + +BOOLEAN +STATIC +MemTSetNextDelay ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr + ) +{ + DIE_STRUCT *MCTPtr; + UINT8 i; + + MCTPtr = TechPtr->NBPtr->MCTPtr; + // + ///< Loop through bytelanes + // + for (i = 0; i < ((MCTPtr->Status[SbEccDimms] && TechPtr->NBPtr->IsSupported[EccByteTraining]) ? 9 : 8) ; i++) { + // + /// Skip Bytelanes that have already reached the desired result + // + if ( (SweepPtr->ResultFound & ((UINT16)1 << i)) == 0) { + // + /// If a bytelane has reached the end, flag an error and exit + // + if (SweepPtr->TrnDelays[i] == SweepPtr->EndDelay) { + if ((SweepPtr->EndResult & ((UINT16) (1 << i))) != 0) { + MCTPtr->ErrStatus[EsbNoDqsPos] = TRUE; + SweepPtr->Error = TRUE; + } + return FALSE; + } + // + /// If the Current delay value is less than a step away from EndDelay, + // + if ( ABS (SweepPtr->EndDelay - SweepPtr->TrnDelays[i]) < ABS (SweepPtr->Step)) { + /// set to EndDelay. + // + SweepPtr->TrnDelays[i] = SweepPtr->EndDelay; + } else { + // + /// Otherwise, add the step value to it + SweepPtr->TrnDelays[i] = SweepPtr->TrnDelays[i] + SweepPtr->Step; + } + // + /// Set InsertionDelayMsk bit if Delay < 0 for this bytelane + // + if (SweepPtr->TrnDelays[i] < 0) { + SweepPtr->InsertionDelayMsk |= ((UINT16) 1 << i); + } else { + SweepPtr->InsertionDelayMsk &= ~((UINT16) 1 << i); + } + // + /// Write the scaled value to the Delay Register + // + TechPtr->SetDQSDelayCSR (TechPtr, i, MemTScaleDelayVal (TechPtr, SweepPtr->TrnDelays[i])); + } + } + return TRUE; +} +/* -----------------------------------------------------------------------------*/ +/** + * + * This function accepts a delay value in 32nd of a UI and converts it to an + * actual register value, taking into consideration NB type, rd/wr, + * and frequency. + * + * Delay = (Min + (Delay * ( (Max - Min) / TRN_DELAY_MAX) )) & Mask + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * @param[in] *Delay - INT8 of delay value; + * + * @return UINT8 of the adjusted delay value +*/ +UINT8 +STATIC +MemTScaleDelayVal ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN INT8 Delay + ) +{ + MEM_NB_BLOCK *NBPtr; + TRN_DLY_PARMS Parms; + TRN_DLY_TYPE DelayType; + UINT8 NewDelay; + INT8 Factor; + INT8 ScaledDelay; + + NBPtr = TechPtr->NBPtr; + // + // Determine Delay Type, Get Delay Parameters, and return scaled Delay value + // + DelayType = (TechPtr->Direction == DQS_WRITE_DIR) ? AccessWrDatDly : AccessRdDqsDly; + NBPtr->GetTrainDlyParms (NBPtr, DelayType, &Parms); + Factor = ((Parms.Max - Parms.Min) / TRN_DELAY_MAX); + ScaledDelay = Delay * Factor; + NewDelay = (Parms.Min + ScaledDelay) & Parms.Mask; + return NewDelay; +} + + + + + +/* -----------------------------------------------------------------------------*/ +/** + * + * This function calculates the Center of the Data eye for the specified byte lane + * and stores its DQS Delay value for reference. + * + * @param[in,out] *TechPtr - Pointer to the MEM_TECH_BLOCK + * @param[in,out] *SweepPtr - Pointer to SWEEP_INFO structure. + * @param[in] ByteLane - Bytelane number being targeted + * + */ +BOOLEAN +STATIC +MemTDataEyeSave ( + IN OUT MEM_TECH_BLOCK *TechPtr, + IN OUT SWEEP_INFO *SweepPtr, + IN UINT8 ByteLane + ) +{ + MEM_NB_BLOCK *NBPtr; + UINT8 EyeCenter; + UINT8 DlyMin; + UINT8 DlyMax; + UINT8 EyeWidth; + UINT8 Dimm; + CH_DEF_STRUCT *ChanPtr; + + NBPtr = TechPtr->NBPtr; + ChanPtr = NBPtr->ChannelPtr; + + ASSERT (ByteLane < ((NBPtr->MCTPtr->Status[SbEccDimms] && NBPtr->IsSupported[EccByteTraining]) ? 9 : 8)); + // + // Calculate Data Eye edges, Width, and Center in real terms. + // + if (TechPtr->Direction == DQS_READ_DIR) { + DlyMin = MemTScaleDelayVal (TechPtr, ChanPtr->RdDqsMinDlys[ByteLane]); + DlyMax = MemTScaleDelayVal (TechPtr, ChanPtr->RdDqsMaxDlys[ByteLane]); + EyeWidth = MemTScaleDelayVal (TechPtr, (ChanPtr->RdDqsMaxDlys[ByteLane] - ChanPtr->RdDqsMinDlys[ByteLane])); + EyeCenter = MemTScaleDelayVal (TechPtr, ((ChanPtr->RdDqsMinDlys[ByteLane] + ChanPtr->RdDqsMaxDlys[ByteLane] + 1) / 2)); + if (!NBPtr->FamilySpecificHook[RdDqsDlyRestartChk] (NBPtr, &EyeCenter)) { + return FALSE; + } + ChanPtr->RdDqsMinDlys[ByteLane] = DlyMin; + ChanPtr->RdDqsMaxDlys[ByteLane] = DlyMax; + NBPtr->FamilySpecificHook[ForceRdDqsPhaseB] (NBPtr, &EyeCenter); + } else { + DlyMin = MemTScaleDelayVal (TechPtr, ChanPtr->WrDatMinDlys[ByteLane]); + DlyMax = MemTScaleDelayVal (TechPtr, ChanPtr->WrDatMaxDlys[ByteLane]); + EyeWidth = MemTScaleDelayVal (TechPtr, (ChanPtr->WrDatMaxDlys[ByteLane] - ChanPtr->WrDatMinDlys[ByteLane])); + EyeCenter = MemTScaleDelayVal (TechPtr, ((ChanPtr->WrDatMinDlys[ByteLane] + ChanPtr->WrDatMaxDlys[ByteLane] + 1) / 2)); + ChanPtr->WrDatMinDlys[ByteLane] = DlyMin; + ChanPtr->WrDatMaxDlys[ByteLane] = DlyMax; + } + // + // Flag error for small window. + // + if (EyeWidth < MemTScaleDelayVal (TechPtr, NBPtr->MinDataEyeWidth (NBPtr))) { + TechPtr->SmallDqsPosWindow = TRUE; + SweepPtr->Error = TRUE; + } + + IDS_HDT_CONSOLE (MEM_FLOW, " %02x %02x %02x %02x", DlyMin, DlyMax, EyeWidth, EyeCenter); + + TechPtr->SetDQSDelayCSR (TechPtr, ByteLane, EyeCenter); + if (!SweepPtr->Error) { + TechPtr->DqsRdWrPosSaved |= (UINT8)1 << ByteLane; + } + TechPtr->DqsRdWrPosSaved |= 0xFE00; + + Dimm = (TechPtr->ChipSel / 2) * TechPtr->DlyTableWidth () + ByteLane; + if (TechPtr->Direction == DQS_READ_DIR) { + ChanPtr->RdDqsDlys[Dimm] = EyeCenter; + } else { + ChanPtr->WrDatDlys[Dimm] = EyeCenter + ChanPtr->WrDqsDlys[Dimm]; + } + + return TRUE; +} + |