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/*
* This file is part of the coreboot project.
*
* Copyright (C) 2007 Advanced Micro Devices, Inc.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*
* Description: Max Read Latency Training feature for DDR 2 MCT
*/
static u8 CompareMaxRdLatTestPattern_D(u32 pattern_buf, u32 addr);
static u32 GetMaxRdLatTestAddr_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat, u8 Channel,
u8 *MaxRcvrEnDly, u8 *valid);
u8 mct_GetStartMaxRdLat_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat, u8 Channel,
u8 DQSRcvEnDly, u32 *Margin);
static void maxRdLatencyTrain_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat);
static void mct_setMaxRdLatTrnVal_D(struct DCTStatStruc *pDCTstat, u8 Channel,
u16 MaxRdLatVal);
/*Warning: These must be located so they do not cross a logical 16-bit
segment boundary!*/
static const u32 TestMaxRdLAtPattern_D[] = {
0x6E0E3FAC, 0x0C3CFF52,
0x4A688181, 0x49C5B613,
0x7C780BA6, 0x5C1650E3,
0x0C4F9D76, 0x0C6753E6,
0x205535A5, 0xBABFB6CA,
0x610E6E5F, 0x0C5F1C87,
0x488493CE, 0x14C9C383,
0xF5B9A5CD, 0x9CE8F615,
0xAAD714B5, 0xC38F1B4C,
0x72ED647C, 0x669F7562,
0x5233F802, 0x4A898B30,
0x10A40617, 0x3326B465,
0x55386E04, 0xC807E3D3,
0xAB49E193, 0x14B4E63A,
0x67DF2495, 0xEA517C45,
0x7624CE51, 0xF8140C51,
0x4824BD23, 0xB61DD0C9,
0x072BCFBE, 0xE8F3807D,
0x919EA373, 0x25E30C47,
0xFEB12958, 0x4DA80A5A,
0xE9A0DDF8, 0x792B0076,
0xE81C73DC, 0xF025B496,
0x1DB7E627, 0x808594FE,
0x82668268, 0x655C7783,
};
static u32 SetupMaxRdPattern(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat,
u32 *buffer)
{
/* 1. Copy the alpha and Beta patterns from ROM to Cache,
* aligning on 16 byte boundary
* 2. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufA
* for Alpha
* 3. Set the ptr to Cacheable copy in DCTStatstruc.PtrPatternBufB
* for Beta
*/
u32 *buf;
u8 i;
buf = (u32 *)(((u32)buffer + 0x10) & (0xfffffff0));
for(i = 0; i < (16 * 3); i++) {
buf[i] = TestMaxRdLAtPattern_D[i];
}
return (u32)buf;
}
void TrainMaxReadLatency_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstatA)
{
u8 Node;
for(Node = 0; Node < MAX_NODES_SUPPORTED; Node++) {
struct DCTStatStruc *pDCTstat;
pDCTstat = pDCTstatA + Node;
if(!pDCTstat->NodePresent)
break;
if(pDCTstat->DCTSysLimit)
maxRdLatencyTrain_D(pMCTstat, pDCTstat);
}
}
static void maxRdLatencyTrain_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat)
{
u8 Channel;
u32 TestAddr0;
u8 _DisableDramECC = 0, _Wrap32Dis = 0, _SSE2 = 0;
u16 MaxRdLatDly;
u8 RcvrEnDly = 0;
u32 PatternBuffer[60]; // FIXME: why not 48 + 4
u32 Margin;
u32 addr;
u32 cr4;
u32 lo, hi;
u8 valid;
u32 pattern_buf;
cr4 = read_cr4();
if(cr4 & (1<<9)) { /* save the old value */
_SSE2 = 1;
}
cr4 |= (1<<9); /* OSFXSR enable SSE2 */
write_cr4(cr4);
addr = HWCR;
_RDMSR(addr, &lo, &hi);
if(lo & (1<<17)) { /* save the old value */
_Wrap32Dis = 1;
}
lo |= (1<<17); /* HWCR.wrap32dis */
lo &= ~(1<<15); /* SSEDIS */
/* Setting wrap32dis allows 64-bit memory references in
real mode */
_WRMSR(addr, lo, hi);
_DisableDramECC = mct_DisableDimmEccEn_D(pMCTstat, pDCTstat);
pattern_buf = SetupMaxRdPattern(pMCTstat, pDCTstat, PatternBuffer);
for (Channel = 0; Channel < 2; Channel++) {
print_debug_dqs("\tMaxRdLatencyTrain51: Channel ",Channel, 1);
pDCTstat->Channel = Channel;
if( (pDCTstat->Status & (1 << SB_128bitmode)) && Channel)
break; /*if ganged mode, skip DCT 1 */
TestAddr0 = GetMaxRdLatTestAddr_D(pMCTstat, pDCTstat, Channel, &RcvrEnDly, &valid);
if(!valid) /* Address not supported on current CS */
continue;
/* rank 1 of DIMM, testpattern 0 */
WriteMaxRdLat1CLTestPattern_D(pattern_buf, TestAddr0);
MaxRdLatDly = mct_GetStartMaxRdLat_D(pMCTstat, pDCTstat, Channel, RcvrEnDly, &Margin);
print_debug_dqs("\tMaxRdLatencyTrain52: MaxRdLatDly start ", MaxRdLatDly, 2);
print_debug_dqs("\tMaxRdLatencyTrain52: MaxRdLatDly Margin ", Margin, 2);
while(MaxRdLatDly < MAX_RD_LAT) { /* sweep Delay value here */
mct_setMaxRdLatTrnVal_D(pDCTstat, Channel, MaxRdLatDly);
ReadMaxRdLat1CLTestPattern_D(TestAddr0);
if( CompareMaxRdLatTestPattern_D(pattern_buf, TestAddr0) == DQS_PASS)
break;
SetTargetWTIO_D(TestAddr0);
FlushMaxRdLatTestPattern_D(TestAddr0);
ResetTargetWTIO_D();
MaxRdLatDly++;
}
print_debug_dqs("\tMaxRdLatencyTrain53: MaxRdLatDly end ", MaxRdLatDly, 2);
mct_setMaxRdLatTrnVal_D(pDCTstat, Channel, MaxRdLatDly + Margin);
}
if(_DisableDramECC) {
mct_EnableDimmEccEn_D(pMCTstat, pDCTstat, _DisableDramECC);
}
if(!_Wrap32Dis) {
addr = HWCR;
_RDMSR(addr, &lo, &hi);
lo &= ~(1<<17); /* restore HWCR.wrap32dis */
_WRMSR(addr, lo, hi);
}
if(!_SSE2){
cr4 = read_cr4();
cr4 &= ~(1<<9); /* restore cr4.OSFXSR */
write_cr4(cr4);
}
#if DQS_TRAIN_DEBUG > 0
{
u8 Channel;
print_debug("maxRdLatencyTrain: CH_MaxRdLat:\n");
for(Channel = 0; Channel<2; Channel++) {
print_debug("Channel:"); print_debug_hex8(Channel);
print_debug(": ");
print_debug_hex8( pDCTstat->CH_MaxRdLat[Channel] );
print_debug("\n");
}
}
#endif
}
static void mct_setMaxRdLatTrnVal_D(struct DCTStatStruc *pDCTstat,
u8 Channel, u16 MaxRdLatVal)
{
u8 i;
u32 reg;
u32 dev;
u32 val;
if (pDCTstat->GangedMode) {
Channel = 0; // for safe
for (i=0; i<2; i++)
pDCTstat->CH_MaxRdLat[i] = MaxRdLatVal;
} else {
pDCTstat->CH_MaxRdLat[Channel] = MaxRdLatVal;
}
dev = pDCTstat->dev_dct;
reg = 0x78 + Channel * 0x100;
val = Get_NB32(dev, reg);
val &= ~(0x3ff<<22);
val |= MaxRdLatVal<<22;
/* program MaxRdLatency to correspond with current delay */
Set_NB32(dev, reg, val);
}
static u8 CompareMaxRdLatTestPattern_D(u32 pattern_buf, u32 addr)
{
/* Compare only the first beat of data. Since target addrs are cache
* line aligned, the Channel parameter is used to determine which cache
* QW to compare.
*/
u32 *test_buf = (u32 *)pattern_buf;
u32 addr_lo;
u32 val, val_test;
int i;
u8 ret = DQS_PASS;
SetUpperFSbase(addr);
addr_lo = addr<<8;
_EXECFENCE;
for (i=0; i<(16*3); i++) {
val = read32_fs(addr_lo);
val_test = test_buf[i];
print_debug_dqs_pair("\t\t\t\t\t\ttest_buf = ", (u32)test_buf, " value = ", val_test, 5);
print_debug_dqs_pair("\t\t\t\t\t\ttaddr_lo = ", addr_lo, " value = ", val, 5);
if(val != val_test) {
ret = DQS_FAIL;
break;
}
addr_lo += 4;
}
return ret;
}
static u32 GetMaxRdLatTestAddr_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat,
u8 Channel, u8 *MaxRcvrEnDly,
u8 *valid)
{
u8 Max = 0;
u8 Channel_Max = 0;
u8 d;
u8 d_Max = 0;
u8 Byte;
u32 TestAddr0 = 0;
u8 ch, ch_start, ch_end;
u8 bn;
bn = 8;
if(pDCTstat->Status & (1 << SB_128bitmode)) {
ch_start = 0;
ch_end = 2;
} else {
ch_start = Channel;
ch_end = Channel + 1;
}
*valid = 0;
for(ch = ch_start; ch < ch_end; ch++) {
for(d=0; d<4; d++) {
for(Byte = 0; Byte<bn; Byte++) {
u8 tmp;
tmp = pDCTstat->CH_D_B_RCVRDLY[ch][d][Byte];
if(tmp>Max) {
Max = tmp;
Channel_Max = Channel;
d_Max = d;
}
}
}
}
if(mct_RcvrRankEnabled_D(pMCTstat, pDCTstat, Channel_Max, d_Max << 1)) {
TestAddr0 = mct_GetMCTSysAddr_D(pMCTstat, pDCTstat, Channel_Max, d_Max << 1, valid);
}
if(*valid)
*MaxRcvrEnDly = Max;
return TestAddr0;
}
u8 mct_GetStartMaxRdLat_D(struct MCTStatStruc *pMCTstat,
struct DCTStatStruc *pDCTstat,
u8 Channel, u8 DQSRcvEnDly, u32 *Margin)
{
u32 SubTotal;
u32 val;
u32 valx;
u32 valxx;
u32 index_reg;
u32 reg_off;
u32 dev;
if(pDCTstat->GangedMode)
Channel = 0;
index_reg = 0x98 + 0x100 * Channel;
reg_off = 0x100 * Channel;
dev = pDCTstat->dev_dct;
/* Multiply the CAS Latency by two to get a number of 1/2 MEMCLKs units.*/
val = Get_NB32(dev, 0x88 + reg_off);
SubTotal = ((val & 0x0f) + 1) << 1; /* SubTotal is 1/2 Memclk unit */
/* If registered DIMMs are being used then add 1 MEMCLK to the sub-total*/
val = Get_NB32(dev, 0x90 + reg_off);
if(!(val & (1 << UnBuffDimm)))
SubTotal += 2;
/*If the address prelaunch is setup for 1/2 MEMCLKs then add 1,
* else add 2 to the sub-total. if (AddrCmdSetup || CsOdtSetup
* || CkeSetup) then K := K + 2; */
val = Get_NB32_index_wait(dev, index_reg, 0x04);
if(!(val & 0x00202020))
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. */
val = Get_NB32(dev, 0x78 + reg_off);
SubTotal += 8 - (val & 0x0f);
/* Convert bits 7-5 (also referred to as the course delay) of the current
* (or worst case) DQS receiver enable delay to 1/2 MEMCLKs units,
* rounding up, and add this to the sub-total. */
SubTotal += DQSRcvEnDly >> 5; /*BOZO-no rounding up */
SubTotal <<= 1; /*scale 1/2 MemClk to 1/4 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). */
/*New formula:
SubTotal *= 3*(Fn2xD4[NBFid]+4)/(3+Fn2x94[MemClkFreq])/2 */
val = Get_NB32(dev, 0x94 + reg_off);
/* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
val &= 7;
if (val == 4) {
val++; /* adjust for DDR2-1066 */
}
valx = (val + 3) << 2; /* SubTotal div 4 to scale 1/4 MemClk back to MemClk */
val = Get_NB32(pDCTstat->dev_nbmisc, 0xD4);
val = ((val & 0x1f) + 4 ) * 3;
/* Calculate 1 MemClk + 1 NCLK delay in NCLKs for margin */
valxx = val << 2;
valxx /= valx;
if (valxx % valx)
valxx++; /* round up */
valxx++; /* add 1NCLK */
*Margin = valxx; /* one MemClk delay in NCLKs and one additional NCLK */
val *= SubTotal;
val /= valx;
if (val % valx)
val++; /* round up */
return val;
}
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