/* V2MemTest - A CLI Tool to test & fix Voodoo² TMU System
* Copyright (C) 2026 ChaCha
*
* 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, either version 3 of the License, or
* (at your option) any later version.
*
* 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, see .
*/
#include
#include "cvg.h"
#include
#include "sst1init.h"
#include "fxpci.h"
#include "FaultSources.h"
#include "Utils.h"
#include "Draw.h"
#include "Test_Address.h"
typedef struct _def_sTestAddress {
FxU32 u32Addr;
unsigned char nBank; // RAS0 and RAS1 (Front/Back)
unsigned char nColBit;
unsigned char nRowBit;
}def_sTestAddress;
unsigned long
RenderTestAddress( sst1DeviceInfoStruct* devInfo,
FxU32* sst,
SstRegs *sstregs,
const char ucNumTMU,
const unsigned char RamSizeMB)
{
devInfo->tmuInit0[(int)ucNumTMU] = SST_TREXINIT0_DEFAULT ;
sst1InitIdle(sst);
ISET(SST_TREX(sstregs,ucNumTMU)->trexInit0, devInfo->tmuInit0[(int)ucNumTMU]);
sst1InitIdle(sst);
/*
sst1InitIdle(sst);
ISET(SST_TREX(sstregs,ucNumTMU)->trexInit0, 0x5000 | (devInfo->tmuInit0[(int)ucNumTMU] & ~0x7000));
sst1InitIdle(sst);
*/
// set downstream TMUs to passthrough
for (int i=0; itextureMode, SST_TC_PASS | SST_TCA_PASS);
unsigned long NbErr=0;
//long TestVal1;
//long TestVal2;
//long TestValBlank1;
//long TestValBlank2;
const def_sTestAddress add_list[] =
{
// Bank0
{0x000000,0,0,0},
/* not addressable because its a 64bit bus
{0x000001,0,0,0,0}
{0x000002,0,0,0,0}
{0x000004,0,0,0,0}
*/
{0x000008,0,1,0},
{0x000010,0,2,0}, {0x000018,0,2,0}, // target + adjacent pin
{0x000020,0,3,0}, {0x000030,0,3,0},
{0x000040,0,4,0}, {0x000060,0,4,0},
{0x000080,0,5,0}, {0x0000C0,0,5,0},
{0x000100,0,6,0}, {0x000180,0,6,0},
{0x000200,0,7,0}, {0x000300,0,7,0},
{0x000400,0,8,0}, {0x000600,0,8,0},
{0x000800,0,9,0}, {0x000C00,0,9,0}, // => Ignoring adjacent for now
{0x001000,0,0,1}, {0x001800,0,0,1}, // It seems useless
{0x002000,0,0,2}, {0x003000,0,0,2},
{0x004000,0,0,3}, {0x006000,0,0,3},
{0x008000,0,0,4}, {0x00C000,0,0,4},
{0x010000,0,0,5}, {0x018000,0,0,5},
{0x020000,0,0,6}, {0x030000,0,0,6},
{0x040000,0,0,7}, {0x060000,0,0,7},
{0x080000,0,0,8}, {0x0C0000,0,0,8},
{0x100000,0,0,9}, {0x180000,0,0,9},
// Bank1
{0x200000,1,0,0},
/* not addressable because its a 64bit bus
{0x200001,0,0,0,0}
{0x200002,0,0,0,0}
{0x200004,0,0,0,0}
*/
{0x200008,1,1,0},
{0x200010,1,2,0}, {0x200018,1,2,0},
{0x200020,1,3,0}, {0x200030,1,3,0},
{0x200040,1,4,0}, {0x200060,1,4,0},
{0x200080,1,5,0}, {0x2000C0,1,5,0},
{0x200100,1,6,0}, {0x200180,1,6,0},
{0x200200,1,7,0}, {0x200300,1,7,0},
{0x200400,1,8,0}, {0x200600,1,8,0},
{0x200800,1,9,0}, {0x200C00,1,9,0},
{0x201000,1,0,1}, {0x201800,1,0,1},
{0x202000,1,0,2}, {0x203000,1,0,2},
{0x204000,1,0,3}, {0x206000,1,0,3},
{0x208000,1,0,4}, {0x20C000,1,0,4},
{0x210000,1,0,5}, {0x218000,1,0,5},
{0x220000,1,0,6}, {0x230000,1,0,6},
{0x240000,1,0,7}, {0x260000,1,0,7},
{0x280000,1,0,8}, {0x2C0000,1,0,8},
{0x300000,1,0,9}, {0x380000,1,0,9},
};
for(unsigned char idx=0;
idx < sizeof(add_list)/sizeof(def_sTestAddress);
idx++)
{
if(RamSizeMB<4 && add_list[idx].u32Addr >= 0x300000) continue;
if(RamSizeMB<3 && add_list[idx].u32Addr >= 0x200000) continue;
if(RamSizeMB<2 && add_list[idx].u32Addr >= 0x100000) continue;
const uint32_t TestVal1 = get_notnull_random_balanced_mByte();
const uint32_t TestVal2 = get_notnull_random_balanced_mByte();
const uint32_t TestValBlank1 = get_notnull_random_balanced_mByte();
const uint32_t TestValBlank2 = get_notnull_random_balanced_mByte();
// Clearing memory targets
for(unsigned char idxclr=0;
idxclr < sizeof(add_list)/sizeof(def_sTestAddress);
idxclr++)
{
if(RamSizeMB<4 && add_list[idxclr].u32Addr >= 0x300000) continue;
if(RamSizeMB<3 && add_list[idxclr].u32Addr >= 0x200000) continue;
if(RamSizeMB<2 && add_list[idxclr].u32Addr >= 0x100000) continue;
/* set to mem addr */
ISET(sstregs->texBaseAddr, (add_list[idxclr].u32Addr>>3));
/* First line, using bits 00..31*/
volatile const FxU32 *texAddrBlank = (ucNumTMU<<(21-2)) + (((FxU32)0/*LOD0*/)<<(17-2)) + (FxU32 *)SST_TEX_ADDRESS(sst);
ISET(texAddrBlank[0], TestValBlank1); /* write a value */
/* Second line, to use bits 32..63*/
volatile const FxU32 *texAddrBlank2 = (ucNumTMU<<(21-2)) + (((FxU32)0/*LOD0*/)<<(17-2)) + (1<<(9-2))+ (FxU32 *)SST_TEX_ADDRESS(sst);
ISET(texAddrBlank2[0], TestValBlank2); /* write a value */
}
/* set to mem addr */
ISET(sstregs->texBaseAddr, (add_list[idx].u32Addr>>3));
/* First line, using bits 00..31*/
volatile const FxU32 *texAddr = (ucNumTMU<<(21-2)) + (((FxU32)0/*LOD0*/)<<(17-2)) + (FxU32 *)SST_TEX_ADDRESS(sst);
ISET(texAddr[0], TestVal1); /* write a value */
/* Second line, to use bits 32..63*/
volatile const FxU32 *texAddr2 = (ucNumTMU<<(21-2)) + (((FxU32)0/*LOD0*/)<<(17-2)) + (1<<(9-2))+ (FxU32 *)SST_TEX_ADDRESS(sst);
ISET(texAddr2[0], TestVal2); /* write a value */
// Checking expected memory map is there
for(unsigned char idxdraw=0;
idxdraw < sizeof(add_list) / sizeof(def_sTestAddress);
idxdraw++)
{
if(RamSizeMB<4 && add_list[idxdraw].u32Addr >= 0x300000) continue;
if(RamSizeMB<3 && add_list[idxdraw].u32Addr >= 0x200000) continue;
if(RamSizeMB<2 && add_list[idxdraw].u32Addr >= 0x100000) continue;
// testing copy beyond tested bit is useless & can raise
// false positive
if(idxdraw > idx) break;
/* set to mem addr */ //TODO: 4x2
ISET(sstregs->texBaseAddr, (add_list[idxdraw].u32Addr >> 3));
/* draw a 4x4 triangle */
drawSquare(sstregs, 0, 0, 4);
sst1InitIdle(sst);
// First line, to use bits 00..31
const uint32_t L1 = IGET(sst[(SST_LFB_ADDR>>2) + 0]);
// Second line,to use bits 32..63
const uint32_t L2 = IGET(sst[(SST_LFB_ADDR>>2) + (2048>>2) + 0]);
const uint32_t ErrorMark_L1 = (idxdraw == idx) ? (L1 ^ TestVal1) : (L1 ^ TestValBlank1);
const uint32_t ErrorMark_L2 = (idxdraw == idx) ? (L2 ^ TestVal2) : (L2 ^ TestValBlank2);
const uint32_t ErrorMarkBlank_L1 = (idxdraw == idx) ? (L1 ^ TestValBlank1) : (L1 ^ TestVal1);
const uint32_t ErrorMarkBlank_L2 = (idxdraw == idx) ? (L2 ^ TestValBlank2) : (L2 ^ TestVal2) ;
if(ErrorMark_L1 || ErrorMark_L2)
{
const def_eFaultSource TMUTexADDR_0_0 = (ucNumTMU == 0) ? U9_TMU0_TEX_ADDR_0_0 : U8_TMU1_TEX_ADDR_0_0;
const def_eFaultSource TMUTexADDR_1_0 = (ucNumTMU == 0) ? U9_TMU0_TEX_ADDR_1_0 : U8_TMU1_TEX_ADDR_1_0;
const def_eFaultSource TMUTexADDR_2_0 = (ucNumTMU == 0) ? U9_TMU0_TEX_ADDR_2_0 : U8_TMU1_TEX_ADDR_2_0;
const def_eFaultSource TMUTexADDR_3_0 = (ucNumTMU == 0) ? U9_TMU0_TEX_ADDR_3_0 : U8_TMU1_TEX_ADDR_3_0;
const def_eFaultSource TMUTexWE = (ucNumTMU == 0) ? U9_TMU0_TEX_WE : U8_TMU1_TEX_WE;
const def_eFaultSource TMUTexCAS0 = (ucNumTMU == 0) ? U9_TMU0_TEX_CAS0 : U8_TMU1_TEX_CAS0;
const def_eFaultSource TMUTexCAS1 = (ucNumTMU == 0) ? U9_TMU0_TEX_CAS1 : U8_TMU1_TEX_CAS1;
const def_eFaultSource TMUTexCAS2 = (ucNumTMU == 0) ? U9_TMU0_TEX_CAS2 : U8_TMU1_TEX_CAS2;
const def_eFaultSource TMUTexCAS3 = (ucNumTMU == 0) ? U9_TMU0_TEX_CAS3 : U8_TMU1_TEX_CAS3;
const def_eFaultSource _TMUTexRAS0 = (ucNumTMU == 0) ? U9_TMU0_TEX_RAS0 : U8_TMU1_TEX_RAS0;
const def_eFaultSource _TMUTexRAS1 = (ucNumTMU == 0) ? U9_TMU0_TEX_RAS1 : U8_TMU1_TEX_RAS1;
const def_eFaultSource TMUTexRASCurrent = (add_list[idxdraw].nBank == 0) ? _TMUTexRAS0 : _TMUTexRAS1;
const def_eFaultSource _MEMChip_B0_0_A0 = (ucNumTMU == 0) ? U14_A0 : U13_A0;
const def_eFaultSource _MEMChip_B0_1_A0 = (ucNumTMU == 0) ? U12_A0 : U11_A0;
const def_eFaultSource _MEMChip_B0_2_A0 = (ucNumTMU == 0) ? U18_A0 : U16_A0;
const def_eFaultSource _MEMChip_B0_3_A0 = (ucNumTMU == 0) ? U17_A0 : U15_A0;
const def_eFaultSource _MEMChip_B1_0_A0 = (ucNumTMU == 0) ? U23_A0 : U27_A0;
const def_eFaultSource _MEMChip_B1_1_A0 = (ucNumTMU == 0) ? U24_A0 : U28_A0;
const def_eFaultSource _MEMChip_B1_2_A0 = (ucNumTMU == 0) ? U25_A0 : U29_A0;
const def_eFaultSource _MEMChip_B1_3_A0 = (ucNumTMU == 0) ? U26_A0 : U30_A0;
const def_eFaultSource MEMChip_0_A0 = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_0_A0 : _MEMChip_B1_0_A0;
const def_eFaultSource MEMChip_1_A0 = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_1_A0 : _MEMChip_B1_1_A0;
const def_eFaultSource MEMChip_2_A0 = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_2_A0 : _MEMChip_B1_2_A0;
const def_eFaultSource MEMChip_3_A0 = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_3_A0 : _MEMChip_B1_3_A0;
const def_eFaultSource _MEMChip_B0_0_CASL = (ucNumTMU == 0) ? U14_CASL : U13_CASL;
const def_eFaultSource _MEMChip_B0_1_CASL = (ucNumTMU == 0) ? U12_CASL : U11_CASL;
const def_eFaultSource _MEMChip_B0_2_CASL = (ucNumTMU == 0) ? U18_CASL : U16_CASL;
const def_eFaultSource _MEMChip_B0_3_CASL = (ucNumTMU == 0) ? U17_CASL : U15_CASL;
const def_eFaultSource _MEMChip_B1_0_CASL = (ucNumTMU == 0) ? U23_CASL : U27_CASL;
const def_eFaultSource _MEMChip_B1_1_CASL = (ucNumTMU == 0) ? U24_CASL : U28_CASL;
const def_eFaultSource _MEMChip_B1_2_CASL = (ucNumTMU == 0) ? U25_CASL : U29_CASL;
const def_eFaultSource _MEMChip_B1_3_CASL = (ucNumTMU == 0) ? U26_CASL : U30_CASL;
const def_eFaultSource MEMChip_0_CASL = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_0_CASL : _MEMChip_B1_0_CASL;
const def_eFaultSource MEMChip_1_CASL = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_1_CASL : _MEMChip_B1_1_CASL;
const def_eFaultSource MEMChip_2_CASL = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_2_CASL : _MEMChip_B1_2_CASL;
const def_eFaultSource MEMChip_3_CASL = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_3_CASL : _MEMChip_B1_3_CASL;
const def_eFaultSource _MEMChip_B0_0_CASH = (ucNumTMU == 0) ? U14_CASH : U13_CASH;
const def_eFaultSource _MEMChip_B0_1_CASH = (ucNumTMU == 0) ? U12_CASH : U11_CASH;
const def_eFaultSource _MEMChip_B0_2_CASH = (ucNumTMU == 0) ? U18_CASH : U16_CASH;
const def_eFaultSource _MEMChip_B0_3_CASH = (ucNumTMU == 0) ? U17_CASH : U15_CASH;
const def_eFaultSource _MEMChip_B1_0_CASH = (ucNumTMU == 0) ? U23_CASH : U27_CASH;
const def_eFaultSource _MEMChip_B1_1_CASH = (ucNumTMU == 0) ? U24_CASH : U28_CASH;
const def_eFaultSource _MEMChip_B1_2_CASH = (ucNumTMU == 0) ? U25_CASH : U29_CASH;
const def_eFaultSource _MEMChip_B1_3_CASH = (ucNumTMU == 0) ? U26_CASH : U30_CASH;
const def_eFaultSource MEMChip_0_CASH = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_0_CASH : _MEMChip_B1_0_CASH;
const def_eFaultSource MEMChip_1_CASH = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_1_CASH : _MEMChip_B1_1_CASH;
const def_eFaultSource MEMChip_2_CASH = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_2_CASH : _MEMChip_B1_2_CASH;
const def_eFaultSource MEMChip_3_CASH = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_3_CASH : _MEMChip_B1_3_CASH;
const def_eFaultSource _MEMChip_B0_0_RAS = (ucNumTMU == 0) ? U14_RAS : U13_RAS;
const def_eFaultSource _MEMChip_B0_1_RAS = (ucNumTMU == 0) ? U12_RAS : U11_RAS;
const def_eFaultSource _MEMChip_B0_2_RAS = (ucNumTMU == 0) ? U18_RAS : U16_RAS;
const def_eFaultSource _MEMChip_B0_3_RAS = (ucNumTMU == 0) ? U17_RAS : U15_RAS;
const def_eFaultSource _MEMChip_B1_0_RAS = (ucNumTMU == 0) ? U23_RAS : U27_RAS;
const def_eFaultSource _MEMChip_B1_1_RAS = (ucNumTMU == 0) ? U24_RAS : U28_RAS;
const def_eFaultSource _MEMChip_B1_2_RAS = (ucNumTMU == 0) ? U25_RAS : U29_RAS;
const def_eFaultSource _MEMChip_B1_3_RAS = (ucNumTMU == 0) ? U26_RAS : U30_RAS;
const def_eFaultSource MEMChip_0_RAS = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_0_RAS : _MEMChip_B1_0_RAS;
const def_eFaultSource MEMChip_1_RAS = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_1_RAS : _MEMChip_B1_1_RAS;
const def_eFaultSource MEMChip_2_RAS = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_2_RAS : _MEMChip_B1_2_RAS;
const def_eFaultSource MEMChip_3_RAS = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_3_RAS : _MEMChip_B1_3_RAS;
const def_eFaultSource _MEMChip_B0_0_WE = (ucNumTMU == 0) ? U14_WE : U13_WE;
const def_eFaultSource _MEMChip_B0_1_WE = (ucNumTMU == 0) ? U12_WE : U11_WE;
const def_eFaultSource _MEMChip_B0_2_WE = (ucNumTMU == 0) ? U18_WE : U16_WE;
const def_eFaultSource _MEMChip_B0_3_WE = (ucNumTMU == 0) ? U17_WE : U15_WE;
const def_eFaultSource _MEMChip_B1_0_WE = (ucNumTMU == 0) ? U23_WE : U27_WE;
const def_eFaultSource _MEMChip_B1_1_WE = (ucNumTMU == 0) ? U24_WE : U28_WE;
const def_eFaultSource _MEMChip_B1_2_WE = (ucNumTMU == 0) ? U25_WE : U29_WE;
const def_eFaultSource _MEMChip_B1_3_WE = (ucNumTMU == 0) ? U26_WE : U30_WE;
const def_eFaultSource MEMChip_0_WE = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_0_WE : _MEMChip_B1_0_WE;
const def_eFaultSource MEMChip_1_WE = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_1_WE : _MEMChip_B1_1_WE;
const def_eFaultSource MEMChip_2_WE = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_2_WE : _MEMChip_B1_2_WE;
const def_eFaultSource MEMChip_3_WE = (add_list[idxdraw].nBank == 0) ? _MEMChip_B0_3_WE : _MEMChip_B1_3_WE;
const def_eFaultSource _RES_RAS0 = (ucNumTMU == 0) ? R118 : R115;
const def_eFaultSource _RES_RAS1 = (ucNumTMU == 0) ? R149 : R150;
const def_eFaultSource RES_RAS = (add_list[idxdraw].nBank == 0) ? _RES_RAS0 : _RES_RAS1;
const def_eFaultSource RES_CAS = (ucNumTMU == 0) ? RA36 : RA32;
const def_eFaultSource RES_WE = (ucNumTMU == 0) ? R117 : R114;
const def_eFaultSource RES_TEXADDR_0_L = (ucNumTMU == 0) ? RA35 : RA31;
const def_eFaultSource RES_TEXADDR_0_H = (ucNumTMU == 0) ? RA34 : RA30;
const def_eFaultSource RES_TEXADDR_0_8 = (ucNumTMU == 0) ? R116 : R113;
const def_eFaultSource RES_TEXADDR_1_L = (ucNumTMU == 0) ? RA26 : RA25;
const def_eFaultSource RES_TEXADDR_1_H = (ucNumTMU == 0) ? RA24 : RA23;
const def_eFaultSource RES_TEXADDR_1_8 = (ucNumTMU == 0) ? R102 : R101;
const def_eFaultSource RES_TEXADDR_2_L = (ucNumTMU == 0) ? RA33 : RA29;
const def_eFaultSource RES_TEXADDR_2_H = (ucNumTMU == 0) ? RA28 : RA27;
const def_eFaultSource RES_TEXADDR_2_8 = (ucNumTMU == 0) ? R112 : R111;
const def_eFaultSource RES_TEXADDR_3_L = (ucNumTMU == 0) ? RA22 : RA20;
const def_eFaultSource RES_TEXADDR_3_H = (ucNumTMU == 0) ? RA21 : RA19;
const def_eFaultSource RES_TEXADDR_3_8 = (ucNumTMU == 0) ? R98 : R97;
if(count_bit32(ErrorMark_L1 & 0x0000FFFF) > 2)
{
NbErr++;
/*
printf("1: %08x %d\n",
ErrorMark_L1 & 0x0000FFFF,
count_bit32(ErrorMark_L1 & 0x0000FFFF));*/
if((idxdraw == idx) && count_bit32(ErrorMark_L1 & 0x0000FFFF) > 6)
{
FaultSource_AddScore( TMUTexWE, 1.0/4);
FaultSource_AddScore( RES_WE, 1.0/4);
FaultSource_AddScore( MEMChip_0_WE, 1.0/1);
}
if(count_bit32(ErrorMarkBlank_L1 & 0x0000FFFF) < 3)
{
if(add_list[idx].nColBit!=0)
{
FaultSource_AddScore( MEMChip_0_A0 + add_list[idx].nColBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_0_0 + add_list[idx].nColBit, 1.0/1);
if(add_list[idx].nColBit < 4)
FaultSource_AddScore( RES_TEXADDR_0_L + add_list[idx].nColBit + 1, 1.0/2);
else if(add_list[idx].nColBit < 8)
FaultSource_AddScore( RES_TEXADDR_0_H + add_list[idx].nColBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_0_8 + 1, 1.0/2);
}
if(add_list[idx].nRowBit!=0)
{
FaultSource_AddScore( MEMChip_0_A0 + add_list[idx].nRowBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_0_0 + add_list[idx].nRowBit, 1.0/1);
if(add_list[idx].nRowBit < 4)
FaultSource_AddScore( RES_TEXADDR_0_L + add_list[idx].nRowBit + 1, 1.0/2);
else if(add_list[idx].nRowBit < 8)
FaultSource_AddScore( RES_TEXADDR_0_H + add_list[idx].nRowBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_0_8 + 1, 1.0/2);
}
}
else
{
FaultSource_AddScore( TMUTexRASCurrent, 1.0/8);
FaultSource_AddScore( RES_RAS, 1.0/8);
FaultSource_AddScore( MEMChip_0_RAS, 1.0/4);
if(ErrorMark_L1 & 0x000000FF)
{
FaultSource_AddScore( TMUTexCAS0, 1.0/16);
FaultSource_AddScore( RES_CAS+1, 1.0/16);
FaultSource_AddScore( MEMChip_0_CASL, 1.0/8);
}
if(ErrorMark_L1 & 0x0000FF00)
{
FaultSource_AddScore( TMUTexCAS1, 1.0/16);;
FaultSource_AddScore( RES_CAS+2, 1.0/16);
FaultSource_AddScore( MEMChip_0_CASH, 1.0/8);
}
}
}
// Error only if more than 6/16 bits are in error
if(count_bit32(ErrorMark_L1 & 0xFFFF0000) > 2)
{
NbErr++;/*
printf("2: %08x %d\n",
ErrorMark_L1 & 0xFFFF0000,
count_bit32(ErrorMark_L1 & 0xFFFF0000));*/
if((idxdraw == idx) && count_bit32(ErrorMark_L1 & 0xFFFF0000) > 6)
{
FaultSource_AddScore( TMUTexWE, 1.0/4);
FaultSource_AddScore( RES_WE, 1.0/4);
FaultSource_AddScore( MEMChip_1_WE, 1.0/1);
}
if(count_bit32(ErrorMarkBlank_L1 & 0xFFFF0000) < 3)
{
if(add_list[idx].nColBit!=0)
{
FaultSource_AddScore( MEMChip_1_A0 + add_list[idx].nColBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_1_0 + add_list[idx].nColBit, 1.0/1);
if(add_list[idx].nColBit < 4)
FaultSource_AddScore( RES_TEXADDR_1_L + add_list[idx].nColBit + 1, 1.0/2);
else if(add_list[idx].nColBit < 8)
FaultSource_AddScore( RES_TEXADDR_1_H + add_list[idx].nColBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_1_8 + 1, 1.0/2);
}
if(add_list[idx].nRowBit!=0)
{
FaultSource_AddScore( MEMChip_1_A0 + add_list[idx].nRowBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_1_0 + add_list[idx].nRowBit, 1.0/1);
if(add_list[idx].nRowBit < 4)
FaultSource_AddScore( RES_TEXADDR_1_L + add_list[idx].nRowBit + 1, 1.0/2);
else if(add_list[idx].nRowBit < 8)
FaultSource_AddScore( RES_TEXADDR_1_H + add_list[idx].nRowBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_1_8 + 1, 1.0/2);
}
}
else
{
FaultSource_AddScore( TMUTexRASCurrent, 1.0/8);
FaultSource_AddScore( RES_RAS, 1.0/8);
FaultSource_AddScore( MEMChip_1_RAS, 1.0/4);
if(ErrorMark_L1 & 0x00FF0000)
{
FaultSource_AddScore( TMUTexCAS0, 1.0/16);
FaultSource_AddScore( RES_CAS+1, 1.0/16);
FaultSource_AddScore( MEMChip_1_CASL, 1.0/8);
}
if(ErrorMark_L1 & 0xFF000000)
{
FaultSource_AddScore( TMUTexCAS1, 1.0/16);
FaultSource_AddScore( RES_CAS+2, 1.0/16);
FaultSource_AddScore( MEMChip_1_CASH, 1.0/8);
}
}
}
if(count_bit32(ErrorMark_L2 & 0x0000FFFF) > 2)
{
NbErr++;/*
printf("3: %08x %d\n",
ErrorMark_L2 & 0x0000FFFF,
count_bit32(ErrorMark_L2 & 0x0000FFFF));*/
if((idxdraw == idx) && count_bit32(ErrorMark_L2 & 0x0000FFFF) > 6)
{
FaultSource_AddScore( TMUTexWE, 1.0/4);
FaultSource_AddScore( RES_WE, 1.0/4);
FaultSource_AddScore( MEMChip_2_WE, 1.0);
}
if(count_bit32(ErrorMarkBlank_L2 & 0x0000FFFF) < 3)
{
if(add_list[idx].nColBit!=0)
{
FaultSource_AddScore( MEMChip_2_A0 + add_list[idx].nColBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_2_0 + add_list[idx].nColBit, 1.0/1);
if(add_list[idx].nColBit < 4)
FaultSource_AddScore( RES_TEXADDR_2_L + add_list[idx].nColBit + 1, 1.0/2);
else if(add_list[idx].nColBit < 8)
FaultSource_AddScore( RES_TEXADDR_2_H + add_list[idx].nColBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_2_8 + 1, 1.0/2);
}
if(add_list[idx].nRowBit!=0)
{
FaultSource_AddScore( MEMChip_2_A0 + add_list[idx].nRowBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_2_0 + add_list[idx].nRowBit, 1.0/1);
if(add_list[idx].nRowBit < 4)
FaultSource_AddScore( RES_TEXADDR_2_L + add_list[idx].nRowBit + 1, 1.0/2);
else if(add_list[idx].nRowBit < 8)
FaultSource_AddScore( RES_TEXADDR_2_H + add_list[idx].nRowBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_2_8 + 1, 1.0/2);
}
}
else
{
FaultSource_AddScore( TMUTexRASCurrent, 1.0/8);
FaultSource_AddScore( RES_RAS, 1.0/8);
FaultSource_AddScore( MEMChip_2_RAS, 1.0/4);
if(ErrorMark_L2 & 0x000000FF)
{
FaultSource_AddScore( TMUTexCAS2, 1.0/16);
FaultSource_AddScore( RES_CAS+3, 1.0/16);
FaultSource_AddScore( MEMChip_2_CASL, 1.0/8);
}
if(ErrorMark_L2 & 0x0000FF00)
{
FaultSource_AddScore( TMUTexCAS3, 1.0/16);
FaultSource_AddScore( RES_CAS+4, 1.0/16);
FaultSource_AddScore( MEMChip_2_CASH, 1.0/8);
}
}
}
if(count_bit32(ErrorMark_L2 & 0xFFFF0000) > 2)
{
NbErr++;/*
printf("4: %08x %d\n",
ErrorMark_L2 & 0xFFFF0000,
count_bit32(ErrorMark_L2 & 0xFFFF0000));*/
if((idxdraw == idx) && count_bit32(ErrorMark_L2 & 0xFFFF0000) > 6)
{
FaultSource_AddScore( TMUTexWE, 1.0/4);
FaultSource_AddScore( RES_WE, 1.0/4);
FaultSource_AddScore( MEMChip_3_WE, 1.0);
}
if(count_bit32(ErrorMarkBlank_L2 & 0xFFFF0000) < 3)
{
if(add_list[idx].nColBit!=0)
{
FaultSource_AddScore( MEMChip_3_A0 + add_list[idx].nColBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_3_0 + add_list[idx].nColBit, 1.0/1);
if(add_list[idx].nColBit < 4)
FaultSource_AddScore( RES_TEXADDR_3_L + add_list[idx].nColBit + 1, 1.0/2);
else if(add_list[idx].nColBit < 8)
FaultSource_AddScore( RES_TEXADDR_3_H + add_list[idx].nColBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_3_8 + 1, 1.0/2);
}
if(add_list[idx].nRowBit!=0)
{
FaultSource_AddScore( MEMChip_3_A0 + add_list[idx].nRowBit, 1.0/1);
FaultSource_AddScore( TMUTexADDR_3_0 + add_list[idx].nRowBit, 1.0/1);
if(add_list[idx].nRowBit < 4)
FaultSource_AddScore( RES_TEXADDR_3_L + add_list[idx].nRowBit + 1, 1.0/2);
else if(add_list[idx].nRowBit < 8)
FaultSource_AddScore( RES_TEXADDR_3_H + add_list[idx].nRowBit + 1, 1.0/2);
else
FaultSource_AddScore( RES_TEXADDR_3_8 + 1, 1.0/2);
}
}
else
{
FaultSource_AddScore( TMUTexRASCurrent, 1.0/8);
FaultSource_AddScore( RES_RAS, 1.0/8);
FaultSource_AddScore( MEMChip_3_RAS, 1.0/4);
if(ErrorMark_L2 & 0x00FF0000)
{
FaultSource_AddScore( TMUTexCAS2, 1.0/16);
FaultSource_AddScore( RES_CAS+3, 1.0/16);
FaultSource_AddScore( MEMChip_3_CASL, 1.0/8);
}
if(ErrorMark_L2 & 0xFF000000)
{
FaultSource_AddScore( TMUTexCAS3, 1.0/16);
FaultSource_AddScore( RES_CAS+4, 1.0/16);
FaultSource_AddScore( MEMChip_3_CASH, 1.0/8);
}
}
}
/*
if(idxdraw == idx)
{
if(ErrorMark_L1)
{
printf("E (31..00): @%08x, read %08x, expected %08x !\n" ,
add_list[idxdraw].u32Addr,
L1 ,
TestVal1);
}
if(ErrorMark_L2)
{
printf("E (63..32): @%08x, read %08x, expected %08x !\n" ,
add_list[idxdraw].u32Addr,
L2 ,
TestVal2);
}
}
else
{
if(ErrorMark_L1)
{
printf("E (31..00)(trash) : @%08x, read %08x, expected %08x !\n" ,
add_list[idxdraw].u32Addr,
L1 ,
TestValBlank1);
}
if(ErrorMark_L2)
{
printf("E (63..32)(trash) : @%08x, read %08x, expected %08x !\n" ,
add_list[idxdraw].u32Addr,
L2 ,
TestValBlank2);
}
}
if(!ErrorMark_L1 && !ErrorMark_L2)
{
printf("OK !!\n");
}
*/
//printf("@ %08x done\n",add_list[idx]);
}
}
}
sst1InitIdle(sst);
ISET(SST_TREX(sst,ucNumTMU)->trexInit0, devInfo->tmuInit0[(int)ucNumTMU]);
sst1InitIdle(sst);
return NbErr;
}