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/*
* This file is part of the coreboot project.
*
* Copyright (C) 2005 Nick Barker <nick.barker9@btinternet.com>
*
* 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 2 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, write to the Free Software
* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA
*/
/*
Automatically detect and set up ddr dram on the CLE266 chipset.
Assumes DDR memory, though chipset also supports SDRAM
Assumes at least 266Mhz memory as no attempt is made to clock
the chipset down if slower memory is installed.
So far tested on:
256 Mb 266Mhz 1 Bank (i.e. single sided)
256 Mb 266Mhz 2 Bank (i.e. double sided)
512 Mb 266Mhz 2 Bank (i.e. double sided)
*/
/* ported and enhanced from assembler level code in coreboot v1 */
#include <cpu/x86/mtrr.h>
#include "raminit.h"
void dimm_read(unsigned long bank,unsigned long x)
{
//unsigned long eax;
volatile unsigned long y;
//eax = x;
y = * (volatile unsigned long *) (x+ bank) ;
}
void
dumpnorth(device_t north)
{
uint16_t r, c;
for(r = 0; r < 256; r += 16) {
print_debug_hex8(r);
print_debug(":");
for(c = 0; c < 16; c++) {
print_debug_hex8(pci_read_config8(north, r+c));
print_debug(" ");
}
print_debug("\n");
}
}
void print_val(char *str, int val)
{
print_debug(str);
print_debug_hex8(val);
}
static void ddr_ram_setup(const struct mem_controller *ctrl)
{
device_t north = (device_t) 0;
uint8_t b, c, bank;
uint16_t i;
unsigned long bank_address;
print_debug("vt8623 init starting\n");
north = pci_locate_device(PCI_ID(0x1106, 0x3123), 0);
north = 0;
pci_write_config8(north,0x75,0x08);
/* setup cpu */
pci_write_config8(north,0x50,0xc8);
pci_write_config8(north,0x51,0xde);
pci_write_config8(north,0x52,0xcf);
pci_write_config8(north,0x53,0x88);
pci_write_config8(north,0x55,0x04);
/*
DRAM MA Map Type Device 0 Offset 58
Determine memory addressing based on the module's memory technology and
arrangement. See Table 4-9 of Intel's 82443GX datasheet for details.
Bank 1/0 MA map type 58[7-5]
Bank 1/0 command rate 58[4]
Bank 3/2 MA map type 58[3-1]
Bank 3/2 command rate 58[0]
Read SPD byte 17, Number of banks on SDRAM device.
*/
c = 0;
b = smbus_read_byte(0xa0,17);
print_val("Detecting Memory\nNumber of Banks ",b);
if( b != 2 ){ // not 16 Mb type
/*
Read SPD byte 3, Number of row addresses.
*/
b = smbus_read_byte(0xa0,3);
print_val("\nNumber of Rows ",b);
if( b >= 0x0d ){ // not 64/128Mb (rows <=12)
/*
Read SPD byte 13, Primary DRAM width.
*/
b = smbus_read_byte(0xa0,13);
print_val("\nPriamry DRAM width",b);
if( b != 4 ) // mot 64/128Mb (x4)
c = 0x80; // 256Mb
}
/*
64/128Mb chip
Read SPD byte 4, Number of column addresses.
*/
b = smbus_read_byte(0xa0,4);
print_val("\nNo Columns ",b);
if( b == 10 || b == 11 ) c |= 0x60; // 10/11 bit col addr
if( b == 9 ) c |= 0x40; // 9 bit col addr
if( b == 8 ) c |= 0x20; // 8 bit col addr
}
print_val("\nMA type ",c);
pci_write_config8(north,0x58,c);
/*
DRAM bank size. See 4.3.1 pg 35
5a->5d set to end address for each bank. 1 bit == 16MB
5a = bank 0
5b = bank 0 + b1
5c = bank 0 + b1 + b2
5d = bank 0 + b1 + b2 + b3
*/
// Read SPD byte 31 Module bank density
c = 0;
b = smbus_read_byte(0xa0,31);
if( b & 0x02 ) c = 0x80; // 2GB
else if( b & 0x01) c = 0x40; // 1GB
else if( b & 0x80) c = 0x20; // 512Mb
else if( b & 0x40) c = 0x10; // 256Mb
else if( b & 0x20) c = 0x08; // 128Mb
else if( b & 0x10) c = 0x04; // 64Mb
else if( b & 0x08) c = 0x02; // 32Mb
else if( b & 0x04) c = 0x01; // 16Mb / 4Gb
else c = 0x01; // Error, use default
print_val("\nBank 0 (*16 Mb) ",c);
// set bank zero size
pci_write_config8(north,0x5a,c);
// SPD byte 5 # of physical banks
b = smbus_read_byte(0xa0,5);
print_val("\nNo Physical Banks ",b);
if( b == 2)
c <<=1;
print_val("\nTotal Memory (*16 Mb) ",c);
// set banks 1,2,3
pci_write_config8(north,0x5b,c);
pci_write_config8(north,0x5c,c);
pci_write_config8(north,0x5d,c);
/* Read SPD byte 18 CAS Latency */
b = smbus_read_byte(0xa0,18);
print_debug("\nCAS Supported ");
if(b & 0x04)
print_debug("2 ");
if(b & 0x08)
print_debug("2.5 ");
if(b & 0x10)
print_debug("3");
print_val("\nCycle time at CL X (nS)",smbus_read_byte(0xa0,9));
print_val("\nCycle time at CL X-0.5 (nS)",smbus_read_byte(0xa0,23));
print_val("\nCycle time at CL X-1 (nS)",smbus_read_byte(0xa0,25));
if( b & 0x10 ){ // DDR offering optional CAS 3
print_debug("\nStarting at CAS 3");
c = 0x30;
/* see if we can better it */
if( b & 0x08 ){ // DDR mandatory CAS 2.5
if( smbus_read_byte(0xa0,23) <= 0x75 ){ // we can manage 133Mhz at CAS 2.5
print_debug("\nWe can do CAS 2.5");
c = 0x20;
}
}
if( b & 0x04 ){ // DDR mandatory CAS 2
if( smbus_read_byte(0xa0,25) <= 0x75 ){ // we can manage 133Mhz at CAS 2
print_debug("\nWe can do CAS 2");
c = 0x10;
}
}
}else{ // no optional CAS values just 2 & 2.5
print_debug("\nStarting at CAS 2.5");
c = 0x20; // assume CAS 2.5
if( b & 0x04){ // Should always happen
if( smbus_read_byte(0xa0,23) <= 0x75){ // we can manage 133Mhz at CAS 2
print_debug("\nWe can do CAS 2");
c = 0x10;
}
}
}
/*
DRAM Timing Device 0 Offset 64
Row pre-charge 64[7]
RAS Pulse width 64[6]
CAS Latency 64[5,4]
SDR DDR
00 1T -
01 2T 2T
10 3T 2.5T
11 - 3T
RAS/CAS delay 64[2]
Bank Interleave 64[1,0]
Determine row pre-charge time (tRP)
T nS SPD*4 SPD
1T 7.5 0x1e
2T 15 0x3c
3T 22.5 0x5a
4T 30 0x1e
5T 37.5 0x25 .5?
6T 45 0x2d
Read SPD byte 27, min row pre-charge time.
*/
b = smbus_read_byte(0xa0,27);
print_val("\ntRP ",b);
if( b > 0x3c ) // set tRP = 3T
c |= 0x80;
/*
Determine RAS to CAS delay (tRCD)
Read SPD byte 29, min row pre-charge time.
*/
b = smbus_read_byte(0xa0,29);
print_val("\ntRCD ",b);
if( b > 0x3c ) // set tRCD = 3T
c |= 0x04;
/*
Determine RAS pulse width (tRAS)
Read SPD byte 30, device min active to pre-charge time.
*/
b = smbus_read_byte(0xa0,30);
print_val("\ntRAS ",b);
if( b > 0x25 ) // set tRAS = 6T
c |= 0x40;
/*
Determine bank interleave
Read SPD byte 17, Number of banks on SDRAM device.
*/
b = smbus_read_byte(0xa0,17);
if( b == 4) c |= 0x02;
else if (b == 2) c |= 0x01;
/* set DRAM timing for all banks */
pci_write_config8(north,0x64,c);
/* set DRAM type to DDR */
pci_write_config8(north,0x60,0x02);
/* DRAM arbitration timer */
pci_write_config8(north,0x65,0x32);
/*
CPU Frequency Device 0 Offset 54
CPU Frequency 54[7,6] bootstraps at 0xc0 (133Mhz)
DRAM burst length = 8 54[5]
*/
pci_write_config8(north,0x54,0xe0);
/*
DRAM Clock Device 0 Offset 69
DRAM/CPU speed 69[7,6] (leave at default 00 == CPU)
Controller que > 2 69[5]
Controller que != 4 69[4]
DRAM 8k page size 69[3]
DRAM 4k page size 69[2]
Multiple page mode 69[0]
*/
pci_write_config8(north,0x69,0x2d);
/* Delay >= 100ns after DRAM Frequency adjust, See 4.1.1.3 pg 15 */
udelay(200);
/* Enable CKE */
pci_write_config8(north,0x6b,0x10);
udelay(200);
/* Disable DRAM refresh */
pci_write_config8(north,0x6a,0x0);
/* Set drive for 1 bank DDR (Table 4.4.2, pg 40) */
pci_write_config8(north,0x6d,0x044);
pci_write_config8(north,0x67,0x3a);
b = smbus_read_byte(0xa0,5); // SPD byte 5 # of physical banks
if( b > 1) {
// Increase drive control when there is more than 1 physical bank
pci_write_config8(north,0x6c,0x84); // Drive control: MA, DQS, MD/CKE
pci_write_config8(north,0x6d,0x55); // DC: Early clock select, DQM, CS#, MD
}
/* place frame buffer on last bank */
if( !b) b++; // make sure at least 1 bank reported
pci_write_config8(north,0xe3,b-1);
for( bank = 0 , bank_address=0; bank < b ; bank++){
/*
DDR init described in Via BIOS Porting Guide. Pg 28 (4.2.3.1)
*/
/* NOP command enable */
pci_write_config8(north,0x6b,0x11);
/* read a double word from any address of the dimm */
dimm_read(bank_address,0x1f000);
//udelay(200);
/* All bank precharge Command Enable */
pci_write_config8(north,0x6b,0x12);
dimm_read(bank_address,0x1f000);
/* MSR Enable */
pci_write_config8(north,0x6b,0x13);
dimm_read(bank_address,0x2000);
udelay(1);
dimm_read(bank_address,0x800);
udelay(1);
/* All banks precharge Command Enable */
pci_write_config8(north,0x6b,0x12);
dimm_read(bank_address,0x1f200);
/* CBR Cycle Enable */
pci_write_config8(north,0x6b,0x14);
/* Read 8 times */
dimm_read(bank_address,0x1f300);
udelay(100);
dimm_read(bank_address,0x1f400);
udelay(100);
dimm_read(bank_address,0x1f500);
udelay(100);
dimm_read(bank_address,0x1f600);
udelay(100);
dimm_read(bank_address,0x1f700);
udelay(100);
dimm_read(bank_address,0x1f800);
udelay(100);
dimm_read(bank_address,0x1f900);
udelay(100);
dimm_read(bank_address,0x1fa00);
udelay(100);
/* MSR Enable */
pci_write_config8(north,0x6b,0x13);
/*
Mode Register Definition
with adjustement so that address calculation is correct - 64 bit technology, therefore
a0-a2 refer to byte within a 64 bit long word, and a3 is the first address line presented
to DIMM as a row or column address.
MR[9-7] CAS Latency
MR[6] Burst Type 0 = sequential, 1 = interleaved
MR[5-3] burst length 001 = 2, 010 = 4, 011 = 8, others reserved
MR[0-2] dont care
CAS Latency
000 reserved
001 reserved
010 2
011 3
100 reserved
101 1.5
110 2.5
111 reserved
CAS 2 0101011000 = 0x158
CAS 2.5 1101011000 = 0x358
CAS 3 0111011000 = 0x1d8
*/
c = pci_read_config8(north,0x64);
if( (c & 0x30) == 0x10 )
dimm_read(bank_address,0x150);
else if((c & 0x30) == 0x20 )
dimm_read(bank_address,0x350);
else
dimm_read(bank_address,0x1d0);
//dimm_read(bank_address,0x350);
/* Normal SDRAM Mode */
pci_write_config8(north,0x6b,0x58 );
bank_address = pci_read_config8(north,0x5a+bank) * 0x1000000;
} // end of for each bank
/* Adjust DQS (data strobe output delay). See 4.2.3.2 pg 29 */
pci_write_config8(north,0x66,0x41);
/* determine low bond */
if( b == 2)
bank_address = pci_read_config8(north,0x5a) * 0x1000000;
else
bank_address = 0;
for(i = 0 ; i < 0x0ff; i++){
c = i ^ (i>>1); // convert to gray code
pci_write_config8(north,0x68,c);
// clear
*(volatile unsigned long*)(0x4000) = 0;
*(volatile unsigned long*)(0x4100+bank_address) = 0;
*(volatile unsigned long*)(0x4200) = 0;
*(volatile unsigned long*)(0x4300+bank_address) = 0;
*(volatile unsigned long*)(0x4400) = 0;
*(volatile unsigned long*)(0x4500+bank_address) = 0;
// fill
*(volatile unsigned long*)(0x4000) = 0x12345678;
*(volatile unsigned long*)(0x4100+bank_address) = 0x81234567;
*(volatile unsigned long*)(0x4200) = 0x78123456;
*(volatile unsigned long*)(0x4300+bank_address) = 0x67812345;
*(volatile unsigned long*)(0x4400) = 0x56781234;
*(volatile unsigned long*)(0x4500+bank_address) = 0x45678123;
// verify
if( *(volatile unsigned long*)(0x4000) != 0x12345678)
continue;
if( *(volatile unsigned long*)(0x4100+bank_address) != 0x81234567)
continue;
if( *(volatile unsigned long*)(0x4200) != 0x78123456)
continue;
if( *(volatile unsigned long*)(0x4300+bank_address) != 0x67812345)
continue;
if( *(volatile unsigned long*)(0x4400) != 0x56781234)
continue;
if( *(volatile unsigned long*)(0x4500+bank_address) != 0x45678123)
continue;
// if everything verified then found low bond
break;
}
print_val("\nLow Bond ",i);
if( i < 0xff ){
c = i++;
for( ; i <0xff ; i++){
pci_write_config8(north,0x68,i ^ (i>>1) );
// clear
*(volatile unsigned long*)(0x8000) = 0;
*(volatile unsigned long*)(0x8100+bank_address) = 0;
*(volatile unsigned long*)(0x8200) = 0x0;
*(volatile unsigned long*)(0x8300+bank_address) = 0;
*(volatile unsigned long*)(0x8400) = 0x0;
*(volatile unsigned long*)(0x8500+bank_address) = 0;
// fill
*(volatile unsigned long*)(0x8000) = 0x12345678;
*(volatile unsigned long*)(0x8100+bank_address) = 0x81234567;
*(volatile unsigned long*)(0x8200) = 0x78123456;
*(volatile unsigned long*)(0x8300+bank_address) = 0x67812345;
*(volatile unsigned long*)(0x8400) = 0x56781234;
*(volatile unsigned long*)(0x8500+bank_address) = 0x45678123;
// verify
if( *(volatile unsigned long*)(0x8000) != 0x12345678)
break;
if( *(volatile unsigned long*)(0x8100+bank_address) != 0x81234567)
break;
if( *(volatile unsigned long*)(0x8200) != 0x78123456)
break;
if( *(volatile unsigned long*)(0x8300+bank_address) != 0x67812345)
break;
if( *(volatile unsigned long*)(0x8400) != 0x56781234)
break;
if( *(volatile unsigned long*)(0x8500+bank_address) != 0x45678123)
break;
}
print_val(" High Bond",i);
c = ((i - c)<<1)/3 +c;
print_val(" Setting DQS delay",c);
c = c ^ (c>>1); // convert to gray code
pci_write_config8(north,0x68,c);
pci_write_config8(north,0x68,0x42);
}else{
print_debug("Unable to determine low bond - Setting default\n");
pci_write_config8(north,0x68,0x59);
}
pci_write_config8(north,0x66,0x01);
pci_write_config8(north,0x55,0x07);
/*
DRAM refresh rate Device 0 Offset 6a
Units of 16 DRAM clock cycles. (See 4.4.1 pg 39)
Rx69 (DRAM freq) Rx58 (chip tech) Rx6a
133Mhz 64/128Mb 0x86
133Mhz 256/512Mb 0x43
100Mhz 64/128Mb 0x65
100Mhz 256/512Mb 0x32
*/
b = pci_read_config8(north,0x58);
if( b < 0x80 ) // 256 tech
pci_write_config8(north,0x6a,0x86);
else
pci_write_config8(north,0x6a,0x43);
pci_write_config8(north,0x61,0xff);
//pci_write_config8(north,0x67,0x22);
/* pci */
pci_write_config8(north,0x70,0x82);
pci_write_config8(north,0x73,0x01);
pci_write_config8(north,0x76,0x50);
pci_write_config8(north,0x71,0xc8);
/* graphics aperture base */
pci_write_config8(north,0x13,0xd0);
//pci_write_config8(north,0xe1,0xdf);
//pci_write_config8(north,0xe2,0x42);
pci_write_config8(north,0xe0,0x00);
pci_write_config8(north,0x84,0x80);
pci_write_config16(north,0x80,0x610f);
pci_write_config32(north,0x88,0x00000002);
pci_write_config8(north,0xa8,0x04);
pci_write_config8(north,0xac,0x2f);
pci_write_config8(north,0xae,0x04);
print_debug("vt8623 done\n");
dumpnorth(north);
print_debug("AGP\n");
north = pci_locate_device(PCI_ID(0x1106, 0xb091), 0);
pci_write_config32(north,0x20,0xddf0dc00);
pci_write_config32(north,0x24,0xdbf0d800);
pci_write_config8(north,0x3e,0x0c);
//dumpnorth(north);
//print_err("VGA\n");
//north = pci_locate_device(PCI_ID(0x1106, 0x3122), 0);
//pci_write_config32(north,0x10,0xd8000008);
//pci_write_config32(north,0x14,0xdc000000);
//dumpnorth(north);
}
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