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|
/*
* This file is part of the coreboot project.
*
* Copyright (C) 2006 Jon Dufresne <jon.dufresne@gmail.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
*/
#include <assert.h>
#include <spd.h>
#include <sdram_mode.h>
#include <stdlib.h>
#include <delay.h>
#include "i855.h"
/*-----------------------------------------------------------------------------
Macros and definitions:
-----------------------------------------------------------------------------*/
#define VALIDATE_DIMM_COMPATIBILITY
/* Debugging macros. */
#if CONFIG_DEBUG_RAM_SETUP
#define PRINTK_DEBUG(x...) printk(BIOS_DEBUG, x)
#define DUMPNORTH() dump_pci_device(NORTHBRIDGE_MMC)
#else
#define PRINTK_DEBUG(x...)
#define DUMPNORTH()
#endif
#define delay() udelay(200)
#define VG85X_MODE (SDRAM_BURST_4 | SDRAM_BURST_INTERLEAVED | SDRAM_CAS_2_5)
/* DRC[10:8] - Refresh Mode Select (RMS).
* 0x0 for Refresh Disabled (Self Refresh)
* 0x1 for Refresh interval 15.6 us for 133MHz
* 0x2 for Refresh interval 7.8 us for 133MHz
* 0x7 for Refresh interval 64 Clocks. (Fast Refresh Mode)
*/
#define RAM_COMMAND_REFRESH 0x1
/* DRC[6:4] - SDRAM Mode Select (SMS). */
#define RAM_COMMAND_SELF_REFRESH 0x0
#define RAM_COMMAND_NOP 0x1
#define RAM_COMMAND_PRECHARGE 0x2
#define RAM_COMMAND_MRS 0x3
#define RAM_COMMAND_EMRS 0x4
#define RAM_COMMAND_CBR 0x6
#define RAM_COMMAND_NORMAL 0x7
/* DRC[29] - Initialization Complete (IC). */
#define RAM_COMMAND_IC 0x1
struct dimm_size {
unsigned int side1;
unsigned int side2;
};
static const uint32_t refresh_frequency[] = {
/* Relative frequency (array value) of each E7501 Refresh Mode Select
* (RMS) value (array index)
* 0 == least frequent refresh (longest interval between refreshes)
* [0] disabled -> 0
* [1] 15.6 usec -> 2
* [2] 7.8 usec -> 3
* [3] 64 usec -> 1
* [4] reserved -> 0
* [5] reserved -> 0
* [6] reserved -> 0
* [7] 64 clocks -> 4
*/
0, 2, 3, 1, 0, 0, 0, 4
};
static const uint32_t refresh_rate_map[] = {
/* Map the JEDEC spd refresh rates (array index) to i855 Refresh Mode
* Select values (array value)
* These are all the rates defined by JESD21-C Appendix D, Rev. 1.0
* The i855 supports only 15.6 us (1), 7.8 us (2) and
* 64 clock (481 ns) (7) refresh.
* [0] == 15.625 us -> 15.6 us
* [1] == 3.9 us -> 481 ns
* [2] == 7.8 us -> 7.8 us
* [3] == 31.3 us -> 15.6 us
* [4] == 62.5 us -> 15.6 us
* [5] == 125 us -> 15.6 us
*/
1, 7, 2, 1, 1, 1
};
#define MAX_SPD_REFRESH_RATE ((sizeof(refresh_rate_map) / sizeof(uint32_t)) - 1)
/*-----------------------------------------------------------------------------
SPD functions:
-----------------------------------------------------------------------------*/
static void die_on_spd_error(int spd_return_value)
{
if (spd_return_value < 0)
PRINTK_DEBUG("Error reading SPD info: got %d\n", spd_return_value);
/*
if (spd_return_value < 0)
die("Error reading SPD info\n");
*/
}
/**
* Calculate the page size for each physical bank of the DIMM:
*
* log2(page size) = (# columns) + log2(data width)
*
* NOTE: Page size is the total number of data bits in a row.
*
* @param dimm_socket_address SMBus address of DIMM socket to interrogate.
* @return log2(page size) for each side of the DIMM.
*/
static struct dimm_size sdram_spd_get_page_size(u8 dimm_socket_address)
{
uint16_t module_data_width;
int value;
struct dimm_size pgsz;
pgsz.side1 = 0;
pgsz.side2 = 0;
// Side 1
value = spd_read_byte(dimm_socket_address, SPD_NUM_COLUMNS);
die_on_spd_error(value);
pgsz.side1 = value & 0xf; // # columns in bank 1
/* Get the module data width and convert it to a power of two */
value = spd_read_byte(dimm_socket_address, SPD_MODULE_DATA_WIDTH_MSB);
die_on_spd_error(value);
module_data_width = (value & 0xff) << 8;
value = spd_read_byte(dimm_socket_address, SPD_MODULE_DATA_WIDTH_LSB);
die_on_spd_error(value);
module_data_width |= (value & 0xff);
pgsz.side1 += log2(module_data_width);
/* side two */
value = spd_read_byte(dimm_socket_address, SPD_NUM_DIMM_BANKS);
die_on_spd_error(value);
/*
if (value > 2)
die("Bad SPD value\n");
*/
if (value > 2)
PRINTK_DEBUG("Bad SPD value\n");
if (value == 2) {
pgsz.side2 = pgsz.side1; // Assume symmetric banks until we know differently
value = spd_read_byte(dimm_socket_address, SPD_NUM_COLUMNS);
die_on_spd_error(value);
if ((value & 0xf0) != 0) {
// Asymmetric banks
pgsz.side2 -= value & 0xf; /* Subtract out columns on side 1 */
pgsz.side2 += (value >> 4) & 0xf; /* Add in columns on side 2 */
}
}
return pgsz;
}
/**
* Read the width in bits of each DIMM side's DRAMs via SPD (i.e. 4, 8, 16).
*
* @param dimm_socket_address SMBus address of DIMM socket to interrogate.
* @return Width in bits of each DIMM side's DRAMs.
*/
static struct dimm_size sdram_spd_get_width(u8 dimm_socket_address)
{
int value;
struct dimm_size width;
width.side1 = 0;
width.side2 = 0;
value = spd_read_byte(dimm_socket_address, SPD_PRIMARY_SDRAM_WIDTH);
die_on_spd_error(value);
width.side1 = value & 0x7f; // Mask off bank 2 flag
if (value & 0x80) {
width.side2 = width.side1 << 1; // Bank 2 exists and is double-width
} else {
// If bank 2 exists, it's the same width as bank 1
value = spd_read_byte(dimm_socket_address, SPD_NUM_DIMM_BANKS);
die_on_spd_error(value);
#ifdef ROMCC_IF_BUG_FIXED
if (value == 2)
width.side2 = width.side1;
#else
switch (value) {
case 2:
width.side2 = width.side1;
break;
default:
break;
}
#endif
}
return width;
}
/**
* Calculate the log base 2 size in bits of both DIMM sides.
*
* log2(# bits) = (# columns) + log2(data width) +
* (# rows) + log2(banks per SDRAM)
*
* Note that it might be easier to use SPD byte 31 here, it has the DIMM size
* as a multiple of 4MB. The way we do it now we can size both sides of an
* asymmetric DIMM.
*
* @param dimm SMBus address of DIMM socket to interrogate.
* @return log2(number of bits) for each side of the DIMM.
*/
static struct dimm_size spd_get_dimm_size(unsigned dimm)
{
int value;
// Start with log2(page size)
struct dimm_size sz = sdram_spd_get_page_size(dimm);
if (sz.side1 > 0) {
value = spd_read_byte(dimm, SPD_NUM_ROWS);
die_on_spd_error(value);
sz.side1 += value & 0xf;
if (sz.side2 > 0) {
// Double-sided DIMM
if (value & 0xF0)
sz.side2 += value >> 4; // Asymmetric
else
sz.side2 += value; // Symmetric
}
value = spd_read_byte(dimm, SPD_NUM_BANKS_PER_SDRAM);
die_on_spd_error(value);
value = log2(value);
sz.side1 += value;
if (sz.side2 > 0)
sz.side2 += value;
}
return sz;
}
/**
* Scan for compatible DIMMs.
*
* @return A bitmask indicating which sockets contain a compatible DIMM.
*/
static uint8_t spd_get_supported_dimms(void)
{
int i;
uint8_t dimm_mask = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
u8 dimm = DIMM0 + i;
#ifdef VALIDATE_DIMM_COMPATIBILITY
struct dimm_size page_size;
struct dimm_size sdram_width;
#endif
int spd_value;
if (dimm == 0)
continue; // No such socket on this mainboard
if (spd_read_byte(dimm, SPD_MEMORY_TYPE) != SPD_MEMORY_TYPE_SDRAM_DDR)
continue;
#ifdef VALIDATE_DIMM_COMPATIBILITY
if ((spd_value = spd_read_byte(dimm, SPD_MODULE_VOLTAGE)) != SPD_VOLTAGE_SSTL2) {
PRINTK_DEBUG("Skipping DIMM with unsupported voltage: %02x\n", spd_value);
continue; // Unsupported voltage
}
/*
// E7501 does not support unregistered DIMMs
spd_value = spd_read_byte(dimm, SPD_MODULE_ATTRIBUTES);
if (!(spd_value & MODULE_REGISTERED) || (spd_value < 0)) {
PRINTK_DEBUG("Skipping unregistered DIMM: %02x\n", spd_value);
continue;
}
*/
page_size = sdram_spd_get_page_size(dimm);
sdram_width = sdram_spd_get_width(dimm);
// Validate DIMM page size
// The i855 only supports page sizes of 4, 8, 16 KB per channel
// NOTE: 4 KB = 32 Kb = 2^15
// 16 KB = 128 Kb = 2^17
if ((page_size.side1 < 15) || (page_size.side1 > 17)) {
PRINTK_DEBUG("Skipping DIMM with unsupported page size: %d\n", page_size.side1);
continue;
}
// If DIMM is double-sided, verify side2 page size
if (page_size.side2 != 0) {
if ((page_size.side2 < 15) || (page_size.side2 > 17)) {
PRINTK_DEBUG("Skipping DIMM with unsupported page size: %d\n", page_size.side2);
continue;
}
}
// Validate SDRAM width
// The i855 only supports x8 and x16 devices
if ((sdram_width.side1 != 8) && (sdram_width.side1 != 16)) {
PRINTK_DEBUG("Skipping DIMM with unsupported width: %d\n", sdram_width.side2);
continue;
}
// If DIMM is double-sided, verify side2 width
if (sdram_width.side2 != 0) {
if ((sdram_width.side2 != 8)
&& (sdram_width.side2 != 16)) {
PRINTK_DEBUG("Skipping DIMM with unsupported width: %d\n", sdram_width.side2);
continue;
}
}
#endif
// Made it through all the checks, this DIMM is usable
dimm_mask |= (1 << i);
}
return dimm_mask;
}
/*-----------------------------------------------------------------------------
SDRAM configuration functions:
-----------------------------------------------------------------------------*/
static void do_ram_command(uint8_t command, uint16_t jedec_mode_bits)
{
int i;
u32 reg32;
uint8_t dimm_start_32M_multiple = 0;
uint16_t i855_mode_bits = jedec_mode_bits;
/* Configure the RAM command. */
reg32 = pci_read_config32(NORTHBRIDGE_MMC, DRC);
reg32 &= ~(7 << 4);
reg32 |= (command << 4);
PRINTK_DEBUG(" Sending RAM command 0x%08x\n", reg32);
pci_write_config32(NORTHBRIDGE_MMC, DRC, reg32);
// RAM_COMMAND_NORMAL is an exception.
// It affects only the memory controller and does not need to be "sent" to the DIMMs.
if (command != RAM_COMMAND_NORMAL) {
// Send the command to all DIMMs by accessing a memory location within each
// NOTE: for mode select commands, some of the location address bits
// are part of the command
// Map JEDEC mode bits to i855
if (command == RAM_COMMAND_MRS || command == RAM_COMMAND_EMRS) {
/* Host address lines [13:3] map to DIMM address lines [11, 9:0] */
i855_mode_bits = ((jedec_mode_bits & 0x800) << (13 - 11)) | ((jedec_mode_bits & 0x3ff) << (12 - 9));
}
for (i = 0; i < (DIMM_SOCKETS * 2); ++i) {
uint8_t dimm_end_32M_multiple = pci_read_config8(NORTHBRIDGE_MMC, DRB + i);
if (dimm_end_32M_multiple > dimm_start_32M_multiple) {
uint32_t dimm_start_address = dimm_start_32M_multiple << 25;
PRINTK_DEBUG(" Sending RAM command to 0x%08x\n", dimm_start_address + i855_mode_bits);
read32(dimm_start_address + i855_mode_bits);
// Set the start of the next DIMM
dimm_start_32M_multiple = dimm_end_32M_multiple;
}
}
}
}
static void set_initialize_complete(void)
{
uint32_t drc_reg;
drc_reg = pci_read_config32(NORTHBRIDGE_MMC, DRC);
drc_reg |= (1 << 29);
pci_write_config32(NORTHBRIDGE_MMC, DRC, drc_reg);
}
static void sdram_enable(void)
{
int i;
print_debug("Ram enable 1\n");
delay();
delay();
/* NOP command */
PRINTK_DEBUG(" NOP\n");
do_ram_command(RAM_COMMAND_NOP, 0);
delay();
delay();
delay();
/* Pre-charge all banks (at least 200 us after NOP) */
PRINTK_DEBUG(" Pre-charging all banks\n");
do_ram_command(RAM_COMMAND_PRECHARGE, 0);
delay();
delay();
delay();
print_debug("Ram enable 4\n");
do_ram_command(RAM_COMMAND_EMRS, SDRAM_EXTMODE_DLL_ENABLE);
delay();
delay();
delay();
print_debug("Ram enable 5\n");
do_ram_command(RAM_COMMAND_MRS, VG85X_MODE | SDRAM_MODE_DLL_RESET);
print_debug("Ram enable 6\n");
do_ram_command(RAM_COMMAND_PRECHARGE, 0);
delay();
delay();
delay();
/* 8 CBR refreshes (Auto Refresh) */
PRINTK_DEBUG(" 8 CBR refreshes\n");
for(i = 0; i < 8; i++) {
do_ram_command(RAM_COMMAND_CBR, 0);
delay();
delay();
delay();
}
print_debug("Ram enable 8\n");
do_ram_command(RAM_COMMAND_MRS, VG85X_MODE | SDRAM_MODE_NORMAL);
/* Set GME-M Mode Select bits back to NORMAL operation mode */
PRINTK_DEBUG(" Normal operation mode\n");
do_ram_command(RAM_COMMAND_NORMAL, 0);
delay();
delay();
delay();
print_debug("Ram enable 9\n");
set_initialize_complete();
delay();
delay();
delay();
delay();
delay();
print_debug("After configuration:\n");
/* dump_pci_devices(); */
/*
print_debug("\n\n***** RAM TEST *****\n");
ram_check(0, 0xa0000);
ram_check(0x100000, 0x40000000);
*/
}
/*-----------------------------------------------------------------------------
DIMM-independant configuration functions:
-----------------------------------------------------------------------------*/
/**
* Set only what I need until it works, then make it figure things out on boot
* assumes only one DIMM is populated.
*/
static void sdram_set_registers(void)
{
/*
print_debug("Before configuration:\n");
dump_pci_devices();
*/
}
static void spd_set_row_attributes(uint8_t dimm_mask)
{
int i;
uint16_t row_attributes = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
u8 dimm = DIMM0 + i;
struct dimm_size page_size;
struct dimm_size sdram_width;
if (!(dimm_mask & (1 << i))) {
row_attributes |= 0x77 << (i << 3);
continue; // This DIMM not usable
}
// Get the relevant parameters via SPD
page_size = sdram_spd_get_page_size(dimm);
sdram_width = sdram_spd_get_width(dimm);
// Update the DRAM Row Attributes.
// Page size is encoded as log2(page size in bits) - log2(2 KB) or 4 KB == 1, 8 KB == 3, 16KB == 3
// NOTE: 2 KB = 16 Kb = 2^14
row_attributes |= (page_size.side1 - 14) << (i << 3); // Side 1 of each DIMM is an EVEN row
if (sdram_width.side2 > 0)
row_attributes |= (page_size.side2 - 14) << ((i << 3) + 4); // Side 2 is ODD
else
row_attributes |= 7 << ((i << 3) + 4);
/* go to the next DIMM */
}
PRINTK_DEBUG("DRA: %04x\n", row_attributes);
/* Write the new row attributes register */
pci_write_config16(NORTHBRIDGE_MMC, DRA, row_attributes);
}
static void spd_set_dram_controller_mode(uint8_t dimm_mask)
{
int i;
// Initial settings
u32 controller_mode = pci_read_config32(NORTHBRIDGE_MMC, DRC);
u32 system_refresh_mode = (controller_mode >> 7) & 7;
controller_mode |= (1 << 20); // ECC
controller_mode |= (1 << 15); // RAS lockout
controller_mode |= (1 << 12); // Address Tri-state enable (ADRTRIEN), FIXME: how is this detected?????
controller_mode |= (2 << 10); // FIXME: Undocumented, really needed?????
for (i = 0; i < DIMM_SOCKETS; i++) {
u8 dimm = DIMM0 + i;
uint32_t dimm_refresh_mode;
int value;
u8 tRCD, tRP;
if (!(dimm_mask & (1 << i))) {
continue; // This DIMM not usable
}
// Disable ECC mode if any one of the DIMMs does not support ECC
value = spd_read_byte(dimm, SPD_DIMM_CONFIG_TYPE);
die_on_spd_error(value);
if (value != ERROR_SCHEME_ECC)
controller_mode &= ~(3 << 20);
value = spd_read_byte(dimm, SPD_REFRESH);
die_on_spd_error(value);
value &= 0x7f; // Mask off self-refresh bit
if (value > MAX_SPD_REFRESH_RATE) {
print_err("unsupported refresh rate\n");
continue;
}
// Get the appropriate i855 refresh mode for this DIMM
dimm_refresh_mode = refresh_rate_map[value];
if (dimm_refresh_mode > 7) {
print_err("unsupported refresh rate\n");
continue;
}
// If this DIMM requires more frequent refresh than others,
// update the system setting
if (refresh_frequency[dimm_refresh_mode] >
refresh_frequency[system_refresh_mode])
system_refresh_mode = dimm_refresh_mode;
/* FIXME: is this correct? */
tRCD = spd_read_byte(dimm, SPD_tRCD);
tRP = spd_read_byte(dimm, SPD_tRP);
if (tRCD != tRP) {
PRINTK_DEBUG(" Disabling RAS lockouk due to tRCD (%d) != tRP (%d)\n", tRCD, tRP);
controller_mode &= ~(1 << 15);
}
/* go to the next DIMM */
}
controller_mode &= ~(7 << 7);
controller_mode |= (system_refresh_mode << 7);
PRINTK_DEBUG("DRC: %08x\n", controller_mode);
pci_write_config32(NORTHBRIDGE_MMC, DRC, controller_mode);
}
static void spd_set_dram_timing(uint8_t dimm_mask)
{
int i;
u32 dram_timing;
// CAS# latency bitmasks in SPD_ACCEPTABLE_CAS_LATENCIES format
// NOTE: i82822 supports only 2.0 and 2.5
uint32_t system_compatible_cas_latencies = SPD_CAS_LATENCY_2_0 | SPD_CAS_LATENCY_2_5;
uint8_t slowest_row_precharge = 0;
uint8_t slowest_ras_cas_delay = 0;
uint8_t slowest_active_to_precharge_delay = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
u8 dimm = DIMM0 + i;
int value;
uint32_t current_cas_latency;
uint32_t dimm_compatible_cas_latencies;
if (!(dimm_mask & (1 << i)))
continue; // This DIMM not usable
value = spd_read_byte(dimm, SPD_ACCEPTABLE_CAS_LATENCIES);
PRINTK_DEBUG("SPD_ACCEPTABLE_CAS_LATENCIES: %d\n", value);
die_on_spd_error(value);
dimm_compatible_cas_latencies = value & 0x7f; // Start with all supported by DIMM
PRINTK_DEBUG("dimm_compatible_cas_latencies #1: %d\n", dimm_compatible_cas_latencies);
current_cas_latency = 1 << log2(dimm_compatible_cas_latencies); // Max supported by DIMM
PRINTK_DEBUG("current_cas_latency: %d\n", current_cas_latency);
// Can we support the highest CAS# latency?
value = spd_read_byte(dimm, SPD_MIN_CYCLE_TIME_AT_CAS_MAX);
die_on_spd_error(value);
PRINTK_DEBUG("SPD_MIN_CYCLE_TIME_AT_CAS_MAX: %d.%d\n", value >> 4, value & 0xf);
// NOTE: At 133 MHz, 1 clock == 7.52 ns
if (value > 0x75) {
// Our bus is too fast for this CAS# latency
// Remove it from the bitmask of those supported by the DIMM that are compatible
dimm_compatible_cas_latencies &= ~current_cas_latency;
PRINTK_DEBUG("dimm_compatible_cas_latencies #2: %d\n", dimm_compatible_cas_latencies);
}
// Can we support the next-highest CAS# latency (max - 0.5)?
current_cas_latency >>= 1;
if (current_cas_latency != 0) {
value = spd_read_byte(dimm, SPD_SDRAM_CYCLE_TIME_2ND);
die_on_spd_error(value);
PRINTK_DEBUG("SPD_SDRAM_CYCLE_TIME_2ND: %d.%d\n", value >> 4, value & 0xf);
if (value > 0x75) {
dimm_compatible_cas_latencies &= ~current_cas_latency;
PRINTK_DEBUG("dimm_compatible_cas_latencies #2: %d\n", dimm_compatible_cas_latencies);
}
}
// Can we support the next-highest CAS# latency (max - 1.0)?
current_cas_latency >>= 1;
if (current_cas_latency != 0) {
value = spd_read_byte(dimm, SPD_SDRAM_CYCLE_TIME_3RD);
PRINTK_DEBUG("SPD_SDRAM_CYCLE_TIME_3RD: %d.%d\n", value >> 4, value & 0xf);
die_on_spd_error(value);
if (value > 0x75) {
dimm_compatible_cas_latencies &= ~current_cas_latency;
PRINTK_DEBUG("dimm_compatible_cas_latencies #2: %d\n", dimm_compatible_cas_latencies);
}
}
// Restrict the system to CAS# latencies compatible with this DIMM
system_compatible_cas_latencies &= dimm_compatible_cas_latencies;
value = spd_read_byte(dimm, SPD_MIN_ROW_PRECHARGE_TIME);
die_on_spd_error(value);
if (value > slowest_row_precharge)
slowest_row_precharge = value;
value = spd_read_byte(dimm, SPD_MIN_RAS_TO_CAS_DELAY);
die_on_spd_error(value);
if (value > slowest_ras_cas_delay)
slowest_ras_cas_delay = value;
value = spd_read_byte(dimm, SPD_MIN_ACTIVE_TO_PRECHARGE_DELAY);
die_on_spd_error(value);
if (value > slowest_active_to_precharge_delay)
slowest_active_to_precharge_delay = value;
/* go to the next DIMM */
}
PRINTK_DEBUG("CAS latency: %d\n", system_compatible_cas_latencies);
dram_timing = pci_read_config32(NORTHBRIDGE_MMC, DRT);
dram_timing &= ~(DRT_CAS_MASK | DRT_TRP_MASK | DRT_RCD_MASK);
PRINTK_DEBUG("DRT: %08x\n", dram_timing);
if (system_compatible_cas_latencies & SPD_CAS_LATENCY_2_0) {
dram_timing |= DRT_CAS_2_0;
} else if (system_compatible_cas_latencies & SPD_CAS_LATENCY_2_5) {
dram_timing |= DRT_CAS_2_5;
} else
die("No CAS# latencies compatible with all DIMMs!!\n");
uint32_t current_cas_latency = dram_timing & DRT_CAS_MASK;
/* tRP */
PRINTK_DEBUG("slowest_row_precharge: %d.%d\n", slowest_row_precharge >> 2, slowest_row_precharge & 0x3);
// i855 supports only 2, 3 or 4 clocks for tRP
if (slowest_row_precharge > ((30 << 2)))
die("unsupported DIMM tRP"); // > 30.0 ns: 5 or more clocks
else if (slowest_row_precharge > ((22 << 2) | (2 << 0)))
dram_timing |= DRT_TRP_4; // > 22.5 ns: 4 or more clocks
else if (slowest_row_precharge > (15 << 2))
dram_timing |= DRT_TRP_3; // > 15.0 ns: 3 clocks
else
dram_timing |= DRT_TRP_2; // <= 15.0 ns: 2 clocks
/* tRCD */
PRINTK_DEBUG("slowest_ras_cas_delay: %d.%d\n", slowest_ras_cas_delay >> 2, slowest_ras_cas_delay & 0x3);
// i855 supports only 2, 3 or 4 clocks for tRCD
if (slowest_ras_cas_delay > ((30 << 2)))
die("unsupported DIMM tRCD"); // > 30.0 ns: 5 or more clocks
else if (slowest_ras_cas_delay > ((22 << 2) | (2 << 0)))
dram_timing |= DRT_RCD_4; // > 22.5 ns: 4 or more clocks
else if (slowest_ras_cas_delay > (15 << 2))
dram_timing |= DRT_RCD_3; // > 15.0 ns: 3 clocks
else
dram_timing |= DRT_RCD_2; // <= 15.0 ns: 2 clocks
/* tRAS, min */
PRINTK_DEBUG("slowest_active_to_precharge_delay: %d\n", slowest_active_to_precharge_delay);
// i855 supports only 5, 6, 7 or 8 clocks for tRAS
// 5 clocks ~= 37.6 ns, 6 clocks ~= 45.1 ns, 7 clocks ~= 52.6 ns, 8 clocks ~= 60.1 ns
if (slowest_active_to_precharge_delay > 60)
die("unsupported DIMM tRAS"); // > 52 ns: 8 or more clocks
else if (slowest_active_to_precharge_delay > 52)
dram_timing |= DRT_TRAS_MIN_8; // 46-52 ns: 7 clocks
else if (slowest_active_to_precharge_delay > 45)
dram_timing |= DRT_TRAS_MIN_7; // 46-52 ns: 7 clocks
else if (slowest_active_to_precharge_delay > 37)
dram_timing |= DRT_TRAS_MIN_6; // 38-45 ns: 6 clocks
else
dram_timing |= DRT_TRAS_MIN_5; // < 38 ns: 5 clocks
/* FIXME: guess work starts here...
*
* Intel refers to DQ turn-arround values for back to calculate the values,
* but i have no idea what this means
*/
/*
* Back to Back Read-Write command spacing (DDR, different Rows/Bank)
*/
/* Set to a 3 clock back to back read to write turn around.
* 2 is a good delay if the CAS latency is 2.0 */
dram_timing &= ~(3 << 28);
if (current_cas_latency == DRT_CAS_2_0)
dram_timing |= (2 << 28); // 2 clocks
else
dram_timing |= (1 << 28); // 3 clocks
/*
* Back to Back Read-Write command spacing (DDR, same or different Rows/Bank)
*/
dram_timing &= ~(3 << 26);
if (current_cas_latency == DRT_CAS_2_0)
dram_timing |= (2 << 26); // 5 clocks
else
dram_timing |= (1 << 26); // 6 clocks
/*
* Back To Back Read-Read commands spacing (DDR, different Rows):
*/
dram_timing &= ~(1 << 25);
dram_timing |= (1 << 25); // 3 clocks
PRINTK_DEBUG("DRT: %08x\n", dram_timing);
pci_write_config32(NORTHBRIDGE_MMC, DRT, dram_timing);
}
static void spd_set_dram_size(uint8_t dimm_mask)
{
int i;
int total_dram = 0;
uint32_t drb_reg = 0;
for (i = 0; i < DIMM_SOCKETS; i++) {
u8 dimm = DIMM0 + i;
struct dimm_size sz;
if (!(dimm_mask & (1 << i))) {
/* fill values even for not present DIMMs */
drb_reg |= (total_dram << (i * 16));
drb_reg |= (total_dram << ((i * 16) + 8));
continue; // This DIMM not usable
}
sz = spd_get_dimm_size(dimm);
total_dram += (1 << (sz.side1 - 28));
drb_reg |= (total_dram << (i * 16));
total_dram += (1 << (sz.side2 - 28));
drb_reg |= (total_dram << ((i * 16) + 8));
}
PRINTK_DEBUG("DRB: %08x\n", drb_reg);
pci_write_config32(NORTHBRIDGE_MMC, DRB, drb_reg);
}
static void spd_set_dram_pwr_management(void)
{
uint32_t pwrmg_reg;
pwrmg_reg = 0x10f10430;
pci_write_config32(NORTHBRIDGE_MMC, PWRMG, pwrmg_reg);
}
static void spd_set_dram_throttle_control(void)
{
uint32_t dtc_reg = 0;
/* DDR SDRAM Throttle Mode (TMODE):
* 0011 = Both Rank and GMCH Thermal Sensor based throttling is enabled. When the external SO-
* DIMM Thermal Sensor is Tripped DDR SDRAM Throttling begins based on the setting in RTT
*/
dtc_reg |= (3 << 28);
/* Read Counter Based Power Throttle Control (RCTC):
* 0 = 85%
*/
dtc_reg |= (0 << 24);
/* Write Counter Based Power Throttle Control (WCTC):
* 0 = 85%
*/
dtc_reg |= (0 << 20);
/* Read Thermal Based Power Throttle Control (RTTC):
* 0xA = 20%
*/
dtc_reg |= (0xA << 16);
/* Write Thermal Based Power Throttle Control (WTTC):
* 0xA = 20%
*/
dtc_reg |= (0xA << 12);
/* Counter Based Throttle Lock (CTLOCK): */
dtc_reg |= (0 << 11);
/* Thermal Throttle Lock (TTLOCK): */
dtc_reg |= (0 << 10);
/* Thermal Power Throttle Control fields Enable: */
dtc_reg |= (1 << 9);
/* High Priority Stream Throttling Enable: */
dtc_reg |= (0 << 8);
/* Global DDR SDRAM Sampling Window (GDSW): */
dtc_reg |= 0xff;
PRINTK_DEBUG("DTC: %08x\n", dtc_reg);
pci_write_config32(NORTHBRIDGE_MMC, DTC, dtc_reg);
}
static void spd_update(u8 reg, u32 new_value)
{
#if CONFIG_DEBUG_RAM_SETUP
u32 value1 = pci_read_config32(NORTHBRIDGE_MMC, reg);
#endif
pci_write_config32(NORTHBRIDGE_MMC, reg, new_value);
#if CONFIG_DEBUG_RAM_SETUP
u32 value2 = pci_read_config32(NORTHBRIDGE_MMC, reg);
PRINTK_DEBUG("update reg %02x, old: %08x, new: %08x, read back: %08x\n", reg, value1, new_value, value2);
#endif
}
/* if ram still doesn't work do this function */
static void spd_set_undocumented_registers(void)
{
spd_update(0x74, 0x00000001);
spd_update(0x78, 0x001fe974);
spd_update(0x80, 0x00af0039);
spd_update(0x84, 0x0000033c);
spd_update(0x88, 0x00000010);
spd_update(0xc0, 0x00000003);
}
static void northbridge_set_registers(void)
{
u16 value;
int video_memory = 0;
printk(BIOS_DEBUG, "Setting initial Northbridge registers....\n");
/* Set the value for Fixed DRAM Hole Control Register */
pci_write_config8(NORTHBRIDGE, FDHC, 0x00);
/* Set the value for Programable Attribute Map Registers
* Ideally, this should be R/W for as many ranges as possible.
*/
pci_write_config8(NORTHBRIDGE, PAM0, 0x30);
pci_write_config8(NORTHBRIDGE, PAM1, 0x33);
pci_write_config8(NORTHBRIDGE, PAM2, 0x33);
pci_write_config8(NORTHBRIDGE, PAM3, 0x33);
pci_write_config8(NORTHBRIDGE, PAM4, 0x33);
pci_write_config8(NORTHBRIDGE, PAM5, 0x33);
pci_write_config8(NORTHBRIDGE, PAM6, 0x33);
/* Set the value for System Management RAM Control Register */
pci_write_config8(NORTHBRIDGE, SMRAM, 0x02);
/* Set the value for GMCH Control Register #1 */
switch (CONFIG_VIDEO_MB) {
case 1: /* 1M of memory */
video_memory = 0x1;
break;
case 4: /* 4M of memory */
video_memory = 0x2;
break;
case 8: /* 8M of memory */
video_memory = 0x3;
break;
case 16: /* 16M of memory */
video_memory = 0x4;
break;
case 32: /* 32M of memory */
video_memory = 0x5;
break;
default: /* No memory */
pci_write_config16(NORTHBRIDGE, GMC, pci_read_config16(NORTHBRIDGE, GMC) | 1);
video_memory = 0x0;
}
value = pci_read_config16(NORTHBRIDGE, GGC);
value |= video_memory << 4;
if (video_memory == 0) {
value &= ~(1 < 1);
} else
value |= (1 < 1);
pci_write_config16(NORTHBRIDGE, GGC, value);
/* AGPCMD: disable AGP, Data-Rate: 1x */
pci_write_config32(NORTHBRIDGE, AGPCMD, 0x00000001);
pci_write_config8(NORTHBRIDGE, AMTT, 0x20);
pci_write_config8(NORTHBRIDGE, LPTT, 0x10);
printk(BIOS_DEBUG, "Initial Northbridge registers have been set.\n");
}
static void sdram_set_spd_registers(void)
{
uint8_t dimm_mask;
PRINTK_DEBUG("Reading SPD data...\n");
dimm_mask = spd_get_supported_dimms();
if (dimm_mask == 0) {
print_debug("No usable memory for this controller\n");
} else {
PRINTK_DEBUG("DIMM MASK: %02x\n", dimm_mask);
spd_set_row_attributes(dimm_mask);
spd_set_dram_controller_mode(dimm_mask);
spd_set_dram_timing(dimm_mask);
spd_set_dram_size(dimm_mask);
spd_set_dram_pwr_management();
spd_set_dram_throttle_control();
spd_set_undocumented_registers();
}
/* Setup Initial Northbridge Registers */
northbridge_set_registers();
}
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